/* * Asterisk -- An open source telephony toolkit. * * Copyright (C) 2012-2013, Digium, Inc. * * Mark Michelson * * See http://www.asterisk.org for more information about * the Asterisk project. Please do not directly contact * any of the maintainers of this project for assistance; * the project provides a web site, mailing lists and IRC * channels for your use. * * This program is free software, distributed under the terms of * the GNU General Public License Version 2. See the LICENSE file * at the top of the source tree. */ /*! * \file * \brief taskprocessor unit tests * * \author Mark Michelson * */ /*** MODULEINFO TEST_FRAMEWORK core ***/ #include "asterisk.h" #include "asterisk/test.h" #include "asterisk/taskprocessor.h" #include "asterisk/module.h" #include "asterisk/astobj2.h" /*! * \brief userdata associated with baseline taskprocessor test */ struct task_data { /* Condition used to signal to queuing thread that task was executed */ ast_cond_t cond; /* Lock protecting the condition */ ast_mutex_t lock; /*! Boolean indicating that the task was run */ int task_complete; }; static void task_data_dtor(void *obj) { struct task_data *task_data = obj; ast_mutex_destroy(&task_data->lock); ast_cond_destroy(&task_data->cond); } /*! \brief Create a task_data object */ static struct task_data *task_data_create(void) { struct task_data *task_data = ao2_alloc(sizeof(*task_data), task_data_dtor); if (!task_data) { return NULL; } ast_cond_init(&task_data->cond, NULL); ast_mutex_init(&task_data->lock); task_data->task_complete = 0; return task_data; } /*! * \brief Queued task for baseline test. * * The task simply sets a boolean to indicate the * task has been run and then signals a condition * saying it's complete */ static int task(void *data) { struct task_data *task_data = data; SCOPED_MUTEX(lock, &task_data->lock); task_data->task_complete = 1; ast_cond_signal(&task_data->cond); return 0; } /*! * \brief Wait for a task to execute. */ static int task_wait(struct task_data *task_data) { struct timeval start = ast_tvnow(); struct timespec end; SCOPED_MUTEX(lock, &task_data->lock); end.tv_sec = start.tv_sec + 30; end.tv_nsec = start.tv_usec * 1000; while (!task_data->task_complete) { int res; res = ast_cond_timedwait(&task_data->cond, &task_data->lock, &end); if (res == ETIMEDOUT) { return -1; } } return 0; } /*! * \brief Baseline test for default taskprocessor * * This test ensures that when a task is added to a taskprocessor that * has been allocated with a default listener that the task gets executed * as expected */ AST_TEST_DEFINE(default_taskprocessor) { RAII_VAR(struct ast_taskprocessor *, tps, NULL, ast_taskprocessor_unreference); RAII_VAR(struct task_data *, task_data, NULL, ao2_cleanup); int res; switch (cmd) { case TEST_INIT: info->name = "default_taskprocessor"; info->category = "/main/taskprocessor/"; info->summary = "Test of default taskproccesor"; info->description = "Ensures that a queued task gets executed."; return AST_TEST_NOT_RUN; case TEST_EXECUTE: break; } tps = ast_taskprocessor_get("test", TPS_REF_DEFAULT); if (!tps) { ast_test_status_update(test, "Unable to create test taskprocessor\n"); return AST_TEST_FAIL; } task_data = task_data_create(); if (!task_data) { ast_test_status_update(test, "Unable to create task_data\n"); return AST_TEST_FAIL; } if (ast_taskprocessor_push(tps, task, task_data)) { ast_test_status_update(test, "Failed to queue task\n"); return AST_TEST_FAIL; } res = task_wait(task_data); if (res != 0) { ast_test_status_update(test, "Queued task did not execute!\n"); return AST_TEST_FAIL; } return AST_TEST_PASS; } #define NUM_TASKS 20000 /*! * \brief Relevant data associated with taskprocessor load test */ static struct load_task_data { /*! Condition used to indicate a task has completed executing */ ast_cond_t cond; /*! Lock used to protect the condition */ ast_mutex_t lock; /*! Counter of the number of completed tasks */ int tasks_completed; /*! Storage for task-specific data */ int task_rand[NUM_TASKS]; } load_task_results; /*! * \brief a queued task to be used in the taskprocessor load test * * The task increments the number of tasks executed and puts the passed-in * data into the next slot in the array of random data. */ static int load_task(void *data) { int *randdata = data; SCOPED_MUTEX(lock, &load_task_results.lock); load_task_results.task_rand[load_task_results.tasks_completed++] = *randdata; ast_cond_signal(&load_task_results.cond); return 0; } /*! * \brief Load test for taskprocessor with default listener * * This test queues a large number of tasks, each with random data associated. * The test ensures that all of the tasks are run and that the tasks are executed * in the same order that they were queued */ AST_TEST_DEFINE(default_taskprocessor_load) { struct ast_taskprocessor *tps; struct timeval start; struct timespec ts; enum ast_test_result_state res = AST_TEST_PASS; int timedwait_res; int i; int rand_data[NUM_TASKS]; switch (cmd) { case TEST_INIT: info->name = "default_taskprocessor_load"; info->category = "/main/taskprocessor/"; info->summary = "Load test of default taskproccesor"; info->description = "Ensure that a large number of queued tasks are executed in the proper order."; return AST_TEST_NOT_RUN; case TEST_EXECUTE: break; } tps = ast_taskprocessor_get("test", TPS_REF_DEFAULT); if (!tps) { ast_test_status_update(test, "Unable to create test taskprocessor\n"); return AST_TEST_FAIL; } start = ast_tvnow(); ts.tv_sec = start.tv_sec + 60; ts.tv_nsec = start.tv_usec * 1000; ast_cond_init(&load_task_results.cond, NULL); ast_mutex_init(&load_task_results.lock); load_task_results.tasks_completed = 0; for (i = 0; i < NUM_TASKS; ++i) { rand_data[i] = ast_random(); if (ast_taskprocessor_push(tps, load_task, &rand_data[i])) { ast_test_status_update(test, "Failed to queue task\n"); res = AST_TEST_FAIL; goto test_end; } } ast_mutex_lock(&load_task_results.lock); while (load_task_results.tasks_completed < NUM_TASKS) { timedwait_res = ast_cond_timedwait(&load_task_results.cond, &load_task_results.lock, &ts); if (timedwait_res == ETIMEDOUT) { break; } } ast_mutex_unlock(&load_task_results.lock); if (load_task_results.tasks_completed != NUM_TASKS) { ast_test_status_update(test, "Unexpected number of tasks executed. Expected %d but got %d\n", NUM_TASKS, load_task_results.tasks_completed); res = AST_TEST_FAIL; goto test_end; } for (i = 0; i < NUM_TASKS; ++i) { if (rand_data[i] != load_task_results.task_rand[i]) { ast_test_status_update(test, "Queued tasks did not execute in order\n"); res = AST_TEST_FAIL; goto test_end; } } test_end: tps = ast_taskprocessor_unreference(tps); ast_mutex_destroy(&load_task_results.lock); ast_cond_destroy(&load_task_results.cond); return res; } /*! * \brief Private data for the test taskprocessor listener */ struct test_listener_pvt { /* Counter of number of tasks pushed to the queue */ int num_pushed; /* Counter of number of times the queue was emptied */ int num_emptied; /* Counter of number of times that a pushed task occurred on an empty queue */ int num_was_empty; /* Boolean indicating whether the shutdown callback was called */ int shutdown; }; /*! * \brief test taskprocessor listener's alloc callback */ static void *test_listener_pvt_alloc(void) { struct test_listener_pvt *pvt; pvt = ast_calloc(1, sizeof(*pvt)); return pvt; } /*! * \brief test taskprocessor listener's start callback */ static int test_start(struct ast_taskprocessor_listener *listener) { return 0; } /*! * \brief test taskprocessor listener's task_pushed callback * * Adjusts private data's stats as indicated by the parameters. */ static void test_task_pushed(struct ast_taskprocessor_listener *listener, int was_empty) { struct test_listener_pvt *pvt = ast_taskprocessor_listener_get_user_data(listener); ++pvt->num_pushed; if (was_empty) { ++pvt->num_was_empty; } } /*! * \brief test taskprocessor listener's emptied callback. */ static void test_emptied(struct ast_taskprocessor_listener *listener) { struct test_listener_pvt *pvt = ast_taskprocessor_listener_get_user_data(listener); ++pvt->num_emptied; } /*! * \brief test taskprocessor listener's shutdown callback. */ static void test_shutdown(struct ast_taskprocessor_listener *listener) { struct test_listener_pvt *pvt = ast_taskprocessor_listener_get_user_data(listener); pvt->shutdown = 1; } static const struct ast_taskprocessor_listener_callbacks test_callbacks = { .start = test_start, .task_pushed = test_task_pushed, .emptied = test_emptied, .shutdown = test_shutdown, }; /*! * \brief Queued task for taskprocessor listener test. * * Does nothing. */ static int listener_test_task(void *ignore) { return 0; } /*! * \brief helper to ensure that statistics the listener is keeping are what we expect * * \param test The currently-running test * \param pvt The private data for the taskprocessor listener * \param num_pushed The expected current number of tasks pushed to the processor * \param num_emptied The expected current number of times the taskprocessor has become empty * \param num_was_empty The expected current number of times that tasks were pushed to an empty taskprocessor * \retval -1 Stats were not as expected * \retval 0 Stats were as expected */ static int check_stats(struct ast_test *test, const struct test_listener_pvt *pvt, int num_pushed, int num_emptied, int num_was_empty) { if (pvt->num_pushed != num_pushed) { ast_test_status_update(test, "Unexpected number of tasks pushed. Expected %d but got %d\n", num_pushed, pvt->num_pushed); return -1; } if (pvt->num_emptied != num_emptied) { ast_test_status_update(test, "Unexpected number of empties. Expected %d but got %d\n", num_emptied, pvt->num_emptied); return -1; } if (pvt->num_was_empty != num_was_empty) { ast_test_status_update(test, "Unexpected number of empties. Expected %d but got %d\n", num_was_empty, pvt->num_emptied); return -1; } return 0; } /*! * \brief Test for a taskprocessor with custom listener. * * This test pushes tasks to a taskprocessor with a custom listener, executes the taskss, * and destroys the taskprocessor. * * The test ensures that the listener's callbacks are called when expected and that the data * being passed in is accurate. */ AST_TEST_DEFINE(taskprocessor_listener) { struct ast_taskprocessor *tps = NULL; struct ast_taskprocessor_listener *listener = NULL; struct test_listener_pvt *pvt = NULL; enum ast_test_result_state res = AST_TEST_PASS; switch (cmd) { case TEST_INIT: info->name = "taskprocessor_listener"; info->category = "/main/taskprocessor/"; info->summary = "Test of taskproccesor listeners"; info->description = "Ensures that listener callbacks are called when expected."; return AST_TEST_NOT_RUN; case TEST_EXECUTE: break; } pvt = test_listener_pvt_alloc(); if (!pvt) { ast_test_status_update(test, "Unable to allocate test taskprocessor listener user data\n"); return AST_TEST_FAIL; } listener = ast_taskprocessor_listener_alloc(&test_callbacks, pvt); if (!listener) { ast_test_status_update(test, "Unable to allocate test taskprocessor listener\n"); res = AST_TEST_FAIL; goto test_exit; } tps = ast_taskprocessor_create_with_listener("test_listener", listener); if (!tps) { ast_test_status_update(test, "Unable to allocate test taskprocessor\n"); res = AST_TEST_FAIL; goto test_exit; } if (ast_taskprocessor_push(tps, listener_test_task, NULL)) { ast_test_status_update(test, "Failed to queue task\n"); res = AST_TEST_FAIL; goto test_exit; } if (check_stats(test, pvt, 1, 0, 1) < 0) { res = AST_TEST_FAIL; goto test_exit; } if (ast_taskprocessor_push(tps, listener_test_task, NULL)) { ast_test_status_update(test, "Failed to queue task\n"); res = AST_TEST_FAIL; goto test_exit; } if (check_stats(test, pvt, 2, 0, 1) < 0) { res = AST_TEST_FAIL; goto test_exit; } ast_taskprocessor_execute(tps); if (check_stats(test, pvt, 2, 0, 1) < 0) { res = AST_TEST_FAIL; goto test_exit; } ast_taskprocessor_execute(tps); if (check_stats(test, pvt, 2, 1, 1) < 0) { res = AST_TEST_FAIL; goto test_exit; } tps = ast_taskprocessor_unreference(tps); if (!pvt->shutdown) { res = AST_TEST_FAIL; goto test_exit; } test_exit: ao2_cleanup(listener); /* This is safe even if tps is NULL */ ast_taskprocessor_unreference(tps); ast_free(pvt); return res; } struct shutdown_data { ast_cond_t in; ast_cond_t out; ast_mutex_t lock; int task_complete; int task_started; int task_stop_waiting; }; static void shutdown_data_dtor(void *data) { struct shutdown_data *shutdown_data = data; ast_mutex_destroy(&shutdown_data->lock); ast_cond_destroy(&shutdown_data->in); ast_cond_destroy(&shutdown_data->out); } static struct shutdown_data *shutdown_data_create(int dont_wait) { RAII_VAR(struct shutdown_data *, shutdown_data, NULL, ao2_cleanup); shutdown_data = ao2_alloc(sizeof(*shutdown_data), shutdown_data_dtor); if (!shutdown_data) { return NULL; } ast_mutex_init(&shutdown_data->lock); ast_cond_init(&shutdown_data->in, NULL); ast_cond_init(&shutdown_data->out, NULL); shutdown_data->task_stop_waiting = dont_wait; ao2_ref(shutdown_data, +1); return shutdown_data; } static int shutdown_task_exec(void *data) { struct shutdown_data *shutdown_data = data; SCOPED_MUTEX(lock, &shutdown_data->lock); shutdown_data->task_started = 1; ast_cond_signal(&shutdown_data->out); while (!shutdown_data->task_stop_waiting) { ast_cond_wait(&shutdown_data->in, &shutdown_data->lock); } shutdown_data->task_complete = 1; ast_cond_signal(&shutdown_data->out); return 0; } static int shutdown_waitfor_completion(struct shutdown_data *shutdown_data) { struct timeval start = ast_tvnow(); struct timespec end = { .tv_sec = start.tv_sec + 5, .tv_nsec = start.tv_usec * 1000 }; SCOPED_MUTEX(lock, &shutdown_data->lock); while (!shutdown_data->task_complete) { if (ast_cond_timedwait(&shutdown_data->out, &shutdown_data->lock, &end) == ETIMEDOUT) { break; } } return shutdown_data->task_complete; } static int shutdown_has_completed(struct shutdown_data *shutdown_data) { SCOPED_MUTEX(lock, &shutdown_data->lock); return shutdown_data->task_complete; } static int shutdown_waitfor_start(struct shutdown_data *shutdown_data) { struct timeval start = ast_tvnow(); struct timespec end = { .tv_sec = start.tv_sec + 5, .tv_nsec = start.tv_usec * 1000 }; SCOPED_MUTEX(lock, &shutdown_data->lock); while (!shutdown_data->task_started) { if (ast_cond_timedwait(&shutdown_data->out, &shutdown_data->lock, &end) == ETIMEDOUT) { break; } } return shutdown_data->task_started; } static void shutdown_poke(struct shutdown_data *shutdown_data) { SCOPED_MUTEX(lock, &shutdown_data->lock); shutdown_data->task_stop_waiting = 1; ast_cond_signal(&shutdown_data->in); } static void *tps_shutdown_thread(void *data) { struct ast_taskprocessor *tps = data; ast_taskprocessor_unreference(tps); return NULL; } AST_TEST_DEFINE(taskprocessor_shutdown) { RAII_VAR(struct ast_taskprocessor *, tps, NULL, ast_taskprocessor_unreference); RAII_VAR(struct shutdown_data *, task1, NULL, ao2_cleanup); RAII_VAR(struct shutdown_data *, task2, NULL, ao2_cleanup); int push_res; int wait_res; int pthread_res; pthread_t shutdown_thread; switch (cmd) { case TEST_INIT: info->name = "taskprocessor_shutdown"; info->category = "/main/taskprocessor/"; info->summary = "Test of taskproccesor shutdown sequence"; info->description = "Ensures that all tasks run to completion after the taskprocessor has been unref'ed."; return AST_TEST_NOT_RUN; case TEST_EXECUTE: break; } tps = ast_taskprocessor_get("test_shutdown", TPS_REF_DEFAULT); task1 = shutdown_data_create(0); /* task1 waits to be poked */ task2 = shutdown_data_create(1); /* task2 waits for nothing */ if (!tps || !task1 || !task2) { ast_test_status_update(test, "Allocation error\n"); return AST_TEST_FAIL; } push_res = ast_taskprocessor_push(tps, shutdown_task_exec, task1); if (push_res != 0) { ast_test_status_update(test, "Could not push task1\n"); return AST_TEST_FAIL; } push_res = ast_taskprocessor_push(tps, shutdown_task_exec, task2); if (push_res != 0) { ast_test_status_update(test, "Could not push task2\n"); return AST_TEST_FAIL; } wait_res = shutdown_waitfor_start(task1); if (!wait_res) { ast_test_status_update(test, "Task1 didn't start\n"); return AST_TEST_FAIL; } pthread_res = ast_pthread_create(&shutdown_thread, NULL, tps_shutdown_thread, tps); if (pthread_res != 0) { ast_test_status_update(test, "Failed to create shutdown thread\n"); return AST_TEST_FAIL; } tps = NULL; /* Wakeup task1; it should complete */ shutdown_poke(task1); wait_res = shutdown_waitfor_completion(task1); if (!wait_res) { ast_test_status_update(test, "Task1 didn't complete\n"); return AST_TEST_FAIL; } /* Wait for shutdown to complete */ pthread_join(shutdown_thread, NULL); /* Should have also completed task2 */ wait_res = shutdown_has_completed(task2); if (!wait_res) { ast_test_status_update(test, "Task2 didn't finish\n"); return AST_TEST_FAIL; } return AST_TEST_PASS; } static int local_task_exe(struct ast_taskprocessor_local *local) { int *local_data = local->local_data; struct task_data *task_data = local->data; *local_data = 1; task(task_data); return 0; } AST_TEST_DEFINE(taskprocessor_push_local) { RAII_VAR(struct ast_taskprocessor *, tps, NULL, ast_taskprocessor_unreference); RAII_VAR(struct task_data *, task_data, NULL, ao2_cleanup); int local_data; int res; switch (cmd) { case TEST_INIT: info->name = __func__; info->category = "/main/taskprocessor/"; info->summary = "Test of pushing local data"; info->description = "Ensures that local data is passed along."; return AST_TEST_NOT_RUN; case TEST_EXECUTE: break; } tps = ast_taskprocessor_get("test", TPS_REF_DEFAULT); if (!tps) { ast_test_status_update(test, "Unable to create test taskprocessor\n"); return AST_TEST_FAIL; } task_data = task_data_create(); if (!task_data) { ast_test_status_update(test, "Unable to create task_data\n"); return AST_TEST_FAIL; } local_data = 0; ast_taskprocessor_set_local(tps, &local_data); if (ast_taskprocessor_push_local(tps, local_task_exe, task_data)) { ast_test_status_update(test, "Failed to queue task\n"); return AST_TEST_FAIL; } res = task_wait(task_data); if (res != 0) { ast_test_status_update(test, "Queued task did not execute!\n"); return AST_TEST_FAIL; } if (local_data != 1) { ast_test_status_update(test, "Queued task did not set local_data!\n"); return AST_TEST_FAIL; } return AST_TEST_PASS; } static int unload_module(void) { ast_test_unregister(default_taskprocessor); ast_test_unregister(default_taskprocessor_load); ast_test_unregister(taskprocessor_listener); ast_test_unregister(taskprocessor_shutdown); ast_test_unregister(taskprocessor_push_local); return 0; } static int load_module(void) { ast_test_register(default_taskprocessor); ast_test_register(default_taskprocessor_load); ast_test_register(taskprocessor_listener); ast_test_register(taskprocessor_shutdown); ast_test_register(taskprocessor_push_local); return AST_MODULE_LOAD_SUCCESS; } AST_MODULE_INFO_STANDARD(ASTERISK_GPL_KEY, "taskprocessor test module");