asterisk/tests/test_res_pjsip_scheduler.c

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2023-05-25 18:45:57 +00:00
/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 2016, Fairview 5 Engineering, LLC
*
* George Joseph <george.joseph@fairview5.com>
*
* 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 res_pjsip scheduler tests
*
* \author George Joseph <george.joseph@fairview5.com>
*
*/
/*** MODULEINFO
<depend>TEST_FRAMEWORK</depend>
<depend>pjproject</depend>
<depend>res_pjsip</depend>
<support_level>core</support_level>
***/
#include "asterisk.h"
#include <pjsip.h>
#include "asterisk/test.h"
#include "asterisk/module.h"
#include "asterisk/taskprocessor.h"
#include "asterisk/res_pjsip.h"
#include "asterisk/utils.h"
#define CATEGORY "/res/res_pjsip/scheduler/"
struct test_data {
ast_mutex_t lock;
ast_cond_t cond;
pthread_t tid;
struct timeval test_start;
struct timeval task_start;
struct timeval task_end;
int is_servant;
int interval;
int sleep;
int done;
int no_clear_done;
struct ast_test *test;
};
#define S2U(x) (long int)(x * 1000 * 1000)
#define M2U(x) (long int)(x * 1000)
static int task_1(void *data)
{
struct test_data *test = data;
if (!test->no_clear_done) {
test->done = 0;
}
test->task_start = ast_tvnow();
test->tid = pthread_self();
test->is_servant = ast_sip_thread_is_servant();
usleep(M2U(test->sleep));
test->task_end = ast_tvnow();
ast_mutex_lock(&test->lock);
test->done++;
ast_mutex_unlock(&test->lock);
ast_cond_signal(&test->cond);
return test->interval;
}
static void data_cleanup(void *data)
{
struct test_data *test_data = data;
ast_mutex_destroy(&test_data->lock);
ast_cond_destroy(&test_data->cond);
}
#define waitfor(x) \
{ \
ast_mutex_lock(&(x)->lock); \
while (!(x)->done) { \
ast_cond_wait(&(x)->cond, &(x)->lock); \
} \
(x)->done = 0; \
ast_mutex_unlock(&(x)->lock); \
}
static int scheduler(struct ast_test *test, int serialized)
{
RAII_VAR(struct ast_taskprocessor *, tp1, NULL, ast_taskprocessor_unreference);
RAII_VAR(struct test_data *, test_data1, ao2_alloc(sizeof(*test_data1), data_cleanup), ao2_cleanup);
RAII_VAR(struct test_data *, test_data2, ao2_alloc(sizeof(*test_data2), data_cleanup), ao2_cleanup);
RAII_VAR(struct ast_sip_sched_task *, task1, NULL, ao2_cleanup);
RAII_VAR(struct ast_sip_sched_task *, task2, NULL, ao2_cleanup);
int duration;
int delay;
struct timeval task1_start;
ast_test_validate(test, test_data1 != NULL);
ast_test_validate(test, test_data2 != NULL);
test_data1->test = test;
test_data1->test_start = ast_tvnow();
test_data1->interval = 2000;
test_data1->sleep = 1000;
ast_mutex_init(&test_data1->lock);
ast_cond_init(&test_data1->cond, NULL);
test_data2->test = test;
test_data2->test_start = ast_tvnow();
test_data2->interval = 2000;
test_data2->sleep = 1000;
ast_mutex_init(&test_data2->lock);
ast_cond_init(&test_data2->cond, NULL);
if (serialized) {
ast_test_status_update(test, "This test will take about %3.1f seconds\n",
(test_data1->interval + test_data1->sleep + (MAX(test_data1->interval - test_data2->interval, 0)) + test_data2->sleep) / 1000.0);
tp1 = ast_sip_create_serializer("test-scheduler-serializer");
ast_test_validate(test, (tp1 != NULL));
} else {
ast_test_status_update(test, "This test will take about %3.1f seconds\n",
((MAX(test_data1->interval, test_data2->interval) + MAX(test_data1->sleep, test_data2->sleep)) / 1000.0));
}
task1 = ast_sip_schedule_task(tp1, test_data1->interval, task_1, NULL, test_data1, AST_SIP_SCHED_TASK_FIXED);
ast_test_validate(test, task1 != NULL);
task2 = ast_sip_schedule_task(tp1, test_data2->interval, task_1, NULL, test_data2, AST_SIP_SCHED_TASK_FIXED);
ast_test_validate(test, task2 != NULL);
waitfor(test_data1);
ast_sip_sched_task_cancel(task1);
ast_test_validate(test, test_data1->is_servant);
duration = ast_tvdiff_ms(test_data1->task_end, test_data1->test_start);
ast_test_validate(test, (duration > ((test_data1->interval + test_data1->sleep) * 0.9))
&& (duration < ((test_data1->interval + test_data1->sleep) * 1.1)));
ast_sip_sched_task_get_times(task1, NULL, &task1_start, NULL);
delay = ast_tvdiff_ms(task1_start, test_data1->test_start);
ast_test_validate(test, (delay > (test_data1->interval * 0.9)
&& (delay < (test_data1->interval * 1.1))));
waitfor(test_data2);
ast_sip_sched_task_cancel(task2);
ast_test_validate(test, test_data2->is_servant);
if (serialized) {
ast_test_validate(test, test_data1->tid == test_data2->tid);
ast_test_validate(test, ast_tvdiff_ms(test_data2->task_start, test_data1->task_end) >= 0);
} else {
ast_test_validate(test, test_data1->tid != test_data2->tid);
}
return AST_TEST_PASS;
}
AST_TEST_DEFINE(serialized_scheduler)
{
switch (cmd) {
case TEST_INIT:
info->name = __func__;
info->category = CATEGORY;
info->summary = "Test res_pjsip serialized scheduler";
info->description = "Test res_pjsip serialized scheduler";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
return scheduler(test, 1);
}
AST_TEST_DEFINE(unserialized_scheduler)
{
switch (cmd) {
case TEST_INIT:
info->name = __func__;
info->category = CATEGORY;
info->summary = "Test res_pjsip unserialized scheduler";
info->description = "Test res_pjsip unserialized scheduler";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
return scheduler(test, 0);
}
static int run_count;
static int destruct_count;
static int dummy_task(void *data)
{
int *sleep = data;
usleep(M2U(*sleep));
run_count++;
return 0;
}
static void test_destructor(void *data)
{
destruct_count++;
}
AST_TEST_DEFINE(scheduler_cleanup)
{
RAII_VAR(int *, sleep, NULL, ao2_cleanup);
RAII_VAR(struct ast_sip_sched_task *, task, NULL, ao2_cleanup);
int interval;
int when;
switch (cmd) {
case TEST_INIT:
info->name = __func__;
info->category = CATEGORY;
info->summary = "Test res_pjsip scheduler cleanup";
info->description = "Test res_pjsip scheduler cleanup";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
destruct_count = 0;
interval = 1000;
sleep = ao2_alloc(sizeof(*sleep), test_destructor);
ast_test_validate(test, sleep != NULL);
*sleep = 500;
ast_test_status_update(test, "This test will take about %3.1f seconds\n",
((interval * 1.1) + *sleep) / 1000.0);
task = ast_sip_schedule_task(NULL, interval, dummy_task, "dummy", sleep,
AST_SIP_SCHED_TASK_DATA_AO2 | AST_SIP_SCHED_TASK_DATA_FREE);
ast_test_validate(test, task != NULL);
usleep(M2U(interval * 0.5));
when = ast_sip_sched_task_get_next_run(task);
ast_test_validate(test, (when > (interval * 0.4) && when < (interval * 0.6)));
usleep(M2U(interval * 0.6));
ast_test_validate(test, ast_sip_sched_is_task_running(task));
usleep(M2U(*sleep));
ast_test_validate(test, (ast_sip_sched_is_task_running(task) == 0));
when = ast_sip_sched_task_get_next_run(task);
ast_test_validate(test, (when < 0), res, error);
ast_test_validate(test, (ao2_ref(task, 0) == 1));
ao2_ref(task, -1);
task = NULL;
ast_test_validate(test, (destruct_count == 1));
sleep = NULL;
return AST_TEST_PASS;
}
AST_TEST_DEFINE(scheduler_cancel)
{
RAII_VAR(int *, sleep, NULL, ao2_cleanup);
RAII_VAR(struct ast_sip_sched_task *, task, NULL, ao2_cleanup);
int interval;
int when;
switch (cmd) {
case TEST_INIT:
info->name = __func__;
info->category = CATEGORY;
info->summary = "Test res_pjsip scheduler cancel task";
info->description = "Test res_pjsip scheduler cancel task";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
destruct_count = 0;
interval = 1000;
sleep = ao2_alloc(sizeof(*sleep), test_destructor);
ast_test_validate(test, sleep != NULL);
*sleep = 500;
ast_test_status_update(test, "This test will take about %3.1f seconds\n",
(interval + *sleep) / 1000.0);
task = ast_sip_schedule_task(NULL, interval, dummy_task, "dummy", sleep, AST_SIP_SCHED_TASK_DATA_NO_CLEANUP);
ast_test_validate(test, task != NULL);
usleep(M2U(interval * 0.5));
when = ast_sip_sched_task_get_next_run_by_name("dummy");
ast_test_validate(test, (when > (interval * 0.4) && when < (interval * 0.6)));
ast_test_validate(test, !ast_sip_sched_is_task_running_by_name("dummy"));
ast_test_validate(test, ao2_ref(task, 0) == 2);
ast_sip_sched_task_cancel_by_name("dummy");
when = ast_sip_sched_task_get_next_run(task);
ast_test_validate(test, when < 0);
usleep(M2U(interval));
ast_test_validate(test, run_count == 0);
ast_test_validate(test, destruct_count == 0);
ast_test_validate(test, ao2_ref(task, 0) == 1);
return AST_TEST_PASS;
}
AST_TEST_DEFINE(scheduler_policy)
{
RAII_VAR(struct test_data *, test_data1, ao2_alloc(sizeof(*test_data1), data_cleanup), ao2_cleanup);
RAII_VAR(struct ast_sip_sched_task *, task, NULL, ao2_cleanup);
int when;
switch (cmd) {
case TEST_INIT:
info->name = __func__;
info->category = CATEGORY;
info->summary = "Test res_pjsip scheduler cancel task";
info->description = "Test res_pjsip scheduler cancel task";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
ast_test_validate(test, test_data1 != NULL);
destruct_count = 0;
run_count = 0;
test_data1->test = test;
test_data1->test_start = ast_tvnow();
test_data1->interval = 1000;
test_data1->sleep = 500;
test_data1->no_clear_done = 1;
ast_mutex_init(&test_data1->lock);
ast_cond_init(&test_data1->cond, NULL);
ast_test_status_update(test, "This test will take about %3.1f seconds\n",
((test_data1->interval * 4) + test_data1->sleep) / 1000.0);
task = ast_sip_schedule_task(NULL, test_data1->interval, task_1, "test_1", test_data1,
AST_SIP_SCHED_TASK_DATA_NO_CLEANUP | AST_SIP_SCHED_TASK_PERIODIC);
ast_test_validate(test, task != NULL);
waitfor(test_data1);
when = ast_tvdiff_ms(test_data1->task_start, test_data1->test_start);
ast_test_validate(test, when > test_data1->interval * 0.9 && when < test_data1->interval * 1.1);
waitfor(test_data1);
when = ast_tvdiff_ms(test_data1->task_start, test_data1->test_start);
ast_test_validate(test, when > test_data1->interval * 2 * 0.9 && when < test_data1->interval * 2 * 1.1);
waitfor(test_data1);
when = ast_tvdiff_ms(test_data1->task_start, test_data1->test_start);
ast_test_validate(test, when > test_data1->interval * 3 * 0.9 && when < test_data1->interval * 3 * 1.1);
ast_sip_sched_task_cancel(task);
/* Wait a full interval in case a 4th call to test_1 happened before the cancel */
usleep(M2U(test_data1->interval));
ast_mutex_lock(&test_data1->lock);
if (test_data1->done) {
int done = test_data1->done;
test_data1->done = 0;
ast_mutex_unlock(&test_data1->lock);
ast_test_validate(test, done == 1);
/* Wait two full intervals to be certain no further calls to test_1. */
usleep(M2U(test_data1->interval * 2));
ast_mutex_lock(&test_data1->lock);
if (test_data1->done != 0) {
ast_mutex_unlock(&test_data1->lock);
/* The cancelation failed so we need to prevent cleanup of
* test_data1 to prevent a crash from write-after-free. */
test_data1 = NULL;
ast_test_status_update(test, "Failed to cancel task");
return AST_TEST_FAIL;
}
}
ast_mutex_unlock(&test_data1->lock);
return AST_TEST_PASS;
}
static int load_module(void)
{
AST_TEST_REGISTER(serialized_scheduler);
AST_TEST_REGISTER(unserialized_scheduler);
AST_TEST_REGISTER(scheduler_cleanup);
AST_TEST_REGISTER(scheduler_cancel);
AST_TEST_REGISTER(scheduler_policy);
return AST_MODULE_LOAD_SUCCESS;
}
static int unload_module(void)
{
AST_TEST_UNREGISTER(scheduler_cancel);
AST_TEST_UNREGISTER(scheduler_cleanup);
AST_TEST_UNREGISTER(unserialized_scheduler);
AST_TEST_UNREGISTER(serialized_scheduler);
AST_TEST_UNREGISTER(scheduler_policy);
return 0;
}
AST_MODULE_INFO(ASTERISK_GPL_KEY, AST_MODFLAG_DEFAULT, "res_pjsip scheduler test module",
.support_level = AST_MODULE_SUPPORT_CORE,
.load = load_module,
.unload = unload_module,
.requires = "res_pjsip",
);