// Copyright 2015-2020 Espressif Systems (Shanghai) PTE LTD // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. /* Tests for the adc device driver */ #include "esp_system.h" #include "esp_intr_alloc.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "freertos/queue.h" #include "driver/adc.h" #include "driver/dac.h" #include "driver/rtc_io.h" #include "driver/gpio.h" #include "unity.h" #include "esp_system.h" #include "esp_event.h" #include "esp_wifi.h" #include "esp_log.h" #include "nvs_flash.h" #include "test_utils.h" #include "soc/adc_periph.h" #include "test/test_common_adc.h" #include "esp_rom_sys.h" #if !DISABLED_FOR_TARGETS(ESP8266, ESP32, ESP32S3) // This testcase for ESP32S2 #include "soc/system_reg.h" #include "soc/spi_reg.h" #include "soc/soc.h" #include "soc/lldesc.h" #include "test/test_adc_dac_dma.h" static const char *TAG = "test_adc"; #define PLATFORM_SELECT (1) //0: pxp; 1: chip #if (PLATFORM_SELECT == 0) //PXP platform #include "soc/apb_ctrl_reg.h" #define SET_BREAK_POINT(flag) REG_WRITE(APB_CTRL_DATE_REG, flag) //PXP clk is slower. #define SYS_DELAY_TIME_MOM (1/40) #define RTC_SLOW_CLK_FLAG 1 // Slow clock is 32KHz. static void test_pxp_deinit_io(void) { for (int i = 0; i < 22; i++) { rtc_gpio_init(i); } } #else //PXP clk is slower. #define SET_BREAK_POINT(flag) #define SYS_DELAY_TIME_MOM (1) #define RTC_SLOW_CLK_FLAG 0 // Slow clock is 32KHz. #endif #define ADC_REG_BASE_TEST() ({ \ TEST_ASSERT_EQUAL_UINT32(REG_GET_FIELD(APB_SARADC_APB_CTRL_DATE_REG, APB_SARADC_APB_CTRL_DATE), APB_SARADC.apb_ctrl_date); \ TEST_ASSERT_EQUAL_UINT32(REG_GET_FIELD(SENS_SARDATE_REG, SENS_SAR_DATE), SENS.sardate.sar_date); \ TEST_ASSERT_EQUAL_UINT32(REG_GET_FIELD(RTC_IO_DATE_REG, RTC_IO_IO_DATE), RTCIO.date.date); \ }) /** Sample rate = APB_CLK(80 MHz) / (CLK_DIV + 1) / TRIGGER_INTERVAL / 2. */ #define TEST_ADC_TRIGGER_INTERVAL_DEFAULT (40) #define TEST_ADC_DIGI_CLK_DIV_DEFAULT (9) static uint8_t adc_test_num = 9; static adc_channel_t adc_list[SOC_ADC_PATT_LEN_MAX] = { ADC_CHANNEL_0, ADC_CHANNEL_1, ADC_CHANNEL_2, ADC_CHANNEL_3, ADC_CHANNEL_4, ADC_CHANNEL_5, ADC_CHANNEL_6, // ADC_CHANNEL_7, // Workaround: IO18 is pullup outside in ESP32S2-Saola Runner. ADC_CHANNEL_8, ADC_CHANNEL_9, }; /* For ESP32S2, it should use same atten, or, it will have error. */ #define TEST_ADC_ATTEN_DEFAULT (ADC_ATTEN_11db) extern esp_err_t adc_digi_reset(void); /* Work mode. * single: eof_num; * double: SAR_EOF_NUMBER/2; * alter: eof_num; * */ #define SAR_SIMPLE_NUM 512 // Set sample number of enabled unit. /* Use two DMA linker to save ADC data. ADC sample 1 times -> 2 byte data -> 2 DMA link buf. */ #define SAR_DMA_DATA_SIZE(unit, sample_num) (SAR_EOF_NUMBER(unit, sample_num)) #define SAR_EOF_NUMBER(unit, sample_num) ((sample_num) * (unit)) #define SAR_MEAS_LIMIT_NUM(unit, sample_num) (SAR_SIMPLE_NUM) #define SAR_SIMPLE_TIMEOUT_MS 1000 typedef struct dma_msg { uint32_t int_msk; uint8_t *data; uint32_t data_len; } adc_dma_event_t; static uint8_t link_buf[2][SAR_DMA_DATA_SIZE(2, SAR_SIMPLE_NUM)] = {0}; static lldesc_t dma1 = {0}; static lldesc_t dma2 = {0}; static QueueHandle_t que_adc = NULL; static adc_dma_event_t adc_evt; /** ADC-DMA ISR handler. */ static IRAM_ATTR void adc_dma_isr(void *arg) { uint32_t int_st = REG_READ(SPI_DMA_INT_ST_REG(3)); int task_awoken = pdFALSE; REG_WRITE(SPI_DMA_INT_CLR_REG(3), int_st); if (int_st & SPI_IN_SUC_EOF_INT_ST_M) { adc_evt.int_msk = int_st; xQueueSendFromISR(que_adc, &adc_evt, &task_awoken); } if (int_st & SPI_IN_DONE_INT_ST) { adc_evt.int_msk = int_st; xQueueSendFromISR(que_adc, &adc_evt, &task_awoken); } ESP_EARLY_LOGV(TAG, "int msk%x\n", int_st); if (task_awoken == pdTRUE) { portYIELD_FROM_ISR(); } } /** * DMA liner initialization and start. * @param is_loop * - true: The two dma linked lists are connected end to end, with no end mark (eof). * - false: The two dma linked lists are connected end to end, with end mark (eof). */ static uint32_t adc_dma_linker_init(adc_unit_t adc, bool is_loop) { dma1 = (lldesc_t) { .size = SAR_DMA_DATA_SIZE((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM), .owner = 1, .buf = &link_buf[0][0], .qe.stqe_next = &dma2, }; dma2 = (lldesc_t) { .size = SAR_DMA_DATA_SIZE((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM), .owner = 1, .buf = &link_buf[1][0], }; if (is_loop) { dma2.qe.stqe_next = &dma1; } else { dma2.qe.stqe_next = NULL; } return (uint32_t)&dma1; } #define DEBUG_CHECK_ENABLE 1 #define DEBUG_PRINT_ENABLE 1 #define DEBUG_CHECK_ERROR 10 /** * Check the ADC-DMA data in linker buffer by input level. * ideal_level * - -1: Don't check data. * - 0: ADC channel voltage is 0v. * - 1: ADC channel voltage is 3.3v. * - 2: ADC channel voltage is 1.4v. */ static esp_err_t adc_dma_data_check(adc_unit_t adc, int ideal_level) { int unit_old = 1; int ch_cnt = 0; for (int cnt = 0; cnt < 2; cnt++) { esp_rom_printf("\n[%s] link_buf[%d]: \n", __func__, cnt % 2); for (int i = 0; i < SAR_DMA_DATA_SIZE((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM); i += 2) { uint8_t h = link_buf[cnt % 2][i + 1], l = link_buf[cnt % 2][i]; uint16_t temp = (h << 8 | l); adc_digi_output_data_t *data = (adc_digi_output_data_t *)&temp; if (adc > ADC_UNIT_2) { //ADC_ENCODE_11BIT #if DEBUG_PRINT_ENABLE if (i % 16 == 0) { esp_rom_printf("\n"); } esp_rom_printf("[%d_%d_%04x] ", data->type2.unit, data->type2.channel, data->type2.data); #endif #if DEBUG_CHECK_ENABLE if (ideal_level >= 0) { TEST_ASSERT_NOT_EQUAL(unit_old, data->type2.unit); unit_old = data->type2.unit; if (data->type2.channel > ADC_CHANNEL_MAX) { printf("Data invalid [%d]\n", data->type2.channel); continue; } int cur_ch = ((ch_cnt++ / 2) % adc_test_num); TEST_ASSERT_EQUAL( data->type2.channel, adc_list[cur_ch] ); } if (ideal_level == 1) { // high level 3.3v TEST_ASSERT_EQUAL( 0x7FF, data->type2.data ); } else if (ideal_level == 0) { // low level 0v TEST_ASSERT_LESS_THAN( 10, data->type2.data ); } else if (ideal_level == 2) { // middle level 1.4v TEST_ASSERT_INT_WITHIN( 128, 1100, data->type2.data ); } else if (ideal_level == 3) { // normal level } else { // no check } #endif } else { //ADC_ENCODE_12BIT #if DEBUG_PRINT_ENABLE if (i % 16 == 0) { esp_rom_printf("\n"); } esp_rom_printf("[%d_%04x] ", data->type1.channel, data->type1.data); #endif #if DEBUG_CHECK_ENABLE if (ideal_level >= 0) { int cur_ch = ((ch_cnt++) % adc_test_num); TEST_ASSERT_EQUAL( adc_list[cur_ch], data->type1.channel ); } if (ideal_level == 1) { // high level 3.3v TEST_ASSERT_EQUAL( 0XFFF, data->type1.data ); } else if (ideal_level == 0) { // low level 0v TEST_ASSERT_LESS_THAN( 10, data->type1.data ); } else if (ideal_level == 2) { // middle level 1.4v TEST_ASSERT_INT_WITHIN( 256, 2200, data->type1.data ); } else if (ideal_level == 3) { // normal level } else { // no check } #endif } link_buf[cnt % 2][i] = 0; link_buf[cnt % 2][i + 1] = 0; } esp_rom_printf("\n"); } return ESP_OK; } static esp_err_t adc_dma_data_multi_st_check(adc_unit_t adc, void *dma_addr, uint32_t int_mask) { adc_dma_event_t evt; ESP_LOGI(TAG, "adc IO normal, test ..."); for (int i = 0; i < adc_test_num; i++) { adc_io_normal(adc, adc_list[i]); } TEST_ESP_OK( adc_digi_start() ); while (1) { TEST_ASSERT_EQUAL( xQueueReceive(que_adc, &evt, SAR_SIMPLE_TIMEOUT_MS / portTICK_RATE_MS), pdTRUE ); if (evt.int_msk & SPI_IN_SUC_EOF_INT_ENA) { break; } } TEST_ESP_OK( adc_digi_stop() ); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); adc_digi_reset(); TEST_ESP_OK( adc_dma_data_check(adc, -1) ); // Don't check data. ESP_LOGI(TAG, "adc IO fake tie high, test ..."); for (int i = 0; i < adc_test_num; i++) { adc_fake_tie_high(adc, adc_list[i]); } TEST_ESP_OK( adc_digi_start() ); while (1) { TEST_ASSERT_EQUAL( xQueueReceive(que_adc, &evt, SAR_SIMPLE_TIMEOUT_MS / portTICK_RATE_MS), pdTRUE ); if (evt.int_msk & SPI_IN_SUC_EOF_INT_ENA) { break; } } TEST_ESP_OK( adc_digi_stop() ); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); adc_digi_reset(); TEST_ESP_OK( adc_dma_data_check(adc, 1) ); ESP_LOGI(TAG, "adc IO fake tie low, test ..."); for (int i = 0; i < adc_test_num; i++) { adc_fake_tie_low(adc, adc_list[i]); } TEST_ESP_OK( adc_digi_start() ); while (1) { TEST_ASSERT_EQUAL( xQueueReceive(que_adc, &evt, SAR_SIMPLE_TIMEOUT_MS / portTICK_RATE_MS), pdTRUE ); if (evt.int_msk & SPI_IN_SUC_EOF_INT_ENA) { break; } } TEST_ESP_OK( adc_digi_stop() ); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); adc_digi_reset(); TEST_ESP_OK( adc_dma_data_check(adc, 0) ); ESP_LOGI(TAG, "adc IO fake tie middle, test ..."); for (int i = 0; i < adc_test_num; i++) { adc_fake_tie_middle(adc, adc_list[i]); } TEST_ESP_OK( adc_digi_start() ); while (1) { TEST_ASSERT_EQUAL( xQueueReceive(que_adc, &evt, SAR_SIMPLE_TIMEOUT_MS / portTICK_RATE_MS), pdTRUE ); if (evt.int_msk & SPI_IN_SUC_EOF_INT_ENA) { break; } } TEST_ESP_OK( adc_digi_stop() ); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); adc_digi_reset(); TEST_ESP_OK( adc_dma_data_check(adc, 2) ); return ESP_OK; } #include "soc/apb_saradc_struct.h" /** * Test the partten table setting. It's easy wrong. * * @param adc_n ADC unit. * @param in_partten_len The length of partten be set. * @param in_last_ch The channel number of the last message. */ static esp_err_t adc_check_patt_table(adc_unit_t adc, uint32_t in_partten_len, adc_channel_t in_last_ch) { esp_err_t ret = ESP_FAIL; uint8_t index = (in_partten_len - 1) / 4; uint8_t offset = 24 - ((in_partten_len - 1) % 4) * 8; uint32_t temp = 0, len; if (adc & ADC_UNIT_1) { len = APB_SARADC.ctrl.sar1_patt_len + 1; temp = APB_SARADC.sar1_patt_tab[index]; printf("patt1 len %d\n", len); printf("patt1 0x%08x\n", APB_SARADC.sar1_patt_tab[0]); printf("patt1 0x%08x\n", APB_SARADC.sar1_patt_tab[1]); printf("patt1 0x%08x\n", APB_SARADC.sar1_patt_tab[2]); printf("patt1 0x%08x\n", APB_SARADC.sar1_patt_tab[3]); if (in_partten_len == len) { if (in_last_ch == (((temp >> (offset + 4))) & 0xf)) { ret = ESP_OK; } } } if (adc & ADC_UNIT_2) { len = APB_SARADC.ctrl.sar2_patt_len + 1; temp = APB_SARADC.sar2_patt_tab[index]; printf("patt2 len %d\n", len); printf("patt2 0x%08x\n", APB_SARADC.sar2_patt_tab[0]); printf("patt2 0x%08x\n", APB_SARADC.sar2_patt_tab[1]); printf("patt2 0x%08x\n", APB_SARADC.sar2_patt_tab[2]); printf("patt2 0x%08x\n", APB_SARADC.sar2_patt_tab[3]); if (in_partten_len == len) { if (in_last_ch == (((temp >> (offset + 4))) & 0xf)) { ret = ESP_OK; } } } return ret; } /** * Testcase: Check the base function of ADC-DMA. Include: * - Various conversion modes. * - Whether the channel and data are lost. * - Whether the data is the same as the channel voltage. */ int test_adc_dig_dma_single_unit(adc_unit_t adc) { ESP_LOGI(TAG, " >> %s << ", __func__); ESP_LOGI(TAG, " >> adc unit: %x << ", adc); TEST_ESP_OK( adc_digi_init() ); /* arbiter config */ adc_arbiter_t arb_cfg = { .mode = ADC_ARB_MODE_FIX, .dig_pri = 0, .pwdet_pri = 2, .rtc_pri = 1, }; TEST_ESP_OK( adc_arbiter_config(ADC_UNIT_2, &arb_cfg) ); // If you want use force adc_digi_config_t config = { .conv_limit_en = false, .conv_limit_num = 0, .interval = TEST_ADC_TRIGGER_INTERVAL_DEFAULT, .dig_clk.use_apll = 0, // APB clk .dig_clk.div_num = TEST_ADC_DIGI_CLK_DIV_DEFAULT, .dig_clk.div_b = 0, .dig_clk.div_a = 0, .dma_eof_num = SAR_EOF_NUMBER((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM), }; /* Config pattern table */ adc_digi_pattern_table_t adc1_patt[SOC_ADC_PATT_LEN_MAX] = {0}; adc_digi_pattern_table_t adc2_patt[SOC_ADC_PATT_LEN_MAX] = {0}; if (adc & ADC_UNIT_1) { config.adc1_pattern_len = adc_test_num; config.adc1_pattern = adc1_patt; for (int i = 0; i < adc_test_num; i++) { adc1_patt[i].atten = TEST_ADC_ATTEN_DEFAULT; adc1_patt[i].channel = adc_list[i]; adc_gpio_init(ADC_UNIT_1, adc_list[i]); } } if (adc & ADC_UNIT_2) { config.adc2_pattern_len = adc_test_num; config.adc2_pattern = adc2_patt; for (int i = 0; i < adc_test_num; i++) { adc2_patt[i].atten = TEST_ADC_ATTEN_DEFAULT; adc2_patt[i].channel = adc_list[i]; adc_gpio_init(ADC_UNIT_2, adc_list[i]); } } if (adc == ADC_UNIT_1) { config.conv_mode = ADC_CONV_SINGLE_UNIT_1; config.format = ADC_DIGI_FORMAT_12BIT; } else if (adc == ADC_UNIT_2) { config.conv_mode = ADC_CONV_SINGLE_UNIT_2; config.format = ADC_DIGI_FORMAT_12BIT; } else if (adc == ADC_UNIT_BOTH) { config.conv_mode = ADC_CONV_BOTH_UNIT; config.format = ADC_DIGI_FORMAT_11BIT; } else if (adc == ADC_UNIT_ALTER) { config.conv_mode = ADC_CONV_ALTER_UNIT; config.format = ADC_DIGI_FORMAT_11BIT; } TEST_ESP_OK( adc_digi_controller_config(&config) ); /* ADC-DMA linker init */ if (que_adc == NULL) { que_adc = xQueueCreate(5, sizeof(adc_dma_event_t)); } else { xQueueReset(que_adc); } uint32_t int_mask = SPI_IN_SUC_EOF_INT_ENA; uint32_t dma_addr = adc_dma_linker_init(adc, false); adc_dac_dma_isr_register(adc_dma_isr, NULL, int_mask); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); TEST_ESP_OK( adc_check_patt_table(adc, adc_test_num, adc_list[adc_test_num - 1]) ); adc_dma_data_multi_st_check(adc, (void *)dma_addr, int_mask); adc_dac_dma_linker_deinit(); adc_dac_dma_isr_deregister(adc_dma_isr, NULL); TEST_ESP_OK( adc_digi_deinit() ); return 0; } TEST_CASE("ADC DMA single read", "[ADC]") { test_adc_dig_dma_single_unit(ADC_UNIT_BOTH); test_adc_dig_dma_single_unit(ADC_UNIT_ALTER); test_adc_dig_dma_single_unit(ADC_UNIT_1); test_adc_dig_dma_single_unit(ADC_UNIT_2); } #include "touch_scope.h" /** * 0: ADC1 channels raw data debug. * 1: ADC2 channels raw data debug. * 2: ADC1 one channel raw data debug. */ #define SCOPE_DEBUG_TYPE 0 #define SCOPE_DEBUG_CHANNEL_MAX (10) #define SCOPE_DEBUG_ENABLE (0) #define SCOPE_UART_BUADRATE (256000) #define SCOPE_DEBUG_FREQ_MS (50) #define SCOPE_OUTPUT_UART (0) static float scope_temp[SCOPE_DEBUG_CHANNEL_MAX] = {0}; // max scope channel is 10. int test_adc_dig_scope_debug_unit(adc_unit_t adc) { ESP_LOGI(TAG, " >> %s << ", __func__); ESP_LOGI(TAG, " >> adc unit: %x << ", adc); TEST_ESP_OK( adc_digi_init() ); if (adc & ADC_UNIT_2) { /* arbiter config */ adc_arbiter_t arb_cfg = { .mode = ADC_ARB_MODE_FIX, .dig_pri = 0, .pwdet_pri = 2, .rtc_pri = 1, }; TEST_ESP_OK( adc_arbiter_config(ADC_UNIT_2, &arb_cfg) ); // If you want use force } adc_digi_config_t config = { .conv_limit_en = false, .conv_limit_num = 0, .interval = TEST_ADC_TRIGGER_INTERVAL_DEFAULT, .dig_clk.use_apll = 0, // APB clk .dig_clk.div_num = TEST_ADC_DIGI_CLK_DIV_DEFAULT, .dig_clk.div_a = 0, .dig_clk.div_b = 0, .dma_eof_num = SAR_EOF_NUMBER((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM), }; /* Config pattern table */ adc_digi_pattern_table_t adc1_patt[SOC_ADC_PATT_LEN_MAX] = {0}; adc_digi_pattern_table_t adc2_patt[SOC_ADC_PATT_LEN_MAX] = {0}; if (adc & ADC_UNIT_1) { config.adc1_pattern_len = adc_test_num; config.adc1_pattern = adc1_patt; for (int i = 0; i < adc_test_num; i++) { adc1_patt[i].atten = TEST_ADC_ATTEN_DEFAULT; adc1_patt[i].channel = adc_list[i]; adc_gpio_init(ADC_UNIT_1, adc_list[i]); } } if (adc & ADC_UNIT_2) { config.adc2_pattern_len = adc_test_num; config.adc2_pattern = adc2_patt; for (int i = 0; i < adc_test_num; i++) { adc2_patt[i].atten = TEST_ADC_ATTEN_DEFAULT; adc2_patt[i].channel = adc_list[i]; adc_gpio_init(ADC_UNIT_2, adc_list[i]); } } if (adc == ADC_UNIT_1) { config.conv_mode = ADC_CONV_SINGLE_UNIT_1; config.format = ADC_DIGI_FORMAT_12BIT; } else if (adc == ADC_UNIT_2) { config.conv_mode = ADC_CONV_SINGLE_UNIT_2; config.format = ADC_DIGI_FORMAT_12BIT; } else if (adc == ADC_UNIT_BOTH) { config.conv_mode = ADC_CONV_BOTH_UNIT; config.format = ADC_DIGI_FORMAT_11BIT; } else if (adc == ADC_UNIT_ALTER) { config.conv_mode = ADC_CONV_ALTER_UNIT; config.format = ADC_DIGI_FORMAT_11BIT; } TEST_ESP_OK( adc_digi_controller_config(&config) ); /* ADC-DMA linker init */ if (que_adc == NULL) { que_adc = xQueueCreate(5, sizeof(adc_dma_event_t)); } else { xQueueReset(que_adc); } uint32_t int_mask = SPI_IN_SUC_EOF_INT_ENA; uint32_t dma_addr = adc_dma_linker_init(adc, false); adc_dac_dma_isr_register(adc_dma_isr, NULL, int_mask); adc_dac_dma_linker_start(DMA_ONLY_ADC_INLINK, (void *)dma_addr, int_mask); ESP_LOGI(TAG, "adc IO fake tie middle, test ..."); for (int i = 0; i < adc_test_num; i++) { adc_fake_tie_middle(adc, adc_list[i]); } return 0; } static void scope_output(int adc_num, int channel, int data) { /** can replace by uart log.*/ #if SCOPE_OUTPUT_UART static int icnt = 0; if (icnt++ % 8 == 0) { esp_rom_printf("\n"); } esp_rom_printf("[%d_%d_%04x] ", adc_num, channel, data); return; #endif #if SCOPE_DEBUG_TYPE == 0 if (adc_num != 0) { return; } #elif SCOPE_DEBUG_TYPE == 1 if (adc_num != 1) { return; } #endif int i; /* adc Read */ for (i = 0; i < adc_test_num; i++) { if (adc_list[i] == channel && scope_temp[i] == 0) { scope_temp[i] = data; break; } } if (i == adc_test_num) { test_tp_print_to_scope(scope_temp, adc_test_num); vTaskDelay(SCOPE_DEBUG_FREQ_MS / portTICK_RATE_MS); for (int i = 0; i < adc_test_num; i++) { scope_temp[i] = 0; } } } /** * Manual test: Capture ADC-DMA data and display it on the serial oscilloscope. Used to observe the stability of the data. * Use step: * 1. Run this test from the unit test app. * 2. Use `ESP-Tuning Tool`(download from `www.espressif.com`) to capture. * 3. The readings of multiple channels will be displayed on the tool. */ TEST_CASE("test_adc_digi_slope_debug", "[adc_dma][ignore]") { adc_dma_event_t evt; test_tp_scope_debug_init(0, -1, -1, SCOPE_UART_BUADRATE); adc_unit_t adc = ADC_CONV_BOTH_UNIT; test_adc_dig_scope_debug_unit(adc); while (1) { TEST_ESP_OK( adc_digi_start() ); TEST_ASSERT_EQUAL( xQueueReceive(que_adc, &evt, portMAX_DELAY), pdTRUE ); if (evt.int_msk & SPI_IN_SUC_EOF_INT_ST) { TEST_ESP_OK( adc_digi_stop() ); adc_digi_reset(); for (int cnt = 0; cnt < 2; cnt++) { esp_rom_printf("cnt%d\n", cnt); for (int i = 0; i < SAR_DMA_DATA_SIZE((adc > 2) ? 2 : 1, SAR_SIMPLE_NUM); i += 2) { uint8_t h = link_buf[cnt % 2][i + 1], l = link_buf[cnt % 2][i]; uint16_t temp = (h << 8 | l); adc_digi_output_data_t *data = (adc_digi_output_data_t *)&temp; if (adc > ADC_UNIT_2) { //ADC_ENCODE_11BIT scope_output(data->type2.unit, data->type2.channel, data->type2.data); } else { //ADC_ENCODE_12BIT if (adc == ADC_UNIT_1) { scope_output(0, data->type1.channel, data->type1.data); } else if (adc == ADC_UNIT_2) { scope_output(1, data->type1.channel, data->type1.data); } } link_buf[cnt % 2][i] = 0; link_buf[cnt % 2][i + 1] = 0; } } } } } #endif // !DISABLED_FOR_TARGETS(ESP8266, ESP32)