/* * SPDX-FileCopyrightText: 2015-2022 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #include #include "esp_types.h" #include "freertos/FreeRTOS.h" #include "freertos/semphr.h" #include "esp_log.h" #include "esp_check.h" #include "soc/gpio_periph.h" #include "soc/ledc_periph.h" #include "esp_private/esp_clk.h" #include "soc/soc_caps.h" #include "hal/ledc_hal.h" #include "hal/gpio_hal.h" #include "driver/ledc.h" #include "esp_rom_gpio.h" #include "esp_rom_sys.h" #include "clk_ctrl_os.h" #include "esp_private/periph_ctrl.h" static __attribute__((unused)) const char *LEDC_TAG = "ledc"; #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") #define LEDC_CLK_NOT_FOUND 0 typedef enum { LEDC_FSM_IDLE, LEDC_FSM_HW_FADE, LEDC_FSM_ISR_CAL, LEDC_FSM_KILLED_PENDING, } ledc_fade_fsm_t; typedef struct { ledc_mode_t speed_mode; ledc_duty_direction_t direction; uint32_t target_duty; int cycle_num; int scale; ledc_fade_mode_t mode; SemaphoreHandle_t ledc_fade_sem; SemaphoreHandle_t ledc_fade_mux; #if CONFIG_SPIRAM_USE_MALLOC StaticQueue_t ledc_fade_sem_storage; #endif ledc_cb_t ledc_fade_callback; void *cb_user_arg; volatile ledc_fade_fsm_t fsm; } ledc_fade_t; typedef struct { ledc_hal_context_t ledc_hal; /*!< LEDC hal context*/ } ledc_obj_t; static ledc_obj_t *p_ledc_obj[LEDC_SPEED_MODE_MAX] = {0}; static ledc_fade_t *s_ledc_fade_rec[LEDC_SPEED_MODE_MAX][LEDC_CHANNEL_MAX]; static ledc_isr_handle_t s_ledc_fade_isr_handle = NULL; static portMUX_TYPE ledc_spinlock = portMUX_INITIALIZER_UNLOCKED; #define LEDC_VAL_NO_CHANGE (-1) #define LEDC_DUTY_NUM_MAX LEDC_LL_DUTY_NUM_MAX // Maximum steps per hardware fade #define LEDC_DUTY_DECIMAL_BIT_NUM (4) #define LEDC_TIMER_DIV_NUM_MAX (0x3FFFF) #define LEDC_FADE_TOO_SLOW_STR "LEDC FADE TOO SLOW" #define LEDC_FADE_TOO_FAST_STR "LEDC FADE TOO FAST" #define DIM(array) (sizeof(array)/sizeof(*array)) #define LEDC_IS_DIV_INVALID(div) ((div) <= LEDC_LL_FRACTIONAL_MAX || (div) > LEDC_TIMER_DIV_NUM_MAX) 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"; //This value will be calibrated when in use. static uint32_t s_ledc_slow_clk_8M = 0; static const ledc_slow_clk_sel_t s_glb_clks[] = LEDC_LL_GLOBAL_CLOCKS; #if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX static const struct { ledc_clk_src_t clk; uint32_t freq; } s_timer_specific_clks[] = LEDC_LL_TIMER_SPECIFIC_CLOCKS; #endif static void ledc_ls_timer_update(ledc_mode_t speed_mode, ledc_timer_t timer_sel) { if (speed_mode == LEDC_LOW_SPEED_MODE) { ledc_hal_ls_timer_update(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel); } } static IRAM_ATTR void ledc_ls_channel_update(ledc_mode_t speed_mode, ledc_channel_t channel) { if (speed_mode == LEDC_LOW_SPEED_MODE) { ledc_hal_ls_channel_update(&(p_ledc_obj[speed_mode]->ledc_hal), channel); } } //We know that CLK8M is about 8M, but don't know the actual value. So we need to do a calibration. static bool ledc_slow_clk_calibrate(void) { if (periph_rtc_dig_clk8m_enable()) { s_ledc_slow_clk_8M = periph_rtc_dig_clk8m_get_freq(); #if CONFIG_IDF_TARGET_ESP32H2 /* Workaround: Calibration cannot be done for CLK8M on H2, we just use its theoretic frequency */ ESP_LOGD(LEDC_TAG, "Calibration cannot be performed, approximate CLK8M_CLK : %d Hz", s_ledc_slow_clk_8M); #else ESP_LOGD(LEDC_TAG, "Calibrate CLK8M_CLK : %d Hz", s_ledc_slow_clk_8M); #endif return true; } ESP_LOGE(LEDC_TAG, "Calibrate CLK8M_CLK failed"); return false; } static uint32_t ledc_get_src_clk_freq(ledc_clk_cfg_t clk_cfg) { uint32_t src_clk_freq = 0; if (clk_cfg == LEDC_USE_RTC8M_CLK) { src_clk_freq = s_ledc_slow_clk_8M; #if SOC_LEDC_SUPPORT_APB_CLOCK } else if (clk_cfg == LEDC_USE_APB_CLK) { src_clk_freq = esp_clk_apb_freq(); #endif #if SOC_LEDC_SUPPORT_PLL_DIV_CLOCK } else if (clk_cfg == LEDC_USE_PLL_DIV_CLK) { src_clk_freq = LEDC_LL_PLL_DIV_CLK_FREQ; #endif #if SOC_LEDC_SUPPORT_REF_TICK } else if (clk_cfg == LEDC_USE_REF_TICK) { src_clk_freq = REF_CLK_FREQ; #endif #if SOC_LEDC_SUPPORT_XTAL_CLOCK } else if (clk_cfg == LEDC_USE_XTAL_CLK) { src_clk_freq = esp_clk_xtal_freq(); #endif } return src_clk_freq; } /* Retrieve the clock frequency for global clocks only */ static uint32_t ledc_get_glb_clk_freq(ledc_slow_clk_sel_t clk_cfg) { uint32_t src_clk_freq = 0; switch (clk_cfg) { #if SOC_LEDC_SUPPORT_APB_CLOCK case LEDC_SLOW_CLK_APB: src_clk_freq = esp_clk_apb_freq(); break; #endif #if SOC_LEDC_SUPPORT_PLL_DIV_CLOCK case LEDC_SLOW_CLK_PLL_DIV: src_clk_freq = LEDC_LL_PLL_DIV_CLK_FREQ; break; #endif case LEDC_SLOW_CLK_RTC8M: src_clk_freq = s_ledc_slow_clk_8M; break; #if SOC_LEDC_SUPPORT_XTAL_CLOCK case LEDC_SLOW_CLK_XTAL: src_clk_freq = esp_clk_xtal_freq(); break; #endif } return src_clk_freq; } 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); } else { ledc_hal_set_fade_end_intr(&(p_ledc_obj[speed_mode]->ledc_hal), channel, false); } return ESP_OK; } static void _ledc_fade_hw_acquire(ledc_mode_t mode, ledc_channel_t channel) { ledc_fade_t *fade = s_ledc_fade_rec[mode][channel]; if (fade) { xSemaphoreTake(fade->ledc_fade_sem, portMAX_DELAY); portENTER_CRITICAL(&ledc_spinlock); ledc_enable_intr_type(mode, channel, LEDC_INTR_DISABLE); portEXIT_CRITICAL(&ledc_spinlock); } } static void _ledc_fade_hw_release(ledc_mode_t mode, ledc_channel_t channel) { ledc_fade_t *fade = s_ledc_fade_rec[mode][channel]; if (fade) { xSemaphoreGive(fade->ledc_fade_sem); } } static void _ledc_op_lock_acquire(ledc_mode_t mode, ledc_channel_t channel) { ledc_fade_t *fade = s_ledc_fade_rec[mode][channel]; if (fade) { xSemaphoreTake(fade->ledc_fade_mux, portMAX_DELAY); } } static void _ledc_op_lock_release(ledc_mode_t mode, ledc_channel_t channel) { ledc_fade_t *fade = s_ledc_fade_rec[mode][channel]; if (fade) { xSemaphoreGive(fade->ledc_fade_mux); } } static uint32_t ledc_get_max_duty(ledc_mode_t speed_mode, ledc_channel_t channel) { // The arguments are checked before internally calling this function. uint32_t max_duty; ledc_hal_get_max_duty(&(p_ledc_obj[speed_mode]->ledc_hal), channel, &max_duty); return max_duty; } esp_err_t ledc_timer_set(ledc_mode_t speed_mode, ledc_timer_t timer_sel, uint32_t clock_divider, uint32_t duty_resolution, ledc_clk_src_t clk_src) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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_set_clock_divider(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel, clock_divider); #if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX /* Clock source can only be configured on boards which support timer-specific * source clock. */ ledc_hal_set_clock_source(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel, clk_src); #endif ledc_hal_set_duty_resolution(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel, duty_resolution); ledc_ls_timer_update(speed_mode, timer_sel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } 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) { if (hpoint_val >= 0) { ledc_hal_set_hpoint(&(p_ledc_obj[speed_mode]->ledc_hal), channel, hpoint_val); } if (duty_val >= 0) { ledc_hal_set_duty_int_part(&(p_ledc_obj[speed_mode]->ledc_hal), channel, duty_val); } ledc_hal_set_duty_direction(&(p_ledc_obj[speed_mode]->ledc_hal), channel, duty_direction); ledc_hal_set_duty_num(&(p_ledc_obj[speed_mode]->ledc_hal), channel, duty_num); ledc_hal_set_duty_cycle(&(p_ledc_obj[speed_mode]->ledc_hal), channel, duty_cycle); ledc_hal_set_duty_scale(&(p_ledc_obj[speed_mode]->ledc_hal), channel, duty_scale); ledc_ls_channel_update(speed_mode, channel); return ESP_OK; } esp_err_t ledc_bind_channel_timer(ledc_mode_t speed_mode, ledc_channel_t channel, ledc_timer_t timer_sel) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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); ledc_ls_channel_update(speed_mode, channel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_timer_rst(ledc_mode_t speed_mode, ledc_timer_t timer_sel) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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_timer_rst(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel); ledc_ls_timer_update(speed_mode, timer_sel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_timer_pause(ledc_mode_t speed_mode, ledc_timer_t timer_sel) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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_timer_pause(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel); ledc_ls_timer_update(speed_mode, timer_sel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_timer_resume(ledc_mode_t speed_mode, ledc_timer_t timer_sel) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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_timer_resume(&(p_ledc_obj[speed_mode]->ledc_hal), timer_sel); ledc_ls_timer_update(speed_mode, timer_sel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_isr_register(void (*fn)(void *), void *arg, int intr_alloc_flags, ledc_isr_handle_t *handle) { esp_err_t ret; LEDC_ARG_CHECK(fn, "fn"); portENTER_CRITICAL(&ledc_spinlock); ret = esp_intr_alloc(ETS_LEDC_INTR_SOURCE, intr_alloc_flags, fn, arg, handle); portEXIT_CRITICAL(&ledc_spinlock); return ret; } 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 5KHz clock out of * a 80MHz clock (APB). * If the precision is 1024 (10 bits), the resulted multiplier is: * (80000000 << 8) / (5000 * 1024) = 4000 (0xfa0) * Let's ignore the fractional part to simplify the explanation, so we get * 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 * 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); } static inline uint32_t ledc_auto_global_clk_divisor(int freq_hz, uint32_t precision, ledc_slow_clk_sel_t* clk_target) { uint32_t ret = LEDC_CLK_NOT_FOUND; uint32_t clk_freq = 0; /* This function will go through all the following clock sources to look * for a valid divisor which generates the requested frequency. */ for (int i = 0; i < DIM(s_glb_clks); i++) { /* Before calculating the divisor, we need to have the RTC frequency. * If it hasn't been measured yet, try calibrating it now. */ if (s_glb_clks[i] == LEDC_SLOW_CLK_RTC8M && s_ledc_slow_clk_8M == 0 && !ledc_slow_clk_calibrate()) { ESP_LOGD(LEDC_TAG, "Unable to retrieve RTC clock frequency, skipping it\n"); continue; } clk_freq = ledc_get_glb_clk_freq(s_glb_clks[i]); uint32_t div_param = ledc_calculate_divisor(clk_freq, freq_hz, precision); /* If the divisor is valid, we can return this value. */ if (!LEDC_IS_DIV_INVALID(div_param)) { *clk_target = s_glb_clks[i]; ret = div_param; break; } } return ret; } #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, ledc_clk_src_t* clk_source) { uint32_t ret = LEDC_CLK_NOT_FOUND; for (int i = 0; i < DIM(s_timer_specific_clks); i++) { uint32_t div_param = ledc_calculate_divisor(s_timer_specific_clks[i].freq, freq_hz, precision); /* If the divisor is valid, we can return this value. */ if (!LEDC_IS_DIV_INVALID(div_param)) { *clk_source = s_timer_specific_clks[i].clk; ret = div_param; 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. */ if (speed_mode == LEDC_HIGH_SPEED_MODE && ret == LEDC_CLK_NOT_FOUND) { /* No divider was found yet, try with APB! */ uint32_t div_param = ledc_calculate_divisor(esp_clk_apb_freq(), freq_hz, precision); if (!LEDC_IS_DIV_INVALID(div_param)) { *clk_source = LEDC_APB_CLK; ret = div_param; } } #endif return ret; } #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, ledc_clk_src_t* clk_source, ledc_slow_clk_sel_t* clk_target) { uint32_t ret = LEDC_CLK_NOT_FOUND; #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. */ uint32_t div_param_timer = ledc_auto_timer_specific_clk_divisor(speed_mode, freq_hz, precision, clk_source); if (div_param_timer != LEDC_CLK_NOT_FOUND) { /* The dividor is valid, no need try any other clock, return directly. */ ret = div_param_timer; } #endif /* On ESP32, only low speed channel can use the global clocks. For other * chips, there are no high speed channels. */ 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; } } return ret; } static ledc_slow_clk_sel_t ledc_clk_cfg_to_global_clk(const ledc_clk_cfg_t clk_cfg) { ledc_slow_clk_sel_t glb_clk; switch (clk_cfg) { #if SOC_LEDC_SUPPORT_APB_CLOCK case LEDC_USE_APB_CLK: glb_clk = LEDC_SLOW_CLK_APB; break; #endif #if SOC_LEDC_SUPPORT_PLL_DIV_CLOCK case LEDC_USE_PLL_DIV_CLK: glb_clk = LEDC_SLOW_CLK_PLL_DIV; break; #endif case LEDC_USE_RTC8M_CLK: glb_clk = LEDC_SLOW_CLK_RTC8M; break; #if SOC_LEDC_SUPPORT_XTAL_CLOCK case LEDC_USE_XTAL_CLK: glb_clk = LEDC_SLOW_CLK_XTAL; break; #endif #if SOC_LEDC_SUPPORT_REF_TICK case LEDC_USE_REF_TICK: #endif default: /* We should not get here, REF_TICK is NOT a global clock, * it is a timer-specific clock. */ abort(); } return glb_clk; } extern void esp_sleep_periph_use_8m(bool use_or_not); /** * @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). */ 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; const uint32_t precision = ( 0x1 << duty_resolution ); /* 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. */ ledc_slow_clk_sel_t glb_clk; if (clk_cfg == LEDC_AUTO_CLK) { /* User hasn't specified the speed, we should try to guess it. */ div_param = ledc_auto_clk_divisor(speed_mode, freq_hz, precision, &timer_clk_src, &glb_clk); } else if (clk_cfg == LEDC_USE_RTC8M_CLK) { /* User specified source clock(RTC8M_CLK) for low speed channel. * Make sure the speed mode is correct. */ ESP_RETURN_ON_FALSE((speed_mode == LEDC_LOW_SPEED_MODE), ESP_ERR_INVALID_ARG, LEDC_TAG, "RTC clock can only be used in low speed mode"); /* Before calculating the divisor, we need to have the RTC frequency. * If it hasn't been measured yet, try calibrating it now. */ if(s_ledc_slow_clk_8M == 0 && ledc_slow_clk_calibrate() == false) { goto error; } /* Set the global clock source */ timer_clk_src = LEDC_SCLK; glb_clk = LEDC_SLOW_CLK_RTC8M; /* We have the RTC clock frequency now. */ div_param = ledc_calculate_divisor(s_ledc_slow_clk_8M, freq_hz, precision); if (LEDC_IS_DIV_INVALID(div_param)) { div_param = LEDC_CLK_NOT_FOUND; } } else { #if SOC_LEDC_HAS_TIMER_SPECIFIC_MUX if (LEDC_LL_IS_TIMER_SPECIFIC_CLOCK(speed_mode, clk_cfg)) { /* Currently we can convert a timer-specific clock to a source clock that * 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; } else #endif { timer_clk_src = LEDC_SCLK; glb_clk = ledc_clk_cfg_to_global_clk(clk_cfg); } uint32_t src_clk_freq = ledc_get_src_clk_freq(clk_cfg); div_param = ledc_calculate_divisor(src_clk_freq, freq_hz, precision); if (LEDC_IS_DIV_INVALID(div_param)) { div_param = LEDC_CLK_NOT_FOUND; } } if (div_param == LEDC_CLK_NOT_FOUND) { goto error; } /* The following debug message makes more sense for AUTO mode. */ ESP_LOGD(LEDC_TAG, "Using clock source %d (in %s mode), divisor: 0x%x\n", timer_clk_src, (speed_mode == LEDC_LOW_SPEED_MODE ? "slow" : "fast"), div_param); /* The following block configures the global clock. * 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. */ if (speed_mode == LEDC_LOW_SPEED_MODE) { #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) { glb_clk = LEDC_SLOW_CLK_APB; } #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 ESP_LOGD(LEDC_TAG, "In slow speed mode, global clk set: %d", glb_clk); /* keep ESP_PD_DOMAIN_RTC8M on during light sleep */ esp_sleep_periph_use_8m(glb_clk == LEDC_SLOW_CLK_RTC8M); portENTER_CRITICAL(&ledc_spinlock); ledc_hal_set_slow_clk_sel(&(p_ledc_obj[speed_mode]->ledc_hal), glb_clk); portEXIT_CRITICAL(&ledc_spinlock); } /* The divisor is correct, we can write in the hardware. */ ledc_timer_set(speed_mode, timer_num, div_param, duty_resolution, timer_clk_src); /* Reset the timer. */ ledc_timer_rst(speed_mode, timer_num); return ESP_OK; error: ESP_LOGE(LEDC_TAG, "requested frequency and duty resolution can not be achieved, try reducing freq_hz or duty_resolution. div_param=%d", (uint32_t ) div_param); return ESP_FAIL; } esp_err_t ledc_timer_config(const ledc_timer_config_t *timer_conf) { 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; LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); LEDC_ARG_CHECK(!((timer_conf->clk_cfg == LEDC_USE_RTC8M_CLK) && (speed_mode != LEDC_LOW_SPEED_MODE)), "Only low speed channel support RTC8M_CLK"); periph_module_enable(PERIPH_LEDC_MODULE); if (freq_hz == 0 || duty_resolution == 0 || duty_resolution >= LEDC_TIMER_BIT_MAX) { ESP_LOGE(LEDC_TAG, "freq_hz=%u duty_resolution=%u", freq_hz, duty_resolution); return ESP_ERR_INVALID_ARG; } if (timer_num > LEDC_TIMER_3) { ESP_LOGE(LEDC_TAG, "invalid timer #%u", timer_num); return ESP_ERR_INVALID_ARG; } if (p_ledc_obj[speed_mode] == NULL) { p_ledc_obj[speed_mode] = (ledc_obj_t *) heap_caps_calloc(1, sizeof(ledc_obj_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT); if (p_ledc_obj[speed_mode] == NULL) { return ESP_ERR_NO_MEM; } ledc_hal_init(&(p_ledc_obj[speed_mode]->ledc_hal), speed_mode); } return ledc_set_timer_div(speed_mode, timer_num, timer_conf->clk_cfg, freq_hz, duty_resolution); } esp_err_t ledc_set_pin(int gpio_num, ledc_mode_t speed_mode, ledc_channel_t ledc_channel) { LEDC_ARG_CHECK(ledc_channel < LEDC_CHANNEL_MAX, "ledc_channel"); LEDC_ARG_CHECK(GPIO_IS_VALID_OUTPUT_GPIO(gpio_num), "gpio_num"); LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); gpio_hal_iomux_func_sel(GPIO_PIN_MUX_REG[gpio_num], PIN_FUNC_GPIO); gpio_set_direction(gpio_num, GPIO_MODE_OUTPUT); esp_rom_gpio_connect_out_signal(gpio_num, ledc_periph_signal[speed_mode].sig_out0_idx + ledc_channel, 0, 0); return ESP_OK; } esp_err_t ledc_channel_config(const ledc_channel_config_t *ledc_conf) { LEDC_ARG_CHECK(ledc_conf, "ledc_conf"); uint32_t speed_mode = ledc_conf->speed_mode; int gpio_num = ledc_conf->gpio_num; 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; uint32_t hpoint = ledc_conf->hpoint; bool output_invert = ledc_conf->flags.output_invert; LEDC_ARG_CHECK(ledc_channel < LEDC_CHANNEL_MAX, "ledc_channel"); LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); LEDC_ARG_CHECK(GPIO_IS_VALID_OUTPUT_GPIO(gpio_num), "gpio_num"); LEDC_ARG_CHECK(timer_select < LEDC_TIMER_MAX, "timer_select"); LEDC_ARG_CHECK(intr_type < LEDC_INTR_MAX, "intr_type"); periph_module_enable(PERIPH_LEDC_MODULE); esp_err_t ret = ESP_OK; if (p_ledc_obj[speed_mode] == NULL) { p_ledc_obj[speed_mode] = (ledc_obj_t *) heap_caps_calloc(1, sizeof(ledc_obj_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT); if (p_ledc_obj[speed_mode] == NULL) { return ESP_ERR_NO_MEM; } ledc_hal_init(&(p_ledc_obj[speed_mode]->ledc_hal), speed_mode); } /*set channel parameters*/ /* channel parameters decide how the waveform looks like in one period*/ /* 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); /*update duty settings*/ ledc_update_duty(speed_mode, ledc_channel); /*bind the channel with the timer*/ ledc_bind_channel_timer(speed_mode, ledc_channel, timer_select); /*set interrupt type*/ portENTER_CRITICAL(&ledc_spinlock); ledc_enable_intr_type(speed_mode, ledc_channel, intr_type); portEXIT_CRITICAL(&ledc_spinlock); ESP_LOGD(LEDC_TAG, "LEDC_PWM CHANNEL %1u|GPIO %02u|Duty %04u|Time %01u", ledc_channel, gpio_num, duty, timer_select ); /*set LEDC signal in gpio matrix*/ gpio_hal_iomux_func_sel(GPIO_PIN_MUX_REG[gpio_num], PIN_FUNC_GPIO); gpio_set_level(gpio_num, output_invert); gpio_set_direction(gpio_num, GPIO_MODE_OUTPUT); esp_rom_gpio_connect_out_signal(gpio_num, ledc_periph_signal[speed_mode].sig_out0_idx + ledc_channel, output_invert, 0); return ret; } 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); } esp_err_t ledc_update_duty(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); portENTER_CRITICAL(&ledc_spinlock); _ledc_update_duty(speed_mode, channel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_stop(ledc_mode_t speed_mode, ledc_channel_t channel, uint32_t idle_level) { 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); portENTER_CRITICAL(&ledc_spinlock); 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); ledc_ls_channel_update(speed_mode, channel); portEXIT_CRITICAL(&ledc_spinlock); return ESP_OK; } esp_err_t ledc_set_fade(ledc_mode_t speed_mode, ledc_channel_t channel, uint32_t duty, ledc_duty_direction_t fade_direction, uint32_t step_num, uint32_t duty_cyle_num, uint32_t duty_scale) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); LEDC_ARG_CHECK(channel < LEDC_CHANNEL_MAX, "channel"); LEDC_ARG_CHECK(fade_direction < LEDC_DUTY_DIR_MAX, "fade_direction"); 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"); LEDC_CHECK(p_ledc_obj[speed_mode] != NULL, LEDC_NOT_INIT, ESP_ERR_INVALID_STATE); _ledc_fade_hw_acquire(speed_mode, channel); portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, //uint32_t chan_num, LEDC_VAL_NO_CHANGE, duty, //uint32_t duty_val, fade_direction, //uint32_t increase, step_num, //uint32_t duty_num, duty_cyle_num, //uint32_t duty_cycle, duty_scale //uint32_t duty_scale ); portEXIT_CRITICAL(&ledc_spinlock); _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"); LEDC_ARG_CHECK(hpoint <= LEDC_LL_HPOINT_VAL_MAX, "hpoint"); LEDC_CHECK(p_ledc_obj[speed_mode] != NULL, LEDC_NOT_INIT, ESP_ERR_INVALID_STATE); /* The channel configuration should not be changed before the fade operation is done. */ _ledc_fade_hw_acquire(speed_mode, channel); portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, //uint32_t chan_num, hpoint, //uint32_t hpoint_val, duty, //uint32_t duty_val, 1, //uint32_t increase, 0, //uint32_t duty_num, 0, //uint32_t duty_cycle, 0 //uint32_t duty_scale ); portEXIT_CRITICAL(&ledc_spinlock); _ledc_fade_hw_release(speed_mode, channel); return ESP_OK; } esp_err_t ledc_set_duty(ledc_mode_t speed_mode, ledc_channel_t channel, uint32_t duty) { 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); /* The channel configuration should not be changed before the fade operation is done. */ _ledc_fade_hw_acquire(speed_mode, channel); portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, //uint32_t chan_num, LEDC_VAL_NO_CHANGE, duty, //uint32_t duty_val, 1, //uint32_t increase, 0, //uint32_t duty_num, 0, //uint32_t duty_cycle, 0 //uint32_t duty_scale ); portEXIT_CRITICAL(&ledc_spinlock); _ledc_fade_hw_release(speed_mode, channel); return ESP_OK; } uint32_t ledc_get_duty(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); uint32_t duty = 0; ledc_hal_get_duty(&(p_ledc_obj[speed_mode]->ledc_hal), channel, &duty); return duty; } 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); 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); return hpoint; } esp_err_t ledc_set_freq(ledc_mode_t speed_mode, ledc_timer_t timer_num, uint32_t freq_hz) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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); ledc_clk_cfg_t clk_cfg = LEDC_AUTO_CLK; 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); } uint32_t ledc_get_freq(ledc_mode_t speed_mode, ledc_timer_t timer_num) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); 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); portENTER_CRITICAL(&ledc_spinlock); uint32_t clock_divider = 0; uint32_t duty_resolution = 0; ledc_clk_cfg_t clk_cfg = LEDC_AUTO_CLK; 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); uint32_t precision = (0x1 << duty_resolution); uint32_t src_clk_freq = ledc_get_src_clk_freq(clk_cfg); portEXIT_CRITICAL(&ledc_spinlock); if (clock_divider == 0) { ESP_LOGW(LEDC_TAG, "LEDC timer not configured, call ledc_timer_config to set timer frequency"); return 0; } return ((uint64_t) src_clk_freq << 8) / precision / clock_divider; } static inline void ledc_calc_fade_end_channel(uint32_t *fade_end_status, uint32_t *channel) { uint32_t i = __builtin_ffs((*fade_end_status)) - 1; (*fade_end_status) &= ~(1 << i); *channel = i; } void IRAM_ATTR ledc_fade_isr(void *arg) { bool cb_yield = false; portBASE_TYPE HPTaskAwoken = pdFALSE; uint32_t speed_mode = 0; uint32_t channel = 0; uint32_t intr_status = 0; ledc_fade_fsm_t state; for (speed_mode = 0; speed_mode < LEDC_SPEED_MODE_MAX; speed_mode++) { if (p_ledc_obj[speed_mode] == NULL) { continue; } ledc_hal_get_fade_end_intr_status(&(p_ledc_obj[speed_mode]->ledc_hal), &intr_status); while (intr_status) { 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; } // 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; 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; int scale = s_ledc_fade_rec[speed_mode][channel]->scale; if (duty_cur == duty_tar || scale == 0) { // 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; step = (delta / scale > LEDC_DUTY_NUM_MAX) ? LEDC_DUTY_NUM_MAX : (delta / scale); cycle = s_ledc_fade_rec[speed_mode][channel]->cycle_num; } else { next_duty = duty_tar; step = 1; cycle = 1; scale = 0; } } 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); } portEXIT_CRITICAL_ISR(&ledc_spinlock); if (finished) { xSemaphoreGiveFromISR(s_ledc_fade_rec[speed_mode][channel]->ledc_fade_sem, &HPTaskAwoken); ledc_cb_t fade_cb = s_ledc_fade_rec[speed_mode][channel]->ledc_fade_callback; if (fade_cb) { ledc_cb_param_t param = { .event = LEDC_FADE_END_EVT, .speed_mode = speed_mode, .channel = channel, .duty = duty_cur }; cb_yield |= fade_cb(¶m, s_ledc_fade_rec[speed_mode][channel]->cb_user_arg); } } } } if (HPTaskAwoken == pdTRUE || cb_yield) { portYIELD_FROM_ISR(); } } 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) { if (s_ledc_fade_isr_handle == NULL) { ESP_LOGE(LEDC_TAG, "Fade service not installed, call ledc_fade_func_install"); return ESP_FAIL; } if (s_ledc_fade_rec[speed_mode][channel] == NULL) { #if CONFIG_SPIRAM_USE_MALLOC s_ledc_fade_rec[speed_mode][channel] = (ledc_fade_t *) heap_caps_calloc(1, sizeof(ledc_fade_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT); if (s_ledc_fade_rec[speed_mode][channel] == NULL) { ledc_fade_channel_deinit(speed_mode, channel); return ESP_ERR_NO_MEM; } 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 s_ledc_fade_rec[speed_mode][channel] = (ledc_fade_t *) calloc(1, sizeof(ledc_fade_t)); if (s_ledc_fade_rec[speed_mode][channel] == NULL) { ledc_fade_channel_deinit(speed_mode, channel); return ESP_ERR_NO_MEM; } s_ledc_fade_rec[speed_mode][channel]->ledc_fade_sem = xSemaphoreCreateBinary(); #endif s_ledc_fade_rec[speed_mode][channel]->ledc_fade_mux = xSemaphoreCreateMutex(); xSemaphoreGive(s_ledc_fade_rec[speed_mode][channel]->ledc_fade_sem); s_ledc_fade_rec[speed_mode][channel]->fsm = LEDC_FSM_IDLE; } if (s_ledc_fade_rec[speed_mode][channel] && s_ledc_fade_rec[speed_mode][channel]->ledc_fade_mux && s_ledc_fade_rec[speed_mode][channel]->ledc_fade_sem) { return ESP_OK; } else { ledc_fade_channel_deinit(speed_mode, channel); return ESP_FAIL; } } 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) { portENTER_CRITICAL(&ledc_spinlock); uint32_t duty_cur = 0; ledc_hal_get_duty(&(p_ledc_obj[speed_mode]->ledc_hal), channel, &duty_cur); // When duty == max_duty, meanwhile, if scale == 1 and fade_down == 1, counter would overflow. 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; step_num = step_num > LEDC_DUTY_NUM_MAX ? LEDC_DUTY_NUM_MAX : step_num; } 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; step_num = step_num > LEDC_DUTY_NUM_MAX ? LEDC_DUTY_NUM_MAX : step_num; } } portEXIT_CRITICAL(&ledc_spinlock); if (scale > 0 && step_num > 0) { portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, LEDC_VAL_NO_CHANGE, duty_cur, dir, step_num, cycle_num, scale); portEXIT_CRITICAL(&ledc_spinlock); ESP_LOGD(LEDC_TAG, "cur duty: %d; target: %d, step: %d, cycle: %d; scale: %d; dir: %d\n", duty_cur, target_duty, step_num, cycle_num, scale, dir); } else { portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, LEDC_VAL_NO_CHANGE, target_duty, dir, 0, 1, 0); portEXIT_CRITICAL(&ledc_spinlock); ESP_LOGD(LEDC_TAG, "Set to target duty: %d", target_duty); } return ESP_OK; } 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) { 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); uint32_t freq = ledc_get_freq(speed_mode, timer_sel); uint32_t duty_delta = target_duty > duty_cur ? target_duty - duty_cur : duty_cur - target_duty; if (duty_delta == 0) { return _ledc_set_fade_with_step(speed_mode, channel, target_duty, 0, 0); } uint32_t total_cycles = max_fade_time_ms * freq / 1000; if (total_cycles == 0) { ESP_LOGW(LEDC_TAG, LEDC_FADE_TOO_FAST_STR); return _ledc_set_fade_with_step(speed_mode, channel, target_duty, 0, 0); } int scale, cycle_num; if (total_cycles > duty_delta) { scale = 1; cycle_num = total_cycles / duty_delta; if (cycle_num > LEDC_LL_DUTY_NUM_MAX) { ESP_LOGW(LEDC_TAG, LEDC_FADE_TOO_SLOW_STR); cycle_num = LEDC_LL_DUTY_NUM_MAX; } } else { cycle_num = 1; scale = duty_delta / total_cycles; if (scale > LEDC_LL_DUTY_SCALE_MAX) { ESP_LOGW(LEDC_TAG, LEDC_FADE_TOO_FAST_STR); scale = LEDC_LL_DUTY_SCALE_MAX; } } return _ledc_set_fade_with_step(speed_mode, channel, target_duty, scale, cycle_num); } static void _ledc_fade_start(ledc_mode_t speed_mode, ledc_channel_t channel, ledc_fade_mode_t fade_mode) { ledc_fade_t *fade = s_ledc_fade_rec[speed_mode][channel]; fade->mode = fade_mode; // Clear interrupt status of channel ledc_hal_clear_fade_end_intr_status(&(p_ledc_obj[speed_mode]->ledc_hal), channel); // Enable interrupt for channel portENTER_CRITICAL(&ledc_spinlock); ledc_enable_intr_type(speed_mode, channel, LEDC_INTR_FADE_END); // 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 ledc_update_duty(speed_mode, channel); if (fade_mode == LEDC_FADE_WAIT_DONE) { // 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); } } 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) { LEDC_ARG_CHECK(speed_mode < LEDC_SPEED_MODE_MAX, "speed_mode"); LEDC_ARG_CHECK(channel < LEDC_CHANNEL_MAX, "channel"); LEDC_ARG_CHECK(target_duty <= ledc_get_max_duty(speed_mode, channel), "target_duty"); 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); _ledc_set_fade_with_time(speed_mode, channel, target_duty, max_fade_time_ms); _ledc_fade_hw_release(speed_mode, channel); return ESP_OK; } 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"); 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"); LEDC_ARG_CHECK(target_duty <= ledc_get_max_duty(speed_mode, channel), "target_duty"); 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); _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) { LEDC_CHECK(s_ledc_fade_rec[speed_mode][channel] != NULL, LEDC_FADE_SERVICE_ERR_STR, ESP_ERR_INVALID_STATE); LEDC_ARG_CHECK(channel < LEDC_CHANNEL_MAX, "channel"); 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_fade_hw_acquire(speed_mode, channel); _ledc_fade_start(speed_mode, channel, fade_mode); return ESP_OK; } // 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, 0, //uint32_t duty_num, 0, //uint32_t duty_cycle, 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 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 return ledc_isr_register(ledc_fade_isr, NULL, intr_alloc_flags | ESP_INTR_FLAG_IRAM, &s_ledc_fade_isr_handle); } void ledc_fade_func_uninstall(void) { if (s_ledc_fade_isr_handle) { esp_intr_free(s_ledc_fade_isr_handle); s_ledc_fade_isr_handle = NULL; } 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); } } return; } 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"); 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); 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; } /* * 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) { 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"); LEDC_ARG_CHECK(hpoint <= LEDC_LL_HPOINT_VAL_MAX, "hpoint"); 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); portENTER_CRITICAL(&ledc_spinlock); ledc_duty_config(speed_mode, channel, hpoint, duty, 1, 0, 0, 0); _ledc_update_duty(speed_mode, channel); portEXIT_CRITICAL(&ledc_spinlock); _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"); 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_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"); 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_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"); 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); return ESP_OK; }