/* GIO - GLib Input, Output and Streaming Library * * Copyright 2011-2018 Red Hat, Inc. * * SPDX-License-Identifier: LGPL-2.1-or-later * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General * Public License along with this library; if not, see . */ #include "config.h" #include "gio_trace.h" #include "gtask.h" #include "gasyncresult.h" #include "gcancellable.h" #include "glib-private.h" #include "gtrace-private.h" #include "glibintl.h" #include /** * GTask: * * A `GTask` represents and manages a cancellable ‘task’. * * ## Asynchronous operations * * The most common usage of `GTask` is as a [iface@Gio.AsyncResult], to * manage data during an asynchronous operation. You call * [ctor@Gio.Task.new] in the ‘start’ method, followed by * [method@Gio.Task.set_task_data] and the like if you need to keep some * additional data associated with the task, and then pass the * task object around through your asynchronous operation. * Eventually, you will call a method such as * [method@Gio.Task.return_pointer] or [method@Gio.Task.return_error], which * will save the value you give it and then invoke the task’s callback * function in the thread-default main context (see * [method@GLib.MainContext.push_thread_default]) * where it was created (waiting until the next iteration of the main * loop first, if necessary). The caller will pass the `GTask` back to * the operation’s finish function (as a [iface@Gio.AsyncResult]), and you can * use [method@Gio.Task.propagate_pointer] or the like to extract the * return value. * * Using `GTask` requires the thread-default [struct@GLib.MainContext] from when * the `GTask` was constructed to be running at least until the task has * completed and its data has been freed. * * If a `GTask` has been constructed and its callback set, it is an error to * not call `g_task_return_*()` on it. GLib will warn at runtime if this happens * (since 2.76). * * Here is an example for using `GTask` as a [iface@Gio.AsyncResult]: * ```c * typedef struct { * CakeFrostingType frosting; * char *message; * } DecorationData; * * static void * decoration_data_free (DecorationData *decoration) * { * g_free (decoration->message); * g_slice_free (DecorationData, decoration); * } * * static void * baked_cb (Cake *cake, * gpointer user_data) * { * GTask *task = user_data; * DecorationData *decoration = g_task_get_task_data (task); * GError *error = NULL; * * if (cake == NULL) * { * g_task_return_new_error (task, BAKER_ERROR, BAKER_ERROR_NO_FLOUR, * "Go to the supermarket"); * g_object_unref (task); * return; * } * * if (!cake_decorate (cake, decoration->frosting, decoration->message, &error)) * { * g_object_unref (cake); * // g_task_return_error() takes ownership of error * g_task_return_error (task, error); * g_object_unref (task); * return; * } * * g_task_return_pointer (task, cake, g_object_unref); * g_object_unref (task); * } * * void * baker_bake_cake_async (Baker *self, * guint radius, * CakeFlavor flavor, * CakeFrostingType frosting, * const char *message, * GCancellable *cancellable, * GAsyncReadyCallback callback, * gpointer user_data) * { * GTask *task; * DecorationData *decoration; * Cake *cake; * * task = g_task_new (self, cancellable, callback, user_data); * if (radius < 3) * { * g_task_return_new_error (task, BAKER_ERROR, BAKER_ERROR_TOO_SMALL, * "%ucm radius cakes are silly", * radius); * g_object_unref (task); * return; * } * * cake = _baker_get_cached_cake (self, radius, flavor, frosting, message); * if (cake != NULL) * { * // _baker_get_cached_cake() returns a reffed cake * g_task_return_pointer (task, cake, g_object_unref); * g_object_unref (task); * return; * } * * decoration = g_slice_new (DecorationData); * decoration->frosting = frosting; * decoration->message = g_strdup (message); * g_task_set_task_data (task, decoration, (GDestroyNotify) decoration_data_free); * * _baker_begin_cake (self, radius, flavor, cancellable, baked_cb, task); * } * * Cake * * baker_bake_cake_finish (Baker *self, * GAsyncResult *result, * GError **error) * { * g_return_val_if_fail (g_task_is_valid (result, self), NULL); * * return g_task_propagate_pointer (G_TASK (result), error); * } * ``` * * ## Chained asynchronous operations * * `GTask` also tries to simplify asynchronous operations that * internally chain together several smaller asynchronous * operations. [method@Gio.Task.get_cancellable], [method@Gio.Task.get_context], * and [method@Gio.Task.get_priority] allow you to get back the task’s * [class@Gio.Cancellable], [struct@GLib.MainContext], and * [I/O priority](iface.AsyncResult.html#io-priority) * when starting a new subtask, so you don’t have to keep track * of them yourself. [method@Gio.Task.attach_source] simplifies the case * of waiting for a source to fire (automatically using the correct * [struct@GLib.MainContext] and priority). * * Here is an example for chained asynchronous operations: * ```c * typedef struct { * Cake *cake; * CakeFrostingType frosting; * char *message; * } BakingData; * * static void * decoration_data_free (BakingData *bd) * { * if (bd->cake) * g_object_unref (bd->cake); * g_free (bd->message); * g_slice_free (BakingData, bd); * } * * static void * decorated_cb (Cake *cake, * GAsyncResult *result, * gpointer user_data) * { * GTask *task = user_data; * GError *error = NULL; * * if (!cake_decorate_finish (cake, result, &error)) * { * g_object_unref (cake); * g_task_return_error (task, error); * g_object_unref (task); * return; * } * * // baking_data_free() will drop its ref on the cake, so we have to * // take another here to give to the caller. * g_task_return_pointer (task, g_object_ref (cake), g_object_unref); * g_object_unref (task); * } * * static gboolean * decorator_ready (gpointer user_data) * { * GTask *task = user_data; * BakingData *bd = g_task_get_task_data (task); * * cake_decorate_async (bd->cake, bd->frosting, bd->message, * g_task_get_cancellable (task), * decorated_cb, task); * * return G_SOURCE_REMOVE; * } * * static void * baked_cb (Cake *cake, * gpointer user_data) * { * GTask *task = user_data; * BakingData *bd = g_task_get_task_data (task); * GError *error = NULL; * * if (cake == NULL) * { * g_task_return_new_error (task, BAKER_ERROR, BAKER_ERROR_NO_FLOUR, * "Go to the supermarket"); * g_object_unref (task); * return; * } * * bd->cake = cake; * * // Bail out now if the user has already cancelled * if (g_task_return_error_if_cancelled (task)) * { * g_object_unref (task); * return; * } * * if (cake_decorator_available (cake)) * decorator_ready (task); * else * { * GSource *source; * * source = cake_decorator_wait_source_new (cake); * // Attach @source to @task’s GMainContext and have it call * // decorator_ready() when it is ready. * g_task_attach_source (task, source, decorator_ready); * g_source_unref (source); * } * } * * void * baker_bake_cake_async (Baker *self, * guint radius, * CakeFlavor flavor, * CakeFrostingType frosting, * const char *message, * gint priority, * GCancellable *cancellable, * GAsyncReadyCallback callback, * gpointer user_data) * { * GTask *task; * BakingData *bd; * * task = g_task_new (self, cancellable, callback, user_data); * g_task_set_priority (task, priority); * * bd = g_slice_new0 (BakingData); * bd->frosting = frosting; * bd->message = g_strdup (message); * g_task_set_task_data (task, bd, (GDestroyNotify) baking_data_free); * * _baker_begin_cake (self, radius, flavor, cancellable, baked_cb, task); * } * * Cake * * baker_bake_cake_finish (Baker *self, * GAsyncResult *result, * GError **error) * { * g_return_val_if_fail (g_task_is_valid (result, self), NULL); * * return g_task_propagate_pointer (G_TASK (result), error); * } * ``` * * ## Asynchronous operations from synchronous ones * * You can use [method@Gio.Task.run_in_thread] to turn a synchronous * operation into an asynchronous one, by running it in a thread. * When it completes, the result will be dispatched to the thread-default main * context (see [method@GLib.MainContext.push_thread_default]) where the `GTask` * was created. * * Running a task in a thread: * ```c * typedef struct { * guint radius; * CakeFlavor flavor; * CakeFrostingType frosting; * char *message; * } CakeData; * * static void * cake_data_free (CakeData *cake_data) * { * g_free (cake_data->message); * g_slice_free (CakeData, cake_data); * } * * static void * bake_cake_thread (GTask *task, * gpointer source_object, * gpointer task_data, * GCancellable *cancellable) * { * Baker *self = source_object; * CakeData *cake_data = task_data; * Cake *cake; * GError *error = NULL; * * cake = bake_cake (baker, cake_data->radius, cake_data->flavor, * cake_data->frosting, cake_data->message, * cancellable, &error); * if (cake) * g_task_return_pointer (task, cake, g_object_unref); * else * g_task_return_error (task, error); * } * * void * baker_bake_cake_async (Baker *self, * guint radius, * CakeFlavor flavor, * CakeFrostingType frosting, * const char *message, * GCancellable *cancellable, * GAsyncReadyCallback callback, * gpointer user_data) * { * CakeData *cake_data; * GTask *task; * * cake_data = g_slice_new (CakeData); * cake_data->radius = radius; * cake_data->flavor = flavor; * cake_data->frosting = frosting; * cake_data->message = g_strdup (message); * task = g_task_new (self, cancellable, callback, user_data); * g_task_set_task_data (task, cake_data, (GDestroyNotify) cake_data_free); * g_task_run_in_thread (task, bake_cake_thread); * g_object_unref (task); * } * * Cake * * baker_bake_cake_finish (Baker *self, * GAsyncResult *result, * GError **error) * { * g_return_val_if_fail (g_task_is_valid (result, self), NULL); * * return g_task_propagate_pointer (G_TASK (result), error); * } * ``` * * ## Adding cancellability to uncancellable tasks * * Finally, [method@Gio.Task.run_in_thread] and * [method@Gio.Task.run_in_thread_sync] can be used to turn an uncancellable * operation into a cancellable one. If you call * [method@Gio.Task.set_return_on_cancel], passing `TRUE`, then if the task’s * [class@Gio.Cancellable] is cancelled, it will return control back to the * caller immediately, while allowing the task thread to continue running in the * background (and simply discarding its result when it finally does finish). * Provided that the task thread is careful about how it uses * locks and other externally-visible resources, this allows you * to make ‘GLib-friendly’ asynchronous and cancellable * synchronous variants of blocking APIs. * * Cancelling a task: * ```c * static void * bake_cake_thread (GTask *task, * gpointer source_object, * gpointer task_data, * GCancellable *cancellable) * { * Baker *self = source_object; * CakeData *cake_data = task_data; * Cake *cake; * GError *error = NULL; * * cake = bake_cake (baker, cake_data->radius, cake_data->flavor, * cake_data->frosting, cake_data->message, * &error); * if (error) * { * g_task_return_error (task, error); * return; * } * * // If the task has already been cancelled, then we don’t want to add * // the cake to the cake cache. Likewise, we don’t want to have the * // task get cancelled in the middle of updating the cache. * // g_task_set_return_on_cancel() will return %TRUE here if it managed * // to disable return-on-cancel, or %FALSE if the task was cancelled * // before it could. * if (g_task_set_return_on_cancel (task, FALSE)) * { * // If the caller cancels at this point, their * // GAsyncReadyCallback won’t be invoked until we return, * // so we don’t have to worry that this code will run at * // the same time as that code does. But if there were * // other functions that might look at the cake cache, * // then we’d probably need a GMutex here as well. * baker_add_cake_to_cache (baker, cake); * g_task_return_pointer (task, cake, g_object_unref); * } * } * * void * baker_bake_cake_async (Baker *self, * guint radius, * CakeFlavor flavor, * CakeFrostingType frosting, * const char *message, * GCancellable *cancellable, * GAsyncReadyCallback callback, * gpointer user_data) * { * CakeData *cake_data; * GTask *task; * * cake_data = g_slice_new (CakeData); * * ... * * task = g_task_new (self, cancellable, callback, user_data); * g_task_set_task_data (task, cake_data, (GDestroyNotify) cake_data_free); * g_task_set_return_on_cancel (task, TRUE); * g_task_run_in_thread (task, bake_cake_thread); * } * * Cake * * baker_bake_cake_sync (Baker *self, * guint radius, * CakeFlavor flavor, * CakeFrostingType frosting, * const char *message, * GCancellable *cancellable, * GError **error) * { * CakeData *cake_data; * GTask *task; * Cake *cake; * * cake_data = g_slice_new (CakeData); * * ... * * task = g_task_new (self, cancellable, NULL, NULL); * g_task_set_task_data (task, cake_data, (GDestroyNotify) cake_data_free); * g_task_set_return_on_cancel (task, TRUE); * g_task_run_in_thread_sync (task, bake_cake_thread); * * cake = g_task_propagate_pointer (task, error); * g_object_unref (task); * return cake; * } * ``` * * ## Porting from [class@Gio.SimpleAsyncResult] * * `GTask`’s API attempts to be simpler than [class@Gio.SimpleAsyncResult]’s * in several ways: * * - You can save task-specific data with [method@Gio.Task.set_task_data], and * retrieve it later with [method@Gio.Task.get_task_data]. This replaces the * abuse of [method@Gio.SimpleAsyncResult.set_op_res_gpointer] for the same * purpose with [class@Gio.SimpleAsyncResult]. * - In addition to the task data, `GTask` also keeps track of the * [priority](iface.AsyncResult.html#io-priority), [class@Gio.Cancellable], * and [struct@GLib.MainContext] associated with the task, so tasks that * consist of a chain of simpler asynchronous operations will have easy access * to those values when starting each sub-task. * - [method@Gio.Task.return_error_if_cancelled] provides simplified * handling for cancellation. In addition, cancellation * overrides any other `GTask` return value by default, like * [class@Gio.SimpleAsyncResult] does when * [method@Gio.SimpleAsyncResult.set_check_cancellable] is called. * (You can use [method@Gio.Task.set_check_cancellable] to turn off that * behavior.) On the other hand, [method@Gio.Task.run_in_thread] * guarantees that it will always run your * `task_func`, even if the task’s [class@Gio.Cancellable] * is already cancelled before the task gets a chance to run; * you can start your `task_func` with a * [method@Gio.Task.return_error_if_cancelled] check if you need the * old behavior. * - The ‘return’ methods (eg, [method@Gio.Task.return_pointer]) * automatically cause the task to be ‘completed’ as well, and * there is no need to worry about the ‘complete’ vs ‘complete in idle’ * distinction. (`GTask` automatically figures out * whether the task’s callback can be invoked directly, or * if it needs to be sent to another [struct@GLib.MainContext], or delayed * until the next iteration of the current [struct@GLib.MainContext].) * - The ‘finish’ functions for `GTask` based operations are generally * much simpler than [class@Gio.SimpleAsyncResult] ones, normally consisting * of only a single call to [method@Gio.Task.propagate_pointer] or the like. * Since [method@Gio.Task.propagate_pointer] ‘steals’ the return value from * the `GTask`, it is not necessary to juggle pointers around to * prevent it from being freed twice. * - With [class@Gio.SimpleAsyncResult], it was common to call * [method@Gio.SimpleAsyncResult.propagate_error] from the * `_finish()` wrapper function, and have * virtual method implementations only deal with successful * returns. This behavior is deprecated, because it makes it * difficult for a subclass to chain to a parent class’s async * methods. Instead, the wrapper function should just be a * simple wrapper, and the virtual method should call an * appropriate `g_task_propagate_` function. * Note that wrapper methods can now use * [method@Gio.AsyncResult.legacy_propagate_error] to do old-style * [class@Gio.SimpleAsyncResult] error-returning behavior, and * [method@Gio.AsyncResult.is_tagged] to check if a result is tagged as * having come from the `_async()` wrapper * function (for ‘short-circuit’ results, such as when passing * `0` to [method@Gio.InputStream.read_async]). * * ## Thread-safety considerations * * Due to some infelicities in the API design, there is a * thread-safety concern that users of `GTask` have to be aware of: * * If the `main` thread drops its last reference to the source object * or the task data before the task is finalized, then the finalizers * of these objects may be called on the worker thread. * * This is a problem if the finalizers use non-threadsafe API, and * can lead to hard-to-debug crashes. Possible workarounds include: * * - Clear task data in a signal handler for `notify::completed` * - Keep iterating a main context in the main thread and defer * dropping the reference to the source object to that main * context when the task is finalized */ struct _GTask { GObject parent_instance; gpointer source_object; gpointer source_tag; gchar *name; /* (owned); may only be modified before the #GTask is threaded */ gpointer task_data; GDestroyNotify task_data_destroy; GMainContext *context; gint64 creation_time; gint priority; GCancellable *cancellable; GAsyncReadyCallback callback; gpointer callback_data; GTaskThreadFunc task_func; GMutex lock; GCond cond; /* This can’t be in the bit field because we access it from TRACE(). */ gboolean thread_cancelled; /* Protected by the lock when task is threaded: */ guint thread_complete : 1; guint return_on_cancel : 1; guint : 0; /* Unprotected, but written to when task runs in thread: */ guint completed : 1; guint had_error : 1; guint result_set : 1; guint ever_returned : 1; guint : 0; /* Read-only once task runs in thread: */ guint check_cancellable : 1; guint synchronous : 1; guint blocking_other_task : 1; guint name_is_static : 1; GError *error; union { gpointer pointer; gssize size; gboolean boolean; } result; GDestroyNotify result_destroy; }; #define G_TASK_IS_THREADED(task) ((task)->task_func != NULL) struct _GTaskClass { GObjectClass parent_class; }; typedef enum { PROP_COMPLETED = 1, } GTaskProperty; static void g_task_async_result_iface_init (GAsyncResultIface *iface); static void g_task_thread_pool_init (void); G_DEFINE_TYPE_WITH_CODE (GTask, g_task, G_TYPE_OBJECT, G_IMPLEMENT_INTERFACE (G_TYPE_ASYNC_RESULT, g_task_async_result_iface_init); g_task_thread_pool_init ();) static GThreadPool *task_pool; static GMutex task_pool_mutex; static GPrivate task_private = G_PRIVATE_INIT (NULL); static GSource *task_pool_manager; static guint64 task_wait_time; static gint tasks_running; static guint task_pool_max_counter; static guint tasks_running_counter; /* When the task pool fills up and blocks, and the program keeps * queueing more tasks, we will slowly add more threads to the pool * (in case the existing tasks are trying to queue subtasks of their * own) until tasks start completing again. These "overflow" threads * will only run one task apiece, and then exit, so the pool will * eventually get back down to its base size. * * The base and multiplier below gives us 10 extra threads after about * a second of blocking, 30 after 5 seconds, 100 after a minute, and * 200 after 20 minutes. * * We specify maximum pool size of 330 to increase the waiting time up * to around 30 minutes. */ #define G_TASK_POOL_SIZE 10 #define G_TASK_WAIT_TIME_BASE 100000 #define G_TASK_WAIT_TIME_MULTIPLIER 1.03 #define G_TASK_WAIT_TIME_MAX_POOL_SIZE 330 static void g_task_init (GTask *task) { task->check_cancellable = TRUE; } #ifdef G_ENABLE_DEBUG G_LOCK_DEFINE_STATIC (task_list); static GPtrArray *task_list = NULL; void g_task_print_alive_tasks (void) { GString *message_str = g_string_new (""); G_LOCK (task_list); if (task_list != NULL) { g_string_append_printf (message_str, "%u GTasks still alive:", task_list->len); for (guint i = 0; i < task_list->len; i++) { GTask *task = g_ptr_array_index (task_list, i); const gchar *name = g_task_get_name (task); g_string_append_printf (message_str, "\n • GTask %p, %s, ref count: %u, ever_returned: %u, completed: %u", task, (name != NULL) ? name : "(no name set)", ((GObject *) task)->ref_count, task->ever_returned, task->completed); } } else { g_string_append (message_str, "No GTasks still alive"); } G_UNLOCK (task_list); g_message ("%s", message_str->str); g_string_free (message_str, TRUE); } static void g_task_constructed (GObject *object) { GTask *task = G_TASK (object); G_OBJECT_CLASS (g_task_parent_class)->constructed (object); /* Track pending tasks for debugging purposes */ G_LOCK (task_list); if (G_UNLIKELY (task_list == NULL)) task_list = g_ptr_array_new (); g_ptr_array_add (task_list, task); G_UNLOCK (task_list); } #endif /* G_ENABLE_DEBUG */ static void g_task_finalize (GObject *object) { GTask *task = G_TASK (object); /* Warn if a #GTask is finalised without g_task_return() ever having been * called on it. * * Tasks without a callback or which are run in g_task_run_in_thread{,_sync}() * only trigger a debug message as that’s sometimes used as a pattern for * running work in a worker thread without caring about the result. */ if (!task->ever_returned) { gchar *owned_task_name = NULL; const gchar *task_name = g_task_get_name (task); if (task_name == NULL) task_name = owned_task_name = g_strdup_printf ("%p", task); if (task->callback != NULL && !G_TASK_IS_THREADED (task)) g_critical ("GTask %s (source object: %p, source tag: %p) finalized without " "ever returning (using g_task_return_*()). This potentially " "indicates a bug in the program.", task_name, task->source_object, task->source_tag); else g_debug ("GTask %s (source object: %p, source tag: %p) finalized without " "ever returning (using g_task_return_*()). This potentially " "indicates a bug in the program.", task_name, task->source_object, task->source_tag); g_free (owned_task_name); } g_clear_object (&task->source_object); g_clear_object (&task->cancellable); if (!task->name_is_static) g_free (task->name); if (task->context) g_main_context_unref (task->context); if (task->task_data_destroy) task->task_data_destroy (task->task_data); if (task->result_destroy && task->result.pointer) task->result_destroy (task->result.pointer); if (task->error) g_error_free (task->error); if (G_TASK_IS_THREADED (task)) { g_mutex_clear (&task->lock); g_cond_clear (&task->cond); } /* Track pending tasks for debugging purposes */ #ifdef G_ENABLE_DEBUG G_LOCK (task_list); g_assert (task_list != NULL); g_ptr_array_remove_fast (task_list, task); if (G_UNLIKELY (task_list->len == 0)) g_clear_pointer (&task_list, g_ptr_array_unref); G_UNLOCK (task_list); #endif /* G_ENABLE_DEBUG */ G_OBJECT_CLASS (g_task_parent_class)->finalize (object); } /** * g_task_new: * @source_object: (nullable) (type GObject): the #GObject that owns * this task, or %NULL. * @cancellable: (nullable): optional #GCancellable object, %NULL to ignore. * @callback: (scope async): a #GAsyncReadyCallback. * @callback_data: user data passed to @callback. * * Creates a #GTask acting on @source_object, which will eventually be * used to invoke @callback in the current * [thread-default main context][g-main-context-push-thread-default]. * * Call this in the "start" method of your asynchronous method, and * pass the #GTask around throughout the asynchronous operation. You * can use g_task_set_task_data() to attach task-specific data to the * object, which you can retrieve later via g_task_get_task_data(). * * By default, if @cancellable is cancelled, then the return value of * the task will always be %G_IO_ERROR_CANCELLED, even if the task had * already completed before the cancellation. This allows for * simplified handling in cases where cancellation may imply that * other objects that the task depends on have been destroyed. If you * do not want this behavior, you can use * g_task_set_check_cancellable() to change it. * * Returns: a #GTask. * * Since: 2.36 */ GTask * g_task_new (gpointer source_object, GCancellable *cancellable, GAsyncReadyCallback callback, gpointer callback_data) { GTask *task; GSource *source; task = g_object_new (G_TYPE_TASK, NULL); task->source_object = source_object ? g_object_ref (source_object) : NULL; task->cancellable = cancellable ? g_object_ref (cancellable) : NULL; task->callback = callback; task->callback_data = callback_data; task->context = g_main_context_ref_thread_default (); source = g_main_current_source (); if (source) task->creation_time = g_source_get_time (source); TRACE (GIO_TASK_NEW (task, source_object, cancellable, callback, callback_data)); return task; } /** * g_task_report_error: * @source_object: (nullable) (type GObject): the #GObject that owns * this task, or %NULL. * @callback: (scope async) (closure callback_data): a #GAsyncReadyCallback. * @callback_data: user data passed to @callback. * @source_tag: an opaque pointer indicating the source of this task * @error: (transfer full): error to report * * Creates a #GTask and then immediately calls g_task_return_error() * on it. Use this in the wrapper function of an asynchronous method * when you want to avoid even calling the virtual method. You can * then use g_async_result_is_tagged() in the finish method wrapper to * check if the result there is tagged as having been created by the * wrapper method, and deal with it appropriately if so. * * See also g_task_report_new_error(). * * Since: 2.36 */ void g_task_report_error (gpointer source_object, GAsyncReadyCallback callback, gpointer callback_data, gpointer source_tag, GError *error) { GTask *task; task = g_task_new (source_object, NULL, callback, callback_data); g_task_set_source_tag (task, source_tag); g_task_set_static_name (task, G_STRFUNC); g_task_return_error (task, error); g_object_unref (task); } /** * g_task_report_new_error: * @source_object: (nullable) (type GObject): the #GObject that owns * this task, or %NULL. * @callback: (scope async) (closure callback_data): a #GAsyncReadyCallback. * @callback_data: user data passed to @callback. * @source_tag: an opaque pointer indicating the source of this task * @domain: a #GQuark. * @code: an error code. * @format: a string with format characters. * @...: a list of values to insert into @format. * * Creates a #GTask and then immediately calls * g_task_return_new_error() on it. Use this in the wrapper function * of an asynchronous method when you want to avoid even calling the * virtual method. You can then use g_async_result_is_tagged() in the * finish method wrapper to check if the result there is tagged as * having been created by the wrapper method, and deal with it * appropriately if so. * * See also g_task_report_error(). * * Since: 2.36 */ void g_task_report_new_error (gpointer source_object, GAsyncReadyCallback callback, gpointer callback_data, gpointer source_tag, GQuark domain, gint code, const char *format, ...) { GError *error; va_list ap; va_start (ap, format); error = g_error_new_valist (domain, code, format, ap); va_end (ap); g_task_report_error (source_object, callback, callback_data, source_tag, error); } /** * g_task_set_task_data: * @task: the #GTask * @task_data: (nullable): task-specific data * @task_data_destroy: (nullable): #GDestroyNotify for @task_data * * Sets @task's task data (freeing the existing task data, if any). * * Since: 2.36 */ void g_task_set_task_data (GTask *task, gpointer task_data, GDestroyNotify task_data_destroy) { g_return_if_fail (G_IS_TASK (task)); if (task->task_data_destroy) task->task_data_destroy (task->task_data); task->task_data = task_data; task->task_data_destroy = task_data_destroy; TRACE (GIO_TASK_SET_TASK_DATA (task, task_data, task_data_destroy)); } /** * g_task_set_priority: * @task: the #GTask * @priority: the [priority](iface.AsyncResult.html#io-priority) of the request * * Sets @task's priority. If you do not call this, it will default to * %G_PRIORITY_DEFAULT. * * This will affect the priority of #GSources created with * g_task_attach_source() and the scheduling of tasks run in threads, * and can also be explicitly retrieved later via * g_task_get_priority(). * * Since: 2.36 */ void g_task_set_priority (GTask *task, gint priority) { g_return_if_fail (G_IS_TASK (task)); task->priority = priority; TRACE (GIO_TASK_SET_PRIORITY (task, priority)); } /** * g_task_set_check_cancellable: * @task: the #GTask * @check_cancellable: whether #GTask will check the state of * its #GCancellable for you. * * Sets or clears @task's check-cancellable flag. If this is %TRUE * (the default), then g_task_propagate_pointer(), etc, and * g_task_had_error() will check the task's #GCancellable first, and * if it has been cancelled, then they will consider the task to have * returned an "Operation was cancelled" error * (%G_IO_ERROR_CANCELLED), regardless of any other error or return * value the task may have had. * * If @check_cancellable is %FALSE, then the #GTask will not check the * cancellable itself, and it is up to @task's owner to do this (eg, * via g_task_return_error_if_cancelled()). * * If you are using g_task_set_return_on_cancel() as well, then * you must leave check-cancellable set %TRUE. * * Since: 2.36 */ void g_task_set_check_cancellable (GTask *task, gboolean check_cancellable) { g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (check_cancellable || !task->return_on_cancel); task->check_cancellable = check_cancellable; } static void g_task_thread_complete (GTask *task); /** * g_task_set_return_on_cancel: * @task: the #GTask * @return_on_cancel: whether the task returns automatically when * it is cancelled. * * Sets or clears @task's return-on-cancel flag. This is only * meaningful for tasks run via g_task_run_in_thread() or * g_task_run_in_thread_sync(). * * If @return_on_cancel is %TRUE, then cancelling @task's * #GCancellable will immediately cause it to return, as though the * task's #GTaskThreadFunc had called * g_task_return_error_if_cancelled() and then returned. * * This allows you to create a cancellable wrapper around an * uninterruptible function. The #GTaskThreadFunc just needs to be * careful that it does not modify any externally-visible state after * it has been cancelled. To do that, the thread should call * g_task_set_return_on_cancel() again to (atomically) set * return-on-cancel %FALSE before making externally-visible changes; * if the task gets cancelled before the return-on-cancel flag could * be changed, g_task_set_return_on_cancel() will indicate this by * returning %FALSE. * * You can disable and re-enable this flag multiple times if you wish. * If the task's #GCancellable is cancelled while return-on-cancel is * %FALSE, then calling g_task_set_return_on_cancel() to set it %TRUE * again will cause the task to be cancelled at that point. * * If the task's #GCancellable is already cancelled before you call * g_task_run_in_thread()/g_task_run_in_thread_sync(), then the * #GTaskThreadFunc will still be run (for consistency), but the task * will also be completed right away. * * Returns: %TRUE if @task's return-on-cancel flag was changed to * match @return_on_cancel. %FALSE if @task has already been * cancelled. * * Since: 2.36 */ gboolean g_task_set_return_on_cancel (GTask *task, gboolean return_on_cancel) { g_return_val_if_fail (G_IS_TASK (task), FALSE); g_return_val_if_fail (task->check_cancellable || !return_on_cancel, FALSE); if (!G_TASK_IS_THREADED (task)) { task->return_on_cancel = return_on_cancel; return TRUE; } g_mutex_lock (&task->lock); if (task->thread_cancelled) { if (return_on_cancel && !task->return_on_cancel) { g_mutex_unlock (&task->lock); g_task_thread_complete (task); } else g_mutex_unlock (&task->lock); return FALSE; } task->return_on_cancel = return_on_cancel; g_mutex_unlock (&task->lock); return TRUE; } /** * g_task_set_source_tag: * @task: the #GTask * @source_tag: an opaque pointer indicating the source of this task * * Sets @task's source tag. * * You can use this to tag a task return * value with a particular pointer (usually a pointer to the function * doing the tagging) and then later check it using * g_task_get_source_tag() (or g_async_result_is_tagged()) in the * task's "finish" function, to figure out if the response came from a * particular place. * * A macro wrapper around this function will automatically set the * task’s name to the string form of @source_tag if it’s not already * set, for convenience. * * Since: 2.36 */ void (g_task_set_source_tag) (GTask *task, gpointer source_tag) { g_return_if_fail (G_IS_TASK (task)); task->source_tag = source_tag; TRACE (GIO_TASK_SET_SOURCE_TAG (task, source_tag)); } /** * g_task_set_name: * @task: a #GTask * @name: (nullable): a human readable name for the task, or %NULL to unset it * * Sets @task’s name, used in debugging and profiling. The name defaults to * %NULL. * * The task name should describe in a human readable way what the task does. * For example, ‘Open file’ or ‘Connect to network host’. It is used to set the * name of the #GSource used for idle completion of the task. * * This function may only be called before the @task is first used in a thread * other than the one it was constructed in. It is called automatically by * g_task_set_source_tag() if not called already. * * Since: 2.60 */ void (g_task_set_name) (GTask *task, const char *name) { char *new_name; g_return_if_fail (G_IS_TASK (task)); new_name = g_strdup (name); if (!task->name_is_static) g_free (task->name); task->name = g_steal_pointer (&new_name); task->name_is_static = FALSE; } /** * g_task_set_static_name: * @task: a #GTask * @name: (nullable): a human readable name for the task. Must be a string literal * * Sets @task’s name, used in debugging and profiling. * * This is a variant of g_task_set_name() that avoids copying @name. * * Since: 2.76 */ void g_task_set_static_name (GTask *task, const char *name) { g_return_if_fail (G_IS_TASK (task)); if (!task->name_is_static) g_free (task->name); task->name = (char *) name; task->name_is_static = TRUE; } /** * g_task_get_source_object: * @task: a #GTask * * Gets the source object from @task. Like * g_async_result_get_source_object(), but does not ref the object. * * Returns: (transfer none) (nullable) (type GObject): @task's source object, or %NULL * * Since: 2.36 */ gpointer g_task_get_source_object (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->source_object; } static GObject * g_task_ref_source_object (GAsyncResult *res) { GTask *task = G_TASK (res); if (task->source_object) return g_object_ref (task->source_object); else return NULL; } /** * g_task_get_task_data: * @task: a #GTask * * Gets @task's `task_data`. * * Returns: (transfer none): @task's `task_data`. * * Since: 2.36 */ gpointer g_task_get_task_data (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->task_data; } /** * g_task_get_priority: * @task: a #GTask * * Gets @task's priority * * Returns: @task's priority * * Since: 2.36 */ gint g_task_get_priority (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), G_PRIORITY_DEFAULT); return task->priority; } /** * g_task_get_context: * @task: a #GTask * * Gets the #GMainContext that @task will return its result in (that * is, the context that was the * [thread-default main context][g-main-context-push-thread-default] * at the point when @task was created). * * This will always return a non-%NULL value, even if the task's * context is the default #GMainContext. * * Returns: (transfer none): @task's #GMainContext * * Since: 2.36 */ GMainContext * g_task_get_context (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->context; } /** * g_task_get_cancellable: * @task: a #GTask * * Gets @task's #GCancellable * * Returns: (nullable) (transfer none): @task's #GCancellable * * Since: 2.36 */ GCancellable * g_task_get_cancellable (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->cancellable; } /** * g_task_get_check_cancellable: * @task: the #GTask * * Gets @task's check-cancellable flag. See * g_task_set_check_cancellable() for more details. * * Since: 2.36 */ gboolean g_task_get_check_cancellable (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), FALSE); /* Convert from a bit field to a boolean. */ return task->check_cancellable ? TRUE : FALSE; } /** * g_task_get_return_on_cancel: * @task: the #GTask * * Gets @task's return-on-cancel flag. See * g_task_set_return_on_cancel() for more details. * * Since: 2.36 */ gboolean g_task_get_return_on_cancel (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), FALSE); /* Convert from a bit field to a boolean. */ return task->return_on_cancel ? TRUE : FALSE; } /** * g_task_get_source_tag: * @task: a #GTask * * Gets @task's source tag. See g_task_set_source_tag(). * * Returns: (transfer none): @task's source tag * * Since: 2.36 */ gpointer g_task_get_source_tag (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->source_tag; } /** * g_task_get_name: * @task: a #GTask * * Gets @task’s name. See g_task_set_name(). * * Returns: (nullable) (transfer none): @task’s name, or %NULL * Since: 2.60 */ const gchar * g_task_get_name (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), NULL); return task->name; } static void g_task_return_now (GTask *task) { TRACE (GIO_TASK_BEFORE_RETURN (task, task->source_object, task->callback, task->callback_data)); g_main_context_push_thread_default (task->context); if (task->callback != NULL) { task->callback (task->source_object, G_ASYNC_RESULT (task), task->callback_data); } task->completed = TRUE; g_object_notify (G_OBJECT (task), "completed"); g_main_context_pop_thread_default (task->context); } static gboolean complete_in_idle_cb (gpointer task) { g_task_return_now (task); g_object_unref (task); return FALSE; } typedef enum { G_TASK_RETURN_SUCCESS, G_TASK_RETURN_ERROR, G_TASK_RETURN_FROM_THREAD } GTaskReturnType; static void g_task_return (GTask *task, GTaskReturnType type) { GSource *source; if (type != G_TASK_RETURN_FROM_THREAD) task->ever_returned = TRUE; if (type == G_TASK_RETURN_SUCCESS) task->result_set = TRUE; if (task->synchronous) return; /* Normally we want to invoke the task's callback when its return * value is set. But if the task is running in a thread, then we * want to wait until after the task_func returns, to simplify * locking/refcounting/etc. */ if (G_TASK_IS_THREADED (task) && type != G_TASK_RETURN_FROM_THREAD) return; g_object_ref (task); /* See if we can complete the task immediately. First, we have to be * running inside the task's thread/GMainContext. */ source = g_main_current_source (); if (source && g_source_get_context (source) == task->context) { /* Second, we can only complete immediately if this is not the * same iteration of the main loop that the task was created in. */ if (g_source_get_time (source) > task->creation_time) { /* Finally, if the task has been cancelled, we shouldn't * return synchronously from inside the * GCancellable::cancelled handler. It's easier to run * another iteration of the main loop than tracking how the * cancellation was handled. */ if (!g_cancellable_is_cancelled (task->cancellable)) { g_task_return_now (task); g_object_unref (task); return; } } } /* Otherwise, complete in the next iteration */ source = g_idle_source_new (); /* Note: in case the task name is NULL we set it as a const string instead * of going through the concat path which is more expensive and may show in the * profiler if g_task_return is called very often */ if (task->name == NULL) g_source_set_static_name (source, "[gio] (unnamed) complete_in_idle_cb"); else { gchar *source_name; source_name = g_strconcat ("[gio] ", task->name, " complete_in_idle_cb", NULL); g_source_set_name (source, source_name); g_free (source_name); } g_task_attach_source (task, source, complete_in_idle_cb); g_source_unref (source); } /** * GTaskThreadFunc: * @task: the #GTask * @source_object: (type GObject): @task's source object * @task_data: @task's task data * @cancellable: @task's #GCancellable, or %NULL * * The prototype for a task function to be run in a thread via * g_task_run_in_thread() or g_task_run_in_thread_sync(). * * If the return-on-cancel flag is set on @task, and @cancellable gets * cancelled, then the #GTask will be completed immediately (as though * g_task_return_error_if_cancelled() had been called), without * waiting for the task function to complete. However, the task * function will continue running in its thread in the background. The * function therefore needs to be careful about how it uses * externally-visible state in this case. See * g_task_set_return_on_cancel() for more details. * * Other than in that case, @task will be completed when the * #GTaskThreadFunc returns, not when it calls a * `g_task_return_` function. * * Since: 2.36 */ static void task_thread_cancelled (GCancellable *cancellable, gpointer user_data); static void g_task_thread_complete (GTask *task) { g_mutex_lock (&task->lock); if (task->thread_complete) { /* The task belatedly completed after having been cancelled * (or was cancelled in the midst of being completed). */ g_mutex_unlock (&task->lock); return; } TRACE (GIO_TASK_AFTER_RUN_IN_THREAD (task, task->thread_cancelled)); task->thread_complete = TRUE; g_mutex_unlock (&task->lock); if (task->cancellable) g_signal_handlers_disconnect_by_func (task->cancellable, task_thread_cancelled, task); if (task->synchronous) g_cond_signal (&task->cond); else g_task_return (task, G_TASK_RETURN_FROM_THREAD); } static gboolean task_pool_manager_timeout (gpointer user_data) { g_mutex_lock (&task_pool_mutex); g_thread_pool_set_max_threads (task_pool, tasks_running + 1, NULL); g_trace_set_int64_counter (task_pool_max_counter, tasks_running + 1); g_source_set_ready_time (task_pool_manager, -1); g_mutex_unlock (&task_pool_mutex); return TRUE; } static void g_task_thread_setup (void) { g_private_set (&task_private, GUINT_TO_POINTER (TRUE)); g_mutex_lock (&task_pool_mutex); tasks_running++; g_trace_set_int64_counter (tasks_running_counter, tasks_running); if (tasks_running == G_TASK_POOL_SIZE) task_wait_time = G_TASK_WAIT_TIME_BASE; else if (tasks_running > G_TASK_POOL_SIZE && tasks_running < G_TASK_WAIT_TIME_MAX_POOL_SIZE) task_wait_time *= G_TASK_WAIT_TIME_MULTIPLIER; if (tasks_running >= G_TASK_POOL_SIZE) g_source_set_ready_time (task_pool_manager, g_get_monotonic_time () + task_wait_time); g_mutex_unlock (&task_pool_mutex); } static void g_task_thread_cleanup (void) { gint tasks_pending; g_mutex_lock (&task_pool_mutex); tasks_pending = g_thread_pool_unprocessed (task_pool); if (tasks_running > G_TASK_POOL_SIZE) { g_thread_pool_set_max_threads (task_pool, tasks_running - 1, NULL); g_trace_set_int64_counter (task_pool_max_counter, tasks_running - 1); } else if (tasks_running + tasks_pending < G_TASK_POOL_SIZE) g_source_set_ready_time (task_pool_manager, -1); if (tasks_running > G_TASK_POOL_SIZE && tasks_running < G_TASK_WAIT_TIME_MAX_POOL_SIZE) task_wait_time /= G_TASK_WAIT_TIME_MULTIPLIER; tasks_running--; g_trace_set_int64_counter (tasks_running_counter, tasks_running); g_mutex_unlock (&task_pool_mutex); g_private_set (&task_private, GUINT_TO_POINTER (FALSE)); } static void g_task_thread_pool_thread (gpointer thread_data, gpointer pool_data) { GTask *task = thread_data; g_task_thread_setup (); task->task_func (task, task->source_object, task->task_data, task->cancellable); g_task_thread_complete (task); g_object_unref (task); g_task_thread_cleanup (); } static void task_thread_cancelled (GCancellable *cancellable, gpointer user_data) { GTask *task = user_data; /* Move this task to the front of the queue - no need for * a complete resorting of the queue. */ g_thread_pool_move_to_front (task_pool, task); g_mutex_lock (&task->lock); task->thread_cancelled = TRUE; if (!task->return_on_cancel) { g_mutex_unlock (&task->lock); return; } /* We don't actually set task->error; g_task_return_error() doesn't * use a lock, and g_task_propagate_error() will call * g_cancellable_set_error_if_cancelled() anyway. */ g_mutex_unlock (&task->lock); g_task_thread_complete (task); } static void task_thread_cancelled_disconnect_notify (gpointer task, GClosure *closure) { g_object_unref (task); } static void g_task_start_task_thread (GTask *task, GTaskThreadFunc task_func) { g_mutex_init (&task->lock); g_cond_init (&task->cond); g_mutex_lock (&task->lock); TRACE (GIO_TASK_BEFORE_RUN_IN_THREAD (task, task_func)); task->task_func = task_func; if (task->cancellable) { if (task->return_on_cancel && g_cancellable_set_error_if_cancelled (task->cancellable, &task->error)) { task->thread_cancelled = task->thread_complete = TRUE; TRACE (GIO_TASK_AFTER_RUN_IN_THREAD (task, task->thread_cancelled)); g_thread_pool_push (task_pool, g_object_ref (task), NULL); return; } /* This introduces a reference count loop between the GTask and * GCancellable, but is necessary to avoid a race on finalising the GTask * between task_thread_cancelled() (in one thread) and * g_task_thread_complete() (in another). * * Accordingly, the signal handler *must* be removed once the task has * completed. */ g_signal_connect_data (task->cancellable, "cancelled", G_CALLBACK (task_thread_cancelled), g_object_ref (task), task_thread_cancelled_disconnect_notify, G_CONNECT_DEFAULT); } if (g_private_get (&task_private)) task->blocking_other_task = TRUE; g_thread_pool_push (task_pool, g_object_ref (task), NULL); } /** * g_task_run_in_thread: * @task: a #GTask * @task_func: (scope async): a #GTaskThreadFunc * * Runs @task_func in another thread. When @task_func returns, @task's * #GAsyncReadyCallback will be invoked in @task's #GMainContext. * * This takes a ref on @task until the task completes. * * See #GTaskThreadFunc for more details about how @task_func is handled. * * Although GLib currently rate-limits the tasks queued via * g_task_run_in_thread(), you should not assume that it will always * do this. If you have a very large number of tasks to run (several tens of * tasks), but don't want them to all run at once, you should only queue a * limited number of them (around ten) at a time. * * Be aware that if your task depends on other tasks to complete, use of this * function could lead to a livelock if the other tasks also use this function * and enough of them (around 10) execute in a dependency chain, as that will * exhaust the thread pool. If this situation is possible, consider using a * separate worker thread or thread pool explicitly, rather than using * g_task_run_in_thread(). * * Since: 2.36 */ void g_task_run_in_thread (GTask *task, GTaskThreadFunc task_func) { g_return_if_fail (G_IS_TASK (task)); g_object_ref (task); g_task_start_task_thread (task, task_func); /* The task may already be cancelled, or g_thread_pool_push() may * have failed. */ if (task->thread_complete) { g_mutex_unlock (&task->lock); g_task_return (task, G_TASK_RETURN_FROM_THREAD); } else g_mutex_unlock (&task->lock); g_object_unref (task); } /** * g_task_run_in_thread_sync: * @task: a #GTask * @task_func: (scope async): a #GTaskThreadFunc * * Runs @task_func in another thread, and waits for it to return or be * cancelled. You can use g_task_propagate_pointer(), etc, afterward * to get the result of @task_func. * * See #GTaskThreadFunc for more details about how @task_func is handled. * * Normally this is used with tasks created with a %NULL * `callback`, but note that even if the task does * have a callback, it will not be invoked when @task_func returns. * #GTask:completed will be set to %TRUE just before this function returns. * * Although GLib currently rate-limits the tasks queued via * g_task_run_in_thread_sync(), you should not assume that it will * always do this. If you have a very large number of tasks to run, * but don't want them to all run at once, you should only queue a * limited number of them at a time. * * Since: 2.36 */ void g_task_run_in_thread_sync (GTask *task, GTaskThreadFunc task_func) { g_return_if_fail (G_IS_TASK (task)); g_object_ref (task); task->synchronous = TRUE; g_task_start_task_thread (task, task_func); while (!task->thread_complete) g_cond_wait (&task->cond, &task->lock); g_mutex_unlock (&task->lock); TRACE (GIO_TASK_BEFORE_RETURN (task, task->source_object, NULL /* callback */, NULL /* callback data */)); /* Notify of completion in this thread. */ task->completed = TRUE; g_object_notify (G_OBJECT (task), "completed"); g_object_unref (task); } /** * g_task_attach_source: * @task: a #GTask * @source: the source to attach * @callback: the callback to invoke when @source triggers * * A utility function for dealing with async operations where you need * to wait for a #GSource to trigger. Attaches @source to @task's * #GMainContext with @task's [priority](iface.AsyncResult.html#io-priority), * and sets @source's callback to @callback, with @task as the callback's * `user_data`. * * It will set the @source’s name to the task’s name (as set with * g_task_set_name()), if one has been set on the task and the source doesn’t * yet have a name. * * This takes a reference on @task until @source is destroyed. * * Since: 2.36 */ void g_task_attach_source (GTask *task, GSource *source, GSourceFunc callback) { g_return_if_fail (G_IS_TASK (task)); g_source_set_callback (source, callback, g_object_ref (task), g_object_unref); g_source_set_priority (source, task->priority); if (task->name != NULL && g_source_get_name (source) == NULL) g_source_set_name (source, task->name); g_source_attach (source, task->context); } static gboolean g_task_propagate_error (GTask *task, GError **error) { gboolean error_set; if (task->check_cancellable && g_cancellable_set_error_if_cancelled (task->cancellable, error)) error_set = TRUE; else if (task->error) { g_propagate_error (error, task->error); task->error = NULL; task->had_error = TRUE; error_set = TRUE; } else error_set = FALSE; TRACE (GIO_TASK_PROPAGATE (task, error_set)); return error_set; } /** * g_task_return_pointer: * @task: a #GTask * @result: (nullable) (transfer full): the pointer result of a task * function * @result_destroy: (nullable): a #GDestroyNotify function. * * Sets @task's result to @result and completes the task. If @result * is not %NULL, then @result_destroy will be used to free @result if * the caller does not take ownership of it with * g_task_propagate_pointer(). * * "Completes the task" means that for an ordinary asynchronous task * it will either invoke the task's callback, or else queue that * callback to be invoked in the proper #GMainContext, or in the next * iteration of the current #GMainContext. For a task run via * g_task_run_in_thread() or g_task_run_in_thread_sync(), calling this * method will save @result to be returned to the caller later, but * the task will not actually be completed until the #GTaskThreadFunc * exits. * * Note that since the task may be completed before returning from * g_task_return_pointer(), you cannot assume that @result is still * valid after calling this, unless you are still holding another * reference on it. * * Since: 2.36 */ void g_task_return_pointer (GTask *task, gpointer result, GDestroyNotify result_destroy) { g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); task->result.pointer = result; task->result_destroy = result_destroy; g_task_return (task, G_TASK_RETURN_SUCCESS); } /** * g_task_propagate_pointer: * @task: a #GTask * @error: return location for a #GError * * Gets the result of @task as a pointer, and transfers ownership * of that value to the caller. * * If the task resulted in an error, or was cancelled, then this will * instead return %NULL and set @error. * * Since this method transfers ownership of the return value (or * error) to the caller, you may only call it once. * * Returns: (transfer full): the task result, or %NULL on error * * Since: 2.36 */ gpointer g_task_propagate_pointer (GTask *task, GError **error) { g_return_val_if_fail (G_IS_TASK (task), NULL); if (g_task_propagate_error (task, error)) return NULL; g_return_val_if_fail (task->result_set, NULL); task->result_destroy = NULL; task->result_set = FALSE; return task->result.pointer; } /** * g_task_return_int: * @task: a #GTask. * @result: the integer (#gssize) result of a task function. * * Sets @task's result to @result and completes the task (see * g_task_return_pointer() for more discussion of exactly what this * means). * * Since: 2.36 */ void g_task_return_int (GTask *task, gssize result) { g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); task->result.size = result; g_task_return (task, G_TASK_RETURN_SUCCESS); } /** * g_task_propagate_int: * @task: a #GTask. * @error: return location for a #GError * * Gets the result of @task as an integer (#gssize). * * If the task resulted in an error, or was cancelled, then this will * instead return -1 and set @error. * * Since this method transfers ownership of the return value (or * error) to the caller, you may only call it once. * * Returns: the task result, or -1 on error * * Since: 2.36 */ gssize g_task_propagate_int (GTask *task, GError **error) { g_return_val_if_fail (G_IS_TASK (task), -1); if (g_task_propagate_error (task, error)) return -1; g_return_val_if_fail (task->result_set, -1); task->result_set = FALSE; return task->result.size; } /** * g_task_return_boolean: * @task: a #GTask. * @result: the #gboolean result of a task function. * * Sets @task's result to @result and completes the task (see * g_task_return_pointer() for more discussion of exactly what this * means). * * Since: 2.36 */ void g_task_return_boolean (GTask *task, gboolean result) { g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); task->result.boolean = result; g_task_return (task, G_TASK_RETURN_SUCCESS); } /** * g_task_propagate_boolean: * @task: a #GTask. * @error: return location for a #GError * * Gets the result of @task as a #gboolean. * * If the task resulted in an error, or was cancelled, then this will * instead return %FALSE and set @error. * * Since this method transfers ownership of the return value (or * error) to the caller, you may only call it once. * * Returns: the task result, or %FALSE on error * * Since: 2.36 */ gboolean g_task_propagate_boolean (GTask *task, GError **error) { g_return_val_if_fail (G_IS_TASK (task), FALSE); if (g_task_propagate_error (task, error)) return FALSE; g_return_val_if_fail (task->result_set, FALSE); task->result_set = FALSE; return task->result.boolean; } /** * g_task_return_error: * @task: a #GTask. * @error: (transfer full): the #GError result of a task function. * * Sets @task's result to @error (which @task assumes ownership of) * and completes the task (see g_task_return_pointer() for more * discussion of exactly what this means). * * Note that since the task takes ownership of @error, and since the * task may be completed before returning from g_task_return_error(), * you cannot assume that @error is still valid after calling this. * Call g_error_copy() on the error if you need to keep a local copy * as well. * * See also g_task_return_new_error(). * * Since: 2.36 */ void g_task_return_error (GTask *task, GError *error) { g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); g_return_if_fail (error != NULL); task->error = error; g_task_return (task, G_TASK_RETURN_ERROR); } /** * g_task_return_prefixed_error: * @task: a #GTask. * @error: (transfer full): the #GError result of a task function. * @format: a string with format characters. * @...: a list of values to insert into @format. * * Sets @task's result to @error (which @task assumes ownership of), with * the message prefixed according to @format, and completes the task * (see g_task_return_pointer() for more discussion of exactly what this * means). * * Note that since the task takes ownership of @error, and since the * task may be completed before returning from g_task_return_prefixed_error(), * you cannot assume that @error is still valid after calling this. * Call g_error_copy() on the error if you need to keep a local copy * as well. * * See also g_task_return_error(), g_prefix_error(). * * Since: 2.80 */ void g_task_return_prefixed_error (GTask *task, GError *error, const char *format, ...) { char *prefix; va_list ap; g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); g_return_if_fail (error != NULL); task->error = error; va_start (ap, format); prefix = g_strdup_vprintf (format, ap); va_end (ap); g_prefix_error_literal (&task->error, prefix); g_free (prefix); g_task_return (task, G_TASK_RETURN_ERROR); } /** * g_task_return_new_error: * @task: a #GTask. * @domain: a #GQuark. * @code: an error code. * @format: a string with format characters. * @...: a list of values to insert into @format. * * Sets @task's result to a new #GError created from @domain, @code, * @format, and the remaining arguments, and completes the task (see * g_task_return_pointer() for more discussion of exactly what this * means). * * See also g_task_return_error(). * * Since: 2.36 */ void g_task_return_new_error (GTask *task, GQuark domain, gint code, const char *format, ...) { GError *error; va_list args; va_start (args, format); error = g_error_new_valist (domain, code, format, args); va_end (args); g_task_return_error (task, error); } /** * g_task_return_error_if_cancelled: * @task: a #GTask * * Checks if @task's #GCancellable has been cancelled, and if so, sets * @task's error accordingly and completes the task (see * g_task_return_pointer() for more discussion of exactly what this * means). * * Returns: %TRUE if @task has been cancelled, %FALSE if not * * Since: 2.36 */ gboolean g_task_return_error_if_cancelled (GTask *task) { GError *error = NULL; g_return_val_if_fail (G_IS_TASK (task), FALSE); g_return_val_if_fail (!task->ever_returned, FALSE); if (g_cancellable_set_error_if_cancelled (task->cancellable, &error)) { /* We explicitly set task->error so this works even when * check-cancellable is not set. */ g_clear_error (&task->error); task->error = error; g_task_return (task, G_TASK_RETURN_ERROR); return TRUE; } else return FALSE; } /** * g_task_had_error: * @task: a #GTask. * * Tests if @task resulted in an error. * * Returns: %TRUE if the task resulted in an error, %FALSE otherwise. * * Since: 2.36 */ gboolean g_task_had_error (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), FALSE); if (task->error != NULL || task->had_error) return TRUE; if (task->check_cancellable && g_cancellable_is_cancelled (task->cancellable)) return TRUE; return FALSE; } static void value_free (gpointer value) { g_value_unset (value); g_free (value); } /** * g_task_return_value: * @task: a #GTask * @result: (nullable) (transfer none): the #GValue result of * a task function * * Sets @task's result to @result (by copying it) and completes the task. * * If @result is %NULL then a #GValue of type %G_TYPE_POINTER * with a value of %NULL will be used for the result. * * This is a very generic low-level method intended primarily for use * by language bindings; for C code, g_task_return_pointer() and the * like will normally be much easier to use. * * Since: 2.64 */ void g_task_return_value (GTask *task, GValue *result) { GValue *value; g_return_if_fail (G_IS_TASK (task)); g_return_if_fail (!task->ever_returned); value = g_new0 (GValue, 1); if (result == NULL) { g_value_init (value, G_TYPE_POINTER); g_value_set_pointer (value, NULL); } else { g_value_init (value, G_VALUE_TYPE (result)); g_value_copy (result, value); } g_task_return_pointer (task, value, value_free); } /** * g_task_propagate_value: * @task: a #GTask * @value: (out caller-allocates): return location for the #GValue * @error: return location for a #GError * * Gets the result of @task as a #GValue, and transfers ownership of * that value to the caller. As with g_task_return_value(), this is * a generic low-level method; g_task_propagate_pointer() and the like * will usually be more useful for C code. * * If the task resulted in an error, or was cancelled, then this will * instead set @error and return %FALSE. * * Since this method transfers ownership of the return value (or * error) to the caller, you may only call it once. * * Returns: %TRUE if @task succeeded, %FALSE on error. * * Since: 2.64 */ gboolean g_task_propagate_value (GTask *task, GValue *value, GError **error) { g_return_val_if_fail (G_IS_TASK (task), FALSE); g_return_val_if_fail (value != NULL, FALSE); g_return_val_if_fail (error == NULL || *error == NULL, FALSE); if (g_task_propagate_error (task, error)) return FALSE; g_return_val_if_fail (task->result_set, FALSE); g_return_val_if_fail (task->result_destroy == value_free, FALSE); memcpy (value, task->result.pointer, sizeof (GValue)); g_free (task->result.pointer); task->result_destroy = NULL; task->result_set = FALSE; return TRUE; } /** * g_task_get_completed: * @task: a #GTask. * * Gets the value of #GTask:completed. This changes from %FALSE to %TRUE after * the task’s callback is invoked, and will return %FALSE if called from inside * the callback. * * Returns: %TRUE if the task has completed, %FALSE otherwise. * * Since: 2.44 */ gboolean g_task_get_completed (GTask *task) { g_return_val_if_fail (G_IS_TASK (task), FALSE); /* Convert from a bit field to a boolean. */ return task->completed ? TRUE : FALSE; } /** * g_task_is_valid: * @result: (type Gio.AsyncResult): A #GAsyncResult * @source_object: (nullable) (type GObject): the source object * expected to be associated with the task * * Checks that @result is a #GTask, and that @source_object is its * source object (or that @source_object is %NULL and @result has no * source object). This can be used in g_return_if_fail() checks. * * Returns: %TRUE if @result and @source_object are valid, %FALSE * if not * * Since: 2.36 */ gboolean g_task_is_valid (gpointer result, gpointer source_object) { if (!G_IS_TASK (result)) return FALSE; return G_TASK (result)->source_object == source_object; } static gint g_task_compare_priority (gconstpointer a, gconstpointer b, gpointer user_data) { const GTask *ta = a; const GTask *tb = b; gboolean a_cancelled, b_cancelled; /* Tasks that are causing other tasks to block have higher * priority. */ if (ta->blocking_other_task && !tb->blocking_other_task) return -1; else if (tb->blocking_other_task && !ta->blocking_other_task) return 1; /* Let already-cancelled tasks finish right away */ a_cancelled = (ta->check_cancellable && g_cancellable_is_cancelled (ta->cancellable)); b_cancelled = (tb->check_cancellable && g_cancellable_is_cancelled (tb->cancellable)); if (a_cancelled && !b_cancelled) return -1; else if (b_cancelled && !a_cancelled) return 1; /* Lower priority == run sooner == negative return value */ return ta->priority - tb->priority; } static gboolean trivial_source_dispatch (GSource *source, GSourceFunc callback, gpointer user_data) { return callback (user_data); } GSourceFuncs trivial_source_funcs = { NULL, /* prepare */ NULL, /* check */ trivial_source_dispatch, NULL, /* finalize */ NULL, /* closure */ NULL /* marshal */ }; static void g_task_thread_pool_init (void) { task_pool = g_thread_pool_new (g_task_thread_pool_thread, NULL, G_TASK_POOL_SIZE, FALSE, NULL); g_assert (task_pool != NULL); g_thread_pool_set_sort_function (task_pool, g_task_compare_priority, NULL); task_pool_manager = g_source_new (&trivial_source_funcs, sizeof (GSource)); g_source_set_static_name (task_pool_manager, "GTask thread pool manager"); g_source_set_callback (task_pool_manager, task_pool_manager_timeout, NULL, NULL); g_source_set_ready_time (task_pool_manager, -1); g_source_attach (task_pool_manager, GLIB_PRIVATE_CALL (g_get_worker_context ())); g_source_unref (task_pool_manager); } static void g_task_get_property (GObject *object, guint prop_id, GValue *value, GParamSpec *pspec) { GTask *task = G_TASK (object); switch ((GTaskProperty) prop_id) { case PROP_COMPLETED: g_value_set_boolean (value, g_task_get_completed (task)); break; } } static void g_task_class_init (GTaskClass *klass) { GObjectClass *gobject_class = G_OBJECT_CLASS (klass); #ifdef G_ENABLE_DEBUG gobject_class->constructed = g_task_constructed; #endif gobject_class->get_property = g_task_get_property; gobject_class->finalize = g_task_finalize; /** * GTask:completed: * * Whether the task has completed, meaning its callback (if set) has been * invoked. This can only happen after g_task_return_pointer(), * g_task_return_error() or one of the other return functions have been called * on the task. * * This property is guaranteed to change from %FALSE to %TRUE exactly once. * * The #GObject::notify signal for this change is emitted in the same main * context as the task’s callback, immediately after that callback is invoked. * * Since: 2.44 */ g_object_class_install_property (gobject_class, PROP_COMPLETED, g_param_spec_boolean ("completed", NULL, NULL, FALSE, G_PARAM_READABLE | G_PARAM_STATIC_STRINGS)); if (G_UNLIKELY (task_pool_max_counter == 0)) { /* We use two counters to track characteristics of the GTask thread pool. * task pool max size - the value of g_thread_pool_set_max_threads() * tasks running - the number of running threads */ task_pool_max_counter = g_trace_define_int64_counter ("GIO", "task pool max size", "Maximum number of threads allowed in the GTask thread pool; see g_thread_pool_set_max_threads()"); tasks_running_counter = g_trace_define_int64_counter ("GIO", "tasks running", "Number of currently running tasks in the GTask thread pool"); } } static gpointer g_task_get_user_data (GAsyncResult *res) { return G_TASK (res)->callback_data; } static gboolean g_task_is_tagged (GAsyncResult *res, gpointer source_tag) { return G_TASK (res)->source_tag == source_tag; } static void g_task_async_result_iface_init (GAsyncResultIface *iface) { iface->get_user_data = g_task_get_user_data; iface->get_source_object = g_task_ref_source_object; iface->is_tagged = g_task_is_tagged; }