drivers/cadence/nand/cdns_nand.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2022-2023, Intel Corporation. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <assert.h>
 #include <errno.h>
 #include <stdbool.h>
 #include <string.h>

 #include <arch_helpers.h>
 #include <common/debug.h>
 #include <drivers/cadence/cdns_nand.h>
 #include <drivers/delay_timer.h>
 #include <lib/mmio.h>
 #include <lib/utils.h>
 #include <platform_def.h>

 /* NAND flash device information struct */
 static cnf_dev_info_t dev_info;

 /*
  * Scratch buffers for read and write operations
  * DMA transfer of Cadence NAND expects data 8 bytes aligned
  * to be written to register
  */
 static uint8_t scratch_buff[PLATFORM_MTD_MAX_PAGE_SIZE] __aligned(8);

 /* Wait for controller to be in idle state */
 static inline void cdns_nand_wait_idle(void)
 {
 	uint32_t reg = 0U;

 	do {
 		udelay(CNF_DEF_DELAY_US);
 		reg = mmio_read_32(CNF_CMDREG(CTRL_STATUS));
 	} while (CNF_GET_CTRL_BUSY(reg) != 0U);
 }

 /* Wait for given thread to be in ready state */
 static inline void cdns_nand_wait_thread_ready(uint8_t thread_id)
 {
 	uint32_t reg = 0U;

 	do {
 		udelay(CNF_DEF_DELAY_US);
 		reg = mmio_read_32(CNF_CMDREG(TRD_STATUS));
 		reg &= (1U << (uint32_t)thread_id);
 	} while (reg != 0U);
 }

 /* Check if the last operation/command in selected thread is completed */
 static int cdns_nand_last_opr_status(uint8_t thread_id)
 {
 	uint8_t nthreads = 0U;
 	uint32_t reg = 0U;

 	/* Get number of threads */
 	reg = mmio_read_32(CNF_CTRLPARAM(FEATURE));
 	nthreads = CNF_GET_NTHREADS(reg);

 	if (thread_id > nthreads) {
 		ERROR("%s: Invalid thread ID\n", __func__);
 		return -EINVAL;
 	}

 	/* Select thread */
 	mmio_write_32(CNF_CMDREG(CMD_STAT_PTR), (uint32_t)thread_id);

 	uint32_t err_mask = CNF_ECMD | CNF_EECC | CNF_EDEV | CNF_EDQS | CNF_EFAIL |
 				CNF_EBUS | CNF_EDI | CNF_EPAR | CNF_ECTX | CNF_EPRO;

 	do {
 		udelay(CNF_DEF_DELAY_US * 2);
 		reg = mmio_read_32(CNF_CMDREG(CMD_STAT));
 	} while ((reg & CNF_CMPLT) == 0U);

 	/* last operation is completed, make sure no other error bits are set */
 	if ((reg & err_mask) == 1U) {
 		ERROR("%s, CMD_STATUS:0x%x\n", __func__, reg);
 		return -EIO;
 	}

 	return 0;
 }

 /* Set feature command */
 int cdns_nand_set_feature(uint8_t feat_addr, uint8_t feat_val, uint8_t thread_id)
 {
 	/* Wait for thread to be ready */
 	cdns_nand_wait_thread_ready(thread_id);

 	/* Set feature address */
 	mmio_write_32(CNF_CMDREG(CMD_REG1), (uint32_t)feat_addr);
 	/* Set feature volume */
 	mmio_write_32(CNF_CMDREG(CMD_REG2), (uint32_t)feat_val);

 	/* Set feature command */
 	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

 	reg |= (thread_id << CNF_CMDREG0_TRD);
 	reg |= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
 	reg |= (CNF_INT_DIS << CNF_CMDREG0_INTR);
 	reg |= (CNF_CT_SET_FEATURE << CNF_CMDREG0_CMD);
 	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

 	return cdns_nand_last_opr_status(thread_id);
 }

 /* Reset command to the selected device */
 int cdns_nand_reset(uint8_t thread_id)
 {
 	/* Operation is executed in selected thread */
 	cdns_nand_wait_thread_ready(thread_id);

 	/* Select memory */
 	mmio_write_32(CNF_CMDREG(CMD_REG4),
 			(CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

 	/* Issue reset command */
 	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

 	reg |= (thread_id << CNF_CMDREG0_TRD);
 	reg |= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
 	reg |= (CNF_INT_DIS << CNF_CMDREG0_INTR);
 	reg |= (CNF_CT_RESET_ASYNC << CNF_CMDREG0_CMD);
 	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

 	return cdns_nand_last_opr_status(thread_id);
 }

 /* Set operation work mode */
 static void cdns_nand_set_opr_mode(uint8_t opr_mode)
 {
 	/* Wait for controller to be in idle state */
 	cdns_nand_wait_idle();

 	/* Reset DLL PHY */
 	uint32_t reg = mmio_read_32(CNF_MINICTRL(DLL_PHY_CTRL));

 	reg &= ~(1 << CNF_DLL_PHY_RST_N);
 	mmio_write_32(CNF_MINICTRL(DLL_PHY_CTRL), reg);

 	if (opr_mode == CNF_OPR_WORK_MODE_SDR) {
 		/* Combo PHY Control Timing Block register settings */
 		mmio_write_32(CP_CTB(CTRL_REG), CP_CTRL_REG_SDR);
 		mmio_write_32(CP_CTB(TSEL_REG), CP_TSEL_REG_SDR);

 		/* Combo PHY DLL register settings */
 		mmio_write_32(CP_DLL(DQ_TIMING_REG), CP_DQ_TIMING_REG_SDR);
 		mmio_write_32(CP_DLL(DQS_TIMING_REG), CP_DQS_TIMING_REG_SDR);
 		mmio_write_32(CP_DLL(GATE_LPBK_CTRL_REG), CP_GATE_LPBK_CTRL_REG_SDR);
 		mmio_write_32(CP_DLL(MASTER_CTRL_REG), CP_DLL_MASTER_CTRL_REG_SDR);

 		/* Async mode timing settings */
 		mmio_write_32(CNF_MINICTRL(ASYNC_TOGGLE_TIMINGS),
 				(2 << CNF_ASYNC_TIMINGS_TRH) |
 				(4 << CNF_ASYNC_TIMINGS_TRP) |
 				(2 << CNF_ASYNC_TIMINGS_TWH) |
 				(4 << CNF_ASYNC_TIMINGS_TWP));

 		/* Set extended read and write mode */
 		reg |= (1 << CNF_DLL_PHY_EXT_RD_MODE);
 		reg |= (1 << CNF_DLL_PHY_EXT_WR_MODE);

 		/* Set operation work mode in common settings */
 		mmio_clrsetbits_32(CNF_MINICTRL(CMN_SETTINGS),
 				CNF_CMN_SETTINGS_OPR_MASK,
 				CNF_OPR_WORK_MODE_SDR);
 	} else if (opr_mode == CNF_OPR_WORK_MODE_NVDDR) {
 		; /* ToDo: add DDR mode settings also once available on SIMICS */
 	} else {
 		;
 	}

 	reg |= (1 << CNF_DLL_PHY_RST_N);
 	mmio_write_32(CNF_MINICTRL(DLL_PHY_CTRL), reg);
 }

 /* Data transfer configuration */
 static void cdns_nand_transfer_config(void)
 {
 	/* Wait for controller to be in idle state */
 	cdns_nand_wait_idle();

 	/* Configure data transfer parameters */
 	mmio_write_32(CNF_CTRLCFG(TRANS_CFG0), 1);

 	/* ECC is disabled */
 	mmio_write_32(CNF_CTRLCFG(ECC_CFG0), 0);

 	/* DMA burst select */
 	mmio_write_32(CNF_CTRLCFG(DMA_SETTINGS),
 			(CNF_DMA_BURST_SIZE_MAX << CNF_DMA_SETTINGS_BURST) |
 			(1 << CNF_DMA_SETTINGS_OTE));

 	/* Enable pre-fetching for 1K */
 	mmio_write_32(CNF_CTRLCFG(FIFO_TLEVEL),
 			(CNF_DMA_PREFETCH_SIZE << CNF_FIFO_TLEVEL_POS) |
 			(CNF_DMA_PREFETCH_SIZE << CNF_FIFO_TLEVEL_DMA_SIZE));

 	/* Select access type */
 	mmio_write_32(CNF_CTRLCFG(MULTIPLANE_CFG), 0);
 	mmio_write_32(CNF_CTRLCFG(CACHE_CFG), 0);
 }

 /* Update the nand flash device info */
 static int cdns_nand_update_dev_info(void)
 {
 	uint32_t reg = 0U;

 	/* Read the device type and number of LUNs */
 	reg = mmio_read_32(CNF_CTRLPARAM(DEV_PARAMS0));
 	dev_info.type = CNF_GET_DEV_TYPE(reg);
 	if (dev_info.type == CNF_DT_UNKNOWN) {
 		ERROR("%s: device type unknown\n", __func__);
 		return -ENXIO;
 	}
 	dev_info.nluns = CNF_GET_NLUNS(reg);

 	/* Pages per block */
 	reg = mmio_read_32(CNF_CTRLCFG(DEV_LAYOUT));
 	dev_info.npages_per_block = CNF_GET_NPAGES_PER_BLOCK(reg);

 	/* Sector size and last sector size */
 	reg = mmio_read_32(CNF_CTRLCFG(TRANS_CFG1));
 	dev_info.sector_size = CNF_GET_SCTR_SIZE(reg);
 	dev_info.last_sector_size = CNF_GET_LAST_SCTR_SIZE(reg);

 	/* Page size and spare size */
 	reg = mmio_read_32(CNF_CTRLPARAM(DEV_AREA));
 	dev_info.page_size = CNF_GET_PAGE_SIZE(reg);
 	dev_info.spare_size = CNF_GET_SPARE_SIZE(reg);

 	/* Device blocks per LUN */
 	dev_info.nblocks_per_lun = mmio_read_32(CNF_CTRLPARAM(DEV_BLOCKS_PLUN));

 	/* Calculate block size and total device size */
 	dev_info.block_size = (dev_info.npages_per_block * dev_info.page_size);
 	dev_info.total_size = ((unsigned long long)dev_info.block_size *
 				(unsigned long long)dev_info.nblocks_per_lun *
 				dev_info.nluns);

 	VERBOSE("CNF params: page_size %d, spare_size %d, block_size %u, total_size %llu\n",
 		dev_info.page_size, dev_info.spare_size,
 		dev_info.block_size, dev_info.total_size);

 	return 0;
 }

 /* NAND Flash Controller/Host initialization */
 int cdns_nand_host_init(void)
 {
 	uint32_t reg = 0U;
 	int ret = 0;

 	do {
 		/* Read controller status register for init complete */
 		reg = mmio_read_32(CNF_CMDREG(CTRL_STATUS));
 	} while (CNF_GET_INIT_COMP(reg) == 0);

 	ret = cdns_nand_update_dev_info();
 	if (ret != 0) {
 		return ret;
 	}

 	INFO("CNF: device discovery process completed and device type %d\n",
 			dev_info.type);

 	/* Enable data integrity, enable CRC and parity */
 	reg = mmio_read_32(CNF_DI(CONTROL));
 	reg |= (1 << CNF_DI_PAR_EN);
 	reg |= (1 << CNF_DI_CRC_EN);
 	mmio_write_32(CNF_DI(CONTROL), reg);

 	/* Status polling mode, device control and status register */
 	cdns_nand_wait_idle();
 	reg = mmio_read_32(CNF_CTRLCFG(DEV_STAT));
 	reg = reg & ~1;
 	mmio_write_32(CNF_CTRLCFG(DEV_STAT), reg);

 	/* Set operation work mode */
 	cdns_nand_set_opr_mode(CNF_OPR_WORK_MODE_SDR);

 	/* Set data transfer configuration parameters */
 	cdns_nand_transfer_config();

 	return 0;
 }

 /* erase: Block erase command */
 int cdns_nand_erase(uint32_t offset, uint32_t size)
 {
 	/* Determine the starting block offset i.e row address */
 	uint32_t row_address = dev_info.npages_per_block * offset;

 	/* Wait for thread to be in ready state */
 	cdns_nand_wait_thread_ready(CNF_DEF_TRD);

 	/*Set row address */
 	mmio_write_32(CNF_CMDREG(CMD_REG1), row_address);

 	/* Operation bank number */
 	mmio_write_32(CNF_CMDREG(CMD_REG4), (CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

 	/* Block erase command */
 	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

 	reg |= (CNF_DEF_TRD << CNF_CMDREG0_TRD);
 	reg |= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
 	reg |= (CNF_INT_DIS << CNF_CMDREG0_INTR);
 	reg |= (CNF_CT_ERASE << CNF_CMDREG0_CMD);
 	reg |= (((size-1) & 0xFF) << CNF_CMDREG0_CMD);
 	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

 	/* Wait for erase operation to complete */
 	return cdns_nand_last_opr_status(CNF_DEF_TRD);
 }

 /* io mtd functions */
 int cdns_nand_init_mtd(unsigned long long *size, unsigned int *erase_size)
 {
 	*size = dev_info.total_size;
 	*erase_size = dev_info.block_size;

 	return 0;
 }

 static uint32_t cdns_nand_get_row_address(uint32_t page, uint32_t block)
 {
 	uint32_t row_address = 0U;
 	uint32_t req_bits = 0U;

 	/* The device info is not populated yet. */
 	if (dev_info.npages_per_block == 0U)
 		return 0;

 	for (uint32_t i = 0U; i < sizeof(uint32_t) * 8; i++) {
 		if ((1U << i) & dev_info.npages_per_block)
 			req_bits = i;
 	}

 	row_address = ((page & GENMASK_32((req_bits - 1), 0)) |
 			(block << req_bits));

 	return row_address;
 }

 /* NAND Flash page read */
 static int cdns_nand_read_page(uint32_t block, uint32_t page, uintptr_t buffer)
 {

 	/* Wait for thread to be ready */
 	cdns_nand_wait_thread_ready(CNF_DEF_TRD);

 	/* Select device */
 	mmio_write_32(CNF_CMDREG(CMD_REG4),
 			(CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

 	/* Set host memory address for DMA transfers */
 	mmio_write_32(CNF_CMDREG(CMD_REG2), (buffer & UINT32_MAX));
 	mmio_write_32(CNF_CMDREG(CMD_REG3), ((buffer >> 32) & UINT32_MAX));

 	/* Set row address */
 	mmio_write_32(CNF_CMDREG(CMD_REG1),
 			cdns_nand_get_row_address(page, block));

 	/* Page read command */
 	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

 	reg |= (CNF_DEF_TRD << CNF_CMDREG0_TRD);
 	reg |= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
 	reg |= (CNF_INT_DIS << CNF_CMDREG0_INTR);
 	reg |= (CNF_DMA_MASTER_SEL << CNF_CMDREG0_DMA);
 	reg |= (CNF_CT_PAGE_READ << CNF_CMDREG0_CMD);
 	reg |= (((CNF_READ_SINGLE_PAGE-1) & 0xFF) << CNF_CMDREG0_CMD);
 	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

 	/* Wait for read operation to complete */
 	if (cdns_nand_last_opr_status(CNF_DEF_TRD)) {
 		ERROR("%s: Page read failed\n", __func__);
 		return -EIO;
 	}

 	return 0;
 }

 int cdns_nand_read(unsigned int offset, uintptr_t buffer, size_t length,
 					size_t *out_length)
 {
 	uint32_t block = offset / dev_info.block_size;
 	uint32_t end_block = (offset + length - 1U) / dev_info.block_size;
 	uint32_t page_start = (offset % dev_info.block_size) / dev_info.page_size;
 	uint32_t start_offset = offset % dev_info.page_size;
 	uint32_t nb_pages = dev_info.block_size / dev_info.page_size;
 	uint32_t bytes_read = 0U;
 	uint32_t page = 0U;
 	int result = 0;

 	INFO("CNF: %s: block %u-%u, page_start %u, len %zu, offset %u\n",
 		__func__, block, end_block, page_start, length, offset);

 	if ((offset >= dev_info.total_size) ||
 		(offset + length-1 >= dev_info.total_size) ||
 		(length == 0U)) {
 		ERROR("CNF: Invalid read parameters\n");
 		return -EINVAL;
 	}

 	*out_length = 0UL;

 	while (block <= end_block) {
 		for (page = page_start; page < nb_pages; page++) {
 			if ((start_offset != 0U) || (length < dev_info.page_size)) {
 				/* Partial page read */
 				result = cdns_nand_read_page(block, page,
 							(uintptr_t)scratch_buff);
 				if (result != 0) {
 					return result;
 				}

 				bytes_read = MIN((size_t)(dev_info.page_size - start_offset),
 								length);

 				memcpy((uint8_t *)buffer, scratch_buff + start_offset,
 						bytes_read);
 				start_offset = 0U;
 			} else {
 				/* Full page read */
 				result = cdns_nand_read_page(block, page,
 				(uintptr_t)scratch_buff);
 				if (result != 0) {
 					return result;
 				}

 				bytes_read = dev_info.page_size;
 				memcpy((uint8_t *)buffer, scratch_buff, bytes_read);
 			}

 			length -= bytes_read;
 			buffer += bytes_read;
 			*out_length += bytes_read;

 			/* All the bytes have read */
 			if (length == 0U) {
 				break;
 			}

 			udelay(CNF_READ_INT_DELAY_US);
 		} /* for */

 		page_start = 0U;
 		block++;
 	} /* while */

 	return 0;
 }
	/*
	* Copyright (c) 2022-2023, Intel Corporation. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <assert.h>
	#include <errno.h>
	#include <stdbool.h>
	#include <string.h>

	#include <arch_helpers.h>
	#include <common/debug.h>
	#include <drivers/cadence/cdns_nand.h>
	#include <drivers/delay_timer.h>
	#include <lib/mmio.h>
	#include <lib/utils.h>
	#include <platform_def.h>

	/* NAND flash device information struct */
	static cnf_dev_info_t dev_info;

	/*
	* Scratch buffers for read and write operations
	* DMA transfer of Cadence NAND expects data 8 bytes aligned
	* to be written to register
	*/
	static uint8_t scratch_buff[PLATFORM_MTD_MAX_PAGE_SIZE] __aligned(8);

	/* Wait for controller to be in idle state */
	static inline void cdns_nand_wait_idle(void)
	{
	uint32_t reg = 0U;

	do {
	udelay(CNF_DEF_DELAY_US);
	reg = mmio_read_32(CNF_CMDREG(CTRL_STATUS));
	} while (CNF_GET_CTRL_BUSY(reg) != 0U);
	}

	/* Wait for given thread to be in ready state */
	static inline void cdns_nand_wait_thread_ready(uint8_t thread_id)
	{
	uint32_t reg = 0U;

	do {
	udelay(CNF_DEF_DELAY_US);
	reg = mmio_read_32(CNF_CMDREG(TRD_STATUS));
	reg &= (1U << (uint32_t)thread_id);
	} while (reg != 0U);
	}

	/* Check if the last operation/command in selected thread is completed */
	static int cdns_nand_last_opr_status(uint8_t thread_id)
	{
	uint8_t nthreads = 0U;
	uint32_t reg = 0U;

	/* Get number of threads */
	reg = mmio_read_32(CNF_CTRLPARAM(FEATURE));
	nthreads = CNF_GET_NTHREADS(reg);

	if (thread_id > nthreads) {
	ERROR("%s: Invalid thread ID\n", __func__);
	return -EINVAL;
	}

	/* Select thread */
	mmio_write_32(CNF_CMDREG(CMD_STAT_PTR), (uint32_t)thread_id);

	uint32_t err_mask = CNF_ECMD \| CNF_EECC \| CNF_EDEV \| CNF_EDQS \| CNF_EFAIL \|
	CNF_EBUS \| CNF_EDI \| CNF_EPAR \| CNF_ECTX \| CNF_EPRO;

	do {
	udelay(CNF_DEF_DELAY_US * 2);
	reg = mmio_read_32(CNF_CMDREG(CMD_STAT));
	} while ((reg & CNF_CMPLT) == 0U);

	/* last operation is completed, make sure no other error bits are set */
	if ((reg & err_mask) == 1U) {
	ERROR("%s, CMD_STATUS:0x%x\n", __func__, reg);
	return -EIO;
	}

	return 0;
	}

	/* Set feature command */
	int cdns_nand_set_feature(uint8_t feat_addr, uint8_t feat_val, uint8_t thread_id)
	{
	/* Wait for thread to be ready */
	cdns_nand_wait_thread_ready(thread_id);

	/* Set feature address */
	mmio_write_32(CNF_CMDREG(CMD_REG1), (uint32_t)feat_addr);
	/* Set feature volume */
	mmio_write_32(CNF_CMDREG(CMD_REG2), (uint32_t)feat_val);

	/* Set feature command */
	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

	reg \|= (thread_id << CNF_CMDREG0_TRD);
	reg \|= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
	reg \|= (CNF_INT_DIS << CNF_CMDREG0_INTR);
	reg \|= (CNF_CT_SET_FEATURE << CNF_CMDREG0_CMD);
	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

	return cdns_nand_last_opr_status(thread_id);
	}

	/* Reset command to the selected device */
	int cdns_nand_reset(uint8_t thread_id)
	{
	/* Operation is executed in selected thread */
	cdns_nand_wait_thread_ready(thread_id);

	/* Select memory */
	mmio_write_32(CNF_CMDREG(CMD_REG4),
	(CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

	/* Issue reset command */
	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

	reg \|= (thread_id << CNF_CMDREG0_TRD);
	reg \|= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
	reg \|= (CNF_INT_DIS << CNF_CMDREG0_INTR);
	reg \|= (CNF_CT_RESET_ASYNC << CNF_CMDREG0_CMD);
	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

	return cdns_nand_last_opr_status(thread_id);
	}

	/* Set operation work mode */
	static void cdns_nand_set_opr_mode(uint8_t opr_mode)
	{
	/* Wait for controller to be in idle state */
	cdns_nand_wait_idle();

	/* Reset DLL PHY */
	uint32_t reg = mmio_read_32(CNF_MINICTRL(DLL_PHY_CTRL));

	reg &= ~(1 << CNF_DLL_PHY_RST_N);
	mmio_write_32(CNF_MINICTRL(DLL_PHY_CTRL), reg);

	if (opr_mode == CNF_OPR_WORK_MODE_SDR) {
	/* Combo PHY Control Timing Block register settings */
	mmio_write_32(CP_CTB(CTRL_REG), CP_CTRL_REG_SDR);
	mmio_write_32(CP_CTB(TSEL_REG), CP_TSEL_REG_SDR);

	/* Combo PHY DLL register settings */
	mmio_write_32(CP_DLL(DQ_TIMING_REG), CP_DQ_TIMING_REG_SDR);
	mmio_write_32(CP_DLL(DQS_TIMING_REG), CP_DQS_TIMING_REG_SDR);
	mmio_write_32(CP_DLL(GATE_LPBK_CTRL_REG), CP_GATE_LPBK_CTRL_REG_SDR);
	mmio_write_32(CP_DLL(MASTER_CTRL_REG), CP_DLL_MASTER_CTRL_REG_SDR);

	/* Async mode timing settings */
	mmio_write_32(CNF_MINICTRL(ASYNC_TOGGLE_TIMINGS),
	(2 << CNF_ASYNC_TIMINGS_TRH) \|
	(4 << CNF_ASYNC_TIMINGS_TRP) \|
	(2 << CNF_ASYNC_TIMINGS_TWH) \|
	(4 << CNF_ASYNC_TIMINGS_TWP));

	/* Set extended read and write mode */
	reg \|= (1 << CNF_DLL_PHY_EXT_RD_MODE);
	reg \|= (1 << CNF_DLL_PHY_EXT_WR_MODE);

	/* Set operation work mode in common settings */
	mmio_clrsetbits_32(CNF_MINICTRL(CMN_SETTINGS),
	CNF_CMN_SETTINGS_OPR_MASK,
	CNF_OPR_WORK_MODE_SDR);
	} else if (opr_mode == CNF_OPR_WORK_MODE_NVDDR) {
	; /* ToDo: add DDR mode settings also once available on SIMICS */
	} else {
	;
	}

	reg \|= (1 << CNF_DLL_PHY_RST_N);
	mmio_write_32(CNF_MINICTRL(DLL_PHY_CTRL), reg);
	}

	/* Data transfer configuration */
	static void cdns_nand_transfer_config(void)
	{
	/* Wait for controller to be in idle state */
	cdns_nand_wait_idle();

	/* Configure data transfer parameters */
	mmio_write_32(CNF_CTRLCFG(TRANS_CFG0), 1);

	/* ECC is disabled */
	mmio_write_32(CNF_CTRLCFG(ECC_CFG0), 0);

	/* DMA burst select */
	mmio_write_32(CNF_CTRLCFG(DMA_SETTINGS),
	(CNF_DMA_BURST_SIZE_MAX << CNF_DMA_SETTINGS_BURST) \|
	(1 << CNF_DMA_SETTINGS_OTE));

	/* Enable pre-fetching for 1K */
	mmio_write_32(CNF_CTRLCFG(FIFO_TLEVEL),
	(CNF_DMA_PREFETCH_SIZE << CNF_FIFO_TLEVEL_POS) \|
	(CNF_DMA_PREFETCH_SIZE << CNF_FIFO_TLEVEL_DMA_SIZE));

	/* Select access type */
	mmio_write_32(CNF_CTRLCFG(MULTIPLANE_CFG), 0);
	mmio_write_32(CNF_CTRLCFG(CACHE_CFG), 0);
	}

	/* Update the nand flash device info */
	static int cdns_nand_update_dev_info(void)
	{
	uint32_t reg = 0U;

	/* Read the device type and number of LUNs */
	reg = mmio_read_32(CNF_CTRLPARAM(DEV_PARAMS0));
	dev_info.type = CNF_GET_DEV_TYPE(reg);
	if (dev_info.type == CNF_DT_UNKNOWN) {
	ERROR("%s: device type unknown\n", __func__);
	return -ENXIO;
	}
	dev_info.nluns = CNF_GET_NLUNS(reg);

	/* Pages per block */
	reg = mmio_read_32(CNF_CTRLCFG(DEV_LAYOUT));
	dev_info.npages_per_block = CNF_GET_NPAGES_PER_BLOCK(reg);

	/* Sector size and last sector size */
	reg = mmio_read_32(CNF_CTRLCFG(TRANS_CFG1));
	dev_info.sector_size = CNF_GET_SCTR_SIZE(reg);
	dev_info.last_sector_size = CNF_GET_LAST_SCTR_SIZE(reg);

	/* Page size and spare size */
	reg = mmio_read_32(CNF_CTRLPARAM(DEV_AREA));
	dev_info.page_size = CNF_GET_PAGE_SIZE(reg);
	dev_info.spare_size = CNF_GET_SPARE_SIZE(reg);

	/* Device blocks per LUN */
	dev_info.nblocks_per_lun = mmio_read_32(CNF_CTRLPARAM(DEV_BLOCKS_PLUN));

	/* Calculate block size and total device size */
	dev_info.block_size = (dev_info.npages_per_block * dev_info.page_size);
	dev_info.total_size = ((unsigned long long)dev_info.block_size *
	(unsigned long long)dev_info.nblocks_per_lun *
	dev_info.nluns);

	VERBOSE("CNF params: page_size %d, spare_size %d, block_size %u, total_size %llu\n",
	dev_info.page_size, dev_info.spare_size,
	dev_info.block_size, dev_info.total_size);

	return 0;
	}

	/* NAND Flash Controller/Host initialization */
	int cdns_nand_host_init(void)
	{
	uint32_t reg = 0U;
	int ret = 0;

	do {
	/* Read controller status register for init complete */
	reg = mmio_read_32(CNF_CMDREG(CTRL_STATUS));
	} while (CNF_GET_INIT_COMP(reg) == 0);

	ret = cdns_nand_update_dev_info();
	if (ret != 0) {
	return ret;
	}

	INFO("CNF: device discovery process completed and device type %d\n",
	dev_info.type);

	/* Enable data integrity, enable CRC and parity */
	reg = mmio_read_32(CNF_DI(CONTROL));
	reg \|= (1 << CNF_DI_PAR_EN);
	reg \|= (1 << CNF_DI_CRC_EN);
	mmio_write_32(CNF_DI(CONTROL), reg);

	/* Status polling mode, device control and status register */
	cdns_nand_wait_idle();
	reg = mmio_read_32(CNF_CTRLCFG(DEV_STAT));
	reg = reg & ~1;
	mmio_write_32(CNF_CTRLCFG(DEV_STAT), reg);

	/* Set operation work mode */
	cdns_nand_set_opr_mode(CNF_OPR_WORK_MODE_SDR);

	/* Set data transfer configuration parameters */
	cdns_nand_transfer_config();

	return 0;
	}

	/* erase: Block erase command */
	int cdns_nand_erase(uint32_t offset, uint32_t size)
	{
	/* Determine the starting block offset i.e row address */
	uint32_t row_address = dev_info.npages_per_block * offset;

	/* Wait for thread to be in ready state */
	cdns_nand_wait_thread_ready(CNF_DEF_TRD);

	/Set row address /
	mmio_write_32(CNF_CMDREG(CMD_REG1), row_address);

	/* Operation bank number */
	mmio_write_32(CNF_CMDREG(CMD_REG4), (CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

	/* Block erase command */
	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

	reg \|= (CNF_DEF_TRD << CNF_CMDREG0_TRD);
	reg \|= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
	reg \|= (CNF_INT_DIS << CNF_CMDREG0_INTR);
	reg \|= (CNF_CT_ERASE << CNF_CMDREG0_CMD);
	reg \|= (((size-1) & 0xFF) << CNF_CMDREG0_CMD);
	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

	/* Wait for erase operation to complete */
	return cdns_nand_last_opr_status(CNF_DEF_TRD);
	}

	/* io mtd functions */
	int cdns_nand_init_mtd(unsigned long long size, unsigned int erase_size)
	{
	*size = dev_info.total_size;
	*erase_size = dev_info.block_size;

	return 0;
	}

	static uint32_t cdns_nand_get_row_address(uint32_t page, uint32_t block)
	{
	uint32_t row_address = 0U;
	uint32_t req_bits = 0U;

	/* The device info is not populated yet. */
	if (dev_info.npages_per_block == 0U)
	return 0;

	for (uint32_t i = 0U; i < sizeof(uint32_t) * 8; i++) {
	if ((1U << i) & dev_info.npages_per_block)
	req_bits = i;
	}

	row_address = ((page & GENMASK_32((req_bits - 1), 0)) \|
	(block << req_bits));

	return row_address;
	}

	/* NAND Flash page read */
	static int cdns_nand_read_page(uint32_t block, uint32_t page, uintptr_t buffer)
	{

	/* Wait for thread to be ready */
	cdns_nand_wait_thread_ready(CNF_DEF_TRD);

	/* Select device */
	mmio_write_32(CNF_CMDREG(CMD_REG4),
	(CNF_DEF_DEVICE << CNF_CMDREG4_MEM));

	/* Set host memory address for DMA transfers */
	mmio_write_32(CNF_CMDREG(CMD_REG2), (buffer & UINT32_MAX));
	mmio_write_32(CNF_CMDREG(CMD_REG3), ((buffer >> 32) & UINT32_MAX));

	/* Set row address */
	mmio_write_32(CNF_CMDREG(CMD_REG1),
	cdns_nand_get_row_address(page, block));

	/* Page read command */
	uint32_t reg = (CNF_WORK_MODE_PIO << CNF_CMDREG0_CT);

	reg \|= (CNF_DEF_TRD << CNF_CMDREG0_TRD);
	reg \|= (CNF_DEF_VOL_ID << CNF_CMDREG0_VOL);
	reg \|= (CNF_INT_DIS << CNF_CMDREG0_INTR);
	reg \|= (CNF_DMA_MASTER_SEL << CNF_CMDREG0_DMA);
	reg \|= (CNF_CT_PAGE_READ << CNF_CMDREG0_CMD);
	reg \|= (((CNF_READ_SINGLE_PAGE-1) & 0xFF) << CNF_CMDREG0_CMD);
	mmio_write_32(CNF_CMDREG(CMD_REG0), reg);

	/* Wait for read operation to complete */
	if (cdns_nand_last_opr_status(CNF_DEF_TRD)) {
	ERROR("%s: Page read failed\n", __func__);
	return -EIO;
	}

	return 0;
	}

	int cdns_nand_read(unsigned int offset, uintptr_t buffer, size_t length,
	size_t *out_length)
	{
	uint32_t block = offset / dev_info.block_size;
	uint32_t end_block = (offset + length - 1U) / dev_info.block_size;
	uint32_t page_start = (offset % dev_info.block_size) / dev_info.page_size;
	uint32_t start_offset = offset % dev_info.page_size;
	uint32_t nb_pages = dev_info.block_size / dev_info.page_size;
	uint32_t bytes_read = 0U;
	uint32_t page = 0U;
	int result = 0;

	INFO("CNF: %s: block %u-%u, page_start %u, len %zu, offset %u\n",
	__func__, block, end_block, page_start, length, offset);

	if ((offset >= dev_info.total_size) \|\|
	(offset + length-1 >= dev_info.total_size) \|\|
	(length == 0U)) {
	ERROR("CNF: Invalid read parameters\n");
	return -EINVAL;
	}

	*out_length = 0UL;

	while (block <= end_block) {
	for (page = page_start; page < nb_pages; page++) {
	if ((start_offset != 0U) \|\| (length < dev_info.page_size)) {
	/* Partial page read */
	result = cdns_nand_read_page(block, page,
	(uintptr_t)scratch_buff);
	if (result != 0) {
	return result;
	}

	bytes_read = MIN((size_t)(dev_info.page_size - start_offset),
	length);

	memcpy((uint8_t *)buffer, scratch_buff + start_offset,
	bytes_read);
	start_offset = 0U;
	} else {
	/* Full page read */
	result = cdns_nand_read_page(block, page,
	(uintptr_t)scratch_buff);
	if (result != 0) {
	return result;
	}

	bytes_read = dev_info.page_size;
	memcpy((uint8_t *)buffer, scratch_buff, bytes_read);
	}

	length -= bytes_read;
	buffer += bytes_read;
	*out_length += bytes_read;

	/* All the bytes have read */
	if (length == 0U) {
	break;
	}

	udelay(CNF_READ_INT_DELAY_US);
	} /* for */

	page_start = 0U;
	block++;
	} /* while */

	return 0;
	}