plat/brcm/board/stingray/src/bl2_setup.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2016-2020, Broadcom
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch_helpers.h>
 #include <common/bl_common.h>
 #include <common/debug.h>
 #include <drivers/arm/sp805.h>
 #include <drivers/delay_timer.h>
 #include <lib/mmio.h>

 #include <chimp.h>
 #include <chip_id.h>
 #include <cmn_plat_util.h>
 #include <dmu.h>
 #include <emmc_api.h>
 #include <fru.h>
 #ifdef USE_GPIO
 #include <drivers/gpio.h>
 #include <iproc_gpio.h>
 #endif
 #include <platform_def.h>
 #include <sotp.h>
 #include <swreg.h>
 #include <sr_utils.h>
 #ifdef USE_DDR
 #include <ddr_init.h>
 #else
 #include <ext_sram_init.h>
 #endif
 #if DRIVER_OCOTP_ENABLE
 #include <ocotp.h>
 #endif
 #include "board_info.h"

 #define WORD_SIZE              8
 #define SWREG_AVS_OTP_OFFSET   (13 * WORD_SIZE) /* 13th row byte offset */
 #define AON_GPIO_OTP_OFFSET    (28 * WORD_SIZE) /* 28th row byte offset */
 #define BYTES_TO_READ          8

 /* OTP voltage step definitions */
 #define MVOLT_STEP_MAX         0x18  /* 1v */
 #define MVOLT_PER_STEP         10    /* 0.01mv per step */
 #define MVOLT_BASE             760   /* 0.76v */

 #define STEP_TO_UVOLTS(step) \
 	((MVOLT_BASE + (MVOLT_PER_STEP * (step))) * 1000)

 #define GET_BITS(first, last, data) \
 	((data >> first) & ((1 << (last - first + 1)) - 1))

 /*
  * SW-REG OTP encoding:
  *
  * SWREG_bits[11:0]  = OTP 13th row 12 bits[55:44]
  * SWREG_bits[11:10] - Valid Bits (0x2 - valid, if not 0x2 - Invalid)
  * SWREG_bits[9:5]   - iHost03, iHost12
  * SWREG_bits[4:0]   - Core VDDC
  */
 #define SWREG_OTP_BITS_START        12    /* 44th bit in MSB 32-bits */
 #define SWREG_OTP_BITS_END          23    /* 55th bit in MSB 32-bits */
 #define SWREG_VDDC_FIELD_START      0
 #define SWREG_VDDC_FIELD_END        4
 #define SWREG_IHOST_FIELD_START     5
 #define SWREG_IHOST_FIELD_END       9
 #define SWREG_VALID_BIT_START       10
 #define SWREG_VALID_BIT_END         11
 #define SWREG_VALID_BITS            0x2

 /*
  * Row 13 bit 56 is programmed as '1' today. It is not being used, so plan
  * is to flip this bit to '0' for B1 rev. Hence SW can leverage this bit
  * to identify Bx chip to program different sw-regulators.
  */
 #define SPARE_BIT             24

 #define IS_SR_B0(data)        (((data) >> SPARE_BIT) & 0x1)

 #if DRIVER_OCOTP_ENABLE
 static struct otpc_map otp_stingray_map = {
 	.otpc_row_size = 2,
 	.data_r_offset = {0x10, 0x5c},
 	.data_w_offset = {0x2c, 0x64},
 	.word_size = 8,
 	.stride = 8,
 };
 #endif

 void plat_bcm_bl2_early_platform_setup(void)
 {
 	/* Select UART0 for AP via mux setting*/
 	if (PLAT_BRCM_BOOT_UART_BASE == UART0_BASE_ADDR) {
 		mmio_write_32(UART0_SIN_MODE_SEL_CONTROL, 1);
 		mmio_write_32(UART0_SOUT_MODE_SEL_CONTROL, 1);
 	}
 }

 #ifdef USE_NAND
 static void brcm_stingray_nand_init(void)
 {
 	unsigned int val;
 	unsigned int nand_idm_reset_control = 0x68e0a800;

 	VERBOSE(" stingray nand init start.\n");

 	/* Reset NAND */
 	VERBOSE(" - reset nand\n");
 	val = mmio_read_32((uintptr_t)(nand_idm_reset_control + 0x0));
 	mmio_write_32((uintptr_t)(nand_idm_reset_control + 0x0), val | 0x1);
 	udelay(500);
 	val = mmio_read_32((uintptr_t)(nand_idm_reset_control + 0x0));
 	mmio_write_32((uintptr_t)(nand_idm_reset_control + 0x0), val & ~0x1);
 	udelay(500);

 	VERBOSE(" stingray nand init done.\n");
 }
 #endif

 #if defined(USE_PAXB) || defined(USE_PAXC) || defined(USE_SATA)
 #define PCIE_RESCAL_CFG_0 0x40000130
 #define PCIE_CFG_RESCAL_RSTB_R (1 << 16)
 #define PCIE_CFG_RESCAL_PWRDNB_R (1 << 8)
 #define PCIE_RESCAL_STATUS_0 0x4000014c
 #define PCIE_STAT_PON_VALID_R (1 << 0)
 #define PCIE_RESCAL_OUTPUT_STATUS 0x40000154
 #define CDRU_PCIE_RESET_N_R (1 << CDRU_MISC_RESET_CONTROL__CDRU_PCIE_RESET_N_R)

 #ifdef EMULATION_SETUP
 static void brcm_stingray_pcie_reset(void)
 {
 }
 #else
 static void brcm_stingray_pcie_reset(void)
 {
 	unsigned int data;
 	int try;

 	if (bcm_chimp_is_nic_mode()) {
 		INFO("NIC mode detected; PCIe reset/rescal not executed\n");
 		return;
 	}

 	mmio_clrbits_32(CDRU_MISC_RESET_CONTROL, CDRU_PCIE_RESET_N_R);
 	mmio_setbits_32(CDRU_MISC_RESET_CONTROL, CDRU_PCIE_RESET_N_R);
 	/* Release reset */
 	mmio_setbits_32(PCIE_RESCAL_CFG_0, PCIE_CFG_RESCAL_RSTB_R);
 	mdelay(1);
 	/* Power UP */
 	mmio_setbits_32(PCIE_RESCAL_CFG_0,
 			(PCIE_CFG_RESCAL_RSTB_R | PCIE_CFG_RESCAL_PWRDNB_R));

 	try = 1000;
 	do {
 		udelay(1);
 		data = mmio_read_32(PCIE_RESCAL_STATUS_0);
 		try--;
 	} while ((data & PCIE_STAT_PON_VALID_R) == 0x0 && (try > 0));

 	if (try <= 0)
 		ERROR("PCIE_RESCAL_STATUS_0: 0x%x\n", data);

 	VERBOSE("PCIE_SATA_RESCAL_STATUS_0 0x%x.\n",
 			mmio_read_32(PCIE_RESCAL_STATUS_0));
 	VERBOSE("PCIE_SATA_RESCAL_OUTPUT_STATUS 0x%x.\n",
 			mmio_read_32(PCIE_RESCAL_OUTPUT_STATUS));
 	INFO("PCIE SATA Rescal Init done\n");
 }
 #endif /* EMULATION_SETUP */
 #endif /* USE_PAXB || USE_PAXC || USE_SATA */

 #ifdef USE_PAXC
 void brcm_stingray_chimp_check_and_fastboot(void)
 {
 	int fastboot_init_result;

 	if (bcm_chimp_is_nic_mode())
 		/* Do not wait here */
 		return;

 #if WARMBOOT_DDR_S3_SUPPORT
 	/*
 	 * Currently DDR shmoo parameters and QSPI boot source are
 	 * tied. DDR shmoo parameters are stored in QSPI, which is
 	 * used for warmboot.
 	 * Do not reset nitro for warmboot
 	 */
 	if (is_warmboot() && (boot_source_get() == BOOT_SOURCE_QSPI))
 		return;
 #endif /* WARMBOOT_DDR_S3_SUPPORT */

 	/*
 	 * Not in NIC mode,
 	 * initiate fastboot (if enabled)
 	 */
 	if (FASTBOOT_TYPE == CHIMP_FASTBOOT_NITRO_RESET) {

 		VERBOSE("Bring up Nitro/ChiMP\n");

 		if (boot_source_get() == BOOT_SOURCE_QSPI)
 			WARN("Nitro boots from QSPI when AP has booted from QSPI.\n");
 		brcm_stingray_set_qspi_mux(0);
 		VERBOSE("Nitro controls the QSPI\n");
 	}

 	fastboot_init_result = bcm_chimp_initiate_fastboot(FASTBOOT_TYPE);
 	if (fastboot_init_result && boot_source_get() != BOOT_SOURCE_QSPI)
 		ERROR("Nitro init error %d. Status: 0x%x; bpe_mod reg: 0x%x\n"
 			"fastboot register: 0x%x; handshake register 0x%x\n",
 			fastboot_init_result,
 			bcm_chimp_read_ctrl(CHIMP_REG_CTRL_BPE_STAT_REG),
 			bcm_chimp_read_ctrl(CHIMP_REG_CTRL_BPE_MODE_REG),
 			bcm_chimp_read_ctrl(CHIMP_REG_CTRL_FSTBOOT_PTR_REG),
 			bcm_chimp_read(CHIMP_REG_ECO_RESERVED));

 	/*
 	 * CRMU watchdog kicks is an example, which is L1 reset,
 	 * does not clear Nitro scratch pad ram.
 	 * For Nitro resets: Clear the Nitro health status memory.
 	 */
 	bcm_chimp_write((CHIMP_REG_CHIMP_SCPAD + CHIMP_HEALTH_STATUS_OFFSET),
 			0);
 }
 #endif

 void set_ihost_vddc_swreg(uint32_t ihost_uvolts, uint32_t vddc_uvolts)
 {
 	NOTICE("ihost_uvolts: %duv, vddc_uvolts: %duv\n",
 	       ihost_uvolts, vddc_uvolts);

 	set_swreg(VDDC_CORE, vddc_uvolts);
 	set_swreg(IHOST03, ihost_uvolts);
 	set_swreg(IHOST12, ihost_uvolts);
 }

 /*
  * Reads SWREG AVS OTP bits (13th row) with ECC enabled and get voltage
  * defined in OTP if valid OTP is found
  */
 void read_avs_otp_bits(uint32_t *ihost_uvolts, uint32_t *vddc_uvolts)
 {
 	uint32_t offset = SWREG_AVS_OTP_OFFSET;
 	uint32_t ihost_step, vddc_step;
 	uint32_t avs_bits;
 	uint32_t buf[2];

 	if (bcm_otpc_read(offset, &buf[0], BYTES_TO_READ, 1) == -1)
 		return;

 	VERBOSE("AVS OTP %d ROW: 0x%x.0x%x\n",
 		offset/WORD_SIZE, buf[1], buf[0]);

 	/* get voltage readings from AVS OTP bits */
 	avs_bits = GET_BITS(SWREG_OTP_BITS_START,
 			    SWREG_OTP_BITS_END,
 			    buf[1]);

 	/* check for valid otp bits */
 	if (GET_BITS(SWREG_VALID_BIT_START, SWREG_VALID_BIT_END, avs_bits) !=
 	    SWREG_VALID_BITS) {
 		WARN("Invalid AVS OTP bits at %d row\n", offset/WORD_SIZE);
 		return;
 	}

 	/* get ihost and vddc step value */
 	vddc_step = GET_BITS(SWREG_VDDC_FIELD_START,
 			     SWREG_VDDC_FIELD_END,
 			     avs_bits);

 	ihost_step = GET_BITS(SWREG_IHOST_FIELD_START,
 			      SWREG_IHOST_FIELD_END,
 			      avs_bits);

 	if ((ihost_step > MVOLT_STEP_MAX) || (vddc_step > MVOLT_STEP_MAX)) {
 		WARN("OTP entry invalid\n");
 		return;
 	}

 	/* get voltage in micro-volts */
 	*ihost_uvolts = STEP_TO_UVOLTS(ihost_step);
 	*vddc_uvolts = STEP_TO_UVOLTS(vddc_step);
 }

 /*
  * This api reads otp bits and program internal swreg's - ihos12, ihost03,
  * vddc_core and ddr_core based on different chip. External swreg's
  * programming will be done from crmu.
  *
  * For A2 chip:
  *   Read OTP row 20, bit 50. This bit will be set for A2 chip. Once A2 chip is
  *   found, read AVS OTP row 13, 12bits[55:44], if valid otp bits are found
  *   then set ihost and vddc according to avs otp bits else set them to 0.94v
  *   and 0.91v respectively. Also update the firmware after setting voltage.
  *
  * For B0 chip:
  *   Read OTP row 13, bit 56. This bit will be set for B0 chip. Once B0 chip is
  *   found then set ihost and vddc to 0.95v and ddr_core to 1v. No AVS OTP bits
  *   are used get ihost/vddc voltages.
  *
  * For B1 chip:
  *   Read AVS OTP row 13, 12bits[55:44], if valid otp bits are found then set
  *   ihost and vddc according to avs otp bits else set them to 0.94v and 0.91v
  *   respectively.
  */
 void set_swreg_based_on_otp(void)
 {
 	/* default voltage if no valid OTP */
 	uint32_t vddc_uvolts = VDDC_CORE_DEF_VOLT;
 	uint32_t ihost_uvolts = IHOST_DEF_VOLT;
 	uint32_t ddrc_uvolts;
 	uint32_t offset;
 	uint32_t buf[2];

 	offset = SWREG_AVS_OTP_OFFSET;
 	if (bcm_otpc_read(offset, &buf[0], BYTES_TO_READ, 1) == -1)
 		return;

 	VERBOSE("OTP %d ROW: 0x%x.0x%x\n",
 		offset/WORD_SIZE, buf[1], buf[0]);

 	if (IS_SR_B0(buf[1])) {
 		/* don't read AVS OTP for B0 */
 		ihost_uvolts = B0_IHOST_DEF_VOLT;
 		vddc_uvolts = B0_VDDC_CORE_DEF_VOLT;
 		ddrc_uvolts = B0_DDR_VDDC_DEF_VOLT;
 	} else {
 		read_avs_otp_bits(&ihost_uvolts, &vddc_uvolts);
 	}

 #if (IHOST_REG_TYPE == IHOST_REG_INTEGRATED) && \
 	(VDDC_REG_TYPE == VDDC_REG_INTEGRATED)
 	/* enable IHOST12 cluster before changing voltage */
 	NOTICE("Switching on the Regulator idx: %u\n",
 	       SWREG_IHOST1_DIS);
 	mmio_clrsetbits_32(CRMU_SWREG_CTRL_ADDR,
 			   BIT(SWREG_IHOST1_DIS),
 			   BIT(SWREG_IHOST1_REG_RESETB));

 	/* wait for regulator supply gets stable */
 	while (!(mmio_read_32(CRMU_SWREG_STATUS_ADDR) &
 	       (1 << SWREG_IHOST1_PMU_STABLE)))
 		;

 	INFO("Regulator supply got stable\n");

 #ifndef DEFAULT_SWREG_CONFIG
 	swreg_firmware_update();
 #endif

 	set_ihost_vddc_swreg(ihost_uvolts, vddc_uvolts);
 #endif
 	if (IS_SR_B0(buf[1])) {
 		NOTICE("ddrc_uvolts: %duv\n", ddrc_uvolts);
 		set_swreg(DDR_VDDC, ddrc_uvolts);
 	}
 }

 #ifdef USE_DDR
 static struct ddr_info ddr_info;
 #endif
 #ifdef USE_FRU
 static struct fru_area_info fru_area[FRU_MAX_NR_AREAS];
 static struct fru_board_info board_info;
 static struct fru_time fru_tm;
 static uint8_t fru_tbl[BCM_MAX_FRU_LEN];

 static void board_detect_fru(void)
 {
 	uint32_t i, result;
 	int ret = -1;

 	result = bcm_emmc_init(false);
 	if (!result) {
 		ERROR("eMMC init failed\n");
 		return;
 	}

 	/* go through eMMC boot partitions looking for FRU table */
 	for (i = EMMC_BOOT_PARTITION1; i <= EMMC_BOOT_PARTITION2; i++) {
 		result = emmc_partition_select(i);
 		if (!result) {
 			ERROR("Switching to eMMC part %u failed\n", i);
 			return;
 		}

 		result = emmc_read(BCM_FRU_TBL_OFFSET, (uintptr_t)fru_tbl,
 				   BCM_MAX_FRU_LEN, BCM_MAX_FRU_LEN);
 		if (!result) {
 			ERROR("Failed to read from eMMC part %u\n", i);
 			return;
 		}

 		/*
 		 * Run sanity check and checksum to make sure valid FRU table
 		 * is detected
 		 */
 		ret = fru_validate(fru_tbl, fru_area);
 		if (ret < 0) {
 			WARN("FRU table not found in eMMC part %u\n", i);
 			continue;
 		}

 		/* parse DDR information from FRU table */
 		ret = fru_parse_ddr(fru_tbl, &fru_area[FRU_AREA_INTERNAL],
 				    &ddr_info);
 		if (ret < 0) {
 			WARN("No FRU DDR info found in eMMC part %u\n", i);
 			continue;
 		}

 		/* parse board information from FRU table */
 		ret = fru_parse_board(fru_tbl, &fru_area[FRU_AREA_BOARD_INFO],
 				      &board_info);
 		if (ret < 0) {
 			WARN("No FRU board info found in eMMC part %u\n", i);
 			continue;
 		}

 		/* if we reach here, valid FRU table is parsed */
 		break;
 	}

 	if (ret < 0) {
 		WARN("FRU table missing for this board\n");
 		return;
 	}

 	for (i = 0; i < BCM_MAX_NR_DDR; i++) {
 		INFO("DDR channel index: %d\n", ddr_info.mcb[i].idx);
 		INFO("DDR size %u GB\n", ddr_info.mcb[i].size_mb / 1024);
 		INFO("DDR ref ID by SW (Not MCB Ref ID) 0x%x\n",
 		     ddr_info.mcb[i].ref_id);
 	}

 	fru_format_time(board_info.mfg_date, &fru_tm);

 	INFO("**** FRU board information ****\n");
 	INFO("Language 0x%x\n", board_info.lang);
 	INFO("Manufacturing Date %u.%02u.%02u, %02u:%02u\n",
 	     fru_tm.year, fru_tm.month, fru_tm.day,
 	     fru_tm.hour, fru_tm.min);
 	INFO("Manufacturing Date(Raw) 0x%x\n", board_info.mfg_date);
 	INFO("Manufacturer %s\n", board_info.manufacturer);
 	INFO("Product Name %s\n", board_info.product_name);
 	INFO("Serial number %s\n", board_info.serial_number);
 	INFO("Part number %s\n", board_info.part_number);
 	INFO("File ID %s\n", board_info.file_id);
 }
 #endif /* USE_FRU */

 #ifdef USE_GPIO

 #define INVALID_GPIO    0xffff

 static const int gpio_cfg_bitmap[MAX_NR_GPIOS] = {
 #ifdef BRD_DETECT_GPIO_BIT0
 	BRD_DETECT_GPIO_BIT0,
 #else
 	INVALID_GPIO,
 #endif
 #ifdef BRD_DETECT_GPIO_BIT1
 	BRD_DETECT_GPIO_BIT1,
 #else
 	INVALID_GPIO,
 #endif
 #ifdef BRD_DETECT_GPIO_BIT2
 	BRD_DETECT_GPIO_BIT2,
 #else
 	INVALID_GPIO,
 #endif
 #ifdef BRD_DETECT_GPIO_BIT3
 	BRD_DETECT_GPIO_BIT3,
 #else
 	INVALID_GPIO,
 #endif
 };

 static uint8_t gpio_bitmap;

 /*
  * Use an odd number to avoid potential conflict with public GPIO level
  * defines
  */
 #define GPIO_STATE_FLOAT         15

 /*
  * If GPIO_SUPPORT_FLOAT_DETECTION is disabled, simply return GPIO level
  *
  * If GPIO_SUPPORT_FLOAT_DETECTION is enabled, add additional test for possible
  * pin floating (unconnected) scenario. This support is assuming externally
  * applied pull up / pull down will have a stronger pull than the internal pull
  * up / pull down.
  */
 static uint8_t gpio_get_state(int gpio)
 {
 	uint8_t val;

 	/* set direction to GPIO input */
 	gpio_set_direction(gpio, GPIO_DIR_IN);

 #ifndef GPIO_SUPPORT_FLOAT_DETECTION
 	if (gpio_get_value(gpio) == GPIO_LEVEL_HIGH)
 		val = GPIO_LEVEL_HIGH;
 	else
 		val = GPIO_LEVEL_LOW;

 	return val;
 #else
 	/*
 	 * Enable internal pull down. If GPIO level is still high, there must
 	 * be an external pull up
 	 */
 	gpio_set_pull(gpio, GPIO_PULL_DOWN);
 	if (gpio_get_value(gpio) == GPIO_LEVEL_HIGH) {
 		val = GPIO_LEVEL_HIGH;
 		goto exit;
 	}

 	/*
 	 * Enable internal pull up. If GPIO level is still low, there must
 	 * be an external pull down
 	 */
 	gpio_set_pull(gpio, GPIO_PULL_UP);
 	if (gpio_get_value(gpio) == GPIO_LEVEL_LOW) {
 		val = GPIO_LEVEL_LOW;
 		goto exit;
 	}

 	/* if reached here, the pin must be not connected */
 	val = GPIO_STATE_FLOAT;

 exit:
 	/* make sure internall pull is disabled */
 	if (gpio_get_pull(gpio) != GPIO_PULL_NONE)
 		gpio_set_pull(gpio, GPIO_PULL_NONE);

 	return val;
 #endif
 }

 static void board_detect_gpio(void)
 {
 	unsigned int i, val;
 	int gpio;

 	iproc_gpio_init(IPROC_GPIO_S_BASE, IPROC_GPIO_NR,
 			IPROC_IOPAD_MODE_BASE, HSLS_IOPAD_BASE);

 	gpio_bitmap = 0;
 	for (i = 0; i < MAX_NR_GPIOS; i++) {
 		if (gpio_cfg_bitmap[i] == INVALID_GPIO)
 			continue;

 		/*
 		 * Construct the bitmap based on GPIO value. Floating pin
 		 * detection is a special case. As soon as a floating pin is
 		 * detected, a special value of MAX_GPIO_BITMAP_VAL is
 		 * assigned and we break out of the loop immediately
 		 */
 		gpio = gpio_cfg_bitmap[i];
 		val = gpio_get_state(gpio);
 		if (val == GPIO_STATE_FLOAT) {
 			gpio_bitmap = MAX_GPIO_BITMAP_VAL;
 			break;
 		}

 		if (val == GPIO_LEVEL_HIGH)
 			gpio_bitmap |= BIT(i);
 	}

 	memcpy(&ddr_info, &gpio_ddr_info[gpio_bitmap], sizeof(ddr_info));
 	INFO("Board detection GPIO bitmap = 0x%x\n", gpio_bitmap);
 }
 #endif /* USE_GPIO */

 static void bcm_board_detect(void)
 {
 #ifdef DDR_LEGACY_MCB_SUPPORTED
 	/* Loading default DDR info */
 	memcpy(&ddr_info, &default_ddr_info, sizeof(ddr_info));
 #endif
 #ifdef USE_FRU
 	board_detect_fru();
 #endif
 #ifdef USE_GPIO
 	board_detect_gpio();
 #endif
 }

 static void dump_persistent_regs(void)
 {
 	NOTICE("pr0: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG0));
 	NOTICE("pr1: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG1));
 	NOTICE("pr2: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG2));
 	NOTICE("pr3: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG3));
 	NOTICE("pr4: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG4));
 	NOTICE("pr5: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG5));
 	NOTICE("pr6: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG6));
 	NOTICE("pr7: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG7));
 	NOTICE("pr8: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG8));
 	NOTICE("pr9: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG9));
 	NOTICE("pr10: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG10));
 	NOTICE("pr11: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG11));
 }

 void plat_bcm_bl2_plat_arch_setup(void)
 {
 	if (chip_get_rev_id_major() == CHIP_REV_MAJOR_AX) {
 		if (!(sotp_mem_read(SOTP_ATF_CFG_ROW_ID, SOTP_ROW_NO_ECC) &
 		      SOTP_ATF_WATCHDOG_ENABLE_MASK)) {
 			/*
 			 * Stop sp805 watchdog timer immediately.
 			 * It might has been set up by MCU patch earlier for
 			 * eMMC workaround.
 			 *
 			 * Note the watchdog timer started in CRMU has a very
 			 * short timeout and needs to be stopped immediately.
 			 * Down below we restart it with a much longer timeout
 			 * for BL2 and BL31
 			 */
 			sp805_stop(ARM_SP805_TWDG_BASE);
 		}
 	}

 #if !BRCM_DISABLE_TRUSTED_WDOG
 	/*
 	 * start secure watchdog for BL2 and BL31.
 	 * Note that UART download can take a longer time,
 	 * so do not allow watchdog for UART download,
 	 * as this boot source is not a standard modus operandi.
 	 */
 	if (boot_source_get() != BOOT_SOURCE_UART)
 		sp805_start(ARM_SP805_TWDG_BASE, ARM_TWDG_LOAD_VAL);
 #endif

 #ifdef BCM_ELOG
 	/* Ensure logging is started out fresh in BL2. */
 	mmio_write_32(BCM_ELOG_BL2_BASE, 0);
 #endif
 	/*
 	 * In BL2, since we have very limited space to store logs, we only
 	 * save logs that are >= the WARNING level.
 	 */
 	bcm_elog_init((void *)BCM_ELOG_BL2_BASE, BCM_ELOG_BL2_SIZE,
 		      LOG_LEVEL_WARNING);

 	dump_persistent_regs();

 	/* Read CRMU mailbox 0 */
 	NOTICE("RESET (reported by CRMU): 0x%x\n",
 	       mmio_read_32(CRMU_READ_MAIL_BOX0));

 	/*
 	 * All non-boot-source PADs are in forced input-mode at
 	 * reset so clear the force on non-boot-source PADs using
 	 * CDRU register.
 	 */
 	mmio_clrbits_32((uintptr_t)CDRU_CHIP_IO_PAD_CONTROL,
 		(1 << CDRU_CHIP_IO_PAD_CONTROL__CDRU_IOMUX_FORCE_PAD_IN_R));

 #if DRIVER_OCOTP_ENABLE
 	bcm_otpc_init(&otp_stingray_map);
 #endif

 	set_swreg_based_on_otp();

 #if IHOST_PLL_FREQ != 0
 	bcm_set_ihost_pll_freq(0x0, IHOST_PLL_FREQ);
 #endif

 #ifdef INCLUDE_EMMC_DRIVER_ERASE_CODE
 	/* The erasable unit of the eMMC is the "Erase Group";
 	 * Erase group is measured in write blocks which are the
 	 * basic writable units of the Device.
 	 * The size of the Erase Group is a Device specific parameter
 	 */
 	emmc_erase(EMMC_ERASE_START_BLOCK, EMMC_ERASE_BLOCK_COUNT,
 		   EMMC_ERASE_PARTITION);
 #endif

 	bcm_board_detect();
 #ifdef DRIVER_EMMC_ENABLE
 	/* Initialize the card, if it is not */
 	if (bcm_emmc_init(true) == 0)
 		WARN("eMMC Card Initialization Failed!!!\n");
 #endif

 #if BL2_TEST_I2C
 	i2c_test();
 #endif

 #ifdef USE_DDR
 	ddr_initialize(&ddr_info);

 	ddr_secure_region_config(SECURE_DDR_BASE_ADDRESS,
 				 SECURE_DDR_END_ADDRESS);
 #ifdef NITRO_SECURE_ACCESS
 	ddr_secure_region_config(DDR_NITRO_SECURE_REGION_START,
 				 DDR_NITRO_SECURE_REGION_END);
 #endif
 #else
 	ext_sram_init();
 #endif

 #if BL2_TEST_MEM
 	ddr_test();
 #endif

 #ifdef USE_NAND
 	brcm_stingray_nand_init();
 #endif

 #if defined(USE_PAXB) || defined(USE_PAXC) || defined(USE_SATA)
 	brcm_stingray_pcie_reset();
 #endif

 #ifdef USE_PAXC
 	if (boot_source_get() != BOOT_SOURCE_QSPI)
 		brcm_stingray_chimp_check_and_fastboot();
 #endif

 #if ((!CLEAN_DDR || MMU_DISABLED))
 	/*
 	 * Now DDR has been initialized. We want to copy all the logs in SRAM
 	 * into DDR so we will have much more space to store the logs in the
 	 * next boot stage
 	 */
 	bcm_elog_copy_log((void *)BCM_ELOG_BL31_BASE,
 			   MIN(BCM_ELOG_BL2_SIZE, BCM_ELOG_BL31_SIZE)
 			 );

 	/*
 	 * We are not yet at the end of BL2, but we can stop log here so we do
 	 * not need to add 'bcm_elog_exit' to the standard BL2 code. The
 	 * benefit of capturing BL2 logs after this is very minimal in a
 	 * production system
 	 * NOTE: BL2 logging must be exited before going forward to setup
 	 * page tables
 	 */
 	bcm_elog_exit();
 #endif
 }
	/*
	* Copyright (c) 2016-2020, Broadcom
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch_helpers.h>
	#include <common/bl_common.h>
	#include <common/debug.h>
	#include <drivers/arm/sp805.h>
	#include <drivers/delay_timer.h>
	#include <lib/mmio.h>

	#include <chimp.h>
	#include <chip_id.h>
	#include <cmn_plat_util.h>
	#include <dmu.h>
	#include <emmc_api.h>
	#include <fru.h>
	#ifdef USE_GPIO
	#include <drivers/gpio.h>
	#include <iproc_gpio.h>
	#endif
	#include <platform_def.h>
	#include <sotp.h>
	#include <swreg.h>
	#include <sr_utils.h>
	#ifdef USE_DDR
	#include <ddr_init.h>
	#else
	#include <ext_sram_init.h>
	#endif
	#if DRIVER_OCOTP_ENABLE
	#include <ocotp.h>
	#endif
	#include "board_info.h"

	#define WORD_SIZE 8
	#define SWREG_AVS_OTP_OFFSET (13 * WORD_SIZE) /* 13th row byte offset */
	#define AON_GPIO_OTP_OFFSET (28 * WORD_SIZE) /* 28th row byte offset */
	#define BYTES_TO_READ 8

	/* OTP voltage step definitions */
	#define MVOLT_STEP_MAX 0x18 /* 1v */
	#define MVOLT_PER_STEP 10 /* 0.01mv per step */
	#define MVOLT_BASE 760 /* 0.76v */

	#define STEP_TO_UVOLTS(step) \
	((MVOLT_BASE + (MVOLT_PER_STEP * (step))) * 1000)

	#define GET_BITS(first, last, data) \
	((data >> first) & ((1 << (last - first + 1)) - 1))

	/*
	* SW-REG OTP encoding:
	*
	* SWREG_bits[11:0] = OTP 13th row 12 bits[55:44]
	* SWREG_bits[11:10] - Valid Bits (0x2 - valid, if not 0x2 - Invalid)
	* SWREG_bits[9:5] - iHost03, iHost12
	* SWREG_bits[4:0] - Core VDDC
	*/
	#define SWREG_OTP_BITS_START 12 /* 44th bit in MSB 32-bits */
	#define SWREG_OTP_BITS_END 23 /* 55th bit in MSB 32-bits */
	#define SWREG_VDDC_FIELD_START 0
	#define SWREG_VDDC_FIELD_END 4
	#define SWREG_IHOST_FIELD_START 5
	#define SWREG_IHOST_FIELD_END 9
	#define SWREG_VALID_BIT_START 10
	#define SWREG_VALID_BIT_END 11
	#define SWREG_VALID_BITS 0x2

	/*
	* Row 13 bit 56 is programmed as '1' today. It is not being used, so plan
	* is to flip this bit to '0' for B1 rev. Hence SW can leverage this bit
	* to identify Bx chip to program different sw-regulators.
	*/
	#define SPARE_BIT 24

	#define IS_SR_B0(data) (((data) >> SPARE_BIT) & 0x1)

	#if DRIVER_OCOTP_ENABLE
	static struct otpc_map otp_stingray_map = {
	.otpc_row_size = 2,
	.data_r_offset = {0x10, 0x5c},
	.data_w_offset = {0x2c, 0x64},
	.word_size = 8,
	.stride = 8,
	};
	#endif

	void plat_bcm_bl2_early_platform_setup(void)
	{
	/* Select UART0 for AP via mux setting*/
	if (PLAT_BRCM_BOOT_UART_BASE == UART0_BASE_ADDR) {
	mmio_write_32(UART0_SIN_MODE_SEL_CONTROL, 1);
	mmio_write_32(UART0_SOUT_MODE_SEL_CONTROL, 1);
	}
	}

	#ifdef USE_NAND
	static void brcm_stingray_nand_init(void)
	{
	unsigned int val;
	unsigned int nand_idm_reset_control = 0x68e0a800;

	VERBOSE(" stingray nand init start.\n");

	/* Reset NAND */
	VERBOSE(" - reset nand\n");
	val = mmio_read_32((uintptr_t)(nand_idm_reset_control + 0x0));
	mmio_write_32((uintptr_t)(nand_idm_reset_control + 0x0), val \| 0x1);
	udelay(500);
	val = mmio_read_32((uintptr_t)(nand_idm_reset_control + 0x0));
	mmio_write_32((uintptr_t)(nand_idm_reset_control + 0x0), val & ~0x1);
	udelay(500);

	VERBOSE(" stingray nand init done.\n");
	}
	#endif

	#if defined(USE_PAXB) \|\| defined(USE_PAXC) \|\| defined(USE_SATA)
	#define PCIE_RESCAL_CFG_0 0x40000130
	#define PCIE_CFG_RESCAL_RSTB_R (1 << 16)
	#define PCIE_CFG_RESCAL_PWRDNB_R (1 << 8)
	#define PCIE_RESCAL_STATUS_0 0x4000014c
	#define PCIE_STAT_PON_VALID_R (1 << 0)
	#define PCIE_RESCAL_OUTPUT_STATUS 0x40000154
	#define CDRU_PCIE_RESET_N_R (1 << CDRU_MISC_RESET_CONTROL__CDRU_PCIE_RESET_N_R)

	#ifdef EMULATION_SETUP
	static void brcm_stingray_pcie_reset(void)
	{
	}
	#else
	static void brcm_stingray_pcie_reset(void)
	{
	unsigned int data;
	int try;

	if (bcm_chimp_is_nic_mode()) {
	INFO("NIC mode detected; PCIe reset/rescal not executed\n");
	return;
	}

	mmio_clrbits_32(CDRU_MISC_RESET_CONTROL, CDRU_PCIE_RESET_N_R);
	mmio_setbits_32(CDRU_MISC_RESET_CONTROL, CDRU_PCIE_RESET_N_R);
	/* Release reset */
	mmio_setbits_32(PCIE_RESCAL_CFG_0, PCIE_CFG_RESCAL_RSTB_R);
	mdelay(1);
	/* Power UP */
	mmio_setbits_32(PCIE_RESCAL_CFG_0,
	(PCIE_CFG_RESCAL_RSTB_R \| PCIE_CFG_RESCAL_PWRDNB_R));

	try = 1000;
	do {
	udelay(1);
	data = mmio_read_32(PCIE_RESCAL_STATUS_0);
	try--;
	} while ((data & PCIE_STAT_PON_VALID_R) == 0x0 && (try > 0));

	if (try <= 0)
	ERROR("PCIE_RESCAL_STATUS_0: 0x%x\n", data);

	VERBOSE("PCIE_SATA_RESCAL_STATUS_0 0x%x.\n",
	mmio_read_32(PCIE_RESCAL_STATUS_0));
	VERBOSE("PCIE_SATA_RESCAL_OUTPUT_STATUS 0x%x.\n",
	mmio_read_32(PCIE_RESCAL_OUTPUT_STATUS));
	INFO("PCIE SATA Rescal Init done\n");
	}
	#endif /* EMULATION_SETUP */
	#endif /* USE_PAXB \|\| USE_PAXC \|\| USE_SATA */

	#ifdef USE_PAXC
	void brcm_stingray_chimp_check_and_fastboot(void)
	{
	int fastboot_init_result;

	if (bcm_chimp_is_nic_mode())
	/* Do not wait here */
	return;

	#if WARMBOOT_DDR_S3_SUPPORT
	/*
	* Currently DDR shmoo parameters and QSPI boot source are
	* tied. DDR shmoo parameters are stored in QSPI, which is
	* used for warmboot.
	* Do not reset nitro for warmboot
	*/
	if (is_warmboot() && (boot_source_get() == BOOT_SOURCE_QSPI))
	return;
	#endif /* WARMBOOT_DDR_S3_SUPPORT */

	/*
	* Not in NIC mode,
	* initiate fastboot (if enabled)
	*/
	if (FASTBOOT_TYPE == CHIMP_FASTBOOT_NITRO_RESET) {

	VERBOSE("Bring up Nitro/ChiMP\n");

	if (boot_source_get() == BOOT_SOURCE_QSPI)
	WARN("Nitro boots from QSPI when AP has booted from QSPI.\n");
	brcm_stingray_set_qspi_mux(0);
	VERBOSE("Nitro controls the QSPI\n");
	}

	fastboot_init_result = bcm_chimp_initiate_fastboot(FASTBOOT_TYPE);
	if (fastboot_init_result && boot_source_get() != BOOT_SOURCE_QSPI)
	ERROR("Nitro init error %d. Status: 0x%x; bpe_mod reg: 0x%x\n"
	"fastboot register: 0x%x; handshake register 0x%x\n",
	fastboot_init_result,
	bcm_chimp_read_ctrl(CHIMP_REG_CTRL_BPE_STAT_REG),
	bcm_chimp_read_ctrl(CHIMP_REG_CTRL_BPE_MODE_REG),
	bcm_chimp_read_ctrl(CHIMP_REG_CTRL_FSTBOOT_PTR_REG),
	bcm_chimp_read(CHIMP_REG_ECO_RESERVED));

	/*
	* CRMU watchdog kicks is an example, which is L1 reset,
	* does not clear Nitro scratch pad ram.
	* For Nitro resets: Clear the Nitro health status memory.
	*/
	bcm_chimp_write((CHIMP_REG_CHIMP_SCPAD + CHIMP_HEALTH_STATUS_OFFSET),
	0);
	}
	#endif

	void set_ihost_vddc_swreg(uint32_t ihost_uvolts, uint32_t vddc_uvolts)
	{
	NOTICE("ihost_uvolts: %duv, vddc_uvolts: %duv\n",
	ihost_uvolts, vddc_uvolts);

	set_swreg(VDDC_CORE, vddc_uvolts);
	set_swreg(IHOST03, ihost_uvolts);
	set_swreg(IHOST12, ihost_uvolts);
	}

	/*
	* Reads SWREG AVS OTP bits (13th row) with ECC enabled and get voltage
	* defined in OTP if valid OTP is found
	*/
	void read_avs_otp_bits(uint32_t ihost_uvolts, uint32_t vddc_uvolts)
	{
	uint32_t offset = SWREG_AVS_OTP_OFFSET;
	uint32_t ihost_step, vddc_step;
	uint32_t avs_bits;
	uint32_t buf[2];

	if (bcm_otpc_read(offset, &buf[0], BYTES_TO_READ, 1) == -1)
	return;

	VERBOSE("AVS OTP %d ROW: 0x%x.0x%x\n",
	offset/WORD_SIZE, buf[1], buf[0]);

	/* get voltage readings from AVS OTP bits */
	avs_bits = GET_BITS(SWREG_OTP_BITS_START,
	SWREG_OTP_BITS_END,
	buf[1]);

	/* check for valid otp bits */
	if (GET_BITS(SWREG_VALID_BIT_START, SWREG_VALID_BIT_END, avs_bits) !=
	SWREG_VALID_BITS) {
	WARN("Invalid AVS OTP bits at %d row\n", offset/WORD_SIZE);
	return;
	}

	/* get ihost and vddc step value */
	vddc_step = GET_BITS(SWREG_VDDC_FIELD_START,
	SWREG_VDDC_FIELD_END,
	avs_bits);

	ihost_step = GET_BITS(SWREG_IHOST_FIELD_START,
	SWREG_IHOST_FIELD_END,
	avs_bits);

	if ((ihost_step > MVOLT_STEP_MAX) \|\| (vddc_step > MVOLT_STEP_MAX)) {
	WARN("OTP entry invalid\n");
	return;
	}

	/* get voltage in micro-volts */
	*ihost_uvolts = STEP_TO_UVOLTS(ihost_step);
	*vddc_uvolts = STEP_TO_UVOLTS(vddc_step);
	}

	/*
	* This api reads otp bits and program internal swreg's - ihos12, ihost03,
	* vddc_core and ddr_core based on different chip. External swreg's
	* programming will be done from crmu.
	*
	* For A2 chip:
	* Read OTP row 20, bit 50. This bit will be set for A2 chip. Once A2 chip is
	* found, read AVS OTP row 13, 12bits[55:44], if valid otp bits are found
	* then set ihost and vddc according to avs otp bits else set them to 0.94v
	* and 0.91v respectively. Also update the firmware after setting voltage.
	*
	* For B0 chip:
	* Read OTP row 13, bit 56. This bit will be set for B0 chip. Once B0 chip is
	* found then set ihost and vddc to 0.95v and ddr_core to 1v. No AVS OTP bits
	* are used get ihost/vddc voltages.
	*
	* For B1 chip:
	* Read AVS OTP row 13, 12bits[55:44], if valid otp bits are found then set
	* ihost and vddc according to avs otp bits else set them to 0.94v and 0.91v
	* respectively.
	*/
	void set_swreg_based_on_otp(void)
	{
	/* default voltage if no valid OTP */
	uint32_t vddc_uvolts = VDDC_CORE_DEF_VOLT;
	uint32_t ihost_uvolts = IHOST_DEF_VOLT;
	uint32_t ddrc_uvolts;
	uint32_t offset;
	uint32_t buf[2];

	offset = SWREG_AVS_OTP_OFFSET;
	if (bcm_otpc_read(offset, &buf[0], BYTES_TO_READ, 1) == -1)
	return;

	VERBOSE("OTP %d ROW: 0x%x.0x%x\n",
	offset/WORD_SIZE, buf[1], buf[0]);

	if (IS_SR_B0(buf[1])) {
	/* don't read AVS OTP for B0 */
	ihost_uvolts = B0_IHOST_DEF_VOLT;
	vddc_uvolts = B0_VDDC_CORE_DEF_VOLT;
	ddrc_uvolts = B0_DDR_VDDC_DEF_VOLT;
	} else {
	read_avs_otp_bits(&ihost_uvolts, &vddc_uvolts);
	}

	#if (IHOST_REG_TYPE == IHOST_REG_INTEGRATED) && \
	(VDDC_REG_TYPE == VDDC_REG_INTEGRATED)
	/* enable IHOST12 cluster before changing voltage */
	NOTICE("Switching on the Regulator idx: %u\n",
	SWREG_IHOST1_DIS);
	mmio_clrsetbits_32(CRMU_SWREG_CTRL_ADDR,
	BIT(SWREG_IHOST1_DIS),
	BIT(SWREG_IHOST1_REG_RESETB));

	/* wait for regulator supply gets stable */
	while (!(mmio_read_32(CRMU_SWREG_STATUS_ADDR) &
	(1 << SWREG_IHOST1_PMU_STABLE)))
	;

	INFO("Regulator supply got stable\n");

	#ifndef DEFAULT_SWREG_CONFIG
	swreg_firmware_update();
	#endif

	set_ihost_vddc_swreg(ihost_uvolts, vddc_uvolts);
	#endif
	if (IS_SR_B0(buf[1])) {
	NOTICE("ddrc_uvolts: %duv\n", ddrc_uvolts);
	set_swreg(DDR_VDDC, ddrc_uvolts);
	}
	}

	#ifdef USE_DDR
	static struct ddr_info ddr_info;
	#endif
	#ifdef USE_FRU
	static struct fru_area_info fru_area[FRU_MAX_NR_AREAS];
	static struct fru_board_info board_info;
	static struct fru_time fru_tm;
	static uint8_t fru_tbl[BCM_MAX_FRU_LEN];

	static void board_detect_fru(void)
	{
	uint32_t i, result;
	int ret = -1;

	result = bcm_emmc_init(false);
	if (!result) {
	ERROR("eMMC init failed\n");
	return;
	}

	/* go through eMMC boot partitions looking for FRU table */
	for (i = EMMC_BOOT_PARTITION1; i <= EMMC_BOOT_PARTITION2; i++) {
	result = emmc_partition_select(i);
	if (!result) {
	ERROR("Switching to eMMC part %u failed\n", i);
	return;
	}

	result = emmc_read(BCM_FRU_TBL_OFFSET, (uintptr_t)fru_tbl,
	BCM_MAX_FRU_LEN, BCM_MAX_FRU_LEN);
	if (!result) {
	ERROR("Failed to read from eMMC part %u\n", i);
	return;
	}

	/*
	* Run sanity check and checksum to make sure valid FRU table
	* is detected
	*/
	ret = fru_validate(fru_tbl, fru_area);
	if (ret < 0) {
	WARN("FRU table not found in eMMC part %u\n", i);
	continue;
	}

	/* parse DDR information from FRU table */
	ret = fru_parse_ddr(fru_tbl, &fru_area[FRU_AREA_INTERNAL],
	&ddr_info);
	if (ret < 0) {
	WARN("No FRU DDR info found in eMMC part %u\n", i);
	continue;
	}

	/* parse board information from FRU table */
	ret = fru_parse_board(fru_tbl, &fru_area[FRU_AREA_BOARD_INFO],
	&board_info);
	if (ret < 0) {
	WARN("No FRU board info found in eMMC part %u\n", i);
	continue;
	}

	/* if we reach here, valid FRU table is parsed */
	break;
	}

	if (ret < 0) {
	WARN("FRU table missing for this board\n");
	return;
	}

	for (i = 0; i < BCM_MAX_NR_DDR; i++) {
	INFO("DDR channel index: %d\n", ddr_info.mcb[i].idx);
	INFO("DDR size %u GB\n", ddr_info.mcb[i].size_mb / 1024);
	INFO("DDR ref ID by SW (Not MCB Ref ID) 0x%x\n",
	ddr_info.mcb[i].ref_id);
	}

	fru_format_time(board_info.mfg_date, &fru_tm);

	INFO("** FRU board information **\n");
	INFO("Language 0x%x\n", board_info.lang);
	INFO("Manufacturing Date %u.%02u.%02u, %02u:%02u\n",
	fru_tm.year, fru_tm.month, fru_tm.day,
	fru_tm.hour, fru_tm.min);
	INFO("Manufacturing Date(Raw) 0x%x\n", board_info.mfg_date);
	INFO("Manufacturer %s\n", board_info.manufacturer);
	INFO("Product Name %s\n", board_info.product_name);
	INFO("Serial number %s\n", board_info.serial_number);
	INFO("Part number %s\n", board_info.part_number);
	INFO("File ID %s\n", board_info.file_id);
	}
	#endif /* USE_FRU */

	#ifdef USE_GPIO

	#define INVALID_GPIO 0xffff

	static const int gpio_cfg_bitmap[MAX_NR_GPIOS] = {
	#ifdef BRD_DETECT_GPIO_BIT0
	BRD_DETECT_GPIO_BIT0,
	#else
	INVALID_GPIO,
	#endif
	#ifdef BRD_DETECT_GPIO_BIT1
	BRD_DETECT_GPIO_BIT1,
	#else
	INVALID_GPIO,
	#endif
	#ifdef BRD_DETECT_GPIO_BIT2
	BRD_DETECT_GPIO_BIT2,
	#else
	INVALID_GPIO,
	#endif
	#ifdef BRD_DETECT_GPIO_BIT3
	BRD_DETECT_GPIO_BIT3,
	#else
	INVALID_GPIO,
	#endif
	};

	static uint8_t gpio_bitmap;

	/*
	* Use an odd number to avoid potential conflict with public GPIO level
	* defines
	*/
	#define GPIO_STATE_FLOAT 15

	/*
	* If GPIO_SUPPORT_FLOAT_DETECTION is disabled, simply return GPIO level
	*
	* If GPIO_SUPPORT_FLOAT_DETECTION is enabled, add additional test for possible
	* pin floating (unconnected) scenario. This support is assuming externally
	* applied pull up / pull down will have a stronger pull than the internal pull
	* up / pull down.
	*/
	static uint8_t gpio_get_state(int gpio)
	{
	uint8_t val;

	/* set direction to GPIO input */
	gpio_set_direction(gpio, GPIO_DIR_IN);

	#ifndef GPIO_SUPPORT_FLOAT_DETECTION
	if (gpio_get_value(gpio) == GPIO_LEVEL_HIGH)
	val = GPIO_LEVEL_HIGH;
	else
	val = GPIO_LEVEL_LOW;

	return val;
	#else
	/*
	* Enable internal pull down. If GPIO level is still high, there must
	* be an external pull up
	*/
	gpio_set_pull(gpio, GPIO_PULL_DOWN);
	if (gpio_get_value(gpio) == GPIO_LEVEL_HIGH) {
	val = GPIO_LEVEL_HIGH;
	goto exit;
	}

	/*
	* Enable internal pull up. If GPIO level is still low, there must
	* be an external pull down
	*/
	gpio_set_pull(gpio, GPIO_PULL_UP);
	if (gpio_get_value(gpio) == GPIO_LEVEL_LOW) {
	val = GPIO_LEVEL_LOW;
	goto exit;
	}

	/* if reached here, the pin must be not connected */
	val = GPIO_STATE_FLOAT;

	exit:
	/* make sure internall pull is disabled */
	if (gpio_get_pull(gpio) != GPIO_PULL_NONE)
	gpio_set_pull(gpio, GPIO_PULL_NONE);

	return val;
	#endif
	}

	static void board_detect_gpio(void)
	{
	unsigned int i, val;
	int gpio;

	iproc_gpio_init(IPROC_GPIO_S_BASE, IPROC_GPIO_NR,
	IPROC_IOPAD_MODE_BASE, HSLS_IOPAD_BASE);

	gpio_bitmap = 0;
	for (i = 0; i < MAX_NR_GPIOS; i++) {
	if (gpio_cfg_bitmap[i] == INVALID_GPIO)
	continue;

	/*
	* Construct the bitmap based on GPIO value. Floating pin
	* detection is a special case. As soon as a floating pin is
	* detected, a special value of MAX_GPIO_BITMAP_VAL is
	* assigned and we break out of the loop immediately
	*/
	gpio = gpio_cfg_bitmap[i];
	val = gpio_get_state(gpio);
	if (val == GPIO_STATE_FLOAT) {
	gpio_bitmap = MAX_GPIO_BITMAP_VAL;
	break;
	}

	if (val == GPIO_LEVEL_HIGH)
	gpio_bitmap \|= BIT(i);
	}

	memcpy(&ddr_info, &gpio_ddr_info[gpio_bitmap], sizeof(ddr_info));
	INFO("Board detection GPIO bitmap = 0x%x\n", gpio_bitmap);
	}
	#endif /* USE_GPIO */

	static void bcm_board_detect(void)
	{
	#ifdef DDR_LEGACY_MCB_SUPPORTED
	/* Loading default DDR info */
	memcpy(&ddr_info, &default_ddr_info, sizeof(ddr_info));
	#endif
	#ifdef USE_FRU
	board_detect_fru();
	#endif
	#ifdef USE_GPIO
	board_detect_gpio();
	#endif
	}

	static void dump_persistent_regs(void)
	{
	NOTICE("pr0: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG0));
	NOTICE("pr1: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG1));
	NOTICE("pr2: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG2));
	NOTICE("pr3: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG3));
	NOTICE("pr4: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG4));
	NOTICE("pr5: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG5));
	NOTICE("pr6: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG6));
	NOTICE("pr7: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG7));
	NOTICE("pr8: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG8));
	NOTICE("pr9: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG9));
	NOTICE("pr10: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG10));
	NOTICE("pr11: %x\n", mmio_read_32(CRMU_IHOST_SW_PERSISTENT_REG11));
	}

	void plat_bcm_bl2_plat_arch_setup(void)
	{
	if (chip_get_rev_id_major() == CHIP_REV_MAJOR_AX) {
	if (!(sotp_mem_read(SOTP_ATF_CFG_ROW_ID, SOTP_ROW_NO_ECC) &
	SOTP_ATF_WATCHDOG_ENABLE_MASK)) {
	/*
	* Stop sp805 watchdog timer immediately.
	* It might has been set up by MCU patch earlier for
	* eMMC workaround.
	*
	* Note the watchdog timer started in CRMU has a very
	* short timeout and needs to be stopped immediately.
	* Down below we restart it with a much longer timeout
	* for BL2 and BL31
	*/
	sp805_stop(ARM_SP805_TWDG_BASE);
	}
	}

	#if !BRCM_DISABLE_TRUSTED_WDOG
	/*
	* start secure watchdog for BL2 and BL31.
	* Note that UART download can take a longer time,
	* so do not allow watchdog for UART download,
	* as this boot source is not a standard modus operandi.
	*/
	if (boot_source_get() != BOOT_SOURCE_UART)
	sp805_start(ARM_SP805_TWDG_BASE, ARM_TWDG_LOAD_VAL);
	#endif

	#ifdef BCM_ELOG
	/* Ensure logging is started out fresh in BL2. */
	mmio_write_32(BCM_ELOG_BL2_BASE, 0);
	#endif
	/*
	* In BL2, since we have very limited space to store logs, we only
	* save logs that are >= the WARNING level.
	*/
	bcm_elog_init((void *)BCM_ELOG_BL2_BASE, BCM_ELOG_BL2_SIZE,
	LOG_LEVEL_WARNING);

	dump_persistent_regs();

	/* Read CRMU mailbox 0 */
	NOTICE("RESET (reported by CRMU): 0x%x\n",
	mmio_read_32(CRMU_READ_MAIL_BOX0));

	/*
	* All non-boot-source PADs are in forced input-mode at
	* reset so clear the force on non-boot-source PADs using
	* CDRU register.
	*/
	mmio_clrbits_32((uintptr_t)CDRU_CHIP_IO_PAD_CONTROL,
	(1 << CDRU_CHIP_IO_PAD_CONTROL__CDRU_IOMUX_FORCE_PAD_IN_R));

	#if DRIVER_OCOTP_ENABLE
	bcm_otpc_init(&otp_stingray_map);
	#endif

	set_swreg_based_on_otp();

	#if IHOST_PLL_FREQ != 0
	bcm_set_ihost_pll_freq(0x0, IHOST_PLL_FREQ);
	#endif

	#ifdef INCLUDE_EMMC_DRIVER_ERASE_CODE
	/* The erasable unit of the eMMC is the "Erase Group";
	* Erase group is measured in write blocks which are the
	* basic writable units of the Device.
	* The size of the Erase Group is a Device specific parameter
	*/
	emmc_erase(EMMC_ERASE_START_BLOCK, EMMC_ERASE_BLOCK_COUNT,
	EMMC_ERASE_PARTITION);
	#endif

	bcm_board_detect();
	#ifdef DRIVER_EMMC_ENABLE
	/* Initialize the card, if it is not */
	if (bcm_emmc_init(true) == 0)
	WARN("eMMC Card Initialization Failed!!!\n");
	#endif

	#if BL2_TEST_I2C
	i2c_test();
	#endif

	#ifdef USE_DDR
	ddr_initialize(&ddr_info);

	ddr_secure_region_config(SECURE_DDR_BASE_ADDRESS,
	SECURE_DDR_END_ADDRESS);
	#ifdef NITRO_SECURE_ACCESS
	ddr_secure_region_config(DDR_NITRO_SECURE_REGION_START,
	DDR_NITRO_SECURE_REGION_END);
	#endif
	#else
	ext_sram_init();
	#endif

	#if BL2_TEST_MEM
	ddr_test();
	#endif

	#ifdef USE_NAND
	brcm_stingray_nand_init();
	#endif

	#if defined(USE_PAXB) \|\| defined(USE_PAXC) \|\| defined(USE_SATA)
	brcm_stingray_pcie_reset();
	#endif

	#ifdef USE_PAXC
	if (boot_source_get() != BOOT_SOURCE_QSPI)
	brcm_stingray_chimp_check_and_fastboot();
	#endif

	#if ((!CLEAN_DDR \|\| MMU_DISABLED))
	/*
	* Now DDR has been initialized. We want to copy all the logs in SRAM
	* into DDR so we will have much more space to store the logs in the
	* next boot stage
	*/
	bcm_elog_copy_log((void *)BCM_ELOG_BL31_BASE,
	MIN(BCM_ELOG_BL2_SIZE, BCM_ELOG_BL31_SIZE)
	);

	/*
	* We are not yet at the end of BL2, but we can stop log here so we do
	* not need to add 'bcm_elog_exit' to the standard BL2 code. The
	* benefit of capturing BL2 logs after this is very minimal in a
	* production system
	* NOTE: BL2 logging must be exited before going forward to setup
	* page tables
	*/
	bcm_elog_exit();
	#endif
	}