[utest]add mutex_pi_tc

* add mutex_pi
* fix assertion error when thread wakeup while waiting mutex
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zms123456 2024-09-07 05:44:02 +08:00 committed by GitHub
parent 0c16568387
commit 9631f04abe
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3 changed files with 362 additions and 3 deletions

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@ -33,7 +33,7 @@ if GetDepend(['UTEST_SIGNAL_TC']):
src += ['signal_tc.c']
if GetDepend(['UTEST_MUTEX_TC']):
src += ['mutex_tc.c']
src += ['mutex_tc.c', 'mutex_pi_tc.c']
if GetDepend(['UTEST_MAILBOX_TC']):
src += ['mailbox_tc.c']

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@ -0,0 +1,353 @@
/*
* Copyright (c) 2006-2019, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
*/
#define __RT_IPC_SOURCE__
#include <rtthread.h>
#include <stdlib.h>
#include "utest.h"
#ifdef ARCH_CPU_64BIT
#define THREAD_STACKSIZE 8192
#else
#define THREAD_STACKSIZE 4096
#endif
#define MUTEX_NUM 3
#define THREAD_NUM 5
static struct rt_mutex _mutex[MUTEX_NUM];
static volatile int _sync_flag;
static void test_thread_entry(void *para)
{
while (!_sync_flag)
{
rt_thread_delay(1);
}
rt_ubase_t thread_id = (rt_ubase_t)para;
rt_err_t ret;
rt_thread_mdelay(50 + thread_id * 100);
ret = rt_mutex_take(&_mutex[thread_id % MUTEX_NUM], RT_WAITING_FOREVER);
uassert_true(ret == RT_EOK);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == RT_SCHED_PRIV(rt_thread_self()).init_priority);
if (thread_id == 1)
{
rt_thread_mdelay(100); // wait for main thread re-get _mutex[1]
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
}
ret = rt_mutex_release(&_mutex[thread_id % MUTEX_NUM]);
uassert_true(ret == RT_EOK);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == RT_SCHED_PRIV(rt_thread_self()).init_priority);
_sync_flag ++;
}
static void test_main_thread_entry(void *para)
{
while (!_sync_flag)
{
rt_thread_delay(1);
}
rt_err_t ret;
ret = rt_mutex_take(&_mutex[0], RT_WAITING_FOREVER);
uassert_true(ret == RT_EOK);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 12);
rt_thread_mdelay(100); // wait for t0 take mutex0
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 12);
ret = rt_mutex_take(&_mutex[1], RT_WAITING_FOREVER);
uassert_true(ret == RT_EOK);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 12);
rt_thread_mdelay(100); // wait for t1 take mutex1
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 9);
ret = rt_mutex_take(&_mutex[2], RT_WAITING_FOREVER);
uassert_true(ret == RT_EOK);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 9);
rt_thread_mdelay(100); // wait for t2 take mutex2
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
rt_thread_mdelay(100); // wait for t3 take mutex0
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 7);
rt_thread_mdelay(100); // wait for t4 take mutex1
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 7);
rt_thread_mdelay(100);
rt_mutex_release(&_mutex[0]); // give _mutex0 to t3
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
rt_thread_mdelay(100);
rt_mutex_release(&_mutex[1]); // give _mutex1 to t1
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
rt_thread_mdelay(50);
rt_mutex_take(&_mutex[1], RT_WAITING_FOREVER); // re-get _mutex1, which is hold by t1
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
rt_mutex_release(&_mutex[1]); // give _mutex1 to thread t1
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 8);
rt_thread_mdelay(100);
rt_mutex_release(&_mutex[2]);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 12);
_sync_flag ++;
}
static void test_mutex_pi(void)
{
rt_thread_t t_main;
rt_thread_t t[THREAD_NUM];
rt_uint8_t prio[THREAD_NUM] = {13, 9, 8, 7, 11}; // prio of threads
for (int i = 0; i < MUTEX_NUM; i++)
{
rt_mutex_init(&_mutex[i], "test1", 0);
}
_sync_flag = 0;
t_main = rt_thread_create("t_main", test_main_thread_entry, RT_NULL, THREAD_STACKSIZE, 12, 10000);
uassert_true(t_main != RT_NULL);
rt_thread_startup(t_main);
for (rt_ubase_t i = 0; i < THREAD_NUM; i++)
{
t[i] = rt_thread_create("t", test_thread_entry, (void *)i, THREAD_STACKSIZE, prio[i], 10000);
uassert_true(t[i] != RT_NULL);
rt_thread_startup(t[i]);
}
_sync_flag = 1;
while (_sync_flag != THREAD_NUM + 1 + 1)
{
rt_thread_mdelay(100);
}
for (int i = 0; i < MUTEX_NUM; i++)
{
rt_mutex_detach(&_mutex[i]);
}
}
static struct rt_mutex _timeout_mutex;
static void test_main_timeout_entry(void *para)
{
rt_err_t ret;
ret = rt_mutex_take(&_timeout_mutex, RT_WAITING_FOREVER);
uassert_true(ret == -RT_EOK);
rt_thread_mdelay(100);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 10);
rt_thread_mdelay(100);
uassert_true(RT_SCHED_PRIV(rt_thread_self()).current_priority == 12);
rt_mutex_release(&_timeout_mutex);
_sync_flag ++;
}
static void test_timeout_entry(void *para)
{
rt_err_t ret;
rt_thread_mdelay(50);
ret = rt_mutex_take(&_timeout_mutex, rt_tick_from_millisecond(100));
uassert_true(ret == -RT_ETIMEOUT);
_sync_flag ++;
}
static void test_mutex_pi_timeout(void)
{
_sync_flag = 0;
rt_mutex_init(&_timeout_mutex, "_timeout_mutex", 0);
rt_thread_t t1 = rt_thread_create("t1", test_main_timeout_entry, RT_NULL, THREAD_STACKSIZE, 12, 10000);
uassert_true(t1 != RT_NULL);
rt_thread_startup(t1);
rt_thread_t t2 = rt_thread_create("t2", test_timeout_entry, (void *)t1, THREAD_STACKSIZE, 10, 10000);
uassert_true(t2 != RT_NULL);
rt_thread_startup(t2);
while (_sync_flag != 2)
{
rt_thread_mdelay(100);
}
rt_mutex_detach(&_timeout_mutex);
}
#define TC_THREAD_NUM 4
#define TC_MUTEX_NUM TC_THREAD_NUM
static rt_thread_t t[TC_THREAD_NUM], t_hi_prio;
static struct rt_mutex m[TC_MUTEX_NUM];
static void test_recursive_mutex_depend_entry(void *para)
{
rt_ubase_t id = (rt_ubase_t)para;
rt_mutex_take(&m[id], RT_WAITING_FOREVER);
rt_thread_mdelay(50);
if (id != 0)
{
rt_mutex_take(&m[id - 1], RT_WAITING_FOREVER);
}
if (id == 0)
{
rt_thread_mdelay(250);
rt_mutex_release(&m[id]);
}
else
{
rt_mutex_release(&m[id - 1]);
rt_mutex_release(&m[id]);
}
_sync_flag ++;
}
static void test_recursive_mutex_depend_hi_pri_entry(void *para)
{
rt_thread_mdelay(100);
rt_err_t err = rt_mutex_take(&m[TC_MUTEX_NUM - 1], rt_tick_from_millisecond(100));
uassert_true(err == -RT_ETIMEOUT);
_sync_flag ++;
}
static void test_mutex_pi_recursive_prio_update(void)
{
_sync_flag = 0;
for (int i = 0; i < TC_MUTEX_NUM; i++)
{
rt_mutex_init(&m[i], "test", 0);
}
for (rt_ubase_t i = 0; i < TC_THREAD_NUM; i++)
{
t[i] = rt_thread_create("t", test_recursive_mutex_depend_entry, (void *)i, THREAD_STACKSIZE, 10, 10000);
rt_thread_startup(t[i]);
}
t_hi_prio = rt_thread_create("t", test_recursive_mutex_depend_hi_pri_entry, (void *)RT_NULL, THREAD_STACKSIZE, 3, 10000);
rt_thread_startup(t_hi_prio);
rt_thread_mdelay(150);
for (int i = 0; i < TC_THREAD_NUM; i++)
{
uassert_true(RT_SCHED_PRIV(t[i]).current_priority == 3);
}
rt_thread_mdelay(100);
for (int i = 0; i < TC_THREAD_NUM; i++)
{
uassert_true(RT_SCHED_PRIV(t[i]).current_priority == 10);
}
while (_sync_flag != TC_THREAD_NUM + 1)
{
rt_thread_mdelay(100);
}
for (int i = 0; i < TC_MUTEX_NUM; i++)
{
rt_mutex_detach(&m[i]);
}
_sync_flag ++;
}
static void test_mutex_waiter_to_wakeup_entry(void *para)
{
rt_thread_mdelay(100);
rt_err_t err = rt_mutex_take(&m[TC_MUTEX_NUM - 1], RT_WAITING_FOREVER);
uassert_true(err == -RT_EINTR);
_sync_flag ++;
}
static void wakeup_func(void *para)
{
rt_thread_resume(t_hi_prio);
}
static void test_mutex_pi_wakeup_mutex_waiter(void)
{
struct rt_timer wakeup_timer;
_sync_flag = 0;
for (int i = 0; i < TC_MUTEX_NUM; i++)
{
rt_mutex_init(&m[i], "test", 0);
}
for (rt_ubase_t i = 0; i < TC_THREAD_NUM; i++)
{
t[i] = rt_thread_create("t", test_recursive_mutex_depend_entry, (void *)i, THREAD_STACKSIZE, 10, 10000);
rt_thread_startup(t[i]);
}
t_hi_prio = rt_thread_create("t", test_mutex_waiter_to_wakeup_entry, (void *)RT_NULL, THREAD_STACKSIZE, 3, 10000);
rt_thread_startup(t_hi_prio);
rt_timer_init(&wakeup_timer, "wakeup_timer", wakeup_func, RT_NULL, rt_tick_from_millisecond(200), RT_TIMER_FLAG_ONE_SHOT);
rt_timer_start(&wakeup_timer);
rt_thread_mdelay(150);
for (int i = 0; i < TC_THREAD_NUM; i++)
{
uassert_true(RT_SCHED_PRIV(t[i]).current_priority == 3);
}
rt_thread_mdelay(100);
for (int i = 0; i < TC_THREAD_NUM; i++)
{
uassert_true(RT_SCHED_PRIV(t[i]).current_priority == 10);
}
while (_sync_flag != TC_THREAD_NUM + 1)
{
rt_thread_mdelay(100);
}
for (int i = 0; i < TC_MUTEX_NUM; i++)
{
rt_mutex_detach(&m[i]);
}
rt_timer_detach(&wakeup_timer);
}
static rt_err_t utest_tc_init(void)
{
return RT_EOK;
}
static rt_err_t utest_tc_cleanup(void)
{
return RT_EOK;
}
static void testcase(void)
{
UTEST_UNIT_RUN(test_mutex_pi);
UTEST_UNIT_RUN(test_mutex_pi_recursive_prio_update);
UTEST_UNIT_RUN(test_mutex_pi_timeout);
UTEST_UNIT_RUN(test_mutex_pi_wakeup_mutex_waiter);
}
UTEST_TC_EXPORT(testcase, "testcases.kernel.mutex_pi_tc", utest_tc_init, utest_tc_cleanup, 1000);
/********************* end of file ************************/

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@ -1450,13 +1450,13 @@ static rt_err_t _rt_mutex_take(rt_mutex_t mutex, rt_int32_t timeout, int suspend
rt_spin_lock(&(mutex->spinlock));
if (thread->error == RT_EOK)
if (mutex->owner == thread)
{
/**
* get mutex successfully
* Note: assert to avoid an unexpected resume
*/
RT_ASSERT(mutex->owner == thread);
RT_ASSERT(thread->error == RT_EOK);
}
else
{
@ -1468,6 +1468,12 @@ static rt_err_t _rt_mutex_take(rt_mutex_t mutex, rt_int32_t timeout, int suspend
/* get value first before calling to other APIs */
ret = thread->error;
/* unexpected resume */
if (ret == RT_EOK)
{
ret = -RT_EINTR;
}
rt_sched_lock(&slvl);
/**