// Copyright 2018 Espressif Systems (Shanghai) PTE LTD // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include "esp_log.h" #include "esp_event.h" #include "esp_event_internal.h" #include "esp_event_private.h" #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING #include "esp_timer.h" #endif /* ---------------------------- Definitions --------------------------------- */ #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING // LOOP @ rx: dr: #define LOOP_DUMP_FORMAT "LOOP @%p,%s rx:%u dr:%u\n" // handler @
ev: inv: time: #define HANDLER_DUMP_FORMAT " HANDLER @%p ev:%s,%s inv:%u time:%lld us\n" #define PRINT_DUMP_INFO(dst, sz, ...) do { \ int cb = snprintf(dst, sz, __VA_ARGS__); \ dst += cb; \ sz -= cb; \ } while(0); #endif /* ------------------------- Static Variables ------------------------------- */ static const char* TAG = "event"; static const char* esp_event_any_base = "any"; #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING static SLIST_HEAD(esp_event_loop_instance_list_t, esp_event_loop_instance) s_event_loops = SLIST_HEAD_INITIALIZER(s_event_loops); static portMUX_TYPE s_event_loops_spinlock = portMUX_INITIALIZER_UNLOCKED; #endif /* ------------------------- Static Functions ------------------------------- */ #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING static int esp_event_dump_prepare(void) { esp_event_loop_instance_t* loop_it; esp_event_loop_node_t *loop_node_it; esp_event_base_node_t* base_node_it; esp_event_id_node_t* id_node_it; esp_event_handler_node_t* handler_it; // Count the number of items to be printed. This is needed to compute how much memory to reserve. int loops = 0, handlers = 0; portENTER_CRITICAL(&s_event_loops_spinlock); SLIST_FOREACH(loop_it, &s_event_loops, next) { SLIST_FOREACH(loop_node_it, &(loop_it->loop_nodes), next) { SLIST_FOREACH(handler_it, &(loop_node_it->handlers), next) { handlers++; } SLIST_FOREACH(base_node_it, &(loop_node_it->base_nodes), next) { SLIST_FOREACH(handler_it, &(base_node_it->handlers), next) { handlers++; } SLIST_FOREACH(id_node_it, &(base_node_it->id_nodes), next) { SLIST_FOREACH(handler_it, &(id_node_it->handlers), next) { handlers++; } } } } loops++; } portEXIT_CRITICAL(&s_event_loops_spinlock); // Reserve slightly more memory than computed int allowance = 3; int size = (((loops + allowance) * (sizeof(LOOP_DUMP_FORMAT) + 10 + 20 + 2 * 11)) + ((handlers + allowance) * (sizeof(HANDLER_DUMP_FORMAT) + 10 + 2 * 20 + 11 + 20))); return size; } #endif static void esp_event_loop_run_task(void* args) { esp_err_t err; esp_event_loop_handle_t event_loop = (esp_event_loop_handle_t) args; ESP_LOGD(TAG, "running task for loop %p", event_loop); while(1) { err = esp_event_loop_run(event_loop, portMAX_DELAY); if (err != ESP_OK) { break; } } ESP_LOGE(TAG, "suspended task for loop %p", event_loop); vTaskSuspend(NULL); } static void handler_execute(esp_event_loop_instance_t* loop, esp_event_handler_node_t *handler, esp_event_post_instance_t post) { ESP_LOGD(TAG, "running post %s:%d with handler %p and context %p on loop %p", post.base, post.id, handler->handler_ctx->handler, &handler->handler_ctx, loop); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING int64_t start, diff; start = esp_timer_get_time(); #endif // Execute the handler #if CONFIG_ESP_EVENT_POST_FROM_ISR void* data_ptr = NULL; if (post.data_set) { if (post.data_allocated) { data_ptr = post.data.ptr; } else { data_ptr = &post.data.val; } } (*(handler->handler_ctx->handler))(handler->handler_ctx->arg, post.base, post.id, data_ptr); #else (*(handler->handler_ctx->handler))(handler->handler_ctx->arg, post.base, post.id, post.data); #endif #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING diff = esp_timer_get_time() - start; xSemaphoreTake(loop->profiling_mutex, portMAX_DELAY); handler->invoked++; handler->time += diff; xSemaphoreGive(loop->profiling_mutex); #endif } static esp_err_t handler_instances_add(esp_event_handler_nodes_t* handlers, esp_event_handler_t event_handler, void* event_handler_arg, esp_event_handler_instance_context_t **handler_ctx, bool legacy) { esp_event_handler_node_t *handler_instance = calloc(1, sizeof(*handler_instance)); if (!handler_instance) return ESP_ERR_NO_MEM; esp_event_handler_instance_context_t *context = calloc(1, sizeof(*context)); if (!context) { free(handler_instance); return ESP_ERR_NO_MEM; } context->handler = event_handler; context->arg = event_handler_arg; handler_instance->handler_ctx = context; if (SLIST_EMPTY(handlers)) { SLIST_INSERT_HEAD(handlers, handler_instance, next); } else { esp_event_handler_node_t *it = NULL, *last = NULL; SLIST_FOREACH(it, handlers, next) { if (legacy) { if(event_handler == it->handler_ctx->handler) { it->handler_ctx->arg = event_handler_arg; ESP_LOGW(TAG, "handler already registered, overwriting"); free(handler_instance); free(context); return ESP_OK; } } last = it; } SLIST_INSERT_AFTER(last, handler_instance, next); } // If the caller didn't provide the handler instance context, don't set it. // It will be removed once the event loop is deleted. if (handler_ctx) { *handler_ctx = context; } return ESP_OK; } static esp_err_t base_node_add_handler(esp_event_base_node_t* base_node, int32_t id, esp_event_handler_t event_handler, void *event_handler_arg, esp_event_handler_instance_context_t **handler_ctx, bool legacy) { if (id == ESP_EVENT_ANY_ID) { return handler_instances_add(&(base_node->handlers), event_handler, event_handler_arg, handler_ctx, legacy); } else { esp_err_t err = ESP_OK; esp_event_id_node_t *it = NULL, *id_node = NULL, *last_id_node = NULL; SLIST_FOREACH(it, &(base_node->id_nodes), next) { if (it->id == id) { id_node = it; } last_id_node = it; } if (!last_id_node || !id_node) { id_node = (esp_event_id_node_t*) calloc(1, sizeof(*id_node)); if (!id_node) { ESP_LOGE(TAG, "alloc for new id node failed"); return ESP_ERR_NO_MEM; } id_node->id = id; SLIST_INIT(&(id_node->handlers)); err = handler_instances_add(&(id_node->handlers), event_handler, event_handler_arg, handler_ctx, legacy); if (err == ESP_OK) { if (!last_id_node) { SLIST_INSERT_HEAD(&(base_node->id_nodes), id_node, next); } else { SLIST_INSERT_AFTER(last_id_node, id_node, next); } } else { free(id_node); } return err; } else { return handler_instances_add(&(id_node->handlers), event_handler, event_handler_arg, handler_ctx, legacy); } } } static esp_err_t loop_node_add_handler(esp_event_loop_node_t* loop_node, esp_event_base_t base, int32_t id, esp_event_handler_t event_handler, void *event_handler_arg, esp_event_handler_instance_context_t **handler_ctx, bool legacy) { if (base == esp_event_any_base && id == ESP_EVENT_ANY_ID) { return handler_instances_add(&(loop_node->handlers), event_handler, event_handler_arg, handler_ctx, legacy); } else { esp_err_t err = ESP_OK; esp_event_base_node_t *it = NULL, *base_node = NULL, *last_base_node = NULL; SLIST_FOREACH(it, &(loop_node->base_nodes), next) { if (it->base == base) { base_node = it; } last_base_node = it; } if (!last_base_node || !base_node || (base_node && !SLIST_EMPTY(&(base_node->id_nodes)) && id == ESP_EVENT_ANY_ID) || (last_base_node && last_base_node->base != base && !SLIST_EMPTY(&(last_base_node->id_nodes)) && id == ESP_EVENT_ANY_ID)) { base_node = (esp_event_base_node_t*) calloc(1, sizeof(*base_node)); if (!base_node) { ESP_LOGE(TAG, "alloc mem for new base node failed"); return ESP_ERR_NO_MEM; } base_node->base = base; SLIST_INIT(&(base_node->handlers)); SLIST_INIT(&(base_node->id_nodes)); err = base_node_add_handler(base_node, id, event_handler, event_handler_arg, handler_ctx, legacy); if (err == ESP_OK) { if (!last_base_node) { SLIST_INSERT_HEAD(&(loop_node->base_nodes), base_node, next); } else { SLIST_INSERT_AFTER(last_base_node, base_node, next); } } else { free(base_node); } return err; } else { return base_node_add_handler(base_node, id, event_handler, event_handler_arg, handler_ctx, legacy); } } } static esp_err_t handler_instances_remove(esp_event_handler_nodes_t* handlers, esp_event_handler_instance_context_t* handler_ctx, bool legacy) { esp_event_handler_node_t *it, *temp; SLIST_FOREACH_SAFE(it, handlers, next, temp) { if (legacy) { if (it->handler_ctx->handler == handler_ctx->handler) { SLIST_REMOVE(handlers, it, esp_event_handler_node, next); free(it->handler_ctx); free(it); return ESP_OK; } } else { if (it->handler_ctx == handler_ctx) { SLIST_REMOVE(handlers, it, esp_event_handler_node, next); free(it->handler_ctx); free(it); return ESP_OK; } } } return ESP_ERR_NOT_FOUND; } static esp_err_t base_node_remove_handler(esp_event_base_node_t* base_node, int32_t id, esp_event_handler_instance_context_t* handler_ctx, bool legacy) { if (id == ESP_EVENT_ANY_ID) { return handler_instances_remove(&(base_node->handlers), handler_ctx, legacy); } else { esp_event_id_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(base_node->id_nodes), next, temp) { if (it->id == id) { esp_err_t res = handler_instances_remove(&(it->handlers), handler_ctx, legacy); if (res == ESP_OK) { if (SLIST_EMPTY(&(it->handlers))) { SLIST_REMOVE(&(base_node->id_nodes), it, esp_event_id_node, next); free(it); return ESP_OK; } } } } } return ESP_ERR_NOT_FOUND; } static esp_err_t loop_node_remove_handler(esp_event_loop_node_t* loop_node, esp_event_base_t base, int32_t id, esp_event_handler_instance_context_t* handler_ctx, bool legacy) { if (base == esp_event_any_base && id == ESP_EVENT_ANY_ID) { return handler_instances_remove(&(loop_node->handlers), handler_ctx, legacy); } else { esp_event_base_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(loop_node->base_nodes), next, temp) { if (it->base == base) { esp_err_t res = base_node_remove_handler(it, id, handler_ctx, legacy); if (res == ESP_OK) { if (SLIST_EMPTY(&(it->handlers)) && SLIST_EMPTY(&(it->id_nodes))) { SLIST_REMOVE(&(loop_node->base_nodes), it, esp_event_base_node, next); free(it); return ESP_OK; } } } } } return ESP_ERR_NOT_FOUND; } static void handler_instances_remove_all(esp_event_handler_nodes_t* handlers) { esp_event_handler_node_t *it, *temp; SLIST_FOREACH_SAFE(it, handlers, next, temp) { SLIST_REMOVE(handlers, it, esp_event_handler_node, next); free(it->handler_ctx); free(it); } } static void base_node_remove_all_handler(esp_event_base_node_t* base_node) { handler_instances_remove_all(&(base_node->handlers)); esp_event_id_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(base_node->id_nodes), next, temp) { handler_instances_remove_all(&(it->handlers)); SLIST_REMOVE(&(base_node->id_nodes), it, esp_event_id_node, next); free(it); } } static void loop_node_remove_all_handler(esp_event_loop_node_t* loop_node) { handler_instances_remove_all(&(loop_node->handlers)); esp_event_base_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(loop_node->base_nodes), next, temp) { base_node_remove_all_handler(it); SLIST_REMOVE(&(loop_node->base_nodes), it, esp_event_base_node, next); free(it); } } static void inline __attribute__((always_inline)) post_instance_delete(esp_event_post_instance_t* post) { #if CONFIG_ESP_EVENT_POST_FROM_ISR if (post->data_allocated && post->data.ptr) { free(post->data.ptr); } #else if (post->data) { free(post->data); } #endif memset(post, 0, sizeof(*post)); } /* ---------------------------- Public API --------------------------------- */ esp_err_t esp_event_loop_create(const esp_event_loop_args_t* event_loop_args, esp_event_loop_handle_t* event_loop) { if (event_loop_args == NULL) { ESP_LOGE(TAG, "event_loop_args was NULL"); return ESP_ERR_INVALID_ARG; } if (event_loop == NULL) { ESP_LOGE(TAG, "event_loop was NULL"); return ESP_ERR_INVALID_ARG; } esp_event_loop_instance_t* loop; esp_err_t err = ESP_ERR_NO_MEM; // most likely error loop = calloc(1, sizeof(*loop)); if (loop == NULL) { ESP_LOGE(TAG, "alloc for event loop failed"); return err; } loop->queue = xQueueCreate(event_loop_args->queue_size , sizeof(esp_event_post_instance_t)); if (loop->queue == NULL) { ESP_LOGE(TAG, "create event loop queue failed"); goto on_err; } loop->mutex = xSemaphoreCreateRecursiveMutex(); if (loop->mutex == NULL) { ESP_LOGE(TAG, "create event loop mutex failed"); goto on_err; } #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING loop->profiling_mutex = xSemaphoreCreateMutex(); if (loop->profiling_mutex == NULL) { ESP_LOGE(TAG, "create event loop profiling mutex failed"); goto on_err; } #endif SLIST_INIT(&(loop->loop_nodes)); // Create the loop task if requested if (event_loop_args->task_name != NULL) { BaseType_t task_created = xTaskCreatePinnedToCore(esp_event_loop_run_task, event_loop_args->task_name, event_loop_args->task_stack_size, (void*) loop, event_loop_args->task_priority, &(loop->task), event_loop_args->task_core_id); if (task_created != pdPASS) { ESP_LOGE(TAG, "create task for loop failed"); err = ESP_FAIL; goto on_err; } loop->name = event_loop_args->task_name; ESP_LOGD(TAG, "created task for loop %p", loop); } else { loop->name = ""; loop->task = NULL; } loop->running_task = NULL; #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING portENTER_CRITICAL(&s_event_loops_spinlock); SLIST_INSERT_HEAD(&s_event_loops, loop, next); portEXIT_CRITICAL(&s_event_loops_spinlock); #endif *event_loop = (esp_event_loop_handle_t) loop; ESP_LOGD(TAG, "created event loop %p", loop); return ESP_OK; on_err: if (loop->queue != NULL) { vQueueDelete(loop->queue); } if (loop->mutex != NULL) { vSemaphoreDelete(loop->mutex); } #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING if (loop->profiling_mutex != NULL) { vSemaphoreDelete(loop->profiling_mutex); } #endif free(loop); return err; } // On event lookup performance: The library implements the event list as a linked list, which results to O(n) // lookup time. The test comparing this implementation to the O(lg n) performance of rbtrees // (https://github.com/freebsd/freebsd/blob/master/sys/sys/tree.h) // indicate that the difference is not that substantial, especially considering the additional // pointers per node of rbtrees. Code for the rbtree implementation of the event loop library is archived // in feature/esp_event_loop_library_rbtrees if needed. esp_err_t esp_event_loop_run(esp_event_loop_handle_t event_loop, TickType_t ticks_to_run) { assert(event_loop); esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; esp_event_post_instance_t post; TickType_t marker = xTaskGetTickCount(); TickType_t end = 0; #if (configUSE_16_BIT_TICKS == 1) int32_t remaining_ticks = ticks_to_run; #else int64_t remaining_ticks = ticks_to_run; #endif while(xQueueReceive(loop->queue, &post, ticks_to_run) == pdTRUE) { // The event has already been unqueued, so ensure it gets executed. xSemaphoreTakeRecursive(loop->mutex, portMAX_DELAY); loop->running_task = xTaskGetCurrentTaskHandle(); bool exec = false; esp_event_handler_node_t *handler, *temp_handler; esp_event_loop_node_t *loop_node, *temp_node; esp_event_base_node_t *base_node, *temp_base; esp_event_id_node_t *id_node, *temp_id_node; SLIST_FOREACH_SAFE(loop_node, &(loop->loop_nodes), next, temp_node) { // Execute loop level handlers SLIST_FOREACH_SAFE(handler, &(loop_node->handlers), next, temp_handler) { handler_execute(loop, handler, post); exec |= true; } SLIST_FOREACH_SAFE(base_node, &(loop_node->base_nodes), next, temp_base) { if (base_node->base == post.base) { // Execute base level handlers SLIST_FOREACH_SAFE(handler, &(base_node->handlers), next, temp_handler) { handler_execute(loop, handler, post); exec |= true; } SLIST_FOREACH_SAFE(id_node, &(base_node->id_nodes), next, temp_id_node) { if (id_node->id == post.id) { // Execute id level handlers SLIST_FOREACH_SAFE(handler, &(id_node->handlers), next, temp_handler) { handler_execute(loop, handler, post); exec |= true; } // Skip to next base node break; } } } } } esp_event_base_t base = post.base; int32_t id = post.id; post_instance_delete(&post); if (ticks_to_run != portMAX_DELAY) { end = xTaskGetTickCount(); remaining_ticks -= end - marker; // If the ticks to run expired, return to the caller if (remaining_ticks <= 0) { xSemaphoreGiveRecursive(loop->mutex); break; } else { marker = end; } } loop->running_task = NULL; xSemaphoreGiveRecursive(loop->mutex); if (!exec) { // No handlers were registered, not even loop/base level handlers ESP_LOGD(TAG, "no handlers have been registered for event %s:%d posted to loop %p", base, id, event_loop); } } return ESP_OK; } esp_err_t esp_event_loop_delete(esp_event_loop_handle_t event_loop) { assert(event_loop); esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; SemaphoreHandle_t loop_mutex = loop->mutex; #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING SemaphoreHandle_t loop_profiling_mutex = loop->profiling_mutex; #endif xSemaphoreTakeRecursive(loop->mutex, portMAX_DELAY); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING xSemaphoreTakeRecursive(loop->profiling_mutex, portMAX_DELAY); portENTER_CRITICAL(&s_event_loops_spinlock); SLIST_REMOVE(&s_event_loops, loop, esp_event_loop_instance, next); portEXIT_CRITICAL(&s_event_loops_spinlock); #endif // Delete the task if it was created if (loop->task != NULL) { vTaskDelete(loop->task); } // Remove all registered events and handlers in the loop esp_event_loop_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(loop->loop_nodes), next, temp) { loop_node_remove_all_handler(it); SLIST_REMOVE(&(loop->loop_nodes), it, esp_event_loop_node, next); free(it); } // Drop existing posts on the queue esp_event_post_instance_t post; while(xQueueReceive(loop->queue, &post, 0) == pdTRUE) { post_instance_delete(&post); } // Cleanup loop vQueueDelete(loop->queue); free(loop); // Free loop mutex before deleting xSemaphoreGiveRecursive(loop_mutex); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING xSemaphoreGiveRecursive(loop_profiling_mutex); vSemaphoreDelete(loop_profiling_mutex); #endif vSemaphoreDelete(loop_mutex); ESP_LOGD(TAG, "deleted loop %p", (void*) event_loop); return ESP_OK; } esp_err_t esp_event_handler_register_with_internal(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_t event_handler, void* event_handler_arg, esp_event_handler_instance_context_t** handler_ctx_arg, bool legacy) { assert(event_loop); assert(event_handler); if (event_base == ESP_EVENT_ANY_BASE && event_id != ESP_EVENT_ANY_ID) { ESP_LOGE(TAG, "registering to any event base with specific id unsupported"); return ESP_ERR_INVALID_ARG; } esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; if (event_base == ESP_EVENT_ANY_BASE) { event_base = esp_event_any_base; } esp_err_t err = ESP_OK; xSemaphoreTakeRecursive(loop->mutex, portMAX_DELAY); esp_event_loop_node_t *loop_node = NULL, *last_loop_node = NULL; SLIST_FOREACH(loop_node, &(loop->loop_nodes), next) { last_loop_node = loop_node; } bool is_loop_level_handler = (event_base == esp_event_any_base) && (event_id == ESP_EVENT_ANY_ID); if (!last_loop_node || (last_loop_node && !SLIST_EMPTY(&(last_loop_node->base_nodes)) && is_loop_level_handler)) { loop_node = (esp_event_loop_node_t*) calloc(1, sizeof(*loop_node)); if (!loop_node) { ESP_LOGE(TAG, "alloc for new loop node failed"); err = ESP_ERR_NO_MEM; goto on_err; } SLIST_INIT(&(loop_node->handlers)); SLIST_INIT(&(loop_node->base_nodes)); err = loop_node_add_handler(loop_node, event_base, event_id, event_handler, event_handler_arg, handler_ctx_arg, legacy); if (err == ESP_OK) { if (!last_loop_node) { SLIST_INSERT_HEAD(&(loop->loop_nodes), loop_node, next); } else { SLIST_INSERT_AFTER(last_loop_node, loop_node, next); } } else { free(loop_node); } } else { err = loop_node_add_handler(last_loop_node, event_base, event_id, event_handler, event_handler_arg, handler_ctx_arg, legacy); } on_err: xSemaphoreGiveRecursive(loop->mutex); return err; } esp_err_t esp_event_handler_register_with(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_t event_handler, void* event_handler_arg) { return esp_event_handler_register_with_internal(event_loop, event_base, event_id, event_handler, event_handler_arg, NULL, true); } esp_err_t esp_event_handler_instance_register_with(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_t event_handler, void* event_handler_arg, esp_event_handler_instance_t* handler_ctx_arg) { return esp_event_handler_register_with_internal(event_loop, event_base, event_id, event_handler, event_handler_arg, (esp_event_handler_instance_context_t**) handler_ctx_arg, false); } esp_err_t esp_event_handler_unregister_with_internal(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_instance_context_t* handler_ctx, bool legacy) { assert(event_loop); assert(handler_ctx); if (event_base == ESP_EVENT_ANY_BASE && event_id != ESP_EVENT_ANY_ID) { ESP_LOGE(TAG, "unregistering to any event base with specific id unsupported"); return ESP_FAIL; } if (event_base == ESP_EVENT_ANY_BASE) { event_base = esp_event_any_base; } esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; xSemaphoreTakeRecursive(loop->mutex, portMAX_DELAY); esp_event_loop_node_t *it, *temp; SLIST_FOREACH_SAFE(it, &(loop->loop_nodes), next, temp) { esp_err_t res = loop_node_remove_handler(it, event_base, event_id, handler_ctx, legacy); if (res == ESP_OK && SLIST_EMPTY(&(it->base_nodes)) && SLIST_EMPTY(&(it->handlers))) { SLIST_REMOVE(&(loop->loop_nodes), it, esp_event_loop_node, next); free(it); break; } } xSemaphoreGiveRecursive(loop->mutex); return ESP_OK; } esp_err_t esp_event_handler_unregister_with(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_t event_handler) { esp_event_handler_instance_context_t local_handler_ctx; local_handler_ctx.handler = event_handler; local_handler_ctx.arg = NULL; return esp_event_handler_unregister_with_internal(event_loop, event_base, event_id, &local_handler_ctx, true); } esp_err_t esp_event_handler_instance_unregister_with(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, esp_event_handler_instance_t handler_ctx_arg) { if (!handler_ctx_arg) return ESP_ERR_INVALID_ARG; return esp_event_handler_unregister_with_internal(event_loop, event_base, event_id, (esp_event_handler_instance_context_t*) handler_ctx_arg, false); } esp_err_t esp_event_post_to(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, void* event_data, size_t event_data_size, TickType_t ticks_to_wait) { assert(event_loop); if (event_base == ESP_EVENT_ANY_BASE || event_id == ESP_EVENT_ANY_ID) { return ESP_ERR_INVALID_ARG; } esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; esp_event_post_instance_t post; memset((void*)(&post), 0, sizeof(post)); if (event_data != NULL && event_data_size != 0) { // Make persistent copy of event data on heap. void* event_data_copy = calloc(1, event_data_size); if (event_data_copy == NULL) { return ESP_ERR_NO_MEM; } memcpy(event_data_copy, event_data, event_data_size); #if CONFIG_ESP_EVENT_POST_FROM_ISR post.data.ptr = event_data_copy; post.data_allocated = true; post.data_set = true; #else post.data = event_data_copy; #endif } post.base = event_base; post.id = event_id; BaseType_t result = pdFALSE; // Find the task that currently executes the loop. It is safe to query loop->task since it is // not mutated since loop creation. ENSURE THIS REMAINS TRUE. if (loop->task == NULL) { // The loop has no dedicated task. Find out what task is currently running it. result = xSemaphoreTakeRecursive(loop->mutex, ticks_to_wait); if (result == pdTRUE) { if (loop->running_task != xTaskGetCurrentTaskHandle()) { xSemaphoreGiveRecursive(loop->mutex); result = xQueueSendToBack(loop->queue, &post, ticks_to_wait); } else { xSemaphoreGiveRecursive(loop->mutex); result = xQueueSendToBack(loop->queue, &post, 0); } } } else { // The loop has a dedicated task. if (loop->task != xTaskGetCurrentTaskHandle()) { result = xQueueSendToBack(loop->queue, &post, ticks_to_wait); } else { result = xQueueSendToBack(loop->queue, &post, 0); } } if (result != pdTRUE) { post_instance_delete(&post); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING atomic_fetch_add(&loop->events_dropped, 1); #endif return ESP_ERR_TIMEOUT; } #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING atomic_fetch_add(&loop->events_recieved, 1); #endif return ESP_OK; } #if CONFIG_ESP_EVENT_POST_FROM_ISR esp_err_t esp_event_isr_post_to(esp_event_loop_handle_t event_loop, esp_event_base_t event_base, int32_t event_id, void* event_data, size_t event_data_size, BaseType_t* task_unblocked) { assert(event_loop); if (event_base == ESP_EVENT_ANY_BASE || event_id == ESP_EVENT_ANY_ID) { return ESP_ERR_INVALID_ARG; } esp_event_loop_instance_t* loop = (esp_event_loop_instance_t*) event_loop; esp_event_post_instance_t post; memset((void*)(&post), 0, sizeof(post)); if (event_data_size > sizeof(post.data.val)) { return ESP_ERR_INVALID_ARG; } if (event_data != NULL && event_data_size != 0) { memcpy((void*)(&(post.data.val)), event_data, event_data_size); post.data_allocated = false; post.data_set = true; } post.base = event_base; post.id = event_id; BaseType_t result = pdFALSE; // Post the event from an ISR, result = xQueueSendToBackFromISR(loop->queue, &post, task_unblocked); if (result != pdTRUE) { post_instance_delete(&post); #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING atomic_fetch_add(&loop->events_dropped, 1); #endif return ESP_FAIL; } #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING atomic_fetch_add(&loop->events_recieved, 1); #endif return ESP_OK; } #endif esp_err_t esp_event_dump(FILE* file) { #ifdef CONFIG_ESP_EVENT_LOOP_PROFILING assert(file); esp_event_loop_instance_t* loop_it; esp_event_loop_node_t *loop_node_it; esp_event_base_node_t* base_node_it; esp_event_id_node_t* id_node_it; esp_event_handler_node_t* handler_it; // Allocate memory for printing int sz = esp_event_dump_prepare(); char* buf = calloc(sz, sizeof(char)); char* dst = buf; char id_str_buf[20]; // Print info to buffer portENTER_CRITICAL(&s_event_loops_spinlock); SLIST_FOREACH(loop_it, &s_event_loops, next) { uint32_t events_recieved, events_dropped; events_recieved = atomic_load(&loop_it->events_recieved); events_dropped = atomic_load(&loop_it->events_dropped); PRINT_DUMP_INFO(dst, sz, LOOP_DUMP_FORMAT, loop_it, loop_it->task != NULL ? loop_it->name : "none" , events_recieved, events_dropped); int sz_bak = sz; SLIST_FOREACH(loop_node_it, &(loop_it->loop_nodes), next) { SLIST_FOREACH(handler_it, &(loop_node_it->handlers), next) { PRINT_DUMP_INFO(dst, sz, HANDLER_DUMP_FORMAT, handler_it->handler_ctx->handler, "ESP_EVENT_ANY_BASE", "ESP_EVENT_ANY_ID", handler_it->invoked, handler_it->time); } SLIST_FOREACH(base_node_it, &(loop_node_it->base_nodes), next) { SLIST_FOREACH(handler_it, &(base_node_it->handlers), next) { PRINT_DUMP_INFO(dst, sz, HANDLER_DUMP_FORMAT, handler_it->handler_ctx->handler, base_node_it->base , "ESP_EVENT_ANY_ID", handler_it->invoked, handler_it->time); } SLIST_FOREACH(id_node_it, &(base_node_it->id_nodes), next) { SLIST_FOREACH(handler_it, &(id_node_it->handlers), next) { memset(id_str_buf, 0, sizeof(id_str_buf)); snprintf(id_str_buf, sizeof(id_str_buf), "%d", id_node_it->id); PRINT_DUMP_INFO(dst, sz, HANDLER_DUMP_FORMAT, handler_it->handler_ctx->handler, base_node_it->base , id_str_buf, handler_it->invoked, handler_it->time); } } } } // No handlers registered for this loop if (sz == sz_bak) { PRINT_DUMP_INFO(dst, sz, " NO HANDLERS REGISTERED\n"); } } portEXIT_CRITICAL(&s_event_loops_spinlock); // Print the contents of the buffer to the file fprintf(file, buf); // Free the allocated buffer free(buf); #endif return ESP_OK; }