/* * Copyright (c) 2006-2021, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2018-01-26 Bernard Fix pthread_detach issue for a none-joinable * thread. * 2019-02-07 Bernard Add _pthread_destroy to release pthread resource. * 2022-05-10 xiangxistu Modify the recycle logic about resource of pthread. */ #include #include #include #include #include "pthread_internal.h" RT_DEFINE_HW_SPINLOCK(pth_lock); _pthread_data_t *pth_table[PTHREAD_NUM_MAX] = {NULL}; static int concurrency_level; _pthread_data_t *_pthread_get_data(pthread_t thread) { _pthread_data_t *ptd; if (thread >= PTHREAD_NUM_MAX) return NULL; rt_hw_spin_lock(&pth_lock); ptd = pth_table[thread]; rt_hw_spin_unlock(&pth_lock); if (ptd && ptd->magic == PTHREAD_MAGIC) return ptd; return NULL; } pthread_t _pthread_data_get_pth(_pthread_data_t *ptd) { int index; rt_hw_spin_lock(&pth_lock); for (index = 0; index < PTHREAD_NUM_MAX; index ++) { if (pth_table[index] == ptd) break; } rt_hw_spin_unlock(&pth_lock); return index; } pthread_t _pthread_data_create(void) { int index; _pthread_data_t *ptd = NULL; ptd = (_pthread_data_t*)rt_malloc(sizeof(_pthread_data_t)); if (!ptd) return PTHREAD_NUM_MAX; memset(ptd, 0x0, sizeof(_pthread_data_t)); ptd->canceled = 0; ptd->cancelstate = PTHREAD_CANCEL_DISABLE; ptd->canceltype = PTHREAD_CANCEL_DEFERRED; ptd->magic = PTHREAD_MAGIC; rt_hw_spin_lock(&pth_lock); for (index = 0; index < PTHREAD_NUM_MAX; index ++) { if (pth_table[index] == NULL) { pth_table[index] = ptd; break; } } rt_hw_spin_unlock(&pth_lock); /* full of pthreads, clean magic and release ptd */ if (index == PTHREAD_NUM_MAX) { ptd->magic = 0x0; rt_free(ptd); } return index; } void _pthread_data_destroy(_pthread_data_t *ptd) { extern _pthread_key_data_t _thread_keys[PTHREAD_KEY_MAX]; pthread_t pth; if (ptd) { /* if this thread create the local thread data, * destruct thread local key */ if (ptd->tls != RT_NULL) { void *data; rt_uint32_t index; for (index = 0; index < PTHREAD_KEY_MAX; index ++) { if (_thread_keys[index].is_used) { data = ptd->tls[index]; if (data && _thread_keys[index].destructor) _thread_keys[index].destructor(data); } } /* release tls area */ rt_free(ptd->tls); ptd->tls = RT_NULL; } pth = _pthread_data_get_pth(ptd); /* remove from pthread table */ rt_hw_spin_lock(&pth_lock); pth_table[pth] = NULL; rt_hw_spin_unlock(&pth_lock); /* delete joinable semaphore */ if (ptd->joinable_sem != RT_NULL) { rt_sem_delete(ptd->joinable_sem); ptd->joinable_sem = RT_NULL; } /* clean magic */ ptd->magic = 0x0; /* clear the "ptd->tid->pthread_data" */ ptd->tid->pthread_data = RT_NULL; /* free ptd */ rt_free(ptd); } } static void _pthread_cleanup(rt_thread_t tid) { /* clear cleanup function */ tid->cleanup = RT_NULL; /* restore tid stack */ rt_free(tid->stack_addr); /* restore tid control block */ rt_free(tid); } static void pthread_entry_stub(void *parameter) { void *value; _pthread_data_t *ptd; ptd = (_pthread_data_t *)parameter; /* execute pthread entry */ value = ptd->thread_entry(ptd->thread_parameter); /* According to "detachstate" to whether or not to recycle resource immediately */ if (ptd->attr.detachstate == PTHREAD_CREATE_JOINABLE) { /* set value */ ptd->return_value = value; rt_sem_release(ptd->joinable_sem); } else { /* release pthread resource */ _pthread_data_destroy(ptd); } } int pthread_create(pthread_t *pid, const pthread_attr_t *attr, void *(*start)(void *), void *parameter) { int ret = 0; void *stack; char name[RT_NAME_MAX]; static rt_uint16_t pthread_number = 0; pthread_t pth_id; _pthread_data_t *ptd; /* pid shall be provided */ RT_ASSERT(pid != RT_NULL); /* allocate posix thread data */ pth_id = _pthread_data_create(); if (pth_id == PTHREAD_NUM_MAX) { ret = ENOMEM; goto __exit; } /* get pthread data */ ptd = _pthread_get_data(pth_id); RT_ASSERT(ptd != RT_NULL); if (attr != RT_NULL) { ptd->attr = *attr; } else { /* use default attribute */ pthread_attr_init(&ptd->attr); } if (ptd->attr.stacksize == 0) { ret = EINVAL; goto __exit; } rt_snprintf(name, sizeof(name), "pth%02d", pthread_number ++); /* pthread is a static thread object */ ptd->tid = (rt_thread_t) rt_malloc(sizeof(struct rt_thread)); if (ptd->tid == RT_NULL) { ret = ENOMEM; goto __exit; } memset(ptd->tid, 0, sizeof(struct rt_thread)); if (ptd->attr.detachstate == PTHREAD_CREATE_JOINABLE) { ptd->joinable_sem = rt_sem_create(name, 0, RT_IPC_FLAG_FIFO); if (ptd->joinable_sem == RT_NULL) { ret = ENOMEM; goto __exit; } } else { ptd->joinable_sem = RT_NULL; } /* set parameter */ ptd->thread_entry = start; ptd->thread_parameter = parameter; /* stack */ if (ptd->attr.stackaddr == 0) { stack = (void *)rt_malloc(ptd->attr.stacksize); } else { stack = (void *)(ptd->attr.stackaddr); } if (stack == RT_NULL) { ret = ENOMEM; goto __exit; } /* initial this pthread to system */ if (rt_thread_init(ptd->tid, name, pthread_entry_stub, ptd, stack, ptd->attr.stacksize, ptd->attr.schedparam.sched_priority, 20) != RT_EOK) { ret = EINVAL; goto __exit; } /* set pthread id */ *pid = pth_id; /* set pthread cleanup function and ptd data */ ptd->tid->cleanup = _pthread_cleanup; ptd->tid->pthread_data = (void *)ptd; /* start thread */ if (rt_thread_startup(ptd->tid) == RT_EOK) return 0; /* start thread failed */ rt_thread_detach(ptd->tid); ret = EINVAL; __exit: if (pth_id != PTHREAD_NUM_MAX) { _pthread_data_destroy(ptd); } return ret; } RTM_EXPORT(pthread_create); int pthread_detach(pthread_t thread) { int ret = 0; _pthread_data_t *ptd = _pthread_get_data(thread); if (ptd == RT_NULL) { /* invalid pthread id */ ret = EINVAL; goto __exit; } if (ptd->attr.detachstate == PTHREAD_CREATE_DETACHED) { /* The implementation has detected that the value specified by thread does not refer * to a joinable thread. */ ret = EINVAL; goto __exit; } if ((ptd->tid->stat & RT_THREAD_STAT_MASK) == RT_THREAD_CLOSE) { /* destroy this pthread */ _pthread_data_destroy(ptd); goto __exit; } else { /* change to detach state */ ptd->attr.detachstate = PTHREAD_CREATE_DETACHED; /* detach joinable semaphore */ if (ptd->joinable_sem) { rt_sem_delete(ptd->joinable_sem); ptd->joinable_sem = RT_NULL; } } __exit: return ret; } RTM_EXPORT(pthread_detach); int pthread_join(pthread_t thread, void **value_ptr) { _pthread_data_t *ptd; rt_err_t result; ptd = _pthread_get_data(thread); if (ptd == RT_NULL) { return EINVAL; /* invalid pthread id */ } if (ptd && ptd->tid == rt_thread_self()) { /* join self */ return EDEADLK; } if (ptd->attr.detachstate == PTHREAD_CREATE_DETACHED) { return EINVAL; /* join on a detached pthread */ } result = rt_sem_take(ptd->joinable_sem, RT_WAITING_FOREVER); if (result == RT_EOK) { /* get return value */ if (value_ptr != RT_NULL) *value_ptr = ptd->return_value; /* destroy this pthread */ _pthread_data_destroy(ptd); } else { return ESRCH; } return 0; } RTM_EXPORT(pthread_join); pthread_t pthread_self (void) { rt_thread_t tid; _pthread_data_t *ptd; tid = rt_thread_self(); if (tid == NULL) return PTHREAD_NUM_MAX; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); return _pthread_data_get_pth(ptd); } RTM_EXPORT(pthread_self); int pthread_getcpuclockid(pthread_t thread, clockid_t *clock_id) { if(_pthread_get_data(thread) == NULL) { return EINVAL; } *clock_id = (clockid_t)rt_tick_get(); return 0; } RTM_EXPORT(pthread_getcpuclockid); int pthread_getconcurrency(void) { return concurrency_level; } RTM_EXPORT(pthread_getconcurrency); int pthread_setconcurrency(int new_level) { concurrency_level = new_level; return 0; } RTM_EXPORT(pthread_setconcurrency); int pthread_getschedparam(pthread_t thread, int *policy, struct sched_param *param) { _pthread_data_t *ptd; ptd = _pthread_get_data(thread); pthread_attr_getschedpolicy(&ptd->attr, policy); pthread_attr_getschedparam(&ptd->attr, param); return 0; } RTM_EXPORT(pthread_getschedparam); int pthread_setschedparam(pthread_t thread, int policy, const struct sched_param *param) { _pthread_data_t *ptd; ptd = _pthread_get_data(thread); pthread_attr_setschedpolicy(&ptd->attr, policy); pthread_attr_setschedparam(&ptd->attr, param); return 0; } RTM_EXPORT(pthread_setschedparam); int pthread_setschedprio(pthread_t thread, int prio) { _pthread_data_t *ptd; struct sched_param param; ptd = _pthread_get_data(thread); param.sched_priority = prio; pthread_attr_setschedparam(&ptd->attr, ¶m); return 0; } RTM_EXPORT(pthread_setschedprio); void pthread_exit(void *value) { _pthread_data_t *ptd; _pthread_cleanup_t *cleanup; rt_thread_t tid; if (rt_thread_self() == RT_NULL) { return; } /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; rt_enter_critical(); /* disable cancel */ ptd->cancelstate = PTHREAD_CANCEL_DISABLE; /* set return value */ ptd->return_value = value; rt_exit_critical(); /* * When use pthread_exit to exit. * invoke pushed cleanup */ while (ptd->cleanup != RT_NULL) { cleanup = ptd->cleanup; ptd->cleanup = cleanup->next; cleanup->cleanup_func(cleanup->parameter); /* release this cleanup function */ rt_free(cleanup); } /* get the info aboult "tid" early */ tid = ptd->tid; /* According to "detachstate" to whether or not to recycle resource immediately */ if (ptd->attr.detachstate == PTHREAD_CREATE_JOINABLE) { /* set value */ rt_sem_release(ptd->joinable_sem); } else { /* release pthread resource */ _pthread_data_destroy(ptd); } /* * second: detach thread. * this thread will be removed from scheduler list * and because there is a cleanup function in the * thread (pthread_cleanup), it will move to defunct * thread list and wait for handling in idle thread. */ rt_thread_detach(tid); /* reschedule thread */ rt_schedule(); } RTM_EXPORT(pthread_exit); int pthread_once(pthread_once_t *once_control, void (*init_routine)(void)) { RT_ASSERT(once_control != RT_NULL); RT_ASSERT(init_routine != RT_NULL); rt_enter_critical(); if (!(*once_control)) { /* call routine once */ *once_control = 1; rt_exit_critical(); init_routine(); } rt_exit_critical(); return 0; } RTM_EXPORT(pthread_once); int pthread_atfork(void (*prepare)(void), void (*parent)(void), void (*child)(void)) { return EOPNOTSUPP; } RTM_EXPORT(pthread_atfork); int pthread_kill(pthread_t thread, int sig) { #ifdef RT_USING_SIGNALS _pthread_data_t *ptd; int ret; ptd = _pthread_get_data(thread); if (ptd) { ret = rt_thread_kill(ptd->tid, sig); if (ret == -RT_EINVAL) { return EINVAL; } return ret; } return ESRCH; #else return ENOSYS; #endif } RTM_EXPORT(pthread_kill); #ifdef RT_USING_SIGNALS int pthread_sigmask(int how, const sigset_t *set, sigset_t *oset) { return sigprocmask(how, set, oset); } #endif void pthread_cleanup_pop(int execute) { _pthread_data_t *ptd; _pthread_cleanup_t *cleanup; if (rt_thread_self() == NULL) return; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); if (execute) { rt_enter_critical(); cleanup = ptd->cleanup; if (cleanup) ptd->cleanup = cleanup->next; rt_exit_critical(); if (cleanup) { cleanup->cleanup_func(cleanup->parameter); rt_free(cleanup); } } } RTM_EXPORT(pthread_cleanup_pop); void pthread_cleanup_push(void (*routine)(void *), void *arg) { _pthread_data_t *ptd; _pthread_cleanup_t *cleanup; if (rt_thread_self() == NULL) return; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); cleanup = (_pthread_cleanup_t *)rt_malloc(sizeof(_pthread_cleanup_t)); if (cleanup != RT_NULL) { cleanup->cleanup_func = routine; cleanup->parameter = arg; rt_enter_critical(); cleanup->next = ptd->cleanup; ptd->cleanup = cleanup; rt_exit_critical(); } } RTM_EXPORT(pthread_cleanup_push); /* * According to IEEE Std 1003.1, 2004 Edition , following pthreads * interface support cancellation point: * mq_receive() * mq_send() * mq_timedreceive() * mq_timedsend() * msgrcv() * msgsnd() * msync() * pthread_cond_timedwait() * pthread_cond_wait() * pthread_join() * pthread_testcancel() * sem_timedwait() * sem_wait() * * A cancellation point may also occur when a thread is * executing the following functions: * pthread_rwlock_rdlock() * pthread_rwlock_timedrdlock() * pthread_rwlock_timedwrlock() * pthread_rwlock_wrlock() * * The pthread_cancel(), pthread_setcancelstate(), and pthread_setcanceltype() * functions are defined to be async-cancel safe. */ int pthread_setcancelstate(int state, int *oldstate) { _pthread_data_t *ptd; if (rt_thread_self() == NULL) return EINVAL; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); if ((state == PTHREAD_CANCEL_ENABLE) || (state == PTHREAD_CANCEL_DISABLE)) { if (oldstate) *oldstate = ptd->cancelstate; ptd->cancelstate = state; return 0; } return EINVAL; } RTM_EXPORT(pthread_setcancelstate); int pthread_setcanceltype(int type, int *oldtype) { _pthread_data_t *ptd; if (rt_thread_self() == NULL) return EINVAL; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); if ((type != PTHREAD_CANCEL_DEFERRED) && (type != PTHREAD_CANCEL_ASYNCHRONOUS)) return EINVAL; if (oldtype) *oldtype = ptd->canceltype; ptd->canceltype = type; return 0; } RTM_EXPORT(pthread_setcanceltype); void pthread_testcancel(void) { int cancel = 0; _pthread_data_t *ptd; if (rt_thread_self() == NULL) return; /* get pthread data from pthread_data of thread */ ptd = (_pthread_data_t *)rt_thread_self()->pthread_data; RT_ASSERT(ptd != RT_NULL); if (ptd->cancelstate == PTHREAD_CANCEL_ENABLE) cancel = ptd->canceled; if (cancel) pthread_exit((void *)PTHREAD_CANCELED); } RTM_EXPORT(pthread_testcancel); int pthread_cancel(pthread_t thread) { _pthread_data_t *ptd; _pthread_cleanup_t *cleanup; rt_thread_t tid; /* get posix thread data */ ptd = _pthread_get_data(thread); if (ptd == RT_NULL) { return EINVAL; } tid = ptd->tid; /* cancel self */ if (ptd->tid == rt_thread_self()) return 0; /* set canceled */ if (ptd->cancelstate == PTHREAD_CANCEL_ENABLE) { ptd->canceled = 1; if (ptd->canceltype == PTHREAD_CANCEL_ASYNCHRONOUS) { /* * When use pthread_cancel to exit. * invoke pushed cleanup */ while (ptd->cleanup != RT_NULL) { cleanup = ptd->cleanup; ptd->cleanup = cleanup->next; cleanup->cleanup_func(cleanup->parameter); /* release this cleanup function */ rt_free(cleanup); } /* According to "detachstate" to whether or not to recycle resource immediately */ if (ptd->attr.detachstate == PTHREAD_CREATE_JOINABLE) { /* set value */ rt_sem_release(ptd->joinable_sem); } else { /* release pthread resource */ _pthread_data_destroy(ptd); } /* * second: detach thread. * this thread will be removed from scheduler list * and because there is a cleanup function in the * thread (pthread_cleanup), it will move to defunct * thread list and wait for handling in idle thread. */ rt_thread_detach(tid); } } return 0; } RTM_EXPORT(pthread_cancel);