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git01.mediatek.com / filogic / uboot / 623fbe3907893462994be98eeafd0db77d41af90 / . / board / xilinx / zynqmp / zynqmp-zcu102 / psu_init_gpl.c
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/******************************************************************************
*
* Copyright (C) 2015 Xilinx, Inc. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, see <http://www.gnu.org/licenses/>
*
*
******************************************************************************/
#include <xil_io.h>
/* #include <sleep.h> */
#include "psu_init_gpl.h"
int mask_pollOnValue(u32 add , u32 mask, u32 value );
int mask_poll(u32 add , u32 mask );
void mask_delay(u32 delay);
u32 mask_read(u32 add , u32 mask );
static void PSU_Mask_Write (unsigned long offset, unsigned long mask, unsigned long val)
{
unsigned long RegVal = 0x0;
RegVal = Xil_In32 (offset);
RegVal &= ~(mask);
RegVal |= (val & mask);
Xil_Out32 (offset, RegVal);
}
void prog_reg (unsigned long addr, unsigned long mask, unsigned long shift, unsigned long value) {
int rdata =0;
rdata = Xil_In32(addr);
rdata = rdata & (~mask);
rdata = rdata | (value << shift);
Xil_Out32(addr,rdata);
}
unsigned long psu_pll_init_data() {
// : RPLL INIT
/*Register : RPLL_CFG @ 0XFF5E0034</p>
PLL loop filter resistor control
PSU_CRL_APB_RPLL_CFG_RES 0x2
PLL charge pump control
PSU_CRL_APB_RPLL_CFG_CP 0x3
PLL loop filter high frequency capacitor control
PSU_CRL_APB_RPLL_CFG_LFHF 0x3
Lock circuit counter setting
PSU_CRL_APB_RPLL_CFG_LOCK_CNT 0x258
Lock circuit configuration settings for lock windowsize
PSU_CRL_APB_RPLL_CFG_LOCK_DLY 0x3f
Helper data. Values are to be looked up in a table from Data Sheet
(OFFSET, MASK, VALUE) (0XFF5E0034, 0xFE7FEDEFU ,0x7E4B0C62U)
RegMask = (CRL_APB_RPLL_CFG_RES_MASK | CRL_APB_RPLL_CFG_CP_MASK | CRL_APB_RPLL_CFG_LFHF_MASK | CRL_APB_RPLL_CFG_LOCK_CNT_MASK | CRL_APB_RPLL_CFG_LOCK_DLY_MASK | 0 );
RegVal = ((0x00000002U << CRL_APB_RPLL_CFG_RES_SHIFT
| 0x00000003U << CRL_APB_RPLL_CFG_CP_SHIFT
| 0x00000003U << CRL_APB_RPLL_CFG_LFHF_SHIFT
| 0x00000258U << CRL_APB_RPLL_CFG_LOCK_CNT_SHIFT
| 0x0000003FU << CRL_APB_RPLL_CFG_LOCK_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CFG_OFFSET ,0xFE7FEDEFU ,0x7E4B0C62U);
/*############################################################################################################################ */
// : UPDATE FB_DIV
/*Register : RPLL_CTRL @ 0XFF5E0030</p>
Mux select for determining which clock feeds this PLL. 0XX pss_ref_clk is the source 100 video clk is the source 101 pss_alt_
ef_clk is the source 110 aux_refclk[X] is the source 111 gt_crx_ref_clk is the source
PSU_CRL_APB_RPLL_CTRL_PRE_SRC 0x0
The integer portion of the feedback divider to the PLL
PSU_CRL_APB_RPLL_CTRL_FBDIV 0x48
This turns on the divide by 2 that is inside of the PLL. This does not change the VCO frequency, just the output frequency
PSU_CRL_APB_RPLL_CTRL_DIV2 0x1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0030, 0x00717F00U ,0x00014800U)
RegMask = (CRL_APB_RPLL_CTRL_PRE_SRC_MASK | CRL_APB_RPLL_CTRL_FBDIV_MASK | CRL_APB_RPLL_CTRL_DIV2_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RPLL_CTRL_PRE_SRC_SHIFT
| 0x00000048U << CRL_APB_RPLL_CTRL_FBDIV_SHIFT
| 0x00000001U << CRL_APB_RPLL_CTRL_DIV2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CTRL_OFFSET ,0x00717F00U ,0x00014800U);
/*############################################################################################################################ */
// : BY PASS PLL
/*Register : RPLL_CTRL @ 0XFF5E0030</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_RPLL_CTRL_BYPASS 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0030, 0x00000008U ,0x00000008U)
RegMask = (CRL_APB_RPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_RPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CTRL_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : ASSERT RESET
/*Register : RPLL_CTRL @ 0XFF5E0030</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRL_APB_RPLL_CTRL_RESET 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0030, 0x00000001U ,0x00000001U)
RegMask = (CRL_APB_RPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_RPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : DEASSERT RESET
/*Register : RPLL_CTRL @ 0XFF5E0030</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRL_APB_RPLL_CTRL_RESET 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0030, 0x00000001U ,0x00000000U)
RegMask = (CRL_APB_RPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CTRL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : CHECK PLL STATUS
/*Register : PLL_STATUS @ 0XFF5E0040</p>
RPLL is locked
PSU_CRL_APB_PLL_STATUS_RPLL_LOCK 1
(OFFSET, MASK, VALUE) (0XFF5E0040, 0x00000002U ,0x00000002U) */
mask_poll(CRL_APB_PLL_STATUS_OFFSET,0x00000002U);
/*############################################################################################################################ */
// : REMOVE PLL BY PASS
/*Register : RPLL_CTRL @ 0XFF5E0030</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_RPLL_CTRL_BYPASS 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0030, 0x00000008U ,0x00000000U)
RegMask = (CRL_APB_RPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_CTRL_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
/*Register : RPLL_TO_FPD_CTRL @ 0XFF5E0048</p>
Divisor value for this clock.
PSU_CRL_APB_RPLL_TO_FPD_CTRL_DIVISOR0 0x3
Control for a clock that will be generated in the LPD, but used in the FPD as a clock source for the peripheral clock muxes.
(OFFSET, MASK, VALUE) (0XFF5E0048, 0x00003F00U ,0x00000300U)
RegMask = (CRL_APB_RPLL_TO_FPD_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000003U << CRL_APB_RPLL_TO_FPD_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_TO_FPD_CTRL_OFFSET ,0x00003F00U ,0x00000300U);
/*############################################################################################################################ */
// : RPLL FRAC CFG
/*Register : RPLL_FRAC_CFG @ 0XFF5E0038</p>
Fractional SDM bypass control. When 0, PLL is in integer mode and it ignores all fractional data. When 1, PLL is in fractiona
mode and uses DATA of this register for the fractional portion of the feedback divider.
PSU_CRL_APB_RPLL_FRAC_CFG_ENABLED 0x0
Fractional value for the Feedback value.
PSU_CRL_APB_RPLL_FRAC_CFG_DATA 0x0
Fractional control for the PLL
(OFFSET, MASK, VALUE) (0XFF5E0038, 0x8000FFFFU ,0x00000000U)
RegMask = (CRL_APB_RPLL_FRAC_CFG_ENABLED_MASK | CRL_APB_RPLL_FRAC_CFG_DATA_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RPLL_FRAC_CFG_ENABLED_SHIFT
| 0x00000000U << CRL_APB_RPLL_FRAC_CFG_DATA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RPLL_FRAC_CFG_OFFSET ,0x8000FFFFU ,0x00000000U);
/*############################################################################################################################ */
// : IOPLL INIT
/*Register : IOPLL_CFG @ 0XFF5E0024</p>
PLL loop filter resistor control
PSU_CRL_APB_IOPLL_CFG_RES 0xc
PLL charge pump control
PSU_CRL_APB_IOPLL_CFG_CP 0x3
PLL loop filter high frequency capacitor control
PSU_CRL_APB_IOPLL_CFG_LFHF 0x3
Lock circuit counter setting
PSU_CRL_APB_IOPLL_CFG_LOCK_CNT 0x339
Lock circuit configuration settings for lock windowsize
PSU_CRL_APB_IOPLL_CFG_LOCK_DLY 0x3f
Helper data. Values are to be looked up in a table from Data Sheet
(OFFSET, MASK, VALUE) (0XFF5E0024, 0xFE7FEDEFU ,0x7E672C6CU)
RegMask = (CRL_APB_IOPLL_CFG_RES_MASK | CRL_APB_IOPLL_CFG_CP_MASK | CRL_APB_IOPLL_CFG_LFHF_MASK | CRL_APB_IOPLL_CFG_LOCK_CNT_MASK | CRL_APB_IOPLL_CFG_LOCK_DLY_MASK | 0 );
RegVal = ((0x0000000CU << CRL_APB_IOPLL_CFG_RES_SHIFT
| 0x00000003U << CRL_APB_IOPLL_CFG_CP_SHIFT
| 0x00000003U << CRL_APB_IOPLL_CFG_LFHF_SHIFT
| 0x00000339U << CRL_APB_IOPLL_CFG_LOCK_CNT_SHIFT
| 0x0000003FU << CRL_APB_IOPLL_CFG_LOCK_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CFG_OFFSET ,0xFE7FEDEFU ,0x7E672C6CU);
/*############################################################################################################################ */
// : UPDATE FB_DIV
/*Register : IOPLL_CTRL @ 0XFF5E0020</p>
Mux select for determining which clock feeds this PLL. 0XX pss_ref_clk is the source 100 video clk is the source 101 pss_alt_
ef_clk is the source 110 aux_refclk[X] is the source 111 gt_crx_ref_clk is the source
PSU_CRL_APB_IOPLL_CTRL_PRE_SRC 0x0
The integer portion of the feedback divider to the PLL
PSU_CRL_APB_IOPLL_CTRL_FBDIV 0x2d
This turns on the divide by 2 that is inside of the PLL. This does not change the VCO frequency, just the output frequency
PSU_CRL_APB_IOPLL_CTRL_DIV2 0x0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0020, 0x00717F00U ,0x00002D00U)
RegMask = (CRL_APB_IOPLL_CTRL_PRE_SRC_MASK | CRL_APB_IOPLL_CTRL_FBDIV_MASK | CRL_APB_IOPLL_CTRL_DIV2_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_IOPLL_CTRL_PRE_SRC_SHIFT
| 0x0000002DU << CRL_APB_IOPLL_CTRL_FBDIV_SHIFT
| 0x00000000U << CRL_APB_IOPLL_CTRL_DIV2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CTRL_OFFSET ,0x00717F00U ,0x00002D00U);
/*############################################################################################################################ */
// : BY PASS PLL
/*Register : IOPLL_CTRL @ 0XFF5E0020</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_IOPLL_CTRL_BYPASS 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0020, 0x00000008U ,0x00000008U)
RegMask = (CRL_APB_IOPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_IOPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CTRL_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : ASSERT RESET
/*Register : IOPLL_CTRL @ 0XFF5E0020</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRL_APB_IOPLL_CTRL_RESET 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0020, 0x00000001U ,0x00000001U)
RegMask = (CRL_APB_IOPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_IOPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : DEASSERT RESET
/*Register : IOPLL_CTRL @ 0XFF5E0020</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRL_APB_IOPLL_CTRL_RESET 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0020, 0x00000001U ,0x00000000U)
RegMask = (CRL_APB_IOPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_IOPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CTRL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : CHECK PLL STATUS
/*Register : PLL_STATUS @ 0XFF5E0040</p>
IOPLL is locked
PSU_CRL_APB_PLL_STATUS_IOPLL_LOCK 1
(OFFSET, MASK, VALUE) (0XFF5E0040, 0x00000001U ,0x00000001U) */
mask_poll(CRL_APB_PLL_STATUS_OFFSET,0x00000001U);
/*############################################################################################################################ */
// : REMOVE PLL BY PASS
/*Register : IOPLL_CTRL @ 0XFF5E0020</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_IOPLL_CTRL_BYPASS 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFF5E0020, 0x00000008U ,0x00000000U)
RegMask = (CRL_APB_IOPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_IOPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_CTRL_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
/*Register : IOPLL_TO_FPD_CTRL @ 0XFF5E0044</p>
Divisor value for this clock.
PSU_CRL_APB_IOPLL_TO_FPD_CTRL_DIVISOR0 0x3
Control for a clock that will be generated in the LPD, but used in the FPD as a clock source for the peripheral clock muxes.
(OFFSET, MASK, VALUE) (0XFF5E0044, 0x00003F00U ,0x00000300U)
RegMask = (CRL_APB_IOPLL_TO_FPD_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000003U << CRL_APB_IOPLL_TO_FPD_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_TO_FPD_CTRL_OFFSET ,0x00003F00U ,0x00000300U);
/*############################################################################################################################ */
// : IOPLL FRAC CFG
/*Register : IOPLL_FRAC_CFG @ 0XFF5E0028</p>
Fractional SDM bypass control. When 0, PLL is in integer mode and it ignores all fractional data. When 1, PLL is in fractiona
mode and uses DATA of this register for the fractional portion of the feedback divider.
PSU_CRL_APB_IOPLL_FRAC_CFG_ENABLED 0x0
Fractional value for the Feedback value.
PSU_CRL_APB_IOPLL_FRAC_CFG_DATA 0x0
Fractional control for the PLL
(OFFSET, MASK, VALUE) (0XFF5E0028, 0x8000FFFFU ,0x00000000U)
RegMask = (CRL_APB_IOPLL_FRAC_CFG_ENABLED_MASK | CRL_APB_IOPLL_FRAC_CFG_DATA_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_IOPLL_FRAC_CFG_ENABLED_SHIFT
| 0x00000000U << CRL_APB_IOPLL_FRAC_CFG_DATA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOPLL_FRAC_CFG_OFFSET ,0x8000FFFFU ,0x00000000U);
/*############################################################################################################################ */
// : APU_PLL INIT
/*Register : APLL_CFG @ 0XFD1A0024</p>
PLL loop filter resistor control
PSU_CRF_APB_APLL_CFG_RES 0x2
PLL charge pump control
PSU_CRF_APB_APLL_CFG_CP 0x3
PLL loop filter high frequency capacitor control
PSU_CRF_APB_APLL_CFG_LFHF 0x3
Lock circuit counter setting
PSU_CRF_APB_APLL_CFG_LOCK_CNT 0x258
Lock circuit configuration settings for lock windowsize
PSU_CRF_APB_APLL_CFG_LOCK_DLY 0x3f
Helper data. Values are to be looked up in a table from Data Sheet
(OFFSET, MASK, VALUE) (0XFD1A0024, 0xFE7FEDEFU ,0x7E4B0C62U)
RegMask = (CRF_APB_APLL_CFG_RES_MASK | CRF_APB_APLL_CFG_CP_MASK | CRF_APB_APLL_CFG_LFHF_MASK | CRF_APB_APLL_CFG_LOCK_CNT_MASK | CRF_APB_APLL_CFG_LOCK_DLY_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_APLL_CFG_RES_SHIFT
| 0x00000003U << CRF_APB_APLL_CFG_CP_SHIFT
| 0x00000003U << CRF_APB_APLL_CFG_LFHF_SHIFT
| 0x00000258U << CRF_APB_APLL_CFG_LOCK_CNT_SHIFT
| 0x0000003FU << CRF_APB_APLL_CFG_LOCK_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CFG_OFFSET ,0xFE7FEDEFU ,0x7E4B0C62U);
/*############################################################################################################################ */
// : UPDATE FB_DIV
/*Register : APLL_CTRL @ 0XFD1A0020</p>
Mux select for determining which clock feeds this PLL. 0XX pss_ref_clk is the source 100 video clk is the source 101 pss_alt_
ef_clk is the source 110 aux_refclk[X] is the source 111 gt_crx_ref_clk is the source
PSU_CRF_APB_APLL_CTRL_PRE_SRC 0x0
The integer portion of the feedback divider to the PLL
PSU_CRF_APB_APLL_CTRL_FBDIV 0x48
This turns on the divide by 2 that is inside of the PLL. This does not change the VCO frequency, just the output frequency
PSU_CRF_APB_APLL_CTRL_DIV2 0x1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0020, 0x00717F00U ,0x00014800U)
RegMask = (CRF_APB_APLL_CTRL_PRE_SRC_MASK | CRF_APB_APLL_CTRL_FBDIV_MASK | CRF_APB_APLL_CTRL_DIV2_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_APLL_CTRL_PRE_SRC_SHIFT
| 0x00000048U << CRF_APB_APLL_CTRL_FBDIV_SHIFT
| 0x00000001U << CRF_APB_APLL_CTRL_DIV2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CTRL_OFFSET ,0x00717F00U ,0x00014800U);
/*############################################################################################################################ */
// : BY PASS PLL
/*Register : APLL_CTRL @ 0XFD1A0020</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_APLL_CTRL_BYPASS 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0020, 0x00000008U ,0x00000008U)
RegMask = (CRF_APB_APLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_APLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CTRL_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : ASSERT RESET
/*Register : APLL_CTRL @ 0XFD1A0020</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_APLL_CTRL_RESET 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0020, 0x00000001U ,0x00000001U)
RegMask = (CRF_APB_APLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_APLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : DEASSERT RESET
/*Register : APLL_CTRL @ 0XFD1A0020</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_APLL_CTRL_RESET 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0020, 0x00000001U ,0x00000000U)
RegMask = (CRF_APB_APLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_APLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CTRL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : CHECK PLL STATUS
/*Register : PLL_STATUS @ 0XFD1A0044</p>
APLL is locked
PSU_CRF_APB_PLL_STATUS_APLL_LOCK 1
(OFFSET, MASK, VALUE) (0XFD1A0044, 0x00000001U ,0x00000001U) */
mask_poll(CRF_APB_PLL_STATUS_OFFSET,0x00000001U);
/*############################################################################################################################ */
// : REMOVE PLL BY PASS
/*Register : APLL_CTRL @ 0XFD1A0020</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_APLL_CTRL_BYPASS 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0020, 0x00000008U ,0x00000000U)
RegMask = (CRF_APB_APLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_APLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_CTRL_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
/*Register : APLL_TO_LPD_CTRL @ 0XFD1A0048</p>
Divisor value for this clock.
PSU_CRF_APB_APLL_TO_LPD_CTRL_DIVISOR0 0x3
Control for a clock that will be generated in the FPD, but used in the LPD as a clock source for the peripheral clock muxes.
(OFFSET, MASK, VALUE) (0XFD1A0048, 0x00003F00U ,0x00000300U)
RegMask = (CRF_APB_APLL_TO_LPD_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000003U << CRF_APB_APLL_TO_LPD_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_TO_LPD_CTRL_OFFSET ,0x00003F00U ,0x00000300U);
/*############################################################################################################################ */
// : APLL FRAC CFG
/*Register : APLL_FRAC_CFG @ 0XFD1A0028</p>
Fractional SDM bypass control. When 0, PLL is in integer mode and it ignores all fractional data. When 1, PLL is in fractiona
mode and uses DATA of this register for the fractional portion of the feedback divider.
PSU_CRF_APB_APLL_FRAC_CFG_ENABLED 0x0
Fractional value for the Feedback value.
PSU_CRF_APB_APLL_FRAC_CFG_DATA 0x0
Fractional control for the PLL
(OFFSET, MASK, VALUE) (0XFD1A0028, 0x8000FFFFU ,0x00000000U)
RegMask = (CRF_APB_APLL_FRAC_CFG_ENABLED_MASK | CRF_APB_APLL_FRAC_CFG_DATA_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_APLL_FRAC_CFG_ENABLED_SHIFT
| 0x00000000U << CRF_APB_APLL_FRAC_CFG_DATA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_APLL_FRAC_CFG_OFFSET ,0x8000FFFFU ,0x00000000U);
/*############################################################################################################################ */
// : DDR_PLL INIT
/*Register : DPLL_CFG @ 0XFD1A0030</p>
PLL loop filter resistor control
PSU_CRF_APB_DPLL_CFG_RES 0x2
PLL charge pump control
PSU_CRF_APB_DPLL_CFG_CP 0x3
PLL loop filter high frequency capacitor control
PSU_CRF_APB_DPLL_CFG_LFHF 0x3
Lock circuit counter setting
PSU_CRF_APB_DPLL_CFG_LOCK_CNT 0x258
Lock circuit configuration settings for lock windowsize
PSU_CRF_APB_DPLL_CFG_LOCK_DLY 0x3f
Helper data. Values are to be looked up in a table from Data Sheet
(OFFSET, MASK, VALUE) (0XFD1A0030, 0xFE7FEDEFU ,0x7E4B0C62U)
RegMask = (CRF_APB_DPLL_CFG_RES_MASK | CRF_APB_DPLL_CFG_CP_MASK | CRF_APB_DPLL_CFG_LFHF_MASK | CRF_APB_DPLL_CFG_LOCK_CNT_MASK | CRF_APB_DPLL_CFG_LOCK_DLY_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DPLL_CFG_RES_SHIFT
| 0x00000003U << CRF_APB_DPLL_CFG_CP_SHIFT
| 0x00000003U << CRF_APB_DPLL_CFG_LFHF_SHIFT
| 0x00000258U << CRF_APB_DPLL_CFG_LOCK_CNT_SHIFT
| 0x0000003FU << CRF_APB_DPLL_CFG_LOCK_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CFG_OFFSET ,0xFE7FEDEFU ,0x7E4B0C62U);
/*############################################################################################################################ */
// : UPDATE FB_DIV
/*Register : DPLL_CTRL @ 0XFD1A002C</p>
Mux select for determining which clock feeds this PLL. 0XX pss_ref_clk is the source 100 video clk is the source 101 pss_alt_
ef_clk is the source 110 aux_refclk[X] is the source 111 gt_crx_ref_clk is the source
PSU_CRF_APB_DPLL_CTRL_PRE_SRC 0x0
The integer portion of the feedback divider to the PLL
PSU_CRF_APB_DPLL_CTRL_FBDIV 0x40
This turns on the divide by 2 that is inside of the PLL. This does not change the VCO frequency, just the output frequency
PSU_CRF_APB_DPLL_CTRL_DIV2 0x1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A002C, 0x00717F00U ,0x00014000U)
RegMask = (CRF_APB_DPLL_CTRL_PRE_SRC_MASK | CRF_APB_DPLL_CTRL_FBDIV_MASK | CRF_APB_DPLL_CTRL_DIV2_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_DPLL_CTRL_PRE_SRC_SHIFT
| 0x00000040U << CRF_APB_DPLL_CTRL_FBDIV_SHIFT
| 0x00000001U << CRF_APB_DPLL_CTRL_DIV2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CTRL_OFFSET ,0x00717F00U ,0x00014000U);
/*############################################################################################################################ */
// : BY PASS PLL
/*Register : DPLL_CTRL @ 0XFD1A002C</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DPLL_CTRL_BYPASS 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A002C, 0x00000008U ,0x00000008U)
RegMask = (CRF_APB_DPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_DPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CTRL_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : ASSERT RESET
/*Register : DPLL_CTRL @ 0XFD1A002C</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_DPLL_CTRL_RESET 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A002C, 0x00000001U ,0x00000001U)
RegMask = (CRF_APB_DPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_DPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : DEASSERT RESET
/*Register : DPLL_CTRL @ 0XFD1A002C</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_DPLL_CTRL_RESET 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A002C, 0x00000001U ,0x00000000U)
RegMask = (CRF_APB_DPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_DPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CTRL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : CHECK PLL STATUS
/*Register : PLL_STATUS @ 0XFD1A0044</p>
DPLL is locked
PSU_CRF_APB_PLL_STATUS_DPLL_LOCK 1
(OFFSET, MASK, VALUE) (0XFD1A0044, 0x00000002U ,0x00000002U) */
mask_poll(CRF_APB_PLL_STATUS_OFFSET,0x00000002U);
/*############################################################################################################################ */
// : REMOVE PLL BY PASS
/*Register : DPLL_CTRL @ 0XFD1A002C</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DPLL_CTRL_BYPASS 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A002C, 0x00000008U ,0x00000000U)
RegMask = (CRF_APB_DPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_DPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_CTRL_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
/*Register : DPLL_TO_LPD_CTRL @ 0XFD1A004C</p>
Divisor value for this clock.
PSU_CRF_APB_DPLL_TO_LPD_CTRL_DIVISOR0 0x3
Control for a clock that will be generated in the FPD, but used in the LPD as a clock source for the peripheral clock muxes.
(OFFSET, MASK, VALUE) (0XFD1A004C, 0x00003F00U ,0x00000300U)
RegMask = (CRF_APB_DPLL_TO_LPD_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000003U << CRF_APB_DPLL_TO_LPD_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_TO_LPD_CTRL_OFFSET ,0x00003F00U ,0x00000300U);
/*############################################################################################################################ */
// : DPLL FRAC CFG
/*Register : DPLL_FRAC_CFG @ 0XFD1A0034</p>
Fractional SDM bypass control. When 0, PLL is in integer mode and it ignores all fractional data. When 1, PLL is in fractiona
mode and uses DATA of this register for the fractional portion of the feedback divider.
PSU_CRF_APB_DPLL_FRAC_CFG_ENABLED 0x0
Fractional value for the Feedback value.
PSU_CRF_APB_DPLL_FRAC_CFG_DATA 0x0
Fractional control for the PLL
(OFFSET, MASK, VALUE) (0XFD1A0034, 0x8000FFFFU ,0x00000000U)
RegMask = (CRF_APB_DPLL_FRAC_CFG_ENABLED_MASK | CRF_APB_DPLL_FRAC_CFG_DATA_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_DPLL_FRAC_CFG_ENABLED_SHIFT
| 0x00000000U << CRF_APB_DPLL_FRAC_CFG_DATA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPLL_FRAC_CFG_OFFSET ,0x8000FFFFU ,0x00000000U);
/*############################################################################################################################ */
// : VIDEO_PLL INIT
/*Register : VPLL_CFG @ 0XFD1A003C</p>
PLL loop filter resistor control
PSU_CRF_APB_VPLL_CFG_RES 0x2
PLL charge pump control
PSU_CRF_APB_VPLL_CFG_CP 0x3
PLL loop filter high frequency capacitor control
PSU_CRF_APB_VPLL_CFG_LFHF 0x3
Lock circuit counter setting
PSU_CRF_APB_VPLL_CFG_LOCK_CNT 0x28a
Lock circuit configuration settings for lock windowsize
PSU_CRF_APB_VPLL_CFG_LOCK_DLY 0x3f
Helper data. Values are to be looked up in a table from Data Sheet
(OFFSET, MASK, VALUE) (0XFD1A003C, 0xFE7FEDEFU ,0x7E514C62U)
RegMask = (CRF_APB_VPLL_CFG_RES_MASK | CRF_APB_VPLL_CFG_CP_MASK | CRF_APB_VPLL_CFG_LFHF_MASK | CRF_APB_VPLL_CFG_LOCK_CNT_MASK | CRF_APB_VPLL_CFG_LOCK_DLY_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_VPLL_CFG_RES_SHIFT
| 0x00000003U << CRF_APB_VPLL_CFG_CP_SHIFT
| 0x00000003U << CRF_APB_VPLL_CFG_LFHF_SHIFT
| 0x0000028AU << CRF_APB_VPLL_CFG_LOCK_CNT_SHIFT
| 0x0000003FU << CRF_APB_VPLL_CFG_LOCK_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CFG_OFFSET ,0xFE7FEDEFU ,0x7E514C62U);
/*############################################################################################################################ */
// : UPDATE FB_DIV
/*Register : VPLL_CTRL @ 0XFD1A0038</p>
Mux select for determining which clock feeds this PLL. 0XX pss_ref_clk is the source 100 video clk is the source 101 pss_alt_
ef_clk is the source 110 aux_refclk[X] is the source 111 gt_crx_ref_clk is the source
PSU_CRF_APB_VPLL_CTRL_PRE_SRC 0x0
The integer portion of the feedback divider to the PLL
PSU_CRF_APB_VPLL_CTRL_FBDIV 0x39
This turns on the divide by 2 that is inside of the PLL. This does not change the VCO frequency, just the output frequency
PSU_CRF_APB_VPLL_CTRL_DIV2 0x1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0038, 0x00717F00U ,0x00013900U)
RegMask = (CRF_APB_VPLL_CTRL_PRE_SRC_MASK | CRF_APB_VPLL_CTRL_FBDIV_MASK | CRF_APB_VPLL_CTRL_DIV2_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_VPLL_CTRL_PRE_SRC_SHIFT
| 0x00000039U << CRF_APB_VPLL_CTRL_FBDIV_SHIFT
| 0x00000001U << CRF_APB_VPLL_CTRL_DIV2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CTRL_OFFSET ,0x00717F00U ,0x00013900U);
/*############################################################################################################################ */
// : BY PASS PLL
/*Register : VPLL_CTRL @ 0XFD1A0038</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_VPLL_CTRL_BYPASS 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0038, 0x00000008U ,0x00000008U)
RegMask = (CRF_APB_VPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_VPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CTRL_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : ASSERT RESET
/*Register : VPLL_CTRL @ 0XFD1A0038</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_VPLL_CTRL_RESET 1
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0038, 0x00000001U ,0x00000001U)
RegMask = (CRF_APB_VPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_VPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : DEASSERT RESET
/*Register : VPLL_CTRL @ 0XFD1A0038</p>
Asserts Reset to the PLL. When asserting reset, the PLL must already be in BYPASS.
PSU_CRF_APB_VPLL_CTRL_RESET 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0038, 0x00000001U ,0x00000000U)
RegMask = (CRF_APB_VPLL_CTRL_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_VPLL_CTRL_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CTRL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : CHECK PLL STATUS
/*Register : PLL_STATUS @ 0XFD1A0044</p>
VPLL is locked
PSU_CRF_APB_PLL_STATUS_VPLL_LOCK 1
(OFFSET, MASK, VALUE) (0XFD1A0044, 0x00000004U ,0x00000004U) */
mask_poll(CRF_APB_PLL_STATUS_OFFSET,0x00000004U);
/*############################################################################################################################ */
// : REMOVE PLL BY PASS
/*Register : VPLL_CTRL @ 0XFD1A0038</p>
Bypasses the PLL clock. The usable clock will be determined from the POST_SRC field. (This signal may only be toggled after 4
cycles of the old clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_VPLL_CTRL_BYPASS 0
PLL Basic Control
(OFFSET, MASK, VALUE) (0XFD1A0038, 0x00000008U ,0x00000000U)
RegMask = (CRF_APB_VPLL_CTRL_BYPASS_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_VPLL_CTRL_BYPASS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_CTRL_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
/*Register : VPLL_TO_LPD_CTRL @ 0XFD1A0050</p>
Divisor value for this clock.
PSU_CRF_APB_VPLL_TO_LPD_CTRL_DIVISOR0 0x3
Control for a clock that will be generated in the FPD, but used in the LPD as a clock source for the peripheral clock muxes.
(OFFSET, MASK, VALUE) (0XFD1A0050, 0x00003F00U ,0x00000300U)
RegMask = (CRF_APB_VPLL_TO_LPD_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000003U << CRF_APB_VPLL_TO_LPD_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_TO_LPD_CTRL_OFFSET ,0x00003F00U ,0x00000300U);
/*############################################################################################################################ */
// : VIDEO FRAC CFG
/*Register : VPLL_FRAC_CFG @ 0XFD1A0040</p>
Fractional SDM bypass control. When 0, PLL is in integer mode and it ignores all fractional data. When 1, PLL is in fractiona
mode and uses DATA of this register for the fractional portion of the feedback divider.
PSU_CRF_APB_VPLL_FRAC_CFG_ENABLED 0x1
Fractional value for the Feedback value.
PSU_CRF_APB_VPLL_FRAC_CFG_DATA 0x820c
Fractional control for the PLL
(OFFSET, MASK, VALUE) (0XFD1A0040, 0x8000FFFFU ,0x8000820CU)
RegMask = (CRF_APB_VPLL_FRAC_CFG_ENABLED_MASK | CRF_APB_VPLL_FRAC_CFG_DATA_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_VPLL_FRAC_CFG_ENABLED_SHIFT
| 0x0000820CU << CRF_APB_VPLL_FRAC_CFG_DATA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_VPLL_FRAC_CFG_OFFSET ,0x8000FFFFU ,0x8000820CU);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_clock_init_data() {
// : CLOCK CONTROL SLCR REGISTER
/*Register : GEM3_REF_CTRL @ 0XFF5E005C</p>
Clock active for the RX channel
PSU_CRL_APB_GEM3_REF_CTRL_RX_CLKACT 0x1
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_GEM3_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_GEM3_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_GEM3_REF_CTRL_DIVISOR0 0xc
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_GEM3_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E005C, 0x063F3F07U ,0x06010C00U)
RegMask = (CRL_APB_GEM3_REF_CTRL_RX_CLKACT_MASK | CRL_APB_GEM3_REF_CTRL_CLKACT_MASK | CRL_APB_GEM3_REF_CTRL_DIVISOR1_MASK | CRL_APB_GEM3_REF_CTRL_DIVISOR0_MASK | CRL_APB_GEM3_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_GEM3_REF_CTRL_RX_CLKACT_SHIFT
| 0x00000001U << CRL_APB_GEM3_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_GEM3_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000CU << CRL_APB_GEM3_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_GEM3_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_GEM3_REF_CTRL_OFFSET ,0x063F3F07U ,0x06010C00U);
/*############################################################################################################################ */
/*Register : USB0_BUS_REF_CTRL @ 0XFF5E0060</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_USB0_BUS_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_USB0_BUS_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_USB0_BUS_REF_CTRL_DIVISOR0 0x6
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_USB0_BUS_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0060, 0x023F3F07U ,0x02010600U)
RegMask = (CRL_APB_USB0_BUS_REF_CTRL_CLKACT_MASK | CRL_APB_USB0_BUS_REF_CTRL_DIVISOR1_MASK | CRL_APB_USB0_BUS_REF_CTRL_DIVISOR0_MASK | CRL_APB_USB0_BUS_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_USB0_BUS_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_USB0_BUS_REF_CTRL_DIVISOR1_SHIFT
| 0x00000006U << CRL_APB_USB0_BUS_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_USB0_BUS_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_USB0_BUS_REF_CTRL_OFFSET ,0x023F3F07U ,0x02010600U);
/*############################################################################################################################ */
/*Register : USB3_DUAL_REF_CTRL @ 0XFF5E004C</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_USB3_DUAL_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR1 0xf
6 bit divider
PSU_CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR0 0x5
000 = IOPLL; 010 = RPLL; 011 = DPLL. (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_USB3_DUAL_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E004C, 0x023F3F07U ,0x020F0500U)
RegMask = (CRL_APB_USB3_DUAL_REF_CTRL_CLKACT_MASK | CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR1_MASK | CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR0_MASK | CRL_APB_USB3_DUAL_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_USB3_DUAL_REF_CTRL_CLKACT_SHIFT
| 0x0000000FU << CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR1_SHIFT
| 0x00000005U << CRL_APB_USB3_DUAL_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_USB3_DUAL_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_USB3_DUAL_REF_CTRL_OFFSET ,0x023F3F07U ,0x020F0500U);
/*############################################################################################################################ */
/*Register : QSPI_REF_CTRL @ 0XFF5E0068</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_QSPI_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_QSPI_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_QSPI_REF_CTRL_DIVISOR0 0xc
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_QSPI_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0068, 0x013F3F07U ,0x01010C00U)
RegMask = (CRL_APB_QSPI_REF_CTRL_CLKACT_MASK | CRL_APB_QSPI_REF_CTRL_DIVISOR1_MASK | CRL_APB_QSPI_REF_CTRL_DIVISOR0_MASK | CRL_APB_QSPI_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_QSPI_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_QSPI_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000CU << CRL_APB_QSPI_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_QSPI_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_QSPI_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010C00U);
/*############################################################################################################################ */
/*Register : SDIO1_REF_CTRL @ 0XFF5E0070</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_SDIO1_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_SDIO1_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_SDIO1_REF_CTRL_DIVISOR0 0x6
000 = IOPLL; 010 = RPLL; 011 = VPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_SDIO1_REF_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0070, 0x013F3F07U ,0x01010602U)
RegMask = (CRL_APB_SDIO1_REF_CTRL_CLKACT_MASK | CRL_APB_SDIO1_REF_CTRL_DIVISOR1_MASK | CRL_APB_SDIO1_REF_CTRL_DIVISOR0_MASK | CRL_APB_SDIO1_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_SDIO1_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_SDIO1_REF_CTRL_DIVISOR1_SHIFT
| 0x00000006U << CRL_APB_SDIO1_REF_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_SDIO1_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_SDIO1_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010602U);
/*############################################################################################################################ */
/*Register : SDIO_CLK_CTRL @ 0XFF18030C</p>
MIO pad selection for sdio1_rx_clk (feedback clock from the PAD) 0: MIO [51] 1: MIO [76]
PSU_IOU_SLCR_SDIO_CLK_CTRL_SDIO1_RX_SRC_SEL 0
SoC Debug Clock Control
(OFFSET, MASK, VALUE) (0XFF18030C, 0x00020000U ,0x00000000U)
RegMask = (IOU_SLCR_SDIO_CLK_CTRL_SDIO1_RX_SRC_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_SDIO_CLK_CTRL_SDIO1_RX_SRC_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_SDIO_CLK_CTRL_OFFSET ,0x00020000U ,0x00000000U);
/*############################################################################################################################ */
/*Register : UART0_REF_CTRL @ 0XFF5E0074</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_UART0_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_UART0_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_UART0_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_UART0_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0074, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_UART0_REF_CTRL_CLKACT_MASK | CRL_APB_UART0_REF_CTRL_DIVISOR1_MASK | CRL_APB_UART0_REF_CTRL_DIVISOR0_MASK | CRL_APB_UART0_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_UART0_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_UART0_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_UART0_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_UART0_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_UART0_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : UART1_REF_CTRL @ 0XFF5E0078</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_UART1_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_UART1_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_UART1_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_UART1_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0078, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_UART1_REF_CTRL_CLKACT_MASK | CRL_APB_UART1_REF_CTRL_DIVISOR1_MASK | CRL_APB_UART1_REF_CTRL_DIVISOR0_MASK | CRL_APB_UART1_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_UART1_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_UART1_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_UART1_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_UART1_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_UART1_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : I2C0_REF_CTRL @ 0XFF5E0120</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_I2C0_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_I2C0_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_I2C0_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_I2C0_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0120, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_I2C0_REF_CTRL_CLKACT_MASK | CRL_APB_I2C0_REF_CTRL_DIVISOR1_MASK | CRL_APB_I2C0_REF_CTRL_DIVISOR0_MASK | CRL_APB_I2C0_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_I2C0_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_I2C0_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_I2C0_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_I2C0_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_I2C0_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : I2C1_REF_CTRL @ 0XFF5E0124</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_I2C1_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_I2C1_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_I2C1_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_I2C1_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0124, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_I2C1_REF_CTRL_CLKACT_MASK | CRL_APB_I2C1_REF_CTRL_DIVISOR1_MASK | CRL_APB_I2C1_REF_CTRL_DIVISOR0_MASK | CRL_APB_I2C1_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_I2C1_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_I2C1_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_I2C1_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_I2C1_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_I2C1_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : CAN1_REF_CTRL @ 0XFF5E0088</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_CAN1_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_CAN1_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_CAN1_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_CAN1_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0088, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_CAN1_REF_CTRL_CLKACT_MASK | CRL_APB_CAN1_REF_CTRL_DIVISOR1_MASK | CRL_APB_CAN1_REF_CTRL_DIVISOR0_MASK | CRL_APB_CAN1_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_CAN1_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_CAN1_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_CAN1_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_CAN1_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_CAN1_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : CPU_R5_CTRL @ 0XFF5E0090</p>
Turing this off will shut down the OCM, some parts of the APM, and prevent transactions going from the FPD to the LPD and cou
d lead to system hang
PSU_CRL_APB_CPU_R5_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_CPU_R5_CTRL_DIVISOR0 0x3
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_CPU_R5_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0090, 0x01003F07U ,0x01000302U)
RegMask = (CRL_APB_CPU_R5_CTRL_CLKACT_MASK | CRL_APB_CPU_R5_CTRL_DIVISOR0_MASK | CRL_APB_CPU_R5_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_CPU_R5_CTRL_CLKACT_SHIFT
| 0x00000003U << CRL_APB_CPU_R5_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_CPU_R5_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_CPU_R5_CTRL_OFFSET ,0x01003F07U ,0x01000302U);
/*############################################################################################################################ */
/*Register : IOU_SWITCH_CTRL @ 0XFF5E009C</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_IOU_SWITCH_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_IOU_SWITCH_CTRL_DIVISOR0 0x6
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_IOU_SWITCH_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E009C, 0x01003F07U ,0x01000602U)
RegMask = (CRL_APB_IOU_SWITCH_CTRL_CLKACT_MASK | CRL_APB_IOU_SWITCH_CTRL_DIVISOR0_MASK | CRL_APB_IOU_SWITCH_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_IOU_SWITCH_CTRL_CLKACT_SHIFT
| 0x00000006U << CRL_APB_IOU_SWITCH_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_IOU_SWITCH_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_IOU_SWITCH_CTRL_OFFSET ,0x01003F07U ,0x01000602U);
/*############################################################################################################################ */
/*Register : PCAP_CTRL @ 0XFF5E00A4</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_PCAP_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_PCAP_CTRL_DIVISOR0 0x6
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_PCAP_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00A4, 0x01003F07U ,0x01000602U)
RegMask = (CRL_APB_PCAP_CTRL_CLKACT_MASK | CRL_APB_PCAP_CTRL_DIVISOR0_MASK | CRL_APB_PCAP_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_PCAP_CTRL_CLKACT_SHIFT
| 0x00000006U << CRL_APB_PCAP_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_PCAP_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_PCAP_CTRL_OFFSET ,0x01003F07U ,0x01000602U);
/*############################################################################################################################ */
/*Register : LPD_SWITCH_CTRL @ 0XFF5E00A8</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_LPD_SWITCH_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_LPD_SWITCH_CTRL_DIVISOR0 0x3
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_LPD_SWITCH_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00A8, 0x01003F07U ,0x01000302U)
RegMask = (CRL_APB_LPD_SWITCH_CTRL_CLKACT_MASK | CRL_APB_LPD_SWITCH_CTRL_DIVISOR0_MASK | CRL_APB_LPD_SWITCH_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_LPD_SWITCH_CTRL_CLKACT_SHIFT
| 0x00000003U << CRL_APB_LPD_SWITCH_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_LPD_SWITCH_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_LPD_SWITCH_CTRL_OFFSET ,0x01003F07U ,0x01000302U);
/*############################################################################################################################ */
/*Register : LPD_LSBUS_CTRL @ 0XFF5E00AC</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_LPD_LSBUS_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_LPD_LSBUS_CTRL_DIVISOR0 0xf
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_LPD_LSBUS_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00AC, 0x01003F07U ,0x01000F02U)
RegMask = (CRL_APB_LPD_LSBUS_CTRL_CLKACT_MASK | CRL_APB_LPD_LSBUS_CTRL_DIVISOR0_MASK | CRL_APB_LPD_LSBUS_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_LPD_LSBUS_CTRL_CLKACT_SHIFT
| 0x0000000FU << CRL_APB_LPD_LSBUS_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_LPD_LSBUS_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_LPD_LSBUS_CTRL_OFFSET ,0x01003F07U ,0x01000F02U);
/*############################################################################################################################ */
/*Register : DBG_LPD_CTRL @ 0XFF5E00B0</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_DBG_LPD_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_DBG_LPD_CTRL_DIVISOR0 0x6
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_DBG_LPD_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00B0, 0x01003F07U ,0x01000602U)
RegMask = (CRL_APB_DBG_LPD_CTRL_CLKACT_MASK | CRL_APB_DBG_LPD_CTRL_DIVISOR0_MASK | CRL_APB_DBG_LPD_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_DBG_LPD_CTRL_CLKACT_SHIFT
| 0x00000006U << CRL_APB_DBG_LPD_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_DBG_LPD_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_DBG_LPD_CTRL_OFFSET ,0x01003F07U ,0x01000602U);
/*############################################################################################################################ */
/*Register : ADMA_REF_CTRL @ 0XFF5E00B8</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_ADMA_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_ADMA_REF_CTRL_DIVISOR0 0x3
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_ADMA_REF_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00B8, 0x01003F07U ,0x01000302U)
RegMask = (CRL_APB_ADMA_REF_CTRL_CLKACT_MASK | CRL_APB_ADMA_REF_CTRL_DIVISOR0_MASK | CRL_APB_ADMA_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_ADMA_REF_CTRL_CLKACT_SHIFT
| 0x00000003U << CRL_APB_ADMA_REF_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_ADMA_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_ADMA_REF_CTRL_OFFSET ,0x01003F07U ,0x01000302U);
/*############################################################################################################################ */
/*Register : PL0_REF_CTRL @ 0XFF5E00C0</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_PL0_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_PL0_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_PL0_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_PL0_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00C0, 0x013F3F07U ,0x01010F00U)
RegMask = (CRL_APB_PL0_REF_CTRL_CLKACT_MASK | CRL_APB_PL0_REF_CTRL_DIVISOR1_MASK | CRL_APB_PL0_REF_CTRL_DIVISOR0_MASK | CRL_APB_PL0_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_PL0_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_PL0_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_PL0_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_PL0_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_PL0_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010F00U);
/*############################################################################################################################ */
/*Register : PL1_REF_CTRL @ 0XFF5E00C4</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_PL1_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_PL1_REF_CTRL_DIVISOR1 0x4
6 bit divider
PSU_CRL_APB_PL1_REF_CTRL_DIVISOR0 0xf
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_PL1_REF_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00C4, 0x013F3F07U ,0x01040F00U)
RegMask = (CRL_APB_PL1_REF_CTRL_CLKACT_MASK | CRL_APB_PL1_REF_CTRL_DIVISOR1_MASK | CRL_APB_PL1_REF_CTRL_DIVISOR0_MASK | CRL_APB_PL1_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_PL1_REF_CTRL_CLKACT_SHIFT
| 0x00000004U << CRL_APB_PL1_REF_CTRL_DIVISOR1_SHIFT
| 0x0000000FU << CRL_APB_PL1_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_PL1_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_PL1_REF_CTRL_OFFSET ,0x013F3F07U ,0x01040F00U);
/*############################################################################################################################ */
/*Register : PL2_REF_CTRL @ 0XFF5E00C8</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_PL2_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_PL2_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_PL2_REF_CTRL_DIVISOR0 0x4
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_PL2_REF_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00C8, 0x013F3F07U ,0x01010402U)
RegMask = (CRL_APB_PL2_REF_CTRL_CLKACT_MASK | CRL_APB_PL2_REF_CTRL_DIVISOR1_MASK | CRL_APB_PL2_REF_CTRL_DIVISOR0_MASK | CRL_APB_PL2_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_PL2_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_PL2_REF_CTRL_DIVISOR1_SHIFT
| 0x00000004U << CRL_APB_PL2_REF_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_PL2_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_PL2_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010402U);
/*############################################################################################################################ */
/*Register : PL3_REF_CTRL @ 0XFF5E00CC</p>
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_PL3_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRL_APB_PL3_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_PL3_REF_CTRL_DIVISOR0 0x3
000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_PL3_REF_CTRL_SRCSEL 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E00CC, 0x013F3F07U ,0x01010302U)
RegMask = (CRL_APB_PL3_REF_CTRL_CLKACT_MASK | CRL_APB_PL3_REF_CTRL_DIVISOR1_MASK | CRL_APB_PL3_REF_CTRL_DIVISOR0_MASK | CRL_APB_PL3_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_PL3_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRL_APB_PL3_REF_CTRL_DIVISOR1_SHIFT
| 0x00000003U << CRL_APB_PL3_REF_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_PL3_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_PL3_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010302U);
/*############################################################################################################################ */
/*Register : AMS_REF_CTRL @ 0XFF5E0108</p>
6 bit divider
PSU_CRL_APB_AMS_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRL_APB_AMS_REF_CTRL_DIVISOR0 0x1d
000 = RPLL; 010 = IOPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_AMS_REF_CTRL_SRCSEL 0x2
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_AMS_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0108, 0x013F3F07U ,0x01011D02U)
RegMask = (CRL_APB_AMS_REF_CTRL_DIVISOR1_MASK | CRL_APB_AMS_REF_CTRL_DIVISOR0_MASK | CRL_APB_AMS_REF_CTRL_SRCSEL_MASK | CRL_APB_AMS_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_AMS_REF_CTRL_DIVISOR1_SHIFT
| 0x0000001DU << CRL_APB_AMS_REF_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRL_APB_AMS_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRL_APB_AMS_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_AMS_REF_CTRL_OFFSET ,0x013F3F07U ,0x01011D02U);
/*############################################################################################################################ */
/*Register : DLL_REF_CTRL @ 0XFF5E0104</p>
000 = IOPLL; 001 = RPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new clock. This
is not usually an issue, but designers must be aware.)
PSU_CRL_APB_DLL_REF_CTRL_SRCSEL 0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0104, 0x00000007U ,0x00000000U)
RegMask = (CRL_APB_DLL_REF_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_DLL_REF_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_DLL_REF_CTRL_OFFSET ,0x00000007U ,0x00000000U);
/*############################################################################################################################ */
/*Register : TIMESTAMP_REF_CTRL @ 0XFF5E0128</p>
6 bit divider
PSU_CRL_APB_TIMESTAMP_REF_CTRL_DIVISOR0 0xf
1XX = pss_ref_clk; 000 = IOPLL; 010 = RPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and
cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRL_APB_TIMESTAMP_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRL_APB_TIMESTAMP_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFF5E0128, 0x01003F07U ,0x01000F00U)
RegMask = (CRL_APB_TIMESTAMP_REF_CTRL_DIVISOR0_MASK | CRL_APB_TIMESTAMP_REF_CTRL_SRCSEL_MASK | CRL_APB_TIMESTAMP_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x0000000FU << CRL_APB_TIMESTAMP_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRL_APB_TIMESTAMP_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRL_APB_TIMESTAMP_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_TIMESTAMP_REF_CTRL_OFFSET ,0x01003F07U ,0x01000F00U);
/*############################################################################################################################ */
/*Register : SATA_REF_CTRL @ 0XFD1A00A0</p>
000 = IOPLL_TO_FPD; 010 = APLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_SATA_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_SATA_REF_CTRL_CLKACT 0x1
6 bit divider
PSU_CRF_APB_SATA_REF_CTRL_DIVISOR0 0x2
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00A0, 0x01003F07U ,0x01000200U)
RegMask = (CRF_APB_SATA_REF_CTRL_SRCSEL_MASK | CRF_APB_SATA_REF_CTRL_CLKACT_MASK | CRF_APB_SATA_REF_CTRL_DIVISOR0_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_SATA_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_SATA_REF_CTRL_CLKACT_SHIFT
| 0x00000002U << CRF_APB_SATA_REF_CTRL_DIVISOR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_SATA_REF_CTRL_OFFSET ,0x01003F07U ,0x01000200U);
/*############################################################################################################################ */
/*Register : DP_VIDEO_REF_CTRL @ 0XFD1A0070</p>
6 bit divider
PSU_CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR0 0x3
000 = VPLL; 010 = DPLL; 011 = RPLL_TO_FPD - might be using extra mux; (This signal may only be toggled after 4 cycles of the
ld clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DP_VIDEO_REF_CTRL_SRCSEL 0x3
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DP_VIDEO_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0070, 0x013F3F07U ,0x01010303U)
RegMask = (CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR1_MASK | CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR0_MASK | CRF_APB_DP_VIDEO_REF_CTRL_SRCSEL_MASK | CRF_APB_DP_VIDEO_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR1_SHIFT
| 0x00000003U << CRF_APB_DP_VIDEO_REF_CTRL_DIVISOR0_SHIFT
| 0x00000003U << CRF_APB_DP_VIDEO_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DP_VIDEO_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DP_VIDEO_REF_CTRL_OFFSET ,0x013F3F07U ,0x01010303U);
/*############################################################################################################################ */
/*Register : DP_AUDIO_REF_CTRL @ 0XFD1A0074</p>
6 bit divider
PSU_CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR0 0x27
000 = VPLL; 010 = DPLL; 011 = RPLL_TO_FPD - might be using extra mux; (This signal may only be toggled after 4 cycles of the
ld clock and 4 cycles of the new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DP_AUDIO_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DP_AUDIO_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0074, 0x013F3F07U ,0x01012700U)
RegMask = (CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR1_MASK | CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR0_MASK | CRF_APB_DP_AUDIO_REF_CTRL_SRCSEL_MASK | CRF_APB_DP_AUDIO_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR1_SHIFT
| 0x00000027U << CRF_APB_DP_AUDIO_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DP_AUDIO_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DP_AUDIO_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DP_AUDIO_REF_CTRL_OFFSET ,0x013F3F07U ,0x01012700U);
/*############################################################################################################################ */
/*Register : DP_STC_REF_CTRL @ 0XFD1A007C</p>
6 bit divider
PSU_CRF_APB_DP_STC_REF_CTRL_DIVISOR1 0x1
6 bit divider
PSU_CRF_APB_DP_STC_REF_CTRL_DIVISOR0 0x11
000 = VPLL; 010 = DPLL; 011 = RPLL_TO_FPD; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of t
e new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DP_STC_REF_CTRL_SRCSEL 0x3
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DP_STC_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A007C, 0x013F3F07U ,0x01011103U)
RegMask = (CRF_APB_DP_STC_REF_CTRL_DIVISOR1_MASK | CRF_APB_DP_STC_REF_CTRL_DIVISOR0_MASK | CRF_APB_DP_STC_REF_CTRL_SRCSEL_MASK | CRF_APB_DP_STC_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_DP_STC_REF_CTRL_DIVISOR1_SHIFT
| 0x00000011U << CRF_APB_DP_STC_REF_CTRL_DIVISOR0_SHIFT
| 0x00000003U << CRF_APB_DP_STC_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DP_STC_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DP_STC_REF_CTRL_OFFSET ,0x013F3F07U ,0x01011103U);
/*############################################################################################################################ */
/*Register : ACPU_CTRL @ 0XFD1A0060</p>
6 bit divider
PSU_CRF_APB_ACPU_CTRL_DIVISOR0 0x1
000 = APLL; 010 = DPLL; 011 = VPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
lock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_ACPU_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock. For the half speed APU Clock
PSU_CRF_APB_ACPU_CTRL_CLKACT_HALF 0x1
Clock active signal. Switch to 0 to disable the clock. For the full speed ACPUX Clock. This will shut off the high speed cloc
to the entire APU
PSU_CRF_APB_ACPU_CTRL_CLKACT_FULL 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0060, 0x03003F07U ,0x03000100U)
RegMask = (CRF_APB_ACPU_CTRL_DIVISOR0_MASK | CRF_APB_ACPU_CTRL_SRCSEL_MASK | CRF_APB_ACPU_CTRL_CLKACT_HALF_MASK | CRF_APB_ACPU_CTRL_CLKACT_FULL_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_ACPU_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_ACPU_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_ACPU_CTRL_CLKACT_HALF_SHIFT
| 0x00000001U << CRF_APB_ACPU_CTRL_CLKACT_FULL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_ACPU_CTRL_OFFSET ,0x03003F07U ,0x03000100U);
/*############################################################################################################################ */
/*Register : DBG_TRACE_CTRL @ 0XFD1A0064</p>
6 bit divider
PSU_CRF_APB_DBG_TRACE_CTRL_DIVISOR0 0x2
000 = IOPLL_TO_FPD; 010 = DPLL; 011 = APLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DBG_TRACE_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DBG_TRACE_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0064, 0x01003F07U ,0x01000200U)
RegMask = (CRF_APB_DBG_TRACE_CTRL_DIVISOR0_MASK | CRF_APB_DBG_TRACE_CTRL_SRCSEL_MASK | CRF_APB_DBG_TRACE_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DBG_TRACE_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DBG_TRACE_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DBG_TRACE_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DBG_TRACE_CTRL_OFFSET ,0x01003F07U ,0x01000200U);
/*############################################################################################################################ */
/*Register : DBG_FPD_CTRL @ 0XFD1A0068</p>
6 bit divider
PSU_CRF_APB_DBG_FPD_CTRL_DIVISOR0 0x2
000 = IOPLL_TO_FPD; 010 = DPLL; 011 = APLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DBG_FPD_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DBG_FPD_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0068, 0x01003F07U ,0x01000200U)
RegMask = (CRF_APB_DBG_FPD_CTRL_DIVISOR0_MASK | CRF_APB_DBG_FPD_CTRL_SRCSEL_MASK | CRF_APB_DBG_FPD_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DBG_FPD_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DBG_FPD_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DBG_FPD_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DBG_FPD_CTRL_OFFSET ,0x01003F07U ,0x01000200U);
/*############################################################################################################################ */
/*Register : DDR_CTRL @ 0XFD1A0080</p>
6 bit divider
PSU_CRF_APB_DDR_CTRL_DIVISOR0 0x2
000 = DPLL; 001 = VPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new clock. This
s not usually an issue, but designers must be aware.)
PSU_CRF_APB_DDR_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0080, 0x00003F07U ,0x00000200U)
RegMask = (CRF_APB_DDR_CTRL_DIVISOR0_MASK | CRF_APB_DDR_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DDR_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DDR_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DDR_CTRL_OFFSET ,0x00003F07U ,0x00000200U);
/*############################################################################################################################ */
/*Register : GPU_REF_CTRL @ 0XFD1A0084</p>
6 bit divider
PSU_CRF_APB_GPU_REF_CTRL_DIVISOR0 0x1
000 = IOPLL_TO_FPD; 010 = VPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_GPU_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock, which will stop clock for GPU (and both Pixel Processors).
PSU_CRF_APB_GPU_REF_CTRL_CLKACT 0x1
Clock active signal for Pixel Processor. Switch to 0 to disable the clock only to this Pixel Processor
PSU_CRF_APB_GPU_REF_CTRL_PP0_CLKACT 0x1
Clock active signal for Pixel Processor. Switch to 0 to disable the clock only to this Pixel Processor
PSU_CRF_APB_GPU_REF_CTRL_PP1_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A0084, 0x07003F07U ,0x07000100U)
RegMask = (CRF_APB_GPU_REF_CTRL_DIVISOR0_MASK | CRF_APB_GPU_REF_CTRL_SRCSEL_MASK | CRF_APB_GPU_REF_CTRL_CLKACT_MASK | CRF_APB_GPU_REF_CTRL_PP0_CLKACT_MASK | CRF_APB_GPU_REF_CTRL_PP1_CLKACT_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_GPU_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_GPU_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_GPU_REF_CTRL_CLKACT_SHIFT
| 0x00000001U << CRF_APB_GPU_REF_CTRL_PP0_CLKACT_SHIFT
| 0x00000001U << CRF_APB_GPU_REF_CTRL_PP1_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_GPU_REF_CTRL_OFFSET ,0x07003F07U ,0x07000100U);
/*############################################################################################################################ */
/*Register : GDMA_REF_CTRL @ 0XFD1A00B8</p>
6 bit divider
PSU_CRF_APB_GDMA_REF_CTRL_DIVISOR0 0x2
000 = APLL; 010 = VPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
lock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_GDMA_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_GDMA_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00B8, 0x01003F07U ,0x01000200U)
RegMask = (CRF_APB_GDMA_REF_CTRL_DIVISOR0_MASK | CRF_APB_GDMA_REF_CTRL_SRCSEL_MASK | CRF_APB_GDMA_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_GDMA_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_GDMA_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_GDMA_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_GDMA_REF_CTRL_OFFSET ,0x01003F07U ,0x01000200U);
/*############################################################################################################################ */
/*Register : DPDMA_REF_CTRL @ 0XFD1A00BC</p>
6 bit divider
PSU_CRF_APB_DPDMA_REF_CTRL_DIVISOR0 0x2
000 = APLL; 010 = VPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
lock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DPDMA_REF_CTRL_SRCSEL 0x0
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_DPDMA_REF_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00BC, 0x01003F07U ,0x01000200U)
RegMask = (CRF_APB_DPDMA_REF_CTRL_DIVISOR0_MASK | CRF_APB_DPDMA_REF_CTRL_SRCSEL_MASK | CRF_APB_DPDMA_REF_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DPDMA_REF_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DPDMA_REF_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_DPDMA_REF_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DPDMA_REF_CTRL_OFFSET ,0x01003F07U ,0x01000200U);
/*############################################################################################################################ */
/*Register : TOPSW_MAIN_CTRL @ 0XFD1A00C0</p>
6 bit divider
PSU_CRF_APB_TOPSW_MAIN_CTRL_DIVISOR0 0x2
000 = APLL; 010 = VPLL; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of the new
lock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_TOPSW_MAIN_CTRL_SRCSEL 0x2
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_TOPSW_MAIN_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00C0, 0x01003F07U ,0x01000202U)
RegMask = (CRF_APB_TOPSW_MAIN_CTRL_DIVISOR0_MASK | CRF_APB_TOPSW_MAIN_CTRL_SRCSEL_MASK | CRF_APB_TOPSW_MAIN_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_TOPSW_MAIN_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRF_APB_TOPSW_MAIN_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_TOPSW_MAIN_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_TOPSW_MAIN_CTRL_OFFSET ,0x01003F07U ,0x01000202U);
/*############################################################################################################################ */
/*Register : TOPSW_LSBUS_CTRL @ 0XFD1A00C4</p>
6 bit divider
PSU_CRF_APB_TOPSW_LSBUS_CTRL_DIVISOR0 0x5
000 = APLL; 010 = IOPLL_TO_FPD; 011 = DPLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_TOPSW_LSBUS_CTRL_SRCSEL 0x2
Clock active signal. Switch to 0 to disable the clock
PSU_CRF_APB_TOPSW_LSBUS_CTRL_CLKACT 0x1
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00C4, 0x01003F07U ,0x01000502U)
RegMask = (CRF_APB_TOPSW_LSBUS_CTRL_DIVISOR0_MASK | CRF_APB_TOPSW_LSBUS_CTRL_SRCSEL_MASK | CRF_APB_TOPSW_LSBUS_CTRL_CLKACT_MASK | 0 );
RegVal = ((0x00000005U << CRF_APB_TOPSW_LSBUS_CTRL_DIVISOR0_SHIFT
| 0x00000002U << CRF_APB_TOPSW_LSBUS_CTRL_SRCSEL_SHIFT
| 0x00000001U << CRF_APB_TOPSW_LSBUS_CTRL_CLKACT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_TOPSW_LSBUS_CTRL_OFFSET ,0x01003F07U ,0x01000502U);
/*############################################################################################################################ */
/*Register : DBG_TSTMP_CTRL @ 0XFD1A00F8</p>
6 bit divider
PSU_CRF_APB_DBG_TSTMP_CTRL_DIVISOR0 0x2
000 = IOPLL_TO_FPD; 010 = DPLL; 011 = APLL; (This signal may only be toggled after 4 cycles of the old clock and 4 cycles of
he new clock. This is not usually an issue, but designers must be aware.)
PSU_CRF_APB_DBG_TSTMP_CTRL_SRCSEL 0x0
This register controls this reference clock
(OFFSET, MASK, VALUE) (0XFD1A00F8, 0x00003F07U ,0x00000200U)
RegMask = (CRF_APB_DBG_TSTMP_CTRL_DIVISOR0_MASK | CRF_APB_DBG_TSTMP_CTRL_SRCSEL_MASK | 0 );
RegVal = ((0x00000002U << CRF_APB_DBG_TSTMP_CTRL_DIVISOR0_SHIFT
| 0x00000000U << CRF_APB_DBG_TSTMP_CTRL_SRCSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_DBG_TSTMP_CTRL_OFFSET ,0x00003F07U ,0x00000200U);
/*############################################################################################################################ */
/*Register : IOU_TTC_APB_CLK @ 0XFF180380</p>
00" = Select the APB switch clock for the APB interface of TTC0'01" = Select the PLL ref clock for the APB interface of TTC0'
0" = Select the R5 clock for the APB interface of TTC0
PSU_IOU_SLCR_IOU_TTC_APB_CLK_TTC0_SEL 0
00" = Select the APB switch clock for the APB interface of TTC1'01" = Select the PLL ref clock for the APB interface of TTC1'
0" = Select the R5 clock for the APB interface of TTC1
PSU_IOU_SLCR_IOU_TTC_APB_CLK_TTC1_SEL 0
00" = Select the APB switch clock for the APB interface of TTC2'01" = Select the PLL ref clock for the APB interface of TTC2'
0" = Select the R5 clock for the APB interface of TTC2
PSU_IOU_SLCR_IOU_TTC_APB_CLK_TTC2_SEL 0
00" = Select the APB switch clock for the APB interface of TTC3'01" = Select the PLL ref clock for the APB interface of TTC3'
0" = Select the R5 clock for the APB interface of TTC3
PSU_IOU_SLCR_IOU_TTC_APB_CLK_TTC3_SEL 0
TTC APB clock select
(OFFSET, MASK, VALUE) (0XFF180380, 0x000000FFU ,0x00000000U)
RegMask = (IOU_SLCR_IOU_TTC_APB_CLK_TTC0_SEL_MASK | IOU_SLCR_IOU_TTC_APB_CLK_TTC1_SEL_MASK | IOU_SLCR_IOU_TTC_APB_CLK_TTC2_SEL_MASK | IOU_SLCR_IOU_TTC_APB_CLK_TTC3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_IOU_TTC_APB_CLK_TTC0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_IOU_TTC_APB_CLK_TTC1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_IOU_TTC_APB_CLK_TTC2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_IOU_TTC_APB_CLK_TTC3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_IOU_TTC_APB_CLK_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : WDT_CLK_SEL @ 0XFD610100</p>
System watchdog timer clock source selection: 0: Internal APB clock 1: External (PL clock via EMIO or Pinout clock via MIO)
PSU_FPD_SLCR_WDT_CLK_SEL_SELECT 0
SWDT clock source select
(OFFSET, MASK, VALUE) (0XFD610100, 0x00000001U ,0x00000000U)
RegMask = (FPD_SLCR_WDT_CLK_SEL_SELECT_MASK | 0 );
RegVal = ((0x00000000U << FPD_SLCR_WDT_CLK_SEL_SELECT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (FPD_SLCR_WDT_CLK_SEL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
/*Register : WDT_CLK_SEL @ 0XFF180300</p>
System watchdog timer clock source selection: 0: internal clock APB clock 1: external clock from PL via EMIO, or from pinout
ia MIO
PSU_IOU_SLCR_WDT_CLK_SEL_SELECT 0
SWDT clock source select
(OFFSET, MASK, VALUE) (0XFF180300, 0x00000001U ,0x00000000U)
RegMask = (IOU_SLCR_WDT_CLK_SEL_SELECT_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_WDT_CLK_SEL_SELECT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_WDT_CLK_SEL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
/*Register : CSUPMU_WDT_CLK_SEL @ 0XFF410050</p>
System watchdog timer clock source selection: 0: internal clock APB clock 1: external clock pss_ref_clk
PSU_LPD_SLCR_CSUPMU_WDT_CLK_SEL_SELECT 0
SWDT clock source select
(OFFSET, MASK, VALUE) (0XFF410050, 0x00000001U ,0x00000000U)
RegMask = (LPD_SLCR_CSUPMU_WDT_CLK_SEL_SELECT_MASK | 0 );
RegVal = ((0x00000000U << LPD_SLCR_CSUPMU_WDT_CLK_SEL_SELECT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_SLCR_CSUPMU_WDT_CLK_SEL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_ddr_init_data() {
// : DDR INITIALIZATION
// : DDR CONTROLLER RESET
/*Register : RST_DDR_SS @ 0XFD1A0108</p>
DDR block level reset inside of the DDR Sub System
PSU_CRF_APB_RST_DDR_SS_DDR_RESET 0X1
DDR sub system block level reset
(OFFSET, MASK, VALUE) (0XFD1A0108, 0x00000008U ,0x00000008U)
RegMask = (CRF_APB_RST_DDR_SS_DDR_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_RST_DDR_SS_DDR_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_DDR_SS_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
/*Register : MSTR @ 0XFD070000</p>
Indicates the configuration of the device used in the system. - 00 - x4 device - 01 - x8 device - 10 - x16 device - 11 - x32
evice
PSU_DDRC_MSTR_DEVICE_CONFIG 0x1
Choose which registers are used. - 0 - Original registers - 1 - Shadow registers
PSU_DDRC_MSTR_FREQUENCY_MODE 0x0
Only present for multi-rank configurations. Each bit represents one rank. For two-rank configurations, only bits[25:24] are p
esent. - 1 - populated - 0 - unpopulated LSB is the lowest rank number. For 2 ranks following combinations are legal: - 01 -
ne rank - 11 - Two ranks - Others - Reserved. For 4 ranks following combinations are legal: - 0001 - One rank - 0011 - Two ra
ks - 1111 - Four ranks
PSU_DDRC_MSTR_ACTIVE_RANKS 0x1
SDRAM burst length used: - 0001 - Burst length of 2 (only supported for mDDR) - 0010 - Burst length of 4 - 0100 - Burst lengt
of 8 - 1000 - Burst length of 16 (only supported for mDDR, LPDDR2, and LPDDR4) All other values are reserved. This controls
he burst size used to access the SDRAM. This must match the burst length mode register setting in the SDRAM. (For BC4/8 on-th
-fly mode of DDR3 and DDR4, set this field to 0x0100) Burst length of 2 is not supported with AXI ports when MEMC_BURST_LENGT
is 8. Burst length of 2 is only supported with MEMC_FREQ_RATIO = 1
PSU_DDRC_MSTR_BURST_RDWR 0x4
Set to 1 when the uMCTL2 and DRAM has to be put in DLL-off mode for low frequency operation. Set to 0 to put uMCTL2 and DRAM
n DLL-on mode for normal frequency operation. If DDR4 CRC/parity retry is enabled (CRCPARCTL1.crc_parity_retry_enable = 1), d
l_off_mode is not supported, and this bit must be set to '0'.
PSU_DDRC_MSTR_DLL_OFF_MODE 0x0
Selects proportion of DQ bus width that is used by the SDRAM - 00 - Full DQ bus width to SDRAM - 01 - Half DQ bus width to SD
AM - 10 - Quarter DQ bus width to SDRAM - 11 - Reserved. Note that half bus width mode is only supported when the SDRAM bus w
dth is a multiple of 16, and quarter bus width mode is only supported when the SDRAM bus width is a multiple of 32 and the co
figuration parameter MEMC_QBUS_SUPPORT is set. Bus width refers to DQ bus width (excluding any ECC width).
PSU_DDRC_MSTR_DATA_BUS_WIDTH 0x0
1 indicates put the DRAM in geardown mode (2N) and 0 indicates put the DRAM in normal mode (1N). This register can be changed
only when the Controller is in self-refresh mode. This signal must be set the same value as MR3 bit A3. Note: Geardown mode
s not supported if the configuration parameter MEMC_CMD_RTN2IDLE is set
PSU_DDRC_MSTR_GEARDOWN_MODE 0x0
If 1, then uMCTL2 uses 2T timing. Otherwise, uses 1T timing. In 2T timing, all command signals (except chip select) are held
or 2 clocks on the SDRAM bus. Chip select is asserted on the second cycle of the command Note: 2T timing is not supported in
PDDR2/LPDDR3/LPDDR4 mode Note: 2T timing is not supported if the configuration parameter MEMC_CMD_RTN2IDLE is set Note: 2T ti
ing is not supported in DDR4 geardown mode.
PSU_DDRC_MSTR_EN_2T_TIMING_MODE 0x0
When set, enable burst-chop in DDR3/DDR4. Burst Chop for Reads is exercised only in HIF configurations (UMCTL2_INCL_ARB not s
t) and if in full bus width mode (MSTR.data_bus_width = 00). Burst Chop for Writes is exercised only if Partial Writes enable
(UMCTL2_PARTIAL_WR=1) and if CRC is disabled (CRCPARCTL1.crc_enable = 0). If DDR4 CRC/parity retry is enabled (CRCPARCTL1.cr
_parity_retry_enable = 1), burst chop is not supported, and this bit must be set to '0'
PSU_DDRC_MSTR_BURSTCHOP 0x0
Select LPDDR4 SDRAM - 1 - LPDDR4 SDRAM device in use. - 0 - non-LPDDR4 device in use Present only in designs configured to su
port LPDDR4.
PSU_DDRC_MSTR_LPDDR4 0x0
Select DDR4 SDRAM - 1 - DDR4 SDRAM device in use. - 0 - non-DDR4 device in use Present only in designs configured to support
DR4.
PSU_DDRC_MSTR_DDR4 0x1
Select LPDDR3 SDRAM - 1 - LPDDR3 SDRAM device in use. - 0 - non-LPDDR3 device in use Present only in designs configured to su
port LPDDR3.
PSU_DDRC_MSTR_LPDDR3 0x0
Select LPDDR2 SDRAM - 1 - LPDDR2 SDRAM device in use. - 0 - non-LPDDR2 device in use Present only in designs configured to su
port LPDDR2.
PSU_DDRC_MSTR_LPDDR2 0x0
Select DDR3 SDRAM - 1 - DDR3 SDRAM device in use - 0 - non-DDR3 SDRAM device in use Only present in designs that support DDR3
PSU_DDRC_MSTR_DDR3 0x0
Master Register
(OFFSET, MASK, VALUE) (0XFD070000, 0xE30FBE3DU ,0x41040010U)
RegMask = (DDRC_MSTR_DEVICE_CONFIG_MASK | DDRC_MSTR_FREQUENCY_MODE_MASK | DDRC_MSTR_ACTIVE_RANKS_MASK | DDRC_MSTR_BURST_RDWR_MASK | DDRC_MSTR_DLL_OFF_MODE_MASK | DDRC_MSTR_DATA_BUS_WIDTH_MASK | DDRC_MSTR_GEARDOWN_MODE_MASK | DDRC_MSTR_EN_2T_TIMING_MODE_MASK | DDRC_MSTR_BURSTCHOP_MASK | DDRC_MSTR_LPDDR4_MASK | DDRC_MSTR_DDR4_MASK | DDRC_MSTR_LPDDR3_MASK | DDRC_MSTR_LPDDR2_MASK | DDRC_MSTR_DDR3_MASK | 0 );
RegVal = ((0x00000001U << DDRC_MSTR_DEVICE_CONFIG_SHIFT
| 0x00000000U << DDRC_MSTR_FREQUENCY_MODE_SHIFT
| 0x00000001U << DDRC_MSTR_ACTIVE_RANKS_SHIFT
| 0x00000004U << DDRC_MSTR_BURST_RDWR_SHIFT
| 0x00000000U << DDRC_MSTR_DLL_OFF_MODE_SHIFT
| 0x00000000U << DDRC_MSTR_DATA_BUS_WIDTH_SHIFT
| 0x00000000U << DDRC_MSTR_GEARDOWN_MODE_SHIFT
| 0x00000000U << DDRC_MSTR_EN_2T_TIMING_MODE_SHIFT
| 0x00000000U << DDRC_MSTR_BURSTCHOP_SHIFT
| 0x00000000U << DDRC_MSTR_LPDDR4_SHIFT
| 0x00000001U << DDRC_MSTR_DDR4_SHIFT
| 0x00000000U << DDRC_MSTR_LPDDR3_SHIFT
| 0x00000000U << DDRC_MSTR_LPDDR2_SHIFT
| 0x00000000U << DDRC_MSTR_DDR3_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_MSTR_OFFSET ,0xE30FBE3DU ,0x41040010U);
/*############################################################################################################################ */
/*Register : MRCTRL0 @ 0XFD070010</p>
Setting this register bit to 1 triggers a mode register read or write operation. When the MR operation is complete, the uMCTL
automatically clears this bit. The other register fields of this register must be written in a separate APB transaction, bef
re setting this mr_wr bit. It is recommended NOT to set this signal if in Init, Deep power-down or MPSM operating modes.
PSU_DDRC_MRCTRL0_MR_WR 0x0
Address of the mode register that is to be written to. - 0000 - MR0 - 0001 - MR1 - 0010 - MR2 - 0011 - MR3 - 0100 - MR4 - 010
- MR5 - 0110 - MR6 - 0111 - MR7 Don't Care for LPDDR2/LPDDR3/LPDDR4 (see MRCTRL1.mr_data for mode register addressing in LPD
R2/LPDDR3/LPDDR4) This signal is also used for writing to control words of RDIMMs. In that case, it corresponds to the bank a
dress bits sent to the RDIMM In case of DDR4, the bit[3:2] corresponds to the bank group bits. Therefore, the bit[3] as well
s the bit[2:0] must be set to an appropriate value which is considered both the Address Mirroring of UDIMMs/RDIMMs and the Ou
put Inversion of RDIMMs.
PSU_DDRC_MRCTRL0_MR_ADDR 0x0
Controls which rank is accessed by MRCTRL0.mr_wr. Normally, it is desired to access all ranks, so all bits should be set to 1
However, for multi-rank UDIMMs/RDIMMs which implement address mirroring, it may be necessary to access ranks individually. E
amples (assume uMCTL2 is configured for 4 ranks): - 0x1 - select rank 0 only - 0x2 - select rank 1 only - 0x5 - select ranks
and 2 - 0xA - select ranks 1 and 3 - 0xF - select ranks 0, 1, 2 and 3
PSU_DDRC_MRCTRL0_MR_RANK 0x3
Indicates whether Software intervention is allowed via MRCTRL0/MRCTRL1 before automatic SDRAM initialization routine or not.
or DDR4, this bit can be used to initialize the DDR4 RCD (MR7) before automatic SDRAM initialization. For LPDDR4, this bit ca
be used to program additional mode registers before automatic SDRAM initialization if necessary. Note: This must be cleared
o 0 after completing Software operation. Otherwise, SDRAM initialization routine will not re-start. - 0 - Software interventi
n is not allowed - 1 - Software intervention is allowed
PSU_DDRC_MRCTRL0_SW_INIT_INT 0x0
Indicates whether the mode register operation is MRS in PDA mode or not - 0 - MRS - 1 - MRS in Per DRAM Addressability mode
PSU_DDRC_MRCTRL0_PDA_EN 0x0
Indicates whether the mode register operation is MRS or WR/RD for MPR (only supported for DDR4) - 0 - MRS - 1 - WR/RD for MPR
PSU_DDRC_MRCTRL0_MPR_EN 0x0
Indicates whether the mode register operation is read or write. Only used for LPDDR2/LPDDR3/LPDDR4/DDR4. - 0 - Write - 1 - Re
d
PSU_DDRC_MRCTRL0_MR_TYPE 0x0
Mode Register Read/Write Control Register 0. Note: Do not enable more than one of the following fields simultaneously: - sw_i
it_int - pda_en - mpr_en
(OFFSET, MASK, VALUE) (0XFD070010, 0x8000F03FU ,0x00000030U)
RegMask = (DDRC_MRCTRL0_MR_WR_MASK | DDRC_MRCTRL0_MR_ADDR_MASK | DDRC_MRCTRL0_MR_RANK_MASK | DDRC_MRCTRL0_SW_INIT_INT_MASK | DDRC_MRCTRL0_PDA_EN_MASK | DDRC_MRCTRL0_MPR_EN_MASK | DDRC_MRCTRL0_MR_TYPE_MASK | 0 );
RegVal = ((0x00000000U << DDRC_MRCTRL0_MR_WR_SHIFT
| 0x00000000U << DDRC_MRCTRL0_MR_ADDR_SHIFT
| 0x00000003U << DDRC_MRCTRL0_MR_RANK_SHIFT
| 0x00000000U << DDRC_MRCTRL0_SW_INIT_INT_SHIFT
| 0x00000000U << DDRC_MRCTRL0_PDA_EN_SHIFT
| 0x00000000U << DDRC_MRCTRL0_MPR_EN_SHIFT
| 0x00000000U << DDRC_MRCTRL0_MR_TYPE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_MRCTRL0_OFFSET ,0x8000F03FU ,0x00000030U);
/*############################################################################################################################ */
/*Register : DERATEEN @ 0XFD070020</p>
Derate value of tRC for LPDDR4 - 0 - Derating uses +1. - 1 - Derating uses +2. - 2 - Derating uses +3. - 3 - Derating uses +4
Present only in designs configured to support LPDDR4. The required number of cycles for derating can be determined by dividi
g 3.75ns by the core_ddrc_core_clk period, and rounding up the next integer.
PSU_DDRC_DERATEEN_RC_DERATE_VALUE 0x3
Derate byte Present only in designs configured to support LPDDR2/LPDDR3/LPDDR4 Indicates which byte of the MRR data is used f
r derating. The maximum valid value depends on MEMC_DRAM_TOTAL_DATA_WIDTH.
PSU_DDRC_DERATEEN_DERATE_BYTE 0x0
Derate value - 0 - Derating uses +1. - 1 - Derating uses +2. Present only in designs configured to support LPDDR2/LPDDR3/LPDD
4 Set to 0 for all LPDDR2 speed grades as derating value of +1.875 ns is less than a core_ddrc_core_clk period. Can be 0 or 1
for LPDDR3/LPDDR4, depending if +1.875 ns is less than a core_ddrc_core_clk period or not.
PSU_DDRC_DERATEEN_DERATE_VALUE 0x0
Enables derating - 0 - Timing parameter derating is disabled - 1 - Timing parameter derating is enabled using MR4 read value.
Present only in designs configured to support LPDDR2/LPDDR3/LPDDR4 This field must be set to '0' for non-LPDDR2/LPDDR3/LPDDR4
mode.
PSU_DDRC_DERATEEN_DERATE_ENABLE 0x0
Temperature Derate Enable Register
(OFFSET, MASK, VALUE) (0XFD070020, 0x000003F3U ,0x00000300U)
RegMask = (DDRC_DERATEEN_RC_DERATE_VALUE_MASK | DDRC_DERATEEN_DERATE_BYTE_MASK | DDRC_DERATEEN_DERATE_VALUE_MASK | DDRC_DERATEEN_DERATE_ENABLE_MASK | 0 );
RegVal = ((0x00000003U << DDRC_DERATEEN_RC_DERATE_VALUE_SHIFT
| 0x00000000U << DDRC_DERATEEN_DERATE_BYTE_SHIFT
| 0x00000000U << DDRC_DERATEEN_DERATE_VALUE_SHIFT
| 0x00000000U << DDRC_DERATEEN_DERATE_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DERATEEN_OFFSET ,0x000003F3U ,0x00000300U);
/*############################################################################################################################ */
/*Register : DERATEINT @ 0XFD070024</p>
Interval between two MR4 reads, used to derate the timing parameters. Present only in designs configured to support LPDDR2/LP
DR3/LPDDR4. This register must not be set to zero
PSU_DDRC_DERATEINT_MR4_READ_INTERVAL 0x800000
Temperature Derate Interval Register
(OFFSET, MASK, VALUE) (0XFD070024, 0xFFFFFFFFU ,0x00800000U)
RegMask = (DDRC_DERATEINT_MR4_READ_INTERVAL_MASK | 0 );
RegVal = ((0x00800000U << DDRC_DERATEINT_MR4_READ_INTERVAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DERATEINT_OFFSET ,0xFFFFFFFFU ,0x00800000U);
/*############################################################################################################################ */
/*Register : PWRCTL @ 0XFD070030</p>
Self refresh state is an intermediate state to enter to Self refresh power down state or exit Self refresh power down state f
r LPDDR4. This register controls transition from the Self refresh state. - 1 - Prohibit transition from Self refresh state -
- Allow transition from Self refresh state
PSU_DDRC_PWRCTL_STAY_IN_SELFREF 0x0
A value of 1 to this register causes system to move to Self Refresh state immediately, as long as it is not in INIT or DPD/MP
M operating_mode. This is referred to as Software Entry/Exit to Self Refresh. - 1 - Software Entry to Self Refresh - 0 - Soft
are Exit from Self Refresh
PSU_DDRC_PWRCTL_SELFREF_SW 0x0
When this is 1, the uMCTL2 puts the SDRAM into maximum power saving mode when the transaction store is empty. This register m
st be reset to '0' to bring uMCTL2 out of maximum power saving mode. Present only in designs configured to support DDR4. For
on-DDR4, this register should not be set to 1. Note that MPSM is not supported when using a DWC DDR PHY, if the PHY parameter
DWC_AC_CS_USE is disabled, as the MPSM exit sequence requires the chip-select signal to toggle. FOR PERFORMANCE ONLY.
PSU_DDRC_PWRCTL_MPSM_EN 0x0
Enable the assertion of dfi_dram_clk_disable whenever a clock is not required by the SDRAM. If set to 0, dfi_dram_clk_disable
is never asserted. Assertion of dfi_dram_clk_disable is as follows: In DDR2/DDR3, can only be asserted in Self Refresh. In DD
4, can be asserted in following: - in Self Refresh. - in Maximum Power Saving Mode In mDDR/LPDDR2/LPDDR3, can be asserted in
ollowing: - in Self Refresh - in Power Down - in Deep Power Down - during Normal operation (Clock Stop) In LPDDR4, can be ass
rted in following: - in Self Refresh Power Down - in Power Down - during Normal operation (Clock Stop)
PSU_DDRC_PWRCTL_EN_DFI_DRAM_CLK_DISABLE 0x0
When this is 1, uMCTL2 puts the SDRAM into deep power-down mode when the transaction store is empty. This register must be re
et to '0' to bring uMCTL2 out of deep power-down mode. Controller performs automatic SDRAM initialization on deep power-down
xit. Present only in designs configured to support mDDR or LPDDR2 or LPDDR3. For non-mDDR/non-LPDDR2/non-LPDDR3, this registe
should not be set to 1. FOR PERFORMANCE ONLY.
PSU_DDRC_PWRCTL_DEEPPOWERDOWN_EN 0x0
If true then the uMCTL2 goes into power-down after a programmable number of cycles 'maximum idle clocks before power down' (P
RTMG.powerdown_to_x32). This register bit may be re-programmed during the course of normal operation.
PSU_DDRC_PWRCTL_POWERDOWN_EN 0x0
If true then the uMCTL2 puts the SDRAM into Self Refresh after a programmable number of cycles 'maximum idle clocks before Se
f Refresh (PWRTMG.selfref_to_x32)'. This register bit may be re-programmed during the course of normal operation.
PSU_DDRC_PWRCTL_SELFREF_EN 0x0
Low Power Control Register
(OFFSET, MASK, VALUE) (0XFD070030, 0x0000007FU ,0x00000000U)
RegMask = (DDRC_PWRCTL_STAY_IN_SELFREF_MASK | DDRC_PWRCTL_SELFREF_SW_MASK | DDRC_PWRCTL_MPSM_EN_MASK | DDRC_PWRCTL_EN_DFI_DRAM_CLK_DISABLE_MASK | DDRC_PWRCTL_DEEPPOWERDOWN_EN_MASK | DDRC_PWRCTL_POWERDOWN_EN_MASK | DDRC_PWRCTL_SELFREF_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PWRCTL_STAY_IN_SELFREF_SHIFT
| 0x00000000U << DDRC_PWRCTL_SELFREF_SW_SHIFT
| 0x00000000U << DDRC_PWRCTL_MPSM_EN_SHIFT
| 0x00000000U << DDRC_PWRCTL_EN_DFI_DRAM_CLK_DISABLE_SHIFT
| 0x00000000U << DDRC_PWRCTL_DEEPPOWERDOWN_EN_SHIFT
| 0x00000000U << DDRC_PWRCTL_POWERDOWN_EN_SHIFT
| 0x00000000U << DDRC_PWRCTL_SELFREF_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PWRCTL_OFFSET ,0x0000007FU ,0x00000000U);
/*############################################################################################################################ */
/*Register : PWRTMG @ 0XFD070034</p>
After this many clocks of NOP or deselect the uMCTL2 automatically puts the SDRAM into Self Refresh. This must be enabled in
he PWRCTL.selfref_en. Unit: Multiples of 32 clocks. FOR PERFORMANCE ONLY.
PSU_DDRC_PWRTMG_SELFREF_TO_X32 0x40
Minimum deep power-down time. For mDDR, value from the JEDEC specification is 0 as mDDR exits from deep power-down mode immed
ately after PWRCTL.deeppowerdown_en is de-asserted. For LPDDR2/LPDDR3, value from the JEDEC specification is 500us. Unit: Mul
iples of 4096 clocks. Present only in designs configured to support mDDR, LPDDR2 or LPDDR3. FOR PERFORMANCE ONLY.
PSU_DDRC_PWRTMG_T_DPD_X4096 0x84
After this many clocks of NOP or deselect the uMCTL2 automatically puts the SDRAM into power-down. This must be enabled in th
PWRCTL.powerdown_en. Unit: Multiples of 32 clocks FOR PERFORMANCE ONLY.
PSU_DDRC_PWRTMG_POWERDOWN_TO_X32 0x10
Low Power Timing Register
(OFFSET, MASK, VALUE) (0XFD070034, 0x00FFFF1FU ,0x00408410U)
RegMask = (DDRC_PWRTMG_SELFREF_TO_X32_MASK | DDRC_PWRTMG_T_DPD_X4096_MASK | DDRC_PWRTMG_POWERDOWN_TO_X32_MASK | 0 );
RegVal = ((0x00000040U << DDRC_PWRTMG_SELFREF_TO_X32_SHIFT
| 0x00000084U << DDRC_PWRTMG_T_DPD_X4096_SHIFT
| 0x00000010U << DDRC_PWRTMG_POWERDOWN_TO_X32_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PWRTMG_OFFSET ,0x00FFFF1FU ,0x00408410U);
/*############################################################################################################################ */
/*Register : RFSHCTL0 @ 0XFD070050</p>
Threshold value in number of clock cycles before the critical refresh or page timer expires. A critical refresh is to be issu
d before this threshold is reached. It is recommended that this not be changed from the default value, currently shown as 0x2
It must always be less than internally used t_rfc_nom_x32. Note that, in LPDDR2/LPDDR3/LPDDR4, internally used t_rfc_nom_x32
may be equal to RFSHTMG.t_rfc_nom_x32>>2 if derating is enabled (DERATEEN.derate_enable=1). Otherwise, internally used t_rfc_
om_x32 will be equal to RFSHTMG.t_rfc_nom_x32. Unit: Multiples of 32 clocks.
PSU_DDRC_RFSHCTL0_REFRESH_MARGIN 0x2
If the refresh timer (tRFCnom, also known as tREFI) has expired at least once, but it has not expired (RFSHCTL0.refresh_burst
1) times yet, then a speculative refresh may be performed. A speculative refresh is a refresh performed at a time when refres
would be useful, but before it is absolutely required. When the SDRAM bus is idle for a period of time determined by this RF
HCTL0.refresh_to_x32 and the refresh timer has expired at least once since the last refresh, then a speculative refresh is pe
formed. Speculative refreshes continues successively until there are no refreshes pending or until new reads or writes are is
ued to the uMCTL2. FOR PERFORMANCE ONLY.
PSU_DDRC_RFSHCTL0_REFRESH_TO_X32 0x10
The programmed value + 1 is the number of refresh timeouts that is allowed to accumulate before traffic is blocked and the re
reshes are forced to execute. Closing pages to perform a refresh is a one-time penalty that must be paid for each group of re
reshes. Therefore, performing refreshes in a burst reduces the per-refresh penalty of these page closings. Higher numbers for
RFSHCTL.refresh_burst slightly increases utilization; lower numbers decreases the worst-case latency associated with refreshe
. - 0 - single refresh - 1 - burst-of-2 refresh - 7 - burst-of-8 refresh For information on burst refresh feature refer to se
tion 3.9 of DDR2 JEDEC specification - JESD79-2F.pdf. For DDR2/3, the refresh is always per-rank and not per-bank. The rank r
fresh can be accumulated over 8*tREFI cycles using the burst refresh feature. In DDR4 mode, according to Fine Granularity fea
ure, 8 refreshes can be postponed in 1X mode, 16 refreshes in 2X mode and 32 refreshes in 4X mode. If using PHY-initiated upd
tes, care must be taken in the setting of RFSHCTL0.refresh_burst, to ensure that tRFCmax is not violated due to a PHY-initiat
d update occurring shortly before a refresh burst was due. In this situation, the refresh burst will be delayed until the PHY
initiated update is complete.
PSU_DDRC_RFSHCTL0_REFRESH_BURST 0x0
- 1 - Per bank refresh; - 0 - All bank refresh. Per bank refresh allows traffic to flow to other banks. Per bank refresh is n
t supported by all LPDDR2 devices but should be supported by all LPDDR3/LPDDR4 devices. Present only in designs configured to
support LPDDR2/LPDDR3/LPDDR4
PSU_DDRC_RFSHCTL0_PER_BANK_REFRESH 0x0
Refresh Control Register 0
(OFFSET, MASK, VALUE) (0XFD070050, 0x00F1F1F4U ,0x00210000U)
RegMask = (DDRC_RFSHCTL0_REFRESH_MARGIN_MASK | DDRC_RFSHCTL0_REFRESH_TO_X32_MASK | DDRC_RFSHCTL0_REFRESH_BURST_MASK | DDRC_RFSHCTL0_PER_BANK_REFRESH_MASK | 0 );
RegVal = ((0x00000002U << DDRC_RFSHCTL0_REFRESH_MARGIN_SHIFT
| 0x00000010U << DDRC_RFSHCTL0_REFRESH_TO_X32_SHIFT
| 0x00000000U << DDRC_RFSHCTL0_REFRESH_BURST_SHIFT
| 0x00000000U << DDRC_RFSHCTL0_PER_BANK_REFRESH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_RFSHCTL0_OFFSET ,0x00F1F1F4U ,0x00210000U);
/*############################################################################################################################ */
/*Register : RFSHCTL3 @ 0XFD070060</p>
Fine Granularity Refresh Mode - 000 - Fixed 1x (Normal mode) - 001 - Fixed 2x - 010 - Fixed 4x - 101 - Enable on the fly 2x (
ot supported) - 110 - Enable on the fly 4x (not supported) - Everything else - reserved Note: The on-the-fly modes is not sup
orted in this version of the uMCTL2. Note: This must be set up while the Controller is in reset or while the Controller is in
self-refresh mode. Changing this during normal operation is not allowed. Making this a dynamic register will be supported in
uture version of the uMCTL2.
PSU_DDRC_RFSHCTL3_REFRESH_MODE 0x0
Toggle this signal (either from 0 to 1 or from 1 to 0) to indicate that the refresh register(s) have been updated. The value
s automatically updated when exiting reset, so it does not need to be toggled initially.
PSU_DDRC_RFSHCTL3_REFRESH_UPDATE_LEVEL 0x0
When '1', disable auto-refresh generated by the uMCTL2. When auto-refresh is disabled, the SoC core must generate refreshes u
ing the registers reg_ddrc_rank0_refresh, reg_ddrc_rank1_refresh, reg_ddrc_rank2_refresh and reg_ddrc_rank3_refresh. When dis
auto_refresh transitions from 0 to 1, any pending refreshes are immediately scheduled by the uMCTL2. If DDR4 CRC/parity retry
is enabled (CRCPARCTL1.crc_parity_retry_enable = 1), disable auto-refresh is not supported, and this bit must be set to '0'.
his register field is changeable on the fly.
PSU_DDRC_RFSHCTL3_DIS_AUTO_REFRESH 0x1
Refresh Control Register 3
(OFFSET, MASK, VALUE) (0XFD070060, 0x00000073U ,0x00000001U)
RegMask = (DDRC_RFSHCTL3_REFRESH_MODE_MASK | DDRC_RFSHCTL3_REFRESH_UPDATE_LEVEL_MASK | DDRC_RFSHCTL3_DIS_AUTO_REFRESH_MASK | 0 );
RegVal = ((0x00000000U << DDRC_RFSHCTL3_REFRESH_MODE_SHIFT
| 0x00000000U << DDRC_RFSHCTL3_REFRESH_UPDATE_LEVEL_SHIFT
| 0x00000001U << DDRC_RFSHCTL3_DIS_AUTO_REFRESH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_RFSHCTL3_OFFSET ,0x00000073U ,0x00000001U);
/*############################################################################################################################ */
/*Register : RFSHTMG @ 0XFD070064</p>
tREFI: Average time interval between refreshes per rank (Specification: 7.8us for DDR2, DDR3 and DDR4. See JEDEC specificatio
for mDDR, LPDDR2, LPDDR3 and LPDDR4). For LPDDR2/LPDDR3/LPDDR4: - if using all-bank refreshes (RFSHCTL0.per_bank_refresh = 0
, this register should be set to tREFIab - if using per-bank refreshes (RFSHCTL0.per_bank_refresh = 1), this register should
e set to tREFIpb For configurations with MEMC_FREQ_RATIO=2, program this to (tREFI/2), no rounding up. In DDR4 mode, tREFI va
ue is different depending on the refresh mode. The user should program the appropriate value from the spec based on the value
programmed in the refresh mode register. Note that RFSHTMG.t_rfc_nom_x32 * 32 must be greater than RFSHTMG.t_rfc_min, and RFS
TMG.t_rfc_nom_x32 must be greater than 0x1. Unit: Multiples of 32 clocks.
PSU_DDRC_RFSHTMG_T_RFC_NOM_X32 0x82
Used only when LPDDR3 memory type is connected. Should only be changed when uMCTL2 is in reset. Specifies whether to use the
REFBW parameter (required by some LPDDR3 devices which comply with earlier versions of the LPDDR3 JEDEC specification) or not
- 0 - tREFBW parameter not used - 1 - tREFBW parameter used
PSU_DDRC_RFSHTMG_LPDDR3_TREFBW_EN 0x1
tRFC (min): Minimum time from refresh to refresh or activate. For MEMC_FREQ_RATIO=1 configurations, t_rfc_min should be set t
RoundUp(tRFCmin/tCK). For MEMC_FREQ_RATIO=2 configurations, t_rfc_min should be set to RoundUp(RoundUp(tRFCmin/tCK)/2). In L
DDR2/LPDDR3/LPDDR4 mode: - if using all-bank refreshes, the tRFCmin value in the above equations is equal to tRFCab - if usin
per-bank refreshes, the tRFCmin value in the above equations is equal to tRFCpb In DDR4 mode, the tRFCmin value in the above
equations is different depending on the refresh mode (fixed 1X,2X,4X) and the device density. The user should program the app
opriate value from the spec based on the 'refresh_mode' and the device density that is used. Unit: Clocks.
PSU_DDRC_RFSHTMG_T_RFC_MIN 0x8b
Refresh Timing Register
(OFFSET, MASK, VALUE) (0XFD070064, 0x0FFF83FFU ,0x0082808BU)
RegMask = (DDRC_RFSHTMG_T_RFC_NOM_X32_MASK | DDRC_RFSHTMG_LPDDR3_TREFBW_EN_MASK | DDRC_RFSHTMG_T_RFC_MIN_MASK | 0 );
RegVal = ((0x00000082U << DDRC_RFSHTMG_T_RFC_NOM_X32_SHIFT
| 0x00000001U << DDRC_RFSHTMG_LPDDR3_TREFBW_EN_SHIFT
| 0x0000008BU << DDRC_RFSHTMG_T_RFC_MIN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_RFSHTMG_OFFSET ,0x0FFF83FFU ,0x0082808BU);
/*############################################################################################################################ */
/*Register : ECCCFG0 @ 0XFD070070</p>
Disable ECC scrubs. Valid only when ECCCFG0.ecc_mode = 3'b100 and MEMC_USE_RMW is defined
PSU_DDRC_ECCCFG0_DIS_SCRUB 0x1
ECC mode indicator - 000 - ECC disabled - 100 - ECC enabled - SEC/DED over 1 beat - all other settings are reserved for futur
use
PSU_DDRC_ECCCFG0_ECC_MODE 0x0
ECC Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070070, 0x00000017U ,0x00000010U)
RegMask = (DDRC_ECCCFG0_DIS_SCRUB_MASK | DDRC_ECCCFG0_ECC_MODE_MASK | 0 );
RegVal = ((0x00000001U << DDRC_ECCCFG0_DIS_SCRUB_SHIFT
| 0x00000000U << DDRC_ECCCFG0_ECC_MODE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ECCCFG0_OFFSET ,0x00000017U ,0x00000010U);
/*############################################################################################################################ */
/*Register : ECCCFG1 @ 0XFD070074</p>
Selects whether to poison 1 or 2 bits - if 0 -> 2-bit (uncorrectable) data poisoning, if 1 -> 1-bit (correctable) data poison
ng, if ECCCFG1.data_poison_en=1
PSU_DDRC_ECCCFG1_DATA_POISON_BIT 0x0
Enable ECC data poisoning - introduces ECC errors on writes to address specified by the ECCPOISONADDR0/1 registers
PSU_DDRC_ECCCFG1_DATA_POISON_EN 0x0
ECC Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070074, 0x00000003U ,0x00000000U)
RegMask = (DDRC_ECCCFG1_DATA_POISON_BIT_MASK | DDRC_ECCCFG1_DATA_POISON_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_ECCCFG1_DATA_POISON_BIT_SHIFT
| 0x00000000U << DDRC_ECCCFG1_DATA_POISON_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ECCCFG1_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : CRCPARCTL1 @ 0XFD0700C4</p>
The maximum number of DFI PHY clock cycles allowed from the assertion of the dfi_rddata_en signal to the assertion of each of
the corresponding bits of the dfi_rddata_valid signal. This corresponds to the DFI timing parameter tphy_rdlat. Refer to PHY
pecification for correct value. This value it only used for detecting read data timeout when DDR4 retry is enabled by CRCPARC
L1.crc_parity_retry_enable=1. Maximum supported value: - 1:1 Frequency mode : DFITMG0.dfi_t_rddata_en + CRCPARCTL1.dfi_t_phy_
dlat < 'd114 - 1:2 Frequency mode ANDAND DFITMG0.dfi_rddata_use_sdr == 1 : CRCPARCTL1.dfi_t_phy_rdlat < 64 - 1:2 Frequency mo
e ANDAND DFITMG0.dfi_rddata_use_sdr == 0 : DFITMG0.dfi_t_rddata_en + CRCPARCTL1.dfi_t_phy_rdlat < 'd114 Unit: DFI Clocks
PSU_DDRC_CRCPARCTL1_DFI_T_PHY_RDLAT 0x10
After a Parity or CRC error is flagged on dfi_alert_n signal, the software has an option to read the mode registers in the DR
M before the hardware begins the retry process - 1: Wait for software to read/write the mode registers before hardware begins
the retry. After software is done with its operations, it will clear the alert interrupt register bit - 0: Hardware can begin
the retry right away after the dfi_alert_n pulse goes away. The value on this register is valid only when retry is enabled (P
RCTRL.crc_parity_retry_enable = 1) If this register is set to 1 and if the software doesn't clear the interrupt register afte
handling the parity/CRC error, then the hardware will not begin the retry process and the system will hang. In the case of P
rity/CRC error, there are two possibilities when the software doesn't reset MR5[4] to 0. - (i) If 'Persistent parity' mode re
ister bit is NOT set: the commands sent during retry and normal operation are executed without parity checking. The value in
he Parity error log register MPR Page 1 is valid. - (ii) If 'Persistent parity' mode register bit is SET: Parity checking is
one for commands sent during retry and normal operation. If multiple errors occur before MR5[4] is cleared, the error log in
PR Page 1 should be treated as 'Don't care'.
PSU_DDRC_CRCPARCTL1_ALERT_WAIT_FOR_SW 0x1
- 1: Enable command retry mechanism in case of C/A Parity or CRC error - 0: Disable command retry mechanism when C/A Parity o
CRC features are enabled. Note that retry functionality is not supported if burst chop is enabled (MSTR.burstchop = 1) and/o
disable auto-refresh is enabled (RFSHCTL3.dis_auto_refresh = 1)
PSU_DDRC_CRCPARCTL1_CRC_PARITY_RETRY_ENABLE 0x0
CRC Calculation setting register - 1: CRC includes DM signal - 0: CRC not includes DM signal Present only in designs configur
d to support DDR4.
PSU_DDRC_CRCPARCTL1_CRC_INC_DM 0x0
CRC enable Register - 1: Enable generation of CRC - 0: Disable generation of CRC The setting of this register should match th
CRC mode register setting in the DRAM.
PSU_DDRC_CRCPARCTL1_CRC_ENABLE 0x0
C/A Parity enable register - 1: Enable generation of C/A parity and detection of C/A parity error - 0: Disable generation of
/A parity and disable detection of C/A parity error If RCD's parity error detection or SDRAM's parity detection is enabled, t
is register should be 1.
PSU_DDRC_CRCPARCTL1_PARITY_ENABLE 0x0
CRC Parity Control Register1
(OFFSET, MASK, VALUE) (0XFD0700C4, 0x3F000391U ,0x10000200U)
RegMask = (DDRC_CRCPARCTL1_DFI_T_PHY_RDLAT_MASK | DDRC_CRCPARCTL1_ALERT_WAIT_FOR_SW_MASK | DDRC_CRCPARCTL1_CRC_PARITY_RETRY_ENABLE_MASK | DDRC_CRCPARCTL1_CRC_INC_DM_MASK | DDRC_CRCPARCTL1_CRC_ENABLE_MASK | DDRC_CRCPARCTL1_PARITY_ENABLE_MASK | 0 );
RegVal = ((0x00000010U << DDRC_CRCPARCTL1_DFI_T_PHY_RDLAT_SHIFT
| 0x00000001U << DDRC_CRCPARCTL1_ALERT_WAIT_FOR_SW_SHIFT
| 0x00000000U << DDRC_CRCPARCTL1_CRC_PARITY_RETRY_ENABLE_SHIFT
| 0x00000000U << DDRC_CRCPARCTL1_CRC_INC_DM_SHIFT
| 0x00000000U << DDRC_CRCPARCTL1_CRC_ENABLE_SHIFT
| 0x00000000U << DDRC_CRCPARCTL1_PARITY_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_CRCPARCTL1_OFFSET ,0x3F000391U ,0x10000200U);
/*############################################################################################################################ */
/*Register : CRCPARCTL2 @ 0XFD0700C8</p>
Value from the DRAM spec indicating the maximum width of the dfi_alert_n pulse when a parity error occurs. Recommended values
- tPAR_ALERT_PW.MAX For configurations with MEMC_FREQ_RATIO=2, program this to tPAR_ALERT_PW.MAX/2 and round up to next inte
er value. Values of 0, 1 and 2 are illegal. This value must be greater than CRCPARCTL2.t_crc_alert_pw_max.
PSU_DDRC_CRCPARCTL2_T_PAR_ALERT_PW_MAX 0x40
Value from the DRAM spec indicating the maximum width of the dfi_alert_n pulse when a CRC error occurs. Recommended values: -
tCRC_ALERT_PW.MAX For configurations with MEMC_FREQ_RATIO=2, program this to tCRC_ALERT_PW.MAX/2 and round up to next integer
value. Values of 0, 1 and 2 are illegal. This value must be less than CRCPARCTL2.t_par_alert_pw_max.
PSU_DDRC_CRCPARCTL2_T_CRC_ALERT_PW_MAX 0x5
Indicates the maximum duration in number of DRAM clock cycles for which a command should be held in the Command Retry FIFO be
ore it is popped out. Every location in the Command Retry FIFO has an associated down counting timer that will use this regis
er as the start value. The down counting starts when a command is loaded into the FIFO. The timer counts down every 4 DRAM cy
les. When the counter reaches zero, the entry is popped from the FIFO. All the counters are frozen, if a C/A Parity or CRC er
or occurs before the counter reaches zero. The counter is reset to 0, after all the commands in the FIFO are retried. Recomme
ded(minimum) values: - Only C/A Parity is enabled. RoundUp((PHY Command Latency(DRAM CLK) + CAL + RDIMM delay + tPAR_ALERT_ON
max + tPAR_UNKNOWN + PHY Alert Latency(DRAM CLK) + board delay) / 4) + 2 - Both C/A Parity and CRC is enabled/ Only CRC is en
bled. RoundUp((PHY Command Latency(DRAM CLK) + CAL + RDIMM delay + WL + 5(BL10)+ tCRC_ALERT.max + PHY Alert Latency(DRAM CLK)
+ board delay) / 4) + 2 Note 1: All value (e.g. tPAR_ALERT_ON) should be in terms of DRAM Clock and round up Note 2: Board de
ay(Command/Alert_n) should be considered. Note 3: Use the worst case(longer) value for PHY Latencies/Board delay Note 4: The
ecommended values are minimum value to be set. For mode detail, See 'Calculation of FIFO Depth' section. Max value can be set
to this register is defined below: - MEMC_BURST_LENGTH == 16 Full bus Mode (CRC=OFF) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-
Full bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-3 Half bus Mode (CRC=OFF) Max value = UMCTL2_RETRY_CMD_FIFO_D
PTH-4 Half bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-6 Quarter bus Mode (CRC=OFF) Max value = UMCTL2_RETRY_CM
_FIFO_DEPTH-8 Quarter bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-12 - MEMC_BURST_LENGTH != 16 Full bus Mode (C
C=OFF) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-1 Full bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-2 Half bus Mo
e (CRC=OFF) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-2 Half bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-3 Quarte
bus Mode (CRC=OFF) Max value = UMCTL2_RETRY_CMD_FIFO_DEPTH-4 Quarter bus Mode (CRC=ON) Max value = UMCTL2_RETRY_CMD_FIFO_DEP
H-6 Values of 0, 1 and 2 are illegal.
PSU_DDRC_CRCPARCTL2_RETRY_FIFO_MAX_HOLD_TIMER_X4 0x1f
CRC Parity Control Register2
(OFFSET, MASK, VALUE) (0XFD0700C8, 0x01FF1F3FU ,0x0040051FU)
RegMask = (DDRC_CRCPARCTL2_T_PAR_ALERT_PW_MAX_MASK | DDRC_CRCPARCTL2_T_CRC_ALERT_PW_MAX_MASK | DDRC_CRCPARCTL2_RETRY_FIFO_MAX_HOLD_TIMER_X4_MASK | 0 );
RegVal = ((0x00000040U << DDRC_CRCPARCTL2_T_PAR_ALERT_PW_MAX_SHIFT
| 0x00000005U << DDRC_CRCPARCTL2_T_CRC_ALERT_PW_MAX_SHIFT
| 0x0000001FU << DDRC_CRCPARCTL2_RETRY_FIFO_MAX_HOLD_TIMER_X4_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_CRCPARCTL2_OFFSET ,0x01FF1F3FU ,0x0040051FU);
/*############################################################################################################################ */
/*Register : INIT0 @ 0XFD0700D0</p>
If lower bit is enabled the SDRAM initialization routine is skipped. The upper bit decides what state the controller starts u
in when reset is removed - 00 - SDRAM Intialization routine is run after power-up - 01 - SDRAM Intialization routine is skip
ed after power-up. Controller starts up in Normal Mode - 11 - SDRAM Intialization routine is skipped after power-up. Controll
r starts up in Self-refresh Mode - 10 - SDRAM Intialization routine is run after power-up. Note: The only 2'b00 is supported
or LPDDR4 in this version of the uMCTL2.
PSU_DDRC_INIT0_SKIP_DRAM_INIT 0x0
Cycles to wait after driving CKE high to start the SDRAM initialization sequence. Unit: 1024 clocks. DDR2 typically requires
400 ns delay, requiring this value to be programmed to 2 at all clock speeds. LPDDR2/LPDDR3 typically requires this to be pr
grammed for a delay of 200 us. LPDDR4 typically requires this to be programmed for a delay of 2 us. For configurations with M
MC_FREQ_RATIO=2, program this to JEDEC spec value divided by 2, and round it up to next integer value.
PSU_DDRC_INIT0_POST_CKE_X1024 0x2
Cycles to wait after reset before driving CKE high to start the SDRAM initialization sequence. Unit: 1024 clock cycles. DDR2
pecifications typically require this to be programmed for a delay of >= 200 us. LPDDR2/LPDDR3: tINIT1 of 100 ns (min) LPDDR4:
tINIT3 of 2 ms (min) For configurations with MEMC_FREQ_RATIO=2, program this to JEDEC spec value divided by 2, and round it u
to next integer value.
PSU_DDRC_INIT0_PRE_CKE_X1024 0x106
SDRAM Initialization Register 0
(OFFSET, MASK, VALUE) (0XFD0700D0, 0xC3FF0FFFU ,0x00020106U)
RegMask = (DDRC_INIT0_SKIP_DRAM_INIT_MASK | DDRC_INIT0_POST_CKE_X1024_MASK | DDRC_INIT0_PRE_CKE_X1024_MASK | 0 );
RegVal = ((0x00000000U << DDRC_INIT0_SKIP_DRAM_INIT_SHIFT
| 0x00000002U << DDRC_INIT0_POST_CKE_X1024_SHIFT
| 0x00000106U << DDRC_INIT0_PRE_CKE_X1024_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT0_OFFSET ,0xC3FF0FFFU ,0x00020106U);
/*############################################################################################################################ */
/*Register : INIT1 @ 0XFD0700D4</p>
Number of cycles to assert SDRAM reset signal during init sequence. This is only present for designs supporting DDR3, DDR4 or
LPDDR4 devices. For use with a DDR PHY, this should be set to a minimum of 1
PSU_DDRC_INIT1_DRAM_RSTN_X1024 0x2
Cycles to wait after completing the SDRAM initialization sequence before starting the dynamic scheduler. Unit: Counts of a gl
bal timer that pulses every 32 clock cycles. There is no known specific requirement for this; it may be set to zero.
PSU_DDRC_INIT1_FINAL_WAIT_X32 0x0
Wait period before driving the OCD complete command to SDRAM. Unit: Counts of a global timer that pulses every 32 clock cycle
. There is no known specific requirement for this; it may be set to zero.
PSU_DDRC_INIT1_PRE_OCD_X32 0x0
SDRAM Initialization Register 1
(OFFSET, MASK, VALUE) (0XFD0700D4, 0x01FF7F0FU ,0x00020000U)
RegMask = (DDRC_INIT1_DRAM_RSTN_X1024_MASK | DDRC_INIT1_FINAL_WAIT_X32_MASK | DDRC_INIT1_PRE_OCD_X32_MASK | 0 );
RegVal = ((0x00000002U << DDRC_INIT1_DRAM_RSTN_X1024_SHIFT
| 0x00000000U << DDRC_INIT1_FINAL_WAIT_X32_SHIFT
| 0x00000000U << DDRC_INIT1_PRE_OCD_X32_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT1_OFFSET ,0x01FF7F0FU ,0x00020000U);
/*############################################################################################################################ */
/*Register : INIT2 @ 0XFD0700D8</p>
Idle time after the reset command, tINIT4. Present only in designs configured to support LPDDR2. Unit: 32 clock cycles.
PSU_DDRC_INIT2_IDLE_AFTER_RESET_X32 0x23
Time to wait after the first CKE high, tINIT2. Present only in designs configured to support LPDDR2/LPDDR3. Unit: 1 clock cyc
e. LPDDR2/LPDDR3 typically requires 5 x tCK delay.
PSU_DDRC_INIT2_MIN_STABLE_CLOCK_X1 0x5
SDRAM Initialization Register 2
(OFFSET, MASK, VALUE) (0XFD0700D8, 0x0000FF0FU ,0x00002305U)
RegMask = (DDRC_INIT2_IDLE_AFTER_RESET_X32_MASK | DDRC_INIT2_MIN_STABLE_CLOCK_X1_MASK | 0 );
RegVal = ((0x00000023U << DDRC_INIT2_IDLE_AFTER_RESET_X32_SHIFT
| 0x00000005U << DDRC_INIT2_MIN_STABLE_CLOCK_X1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT2_OFFSET ,0x0000FF0FU ,0x00002305U);
/*############################################################################################################################ */
/*Register : INIT3 @ 0XFD0700DC</p>
DDR2: Value to write to MR register. Bit 8 is for DLL and the setting here is ignored. The uMCTL2 sets this bit appropriately
DDR3/DDR4: Value loaded into MR0 register. mDDR: Value to write to MR register. LPDDR2/LPDDR3/LPDDR4 - Value to write to MR1
register
PSU_DDRC_INIT3_MR 0x930
DDR2: Value to write to EMR register. Bits 9:7 are for OCD and the setting in this register is ignored. The uMCTL2 sets those
bits appropriately. DDR3/DDR4: Value to write to MR1 register Set bit 7 to 0. If PHY-evaluation mode training is enabled, thi
bit is set appropriately by the uMCTL2 during write leveling. mDDR: Value to write to EMR register. LPDDR2/LPDDR3/LPDDR4 - V
lue to write to MR2 register
PSU_DDRC_INIT3_EMR 0x301
SDRAM Initialization Register 3
(OFFSET, MASK, VALUE) (0XFD0700DC, 0xFFFFFFFFU ,0x09300301U)
RegMask = (DDRC_INIT3_MR_MASK | DDRC_INIT3_EMR_MASK | 0 );
RegVal = ((0x00000930U << DDRC_INIT3_MR_SHIFT
| 0x00000301U << DDRC_INIT3_EMR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT3_OFFSET ,0xFFFFFFFFU ,0x09300301U);
/*############################################################################################################################ */
/*Register : INIT4 @ 0XFD0700E0</p>
DDR2: Value to write to EMR2 register. DDR3/DDR4: Value to write to MR2 register LPDDR2/LPDDR3/LPDDR4: Value to write to MR3
egister mDDR: Unused
PSU_DDRC_INIT4_EMR2 0x20
DDR2: Value to write to EMR3 register. DDR3/DDR4: Value to write to MR3 register mDDR/LPDDR2/LPDDR3: Unused LPDDR4: Value to
rite to MR13 register
PSU_DDRC_INIT4_EMR3 0x200
SDRAM Initialization Register 4
(OFFSET, MASK, VALUE) (0XFD0700E0, 0xFFFFFFFFU ,0x00200200U)
RegMask = (DDRC_INIT4_EMR2_MASK | DDRC_INIT4_EMR3_MASK | 0 );
RegVal = ((0x00000020U << DDRC_INIT4_EMR2_SHIFT
| 0x00000200U << DDRC_INIT4_EMR3_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT4_OFFSET ,0xFFFFFFFFU ,0x00200200U);
/*############################################################################################################################ */
/*Register : INIT5 @ 0XFD0700E4</p>
ZQ initial calibration, tZQINIT. Present only in designs configured to support DDR3 or DDR4 or LPDDR2/LPDDR3. Unit: 32 clock
ycles. DDR3 typically requires 512 clocks. DDR4 requires 1024 clocks. LPDDR2/LPDDR3 requires 1 us.
PSU_DDRC_INIT5_DEV_ZQINIT_X32 0x21
Maximum duration of the auto initialization, tINIT5. Present only in designs configured to support LPDDR2/LPDDR3. LPDDR2/LPDD
3 typically requires 10 us.
PSU_DDRC_INIT5_MAX_AUTO_INIT_X1024 0x4
SDRAM Initialization Register 5
(OFFSET, MASK, VALUE) (0XFD0700E4, 0x00FF03FFU ,0x00210004U)
RegMask = (DDRC_INIT5_DEV_ZQINIT_X32_MASK | DDRC_INIT5_MAX_AUTO_INIT_X1024_MASK | 0 );
RegVal = ((0x00000021U << DDRC_INIT5_DEV_ZQINIT_X32_SHIFT
| 0x00000004U << DDRC_INIT5_MAX_AUTO_INIT_X1024_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT5_OFFSET ,0x00FF03FFU ,0x00210004U);
/*############################################################################################################################ */
/*Register : INIT6 @ 0XFD0700E8</p>
DDR4- Value to be loaded into SDRAM MR4 registers. Used in DDR4 designs only.
PSU_DDRC_INIT6_MR4 0x0
DDR4- Value to be loaded into SDRAM MR5 registers. Used in DDR4 designs only.
PSU_DDRC_INIT6_MR5 0x6c0
SDRAM Initialization Register 6
(OFFSET, MASK, VALUE) (0XFD0700E8, 0xFFFFFFFFU ,0x000006C0U)
RegMask = (DDRC_INIT6_MR4_MASK | DDRC_INIT6_MR5_MASK | 0 );
RegVal = ((0x00000000U << DDRC_INIT6_MR4_SHIFT
| 0x000006C0U << DDRC_INIT6_MR5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT6_OFFSET ,0xFFFFFFFFU ,0x000006C0U);
/*############################################################################################################################ */
/*Register : INIT7 @ 0XFD0700EC</p>
DDR4- Value to be loaded into SDRAM MR6 registers. Used in DDR4 designs only.
PSU_DDRC_INIT7_MR6 0x819
SDRAM Initialization Register 7
(OFFSET, MASK, VALUE) (0XFD0700EC, 0xFFFF0000U ,0x08190000U)
RegMask = (DDRC_INIT7_MR6_MASK | 0 );
RegVal = ((0x00000819U << DDRC_INIT7_MR6_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_INIT7_OFFSET ,0xFFFF0000U ,0x08190000U);
/*############################################################################################################################ */
/*Register : DIMMCTL @ 0XFD0700F0</p>
Disabling Address Mirroring for BG bits. When this is set to 1, BG0 and BG1 are NOT swapped even if Address Mirroring is enab
ed. This will be required for DDR4 DIMMs with x16 devices. - 1 - BG0 and BG1 are NOT swapped. - 0 - BG0 and BG1 are swapped i
address mirroring is enabled.
PSU_DDRC_DIMMCTL_DIMM_DIS_BG_MIRRORING 0x0
Enable for BG1 bit of MRS command. BG1 bit of the mode register address is specified as RFU (Reserved for Future Use) and mus
be programmed to 0 during MRS. In case where DRAMs which do not have BG1 are attached and both the CA parity and the Output
nversion are enabled, this must be set to 0, so that the calculation of CA parity will not include BG1 bit. Note: This has no
effect on the address of any other memory accesses, or of software-driven mode register accesses. If address mirroring is ena
led, this is applied to BG1 of even ranks and BG0 of odd ranks. - 1 - Enabled - 0 - Disabled
PSU_DDRC_DIMMCTL_MRS_BG1_EN 0x1
Enable for A17 bit of MRS command. A17 bit of the mode register address is specified as RFU (Reserved for Future Use) and mus
be programmed to 0 during MRS. In case where DRAMs which do not have A17 are attached and the Output Inversion are enabled,
his must be set to 0, so that the calculation of CA parity will not include A17 bit. Note: This has no effect on the address
f any other memory accesses, or of software-driven mode register accesses. - 1 - Enabled - 0 - Disabled
PSU_DDRC_DIMMCTL_MRS_A17_EN 0x0
Output Inversion Enable (for DDR4 RDIMM implementations only). DDR4 RDIMM implements the Output Inversion feature by default,
which means that the following address, bank address and bank group bits of B-side DRAMs are inverted: A3-A9, A11, A13, A17,
A0-BA1, BG0-BG1. Setting this bit ensures that, for mode register accesses generated by the uMCTL2 during the automatic initi
lization routine and enabling of a particular DDR4 feature, separate A-side and B-side mode register accesses are generated.
or B-side mode register accesses, these bits are inverted within the uMCTL2 to compensate for this RDIMM inversion. Note: Thi
has no effect on the address of any other memory accesses, or of software-driven mode register accesses. - 1 - Implement out
ut inversion for B-side DRAMs. - 0 - Do not implement output inversion for B-side DRAMs.
PSU_DDRC_DIMMCTL_DIMM_OUTPUT_INV_EN 0x0
Address Mirroring Enable (for multi-rank UDIMM implementations and multi-rank DDR4 RDIMM implementations). Some UDIMMs and DD
4 RDIMMs implement address mirroring for odd ranks, which means that the following address, bank address and bank group bits
re swapped: (A3, A4), (A5, A6), (A7, A8), (BA0, BA1) and also (A11, A13), (BG0, BG1) for the DDR4. Setting this bit ensures t
at, for mode register accesses during the automatic initialization routine, these bits are swapped within the uMCTL2 to compe
sate for this UDIMM/RDIMM swapping. In addition to the automatic initialization routine, in case of DDR4 UDIMM/RDIMM, they ar
swapped during the automatic MRS access to enable/disable of a particular DDR4 feature. Note: This has no effect on the addr
ss of any other memory accesses, or of software-driven mode register accesses. This is not supported for mDDR, LPDDR2, LPDDR3
or LPDDR4 SDRAMs. Note: In case of x16 DDR4 DIMMs, BG1 output of MRS for the odd ranks is same as BG0 because BG1 is invalid,
hence dimm_dis_bg_mirroring register must be set to 1. - 1 - For odd ranks, implement address mirroring for MRS commands to d
ring initialization and for any automatic DDR4 MRS commands (to be used if UDIMM/RDIMM implements address mirroring) - 0 - Do
not implement address mirroring
PSU_DDRC_DIMMCTL_DIMM_ADDR_MIRR_EN 0x0
Staggering enable for multi-rank accesses (for multi-rank UDIMM and RDIMM implementations only). This is not supported for mD
R, LPDDR2, LPDDR3 or LPDDR4 SDRAMs. Note: Even if this bit is set it does not take care of software driven MR commands (via M
CTRL0/MRCTRL1), where software is responsible to send them to seperate ranks as appropriate. - 1 - (DDR4) Send MRS commands t
each ranks seperately - 1 - (non-DDR4) Send all commands to even and odd ranks seperately - 0 - Do not stagger accesses
PSU_DDRC_DIMMCTL_DIMM_STAGGER_CS_EN 0x0
DIMM Control Register
(OFFSET, MASK, VALUE) (0XFD0700F0, 0x0000003FU ,0x00000010U)
RegMask = (DDRC_DIMMCTL_DIMM_DIS_BG_MIRRORING_MASK | DDRC_DIMMCTL_MRS_BG1_EN_MASK | DDRC_DIMMCTL_MRS_A17_EN_MASK | DDRC_DIMMCTL_DIMM_OUTPUT_INV_EN_MASK | DDRC_DIMMCTL_DIMM_ADDR_MIRR_EN_MASK | DDRC_DIMMCTL_DIMM_STAGGER_CS_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DIMMCTL_DIMM_DIS_BG_MIRRORING_SHIFT
| 0x00000001U << DDRC_DIMMCTL_MRS_BG1_EN_SHIFT
| 0x00000000U << DDRC_DIMMCTL_MRS_A17_EN_SHIFT
| 0x00000000U << DDRC_DIMMCTL_DIMM_OUTPUT_INV_EN_SHIFT
| 0x00000000U << DDRC_DIMMCTL_DIMM_ADDR_MIRR_EN_SHIFT
| 0x00000000U << DDRC_DIMMCTL_DIMM_STAGGER_CS_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DIMMCTL_OFFSET ,0x0000003FU ,0x00000010U);
/*############################################################################################################################ */
/*Register : RANKCTL @ 0XFD0700F4</p>
Only present for multi-rank configurations. Indicates the number of clocks of gap in data responses when performing consecuti
e writes to different ranks. This is used to switch the delays in the PHY to match the rank requirements. This value should c
nsider both PHY requirement and ODT requirement. - PHY requirement: tphy_wrcsgap + 1 (see PHY databook for value of tphy_wrcs
ap) If CRC feature is enabled, should be increased by 1. If write preamble is set to 2tCK(DDR4/LPDDR4 only), should be increa
ed by 1. If write postamble is set to 1.5tCK(LPDDR4 only), should be increased by 1. - ODT requirement: The value programmed
n this register takes care of the ODT switch off timing requirement when switching ranks during writes. For LPDDR4, the requi
ement is ODTLoff - ODTLon - BL/2 + 1 For configurations with MEMC_FREQ_RATIO=1, program this to the larger of PHY requirement
or ODT requirement. For configurations with MEMC_FREQ_RATIO=2, program this to the larger value divided by two and round it u
to the next integer.
PSU_DDRC_RANKCTL_DIFF_RANK_WR_GAP 0x6
Only present for multi-rank configurations. Indicates the number of clocks of gap in data responses when performing consecuti
e reads to different ranks. This is used to switch the delays in the PHY to match the rank requirements. This value should co
sider both PHY requirement and ODT requirement. - PHY requirement: tphy_rdcsgap + 1 (see PHY databook for value of tphy_rdcsg
p) If read preamble is set to 2tCK(DDR4/LPDDR4 only), should be increased by 1. If read postamble is set to 1.5tCK(LPDDR4 onl
), should be increased by 1. - ODT requirement: The value programmed in this register takes care of the ODT switch off timing
requirement when switching ranks during reads. For configurations with MEMC_FREQ_RATIO=1, program this to the larger of PHY r
quirement or ODT requirement. For configurations with MEMC_FREQ_RATIO=2, program this to the larger value divided by two and
ound it up to the next integer.
PSU_DDRC_RANKCTL_DIFF_RANK_RD_GAP 0x6
Only present for multi-rank configurations. Background: Reads to the same rank can be performed back-to-back. Reads to differ
nt ranks require additional gap dictated by the register RANKCTL.diff_rank_rd_gap. This is to avoid possible data bus content
on as well as to give PHY enough time to switch the delay when changing ranks. The uMCTL2 arbitrates for bus access on a cycl
-by-cycle basis; therefore after a read is scheduled, there are few clock cycles (determined by the value on RANKCTL.diff_ran
_rd_gap register) in which only reads from the same rank are eligible to be scheduled. This prevents reads from other ranks f
om having fair access to the data bus. This parameter represents the maximum number of reads that can be scheduled consecutiv
ly to the same rank. After this number is reached, a delay equal to RANKCTL.diff_rank_rd_gap is inserted by the scheduler to
llow all ranks a fair opportunity to be scheduled. Higher numbers increase bandwidth utilization, lower numbers increase fair
ess. This feature can be DISABLED by setting this register to 0. When set to 0, the Controller will stay on the same rank as
ong as commands are available for it. Minimum programmable value is 0 (feature disabled) and maximum programmable value is 0x
. FOR PERFORMANCE ONLY.
PSU_DDRC_RANKCTL_MAX_RANK_RD 0xf
Rank Control Register
(OFFSET, MASK, VALUE) (0XFD0700F4, 0x00000FFFU ,0x0000066FU)
RegMask = (DDRC_RANKCTL_DIFF_RANK_WR_GAP_MASK | DDRC_RANKCTL_DIFF_RANK_RD_GAP_MASK | DDRC_RANKCTL_MAX_RANK_RD_MASK | 0 );
RegVal = ((0x00000006U << DDRC_RANKCTL_DIFF_RANK_WR_GAP_SHIFT
| 0x00000006U << DDRC_RANKCTL_DIFF_RANK_RD_GAP_SHIFT
| 0x0000000FU << DDRC_RANKCTL_MAX_RANK_RD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_RANKCTL_OFFSET ,0x00000FFFU ,0x0000066FU);
/*############################################################################################################################ */
/*Register : DRAMTMG0 @ 0XFD070100</p>
Minimum time between write and precharge to same bank. Unit: Clocks Specifications: WL + BL/2 + tWR = approximately 8 cycles
15 ns = 14 clocks @400MHz and less for lower frequencies where: - WL = write latency - BL = burst length. This must match th
value programmed in the BL bit of the mode register to the SDRAM. BST (burst terminate) is not supported at present. - tWR =
Write recovery time. This comes directly from the SDRAM specification. Add one extra cycle for LPDDR2/LPDDR3/LPDDR4 for this
arameter. For configurations with MEMC_FREQ_RATIO=2, 1T mode, divide the above value by 2. No rounding up. For configurations
with MEMC_FREQ_RATIO=2, 2T mode or LPDDR4 mode, divide the above value by 2 and round it up to the next integer value.
PSU_DDRC_DRAMTMG0_WR2PRE 0x11
tFAW Valid only when 8 or more banks(or banks x bank groups) are present. In 8-bank design, at most 4 banks must be activated
in a rolling window of tFAW cycles. For configurations with MEMC_FREQ_RATIO=2, program this to (tFAW/2) and round up to next
nteger value. In a 4-bank design, set this register to 0x1 independent of the MEMC_FREQ_RATIO configuration. Unit: Clocks
PSU_DDRC_DRAMTMG0_T_FAW 0x11
tRAS(max): Maximum time between activate and precharge to same bank. This is the maximum time that a page can be kept open Mi
imum value of this register is 1. Zero is invalid. For configurations with MEMC_FREQ_RATIO=2, program this to (tRAS(max)-1)/2
No rounding up. Unit: Multiples of 1024 clocks.
PSU_DDRC_DRAMTMG0_T_RAS_MAX 0x24
tRAS(min): Minimum time between activate and precharge to the same bank. For configurations with MEMC_FREQ_RATIO=2, 1T mode,
rogram this to tRAS(min)/2. No rounding up. For configurations with MEMC_FREQ_RATIO=2, 2T mode or LPDDR4 mode, program this t
(tRAS(min)/2) and round it up to the next integer value. Unit: Clocks
PSU_DDRC_DRAMTMG0_T_RAS_MIN 0x12
SDRAM Timing Register 0
(OFFSET, MASK, VALUE) (0XFD070100, 0x7F3F7F3FU ,0x11112412U)
RegMask = (DDRC_DRAMTMG0_WR2PRE_MASK | DDRC_DRAMTMG0_T_FAW_MASK | DDRC_DRAMTMG0_T_RAS_MAX_MASK | DDRC_DRAMTMG0_T_RAS_MIN_MASK | 0 );
RegVal = ((0x00000011U << DDRC_DRAMTMG0_WR2PRE_SHIFT
| 0x00000011U << DDRC_DRAMTMG0_T_FAW_SHIFT
| 0x00000024U << DDRC_DRAMTMG0_T_RAS_MAX_SHIFT
| 0x00000012U << DDRC_DRAMTMG0_T_RAS_MIN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG0_OFFSET ,0x7F3F7F3FU ,0x11112412U);
/*############################################################################################################################ */
/*Register : DRAMTMG1 @ 0XFD070104</p>
tXP: Minimum time after power-down exit to any operation. For DDR3, this should be programmed to tXPDLL if slow powerdown exi
is selected in MR0[12]. If C/A parity for DDR4 is used, set to (tXP+PL) instead. For configurations with MEMC_FREQ_RATIO=2,
rogram this to (tXP/2) and round it up to the next integer value. Units: Clocks
PSU_DDRC_DRAMTMG1_T_XP 0x4
tRTP: Minimum time from read to precharge of same bank. - DDR2: tAL + BL/2 + max(tRTP, 2) - 2 - DDR3: tAL + max (tRTP, 4) - D
R4: Max of following two equations: tAL + max (tRTP, 4) or, RL + BL/2 - tRP. - mDDR: BL/2 - LPDDR2: Depends on if it's LPDDR2
S2 or LPDDR2-S4: LPDDR2-S2: BL/2 + tRTP - 1. LPDDR2-S4: BL/2 + max(tRTP,2) - 2. - LPDDR3: BL/2 + max(tRTP,4) - 4 - LPDDR4: BL
2 + max(tRTP,8) - 8 For configurations with MEMC_FREQ_RATIO=2, 1T mode, divide the above value by 2. No rounding up. For conf
gurations with MEMC_FREQ_RATIO=2, 2T mode or LPDDR4 mode, divide the above value by 2 and round it up to the next integer val
e. Unit: Clocks.
PSU_DDRC_DRAMTMG1_RD2PRE 0x4
tRC: Minimum time between activates to same bank. For configurations with MEMC_FREQ_RATIO=2, program this to (tRC/2) and roun
up to next integer value. Unit: Clocks.
PSU_DDRC_DRAMTMG1_T_RC 0x1a
SDRAM Timing Register 1
(OFFSET, MASK, VALUE) (0XFD070104, 0x001F1F7FU ,0x0004041AU)
RegMask = (DDRC_DRAMTMG1_T_XP_MASK | DDRC_DRAMTMG1_RD2PRE_MASK | DDRC_DRAMTMG1_T_RC_MASK | 0 );
RegVal = ((0x00000004U << DDRC_DRAMTMG1_T_XP_SHIFT
| 0x00000004U << DDRC_DRAMTMG1_RD2PRE_SHIFT
| 0x0000001AU << DDRC_DRAMTMG1_T_RC_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG1_OFFSET ,0x001F1F7FU ,0x0004041AU);
/*############################################################################################################################ */
/*Register : DRAMTMG2 @ 0XFD070108</p>
Set to WL Time from write command to write data on SDRAM interface. This must be set to WL. For mDDR, it should normally be s
t to 1. Note that, depending on the PHY, if using RDIMM, it may be necessary to use a value of WL + 1 to compensate for the e
tra cycle of latency through the RDIMM For configurations with MEMC_FREQ_RATIO=2, divide the value calculated using the above
equation by 2, and round it up to next integer. This register field is not required for DDR2 and DDR3 (except if MEMC_TRAININ
is set), as the DFI read and write latencies defined in DFITMG0 and DFITMG1 are sufficient for those protocols Unit: clocks
PSU_DDRC_DRAMTMG2_WRITE_LATENCY 0x7
Set to RL Time from read command to read data on SDRAM interface. This must be set to RL. Note that, depending on the PHY, if
using RDIMM, it mat be necessary to use a value of RL + 1 to compensate for the extra cycle of latency through the RDIMM For
onfigurations with MEMC_FREQ_RATIO=2, divide the value calculated using the above equation by 2, and round it up to next inte
er. This register field is not required for DDR2 and DDR3 (except if MEMC_TRAINING is set), as the DFI read and write latenci
s defined in DFITMG0 and DFITMG1 are sufficient for those protocols Unit: clocks
PSU_DDRC_DRAMTMG2_READ_LATENCY 0x8
DDR2/3/mDDR: RL + BL/2 + 2 - WL DDR4: RL + BL/2 + 1 + WR_PREAMBLE - WL LPDDR2/LPDDR3: RL + BL/2 + RU(tDQSCKmax/tCK) + 1 - WL
PDDR4(DQ ODT is Disabled): RL + BL/2 + RU(tDQSCKmax/tCK) + WR_PREAMBLE + RD_POSTAMBLE - WL LPDDR4(DQ ODT is Enabled) : RL + B
/2 + RU(tDQSCKmax/tCK) + RD_POSTAMBLE - ODTLon - RU(tODTon(min)/tCK) Minimum time from read command to write command. Include
time for bus turnaround and all per-bank, per-rank, and global constraints. Unit: Clocks. Where: - WL = write latency - BL =
urst length. This must match the value programmed in the BL bit of the mode register to the SDRAM - RL = read latency = CAS l
tency - WR_PREAMBLE = write preamble. This is unique to DDR4 and LPDDR4. - RD_POSTAMBLE = read postamble. This is unique to L
DDR4. For LPDDR2/LPDDR3/LPDDR4, if derating is enabled (DERATEEN.derate_enable=1), derated tDQSCKmax should be used. For conf
gurations with MEMC_FREQ_RATIO=2, divide the value calculated using the above equation by 2, and round it up to next integer.
PSU_DDRC_DRAMTMG2_RD2WR 0x6
DDR4: CWL + PL + BL/2 + tWTR_L Others: CWL + BL/2 + tWTR In DDR4, minimum time from write command to read command for same ba
k group. In others, minimum time from write command to read command. Includes time for bus turnaround, recovery times, and al
per-bank, per-rank, and global constraints. Unit: Clocks. Where: - CWL = CAS write latency - PL = Parity latency - BL = burs
length. This must match the value programmed in the BL bit of the mode register to the SDRAM - tWTR_L = internal write to re
d command delay for same bank group. This comes directly from the SDRAM specification. - tWTR = internal write to read comman
delay. This comes directly from the SDRAM specification. Add one extra cycle for LPDDR2/LPDDR3/LPDDR4 operation. For configu
ations with MEMC_FREQ_RATIO=2, divide the value calculated using the above equation by 2, and round it up to next integer.
PSU_DDRC_DRAMTMG2_WR2RD 0xe
SDRAM Timing Register 2
(OFFSET, MASK, VALUE) (0XFD070108, 0x3F3F3F3FU ,0x0708060EU)
RegMask = (DDRC_DRAMTMG2_WRITE_LATENCY_MASK | DDRC_DRAMTMG2_READ_LATENCY_MASK | DDRC_DRAMTMG2_RD2WR_MASK | DDRC_DRAMTMG2_WR2RD_MASK | 0 );
RegVal = ((0x00000007U << DDRC_DRAMTMG2_WRITE_LATENCY_SHIFT
| 0x00000008U << DDRC_DRAMTMG2_READ_LATENCY_SHIFT
| 0x00000006U << DDRC_DRAMTMG2_RD2WR_SHIFT
| 0x0000000EU << DDRC_DRAMTMG2_WR2RD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG2_OFFSET ,0x3F3F3F3FU ,0x0708060EU);
/*############################################################################################################################ */
/*Register : DRAMTMG3 @ 0XFD07010C</p>
Time to wait after a mode register write or read (MRW or MRR). Present only in designs configured to support LPDDR2, LPDDR3 o
LPDDR4. LPDDR2 typically requires value of 5. LPDDR3 typically requires value of 10. LPDDR4: Set this to the larger of tMRW
nd tMRWCKEL. For LPDDR2, this register is used for the time from a MRW/MRR to all other commands. For LDPDR3, this register i
used for the time from a MRW/MRR to a MRW/MRR.
PSU_DDRC_DRAMTMG3_T_MRW 0x5
tMRD: Cycles to wait after a mode register write or read. Depending on the connected SDRAM, tMRD represents: DDR2/mDDR: Time
rom MRS to any command DDR3/4: Time from MRS to MRS command LPDDR2: not used LPDDR3/4: Time from MRS to non-MRS command For c
nfigurations with MEMC_FREQ_RATIO=2, program this to (tMRD/2) and round it up to the next integer value. If C/A parity for DD
4 is used, set to tMRD_PAR(tMOD+PL) instead.
PSU_DDRC_DRAMTMG3_T_MRD 0x4
tMOD: Parameter used only in DDR3 and DDR4. Cycles between load mode command and following non-load mode command. If C/A pari
y for DDR4 is used, set to tMOD_PAR(tMOD+PL) instead. Set to tMOD if MEMC_FREQ_RATIO=1, or tMOD/2 (rounded up to next integer
if MEMC_FREQ_RATIO=2. Note that if using RDIMM, depending on the PHY, it may be necessary to use a value of tMOD + 1 or (tMO
+ 1)/2 to compensate for the extra cycle of latency applied to mode register writes by the RDIMM chip.
PSU_DDRC_DRAMTMG3_T_MOD 0xc
SDRAM Timing Register 3
(OFFSET, MASK, VALUE) (0XFD07010C, 0x3FF3F3FFU ,0x0050400CU)
RegMask = (DDRC_DRAMTMG3_T_MRW_MASK | DDRC_DRAMTMG3_T_MRD_MASK | DDRC_DRAMTMG3_T_MOD_MASK | 0 );
RegVal = ((0x00000005U << DDRC_DRAMTMG3_T_MRW_SHIFT
| 0x00000004U << DDRC_DRAMTMG3_T_MRD_SHIFT
| 0x0000000CU << DDRC_DRAMTMG3_T_MOD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG3_OFFSET ,0x3FF3F3FFU ,0x0050400CU);
/*############################################################################################################################ */
/*Register : DRAMTMG4 @ 0XFD070110</p>
tRCD - tAL: Minimum time from activate to read or write command to same bank. For configurations with MEMC_FREQ_RATIO=2, prog
am this to ((tRCD - tAL)/2) and round it up to the next integer value. Minimum value allowed for this register is 1, which im
lies minimum (tRCD - tAL) value to be 2 in configurations with MEMC_FREQ_RATIO=2. Unit: Clocks.
PSU_DDRC_DRAMTMG4_T_RCD 0x8
DDR4: tCCD_L: This is the minimum time between two reads or two writes for same bank group. Others: tCCD: This is the minimum
time between two reads or two writes. For configurations with MEMC_FREQ_RATIO=2, program this to (tCCD_L/2 or tCCD/2) and rou
d it up to the next integer value. Unit: clocks.
PSU_DDRC_DRAMTMG4_T_CCD 0x3
DDR4: tRRD_L: Minimum time between activates from bank 'a' to bank 'b' for same bank group. Others: tRRD: Minimum time betwee
activates from bank 'a' to bank 'b'For configurations with MEMC_FREQ_RATIO=2, program this to (tRRD_L/2 or tRRD/2) and round
it up to the next integer value. Unit: Clocks.
PSU_DDRC_DRAMTMG4_T_RRD 0x3
tRP: Minimum time from precharge to activate of same bank. For MEMC_FREQ_RATIO=1 configurations, t_rp should be set to RoundU
(tRP/tCK). For MEMC_FREQ_RATIO=2 configurations, t_rp should be set to RoundDown(RoundUp(tRP/tCK)/2) + 1. For MEMC_FREQ_RATIO
2 configurations in LPDDR4, t_rp should be set to RoundUp(RoundUp(tRP/tCK)/2). Unit: Clocks.
PSU_DDRC_DRAMTMG4_T_RP 0x9
SDRAM Timing Register 4
(OFFSET, MASK, VALUE) (0XFD070110, 0x1F0F0F1FU ,0x08030309U)
RegMask = (DDRC_DRAMTMG4_T_RCD_MASK | DDRC_DRAMTMG4_T_CCD_MASK | DDRC_DRAMTMG4_T_RRD_MASK | DDRC_DRAMTMG4_T_RP_MASK | 0 );
RegVal = ((0x00000008U << DDRC_DRAMTMG4_T_RCD_SHIFT
| 0x00000003U << DDRC_DRAMTMG4_T_CCD_SHIFT
| 0x00000003U << DDRC_DRAMTMG4_T_RRD_SHIFT
| 0x00000009U << DDRC_DRAMTMG4_T_RP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG4_OFFSET ,0x1F0F0F1FU ,0x08030309U);
/*############################################################################################################################ */
/*Register : DRAMTMG5 @ 0XFD070114</p>
This is the time before Self Refresh Exit that CK is maintained as a valid clock before issuing SRX. Specifies the clock stab
e time before SRX. Recommended settings: - mDDR: 1 - LPDDR2: 2 - LPDDR3: 2 - LPDDR4: tCKCKEH - DDR2: 1 - DDR3: tCKSRX - DDR4:
tCKSRX For configurations with MEMC_FREQ_RATIO=2, program this to recommended value divided by two and round it up to next in
eger.
PSU_DDRC_DRAMTMG5_T_CKSRX 0x6
This is the time after Self Refresh Down Entry that CK is maintained as a valid clock. Specifies the clock disable delay afte
SRE. Recommended settings: - mDDR: 0 - LPDDR2: 2 - LPDDR3: 2 - LPDDR4: tCKCKEL - DDR2: 1 - DDR3: max (10 ns, 5 tCK) - DDR4:
ax (10 ns, 5 tCK) For configurations with MEMC_FREQ_RATIO=2, program this to recommended value divided by two and round it up
to next integer.
PSU_DDRC_DRAMTMG5_T_CKSRE 0x6
Minimum CKE low width for Self refresh or Self refresh power down entry to exit timing in memory clock cycles. Recommended se
tings: - mDDR: tRFC - LPDDR2: tCKESR - LPDDR3: tCKESR - LPDDR4: max(tCKELPD, tSR) - DDR2: tCKE - DDR3: tCKE + 1 - DDR4: tCKE
1 For configurations with MEMC_FREQ_RATIO=2, program this to recommended value divided by two and round it up to next intege
.
PSU_DDRC_DRAMTMG5_T_CKESR 0x4
Minimum number of cycles of CKE HIGH/LOW during power-down and self refresh. - LPDDR2/LPDDR3 mode: Set this to the larger of
CKE or tCKESR - LPDDR4 mode: Set this to the larger of tCKE, tCKELPD or tSR. - Non-LPDDR2/non-LPDDR3/non-LPDDR4 designs: Set
his to tCKE value. For configurations with MEMC_FREQ_RATIO=2, program this to (value described above)/2 and round it up to th
next integer value. Unit: Clocks.
PSU_DDRC_DRAMTMG5_T_CKE 0x3
SDRAM Timing Register 5
(OFFSET, MASK, VALUE) (0XFD070114, 0x0F0F3F1FU ,0x06060403U)
RegMask = (DDRC_DRAMTMG5_T_CKSRX_MASK | DDRC_DRAMTMG5_T_CKSRE_MASK | DDRC_DRAMTMG5_T_CKESR_MASK | DDRC_DRAMTMG5_T_CKE_MASK | 0 );
RegVal = ((0x00000006U << DDRC_DRAMTMG5_T_CKSRX_SHIFT
| 0x00000006U << DDRC_DRAMTMG5_T_CKSRE_SHIFT
| 0x00000004U << DDRC_DRAMTMG5_T_CKESR_SHIFT
| 0x00000003U << DDRC_DRAMTMG5_T_CKE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG5_OFFSET ,0x0F0F3F1FU ,0x06060403U);
/*############################################################################################################################ */
/*Register : DRAMTMG6 @ 0XFD070118</p>
This is the time after Deep Power Down Entry that CK is maintained as a valid clock. Specifies the clock disable delay after
PDE. Recommended settings: - mDDR: 0 - LPDDR2: 2 - LPDDR3: 2 For configurations with MEMC_FREQ_RATIO=2, program this to recom
ended value divided by two and round it up to next integer. This is only present for designs supporting mDDR or LPDDR2/LPDDR3
devices.
PSU_DDRC_DRAMTMG6_T_CKDPDE 0x1
This is the time before Deep Power Down Exit that CK is maintained as a valid clock before issuing DPDX. Specifies the clock
table time before DPDX. Recommended settings: - mDDR: 1 - LPDDR2: 2 - LPDDR3: 2 For configurations with MEMC_FREQ_RATIO=2, pr
gram this to recommended value divided by two and round it up to next integer. This is only present for designs supporting mD
R or LPDDR2 devices.
PSU_DDRC_DRAMTMG6_T_CKDPDX 0x1
This is the time before Clock Stop Exit that CK is maintained as a valid clock before issuing Clock Stop Exit. Specifies the
lock stable time before next command after Clock Stop Exit. Recommended settings: - mDDR: 1 - LPDDR2: tXP + 2 - LPDDR3: tXP +
2 - LPDDR4: tXP + 2 For configurations with MEMC_FREQ_RATIO=2, program this to recommended value divided by two and round it
p to next integer. This is only present for designs supporting mDDR or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_DRAMTMG6_T_CKCSX 0x4
SDRAM Timing Register 6
(OFFSET, MASK, VALUE) (0XFD070118, 0x0F0F000FU ,0x01010004U)
RegMask = (DDRC_DRAMTMG6_T_CKDPDE_MASK | DDRC_DRAMTMG6_T_CKDPDX_MASK | DDRC_DRAMTMG6_T_CKCSX_MASK | 0 );
RegVal = ((0x00000001U << DDRC_DRAMTMG6_T_CKDPDE_SHIFT
| 0x00000001U << DDRC_DRAMTMG6_T_CKDPDX_SHIFT
| 0x00000004U << DDRC_DRAMTMG6_T_CKCSX_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG6_OFFSET ,0x0F0F000FU ,0x01010004U);
/*############################################################################################################################ */
/*Register : DRAMTMG7 @ 0XFD07011C</p>
This is the time after Power Down Entry that CK is maintained as a valid clock. Specifies the clock disable delay after PDE.
ecommended settings: - mDDR: 0 - LPDDR2: 2 - LPDDR3: 2 - LPDDR4: tCKCKEL For configurations with MEMC_FREQ_RATIO=2, program t
is to recommended value divided by two and round it up to next integer. This is only present for designs supporting mDDR or L
DDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_DRAMTMG7_T_CKPDE 0x6
This is the time before Power Down Exit that CK is maintained as a valid clock before issuing PDX. Specifies the clock stable
time before PDX. Recommended settings: - mDDR: 0 - LPDDR2: 2 - LPDDR3: 2 - LPDDR4: 2 For configurations with MEMC_FREQ_RATIO=
, program this to recommended value divided by two and round it up to next integer. This is only present for designs supporti
g mDDR or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_DRAMTMG7_T_CKPDX 0x6
SDRAM Timing Register 7
(OFFSET, MASK, VALUE) (0XFD07011C, 0x00000F0FU ,0x00000606U)
RegMask = (DDRC_DRAMTMG7_T_CKPDE_MASK | DDRC_DRAMTMG7_T_CKPDX_MASK | 0 );
RegVal = ((0x00000006U << DDRC_DRAMTMG7_T_CKPDE_SHIFT
| 0x00000006U << DDRC_DRAMTMG7_T_CKPDX_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG7_OFFSET ,0x00000F0FU ,0x00000606U);
/*############################################################################################################################ */
/*Register : DRAMTMG8 @ 0XFD070120</p>
tXS_FAST: Exit Self Refresh to ZQCL, ZQCS and MRS (only CL, WR, RTP and Geardown mode). For configurations with MEMC_FREQ_RAT
O=2, program this to the above value divided by 2 and round up to next integer value. Unit: Multiples of 32 clocks. Note: Thi
is applicable to only ZQCL/ZQCS commands. Note: Ensure this is less than or equal to t_xs_x32.
PSU_DDRC_DRAMTMG8_T_XS_FAST_X32 0x4
tXS_ABORT: Exit Self Refresh to commands not requiring a locked DLL in Self Refresh Abort. For configurations with MEMC_FREQ_
ATIO=2, program this to the above value divided by 2 and round up to next integer value. Unit: Multiples of 32 clocks. Note:
nsure this is less than or equal to t_xs_x32.
PSU_DDRC_DRAMTMG8_T_XS_ABORT_X32 0x4
tXSDLL: Exit Self Refresh to commands requiring a locked DLL. For configurations with MEMC_FREQ_RATIO=2, program this to the
bove value divided by 2 and round up to next integer value. Unit: Multiples of 32 clocks. Note: Used only for DDR2, DDR3 and
DR4 SDRAMs.
PSU_DDRC_DRAMTMG8_T_XS_DLL_X32 0xd
tXS: Exit Self Refresh to commands not requiring a locked DLL. For configurations with MEMC_FREQ_RATIO=2, program this to the
above value divided by 2 and round up to next integer value. Unit: Multiples of 32 clocks. Note: Used only for DDR2, DDR3 and
DDR4 SDRAMs.
PSU_DDRC_DRAMTMG8_T_XS_X32 0x6
SDRAM Timing Register 8
(OFFSET, MASK, VALUE) (0XFD070120, 0x7F7F7F7FU ,0x04040D06U)
RegMask = (DDRC_DRAMTMG8_T_XS_FAST_X32_MASK | DDRC_DRAMTMG8_T_XS_ABORT_X32_MASK | DDRC_DRAMTMG8_T_XS_DLL_X32_MASK | DDRC_DRAMTMG8_T_XS_X32_MASK | 0 );
RegVal = ((0x00000004U << DDRC_DRAMTMG8_T_XS_FAST_X32_SHIFT
| 0x00000004U << DDRC_DRAMTMG8_T_XS_ABORT_X32_SHIFT
| 0x0000000DU << DDRC_DRAMTMG8_T_XS_DLL_X32_SHIFT
| 0x00000006U << DDRC_DRAMTMG8_T_XS_X32_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG8_OFFSET ,0x7F7F7F7FU ,0x04040D06U);
/*############################################################################################################################ */
/*Register : DRAMTMG9 @ 0XFD070124</p>
DDR4 Write preamble mode - 0: 1tCK preamble - 1: 2tCK preamble Present only with MEMC_FREQ_RATIO=2
PSU_DDRC_DRAMTMG9_DDR4_WR_PREAMBLE 0x0
tCCD_S: This is the minimum time between two reads or two writes for different bank group. For bank switching (from bank 'a'
o bank 'b'), the minimum time is this value + 1. For configurations with MEMC_FREQ_RATIO=2, program this to (tCCD_S/2) and ro
nd it up to the next integer value. Present only in designs configured to support DDR4. Unit: clocks.
PSU_DDRC_DRAMTMG9_T_CCD_S 0x2
tRRD_S: Minimum time between activates from bank 'a' to bank 'b' for different bank group. For configurations with MEMC_FREQ_
ATIO=2, program this to (tRRD_S/2) and round it up to the next integer value. Present only in designs configured to support D
R4. Unit: Clocks.
PSU_DDRC_DRAMTMG9_T_RRD_S 0x2
CWL + PL + BL/2 + tWTR_S Minimum time from write command to read command for different bank group. Includes time for bus turn
round, recovery times, and all per-bank, per-rank, and global constraints. Present only in designs configured to support DDR4
Unit: Clocks. Where: - CWL = CAS write latency - PL = Parity latency - BL = burst length. This must match the value programm
d in the BL bit of the mode register to the SDRAM - tWTR_S = internal write to read command delay for different bank group. T
is comes directly from the SDRAM specification. For configurations with MEMC_FREQ_RATIO=2, divide the value calculated using
he above equation by 2, and round it up to next integer.
PSU_DDRC_DRAMTMG9_WR2RD_S 0xb
SDRAM Timing Register 9
(OFFSET, MASK, VALUE) (0XFD070124, 0x40070F3FU ,0x0002020BU)
RegMask = (DDRC_DRAMTMG9_DDR4_WR_PREAMBLE_MASK | DDRC_DRAMTMG9_T_CCD_S_MASK | DDRC_DRAMTMG9_T_RRD_S_MASK | DDRC_DRAMTMG9_WR2RD_S_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DRAMTMG9_DDR4_WR_PREAMBLE_SHIFT
| 0x00000002U << DDRC_DRAMTMG9_T_CCD_S_SHIFT
| 0x00000002U << DDRC_DRAMTMG9_T_RRD_S_SHIFT
| 0x0000000BU << DDRC_DRAMTMG9_WR2RD_S_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG9_OFFSET ,0x40070F3FU ,0x0002020BU);
/*############################################################################################################################ */
/*Register : DRAMTMG11 @ 0XFD07012C</p>
tXMPDLL: This is the minimum Exit MPSM to commands requiring a locked DLL. For configurations with MEMC_FREQ_RATIO=2, program
this to (tXMPDLL/2) and round it up to the next integer value. Present only in designs configured to support DDR4. Unit: Mult
ples of 32 clocks.
PSU_DDRC_DRAMTMG11_POST_MPSM_GAP_X32 0x6f
tMPX_LH: This is the minimum CS_n Low hold time to CKE rising edge. For configurations with MEMC_FREQ_RATIO=2, program this t
RoundUp(tMPX_LH/2)+1. Present only in designs configured to support DDR4. Unit: clocks.
PSU_DDRC_DRAMTMG11_T_MPX_LH 0x7
tMPX_S: Minimum time CS setup time to CKE. For configurations with MEMC_FREQ_RATIO=2, program this to (tMPX_S/2) and round it
up to the next integer value. Present only in designs configured to support DDR4. Unit: Clocks.
PSU_DDRC_DRAMTMG11_T_MPX_S 0x1
tCKMPE: Minimum valid clock requirement after MPSM entry. Present only in designs configured to support DDR4. Unit: Clocks. F
r configurations with MEMC_FREQ_RATIO=2, divide the value calculated using the above equation by 2, and round it up to next i
teger.
PSU_DDRC_DRAMTMG11_T_CKMPE 0xe
SDRAM Timing Register 11
(OFFSET, MASK, VALUE) (0XFD07012C, 0x7F1F031FU ,0x6F07010EU)
RegMask = (DDRC_DRAMTMG11_POST_MPSM_GAP_X32_MASK | DDRC_DRAMTMG11_T_MPX_LH_MASK | DDRC_DRAMTMG11_T_MPX_S_MASK | DDRC_DRAMTMG11_T_CKMPE_MASK | 0 );
RegVal = ((0x0000006FU << DDRC_DRAMTMG11_POST_MPSM_GAP_X32_SHIFT
| 0x00000007U << DDRC_DRAMTMG11_T_MPX_LH_SHIFT
| 0x00000001U << DDRC_DRAMTMG11_T_MPX_S_SHIFT
| 0x0000000EU << DDRC_DRAMTMG11_T_CKMPE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG11_OFFSET ,0x7F1F031FU ,0x6F07010EU);
/*############################################################################################################################ */
/*Register : DRAMTMG12 @ 0XFD070130</p>
tCMDCKE: Delay from valid command to CKE input LOW. Set this to the larger of tESCKE or tCMDCKE For configurations with MEMC_
REQ_RATIO=2, program this to (max(tESCKE, tCMDCKE)/2) and round it up to next integer value.
PSU_DDRC_DRAMTMG12_T_CMDCKE 0x2
tCKEHCMD: Valid command requirement after CKE input HIGH. For configurations with MEMC_FREQ_RATIO=2, program this to (tCKEHCM
/2) and round it up to next integer value.
PSU_DDRC_DRAMTMG12_T_CKEHCMD 0x6
tMRD_PDA: This is the Mode Register Set command cycle time in PDA mode. For configurations with MEMC_FREQ_RATIO=2, program th
s to (tMRD_PDA/2) and round it up to next integer value.
PSU_DDRC_DRAMTMG12_T_MRD_PDA 0x8
SDRAM Timing Register 12
(OFFSET, MASK, VALUE) (0XFD070130, 0x00030F1FU ,0x00020608U)
RegMask = (DDRC_DRAMTMG12_T_CMDCKE_MASK | DDRC_DRAMTMG12_T_CKEHCMD_MASK | DDRC_DRAMTMG12_T_MRD_PDA_MASK | 0 );
RegVal = ((0x00000002U << DDRC_DRAMTMG12_T_CMDCKE_SHIFT
| 0x00000006U << DDRC_DRAMTMG12_T_CKEHCMD_SHIFT
| 0x00000008U << DDRC_DRAMTMG12_T_MRD_PDA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DRAMTMG12_OFFSET ,0x00030F1FU ,0x00020608U);
/*############################################################################################################################ */
/*Register : ZQCTL0 @ 0XFD070180</p>
- 1 - Disable uMCTL2 generation of ZQCS/MPC(ZQ calibration) command. Register DBGCMD.zq_calib_short can be used instead to is
ue ZQ calibration request from APB module. - 0 - Internally generate ZQCS/MPC(ZQ calibration) commands based on ZQCTL1.t_zq_s
ort_interval_x1024. This is only present for designs supporting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL0_DIS_AUTO_ZQ 0x1
- 1 - Disable issuing of ZQCL/MPC(ZQ calibration) command at Self-Refresh/SR-Powerdown exit. Only applicable when run in DDR3
or DDR4 or LPDDR2 or LPDDR3 or LPDDR4 mode. - 0 - Enable issuing of ZQCL/MPC(ZQ calibration) command at Self-Refresh/SR-Power
own exit. Only applicable when run in DDR3 or DDR4 or LPDDR2 or LPDDR3 or LPDDR4 mode. This is only present for designs suppo
ting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL0_DIS_SRX_ZQCL 0x0
- 1 - Denotes that ZQ resistor is shared between ranks. Means ZQinit/ZQCL/ZQCS/MPC(ZQ calibration) commands are sent to one r
nk at a time with tZQinit/tZQCL/tZQCS/tZQCAL/tZQLAT timing met between commands so that commands to different ranks do not ov
rlap. - 0 - ZQ resistor is not shared. This is only present for designs supporting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL0_ZQ_RESISTOR_SHARED 0x0
- 1 - Disable issuing of ZQCL command at Maximum Power Saving Mode exit. Only applicable when run in DDR4 mode. - 0 - Enable
ssuing of ZQCL command at Maximum Power Saving Mode exit. Only applicable when run in DDR4 mode. This is only present for des
gns supporting DDR4 devices.
PSU_DDRC_ZQCTL0_DIS_MPSMX_ZQCL 0x0
tZQoper for DDR3/DDR4, tZQCL for LPDDR2/LPDDR3, tZQCAL for LPDDR4: Number of cycles of NOP required after a ZQCL (ZQ calibrat
on long)/MPC(ZQ Start) command is issued to SDRAM. For configurations with MEMC_FREQ_RATIO=2: DDR3/DDR4: program this to tZQo
er/2 and round it up to the next integer value. LPDDR2/LPDDR3: program this to tZQCL/2 and round it up to the next integer va
ue. LPDDR4: program this to tZQCAL/2 and round it up to the next integer value. Unit: Clock cycles. This is only present for
esigns supporting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL0_T_ZQ_LONG_NOP 0x100
tZQCS for DDR3/DD4/LPDDR2/LPDDR3, tZQLAT for LPDDR4: Number of cycles of NOP required after a ZQCS (ZQ calibration short)/MPC
ZQ Latch) command is issued to SDRAM. For configurations with MEMC_FREQ_RATIO=2, program this to tZQCS/2 and round it up to t
e next integer value. Unit: Clock cycles. This is only present for designs supporting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devic
s.
PSU_DDRC_ZQCTL0_T_ZQ_SHORT_NOP 0x40
ZQ Control Register 0
(OFFSET, MASK, VALUE) (0XFD070180, 0xF7FF03FFU ,0x81000040U)
RegMask = (DDRC_ZQCTL0_DIS_AUTO_ZQ_MASK | DDRC_ZQCTL0_DIS_SRX_ZQCL_MASK | DDRC_ZQCTL0_ZQ_RESISTOR_SHARED_MASK | DDRC_ZQCTL0_DIS_MPSMX_ZQCL_MASK | DDRC_ZQCTL0_T_ZQ_LONG_NOP_MASK | DDRC_ZQCTL0_T_ZQ_SHORT_NOP_MASK | 0 );
RegVal = ((0x00000001U << DDRC_ZQCTL0_DIS_AUTO_ZQ_SHIFT
| 0x00000000U << DDRC_ZQCTL0_DIS_SRX_ZQCL_SHIFT
| 0x00000000U << DDRC_ZQCTL0_ZQ_RESISTOR_SHARED_SHIFT
| 0x00000000U << DDRC_ZQCTL0_DIS_MPSMX_ZQCL_SHIFT
| 0x00000100U << DDRC_ZQCTL0_T_ZQ_LONG_NOP_SHIFT
| 0x00000040U << DDRC_ZQCTL0_T_ZQ_SHORT_NOP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ZQCTL0_OFFSET ,0xF7FF03FFU ,0x81000040U);
/*############################################################################################################################ */
/*Register : ZQCTL1 @ 0XFD070184</p>
tZQReset: Number of cycles of NOP required after a ZQReset (ZQ calibration Reset) command is issued to SDRAM. For configurati
ns with MEMC_FREQ_RATIO=2, program this to tZQReset/2 and round it up to the next integer value. Unit: Clock cycles. This is
nly present for designs supporting LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL1_T_ZQ_RESET_NOP 0x20
Average interval to wait between automatically issuing ZQCS (ZQ calibration short)/MPC(ZQ calibration) commands to DDR3/DDR4/
PDDR2/LPDDR3/LPDDR4 devices. Meaningless, if ZQCTL0.dis_auto_zq=1. Unit: 1024 clock cycles. This is only present for designs
upporting DDR3/DDR4 or LPDDR2/LPDDR3/LPDDR4 devices.
PSU_DDRC_ZQCTL1_T_ZQ_SHORT_INTERVAL_X1024 0x19707
ZQ Control Register 1
(OFFSET, MASK, VALUE) (0XFD070184, 0x3FFFFFFFU ,0x02019707U)
RegMask = (DDRC_ZQCTL1_T_ZQ_RESET_NOP_MASK | DDRC_ZQCTL1_T_ZQ_SHORT_INTERVAL_X1024_MASK | 0 );
RegVal = ((0x00000020U << DDRC_ZQCTL1_T_ZQ_RESET_NOP_SHIFT
| 0x00019707U << DDRC_ZQCTL1_T_ZQ_SHORT_INTERVAL_X1024_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ZQCTL1_OFFSET ,0x3FFFFFFFU ,0x02019707U);
/*############################################################################################################################ */
/*Register : DFITMG0 @ 0XFD070190</p>
Specifies the number of DFI clock cycles after an assertion or de-assertion of the DFI control signals that the control signa
s at the PHY-DRAM interface reflect the assertion or de-assertion. If the DFI clock and the memory clock are not phase-aligne
, this timing parameter should be rounded up to the next integer value. Note that if using RDIMM, it is necessary to incremen
this parameter by RDIMM's extra cycle of latency in terms of DFI clock.
PSU_DDRC_DFITMG0_DFI_T_CTRL_DELAY 0x4
Defines whether dfi_rddata_en/dfi_rddata/dfi_rddata_valid is generated using HDR or SDR values Selects whether value in DFITM
0.dfi_t_rddata_en is in terms of SDR or HDR clock cycles: - 0 in terms of HDR clock cycles - 1 in terms of SDR clock cycles R
fer to PHY specification for correct value.
PSU_DDRC_DFITMG0_DFI_RDDATA_USE_SDR 0x1
Time from the assertion of a read command on the DFI interface to the assertion of the dfi_rddata_en signal. Refer to PHY spe
ification for correct value. This corresponds to the DFI parameter trddata_en. Note that, depending on the PHY, if using RDIM
, it may be necessary to use the value (CL + 1) in the calculation of trddata_en. This is to compensate for the extra cycle o
latency through the RDIMM. Unit: Clocks
PSU_DDRC_DFITMG0_DFI_T_RDDATA_EN 0xb
Defines whether dfi_wrdata_en/dfi_wrdata/dfi_wrdata_mask is generated using HDR or SDR values Selects whether value in DFITMG
.dfi_tphy_wrlat is in terms of SDR or HDR clock cycles Selects whether value in DFITMG0.dfi_tphy_wrdata is in terms of SDR or
HDR clock cycles - 0 in terms of HDR clock cycles - 1 in terms of SDR clock cycles Refer to PHY specification for correct val
e.
PSU_DDRC_DFITMG0_DFI_WRDATA_USE_SDR 0x1
Specifies the number of clock cycles between when dfi_wrdata_en is asserted to when the associated write data is driven on th
dfi_wrdata signal. This corresponds to the DFI timing parameter tphy_wrdata. Refer to PHY specification for correct value. N
te, max supported value is 8. Unit: Clocks
PSU_DDRC_DFITMG0_DFI_TPHY_WRDATA 0x2
Write latency Number of clocks from the write command to write data enable (dfi_wrdata_en). This corresponds to the DFI timin
parameter tphy_wrlat. Refer to PHY specification for correct value.Note that, depending on the PHY, if using RDIMM, it may b
necessary to use the value (CL + 1) in the calculation of tphy_wrlat. This is to compensate for the extra cycle of latency t
rough the RDIMM.
PSU_DDRC_DFITMG0_DFI_TPHY_WRLAT 0xb
DFI Timing Register 0
(OFFSET, MASK, VALUE) (0XFD070190, 0x1FBFBF3FU ,0x048B820BU)
RegMask = (DDRC_DFITMG0_DFI_T_CTRL_DELAY_MASK | DDRC_DFITMG0_DFI_RDDATA_USE_SDR_MASK | DDRC_DFITMG0_DFI_T_RDDATA_EN_MASK | DDRC_DFITMG0_DFI_WRDATA_USE_SDR_MASK | DDRC_DFITMG0_DFI_TPHY_WRDATA_MASK | DDRC_DFITMG0_DFI_TPHY_WRLAT_MASK | 0 );
RegVal = ((0x00000004U << DDRC_DFITMG0_DFI_T_CTRL_DELAY_SHIFT
| 0x00000001U << DDRC_DFITMG0_DFI_RDDATA_USE_SDR_SHIFT
| 0x0000000BU << DDRC_DFITMG0_DFI_T_RDDATA_EN_SHIFT
| 0x00000001U << DDRC_DFITMG0_DFI_WRDATA_USE_SDR_SHIFT
| 0x00000002U << DDRC_DFITMG0_DFI_TPHY_WRDATA_SHIFT
| 0x0000000BU << DDRC_DFITMG0_DFI_TPHY_WRLAT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFITMG0_OFFSET ,0x1FBFBF3FU ,0x048B820BU);
/*############################################################################################################################ */
/*Register : DFITMG1 @ 0XFD070194</p>
Specifies the number of DFI PHY clocks between when the dfi_cs signal is asserted and when the associated command is driven.
his field is used for CAL mode, should be set to '0' or the value which matches the CAL mode register setting in the DRAM. If
the PHY can add the latency for CAL mode, this should be set to '0'. Valid Range: 0, 3, 4, 5, 6, and 8
PSU_DDRC_DFITMG1_DFI_T_CMD_LAT 0x0
Specifies the number of DFI PHY clocks between when the dfi_cs signal is asserted and when the associated dfi_parity_in signa
is driven.
PSU_DDRC_DFITMG1_DFI_T_PARIN_LAT 0x0
Specifies the number of DFI clocks between when the dfi_wrdata_en signal is asserted and when the corresponding write data tr
nsfer is completed on the DRAM bus. This corresponds to the DFI timing parameter twrdata_delay. Refer to PHY specification fo
correct value. For DFI 3.0 PHY, set to twrdata_delay, a new timing parameter introduced in DFI 3.0. For DFI 2.1 PHY, set to
phy_wrdata + (delay of DFI write data to the DRAM). Value to be programmed is in terms of DFI clocks, not PHY clocks. In FREQ
RATIO=2, divide PHY's value by 2 and round up to next integer. If using DFITMG0.dfi_wrdata_use_sdr=1, add 1 to the value. Uni
: Clocks
PSU_DDRC_DFITMG1_DFI_T_WRDATA_DELAY 0x3
Specifies the number of DFI clock cycles from the assertion of the dfi_dram_clk_disable signal on the DFI until the clock to
he DRAM memory devices, at the PHY-DRAM boundary, maintains a low value. If the DFI clock and the memory clock are not phase
ligned, this timing parameter should be rounded up to the next integer value.
PSU_DDRC_DFITMG1_DFI_T_DRAM_CLK_DISABLE 0x3
Specifies the number of DFI clock cycles from the de-assertion of the dfi_dram_clk_disable signal on the DFI until the first
alid rising edge of the clock to the DRAM memory devices, at the PHY-DRAM boundary. If the DFI clock and the memory clock are
not phase aligned, this timing parameter should be rounded up to the next integer value.
PSU_DDRC_DFITMG1_DFI_T_DRAM_CLK_ENABLE 0x4
DFI Timing Register 1
(OFFSET, MASK, VALUE) (0XFD070194, 0xF31F0F0FU ,0x00030304U)
RegMask = (DDRC_DFITMG1_DFI_T_CMD_LAT_MASK | DDRC_DFITMG1_DFI_T_PARIN_LAT_MASK | DDRC_DFITMG1_DFI_T_WRDATA_DELAY_MASK | DDRC_DFITMG1_DFI_T_DRAM_CLK_DISABLE_MASK | DDRC_DFITMG1_DFI_T_DRAM_CLK_ENABLE_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DFITMG1_DFI_T_CMD_LAT_SHIFT
| 0x00000000U << DDRC_DFITMG1_DFI_T_PARIN_LAT_SHIFT
| 0x00000003U << DDRC_DFITMG1_DFI_T_WRDATA_DELAY_SHIFT
| 0x00000003U << DDRC_DFITMG1_DFI_T_DRAM_CLK_DISABLE_SHIFT
| 0x00000004U << DDRC_DFITMG1_DFI_T_DRAM_CLK_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFITMG1_OFFSET ,0xF31F0F0FU ,0x00030304U);
/*############################################################################################################################ */
/*Register : DFILPCFG0 @ 0XFD070198</p>
Setting for DFI's tlp_resp time. Same value is used for both Power Down, Self Refresh, Deep Power Down and Maximum Power Savi
g modes. DFI 2.1 specification onwards, recommends using a fixed value of 7 always.
PSU_DDRC_DFILPCFG0_DFI_TLP_RESP 0x7
Value to drive on dfi_lp_wakeup signal when Deep Power Down mode is entered. Determines the DFI's tlp_wakeup time: - 0x0 - 16
cycles - 0x1 - 32 cycles - 0x2 - 64 cycles - 0x3 - 128 cycles - 0x4 - 256 cycles - 0x5 - 512 cycles - 0x6 - 1024 cycles - 0x7
- 2048 cycles - 0x8 - 4096 cycles - 0x9 - 8192 cycles - 0xA - 16384 cycles - 0xB - 32768 cycles - 0xC - 65536 cycles - 0xD -
31072 cycles - 0xE - 262144 cycles - 0xF - Unlimited This is only present for designs supporting mDDR or LPDDR2/LPDDR3 device
.
PSU_DDRC_DFILPCFG0_DFI_LP_WAKEUP_DPD 0x0
Enables DFI Low Power interface handshaking during Deep Power Down Entry/Exit. - 0 - Disabled - 1 - Enabled This is only pres
nt for designs supporting mDDR or LPDDR2/LPDDR3 devices.
PSU_DDRC_DFILPCFG0_DFI_LP_EN_DPD 0x0
Value to drive on dfi_lp_wakeup signal when Self Refresh mode is entered. Determines the DFI's tlp_wakeup time: - 0x0 - 16 cy
les - 0x1 - 32 cycles - 0x2 - 64 cycles - 0x3 - 128 cycles - 0x4 - 256 cycles - 0x5 - 512 cycles - 0x6 - 1024 cycles - 0x7 -
048 cycles - 0x8 - 4096 cycles - 0x9 - 8192 cycles - 0xA - 16384 cycles - 0xB - 32768 cycles - 0xC - 65536 cycles - 0xD - 131
72 cycles - 0xE - 262144 cycles - 0xF - Unlimited
PSU_DDRC_DFILPCFG0_DFI_LP_WAKEUP_SR 0x0
Enables DFI Low Power interface handshaking during Self Refresh Entry/Exit. - 0 - Disabled - 1 - Enabled
PSU_DDRC_DFILPCFG0_DFI_LP_EN_SR 0x1
Value to drive on dfi_lp_wakeup signal when Power Down mode is entered. Determines the DFI's tlp_wakeup time: - 0x0 - 16 cycl
s - 0x1 - 32 cycles - 0x2 - 64 cycles - 0x3 - 128 cycles - 0x4 - 256 cycles - 0x5 - 512 cycles - 0x6 - 1024 cycles - 0x7 - 20
8 cycles - 0x8 - 4096 cycles - 0x9 - 8192 cycles - 0xA - 16384 cycles - 0xB - 32768 cycles - 0xC - 65536 cycles - 0xD - 13107
cycles - 0xE - 262144 cycles - 0xF - Unlimited
PSU_DDRC_DFILPCFG0_DFI_LP_WAKEUP_PD 0x0
Enables DFI Low Power interface handshaking during Power Down Entry/Exit. - 0 - Disabled - 1 - Enabled
PSU_DDRC_DFILPCFG0_DFI_LP_EN_PD 0x1
DFI Low Power Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070198, 0x0FF1F1F1U ,0x07000101U)
RegMask = (DDRC_DFILPCFG0_DFI_TLP_RESP_MASK | DDRC_DFILPCFG0_DFI_LP_WAKEUP_DPD_MASK | DDRC_DFILPCFG0_DFI_LP_EN_DPD_MASK | DDRC_DFILPCFG0_DFI_LP_WAKEUP_SR_MASK | DDRC_DFILPCFG0_DFI_LP_EN_SR_MASK | DDRC_DFILPCFG0_DFI_LP_WAKEUP_PD_MASK | DDRC_DFILPCFG0_DFI_LP_EN_PD_MASK | 0 );
RegVal = ((0x00000007U << DDRC_DFILPCFG0_DFI_TLP_RESP_SHIFT
| 0x00000000U << DDRC_DFILPCFG0_DFI_LP_WAKEUP_DPD_SHIFT
| 0x00000000U << DDRC_DFILPCFG0_DFI_LP_EN_DPD_SHIFT
| 0x00000000U << DDRC_DFILPCFG0_DFI_LP_WAKEUP_SR_SHIFT
| 0x00000001U << DDRC_DFILPCFG0_DFI_LP_EN_SR_SHIFT
| 0x00000000U << DDRC_DFILPCFG0_DFI_LP_WAKEUP_PD_SHIFT
| 0x00000001U << DDRC_DFILPCFG0_DFI_LP_EN_PD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFILPCFG0_OFFSET ,0x0FF1F1F1U ,0x07000101U);
/*############################################################################################################################ */
/*Register : DFILPCFG1 @ 0XFD07019C</p>
Value to drive on dfi_lp_wakeup signal when Maximum Power Saving Mode is entered. Determines the DFI's tlp_wakeup time: - 0x0
- 16 cycles - 0x1 - 32 cycles - 0x2 - 64 cycles - 0x3 - 128 cycles - 0x4 - 256 cycles - 0x5 - 512 cycles - 0x6 - 1024 cycles
0x7 - 2048 cycles - 0x8 - 4096 cycles - 0x9 - 8192 cycles - 0xA - 16384 cycles - 0xB - 32768 cycles - 0xC - 65536 cycles - 0
D - 131072 cycles - 0xE - 262144 cycles - 0xF - Unlimited This is only present for designs supporting DDR4 devices.
PSU_DDRC_DFILPCFG1_DFI_LP_WAKEUP_MPSM 0x2
Enables DFI Low Power interface handshaking during Maximum Power Saving Mode Entry/Exit. - 0 - Disabled - 1 - Enabled This is
only present for designs supporting DDR4 devices.
PSU_DDRC_DFILPCFG1_DFI_LP_EN_MPSM 0x1
DFI Low Power Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD07019C, 0x000000F1U ,0x00000021U)
RegMask = (DDRC_DFILPCFG1_DFI_LP_WAKEUP_MPSM_MASK | DDRC_DFILPCFG1_DFI_LP_EN_MPSM_MASK | 0 );
RegVal = ((0x00000002U << DDRC_DFILPCFG1_DFI_LP_WAKEUP_MPSM_SHIFT
| 0x00000001U << DDRC_DFILPCFG1_DFI_LP_EN_MPSM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFILPCFG1_OFFSET ,0x000000F1U ,0x00000021U);
/*############################################################################################################################ */
/*Register : DFIUPD1 @ 0XFD0701A4</p>
This is the minimum amount of time between uMCTL2 initiated DFI update requests (which is executed whenever the uMCTL2 is idl
). Set this number higher to reduce the frequency of update requests, which can have a small impact on the latency of the fir
t read request when the uMCTL2 is idle. Unit: 1024 clocks
PSU_DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MIN_X1024 0x41
This is the maximum amount of time between uMCTL2 initiated DFI update requests. This timer resets with each update request;
hen the timer expires dfi_ctrlupd_req is sent and traffic is blocked until the dfi_ctrlupd_ackx is received. PHY can use this
idle time to recalibrate the delay lines to the DLLs. The DFI controller update is also used to reset PHY FIFO pointers in ca
e of data capture errors. Updates are required to maintain calibration over PVT, but frequent updates may impact performance.
Note: Value programmed for DFIUPD1.dfi_t_ctrlupd_interval_max_x1024 must be greater than DFIUPD1.dfi_t_ctrlupd_interval_min_x
024. Unit: 1024 clocks
PSU_DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MAX_X1024 0xe2
DFI Update Register 1
(OFFSET, MASK, VALUE) (0XFD0701A4, 0x00FF00FFU ,0x004100E2U)
RegMask = (DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MIN_X1024_MASK | DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MAX_X1024_MASK | 0 );
RegVal = ((0x00000041U << DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MIN_X1024_SHIFT
| 0x000000E2U << DDRC_DFIUPD1_DFI_T_CTRLUPD_INTERVAL_MAX_X1024_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFIUPD1_OFFSET ,0x00FF00FFU ,0x004100E2U);
/*############################################################################################################################ */
/*Register : DFIMISC @ 0XFD0701B0</p>
Defines polarity of dfi_wrdata_cs and dfi_rddata_cs signals. - 0: Signals are active low - 1: Signals are active high
PSU_DDRC_DFIMISC_DFI_DATA_CS_POLARITY 0x0
DBI implemented in DDRC or PHY. - 0 - DDRC implements DBI functionality. - 1 - PHY implements DBI functionality. Present only
in designs configured to support DDR4 and LPDDR4.
PSU_DDRC_DFIMISC_PHY_DBI_MODE 0x0
PHY initialization complete enable signal. When asserted the dfi_init_complete signal can be used to trigger SDRAM initialisa
ion
PSU_DDRC_DFIMISC_DFI_INIT_COMPLETE_EN 0x0
DFI Miscellaneous Control Register
(OFFSET, MASK, VALUE) (0XFD0701B0, 0x00000007U ,0x00000000U)
RegMask = (DDRC_DFIMISC_DFI_DATA_CS_POLARITY_MASK | DDRC_DFIMISC_PHY_DBI_MODE_MASK | DDRC_DFIMISC_DFI_INIT_COMPLETE_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DFIMISC_DFI_DATA_CS_POLARITY_SHIFT
| 0x00000000U << DDRC_DFIMISC_PHY_DBI_MODE_SHIFT
| 0x00000000U << DDRC_DFIMISC_DFI_INIT_COMPLETE_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFIMISC_OFFSET ,0x00000007U ,0x00000000U);
/*############################################################################################################################ */
/*Register : DFITMG2 @ 0XFD0701B4</p>
>Number of clocks between when a read command is sent on the DFI control interface and when the associated dfi_rddata_cs sign
l is asserted. This corresponds to the DFI timing parameter tphy_rdcslat. Refer to PHY specification for correct value.
PSU_DDRC_DFITMG2_DFI_TPHY_RDCSLAT 0x9
Number of clocks between when a write command is sent on the DFI control interface and when the associated dfi_wrdata_cs sign
l is asserted. This corresponds to the DFI timing parameter tphy_wrcslat. Refer to PHY specification for correct value.
PSU_DDRC_DFITMG2_DFI_TPHY_WRCSLAT 0x6
DFI Timing Register 2
(OFFSET, MASK, VALUE) (0XFD0701B4, 0x00003F3FU ,0x00000906U)
RegMask = (DDRC_DFITMG2_DFI_TPHY_RDCSLAT_MASK | DDRC_DFITMG2_DFI_TPHY_WRCSLAT_MASK | 0 );
RegVal = ((0x00000009U << DDRC_DFITMG2_DFI_TPHY_RDCSLAT_SHIFT
| 0x00000006U << DDRC_DFITMG2_DFI_TPHY_WRCSLAT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFITMG2_OFFSET ,0x00003F3FU ,0x00000906U);
/*############################################################################################################################ */
/*Register : DBICTL @ 0XFD0701C0</p>
Read DBI enable signal in DDRC. - 0 - Read DBI is disabled. - 1 - Read DBI is enabled. This signal must be set the same value
as DRAM's mode register. - DDR4: MR5 bit A12. When x4 devices are used, this signal must be set to 0. - LPDDR4: MR3[6]
PSU_DDRC_DBICTL_RD_DBI_EN 0x0
Write DBI enable signal in DDRC. - 0 - Write DBI is disabled. - 1 - Write DBI is enabled. This signal must be set the same va
ue as DRAM's mode register. - DDR4: MR5 bit A11. When x4 devices are used, this signal must be set to 0. - LPDDR4: MR3[7]
PSU_DDRC_DBICTL_WR_DBI_EN 0x0
DM enable signal in DDRC. - 0 - DM is disabled. - 1 - DM is enabled. This signal must be set the same logical value as DRAM's
mode register. - DDR4: Set this to same value as MR5 bit A10. When x4 devices are used, this signal must be set to 0. - LPDDR
: Set this to inverted value of MR13[5] which is opposite polarity from this signal
PSU_DDRC_DBICTL_DM_EN 0x1
DM/DBI Control Register
(OFFSET, MASK, VALUE) (0XFD0701C0, 0x00000007U ,0x00000001U)
RegMask = (DDRC_DBICTL_RD_DBI_EN_MASK | DDRC_DBICTL_WR_DBI_EN_MASK | DDRC_DBICTL_DM_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DBICTL_RD_DBI_EN_SHIFT
| 0x00000000U << DDRC_DBICTL_WR_DBI_EN_SHIFT
| 0x00000001U << DDRC_DBICTL_DM_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DBICTL_OFFSET ,0x00000007U ,0x00000001U);
/*############################################################################################################################ */
/*Register : ADDRMAP0 @ 0XFD070200</p>
Selects the HIF address bit used as rank address bit 0. Valid Range: 0 to 27, and 31 Internal Base: 6 The selected HIF addres
bit is determined by adding the internal base to the value of this field. If set to 31, rank address bit 0 is set to 0.
PSU_DDRC_ADDRMAP0_ADDRMAP_CS_BIT0 0x1f
Address Map Register 0
(OFFSET, MASK, VALUE) (0XFD070200, 0x0000001FU ,0x0000001FU)
RegMask = (DDRC_ADDRMAP0_ADDRMAP_CS_BIT0_MASK | 0 );
RegVal = ((0x0000001FU << DDRC_ADDRMAP0_ADDRMAP_CS_BIT0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP0_OFFSET ,0x0000001FU ,0x0000001FU);
/*############################################################################################################################ */
/*Register : ADDRMAP1 @ 0XFD070204</p>
Selects the HIF address bit used as bank address bit 2. Valid Range: 0 to 29 and 31 Internal Base: 4 The selected HIF address
bit is determined by adding the internal base to the value of this field. If set to 31, bank address bit 2 is set to 0.
PSU_DDRC_ADDRMAP1_ADDRMAP_BANK_B2 0x1f
Selects the HIF address bits used as bank address bit 1. Valid Range: 0 to 30 Internal Base: 3 The selected HIF address bit f
r each of the bank address bits is determined by adding the internal base to the value of this field.
PSU_DDRC_ADDRMAP1_ADDRMAP_BANK_B1 0xa
Selects the HIF address bits used as bank address bit 0. Valid Range: 0 to 30 Internal Base: 2 The selected HIF address bit f
r each of the bank address bits is determined by adding the internal base to the value of this field.
PSU_DDRC_ADDRMAP1_ADDRMAP_BANK_B0 0xa
Address Map Register 1
(OFFSET, MASK, VALUE) (0XFD070204, 0x001F1F1FU ,0x001F0A0AU)
RegMask = (DDRC_ADDRMAP1_ADDRMAP_BANK_B2_MASK | DDRC_ADDRMAP1_ADDRMAP_BANK_B1_MASK | DDRC_ADDRMAP1_ADDRMAP_BANK_B0_MASK | 0 );
RegVal = ((0x0000001FU << DDRC_ADDRMAP1_ADDRMAP_BANK_B2_SHIFT
| 0x0000000AU << DDRC_ADDRMAP1_ADDRMAP_BANK_B1_SHIFT
| 0x0000000AU << DDRC_ADDRMAP1_ADDRMAP_BANK_B0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP1_OFFSET ,0x001F1F1FU ,0x001F0A0AU);
/*############################################################################################################################ */
/*Register : ADDRMAP2 @ 0XFD070208</p>
- Full bus width mode: Selects the HIF address bit used as column address bit 5. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 6. - Quarter bus width mode: Selects the HIF address bit used as column address bit 7 . Vali
Range: 0 to 7, and 15 Internal Base: 5 The selected HIF address bit is determined by adding the internal base to the value o
this field. If set to 15, this column address bit is set to 0.
PSU_DDRC_ADDRMAP2_ADDRMAP_COL_B5 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 4. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 5. - Quarter bus width mode: Selects the HIF address bit used as column address bit 6. Valid
Range: 0 to 7, and 15 Internal Base: 4 The selected HIF address bit is determined by adding the internal base to the value of
this field. If set to 15, this column address bit is set to 0.
PSU_DDRC_ADDRMAP2_ADDRMAP_COL_B4 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 3. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 4. - Quarter bus width mode: Selects the HIF address bit used as column address bit 5. Valid
Range: 0 to 7 Internal Base: 3 The selected HIF address bit is determined by adding the internal base to the value of this fi
ld. Note, if UMCTL2_INCL_ARB=1 and MEMC_BURST_LENGTH=16, it is required to program this to 0, hence register does not exist i
this case.
PSU_DDRC_ADDRMAP2_ADDRMAP_COL_B3 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 2. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 3. - Quarter bus width mode: Selects the HIF address bit used as column address bit 4. Valid
Range: 0 to 7 Internal Base: 2 The selected HIF address bit is determined by adding the internal base to the value of this fi
ld. Note, if UMCTL2_INCL_ARB=1 and MEMC_BURST_LENGTH=8 or 16, it is required to program this to 0.
PSU_DDRC_ADDRMAP2_ADDRMAP_COL_B2 0x0
Address Map Register 2
(OFFSET, MASK, VALUE) (0XFD070208, 0x0F0F0F0FU ,0x00000000U)
RegMask = (DDRC_ADDRMAP2_ADDRMAP_COL_B5_MASK | DDRC_ADDRMAP2_ADDRMAP_COL_B4_MASK | DDRC_ADDRMAP2_ADDRMAP_COL_B3_MASK | DDRC_ADDRMAP2_ADDRMAP_COL_B2_MASK | 0 );
RegVal = ((0x00000000U << DDRC_ADDRMAP2_ADDRMAP_COL_B5_SHIFT
| 0x00000000U << DDRC_ADDRMAP2_ADDRMAP_COL_B4_SHIFT
| 0x00000000U << DDRC_ADDRMAP2_ADDRMAP_COL_B3_SHIFT
| 0x00000000U << DDRC_ADDRMAP2_ADDRMAP_COL_B2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP2_OFFSET ,0x0F0F0F0FU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ADDRMAP3 @ 0XFD07020C</p>
- Full bus width mode: Selects the HIF address bit used as column address bit 9. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 11 (10 in LPDDR2/LPDDR3 mode). - Quarter bus width mode: Selects the HIF address bit used as
column address bit 13 (11 in LPDDR2/LPDDR3 mode). Valid Range: 0 to 7, and 15 Internal Base: 9 The selected HIF address bit i
determined by adding the internal base to the value of this field. If set to 15, this column address bit is set to 0. Note:
er JEDEC DDR2/3/mDDR specification, column address bit 10 is reserved for indicating auto-precharge, and hence no source addr
ss bit can be mapped to column address bit 10. In LPDDR2/LPDDR3, there is a dedicated bit for auto-precharge in the CA bus an
hence column bit 10 is used.
PSU_DDRC_ADDRMAP3_ADDRMAP_COL_B9 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 8. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 9. - Quarter bus width mode: Selects the HIF address bit used as column address bit 11 (10 i
LPDDR2/LPDDR3 mode). Valid Range: 0 to 7, and 15 Internal Base: 8 The selected HIF address bit is determined by adding the i
ternal base to the value of this field. If set to 15, this column address bit is set to 0. Note: Per JEDEC DDR2/3/mDDR specif
cation, column address bit 10 is reserved for indicating auto-precharge, and hence no source address bit can be mapped to col
mn address bit 10. In LPDDR2/LPDDR3, there is a dedicated bit for auto-precharge in the CA bus and hence column bit 10 is use
.
PSU_DDRC_ADDRMAP3_ADDRMAP_COL_B8 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 7. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 8. - Quarter bus width mode: Selects the HIF address bit used as column address bit 9. Valid
Range: 0 to 7, and 15 Internal Base: 7 The selected HIF address bit is determined by adding the internal base to the value of
this field. If set to 15, this column address bit is set to 0.
PSU_DDRC_ADDRMAP3_ADDRMAP_COL_B7 0x0
- Full bus width mode: Selects the HIF address bit used as column address bit 6. - Half bus width mode: Selects the HIF addre
s bit used as column address bit 7. - Quarter bus width mode: Selects the HIF address bit used as column address bit 8. Valid
Range: 0 to 7, and 15 Internal Base: 6 The selected HIF address bit is determined by adding the internal base to the value of
this field. If set to 15, this column address bit is set to 0.
PSU_DDRC_ADDRMAP3_ADDRMAP_COL_B6 0x0
Address Map Register 3
(OFFSET, MASK, VALUE) (0XFD07020C, 0x0F0F0F0FU ,0x00000000U)
RegMask = (DDRC_ADDRMAP3_ADDRMAP_COL_B9_MASK | DDRC_ADDRMAP3_ADDRMAP_COL_B8_MASK | DDRC_ADDRMAP3_ADDRMAP_COL_B7_MASK | DDRC_ADDRMAP3_ADDRMAP_COL_B6_MASK | 0 );
RegVal = ((0x00000000U << DDRC_ADDRMAP3_ADDRMAP_COL_B9_SHIFT
| 0x00000000U << DDRC_ADDRMAP3_ADDRMAP_COL_B8_SHIFT
| 0x00000000U << DDRC_ADDRMAP3_ADDRMAP_COL_B7_SHIFT
| 0x00000000U << DDRC_ADDRMAP3_ADDRMAP_COL_B6_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP3_OFFSET ,0x0F0F0F0FU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ADDRMAP4 @ 0XFD070210</p>
- Full bus width mode: Selects the HIF address bit used as column address bit 13 (11 in LPDDR2/LPDDR3 mode). - Half bus width
mode: Unused. To make it unused, this should be tied to 4'hF. - Quarter bus width mode: Unused. To make it unused, this must
e tied to 4'hF. Valid Range: 0 to 7, and 15 Internal Base: 11 The selected HIF address bit is determined by adding the intern
l base to the value of this field. If set to 15, this column address bit is set to 0. Note: Per JEDEC DDR2/3/mDDR specificati
n, column address bit 10 is reserved for indicating auto-precharge, and hence no source address bit can be mapped to column a
dress bit 10. In LPDDR2/LPDDR3, there is a dedicated bit for auto-precharge in the CA bus and hence column bit 10 is used.
PSU_DDRC_ADDRMAP4_ADDRMAP_COL_B11 0xf
- Full bus width mode: Selects the HIF address bit used as column address bit 11 (10 in LPDDR2/LPDDR3 mode). - Half bus width
mode: Selects the HIF address bit used as column address bit 13 (11 in LPDDR2/LPDDR3 mode). - Quarter bus width mode: UNUSED.
To make it unused, this must be tied to 4'hF. Valid Range: 0 to 7, and 15 Internal Base: 10 The selected HIF address bit is d
termined by adding the internal base to the value of this field. If set to 15, this column address bit is set to 0. Note: Per
JEDEC DDR2/3/mDDR specification, column address bit 10 is reserved for indicating auto-precharge, and hence no source address
bit can be mapped to column address bit 10. In LPDDR2/LPDDR3, there is a dedicated bit for auto-precharge in the CA bus and h
nce column bit 10 is used.
PSU_DDRC_ADDRMAP4_ADDRMAP_COL_B10 0xf
Address Map Register 4
(OFFSET, MASK, VALUE) (0XFD070210, 0x00000F0FU ,0x00000F0FU)
RegMask = (DDRC_ADDRMAP4_ADDRMAP_COL_B11_MASK | DDRC_ADDRMAP4_ADDRMAP_COL_B10_MASK | 0 );
RegVal = ((0x0000000FU << DDRC_ADDRMAP4_ADDRMAP_COL_B11_SHIFT
| 0x0000000FU << DDRC_ADDRMAP4_ADDRMAP_COL_B10_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP4_OFFSET ,0x00000F0FU ,0x00000F0FU);
/*############################################################################################################################ */
/*Register : ADDRMAP5 @ 0XFD070214</p>
Selects the HIF address bit used as row address bit 11. Valid Range: 0 to 11, and 15 Internal Base: 17 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 11 is set to 0.
PSU_DDRC_ADDRMAP5_ADDRMAP_ROW_B11 0x8
Selects the HIF address bits used as row address bits 2 to 10. Valid Range: 0 to 11, and 15 Internal Base: 8 (for row address
bit 2), 9 (for row address bit 3), 10 (for row address bit 4) etc increasing to 16 (for row address bit 10) The selected HIF
ddress bit for each of the row address bits is determined by adding the internal base to the value of this field. When value
5 is used the values of row address bits 2 to 10 are defined by registers ADDRMAP9, ADDRMAP10, ADDRMAP11.
PSU_DDRC_ADDRMAP5_ADDRMAP_ROW_B2_10 0xf
Selects the HIF address bits used as row address bit 1. Valid Range: 0 to 11 Internal Base: 7 The selected HIF address bit fo
each of the row address bits is determined by adding the internal base to the value of this field.
PSU_DDRC_ADDRMAP5_ADDRMAP_ROW_B1 0x8
Selects the HIF address bits used as row address bit 0. Valid Range: 0 to 11 Internal Base: 6 The selected HIF address bit fo
each of the row address bits is determined by adding the internal base to the value of this field.
PSU_DDRC_ADDRMAP5_ADDRMAP_ROW_B0 0x8
Address Map Register 5
(OFFSET, MASK, VALUE) (0XFD070214, 0x0F0F0F0FU ,0x080F0808U)
RegMask = (DDRC_ADDRMAP5_ADDRMAP_ROW_B11_MASK | DDRC_ADDRMAP5_ADDRMAP_ROW_B2_10_MASK | DDRC_ADDRMAP5_ADDRMAP_ROW_B1_MASK | DDRC_ADDRMAP5_ADDRMAP_ROW_B0_MASK | 0 );
RegVal = ((0x00000008U << DDRC_ADDRMAP5_ADDRMAP_ROW_B11_SHIFT
| 0x0000000FU << DDRC_ADDRMAP5_ADDRMAP_ROW_B2_10_SHIFT
| 0x00000008U << DDRC_ADDRMAP5_ADDRMAP_ROW_B1_SHIFT
| 0x00000008U << DDRC_ADDRMAP5_ADDRMAP_ROW_B0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP5_OFFSET ,0x0F0F0F0FU ,0x080F0808U);
/*############################################################################################################################ */
/*Register : ADDRMAP6 @ 0XFD070218</p>
Set this to 1 if there is an LPDDR3 SDRAM 6Gb or 12Gb device in use. - 1 - LPDDR3 SDRAM 6Gb/12Gb device in use. Every address
having row[14:13]==2'b11 is considered as invalid - 0 - non-LPDDR3 6Gb/12Gb device in use. All addresses are valid Present on
y in designs configured to support LPDDR3.
PSU_DDRC_ADDRMAP6_LPDDR3_6GB_12GB 0x0
Selects the HIF address bit used as row address bit 15. Valid Range: 0 to 11, and 15 Internal Base: 21 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 15 is set to 0.
PSU_DDRC_ADDRMAP6_ADDRMAP_ROW_B15 0xf
Selects the HIF address bit used as row address bit 14. Valid Range: 0 to 11, and 15 Internal Base: 20 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 14 is set to 0.
PSU_DDRC_ADDRMAP6_ADDRMAP_ROW_B14 0x8
Selects the HIF address bit used as row address bit 13. Valid Range: 0 to 11, and 15 Internal Base: 19 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 13 is set to 0.
PSU_DDRC_ADDRMAP6_ADDRMAP_ROW_B13 0x8
Selects the HIF address bit used as row address bit 12. Valid Range: 0 to 11, and 15 Internal Base: 18 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 12 is set to 0.
PSU_DDRC_ADDRMAP6_ADDRMAP_ROW_B12 0x8
Address Map Register 6
(OFFSET, MASK, VALUE) (0XFD070218, 0x8F0F0F0FU ,0x0F080808U)
RegMask = (DDRC_ADDRMAP6_LPDDR3_6GB_12GB_MASK | DDRC_ADDRMAP6_ADDRMAP_ROW_B15_MASK | DDRC_ADDRMAP6_ADDRMAP_ROW_B14_MASK | DDRC_ADDRMAP6_ADDRMAP_ROW_B13_MASK | DDRC_ADDRMAP6_ADDRMAP_ROW_B12_MASK | 0 );
RegVal = ((0x00000000U << DDRC_ADDRMAP6_LPDDR3_6GB_12GB_SHIFT
| 0x0000000FU << DDRC_ADDRMAP6_ADDRMAP_ROW_B15_SHIFT
| 0x00000008U << DDRC_ADDRMAP6_ADDRMAP_ROW_B14_SHIFT
| 0x00000008U << DDRC_ADDRMAP6_ADDRMAP_ROW_B13_SHIFT
| 0x00000008U << DDRC_ADDRMAP6_ADDRMAP_ROW_B12_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP6_OFFSET ,0x8F0F0F0FU ,0x0F080808U);
/*############################################################################################################################ */
/*Register : ADDRMAP7 @ 0XFD07021C</p>
Selects the HIF address bit used as row address bit 17. Valid Range: 0 to 10, and 15 Internal Base: 23 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 17 is set to 0.
PSU_DDRC_ADDRMAP7_ADDRMAP_ROW_B17 0xf
Selects the HIF address bit used as row address bit 16. Valid Range: 0 to 11, and 15 Internal Base: 22 The selected HIF addre
s bit is determined by adding the internal base to the value of this field. If set to 15, row address bit 16 is set to 0.
PSU_DDRC_ADDRMAP7_ADDRMAP_ROW_B16 0xf
Address Map Register 7
(OFFSET, MASK, VALUE) (0XFD07021C, 0x00000F0FU ,0x00000F0FU)
RegMask = (DDRC_ADDRMAP7_ADDRMAP_ROW_B17_MASK | DDRC_ADDRMAP7_ADDRMAP_ROW_B16_MASK | 0 );
RegVal = ((0x0000000FU << DDRC_ADDRMAP7_ADDRMAP_ROW_B17_SHIFT
| 0x0000000FU << DDRC_ADDRMAP7_ADDRMAP_ROW_B16_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP7_OFFSET ,0x00000F0FU ,0x00000F0FU);
/*############################################################################################################################ */
/*Register : ADDRMAP8 @ 0XFD070220</p>
Selects the HIF address bits used as bank group address bit 1. Valid Range: 0 to 30, and 31 Internal Base: 3 The selected HIF
address bit for each of the bank group address bits is determined by adding the internal base to the value of this field. If
et to 31, bank group address bit 1 is set to 0.
PSU_DDRC_ADDRMAP8_ADDRMAP_BG_B1 0x8
Selects the HIF address bits used as bank group address bit 0. Valid Range: 0 to 30 Internal Base: 2 The selected HIF address
bit for each of the bank group address bits is determined by adding the internal base to the value of this field.
PSU_DDRC_ADDRMAP8_ADDRMAP_BG_B0 0x8
Address Map Register 8
(OFFSET, MASK, VALUE) (0XFD070220, 0x00001F1FU ,0x00000808U)
RegMask = (DDRC_ADDRMAP8_ADDRMAP_BG_B1_MASK | DDRC_ADDRMAP8_ADDRMAP_BG_B0_MASK | 0 );
RegVal = ((0x00000008U << DDRC_ADDRMAP8_ADDRMAP_BG_B1_SHIFT
| 0x00000008U << DDRC_ADDRMAP8_ADDRMAP_BG_B0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP8_OFFSET ,0x00001F1FU ,0x00000808U);
/*############################################################################################################################ */
/*Register : ADDRMAP9 @ 0XFD070224</p>
Selects the HIF address bits used as row address bit 5. Valid Range: 0 to 11 Internal Base: 11 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP9_ADDRMAP_ROW_B5 0x8
Selects the HIF address bits used as row address bit 4. Valid Range: 0 to 11 Internal Base: 10 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP9_ADDRMAP_ROW_B4 0x8
Selects the HIF address bits used as row address bit 3. Valid Range: 0 to 11 Internal Base: 9 The selected HIF address bit fo
each of the row address bits is determined by adding the internal base to the value of this field. This register field is us
d only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP9_ADDRMAP_ROW_B3 0x8
Selects the HIF address bits used as row address bit 2. Valid Range: 0 to 11 Internal Base: 8 The selected HIF address bit fo
each of the row address bits is determined by adding the internal base to the value of this field. This register field is us
d only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP9_ADDRMAP_ROW_B2 0x8
Address Map Register 9
(OFFSET, MASK, VALUE) (0XFD070224, 0x0F0F0F0FU ,0x08080808U)
RegMask = (DDRC_ADDRMAP9_ADDRMAP_ROW_B5_MASK | DDRC_ADDRMAP9_ADDRMAP_ROW_B4_MASK | DDRC_ADDRMAP9_ADDRMAP_ROW_B3_MASK | DDRC_ADDRMAP9_ADDRMAP_ROW_B2_MASK | 0 );
RegVal = ((0x00000008U << DDRC_ADDRMAP9_ADDRMAP_ROW_B5_SHIFT
| 0x00000008U << DDRC_ADDRMAP9_ADDRMAP_ROW_B4_SHIFT
| 0x00000008U << DDRC_ADDRMAP9_ADDRMAP_ROW_B3_SHIFT
| 0x00000008U << DDRC_ADDRMAP9_ADDRMAP_ROW_B2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP9_OFFSET ,0x0F0F0F0FU ,0x08080808U);
/*############################################################################################################################ */
/*Register : ADDRMAP10 @ 0XFD070228</p>
Selects the HIF address bits used as row address bit 9. Valid Range: 0 to 11 Internal Base: 15 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP10_ADDRMAP_ROW_B9 0x8
Selects the HIF address bits used as row address bit 8. Valid Range: 0 to 11 Internal Base: 14 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP10_ADDRMAP_ROW_B8 0x8
Selects the HIF address bits used as row address bit 7. Valid Range: 0 to 11 Internal Base: 13 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP10_ADDRMAP_ROW_B7 0x8
Selects the HIF address bits used as row address bit 6. Valid Range: 0 to 11 Internal Base: 12 The selected HIF address bit f
r each of the row address bits is determined by adding the internal base to the value of this field. This register field is u
ed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP10_ADDRMAP_ROW_B6 0x8
Address Map Register 10
(OFFSET, MASK, VALUE) (0XFD070228, 0x0F0F0F0FU ,0x08080808U)
RegMask = (DDRC_ADDRMAP10_ADDRMAP_ROW_B9_MASK | DDRC_ADDRMAP10_ADDRMAP_ROW_B8_MASK | DDRC_ADDRMAP10_ADDRMAP_ROW_B7_MASK | DDRC_ADDRMAP10_ADDRMAP_ROW_B6_MASK | 0 );
RegVal = ((0x00000008U << DDRC_ADDRMAP10_ADDRMAP_ROW_B9_SHIFT
| 0x00000008U << DDRC_ADDRMAP10_ADDRMAP_ROW_B8_SHIFT
| 0x00000008U << DDRC_ADDRMAP10_ADDRMAP_ROW_B7_SHIFT
| 0x00000008U << DDRC_ADDRMAP10_ADDRMAP_ROW_B6_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP10_OFFSET ,0x0F0F0F0FU ,0x08080808U);
/*############################################################################################################################ */
/*Register : ADDRMAP11 @ 0XFD07022C</p>
Selects the HIF address bits used as row address bit 10. Valid Range: 0 to 11 Internal Base: 16 The selected HIF address bit
or each of the row address bits is determined by adding the internal base to the value of this field. This register field is
sed only when ADDRMAP5.addrmap_row_b2_10 is set to value 15.
PSU_DDRC_ADDRMAP11_ADDRMAP_ROW_B10 0x8
Address Map Register 11
(OFFSET, MASK, VALUE) (0XFD07022C, 0x0000000FU ,0x00000008U)
RegMask = (DDRC_ADDRMAP11_ADDRMAP_ROW_B10_MASK | 0 );
RegVal = ((0x00000008U << DDRC_ADDRMAP11_ADDRMAP_ROW_B10_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ADDRMAP11_OFFSET ,0x0000000FU ,0x00000008U);
/*############################################################################################################################ */
/*Register : ODTCFG @ 0XFD070240</p>
Cycles to hold ODT for a write command. The minimum supported value is 2. Recommended values: DDR2: - BL8: 0x5 (DDR2-400/533/
67), 0x6 (DDR2-800), 0x7 (DDR2-1066) - BL4: 0x3 (DDR2-400/533/667), 0x4 (DDR2-800), 0x5 (DDR2-1066) DDR3: - BL8: 0x6 DDR4: -
L8: 5 + WR_PREAMBLE + CRC_MODE WR_PREAMBLE = 1 (1tCK write preamble), 2 (2tCK write preamble) CRC_MODE = 0 (not CRC mode), 1
CRC mode) LPDDR3: - BL8: 7 + RU(tODTon(max)/tCK)
PSU_DDRC_ODTCFG_WR_ODT_HOLD 0x6
The delay, in clock cycles, from issuing a write command to setting ODT values associated with that command. ODT setting must
remain constant for the entire time that DQS is driven by the uMCTL2. Recommended values: DDR2: - CWL + AL - 3 (DDR2-400/533/
67), CWL + AL - 4 (DDR2-800), CWL + AL - 5 (DDR2-1066) If (CWL + AL - 3 < 0), uMCTL2 does not support ODT for write operation
DDR3: - 0x0 DDR4: - DFITMG1.dfi_t_cmd_lat (to adjust for CAL mode) LPDDR3: - WL - 1 - RU(tODTon(max)/tCK))
PSU_DDRC_ODTCFG_WR_ODT_DELAY 0x0
Cycles to hold ODT for a read command. The minimum supported value is 2. Recommended values: DDR2: - BL8: 0x6 (not DDR2-1066)
0x7 (DDR2-1066) - BL4: 0x4 (not DDR2-1066), 0x5 (DDR2-1066) DDR3: - BL8 - 0x6 DDR4: - BL8: 5 + RD_PREAMBLE RD_PREAMBLE = 1 (
tCK write preamble), 2 (2tCK write preamble) LPDDR3: - BL8: 5 + RU(tDQSCK(max)/tCK) - RD(tDQSCK(min)/tCK) + RU(tODTon(max)/tC
)
PSU_DDRC_ODTCFG_RD_ODT_HOLD 0x6
The delay, in clock cycles, from issuing a read command to setting ODT values associated with that command. ODT setting must
emain constant for the entire time that DQS is driven by the uMCTL2. Recommended values: DDR2: - CL + AL - 4 (not DDR2-1066),
CL + AL - 5 (DDR2-1066) If (CL + AL - 4 < 0), uMCTL2 does not support ODT for read operation. DDR3: - CL - CWL DDR4: - CL - C
L - RD_PREAMBLE + WR_PREAMBLE + DFITMG1.dfi_t_cmd_lat (to adjust for CAL mode) WR_PREAMBLE = 1 (1tCK write preamble), 2 (2tCK
write preamble) RD_PREAMBLE = 1 (1tCK write preamble), 2 (2tCK write preamble) If (CL - CWL - RD_PREAMBLE + WR_PREAMBLE) < 0,
uMCTL2 does not support ODT for read operation. LPDDR3: - RL + RD(tDQSCK(min)/tCK) - 1 - RU(tODTon(max)/tCK)
PSU_DDRC_ODTCFG_RD_ODT_DELAY 0x0
ODT Configuration Register
(OFFSET, MASK, VALUE) (0XFD070240, 0x0F1F0F7CU ,0x06000600U)
RegMask = (DDRC_ODTCFG_WR_ODT_HOLD_MASK | DDRC_ODTCFG_WR_ODT_DELAY_MASK | DDRC_ODTCFG_RD_ODT_HOLD_MASK | DDRC_ODTCFG_RD_ODT_DELAY_MASK | 0 );
RegVal = ((0x00000006U << DDRC_ODTCFG_WR_ODT_HOLD_SHIFT
| 0x00000000U << DDRC_ODTCFG_WR_ODT_DELAY_SHIFT
| 0x00000006U << DDRC_ODTCFG_RD_ODT_HOLD_SHIFT
| 0x00000000U << DDRC_ODTCFG_RD_ODT_DELAY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ODTCFG_OFFSET ,0x0F1F0F7CU ,0x06000600U);
/*############################################################################################################################ */
/*Register : ODTMAP @ 0XFD070244</p>
Indicates which remote ODTs must be turned on during a read from rank 1. Each rank has a remote ODT (in the SDRAM) which can
e turned on by setting the appropriate bit here. Rank 0 is controlled by the LSB; rank 1 is controlled by bit next to the LSB
etc. For each rank, set its bit to 1 to enable its ODT. Present only in configurations that have 2 or more ranks
PSU_DDRC_ODTMAP_RANK1_RD_ODT 0x0
Indicates which remote ODTs must be turned on during a write to rank 1. Each rank has a remote ODT (in the SDRAM) which can b
turned on by setting the appropriate bit here. Rank 0 is controlled by the LSB; rank 1 is controlled by bit next to the LSB,
etc. For each rank, set its bit to 1 to enable its ODT. Present only in configurations that have 2 or more ranks
PSU_DDRC_ODTMAP_RANK1_WR_ODT 0x0
Indicates which remote ODTs must be turned on during a read from rank 0. Each rank has a remote ODT (in the SDRAM) which can
e turned on by setting the appropriate bit here. Rank 0 is controlled by the LSB; rank 1 is controlled by bit next to the LSB
etc. For each rank, set its bit to 1 to enable its ODT.
PSU_DDRC_ODTMAP_RANK0_RD_ODT 0x0
Indicates which remote ODTs must be turned on during a write to rank 0. Each rank has a remote ODT (in the SDRAM) which can b
turned on by setting the appropriate bit here. Rank 0 is controlled by the LSB; rank 1 is controlled by bit next to the LSB,
etc. For each rank, set its bit to 1 to enable its ODT.
PSU_DDRC_ODTMAP_RANK0_WR_ODT 0x1
ODT/Rank Map Register
(OFFSET, MASK, VALUE) (0XFD070244, 0x00003333U ,0x00000001U)
RegMask = (DDRC_ODTMAP_RANK1_RD_ODT_MASK | DDRC_ODTMAP_RANK1_WR_ODT_MASK | DDRC_ODTMAP_RANK0_RD_ODT_MASK | DDRC_ODTMAP_RANK0_WR_ODT_MASK | 0 );
RegVal = ((0x00000000U << DDRC_ODTMAP_RANK1_RD_ODT_SHIFT
| 0x00000000U << DDRC_ODTMAP_RANK1_WR_ODT_SHIFT
| 0x00000000U << DDRC_ODTMAP_RANK0_RD_ODT_SHIFT
| 0x00000001U << DDRC_ODTMAP_RANK0_WR_ODT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_ODTMAP_OFFSET ,0x00003333U ,0x00000001U);
/*############################################################################################################################ */
/*Register : SCHED @ 0XFD070250</p>
When the preferred transaction store is empty for these many clock cycles, switch to the alternate transaction store if it is
non-empty. The read transaction store (both high and low priority) is the default preferred transaction store and the write t
ansaction store is the alternative store. When prefer write over read is set this is reversed. 0x0 is a legal value for this
egister. When set to 0x0, the transaction store switching will happen immediately when the switching conditions become true.
OR PERFORMANCE ONLY
PSU_DDRC_SCHED_RDWR_IDLE_GAP 0x1
UNUSED
PSU_DDRC_SCHED_GO2CRITICAL_HYSTERESIS 0x0
Number of entries in the low priority transaction store is this value + 1. (MEMC_NO_OF_ENTRY - (SCHED.lpr_num_entries + 1)) i
the number of entries available for the high priority transaction store. Setting this to maximum value allocates all entries
to low priority transaction store. Setting this to 0 allocates 1 entry to low priority transaction store and the rest to high
priority transaction store. Note: In ECC configurations, the numbers of write and low priority read credits issued is one les
than in the non-ECC case. One entry each is reserved in the write and low-priority read CAMs for storing the RMW requests ar
sing out of single bit error correction RMW operation.
PSU_DDRC_SCHED_LPR_NUM_ENTRIES 0x20
If true, bank is kept open only while there are page hit transactions available in the CAM to that bank. The last read or wri
e command in the CAM with a bank and page hit will be executed with auto-precharge if SCHED1.pageclose_timer=0. Even if this
egister set to 1 and SCHED1.pageclose_timer is set to 0, explicit precharge (and not auto-precharge) may be issued in some ca
es where there is a mode switch between Write and Read or between LPR and HPR. The Read and Write commands that are executed
s part of the ECC scrub requests are also executed without auto-precharge. If false, the bank remains open until there is a n
ed to close it (to open a different page, or for page timeout or refresh timeout) - also known as open page policy. The open
age policy can be overridden by setting the per-command-autopre bit on the HIF interface (hif_cmd_autopre). The pageclose fea
ure provids a midway between Open and Close page policies. FOR PERFORMANCE ONLY.
PSU_DDRC_SCHED_PAGECLOSE 0x0
If set then the bank selector prefers writes over reads. FOR DEBUG ONLY.
PSU_DDRC_SCHED_PREFER_WRITE 0x0
Active low signal. When asserted ('0'), all incoming transactions are forced to low priority. This implies that all High Prio
ity Read (HPR) and Variable Priority Read commands (VPR) will be treated as Low Priority Read (LPR) commands. On the write si
e, all Variable Priority Write (VPW) commands will be treated as Normal Priority Write (NPW) commands. Forcing the incoming t
ansactions to low priority implicitly turns off Bypass path for read commands. FOR PERFORMANCE ONLY.
PSU_DDRC_SCHED_FORCE_LOW_PRI_N 0x1
Scheduler Control Register
(OFFSET, MASK, VALUE) (0XFD070250, 0x7FFF3F07U ,0x01002001U)
RegMask = (DDRC_SCHED_RDWR_IDLE_GAP_MASK | DDRC_SCHED_GO2CRITICAL_HYSTERESIS_MASK | DDRC_SCHED_LPR_NUM_ENTRIES_MASK | DDRC_SCHED_PAGECLOSE_MASK | DDRC_SCHED_PREFER_WRITE_MASK | DDRC_SCHED_FORCE_LOW_PRI_N_MASK | 0 );
RegVal = ((0x00000001U << DDRC_SCHED_RDWR_IDLE_GAP_SHIFT
| 0x00000000U << DDRC_SCHED_GO2CRITICAL_HYSTERESIS_SHIFT
| 0x00000020U << DDRC_SCHED_LPR_NUM_ENTRIES_SHIFT
| 0x00000000U << DDRC_SCHED_PAGECLOSE_SHIFT
| 0x00000000U << DDRC_SCHED_PREFER_WRITE_SHIFT
| 0x00000001U << DDRC_SCHED_FORCE_LOW_PRI_N_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SCHED_OFFSET ,0x7FFF3F07U ,0x01002001U);
/*############################################################################################################################ */
/*Register : PERFLPR1 @ 0XFD070264</p>
Number of transactions that are serviced once the LPR queue goes critical is the smaller of: - (a) This number - (b) Number o
transactions available. Unit: Transaction. FOR PERFORMANCE ONLY.
PSU_DDRC_PERFLPR1_LPR_XACT_RUN_LENGTH 0x8
Number of clocks that the LPR queue can be starved before it goes critical. The minimum valid functional value for this regis
er is 0x1. Programming it to 0x0 will disable the starvation functionality; during normal operation, this function should not
be disabled as it will cause excessive latencies. Unit: Clock cycles. FOR PERFORMANCE ONLY.
PSU_DDRC_PERFLPR1_LPR_MAX_STARVE 0x40
Low Priority Read CAM Register 1
(OFFSET, MASK, VALUE) (0XFD070264, 0xFF00FFFFU ,0x08000040U)
RegMask = (DDRC_PERFLPR1_LPR_XACT_RUN_LENGTH_MASK | DDRC_PERFLPR1_LPR_MAX_STARVE_MASK | 0 );
RegVal = ((0x00000008U << DDRC_PERFLPR1_LPR_XACT_RUN_LENGTH_SHIFT
| 0x00000040U << DDRC_PERFLPR1_LPR_MAX_STARVE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PERFLPR1_OFFSET ,0xFF00FFFFU ,0x08000040U);
/*############################################################################################################################ */
/*Register : PERFWR1 @ 0XFD07026C</p>
Number of transactions that are serviced once the WR queue goes critical is the smaller of: - (a) This number - (b) Number of
transactions available. Unit: Transaction. FOR PERFORMANCE ONLY.
PSU_DDRC_PERFWR1_W_XACT_RUN_LENGTH 0x8
Number of clocks that the WR queue can be starved before it goes critical. The minimum valid functional value for this regist
r is 0x1. Programming it to 0x0 will disable the starvation functionality; during normal operation, this function should not
e disabled as it will cause excessive latencies. Unit: Clock cycles. FOR PERFORMANCE ONLY.
PSU_DDRC_PERFWR1_W_MAX_STARVE 0x40
Write CAM Register 1
(OFFSET, MASK, VALUE) (0XFD07026C, 0xFF00FFFFU ,0x08000040U)
RegMask = (DDRC_PERFWR1_W_XACT_RUN_LENGTH_MASK | DDRC_PERFWR1_W_MAX_STARVE_MASK | 0 );
RegVal = ((0x00000008U << DDRC_PERFWR1_W_XACT_RUN_LENGTH_SHIFT
| 0x00000040U << DDRC_PERFWR1_W_MAX_STARVE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PERFWR1_OFFSET ,0xFF00FFFFU ,0x08000040U);
/*############################################################################################################################ */
/*Register : DQMAP5 @ 0XFD070294</p>
All even ranks have the same DQ mapping controled by DQMAP0-4 register as rank 0. This register provides DQ swap function for
all odd ranks to support CRC feature. rank based DQ swapping is: swap bit 0 with 1, swap bit 2 with 3, swap bit 4 with 5 and
wap bit 6 with 7. 1: Disable rank based DQ swapping 0: Enable rank based DQ swapping Present only in designs configured to su
port DDR4.
PSU_DDRC_DQMAP5_DIS_DQ_RANK_SWAP 0x1
DQ Map Register 5
(OFFSET, MASK, VALUE) (0XFD070294, 0x00000001U ,0x00000001U)
RegMask = (DDRC_DQMAP5_DIS_DQ_RANK_SWAP_MASK | 0 );
RegVal = ((0x00000001U << DDRC_DQMAP5_DIS_DQ_RANK_SWAP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DQMAP5_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : DBG0 @ 0XFD070300</p>
When this is set to '0', auto-precharge is disabled for the flushed command in a collision case. Collision cases are write fo
lowed by read to same address, read followed by write to same address, or write followed by write to same address with DBG0.d
s_wc bit = 1 (where same address comparisons exclude the two address bits representing critical word). FOR DEBUG ONLY.
PSU_DDRC_DBG0_DIS_COLLISION_PAGE_OPT 0x0
When 1, disable write combine. FOR DEBUG ONLY
PSU_DDRC_DBG0_DIS_WC 0x0
Debug Register 0
(OFFSET, MASK, VALUE) (0XFD070300, 0x00000011U ,0x00000000U)
RegMask = (DDRC_DBG0_DIS_COLLISION_PAGE_OPT_MASK | DDRC_DBG0_DIS_WC_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DBG0_DIS_COLLISION_PAGE_OPT_SHIFT
| 0x00000000U << DDRC_DBG0_DIS_WC_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DBG0_OFFSET ,0x00000011U ,0x00000000U);
/*############################################################################################################################ */
/*Register : DBGCMD @ 0XFD07030C</p>
Setting this register bit to 1 allows refresh and ZQCS commands to be triggered from hardware via the IOs ext_*. If set to 1,
the fields DBGCMD.zq_calib_short and DBGCMD.rank*_refresh have no function, and are ignored by the uMCTL2 logic. Setting this
register bit to 0 allows refresh and ZQCS to be triggered from software, via the fields DBGCMD.zq_calib_short and DBGCMD.rank
_refresh. If set to 0, the hardware pins ext_* have no function, and are ignored by the uMCTL2 logic. This register is static
and may only be changed when the DDRC reset signal, core_ddrc_rstn, is asserted (0).
PSU_DDRC_DBGCMD_HW_REF_ZQ_EN 0x0
Setting this register bit to 1 indicates to the uMCTL2 to issue a dfi_ctrlupd_req to the PHY. When this request is stored in
he uMCTL2, the bit is automatically cleared. This operation must only be performed when DFIUPD0.dis_auto_ctrlupd=1.
PSU_DDRC_DBGCMD_CTRLUPD 0x0
Setting this register bit to 1 indicates to the uMCTL2 to issue a ZQCS (ZQ calibration short)/MPC(ZQ calibration) command to
he SDRAM. When this request is stored in the uMCTL2, the bit is automatically cleared. This operation can be performed only w
en ZQCTL0.dis_auto_zq=1. It is recommended NOT to set this register bit if in Init operating mode. This register bit is ignor
d when in Self-Refresh(except LPDDR4) and SR-Powerdown(LPDDR4) and Deep power-down operating modes and Maximum Power Saving M
de.
PSU_DDRC_DBGCMD_ZQ_CALIB_SHORT 0x0
Setting this register bit to 1 indicates to the uMCTL2 to issue a refresh to rank 1. Writing to this bit causes DBGSTAT.rank1
refresh_busy to be set. When DBGSTAT.rank1_refresh_busy is cleared, the command has been stored in uMCTL2. This operation can
be performed only when RFSHCTL3.dis_auto_refresh=1. It is recommended NOT to set this register bit if in Init or Deep power-d
wn operating modes or Maximum Power Saving Mode.
PSU_DDRC_DBGCMD_RANK1_REFRESH 0x0
Setting this register bit to 1 indicates to the uMCTL2 to issue a refresh to rank 0. Writing to this bit causes DBGSTAT.rank0
refresh_busy to be set. When DBGSTAT.rank0_refresh_busy is cleared, the command has been stored in uMCTL2. This operation can
be performed only when RFSHCTL3.dis_auto_refresh=1. It is recommended NOT to set this register bit if in Init or Deep power-d
wn operating modes or Maximum Power Saving Mode.
PSU_DDRC_DBGCMD_RANK0_REFRESH 0x0
Command Debug Register
(OFFSET, MASK, VALUE) (0XFD07030C, 0x80000033U ,0x00000000U)
RegMask = (DDRC_DBGCMD_HW_REF_ZQ_EN_MASK | DDRC_DBGCMD_CTRLUPD_MASK | DDRC_DBGCMD_ZQ_CALIB_SHORT_MASK | DDRC_DBGCMD_RANK1_REFRESH_MASK | DDRC_DBGCMD_RANK0_REFRESH_MASK | 0 );
RegVal = ((0x00000000U << DDRC_DBGCMD_HW_REF_ZQ_EN_SHIFT
| 0x00000000U << DDRC_DBGCMD_CTRLUPD_SHIFT
| 0x00000000U << DDRC_DBGCMD_ZQ_CALIB_SHORT_SHIFT
| 0x00000000U << DDRC_DBGCMD_RANK1_REFRESH_SHIFT
| 0x00000000U << DDRC_DBGCMD_RANK0_REFRESH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DBGCMD_OFFSET ,0x80000033U ,0x00000000U);
/*############################################################################################################################ */
/*Register : SWCTL @ 0XFD070320</p>
Enable quasi-dynamic register programming outside reset. Program register to 0 to enable quasi-dynamic programming. Set back
egister to 1 once programming is done.
PSU_DDRC_SWCTL_SW_DONE 0x0
Software register programming control enable
(OFFSET, MASK, VALUE) (0XFD070320, 0x00000001U ,0x00000000U)
RegMask = (DDRC_SWCTL_SW_DONE_MASK | 0 );
RegVal = ((0x00000000U << DDRC_SWCTL_SW_DONE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SWCTL_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
/*Register : PCCFG @ 0XFD070400</p>
Burst length expansion mode. By default (i.e. bl_exp_mode==0) XPI expands every AXI burst into multiple HIF commands, using t
e memory burst length as a unit. If set to 1, then XPI will use half of the memory burst length as a unit. This applies to bo
h reads and writes. When MSTR.data_bus_width==00, setting bl_exp_mode to 1 has no effect. This can be used in cases where Par
ial Writes is enabled (UMCTL2_PARTIAL_WR=1) and DBG0.dis_wc=1, in order to avoid or minimize t_ccd_l penalty in DDR4 and t_cc
_mw penalty in LPDDR4. Note that if DBICTL.reg_ddrc_dm_en=0, functionality is not supported in the following cases: - UMCTL2_
ARTIAL_WR=0 - UMCTL2_PARTIAL_WR=1, MSTR.reg_ddrc_data_bus_width=01, MEMC_BURST_LENGTH=8 and MSTR.reg_ddrc_burst_rdwr=1000 (LP
DR4 only) - UMCTL2_PARTIAL_WR=1, MSTR.reg_ddrc_data_bus_width=01, MEMC_BURST_LENGTH=4 and MSTR.reg_ddrc_burst_rdwr=0100 (DDR4
only), with either MSTR.reg_ddrc_burstchop=0 or CRCPARCTL1.reg_ddrc_crc_enable=1 Functionality is also not supported if Share
-AC is enabled
PSU_DDRC_PCCFG_BL_EXP_MODE 0x0
Page match four limit. If set to 1, limits the number of consecutive same page DDRC transactions that can be granted by the P
rt Arbiter to four when Page Match feature is enabled. If set to 0, there is no limit imposed on number of consecutive same p
ge DDRC transactions.
PSU_DDRC_PCCFG_PAGEMATCH_LIMIT 0x0
If set to 1 (enabled), sets co_gs_go2critical_wr and co_gs_go2critical_lpr/co_gs_go2critical_hpr signals going to DDRC based
n urgent input (awurgent, arurgent) coming from AXI master. If set to 0 (disabled), co_gs_go2critical_wr and co_gs_go2critica
_lpr/co_gs_go2critical_hpr signals at DDRC are driven to 1b'0.
PSU_DDRC_PCCFG_GO2CRITICAL_EN 0x1
Port Common Configuration Register
(OFFSET, MASK, VALUE) (0XFD070400, 0x00000111U ,0x00000001U)
RegMask = (DDRC_PCCFG_BL_EXP_MODE_MASK | DDRC_PCCFG_PAGEMATCH_LIMIT_MASK | DDRC_PCCFG_GO2CRITICAL_EN_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCCFG_BL_EXP_MODE_SHIFT
| 0x00000000U << DDRC_PCCFG_PAGEMATCH_LIMIT_SHIFT
| 0x00000001U << DDRC_PCCFG_GO2CRITICAL_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCCFG_OFFSET ,0x00000111U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGR_0 @ 0XFD070404</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_0_RD_PORT_PAGEMATCH_EN 0x0
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_0_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_0_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_0_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD070404, 0x000073FFU ,0x0000200FU)
RegMask = (DDRC_PCFGR_0_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_0_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_0_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_0_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGR_0_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_0_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_0_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_0_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_0_OFFSET ,0x000073FFU ,0x0000200FU);
/*############################################################################################################################ */
/*Register : PCFGW_0 @ 0XFD070408</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_0_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_0_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_0_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_0_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD070408, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_0_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_0_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_0_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_0_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_0_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_0_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_0_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_0_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_0_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_0 @ 0XFD070490</p>
Enables port n.
PSU_DDRC_PCTRL_0_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD070490, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_0_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_0_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_0_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_0 @ 0XFD070494</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_0_RQOS_MAP_REGION1 0x2
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_0_RQOS_MAP_REGION0 0x0
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_0_RQOS_MAP_LEVEL1 0xb
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070494, 0x0033000FU ,0x0020000BU)
RegMask = (DDRC_PCFGQOS0_0_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_0_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_0_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000002U << DDRC_PCFGQOS0_0_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_0_RQOS_MAP_REGION0_SHIFT
| 0x0000000BU << DDRC_PCFGQOS0_0_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_0_OFFSET ,0x0033000FU ,0x0020000BU);
/*############################################################################################################################ */
/*Register : PCFGQOS1_0 @ 0XFD070498</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTB 0x0
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070498, 0x07FF07FFU ,0x00000000U)
RegMask = (DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTR_SHIFT
| 0x00000000U << DDRC_PCFGQOS1_0_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_0_OFFSET ,0x07FF07FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : PCFGR_1 @ 0XFD0704B4</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_1_RD_PORT_PAGEMATCH_EN 0x0
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_1_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_1_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_1_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD0704B4, 0x000073FFU ,0x0000200FU)
RegMask = (DDRC_PCFGR_1_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_1_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_1_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_1_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGR_1_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_1_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_1_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_1_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_1_OFFSET ,0x000073FFU ,0x0000200FU);
/*############################################################################################################################ */
/*Register : PCFGW_1 @ 0XFD0704B8</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_1_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_1_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_1_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_1_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD0704B8, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_1_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_1_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_1_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_1_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_1_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_1_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_1_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_1_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_1_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_1 @ 0XFD070540</p>
Enables port n.
PSU_DDRC_PCTRL_1_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD070540, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_1_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_1_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_1_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_1 @ 0XFD070544</p>
This bitfield indicates the traffic class of region2. For dual address queue configurations, region2 maps to the red address
ueue. Valid values are 1: VPR and 2: HPR only. When VPR support is disabled (UMCTL2_VPR_EN = 0) and traffic class of region2
s set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_1_RQOS_MAP_REGION2 0x2
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_1_RQOS_MAP_REGION1 0x0
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_1_RQOS_MAP_REGION0 0x0
Separation level2 indicating the end of region1 mapping; start of region1 is (level1 + 1). Possible values for level2 are (le
el1 + 1) to 14 which corresponds to arqos. Region2 starts from (level2 + 1) up to 15. Note that for PA, arqos values are used
directly as port priorities, where the higher the value corresponds to higher port priority. All of the map_level* registers
ust be set to distinct values.
PSU_DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL2 0xb
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL1 0x3
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070544, 0x03330F0FU ,0x02000B03U)
RegMask = (DDRC_PCFGQOS0_1_RQOS_MAP_REGION2_MASK | DDRC_PCFGQOS0_1_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_1_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL2_MASK | DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000002U << DDRC_PCFGQOS0_1_RQOS_MAP_REGION2_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_1_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_1_RQOS_MAP_REGION0_SHIFT
| 0x0000000BU << DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL2_SHIFT
| 0x00000003U << DDRC_PCFGQOS0_1_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_1_OFFSET ,0x03330F0FU ,0x02000B03U);
/*############################################################################################################################ */
/*Register : PCFGQOS1_1 @ 0XFD070548</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTB 0x0
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070548, 0x07FF07FFU ,0x00000000U)
RegMask = (DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTR_SHIFT
| 0x00000000U << DDRC_PCFGQOS1_1_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_1_OFFSET ,0x07FF07FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : PCFGR_2 @ 0XFD070564</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_2_RD_PORT_PAGEMATCH_EN 0x0
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_2_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_2_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_2_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD070564, 0x000073FFU ,0x0000200FU)
RegMask = (DDRC_PCFGR_2_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_2_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_2_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_2_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGR_2_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_2_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_2_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_2_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_2_OFFSET ,0x000073FFU ,0x0000200FU);
/*############################################################################################################################ */
/*Register : PCFGW_2 @ 0XFD070568</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_2_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_2_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_2_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_2_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD070568, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_2_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_2_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_2_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_2_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_2_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_2_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_2_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_2_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_2_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_2 @ 0XFD0705F0</p>
Enables port n.
PSU_DDRC_PCTRL_2_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD0705F0, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_2_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_2_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_2_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_2 @ 0XFD0705F4</p>
This bitfield indicates the traffic class of region2. For dual address queue configurations, region2 maps to the red address
ueue. Valid values are 1: VPR and 2: HPR only. When VPR support is disabled (UMCTL2_VPR_EN = 0) and traffic class of region2
s set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_2_RQOS_MAP_REGION2 0x2
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_2_RQOS_MAP_REGION1 0x0
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_2_RQOS_MAP_REGION0 0x0
Separation level2 indicating the end of region1 mapping; start of region1 is (level1 + 1). Possible values for level2 are (le
el1 + 1) to 14 which corresponds to arqos. Region2 starts from (level2 + 1) up to 15. Note that for PA, arqos values are used
directly as port priorities, where the higher the value corresponds to higher port priority. All of the map_level* registers
ust be set to distinct values.
PSU_DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL2 0xb
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL1 0x3
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD0705F4, 0x03330F0FU ,0x02000B03U)
RegMask = (DDRC_PCFGQOS0_2_RQOS_MAP_REGION2_MASK | DDRC_PCFGQOS0_2_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_2_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL2_MASK | DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000002U << DDRC_PCFGQOS0_2_RQOS_MAP_REGION2_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_2_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_2_RQOS_MAP_REGION0_SHIFT
| 0x0000000BU << DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL2_SHIFT
| 0x00000003U << DDRC_PCFGQOS0_2_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_2_OFFSET ,0x03330F0FU ,0x02000B03U);
/*############################################################################################################################ */
/*Register : PCFGQOS1_2 @ 0XFD0705F8</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTB 0x0
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD0705F8, 0x07FF07FFU ,0x00000000U)
RegMask = (DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTR_SHIFT
| 0x00000000U << DDRC_PCFGQOS1_2_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_2_OFFSET ,0x07FF07FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : PCFGR_3 @ 0XFD070614</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_3_RD_PORT_PAGEMATCH_EN 0x0
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_3_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_3_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_3_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD070614, 0x000073FFU ,0x0000200FU)
RegMask = (DDRC_PCFGR_3_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_3_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_3_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_3_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGR_3_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_3_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_3_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_3_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_3_OFFSET ,0x000073FFU ,0x0000200FU);
/*############################################################################################################################ */
/*Register : PCFGW_3 @ 0XFD070618</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_3_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_3_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_3_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_3_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD070618, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_3_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_3_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_3_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_3_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_3_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_3_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_3_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_3_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_3_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_3 @ 0XFD0706A0</p>
Enables port n.
PSU_DDRC_PCTRL_3_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD0706A0, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_3_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_3_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_3_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_3 @ 0XFD0706A4</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_3_RQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_3_RQOS_MAP_REGION0 0x0
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_3_RQOS_MAP_LEVEL1 0x3
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD0706A4, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGQOS0_3_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_3_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_3_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGQOS0_3_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_3_RQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGQOS0_3_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_3_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGQOS1_3 @ 0XFD0706A8</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTB 0x4f
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD0706A8, 0x07FF07FFU ,0x0000004FU)
RegMask = (DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTR_SHIFT
| 0x0000004FU << DDRC_PCFGQOS1_3_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_3_OFFSET ,0x07FF07FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : PCFGWQOS0_3 @ 0XFD0706AC</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region 1 is set to 1 (VPW), VPW traffic is aliased to LPW traffic.
PSU_DDRC_PCFGWQOS0_3_WQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region0 is set to 1 (VPW), VPW traffic is aliased to NPW traffic.
PSU_DDRC_PCFGWQOS0_3_WQOS_MAP_REGION0 0x0
Separation level indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 14 which c
rresponds to awqos. Note that for PA, awqos values are used directly as port priorities, where the higher the value correspon
s to higher port priority.
PSU_DDRC_PCFGWQOS0_3_WQOS_MAP_LEVEL 0x3
Port n Write QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD0706AC, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGWQOS0_3_WQOS_MAP_REGION1_MASK | DDRC_PCFGWQOS0_3_WQOS_MAP_REGION0_MASK | DDRC_PCFGWQOS0_3_WQOS_MAP_LEVEL_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGWQOS0_3_WQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGWQOS0_3_WQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGWQOS0_3_WQOS_MAP_LEVEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS0_3_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGWQOS1_3 @ 0XFD0706B0</p>
Specifies the timeout value for write transactions.
PSU_DDRC_PCFGWQOS1_3_WQOS_MAP_TIMEOUT 0x4f
Port n Write QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD0706B0, 0x000007FFU ,0x0000004FU)
RegMask = (DDRC_PCFGWQOS1_3_WQOS_MAP_TIMEOUT_MASK | 0 );
RegVal = ((0x0000004FU << DDRC_PCFGWQOS1_3_WQOS_MAP_TIMEOUT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS1_3_OFFSET ,0x000007FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : PCFGR_4 @ 0XFD0706C4</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_4_RD_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_4_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_4_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_4_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD0706C4, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGR_4_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_4_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_4_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_4_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGR_4_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_4_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_4_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_4_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_4_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCFGW_4 @ 0XFD0706C8</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_4_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_4_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_4_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_4_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD0706C8, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_4_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_4_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_4_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_4_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_4_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_4_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_4_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_4_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_4_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_4 @ 0XFD070750</p>
Enables port n.
PSU_DDRC_PCTRL_4_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD070750, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_4_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_4_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_4_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_4 @ 0XFD070754</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_4_RQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_4_RQOS_MAP_REGION0 0x0
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_4_RQOS_MAP_LEVEL1 0x3
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070754, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGQOS0_4_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_4_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_4_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGQOS0_4_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_4_RQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGQOS0_4_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_4_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGQOS1_4 @ 0XFD070758</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTB 0x4f
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070758, 0x07FF07FFU ,0x0000004FU)
RegMask = (DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTR_SHIFT
| 0x0000004FU << DDRC_PCFGQOS1_4_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_4_OFFSET ,0x07FF07FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : PCFGWQOS0_4 @ 0XFD07075C</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region 1 is set to 1 (VPW), VPW traffic is aliased to LPW traffic.
PSU_DDRC_PCFGWQOS0_4_WQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region0 is set to 1 (VPW), VPW traffic is aliased to NPW traffic.
PSU_DDRC_PCFGWQOS0_4_WQOS_MAP_REGION0 0x0
Separation level indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 14 which c
rresponds to awqos. Note that for PA, awqos values are used directly as port priorities, where the higher the value correspon
s to higher port priority.
PSU_DDRC_PCFGWQOS0_4_WQOS_MAP_LEVEL 0x3
Port n Write QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD07075C, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGWQOS0_4_WQOS_MAP_REGION1_MASK | DDRC_PCFGWQOS0_4_WQOS_MAP_REGION0_MASK | DDRC_PCFGWQOS0_4_WQOS_MAP_LEVEL_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGWQOS0_4_WQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGWQOS0_4_WQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGWQOS0_4_WQOS_MAP_LEVEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS0_4_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGWQOS1_4 @ 0XFD070760</p>
Specifies the timeout value for write transactions.
PSU_DDRC_PCFGWQOS1_4_WQOS_MAP_TIMEOUT 0x4f
Port n Write QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070760, 0x000007FFU ,0x0000004FU)
RegMask = (DDRC_PCFGWQOS1_4_WQOS_MAP_TIMEOUT_MASK | 0 );
RegVal = ((0x0000004FU << DDRC_PCFGWQOS1_4_WQOS_MAP_TIMEOUT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS1_4_OFFSET ,0x000007FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : PCFGR_5 @ 0XFD070774</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGR_5_RD_PORT_PAGEMATCH_EN 0x0
If set to 1, enables the AXI urgent sideband signal (arurgent). When enabled and arurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_lpr/co_gs_go2critical_hpr signal to DDRC is asserted if enabled in PCCFG.
o2critical_en register. Note that arurgent signal can be asserted anytime and as long as required which is independent of add
ess handshaking (it is not associated with any particular command).
PSU_DDRC_PCFGR_5_RD_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the read channel of the port.
PSU_DDRC_PCFGR_5_RD_PORT_AGING_EN 0x0
Determines the initial load value of read aging counters. These counters will be parallel loaded after reset, or after each g
ant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
he higher significant 5-bits of the read aging counter sets the priority of the read channel of a given port. Port's priority
will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0, the corre
ponding port channel will have the highest priority level (timeout condition - Priority0). For multi-port configurations, the
aging counters cannot be used to set port priorities when external dynamic priority inputs (arqos) are enabled (timeout is st
ll applicable). For single port configurations, the aging counters are only used when they timeout (become 0) to force read-w
ite direction switching. In this case, external dynamic priority input, arqos (for reads only) can still be used to set the D
RC read priority (2 priority levels: low priority read - LPR, high priority read - HPR) on a command by command basis. Note:
he two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGR_5_RD_PORT_PRIORITY 0xf
Port n Configuration Read Register
(OFFSET, MASK, VALUE) (0XFD070774, 0x000073FFU ,0x0000200FU)
RegMask = (DDRC_PCFGR_5_RD_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGR_5_RD_PORT_URGENT_EN_MASK | DDRC_PCFGR_5_RD_PORT_AGING_EN_MASK | DDRC_PCFGR_5_RD_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGR_5_RD_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGR_5_RD_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGR_5_RD_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGR_5_RD_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGR_5_OFFSET ,0x000073FFU ,0x0000200FU);
/*############################################################################################################################ */
/*Register : PCFGW_5 @ 0XFD070778</p>
If set to 1, enables the Page Match feature. If enabled, once a requesting port is granted, the port is continued to be grant
d if the following immediate commands are to the same memory page (same bank and same row). See also related PCCFG.pagematch_
imit register.
PSU_DDRC_PCFGW_5_WR_PORT_PAGEMATCH_EN 0x1
If set to 1, enables the AXI urgent sideband signal (awurgent). When enabled and awurgent is asserted by the master, that por
becomes the highest priority and co_gs_go2critical_wr signal to DDRC is asserted if enabled in PCCFG.go2critical_en register
Note that awurgent signal can be asserted anytime and as long as required which is independent of address handshaking (it is
not associated with any particular command).
PSU_DDRC_PCFGW_5_WR_PORT_URGENT_EN 0x1
If set to 1, enables aging function for the write channel of the port.
PSU_DDRC_PCFGW_5_WR_PORT_AGING_EN 0x0
Determines the initial load value of write aging counters. These counters will be parallel loaded after reset, or after each
rant to the corresponding port. The aging counters down-count every clock cycle where the port is requesting but not granted.
The higher significant 5-bits of the write aging counter sets the initial priority of the write channel of a given port. Port
s priority will increase as the higher significant 5-bits of the counter starts to decrease. When the aging counter becomes 0
the corresponding port channel will have the highest priority level. For multi-port configurations, the aging counters canno
be used to set port priorities when external dynamic priority inputs (awqos) are enabled (timeout is still applicable). For
ingle port configurations, the aging counters are only used when they timeout (become 0) to force read-write direction switch
ng. Note: The two LSBs of this register field are tied internally to 2'b00.
PSU_DDRC_PCFGW_5_WR_PORT_PRIORITY 0xf
Port n Configuration Write Register
(OFFSET, MASK, VALUE) (0XFD070778, 0x000073FFU ,0x0000600FU)
RegMask = (DDRC_PCFGW_5_WR_PORT_PAGEMATCH_EN_MASK | DDRC_PCFGW_5_WR_PORT_URGENT_EN_MASK | DDRC_PCFGW_5_WR_PORT_AGING_EN_MASK | DDRC_PCFGW_5_WR_PORT_PRIORITY_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGW_5_WR_PORT_PAGEMATCH_EN_SHIFT
| 0x00000001U << DDRC_PCFGW_5_WR_PORT_URGENT_EN_SHIFT
| 0x00000000U << DDRC_PCFGW_5_WR_PORT_AGING_EN_SHIFT
| 0x0000000FU << DDRC_PCFGW_5_WR_PORT_PRIORITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGW_5_OFFSET ,0x000073FFU ,0x0000600FU);
/*############################################################################################################################ */
/*Register : PCTRL_5 @ 0XFD070800</p>
Enables port n.
PSU_DDRC_PCTRL_5_PORT_EN 0x1
Port n Control Register
(OFFSET, MASK, VALUE) (0XFD070800, 0x00000001U ,0x00000001U)
RegMask = (DDRC_PCTRL_5_PORT_EN_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCTRL_5_PORT_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCTRL_5_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : PCFGQOS0_5 @ 0XFD070804</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0 : LPR, 1: VPR, 2: HPR. For dual address queue conf
gurations, region1 maps to the blue address queue. In this case, valid values are 0: LPR and 1: VPR only. When VPR support is
disabled (UMCTL2_VPR_EN = 0) and traffic class of region 1 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_5_RQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: LPR, 1: VPR, 2: HPR. For dual address queue confi
urations, region 0 maps to the blue address queue. In this case, valid values are: 0: LPR and 1: VPR only. When VPR support i
disabled (UMCTL2_VPR_EN = 0) and traffic class of region0 is set to 1 (VPR), VPR traffic is aliased to LPR traffic.
PSU_DDRC_PCFGQOS0_5_RQOS_MAP_REGION0 0x0
Separation level1 indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 13 (for d
al RAQ) or 0 to 14 (for single RAQ) which corresponds to arqos. Note that for PA, arqos values are used directly as port prio
ities, where the higher the value corresponds to higher port priority. All of the map_level* registers must be set to distinc
values.
PSU_DDRC_PCFGQOS0_5_RQOS_MAP_LEVEL1 0x3
Port n Read QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD070804, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGQOS0_5_RQOS_MAP_REGION1_MASK | DDRC_PCFGQOS0_5_RQOS_MAP_REGION0_MASK | DDRC_PCFGQOS0_5_RQOS_MAP_LEVEL1_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGQOS0_5_RQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGQOS0_5_RQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGQOS0_5_RQOS_MAP_LEVEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS0_5_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGQOS1_5 @ 0XFD070808</p>
Specifies the timeout value for transactions mapped to the red address queue.
PSU_DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTR 0x0
Specifies the timeout value for transactions mapped to the blue address queue.
PSU_DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTB 0x4f
Port n Read QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070808, 0x07FF07FFU ,0x0000004FU)
RegMask = (DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTR_MASK | DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTB_MASK | 0 );
RegVal = ((0x00000000U << DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTR_SHIFT
| 0x0000004FU << DDRC_PCFGQOS1_5_RQOS_MAP_TIMEOUTB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGQOS1_5_OFFSET ,0x07FF07FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : PCFGWQOS0_5 @ 0XFD07080C</p>
This bitfield indicates the traffic class of region 1. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region 1 is set to 1 (VPW), VPW traffic is aliased to LPW traffic.
PSU_DDRC_PCFGWQOS0_5_WQOS_MAP_REGION1 0x1
This bitfield indicates the traffic class of region 0. Valid values are: 0: NPW, 1: VPW. When VPW support is disabled (UMCTL2
VPW_EN = 0) and traffic class of region0 is set to 1 (VPW), VPW traffic is aliased to NPW traffic.
PSU_DDRC_PCFGWQOS0_5_WQOS_MAP_REGION0 0x0
Separation level indicating the end of region0 mapping; start of region0 is 0. Possible values for level1 are 0 to 14 which c
rresponds to awqos. Note that for PA, awqos values are used directly as port priorities, where the higher the value correspon
s to higher port priority.
PSU_DDRC_PCFGWQOS0_5_WQOS_MAP_LEVEL 0x3
Port n Write QoS Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD07080C, 0x0033000FU ,0x00100003U)
RegMask = (DDRC_PCFGWQOS0_5_WQOS_MAP_REGION1_MASK | DDRC_PCFGWQOS0_5_WQOS_MAP_REGION0_MASK | DDRC_PCFGWQOS0_5_WQOS_MAP_LEVEL_MASK | 0 );
RegVal = ((0x00000001U << DDRC_PCFGWQOS0_5_WQOS_MAP_REGION1_SHIFT
| 0x00000000U << DDRC_PCFGWQOS0_5_WQOS_MAP_REGION0_SHIFT
| 0x00000003U << DDRC_PCFGWQOS0_5_WQOS_MAP_LEVEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS0_5_OFFSET ,0x0033000FU ,0x00100003U);
/*############################################################################################################################ */
/*Register : PCFGWQOS1_5 @ 0XFD070810</p>
Specifies the timeout value for write transactions.
PSU_DDRC_PCFGWQOS1_5_WQOS_MAP_TIMEOUT 0x4f
Port n Write QoS Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD070810, 0x000007FFU ,0x0000004FU)
RegMask = (DDRC_PCFGWQOS1_5_WQOS_MAP_TIMEOUT_MASK | 0 );
RegVal = ((0x0000004FU << DDRC_PCFGWQOS1_5_WQOS_MAP_TIMEOUT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_PCFGWQOS1_5_OFFSET ,0x000007FFU ,0x0000004FU);
/*############################################################################################################################ */
/*Register : SARBASE0 @ 0XFD070F04</p>
Base address for address region n specified as awaddr[UMCTL2_A_ADDRW-1:x] and araddr[UMCTL2_A_ADDRW-1:x] where x is determine
by the minimum block size parameter UMCTL2_SARMINSIZE: (x=log2(block size)).
PSU_DDRC_SARBASE0_BASE_ADDR 0x0
SAR Base Address Register n
(OFFSET, MASK, VALUE) (0XFD070F04, 0x000001FFU ,0x00000000U)
RegMask = (DDRC_SARBASE0_BASE_ADDR_MASK | 0 );
RegVal = ((0x00000000U << DDRC_SARBASE0_BASE_ADDR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SARBASE0_OFFSET ,0x000001FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : SARSIZE0 @ 0XFD070F08</p>
Number of blocks for address region n. This register determines the total size of the region in multiples of minimum block si
e as specified by the hardware parameter UMCTL2_SARMINSIZE. The register value is encoded as number of blocks = nblocks + 1.
or example, if register is programmed to 0, region will have 1 block.
PSU_DDRC_SARSIZE0_NBLOCKS 0x0
SAR Size Register n
(OFFSET, MASK, VALUE) (0XFD070F08, 0x000000FFU ,0x00000000U)
RegMask = (DDRC_SARSIZE0_NBLOCKS_MASK | 0 );
RegVal = ((0x00000000U << DDRC_SARSIZE0_NBLOCKS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SARSIZE0_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : SARBASE1 @ 0XFD070F0C</p>
Base address for address region n specified as awaddr[UMCTL2_A_ADDRW-1:x] and araddr[UMCTL2_A_ADDRW-1:x] where x is determine
by the minimum block size parameter UMCTL2_SARMINSIZE: (x=log2(block size)).
PSU_DDRC_SARBASE1_BASE_ADDR 0x10
SAR Base Address Register n
(OFFSET, MASK, VALUE) (0XFD070F0C, 0x000001FFU ,0x00000010U)
RegMask = (DDRC_SARBASE1_BASE_ADDR_MASK | 0 );
RegVal = ((0x00000010U << DDRC_SARBASE1_BASE_ADDR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SARBASE1_OFFSET ,0x000001FFU ,0x00000010U);
/*############################################################################################################################ */
/*Register : SARSIZE1 @ 0XFD070F10</p>
Number of blocks for address region n. This register determines the total size of the region in multiples of minimum block si
e as specified by the hardware parameter UMCTL2_SARMINSIZE. The register value is encoded as number of blocks = nblocks + 1.
or example, if register is programmed to 0, region will have 1 block.
PSU_DDRC_SARSIZE1_NBLOCKS 0xf
SAR Size Register n
(OFFSET, MASK, VALUE) (0XFD070F10, 0x000000FFU ,0x0000000FU)
RegMask = (DDRC_SARSIZE1_NBLOCKS_MASK | 0 );
RegVal = ((0x0000000FU << DDRC_SARSIZE1_NBLOCKS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_SARSIZE1_OFFSET ,0x000000FFU ,0x0000000FU);
/*############################################################################################################################ */
/*Register : DFITMG0_SHADOW @ 0XFD072190</p>
Specifies the number of DFI clock cycles after an assertion or de-assertion of the DFI control signals that the control signa
s at the PHY-DRAM interface reflect the assertion or de-assertion. If the DFI clock and the memory clock are not phase-aligne
, this timing parameter should be rounded up to the next integer value. Note that if using RDIMM, it is necessary to incremen
this parameter by RDIMM's extra cycle of latency in terms of DFI clock.
PSU_DDRC_DFITMG0_SHADOW_DFI_T_CTRL_DELAY 0x7
Defines whether dfi_rddata_en/dfi_rddata/dfi_rddata_valid is generated using HDR or SDR values Selects whether value in DFITM
0.dfi_t_rddata_en is in terms of SDR or HDR clock cycles: - 0 in terms of HDR clock cycles - 1 in terms of SDR clock cycles R
fer to PHY specification for correct value.
PSU_DDRC_DFITMG0_SHADOW_DFI_RDDATA_USE_SDR 0x1
Time from the assertion of a read command on the DFI interface to the assertion of the dfi_rddata_en signal. Refer to PHY spe
ification for correct value. This corresponds to the DFI parameter trddata_en. Note that, depending on the PHY, if using RDIM
, it may be necessary to use the value (CL + 1) in the calculation of trddata_en. This is to compensate for the extra cycle o
latency through the RDIMM. Unit: Clocks
PSU_DDRC_DFITMG0_SHADOW_DFI_T_RDDATA_EN 0x2
Defines whether dfi_wrdata_en/dfi_wrdata/dfi_wrdata_mask is generated using HDR or SDR values Selects whether value in DFITMG
.dfi_tphy_wrlat is in terms of SDR or HDR clock cycles Selects whether value in DFITMG0.dfi_tphy_wrdata is in terms of SDR or
HDR clock cycles - 0 in terms of HDR clock cycles - 1 in terms of SDR clock cycles Refer to PHY specification for correct val
e.
PSU_DDRC_DFITMG0_SHADOW_DFI_WRDATA_USE_SDR 0x1
Specifies the number of clock cycles between when dfi_wrdata_en is asserted to when the associated write data is driven on th
dfi_wrdata signal. This corresponds to the DFI timing parameter tphy_wrdata. Refer to PHY specification for correct value. N
te, max supported value is 8. Unit: Clocks
PSU_DDRC_DFITMG0_SHADOW_DFI_TPHY_WRDATA 0x0
Write latency Number of clocks from the write command to write data enable (dfi_wrdata_en). This corresponds to the DFI timin
parameter tphy_wrlat. Refer to PHY specification for correct value.Note that, depending on the PHY, if using RDIMM, it may b
necessary to use the value (CL + 1) in the calculation of tphy_wrlat. This is to compensate for the extra cycle of latency t
rough the RDIMM.
PSU_DDRC_DFITMG0_SHADOW_DFI_TPHY_WRLAT 0x2
DFI Timing Shadow Register 0
(OFFSET, MASK, VALUE) (0XFD072190, 0x1FBFBF3FU ,0x07828002U)
RegMask = (DDRC_DFITMG0_SHADOW_DFI_T_CTRL_DELAY_MASK | DDRC_DFITMG0_SHADOW_DFI_RDDATA_USE_SDR_MASK | DDRC_DFITMG0_SHADOW_DFI_T_RDDATA_EN_MASK | DDRC_DFITMG0_SHADOW_DFI_WRDATA_USE_SDR_MASK | DDRC_DFITMG0_SHADOW_DFI_TPHY_WRDATA_MASK | DDRC_DFITMG0_SHADOW_DFI_TPHY_WRLAT_MASK | 0 );
RegVal = ((0x00000007U << DDRC_DFITMG0_SHADOW_DFI_T_CTRL_DELAY_SHIFT
| 0x00000001U << DDRC_DFITMG0_SHADOW_DFI_RDDATA_USE_SDR_SHIFT
| 0x00000002U << DDRC_DFITMG0_SHADOW_DFI_T_RDDATA_EN_SHIFT
| 0x00000001U << DDRC_DFITMG0_SHADOW_DFI_WRDATA_USE_SDR_SHIFT
| 0x00000000U << DDRC_DFITMG0_SHADOW_DFI_TPHY_WRDATA_SHIFT
| 0x00000002U << DDRC_DFITMG0_SHADOW_DFI_TPHY_WRLAT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDRC_DFITMG0_SHADOW_OFFSET ,0x1FBFBF3FU ,0x07828002U);
/*############################################################################################################################ */
// : DDR CONTROLLER RESET
/*Register : RST_DDR_SS @ 0XFD1A0108</p>
DDR block level reset inside of the DDR Sub System
PSU_CRF_APB_RST_DDR_SS_DDR_RESET 0X0
DDR sub system block level reset
(OFFSET, MASK, VALUE) (0XFD1A0108, 0x00000008U ,0x00000000U)
RegMask = (CRF_APB_RST_DDR_SS_DDR_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_RST_DDR_SS_DDR_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_DDR_SS_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
// : DDR PHY
/*Register : PGCR0 @ 0XFD080010</p>
Address Copy
PSU_DDR_PHY_PGCR0_ADCP 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_PGCR0_RESERVED_30_27 0x0
PHY FIFO Reset
PSU_DDR_PHY_PGCR0_PHYFRST 0x1
Oscillator Mode Address/Command Delay Line Select
PSU_DDR_PHY_PGCR0_OSCACDL 0x3
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_PGCR0_RESERVED_23_19 0x0
Digital Test Output Select
PSU_DDR_PHY_PGCR0_DTOSEL 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_PGCR0_RESERVED_13 0x0
Oscillator Mode Division
PSU_DDR_PHY_PGCR0_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_PGCR0_OSCEN 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_PGCR0_RESERVED_7_0 0x0
PHY General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080010, 0xFFFFFFFFU ,0x07001E00U)
RegMask = (DDR_PHY_PGCR0_ADCP_MASK | DDR_PHY_PGCR0_RESERVED_30_27_MASK | DDR_PHY_PGCR0_PHYFRST_MASK | DDR_PHY_PGCR0_OSCACDL_MASK | DDR_PHY_PGCR0_RESERVED_23_19_MASK | DDR_PHY_PGCR0_DTOSEL_MASK | DDR_PHY_PGCR0_RESERVED_13_MASK | DDR_PHY_PGCR0_OSCDIV_MASK | DDR_PHY_PGCR0_OSCEN_MASK | DDR_PHY_PGCR0_RESERVED_7_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_PGCR0_ADCP_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_RESERVED_30_27_SHIFT
| 0x00000001U << DDR_PHY_PGCR0_PHYFRST_SHIFT
| 0x00000003U << DDR_PHY_PGCR0_OSCACDL_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_RESERVED_23_19_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_DTOSEL_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_RESERVED_13_SHIFT
| 0x0000000FU << DDR_PHY_PGCR0_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_OSCEN_SHIFT
| 0x00000000U << DDR_PHY_PGCR0_RESERVED_7_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PGCR0_OFFSET ,0xFFFFFFFFU ,0x07001E00U);
/*############################################################################################################################ */
/*Register : PGCR2 @ 0XFD080018</p>
Clear Training Status Registers
PSU_DDR_PHY_PGCR2_CLRTSTAT 0x0
Clear Impedance Calibration
PSU_DDR_PHY_PGCR2_CLRZCAL 0x0
Clear Parity Error
PSU_DDR_PHY_PGCR2_CLRPERR 0x0
Initialization Complete Pin Configuration
PSU_DDR_PHY_PGCR2_ICPC 0x0
Data Training PUB Mode Exit Timer
PSU_DDR_PHY_PGCR2_DTPMXTMR 0xf
Initialization Bypass
PSU_DDR_PHY_PGCR2_INITFSMBYP 0x0
PLL FSM Bypass
PSU_DDR_PHY_PGCR2_PLLFSMBYP 0x0
Refresh Period
PSU_DDR_PHY_PGCR2_TREFPRD 0x10028
PHY General Configuration Register 2
(OFFSET, MASK, VALUE) (0XFD080018, 0xFFFFFFFFU ,0x00F10028U)
RegMask = (DDR_PHY_PGCR2_CLRTSTAT_MASK | DDR_PHY_PGCR2_CLRZCAL_MASK | DDR_PHY_PGCR2_CLRPERR_MASK | DDR_PHY_PGCR2_ICPC_MASK | DDR_PHY_PGCR2_DTPMXTMR_MASK | DDR_PHY_PGCR2_INITFSMBYP_MASK | DDR_PHY_PGCR2_PLLFSMBYP_MASK | DDR_PHY_PGCR2_TREFPRD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_PGCR2_CLRTSTAT_SHIFT
| 0x00000000U << DDR_PHY_PGCR2_CLRZCAL_SHIFT
| 0x00000000U << DDR_PHY_PGCR2_CLRPERR_SHIFT
| 0x00000000U << DDR_PHY_PGCR2_ICPC_SHIFT
| 0x0000000FU << DDR_PHY_PGCR2_DTPMXTMR_SHIFT
| 0x00000000U << DDR_PHY_PGCR2_INITFSMBYP_SHIFT
| 0x00000000U << DDR_PHY_PGCR2_PLLFSMBYP_SHIFT
| 0x00010028U << DDR_PHY_PGCR2_TREFPRD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PGCR2_OFFSET ,0xFFFFFFFFU ,0x00F10028U);
/*############################################################################################################################ */
/*Register : PGCR3 @ 0XFD08001C</p>
CKN Enable
PSU_DDR_PHY_PGCR3_CKNEN 0x55
CK Enable
PSU_DDR_PHY_PGCR3_CKEN 0xaa
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PGCR3_RESERVED_15 0x0
Enable Clock Gating for AC [0] ctl_rd_clk
PSU_DDR_PHY_PGCR3_GATEACRDCLK 0x2
Enable Clock Gating for AC [0] ddr_clk
PSU_DDR_PHY_PGCR3_GATEACDDRCLK 0x2
Enable Clock Gating for AC [0] ctl_clk
PSU_DDR_PHY_PGCR3_GATEACCTLCLK 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PGCR3_RESERVED_8 0x0
Controls DDL Bypass Modes
PSU_DDR_PHY_PGCR3_DDLBYPMODE 0x2
IO Loop-Back Select
PSU_DDR_PHY_PGCR3_IOLB 0x0
AC Receive FIFO Read Mode
PSU_DDR_PHY_PGCR3_RDMODE 0x0
Read FIFO Reset Disable
PSU_DDR_PHY_PGCR3_DISRST 0x0
Clock Level when Clock Gating
PSU_DDR_PHY_PGCR3_CLKLEVEL 0x0
PHY General Configuration Register 3
(OFFSET, MASK, VALUE) (0XFD08001C, 0xFFFFFFFFU ,0x55AA5480U)
RegMask = (DDR_PHY_PGCR3_CKNEN_MASK | DDR_PHY_PGCR3_CKEN_MASK | DDR_PHY_PGCR3_RESERVED_15_MASK | DDR_PHY_PGCR3_GATEACRDCLK_MASK | DDR_PHY_PGCR3_GATEACDDRCLK_MASK | DDR_PHY_PGCR3_GATEACCTLCLK_MASK | DDR_PHY_PGCR3_RESERVED_8_MASK | DDR_PHY_PGCR3_DDLBYPMODE_MASK | DDR_PHY_PGCR3_IOLB_MASK | DDR_PHY_PGCR3_RDMODE_MASK | DDR_PHY_PGCR3_DISRST_MASK | DDR_PHY_PGCR3_CLKLEVEL_MASK | 0 );
RegVal = ((0x00000055U << DDR_PHY_PGCR3_CKNEN_SHIFT
| 0x000000AAU << DDR_PHY_PGCR3_CKEN_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_RESERVED_15_SHIFT
| 0x00000002U << DDR_PHY_PGCR3_GATEACRDCLK_SHIFT
| 0x00000002U << DDR_PHY_PGCR3_GATEACDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_PGCR3_GATEACCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_RESERVED_8_SHIFT
| 0x00000002U << DDR_PHY_PGCR3_DDLBYPMODE_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_IOLB_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_DISRST_SHIFT
| 0x00000000U << DDR_PHY_PGCR3_CLKLEVEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PGCR3_OFFSET ,0xFFFFFFFFU ,0x55AA5480U);
/*############################################################################################################################ */
/*Register : PGCR5 @ 0XFD080024</p>
Frequency B Ratio Term
PSU_DDR_PHY_PGCR5_FRQBT 0x1
Frequency A Ratio Term
PSU_DDR_PHY_PGCR5_FRQAT 0x1
DFI Disconnect Time Period
PSU_DDR_PHY_PGCR5_DISCNPERIOD 0x0
Receiver bias core side control
PSU_DDR_PHY_PGCR5_VREF_RBCTRL 0xf
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PGCR5_RESERVED_3 0x0
Internal VREF generator REFSEL ragne select
PSU_DDR_PHY_PGCR5_DXREFISELRANGE 0x1
DDL Page Read Write select
PSU_DDR_PHY_PGCR5_DDLPGACT 0x0
DDL Page Read Write select
PSU_DDR_PHY_PGCR5_DDLPGRW 0x0
PHY General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080024, 0xFFFFFFFFU ,0x010100F4U)
RegMask = (DDR_PHY_PGCR5_FRQBT_MASK | DDR_PHY_PGCR5_FRQAT_MASK | DDR_PHY_PGCR5_DISCNPERIOD_MASK | DDR_PHY_PGCR5_VREF_RBCTRL_MASK | DDR_PHY_PGCR5_RESERVED_3_MASK | DDR_PHY_PGCR5_DXREFISELRANGE_MASK | DDR_PHY_PGCR5_DDLPGACT_MASK | DDR_PHY_PGCR5_DDLPGRW_MASK | 0 );
RegVal = ((0x00000001U << DDR_PHY_PGCR5_FRQBT_SHIFT
| 0x00000001U << DDR_PHY_PGCR5_FRQAT_SHIFT
| 0x00000000U << DDR_PHY_PGCR5_DISCNPERIOD_SHIFT
| 0x0000000FU << DDR_PHY_PGCR5_VREF_RBCTRL_SHIFT
| 0x00000000U << DDR_PHY_PGCR5_RESERVED_3_SHIFT
| 0x00000001U << DDR_PHY_PGCR5_DXREFISELRANGE_SHIFT
| 0x00000000U << DDR_PHY_PGCR5_DDLPGACT_SHIFT
| 0x00000000U << DDR_PHY_PGCR5_DDLPGRW_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PGCR5_OFFSET ,0xFFFFFFFFU ,0x010100F4U);
/*############################################################################################################################ */
/*Register : PTR0 @ 0XFD080040</p>
PLL Power-Down Time
PSU_DDR_PHY_PTR0_TPLLPD 0x2f0
PLL Gear Shift Time
PSU_DDR_PHY_PTR0_TPLLGS 0x60
PHY Reset Time
PSU_DDR_PHY_PTR0_TPHYRST 0x10
PHY Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080040, 0xFFFFFFFFU ,0x5E001810U)
RegMask = (DDR_PHY_PTR0_TPLLPD_MASK | DDR_PHY_PTR0_TPLLGS_MASK | DDR_PHY_PTR0_TPHYRST_MASK | 0 );
RegVal = ((0x000002F0U << DDR_PHY_PTR0_TPLLPD_SHIFT
| 0x00000060U << DDR_PHY_PTR0_TPLLGS_SHIFT
| 0x00000010U << DDR_PHY_PTR0_TPHYRST_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PTR0_OFFSET ,0xFFFFFFFFU ,0x5E001810U);
/*############################################################################################################################ */
/*Register : PTR1 @ 0XFD080044</p>
PLL Lock Time
PSU_DDR_PHY_PTR1_TPLLLOCK 0x80
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_PTR1_RESERVED_15_13 0x0
PLL Reset Time
PSU_DDR_PHY_PTR1_TPLLRST 0x5f0
PHY Timing Register 1
(OFFSET, MASK, VALUE) (0XFD080044, 0xFFFFFFFFU ,0x008005F0U)
RegMask = (DDR_PHY_PTR1_TPLLLOCK_MASK | DDR_PHY_PTR1_RESERVED_15_13_MASK | DDR_PHY_PTR1_TPLLRST_MASK | 0 );
RegVal = ((0x00000080U << DDR_PHY_PTR1_TPLLLOCK_SHIFT
| 0x00000000U << DDR_PHY_PTR1_RESERVED_15_13_SHIFT
| 0x000005F0U << DDR_PHY_PTR1_TPLLRST_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PTR1_OFFSET ,0xFFFFFFFFU ,0x008005F0U);
/*############################################################################################################################ */
/*Register : DSGCR @ 0XFD080090</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DSGCR_RESERVED_31_28 0x0
When RDBI enabled, this bit is used to select RDBI CL calculation, if it is 1b1, calculation will use RDBICL, otherwise use d
fault calculation.
PSU_DDR_PHY_DSGCR_RDBICLSEL 0x0
When RDBI enabled, if RDBICLSEL is asserted, RDBI CL adjust using this value.
PSU_DDR_PHY_DSGCR_RDBICL 0x2
PHY Impedance Update Enable
PSU_DDR_PHY_DSGCR_PHYZUEN 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DSGCR_RESERVED_22 0x0
SDRAM Reset Output Enable
PSU_DDR_PHY_DSGCR_RSTOE 0x1
Single Data Rate Mode
PSU_DDR_PHY_DSGCR_SDRMODE 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DSGCR_RESERVED_18 0x0
ATO Analog Test Enable
PSU_DDR_PHY_DSGCR_ATOAE 0x0
DTO Output Enable
PSU_DDR_PHY_DSGCR_DTOOE 0x0
DTO I/O Mode
PSU_DDR_PHY_DSGCR_DTOIOM 0x0
DTO Power Down Receiver
PSU_DDR_PHY_DSGCR_DTOPDR 0x1
Reserved. Return zeroes on reads
PSU_DDR_PHY_DSGCR_RESERVED_13 0x0
DTO On-Die Termination
PSU_DDR_PHY_DSGCR_DTOODT 0x0
PHY Update Acknowledge Delay
PSU_DDR_PHY_DSGCR_PUAD 0x4
Controller Update Acknowledge Enable
PSU_DDR_PHY_DSGCR_CUAEN 0x1
Reserved. Return zeroes on reads
PSU_DDR_PHY_DSGCR_RESERVED_4_3 0x0
Controller Impedance Update Enable
PSU_DDR_PHY_DSGCR_CTLZUEN 0x0
Reserved. Return zeroes on reads
PSU_DDR_PHY_DSGCR_RESERVED_1 0x0
PHY Update Request Enable
PSU_DDR_PHY_DSGCR_PUREN 0x1
DDR System General Configuration Register
(OFFSET, MASK, VALUE) (0XFD080090, 0xFFFFFFFFU ,0x02A04121U)
RegMask = (DDR_PHY_DSGCR_RESERVED_31_28_MASK | DDR_PHY_DSGCR_RDBICLSEL_MASK | DDR_PHY_DSGCR_RDBICL_MASK | DDR_PHY_DSGCR_PHYZUEN_MASK | DDR_PHY_DSGCR_RESERVED_22_MASK | DDR_PHY_DSGCR_RSTOE_MASK | DDR_PHY_DSGCR_SDRMODE_MASK | DDR_PHY_DSGCR_RESERVED_18_MASK | DDR_PHY_DSGCR_ATOAE_MASK | DDR_PHY_DSGCR_DTOOE_MASK | DDR_PHY_DSGCR_DTOIOM_MASK | DDR_PHY_DSGCR_DTOPDR_MASK | DDR_PHY_DSGCR_RESERVED_13_MASK | DDR_PHY_DSGCR_DTOODT_MASK | DDR_PHY_DSGCR_PUAD_MASK | DDR_PHY_DSGCR_CUAEN_MASK | DDR_PHY_DSGCR_RESERVED_4_3_MASK | DDR_PHY_DSGCR_CTLZUEN_MASK | DDR_PHY_DSGCR_RESERVED_1_MASK | DDR_PHY_DSGCR_PUREN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DSGCR_RESERVED_31_28_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RDBICLSEL_SHIFT
| 0x00000002U << DDR_PHY_DSGCR_RDBICL_SHIFT
| 0x00000001U << DDR_PHY_DSGCR_PHYZUEN_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RESERVED_22_SHIFT
| 0x00000001U << DDR_PHY_DSGCR_RSTOE_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_SDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RESERVED_18_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_ATOAE_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_DTOOE_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_DTOIOM_SHIFT
| 0x00000001U << DDR_PHY_DSGCR_DTOPDR_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RESERVED_13_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_DTOODT_SHIFT
| 0x00000004U << DDR_PHY_DSGCR_PUAD_SHIFT
| 0x00000001U << DDR_PHY_DSGCR_CUAEN_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RESERVED_4_3_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_CTLZUEN_SHIFT
| 0x00000000U << DDR_PHY_DSGCR_RESERVED_1_SHIFT
| 0x00000001U << DDR_PHY_DSGCR_PUREN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DSGCR_OFFSET ,0xFFFFFFFFU ,0x02A04121U);
/*############################################################################################################################ */
/*Register : DCR @ 0XFD080100</p>
DDR4 Gear Down Timing.
PSU_DDR_PHY_DCR_GEARDN 0x0
Un-used Bank Group
PSU_DDR_PHY_DCR_UBG 0x0
Un-buffered DIMM Address Mirroring
PSU_DDR_PHY_DCR_UDIMM 0x0
DDR 2T Timing
PSU_DDR_PHY_DCR_DDR2T 0x0
No Simultaneous Rank Access
PSU_DDR_PHY_DCR_NOSRA 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DCR_RESERVED_26_18 0x0
Byte Mask
PSU_DDR_PHY_DCR_BYTEMASK 0x1
DDR Type
PSU_DDR_PHY_DCR_DDRTYPE 0x0
Multi-Purpose Register (MPR) DQ (DDR3 Only)
PSU_DDR_PHY_DCR_MPRDQ 0x0
Primary DQ (DDR3 Only)
PSU_DDR_PHY_DCR_PDQ 0x0
DDR 8-Bank
PSU_DDR_PHY_DCR_DDR8BNK 0x1
DDR Mode
PSU_DDR_PHY_DCR_DDRMD 0x4
DRAM Configuration Register
(OFFSET, MASK, VALUE) (0XFD080100, 0xFFFFFFFFU ,0x0800040CU)
RegMask = (DDR_PHY_DCR_GEARDN_MASK | DDR_PHY_DCR_UBG_MASK | DDR_PHY_DCR_UDIMM_MASK | DDR_PHY_DCR_DDR2T_MASK | DDR_PHY_DCR_NOSRA_MASK | DDR_PHY_DCR_RESERVED_26_18_MASK | DDR_PHY_DCR_BYTEMASK_MASK | DDR_PHY_DCR_DDRTYPE_MASK | DDR_PHY_DCR_MPRDQ_MASK | DDR_PHY_DCR_PDQ_MASK | DDR_PHY_DCR_DDR8BNK_MASK | DDR_PHY_DCR_DDRMD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DCR_GEARDN_SHIFT
| 0x00000000U << DDR_PHY_DCR_UBG_SHIFT
| 0x00000000U << DDR_PHY_DCR_UDIMM_SHIFT
| 0x00000000U << DDR_PHY_DCR_DDR2T_SHIFT
| 0x00000001U << DDR_PHY_DCR_NOSRA_SHIFT
| 0x00000000U << DDR_PHY_DCR_RESERVED_26_18_SHIFT
| 0x00000001U << DDR_PHY_DCR_BYTEMASK_SHIFT
| 0x00000000U << DDR_PHY_DCR_DDRTYPE_SHIFT
| 0x00000000U << DDR_PHY_DCR_MPRDQ_SHIFT
| 0x00000000U << DDR_PHY_DCR_PDQ_SHIFT
| 0x00000001U << DDR_PHY_DCR_DDR8BNK_SHIFT
| 0x00000004U << DDR_PHY_DCR_DDRMD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DCR_OFFSET ,0xFFFFFFFFU ,0x0800040CU);
/*############################################################################################################################ */
/*Register : DTPR0 @ 0XFD080110</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR0_RESERVED_31_29 0x0
Activate to activate command delay (different banks)
PSU_DDR_PHY_DTPR0_TRRD 0x6
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR0_RESERVED_23 0x0
Activate to precharge command delay
PSU_DDR_PHY_DTPR0_TRAS 0x24
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR0_RESERVED_15 0x0
Precharge command period
PSU_DDR_PHY_DTPR0_TRP 0xf
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR0_RESERVED_7_5 0x0
Internal read to precharge command delay
PSU_DDR_PHY_DTPR0_TRTP 0x9
DRAM Timing Parameters Register 0
(OFFSET, MASK, VALUE) (0XFD080110, 0xFFFFFFFFU ,0x06240F09U)
RegMask = (DDR_PHY_DTPR0_RESERVED_31_29_MASK | DDR_PHY_DTPR0_TRRD_MASK | DDR_PHY_DTPR0_RESERVED_23_MASK | DDR_PHY_DTPR0_TRAS_MASK | DDR_PHY_DTPR0_RESERVED_15_MASK | DDR_PHY_DTPR0_TRP_MASK | DDR_PHY_DTPR0_RESERVED_7_5_MASK | DDR_PHY_DTPR0_TRTP_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR0_RESERVED_31_29_SHIFT
| 0x00000006U << DDR_PHY_DTPR0_TRRD_SHIFT
| 0x00000000U << DDR_PHY_DTPR0_RESERVED_23_SHIFT
| 0x00000024U << DDR_PHY_DTPR0_TRAS_SHIFT
| 0x00000000U << DDR_PHY_DTPR0_RESERVED_15_SHIFT
| 0x0000000FU << DDR_PHY_DTPR0_TRP_SHIFT
| 0x00000000U << DDR_PHY_DTPR0_RESERVED_7_5_SHIFT
| 0x00000009U << DDR_PHY_DTPR0_TRTP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR0_OFFSET ,0xFFFFFFFFU ,0x06240F09U);
/*############################################################################################################################ */
/*Register : DTPR1 @ 0XFD080114</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR1_RESERVED_31 0x0
Minimum delay from when write leveling mode is programmed to the first DQS/DQS# rising edge.
PSU_DDR_PHY_DTPR1_TWLMRD 0x28
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR1_RESERVED_23 0x0
4-bank activate period
PSU_DDR_PHY_DTPR1_TFAW 0x22
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR1_RESERVED_15_11 0x0
Load mode update delay (DDR4 and DDR3 only)
PSU_DDR_PHY_DTPR1_TMOD 0x7
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR1_RESERVED_7_5 0x0
Load mode cycle time
PSU_DDR_PHY_DTPR1_TMRD 0x8
DRAM Timing Parameters Register 1
(OFFSET, MASK, VALUE) (0XFD080114, 0xFFFFFFFFU ,0x28220708U)
RegMask = (DDR_PHY_DTPR1_RESERVED_31_MASK | DDR_PHY_DTPR1_TWLMRD_MASK | DDR_PHY_DTPR1_RESERVED_23_MASK | DDR_PHY_DTPR1_TFAW_MASK | DDR_PHY_DTPR1_RESERVED_15_11_MASK | DDR_PHY_DTPR1_TMOD_MASK | DDR_PHY_DTPR1_RESERVED_7_5_MASK | DDR_PHY_DTPR1_TMRD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR1_RESERVED_31_SHIFT
| 0x00000028U << DDR_PHY_DTPR1_TWLMRD_SHIFT
| 0x00000000U << DDR_PHY_DTPR1_RESERVED_23_SHIFT
| 0x00000022U << DDR_PHY_DTPR1_TFAW_SHIFT
| 0x00000000U << DDR_PHY_DTPR1_RESERVED_15_11_SHIFT
| 0x00000007U << DDR_PHY_DTPR1_TMOD_SHIFT
| 0x00000000U << DDR_PHY_DTPR1_RESERVED_7_5_SHIFT
| 0x00000008U << DDR_PHY_DTPR1_TMRD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR1_OFFSET ,0xFFFFFFFFU ,0x28220708U);
/*############################################################################################################################ */
/*Register : DTPR2 @ 0XFD080118</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR2_RESERVED_31_29 0x0
Read to Write command delay. Valid values are
PSU_DDR_PHY_DTPR2_TRTW 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR2_RESERVED_27_25 0x0
Read to ODT delay (DDR3 only)
PSU_DDR_PHY_DTPR2_TRTODT 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR2_RESERVED_23_20 0x0
CKE minimum pulse width
PSU_DDR_PHY_DTPR2_TCKE 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR2_RESERVED_15_10 0x0
Self refresh exit delay
PSU_DDR_PHY_DTPR2_TXS 0x200
DRAM Timing Parameters Register 2
(OFFSET, MASK, VALUE) (0XFD080118, 0xFFFFFFFFU ,0x00080200U)
RegMask = (DDR_PHY_DTPR2_RESERVED_31_29_MASK | DDR_PHY_DTPR2_TRTW_MASK | DDR_PHY_DTPR2_RESERVED_27_25_MASK | DDR_PHY_DTPR2_TRTODT_MASK | DDR_PHY_DTPR2_RESERVED_23_20_MASK | DDR_PHY_DTPR2_TCKE_MASK | DDR_PHY_DTPR2_RESERVED_15_10_MASK | DDR_PHY_DTPR2_TXS_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR2_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DTPR2_TRTW_SHIFT
| 0x00000000U << DDR_PHY_DTPR2_RESERVED_27_25_SHIFT
| 0x00000000U << DDR_PHY_DTPR2_TRTODT_SHIFT
| 0x00000000U << DDR_PHY_DTPR2_RESERVED_23_20_SHIFT
| 0x00000008U << DDR_PHY_DTPR2_TCKE_SHIFT
| 0x00000000U << DDR_PHY_DTPR2_RESERVED_15_10_SHIFT
| 0x00000200U << DDR_PHY_DTPR2_TXS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR2_OFFSET ,0xFFFFFFFFU ,0x00080200U);
/*############################################################################################################################ */
/*Register : DTPR3 @ 0XFD08011C</p>
ODT turn-off delay extension
PSU_DDR_PHY_DTPR3_TOFDX 0x4
Read to read and write to write command delay
PSU_DDR_PHY_DTPR3_TCCD 0x0
DLL locking time
PSU_DDR_PHY_DTPR3_TDLLK 0x300
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR3_RESERVED_15_12 0x0
Maximum DQS output access time from CK/CK# (LPDDR2/3 only)
PSU_DDR_PHY_DTPR3_TDQSCKMAX 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR3_RESERVED_7_3 0x0
DQS output access time from CK/CK# (LPDDR2/3 only)
PSU_DDR_PHY_DTPR3_TDQSCK 0x0
DRAM Timing Parameters Register 3
(OFFSET, MASK, VALUE) (0XFD08011C, 0xFFFFFFFFU ,0x83000800U)
RegMask = (DDR_PHY_DTPR3_TOFDX_MASK | DDR_PHY_DTPR3_TCCD_MASK | DDR_PHY_DTPR3_TDLLK_MASK | DDR_PHY_DTPR3_RESERVED_15_12_MASK | DDR_PHY_DTPR3_TDQSCKMAX_MASK | DDR_PHY_DTPR3_RESERVED_7_3_MASK | DDR_PHY_DTPR3_TDQSCK_MASK | 0 );
RegVal = ((0x00000004U << DDR_PHY_DTPR3_TOFDX_SHIFT
| 0x00000000U << DDR_PHY_DTPR3_TCCD_SHIFT
| 0x00000300U << DDR_PHY_DTPR3_TDLLK_SHIFT
| 0x00000000U << DDR_PHY_DTPR3_RESERVED_15_12_SHIFT
| 0x00000008U << DDR_PHY_DTPR3_TDQSCKMAX_SHIFT
| 0x00000000U << DDR_PHY_DTPR3_RESERVED_7_3_SHIFT
| 0x00000000U << DDR_PHY_DTPR3_TDQSCK_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR3_OFFSET ,0xFFFFFFFFU ,0x83000800U);
/*############################################################################################################################ */
/*Register : DTPR4 @ 0XFD080120</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR4_RESERVED_31_30 0x0
ODT turn-on/turn-off delays (DDR2 only)
PSU_DDR_PHY_DTPR4_TAOND_TAOFD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR4_RESERVED_27_26 0x0
Refresh-to-Refresh
PSU_DDR_PHY_DTPR4_TRFC 0x116
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR4_RESERVED_15_14 0x0
Write leveling output delay
PSU_DDR_PHY_DTPR4_TWLO 0x2b
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR4_RESERVED_7_5 0x0
Power down exit delay
PSU_DDR_PHY_DTPR4_TXP 0x8
DRAM Timing Parameters Register 4
(OFFSET, MASK, VALUE) (0XFD080120, 0xFFFFFFFFU ,0x01162B08U)
RegMask = (DDR_PHY_DTPR4_RESERVED_31_30_MASK | DDR_PHY_DTPR4_TAOND_TAOFD_MASK | DDR_PHY_DTPR4_RESERVED_27_26_MASK | DDR_PHY_DTPR4_TRFC_MASK | DDR_PHY_DTPR4_RESERVED_15_14_MASK | DDR_PHY_DTPR4_TWLO_MASK | DDR_PHY_DTPR4_RESERVED_7_5_MASK | DDR_PHY_DTPR4_TXP_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR4_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_DTPR4_TAOND_TAOFD_SHIFT
| 0x00000000U << DDR_PHY_DTPR4_RESERVED_27_26_SHIFT
| 0x00000116U << DDR_PHY_DTPR4_TRFC_SHIFT
| 0x00000000U << DDR_PHY_DTPR4_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DTPR4_TWLO_SHIFT
| 0x00000000U << DDR_PHY_DTPR4_RESERVED_7_5_SHIFT
| 0x00000008U << DDR_PHY_DTPR4_TXP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR4_OFFSET ,0xFFFFFFFFU ,0x01162B08U);
/*############################################################################################################################ */
/*Register : DTPR5 @ 0XFD080124</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR5_RESERVED_31_24 0x0
Activate to activate command delay (same bank)
PSU_DDR_PHY_DTPR5_TRC 0x34
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR5_RESERVED_15 0x0
Activate to read or write delay
PSU_DDR_PHY_DTPR5_TRCD 0xf
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR5_RESERVED_7_5 0x0
Internal write to read command delay
PSU_DDR_PHY_DTPR5_TWTR 0x9
DRAM Timing Parameters Register 5
(OFFSET, MASK, VALUE) (0XFD080124, 0xFFFFFFFFU ,0x00340F09U)
RegMask = (DDR_PHY_DTPR5_RESERVED_31_24_MASK | DDR_PHY_DTPR5_TRC_MASK | DDR_PHY_DTPR5_RESERVED_15_MASK | DDR_PHY_DTPR5_TRCD_MASK | DDR_PHY_DTPR5_RESERVED_7_5_MASK | DDR_PHY_DTPR5_TWTR_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR5_RESERVED_31_24_SHIFT
| 0x00000034U << DDR_PHY_DTPR5_TRC_SHIFT
| 0x00000000U << DDR_PHY_DTPR5_RESERVED_15_SHIFT
| 0x0000000FU << DDR_PHY_DTPR5_TRCD_SHIFT
| 0x00000000U << DDR_PHY_DTPR5_RESERVED_7_5_SHIFT
| 0x00000009U << DDR_PHY_DTPR5_TWTR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR5_OFFSET ,0xFFFFFFFFU ,0x00340F09U);
/*############################################################################################################################ */
/*Register : DTPR6 @ 0XFD080128</p>
PUB Write Latency Enable
PSU_DDR_PHY_DTPR6_PUBWLEN 0x0
PUB Read Latency Enable
PSU_DDR_PHY_DTPR6_PUBRLEN 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR6_RESERVED_29_14 0x0
Write Latency
PSU_DDR_PHY_DTPR6_PUBWL 0xe
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTPR6_RESERVED_7_6 0x0
Read Latency
PSU_DDR_PHY_DTPR6_PUBRL 0xf
DRAM Timing Parameters Register 6
(OFFSET, MASK, VALUE) (0XFD080128, 0xFFFFFFFFU ,0x00000E0FU)
RegMask = (DDR_PHY_DTPR6_PUBWLEN_MASK | DDR_PHY_DTPR6_PUBRLEN_MASK | DDR_PHY_DTPR6_RESERVED_29_14_MASK | DDR_PHY_DTPR6_PUBWL_MASK | DDR_PHY_DTPR6_RESERVED_7_6_MASK | DDR_PHY_DTPR6_PUBRL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTPR6_PUBWLEN_SHIFT
| 0x00000000U << DDR_PHY_DTPR6_PUBRLEN_SHIFT
| 0x00000000U << DDR_PHY_DTPR6_RESERVED_29_14_SHIFT
| 0x0000000EU << DDR_PHY_DTPR6_PUBWL_SHIFT
| 0x00000000U << DDR_PHY_DTPR6_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DTPR6_PUBRL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTPR6_OFFSET ,0xFFFFFFFFU ,0x00000E0FU);
/*############################################################################################################################ */
/*Register : RDIMMGCR0 @ 0XFD080140</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_31 0x0
RDMIMM Quad CS Enable
PSU_DDR_PHY_RDIMMGCR0_QCSEN 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_29_28 0x0
RDIMM Outputs I/O Mode
PSU_DDR_PHY_RDIMMGCR0_RDIMMIOM 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_26_24 0x0
ERROUT# Output Enable
PSU_DDR_PHY_RDIMMGCR0_ERROUTOE 0x0
ERROUT# I/O Mode
PSU_DDR_PHY_RDIMMGCR0_ERROUTIOM 0x1
ERROUT# Power Down Receiver
PSU_DDR_PHY_RDIMMGCR0_ERROUTPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_20 0x0
ERROUT# On-Die Termination
PSU_DDR_PHY_RDIMMGCR0_ERROUTODT 0x0
Load Reduced DIMM
PSU_DDR_PHY_RDIMMGCR0_LRDIMM 0x0
PAR_IN I/O Mode
PSU_DDR_PHY_RDIMMGCR0_PARINIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_16_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RNKMRREN_RSVD 0x0
Rank Mirror Enable.
PSU_DDR_PHY_RDIMMGCR0_RNKMRREN 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR0_RESERVED_3 0x0
Stop on Parity Error
PSU_DDR_PHY_RDIMMGCR0_SOPERR 0x0
Parity Error No Registering
PSU_DDR_PHY_RDIMMGCR0_ERRNOREG 0x0
Registered DIMM
PSU_DDR_PHY_RDIMMGCR0_RDIMM 0x0
RDIMM General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080140, 0xFFFFFFFFU ,0x08400020U)
RegMask = (DDR_PHY_RDIMMGCR0_RESERVED_31_MASK | DDR_PHY_RDIMMGCR0_QCSEN_MASK | DDR_PHY_RDIMMGCR0_RESERVED_29_28_MASK | DDR_PHY_RDIMMGCR0_RDIMMIOM_MASK | DDR_PHY_RDIMMGCR0_RESERVED_26_24_MASK | DDR_PHY_RDIMMGCR0_ERROUTOE_MASK | DDR_PHY_RDIMMGCR0_ERROUTIOM_MASK | DDR_PHY_RDIMMGCR0_ERROUTPDR_MASK | DDR_PHY_RDIMMGCR0_RESERVED_20_MASK | DDR_PHY_RDIMMGCR0_ERROUTODT_MASK | DDR_PHY_RDIMMGCR0_LRDIMM_MASK | DDR_PHY_RDIMMGCR0_PARINIOM_MASK | DDR_PHY_RDIMMGCR0_RESERVED_16_8_MASK | DDR_PHY_RDIMMGCR0_RNKMRREN_RSVD_MASK | DDR_PHY_RDIMMGCR0_RNKMRREN_MASK | DDR_PHY_RDIMMGCR0_RESERVED_3_MASK | DDR_PHY_RDIMMGCR0_SOPERR_MASK | DDR_PHY_RDIMMGCR0_ERRNOREG_MASK | DDR_PHY_RDIMMGCR0_RDIMM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_31_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_QCSEN_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_29_28_SHIFT
| 0x00000001U << DDR_PHY_RDIMMGCR0_RDIMMIOM_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_26_24_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_ERROUTOE_SHIFT
| 0x00000001U << DDR_PHY_RDIMMGCR0_ERROUTIOM_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_ERROUTPDR_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_20_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_ERROUTODT_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_LRDIMM_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_PARINIOM_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_16_8_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RNKMRREN_RSVD_SHIFT
| 0x00000002U << DDR_PHY_RDIMMGCR0_RNKMRREN_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RESERVED_3_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_SOPERR_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_ERRNOREG_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR0_RDIMM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_RDIMMGCR0_OFFSET ,0xFFFFFFFFU ,0x08400020U);
/*############################################################################################################################ */
/*Register : RDIMMGCR1 @ 0XFD080144</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR1_RESERVED_31_29 0x0
Address [17] B-side Inversion Disable
PSU_DDR_PHY_RDIMMGCR1_A17BID 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR1_RESERVED_27 0x0
Command word to command word programming delay
PSU_DDR_PHY_RDIMMGCR1_TBCMRD_L2 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR1_RESERVED_23 0x0
Command word to command word programming delay
PSU_DDR_PHY_RDIMMGCR1_TBCMRD_L 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR1_RESERVED_19 0x0
Command word to command word programming delay
PSU_DDR_PHY_RDIMMGCR1_TBCMRD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RDIMMGCR1_RESERVED_15_14 0x0
Stabilization time
PSU_DDR_PHY_RDIMMGCR1_TBCSTAB 0xc80
RDIMM General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080144, 0xFFFFFFFFU ,0x00000C80U)
RegMask = (DDR_PHY_RDIMMGCR1_RESERVED_31_29_MASK | DDR_PHY_RDIMMGCR1_A17BID_MASK | DDR_PHY_RDIMMGCR1_RESERVED_27_MASK | DDR_PHY_RDIMMGCR1_TBCMRD_L2_MASK | DDR_PHY_RDIMMGCR1_RESERVED_23_MASK | DDR_PHY_RDIMMGCR1_TBCMRD_L_MASK | DDR_PHY_RDIMMGCR1_RESERVED_19_MASK | DDR_PHY_RDIMMGCR1_TBCMRD_MASK | DDR_PHY_RDIMMGCR1_RESERVED_15_14_MASK | DDR_PHY_RDIMMGCR1_TBCSTAB_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_RDIMMGCR1_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_A17BID_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_RESERVED_27_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_TBCMRD_L2_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_RESERVED_23_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_TBCMRD_L_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_RESERVED_19_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_TBCMRD_SHIFT
| 0x00000000U << DDR_PHY_RDIMMGCR1_RESERVED_15_14_SHIFT
| 0x00000C80U << DDR_PHY_RDIMMGCR1_TBCSTAB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_RDIMMGCR1_OFFSET ,0xFFFFFFFFU ,0x00000C80U);
/*############################################################################################################################ */
/*Register : RDIMMCR0 @ 0XFD080150</p>
DDR4/DDR3 Control Word 7
PSU_DDR_PHY_RDIMMCR0_RC7 0x0
DDR4 Control Word 6 (Comman space Control Word) / DDR3 Reserved
PSU_DDR_PHY_RDIMMCR0_RC6 0x0
DDR4/DDR3 Control Word 5 (CK Driver Characteristics Control Word)
PSU_DDR_PHY_RDIMMCR0_RC5 0x0
DDR4 Control Word 4 (ODT and CKE Signals Driver Characteristics Control Word) / DDR3 Control Word 4 (Control Signals Driver C
aracteristics Control Word)
PSU_DDR_PHY_RDIMMCR0_RC4 0x0
DDR4 Control Word 3 (CA and CS Signals Driver Characteristics Control Word) / DDR3 Control Word 3 (Command/Address Signals Dr
ver Characteristrics Control Word)
PSU_DDR_PHY_RDIMMCR0_RC3 0x0
DDR4 Control Word 2 (Timing and IBT Control Word) / DDR3 Control Word 2 (Timing Control Word)
PSU_DDR_PHY_RDIMMCR0_RC2 0x0
DDR4/DDR3 Control Word 1 (Clock Driver Enable Control Word)
PSU_DDR_PHY_RDIMMCR0_RC1 0x0
DDR4/DDR3 Control Word 0 (Global Features Control Word)
PSU_DDR_PHY_RDIMMCR0_RC0 0x0
RDIMM Control Register 0
(OFFSET, MASK, VALUE) (0XFD080150, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_RDIMMCR0_RC7_MASK | DDR_PHY_RDIMMCR0_RC6_MASK | DDR_PHY_RDIMMCR0_RC5_MASK | DDR_PHY_RDIMMCR0_RC4_MASK | DDR_PHY_RDIMMCR0_RC3_MASK | DDR_PHY_RDIMMCR0_RC2_MASK | DDR_PHY_RDIMMCR0_RC1_MASK | DDR_PHY_RDIMMCR0_RC0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_RDIMMCR0_RC7_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC6_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC5_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC4_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC3_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC2_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC1_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR0_RC0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_RDIMMCR0_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : RDIMMCR1 @ 0XFD080154</p>
Control Word 15
PSU_DDR_PHY_RDIMMCR1_RC15 0x0
DDR4 Control Word 14 (Parity Control Word) / DDR3 Reserved
PSU_DDR_PHY_RDIMMCR1_RC14 0x0
DDR4 Control Word 13 (DIMM Configuration Control Word) / DDR3 Reserved
PSU_DDR_PHY_RDIMMCR1_RC13 0x0
DDR4 Control Word 12 (Training Control Word) / DDR3 Reserved
PSU_DDR_PHY_RDIMMCR1_RC12 0x0
DDR4 Control Word 11 (Operating Voltage VDD and VREFCA Source Control Word) / DDR3 Control Word 11 (Operation Voltage VDD Con
rol Word)
PSU_DDR_PHY_RDIMMCR1_RC11 0x0
DDR4/DDR3 Control Word 10 (RDIMM Operating Speed Control Word)
PSU_DDR_PHY_RDIMMCR1_RC10 0x2
DDR4/DDR3 Control Word 9 (Power Saving Settings Control Word)
PSU_DDR_PHY_RDIMMCR1_RC9 0x0
DDR4 Control Word 8 (Input/Output Configuration Control Word) / DDR3 Control Word 8 (Additional Input Bus Termination Setting
Control Word)
PSU_DDR_PHY_RDIMMCR1_RC8 0x0
RDIMM Control Register 1
(OFFSET, MASK, VALUE) (0XFD080154, 0xFFFFFFFFU ,0x00000200U)
RegMask = (DDR_PHY_RDIMMCR1_RC15_MASK | DDR_PHY_RDIMMCR1_RC14_MASK | DDR_PHY_RDIMMCR1_RC13_MASK | DDR_PHY_RDIMMCR1_RC12_MASK | DDR_PHY_RDIMMCR1_RC11_MASK | DDR_PHY_RDIMMCR1_RC10_MASK | DDR_PHY_RDIMMCR1_RC9_MASK | DDR_PHY_RDIMMCR1_RC8_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_RDIMMCR1_RC15_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC14_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC13_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC12_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC11_SHIFT
| 0x00000002U << DDR_PHY_RDIMMCR1_RC10_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC9_SHIFT
| 0x00000000U << DDR_PHY_RDIMMCR1_RC8_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_RDIMMCR1_OFFSET ,0xFFFFFFFFU ,0x00000200U);
/*############################################################################################################################ */
/*Register : MR0 @ 0XFD080180</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR0_RESERVED_31_8 0x8
CA Terminating Rank
PSU_DDR_PHY_MR0_CATR 0x0
Reserved. These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR0_RSVD_6_5 0x1
Built-in Self-Test for RZQ
PSU_DDR_PHY_MR0_RZQI 0x2
Reserved. These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR0_RSVD_2_0 0x0
LPDDR4 Mode Register 0
(OFFSET, MASK, VALUE) (0XFD080180, 0xFFFFFFFFU ,0x00000830U)
RegMask = (DDR_PHY_MR0_RESERVED_31_8_MASK | DDR_PHY_MR0_CATR_MASK | DDR_PHY_MR0_RSVD_6_5_MASK | DDR_PHY_MR0_RZQI_MASK | DDR_PHY_MR0_RSVD_2_0_MASK | 0 );
RegVal = ((0x00000008U << DDR_PHY_MR0_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR0_CATR_SHIFT
| 0x00000001U << DDR_PHY_MR0_RSVD_6_5_SHIFT
| 0x00000002U << DDR_PHY_MR0_RZQI_SHIFT
| 0x00000000U << DDR_PHY_MR0_RSVD_2_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR0_OFFSET ,0xFFFFFFFFU ,0x00000830U);
/*############################################################################################################################ */
/*Register : MR1 @ 0XFD080184</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR1_RESERVED_31_8 0x3
Read Postamble Length
PSU_DDR_PHY_MR1_RDPST 0x0
Write-recovery for auto-precharge command
PSU_DDR_PHY_MR1_NWR 0x0
Read Preamble Length
PSU_DDR_PHY_MR1_RDPRE 0x0
Write Preamble Length
PSU_DDR_PHY_MR1_WRPRE 0x0
Burst Length
PSU_DDR_PHY_MR1_BL 0x1
LPDDR4 Mode Register 1
(OFFSET, MASK, VALUE) (0XFD080184, 0xFFFFFFFFU ,0x00000301U)
RegMask = (DDR_PHY_MR1_RESERVED_31_8_MASK | DDR_PHY_MR1_RDPST_MASK | DDR_PHY_MR1_NWR_MASK | DDR_PHY_MR1_RDPRE_MASK | DDR_PHY_MR1_WRPRE_MASK | DDR_PHY_MR1_BL_MASK | 0 );
RegVal = ((0x00000003U << DDR_PHY_MR1_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR1_RDPST_SHIFT
| 0x00000000U << DDR_PHY_MR1_NWR_SHIFT
| 0x00000000U << DDR_PHY_MR1_RDPRE_SHIFT
| 0x00000000U << DDR_PHY_MR1_WRPRE_SHIFT
| 0x00000001U << DDR_PHY_MR1_BL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR1_OFFSET ,0xFFFFFFFFU ,0x00000301U);
/*############################################################################################################################ */
/*Register : MR2 @ 0XFD080188</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR2_RESERVED_31_8 0x0
Write Leveling
PSU_DDR_PHY_MR2_WRL 0x0
Write Latency Set
PSU_DDR_PHY_MR2_WLS 0x0
Write Latency
PSU_DDR_PHY_MR2_WL 0x4
Read Latency
PSU_DDR_PHY_MR2_RL 0x0
LPDDR4 Mode Register 2
(OFFSET, MASK, VALUE) (0XFD080188, 0xFFFFFFFFU ,0x00000020U)
RegMask = (DDR_PHY_MR2_RESERVED_31_8_MASK | DDR_PHY_MR2_WRL_MASK | DDR_PHY_MR2_WLS_MASK | DDR_PHY_MR2_WL_MASK | DDR_PHY_MR2_RL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR2_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR2_WRL_SHIFT
| 0x00000000U << DDR_PHY_MR2_WLS_SHIFT
| 0x00000004U << DDR_PHY_MR2_WL_SHIFT
| 0x00000000U << DDR_PHY_MR2_RL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR2_OFFSET ,0xFFFFFFFFU ,0x00000020U);
/*############################################################################################################################ */
/*Register : MR3 @ 0XFD08018C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR3_RESERVED_31_8 0x2
DBI-Write Enable
PSU_DDR_PHY_MR3_DBIWR 0x0
DBI-Read Enable
PSU_DDR_PHY_MR3_DBIRD 0x0
Pull-down Drive Strength
PSU_DDR_PHY_MR3_PDDS 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR3_RSVD 0x0
Write Postamble Length
PSU_DDR_PHY_MR3_WRPST 0x0
Pull-up Calibration Point
PSU_DDR_PHY_MR3_PUCAL 0x0
LPDDR4 Mode Register 3
(OFFSET, MASK, VALUE) (0XFD08018C, 0xFFFFFFFFU ,0x00000200U)
RegMask = (DDR_PHY_MR3_RESERVED_31_8_MASK | DDR_PHY_MR3_DBIWR_MASK | DDR_PHY_MR3_DBIRD_MASK | DDR_PHY_MR3_PDDS_MASK | DDR_PHY_MR3_RSVD_MASK | DDR_PHY_MR3_WRPST_MASK | DDR_PHY_MR3_PUCAL_MASK | 0 );
RegVal = ((0x00000002U << DDR_PHY_MR3_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR3_DBIWR_SHIFT
| 0x00000000U << DDR_PHY_MR3_DBIRD_SHIFT
| 0x00000000U << DDR_PHY_MR3_PDDS_SHIFT
| 0x00000000U << DDR_PHY_MR3_RSVD_SHIFT
| 0x00000000U << DDR_PHY_MR3_WRPST_SHIFT
| 0x00000000U << DDR_PHY_MR3_PUCAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR3_OFFSET ,0xFFFFFFFFU ,0x00000200U);
/*############################################################################################################################ */
/*Register : MR4 @ 0XFD080190</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR4_RESERVED_31_16 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR4_RSVD_15_13 0x0
Write Preamble
PSU_DDR_PHY_MR4_WRP 0x0
Read Preamble
PSU_DDR_PHY_MR4_RDP 0x0
Read Preamble Training Mode
PSU_DDR_PHY_MR4_RPTM 0x0
Self Refresh Abort
PSU_DDR_PHY_MR4_SRA 0x0
CS to Command Latency Mode
PSU_DDR_PHY_MR4_CS2CMDL 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR4_RSVD1 0x0
Internal VREF Monitor
PSU_DDR_PHY_MR4_IVM 0x0
Temperature Controlled Refresh Mode
PSU_DDR_PHY_MR4_TCRM 0x0
Temperature Controlled Refresh Range
PSU_DDR_PHY_MR4_TCRR 0x0
Maximum Power Down Mode
PSU_DDR_PHY_MR4_MPDM 0x0
This is a JEDEC reserved bit and is recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR4_RSVD_0 0x0
DDR4 Mode Register 4
(OFFSET, MASK, VALUE) (0XFD080190, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_MR4_RESERVED_31_16_MASK | DDR_PHY_MR4_RSVD_15_13_MASK | DDR_PHY_MR4_WRP_MASK | DDR_PHY_MR4_RDP_MASK | DDR_PHY_MR4_RPTM_MASK | DDR_PHY_MR4_SRA_MASK | DDR_PHY_MR4_CS2CMDL_MASK | DDR_PHY_MR4_RSVD1_MASK | DDR_PHY_MR4_IVM_MASK | DDR_PHY_MR4_TCRM_MASK | DDR_PHY_MR4_TCRR_MASK | DDR_PHY_MR4_MPDM_MASK | DDR_PHY_MR4_RSVD_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR4_RESERVED_31_16_SHIFT
| 0x00000000U << DDR_PHY_MR4_RSVD_15_13_SHIFT
| 0x00000000U << DDR_PHY_MR4_WRP_SHIFT
| 0x00000000U << DDR_PHY_MR4_RDP_SHIFT
| 0x00000000U << DDR_PHY_MR4_RPTM_SHIFT
| 0x00000000U << DDR_PHY_MR4_SRA_SHIFT
| 0x00000000U << DDR_PHY_MR4_CS2CMDL_SHIFT
| 0x00000000U << DDR_PHY_MR4_RSVD1_SHIFT
| 0x00000000U << DDR_PHY_MR4_IVM_SHIFT
| 0x00000000U << DDR_PHY_MR4_TCRM_SHIFT
| 0x00000000U << DDR_PHY_MR4_TCRR_SHIFT
| 0x00000000U << DDR_PHY_MR4_MPDM_SHIFT
| 0x00000000U << DDR_PHY_MR4_RSVD_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR4_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MR5 @ 0XFD080194</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR5_RESERVED_31_16 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR5_RSVD 0x0
Read DBI
PSU_DDR_PHY_MR5_RDBI 0x0
Write DBI
PSU_DDR_PHY_MR5_WDBI 0x0
Data Mask
PSU_DDR_PHY_MR5_DM 0x1
CA Parity Persistent Error
PSU_DDR_PHY_MR5_CAPPE 0x1
RTT_PARK
PSU_DDR_PHY_MR5_RTTPARK 0x3
ODT Input Buffer during Power Down mode
PSU_DDR_PHY_MR5_ODTIBPD 0x0
C/A Parity Error Status
PSU_DDR_PHY_MR5_CAPES 0x0
CRC Error Clear
PSU_DDR_PHY_MR5_CRCEC 0x0
C/A Parity Latency Mode
PSU_DDR_PHY_MR5_CAPM 0x0
DDR4 Mode Register 5
(OFFSET, MASK, VALUE) (0XFD080194, 0xFFFFFFFFU ,0x000006C0U)
RegMask = (DDR_PHY_MR5_RESERVED_31_16_MASK | DDR_PHY_MR5_RSVD_MASK | DDR_PHY_MR5_RDBI_MASK | DDR_PHY_MR5_WDBI_MASK | DDR_PHY_MR5_DM_MASK | DDR_PHY_MR5_CAPPE_MASK | DDR_PHY_MR5_RTTPARK_MASK | DDR_PHY_MR5_ODTIBPD_MASK | DDR_PHY_MR5_CAPES_MASK | DDR_PHY_MR5_CRCEC_MASK | DDR_PHY_MR5_CAPM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR5_RESERVED_31_16_SHIFT
| 0x00000000U << DDR_PHY_MR5_RSVD_SHIFT
| 0x00000000U << DDR_PHY_MR5_RDBI_SHIFT
| 0x00000000U << DDR_PHY_MR5_WDBI_SHIFT
| 0x00000001U << DDR_PHY_MR5_DM_SHIFT
| 0x00000001U << DDR_PHY_MR5_CAPPE_SHIFT
| 0x00000003U << DDR_PHY_MR5_RTTPARK_SHIFT
| 0x00000000U << DDR_PHY_MR5_ODTIBPD_SHIFT
| 0x00000000U << DDR_PHY_MR5_CAPES_SHIFT
| 0x00000000U << DDR_PHY_MR5_CRCEC_SHIFT
| 0x00000000U << DDR_PHY_MR5_CAPM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR5_OFFSET ,0xFFFFFFFFU ,0x000006C0U);
/*############################################################################################################################ */
/*Register : MR6 @ 0XFD080198</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR6_RESERVED_31_16 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR6_RSVD_15_13 0x0
CAS_n to CAS_n command delay for same bank group (tCCD_L)
PSU_DDR_PHY_MR6_TCCDL 0x2
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR6_RSVD_9_8 0x0
VrefDQ Training Enable
PSU_DDR_PHY_MR6_VDDQTEN 0x0
VrefDQ Training Range
PSU_DDR_PHY_MR6_VDQTRG 0x0
VrefDQ Training Values
PSU_DDR_PHY_MR6_VDQTVAL 0x19
DDR4 Mode Register 6
(OFFSET, MASK, VALUE) (0XFD080198, 0xFFFFFFFFU ,0x00000819U)
RegMask = (DDR_PHY_MR6_RESERVED_31_16_MASK | DDR_PHY_MR6_RSVD_15_13_MASK | DDR_PHY_MR6_TCCDL_MASK | DDR_PHY_MR6_RSVD_9_8_MASK | DDR_PHY_MR6_VDDQTEN_MASK | DDR_PHY_MR6_VDQTRG_MASK | DDR_PHY_MR6_VDQTVAL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR6_RESERVED_31_16_SHIFT
| 0x00000000U << DDR_PHY_MR6_RSVD_15_13_SHIFT
| 0x00000002U << DDR_PHY_MR6_TCCDL_SHIFT
| 0x00000000U << DDR_PHY_MR6_RSVD_9_8_SHIFT
| 0x00000000U << DDR_PHY_MR6_VDDQTEN_SHIFT
| 0x00000000U << DDR_PHY_MR6_VDQTRG_SHIFT
| 0x00000019U << DDR_PHY_MR6_VDQTVAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR6_OFFSET ,0xFFFFFFFFU ,0x00000819U);
/*############################################################################################################################ */
/*Register : MR11 @ 0XFD0801AC</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR11_RESERVED_31_8 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR11_RSVD 0x0
Power Down Control
PSU_DDR_PHY_MR11_PDCTL 0x0
DQ Bus Receiver On-Die-Termination
PSU_DDR_PHY_MR11_DQODT 0x0
LPDDR4 Mode Register 11
(OFFSET, MASK, VALUE) (0XFD0801AC, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_MR11_RESERVED_31_8_MASK | DDR_PHY_MR11_RSVD_MASK | DDR_PHY_MR11_PDCTL_MASK | DDR_PHY_MR11_DQODT_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR11_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR11_RSVD_SHIFT
| 0x00000000U << DDR_PHY_MR11_PDCTL_SHIFT
| 0x00000000U << DDR_PHY_MR11_DQODT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR11_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MR12 @ 0XFD0801B0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR12_RESERVED_31_8 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR12_RSVD 0x0
VREF_CA Range Select.
PSU_DDR_PHY_MR12_VR_CA 0x1
Controls the VREF(ca) levels for Frequency-Set-Point[1:0].
PSU_DDR_PHY_MR12_VREF_CA 0xd
LPDDR4 Mode Register 12
(OFFSET, MASK, VALUE) (0XFD0801B0, 0xFFFFFFFFU ,0x0000004DU)
RegMask = (DDR_PHY_MR12_RESERVED_31_8_MASK | DDR_PHY_MR12_RSVD_MASK | DDR_PHY_MR12_VR_CA_MASK | DDR_PHY_MR12_VREF_CA_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR12_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR12_RSVD_SHIFT
| 0x00000001U << DDR_PHY_MR12_VR_CA_SHIFT
| 0x0000000DU << DDR_PHY_MR12_VREF_CA_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR12_OFFSET ,0xFFFFFFFFU ,0x0000004DU);
/*############################################################################################################################ */
/*Register : MR13 @ 0XFD0801B4</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR13_RESERVED_31_8 0x0
Frequency Set Point Operation Mode
PSU_DDR_PHY_MR13_FSPOP 0x0
Frequency Set Point Write Enable
PSU_DDR_PHY_MR13_FSPWR 0x0
Data Mask Enable
PSU_DDR_PHY_MR13_DMD 0x0
Refresh Rate Option
PSU_DDR_PHY_MR13_RRO 0x0
VREF Current Generator
PSU_DDR_PHY_MR13_VRCG 0x1
VREF Output
PSU_DDR_PHY_MR13_VRO 0x0
Read Preamble Training Mode
PSU_DDR_PHY_MR13_RPT 0x0
Command Bus Training
PSU_DDR_PHY_MR13_CBT 0x0
LPDDR4 Mode Register 13
(OFFSET, MASK, VALUE) (0XFD0801B4, 0xFFFFFFFFU ,0x00000008U)
RegMask = (DDR_PHY_MR13_RESERVED_31_8_MASK | DDR_PHY_MR13_FSPOP_MASK | DDR_PHY_MR13_FSPWR_MASK | DDR_PHY_MR13_DMD_MASK | DDR_PHY_MR13_RRO_MASK | DDR_PHY_MR13_VRCG_MASK | DDR_PHY_MR13_VRO_MASK | DDR_PHY_MR13_RPT_MASK | DDR_PHY_MR13_CBT_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR13_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR13_FSPOP_SHIFT
| 0x00000000U << DDR_PHY_MR13_FSPWR_SHIFT
| 0x00000000U << DDR_PHY_MR13_DMD_SHIFT
| 0x00000000U << DDR_PHY_MR13_RRO_SHIFT
| 0x00000001U << DDR_PHY_MR13_VRCG_SHIFT
| 0x00000000U << DDR_PHY_MR13_VRO_SHIFT
| 0x00000000U << DDR_PHY_MR13_RPT_SHIFT
| 0x00000000U << DDR_PHY_MR13_CBT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR13_OFFSET ,0xFFFFFFFFU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MR14 @ 0XFD0801B8</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR14_RESERVED_31_8 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR14_RSVD 0x0
VREFDQ Range Selects.
PSU_DDR_PHY_MR14_VR_DQ 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR14_VREF_DQ 0xd
LPDDR4 Mode Register 14
(OFFSET, MASK, VALUE) (0XFD0801B8, 0xFFFFFFFFU ,0x0000004DU)
RegMask = (DDR_PHY_MR14_RESERVED_31_8_MASK | DDR_PHY_MR14_RSVD_MASK | DDR_PHY_MR14_VR_DQ_MASK | DDR_PHY_MR14_VREF_DQ_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR14_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR14_RSVD_SHIFT
| 0x00000001U << DDR_PHY_MR14_VR_DQ_SHIFT
| 0x0000000DU << DDR_PHY_MR14_VREF_DQ_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR14_OFFSET ,0xFFFFFFFFU ,0x0000004DU);
/*############################################################################################################################ */
/*Register : MR22 @ 0XFD0801D8</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_MR22_RESERVED_31_8 0x0
These are JEDEC reserved bits and are recommended by JEDEC to be programmed to 0x0.
PSU_DDR_PHY_MR22_RSVD 0x0
CA ODT termination disable.
PSU_DDR_PHY_MR22_ODTD_CA 0x0
ODT CS override.
PSU_DDR_PHY_MR22_ODTE_CS 0x0
ODT CK override.
PSU_DDR_PHY_MR22_ODTE_CK 0x0
Controller ODT value for VOH calibration.
PSU_DDR_PHY_MR22_CODT 0x0
LPDDR4 Mode Register 22
(OFFSET, MASK, VALUE) (0XFD0801D8, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_MR22_RESERVED_31_8_MASK | DDR_PHY_MR22_RSVD_MASK | DDR_PHY_MR22_ODTD_CA_MASK | DDR_PHY_MR22_ODTE_CS_MASK | DDR_PHY_MR22_ODTE_CK_MASK | DDR_PHY_MR22_CODT_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_MR22_RESERVED_31_8_SHIFT
| 0x00000000U << DDR_PHY_MR22_RSVD_SHIFT
| 0x00000000U << DDR_PHY_MR22_ODTD_CA_SHIFT
| 0x00000000U << DDR_PHY_MR22_ODTE_CS_SHIFT
| 0x00000000U << DDR_PHY_MR22_ODTE_CK_SHIFT
| 0x00000000U << DDR_PHY_MR22_CODT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_MR22_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DTCR0 @ 0XFD080200</p>
Refresh During Training
PSU_DDR_PHY_DTCR0_RFSHDT 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR0_RESERVED_27_26 0x0
Data Training Debug Rank Select
PSU_DDR_PHY_DTCR0_DTDRS 0x0
Data Training with Early/Extended Gate
PSU_DDR_PHY_DTCR0_DTEXG 0x0
Data Training Extended Write DQS
PSU_DDR_PHY_DTCR0_DTEXD 0x0
Data Training Debug Step
PSU_DDR_PHY_DTCR0_DTDSTP 0x0
Data Training Debug Enable
PSU_DDR_PHY_DTCR0_DTDEN 0x0
Data Training Debug Byte Select
PSU_DDR_PHY_DTCR0_DTDBS 0x0
Data Training read DBI deskewing configuration
PSU_DDR_PHY_DTCR0_DTRDBITR 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR0_RESERVED_13 0x0
Data Training Write Bit Deskew Data Mask
PSU_DDR_PHY_DTCR0_DTWBDDM 0x1
Refreshes Issued During Entry to Training
PSU_DDR_PHY_DTCR0_RFSHEN 0x1
Data Training Compare Data
PSU_DDR_PHY_DTCR0_DTCMPD 0x1
Data Training Using MPR
PSU_DDR_PHY_DTCR0_DTMPR 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR0_RESERVED_5_4 0x0
Data Training Repeat Number
PSU_DDR_PHY_DTCR0_DTRPTN 0x7
Data Training Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080200, 0xFFFFFFFFU ,0x800091C7U)
RegMask = (DDR_PHY_DTCR0_RFSHDT_MASK | DDR_PHY_DTCR0_RESERVED_27_26_MASK | DDR_PHY_DTCR0_DTDRS_MASK | DDR_PHY_DTCR0_DTEXG_MASK | DDR_PHY_DTCR0_DTEXD_MASK | DDR_PHY_DTCR0_DTDSTP_MASK | DDR_PHY_DTCR0_DTDEN_MASK | DDR_PHY_DTCR0_DTDBS_MASK | DDR_PHY_DTCR0_DTRDBITR_MASK | DDR_PHY_DTCR0_RESERVED_13_MASK | DDR_PHY_DTCR0_DTWBDDM_MASK | DDR_PHY_DTCR0_RFSHEN_MASK | DDR_PHY_DTCR0_DTCMPD_MASK | DDR_PHY_DTCR0_DTMPR_MASK | DDR_PHY_DTCR0_RESERVED_5_4_MASK | DDR_PHY_DTCR0_DTRPTN_MASK | 0 );
RegVal = ((0x00000008U << DDR_PHY_DTCR0_RFSHDT_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_RESERVED_27_26_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTDRS_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTEXG_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTEXD_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTDSTP_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTDEN_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_DTDBS_SHIFT
| 0x00000002U << DDR_PHY_DTCR0_DTRDBITR_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_RESERVED_13_SHIFT
| 0x00000001U << DDR_PHY_DTCR0_DTWBDDM_SHIFT
| 0x00000001U << DDR_PHY_DTCR0_RFSHEN_SHIFT
| 0x00000001U << DDR_PHY_DTCR0_DTCMPD_SHIFT
| 0x00000001U << DDR_PHY_DTCR0_DTMPR_SHIFT
| 0x00000000U << DDR_PHY_DTCR0_RESERVED_5_4_SHIFT
| 0x00000007U << DDR_PHY_DTCR0_DTRPTN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTCR0_OFFSET ,0xFFFFFFFFU ,0x800091C7U);
/*############################################################################################################################ */
/*Register : DTCR1 @ 0XFD080204</p>
Rank Enable.
PSU_DDR_PHY_DTCR1_RANKEN_RSVD 0x0
Rank Enable.
PSU_DDR_PHY_DTCR1_RANKEN 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR1_RESERVED_15_14 0x0
Data Training Rank
PSU_DDR_PHY_DTCR1_DTRANK 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR1_RESERVED_11 0x0
Read Leveling Gate Sampling Difference
PSU_DDR_PHY_DTCR1_RDLVLGDIFF 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR1_RESERVED_7 0x0
Read Leveling Gate Shift
PSU_DDR_PHY_DTCR1_RDLVLGS 0x3
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DTCR1_RESERVED_3 0x0
Read Preamble Training enable
PSU_DDR_PHY_DTCR1_RDPRMVL_TRN 0x1
Read Leveling Enable
PSU_DDR_PHY_DTCR1_RDLVLEN 0x1
Basic Gate Training Enable
PSU_DDR_PHY_DTCR1_BSTEN 0x0
Data Training Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080204, 0xFFFFFFFFU ,0x00010236U)
RegMask = (DDR_PHY_DTCR1_RANKEN_RSVD_MASK | DDR_PHY_DTCR1_RANKEN_MASK | DDR_PHY_DTCR1_RESERVED_15_14_MASK | DDR_PHY_DTCR1_DTRANK_MASK | DDR_PHY_DTCR1_RESERVED_11_MASK | DDR_PHY_DTCR1_RDLVLGDIFF_MASK | DDR_PHY_DTCR1_RESERVED_7_MASK | DDR_PHY_DTCR1_RDLVLGS_MASK | DDR_PHY_DTCR1_RESERVED_3_MASK | DDR_PHY_DTCR1_RDPRMVL_TRN_MASK | DDR_PHY_DTCR1_RDLVLEN_MASK | DDR_PHY_DTCR1_BSTEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DTCR1_RANKEN_RSVD_SHIFT
| 0x00000001U << DDR_PHY_DTCR1_RANKEN_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_DTRANK_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_RESERVED_11_SHIFT
| 0x00000002U << DDR_PHY_DTCR1_RDLVLGDIFF_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_RESERVED_7_SHIFT
| 0x00000003U << DDR_PHY_DTCR1_RDLVLGS_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_RESERVED_3_SHIFT
| 0x00000001U << DDR_PHY_DTCR1_RDPRMVL_TRN_SHIFT
| 0x00000001U << DDR_PHY_DTCR1_RDLVLEN_SHIFT
| 0x00000000U << DDR_PHY_DTCR1_BSTEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DTCR1_OFFSET ,0xFFFFFFFFU ,0x00010236U);
/*############################################################################################################################ */
/*Register : CATR0 @ 0XFD080240</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_CATR0_RESERVED_31_21 0x0
Minimum time (in terms of number of dram clocks) between two consectuve CA calibration command
PSU_DDR_PHY_CATR0_CACD 0x14
Reserved. Return zeroes on reads.
PSU_DDR_PHY_CATR0_RESERVED_15_13 0x0
Minimum time (in terms of number of dram clocks) PUB should wait before sampling the CA response after Calibration command ha
been sent to the memory
PSU_DDR_PHY_CATR0_CAADR 0x10
CA_1 Response Byte Lane 1
PSU_DDR_PHY_CATR0_CA1BYTE1 0x5
CA_1 Response Byte Lane 0
PSU_DDR_PHY_CATR0_CA1BYTE0 0x4
CA Training Register 0
(OFFSET, MASK, VALUE) (0XFD080240, 0xFFFFFFFFU ,0x00141054U)
RegMask = (DDR_PHY_CATR0_RESERVED_31_21_MASK | DDR_PHY_CATR0_CACD_MASK | DDR_PHY_CATR0_RESERVED_15_13_MASK | DDR_PHY_CATR0_CAADR_MASK | DDR_PHY_CATR0_CA1BYTE1_MASK | DDR_PHY_CATR0_CA1BYTE0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_CATR0_RESERVED_31_21_SHIFT
| 0x00000014U << DDR_PHY_CATR0_CACD_SHIFT
| 0x00000000U << DDR_PHY_CATR0_RESERVED_15_13_SHIFT
| 0x00000010U << DDR_PHY_CATR0_CAADR_SHIFT
| 0x00000005U << DDR_PHY_CATR0_CA1BYTE1_SHIFT
| 0x00000004U << DDR_PHY_CATR0_CA1BYTE0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_CATR0_OFFSET ,0xFFFFFFFFU ,0x00141054U);
/*############################################################################################################################ */
/*Register : BISTLSR @ 0XFD080414</p>
LFSR seed for pseudo-random BIST patterns
PSU_DDR_PHY_BISTLSR_SEED 0x12341000
BIST LFSR Seed Register
(OFFSET, MASK, VALUE) (0XFD080414, 0xFFFFFFFFU ,0x12341000U)
RegMask = (DDR_PHY_BISTLSR_SEED_MASK | 0 );
RegVal = ((0x12341000U << DDR_PHY_BISTLSR_SEED_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_BISTLSR_OFFSET ,0xFFFFFFFFU ,0x12341000U);
/*############################################################################################################################ */
/*Register : RIOCR5 @ 0XFD0804F4</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_RIOCR5_RESERVED_31_16 0x0
Reserved. Return zeros on reads.
PSU_DDR_PHY_RIOCR5_ODTOEMODE_RSVD 0x0
SDRAM On-die Termination Output Enable (OE) Mode Selection.
PSU_DDR_PHY_RIOCR5_ODTOEMODE 0x5
Rank I/O Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD0804F4, 0xFFFFFFFFU ,0x00000005U)
RegMask = (DDR_PHY_RIOCR5_RESERVED_31_16_MASK | DDR_PHY_RIOCR5_ODTOEMODE_RSVD_MASK | DDR_PHY_RIOCR5_ODTOEMODE_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_RIOCR5_RESERVED_31_16_SHIFT
| 0x00000000U << DDR_PHY_RIOCR5_ODTOEMODE_RSVD_SHIFT
| 0x00000005U << DDR_PHY_RIOCR5_ODTOEMODE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_RIOCR5_OFFSET ,0xFFFFFFFFU ,0x00000005U);
/*############################################################################################################################ */
/*Register : ACIOCR0 @ 0XFD080500</p>
Address/Command Slew Rate (D3F I/O Only)
PSU_DDR_PHY_ACIOCR0_ACSR 0x0
SDRAM Reset I/O Mode
PSU_DDR_PHY_ACIOCR0_RSTIOM 0x1
SDRAM Reset Power Down Receiver
PSU_DDR_PHY_ACIOCR0_RSTPDR 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACIOCR0_RESERVED_27 0x0
SDRAM Reset On-Die Termination
PSU_DDR_PHY_ACIOCR0_RSTODT 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACIOCR0_RESERVED_25_10 0x0
CK Duty Cycle Correction
PSU_DDR_PHY_ACIOCR0_CKDCC 0x0
AC Power Down Receiver Mode
PSU_DDR_PHY_ACIOCR0_ACPDRMODE 0x2
AC On-die Termination Mode
PSU_DDR_PHY_ACIOCR0_ACODTMODE 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACIOCR0_RESERVED_1 0x0
Control delayed or non-delayed clock to CS_N/ODT?CKE AC slices.
PSU_DDR_PHY_ACIOCR0_ACRANKCLKSEL 0x0
AC I/O Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080500, 0xFFFFFFFFU ,0x30000028U)
RegMask = (DDR_PHY_ACIOCR0_ACSR_MASK | DDR_PHY_ACIOCR0_RSTIOM_MASK | DDR_PHY_ACIOCR0_RSTPDR_MASK | DDR_PHY_ACIOCR0_RESERVED_27_MASK | DDR_PHY_ACIOCR0_RSTODT_MASK | DDR_PHY_ACIOCR0_RESERVED_25_10_MASK | DDR_PHY_ACIOCR0_CKDCC_MASK | DDR_PHY_ACIOCR0_ACPDRMODE_MASK | DDR_PHY_ACIOCR0_ACODTMODE_MASK | DDR_PHY_ACIOCR0_RESERVED_1_MASK | DDR_PHY_ACIOCR0_ACRANKCLKSEL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACIOCR0_ACSR_SHIFT
| 0x00000001U << DDR_PHY_ACIOCR0_RSTIOM_SHIFT
| 0x00000001U << DDR_PHY_ACIOCR0_RSTPDR_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_RESERVED_27_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_RSTODT_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_RESERVED_25_10_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_CKDCC_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR0_ACPDRMODE_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR0_ACODTMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_RESERVED_1_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR0_ACRANKCLKSEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACIOCR0_OFFSET ,0xFFFFFFFFU ,0x30000028U);
/*############################################################################################################################ */
/*Register : ACIOCR2 @ 0XFD080508</p>
Clock gating for glue logic inside CLKGEN and glue logic inside CONTROL slice
PSU_DDR_PHY_ACIOCR2_CLKGENCLKGATE 0x0
Clock gating for Output Enable D slices [0]
PSU_DDR_PHY_ACIOCR2_ACOECLKGATE0 0x0
Clock gating for Power Down Receiver D slices [0]
PSU_DDR_PHY_ACIOCR2_ACPDRCLKGATE0 0x0
Clock gating for Termination Enable D slices [0]
PSU_DDR_PHY_ACIOCR2_ACTECLKGATE0 0x0
Clock gating for CK# D slices [1:0]
PSU_DDR_PHY_ACIOCR2_CKNCLKGATE0 0x2
Clock gating for CK D slices [1:0]
PSU_DDR_PHY_ACIOCR2_CKCLKGATE0 0x2
Clock gating for AC D slices [23:0]
PSU_DDR_PHY_ACIOCR2_ACCLKGATE0 0x0
AC I/O Configuration Register 2
(OFFSET, MASK, VALUE) (0XFD080508, 0xFFFFFFFFU ,0x0A000000U)
RegMask = (DDR_PHY_ACIOCR2_CLKGENCLKGATE_MASK | DDR_PHY_ACIOCR2_ACOECLKGATE0_MASK | DDR_PHY_ACIOCR2_ACPDRCLKGATE0_MASK | DDR_PHY_ACIOCR2_ACTECLKGATE0_MASK | DDR_PHY_ACIOCR2_CKNCLKGATE0_MASK | DDR_PHY_ACIOCR2_CKCLKGATE0_MASK | DDR_PHY_ACIOCR2_ACCLKGATE0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACIOCR2_CLKGENCLKGATE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR2_ACOECLKGATE0_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR2_ACPDRCLKGATE0_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR2_ACTECLKGATE0_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR2_CKNCLKGATE0_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR2_CKCLKGATE0_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR2_ACCLKGATE0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACIOCR2_OFFSET ,0xFFFFFFFFU ,0x0A000000U);
/*############################################################################################################################ */
/*Register : ACIOCR3 @ 0XFD08050C</p>
SDRAM Parity Output Enable (OE) Mode Selection
PSU_DDR_PHY_ACIOCR3_PAROEMODE 0x0
SDRAM Bank Group Output Enable (OE) Mode Selection
PSU_DDR_PHY_ACIOCR3_BGOEMODE 0x0
SDRAM Bank Address Output Enable (OE) Mode Selection
PSU_DDR_PHY_ACIOCR3_BAOEMODE 0x0
SDRAM A[17] Output Enable (OE) Mode Selection
PSU_DDR_PHY_ACIOCR3_A17OEMODE 0x0
SDRAM A[16] / RAS_n Output Enable (OE) Mode Selection
PSU_DDR_PHY_ACIOCR3_A16OEMODE 0x0
SDRAM ACT_n Output Enable (OE) Mode Selection (DDR4 only)
PSU_DDR_PHY_ACIOCR3_ACTOEMODE 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACIOCR3_RESERVED_15_8 0x0
Reserved. Return zeros on reads.
PSU_DDR_PHY_ACIOCR3_CKOEMODE_RSVD 0x0
SDRAM CK Output Enable (OE) Mode Selection.
PSU_DDR_PHY_ACIOCR3_CKOEMODE 0x9
AC I/O Configuration Register 3
(OFFSET, MASK, VALUE) (0XFD08050C, 0xFFFFFFFFU ,0x00000009U)
RegMask = (DDR_PHY_ACIOCR3_PAROEMODE_MASK | DDR_PHY_ACIOCR3_BGOEMODE_MASK | DDR_PHY_ACIOCR3_BAOEMODE_MASK | DDR_PHY_ACIOCR3_A17OEMODE_MASK | DDR_PHY_ACIOCR3_A16OEMODE_MASK | DDR_PHY_ACIOCR3_ACTOEMODE_MASK | DDR_PHY_ACIOCR3_RESERVED_15_8_MASK | DDR_PHY_ACIOCR3_CKOEMODE_RSVD_MASK | DDR_PHY_ACIOCR3_CKOEMODE_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACIOCR3_PAROEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_BGOEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_BAOEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_A17OEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_A16OEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_ACTOEMODE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_RESERVED_15_8_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR3_CKOEMODE_RSVD_SHIFT
| 0x00000009U << DDR_PHY_ACIOCR3_CKOEMODE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACIOCR3_OFFSET ,0xFFFFFFFFU ,0x00000009U);
/*############################################################################################################################ */
/*Register : ACIOCR4 @ 0XFD080510</p>
Clock gating for AC LB slices and loopback read valid slices
PSU_DDR_PHY_ACIOCR4_LBCLKGATE 0x0
Clock gating for Output Enable D slices [1]
PSU_DDR_PHY_ACIOCR4_ACOECLKGATE1 0x0
Clock gating for Power Down Receiver D slices [1]
PSU_DDR_PHY_ACIOCR4_ACPDRCLKGATE1 0x0
Clock gating for Termination Enable D slices [1]
PSU_DDR_PHY_ACIOCR4_ACTECLKGATE1 0x0
Clock gating for CK# D slices [3:2]
PSU_DDR_PHY_ACIOCR4_CKNCLKGATE1 0x2
Clock gating for CK D slices [3:2]
PSU_DDR_PHY_ACIOCR4_CKCLKGATE1 0x2
Clock gating for AC D slices [47:24]
PSU_DDR_PHY_ACIOCR4_ACCLKGATE1 0x0
AC I/O Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080510, 0xFFFFFFFFU ,0x0A000000U)
RegMask = (DDR_PHY_ACIOCR4_LBCLKGATE_MASK | DDR_PHY_ACIOCR4_ACOECLKGATE1_MASK | DDR_PHY_ACIOCR4_ACPDRCLKGATE1_MASK | DDR_PHY_ACIOCR4_ACTECLKGATE1_MASK | DDR_PHY_ACIOCR4_CKNCLKGATE1_MASK | DDR_PHY_ACIOCR4_CKCLKGATE1_MASK | DDR_PHY_ACIOCR4_ACCLKGATE1_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACIOCR4_LBCLKGATE_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR4_ACOECLKGATE1_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR4_ACPDRCLKGATE1_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR4_ACTECLKGATE1_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR4_CKNCLKGATE1_SHIFT
| 0x00000002U << DDR_PHY_ACIOCR4_CKCLKGATE1_SHIFT
| 0x00000000U << DDR_PHY_ACIOCR4_ACCLKGATE1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACIOCR4_OFFSET ,0xFFFFFFFFU ,0x0A000000U);
/*############################################################################################################################ */
/*Register : IOVCR0 @ 0XFD080520</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_IOVCR0_RESERVED_31_29 0x0
Address/command lane VREF Pad Enable
PSU_DDR_PHY_IOVCR0_ACREFPEN 0x0
Address/command lane Internal VREF Enable
PSU_DDR_PHY_IOVCR0_ACREFEEN 0x0
Address/command lane Single-End VREF Enable
PSU_DDR_PHY_IOVCR0_ACREFSEN 0x1
Address/command lane Internal VREF Enable
PSU_DDR_PHY_IOVCR0_ACREFIEN 0x1
External VREF generato REFSEL range select
PSU_DDR_PHY_IOVCR0_ACREFESELRANGE 0x0
Address/command lane External VREF Select
PSU_DDR_PHY_IOVCR0_ACREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_IOVCR0_ACREFSSELRANGE 0x1
Address/command lane Single-End VREF Select
PSU_DDR_PHY_IOVCR0_ACREFSSEL 0x30
Internal VREF generator REFSEL ragne select
PSU_DDR_PHY_IOVCR0_ACVREFISELRANGE 0x1
REFSEL Control for internal AC IOs
PSU_DDR_PHY_IOVCR0_ACVREFISEL 0x30
IO VREF Control Register 0
(OFFSET, MASK, VALUE) (0XFD080520, 0xFFFFFFFFU ,0x0300B0B0U)
RegMask = (DDR_PHY_IOVCR0_RESERVED_31_29_MASK | DDR_PHY_IOVCR0_ACREFPEN_MASK | DDR_PHY_IOVCR0_ACREFEEN_MASK | DDR_PHY_IOVCR0_ACREFSEN_MASK | DDR_PHY_IOVCR0_ACREFIEN_MASK | DDR_PHY_IOVCR0_ACREFESELRANGE_MASK | DDR_PHY_IOVCR0_ACREFESEL_MASK | DDR_PHY_IOVCR0_ACREFSSELRANGE_MASK | DDR_PHY_IOVCR0_ACREFSSEL_MASK | DDR_PHY_IOVCR0_ACVREFISELRANGE_MASK | DDR_PHY_IOVCR0_ACVREFISEL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_IOVCR0_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_IOVCR0_ACREFPEN_SHIFT
| 0x00000000U << DDR_PHY_IOVCR0_ACREFEEN_SHIFT
| 0x00000001U << DDR_PHY_IOVCR0_ACREFSEN_SHIFT
| 0x00000001U << DDR_PHY_IOVCR0_ACREFIEN_SHIFT
| 0x00000000U << DDR_PHY_IOVCR0_ACREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_IOVCR0_ACREFESEL_SHIFT
| 0x00000001U << DDR_PHY_IOVCR0_ACREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_IOVCR0_ACREFSSEL_SHIFT
| 0x00000001U << DDR_PHY_IOVCR0_ACVREFISELRANGE_SHIFT
| 0x00000030U << DDR_PHY_IOVCR0_ACVREFISEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_IOVCR0_OFFSET ,0xFFFFFFFFU ,0x0300B0B0U);
/*############################################################################################################################ */
/*Register : VTCR0 @ 0XFD080528</p>
Number of ctl_clk required to meet (> 150ns) timing requirements during DRAM DQ VREF training
PSU_DDR_PHY_VTCR0_TVREF 0x7
DRM DQ VREF training Enable
PSU_DDR_PHY_VTCR0_DVEN 0x1
Per Device Addressability Enable
PSU_DDR_PHY_VTCR0_PDAEN 0x1
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_VTCR0_RESERVED_26 0x0
VREF Word Count
PSU_DDR_PHY_VTCR0_VWCR 0x4
DRAM DQ VREF step size used during DRAM VREF training
PSU_DDR_PHY_VTCR0_DVSS 0x0
Maximum VREF limit value used during DRAM VREF training
PSU_DDR_PHY_VTCR0_DVMAX 0x32
Minimum VREF limit value used during DRAM VREF training
PSU_DDR_PHY_VTCR0_DVMIN 0x0
Initial DRAM DQ VREF value used during DRAM VREF training
PSU_DDR_PHY_VTCR0_DVINIT 0x19
VREF Training Control Register 0
(OFFSET, MASK, VALUE) (0XFD080528, 0xFFFFFFFFU ,0xF9032019U)
RegMask = (DDR_PHY_VTCR0_TVREF_MASK | DDR_PHY_VTCR0_DVEN_MASK | DDR_PHY_VTCR0_PDAEN_MASK | DDR_PHY_VTCR0_RESERVED_26_MASK | DDR_PHY_VTCR0_VWCR_MASK | DDR_PHY_VTCR0_DVSS_MASK | DDR_PHY_VTCR0_DVMAX_MASK | DDR_PHY_VTCR0_DVMIN_MASK | DDR_PHY_VTCR0_DVINIT_MASK | 0 );
RegVal = ((0x00000007U << DDR_PHY_VTCR0_TVREF_SHIFT
| 0x00000001U << DDR_PHY_VTCR0_DVEN_SHIFT
| 0x00000001U << DDR_PHY_VTCR0_PDAEN_SHIFT
| 0x00000000U << DDR_PHY_VTCR0_RESERVED_26_SHIFT
| 0x00000004U << DDR_PHY_VTCR0_VWCR_SHIFT
| 0x00000000U << DDR_PHY_VTCR0_DVSS_SHIFT
| 0x00000032U << DDR_PHY_VTCR0_DVMAX_SHIFT
| 0x00000000U << DDR_PHY_VTCR0_DVMIN_SHIFT
| 0x00000019U << DDR_PHY_VTCR0_DVINIT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_VTCR0_OFFSET ,0xFFFFFFFFU ,0xF9032019U);
/*############################################################################################################################ */
/*Register : VTCR1 @ 0XFD08052C</p>
Host VREF step size used during VREF training. The register value of N indicates step size of (N+1)
PSU_DDR_PHY_VTCR1_HVSS 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_VTCR1_RESERVED_27 0x0
Maximum VREF limit value used during DRAM VREF training.
PSU_DDR_PHY_VTCR1_HVMAX 0x7f
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_VTCR1_RESERVED_19 0x0
Minimum VREF limit value used during DRAM VREF training.
PSU_DDR_PHY_VTCR1_HVMIN 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_VTCR1_RESERVED_11 0x0
Static Host Vref Rank Value
PSU_DDR_PHY_VTCR1_SHRNK 0x0
Static Host Vref Rank Enable
PSU_DDR_PHY_VTCR1_SHREN 0x1
Number of ctl_clk required to meet (> 200ns) VREF Settling timing requirements during Host IO VREF training
PSU_DDR_PHY_VTCR1_TVREFIO 0x7
Eye LCDL Offset value for VREF training
PSU_DDR_PHY_VTCR1_EOFF 0x0
Number of LCDL Eye points for which VREF training is repeated
PSU_DDR_PHY_VTCR1_ENUM 0x0
HOST (IO) internal VREF training Enable
PSU_DDR_PHY_VTCR1_HVEN 0x1
Host IO Type Control
PSU_DDR_PHY_VTCR1_HVIO 0x1
VREF Training Control Register 1
(OFFSET, MASK, VALUE) (0XFD08052C, 0xFFFFFFFFU ,0x07F001E3U)
RegMask = (DDR_PHY_VTCR1_HVSS_MASK | DDR_PHY_VTCR1_RESERVED_27_MASK | DDR_PHY_VTCR1_HVMAX_MASK | DDR_PHY_VTCR1_RESERVED_19_MASK | DDR_PHY_VTCR1_HVMIN_MASK | DDR_PHY_VTCR1_RESERVED_11_MASK | DDR_PHY_VTCR1_SHRNK_MASK | DDR_PHY_VTCR1_SHREN_MASK | DDR_PHY_VTCR1_TVREFIO_MASK | DDR_PHY_VTCR1_EOFF_MASK | DDR_PHY_VTCR1_ENUM_MASK | DDR_PHY_VTCR1_HVEN_MASK | DDR_PHY_VTCR1_HVIO_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_VTCR1_HVSS_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_RESERVED_27_SHIFT
| 0x0000007FU << DDR_PHY_VTCR1_HVMAX_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_RESERVED_19_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_HVMIN_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_RESERVED_11_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_SHRNK_SHIFT
| 0x00000001U << DDR_PHY_VTCR1_SHREN_SHIFT
| 0x00000007U << DDR_PHY_VTCR1_TVREFIO_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_EOFF_SHIFT
| 0x00000000U << DDR_PHY_VTCR1_ENUM_SHIFT
| 0x00000001U << DDR_PHY_VTCR1_HVEN_SHIFT
| 0x00000001U << DDR_PHY_VTCR1_HVIO_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_VTCR1_OFFSET ,0xFFFFFFFFU ,0x07F001E3U);
/*############################################################################################################################ */
/*Register : ACBDLR1 @ 0XFD080544</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR1_RESERVED_31_30 0x0
Delay select for the BDL on Parity.
PSU_DDR_PHY_ACBDLR1_PARBD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR1_RESERVED_23_22 0x0
Delay select for the BDL on Address A[16]. In DDR3 mode this pin is connected to WE.
PSU_DDR_PHY_ACBDLR1_A16BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR1_RESERVED_15_14 0x0
Delay select for the BDL on Address A[17]. When not in DDR4 modemode this pin is connected to CAS.
PSU_DDR_PHY_ACBDLR1_A17BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR1_RESERVED_7_6 0x0
Delay select for the BDL on ACTN.
PSU_DDR_PHY_ACBDLR1_ACTBD 0x0
AC Bit Delay Line Register 1
(OFFSET, MASK, VALUE) (0XFD080544, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR1_RESERVED_31_30_MASK | DDR_PHY_ACBDLR1_PARBD_MASK | DDR_PHY_ACBDLR1_RESERVED_23_22_MASK | DDR_PHY_ACBDLR1_A16BD_MASK | DDR_PHY_ACBDLR1_RESERVED_15_14_MASK | DDR_PHY_ACBDLR1_A17BD_MASK | DDR_PHY_ACBDLR1_RESERVED_7_6_MASK | DDR_PHY_ACBDLR1_ACTBD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR1_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_PARBD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_A16BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_A17BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR1_ACTBD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR1_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ACBDLR2 @ 0XFD080548</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR2_RESERVED_31_30 0x0
Delay select for the BDL on BG[1].
PSU_DDR_PHY_ACBDLR2_BG1BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR2_RESERVED_23_22 0x0
Delay select for the BDL on BG[0].
PSU_DDR_PHY_ACBDLR2_BG0BD 0x0
Reser.ved Return zeroes on reads.
PSU_DDR_PHY_ACBDLR2_RESERVED_15_14 0x0
Delay select for the BDL on BA[1].
PSU_DDR_PHY_ACBDLR2_BA1BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR2_RESERVED_7_6 0x0
Delay select for the BDL on BA[0].
PSU_DDR_PHY_ACBDLR2_BA0BD 0x0
AC Bit Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080548, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR2_RESERVED_31_30_MASK | DDR_PHY_ACBDLR2_BG1BD_MASK | DDR_PHY_ACBDLR2_RESERVED_23_22_MASK | DDR_PHY_ACBDLR2_BG0BD_MASK | DDR_PHY_ACBDLR2_RESERVED_15_14_MASK | DDR_PHY_ACBDLR2_BA1BD_MASK | DDR_PHY_ACBDLR2_RESERVED_7_6_MASK | DDR_PHY_ACBDLR2_BA0BD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR2_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_BG1BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_BG0BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_BA1BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR2_BA0BD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ACBDLR6 @ 0XFD080558</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR6_RESERVED_31_30 0x0
Delay select for the BDL on Address A[3].
PSU_DDR_PHY_ACBDLR6_A03BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR6_RESERVED_23_22 0x0
Delay select for the BDL on Address A[2].
PSU_DDR_PHY_ACBDLR6_A02BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR6_RESERVED_15_14 0x0
Delay select for the BDL on Address A[1].
PSU_DDR_PHY_ACBDLR6_A01BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR6_RESERVED_7_6 0x0
Delay select for the BDL on Address A[0].
PSU_DDR_PHY_ACBDLR6_A00BD 0x0
AC Bit Delay Line Register 6
(OFFSET, MASK, VALUE) (0XFD080558, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR6_RESERVED_31_30_MASK | DDR_PHY_ACBDLR6_A03BD_MASK | DDR_PHY_ACBDLR6_RESERVED_23_22_MASK | DDR_PHY_ACBDLR6_A02BD_MASK | DDR_PHY_ACBDLR6_RESERVED_15_14_MASK | DDR_PHY_ACBDLR6_A01BD_MASK | DDR_PHY_ACBDLR6_RESERVED_7_6_MASK | DDR_PHY_ACBDLR6_A00BD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR6_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_A03BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_A02BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_A01BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR6_A00BD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR6_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ACBDLR7 @ 0XFD08055C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR7_RESERVED_31_30 0x0
Delay select for the BDL on Address A[7].
PSU_DDR_PHY_ACBDLR7_A07BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR7_RESERVED_23_22 0x0
Delay select for the BDL on Address A[6].
PSU_DDR_PHY_ACBDLR7_A06BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR7_RESERVED_15_14 0x0
Delay select for the BDL on Address A[5].
PSU_DDR_PHY_ACBDLR7_A05BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR7_RESERVED_7_6 0x0
Delay select for the BDL on Address A[4].
PSU_DDR_PHY_ACBDLR7_A04BD 0x0
AC Bit Delay Line Register 7
(OFFSET, MASK, VALUE) (0XFD08055C, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR7_RESERVED_31_30_MASK | DDR_PHY_ACBDLR7_A07BD_MASK | DDR_PHY_ACBDLR7_RESERVED_23_22_MASK | DDR_PHY_ACBDLR7_A06BD_MASK | DDR_PHY_ACBDLR7_RESERVED_15_14_MASK | DDR_PHY_ACBDLR7_A05BD_MASK | DDR_PHY_ACBDLR7_RESERVED_7_6_MASK | DDR_PHY_ACBDLR7_A04BD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR7_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_A07BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_A06BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_A05BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR7_A04BD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR7_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ACBDLR8 @ 0XFD080560</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR8_RESERVED_31_30 0x0
Delay select for the BDL on Address A[11].
PSU_DDR_PHY_ACBDLR8_A11BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR8_RESERVED_23_22 0x0
Delay select for the BDL on Address A[10].
PSU_DDR_PHY_ACBDLR8_A10BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR8_RESERVED_15_14 0x0
Delay select for the BDL on Address A[9].
PSU_DDR_PHY_ACBDLR8_A09BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR8_RESERVED_7_6 0x0
Delay select for the BDL on Address A[8].
PSU_DDR_PHY_ACBDLR8_A08BD 0x0
AC Bit Delay Line Register 8
(OFFSET, MASK, VALUE) (0XFD080560, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR8_RESERVED_31_30_MASK | DDR_PHY_ACBDLR8_A11BD_MASK | DDR_PHY_ACBDLR8_RESERVED_23_22_MASK | DDR_PHY_ACBDLR8_A10BD_MASK | DDR_PHY_ACBDLR8_RESERVED_15_14_MASK | DDR_PHY_ACBDLR8_A09BD_MASK | DDR_PHY_ACBDLR8_RESERVED_7_6_MASK | DDR_PHY_ACBDLR8_A08BD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR8_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_A11BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_A10BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_A09BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR8_A08BD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR8_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ACBDLR9 @ 0XFD080564</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR9_RESERVED_31_30 0x0
Delay select for the BDL on Address A[15].
PSU_DDR_PHY_ACBDLR9_A15BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR9_RESERVED_23_22 0x0
Delay select for the BDL on Address A[14].
PSU_DDR_PHY_ACBDLR9_A14BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR9_RESERVED_15_14 0x0
Delay select for the BDL on Address A[13].
PSU_DDR_PHY_ACBDLR9_A13BD 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ACBDLR9_RESERVED_7_6 0x0
Delay select for the BDL on Address A[12].
PSU_DDR_PHY_ACBDLR9_A12BD 0x0
AC Bit Delay Line Register 9
(OFFSET, MASK, VALUE) (0XFD080564, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_ACBDLR9_RESERVED_31_30_MASK | DDR_PHY_ACBDLR9_A15BD_MASK | DDR_PHY_ACBDLR9_RESERVED_23_22_MASK | DDR_PHY_ACBDLR9_A14BD_MASK | DDR_PHY_ACBDLR9_RESERVED_15_14_MASK | DDR_PHY_ACBDLR9_A13BD_MASK | DDR_PHY_ACBDLR9_RESERVED_7_6_MASK | DDR_PHY_ACBDLR9_A12BD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ACBDLR9_RESERVED_31_30_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_A15BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_RESERVED_23_22_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_A14BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_RESERVED_15_14_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_A13BD_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_RESERVED_7_6_SHIFT
| 0x00000000U << DDR_PHY_ACBDLR9_A12BD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ACBDLR9_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : ZQCR @ 0XFD080680</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_ZQCR_RESERVED_31_26 0x0
ZQ VREF Range
PSU_DDR_PHY_ZQCR_ZQREFISELRANGE 0x0
Programmable Wait for Frequency B
PSU_DDR_PHY_ZQCR_PGWAIT_FRQB 0x11
Programmable Wait for Frequency A
PSU_DDR_PHY_ZQCR_PGWAIT_FRQA 0x11
ZQ VREF Pad Enable
PSU_DDR_PHY_ZQCR_ZQREFPEN 0x0
ZQ Internal VREF Enable
PSU_DDR_PHY_ZQCR_ZQREFIEN 0x1
Choice of termination mode
PSU_DDR_PHY_ZQCR_ODT_MODE 0x1
Force ZCAL VT update
PSU_DDR_PHY_ZQCR_FORCE_ZCAL_VT_UPDATE 0x0
IO VT Drift Limit
PSU_DDR_PHY_ZQCR_IODLMT 0x2
Averaging algorithm enable, if set, enables averaging algorithm
PSU_DDR_PHY_ZQCR_AVGEN 0x1
Maximum number of averaging rounds to be used by averaging algorithm
PSU_DDR_PHY_ZQCR_AVGMAX 0x2
ZQ Calibration Type
PSU_DDR_PHY_ZQCR_ZCALT 0x0
ZQ Power Down
PSU_DDR_PHY_ZQCR_ZQPD 0x0
ZQ Impedance Control Register
(OFFSET, MASK, VALUE) (0XFD080680, 0xFFFFFFFFU ,0x008A2A58U)
RegMask = (DDR_PHY_ZQCR_RESERVED_31_26_MASK | DDR_PHY_ZQCR_ZQREFISELRANGE_MASK | DDR_PHY_ZQCR_PGWAIT_FRQB_MASK | DDR_PHY_ZQCR_PGWAIT_FRQA_MASK | DDR_PHY_ZQCR_ZQREFPEN_MASK | DDR_PHY_ZQCR_ZQREFIEN_MASK | DDR_PHY_ZQCR_ODT_MODE_MASK | DDR_PHY_ZQCR_FORCE_ZCAL_VT_UPDATE_MASK | DDR_PHY_ZQCR_IODLMT_MASK | DDR_PHY_ZQCR_AVGEN_MASK | DDR_PHY_ZQCR_AVGMAX_MASK | DDR_PHY_ZQCR_ZCALT_MASK | DDR_PHY_ZQCR_ZQPD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ZQCR_RESERVED_31_26_SHIFT
| 0x00000000U << DDR_PHY_ZQCR_ZQREFISELRANGE_SHIFT
| 0x00000011U << DDR_PHY_ZQCR_PGWAIT_FRQB_SHIFT
| 0x00000011U << DDR_PHY_ZQCR_PGWAIT_FRQA_SHIFT
| 0x00000000U << DDR_PHY_ZQCR_ZQREFPEN_SHIFT
| 0x00000001U << DDR_PHY_ZQCR_ZQREFIEN_SHIFT
| 0x00000001U << DDR_PHY_ZQCR_ODT_MODE_SHIFT
| 0x00000000U << DDR_PHY_ZQCR_FORCE_ZCAL_VT_UPDATE_SHIFT
| 0x00000002U << DDR_PHY_ZQCR_IODLMT_SHIFT
| 0x00000001U << DDR_PHY_ZQCR_AVGEN_SHIFT
| 0x00000002U << DDR_PHY_ZQCR_AVGMAX_SHIFT
| 0x00000000U << DDR_PHY_ZQCR_ZCALT_SHIFT
| 0x00000000U << DDR_PHY_ZQCR_ZQPD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ZQCR_OFFSET ,0xFFFFFFFFU ,0x008A2A58U);
/*############################################################################################################################ */
/*Register : ZQ0PR0 @ 0XFD080684</p>
Pull-down drive strength ZCTRL over-ride enable
PSU_DDR_PHY_ZQ0PR0_PD_DRV_ZDEN 0x0
Pull-up drive strength ZCTRL over-ride enable
PSU_DDR_PHY_ZQ0PR0_PU_DRV_ZDEN 0x0
Pull-down termination ZCTRL over-ride enable
PSU_DDR_PHY_ZQ0PR0_PD_ODT_ZDEN 0x0
Pull-up termination ZCTRL over-ride enable
PSU_DDR_PHY_ZQ0PR0_PU_ODT_ZDEN 0x0
Calibration segment bypass
PSU_DDR_PHY_ZQ0PR0_ZSEGBYP 0x0
VREF latch mode controls the mode in which the ZLE pin of the PVREF cell is driven by the PUB
PSU_DDR_PHY_ZQ0PR0_ZLE_MODE 0x0
Termination adjustment
PSU_DDR_PHY_ZQ0PR0_ODT_ADJUST 0x0
Pulldown drive strength adjustment
PSU_DDR_PHY_ZQ0PR0_PD_DRV_ADJUST 0x0
Pullup drive strength adjustment
PSU_DDR_PHY_ZQ0PR0_PU_DRV_ADJUST 0x0
DRAM Impedance Divide Ratio
PSU_DDR_PHY_ZQ0PR0_ZPROG_DRAM_ODT 0x7
HOST Impedance Divide Ratio
PSU_DDR_PHY_ZQ0PR0_ZPROG_HOST_ODT 0x7
Impedance Divide Ratio (pulldown drive calibration during asymmetric drive strength calibration)
PSU_DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PD 0xd
Impedance Divide Ratio (pullup drive calibration during asymmetric drive strength calibration)
PSU_DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PU 0xd
ZQ n Impedance Control Program Register 0
(OFFSET, MASK, VALUE) (0XFD080684, 0xFFFFFFFFU ,0x000077DDU)
RegMask = (DDR_PHY_ZQ0PR0_PD_DRV_ZDEN_MASK | DDR_PHY_ZQ0PR0_PU_DRV_ZDEN_MASK | DDR_PHY_ZQ0PR0_PD_ODT_ZDEN_MASK | DDR_PHY_ZQ0PR0_PU_ODT_ZDEN_MASK | DDR_PHY_ZQ0PR0_ZSEGBYP_MASK | DDR_PHY_ZQ0PR0_ZLE_MODE_MASK | DDR_PHY_ZQ0PR0_ODT_ADJUST_MASK | DDR_PHY_ZQ0PR0_PD_DRV_ADJUST_MASK | DDR_PHY_ZQ0PR0_PU_DRV_ADJUST_MASK | DDR_PHY_ZQ0PR0_ZPROG_DRAM_ODT_MASK | DDR_PHY_ZQ0PR0_ZPROG_HOST_ODT_MASK | DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PD_MASK | DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PU_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ZQ0PR0_PD_DRV_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_PU_DRV_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_PD_ODT_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_PU_ODT_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_ZSEGBYP_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_ZLE_MODE_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_ODT_ADJUST_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_PD_DRV_ADJUST_SHIFT
| 0x00000000U << DDR_PHY_ZQ0PR0_PU_DRV_ADJUST_SHIFT
| 0x00000007U << DDR_PHY_ZQ0PR0_ZPROG_DRAM_ODT_SHIFT
| 0x00000007U << DDR_PHY_ZQ0PR0_ZPROG_HOST_ODT_SHIFT
| 0x0000000DU << DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PD_SHIFT
| 0x0000000DU << DDR_PHY_ZQ0PR0_ZPROG_ASYM_DRV_PU_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ZQ0PR0_OFFSET ,0xFFFFFFFFU ,0x000077DDU);
/*############################################################################################################################ */
/*Register : ZQ0OR0 @ 0XFD080694</p>
Reserved. Return zeros on reads.
PSU_DDR_PHY_ZQ0OR0_RESERVED_31_26 0x0
Override value for the pull-up output impedance
PSU_DDR_PHY_ZQ0OR0_ZDATA_PU_DRV_OVRD 0x1e1
Reserved. Return zeros on reads.
PSU_DDR_PHY_ZQ0OR0_RESERVED_15_10 0x0
Override value for the pull-down output impedance
PSU_DDR_PHY_ZQ0OR0_ZDATA_PD_DRV_OVRD 0x210
ZQ n Impedance Control Override Data Register 0
(OFFSET, MASK, VALUE) (0XFD080694, 0xFFFFFFFFU ,0x01E10210U)
RegMask = (DDR_PHY_ZQ0OR0_RESERVED_31_26_MASK | DDR_PHY_ZQ0OR0_ZDATA_PU_DRV_OVRD_MASK | DDR_PHY_ZQ0OR0_RESERVED_15_10_MASK | DDR_PHY_ZQ0OR0_ZDATA_PD_DRV_OVRD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ZQ0OR0_RESERVED_31_26_SHIFT
| 0x000001E1U << DDR_PHY_ZQ0OR0_ZDATA_PU_DRV_OVRD_SHIFT
| 0x00000000U << DDR_PHY_ZQ0OR0_RESERVED_15_10_SHIFT
| 0x00000210U << DDR_PHY_ZQ0OR0_ZDATA_PD_DRV_OVRD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ZQ0OR0_OFFSET ,0xFFFFFFFFU ,0x01E10210U);
/*############################################################################################################################ */
/*Register : ZQ0OR1 @ 0XFD080698</p>
Reserved. Return zeros on reads.
PSU_DDR_PHY_ZQ0OR1_RESERVED_31_26 0x0
Override value for the pull-up termination
PSU_DDR_PHY_ZQ0OR1_ZDATA_PU_ODT_OVRD 0x1e1
Reserved. Return zeros on reads.
PSU_DDR_PHY_ZQ0OR1_RESERVED_15_10 0x0
Override value for the pull-down termination
PSU_DDR_PHY_ZQ0OR1_ZDATA_PD_ODT_OVRD 0x0
ZQ n Impedance Control Override Data Register 1
(OFFSET, MASK, VALUE) (0XFD080698, 0xFFFFFFFFU ,0x01E10000U)
RegMask = (DDR_PHY_ZQ0OR1_RESERVED_31_26_MASK | DDR_PHY_ZQ0OR1_ZDATA_PU_ODT_OVRD_MASK | DDR_PHY_ZQ0OR1_RESERVED_15_10_MASK | DDR_PHY_ZQ0OR1_ZDATA_PD_ODT_OVRD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ZQ0OR1_RESERVED_31_26_SHIFT
| 0x000001E1U << DDR_PHY_ZQ0OR1_ZDATA_PU_ODT_OVRD_SHIFT
| 0x00000000U << DDR_PHY_ZQ0OR1_RESERVED_15_10_SHIFT
| 0x00000000U << DDR_PHY_ZQ0OR1_ZDATA_PD_ODT_OVRD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ZQ0OR1_OFFSET ,0xFFFFFFFFU ,0x01E10000U);
/*############################################################################################################################ */
/*Register : ZQ1PR0 @ 0XFD0806A4</p>
Pull-down drive strength ZCTRL over-ride enable
PSU_DDR_PHY_ZQ1PR0_PD_DRV_ZDEN 0x0
Pull-up drive strength ZCTRL over-ride enable
PSU_DDR_PHY_ZQ1PR0_PU_DRV_ZDEN 0x0
Pull-down termination ZCTRL over-ride enable
PSU_DDR_PHY_ZQ1PR0_PD_ODT_ZDEN 0x0
Pull-up termination ZCTRL over-ride enable
PSU_DDR_PHY_ZQ1PR0_PU_ODT_ZDEN 0x0
Calibration segment bypass
PSU_DDR_PHY_ZQ1PR0_ZSEGBYP 0x0
VREF latch mode controls the mode in which the ZLE pin of the PVREF cell is driven by the PUB
PSU_DDR_PHY_ZQ1PR0_ZLE_MODE 0x0
Termination adjustment
PSU_DDR_PHY_ZQ1PR0_ODT_ADJUST 0x0
Pulldown drive strength adjustment
PSU_DDR_PHY_ZQ1PR0_PD_DRV_ADJUST 0x1
Pullup drive strength adjustment
PSU_DDR_PHY_ZQ1PR0_PU_DRV_ADJUST 0x0
DRAM Impedance Divide Ratio
PSU_DDR_PHY_ZQ1PR0_ZPROG_DRAM_ODT 0x7
HOST Impedance Divide Ratio
PSU_DDR_PHY_ZQ1PR0_ZPROG_HOST_ODT 0xb
Impedance Divide Ratio (pulldown drive calibration during asymmetric drive strength calibration)
PSU_DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PD 0xd
Impedance Divide Ratio (pullup drive calibration during asymmetric drive strength calibration)
PSU_DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PU 0xb
ZQ n Impedance Control Program Register 0
(OFFSET, MASK, VALUE) (0XFD0806A4, 0xFFFFFFFFU ,0x00087BDBU)
RegMask = (DDR_PHY_ZQ1PR0_PD_DRV_ZDEN_MASK | DDR_PHY_ZQ1PR0_PU_DRV_ZDEN_MASK | DDR_PHY_ZQ1PR0_PD_ODT_ZDEN_MASK | DDR_PHY_ZQ1PR0_PU_ODT_ZDEN_MASK | DDR_PHY_ZQ1PR0_ZSEGBYP_MASK | DDR_PHY_ZQ1PR0_ZLE_MODE_MASK | DDR_PHY_ZQ1PR0_ODT_ADJUST_MASK | DDR_PHY_ZQ1PR0_PD_DRV_ADJUST_MASK | DDR_PHY_ZQ1PR0_PU_DRV_ADJUST_MASK | DDR_PHY_ZQ1PR0_ZPROG_DRAM_ODT_MASK | DDR_PHY_ZQ1PR0_ZPROG_HOST_ODT_MASK | DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PD_MASK | DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PU_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_ZQ1PR0_PD_DRV_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_PU_DRV_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_PD_ODT_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_PU_ODT_ZDEN_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_ZSEGBYP_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_ZLE_MODE_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_ODT_ADJUST_SHIFT
| 0x00000001U << DDR_PHY_ZQ1PR0_PD_DRV_ADJUST_SHIFT
| 0x00000000U << DDR_PHY_ZQ1PR0_PU_DRV_ADJUST_SHIFT
| 0x00000007U << DDR_PHY_ZQ1PR0_ZPROG_DRAM_ODT_SHIFT
| 0x0000000BU << DDR_PHY_ZQ1PR0_ZPROG_HOST_ODT_SHIFT
| 0x0000000DU << DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PD_SHIFT
| 0x0000000BU << DDR_PHY_ZQ1PR0_ZPROG_ASYM_DRV_PU_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_ZQ1PR0_OFFSET ,0xFFFFFFFFU ,0x00087BDBU);
/*############################################################################################################################ */
/*Register : DX0GCR0 @ 0XFD080700</p>
Calibration Bypass
PSU_DDR_PHY_DX0GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX0GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX0GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX0GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX0GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX0GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX0GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX0GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX0GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX0GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX0GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX0GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX0GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX0GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080700, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX0GCR0_CALBYP_MASK | DDR_PHY_DX0GCR0_MDLEN_MASK | DDR_PHY_DX0GCR0_CODTSHFT_MASK | DDR_PHY_DX0GCR0_DQSDCC_MASK | DDR_PHY_DX0GCR0_RDDLY_MASK | DDR_PHY_DX0GCR0_RESERVED_19_14_MASK | DDR_PHY_DX0GCR0_DQSNSEPDR_MASK | DDR_PHY_DX0GCR0_DQSSEPDR_MASK | DDR_PHY_DX0GCR0_RTTOAL_MASK | DDR_PHY_DX0GCR0_RTTOH_MASK | DDR_PHY_DX0GCR0_CPDRSHFT_MASK | DDR_PHY_DX0GCR0_DQSRPD_MASK | DDR_PHY_DX0GCR0_DQSGPDR_MASK | DDR_PHY_DX0GCR0_RESERVED_4_MASK | DDR_PHY_DX0GCR0_DQSGODT_MASK | DDR_PHY_DX0GCR0_DQSGOE_MASK | DDR_PHY_DX0GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX0GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX0GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX0GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX0GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX0GCR4 @ 0XFD080710</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX0GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX0GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX0GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX0GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX0GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX0GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX0GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX0GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX0GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX0GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080710, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX0GCR4_RESERVED_31_29_MASK | DDR_PHY_DX0GCR4_DXREFPEN_MASK | DDR_PHY_DX0GCR4_DXREFEEN_MASK | DDR_PHY_DX0GCR4_DXREFSEN_MASK | DDR_PHY_DX0GCR4_RESERVED_24_MASK | DDR_PHY_DX0GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX0GCR4_DXREFESEL_MASK | DDR_PHY_DX0GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX0GCR4_DXREFSSEL_MASK | DDR_PHY_DX0GCR4_RESERVED_7_6_MASK | DDR_PHY_DX0GCR4_DXREFIEN_MASK | DDR_PHY_DX0GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX0GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX0GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX0GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX0GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX0GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX0GCR5 @ 0XFD080714</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX0GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX0GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX0GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX0GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080714, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX0GCR5_RESERVED_31_MASK | DDR_PHY_DX0GCR5_DXREFISELR3_MASK | DDR_PHY_DX0GCR5_RESERVED_23_MASK | DDR_PHY_DX0GCR5_DXREFISELR2_MASK | DDR_PHY_DX0GCR5_RESERVED_15_MASK | DDR_PHY_DX0GCR5_DXREFISELR1_MASK | DDR_PHY_DX0GCR5_RESERVED_7_MASK | DDR_PHY_DX0GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX0GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX0GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX0GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX0GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX0GCR6 @ 0XFD080718</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX0GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX0GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX0GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX0GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX0GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080718, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX0GCR6_RESERVED_31_30_MASK | DDR_PHY_DX0GCR6_DXDQVREFR3_MASK | DDR_PHY_DX0GCR6_RESERVED_23_22_MASK | DDR_PHY_DX0GCR6_DXDQVREFR2_MASK | DDR_PHY_DX0GCR6_RESERVED_15_14_MASK | DDR_PHY_DX0GCR6_DXDQVREFR1_MASK | DDR_PHY_DX0GCR6_RESERVED_7_6_MASK | DDR_PHY_DX0GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX0GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX0GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX0GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX0GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX0GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX0LCDLR2 @ 0XFD080788</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX0LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX0LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080788, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX0LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX0LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX0LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX0LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX0LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX0LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX0LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX0GTR0 @ 0XFD0807C0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX0GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX0GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX0GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX0GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX0GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX0GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD0807C0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX0GTR0_RESERVED_31_24_MASK | DDR_PHY_DX0GTR0_WDQSL_MASK | DDR_PHY_DX0GTR0_RESERVED_23_20_MASK | DDR_PHY_DX0GTR0_WLSL_MASK | DDR_PHY_DX0GTR0_RESERVED_15_13_MASK | DDR_PHY_DX0GTR0_RESERVED_12_8_MASK | DDR_PHY_DX0GTR0_RESERVED_7_5_MASK | DDR_PHY_DX0GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX0GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX0GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX0GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX0GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX1GCR0 @ 0XFD080800</p>
Calibration Bypass
PSU_DDR_PHY_DX1GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX1GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX1GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX1GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX1GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX1GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX1GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX1GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX1GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX1GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX1GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX1GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX1GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX1GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080800, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX1GCR0_CALBYP_MASK | DDR_PHY_DX1GCR0_MDLEN_MASK | DDR_PHY_DX1GCR0_CODTSHFT_MASK | DDR_PHY_DX1GCR0_DQSDCC_MASK | DDR_PHY_DX1GCR0_RDDLY_MASK | DDR_PHY_DX1GCR0_RESERVED_19_14_MASK | DDR_PHY_DX1GCR0_DQSNSEPDR_MASK | DDR_PHY_DX1GCR0_DQSSEPDR_MASK | DDR_PHY_DX1GCR0_RTTOAL_MASK | DDR_PHY_DX1GCR0_RTTOH_MASK | DDR_PHY_DX1GCR0_CPDRSHFT_MASK | DDR_PHY_DX1GCR0_DQSRPD_MASK | DDR_PHY_DX1GCR0_DQSGPDR_MASK | DDR_PHY_DX1GCR0_RESERVED_4_MASK | DDR_PHY_DX1GCR0_DQSGODT_MASK | DDR_PHY_DX1GCR0_DQSGOE_MASK | DDR_PHY_DX1GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX1GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX1GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX1GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX1GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX1GCR4 @ 0XFD080810</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX1GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX1GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX1GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX1GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX1GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX1GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX1GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX1GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX1GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX1GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080810, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX1GCR4_RESERVED_31_29_MASK | DDR_PHY_DX1GCR4_DXREFPEN_MASK | DDR_PHY_DX1GCR4_DXREFEEN_MASK | DDR_PHY_DX1GCR4_DXREFSEN_MASK | DDR_PHY_DX1GCR4_RESERVED_24_MASK | DDR_PHY_DX1GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX1GCR4_DXREFESEL_MASK | DDR_PHY_DX1GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX1GCR4_DXREFSSEL_MASK | DDR_PHY_DX1GCR4_RESERVED_7_6_MASK | DDR_PHY_DX1GCR4_DXREFIEN_MASK | DDR_PHY_DX1GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX1GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX1GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX1GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX1GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX1GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX1GCR5 @ 0XFD080814</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX1GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX1GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX1GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX1GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080814, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX1GCR5_RESERVED_31_MASK | DDR_PHY_DX1GCR5_DXREFISELR3_MASK | DDR_PHY_DX1GCR5_RESERVED_23_MASK | DDR_PHY_DX1GCR5_DXREFISELR2_MASK | DDR_PHY_DX1GCR5_RESERVED_15_MASK | DDR_PHY_DX1GCR5_DXREFISELR1_MASK | DDR_PHY_DX1GCR5_RESERVED_7_MASK | DDR_PHY_DX1GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX1GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX1GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX1GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX1GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX1GCR6 @ 0XFD080818</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX1GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX1GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX1GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX1GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX1GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080818, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX1GCR6_RESERVED_31_30_MASK | DDR_PHY_DX1GCR6_DXDQVREFR3_MASK | DDR_PHY_DX1GCR6_RESERVED_23_22_MASK | DDR_PHY_DX1GCR6_DXDQVREFR2_MASK | DDR_PHY_DX1GCR6_RESERVED_15_14_MASK | DDR_PHY_DX1GCR6_DXDQVREFR1_MASK | DDR_PHY_DX1GCR6_RESERVED_7_6_MASK | DDR_PHY_DX1GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX1GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX1GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX1GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX1GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX1GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX1LCDLR2 @ 0XFD080888</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX1LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX1LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080888, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX1LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX1LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX1LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX1LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX1LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX1LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX1LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX1GTR0 @ 0XFD0808C0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX1GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX1GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX1GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX1GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX1GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX1GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD0808C0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX1GTR0_RESERVED_31_24_MASK | DDR_PHY_DX1GTR0_WDQSL_MASK | DDR_PHY_DX1GTR0_RESERVED_23_20_MASK | DDR_PHY_DX1GTR0_WLSL_MASK | DDR_PHY_DX1GTR0_RESERVED_15_13_MASK | DDR_PHY_DX1GTR0_RESERVED_12_8_MASK | DDR_PHY_DX1GTR0_RESERVED_7_5_MASK | DDR_PHY_DX1GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX1GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX1GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX1GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX1GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX2GCR0 @ 0XFD080900</p>
Calibration Bypass
PSU_DDR_PHY_DX2GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX2GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX2GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX2GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX2GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX2GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX2GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX2GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX2GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX2GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX2GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX2GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX2GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX2GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080900, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX2GCR0_CALBYP_MASK | DDR_PHY_DX2GCR0_MDLEN_MASK | DDR_PHY_DX2GCR0_CODTSHFT_MASK | DDR_PHY_DX2GCR0_DQSDCC_MASK | DDR_PHY_DX2GCR0_RDDLY_MASK | DDR_PHY_DX2GCR0_RESERVED_19_14_MASK | DDR_PHY_DX2GCR0_DQSNSEPDR_MASK | DDR_PHY_DX2GCR0_DQSSEPDR_MASK | DDR_PHY_DX2GCR0_RTTOAL_MASK | DDR_PHY_DX2GCR0_RTTOH_MASK | DDR_PHY_DX2GCR0_CPDRSHFT_MASK | DDR_PHY_DX2GCR0_DQSRPD_MASK | DDR_PHY_DX2GCR0_DQSGPDR_MASK | DDR_PHY_DX2GCR0_RESERVED_4_MASK | DDR_PHY_DX2GCR0_DQSGODT_MASK | DDR_PHY_DX2GCR0_DQSGOE_MASK | DDR_PHY_DX2GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX2GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX2GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX2GCR1 @ 0XFD080904</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX2GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX2GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX2GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX2GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX2GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX2GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX2GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX2GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX2GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX2GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080904, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX2GCR1_DXPDRMODE_MASK | DDR_PHY_DX2GCR1_RESERVED_15_MASK | DDR_PHY_DX2GCR1_QSNSEL_MASK | DDR_PHY_DX2GCR1_QSSEL_MASK | DDR_PHY_DX2GCR1_OEEN_MASK | DDR_PHY_DX2GCR1_PDREN_MASK | DDR_PHY_DX2GCR1_TEEN_MASK | DDR_PHY_DX2GCR1_DSEN_MASK | DDR_PHY_DX2GCR1_DMEN_MASK | DDR_PHY_DX2GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX2GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX2GCR4 @ 0XFD080910</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX2GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX2GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX2GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX2GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX2GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX2GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX2GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX2GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX2GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX2GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080910, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX2GCR4_RESERVED_31_29_MASK | DDR_PHY_DX2GCR4_DXREFPEN_MASK | DDR_PHY_DX2GCR4_DXREFEEN_MASK | DDR_PHY_DX2GCR4_DXREFSEN_MASK | DDR_PHY_DX2GCR4_RESERVED_24_MASK | DDR_PHY_DX2GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX2GCR4_DXREFESEL_MASK | DDR_PHY_DX2GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX2GCR4_DXREFSSEL_MASK | DDR_PHY_DX2GCR4_RESERVED_7_6_MASK | DDR_PHY_DX2GCR4_DXREFIEN_MASK | DDR_PHY_DX2GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX2GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX2GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX2GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX2GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX2GCR5 @ 0XFD080914</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX2GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX2GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX2GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX2GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080914, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX2GCR5_RESERVED_31_MASK | DDR_PHY_DX2GCR5_DXREFISELR3_MASK | DDR_PHY_DX2GCR5_RESERVED_23_MASK | DDR_PHY_DX2GCR5_DXREFISELR2_MASK | DDR_PHY_DX2GCR5_RESERVED_15_MASK | DDR_PHY_DX2GCR5_DXREFISELR1_MASK | DDR_PHY_DX2GCR5_RESERVED_7_MASK | DDR_PHY_DX2GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX2GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX2GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX2GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX2GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX2GCR6 @ 0XFD080918</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX2GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX2GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX2GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX2GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX2GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080918, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX2GCR6_RESERVED_31_30_MASK | DDR_PHY_DX2GCR6_DXDQVREFR3_MASK | DDR_PHY_DX2GCR6_RESERVED_23_22_MASK | DDR_PHY_DX2GCR6_DXDQVREFR2_MASK | DDR_PHY_DX2GCR6_RESERVED_15_14_MASK | DDR_PHY_DX2GCR6_DXDQVREFR1_MASK | DDR_PHY_DX2GCR6_RESERVED_7_6_MASK | DDR_PHY_DX2GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX2GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX2GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX2GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX2GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX2GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX2LCDLR2 @ 0XFD080988</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX2LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX2LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080988, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX2LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX2LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX2LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX2LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX2LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX2LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX2LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX2GTR0 @ 0XFD0809C0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX2GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX2GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX2GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX2GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX2GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX2GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD0809C0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX2GTR0_RESERVED_31_24_MASK | DDR_PHY_DX2GTR0_WDQSL_MASK | DDR_PHY_DX2GTR0_RESERVED_23_20_MASK | DDR_PHY_DX2GTR0_WLSL_MASK | DDR_PHY_DX2GTR0_RESERVED_15_13_MASK | DDR_PHY_DX2GTR0_RESERVED_12_8_MASK | DDR_PHY_DX2GTR0_RESERVED_7_5_MASK | DDR_PHY_DX2GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX2GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX2GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX2GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX2GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX3GCR0 @ 0XFD080A00</p>
Calibration Bypass
PSU_DDR_PHY_DX3GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX3GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX3GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX3GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX3GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX3GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX3GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX3GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX3GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX3GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX3GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX3GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX3GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX3GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080A00, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX3GCR0_CALBYP_MASK | DDR_PHY_DX3GCR0_MDLEN_MASK | DDR_PHY_DX3GCR0_CODTSHFT_MASK | DDR_PHY_DX3GCR0_DQSDCC_MASK | DDR_PHY_DX3GCR0_RDDLY_MASK | DDR_PHY_DX3GCR0_RESERVED_19_14_MASK | DDR_PHY_DX3GCR0_DQSNSEPDR_MASK | DDR_PHY_DX3GCR0_DQSSEPDR_MASK | DDR_PHY_DX3GCR0_RTTOAL_MASK | DDR_PHY_DX3GCR0_RTTOH_MASK | DDR_PHY_DX3GCR0_CPDRSHFT_MASK | DDR_PHY_DX3GCR0_DQSRPD_MASK | DDR_PHY_DX3GCR0_DQSGPDR_MASK | DDR_PHY_DX3GCR0_RESERVED_4_MASK | DDR_PHY_DX3GCR0_DQSGODT_MASK | DDR_PHY_DX3GCR0_DQSGOE_MASK | DDR_PHY_DX3GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX3GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX3GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX3GCR1 @ 0XFD080A04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX3GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX3GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX3GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX3GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX3GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX3GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX3GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX3GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX3GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX3GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080A04, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX3GCR1_DXPDRMODE_MASK | DDR_PHY_DX3GCR1_RESERVED_15_MASK | DDR_PHY_DX3GCR1_QSNSEL_MASK | DDR_PHY_DX3GCR1_QSSEL_MASK | DDR_PHY_DX3GCR1_OEEN_MASK | DDR_PHY_DX3GCR1_PDREN_MASK | DDR_PHY_DX3GCR1_TEEN_MASK | DDR_PHY_DX3GCR1_DSEN_MASK | DDR_PHY_DX3GCR1_DMEN_MASK | DDR_PHY_DX3GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX3GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX3GCR4 @ 0XFD080A10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX3GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX3GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX3GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX3GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX3GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX3GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX3GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX3GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX3GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX3GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080A10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX3GCR4_RESERVED_31_29_MASK | DDR_PHY_DX3GCR4_DXREFPEN_MASK | DDR_PHY_DX3GCR4_DXREFEEN_MASK | DDR_PHY_DX3GCR4_DXREFSEN_MASK | DDR_PHY_DX3GCR4_RESERVED_24_MASK | DDR_PHY_DX3GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX3GCR4_DXREFESEL_MASK | DDR_PHY_DX3GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX3GCR4_DXREFSSEL_MASK | DDR_PHY_DX3GCR4_RESERVED_7_6_MASK | DDR_PHY_DX3GCR4_DXREFIEN_MASK | DDR_PHY_DX3GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX3GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX3GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX3GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX3GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX3GCR5 @ 0XFD080A14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX3GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX3GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX3GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX3GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080A14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX3GCR5_RESERVED_31_MASK | DDR_PHY_DX3GCR5_DXREFISELR3_MASK | DDR_PHY_DX3GCR5_RESERVED_23_MASK | DDR_PHY_DX3GCR5_DXREFISELR2_MASK | DDR_PHY_DX3GCR5_RESERVED_15_MASK | DDR_PHY_DX3GCR5_DXREFISELR1_MASK | DDR_PHY_DX3GCR5_RESERVED_7_MASK | DDR_PHY_DX3GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX3GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX3GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX3GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX3GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX3GCR6 @ 0XFD080A18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX3GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX3GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX3GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX3GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX3GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080A18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX3GCR6_RESERVED_31_30_MASK | DDR_PHY_DX3GCR6_DXDQVREFR3_MASK | DDR_PHY_DX3GCR6_RESERVED_23_22_MASK | DDR_PHY_DX3GCR6_DXDQVREFR2_MASK | DDR_PHY_DX3GCR6_RESERVED_15_14_MASK | DDR_PHY_DX3GCR6_DXDQVREFR1_MASK | DDR_PHY_DX3GCR6_RESERVED_7_6_MASK | DDR_PHY_DX3GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX3GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX3GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX3GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX3GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX3GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX3LCDLR2 @ 0XFD080A88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX3LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX3LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080A88, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX3LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX3LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX3LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX3LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX3LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX3LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX3LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX3GTR0 @ 0XFD080AC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX3GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX3GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX3GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX3GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX3GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX3GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080AC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX3GTR0_RESERVED_31_24_MASK | DDR_PHY_DX3GTR0_WDQSL_MASK | DDR_PHY_DX3GTR0_RESERVED_23_20_MASK | DDR_PHY_DX3GTR0_WLSL_MASK | DDR_PHY_DX3GTR0_RESERVED_15_13_MASK | DDR_PHY_DX3GTR0_RESERVED_12_8_MASK | DDR_PHY_DX3GTR0_RESERVED_7_5_MASK | DDR_PHY_DX3GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX3GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX3GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX3GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX3GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX4GCR0 @ 0XFD080B00</p>
Calibration Bypass
PSU_DDR_PHY_DX4GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX4GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX4GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX4GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX4GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX4GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX4GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX4GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX4GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX4GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX4GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX4GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX4GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX4GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080B00, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX4GCR0_CALBYP_MASK | DDR_PHY_DX4GCR0_MDLEN_MASK | DDR_PHY_DX4GCR0_CODTSHFT_MASK | DDR_PHY_DX4GCR0_DQSDCC_MASK | DDR_PHY_DX4GCR0_RDDLY_MASK | DDR_PHY_DX4GCR0_RESERVED_19_14_MASK | DDR_PHY_DX4GCR0_DQSNSEPDR_MASK | DDR_PHY_DX4GCR0_DQSSEPDR_MASK | DDR_PHY_DX4GCR0_RTTOAL_MASK | DDR_PHY_DX4GCR0_RTTOH_MASK | DDR_PHY_DX4GCR0_CPDRSHFT_MASK | DDR_PHY_DX4GCR0_DQSRPD_MASK | DDR_PHY_DX4GCR0_DQSGPDR_MASK | DDR_PHY_DX4GCR0_RESERVED_4_MASK | DDR_PHY_DX4GCR0_DQSGODT_MASK | DDR_PHY_DX4GCR0_DQSGOE_MASK | DDR_PHY_DX4GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX4GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX4GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX4GCR1 @ 0XFD080B04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX4GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX4GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX4GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX4GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX4GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX4GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX4GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX4GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX4GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX4GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080B04, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX4GCR1_DXPDRMODE_MASK | DDR_PHY_DX4GCR1_RESERVED_15_MASK | DDR_PHY_DX4GCR1_QSNSEL_MASK | DDR_PHY_DX4GCR1_QSSEL_MASK | DDR_PHY_DX4GCR1_OEEN_MASK | DDR_PHY_DX4GCR1_PDREN_MASK | DDR_PHY_DX4GCR1_TEEN_MASK | DDR_PHY_DX4GCR1_DSEN_MASK | DDR_PHY_DX4GCR1_DMEN_MASK | DDR_PHY_DX4GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX4GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX4GCR4 @ 0XFD080B10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX4GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX4GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX4GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX4GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX4GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX4GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX4GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX4GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX4GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX4GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080B10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX4GCR4_RESERVED_31_29_MASK | DDR_PHY_DX4GCR4_DXREFPEN_MASK | DDR_PHY_DX4GCR4_DXREFEEN_MASK | DDR_PHY_DX4GCR4_DXREFSEN_MASK | DDR_PHY_DX4GCR4_RESERVED_24_MASK | DDR_PHY_DX4GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX4GCR4_DXREFESEL_MASK | DDR_PHY_DX4GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX4GCR4_DXREFSSEL_MASK | DDR_PHY_DX4GCR4_RESERVED_7_6_MASK | DDR_PHY_DX4GCR4_DXREFIEN_MASK | DDR_PHY_DX4GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX4GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX4GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX4GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX4GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX4GCR5 @ 0XFD080B14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX4GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX4GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX4GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX4GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080B14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX4GCR5_RESERVED_31_MASK | DDR_PHY_DX4GCR5_DXREFISELR3_MASK | DDR_PHY_DX4GCR5_RESERVED_23_MASK | DDR_PHY_DX4GCR5_DXREFISELR2_MASK | DDR_PHY_DX4GCR5_RESERVED_15_MASK | DDR_PHY_DX4GCR5_DXREFISELR1_MASK | DDR_PHY_DX4GCR5_RESERVED_7_MASK | DDR_PHY_DX4GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX4GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX4GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX4GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX4GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX4GCR6 @ 0XFD080B18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX4GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX4GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX4GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX4GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX4GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080B18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX4GCR6_RESERVED_31_30_MASK | DDR_PHY_DX4GCR6_DXDQVREFR3_MASK | DDR_PHY_DX4GCR6_RESERVED_23_22_MASK | DDR_PHY_DX4GCR6_DXDQVREFR2_MASK | DDR_PHY_DX4GCR6_RESERVED_15_14_MASK | DDR_PHY_DX4GCR6_DXDQVREFR1_MASK | DDR_PHY_DX4GCR6_RESERVED_7_6_MASK | DDR_PHY_DX4GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX4GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX4GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX4GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX4GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX4GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX4LCDLR2 @ 0XFD080B88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX4LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX4LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080B88, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX4LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX4LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX4LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX4LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX4LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX4LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX4LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX4GTR0 @ 0XFD080BC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX4GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX4GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX4GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX4GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX4GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX4GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080BC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX4GTR0_RESERVED_31_24_MASK | DDR_PHY_DX4GTR0_WDQSL_MASK | DDR_PHY_DX4GTR0_RESERVED_23_20_MASK | DDR_PHY_DX4GTR0_WLSL_MASK | DDR_PHY_DX4GTR0_RESERVED_15_13_MASK | DDR_PHY_DX4GTR0_RESERVED_12_8_MASK | DDR_PHY_DX4GTR0_RESERVED_7_5_MASK | DDR_PHY_DX4GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX4GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX4GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX4GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX4GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX5GCR0 @ 0XFD080C00</p>
Calibration Bypass
PSU_DDR_PHY_DX5GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX5GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX5GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX5GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX5GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX5GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX5GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX5GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX5GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX5GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX5GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX5GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX5GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX5GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080C00, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX5GCR0_CALBYP_MASK | DDR_PHY_DX5GCR0_MDLEN_MASK | DDR_PHY_DX5GCR0_CODTSHFT_MASK | DDR_PHY_DX5GCR0_DQSDCC_MASK | DDR_PHY_DX5GCR0_RDDLY_MASK | DDR_PHY_DX5GCR0_RESERVED_19_14_MASK | DDR_PHY_DX5GCR0_DQSNSEPDR_MASK | DDR_PHY_DX5GCR0_DQSSEPDR_MASK | DDR_PHY_DX5GCR0_RTTOAL_MASK | DDR_PHY_DX5GCR0_RTTOH_MASK | DDR_PHY_DX5GCR0_CPDRSHFT_MASK | DDR_PHY_DX5GCR0_DQSRPD_MASK | DDR_PHY_DX5GCR0_DQSGPDR_MASK | DDR_PHY_DX5GCR0_RESERVED_4_MASK | DDR_PHY_DX5GCR0_DQSGODT_MASK | DDR_PHY_DX5GCR0_DQSGOE_MASK | DDR_PHY_DX5GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX5GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX5GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX5GCR1 @ 0XFD080C04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX5GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX5GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX5GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX5GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX5GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX5GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX5GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX5GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX5GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX5GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080C04, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX5GCR1_DXPDRMODE_MASK | DDR_PHY_DX5GCR1_RESERVED_15_MASK | DDR_PHY_DX5GCR1_QSNSEL_MASK | DDR_PHY_DX5GCR1_QSSEL_MASK | DDR_PHY_DX5GCR1_OEEN_MASK | DDR_PHY_DX5GCR1_PDREN_MASK | DDR_PHY_DX5GCR1_TEEN_MASK | DDR_PHY_DX5GCR1_DSEN_MASK | DDR_PHY_DX5GCR1_DMEN_MASK | DDR_PHY_DX5GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX5GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX5GCR4 @ 0XFD080C10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX5GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX5GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX5GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX5GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX5GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX5GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX5GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX5GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX5GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX5GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080C10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX5GCR4_RESERVED_31_29_MASK | DDR_PHY_DX5GCR4_DXREFPEN_MASK | DDR_PHY_DX5GCR4_DXREFEEN_MASK | DDR_PHY_DX5GCR4_DXREFSEN_MASK | DDR_PHY_DX5GCR4_RESERVED_24_MASK | DDR_PHY_DX5GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX5GCR4_DXREFESEL_MASK | DDR_PHY_DX5GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX5GCR4_DXREFSSEL_MASK | DDR_PHY_DX5GCR4_RESERVED_7_6_MASK | DDR_PHY_DX5GCR4_DXREFIEN_MASK | DDR_PHY_DX5GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX5GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX5GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX5GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX5GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX5GCR5 @ 0XFD080C14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX5GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX5GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX5GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX5GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080C14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX5GCR5_RESERVED_31_MASK | DDR_PHY_DX5GCR5_DXREFISELR3_MASK | DDR_PHY_DX5GCR5_RESERVED_23_MASK | DDR_PHY_DX5GCR5_DXREFISELR2_MASK | DDR_PHY_DX5GCR5_RESERVED_15_MASK | DDR_PHY_DX5GCR5_DXREFISELR1_MASK | DDR_PHY_DX5GCR5_RESERVED_7_MASK | DDR_PHY_DX5GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX5GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX5GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX5GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX5GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX5GCR6 @ 0XFD080C18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX5GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX5GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX5GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX5GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX5GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080C18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX5GCR6_RESERVED_31_30_MASK | DDR_PHY_DX5GCR6_DXDQVREFR3_MASK | DDR_PHY_DX5GCR6_RESERVED_23_22_MASK | DDR_PHY_DX5GCR6_DXDQVREFR2_MASK | DDR_PHY_DX5GCR6_RESERVED_15_14_MASK | DDR_PHY_DX5GCR6_DXDQVREFR1_MASK | DDR_PHY_DX5GCR6_RESERVED_7_6_MASK | DDR_PHY_DX5GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX5GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX5GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX5GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX5GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX5GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX5LCDLR2 @ 0XFD080C88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX5LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX5LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080C88, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX5LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX5LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX5LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX5LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX5LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX5LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX5LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX5GTR0 @ 0XFD080CC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX5GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX5GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX5GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX5GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX5GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX5GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080CC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX5GTR0_RESERVED_31_24_MASK | DDR_PHY_DX5GTR0_WDQSL_MASK | DDR_PHY_DX5GTR0_RESERVED_23_20_MASK | DDR_PHY_DX5GTR0_WLSL_MASK | DDR_PHY_DX5GTR0_RESERVED_15_13_MASK | DDR_PHY_DX5GTR0_RESERVED_12_8_MASK | DDR_PHY_DX5GTR0_RESERVED_7_5_MASK | DDR_PHY_DX5GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX5GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX5GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX5GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX5GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX6GCR0 @ 0XFD080D00</p>
Calibration Bypass
PSU_DDR_PHY_DX6GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX6GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX6GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX6GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX6GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX6GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX6GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX6GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX6GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX6GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX6GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX6GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX6GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX6GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080D00, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX6GCR0_CALBYP_MASK | DDR_PHY_DX6GCR0_MDLEN_MASK | DDR_PHY_DX6GCR0_CODTSHFT_MASK | DDR_PHY_DX6GCR0_DQSDCC_MASK | DDR_PHY_DX6GCR0_RDDLY_MASK | DDR_PHY_DX6GCR0_RESERVED_19_14_MASK | DDR_PHY_DX6GCR0_DQSNSEPDR_MASK | DDR_PHY_DX6GCR0_DQSSEPDR_MASK | DDR_PHY_DX6GCR0_RTTOAL_MASK | DDR_PHY_DX6GCR0_RTTOH_MASK | DDR_PHY_DX6GCR0_CPDRSHFT_MASK | DDR_PHY_DX6GCR0_DQSRPD_MASK | DDR_PHY_DX6GCR0_DQSGPDR_MASK | DDR_PHY_DX6GCR0_RESERVED_4_MASK | DDR_PHY_DX6GCR0_DQSGODT_MASK | DDR_PHY_DX6GCR0_DQSGOE_MASK | DDR_PHY_DX6GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX6GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX6GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX6GCR1 @ 0XFD080D04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX6GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX6GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX6GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX6GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX6GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX6GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX6GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX6GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX6GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX6GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080D04, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX6GCR1_DXPDRMODE_MASK | DDR_PHY_DX6GCR1_RESERVED_15_MASK | DDR_PHY_DX6GCR1_QSNSEL_MASK | DDR_PHY_DX6GCR1_QSSEL_MASK | DDR_PHY_DX6GCR1_OEEN_MASK | DDR_PHY_DX6GCR1_PDREN_MASK | DDR_PHY_DX6GCR1_TEEN_MASK | DDR_PHY_DX6GCR1_DSEN_MASK | DDR_PHY_DX6GCR1_DMEN_MASK | DDR_PHY_DX6GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX6GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX6GCR4 @ 0XFD080D10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX6GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX6GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX6GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX6GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX6GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX6GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX6GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX6GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX6GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX6GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080D10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX6GCR4_RESERVED_31_29_MASK | DDR_PHY_DX6GCR4_DXREFPEN_MASK | DDR_PHY_DX6GCR4_DXREFEEN_MASK | DDR_PHY_DX6GCR4_DXREFSEN_MASK | DDR_PHY_DX6GCR4_RESERVED_24_MASK | DDR_PHY_DX6GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX6GCR4_DXREFESEL_MASK | DDR_PHY_DX6GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX6GCR4_DXREFSSEL_MASK | DDR_PHY_DX6GCR4_RESERVED_7_6_MASK | DDR_PHY_DX6GCR4_DXREFIEN_MASK | DDR_PHY_DX6GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX6GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX6GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX6GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX6GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX6GCR5 @ 0XFD080D14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX6GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX6GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX6GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX6GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080D14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX6GCR5_RESERVED_31_MASK | DDR_PHY_DX6GCR5_DXREFISELR3_MASK | DDR_PHY_DX6GCR5_RESERVED_23_MASK | DDR_PHY_DX6GCR5_DXREFISELR2_MASK | DDR_PHY_DX6GCR5_RESERVED_15_MASK | DDR_PHY_DX6GCR5_DXREFISELR1_MASK | DDR_PHY_DX6GCR5_RESERVED_7_MASK | DDR_PHY_DX6GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX6GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX6GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX6GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX6GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX6GCR6 @ 0XFD080D18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX6GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX6GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX6GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX6GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX6GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080D18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX6GCR6_RESERVED_31_30_MASK | DDR_PHY_DX6GCR6_DXDQVREFR3_MASK | DDR_PHY_DX6GCR6_RESERVED_23_22_MASK | DDR_PHY_DX6GCR6_DXDQVREFR2_MASK | DDR_PHY_DX6GCR6_RESERVED_15_14_MASK | DDR_PHY_DX6GCR6_DXDQVREFR1_MASK | DDR_PHY_DX6GCR6_RESERVED_7_6_MASK | DDR_PHY_DX6GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX6GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX6GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX6GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX6GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX6GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX6LCDLR2 @ 0XFD080D88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX6LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX6LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080D88, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX6LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX6LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX6LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX6LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX6LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX6LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX6LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX6GTR0 @ 0XFD080DC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX6GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX6GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX6GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX6GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX6GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX6GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080DC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX6GTR0_RESERVED_31_24_MASK | DDR_PHY_DX6GTR0_WDQSL_MASK | DDR_PHY_DX6GTR0_RESERVED_23_20_MASK | DDR_PHY_DX6GTR0_WLSL_MASK | DDR_PHY_DX6GTR0_RESERVED_15_13_MASK | DDR_PHY_DX6GTR0_RESERVED_12_8_MASK | DDR_PHY_DX6GTR0_RESERVED_7_5_MASK | DDR_PHY_DX6GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX6GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX6GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX6GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX6GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX7GCR0 @ 0XFD080E00</p>
Calibration Bypass
PSU_DDR_PHY_DX7GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX7GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX7GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX7GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX7GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX7GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX7GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX7GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX7GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX7GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX7GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX7GCR0_DQSGPDR 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX7GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX7GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080E00, 0xFFFFFFFFU ,0x40800604U)
RegMask = (DDR_PHY_DX7GCR0_CALBYP_MASK | DDR_PHY_DX7GCR0_MDLEN_MASK | DDR_PHY_DX7GCR0_CODTSHFT_MASK | DDR_PHY_DX7GCR0_DQSDCC_MASK | DDR_PHY_DX7GCR0_RDDLY_MASK | DDR_PHY_DX7GCR0_RESERVED_19_14_MASK | DDR_PHY_DX7GCR0_DQSNSEPDR_MASK | DDR_PHY_DX7GCR0_DQSSEPDR_MASK | DDR_PHY_DX7GCR0_RTTOAL_MASK | DDR_PHY_DX7GCR0_RTTOH_MASK | DDR_PHY_DX7GCR0_CPDRSHFT_MASK | DDR_PHY_DX7GCR0_DQSRPD_MASK | DDR_PHY_DX7GCR0_DQSGPDR_MASK | DDR_PHY_DX7GCR0_RESERVED_4_MASK | DDR_PHY_DX7GCR0_DQSGODT_MASK | DDR_PHY_DX7GCR0_DQSGOE_MASK | DDR_PHY_DX7GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX7GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX7GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSRPD_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GCR0_OFFSET ,0xFFFFFFFFU ,0x40800604U);
/*############################################################################################################################ */
/*Register : DX7GCR1 @ 0XFD080E04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX7GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX7GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX7GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX7GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX7GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX7GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX7GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX7GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX7GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX7GCR1_DQEN 0xff
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080E04, 0xFFFFFFFFU ,0x00007FFFU)
RegMask = (DDR_PHY_DX7GCR1_DXPDRMODE_MASK | DDR_PHY_DX7GCR1_RESERVED_15_MASK | DDR_PHY_DX7GCR1_QSNSEL_MASK | DDR_PHY_DX7GCR1_QSSEL_MASK | DDR_PHY_DX7GCR1_OEEN_MASK | DDR_PHY_DX7GCR1_PDREN_MASK | DDR_PHY_DX7GCR1_TEEN_MASK | DDR_PHY_DX7GCR1_DSEN_MASK | DDR_PHY_DX7GCR1_DMEN_MASK | DDR_PHY_DX7GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR1_DMEN_SHIFT
| 0x000000FFU << DDR_PHY_DX7GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GCR1_OFFSET ,0xFFFFFFFFU ,0x00007FFFU);
/*############################################################################################################################ */
/*Register : DX7GCR4 @ 0XFD080E10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX7GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX7GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX7GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX7GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX7GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX7GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX7GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX7GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX7GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX7GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080E10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX7GCR4_RESERVED_31_29_MASK | DDR_PHY_DX7GCR4_DXREFPEN_MASK | DDR_PHY_DX7GCR4_DXREFEEN_MASK | DDR_PHY_DX7GCR4_DXREFSEN_MASK | DDR_PHY_DX7GCR4_RESERVED_24_MASK | DDR_PHY_DX7GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX7GCR4_DXREFESEL_MASK | DDR_PHY_DX7GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX7GCR4_DXREFSSEL_MASK | DDR_PHY_DX7GCR4_RESERVED_7_6_MASK | DDR_PHY_DX7GCR4_DXREFIEN_MASK | DDR_PHY_DX7GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX7GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX7GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX7GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX7GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX7GCR5 @ 0XFD080E14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX7GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX7GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX7GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX7GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080E14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX7GCR5_RESERVED_31_MASK | DDR_PHY_DX7GCR5_DXREFISELR3_MASK | DDR_PHY_DX7GCR5_RESERVED_23_MASK | DDR_PHY_DX7GCR5_DXREFISELR2_MASK | DDR_PHY_DX7GCR5_RESERVED_15_MASK | DDR_PHY_DX7GCR5_DXREFISELR1_MASK | DDR_PHY_DX7GCR5_RESERVED_7_MASK | DDR_PHY_DX7GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX7GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX7GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX7GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX7GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX7GCR6 @ 0XFD080E18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX7GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX7GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX7GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX7GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX7GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080E18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX7GCR6_RESERVED_31_30_MASK | DDR_PHY_DX7GCR6_DXDQVREFR3_MASK | DDR_PHY_DX7GCR6_RESERVED_23_22_MASK | DDR_PHY_DX7GCR6_DXDQVREFR2_MASK | DDR_PHY_DX7GCR6_RESERVED_15_14_MASK | DDR_PHY_DX7GCR6_DXDQVREFR1_MASK | DDR_PHY_DX7GCR6_RESERVED_7_6_MASK | DDR_PHY_DX7GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX7GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX7GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX7GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX7GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX7GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX7LCDLR2 @ 0XFD080E88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX7LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX7LCDLR2_DQSGD 0xa
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080E88, 0xFFFFFFFFU ,0x0000000AU)
RegMask = (DDR_PHY_DX7LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX7LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX7LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX7LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX7LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX7LCDLR2_RESERVED_15_9_SHIFT
| 0x0000000AU << DDR_PHY_DX7LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7LCDLR2_OFFSET ,0xFFFFFFFFU ,0x0000000AU);
/*############################################################################################################################ */
/*Register : DX7GTR0 @ 0XFD080EC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX7GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX7GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX7GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX7GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX7GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX7GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080EC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX7GTR0_RESERVED_31_24_MASK | DDR_PHY_DX7GTR0_WDQSL_MASK | DDR_PHY_DX7GTR0_RESERVED_23_20_MASK | DDR_PHY_DX7GTR0_WLSL_MASK | DDR_PHY_DX7GTR0_RESERVED_15_13_MASK | DDR_PHY_DX7GTR0_RESERVED_12_8_MASK | DDR_PHY_DX7GTR0_RESERVED_7_5_MASK | DDR_PHY_DX7GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX7GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX7GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX7GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX7GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX8GCR0 @ 0XFD080F00</p>
Calibration Bypass
PSU_DDR_PHY_DX8GCR0_CALBYP 0x0
Master Delay Line Enable
PSU_DDR_PHY_DX8GCR0_MDLEN 0x1
Configurable ODT(TE) Phase Shift
PSU_DDR_PHY_DX8GCR0_CODTSHFT 0x0
DQS Duty Cycle Correction
PSU_DDR_PHY_DX8GCR0_DQSDCC 0x0
Number of Cycles ( in terms of ctl_clk) to generate ctl_dx_get_static_rd input for the respective bypte lane of the PHY
PSU_DDR_PHY_DX8GCR0_RDDLY 0x8
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GCR0_RESERVED_19_14 0x0
DQSNSE Power Down Receiver
PSU_DDR_PHY_DX8GCR0_DQSNSEPDR 0x0
DQSSE Power Down Receiver
PSU_DDR_PHY_DX8GCR0_DQSSEPDR 0x0
RTT On Additive Latency
PSU_DDR_PHY_DX8GCR0_RTTOAL 0x0
RTT Output Hold
PSU_DDR_PHY_DX8GCR0_RTTOH 0x3
Configurable PDR Phase Shift
PSU_DDR_PHY_DX8GCR0_CPDRSHFT 0x0
DQSR Power Down
PSU_DDR_PHY_DX8GCR0_DQSRPD 0x0
DQSG Power Down Receiver
PSU_DDR_PHY_DX8GCR0_DQSGPDR 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GCR0_RESERVED_4 0x0
DQSG On-Die Termination
PSU_DDR_PHY_DX8GCR0_DQSGODT 0x0
DQSG Output Enable
PSU_DDR_PHY_DX8GCR0_DQSGOE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GCR0_RESERVED_1_0 0x0
DATX8 n General Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD080F00, 0xFFFFFFFFU ,0x40800624U)
RegMask = (DDR_PHY_DX8GCR0_CALBYP_MASK | DDR_PHY_DX8GCR0_MDLEN_MASK | DDR_PHY_DX8GCR0_CODTSHFT_MASK | DDR_PHY_DX8GCR0_DQSDCC_MASK | DDR_PHY_DX8GCR0_RDDLY_MASK | DDR_PHY_DX8GCR0_RESERVED_19_14_MASK | DDR_PHY_DX8GCR0_DQSNSEPDR_MASK | DDR_PHY_DX8GCR0_DQSSEPDR_MASK | DDR_PHY_DX8GCR0_RTTOAL_MASK | DDR_PHY_DX8GCR0_RTTOH_MASK | DDR_PHY_DX8GCR0_CPDRSHFT_MASK | DDR_PHY_DX8GCR0_DQSRPD_MASK | DDR_PHY_DX8GCR0_DQSGPDR_MASK | DDR_PHY_DX8GCR0_RESERVED_4_MASK | DDR_PHY_DX8GCR0_DQSGODT_MASK | DDR_PHY_DX8GCR0_DQSGOE_MASK | DDR_PHY_DX8GCR0_RESERVED_1_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GCR0_CALBYP_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR0_MDLEN_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_CODTSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_DQSDCC_SHIFT
| 0x00000008U << DDR_PHY_DX8GCR0_RDDLY_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_RESERVED_19_14_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_DQSNSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_DQSSEPDR_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_RTTOAL_SHIFT
| 0x00000003U << DDR_PHY_DX8GCR0_RTTOH_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_CPDRSHFT_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_DQSRPD_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR0_DQSGPDR_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_RESERVED_4_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_DQSGODT_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR0_DQSGOE_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR0_RESERVED_1_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GCR0_OFFSET ,0xFFFFFFFFU ,0x40800624U);
/*############################################################################################################################ */
/*Register : DX8GCR1 @ 0XFD080F04</p>
Enables the PDR mode for DQ[7:0]
PSU_DDR_PHY_DX8GCR1_DXPDRMODE 0x0
Reserved. Returns zeroes on reads.
PSU_DDR_PHY_DX8GCR1_RESERVED_15 0x0
Select the delayed or non-delayed read data strobe #
PSU_DDR_PHY_DX8GCR1_QSNSEL 0x1
Select the delayed or non-delayed read data strobe
PSU_DDR_PHY_DX8GCR1_QSSEL 0x1
Enables Read Data Strobe in a byte lane
PSU_DDR_PHY_DX8GCR1_OEEN 0x1
Enables PDR in a byte lane
PSU_DDR_PHY_DX8GCR1_PDREN 0x1
Enables ODT/TE in a byte lane
PSU_DDR_PHY_DX8GCR1_TEEN 0x1
Enables Write Data strobe in a byte lane
PSU_DDR_PHY_DX8GCR1_DSEN 0x1
Enables DM pin in a byte lane
PSU_DDR_PHY_DX8GCR1_DMEN 0x1
Enables DQ corresponding to each bit in a byte
PSU_DDR_PHY_DX8GCR1_DQEN 0x0
DATX8 n General Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD080F04, 0xFFFFFFFFU ,0x00007F00U)
RegMask = (DDR_PHY_DX8GCR1_DXPDRMODE_MASK | DDR_PHY_DX8GCR1_RESERVED_15_MASK | DDR_PHY_DX8GCR1_QSNSEL_MASK | DDR_PHY_DX8GCR1_QSSEL_MASK | DDR_PHY_DX8GCR1_OEEN_MASK | DDR_PHY_DX8GCR1_PDREN_MASK | DDR_PHY_DX8GCR1_TEEN_MASK | DDR_PHY_DX8GCR1_DSEN_MASK | DDR_PHY_DX8GCR1_DMEN_MASK | DDR_PHY_DX8GCR1_DQEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GCR1_DXPDRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR1_RESERVED_15_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_QSNSEL_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_QSSEL_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_OEEN_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_PDREN_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_TEEN_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_DSEN_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR1_DMEN_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR1_DQEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GCR1_OFFSET ,0xFFFFFFFFU ,0x00007F00U);
/*############################################################################################################################ */
/*Register : DX8GCR4 @ 0XFD080F10</p>
Byte lane VREF IOM (Used only by D4MU IOs)
PSU_DDR_PHY_DX8GCR4_RESERVED_31_29 0x0
Byte Lane VREF Pad Enable
PSU_DDR_PHY_DX8GCR4_DXREFPEN 0x0
Byte Lane Internal VREF Enable
PSU_DDR_PHY_DX8GCR4_DXREFEEN 0x3
Byte Lane Single-End VREF Enable
PSU_DDR_PHY_DX8GCR4_DXREFSEN 0x1
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR4_RESERVED_24 0x0
External VREF generator REFSEL range select
PSU_DDR_PHY_DX8GCR4_DXREFESELRANGE 0x0
Byte Lane External VREF Select
PSU_DDR_PHY_DX8GCR4_DXREFESEL 0x0
Single ended VREF generator REFSEL range select
PSU_DDR_PHY_DX8GCR4_DXREFSSELRANGE 0x1
Byte Lane Single-End VREF Select
PSU_DDR_PHY_DX8GCR4_DXREFSSEL 0x30
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR4_RESERVED_7_6 0x0
VREF Enable control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX8GCR4_DXREFIEN 0xf
VRMON control for DQ IO (Single Ended) buffers of a byte lane.
PSU_DDR_PHY_DX8GCR4_DXREFIMON 0x0
DATX8 n General Configuration Register 4
(OFFSET, MASK, VALUE) (0XFD080F10, 0xFFFFFFFFU ,0x0E00B03CU)
RegMask = (DDR_PHY_DX8GCR4_RESERVED_31_29_MASK | DDR_PHY_DX8GCR4_DXREFPEN_MASK | DDR_PHY_DX8GCR4_DXREFEEN_MASK | DDR_PHY_DX8GCR4_DXREFSEN_MASK | DDR_PHY_DX8GCR4_RESERVED_24_MASK | DDR_PHY_DX8GCR4_DXREFESELRANGE_MASK | DDR_PHY_DX8GCR4_DXREFESEL_MASK | DDR_PHY_DX8GCR4_DXREFSSELRANGE_MASK | DDR_PHY_DX8GCR4_DXREFSSEL_MASK | DDR_PHY_DX8GCR4_RESERVED_7_6_MASK | DDR_PHY_DX8GCR4_DXREFIEN_MASK | DDR_PHY_DX8GCR4_DXREFIMON_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GCR4_RESERVED_31_29_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_DXREFPEN_SHIFT
| 0x00000003U << DDR_PHY_DX8GCR4_DXREFEEN_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR4_DXREFSEN_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_RESERVED_24_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_DXREFESELRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_DXREFESEL_SHIFT
| 0x00000001U << DDR_PHY_DX8GCR4_DXREFSSELRANGE_SHIFT
| 0x00000030U << DDR_PHY_DX8GCR4_DXREFSSEL_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_RESERVED_7_6_SHIFT
| 0x0000000FU << DDR_PHY_DX8GCR4_DXREFIEN_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR4_DXREFIMON_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GCR4_OFFSET ,0xFFFFFFFFU ,0x0E00B03CU);
/*############################################################################################################################ */
/*Register : DX8GCR5 @ 0XFD080F14</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR5_RESERVED_31 0x0
Byte Lane internal VREF Select for Rank 3
PSU_DDR_PHY_DX8GCR5_DXREFISELR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR5_RESERVED_23 0x0
Byte Lane internal VREF Select for Rank 2
PSU_DDR_PHY_DX8GCR5_DXREFISELR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR5_RESERVED_15 0x0
Byte Lane internal VREF Select for Rank 1
PSU_DDR_PHY_DX8GCR5_DXREFISELR1 0x4f
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR5_RESERVED_7 0x0
Byte Lane internal VREF Select for Rank 0
PSU_DDR_PHY_DX8GCR5_DXREFISELR0 0x4f
DATX8 n General Configuration Register 5
(OFFSET, MASK, VALUE) (0XFD080F14, 0xFFFFFFFFU ,0x09094F4FU)
RegMask = (DDR_PHY_DX8GCR5_RESERVED_31_MASK | DDR_PHY_DX8GCR5_DXREFISELR3_MASK | DDR_PHY_DX8GCR5_RESERVED_23_MASK | DDR_PHY_DX8GCR5_DXREFISELR2_MASK | DDR_PHY_DX8GCR5_RESERVED_15_MASK | DDR_PHY_DX8GCR5_DXREFISELR1_MASK | DDR_PHY_DX8GCR5_RESERVED_7_MASK | DDR_PHY_DX8GCR5_DXREFISELR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GCR5_RESERVED_31_SHIFT
| 0x00000009U << DDR_PHY_DX8GCR5_DXREFISELR3_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR5_RESERVED_23_SHIFT
| 0x00000009U << DDR_PHY_DX8GCR5_DXREFISELR2_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR5_RESERVED_15_SHIFT
| 0x0000004FU << DDR_PHY_DX8GCR5_DXREFISELR1_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR5_RESERVED_7_SHIFT
| 0x0000004FU << DDR_PHY_DX8GCR5_DXREFISELR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GCR5_OFFSET ,0xFFFFFFFFU ,0x09094F4FU);
/*############################################################################################################################ */
/*Register : DX8GCR6 @ 0XFD080F18</p>
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR6_RESERVED_31_30 0x0
DRAM DQ VREF Select for Rank3
PSU_DDR_PHY_DX8GCR6_DXDQVREFR3 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR6_RESERVED_23_22 0x0
DRAM DQ VREF Select for Rank2
PSU_DDR_PHY_DX8GCR6_DXDQVREFR2 0x9
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR6_RESERVED_15_14 0x0
DRAM DQ VREF Select for Rank1
PSU_DDR_PHY_DX8GCR6_DXDQVREFR1 0x2b
Reserved. Returns zeros on reads.
PSU_DDR_PHY_DX8GCR6_RESERVED_7_6 0x0
DRAM DQ VREF Select for Rank0
PSU_DDR_PHY_DX8GCR6_DXDQVREFR0 0x2b
DATX8 n General Configuration Register 6
(OFFSET, MASK, VALUE) (0XFD080F18, 0xFFFFFFFFU ,0x09092B2BU)
RegMask = (DDR_PHY_DX8GCR6_RESERVED_31_30_MASK | DDR_PHY_DX8GCR6_DXDQVREFR3_MASK | DDR_PHY_DX8GCR6_RESERVED_23_22_MASK | DDR_PHY_DX8GCR6_DXDQVREFR2_MASK | DDR_PHY_DX8GCR6_RESERVED_15_14_MASK | DDR_PHY_DX8GCR6_DXDQVREFR1_MASK | DDR_PHY_DX8GCR6_RESERVED_7_6_MASK | DDR_PHY_DX8GCR6_DXDQVREFR0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GCR6_RESERVED_31_30_SHIFT
| 0x00000009U << DDR_PHY_DX8GCR6_DXDQVREFR3_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR6_RESERVED_23_22_SHIFT
| 0x00000009U << DDR_PHY_DX8GCR6_DXDQVREFR2_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR6_RESERVED_15_14_SHIFT
| 0x0000002BU << DDR_PHY_DX8GCR6_DXDQVREFR1_SHIFT
| 0x00000000U << DDR_PHY_DX8GCR6_RESERVED_7_6_SHIFT
| 0x0000002BU << DDR_PHY_DX8GCR6_DXDQVREFR0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GCR6_OFFSET ,0xFFFFFFFFU ,0x09092B2BU);
/*############################################################################################################################ */
/*Register : DX8LCDLR2 @ 0XFD080F88</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8LCDLR2_RESERVED_31_25 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8LCDLR2_RESERVED_24_16 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8LCDLR2_RESERVED_15_9 0x0
Read DQS Gating Delay
PSU_DDR_PHY_DX8LCDLR2_DQSGD 0x0
DATX8 n Local Calibrated Delay Line Register 2
(OFFSET, MASK, VALUE) (0XFD080F88, 0xFFFFFFFFU ,0x00000000U)
RegMask = (DDR_PHY_DX8LCDLR2_RESERVED_31_25_MASK | DDR_PHY_DX8LCDLR2_RESERVED_24_16_MASK | DDR_PHY_DX8LCDLR2_RESERVED_15_9_MASK | DDR_PHY_DX8LCDLR2_DQSGD_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8LCDLR2_RESERVED_31_25_SHIFT
| 0x00000000U << DDR_PHY_DX8LCDLR2_RESERVED_24_16_SHIFT
| 0x00000000U << DDR_PHY_DX8LCDLR2_RESERVED_15_9_SHIFT
| 0x00000000U << DDR_PHY_DX8LCDLR2_DQSGD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8LCDLR2_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : DX8GTR0 @ 0XFD080FC0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GTR0_RESERVED_31_24 0x0
DQ Write Path Latency Pipeline
PSU_DDR_PHY_DX8GTR0_WDQSL 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8GTR0_RESERVED_23_20 0x0
Write Leveling System Latency
PSU_DDR_PHY_DX8GTR0_WLSL 0x2
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GTR0_RESERVED_15_13 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8GTR0_RESERVED_12_8 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8GTR0_RESERVED_7_5 0x0
DQS Gating System Latency
PSU_DDR_PHY_DX8GTR0_DGSL 0x0
DATX8 n General Timing Register 0
(OFFSET, MASK, VALUE) (0XFD080FC0, 0xFFFFFFFFU ,0x00020000U)
RegMask = (DDR_PHY_DX8GTR0_RESERVED_31_24_MASK | DDR_PHY_DX8GTR0_WDQSL_MASK | DDR_PHY_DX8GTR0_RESERVED_23_20_MASK | DDR_PHY_DX8GTR0_WLSL_MASK | DDR_PHY_DX8GTR0_RESERVED_15_13_MASK | DDR_PHY_DX8GTR0_RESERVED_12_8_MASK | DDR_PHY_DX8GTR0_RESERVED_7_5_MASK | DDR_PHY_DX8GTR0_DGSL_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8GTR0_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_WDQSL_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_RESERVED_23_20_SHIFT
| 0x00000002U << DDR_PHY_DX8GTR0_WLSL_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_RESERVED_15_13_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_RESERVED_12_8_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_RESERVED_7_5_SHIFT
| 0x00000000U << DDR_PHY_DX8GTR0_DGSL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8GTR0_OFFSET ,0xFFFFFFFFU ,0x00020000U);
/*############################################################################################################################ */
/*Register : DX8SL0OSC @ 0XFD081400</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0OSC_RESERVED_31_30 0x0
Enable Clock Gating for DX ddr_clk
PSU_DDR_PHY_DX8SL0OSC_GATEDXRDCLK 0x2
Enable Clock Gating for DX ctl_rd_clk
PSU_DDR_PHY_DX8SL0OSC_GATEDXDDRCLK 0x2
Enable Clock Gating for DX ctl_clk
PSU_DDR_PHY_DX8SL0OSC_GATEDXCTLCLK 0x2
Selects the level to which clocks will be stalled when clock gating is enabled.
PSU_DDR_PHY_DX8SL0OSC_CLKLEVEL 0x0
Loopback Mode
PSU_DDR_PHY_DX8SL0OSC_LBMODE 0x0
Load GSDQS LCDL with 2x the calibrated GSDQSPRD value
PSU_DDR_PHY_DX8SL0OSC_LBGSDQS 0x0
Loopback DQS Gating
PSU_DDR_PHY_DX8SL0OSC_LBGDQS 0x0
Loopback DQS Shift
PSU_DDR_PHY_DX8SL0OSC_LBDQSS 0x0
PHY High-Speed Reset
PSU_DDR_PHY_DX8SL0OSC_PHYHRST 0x1
PHY FIFO Reset
PSU_DDR_PHY_DX8SL0OSC_PHYFRST 0x1
Delay Line Test Start
PSU_DDR_PHY_DX8SL0OSC_DLTST 0x0
Delay Line Test Mode
PSU_DDR_PHY_DX8SL0OSC_DLTMODE 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL0OSC_RESERVED_12_11 0x3
Oscillator Mode Write-Data Delay Line Select
PSU_DDR_PHY_DX8SL0OSC_OSCWDDL 0x3
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL0OSC_RESERVED_8_7 0x3
Oscillator Mode Write-Leveling Delay Line Select
PSU_DDR_PHY_DX8SL0OSC_OSCWDL 0x3
Oscillator Mode Division
PSU_DDR_PHY_DX8SL0OSC_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_DX8SL0OSC_OSCEN 0x0
DATX8 0-1 Oscillator, Delay Line Test, PHY FIFO and High Speed Reset, Loopback, and Gated Clock Control Register
(OFFSET, MASK, VALUE) (0XFD081400, 0xFFFFFFFFU ,0x2A019FFEU)
RegMask = (DDR_PHY_DX8SL0OSC_RESERVED_31_30_MASK | DDR_PHY_DX8SL0OSC_GATEDXRDCLK_MASK | DDR_PHY_DX8SL0OSC_GATEDXDDRCLK_MASK | DDR_PHY_DX8SL0OSC_GATEDXCTLCLK_MASK | DDR_PHY_DX8SL0OSC_CLKLEVEL_MASK | DDR_PHY_DX8SL0OSC_LBMODE_MASK | DDR_PHY_DX8SL0OSC_LBGSDQS_MASK | DDR_PHY_DX8SL0OSC_LBGDQS_MASK | DDR_PHY_DX8SL0OSC_LBDQSS_MASK | DDR_PHY_DX8SL0OSC_PHYHRST_MASK | DDR_PHY_DX8SL0OSC_PHYFRST_MASK | DDR_PHY_DX8SL0OSC_DLTST_MASK | DDR_PHY_DX8SL0OSC_DLTMODE_MASK | DDR_PHY_DX8SL0OSC_RESERVED_12_11_MASK | DDR_PHY_DX8SL0OSC_OSCWDDL_MASK | DDR_PHY_DX8SL0OSC_RESERVED_8_7_MASK | DDR_PHY_DX8SL0OSC_OSCWDL_MASK | DDR_PHY_DX8SL0OSC_OSCDIV_MASK | DDR_PHY_DX8SL0OSC_OSCEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL0OSC_RESERVED_31_30_SHIFT
| 0x00000002U << DDR_PHY_DX8SL0OSC_GATEDXRDCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL0OSC_GATEDXDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL0OSC_GATEDXCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_CLKLEVEL_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_LBMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_LBGSDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_LBGDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_LBDQSS_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0OSC_PHYHRST_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0OSC_PHYFRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_DLTST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_DLTMODE_SHIFT
| 0x00000003U << DDR_PHY_DX8SL0OSC_RESERVED_12_11_SHIFT
| 0x00000003U << DDR_PHY_DX8SL0OSC_OSCWDDL_SHIFT
| 0x00000003U << DDR_PHY_DX8SL0OSC_RESERVED_8_7_SHIFT
| 0x00000003U << DDR_PHY_DX8SL0OSC_OSCWDL_SHIFT
| 0x0000000FU << DDR_PHY_DX8SL0OSC_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0OSC_OSCEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL0OSC_OFFSET ,0xFFFFFFFFU ,0x2A019FFEU);
/*############################################################################################################################ */
/*Register : DX8SL0DQSCTL @ 0XFD08141C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL0DQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL0DQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SL0DQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SL0DQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SL0DQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SL0DQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SL0DQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SL0DQSCTL_DXSR 0x3
DQS_N Resistor
PSU_DDR_PHY_DX8SL0DQSCTL_DQSNRES 0x0
DQS Resistor
PSU_DDR_PHY_DX8SL0DQSCTL_DQSRES 0x0
DATX8 0-1 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD08141C, 0xFFFFFFFFU ,0x01264300U)
RegMask = (DDR_PHY_DX8SL0DQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SL0DQSCTL_RRRMODE_MASK | DDR_PHY_DX8SL0DQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SL0DQSCTL_WRRMODE_MASK | DDR_PHY_DX8SL0DQSCTL_DQSGX_MASK | DDR_PHY_DX8SL0DQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SL0DQSCTL_LPIOPD_MASK | DDR_PHY_DX8SL0DQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SL0DQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SL0DQSCTL_UDQIOM_MASK | DDR_PHY_DX8SL0DQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SL0DQSCTL_DXSR_MASK | DDR_PHY_DX8SL0DQSCTL_DQSNRES_MASK | DDR_PHY_DX8SL0DQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL0DQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SL0DQSCTL_DXSR_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_DQSNRES_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL0DQSCTL_OFFSET ,0xFFFFFFFFU ,0x01264300U);
/*############################################################################################################################ */
/*Register : DX8SL0DXCTL2 @ 0XFD08142C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DXCTL2_RESERVED_31_24 0x0
Configurable Read Data Enable
PSU_DDR_PHY_DX8SL0DXCTL2_CRDEN 0x0
OX Extension during Post-amble
PSU_DDR_PHY_DX8SL0DXCTL2_POSOEX 0x0
OE Extension during Pre-amble
PSU_DDR_PHY_DX8SL0DXCTL2_PREOEX 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DXCTL2_RESERVED_17 0x0
I/O Assisted Gate Select
PSU_DDR_PHY_DX8SL0DXCTL2_IOAG 0x0
I/O Loopback Select
PSU_DDR_PHY_DX8SL0DXCTL2_IOLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DXCTL2_RESERVED_14_13 0x0
Low Power Wakeup Threshold
PSU_DDR_PHY_DX8SL0DXCTL2_LPWAKEUP_THRSH 0xc
Read Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL0DXCTL2_RDBI 0x0
Write Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL0DXCTL2_WDBI 0x0
PUB Read FIFO Bypass
PSU_DDR_PHY_DX8SL0DXCTL2_PRFBYP 0x0
DATX8 Receive FIFO Read Mode
PSU_DDR_PHY_DX8SL0DXCTL2_RDMODE 0x0
Disables the Read FIFO Reset
PSU_DDR_PHY_DX8SL0DXCTL2_DISRST 0x0
Read DQS Gate I/O Loopback
PSU_DDR_PHY_DX8SL0DXCTL2_DQSGLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0DXCTL2_RESERVED_0 0x0
DATX8 0-1 DX Control Register 2
(OFFSET, MASK, VALUE) (0XFD08142C, 0xFFFFFFFFU ,0x00041800U)
RegMask = (DDR_PHY_DX8SL0DXCTL2_RESERVED_31_24_MASK | DDR_PHY_DX8SL0DXCTL2_CRDEN_MASK | DDR_PHY_DX8SL0DXCTL2_POSOEX_MASK | DDR_PHY_DX8SL0DXCTL2_PREOEX_MASK | DDR_PHY_DX8SL0DXCTL2_RESERVED_17_MASK | DDR_PHY_DX8SL0DXCTL2_IOAG_MASK | DDR_PHY_DX8SL0DXCTL2_IOLB_MASK | DDR_PHY_DX8SL0DXCTL2_RESERVED_14_13_MASK | DDR_PHY_DX8SL0DXCTL2_LPWAKEUP_THRSH_MASK | DDR_PHY_DX8SL0DXCTL2_RDBI_MASK | DDR_PHY_DX8SL0DXCTL2_WDBI_MASK | DDR_PHY_DX8SL0DXCTL2_PRFBYP_MASK | DDR_PHY_DX8SL0DXCTL2_RDMODE_MASK | DDR_PHY_DX8SL0DXCTL2_DISRST_MASK | DDR_PHY_DX8SL0DXCTL2_DQSGLB_MASK | DDR_PHY_DX8SL0DXCTL2_RESERVED_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL0DXCTL2_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_CRDEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_POSOEX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL0DXCTL2_PREOEX_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_RESERVED_17_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_IOAG_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_IOLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_RESERVED_14_13_SHIFT
| 0x0000000CU << DDR_PHY_DX8SL0DXCTL2_LPWAKEUP_THRSH_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_RDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_WDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_PRFBYP_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_DISRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_DQSGLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0DXCTL2_RESERVED_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL0DXCTL2_OFFSET ,0xFFFFFFFFU ,0x00041800U);
/*############################################################################################################################ */
/*Register : DX8SL0IOCR @ 0XFD081430</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL0IOCR_RESERVED_31 0x0
PVREF_DAC REFSEL range select
PSU_DDR_PHY_DX8SL0IOCR_DXDACRANGE 0x7
IOM bits for PVREF, PVREF_DAC and PVREFE cells in DX IO ring
PSU_DDR_PHY_DX8SL0IOCR_DXVREFIOM 0x0
DX IO Mode
PSU_DDR_PHY_DX8SL0IOCR_DXIOM 0x2
DX IO Transmitter Mode
PSU_DDR_PHY_DX8SL0IOCR_DXTXM 0x0
DX IO Receiver Mode
PSU_DDR_PHY_DX8SL0IOCR_DXRXM 0x0
DATX8 0-1 I/O Configuration Register
(OFFSET, MASK, VALUE) (0XFD081430, 0xFFFFFFFFU ,0x70800000U)
RegMask = (DDR_PHY_DX8SL0IOCR_RESERVED_31_MASK | DDR_PHY_DX8SL0IOCR_DXDACRANGE_MASK | DDR_PHY_DX8SL0IOCR_DXVREFIOM_MASK | DDR_PHY_DX8SL0IOCR_DXIOM_MASK | DDR_PHY_DX8SL0IOCR_DXTXM_MASK | DDR_PHY_DX8SL0IOCR_DXRXM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL0IOCR_RESERVED_31_SHIFT
| 0x00000007U << DDR_PHY_DX8SL0IOCR_DXDACRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0IOCR_DXVREFIOM_SHIFT
| 0x00000002U << DDR_PHY_DX8SL0IOCR_DXIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0IOCR_DXTXM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL0IOCR_DXRXM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL0IOCR_OFFSET ,0xFFFFFFFFU ,0x70800000U);
/*############################################################################################################################ */
/*Register : DX8SL1OSC @ 0XFD081440</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1OSC_RESERVED_31_30 0x0
Enable Clock Gating for DX ddr_clk
PSU_DDR_PHY_DX8SL1OSC_GATEDXRDCLK 0x2
Enable Clock Gating for DX ctl_rd_clk
PSU_DDR_PHY_DX8SL1OSC_GATEDXDDRCLK 0x2
Enable Clock Gating for DX ctl_clk
PSU_DDR_PHY_DX8SL1OSC_GATEDXCTLCLK 0x2
Selects the level to which clocks will be stalled when clock gating is enabled.
PSU_DDR_PHY_DX8SL1OSC_CLKLEVEL 0x0
Loopback Mode
PSU_DDR_PHY_DX8SL1OSC_LBMODE 0x0
Load GSDQS LCDL with 2x the calibrated GSDQSPRD value
PSU_DDR_PHY_DX8SL1OSC_LBGSDQS 0x0
Loopback DQS Gating
PSU_DDR_PHY_DX8SL1OSC_LBGDQS 0x0
Loopback DQS Shift
PSU_DDR_PHY_DX8SL1OSC_LBDQSS 0x0
PHY High-Speed Reset
PSU_DDR_PHY_DX8SL1OSC_PHYHRST 0x1
PHY FIFO Reset
PSU_DDR_PHY_DX8SL1OSC_PHYFRST 0x1
Delay Line Test Start
PSU_DDR_PHY_DX8SL1OSC_DLTST 0x0
Delay Line Test Mode
PSU_DDR_PHY_DX8SL1OSC_DLTMODE 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL1OSC_RESERVED_12_11 0x3
Oscillator Mode Write-Data Delay Line Select
PSU_DDR_PHY_DX8SL1OSC_OSCWDDL 0x3
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL1OSC_RESERVED_8_7 0x3
Oscillator Mode Write-Leveling Delay Line Select
PSU_DDR_PHY_DX8SL1OSC_OSCWDL 0x3
Oscillator Mode Division
PSU_DDR_PHY_DX8SL1OSC_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_DX8SL1OSC_OSCEN 0x0
DATX8 0-1 Oscillator, Delay Line Test, PHY FIFO and High Speed Reset, Loopback, and Gated Clock Control Register
(OFFSET, MASK, VALUE) (0XFD081440, 0xFFFFFFFFU ,0x2A019FFEU)
RegMask = (DDR_PHY_DX8SL1OSC_RESERVED_31_30_MASK | DDR_PHY_DX8SL1OSC_GATEDXRDCLK_MASK | DDR_PHY_DX8SL1OSC_GATEDXDDRCLK_MASK | DDR_PHY_DX8SL1OSC_GATEDXCTLCLK_MASK | DDR_PHY_DX8SL1OSC_CLKLEVEL_MASK | DDR_PHY_DX8SL1OSC_LBMODE_MASK | DDR_PHY_DX8SL1OSC_LBGSDQS_MASK | DDR_PHY_DX8SL1OSC_LBGDQS_MASK | DDR_PHY_DX8SL1OSC_LBDQSS_MASK | DDR_PHY_DX8SL1OSC_PHYHRST_MASK | DDR_PHY_DX8SL1OSC_PHYFRST_MASK | DDR_PHY_DX8SL1OSC_DLTST_MASK | DDR_PHY_DX8SL1OSC_DLTMODE_MASK | DDR_PHY_DX8SL1OSC_RESERVED_12_11_MASK | DDR_PHY_DX8SL1OSC_OSCWDDL_MASK | DDR_PHY_DX8SL1OSC_RESERVED_8_7_MASK | DDR_PHY_DX8SL1OSC_OSCWDL_MASK | DDR_PHY_DX8SL1OSC_OSCDIV_MASK | DDR_PHY_DX8SL1OSC_OSCEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL1OSC_RESERVED_31_30_SHIFT
| 0x00000002U << DDR_PHY_DX8SL1OSC_GATEDXRDCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL1OSC_GATEDXDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL1OSC_GATEDXCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_CLKLEVEL_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_LBMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_LBGSDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_LBGDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_LBDQSS_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1OSC_PHYHRST_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1OSC_PHYFRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_DLTST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_DLTMODE_SHIFT
| 0x00000003U << DDR_PHY_DX8SL1OSC_RESERVED_12_11_SHIFT
| 0x00000003U << DDR_PHY_DX8SL1OSC_OSCWDDL_SHIFT
| 0x00000003U << DDR_PHY_DX8SL1OSC_RESERVED_8_7_SHIFT
| 0x00000003U << DDR_PHY_DX8SL1OSC_OSCWDL_SHIFT
| 0x0000000FU << DDR_PHY_DX8SL1OSC_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1OSC_OSCEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL1OSC_OFFSET ,0xFFFFFFFFU ,0x2A019FFEU);
/*############################################################################################################################ */
/*Register : DX8SL1DQSCTL @ 0XFD08145C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL1DQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL1DQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SL1DQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SL1DQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SL1DQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SL1DQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SL1DQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SL1DQSCTL_DXSR 0x3
DQS_N Resistor
PSU_DDR_PHY_DX8SL1DQSCTL_DQSNRES 0x0
DQS Resistor
PSU_DDR_PHY_DX8SL1DQSCTL_DQSRES 0x0
DATX8 0-1 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD08145C, 0xFFFFFFFFU ,0x01264300U)
RegMask = (DDR_PHY_DX8SL1DQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SL1DQSCTL_RRRMODE_MASK | DDR_PHY_DX8SL1DQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SL1DQSCTL_WRRMODE_MASK | DDR_PHY_DX8SL1DQSCTL_DQSGX_MASK | DDR_PHY_DX8SL1DQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SL1DQSCTL_LPIOPD_MASK | DDR_PHY_DX8SL1DQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SL1DQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SL1DQSCTL_UDQIOM_MASK | DDR_PHY_DX8SL1DQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SL1DQSCTL_DXSR_MASK | DDR_PHY_DX8SL1DQSCTL_DQSNRES_MASK | DDR_PHY_DX8SL1DQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL1DQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SL1DQSCTL_DXSR_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_DQSNRES_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL1DQSCTL_OFFSET ,0xFFFFFFFFU ,0x01264300U);
/*############################################################################################################################ */
/*Register : DX8SL1DXCTL2 @ 0XFD08146C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DXCTL2_RESERVED_31_24 0x0
Configurable Read Data Enable
PSU_DDR_PHY_DX8SL1DXCTL2_CRDEN 0x0
OX Extension during Post-amble
PSU_DDR_PHY_DX8SL1DXCTL2_POSOEX 0x0
OE Extension during Pre-amble
PSU_DDR_PHY_DX8SL1DXCTL2_PREOEX 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DXCTL2_RESERVED_17 0x0
I/O Assisted Gate Select
PSU_DDR_PHY_DX8SL1DXCTL2_IOAG 0x0
I/O Loopback Select
PSU_DDR_PHY_DX8SL1DXCTL2_IOLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DXCTL2_RESERVED_14_13 0x0
Low Power Wakeup Threshold
PSU_DDR_PHY_DX8SL1DXCTL2_LPWAKEUP_THRSH 0xc
Read Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL1DXCTL2_RDBI 0x0
Write Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL1DXCTL2_WDBI 0x0
PUB Read FIFO Bypass
PSU_DDR_PHY_DX8SL1DXCTL2_PRFBYP 0x0
DATX8 Receive FIFO Read Mode
PSU_DDR_PHY_DX8SL1DXCTL2_RDMODE 0x0
Disables the Read FIFO Reset
PSU_DDR_PHY_DX8SL1DXCTL2_DISRST 0x0
Read DQS Gate I/O Loopback
PSU_DDR_PHY_DX8SL1DXCTL2_DQSGLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1DXCTL2_RESERVED_0 0x0
DATX8 0-1 DX Control Register 2
(OFFSET, MASK, VALUE) (0XFD08146C, 0xFFFFFFFFU ,0x00041800U)
RegMask = (DDR_PHY_DX8SL1DXCTL2_RESERVED_31_24_MASK | DDR_PHY_DX8SL1DXCTL2_CRDEN_MASK | DDR_PHY_DX8SL1DXCTL2_POSOEX_MASK | DDR_PHY_DX8SL1DXCTL2_PREOEX_MASK | DDR_PHY_DX8SL1DXCTL2_RESERVED_17_MASK | DDR_PHY_DX8SL1DXCTL2_IOAG_MASK | DDR_PHY_DX8SL1DXCTL2_IOLB_MASK | DDR_PHY_DX8SL1DXCTL2_RESERVED_14_13_MASK | DDR_PHY_DX8SL1DXCTL2_LPWAKEUP_THRSH_MASK | DDR_PHY_DX8SL1DXCTL2_RDBI_MASK | DDR_PHY_DX8SL1DXCTL2_WDBI_MASK | DDR_PHY_DX8SL1DXCTL2_PRFBYP_MASK | DDR_PHY_DX8SL1DXCTL2_RDMODE_MASK | DDR_PHY_DX8SL1DXCTL2_DISRST_MASK | DDR_PHY_DX8SL1DXCTL2_DQSGLB_MASK | DDR_PHY_DX8SL1DXCTL2_RESERVED_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL1DXCTL2_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_CRDEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_POSOEX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL1DXCTL2_PREOEX_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_RESERVED_17_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_IOAG_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_IOLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_RESERVED_14_13_SHIFT
| 0x0000000CU << DDR_PHY_DX8SL1DXCTL2_LPWAKEUP_THRSH_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_RDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_WDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_PRFBYP_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_DISRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_DQSGLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1DXCTL2_RESERVED_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL1DXCTL2_OFFSET ,0xFFFFFFFFU ,0x00041800U);
/*############################################################################################################################ */
/*Register : DX8SL1IOCR @ 0XFD081470</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL1IOCR_RESERVED_31 0x0
PVREF_DAC REFSEL range select
PSU_DDR_PHY_DX8SL1IOCR_DXDACRANGE 0x7
IOM bits for PVREF, PVREF_DAC and PVREFE cells in DX IO ring
PSU_DDR_PHY_DX8SL1IOCR_DXVREFIOM 0x0
DX IO Mode
PSU_DDR_PHY_DX8SL1IOCR_DXIOM 0x2
DX IO Transmitter Mode
PSU_DDR_PHY_DX8SL1IOCR_DXTXM 0x0
DX IO Receiver Mode
PSU_DDR_PHY_DX8SL1IOCR_DXRXM 0x0
DATX8 0-1 I/O Configuration Register
(OFFSET, MASK, VALUE) (0XFD081470, 0xFFFFFFFFU ,0x70800000U)
RegMask = (DDR_PHY_DX8SL1IOCR_RESERVED_31_MASK | DDR_PHY_DX8SL1IOCR_DXDACRANGE_MASK | DDR_PHY_DX8SL1IOCR_DXVREFIOM_MASK | DDR_PHY_DX8SL1IOCR_DXIOM_MASK | DDR_PHY_DX8SL1IOCR_DXTXM_MASK | DDR_PHY_DX8SL1IOCR_DXRXM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL1IOCR_RESERVED_31_SHIFT
| 0x00000007U << DDR_PHY_DX8SL1IOCR_DXDACRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1IOCR_DXVREFIOM_SHIFT
| 0x00000002U << DDR_PHY_DX8SL1IOCR_DXIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1IOCR_DXTXM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL1IOCR_DXRXM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL1IOCR_OFFSET ,0xFFFFFFFFU ,0x70800000U);
/*############################################################################################################################ */
/*Register : DX8SL2OSC @ 0XFD081480</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2OSC_RESERVED_31_30 0x0
Enable Clock Gating for DX ddr_clk
PSU_DDR_PHY_DX8SL2OSC_GATEDXRDCLK 0x2
Enable Clock Gating for DX ctl_rd_clk
PSU_DDR_PHY_DX8SL2OSC_GATEDXDDRCLK 0x2
Enable Clock Gating for DX ctl_clk
PSU_DDR_PHY_DX8SL2OSC_GATEDXCTLCLK 0x2
Selects the level to which clocks will be stalled when clock gating is enabled.
PSU_DDR_PHY_DX8SL2OSC_CLKLEVEL 0x0
Loopback Mode
PSU_DDR_PHY_DX8SL2OSC_LBMODE 0x0
Load GSDQS LCDL with 2x the calibrated GSDQSPRD value
PSU_DDR_PHY_DX8SL2OSC_LBGSDQS 0x0
Loopback DQS Gating
PSU_DDR_PHY_DX8SL2OSC_LBGDQS 0x0
Loopback DQS Shift
PSU_DDR_PHY_DX8SL2OSC_LBDQSS 0x0
PHY High-Speed Reset
PSU_DDR_PHY_DX8SL2OSC_PHYHRST 0x1
PHY FIFO Reset
PSU_DDR_PHY_DX8SL2OSC_PHYFRST 0x1
Delay Line Test Start
PSU_DDR_PHY_DX8SL2OSC_DLTST 0x0
Delay Line Test Mode
PSU_DDR_PHY_DX8SL2OSC_DLTMODE 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL2OSC_RESERVED_12_11 0x3
Oscillator Mode Write-Data Delay Line Select
PSU_DDR_PHY_DX8SL2OSC_OSCWDDL 0x3
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL2OSC_RESERVED_8_7 0x3
Oscillator Mode Write-Leveling Delay Line Select
PSU_DDR_PHY_DX8SL2OSC_OSCWDL 0x3
Oscillator Mode Division
PSU_DDR_PHY_DX8SL2OSC_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_DX8SL2OSC_OSCEN 0x0
DATX8 0-1 Oscillator, Delay Line Test, PHY FIFO and High Speed Reset, Loopback, and Gated Clock Control Register
(OFFSET, MASK, VALUE) (0XFD081480, 0xFFFFFFFFU ,0x2A019FFEU)
RegMask = (DDR_PHY_DX8SL2OSC_RESERVED_31_30_MASK | DDR_PHY_DX8SL2OSC_GATEDXRDCLK_MASK | DDR_PHY_DX8SL2OSC_GATEDXDDRCLK_MASK | DDR_PHY_DX8SL2OSC_GATEDXCTLCLK_MASK | DDR_PHY_DX8SL2OSC_CLKLEVEL_MASK | DDR_PHY_DX8SL2OSC_LBMODE_MASK | DDR_PHY_DX8SL2OSC_LBGSDQS_MASK | DDR_PHY_DX8SL2OSC_LBGDQS_MASK | DDR_PHY_DX8SL2OSC_LBDQSS_MASK | DDR_PHY_DX8SL2OSC_PHYHRST_MASK | DDR_PHY_DX8SL2OSC_PHYFRST_MASK | DDR_PHY_DX8SL2OSC_DLTST_MASK | DDR_PHY_DX8SL2OSC_DLTMODE_MASK | DDR_PHY_DX8SL2OSC_RESERVED_12_11_MASK | DDR_PHY_DX8SL2OSC_OSCWDDL_MASK | DDR_PHY_DX8SL2OSC_RESERVED_8_7_MASK | DDR_PHY_DX8SL2OSC_OSCWDL_MASK | DDR_PHY_DX8SL2OSC_OSCDIV_MASK | DDR_PHY_DX8SL2OSC_OSCEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL2OSC_RESERVED_31_30_SHIFT
| 0x00000002U << DDR_PHY_DX8SL2OSC_GATEDXRDCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL2OSC_GATEDXDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL2OSC_GATEDXCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_CLKLEVEL_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_LBMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_LBGSDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_LBGDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_LBDQSS_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2OSC_PHYHRST_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2OSC_PHYFRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_DLTST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_DLTMODE_SHIFT
| 0x00000003U << DDR_PHY_DX8SL2OSC_RESERVED_12_11_SHIFT
| 0x00000003U << DDR_PHY_DX8SL2OSC_OSCWDDL_SHIFT
| 0x00000003U << DDR_PHY_DX8SL2OSC_RESERVED_8_7_SHIFT
| 0x00000003U << DDR_PHY_DX8SL2OSC_OSCWDL_SHIFT
| 0x0000000FU << DDR_PHY_DX8SL2OSC_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2OSC_OSCEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL2OSC_OFFSET ,0xFFFFFFFFU ,0x2A019FFEU);
/*############################################################################################################################ */
/*Register : DX8SL2DQSCTL @ 0XFD08149C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL2DQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL2DQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SL2DQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SL2DQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SL2DQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SL2DQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SL2DQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SL2DQSCTL_DXSR 0x3
DQS_N Resistor
PSU_DDR_PHY_DX8SL2DQSCTL_DQSNRES 0x0
DQS Resistor
PSU_DDR_PHY_DX8SL2DQSCTL_DQSRES 0x0
DATX8 0-1 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD08149C, 0xFFFFFFFFU ,0x01264300U)
RegMask = (DDR_PHY_DX8SL2DQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SL2DQSCTL_RRRMODE_MASK | DDR_PHY_DX8SL2DQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SL2DQSCTL_WRRMODE_MASK | DDR_PHY_DX8SL2DQSCTL_DQSGX_MASK | DDR_PHY_DX8SL2DQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SL2DQSCTL_LPIOPD_MASK | DDR_PHY_DX8SL2DQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SL2DQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SL2DQSCTL_UDQIOM_MASK | DDR_PHY_DX8SL2DQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SL2DQSCTL_DXSR_MASK | DDR_PHY_DX8SL2DQSCTL_DQSNRES_MASK | DDR_PHY_DX8SL2DQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL2DQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SL2DQSCTL_DXSR_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_DQSNRES_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL2DQSCTL_OFFSET ,0xFFFFFFFFU ,0x01264300U);
/*############################################################################################################################ */
/*Register : DX8SL2DXCTL2 @ 0XFD0814AC</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DXCTL2_RESERVED_31_24 0x0
Configurable Read Data Enable
PSU_DDR_PHY_DX8SL2DXCTL2_CRDEN 0x0
OX Extension during Post-amble
PSU_DDR_PHY_DX8SL2DXCTL2_POSOEX 0x0
OE Extension during Pre-amble
PSU_DDR_PHY_DX8SL2DXCTL2_PREOEX 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DXCTL2_RESERVED_17 0x0
I/O Assisted Gate Select
PSU_DDR_PHY_DX8SL2DXCTL2_IOAG 0x0
I/O Loopback Select
PSU_DDR_PHY_DX8SL2DXCTL2_IOLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DXCTL2_RESERVED_14_13 0x0
Low Power Wakeup Threshold
PSU_DDR_PHY_DX8SL2DXCTL2_LPWAKEUP_THRSH 0xc
Read Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL2DXCTL2_RDBI 0x0
Write Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL2DXCTL2_WDBI 0x0
PUB Read FIFO Bypass
PSU_DDR_PHY_DX8SL2DXCTL2_PRFBYP 0x0
DATX8 Receive FIFO Read Mode
PSU_DDR_PHY_DX8SL2DXCTL2_RDMODE 0x0
Disables the Read FIFO Reset
PSU_DDR_PHY_DX8SL2DXCTL2_DISRST 0x0
Read DQS Gate I/O Loopback
PSU_DDR_PHY_DX8SL2DXCTL2_DQSGLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2DXCTL2_RESERVED_0 0x0
DATX8 0-1 DX Control Register 2
(OFFSET, MASK, VALUE) (0XFD0814AC, 0xFFFFFFFFU ,0x00041800U)
RegMask = (DDR_PHY_DX8SL2DXCTL2_RESERVED_31_24_MASK | DDR_PHY_DX8SL2DXCTL2_CRDEN_MASK | DDR_PHY_DX8SL2DXCTL2_POSOEX_MASK | DDR_PHY_DX8SL2DXCTL2_PREOEX_MASK | DDR_PHY_DX8SL2DXCTL2_RESERVED_17_MASK | DDR_PHY_DX8SL2DXCTL2_IOAG_MASK | DDR_PHY_DX8SL2DXCTL2_IOLB_MASK | DDR_PHY_DX8SL2DXCTL2_RESERVED_14_13_MASK | DDR_PHY_DX8SL2DXCTL2_LPWAKEUP_THRSH_MASK | DDR_PHY_DX8SL2DXCTL2_RDBI_MASK | DDR_PHY_DX8SL2DXCTL2_WDBI_MASK | DDR_PHY_DX8SL2DXCTL2_PRFBYP_MASK | DDR_PHY_DX8SL2DXCTL2_RDMODE_MASK | DDR_PHY_DX8SL2DXCTL2_DISRST_MASK | DDR_PHY_DX8SL2DXCTL2_DQSGLB_MASK | DDR_PHY_DX8SL2DXCTL2_RESERVED_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL2DXCTL2_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_CRDEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_POSOEX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL2DXCTL2_PREOEX_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_RESERVED_17_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_IOAG_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_IOLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_RESERVED_14_13_SHIFT
| 0x0000000CU << DDR_PHY_DX8SL2DXCTL2_LPWAKEUP_THRSH_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_RDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_WDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_PRFBYP_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_DISRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_DQSGLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2DXCTL2_RESERVED_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL2DXCTL2_OFFSET ,0xFFFFFFFFU ,0x00041800U);
/*############################################################################################################################ */
/*Register : DX8SL2IOCR @ 0XFD0814B0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL2IOCR_RESERVED_31 0x0
PVREF_DAC REFSEL range select
PSU_DDR_PHY_DX8SL2IOCR_DXDACRANGE 0x7
IOM bits for PVREF, PVREF_DAC and PVREFE cells in DX IO ring
PSU_DDR_PHY_DX8SL2IOCR_DXVREFIOM 0x0
DX IO Mode
PSU_DDR_PHY_DX8SL2IOCR_DXIOM 0x2
DX IO Transmitter Mode
PSU_DDR_PHY_DX8SL2IOCR_DXTXM 0x0
DX IO Receiver Mode
PSU_DDR_PHY_DX8SL2IOCR_DXRXM 0x0
DATX8 0-1 I/O Configuration Register
(OFFSET, MASK, VALUE) (0XFD0814B0, 0xFFFFFFFFU ,0x70800000U)
RegMask = (DDR_PHY_DX8SL2IOCR_RESERVED_31_MASK | DDR_PHY_DX8SL2IOCR_DXDACRANGE_MASK | DDR_PHY_DX8SL2IOCR_DXVREFIOM_MASK | DDR_PHY_DX8SL2IOCR_DXIOM_MASK | DDR_PHY_DX8SL2IOCR_DXTXM_MASK | DDR_PHY_DX8SL2IOCR_DXRXM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL2IOCR_RESERVED_31_SHIFT
| 0x00000007U << DDR_PHY_DX8SL2IOCR_DXDACRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2IOCR_DXVREFIOM_SHIFT
| 0x00000002U << DDR_PHY_DX8SL2IOCR_DXIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2IOCR_DXTXM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL2IOCR_DXRXM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL2IOCR_OFFSET ,0xFFFFFFFFU ,0x70800000U);
/*############################################################################################################################ */
/*Register : DX8SL3OSC @ 0XFD0814C0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3OSC_RESERVED_31_30 0x0
Enable Clock Gating for DX ddr_clk
PSU_DDR_PHY_DX8SL3OSC_GATEDXRDCLK 0x2
Enable Clock Gating for DX ctl_rd_clk
PSU_DDR_PHY_DX8SL3OSC_GATEDXDDRCLK 0x2
Enable Clock Gating for DX ctl_clk
PSU_DDR_PHY_DX8SL3OSC_GATEDXCTLCLK 0x2
Selects the level to which clocks will be stalled when clock gating is enabled.
PSU_DDR_PHY_DX8SL3OSC_CLKLEVEL 0x0
Loopback Mode
PSU_DDR_PHY_DX8SL3OSC_LBMODE 0x0
Load GSDQS LCDL with 2x the calibrated GSDQSPRD value
PSU_DDR_PHY_DX8SL3OSC_LBGSDQS 0x0
Loopback DQS Gating
PSU_DDR_PHY_DX8SL3OSC_LBGDQS 0x0
Loopback DQS Shift
PSU_DDR_PHY_DX8SL3OSC_LBDQSS 0x0
PHY High-Speed Reset
PSU_DDR_PHY_DX8SL3OSC_PHYHRST 0x1
PHY FIFO Reset
PSU_DDR_PHY_DX8SL3OSC_PHYFRST 0x1
Delay Line Test Start
PSU_DDR_PHY_DX8SL3OSC_DLTST 0x0
Delay Line Test Mode
PSU_DDR_PHY_DX8SL3OSC_DLTMODE 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL3OSC_RESERVED_12_11 0x3
Oscillator Mode Write-Data Delay Line Select
PSU_DDR_PHY_DX8SL3OSC_OSCWDDL 0x3
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL3OSC_RESERVED_8_7 0x3
Oscillator Mode Write-Leveling Delay Line Select
PSU_DDR_PHY_DX8SL3OSC_OSCWDL 0x3
Oscillator Mode Division
PSU_DDR_PHY_DX8SL3OSC_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_DX8SL3OSC_OSCEN 0x0
DATX8 0-1 Oscillator, Delay Line Test, PHY FIFO and High Speed Reset, Loopback, and Gated Clock Control Register
(OFFSET, MASK, VALUE) (0XFD0814C0, 0xFFFFFFFFU ,0x2A019FFEU)
RegMask = (DDR_PHY_DX8SL3OSC_RESERVED_31_30_MASK | DDR_PHY_DX8SL3OSC_GATEDXRDCLK_MASK | DDR_PHY_DX8SL3OSC_GATEDXDDRCLK_MASK | DDR_PHY_DX8SL3OSC_GATEDXCTLCLK_MASK | DDR_PHY_DX8SL3OSC_CLKLEVEL_MASK | DDR_PHY_DX8SL3OSC_LBMODE_MASK | DDR_PHY_DX8SL3OSC_LBGSDQS_MASK | DDR_PHY_DX8SL3OSC_LBGDQS_MASK | DDR_PHY_DX8SL3OSC_LBDQSS_MASK | DDR_PHY_DX8SL3OSC_PHYHRST_MASK | DDR_PHY_DX8SL3OSC_PHYFRST_MASK | DDR_PHY_DX8SL3OSC_DLTST_MASK | DDR_PHY_DX8SL3OSC_DLTMODE_MASK | DDR_PHY_DX8SL3OSC_RESERVED_12_11_MASK | DDR_PHY_DX8SL3OSC_OSCWDDL_MASK | DDR_PHY_DX8SL3OSC_RESERVED_8_7_MASK | DDR_PHY_DX8SL3OSC_OSCWDL_MASK | DDR_PHY_DX8SL3OSC_OSCDIV_MASK | DDR_PHY_DX8SL3OSC_OSCEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL3OSC_RESERVED_31_30_SHIFT
| 0x00000002U << DDR_PHY_DX8SL3OSC_GATEDXRDCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL3OSC_GATEDXDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL3OSC_GATEDXCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_CLKLEVEL_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_LBMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_LBGSDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_LBGDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_LBDQSS_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3OSC_PHYHRST_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3OSC_PHYFRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_DLTST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_DLTMODE_SHIFT
| 0x00000003U << DDR_PHY_DX8SL3OSC_RESERVED_12_11_SHIFT
| 0x00000003U << DDR_PHY_DX8SL3OSC_OSCWDDL_SHIFT
| 0x00000003U << DDR_PHY_DX8SL3OSC_RESERVED_8_7_SHIFT
| 0x00000003U << DDR_PHY_DX8SL3OSC_OSCWDL_SHIFT
| 0x0000000FU << DDR_PHY_DX8SL3OSC_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3OSC_OSCEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL3OSC_OFFSET ,0xFFFFFFFFU ,0x2A019FFEU);
/*############################################################################################################################ */
/*Register : DX8SL3DQSCTL @ 0XFD0814DC</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL3DQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL3DQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SL3DQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SL3DQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SL3DQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SL3DQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SL3DQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SL3DQSCTL_DXSR 0x3
DQS_N Resistor
PSU_DDR_PHY_DX8SL3DQSCTL_DQSNRES 0x0
DQS Resistor
PSU_DDR_PHY_DX8SL3DQSCTL_DQSRES 0x0
DATX8 0-1 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD0814DC, 0xFFFFFFFFU ,0x01264300U)
RegMask = (DDR_PHY_DX8SL3DQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SL3DQSCTL_RRRMODE_MASK | DDR_PHY_DX8SL3DQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SL3DQSCTL_WRRMODE_MASK | DDR_PHY_DX8SL3DQSCTL_DQSGX_MASK | DDR_PHY_DX8SL3DQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SL3DQSCTL_LPIOPD_MASK | DDR_PHY_DX8SL3DQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SL3DQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SL3DQSCTL_UDQIOM_MASK | DDR_PHY_DX8SL3DQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SL3DQSCTL_DXSR_MASK | DDR_PHY_DX8SL3DQSCTL_DQSNRES_MASK | DDR_PHY_DX8SL3DQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL3DQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SL3DQSCTL_DXSR_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_DQSNRES_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL3DQSCTL_OFFSET ,0xFFFFFFFFU ,0x01264300U);
/*############################################################################################################################ */
/*Register : DX8SL3DXCTL2 @ 0XFD0814EC</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DXCTL2_RESERVED_31_24 0x0
Configurable Read Data Enable
PSU_DDR_PHY_DX8SL3DXCTL2_CRDEN 0x0
OX Extension during Post-amble
PSU_DDR_PHY_DX8SL3DXCTL2_POSOEX 0x0
OE Extension during Pre-amble
PSU_DDR_PHY_DX8SL3DXCTL2_PREOEX 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DXCTL2_RESERVED_17 0x0
I/O Assisted Gate Select
PSU_DDR_PHY_DX8SL3DXCTL2_IOAG 0x0
I/O Loopback Select
PSU_DDR_PHY_DX8SL3DXCTL2_IOLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DXCTL2_RESERVED_14_13 0x0
Low Power Wakeup Threshold
PSU_DDR_PHY_DX8SL3DXCTL2_LPWAKEUP_THRSH 0xc
Read Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL3DXCTL2_RDBI 0x0
Write Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL3DXCTL2_WDBI 0x0
PUB Read FIFO Bypass
PSU_DDR_PHY_DX8SL3DXCTL2_PRFBYP 0x0
DATX8 Receive FIFO Read Mode
PSU_DDR_PHY_DX8SL3DXCTL2_RDMODE 0x0
Disables the Read FIFO Reset
PSU_DDR_PHY_DX8SL3DXCTL2_DISRST 0x0
Read DQS Gate I/O Loopback
PSU_DDR_PHY_DX8SL3DXCTL2_DQSGLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3DXCTL2_RESERVED_0 0x0
DATX8 0-1 DX Control Register 2
(OFFSET, MASK, VALUE) (0XFD0814EC, 0xFFFFFFFFU ,0x00041800U)
RegMask = (DDR_PHY_DX8SL3DXCTL2_RESERVED_31_24_MASK | DDR_PHY_DX8SL3DXCTL2_CRDEN_MASK | DDR_PHY_DX8SL3DXCTL2_POSOEX_MASK | DDR_PHY_DX8SL3DXCTL2_PREOEX_MASK | DDR_PHY_DX8SL3DXCTL2_RESERVED_17_MASK | DDR_PHY_DX8SL3DXCTL2_IOAG_MASK | DDR_PHY_DX8SL3DXCTL2_IOLB_MASK | DDR_PHY_DX8SL3DXCTL2_RESERVED_14_13_MASK | DDR_PHY_DX8SL3DXCTL2_LPWAKEUP_THRSH_MASK | DDR_PHY_DX8SL3DXCTL2_RDBI_MASK | DDR_PHY_DX8SL3DXCTL2_WDBI_MASK | DDR_PHY_DX8SL3DXCTL2_PRFBYP_MASK | DDR_PHY_DX8SL3DXCTL2_RDMODE_MASK | DDR_PHY_DX8SL3DXCTL2_DISRST_MASK | DDR_PHY_DX8SL3DXCTL2_DQSGLB_MASK | DDR_PHY_DX8SL3DXCTL2_RESERVED_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL3DXCTL2_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_CRDEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_POSOEX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL3DXCTL2_PREOEX_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_RESERVED_17_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_IOAG_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_IOLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_RESERVED_14_13_SHIFT
| 0x0000000CU << DDR_PHY_DX8SL3DXCTL2_LPWAKEUP_THRSH_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_RDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_WDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_PRFBYP_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_DISRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_DQSGLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3DXCTL2_RESERVED_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL3DXCTL2_OFFSET ,0xFFFFFFFFU ,0x00041800U);
/*############################################################################################################################ */
/*Register : DX8SL3IOCR @ 0XFD0814F0</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL3IOCR_RESERVED_31 0x0
PVREF_DAC REFSEL range select
PSU_DDR_PHY_DX8SL3IOCR_DXDACRANGE 0x7
IOM bits for PVREF, PVREF_DAC and PVREFE cells in DX IO ring
PSU_DDR_PHY_DX8SL3IOCR_DXVREFIOM 0x0
DX IO Mode
PSU_DDR_PHY_DX8SL3IOCR_DXIOM 0x2
DX IO Transmitter Mode
PSU_DDR_PHY_DX8SL3IOCR_DXTXM 0x0
DX IO Receiver Mode
PSU_DDR_PHY_DX8SL3IOCR_DXRXM 0x0
DATX8 0-1 I/O Configuration Register
(OFFSET, MASK, VALUE) (0XFD0814F0, 0xFFFFFFFFU ,0x70800000U)
RegMask = (DDR_PHY_DX8SL3IOCR_RESERVED_31_MASK | DDR_PHY_DX8SL3IOCR_DXDACRANGE_MASK | DDR_PHY_DX8SL3IOCR_DXVREFIOM_MASK | DDR_PHY_DX8SL3IOCR_DXIOM_MASK | DDR_PHY_DX8SL3IOCR_DXTXM_MASK | DDR_PHY_DX8SL3IOCR_DXRXM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL3IOCR_RESERVED_31_SHIFT
| 0x00000007U << DDR_PHY_DX8SL3IOCR_DXDACRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3IOCR_DXVREFIOM_SHIFT
| 0x00000002U << DDR_PHY_DX8SL3IOCR_DXIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3IOCR_DXTXM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL3IOCR_DXRXM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL3IOCR_OFFSET ,0xFFFFFFFFU ,0x70800000U);
/*############################################################################################################################ */
/*Register : DX8SL4OSC @ 0XFD081500</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4OSC_RESERVED_31_30 0x0
Enable Clock Gating for DX ddr_clk
PSU_DDR_PHY_DX8SL4OSC_GATEDXRDCLK 0x2
Enable Clock Gating for DX ctl_rd_clk
PSU_DDR_PHY_DX8SL4OSC_GATEDXDDRCLK 0x2
Enable Clock Gating for DX ctl_clk
PSU_DDR_PHY_DX8SL4OSC_GATEDXCTLCLK 0x2
Selects the level to which clocks will be stalled when clock gating is enabled.
PSU_DDR_PHY_DX8SL4OSC_CLKLEVEL 0x0
Loopback Mode
PSU_DDR_PHY_DX8SL4OSC_LBMODE 0x0
Load GSDQS LCDL with 2x the calibrated GSDQSPRD value
PSU_DDR_PHY_DX8SL4OSC_LBGSDQS 0x0
Loopback DQS Gating
PSU_DDR_PHY_DX8SL4OSC_LBGDQS 0x0
Loopback DQS Shift
PSU_DDR_PHY_DX8SL4OSC_LBDQSS 0x0
PHY High-Speed Reset
PSU_DDR_PHY_DX8SL4OSC_PHYHRST 0x1
PHY FIFO Reset
PSU_DDR_PHY_DX8SL4OSC_PHYFRST 0x1
Delay Line Test Start
PSU_DDR_PHY_DX8SL4OSC_DLTST 0x0
Delay Line Test Mode
PSU_DDR_PHY_DX8SL4OSC_DLTMODE 0x0
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL4OSC_RESERVED_12_11 0x3
Oscillator Mode Write-Data Delay Line Select
PSU_DDR_PHY_DX8SL4OSC_OSCWDDL 0x3
Reserved. Caution, do not write to this register field.
PSU_DDR_PHY_DX8SL4OSC_RESERVED_8_7 0x3
Oscillator Mode Write-Leveling Delay Line Select
PSU_DDR_PHY_DX8SL4OSC_OSCWDL 0x3
Oscillator Mode Division
PSU_DDR_PHY_DX8SL4OSC_OSCDIV 0xf
Oscillator Enable
PSU_DDR_PHY_DX8SL4OSC_OSCEN 0x0
DATX8 0-1 Oscillator, Delay Line Test, PHY FIFO and High Speed Reset, Loopback, and Gated Clock Control Register
(OFFSET, MASK, VALUE) (0XFD081500, 0xFFFFFFFFU ,0x2A019FFEU)
RegMask = (DDR_PHY_DX8SL4OSC_RESERVED_31_30_MASK | DDR_PHY_DX8SL4OSC_GATEDXRDCLK_MASK | DDR_PHY_DX8SL4OSC_GATEDXDDRCLK_MASK | DDR_PHY_DX8SL4OSC_GATEDXCTLCLK_MASK | DDR_PHY_DX8SL4OSC_CLKLEVEL_MASK | DDR_PHY_DX8SL4OSC_LBMODE_MASK | DDR_PHY_DX8SL4OSC_LBGSDQS_MASK | DDR_PHY_DX8SL4OSC_LBGDQS_MASK | DDR_PHY_DX8SL4OSC_LBDQSS_MASK | DDR_PHY_DX8SL4OSC_PHYHRST_MASK | DDR_PHY_DX8SL4OSC_PHYFRST_MASK | DDR_PHY_DX8SL4OSC_DLTST_MASK | DDR_PHY_DX8SL4OSC_DLTMODE_MASK | DDR_PHY_DX8SL4OSC_RESERVED_12_11_MASK | DDR_PHY_DX8SL4OSC_OSCWDDL_MASK | DDR_PHY_DX8SL4OSC_RESERVED_8_7_MASK | DDR_PHY_DX8SL4OSC_OSCWDL_MASK | DDR_PHY_DX8SL4OSC_OSCDIV_MASK | DDR_PHY_DX8SL4OSC_OSCEN_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL4OSC_RESERVED_31_30_SHIFT
| 0x00000002U << DDR_PHY_DX8SL4OSC_GATEDXRDCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL4OSC_GATEDXDDRCLK_SHIFT
| 0x00000002U << DDR_PHY_DX8SL4OSC_GATEDXCTLCLK_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_CLKLEVEL_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_LBMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_LBGSDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_LBGDQS_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_LBDQSS_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4OSC_PHYHRST_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4OSC_PHYFRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_DLTST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_DLTMODE_SHIFT
| 0x00000003U << DDR_PHY_DX8SL4OSC_RESERVED_12_11_SHIFT
| 0x00000003U << DDR_PHY_DX8SL4OSC_OSCWDDL_SHIFT
| 0x00000003U << DDR_PHY_DX8SL4OSC_RESERVED_8_7_SHIFT
| 0x00000003U << DDR_PHY_DX8SL4OSC_OSCWDL_SHIFT
| 0x0000000FU << DDR_PHY_DX8SL4OSC_OSCDIV_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4OSC_OSCEN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL4OSC_OFFSET ,0xFFFFFFFFU ,0x2A019FFEU);
/*############################################################################################################################ */
/*Register : DX8SL4DQSCTL @ 0XFD08151C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL4DQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SL4DQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SL4DQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SL4DQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SL4DQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SL4DQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SL4DQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SL4DQSCTL_DXSR 0x3
DQS_N Resistor
PSU_DDR_PHY_DX8SL4DQSCTL_DQSNRES 0x0
DQS Resistor
PSU_DDR_PHY_DX8SL4DQSCTL_DQSRES 0x0
DATX8 0-1 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD08151C, 0xFFFFFFFFU ,0x01264300U)
RegMask = (DDR_PHY_DX8SL4DQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SL4DQSCTL_RRRMODE_MASK | DDR_PHY_DX8SL4DQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SL4DQSCTL_WRRMODE_MASK | DDR_PHY_DX8SL4DQSCTL_DQSGX_MASK | DDR_PHY_DX8SL4DQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SL4DQSCTL_LPIOPD_MASK | DDR_PHY_DX8SL4DQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SL4DQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SL4DQSCTL_UDQIOM_MASK | DDR_PHY_DX8SL4DQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SL4DQSCTL_DXSR_MASK | DDR_PHY_DX8SL4DQSCTL_DQSNRES_MASK | DDR_PHY_DX8SL4DQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL4DQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SL4DQSCTL_DXSR_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_DQSNRES_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL4DQSCTL_OFFSET ,0xFFFFFFFFU ,0x01264300U);
/*############################################################################################################################ */
/*Register : DX8SL4DXCTL2 @ 0XFD08152C</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DXCTL2_RESERVED_31_24 0x0
Configurable Read Data Enable
PSU_DDR_PHY_DX8SL4DXCTL2_CRDEN 0x0
OX Extension during Post-amble
PSU_DDR_PHY_DX8SL4DXCTL2_POSOEX 0x0
OE Extension during Pre-amble
PSU_DDR_PHY_DX8SL4DXCTL2_PREOEX 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DXCTL2_RESERVED_17 0x0
I/O Assisted Gate Select
PSU_DDR_PHY_DX8SL4DXCTL2_IOAG 0x0
I/O Loopback Select
PSU_DDR_PHY_DX8SL4DXCTL2_IOLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DXCTL2_RESERVED_14_13 0x0
Low Power Wakeup Threshold
PSU_DDR_PHY_DX8SL4DXCTL2_LPWAKEUP_THRSH 0xc
Read Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL4DXCTL2_RDBI 0x0
Write Data Bus Inversion Enable
PSU_DDR_PHY_DX8SL4DXCTL2_WDBI 0x0
PUB Read FIFO Bypass
PSU_DDR_PHY_DX8SL4DXCTL2_PRFBYP 0x0
DATX8 Receive FIFO Read Mode
PSU_DDR_PHY_DX8SL4DXCTL2_RDMODE 0x0
Disables the Read FIFO Reset
PSU_DDR_PHY_DX8SL4DXCTL2_DISRST 0x0
Read DQS Gate I/O Loopback
PSU_DDR_PHY_DX8SL4DXCTL2_DQSGLB 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4DXCTL2_RESERVED_0 0x0
DATX8 0-1 DX Control Register 2
(OFFSET, MASK, VALUE) (0XFD08152C, 0xFFFFFFFFU ,0x00041800U)
RegMask = (DDR_PHY_DX8SL4DXCTL2_RESERVED_31_24_MASK | DDR_PHY_DX8SL4DXCTL2_CRDEN_MASK | DDR_PHY_DX8SL4DXCTL2_POSOEX_MASK | DDR_PHY_DX8SL4DXCTL2_PREOEX_MASK | DDR_PHY_DX8SL4DXCTL2_RESERVED_17_MASK | DDR_PHY_DX8SL4DXCTL2_IOAG_MASK | DDR_PHY_DX8SL4DXCTL2_IOLB_MASK | DDR_PHY_DX8SL4DXCTL2_RESERVED_14_13_MASK | DDR_PHY_DX8SL4DXCTL2_LPWAKEUP_THRSH_MASK | DDR_PHY_DX8SL4DXCTL2_RDBI_MASK | DDR_PHY_DX8SL4DXCTL2_WDBI_MASK | DDR_PHY_DX8SL4DXCTL2_PRFBYP_MASK | DDR_PHY_DX8SL4DXCTL2_RDMODE_MASK | DDR_PHY_DX8SL4DXCTL2_DISRST_MASK | DDR_PHY_DX8SL4DXCTL2_DQSGLB_MASK | DDR_PHY_DX8SL4DXCTL2_RESERVED_0_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL4DXCTL2_RESERVED_31_24_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_CRDEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_POSOEX_SHIFT
| 0x00000001U << DDR_PHY_DX8SL4DXCTL2_PREOEX_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_RESERVED_17_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_IOAG_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_IOLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_RESERVED_14_13_SHIFT
| 0x0000000CU << DDR_PHY_DX8SL4DXCTL2_LPWAKEUP_THRSH_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_RDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_WDBI_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_PRFBYP_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_RDMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_DISRST_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_DQSGLB_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4DXCTL2_RESERVED_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL4DXCTL2_OFFSET ,0xFFFFFFFFU ,0x00041800U);
/*############################################################################################################################ */
/*Register : DX8SL4IOCR @ 0XFD081530</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SL4IOCR_RESERVED_31 0x0
PVREF_DAC REFSEL range select
PSU_DDR_PHY_DX8SL4IOCR_DXDACRANGE 0x7
IOM bits for PVREF, PVREF_DAC and PVREFE cells in DX IO ring
PSU_DDR_PHY_DX8SL4IOCR_DXVREFIOM 0x0
DX IO Mode
PSU_DDR_PHY_DX8SL4IOCR_DXIOM 0x2
DX IO Transmitter Mode
PSU_DDR_PHY_DX8SL4IOCR_DXTXM 0x0
DX IO Receiver Mode
PSU_DDR_PHY_DX8SL4IOCR_DXRXM 0x0
DATX8 0-1 I/O Configuration Register
(OFFSET, MASK, VALUE) (0XFD081530, 0xFFFFFFFFU ,0x70800000U)
RegMask = (DDR_PHY_DX8SL4IOCR_RESERVED_31_MASK | DDR_PHY_DX8SL4IOCR_DXDACRANGE_MASK | DDR_PHY_DX8SL4IOCR_DXVREFIOM_MASK | DDR_PHY_DX8SL4IOCR_DXIOM_MASK | DDR_PHY_DX8SL4IOCR_DXTXM_MASK | DDR_PHY_DX8SL4IOCR_DXRXM_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SL4IOCR_RESERVED_31_SHIFT
| 0x00000007U << DDR_PHY_DX8SL4IOCR_DXDACRANGE_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4IOCR_DXVREFIOM_SHIFT
| 0x00000002U << DDR_PHY_DX8SL4IOCR_DXIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4IOCR_DXTXM_SHIFT
| 0x00000000U << DDR_PHY_DX8SL4IOCR_DXRXM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SL4IOCR_OFFSET ,0xFFFFFFFFU ,0x70800000U);
/*############################################################################################################################ */
/*Register : DX8SLbDQSCTL @ 0XFD0817DC</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SLBDQSCTL_RESERVED_31_25 0x0
Read Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SLBDQSCTL_RRRMODE 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SLBDQSCTL_RESERVED_23_22 0x0
Write Path Rise-to-Rise Mode
PSU_DDR_PHY_DX8SLBDQSCTL_WRRMODE 0x1
DQS Gate Extension
PSU_DDR_PHY_DX8SLBDQSCTL_DQSGX 0x0
Low Power PLL Power Down
PSU_DDR_PHY_DX8SLBDQSCTL_LPPLLPD 0x1
Low Power I/O Power Down
PSU_DDR_PHY_DX8SLBDQSCTL_LPIOPD 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SLBDQSCTL_RESERVED_16_15 0x0
QS Counter Enable
PSU_DDR_PHY_DX8SLBDQSCTL_QSCNTEN 0x1
Unused DQ I/O Mode
PSU_DDR_PHY_DX8SLBDQSCTL_UDQIOM 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_DX8SLBDQSCTL_RESERVED_12_10 0x0
Data Slew Rate
PSU_DDR_PHY_DX8SLBDQSCTL_DXSR 0x3
DQS# Resistor
PSU_DDR_PHY_DX8SLBDQSCTL_DQSNRES 0xc
DQS Resistor
PSU_DDR_PHY_DX8SLBDQSCTL_DQSRES 0x4
DATX8 0-8 DQS Control Register
(OFFSET, MASK, VALUE) (0XFD0817DC, 0xFFFFFFFFU ,0x012643C4U)
RegMask = (DDR_PHY_DX8SLBDQSCTL_RESERVED_31_25_MASK | DDR_PHY_DX8SLBDQSCTL_RRRMODE_MASK | DDR_PHY_DX8SLBDQSCTL_RESERVED_23_22_MASK | DDR_PHY_DX8SLBDQSCTL_WRRMODE_MASK | DDR_PHY_DX8SLBDQSCTL_DQSGX_MASK | DDR_PHY_DX8SLBDQSCTL_LPPLLPD_MASK | DDR_PHY_DX8SLBDQSCTL_LPIOPD_MASK | DDR_PHY_DX8SLBDQSCTL_RESERVED_16_15_MASK | DDR_PHY_DX8SLBDQSCTL_QSCNTEN_MASK | DDR_PHY_DX8SLBDQSCTL_UDQIOM_MASK | DDR_PHY_DX8SLBDQSCTL_RESERVED_12_10_MASK | DDR_PHY_DX8SLBDQSCTL_DXSR_MASK | DDR_PHY_DX8SLBDQSCTL_DQSNRES_MASK | DDR_PHY_DX8SLBDQSCTL_DQSRES_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_DX8SLBDQSCTL_RESERVED_31_25_SHIFT
| 0x00000001U << DDR_PHY_DX8SLBDQSCTL_RRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SLBDQSCTL_RESERVED_23_22_SHIFT
| 0x00000001U << DDR_PHY_DX8SLBDQSCTL_WRRMODE_SHIFT
| 0x00000000U << DDR_PHY_DX8SLBDQSCTL_DQSGX_SHIFT
| 0x00000001U << DDR_PHY_DX8SLBDQSCTL_LPPLLPD_SHIFT
| 0x00000001U << DDR_PHY_DX8SLBDQSCTL_LPIOPD_SHIFT
| 0x00000000U << DDR_PHY_DX8SLBDQSCTL_RESERVED_16_15_SHIFT
| 0x00000001U << DDR_PHY_DX8SLBDQSCTL_QSCNTEN_SHIFT
| 0x00000000U << DDR_PHY_DX8SLBDQSCTL_UDQIOM_SHIFT
| 0x00000000U << DDR_PHY_DX8SLBDQSCTL_RESERVED_12_10_SHIFT
| 0x00000003U << DDR_PHY_DX8SLBDQSCTL_DXSR_SHIFT
| 0x0000000CU << DDR_PHY_DX8SLBDQSCTL_DQSNRES_SHIFT
| 0x00000004U << DDR_PHY_DX8SLBDQSCTL_DQSRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_DX8SLBDQSCTL_OFFSET ,0xFFFFFFFFU ,0x012643C4U);
/*############################################################################################################################ */
/*Register : PIR @ 0XFD080004</p>
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PIR_RESERVED_31 0x0
Impedance Calibration Bypass
PSU_DDR_PHY_PIR_ZCALBYP 0x0
Digital Delay Line (DDL) Calibration Pause
PSU_DDR_PHY_PIR_DCALPSE 0x0
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PIR_RESERVED_28_21 0x0
Write DQS2DQ Training
PSU_DDR_PHY_PIR_DQS2DQ 0x0
RDIMM Initialization
PSU_DDR_PHY_PIR_RDIMMINIT 0x0
Controller DRAM Initialization
PSU_DDR_PHY_PIR_CTLDINIT 0x1
VREF Training
PSU_DDR_PHY_PIR_VREF 0x0
Static Read Training
PSU_DDR_PHY_PIR_SRD 0x0
Write Data Eye Training
PSU_DDR_PHY_PIR_WREYE 0x0
Read Data Eye Training
PSU_DDR_PHY_PIR_RDEYE 0x0
Write Data Bit Deskew
PSU_DDR_PHY_PIR_WRDSKW 0x0
Read Data Bit Deskew
PSU_DDR_PHY_PIR_RDDSKW 0x0
Write Leveling Adjust
PSU_DDR_PHY_PIR_WLADJ 0x0
Read DQS Gate Training
PSU_DDR_PHY_PIR_QSGATE 0x0
Write Leveling
PSU_DDR_PHY_PIR_WL 0x0
DRAM Initialization
PSU_DDR_PHY_PIR_DRAMINIT 0x0
DRAM Reset (DDR3/DDR4/LPDDR4 Only)
PSU_DDR_PHY_PIR_DRAMRST 0x0
PHY Reset
PSU_DDR_PHY_PIR_PHYRST 0x1
Digital Delay Line (DDL) Calibration
PSU_DDR_PHY_PIR_DCAL 0x1
PLL Initialiazation
PSU_DDR_PHY_PIR_PLLINIT 0x1
Reserved. Return zeroes on reads.
PSU_DDR_PHY_PIR_RESERVED_3 0x0
CA Training
PSU_DDR_PHY_PIR_CA 0x0
Impedance Calibration
PSU_DDR_PHY_PIR_ZCAL 0x1
Initialization Trigger
PSU_DDR_PHY_PIR_INIT 0x1
PHY Initialization Register
(OFFSET, MASK, VALUE) (0XFD080004, 0xFFFFFFFFU ,0x00040073U)
RegMask = (DDR_PHY_PIR_RESERVED_31_MASK | DDR_PHY_PIR_ZCALBYP_MASK | DDR_PHY_PIR_DCALPSE_MASK | DDR_PHY_PIR_RESERVED_28_21_MASK | DDR_PHY_PIR_DQS2DQ_MASK | DDR_PHY_PIR_RDIMMINIT_MASK | DDR_PHY_PIR_CTLDINIT_MASK | DDR_PHY_PIR_VREF_MASK | DDR_PHY_PIR_SRD_MASK | DDR_PHY_PIR_WREYE_MASK | DDR_PHY_PIR_RDEYE_MASK | DDR_PHY_PIR_WRDSKW_MASK | DDR_PHY_PIR_RDDSKW_MASK | DDR_PHY_PIR_WLADJ_MASK | DDR_PHY_PIR_QSGATE_MASK | DDR_PHY_PIR_WL_MASK | DDR_PHY_PIR_DRAMINIT_MASK | DDR_PHY_PIR_DRAMRST_MASK | DDR_PHY_PIR_PHYRST_MASK | DDR_PHY_PIR_DCAL_MASK | DDR_PHY_PIR_PLLINIT_MASK | DDR_PHY_PIR_RESERVED_3_MASK | DDR_PHY_PIR_CA_MASK | DDR_PHY_PIR_ZCAL_MASK | DDR_PHY_PIR_INIT_MASK | 0 );
RegVal = ((0x00000000U << DDR_PHY_PIR_RESERVED_31_SHIFT
| 0x00000000U << DDR_PHY_PIR_ZCALBYP_SHIFT
| 0x00000000U << DDR_PHY_PIR_DCALPSE_SHIFT
| 0x00000000U << DDR_PHY_PIR_RESERVED_28_21_SHIFT
| 0x00000000U << DDR_PHY_PIR_DQS2DQ_SHIFT
| 0x00000000U << DDR_PHY_PIR_RDIMMINIT_SHIFT
| 0x00000001U << DDR_PHY_PIR_CTLDINIT_SHIFT
| 0x00000000U << DDR_PHY_PIR_VREF_SHIFT
| 0x00000000U << DDR_PHY_PIR_SRD_SHIFT
| 0x00000000U << DDR_PHY_PIR_WREYE_SHIFT
| 0x00000000U << DDR_PHY_PIR_RDEYE_SHIFT
| 0x00000000U << DDR_PHY_PIR_WRDSKW_SHIFT
| 0x00000000U << DDR_PHY_PIR_RDDSKW_SHIFT
| 0x00000000U << DDR_PHY_PIR_WLADJ_SHIFT
| 0x00000000U << DDR_PHY_PIR_QSGATE_SHIFT
| 0x00000000U << DDR_PHY_PIR_WL_SHIFT
| 0x00000000U << DDR_PHY_PIR_DRAMINIT_SHIFT
| 0x00000000U << DDR_PHY_PIR_DRAMRST_SHIFT
| 0x00000001U << DDR_PHY_PIR_PHYRST_SHIFT
| 0x00000001U << DDR_PHY_PIR_DCAL_SHIFT
| 0x00000001U << DDR_PHY_PIR_PLLINIT_SHIFT
| 0x00000000U << DDR_PHY_PIR_RESERVED_3_SHIFT
| 0x00000000U << DDR_PHY_PIR_CA_SHIFT
| 0x00000001U << DDR_PHY_PIR_ZCAL_SHIFT
| 0x00000001U << DDR_PHY_PIR_INIT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DDR_PHY_PIR_OFFSET ,0xFFFFFFFFU ,0x00040073U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_mio_init_data() {
// : MIO PROGRAMMING
/*Register : MIO_PIN_0 @ 0XFF180000</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_sclk_out- (QSPI Clock)
PSU_IOU_SLCR_MIO_PIN_0_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_0_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[0]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[0]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_0_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[0]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[0]- (GPIO bank 0) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, spi0_sclk_out- (SPI Cloc
) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, trace_
lk- (Trace Port Clock)
PSU_IOU_SLCR_MIO_PIN_0_L3_SEL 0
Configures MIO Pin 0 peripheral interface mapping. S
(OFFSET, MASK, VALUE) (0XFF180000, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_0_L0_SEL_MASK | IOU_SLCR_MIO_PIN_0_L1_SEL_MASK | IOU_SLCR_MIO_PIN_0_L2_SEL_MASK | IOU_SLCR_MIO_PIN_0_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_0_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_0_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_0_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_0_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_0_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_1 @ 0XFF180004</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi_mi1- (QSPI Databus) 1= qspi, Output, qspi_so_mo1- (QSPI Data
us)
PSU_IOU_SLCR_MIO_PIN_1_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_1_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[1]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[1]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_1_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[1]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[1]- (GPIO bank 0) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5= ttc3, Output, ttc3_wave_o
t- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= trace, Output, trace_ctl- (Trace Port Control
Signal)
PSU_IOU_SLCR_MIO_PIN_1_L3_SEL 0
Configures MIO Pin 1 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180004, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_1_L0_SEL_MASK | IOU_SLCR_MIO_PIN_1_L1_SEL_MASK | IOU_SLCR_MIO_PIN_1_L2_SEL_MASK | IOU_SLCR_MIO_PIN_1_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_1_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_1_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_1_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_1_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_1_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_2 @ 0XFF180008</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi2- (QSPI Databus) 1= qspi, Output, qspi_mo2- (QSPI Databus)
PSU_IOU_SLCR_MIO_PIN_2_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_2_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[2]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[2]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_2_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[2]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[2]- (GPIO bank 0) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= ttc2, Input, ttc2_clk_in
(TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[0]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_2_L3_SEL 0
Configures MIO Pin 2 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180008, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_2_L0_SEL_MASK | IOU_SLCR_MIO_PIN_2_L1_SEL_MASK | IOU_SLCR_MIO_PIN_2_L2_SEL_MASK | IOU_SLCR_MIO_PIN_2_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_2_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_2_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_2_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_2_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_2_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_3 @ 0XFF18000C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi3- (QSPI Databus) 1= qspi, Output, qspi_mo3- (QSPI Databus)
PSU_IOU_SLCR_MIO_PIN_3_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_3_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[3]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[3]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_3_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[3]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[3]- (GPIO bank 0) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi0, Output, spi0_n_ss_out[0
- (SPI Master Selects) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial
output) 7= trace, Output, tracedq[1]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_3_L3_SEL 0
Configures MIO Pin 3 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18000C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_3_L0_SEL_MASK | IOU_SLCR_MIO_PIN_3_L1_SEL_MASK | IOU_SLCR_MIO_PIN_3_L2_SEL_MASK | IOU_SLCR_MIO_PIN_3_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_3_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_3_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_3_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_3_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_3_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_4 @ 0XFF180010</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_mo_mo0- (QSPI Databus) 1= qspi, Input, qspi_si_mi0- (QSPI Data
us)
PSU_IOU_SLCR_MIO_PIN_4_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_4_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[4]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[4]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_4_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[4]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[4]- (GPIO bank 0) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0_s
- (MISO signal) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace,
utput, tracedq[2]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_4_L3_SEL 0
Configures MIO Pin 4 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180010, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_4_L0_SEL_MASK | IOU_SLCR_MIO_PIN_4_L1_SEL_MASK | IOU_SLCR_MIO_PIN_4_L2_SEL_MASK | IOU_SLCR_MIO_PIN_4_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_4_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_4_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_4_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_4_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_4_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_5 @ 0XFF180014</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_n_ss_out- (QSPI Slave Select)
PSU_IOU_SLCR_MIO_PIN_5_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_5_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[5]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[5]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_5_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[5]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[5]- (GPIO bank 0) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, spi0
si- (MOSI signal) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7
trace, Output, tracedq[3]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_5_L3_SEL 0
Configures MIO Pin 5 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180014, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_5_L0_SEL_MASK | IOU_SLCR_MIO_PIN_5_L1_SEL_MASK | IOU_SLCR_MIO_PIN_5_L2_SEL_MASK | IOU_SLCR_MIO_PIN_5_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_5_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_5_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_5_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_5_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_5_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_6 @ 0XFF180018</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_clk_for_lpbk- (QSPI Clock to be fed-back)
PSU_IOU_SLCR_MIO_PIN_6_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_6_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[6]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[6]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_6_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[6]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[6]- (GPIO bank 0) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, spi1
sclk_out- (SPI Clock) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace,
Output, tracedq[4]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_6_L3_SEL 0
Configures MIO Pin 6 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180018, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_6_L0_SEL_MASK | IOU_SLCR_MIO_PIN_6_L1_SEL_MASK | IOU_SLCR_MIO_PIN_6_L2_SEL_MASK | IOU_SLCR_MIO_PIN_6_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_6_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_6_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_6_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_6_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_6_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_7 @ 0XFF18001C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_n_ss_out_upper- (QSPI Slave Select upper)
PSU_IOU_SLCR_MIO_PIN_7_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_7_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[7]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[7]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_7_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[7]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[7]- (GPIO bank 0) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5=
tc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= trace, Output,
racedq[5]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_7_L3_SEL 0
Configures MIO Pin 7 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18001C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_7_L0_SEL_MASK | IOU_SLCR_MIO_PIN_7_L1_SEL_MASK | IOU_SLCR_MIO_PIN_7_L2_SEL_MASK | IOU_SLCR_MIO_PIN_7_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_7_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_7_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_7_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_7_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_7_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_8 @ 0XFF180020</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi_upper[0]- (QSPI Upper Databus) 1= qspi, Output, qspi_mo_uppe
[0]- (QSPI Upper Databus)
PSU_IOU_SLCR_MIO_PIN_8_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_8_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[8]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[8]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_8_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[8]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[8]- (GPIO bank 0) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= ttc
, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, tracedq[6]- (Tr
ce Port Databus)
PSU_IOU_SLCR_MIO_PIN_8_L3_SEL 0
Configures MIO Pin 8 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180020, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_8_L0_SEL_MASK | IOU_SLCR_MIO_PIN_8_L1_SEL_MASK | IOU_SLCR_MIO_PIN_8_L2_SEL_MASK | IOU_SLCR_MIO_PIN_8_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_8_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_8_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_8_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_8_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_8_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_9 @ 0XFF180024</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi_upper[1]- (QSPI Upper Databus) 1= qspi, Output, qspi_mo_uppe
[1]- (QSPI Upper Databus)
PSU_IOU_SLCR_MIO_PIN_9_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_ce[1]- (NAND chip enable)
PSU_IOU_SLCR_MIO_PIN_9_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[9]- (Test Scan Port) = test_scan, Outp
t, test_scan_out[9]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_9_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[9]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[9]- (GPIO bank 0) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi1,
utput, spi1_n_ss_out[0]- (SPI Master Selects) 5= ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (U
RT receiver serial input) 7= trace, Output, tracedq[7]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_9_L3_SEL 0
Configures MIO Pin 9 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180024, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_9_L0_SEL_MASK | IOU_SLCR_MIO_PIN_9_L1_SEL_MASK | IOU_SLCR_MIO_PIN_9_L2_SEL_MASK | IOU_SLCR_MIO_PIN_9_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_9_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_9_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_9_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_9_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_9_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_10 @ 0XFF180028</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi_upper[2]- (QSPI Upper Databus) 1= qspi, Output, qspi_mo_uppe
[2]- (QSPI Upper Databus)
PSU_IOU_SLCR_MIO_PIN_10_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_rb_n[0]- (NAND Ready/Busy)
PSU_IOU_SLCR_MIO_PIN_10_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[10]- (Test Scan Port) = test_scan, Out
ut, test_scan_out[10]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_10_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[10]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[10]- (GPIO bank 0) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1_
o- (MISO signal) 5= ttc2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Outp
t, tracedq[8]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_10_L3_SEL 0
Configures MIO Pin 10 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180028, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_10_L0_SEL_MASK | IOU_SLCR_MIO_PIN_10_L1_SEL_MASK | IOU_SLCR_MIO_PIN_10_L2_SEL_MASK | IOU_SLCR_MIO_PIN_10_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_10_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_10_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_10_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_10_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_10_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_11 @ 0XFF18002C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Input, qspi_mi_upper[3]- (QSPI Upper Databus) 1= qspi, Output, qspi_mo_uppe
[3]- (QSPI Upper Databus)
PSU_IOU_SLCR_MIO_PIN_11_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_rb_n[1]- (NAND Ready/Busy)
PSU_IOU_SLCR_MIO_PIN_11_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[11]- (Test Scan Port) = test_scan, Out
ut, test_scan_out[11]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_11_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[11]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[11]- (GPIO bank 0) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, s
i1_si- (MOSI signal) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial o
tput) 7= trace, Output, tracedq[9]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_11_L3_SEL 0
Configures MIO Pin 11 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18002C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_11_L0_SEL_MASK | IOU_SLCR_MIO_PIN_11_L1_SEL_MASK | IOU_SLCR_MIO_PIN_11_L2_SEL_MASK | IOU_SLCR_MIO_PIN_11_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_11_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_11_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_11_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_11_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_11_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_12 @ 0XFF180030</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= qspi, Output, qspi_sclk_out_upper- (QSPI Upper Clock)
PSU_IOU_SLCR_MIO_PIN_12_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dqs_in- (NAND Strobe) 1= nand, Output, nfc_dqs_out- (NAND Strobe
PSU_IOU_SLCR_MIO_PIN_12_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= test_scan, Input, test_scan_in[12]- (Test Scan Port) = test_scan, Out
ut, test_scan_out[12]- (Test Scan Port) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_12_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[12]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[12]- (GPIO bank 0) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, spi0_sclk_out- (SPI Cl
ck) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, trac
dq[10]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_12_L3_SEL 0
Configures MIO Pin 12 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180030, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_12_L0_SEL_MASK | IOU_SLCR_MIO_PIN_12_L1_SEL_MASK | IOU_SLCR_MIO_PIN_12_L2_SEL_MASK | IOU_SLCR_MIO_PIN_12_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_12_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_12_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_12_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_12_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_12_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_13 @ 0XFF180034</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_13_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_ce[0]- (NAND chip enable)
PSU_IOU_SLCR_MIO_PIN_13_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[0]- (8-bit Data bus) = sd0, Output, sdio0_data_out[0]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[13]- (Test Scan Port) = test_scan, Output, test_scan_out[13]- (Test Scan Port
3= Not Used
PSU_IOU_SLCR_MIO_PIN_13_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[13]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[13]- (GPIO bank 0) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5= ttc1, Output, ttc1_wave
out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= trace, Output, tracedq[11]- (Trace Port Dat
bus)
PSU_IOU_SLCR_MIO_PIN_13_L3_SEL 0
Configures MIO Pin 13 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180034, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_13_L0_SEL_MASK | IOU_SLCR_MIO_PIN_13_L1_SEL_MASK | IOU_SLCR_MIO_PIN_13_L2_SEL_MASK | IOU_SLCR_MIO_PIN_13_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_13_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_13_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_13_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_13_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_13_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_14 @ 0XFF180038</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_14_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_cle- (NAND Command Latch Enable)
PSU_IOU_SLCR_MIO_PIN_14_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[1]- (8-bit Data bus) = sd0, Output, sdio0_data_out[1]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[14]- (Test Scan Port) = test_scan, Output, test_scan_out[14]- (Test Scan Port
3= Not Used
PSU_IOU_SLCR_MIO_PIN_14_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[14]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[14]- (GPIO bank 0) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= ttc0, Input, ttc0_clk_
n- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[12]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_14_L3_SEL 2
Configures MIO Pin 14 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180038, 0x000000FEU ,0x00000040U)
RegMask = (IOU_SLCR_MIO_PIN_14_L0_SEL_MASK | IOU_SLCR_MIO_PIN_14_L1_SEL_MASK | IOU_SLCR_MIO_PIN_14_L2_SEL_MASK | IOU_SLCR_MIO_PIN_14_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_14_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_14_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_14_L2_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_14_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_14_OFFSET ,0x000000FEU ,0x00000040U);
/*############################################################################################################################ */
/*Register : MIO_PIN_15 @ 0XFF18003C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_15_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_ale- (NAND Address Latch Enable)
PSU_IOU_SLCR_MIO_PIN_15_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[2]- (8-bit Data bus) = sd0, Output, sdio0_data_out[2]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[15]- (Test Scan Port) = test_scan, Output, test_scan_out[15]- (Test Scan Port
3= Not Used
PSU_IOU_SLCR_MIO_PIN_15_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[15]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[15]- (GPIO bank 0) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi0, Output, spi0_n_ss_out
0]- (SPI Master Selects) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter seri
l output) 7= trace, Output, tracedq[13]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_15_L3_SEL 2
Configures MIO Pin 15 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18003C, 0x000000FEU ,0x00000040U)
RegMask = (IOU_SLCR_MIO_PIN_15_L0_SEL_MASK | IOU_SLCR_MIO_PIN_15_L1_SEL_MASK | IOU_SLCR_MIO_PIN_15_L2_SEL_MASK | IOU_SLCR_MIO_PIN_15_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_15_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_15_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_15_L2_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_15_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_15_OFFSET ,0x000000FEU ,0x00000040U);
/*############################################################################################################################ */
/*Register : MIO_PIN_16 @ 0XFF180040</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_16_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[0]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[0]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_16_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[3]- (8-bit Data bus) = sd0, Output, sdio0_data_out[3]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[16]- (Test Scan Port) = test_scan, Output, test_scan_out[16]- (Test Scan Port
3= Not Used
PSU_IOU_SLCR_MIO_PIN_16_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[16]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[16]- (GPIO bank 0) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0
so- (MISO signal) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace
Output, tracedq[14]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_16_L3_SEL 2
Configures MIO Pin 16 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180040, 0x000000FEU ,0x00000040U)
RegMask = (IOU_SLCR_MIO_PIN_16_L0_SEL_MASK | IOU_SLCR_MIO_PIN_16_L1_SEL_MASK | IOU_SLCR_MIO_PIN_16_L2_SEL_MASK | IOU_SLCR_MIO_PIN_16_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_16_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_16_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_16_L2_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_16_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_16_OFFSET ,0x000000FEU ,0x00000040U);
/*############################################################################################################################ */
/*Register : MIO_PIN_17 @ 0XFF180044</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_17_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[1]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[1]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_17_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[4]- (8-bit Data bus) = sd0, Output, sdio0_data_out[4]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[17]- (Test Scan Port) = test_scan, Output, test_scan_out[17]- (Test Scan Port
3= Not Used
PSU_IOU_SLCR_MIO_PIN_17_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[17]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[17]- (GPIO bank 0) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, sp
0_si- (MOSI signal) 5= ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input)
7= trace, Output, tracedq[15]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_17_L3_SEL 2
Configures MIO Pin 17 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180044, 0x000000FEU ,0x00000040U)
RegMask = (IOU_SLCR_MIO_PIN_17_L0_SEL_MASK | IOU_SLCR_MIO_PIN_17_L1_SEL_MASK | IOU_SLCR_MIO_PIN_17_L2_SEL_MASK | IOU_SLCR_MIO_PIN_17_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_17_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_17_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_17_L2_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_17_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_17_OFFSET ,0x000000FEU ,0x00000040U);
/*############################################################################################################################ */
/*Register : MIO_PIN_18 @ 0XFF180048</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_18_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[2]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[2]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_18_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[5]- (8-bit Data bus) = sd0, Output, sdio0_data_out[5]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[18]- (Test Scan Port) = test_scan, Output, test_scan_out[18]- (Test Scan Port
3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_18_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[18]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[18]- (GPIO bank 0) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1_
o- (MISO signal) 5= ttc2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_18_L3_SEL 6
Configures MIO Pin 18 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180048, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_18_L0_SEL_MASK | IOU_SLCR_MIO_PIN_18_L1_SEL_MASK | IOU_SLCR_MIO_PIN_18_L2_SEL_MASK | IOU_SLCR_MIO_PIN_18_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_18_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_18_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_18_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_18_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_18_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_PIN_19 @ 0XFF18004C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_19_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[3]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[3]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_19_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[6]- (8-bit Data bus) = sd0, Output, sdio0_data_out[6]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[19]- (Test Scan Port) = test_scan, Output, test_scan_out[19]- (Test Scan Port
3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_19_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[19]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[19]- (GPIO bank 0) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5
ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_19_L3_SEL 6
Configures MIO Pin 19 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18004C, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_19_L0_SEL_MASK | IOU_SLCR_MIO_PIN_19_L1_SEL_MASK | IOU_SLCR_MIO_PIN_19_L2_SEL_MASK | IOU_SLCR_MIO_PIN_19_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_19_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_19_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_19_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_19_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_19_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_PIN_20 @ 0XFF180050</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_20_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[4]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[4]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_20_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[7]- (8-bit Data bus) = sd0, Output, sdio0_data_out[7]- (8
bit Data bus) 2= test_scan, Input, test_scan_in[20]- (Test Scan Port) = test_scan, Output, test_scan_out[20]- (Test Scan Port
3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_20_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[20]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[20]- (GPIO bank 0) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= t
c1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_20_L3_SEL 6
Configures MIO Pin 20 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180050, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_20_L0_SEL_MASK | IOU_SLCR_MIO_PIN_20_L1_SEL_MASK | IOU_SLCR_MIO_PIN_20_L2_SEL_MASK | IOU_SLCR_MIO_PIN_20_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_20_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_20_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_20_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_20_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_20_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_PIN_21 @ 0XFF180054</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_21_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[5]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[5]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_21_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_cmd_in- (Command Indicator) = sd0, Output, sdio0_cmd_out- (Comman
Indicator) 2= test_scan, Input, test_scan_in[21]- (Test Scan Port) = test_scan, Output, test_scan_out[21]- (Test Scan Port)
= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_21_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[21]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[21]- (GPIO bank 0) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi1
Output, spi1_n_ss_out[0]- (SPI Master Selects) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd-
UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_21_L3_SEL 6
Configures MIO Pin 21 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180054, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_21_L0_SEL_MASK | IOU_SLCR_MIO_PIN_21_L1_SEL_MASK | IOU_SLCR_MIO_PIN_21_L2_SEL_MASK | IOU_SLCR_MIO_PIN_21_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_21_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_21_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_21_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_21_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_21_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_PIN_22 @ 0XFF180058</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_22_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_we_b- (NAND Write Enable)
PSU_IOU_SLCR_MIO_PIN_22_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_clk_out- (SDSDIO clock) 2= test_scan, Input, test_scan_in[22]-
(Test Scan Port) = test_scan, Output, test_scan_out[22]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_22_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[22]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[22]- (GPIO bank 0) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, sp
1_sclk_out- (SPI Clock) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not
sed
PSU_IOU_SLCR_MIO_PIN_22_L3_SEL 0
Configures MIO Pin 22 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180058, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_22_L0_SEL_MASK | IOU_SLCR_MIO_PIN_22_L1_SEL_MASK | IOU_SLCR_MIO_PIN_22_L2_SEL_MASK | IOU_SLCR_MIO_PIN_22_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_22_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_22_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_22_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_22_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_22_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_23 @ 0XFF18005C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_23_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[6]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[6]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_23_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_bus_pow- (SD card bus power) 2= test_scan, Input, test_scan_in
23]- (Test Scan Port) = test_scan, Output, test_scan_out[23]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper
PSU_IOU_SLCR_MIO_PIN_23_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[23]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[23]- (GPIO bank 0) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, s
i1_si- (MOSI signal) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial o
tput) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_23_L3_SEL 0
Configures MIO Pin 23 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18005C, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_23_L0_SEL_MASK | IOU_SLCR_MIO_PIN_23_L1_SEL_MASK | IOU_SLCR_MIO_PIN_23_L2_SEL_MASK | IOU_SLCR_MIO_PIN_23_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_23_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_23_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_23_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_23_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_23_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_24 @ 0XFF180060</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_24_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dq_in[7]- (NAND Data Bus) 1= nand, Output, nfc_dq_out[7]- (NAND
ata Bus)
PSU_IOU_SLCR_MIO_PIN_24_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_cd_n- (SD card detect from connector) 2= test_scan, Input, test
scan_in[24]- (Test Scan Port) = test_scan, Output, test_scan_out[24]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ex
Tamper)
PSU_IOU_SLCR_MIO_PIN_24_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[24]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[24]- (GPIO bank 0) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= Not Used 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1,
Output, ua1_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_24_L3_SEL 1
Configures MIO Pin 24 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180060, 0x000000FEU ,0x00000020U)
RegMask = (IOU_SLCR_MIO_PIN_24_L0_SEL_MASK | IOU_SLCR_MIO_PIN_24_L1_SEL_MASK | IOU_SLCR_MIO_PIN_24_L2_SEL_MASK | IOU_SLCR_MIO_PIN_24_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_24_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_24_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_24_L2_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_24_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_24_OFFSET ,0x000000FEU ,0x00000020U);
/*############################################################################################################################ */
/*Register : MIO_PIN_25 @ 0XFF180064</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_25_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_re_n- (NAND Read Enable)
PSU_IOU_SLCR_MIO_PIN_25_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_wp- (SD card write protect from connector) 2= test_scan, Input,
test_scan_in[25]- (Test Scan Port) = test_scan, Output, test_scan_out[25]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (C
U Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_25_L2_SEL 0
Level 3 Mux Select 0= gpio0, Input, gpio_0_pin_in[25]- (GPIO bank 0) 0= gpio0, Output, gpio_0_pin_out[25]- (GPIO bank 0) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= Not Used 5= ttc3, Output, ttc3_wave_out- (TTC Waveform
lock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_25_L3_SEL 1
Configures MIO Pin 25 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180064, 0x000000FEU ,0x00000020U)
RegMask = (IOU_SLCR_MIO_PIN_25_L0_SEL_MASK | IOU_SLCR_MIO_PIN_25_L1_SEL_MASK | IOU_SLCR_MIO_PIN_25_L2_SEL_MASK | IOU_SLCR_MIO_PIN_25_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_25_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_25_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_25_L2_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_25_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_25_OFFSET ,0x000000FEU ,0x00000020U);
/*############################################################################################################################ */
/*Register : MIO_PIN_26 @ 0XFF180068</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_tx_clk- (TX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_26_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Output, nfc_ce[1]- (NAND chip enable)
PSU_IOU_SLCR_MIO_PIN_26_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[0]- (PMU GPI) 2= test_scan, Input, test_scan_in[26]- (Test Sc
n Port) = test_scan, Output, test_scan_out[26]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_26_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[0]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[0]- (GPIO bank 1) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, spi0_sclk_out- (SPI Clock
5= ttc2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[4]-
Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_26_L3_SEL 0
Configures MIO Pin 26 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180068, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_26_L0_SEL_MASK | IOU_SLCR_MIO_PIN_26_L1_SEL_MASK | IOU_SLCR_MIO_PIN_26_L2_SEL_MASK | IOU_SLCR_MIO_PIN_26_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_26_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_26_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_26_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_26_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_26_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_27 @ 0XFF18006C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_txd[0]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_27_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_rb_n[0]- (NAND Ready/Busy)
PSU_IOU_SLCR_MIO_PIN_27_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[1]- (PMU GPI) 2= test_scan, Input, test_scan_in[27]- (Test Sc
n Port) = test_scan, Output, test_scan_out[27]- (Test Scan Port) 3= dpaux, Input, dp_aux_data_in- (Dp Aux Data) = dpaux, Outp
t, dp_aux_data_out- (Dp Aux Data)
PSU_IOU_SLCR_MIO_PIN_27_L2_SEL 3
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[1]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[1]- (GPIO bank 1) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5= ttc2, Output, ttc2_wave_
ut- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= trace, Output, tracedq[5]- (Trace Port
atabus)
PSU_IOU_SLCR_MIO_PIN_27_L3_SEL 0
Configures MIO Pin 27 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18006C, 0x000000FEU ,0x00000018U)
RegMask = (IOU_SLCR_MIO_PIN_27_L0_SEL_MASK | IOU_SLCR_MIO_PIN_27_L1_SEL_MASK | IOU_SLCR_MIO_PIN_27_L2_SEL_MASK | IOU_SLCR_MIO_PIN_27_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_27_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_27_L1_SEL_SHIFT
| 0x00000003U << IOU_SLCR_MIO_PIN_27_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_27_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_27_OFFSET ,0x000000FEU ,0x00000018U);
/*############################################################################################################################ */
/*Register : MIO_PIN_28 @ 0XFF180070</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_txd[1]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_28_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_rb_n[1]- (NAND Ready/Busy)
PSU_IOU_SLCR_MIO_PIN_28_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[2]- (PMU GPI) 2= test_scan, Input, test_scan_in[28]- (Test Sc
n Port) = test_scan, Output, test_scan_out[28]- (Test Scan Port) 3= dpaux, Input, dp_hot_plug_detect- (Dp Aux Hot Plug)
PSU_IOU_SLCR_MIO_PIN_28_L2_SEL 3
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[2]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[2]- (GPIO bank 1) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= ttc1, Input, ttc1_clk_i
- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, tracedq[6]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_28_L3_SEL 0
Configures MIO Pin 28 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180070, 0x000000FEU ,0x00000018U)
RegMask = (IOU_SLCR_MIO_PIN_28_L0_SEL_MASK | IOU_SLCR_MIO_PIN_28_L1_SEL_MASK | IOU_SLCR_MIO_PIN_28_L2_SEL_MASK | IOU_SLCR_MIO_PIN_28_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_28_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_28_L1_SEL_SHIFT
| 0x00000003U << IOU_SLCR_MIO_PIN_28_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_28_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_28_OFFSET ,0x000000FEU ,0x00000018U);
/*############################################################################################################################ */
/*Register : MIO_PIN_29 @ 0XFF180074</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_txd[2]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_29_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_29_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[3]- (PMU GPI) 2= test_scan, Input, test_scan_in[29]- (Test Sc
n Port) = test_scan, Output, test_scan_out[29]- (Test Scan Port) 3= dpaux, Input, dp_aux_data_in- (Dp Aux Data) = dpaux, Outp
t, dp_aux_data_out- (Dp Aux Data)
PSU_IOU_SLCR_MIO_PIN_29_L2_SEL 3
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[3]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[3]- (GPIO bank 1) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi0, Output, spi0_n_ss_out[0]
(SPI Master Selects) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial inpu
) 7= trace, Output, tracedq[7]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_29_L3_SEL 0
Configures MIO Pin 29 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180074, 0x000000FEU ,0x00000018U)
RegMask = (IOU_SLCR_MIO_PIN_29_L0_SEL_MASK | IOU_SLCR_MIO_PIN_29_L1_SEL_MASK | IOU_SLCR_MIO_PIN_29_L2_SEL_MASK | IOU_SLCR_MIO_PIN_29_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_29_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_29_L1_SEL_SHIFT
| 0x00000003U << IOU_SLCR_MIO_PIN_29_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_29_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_29_OFFSET ,0x000000FEU ,0x00000018U);
/*############################################################################################################################ */
/*Register : MIO_PIN_30 @ 0XFF180078</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_txd[3]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_30_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_30_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[4]- (PMU GPI) 2= test_scan, Input, test_scan_in[30]- (Test Sc
n Port) = test_scan, Output, test_scan_out[30]- (Test Scan Port) 3= dpaux, Input, dp_hot_plug_detect- (Dp Aux Hot Plug)
PSU_IOU_SLCR_MIO_PIN_30_L2_SEL 3
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[4]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[4]- (GPIO bank 1) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0_so
(MISO signal) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output
tracedq[8]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_30_L3_SEL 0
Configures MIO Pin 30 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180078, 0x000000FEU ,0x00000018U)
RegMask = (IOU_SLCR_MIO_PIN_30_L0_SEL_MASK | IOU_SLCR_MIO_PIN_30_L1_SEL_MASK | IOU_SLCR_MIO_PIN_30_L2_SEL_MASK | IOU_SLCR_MIO_PIN_30_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_30_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_30_L1_SEL_SHIFT
| 0x00000003U << IOU_SLCR_MIO_PIN_30_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_30_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_30_OFFSET ,0x000000FEU ,0x00000018U);
/*############################################################################################################################ */
/*Register : MIO_PIN_31 @ 0XFF18007C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Output, gem0_rgmii_tx_ctl- (TX RGMII control)
PSU_IOU_SLCR_MIO_PIN_31_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_31_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Input, pmu_gpi[5]- (PMU GPI) 2= test_scan, Input, test_scan_in[31]- (Test Sc
n Port) = test_scan, Output, test_scan_out[31]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_31_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[5]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[5]- (GPIO bank 1) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, spi
_si- (MOSI signal) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial out
ut) 7= trace, Output, tracedq[9]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_31_L3_SEL 0
Configures MIO Pin 31 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18007C, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_31_L0_SEL_MASK | IOU_SLCR_MIO_PIN_31_L1_SEL_MASK | IOU_SLCR_MIO_PIN_31_L2_SEL_MASK | IOU_SLCR_MIO_PIN_31_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_31_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_31_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_31_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_31_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_31_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_32 @ 0XFF180080</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rx_clk- (RX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_32_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= nand, Input, nfc_dqs_in- (NAND Strobe) 1= nand, Output, nfc_dqs_out- (NAND Strobe
PSU_IOU_SLCR_MIO_PIN_32_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[0]- (PMU GPI) 2= test_scan, Input, test_scan_in[32]- (Test S
an Port) = test_scan, Output, test_scan_out[32]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_32_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[6]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[6]- (GPIO bank 1) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, spi
_sclk_out- (SPI Clock) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7=
race, Output, tracedq[10]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_32_L3_SEL 0
Configures MIO Pin 32 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180080, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_32_L0_SEL_MASK | IOU_SLCR_MIO_PIN_32_L1_SEL_MASK | IOU_SLCR_MIO_PIN_32_L2_SEL_MASK | IOU_SLCR_MIO_PIN_32_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_32_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_32_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_32_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_32_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_32_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_33 @ 0XFF180084</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rxd[0]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_33_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_33_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[1]- (PMU GPI) 2= test_scan, Input, test_scan_in[33]- (Test S
an Port) = test_scan, Output, test_scan_out[33]- (Test Scan Port) 3= csu, Input, csu_ext_tamper- (CSU Ext Tamper)
PSU_IOU_SLCR_MIO_PIN_33_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[7]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[7]- (GPIO bank 1) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5= t
c3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= trace, Output, traced
[11]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_33_L3_SEL 0
Configures MIO Pin 33 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180084, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_33_L0_SEL_MASK | IOU_SLCR_MIO_PIN_33_L1_SEL_MASK | IOU_SLCR_MIO_PIN_33_L2_SEL_MASK | IOU_SLCR_MIO_PIN_33_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_33_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_33_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_33_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_33_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_33_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_34 @ 0XFF180088</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rxd[1]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_34_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_34_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[2]- (PMU GPI) 2= test_scan, Input, test_scan_in[34]- (Test S
an Port) = test_scan, Output, test_scan_out[34]- (Test Scan Port) 3= dpaux, Input, dp_aux_data_in- (Dp Aux Data) = dpaux, Out
ut, dp_aux_data_out- (Dp Aux Data)
PSU_IOU_SLCR_MIO_PIN_34_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[8]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[8]- (GPIO bank 1) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= ttc2
Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[12]- (Trace P
rt Databus)
PSU_IOU_SLCR_MIO_PIN_34_L3_SEL 0
Configures MIO Pin 34 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180088, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_34_L0_SEL_MASK | IOU_SLCR_MIO_PIN_34_L1_SEL_MASK | IOU_SLCR_MIO_PIN_34_L2_SEL_MASK | IOU_SLCR_MIO_PIN_34_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_34_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_34_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_34_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_34_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_34_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_35 @ 0XFF18008C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rxd[2]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_35_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_35_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[3]- (PMU GPI) 2= test_scan, Input, test_scan_in[35]- (Test S
an Port) = test_scan, Output, test_scan_out[35]- (Test Scan Port) 3= dpaux, Input, dp_hot_plug_detect- (Dp Aux Hot Plug)
PSU_IOU_SLCR_MIO_PIN_35_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[9]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[9]- (GPIO bank 1) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi1,
Output, spi1_n_ss_out[0]- (SPI Master Selects) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd-
UART transmitter serial output) 7= trace, Output, tracedq[13]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_35_L3_SEL 0
Configures MIO Pin 35 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18008C, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_35_L0_SEL_MASK | IOU_SLCR_MIO_PIN_35_L1_SEL_MASK | IOU_SLCR_MIO_PIN_35_L2_SEL_MASK | IOU_SLCR_MIO_PIN_35_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_35_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_35_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_35_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_35_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_35_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_36 @ 0XFF180090</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rxd[3]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_36_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_36_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[4]- (PMU GPI) 2= test_scan, Input, test_scan_in[36]- (Test S
an Port) = test_scan, Output, test_scan_out[36]- (Test Scan Port) 3= dpaux, Input, dp_aux_data_in- (Dp Aux Data) = dpaux, Out
ut, dp_aux_data_out- (Dp Aux Data)
PSU_IOU_SLCR_MIO_PIN_36_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[10]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[10]- (GPIO bank 1) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1
so- (MISO signal) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace
Output, tracedq[14]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_36_L3_SEL 0
Configures MIO Pin 36 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180090, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_36_L0_SEL_MASK | IOU_SLCR_MIO_PIN_36_L1_SEL_MASK | IOU_SLCR_MIO_PIN_36_L2_SEL_MASK | IOU_SLCR_MIO_PIN_36_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_36_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_36_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_36_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_36_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_36_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_37 @ 0XFF180094</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem0, Input, gem0_rgmii_rx_ctl- (RX RGMII control )
PSU_IOU_SLCR_MIO_PIN_37_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= pcie, Input, pcie_reset_n- (PCIE Reset signal)
PSU_IOU_SLCR_MIO_PIN_37_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= pmu, Output, pmu_gpo[5]- (PMU GPI) 2= test_scan, Input, test_scan_in[37]- (Test S
an Port) = test_scan, Output, test_scan_out[37]- (Test Scan Port) 3= dpaux, Input, dp_hot_plug_detect- (Dp Aux Hot Plug)
PSU_IOU_SLCR_MIO_PIN_37_L2_SEL 1
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[11]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[11]- (GPIO bank 1) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, sp
1_si- (MOSI signal) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input)
7= trace, Output, tracedq[15]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_37_L3_SEL 0
Configures MIO Pin 37 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180094, 0x000000FEU ,0x00000008U)
RegMask = (IOU_SLCR_MIO_PIN_37_L0_SEL_MASK | IOU_SLCR_MIO_PIN_37_L1_SEL_MASK | IOU_SLCR_MIO_PIN_37_L2_SEL_MASK | IOU_SLCR_MIO_PIN_37_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_37_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_37_L1_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_37_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_37_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_37_OFFSET ,0x000000FEU ,0x00000008U);
/*############################################################################################################################ */
/*Register : MIO_PIN_38 @ 0XFF180098</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_tx_clk- (TX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_38_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_38_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_clk_out- (SDSDIO clock) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_38_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[12]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[12]- (GPIO bank 1) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, spi0_sclk_out- (SPI Clo
k) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, trace_clk-
(Trace Port Clock)
PSU_IOU_SLCR_MIO_PIN_38_L3_SEL 0
Configures MIO Pin 38 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180098, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_38_L0_SEL_MASK | IOU_SLCR_MIO_PIN_38_L1_SEL_MASK | IOU_SLCR_MIO_PIN_38_L2_SEL_MASK | IOU_SLCR_MIO_PIN_38_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_38_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_38_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_38_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_38_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_38_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_39 @ 0XFF18009C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_txd[0]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_39_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_39_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_cd_n- (SD card detect from connector) 2= sd1, Input, sd1_data_i
[4]- (8-bit Data bus) = sd1, Output, sdio1_data_out[4]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_39_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[13]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[13]- (GPIO bank 1) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5= ttc0, Output, ttc0_wav
_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= trace, Output, trace_ctl- (Trace Port
Control Signal)
PSU_IOU_SLCR_MIO_PIN_39_L3_SEL 0
Configures MIO Pin 39 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18009C, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_39_L0_SEL_MASK | IOU_SLCR_MIO_PIN_39_L1_SEL_MASK | IOU_SLCR_MIO_PIN_39_L2_SEL_MASK | IOU_SLCR_MIO_PIN_39_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_39_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_39_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_39_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_39_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_39_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_40 @ 0XFF1800A0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_txd[1]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_40_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_40_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_cmd_in- (Command Indicator) = sd0, Output, sdio0_cmd_out- (Comman
Indicator) 2= sd1, Input, sd1_data_in[5]- (8-bit Data bus) = sd1, Output, sdio1_data_out[5]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_40_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[14]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[14]- (GPIO bank 1) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= ttc3, Input, ttc3_clk
in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, tracedq[0]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_40_L3_SEL 0
Configures MIO Pin 40 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800A0, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_40_L0_SEL_MASK | IOU_SLCR_MIO_PIN_40_L1_SEL_MASK | IOU_SLCR_MIO_PIN_40_L2_SEL_MASK | IOU_SLCR_MIO_PIN_40_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_40_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_40_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_40_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_40_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_40_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_41 @ 0XFF1800A4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_txd[2]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_41_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_41_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[0]- (8-bit Data bus) = sd0, Output, sdio0_data_out[0]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[6]- (8-bit Data bus) = sd1, Output, sdio1_data_out[6]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_41_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[15]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[15]- (GPIO bank 1) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi0, Output, spi0_n_ss_out[
]- (SPI Master Selects) 5= ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial in
ut) 7= trace, Output, tracedq[1]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_41_L3_SEL 0
Configures MIO Pin 41 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800A4, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_41_L0_SEL_MASK | IOU_SLCR_MIO_PIN_41_L1_SEL_MASK | IOU_SLCR_MIO_PIN_41_L2_SEL_MASK | IOU_SLCR_MIO_PIN_41_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_41_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_41_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_41_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_41_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_41_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_42 @ 0XFF1800A8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_txd[3]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_42_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_42_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[1]- (8-bit Data bus) = sd0, Output, sdio0_data_out[1]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[7]- (8-bit Data bus) = sd1, Output, sdio1_data_out[7]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_42_L2_SEL 0
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[16]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[16]- (GPIO bank 1) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0_
o- (MISO signal) 5= ttc2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Outp
t, tracedq[2]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_42_L3_SEL 0
Configures MIO Pin 42 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800A8, 0x000000FEU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_PIN_42_L0_SEL_MASK | IOU_SLCR_MIO_PIN_42_L1_SEL_MASK | IOU_SLCR_MIO_PIN_42_L2_SEL_MASK | IOU_SLCR_MIO_PIN_42_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_42_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_42_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_42_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_42_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_42_OFFSET ,0x000000FEU ,0x00000000U);
/*############################################################################################################################ */
/*Register : MIO_PIN_43 @ 0XFF1800AC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Output, gem1_rgmii_tx_ctl- (TX RGMII control)
PSU_IOU_SLCR_MIO_PIN_43_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_43_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[2]- (8-bit Data bus) = sd0, Output, sdio0_data_out[2]- (8
bit Data bus) 2= sd1, Output, sdio1_bus_pow- (SD card bus power) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_43_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[17]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[17]- (GPIO bank 1) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, s
i0_si- (MOSI signal) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial o
tput) 7= trace, Output, tracedq[3]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_43_L3_SEL 0
Configures MIO Pin 43 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800AC, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_43_L0_SEL_MASK | IOU_SLCR_MIO_PIN_43_L1_SEL_MASK | IOU_SLCR_MIO_PIN_43_L2_SEL_MASK | IOU_SLCR_MIO_PIN_43_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_43_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_43_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_43_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_43_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_43_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_44 @ 0XFF1800B0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rx_clk- (RX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_44_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_44_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[3]- (8-bit Data bus) = sd0, Output, sdio0_data_out[3]- (8
bit Data bus) 2= sd1, Input, sdio1_wp- (SD card write protect from connector) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_44_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[18]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[18]- (GPIO bank 1) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, s
i1_sclk_out- (SPI Clock) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7
Not Used
PSU_IOU_SLCR_MIO_PIN_44_L3_SEL 0
Configures MIO Pin 44 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800B0, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_44_L0_SEL_MASK | IOU_SLCR_MIO_PIN_44_L1_SEL_MASK | IOU_SLCR_MIO_PIN_44_L2_SEL_MASK | IOU_SLCR_MIO_PIN_44_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_44_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_44_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_44_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_44_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_44_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_45 @ 0XFF1800B4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rxd[0]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_45_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_45_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[4]- (8-bit Data bus) = sd0, Output, sdio0_data_out[4]- (8
bit Data bus) 2= sd1, Input, sdio1_cd_n- (SD card detect from connector) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_45_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[19]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[19]- (GPIO bank 1) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5=
ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_45_L3_SEL 0
Configures MIO Pin 45 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800B4, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_45_L0_SEL_MASK | IOU_SLCR_MIO_PIN_45_L1_SEL_MASK | IOU_SLCR_MIO_PIN_45_L2_SEL_MASK | IOU_SLCR_MIO_PIN_45_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_45_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_45_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_45_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_45_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_45_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_46 @ 0XFF1800B8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rxd[1]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_46_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_46_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[5]- (8-bit Data bus) = sd0, Output, sdio0_data_out[5]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[0]- (8-bit Data bus) = sd1, Output, sdio1_data_out[0]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_46_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[20]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[20]- (GPIO bank 1) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= tt
0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_46_L3_SEL 0
Configures MIO Pin 46 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800B8, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_46_L0_SEL_MASK | IOU_SLCR_MIO_PIN_46_L1_SEL_MASK | IOU_SLCR_MIO_PIN_46_L2_SEL_MASK | IOU_SLCR_MIO_PIN_46_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_46_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_46_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_46_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_46_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_46_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_47 @ 0XFF1800BC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rxd[2]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_47_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_47_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[6]- (8-bit Data bus) = sd0, Output, sdio0_data_out[6]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[1]- (8-bit Data bus) = sd1, Output, sdio1_data_out[1]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_47_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[21]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[21]- (GPIO bank 1) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi
, Output, spi1_n_ss_out[0]- (SPI Master Selects) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd
(UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_47_L3_SEL 0
Configures MIO Pin 47 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800BC, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_47_L0_SEL_MASK | IOU_SLCR_MIO_PIN_47_L1_SEL_MASK | IOU_SLCR_MIO_PIN_47_L2_SEL_MASK | IOU_SLCR_MIO_PIN_47_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_47_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_47_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_47_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_47_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_47_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_48 @ 0XFF1800C0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rxd[3]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_48_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_48_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[7]- (8-bit Data bus) = sd0, Output, sdio0_data_out[7]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[2]- (8-bit Data bus) = sd1, Output, sdio1_data_out[2]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_48_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[22]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[22]- (GPIO bank 1) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1
so- (MISO signal) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= Not U
ed
PSU_IOU_SLCR_MIO_PIN_48_L3_SEL 0
Configures MIO Pin 48 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800C0, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_48_L0_SEL_MASK | IOU_SLCR_MIO_PIN_48_L1_SEL_MASK | IOU_SLCR_MIO_PIN_48_L2_SEL_MASK | IOU_SLCR_MIO_PIN_48_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_48_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_48_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_48_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_48_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_48_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_49 @ 0XFF1800C4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem1, Input, gem1_rgmii_rx_ctl- (RX RGMII control )
PSU_IOU_SLCR_MIO_PIN_49_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_49_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_bus_pow- (SD card bus power) 2= sd1, Input, sd1_data_in[3]- (8
bit Data bus) = sd1, Output, sdio1_data_out[3]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_49_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[23]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[23]- (GPIO bank 1) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, sp
1_si- (MOSI signal) 5= ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input)
7= Not Used
PSU_IOU_SLCR_MIO_PIN_49_L3_SEL 0
Configures MIO Pin 49 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800C4, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_49_L0_SEL_MASK | IOU_SLCR_MIO_PIN_49_L1_SEL_MASK | IOU_SLCR_MIO_PIN_49_L2_SEL_MASK | IOU_SLCR_MIO_PIN_49_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_49_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_49_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_49_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_49_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_49_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_50 @ 0XFF1800C8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem_tsu, Input, gem_tsu_clk- (TSU clock)
PSU_IOU_SLCR_MIO_PIN_50_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_50_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_wp- (SD card write protect from connector) 2= sd1, Input, sd1_c
d_in- (Command Indicator) = sd1, Output, sdio1_cmd_out- (Command Indicator) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_50_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[24]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[24]- (GPIO bank 1) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= mdio1, Output, gem1_mdc- (MDIO Clock) 5= ttc2, Input, ttc2
clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_50_L3_SEL 0
Configures MIO Pin 50 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800C8, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_50_L0_SEL_MASK | IOU_SLCR_MIO_PIN_50_L1_SEL_MASK | IOU_SLCR_MIO_PIN_50_L2_SEL_MASK | IOU_SLCR_MIO_PIN_50_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_50_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_50_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_50_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_50_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_50_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_51 @ 0XFF1800CC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem_tsu, Input, gem_tsu_clk- (TSU clock)
PSU_IOU_SLCR_MIO_PIN_51_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_51_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= sd1, Output, sdio1_clk_out- (SDSDIO clock) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_51_L2_SEL 2
Level 3 Mux Select 0= gpio1, Input, gpio_1_pin_in[25]- (GPIO bank 1) 0= gpio1, Output, gpio_1_pin_out[25]- (GPIO bank 1) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= mdio1, Input, gem1_mdio_in- (MDIO Data) 4= mdio1, Outp
t, gem1_mdio_out- (MDIO Data) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter
serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_51_L3_SEL 0
Configures MIO Pin 51 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800CC, 0x000000FEU ,0x00000010U)
RegMask = (IOU_SLCR_MIO_PIN_51_L0_SEL_MASK | IOU_SLCR_MIO_PIN_51_L1_SEL_MASK | IOU_SLCR_MIO_PIN_51_L2_SEL_MASK | IOU_SLCR_MIO_PIN_51_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_51_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_51_L1_SEL_SHIFT
| 0x00000002U << IOU_SLCR_MIO_PIN_51_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_51_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_51_OFFSET ,0x000000FEU ,0x00000010U);
/*############################################################################################################################ */
/*Register : MIO_PIN_52 @ 0XFF1800D0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_tx_clk- (TX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_52_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_clk_in- (ULPI Clock)
PSU_IOU_SLCR_MIO_PIN_52_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_52_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[0]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[0]- (GPIO bank 2) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, spi0_sclk_out- (SPI Cloc
) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, trace_
lk- (Trace Port Clock)
PSU_IOU_SLCR_MIO_PIN_52_L3_SEL 0
Configures MIO Pin 52 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800D0, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_52_L0_SEL_MASK | IOU_SLCR_MIO_PIN_52_L1_SEL_MASK | IOU_SLCR_MIO_PIN_52_L2_SEL_MASK | IOU_SLCR_MIO_PIN_52_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_52_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_52_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_52_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_52_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_52_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_53 @ 0XFF1800D4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_txd[0]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_53_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_dir- (Data bus direction control)
PSU_IOU_SLCR_MIO_PIN_53_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_53_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[1]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[1]- (GPIO bank 2) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5= ttc1, Output, ttc1_wave_o
t- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= trace, Output, trace_ctl- (Trace Port Control
Signal)
PSU_IOU_SLCR_MIO_PIN_53_L3_SEL 0
Configures MIO Pin 53 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800D4, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_53_L0_SEL_MASK | IOU_SLCR_MIO_PIN_53_L1_SEL_MASK | IOU_SLCR_MIO_PIN_53_L2_SEL_MASK | IOU_SLCR_MIO_PIN_53_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_53_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_53_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_53_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_53_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_53_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_54 @ 0XFF1800D8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_txd[1]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_54_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[2]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[2]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_54_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_54_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[2]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[2]- (GPIO bank 2) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= ttc0, Input, ttc0_clk_in
(TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[0]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_54_L3_SEL 0
Configures MIO Pin 54 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800D8, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_54_L0_SEL_MASK | IOU_SLCR_MIO_PIN_54_L1_SEL_MASK | IOU_SLCR_MIO_PIN_54_L2_SEL_MASK | IOU_SLCR_MIO_PIN_54_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_54_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_54_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_54_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_54_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_54_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_55 @ 0XFF1800DC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_txd[2]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_55_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_nxt- (Data flow control signal from the PHY)
PSU_IOU_SLCR_MIO_PIN_55_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_55_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[3]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[3]- (GPIO bank 2) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi0, Output, spi0_n_ss_out[0
- (SPI Master Selects) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial
output) 7= trace, Output, tracedq[1]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_55_L3_SEL 0
Configures MIO Pin 55 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800DC, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_55_L0_SEL_MASK | IOU_SLCR_MIO_PIN_55_L1_SEL_MASK | IOU_SLCR_MIO_PIN_55_L2_SEL_MASK | IOU_SLCR_MIO_PIN_55_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_55_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_55_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_55_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_55_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_55_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_56 @ 0XFF1800E0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_txd[3]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_56_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[0]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[0]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_56_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_56_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[4]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[4]- (GPIO bank 2) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0_s
- (MISO signal) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace,
utput, tracedq[2]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_56_L3_SEL 0
Configures MIO Pin 56 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800E0, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_56_L0_SEL_MASK | IOU_SLCR_MIO_PIN_56_L1_SEL_MASK | IOU_SLCR_MIO_PIN_56_L2_SEL_MASK | IOU_SLCR_MIO_PIN_56_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_56_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_56_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_56_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_56_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_56_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_57 @ 0XFF1800E4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Output, gem2_rgmii_tx_ctl- (TX RGMII control)
PSU_IOU_SLCR_MIO_PIN_57_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[1]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[1]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_57_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_57_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[5]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[5]- (GPIO bank 2) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, spi0
si- (MOSI signal) 5= ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7
trace, Output, tracedq[3]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_57_L3_SEL 0
Configures MIO Pin 57 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800E4, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_57_L0_SEL_MASK | IOU_SLCR_MIO_PIN_57_L1_SEL_MASK | IOU_SLCR_MIO_PIN_57_L2_SEL_MASK | IOU_SLCR_MIO_PIN_57_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_57_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_57_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_57_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_57_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_57_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_58 @ 0XFF1800E8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rx_clk- (RX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_58_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Output, usb0_ulpi_stp- (Asserted to end or interrupt transfers)
PSU_IOU_SLCR_MIO_PIN_58_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_58_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[6]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[6]- (GPIO bank 2) 1= can
, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL signal
3= pjtag, Input, pjtag_tck- (PJTAG TCK) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, spi1_sclk_out- (SPI Clock
5= ttc2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[4]-
Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_58_L3_SEL 0
Configures MIO Pin 58 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800E8, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_58_L0_SEL_MASK | IOU_SLCR_MIO_PIN_58_L1_SEL_MASK | IOU_SLCR_MIO_PIN_58_L2_SEL_MASK | IOU_SLCR_MIO_PIN_58_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_58_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_58_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_58_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_58_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_58_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_59 @ 0XFF1800EC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rxd[0]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_59_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[3]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[3]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_59_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_59_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[7]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[7]- (GPIO bank 2) 1= can
, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA signa
) 3= pjtag, Input, pjtag_tdi- (PJTAG TDI) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5= ttc2, Output, ttc2_wave_
ut- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= trace, Output, tracedq[5]- (Trace Port
atabus)
PSU_IOU_SLCR_MIO_PIN_59_L3_SEL 0
Configures MIO Pin 59 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800EC, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_59_L0_SEL_MASK | IOU_SLCR_MIO_PIN_59_L1_SEL_MASK | IOU_SLCR_MIO_PIN_59_L2_SEL_MASK | IOU_SLCR_MIO_PIN_59_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_59_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_59_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_59_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_59_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_59_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_60 @ 0XFF1800F0</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rxd[1]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_60_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[4]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[4]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_60_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_60_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[8]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[8]- (GPIO bank 2) 1= can
, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL signa
) 3= pjtag, Output, pjtag_tdo- (PJTAG TDO) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= ttc1, Input, ttc1_clk_i
- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace, Output, tracedq[6]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_60_L3_SEL 0
Configures MIO Pin 60 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800F0, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_60_L0_SEL_MASK | IOU_SLCR_MIO_PIN_60_L1_SEL_MASK | IOU_SLCR_MIO_PIN_60_L2_SEL_MASK | IOU_SLCR_MIO_PIN_60_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_60_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_60_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_60_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_60_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_60_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_61 @ 0XFF1800F4</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rxd[2]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_61_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[5]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[5]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_61_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_61_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[9]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[9]- (GPIO bank 2) 1= can
, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA signal
3= pjtag, Input, pjtag_tms- (PJTAG TMS) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi1, Output, spi1_n_ss_out[0]
(SPI Master Selects) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial inpu
) 7= trace, Output, tracedq[7]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_61_L3_SEL 0
Configures MIO Pin 61 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800F4, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_61_L0_SEL_MASK | IOU_SLCR_MIO_PIN_61_L1_SEL_MASK | IOU_SLCR_MIO_PIN_61_L2_SEL_MASK | IOU_SLCR_MIO_PIN_61_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_61_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_61_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_61_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_61_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_61_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_62 @ 0XFF1800F8</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rxd[3]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_62_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[6]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[6]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_62_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_62_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[10]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[10]- (GPIO bank 2) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1_
o- (MISO signal) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Outp
t, tracedq[8]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_62_L3_SEL 0
Configures MIO Pin 62 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800F8, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_62_L0_SEL_MASK | IOU_SLCR_MIO_PIN_62_L1_SEL_MASK | IOU_SLCR_MIO_PIN_62_L2_SEL_MASK | IOU_SLCR_MIO_PIN_62_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_62_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_62_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_62_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_62_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_62_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_63 @ 0XFF1800FC</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem2, Input, gem2_rgmii_rx_ctl- (RX RGMII control )
PSU_IOU_SLCR_MIO_PIN_63_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= usb0, Input, usb0_ulpi_rx_data[7]- (ULPI data bus) 1= usb0, Output, usb0_ulpi_tx_
ata[7]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_63_L1_SEL 1
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_63_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[11]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[11]- (GPIO bank 2) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, s
i1_si- (MOSI signal) 5= ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial o
tput) 7= trace, Output, tracedq[9]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_63_L3_SEL 0
Configures MIO Pin 63 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF1800FC, 0x000000FEU ,0x00000004U)
RegMask = (IOU_SLCR_MIO_PIN_63_L0_SEL_MASK | IOU_SLCR_MIO_PIN_63_L1_SEL_MASK | IOU_SLCR_MIO_PIN_63_L2_SEL_MASK | IOU_SLCR_MIO_PIN_63_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_63_L0_SEL_SHIFT
| 0x00000001U << IOU_SLCR_MIO_PIN_63_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_63_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_63_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_63_OFFSET ,0x000000FEU ,0x00000004U);
/*############################################################################################################################ */
/*Register : MIO_PIN_64 @ 0XFF180100</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_tx_clk- (TX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_64_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_clk_in- (ULPI Clock)
PSU_IOU_SLCR_MIO_PIN_64_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_clk_out- (SDSDIO clock) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_64_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[12]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[12]- (GPIO bank 2) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_sclk_in- (SPI Clock) 4= spi0, Output, s
i0_sclk_out- (SPI Clock) 5= ttc3, Input, ttc3_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7
trace, Output, tracedq[10]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_64_L3_SEL 0
Configures MIO Pin 64 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180100, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_64_L0_SEL_MASK | IOU_SLCR_MIO_PIN_64_L1_SEL_MASK | IOU_SLCR_MIO_PIN_64_L2_SEL_MASK | IOU_SLCR_MIO_PIN_64_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_64_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_64_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_64_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_64_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_64_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_65 @ 0XFF180104</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_txd[0]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_65_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_dir- (Data bus direction control)
PSU_IOU_SLCR_MIO_PIN_65_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_cd_n- (SD card detect from connector) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_65_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[13]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[13]- (GPIO bank 2) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_n_ss_out[2]- (SPI Master Selects) 5=
ttc3, Output, ttc3_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= trace, Output, trac
dq[11]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_65_L3_SEL 0
Configures MIO Pin 65 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180104, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_65_L0_SEL_MASK | IOU_SLCR_MIO_PIN_65_L1_SEL_MASK | IOU_SLCR_MIO_PIN_65_L2_SEL_MASK | IOU_SLCR_MIO_PIN_65_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_65_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_65_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_65_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_65_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_65_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_66 @ 0XFF180108</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_txd[1]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_66_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[2]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[2]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_66_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_cmd_in- (Command Indicator) = sd0, Output, sdio0_cmd_out- (Comman
Indicator) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_66_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[14]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[14]- (GPIO bank 2) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi0, Output, spi0_n_ss_out[1]- (SPI Master Selects) 5= tt
2, Input, ttc2_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= trace, Output, tracedq[12]- (Trace
Port Databus)
PSU_IOU_SLCR_MIO_PIN_66_L3_SEL 0
Configures MIO Pin 66 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180108, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_66_L0_SEL_MASK | IOU_SLCR_MIO_PIN_66_L1_SEL_MASK | IOU_SLCR_MIO_PIN_66_L2_SEL_MASK | IOU_SLCR_MIO_PIN_66_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_66_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_66_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_66_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_66_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_66_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_67 @ 0XFF18010C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_txd[2]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_67_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_nxt- (Data flow control signal from the PHY)
PSU_IOU_SLCR_MIO_PIN_67_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[0]- (8-bit Data bus) = sd0, Output, sdio0_data_out[0]- (8
bit Data bus) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_67_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[15]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[15]- (GPIO bank 2) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi0, Input, spi0_n_ss_in- (SPI Master Selects) 4= spi
, Output, spi0_n_ss_out[0]- (SPI Master Selects) 5= ttc2, Output, ttc2_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd
(UART transmitter serial output) 7= trace, Output, tracedq[13]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_67_L3_SEL 0
Configures MIO Pin 67 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18010C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_67_L0_SEL_MASK | IOU_SLCR_MIO_PIN_67_L1_SEL_MASK | IOU_SLCR_MIO_PIN_67_L2_SEL_MASK | IOU_SLCR_MIO_PIN_67_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_67_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_67_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_67_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_67_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_67_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_68 @ 0XFF180110</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_txd[3]- (TX RGMII data)
PSU_IOU_SLCR_MIO_PIN_68_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[0]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[0]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_68_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[1]- (8-bit Data bus) = sd0, Output, sdio0_data_out[1]- (8
bit Data bus) 2= Not Used 3= Not Used
PSU_IOU_SLCR_MIO_PIN_68_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[16]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[16]- (GPIO bank 2) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi0, Input, spi0_mi- (MISO signal) 4= spi0, Output, spi0
so- (MISO signal) 5= ttc1, Input, ttc1_clk_in- (TTC Clock) 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= trace
Output, tracedq[14]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_68_L3_SEL 0
Configures MIO Pin 68 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180110, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_68_L0_SEL_MASK | IOU_SLCR_MIO_PIN_68_L1_SEL_MASK | IOU_SLCR_MIO_PIN_68_L2_SEL_MASK | IOU_SLCR_MIO_PIN_68_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_68_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_68_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_68_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_68_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_68_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_69 @ 0XFF180114</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Output, gem3_rgmii_tx_ctl- (TX RGMII control)
PSU_IOU_SLCR_MIO_PIN_69_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[1]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[1]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_69_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[2]- (8-bit Data bus) = sd0, Output, sdio0_data_out[2]- (8
bit Data bus) 2= sd1, Input, sdio1_wp- (SD card write protect from connector) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_69_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[17]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[17]- (GPIO bank 2) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi0, Output, spi0_mo- (MOSI signal) 4= spi0, Input, sp
0_si- (MOSI signal) 5= ttc1, Output, ttc1_wave_out- (TTC Waveform Clock) 6= ua1, Input, ua1_rxd- (UART receiver serial input)
7= trace, Output, tracedq[15]- (Trace Port Databus)
PSU_IOU_SLCR_MIO_PIN_69_L3_SEL 0
Configures MIO Pin 69 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180114, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_69_L0_SEL_MASK | IOU_SLCR_MIO_PIN_69_L1_SEL_MASK | IOU_SLCR_MIO_PIN_69_L2_SEL_MASK | IOU_SLCR_MIO_PIN_69_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_69_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_69_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_69_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_69_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_69_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_70 @ 0XFF180118</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rx_clk- (RX RGMII clock)
PSU_IOU_SLCR_MIO_PIN_70_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Output, usb1_ulpi_stp- (Asserted to end or interrupt transfers)
PSU_IOU_SLCR_MIO_PIN_70_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[3]- (8-bit Data bus) = sd0, Output, sdio0_data_out[3]- (8
bit Data bus) 2= sd1, Output, sdio1_bus_pow- (SD card bus power) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_70_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[18]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[18]- (GPIO bank 2) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_sclk_in- (SPI Clock) 4= spi1, Output, sp
1_sclk_out- (SPI Clock) 5= ttc0, Input, ttc0_clk_in- (TTC Clock) 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not
sed
PSU_IOU_SLCR_MIO_PIN_70_L3_SEL 0
Configures MIO Pin 70 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180118, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_70_L0_SEL_MASK | IOU_SLCR_MIO_PIN_70_L1_SEL_MASK | IOU_SLCR_MIO_PIN_70_L2_SEL_MASK | IOU_SLCR_MIO_PIN_70_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_70_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_70_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_70_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_70_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_70_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_71 @ 0XFF18011C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rxd[0]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_71_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[3]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[3]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_71_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[4]- (8-bit Data bus) = sd0, Output, sdio0_data_out[4]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[0]- (8-bit Data bus) = sd1, Output, sdio1_data_out[0]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_71_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[19]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[19]- (GPIO bank 2) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_n_ss_out[2]- (SPI Master Selects) 5
ttc0, Output, ttc0_wave_out- (TTC Waveform Clock) 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_71_L3_SEL 0
Configures MIO Pin 71 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18011C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_71_L0_SEL_MASK | IOU_SLCR_MIO_PIN_71_L1_SEL_MASK | IOU_SLCR_MIO_PIN_71_L2_SEL_MASK | IOU_SLCR_MIO_PIN_71_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_71_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_71_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_71_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_71_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_71_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_72 @ 0XFF180120</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rxd[1]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_72_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[4]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[4]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_72_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[5]- (8-bit Data bus) = sd0, Output, sdio0_data_out[5]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[1]- (8-bit Data bus) = sd1, Output, sdio1_data_out[1]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_72_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[20]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[20]- (GPIO bank 2) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= swdt1, Input, swdt1_clk_in- (Watch Dog Timer Input clock) 4= spi1, Output, spi1_n_ss_out[1]- (SPI Master Selects) 5= N
t Used 6= ua1, Output, ua1_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_72_L3_SEL 0
Configures MIO Pin 72 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180120, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_72_L0_SEL_MASK | IOU_SLCR_MIO_PIN_72_L1_SEL_MASK | IOU_SLCR_MIO_PIN_72_L2_SEL_MASK | IOU_SLCR_MIO_PIN_72_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_72_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_72_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_72_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_72_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_72_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_73 @ 0XFF180124</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rxd[2]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_73_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[5]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[5]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_73_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[6]- (8-bit Data bus) = sd0, Output, sdio0_data_out[6]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[2]- (8-bit Data bus) = sd1, Output, sdio1_data_out[2]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_73_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[21]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[21]- (GPIO bank 2) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= swdt1, Output, swdt1_rst_out- (Watch Dog Timer Output clock) 4= spi1, Input, spi1_n_ss_in- (SPI Master Selects) 4= spi1
Output, spi1_n_ss_out[0]- (SPI Master Selects) 5= Not Used 6= ua1, Input, ua1_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_73_L3_SEL 0
Configures MIO Pin 73 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180124, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_73_L0_SEL_MASK | IOU_SLCR_MIO_PIN_73_L1_SEL_MASK | IOU_SLCR_MIO_PIN_73_L2_SEL_MASK | IOU_SLCR_MIO_PIN_73_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_73_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_73_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_73_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_73_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_73_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_74 @ 0XFF180128</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rxd[3]- (RX RGMII data)
PSU_IOU_SLCR_MIO_PIN_74_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[6]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[6]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_74_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sd0_data_in[7]- (8-bit Data bus) = sd0, Output, sdio0_data_out[7]- (8
bit Data bus) 2= sd1, Input, sd1_data_in[3]- (8-bit Data bus) = sd1, Output, sdio1_data_out[3]- (8-bit Data bus) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_74_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[22]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[22]- (GPIO bank 2) 1= c
n0, Input, can0_phy_rx- (Can RX signal) 2= i2c0, Input, i2c0_scl_input- (SCL signal) 2= i2c0, Output, i2c0_scl_out- (SCL sign
l) 3= swdt0, Input, swdt0_clk_in- (Watch Dog Timer Input clock) 4= spi1, Input, spi1_mi- (MISO signal) 4= spi1, Output, spi1_
o- (MISO signal) 5= Not Used 6= ua0, Input, ua0_rxd- (UART receiver serial input) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_74_L3_SEL 0
Configures MIO Pin 74 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180128, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_74_L0_SEL_MASK | IOU_SLCR_MIO_PIN_74_L1_SEL_MASK | IOU_SLCR_MIO_PIN_74_L2_SEL_MASK | IOU_SLCR_MIO_PIN_74_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_74_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_74_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_74_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_74_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_74_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_75 @ 0XFF18012C</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= gem3, Input, gem3_rgmii_rx_ctl- (RX RGMII control )
PSU_IOU_SLCR_MIO_PIN_75_L0_SEL 1
Level 1 Mux Select 0= Level 2 Mux Output 1= usb1, Input, usb1_ulpi_rx_data[7]- (ULPI data bus) 1= usb1, Output, usb1_ulpi_tx_
ata[7]- (ULPI data bus)
PSU_IOU_SLCR_MIO_PIN_75_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Output, sdio0_bus_pow- (SD card bus power) 2= sd1, Input, sd1_cmd_in- (Comma
d Indicator) = sd1, Output, sdio1_cmd_out- (Command Indicator) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_75_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[23]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[23]- (GPIO bank 2) 1= c
n0, Output, can0_phy_tx- (Can TX signal) 2= i2c0, Input, i2c0_sda_input- (SDA signal) 2= i2c0, Output, i2c0_sda_out- (SDA sig
al) 3= swdt0, Output, swdt0_rst_out- (Watch Dog Timer Output clock) 4= spi1, Output, spi1_mo- (MOSI signal) 4= spi1, Input, s
i1_si- (MOSI signal) 5= Not Used 6= ua0, Output, ua0_txd- (UART transmitter serial output) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_75_L3_SEL 0
Configures MIO Pin 75 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF18012C, 0x000000FEU ,0x00000002U)
RegMask = (IOU_SLCR_MIO_PIN_75_L0_SEL_MASK | IOU_SLCR_MIO_PIN_75_L1_SEL_MASK | IOU_SLCR_MIO_PIN_75_L2_SEL_MASK | IOU_SLCR_MIO_PIN_75_L3_SEL_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_MIO_PIN_75_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_75_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_75_L2_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_75_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_75_OFFSET ,0x000000FEU ,0x00000002U);
/*############################################################################################################################ */
/*Register : MIO_PIN_76 @ 0XFF180130</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_76_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_76_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= sd0, Input, sdio0_wp- (SD card write protect from connector) 2= sd1, Output, sdio
_clk_out- (SDSDIO clock) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_76_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[24]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[24]- (GPIO bank 2) 1= c
n1, Output, can1_phy_tx- (Can TX signal) 2= i2c1, Input, i2c1_scl_input- (SCL signal) 2= i2c1, Output, i2c1_scl_out- (SCL sig
al) 3= mdio0, Output, gem0_mdc- (MDIO Clock) 4= mdio1, Output, gem1_mdc- (MDIO Clock) 5= mdio2, Output, gem2_mdc- (MDIO Clock
6= mdio3, Output, gem3_mdc- (MDIO Clock) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_76_L3_SEL 6
Configures MIO Pin 76 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180130, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_76_L0_SEL_MASK | IOU_SLCR_MIO_PIN_76_L1_SEL_MASK | IOU_SLCR_MIO_PIN_76_L2_SEL_MASK | IOU_SLCR_MIO_PIN_76_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_76_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_76_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_76_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_76_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_76_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_PIN_77 @ 0XFF180134</p>
Level 0 Mux Select 0= Level 1 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_77_L0_SEL 0
Level 1 Mux Select 0= Level 2 Mux Output 1= Not Used
PSU_IOU_SLCR_MIO_PIN_77_L1_SEL 0
Level 2 Mux Select 0= Level 3 Mux Output 1= Not Used 2= sd1, Input, sdio1_cd_n- (SD card detect from connector) 3= Not Used
PSU_IOU_SLCR_MIO_PIN_77_L2_SEL 0
Level 3 Mux Select 0= gpio2, Input, gpio_2_pin_in[25]- (GPIO bank 2) 0= gpio2, Output, gpio_2_pin_out[25]- (GPIO bank 2) 1= c
n1, Input, can1_phy_rx- (Can RX signal) 2= i2c1, Input, i2c1_sda_input- (SDA signal) 2= i2c1, Output, i2c1_sda_out- (SDA sign
l) 3= mdio0, Input, gem0_mdio_in- (MDIO Data) 3= mdio0, Output, gem0_mdio_out- (MDIO Data) 4= mdio1, Input, gem1_mdio_in- (MD
O Data) 4= mdio1, Output, gem1_mdio_out- (MDIO Data) 5= mdio2, Input, gem2_mdio_in- (MDIO Data) 5= mdio2, Output, gem2_mdio_o
t- (MDIO Data) 6= mdio3, Input, gem3_mdio_in- (MDIO Data) 6= mdio3, Output, gem3_mdio_out- (MDIO Data) 7= Not Used
PSU_IOU_SLCR_MIO_PIN_77_L3_SEL 6
Configures MIO Pin 77 peripheral interface mapping
(OFFSET, MASK, VALUE) (0XFF180134, 0x000000FEU ,0x000000C0U)
RegMask = (IOU_SLCR_MIO_PIN_77_L0_SEL_MASK | IOU_SLCR_MIO_PIN_77_L1_SEL_MASK | IOU_SLCR_MIO_PIN_77_L2_SEL_MASK | IOU_SLCR_MIO_PIN_77_L3_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_PIN_77_L0_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_77_L1_SEL_SHIFT
| 0x00000000U << IOU_SLCR_MIO_PIN_77_L2_SEL_SHIFT
| 0x00000006U << IOU_SLCR_MIO_PIN_77_L3_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_PIN_77_OFFSET ,0x000000FEU ,0x000000C0U);
/*############################################################################################################################ */
/*Register : MIO_MST_TRI0 @ 0XFF180204</p>
Master Tri-state Enable for pin 0, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_00_TRI 0
Master Tri-state Enable for pin 1, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_01_TRI 0
Master Tri-state Enable for pin 2, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_02_TRI 0
Master Tri-state Enable for pin 3, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_03_TRI 0
Master Tri-state Enable for pin 4, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_04_TRI 0
Master Tri-state Enable for pin 5, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_05_TRI 0
Master Tri-state Enable for pin 6, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_06_TRI 0
Master Tri-state Enable for pin 7, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_07_TRI 0
Master Tri-state Enable for pin 8, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_08_TRI 0
Master Tri-state Enable for pin 9, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_09_TRI 0
Master Tri-state Enable for pin 10, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_10_TRI 0
Master Tri-state Enable for pin 11, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_11_TRI 0
Master Tri-state Enable for pin 12, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_12_TRI 0
Master Tri-state Enable for pin 13, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_13_TRI 0
Master Tri-state Enable for pin 14, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_14_TRI 0
Master Tri-state Enable for pin 15, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_15_TRI 0
Master Tri-state Enable for pin 16, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_16_TRI 0
Master Tri-state Enable for pin 17, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_17_TRI 0
Master Tri-state Enable for pin 18, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_18_TRI 1
Master Tri-state Enable for pin 19, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_19_TRI 0
Master Tri-state Enable for pin 20, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_20_TRI 0
Master Tri-state Enable for pin 21, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_21_TRI 1
Master Tri-state Enable for pin 22, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_22_TRI 0
Master Tri-state Enable for pin 23, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_23_TRI 0
Master Tri-state Enable for pin 24, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_24_TRI 0
Master Tri-state Enable for pin 25, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_25_TRI 1
Master Tri-state Enable for pin 26, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_26_TRI 0
Master Tri-state Enable for pin 27, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_27_TRI 0
Master Tri-state Enable for pin 28, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_28_TRI 1
Master Tri-state Enable for pin 29, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_29_TRI 0
Master Tri-state Enable for pin 30, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_30_TRI 1
Master Tri-state Enable for pin 31, active high
PSU_IOU_SLCR_MIO_MST_TRI0_PIN_31_TRI 0
MIO pin Tri-state Enables, 31:0
(OFFSET, MASK, VALUE) (0XFF180204, 0xFFFFFFFFU ,0x52240000U)
RegMask = (IOU_SLCR_MIO_MST_TRI0_PIN_00_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_01_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_02_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_03_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_04_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_05_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_06_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_07_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_08_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_09_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_10_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_11_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_12_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_13_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_14_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_15_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_16_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_17_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_18_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_19_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_20_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_21_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_22_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_23_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_24_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_25_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_26_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_27_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_28_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_29_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_30_TRI_MASK | IOU_SLCR_MIO_MST_TRI0_PIN_31_TRI_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_00_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_01_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_02_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_03_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_04_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_05_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_06_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_07_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_08_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_09_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_10_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_11_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_12_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_13_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_14_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_15_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_16_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_17_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI0_PIN_18_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_19_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_20_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI0_PIN_21_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_22_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_23_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_24_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI0_PIN_25_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_26_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_27_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI0_PIN_28_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_29_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI0_PIN_30_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI0_PIN_31_TRI_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_MST_TRI0_OFFSET ,0xFFFFFFFFU ,0x52240000U);
/*############################################################################################################################ */
/*Register : MIO_MST_TRI1 @ 0XFF180208</p>
Master Tri-state Enable for pin 32, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_32_TRI 0
Master Tri-state Enable for pin 33, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_33_TRI 0
Master Tri-state Enable for pin 34, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_34_TRI 0
Master Tri-state Enable for pin 35, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_35_TRI 0
Master Tri-state Enable for pin 36, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_36_TRI 0
Master Tri-state Enable for pin 37, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_37_TRI 0
Master Tri-state Enable for pin 38, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_38_TRI 0
Master Tri-state Enable for pin 39, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_39_TRI 0
Master Tri-state Enable for pin 40, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_40_TRI 0
Master Tri-state Enable for pin 41, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_41_TRI 0
Master Tri-state Enable for pin 42, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_42_TRI 0
Master Tri-state Enable for pin 43, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_43_TRI 0
Master Tri-state Enable for pin 44, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_44_TRI 1
Master Tri-state Enable for pin 45, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_45_TRI 1
Master Tri-state Enable for pin 46, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_46_TRI 0
Master Tri-state Enable for pin 47, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_47_TRI 0
Master Tri-state Enable for pin 48, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_48_TRI 0
Master Tri-state Enable for pin 49, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_49_TRI 0
Master Tri-state Enable for pin 50, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_50_TRI 0
Master Tri-state Enable for pin 51, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_51_TRI 0
Master Tri-state Enable for pin 52, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_52_TRI 1
Master Tri-state Enable for pin 53, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_53_TRI 1
Master Tri-state Enable for pin 54, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_54_TRI 0
Master Tri-state Enable for pin 55, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_55_TRI 1
Master Tri-state Enable for pin 56, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_56_TRI 0
Master Tri-state Enable for pin 57, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_57_TRI 0
Master Tri-state Enable for pin 58, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_58_TRI 0
Master Tri-state Enable for pin 59, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_59_TRI 0
Master Tri-state Enable for pin 60, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_60_TRI 0
Master Tri-state Enable for pin 61, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_61_TRI 0
Master Tri-state Enable for pin 62, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_62_TRI 0
Master Tri-state Enable for pin 63, active high
PSU_IOU_SLCR_MIO_MST_TRI1_PIN_63_TRI 0
MIO pin Tri-state Enables, 63:32
(OFFSET, MASK, VALUE) (0XFF180208, 0xFFFFFFFFU ,0x00B03000U)
RegMask = (IOU_SLCR_MIO_MST_TRI1_PIN_32_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_33_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_34_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_35_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_36_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_37_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_38_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_39_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_40_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_41_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_42_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_43_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_44_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_45_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_46_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_47_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_48_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_49_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_50_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_51_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_52_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_53_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_54_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_55_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_56_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_57_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_58_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_59_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_60_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_61_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_62_TRI_MASK | IOU_SLCR_MIO_MST_TRI1_PIN_63_TRI_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_32_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_33_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_34_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_35_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_36_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_37_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_38_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_39_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_40_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_41_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_42_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_43_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI1_PIN_44_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI1_PIN_45_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_46_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_47_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_48_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_49_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_50_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_51_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI1_PIN_52_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI1_PIN_53_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_54_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI1_PIN_55_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_56_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_57_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_58_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_59_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_60_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_61_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_62_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI1_PIN_63_TRI_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_MST_TRI1_OFFSET ,0xFFFFFFFFU ,0x00B03000U);
/*############################################################################################################################ */
/*Register : MIO_MST_TRI2 @ 0XFF18020C</p>
Master Tri-state Enable for pin 64, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_64_TRI 0
Master Tri-state Enable for pin 65, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_65_TRI 0
Master Tri-state Enable for pin 66, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_66_TRI 0
Master Tri-state Enable for pin 67, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_67_TRI 0
Master Tri-state Enable for pin 68, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_68_TRI 0
Master Tri-state Enable for pin 69, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_69_TRI 0
Master Tri-state Enable for pin 70, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_70_TRI 1
Master Tri-state Enable for pin 71, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_71_TRI 1
Master Tri-state Enable for pin 72, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_72_TRI 1
Master Tri-state Enable for pin 73, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_73_TRI 1
Master Tri-state Enable for pin 74, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_74_TRI 1
Master Tri-state Enable for pin 75, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_75_TRI 1
Master Tri-state Enable for pin 76, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_76_TRI 0
Master Tri-state Enable for pin 77, active high
PSU_IOU_SLCR_MIO_MST_TRI2_PIN_77_TRI 0
MIO pin Tri-state Enables, 77:64
(OFFSET, MASK, VALUE) (0XFF18020C, 0x00003FFFU ,0x00000FC0U)
RegMask = (IOU_SLCR_MIO_MST_TRI2_PIN_64_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_65_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_66_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_67_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_68_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_69_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_70_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_71_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_72_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_73_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_74_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_75_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_76_TRI_MASK | IOU_SLCR_MIO_MST_TRI2_PIN_77_TRI_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_64_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_65_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_66_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_67_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_68_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_69_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_70_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_71_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_72_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_73_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_74_TRI_SHIFT
| 0x00000001U << IOU_SLCR_MIO_MST_TRI2_PIN_75_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_76_TRI_SHIFT
| 0x00000000U << IOU_SLCR_MIO_MST_TRI2_PIN_77_TRI_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_MST_TRI2_OFFSET ,0x00003FFFU ,0x00000FC0U);
/*############################################################################################################################ */
/*Register : bank0_ctrl0 @ 0XFF180138</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_25 1
Drive0 control to MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF180138, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_0_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_1_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_2_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_3_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_4_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_5_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_6_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_7_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_8_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_9_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_10_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_11_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_12_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_13_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_14_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_15_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_16_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_17_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_18_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_19_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_20_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_21_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_22_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_23_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_24_MASK | IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL0_DRIVE0_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL0_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank0_ctrl1 @ 0XFF18013C</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_25 1
Drive1 control to MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF18013C, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_0_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_1_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_2_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_3_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_4_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_5_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_6_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_7_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_8_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_9_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_10_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_11_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_12_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_13_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_14_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_15_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_16_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_17_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_18_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_19_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_20_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_21_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_22_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_23_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_24_MASK | IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL1_DRIVE1_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL1_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank0_ctrl3 @ 0XFF180140</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_25 0
Selects either Schmitt or CMOS input for MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF180140, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_0_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_1_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_2_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_3_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_4_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_5_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_6_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_7_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_8_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_9_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_10_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_11_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_12_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_13_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_14_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_15_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_16_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_17_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_18_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_19_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_20_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_21_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_22_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_23_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_24_MASK | IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL3_SCHMITT_CMOS_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL3_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : bank0_ctrl4 @ 0XFF180144</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_25 1
When mio_bank0_pull_enable is set, this selects pull up or pull down for MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF180144, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_0_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_1_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_2_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_3_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_4_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_5_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_6_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_7_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_8_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_9_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_10_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_11_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_12_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_13_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_14_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_15_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_16_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_17_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_18_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_19_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_20_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_21_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_22_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_23_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_24_MASK | IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL4_PULL_HIGH_LOW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL4_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank0_ctrl5 @ 0XFF180148</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_25 1
When set, this enables mio_bank0_pullupdown to selects pull up or pull down for MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF180148, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_0_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_1_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_2_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_3_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_4_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_5_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_6_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_7_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_8_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_9_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_10_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_11_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_12_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_13_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_14_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_15_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_16_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_17_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_18_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_19_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_20_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_21_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_22_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_23_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_24_MASK | IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK0_CTRL5_PULL_ENABLE_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL5_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank0_ctrl6 @ 0XFF18014C</p>
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[0].
PSU_IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_25 0
Slew rate control to MIO Bank 0 - control MIO[25:0]
(OFFSET, MASK, VALUE) (0XFF18014C, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_0_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_1_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_2_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_3_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_4_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_5_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_6_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_7_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_8_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_9_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_10_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_11_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_12_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_13_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_14_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_15_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_16_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_17_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_18_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_19_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_20_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_21_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_22_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_23_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_24_MASK | IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK0_CTRL6_SLOW_FAST_SLEW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK0_CTRL6_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : bank1_ctrl0 @ 0XFF180154</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_25 1
Drive0 control to MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF180154, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_0_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_1_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_2_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_3_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_4_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_5_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_6_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_7_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_8_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_9_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_10_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_11_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_12_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_13_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_14_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_15_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_16_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_17_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_18_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_19_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_20_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_21_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_22_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_23_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_24_MASK | IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL0_DRIVE0_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL0_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank1_ctrl1 @ 0XFF180158</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_25 1
Drive1 control to MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF180158, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_0_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_1_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_2_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_3_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_4_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_5_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_6_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_7_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_8_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_9_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_10_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_11_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_12_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_13_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_14_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_15_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_16_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_17_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_18_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_19_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_20_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_21_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_22_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_23_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_24_MASK | IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL1_DRIVE1_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL1_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank1_ctrl3 @ 0XFF18015C</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_25 0
Selects either Schmitt or CMOS input for MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF18015C, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_0_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_1_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_2_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_3_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_4_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_5_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_6_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_7_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_8_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_9_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_10_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_11_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_12_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_13_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_14_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_15_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_16_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_17_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_18_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_19_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_20_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_21_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_22_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_23_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_24_MASK | IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL3_SCHMITT_CMOS_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL3_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : bank1_ctrl4 @ 0XFF180160</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_25 1
When mio_bank1_pull_enable is set, this selects pull up or pull down for MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF180160, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_0_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_1_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_2_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_3_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_4_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_5_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_6_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_7_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_8_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_9_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_10_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_11_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_12_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_13_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_14_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_15_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_16_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_17_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_18_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_19_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_20_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_21_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_22_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_23_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_24_MASK | IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL4_PULL_HIGH_LOW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL4_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank1_ctrl5 @ 0XFF180164</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_25 1
When set, this enables mio_bank1_pullupdown to selects pull up or pull down for MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF180164, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_0_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_1_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_2_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_3_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_4_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_5_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_6_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_7_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_8_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_9_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_10_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_11_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_12_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_13_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_14_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_15_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_16_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_17_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_18_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_19_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_20_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_21_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_22_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_23_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_24_MASK | IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK1_CTRL5_PULL_ENABLE_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL5_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank1_ctrl6 @ 0XFF180168</p>
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[26].
PSU_IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_25 0
Slew rate control to MIO Bank 1 - control MIO[51:26]
(OFFSET, MASK, VALUE) (0XFF180168, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_0_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_1_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_2_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_3_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_4_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_5_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_6_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_7_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_8_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_9_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_10_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_11_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_12_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_13_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_14_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_15_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_16_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_17_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_18_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_19_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_20_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_21_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_22_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_23_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_24_MASK | IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK1_CTRL6_SLOW_FAST_SLEW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK1_CTRL6_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : bank2_ctrl0 @ 0XFF180170</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_25 1
Drive0 control to MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF180170, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_0_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_1_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_2_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_3_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_4_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_5_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_6_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_7_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_8_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_9_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_10_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_11_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_12_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_13_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_14_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_15_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_16_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_17_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_18_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_19_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_20_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_21_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_22_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_23_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_24_MASK | IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL0_DRIVE0_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL0_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank2_ctrl1 @ 0XFF180174</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_25 1
Drive1 control to MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF180174, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_0_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_1_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_2_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_3_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_4_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_5_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_6_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_7_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_8_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_9_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_10_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_11_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_12_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_13_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_14_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_15_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_16_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_17_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_18_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_19_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_20_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_21_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_22_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_23_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_24_MASK | IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL1_DRIVE1_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL1_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank2_ctrl3 @ 0XFF180178</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_25 0
Selects either Schmitt or CMOS input for MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF180178, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_0_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_1_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_2_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_3_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_4_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_5_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_6_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_7_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_8_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_9_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_10_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_11_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_12_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_13_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_14_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_15_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_16_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_17_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_18_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_19_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_20_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_21_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_22_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_23_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_24_MASK | IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL3_SCHMITT_CMOS_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL3_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : bank2_ctrl4 @ 0XFF18017C</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_25 1
When mio_bank2_pull_enable is set, this selects pull up or pull down for MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF18017C, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_0_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_1_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_2_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_3_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_4_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_5_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_6_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_7_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_8_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_9_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_10_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_11_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_12_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_13_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_14_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_15_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_16_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_17_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_18_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_19_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_20_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_21_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_22_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_23_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_24_MASK | IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL4_PULL_HIGH_LOW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL4_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank2_ctrl5 @ 0XFF180180</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_0 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_1 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_2 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_3 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_4 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_5 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_6 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_7 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_8 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_9 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_10 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_11 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_12 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_13 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_14 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_15 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_16 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_17 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_18 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_19 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_20 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_21 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_22 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_23 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_24 1
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_25 1
When set, this enables mio_bank2_pullupdown to selects pull up or pull down for MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF180180, 0x03FFFFFFU ,0x03FFFFFFU)
RegMask = (IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_0_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_1_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_2_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_3_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_4_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_5_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_6_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_7_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_8_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_9_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_10_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_11_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_12_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_13_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_14_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_15_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_16_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_17_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_18_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_19_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_20_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_21_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_22_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_23_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_24_MASK | IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_25_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_0_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_1_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_2_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_3_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_4_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_5_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_6_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_7_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_8_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_9_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_10_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_11_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_12_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_13_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_14_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_15_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_16_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_17_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_18_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_19_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_20_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_21_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_22_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_23_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_24_SHIFT
| 0x00000001U << IOU_SLCR_BANK2_CTRL5_PULL_ENABLE_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL5_OFFSET ,0x03FFFFFFU ,0x03FFFFFFU);
/*############################################################################################################################ */
/*Register : bank2_ctrl6 @ 0XFF180184</p>
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_0 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_1 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_2 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_3 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_4 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_5 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_6 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_7 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_8 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_9 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_10 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_11 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_12 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_13 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_14 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_15 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_16 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_17 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_18 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_19 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_20 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_21 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_22 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_23 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_24 0
Each bit applies to a single IO. Bit 0 for MIO[52].
PSU_IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_25 0
Slew rate control to MIO Bank 2 - control MIO[77:52]
(OFFSET, MASK, VALUE) (0XFF180184, 0x03FFFFFFU ,0x00000000U)
RegMask = (IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_0_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_1_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_2_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_3_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_4_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_5_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_6_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_7_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_8_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_9_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_10_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_11_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_12_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_13_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_14_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_15_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_16_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_17_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_18_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_19_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_20_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_21_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_22_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_23_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_24_MASK | IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_25_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_0_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_1_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_2_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_3_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_4_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_5_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_6_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_7_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_8_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_9_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_10_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_11_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_12_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_13_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_14_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_15_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_16_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_17_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_18_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_19_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_20_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_21_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_22_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_23_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_24_SHIFT
| 0x00000000U << IOU_SLCR_BANK2_CTRL6_SLOW_FAST_SLEW_N_BIT_25_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_BANK2_CTRL6_OFFSET ,0x03FFFFFFU ,0x00000000U);
/*############################################################################################################################ */
// : LOOPBACK
/*Register : MIO_LOOPBACK @ 0XFF180200</p>
I2C Loopback Control. 0 = Connect I2C inputs according to MIO mapping. 1 = Loop I2C 0 outputs to I2C 1 inputs, and I2C 1 outp
ts to I2C 0 inputs.
PSU_IOU_SLCR_MIO_LOOPBACK_I2C0_LOOP_I2C1 0
CAN Loopback Control. 0 = Connect CAN inputs according to MIO mapping. 1 = Loop CAN 0 Tx to CAN 1 Rx, and CAN 1 Tx to CAN 0 R
.
PSU_IOU_SLCR_MIO_LOOPBACK_CAN0_LOOP_CAN1 0
UART Loopback Control. 0 = Connect UART inputs according to MIO mapping. 1 = Loop UART 0 outputs to UART 1 inputs, and UART 1
outputs to UART 0 inputs. RXD/TXD cross-connected. RTS/CTS cross-connected. DSR, DTR, DCD and RI not used.
PSU_IOU_SLCR_MIO_LOOPBACK_UA0_LOOP_UA1 0
SPI Loopback Control. 0 = Connect SPI inputs according to MIO mapping. 1 = Loop SPI 0 outputs to SPI 1 inputs, and SPI 1 outp
ts to SPI 0 inputs. The other SPI core will appear on the LS Slave Select.
PSU_IOU_SLCR_MIO_LOOPBACK_SPI0_LOOP_SPI1 0
Loopback function within MIO
(OFFSET, MASK, VALUE) (0XFF180200, 0x0000000FU ,0x00000000U)
RegMask = (IOU_SLCR_MIO_LOOPBACK_I2C0_LOOP_I2C1_MASK | IOU_SLCR_MIO_LOOPBACK_CAN0_LOOP_CAN1_MASK | IOU_SLCR_MIO_LOOPBACK_UA0_LOOP_UA1_MASK | IOU_SLCR_MIO_LOOPBACK_SPI0_LOOP_SPI1_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_MIO_LOOPBACK_I2C0_LOOP_I2C1_SHIFT
| 0x00000000U << IOU_SLCR_MIO_LOOPBACK_CAN0_LOOP_CAN1_SHIFT
| 0x00000000U << IOU_SLCR_MIO_LOOPBACK_UA0_LOOP_UA1_SHIFT
| 0x00000000U << IOU_SLCR_MIO_LOOPBACK_SPI0_LOOP_SPI1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_MIO_LOOPBACK_OFFSET ,0x0000000FU ,0x00000000U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_peripherals_init_data() {
// : RESET BLOCKS
// : TIMESTAMP
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_TIMESTAMP_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00100000U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_TIMESTAMP_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_TIMESTAMP_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00100000U ,0x00000000U);
/*############################################################################################################################ */
// : ENET
/*Register : RST_LPD_IOU0 @ 0XFF5E0230</p>
GEM 3 reset
PSU_CRL_APB_RST_LPD_IOU0_GEM3_RESET 0
Software controlled reset for the GEMs
(OFFSET, MASK, VALUE) (0XFF5E0230, 0x00000008U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU0_GEM3_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU0_GEM3_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU0_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
// : QSPI
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_QSPI_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00000001U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_QSPI_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_QSPI_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// : QSPI TAP DELAY
/*Register : IOU_TAPDLY_BYPASS @ 0XFF180390</p>
0: Do not by pass the tap delays on the Rx clock signal of LQSPI 1: Bypass the Tap delay on the Rx clock signal of LQSPI
PSU_IOU_SLCR_IOU_TAPDLY_BYPASS_LQSPI_RX 1
IOU tap delay bypass for the LQSPI and NAND controllers
(OFFSET, MASK, VALUE) (0XFF180390, 0x00000004U ,0x00000004U)
RegMask = (IOU_SLCR_IOU_TAPDLY_BYPASS_LQSPI_RX_MASK | 0 );
RegVal = ((0x00000001U << IOU_SLCR_IOU_TAPDLY_BYPASS_LQSPI_RX_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_IOU_TAPDLY_BYPASS_OFFSET ,0x00000004U ,0x00000004U);
/*############################################################################################################################ */
// : NAND
// : USB
/*Register : RST_LPD_TOP @ 0XFF5E023C</p>
USB 0 reset for control registers
PSU_CRL_APB_RST_LPD_TOP_USB0_APB_RESET 0
USB 0 sleep circuit reset
PSU_CRL_APB_RST_LPD_TOP_USB0_HIBERRESET 0
USB 0 reset
PSU_CRL_APB_RST_LPD_TOP_USB0_CORERESET 0
Software control register for the LPD block.
(OFFSET, MASK, VALUE) (0XFF5E023C, 0x00000540U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_TOP_USB0_APB_RESET_MASK | CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_MASK | CRL_APB_RST_LPD_TOP_USB0_CORERESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_TOP_USB0_APB_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_TOP_USB0_CORERESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_TOP_OFFSET ,0x00000540U ,0x00000000U);
/*############################################################################################################################ */
// : FPD RESET
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
Display Port block level reset (includes DPDMA)
PSU_CRF_APB_RST_FPD_TOP_DP_RESET 0
FPD WDT reset
PSU_CRF_APB_RST_FPD_TOP_SWDT_RESET 0
GDMA block level reset
PSU_CRF_APB_RST_FPD_TOP_GDMA_RESET 0
Pixel Processor (submodule of GPU) block level reset
PSU_CRF_APB_RST_FPD_TOP_GPU_PP0_RESET 0
Pixel Processor (submodule of GPU) block level reset
PSU_CRF_APB_RST_FPD_TOP_GPU_PP1_RESET 0
GPU block level reset
PSU_CRF_APB_RST_FPD_TOP_GPU_RESET 0
GT block level reset
PSU_CRF_APB_RST_FPD_TOP_GT_RESET 0
Sata block level reset
PSU_CRF_APB_RST_FPD_TOP_SATA_RESET 0
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x0001807EU ,0x00000000U)
RegMask = (CRF_APB_RST_FPD_TOP_DP_RESET_MASK | CRF_APB_RST_FPD_TOP_SWDT_RESET_MASK | CRF_APB_RST_FPD_TOP_GDMA_RESET_MASK | CRF_APB_RST_FPD_TOP_GPU_PP0_RESET_MASK | CRF_APB_RST_FPD_TOP_GPU_PP1_RESET_MASK | CRF_APB_RST_FPD_TOP_GPU_RESET_MASK | CRF_APB_RST_FPD_TOP_GT_RESET_MASK | CRF_APB_RST_FPD_TOP_SATA_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_RST_FPD_TOP_DP_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_SWDT_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_GDMA_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_GPU_PP0_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_GPU_PP1_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_GPU_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_GT_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_SATA_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x0001807EU ,0x00000000U);
/*############################################################################################################################ */
// : SD
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_SDIO1_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00000040U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_SDIO1_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_SDIO1_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00000040U ,0x00000000U);
/*############################################################################################################################ */
/*Register : CTRL_REG_SD @ 0XFF180310</p>
SD or eMMC selection on SDIO1 0: SD enabled 1: eMMC enabled
PSU_IOU_SLCR_CTRL_REG_SD_SD1_EMMC_SEL 0
SD eMMC selection
(OFFSET, MASK, VALUE) (0XFF180310, 0x00008000U ,0x00000000U)
RegMask = (IOU_SLCR_CTRL_REG_SD_SD1_EMMC_SEL_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_CTRL_REG_SD_SD1_EMMC_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_CTRL_REG_SD_OFFSET ,0x00008000U ,0x00000000U);
/*############################################################################################################################ */
/*Register : SD_CONFIG_REG2 @ 0XFF180320</p>
Should be set based on the final product usage 00 - Removable SCard Slot 01 - Embedded Slot for One Device 10 - Shared Bus Sl
t 11 - Reserved
PSU_IOU_SLCR_SD_CONFIG_REG2_SD1_SLOTTYPE 0
1.8V Support 1: 1.8V supported 0: 1.8V not supported support
PSU_IOU_SLCR_SD_CONFIG_REG2_SD1_1P8V 0
3.0V Support 1: 3.0V supported 0: 3.0V not supported support
PSU_IOU_SLCR_SD_CONFIG_REG2_SD1_3P0V 0
3.3V Support 1: 3.3V supported 0: 3.3V not supported support
PSU_IOU_SLCR_SD_CONFIG_REG2_SD1_3P3V 1
SD Config Register 2
(OFFSET, MASK, VALUE) (0XFF180320, 0x33800000U ,0x00800000U)
RegMask = (IOU_SLCR_SD_CONFIG_REG2_SD1_SLOTTYPE_MASK | IOU_SLCR_SD_CONFIG_REG2_SD1_1P8V_MASK | IOU_SLCR_SD_CONFIG_REG2_SD1_3P0V_MASK | IOU_SLCR_SD_CONFIG_REG2_SD1_3P3V_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_SD_CONFIG_REG2_SD1_SLOTTYPE_SHIFT
| 0x00000000U << IOU_SLCR_SD_CONFIG_REG2_SD1_1P8V_SHIFT
| 0x00000000U << IOU_SLCR_SD_CONFIG_REG2_SD1_3P0V_SHIFT
| 0x00000001U << IOU_SLCR_SD_CONFIG_REG2_SD1_3P3V_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_SD_CONFIG_REG2_OFFSET ,0x33800000U ,0x00800000U);
/*############################################################################################################################ */
// : SD1 BASE CLOCK
/*Register : SD_CONFIG_REG1 @ 0XFF18031C</p>
Base Clock Frequency for SD Clock. This is the frequency of the xin_clk.
PSU_IOU_SLCR_SD_CONFIG_REG1_SD1_BASECLK 0xc7
SD Config Register 1
(OFFSET, MASK, VALUE) (0XFF18031C, 0x7F800000U ,0x63800000U)
RegMask = (IOU_SLCR_SD_CONFIG_REG1_SD1_BASECLK_MASK | 0 );
RegVal = ((0x000000C7U << IOU_SLCR_SD_CONFIG_REG1_SD1_BASECLK_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_SD_CONFIG_REG1_OFFSET ,0x7F800000U ,0x63800000U);
/*############################################################################################################################ */
// : SD1 RETUNER
/*Register : SD_CONFIG_REG3 @ 0XFF180324</p>
This is the Timer Count for Re-Tuning Timer for Re-Tuning Mode 1 to 3. Setting to 4'b0 disables Re-Tuning Timer. 0h - Get inf
rmation via other source 1h = 1 seconds 2h = 2 seconds 3h = 4 seconds 4h = 8 seconds -- n = 2(n-1) seconds -- Bh = 1024 secon
s Fh - Ch = Reserved
PSU_IOU_SLCR_SD_CONFIG_REG3_SD1_RETUNETMR 0X0
SD Config Register 3
(OFFSET, MASK, VALUE) (0XFF180324, 0x03C00000U ,0x00000000U)
RegMask = (IOU_SLCR_SD_CONFIG_REG3_SD1_RETUNETMR_MASK | 0 );
RegVal = ((0x00000000U << IOU_SLCR_SD_CONFIG_REG3_SD1_RETUNETMR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SLCR_SD_CONFIG_REG3_OFFSET ,0x03C00000U ,0x00000000U);
/*############################################################################################################################ */
// : CAN
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_CAN1_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00000100U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_CAN1_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_CAN1_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00000100U ,0x00000000U);
/*############################################################################################################################ */
// : I2C
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_I2C0_RESET 0
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_I2C1_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00000600U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_I2C0_RESET_MASK | CRL_APB_RST_LPD_IOU2_I2C1_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_I2C0_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_IOU2_I2C1_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00000600U ,0x00000000U);
/*############################################################################################################################ */
// : SWDT
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_SWDT_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00008000U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_SWDT_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_SWDT_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00008000U ,0x00000000U);
/*############################################################################################################################ */
// : SPI
// : TTC
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_TTC0_RESET 0
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_TTC1_RESET 0
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_TTC2_RESET 0
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_TTC3_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00007800U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_TTC0_RESET_MASK | CRL_APB_RST_LPD_IOU2_TTC1_RESET_MASK | CRL_APB_RST_LPD_IOU2_TTC2_RESET_MASK | CRL_APB_RST_LPD_IOU2_TTC3_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_TTC0_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_IOU2_TTC1_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_IOU2_TTC2_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_IOU2_TTC3_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00007800U ,0x00000000U);
/*############################################################################################################################ */
// : UART
/*Register : RST_LPD_IOU2 @ 0XFF5E0238</p>
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_UART0_RESET 0
Block level reset
PSU_CRL_APB_RST_LPD_IOU2_UART1_RESET 0
Software control register for the IOU block. Each bit will cause a singlerperipheral or part of the peripheral to be reset.
(OFFSET, MASK, VALUE) (0XFF5E0238, 0x00000006U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU2_UART0_RESET_MASK | CRL_APB_RST_LPD_IOU2_UART1_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU2_UART0_RESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_IOU2_UART1_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU2_OFFSET ,0x00000006U ,0x00000000U);
/*############################################################################################################################ */
// : TPIU WIDTH
// : TRACE LOCK ACCESS REGISTER
/*Register : LAR @ 0XFE980FB0</p>
A write of 0xC5ACCE55 enables further write access to this device. A write of any value other than 0xC5ACCE55 will have the a
fect of removing write access.
PSU_TPIU_LAR_ACCESS_W 0XC5ACCE55
This is used to enable write access to device registers. External accesses from a debugger (paddrdbg31 = 1) are not subject t
the Lock Registers. A debugger does not have to unlock the component in order to write and modify the registers in the compo
ent.
(OFFSET, MASK, VALUE) (0XFE980FB0, 0xFFFFFFFFU ,0xC5ACCE55U)
RegMask = (TPIU_LAR_ACCESS_W_MASK | 0 );
RegVal = ((0xC5ACCE55U << TPIU_LAR_ACCESS_W_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (TPIU_LAR_OFFSET ,0xFFFFFFFFU ,0xC5ACCE55U);
/*############################################################################################################################ */
// : TRACE CURRENT PORT SIZE
/*Register : Current_port_size @ 0XFE980004</p>
Indicates whether the current port size of the TPIU is 32 bits.
PSU_TPIU_CURRENT_PORT_SIZE_PORT_SIZE_32 1
The Current Port Size Register has the same format as the Supported Port Sizes register but only one bit is set, and all othe
s must be zero. Writing values with more than one bit set or setting a bit that is not indicated as supported is not supporte
and causes unpredictable behavior.On reset this defaults to the smallest possible port size, 1 bit, and so reads as 0x000000
1.Note : Do not modify the value while the Trace Port is still active, or without correctly stopping the formatter (see Forma
ter and Flush Control Register, 0x304). This can result in data not being aligned to the port width. For example, data on an
-bit Trace Port might not be byte aligned.
(OFFSET, MASK, VALUE) (0XFE980004, 0x80000000U ,0x80000000U)
RegMask = (TPIU_CURRENT_PORT_SIZE_PORT_SIZE_32_MASK | 0 );
RegVal = ((0x00000001U << TPIU_CURRENT_PORT_SIZE_PORT_SIZE_32_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (TPIU_CURRENT_PORT_SIZE_OFFSET ,0x80000000U ,0x80000000U);
/*############################################################################################################################ */
// : TRACE LOCK ACCESS REGISTER
/*Register : LAR @ 0XFE980FB0</p>
A write of 0xC5ACCE55 enables further write access to this device. A write of any value other than 0xC5ACCE55 will have the a
fect of removing write access.
PSU_TPIU_LAR_ACCESS_W 0X0
This is used to enable write access to device registers. External accesses from a debugger (paddrdbg31 = 1) are not subject t
the Lock Registers. A debugger does not have to unlock the component in order to write and modify the registers in the compo
ent.
(OFFSET, MASK, VALUE) (0XFE980FB0, 0xFFFFFFFFU ,0x00000000U)
RegMask = (TPIU_LAR_ACCESS_W_MASK | 0 );
RegVal = ((0x00000000U << TPIU_LAR_ACCESS_W_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (TPIU_LAR_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
// : UART BAUD RATE
/*Register : Baud_rate_divider_reg0 @ 0XFF000034</p>
Baud rate divider value: 0 - 3: ignored 4 - 255: Baud rate
PSU_UART0_BAUD_RATE_DIVIDER_REG0_BDIV 0x5
Baud Rate Divider Register
(OFFSET, MASK, VALUE) (0XFF000034, 0x000000FFU ,0x00000005U)
RegMask = (UART0_BAUD_RATE_DIVIDER_REG0_BDIV_MASK | 0 );
RegVal = ((0x00000005U << UART0_BAUD_RATE_DIVIDER_REG0_BDIV_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART0_BAUD_RATE_DIVIDER_REG0_OFFSET ,0x000000FFU ,0x00000005U);
/*############################################################################################################################ */
/*Register : Baud_rate_gen_reg0 @ 0XFF000018</p>
Baud Rate Clock Divisor Value: 0: Disables baud_sample 1: Clock divisor bypass (baud_sample = sel_clk) 2 - 65535: baud_sample
PSU_UART0_BAUD_RATE_GEN_REG0_CD 0x8f
Baud Rate Generator Register.
(OFFSET, MASK, VALUE) (0XFF000018, 0x0000FFFFU ,0x0000008FU)
RegMask = (UART0_BAUD_RATE_GEN_REG0_CD_MASK | 0 );
RegVal = ((0x0000008FU << UART0_BAUD_RATE_GEN_REG0_CD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART0_BAUD_RATE_GEN_REG0_OFFSET ,0x0000FFFFU ,0x0000008FU);
/*############################################################################################################################ */
/*Register : Control_reg0 @ 0XFF000000</p>
Stop transmitter break: 0: no affect 1: stop transmission of the break after a minimum of one character length and transmit a
high level during 12 bit periods. It can be set regardless of the value of STTBRK.
PSU_UART0_CONTROL_REG0_STPBRK 0x0
Start transmitter break: 0: no affect 1: start to transmit a break after the characters currently present in the FIFO and the
transmit shift register have been transmitted. It can only be set if STPBRK (Stop transmitter break) is not high.
PSU_UART0_CONTROL_REG0_STTBRK 0x0
Restart receiver timeout counter: 1: receiver timeout counter is restarted. This bit is self clearing once the restart has co
pleted.
PSU_UART0_CONTROL_REG0_RSTTO 0x0
Transmit disable: 0: enable transmitter 1: disable transmitter
PSU_UART0_CONTROL_REG0_TXDIS 0x0
Transmit enable: 0: disable transmitter 1: enable transmitter, provided the TXDIS field is set to 0.
PSU_UART0_CONTROL_REG0_TXEN 0x1
Receive disable: 0: enable 1: disable, regardless of the value of RXEN
PSU_UART0_CONTROL_REG0_RXDIS 0x0
Receive enable: 0: disable 1: enable When set to one, the receiver logic is enabled, provided the RXDIS field is set to zero.
PSU_UART0_CONTROL_REG0_RXEN 0x1
Software reset for Tx data path: 0: no affect 1: transmitter logic is reset and all pending transmitter data is discarded Thi
bit is self clearing once the reset has completed.
PSU_UART0_CONTROL_REG0_TXRES 0x1
Software reset for Rx data path: 0: no affect 1: receiver logic is reset and all pending receiver data is discarded. This bit
is self clearing once the reset has completed.
PSU_UART0_CONTROL_REG0_RXRES 0x1
UART Control Register
(OFFSET, MASK, VALUE) (0XFF000000, 0x000001FFU ,0x00000017U)
RegMask = (UART0_CONTROL_REG0_STPBRK_MASK | UART0_CONTROL_REG0_STTBRK_MASK | UART0_CONTROL_REG0_RSTTO_MASK | UART0_CONTROL_REG0_TXDIS_MASK | UART0_CONTROL_REG0_TXEN_MASK | UART0_CONTROL_REG0_RXDIS_MASK | UART0_CONTROL_REG0_RXEN_MASK | UART0_CONTROL_REG0_TXRES_MASK | UART0_CONTROL_REG0_RXRES_MASK | 0 );
RegVal = ((0x00000000U << UART0_CONTROL_REG0_STPBRK_SHIFT
| 0x00000000U << UART0_CONTROL_REG0_STTBRK_SHIFT
| 0x00000000U << UART0_CONTROL_REG0_RSTTO_SHIFT
| 0x00000000U << UART0_CONTROL_REG0_TXDIS_SHIFT
| 0x00000001U << UART0_CONTROL_REG0_TXEN_SHIFT
| 0x00000000U << UART0_CONTROL_REG0_RXDIS_SHIFT
| 0x00000001U << UART0_CONTROL_REG0_RXEN_SHIFT
| 0x00000001U << UART0_CONTROL_REG0_TXRES_SHIFT
| 0x00000001U << UART0_CONTROL_REG0_RXRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART0_CONTROL_REG0_OFFSET ,0x000001FFU ,0x00000017U);
/*############################################################################################################################ */
/*Register : mode_reg0 @ 0XFF000004</p>
Channel mode: Defines the mode of operation of the UART. 00: normal 01: automatic echo 10: local loopback 11: remote loopback
PSU_UART0_MODE_REG0_CHMODE 0x0
Number of stop bits: Defines the number of stop bits to detect on receive and to generate on transmit. 00: 1 stop bit 01: 1.5
stop bits 10: 2 stop bits 11: reserved
PSU_UART0_MODE_REG0_NBSTOP 0x0
Parity type select: Defines the expected parity to check on receive and the parity to generate on transmit. 000: even parity
01: odd parity 010: forced to 0 parity (space) 011: forced to 1 parity (mark) 1xx: no parity
PSU_UART0_MODE_REG0_PAR 0x4
Character length select: Defines the number of bits in each character. 11: 6 bits 10: 7 bits 0x: 8 bits
PSU_UART0_MODE_REG0_CHRL 0x0
Clock source select: This field defines whether a pre-scalar of 8 is applied to the baud rate generator input clock. 0: clock
source is uart_ref_clk 1: clock source is uart_ref_clk/8
PSU_UART0_MODE_REG0_CLKS 0x0
UART Mode Register
(OFFSET, MASK, VALUE) (0XFF000004, 0x000003FFU ,0x00000020U)
RegMask = (UART0_MODE_REG0_CHMODE_MASK | UART0_MODE_REG0_NBSTOP_MASK | UART0_MODE_REG0_PAR_MASK | UART0_MODE_REG0_CHRL_MASK | UART0_MODE_REG0_CLKS_MASK | 0 );
RegVal = ((0x00000000U << UART0_MODE_REG0_CHMODE_SHIFT
| 0x00000000U << UART0_MODE_REG0_NBSTOP_SHIFT
| 0x00000004U << UART0_MODE_REG0_PAR_SHIFT
| 0x00000000U << UART0_MODE_REG0_CHRL_SHIFT
| 0x00000000U << UART0_MODE_REG0_CLKS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART0_MODE_REG0_OFFSET ,0x000003FFU ,0x00000020U);
/*############################################################################################################################ */
/*Register : Baud_rate_divider_reg0 @ 0XFF010034</p>
Baud rate divider value: 0 - 3: ignored 4 - 255: Baud rate
PSU_UART1_BAUD_RATE_DIVIDER_REG0_BDIV 0x5
Baud Rate Divider Register
(OFFSET, MASK, VALUE) (0XFF010034, 0x000000FFU ,0x00000005U)
RegMask = (UART1_BAUD_RATE_DIVIDER_REG0_BDIV_MASK | 0 );
RegVal = ((0x00000005U << UART1_BAUD_RATE_DIVIDER_REG0_BDIV_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART1_BAUD_RATE_DIVIDER_REG0_OFFSET ,0x000000FFU ,0x00000005U);
/*############################################################################################################################ */
/*Register : Baud_rate_gen_reg0 @ 0XFF010018</p>
Baud Rate Clock Divisor Value: 0: Disables baud_sample 1: Clock divisor bypass (baud_sample = sel_clk) 2 - 65535: baud_sample
PSU_UART1_BAUD_RATE_GEN_REG0_CD 0x8f
Baud Rate Generator Register.
(OFFSET, MASK, VALUE) (0XFF010018, 0x0000FFFFU ,0x0000008FU)
RegMask = (UART1_BAUD_RATE_GEN_REG0_CD_MASK | 0 );
RegVal = ((0x0000008FU << UART1_BAUD_RATE_GEN_REG0_CD_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART1_BAUD_RATE_GEN_REG0_OFFSET ,0x0000FFFFU ,0x0000008FU);
/*############################################################################################################################ */
/*Register : Control_reg0 @ 0XFF010000</p>
Stop transmitter break: 0: no affect 1: stop transmission of the break after a minimum of one character length and transmit a
high level during 12 bit periods. It can be set regardless of the value of STTBRK.
PSU_UART1_CONTROL_REG0_STPBRK 0x0
Start transmitter break: 0: no affect 1: start to transmit a break after the characters currently present in the FIFO and the
transmit shift register have been transmitted. It can only be set if STPBRK (Stop transmitter break) is not high.
PSU_UART1_CONTROL_REG0_STTBRK 0x0
Restart receiver timeout counter: 1: receiver timeout counter is restarted. This bit is self clearing once the restart has co
pleted.
PSU_UART1_CONTROL_REG0_RSTTO 0x0
Transmit disable: 0: enable transmitter 1: disable transmitter
PSU_UART1_CONTROL_REG0_TXDIS 0x0
Transmit enable: 0: disable transmitter 1: enable transmitter, provided the TXDIS field is set to 0.
PSU_UART1_CONTROL_REG0_TXEN 0x1
Receive disable: 0: enable 1: disable, regardless of the value of RXEN
PSU_UART1_CONTROL_REG0_RXDIS 0x0
Receive enable: 0: disable 1: enable When set to one, the receiver logic is enabled, provided the RXDIS field is set to zero.
PSU_UART1_CONTROL_REG0_RXEN 0x1
Software reset for Tx data path: 0: no affect 1: transmitter logic is reset and all pending transmitter data is discarded Thi
bit is self clearing once the reset has completed.
PSU_UART1_CONTROL_REG0_TXRES 0x1
Software reset for Rx data path: 0: no affect 1: receiver logic is reset and all pending receiver data is discarded. This bit
is self clearing once the reset has completed.
PSU_UART1_CONTROL_REG0_RXRES 0x1
UART Control Register
(OFFSET, MASK, VALUE) (0XFF010000, 0x000001FFU ,0x00000017U)
RegMask = (UART1_CONTROL_REG0_STPBRK_MASK | UART1_CONTROL_REG0_STTBRK_MASK | UART1_CONTROL_REG0_RSTTO_MASK | UART1_CONTROL_REG0_TXDIS_MASK | UART1_CONTROL_REG0_TXEN_MASK | UART1_CONTROL_REG0_RXDIS_MASK | UART1_CONTROL_REG0_RXEN_MASK | UART1_CONTROL_REG0_TXRES_MASK | UART1_CONTROL_REG0_RXRES_MASK | 0 );
RegVal = ((0x00000000U << UART1_CONTROL_REG0_STPBRK_SHIFT
| 0x00000000U << UART1_CONTROL_REG0_STTBRK_SHIFT
| 0x00000000U << UART1_CONTROL_REG0_RSTTO_SHIFT
| 0x00000000U << UART1_CONTROL_REG0_TXDIS_SHIFT
| 0x00000001U << UART1_CONTROL_REG0_TXEN_SHIFT
| 0x00000000U << UART1_CONTROL_REG0_RXDIS_SHIFT
| 0x00000001U << UART1_CONTROL_REG0_RXEN_SHIFT
| 0x00000001U << UART1_CONTROL_REG0_TXRES_SHIFT
| 0x00000001U << UART1_CONTROL_REG0_RXRES_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART1_CONTROL_REG0_OFFSET ,0x000001FFU ,0x00000017U);
/*############################################################################################################################ */
/*Register : mode_reg0 @ 0XFF010004</p>
Channel mode: Defines the mode of operation of the UART. 00: normal 01: automatic echo 10: local loopback 11: remote loopback
PSU_UART1_MODE_REG0_CHMODE 0x0
Number of stop bits: Defines the number of stop bits to detect on receive and to generate on transmit. 00: 1 stop bit 01: 1.5
stop bits 10: 2 stop bits 11: reserved
PSU_UART1_MODE_REG0_NBSTOP 0x0
Parity type select: Defines the expected parity to check on receive and the parity to generate on transmit. 000: even parity
01: odd parity 010: forced to 0 parity (space) 011: forced to 1 parity (mark) 1xx: no parity
PSU_UART1_MODE_REG0_PAR 0x4
Character length select: Defines the number of bits in each character. 11: 6 bits 10: 7 bits 0x: 8 bits
PSU_UART1_MODE_REG0_CHRL 0x0
Clock source select: This field defines whether a pre-scalar of 8 is applied to the baud rate generator input clock. 0: clock
source is uart_ref_clk 1: clock source is uart_ref_clk/8
PSU_UART1_MODE_REG0_CLKS 0x0
UART Mode Register
(OFFSET, MASK, VALUE) (0XFF010004, 0x000003FFU ,0x00000020U)
RegMask = (UART1_MODE_REG0_CHMODE_MASK | UART1_MODE_REG0_NBSTOP_MASK | UART1_MODE_REG0_PAR_MASK | UART1_MODE_REG0_CHRL_MASK | UART1_MODE_REG0_CLKS_MASK | 0 );
RegVal = ((0x00000000U << UART1_MODE_REG0_CHMODE_SHIFT
| 0x00000000U << UART1_MODE_REG0_NBSTOP_SHIFT
| 0x00000004U << UART1_MODE_REG0_PAR_SHIFT
| 0x00000000U << UART1_MODE_REG0_CHRL_SHIFT
| 0x00000000U << UART1_MODE_REG0_CLKS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (UART1_MODE_REG0_OFFSET ,0x000003FFU ,0x00000020U);
/*############################################################################################################################ */
// : GPIO
// : ADMA TZ
/*Register : slcr_adma @ 0XFF4B0024</p>
TrustZone Classification for ADMA
PSU_LPD_SLCR_SECURE_SLCR_ADMA_TZ 0XFF
RPU TrustZone settings
(OFFSET, MASK, VALUE) (0XFF4B0024, 0x000000FFU ,0x000000FFU)
RegMask = (LPD_SLCR_SECURE_SLCR_ADMA_TZ_MASK | 0 );
RegVal = ((0x000000FFU << LPD_SLCR_SECURE_SLCR_ADMA_TZ_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_SLCR_SECURE_SLCR_ADMA_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
// : CSU TAMPERING
// : CSU TAMPER STATUS
/*Register : tamper_status @ 0XFFCA5000</p>
CSU regsiter
PSU_CSU_TAMPER_STATUS_TAMPER_0 0
External MIO
PSU_CSU_TAMPER_STATUS_TAMPER_1 0
JTAG toggle detect
PSU_CSU_TAMPER_STATUS_TAMPER_2 0
PL SEU error
PSU_CSU_TAMPER_STATUS_TAMPER_3 0
AMS over temperature alarm for LPD
PSU_CSU_TAMPER_STATUS_TAMPER_4 0
AMS over temperature alarm for APU
PSU_CSU_TAMPER_STATUS_TAMPER_5 0
AMS voltage alarm for VCCPINT_FPD
PSU_CSU_TAMPER_STATUS_TAMPER_6 0
AMS voltage alarm for VCCPINT_LPD
PSU_CSU_TAMPER_STATUS_TAMPER_7 0
AMS voltage alarm for VCCPAUX
PSU_CSU_TAMPER_STATUS_TAMPER_8 0
AMS voltage alarm for DDRPHY
PSU_CSU_TAMPER_STATUS_TAMPER_9 0
AMS voltage alarm for PSIO bank 0/1/2
PSU_CSU_TAMPER_STATUS_TAMPER_10 0
AMS voltage alarm for PSIO bank 3 (dedicated pins)
PSU_CSU_TAMPER_STATUS_TAMPER_11 0
AMS voltaage alarm for GT
PSU_CSU_TAMPER_STATUS_TAMPER_12 0
Tamper Response Status
(OFFSET, MASK, VALUE) (0XFFCA5000, 0x00001FFFU ,0x00000000U)
RegMask = (CSU_TAMPER_STATUS_TAMPER_0_MASK | CSU_TAMPER_STATUS_TAMPER_1_MASK | CSU_TAMPER_STATUS_TAMPER_2_MASK | CSU_TAMPER_STATUS_TAMPER_3_MASK | CSU_TAMPER_STATUS_TAMPER_4_MASK | CSU_TAMPER_STATUS_TAMPER_5_MASK | CSU_TAMPER_STATUS_TAMPER_6_MASK | CSU_TAMPER_STATUS_TAMPER_7_MASK | CSU_TAMPER_STATUS_TAMPER_8_MASK | CSU_TAMPER_STATUS_TAMPER_9_MASK | CSU_TAMPER_STATUS_TAMPER_10_MASK | CSU_TAMPER_STATUS_TAMPER_11_MASK | CSU_TAMPER_STATUS_TAMPER_12_MASK | 0 );
RegVal = ((0x00000000U << CSU_TAMPER_STATUS_TAMPER_0_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_1_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_2_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_3_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_4_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_5_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_6_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_7_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_8_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_9_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_10_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_11_SHIFT
| 0x00000000U << CSU_TAMPER_STATUS_TAMPER_12_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CSU_TAMPER_STATUS_OFFSET ,0x00001FFFU ,0x00000000U);
/*############################################################################################################################ */
// : CSU TAMPER RESPONSE
// : CPU QOS DEFAULT
/*Register : ACE_CTRL @ 0XFD5C0060</p>
Set ACE outgoing AWQOS value
PSU_APU_ACE_CTRL_AWQOS 0X0
Set ACE outgoing ARQOS value
PSU_APU_ACE_CTRL_ARQOS 0X0
ACE Control Register
(OFFSET, MASK, VALUE) (0XFD5C0060, 0x000F000FU ,0x00000000U)
RegMask = (APU_ACE_CTRL_AWQOS_MASK | APU_ACE_CTRL_ARQOS_MASK | 0 );
RegVal = ((0x00000000U << APU_ACE_CTRL_AWQOS_SHIFT
| 0x00000000U << APU_ACE_CTRL_ARQOS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (APU_ACE_CTRL_OFFSET ,0x000F000FU ,0x00000000U);
/*############################################################################################################################ */
// : ENABLES RTC SWITCH TO BATTERY WHEN VCC_PSAUX IS NOT AVAILABLE
/*Register : CONTROL @ 0XFFA60040</p>
Enables the RTC. By writing a 0 to this bit, RTC will be powered off and the only module that potentially draws current from
he battery will be BBRAM. The value read through this bit does not necessarily reflect whether RTC is enabled or not. It is e
pected that RTC is enabled every time it is being configured. If RTC is not used in the design, FSBL will disable it by writi
g a 0 to this bit.
PSU_RTC_CONTROL_BATTERY_DISABLE 0X1
This register controls various functionalities within the RTC
(OFFSET, MASK, VALUE) (0XFFA60040, 0x80000000U ,0x80000000U)
RegMask = (RTC_CONTROL_BATTERY_DISABLE_MASK | 0 );
RegVal = ((0x00000001U << RTC_CONTROL_BATTERY_DISABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (RTC_CONTROL_OFFSET ,0x80000000U ,0x80000000U);
/*############################################################################################################################ */
// : TIMESTAMP COUNTER
/*Register : base_frequency_ID_register @ 0XFF260020</p>
Frequency in number of ticks per second. Valid range from 10 MHz to 100 MHz.
PSU_IOU_SCNTRS_BASE_FREQUENCY_ID_REGISTER_FREQ 0x5f5e100
Program this register to match the clock frequency of the timestamp generator, in ticks per second. For example, for a 50 MHz
clock, program 0x02FAF080. This register is not accessible to the read-only programming interface.
(OFFSET, MASK, VALUE) (0XFF260020, 0xFFFFFFFFU ,0x05F5E100U)
RegMask = (IOU_SCNTRS_BASE_FREQUENCY_ID_REGISTER_FREQ_MASK | 0 );
RegVal = ((0x05F5E100U << IOU_SCNTRS_BASE_FREQUENCY_ID_REGISTER_FREQ_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SCNTRS_BASE_FREQUENCY_ID_REGISTER_OFFSET ,0xFFFFFFFFU ,0x05F5E100U);
/*############################################################################################################################ */
/*Register : counter_control_register @ 0XFF260000</p>
Enable 0: The counter is disabled and not incrementing. 1: The counter is enabled and is incrementing.
PSU_IOU_SCNTRS_COUNTER_CONTROL_REGISTER_EN 0x1
Controls the counter increments. This register is not accessible to the read-only programming interface.
(OFFSET, MASK, VALUE) (0XFF260000, 0x00000001U ,0x00000001U)
RegMask = (IOU_SCNTRS_COUNTER_CONTROL_REGISTER_EN_MASK | 0 );
RegVal = ((0x00000001U << IOU_SCNTRS_COUNTER_CONTROL_REGISTER_EN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (IOU_SCNTRS_COUNTER_CONTROL_REGISTER_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : TTC SRC SELECT
return 1;
}
unsigned long psu_post_config_data() {
// : POST_CONFIG
return 1;
}
unsigned long psu_peripherals_powerdwn_data() {
// : POWER DOWN REQUEST INTERRUPT ENABLE
// : POWER DOWN TRIGGER
return 1;
}
unsigned long psu_lpd_xppu_data() {
// : MASTER ID LIST
/*Register : MASTER_ID00 @ 0XFF980100</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID00_MIDR 1
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID00_MIDM 960
Predefined Master ID for PMU
PSU_LPD_XPPU_CFG_MASTER_ID00_MID 128
Master ID 00 Register
(OFFSET, MASK, VALUE) (0XFF980100, 0x43FF03FFU ,0x43C00080U)
RegMask = (LPD_XPPU_CFG_MASTER_ID00_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID00_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID00_MID_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_MASTER_ID00_MIDR_SHIFT
| 0x000003C0U << LPD_XPPU_CFG_MASTER_ID00_MIDM_SHIFT
| 0x00000080U << LPD_XPPU_CFG_MASTER_ID00_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID00_OFFSET ,0x43FF03FFU ,0x43C00080U);
/*############################################################################################################################ */
/*Register : MASTER_ID01 @ 0XFF980104</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID01_MIDR 1
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID01_MIDM 1023
Predefined Master ID for RPU0
PSU_LPD_XPPU_CFG_MASTER_ID01_MID 64
Master ID 01 Register
(OFFSET, MASK, VALUE) (0XFF980104, 0x43FF03FFU ,0x43FF0040U)
RegMask = (LPD_XPPU_CFG_MASTER_ID01_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID01_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID01_MID_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_MASTER_ID01_MIDR_SHIFT
| 0x000003FFU << LPD_XPPU_CFG_MASTER_ID01_MIDM_SHIFT
| 0x00000040U << LPD_XPPU_CFG_MASTER_ID01_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID01_OFFSET ,0x43FF03FFU ,0x43FF0040U);
/*############################################################################################################################ */
/*Register : MASTER_ID02 @ 0XFF980108</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID02_MIDR 1
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID02_MIDM 1008
Predefined Master ID for RPU1
PSU_LPD_XPPU_CFG_MASTER_ID02_MID 0
Master ID 02 Register
(OFFSET, MASK, VALUE) (0XFF980108, 0x43FF03FFU ,0x43F00000U)
RegMask = (LPD_XPPU_CFG_MASTER_ID02_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID02_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID02_MID_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_MASTER_ID02_MIDR_SHIFT
| 0x000003F0U << LPD_XPPU_CFG_MASTER_ID02_MIDM_SHIFT
| 0x00000000U << LPD_XPPU_CFG_MASTER_ID02_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID02_OFFSET ,0x43FF03FFU ,0x43F00000U);
/*############################################################################################################################ */
/*Register : MASTER_ID03 @ 0XFF98010C</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID03_MIDR 1
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID03_MIDM 1008
Predefined Master ID for APU
PSU_LPD_XPPU_CFG_MASTER_ID03_MID 16
Master ID 03 Register
(OFFSET, MASK, VALUE) (0XFF98010C, 0x43FF03FFU ,0x43F00010U)
RegMask = (LPD_XPPU_CFG_MASTER_ID03_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID03_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID03_MID_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_MASTER_ID03_MIDR_SHIFT
| 0x000003F0U << LPD_XPPU_CFG_MASTER_ID03_MIDM_SHIFT
| 0x00000010U << LPD_XPPU_CFG_MASTER_ID03_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID03_OFFSET ,0x43FF03FFU ,0x43F00010U);
/*############################################################################################################################ */
/*Register : MASTER_ID04 @ 0XFF980110</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID04_MIDR 0
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID04_MIDM 960
Predefined Master ID for A53 Core 0
PSU_LPD_XPPU_CFG_MASTER_ID04_MID 128
Master ID 04 Register
(OFFSET, MASK, VALUE) (0XFF980110, 0x43FF03FFU ,0x03C00080U)
RegMask = (LPD_XPPU_CFG_MASTER_ID04_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID04_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID04_MID_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_MASTER_ID04_MIDR_SHIFT
| 0x000003C0U << LPD_XPPU_CFG_MASTER_ID04_MIDM_SHIFT
| 0x00000080U << LPD_XPPU_CFG_MASTER_ID04_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID04_OFFSET ,0x43FF03FFU ,0x03C00080U);
/*############################################################################################################################ */
/*Register : MASTER_ID05 @ 0XFF980114</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID05_MIDR 0
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID05_MIDM 1023
Predefined Master ID for A53 Core 1
PSU_LPD_XPPU_CFG_MASTER_ID05_MID 64
Master ID 05 Register
(OFFSET, MASK, VALUE) (0XFF980114, 0x43FF03FFU ,0x03FF0040U)
RegMask = (LPD_XPPU_CFG_MASTER_ID05_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID05_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID05_MID_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_MASTER_ID05_MIDR_SHIFT
| 0x000003FFU << LPD_XPPU_CFG_MASTER_ID05_MIDM_SHIFT
| 0x00000040U << LPD_XPPU_CFG_MASTER_ID05_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID05_OFFSET ,0x43FF03FFU ,0x03FF0040U);
/*############################################################################################################################ */
/*Register : MASTER_ID06 @ 0XFF980118</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID06_MIDR 0
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID06_MIDM 1008
Predefined Master ID for A53 Core 2
PSU_LPD_XPPU_CFG_MASTER_ID06_MID 0
Master ID 06 Register
(OFFSET, MASK, VALUE) (0XFF980118, 0x43FF03FFU ,0x03F00000U)
RegMask = (LPD_XPPU_CFG_MASTER_ID06_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID06_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID06_MID_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_MASTER_ID06_MIDR_SHIFT
| 0x000003F0U << LPD_XPPU_CFG_MASTER_ID06_MIDM_SHIFT
| 0x00000000U << LPD_XPPU_CFG_MASTER_ID06_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID06_OFFSET ,0x43FF03FFU ,0x03F00000U);
/*############################################################################################################################ */
/*Register : MASTER_ID07 @ 0XFF98011C</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID07_MIDR 0
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID07_MIDM 1008
Predefined Master ID for A53 Core 3
PSU_LPD_XPPU_CFG_MASTER_ID07_MID 16
Master ID 07 Register
(OFFSET, MASK, VALUE) (0XFF98011C, 0x43FF03FFU ,0x03F00010U)
RegMask = (LPD_XPPU_CFG_MASTER_ID07_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID07_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID07_MID_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_MASTER_ID07_MIDR_SHIFT
| 0x000003F0U << LPD_XPPU_CFG_MASTER_ID07_MIDM_SHIFT
| 0x00000010U << LPD_XPPU_CFG_MASTER_ID07_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID07_OFFSET ,0x43FF03FFU ,0x03F00010U);
/*############################################################################################################################ */
/*Register : MASTER_ID19 @ 0XFF98014C</p>
If set, only read transactions are allowed for the masters matching this register
PSU_LPD_XPPU_CFG_MASTER_ID19_MIDR 0
Mask to be applied before comparing
PSU_LPD_XPPU_CFG_MASTER_ID19_MIDM 0
Programmable Master ID
PSU_LPD_XPPU_CFG_MASTER_ID19_MID 0
Master ID 19 Register
(OFFSET, MASK, VALUE) (0XFF98014C, 0x43FF03FFU ,0x00000000U)
RegMask = (LPD_XPPU_CFG_MASTER_ID19_MIDR_MASK | LPD_XPPU_CFG_MASTER_ID19_MIDM_MASK | LPD_XPPU_CFG_MASTER_ID19_MID_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_MASTER_ID19_MIDR_SHIFT
| 0x00000000U << LPD_XPPU_CFG_MASTER_ID19_MIDM_SHIFT
| 0x00000000U << LPD_XPPU_CFG_MASTER_ID19_MID_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_MASTER_ID19_OFFSET ,0x43FF03FFU ,0x00000000U);
/*############################################################################################################################ */
// : APERTURE PERMISIION LIST
// : APERTURE NAME: UART0, START ADDRESS: FF000000, END ADDRESS: FF00FFFF
// : APERTURE NAME: UART1, START ADDRESS: FF010000, END ADDRESS: FF01FFFF
// : APERTURE NAME: I2C0, START ADDRESS: FF020000, END ADDRESS: FF02FFFF
// : APERTURE NAME: I2C1, START ADDRESS: FF030000, END ADDRESS: FF03FFFF
// : APERTURE NAME: SPI0, START ADDRESS: FF040000, END ADDRESS: FF04FFFF
// : APERTURE NAME: SPI1, START ADDRESS: FF050000, END ADDRESS: FF05FFFF
// : APERTURE NAME: CAN0, START ADDRESS: FF060000, END ADDRESS: FF06FFFF
// : APERTURE NAME: CAN1, START ADDRESS: FF070000, END ADDRESS: FF07FFFF
// : APERTURE NAME: RPU_UNUSED_12, START ADDRESS: FF080000, END ADDRESS: FF09FFFF
// : APERTURE NAME: RPU_UNUSED_12, START ADDRESS: FF080000, END ADDRESS: FF09FFFF
// : APERTURE NAME: GPIO, START ADDRESS: FF0A0000, END ADDRESS: FF0AFFFF
// : APERTURE NAME: GEM0, START ADDRESS: FF0B0000, END ADDRESS: FF0BFFFF
// : APERTURE NAME: GEM1, START ADDRESS: FF0C0000, END ADDRESS: FF0CFFFF
// : APERTURE NAME: GEM2, START ADDRESS: FF0D0000, END ADDRESS: FF0DFFFF
// : APERTURE NAME: GEM3, START ADDRESS: FF0E0000, END ADDRESS: FF0EFFFF
// : APERTURE NAME: QSPI, START ADDRESS: FF0F0000, END ADDRESS: FF0FFFFF
// : APERTURE NAME: NAND, START ADDRESS: FF100000, END ADDRESS: FF10FFFF
// : APERTURE NAME: TTC0, START ADDRESS: FF110000, END ADDRESS: FF11FFFF
// : APERTURE NAME: TTC1, START ADDRESS: FF120000, END ADDRESS: FF12FFFF
// : APERTURE NAME: TTC2, START ADDRESS: FF130000, END ADDRESS: FF13FFFF
// : APERTURE NAME: TTC3, START ADDRESS: FF140000, END ADDRESS: FF14FFFF
// : APERTURE NAME: SWDT, START ADDRESS: FF150000, END ADDRESS: FF15FFFF
// : APERTURE NAME: SD0, START ADDRESS: FF160000, END ADDRESS: FF16FFFF
// : APERTURE NAME: SD1, START ADDRESS: FF170000, END ADDRESS: FF17FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SLCR, START ADDRESS: FF180000, END ADDRESS: FF23FFFF
// : APERTURE NAME: IOU_SECURE_SLCR, START ADDRESS: FF240000, END ADDRESS: FF24FFFF
// : APERTURE NAME: IOU_SCNTR, START ADDRESS: FF250000, END ADDRESS: FF25FFFF
// : APERTURE NAME: IOU_SCNTRS, START ADDRESS: FF260000, END ADDRESS: FF26FFFF
// : APERTURE NAME: RPU_UNUSED_11, START ADDRESS: FF270000, END ADDRESS: FF2AFFFF
// : APERTURE NAME: RPU_UNUSED_11, START ADDRESS: FF270000, END ADDRESS: FF2AFFFF
// : APERTURE NAME: RPU_UNUSED_11, START ADDRESS: FF270000, END ADDRESS: FF2AFFFF
// : APERTURE NAME: RPU_UNUSED_11, START ADDRESS: FF270000, END ADDRESS: FF2AFFFF
// : APERTURE NAME: LPD_UNUSED_14, START ADDRESS: FF2B0000, END ADDRESS: FF2FFFFF
// : APERTURE NAME: LPD_UNUSED_14, START ADDRESS: FF2B0000, END ADDRESS: FF2FFFFF
// : APERTURE NAME: LPD_UNUSED_14, START ADDRESS: FF2B0000, END ADDRESS: FF2FFFFF
// : APERTURE NAME: LPD_UNUSED_14, START ADDRESS: FF2B0000, END ADDRESS: FF2FFFFF
// : APERTURE NAME: LPD_UNUSED_14, START ADDRESS: FF2B0000, END ADDRESS: FF2FFFFF
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_048 @ 0XFF9810C0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_048_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_048_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_048_PARITY 0x0
Entry 048 of the Aperture Permission List, for the 64K-byte aperture at BASE_64KB + 0x00300000
(OFFSET, MASK, VALUE) (0XFF9810C0, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_048_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_048_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_048_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_048_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_048_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_048_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_048_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_049 @ 0XFF9810C4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_049_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_049_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_049_PARITY 0x0
Entry 049 of the Aperture Permission List, for the 64K-byte aperture at BASE_64KB + 0x00310000
(OFFSET, MASK, VALUE) (0XFF9810C4, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_049_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_049_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_049_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_049_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_049_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_049_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_049_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_050 @ 0XFF9810C8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_050_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_050_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_050_PARITY 0x0
Entry 050 of the Aperture Permission List, for the 64K-byte aperture at BASE_64KB + 0x00320000
(OFFSET, MASK, VALUE) (0XFF9810C8, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_050_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_050_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_050_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_050_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_050_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_050_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_050_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_051 @ 0XFF9810CC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_051_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_051_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_051_PARITY 0x0
Entry 051 of the Aperture Permission List, for the 64K-byte aperture at BASE_64KB + 0x00330000
(OFFSET, MASK, VALUE) (0XFF9810CC, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_051_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_051_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_051_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_051_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_051_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_051_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_051_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: IPI_CTRL, START ADDRESS: FF380000, END ADDRESS: FF3FFFFF
// : APERTURE NAME: LPD_UNUSED_1, START ADDRESS: FF400000, END ADDRESS: FF40FFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR, START ADDRESS: FF410000, END ADDRESS: FF4AFFFF
// : APERTURE NAME: LPD_SLCR_SECURE, START ADDRESS: FF4B0000, END ADDRESS: FF4DFFFF
// : APERTURE NAME: LPD_SLCR_SECURE, START ADDRESS: FF4B0000, END ADDRESS: FF4DFFFF
// : APERTURE NAME: LPD_SLCR_SECURE, START ADDRESS: FF4B0000, END ADDRESS: FF4DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: LPD_UNUSED_2, START ADDRESS: FF4E0000, END ADDRESS: FF5DFFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: CRL_APB, START ADDRESS: FF5E0000, END ADDRESS: FF85FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: LPD_UNUSED_3, START ADDRESS: FF860000, END ADDRESS: FF95FFFF
// : APERTURE NAME: OCM_SLCR, START ADDRESS: FF960000, END ADDRESS: FF96FFFF
// : APERTURE NAME: LPD_UNUSED_4, START ADDRESS: FF970000, END ADDRESS: FF97FFFF
// : APERTURE NAME: LPD_XPPU, START ADDRESS: FF980000, END ADDRESS: FF99FFFF
// : APERTURE NAME: RPU, START ADDRESS: FF9A0000, END ADDRESS: FF9AFFFF
// : APERTURE NAME: AFIFM6, START ADDRESS: FF9B0000, END ADDRESS: FF9BFFFF
// : APERTURE NAME: LPD_XPPU_SINK, START ADDRESS: FF9C0000, END ADDRESS: FF9CFFFF
// : APERTURE NAME: USB3_0, START ADDRESS: FF9D0000, END ADDRESS: FF9DFFFF
// : APERTURE NAME: USB3_1, START ADDRESS: FF9E0000, END ADDRESS: FF9EFFFF
// : APERTURE NAME: LPD_UNUSED_5, START ADDRESS: FF9F0000, END ADDRESS: FF9FFFFF
// : APERTURE NAME: APM0, START ADDRESS: FFA00000, END ADDRESS: FFA0FFFF
// : APERTURE NAME: APM1, START ADDRESS: FFA10000, END ADDRESS: FFA1FFFF
// : APERTURE NAME: APM_INTC_IOU, START ADDRESS: FFA20000, END ADDRESS: FFA2FFFF
// : APERTURE NAME: APM_FPD_LPD, START ADDRESS: FFA30000, END ADDRESS: FFA3FFFF
// : APERTURE NAME: LPD_UNUSED_6, START ADDRESS: FFA40000, END ADDRESS: FFA4FFFF
// : APERTURE NAME: AMS, START ADDRESS: FFA50000, END ADDRESS: FFA5FFFF
// : APERTURE NAME: RTC, START ADDRESS: FFA60000, END ADDRESS: FFA6FFFF
// : APERTURE NAME: OCM_XMPU_CFG, START ADDRESS: FFA70000, END ADDRESS: FFA7FFFF
// : APERTURE NAME: ADMA_0, START ADDRESS: FFA80000, END ADDRESS: FFA8FFFF
// : APERTURE NAME: ADMA_1, START ADDRESS: FFA90000, END ADDRESS: FFA9FFFF
// : APERTURE NAME: ADMA_2, START ADDRESS: FFAA0000, END ADDRESS: FFAAFFFF
// : APERTURE NAME: ADMA_3, START ADDRESS: FFAB0000, END ADDRESS: FFABFFFF
// : APERTURE NAME: ADMA_4, START ADDRESS: FFAC0000, END ADDRESS: FFACFFFF
// : APERTURE NAME: ADMA_5, START ADDRESS: FFAD0000, END ADDRESS: FFADFFFF
// : APERTURE NAME: ADMA_6, START ADDRESS: FFAE0000, END ADDRESS: FFAEFFFF
// : APERTURE NAME: ADMA_7, START ADDRESS: FFAF0000, END ADDRESS: FFAFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: LPD_UNUSED_7, START ADDRESS: FFB00000, END ADDRESS: FFBFFFFF
// : APERTURE NAME: CSU_ROM, START ADDRESS: FFC00000, END ADDRESS: FFC1FFFF
// : APERTURE NAME: CSU_ROM, START ADDRESS: FFC00000, END ADDRESS: FFC1FFFF
// : APERTURE NAME: CSU_LOCAL, START ADDRESS: FFC20000, END ADDRESS: FFC2FFFF
// : APERTURE NAME: PUF, START ADDRESS: FFC30000, END ADDRESS: FFC3FFFF
// : APERTURE NAME: CSU_RAM, START ADDRESS: FFC40000, END ADDRESS: FFC5FFFF
// : APERTURE NAME: CSU_RAM, START ADDRESS: FFC40000, END ADDRESS: FFC5FFFF
// : APERTURE NAME: CSU_IOMODULE, START ADDRESS: FFC60000, END ADDRESS: FFC7FFFF
// : APERTURE NAME: CSU_IOMODULE, START ADDRESS: FFC60000, END ADDRESS: FFC7FFFF
// : APERTURE NAME: CSUDMA, START ADDRESS: FFC80000, END ADDRESS: FFC9FFFF
// : APERTURE NAME: CSUDMA, START ADDRESS: FFC80000, END ADDRESS: FFC9FFFF
// : APERTURE NAME: CSU, START ADDRESS: FFCA0000, END ADDRESS: FFCAFFFF
// : APERTURE NAME: CSU_WDT, START ADDRESS: FFCB0000, END ADDRESS: FFCBFFFF
// : APERTURE NAME: EFUSE, START ADDRESS: FFCC0000, END ADDRESS: FFCCFFFF
// : APERTURE NAME: BBRAM, START ADDRESS: FFCD0000, END ADDRESS: FFCDFFFF
// : APERTURE NAME: RSA_CORE, START ADDRESS: FFCE0000, END ADDRESS: FFCEFFFF
// : APERTURE NAME: MBISTJTAG, START ADDRESS: FFCF0000, END ADDRESS: FFCFFFFF
// : APERTURE NAME: PMU_ROM, START ADDRESS: FFD00000, END ADDRESS: FFD3FFFF
// : APERTURE NAME: PMU_ROM, START ADDRESS: FFD00000, END ADDRESS: FFD3FFFF
// : APERTURE NAME: PMU_ROM, START ADDRESS: FFD00000, END ADDRESS: FFD3FFFF
// : APERTURE NAME: PMU_ROM, START ADDRESS: FFD00000, END ADDRESS: FFD3FFFF
// : APERTURE NAME: PMU_IOMODULE, START ADDRESS: FFD40000, END ADDRESS: FFD5FFFF
// : APERTURE NAME: PMU_IOMODULE, START ADDRESS: FFD40000, END ADDRESS: FFD5FFFF
// : APERTURE NAME: PMU_LOCAL, START ADDRESS: FFD60000, END ADDRESS: FFD7FFFF
// : APERTURE NAME: PMU_LOCAL, START ADDRESS: FFD60000, END ADDRESS: FFD7FFFF
// : APERTURE NAME: PMU_GLOBAL, START ADDRESS: FFD80000, END ADDRESS: FFDBFFFF
// : APERTURE NAME: PMU_GLOBAL, START ADDRESS: FFD80000, END ADDRESS: FFDBFFFF
// : APERTURE NAME: PMU_GLOBAL, START ADDRESS: FFD80000, END ADDRESS: FFDBFFFF
// : APERTURE NAME: PMU_GLOBAL, START ADDRESS: FFD80000, END ADDRESS: FFDBFFFF
// : APERTURE NAME: PMU_RAM, START ADDRESS: FFDC0000, END ADDRESS: FFDFFFFF
// : APERTURE NAME: PMU_RAM, START ADDRESS: FFDC0000, END ADDRESS: FFDFFFFF
// : APERTURE NAME: PMU_RAM, START ADDRESS: FFDC0000, END ADDRESS: FFDFFFFF
// : APERTURE NAME: PMU_RAM, START ADDRESS: FFDC0000, END ADDRESS: FFDFFFFF
// : APERTURE NAME: R5_0_ATCM, START ADDRESS: FFE00000, END ADDRESS: FFE0FFFF
// : APERTURE NAME: R5_0_ATCM_LOCKSTEP, START ADDRESS: FFE10000, END ADDRESS: FFE1FFFF
// : APERTURE NAME: R5_0_BTCM, START ADDRESS: FFE20000, END ADDRESS: FFE2FFFF
// : APERTURE NAME: R5_0_BTCM_LOCKSTEP, START ADDRESS: FFE30000, END ADDRESS: FFE3FFFF
// : APERTURE NAME: R5_0_INSTRUCTION_CACHE, START ADDRESS: FFE40000, END ADDRESS: FFE4FFFF
// : APERTURE NAME: R5_0_DATA_CACHE, START ADDRESS: FFE50000, END ADDRESS: FFE5FFFF
// : APERTURE NAME: LPD_UNUSED_8, START ADDRESS: FFE60000, END ADDRESS: FFE8FFFF
// : APERTURE NAME: LPD_UNUSED_8, START ADDRESS: FFE60000, END ADDRESS: FFE8FFFF
// : APERTURE NAME: LPD_UNUSED_8, START ADDRESS: FFE60000, END ADDRESS: FFE8FFFF
// : APERTURE NAME: R5_1_ATCM_, START ADDRESS: FFE90000, END ADDRESS: FFE9FFFF
// : APERTURE NAME: RPU_UNUSED_10, START ADDRESS: FFEA0000, END ADDRESS: FFEAFFFF
// : APERTURE NAME: R5_1_BTCM_, START ADDRESS: FFEB0000, END ADDRESS: FFEBFFFF
// : APERTURE NAME: R5_1_INSTRUCTION_CACHE, START ADDRESS: FFEC0000, END ADDRESS: FFECFFFF
// : APERTURE NAME: R5_1_DATA_CACHE, START ADDRESS: FFED0000, END ADDRESS: FFEDFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_9, START ADDRESS: FFEE0000, END ADDRESS: FFFBFFFF
// : APERTURE NAME: LPD_UNUSED_15, START ADDRESS: FFFD0000, END ADDRESS: FFFFFFFF
// : APERTURE NAME: LPD_UNUSED_15, START ADDRESS: FFFD0000, END ADDRESS: FFFFFFFF
// : APERTURE NAME: LPD_UNUSED_15, START ADDRESS: FFFD0000, END ADDRESS: FFFFFFFF
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_256 @ 0XFF981400</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_256_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_256_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_256_PARITY 0x0
Entry 256 of the Aperture Permission List, for 32-byte IPI buffer 000 at BASE_32B + 0x00000000
(OFFSET, MASK, VALUE) (0XFF981400, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_256_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_256_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_256_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_256_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_256_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_256_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_256_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_257 @ 0XFF981404</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_257_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_257_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_257_PARITY 0x0
Entry 257 of the Aperture Permission List, for 32-byte IPI buffer 001 at BASE_32B + 0x00000020
(OFFSET, MASK, VALUE) (0XFF981404, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_257_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_257_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_257_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_257_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_257_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_257_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_257_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_258 @ 0XFF981408</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_258_PERMISSION 0x48
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_258_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_258_PARITY 0x0
Entry 258 of the Aperture Permission List, for 32-byte IPI buffer 002 at BASE_32B + 0x00000040
(OFFSET, MASK, VALUE) (0XFF981408, 0xF80FFFFFU ,0x08000048U)
RegMask = (LPD_XPPU_CFG_APERPERM_258_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_258_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_258_PARITY_MASK | 0 );
RegVal = ((0x00000048U << LPD_XPPU_CFG_APERPERM_258_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_258_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_258_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_258_OFFSET ,0xF80FFFFFU ,0x08000048U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_259 @ 0XFF98140C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_259_PERMISSION 0x84
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_259_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_259_PARITY 0x0
Entry 259 of the Aperture Permission List, for 32-byte IPI buffer 003 at BASE_32B + 0x00000060
(OFFSET, MASK, VALUE) (0XFF98140C, 0xF80FFFFFU ,0x08000084U)
RegMask = (LPD_XPPU_CFG_APERPERM_259_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_259_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_259_PARITY_MASK | 0 );
RegVal = ((0x00000084U << LPD_XPPU_CFG_APERPERM_259_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_259_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_259_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_259_OFFSET ,0xF80FFFFFU ,0x08000084U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_260 @ 0XFF981410</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_260_PERMISSION 0x41
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_260_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_260_PARITY 0x0
Entry 260 of the Aperture Permission List, for 32-byte IPI buffer 004 at BASE_32B + 0x00000080
(OFFSET, MASK, VALUE) (0XFF981410, 0xF80FFFFFU ,0x08000041U)
RegMask = (LPD_XPPU_CFG_APERPERM_260_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_260_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_260_PARITY_MASK | 0 );
RegVal = ((0x00000041U << LPD_XPPU_CFG_APERPERM_260_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_260_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_260_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_260_OFFSET ,0xF80FFFFFU ,0x08000041U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_261 @ 0XFF981414</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_261_PERMISSION 0x14
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_261_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_261_PARITY 0x0
Entry 261 of the Aperture Permission List, for 32-byte IPI buffer 005 at BASE_32B + 0x000000A0
(OFFSET, MASK, VALUE) (0XFF981414, 0xF80FFFFFU ,0x08000014U)
RegMask = (LPD_XPPU_CFG_APERPERM_261_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_261_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_261_PARITY_MASK | 0 );
RegVal = ((0x00000014U << LPD_XPPU_CFG_APERPERM_261_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_261_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_261_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_261_OFFSET ,0xF80FFFFFU ,0x08000014U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_262 @ 0XFF981418</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_262_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_262_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_262_PARITY 0x0
Entry 262 of the Aperture Permission List, for 32-byte IPI buffer 006 at BASE_32B + 0x000000C0
(OFFSET, MASK, VALUE) (0XFF981418, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_262_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_262_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_262_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_262_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_262_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_262_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_262_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_263 @ 0XFF98141C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_263_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_263_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_263_PARITY 0x0
Entry 263 of the Aperture Permission List, for 32-byte IPI buffer 007 at BASE_32B + 0x000000E0
(OFFSET, MASK, VALUE) (0XFF98141C, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_263_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_263_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_263_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_263_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_263_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_263_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_263_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_264 @ 0XFF981420</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_264_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_264_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_264_PARITY 0x0
Entry 264 of the Aperture Permission List, for 32-byte IPI buffer 008 at BASE_32B + 0x00000100
(OFFSET, MASK, VALUE) (0XFF981420, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_264_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_264_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_264_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_264_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_264_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_264_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_264_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_265 @ 0XFF981424</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_265_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_265_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_265_PARITY 0x0
Entry 265 of the Aperture Permission List, for 32-byte IPI buffer 009 at BASE_32B + 0x00000120
(OFFSET, MASK, VALUE) (0XFF981424, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_265_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_265_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_265_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_265_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_265_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_265_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_265_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_266 @ 0XFF981428</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_266_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_266_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_266_PARITY 0x0
Entry 266 of the Aperture Permission List, for 32-byte IPI buffer 010 at BASE_32B + 0x00000140
(OFFSET, MASK, VALUE) (0XFF981428, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_266_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_266_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_266_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_266_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_266_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_266_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_266_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_267 @ 0XFF98142C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_267_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_267_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_267_PARITY 0x0
Entry 267 of the Aperture Permission List, for 32-byte IPI buffer 011 at BASE_32B + 0x00000160
(OFFSET, MASK, VALUE) (0XFF98142C, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_267_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_267_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_267_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_267_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_267_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_267_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_267_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_268 @ 0XFF981430</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_268_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_268_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_268_PARITY 0x0
Entry 268 of the Aperture Permission List, for 32-byte IPI buffer 012 at BASE_32B + 0x00000180
(OFFSET, MASK, VALUE) (0XFF981430, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_268_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_268_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_268_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_268_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_268_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_268_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_268_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_269 @ 0XFF981434</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_269_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_269_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_269_PARITY 0x0
Entry 269 of the Aperture Permission List, for 32-byte IPI buffer 013 at BASE_32B + 0x000001A0
(OFFSET, MASK, VALUE) (0XFF981434, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_269_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_269_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_269_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_269_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_269_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_269_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_269_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_270 @ 0XFF981438</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_270_PERMISSION 0x42
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_270_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_270_PARITY 0x0
Entry 270 of the Aperture Permission List, for 32-byte IPI buffer 014 at BASE_32B + 0x000001C0
(OFFSET, MASK, VALUE) (0XFF981438, 0xF80FFFFFU ,0x08000042U)
RegMask = (LPD_XPPU_CFG_APERPERM_270_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_270_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_270_PARITY_MASK | 0 );
RegVal = ((0x00000042U << LPD_XPPU_CFG_APERPERM_270_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_270_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_270_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_270_OFFSET ,0xF80FFFFFU ,0x08000042U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_1, START ADDRESS: FF310000, END ADDRESS: FF31FFFF
/*Register : APERPERM_271 @ 0XFF98143C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_271_PERMISSION 0x24
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_271_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_271_PARITY 0x0
Entry 271 of the Aperture Permission List, for 32-byte IPI buffer 015 at BASE_32B + 0x000001E0
(OFFSET, MASK, VALUE) (0XFF98143C, 0xF80FFFFFU ,0x08000024U)
RegMask = (LPD_XPPU_CFG_APERPERM_271_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_271_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_271_PARITY_MASK | 0 );
RegVal = ((0x00000024U << LPD_XPPU_CFG_APERPERM_271_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_271_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_271_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_271_OFFSET ,0xF80FFFFFU ,0x08000024U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_272 @ 0XFF981440</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_272_PERMISSION 0x84
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_272_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_272_PARITY 0x0
Entry 272 of the Aperture Permission List, for 32-byte IPI buffer 016 at BASE_32B + 0x00000200
(OFFSET, MASK, VALUE) (0XFF981440, 0xF80FFFFFU ,0x08000084U)
RegMask = (LPD_XPPU_CFG_APERPERM_272_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_272_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_272_PARITY_MASK | 0 );
RegVal = ((0x00000084U << LPD_XPPU_CFG_APERPERM_272_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_272_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_272_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_272_OFFSET ,0xF80FFFFFU ,0x08000084U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_273 @ 0XFF981444</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_273_PERMISSION 0x48
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_273_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_273_PARITY 0x0
Entry 273 of the Aperture Permission List, for 32-byte IPI buffer 017 at BASE_32B + 0x00000220
(OFFSET, MASK, VALUE) (0XFF981444, 0xF80FFFFFU ,0x08000048U)
RegMask = (LPD_XPPU_CFG_APERPERM_273_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_273_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_273_PARITY_MASK | 0 );
RegVal = ((0x00000048U << LPD_XPPU_CFG_APERPERM_273_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_273_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_273_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_273_OFFSET ,0xF80FFFFFU ,0x08000048U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_274 @ 0XFF981448</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_274_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_274_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_274_PARITY 0x0
Entry 274 of the Aperture Permission List, for 32-byte IPI buffer 018 at BASE_32B + 0x00000240
(OFFSET, MASK, VALUE) (0XFF981448, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_274_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_274_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_274_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_274_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_274_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_274_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_274_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_275 @ 0XFF98144C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_275_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_275_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_275_PARITY 0x0
Entry 275 of the Aperture Permission List, for 32-byte IPI buffer 019 at BASE_32B + 0x00000260
(OFFSET, MASK, VALUE) (0XFF98144C, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_275_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_275_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_275_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_275_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_275_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_275_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_275_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_276 @ 0XFF981450</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_276_PERMISSION 0x81
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_276_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_276_PARITY 0x0
Entry 276 of the Aperture Permission List, for 32-byte IPI buffer 020 at BASE_32B + 0x00000280
(OFFSET, MASK, VALUE) (0XFF981450, 0xF80FFFFFU ,0x08000081U)
RegMask = (LPD_XPPU_CFG_APERPERM_276_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_276_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_276_PARITY_MASK | 0 );
RegVal = ((0x00000081U << LPD_XPPU_CFG_APERPERM_276_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_276_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_276_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_276_OFFSET ,0xF80FFFFFU ,0x08000081U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_277 @ 0XFF981454</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_277_PERMISSION 0x18
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_277_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_277_PARITY 0x0
Entry 277 of the Aperture Permission List, for 32-byte IPI buffer 021 at BASE_32B + 0x000002A0
(OFFSET, MASK, VALUE) (0XFF981454, 0xF80FFFFFU ,0x08000018U)
RegMask = (LPD_XPPU_CFG_APERPERM_277_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_277_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_277_PARITY_MASK | 0 );
RegVal = ((0x00000018U << LPD_XPPU_CFG_APERPERM_277_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_277_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_277_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_277_OFFSET ,0xF80FFFFFU ,0x08000018U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_278 @ 0XFF981458</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_278_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_278_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_278_PARITY 0x0
Entry 278 of the Aperture Permission List, for 32-byte IPI buffer 022 at BASE_32B + 0x000002C0
(OFFSET, MASK, VALUE) (0XFF981458, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_278_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_278_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_278_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_278_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_278_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_278_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_278_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_279 @ 0XFF98145C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_279_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_279_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_279_PARITY 0x0
Entry 279 of the Aperture Permission List, for 32-byte IPI buffer 023 at BASE_32B + 0x000002E0
(OFFSET, MASK, VALUE) (0XFF98145C, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_279_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_279_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_279_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_279_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_279_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_279_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_279_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_280 @ 0XFF981460</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_280_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_280_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_280_PARITY 0x0
Entry 280 of the Aperture Permission List, for 32-byte IPI buffer 024 at BASE_32B + 0x00000300
(OFFSET, MASK, VALUE) (0XFF981460, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_280_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_280_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_280_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_280_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_280_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_280_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_280_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_281 @ 0XFF981464</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_281_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_281_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_281_PARITY 0x0
Entry 281 of the Aperture Permission List, for 32-byte IPI buffer 025 at BASE_32B + 0x00000320
(OFFSET, MASK, VALUE) (0XFF981464, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_281_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_281_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_281_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_281_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_281_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_281_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_281_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_282 @ 0XFF981468</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_282_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_282_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_282_PARITY 0x0
Entry 282 of the Aperture Permission List, for 32-byte IPI buffer 026 at BASE_32B + 0x00000340
(OFFSET, MASK, VALUE) (0XFF981468, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_282_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_282_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_282_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_282_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_282_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_282_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_282_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_283 @ 0XFF98146C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_283_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_283_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_283_PARITY 0x0
Entry 283 of the Aperture Permission List, for 32-byte IPI buffer 027 at BASE_32B + 0x00000360
(OFFSET, MASK, VALUE) (0XFF98146C, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_283_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_283_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_283_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_283_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_283_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_283_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_283_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_284 @ 0XFF981470</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_284_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_284_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_284_PARITY 0x0
Entry 284 of the Aperture Permission List, for 32-byte IPI buffer 028 at BASE_32B + 0x00000380
(OFFSET, MASK, VALUE) (0XFF981470, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_284_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_284_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_284_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_284_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_284_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_284_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_284_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_285 @ 0XFF981474</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_285_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_285_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_285_PARITY 0x0
Entry 285 of the Aperture Permission List, for 32-byte IPI buffer 029 at BASE_32B + 0x000003A0
(OFFSET, MASK, VALUE) (0XFF981474, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_285_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_285_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_285_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_285_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_285_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_285_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_285_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_286 @ 0XFF981478</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_286_PERMISSION 0x82
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_286_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_286_PARITY 0x0
Entry 286 of the Aperture Permission List, for 32-byte IPI buffer 030 at BASE_32B + 0x000003C0
(OFFSET, MASK, VALUE) (0XFF981478, 0xF80FFFFFU ,0x08000082U)
RegMask = (LPD_XPPU_CFG_APERPERM_286_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_286_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_286_PARITY_MASK | 0 );
RegVal = ((0x00000082U << LPD_XPPU_CFG_APERPERM_286_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_286_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_286_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_286_OFFSET ,0xF80FFFFFU ,0x08000082U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_2, START ADDRESS: FF320000, END ADDRESS: FF32FFFF
/*Register : APERPERM_287 @ 0XFF98147C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_287_PERMISSION 0x28
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_287_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_287_PARITY 0x0
Entry 287 of the Aperture Permission List, for 32-byte IPI buffer 031 at BASE_32B + 0x000003E0
(OFFSET, MASK, VALUE) (0XFF98147C, 0xF80FFFFFU ,0x08000028U)
RegMask = (LPD_XPPU_CFG_APERPERM_287_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_287_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_287_PARITY_MASK | 0 );
RegVal = ((0x00000028U << LPD_XPPU_CFG_APERPERM_287_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_287_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_287_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_287_OFFSET ,0xF80FFFFFU ,0x08000028U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_288 @ 0XFF981480</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_288_PERMISSION 0x14
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_288_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_288_PARITY 0x0
Entry 288 of the Aperture Permission List, for 32-byte IPI buffer 032 at BASE_32B + 0x00000400
(OFFSET, MASK, VALUE) (0XFF981480, 0xF80FFFFFU ,0x08000014U)
RegMask = (LPD_XPPU_CFG_APERPERM_288_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_288_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_288_PARITY_MASK | 0 );
RegVal = ((0x00000014U << LPD_XPPU_CFG_APERPERM_288_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_288_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_288_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_288_OFFSET ,0xF80FFFFFU ,0x08000014U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_289 @ 0XFF981484</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_289_PERMISSION 0x41
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_289_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_289_PARITY 0x0
Entry 289 of the Aperture Permission List, for 32-byte IPI buffer 033 at BASE_32B + 0x00000420
(OFFSET, MASK, VALUE) (0XFF981484, 0xF80FFFFFU ,0x08000041U)
RegMask = (LPD_XPPU_CFG_APERPERM_289_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_289_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_289_PARITY_MASK | 0 );
RegVal = ((0x00000041U << LPD_XPPU_CFG_APERPERM_289_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_289_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_289_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_289_OFFSET ,0xF80FFFFFU ,0x08000041U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_290 @ 0XFF981488</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_290_PERMISSION 0x18
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_290_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_290_PARITY 0x0
Entry 290 of the Aperture Permission List, for 32-byte IPI buffer 034 at BASE_32B + 0x00000440
(OFFSET, MASK, VALUE) (0XFF981488, 0xF80FFFFFU ,0x08000018U)
RegMask = (LPD_XPPU_CFG_APERPERM_290_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_290_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_290_PARITY_MASK | 0 );
RegVal = ((0x00000018U << LPD_XPPU_CFG_APERPERM_290_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_290_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_290_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_290_OFFSET ,0xF80FFFFFU ,0x08000018U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_291 @ 0XFF98148C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_291_PERMISSION 0x81
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_291_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_291_PARITY 0x0
Entry 291 of the Aperture Permission List, for 32-byte IPI buffer 035 at BASE_32B + 0x00000460
(OFFSET, MASK, VALUE) (0XFF98148C, 0xF80FFFFFU ,0x08000081U)
RegMask = (LPD_XPPU_CFG_APERPERM_291_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_291_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_291_PARITY_MASK | 0 );
RegVal = ((0x00000081U << LPD_XPPU_CFG_APERPERM_291_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_291_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_291_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_291_OFFSET ,0xF80FFFFFU ,0x08000081U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_292 @ 0XFF981490</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_292_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_292_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_292_PARITY 0x0
Entry 292 of the Aperture Permission List, for 32-byte IPI buffer 036 at BASE_32B + 0x00000480
(OFFSET, MASK, VALUE) (0XFF981490, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_292_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_292_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_292_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_292_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_292_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_292_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_292_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_293 @ 0XFF981494</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_293_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_293_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_293_PARITY 0x0
Entry 293 of the Aperture Permission List, for 32-byte IPI buffer 037 at BASE_32B + 0x000004A0
(OFFSET, MASK, VALUE) (0XFF981494, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_293_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_293_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_293_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_293_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_293_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_293_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_293_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_294 @ 0XFF981498</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_294_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_294_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_294_PARITY 0x0
Entry 294 of the Aperture Permission List, for 32-byte IPI buffer 038 at BASE_32B + 0x000004C0
(OFFSET, MASK, VALUE) (0XFF981498, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_294_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_294_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_294_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_294_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_294_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_294_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_294_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_295 @ 0XFF98149C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_295_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_295_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_295_PARITY 0x0
Entry 295 of the Aperture Permission List, for 32-byte IPI buffer 039 at BASE_32B + 0x000004E0
(OFFSET, MASK, VALUE) (0XFF98149C, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_295_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_295_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_295_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_295_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_295_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_295_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_295_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_296 @ 0XFF9814A0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_296_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_296_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_296_PARITY 0x0
Entry 296 of the Aperture Permission List, for 32-byte IPI buffer 040 at BASE_32B + 0x00000500
(OFFSET, MASK, VALUE) (0XFF9814A0, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_296_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_296_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_296_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_296_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_296_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_296_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_296_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_297 @ 0XFF9814A4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_297_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_297_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_297_PARITY 0x0
Entry 297 of the Aperture Permission List, for 32-byte IPI buffer 041 at BASE_32B + 0x00000520
(OFFSET, MASK, VALUE) (0XFF9814A4, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_297_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_297_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_297_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_297_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_297_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_297_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_297_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_298 @ 0XFF9814A8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_298_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_298_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_298_PARITY 0x0
Entry 298 of the Aperture Permission List, for 32-byte IPI buffer 042 at BASE_32B + 0x00000540
(OFFSET, MASK, VALUE) (0XFF9814A8, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_298_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_298_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_298_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_298_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_298_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_298_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_298_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_299 @ 0XFF9814AC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_299_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_299_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_299_PARITY 0x0
Entry 299 of the Aperture Permission List, for 32-byte IPI buffer 043 at BASE_32B + 0x00000560
(OFFSET, MASK, VALUE) (0XFF9814AC, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_299_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_299_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_299_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_299_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_299_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_299_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_299_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_300 @ 0XFF9814B0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_300_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_300_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_300_PARITY 0x0
Entry 300 of the Aperture Permission List, for 32-byte IPI buffer 044 at BASE_32B + 0x00000580
(OFFSET, MASK, VALUE) (0XFF9814B0, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_300_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_300_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_300_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_300_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_300_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_300_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_300_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_301 @ 0XFF9814B4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_301_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_301_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_301_PARITY 0x0
Entry 301 of the Aperture Permission List, for 32-byte IPI buffer 045 at BASE_32B + 0x000005A0
(OFFSET, MASK, VALUE) (0XFF9814B4, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_301_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_301_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_301_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_301_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_301_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_301_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_301_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_302 @ 0XFF9814B8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_302_PERMISSION 0x12
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_302_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_302_PARITY 0x0
Entry 302 of the Aperture Permission List, for 32-byte IPI buffer 046 at BASE_32B + 0x000005C0
(OFFSET, MASK, VALUE) (0XFF9814B8, 0xF80FFFFFU ,0x08000012U)
RegMask = (LPD_XPPU_CFG_APERPERM_302_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_302_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_302_PARITY_MASK | 0 );
RegVal = ((0x00000012U << LPD_XPPU_CFG_APERPERM_302_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_302_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_302_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_302_OFFSET ,0xF80FFFFFU ,0x08000012U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_0, START ADDRESS: FF300000, END ADDRESS: FF30FFFF
/*Register : APERPERM_303 @ 0XFF9814BC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_303_PERMISSION 0x21
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_303_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_303_PARITY 0x0
Entry 303 of the Aperture Permission List, for 32-byte IPI buffer 047 at BASE_32B + 0x000005E0
(OFFSET, MASK, VALUE) (0XFF9814BC, 0xF80FFFFFU ,0x08000021U)
RegMask = (LPD_XPPU_CFG_APERPERM_303_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_303_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_303_PARITY_MASK | 0 );
RegVal = ((0x00000021U << LPD_XPPU_CFG_APERPERM_303_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_303_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_303_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_303_OFFSET ,0xF80FFFFFU ,0x08000021U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_304 @ 0XFF9814C0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_304_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_304_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_304_PARITY 0x0
Entry 304 of the Aperture Permission List, for 32-byte IPI buffer 048 at BASE_32B + 0x00000600
(OFFSET, MASK, VALUE) (0XFF9814C0, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_304_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_304_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_304_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_304_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_304_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_304_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_304_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_305 @ 0XFF9814C4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_305_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_305_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_305_PARITY 0x0
Entry 305 of the Aperture Permission List, for 32-byte IPI buffer 049 at BASE_32B + 0x00000620
(OFFSET, MASK, VALUE) (0XFF9814C4, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_305_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_305_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_305_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_305_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_305_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_305_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_305_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_306 @ 0XFF9814C8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_306_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_306_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_306_PARITY 0x0
Entry 306 of the Aperture Permission List, for 32-byte IPI buffer 050 at BASE_32B + 0x00000640
(OFFSET, MASK, VALUE) (0XFF9814C8, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_306_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_306_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_306_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_306_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_306_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_306_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_306_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_307 @ 0XFF9814CC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_307_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_307_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_307_PARITY 0x0
Entry 307 of the Aperture Permission List, for 32-byte IPI buffer 051 at BASE_32B + 0x00000660
(OFFSET, MASK, VALUE) (0XFF9814CC, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_307_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_307_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_307_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_307_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_307_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_307_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_307_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_308 @ 0XFF9814D0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_308_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_308_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_308_PARITY 0x0
Entry 308 of the Aperture Permission List, for 32-byte IPI buffer 052 at BASE_32B + 0x00000680
(OFFSET, MASK, VALUE) (0XFF9814D0, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_308_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_308_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_308_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_308_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_308_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_308_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_308_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_309 @ 0XFF9814D4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_309_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_309_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_309_PARITY 0x0
Entry 309 of the Aperture Permission List, for 32-byte IPI buffer 053 at BASE_32B + 0x000006A0
(OFFSET, MASK, VALUE) (0XFF9814D4, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_309_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_309_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_309_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_309_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_309_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_309_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_309_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_318 @ 0XFF9814F8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_318_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_318_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_318_PARITY 0x0
Entry 318 of the Aperture Permission List, for 32-byte IPI buffer 062 at BASE_32B + 0x000007C0
(OFFSET, MASK, VALUE) (0XFF9814F8, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_318_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_318_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_318_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_318_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_318_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_318_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_318_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_7, START ADDRESS: FF340000, END ADDRESS: FF34FFFF
/*Register : APERPERM_319 @ 0XFF9814FC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_319_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_319_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_319_PARITY 0x0
Entry 319 of the Aperture Permission List, for 32-byte IPI buffer 063 at BASE_32B + 0x000007E0
(OFFSET, MASK, VALUE) (0XFF9814FC, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_319_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_319_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_319_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_319_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_319_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_319_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_319_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_320 @ 0XFF981500</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_320_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_320_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_320_PARITY 0x0
Entry 320 of the Aperture Permission List, for 32-byte IPI buffer 064 at BASE_32B + 0x00000800
(OFFSET, MASK, VALUE) (0XFF981500, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_320_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_320_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_320_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_320_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_320_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_320_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_320_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_321 @ 0XFF981504</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_321_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_321_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_321_PARITY 0x0
Entry 321 of the Aperture Permission List, for 32-byte IPI buffer 065 at BASE_32B + 0x00000820
(OFFSET, MASK, VALUE) (0XFF981504, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_321_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_321_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_321_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_321_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_321_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_321_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_321_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_322 @ 0XFF981508</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_322_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_322_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_322_PARITY 0x0
Entry 322 of the Aperture Permission List, for 32-byte IPI buffer 066 at BASE_32B + 0x00000840
(OFFSET, MASK, VALUE) (0XFF981508, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_322_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_322_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_322_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_322_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_322_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_322_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_322_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_323 @ 0XFF98150C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_323_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_323_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_323_PARITY 0x0
Entry 323 of the Aperture Permission List, for 32-byte IPI buffer 067 at BASE_32B + 0x00000860
(OFFSET, MASK, VALUE) (0XFF98150C, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_323_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_323_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_323_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_323_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_323_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_323_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_323_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_324 @ 0XFF981510</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_324_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_324_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_324_PARITY 0x0
Entry 324 of the Aperture Permission List, for 32-byte IPI buffer 068 at BASE_32B + 0x00000880
(OFFSET, MASK, VALUE) (0XFF981510, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_324_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_324_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_324_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_324_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_324_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_324_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_324_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_325 @ 0XFF981514</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_325_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_325_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_325_PARITY 0x0
Entry 325 of the Aperture Permission List, for 32-byte IPI buffer 069 at BASE_32B + 0x000008A0
(OFFSET, MASK, VALUE) (0XFF981514, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_325_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_325_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_325_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_325_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_325_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_325_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_325_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_334 @ 0XFF981538</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_334_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_334_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_334_PARITY 0x0
Entry 334 of the Aperture Permission List, for 32-byte IPI buffer 078 at BASE_32B + 0x000009C0
(OFFSET, MASK, VALUE) (0XFF981538, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_334_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_334_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_334_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_334_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_334_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_334_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_334_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_8, START ADDRESS: FF350000, END ADDRESS: FF35FFFF
/*Register : APERPERM_335 @ 0XFF98153C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_335_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_335_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_335_PARITY 0x0
Entry 335 of the Aperture Permission List, for 32-byte IPI buffer 079 at BASE_32B + 0x000009E0
(OFFSET, MASK, VALUE) (0XFF98153C, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_335_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_335_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_335_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_335_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_335_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_335_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_335_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_336 @ 0XFF981540</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_336_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_336_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_336_PARITY 0x0
Entry 336 of the Aperture Permission List, for 32-byte IPI buffer 080 at BASE_32B + 0x00000A00
(OFFSET, MASK, VALUE) (0XFF981540, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_336_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_336_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_336_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_336_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_336_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_336_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_336_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_337 @ 0XFF981544</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_337_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_337_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_337_PARITY 0x0
Entry 337 of the Aperture Permission List, for 32-byte IPI buffer 081 at BASE_32B + 0x00000A20
(OFFSET, MASK, VALUE) (0XFF981544, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_337_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_337_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_337_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_337_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_337_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_337_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_337_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_338 @ 0XFF981548</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_338_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_338_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_338_PARITY 0x0
Entry 338 of the Aperture Permission List, for 32-byte IPI buffer 082 at BASE_32B + 0x00000A40
(OFFSET, MASK, VALUE) (0XFF981548, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_338_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_338_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_338_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_338_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_338_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_338_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_338_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_339 @ 0XFF98154C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_339_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_339_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_339_PARITY 0x0
Entry 339 of the Aperture Permission List, for 32-byte IPI buffer 083 at BASE_32B + 0x00000A60
(OFFSET, MASK, VALUE) (0XFF98154C, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_339_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_339_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_339_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_339_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_339_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_339_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_339_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_340 @ 0XFF981550</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_340_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_340_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_340_PARITY 0x0
Entry 340 of the Aperture Permission List, for 32-byte IPI buffer 084 at BASE_32B + 0x00000A80
(OFFSET, MASK, VALUE) (0XFF981550, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_340_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_340_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_340_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_340_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_340_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_340_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_340_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_341 @ 0XFF981554</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_341_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_341_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_341_PARITY 0x0
Entry 341 of the Aperture Permission List, for 32-byte IPI buffer 085 at BASE_32B + 0x00000AA0
(OFFSET, MASK, VALUE) (0XFF981554, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_341_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_341_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_341_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_341_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_341_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_341_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_341_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_350 @ 0XFF981578</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_350_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_350_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_350_PARITY 0x0
Entry 350 of the Aperture Permission List, for 32-byte IPI buffer 094 at BASE_32B + 0x00000BC0
(OFFSET, MASK, VALUE) (0XFF981578, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_350_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_350_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_350_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_350_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_350_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_350_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_350_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_9, START ADDRESS: FF360000, END ADDRESS: FF36FFFF
/*Register : APERPERM_351 @ 0XFF98157C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_351_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_351_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_351_PARITY 0x0
Entry 351 of the Aperture Permission List, for 32-byte IPI buffer 095 at BASE_32B + 0x00000BE0
(OFFSET, MASK, VALUE) (0XFF98157C, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_351_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_351_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_351_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_351_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_351_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_351_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_351_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_352 @ 0XFF981580</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_352_PERMISSION 0x4
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_352_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_352_PARITY 0x0
Entry 352 of the Aperture Permission List, for 32-byte IPI buffer 096 at BASE_32B + 0x00000C00
(OFFSET, MASK, VALUE) (0XFF981580, 0xF80FFFFFU ,0x08000004U)
RegMask = (LPD_XPPU_CFG_APERPERM_352_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_352_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_352_PARITY_MASK | 0 );
RegVal = ((0x00000004U << LPD_XPPU_CFG_APERPERM_352_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_352_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_352_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_352_OFFSET ,0xF80FFFFFU ,0x08000004U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_353 @ 0XFF981584</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_353_PERMISSION 0x40
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_353_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_353_PARITY 0x0
Entry 353 of the Aperture Permission List, for 32-byte IPI buffer 097 at BASE_32B + 0x00000C20
(OFFSET, MASK, VALUE) (0XFF981584, 0xF80FFFFFU ,0x08000040U)
RegMask = (LPD_XPPU_CFG_APERPERM_353_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_353_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_353_PARITY_MASK | 0 );
RegVal = ((0x00000040U << LPD_XPPU_CFG_APERPERM_353_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_353_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_353_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_353_OFFSET ,0xF80FFFFFU ,0x08000040U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_354 @ 0XFF981588</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_354_PERMISSION 0x8
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_354_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_354_PARITY 0x0
Entry 354 of the Aperture Permission List, for 32-byte IPI buffer 098 at BASE_32B + 0x00000C40
(OFFSET, MASK, VALUE) (0XFF981588, 0xF80FFFFFU ,0x08000008U)
RegMask = (LPD_XPPU_CFG_APERPERM_354_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_354_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_354_PARITY_MASK | 0 );
RegVal = ((0x00000008U << LPD_XPPU_CFG_APERPERM_354_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_354_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_354_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_354_OFFSET ,0xF80FFFFFU ,0x08000008U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_355 @ 0XFF98158C</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_355_PERMISSION 0x80
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_355_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_355_PARITY 0x0
Entry 355 of the Aperture Permission List, for 32-byte IPI buffer 099 at BASE_32B + 0x00000C60
(OFFSET, MASK, VALUE) (0XFF98158C, 0xF80FFFFFU ,0x08000080U)
RegMask = (LPD_XPPU_CFG_APERPERM_355_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_355_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_355_PARITY_MASK | 0 );
RegVal = ((0x00000080U << LPD_XPPU_CFG_APERPERM_355_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_355_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_355_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_355_OFFSET ,0xF80FFFFFU ,0x08000080U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_356 @ 0XFF981590</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_356_PERMISSION 0x1
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_356_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_356_PARITY 0x0
Entry 356 of the Aperture Permission List, for 32-byte IPI buffer 100 at BASE_32B + 0x00000C80
(OFFSET, MASK, VALUE) (0XFF981590, 0xF80FFFFFU ,0x08000001U)
RegMask = (LPD_XPPU_CFG_APERPERM_356_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_356_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_356_PARITY_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_APERPERM_356_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_356_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_356_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_356_OFFSET ,0xF80FFFFFU ,0x08000001U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_357 @ 0XFF981594</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_357_PERMISSION 0x10
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_357_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_357_PARITY 0x0
Entry 357 of the Aperture Permission List, for 32-byte IPI buffer 101 at BASE_32B + 0x00000CA0
(OFFSET, MASK, VALUE) (0XFF981594, 0xF80FFFFFU ,0x08000010U)
RegMask = (LPD_XPPU_CFG_APERPERM_357_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_357_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_357_PARITY_MASK | 0 );
RegVal = ((0x00000010U << LPD_XPPU_CFG_APERPERM_357_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_357_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_357_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_357_OFFSET ,0xF80FFFFFU ,0x08000010U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_366 @ 0XFF9815B8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_366_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_366_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_366_PARITY 0x0
Entry 366 of the Aperture Permission List, for 32-byte IPI buffer 110 at BASE_32B + 0x00000DC0
(OFFSET, MASK, VALUE) (0XFF9815B8, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_366_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_366_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_366_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_366_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_366_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_366_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_366_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_10, START ADDRESS: FF370000, END ADDRESS: FF37FFFF
/*Register : APERPERM_367 @ 0XFF9815BC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_367_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_367_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_367_PARITY 0x0
Entry 367 of the Aperture Permission List, for 32-byte IPI buffer 111 at BASE_32B + 0x00000DE0
(OFFSET, MASK, VALUE) (0XFF9815BC, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_367_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_367_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_367_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_367_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_367_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_367_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_367_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_368 @ 0XFF9815C0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_368_PERMISSION 0x24
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_368_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_368_PARITY 0x0
Entry 368 of the Aperture Permission List, for 32-byte IPI buffer 112 at BASE_32B + 0x00000E00
(OFFSET, MASK, VALUE) (0XFF9815C0, 0xF80FFFFFU ,0x08000024U)
RegMask = (LPD_XPPU_CFG_APERPERM_368_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_368_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_368_PARITY_MASK | 0 );
RegVal = ((0x00000024U << LPD_XPPU_CFG_APERPERM_368_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_368_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_368_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_368_OFFSET ,0xF80FFFFFU ,0x08000024U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_369 @ 0XFF9815C4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_369_PERMISSION 0x42
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_369_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_369_PARITY 0x0
Entry 369 of the Aperture Permission List, for 32-byte IPI buffer 113 at BASE_32B + 0x00000E20
(OFFSET, MASK, VALUE) (0XFF9815C4, 0xF80FFFFFU ,0x08000042U)
RegMask = (LPD_XPPU_CFG_APERPERM_369_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_369_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_369_PARITY_MASK | 0 );
RegVal = ((0x00000042U << LPD_XPPU_CFG_APERPERM_369_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_369_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_369_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_369_OFFSET ,0xF80FFFFFU ,0x08000042U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_370 @ 0XFF9815C8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_370_PERMISSION 0x28
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_370_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_370_PARITY 0x0
Entry 370 of the Aperture Permission List, for 32-byte IPI buffer 114 at BASE_32B + 0x00000E40
(OFFSET, MASK, VALUE) (0XFF9815C8, 0xF80FFFFFU ,0x08000028U)
RegMask = (LPD_XPPU_CFG_APERPERM_370_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_370_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_370_PARITY_MASK | 0 );
RegVal = ((0x00000028U << LPD_XPPU_CFG_APERPERM_370_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_370_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_370_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_370_OFFSET ,0xF80FFFFFU ,0x08000028U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_371 @ 0XFF9815CC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_371_PERMISSION 0x82
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_371_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_371_PARITY 0x0
Entry 371 of the Aperture Permission List, for 32-byte IPI buffer 115 at BASE_32B + 0x00000E60
(OFFSET, MASK, VALUE) (0XFF9815CC, 0xF80FFFFFU ,0x08000082U)
RegMask = (LPD_XPPU_CFG_APERPERM_371_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_371_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_371_PARITY_MASK | 0 );
RegVal = ((0x00000082U << LPD_XPPU_CFG_APERPERM_371_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_371_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_371_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_371_OFFSET ,0xF80FFFFFU ,0x08000082U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_372 @ 0XFF9815D0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_372_PERMISSION 0x21
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_372_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_372_PARITY 0x0
Entry 372 of the Aperture Permission List, for 32-byte IPI buffer 116 at BASE_32B + 0x00000E80
(OFFSET, MASK, VALUE) (0XFF9815D0, 0xF80FFFFFU ,0x08000021U)
RegMask = (LPD_XPPU_CFG_APERPERM_372_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_372_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_372_PARITY_MASK | 0 );
RegVal = ((0x00000021U << LPD_XPPU_CFG_APERPERM_372_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_372_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_372_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_372_OFFSET ,0xF80FFFFFU ,0x08000021U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_373 @ 0XFF9815D4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_373_PERMISSION 0x12
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_373_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_373_PARITY 0x0
Entry 373 of the Aperture Permission List, for 32-byte IPI buffer 117 at BASE_32B + 0x00000EA0
(OFFSET, MASK, VALUE) (0XFF9815D4, 0xF80FFFFFU ,0x08000012U)
RegMask = (LPD_XPPU_CFG_APERPERM_373_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_373_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_373_PARITY_MASK | 0 );
RegVal = ((0x00000012U << LPD_XPPU_CFG_APERPERM_373_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_373_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_373_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_373_OFFSET ,0xF80FFFFFU ,0x08000012U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_374 @ 0XFF9815D8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_374_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_374_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_374_PARITY 0x0
Entry 374 of the Aperture Permission List, for 32-byte IPI buffer 118 at BASE_32B + 0x00000EC0
(OFFSET, MASK, VALUE) (0XFF9815D8, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_374_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_374_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_374_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_374_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_374_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_374_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_374_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_375 @ 0XFF9815DC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_375_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_375_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_375_PARITY 0x0
Entry 375 of the Aperture Permission List, for 32-byte IPI buffer 119 at BASE_32B + 0x00000EE0
(OFFSET, MASK, VALUE) (0XFF9815DC, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_375_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_375_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_375_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_375_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_375_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_375_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_375_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_376 @ 0XFF9815E0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_376_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_376_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_376_PARITY 0x0
Entry 376 of the Aperture Permission List, for 32-byte IPI buffer 120 at BASE_32B + 0x00000F00
(OFFSET, MASK, VALUE) (0XFF9815E0, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_376_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_376_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_376_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_376_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_376_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_376_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_376_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_377 @ 0XFF9815E4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_377_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_377_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_377_PARITY 0x0
Entry 377 of the Aperture Permission List, for 32-byte IPI buffer 121 at BASE_32B + 0x00000F20
(OFFSET, MASK, VALUE) (0XFF9815E4, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_377_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_377_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_377_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_377_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_377_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_377_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_377_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_378 @ 0XFF9815E8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_378_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_378_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_378_PARITY 0x0
Entry 378 of the Aperture Permission List, for 32-byte IPI buffer 122 at BASE_32B + 0x00000F40
(OFFSET, MASK, VALUE) (0XFF9815E8, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_378_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_378_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_378_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_378_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_378_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_378_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_378_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_379 @ 0XFF9815EC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_379_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_379_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_379_PARITY 0x0
Entry 379 of the Aperture Permission List, for 32-byte IPI buffer 123 at BASE_32B + 0x00000F60
(OFFSET, MASK, VALUE) (0XFF9815EC, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_379_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_379_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_379_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_379_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_379_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_379_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_379_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_380 @ 0XFF9815F0</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_380_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_380_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_380_PARITY 0x0
Entry 380 of the Aperture Permission List, for 32-byte IPI buffer 124 at BASE_32B + 0x00000F80
(OFFSET, MASK, VALUE) (0XFF9815F0, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_380_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_380_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_380_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_380_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_380_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_380_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_380_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_381 @ 0XFF9815F4</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_381_PERMISSION 0x2
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_381_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_381_PARITY 0x0
Entry 381 of the Aperture Permission List, for 32-byte IPI buffer 125 at BASE_32B + 0x00000FA0
(OFFSET, MASK, VALUE) (0XFF9815F4, 0xF80FFFFFU ,0x08000002U)
RegMask = (LPD_XPPU_CFG_APERPERM_381_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_381_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_381_PARITY_MASK | 0 );
RegVal = ((0x00000002U << LPD_XPPU_CFG_APERPERM_381_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_381_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_381_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_381_OFFSET ,0xF80FFFFFU ,0x08000002U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_382 @ 0XFF9815F8</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_382_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_382_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_382_PARITY 0x0
Entry 382 of the Aperture Permission List, for 32-byte IPI buffer 126 at BASE_32B + 0x00000FC0
(OFFSET, MASK, VALUE) (0XFF9815F8, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_382_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_382_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_382_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_382_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_382_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_382_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_382_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IPI_PMU, START ADDRESS: FF330000, END ADDRESS: FF33FFFF
/*Register : APERPERM_383 @ 0XFF9815FC</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_383_PERMISSION 0x20
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_383_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_383_PARITY 0x0
Entry 383 of the Aperture Permission List, for 32-byte IPI buffer 127 at BASE_32B + 0x00000FE0
(OFFSET, MASK, VALUE) (0XFF9815FC, 0xF80FFFFFU ,0x08000020U)
RegMask = (LPD_XPPU_CFG_APERPERM_383_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_383_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_383_PARITY_MASK | 0 );
RegVal = ((0x00000020U << LPD_XPPU_CFG_APERPERM_383_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_383_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_383_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_383_OFFSET ,0xF80FFFFFU ,0x08000020U);
/*############################################################################################################################ */
// : APERTURE NAME: IOU_GPV, START ADDRESS: FE000000, END ADDRESS: FE0FFFFF
// : APERTURE NAME: LPD_GPV, START ADDRESS: FE100000, END ADDRESS: FE1FFFFF
// : APERTURE NAME: USB3_0_XHCI, START ADDRESS: FE200000, END ADDRESS: FE2FFFFF
// : APERTURE NAME: USB3_1_XHCI, START ADDRESS: FE300000, END ADDRESS: FE3FFFFF
// : APERTURE NAME: LPD_UNUSED_13, START ADDRESS: FE400000, END ADDRESS: FE7FFFFF
// : APERTURE NAME: LPD_UNUSED_13, START ADDRESS: FE400000, END ADDRESS: FE7FFFFF
// : APERTURE NAME: LPD_UNUSED_13, START ADDRESS: FE400000, END ADDRESS: FE7FFFFF
// : APERTURE NAME: LPD_UNUSED_13, START ADDRESS: FE400000, END ADDRESS: FE7FFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: CORESIGHT, START ADDRESS: FE800000, END ADDRESS: FEFFFFFF
// : APERTURE NAME: QSPI_LINEAR_ADDRESS, START ADDRESS: C0000000, END ADDRESS: DFFFFFFF
// : XPPU CONTROL
/*Register : err_ctrl @ 0XFF9CFFEC</p>
Whether an APB access to the "hole" region and to an unimplemented register space causes PSLVERR
PSU_LPD_XPPU_SINK_ERR_CTRL_PSLVERR 1
Error control register
(OFFSET, MASK, VALUE) (0XFF9CFFEC, 0x00000001U ,0x00000001U)
RegMask = (LPD_XPPU_SINK_ERR_CTRL_PSLVERR_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_SINK_ERR_CTRL_PSLVERR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_SINK_ERR_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : CTRL @ 0XFF980000</p>
0=Bypass XPPU (transparent) 1=Enable XPPU permission checking
PSU_LPD_XPPU_CFG_CTRL_ENABLE 1
XPPU Control Register
(OFFSET, MASK, VALUE) (0XFF980000, 0x00000001U ,0x00000001U)
RegMask = (LPD_XPPU_CFG_CTRL_ENABLE_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_CTRL_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_CTRL_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : XPPU INTERRUPT ENABLE
/*Register : IEN @ 0XFF980018</p>
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_APER_PARITY 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_APER_TZ 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_APER_PERM 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_MID_PARITY 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_MID_RO 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_MID_MISS 0X1
See Interuppt Status Register for details
PSU_LPD_XPPU_CFG_IEN_INV_APB 0X1
Interrupt Enable Register
(OFFSET, MASK, VALUE) (0XFF980018, 0x000000EFU ,0x000000EFU)
RegMask = (LPD_XPPU_CFG_IEN_APER_PARITY_MASK | LPD_XPPU_CFG_IEN_APER_TZ_MASK | LPD_XPPU_CFG_IEN_APER_PERM_MASK | LPD_XPPU_CFG_IEN_MID_PARITY_MASK | LPD_XPPU_CFG_IEN_MID_RO_MASK | LPD_XPPU_CFG_IEN_MID_MISS_MASK | LPD_XPPU_CFG_IEN_INV_APB_MASK | 0 );
RegVal = ((0x00000001U << LPD_XPPU_CFG_IEN_APER_PARITY_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_APER_TZ_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_APER_PERM_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_MID_PARITY_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_MID_RO_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_MID_MISS_SHIFT
| 0x00000001U << LPD_XPPU_CFG_IEN_INV_APB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_IEN_OFFSET ,0x000000EFU ,0x000000EFU);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_ddr_xmpu0_data() {
// : DDR XMPU0
return 1;
}
unsigned long psu_ddr_xmpu1_data() {
// : DDR XMPU1
return 1;
}
unsigned long psu_ddr_xmpu2_data() {
// : DDR XMPU2
return 1;
}
unsigned long psu_ddr_xmpu3_data() {
// : DDR XMPU3
return 1;
}
unsigned long psu_ddr_xmpu4_data() {
// : DDR XMPU4
return 1;
}
unsigned long psu_ddr_xmpu5_data() {
// : DDR XMPU5
return 1;
}
unsigned long psu_ocm_xmpu_data() {
// : OCM XMPU
return 1;
}
unsigned long psu_fpd_xmpu_data() {
// : FPD XMPU
return 1;
}
unsigned long psu_protection_lock_data() {
// : LOCKING PROTECTION MODULE
// : XPPU LOCK
// : APERTURE NAME: LPD_XPPU, START ADDRESS: FF980000, END ADDRESS: FF99FFFF
/*Register : APERPERM_152 @ 0XFF981260</p>
This field defines the MASTER ID match criteria. Each entry in the IDL corresponds to a bit in this field. 0=not match, 1=mat
h.
PSU_LPD_XPPU_CFG_APERPERM_152_PERMISSION 0x0
1=secure or non-secure transactions are allowed 0=only secure transactiona are allowed
PSU_LPD_XPPU_CFG_APERPERM_152_TRUSTZONE 0x1
SW must calculate and set up parity, if parity check is enabled by the CTRL register. 31: parity for bits 19:15 30: parity fo
bits 14:10 29: parity for bits 9:5 28: parity for bits 27, 4:0
PSU_LPD_XPPU_CFG_APERPERM_152_PARITY 0x0
Entry 152 of the Aperture Permission List, for the 64K-byte aperture at BASE_64KB + 0x00980000
(OFFSET, MASK, VALUE) (0XFF981260, 0xF80FFFFFU ,0x08000000U)
RegMask = (LPD_XPPU_CFG_APERPERM_152_PERMISSION_MASK | LPD_XPPU_CFG_APERPERM_152_TRUSTZONE_MASK | LPD_XPPU_CFG_APERPERM_152_PARITY_MASK | 0 );
RegVal = ((0x00000000U << LPD_XPPU_CFG_APERPERM_152_PERMISSION_SHIFT
| 0x00000001U << LPD_XPPU_CFG_APERPERM_152_TRUSTZONE_SHIFT
| 0x00000000U << LPD_XPPU_CFG_APERPERM_152_PARITY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_XPPU_CFG_APERPERM_152_OFFSET ,0xF80FFFFFU ,0x08000000U);
/*############################################################################################################################ */
// : XMPU LOCK
return 1;
}
unsigned long psu_apply_master_tz() {
// : RPU
// : DP TZ
// : SATA TZ
// : PCIE TZ
// : USB TZ
// : SD TZ
// : GEM TZ
// : QSPI TZ
// : NAND TZ
return 1;
}
unsigned long psu_serdes_init_data() {
// : SERDES INITIALIZATION
// : GT REFERENCE CLOCK SOURCE SELECTION
/*Register : PLL_REF_SEL0 @ 0XFD410000</p>
PLL0 Reference Selection. 0x0 - 5MHz, 0x1 - 9.6MHz, 0x2 - 10MHz, 0x3 - 12MHz, 0x4 - 13MHz, 0x5 - 19.2MHz, 0x6 - 20MHz, 0x7 -
4MHz, 0x8 - 26MHz, 0x9 - 27MHz, 0xA - 38.4MHz, 0xB - 40MHz, 0xC - 52MHz, 0xD - 100MHz, 0xE - 108MHz, 0xF - 125MHz, 0x10 - 135
Hz, 0x11 - 150 MHz. 0x12 to 0x1F - Reserved
PSU_SERDES_PLL_REF_SEL0_PLLREFSEL0 0x9
PLL0 Reference Selection Register
(OFFSET, MASK, VALUE) (0XFD410000, 0x0000001FU ,0x00000009U)
RegMask = (SERDES_PLL_REF_SEL0_PLLREFSEL0_MASK | 0 );
RegVal = ((0x00000009U << SERDES_PLL_REF_SEL0_PLLREFSEL0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_PLL_REF_SEL0_OFFSET ,0x0000001FU ,0x00000009U);
/*############################################################################################################################ */
/*Register : PLL_REF_SEL1 @ 0XFD410004</p>
PLL1 Reference Selection. 0x0 - 5MHz, 0x1 - 9.6MHz, 0x2 - 10MHz, 0x3 - 12MHz, 0x4 - 13MHz, 0x5 - 19.2MHz, 0x6 - 20MHz, 0x7 -
4MHz, 0x8 - 26MHz, 0x9 - 27MHz, 0xA - 38.4MHz, 0xB - 40MHz, 0xC - 52MHz, 0xD - 100MHz, 0xE - 108MHz, 0xF - 125MHz, 0x10 - 135
Hz, 0x11 - 150 MHz. 0x12 to 0x1F - Reserved
PSU_SERDES_PLL_REF_SEL1_PLLREFSEL1 0x9
PLL1 Reference Selection Register
(OFFSET, MASK, VALUE) (0XFD410004, 0x0000001FU ,0x00000009U)
RegMask = (SERDES_PLL_REF_SEL1_PLLREFSEL1_MASK | 0 );
RegVal = ((0x00000009U << SERDES_PLL_REF_SEL1_PLLREFSEL1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_PLL_REF_SEL1_OFFSET ,0x0000001FU ,0x00000009U);
/*############################################################################################################################ */
/*Register : PLL_REF_SEL2 @ 0XFD410008</p>
PLL2 Reference Selection. 0x0 - 5MHz, 0x1 - 9.6MHz, 0x2 - 10MHz, 0x3 - 12MHz, 0x4 - 13MHz, 0x5 - 19.2MHz, 0x6 - 20MHz, 0x7 -
4MHz, 0x8 - 26MHz, 0x9 - 27MHz, 0xA - 38.4MHz, 0xB - 40MHz, 0xC - 52MHz, 0xD - 100MHz, 0xE - 108MHz, 0xF - 125MHz, 0x10 - 135
Hz, 0x11 - 150 MHz. 0x12 to 0x1F - Reserved
PSU_SERDES_PLL_REF_SEL2_PLLREFSEL2 0x8
PLL2 Reference Selection Register
(OFFSET, MASK, VALUE) (0XFD410008, 0x0000001FU ,0x00000008U)
RegMask = (SERDES_PLL_REF_SEL2_PLLREFSEL2_MASK | 0 );
RegVal = ((0x00000008U << SERDES_PLL_REF_SEL2_PLLREFSEL2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_PLL_REF_SEL2_OFFSET ,0x0000001FU ,0x00000008U);
/*############################################################################################################################ */
/*Register : PLL_REF_SEL3 @ 0XFD41000C</p>
PLL3 Reference Selection. 0x0 - 5MHz, 0x1 - 9.6MHz, 0x2 - 10MHz, 0x3 - 12MHz, 0x4 - 13MHz, 0x5 - 19.2MHz, 0x6 - 20MHz, 0x7 -
4MHz, 0x8 - 26MHz, 0x9 - 27MHz, 0xA - 38.4MHz, 0xB - 40MHz, 0xC - 52MHz, 0xD - 100MHz, 0xE - 108MHz, 0xF - 125MHz, 0x10 - 135
Hz, 0x11 - 150 MHz. 0x12 to 0x1F - Reserved
PSU_SERDES_PLL_REF_SEL3_PLLREFSEL3 0xF
PLL3 Reference Selection Register
(OFFSET, MASK, VALUE) (0XFD41000C, 0x0000001FU ,0x0000000FU)
RegMask = (SERDES_PLL_REF_SEL3_PLLREFSEL3_MASK | 0 );
RegVal = ((0x0000000FU << SERDES_PLL_REF_SEL3_PLLREFSEL3_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_PLL_REF_SEL3_OFFSET ,0x0000001FU ,0x0000000FU);
/*############################################################################################################################ */
// : GT REFERENCE CLOCK FREQUENCY SELECTION
/*Register : L0_L0_REF_CLK_SEL @ 0XFD402860</p>
Sel of lane 0 ref clock local mux. Set to 1 to select lane 0 slicer output. Set to 0 to select lane0 ref clock mux output.
PSU_SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_LCL_SEL 0x0
Bit 3 of lane 0 ref clock mux one hot sel. Set to 1 to select lane 3 slicer output from ref clock network
PSU_SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_SEL_3 0x1
Lane0 Ref Clock Selection Register
(OFFSET, MASK, VALUE) (0XFD402860, 0x00000088U ,0x00000008U)
RegMask = (SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_LCL_SEL_MASK | SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_SEL_3_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_LCL_SEL_SHIFT
| 0x00000001U << SERDES_L0_L0_REF_CLK_SEL_L0_REF_CLK_SEL_3_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_L0_REF_CLK_SEL_OFFSET ,0x00000088U ,0x00000008U);
/*############################################################################################################################ */
/*Register : L0_L1_REF_CLK_SEL @ 0XFD402864</p>
Sel of lane 1 ref clock local mux. Set to 1 to select lane 1 slicer output. Set to 0 to select lane1 ref clock mux output.
PSU_SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_LCL_SEL 0x0
Bit 3 of lane 1 ref clock mux one hot sel. Set to 1 to select lane 3 slicer output from ref clock network
PSU_SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_SEL_3 0x1
Lane1 Ref Clock Selection Register
(OFFSET, MASK, VALUE) (0XFD402864, 0x00000088U ,0x00000008U)
RegMask = (SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_LCL_SEL_MASK | SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_SEL_3_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_LCL_SEL_SHIFT
| 0x00000001U << SERDES_L0_L1_REF_CLK_SEL_L1_REF_CLK_SEL_3_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_L1_REF_CLK_SEL_OFFSET ,0x00000088U ,0x00000008U);
/*############################################################################################################################ */
/*Register : L0_L2_REF_CLK_SEL @ 0XFD402868</p>
Sel of lane 2 ref clock local mux. Set to 1 to select lane 1 slicer output. Set to 0 to select lane2 ref clock mux output.
PSU_SERDES_L0_L2_REF_CLK_SEL_L2_REF_CLK_LCL_SEL 0x1
Lane2 Ref Clock Selection Register
(OFFSET, MASK, VALUE) (0XFD402868, 0x00000080U ,0x00000080U)
RegMask = (SERDES_L0_L2_REF_CLK_SEL_L2_REF_CLK_LCL_SEL_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_L2_REF_CLK_SEL_L2_REF_CLK_LCL_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_L2_REF_CLK_SEL_OFFSET ,0x00000080U ,0x00000080U);
/*############################################################################################################################ */
/*Register : L0_L3_REF_CLK_SEL @ 0XFD40286C</p>
Sel of lane 3 ref clock local mux. Set to 1 to select lane 3 slicer output. Set to 0 to select lane3 ref clock mux output.
PSU_SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_LCL_SEL 0x0
Bit 1 of lane 3 ref clock mux one hot sel. Set to 1 to select lane 1 slicer output from ref clock network
PSU_SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_SEL_1 0x1
Lane3 Ref Clock Selection Register
(OFFSET, MASK, VALUE) (0XFD40286C, 0x00000082U ,0x00000002U)
RegMask = (SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_LCL_SEL_MASK | SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_SEL_1_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_LCL_SEL_SHIFT
| 0x00000001U << SERDES_L0_L3_REF_CLK_SEL_L3_REF_CLK_SEL_1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_L3_REF_CLK_SEL_OFFSET ,0x00000082U ,0x00000002U);
/*############################################################################################################################ */
// : ENABLE SPREAD SPECTRUM
/*Register : L2_TM_PLL_DIG_37 @ 0XFD40A094</p>
Enable/Disable coarse code satureation limiting logic
PSU_SERDES_L2_TM_PLL_DIG_37_TM_ENABLE_COARSE_SATURATION 0x1
Test mode register 37
(OFFSET, MASK, VALUE) (0XFD40A094, 0x00000010U ,0x00000010U)
RegMask = (SERDES_L2_TM_PLL_DIG_37_TM_ENABLE_COARSE_SATURATION_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_PLL_DIG_37_TM_ENABLE_COARSE_SATURATION_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_PLL_DIG_37_OFFSET ,0x00000010U ,0x00000010U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEPS_0_LSB @ 0XFD40A368</p>
Spread Spectrum No of Steps [7:0]
PSU_SERDES_L2_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB 0x38
Spread Spectrum No of Steps bits 7:0
(OFFSET, MASK, VALUE) (0XFD40A368, 0x000000FFU ,0x00000038U)
RegMask = (SERDES_L2_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_MASK | 0 );
RegVal = ((0x00000038U << SERDES_L2_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEPS_0_LSB_OFFSET ,0x000000FFU ,0x00000038U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEPS_1_MSB @ 0XFD40A36C</p>
Spread Spectrum No of Steps [10:8]
PSU_SERDES_L2_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB 0x03
Spread Spectrum No of Steps bits 10:8
(OFFSET, MASK, VALUE) (0XFD40A36C, 0x00000007U ,0x00000003U)
RegMask = (SERDES_L2_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_MASK | 0 );
RegVal = ((0x00000003U << SERDES_L2_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEPS_1_MSB_OFFSET ,0x00000007U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEPS_0_LSB @ 0XFD40E368</p>
Spread Spectrum No of Steps [7:0]
PSU_SERDES_L3_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB 0xE0
Spread Spectrum No of Steps bits 7:0
(OFFSET, MASK, VALUE) (0XFD40E368, 0x000000FFU ,0x000000E0U)
RegMask = (SERDES_L3_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_MASK | 0 );
RegVal = ((0x000000E0U << SERDES_L3_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEPS_0_LSB_OFFSET ,0x000000FFU ,0x000000E0U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEPS_1_MSB @ 0XFD40E36C</p>
Spread Spectrum No of Steps [10:8]
PSU_SERDES_L3_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB 0x3
Spread Spectrum No of Steps bits 10:8
(OFFSET, MASK, VALUE) (0XFD40E36C, 0x00000007U ,0x00000003U)
RegMask = (SERDES_L3_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_MASK | 0 );
RegVal = ((0x00000003U << SERDES_L3_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEPS_1_MSB_OFFSET ,0x00000007U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEPS_0_LSB @ 0XFD402368</p>
Spread Spectrum No of Steps [7:0]
PSU_SERDES_L0_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB 0x58
Spread Spectrum No of Steps bits 7:0
(OFFSET, MASK, VALUE) (0XFD402368, 0x000000FFU ,0x00000058U)
RegMask = (SERDES_L0_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_MASK | 0 );
RegVal = ((0x00000058U << SERDES_L0_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEPS_0_LSB_OFFSET ,0x000000FFU ,0x00000058U);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEPS_1_MSB @ 0XFD40236C</p>
Spread Spectrum No of Steps [10:8]
PSU_SERDES_L0_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB 0x3
Spread Spectrum No of Steps bits 10:8
(OFFSET, MASK, VALUE) (0XFD40236C, 0x00000007U ,0x00000003U)
RegMask = (SERDES_L0_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_MASK | 0 );
RegVal = ((0x00000003U << SERDES_L0_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEPS_1_MSB_OFFSET ,0x00000007U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEPS_0_LSB @ 0XFD406368</p>
Spread Spectrum No of Steps [7:0]
PSU_SERDES_L1_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB 0x58
Spread Spectrum No of Steps bits 7:0
(OFFSET, MASK, VALUE) (0XFD406368, 0x000000FFU ,0x00000058U)
RegMask = (SERDES_L1_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_MASK | 0 );
RegVal = ((0x00000058U << SERDES_L1_PLL_SS_STEPS_0_LSB_SS_NUM_OF_STEPS_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEPS_0_LSB_OFFSET ,0x000000FFU ,0x00000058U);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEPS_1_MSB @ 0XFD40636C</p>
Spread Spectrum No of Steps [10:8]
PSU_SERDES_L1_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB 0x3
Spread Spectrum No of Steps bits 10:8
(OFFSET, MASK, VALUE) (0XFD40636C, 0x00000007U ,0x00000003U)
RegMask = (SERDES_L1_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_MASK | 0 );
RegVal = ((0x00000003U << SERDES_L1_PLL_SS_STEPS_1_MSB_SS_NUM_OF_STEPS_1_MSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEPS_1_MSB_OFFSET ,0x00000007U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEP_SIZE_0_LSB @ 0XFD402370</p>
Step Size for Spread Spectrum [7:0]
PSU_SERDES_L0_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB 0x7C
Step Size for Spread Spectrum LSB
(OFFSET, MASK, VALUE) (0XFD402370, 0x000000FFU ,0x0000007CU)
RegMask = (SERDES_L0_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_MASK | 0 );
RegVal = ((0x0000007CU << SERDES_L0_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEP_SIZE_0_LSB_OFFSET ,0x000000FFU ,0x0000007CU);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEP_SIZE_1 @ 0XFD402374</p>
Step Size for Spread Spectrum [15:8]
PSU_SERDES_L0_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1 0x33
Step Size for Spread Spectrum 1
(OFFSET, MASK, VALUE) (0XFD402374, 0x000000FFU ,0x00000033U)
RegMask = (SERDES_L0_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_MASK | 0 );
RegVal = ((0x00000033U << SERDES_L0_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEP_SIZE_1_OFFSET ,0x000000FFU ,0x00000033U);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEP_SIZE_2 @ 0XFD402378</p>
Step Size for Spread Spectrum [23:16]
PSU_SERDES_L0_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2 0x2
Step Size for Spread Spectrum 2
(OFFSET, MASK, VALUE) (0XFD402378, 0x000000FFU ,0x00000002U)
RegMask = (SERDES_L0_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_MASK | 0 );
RegVal = ((0x00000002U << SERDES_L0_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEP_SIZE_2_OFFSET ,0x000000FFU ,0x00000002U);
/*############################################################################################################################ */
/*Register : L0_PLL_SS_STEP_SIZE_3_MSB @ 0XFD40237C</p>
Step Size for Spread Spectrum [25:24]
PSU_SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB 0x0
Enable/Disable test mode force on SS step size
PSU_SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE 0x1
Enable/Disable test mode force on SS no of steps
PSU_SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS 0x1
Enable force on enable Spread Spectrum
(OFFSET, MASK, VALUE) (0XFD40237C, 0x00000033U ,0x00000030U)
RegMask = (SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_MASK | SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_MASK | SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_SHIFT
| 0x00000001U << SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_SHIFT
| 0x00000001U << SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_PLL_SS_STEP_SIZE_3_MSB_OFFSET ,0x00000033U ,0x00000030U);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEP_SIZE_0_LSB @ 0XFD406370</p>
Step Size for Spread Spectrum [7:0]
PSU_SERDES_L1_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB 0x7C
Step Size for Spread Spectrum LSB
(OFFSET, MASK, VALUE) (0XFD406370, 0x000000FFU ,0x0000007CU)
RegMask = (SERDES_L1_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_MASK | 0 );
RegVal = ((0x0000007CU << SERDES_L1_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEP_SIZE_0_LSB_OFFSET ,0x000000FFU ,0x0000007CU);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEP_SIZE_1 @ 0XFD406374</p>
Step Size for Spread Spectrum [15:8]
PSU_SERDES_L1_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1 0x33
Step Size for Spread Spectrum 1
(OFFSET, MASK, VALUE) (0XFD406374, 0x000000FFU ,0x00000033U)
RegMask = (SERDES_L1_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_MASK | 0 );
RegVal = ((0x00000033U << SERDES_L1_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEP_SIZE_1_OFFSET ,0x000000FFU ,0x00000033U);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEP_SIZE_2 @ 0XFD406378</p>
Step Size for Spread Spectrum [23:16]
PSU_SERDES_L1_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2 0x2
Step Size for Spread Spectrum 2
(OFFSET, MASK, VALUE) (0XFD406378, 0x000000FFU ,0x00000002U)
RegMask = (SERDES_L1_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_MASK | 0 );
RegVal = ((0x00000002U << SERDES_L1_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEP_SIZE_2_OFFSET ,0x000000FFU ,0x00000002U);
/*############################################################################################################################ */
/*Register : L1_PLL_SS_STEP_SIZE_3_MSB @ 0XFD40637C</p>
Step Size for Spread Spectrum [25:24]
PSU_SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB 0x0
Enable/Disable test mode force on SS step size
PSU_SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE 0x1
Enable/Disable test mode force on SS no of steps
PSU_SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS 0x1
Enable force on enable Spread Spectrum
(OFFSET, MASK, VALUE) (0XFD40637C, 0x00000033U ,0x00000030U)
RegMask = (SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_MASK | SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_MASK | SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_SHIFT
| 0x00000001U << SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_SHIFT
| 0x00000001U << SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_PLL_SS_STEP_SIZE_3_MSB_OFFSET ,0x00000033U ,0x00000030U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEP_SIZE_0_LSB @ 0XFD40A370</p>
Step Size for Spread Spectrum [7:0]
PSU_SERDES_L2_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB 0xF4
Step Size for Spread Spectrum LSB
(OFFSET, MASK, VALUE) (0XFD40A370, 0x000000FFU ,0x000000F4U)
RegMask = (SERDES_L2_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_MASK | 0 );
RegVal = ((0x000000F4U << SERDES_L2_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEP_SIZE_0_LSB_OFFSET ,0x000000FFU ,0x000000F4U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEP_SIZE_1 @ 0XFD40A374</p>
Step Size for Spread Spectrum [15:8]
PSU_SERDES_L2_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1 0x31
Step Size for Spread Spectrum 1
(OFFSET, MASK, VALUE) (0XFD40A374, 0x000000FFU ,0x00000031U)
RegMask = (SERDES_L2_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_MASK | 0 );
RegVal = ((0x00000031U << SERDES_L2_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEP_SIZE_1_OFFSET ,0x000000FFU ,0x00000031U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEP_SIZE_2 @ 0XFD40A378</p>
Step Size for Spread Spectrum [23:16]
PSU_SERDES_L2_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2 0x2
Step Size for Spread Spectrum 2
(OFFSET, MASK, VALUE) (0XFD40A378, 0x000000FFU ,0x00000002U)
RegMask = (SERDES_L2_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_MASK | 0 );
RegVal = ((0x00000002U << SERDES_L2_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEP_SIZE_2_OFFSET ,0x000000FFU ,0x00000002U);
/*############################################################################################################################ */
/*Register : L2_PLL_SS_STEP_SIZE_3_MSB @ 0XFD40A37C</p>
Step Size for Spread Spectrum [25:24]
PSU_SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB 0x0
Enable/Disable test mode force on SS step size
PSU_SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE 0x1
Enable/Disable test mode force on SS no of steps
PSU_SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS 0x1
Enable force on enable Spread Spectrum
(OFFSET, MASK, VALUE) (0XFD40A37C, 0x00000033U ,0x00000030U)
RegMask = (SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_MASK | SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_MASK | SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_SHIFT
| 0x00000001U << SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_SHIFT
| 0x00000001U << SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_PLL_SS_STEP_SIZE_3_MSB_OFFSET ,0x00000033U ,0x00000030U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEP_SIZE_0_LSB @ 0XFD40E370</p>
Step Size for Spread Spectrum [7:0]
PSU_SERDES_L3_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB 0xC9
Step Size for Spread Spectrum LSB
(OFFSET, MASK, VALUE) (0XFD40E370, 0x000000FFU ,0x000000C9U)
RegMask = (SERDES_L3_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_MASK | 0 );
RegVal = ((0x000000C9U << SERDES_L3_PLL_SS_STEP_SIZE_0_LSB_SS_STEP_SIZE_0_LSB_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEP_SIZE_0_LSB_OFFSET ,0x000000FFU ,0x000000C9U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEP_SIZE_1 @ 0XFD40E374</p>
Step Size for Spread Spectrum [15:8]
PSU_SERDES_L3_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1 0xD2
Step Size for Spread Spectrum 1
(OFFSET, MASK, VALUE) (0XFD40E374, 0x000000FFU ,0x000000D2U)
RegMask = (SERDES_L3_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_MASK | 0 );
RegVal = ((0x000000D2U << SERDES_L3_PLL_SS_STEP_SIZE_1_SS_STEP_SIZE_1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEP_SIZE_1_OFFSET ,0x000000FFU ,0x000000D2U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEP_SIZE_2 @ 0XFD40E378</p>
Step Size for Spread Spectrum [23:16]
PSU_SERDES_L3_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2 0x1
Step Size for Spread Spectrum 2
(OFFSET, MASK, VALUE) (0XFD40E378, 0x000000FFU ,0x00000001U)
RegMask = (SERDES_L3_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_PLL_SS_STEP_SIZE_2_SS_STEP_SIZE_2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEP_SIZE_2_OFFSET ,0x000000FFU ,0x00000001U);
/*############################################################################################################################ */
/*Register : L3_PLL_SS_STEP_SIZE_3_MSB @ 0XFD40E37C</p>
Step Size for Spread Spectrum [25:24]
PSU_SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB 0x0
Enable/Disable test mode force on SS step size
PSU_SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE 0x1
Enable/Disable test mode force on SS no of steps
PSU_SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS 0x1
Enable test mode forcing on enable Spread Spectrum
PSU_SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_TM_FORCE_EN_SS 0x1
Enable force on enable Spread Spectrum
(OFFSET, MASK, VALUE) (0XFD40E37C, 0x000000B3U ,0x000000B0U)
RegMask = (SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_MASK | SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_MASK | SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_MASK | SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_TM_FORCE_EN_SS_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_SS_STEP_SIZE_3_MSB_SHIFT
| 0x00000001U << SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_STEP_SIZE_SHIFT
| 0x00000001U << SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_FORCE_SS_NUM_OF_STEPS_SHIFT
| 0x00000001U << SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_TM_FORCE_EN_SS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_SS_STEP_SIZE_3_MSB_OFFSET ,0x000000B3U ,0x000000B0U);
/*############################################################################################################################ */
/*Register : L2_TM_DIG_6 @ 0XFD40906C</p>
Bypass Descrambler
PSU_SERDES_L2_TM_DIG_6_BYPASS_DESCRAM 0x1
Enable Bypass for <1> TM_DIG_CTRL_6
PSU_SERDES_L2_TM_DIG_6_FORCE_BYPASS_DESCRAM 0x1
Data path test modes in decoder and descram
(OFFSET, MASK, VALUE) (0XFD40906C, 0x00000003U ,0x00000003U)
RegMask = (SERDES_L2_TM_DIG_6_BYPASS_DESCRAM_MASK | SERDES_L2_TM_DIG_6_FORCE_BYPASS_DESCRAM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_DIG_6_BYPASS_DESCRAM_SHIFT
| 0x00000001U << SERDES_L2_TM_DIG_6_FORCE_BYPASS_DESCRAM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_DIG_6_OFFSET ,0x00000003U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L2_TX_DIG_TM_61 @ 0XFD4080F4</p>
Bypass scrambler signal
PSU_SERDES_L2_TX_DIG_TM_61_BYPASS_SCRAM 0x1
Enable/disable scrambler bypass signal
PSU_SERDES_L2_TX_DIG_TM_61_FORCE_BYPASS_SCRAM 0x1
MPHY PLL Gear and bypass scrambler
(OFFSET, MASK, VALUE) (0XFD4080F4, 0x00000003U ,0x00000003U)
RegMask = (SERDES_L2_TX_DIG_TM_61_BYPASS_SCRAM_MASK | SERDES_L2_TX_DIG_TM_61_FORCE_BYPASS_SCRAM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TX_DIG_TM_61_BYPASS_SCRAM_SHIFT
| 0x00000001U << SERDES_L2_TX_DIG_TM_61_FORCE_BYPASS_SCRAM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TX_DIG_TM_61_OFFSET ,0x00000003U ,0x00000003U);
/*############################################################################################################################ */
/*Register : L3_PLL_FBDIV_FRAC_3_MSB @ 0XFD40E360</p>
Enable test mode force on fractional mode enable
PSU_SERDES_L3_PLL_FBDIV_FRAC_3_MSB_TM_FORCE_EN_FRAC 0x1
Fractional feedback division control and fractional value for feedback division bits 26:24
(OFFSET, MASK, VALUE) (0XFD40E360, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L3_PLL_FBDIV_FRAC_3_MSB_TM_FORCE_EN_FRAC_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_PLL_FBDIV_FRAC_3_MSB_TM_FORCE_EN_FRAC_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_PLL_FBDIV_FRAC_3_MSB_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L3_TM_DIG_6 @ 0XFD40D06C</p>
Bypass 8b10b decoder
PSU_SERDES_L3_TM_DIG_6_BYPASS_DECODER 0x1
Enable Bypass for <3> TM_DIG_CTRL_6
PSU_SERDES_L3_TM_DIG_6_FORCE_BYPASS_DEC 0x1
Bypass Descrambler
PSU_SERDES_L3_TM_DIG_6_BYPASS_DESCRAM 0x1
Enable Bypass for <1> TM_DIG_CTRL_6
PSU_SERDES_L3_TM_DIG_6_FORCE_BYPASS_DESCRAM 0x1
Data path test modes in decoder and descram
(OFFSET, MASK, VALUE) (0XFD40D06C, 0x0000000FU ,0x0000000FU)
RegMask = (SERDES_L3_TM_DIG_6_BYPASS_DECODER_MASK | SERDES_L3_TM_DIG_6_FORCE_BYPASS_DEC_MASK | SERDES_L3_TM_DIG_6_BYPASS_DESCRAM_MASK | SERDES_L3_TM_DIG_6_FORCE_BYPASS_DESCRAM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_DIG_6_BYPASS_DECODER_SHIFT
| 0x00000001U << SERDES_L3_TM_DIG_6_FORCE_BYPASS_DEC_SHIFT
| 0x00000001U << SERDES_L3_TM_DIG_6_BYPASS_DESCRAM_SHIFT
| 0x00000001U << SERDES_L3_TM_DIG_6_FORCE_BYPASS_DESCRAM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_DIG_6_OFFSET ,0x0000000FU ,0x0000000FU);
/*############################################################################################################################ */
/*Register : L3_TX_DIG_TM_61 @ 0XFD40C0F4</p>
Enable/disable encoder bypass signal
PSU_SERDES_L3_TX_DIG_TM_61_BYPASS_ENC 0x1
Bypass scrambler signal
PSU_SERDES_L3_TX_DIG_TM_61_BYPASS_SCRAM 0x1
Enable/disable scrambler bypass signal
PSU_SERDES_L3_TX_DIG_TM_61_FORCE_BYPASS_SCRAM 0x1
MPHY PLL Gear and bypass scrambler
(OFFSET, MASK, VALUE) (0XFD40C0F4, 0x0000000BU ,0x0000000BU)
RegMask = (SERDES_L3_TX_DIG_TM_61_BYPASS_ENC_MASK | SERDES_L3_TX_DIG_TM_61_BYPASS_SCRAM_MASK | SERDES_L3_TX_DIG_TM_61_FORCE_BYPASS_SCRAM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TX_DIG_TM_61_BYPASS_ENC_SHIFT
| 0x00000001U << SERDES_L3_TX_DIG_TM_61_BYPASS_SCRAM_SHIFT
| 0x00000001U << SERDES_L3_TX_DIG_TM_61_FORCE_BYPASS_SCRAM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TX_DIG_TM_61_OFFSET ,0x0000000BU ,0x0000000BU);
/*############################################################################################################################ */
/*Register : L3_TXPMA_ST_0 @ 0XFD40CB00</p>
PHY Mode: 4'b000 - PCIe, 4'b001 - USB3, 4'b0010 - SATA, 4'b0100 - SGMII, 4'b0101 - DP, 4'b1000 - MPHY
PSU_SERDES_L3_TXPMA_ST_0_TX_PHY_MODE 0x21
Opmode Info
(OFFSET, MASK, VALUE) (0XFD40CB00, 0x000000F0U ,0x000000F0U)
RegMask = (SERDES_L3_TXPMA_ST_0_TX_PHY_MODE_MASK | 0 );
RegVal = ((0x00000021U << SERDES_L3_TXPMA_ST_0_TX_PHY_MODE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TXPMA_ST_0_OFFSET ,0x000000F0U ,0x000000F0U);
/*############################################################################################################################ */
// : ENABLE CHICKEN BIT FOR PCIE AND USB
/*Register : L2_TM_AUX_0 @ 0XFD4090CC</p>
Spare- not used
PSU_SERDES_L2_TM_AUX_0_BIT_2 1
Spare registers
(OFFSET, MASK, VALUE) (0XFD4090CC, 0x00000020U ,0x00000020U)
RegMask = (SERDES_L2_TM_AUX_0_BIT_2_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_AUX_0_BIT_2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_AUX_0_OFFSET ,0x00000020U ,0x00000020U);
/*############################################################################################################################ */
// : ENABLING EYE SURF
/*Register : L0_TM_DIG_8 @ 0XFD401074</p>
Enable Eye Surf
PSU_SERDES_L0_TM_DIG_8_EYESURF_ENABLE 0x1
Test modes for Elastic buffer and enabling Eye Surf
(OFFSET, MASK, VALUE) (0XFD401074, 0x00000010U ,0x00000010U)
RegMask = (SERDES_L0_TM_DIG_8_EYESURF_ENABLE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_TM_DIG_8_EYESURF_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TM_DIG_8_OFFSET ,0x00000010U ,0x00000010U);
/*############################################################################################################################ */
/*Register : L1_TM_DIG_8 @ 0XFD405074</p>
Enable Eye Surf
PSU_SERDES_L1_TM_DIG_8_EYESURF_ENABLE 0x1
Test modes for Elastic buffer and enabling Eye Surf
(OFFSET, MASK, VALUE) (0XFD405074, 0x00000010U ,0x00000010U)
RegMask = (SERDES_L1_TM_DIG_8_EYESURF_ENABLE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L1_TM_DIG_8_EYESURF_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TM_DIG_8_OFFSET ,0x00000010U ,0x00000010U);
/*############################################################################################################################ */
/*Register : L2_TM_DIG_8 @ 0XFD409074</p>
Enable Eye Surf
PSU_SERDES_L2_TM_DIG_8_EYESURF_ENABLE 0x1
Test modes for Elastic buffer and enabling Eye Surf
(OFFSET, MASK, VALUE) (0XFD409074, 0x00000010U ,0x00000010U)
RegMask = (SERDES_L2_TM_DIG_8_EYESURF_ENABLE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_DIG_8_EYESURF_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_DIG_8_OFFSET ,0x00000010U ,0x00000010U);
/*############################################################################################################################ */
/*Register : L3_TM_DIG_8 @ 0XFD40D074</p>
Enable Eye Surf
PSU_SERDES_L3_TM_DIG_8_EYESURF_ENABLE 0x1
Test modes for Elastic buffer and enabling Eye Surf
(OFFSET, MASK, VALUE) (0XFD40D074, 0x00000010U ,0x00000010U)
RegMask = (SERDES_L3_TM_DIG_8_EYESURF_ENABLE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_DIG_8_EYESURF_ENABLE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_DIG_8_OFFSET ,0x00000010U ,0x00000010U);
/*############################################################################################################################ */
// : ILL SETTINGS FOR GAIN AND LOCK SETTINGS
/*Register : L2_TM_MISC2 @ 0XFD40989C</p>
ILL calib counts BYPASSED with calcode bits
PSU_SERDES_L2_TM_MISC2_ILL_CAL_BYPASS_COUNTS 0x1
sampler cal
(OFFSET, MASK, VALUE) (0XFD40989C, 0x00000080U ,0x00000080U)
RegMask = (SERDES_L2_TM_MISC2_ILL_CAL_BYPASS_COUNTS_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_MISC2_ILL_CAL_BYPASS_COUNTS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_MISC2_OFFSET ,0x00000080U ,0x00000080U);
/*############################################################################################################################ */
/*Register : L2_TM_IQ_ILL1 @ 0XFD4098F8</p>
IQ ILL F0 CALCODE bypass value. MPHY : G1a, PCIE : Gen 1, SATA : Gen1 , USB3 : SS
PSU_SERDES_L2_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0 0x1A
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD4098F8, 0x000000FFU ,0x0000001AU)
RegMask = (SERDES_L2_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0_MASK | 0 );
RegVal = ((0x0000001AU << SERDES_L2_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_IQ_ILL1_OFFSET ,0x000000FFU ,0x0000001AU);
/*############################################################################################################################ */
/*Register : L2_TM_IQ_ILL2 @ 0XFD4098FC</p>
IQ ILL F1 CALCODE bypass value. MPHY : G1b, PCIE : Gen2, SATA: Gen2
PSU_SERDES_L2_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1 0x1A
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD4098FC, 0x000000FFU ,0x0000001AU)
RegMask = (SERDES_L2_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1_MASK | 0 );
RegVal = ((0x0000001AU << SERDES_L2_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_IQ_ILL2_OFFSET ,0x000000FFU ,0x0000001AU);
/*############################################################################################################################ */
/*Register : L2_TM_ILL12 @ 0XFD409990</p>
G1A pll ctr bypass value
PSU_SERDES_L2_TM_ILL12_G1A_PLL_CTR_BYP_VAL 0x10
ill pll counter values
(OFFSET, MASK, VALUE) (0XFD409990, 0x000000FFU ,0x00000010U)
RegMask = (SERDES_L2_TM_ILL12_G1A_PLL_CTR_BYP_VAL_MASK | 0 );
RegVal = ((0x00000010U << SERDES_L2_TM_ILL12_G1A_PLL_CTR_BYP_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_ILL12_OFFSET ,0x000000FFU ,0x00000010U);
/*############################################################################################################################ */
/*Register : L2_TM_E_ILL1 @ 0XFD409924</p>
E ILL F0 CALCODE bypass value. MPHY : G1a, PCIE : Gen 1, SATA : Gen1 , USB3 : SS
PSU_SERDES_L2_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0 0xFE
epi cal code
(OFFSET, MASK, VALUE) (0XFD409924, 0x000000FFU ,0x000000FEU)
RegMask = (SERDES_L2_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0_MASK | 0 );
RegVal = ((0x000000FEU << SERDES_L2_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_E_ILL1_OFFSET ,0x000000FFU ,0x000000FEU);
/*############################################################################################################################ */
/*Register : L2_TM_E_ILL2 @ 0XFD409928</p>
E ILL F1 CALCODE bypass value. MPHY : G1b, PCIE : Gen2, SATA: Gen2
PSU_SERDES_L2_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1 0x0
epi cal code
(OFFSET, MASK, VALUE) (0XFD409928, 0x000000FFU ,0x00000000U)
RegMask = (SERDES_L2_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L2_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_E_ILL2_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L2_TM_IQ_ILL3 @ 0XFD409900</p>
IQ ILL F2CALCODE bypass value. MPHY : G2a, SATA : Gen3
PSU_SERDES_L2_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2 0x1A
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD409900, 0x000000FFU ,0x0000001AU)
RegMask = (SERDES_L2_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2_MASK | 0 );
RegVal = ((0x0000001AU << SERDES_L2_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_IQ_ILL3_OFFSET ,0x000000FFU ,0x0000001AU);
/*############################################################################################################################ */
/*Register : L2_TM_E_ILL3 @ 0XFD40992C</p>
E ILL F2CALCODE bypass value. MPHY : G2a, SATA : Gen3
PSU_SERDES_L2_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2 0x0
epi cal code
(OFFSET, MASK, VALUE) (0XFD40992C, 0x000000FFU ,0x00000000U)
RegMask = (SERDES_L2_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L2_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_E_ILL3_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L2_TM_ILL8 @ 0XFD409980</p>
ILL calibration code change wait time
PSU_SERDES_L2_TM_ILL8_ILL_CAL_ITER_WAIT 0xFF
ILL cal routine control
(OFFSET, MASK, VALUE) (0XFD409980, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L2_TM_ILL8_ILL_CAL_ITER_WAIT_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L2_TM_ILL8_ILL_CAL_ITER_WAIT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_ILL8_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L2_TM_IQ_ILL8 @ 0XFD409914</p>
IQ ILL polytrim bypass value
PSU_SERDES_L2_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL 0xF7
iqpi polytrim
(OFFSET, MASK, VALUE) (0XFD409914, 0x000000FFU ,0x000000F7U)
RegMask = (SERDES_L2_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL_MASK | 0 );
RegVal = ((0x000000F7U << SERDES_L2_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_IQ_ILL8_OFFSET ,0x000000FFU ,0x000000F7U);
/*############################################################################################################################ */
/*Register : L2_TM_IQ_ILL9 @ 0XFD409918</p>
bypass IQ polytrim
PSU_SERDES_L2_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM 0x1
enables for lf,constant gm trim and polytirm
(OFFSET, MASK, VALUE) (0XFD409918, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L2_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_IQ_ILL9_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : L2_TM_E_ILL8 @ 0XFD409940</p>
E ILL polytrim bypass value
PSU_SERDES_L2_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL 0xF7
epi polytrim
(OFFSET, MASK, VALUE) (0XFD409940, 0x000000FFU ,0x000000F7U)
RegMask = (SERDES_L2_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL_MASK | 0 );
RegVal = ((0x000000F7U << SERDES_L2_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_E_ILL8_OFFSET ,0x000000FFU ,0x000000F7U);
/*############################################################################################################################ */
/*Register : L2_TM_E_ILL9 @ 0XFD409944</p>
bypass E polytrim
PSU_SERDES_L2_TM_E_ILL9_ILL_BYPASS_E_POLYTIM 0x1
enables for lf,constant gm trim and polytirm
(OFFSET, MASK, VALUE) (0XFD409944, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L2_TM_E_ILL9_ILL_BYPASS_E_POLYTIM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_E_ILL9_ILL_BYPASS_E_POLYTIM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_E_ILL9_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : L3_TM_MISC2 @ 0XFD40D89C</p>
ILL calib counts BYPASSED with calcode bits
PSU_SERDES_L3_TM_MISC2_ILL_CAL_BYPASS_COUNTS 0x1
sampler cal
(OFFSET, MASK, VALUE) (0XFD40D89C, 0x00000080U ,0x00000080U)
RegMask = (SERDES_L3_TM_MISC2_ILL_CAL_BYPASS_COUNTS_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_MISC2_ILL_CAL_BYPASS_COUNTS_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_MISC2_OFFSET ,0x00000080U ,0x00000080U);
/*############################################################################################################################ */
/*Register : L3_TM_IQ_ILL1 @ 0XFD40D8F8</p>
IQ ILL F0 CALCODE bypass value. MPHY : G1a, PCIE : Gen 1, SATA : Gen1 , USB3 : SS
PSU_SERDES_L3_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0 0x7D
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD40D8F8, 0x000000FFU ,0x0000007DU)
RegMask = (SERDES_L3_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0_MASK | 0 );
RegVal = ((0x0000007DU << SERDES_L3_TM_IQ_ILL1_ILL_BYPASS_IQ_CALCODE_F0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_IQ_ILL1_OFFSET ,0x000000FFU ,0x0000007DU);
/*############################################################################################################################ */
/*Register : L3_TM_IQ_ILL2 @ 0XFD40D8FC</p>
IQ ILL F1 CALCODE bypass value. MPHY : G1b, PCIE : Gen2, SATA: Gen2
PSU_SERDES_L3_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1 0x7D
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD40D8FC, 0x000000FFU ,0x0000007DU)
RegMask = (SERDES_L3_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1_MASK | 0 );
RegVal = ((0x0000007DU << SERDES_L3_TM_IQ_ILL2_ILL_BYPASS_IQ_CALCODE_F1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_IQ_ILL2_OFFSET ,0x000000FFU ,0x0000007DU);
/*############################################################################################################################ */
/*Register : L3_TM_ILL12 @ 0XFD40D990</p>
G1A pll ctr bypass value
PSU_SERDES_L3_TM_ILL12_G1A_PLL_CTR_BYP_VAL 0x1
ill pll counter values
(OFFSET, MASK, VALUE) (0XFD40D990, 0x000000FFU ,0x00000001U)
RegMask = (SERDES_L3_TM_ILL12_G1A_PLL_CTR_BYP_VAL_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_ILL12_G1A_PLL_CTR_BYP_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_ILL12_OFFSET ,0x000000FFU ,0x00000001U);
/*############################################################################################################################ */
/*Register : L3_TM_E_ILL1 @ 0XFD40D924</p>
E ILL F0 CALCODE bypass value. MPHY : G1a, PCIE : Gen 1, SATA : Gen1 , USB3 : SS
PSU_SERDES_L3_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0 0x9C
epi cal code
(OFFSET, MASK, VALUE) (0XFD40D924, 0x000000FFU ,0x0000009CU)
RegMask = (SERDES_L3_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0_MASK | 0 );
RegVal = ((0x0000009CU << SERDES_L3_TM_E_ILL1_ILL_BYPASS_E_CALCODE_F0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_E_ILL1_OFFSET ,0x000000FFU ,0x0000009CU);
/*############################################################################################################################ */
/*Register : L3_TM_E_ILL2 @ 0XFD40D928</p>
E ILL F1 CALCODE bypass value. MPHY : G1b, PCIE : Gen2, SATA: Gen2
PSU_SERDES_L3_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1 0x39
epi cal code
(OFFSET, MASK, VALUE) (0XFD40D928, 0x000000FFU ,0x00000039U)
RegMask = (SERDES_L3_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1_MASK | 0 );
RegVal = ((0x00000039U << SERDES_L3_TM_E_ILL2_ILL_BYPASS_E_CALCODE_F1_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_E_ILL2_OFFSET ,0x000000FFU ,0x00000039U);
/*############################################################################################################################ */
/*Register : L3_TM_ILL11 @ 0XFD40D98C</p>
G2A_PCIe1 PLL ctr bypass value
PSU_SERDES_L3_TM_ILL11_G2A_PCIEG1_PLL_CTR_11_8_BYP_VAL 0x2
ill pll counter values
(OFFSET, MASK, VALUE) (0XFD40D98C, 0x000000F0U ,0x00000020U)
RegMask = (SERDES_L3_TM_ILL11_G2A_PCIEG1_PLL_CTR_11_8_BYP_VAL_MASK | 0 );
RegVal = ((0x00000002U << SERDES_L3_TM_ILL11_G2A_PCIEG1_PLL_CTR_11_8_BYP_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_ILL11_OFFSET ,0x000000F0U ,0x00000020U);
/*############################################################################################################################ */
/*Register : L3_TM_IQ_ILL3 @ 0XFD40D900</p>
IQ ILL F2CALCODE bypass value. MPHY : G2a, SATA : Gen3
PSU_SERDES_L3_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2 0x7D
iqpi cal code
(OFFSET, MASK, VALUE) (0XFD40D900, 0x000000FFU ,0x0000007DU)
RegMask = (SERDES_L3_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2_MASK | 0 );
RegVal = ((0x0000007DU << SERDES_L3_TM_IQ_ILL3_ILL_BYPASS_IQ_CALCODE_F2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_IQ_ILL3_OFFSET ,0x000000FFU ,0x0000007DU);
/*############################################################################################################################ */
/*Register : L3_TM_E_ILL3 @ 0XFD40D92C</p>
E ILL F2CALCODE bypass value. MPHY : G2a, SATA : Gen3
PSU_SERDES_L3_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2 0x64
epi cal code
(OFFSET, MASK, VALUE) (0XFD40D92C, 0x000000FFU ,0x00000064U)
RegMask = (SERDES_L3_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2_MASK | 0 );
RegVal = ((0x00000064U << SERDES_L3_TM_E_ILL3_ILL_BYPASS_E_CALCODE_F2_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_E_ILL3_OFFSET ,0x000000FFU ,0x00000064U);
/*############################################################################################################################ */
/*Register : L3_TM_ILL8 @ 0XFD40D980</p>
ILL calibration code change wait time
PSU_SERDES_L3_TM_ILL8_ILL_CAL_ITER_WAIT 0xFF
ILL cal routine control
(OFFSET, MASK, VALUE) (0XFD40D980, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L3_TM_ILL8_ILL_CAL_ITER_WAIT_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L3_TM_ILL8_ILL_CAL_ITER_WAIT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_ILL8_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L3_TM_IQ_ILL8 @ 0XFD40D914</p>
IQ ILL polytrim bypass value
PSU_SERDES_L3_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL 0xF7
iqpi polytrim
(OFFSET, MASK, VALUE) (0XFD40D914, 0x000000FFU ,0x000000F7U)
RegMask = (SERDES_L3_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL_MASK | 0 );
RegVal = ((0x000000F7U << SERDES_L3_TM_IQ_ILL8_ILL_BYPASS_IQ_POLYTRIM_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_IQ_ILL8_OFFSET ,0x000000FFU ,0x000000F7U);
/*############################################################################################################################ */
/*Register : L3_TM_IQ_ILL9 @ 0XFD40D918</p>
bypass IQ polytrim
PSU_SERDES_L3_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM 0x1
enables for lf,constant gm trim and polytirm
(OFFSET, MASK, VALUE) (0XFD40D918, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L3_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_IQ_ILL9_ILL_BYPASS_IQ_POLYTIM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_IQ_ILL9_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : L3_TM_E_ILL8 @ 0XFD40D940</p>
E ILL polytrim bypass value
PSU_SERDES_L3_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL 0xF7
epi polytrim
(OFFSET, MASK, VALUE) (0XFD40D940, 0x000000FFU ,0x000000F7U)
RegMask = (SERDES_L3_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL_MASK | 0 );
RegVal = ((0x000000F7U << SERDES_L3_TM_E_ILL8_ILL_BYPASS_E_POLYTRIM_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_E_ILL8_OFFSET ,0x000000FFU ,0x000000F7U);
/*############################################################################################################################ */
/*Register : L3_TM_E_ILL9 @ 0XFD40D944</p>
bypass E polytrim
PSU_SERDES_L3_TM_E_ILL9_ILL_BYPASS_E_POLYTIM 0x1
enables for lf,constant gm trim and polytirm
(OFFSET, MASK, VALUE) (0XFD40D944, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L3_TM_E_ILL9_ILL_BYPASS_E_POLYTIM_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_E_ILL9_ILL_BYPASS_E_POLYTIM_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_E_ILL9_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : SYMBOL LOCK AND WAIT
// : SIOU SETTINGS FOR BYPASS CONTROL,HSRX-DIG
/*Register : L0_TM_RST_DLY @ 0XFD4019A4</p>
Delay apb reset by specified amount
PSU_SERDES_L0_TM_RST_DLY_APB_RST_DLY 0xFF
reset delay for apb reset w.r.t pso of hsrx
(OFFSET, MASK, VALUE) (0XFD4019A4, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L0_TM_RST_DLY_APB_RST_DLY_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L0_TM_RST_DLY_APB_RST_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TM_RST_DLY_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L0_TM_ANA_BYP_15 @ 0XFD401038</p>
Enable Bypass for <7> of TM_ANA_BYPS_15
PSU_SERDES_L0_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE 0x1
Bypass control for pcs-pma interface. EQ supplies, main master supply and ps for samp c2c
(OFFSET, MASK, VALUE) (0XFD401038, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L0_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TM_ANA_BYP_15_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L0_TM_ANA_BYP_12 @ 0XFD40102C</p>
Enable Bypass for <7> of TM_ANA_BYPS_12
PSU_SERDES_L0_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG 0x1
Bypass control for pcs-pma interface. Hsrx supply, hsrx des, and cdr enable controls
(OFFSET, MASK, VALUE) (0XFD40102C, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L0_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TM_ANA_BYP_12_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L1_TM_RST_DLY @ 0XFD4059A4</p>
Delay apb reset by specified amount
PSU_SERDES_L1_TM_RST_DLY_APB_RST_DLY 0xFF
reset delay for apb reset w.r.t pso of hsrx
(OFFSET, MASK, VALUE) (0XFD4059A4, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L1_TM_RST_DLY_APB_RST_DLY_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L1_TM_RST_DLY_APB_RST_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TM_RST_DLY_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L1_TM_ANA_BYP_15 @ 0XFD405038</p>
Enable Bypass for <7> of TM_ANA_BYPS_15
PSU_SERDES_L1_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE 0x1
Bypass control for pcs-pma interface. EQ supplies, main master supply and ps for samp c2c
(OFFSET, MASK, VALUE) (0XFD405038, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L1_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L1_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TM_ANA_BYP_15_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L1_TM_ANA_BYP_12 @ 0XFD40502C</p>
Enable Bypass for <7> of TM_ANA_BYPS_12
PSU_SERDES_L1_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG 0x1
Bypass control for pcs-pma interface. Hsrx supply, hsrx des, and cdr enable controls
(OFFSET, MASK, VALUE) (0XFD40502C, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L1_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L1_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TM_ANA_BYP_12_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L2_TM_RST_DLY @ 0XFD4099A4</p>
Delay apb reset by specified amount
PSU_SERDES_L2_TM_RST_DLY_APB_RST_DLY 0xFF
reset delay for apb reset w.r.t pso of hsrx
(OFFSET, MASK, VALUE) (0XFD4099A4, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L2_TM_RST_DLY_APB_RST_DLY_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L2_TM_RST_DLY_APB_RST_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_RST_DLY_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L2_TM_ANA_BYP_15 @ 0XFD409038</p>
Enable Bypass for <7> of TM_ANA_BYPS_15
PSU_SERDES_L2_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE 0x1
Bypass control for pcs-pma interface. EQ supplies, main master supply and ps for samp c2c
(OFFSET, MASK, VALUE) (0XFD409038, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L2_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_ANA_BYP_15_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L2_TM_ANA_BYP_12 @ 0XFD40902C</p>
Enable Bypass for <7> of TM_ANA_BYPS_12
PSU_SERDES_L2_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG 0x1
Bypass control for pcs-pma interface. Hsrx supply, hsrx des, and cdr enable controls
(OFFSET, MASK, VALUE) (0XFD40902C, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L2_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L2_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L2_TM_ANA_BYP_12_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L3_TM_RST_DLY @ 0XFD40D9A4</p>
Delay apb reset by specified amount
PSU_SERDES_L3_TM_RST_DLY_APB_RST_DLY 0xFF
reset delay for apb reset w.r.t pso of hsrx
(OFFSET, MASK, VALUE) (0XFD40D9A4, 0x000000FFU ,0x000000FFU)
RegMask = (SERDES_L3_TM_RST_DLY_APB_RST_DLY_MASK | 0 );
RegVal = ((0x000000FFU << SERDES_L3_TM_RST_DLY_APB_RST_DLY_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_RST_DLY_OFFSET ,0x000000FFU ,0x000000FFU);
/*############################################################################################################################ */
/*Register : L3_TM_ANA_BYP_15 @ 0XFD40D038</p>
Enable Bypass for <7> of TM_ANA_BYPS_15
PSU_SERDES_L3_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE 0x1
Bypass control for pcs-pma interface. EQ supplies, main master supply and ps for samp c2c
(OFFSET, MASK, VALUE) (0XFD40D038, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L3_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_ANA_BYP_15_FORCE_UPHY_ENABLE_LOW_LEAKAGE_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_ANA_BYP_15_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
/*Register : L3_TM_ANA_BYP_12 @ 0XFD40D02C</p>
Enable Bypass for <7> of TM_ANA_BYPS_12
PSU_SERDES_L3_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG 0x1
Bypass control for pcs-pma interface. Hsrx supply, hsrx des, and cdr enable controls
(OFFSET, MASK, VALUE) (0XFD40D02C, 0x00000040U ,0x00000040U)
RegMask = (SERDES_L3_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_ANA_BYP_12_FORCE_UPHY_PSO_HSRXDIG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_ANA_BYP_12_OFFSET ,0x00000040U ,0x00000040U);
/*############################################################################################################################ */
// : GT LANE SETTINGS
/*Register : ICM_CFG0 @ 0XFD410010</p>
Controls UPHY Lane 0 protocol configuration. 0 - PowerDown, 1 - PCIe .0, 2 - Sata0, 3 - USB0, 4 - DP.1, 5 - SGMII0, 6 - Unuse
, 7 - Unused
PSU_SERDES_ICM_CFG0_L0_ICM_CFG 4
Controls UPHY Lane 1 protocol configuration. 0 - PowerDown, 1 - PCIe.1, 2 - Sata1, 3 - USB0, 4 - DP.0, 5 - SGMII1, 6 - Unused
7 - Unused
PSU_SERDES_ICM_CFG0_L1_ICM_CFG 4
ICM Configuration Register 0
(OFFSET, MASK, VALUE) (0XFD410010, 0x00000077U ,0x00000044U)
RegMask = (SERDES_ICM_CFG0_L0_ICM_CFG_MASK | SERDES_ICM_CFG0_L1_ICM_CFG_MASK | 0 );
RegVal = ((0x00000004U << SERDES_ICM_CFG0_L0_ICM_CFG_SHIFT
| 0x00000004U << SERDES_ICM_CFG0_L1_ICM_CFG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_ICM_CFG0_OFFSET ,0x00000077U ,0x00000044U);
/*############################################################################################################################ */
/*Register : ICM_CFG1 @ 0XFD410014</p>
Controls UPHY Lane 2 protocol configuration. 0 - PowerDown, 1 - PCIe.1, 2 - Sata0, 3 - USB0, 4 - DP.1, 5 - SGMII2, 6 - Unused
7 - Unused
PSU_SERDES_ICM_CFG1_L2_ICM_CFG 3
Controls UPHY Lane 3 protocol configuration. 0 - PowerDown, 1 - PCIe.3, 2 - Sata1, 3 - USB1, 4 - DP.0, 5 - SGMII3, 6 - Unused
7 - Unused
PSU_SERDES_ICM_CFG1_L3_ICM_CFG 2
ICM Configuration Register 1
(OFFSET, MASK, VALUE) (0XFD410014, 0x00000077U ,0x00000023U)
RegMask = (SERDES_ICM_CFG1_L2_ICM_CFG_MASK | SERDES_ICM_CFG1_L3_ICM_CFG_MASK | 0 );
RegVal = ((0x00000003U << SERDES_ICM_CFG1_L2_ICM_CFG_SHIFT
| 0x00000002U << SERDES_ICM_CFG1_L3_ICM_CFG_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_ICM_CFG1_OFFSET ,0x00000077U ,0x00000023U);
/*############################################################################################################################ */
// : CHECKING PLL LOCK
// : ENABLE SERIAL DATA MUX DEEMPH
/*Register : L0_TXPMD_TM_45 @ 0XFD400CB4</p>
Enable/disable DP post2 path
PSU_SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH 0x1
Override enable/disable of DP post2 path
PSU_SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH 0x1
Override enable/disable of DP post1 path
PSU_SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH 0x1
Enable/disable DP main path
PSU_SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH 0x1
Override enable/disable of DP main path
PSU_SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH 0x1
Post or pre or main DP path selection
(OFFSET, MASK, VALUE) (0XFD400CB4, 0x00000037U ,0x00000037U)
RegMask = (SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH_MASK | SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH_MASK | SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH_MASK | SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH_MASK | SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH_SHIFT
| 0x00000001U << SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH_SHIFT
| 0x00000001U << SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH_SHIFT
| 0x00000001U << SERDES_L0_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH_SHIFT
| 0x00000001U << SERDES_L0_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TXPMD_TM_45_OFFSET ,0x00000037U ,0x00000037U);
/*############################################################################################################################ */
/*Register : L1_TXPMD_TM_45 @ 0XFD404CB4</p>
Enable/disable DP post2 path
PSU_SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH 0x1
Override enable/disable of DP post2 path
PSU_SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH 0x1
Override enable/disable of DP post1 path
PSU_SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH 0x1
Enable/disable DP main path
PSU_SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH 0x1
Override enable/disable of DP main path
PSU_SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH 0x1
Post or pre or main DP path selection
(OFFSET, MASK, VALUE) (0XFD404CB4, 0x00000037U ,0x00000037U)
RegMask = (SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH_MASK | SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH_MASK | SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH_MASK | SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH_MASK | SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_POST2_PATH_SHIFT
| 0x00000001U << SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST2_PATH_SHIFT
| 0x00000001U << SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_POST1_PATH_SHIFT
| 0x00000001U << SERDES_L1_TXPMD_TM_45_DP_TM_TX_DP_ENABLE_MAIN_PATH_SHIFT
| 0x00000001U << SERDES_L1_TXPMD_TM_45_DP_TM_TX_OVRD_DP_ENABLE_MAIN_PATH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TXPMD_TM_45_OFFSET ,0x00000037U ,0x00000037U);
/*############################################################################################################################ */
/*Register : L0_TX_ANA_TM_118 @ 0XFD4001D8</p>
Test register force for enabling/disablign TX deemphasis bits <17:0>
PSU_SERDES_L0_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0 0x1
Enable Override of TX deemphasis
(OFFSET, MASK, VALUE) (0XFD4001D8, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L0_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L0_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TX_ANA_TM_118_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : L1_TX_ANA_TM_118 @ 0XFD4041D8</p>
Test register force for enabling/disablign TX deemphasis bits <17:0>
PSU_SERDES_L1_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0 0x1
Enable Override of TX deemphasis
(OFFSET, MASK, VALUE) (0XFD4041D8, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L1_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L1_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TX_ANA_TM_118_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : L3_TX_ANA_TM_118 @ 0XFD40C1D8</p>
Test register force for enabling/disablign TX deemphasis bits <17:0>
PSU_SERDES_L3_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0 0x1
Enable Override of TX deemphasis
(OFFSET, MASK, VALUE) (0XFD40C1D8, 0x00000001U ,0x00000001U)
RegMask = (SERDES_L3_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TX_ANA_TM_118_FORCE_TX_DEEMPH_17_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TX_ANA_TM_118_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
// : CDR AND RX EQUALIZATION SETTINGS
/*Register : L3_TM_CDR5 @ 0XFD40DC14</p>
FPHL FSM accumulate cycles
PSU_SERDES_L3_TM_CDR5_FPHL_FSM_ACC_CYCLES 0x7
FFL Phase0 int gain aka 2ol SD update rate
PSU_SERDES_L3_TM_CDR5_FFL_PH0_INT_GAIN 0x6
Fast phase lock controls -- FSM accumulator cycle control and phase 0 int gain control.
(OFFSET, MASK, VALUE) (0XFD40DC14, 0x000000FFU ,0x000000E6U)
RegMask = (SERDES_L3_TM_CDR5_FPHL_FSM_ACC_CYCLES_MASK | SERDES_L3_TM_CDR5_FFL_PH0_INT_GAIN_MASK | 0 );
RegVal = ((0x00000007U << SERDES_L3_TM_CDR5_FPHL_FSM_ACC_CYCLES_SHIFT
| 0x00000006U << SERDES_L3_TM_CDR5_FFL_PH0_INT_GAIN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_CDR5_OFFSET ,0x000000FFU ,0x000000E6U);
/*############################################################################################################################ */
/*Register : L3_TM_CDR16 @ 0XFD40DC40</p>
FFL Phase0 prop gain aka 1ol SD update rate
PSU_SERDES_L3_TM_CDR16_FFL_PH0_PROP_GAIN 0xC
Fast phase lock controls -- phase 0 prop gain
(OFFSET, MASK, VALUE) (0XFD40DC40, 0x0000001FU ,0x0000000CU)
RegMask = (SERDES_L3_TM_CDR16_FFL_PH0_PROP_GAIN_MASK | 0 );
RegVal = ((0x0000000CU << SERDES_L3_TM_CDR16_FFL_PH0_PROP_GAIN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_CDR16_OFFSET ,0x0000001FU ,0x0000000CU);
/*############################################################################################################################ */
/*Register : L3_TM_EQ0 @ 0XFD40D94C</p>
EQ stg 2 controls BYPASSED
PSU_SERDES_L3_TM_EQ0_EQ_STG2_CTRL_BYP 1
eq stg1 and stg2 controls
(OFFSET, MASK, VALUE) (0XFD40D94C, 0x00000020U ,0x00000020U)
RegMask = (SERDES_L3_TM_EQ0_EQ_STG2_CTRL_BYP_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TM_EQ0_EQ_STG2_CTRL_BYP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_EQ0_OFFSET ,0x00000020U ,0x00000020U);
/*############################################################################################################################ */
/*Register : L3_TM_EQ1 @ 0XFD40D950</p>
EQ STG2 RL PROG
PSU_SERDES_L3_TM_EQ1_EQ_STG2_RL_PROG 0x2
EQ stg 2 preamp mode val
PSU_SERDES_L3_TM_EQ1_EQ_STG2_PREAMP_MODE_VAL 0x1
eq stg1 and stg2 controls
(OFFSET, MASK, VALUE) (0XFD40D950, 0x00000007U ,0x00000006U)
RegMask = (SERDES_L3_TM_EQ1_EQ_STG2_RL_PROG_MASK | SERDES_L3_TM_EQ1_EQ_STG2_PREAMP_MODE_VAL_MASK | 0 );
RegVal = ((0x00000002U << SERDES_L3_TM_EQ1_EQ_STG2_RL_PROG_SHIFT
| 0x00000001U << SERDES_L3_TM_EQ1_EQ_STG2_PREAMP_MODE_VAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TM_EQ1_OFFSET ,0x00000007U ,0x00000006U);
/*############################################################################################################################ */
// : GEM SERDES SETTINGS
// : ENABLE PRE EMPHAIS AND VOLTAGE SWING
/*Register : L1_TXPMD_TM_48 @ 0XFD404CC0</p>
Margining factor value
PSU_SERDES_L1_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR 0
Margining factor
(OFFSET, MASK, VALUE) (0XFD404CC0, 0x0000001FU ,0x00000000U)
RegMask = (SERDES_L1_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L1_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TXPMD_TM_48_OFFSET ,0x0000001FU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L0_TXPMD_TM_48 @ 0XFD400CC0</p>
Margining factor value
PSU_SERDES_L0_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR 0
Margining factor
(OFFSET, MASK, VALUE) (0XFD400CC0, 0x0000001FU ,0x00000000U)
RegMask = (SERDES_L0_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_TXPMD_TM_48_TM_RESULTANT_MARGINING_FACTOR_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TXPMD_TM_48_OFFSET ,0x0000001FU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L1_TX_ANA_TM_18 @ 0XFD404048</p>
pipe_TX_Deemph. 0: -6dB de-emphasis, 1: -3.5dB de-emphasis, 2 : No de-emphasis, Others: reserved
PSU_SERDES_L1_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0 0
Override for PIPE TX de-emphasis
(OFFSET, MASK, VALUE) (0XFD404048, 0x000000FFU ,0x00000000U)
RegMask = (SERDES_L1_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L1_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L1_TX_ANA_TM_18_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L0_TX_ANA_TM_18 @ 0XFD400048</p>
pipe_TX_Deemph. 0: -6dB de-emphasis, 1: -3.5dB de-emphasis, 2 : No de-emphasis, Others: reserved
PSU_SERDES_L0_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0 0
Override for PIPE TX de-emphasis
(OFFSET, MASK, VALUE) (0XFD400048, 0x000000FFU ,0x00000000U)
RegMask = (SERDES_L0_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_MASK | 0 );
RegVal = ((0x00000000U << SERDES_L0_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L0_TX_ANA_TM_18_OFFSET ,0x000000FFU ,0x00000000U);
/*############################################################################################################################ */
/*Register : L3_TX_ANA_TM_18 @ 0XFD40C048</p>
pipe_TX_Deemph. 0: -6dB de-emphasis, 1: -3.5dB de-emphasis, 2 : No de-emphasis, Others: reserved
PSU_SERDES_L3_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0 0x1
Override for PIPE TX de-emphasis
(OFFSET, MASK, VALUE) (0XFD40C048, 0x000000FFU ,0x00000001U)
RegMask = (SERDES_L3_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_MASK | 0 );
RegVal = ((0x00000001U << SERDES_L3_TX_ANA_TM_18_PIPE_TX_DEEMPH_7_0_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SERDES_L3_TX_ANA_TM_18_OFFSET ,0x000000FFU ,0x00000001U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_resetout_init_data() {
// : TAKING SERDES PERIPHERAL OUT OF RESET RESET
// : PUTTING USB0 IN RESET
/*Register : RST_LPD_TOP @ 0XFF5E023C</p>
USB 0 reset for control registers
PSU_CRL_APB_RST_LPD_TOP_USB0_APB_RESET 0X0
Software control register for the LPD block.
(OFFSET, MASK, VALUE) (0XFF5E023C, 0x00000400U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_TOP_USB0_APB_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_TOP_USB0_APB_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_TOP_OFFSET ,0x00000400U ,0x00000000U);
/*############################################################################################################################ */
// : USB0 PIPE POWER PRESENT
/*Register : fpd_power_prsnt @ 0XFF9D0080</p>
This bit is used to choose between PIPE power present and 1'b1
PSU_USB3_0_FPD_POWER_PRSNT_OPTION 0X1
fpd_power_prsnt
(OFFSET, MASK, VALUE) (0XFF9D0080, 0x00000001U ,0x00000001U)
RegMask = (USB3_0_FPD_POWER_PRSNT_OPTION_MASK | 0 );
RegVal = ((0x00000001U << USB3_0_FPD_POWER_PRSNT_OPTION_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (USB3_0_FPD_POWER_PRSNT_OFFSET ,0x00000001U ,0x00000001U);
/*############################################################################################################################ */
/*Register : fpd_pipe_clk @ 0XFF9D007C</p>
This bit is used to choose between PIPE clock coming from SerDes and the suspend clk
PSU_USB3_0_FPD_PIPE_CLK_OPTION 0x0
fpd_pipe_clk
(OFFSET, MASK, VALUE) (0XFF9D007C, 0x00000001U ,0x00000000U)
RegMask = (USB3_0_FPD_PIPE_CLK_OPTION_MASK | 0 );
RegVal = ((0x00000000U << USB3_0_FPD_PIPE_CLK_OPTION_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (USB3_0_FPD_PIPE_CLK_OFFSET ,0x00000001U ,0x00000000U);
/*############################################################################################################################ */
// :
/*Register : RST_LPD_TOP @ 0XFF5E023C</p>
USB 0 sleep circuit reset
PSU_CRL_APB_RST_LPD_TOP_USB0_HIBERRESET 0X0
USB 0 reset
PSU_CRL_APB_RST_LPD_TOP_USB0_CORERESET 0X0
Software control register for the LPD block.
(OFFSET, MASK, VALUE) (0XFF5E023C, 0x00000140U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_MASK | CRL_APB_RST_LPD_TOP_USB0_CORERESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_SHIFT
| 0x00000000U << CRL_APB_RST_LPD_TOP_USB0_CORERESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_TOP_OFFSET ,0x00000140U ,0x00000000U);
/*############################################################################################################################ */
// : PUTTING GEM0 IN RESET
/*Register : RST_LPD_IOU0 @ 0XFF5E0230</p>
GEM 3 reset
PSU_CRL_APB_RST_LPD_IOU0_GEM3_RESET 0X0
Software controlled reset for the GEMs
(OFFSET, MASK, VALUE) (0XFF5E0230, 0x00000008U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_IOU0_GEM3_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_IOU0_GEM3_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU0_OFFSET ,0x00000008U ,0x00000000U);
/*############################################################################################################################ */
// : PUTTING SATA IN RESET
/*Register : sata_misc_ctrl @ 0XFD3D0100</p>
Sata PM clock control select
PSU_SIOU_SATA_MISC_CTRL_SATA_PM_CLK_SEL 0x3
Misc Contorls for SATA.This register may only be modified during bootup (while SATA block is disabled)
(OFFSET, MASK, VALUE) (0XFD3D0100, 0x00000003U ,0x00000003U)
RegMask = (SIOU_SATA_MISC_CTRL_SATA_PM_CLK_SEL_MASK | 0 );
RegVal = ((0x00000003U << SIOU_SATA_MISC_CTRL_SATA_PM_CLK_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SIOU_SATA_MISC_CTRL_OFFSET ,0x00000003U ,0x00000003U);
/*############################################################################################################################ */
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
Sata block level reset
PSU_CRF_APB_RST_FPD_TOP_SATA_RESET 0X0
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x00000002U ,0x00000000U)
RegMask = (CRF_APB_RST_FPD_TOP_SATA_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_RST_FPD_TOP_SATA_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x00000002U ,0x00000000U);
/*############################################################################################################################ */
// : PUTTING DP IN RESET
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
Display Port block level reset (includes DPDMA)
PSU_CRF_APB_RST_FPD_TOP_DP_RESET 0X0
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x00010000U ,0x00000000U)
RegMask = (CRF_APB_RST_FPD_TOP_DP_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_RST_FPD_TOP_DP_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x00010000U ,0x00000000U);
/*############################################################################################################################ */
/*Register : DP_PHY_RESET @ 0XFD4A0200</p>
Set to '1' to hold the GT in reset. Clear to release.
PSU_DP_DP_PHY_RESET_GT_RESET 0X0
Reset the transmitter PHY.
(OFFSET, MASK, VALUE) (0XFD4A0200, 0x00000002U ,0x00000000U)
RegMask = (DP_DP_PHY_RESET_GT_RESET_MASK | 0 );
RegVal = ((0x00000000U << DP_DP_PHY_RESET_GT_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DP_DP_PHY_RESET_OFFSET ,0x00000002U ,0x00000000U);
/*############################################################################################################################ */
/*Register : DP_TX_PHY_POWER_DOWN @ 0XFD4A0238</p>
Two bits per lane. When set to 11, moves the GT to power down mode. When set to 00, GT will be in active state. bits [1:0] -
ane0 Bits [3:2] - lane 1
PSU_DP_DP_TX_PHY_POWER_DOWN_POWER_DWN 0X0
Control PHY Power down
(OFFSET, MASK, VALUE) (0XFD4A0238, 0x0000000FU ,0x00000000U)
RegMask = (DP_DP_TX_PHY_POWER_DOWN_POWER_DWN_MASK | 0 );
RegVal = ((0x00000000U << DP_DP_TX_PHY_POWER_DOWN_POWER_DWN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DP_DP_TX_PHY_POWER_DOWN_OFFSET ,0x0000000FU ,0x00000000U);
/*############################################################################################################################ */
// : USB0 GFLADJ
/*Register : GUSB2PHYCFG @ 0XFE20C200</p>
USB 2.0 Turnaround Time (USBTrdTim) Sets the turnaround time in PHY clocks. Specifies the response time for a MAC request to
he Packet FIFO Controller (PFC) to fetch data from the DFIFO (SPRAM). The following are the required values for the minimum S
C bus frequency of 60 MHz. USB turnaround time is a critical certification criteria when using long cables and five hub level
. The required values for this field: - 4'h5: When the MAC interface is 16-bit UTMI+. - 4'h9: When the MAC interface is 8-bit
UTMI+/ULPI. If SoC bus clock is less than 60 MHz, and USB turnaround time is not critical, this field can be set to a larger
alue. Note: This field is valid only in device mode.
PSU_USB3_0_XHCI_GUSB2PHYCFG_USBTRDTIM 0x9
Transceiver Delay: Enables a delay between the assertion of the UTMI/ULPI Transceiver Select signal (for HS) and the assertio
of the TxValid signal during a HS Chirp. When this bit is set to 1, a delay (of approximately 2.5 us) is introduced from the
time when the Transceiver Select is set to 2'b00 (HS) to the time the TxValid is driven to 0 for sending the chirp-K. This de
ay is required for some UTMI/ULPI PHYs. Note: - If you enable the hibernation feature when the device core comes out of power
off, you must re-initialize this bit with the appropriate value because the core does not save and restore this bit value dur
ng hibernation. - This bit is valid only in device mode.
PSU_USB3_0_XHCI_GUSB2PHYCFG_XCVRDLY 0x0
Enable utmi_sleep_n and utmi_l1_suspend_n (EnblSlpM) The application uses this bit to control utmi_sleep_n and utmi_l1_suspen
_n assertion to the PHY in the L1 state. - 1'b0: utmi_sleep_n and utmi_l1_suspend_n assertion from the core is not transferre
to the external PHY. - 1'b1: utmi_sleep_n and utmi_l1_suspend_n assertion from the core is transferred to the external PHY.
ote: This bit must be set high for Port0 if PHY is used. Note: In Device mode - Before issuing any device endpoint command wh
n operating in 2.0 speeds, disable this bit and enable it after the command completes. Without disabling this bit, if a comma
d is issued when the device is in L1 state and if mac2_clk (utmi_clk/ulpi_clk) is gated off, the command will not get complet
d.
PSU_USB3_0_XHCI_GUSB2PHYCFG_ENBLSLPM 0x0
USB 2.0 High-Speed PHY or USB 1.1 Full-Speed Serial Transceiver Select The application uses this bit to select a high-speed P
Y or a full-speed transceiver. - 1'b0: USB 2.0 high-speed UTMI+ or ULPI PHY. This bit is always 0, with Write Only access. -
'b1: USB 1.1 full-speed serial transceiver. This bit is always 1, with Write Only access. If both interface types are selecte
in coreConsultant (that is, parameters' values are not zero), the application uses this bit to select the active interface i
active, with Read-Write bit access. Note: USB 1.1 full-serial transceiver is not supported. This bit always reads as 1'b0.
PSU_USB3_0_XHCI_GUSB2PHYCFG_PHYSEL 0x0
Full-Speed Serial Interface Select (FSIntf) The application uses this bit to select a unidirectional or bidirectional USB 1.1
full-speed serial transceiver interface. - 1'b0: 6-pin unidirectional full-speed serial interface. This bit is set to 0 with
ead Only access. - 1'b1: 3-pin bidirectional full-speed serial interface. This bit is set to 0 with Read Only access. Note: U
B 1.1 full-speed serial interface is not supported. This bit always reads as 1'b0.
PSU_USB3_0_XHCI_GUSB2PHYCFG_FSINTF 0x0
ULPI or UTMI+ Select (ULPI_UTMI_Sel) The application uses this bit to select a UTMI+ or ULPI Interface. - 1'b0: UTMI+ Interfa
e - 1'b1: ULPI Interface This bit is writable only if UTMI+ and ULPI is specified for High-Speed PHY Interface(s) in coreCons
ltant configuration (DWC_USB3_HSPHY_INTERFACE = 3). Otherwise, this bit is read-only and the value depends on the interface s
lected through DWC_USB3_HSPHY_INTERFACE.
PSU_USB3_0_XHCI_GUSB2PHYCFG_ULPI_UTMI_SEL 0x1
PHY Interface (PHYIf) If UTMI+ is selected, the application uses this bit to configure the core to support a UTMI+ PHY with a
8- or 16-bit interface. - 1'b0: 8 bits - 1'b1: 16 bits ULPI Mode: 1'b0 Note: - All the enabled 2.0 ports must have the same
lock frequency as Port0 clock frequency (utmi_clk[0]). - The UTMI 8-bit and 16-bit modes cannot be used together for differen
ports at the same time (that is, all the ports must be in 8-bit mode, or all of them must be in 16-bit mode, at a time). - I
any of the USB 2.0 ports is selected as ULPI port for operation, then all the USB 2.0 ports must be operating at 60 MHz.
PSU_USB3_0_XHCI_GUSB2PHYCFG_PHYIF 0x0
HS/FS Timeout Calibration (TOutCal) The number of PHY clocks, as indicated by the application in this field, is multiplied by
a bit-time factor; this factor is added to the high-speed/full-speed interpacket timeout duration in the core to account for
dditional delays introduced by the PHY. This may be required, since the delay introduced by the PHY in generating the linesta
e condition may vary among PHYs. The USB standard timeout value for high-speed operation is 736 to 816 (inclusive) bit times.
The USB standard timeout value for full-speed operation is 16 to 18 (inclusive) bit times. The application must program this
ield based on the speed of connection. The number of bit times added per PHY clock are: High-speed operation: - One 30-MHz PH
clock = 16 bit times - One 60-MHz PHY clock = 8 bit times Full-speed operation: - One 30-MHz PHY clock = 0.4 bit times - One
60-MHz PHY clock = 0.2 bit times - One 48-MHz PHY clock = 0.25 bit times
PSU_USB3_0_XHCI_GUSB2PHYCFG_TOUTCAL 0x7
Global USB2 PHY Configuration Register The application must program this register before starting any transactions on either
he SoC bus or the USB. In Device-only configurations, only one register is needed. In Host mode, per-port registers are imple
ented.
(OFFSET, MASK, VALUE) (0XFE20C200, 0x00003FBFU ,0x00002417U)
RegMask = (USB3_0_XHCI_GUSB2PHYCFG_USBTRDTIM_MASK | USB3_0_XHCI_GUSB2PHYCFG_XCVRDLY_MASK | USB3_0_XHCI_GUSB2PHYCFG_ENBLSLPM_MASK | USB3_0_XHCI_GUSB2PHYCFG_PHYSEL_MASK | USB3_0_XHCI_GUSB2PHYCFG_FSINTF_MASK | USB3_0_XHCI_GUSB2PHYCFG_ULPI_UTMI_SEL_MASK | USB3_0_XHCI_GUSB2PHYCFG_PHYIF_MASK | USB3_0_XHCI_GUSB2PHYCFG_TOUTCAL_MASK | 0 );
RegVal = ((0x00000009U << USB3_0_XHCI_GUSB2PHYCFG_USBTRDTIM_SHIFT
| 0x00000000U << USB3_0_XHCI_GUSB2PHYCFG_XCVRDLY_SHIFT
| 0x00000000U << USB3_0_XHCI_GUSB2PHYCFG_ENBLSLPM_SHIFT
| 0x00000000U << USB3_0_XHCI_GUSB2PHYCFG_PHYSEL_SHIFT
| 0x00000000U << USB3_0_XHCI_GUSB2PHYCFG_FSINTF_SHIFT
| 0x00000001U << USB3_0_XHCI_GUSB2PHYCFG_ULPI_UTMI_SEL_SHIFT
| 0x00000000U << USB3_0_XHCI_GUSB2PHYCFG_PHYIF_SHIFT
| 0x00000007U << USB3_0_XHCI_GUSB2PHYCFG_TOUTCAL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (USB3_0_XHCI_GUSB2PHYCFG_OFFSET ,0x00003FBFU ,0x00002417U);
/*############################################################################################################################ */
/*Register : GFLADJ @ 0XFE20C630</p>
This field indicates the frame length adjustment to be applied when SOF/ITP counter is running on the ref_clk. This register
alue is used to adjust the ITP interval when GCTL[SOFITPSYNC] is set to '1'; SOF and ITP interval when GLADJ.GFLADJ_REFCLK_LP
_SEL is set to '1'. This field must be programmed to a non-zero value only if GFLADJ_REFCLK_LPM_SEL is set to '1' or GCTL.SOF
TPSYNC is set to '1'. The value is derived as follows: FLADJ_REF_CLK_FLADJ=((125000/ref_clk_period_integer)-(125000/ref_clk_p
riod)) * ref_clk_period where - the ref_clk_period_integer is the integer value of the ref_clk period got by truncating the d
cimal (fractional) value that is programmed in the GUCTL.REF_CLK_PERIOD field. - the ref_clk_period is the ref_clk period inc
uding the fractional value. Examples: If the ref_clk is 24 MHz then - GUCTL.REF_CLK_PERIOD = 41 - GFLADJ.GLADJ_REFCLK_FLADJ =
((125000/41)-(125000/41.6666))*41.6666 = 2032 (ignoring the fractional value) If the ref_clk is 48 MHz then - GUCTL.REF_CLK_P
RIOD = 20 - GFLADJ.GLADJ_REFCLK_FLADJ = ((125000/20)-(125000/20.8333))*20.8333 = 5208 (ignoring the fractional value)
PSU_USB3_0_XHCI_GFLADJ_GFLADJ_REFCLK_FLADJ 0x0
Global Frame Length Adjustment Register This register provides options for the software to control the core behavior with res
ect to SOF (Start of Frame) and ITP (Isochronous Timestamp Packet) timers and frame timer functionality. It provides an optio
to override the fladj_30mhz_reg sideband signal. In addition, it enables running SOF or ITP frame timer counters completely
rom the ref_clk. This facilitates hardware LPM in host mode with the SOF or ITP counters being run from the ref_clk signal.
(OFFSET, MASK, VALUE) (0XFE20C630, 0x003FFF00U ,0x00000000U)
RegMask = (USB3_0_XHCI_GFLADJ_GFLADJ_REFCLK_FLADJ_MASK | 0 );
RegVal = ((0x00000000U << USB3_0_XHCI_GFLADJ_GFLADJ_REFCLK_FLADJ_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (USB3_0_XHCI_GFLADJ_OFFSET ,0x003FFF00U ,0x00000000U);
/*############################################################################################################################ */
// : UPDATING TWO PCIE REGISTERS DEFAULT VALUES, AS THESE REGISTERS HAVE INCORRECT RESET VALUES IN SILICON.
/*Register : ATTR_25 @ 0XFD480064</p>
If TRUE Completion Timeout Disable is supported. This is required to be TRUE for Endpoint and either setting allowed for Root
ports. Drives Device Capability 2 [4]; EP=0x0001; RP=0x0001
PSU_PCIE_ATTRIB_ATTR_25_ATTR_CPL_TIMEOUT_DISABLE_SUPPORTED 0X1
ATTR_25
(OFFSET, MASK, VALUE) (0XFD480064, 0x00000200U ,0x00000200U)
RegMask = (PCIE_ATTRIB_ATTR_25_ATTR_CPL_TIMEOUT_DISABLE_SUPPORTED_MASK | 0 );
RegVal = ((0x00000001U << PCIE_ATTRIB_ATTR_25_ATTR_CPL_TIMEOUT_DISABLE_SUPPORTED_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (PCIE_ATTRIB_ATTR_25_OFFSET ,0x00000200U ,0x00000200U);
/*############################################################################################################################ */
// : CHECK PLL LOCK FOR LANE1
/*Register : L1_PLL_STATUS_READ_1 @ 0XFD4063E4</p>
Status Read value of PLL Lock
PSU_SERDES_L1_PLL_STATUS_READ_1_PLL_LOCK_STATUS_READ 1
(OFFSET, MASK, VALUE) (0XFD4063E4, 0x00000010U ,0x00000010U) */
mask_poll(SERDES_L1_PLL_STATUS_READ_1_OFFSET,0x00000010U);
/*############################################################################################################################ */
// : CHECK PLL LOCK FOR LANE2
/*Register : L2_PLL_STATUS_READ_1 @ 0XFD40A3E4</p>
Status Read value of PLL Lock
PSU_SERDES_L2_PLL_STATUS_READ_1_PLL_LOCK_STATUS_READ 1
(OFFSET, MASK, VALUE) (0XFD40A3E4, 0x00000010U ,0x00000010U) */
mask_poll(SERDES_L2_PLL_STATUS_READ_1_OFFSET,0x00000010U);
/*############################################################################################################################ */
// : CHECK PLL LOCK FOR LANE3
/*Register : L3_PLL_STATUS_READ_1 @ 0XFD40E3E4</p>
Status Read value of PLL Lock
PSU_SERDES_L3_PLL_STATUS_READ_1_PLL_LOCK_STATUS_READ 1
(OFFSET, MASK, VALUE) (0XFD40E3E4, 0x00000010U ,0x00000010U) */
mask_poll(SERDES_L3_PLL_STATUS_READ_1_OFFSET,0x00000010U);
/*############################################################################################################################ */
// : SATA AHCI VENDOR SETTING
/*Register : PP2C @ 0XFD0C00AC</p>
CIBGMN: COMINIT Burst Gap Minimum.
PSU_SATA_AHCI_VENDOR_PP2C_CIBGMN 0x18
CIBGMX: COMINIT Burst Gap Maximum.
PSU_SATA_AHCI_VENDOR_PP2C_CIBGMX 0x40
CIBGN: COMINIT Burst Gap Nominal.
PSU_SATA_AHCI_VENDOR_PP2C_CIBGN 0x18
CINMP: COMINIT Negate Minimum Period.
PSU_SATA_AHCI_VENDOR_PP2C_CINMP 0x28
PP2C - Port Phy2Cfg Register. This register controls the configuration of the Phy Control OOB timing for the COMINIT paramete
s for either Port 0 or Port 1. The Port configured is controlled by the value programmed into the Port Config Register.
(OFFSET, MASK, VALUE) (0XFD0C00AC, 0xFFFFFFFFU ,0x28184018U)
RegMask = (SATA_AHCI_VENDOR_PP2C_CIBGMN_MASK | SATA_AHCI_VENDOR_PP2C_CIBGMX_MASK | SATA_AHCI_VENDOR_PP2C_CIBGN_MASK | SATA_AHCI_VENDOR_PP2C_CINMP_MASK | 0 );
RegVal = ((0x00000018U << SATA_AHCI_VENDOR_PP2C_CIBGMN_SHIFT
| 0x00000040U << SATA_AHCI_VENDOR_PP2C_CIBGMX_SHIFT
| 0x00000018U << SATA_AHCI_VENDOR_PP2C_CIBGN_SHIFT
| 0x00000028U << SATA_AHCI_VENDOR_PP2C_CINMP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SATA_AHCI_VENDOR_PP2C_OFFSET ,0xFFFFFFFFU ,0x28184018U);
/*############################################################################################################################ */
/*Register : PP3C @ 0XFD0C00B0</p>
CWBGMN: COMWAKE Burst Gap Minimum.
PSU_SATA_AHCI_VENDOR_PP3C_CWBGMN 0x06
CWBGMX: COMWAKE Burst Gap Maximum.
PSU_SATA_AHCI_VENDOR_PP3C_CWBGMX 0x14
CWBGN: COMWAKE Burst Gap Nominal.
PSU_SATA_AHCI_VENDOR_PP3C_CWBGN 0x08
CWNMP: COMWAKE Negate Minimum Period.
PSU_SATA_AHCI_VENDOR_PP3C_CWNMP 0x0E
PP3C - Port Phy3CfgRegister. This register controls the configuration of the Phy Control OOB timing for the COMWAKE parameter
for either Port 0 or Port 1. The Port configured is controlled by the value programmed into the Port Config Register.
(OFFSET, MASK, VALUE) (0XFD0C00B0, 0xFFFFFFFFU ,0x0E081406U)
RegMask = (SATA_AHCI_VENDOR_PP3C_CWBGMN_MASK | SATA_AHCI_VENDOR_PP3C_CWBGMX_MASK | SATA_AHCI_VENDOR_PP3C_CWBGN_MASK | SATA_AHCI_VENDOR_PP3C_CWNMP_MASK | 0 );
RegVal = ((0x00000006U << SATA_AHCI_VENDOR_PP3C_CWBGMN_SHIFT
| 0x00000014U << SATA_AHCI_VENDOR_PP3C_CWBGMX_SHIFT
| 0x00000008U << SATA_AHCI_VENDOR_PP3C_CWBGN_SHIFT
| 0x0000000EU << SATA_AHCI_VENDOR_PP3C_CWNMP_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SATA_AHCI_VENDOR_PP3C_OFFSET ,0xFFFFFFFFU ,0x0E081406U);
/*############################################################################################################################ */
/*Register : PP4C @ 0XFD0C00B4</p>
BMX: COM Burst Maximum.
PSU_SATA_AHCI_VENDOR_PP4C_BMX 0x13
BNM: COM Burst Nominal.
PSU_SATA_AHCI_VENDOR_PP4C_BNM 0x08
SFD: Signal Failure Detection, if the signal detection de-asserts for a time greater than this then the OOB detector will det
rmine this is a line idle and cause the PhyInit state machine to exit the Phy Ready State. A value of zero disables the Signa
Failure Detector. The value is based on the OOB Detector Clock typically (PMCLK Clock Period) * SFD giving a nominal time of
500ns based on a 150MHz PMCLK.
PSU_SATA_AHCI_VENDOR_PP4C_SFD 0x4A
PTST: Partial to Slumber timer value, specific delay the controller should apply while in partial before entering slumber. Th
value is bases on the system clock divided by 128, total delay = (Sys Clock Period) * PTST * 128
PSU_SATA_AHCI_VENDOR_PP4C_PTST 0x06
PP4C - Port Phy4Cfg Register. This register controls the configuration of the Phy Control Burst timing for the COM parameters
for either Port 0 or Port 1. The Port configured is controlled by the value programmed into the Port Config Register.
(OFFSET, MASK, VALUE) (0XFD0C00B4, 0xFFFFFFFFU ,0x064A0813U)
RegMask = (SATA_AHCI_VENDOR_PP4C_BMX_MASK | SATA_AHCI_VENDOR_PP4C_BNM_MASK | SATA_AHCI_VENDOR_PP4C_SFD_MASK | SATA_AHCI_VENDOR_PP4C_PTST_MASK | 0 );
RegVal = ((0x00000013U << SATA_AHCI_VENDOR_PP4C_BMX_SHIFT
| 0x00000008U << SATA_AHCI_VENDOR_PP4C_BNM_SHIFT
| 0x0000004AU << SATA_AHCI_VENDOR_PP4C_SFD_SHIFT
| 0x00000006U << SATA_AHCI_VENDOR_PP4C_PTST_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SATA_AHCI_VENDOR_PP4C_OFFSET ,0xFFFFFFFFU ,0x064A0813U);
/*############################################################################################################################ */
/*Register : PP5C @ 0XFD0C00B8</p>
RIT: Retry Interval Timer. The calculated value divided by two, the lower digit of precision is not needed.
PSU_SATA_AHCI_VENDOR_PP5C_RIT 0xC96A4
RCT: Rate Change Timer, a value based on the 54.2us for which a SATA device will transmit at a fixed rate ALIGNp after OOB ha
completed, for a fast SERDES it is suggested that this value be 54.2us / 4
PSU_SATA_AHCI_VENDOR_PP5C_RCT 0x3FF
PP5C - Port Phy5Cfg Register. This register controls the configuration of the Phy Control Retry Interval timing for either Po
t 0 or Port 1. The Port configured is controlled by the value programmed into the Port Config Register.
(OFFSET, MASK, VALUE) (0XFD0C00B8, 0xFFFFFFFFU ,0x3FFC96A4U)
RegMask = (SATA_AHCI_VENDOR_PP5C_RIT_MASK | SATA_AHCI_VENDOR_PP5C_RCT_MASK | 0 );
RegVal = ((0x000C96A4U << SATA_AHCI_VENDOR_PP5C_RIT_SHIFT
| 0x000003FFU << SATA_AHCI_VENDOR_PP5C_RCT_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (SATA_AHCI_VENDOR_PP5C_OFFSET ,0xFFFFFFFFU ,0x3FFC96A4U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_resetin_init_data() {
// : PUTTING SERDES PERIPHERAL IN RESET
// : PUTTING USB0 IN RESET
/*Register : RST_LPD_TOP @ 0XFF5E023C</p>
USB 0 reset for control registers
PSU_CRL_APB_RST_LPD_TOP_USB0_APB_RESET 0X1
USB 0 sleep circuit reset
PSU_CRL_APB_RST_LPD_TOP_USB0_HIBERRESET 0X1
USB 0 reset
PSU_CRL_APB_RST_LPD_TOP_USB0_CORERESET 0X1
Software control register for the LPD block.
(OFFSET, MASK, VALUE) (0XFF5E023C, 0x00000540U ,0x00000540U)
RegMask = (CRL_APB_RST_LPD_TOP_USB0_APB_RESET_MASK | CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_MASK | CRL_APB_RST_LPD_TOP_USB0_CORERESET_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_RST_LPD_TOP_USB0_APB_RESET_SHIFT
| 0x00000001U << CRL_APB_RST_LPD_TOP_USB0_HIBERRESET_SHIFT
| 0x00000001U << CRL_APB_RST_LPD_TOP_USB0_CORERESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_TOP_OFFSET ,0x00000540U ,0x00000540U);
/*############################################################################################################################ */
// : PUTTING GEM0 IN RESET
/*Register : RST_LPD_IOU0 @ 0XFF5E0230</p>
GEM 3 reset
PSU_CRL_APB_RST_LPD_IOU0_GEM3_RESET 0X1
Software controlled reset for the GEMs
(OFFSET, MASK, VALUE) (0XFF5E0230, 0x00000008U ,0x00000008U)
RegMask = (CRL_APB_RST_LPD_IOU0_GEM3_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRL_APB_RST_LPD_IOU0_GEM3_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_IOU0_OFFSET ,0x00000008U ,0x00000008U);
/*############################################################################################################################ */
// : PUTTING SATA IN RESET
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
Sata block level reset
PSU_CRF_APB_RST_FPD_TOP_SATA_RESET 0X1
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x00000002U ,0x00000002U)
RegMask = (CRF_APB_RST_FPD_TOP_SATA_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_RST_FPD_TOP_SATA_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x00000002U ,0x00000002U);
/*############################################################################################################################ */
// : PUTTING DP IN RESET
/*Register : DP_TX_PHY_POWER_DOWN @ 0XFD4A0238</p>
Two bits per lane. When set to 11, moves the GT to power down mode. When set to 00, GT will be in active state. bits [1:0] -
ane0 Bits [3:2] - lane 1
PSU_DP_DP_TX_PHY_POWER_DOWN_POWER_DWN 0XA
Control PHY Power down
(OFFSET, MASK, VALUE) (0XFD4A0238, 0x0000000FU ,0x0000000AU)
RegMask = (DP_DP_TX_PHY_POWER_DOWN_POWER_DWN_MASK | 0 );
RegVal = ((0x0000000AU << DP_DP_TX_PHY_POWER_DOWN_POWER_DWN_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DP_DP_TX_PHY_POWER_DOWN_OFFSET ,0x0000000FU ,0x0000000AU);
/*############################################################################################################################ */
/*Register : DP_PHY_RESET @ 0XFD4A0200</p>
Set to '1' to hold the GT in reset. Clear to release.
PSU_DP_DP_PHY_RESET_GT_RESET 0X1
Reset the transmitter PHY.
(OFFSET, MASK, VALUE) (0XFD4A0200, 0x00000002U ,0x00000002U)
RegMask = (DP_DP_PHY_RESET_GT_RESET_MASK | 0 );
RegVal = ((0x00000001U << DP_DP_PHY_RESET_GT_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (DP_DP_PHY_RESET_OFFSET ,0x00000002U ,0x00000002U);
/*############################################################################################################################ */
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
Display Port block level reset (includes DPDMA)
PSU_CRF_APB_RST_FPD_TOP_DP_RESET 0X1
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x00010000U ,0x00010000U)
RegMask = (CRF_APB_RST_FPD_TOP_DP_RESET_MASK | 0 );
RegVal = ((0x00000001U << CRF_APB_RST_FPD_TOP_DP_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x00010000U ,0x00010000U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_ps_pl_isolation_removal_data() {
// : AFI RESET
/*Register : RST_FPD_TOP @ 0XFD1A0100</p>
AF_FM0 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM0_RESET 0
AF_FM1 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM1_RESET 0
AF_FM2 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM2_RESET 0
AF_FM3 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM3_RESET 0
AF_FM4 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM4_RESET 0
AF_FM5 block level reset
PSU_CRF_APB_RST_FPD_TOP_AFI_FM5_RESET 0
FPD Block level software controlled reset
(OFFSET, MASK, VALUE) (0XFD1A0100, 0x00001F80U ,0x00000000U)
RegMask = (CRF_APB_RST_FPD_TOP_AFI_FM0_RESET_MASK | CRF_APB_RST_FPD_TOP_AFI_FM1_RESET_MASK | CRF_APB_RST_FPD_TOP_AFI_FM2_RESET_MASK | CRF_APB_RST_FPD_TOP_AFI_FM3_RESET_MASK | CRF_APB_RST_FPD_TOP_AFI_FM4_RESET_MASK | CRF_APB_RST_FPD_TOP_AFI_FM5_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM0_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM1_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM2_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM3_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM4_RESET_SHIFT
| 0x00000000U << CRF_APB_RST_FPD_TOP_AFI_FM5_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRF_APB_RST_FPD_TOP_OFFSET ,0x00001F80U ,0x00000000U);
/*############################################################################################################################ */
/*Register : RST_LPD_TOP @ 0XFF5E023C</p>
AFI FM 6
PSU_CRL_APB_RST_LPD_TOP_AFI_FM6_RESET 0
Software control register for the LPD block.
(OFFSET, MASK, VALUE) (0XFF5E023C, 0x00080000U ,0x00000000U)
RegMask = (CRL_APB_RST_LPD_TOP_AFI_FM6_RESET_MASK | 0 );
RegVal = ((0x00000000U << CRL_APB_RST_LPD_TOP_AFI_FM6_RESET_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (CRL_APB_RST_LPD_TOP_OFFSET ,0x00080000U ,0x00000000U);
/*############################################################################################################################ */
// : AFIFM INTERFACE WIDTH
/*Register : afi_fs @ 0XFD615000</p>
Select the 32/64/128-bit data width selection for the Slave 0 00: 32-bit AXI data width (default) 01: 64-bit AXI data width 1
: 128-bit AXI data width 11: reserved
PSU_FPD_SLCR_AFI_FS_DW_SS0_SEL 0x2
Select the 32/64/128-bit data width selection for the Slave 1 00: 32-bit AXI data width (default) 01: 64-bit AXI data width 1
: 128-bit AXI data width 11: reserved
PSU_FPD_SLCR_AFI_FS_DW_SS1_SEL 0x2
afi fs SLCR control register. This register is static and should not be modified during operation.
(OFFSET, MASK, VALUE) (0XFD615000, 0x00000F00U ,0x00000A00U)
RegMask = (FPD_SLCR_AFI_FS_DW_SS0_SEL_MASK | FPD_SLCR_AFI_FS_DW_SS1_SEL_MASK | 0 );
RegVal = ((0x00000002U << FPD_SLCR_AFI_FS_DW_SS0_SEL_SHIFT
| 0x00000002U << FPD_SLCR_AFI_FS_DW_SS1_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (FPD_SLCR_AFI_FS_OFFSET ,0x00000F00U ,0x00000A00U);
/*############################################################################################################################ */
/*Register : afi_fs @ 0XFF419000</p>
Select the 32/64/128-bit data width selection for the Slave 0 00: 32-bit AXI data width (default) 01: 64-bit AXI data width 1
: 128-bit AXI data width 11: reserved
PSU_LPD_SLCR_AFI_FS_DW_SS2_SEL 0x2
afi fs SLCR control register. Do not change the bits durin
(OFFSET, MASK, VALUE) (0XFF419000, 0x00000300U ,0x00000200U)
RegMask = (LPD_SLCR_AFI_FS_DW_SS2_SEL_MASK | 0 );
RegVal = ((0x00000002U << LPD_SLCR_AFI_FS_DW_SS2_SEL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (LPD_SLCR_AFI_FS_OFFSET ,0x00000300U ,0x00000200U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD360000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM0_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD360000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM0_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM0_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM0_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD370000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM1_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD370000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM1_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM1_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM1_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD380000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM2_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD380000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM2_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM2_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM2_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD390000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM3_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD390000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM3_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM3_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM3_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD3A0000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM4_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD3A0000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM4_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM4_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM4_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFD3B0000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM5_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFD3B0000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM5_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM5_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM5_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_RDCTRL @ 0XFF9B0000</p>
Configures the Read Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 128
bit enabled
PSU_AFIFM6_AFIFM_RDCTRL_FABRIC_WIDTH 0x0
Read Channel Control Register
(OFFSET, MASK, VALUE) (0XFF9B0000, 0x00000003U ,0x00000000U)
RegMask = (AFIFM6_AFIFM_RDCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM6_AFIFM_RDCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM6_AFIFM_RDCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD360014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM0_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD360014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM0_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM0_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM0_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD370014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM1_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD370014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM1_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM1_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM1_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD380014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM2_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD380014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM2_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM2_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM2_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD390014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM3_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD390014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM3_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM3_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM3_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD3A0014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM4_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD3A0014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM4_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM4_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM4_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFD3B0014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM5_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFD3B0014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM5_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM5_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM5_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
/*Register : AFIFM_WRCTRL @ 0XFF9B0014</p>
Configures the Write Channel Fabric interface width. 2'b11 : Reserved 2'b10 : 32-bit Fabric 2'b01 : 64-bit enabled 2'b00 : 12
-bit enabled
PSU_AFIFM6_AFIFM_WRCTRL_FABRIC_WIDTH 0x0
Write Channel Control Register
(OFFSET, MASK, VALUE) (0XFF9B0014, 0x00000003U ,0x00000000U)
RegMask = (AFIFM6_AFIFM_WRCTRL_FABRIC_WIDTH_MASK | 0 );
RegVal = ((0x00000000U << AFIFM6_AFIFM_WRCTRL_FABRIC_WIDTH_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (AFIFM6_AFIFM_WRCTRL_OFFSET ,0x00000003U ,0x00000000U);
/*############################################################################################################################ */
// : PS-PL POWER UP REQUEST
/*Register : REQ_PWRUP_INT_EN @ 0XFFD80118</p>
Power-up Request Interrupt Enable for PL
PSU_PMU_GLOBAL_REQ_PWRUP_INT_EN_PL 1
Power-up Request Interrupt Enable Register. Writing a 1 to this location will unmask the interrupt.
(OFFSET, MASK, VALUE) (0XFFD80118, 0x00800000U ,0x00800000U)
RegMask = (PMU_GLOBAL_REQ_PWRUP_INT_EN_PL_MASK | 0 );
RegVal = ((0x00000001U << PMU_GLOBAL_REQ_PWRUP_INT_EN_PL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (PMU_GLOBAL_REQ_PWRUP_INT_EN_OFFSET ,0x00800000U ,0x00800000U);
/*############################################################################################################################ */
/*Register : REQ_PWRUP_TRIG @ 0XFFD80120</p>
Power-up Request Trigger for PL
PSU_PMU_GLOBAL_REQ_PWRUP_TRIG_PL 1
Power-up Request Trigger Register. A write of one to this location will generate a power-up request to the PMU.
(OFFSET, MASK, VALUE) (0XFFD80120, 0x00800000U ,0x00800000U)
RegMask = (PMU_GLOBAL_REQ_PWRUP_TRIG_PL_MASK | 0 );
RegVal = ((0x00000001U << PMU_GLOBAL_REQ_PWRUP_TRIG_PL_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (PMU_GLOBAL_REQ_PWRUP_TRIG_OFFSET ,0x00800000U ,0x00800000U);
/*############################################################################################################################ */
// : POLL ON PL POWER STATUS
/*Register : REQ_PWRUP_STATUS @ 0XFFD80110</p>
Power-up Request Status for PL
PSU_PMU_GLOBAL_REQ_PWRUP_STATUS_PL 1
(OFFSET, MASK, VALUE) (0XFFD80110, 0x00800000U ,0x00000000U) */
mask_pollOnValue(PMU_GLOBAL_REQ_PWRUP_STATUS_OFFSET,0x00800000U,0x00000000U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_ps_pl_reset_config_data() {
// : PS PL RESET SEQUENCE
// : FABRIC RESET USING EMIO
/*Register : MASK_DATA_5_MSW @ 0XFF0A002C</p>
Operation is the same as MASK_DATA_0_LSW[MASK_0_LSW]
PSU_GPIO_MASK_DATA_5_MSW_MASK_5_MSW 0x8000
Maskable Output Data (GPIO Bank5, EMIO, Upper 16bits)
(OFFSET, MASK, VALUE) (0XFF0A002C, 0xFFFF0000U ,0x80000000U)
RegMask = (GPIO_MASK_DATA_5_MSW_MASK_5_MSW_MASK | 0 );
RegVal = ((0x00008000U << GPIO_MASK_DATA_5_MSW_MASK_5_MSW_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_MASK_DATA_5_MSW_OFFSET ,0xFFFF0000U ,0x80000000U);
/*############################################################################################################################ */
/*Register : DIRM_5 @ 0XFF0A0344</p>
Operation is the same as DIRM_0[DIRECTION_0]
PSU_GPIO_DIRM_5_DIRECTION_5 0x80000000
Direction mode (GPIO Bank5, EMIO)
(OFFSET, MASK, VALUE) (0XFF0A0344, 0xFFFFFFFFU ,0x80000000U)
RegMask = (GPIO_DIRM_5_DIRECTION_5_MASK | 0 );
RegVal = ((0x80000000U << GPIO_DIRM_5_DIRECTION_5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_DIRM_5_OFFSET ,0xFFFFFFFFU ,0x80000000U);
/*############################################################################################################################ */
/*Register : OEN_5 @ 0XFF0A0348</p>
Operation is the same as OEN_0[OP_ENABLE_0]
PSU_GPIO_OEN_5_OP_ENABLE_5 0x80000000
Output enable (GPIO Bank5, EMIO)
(OFFSET, MASK, VALUE) (0XFF0A0348, 0xFFFFFFFFU ,0x80000000U)
RegMask = (GPIO_OEN_5_OP_ENABLE_5_MASK | 0 );
RegVal = ((0x80000000U << GPIO_OEN_5_OP_ENABLE_5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_OEN_5_OFFSET ,0xFFFFFFFFU ,0x80000000U);
/*############################################################################################################################ */
/*Register : DATA_5 @ 0XFF0A0054</p>
Output Data
PSU_GPIO_DATA_5_DATA_5 0x80000000
Output Data (GPIO Bank5, EMIO)
(OFFSET, MASK, VALUE) (0XFF0A0054, 0xFFFFFFFFU ,0x80000000U)
RegMask = (GPIO_DATA_5_DATA_5_MASK | 0 );
RegVal = ((0x80000000U << GPIO_DATA_5_DATA_5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_DATA_5_OFFSET ,0xFFFFFFFFU ,0x80000000U);
/*############################################################################################################################ */
mask_delay(1);
/*############################################################################################################################ */
// : FABRIC RESET USING DATA_5 TOGGLE
/*Register : DATA_5 @ 0XFF0A0054</p>
Output Data
PSU_GPIO_DATA_5_DATA_5 0X00000000
Output Data (GPIO Bank5, EMIO)
(OFFSET, MASK, VALUE) (0XFF0A0054, 0xFFFFFFFFU ,0x00000000U)
RegMask = (GPIO_DATA_5_DATA_5_MASK | 0 );
RegVal = ((0x00000000U << GPIO_DATA_5_DATA_5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_DATA_5_OFFSET ,0xFFFFFFFFU ,0x00000000U);
/*############################################################################################################################ */
mask_delay(1);
/*############################################################################################################################ */
// : FABRIC RESET USING DATA_5 TOGGLE
/*Register : DATA_5 @ 0XFF0A0054</p>
Output Data
PSU_GPIO_DATA_5_DATA_5 0x80000000
Output Data (GPIO Bank5, EMIO)
(OFFSET, MASK, VALUE) (0XFF0A0054, 0xFFFFFFFFU ,0x80000000U)
RegMask = (GPIO_DATA_5_DATA_5_MASK | 0 );
RegVal = ((0x80000000U << GPIO_DATA_5_DATA_5_SHIFT
| 0 ) & RegMask); */
PSU_Mask_Write (GPIO_DATA_5_OFFSET ,0xFFFFFFFFU ,0x80000000U);
/*############################################################################################################################ */
return 1;
}
unsigned long psu_ddr_phybringup_data() {
unsigned int regval = 0;
int dpll_divisor;
dpll_divisor = (Xil_In32(0xFD1A0080U) & 0x00003F00U) >> 0x00000008U;
prog_reg (0xFD1A0080U, 0x00003F00U, 0x00000008U, 0x00000005U);
prog_reg (0xFD080028U, 0x00000001U, 0x00000000U, 0x00000001U);
Xil_Out32(0xFD080004U, 0x00040003U);
while ((Xil_In32(0xFD080030U) & 0x00000001U) != 0x00000001U);
prog_reg (0xFD080684U, 0x06000000U, 0x00000019U, 0x00000001U);
prog_reg (0xFD0806A4U, 0x06000000U, 0x00000019U, 0x00000001U);
prog_reg (0xFD0806C4U, 0x06000000U, 0x00000019U, 0x00000001U);
prog_reg (0xFD0806E4U, 0x06000000U, 0x00000019U, 0x00000001U);
prog_reg (0xFD1A0080, 0x3F00, 0x8, dpll_divisor);
Xil_Out32(0xFD080004U, 0x40040071U);
while ((Xil_In32(0xFD080030U) & 0x00000001U) != 0x00000001U);
Xil_Out32(0xFD080004U, 0x40040001U);
while ((Xil_In32(0xFD080030U) & 0x00000001U) != 0x00000001U);
// PHY BRINGUP SEQ
while ((Xil_In32(0xFD080030U) & 0x0000000FU) != 0x0000000FU);
prog_reg (0xFD080004U, 0x00000001U, 0x00000000U, 0x00000001U);
//poll for PHY initialization to complete
while ((Xil_In32(0xFD080030U) & 0x000000FFU) != 0x0000001FU);
Xil_Out32(0xFD0701B0U, 0x00000001U);
Xil_Out32(0xFD070320U, 0x00000001U);
while ((Xil_In32(0xFD070004U) & 0x0000000FU) != 0x00000001U);
prog_reg (0xFD080014U, 0x00000040U, 0x00000006U, 0x00000001U);
Xil_Out32(0xFD080004, 0x0004FE01); //PUB_PIR
regval = Xil_In32(0xFD080030); //PUB_PGSR0
while(regval != 0x80000FFF){
regval = Xil_In32(0xFD080030); //PUB_PGSR0
}
// Run Vref training in static read mode
Xil_Out32(0xFD080200U, 0x100091C7U);
Xil_Out32(0xFD080018U, 0x00F01EF2U);
Xil_Out32(0xFD08001CU, 0x55AA5498U);
Xil_Out32(0xFD08142CU, 0x00041830U);
Xil_Out32(0xFD08146CU, 0x00041830U);
Xil_Out32(0xFD0814ACU, 0x00041830U);
Xil_Out32(0xFD0814ECU, 0x00041830U);
Xil_Out32(0xFD08152CU, 0x00041830U);
Xil_Out32(0xFD080004, 0x00060001); //PUB_PIR
regval = Xil_In32(0xFD080030); //PUB_PGSR0
while((regval & 0x80004001) != 0x80004001){
regval = Xil_In32(0xFD080030); //PUB_PGSR0
}
// Vref training is complete, disabling static read mode
Xil_Out32(0xFD080200U, 0x800091C7U);
Xil_Out32(0xFD080018U, 0x00F12302U);
Xil_Out32(0xFD08001CU, 0x55AA5480U);
Xil_Out32(0xFD08142CU, 0x00041800U);
Xil_Out32(0xFD08146CU, 0x00041800U);
Xil_Out32(0xFD0814ACU, 0x00041800U);
Xil_Out32(0xFD0814ECU, 0x00041800U);
Xil_Out32(0xFD08152CU, 0x00041800U);
Xil_Out32(0xFD080004, 0x0000C001); //PUB_PIR
regval = Xil_In32(0xFD080030); //PUB_PGSR0
while((regval & 0x80000C01) != 0x80000C01){
regval = Xil_In32(0xFD080030); //PUB_PGSR0
}
Xil_Out32(0xFD070180U, 0x01000040U);
Xil_Out32(0xFD070060U, 0x00000000U);
prog_reg (0xFD080014U, 0x00000040U, 0x00000006U, 0x00000000U);
return 1;
}
/**
* CRL_APB Base Address
*/
#define CRL_APB_BASEADDR 0XFF5E0000U
#define CRL_APB_RST_LPD_IOU0 ( ( CRL_APB_BASEADDR ) + 0X00000230U )
#define CRL_APB_RST_LPD_IOU1 ( ( CRL_APB_BASEADDR ) + 0X00000234U )
#define CRL_APB_RST_LPD_IOU2 ( ( CRL_APB_BASEADDR ) + 0X00000238U )
#define CRL_APB_RST_LPD_TOP ( ( CRL_APB_BASEADDR ) + 0X0000023CU )
#define CRL_APB_IOU_SWITCH_CTRL ( ( CRL_APB_BASEADDR ) + 0X0000009CU )
/**
* CRF_APB Base Address
*/
#define CRF_APB_BASEADDR 0XFD1A0000U
#define CRF_APB_RST_FPD_TOP ( ( CRF_APB_BASEADDR ) + 0X00000100U )
#define CRF_APB_GPU_REF_CTRL ( ( CRF_APB_BASEADDR ) + 0X00000084U )
#define CRF_APB_RST_DDR_SS ( ( CRF_APB_BASEADDR ) + 0X00000108U )
#define PSU_MASK_POLL_TIME 1100000
int mask_pollOnValue(u32 add , u32 mask, u32 value ) {
volatile u32 *addr = (volatile u32*)(unsigned long) add;
int i = 0;
while ((*addr & mask)!= value) {
if (i == PSU_MASK_POLL_TIME) {
return 0;
}
i++;
}
return 1;
//xil_printf("MaskPoll : 0x%x --> 0x%x \n \r" , add, *addr);
}
int mask_poll(u32 add , u32 mask) {
volatile u32 *addr = (volatile u32*)(unsigned long) add;
int i = 0;
while (!(*addr & mask)) {
if (i == PSU_MASK_POLL_TIME) {
return 0;
}
i++;
}
return 1;
//xil_printf("MaskPoll : 0x%x --> 0x%x \n \r" , add, *addr);
}
void mask_delay(u32 delay) {
usleep (delay);
}
u32 mask_read(u32 add , u32 mask ) {
volatile u32 *addr = (volatile u32*)(unsigned long) add;
u32 val = (*addr & mask);
//xil_printf("MaskRead : 0x%x --> 0x%x \n \r" , add, val);
return val;
}
//Following SERDES programming sequences that a user need to follow to work around the known limitation with SERDES.
//These sequences should done before STEP 1 and STEP 2 as described in previous section. These programming steps are
//required for current silicon version and are likely to undergo further changes with subsequent silicon versions.
int serdes_fixcal_code() {
int MaskStatus = 1;
// L3_TM_CALIB_DIG19
Xil_Out32(0xFD40EC4C,0x00000020);
//ICM_CFG0
Xil_Out32(0xFD410010,0x00000001);
//is calibration done, polling on L3_CALIB_DONE_STATUS
MaskStatus = mask_poll(0xFD40EF14, 0x2);
if (MaskStatus == 0)
{
xil_printf("SERDES initialization timed out\n\r");
}
unsigned int tmp_0_1;
tmp_0_1 = mask_read(0xFD400B0C, 0x3F);
unsigned int tmp_0_2 = tmp_0_1 & (0x7);
unsigned int tmp_0_3 = tmp_0_1 & (0x38);
//Configure ICM for de-asserting CMN_Resetn
Xil_Out32(0xFD410010,0x00000000);
Xil_Out32(0xFD410014,0x00000000);
unsigned int tmp_0_2_mod = (tmp_0_2 <<1) | (0x1);
tmp_0_2_mod = (tmp_0_2_mod <<4);
tmp_0_3 = tmp_0_3 >>3;
Xil_Out32(0xFD40EC4C,tmp_0_3);
//L3_TM_CALIB_DIG18
Xil_Out32(0xFD40EC48,tmp_0_2_mod);
return MaskStatus;
}
int serdes_enb_coarse_saturation() {
//Enable PLL Coarse Code saturation Logic
Xil_Out32(0xFD402094,0x00000010);
Xil_Out32(0xFD406094,0x00000010);
Xil_Out32(0xFD40A094,0x00000010);
Xil_Out32(0xFD40E094,0x00000010);
return 1;
}
int init_serdes() {
int status = 1;
status &= psu_resetin_init_data();
status &= serdes_fixcal_code();
status &= serdes_enb_coarse_saturation();
status &= psu_serdes_init_data();
status &= psu_resetout_init_data();
return status;
}
void init_peripheral()
{
unsigned int RegValue;
/* Turn on IOU Clock */
//Xil_Out32( CRL_APB_IOU_SWITCH_CTRL, 0x01001500);
/* Release all resets in the IOU */
Xil_Out32( CRL_APB_RST_LPD_IOU0, 0x00000000);
Xil_Out32( CRL_APB_RST_LPD_IOU1, 0x00000000);
Xil_Out32( CRL_APB_RST_LPD_IOU2, 0x00000000);
/* Activate GPU clocks */
//Xil_Out32(CRF_APB_GPU_REF_CTRL, 0x07001500);
/* Take LPD out of reset except R5 */
RegValue = Xil_In32(CRL_APB_RST_LPD_TOP);
RegValue &= 0x7;
Xil_Out32( CRL_APB_RST_LPD_TOP, RegValue);
/* Take most of FPD out of reset */
Xil_Out32( CRF_APB_RST_FPD_TOP, 0x00000000);
/* Making DPDMA as secure */
unsigned int tmp_regval;
tmp_regval = Xil_In32(0xFD690040);
tmp_regval &= ~0x00000001;
Xil_Out32(0xFD690040, tmp_regval);
/* Making PCIe as secure */
tmp_regval = Xil_In32(0xFD690030);
tmp_regval &= ~0x00000001;
Xil_Out32(0xFD690030, tmp_regval);
}
int psu_init_xppu_aper_ram() {
unsigned long APER_OFFSET = 0xFF981000;
int i = 0;
for (; i <= 400; i++) {
PSU_Mask_Write (APER_OFFSET ,0xF80FFFFFU ,0x08080000U);
APER_OFFSET = APER_OFFSET + 0x4;
}
return 0;
}
int psu_lpd_protection() {
psu_init_xppu_aper_ram();
psu_lpd_xppu_data();
return 0;
}
int psu_ddr_protection() {
psu_ddr_xmpu0_data();
psu_ddr_xmpu1_data();
psu_ddr_xmpu2_data();
psu_ddr_xmpu3_data();
psu_ddr_xmpu4_data();
psu_ddr_xmpu5_data();
return 0;
}
int psu_ocm_protection() {
psu_ocm_xmpu_data();
return 0;
}
int psu_fpd_protection() {
psu_fpd_xmpu_data();
return 0;
}
int psu_protection_lock() {
psu_protection_lock_data();
return 0;
}
int psu_protection() {
psu_ddr_protection();
psu_ocm_protection();
psu_fpd_protection();
psu_lpd_protection();
return 0;
}
int
psu_init()
{
int status = 1;
status &= psu_mio_init_data ();
status &= psu_pll_init_data ();
status &= psu_clock_init_data ();
status &= psu_ddr_init_data ();
status &= psu_ddr_phybringup_data ();
status &= psu_peripherals_init_data ();
status &= init_serdes();
init_peripheral ();
status &= psu_peripherals_powerdwn_data ();
if (status == 0) {
return 1;
}
return 0;
}