lib/posix/pthread.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2018 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/kernel.h>
 #include <stdio.h>
 #include <zephyr/sys/atomic.h>
 #include <ksched.h>
 #include <zephyr/wait_q.h>
 #include <zephyr/posix/pthread.h>
 #include <zephyr/sys/slist.h>

 #define PTHREAD_INIT_FLAGS	PTHREAD_CANCEL_ENABLE
 #define PTHREAD_CANCELED	((void *) -1)

 #define LOWEST_POSIX_THREAD_PRIORITY 1

 PTHREAD_MUTEX_DEFINE(pthread_key_lock);

 static const pthread_attr_t init_pthread_attrs = {
 	.priority = LOWEST_POSIX_THREAD_PRIORITY,
 	.stack = NULL,
 	.stacksize = 0,
 	.flags = PTHREAD_INIT_FLAGS,
 	.delayedstart = 0,
 #if defined(CONFIG_PREEMPT_ENABLED)
 	.schedpolicy = SCHED_RR,
 #else
 	.schedpolicy = SCHED_FIFO,
 #endif
 	.detachstate = PTHREAD_CREATE_JOINABLE,
 	.initialized = true,
 };

 static struct posix_thread posix_thread_pool[CONFIG_MAX_PTHREAD_COUNT];
 PTHREAD_MUTEX_DEFINE(pthread_pool_lock);

 static bool is_posix_prio_valid(uint32_t priority, int policy)
 {
 	if (priority >= sched_get_priority_min(policy) &&
 	    priority <= sched_get_priority_max(policy)) {
 		return true;
 	}

 	return false;
 }

 static uint32_t zephyr_to_posix_priority(int32_t z_prio, int *policy)
 {
 	uint32_t prio;

 	if (z_prio < 0) {
 		*policy = SCHED_FIFO;
 		prio = -1 * (z_prio + 1);
 	} else {
 		*policy = SCHED_RR;
 		prio = (CONFIG_NUM_PREEMPT_PRIORITIES - z_prio);
 	}

 	return prio;
 }

 static int32_t posix_to_zephyr_priority(uint32_t priority, int policy)
 {
 	int32_t prio;

 	if (policy == SCHED_FIFO) {
 		/* Zephyr COOP priority starts from -1 */
 		prio =  -1 * (priority + 1);
 	} else {
 		prio = (CONFIG_NUM_PREEMPT_PRIORITIES - priority);
 	}

 	return prio;
 }

 /**
  * @brief Set scheduling parameter attributes in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_setschedparam(pthread_attr_t *attr,
 			       const struct sched_param *schedparam)
 {
 	int priority = schedparam->sched_priority;

 	if ((attr == NULL) || (attr->initialized == 0U) ||
 	    (is_posix_prio_valid(priority, attr->schedpolicy) == false)) {
 		return EINVAL;
 	}

 	attr->priority = priority;
 	return 0;
 }

 /**
  * @brief Set stack attributes in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_setstack(pthread_attr_t *attr, void *stackaddr,
 			  size_t stacksize)
 {
 	if (stackaddr == NULL) {
 		return EACCES;
 	}

 	attr->stack = stackaddr;
 	attr->stacksize = stacksize;
 	return 0;
 }

 static void zephyr_thread_wrapper(void *arg1, void *arg2, void *arg3)
 {
 	void * (*fun_ptr)(void *) = arg3;

 	fun_ptr(arg1);
 	pthread_exit(NULL);
 }

 /**
  * @brief Create a new thread.
  *
  * Pthread attribute should not be NULL. API will return Error on NULL
  * attribute value.
  *
  * See IEEE 1003.1
  */
 int pthread_create(pthread_t *newthread, const pthread_attr_t *attr,
 		   void *(*threadroutine)(void *), void *arg)
 {
 	int32_t prio;
 	uint32_t pthread_num;
 	pthread_condattr_t cond_attr;
 	struct posix_thread *thread;

 	/*
 	 * FIXME: Pthread attribute must be non-null and it provides stack
 	 * pointer and stack size. So even though POSIX 1003.1 spec accepts
 	 * attrib as NULL but zephyr needs it initialized with valid stack.
 	 */
 	if ((attr == NULL) || (attr->initialized == 0U)
 	    || (attr->stack == NULL) || (attr->stacksize == 0)) {
 		return EINVAL;
 	}

 	pthread_mutex_lock(&pthread_pool_lock);
 	for (pthread_num = 0;
 	    pthread_num < CONFIG_MAX_PTHREAD_COUNT; pthread_num++) {
 		thread = &posix_thread_pool[pthread_num];
 		if (thread->state == PTHREAD_EXITED || thread->state == PTHREAD_TERMINATED) {
 			thread->state = PTHREAD_JOINABLE;
 			break;
 		}
 	}
 	pthread_mutex_unlock(&pthread_pool_lock);

 	if (pthread_num >= CONFIG_MAX_PTHREAD_COUNT) {
 		return EAGAIN;
 	}

 	prio = posix_to_zephyr_priority(attr->priority, attr->schedpolicy);

 	thread = &posix_thread_pool[pthread_num];
 	/*
 	 * Ignore return value, as we know that Zephyr implementation
 	 * cannot fail.
 	 */
 	(void)pthread_mutex_init(&thread->state_lock, NULL);
 	(void)pthread_mutex_init(&thread->cancel_lock, NULL);

 	pthread_mutex_lock(&thread->cancel_lock);
 	thread->cancel_state = (1 << _PTHREAD_CANCEL_POS) & attr->flags;
 	thread->cancel_pending = 0;
 	pthread_mutex_unlock(&thread->cancel_lock);

 	pthread_mutex_lock(&thread->state_lock);
 	thread->state = attr->detachstate;
 	pthread_mutex_unlock(&thread->state_lock);

 	pthread_cond_init(&thread->state_cond, &cond_attr);
 	sys_slist_init(&thread->key_list);

 	*newthread = (pthread_t) k_thread_create(&thread->thread, attr->stack,
 						 attr->stacksize,
 						 (k_thread_entry_t)
 						 zephyr_thread_wrapper,
 						 (void *)arg, NULL,
 						 threadroutine, prio,
 						 (~K_ESSENTIAL & attr->flags),
 						 K_MSEC(attr->delayedstart));
 	return 0;
 }


 /**
  * @brief Set cancelability State.
  *
  * See IEEE 1003.1
  */
 int pthread_setcancelstate(int state, int *oldstate)
 {
 	struct posix_thread *pthread = (struct posix_thread *) pthread_self();

 	if (state != PTHREAD_CANCEL_ENABLE &&
 	    state != PTHREAD_CANCEL_DISABLE) {
 		return EINVAL;
 	}

 	*oldstate = pthread->cancel_state;

 	pthread_mutex_lock(&pthread->cancel_lock);
 	pthread->cancel_state = state;
 	pthread_mutex_unlock(&pthread->cancel_lock);

 	if (state == PTHREAD_CANCEL_ENABLE && pthread->cancel_pending) {
 		pthread_exit((void *)PTHREAD_CANCELED);
 	}

 	return 0;
 }

 /**
  * @brief Cancel execution of a thread.
  *
  * See IEEE 1003.1
  */
 int pthread_cancel(pthread_t pthread)
 {
 	struct posix_thread *thread = (struct posix_thread *) pthread;
 	int cancel_state;

 	if ((thread == NULL) || (thread->state == PTHREAD_TERMINATED)) {
 		return ESRCH;
 	}

 	pthread_mutex_lock(&thread->cancel_lock);
 	thread->cancel_pending = 1;
 	cancel_state = thread->cancel_state;
 	pthread_mutex_unlock(&thread->cancel_lock);

 	if (cancel_state == PTHREAD_CANCEL_ENABLE) {
 		pthread_mutex_lock(&thread->state_lock);
 		if (thread->state == PTHREAD_DETACHED) {
 			thread->state = PTHREAD_TERMINATED;
 		} else {
 			thread->retval = PTHREAD_CANCELED;
 			thread->state = PTHREAD_EXITED;
 			pthread_cond_broadcast(&thread->state_cond);
 		}
 		pthread_mutex_unlock(&thread->state_lock);

 		k_thread_abort((k_tid_t) thread);
 	}

 	return 0;
 }

 /**
  * @brief Set thread scheduling policy and parameters.
  *
  * See IEEE 1003.1
  */
 int pthread_setschedparam(pthread_t pthread, int policy,
 			  const struct sched_param *param)
 {
 	k_tid_t thread = (k_tid_t)pthread;
 	int new_prio;

 	if (thread == NULL) {
 		return ESRCH;
 	}

 	if (policy != SCHED_RR && policy != SCHED_FIFO) {
 		return EINVAL;
 	}

 	if (is_posix_prio_valid(param->sched_priority, policy) == false) {
 		return EINVAL;
 	}

 	new_prio = posix_to_zephyr_priority(param->sched_priority, policy);

 	k_thread_priority_set(thread, new_prio);
 	return 0;
 }

 /**
  * @brief Initialise threads attribute object
  *
  * See IEEE 1003.1
  */
 int pthread_attr_init(pthread_attr_t *attr)
 {

 	if (attr == NULL) {
 		return ENOMEM;
 	}

 	(void)memcpy(attr, &init_pthread_attrs, sizeof(pthread_attr_t));

 	return 0;
 }

 /**
  * @brief Get thread scheduling policy and parameters
  *
  * See IEEE 1003.1
  */
 int pthread_getschedparam(pthread_t pthread, int *policy,
 			  struct sched_param *param)
 {
 	struct posix_thread *thread = (struct posix_thread *) pthread;
 	uint32_t priority;

 	if ((thread == NULL) || (thread->state == PTHREAD_TERMINATED)) {
 		return ESRCH;
 	}

 	priority = k_thread_priority_get((k_tid_t) thread);

 	param->sched_priority = zephyr_to_posix_priority(priority, policy);
 	return 0;
 }

 /**
  * @brief Dynamic package initialization
  *
  * See IEEE 1003.1
  */
 int pthread_once(pthread_once_t *once, void (*init_func)(void))
 {
 	pthread_mutex_lock(&pthread_key_lock);

 	if (*once != PTHREAD_ONCE_INIT) {
 		pthread_mutex_unlock(&pthread_key_lock);
 		return 0;
 	}

 	init_func();
 	*once = 0;

 	pthread_mutex_unlock(&pthread_key_lock);

 	return 0;
 }

 /**
  * @brief Terminate calling thread.
  *
  * See IEEE 1003.1
  */
 void pthread_exit(void *retval)
 {
 	struct posix_thread *self = (struct posix_thread *)pthread_self();
 	pthread_key_obj *key_obj;
 	pthread_thread_data *thread_spec_data;
 	sys_snode_t *node_l;

 	/* Make a thread as cancelable before exiting */
 	pthread_mutex_lock(&self->cancel_lock);
 	if (self->cancel_state == PTHREAD_CANCEL_DISABLE) {
 		self->cancel_state = PTHREAD_CANCEL_ENABLE;
 	}

 	pthread_mutex_unlock(&self->cancel_lock);

 	pthread_mutex_lock(&self->state_lock);
 	if (self->state == PTHREAD_JOINABLE) {
 		self->retval = retval;
 		self->state = PTHREAD_EXITED;
 		self->retval = retval;
 		pthread_cond_broadcast(&self->state_cond);
 	} else {
 		self->state = PTHREAD_TERMINATED;
 	}

 	SYS_SLIST_FOR_EACH_NODE(&self->key_list, node_l) {
 		thread_spec_data = (pthread_thread_data *)node_l;
 		if (thread_spec_data != NULL) {
 			key_obj = thread_spec_data->key;
 			if (key_obj->destructor != NULL) {
 				(key_obj->destructor)(thread_spec_data->spec_data);
 			}
 		}
 	}

 	pthread_mutex_unlock(&self->state_lock);
 	k_thread_abort((k_tid_t)self);
 }

 /**
  * @brief Wait for a thread termination.
  *
  * See IEEE 1003.1
  */
 int pthread_join(pthread_t thread, void **status)
 {
 	struct posix_thread *pthread = (struct posix_thread *) thread;
 	int ret = 0;

 	if (pthread == NULL) {
 		return ESRCH;
 	}

 	if (pthread == pthread_self()) {
 		return EDEADLK;
 	}

 	pthread_mutex_lock(&pthread->state_lock);

 	if (pthread->state == PTHREAD_JOINABLE) {
 		pthread_cond_wait(&pthread->state_cond, &pthread->state_lock);
 	}

 	if (pthread->state == PTHREAD_EXITED) {
 		if (status != NULL) {
 			*status = pthread->retval;
 		}
 	} else if (pthread->state == PTHREAD_DETACHED) {
 		ret = EINVAL;
 	} else {
 		ret = ESRCH;
 	}

 	pthread_mutex_unlock(&pthread->state_lock);
 	return ret;
 }

 /**
  * @brief Detach a thread.
  *
  * See IEEE 1003.1
  */
 int pthread_detach(pthread_t thread)
 {
 	struct posix_thread *pthread = (struct posix_thread *) thread;
 	int ret = 0;

 	if (pthread == NULL) {
 		return ESRCH;
 	}

 	pthread_mutex_lock(&pthread->state_lock);

 	switch (pthread->state) {
 	case PTHREAD_JOINABLE:
 		pthread->state = PTHREAD_DETACHED;
 		/* Broadcast the condition.
 		 * This will make threads waiting to join this thread continue.
 		 */
 		pthread_cond_broadcast(&pthread->state_cond);
 		break;
 	case PTHREAD_EXITED:
 		pthread->state = PTHREAD_TERMINATED;
 		/* THREAD has already exited.
 		 * Pthread remained to provide exit status.
 		 */
 		break;
 	case PTHREAD_TERMINATED:
 		ret = ESRCH;
 		break;
 	default:
 		ret = EINVAL;
 		break;
 	}

 	pthread_mutex_unlock(&pthread->state_lock);
 	return ret;
 }

 /**
  * @brief Get detach state attribute in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_getdetachstate(const pthread_attr_t *attr, int *detachstate)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	*detachstate = attr->detachstate;
 	return 0;
 }

 /**
  * @brief Set detach state attribute in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_setdetachstate(pthread_attr_t *attr, int detachstate)
 {
 	if ((attr == NULL) || (attr->initialized == 0U) ||
 	    (detachstate != PTHREAD_CREATE_DETACHED &&
 	     detachstate != PTHREAD_CREATE_JOINABLE)) {
 		return EINVAL;
 	}

 	attr->detachstate = detachstate;
 	return 0;
 }


 /**
  * @brief Get scheduling policy attribute in Thread attributes.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_getschedpolicy(const pthread_attr_t *attr, int *policy)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	*policy = attr->schedpolicy;
 	return 0;
 }


 /**
  * @brief Set scheduling policy attribute in Thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_setschedpolicy(pthread_attr_t *attr, int policy)
 {
 	if ((attr == NULL) || (attr->initialized == 0U) ||
 	    (policy != SCHED_RR && policy != SCHED_FIFO)) {
 		return EINVAL;
 	}

 	attr->schedpolicy = policy;
 	return 0;
 }

 /**
  * @brief Get stack size attribute in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_getstacksize(const pthread_attr_t *attr, size_t *stacksize)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	*stacksize = attr->stacksize;
 	return 0;

 }

 /**
  * @brief Set stack size attribute in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_setstacksize(pthread_attr_t *attr, size_t stacksize)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	if (stacksize < PTHREAD_STACK_MIN) {
 		return EINVAL;
 	}

 	attr->stacksize = stacksize;
 	return 0;
 }

 /**
  * @brief Get stack attributes in thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_getstack(const pthread_attr_t *attr,
 				 void **stackaddr, size_t *stacksize)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	*stackaddr = attr->stack;
 	*stacksize = attr->stacksize;
 	return 0;
 }

 /**
  * @brief Get thread attributes object scheduling parameters.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_getschedparam(const pthread_attr_t *attr,
 			       struct sched_param *schedparam)
 {
 	if ((attr == NULL) || (attr->initialized == 0U)) {
 		return EINVAL;
 	}

 	schedparam->sched_priority = attr->priority;
 	return 0;
 }

 /**
  * @brief Destroy thread attributes object.
  *
  * See IEEE 1003.1
  */
 int pthread_attr_destroy(pthread_attr_t *attr)
 {
 	if ((attr != NULL) && (attr->initialized != 0U)) {
 		attr->initialized = false;
 		return 0;
 	}

 	return EINVAL;
 }

 int pthread_setname_np(pthread_t thread, const char *name)
 {
 #ifdef CONFIG_THREAD_NAME
 	k_tid_t kthread = (k_tid_t)thread;

 	if (kthread == NULL) {
 		return ESRCH;
 	}

 	if (name == NULL) {
 		return EINVAL;
 	}

 	return k_thread_name_set(kthread, name);
 #else
 	ARG_UNUSED(thread);
 	ARG_UNUSED(name);
 	return 0;
 #endif
 }

 int pthread_getname_np(pthread_t thread, char *name, size_t len)
 {
 #ifdef CONFIG_THREAD_NAME
 	k_tid_t kthread = (k_tid_t)thread;

 	if (kthread == NULL) {
 		return ESRCH;
 	}

 	if (name == NULL) {
 		return EINVAL;
 	}

 	memset(name, '\0', len);
 	return k_thread_name_copy(kthread, name, len-1);
 #else
 	ARG_UNUSED(thread);
 	ARG_UNUSED(name);
 	ARG_UNUSED(len);
 	return 0;
 #endif
 }
	/*
	* Copyright (c) 2018 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/kernel.h>
	#include <stdio.h>
	#include <zephyr/sys/atomic.h>
	#include <ksched.h>
	#include <zephyr/wait_q.h>
	#include <zephyr/posix/pthread.h>
	#include <zephyr/sys/slist.h>

	#define PTHREAD_INIT_FLAGS PTHREAD_CANCEL_ENABLE
	#define PTHREAD_CANCELED ((void *) -1)

	#define LOWEST_POSIX_THREAD_PRIORITY 1

	PTHREAD_MUTEX_DEFINE(pthread_key_lock);

	static const pthread_attr_t init_pthread_attrs = {
	.priority = LOWEST_POSIX_THREAD_PRIORITY,
	.stack = NULL,
	.stacksize = 0,
	.flags = PTHREAD_INIT_FLAGS,
	.delayedstart = 0,
	#if defined(CONFIG_PREEMPT_ENABLED)
	.schedpolicy = SCHED_RR,
	#else
	.schedpolicy = SCHED_FIFO,
	#endif
	.detachstate = PTHREAD_CREATE_JOINABLE,
	.initialized = true,
	};

	static struct posix_thread posix_thread_pool[CONFIG_MAX_PTHREAD_COUNT];
	PTHREAD_MUTEX_DEFINE(pthread_pool_lock);

	static bool is_posix_prio_valid(uint32_t priority, int policy)
	{
	if (priority >= sched_get_priority_min(policy) &&
	priority <= sched_get_priority_max(policy)) {
	return true;
	}

	return false;
	}

	static uint32_t zephyr_to_posix_priority(int32_t z_prio, int *policy)
	{
	uint32_t prio;

	if (z_prio < 0) {
	*policy = SCHED_FIFO;
	prio = -1 * (z_prio + 1);
	} else {
	*policy = SCHED_RR;
	prio = (CONFIG_NUM_PREEMPT_PRIORITIES - z_prio);
	}

	return prio;
	}

	static int32_t posix_to_zephyr_priority(uint32_t priority, int policy)
	{
	int32_t prio;

	if (policy == SCHED_FIFO) {
	/* Zephyr COOP priority starts from -1 */
	prio = -1 * (priority + 1);
	} else {
	prio = (CONFIG_NUM_PREEMPT_PRIORITIES - priority);
	}

	return prio;
	}

	/**
	* @brief Set scheduling parameter attributes in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_setschedparam(pthread_attr_t *attr,
	const struct sched_param *schedparam)
	{
	int priority = schedparam->sched_priority;

	if ((attr == NULL) \|\| (attr->initialized == 0U) \|\|
	(is_posix_prio_valid(priority, attr->schedpolicy) == false)) {
	return EINVAL;
	}

	attr->priority = priority;
	return 0;
	}

	/**
	* @brief Set stack attributes in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_setstack(pthread_attr_t attr, void stackaddr,
	size_t stacksize)
	{
	if (stackaddr == NULL) {
	return EACCES;
	}

	attr->stack = stackaddr;
	attr->stacksize = stacksize;
	return 0;
	}

	static void zephyr_thread_wrapper(void arg1, void arg2, void *arg3)
	{
	void * (fun_ptr)(void ) = arg3;

	fun_ptr(arg1);
	pthread_exit(NULL);
	}

	/**
	* @brief Create a new thread.
	*
	* Pthread attribute should not be NULL. API will return Error on NULL
	* attribute value.
	*
	* See IEEE 1003.1
	*/
	int pthread_create(pthread_t newthread, const pthread_attr_t attr,
	void (threadroutine)(void ), void arg)
	{
	int32_t prio;
	uint32_t pthread_num;
	pthread_condattr_t cond_attr;
	struct posix_thread *thread;

	/*
	* FIXME: Pthread attribute must be non-null and it provides stack
	* pointer and stack size. So even though POSIX 1003.1 spec accepts
	* attrib as NULL but zephyr needs it initialized with valid stack.
	*/
	if ((attr == NULL) \|\| (attr->initialized == 0U)
	\|\| (attr->stack == NULL) \|\| (attr->stacksize == 0)) {
	return EINVAL;
	}

	pthread_mutex_lock(&pthread_pool_lock);
	for (pthread_num = 0;
	pthread_num < CONFIG_MAX_PTHREAD_COUNT; pthread_num++) {
	thread = &posix_thread_pool[pthread_num];
	if (thread->state == PTHREAD_EXITED \|\| thread->state == PTHREAD_TERMINATED) {
	thread->state = PTHREAD_JOINABLE;
	break;
	}
	}
	pthread_mutex_unlock(&pthread_pool_lock);

	if (pthread_num >= CONFIG_MAX_PTHREAD_COUNT) {
	return EAGAIN;
	}

	prio = posix_to_zephyr_priority(attr->priority, attr->schedpolicy);

	thread = &posix_thread_pool[pthread_num];
	/*
	* Ignore return value, as we know that Zephyr implementation
	* cannot fail.
	*/
	(void)pthread_mutex_init(&thread->state_lock, NULL);
	(void)pthread_mutex_init(&thread->cancel_lock, NULL);

	pthread_mutex_lock(&thread->cancel_lock);
	thread->cancel_state = (1 << _PTHREAD_CANCEL_POS) & attr->flags;
	thread->cancel_pending = 0;
	pthread_mutex_unlock(&thread->cancel_lock);

	pthread_mutex_lock(&thread->state_lock);
	thread->state = attr->detachstate;
	pthread_mutex_unlock(&thread->state_lock);

	pthread_cond_init(&thread->state_cond, &cond_attr);
	sys_slist_init(&thread->key_list);

	*newthread = (pthread_t) k_thread_create(&thread->thread, attr->stack,
	attr->stacksize,
	(k_thread_entry_t)
	zephyr_thread_wrapper,
	(void *)arg, NULL,
	threadroutine, prio,
	(~K_ESSENTIAL & attr->flags),
	K_MSEC(attr->delayedstart));
	return 0;
	}


	/**
	* @brief Set cancelability State.
	*
	* See IEEE 1003.1
	*/
	int pthread_setcancelstate(int state, int *oldstate)
	{
	struct posix_thread pthread = (struct posix_thread ) pthread_self();

	if (state != PTHREAD_CANCEL_ENABLE &&
	state != PTHREAD_CANCEL_DISABLE) {
	return EINVAL;
	}

	*oldstate = pthread->cancel_state;

	pthread_mutex_lock(&pthread->cancel_lock);
	pthread->cancel_state = state;
	pthread_mutex_unlock(&pthread->cancel_lock);

	if (state == PTHREAD_CANCEL_ENABLE && pthread->cancel_pending) {
	pthread_exit((void *)PTHREAD_CANCELED);
	}

	return 0;
	}

	/**
	* @brief Cancel execution of a thread.
	*
	* See IEEE 1003.1
	*/
	int pthread_cancel(pthread_t pthread)
	{
	struct posix_thread thread = (struct posix_thread ) pthread;
	int cancel_state;

	if ((thread == NULL) \|\| (thread->state == PTHREAD_TERMINATED)) {
	return ESRCH;
	}

	pthread_mutex_lock(&thread->cancel_lock);
	thread->cancel_pending = 1;
	cancel_state = thread->cancel_state;
	pthread_mutex_unlock(&thread->cancel_lock);

	if (cancel_state == PTHREAD_CANCEL_ENABLE) {
	pthread_mutex_lock(&thread->state_lock);
	if (thread->state == PTHREAD_DETACHED) {
	thread->state = PTHREAD_TERMINATED;
	} else {
	thread->retval = PTHREAD_CANCELED;
	thread->state = PTHREAD_EXITED;
	pthread_cond_broadcast(&thread->state_cond);
	}
	pthread_mutex_unlock(&thread->state_lock);

	k_thread_abort((k_tid_t) thread);
	}

	return 0;
	}

	/**
	* @brief Set thread scheduling policy and parameters.
	*
	* See IEEE 1003.1
	*/
	int pthread_setschedparam(pthread_t pthread, int policy,
	const struct sched_param *param)
	{
	k_tid_t thread = (k_tid_t)pthread;
	int new_prio;

	if (thread == NULL) {
	return ESRCH;
	}

	if (policy != SCHED_RR && policy != SCHED_FIFO) {
	return EINVAL;
	}

	if (is_posix_prio_valid(param->sched_priority, policy) == false) {
	return EINVAL;
	}

	new_prio = posix_to_zephyr_priority(param->sched_priority, policy);

	k_thread_priority_set(thread, new_prio);
	return 0;
	}

	/**
	* @brief Initialise threads attribute object
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_init(pthread_attr_t *attr)
	{

	if (attr == NULL) {
	return ENOMEM;
	}

	(void)memcpy(attr, &init_pthread_attrs, sizeof(pthread_attr_t));

	return 0;
	}

	/**
	* @brief Get thread scheduling policy and parameters
	*
	* See IEEE 1003.1
	*/
	int pthread_getschedparam(pthread_t pthread, int *policy,
	struct sched_param *param)
	{
	struct posix_thread thread = (struct posix_thread ) pthread;
	uint32_t priority;

	if ((thread == NULL) \|\| (thread->state == PTHREAD_TERMINATED)) {
	return ESRCH;
	}

	priority = k_thread_priority_get((k_tid_t) thread);

	param->sched_priority = zephyr_to_posix_priority(priority, policy);
	return 0;
	}

	/**
	* @brief Dynamic package initialization
	*
	* See IEEE 1003.1
	*/
	int pthread_once(pthread_once_t once, void (init_func)(void))
	{
	pthread_mutex_lock(&pthread_key_lock);

	if (*once != PTHREAD_ONCE_INIT) {
	pthread_mutex_unlock(&pthread_key_lock);
	return 0;
	}

	init_func();
	*once = 0;

	pthread_mutex_unlock(&pthread_key_lock);

	return 0;
	}

	/**
	* @brief Terminate calling thread.
	*
	* See IEEE 1003.1
	*/
	void pthread_exit(void *retval)
	{
	struct posix_thread self = (struct posix_thread )pthread_self();
	pthread_key_obj *key_obj;
	pthread_thread_data *thread_spec_data;
	sys_snode_t *node_l;

	/* Make a thread as cancelable before exiting */
	pthread_mutex_lock(&self->cancel_lock);
	if (self->cancel_state == PTHREAD_CANCEL_DISABLE) {
	self->cancel_state = PTHREAD_CANCEL_ENABLE;
	}

	pthread_mutex_unlock(&self->cancel_lock);

	pthread_mutex_lock(&self->state_lock);
	if (self->state == PTHREAD_JOINABLE) {
	self->retval = retval;
	self->state = PTHREAD_EXITED;
	self->retval = retval;
	pthread_cond_broadcast(&self->state_cond);
	} else {
	self->state = PTHREAD_TERMINATED;
	}

	SYS_SLIST_FOR_EACH_NODE(&self->key_list, node_l) {
	thread_spec_data = (pthread_thread_data *)node_l;
	if (thread_spec_data != NULL) {
	key_obj = thread_spec_data->key;
	if (key_obj->destructor != NULL) {
	(key_obj->destructor)(thread_spec_data->spec_data);
	}
	}
	}

	pthread_mutex_unlock(&self->state_lock);
	k_thread_abort((k_tid_t)self);
	}

	/**
	* @brief Wait for a thread termination.
	*
	* See IEEE 1003.1
	*/
	int pthread_join(pthread_t thread, void **status)
	{
	struct posix_thread pthread = (struct posix_thread ) thread;
	int ret = 0;

	if (pthread == NULL) {
	return ESRCH;
	}

	if (pthread == pthread_self()) {
	return EDEADLK;
	}

	pthread_mutex_lock(&pthread->state_lock);

	if (pthread->state == PTHREAD_JOINABLE) {
	pthread_cond_wait(&pthread->state_cond, &pthread->state_lock);
	}

	if (pthread->state == PTHREAD_EXITED) {
	if (status != NULL) {
	*status = pthread->retval;
	}
	} else if (pthread->state == PTHREAD_DETACHED) {
	ret = EINVAL;
	} else {
	ret = ESRCH;
	}

	pthread_mutex_unlock(&pthread->state_lock);
	return ret;
	}

	/**
	* @brief Detach a thread.
	*
	* See IEEE 1003.1
	*/
	int pthread_detach(pthread_t thread)
	{
	struct posix_thread pthread = (struct posix_thread ) thread;
	int ret = 0;

	if (pthread == NULL) {
	return ESRCH;
	}

	pthread_mutex_lock(&pthread->state_lock);

	switch (pthread->state) {
	case PTHREAD_JOINABLE:
	pthread->state = PTHREAD_DETACHED;
	/* Broadcast the condition.
	* This will make threads waiting to join this thread continue.
	*/
	pthread_cond_broadcast(&pthread->state_cond);
	break;
	case PTHREAD_EXITED:
	pthread->state = PTHREAD_TERMINATED;
	/* THREAD has already exited.
	* Pthread remained to provide exit status.
	*/
	break;
	case PTHREAD_TERMINATED:
	ret = ESRCH;
	break;
	default:
	ret = EINVAL;
	break;
	}

	pthread_mutex_unlock(&pthread->state_lock);
	return ret;
	}

	/**
	* @brief Get detach state attribute in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_getdetachstate(const pthread_attr_t attr, int detachstate)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	*detachstate = attr->detachstate;
	return 0;
	}

	/**
	* @brief Set detach state attribute in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_setdetachstate(pthread_attr_t *attr, int detachstate)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U) \|\|
	(detachstate != PTHREAD_CREATE_DETACHED &&
	detachstate != PTHREAD_CREATE_JOINABLE)) {
	return EINVAL;
	}

	attr->detachstate = detachstate;
	return 0;
	}


	/**
	* @brief Get scheduling policy attribute in Thread attributes.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_getschedpolicy(const pthread_attr_t attr, int policy)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	*policy = attr->schedpolicy;
	return 0;
	}


	/**
	* @brief Set scheduling policy attribute in Thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_setschedpolicy(pthread_attr_t *attr, int policy)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U) \|\|
	(policy != SCHED_RR && policy != SCHED_FIFO)) {
	return EINVAL;
	}

	attr->schedpolicy = policy;
	return 0;
	}

	/**
	* @brief Get stack size attribute in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_getstacksize(const pthread_attr_t attr, size_t stacksize)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	*stacksize = attr->stacksize;
	return 0;

	}

	/**
	* @brief Set stack size attribute in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_setstacksize(pthread_attr_t *attr, size_t stacksize)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	if (stacksize < PTHREAD_STACK_MIN) {
	return EINVAL;
	}

	attr->stacksize = stacksize;
	return 0;
	}

	/**
	* @brief Get stack attributes in thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_getstack(const pthread_attr_t *attr,
	void *stackaddr, size_t stacksize)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	*stackaddr = attr->stack;
	*stacksize = attr->stacksize;
	return 0;
	}

	/**
	* @brief Get thread attributes object scheduling parameters.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_getschedparam(const pthread_attr_t *attr,
	struct sched_param *schedparam)
	{
	if ((attr == NULL) \|\| (attr->initialized == 0U)) {
	return EINVAL;
	}

	schedparam->sched_priority = attr->priority;
	return 0;
	}

	/**
	* @brief Destroy thread attributes object.
	*
	* See IEEE 1003.1
	*/
	int pthread_attr_destroy(pthread_attr_t *attr)
	{
	if ((attr != NULL) && (attr->initialized != 0U)) {
	attr->initialized = false;
	return 0;
	}

	return EINVAL;
	}

	int pthread_setname_np(pthread_t thread, const char *name)
	{
	#ifdef CONFIG_THREAD_NAME
	k_tid_t kthread = (k_tid_t)thread;

	if (kthread == NULL) {
	return ESRCH;
	}

	if (name == NULL) {
	return EINVAL;
	}

	return k_thread_name_set(kthread, name);
	#else
	ARG_UNUSED(thread);
	ARG_UNUSED(name);
	return 0;
	#endif
	}

	int pthread_getname_np(pthread_t thread, char *name, size_t len)
	{
	#ifdef CONFIG_THREAD_NAME
	k_tid_t kthread = (k_tid_t)thread;

	if (kthread == NULL) {
	return ESRCH;
	}

	if (name == NULL) {
	return EINVAL;
	}

	memset(name, '\0', len);
	return k_thread_name_copy(kthread, name, len-1);
	#else
	ARG_UNUSED(thread);
	ARG_UNUSED(name);
	ARG_UNUSED(len);
	return 0;
	#endif
	}