glib/glib/gthread-posix.c
Philip Withnall c8840ff9a8 gthread: Only print scheduler setting warnings once
If one thread pool thread fails to set its scheduler settings, it’s
likely that all the rest of them will fail for the same reason. Avoid
printing duplicate critical warnings in that case.

Signed-off-by: Philip Withnall <withnall@endlessm.com>

Fixes: #2191
2020-09-02 16:09:12 +01:00

1603 lines
40 KiB
C

/* GLIB - Library of useful routines for C programming
* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
*
* gthread.c: posix thread system implementation
* Copyright 1998 Sebastian Wilhelmi; University of Karlsruhe
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
/*
* Modified by the GLib Team and others 1997-2000. See the AUTHORS
* file for a list of people on the GLib Team. See the ChangeLog
* files for a list of changes. These files are distributed with
* GLib at ftp://ftp.gtk.org/pub/gtk/.
*/
/* The GMutex, GCond and GPrivate implementations in this file are some
* of the lowest-level code in GLib. All other parts of GLib (messages,
* memory, slices, etc) assume that they can freely use these facilities
* without risking recursion.
*
* As such, these functions are NOT permitted to call any other part of
* GLib.
*
* The thread manipulation functions (create, exit, join, etc.) have
* more freedom -- they can do as they please.
*/
#include "config.h"
#include "gthread.h"
#include "gmain.h"
#include "gmessages.h"
#include "gslice.h"
#include "gstrfuncs.h"
#include "gtestutils.h"
#include "gthreadprivate.h"
#include "gutils.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <errno.h>
#include <pthread.h>
#include <sys/time.h>
#include <unistd.h>
#ifdef HAVE_PTHREAD_SET_NAME_NP
#include <pthread_np.h>
#endif
#ifdef HAVE_SCHED_H
#include <sched.h>
#endif
#ifdef G_OS_WIN32
#include <windows.h>
#endif
#if defined(HAVE_SYS_SCHED_GETATTR)
#include <sys/syscall.h>
#endif
/* clang defines __ATOMIC_SEQ_CST but doesn't support the GCC extension */
#if defined(HAVE_FUTEX) && defined(__ATOMIC_SEQ_CST) && !defined(__clang__)
#define USE_NATIVE_MUTEX
#endif
static void
g_thread_abort (gint status,
const gchar *function)
{
fprintf (stderr, "GLib (gthread-posix.c): Unexpected error from C library during '%s': %s. Aborting.\n",
function, strerror (status));
g_abort ();
}
/* {{{1 GMutex */
#if !defined(USE_NATIVE_MUTEX)
static pthread_mutex_t *
g_mutex_impl_new (void)
{
pthread_mutexattr_t *pattr = NULL;
pthread_mutex_t *mutex;
gint status;
#ifdef PTHREAD_ADAPTIVE_MUTEX_INITIALIZER_NP
pthread_mutexattr_t attr;
#endif
mutex = malloc (sizeof (pthread_mutex_t));
if G_UNLIKELY (mutex == NULL)
g_thread_abort (errno, "malloc");
#ifdef PTHREAD_ADAPTIVE_MUTEX_INITIALIZER_NP
pthread_mutexattr_init (&attr);
pthread_mutexattr_settype (&attr, PTHREAD_MUTEX_ADAPTIVE_NP);
pattr = &attr;
#endif
if G_UNLIKELY ((status = pthread_mutex_init (mutex, pattr)) != 0)
g_thread_abort (status, "pthread_mutex_init");
#ifdef PTHREAD_ADAPTIVE_MUTEX_INITIALIZER_NP
pthread_mutexattr_destroy (&attr);
#endif
return mutex;
}
static void
g_mutex_impl_free (pthread_mutex_t *mutex)
{
pthread_mutex_destroy (mutex);
free (mutex);
}
static inline pthread_mutex_t *
g_mutex_get_impl (GMutex *mutex)
{
pthread_mutex_t *impl = g_atomic_pointer_get (&mutex->p);
if G_UNLIKELY (impl == NULL)
{
impl = g_mutex_impl_new ();
if (!g_atomic_pointer_compare_and_exchange (&mutex->p, NULL, impl))
g_mutex_impl_free (impl);
impl = mutex->p;
}
return impl;
}
/**
* g_mutex_init:
* @mutex: an uninitialized #GMutex
*
* Initializes a #GMutex so that it can be used.
*
* This function is useful to initialize a mutex that has been
* allocated on the stack, or as part of a larger structure.
* It is not necessary to initialize a mutex that has been
* statically allocated.
*
* |[<!-- language="C" -->
* typedef struct {
* GMutex m;
* ...
* } Blob;
*
* Blob *b;
*
* b = g_new (Blob, 1);
* g_mutex_init (&b->m);
* ]|
*
* To undo the effect of g_mutex_init() when a mutex is no longer
* needed, use g_mutex_clear().
*
* Calling g_mutex_init() on an already initialized #GMutex leads
* to undefined behaviour.
*
* Since: 2.32
*/
void
g_mutex_init (GMutex *mutex)
{
mutex->p = g_mutex_impl_new ();
}
/**
* g_mutex_clear:
* @mutex: an initialized #GMutex
*
* Frees the resources allocated to a mutex with g_mutex_init().
*
* This function should not be used with a #GMutex that has been
* statically allocated.
*
* Calling g_mutex_clear() on a locked mutex leads to undefined
* behaviour.
*
* Sine: 2.32
*/
void
g_mutex_clear (GMutex *mutex)
{
g_mutex_impl_free (mutex->p);
}
/**
* g_mutex_lock:
* @mutex: a #GMutex
*
* Locks @mutex. If @mutex is already locked by another thread, the
* current thread will block until @mutex is unlocked by the other
* thread.
*
* #GMutex is neither guaranteed to be recursive nor to be
* non-recursive. As such, calling g_mutex_lock() on a #GMutex that has
* already been locked by the same thread results in undefined behaviour
* (including but not limited to deadlocks).
*/
void
g_mutex_lock (GMutex *mutex)
{
gint status;
if G_UNLIKELY ((status = pthread_mutex_lock (g_mutex_get_impl (mutex))) != 0)
g_thread_abort (status, "pthread_mutex_lock");
}
/**
* g_mutex_unlock:
* @mutex: a #GMutex
*
* Unlocks @mutex. If another thread is blocked in a g_mutex_lock()
* call for @mutex, it will become unblocked and can lock @mutex itself.
*
* Calling g_mutex_unlock() on a mutex that is not locked by the
* current thread leads to undefined behaviour.
*/
void
g_mutex_unlock (GMutex *mutex)
{
gint status;
if G_UNLIKELY ((status = pthread_mutex_unlock (g_mutex_get_impl (mutex))) != 0)
g_thread_abort (status, "pthread_mutex_unlock");
}
/**
* g_mutex_trylock:
* @mutex: a #GMutex
*
* Tries to lock @mutex. If @mutex is already locked by another thread,
* it immediately returns %FALSE. Otherwise it locks @mutex and returns
* %TRUE.
*
* #GMutex is neither guaranteed to be recursive nor to be
* non-recursive. As such, calling g_mutex_lock() on a #GMutex that has
* already been locked by the same thread results in undefined behaviour
* (including but not limited to deadlocks or arbitrary return values).
*
* Returns: %TRUE if @mutex could be locked
*/
gboolean
g_mutex_trylock (GMutex *mutex)
{
gint status;
if G_LIKELY ((status = pthread_mutex_trylock (g_mutex_get_impl (mutex))) == 0)
return TRUE;
if G_UNLIKELY (status != EBUSY)
g_thread_abort (status, "pthread_mutex_trylock");
return FALSE;
}
#endif /* !defined(USE_NATIVE_MUTEX) */
/* {{{1 GRecMutex */
static pthread_mutex_t *
g_rec_mutex_impl_new (void)
{
pthread_mutexattr_t attr;
pthread_mutex_t *mutex;
mutex = malloc (sizeof (pthread_mutex_t));
if G_UNLIKELY (mutex == NULL)
g_thread_abort (errno, "malloc");
pthread_mutexattr_init (&attr);
pthread_mutexattr_settype (&attr, PTHREAD_MUTEX_RECURSIVE);
pthread_mutex_init (mutex, &attr);
pthread_mutexattr_destroy (&attr);
return mutex;
}
static void
g_rec_mutex_impl_free (pthread_mutex_t *mutex)
{
pthread_mutex_destroy (mutex);
free (mutex);
}
static inline pthread_mutex_t *
g_rec_mutex_get_impl (GRecMutex *rec_mutex)
{
pthread_mutex_t *impl = g_atomic_pointer_get (&rec_mutex->p);
if G_UNLIKELY (impl == NULL)
{
impl = g_rec_mutex_impl_new ();
if (!g_atomic_pointer_compare_and_exchange (&rec_mutex->p, NULL, impl))
g_rec_mutex_impl_free (impl);
impl = rec_mutex->p;
}
return impl;
}
/**
* g_rec_mutex_init:
* @rec_mutex: an uninitialized #GRecMutex
*
* Initializes a #GRecMutex so that it can be used.
*
* This function is useful to initialize a recursive mutex
* that has been allocated on the stack, or as part of a larger
* structure.
*
* It is not necessary to initialise a recursive mutex that has been
* statically allocated.
*
* |[<!-- language="C" -->
* typedef struct {
* GRecMutex m;
* ...
* } Blob;
*
* Blob *b;
*
* b = g_new (Blob, 1);
* g_rec_mutex_init (&b->m);
* ]|
*
* Calling g_rec_mutex_init() on an already initialized #GRecMutex
* leads to undefined behaviour.
*
* To undo the effect of g_rec_mutex_init() when a recursive mutex
* is no longer needed, use g_rec_mutex_clear().
*
* Since: 2.32
*/
void
g_rec_mutex_init (GRecMutex *rec_mutex)
{
rec_mutex->p = g_rec_mutex_impl_new ();
}
/**
* g_rec_mutex_clear:
* @rec_mutex: an initialized #GRecMutex
*
* Frees the resources allocated to a recursive mutex with
* g_rec_mutex_init().
*
* This function should not be used with a #GRecMutex that has been
* statically allocated.
*
* Calling g_rec_mutex_clear() on a locked recursive mutex leads
* to undefined behaviour.
*
* Sine: 2.32
*/
void
g_rec_mutex_clear (GRecMutex *rec_mutex)
{
g_rec_mutex_impl_free (rec_mutex->p);
}
/**
* g_rec_mutex_lock:
* @rec_mutex: a #GRecMutex
*
* Locks @rec_mutex. If @rec_mutex is already locked by another
* thread, the current thread will block until @rec_mutex is
* unlocked by the other thread. If @rec_mutex is already locked
* by the current thread, the 'lock count' of @rec_mutex is increased.
* The mutex will only become available again when it is unlocked
* as many times as it has been locked.
*
* Since: 2.32
*/
void
g_rec_mutex_lock (GRecMutex *mutex)
{
pthread_mutex_lock (g_rec_mutex_get_impl (mutex));
}
/**
* g_rec_mutex_unlock:
* @rec_mutex: a #GRecMutex
*
* Unlocks @rec_mutex. If another thread is blocked in a
* g_rec_mutex_lock() call for @rec_mutex, it will become unblocked
* and can lock @rec_mutex itself.
*
* Calling g_rec_mutex_unlock() on a recursive mutex that is not
* locked by the current thread leads to undefined behaviour.
*
* Since: 2.32
*/
void
g_rec_mutex_unlock (GRecMutex *rec_mutex)
{
pthread_mutex_unlock (rec_mutex->p);
}
/**
* g_rec_mutex_trylock:
* @rec_mutex: a #GRecMutex
*
* Tries to lock @rec_mutex. If @rec_mutex is already locked
* by another thread, it immediately returns %FALSE. Otherwise
* it locks @rec_mutex and returns %TRUE.
*
* Returns: %TRUE if @rec_mutex could be locked
*
* Since: 2.32
*/
gboolean
g_rec_mutex_trylock (GRecMutex *rec_mutex)
{
if (pthread_mutex_trylock (g_rec_mutex_get_impl (rec_mutex)) != 0)
return FALSE;
return TRUE;
}
/* {{{1 GRWLock */
static pthread_rwlock_t *
g_rw_lock_impl_new (void)
{
pthread_rwlock_t *rwlock;
gint status;
rwlock = malloc (sizeof (pthread_rwlock_t));
if G_UNLIKELY (rwlock == NULL)
g_thread_abort (errno, "malloc");
if G_UNLIKELY ((status = pthread_rwlock_init (rwlock, NULL)) != 0)
g_thread_abort (status, "pthread_rwlock_init");
return rwlock;
}
static void
g_rw_lock_impl_free (pthread_rwlock_t *rwlock)
{
pthread_rwlock_destroy (rwlock);
free (rwlock);
}
static inline pthread_rwlock_t *
g_rw_lock_get_impl (GRWLock *lock)
{
pthread_rwlock_t *impl = g_atomic_pointer_get (&lock->p);
if G_UNLIKELY (impl == NULL)
{
impl = g_rw_lock_impl_new ();
if (!g_atomic_pointer_compare_and_exchange (&lock->p, NULL, impl))
g_rw_lock_impl_free (impl);
impl = lock->p;
}
return impl;
}
/**
* g_rw_lock_init:
* @rw_lock: an uninitialized #GRWLock
*
* Initializes a #GRWLock so that it can be used.
*
* This function is useful to initialize a lock that has been
* allocated on the stack, or as part of a larger structure. It is not
* necessary to initialise a reader-writer lock that has been statically
* allocated.
*
* |[<!-- language="C" -->
* typedef struct {
* GRWLock l;
* ...
* } Blob;
*
* Blob *b;
*
* b = g_new (Blob, 1);
* g_rw_lock_init (&b->l);
* ]|
*
* To undo the effect of g_rw_lock_init() when a lock is no longer
* needed, use g_rw_lock_clear().
*
* Calling g_rw_lock_init() on an already initialized #GRWLock leads
* to undefined behaviour.
*
* Since: 2.32
*/
void
g_rw_lock_init (GRWLock *rw_lock)
{
rw_lock->p = g_rw_lock_impl_new ();
}
/**
* g_rw_lock_clear:
* @rw_lock: an initialized #GRWLock
*
* Frees the resources allocated to a lock with g_rw_lock_init().
*
* This function should not be used with a #GRWLock that has been
* statically allocated.
*
* Calling g_rw_lock_clear() when any thread holds the lock
* leads to undefined behaviour.
*
* Sine: 2.32
*/
void
g_rw_lock_clear (GRWLock *rw_lock)
{
g_rw_lock_impl_free (rw_lock->p);
}
/**
* g_rw_lock_writer_lock:
* @rw_lock: a #GRWLock
*
* Obtain a write lock on @rw_lock. If any thread already holds
* a read or write lock on @rw_lock, the current thread will block
* until all other threads have dropped their locks on @rw_lock.
*
* Since: 2.32
*/
void
g_rw_lock_writer_lock (GRWLock *rw_lock)
{
int retval = pthread_rwlock_wrlock (g_rw_lock_get_impl (rw_lock));
if (retval != 0)
g_critical ("Failed to get RW lock %p: %s", rw_lock, g_strerror (retval));
}
/**
* g_rw_lock_writer_trylock:
* @rw_lock: a #GRWLock
*
* Tries to obtain a write lock on @rw_lock. If any other thread holds
* a read or write lock on @rw_lock, it immediately returns %FALSE.
* Otherwise it locks @rw_lock and returns %TRUE.
*
* Returns: %TRUE if @rw_lock could be locked
*
* Since: 2.32
*/
gboolean
g_rw_lock_writer_trylock (GRWLock *rw_lock)
{
if (pthread_rwlock_trywrlock (g_rw_lock_get_impl (rw_lock)) != 0)
return FALSE;
return TRUE;
}
/**
* g_rw_lock_writer_unlock:
* @rw_lock: a #GRWLock
*
* Release a write lock on @rw_lock.
*
* Calling g_rw_lock_writer_unlock() on a lock that is not held
* by the current thread leads to undefined behaviour.
*
* Since: 2.32
*/
void
g_rw_lock_writer_unlock (GRWLock *rw_lock)
{
pthread_rwlock_unlock (g_rw_lock_get_impl (rw_lock));
}
/**
* g_rw_lock_reader_lock:
* @rw_lock: a #GRWLock
*
* Obtain a read lock on @rw_lock. If another thread currently holds
* the write lock on @rw_lock, the current thread will block. If another thread
* does not hold the write lock, but is waiting for it, it is implementation
* defined whether the reader or writer will block. Read locks can be taken
* recursively.
*
* It is implementation-defined how many threads are allowed to
* hold read locks on the same lock simultaneously. If the limit is hit,
* or if a deadlock is detected, a critical warning will be emitted.
*
* Since: 2.32
*/
void
g_rw_lock_reader_lock (GRWLock *rw_lock)
{
int retval = pthread_rwlock_rdlock (g_rw_lock_get_impl (rw_lock));
if (retval != 0)
g_critical ("Failed to get RW lock %p: %s", rw_lock, g_strerror (retval));
}
/**
* g_rw_lock_reader_trylock:
* @rw_lock: a #GRWLock
*
* Tries to obtain a read lock on @rw_lock and returns %TRUE if
* the read lock was successfully obtained. Otherwise it
* returns %FALSE.
*
* Returns: %TRUE if @rw_lock could be locked
*
* Since: 2.32
*/
gboolean
g_rw_lock_reader_trylock (GRWLock *rw_lock)
{
if (pthread_rwlock_tryrdlock (g_rw_lock_get_impl (rw_lock)) != 0)
return FALSE;
return TRUE;
}
/**
* g_rw_lock_reader_unlock:
* @rw_lock: a #GRWLock
*
* Release a read lock on @rw_lock.
*
* Calling g_rw_lock_reader_unlock() on a lock that is not held
* by the current thread leads to undefined behaviour.
*
* Since: 2.32
*/
void
g_rw_lock_reader_unlock (GRWLock *rw_lock)
{
pthread_rwlock_unlock (g_rw_lock_get_impl (rw_lock));
}
/* {{{1 GCond */
#if !defined(USE_NATIVE_MUTEX)
static pthread_cond_t *
g_cond_impl_new (void)
{
pthread_condattr_t attr;
pthread_cond_t *cond;
gint status;
pthread_condattr_init (&attr);
#ifdef HAVE_PTHREAD_COND_TIMEDWAIT_RELATIVE_NP
#elif defined (HAVE_PTHREAD_CONDATTR_SETCLOCK) && defined (CLOCK_MONOTONIC)
if G_UNLIKELY ((status = pthread_condattr_setclock (&attr, CLOCK_MONOTONIC)) != 0)
g_thread_abort (status, "pthread_condattr_setclock");
#else
#error Cannot support GCond on your platform.
#endif
cond = malloc (sizeof (pthread_cond_t));
if G_UNLIKELY (cond == NULL)
g_thread_abort (errno, "malloc");
if G_UNLIKELY ((status = pthread_cond_init (cond, &attr)) != 0)
g_thread_abort (status, "pthread_cond_init");
pthread_condattr_destroy (&attr);
return cond;
}
static void
g_cond_impl_free (pthread_cond_t *cond)
{
pthread_cond_destroy (cond);
free (cond);
}
static inline pthread_cond_t *
g_cond_get_impl (GCond *cond)
{
pthread_cond_t *impl = g_atomic_pointer_get (&cond->p);
if G_UNLIKELY (impl == NULL)
{
impl = g_cond_impl_new ();
if (!g_atomic_pointer_compare_and_exchange (&cond->p, NULL, impl))
g_cond_impl_free (impl);
impl = cond->p;
}
return impl;
}
/**
* g_cond_init:
* @cond: an uninitialized #GCond
*
* Initialises a #GCond so that it can be used.
*
* This function is useful to initialise a #GCond that has been
* allocated as part of a larger structure. It is not necessary to
* initialise a #GCond that has been statically allocated.
*
* To undo the effect of g_cond_init() when a #GCond is no longer
* needed, use g_cond_clear().
*
* Calling g_cond_init() on an already-initialised #GCond leads
* to undefined behaviour.
*
* Since: 2.32
*/
void
g_cond_init (GCond *cond)
{
cond->p = g_cond_impl_new ();
}
/**
* g_cond_clear:
* @cond: an initialised #GCond
*
* Frees the resources allocated to a #GCond with g_cond_init().
*
* This function should not be used with a #GCond that has been
* statically allocated.
*
* Calling g_cond_clear() for a #GCond on which threads are
* blocking leads to undefined behaviour.
*
* Since: 2.32
*/
void
g_cond_clear (GCond *cond)
{
g_cond_impl_free (cond->p);
}
/**
* g_cond_wait:
* @cond: a #GCond
* @mutex: a #GMutex that is currently locked
*
* Atomically releases @mutex and waits until @cond is signalled.
* When this function returns, @mutex is locked again and owned by the
* calling thread.
*
* When using condition variables, it is possible that a spurious wakeup
* may occur (ie: g_cond_wait() returns even though g_cond_signal() was
* not called). It's also possible that a stolen wakeup may occur.
* This is when g_cond_signal() is called, but another thread acquires
* @mutex before this thread and modifies the state of the program in
* such a way that when g_cond_wait() is able to return, the expected
* condition is no longer met.
*
* For this reason, g_cond_wait() must always be used in a loop. See
* the documentation for #GCond for a complete example.
**/
void
g_cond_wait (GCond *cond,
GMutex *mutex)
{
gint status;
if G_UNLIKELY ((status = pthread_cond_wait (g_cond_get_impl (cond), g_mutex_get_impl (mutex))) != 0)
g_thread_abort (status, "pthread_cond_wait");
}
/**
* g_cond_signal:
* @cond: a #GCond
*
* If threads are waiting for @cond, at least one of them is unblocked.
* If no threads are waiting for @cond, this function has no effect.
* It is good practice to hold the same lock as the waiting thread
* while calling this function, though not required.
*/
void
g_cond_signal (GCond *cond)
{
gint status;
if G_UNLIKELY ((status = pthread_cond_signal (g_cond_get_impl (cond))) != 0)
g_thread_abort (status, "pthread_cond_signal");
}
/**
* g_cond_broadcast:
* @cond: a #GCond
*
* If threads are waiting for @cond, all of them are unblocked.
* If no threads are waiting for @cond, this function has no effect.
* It is good practice to lock the same mutex as the waiting threads
* while calling this function, though not required.
*/
void
g_cond_broadcast (GCond *cond)
{
gint status;
if G_UNLIKELY ((status = pthread_cond_broadcast (g_cond_get_impl (cond))) != 0)
g_thread_abort (status, "pthread_cond_broadcast");
}
/**
* g_cond_wait_until:
* @cond: a #GCond
* @mutex: a #GMutex that is currently locked
* @end_time: the monotonic time to wait until
*
* Waits until either @cond is signalled or @end_time has passed.
*
* As with g_cond_wait() it is possible that a spurious or stolen wakeup
* could occur. For that reason, waiting on a condition variable should
* always be in a loop, based on an explicitly-checked predicate.
*
* %TRUE is returned if the condition variable was signalled (or in the
* case of a spurious wakeup). %FALSE is returned if @end_time has
* passed.
*
* The following code shows how to correctly perform a timed wait on a
* condition variable (extending the example presented in the
* documentation for #GCond):
*
* |[<!-- language="C" -->
* gpointer
* pop_data_timed (void)
* {
* gint64 end_time;
* gpointer data;
*
* g_mutex_lock (&data_mutex);
*
* end_time = g_get_monotonic_time () + 5 * G_TIME_SPAN_SECOND;
* while (!current_data)
* if (!g_cond_wait_until (&data_cond, &data_mutex, end_time))
* {
* // timeout has passed.
* g_mutex_unlock (&data_mutex);
* return NULL;
* }
*
* // there is data for us
* data = current_data;
* current_data = NULL;
*
* g_mutex_unlock (&data_mutex);
*
* return data;
* }
* ]|
*
* Notice that the end time is calculated once, before entering the
* loop and reused. This is the motivation behind the use of absolute
* time on this API -- if a relative time of 5 seconds were passed
* directly to the call and a spurious wakeup occurred, the program would
* have to start over waiting again (which would lead to a total wait
* time of more than 5 seconds).
*
* Returns: %TRUE on a signal, %FALSE on a timeout
* Since: 2.32
**/
gboolean
g_cond_wait_until (GCond *cond,
GMutex *mutex,
gint64 end_time)
{
struct timespec ts;
gint status;
#ifdef HAVE_PTHREAD_COND_TIMEDWAIT_RELATIVE_NP
/* end_time is given relative to the monotonic clock as returned by
* g_get_monotonic_time().
*
* Since this pthreads wants the relative time, convert it back again.
*/
{
gint64 now = g_get_monotonic_time ();
gint64 relative;
if (end_time <= now)
return FALSE;
relative = end_time - now;
ts.tv_sec = relative / 1000000;
ts.tv_nsec = (relative % 1000000) * 1000;
if ((status = pthread_cond_timedwait_relative_np (g_cond_get_impl (cond), g_mutex_get_impl (mutex), &ts)) == 0)
return TRUE;
}
#elif defined (HAVE_PTHREAD_CONDATTR_SETCLOCK) && defined (CLOCK_MONOTONIC)
/* This is the exact check we used during init to set the clock to
* monotonic, so if we're in this branch, timedwait() will already be
* expecting a monotonic clock.
*/
{
ts.tv_sec = end_time / 1000000;
ts.tv_nsec = (end_time % 1000000) * 1000;
if ((status = pthread_cond_timedwait (g_cond_get_impl (cond), g_mutex_get_impl (mutex), &ts)) == 0)
return TRUE;
}
#else
#error Cannot support GCond on your platform.
#endif
if G_UNLIKELY (status != ETIMEDOUT)
g_thread_abort (status, "pthread_cond_timedwait");
return FALSE;
}
#endif /* defined(USE_NATIVE_MUTEX) */
/* {{{1 GPrivate */
/**
* GPrivate:
*
* The #GPrivate struct is an opaque data structure to represent a
* thread-local data key. It is approximately equivalent to the
* pthread_setspecific()/pthread_getspecific() APIs on POSIX and to
* TlsSetValue()/TlsGetValue() on Windows.
*
* If you don't already know why you might want this functionality,
* then you probably don't need it.
*
* #GPrivate is a very limited resource (as far as 128 per program,
* shared between all libraries). It is also not possible to destroy a
* #GPrivate after it has been used. As such, it is only ever acceptable
* to use #GPrivate in static scope, and even then sparingly so.
*
* See G_PRIVATE_INIT() for a couple of examples.
*
* The #GPrivate structure should be considered opaque. It should only
* be accessed via the g_private_ functions.
*/
/**
* G_PRIVATE_INIT:
* @notify: a #GDestroyNotify
*
* A macro to assist with the static initialisation of a #GPrivate.
*
* This macro is useful for the case that a #GDestroyNotify function
* should be associated with the key. This is needed when the key will be
* used to point at memory that should be deallocated when the thread
* exits.
*
* Additionally, the #GDestroyNotify will also be called on the previous
* value stored in the key when g_private_replace() is used.
*
* If no #GDestroyNotify is needed, then use of this macro is not
* required -- if the #GPrivate is declared in static scope then it will
* be properly initialised by default (ie: to all zeros). See the
* examples below.
*
* |[<!-- language="C" -->
* static GPrivate name_key = G_PRIVATE_INIT (g_free);
*
* // return value should not be freed
* const gchar *
* get_local_name (void)
* {
* return g_private_get (&name_key);
* }
*
* void
* set_local_name (const gchar *name)
* {
* g_private_replace (&name_key, g_strdup (name));
* }
*
*
* static GPrivate count_key; // no free function
*
* gint
* get_local_count (void)
* {
* return GPOINTER_TO_INT (g_private_get (&count_key));
* }
*
* void
* set_local_count (gint count)
* {
* g_private_set (&count_key, GINT_TO_POINTER (count));
* }
* ]|
*
* Since: 2.32
**/
static pthread_key_t *
g_private_impl_new (GDestroyNotify notify)
{
pthread_key_t *key;
gint status;
key = malloc (sizeof (pthread_key_t));
if G_UNLIKELY (key == NULL)
g_thread_abort (errno, "malloc");
status = pthread_key_create (key, notify);
if G_UNLIKELY (status != 0)
g_thread_abort (status, "pthread_key_create");
return key;
}
static void
g_private_impl_free (pthread_key_t *key)
{
gint status;
status = pthread_key_delete (*key);
if G_UNLIKELY (status != 0)
g_thread_abort (status, "pthread_key_delete");
free (key);
}
static inline pthread_key_t *
g_private_get_impl (GPrivate *key)
{
pthread_key_t *impl = g_atomic_pointer_get (&key->p);
if G_UNLIKELY (impl == NULL)
{
impl = g_private_impl_new (key->notify);
if (!g_atomic_pointer_compare_and_exchange (&key->p, NULL, impl))
{
g_private_impl_free (impl);
impl = key->p;
}
}
return impl;
}
/**
* g_private_get:
* @key: a #GPrivate
*
* Returns the current value of the thread local variable @key.
*
* If the value has not yet been set in this thread, %NULL is returned.
* Values are never copied between threads (when a new thread is
* created, for example).
*
* Returns: the thread-local value
*/
gpointer
g_private_get (GPrivate *key)
{
/* quote POSIX: No errors are returned from pthread_getspecific(). */
return pthread_getspecific (*g_private_get_impl (key));
}
/**
* g_private_set:
* @key: a #GPrivate
* @value: the new value
*
* Sets the thread local variable @key to have the value @value in the
* current thread.
*
* This function differs from g_private_replace() in the following way:
* the #GDestroyNotify for @key is not called on the old value.
*/
void
g_private_set (GPrivate *key,
gpointer value)
{
gint status;
if G_UNLIKELY ((status = pthread_setspecific (*g_private_get_impl (key), value)) != 0)
g_thread_abort (status, "pthread_setspecific");
}
/**
* g_private_replace:
* @key: a #GPrivate
* @value: the new value
*
* Sets the thread local variable @key to have the value @value in the
* current thread.
*
* This function differs from g_private_set() in the following way: if
* the previous value was non-%NULL then the #GDestroyNotify handler for
* @key is run on it.
*
* Since: 2.32
**/
void
g_private_replace (GPrivate *key,
gpointer value)
{
pthread_key_t *impl = g_private_get_impl (key);
gpointer old;
gint status;
old = pthread_getspecific (*impl);
if (old && key->notify)
key->notify (old);
if G_UNLIKELY ((status = pthread_setspecific (*impl, value)) != 0)
g_thread_abort (status, "pthread_setspecific");
}
/* {{{1 GThread */
#define posix_check_err(err, name) G_STMT_START{ \
int error = (err); \
if (error) \
g_error ("file %s: line %d (%s): error '%s' during '%s'", \
__FILE__, __LINE__, G_STRFUNC, \
g_strerror (error), name); \
}G_STMT_END
#define posix_check_cmd(cmd) posix_check_err (cmd, #cmd)
typedef struct
{
GRealThread thread;
pthread_t system_thread;
gboolean joined;
GMutex lock;
void *(*proxy) (void *);
/* Must be statically allocated and valid forever */
const GThreadSchedulerSettings *scheduler_settings;
} GThreadPosix;
void
g_system_thread_free (GRealThread *thread)
{
GThreadPosix *pt = (GThreadPosix *) thread;
if (!pt->joined)
pthread_detach (pt->system_thread);
g_mutex_clear (&pt->lock);
g_slice_free (GThreadPosix, pt);
}
gboolean
g_system_thread_get_scheduler_settings (GThreadSchedulerSettings *scheduler_settings)
{
/* FIXME: Implement the same for macOS and the BSDs so it doesn't go through
* the fallback code using an additional thread. */
#if defined(HAVE_SYS_SCHED_GETATTR)
pid_t tid;
int res;
/* FIXME: The struct definition does not seem to be possible to pull in
* via any of the normal system headers and it's only declared in the
* kernel headers. That's why we hardcode 56 here right now. */
guint size = 56; /* Size as of Linux 5.3.9 */
guint flags = 0;
tid = (pid_t) syscall (SYS_gettid);
scheduler_settings->attr = g_malloc0 (size);
do
{
int errsv;
res = syscall (SYS_sched_getattr, tid, scheduler_settings->attr, size, flags);
errsv = errno;
if (res == -1)
{
if (errsv == EAGAIN)
{
continue;
}
else if (errsv == E2BIG)
{
g_assert (size < G_MAXINT);
size *= 2;
scheduler_settings->attr = g_realloc (scheduler_settings->attr, size);
/* Needs to be zero-initialized */
memset (scheduler_settings->attr, 0, size);
}
else
{
g_debug ("Failed to get thread scheduler attributes: %s", g_strerror (errsv));
g_free (scheduler_settings->attr);
return FALSE;
}
}
}
while (res == -1);
/* Try setting them on the current thread to see if any system policies are
* in place that would disallow doing so */
res = syscall (SYS_sched_setattr, tid, scheduler_settings->attr, flags);
if (res == -1)
{
int errsv = errno;
g_debug ("Failed to set thread scheduler attributes: %s", g_strerror (errsv));
g_free (scheduler_settings->attr);
return FALSE;
}
return TRUE;
#else
return FALSE;
#endif
}
#if defined(HAVE_SYS_SCHED_GETATTR)
static void *
linux_pthread_proxy (void *data)
{
GThreadPosix *thread = data;
static gboolean printed_scheduler_warning = FALSE; /* (atomic) */
/* Set scheduler settings first if requested */
if (thread->scheduler_settings)
{
pid_t tid = 0;
guint flags = 0;
int res;
int errsv;
tid = (pid_t) syscall (SYS_gettid);
res = syscall (SYS_sched_setattr, tid, thread->scheduler_settings->attr, flags);
errsv = errno;
if (res == -1 && g_atomic_int_compare_and_exchange (&printed_scheduler_warning, FALSE, TRUE))
g_critical ("Failed to set scheduler settings: %s", g_strerror (errsv));
else if (res == -1)
g_debug ("Failed to set scheduler settings: %s", g_strerror (errsv));
printed_scheduler_warning = TRUE;
}
return thread->proxy (data);
}
#endif
GRealThread *
g_system_thread_new (GThreadFunc proxy,
gulong stack_size,
const GThreadSchedulerSettings *scheduler_settings,
const char *name,
GThreadFunc func,
gpointer data,
GError **error)
{
GThreadPosix *thread;
GRealThread *base_thread;
pthread_attr_t attr;
gint ret;
thread = g_slice_new0 (GThreadPosix);
base_thread = (GRealThread*)thread;
base_thread->ref_count = 2;
base_thread->ours = TRUE;
base_thread->thread.joinable = TRUE;
base_thread->thread.func = func;
base_thread->thread.data = data;
base_thread->name = g_strdup (name);
thread->scheduler_settings = scheduler_settings;
thread->proxy = proxy;
posix_check_cmd (pthread_attr_init (&attr));
#ifdef HAVE_PTHREAD_ATTR_SETSTACKSIZE
if (stack_size)
{
#ifdef _SC_THREAD_STACK_MIN
long min_stack_size = sysconf (_SC_THREAD_STACK_MIN);
if (min_stack_size >= 0)
stack_size = MAX ((gulong) min_stack_size, stack_size);
#endif /* _SC_THREAD_STACK_MIN */
/* No error check here, because some systems can't do it and
* we simply don't want threads to fail because of that. */
pthread_attr_setstacksize (&attr, stack_size);
}
#endif /* HAVE_PTHREAD_ATTR_SETSTACKSIZE */
#ifdef HAVE_PTHREAD_ATTR_SETINHERITSCHED
if (!scheduler_settings)
{
/* While this is the default, better be explicit about it */
pthread_attr_setinheritsched (&attr, PTHREAD_INHERIT_SCHED);
}
#endif /* HAVE_PTHREAD_ATTR_SETINHERITSCHED */
#if defined(HAVE_SYS_SCHED_GETATTR)
ret = pthread_create (&thread->system_thread, &attr, linux_pthread_proxy, thread);
#else
ret = pthread_create (&thread->system_thread, &attr, (void* (*)(void*))proxy, thread);
#endif
posix_check_cmd (pthread_attr_destroy (&attr));
if (ret == EAGAIN)
{
g_set_error (error, G_THREAD_ERROR, G_THREAD_ERROR_AGAIN,
"Error creating thread: %s", g_strerror (ret));
g_slice_free (GThreadPosix, thread);
return NULL;
}
posix_check_err (ret, "pthread_create");
g_mutex_init (&thread->lock);
return (GRealThread *) thread;
}
/**
* g_thread_yield:
*
* Causes the calling thread to voluntarily relinquish the CPU, so
* that other threads can run.
*
* This function is often used as a method to make busy wait less evil.
*/
void
g_thread_yield (void)
{
sched_yield ();
}
void
g_system_thread_wait (GRealThread *thread)
{
GThreadPosix *pt = (GThreadPosix *) thread;
g_mutex_lock (&pt->lock);
if (!pt->joined)
{
posix_check_cmd (pthread_join (pt->system_thread, NULL));
pt->joined = TRUE;
}
g_mutex_unlock (&pt->lock);
}
void
g_system_thread_exit (void)
{
pthread_exit (NULL);
}
void
g_system_thread_set_name (const gchar *name)
{
#if defined(HAVE_PTHREAD_SETNAME_NP_WITHOUT_TID)
pthread_setname_np (name); /* on OS X and iOS */
#elif defined(HAVE_PTHREAD_SETNAME_NP_WITH_TID)
pthread_setname_np (pthread_self (), name); /* on Linux and Solaris */
#elif defined(HAVE_PTHREAD_SETNAME_NP_WITH_TID_AND_ARG)
pthread_setname_np (pthread_self (), "%s", (gchar *) name); /* on NetBSD */
#elif defined(HAVE_PTHREAD_SET_NAME_NP)
pthread_set_name_np (pthread_self (), name); /* on FreeBSD, DragonFlyBSD, OpenBSD */
#endif
}
/* {{{1 GMutex and GCond futex implementation */
#if defined(USE_NATIVE_MUTEX)
#include <linux/futex.h>
#include <sys/syscall.h>
#ifndef FUTEX_WAIT_PRIVATE
#define FUTEX_WAIT_PRIVATE FUTEX_WAIT
#define FUTEX_WAKE_PRIVATE FUTEX_WAKE
#endif
/* We should expand the set of operations available in gatomic once we
* have better C11 support in GCC in common distributions (ie: 4.9).
*
* Before then, let's define a couple of useful things for our own
* purposes...
*/
#define exchange_acquire(ptr, new) \
__atomic_exchange_4((ptr), (new), __ATOMIC_ACQUIRE)
#define compare_exchange_acquire(ptr, old, new) \
__atomic_compare_exchange_4((ptr), (old), (new), 0, __ATOMIC_ACQUIRE, __ATOMIC_RELAXED)
#define exchange_release(ptr, new) \
__atomic_exchange_4((ptr), (new), __ATOMIC_RELEASE)
#define store_release(ptr, new) \
__atomic_store_4((ptr), (new), __ATOMIC_RELEASE)
/* Our strategy for the mutex is pretty simple:
*
* 0: not in use
*
* 1: acquired by one thread only, no contention
*
* > 1: contended
*
*
* As such, attempting to acquire the lock should involve an increment.
* If we find that the previous value was 0 then we can return
* immediately.
*
* On unlock, we always store 0 to indicate that the lock is available.
* If the value there was 1 before then we didn't have contention and
* can return immediately. If the value was something other than 1 then
* we have the contended case and need to wake a waiter.
*
* If it was not 0 then there is another thread holding it and we must
* wait. We must always ensure that we mark a value >1 while we are
* waiting in order to instruct the holder to do a wake operation on
* unlock.
*/
void
g_mutex_init (GMutex *mutex)
{
mutex->i[0] = 0;
}
void
g_mutex_clear (GMutex *mutex)
{
if G_UNLIKELY (mutex->i[0] != 0)
{
fprintf (stderr, "g_mutex_clear() called on uninitialised or locked mutex\n");
g_abort ();
}
}
static void __attribute__((noinline))
g_mutex_lock_slowpath (GMutex *mutex)
{
/* Set to 2 to indicate contention. If it was zero before then we
* just acquired the lock.
*
* Otherwise, sleep for as long as the 2 remains...
*/
while (exchange_acquire (&mutex->i[0], 2) != 0)
syscall (__NR_futex, &mutex->i[0], (gsize) FUTEX_WAIT_PRIVATE, (gsize) 2, NULL);
}
static void __attribute__((noinline))
g_mutex_unlock_slowpath (GMutex *mutex,
guint prev)
{
/* We seem to get better code for the uncontended case by splitting
* this out...
*/
if G_UNLIKELY (prev == 0)
{
fprintf (stderr, "Attempt to unlock mutex that was not locked\n");
g_abort ();
}
syscall (__NR_futex, &mutex->i[0], (gsize) FUTEX_WAKE_PRIVATE, (gsize) 1, NULL);
}
void
g_mutex_lock (GMutex *mutex)
{
/* 0 -> 1 and we're done. Anything else, and we need to wait... */
if G_UNLIKELY (g_atomic_int_add (&mutex->i[0], 1) != 0)
g_mutex_lock_slowpath (mutex);
}
void
g_mutex_unlock (GMutex *mutex)
{
guint prev;
prev = exchange_release (&mutex->i[0], 0);
/* 1-> 0 and we're done. Anything else and we need to signal... */
if G_UNLIKELY (prev != 1)
g_mutex_unlock_slowpath (mutex, prev);
}
gboolean
g_mutex_trylock (GMutex *mutex)
{
guint zero = 0;
/* We don't want to touch the value at all unless we can move it from
* exactly 0 to 1.
*/
return compare_exchange_acquire (&mutex->i[0], &zero, 1);
}
/* Condition variables are implemented in a rather simple way as well.
* In many ways, futex() as an abstraction is even more ideally suited
* to condition variables than it is to mutexes.
*
* We store a generation counter. We sample it with the lock held and
* unlock before sleeping on the futex.
*
* Signalling simply involves increasing the counter and making the
* appropriate futex call.
*
* The only thing that is the slightest bit complicated is timed waits
* because we must convert our absolute time to relative.
*/
void
g_cond_init (GCond *cond)
{
cond->i[0] = 0;
}
void
g_cond_clear (GCond *cond)
{
}
void
g_cond_wait (GCond *cond,
GMutex *mutex)
{
guint sampled = (guint) g_atomic_int_get (&cond->i[0]);
g_mutex_unlock (mutex);
syscall (__NR_futex, &cond->i[0], (gsize) FUTEX_WAIT_PRIVATE, (gsize) sampled, NULL);
g_mutex_lock (mutex);
}
void
g_cond_signal (GCond *cond)
{
g_atomic_int_inc (&cond->i[0]);
syscall (__NR_futex, &cond->i[0], (gsize) FUTEX_WAKE_PRIVATE, (gsize) 1, NULL);
}
void
g_cond_broadcast (GCond *cond)
{
g_atomic_int_inc (&cond->i[0]);
syscall (__NR_futex, &cond->i[0], (gsize) FUTEX_WAKE_PRIVATE, (gsize) INT_MAX, NULL);
}
gboolean
g_cond_wait_until (GCond *cond,
GMutex *mutex,
gint64 end_time)
{
struct timespec now;
struct timespec span;
guint sampled;
int res;
gboolean success;
if (end_time < 0)
return FALSE;
clock_gettime (CLOCK_MONOTONIC, &now);
span.tv_sec = (end_time / 1000000) - now.tv_sec;
span.tv_nsec = ((end_time % 1000000) * 1000) - now.tv_nsec;
if (span.tv_nsec < 0)
{
span.tv_nsec += 1000000000;
span.tv_sec--;
}
if (span.tv_sec < 0)
return FALSE;
sampled = cond->i[0];
g_mutex_unlock (mutex);
res = syscall (__NR_futex, &cond->i[0], (gsize) FUTEX_WAIT_PRIVATE, (gsize) sampled, &span);
success = (res < 0 && errno == ETIMEDOUT) ? FALSE : TRUE;
g_mutex_lock (mutex);
return success;
}
#endif
/* {{{1 Epilogue */
/* vim:set foldmethod=marker: */