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/*
* SPDX - FileCopyrightText : 2015 - 2021 Espressif Systems ( Shanghai ) CO LTD
*
* SPDX - License - Identifier : Apache - 2.0
*/
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# include <stdlib.h>
# include <stdio.h>
# include <sys/param.h>
# include <string.h>
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# include "esp_memory_utils.h"
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# include "spi_flash_chip_driver.h"
# include "memspi_host_driver.h"
# include "esp_log.h"
# include "sdkconfig.h"
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# include "esp_flash_internal.h"
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# include "spi_flash_defs.h"
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# include "spi_flash_mmap.h"
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# include "esp_rom_caps.h"
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# include "esp_rom_spiflash.h"
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# include "esp_private/esp_clk.h"
# include "esp_spi_flash_counters.h"
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# if CONFIG_IDF_TARGET_ESP32S2
# include "esp_crypto_lock.h" // for locking flash encryption peripheral
# endif //CONFIG_IDF_TARGET_ESP32S2
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DRAM_ATTR static const char TAG [ ] = " spi_flash " ;
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# ifdef CONFIG_SPI_FLASH_WRITE_CHUNK_SIZE
# define MAX_WRITE_CHUNK CONFIG_SPI_FLASH_WRITE_CHUNK_SIZE /* write in chunks */
# else
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# define MAX_WRITE_CHUNK 8192 /* write in chunks */
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# endif // CONFIG_SPI_FLASH_WRITE_CHUNK_SIZE
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# define MAX_READ_CHUNK 16384
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# define VERIFY_BUF_LEN 64
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# ifdef CONFIG_SPI_FLASH_DANGEROUS_WRITE_ABORTS
# define UNSAFE_WRITE_ADDRESS abort()
# else
# define UNSAFE_WRITE_ADDRESS return ESP_ERR_INVALID_ARG
# endif
/* CHECK_WRITE_ADDRESS macro to fail writes which land in the
bootloader , partition table , or running application region .
*/
# if CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
# define CHECK_WRITE_ADDRESS(CHIP, ADDR, SIZE)
# else /* FAILS or ABORTS */
# define CHECK_WRITE_ADDRESS(CHIP, ADDR, SIZE) do { \
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if ( CHIP & & CHIP - > os_func - > region_protected & & CHIP - > os_func - > region_protected ( CHIP - > os_func_data , ADDR , SIZE ) ) { \
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UNSAFE_WRITE_ADDRESS ; \
} \
} while ( 0 )
# endif // CONFIG_SPI_FLASH_DANGEROUS_WRITE_ALLOWED
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/* Convenience macro for beginning of all API functions.
* Check the return value of ` rom_spiflash_api_funcs - > chip_check ` is correct ,
* and the chip supports the operation in question .
*/
# define VERIFY_CHIP_OP(op) do { \
if ( err ! = ESP_OK ) return err ; \
if ( chip - > chip_drv - > op = = NULL ) { \
return ESP_ERR_FLASH_UNSUPPORTED_CHIP ; \
} \
} while ( 0 )
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# if CONFIG_SPI_FLASH_ENABLE_COUNTERS
static esp_flash_counters_t esp_flash_stats ;
# define COUNTER_START() uint32_t ts_begin = esp_cpu_get_cycle_count()
# define COUNTER_STOP(counter) \
do { \
esp_flash_stats . counter . count + + ; \
esp_flash_stats . counter . time + = ( esp_cpu_get_cycle_count ( ) - ts_begin ) / ( esp_clk_cpu_freq ( ) / 1000000 ) ; \
} while ( 0 )
# define COUNTER_ADD_BYTES(counter, size) \
do { \
esp_flash_stats . counter . bytes + = size ; \
} while ( 0 )
const esp_flash_counters_t * esp_flash_get_counters ( void )
{
return & esp_flash_stats ;
}
void esp_flash_reset_counters ( void )
{
memset ( & esp_flash_stats , 0 , sizeof ( esp_flash_stats ) ) ;
}
void esp_flash_dump_counters ( FILE * stream )
{
if ( stream ! = NULL ) {
fprintf ( stream , " read: count=%8ld time=%8ldus bytes=%8ld \n " , esp_flash_stats . read . count , esp_flash_stats . read . time , esp_flash_stats . read . bytes ) ;
fprintf ( stream , " write: count=%8ld time=%8ldus bytes=%8ld \n " , esp_flash_stats . write . count , esp_flash_stats . write . time , esp_flash_stats . write . bytes ) ;
fprintf ( stream , " erase: count=%8ld time=%8ldus bytes=%8ld \n " , esp_flash_stats . erase . count , esp_flash_stats . erase . time , esp_flash_stats . erase . bytes ) ;
}
}
const spi_flash_counters_t * spi_flash_get_counters ( void )
{
return ( spi_flash_counters_t * ) esp_flash_get_counters ( ) ;
}
void spi_flash_reset_counters ( void )
{
esp_flash_reset_counters ( ) ;
}
void spi_flash_dump_counters ( void )
{
esp_flash_dump_counters ( stdout ) ;
}
# else
# define COUNTER_START()
# define COUNTER_STOP(counter)
# define COUNTER_ADD_BYTES(counter, size)
# endif //CONFIG_SPI_FLASH_ENABLE_COUNTERS
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# define IO_STR_LEN 10
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static const char io_mode_str [ ] [ IO_STR_LEN ] = {
" slowrd " ,
" fastrd " ,
" dout " ,
" dio " ,
" qout " ,
" qio " ,
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[ 6 . . . 15 ] = " not used " , // reserved io mode for future, not used currently.
" opi_str " ,
" opi_dtr " ,
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} ;
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_Static_assert ( sizeof ( io_mode_str ) / IO_STR_LEN = = SPI_FLASH_READ_MODE_MAX , " the io_mode_str should be consistent with the esp_flash_io_mode_t defined in spi_flash_types.h " ) ;
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esp_err_t esp_flash_read_chip_id ( esp_flash_t * chip , uint32_t * flash_id ) ;
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# ifndef CONFIG_SPI_FLASH_ROM_IMPL
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static esp_err_t spiflash_start_default ( esp_flash_t * chip ) ;
static esp_err_t spiflash_end_default ( esp_flash_t * chip , esp_err_t err ) ;
static esp_err_t check_chip_pointer_default ( esp_flash_t * * inout_chip ) ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
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static esp_err_t flash_end_flush_cache ( esp_flash_t * chip , esp_err_t err , bool bus_acquired , uint32_t address , uint32_t length ) ;
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# endif //CONFIG_SPI_FLASH_ROM_IMPL
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typedef struct {
esp_err_t ( * start ) ( esp_flash_t * chip ) ;
esp_err_t ( * end ) ( esp_flash_t * chip , esp_err_t err ) ;
esp_err_t ( * chip_check ) ( esp_flash_t * * inout_chip ) ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
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esp_err_t ( * flash_end_flush_cache ) ( esp_flash_t * chip , esp_err_t err , bool bus_acquired , uint32_t address , uint32_t length ) ;
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} rom_spiflash_api_func_t ;
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# ifndef CONFIG_SPI_FLASH_ROM_IMPL
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// These functions can be placed in the ROM. For now we use the code in IDF.
DRAM_ATTR static rom_spiflash_api_func_t default_spiflash_rom_api = {
. start = spiflash_start_default ,
. end = spiflash_end_default ,
. chip_check = check_chip_pointer_default ,
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
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. flash_end_flush_cache = flash_end_flush_cache ,
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} ;
DRAM_ATTR rom_spiflash_api_func_t * rom_spiflash_api_funcs = & default_spiflash_rom_api ;
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# else
extern rom_spiflash_api_func_t * esp_flash_api_funcs ;
# define rom_spiflash_api_funcs esp_flash_api_funcs
# endif // CONFIG_SPI_FLASH_ROM_IMPL
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/* Static function to notify OS of a new SPI flash operation.
If returns an error result , caller must abort . If returns ESP_OK , caller must
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call rom_spiflash_api_funcs - > end ( ) before returning .
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*/
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# ifndef CONFIG_SPI_FLASH_ROM_IMPL
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static esp_err_t IRAM_ATTR spiflash_start_default ( esp_flash_t * chip )
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{
if ( chip - > os_func ! = NULL & & chip - > os_func - > start ! = NULL ) {
esp_err_t err = chip - > os_func - > start ( chip - > os_func_data ) ;
if ( err ! = ESP_OK ) {
return err ;
}
}
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chip - > host - > driver - > dev_config ( chip - > host ) ;
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return ESP_OK ;
}
/* Static function to notify OS that SPI flash operation is complete.
*/
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static esp_err_t IRAM_ATTR spiflash_end_default ( esp_flash_t * chip , esp_err_t err )
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{
if ( chip - > os_func ! = NULL
& & chip - > os_func - > end ! = NULL ) {
esp_err_t end_err = chip - > os_func - > end ( chip - > os_func_data ) ;
if ( err = = ESP_OK ) {
err = end_err ; // Only return the 'end' error if we haven't already failed
}
}
return err ;
}
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// check that the 'chip' parameter is properly initialised
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static IRAM_ATTR esp_err_t check_chip_pointer_default ( esp_flash_t * * inout_chip )
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{
esp_flash_t * chip = * inout_chip ;
if ( chip = = NULL ) {
chip = esp_flash_default_chip ;
}
* inout_chip = chip ;
if ( chip = = NULL | | ! esp_flash_chip_driver_initialized ( chip ) ) {
return ESP_ERR_FLASH_NOT_INITIALISED ;
}
return ESP_OK ;
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
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static IRAM_ATTR esp_err_t flash_end_flush_cache ( esp_flash_t * chip , esp_err_t err , bool bus_acquired , uint32_t address , uint32_t length )
{
if ( ! bus_acquired ) {
// Try to acquire the bus again to flush the cache before exit.
esp_err_t acquire_err = rom_spiflash_api_funcs - > start ( chip ) ;
if ( acquire_err ! = ESP_OK ) {
return ( err = = ESP_OK ) ? acquire_err : err ;
}
}
if ( chip - > host - > driver - > flush_cache ) {
esp_err_t flush_err = chip - > host - > driver - > flush_cache ( chip - > host , address , length ) ;
if ( err = = ESP_OK ) {
err = flush_err ;
}
}
return rom_spiflash_api_funcs - > end ( chip , err ) ;
}
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# endif //CONFIG_SPI_FLASH_ROM_IMPL
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/* Top-level API functions, calling into chip_drv functions via chip->drv */
static esp_err_t detect_spi_flash_chip ( esp_flash_t * chip ) ;
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bool IRAM_ATTR esp_flash_chip_driver_initialized ( const esp_flash_t * chip )
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{
if ( ! chip - > chip_drv ) return false ;
return true ;
}
esp_err_t IRAM_ATTR esp_flash_init ( esp_flash_t * chip )
{
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// Chip init flow
// 1. Read chip id
// 2. (optional) Detect chip vendor
// 3. Get basic parameters of the chip (size, dummy count, etc.)
// 4. Init chip into desired mode (without breaking the cache!)
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esp_err_t err = ESP_OK ;
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if ( chip = = NULL | | chip - > host = = NULL | | chip - > host - > driver = = NULL | |
( ( memspi_host_inst_t * ) chip - > host ) - > spi = = NULL ) {
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return ESP_ERR_INVALID_ARG ;
}
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//read chip id
uint32_t flash_id ;
int retries = 10 ;
do {
err = esp_flash_read_chip_id ( chip , & flash_id ) ;
} while ( err = = ESP_ERR_FLASH_NOT_INITIALISED & & retries - - > 0 ) ;
if ( err ! = ESP_OK ) {
return err ;
}
chip - > chip_id = flash_id ;
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if ( ! esp_flash_chip_driver_initialized ( chip ) ) {
// Detect chip_drv
err = detect_spi_flash_chip ( chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
}
// Detect flash size
uint32_t size ;
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err = esp_flash_get_physical_size ( chip , & size ) ;
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if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " failed to get chip size " ) ;
return err ;
}
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if ( chip - > chip_drv - > get_chip_caps = = NULL ) {
// chip caps get failed, pass the flash capability check.
ESP_EARLY_LOGW ( TAG , " get_chip_caps function pointer hasn't been initialized " ) ;
} else {
if ( ( ( chip - > chip_drv - > get_chip_caps ( chip ) & SPI_FLASH_CHIP_CAP_32MB_SUPPORT ) = = 0 ) & & ( size > ( 16 * 1024 * 1024 ) ) ) {
ESP_EARLY_LOGW ( TAG , " Detected flash size > 16 MB, but access beyond 16 MB is not supported for this flash model yet. " ) ;
size = ( 16 * 1024 * 1024 ) ;
}
}
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ESP_LOGI ( TAG , " flash io: %s " , io_mode_str [ chip - > read_mode ] ) ;
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
if ( err = = ESP_OK ) {
// Try to set the flash mode to whatever default mode was chosen
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err = chip - > chip_drv - > set_io_mode ( chip ) ;
if ( err = = ESP_ERR_FLASH_NO_RESPONSE & & ! esp_flash_is_quad_mode ( chip ) ) {
//some chips (e.g. Winbond) don't support to clear QE, treat as success
err = ESP_OK ;
}
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}
// Done: all fields on 'chip' are initialised
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return rom_spiflash_api_funcs - > end ( chip , err ) ;
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}
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// Note: This function is only used for internal. Only call this function to initialize the main flash.
// (flash chip on SPI1 CS0)
esp_err_t IRAM_ATTR esp_flash_init_main ( esp_flash_t * chip )
{
// Chip init flow
// 1. Read chip id
// 2. (optional) Detect chip vendor
// 3. Get basic parameters of the chip (size, dummy count, etc.)
// 4. Init chip into desired mode (without breaking the cache!)
esp_err_t err = ESP_OK ;
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bool octal_mode ;
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if ( chip = = NULL | | chip - > host = = NULL | | chip - > host - > driver = = NULL | |
( ( memspi_host_inst_t * ) chip - > host ) - > spi = = NULL ) {
return ESP_ERR_INVALID_ARG ;
}
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octal_mode = ( chip - > read_mode > = SPI_FLASH_OPI_FLAG ) ;
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//read chip id
// This can indicate the MSPI support OPI, if the flash works on MSPI in OPI mode, we directly bypass read id.
uint32_t flash_id = 0 ;
if ( octal_mode ) {
// bypass the reading but get the flash_id from the ROM variable, to avoid resetting the chip to QSPI mode and read the ID again
flash_id = g_rom_flashchip . device_id ;
} else {
int retries = 10 ;
do {
err = esp_flash_read_chip_id ( chip , & flash_id ) ;
} while ( err = = ESP_ERR_FLASH_NOT_INITIALISED & & retries - - > 0 ) ;
}
if ( err ! = ESP_OK ) {
return err ;
}
chip - > chip_id = flash_id ;
if ( ! esp_flash_chip_driver_initialized ( chip ) ) {
// Detect chip_drv
err = detect_spi_flash_chip ( chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
}
// Detect flash size
uint32_t size ;
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err = esp_flash_get_physical_size ( chip , & size ) ;
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if ( err ! = ESP_OK ) {
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ESP_EARLY_LOGE ( TAG , " failed to get chip size " ) ;
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return err ;
}
if ( chip - > chip_drv - > get_chip_caps = = NULL ) {
// chip caps get failed, pass the flash capability check.
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ESP_EARLY_LOGW ( TAG , " get_chip_caps function pointer hasn't been initialized " ) ;
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} else {
if ( ( ( chip - > chip_drv - > get_chip_caps ( chip ) & SPI_FLASH_CHIP_CAP_32MB_SUPPORT ) = = 0 ) & & ( size > ( 16 * 1024 * 1024 ) ) ) {
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ESP_EARLY_LOGW ( TAG , " Detected flash size > 16 MB, but access beyond 16 MB is not supported for this flash model yet. " ) ;
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size = ( 16 * 1024 * 1024 ) ;
}
}
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ESP_EARLY_LOGI ( TAG , " flash io: %s " , io_mode_str [ chip - > read_mode ] ) ;
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err = rom_spiflash_api_funcs - > start ( chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
if ( err = = ESP_OK & & ! octal_mode ) {
// Try to set the flash mode to whatever default mode was chosen
err = chip - > chip_drv - > set_io_mode ( chip ) ;
if ( err = = ESP_ERR_FLASH_NO_RESPONSE & & ! esp_flash_is_quad_mode ( chip ) ) {
//some chips (e.g. Winbond) don't support to clear QE, treat as success
err = ESP_OK ;
}
}
// Done: all fields on 'chip' are initialised
return rom_spiflash_api_funcs - > end ( chip , err ) ;
}
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static esp_err_t IRAM_ATTR read_id_core ( esp_flash_t * chip , uint32_t * out_id , bool sanity_check )
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{
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bool installed = esp_flash_chip_driver_initialized ( chip ) ;
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esp_err_t err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
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esp_err_t ( * read_id_func ) ( void * , uint32_t * ) ;
void * read_id_arg ;
if ( installed & & chip - > chip_drv - > read_id ) {
read_id_func = ( void * ) chip - > chip_drv - > read_id ;
read_id_arg = ( void * ) chip ;
} else {
//default option if the chip is not detected/chosen yet.
read_id_func = ( void * ) chip - > host - > driver - > read_id ;
read_id_arg = ( void * ) chip - > host ;
}
// Inner function fails if it sees all-ones or all-zeroes.
err = read_id_func ( read_id_arg , out_id ) ;
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if ( sanity_check & & err = = ESP_OK ) {
// Send RDID command twice, check for a matching result and retry in case we just powered on
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uint32_t new_id ;
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err = read_id_func ( read_id_arg , & new_id ) ;
if ( err = = ESP_OK & & ( new_id ! = * out_id ) ) {
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err = ESP_ERR_FLASH_NOT_INITIALISED ;
}
}
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return rom_spiflash_api_funcs - > end ( chip , err ) ;
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}
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// Faster version with sanity check.
// Called in esp_flash_init and unit test (though not public)
esp_err_t esp_flash_read_chip_id ( esp_flash_t * chip , uint32_t * out_id )
{
return read_id_core ( chip , out_id , true ) ;
}
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# ifndef CONFIG_SPI_FLASH_ROM_IMPL
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esp_err_t esp_flash_read_id ( esp_flash_t * chip , uint32_t * out_id )
{
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
//Accept uninitialized chip when reading chip id
if ( err ! = ESP_OK & & ! ( err = = ESP_ERR_FLASH_NOT_INITIALISED & & chip ! = NULL ) ) return err ;
if ( out_id = = NULL ) return ESP_ERR_INVALID_ARG ;
return read_id_core ( chip , out_id , false ) ;
}
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# endif //CONFIG_SPI_FLASH_ROM_IMPL
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static esp_err_t IRAM_ATTR NOINLINE_ATTR read_unique_id ( esp_flash_t * chip , uint64_t * out_uid )
{
esp_err_t err = rom_spiflash_api_funcs - > start ( chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
err = chip - > chip_drv - > read_unique_id ( chip , out_uid ) ;
return rom_spiflash_api_funcs - > end ( chip , err ) ;
}
esp_err_t esp_flash_read_unique_chip_id ( esp_flash_t * chip , uint64_t * out_uid )
{
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
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if ( chip - > chip_drv - > get_chip_caps = = NULL ) {
// chip caps get failed, pass the flash capability check.
ESP_EARLY_LOGW ( TAG , " get_chip_caps function pointer hasn't been initialized " ) ;
} else {
if ( ( chip - > chip_drv - > get_chip_caps ( chip ) & SPI_FLASH_CHIP_CAP_UNIQUE_ID ) = = 0 ) {
ESP_EARLY_LOGE ( TAG , " chip %s doesn't support reading unique id " , chip - > chip_drv - > name ) ;
return ESP_ERR_NOT_SUPPORTED ;
}
}
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if ( out_uid = = NULL ) {
return ESP_ERR_INVALID_ARG ;
} ;
return read_unique_id ( chip , out_uid ) ;
}
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static esp_err_t IRAM_ATTR detect_spi_flash_chip ( esp_flash_t * chip )
{
esp_err_t err ;
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uint32_t flash_id = chip - > chip_id ;
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// Detect the chip and set the chip_drv structure for it
const spi_flash_chip_t * * drivers = esp_flash_registered_chips ;
while ( * drivers ! = NULL & & ! esp_flash_chip_driver_initialized ( chip ) ) {
chip - > chip_drv = * drivers ;
// start/end SPI operation each time, for multitasking
// and also so esp_flash_registered_flash_drivers can live in flash
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ESP_EARLY_LOGD ( TAG , " trying chip: %s " , chip - > chip_drv - > name ) ;
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
if ( chip - > chip_drv - > probe ( chip , flash_id ) ! = ESP_OK ) {
chip - > chip_drv = NULL ;
}
// if probe succeeded, chip->drv stays set
drivers + + ;
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err = rom_spiflash_api_funcs - > end ( chip , err ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
}
if ( ! esp_flash_chip_driver_initialized ( chip ) ) {
return ESP_ERR_NOT_FOUND ;
}
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ESP_EARLY_LOGI ( TAG , " detected chip: %s " , chip - > chip_drv - > name ) ;
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return ESP_OK ;
}
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esp_err_t IRAM_ATTR esp_flash_get_physical_size ( esp_flash_t * chip , uint32_t * flash_size )
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{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
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VERIFY_CHIP_OP ( detect_size ) ;
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if ( flash_size = = NULL ) {
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return ESP_ERR_INVALID_ARG ;
}
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
uint32_t detect_size ;
err = chip - > chip_drv - > detect_size ( chip , & detect_size ) ;
if ( err = = ESP_OK ) {
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if ( chip - > size = = 0 ) {
// chip->size will not be changed if detected, it will always be equal to configured flash size.
chip - > size = detect_size ;
}
* flash_size = detect_size ;
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}
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return rom_spiflash_api_funcs - > end ( chip , err ) ;
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}
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# ifndef CONFIG_SPI_FLASH_ROM_IMPL
/* Return true if regions 'a' and 'b' overlap at all, based on their start offsets and lengths. */
inline static bool regions_overlap ( uint32_t a_start , uint32_t a_len , uint32_t b_start , uint32_t b_len ) ;
esp_err_t IRAM_ATTR esp_flash_get_size ( esp_flash_t * chip , uint32_t * out_size )
{
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
if ( err ! = ESP_OK ) {
return err ;
}
if ( out_size = = NULL ) {
return ESP_ERR_INVALID_ARG ;
}
if ( chip - > size ! = 0 ) {
* out_size = chip - > size ;
return ESP_OK ;
}
//Return flash chip physical size, when this API is called before flash initialisation,
//After initialization will return available size.
return esp_flash_get_physical_size ( chip , out_size ) ;
}
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esp_err_t IRAM_ATTR esp_flash_erase_chip ( esp_flash_t * chip )
{
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esp_err_t err = ESP_OK ;
uint32_t size = 0 ;
err = esp_flash_get_size ( chip , & size ) ;
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if ( err ! = ESP_OK ) {
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ESP_LOGE ( TAG , " esp_flash_get_size failed, flash error code: %d " , err ) ;
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return err ;
}
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err = esp_flash_erase_region ( chip , 0 , size ) ;
return err ;
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}
esp_err_t IRAM_ATTR esp_flash_erase_region ( esp_flash_t * chip , uint32_t start , uint32_t len )
{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( erase_sector ) ;
VERIFY_CHIP_OP ( erase_block ) ;
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CHECK_WRITE_ADDRESS ( chip , start , len ) ;
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2019-01-08 05:29:25 -05:00
uint32_t block_erase_size = chip - > chip_drv - > erase_block = = NULL ? 0 : chip - > chip_drv - > block_erase_size ;
uint32_t sector_size = chip - > chip_drv - > sector_size ;
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COUNTER_START ( ) ;
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if ( sector_size = = 0 | | ( block_erase_size % sector_size ) ! = 0 ) {
return ESP_ERR_FLASH_NOT_INITIALISED ;
}
if ( start > chip - > size | | start + len > chip - > size ) {
return ESP_ERR_INVALID_ARG ;
}
if ( ( start % chip - > chip_drv - > sector_size ) ! = 0 | | ( len % chip - > chip_drv - > sector_size ) ! = 0 ) {
// Can only erase multiples of the sector size, starting at sector boundary
return ESP_ERR_INVALID_ARG ;
}
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if ( len = = 0 ) {
return ESP_OK ;
}
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err = ESP_OK ;
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// Check for write protected regions overlapping the erase region
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if ( chip - > chip_drv - > get_protected_regions ! = NULL & &
chip - > chip_drv - > num_protectable_regions > 0 ) {
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
2019-01-08 05:29:25 -05:00
uint64_t protected = 0 ;
err = chip - > chip_drv - > get_protected_regions ( chip , & protected ) ;
if ( err = = ESP_OK & & protected ! = 0 ) {
for ( int i = 0 ; i < chip - > chip_drv - > num_protectable_regions & & err = = ESP_OK ; i + + ) {
const esp_flash_region_t * region = & chip - > chip_drv - > protectable_regions [ i ] ;
if ( ( protected & BIT64 ( i ) )
& & regions_overlap ( start , len , region - > offset , region - > size ) ) {
err = ESP_ERR_FLASH_PROTECTED ;
}
}
}
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// Don't lock the SPI flash for the entire erase, as this may be very long
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err = rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
if ( err ! = ESP_OK ) {
return err ;
}
uint32_t erase_addr = start ;
uint32_t len_remain = len ;
// Indicate whether the bus is acquired by the driver, needs to be released before return
bool bus_acquired = false ;
while ( 1 ) {
//check before the operation, in case this is called too close to the last operation
2020-12-15 22:50:13 -05:00
if ( chip - > chip_drv - > yield ) {
err = chip - > chip_drv - > yield ( chip , 0 ) ;
if ( err ! = ESP_OK ) {
return err ;
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
}
2019-01-08 05:29:25 -05:00
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
break ;
2019-01-08 05:29:25 -05:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
bus_acquired = true ;
2019-01-08 05:29:25 -05:00
2020-04-23 14:13:17 -04:00
# ifndef CONFIG_SPI_FLASH_BYPASS_BLOCK_ERASE
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// If possible erase an entire multi-sector block
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
if ( block_erase_size > 0 & & len_remain > = block_erase_size & & ( erase_addr % block_erase_size ) = = 0 ) {
err = chip - > chip_drv - > erase_block ( chip , erase_addr ) ;
erase_addr + = block_erase_size ;
len_remain - = block_erase_size ;
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COUNTER_ADD_BYTES ( erase , block_erase_size ) ;
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} else
# endif
{
2019-01-08 05:29:25 -05:00
// Otherwise erase individual sector only
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
err = chip - > chip_drv - > erase_sector ( chip , erase_addr ) ;
erase_addr + = sector_size ;
len_remain - = sector_size ;
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COUNTER_ADD_BYTES ( erase , sector_size ) ;
2019-01-08 05:29:25 -05:00
}
2021-07-23 05:35:27 -04:00
assert ( len_remain < len ) ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
if ( err ! = ESP_OK | | len_remain = = 0 ) {
// On ESP32, the cache re-enable is in the end() function, while flush_cache should
// happen when the cache is still disabled on ESP32. Break before the end() function and
// do end() later
assert ( bus_acquired ) ;
break ;
}
2020-04-02 05:29:21 -04:00
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
err = rom_spiflash_api_funcs - > end ( chip , ESP_OK ) ;
if ( err ! = ESP_OK ) {
break ;
2020-04-02 05:29:21 -04:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
bus_acquired = false ;
2019-01-08 05:29:25 -05:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
2022-08-23 00:31:53 -04:00
COUNTER_STOP ( erase ) ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
return rom_spiflash_api_funcs - > flash_end_flush_cache ( chip , err , bus_acquired , start , len ) ;
2019-01-08 05:29:25 -05:00
}
2021-07-24 07:28:25 -04:00
# endif // !CONFIG_SPI_FLASH_ROM_IMPL
# if defined(CONFIG_SPI_FLASH_ROM_IMPL) && ESP_ROM_HAS_ERASE_0_REGION_BUG
/* ROM esp_flash_erase_region implementation doesn't handle 0 erase size correctly.
* Check the size and call ROM function instead of overriding it completely .
* The behavior is slightly different from esp_flash_erase_region above , thought :
* here the check for 0 size is done first , but in esp_flash_erase_region the check is
* done after the other arguments are checked .
*/
extern esp_err_t rom_esp_flash_erase_region ( esp_flash_t * chip , uint32_t start , uint32_t len ) ;
esp_err_t IRAM_ATTR esp_flash_erase_region ( esp_flash_t * chip , uint32_t start , uint32_t len )
{
if ( len = = 0 ) {
return ESP_OK ;
}
return rom_esp_flash_erase_region ( chip , start , len ) ;
}
# endif // defined(CONFIG_SPI_FLASH_ROM_IMPL) && ESP_ROM_HAS_ERASE_0_REGION_BUG
# ifndef CONFIG_SPI_FLASH_ROM_IMPL
2019-08-02 01:04:48 -04:00
esp_err_t IRAM_ATTR esp_flash_get_chip_write_protect ( esp_flash_t * chip , bool * out_write_protected )
2019-01-08 05:29:25 -05:00
{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( get_chip_write_protect ) ;
2019-08-02 01:04:48 -04:00
if ( out_write_protected = = NULL ) {
2019-01-08 05:29:25 -05:00
return ESP_ERR_INVALID_ARG ;
}
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err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
2019-08-02 01:04:48 -04:00
err = chip - > chip_drv - > get_chip_write_protect ( chip , out_write_protected ) ;
2019-01-08 05:29:25 -05:00
2020-04-29 22:37:35 -04:00
return rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
}
2019-06-19 08:35:55 -04:00
esp_err_t IRAM_ATTR esp_flash_set_chip_write_protect ( esp_flash_t * chip , bool write_protect )
2019-01-08 05:29:25 -05:00
{
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( set_chip_write_protect ) ;
2019-01-08 05:29:25 -05:00
//TODO: skip writing if already locked or unlocked
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
2019-06-19 08:35:55 -04:00
err = chip - > chip_drv - > set_chip_write_protect ( chip , write_protect ) ;
2019-01-08 05:29:25 -05:00
2020-04-29 22:37:35 -04:00
return rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
}
2019-06-19 08:35:55 -04:00
esp_err_t esp_flash_get_protectable_regions ( const esp_flash_t * chip , const esp_flash_region_t * * out_regions , uint32_t * out_num_regions )
2019-01-08 05:29:25 -05:00
{
2019-06-19 08:35:55 -04:00
if ( out_num_regions ! = NULL ) {
* out_num_regions = 0 ; // In case caller doesn't check result
2019-01-08 05:29:25 -05:00
}
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( ( esp_flash_t * * ) & chip ) ;
VERIFY_CHIP_OP ( get_protected_regions ) ;
2019-01-08 05:29:25 -05:00
2019-06-19 08:35:55 -04:00
if ( out_regions = = NULL | | out_num_regions = = NULL ) {
2019-01-08 05:29:25 -05:00
return ESP_ERR_INVALID_ARG ;
}
2019-06-19 08:35:55 -04:00
* out_num_regions = chip - > chip_drv - > num_protectable_regions ;
* out_regions = chip - > chip_drv - > protectable_regions ;
2019-01-08 05:29:25 -05:00
return ESP_OK ;
}
static esp_err_t find_region ( const esp_flash_t * chip , const esp_flash_region_t * region , uint8_t * index )
{
if ( region = = NULL ) {
return ESP_ERR_INVALID_ARG ;
}
for ( * index = 0 ; * index < chip - > chip_drv - > num_protectable_regions ; ( * index ) + + ) {
if ( memcmp ( & chip - > chip_drv - > protectable_regions [ * index ] ,
region , sizeof ( esp_flash_region_t ) ) = = 0 ) {
return ESP_OK ;
}
}
return ESP_ERR_NOT_FOUND ;
}
2019-06-19 04:37:11 -04:00
esp_err_t IRAM_ATTR esp_flash_get_protected_region ( esp_flash_t * chip , const esp_flash_region_t * region , bool * out_protected )
2019-01-08 05:29:25 -05:00
{
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( get_protected_regions ) ;
2019-01-08 05:29:25 -05:00
2019-06-19 04:37:11 -04:00
if ( out_protected = = NULL ) {
2019-01-08 05:29:25 -05:00
return ESP_ERR_INVALID_ARG ;
}
uint8_t index ;
2020-04-29 22:37:35 -04:00
err = find_region ( chip , region , & index ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
uint64_t protection_mask = 0 ;
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
err = chip - > chip_drv - > get_protected_regions ( chip , & protection_mask ) ;
if ( err = = ESP_OK ) {
2019-06-19 04:37:11 -04:00
* out_protected = protection_mask & ( 1LL < < index ) ;
2019-01-08 05:29:25 -05:00
}
2020-04-29 22:37:35 -04:00
return rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
}
2019-06-19 04:37:11 -04:00
esp_err_t IRAM_ATTR esp_flash_set_protected_region ( esp_flash_t * chip , const esp_flash_region_t * region , bool protect )
2019-01-08 05:29:25 -05:00
{
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( set_protected_regions ) ;
2019-01-08 05:29:25 -05:00
uint8_t index ;
2020-04-29 22:37:35 -04:00
err = find_region ( chip , region , & index ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
uint64_t protection_mask = 0 ;
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
return err ;
}
err = chip - > chip_drv - > get_protected_regions ( chip , & protection_mask ) ;
if ( err = = ESP_OK ) {
2019-06-19 04:37:11 -04:00
if ( protect ) {
2019-01-08 05:29:25 -05:00
protection_mask | = ( 1LL < < index ) ;
} else {
protection_mask & = ~ ( 1LL < < index ) ;
}
err = chip - > chip_drv - > set_protected_regions ( chip , protection_mask ) ;
}
2020-04-29 22:37:35 -04:00
return rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
}
esp_err_t IRAM_ATTR esp_flash_read ( esp_flash_t * chip , void * buffer , uint32_t address , uint32_t length )
{
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( read ) ;
2019-01-08 05:29:25 -05:00
if ( buffer = = NULL | | address > chip - > size | | address + length > chip - > size ) {
return ESP_ERR_INVALID_ARG ;
}
2021-07-23 05:35:27 -04:00
if ( length = = 0 ) {
return ESP_OK ;
}
2019-01-08 05:29:25 -05:00
//when the cache is disabled, only the DRAM can be read, check whether we need to receive in another buffer in DRAM.
2022-04-01 04:53:40 -04:00
bool direct_read = false ;
//If the buffer is internal already, it's ok to use it directly
direct_read | = esp_ptr_in_dram ( buffer ) ;
//If not, we need to check if the HW support direct write
direct_read | = chip - > host - > driver - > supports_direct_read ( chip - > host , buffer ) ;
2019-01-08 05:29:25 -05:00
uint8_t * temp_buffer = NULL ;
2020-02-26 19:57:00 -05:00
//each time, we at most read this length
//after that, we release the lock to allow some other operations
size_t read_chunk_size = MIN ( MAX_READ_CHUNK , length ) ;
2019-01-08 05:29:25 -05:00
if ( ! direct_read ) {
2020-04-29 22:37:35 -04:00
size_t actual_len = 0 ;
2020-07-29 05:39:56 -04:00
if ( chip - > os_func - > get_temp_buffer ! = NULL ) {
temp_buffer = chip - > os_func - > get_temp_buffer ( chip - > os_func_data , read_chunk_size , & actual_len ) ;
read_chunk_size = actual_len ;
}
2020-02-24 22:56:13 -05:00
if ( temp_buffer = = NULL ) {
return ESP_ERR_NO_MEM ;
}
2019-01-08 05:29:25 -05:00
}
2022-08-23 00:31:53 -04:00
COUNTER_START ( ) ;
2020-04-29 22:37:35 -04:00
err = ESP_OK ;
2019-01-08 05:29:25 -05:00
do {
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
break ;
}
//if required (dma buffer allocated), read to the buffer instead of the original buffer
uint8_t * buffer_to_read = ( temp_buffer ) ? temp_buffer : buffer ;
2020-02-26 19:57:00 -05:00
// Length we will read this iteration is either the chunk size or the remaining length, whichever is smaller
size_t length_to_read = MIN ( read_chunk_size , length ) ;
2019-01-08 05:29:25 -05:00
if ( err = = ESP_OK ) {
err = chip - > chip_drv - > read ( chip , buffer_to_read , address , length_to_read ) ;
}
if ( err ! = ESP_OK ) {
2020-04-29 22:37:35 -04:00
rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
break ;
}
//even if this is failed, the data is still valid, copy before quit
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > end ( chip , err ) ;
2019-01-08 05:29:25 -05:00
//copy back to the original buffer
if ( temp_buffer ) {
memcpy ( buffer , temp_buffer , length_to_read ) ;
}
address + = length_to_read ;
length - = length_to_read ;
2020-04-29 22:37:35 -04:00
buffer = ( void * ) ( ( intptr_t ) buffer + length_to_read ) ;
2022-08-23 00:31:53 -04:00
COUNTER_ADD_BYTES ( read , length_to_read ) ;
2019-01-08 05:29:25 -05:00
} while ( err = = ESP_OK & & length > 0 ) ;
2020-07-29 05:39:56 -04:00
if ( chip - > os_func - > release_temp_buffer ! = NULL ) {
chip - > os_func - > release_temp_buffer ( chip - > os_func_data , temp_buffer ) ;
}
2022-08-23 00:31:53 -04:00
COUNTER_STOP ( read ) ;
2019-01-08 05:29:25 -05:00
return err ;
}
2023-03-02 03:10:02 -05:00
# if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
static esp_err_t IRAM_ATTR s_check_setting_zero_to_one ( esp_flash_t * chip , uint32_t verify_address , uint32_t remain_verify_len , const uint32_t * to_write_buf , bool is_encrypted )
{
esp_err_t err = ESP_FAIL ;
uint8_t verify_buffer [ VERIFY_BUF_LEN ] ;
uint32_t * val_in_flash = ( uint32_t * ) verify_buffer ;
while ( remain_verify_len ) {
uint32_t this_len = MIN ( remain_verify_len , VERIFY_BUF_LEN ) ;
err = chip - > chip_drv - > read ( chip , verify_buffer , verify_address , this_len ) ;
if ( err ! = ESP_OK ) {
ESP_DRAM_LOGE ( TAG , " failed to read flash to verify if setting zero to one, err: 0x%x " , err ) ;
return err ;
}
for ( int r = 0 ; r < this_len / sizeof ( uint32_t ) ; r + + ) {
if ( is_encrypted ) {
( void ) to_write_buf ;
if ( val_in_flash [ r ] ! = 0xFFFFFFFF ) {
ESP_DRAM_LOGW ( TAG , " Write at offset 0x%x but not erased (0x%08x) " ,
verify_address + r , val_in_flash [ r ] ) ;
}
} else {
if ( ( val_in_flash [ r ] & to_write_buf [ r ] ) ! = to_write_buf [ r ] ) {
ESP_DRAM_LOGW ( TAG , " Write at offset 0x%x requests 0x%08x but will write 0x%08x -> 0x%08x " ,
verify_address + r , to_write_buf [ r ] , val_in_flash [ r ] , ( val_in_flash [ r ] & to_write_buf [ r ] ) ) ;
}
}
}
remain_verify_len - = this_len ;
verify_address + = this_len ;
}
return ESP_OK ;
}
# endif //#if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
# if CONFIG_SPI_FLASH_VERIFY_WRITE
static esp_err_t IRAM_ATTR s_verify_write ( esp_flash_t * chip , uint32_t verify_address , uint32_t remain_verify_len , const uint32_t * expected_buf , bool is_encrypted )
{
esp_err_t err = ESP_FAIL ;
uint8_t verify_buffer [ VERIFY_BUF_LEN ] ;
uint32_t * val_in_flash = ( uint32_t * ) verify_buffer ;
while ( remain_verify_len ) {
uint32_t this_len = MIN ( remain_verify_len , VERIFY_BUF_LEN ) ;
if ( is_encrypted ) {
err = esp_flash_read_encrypted ( chip , verify_address , verify_buffer , this_len ) ;
} else {
err = chip - > chip_drv - > read ( chip , verify_buffer , verify_address , this_len ) ;
}
if ( err ! = ESP_OK ) {
ESP_DRAM_LOGE ( TAG , " failed to read flash to verify previous write, err: 0x%x " , err ) ;
return err ;
}
for ( int r = 0 ; r < this_len / sizeof ( uint32_t ) ; r + + ) {
if ( val_in_flash [ r ] ! = expected_buf [ r ] ) {
# if CONFIG_SPI_FLASH_LOG_FAILED_WRITE
ESP_DRAM_LOGE ( TAG , " Bad write at %d offset: 0x%x, expected: 0x%08x, readback: 0x%08x " , r , verify_address + r , expected_buf [ r ] , val_in_flash [ r ] ) ;
# endif //#if CONFIG_SPI_FLASH_LOG_FAILED_WRITE
return ESP_FAIL ;
}
}
expected_buf = ( uint32_t * ) ( ( void * ) expected_buf + this_len ) ;
remain_verify_len - = this_len ;
verify_address + = this_len ;
}
return ESP_OK ;
}
# endif //#if CONFIG_SPI_FLASH_VERIFY_WRITE
2019-01-08 05:29:25 -05:00
esp_err_t IRAM_ATTR esp_flash_write ( esp_flash_t * chip , const void * buffer , uint32_t address , uint32_t length )
{
2023-03-02 03:10:02 -05:00
esp_err_t ret = ESP_FAIL ;
2022-09-12 22:26:59 -04:00
# if CONFIG_SPI_FLASH_VERIFY_WRITE
2023-03-02 03:10:02 -05:00
//used for verify write
bool is_encrypted = false ;
2022-09-12 22:26:59 -04:00
# endif //CONFIG_SPI_FLASH_VERIFY_WRITE
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( write ) ;
2019-01-08 05:29:25 -05:00
CHECK_WRITE_ADDRESS ( chip , address , length ) ;
if ( buffer = = NULL | | address > chip - > size | | address + length > chip - > size ) {
return ESP_ERR_INVALID_ARG ;
}
2021-07-23 05:35:27 -04:00
if ( length = = 0 ) {
return ESP_OK ;
}
2019-01-08 05:29:25 -05:00
//when the cache is disabled, only the DRAM can be read, check whether we need to copy the data first
2022-04-01 04:53:40 -04:00
bool direct_write = false ;
//If the buffer is internal already, it's ok to write it directly
direct_write | = esp_ptr_in_dram ( buffer ) ;
//If not, we need to check if the HW support direct write
direct_write | = chip - > host - > driver - > supports_direct_write ( chip - > host , buffer ) ;
2019-01-08 05:29:25 -05:00
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
// Indicate whether the bus is acquired by the driver, needs to be released before return
bool bus_acquired = false ;
2020-04-29 22:37:35 -04:00
err = ESP_OK ;
2022-08-23 00:31:53 -04:00
COUNTER_START ( ) ;
2019-01-08 05:29:25 -05:00
/* Write output in chunks, either by buffering on stack or
by artificially cutting into MAX_WRITE_CHUNK parts ( in an OS
environment , this prevents writing from causing interrupt or higher priority task
starvation . ) */
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
uint32_t write_addr = address ;
uint32_t len_remain = length ;
while ( 1 ) {
2019-01-08 05:29:25 -05:00
uint32_t write_len ;
const void * write_buf ;
2020-08-05 01:37:42 -04:00
uint32_t temp_buf [ 8 ] ;
2019-01-08 05:29:25 -05:00
if ( direct_write ) {
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
write_len = MIN ( len_remain , MAX_WRITE_CHUNK ) ;
2019-01-08 05:29:25 -05:00
write_buf = buffer ;
} else {
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
write_len = MIN ( len_remain , sizeof ( temp_buf ) ) ;
2020-08-05 01:37:42 -04:00
memcpy ( temp_buf , buffer , write_len ) ;
write_buf = temp_buf ;
2019-01-08 05:29:25 -05:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
//check before the operation, in case this is called too close to the last operation
2020-12-15 22:50:13 -05:00
if ( chip - > chip_drv - > yield ) {
err = chip - > chip_drv - > yield ( chip , 0 ) ;
if ( err ! = ESP_OK ) {
return err ;
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
}
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > start ( chip ) ;
2019-01-08 05:29:25 -05:00
if ( err ! = ESP_OK ) {
2023-03-02 03:10:02 -05:00
goto restore_cache ;
2019-01-08 05:29:25 -05:00
}
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
bus_acquired = true ;
2019-01-08 05:29:25 -05:00
2023-03-02 03:10:02 -05:00
# if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
err = s_check_setting_zero_to_one ( chip , write_addr , write_len , write_buf , is_encrypted ) ;
if ( err ! = ESP_OK ) {
//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
}
# endif //#if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
err = chip - > chip_drv - > write ( chip , write_buf , write_addr , write_len ) ;
len_remain - = write_len ;
2021-07-23 05:35:27 -04:00
assert ( len_remain < length ) ;
2022-08-23 00:31:53 -04:00
COUNTER_ADD_BYTES ( write , write_len ) ;
2019-01-08 05:29:25 -05:00
2023-03-02 03:10:02 -05:00
if ( err ! = ESP_OK ) {
//Error happens, we end flash operation. Re-enable cache and flush it
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
assert ( bus_acquired ) ;
2023-03-02 03:10:02 -05:00
goto restore_cache ;
}
# if CONFIG_SPI_FLASH_VERIFY_WRITE
err = s_verify_write ( chip , write_addr , write_len , write_buf , is_encrypted ) ;
if ( err ! = ESP_OK ) {
//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
}
# endif //#if CONFIG_SPI_FLASH_VERIFY_WRITE
if ( len_remain = = 0 ) {
//Flash operation done
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
break ;
}
2019-01-08 05:29:25 -05:00
2020-04-29 22:37:35 -04:00
err = rom_spiflash_api_funcs - > end ( chip , err ) ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
if ( err ! = ESP_OK ) {
2023-03-02 03:10:02 -05:00
goto restore_cache ;
esp_flash: refactor to support various type of yield
There is a periodically yield in the esp_flash driver, to ensure the
cache will not be disabled for too long on ESP32.
On ESP32-S2 and later, we need to support more different kind of yield:
1. polling conditions, including timeout, SW read request, etc.
2. wait for events, including HW done/error/auto-suspend, timeout
semaphore, etc.
The check_yield() and yield() is separated into two parts, because we
may need to insert suspend, etc. between them.
2020-09-11 06:20:08 -04:00
}
bus_acquired = false ;
write_addr + = write_len ;
buffer = ( void * ) ( ( intptr_t ) buffer + write_len ) ;
}
2022-08-23 00:31:53 -04:00
COUNTER_STOP ( write ) ;
2022-09-12 22:26:59 -04:00
err = rom_spiflash_api_funcs - > flash_end_flush_cache ( chip , err , bus_acquired , address , length ) ;
2023-03-02 03:10:02 -05:00
return err ;
2022-09-12 22:26:59 -04:00
2023-03-02 03:10:02 -05:00
restore_cache :
2022-08-23 00:31:53 -04:00
COUNTER_STOP ( write ) ;
2023-03-02 03:10:02 -05:00
ret = rom_spiflash_api_funcs - > flash_end_flush_cache ( chip , err , bus_acquired , address , length ) ;
if ( ret ! = ESP_OK ) {
ESP_DRAM_LOGE ( TAG , " restore cache fail \n " ) ;
}
2022-09-12 22:26:59 -04:00
return err ;
2019-01-08 05:29:25 -05:00
}
esp_err_t IRAM_ATTR esp_flash_write_encrypted ( esp_flash_t * chip , uint32_t address , const void * buffer , uint32_t length )
{
2023-03-02 03:11:54 -05:00
esp_err_t ret = ESP_FAIL ;
2022-09-12 22:26:59 -04:00
# if CONFIG_SPI_FLASH_VERIFY_WRITE
2023-03-02 03:11:54 -05:00
//used for verify write
bool is_encrypted = true ;
2022-09-12 22:26:59 -04:00
# endif //CONFIG_SPI_FLASH_VERIFY_WRITE
2020-04-29 22:37:35 -04:00
esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
2021-02-24 23:25:38 -05:00
// Flash encryption only support on main flash.
if ( chip ! = esp_flash_default_chip ) {
return ESP_ERR_NOT_SUPPORTED ;
}
2020-04-29 22:37:35 -04:00
if ( err ! = ESP_OK ) return err ;
2021-02-24 23:25:38 -05:00
if ( buffer = = NULL | | address + length > chip - > size ) {
return ESP_ERR_INVALID_ARG ;
}
if ( ( address % 16 ) ! = 0 ) {
ESP_EARLY_LOGE ( TAG , " flash encrypted write address must be 16 bytes aligned " ) ;
2019-01-08 05:29:25 -05:00
return ESP_ERR_INVALID_ARG ;
}
2021-02-24 23:25:38 -05:00
2021-07-23 05:35:27 -04:00
if ( length = = 0 ) {
return ESP_OK ;
}
2021-02-24 23:25:38 -05:00
if ( ( length % 16 ) ! = 0 ) {
ESP_EARLY_LOGE ( TAG , " flash encrypted write length must be multiple of 16 " ) ;
return ESP_ERR_INVALID_SIZE ;
}
bool bus_acquired = false ;
const uint8_t * ssrc = ( const uint8_t * ) buffer ;
2022-08-23 00:31:53 -04:00
COUNTER_START ( ) ;
2021-02-24 23:25:38 -05:00
/* On ESP32, write_encrypted encrypts data in RAM as it writes,
so copy to a temporary buffer - 32 bytes at a time .
Each call to write_encrypted takes a 32 byte " row " of
data to encrypt , and each row is two 16 byte AES blocks
that share a key ( as derived from flash address ) .
On ESP32 - S2 and later , the temporary buffer need to be
seperated into 16 - bytes , 32 - bytes , 64 - bytes ( if supported ) .
So , on ESP32 - S2 and later , here has a totally different
data prepare implementation .
*/
uint8_t encrypt_buf [ 64 ] __attribute__ ( ( aligned ( 4 ) ) ) ;
uint32_t row_size_length ;
for ( size_t i = 0 ; i < length ; i + = row_size_length ) {
uint32_t row_addr = address + i ;
uint8_t row_size ;
uint8_t encrypt_byte ;
# if CONFIG_IDF_TARGET_ESP32
if ( i = = 0 & & ( row_addr % 32 ) ! = 0 ) {
/* writing to second block of a 32 byte row */
row_size = 16 ;
row_addr - = 16 ;
/* copy to second block in buffer */
memcpy ( encrypt_buf + 16 , ssrc + i , row_size ) ;
/* decrypt the first block from flash, will reencrypt to same bytes */
esp_flash_read_encrypted ( chip , row_addr , encrypt_buf , 16 ) ;
} else if ( length - i = = 16 ) {
/* 16 bytes left, is first block of a 32 byte row */
row_size = 16 ;
/* copy to first block in buffer */
memcpy ( encrypt_buf , ssrc + i , row_size ) ;
/* decrypt the second block from flash, will reencrypt to same bytes */
esp_flash_read_encrypted ( chip , row_addr + 16 , encrypt_buf + 16 , 16 ) ;
} else {
/* Writing a full 32 byte row (2 blocks) */
row_size = 32 ;
memcpy ( encrypt_buf , ssrc + i , row_size ) ;
}
encrypt_byte = 32 ;
row_size_length = row_size ;
# else // FOR ESP32-S2, ESP32-S3, ESP32-C3
if ( ( row_addr % 64 ) = = 0 & & ( length - i ) > = 64 & & SOC_FLASH_ENCRYPTED_XTS_AES_BLOCK_MAX = = 64 ) {
row_size = 64 ;
memcpy ( encrypt_buf , ssrc + i , row_size ) ;
} else if ( ( row_addr % 32 ) = = 0 & & ( length - i ) > = 32 ) {
row_size = 32 ;
memcpy ( encrypt_buf , ssrc + i , row_size ) ;
} else {
row_size = 16 ;
memcpy ( encrypt_buf , ssrc + i , row_size ) ;
}
encrypt_byte = row_size ;
row_size_length = row_size ;
# endif //CONFIG_IDF_TARGET_ESP32
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# if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
err = s_check_setting_zero_to_one ( chip , row_addr , encrypt_byte , NULL , is_encrypted ) ;
if ( err ! = ESP_OK ) {
//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
}
# endif //#if CONFIG_SPI_FLASH_WARN_SETTING_ZERO_TO_ONE
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# if CONFIG_IDF_TARGET_ESP32S2
esp_crypto_dma_lock_acquire ( ) ;
# endif //CONFIG_IDF_TARGET_ESP32S2
err = rom_spiflash_api_funcs - > start ( chip ) ;
if ( err ! = ESP_OK ) {
# if CONFIG_IDF_TARGET_ESP32S2
esp_crypto_dma_lock_release ( ) ;
# endif //CONFIG_IDF_TARGET_ESP32S2
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//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
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}
bus_acquired = true ;
err = chip - > chip_drv - > write_encrypted ( chip , ( uint32_t * ) encrypt_buf , row_addr , encrypt_byte ) ;
if ( err ! = ESP_OK ) {
# if CONFIG_IDF_TARGET_ESP32S2
esp_crypto_dma_lock_release ( ) ;
# endif //CONFIG_IDF_TARGET_ESP32S2
bus_acquired = false ;
assert ( bus_acquired ) ;
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//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
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}
err = rom_spiflash_api_funcs - > end ( chip , ESP_OK ) ;
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COUNTER_ADD_BYTES ( write , encrypt_byte ) ;
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# if CONFIG_IDF_TARGET_ESP32S2
esp_crypto_dma_lock_release ( ) ;
# endif //CONFIG_IDF_TARGET_ESP32S2
if ( err ! = ESP_OK ) {
bus_acquired = false ;
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//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
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}
bus_acquired = false ;
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# if CONFIG_SPI_FLASH_VERIFY_WRITE
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err = s_verify_write ( chip , row_addr , encrypt_byte , ( uint32_t * ) encrypt_buf , is_encrypted ) ;
if ( err ! = ESP_OK ) {
//Error happens, we end flash operation. Re-enable cache and flush it
goto restore_cache ;
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}
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# endif //CONFIG_SPI_FLASH_VERIFY_WRITE
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}
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COUNTER_STOP ( write ) ;
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err = rom_spiflash_api_funcs - > flash_end_flush_cache ( chip , err , bus_acquired , address , length ) ;
return err ;
restore_cache :
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COUNTER_STOP ( write ) ;
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ret = rom_spiflash_api_funcs - > flash_end_flush_cache ( chip , err , bus_acquired , address , length ) ;
if ( ret ! = ESP_OK ) {
ESP_DRAM_LOGE ( TAG , " restore cache fail \n " ) ;
}
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return err ;
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}
inline static IRAM_ATTR bool regions_overlap ( uint32_t a_start , uint32_t a_len , uint32_t b_start , uint32_t b_len )
{
uint32_t a_end = a_start + a_len ;
uint32_t b_end = b_start + b_len ;
return ( a_end > b_start & & b_end > a_start ) ;
}
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esp_err_t IRAM_ATTR esp_flash_read_encrypted ( esp_flash_t * chip , uint32_t address , void * out_buffer , uint32_t length )
{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
if ( err ! = ESP_OK ) return err ;
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if ( address + length > g_rom_flashchip . chip_size ) {
return ESP_ERR_INVALID_SIZE ;
}
if ( length = = 0 ) {
return ESP_OK ;
}
if ( out_buffer = = NULL ) {
return ESP_ERR_INVALID_ARG ;
}
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COUNTER_START ( ) ;
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const uint8_t * map ;
spi_flash_mmap_handle_t map_handle ;
size_t map_src = address & ~ ( SPI_FLASH_MMU_PAGE_SIZE - 1 ) ;
size_t map_size = length + ( address - map_src ) ;
err = spi_flash_mmap ( map_src , map_size , SPI_FLASH_MMAP_DATA , ( const void * * ) & map , & map_handle ) ;
if ( err ! = ESP_OK ) {
return err ;
}
memcpy ( out_buffer , map + ( address - map_src ) , length ) ;
spi_flash_munmap ( map_handle ) ;
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COUNTER_ADD_BYTES ( read , length ) ;
COUNTER_STOP ( read ) ;
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return err ;
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}
2019-01-08 05:29:25 -05:00
2019-09-05 01:11:36 -04:00
// test only, non-public
IRAM_ATTR esp_err_t esp_flash_get_io_mode ( esp_flash_t * chip , bool * qe )
{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( get_io_mode ) ;
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esp_flash_io_mode_t io_mode ;
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
err = chip - > chip_drv - > get_io_mode ( chip , & io_mode ) ;
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err = rom_spiflash_api_funcs - > end ( chip , err ) ;
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if ( err = = ESP_OK ) {
* qe = ( io_mode = = SPI_FLASH_QOUT ) ;
}
return err ;
}
IRAM_ATTR esp_err_t esp_flash_set_io_mode ( esp_flash_t * chip , bool qe )
{
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esp_err_t err = rom_spiflash_api_funcs - > chip_check ( & chip ) ;
VERIFY_CHIP_OP ( set_io_mode ) ;
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chip - > read_mode = ( qe ? SPI_FLASH_QOUT : SPI_FLASH_SLOWRD ) ;
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err = rom_spiflash_api_funcs - > start ( chip ) ;
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if ( err ! = ESP_OK ) {
return err ;
}
err = chip - > chip_drv - > set_io_mode ( chip ) ;
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return rom_spiflash_api_funcs - > end ( chip , err ) ;
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}
2020-12-15 22:50:13 -05:00
# endif //CONFIG_SPI_FLASH_ROM_IMPL
2019-09-05 01:11:36 -04:00
2020-12-17 23:57:55 -05:00
//init suspend mode cmd, uses internal.
esp_err_t esp_flash_suspend_cmd_init ( esp_flash_t * chip )
{
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ESP_EARLY_LOGW ( TAG , " Flash suspend feature is enabled " ) ;
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if ( chip - > chip_drv - > get_chip_caps = = NULL ) {
// chip caps get failed, pass the flash capability check.
ESP_EARLY_LOGW ( TAG , " get_chip_caps function pointer hasn't been initialized " ) ;
} else {
if ( ( chip - > chip_drv - > get_chip_caps ( chip ) & SPI_FLASH_CHIP_CAP_SUSPEND ) = = 0 ) {
ESP_EARLY_LOGW ( TAG , " Suspend and resume may not supported for this flash model yet. " ) ;
}
}
2020-12-17 23:57:55 -05:00
return chip - > chip_drv - > sus_setup ( chip ) ;
}
2019-09-11 14:41:00 -04:00
esp_err_t esp_flash_app_disable_protect ( bool disable )
{
if ( disable ) {
return esp_flash_app_disable_os_functions ( esp_flash_default_chip ) ;
} else {
2020-04-09 01:30:12 -04:00
return esp_flash_app_enable_os_functions ( esp_flash_default_chip ) ;
2019-09-11 14:41:00 -04:00
}
}