/* * Copyright (c) 2022 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT espressif_esp32_adc #include #include #include #include #include #include #include #include #include #if defined(CONFIG_ADC_ESP32_DMA) #if !SOC_GDMA_SUPPORTED #error "SoCs without GDMA peripheral are not supported!" #endif #include #include #endif #include #include #include #include #include LOG_MODULE_REGISTER(adc_esp32, CONFIG_ADC_LOG_LEVEL); #define ADC_RESOLUTION_MIN SOC_ADC_DIGI_MIN_BITWIDTH #define ADC_RESOLUTION_MAX SOC_ADC_DIGI_MAX_BITWIDTH #if CONFIG_SOC_SERIES_ESP32 #define ADC_CALI_SCHEME ESP_ADC_CAL_VAL_EFUSE_VREF /* Due to significant measurement discrepancy in higher voltage range, we * clip the value instead of yet another correction. The IDF implementation * for ESP32-S2 is doing it, so we copy that approach in Zephyr driver */ #define ADC_CLIP_MVOLT_11DB 2550 #elif CONFIG_SOC_SERIES_ESP32S3 #define ADC_CALI_SCHEME ESP_ADC_CAL_VAL_EFUSE_TP_FIT #else #define ADC_CALI_SCHEME ESP_ADC_CAL_VAL_EFUSE_TP #endif /* Validate if resolution in bits is within allowed values */ #define VALID_RESOLUTION(r) ((r) >= ADC_RESOLUTION_MIN && (r) <= ADC_RESOLUTION_MAX) #define INVALID_RESOLUTION(r) (!VALID_RESOLUTION(r)) /* Default internal reference voltage */ #define ADC_ESP32_DEFAULT_VREF_INTERNAL (1100) #define ADC_DMA_BUFFER_SIZE DMA_DESCRIPTOR_BUFFER_MAX_SIZE_4B_ALIGNED struct adc_esp32_conf { adc_unit_t unit; uint8_t channel_count; #if defined(CONFIG_ADC_ESP32_DMA) const struct device *gpio_port; const struct device *dma_dev; uint8_t dma_channel; #endif /* defined(CONFIG_ADC_ESP32_DMA) */ }; struct adc_esp32_data { adc_atten_t attenuation[SOC_ADC_MAX_CHANNEL_NUM]; uint8_t resolution[SOC_ADC_MAX_CHANNEL_NUM]; esp_adc_cal_characteristics_t chars[SOC_ADC_MAX_CHANNEL_NUM]; uint16_t meas_ref_internal; uint16_t *buffer; bool calibrate; #if defined(CONFIG_ADC_ESP32_DMA) adc_hal_dma_ctx_t adc_hal_dma_ctx; uint8_t *dma_buffer; struct k_sem dma_conv_wait_lock; #endif /* defined(CONFIG_ADC_ESP32_DMA) */ }; /* Convert zephyr,gain property to the ESP32 attenuation */ static inline int gain_to_atten(enum adc_gain gain, adc_atten_t *atten) { switch (gain) { case ADC_GAIN_1: *atten = ADC_ATTEN_DB_0; break; case ADC_GAIN_4_5: *atten = ADC_ATTEN_DB_2_5; break; case ADC_GAIN_1_2: *atten = ADC_ATTEN_DB_6; break; case ADC_GAIN_1_4: *atten = ADC_ATTEN_DB_11; break; default: return -ENOTSUP; } return 0; } #if !defined(CONFIG_ADC_ESP32_DMA) /* Convert voltage by inverted attenuation to support zephyr gain values */ static void atten_to_gain(adc_atten_t atten, uint32_t *val_mv) { if (!val_mv) { return; } switch (atten) { case ADC_ATTEN_DB_2_5: *val_mv = (*val_mv * 4) / 5; /* 1/ADC_GAIN_4_5 */ break; case ADC_ATTEN_DB_6: *val_mv = *val_mv >> 1; /* 1/ADC_GAIN_1_2 */ break; case ADC_ATTEN_DB_11: *val_mv = *val_mv / 4; /* 1/ADC_GAIN_1_4 */ break; case ADC_ATTEN_DB_0: /* 1/ADC_GAIN_1 */ default: break; } } #endif /* !defined(CONFIG_ADC_ESP32_DMA) */ static void adc_hw_calibration(adc_unit_t unit) { #if SOC_ADC_CALIBRATION_V1_SUPPORTED adc_hal_calibration_init(unit); for (int j = 0; j < SOC_ADC_ATTEN_NUM; j++) { adc_calc_hw_calibration_code(unit, j); #if SOC_ADC_CALIB_CHAN_COMPENS_SUPPORTED /* Load the channel compensation from efuse */ for (int k = 0; k < SOC_ADC_CHANNEL_NUM(unit); k++) { adc_load_hw_calibration_chan_compens(unit, k, j); } #endif /* SOC_ADC_CALIB_CHAN_COMPENS_SUPPORTED */ } #endif /* SOC_ADC_CALIBRATION_V1_SUPPORTED */ } static bool adc_calibration_init(const struct device *dev) { switch (esp_adc_cal_check_efuse(ADC_CALI_SCHEME)) { case ESP_ERR_NOT_SUPPORTED: LOG_WRN("Skip software calibration - Not supported!"); break; case ESP_ERR_INVALID_VERSION: LOG_WRN("Skip software calibration - Invalid version!"); break; case ESP_OK: LOG_DBG("Software calibration possible"); return true; default: LOG_ERR("Invalid arg"); break; } return false; } #if defined(CONFIG_ADC_ESP32_DMA) static void IRAM_ATTR adc_esp32_dma_conv_done(const struct device *dma_dev, void *user_data, uint32_t channel, int status) { ARG_UNUSED(dma_dev); ARG_UNUSED(status); const struct device *dev = user_data; struct adc_esp32_data *data = dev->data; k_sem_give(&data->dma_conv_wait_lock); } static int adc_esp32_dma_start(const struct device *dev, uint8_t *buf, size_t len) { const struct adc_esp32_conf *conf = dev->config; struct adc_esp32_data *data = dev->data; int err = 0; struct dma_config dma_cfg = {0}; struct dma_status dma_status = {0}; struct dma_block_config dma_blk = {0}; err = dma_get_status(conf->dma_dev, conf->dma_channel, &dma_status); if (err) { LOG_ERR("Unable to get dma channel[%u] status (%d)", (unsigned int)conf->dma_channel, err); return -EINVAL; } if (dma_status.busy) { LOG_ERR("dma channel[%u] is busy!", (unsigned int)conf->dma_channel); return -EBUSY; } unsigned int key = irq_lock(); dma_cfg.channel_direction = PERIPHERAL_TO_MEMORY; dma_cfg.dma_callback = adc_esp32_dma_conv_done; dma_cfg.user_data = (void *)dev; dma_cfg.dma_slot = ESP_GDMA_TRIG_PERIPH_ADC0; dma_cfg.block_count = 1; dma_cfg.head_block = &dma_blk; dma_blk.block_size = len; dma_blk.dest_address = (uint32_t)buf; err = dma_config(conf->dma_dev, conf->dma_channel, &dma_cfg); if (err) { LOG_ERR("Error configuring dma (%d)", err); goto unlock; } err = dma_start(conf->dma_dev, conf->dma_channel); if (err) { LOG_ERR("Error starting dma (%d)", err); goto unlock; } unlock: irq_unlock(key); return err; } static int adc_esp32_dma_stop(const struct device *dev) { const struct adc_esp32_conf *conf = dev->config; unsigned int key = irq_lock(); int err = 0; err = dma_stop(conf->dma_dev, conf->dma_channel); if (err) { LOG_ERR("Error stopping dma (%d)", err); } irq_unlock(key); return err; } static int adc_esp32_fill_digi_pattern(const struct device *dev, const struct adc_sequence *seq, void *pattern_config, uint32_t *pattern_len, uint32_t *unit_attenuation) { const struct adc_esp32_conf *conf = dev->config; struct adc_esp32_data *data = dev->data; adc_digi_pattern_config_t *adc_digi_pattern_config = (adc_digi_pattern_config_t *)pattern_config; const uint32_t unit_atten_uninit = 999; uint32_t channel_mask = 1, channels_copy = seq->channels; *pattern_len = 0; *unit_attenuation = unit_atten_uninit; for (uint8_t channel_id = 0; channel_id < conf->channel_count; channel_id++) { if (channels_copy & channel_mask) { if (*unit_attenuation == unit_atten_uninit) { *unit_attenuation = data->attenuation[channel_id]; } else if (*unit_attenuation != data->attenuation[channel_id]) { LOG_ERR("Channel[%u] attenuation different of unit[%u] attenuation", (unsigned int)channel_id, (unsigned int)conf->unit); return -EINVAL; } adc_digi_pattern_config->atten = data->attenuation[channel_id]; adc_digi_pattern_config->channel = channel_id; adc_digi_pattern_config->unit = conf->unit; adc_digi_pattern_config->bit_width = seq->resolution; adc_digi_pattern_config++; *pattern_len += 1; if (*pattern_len > SOC_ADC_PATT_LEN_MAX) { LOG_ERR("Max pattern len is %d", SOC_ADC_PATT_LEN_MAX); return -EINVAL; } channels_copy &= ~channel_mask; if (!channels_copy) { break; } } channel_mask <<= 1; } return 0; } static void adc_esp32_digi_start(const struct device *dev, void *pattern_config, uint32_t pattern_len, uint32_t number_of_samplings, uint32_t sample_freq_hz, uint32_t unit_attenuation) { const struct adc_esp32_conf *conf = dev->config; struct adc_esp32_data *data = dev->data; sar_periph_ctrl_adc_continuous_power_acquire(); adc_lock_acquire(conf->unit); #if SOC_ADC_CALIBRATION_V1_SUPPORTED adc_set_hw_calibration_code(conf->unit, unit_attenuation); #endif /* SOC_ADC_CALIBRATION_V1_SUPPORTED */ #if SOC_ADC_ARBITER_SUPPORTED if (conf->unit == ADC_UNIT_2) { adc_arbiter_t config = ADC_ARBITER_CONFIG_DEFAULT(); adc_hal_arbiter_config(&config); } #endif /* SOC_ADC_ARBITER_SUPPORTED */ adc_hal_digi_ctrlr_cfg_t adc_hal_digi_ctrlr_cfg; soc_module_clk_t clk_src = ADC_DIGI_CLK_SRC_DEFAULT; uint32_t clk_src_freq_hz = 0; esp_clk_tree_src_get_freq_hz(clk_src, ESP_CLK_TREE_SRC_FREQ_PRECISION_CACHED, &clk_src_freq_hz); adc_hal_digi_ctrlr_cfg.conv_mode = (conf->unit == ADC_UNIT_1)?ADC_CONV_SINGLE_UNIT_1:ADC_CONV_SINGLE_UNIT_2; adc_hal_digi_ctrlr_cfg.clk_src = clk_src; adc_hal_digi_ctrlr_cfg.clk_src_freq_hz = clk_src_freq_hz; adc_hal_digi_ctrlr_cfg.sample_freq_hz = sample_freq_hz; adc_hal_digi_ctrlr_cfg.adc_pattern = (adc_digi_pattern_config_t *)pattern_config; adc_hal_digi_ctrlr_cfg.adc_pattern_len = pattern_len; uint32_t number_of_adc_digi_samples = number_of_samplings * pattern_len; adc_hal_dma_config_t adc_hal_dma_config = { .dev = (void *)GDMA_LL_GET_HW(0), .eof_desc_num = 1, .eof_step = 1, .dma_chan = conf->dma_channel, .eof_num = number_of_adc_digi_samples, }; adc_hal_dma_ctx_config(&data->adc_hal_dma_ctx, &adc_hal_dma_config); adc_hal_set_controller(conf->unit, ADC_HAL_CONTINUOUS_READ_MODE); adc_hal_digi_init(&data->adc_hal_dma_ctx); adc_hal_digi_controller_config(&data->adc_hal_dma_ctx, &adc_hal_digi_ctrlr_cfg); adc_hal_digi_start(&data->adc_hal_dma_ctx, data->dma_buffer); } static void adc_esp32_digi_stop(const struct device *dev) { const struct adc_esp32_conf *conf = dev->config; struct adc_esp32_data *data = dev->data; adc_hal_digi_dis_intr(&data->adc_hal_dma_ctx, ADC_HAL_DMA_INTR_MASK); adc_hal_digi_clr_intr(&data->adc_hal_dma_ctx, ADC_HAL_DMA_INTR_MASK); adc_hal_digi_stop(&data->adc_hal_dma_ctx); adc_hal_digi_deinit(&data->adc_hal_dma_ctx); adc_lock_release(conf->unit); sar_periph_ctrl_adc_continuous_power_release(); } static void adc_esp32_fill_seq_buffer(const void *seq_buffer, const void *dma_buffer, uint32_t number_of_samples) { uint16_t *sample = (uint16_t *)seq_buffer; adc_digi_output_data_t *digi_data = (adc_digi_output_data_t *)dma_buffer; for (uint32_t k = 0; k < number_of_samples; k++) { *sample++ = (uint16_t)(digi_data++)->type2.data; } } static int adc_esp32_wait_for_dma_conv_done(const struct device *dev) { struct adc_esp32_data *data = dev->data; int err = 0; err = k_sem_take(&data->dma_conv_wait_lock, K_FOREVER); if (err) { LOG_ERR("Error taking dma_conv_wait_lock (%d)", err); } return err; } #endif /* defined(CONFIG_ADC_ESP32_DMA) */ static int adc_esp32_read(const struct device *dev, const struct adc_sequence *seq) { const struct adc_esp32_conf *conf = dev->config; struct adc_esp32_data *data = dev->data; int reading; uint32_t cal, cal_mv; uint8_t channel_id = find_lsb_set(seq->channels) - 1; if (seq->buffer_size < 2) { LOG_ERR("Sequence buffer space too low '%d'", seq->buffer_size); return -ENOMEM; } #if !defined(CONFIG_ADC_ESP32_DMA) if (seq->channels > BIT(channel_id)) { LOG_ERR("Multi-channel readings not supported"); return -ENOTSUP; } #endif /* !defined(CONFIG_ADC_ESP32_DMA) */ if (seq->options) { if (seq->options->extra_samplings) { LOG_ERR("Extra samplings not supported"); return -ENOTSUP; } #if !defined(CONFIG_ADC_ESP32_DMA) if (seq->options->interval_us) { LOG_ERR("Interval between samplings not supported"); return -ENOTSUP; } #endif /* !defined(CONFIG_ADC_ESP32_DMA) */ } if (INVALID_RESOLUTION(seq->resolution)) { LOG_ERR("unsupported resolution (%d)", seq->resolution); return -ENOTSUP; } if (seq->calibrate) { /* TODO: Does this mean actual Vref measurement on selected GPIO ?*/ LOG_ERR("calibration is not supported"); return -ENOTSUP; } data->resolution[channel_id] = seq->resolution; #if CONFIG_SOC_SERIES_ESP32C3 /* NOTE: nothing to set on ESP32C3 SoC */ if (conf->unit == ADC_UNIT_1) { adc1_config_width(ADC_WIDTH_BIT_DEFAULT); } #else adc_set_data_width(conf->unit, data->resolution[channel_id]); #endif /* CONFIG_SOC_SERIES_ESP32C3 */ #if !defined(CONFIG_ADC_ESP32_DMA) /* Read raw value */ if (conf->unit == ADC_UNIT_1) { reading = adc1_get_raw(channel_id); } if (conf->unit == ADC_UNIT_2) { if (adc2_get_raw(channel_id, ADC_WIDTH_BIT_DEFAULT, &reading)) { LOG_ERR("Conversion timeout on '%s' channel %d", dev->name, channel_id); return -ETIMEDOUT; } } /* Calibration scheme is available */ if (data->calibrate) { data->chars[channel_id].bit_width = data->resolution[channel_id]; /* Get corrected voltage output */ cal = cal_mv = esp_adc_cal_raw_to_voltage(reading, &data->chars[channel_id]); #if CONFIG_SOC_SERIES_ESP32 if (data->attenuation[channel_id] == ADC_ATTEN_DB_11) { if (cal > ADC_CLIP_MVOLT_11DB) { cal = ADC_CLIP_MVOLT_11DB; } } #endif /* CONFIG_SOC_SERIES_ESP32 */ /* Fit according to selected attenuation */ atten_to_gain(data->attenuation[channel_id], &cal); if (data->meas_ref_internal > 0) { cal = (cal << data->resolution[channel_id]) / data->meas_ref_internal; } } else { LOG_DBG("Using uncalibrated values!"); /* Uncalibrated raw value */ cal = reading; } /* Store result */ data->buffer = (uint16_t *) seq->buffer; data->buffer[0] = cal; #else /* !defined(CONFIG_ADC_ESP32_DMA) */ int err = 0; uint32_t adc_pattern_len, unit_attenuation; adc_digi_pattern_config_t adc_digi_pattern_config[SOC_ADC_MAX_CHANNEL_NUM]; err = adc_esp32_fill_digi_pattern(dev, seq, &adc_digi_pattern_config, &adc_pattern_len, &unit_attenuation); if (err || adc_pattern_len == 0) { return -EINVAL; } const struct adc_sequence_options *options = seq->options; uint32_t sample_freq_hz = SOC_ADC_SAMPLE_FREQ_THRES_HIGH, number_of_samplings = 1; if (options != NULL) { number_of_samplings = seq->buffer_size / (adc_pattern_len * sizeof(uint16_t)); if (options->interval_us) { sample_freq_hz = MHZ(1) / options->interval_us; } } if (!number_of_samplings) { LOG_ERR("buffer_size insufficient to store at least one set of samples!"); return -EINVAL; } if (sample_freq_hz < SOC_ADC_SAMPLE_FREQ_THRES_LOW || sample_freq_hz > SOC_ADC_SAMPLE_FREQ_THRES_HIGH) { LOG_ERR("ADC sampling frequency out of range: %uHz", sample_freq_hz); return -EINVAL; } uint32_t number_of_adc_samples = number_of_samplings * adc_pattern_len; uint32_t number_of_adc_dma_data_bytes = number_of_adc_samples * SOC_ADC_DIGI_DATA_BYTES_PER_CONV; if (number_of_adc_dma_data_bytes > ADC_DMA_BUFFER_SIZE) { LOG_ERR("dma buffer size insufficient to store a complete sequence!"); return -EINVAL; } err = adc_esp32_dma_start(dev, data->dma_buffer, number_of_adc_dma_data_bytes); if (err) { return err; } adc_esp32_digi_start(dev, &adc_digi_pattern_config, adc_pattern_len, number_of_samplings, sample_freq_hz, unit_attenuation); err = adc_esp32_wait_for_dma_conv_done(dev); if (err) { return err; } adc_esp32_digi_stop(dev); err = adc_esp32_dma_stop(dev); if (err) { return err; } adc_esp32_fill_seq_buffer(seq->buffer, data->dma_buffer, number_of_adc_samples); #endif /* !defined(CONFIG_ADC_ESP32_DMA) */ return 0; } #ifdef CONFIG_ADC_ASYNC static int adc_esp32_read_async(const struct device *dev, const struct adc_sequence *sequence, struct k_poll_signal *async) { (void)(dev); (void)(sequence); (void)(async); return -ENOTSUP; } #endif /* CONFIG_ADC_ASYNC */ static int adc_esp32_channel_setup(const struct device *dev, const struct adc_channel_cfg *cfg) { const struct adc_esp32_conf *conf = (const struct adc_esp32_conf *)dev->config; struct adc_esp32_data *data = (struct adc_esp32_data *) dev->data; if (cfg->channel_id >= conf->channel_count) { LOG_ERR("Unsupported channel id '%d'", cfg->channel_id); return -ENOTSUP; } if (cfg->reference != ADC_REF_INTERNAL) { LOG_ERR("Unsupported channel reference '%d'", cfg->reference); return -ENOTSUP; } if (cfg->acquisition_time != ADC_ACQ_TIME_DEFAULT) { LOG_ERR("Unsupported acquisition_time '%d'", cfg->acquisition_time); return -ENOTSUP; } if (cfg->differential) { LOG_ERR("Differential channels are not supported"); return -ENOTSUP; } if (gain_to_atten(cfg->gain, &data->attenuation[cfg->channel_id])) { LOG_ERR("Unsupported gain value '%d'", cfg->gain); return -ENOTSUP; } /* Prepare channel */ if (conf->unit == ADC_UNIT_1) { adc1_config_channel_atten(cfg->channel_id, data->attenuation[cfg->channel_id]); } if (conf->unit == ADC_UNIT_2) { adc2_config_channel_atten(cfg->channel_id, data->attenuation[cfg->channel_id]); } if (data->calibrate) { esp_adc_cal_value_t cal = esp_adc_cal_characterize(conf->unit, data->attenuation[cfg->channel_id], data->resolution[cfg->channel_id], data->meas_ref_internal, &data->chars[cfg->channel_id]); if (cal >= ESP_ADC_CAL_VAL_NOT_SUPPORTED) { LOG_ERR("Calibration error or not supported"); return -EIO; } LOG_DBG("Using ADC calibration method %d", cal); } #if defined(CONFIG_ADC_ESP32_DMA) if (!SOC_ADC_DIG_SUPPORTED_UNIT(conf->unit)) { LOG_ERR("ADC2 dma mode is no longer supported, please use ADC1!"); return -EINVAL; } int io_num = adc_channel_io_map[conf->unit][cfg->channel_id]; if (io_num < 0) { LOG_ERR("Channel %u not supported!", cfg->channel_id); return -ENOTSUP; } struct gpio_dt_spec gpio = { .port = conf->gpio_port, .dt_flags = 0, .pin = io_num, }; int err = gpio_pin_configure_dt(&gpio, GPIO_DISCONNECTED); if (err) { LOG_ERR("Error disconnecting io (%d)", io_num); return err; } #endif /* defined(CONFIG_ADC_ESP32_DMA) */ return 0; } static int adc_esp32_init(const struct device *dev) { struct adc_esp32_data *data = (struct adc_esp32_data *) dev->data; const struct adc_esp32_conf *conf = (struct adc_esp32_conf *) dev->config; adc_hw_calibration(conf->unit); #if CONFIG_SOC_SERIES_ESP32S2 || CONFIG_SOC_SERIES_ESP32C3 if (conf->unit == ADC_UNIT_2) { adc2_init_code_calibration(); } #endif /* CONFIG_SOC_SERIES_ESP32S2 || CONFIG_SOC_SERIES_ESP32C3 */ #if defined(CONFIG_ADC_ESP32_DMA) if (!device_is_ready(conf->gpio_port)) { LOG_ERR("gpio0 port not ready"); return -ENODEV; } if (k_sem_init(&data->dma_conv_wait_lock, 0, 1)) { LOG_ERR("dma_conv_wait_lock initialization failed!"); return -EINVAL; } data->adc_hal_dma_ctx.rx_desc = k_aligned_alloc(sizeof(uint32_t), sizeof(dma_descriptor_t)); if (!data->adc_hal_dma_ctx.rx_desc) { LOG_ERR("rx_desc allocation failed!"); return -ENOMEM; } LOG_DBG("rx_desc = 0x%08X", (unsigned int)data->adc_hal_dma_ctx.rx_desc); data->dma_buffer = k_aligned_alloc(sizeof(uint32_t), ADC_DMA_BUFFER_SIZE); if (!data->dma_buffer) { LOG_ERR("dma buffer allocation failed!"); k_free(data->adc_hal_dma_ctx.rx_desc); return -ENOMEM; } LOG_DBG("data->dma_buffer = 0x%08X", (unsigned int)data->dma_buffer); #endif /* defined(CONFIG_ADC_ESP32_DMA) */ for (uint8_t i = 0; i < ARRAY_SIZE(data->resolution); i++) { data->resolution[i] = ADC_RESOLUTION_MAX; } for (uint8_t i = 0; i < ARRAY_SIZE(data->attenuation); i++) { data->attenuation[i] = ADC_ATTEN_DB_0; } /* Default reference voltage. This could be calibrated externaly */ data->meas_ref_internal = ADC_ESP32_DEFAULT_VREF_INTERNAL; /* Check if calibration is possible */ data->calibrate = adc_calibration_init(dev); return 0; } static const struct adc_driver_api api_esp32_driver_api = { .channel_setup = adc_esp32_channel_setup, .read = adc_esp32_read, #ifdef CONFIG_ADC_ASYNC .read_async = adc_esp32_read_async, #endif /* CONFIG_ADC_ASYNC */ .ref_internal = ADC_ESP32_DEFAULT_VREF_INTERNAL, }; #if defined(CONFIG_ADC_ESP32_DMA) #define ADC_ESP32_CONF_GPIO_PORT_INIT .gpio_port = DEVICE_DT_GET(DT_NODELABEL(gpio0)), #define ADC_ESP32_CONF_DMA_INIT(n) .dma_dev = COND_CODE_1(DT_INST_NODE_HAS_PROP(n, dmas), \ (DEVICE_DT_GET(DT_INST_DMAS_CTLR_BY_IDX(n, 0))), \ (NULL)), \ .dma_channel = COND_CODE_1(DT_INST_NODE_HAS_PROP(n, dmas), \ (DT_INST_DMAS_CELL_BY_IDX(n, 0, channel)), \ (0xff)), #else #define ADC_ESP32_CONF_GPIO_PORT_INIT #define ADC_ESP32_CONF_DMA_INIT(inst) #endif /* defined(CONFIG_ADC_ESP32_DMA) */ #define ESP32_ADC_INIT(inst) \ \ static const struct adc_esp32_conf adc_esp32_conf_##inst = { \ .unit = DT_PROP(DT_DRV_INST(inst), unit) - 1, \ .channel_count = DT_PROP(DT_DRV_INST(inst), channel_count), \ ADC_ESP32_CONF_GPIO_PORT_INIT \ ADC_ESP32_CONF_DMA_INIT(inst) \ }; \ \ static struct adc_esp32_data adc_esp32_data_##inst = { \ }; \ \ DEVICE_DT_INST_DEFINE(inst, &adc_esp32_init, NULL, \ &adc_esp32_data_##inst, \ &adc_esp32_conf_##inst, \ POST_KERNEL, \ CONFIG_ADC_INIT_PRIORITY, \ &api_esp32_driver_api); DT_INST_FOREACH_STATUS_OKAY(ESP32_ADC_INIT)