Google Git
Sign in
pigweed / third_party / github / zephyrproject-rtos / zephyr / c9faea2c2b8dcc2eb7ec36a57ec424dfbe70c3c8 / . / lib / posix / options / pthread.c
blob: bd9c85eeccbd480b2641120ee839d4be3b5eb33c [file] [log] [blame]
/*
* Copyright (c) 2018 Intel Corporation
* Copyright (c) 2023 Meta
*
* SPDX-License-Identifier: Apache-2.0
*/
#include "posix_internal.h"
#include "pthread_sched.h"
#include <stdio.h>
#include <zephyr/init.h>
#include <zephyr/kernel.h>
#include <zephyr/logging/log.h>
#include <zephyr/sys/atomic.h>
#include <zephyr/posix/pthread.h>
#include <zephyr/posix/unistd.h>
#include <zephyr/sys/sem.h>
#include <zephyr/sys/slist.h>
#include <zephyr/sys/util.h>
#define ZEPHYR_TO_POSIX_PRIORITY(_zprio) \
(((_zprio) < 0) ? (-1 * ((_zprio) + 1)) : (CONFIG_NUM_PREEMPT_PRIORITIES - (_zprio)-1))
#define POSIX_TO_ZEPHYR_PRIORITY(_prio, _pol) \
(((_pol) == SCHED_FIFO) ? (-1 * ((_prio) + 1)) \
: (CONFIG_NUM_PREEMPT_PRIORITIES - (_prio)-1))
#define DEFAULT_PTHREAD_PRIORITY \
POSIX_TO_ZEPHYR_PRIORITY(K_LOWEST_APPLICATION_THREAD_PRIO, DEFAULT_PTHREAD_POLICY)
#define DEFAULT_PTHREAD_POLICY (IS_ENABLED(CONFIG_PREEMPT_ENABLED) ? SCHED_RR : SCHED_FIFO)
#define PTHREAD_STACK_MAX BIT(CONFIG_POSIX_PTHREAD_ATTR_STACKSIZE_BITS)
#define PTHREAD_GUARD_MAX BIT_MASK(CONFIG_POSIX_PTHREAD_ATTR_GUARDSIZE_BITS)
LOG_MODULE_REGISTER(pthread, CONFIG_PTHREAD_LOG_LEVEL);
#ifdef CONFIG_DYNAMIC_THREAD_STACK_SIZE
#define DYNAMIC_STACK_SIZE CONFIG_DYNAMIC_THREAD_STACK_SIZE
#else
#define DYNAMIC_STACK_SIZE 0
#endif
static inline size_t __get_attr_stacksize(const struct posix_thread_attr *attr)
{
return attr->stacksize + 1;
}
static inline void __set_attr_stacksize(struct posix_thread_attr *attr, size_t stacksize)
{
attr->stacksize = stacksize - 1;
}
struct __pthread_cleanup {
void (*routine)(void *arg);
void *arg;
sys_snode_t node;
};
enum posix_thread_qid {
/* ready to be started via pthread_create() */
POSIX_THREAD_READY_Q,
/* running */
POSIX_THREAD_RUN_Q,
/* exited (either joinable or detached) */
POSIX_THREAD_DONE_Q,
/* invalid */
POSIX_THREAD_INVALID_Q,
};
/* only 2 bits in struct posix_thread_attr for schedpolicy */
BUILD_ASSERT(SCHED_OTHER < BIT(2) && SCHED_FIFO < BIT(2) && SCHED_RR < BIT(2));
BUILD_ASSERT((PTHREAD_CREATE_DETACHED == 0 || PTHREAD_CREATE_JOINABLE == 0) &&
(PTHREAD_CREATE_DETACHED == 1 || PTHREAD_CREATE_JOINABLE == 1));
BUILD_ASSERT((PTHREAD_CANCEL_ENABLE == 0 || PTHREAD_CANCEL_DISABLE == 0) &&
(PTHREAD_CANCEL_ENABLE == 1 || PTHREAD_CANCEL_DISABLE == 1));
BUILD_ASSERT(CONFIG_POSIX_PTHREAD_ATTR_STACKSIZE_BITS + CONFIG_POSIX_PTHREAD_ATTR_GUARDSIZE_BITS <=
32);
static void posix_thread_recycle(void);
static sys_dlist_t posix_thread_q[] = {
SYS_DLIST_STATIC_INIT(&posix_thread_q[POSIX_THREAD_READY_Q]),
SYS_DLIST_STATIC_INIT(&posix_thread_q[POSIX_THREAD_RUN_Q]),
SYS_DLIST_STATIC_INIT(&posix_thread_q[POSIX_THREAD_DONE_Q]),
};
static struct posix_thread posix_thread_pool[CONFIG_MAX_PTHREAD_COUNT];
static SYS_SEM_DEFINE(pthread_pool_lock, 1, 1);
static int pthread_concurrency;
static inline void posix_thread_q_set(struct posix_thread *t, enum posix_thread_qid qid)
{
switch (qid) {
case POSIX_THREAD_READY_Q:
case POSIX_THREAD_RUN_Q:
case POSIX_THREAD_DONE_Q:
sys_dlist_append(&posix_thread_q[qid], &t->q_node);
t->qid = qid;
break;
default:
__ASSERT(false, "cannot set invalid qid %d for posix thread %p", qid, t);
break;
}
}
static inline enum posix_thread_qid posix_thread_q_get(struct posix_thread *t)
{
switch (t->qid) {
case POSIX_THREAD_READY_Q:
case POSIX_THREAD_RUN_Q:
case POSIX_THREAD_DONE_Q:
return t->qid;
default:
__ASSERT(false, "posix thread %p has invalid qid: %d", t, t->qid);
return POSIX_THREAD_INVALID_Q;
}
}
/*
* We reserve the MSB to mark a pthread_t as initialized (from the
* perspective of the application). With a linear space, this means that
* the theoretical pthread_t range is [0,2147483647].
*/
BUILD_ASSERT(CONFIG_MAX_PTHREAD_COUNT < PTHREAD_OBJ_MASK_INIT,
"CONFIG_MAX_PTHREAD_COUNT is too high");
static inline size_t posix_thread_to_offset(struct posix_thread *t)
{
return t - posix_thread_pool;
}
static inline size_t get_posix_thread_idx(pthread_t pth)
{
return mark_pthread_obj_uninitialized(pth);
}
struct posix_thread *to_posix_thread(pthread_t pthread)
{
struct posix_thread *t;
bool actually_initialized;
size_t bit = get_posix_thread_idx(pthread);
/* if the provided thread does not claim to be initialized, its invalid */
if (!is_pthread_obj_initialized(pthread)) {
LOG_DBG("pthread is not initialized (%x)", pthread);
return NULL;
}
if (bit >= CONFIG_MAX_PTHREAD_COUNT) {
LOG_DBG("Invalid pthread (%x)", pthread);
return NULL;
}
t = &posix_thread_pool[bit];
/*
* Denote a pthread as "initialized" (i.e. allocated) if it is not in ready_q.
* This differs from other posix object allocation strategies because they use
* a bitarray to indicate whether an object has been allocated.
*/
actually_initialized = !(posix_thread_q_get(t) == POSIX_THREAD_READY_Q ||
(posix_thread_q_get(t) == POSIX_THREAD_DONE_Q &&
t->attr.detachstate == PTHREAD_CREATE_DETACHED));
if (!actually_initialized) {
LOG_DBG("Pthread claims to be initialized (%x)", pthread);
return NULL;
}
return &posix_thread_pool[bit];
}
pthread_t pthread_self(void)
{
size_t bit;
struct posix_thread *t;
t = (struct posix_thread *)CONTAINER_OF(k_current_get(), struct posix_thread, thread);
bit = posix_thread_to_offset(t);
return mark_pthread_obj_initialized(bit);
}
int pthread_equal(pthread_t pt1, pthread_t pt2)
{
return (pt1 == pt2);
}
pid_t getpid(void)
{
/*
* To maintain compatibility with some other POSIX operating systems,
* a PID of zero is used to indicate that the process exists in another namespace.
* PID zero is also used by the scheduler in some cases.
* PID one is usually reserved for the init process.
* Also note, that negative PIDs may be used by kill()
* to send signals to process groups in some implementations.
*
* At the moment, getpid just returns an arbitrary number >= 2
*/
return 42;
}
static inline void __z_pthread_cleanup_init(struct __pthread_cleanup *c, void (*routine)(void *arg),
void *arg)
{
*c = (struct __pthread_cleanup){
.routine = routine,
.arg = arg,
.node = {0},
};
}
void __z_pthread_cleanup_push(void *cleanup[3], void (*routine)(void *arg), void *arg)
{
struct posix_thread *t = NULL;
struct __pthread_cleanup *const c = (struct __pthread_cleanup *)cleanup;
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
BUILD_ASSERT(3 * sizeof(void *) == sizeof(*c));
__ASSERT_NO_MSG(t != NULL);
__ASSERT_NO_MSG(c != NULL);
__ASSERT_NO_MSG(routine != NULL);
__z_pthread_cleanup_init(c, routine, arg);
sys_slist_prepend(&t->cleanup_list, &c->node);
}
}
void __z_pthread_cleanup_pop(int execute)
{
sys_snode_t *node;
struct __pthread_cleanup *c = NULL;
struct posix_thread *t = NULL;
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
__ASSERT_NO_MSG(t != NULL);
node = sys_slist_get(&t->cleanup_list);
__ASSERT_NO_MSG(node != NULL);
c = CONTAINER_OF(node, struct __pthread_cleanup, node);
__ASSERT_NO_MSG(c != NULL);
__ASSERT_NO_MSG(c->routine != NULL);
}
if (execute) {
c->routine(c->arg);
}
}
static bool is_posix_policy_prio_valid(int priority, int policy)
{
if (priority >= sched_get_priority_min(policy) &&
priority <= sched_get_priority_max(policy)) {
return true;
}
LOG_DBG("Invalid priority %d and / or policy %d", priority, policy);
return false;
}
/* Non-static so that they can be tested in ztest */
int zephyr_to_posix_priority(int z_prio, int *policy)
{
int priority;
if (z_prio < 0) {
__ASSERT_NO_MSG(-z_prio <= CONFIG_NUM_COOP_PRIORITIES);
} else {
__ASSERT_NO_MSG(z_prio < CONFIG_NUM_PREEMPT_PRIORITIES);
}
*policy = (z_prio < 0) ? SCHED_FIFO : SCHED_RR;
priority = ZEPHYR_TO_POSIX_PRIORITY(z_prio);
__ASSERT_NO_MSG(is_posix_policy_prio_valid(priority, *policy));
return priority;
}
/* Non-static so that they can be tested in ztest */
int posix_to_zephyr_priority(int priority, int policy)
{
__ASSERT_NO_MSG(is_posix_policy_prio_valid(priority, policy));
return POSIX_TO_ZEPHYR_PRIORITY(priority, policy);
}
static bool __attr_is_runnable(const struct posix_thread_attr *attr)
{
size_t stacksize;
if (attr == NULL || attr->stack == NULL) {
LOG_DBG("attr %p is not initialized", attr);
return false;
}
stacksize = __get_attr_stacksize(attr);
if (stacksize < PTHREAD_STACK_MIN) {
LOG_DBG("attr %p has stacksize %zu is smaller than PTHREAD_STACK_MIN (%zu)", attr,
stacksize, (size_t)PTHREAD_STACK_MIN);
return false;
}
/* require a valid scheduler policy */
if (!valid_posix_policy(attr->schedpolicy)) {
LOG_DBG("Invalid scheduler policy %d", attr->schedpolicy);
return false;
}
return true;
}
static bool __attr_is_initialized(const struct posix_thread_attr *attr)
{
if (IS_ENABLED(CONFIG_DYNAMIC_THREAD)) {
return __attr_is_runnable(attr);
}
if (attr == NULL || !attr->initialized) {
LOG_DBG("attr %p is not initialized", attr);
return false;
}
return true;
}
/**
* @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)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || schedparam == NULL ||
!is_posix_policy_prio_valid(schedparam->sched_priority, attr->schedpolicy)) {
LOG_DBG("Invalid pthread_attr_t or sched_param");
return EINVAL;
}
attr->priority = schedparam->sched_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)
{
int ret;
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (stackaddr == NULL) {
LOG_DBG("NULL stack address");
return EACCES;
}
if (!__attr_is_initialized(attr) || stacksize == 0 || stacksize < PTHREAD_STACK_MIN ||
stacksize > PTHREAD_STACK_MAX) {
LOG_DBG("Invalid stacksize %zu", stacksize);
return EINVAL;
}
if (attr->stack != NULL) {
ret = k_thread_stack_free(attr->stack);
if (ret == 0) {
LOG_DBG("Freed attr %p thread stack %zu@%p", _attr,
__get_attr_stacksize(attr), attr->stack);
}
}
attr->stack = stackaddr;
__set_attr_stacksize(attr, stacksize);
LOG_DBG("Assigned thread stack %zu@%p to attr %p", __get_attr_stacksize(attr), attr->stack,
_attr);
return 0;
}
/**
* @brief Get scope attributes in thread attributes object.
*
* See IEEE 1003.1
*/
int pthread_attr_getscope(const pthread_attr_t *_attr, int *contentionscope)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || contentionscope == NULL) {
return EINVAL;
}
*contentionscope = attr->contentionscope;
return 0;
}
/**
* @brief Set scope attributes in thread attributes object.
*
* See IEEE 1003.1
*/
int pthread_attr_setscope(pthread_attr_t *_attr, int contentionscope)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr)) {
LOG_DBG("attr %p is not initialized", attr);
return EINVAL;
}
if (!(contentionscope == PTHREAD_SCOPE_PROCESS ||
contentionscope == PTHREAD_SCOPE_SYSTEM)) {
LOG_DBG("%s contentionscope %d", "Invalid", contentionscope);
return EINVAL;
}
if (contentionscope == PTHREAD_SCOPE_PROCESS) {
/* Zephyr does not yet support processes or process scheduling */
LOG_DBG("%s contentionscope %d", "Unsupported", contentionscope);
return ENOTSUP;
}
attr->contentionscope = contentionscope;
return 0;
}
/**
* @brief Get inherit scheduler attributes in thread attributes object.
*
* See IEEE 1003.1
*/
int pthread_attr_getinheritsched(const pthread_attr_t *_attr, int *inheritsched)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || inheritsched == NULL) {
return EINVAL;
}
*inheritsched = attr->inheritsched;
return 0;
}
/**
* @brief Set inherit scheduler attributes in thread attributes object.
*
* See IEEE 1003.1
*/
int pthread_attr_setinheritsched(pthread_attr_t *_attr, int inheritsched)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr)) {
LOG_DBG("attr %p is not initialized", attr);
return EINVAL;
}
if (inheritsched != PTHREAD_INHERIT_SCHED && inheritsched != PTHREAD_EXPLICIT_SCHED) {
LOG_DBG("Invalid inheritsched %d", inheritsched);
return EINVAL;
}
attr->inheritsched = inheritsched;
return 0;
}
static void posix_thread_recycle_work_handler(struct k_work *work)
{
ARG_UNUSED(work);
posix_thread_recycle();
}
static K_WORK_DELAYABLE_DEFINE(posix_thread_recycle_work, posix_thread_recycle_work_handler);
static void posix_thread_finalize(struct posix_thread *t, void *retval)
{
sys_snode_t *node_l;
pthread_key_obj *key_obj;
pthread_thread_data *thread_spec_data;
SYS_SLIST_FOR_EACH_NODE(&t->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);
}
}
}
/* move thread from run_q to done_q */
SYS_SEM_LOCK(&pthread_pool_lock) {
sys_dlist_remove(&t->q_node);
posix_thread_q_set(t, POSIX_THREAD_DONE_Q);
t->retval = retval;
}
/* trigger recycle work */
(void)k_work_schedule(&posix_thread_recycle_work, K_MSEC(CONFIG_PTHREAD_RECYCLER_DELAY_MS));
/* abort the underlying k_thread */
k_thread_abort(&t->thread);
}
FUNC_NORETURN
static void zephyr_thread_wrapper(void *arg1, void *arg2, void *arg3)
{
int err;
int barrier;
void *(*fun_ptr)(void *arg) = arg2;
struct posix_thread *t = CONTAINER_OF(k_current_get(), struct posix_thread, thread);
if (IS_ENABLED(CONFIG_PTHREAD_CREATE_BARRIER)) {
/* cross the barrier so that pthread_create() can continue */
barrier = POINTER_TO_UINT(arg3);
err = pthread_barrier_wait(&barrier);
__ASSERT_NO_MSG(err == 0 || err == PTHREAD_BARRIER_SERIAL_THREAD);
}
posix_thread_finalize(t, fun_ptr(arg1));
CODE_UNREACHABLE;
}
static void posix_thread_recycle(void)
{
struct posix_thread *t;
struct posix_thread *safe_t;
sys_dlist_t recyclables = SYS_DLIST_STATIC_INIT(&recyclables);
SYS_SEM_LOCK(&pthread_pool_lock) {
SYS_DLIST_FOR_EACH_CONTAINER_SAFE(&posix_thread_q[POSIX_THREAD_DONE_Q], t, safe_t,
q_node) {
if (t->attr.detachstate == PTHREAD_CREATE_JOINABLE) {
/* thread has not been joined yet */
continue;
}
sys_dlist_remove(&t->q_node);
sys_dlist_append(&recyclables, &t->q_node);
}
}
if (sys_dlist_is_empty(&recyclables)) {
return;
}
LOG_DBG("Recycling %zu threads", sys_dlist_len(&recyclables));
SYS_DLIST_FOR_EACH_CONTAINER(&recyclables, t, q_node) {
if (t->attr.caller_destroys) {
t->attr = (struct posix_thread_attr){0};
} else {
(void)pthread_attr_destroy((pthread_attr_t *)&t->attr);
}
}
SYS_SEM_LOCK(&pthread_pool_lock) {
while (!sys_dlist_is_empty(&recyclables)) {
t = CONTAINER_OF(sys_dlist_get(&recyclables), struct posix_thread, q_node);
posix_thread_q_set(t, POSIX_THREAD_READY_Q);
}
}
}
/**
* @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 *th, const pthread_attr_t *_attr, void *(*threadroutine)(void *),
void *arg)
{
int err;
pthread_barrier_t barrier;
struct posix_thread *t = NULL;
if (!(_attr == NULL || __attr_is_runnable((struct posix_thread_attr *)_attr))) {
return EINVAL;
}
/* reclaim resources greedily */
posix_thread_recycle();
SYS_SEM_LOCK(&pthread_pool_lock) {
if (!sys_dlist_is_empty(&posix_thread_q[POSIX_THREAD_READY_Q])) {
t = CONTAINER_OF(sys_dlist_get(&posix_thread_q[POSIX_THREAD_READY_Q]),
struct posix_thread, q_node);
/* initialize thread state */
posix_thread_q_set(t, POSIX_THREAD_RUN_Q);
sys_slist_init(&t->key_list);
sys_slist_init(&t->cleanup_list);
}
}
if (t != NULL && IS_ENABLED(CONFIG_PTHREAD_CREATE_BARRIER)) {
err = pthread_barrier_init(&barrier, NULL, 2);
if (err != 0) {
/* cannot allocate barrier. move thread back to ready_q */
SYS_SEM_LOCK(&pthread_pool_lock) {
sys_dlist_remove(&t->q_node);
posix_thread_q_set(t, POSIX_THREAD_READY_Q);
}
t = NULL;
}
}
if (t == NULL) {
/* no threads are ready */
LOG_DBG("No threads are ready");
return EAGAIN;
}
if (_attr == NULL) {
err = pthread_attr_init((pthread_attr_t *)&t->attr);
if (err == 0 && !__attr_is_runnable(&t->attr)) {
(void)pthread_attr_destroy((pthread_attr_t *)&t->attr);
err = EINVAL;
}
if (err != 0) {
/* cannot allocate pthread attributes (e.g. stack) */
SYS_SEM_LOCK(&pthread_pool_lock) {
sys_dlist_remove(&t->q_node);
posix_thread_q_set(t, POSIX_THREAD_READY_Q);
}
return err;
}
/* caller not responsible for destroying attr */
t->attr.caller_destroys = false;
} else {
/* copy user-provided attr into thread, caller must destroy attr at a later time */
t->attr = *(struct posix_thread_attr *)_attr;
}
if (t->attr.inheritsched == PTHREAD_INHERIT_SCHED) {
int pol;
t->attr.priority =
zephyr_to_posix_priority(k_thread_priority_get(k_current_get()), &pol);
t->attr.schedpolicy = pol;
}
/* spawn the thread */
k_thread_create(
&t->thread, t->attr.stack, __get_attr_stacksize(&t->attr) + t->attr.guardsize,
zephyr_thread_wrapper, (void *)arg, threadroutine,
IS_ENABLED(CONFIG_PTHREAD_CREATE_BARRIER) ? UINT_TO_POINTER(barrier) : NULL,
posix_to_zephyr_priority(t->attr.priority, t->attr.schedpolicy), 0, K_NO_WAIT);
if (IS_ENABLED(CONFIG_PTHREAD_CREATE_BARRIER)) {
/* wait for the spawned thread to cross our barrier */
err = pthread_barrier_wait(&barrier);
__ASSERT_NO_MSG(err == 0 || err == PTHREAD_BARRIER_SERIAL_THREAD);
err = pthread_barrier_destroy(&barrier);
__ASSERT_NO_MSG(err == 0);
}
/* finally provide the initialized thread to the caller */
*th = mark_pthread_obj_initialized(posix_thread_to_offset(t));
LOG_DBG("Created pthread %p", &t->thread);
return 0;
}
int pthread_getconcurrency(void)
{
int ret = 0;
SYS_SEM_LOCK(&pthread_pool_lock) {
ret = pthread_concurrency;
}
return ret;
}
int pthread_setconcurrency(int new_level)
{
if (new_level < 0) {
return EINVAL;
}
if (new_level > CONFIG_MP_MAX_NUM_CPUS) {
return EAGAIN;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
pthread_concurrency = new_level;
}
return 0;
}
/**
* @brief Set cancelability State.
*
* See IEEE 1003.1
*/
int pthread_setcancelstate(int state, int *oldstate)
{
int ret = 0;
bool cancel_pending = false;
struct posix_thread *t = NULL;
bool cancel_type = PTHREAD_CANCEL_ENABLE;
if (state != PTHREAD_CANCEL_ENABLE && state != PTHREAD_CANCEL_DISABLE) {
LOG_DBG("Invalid pthread state %d", state);
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
if (t == NULL) {
ret = EINVAL;
SYS_SEM_LOCK_BREAK;
}
if (oldstate != NULL) {
*oldstate = t->attr.cancelstate;
}
t->attr.cancelstate = state;
cancel_pending = t->attr.cancelpending;
cancel_type = t->attr.canceltype;
}
if (state == PTHREAD_CANCEL_ENABLE && cancel_type == PTHREAD_CANCEL_ASYNCHRONOUS &&
cancel_pending) {
posix_thread_finalize(t, PTHREAD_CANCELED);
}
return 0;
}
/**
* @brief Set cancelability Type.
*
* See IEEE 1003.1
*/
int pthread_setcanceltype(int type, int *oldtype)
{
int ret = 0;
struct posix_thread *t;
if (type != PTHREAD_CANCEL_DEFERRED && type != PTHREAD_CANCEL_ASYNCHRONOUS) {
LOG_DBG("Invalid pthread cancel type %d", type);
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
if (t == NULL) {
ret = EINVAL;
SYS_SEM_LOCK_BREAK;
}
if (oldtype != NULL) {
*oldtype = t->attr.canceltype;
}
t->attr.canceltype = type;
}
return ret;
}
/**
* @brief Create a cancellation point in the calling thread.
*
* See IEEE 1003.1
*/
void pthread_testcancel(void)
{
bool cancel_pended = false;
struct posix_thread *t = NULL;
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
if (t == NULL) {
SYS_SEM_LOCK_BREAK;
}
if (t->attr.cancelstate != PTHREAD_CANCEL_ENABLE) {
SYS_SEM_LOCK_BREAK;
}
if (t->attr.cancelpending) {
cancel_pended = true;
t->attr.cancelstate = PTHREAD_CANCEL_DISABLE;
}
}
if (cancel_pended) {
posix_thread_finalize(t, PTHREAD_CANCELED);
}
}
/**
* @brief Cancel execution of a thread.
*
* See IEEE 1003.1
*/
int pthread_cancel(pthread_t pthread)
{
int ret = 0;
bool cancel_state = PTHREAD_CANCEL_ENABLE;
bool cancel_type = PTHREAD_CANCEL_DEFERRED;
struct posix_thread *t = NULL;
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
if (!__attr_is_initialized(&t->attr)) {
/* thread has already terminated */
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
t->attr.cancelpending = true;
cancel_state = t->attr.cancelstate;
cancel_type = t->attr.canceltype;
}
if (ret == 0 && cancel_state == PTHREAD_CANCEL_ENABLE &&
cancel_type == PTHREAD_CANCEL_ASYNCHRONOUS) {
posix_thread_finalize(t, PTHREAD_CANCELED);
}
return ret;
}
/**
* @brief Set thread scheduling policy and parameters.
*
* See IEEE 1003.1
*/
int pthread_setschedparam(pthread_t pthread, int policy, const struct sched_param *param)
{
int ret = 0;
int new_prio = K_LOWEST_APPLICATION_THREAD_PRIO;
struct posix_thread *t = NULL;
if (param == NULL || !valid_posix_policy(policy) ||
!is_posix_policy_prio_valid(param->sched_priority, policy)) {
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
new_prio = posix_to_zephyr_priority(param->sched_priority, policy);
}
if (ret == 0) {
k_thread_priority_set(&t->thread, new_prio);
}
return ret;
}
/**
* @brief Set thread scheduling priority.
*
* See IEEE 1003.1
*/
int pthread_setschedprio(pthread_t thread, int prio)
{
int ret;
int new_prio = K_LOWEST_APPLICATION_THREAD_PRIO;
struct posix_thread *t = NULL;
int policy;
struct sched_param param;
ret = pthread_getschedparam(thread, &policy, &param);
if (ret != 0) {
return ret;
}
if (!is_posix_policy_prio_valid(prio, policy)) {
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(thread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
new_prio = posix_to_zephyr_priority(prio, policy);
}
if (ret == 0) {
k_thread_priority_set(&t->thread, new_prio);
}
return ret;
}
/**
* @brief Initialise threads attribute object
*
* See IEEE 1003.1
*/
int pthread_attr_init(pthread_attr_t *_attr)
{
struct posix_thread_attr *const attr = (struct posix_thread_attr *)_attr;
if (attr == NULL) {
LOG_DBG("Invalid attr pointer");
return ENOMEM;
}
BUILD_ASSERT(DYNAMIC_STACK_SIZE <= PTHREAD_STACK_MAX);
*attr = (struct posix_thread_attr){0};
attr->guardsize = CONFIG_POSIX_PTHREAD_ATTR_GUARDSIZE_DEFAULT;
attr->contentionscope = PTHREAD_SCOPE_SYSTEM;
attr->inheritsched = PTHREAD_INHERIT_SCHED;
if (DYNAMIC_STACK_SIZE > 0) {
attr->stack = k_thread_stack_alloc(DYNAMIC_STACK_SIZE + attr->guardsize,
k_is_user_context() ? K_USER : 0);
if (attr->stack == NULL) {
LOG_DBG("Did not auto-allocate thread stack");
} else {
__set_attr_stacksize(attr, DYNAMIC_STACK_SIZE);
__ASSERT_NO_MSG(__attr_is_initialized(attr));
LOG_DBG("Allocated thread stack %zu@%p", __get_attr_stacksize(attr),
attr->stack);
}
}
/* caller responsible for destroying attr */
attr->initialized = true;
LOG_DBG("Initialized attr %p", _attr);
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)
{
int ret = 0;
struct posix_thread *t;
if (policy == NULL || param == NULL) {
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
if (!__attr_is_initialized(&t->attr)) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
param->sched_priority =
zephyr_to_posix_priority(k_thread_priority_get(&t->thread), policy);
}
return ret;
}
/**
* @brief Dynamic package initialization
*
* See IEEE 1003.1
*/
int pthread_once(pthread_once_t *once, void (*init_func)(void))
{
__unused int ret;
bool run_init_func = false;
struct pthread_once *const _once = (struct pthread_once *)once;
if (init_func == NULL) {
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
if (!_once->flag) {
run_init_func = true;
_once->flag = true;
}
}
if (run_init_func) {
init_func();
}
return 0;
}
/**
* @brief Terminate calling thread.
*
* See IEEE 1003.1
*/
FUNC_NORETURN
void pthread_exit(void *retval)
{
struct posix_thread *self = NULL;
SYS_SEM_LOCK(&pthread_pool_lock) {
self = to_posix_thread(pthread_self());
if (self == NULL) {
SYS_SEM_LOCK_BREAK;
}
/* Mark a thread as cancellable before exiting */
self->attr.cancelstate = PTHREAD_CANCEL_ENABLE;
}
if (self == NULL) {
/* not a valid posix_thread */
LOG_DBG("Aborting non-pthread %p", k_current_get());
k_thread_abort(k_current_get());
CODE_UNREACHABLE;
}
posix_thread_finalize(self, retval);
CODE_UNREACHABLE;
}
/**
* @brief Wait for a thread termination.
*
* See IEEE 1003.1
*/
int pthread_join(pthread_t pthread, void **status)
{
int ret = 0;
struct posix_thread *t = NULL;
if (pthread == pthread_self()) {
LOG_DBG("Pthread attempted to join itself (%x)", pthread);
return EDEADLK;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
LOG_DBG("Pthread %p joining..", &t->thread);
if (t->attr.detachstate != PTHREAD_CREATE_JOINABLE) {
/* undefined behaviour */
ret = EINVAL;
SYS_SEM_LOCK_BREAK;
}
if (posix_thread_q_get(t) == POSIX_THREAD_READY_Q) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
/*
* thread is joinable and is in run_q or done_q.
* let's ensure that the thread cannot be joined again after this point.
*/
t->attr.detachstate = PTHREAD_CREATE_DETACHED;
}
switch (ret) {
case ESRCH:
LOG_DBG("Pthread %p has already been joined", &t->thread);
return ret;
case EINVAL:
LOG_DBG("Pthread %p is not a joinable", &t->thread);
return ret;
case 0:
break;
}
ret = k_thread_join(&t->thread, K_FOREVER);
/* other possibilities? */
__ASSERT_NO_MSG(ret == 0);
LOG_DBG("Joined pthread %p", &t->thread);
if (status != NULL) {
LOG_DBG("Writing status to %p", status);
*status = t->retval;
}
posix_thread_recycle();
return 0;
}
/**
* @brief Detach a thread.
*
* See IEEE 1003.1
*/
int pthread_detach(pthread_t pthread)
{
int ret = 0;
struct posix_thread *t;
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread);
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
if (posix_thread_q_get(t) == POSIX_THREAD_READY_Q ||
t->attr.detachstate != PTHREAD_CREATE_JOINABLE) {
LOG_DBG("Pthread %p cannot be detached", &t->thread);
ret = EINVAL;
SYS_SEM_LOCK_BREAK;
}
t->attr.detachstate = PTHREAD_CREATE_DETACHED;
}
if (ret == 0) {
LOG_DBG("Pthread %p detached", &t->thread);
}
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)
{
const struct posix_thread_attr *attr = (const struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || (detachstate == NULL)) {
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)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || ((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)
{
const struct posix_thread_attr *attr = (const struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || (policy == NULL)) {
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)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || !valid_posix_policy(policy)) {
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)
{
const struct posix_thread_attr *attr = (const struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || (stacksize == NULL)) {
return EINVAL;
}
*stacksize = __get_attr_stacksize(attr);
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)
{
int ret;
void *new_stack;
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || stacksize == 0 || stacksize < PTHREAD_STACK_MIN ||
stacksize > PTHREAD_STACK_MAX) {
return EINVAL;
}
if (__get_attr_stacksize(attr) == stacksize) {
return 0;
}
new_stack =
k_thread_stack_alloc(stacksize + attr->guardsize, k_is_user_context() ? K_USER : 0);
if (new_stack == NULL) {
if (stacksize < __get_attr_stacksize(attr)) {
__set_attr_stacksize(attr, stacksize);
return 0;
}
LOG_DBG("k_thread_stack_alloc(%zu) failed",
__get_attr_stacksize(attr) + attr->guardsize);
return ENOMEM;
}
LOG_DBG("Allocated thread stack %zu@%p", stacksize + attr->guardsize, attr->stack);
if (attr->stack != NULL) {
ret = k_thread_stack_free(attr->stack);
if (ret == 0) {
LOG_DBG("Freed attr %p thread stack %zu@%p", _attr,
__get_attr_stacksize(attr), attr->stack);
}
}
__set_attr_stacksize(attr, stacksize);
attr->stack = new_stack;
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)
{
const struct posix_thread_attr *attr = (const struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || (stackaddr == NULL) || (stacksize == NULL)) {
return EINVAL;
}
*stackaddr = attr->stack;
*stacksize = __get_attr_stacksize(attr);
return 0;
}
int pthread_attr_getguardsize(const pthread_attr_t *ZRESTRICT _attr, size_t *ZRESTRICT guardsize)
{
struct posix_thread_attr *const attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || guardsize == NULL) {
return EINVAL;
}
*guardsize = attr->guardsize;
return 0;
}
int pthread_attr_setguardsize(pthread_attr_t *_attr, size_t guardsize)
{
struct posix_thread_attr *const attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || guardsize > PTHREAD_GUARD_MAX) {
return EINVAL;
}
attr->guardsize = guardsize;
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)
{
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr) || (schedparam == NULL)) {
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)
{
int ret;
struct posix_thread_attr *attr = (struct posix_thread_attr *)_attr;
if (!__attr_is_initialized(attr)) {
return EINVAL;
}
ret = k_thread_stack_free(attr->stack);
if (ret == 0) {
LOG_DBG("Freed attr %p thread stack %zu@%p", _attr, __get_attr_stacksize(attr),
attr->stack);
}
*attr = (struct posix_thread_attr){0};
LOG_DBG("Destroyed attr %p", _attr);
return 0;
}
int pthread_setname_np(pthread_t thread, const char *name)
{
#ifdef CONFIG_THREAD_NAME
k_tid_t kthread;
thread = get_posix_thread_idx(thread);
if (thread >= CONFIG_MAX_PTHREAD_COUNT) {
return ESRCH;
}
kthread = &posix_thread_pool[thread].thread;
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;
thread = get_posix_thread_idx(thread);
if (thread >= CONFIG_MAX_PTHREAD_COUNT) {
return ESRCH;
}
if (name == NULL) {
return EINVAL;
}
memset(name, '\0', len);
kthread = &posix_thread_pool[thread].thread;
return k_thread_name_copy(kthread, name, len - 1);
#else
ARG_UNUSED(thread);
ARG_UNUSED(name);
ARG_UNUSED(len);
return 0;
#endif
}
int pthread_atfork(void (*prepare)(void), void (*parent)(void), void (*child)(void))
{
ARG_UNUSED(prepare);
ARG_UNUSED(parent);
ARG_UNUSED(child);
return ENOSYS;
}
/* this should probably go into signal.c but we need access to the lock */
int pthread_sigmask(int how, const sigset_t *ZRESTRICT set, sigset_t *ZRESTRICT oset)
{
int ret = 0;
struct posix_thread *t;
if (!(how == SIG_BLOCK || how == SIG_SETMASK || how == SIG_UNBLOCK)) {
return EINVAL;
}
SYS_SEM_LOCK(&pthread_pool_lock) {
t = to_posix_thread(pthread_self());
if (t == NULL) {
ret = ESRCH;
SYS_SEM_LOCK_BREAK;
}
if (oset != NULL) {
*oset = t->sigset;
}
if (set == NULL) {
SYS_SEM_LOCK_BREAK;
}
switch (how) {
case SIG_BLOCK:
for (size_t i = 0; i < ARRAY_SIZE(set->sig); ++i) {
t->sigset.sig[i] |= set->sig[i];
}
break;
case SIG_SETMASK:
t->sigset = *set;
break;
case SIG_UNBLOCK:
for (size_t i = 0; i < ARRAY_SIZE(set->sig); ++i) {
t->sigset.sig[i] &= ~set->sig[i];
}
break;
}
}
return ret;
}
static int posix_thread_pool_init(void)
{
size_t i;
for (i = 0; i < CONFIG_MAX_PTHREAD_COUNT; ++i) {
posix_thread_q_set(&posix_thread_pool[i], POSIX_THREAD_READY_Q);
}
return 0;
}
SYS_INIT(posix_thread_pool_init, PRE_KERNEL_1, 0);