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/*
* SPDX - FileCopyrightText : 2022 - 2023 Espressif Systems ( Shanghai ) CO LTD
*
* SPDX - License - Identifier : Apache - 2.0
*/
# include <stddef.h>
# include <string.h>
# include "sdkconfig.h"
# include "soc/soc_caps.h"
# include "esp_sleep.h"
# include "esp_log.h"
# include "esp_check.h"
# include "esp_private/startup_internal.h"
# include "esp_private/sleep_retention.h"
# include "esp_regdma.h"
# include "soc/uart_reg.h"
# include "soc/systimer_reg.h"
# include "soc/timer_group_reg.h"
# include "soc/spi_mem_reg.h"
# include "soc/hp_system_reg.h"
# include "soc/tee_reg.h"
# include "soc/hp_apm_reg.h"
# include "soc/gpio_reg.h"
# include "soc/io_mux_reg.h"
# include "soc/interrupt_matrix_reg.h"
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static __attribute__ ( ( unused ) ) const char * TAG = " sleep_sys_periph " ;
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# define SLEEP_RETENTION_PERIPHERALS_PRIORITY_DEFAULT (REGDMA_LINK_PRI_6)
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esp_err_t sleep_sys_periph_intr_matrix_retention_init ( void )
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{
# define N_REGS_INTR_MATRIX() (((INTMTX_CORE0_CLOCK_GATE_REG - DR_REG_INTERRUPT_MATRIX_BASE) / 4) + 1)
const static sleep_retention_entries_config_t intr_matrix_regs_retention [ ] = {
[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_INTMTX_LINK ( 0 ) , DR_REG_INTERRUPT_MATRIX_BASE , DR_REG_INTERRUPT_MATRIX_BASE , N_REGS_INTR_MATRIX ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } /* intr matrix */
} ;
esp_err_t err = sleep_retention_entries_create ( intr_matrix_regs_retention , ARRAY_SIZE ( intr_matrix_regs_retention ) , REGDMA_LINK_PRI_5 , SLEEP_RETENTION_MODULE_INTR_MATRIX ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (Interrupt matrix) retention " ) ;
ESP_LOGI ( TAG , " Interrupt Matrix sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_hp_system_retention_init ( void )
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{
# define N_REGS_HP_SYSTEM() (((HP_SYSTEM_MEM_TEST_CONF_REG - DR_REG_HP_SYSTEM_BASE) / 4) + 1)
const static sleep_retention_entries_config_t hp_system_regs_retention [ ] = {
[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_HPSYS_LINK ( 0 ) , DR_REG_HP_SYSTEM_BASE , DR_REG_HP_SYSTEM_BASE , N_REGS_HP_SYSTEM ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } /* hp system */
} ;
esp_err_t err = sleep_retention_entries_create ( hp_system_regs_retention , ARRAY_SIZE ( hp_system_regs_retention ) , REGDMA_LINK_PRI_5 , SLEEP_RETENTION_MODULE_HP_SYSTEM ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (HP system) retention " ) ;
ESP_LOGI ( TAG , " HP System sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_tee_apm_retention_init ( void )
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{
# define N_REGS_TEE() (((TEE_CLOCK_GATE_REG - DR_REG_TEE_BASE) / 4) + 1)
# define N_REGS_APM() (((HP_APM_CLOCK_GATE_REG - DR_REG_HP_APM_BASE) / 4) + 1)
const static sleep_retention_entries_config_t tee_apm_regs_retention [ ] = {
[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_TEEAPM_LINK ( 0 ) , DR_REG_TEE_BASE , DR_REG_TEE_BASE , N_REGS_TEE ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* tee */
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[ 1 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_TEEAPM_LINK ( 1 ) , DR_REG_HP_APM_BASE , DR_REG_HP_APM_BASE , N_REGS_APM ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } /* apm */
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} ;
esp_err_t err = sleep_retention_entries_create ( tee_apm_regs_retention , ARRAY_SIZE ( tee_apm_regs_retention ) , REGDMA_LINK_PRI_4 , SLEEP_RETENTION_MODULE_TEE_APM ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (TEE/APM) retention " ) ;
ESP_LOGI ( TAG , " TEE/APM sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_uart0_retention_init ( void )
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{
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# define N_REGS_UART() (((UART_ID_REG(0) - UART_INT_RAW_REG(0)) / 4) + 1)
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const static sleep_retention_entries_config_t uart_regs_retention [ ] = {
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[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_UART_LINK ( 0x00 ) , UART_INT_RAW_REG ( 0 ) , UART_INT_RAW_REG ( 0 ) , N_REGS_UART ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* uart */
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/* Note: uart register should set update reg to make the configuration take effect */
[ 1 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_UART_LINK ( 0x01 ) , UART_REG_UPDATE_REG ( 0 ) , UART_REG_UPDATE , UART_REG_UPDATE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 2 ] = { . config = REGDMA_LINK_WAIT_INIT ( REGDMA_UART_LINK ( 0x02 ) , UART_REG_UPDATE_REG ( 0 ) , 0x0 , UART_REG_UPDATE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) }
} ;
esp_err_t err = sleep_retention_entries_create ( uart_regs_retention , ARRAY_SIZE ( uart_regs_retention ) , REGDMA_LINK_PRI_5 , SLEEP_RETENTION_MODULE_UART0 ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (UART) retention " ) ;
ESP_LOGI ( TAG , " UART sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_tg0_retention_init ( void )
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{
# define N_REGS_TG() (((TIMG_REGCLK_REG(0) - REG_TIMG_BASE(0)) / 4) + 1)
const static sleep_retention_entries_config_t tg_regs_retention [ ] = {
/*Timer group0 backup. T0_wdt should get of write project firstly. wdt used by RTOS.*/
[ 0 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_TIMG_LINK ( 0x00 ) , TIMG_WDTWPROTECT_REG ( 0 ) , TIMG_WDT_WKEY_VALUE , TIMG_WDT_WKEY_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* TG0 */
[ 1 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_TIMG_LINK ( 0x01 ) , REG_TIMG_BASE ( 0 ) , REG_TIMG_BASE ( 0 ) , N_REGS_TG ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 2 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_TIMG_LINK ( 0x02 ) , TIMG_WDTWPROTECT_REG ( 0 ) , TIMG_WDT_WKEY_VALUE , TIMG_WDT_WKEY_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 3 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_TIMG_LINK ( 0x03 ) , TIMG_WDTCONFIG0_REG ( 0 ) , TIMG_WDT_CONF_UPDATE_EN , TIMG_WDT_CONF_UPDATE_EN_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 4 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_TIMG_LINK ( 0x04 ) , TIMG_T0UPDATE_REG ( 0 ) , TIMG_T0_UPDATE , TIMG_T0_UPDATE_M , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 5 ] = { . config = REGDMA_LINK_WAIT_INIT ( REGDMA_TIMG_LINK ( 0x05 ) , TIMG_T0UPDATE_REG ( 0 ) , 0x0 , TIMG_T0_UPDATE_M , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 6 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_TIMG_LINK ( 0x06 ) , TIMG_T0LO_REG ( 0 ) , TIMG_T0LOADLO_REG ( 0 ) , 2 , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 7 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_TIMG_LINK ( 0x07 ) , TIMG_T0LOAD_REG ( 0 ) , 0x1 , TIMG_T0_LOAD_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) }
} ;
esp_err_t err = sleep_retention_entries_create ( tg_regs_retention , ARRAY_SIZE ( tg_regs_retention ) , SLEEP_RETENTION_PERIPHERALS_PRIORITY_DEFAULT , SLEEP_RETENTION_MODULE_TG0 ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (Timer Group) retention " ) ;
ESP_LOGI ( TAG , " Timer Group sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_iomux_retention_init ( void )
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{
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# if CONFIG_IDF_TARGET_ESP32C6
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# define N_REGS_IOMUX_0() (((PERIPHS_IO_MUX_SPID_U - REG_IO_MUX_BASE) / 4) + 1)
# define N_REGS_IOMUX_1() (((GPIO_FUNC34_OUT_SEL_CFG_REG - GPIO_FUNC0_OUT_SEL_CFG_REG) / 4) + 1)
# define N_REGS_IOMUX_2() (((GPIO_FUNC124_IN_SEL_CFG_REG - GPIO_STATUS_NEXT_REG) / 4) + 1)
# define N_REGS_IOMUX_3() (((GPIO_PIN34_REG - DR_REG_GPIO_BASE) / 4) + 1)
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# elif CONFIG_IDF_TARGET_ESP32H2
# define N_REGS_IOMUX_0() (((PERIPHS_IO_MUX_SPID_U - REG_IO_MUX_BASE) / 4) + 1)
# define N_REGS_IOMUX_1() (((GPIO_FUNC31_OUT_SEL_CFG_REG - GPIO_FUNC0_OUT_SEL_CFG_REG) / 4) + 1)
# define N_REGS_IOMUX_2() (((GPIO_FUNC124_IN_SEL_CFG_REG - GPIO_STATUS_NEXT_REG) / 4) + 1)
# define N_REGS_IOMUX_3() (((GPIO_PIN31_REG - DR_REG_GPIO_BASE) / 4) + 1)
# endif
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const static sleep_retention_entries_config_t iomux_regs_retention [ ] = {
[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_IOMUX_LINK ( 0x00 ) , REG_IO_MUX_BASE , REG_IO_MUX_BASE , N_REGS_IOMUX_0 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* io_mux */
[ 1 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_IOMUX_LINK ( 0x01 ) , GPIO_FUNC0_OUT_SEL_CFG_REG , GPIO_FUNC0_OUT_SEL_CFG_REG , N_REGS_IOMUX_1 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 2 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_IOMUX_LINK ( 0x02 ) , GPIO_STATUS_NEXT_REG , GPIO_STATUS_NEXT_REG , N_REGS_IOMUX_2 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 3 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_IOMUX_LINK ( 0x03 ) , DR_REG_GPIO_BASE , DR_REG_GPIO_BASE , N_REGS_IOMUX_3 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) }
} ;
esp_err_t err = sleep_retention_entries_create ( iomux_regs_retention , ARRAY_SIZE ( iomux_regs_retention ) , SLEEP_RETENTION_PERIPHERALS_PRIORITY_DEFAULT , SLEEP_RETENTION_MODULE_IOMUX ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (IO Matrix) retention " ) ;
ESP_LOGI ( TAG , " IO Matrix sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_spimem_retention_init ( void )
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{
# define N_REGS_SPI1_MEM_0() (((SPI_MEM_SPI_SMEM_DDR_REG(1) - REG_SPI_MEM_BASE(1)) / 4) + 1)
# define N_REGS_SPI1_MEM_1() (((SPI_MEM_SPI_SMEM_AC_REG(1) - SPI_MEM_SPI_FMEM_PMS0_ATTR_REG(1)) / 4) + 1)
# define N_REGS_SPI1_MEM_2() (1)
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# define N_REGS_SPI1_MEM_3() (((SPI_MEM_DATE_REG(1) - SPI_MEM_MMU_POWER_CTRL_REG(1)) / 4) + 1)
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# define N_REGS_SPI0_MEM_0() (((SPI_MEM_SPI_SMEM_DDR_REG(0) - REG_SPI_MEM_BASE(0)) / 4) + 1)
# define N_REGS_SPI0_MEM_1() (((SPI_MEM_SPI_SMEM_AC_REG(0) - SPI_MEM_SPI_FMEM_PMS0_ATTR_REG(0)) / 4) + 1)
# define N_REGS_SPI0_MEM_2() (1)
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# define N_REGS_SPI0_MEM_3() (((SPI_MEM_DATE_REG(0) - SPI_MEM_MMU_POWER_CTRL_REG(0)) / 4) + 1)
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const static sleep_retention_entries_config_t spimem_regs_retention [ ] = {
/* Note: SPI mem should not to write mmu SPI_MEM_MMU_ITEM_CONTENT_REG and SPI_MEM_MMU_ITEM_INDEX_REG */
[ 0 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x00 ) , REG_SPI_MEM_BASE ( 1 ) , REG_SPI_MEM_BASE ( 1 ) , N_REGS_SPI1_MEM_0 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* spi1_mem */
[ 1 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x01 ) , SPI_MEM_SPI_FMEM_PMS0_ATTR_REG ( 1 ) , SPI_MEM_SPI_FMEM_PMS0_ATTR_REG ( 1 ) , N_REGS_SPI1_MEM_1 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 2 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x02 ) , SPI_MEM_CLOCK_GATE_REG ( 1 ) , SPI_MEM_CLOCK_GATE_REG ( 1 ) , N_REGS_SPI1_MEM_2 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
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[ 3 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x03 ) , SPI_MEM_MMU_POWER_CTRL_REG ( 1 ) , SPI_MEM_MMU_POWER_CTRL_REG ( 1 ) , N_REGS_SPI1_MEM_3 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
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/* Note: SPI mem should not to write mmu SPI_MEM_MMU_ITEM_CONTENT_REG and SPI_MEM_MMU_ITEM_INDEX_REG */
[ 4 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x04 ) , REG_SPI_MEM_BASE ( 0 ) , REG_SPI_MEM_BASE ( 0 ) , N_REGS_SPI0_MEM_0 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* spi0_mem */
[ 5 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x05 ) , SPI_MEM_SPI_FMEM_PMS0_ATTR_REG ( 0 ) , SPI_MEM_SPI_FMEM_PMS0_ATTR_REG ( 0 ) , N_REGS_SPI0_MEM_1 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 6 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x06 ) , SPI_MEM_CLOCK_GATE_REG ( 0 ) , SPI_MEM_CLOCK_GATE_REG ( 0 ) , N_REGS_SPI0_MEM_2 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
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[ 7 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SPIMEM_LINK ( 0x07 ) , SPI_MEM_MMU_POWER_CTRL_REG ( 0 ) , SPI_MEM_MMU_POWER_CTRL_REG ( 0 ) , N_REGS_SPI0_MEM_3 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) }
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} ;
esp_err_t err = sleep_retention_entries_create ( spimem_regs_retention , ARRAY_SIZE ( spimem_regs_retention ) , SLEEP_RETENTION_PERIPHERALS_PRIORITY_DEFAULT , SLEEP_RETENTION_MODULE_SPIMEM ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (SPI mem) retention " ) ;
ESP_LOGI ( TAG , " SPI Mem sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_systimer_retention_init ( void )
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{
# define N_REGS_SYSTIMER_0() (((SYSTIMER_TARGET2_CONF_REG - SYSTIMER_TARGET0_HI_REG) / 4) + 1)
const static sleep_retention_entries_config_t systimer_regs_retention [ ] = {
[ 0 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x00 ) , SYSTIMER_UNIT0_OP_REG , SYSTIMER_TIMER_UNIT0_UPDATE_M , SYSTIMER_TIMER_UNIT0_UPDATE_M , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* Systimer */
[ 1 ] = { . config = REGDMA_LINK_WAIT_INIT ( REGDMA_SYSTIMER_LINK ( 0x01 ) , SYSTIMER_UNIT0_OP_REG , SYSTIMER_TIMER_UNIT0_VALUE_VALID , SYSTIMER_TIMER_UNIT0_VALUE_VALID , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 2 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SYSTIMER_LINK ( 0x02 ) , SYSTIMER_UNIT0_VALUE_HI_REG , SYSTIMER_UNIT0_LOAD_HI_REG , 2 , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 3 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x03 ) , SYSTIMER_UNIT0_LOAD_REG , SYSTIMER_TIMER_UNIT0_LOAD_M , SYSTIMER_TIMER_UNIT0_LOAD_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 4 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x04 ) , SYSTIMER_UNIT1_OP_REG , SYSTIMER_TIMER_UNIT1_UPDATE_M , SYSTIMER_TIMER_UNIT1_UPDATE_M , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 5 ] = { . config = REGDMA_LINK_WAIT_INIT ( REGDMA_SYSTIMER_LINK ( 0x05 ) , SYSTIMER_UNIT1_OP_REG , SYSTIMER_TIMER_UNIT1_VALUE_VALID , SYSTIMER_TIMER_UNIT1_VALUE_VALID , 0 , 1 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 6 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SYSTIMER_LINK ( 0x06 ) , SYSTIMER_UNIT1_VALUE_HI_REG , SYSTIMER_UNIT1_LOAD_HI_REG , 2 , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 7 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x07 ) , SYSTIMER_UNIT1_LOAD_REG , SYSTIMER_TIMER_UNIT1_LOAD_M , SYSTIMER_TIMER_UNIT1_LOAD_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 8 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SYSTIMER_LINK ( 0x08 ) , SYSTIMER_TARGET0_HI_REG , SYSTIMER_TARGET0_HI_REG , N_REGS_SYSTIMER_0 ( ) , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* Systimer target value & period */
[ 9 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x09 ) , SYSTIMER_COMP0_LOAD_REG , SYSTIMER_TIMER_COMP0_LOAD , SYSTIMER_TIMER_COMP0_LOAD , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 10 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0a ) , SYSTIMER_COMP1_LOAD_REG , SYSTIMER_TIMER_COMP1_LOAD , SYSTIMER_TIMER_COMP1_LOAD , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 11 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0b ) , SYSTIMER_COMP2_LOAD_REG , SYSTIMER_TIMER_COMP2_LOAD , SYSTIMER_TIMER_COMP2_LOAD , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 12 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0c ) , SYSTIMER_TARGET0_CONF_REG , 0 , SYSTIMER_TARGET0_PERIOD_MODE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 13 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0d ) , SYSTIMER_TARGET0_CONF_REG , SYSTIMER_TARGET0_PERIOD_MODE_M , SYSTIMER_TARGET0_PERIOD_MODE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 14 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0e ) , SYSTIMER_TARGET1_CONF_REG , 0 , SYSTIMER_TARGET1_PERIOD_MODE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 15 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x0f ) , SYSTIMER_TARGET1_CONF_REG , SYSTIMER_TARGET1_PERIOD_MODE_M , SYSTIMER_TARGET1_PERIOD_MODE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 16 ] = { . config = REGDMA_LINK_WRITE_INIT ( REGDMA_SYSTIMER_LINK ( 0x10 ) , SYSTIMER_TARGET2_CONF_REG , 0 , SYSTIMER_TARGET2_PERIOD_MODE_M , 1 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } ,
[ 17 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SYSTIMER_LINK ( 0x11 ) , SYSTIMER_CONF_REG , SYSTIMER_CONF_REG , 1 , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } , /* Systimer work enable */
[ 18 ] = { . config = REGDMA_LINK_CONTINUOUS_INIT ( REGDMA_SYSTIMER_LINK ( 0x12 ) , SYSTIMER_INT_ENA_REG , SYSTIMER_INT_ENA_REG , 1 , 0 , 0 ) , . owner = ENTRY ( 0 ) | ENTRY ( 2 ) } /* Systimer intr enable */
} ;
esp_err_t err = sleep_retention_entries_create ( systimer_regs_retention , ARRAY_SIZE ( systimer_regs_retention ) , SLEEP_RETENTION_PERIPHERALS_PRIORITY_DEFAULT , SLEEP_RETENTION_MODULE_SYSTIMER ) ;
ESP_RETURN_ON_ERROR ( err , TAG , " failed to allocate memory for digital peripherals (SysTimer) retention " ) ;
ESP_LOGI ( TAG , " SysTimer sleep retention initialization " ) ;
return ESP_OK ;
}
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esp_err_t sleep_sys_periph_retention_init ( void )
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{
esp_err_t err ;
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err = sleep_sys_periph_intr_matrix_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_hp_system_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_tee_apm_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_uart0_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_tg0_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_iomux_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_spimem_retention_init ( ) ;
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if ( err ) goto error ;
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err = sleep_sys_periph_systimer_retention_init ( ) ;
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error :
return err ;
}
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bool peripheral_domain_pd_allowed ( void )
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{
const uint32_t modules = sleep_retention_get_modules ( ) ;
const uint32_t mask = ( const uint32_t ) (
SLEEP_RETENTION_MODULE_INTR_MATRIX | \
SLEEP_RETENTION_MODULE_HP_SYSTEM | \
SLEEP_RETENTION_MODULE_TEE_APM | \
SLEEP_RETENTION_MODULE_UART0 | \
SLEEP_RETENTION_MODULE_TG0 | \
SLEEP_RETENTION_MODULE_IOMUX | \
SLEEP_RETENTION_MODULE_SPIMEM | \
SLEEP_RETENTION_MODULE_SYSTIMER ) ;
return ( ( modules & mask ) = = mask ) ;
}
# if CONFIG_PM_POWER_DOWN_PERIPHERAL_IN_LIGHT_SLEEP
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ESP_SYSTEM_INIT_FN ( sleep_sys_periph_startup_init , BIT ( 0 ) , 107 )
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{
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sleep_sys_periph_retention_init ( ) ;
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return ESP_OK ;
}
# endif