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/*
* SPDX - FileCopyrightText : 2018 - 2021 Espressif Systems ( Shanghai ) CO LTD
*
* SPDX - License - Identifier : Apache - 2.0
*/
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# include <string.h>
# include <stdint.h>
# include <limits.h>
# include <sys/param.h>
# include "esp_attr.h"
# include "esp_log.h"
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# include "esp_rom_sys.h"
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# include "esp_rom_uart.h"
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# include "sdkconfig.h"
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# if CONFIG_IDF_TARGET_ESP32
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# include "soc/dport_reg.h"
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# include "esp32/rom/cache.h"
# include "esp32/rom/spi_flash.h"
# include "esp32/rom/secure_boot.h"
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# elif CONFIG_IDF_TARGET_ESP32S2
# include "esp32s2/rom/cache.h"
# include "esp32s2/rom/spi_flash.h"
# include "esp32s2/rom/secure_boot.h"
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# include "soc/extmem_reg.h"
# include "soc/cache_memory.h"
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# elif CONFIG_IDF_TARGET_ESP32S3
# include "esp32s3/rom/cache.h"
# include "esp32s3/rom/spi_flash.h"
# include "esp32s3/rom/secure_boot.h"
# include "soc/extmem_reg.h"
# include "soc/cache_memory.h"
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# elif CONFIG_IDF_TARGET_ESP32C3
# include "esp32c3/rom/cache.h"
# include "esp32c3/rom/efuse.h"
# include "esp32c3/rom/ets_sys.h"
# include "esp32c3/rom/spi_flash.h"
# include "esp32c3/rom/crc.h"
# include "esp32c3/rom/uart.h"
# include "esp32c3/rom/gpio.h"
# include "esp32c3/rom/secure_boot.h"
# include "soc/extmem_reg.h"
# include "soc/cache_memory.h"
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# elif CONFIG_IDF_TARGET_ESP32H2
# include "esp32h2/rom/cache.h"
# include "esp32h2/rom/efuse.h"
# include "esp32h2/rom/ets_sys.h"
# include "esp32h2/rom/spi_flash.h"
# include "esp32h2/rom/crc.h"
# include "esp32h2/rom/uart.h"
# include "esp32h2/rom/gpio.h"
# include "esp32h2/rom/secure_boot.h"
# include "soc/extmem_reg.h"
# include "soc/cache_memory.h"
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# else // CONFIG_IDF_TARGET_*
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# error "Unsupported IDF_TARGET"
# endif
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# include "soc/soc.h"
# include "soc/cpu.h"
# include "soc/rtc.h"
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# include "soc/gpio_periph.h"
# include "soc/efuse_periph.h"
# include "soc/rtc_periph.h"
# include "soc/timer_periph.h"
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# include "esp_image_format.h"
# include "esp_secure_boot.h"
# include "esp_flash_encrypt.h"
# include "esp_flash_partitions.h"
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# include "bootloader_flash_priv.h"
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# include "bootloader_random.h"
# include "bootloader_config.h"
# include "bootloader_common.h"
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# include "bootloader_utility.h"
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# include "bootloader_sha.h"
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# include "bootloader_console.h"
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# include "esp_efuse.h"
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static const char * TAG = " boot " ;
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/* Reduce literal size for some generic string literals */
# define MAP_ERR_MSG "Image contains multiple %s segments. Only the last one will be mapped."
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static bool ota_has_initial_contents ;
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static void load_image ( const esp_image_metadata_t * image_data ) ;
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static void unpack_load_app ( const esp_image_metadata_t * data ) ;
static void set_cache_and_start_app ( uint32_t drom_addr ,
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uint32_t drom_load_addr ,
uint32_t drom_size ,
uint32_t irom_addr ,
uint32_t irom_load_addr ,
uint32_t irom_size ,
uint32_t entry_addr ) ;
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// Read ota_info partition and fill array from two otadata structures.
static esp_err_t read_otadata ( const esp_partition_pos_t * ota_info , esp_ota_select_entry_t * two_otadata )
{
const esp_ota_select_entry_t * ota_select_map ;
if ( ota_info - > offset = = 0 ) {
return ESP_ERR_NOT_FOUND ;
}
// partition table has OTA data partition
if ( ota_info - > size < 2 * SPI_SEC_SIZE ) {
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ESP_LOGE ( TAG , " ota_info partition size %d is too small (minimum %d bytes) " , ota_info - > size , ( 2 * SPI_SEC_SIZE ) ) ;
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return ESP_FAIL ; // can't proceed
}
ESP_LOGD ( TAG , " OTA data offset 0x%x " , ota_info - > offset ) ;
ota_select_map = bootloader_mmap ( ota_info - > offset , ota_info - > size ) ;
if ( ! ota_select_map ) {
ESP_LOGE ( TAG , " bootloader_mmap(0x%x, 0x%x) failed " , ota_info - > offset , ota_info - > size ) ;
return ESP_FAIL ; // can't proceed
}
memcpy ( & two_otadata [ 0 ] , ota_select_map , sizeof ( esp_ota_select_entry_t ) ) ;
memcpy ( & two_otadata [ 1 ] , ( uint8_t * ) ota_select_map + SPI_SEC_SIZE , sizeof ( esp_ota_select_entry_t ) ) ;
bootloader_munmap ( ota_select_map ) ;
return ESP_OK ;
}
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bool bootloader_utility_load_partition_table ( bootloader_state_t * bs )
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{
const esp_partition_info_t * partitions ;
const char * partition_usage ;
esp_err_t err ;
int num_partitions ;
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partitions = bootloader_mmap ( ESP_PARTITION_TABLE_OFFSET , ESP_PARTITION_TABLE_MAX_LEN ) ;
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if ( ! partitions ) {
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ESP_LOGE ( TAG , " bootloader_mmap(0x%x, 0x%x) failed " , ESP_PARTITION_TABLE_OFFSET , ESP_PARTITION_TABLE_MAX_LEN ) ;
return false ;
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}
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ESP_LOGD ( TAG , " mapped partition table 0x%x at 0x%x " , ESP_PARTITION_TABLE_OFFSET , ( intptr_t ) partitions ) ;
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err = esp_partition_table_verify ( partitions , true , & num_partitions ) ;
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if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " Failed to verify partition table " ) ;
return false ;
}
ESP_LOGI ( TAG , " Partition Table: " ) ;
ESP_LOGI ( TAG , " ## Label Usage Type ST Offset Length " ) ;
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for ( int i = 0 ; i < num_partitions ; i + + ) {
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const esp_partition_info_t * partition = & partitions [ i ] ;
ESP_LOGD ( TAG , " load partition table entry 0x%x " , ( intptr_t ) partition ) ;
ESP_LOGD ( TAG , " type=%x subtype=%x " , partition - > type , partition - > subtype ) ;
partition_usage = " unknown " ;
/* valid partition table */
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switch ( partition - > type ) {
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case PART_TYPE_APP : /* app partition */
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switch ( partition - > subtype ) {
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case PART_SUBTYPE_FACTORY : /* factory binary */
bs - > factory = partition - > pos ;
partition_usage = " factory app " ;
break ;
case PART_SUBTYPE_TEST : /* test binary */
bs - > test = partition - > pos ;
partition_usage = " test app " ;
break ;
default :
/* OTA binary */
if ( ( partition - > subtype & ~ PART_SUBTYPE_OTA_MASK ) = = PART_SUBTYPE_OTA_FLAG ) {
bs - > ota [ partition - > subtype & PART_SUBTYPE_OTA_MASK ] = partition - > pos ;
+ + bs - > app_count ;
partition_usage = " OTA app " ;
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} else {
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partition_usage = " Unknown app " ;
}
break ;
}
break ; /* PART_TYPE_APP */
case PART_TYPE_DATA : /* data partition */
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switch ( partition - > subtype ) {
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case PART_SUBTYPE_DATA_OTA : /* ota data */
bs - > ota_info = partition - > pos ;
partition_usage = " OTA data " ;
break ;
case PART_SUBTYPE_DATA_RF :
partition_usage = " RF data " ;
break ;
case PART_SUBTYPE_DATA_WIFI :
partition_usage = " WiFi data " ;
break ;
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case PART_SUBTYPE_DATA_NVS_KEYS :
partition_usage = " NVS keys " ;
break ;
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case PART_SUBTYPE_DATA_EFUSE_EM :
partition_usage = " efuse " ;
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# ifdef CONFIG_EFUSE_VIRTUAL_KEEP_IN_FLASH
esp_efuse_init_virtual_mode_in_flash ( partition - > pos . offset , partition - > pos . size ) ;
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# endif
break ;
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default :
partition_usage = " Unknown data " ;
break ;
}
break ; /* PARTITION_USAGE_DATA */
default : /* other partition type */
break ;
}
/* print partition type info */
ESP_LOGI ( TAG , " %2d %-16s %-16s %02x %02x %08x %08x " , i , partition - > label , partition_usage ,
partition - > type , partition - > subtype ,
partition - > pos . offset , partition - > pos . size ) ;
}
bootloader_munmap ( partitions ) ;
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ESP_LOGI ( TAG , " End of partition table " ) ;
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return true ;
}
/* Given a partition index, return the partition position data from the bootloader_state_t structure */
static esp_partition_pos_t index_to_partition ( const bootloader_state_t * bs , int index )
{
if ( index = = FACTORY_INDEX ) {
return bs - > factory ;
}
if ( index = = TEST_APP_INDEX ) {
return bs - > test ;
}
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if ( index > = 0 & & index < MAX_OTA_SLOTS & & index < ( int ) bs - > app_count ) {
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return bs - > ota [ index ] ;
}
esp_partition_pos_t invalid = { 0 } ;
return invalid ;
}
static void log_invalid_app_partition ( int index )
{
const char * not_bootable = " is not bootable " ; /* save a few string literal bytes */
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switch ( index ) {
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case FACTORY_INDEX :
ESP_LOGE ( TAG , " Factory app partition%s " , not_bootable ) ;
break ;
case TEST_APP_INDEX :
ESP_LOGE ( TAG , " Factory test app partition%s " , not_bootable ) ;
break ;
default :
ESP_LOGE ( TAG , " OTA app partition slot %d%s " , index , not_bootable ) ;
break ;
}
}
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static esp_err_t write_otadata ( esp_ota_select_entry_t * otadata , uint32_t offset , bool write_encrypted )
{
esp_err_t err = bootloader_flash_erase_sector ( offset / FLASH_SECTOR_SIZE ) ;
if ( err = = ESP_OK ) {
err = bootloader_flash_write ( offset , otadata , sizeof ( esp_ota_select_entry_t ) , write_encrypted ) ;
}
if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " Error in write_otadata operation. err = 0x%x " , err ) ;
}
return err ;
}
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static bool check_anti_rollback ( const esp_partition_pos_t * partition )
{
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# ifdef CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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esp_app_desc_t app_desc ;
esp_err_t err = bootloader_common_get_partition_description ( partition , & app_desc ) ;
return err = = ESP_OK & & esp_efuse_check_secure_version ( app_desc . secure_version ) = = true ;
# else
return true ;
# endif
}
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# ifdef CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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static void update_anti_rollback ( const esp_partition_pos_t * partition )
{
esp_app_desc_t app_desc ;
esp_err_t err = bootloader_common_get_partition_description ( partition , & app_desc ) ;
if ( err = = ESP_OK ) {
esp_efuse_update_secure_version ( app_desc . secure_version ) ;
}
}
static int get_active_otadata_with_check_anti_rollback ( const bootloader_state_t * bs , esp_ota_select_entry_t * two_otadata )
{
uint32_t ota_seq ;
uint32_t ota_slot ;
bool valid_otadata [ 2 ] ;
valid_otadata [ 0 ] = bootloader_common_ota_select_valid ( & two_otadata [ 0 ] ) ;
valid_otadata [ 1 ] = bootloader_common_ota_select_valid ( & two_otadata [ 1 ] ) ;
bool sec_ver_valid_otadata [ 2 ] = { 0 } ;
for ( int i = 0 ; i < 2 ; + + i ) {
if ( valid_otadata [ i ] = = true ) {
ota_seq = two_otadata [ i ] . ota_seq - 1 ; // Raw OTA sequence number. May be more than # of OTA slots
ota_slot = ota_seq % bs - > app_count ; // Actual OTA partition selection
if ( check_anti_rollback ( & bs - > ota [ ota_slot ] ) = = false ) {
// invalid. This otadata[i] will not be selected as active.
ESP_LOGD ( TAG , " OTA slot %d has an app with secure_version, this version is smaller than in the device. This OTA slot will not be selected. " , ota_slot ) ;
} else {
sec_ver_valid_otadata [ i ] = true ;
}
}
}
return bootloader_common_select_otadata ( two_otadata , sec_ver_valid_otadata , true ) ;
}
# endif
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int bootloader_utility_get_selected_boot_partition ( const bootloader_state_t * bs )
{
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esp_ota_select_entry_t otadata [ 2 ] ;
int boot_index = FACTORY_INDEX ;
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if ( bs - > ota_info . offset = = 0 ) {
return FACTORY_INDEX ;
}
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if ( read_otadata ( & bs - > ota_info , otadata ) ! = ESP_OK ) {
return INVALID_INDEX ;
}
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ota_has_initial_contents = false ;
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ESP_LOGD ( TAG , " otadata[0]: sequence values 0x%08x " , otadata [ 0 ] . ota_seq ) ;
ESP_LOGD ( TAG , " otadata[1]: sequence values 0x%08x " , otadata [ 1 ] . ota_seq ) ;
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# ifdef CONFIG_BOOTLOADER_APP_ROLLBACK_ENABLE
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bool write_encrypted = esp_flash_encryption_enabled ( ) ;
for ( int i = 0 ; i < 2 ; + + i ) {
if ( otadata [ i ] . ota_state = = ESP_OTA_IMG_PENDING_VERIFY ) {
ESP_LOGD ( TAG , " otadata[%d] is marking as ABORTED " , i ) ;
otadata [ i ] . ota_state = ESP_OTA_IMG_ABORTED ;
write_otadata ( & otadata [ i ] , bs - > ota_info . offset + FLASH_SECTOR_SIZE * i , write_encrypted ) ;
}
}
# endif
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# ifndef CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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if ( ( bootloader_common_ota_select_invalid ( & otadata [ 0 ] ) & &
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bootloader_common_ota_select_invalid ( & otadata [ 1 ] ) ) | |
bs - > app_count = = 0 ) {
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ESP_LOGD ( TAG , " OTA sequence numbers both empty (all-0xFF) or partition table does not have bootable ota_apps (app_count=%d) " , bs - > app_count ) ;
if ( bs - > factory . offset ! = 0 ) {
ESP_LOGI ( TAG , " Defaulting to factory image " ) ;
boot_index = FACTORY_INDEX ;
} else {
ESP_LOGI ( TAG , " No factory image, trying OTA 0 " ) ;
boot_index = 0 ;
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// Try to boot from ota_0.
if ( ( otadata [ 0 ] . ota_seq = = UINT32_MAX | | otadata [ 0 ] . crc ! = bootloader_common_ota_select_crc ( & otadata [ 0 ] ) ) & &
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( otadata [ 1 ] . ota_seq = = UINT32_MAX | | otadata [ 1 ] . crc ! = bootloader_common_ota_select_crc ( & otadata [ 1 ] ) ) ) {
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// Factory is not found and both otadata are initial(0xFFFFFFFF) or incorrect crc.
// will set correct ota_seq.
ota_has_initial_contents = true ;
}
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}
} else {
int active_otadata = bootloader_common_get_active_otadata ( otadata ) ;
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# else
ESP_LOGI ( TAG , " Enabled a check secure version of app for anti rollback " ) ;
ESP_LOGI ( TAG , " Secure version (from eFuse) = %d " , esp_efuse_read_secure_version ( ) ) ;
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// When CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK is enabled factory partition should not be in partition table, only two ota_app are there.
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if ( ( otadata [ 0 ] . ota_seq = = UINT32_MAX | | otadata [ 0 ] . crc ! = bootloader_common_ota_select_crc ( & otadata [ 0 ] ) ) & &
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( otadata [ 1 ] . ota_seq = = UINT32_MAX | | otadata [ 1 ] . crc ! = bootloader_common_ota_select_crc ( & otadata [ 1 ] ) ) ) {
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ESP_LOGI ( TAG , " otadata[0..1] in initial state " ) ;
// both otadata are initial(0xFFFFFFFF) or incorrect crc.
// will set correct ota_seq.
ota_has_initial_contents = true ;
} else {
int active_otadata = get_active_otadata_with_check_anti_rollback ( bs , otadata ) ;
# endif
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if ( active_otadata ! = - 1 ) {
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ESP_LOGD ( TAG , " Active otadata[%d] " , active_otadata ) ;
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uint32_t ota_seq = otadata [ active_otadata ] . ota_seq - 1 ; // Raw OTA sequence number. May be more than # of OTA slots
boot_index = ota_seq % bs - > app_count ; // Actual OTA partition selection
ESP_LOGD ( TAG , " Mapping seq %d -> OTA slot %d " , ota_seq , boot_index ) ;
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# ifdef CONFIG_BOOTLOADER_APP_ROLLBACK_ENABLE
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if ( otadata [ active_otadata ] . ota_state = = ESP_OTA_IMG_NEW ) {
ESP_LOGD ( TAG , " otadata[%d] is selected as new and marked PENDING_VERIFY state " , active_otadata ) ;
otadata [ active_otadata ] . ota_state = ESP_OTA_IMG_PENDING_VERIFY ;
write_otadata ( & otadata [ active_otadata ] , bs - > ota_info . offset + FLASH_SECTOR_SIZE * active_otadata , write_encrypted ) ;
}
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# endif // CONFIG_BOOTLOADER_APP_ROLLBACK_ENABLE
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# ifdef CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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if ( otadata [ active_otadata ] . ota_state = = ESP_OTA_IMG_VALID ) {
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update_anti_rollback ( & bs - > ota [ boot_index ] ) ;
}
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# endif // CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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} else if ( bs - > factory . offset ! = 0 ) {
ESP_LOGE ( TAG , " ota data partition invalid, falling back to factory " ) ;
boot_index = FACTORY_INDEX ;
} else {
ESP_LOGE ( TAG , " ota data partition invalid and no factory, will try all partitions " ) ;
boot_index = FACTORY_INDEX ;
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}
}
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return boot_index ;
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}
/* Return true if a partition has a valid app image that was successfully loaded */
static bool try_load_partition ( const esp_partition_pos_t * partition , esp_image_metadata_t * data )
{
if ( partition - > size = = 0 ) {
ESP_LOGD ( TAG , " Can't boot from zero-length partition " ) ;
return false ;
}
# ifdef BOOTLOADER_BUILD
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if ( bootloader_load_image ( partition , data ) = = ESP_OK ) {
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ESP_LOGI ( TAG , " Loaded app from partition at offset 0x%x " ,
partition - > offset ) ;
return true ;
}
# endif
return false ;
}
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// ota_has_initial_contents flag is set if factory does not present in partition table and
// otadata has initial content(0xFFFFFFFF), then set actual ota_seq.
static void set_actual_ota_seq ( const bootloader_state_t * bs , int index )
{
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if ( index > FACTORY_INDEX & & ota_has_initial_contents = = true ) {
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esp_ota_select_entry_t otadata ;
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memset ( & otadata , 0xFF , sizeof ( otadata ) ) ;
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otadata . ota_seq = index + 1 ;
otadata . ota_state = ESP_OTA_IMG_VALID ;
otadata . crc = bootloader_common_ota_select_crc ( & otadata ) ;
bool write_encrypted = esp_flash_encryption_enabled ( ) ;
write_otadata ( & otadata , bs - > ota_info . offset + FLASH_SECTOR_SIZE * 0 , write_encrypted ) ;
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ESP_LOGI ( TAG , " Set actual ota_seq=%d in otadata[0] " , otadata . ota_seq ) ;
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# ifdef CONFIG_BOOTLOADER_APP_ANTI_ROLLBACK
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update_anti_rollback ( & bs - > ota [ index ] ) ;
# endif
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}
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# if defined( CONFIG_BOOTLOADER_SKIP_VALIDATE_IN_DEEP_SLEEP ) || defined( CONFIG_BOOTLOADER_CUSTOM_RESERVE_RTC )
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esp_partition_pos_t partition = index_to_partition ( bs , index ) ;
bootloader_common_update_rtc_retain_mem ( & partition , true ) ;
# endif
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}
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# ifdef CONFIG_BOOTLOADER_SKIP_VALIDATE_IN_DEEP_SLEEP
void bootloader_utility_load_boot_image_from_deep_sleep ( void )
{
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if ( esp_rom_get_reset_reason ( 0 ) = = RESET_REASON_CORE_DEEP_SLEEP ) {
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esp_partition_pos_t * partition = bootloader_common_get_rtc_retain_mem_partition ( ) ;
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if ( partition ! = NULL ) {
esp_image_metadata_t image_data ;
if ( bootloader_load_image_no_verify ( partition , & image_data ) = = ESP_OK ) {
ESP_LOGI ( TAG , " Fast booting app from partition at offset 0x%x " , partition - > offset ) ;
bootloader_common_update_rtc_retain_mem ( NULL , true ) ;
load_image ( & image_data ) ;
}
}
ESP_LOGE ( TAG , " Fast booting is not successful " ) ;
ESP_LOGI ( TAG , " Try to load an app as usual with all validations " ) ;
}
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}
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# endif
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# define TRY_LOG_FORMAT "Trying partition index %d offs 0x%x size 0x%x"
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void bootloader_utility_load_boot_image ( const bootloader_state_t * bs , int start_index )
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{
int index = start_index ;
esp_partition_pos_t part ;
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esp_image_metadata_t image_data ;
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if ( start_index = = TEST_APP_INDEX ) {
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if ( check_anti_rollback ( & bs - > test ) & & try_load_partition ( & bs - > test , & image_data ) ) {
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load_image ( & image_data ) ;
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} else {
ESP_LOGE ( TAG , " No bootable test partition in the partition table " ) ;
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bootloader_reset ( ) ;
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}
}
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/* work backwards from start_index, down to the factory app */
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for ( index = start_index ; index > = FACTORY_INDEX ; index - - ) {
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part = index_to_partition ( bs , index ) ;
if ( part . size = = 0 ) {
continue ;
}
ESP_LOGD ( TAG , TRY_LOG_FORMAT , index , part . offset , part . size ) ;
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if ( check_anti_rollback ( & part ) & & try_load_partition ( & part , & image_data ) ) {
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set_actual_ota_seq ( bs , index ) ;
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load_image ( & image_data ) ;
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}
log_invalid_app_partition ( index ) ;
}
/* failing that work forwards from start_index, try valid OTA slots */
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for ( index = start_index + 1 ; index < ( int ) bs - > app_count ; index + + ) {
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part = index_to_partition ( bs , index ) ;
if ( part . size = = 0 ) {
continue ;
}
ESP_LOGD ( TAG , TRY_LOG_FORMAT , index , part . offset , part . size ) ;
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if ( check_anti_rollback ( & part ) & & try_load_partition ( & part , & image_data ) ) {
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set_actual_ota_seq ( bs , index ) ;
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load_image ( & image_data ) ;
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}
log_invalid_app_partition ( index ) ;
}
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if ( check_anti_rollback ( & bs - > test ) & & try_load_partition ( & bs - > test , & image_data ) ) {
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ESP_LOGW ( TAG , " Falling back to test app as only bootable partition " ) ;
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load_image ( & image_data ) ;
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}
ESP_LOGE ( TAG , " No bootable app partitions in the partition table " ) ;
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bzero ( & image_data , sizeof ( esp_image_metadata_t ) ) ;
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bootloader_reset ( ) ;
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}
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// Copy loaded segments to RAM, set up caches for mapped segments, and start application.
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static void load_image ( const esp_image_metadata_t * image_data )
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{
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/**
* Rough steps for a first boot , when encryption and secure boot are both disabled :
* 1 ) Generate secure boot key and write to EFUSE .
* 2 ) Write plaintext digest based on plaintext bootloader
* 3 ) Generate flash encryption key and write to EFUSE .
* 4 ) Encrypt flash in - place including bootloader , then digest ,
* then app partitions and other encrypted partitions
* 5 ) Burn EFUSE to enable flash encryption ( FLASH_CRYPT_CNT )
* 6 ) Burn EFUSE to enable secure boot ( ABS_DONE_0 )
*
* If power failure happens during Step 1 , probably the next boot will continue from Step 2.
* There is some small chance that EFUSEs will be part - way through being written so will be
* somehow corrupted here . Thankfully this window of time is very small , but if that ' s the
* case , one has to use the espefuse tool to manually set the remaining bits and enable R / W
* protection . Once the relevant EFUSE bits are set and R / W protected , Step 1 will be skipped
* successfully on further reboots .
*
* If power failure happens during Step 2 , Step 1 will be skipped and Step 2 repeated :
* the digest will get re - written on the next boot .
*
* If power failure happens during Step 3 , it ' s possible that EFUSE was partially written
* with the generated flash encryption key , though the time window for that would again
* be very small . On reboot , Step 1 will be skipped and Step 2 repeated , though , Step 3
* may fail due to the above mentioned reason , in which case , one has to use the espefuse
* tool to manually set the remaining bits and enable R / W protection . Once the relevant EFUSE
* bits are set and R / W protected , Step 3 will be skipped successfully on further reboots .
*
* If power failure happens after start of 4 and before end of 5 , the next boot will fail
* ( bootloader header is encrypted and flash encryption isn ' t enabled yet , so it looks like
* noise to the ROM bootloader ) . The check in the ROM is pretty basic so if the first byte of
* ciphertext happens to be the magic byte E9 then it may try to boot , but it will definitely
* crash ( no chance that the remaining ciphertext will look like a valid bootloader image ) .
* Only solution is to reflash with all plaintext and the whole process starts again : skips
* Step 1 , repeats Step 2 , skips Step 3 , etc .
*
* If power failure happens after 5 but before 6 , the device will reboot with flash
* encryption on and will regenerate an encrypted digest in Step 2. This should still
* be valid as the input data for the digest is read via flash cache ( so will be decrypted )
* and the code in secure_boot_generate ( ) tells bootloader_flash_write ( ) to encrypt the data
* on write if flash encryption is enabled . Steps 3 - 5 are skipped ( encryption already on ) ,
* then Step 6 enables secure boot .
*/
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# if defined(CONFIG_SECURE_BOOT) || defined(CONFIG_SECURE_FLASH_ENC_ENABLED)
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esp_err_t err ;
# endif
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# ifdef CONFIG_SECURE_BOOT_V2_ENABLED
err = esp_secure_boot_v2_permanently_enable ( image_data ) ;
if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " Secure Boot v2 failed (%d) " , err ) ;
return ;
}
# endif
# ifdef CONFIG_SECURE_BOOT_V1_ENABLED
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/* Steps 1 & 2 (see above for full description):
* 1 ) Generate secure boot EFUSE key
* 2 ) Compute digest of plaintext bootloader
*/
err = esp_secure_boot_generate_digest ( ) ;
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if ( err ! = ESP_OK ) {
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ESP_LOGE ( TAG , " Bootloader digest generation for secure boot failed (%d). " , err ) ;
return ;
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}
# endif
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# ifdef CONFIG_SECURE_FLASH_ENC_ENABLED
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/* Steps 3, 4 & 5 (see above for full description):
* 3 ) Generate flash encryption EFUSE key
* 4 ) Encrypt flash contents
* 5 ) Burn EFUSE to enable flash encryption
*/
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ESP_LOGI ( TAG , " Checking flash encryption... " ) ;
bool flash_encryption_enabled = esp_flash_encryption_enabled ( ) ;
err = esp_flash_encrypt_check_and_update ( ) ;
if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " Flash encryption check failed (%d). " , err ) ;
return ;
}
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# endif
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# ifdef CONFIG_SECURE_BOOT_V1_ENABLED
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/* Step 6 (see above for full description):
* 6 ) Burn EFUSE to enable secure boot
*/
ESP_LOGI ( TAG , " Checking secure boot... " ) ;
err = esp_secure_boot_permanently_enable ( ) ;
if ( err ! = ESP_OK ) {
ESP_LOGE ( TAG , " FAILED TO ENABLE SECURE BOOT (%d). " , err ) ;
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/* Panic here as secure boot is not properly enabled
due to one of the reasons in above function
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*/
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abort ( ) ;
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}
# endif
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# ifdef CONFIG_SECURE_FLASH_ENC_ENABLED
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if ( ! flash_encryption_enabled & & esp_flash_encryption_enabled ( ) ) {
/* Flash encryption was just enabled for the first time,
so issue a system reset to ensure flash encryption
cache resets properly */
ESP_LOGI ( TAG , " Resetting with flash encryption enabled... " ) ;
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esp_rom_uart_tx_wait_idle ( 0 ) ;
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bootloader_reset ( ) ;
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}
# endif
ESP_LOGI ( TAG , " Disabling RNG early entropy source... " ) ;
bootloader_random_disable ( ) ;
// copy loaded segments to RAM, set up caches for mapped segments, and start application
unpack_load_app ( image_data ) ;
}
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static void unpack_load_app ( const esp_image_metadata_t * data )
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{
uint32_t drom_addr = 0 ;
uint32_t drom_load_addr = 0 ;
uint32_t drom_size = 0 ;
uint32_t irom_addr = 0 ;
uint32_t irom_load_addr = 0 ;
uint32_t irom_size = 0 ;
// Find DROM & IROM addresses, to configure cache mappings
for ( int i = 0 ; i < data - > image . segment_count ; i + + ) {
const esp_image_segment_header_t * header = & data - > segments [ i ] ;
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if ( header - > load_addr > = SOC_DROM_LOW & & header - > load_addr < SOC_DROM_HIGH ) {
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if ( drom_addr ! = 0 ) {
ESP_LOGE ( TAG , MAP_ERR_MSG , " DROM " ) ;
} else {
ESP_LOGD ( TAG , " Mapping segment %d as %s " , i , " DROM " ) ;
}
drom_addr = data - > segment_data [ i ] ;
drom_load_addr = header - > load_addr ;
drom_size = header - > data_len ;
}
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if ( header - > load_addr > = SOC_IROM_LOW & & header - > load_addr < SOC_IROM_HIGH ) {
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if ( irom_addr ! = 0 ) {
ESP_LOGE ( TAG , MAP_ERR_MSG , " IROM " ) ;
} else {
ESP_LOGD ( TAG , " Mapping segment %d as %s " , i , " IROM " ) ;
}
irom_addr = data - > segment_data [ i ] ;
irom_load_addr = header - > load_addr ;
irom_size = header - > data_len ;
}
}
ESP_LOGD ( TAG , " calling set_cache_and_start_app " ) ;
set_cache_and_start_app ( drom_addr ,
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drom_load_addr ,
drom_size ,
irom_addr ,
irom_load_addr ,
irom_size ,
data - > image . entry_addr ) ;
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}
static void set_cache_and_start_app (
uint32_t drom_addr ,
uint32_t drom_load_addr ,
uint32_t drom_size ,
uint32_t irom_addr ,
uint32_t irom_load_addr ,
uint32_t irom_size ,
uint32_t entry_addr )
{
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int rc ;
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ESP_LOGD ( TAG , " configure drom and irom and start " ) ;
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# if CONFIG_IDF_TARGET_ESP32
Cache_Read_Disable ( 0 ) ;
Cache_Flush ( 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S2
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uint32_t autoload = Cache_Suspend_ICache ( ) ;
Cache_Invalidate_ICache_All ( ) ;
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# elif CONFIG_IDF_TARGET_ESP32S3
uint32_t autoload = Cache_Suspend_DCache ( ) ;
Cache_Invalidate_DCache_All ( ) ;
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# elif CONFIG_IDF_TARGET_ESP32C3
uint32_t autoload = Cache_Suspend_ICache ( ) ;
Cache_Invalidate_ICache_All ( ) ;
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# elif CONFIG_IDF_TARGET_ESP32H2
uint32_t autoload = Cache_Suspend_ICache ( ) ;
Cache_Invalidate_ICache_All ( ) ;
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# endif
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/* Clear the MMU entries that are already set up,
so the new app only has the mappings it creates .
*/
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# if CONFIG_IDF_TARGET_ESP32
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for ( int i = 0 ; i < DPORT_FLASH_MMU_TABLE_SIZE ; i + + ) {
DPORT_PRO_FLASH_MMU_TABLE [ i ] = DPORT_FLASH_MMU_TABLE_INVALID_VAL ;
}
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# else
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for ( size_t i = 0 ; i < FLASH_MMU_TABLE_SIZE ; i + + ) {
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FLASH_MMU_TABLE [ i ] = MMU_TABLE_INVALID_VAL ;
}
# endif
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uint32_t drom_load_addr_aligned = drom_load_addr & MMU_FLASH_MASK ;
uint32_t drom_page_count = bootloader_cache_pages_to_map ( drom_size , drom_load_addr ) ;
ESP_LOGV ( TAG , " d mmu set paddr=%08x vaddr=%08x size=%d n=%d " ,
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drom_addr & MMU_FLASH_MASK , drom_load_addr_aligned , drom_size , drom_page_count ) ;
# if CONFIG_IDF_TARGET_ESP32
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rc = cache_flash_mmu_set ( 0 , 0 , drom_load_addr_aligned , drom_addr & MMU_FLASH_MASK , 64 , drom_page_count ) ;
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# elif CONFIG_IDF_TARGET_ESP32S2
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rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , drom_load_addr & 0xffff0000 , drom_addr & 0xffff0000 , 64 , drom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S3
rc = Cache_Dbus_MMU_Set ( MMU_ACCESS_FLASH , drom_load_addr & 0xffff0000 , drom_addr & 0xffff0000 , 64 , drom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32C3
rc = Cache_Dbus_MMU_Set ( MMU_ACCESS_FLASH , drom_load_addr & 0xffff0000 , drom_addr & 0xffff0000 , 64 , drom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32H2
rc = Cache_Dbus_MMU_Set ( MMU_ACCESS_FLASH , drom_load_addr & 0xffff0000 , drom_addr & 0xffff0000 , 64 , drom_page_count , 0 ) ;
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# endif
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ESP_LOGV ( TAG , " rc=%d " , rc ) ;
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# if CONFIG_IDF_TARGET_ESP32
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rc = cache_flash_mmu_set ( 1 , 0 , drom_load_addr_aligned , drom_addr & MMU_FLASH_MASK , 64 , drom_page_count ) ;
ESP_LOGV ( TAG , " rc=%d " , rc ) ;
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# endif
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uint32_t irom_load_addr_aligned = irom_load_addr & MMU_FLASH_MASK ;
uint32_t irom_page_count = bootloader_cache_pages_to_map ( irom_size , irom_load_addr ) ;
ESP_LOGV ( TAG , " i mmu set paddr=%08x vaddr=%08x size=%d n=%d " ,
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irom_addr & MMU_FLASH_MASK , irom_load_addr_aligned , irom_size , irom_page_count ) ;
# if CONFIG_IDF_TARGET_ESP32
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rc = cache_flash_mmu_set ( 0 , 0 , irom_load_addr_aligned , irom_addr & MMU_FLASH_MASK , 64 , irom_page_count ) ;
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# elif CONFIG_IDF_TARGET_ESP32S2
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uint32_t iram1_used = 0 ;
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if ( irom_load_addr + irom_size > IRAM1_ADDRESS_LOW ) {
iram1_used = 1 ;
}
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if ( iram1_used ) {
rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , IRAM0_ADDRESS_LOW , 0 , 64 , 64 , 1 ) ;
rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , IRAM1_ADDRESS_LOW , 0 , 64 , 64 , 1 ) ;
REG_CLR_BIT ( EXTMEM_PRO_ICACHE_CTRL1_REG , EXTMEM_PRO_ICACHE_MASK_IRAM1 ) ;
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}
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rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , irom_load_addr & 0xffff0000 , irom_addr & 0xffff0000 , 64 , irom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S3
rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , irom_load_addr & 0xffff0000 , irom_addr & 0xffff0000 , 64 , irom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32C3
rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , irom_load_addr & 0xffff0000 , irom_addr & 0xffff0000 , 64 , irom_page_count , 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32H2
rc = Cache_Ibus_MMU_Set ( MMU_ACCESS_FLASH , irom_load_addr & 0xffff0000 , irom_addr & 0xffff0000 , 64 , irom_page_count , 0 ) ;
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# endif
ESP_LOGV ( TAG , " rc=%d " , rc ) ;
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# if CONFIG_IDF_TARGET_ESP32
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rc = cache_flash_mmu_set ( 1 , 0 , irom_load_addr_aligned , irom_addr & MMU_FLASH_MASK , 64 , irom_page_count ) ;
ESP_LOGV ( TAG , " rc=%d " , rc ) ;
DPORT_REG_CLR_BIT ( DPORT_PRO_CACHE_CTRL1_REG ,
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( DPORT_PRO_CACHE_MASK_IRAM0 ) | ( DPORT_PRO_CACHE_MASK_IRAM1 & 0 ) |
( DPORT_PRO_CACHE_MASK_IROM0 & 0 ) | DPORT_PRO_CACHE_MASK_DROM0 |
DPORT_PRO_CACHE_MASK_DRAM1 ) ;
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DPORT_REG_CLR_BIT ( DPORT_APP_CACHE_CTRL1_REG ,
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( DPORT_APP_CACHE_MASK_IRAM0 ) | ( DPORT_APP_CACHE_MASK_IRAM1 & 0 ) |
( DPORT_APP_CACHE_MASK_IROM0 & 0 ) | DPORT_APP_CACHE_MASK_DROM0 |
DPORT_APP_CACHE_MASK_DRAM1 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S2
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REG_CLR_BIT ( EXTMEM_PRO_ICACHE_CTRL1_REG , ( EXTMEM_PRO_ICACHE_MASK_IRAM0 ) | ( EXTMEM_PRO_ICACHE_MASK_IRAM1 & 0 ) | EXTMEM_PRO_ICACHE_MASK_DROM0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S3
REG_CLR_BIT ( EXTMEM_DCACHE_CTRL1_REG , EXTMEM_DCACHE_SHUT_CORE0_BUS ) ;
# if !CONFIG_FREERTOS_UNICORE
REG_CLR_BIT ( EXTMEM_DCACHE_CTRL1_REG , EXTMEM_DCACHE_SHUT_CORE1_BUS ) ;
# endif
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# elif CONFIG_IDF_TARGET_ESP32C3
REG_CLR_BIT ( EXTMEM_ICACHE_CTRL1_REG , EXTMEM_ICACHE_SHUT_IBUS ) ;
REG_CLR_BIT ( EXTMEM_ICACHE_CTRL1_REG , EXTMEM_ICACHE_SHUT_DBUS ) ;
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# elif CONFIG_IDF_TARGET_ESP32H2
REG_CLR_BIT ( EXTMEM_ICACHE_CTRL1_REG , EXTMEM_ICACHE_SHUT_IBUS ) ;
REG_CLR_BIT ( EXTMEM_ICACHE_CTRL1_REG , EXTMEM_ICACHE_SHUT_DBUS ) ;
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# endif
# if CONFIG_IDF_TARGET_ESP32
Cache_Read_Enable ( 0 ) ;
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# elif CONFIG_IDF_TARGET_ESP32S2
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Cache_Resume_ICache ( autoload ) ;
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# elif CONFIG_IDF_TARGET_ESP32S3
Cache_Resume_DCache ( autoload ) ;
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# elif CONFIG_IDF_TARGET_ESP32C3
Cache_Resume_ICache ( autoload ) ;
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# elif CONFIG_IDF_TARGET_ESP32H2
Cache_Resume_ICache ( autoload ) ;
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# endif
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// Application will need to do Cache_Flush(1) and Cache_Read_Enable(1)
ESP_LOGD ( TAG , " start: 0x%08x " , entry_addr ) ;
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bootloader_atexit ( ) ;
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typedef void ( * entry_t ) ( void ) __attribute__ ( ( noreturn ) ) ;
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entry_t entry = ( ( entry_t ) entry_addr ) ;
// TODO: we have used quite a bit of stack at this point.
// use "movsp" instruction to reset stack back to where ROM stack starts.
( * entry ) ( ) ;
}
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void bootloader_reset ( void )
{
# ifdef BOOTLOADER_BUILD
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bootloader_atexit ( ) ;
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esp_rom_delay_us ( 1000 ) ; /* Allow last byte to leave FIFO */
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REG_WRITE ( RTC_CNTL_OPTIONS0_REG , RTC_CNTL_SW_SYS_RST ) ;
while ( 1 ) { } /* This line will never be reached, used to keep gcc happy */
# else
abort ( ) ; /* This function should really not be called from application code */
# endif
}
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void bootloader_atexit ( void )
{
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# ifdef BOOTLOADER_BUILD
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bootloader_console_deinit ( ) ;
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# else
abort ( ) ;
# endif
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}
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esp_err_t bootloader_sha256_hex_to_str ( char * out_str , const uint8_t * in_array_hex , size_t len )
{
if ( out_str = = NULL | | in_array_hex = = NULL | | len = = 0 ) {
return ESP_ERR_INVALID_ARG ;
}
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for ( size_t i = 0 ; i < len ; i + + ) {
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for ( int shift = 0 ; shift < 2 ; shift + + ) {
uint8_t nibble = ( in_array_hex [ i ] > > ( shift ? 0 : 4 ) ) & 0x0F ;
if ( nibble < 10 ) {
out_str [ i * 2 + shift ] = ' 0 ' + nibble ;
} else {
out_str [ i * 2 + shift ] = ' a ' + nibble - 10 ;
}
}
}
return ESP_OK ;
}
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void bootloader_debug_buffer ( const void * buffer , size_t length , const char * label )
{
# if BOOT_LOG_LEVEL >= LOG_LEVEL_DEBUG
assert ( length < = 128 ) ; // Avoid unbounded VLA size
const uint8_t * bytes = ( const uint8_t * ) buffer ;
char hexbuf [ length * 2 + 1 ] ;
hexbuf [ length * 2 ] = 0 ;
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for ( size_t i = 0 ; i < length ; i + + ) {
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for ( int shift = 0 ; shift < 2 ; shift + + ) {
uint8_t nibble = ( bytes [ i ] > > ( shift ? 0 : 4 ) ) & 0x0F ;
if ( nibble < 10 ) {
hexbuf [ i * 2 + shift ] = ' 0 ' + nibble ;
} else {
hexbuf [ i * 2 + shift ] = ' a ' + nibble - 10 ;
}
}
}
ESP_LOGD ( TAG , " %s: %s " , label , hexbuf ) ;
# endif
}
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esp_err_t bootloader_sha256_flash_contents ( uint32_t flash_offset , uint32_t len , uint8_t * digest )
{
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if ( digest = = NULL ) {
return ESP_ERR_INVALID_ARG ;
}
/* Handling firmware images larger than MMU capacity */
uint32_t mmu_free_pages_count = bootloader_mmap_get_free_pages ( ) ;
bootloader_sha256_handle_t sha_handle = NULL ;
sha_handle = bootloader_sha256_start ( ) ;
if ( sha_handle = = NULL ) {
return ESP_ERR_NO_MEM ;
}
while ( len > 0 ) {
uint32_t mmu_page_offset = ( ( flash_offset & MMAP_ALIGNED_MASK ) ! = 0 ) ? 1 : 0 ; /* Skip 1st MMU Page if it is already populated */
uint32_t partial_image_len = MIN ( len , ( ( mmu_free_pages_count - mmu_page_offset ) * SPI_FLASH_MMU_PAGE_SIZE ) ) ; /* Read the image that fits in the free MMU pages */
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const void * image = bootloader_mmap ( flash_offset , partial_image_len ) ;
if ( image = = NULL ) {
bootloader_sha256_finish ( sha_handle , NULL ) ;
return ESP_FAIL ;
}
bootloader_sha256_data ( sha_handle , image , partial_image_len ) ;
bootloader_munmap ( image ) ;
flash_offset + = partial_image_len ;
len - = partial_image_len ;
}
bootloader_sha256_finish ( sha_handle , digest ) ;
return ESP_OK ;
}