drivers/flash/flash_stm32wbx.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Linaro Limited
  * Copyright (c) 2020 STMicroelectronics
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #define LOG_DOMAIN flash_stm32wb
 #define LOG_LEVEL CONFIG_FLASH_LOG_LEVEL
 #include <zephyr/logging/log.h>
 LOG_MODULE_REGISTER(LOG_DOMAIN);

 #include <zephyr/kernel.h>
 #include <zephyr/device.h>
 #include <string.h>
 #include <zephyr/drivers/flash.h>
 #include <zephyr/init.h>
 #include <soc.h>
 #include <zephyr/sys/__assert.h>

 #include "flash_stm32.h"
 #include "stm32_hsem.h"
 #if defined(CONFIG_BT)
 #include "shci.h"
 #endif

 #define STM32WBX_PAGE_SHIFT	12

 /* offset and len must be aligned on 8 for write,
  * positive and not beyond end of flash
  */
 bool flash_stm32_valid_range(const struct device *dev, off_t offset,
 			     uint32_t len,
 			     bool write)
 {
 	return (!write || (offset % 8 == 0 && len % 8 == 0U)) &&
 	       flash_stm32_range_exists(dev, offset, len);
 }

 /*
  * Up to 255 4K pages
  */
 static uint32_t get_page(off_t offset)
 {
 	return offset >> STM32WBX_PAGE_SHIFT;
 }

 static inline void flush_cache(FLASH_TypeDef *regs)
 {
 	if (regs->ACR & FLASH_ACR_DCEN) {
 		regs->ACR &= ~FLASH_ACR_DCEN;
 		/* Datasheet: DCRST: Data cache reset
 		 * This bit can be written only when the data cache is disabled
 		 */
 		regs->ACR |= FLASH_ACR_DCRST;
 		regs->ACR &= ~FLASH_ACR_DCRST;
 		regs->ACR |= FLASH_ACR_DCEN;
 	}

 	if (regs->ACR & FLASH_ACR_ICEN) {
 		regs->ACR &= ~FLASH_ACR_ICEN;
 		/* Datasheet: ICRST: Instruction cache reset :
 		 * This bit can be written only when the instruction cache
 		 * is disabled
 		 */
 		regs->ACR |= FLASH_ACR_ICRST;
 		regs->ACR &= ~FLASH_ACR_ICRST;
 		regs->ACR |= FLASH_ACR_ICEN;
 	}
 }

 static int write_dword(const struct device *dev, off_t offset, uint64_t val)
 {
 	volatile uint32_t *flash = (uint32_t *)(offset + CONFIG_FLASH_BASE_ADDRESS);
 	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
 	uint32_t tmp;
 	int ret, rc;
 	uint32_t cpu1_sem_status;
 	uint32_t cpu2_sem_status = 0;
 	uint32_t key;

 	/* if the control register is locked, do not fail silently */
 	if (regs->CR & FLASH_CR_LOCK) {
 		return -EIO;
 	}

 	/* Check if this double word is erased */
 	if (flash[0] != 0xFFFFFFFFUL ||
 	    flash[1] != 0xFFFFFFFFUL) {
 		return -EIO;
 	}

 	ret = flash_stm32_check_status(dev);
 	if (ret < 0) {
 		return -EIO;
 	}

 	/* Implementation of STM32 AN5289, proposed in STM32WB Cube Application
 	 * BLE_RfWithFlash
 	 * https://github.com/STMicroelectronics/STM32CubeWB/tree/master/Projects/P-NUCLEO-WB55.Nucleo/Applications/BLE/BLE_RfWithFlash
 	 */

 	do {
 		/**
 		 * When the PESD bit mechanism is used by CPU2 to protect its
 		 * timing, the PESD bit should be polled here.
 		 * If the PESD is set, the CPU1 will be stalled when reading
 		 * literals from an ISR that may occur after the flash
 		 * processing has been requested but suspended due to the PESD
 		 * bit.
 		 *
 		 * Note: This code is required only when the PESD mechanism is
 		 * used to protect the CPU2 timing.
 		 * However, keeping that code make it compatible with both
 		 * mechanisms.
 		 */
 		while (LL_FLASH_IsActiveFlag_OperationSuspended()) {
 			;
 		}

 		/* Enter critical section */
 		key = irq_lock();

 		/**
 		 *  Depending on the application implementation, in case a
 		 *  multitasking is possible with an OS, it should be checked
 		 *  here if another task in the application disallowed flash
 		 *  processing to protect some latency in critical code
 		 *  execution.
 		 *  When flash processing is ongoing, the CPU cannot access the
 		 *  flash anymore.Trying to access the flash during that time
 		 *  stalls the CPU.
 		 *  The only way for CPU1 to disallow flash processing is to
 		 *  take CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID.
 		 */
 		cpu1_sem_status = LL_HSEM_GetStatus(HSEM,
 			CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID);
 		if (cpu1_sem_status == 0) {
 			/**
 			 *  Check now if the CPU2 disallows flash processing to
 			 *  protect its timing. If the semaphore is locked, the
 			 *  CPU2 does not allow flash processing
 			 *
 			 *  Note: By default, the CPU2 uses the PESD mechanism
 			 *  to protect its timing, therefore, it is useless to
 			 *  get/release the semaphore.
 			 *
 			 *  However, keeping that code make it compatible with
 			 *  both mechanisms.
 			 *  The protection by semaphore is enabled on CPU2 side
 			 *  with the command SHCI_C2_SetFlashActivityControl()
 			 *
 			 */
 			cpu2_sem_status = LL_HSEM_1StepLock(HSEM,
 				CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID);
 			if (cpu2_sem_status == 0) {
 				/**
 				 * When CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID is
 				 * taken, it is allowed to only write one
 				 * single 64bits data.
 				 * When several 64bits data need to be erased,
 				 * the application shall first exit from the
 				 * critical section and try again.
 				 */
 				/* Set the PG bit */
 				regs->CR |= FLASH_CR_PG;

 				/* Flush the register write */
 				tmp = regs->CR;

 				/* Perform the data write operation at desired
 				 * memory address
 				 */
 				flash[0] = (uint32_t)val;
 				flash[1] = (uint32_t)(val >> 32);

 				/**
 				 *  Release the semaphore to give the
 				 *  opportunity to CPU2 to protect its timing
 				 *  versus the next flash operation by taking
 				 *  this semaphore.
 				 *  Note that the CPU2 is polling on this
 				 *  semaphore so CPU1 shall release it as fast
 				 *  as possible.
 				 *  This is why this code is protected by a
 				 *  critical section.
 				 */
 				LL_HSEM_ReleaseLock(HSEM,
 					CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID,
 					0);
 			}
 		}

 		/* Exit critical section */
 		irq_unlock(key);

 	} while (cpu2_sem_status || cpu1_sem_status);

 	/* Wait until the BSY bit is cleared */
 	rc = flash_stm32_wait_flash_idle(dev);

 	/* Clear the PG bit */
 	regs->CR &= (~FLASH_CR_PG);

 	return rc;
 }

 static int erase_page(const struct device *dev, uint32_t page)
 {
 	uint32_t cpu1_sem_status;
 	uint32_t cpu2_sem_status = 0;
 	uint32_t key;

 	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
 	int rc;

 	/* if the control register is locked, do not fail silently */
 	if (regs->CR & FLASH_CR_LOCK) {
 		return -EIO;
 	}

 	/* Check that no Flash memory operation is ongoing */
 	rc = flash_stm32_wait_flash_idle(dev);
 	if (rc < 0) {
 		return rc;
 	}

 	/*
 	 * If an erase operation in Flash memory also concerns data in the data
 	 * or instruction cache, the user has to ensure that these data
 	 * are rewritten before they are accessed during code execution.
 	 */
 	flush_cache(regs);

 	/* Implementation of STM32 AN5289, proposed in STM32WB Cube Application
 	 * BLE_RfWithFlash
 	 * https://github.com/STMicroelectronics/STM32CubeWB/tree/master/Projects/P-NUCLEO-WB55.Nucleo/Applications/BLE/BLE_RfWithFlash
 	 */

 	do {
 		/**
 		 * When the PESD bit mechanism is used by CPU2 to protect its
 		 * timing, the PESD bit should be polled here.
 		 * If the PESD is set, the CPU1 will be stalled when reading
 		 * literals from an ISR that may occur after the flash
 		 * processing has been requested but suspended due to the PESD
 		 * bit.
 		 *
 		 * Note: This code is required only when the PESD mechanism is
 		 * used to protect the CPU2 timing.
 		 * However, keeping that code make it compatible with both
 		 * mechanisms.
 		 */
 		while (LL_FLASH_IsActiveFlag_OperationSuspended()) {
 			;
 		}

 		/* Enter critical section */
 		key = irq_lock();

 		/**
 		 *  Depending on the application implementation, in case a
 		 *  multitasking is possible with an OS, it should be checked
 		 *  here if another task in the application disallowed flash
 		 *  processing to protect some latency in critical code
 		 *  execution.
 		 *  When flash processing is ongoing, the CPU cannot access the
 		 *  flash anymore.Trying to access the flash during that time
 		 *  stalls the CPU.
 		 *  The only way for CPU1 to disallow flash processing is to
 		 *  take CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID.
 		 */
 		cpu1_sem_status = LL_HSEM_GetStatus(HSEM,
 			CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID);
 		if (cpu1_sem_status == 0) {
 			/**
 			 *  Check now if the CPU2 disallows flash processing to
 			 *  protect its timing. If the semaphore is locked, the
 			 *  CPU2 does not allow flash processing
 			 *
 			 *  Note: By default, the CPU2 uses the PESD mechanism
 			 *  to protect its timing, therefore, it is useless to
 			 *  get/release the semaphore.
 			 *
 			 *  However, keeping that code make it compatible with
 			 *  both mechanisms.
 			 *  The protection by semaphore is enabled on CPU2 side
 			 *  with the command SHCI_C2_SetFlashActivityControl()
 			 *
 			 */
 			cpu2_sem_status = LL_HSEM_1StepLock(HSEM,
 				CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID);
 			if (cpu2_sem_status == 0) {
 				/**
 				 * When CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID is
 				 * taken, it is allowed to only erase one
 				 * sector.
 				 * When several sectors need to be erased,
 				 * the application shall first exit from the
 				 * critical section and try again.
 				 */
 				regs->CR |= FLASH_CR_PER;
 				regs->CR &= ~FLASH_CR_PNB_Msk;
 				regs->CR |= page << FLASH_CR_PNB_Pos;

 				regs->CR |= FLASH_CR_STRT;

 				/**
 				 *  Release the semaphore to give the
 				 *  opportunity to CPU2 to protect its timing
 				 *  versus the next flash operation by taking
 				 *  this semaphore.
 				 *  Note that the CPU2 is polling on this
 				 *  semaphore so CPU1 shall release it as fast
 				 *  as possible.
 				 *  This is why this code is protected by a
 				 *  critical section.
 				 */
 				LL_HSEM_ReleaseLock(HSEM,
 					CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID,
 					0);
 			}
 		}

 		/* Exit critical section */
 		irq_unlock(key);

 	} while (cpu2_sem_status || cpu1_sem_status);


 	/* Wait for the BSY bit */
 	rc = flash_stm32_wait_flash_idle(dev);

 	regs->CR &= ~FLASH_CR_PER;

 	return rc;
 }

 int flash_stm32_block_erase_loop(const struct device *dev,
 				 unsigned int offset,
 				 unsigned int len)
 {
 	int i, rc = 0;

 #if defined(CONFIG_BT)
 	/**
 	 *  Notify the CPU2 that some flash erase activity may be executed
 	 *  On reception of this command, the CPU2 enables the BLE timing
 	 *  protection versus flash erase processing.
 	 *  The Erase flash activity will be executed only when the BLE RF is
 	 *  idle for at least 25ms.
 	 *  The CPU2 will prevent all flash activity (write or erase) in all
 	 *  cases when the BL RF Idle is shorter than 25ms.
 	 */
 	SHCI_C2_FLASH_EraseActivity(ERASE_ACTIVITY_ON);
 #endif /* CONFIG_BT */

 	i = get_page(offset);
 	for (; i <= get_page(offset + len - 1) ; ++i) {
 		rc = erase_page(dev, i);
 		if (rc < 0) {
 			break;
 		}
 	}

 #if defined(CONFIG_BT)
 	/**
 	 *  Notify the CPU2 there will be no request anymore to erase the flash
 	 *  On reception of this command, the CPU2 disables the BLE timing
 	 *  protection versus flash erase processing
 	 */
 	SHCI_C2_FLASH_EraseActivity(ERASE_ACTIVITY_OFF);
 #endif /* CONFIG_BT */

 	return rc;
 }

 int flash_stm32_write_range(const struct device *dev, unsigned int offset,
 			    const void *data, unsigned int len)
 {
 	int i, rc = 0;

 	for (i = 0; i < len; i += 8, offset += 8U) {
 		rc = write_dword(dev, offset,
 				UNALIGNED_GET((const uint64_t *) data + (i >> 3)));
 		if (rc < 0) {
 			return rc;
 		}
 	}

 	return rc;
 }

 void flash_stm32_page_layout(const struct device *dev,
 			     const struct flash_pages_layout **layout,
 			     size_t *layout_size)
 {
 	static struct flash_pages_layout stm32wb_flash_layout = {
 		.pages_count = 0,
 		.pages_size = 0,
 	};

 	ARG_UNUSED(dev);

 	if (stm32wb_flash_layout.pages_count == 0) {
 		stm32wb_flash_layout.pages_count = FLASH_SIZE / FLASH_PAGE_SIZE;
 		stm32wb_flash_layout.pages_size = FLASH_PAGE_SIZE;
 	}

 	*layout = &stm32wb_flash_layout;
 	*layout_size = 1;
 }

 int flash_stm32_check_status(const struct device *dev)
 {
 	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
 	uint32_t error = 0;

 	/* Save Flash errors */
 	error = (regs->SR & FLASH_FLAG_SR_ERRORS);
 	error |= (regs->ECCR & FLASH_FLAG_ECCC);

 	/* Clear systematic Option and Engineering bits validity error */
 	if (error & FLASH_FLAG_OPTVERR) {
 		regs->SR |= FLASH_FLAG_SR_ERRORS;
 		return 0;
 	}

 	if (error) {
 		return -EIO;
 	}

 	return 0;
 }
	/*
	* Copyright (c) 2019 Linaro Limited
	* Copyright (c) 2020 STMicroelectronics
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#define LOG_DOMAIN flash_stm32wb
	#define LOG_LEVEL CONFIG_FLASH_LOG_LEVEL
	#include <zephyr/logging/log.h>
	LOG_MODULE_REGISTER(LOG_DOMAIN);

	#include <zephyr/kernel.h>
	#include <zephyr/device.h>
	#include <string.h>
	#include <zephyr/drivers/flash.h>
	#include <zephyr/init.h>
	#include <soc.h>
	#include <zephyr/sys/__assert.h>

	#include "flash_stm32.h"
	#include "stm32_hsem.h"
	#if defined(CONFIG_BT)
	#include "shci.h"
	#endif

	#define STM32WBX_PAGE_SHIFT 12

	/* offset and len must be aligned on 8 for write,
	* positive and not beyond end of flash
	*/
	bool flash_stm32_valid_range(const struct device *dev, off_t offset,
	uint32_t len,
	bool write)
	{
	return (!write \|\| (offset % 8 == 0 && len % 8 == 0U)) &&
	flash_stm32_range_exists(dev, offset, len);
	}

	/*
	* Up to 255 4K pages
	*/
	static uint32_t get_page(off_t offset)
	{
	return offset >> STM32WBX_PAGE_SHIFT;
	}

	static inline void flush_cache(FLASH_TypeDef *regs)
	{
	if (regs->ACR & FLASH_ACR_DCEN) {
	regs->ACR &= ~FLASH_ACR_DCEN;
	/* Datasheet: DCRST: Data cache reset
	* This bit can be written only when the data cache is disabled
	*/
	regs->ACR \|= FLASH_ACR_DCRST;
	regs->ACR &= ~FLASH_ACR_DCRST;
	regs->ACR \|= FLASH_ACR_DCEN;
	}

	if (regs->ACR & FLASH_ACR_ICEN) {
	regs->ACR &= ~FLASH_ACR_ICEN;
	/* Datasheet: ICRST: Instruction cache reset :
	* This bit can be written only when the instruction cache
	* is disabled
	*/
	regs->ACR \|= FLASH_ACR_ICRST;
	regs->ACR &= ~FLASH_ACR_ICRST;
	regs->ACR \|= FLASH_ACR_ICEN;
	}
	}

	static int write_dword(const struct device *dev, off_t offset, uint64_t val)
	{
	volatile uint32_t flash = (uint32_t )(offset + CONFIG_FLASH_BASE_ADDRESS);
	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
	uint32_t tmp;
	int ret, rc;
	uint32_t cpu1_sem_status;
	uint32_t cpu2_sem_status = 0;
	uint32_t key;

	/* if the control register is locked, do not fail silently */
	if (regs->CR & FLASH_CR_LOCK) {
	return -EIO;
	}

	/* Check if this double word is erased */
	if (flash[0] != 0xFFFFFFFFUL \|\|
	flash[1] != 0xFFFFFFFFUL) {
	return -EIO;
	}

	ret = flash_stm32_check_status(dev);
	if (ret < 0) {
	return -EIO;
	}

	/* Implementation of STM32 AN5289, proposed in STM32WB Cube Application
	* BLE_RfWithFlash
	* https://github.com/STMicroelectronics/STM32CubeWB/tree/master/Projects/P-NUCLEO-WB55.Nucleo/Applications/BLE/BLE_RfWithFlash
	*/

	do {
	/**
	* When the PESD bit mechanism is used by CPU2 to protect its
	* timing, the PESD bit should be polled here.
	* If the PESD is set, the CPU1 will be stalled when reading
	* literals from an ISR that may occur after the flash
	* processing has been requested but suspended due to the PESD
	* bit.
	*
	* Note: This code is required only when the PESD mechanism is
	* used to protect the CPU2 timing.
	* However, keeping that code make it compatible with both
	* mechanisms.
	*/
	while (LL_FLASH_IsActiveFlag_OperationSuspended()) {
	;
	}

	/* Enter critical section */
	key = irq_lock();

	/**
	* Depending on the application implementation, in case a
	* multitasking is possible with an OS, it should be checked
	* here if another task in the application disallowed flash
	* processing to protect some latency in critical code
	* execution.
	* When flash processing is ongoing, the CPU cannot access the
	* flash anymore.Trying to access the flash during that time
	* stalls the CPU.
	* The only way for CPU1 to disallow flash processing is to
	* take CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID.
	*/
	cpu1_sem_status = LL_HSEM_GetStatus(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID);
	if (cpu1_sem_status == 0) {
	/**
	* Check now if the CPU2 disallows flash processing to
	* protect its timing. If the semaphore is locked, the
	* CPU2 does not allow flash processing
	*
	* Note: By default, the CPU2 uses the PESD mechanism
	* to protect its timing, therefore, it is useless to
	* get/release the semaphore.
	*
	* However, keeping that code make it compatible with
	* both mechanisms.
	* The protection by semaphore is enabled on CPU2 side
	* with the command SHCI_C2_SetFlashActivityControl()
	*
	*/
	cpu2_sem_status = LL_HSEM_1StepLock(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID);
	if (cpu2_sem_status == 0) {
	/**
	* When CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID is
	* taken, it is allowed to only write one
	* single 64bits data.
	* When several 64bits data need to be erased,
	* the application shall first exit from the
	* critical section and try again.
	*/
	/* Set the PG bit */
	regs->CR \|= FLASH_CR_PG;

	/* Flush the register write */
	tmp = regs->CR;

	/* Perform the data write operation at desired
	* memory address
	*/
	flash[0] = (uint32_t)val;
	flash[1] = (uint32_t)(val >> 32);

	/**
	* Release the semaphore to give the
	* opportunity to CPU2 to protect its timing
	* versus the next flash operation by taking
	* this semaphore.
	* Note that the CPU2 is polling on this
	* semaphore so CPU1 shall release it as fast
	* as possible.
	* This is why this code is protected by a
	* critical section.
	*/
	LL_HSEM_ReleaseLock(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID,
	0);
	}
	}

	/* Exit critical section */
	irq_unlock(key);

	} while (cpu2_sem_status \|\| cpu1_sem_status);

	/* Wait until the BSY bit is cleared */
	rc = flash_stm32_wait_flash_idle(dev);

	/* Clear the PG bit */
	regs->CR &= (~FLASH_CR_PG);

	return rc;
	}

	static int erase_page(const struct device *dev, uint32_t page)
	{
	uint32_t cpu1_sem_status;
	uint32_t cpu2_sem_status = 0;
	uint32_t key;

	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
	int rc;

	/* if the control register is locked, do not fail silently */
	if (regs->CR & FLASH_CR_LOCK) {
	return -EIO;
	}

	/* Check that no Flash memory operation is ongoing */
	rc = flash_stm32_wait_flash_idle(dev);
	if (rc < 0) {
	return rc;
	}

	/*
	* If an erase operation in Flash memory also concerns data in the data
	* or instruction cache, the user has to ensure that these data
	* are rewritten before they are accessed during code execution.
	*/
	flush_cache(regs);

	/* Implementation of STM32 AN5289, proposed in STM32WB Cube Application
	* BLE_RfWithFlash
	* https://github.com/STMicroelectronics/STM32CubeWB/tree/master/Projects/P-NUCLEO-WB55.Nucleo/Applications/BLE/BLE_RfWithFlash
	*/

	do {
	/**
	* When the PESD bit mechanism is used by CPU2 to protect its
	* timing, the PESD bit should be polled here.
	* If the PESD is set, the CPU1 will be stalled when reading
	* literals from an ISR that may occur after the flash
	* processing has been requested but suspended due to the PESD
	* bit.
	*
	* Note: This code is required only when the PESD mechanism is
	* used to protect the CPU2 timing.
	* However, keeping that code make it compatible with both
	* mechanisms.
	*/
	while (LL_FLASH_IsActiveFlag_OperationSuspended()) {
	;
	}

	/* Enter critical section */
	key = irq_lock();

	/**
	* Depending on the application implementation, in case a
	* multitasking is possible with an OS, it should be checked
	* here if another task in the application disallowed flash
	* processing to protect some latency in critical code
	* execution.
	* When flash processing is ongoing, the CPU cannot access the
	* flash anymore.Trying to access the flash during that time
	* stalls the CPU.
	* The only way for CPU1 to disallow flash processing is to
	* take CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID.
	*/
	cpu1_sem_status = LL_HSEM_GetStatus(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU1_SEMID);
	if (cpu1_sem_status == 0) {
	/**
	* Check now if the CPU2 disallows flash processing to
	* protect its timing. If the semaphore is locked, the
	* CPU2 does not allow flash processing
	*
	* Note: By default, the CPU2 uses the PESD mechanism
	* to protect its timing, therefore, it is useless to
	* get/release the semaphore.
	*
	* However, keeping that code make it compatible with
	* both mechanisms.
	* The protection by semaphore is enabled on CPU2 side
	* with the command SHCI_C2_SetFlashActivityControl()
	*
	*/
	cpu2_sem_status = LL_HSEM_1StepLock(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID);
	if (cpu2_sem_status == 0) {
	/**
	* When CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID is
	* taken, it is allowed to only erase one
	* sector.
	* When several sectors need to be erased,
	* the application shall first exit from the
	* critical section and try again.
	*/
	regs->CR \|= FLASH_CR_PER;
	regs->CR &= ~FLASH_CR_PNB_Msk;
	regs->CR \|= page << FLASH_CR_PNB_Pos;

	regs->CR \|= FLASH_CR_STRT;

	/**
	* Release the semaphore to give the
	* opportunity to CPU2 to protect its timing
	* versus the next flash operation by taking
	* this semaphore.
	* Note that the CPU2 is polling on this
	* semaphore so CPU1 shall release it as fast
	* as possible.
	* This is why this code is protected by a
	* critical section.
	*/
	LL_HSEM_ReleaseLock(HSEM,
	CFG_HW_BLOCK_FLASH_REQ_BY_CPU2_SEMID,
	0);
	}
	}

	/* Exit critical section */
	irq_unlock(key);

	} while (cpu2_sem_status \|\| cpu1_sem_status);


	/* Wait for the BSY bit */
	rc = flash_stm32_wait_flash_idle(dev);

	regs->CR &= ~FLASH_CR_PER;

	return rc;
	}

	int flash_stm32_block_erase_loop(const struct device *dev,
	unsigned int offset,
	unsigned int len)
	{
	int i, rc = 0;

	#if defined(CONFIG_BT)
	/**
	* Notify the CPU2 that some flash erase activity may be executed
	* On reception of this command, the CPU2 enables the BLE timing
	* protection versus flash erase processing.
	* The Erase flash activity will be executed only when the BLE RF is
	* idle for at least 25ms.
	* The CPU2 will prevent all flash activity (write or erase) in all
	* cases when the BL RF Idle is shorter than 25ms.
	*/
	SHCI_C2_FLASH_EraseActivity(ERASE_ACTIVITY_ON);
	#endif /* CONFIG_BT */

	i = get_page(offset);
	for (; i <= get_page(offset + len - 1) ; ++i) {
	rc = erase_page(dev, i);
	if (rc < 0) {
	break;
	}
	}

	#if defined(CONFIG_BT)
	/**
	* Notify the CPU2 there will be no request anymore to erase the flash
	* On reception of this command, the CPU2 disables the BLE timing
	* protection versus flash erase processing
	*/
	SHCI_C2_FLASH_EraseActivity(ERASE_ACTIVITY_OFF);
	#endif /* CONFIG_BT */

	return rc;
	}

	int flash_stm32_write_range(const struct device *dev, unsigned int offset,
	const void *data, unsigned int len)
	{
	int i, rc = 0;

	for (i = 0; i < len; i += 8, offset += 8U) {
	rc = write_dword(dev, offset,
	UNALIGNED_GET((const uint64_t *) data + (i >> 3)));
	if (rc < 0) {
	return rc;
	}
	}

	return rc;
	}

	void flash_stm32_page_layout(const struct device *dev,
	const struct flash_pages_layout **layout,
	size_t *layout_size)
	{
	static struct flash_pages_layout stm32wb_flash_layout = {
	.pages_count = 0,
	.pages_size = 0,
	};

	ARG_UNUSED(dev);

	if (stm32wb_flash_layout.pages_count == 0) {
	stm32wb_flash_layout.pages_count = FLASH_SIZE / FLASH_PAGE_SIZE;
	stm32wb_flash_layout.pages_size = FLASH_PAGE_SIZE;
	}

	*layout = &stm32wb_flash_layout;
	*layout_size = 1;
	}

	int flash_stm32_check_status(const struct device *dev)
	{
	FLASH_TypeDef *regs = FLASH_STM32_REGS(dev);
	uint32_t error = 0;

	/* Save Flash errors */
	error = (regs->SR & FLASH_FLAG_SR_ERRORS);
	error \|= (regs->ECCR & FLASH_FLAG_ECCC);

	/* Clear systematic Option and Engineering bits validity error */
	if (error & FLASH_FLAG_OPTVERR) {
	regs->SR \|= FLASH_FLAG_SR_ERRORS;
	return 0;
	}

	if (error) {
	return -EIO;
	}

	return 0;
	}