#include #include #include "esp_event.h" #include "sdkconfig.h" #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "esp_log.h" #include "esp_private/periph_ctrl.h" #include "driver/timer.h" #include "esp_event.h" #include "esp_event_private.h" #include "esp_event_internal.h" #include "esp_heap_caps.h" #include "esp_timer.h" #include "sdkconfig.h" #include "unity.h" #include "test_utils.h" static const char* TAG = "test_event"; #define TEST_CONFIG_ITEMS_TO_REGISTER 5 #define TEST_CONFIG_TASKS_TO_SPAWN 2 #define TEST_CONFIG_WAIT_MULTIPLIER 5 // The initial logging "initializing test" is to ensure mutex allocation is not counted against memory not being freed // during teardown. #define TEST_SETUP() \ ESP_LOGI(TAG, "initializing test"); \ size_t free_mem_before = heap_caps_get_free_size(MALLOC_CAP_DEFAULT); \ test_setup(); \ s_test_core_id = xPortGetCoreID(); \ s_test_priority = uxTaskPriorityGet(NULL); #define TEST_TEARDOWN() \ test_teardown(); \ vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); \ TEST_ASSERT_EQUAL(free_mem_before, heap_caps_get_free_size(MALLOC_CAP_DEFAULT)); typedef struct { void* data; SemaphoreHandle_t start; SemaphoreHandle_t done; } task_arg_t; typedef struct { esp_event_base_t base; int32_t id; esp_event_handler_t* handles; int32_t num; esp_event_loop_handle_t loop; bool is_registration; } handler_registration_data_t; typedef struct { esp_event_base_t base; int32_t id; esp_event_loop_handle_t loop; int32_t num; } post_event_data_t; typedef struct { int performed; int expected; SemaphoreHandle_t done; } performance_data_t; typedef struct { void* data; SemaphoreHandle_t mutex; } simple_arg_t; typedef struct { esp_event_handler_instance_t *context; void* data; } instance_unregister_data_t; typedef struct { int *arr; int index; } ordered_data_t; static BaseType_t s_test_core_id; static UBaseType_t s_test_priority; ESP_EVENT_DECLARE_BASE(s_test_base1); ESP_EVENT_DECLARE_BASE(s_test_base2); ESP_EVENT_DEFINE_BASE(s_test_base1); ESP_EVENT_DEFINE_BASE(s_test_base2); enum { TEST_EVENT_BASE1_EV1, TEST_EVENT_BASE1_EV2, TEST_EVENT_BASE1_MAX }; enum { TEST_EVENT_BASE2_EV1, TEST_EVENT_BASE2_EV2, TEST_EVENT_BASE2_MAX }; static BaseType_t test_event_get_core(void) { static int calls = 0; if (portNUM_PROCESSORS > 1) { return (s_test_core_id + calls++) % portNUM_PROCESSORS; } else { return s_test_core_id; } } static esp_event_loop_args_t test_event_get_default_loop_args(void) { esp_event_loop_args_t loop_config = { .queue_size = CONFIG_ESP_SYSTEM_EVENT_QUEUE_SIZE, .task_name = "loop", .task_priority = s_test_priority, .task_stack_size = 2048, .task_core_id = test_event_get_core() }; return loop_config; } static void test_event_simple_handler(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { if (!event_handler_arg) { return; } simple_arg_t* arg = (simple_arg_t*) event_handler_arg; xSemaphoreTake(arg->mutex, portMAX_DELAY); int* count = (int*) arg->data; if (event_data == NULL) { (*count)++; } else { (*count) += *((int*) event_data); } xSemaphoreGive(arg->mutex); } static void test_event_ordered_dispatch(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { int *arg = (int*) event_handler_arg; ordered_data_t *data = *((ordered_data_t**) (event_data)); data->arr[data->index++] = *arg; } static void test_event_performance_handler(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { performance_data_t* data = (performance_data_t*) event_handler_arg; data->performed++; if (data->performed >= data->expected) { xSemaphoreGive(data->done); } } static void test_event_post_task(void* args) { task_arg_t* arg = (task_arg_t*) args; post_event_data_t* data = arg->data; xSemaphoreTake(arg->start, portMAX_DELAY); for (int i = 0; i < data->num; i++) { TEST_ESP_OK(esp_event_post_to(data->loop, data->base, data->id, NULL, 0, portMAX_DELAY)); vTaskDelay(1); } xSemaphoreGive(arg->done); vTaskDelete(NULL); } static void test_event_simple_handler_registration_task(void* args) { task_arg_t* arg = (task_arg_t*) args; handler_registration_data_t* data = (handler_registration_data_t*) arg->data; xSemaphoreTake(arg->start, portMAX_DELAY); for(int i = 0; i < data->num; i++) { if (data->is_registration) { TEST_ESP_OK(esp_event_handler_register_with(data->loop, data->base, data->id, data->handles[i], NULL)); } else { TEST_ESP_OK(esp_event_handler_unregister_with(data->loop, data->base, data->id, data->handles[i])); } vTaskDelay(1); } xSemaphoreGive(arg->done); vTaskDelete(NULL); } static void test_handler_post_w_task(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { simple_arg_t* arg = (simple_arg_t*) event_handler_arg; esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_data; int* count = (int*) arg->data; (*count)++; if (*count <= 2) { if (event_base == s_test_base1 && event_id == TEST_EVENT_BASE1_EV1) { TEST_ESP_OK(esp_event_post_to(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } else{ xSemaphoreGive((SemaphoreHandle_t) arg->mutex); } } else { // Test that once the queue is full and the handler attempts to post to the same loop, // posting does not block indefinitely. if (event_base == s_test_base1 && event_id == TEST_EVENT_BASE1_EV1) { xSemaphoreTake((SemaphoreHandle_t) arg->mutex, portMAX_DELAY); TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } } } static void test_handler_post_wo_task(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { simple_arg_t* arg = (simple_arg_t*) event_handler_arg; esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_data; int* count = (int*) arg->data; (*count)++; if (*count <= 2) { if (event_base == s_test_base1 && event_id == TEST_EVENT_BASE1_EV1) { TEST_ESP_OK(esp_event_post_to(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } else{ xSemaphoreGive((SemaphoreHandle_t) arg->mutex); } } else { // Test that once the queue is full and the handler attempts to post to the same loop, // posting does not block indefinitely. if (event_base == s_test_base1 && event_id == TEST_EVENT_BASE1_EV1) { xSemaphoreTake((SemaphoreHandle_t) arg->mutex, portMAX_DELAY); TEST_ESP_OK(esp_event_post_to(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } } } static void test_handler_unregister_itself(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_data; int* unregistered = (int*) event_handler_arg; (*unregistered) += (event_base == s_test_base1 ? 0 : 10) + event_id + 1; // Unregister this handler for this event TEST_ESP_OK(esp_event_handler_unregister_with(*loop, event_base, event_id, test_handler_unregister_itself)); } static void test_handler_instance_unregister_itself(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_data; instance_unregister_data_t *unregister_data = (instance_unregister_data_t*) event_handler_arg; esp_event_handler_instance_t *context = (esp_event_handler_instance_t*) unregister_data->context; int *count = (int*) unregister_data->data; (*count)++; // Unregister this handler for this event TEST_ESP_OK(esp_event_handler_instance_unregister_with(*loop, event_base, event_id, *context)); } static void test_post_from_handler_loop_task(void* args) { esp_event_loop_handle_t event_loop = (esp_event_loop_handle_t) args; while(1) { TEST_ESP_OK(esp_event_loop_run(event_loop, portMAX_DELAY)); } } static void test_setup(void) { TEST_ASSERT_TRUE(TEST_CONFIG_TASKS_TO_SPAWN >= 2); TEST_ESP_OK(esp_event_loop_create_default()); } static void test_teardown(void) { TEST_ESP_OK(esp_event_loop_delete_default()); } #define TIMER_DIVIDER 16 // Hardware timer clock divider #define TIMER_SCALE (TIMER_BASE_CLK / TIMER_DIVIDER) // convert counter value to seconds #define TIMER_INTERVAL0_SEC (2.0) // sample test interval for the first timer TEST_CASE("can create and delete event loops", "[event]") { /* this test aims to verify that: * - creating loops with and without a task succeeds * - event queue can accomodate the set queue size, and drops the post when exceeded * - deleting loops with unconsumed posts and unregistered handlers (when unregistration is enabled) does not leak memory */ TEST_SETUP(); esp_event_loop_handle_t loop1; // with dedicated task esp_event_loop_handle_t loop2; // without dedicated task esp_event_loop_handle_t loop3; // with leftover post and handlers esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop1)); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop2)); TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop3)); TEST_ESP_OK(esp_event_handler_register_with(loop3, s_test_base1, TEST_EVENT_BASE1_EV1, (void*) 0x00000001, NULL)); TEST_ESP_OK(esp_event_handler_register_with(loop3, s_test_base1, TEST_EVENT_BASE1_EV2, (void*) 0x00000002, NULL)); TEST_ESP_OK(esp_event_handler_register_with(loop3, s_test_base2, TEST_EVENT_BASE1_EV1, (void*) 0x00000003, NULL)); for (int i = 0; i < loop_args.queue_size; i++) { int mod = i % 4; switch(mod) { case 0: TEST_ESP_OK(esp_event_post_to(loop3, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); break; case 1: TEST_ESP_OK(esp_event_post_to(loop3, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); break; case 2: TEST_ESP_OK(esp_event_post_to(loop3, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); break; case 3: TEST_ESP_OK(esp_event_post_to(loop3, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); break; default: break; } } TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(loop3, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, pdMS_TO_TICKS(10))); TEST_ESP_OK(esp_event_loop_delete(loop1)); TEST_ESP_OK(esp_event_loop_delete(loop2)); TEST_ESP_OK(esp_event_loop_delete(loop3)); TEST_TEARDOWN(); } TEST_CASE("registering event handler instance without instance context works", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count_1 = 0; simple_arg_t arg_1 = { .data = &count_1, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg_1, NULL)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count_1); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg_1.mutex); TEST_TEARDOWN(); } TEST_CASE("registering event twice with same handler yields updated handler arg", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); /* Register the handler twice to the same base and id but with a different argument (expects to return ESP_OK and log a warning) * This aims to verify: 1) Handler's argument to be updated * 2) Registration not to leak memory */ TEST_ESP_OK(esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, NULL)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); // exec loop, no handler data: count stays 0 TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // overriding the former registration of the same event TEST_ESP_OK(esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); // exec loop, registered handler data exists: count increases TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("registering event handler instance twice works", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count_1 = 0; int count_2 = 0; simple_arg_t arg_1 = { .data = &count_1, .mutex = xSemaphoreCreateMutex() }; simple_arg_t arg_2 = { .data = &count_2, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx_1; esp_event_handler_instance_t ctx_2; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg_1, &ctx_1)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg_2, &ctx_2)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count_1); TEST_ASSERT_EQUAL(1, count_2); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg_1.mutex); vSemaphoreDelete(arg_2.mutex); TEST_TEARDOWN(); } TEST_CASE("registering with ANY_BASE but specific ID fails", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("registering instance with ANY_BASE but specific ID fails", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; esp_event_handler_instance_t ctx; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_handler_instance_register_with(loop, ESP_EVENT_ANY_BASE, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg, &ctx)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Check registering ANY_ID", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg)); // handler shouldn't be triggered with different base TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for all events with correct base, it should be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(2, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Check registering instance with ANY_ID", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg, &ctx)); // handler shouldn't be triggered with different base TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for all events with correct base, it should be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(2, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Check registering specific event", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); // handler should not be triggered with different base TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for incorrect id, it should not be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for correct event and base, it should be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Check registering instance with specific event", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg, &ctx)); // handler should not be triggered with different base TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for incorrect id, it should not be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // for correct event and base, it should be triggered TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Specific event is not called when no correct events are posted", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); // handler should not be triggered by any of these postings TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // Post unknown events. TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_MAX, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_MAX, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("Specific event instance is not called when no correct events are posted", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg, &ctx)); // handler should not be triggered by any of these postings TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); // Post unknown events. TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_MAX, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_MAX, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can register/unregister handlers for all events/all events for a specific base", "[event]") { /* this test aims to verify that handlers can be registered to be called on all events * or for all events with specific bases */ TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); /* Register the handler twice to the same base and id but with a different argument (expects to return ESP_OK and log a warning) * This aims to verify: 1) Handler's argument to be updated * 2) Registration not to leak memory */ TEST_ESP_OK(esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, NULL)); TEST_ESP_OK(esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, ESP_EVENT_ANY_ID, test_event_simple_handler, &arg)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, s_test_base1, ESP_EVENT_ANY_ID, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, ESP_EVENT_ANY_BASE, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); // exec loop, base and id level (+3) TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); // exec loop, base and id level (+3) // Post unknown events. Respective loop level and base level handlers should still execute. TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_MAX, NULL, 0, portMAX_DELAY)); // exec loop and base level (+2) TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_MAX, NULL, 0, portMAX_DELAY)); // exec loop level (+1) TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(9, count); // 3 + 3 + 2 + 1 TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can unregister handler", "[event]") { /* this test aims to verify that unregistered handlers no longer execute when events are raised */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(2, count); TEST_ESP_OK(esp_event_handler_unregister_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(3, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can unregister handler instance", "[event]") { /* this test aims to verify that unregistered handlers no longer execute when events are raised */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx; TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg, &ctx)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_handler_instance_unregister_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, ctx)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("handler can unregister itself", "[event]") { /* this test aims to verify that handlers can unregister themselves */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int unregistered = 0; /* * s_test_base1, ev1 = 1 * s_test_base1, ev2 = 2 * s_test_base2, ev1 = 11 * s_test_base2, ev2 = 12 */ int expected_unregistered = 0; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_unregister_itself, &unregistered)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_handler_unregister_itself, &unregistered)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE2_EV1, test_handler_unregister_itself, &unregistered)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE2_EV2, test_handler_unregister_itself, &unregistered)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); expected_unregistered = 2; // base1, ev2 TEST_ASSERT_EQUAL(expected_unregistered, unregistered); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); expected_unregistered += 1 + 11; // base1, ev1 + base2, ev1 TEST_ASSERT_EQUAL(expected_unregistered, unregistered); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_EV2, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); expected_unregistered += 12; // base2, ev2 TEST_ASSERT_EQUAL(expected_unregistered, unregistered); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_EV2, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(expected_unregistered, unregistered); // all handlers unregistered TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } TEST_CASE("handler instance can unregister itself", "[event]") { /* this test aims to verify that handlers can unregister themselves */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); esp_event_handler_instance_t ctx; int count = 0; instance_unregister_data_t instance_data = { .context = &ctx, .data = &count }; TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_instance_unregister_itself, &instance_data, &ctx)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); vTaskDelay(1000); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &loop, sizeof(loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(1, count); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } TEST_CASE("can exit running loop at approximately the set amount of time", "[event]") { /* this test aims to verify that running loop does not block indefinitely in cases where * events are posted frequently */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); performance_data_t handler_data = { .performed = 0, .expected = INT32_MAX, .done = xSemaphoreCreateBinary() }; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_performance_handler, &handler_data)); post_event_data_t post_event_data = { .base = s_test_base1, .id = TEST_EVENT_BASE1_EV1, .loop = loop, .num = INT32_MAX }; task_arg_t post_event_arg = { .data = &post_event_data, .done = xSemaphoreCreateBinary(), .start = xSemaphoreCreateBinary() }; TaskHandle_t post_task; xTaskCreatePinnedToCore(test_event_post_task, "post", 2048, &post_event_arg, s_test_priority, &post_task, test_event_get_core()); int runtime_ms = 10; int runtime_us = runtime_ms * 1000; int64_t start, diff; start = esp_timer_get_time(); xSemaphoreGive(post_event_arg.start); // Run the loop for the runtime_ms set amount of time, regardless of whether events // are still being posted to the loop. TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(runtime_ms))); diff = (esp_timer_get_time() - start); // Threshold is 25 percent. TEST_ASSERT(diff < runtime_us * 1.25f); // Verify that the post task still continues TEST_ASSERT_NOT_EQUAL(pdTRUE, xSemaphoreTake(post_event_arg.done, pdMS_TO_TICKS(10))); vSemaphoreDelete(post_event_arg.done); vSemaphoreDelete(post_event_arg.start); vSemaphoreDelete(handler_data.done); vTaskDelete(post_task); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } TEST_CASE("can register/unregister handlers simultaneously", "[event]") { /* this test aims to verify that the event handlers list remains consistent despite * simultaneous access by differenct tasks */ TEST_SETUP(); const char* base = "base"; int32_t id = 0; esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); ESP_LOGI(TAG, "registering handlers"); handler_registration_data_t* registration_data = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*registration_data)); task_arg_t* registration_arg = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*registration_arg)); for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { registration_data[i].base = base; registration_data[i].id = id; registration_data[i].loop = loop; registration_data[i].handles = calloc(TEST_CONFIG_ITEMS_TO_REGISTER, sizeof(esp_event_handler_t)); registration_data[i].num = TEST_CONFIG_ITEMS_TO_REGISTER; registration_data[i].is_registration = true; for (int j = 0; j < TEST_CONFIG_ITEMS_TO_REGISTER; j++) { registration_data[i].handles[j] = (void*) (i * TEST_CONFIG_ITEMS_TO_REGISTER) + (j + TEST_CONFIG_ITEMS_TO_REGISTER); } registration_arg[i].start = xSemaphoreCreateBinary(); registration_arg[i].done = xSemaphoreCreateBinary(); registration_arg[i].data = ®istration_data[i]; xTaskCreatePinnedToCore(test_event_simple_handler_registration_task, "register", 2048, ®istration_arg[i], s_test_priority, NULL, test_event_get_core()); } // Give the semaphores to the spawned registration task for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreGive(registration_arg[i].start); } // Take the same semaphores in order to proceed for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreTake(registration_arg[i].done, portMAX_DELAY); } ESP_LOGI(TAG, "checking consistency of handlers list"); // Check consistency of events list for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { for (int j = 0; j < TEST_CONFIG_ITEMS_TO_REGISTER; j++) { TEST_ASSERT_TRUE(esp_event_is_handler_registered(loop, base, id, registration_data[i].handles[j])); } } ESP_LOGI(TAG, "unregistering handlers"); /* Test if tasks can unregister simultaneously */ // Unregister registered events handler_registration_data_t* unregistration_data = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*unregistration_data)); task_arg_t* unregistration_arg = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*unregistration_arg)); for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { unregistration_data[i].base = base; unregistration_data[i].id = id; unregistration_data[i].loop = loop; unregistration_data[i].handles = calloc(TEST_CONFIG_ITEMS_TO_REGISTER, sizeof(esp_event_handler_t)); unregistration_data[i].num = TEST_CONFIG_ITEMS_TO_REGISTER; unregistration_data[i].is_registration = false; memcpy(unregistration_data[i].handles, registration_data[i].handles, TEST_CONFIG_ITEMS_TO_REGISTER * sizeof(esp_event_handler_t)); unregistration_arg[i].data = &unregistration_data[i]; unregistration_arg[i].start = xSemaphoreCreateBinary(); unregistration_arg[i].done = xSemaphoreCreateBinary(); xTaskCreatePinnedToCore(test_event_simple_handler_registration_task, "unregister", 2048, &unregistration_arg[i], s_test_priority, NULL, test_event_get_core()); } // Give the semaphores to the spawned unregistration task for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreGive(unregistration_arg[i].start); } // Take the same semaphores in order to proceed for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreTake(unregistration_arg[i].done, portMAX_DELAY); } ESP_LOGI(TAG, "checking consistency of handlers list"); // Check consistency of events list for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { for (int j = 0; j < TEST_CONFIG_ITEMS_TO_REGISTER; j++) { TEST_ASSERT_FALSE(esp_event_is_handler_registered(loop, base, id, registration_data[i].handles[j])); } } // Do cleanup for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { free(registration_data[i].handles); vSemaphoreDelete(registration_arg[i].start); vSemaphoreDelete(registration_arg[i].done); free(unregistration_data[i].handles); vSemaphoreDelete(unregistration_arg[i].start); vSemaphoreDelete(unregistration_arg[i].done); } free(registration_data); free(unregistration_data); free(registration_arg); free(unregistration_arg); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } TEST_CASE("posting ANY_EVENT or ANY_ID fails", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, s_test_base1, ESP_EVENT_ANY_ID, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_post_to(loop, ESP_EVENT_ANY_BASE, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(0, count); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can post and run events", "[event]") { /* this test aims to verify that: * - multiple tasks can post to the queue simultaneously * - handlers recieve the appropriate handler arg and associated event data */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; loop_args.queue_size = TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg)); post_event_data_t* post_event_data = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*post_event_data)); task_arg_t* post_event_arg = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*post_event_arg)); for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { post_event_data[i].base = s_test_base1; post_event_data[i].id = TEST_EVENT_BASE1_EV1; post_event_data[i].loop = loop; post_event_data[i].num = TEST_CONFIG_ITEMS_TO_REGISTER; post_event_arg[i].data = &post_event_data[i]; post_event_arg[i].start = xSemaphoreCreateBinary(); post_event_arg[i].done = xSemaphoreCreateBinary(); xTaskCreatePinnedToCore(test_event_post_task, "post", 2048, &post_event_arg[i], s_test_priority, NULL, test_event_get_core()); } for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreGive(post_event_arg[i].start); } // Execute some events as they are posted for (int i = 0; i < (TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER) / 2; i++) { TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); } for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreTake(post_event_arg[i].done, portMAX_DELAY); } // Execute the rest TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER, count); // Cleanup for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { vSemaphoreDelete(post_event_arg[i].start); vSemaphoreDelete(post_event_arg[i].done); } free(post_event_data); free(post_event_arg); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can post and run events with instances", "[event]") { /* this test aims to verify that: * - multiple tasks can post to the queue simultaneously * - handlers recieve the appropriate handler arg and associated event data */ TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; loop_args.queue_size = TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int count = 0; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateMutex() }; esp_event_handler_instance_t ctx; TEST_ESP_OK(esp_event_handler_instance_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_simple_handler, &arg, &ctx)); post_event_data_t* post_event_data = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*post_event_data)); task_arg_t* post_event_arg = calloc(TEST_CONFIG_TASKS_TO_SPAWN, sizeof(*post_event_arg)); for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { post_event_data[i].base = s_test_base1; post_event_data[i].id = TEST_EVENT_BASE1_EV1; post_event_data[i].loop = loop; post_event_data[i].num = TEST_CONFIG_ITEMS_TO_REGISTER; post_event_arg[i].data = &post_event_data[i]; post_event_arg[i].start = xSemaphoreCreateBinary(); post_event_arg[i].done = xSemaphoreCreateBinary(); xTaskCreatePinnedToCore(test_event_post_task, "post", 2048, &post_event_arg[i], s_test_priority, NULL, test_event_get_core()); } for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreGive(post_event_arg[i].start); } // Execute some events as they are posted for (int i = 0; i < (TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER) / 2; i++) { TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); } for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { xSemaphoreTake(post_event_arg[i].done, portMAX_DELAY); } // Execute the rest TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(TEST_CONFIG_TASKS_TO_SPAWN * TEST_CONFIG_ITEMS_TO_REGISTER, count); // Cleanup for (int i = 0; i < TEST_CONFIG_TASKS_TO_SPAWN; i++) { vSemaphoreDelete(post_event_arg[i].start); vSemaphoreDelete(post_event_arg[i].done); } free(post_event_data); free(post_event_arg); TEST_ESP_OK(esp_event_loop_delete(loop)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } static void loop_run_task(void* args) { esp_event_loop_handle_t event_loop = (esp_event_loop_handle_t) args; while(1) { esp_event_loop_run(event_loop, portMAX_DELAY); } } static void performance_test(bool dedicated_task) { // rand() seems to do a one-time allocation. Call it here so that the memory it allocates // is not counted as a leak. unsigned int _rand __attribute__((unused)) = rand(); TEST_SETUP(); const char test_base[] = "qwertyuiopasdfghjklzxvbnmmnbvcxz"; #define TEST_CONFIG_BASES (sizeof(test_base) - 1) #define TEST_CONFIG_IDS (TEST_CONFIG_BASES / 2) // Create loop esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); esp_event_loop_handle_t loop; if (!dedicated_task) { loop_args.task_name = NULL; } TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); performance_data_t data; // Register the handlers for (int base = 0; base < TEST_CONFIG_BASES; base++) { for (int id = 0; id < TEST_CONFIG_IDS; id++) { TEST_ESP_OK(esp_event_handler_register_with(loop, test_base + base, id, test_event_performance_handler, &data)); } } TaskHandle_t mtask = NULL; if (!dedicated_task) { xTaskCreate(loop_run_task, "loop_run", loop_args.task_stack_size, (void*) loop, loop_args.task_priority, &mtask); } // Perform performance test float running_sum = 0; float running_count = 0; for (int bases = 1; bases <= TEST_CONFIG_BASES; bases *= 2) { for (int ids = 1; ids <= TEST_CONFIG_IDS; ids *= 2) { data.performed = 0; data.expected = bases * ids; data.done = xSemaphoreCreateBinary(); // Generate randomized list of posts int post_bases[TEST_CONFIG_BASES]; int post_ids[TEST_CONFIG_IDS]; for (int i = 0; i < bases; i++) { post_bases[i] = i; } for (int i = 0; i < ids; i++) { post_ids[i] = i; } for (int i = 0; i < bases; i++) { int rand_a = rand() % bases; int rand_b = rand() % bases; int temp = post_bases[rand_a]; post_bases[rand_a]= post_bases[rand_b]; post_bases[rand_b] = temp; } for (int i = 0; i < ids; i++) { int rand_a = rand() % ids; int rand_b = rand() % ids; int temp = post_ids[rand_a]; post_ids[rand_a]= post_ids[rand_b]; post_ids[rand_b] = temp; } // Post the events int64_t start = esp_timer_get_time(); for (int base = 0; base < bases; base++) { for (int id = 0; id < ids; id++) { TEST_ESP_OK(esp_event_post_to(loop, test_base + post_bases[base], post_ids[id], NULL, 0, portMAX_DELAY)); } } xSemaphoreTake(data.done, portMAX_DELAY); int64_t elapsed = esp_timer_get_time() - start; // Record data TEST_ASSERT_EQUAL(data.expected, data.performed); running_count++; running_sum += data.performed / (elapsed / (1000000.0)); vSemaphoreDelete(data.done); } } int average = (int) (running_sum / (running_count)); if (!dedicated_task) { ((esp_event_loop_instance_t*) loop)->task = mtask; } TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING ESP_LOGI(TAG, "events dispatched/second with profiling enabled: %d", average); // Enabling profiling will slow down event dispatch, so the set threshold // is not valid when it is enabled. #else #ifndef CONFIG_SPIRAM TEST_PERFORMANCE_GREATER_THAN(EVENT_DISPATCH, "%d", average); #else TEST_PERFORMANCE_GREATER_THAN(EVENT_DISPATCH_PSRAM, "%d", average); #endif // CONFIG_SPIRAM #endif // CONFIG_ESP_EVENT_LOOP_PROFILING } TEST_CASE("performance test - dedicated task", "[event]") { performance_test(true); } TEST_CASE("performance test - no dedicated task", "[event]") { performance_test(false); } TEST_CASE("can post to loop from handler - dedicated task", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop_w_task; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); int count; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateBinary() }; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop_w_task)); count = 0; // Test that a handler can post to a different loop while there is still slots on the queue TEST_ESP_OK(esp_event_handler_register_with(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_post_w_task, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, test_handler_post_w_task, &arg)); TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_w_task, sizeof(&loop_w_task), portMAX_DELAY)); xSemaphoreTake(arg.mutex, portMAX_DELAY); TEST_ASSERT_EQUAL(2, count); // Test that other tasks can still post while there is still slots in the queue, while handler is executing count = 100; TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_w_task, sizeof(&loop_w_task), portMAX_DELAY)); for (int i = 0; i < loop_args.queue_size; i++) { TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER))); xSemaphoreGive(arg.mutex); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); TEST_ESP_OK(esp_event_loop_delete(loop_w_task)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can post to loop from handler instance - dedicated task", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop_w_task; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); int count; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateBinary() }; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop_w_task)); count = 0; esp_event_handler_instance_t ctx_1; esp_event_handler_instance_t ctx_2; // Test that a handler can post to a different loop while there is still slots on the queue TEST_ESP_OK(esp_event_handler_instance_register_with(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_post_w_task, &arg, &ctx_1)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, test_handler_post_w_task, &arg, &ctx_2)); TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_w_task, sizeof(&loop_w_task), portMAX_DELAY)); xSemaphoreTake(arg.mutex, portMAX_DELAY); TEST_ASSERT_EQUAL(2, count); // Test that other tasks can still post while there is still slots in the queue, while handler is executing count = 100; TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_w_task, sizeof(&loop_w_task), portMAX_DELAY)); for (int i = 0; i < loop_args.queue_size; i++) { TEST_ESP_OK(esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); } TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(loop_w_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER))); xSemaphoreGive(arg.mutex); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); TEST_ESP_OK(esp_event_loop_delete(loop_w_task)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can post to loop from handler - no dedicated task", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop_wo_task; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); int count; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateBinary() }; count = 0; loop_args.queue_size = 1; loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop_wo_task)); TaskHandle_t mtask; xTaskCreate(test_post_from_handler_loop_task, "task", 2584, (void*) loop_wo_task, s_test_priority, &mtask); // Test that a handler can post to a different loop while there is still slots on the queue TEST_ESP_OK(esp_event_handler_register_with(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_post_wo_task, &arg)); TEST_ESP_OK(esp_event_handler_register_with(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV2, test_handler_post_wo_task, &arg)); TEST_ESP_OK(esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_wo_task, sizeof(&loop_wo_task), portMAX_DELAY)); xSemaphoreTake(arg.mutex, portMAX_DELAY); TEST_ASSERT_EQUAL(2, count); count = 100; TEST_ESP_OK(esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_wo_task, sizeof(&loop_wo_task), portMAX_DELAY)); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); // For loop without tasks, posting is more restrictive. Posting should wait until execution of handler finishes TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER))); xSemaphoreGive(arg.mutex); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); vTaskDelete(mtask); TEST_ESP_OK(esp_event_loop_delete(loop_wo_task)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } TEST_CASE("can post to loop from handler instance - no dedicated task", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop_wo_task; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); int count; simple_arg_t arg = { .data = &count, .mutex = xSemaphoreCreateBinary() }; count = 0; esp_event_handler_instance_t ctx_1; esp_event_handler_instance_t ctx_2; loop_args.queue_size = 1; loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop_wo_task)); TaskHandle_t mtask; xTaskCreate(test_post_from_handler_loop_task, "task", 2584, (void*) loop_wo_task, s_test_priority, &mtask); // Test that a handler can post to a different loop while there is still slots on the queue TEST_ESP_OK(esp_event_handler_instance_register_with(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_post_wo_task, &arg, &ctx_1)); TEST_ESP_OK(esp_event_handler_instance_register_with(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV2, test_handler_post_wo_task, &arg, &ctx_2)); TEST_ESP_OK(esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_wo_task, sizeof(&loop_wo_task), portMAX_DELAY)); xSemaphoreTake(arg.mutex, portMAX_DELAY); TEST_ASSERT_EQUAL(2, count); count = 100; TEST_ESP_OK(esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV1, &loop_wo_task, sizeof(&loop_wo_task), portMAX_DELAY)); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); // For loop without tasks, posting is more restrictive. Posting should wait until execution of handler finishes TEST_ASSERT_EQUAL(ESP_ERR_TIMEOUT, esp_event_post_to(loop_wo_task, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER))); xSemaphoreGive(arg.mutex); vTaskDelay(pdMS_TO_TICKS(CONFIG_ESP_INT_WDT_TIMEOUT_MS * TEST_CONFIG_WAIT_MULTIPLIER)); vTaskDelete(mtask); TEST_ESP_OK(esp_event_loop_delete(loop_wo_task)); vSemaphoreDelete(arg.mutex); TEST_TEARDOWN(); } static void test_event_simple_handler_template(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { int* count = (int*) handler_arg; (*count)++; } static void test_event_simple_handler_1(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { test_event_simple_handler_template(handler_arg, base, id, event_arg); } static void test_event_simple_handler_3(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { test_event_simple_handler_template(handler_arg, base, id, event_arg); } static void test_event_simple_handler_2(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { test_event_simple_handler_template(handler_arg, base, id, event_arg); } static void test_registration_from_handler_hdlr(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_arg; TEST_ESP_OK(esp_event_handler_register_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_1, handler_arg)); TEST_ESP_OK(esp_event_handler_register_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_2, handler_arg)); TEST_ESP_OK(esp_event_handler_register_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_3, handler_arg)); } static void test_unregistration_from_handler_hdlr(void* handler_arg, esp_event_base_t base, int32_t id, void* event_arg) { esp_event_loop_handle_t* loop = (esp_event_loop_handle_t*) event_arg; TEST_ESP_OK(esp_event_handler_unregister_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_1)); TEST_ESP_OK(esp_event_handler_unregister_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_2)); TEST_ESP_OK(esp_event_handler_unregister_with(*loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_simple_handler_3)); } TEST_CASE("can register from handler", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int count = 0; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_registration_from_handler_hdlr, &count)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE2_EV1, test_unregistration_from_handler_hdlr, &count)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &loop, sizeof(&loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(3, count); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE2_EV1, &loop, sizeof(&loop), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ASSERT_EQUAL(3, count); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } static void test_create_loop_handler(void* handler_args, esp_event_base_t base, int32_t id, void* event_data) { esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); if (id == TEST_EVENT_BASE1_EV1) { TEST_ESP_OK(esp_event_loop_create(&loop_args, (esp_event_loop_handle_t*) handler_args)); } else { TEST_ESP_OK(esp_event_loop_delete(*((esp_event_loop_handle_t*) handler_args))); } } TEST_CASE("can create and delete loop from handler", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_handle_t test_loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_create_loop_handler, &test_loop)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_create_loop_handler, &test_loop)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, NULL, 0, portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } TEST_CASE("events are dispatched in the order they are registered", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); int id_arr[7]; for (int i = 0; i < 7; i++) { id_arr[i] = i; } int data_arr[12] = {0}; TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE2_EV1, test_event_ordered_dispatch, id_arr + 0)); TEST_ESP_OK(esp_event_handler_register_with(loop, ESP_EVENT_ANY_BASE, ESP_EVENT_ANY_ID, test_event_ordered_dispatch, id_arr + 1)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, ESP_EVENT_ANY_ID, test_event_ordered_dispatch, id_arr + 2)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, TEST_EVENT_BASE2_EV2, test_event_ordered_dispatch, id_arr + 3)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV1, test_event_ordered_dispatch, id_arr + 4)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base2, ESP_EVENT_ANY_ID, test_event_ordered_dispatch, id_arr + 5)); TEST_ESP_OK(esp_event_handler_register_with(loop, s_test_base1, TEST_EVENT_BASE1_EV2, test_event_ordered_dispatch, id_arr + 6)); esp_event_dump(stdout); ordered_data_t data = { .arr = data_arr, .index = 0 }; ordered_data_t* dptr = &data; TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV2, &dptr, sizeof(dptr), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &dptr, sizeof(dptr), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV2, &dptr, sizeof(dptr), portMAX_DELAY)); TEST_ESP_OK(esp_event_post_to(loop, s_test_base2, TEST_EVENT_BASE1_EV1, &dptr, sizeof(dptr), portMAX_DELAY)); TEST_ESP_OK(esp_event_loop_run(loop, pdMS_TO_TICKS(10))); // Expected data executing the posts above int ref_arr[12] = {1, 3, 5, 1, 2, 4, 1, 2, 6, 0, 1, 5}; for (int i = 0; i < 12; i++) { TEST_ASSERT_EQUAL(ref_arr[i], data_arr[i]); } TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } #if CONFIG_ESP_EVENT_POST_FROM_ISR TEST_CASE("can properly prepare event data posted to loop", "[event]") { TEST_SETUP(); esp_event_loop_handle_t loop; esp_event_loop_args_t loop_args = test_event_get_default_loop_args(); loop_args.task_name = NULL; TEST_ESP_OK(esp_event_loop_create(&loop_args, &loop)); esp_event_post_instance_t post; esp_event_loop_instance_t* loop_def = (esp_event_loop_instance_t*) loop; TEST_ESP_OK(esp_event_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, NULL, 0, portMAX_DELAY)); TEST_ASSERT_EQUAL(pdTRUE, xQueueReceive(loop_def->queue, &post, portMAX_DELAY)); TEST_ASSERT_EQUAL(false, post.data_set); TEST_ASSERT_EQUAL(false, post.data_allocated); TEST_ASSERT_EQUAL(NULL, post.data.ptr); int sample = 0; TEST_ESP_OK(esp_event_isr_post_to(loop, s_test_base1, TEST_EVENT_BASE1_EV1, &sample, sizeof(sample), NULL)); TEST_ASSERT_EQUAL(pdTRUE, xQueueReceive(loop_def->queue, &post, portMAX_DELAY)); TEST_ASSERT_EQUAL(true, post.data_set); TEST_ASSERT_EQUAL(false, post.data_allocated); TEST_ASSERT_EQUAL(false, post.data.val); TEST_ESP_OK(esp_event_loop_delete(loop)); TEST_TEARDOWN(); } static void test_handler_post_from_isr(void* event_handler_arg, esp_event_base_t event_base, int32_t event_id, void* event_data) { SemaphoreHandle_t *sem = (SemaphoreHandle_t*) event_handler_arg; // Event data is just the address value (maybe have been truncated due to casting). int *data = (int*) event_data; TEST_ASSERT_EQUAL(*data, (int) (*sem)); xSemaphoreGive(*sem); } void IRAM_ATTR test_event_on_timer_alarm(void* para) { /* Retrieve the interrupt status and the counter value from the timer that reported the interrupt */ uint64_t timer_counter_value = timer_group_get_counter_value_in_isr(TIMER_GROUP_0, TIMER_0); timer_group_clr_intr_status_in_isr(TIMER_GROUP_0, TIMER_0); timer_counter_value += (uint64_t) (TIMER_INTERVAL0_SEC * TIMER_SCALE); timer_group_set_alarm_value_in_isr(TIMER_GROUP_0, TIMER_0, timer_counter_value); int data = (int) para; // Posting events with data more than 4 bytes should fail. TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, esp_event_isr_post(s_test_base1, TEST_EVENT_BASE1_EV1, &data, 5, NULL)); // This should succeedd, as data is int-sized. The handler for the event checks that the passed event data // is correct. BaseType_t task_unblocked; TEST_ESP_OK(esp_event_isr_post(s_test_base1, TEST_EVENT_BASE1_EV1, &data, sizeof(data), &task_unblocked)); if (task_unblocked == pdTRUE) { portYIELD_FROM_ISR(); } } TEST_CASE("can post events from interrupt handler", "[event]") { SemaphoreHandle_t sem = xSemaphoreCreateBinary(); /* Select and initialize basic parameters of the timer */ timer_config_t config = { .divider = TIMER_DIVIDER, .counter_dir = TIMER_COUNT_UP, .counter_en = TIMER_PAUSE, .alarm_en = TIMER_ALARM_EN, .intr_type = TIMER_INTR_LEVEL, .auto_reload = false, }; timer_init(TIMER_GROUP_0, TIMER_0, &config); /* Timer's counter will initially start from value below. Also, if auto_reload is set, this value will be automatically reload on alarm */ timer_set_counter_value(TIMER_GROUP_0, TIMER_0, 0x00000000ULL); /* Configure the alarm value and the interrupt on alarm. */ timer_set_alarm_value(TIMER_GROUP_0, TIMER_0, TIMER_INTERVAL0_SEC * TIMER_SCALE); timer_enable_intr(TIMER_GROUP_0, TIMER_0); timer_isr_register(TIMER_GROUP_0, TIMER_0, test_event_on_timer_alarm, (void *) sem, ESP_INTR_FLAG_IRAM, NULL); timer_start(TIMER_GROUP_0, TIMER_0); TEST_SETUP(); TEST_ESP_OK(esp_event_handler_register(s_test_base1, TEST_EVENT_BASE1_EV1, test_handler_post_from_isr, &sem)); xSemaphoreTake(sem, portMAX_DELAY); TEST_TEARDOWN(); } #endif // CONFIG_ESP_EVENT_POST_FROM_ISR