blob: 9e4c192d94867adf055bde8ee9544805db6ccc28 [file] [log] [blame]
/*
* Copyright (c) 2020 Piotr Mienkowski
* Copyright (c) 2020 Linaro Limited
*
* SPDX-License-Identifier: Apache-2.0
*/
#define DT_DRV_COMPAT st_stm32_qspi_nor
#include <errno.h>
#include <kernel.h>
#include <toolchain.h>
#include <arch/common/ffs.h>
#include <sys/util.h>
#include <soc.h>
#include <drivers/pinctrl.h>
#include <drivers/clock_control/stm32_clock_control.h>
#include <drivers/clock_control.h>
#include <drivers/flash.h>
#include <drivers/dma.h>
#include <drivers/dma/dma_stm32.h>
#if DT_INST_NODE_HAS_PROP(0, spi_bus_width) && \
DT_INST_PROP(0, spi_bus_width) == 4
#define STM32_QSPI_USE_QUAD_IO 1
#else
#define STM32_QSPI_USE_QUAD_IO 0
#endif
#define STM32_QSPI_RESET_GPIO DT_INST_NODE_HAS_PROP(0, reset_gpios)
#if STM32_QSPI_RESET_GPIO
#include <drivers/gpio.h>
#endif
#include <stm32_ll_dma.h>
#include "spi_nor.h"
#include "jesd216.h"
#include <logging/log.h>
LOG_MODULE_REGISTER(flash_stm32_qspi, CONFIG_FLASH_LOG_LEVEL);
#define STM32_QSPI_FIFO_THRESHOLD 8
#define STM32_QSPI_CLOCK_PRESCALER_MAX 255
#define STM32_QSPI_USE_DMA DT_NODE_HAS_PROP(DT_INST_PARENT(0), dmas)
#if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_qspi_nor)
uint32_t table_m_size[] = {
LL_DMA_MDATAALIGN_BYTE,
LL_DMA_MDATAALIGN_HALFWORD,
LL_DMA_MDATAALIGN_WORD,
};
uint32_t table_p_size[] = {
LL_DMA_PDATAALIGN_BYTE,
LL_DMA_PDATAALIGN_HALFWORD,
LL_DMA_PDATAALIGN_WORD,
};
typedef void (*irq_config_func_t)(const struct device *dev);
struct stream {
DMA_TypeDef *reg;
const struct device *dev;
uint32_t channel;
struct dma_config cfg;
};
struct flash_stm32_qspi_config {
QUADSPI_TypeDef *regs;
struct stm32_pclken pclken;
irq_config_func_t irq_config;
size_t flash_size;
uint32_t max_frequency;
const struct pinctrl_dev_config *pcfg;
#if STM32_QSPI_RESET_GPIO
const struct gpio_dt_spec reset;
#endif
};
struct flash_stm32_qspi_data {
QSPI_HandleTypeDef hqspi;
struct k_sem sem;
struct k_sem sync;
#if defined(CONFIG_FLASH_PAGE_LAYOUT)
struct flash_pages_layout layout;
#endif
struct jesd216_erase_type erase_types[JESD216_NUM_ERASE_TYPES];
/* Number of bytes per page */
uint16_t page_size;
int cmd_status;
struct stream dma;
uint8_t qspi_read_cmd;
uint8_t qspi_read_cmd_latency;
/*
* If set addressed operations should use 32-bit rather than
* 24-bit addresses.
*/
bool flag_access_32bit: 1;
/*
* If set IO operations will be perfromed on SIO[0123] pins
*/
bool flag_quad_io_en: 1;
};
static inline void qspi_lock_thread(const struct device *dev)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
k_sem_take(&dev_data->sem, K_FOREVER);
}
static inline void qspi_unlock_thread(const struct device *dev)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
k_sem_give(&dev_data->sem);
}
static inline void qspi_set_address_size(const struct device *dev,
QSPI_CommandTypeDef *cmd)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
if (dev_data->flag_access_32bit) {
cmd->AddressSize = QSPI_ADDRESS_32_BITS;
return;
}
cmd->AddressSize = QSPI_ADDRESS_24_BITS;
}
static inline void qspi_prepare_quad_read(const struct device *dev,
QSPI_CommandTypeDef *cmd)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
if (IS_ENABLED(STM32_QSPI_USE_QUAD_IO) && dev_data->flag_quad_io_en) {
cmd->Instruction = dev_data->qspi_read_cmd;
cmd->AddressMode = QSPI_ADDRESS_4_LINES;
cmd->DataMode = QSPI_DATA_4_LINES;
cmd->DummyCycles = dev_data->qspi_read_cmd_latency;
}
}
static inline void qspi_prepare_quad_program(const struct device *dev,
QSPI_CommandTypeDef *cmd)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
/*
* There is no info about PP/4PP command in the SFDP tables,
* hence it has been assumed that NOR flash memory supporting
* 1-4-4 mode also would support fast page programming.
*/
if (IS_ENABLED(STM32_QSPI_USE_QUAD_IO) && dev_data->flag_quad_io_en) {
cmd->Instruction = SPI_NOR_CMD_4PP;
cmd->AddressMode = QSPI_ADDRESS_4_LINES;
cmd->DataMode = QSPI_DATA_4_LINES;
/*
* Dummy cycles are not required for 4PP command -
* data to be programmed are sent just after address.
*/
cmd->DummyCycles = 0;
}
}
/*
* Send a command over QSPI bus.
*/
static int qspi_send_cmd(const struct device *dev, QSPI_CommandTypeDef *cmd)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *dev_data = dev->data;
HAL_StatusTypeDef hal_ret;
ARG_UNUSED(dev_cfg);
LOG_DBG("Instruction 0x%x", cmd->Instruction);
dev_data->cmd_status = 0;
hal_ret = HAL_QSPI_Command_IT(&dev_data->hqspi, cmd);
if (hal_ret != HAL_OK) {
LOG_ERR("%d: Failed to send QSPI instruction", hal_ret);
return -EIO;
}
LOG_DBG("CCR 0x%x", dev_cfg->regs->CCR);
k_sem_take(&dev_data->sync, K_FOREVER);
return dev_data->cmd_status;
}
/*
* Perform a read access over QSPI bus.
*/
static int qspi_read_access(const struct device *dev, QSPI_CommandTypeDef *cmd,
uint8_t *data, size_t size)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *dev_data = dev->data;
HAL_StatusTypeDef hal_ret;
ARG_UNUSED(dev_cfg);
cmd->NbData = size;
dev_data->cmd_status = 0;
hal_ret = HAL_QSPI_Command_IT(&dev_data->hqspi, cmd);
if (hal_ret != HAL_OK) {
LOG_ERR("%d: Failed to send QSPI instruction", hal_ret);
return -EIO;
}
#if STM32_QSPI_USE_DMA
hal_ret = HAL_QSPI_Receive_DMA(&dev_data->hqspi, data);
#else
hal_ret = HAL_QSPI_Receive_IT(&dev_data->hqspi, data);
#endif
if (hal_ret != HAL_OK) {
LOG_ERR("%d: Failed to read data", hal_ret);
return -EIO;
}
k_sem_take(&dev_data->sync, K_FOREVER);
return dev_data->cmd_status;
}
/*
* Perform a write access over QSPI bus.
*/
static int qspi_write_access(const struct device *dev, QSPI_CommandTypeDef *cmd,
const uint8_t *data, size_t size)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *dev_data = dev->data;
HAL_StatusTypeDef hal_ret;
ARG_UNUSED(dev_cfg);
LOG_DBG("Instruction 0x%x", cmd->Instruction);
cmd->NbData = size;
dev_data->cmd_status = 0;
hal_ret = HAL_QSPI_Command_IT(&dev_data->hqspi, cmd);
if (hal_ret != HAL_OK) {
LOG_ERR("%d: Failed to send QSPI instruction", hal_ret);
return -EIO;
}
#if STM32_QSPI_USE_DMA
hal_ret = HAL_QSPI_Transmit_DMA(&dev_data->hqspi, (uint8_t *)data);
#else
hal_ret = HAL_QSPI_Transmit_IT(&dev_data->hqspi, (uint8_t *)data);
#endif
if (hal_ret != HAL_OK) {
LOG_ERR("%d: Failed to read data", hal_ret);
return -EIO;
}
LOG_DBG("CCR 0x%x", dev_cfg->regs->CCR);
k_sem_take(&dev_data->sync, K_FOREVER);
return dev_data->cmd_status;
}
/*
* Read Serial Flash Discovery Parameter
*/
static int qspi_read_sfdp(const struct device *dev, off_t addr, uint8_t *data,
size_t size)
{
QSPI_CommandTypeDef cmd = {
.Instruction = JESD216_CMD_READ_SFDP,
.Address = addr,
.AddressSize = QSPI_ADDRESS_24_BITS,
.DummyCycles = 8,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.AddressMode = QSPI_ADDRESS_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
return qspi_read_access(dev, &cmd, data, size);
}
static bool qspi_address_is_valid(const struct device *dev, off_t addr,
size_t size)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
size_t flash_size = dev_cfg->flash_size;
return (addr >= 0) && ((uint64_t)addr + (uint64_t)size <= flash_size);
}
static int flash_stm32_qspi_read(const struct device *dev, off_t addr,
void *data, size_t size)
{
int ret;
if (!qspi_address_is_valid(dev, addr, size)) {
LOG_DBG("Error: address or size exceeds expected values: "
"addr 0x%lx, size %zu", (long)addr, size);
return -EINVAL;
}
/* read non-zero size */
if (size == 0) {
return 0;
}
QSPI_CommandTypeDef cmd = {
.Instruction = SPI_NOR_CMD_READ,
.Address = addr,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.AddressMode = QSPI_ADDRESS_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
qspi_set_address_size(dev, &cmd);
qspi_prepare_quad_read(dev, &cmd);
qspi_lock_thread(dev);
ret = qspi_read_access(dev, &cmd, data, size);
qspi_unlock_thread(dev);
return ret;
}
static int qspi_wait_until_ready(const struct device *dev)
{
uint8_t reg;
int ret;
QSPI_CommandTypeDef cmd = {
.Instruction = SPI_NOR_CMD_RDSR,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
do {
ret = qspi_read_access(dev, &cmd, &reg, sizeof(reg));
} while (!ret && (reg & SPI_NOR_WIP_BIT));
return ret;
}
static int flash_stm32_qspi_write(const struct device *dev, off_t addr,
const void *data, size_t size)
{
int ret = 0;
if (!qspi_address_is_valid(dev, addr, size)) {
LOG_DBG("Error: address or size exceeds expected values: "
"addr 0x%lx, size %zu", (long)addr, size);
return -EINVAL;
}
/* write non-zero size */
if (size == 0) {
return 0;
}
QSPI_CommandTypeDef cmd_write_en = {
.Instruction = SPI_NOR_CMD_WREN,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
};
QSPI_CommandTypeDef cmd_pp = {
.Instruction = SPI_NOR_CMD_PP,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.AddressMode = QSPI_ADDRESS_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
qspi_set_address_size(dev, &cmd_pp);
qspi_prepare_quad_program(dev, &cmd_pp);
qspi_lock_thread(dev);
while (size > 0) {
size_t to_write = size;
/* Don't write more than a page. */
if (to_write >= SPI_NOR_PAGE_SIZE) {
to_write = SPI_NOR_PAGE_SIZE;
}
/* Don't write across a page boundary */
if (((addr + to_write - 1U) / SPI_NOR_PAGE_SIZE)
!= (addr / SPI_NOR_PAGE_SIZE)) {
to_write = SPI_NOR_PAGE_SIZE -
(addr % SPI_NOR_PAGE_SIZE);
}
ret = qspi_send_cmd(dev, &cmd_write_en);
if (ret != 0) {
break;
}
cmd_pp.Address = addr;
ret = qspi_write_access(dev, &cmd_pp, data, to_write);
if (ret != 0) {
break;
}
size -= to_write;
data = (const uint8_t *)data + to_write;
addr += to_write;
ret = qspi_wait_until_ready(dev);
if (ret != 0) {
break;
}
}
qspi_unlock_thread(dev);
return ret;
}
static int flash_stm32_qspi_erase(const struct device *dev, off_t addr,
size_t size)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *dev_data = dev->data;
int ret = 0;
if (!qspi_address_is_valid(dev, addr, size)) {
LOG_DBG("Error: address or size exceeds expected values: "
"addr 0x%lx, size %zu", (long)addr, size);
return -EINVAL;
}
/* erase non-zero size */
if (size == 0) {
return 0;
}
QSPI_CommandTypeDef cmd_write_en = {
.Instruction = SPI_NOR_CMD_WREN,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
};
QSPI_CommandTypeDef cmd_erase = {
.Instruction = 0,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.AddressMode = QSPI_ADDRESS_1_LINE,
};
qspi_set_address_size(dev, &cmd_erase);
qspi_lock_thread(dev);
while ((size > 0) && (ret == 0)) {
cmd_erase.Address = addr;
qspi_send_cmd(dev, &cmd_write_en);
if (size == dev_cfg->flash_size) {
/* chip erase */
cmd_erase.Instruction = SPI_NOR_CMD_CE;
cmd_erase.AddressMode = QSPI_ADDRESS_NONE;
qspi_send_cmd(dev, &cmd_erase);
size -= dev_cfg->flash_size;
} else {
const struct jesd216_erase_type *erase_types =
dev_data->erase_types;
const struct jesd216_erase_type *bet = NULL;
for (uint8_t ei = 0;
ei < JESD216_NUM_ERASE_TYPES; ++ei) {
const struct jesd216_erase_type *etp =
&erase_types[ei];
if ((etp->exp != 0)
&& SPI_NOR_IS_ALIGNED(addr, etp->exp)
&& SPI_NOR_IS_ALIGNED(size, etp->exp)
&& ((bet == NULL)
|| (etp->exp > bet->exp))) {
bet = etp;
cmd_erase.Instruction = bet->cmd;
}
}
if (bet != NULL) {
qspi_send_cmd(dev, &cmd_erase);
addr += BIT(bet->exp);
size -= BIT(bet->exp);
} else {
LOG_ERR("Can't erase %zu at 0x%lx",
size, (long)addr);
ret = -EINVAL;
}
}
qspi_wait_until_ready(dev);
}
qspi_unlock_thread(dev);
return ret;
}
static const struct flash_parameters flash_stm32_qspi_parameters = {
.write_block_size = 1,
.erase_value = 0xff
};
static const struct flash_parameters *
flash_stm32_qspi_get_parameters(const struct device *dev)
{
ARG_UNUSED(dev);
return &flash_stm32_qspi_parameters;
}
static void flash_stm32_qspi_isr(const struct device *dev)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
HAL_QSPI_IRQHandler(&dev_data->hqspi);
}
/* This function is executed in the interrupt context */
#if STM32_QSPI_USE_DMA
static void qspi_dma_callback(const struct device *dev, void *arg,
uint32_t channel, int status)
{
DMA_HandleTypeDef *hdma = arg;
if (status != 0) {
LOG_ERR("DMA callback error with channel %d.", channel);
}
HAL_DMA_IRQHandler(hdma);
}
#endif
__weak HAL_StatusTypeDef HAL_DMA_Abort_IT(DMA_HandleTypeDef *hdma)
{
return HAL_OK;
}
/*
* Transfer Error callback.
*/
void HAL_QSPI_ErrorCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
LOG_DBG("Enter");
dev_data->cmd_status = -EIO;
k_sem_give(&dev_data->sync);
}
/*
* Command completed callback.
*/
void HAL_QSPI_CmdCpltCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
k_sem_give(&dev_data->sync);
}
/*
* Rx Transfer completed callback.
*/
void HAL_QSPI_RxCpltCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
k_sem_give(&dev_data->sync);
}
/*
* Tx Transfer completed callback.
*/
void HAL_QSPI_TxCpltCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
k_sem_give(&dev_data->sync);
}
/*
* Status Match callback.
*/
void HAL_QSPI_StatusMatchCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
k_sem_give(&dev_data->sync);
}
/*
* Timeout callback.
*/
void HAL_QSPI_TimeOutCallback(QSPI_HandleTypeDef *hqspi)
{
struct flash_stm32_qspi_data *dev_data =
CONTAINER_OF(hqspi, struct flash_stm32_qspi_data, hqspi);
LOG_DBG("Enter");
dev_data->cmd_status = -EIO;
k_sem_give(&dev_data->sync);
}
#if defined(CONFIG_FLASH_PAGE_LAYOUT)
static void flash_stm32_qspi_pages_layout(const struct device *dev,
const struct flash_pages_layout **layout,
size_t *layout_size)
{
struct flash_stm32_qspi_data *dev_data = dev->data;
*layout = &dev_data->layout;
*layout_size = 1;
}
#endif
static const struct flash_driver_api flash_stm32_qspi_driver_api = {
.read = flash_stm32_qspi_read,
.write = flash_stm32_qspi_write,
.erase = flash_stm32_qspi_erase,
.get_parameters = flash_stm32_qspi_get_parameters,
#if defined(CONFIG_FLASH_PAGE_LAYOUT)
.page_layout = flash_stm32_qspi_pages_layout,
#endif
};
#if defined(CONFIG_FLASH_PAGE_LAYOUT)
static int setup_pages_layout(const struct device *dev)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *data = dev->data;
const size_t flash_size = dev_cfg->flash_size;
uint32_t layout_page_size = data->page_size;
uint8_t exp = 0;
int rv = 0;
/* Find the smallest erase size. */
for (size_t i = 0; i < ARRAY_SIZE(data->erase_types); ++i) {
const struct jesd216_erase_type *etp = &data->erase_types[i];
if ((etp->cmd != 0)
&& ((exp == 0) || (etp->exp < exp))) {
exp = etp->exp;
}
}
if (exp == 0) {
return -ENOTSUP;
}
uint32_t erase_size = BIT(exp);
/* We need layout page size to be compatible with erase size */
if ((layout_page_size % erase_size) != 0) {
LOG_DBG("layout page %u not compatible with erase size %u",
layout_page_size, erase_size);
LOG_DBG("erase size will be used as layout page size");
layout_page_size = erase_size;
}
/* Warn but accept layout page sizes that leave inaccessible
* space.
*/
if ((flash_size % layout_page_size) != 0) {
LOG_INF("layout page %u wastes space with device size %zu",
layout_page_size, flash_size);
}
data->layout.pages_size = layout_page_size;
data->layout.pages_count = flash_size / layout_page_size;
LOG_DBG("layout %u x %u By pages", data->layout.pages_count,
data->layout.pages_size);
return rv;
}
#endif /* CONFIG_FLASH_PAGE_LAYOUT */
static int qspi_program_addr_4b(const struct device *dev)
{
uint8_t reg;
int ret;
/* Program the flash memory to use 4 bytes addressing */
QSPI_CommandTypeDef cmd = {
.Instruction = SPI_NOR_CMD_4BA,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
};
ret = qspi_send_cmd(dev, &cmd);
if (ret) {
return ret;
}
/*
* Read control register to verify if 4byte addressing mode
* is enabled.
*/
cmd.Instruction = SPI_NOR_CMD_RDCR;
cmd.InstructionMode = QSPI_INSTRUCTION_1_LINE;
cmd.DataMode = QSPI_DATA_1_LINE;
ret = qspi_read_access(dev, &cmd, &reg, sizeof(reg));
if (!ret && !(reg & SPI_NOR_4BYTE_BIT)) {
return -EINVAL;
}
return ret;
}
static int qspi_read_status_register(const struct device *dev, uint8_t *reg)
{
QSPI_CommandTypeDef cmd = {
.Instruction = SPI_NOR_CMD_RDSR,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
return qspi_read_access(dev, &cmd, reg, sizeof(*reg));
}
static int qspi_write_status_register(const struct device *dev, uint8_t reg)
{
QSPI_CommandTypeDef cmd = {
.Instruction = SPI_NOR_CMD_WRSR,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
.DataMode = QSPI_DATA_1_LINE,
};
return qspi_write_access(dev, &cmd, &reg, sizeof(reg));
}
static int qspi_write_enable(const struct device *dev)
{
uint8_t reg;
int ret;
QSPI_CommandTypeDef cmd_write_en = {
.Instruction = SPI_NOR_CMD_WREN,
.InstructionMode = QSPI_INSTRUCTION_1_LINE,
};
ret = qspi_send_cmd(dev, &cmd_write_en);
if (ret) {
return ret;
}
do {
ret = qspi_read_status_register(dev, &reg);
} while (!ret && !(reg & SPI_NOR_WEL_BIT));
return ret;
}
static int qspi_program_quad_io(const struct device *dev)
{
struct flash_stm32_qspi_data *data = dev->data;
uint8_t reg;
int ret;
/* Check if QE bit setting is required */
ret = qspi_read_status_register(dev, &reg);
if (ret) {
return ret;
}
/* Quit early when QE bit is already set */
if (reg & SPI_NOR_QE_BIT) {
goto out;
}
ret = qspi_write_enable(dev);
if (ret) {
return ret;
}
reg |= SPI_NOR_QE_BIT;
ret = qspi_write_status_register(dev, reg);
if (ret) {
return ret;
}
ret = qspi_wait_until_ready(dev);
if (ret) {
return ret;
}
ret = qspi_read_status_register(dev, &reg);
if (ret) {
return ret;
}
/* Check if QE bit programming is finished */
if (!(reg & SPI_NOR_QE_BIT)) {
LOG_ERR("Quad Enable [QE] bit in status reg not set");
return -EIO;
}
out:
LOG_INF("Flash - QUAD mode enabled [SR:0x%02x]", reg);
data->flag_quad_io_en = true;
return ret;
}
static int spi_nor_process_bfp(const struct device *dev,
const struct jesd216_param_header *php,
const struct jesd216_bfp *bfp)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *data = dev->data;
struct jesd216_erase_type *etp = data->erase_types;
const size_t flash_size = jesd216_bfp_density(bfp) / 8U;
uint8_t addr_mode;
int rc;
if (flash_size != dev_cfg->flash_size) {
LOG_ERR("Unexpected flash size: %u", flash_size);
}
LOG_INF("%s: %u MiBy flash", dev->name, (uint32_t)(flash_size >> 20));
/* Copy over the erase types, preserving their order. (The
* Sector Map Parameter table references them by index.)
*/
memset(data->erase_types, 0, sizeof(data->erase_types));
for (uint8_t ti = 1; ti <= ARRAY_SIZE(data->erase_types); ++ti) {
if (jesd216_bfp_erase(bfp, ti, etp) == 0) {
LOG_DBG("Erase %u with %02x",
(uint32_t)BIT(etp->exp), etp->cmd);
}
++etp;
}
data->page_size = jesd216_bfp_page_size(php, bfp);
LOG_DBG("Page size %u bytes", data->page_size);
LOG_DBG("Flash size %u bytes", flash_size);
addr_mode = jesd216_bfp_addrbytes(bfp);
if (addr_mode == JESD216_SFDP_BFP_DW1_ADDRBYTES_VAL_3B4B) {
struct jesd216_bfp_dw16 dw16;
if (jesd216_bfp_decode_dw16(php, bfp, &dw16) == 0) {
/*
* According to JESD216, the bit0 of dw16.enter_4ba
* portion of flash description register 16 indicates
* if it is enough to use 0xB7 instruction without
* write enable to switch to 4 bytes addressing mode.
*/
if (dw16.enter_4ba & 0x1) {
rc = qspi_program_addr_4b(dev);
if (rc == 0) {
data->flag_access_32bit = true;
LOG_INF("Flash - address mode: 4B");
} else {
LOG_ERR("Unable to enter 4B mode: %d\n", rc);
return rc;
}
}
}
}
/*
* Only check if the 1-4-4 (i.e. 4READ) fast read operation is
* supported - other modes - e.g. 1-1-4 (QREAD) or 1-1-2 (DREAD) are
* not.
*/
if (IS_ENABLED(STM32_QSPI_USE_QUAD_IO)) {
struct jesd216_instr res;
rc = jesd216_bfp_read_support(php, bfp, JESD216_MODE_144, &res);
if (rc > 0) {
/* Program flash memory to use SIO[0123] */
rc = qspi_program_quad_io(dev);
if (rc) {
LOG_ERR("Unable to enable QUAD IO mode: %d\n",
rc);
return rc;
}
LOG_INF("Mode: 1-4-4 with instr:[0x%x] supported!",
res.instr);
data->qspi_read_cmd = res.instr;
data->qspi_read_cmd_latency = res.wait_states;
if (res.mode_clocks) {
data->qspi_read_cmd_latency +=
res.mode_clocks;
}
}
}
return 0;
}
#if STM32_QSPI_RESET_GPIO
static void flash_stm32_qspi_gpio_reset(const struct device *dev)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
/* Generate RESETn pulse for the flash memory */
gpio_pin_configure_dt(&dev_cfg->reset, GPIO_OUTPUT_ACTIVE);
k_msleep(DT_INST_PROP(0, reset_gpios_duration));
gpio_pin_set_dt(&dev_cfg->reset, 0);
}
#endif
static int flash_stm32_qspi_init(const struct device *dev)
{
const struct flash_stm32_qspi_config *dev_cfg = dev->config;
struct flash_stm32_qspi_data *dev_data = dev->data;
uint32_t ahb_clock_freq;
uint32_t prescaler = 0;
int ret;
/* Signals configuration */
ret = pinctrl_apply_state(dev_cfg->pcfg, PINCTRL_STATE_DEFAULT);
if (ret < 0) {
LOG_ERR("QSPI pinctrl setup failed (%d)", ret);
return ret;
}
#if STM32_QSPI_RESET_GPIO
flash_stm32_qspi_gpio_reset(dev);
#endif
#if STM32_QSPI_USE_DMA
/*
* DMA configuration
* Due to use of QSPI HAL API in current driver,
* both HAL and Zephyr DMA drivers should be configured.
* The required configuration for Zephyr DMA driver should only provide
* the minimum information to inform the DMA slot will be in used and
* how to route callbacks.
*/
struct dma_config dma_cfg = dev_data->dma.cfg;
static DMA_HandleTypeDef hdma;
if (!device_is_ready(dev_data->dma.dev)) {
LOG_ERR("%s device not ready", dev_data->dma.dev->name);
return -ENODEV;
}
/* Proceed to the minimum Zephyr DMA driver init */
dma_cfg.user_data = &hdma;
/* HACK: This field is used to inform driver that it is overridden */
dma_cfg.linked_channel = STM32_DMA_HAL_OVERRIDE;
ret = dma_config(dev_data->dma.dev, dev_data->dma.channel, &dma_cfg);
if (ret != 0) {
return ret;
}
/* Proceed to the HAL DMA driver init */
if (dma_cfg.source_data_size != dma_cfg.dest_data_size) {
LOG_ERR("Source and destination data sizes not aligned");
return -EINVAL;
}
int index = find_lsb_set(dma_cfg.source_data_size) - 1;
hdma.Init.PeriphDataAlignment = table_p_size[index];
hdma.Init.MemDataAlignment = table_m_size[index];
hdma.Init.PeriphInc = DMA_PINC_DISABLE;
hdma.Init.MemInc = DMA_MINC_ENABLE;
hdma.Init.Mode = DMA_NORMAL;
hdma.Init.Priority = dma_cfg.channel_priority;
#ifdef CONFIG_DMA_STM32_V1
/* TODO: Not tested in this configuration */
hdma.Init.Channel = dma_cfg.dma_slot;
hdma.Instance = __LL_DMA_GET_STREAM_INSTANCE(dev_data->dma.reg,
dev_data->dma.channel);
#else
hdma.Init.Request = dma_cfg.dma_slot;
#ifdef CONFIG_DMAMUX_STM32
/* HAL expects a valid DMA channel (not DAMMUX) */
/* TODO: Get DMA instance from DT */
hdma.Instance = __LL_DMA_GET_CHANNEL_INSTANCE(DMA1,
dev_data->dma.channel+1);
#else
hdma.Instance = __LL_DMA_GET_CHANNEL_INSTANCE(dev_data->dma.reg,
dev_data->dma.channel-1);
#endif
#endif /* CONFIG_DMA_STM32_V1 */
/* Initialize DMA HAL */
__HAL_LINKDMA(&dev_data->hqspi, hdma, hdma);
HAL_DMA_Init(&hdma);
#endif /* STM32_QSPI_USE_DMA */
/* Clock configuration */
if (clock_control_on(DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE),
(clock_control_subsys_t) &dev_cfg->pclken) != 0) {
LOG_DBG("Could not enable QSPI clock");
return -EIO;
}
if (clock_control_get_rate(DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE),
(clock_control_subsys_t) &dev_cfg->pclken,
&ahb_clock_freq) < 0) {
LOG_DBG("Failed to get AHB clock frequency");
return -EIO;
}
for (; prescaler <= STM32_QSPI_CLOCK_PRESCALER_MAX; prescaler++) {
uint32_t clk = ahb_clock_freq / (prescaler + 1);
if (clk <= dev_cfg->max_frequency) {
break;
}
}
__ASSERT_NO_MSG(prescaler <= STM32_QSPI_CLOCK_PRESCALER_MAX);
/* Initialize QSPI HAL */
dev_data->hqspi.Init.ClockPrescaler = prescaler;
dev_data->hqspi.Init.FlashSize = find_lsb_set(dev_cfg->flash_size);
HAL_QSPI_Init(&dev_data->hqspi);
#if DT_NODE_HAS_PROP(DT_NODELABEL(quadspi), flash_id)
uint8_t qspi_flash_id = DT_PROP(DT_NODELABEL(quadspi), flash_id);
HAL_QSPI_SetFlashID(&dev_data->hqspi,
(qspi_flash_id - 1) << QUADSPI_CR_FSEL_Pos);
#endif
/* Initialize semaphores */
k_sem_init(&dev_data->sem, 1, 1);
k_sem_init(&dev_data->sync, 0, 1);
/* Run IRQ init */
dev_cfg->irq_config(dev);
/* Run NOR init */
const uint8_t decl_nph = 2;
union {
/* We only process BFP so use one parameter block */
uint8_t raw[JESD216_SFDP_SIZE(decl_nph)];
struct jesd216_sfdp_header sfdp;
} u;
const struct jesd216_sfdp_header *hp = &u.sfdp;
ret = qspi_read_sfdp(dev, 0, u.raw, sizeof(u.raw));
if (ret != 0) {
LOG_ERR("SFDP read failed: %d", ret);
return ret;
}
uint32_t magic = jesd216_sfdp_magic(hp);
if (magic != JESD216_SFDP_MAGIC) {
LOG_ERR("SFDP magic %08x invalid", magic);
return -EINVAL;
}
LOG_INF("%s: SFDP v %u.%u AP %x with %u PH", dev->name,
hp->rev_major, hp->rev_minor, hp->access, 1 + hp->nph);
const struct jesd216_param_header *php = hp->phdr;
const struct jesd216_param_header *phpe = php +
MIN(decl_nph, 1 + hp->nph);
while (php != phpe) {
uint16_t id = jesd216_param_id(php);
LOG_INF("PH%u: %04x rev %u.%u: %u DW @ %x",
(php - hp->phdr), id, php->rev_major, php->rev_minor,
php->len_dw, jesd216_param_addr(php));
if (id == JESD216_SFDP_PARAM_ID_BFP) {
union {
uint32_t dw[MIN(php->len_dw, 20)];
struct jesd216_bfp bfp;
} u;
const struct jesd216_bfp *bfp = &u.bfp;
ret = qspi_read_sfdp(dev, jesd216_param_addr(php),
(uint8_t *)u.dw, sizeof(u.dw));
if (ret == 0) {
ret = spi_nor_process_bfp(dev, php, bfp);
}
if (ret != 0) {
LOG_ERR("SFDP BFP failed: %d", ret);
break;
}
}
++php;
}
#if defined(CONFIG_FLASH_PAGE_LAYOUT)
ret = setup_pages_layout(dev);
if (ret != 0) {
LOG_ERR("layout setup failed: %d", ret);
return -ENODEV;
}
#endif /* CONFIG_FLASH_PAGE_LAYOUT */
LOG_INF("Device %s initialized", dev->name);
return 0;
}
#define DMA_CHANNEL_CONFIG(node, dir) \
DT_DMAS_CELL_BY_NAME(node, dir, channel_config)
#define QSPI_DMA_CHANNEL_INIT(node, dir) \
.dev = DEVICE_DT_GET(DT_DMAS_CTLR(node)), \
.channel = DT_DMAS_CELL_BY_NAME(node, dir, channel), \
.reg = (DMA_TypeDef *)DT_REG_ADDR( \
DT_PHANDLE_BY_NAME(node, dmas, dir)),\
.cfg = { \
.dma_slot = DT_DMAS_CELL_BY_NAME(node, dir, slot), \
.source_data_size = STM32_DMA_CONFIG_PERIPHERAL_DATA_SIZE( \
DMA_CHANNEL_CONFIG(node, dir)), \
.dest_data_size = STM32_DMA_CONFIG_MEMORY_DATA_SIZE( \
DMA_CHANNEL_CONFIG(node, dir)), \
.channel_priority = STM32_DMA_CONFIG_PRIORITY( \
DMA_CHANNEL_CONFIG(node, dir)), \
.dma_callback = qspi_dma_callback, \
}, \
#define QSPI_DMA_CHANNEL(node, dir) \
.dma = { \
COND_CODE_1(DT_DMAS_HAS_NAME(node, dir), \
(QSPI_DMA_CHANNEL_INIT(node, dir)), \
(NULL)) \
},
#define QSPI_FLASH_MODULE(drv_id, flash_id) \
(DT_DRV_INST(drv_id), qspi_nor_flash_##flash_id)
static void flash_stm32_qspi_irq_config_func(const struct device *dev);
#define STM32_QSPI_NODE DT_INST_PARENT(0)
PINCTRL_DT_DEFINE(STM32_QSPI_NODE);
static const struct flash_stm32_qspi_config flash_stm32_qspi_cfg = {
.regs = (QUADSPI_TypeDef *)DT_REG_ADDR(STM32_QSPI_NODE),
.pclken = {
.enr = DT_CLOCKS_CELL(STM32_QSPI_NODE, bits),
.bus = DT_CLOCKS_CELL(STM32_QSPI_NODE, bus)
},
.irq_config = flash_stm32_qspi_irq_config_func,
.flash_size = DT_INST_PROP(0, size) / 8U,
.max_frequency = DT_INST_PROP(0, qspi_max_frequency),
.pcfg = PINCTRL_DT_DEV_CONFIG_GET(STM32_QSPI_NODE),
#if STM32_QSPI_RESET_GPIO
.reset = GPIO_DT_SPEC_INST_GET(0, reset_gpios),
#endif
};
static struct flash_stm32_qspi_data flash_stm32_qspi_dev_data = {
.hqspi = {
.Instance = (QUADSPI_TypeDef *)DT_REG_ADDR(STM32_QSPI_NODE),
.Init = {
.FifoThreshold = STM32_QSPI_FIFO_THRESHOLD,
.SampleShifting = QSPI_SAMPLE_SHIFTING_NONE,
.ChipSelectHighTime = QSPI_CS_HIGH_TIME_1_CYCLE,
.ClockMode = QSPI_CLOCK_MODE_0,
},
},
QSPI_DMA_CHANNEL(STM32_QSPI_NODE, tx_rx)
};
DEVICE_DT_INST_DEFINE(0, &flash_stm32_qspi_init, NULL,
&flash_stm32_qspi_dev_data, &flash_stm32_qspi_cfg,
POST_KERNEL, CONFIG_FLASH_INIT_PRIORITY,
&flash_stm32_qspi_driver_api);
static void flash_stm32_qspi_irq_config_func(const struct device *dev)
{
IRQ_CONNECT(DT_IRQN(STM32_QSPI_NODE), DT_IRQ(STM32_QSPI_NODE, priority),
flash_stm32_qspi_isr, DEVICE_DT_INST_GET(0), 0);
irq_enable(DT_IRQN(STM32_QSPI_NODE));
}
#endif