/* * SPDX-FileCopyrightText: 2021-2022 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ /** * No specific runner required to run GPIO unit test. * TEST_GPIO_EXT_OUT_IO and TEST_GPIO_EXT_IN_IO are connected internally through gpio matrix. * * If wants to externally connect TEST_GPIO_EXT_OUT_IO to TEST_GPIO_EXT_IN_IO (UT_T1_GPIO), please set * TEST_GPIO_INTERNAL_ROUTING to 0 */ #include #include #include "test_gpio.h" #include "esp_system.h" #include "esp_cpu.h" #include "esp_sleep.h" #include "unity.h" #include "unity_test_utils.h" #include "driver/gpio.h" #include "hal/gpio_ll.h" #include "soc/gpio_periph.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "freertos/queue.h" #include "freertos/semphr.h" #include "sdkconfig.h" #include "esp_rom_uart.h" #include "esp_rom_sys.h" #include "spi_flash_mmap.h" #include "esp_attr.h" #include "esp_private/spi_flash_os.h" // Enable internal routing for the output and input gpio pins #define TEST_GPIO_INTERNAL_ROUTING 1 // If there is any input-only pin, enable input-only pin part of some tests. #define SOC_HAS_INPUT_ONLY_PIN (CONFIG_IDF_TARGET_ESP32 || CONFIG_IDF_TARGET_ESP32S2) static volatile int disable_intr_times = 0; // use this to calculate how many times it go into interrupt static volatile int level_intr_times = 0; // use this to get how many times the level interrupt happened static volatile int edge_intr_times = 0; // use this to get how many times the edge interrupt happened /** * Do some initialization operation in this function * @param num it is the destination GPIO wanted to be initialized */ static gpio_config_t test_init_io(gpio_num_t num) { TEST_ASSERT(GPIO_IS_VALID_OUTPUT_GPIO(num)); gpio_config_t io_conf = { .intr_type = GPIO_INTR_DISABLE, .mode = GPIO_MODE_OUTPUT, .pin_bit_mask = (1ULL << num), .pull_down_en = 0, .pull_up_en = 0, }; return io_conf; } /** * Configure gpio pin as GPIO_MODE_INPUT_OUTPUT for all the interrupt related tests to avoid runner requirements */ static void test_gpio_config_mode_input_output(gpio_num_t num) { gpio_config_t input_output_io = test_init_io(num); input_output_io.mode = GPIO_MODE_INPUT_OUTPUT; input_output_io.pull_up_en = 1; TEST_ESP_OK(gpio_config(&input_output_io)); } // test the basic configuration function with right parameters and error parameters TEST_CASE("GPIO_config_parameters_test", "[gpio]") { gpio_config_t io_config = { 0 }; io_config.intr_type = GPIO_INTR_DISABLE; // test 0 io_config.pin_bit_mask = 0; TEST_ASSERT(gpio_config(&io_config) == ESP_ERR_INVALID_ARG); // test a non-exist pin io_config.pin_bit_mask = ((uint64_t)1 << GPIO_NUM_MAX); TEST_ASSERT(gpio_config(&io_config) == ESP_ERR_INVALID_ARG); // test an available pin io_config.pin_bit_mask = ((uint64_t)1 << TEST_GPIO_EXT_OUT_IO); TEST_ESP_OK(gpio_config(&io_config)); //This IO is just used for input, C3 and S3 doesn't have input only pin. #if SOC_HAS_INPUT_ONLY_PIN io_config.pin_bit_mask = ((uint64_t)1 << TEST_GPIO_INPUT_ONLY_PIN); io_config.mode = GPIO_MODE_INPUT; TEST_ESP_OK(gpio_config(&io_config)); io_config.mode = GPIO_MODE_OUTPUT; // The pin is input only, once set as output should log something TEST_ASSERT(gpio_config(&io_config) == ESP_ERR_INVALID_ARG); #endif // SOC_HAS_INPUT_ONLY_PIN } // edge interrupt event static void gpio_isr_edge_handler(void *arg) { uint32_t gpio_num = (uint32_t) arg; esp_rom_printf("GPIO[%d] intr on core %d, val: %d\n", gpio_num, esp_cpu_get_core_id(), gpio_get_level(gpio_num)); edge_intr_times++; } // level interrupt event with "gpio_intr_disable" static void gpio_isr_level_handler(void *arg) { uint32_t gpio_num = (uint32_t) arg; disable_intr_times++; esp_rom_printf("GPIO[%d] intr, val: %d, disable_intr_times = %d\n", gpio_num, gpio_get_level(gpio_num), disable_intr_times); gpio_intr_disable(gpio_num); } // level interrupt event with "gpio_set_level(!gpio_get_level)" static void gpio_isr_level_handler2(void *arg) { uint32_t gpio_num = (uint32_t) arg; level_intr_times++; esp_rom_printf("GPIO[%d] intr, val: %d, level_intr_times = %d\n", gpio_num, gpio_get_level(gpio_num), level_intr_times); if (gpio_get_level(gpio_num)) { gpio_set_level(gpio_num, 0); } else { gpio_set_level(gpio_num, 1); } } TEST_CASE("GPIO_rising_edge_interrupt_test", "[gpio]") { edge_intr_times = 0; // set it as 0 prepare to test test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); // Rising edge intr TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_POSEDGE)); TEST_ESP_OK(gpio_install_isr_service(0)); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_edge_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT(1, edge_intr_times); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_falling_edge_interrupt_test", "[gpio]") { edge_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_NEGEDGE); gpio_install_isr_service(0); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_edge_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT(1, edge_intr_times); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_both_rising_and_falling_edge_interrupt_test", "[gpio]") { edge_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); int level = 0; gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_ANYEDGE); gpio_install_isr_service(0); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_edge_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); // For rising edge in GPIO_INTR_ANYEDGE while (1) { level = level + 1; gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, level * 0.2); if (level > 10) { break; } vTaskDelay(100 / portTICK_PERIOD_MS); } vTaskDelay(100 / portTICK_PERIOD_MS); // For falling edge in GPIO_INTR_ANYEDGE while (1) { level = level - 1; gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, level / 5); if (level < 0) { break; } vTaskDelay(100 / portTICK_PERIOD_MS); } vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT(2, edge_intr_times); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_input_high_level_trigger_cut_the_interrupt_source_exit_interrupt_test", "[gpio]") { level_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_HIGH_LEVEL); gpio_install_isr_service(0); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_handler2, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, level_intr_times, "go into high-level interrupt more than once with cut interrupt source way"); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_low_level_interrupt_test", "[gpio]") { disable_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_LOW_LEVEL); gpio_install_isr_service(0); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0); printf("get level:%d\n", gpio_get_level(TEST_GPIO_INPUT_OUTPUT_IO1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, disable_intr_times, "go into low-level interrupt more than once with disable way"); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_multi-level_trigger_cut_the_interrupt_source_exit_interrupt_test", "[gpio]") { level_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_HIGH_LEVEL); gpio_install_isr_service(0); gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_handler2, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, level_intr_times, "go into high-level interrupt more than once with cut interrupt source way"); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1); vTaskDelay(200 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(2, level_intr_times, "go into high-level interrupt more than once with cut interrupt source way"); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); } TEST_CASE("GPIO_enable_and_disable_interrupt_test", "[gpio]") { disable_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_HIGH_LEVEL)); TEST_ESP_OK(gpio_install_isr_service(0)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); TEST_ESP_OK(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, disable_intr_times, "go into high-level interrupt more than once with disable way"); // Interrupt disabled now TEST_ESP_OK(gpio_intr_disable(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, disable_intr_times, "disable interrupt does not work, still go into interrupt!"); // Uninstall interrupt service gpio_uninstall_isr_service(); TEST_ASSERT(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1) == ESP_ERR_INVALID_STATE); TEST_ASSERT(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1) == ESP_ERR_INVALID_STATE); } TEST_CASE("GPIO_repeatedly_call_service_and_isr_has_no_memory_leak_test", "[gpio][timeout=90]") { test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); // Rising edge intr uint32_t size = esp_get_free_heap_size(); for (int i = 0; i < 1000; i++) { TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_POSEDGE)); TEST_ESP_OK(gpio_install_isr_service(0)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_edge_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1)); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1); TEST_ESP_OK(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1)); gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0); gpio_uninstall_isr_service(); } TEST_ASSERT_INT32_WITHIN(100, size, esp_get_free_heap_size()); } typedef struct { int gpio_num; int isr_cnt; } gpio_isr_param_t; static void gpio_isr_per_pin_handler(void *arg) { gpio_isr_param_t *param = (gpio_isr_param_t *)arg; esp_rom_printf("GPIO[%d] intr, val: %d\n", param->gpio_num, gpio_get_level(param->gpio_num)); param->isr_cnt++; } /** The old GPIO interrupt service routine used to poll the interrupt raw status register to find the GPIO that * triggered the interrupt. But this will incorrectly handle the interrupt disabled GPIOs, because the raw interrupt * status register can still be set when the trigger signal arrives, even if the interrupt is disabled. * * Do the following steps: * 1. Configure TEST_GPIO_INPUT_OUTPUT_IO1 and TEST_GPIO_INPUT_OUTPUT_IO2 input_output mode. * 2. Enable TEST_GPIO_INPUT_OUTPUT_IO1 dual edge triggered interrupt, enable TEST_GPIO_INPUT_OUTPUT_IO2 falling edge triggered interrupt. * 3. Trigger TEST_GPIO_INPUT_OUTPUT_IO1 interrupt, then disable TEST_GPIO_INPUT_OUTPUT_IO1 interrupt, and then trigger TEST_GPIO_INPUT_OUTPUT_IO1 interrupt again (This time will not respond to the interrupt). * 4. Trigger TEST_GPIO_INPUT_OUTPUT_IO2 interrupt. * * If the bug is not fixed, you will see, in the step 4, the interrupt of TEST_GPIO_INPUT_OUTPUT_IO1 will also respond. */ TEST_CASE("GPIO_isr_responses_to_correct_gpios_test", "[gpio]") { gpio_isr_param_t io1_param = { .gpio_num = TEST_GPIO_INPUT_OUTPUT_IO1, .isr_cnt = 0, }; gpio_isr_param_t io2_param = { .gpio_num = TEST_GPIO_INPUT_OUTPUT_IO2, .isr_cnt = 0, }; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO2); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO2, 0)); TEST_ESP_OK(gpio_install_isr_service(0)); TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_ANYEDGE)); TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO2, GPIO_INTR_NEGEDGE)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_per_pin_handler, (void *) &io1_param)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO2, gpio_isr_per_pin_handler, (void *) &io2_param)); printf("Triggering the interrupt of GPIO%d\n", TEST_GPIO_INPUT_OUTPUT_IO1); // Rising edge TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); printf("Disable the interrupt of GPIO%d\n", TEST_GPIO_INPUT_OUTPUT_IO1); // Disable TEST_GPIO_INPUT_OUTPUT_IO1 interrupt, TEST_GPIO_INPUT_OUTPUT_IO1 will not respond to the next falling edge interrupt TEST_ESP_OK(gpio_intr_disable(TEST_GPIO_INPUT_OUTPUT_IO1)); vTaskDelay(100 / portTICK_PERIOD_MS); // Falling edge TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); printf("Triggering the interrupt of GPIO%d\n", TEST_GPIO_INPUT_OUTPUT_IO2); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO2, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); // Falling edge TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO2, 0)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO2)); gpio_uninstall_isr_service(); TEST_ASSERT((io1_param.isr_cnt == 1) && (io2_param.isr_cnt == 1)); } #if !CONFIG_FREERTOS_UNICORE #include "esp_ipc.h" static void install_isr_service_task(void *arg) { uint32_t gpio_num = (uint32_t) arg; // Rising edge intr TEST_ESP_OK(gpio_set_intr_type(gpio_num, GPIO_INTR_POSEDGE)); TEST_ESP_OK(gpio_install_isr_service(0)); gpio_isr_handler_add(gpio_num, gpio_isr_edge_handler, (void *) gpio_num); vTaskSuspend(NULL); } TEST_CASE("GPIO_interrupt_on_other_CPUs_test", "[gpio]") { TaskHandle_t gpio_task_handle; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); for (int cpu_num = 1; cpu_num < portNUM_PROCESSORS; ++cpu_num) { // We assume unit-test task is running on core 0, so we install gpio interrupt on other cores edge_intr_times = 0; TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); xTaskCreatePinnedToCore(install_isr_service_task, "install_isr_service_task", 2048, (void *) TEST_GPIO_INPUT_OUTPUT_IO1, 1, &gpio_task_handle, cpu_num); vTaskDelay(200 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT(1, edge_intr_times); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); unity_utils_task_delete(gpio_task_handle); } } static void gpio_intr_enable_task(void *param) { int gpio_num = (int) param; TEST_ESP_OK(gpio_intr_enable(gpio_num)); } /** Test the GPIO Interrupt Enable API with dual core enabled. The GPIO ISR service routine is registered on one core. * When the GPIO interrupt on another core is enabled, the GPIO interrupt will be lost. * Note. This is only a problem for ESP32. On ESP32S3, interrupt enable is effective to both cores, therefore, no matter * which core the interrupt service is installed on, the GPIO interrupt won't be lost. * * First on the core 0, do the following steps: * 1. Configure TEST_GPIO_INPUT_OUTPUT_IO1 input_output mode, and enable the falling edge interrupt mode. * 2. Trigger TEST_GPIO_INPUT_OUTPUT_IO1 interrupt and check if the interrupt responds correctly. * 3. Disable TEST_GPIO_INPUT_OUTPUT_IO1 interrupt * Then on the core 1, do the following steps: * 1. Enable TEST_GPIO_INPUT_OUTPUT_IO1 interrupt again. * 2. Trigger TEST_GPIO_INPUT_OUTPUT_IO1 interrupt and check if the interrupt responds correctly. */ TEST_CASE("GPIO_crosscore_interrupt_test", "[gpio]") { edge_intr_times = 0; test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_NEGEDGE)); // GPIO interrupt service installed on core 0 TEST_ESP_OK(gpio_install_isr_service(0)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_edge_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1)); vTaskDelay(1000 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_intr_disable(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ASSERT(edge_intr_times == 1); // Here, interrupt is enabling from core 1, but since the isr is installed on core 0, core 0 interrupt enable bit // will still be set instead of core 1 interrupt enable bit esp_ipc_call_blocking((xPortGetCoreID() == 0), gpio_intr_enable_task, (void *) TEST_GPIO_INPUT_OUTPUT_IO1); vTaskDelay(1000 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ESP_OK(gpio_intr_disable(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1)); gpio_uninstall_isr_service(); TEST_ASSERT(edge_intr_times == 2); } #endif //!CONFIG_FREERTOS_UNICORE #if CONFIG_GPIO_CTRL_FUNC_IN_IRAM static volatile DRAM_ATTR bool isr_triggered = false; static void IRAM_ATTR gpio_isr_level_iram_handler(void *arg) { uint32_t gpio_num = (uint32_t) arg; isr_triggered = true; gpio_intr_disable(gpio_num); } static void IRAM_ATTR gpio_wait_intr_done_task(void *arg) { SemaphoreHandle_t sem = (SemaphoreHandle_t) arg; spi_flash_guard_get()->start(); // Disables flash cache // Since interrupt service is installed on core 0, we enable the gpio intr on core 0 gpio_ll_intr_enable_on_core(&GPIO, 0, TEST_GPIO_INPUT_OUTPUT_IO1); // Wait until interrupt triggered while (!isr_triggered) { ; } spi_flash_guard_get()->end(); // Re-enables flash cache xSemaphoreGive(sem); vTaskSuspend(NULL); } TEST_CASE("GPIO_iram_interrupt_safe_test", "[gpio]") { SemaphoreHandle_t done_sem = xSemaphoreCreateBinary(); TaskHandle_t task_handle; TEST_ASSERT_NOT_NULL(done_sem); test_gpio_config_mode_input_output(TEST_GPIO_INPUT_OUTPUT_IO1); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 0)); TEST_ESP_OK(gpio_set_intr_type(TEST_GPIO_INPUT_OUTPUT_IO1, GPIO_INTR_HIGH_LEVEL)); // We assume unit-test task is running on core 0, so interrupt service is installed on core 0 TEST_ESP_OK(gpio_install_isr_service(ESP_INTR_FLAG_IRAM)); TEST_ESP_OK(gpio_isr_handler_add(TEST_GPIO_INPUT_OUTPUT_IO1, gpio_isr_level_iram_handler, (void *) TEST_GPIO_INPUT_OUTPUT_IO1)); // Disable intr and set pin level high, such that once the intr is re-enabled, it will trigger isr TEST_ESP_OK(gpio_intr_disable(TEST_GPIO_INPUT_OUTPUT_IO1)); TEST_ESP_OK(gpio_set_level(TEST_GPIO_INPUT_OUTPUT_IO1, 1)); xTaskCreate(gpio_wait_intr_done_task, "gpio_wait_intr_done_task", 2048, done_sem, 1, &task_handle); xSemaphoreTake(done_sem, portMAX_DELAY); gpio_isr_handler_remove(TEST_GPIO_INPUT_OUTPUT_IO1); gpio_uninstall_isr_service(); vSemaphoreDelete(done_sem); unity_utils_task_delete(task_handle); } #endif #if TEST_GPIO_INTERNAL_ROUTING // Inter-connect input pin and output pin through an internal signal static void gpio_interconnect_input_output_pin(uint32_t input_pin, uint32_t output_pin, uint32_t signal_idx) { // signal256 -> output pin -> signal_idx -> input_pin // Set output pin IE to be able to connect to the signal PIN_INPUT_ENABLE(GPIO_PIN_MUX_REG[output_pin]); esp_rom_gpio_connect_in_signal(output_pin, signal_idx, 0); // Input pin OE to be able to connect to the signal is done by the esp_rom_gpio_connect_out_signal function esp_rom_gpio_connect_out_signal(input_pin, signal_idx, 0, 0); } #endif TEST_CASE("GPIO_set_output_level_get_input_level_test", "[gpio]") { gpio_config_t output_io = test_init_io(TEST_GPIO_EXT_OUT_IO); gpio_config(&output_io); gpio_config_t input_io = test_init_io(TEST_GPIO_EXT_IN_IO); input_io.mode = GPIO_MODE_INPUT; gpio_config(&input_io); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif gpio_set_level(TEST_GPIO_EXT_OUT_IO, 0); vTaskDelay(100 / portTICK_PERIOD_MS); // tested voltage is around 0v TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "get level error! the level should be low!"); gpio_set_level(TEST_GPIO_EXT_OUT_IO, 1); vTaskDelay(100 / portTICK_PERIOD_MS); // tested voltage is around 3.3v TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "get level error! the level should be high!"); } // This test routes constant-high/low signal to pins, another way is to directly connect TEST_GPIO_EXT_IN_IO to // 3.3v or GND pin TEST_CASE("GPIO_get_level_from_fixed_voltage_test", "[gpio]") { #if !TEST_GPIO_INTERNAL_ROUTING // If TEST_GPIO_EXT_OUT_IO is connected to TEST_GPIO_EXT_IN_IO, prevent being affected gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_DISABLE); #endif gpio_config_t input_io = test_init_io(TEST_GPIO_EXT_IN_IO); input_io.mode = GPIO_MODE_INPUT; gpio_config(&input_io); esp_rom_gpio_connect_out_signal(TEST_GPIO_EXT_IN_IO, TEST_GPIO_SIGNAL_IDX, 0, 0); // Connect TEST_GPIO_EXT_IN_IO to a constant-high signal (to simulate connection to 3.3v) esp_rom_gpio_connect_in_signal(GPIO_MATRIX_CONST_ONE_INPUT, TEST_GPIO_SIGNAL_IDX, 0); int level1 = gpio_get_level(TEST_GPIO_EXT_IN_IO); printf("TEST_GPIO_EXT_IN_IO(GPIO%d)'s level is: %d\n", TEST_GPIO_EXT_IN_IO, level1); TEST_ASSERT_EQUAL_INT_MESSAGE(1, level1, "get level error! the level should be high!"); // Connect TEST_GPIO_EXT_IN_IO to a constant-low signal (to simulate connection to GND) esp_rom_gpio_connect_in_signal(GPIO_MATRIX_CONST_ZERO_INPUT, TEST_GPIO_SIGNAL_IDX, 0); int level2 = gpio_get_level(TEST_GPIO_EXT_IN_IO); printf("TEST_GPIO_EXT_IN_IO(GPIO%d)'s level is: %d\n", TEST_GPIO_EXT_IN_IO, level2); TEST_ASSERT_EQUAL_INT_MESSAGE(0, level2, "get level error! the level should be low!"); } TEST_CASE("GPIO_io_pull_up/down_function", "[gpio]") { // First, ensure that the output IO will not affect the level gpio_config_t io_conf = test_init_io(TEST_GPIO_EXT_OUT_IO); gpio_config(&io_conf); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT); io_conf = test_init_io(TEST_GPIO_EXT_IN_IO); gpio_config(&io_conf); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_INPUT); TEST_ESP_OK(gpio_pullup_en(TEST_GPIO_EXT_IN_IO)); // pull up first vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "gpio_pullup_en error, it can't pull up"); TEST_ESP_OK(gpio_pulldown_dis(TEST_GPIO_EXT_IN_IO)); //can't be pull down vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "gpio_pulldown_dis error, it can pull down"); TEST_ESP_OK(gpio_pulldown_en(TEST_GPIO_EXT_IN_IO)); // can be pull down now vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "gpio_pulldown_en error, it can't pull down"); TEST_ESP_OK(gpio_pullup_dis(TEST_GPIO_EXT_IN_IO)); // can't be pull up vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "gpio_pullup_dis error, it can pull up"); } // This test case tests whether gpio_set_level() outputs correctly with all gpio modes (gpio_mode_t) TEST_CASE("GPIO_mode_test", "[gpio]") { gpio_config_t output_io = test_init_io(TEST_GPIO_EXT_OUT_IO); gpio_config_t input_io = test_init_io(TEST_GPIO_EXT_IN_IO); gpio_config(&output_io); gpio_config(&input_io); int level = gpio_get_level(TEST_GPIO_EXT_IN_IO); // Disable mode gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_DISABLE); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_OUTPUT); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif gpio_set_level(TEST_GPIO_EXT_OUT_IO, !level); TEST_ASSERT_EQUAL_INT_MESSAGE(level, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_DISABLE set error, it can output"); // Output mode gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_INPUT); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif gpio_set_level(TEST_GPIO_EXT_OUT_IO, 1); TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_OUTPUT set error, it can't output"); gpio_set_level(TEST_GPIO_EXT_OUT_IO, 0); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_OUTPUT set error, it can't output"); // Open drain mode(output), can just output low level gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT_OD); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_INPUT); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif // Outputs high level: w/ pull up, then must read high level; w/ pull down, then must read low level gpio_set_level(TEST_GPIO_EXT_OUT_IO, 1); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_OUTPUT_OD with GPIO_PULLUP_ONLY set error, it outputs low level"); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_OUTPUT_OD with GPIO_PULLDOWN_ONLY set error, it outputs high level"); // Outputs low level: must read low level gpio_set_level(TEST_GPIO_EXT_OUT_IO, 0); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_FLOATING); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_OUTPUT_OD set error, it outputs high level"); // Open drain mode(output and input), can just output low level gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT_OD); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_INPUT); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif // Outputs high level: w/ pull up, then must read high level; w/ pull down, then must read low level gpio_set_level(TEST_GPIO_EXT_OUT_IO, 1); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_INPUT_OUTPUT_OD with GPIO_PULLDOWN_ONLY set error, it outputs high level"); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY); vTaskDelay(100 / portTICK_PERIOD_MS); TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_INPUT_OUTPUT_OD with GPIO_PULLUP_ONLY set error, it outputs low level"); // Outputs low level: must read low level gpio_set_level(TEST_GPIO_EXT_OUT_IO, 0); gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_FLOATING); TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_INPUT_OUTPUT_OD set error, it outputs high level"); // GPIO_MODE_INPUT_OUTPUT mode level = gpio_get_level(TEST_GPIO_EXT_IN_IO); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT); gpio_set_direction(TEST_GPIO_EXT_IN_IO, GPIO_MODE_INPUT); #if TEST_GPIO_INTERNAL_ROUTING gpio_interconnect_input_output_pin(TEST_GPIO_EXT_IN_IO, TEST_GPIO_EXT_OUT_IO, TEST_GPIO_SIGNAL_IDX); #endif gpio_set_level(TEST_GPIO_EXT_OUT_IO, !level); TEST_ASSERT_EQUAL_INT_MESSAGE(!level, gpio_get_level(TEST_GPIO_EXT_IN_IO), "direction GPIO_MODE_INPUT_OUTPUT set error, it gives incorrect output"); } static void prompt_to_continue(const char *str) { printf("%s , please press \"Enter\" to go on!\n", str); char sign[5] = {0}; while (strlen(sign) == 0) { /* Flush anything already in the RX buffer */ while (esp_rom_uart_rx_one_char((uint8_t *) sign) == 0) { } /* Read line */ esp_rom_uart_rx_string((uint8_t *) sign, sizeof(sign) - 1); } } // This case needs the resistance to pull up the voltage or pull down the voltage // Ignored in CI because the voltage needs to be tested with multimeter TEST_CASE("GPIO_verify_only_the_gpio_with_input_ability_can_be_set_pull/down", "[gpio][ignore]") { gpio_config_t output_io = test_init_io(TEST_GPIO_EXT_OUT_IO); gpio_config_t input_io = test_init_io(TEST_GPIO_EXT_IN_IO); gpio_config(&output_io); input_io.mode = GPIO_MODE_INPUT; gpio_config(&input_io); printf("pull up test!\n"); // pull up test gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY)); prompt_to_continue("mode: GPIO_MODE_OUTPUT"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT_OD); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY)); // open drain just can output low level gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT_OD); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY)); prompt_to_continue("mode: GPIO_MODE_OUTPUT_OD"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY)); prompt_to_continue("mode: GPIO_MODE_INPUT_OUTPUT"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLUP_ONLY)); prompt_to_continue("mode: GPIO_MODE_INPUT"); // after pull up the level is high now // pull down test printf("pull down test!\n"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY)); prompt_to_continue("mode: GPIO_MODE_OUTPUT"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_OUTPUT_OD); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY)); prompt_to_continue("mode: GPIO_MODE_OUTPUT_OD"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT_OD); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY)); prompt_to_continue("mode: GPIO_MODE_INPUT_OUTPUT_OD"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT_OUTPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY)); prompt_to_continue("mode: GPIO_MODE_INPUT_OUTPUT"); gpio_set_direction(TEST_GPIO_EXT_OUT_IO, GPIO_MODE_INPUT); TEST_ESP_OK(gpio_set_pull_mode(TEST_GPIO_EXT_OUT_IO, GPIO_PULLDOWN_ONLY)); prompt_to_continue("mode: GPIO_MODE_INPUT"); } static void drive_capability_set_get(gpio_num_t num, gpio_drive_cap_t capability) { gpio_config_t pad_io = test_init_io(num); TEST_ESP_OK(gpio_config(&pad_io)); TEST_ASSERT(gpio_set_drive_capability(num, GPIO_DRIVE_CAP_MAX) == ESP_ERR_INVALID_ARG); gpio_drive_cap_t cap; TEST_ESP_OK(gpio_set_drive_capability(num, capability)); TEST_ESP_OK(gpio_get_drive_capability(num, &cap)); TEST_ASSERT_EQUAL_INT(capability, cap); } /** * There are 5 situation for the GPIO drive capability: * 1. GPIO drive weak capability test * 2. GPIO drive stronger capability test * 3. GPIO drive default capability test * 4. GPIO drive default capability test2 * 5. GPIO drive strongest capability test * * How to test: * when testing, use the sliding resistor and a multimeter * adjust the resistor from low to high, 0-10k * watch the current change * the current test result: * weak capability: (0.32-10.1)mA * stronger capability: (0.32-20.0)mA * default capability: (0.33-39.8)mA * default capability2: (0.33-39.9)mA * strongest capability: (0.33-64.2)mA * * the data shows: * weak capability < stronger capability < default capability = default capability2 < strongest capability * * all of these cases should be ignored that it will not run in CI */ TEST_CASE("GPIO_drive_capability_test", "[gpio][ignore]") { printf("weak capability test! please view the current change!\n"); drive_capability_set_get(TEST_GPIO_EXT_OUT_IO, GPIO_DRIVE_CAP_0); prompt_to_continue("If this test finishes"); printf("stronger capability test! please view the current change!\n"); drive_capability_set_get(TEST_GPIO_EXT_OUT_IO, GPIO_DRIVE_CAP_1); prompt_to_continue("If this test finishes"); printf("default capability test! please view the current change!\n"); drive_capability_set_get(TEST_GPIO_EXT_OUT_IO, GPIO_DRIVE_CAP_2); prompt_to_continue("If this test finishes"); printf("default capability2 test! please view the current change!\n"); drive_capability_set_get(TEST_GPIO_EXT_OUT_IO, GPIO_DRIVE_CAP_DEFAULT); prompt_to_continue("If this test finishes"); printf("strongest capability test! please view the current change!\n"); drive_capability_set_get(TEST_GPIO_EXT_OUT_IO, GPIO_DRIVE_CAP_3); prompt_to_continue("If this test finishes"); } #if SOC_USB_SERIAL_JTAG_SUPPORTED TEST_CASE("GPIO_input_and_output_of_USB_pins_test", "[gpio]") { const int test_pins[] = {USB_DP_GPIO_NUM, USB_DM_GPIO_NUM}; gpio_config_t io_conf = { .intr_type = GPIO_INTR_DISABLE, .mode = GPIO_MODE_INPUT_OUTPUT, .pin_bit_mask = (BIT64(test_pins[0]) | BIT64(test_pins[1])), .pull_down_en = 0, .pull_up_en = 0, }; gpio_config(&io_conf); for (int i = 0; i < sizeof(test_pins) / sizeof(int); i++) { int pin = test_pins[i]; // test pin gpio_set_level(pin, 0); esp_rom_delay_us(10); // tested voltage is around 0v TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(pin), "get level error! the level should be low!"); gpio_set_level(pin, 1); esp_rom_delay_us(10); // tested voltage is around 3.3v TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(pin), "get level error! the level should be high!"); gpio_set_level(pin, 0); esp_rom_delay_us(10); // tested voltage is around 0v TEST_ASSERT_EQUAL_INT_MESSAGE(0, gpio_get_level(pin), "get level error! the level should be low!"); gpio_set_level(pin, 1); esp_rom_delay_us(10); // tested voltage is around 3.3v TEST_ASSERT_EQUAL_INT_MESSAGE(1, gpio_get_level(pin), "get level error! the level should be high!"); } } TEST_CASE("GPIO_USB_DP_pin_pullup_disable_test", "[gpio]") { // This test ensures the USB D+ pin pull-up can be disabled // The pull-up value of the D+ pin is controlled by the pin's pull-up value together with the USB pull-up value. // If any one of the pull-up value is 1, the pin’s pull-up resistor will be enabled. // USB D+ pull-up value is default to 1 (USB_SERIAL_JTAG_DP_PULLUP) // Therefore, when D+ pin's pull-up value is set to 0, it will also clear USB D+ pull-up value to allow // its full functionality as a normal gpio pin gpio_config_t input_io = test_init_io(USB_DP_GPIO_NUM); input_io.mode = GPIO_MODE_INPUT; input_io.pull_up_en = 0; input_io.pull_down_en = 1; gpio_config(&input_io); TEST_ASSERT_EQUAL_INT(0, gpio_get_level(USB_DP_GPIO_NUM)); } #endif //SOC_USB_SERIAL_JTAG_SUPPORTED #if !TEMPORARY_DISABLED_FOR_TARGETS(ESP32H2) // TODO: IDF-6267 Remove when light sleep is supported // Ignored in CI because it needs manually connect TEST_GPIO_INPUT_LEVEL_LOW_PIN to 3.3v to wake up from light sleep TEST_CASE("GPIO_light_sleep_wake_up_test", "[gpio][ignore]") { gpio_config_t io_config = test_init_io(TEST_GPIO_INPUT_LEVEL_LOW_PIN); io_config.mode = GPIO_MODE_INPUT; io_config.pull_down_en = 1; gpio_config(&io_config); TEST_ESP_OK(gpio_wakeup_enable(TEST_GPIO_INPUT_LEVEL_LOW_PIN, GPIO_INTR_HIGH_LEVEL)); TEST_ESP_OK(esp_sleep_enable_gpio_wakeup()); printf("Entering light sleep... Please connect GPIO%d to 3.3v to wake up...\n", TEST_GPIO_INPUT_LEVEL_LOW_PIN); // Wait for the complete line to be printed before entering sleep vTaskDelay(1000 / portTICK_PERIOD_MS); esp_light_sleep_start(); printf("Waked up from light sleep\n"); TEST_ASSERT(esp_sleep_get_wakeup_cause() == ESP_SLEEP_WAKEUP_GPIO); } #endif //!TEMPORARY_DISABLED_FOR_TARGETS(...)