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/*
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* SPDX - FileCopyrightText : 2015 - 2023 Espressif Systems ( Shanghai ) CO LTD
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*
* SPDX - License - Identifier : Apache - 2.0
*/
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# include <string.h>
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# include "esp_types.h"
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# include "freertos/FreeRTOS.h"
# include "freertos/semphr.h"
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# include "esp_log.h"
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# include "esp_check.h"
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# include "soc/gpio_periph.h"
# include "soc/ledc_periph.h"
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# include "esp_clk_tree.h"
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# include "soc/soc_caps.h"
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# include "hal/ledc_hal.h"
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# include "hal/gpio_hal.h"
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# include "driver/ledc.h"
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# include "esp_rom_gpio.h"
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# include "esp_rom_sys.h"
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# include "clk_ctrl_os.h"
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# include "esp_private/periph_ctrl.h"
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# include "esp_memory_utils.h"
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static __attribute__ ( ( unused ) ) const char * LEDC_TAG = " ledc " ;
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# define LEDC_CHECK(a, str, ret_val) ESP_RETURN_ON_FALSE(a, ret_val, LEDC_TAG, "%s", str)
# define LEDC_ARG_CHECK(a, param) ESP_RETURN_ON_FALSE(a, ESP_ERR_INVALID_ARG, LEDC_TAG, param " argument is invalid")
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# define LEDC_CHECK_ISR(a, str, ret_val) ESP_RETURN_ON_FALSE_ISR(a, ret_val, LEDC_TAG, "%s", str)
# define LEDC_ARG_CHECK_ISR(a, param) ESP_RETURN_ON_FALSE_ISR(a, ESP_ERR_INVALID_ARG, LEDC_TAG, param " argument is invalid")
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# define LEDC_CLK_NOT_FOUND 0
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# define LEDC_SLOW_CLK_UNINIT -1
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# define LEDC_TIMER_SPECIFIC_CLK_UNINIT -1
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// Precision degree only affects RC_FAST, other clock sources' frequences are fixed values
// For targets that do not support RC_FAST calibration, can only use its approx. value. Precision degree other than
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// APPROX will trigger LOGW during the call to `esp_clk_tree_src_get_freq_hz`.
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# if SOC_CLK_RC_FAST_SUPPORT_CALIBRATION
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# define LEDC_CLK_SRC_FREQ_PRECISION ESP_CLK_TREE_SRC_FREQ_PRECISION_CACHED
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# else
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# define LEDC_CLK_SRC_FREQ_PRECISION ESP_CLK_TREE_SRC_FREQ_PRECISION_APPROX
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# endif
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typedef enum {
LEDC_FSM_IDLE ,
LEDC_FSM_HW_FADE ,
LEDC_FSM_ISR_CAL ,
LEDC_FSM_KILLED_PENDING ,
} ledc_fade_fsm_t ;
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typedef struct {
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ledc_mode_t speed_mode ;
ledc_duty_direction_t direction ;
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uint32_t target_duty ;
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int cycle_num ;
int scale ;
ledc_fade_mode_t mode ;
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SemaphoreHandle_t ledc_fade_sem ;
SemaphoreHandle_t ledc_fade_mux ;
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# if CONFIG_SPIRAM_USE_MALLOC
StaticQueue_t ledc_fade_sem_storage ;
# endif
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ledc_cb_t ledc_fade_callback ;
void * cb_user_arg ;
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volatile ledc_fade_fsm_t fsm ;
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} ledc_fade_t ;
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typedef struct {
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ledc_hal_context_t ledc_hal ; /*!< LEDC hal context */
ledc_slow_clk_sel_t glb_clk ; /*!< LEDC global clock selection */
bool timer_is_stopped [ LEDC_TIMER_MAX ] ; /*!< Indicates whether each timer has been stopped */
bool glb_clk_is_acquired [ LEDC_TIMER_MAX ] ; /*!< Tracks whether the global clock is being acquired by each timer */
# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
ledc_clk_src_t timer_specific_clk [ LEDC_TIMER_MAX ] ; /*!< Tracks the timer-specific clock selection for each timer */
# endif
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} ledc_obj_t ;
static ledc_obj_t * p_ledc_obj [ LEDC_SPEED_MODE_MAX ] = { 0 } ;
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static ledc_fade_t * s_ledc_fade_rec [ LEDC_SPEED_MODE_MAX ] [ LEDC_CHANNEL_MAX ] ;
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static ledc_isr_handle_t s_ledc_fade_isr_handle = NULL ;
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static portMUX_TYPE ledc_spinlock = portMUX_INITIALIZER_UNLOCKED ;
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static _lock_t s_ledc_mutex [ LEDC_SPEED_MODE_MAX ] ;
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# define LEDC_VAL_NO_CHANGE (-1)
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# define LEDC_DUTY_NUM_MAX LEDC_LL_DUTY_NUM_MAX // Maximum steps per hardware fade
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# define LEDC_DUTY_DECIMAL_BIT_NUM (4)
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# define LEDC_TIMER_DIV_NUM_MAX (0x3FFFF)
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# define LEDC_FADE_TOO_SLOW_STR "LEDC FADE TOO SLOW"
# define LEDC_FADE_TOO_FAST_STR "LEDC FADE TOO FAST"
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# define DIM(array) (sizeof(array) / sizeof(*array))
# define LEDC_IS_DIV_INVALID(div) ((div) <= LEDC_LL_FRACTIONAL_MAX || (div) > LEDC_TIMER_DIV_NUM_MAX)
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static __attribute__ ( ( unused ) ) const char * LEDC_NOT_INIT = " LEDC is not initialized " ;
static __attribute__ ( ( unused ) ) const char * LEDC_FADE_SERVICE_ERR_STR = " LEDC fade service not installed " ;
static __attribute__ ( ( unused ) ) const char * LEDC_FADE_INIT_ERROR_STR = " LEDC fade channel init error, not enough memory or service not installed " ;
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//This value will be calibrated when in use.
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static uint32_t s_ledc_slow_clk_rc_fast_freq = 0 ;
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static const ledc_slow_clk_sel_t s_glb_clks [ ] = LEDC_LL_GLOBAL_CLOCKS ;
# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
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static const ledc_clk_src_t s_timer_specific_clks [ ] = LEDC_LL_TIMER_SPECIFIC_CLOCKS ;
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# endif
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static void ledc_ls_timer_update ( ledc_mode_t speed_mode , ledc_timer_t timer_sel )
{
if ( speed_mode = = LEDC_LOW_SPEED_MODE ) {
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ledc_hal_ls_timer_update ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel ) ;
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}
}
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static IRAM_ATTR void ledc_ls_channel_update ( ledc_mode_t speed_mode , ledc_channel_t channel )
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{
if ( speed_mode = = LEDC_LOW_SPEED_MODE ) {
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ledc_hal_ls_channel_update ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel ) ;
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}
}
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//We know that RC_FAST is about 8M/20M, but don't know the actual value. So we need to do a calibration.
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static bool ledc_slow_clk_calibrate ( void )
{
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if ( periph_rtc_dig_clk8m_enable ( ) ) {
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s_ledc_slow_clk_rc_fast_freq = periph_rtc_dig_clk8m_get_freq ( ) ;
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# if !SOC_CLK_RC_FAST_SUPPORT_CALIBRATION
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/* Workaround: RC_FAST calibration cannot be performed, we can only use its theoretic freq */
ESP_LOGD ( LEDC_TAG , " Calibration cannot be performed, approximate RC_FAST_CLK : % " PRIu32 " Hz " , s_ledc_slow_clk_rc_fast_freq ) ;
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# else
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ESP_LOGD ( LEDC_TAG , " Calibrate RC_FAST_CLK : % " PRIu32 " Hz " , s_ledc_slow_clk_rc_fast_freq ) ;
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# endif
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return true ;
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}
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ESP_LOGE ( LEDC_TAG , " Calibrate RC_FAST_CLK failed " ) ;
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return false ;
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}
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static esp_err_t ledc_enable_intr_type ( ledc_mode_t speed_mode , ledc_channel_t channel , ledc_intr_type_t type )
{
if ( type = = LEDC_INTR_FADE_END ) {
ledc_hal_set_fade_end_intr ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , true ) ;
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} else {
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ledc_hal_set_fade_end_intr ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , false ) ;
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}
return ESP_OK ;
}
static void _ledc_fade_hw_acquire ( ledc_mode_t mode , ledc_channel_t channel )
{
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ledc_fade_t * fade = s_ledc_fade_rec [ mode ] [ channel ] ;
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if ( fade ) {
xSemaphoreTake ( fade - > ledc_fade_sem , portMAX_DELAY ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_enable_intr_type ( mode , channel , LEDC_INTR_DISABLE ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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}
}
static void _ledc_fade_hw_release ( ledc_mode_t mode , ledc_channel_t channel )
{
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ledc_fade_t * fade = s_ledc_fade_rec [ mode ] [ channel ] ;
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if ( fade ) {
xSemaphoreGive ( fade - > ledc_fade_sem ) ;
}
}
static void _ledc_op_lock_acquire ( ledc_mode_t mode , ledc_channel_t channel )
{
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ledc_fade_t * fade = s_ledc_fade_rec [ mode ] [ channel ] ;
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if ( fade ) {
xSemaphoreTake ( fade - > ledc_fade_mux , portMAX_DELAY ) ;
}
}
static void _ledc_op_lock_release ( ledc_mode_t mode , ledc_channel_t channel )
{
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ledc_fade_t * fade = s_ledc_fade_rec [ mode ] [ channel ] ;
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if ( fade ) {
xSemaphoreGive ( fade - > ledc_fade_mux ) ;
}
}
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static uint32_t ledc_get_max_duty ( ledc_mode_t speed_mode , ledc_channel_t channel )
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{
// The arguments are checked before internally calling this function.
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ledc_timer_t timer_sel ;
ledc_hal_get_channel_timer ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & timer_sel ) ;
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uint32_t max_duty ;
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ledc_hal_get_max_duty ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel , & max_duty ) ;
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return max_duty ;
}
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esp_err_t ledc_timer_set ( ledc_mode_t speed_mode , ledc_timer_t timer_sel , uint32_t clock_divider , uint32_t duty_resolution ,
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ledc_clk_src_t clk_src )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_sel < LEDC_TIMER_MAX , " timer_select " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_hal_set_clock_divider ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel , clock_divider ) ;
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# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
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/* Clock source can only be configured on targets which support timer-specific source clock. */
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ledc_hal_set_clock_source ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel , clk_src ) ;
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// TODO: acquire clk_src, and release old clk_src if initialized and different than new one [clk_tree]
p_ledc_obj [ speed_mode ] - > timer_specific_clk [ timer_sel ] = clk_src ;
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# endif
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ledc_hal_set_duty_resolution ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel , duty_resolution ) ;
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ledc_ls_timer_update ( speed_mode , timer_sel ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
return ESP_OK ;
}
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static IRAM_ATTR esp_err_t ledc_duty_config ( ledc_mode_t speed_mode , ledc_channel_t channel , int hpoint_val ,
int duty_val , ledc_duty_direction_t duty_direction , uint32_t duty_num , uint32_t duty_cycle , uint32_t duty_scale )
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{
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if ( hpoint_val > = 0 ) {
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ledc_hal_set_hpoint ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , hpoint_val ) ;
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}
if ( duty_val > = 0 ) {
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ledc_hal_set_duty_int_part ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , duty_val ) ;
}
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ledc_hal_set_fade_param ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , 0 , duty_direction , duty_cycle , duty_scale , duty_num ) ;
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# if SOC_LEDC_GAMMA_CURVE_FADE_SUPPORTED
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ledc_hal_set_range_number ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , 1 ) ;
# endif
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return ESP_OK ;
}
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esp_err_t ledc_bind_channel_timer ( ledc_mode_t speed_mode , ledc_channel_t channel , ledc_timer_t timer_sel )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_sel < LEDC_TIMER_MAX , " timer_select " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
portENTER_CRITICAL ( & ledc_spinlock ) ;
ledc_hal_bind_channel_timer ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , timer_sel ) ;
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ledc_ls_channel_update ( speed_mode , channel ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
return ESP_OK ;
}
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esp_err_t ledc_timer_rst ( ledc_mode_t speed_mode , ledc_timer_t timer_sel )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_sel < LEDC_TIMER_MAX , " timer_select " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_hal_timer_rst ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
return ESP_OK ;
}
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esp_err_t ledc_timer_pause ( ledc_mode_t speed_mode , ledc_timer_t timer_sel )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_sel < LEDC_TIMER_MAX , " timer_select " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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p_ledc_obj [ speed_mode ] - > timer_is_stopped [ timer_sel ] = true ;
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ledc_hal_timer_pause ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
return ESP_OK ;
}
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esp_err_t ledc_timer_resume ( ledc_mode_t speed_mode , ledc_timer_t timer_sel )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_sel < LEDC_TIMER_MAX , " timer_select " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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p_ledc_obj [ speed_mode ] - > timer_is_stopped [ timer_sel ] = false ;
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ledc_hal_timer_resume ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_sel ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
return ESP_OK ;
}
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esp_err_t ledc_isr_register ( void ( * fn ) ( void * ) , void * arg , int intr_alloc_flags , ledc_isr_handle_t * handle )
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{
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esp_err_t ret ;
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LEDC_ARG_CHECK ( fn , " fn " ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ret = esp_intr_alloc ( ETS_LEDC_INTR_SOURCE , intr_alloc_flags , fn , arg , handle ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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return ret ;
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}
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static bool ledc_speed_mode_ctx_create ( ledc_mode_t speed_mode )
{
bool new_ctx = false ;
// Prevent p_ledc_obj malloc concurrently
_lock_acquire ( & s_ledc_mutex [ speed_mode ] ) ;
if ( ! p_ledc_obj [ speed_mode ] ) {
ledc_obj_t * ledc_new_mode_obj = ( ledc_obj_t * ) heap_caps_calloc ( 1 , sizeof ( ledc_obj_t ) , MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT ) ;
if ( ledc_new_mode_obj ) {
new_ctx = true ;
ledc_hal_init ( & ( ledc_new_mode_obj - > ledc_hal ) , speed_mode ) ;
ledc_new_mode_obj - > glb_clk = LEDC_SLOW_CLK_UNINIT ;
# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
memset ( ledc_new_mode_obj - > timer_specific_clk , LEDC_TIMER_SPECIFIC_CLK_UNINIT , sizeof ( ledc_clk_src_t ) * LEDC_TIMER_MAX ) ;
# endif
p_ledc_obj [ speed_mode ] = ledc_new_mode_obj ;
// Enable APB access to LEDC registers
periph_module_enable ( PERIPH_LEDC_MODULE ) ;
}
}
_lock_release ( & s_ledc_mutex [ speed_mode ] ) ;
return new_ctx ;
}
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static inline uint32_t ledc_calculate_divisor ( uint32_t src_clk_freq , int freq_hz , uint32_t precision )
{
/**
* In order to find the right divisor , we need to divide the source clock
* frequency by the desired frequency . However , two things to note here :
* - The lowest LEDC_LL_FRACTIONAL_BITS bits of the result are the FRACTIONAL
* part . The higher bits represent the integer part , this is why we need
* to right shift the source frequency .
* - The ` precision ` parameter represents the granularity of the clock . It
* * * must * * be a power of 2. It means that the resulted divisor is
* a multiplier of ` precision ` .
*
* Let ' s take a concrete example , we need to generate a 5 KHz clock out of
* a 80 MHz clock ( APB ) .
* If the precision is 1024 ( 10 bits ) , the resulted multiplier is :
* ( 80000000 < < 8 ) / ( 5000 * 1024 ) = 4000 ( 0xfa0 )
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* Let ' s ignore the fractional part to simplify the explanation , so we get
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* a result of 15 ( 0xf ) .
* This can be interpreted as : every 15 " precision " ticks , the resulted
* clock will go high , where one precision tick is made out of 1024 source
* clock ticks .
* Thus , every ` 15 * 1024 ` source clock ticks , the resulted clock will go
2021-11-02 02:40:58 -04:00
* high .
*
* NOTE : We are also going to round up the value when necessary , thanks to :
* ( freq_hz * precision ) / 2
*/
return ( ( ( uint64_t ) src_clk_freq < < LEDC_LL_FRACTIONAL_BITS ) + ( ( freq_hz * precision ) / 2 ) )
/ ( freq_hz * precision ) ;
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}
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static inline uint32_t ledc_auto_global_clk_divisor ( int freq_hz , uint32_t precision , ledc_slow_clk_sel_t * clk_target )
2021-06-02 08:19:09 -04:00
{
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uint32_t ret = LEDC_CLK_NOT_FOUND ;
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uint32_t clk_freq = 0 ;
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/* This function will go through all the following clock sources to look
* for a valid divisor which generates the requested frequency . */
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for ( int i = 0 ; i < DIM ( s_glb_clks ) ; i + + ) {
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/* Before calculating the divisor, we need to have the RC_FAST frequency.
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* If it hasn ' t been measured yet , try calibrating it now . */
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if ( s_glb_clks [ i ] = = LEDC_SLOW_CLK_RC_FAST & & s_ledc_slow_clk_rc_fast_freq = = 0 & & ! ledc_slow_clk_calibrate ( ) ) {
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ESP_LOGD ( LEDC_TAG , " Unable to retrieve RC_FAST clock frequency, skipping it " ) ;
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continue ;
}
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esp_clk_tree_src_get_freq_hz ( ( soc_module_clk_t ) s_glb_clks [ i ] , LEDC_CLK_SRC_FREQ_PRECISION , & clk_freq ) ;
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uint32_t div_param = ledc_calculate_divisor ( clk_freq , freq_hz , precision ) ;
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/* If the divisor is valid, we can return this value. */
if ( ! LEDC_IS_DIV_INVALID ( div_param ) ) {
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* clk_target = s_glb_clks [ i ] ;
ret = div_param ;
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break ;
}
}
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return ret ;
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}
# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
static inline uint32_t ledc_auto_timer_specific_clk_divisor ( ledc_mode_t speed_mode , int freq_hz , uint32_t precision ,
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ledc_clk_src_t * clk_source )
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{
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uint32_t ret = LEDC_CLK_NOT_FOUND ;
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uint32_t clk_freq = 0 ;
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2022-04-08 05:58:32 -04:00
for ( int i = 0 ; i < DIM ( s_timer_specific_clks ) ; i + + ) {
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esp_clk_tree_src_get_freq_hz ( ( soc_module_clk_t ) s_timer_specific_clks [ i ] , LEDC_CLK_SRC_FREQ_PRECISION , & clk_freq ) ;
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uint32_t div_param = ledc_calculate_divisor ( clk_freq , freq_hz , precision ) ;
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/* If the divisor is valid, we can return this value. */
if ( ! LEDC_IS_DIV_INVALID ( div_param ) ) {
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* clk_source = s_timer_specific_clks [ i ] ;
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ret = div_param ;
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break ;
}
}
# if SOC_LEDC_SUPPORT_HS_MODE
/* On board that support LEDC high-speed mode, APB clock becomes a timer-
* specific clock when in high speed mode . Check if it is necessary here
* to test APB . */
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if ( speed_mode = = LEDC_HIGH_SPEED_MODE & & ret = = LEDC_CLK_NOT_FOUND ) {
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/* No divider was found yet, try with APB! */
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esp_clk_tree_src_get_freq_hz ( ( soc_module_clk_t ) LEDC_APB_CLK , LEDC_CLK_SRC_FREQ_PRECISION , & clk_freq ) ;
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uint32_t div_param = ledc_calculate_divisor ( clk_freq , freq_hz , precision ) ;
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if ( ! LEDC_IS_DIV_INVALID ( div_param ) ) {
* clk_source = LEDC_APB_CLK ;
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ret = div_param ;
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}
}
# endif
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return ret ;
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}
# endif
/**
* @ brief Try to find the clock with its divisor giving the frequency requested
* by the caller .
*/
static uint32_t ledc_auto_clk_divisor ( ledc_mode_t speed_mode , int freq_hz , uint32_t precision ,
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ledc_clk_src_t * clk_source , ledc_slow_clk_sel_t * clk_target )
2021-06-02 08:19:09 -04:00
{
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uint32_t ret = LEDC_CLK_NOT_FOUND ;
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# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
/* If the SoC presents timer-specific clock(s), try to achieve the given frequency
* thanks to it / them .
* clk_source parameter will returned by this function . */
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uint32_t div_param_timer = ledc_auto_timer_specific_clk_divisor ( speed_mode , freq_hz , precision , clk_source ) ;
2021-06-02 08:19:09 -04:00
2022-04-08 05:58:32 -04:00
if ( div_param_timer ! = LEDC_CLK_NOT_FOUND ) {
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/* The dividor is valid, no need try any other clock, return directly. */
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ret = div_param_timer ;
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}
# endif
/* On ESP32, only low speed channel can use the global clocks. For other
* chips , there are no high speed channels . */
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if ( ret = = LEDC_CLK_NOT_FOUND & & speed_mode = = LEDC_LOW_SPEED_MODE ) {
uint32_t div_param_global = ledc_auto_global_clk_divisor ( freq_hz , precision , clk_target ) ;
if ( div_param_global ! = LEDC_CLK_NOT_FOUND ) {
* clk_source = LEDC_SCLK ;
ret = div_param_global ;
}
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}
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return ret ;
2021-06-02 08:19:09 -04:00
}
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extern void esp_sleep_periph_use_8m ( bool use_or_not ) ;
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/**
* @ brief Function setting the LEDC timer divisor with the given source clock ,
* frequency and resolution . If the clock configuration passed is
* LEDC_AUTO_CLK , the clock will be determined automatically ( if possible ) .
*/
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static esp_err_t ledc_set_timer_div ( ledc_mode_t speed_mode , ledc_timer_t timer_num , ledc_clk_cfg_t clk_cfg , int freq_hz , int duty_resolution )
{
uint32_t div_param = 0 ;
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const uint32_t precision = ( 0x1 < < duty_resolution ) ;
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/* The clock sources are not initialized on purpose. To produce compiler warning if used but the selector functions
* don ' t set them properly . */
/* Timer-specific mux. Set to timer-specific clock or LEDC_SCLK if a global clock is used. */
ledc_clk_src_t timer_clk_src ;
/* Global clock mux. Should be set when LEDC_SCLK is used in LOW_SPEED_MODE. Otherwise left uninitialized. */
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ledc_slow_clk_sel_t glb_clk = LEDC_SLOW_CLK_UNINIT ;
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if ( clk_cfg = = LEDC_AUTO_CLK ) {
/* User hasn't specified the speed, we should try to guess it. */
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div_param = ledc_auto_clk_divisor ( speed_mode , freq_hz , precision , & timer_clk_src , & glb_clk ) ;
2023-01-23 12:54:34 -05:00
} else if ( clk_cfg = = LEDC_USE_RC_FAST_CLK ) {
/* User specified source clock(RC_FAST_CLK) for low speed channel.
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* Make sure the speed mode is correct . */
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ESP_RETURN_ON_FALSE ( ( speed_mode = = LEDC_LOW_SPEED_MODE ) , ESP_ERR_INVALID_ARG , LEDC_TAG , " RC_FAST clock can only be used in low speed mode " ) ;
2021-06-02 08:19:09 -04:00
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/* Before calculating the divisor, we need to have the RC_FAST frequency.
2022-02-08 23:50:19 -05:00
* If it hasn ' t been measured yet , try calibrating it now . */
2023-01-23 12:54:34 -05:00
if ( s_ledc_slow_clk_rc_fast_freq = = 0 & & ledc_slow_clk_calibrate ( ) = = false ) {
2021-06-02 08:19:09 -04:00
goto error ;
2018-11-01 00:23:11 -04:00
}
2021-06-02 08:19:09 -04:00
2021-11-02 02:40:58 -04:00
/* Set the global clock source */
2022-04-08 05:58:32 -04:00
timer_clk_src = LEDC_SCLK ;
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glb_clk = LEDC_SLOW_CLK_RC_FAST ;
2021-11-02 02:40:58 -04:00
2023-01-23 12:54:34 -05:00
/* We have the RC_FAST clock frequency now. */
div_param = ledc_calculate_divisor ( s_ledc_slow_clk_rc_fast_freq , freq_hz , precision ) ;
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if ( LEDC_IS_DIV_INVALID ( div_param ) ) {
div_param = LEDC_CLK_NOT_FOUND ;
}
2018-11-01 00:23:11 -04:00
} else {
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# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
if ( LEDC_LL_IS_TIMER_SPECIFIC_CLOCK ( speed_mode , clk_cfg ) ) {
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/* Currently we can convert a timer-specific clock to a source clock that
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* easily because their values are identical in the enumerations ( on purpose )
* If we decide to change the values in the future , we should consider defining
* a macro / function to convert timer - specific clock to clock source . */
timer_clk_src = ( ledc_clk_src_t ) clk_cfg ;
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} else
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# endif
2021-11-02 02:40:58 -04:00
{
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timer_clk_src = LEDC_SCLK ;
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# if SOC_LEDC_SUPPORT_REF_TICK
assert ( clk_cfg ! = LEDC_USE_REF_TICK ) ; // REF_TICK is NOT a global clock, it is a timer-specific clock
# endif
glb_clk = ( ledc_slow_clk_sel_t ) clk_cfg ;
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}
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uint32_t src_clk_freq = 0 ;
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esp_clk_tree_src_get_freq_hz ( ( soc_module_clk_t ) clk_cfg , LEDC_CLK_SRC_FREQ_PRECISION , & src_clk_freq ) ;
2021-06-02 08:19:09 -04:00
div_param = ledc_calculate_divisor ( src_clk_freq , freq_hz , precision ) ;
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if ( LEDC_IS_DIV_INVALID ( div_param ) ) {
div_param = LEDC_CLK_NOT_FOUND ;
}
2018-11-01 00:23:11 -04:00
}
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2022-04-08 05:58:32 -04:00
if ( div_param = = LEDC_CLK_NOT_FOUND ) {
2018-11-01 00:23:11 -04:00
goto error ;
}
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/* The following debug message makes more sense for AUTO mode. */
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ESP_LOGD ( LEDC_TAG , " Using clock source %d (in %s mode), divisor: 0x% " PRIx32 ,
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timer_clk_src , ( speed_mode = = LEDC_LOW_SPEED_MODE ? " slow " : " fast " ) , div_param ) ;
/* The following block configures the global clock.
2022-04-08 05:58:32 -04:00
* Thus , in theory , this only makes sense when configuring the LOW_SPEED timer and the source clock is LEDC_SCLK ( as
* HIGH_SPEED timers won ' t be clocked by the global clock ) . However , there are some limitations due to HW design .
2021-06-02 08:19:09 -04:00
*/
2018-11-01 00:23:11 -04:00
if ( speed_mode = = LEDC_LOW_SPEED_MODE ) {
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# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
/* On ESP32 and ESP32-S2, when the source clock of LOW_SPEED timer is a timer-specific one (i.e. REF_TICK), the
* global clock MUST be set to APB_CLK . For HIGH_SPEED timers , this is not necessary .
*/
if ( timer_clk_src ! = LEDC_SCLK ) {
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glb_clk = LEDC_SLOW_CLK_APB ;
}
2022-04-08 05:58:32 -04:00
# else
/* On later chips, there is only one type of timer/channel (referred as LOW_SPEED in the code), which can only be
* clocked by the global clock . So there ' s no limitation on the global clock , except that it must be set .
*/
assert ( timer_clk_src = = LEDC_SCLK ) ;
# endif
2023-01-03 23:06:41 -05:00
// Arriving here, variable glb_clk must have been assigned to one of the ledc_slow_clk_sel_t enum values
assert ( glb_clk ! = LEDC_SLOW_CLK_UNINIT ) ;
2023-03-24 07:40:18 -04:00
portENTER_CRITICAL ( & ledc_spinlock ) ;
if ( p_ledc_obj [ speed_mode ] - > glb_clk ! = LEDC_SLOW_CLK_UNINIT & & p_ledc_obj [ speed_mode ] - > glb_clk ! = glb_clk ) {
for ( int i = 0 ; i < LEDC_TIMER_MAX ; i + + ) {
if ( i ! = timer_num & & p_ledc_obj [ speed_mode ] - > glb_clk_is_acquired [ i ] ) {
portEXIT_CRITICAL ( & ledc_spinlock ) ;
ESP_RETURN_ON_FALSE ( false , ESP_FAIL , LEDC_TAG ,
" timer clock conflict, already is %d but attempt to %d " , p_ledc_obj [ speed_mode ] - > glb_clk , glb_clk ) ;
}
}
}
p_ledc_obj [ speed_mode ] - > glb_clk_is_acquired [ timer_num ] = true ;
if ( p_ledc_obj [ speed_mode ] - > glb_clk ! = glb_clk ) {
// TODO: release old glb_clk (if not UNINIT), and acquire new glb_clk [clk_tree]
p_ledc_obj [ speed_mode ] - > glb_clk = glb_clk ;
ledc_hal_set_slow_clk_sel ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , glb_clk ) ;
}
portEXIT_CRITICAL ( & ledc_spinlock ) ;
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ESP_LOGD ( LEDC_TAG , " In slow speed mode, global clk set: %d " , glb_clk ) ;
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2022-12-26 08:57:52 -05:00
/* keep ESP_PD_DOMAIN_RC_FAST on during light sleep */
2023-01-23 12:54:34 -05:00
esp_sleep_periph_use_8m ( glb_clk = = LEDC_SLOW_CLK_RC_FAST ) ;
2019-10-22 04:34:13 -04:00
}
2021-06-02 08:19:09 -04:00
/* The divisor is correct, we can write in the hardware. */
2018-11-01 00:23:11 -04:00
ledc_timer_set ( speed_mode , timer_num , div_param , duty_resolution , timer_clk_src ) ;
return ESP_OK ;
2022-04-08 05:58:32 -04:00
2018-11-01 00:23:11 -04:00
error :
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ESP_LOGE ( LEDC_TAG , " requested frequency and duty resolution can not be achieved, try reducing freq_hz or duty_resolution. div_param=% " PRIu32 , div_param ) ;
2018-11-01 00:23:11 -04:00
return ESP_FAIL ;
}
2023-03-24 07:40:18 -04:00
static esp_err_t ledc_timer_del ( ledc_mode_t speed_mode , ledc_timer_t timer_sel )
{
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
bool is_configured = true ;
bool is_deleted = false ;
portENTER_CRITICAL ( & ledc_spinlock ) ;
if ( p_ledc_obj [ speed_mode ] - > glb_clk_is_acquired [ timer_sel ] = = false
# if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX
& & p_ledc_obj [ speed_mode ] - > timer_specific_clk [ timer_sel ] = = LEDC_TIMER_SPECIFIC_CLK_UNINIT
# endif
) {
is_configured = false ;
} else if ( p_ledc_obj [ speed_mode ] - > timer_is_stopped [ timer_sel ] = = true ) {
is_deleted = true ;
p_ledc_obj [ speed_mode ] - > glb_clk_is_acquired [ timer_sel ] = false ;
// TODO: release timer specific clk and global clk if possible [clk_tree]
}
portEXIT_CRITICAL ( & ledc_spinlock ) ;
ESP_RETURN_ON_FALSE ( is_configured & & is_deleted , ESP_ERR_INVALID_STATE , LEDC_TAG , " timer hasn't been configured, or it is still running, please stop it with ledc_timer_pause first " ) ;
return ESP_OK ;
}
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esp_err_t ledc_timer_config ( const ledc_timer_config_t * timer_conf )
2016-09-22 21:21:37 -04:00
{
2018-04-12 03:38:39 -04:00
LEDC_ARG_CHECK ( timer_conf ! = NULL , " timer_conf " ) ;
uint32_t freq_hz = timer_conf - > freq_hz ;
uint32_t duty_resolution = timer_conf - > duty_resolution ;
uint32_t timer_num = timer_conf - > timer_num ;
uint32_t speed_mode = timer_conf - > speed_mode ;
2018-05-10 05:18:17 -04:00
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_num < LEDC_TIMER_MAX , " timer_num " ) ;
if ( timer_conf - > deconfigure ) {
return ledc_timer_del ( speed_mode , timer_num ) ;
}
2023-01-23 12:54:34 -05:00
LEDC_ARG_CHECK ( ! ( ( timer_conf - > clk_cfg = = LEDC_USE_RC_FAST_CLK ) & & ( speed_mode ! = LEDC_LOW_SPEED_MODE ) ) , " Only low speed channel support RC_FAST_CLK " ) ;
2018-04-12 03:38:39 -04:00
if ( freq_hz = = 0 | | duty_resolution = = 0 | | duty_resolution > = LEDC_TIMER_BIT_MAX ) {
2022-08-04 01:08:48 -04:00
ESP_LOGE ( LEDC_TAG , " freq_hz=% " PRIu32 " duty_resolution=% " PRIu32 , freq_hz , duty_resolution ) ;
2016-09-22 21:21:37 -04:00
return ESP_ERR_INVALID_ARG ;
}
2019-08-09 08:30:19 -04:00
2023-03-24 07:40:18 -04:00
if ( ! ledc_speed_mode_ctx_create ( speed_mode ) & & ! p_ledc_obj [ speed_mode ] ) {
return ESP_ERR_NO_MEM ;
2019-08-09 08:30:19 -04:00
}
2022-08-18 00:34:11 -04:00
esp_err_t ret = ledc_set_timer_div ( speed_mode , timer_num , timer_conf - > clk_cfg , freq_hz , duty_resolution ) ;
if ( ret = = ESP_OK ) {
2023-03-24 07:40:18 -04:00
/* Make sure timer is running and reset the timer. */
ledc_timer_resume ( speed_mode , timer_num ) ;
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ledc_timer_rst ( speed_mode , timer_num ) ;
}
return ret ;
2016-09-28 11:20:34 -04:00
}
2016-10-24 03:57:23 -04:00
esp_err_t ledc_set_pin ( int gpio_num , ledc_mode_t speed_mode , ledc_channel_t ledc_channel )
{
2018-04-12 03:38:39 -04:00
LEDC_ARG_CHECK ( ledc_channel < LEDC_CHANNEL_MAX , " ledc_channel " ) ;
2018-05-10 05:18:17 -04:00
LEDC_ARG_CHECK ( GPIO_IS_VALID_OUTPUT_GPIO ( gpio_num ) , " gpio_num " ) ;
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
2021-03-15 22:55:05 -04:00
gpio_hal_iomux_func_sel ( GPIO_PIN_MUX_REG [ gpio_num ] , PIN_FUNC_GPIO ) ;
2016-10-24 03:57:23 -04:00
gpio_set_direction ( gpio_num , GPIO_MODE_OUTPUT ) ;
2020-06-19 00:00:58 -04:00
esp_rom_gpio_connect_out_signal ( gpio_num , ledc_periph_signal [ speed_mode ] . sig_out0_idx + ledc_channel , 0 , 0 ) ;
2016-10-24 03:57:23 -04:00
return ESP_OK ;
}
2021-10-25 05:13:46 -04:00
esp_err_t ledc_channel_config ( const ledc_channel_config_t * ledc_conf )
2016-09-28 11:20:34 -04:00
{
2018-04-12 03:38:39 -04:00
LEDC_ARG_CHECK ( ledc_conf , " ledc_conf " ) ;
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uint32_t speed_mode = ledc_conf - > speed_mode ;
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int gpio_num = ledc_conf - > gpio_num ;
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uint32_t ledc_channel = ledc_conf - > channel ;
uint32_t timer_select = ledc_conf - > timer_sel ;
uint32_t intr_type = ledc_conf - > intr_type ;
uint32_t duty = ledc_conf - > duty ;
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uint32_t hpoint = ledc_conf - > hpoint ;
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bool output_invert = ledc_conf - > flags . output_invert ;
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LEDC_ARG_CHECK ( ledc_channel < LEDC_CHANNEL_MAX , " ledc_channel " ) ;
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( GPIO_IS_VALID_OUTPUT_GPIO ( gpio_num ) , " gpio_num " ) ;
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LEDC_ARG_CHECK ( timer_select < LEDC_TIMER_MAX , " timer_select " ) ;
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LEDC_ARG_CHECK ( intr_type < LEDC_INTR_MAX , " intr_type " ) ;
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esp_err_t ret = ESP_OK ;
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bool new_speed_mode_ctx_created = ledc_speed_mode_ctx_create ( speed_mode ) ;
if ( ! new_speed_mode_ctx_created & & ! p_ledc_obj [ speed_mode ] ) {
return ESP_ERR_NO_MEM ;
}
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# if !(CONFIG_IDF_TARGET_ESP32 || CONFIG_IDF_TARGET_ESP32H2)
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// On such targets, the default ledc core(global) clock does not connect to any clock source
// Set channel configurations and update bits before core clock is on could lead to error
// Therefore, we should connect the core clock to a real clock source to make it on before any ledc register operation
// It can be switched to the other desired clock sources to meet the output pwm freq requirement later at timer configuration
// So we consider the glb_clk still as LEDC_SLOW_CLK_UNINIT
else if ( new_speed_mode_ctx_created ) {
portENTER_CRITICAL ( & ledc_spinlock ) ;
if ( p_ledc_obj [ speed_mode ] - > glb_clk = = LEDC_SLOW_CLK_UNINIT ) {
ledc_hal_set_slow_clk_sel ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , LEDC_LL_GLOBAL_CLK_DEFAULT ) ;
}
portEXIT_CRITICAL ( & ledc_spinlock ) ;
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}
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# endif
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/*set channel parameters*/
/* channel parameters decide how the waveform looks like in one period*/
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/* set channel duty and hpoint value, duty range is (0 ~ ((2 ** duty_resolution) - 1)), max hpoint value is 0xfffff*/
ledc_set_duty_with_hpoint ( speed_mode , ledc_channel , duty , hpoint ) ;
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/*update duty settings*/
ledc_update_duty ( speed_mode , ledc_channel ) ;
/*bind the channel with the timer*/
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ledc_bind_channel_timer ( speed_mode , ledc_channel , timer_select ) ;
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/*set interrupt type*/
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_enable_intr_type ( speed_mode , ledc_channel , intr_type ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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ESP_LOGD ( LEDC_TAG , " LEDC_PWM CHANNEL % " PRIu32 " |GPIO %02u|Duty %04 " PRIu32 " |Time % " PRIu32 ,
ledc_channel , gpio_num , duty , timer_select ) ;
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/*set LEDC signal in gpio matrix*/
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gpio_hal_iomux_func_sel ( GPIO_PIN_MUX_REG [ gpio_num ] , PIN_FUNC_GPIO ) ;
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gpio_set_level ( gpio_num , output_invert ) ;
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gpio_set_direction ( gpio_num , GPIO_MODE_OUTPUT ) ;
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esp_rom_gpio_connect_out_signal ( gpio_num , ledc_periph_signal [ speed_mode ] . sig_out0_idx + ledc_channel , output_invert , 0 ) ;
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return ret ;
}
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static void _ledc_update_duty ( ledc_mode_t speed_mode , ledc_channel_t channel )
{
ledc_hal_set_sig_out_en ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , true ) ;
ledc_hal_set_duty_start ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , true ) ;
ledc_ls_channel_update ( speed_mode , channel ) ;
}
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esp_err_t ledc_update_duty ( ledc_mode_t speed_mode , ledc_channel_t channel )
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{
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LEDC_ARG_CHECK_ISR ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK_ISR ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_CHECK_ISR ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
portENTER_CRITICAL_SAFE ( & ledc_spinlock ) ;
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_ledc_update_duty ( speed_mode , channel ) ;
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portEXIT_CRITICAL_SAFE ( & ledc_spinlock ) ;
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return ESP_OK ;
}
esp_err_t ledc_stop ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t idle_level )
{
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LEDC_ARG_CHECK_ISR ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK_ISR ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_CHECK_ISR ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
portENTER_CRITICAL_SAFE ( & ledc_spinlock ) ;
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ledc_hal_set_idle_level ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , idle_level ) ;
ledc_hal_set_sig_out_en ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , false ) ;
ledc_hal_set_duty_start ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , false ) ;
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ledc_ls_channel_update ( speed_mode , channel ) ;
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portEXIT_CRITICAL_SAFE ( & ledc_spinlock ) ;
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return ESP_OK ;
}
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esp_err_t ledc_set_fade ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t duty , ledc_duty_direction_t fade_direction ,
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uint32_t step_num , uint32_t duty_cyle_num , uint32_t duty_scale )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( fade_direction < LEDC_DUTY_DIR_MAX , " fade_direction " ) ;
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LEDC_ARG_CHECK ( step_num < = LEDC_LL_DUTY_NUM_MAX , " step_num " ) ;
LEDC_ARG_CHECK ( duty_cyle_num < = LEDC_LL_DUTY_CYCLE_MAX , " duty_cycle_num " ) ;
LEDC_ARG_CHECK ( duty_scale < = LEDC_LL_DUTY_SCALE_MAX , " duty_scale " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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_ledc_fade_hw_acquire ( speed_mode , channel ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode ,
channel , //uint32_t chan_num,
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LEDC_VAL_NO_CHANGE ,
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duty , //uint32_t duty_val,
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fade_direction , //uint32_t increase,
step_num , //uint32_t duty_num,
duty_cyle_num , //uint32_t duty_cycle,
duty_scale //uint32_t duty_scale
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) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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_ledc_fade_hw_release ( speed_mode , channel ) ;
return ESP_OK ;
}
esp_err_t ledc_set_duty_with_hpoint ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t duty , uint32_t hpoint )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_ARG_CHECK ( hpoint < = LEDC_LL_HPOINT_VAL_MAX , " hpoint " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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/* The channel configuration should not be changed before the fade operation is done. */
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode ,
channel , //uint32_t chan_num,
hpoint , //uint32_t hpoint_val,
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duty , //uint32_t duty_val,
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1 , //uint32_t increase,
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1 , //uint32_t duty_num,
1 , //uint32_t duty_cycle,
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0 //uint32_t duty_scale
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) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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_ledc_fade_hw_release ( speed_mode , channel ) ;
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return ESP_OK ;
}
esp_err_t ledc_set_duty ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t duty )
{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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/* The channel configuration should not be changed before the fade operation is done. */
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode ,
channel , //uint32_t chan_num,
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LEDC_VAL_NO_CHANGE ,
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duty , //uint32_t duty_val,
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1 , //uint32_t increase,
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1 , //uint32_t duty_num,
1 , //uint32_t duty_cycle,
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0 //uint32_t duty_scale
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) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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_ledc_fade_hw_release ( speed_mode , channel ) ;
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return ESP_OK ;
}
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uint32_t ledc_get_duty ( ledc_mode_t speed_mode , ledc_channel_t channel )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
uint32_t duty = 0 ;
ledc_hal_get_duty ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & duty ) ;
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return duty ;
}
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int ledc_get_hpoint ( ledc_mode_t speed_mode , ledc_channel_t channel )
{
LEDC_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode argument is invalid " , LEDC_ERR_VAL ) ;
LEDC_CHECK ( channel < LEDC_CHANNEL_MAX , " channel argument is invalid " , LEDC_ERR_VAL ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
uint32_t hpoint = 0 ;
ledc_hal_get_hpoint ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & hpoint ) ;
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return hpoint ;
}
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esp_err_t ledc_set_freq ( ledc_mode_t speed_mode , ledc_timer_t timer_num , uint32_t freq_hz )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_num < LEDC_TIMER_MAX , " timer_num " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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ledc_clk_cfg_t clk_cfg = LEDC_AUTO_CLK ;
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uint32_t duty_resolution = 0 ;
ledc_hal_get_clk_cfg ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_num , & clk_cfg ) ;
ledc_hal_get_duty_resolution ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_num , & duty_resolution ) ;
return ledc_set_timer_div ( speed_mode , timer_num , clk_cfg , freq_hz , duty_resolution ) ;
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}
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uint32_t ledc_get_freq ( ledc_mode_t speed_mode , ledc_timer_t timer_num )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
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LEDC_ARG_CHECK ( timer_num < LEDC_TIMER_MAX , " timer_num " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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uint32_t clock_divider = 0 ;
uint32_t duty_resolution = 0 ;
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ledc_clk_cfg_t clk_cfg = LEDC_AUTO_CLK ;
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ledc_hal_get_clock_divider ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_num , & clock_divider ) ;
ledc_hal_get_duty_resolution ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_num , & duty_resolution ) ;
ledc_hal_get_clk_cfg ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , timer_num , & clk_cfg ) ;
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uint32_t precision = ( 0x1 < < duty_resolution ) ;
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uint32_t src_clk_freq = 0 ;
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esp_clk_tree_src_get_freq_hz ( ( soc_module_clk_t ) clk_cfg , LEDC_CLK_SRC_FREQ_PRECISION , & src_clk_freq ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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if ( clock_divider = = 0 ) {
ESP_LOGW ( LEDC_TAG , " LEDC timer not configured, call ledc_timer_config to set timer frequency " ) ;
return 0 ;
}
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return ( ( ( uint64_t ) src_clk_freq < < LEDC_LL_FRACTIONAL_BITS ) + ( uint64_t ) precision * clock_divider / 2 ) / precision / clock_divider ;
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}
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static inline void IRAM_ATTR ledc_calc_fade_end_channel ( uint32_t * fade_end_status , uint32_t * channel )
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{
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uint32_t i = __builtin_ffs ( ( * fade_end_status ) ) - 1 ;
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( * fade_end_status ) & = ~ ( 1 < < i ) ;
* channel = i ;
}
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void IRAM_ATTR ledc_fade_isr ( void * arg )
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{
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bool cb_yield = false ;
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BaseType_t HPTaskAwoken = pdFALSE ;
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uint32_t speed_mode = 0 ;
uint32_t channel = 0 ;
uint32_t intr_status = 0 ;
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ledc_fade_fsm_t state ;
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for ( speed_mode = 0 ; speed_mode < LEDC_SPEED_MODE_MAX ; speed_mode + + ) {
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if ( p_ledc_obj [ speed_mode ] = = NULL ) {
continue ;
}
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ledc_hal_get_fade_end_intr_status ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , & intr_status ) ;
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while ( intr_status ) {
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ledc_calc_fade_end_channel ( & intr_status , & channel ) ;
// clear interrupt
ledc_hal_clear_fade_end_intr_status ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel ) ;
if ( s_ledc_fade_rec [ speed_mode ] [ channel ] = = NULL ) {
//fade object not initialized yet.
continue ;
}
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// Switch fade state to ISR_CAL if current state is HW_FADE
bool already_stopped = false ;
portENTER_CRITICAL_ISR ( & ledc_spinlock ) ;
state = s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm ;
assert ( state ! = LEDC_FSM_ISR_CAL & & state ! = LEDC_FSM_KILLED_PENDING ) ;
if ( state = = LEDC_FSM_HW_FADE ) {
s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm = LEDC_FSM_ISR_CAL ;
} else if ( state = = LEDC_FSM_IDLE ) {
// interrupt seen, but has already been stopped by task
already_stopped = true ;
}
portEXIT_CRITICAL_ISR ( & ledc_spinlock ) ;
if ( already_stopped ) {
continue ;
}
bool set_to_idle = false ;
int cycle = 0 ;
int delta = 0 ;
int step = 0 ;
int next_duty = 0 ;
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uint32_t duty_cur = 0 ;
ledc_hal_get_duty ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & duty_cur ) ;
uint32_t duty_tar = s_ledc_fade_rec [ speed_mode ] [ channel ] - > target_duty ;
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# if SOC_LEDC_GAMMA_CURVE_FADE_SUPPORTED
// If a multi-fade is done, check that target duty computed in sw is equal to the duty at the end of the fade
uint32_t range_num ;
ledc_hal_get_range_number ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & range_num ) ;
if ( range_num > 1 ) {
assert ( duty_cur = = duty_tar ) ;
}
# endif
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int scale = s_ledc_fade_rec [ speed_mode ] [ channel ] - > scale ;
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if ( duty_cur = = duty_tar | | scale = = 0 ) {
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// Target duty has reached
set_to_idle = true ;
} else {
// Calculate new duty config parameters
delta = ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > direction = = LEDC_DUTY_DIR_DECREASE ) ?
( duty_cur - duty_tar ) : ( duty_tar - duty_cur ) ;
if ( delta > scale ) {
next_duty = duty_cur ;
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step = ( delta / scale > LEDC_DUTY_NUM_MAX ) ? LEDC_DUTY_NUM_MAX : ( delta / scale ) ;
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cycle = s_ledc_fade_rec [ speed_mode ] [ channel ] - > cycle_num ;
} else {
next_duty = duty_tar ;
step = 1 ;
cycle = 1 ;
scale = 0 ;
}
}
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bool finished = false ;
portENTER_CRITICAL_ISR ( & ledc_spinlock ) ;
state = s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm ;
assert ( state ! = LEDC_FSM_IDLE & & state ! = LEDC_FSM_HW_FADE ) ;
if ( set_to_idle | | state = = LEDC_FSM_KILLED_PENDING ) {
// Either fade has completed or has been killed, skip HW duty config
finished = true ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm = LEDC_FSM_IDLE ;
} else if ( state = = LEDC_FSM_ISR_CAL ) {
// Loading new fade to start
ledc_duty_config ( speed_mode ,
channel ,
LEDC_VAL_NO_CHANGE ,
next_duty ,
s_ledc_fade_rec [ speed_mode ] [ channel ] - > direction ,
step ,
cycle ,
scale ) ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm = LEDC_FSM_HW_FADE ;
ledc_hal_set_duty_start ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , true ) ;
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ledc_ls_channel_update ( speed_mode , channel ) ;
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}
portEXIT_CRITICAL_ISR ( & ledc_spinlock ) ;
if ( finished ) {
xSemaphoreGiveFromISR ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem , & HPTaskAwoken ) ;
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ledc_cb_t fade_cb = s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_callback ;
if ( fade_cb ) {
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ledc_cb_param_t param = {
. event = LEDC_FADE_END_EVT ,
. speed_mode = speed_mode ,
. channel = channel ,
. duty = duty_cur
} ;
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cb_yield | = fade_cb ( & param , s_ledc_fade_rec [ speed_mode ] [ channel ] - > cb_user_arg ) ;
}
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}
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}
}
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if ( HPTaskAwoken = = pdTRUE | | cb_yield ) {
portYIELD_FROM_ISR ( ) ;
}
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}
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static esp_err_t ledc_fade_channel_deinit ( ledc_mode_t speed_mode , ledc_channel_t channel )
{
if ( s_ledc_fade_rec [ speed_mode ] [ channel ] ) {
if ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_mux ) {
vSemaphoreDelete ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_mux ) ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_mux = NULL ;
}
if ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem ) {
vSemaphoreDelete ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem ) ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem = NULL ;
}
free ( s_ledc_fade_rec [ speed_mode ] [ channel ] ) ;
s_ledc_fade_rec [ speed_mode ] [ channel ] = NULL ;
}
return ESP_OK ;
}
static esp_err_t ledc_fade_channel_init_check ( ledc_mode_t speed_mode , ledc_channel_t channel )
{
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if ( s_ledc_fade_isr_handle = = NULL ) {
ESP_LOGE ( LEDC_TAG , " Fade service not installed, call ledc_fade_func_install " ) ;
return ESP_FAIL ;
}
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if ( s_ledc_fade_rec [ speed_mode ] [ channel ] = = NULL ) {
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# if CONFIG_SPIRAM_USE_MALLOC
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s_ledc_fade_rec [ speed_mode ] [ channel ] = ( ledc_fade_t * ) heap_caps_calloc ( 1 , sizeof ( ledc_fade_t ) , MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT ) ;
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if ( s_ledc_fade_rec [ speed_mode ] [ channel ] = = NULL ) {
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ledc_fade_channel_deinit ( speed_mode , channel ) ;
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return ESP_ERR_NO_MEM ;
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}
memset ( & s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem_storage , 0 , sizeof ( StaticQueue_t ) ) ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem = xSemaphoreCreateBinaryStatic ( & s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem_storage ) ;
# else
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s_ledc_fade_rec [ speed_mode ] [ channel ] = ( ledc_fade_t * ) calloc ( 1 , sizeof ( ledc_fade_t ) ) ;
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if ( s_ledc_fade_rec [ speed_mode ] [ channel ] = = NULL ) {
ledc_fade_channel_deinit ( speed_mode , channel ) ;
return ESP_ERR_NO_MEM ;
}
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s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem = xSemaphoreCreateBinary ( ) ;
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# endif
s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_mux = xSemaphoreCreateMutex ( ) ;
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xSemaphoreGive ( s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem ) ;
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s_ledc_fade_rec [ speed_mode ] [ channel ] - > fsm = LEDC_FSM_IDLE ;
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}
if ( s_ledc_fade_rec [ speed_mode ] [ channel ]
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& & s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_mux
& & s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_sem ) {
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return ESP_OK ;
} else {
ledc_fade_channel_deinit ( speed_mode , channel ) ;
return ESP_FAIL ;
}
}
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static esp_err_t _ledc_set_fade_with_step ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , int scale , int cycle_num )
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{
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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uint32_t duty_cur = 0 ;
ledc_hal_get_duty ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & duty_cur ) ;
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// When duty == max_duty, meanwhile, if scale == 1 and fade_down == 1, counter would overflow.
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if ( duty_cur = = ledc_get_max_duty ( speed_mode , channel ) ) {
duty_cur - = 1 ;
}
s_ledc_fade_rec [ speed_mode ] [ channel ] - > speed_mode = speed_mode ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > target_duty = target_duty ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > cycle_num = cycle_num ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > scale = scale ;
int step_num = 0 ;
int dir = LEDC_DUTY_DIR_DECREASE ;
if ( scale > 0 ) {
if ( duty_cur > target_duty ) {
s_ledc_fade_rec [ speed_mode ] [ channel ] - > direction = LEDC_DUTY_DIR_DECREASE ;
step_num = ( duty_cur - target_duty ) / scale ;
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step_num = step_num > LEDC_DUTY_NUM_MAX ? LEDC_DUTY_NUM_MAX : step_num ;
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} else {
s_ledc_fade_rec [ speed_mode ] [ channel ] - > direction = LEDC_DUTY_DIR_INCREASE ;
dir = LEDC_DUTY_DIR_INCREASE ;
step_num = ( target_duty - duty_cur ) / scale ;
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step_num = step_num > LEDC_DUTY_NUM_MAX ? LEDC_DUTY_NUM_MAX : step_num ;
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}
}
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
if ( scale > 0 & & step_num > 0 ) {
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode , channel , LEDC_VAL_NO_CHANGE , duty_cur , dir , step_num , cycle_num , scale ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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ESP_LOGD ( LEDC_TAG , " cur duty: % " PRIu32 " ; target: % " PRIu32 " , step: %d, cycle: %d; scale: %d; dir: %d " ,
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duty_cur , target_duty , step_num , cycle_num , scale , dir ) ;
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} else {
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode , channel , LEDC_VAL_NO_CHANGE , target_duty , dir , 1 , 1 , 0 ) ;
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portEXIT_CRITICAL ( & ledc_spinlock ) ;
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ESP_LOGD ( LEDC_TAG , " Set to target duty: % " PRIu32 , target_duty ) ;
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}
return ESP_OK ;
}
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static esp_err_t _ledc_set_fade_with_time ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , int max_fade_time_ms )
{
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ledc_timer_t timer_sel ;
uint32_t duty_cur = 0 ;
ledc_hal_get_channel_timer ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & timer_sel ) ;
ledc_hal_get_duty ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & duty_cur ) ;
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uint32_t freq = ledc_get_freq ( speed_mode , timer_sel ) ;
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uint32_t duty_delta = target_duty > duty_cur ? target_duty - duty_cur : duty_cur - target_duty ;
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if ( duty_delta = = 0 ) {
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return _ledc_set_fade_with_step ( speed_mode , channel , target_duty , 0 , 0 ) ;
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}
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uint32_t total_cycles = max_fade_time_ms * freq / 1000 ;
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if ( total_cycles = = 0 ) {
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ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_FAST_STR ) ;
return _ledc_set_fade_with_step ( speed_mode , channel , target_duty , 0 , 0 ) ;
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}
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int scale , cycle_num ;
if ( total_cycles > duty_delta ) {
scale = 1 ;
cycle_num = total_cycles / duty_delta ;
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if ( cycle_num > LEDC_LL_DUTY_CYCLE_MAX ) {
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ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_SLOW_STR ) ;
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cycle_num = LEDC_LL_DUTY_CYCLE_MAX ;
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}
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} else {
cycle_num = 1 ;
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scale = duty_delta / total_cycles ;
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if ( scale > LEDC_LL_DUTY_SCALE_MAX ) {
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ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_FAST_STR ) ;
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scale = LEDC_LL_DUTY_SCALE_MAX ;
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}
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}
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return _ledc_set_fade_with_step ( speed_mode , channel , target_duty , scale , cycle_num ) ;
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}
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static void _ledc_fade_start ( ledc_mode_t speed_mode , ledc_channel_t channel , ledc_fade_mode_t fade_mode )
{
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ledc_fade_t * fade = s_ledc_fade_rec [ speed_mode ] [ channel ] ;
fade - > mode = fade_mode ;
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// Clear interrupt status of channel
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ledc_hal_clear_fade_end_intr_status ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel ) ;
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// Enable interrupt for channel
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_enable_intr_type ( speed_mode , channel , LEDC_INTR_FADE_END ) ;
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// Set fade state to HW_FADE state for starting the fade
assert ( fade - > fsm = = LEDC_FSM_IDLE ) ;
fade - > fsm = LEDC_FSM_HW_FADE ;
portEXIT_CRITICAL ( & ledc_spinlock ) ;
// Trigger the fade
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ledc_update_duty ( speed_mode , channel ) ;
if ( fade_mode = = LEDC_FADE_WAIT_DONE ) {
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// Waiting for fade done
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
// Release hardware to support next time fade configure
_ledc_fade_hw_release ( speed_mode , channel ) ;
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}
}
esp_err_t ledc_set_fade_with_time ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , int max_fade_time_ms )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_ARG_CHECK ( target_duty < = ledc_get_max_duty ( speed_mode , channel ) , " target_duty " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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_ledc_fade_hw_acquire ( speed_mode , channel ) ;
_ledc_set_fade_with_time ( speed_mode , channel , target_duty , max_fade_time_ms ) ;
_ledc_fade_hw_release ( speed_mode , channel ) ;
return ESP_OK ;
}
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esp_err_t ledc_set_fade_with_step ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , uint32_t scale , uint32_t cycle_num )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_ARG_CHECK ( ( scale > 0 ) & & ( scale < = LEDC_LL_DUTY_SCALE_MAX ) , " fade scale " ) ;
LEDC_ARG_CHECK ( ( cycle_num > 0 ) & & ( cycle_num < = LEDC_LL_DUTY_CYCLE_MAX ) , " cycle_num " ) ;
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LEDC_ARG_CHECK ( target_duty < = ledc_get_max_duty ( speed_mode , channel ) , " target_duty " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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_ledc_fade_hw_acquire ( speed_mode , channel ) ;
_ledc_set_fade_with_step ( speed_mode , channel , target_duty , scale , cycle_num ) ;
_ledc_fade_hw_release ( speed_mode , channel ) ;
return ESP_OK ;
}
esp_err_t ledc_fade_start ( ledc_mode_t speed_mode , ledc_channel_t channel , ledc_fade_mode_t fade_mode )
{
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LEDC_CHECK ( s_ledc_fade_rec [ speed_mode ] [ channel ] ! = NULL , LEDC_FADE_SERVICE_ERR_STR , ESP_ERR_INVALID_STATE ) ;
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LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_ARG_CHECK ( fade_mode < LEDC_FADE_MAX , " fade_mode " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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_ledc_fade_hw_acquire ( speed_mode , channel ) ;
_ledc_fade_start ( speed_mode , channel , fade_mode ) ;
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return ESP_OK ;
}
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// ESP32 does not support this functionality, fade cannot be overwritten with new duty config
# if SOC_LEDC_SUPPORT_FADE_STOP
esp_err_t ledc_fade_stop ( ledc_mode_t speed_mode , ledc_channel_t channel )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
ledc_fade_t * fade = s_ledc_fade_rec [ speed_mode ] [ channel ] ;
ledc_fade_fsm_t state = fade - > fsm ;
bool wait_for_idle = false ;
assert ( state ! = LEDC_FSM_KILLED_PENDING ) ;
if ( state = = LEDC_FSM_IDLE ) {
// if there is no fade going on, do nothing
return ESP_OK ;
}
// Fade state is either HW_FADE or ISR_CAL (there is a fade in process)
portENTER_CRITICAL ( & ledc_spinlock ) ;
// Disable ledc channel interrupt first
ledc_enable_intr_type ( speed_mode , channel , LEDC_INTR_DISABLE ) ;
// Config duty to the duty cycle at this moment
uint32_t duty_cur = ledc_get_duty ( speed_mode , channel ) ;
ledc_duty_config ( speed_mode ,
channel , //uint32_t chan_num,
LEDC_VAL_NO_CHANGE ,
duty_cur , //uint32_t duty_val,
1 , //uint32_t increase,
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1 , //uint32_t duty_num,
1 , //uint32_t duty_cycle,
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0 //uint32_t duty_scale
) ;
_ledc_update_duty ( speed_mode , channel ) ;
state = fade - > fsm ;
assert ( state ! = LEDC_FSM_IDLE & & state ! = LEDC_FSM_KILLED_PENDING ) ;
if ( state = = LEDC_FSM_HW_FADE ) {
fade - > fsm = LEDC_FSM_IDLE ;
} else if ( state = = LEDC_FSM_ISR_CAL ) {
fade - > fsm = LEDC_FSM_KILLED_PENDING ;
wait_for_idle = true ;
}
portEXIT_CRITICAL ( & ledc_spinlock ) ;
if ( wait_for_idle ) {
// Wait for ISR return, which gives the semaphore and switchs state to IDLE
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
assert ( fade - > fsm = = LEDC_FSM_IDLE ) ;
}
_ledc_fade_hw_release ( speed_mode , channel ) ;
return ESP_OK ;
}
# endif
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esp_err_t ledc_fade_func_install ( int intr_alloc_flags )
{
//OR intr_alloc_flags with ESP_INTR_FLAG_IRAM because the fade isr is in IRAM
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return ledc_isr_register ( ledc_fade_isr , NULL , intr_alloc_flags | ESP_INTR_FLAG_IRAM , & s_ledc_fade_isr_handle ) ;
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}
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void ledc_fade_func_uninstall ( void )
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{
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if ( s_ledc_fade_isr_handle ) {
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esp_intr_free ( s_ledc_fade_isr_handle ) ;
s_ledc_fade_isr_handle = NULL ;
}
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int channel , mode ;
for ( mode = 0 ; mode < LEDC_SPEED_MODE_MAX ; mode + + ) {
for ( channel = 0 ; channel < LEDC_CHANNEL_MAX ; channel + + ) {
ledc_fade_channel_deinit ( mode , channel ) ;
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}
}
return ;
}
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esp_err_t ledc_cb_register ( ledc_mode_t speed_mode , ledc_channel_t channel , ledc_cbs_t * cbs , void * user_arg )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
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LEDC_ARG_CHECK ( cbs , " callback " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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if ( cbs - > fade_cb & & ! esp_ptr_in_iram ( cbs - > fade_cb ) ) {
ESP_LOGW ( LEDC_TAG , " fade callback not in IRAM " ) ;
}
if ( user_arg & & ! esp_ptr_internal ( user_arg ) ) {
ESP_LOGW ( LEDC_TAG , " user context not in internal RAM " ) ;
}
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s_ledc_fade_rec [ speed_mode ] [ channel ] - > ledc_fade_callback = cbs - > fade_cb ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > cb_user_arg = user_arg ;
return ESP_OK ;
}
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/*
* The functions below are thread - safe version of APIs for duty and fade control .
* These APIs can be called from different tasks .
*/
esp_err_t ledc_set_duty_and_update ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t duty , uint32_t hpoint )
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{
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LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( duty < = ledc_get_max_duty ( speed_mode , channel ) , " target_duty " ) ;
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LEDC_ARG_CHECK ( hpoint < = LEDC_LL_HPOINT_VAL_MAX , " hpoint " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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_ledc_fade_hw_acquire ( speed_mode , channel ) ;
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portENTER_CRITICAL ( & ledc_spinlock ) ;
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ledc_duty_config ( speed_mode , channel , hpoint , duty , 1 , 1 , 1 , 0 ) ;
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_ledc_update_duty ( speed_mode , channel ) ;
portEXIT_CRITICAL ( & ledc_spinlock ) ;
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_ledc_fade_hw_release ( speed_mode , channel ) ;
return ESP_OK ;
}
esp_err_t ledc_set_fade_time_and_start ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , uint32_t max_fade_time_ms , ledc_fade_mode_t fade_mode )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( fade_mode < LEDC_FADE_MAX , " fade_mode " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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LEDC_ARG_CHECK ( target_duty < = ledc_get_max_duty ( speed_mode , channel ) , " target_duty " ) ;
_ledc_op_lock_acquire ( speed_mode , channel ) ;
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
_ledc_set_fade_with_time ( speed_mode , channel , target_duty , max_fade_time_ms ) ;
_ledc_fade_start ( speed_mode , channel , fade_mode ) ;
_ledc_op_lock_release ( speed_mode , channel ) ;
return ESP_OK ;
}
esp_err_t ledc_set_fade_step_and_start ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t target_duty , uint32_t scale , uint32_t cycle_num , ledc_fade_mode_t fade_mode )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( fade_mode < LEDC_FADE_MAX , " fade_mode " ) ;
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LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
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LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
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LEDC_ARG_CHECK ( ( scale > 0 ) & & ( scale < = LEDC_LL_DUTY_SCALE_MAX ) , " fade scale " ) ;
LEDC_ARG_CHECK ( ( cycle_num > 0 ) & & ( cycle_num < = LEDC_LL_DUTY_CYCLE_MAX ) , " cycle_num " ) ;
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LEDC_ARG_CHECK ( target_duty < = ledc_get_max_duty ( speed_mode , channel ) , " target_duty " ) ;
_ledc_op_lock_acquire ( speed_mode , channel ) ;
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
_ledc_set_fade_with_step ( speed_mode , channel , target_duty , scale , cycle_num ) ;
_ledc_fade_start ( speed_mode , channel , fade_mode ) ;
_ledc_op_lock_release ( speed_mode , channel ) ;
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return ESP_OK ;
}
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# if SOC_LEDC_GAMMA_CURVE_FADE_SUPPORTED
static esp_err_t _ledc_set_multi_fade ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t start_duty , const ledc_fade_param_config_t * fade_params_list , uint32_t list_len )
{
uint32_t max_duty = ledc_get_max_duty ( speed_mode , channel ) ;
LEDC_ARG_CHECK ( start_duty < = max_duty , " start_duty " ) ;
portENTER_CRITICAL ( & ledc_spinlock ) ;
ledc_hal_set_duty_int_part ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , start_duty ) ;
for ( int i = 0 ; i < list_len ; i + + ) {
ledc_fade_param_config_t fade_param = fade_params_list [ i ] ;
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ledc_hal_set_fade_param ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , i , fade_param . dir , fade_param . cycle_num , fade_param . scale , fade_param . step_num ) ;
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}
ledc_hal_set_range_number ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , list_len ) ;
portEXIT_CRITICAL ( & ledc_spinlock ) ;
// Calculate target duty, and take account for overflow
uint32_t target_duty = start_duty ;
for ( int i = 0 ; i < list_len ; i + + ) {
uint32_t delta_duty = ( fade_params_list [ i ] . step_num * fade_params_list [ i ] . scale ) % ( max_duty + 1 ) ;
if ( fade_params_list [ i ] . dir = = LEDC_DUTY_DIR_INCREASE ) {
target_duty + = delta_duty ;
if ( target_duty > max_duty ) {
target_duty - = max_duty + 1 ;
}
} else {
if ( delta_duty > target_duty ) {
target_duty + = max_duty + 1 ;
}
target_duty - = delta_duty ;
}
}
// Set interrupt exit criteria
s_ledc_fade_rec [ speed_mode ] [ channel ] - > target_duty = target_duty ;
s_ledc_fade_rec [ speed_mode ] [ channel ] - > scale = fade_params_list [ list_len - 1 ] . scale ;
return ESP_OK ;
}
esp_err_t ledc_set_multi_fade ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t start_duty , const ledc_fade_param_config_t * fade_params_list , uint32_t list_len )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( list_len < = SOC_LEDC_GAMMA_CURVE_FADE_RANGE_MAX , " list_len " ) ;
LEDC_ARG_CHECK ( fade_params_list , " fade_params_list " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
esp_err_t ret = _ledc_set_multi_fade ( speed_mode , channel , start_duty , fade_params_list , list_len ) ;
_ledc_fade_hw_release ( speed_mode , channel ) ;
return ret ;
}
esp_err_t ledc_set_multi_fade_and_start ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t start_duty , const ledc_fade_param_config_t * fade_params_list , uint32_t list_len , ledc_fade_mode_t fade_mode )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( list_len < = SOC_LEDC_GAMMA_CURVE_FADE_RANGE_MAX , " list_len " ) ;
LEDC_ARG_CHECK ( fade_params_list , " fade_params_list " ) ;
LEDC_ARG_CHECK ( fade_mode < LEDC_FADE_MAX , " fade_mode " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
LEDC_CHECK ( ledc_fade_channel_init_check ( speed_mode , channel ) = = ESP_OK , LEDC_FADE_INIT_ERROR_STR , ESP_FAIL ) ;
_ledc_op_lock_acquire ( speed_mode , channel ) ;
_ledc_fade_hw_acquire ( speed_mode , channel ) ;
esp_err_t ret = _ledc_set_multi_fade ( speed_mode , channel , start_duty , fade_params_list , list_len ) ;
if ( ret ! = ESP_OK ) {
_ledc_fade_hw_release ( speed_mode , channel ) ;
} else {
_ledc_fade_start ( speed_mode , channel , fade_mode ) ;
}
_ledc_op_lock_release ( speed_mode , channel ) ;
return ret ;
}
esp_err_t ledc_fill_multi_fade_param_list ( ledc_mode_t speed_mode , ledc_channel_t channel ,
uint32_t start_duty , uint32_t end_duty ,
uint32_t linear_phase_num , uint32_t max_fade_time_ms ,
uint32_t ( * gamma_correction_operator ) ( uint32_t ) ,
uint32_t fade_params_list_size ,
ledc_fade_param_config_t * fade_params_list , uint32_t * hw_fade_range_num )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( linear_phase_num > 0 & & linear_phase_num < = SOC_LEDC_GAMMA_CURVE_FADE_RANGE_MAX , " linear_phase_num " ) ;
LEDC_ARG_CHECK ( gamma_correction_operator , " gamma_correction_operator " ) ;
LEDC_ARG_CHECK ( fade_params_list_size < = SOC_LEDC_GAMMA_CURVE_FADE_RANGE_MAX , " fade_params_list_size " ) ;
LEDC_ARG_CHECK ( fade_params_list , " fade_params_list " ) ;
LEDC_ARG_CHECK ( hw_fade_range_num , " hw_fade_range_num " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
uint32_t max_duty = ledc_get_max_duty ( speed_mode , channel ) ;
LEDC_ARG_CHECK ( start_duty < = max_duty & & end_duty < = max_duty , " duty " ) ;
esp_err_t ret = ESP_OK ;
ledc_timer_t timer_sel ;
ledc_hal_get_channel_timer ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , & timer_sel ) ;
uint32_t freq = ledc_get_freq ( speed_mode , timer_sel ) ;
uint32_t dir = ( end_duty > start_duty ) ? LEDC_DUTY_DIR_INCREASE : LEDC_DUTY_DIR_DECREASE ;
uint32_t total_cycles = max_fade_time_ms * freq / 1000 ;
// If no duty change is need, then simplify the case
if ( start_duty = = end_duty ) {
total_cycles = 1 ;
linear_phase_num = 1 ;
}
uint32_t avg_cycles_per_phase = total_cycles / linear_phase_num ;
if ( avg_cycles_per_phase = = 0 ) {
ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_FAST_STR ) ;
avg_cycles_per_phase = 1 ;
}
int sgn = ( dir = = LEDC_DUTY_DIR_INCREASE ) ? 1 : ( - 1 ) ;
int32_t delta_brightness_per_phase = sgn * ( ( sgn * ( end_duty - start_duty ) ) / linear_phase_num ) ;
// First phase start and end values
uint32_t gamma_corrected_phase_head = gamma_correction_operator ( start_duty ) ;
uint32_t gamma_corrected_phase_tail = 0 ;
int32_t phase_tail = start_duty + delta_brightness_per_phase ;
// Compute raw fade parameters for each linear phase
uint32_t total_fade_range = 0 ; // To record the required hw fade ranges
uint32_t surplus_cycles_last_phase = 0 ;
for ( int i = 0 ; i < linear_phase_num ; i + + ) {
uint32_t cycle , scale , step ;
gamma_corrected_phase_tail = gamma_correction_operator ( phase_tail ) ;
uint32_t duty_delta = ( dir = = LEDC_DUTY_DIR_INCREASE ) ? ( gamma_corrected_phase_tail - gamma_corrected_phase_head ) :
( gamma_corrected_phase_head - gamma_corrected_phase_tail ) ;
uint32_t cycles_per_phase = avg_cycles_per_phase + surplus_cycles_last_phase ;
if ( duty_delta = = 0 ) {
scale = 0 ;
cycle = ( cycles_per_phase > LEDC_LL_DUTY_CYCLE_MAX ) ? LEDC_LL_DUTY_CYCLE_MAX : cycles_per_phase ;
step = 1 ;
} else if ( cycles_per_phase > duty_delta ) {
scale = 1 ;
step = duty_delta ;
cycle = cycles_per_phase / duty_delta ;
if ( cycle > LEDC_LL_DUTY_CYCLE_MAX ) {
ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_SLOW_STR ) ;
cycle = LEDC_LL_DUTY_CYCLE_MAX ;
}
} else {
cycle = 1 ;
scale = duty_delta / cycles_per_phase ;
if ( scale > LEDC_LL_DUTY_SCALE_MAX ) {
ESP_LOGW ( LEDC_TAG , LEDC_FADE_TOO_FAST_STR ) ;
scale = LEDC_LL_DUTY_SCALE_MAX ;
}
step = duty_delta / scale ;
}
// Prepare for next phase calculation
phase_tail = phase_tail + delta_brightness_per_phase ;
if ( dir = = LEDC_DUTY_DIR_INCREASE ) {
gamma_corrected_phase_head + = step * scale ;
} else {
gamma_corrected_phase_head - = step * scale ;
}
surplus_cycles_last_phase = cycles_per_phase - step * cycle ;
// If next phase is the last one, then account for all remaining duty and cycles
if ( i = = linear_phase_num - 2 ) {
phase_tail = end_duty ;
surplus_cycles_last_phase + = total_cycles - avg_cycles_per_phase * linear_phase_num ;
}
// Fill into the fade parameter list
// One linear phase might need multiple hardware fade ranges
do {
if ( total_fade_range > = fade_params_list_size ) {
ret = ESP_FAIL ;
break ;
}
fade_params_list [ total_fade_range ] . dir = dir ;
fade_params_list [ total_fade_range ] . cycle_num = cycle ;
fade_params_list [ total_fade_range ] . scale = scale ;
fade_params_list [ total_fade_range ] . step_num = ( step > LEDC_LL_DUTY_NUM_MAX ) ? LEDC_LL_DUTY_NUM_MAX : step ;
step - = fade_params_list [ total_fade_range ] . step_num ;
total_fade_range + = 1 ;
} while ( step > 0 ) ;
if ( ret ! = ESP_OK ) {
break ;
}
}
uint32_t remaining_duty_delta = ( dir = = LEDC_DUTY_DIR_INCREASE ) ? ( gamma_corrected_phase_tail - gamma_corrected_phase_head ) :
( gamma_corrected_phase_head - gamma_corrected_phase_tail ) ;
if ( remaining_duty_delta ) {
total_fade_range + = 1 ;
}
ESP_RETURN_ON_FALSE ( total_fade_range < = fade_params_list_size , ESP_FAIL , LEDC_TAG ,
" hw fade ranges required exceeds the space offered to fill the fade params. "
" Please allocate more space, or split into smaller multi-fades, or reduce linear_phase_num " ) ;
if ( remaining_duty_delta ) {
fade_params_list [ total_fade_range ] . dir = dir ;
fade_params_list [ total_fade_range ] . step_num = 1 ;
fade_params_list [ total_fade_range ] . cycle_num = 1 ;
fade_params_list [ total_fade_range ] . scale = remaining_duty_delta ;
}
* hw_fade_range_num = total_fade_range ;
return ret ;
}
esp_err_t ledc_read_fade_param ( ledc_mode_t speed_mode , ledc_channel_t channel , uint32_t range , uint32_t * dir , uint32_t * cycle , uint32_t * scale , uint32_t * step )
{
LEDC_ARG_CHECK ( speed_mode < LEDC_SPEED_MODE_MAX , " speed_mode " ) ;
LEDC_ARG_CHECK ( channel < LEDC_CHANNEL_MAX , " channel " ) ;
LEDC_ARG_CHECK ( range < SOC_LEDC_GAMMA_CURVE_FADE_RANGE_MAX , " range " ) ;
LEDC_CHECK ( p_ledc_obj [ speed_mode ] ! = NULL , LEDC_NOT_INIT , ESP_ERR_INVALID_STATE ) ;
ledc_hal_get_fade_param ( & ( p_ledc_obj [ speed_mode ] - > ledc_hal ) , channel , range , dir , cycle , scale , step ) ;
return ESP_OK ;
}
# endif // SOC_LEDC_GAMMA_CURVE_FADE_SUPPORTED