mutex source code [include/c++/11/mutex]

1	// <mutex> -- C++ --
2
3	// Copyright (C) 2003-2021 Free Software Foundation, Inc.
4	//
5	// This file is part of the GNU ISO C++ Library. This library is free
6	// software; you can redistribute it and/or modify it under the
7	// terms of the GNU General Public License as published by the
8	// Free Software Foundation; either version 3, or (at your option)
9	// any later version.
10
11	// This library is distributed in the hope that it will be useful,
12	// but WITHOUT ANY WARRANTY; without even the implied warranty of
13	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	// GNU General Public License for more details.
15
16	// Under Section 7 of GPL version 3, you are granted additional
17	// permissions described in the GCC Runtime Library Exception, version
18	// 3.1, as published by the Free Software Foundation.
19
20	// You should have received a copy of the GNU General Public License and
21	// a copy of the GCC Runtime Library Exception along with this program;
22	// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
23	// <http://www.gnu.org/licenses/>.
24
25	/* @file include/mutex*
26	* This is a Standard C++ Library header.
27	*/
28
29	#ifndef _GLIBCXX_MUTEX
30	#define _GLIBCXX_MUTEX 1
31
32	#pragma GCC system_header
33
34	#if __cplusplus < 201103L
35	# include <bits/c++0x_warning.h>
36	#else
37
38	#include <tuple>
39	#include <chrono>
40	#include <exception>
41	#include <type_traits>
42	#include <system_error>
43	#include <bits/std_mutex.h>
44	#include <bits/unique_lock.h>
45	#if ! _GTHREAD_USE_MUTEX_TIMEDLOCK
46	# include <condition_variable>
47	# include <thread>
48	#endif
49	#include <ext/atomicity.h> // __gnu_cxx::__is_single_threaded
50
51	#if defined _GLIBCXX_HAS_GTHREADS && ! defined _GLIBCXX_HAVE_TLS
52	# include <bits/std_function.h> // std::function
53	#endif
54
55	namespace std _GLIBCXX_VISIBILITY(default)
56	{
57	_GLIBCXX_BEGIN_NAMESPACE_VERSION
58
59	/**
60	* @addtogroup mutexes
61	* @{
62	*/
63
64	#ifdef _GLIBCXX_HAS_GTHREADS
65
66	// Common base class for std::recursive_mutex and std::recursive_timed_mutex
67	class __recursive_mutex_base
68	{
69	protected:
70	typedef __gthread_recursive_mutex_t __native_type;
71
72	__recursive_mutex_base(const __recursive_mutex_base&) = delete;
73	__recursive_mutex_base& operator=(const __recursive_mutex_base&) = delete;
74
75	#ifdef __GTHREAD_RECURSIVE_MUTEX_INIT
76	__native_type _M_mutex = __GTHREAD_RECURSIVE_MUTEX_INIT;
77
78	__recursive_mutex_base() = default;
79	#else
80	__native_type _M_mutex;
81
82	__recursive_mutex_base()
83	{
84	// XXX EAGAIN, ENOMEM, EPERM, EBUSY(may), EINVAL(may)
85	__GTHREAD_RECURSIVE_MUTEX_INIT_FUNCTION(&_M_mutex);
86	}
87
88	~__recursive_mutex_base()
89	{ __gthread_recursive_mutex_destroy(&_M_mutex); }
90	#endif
91	};
92
93	/// The standard recursive mutex type.
94	class recursive_mutex : private __recursive_mutex_base
95	{
96	public:
97	typedef __native_type* native_handle_type;
98
99	recursive_mutex() = default;
100	~recursive_mutex() = default;
101
102	recursive_mutex(const recursive_mutex&) = delete;
103	recursive_mutex& operator=(const recursive_mutex&) = delete;
104
105	void
106	lock()
107	{
108	int __e = __gthread_recursive_mutex_lock(mutex: &_M_mutex);
109
110	// EINVAL, EAGAIN, EBUSY, EINVAL, EDEADLK(may)
111	if (__e)
112	__throw_system_error(__e);
113	}
114
115	bool
116	try_lock() noexcept
117	{
118	// XXX EINVAL, EAGAIN, EBUSY
119	return !__gthread_recursive_mutex_trylock(mutex: &_M_mutex);
120	}
121
122	void
123	unlock()
124	{
125	// XXX EINVAL, EAGAIN, EBUSY
126	__gthread_recursive_mutex_unlock(mutex: &_M_mutex);
127	}
128
129	native_handle_type
130	native_handle() noexcept
131	{ return &_M_mutex; }
132	};
133
134	#if _GTHREAD_USE_MUTEX_TIMEDLOCK
135	template<typename _Derived>
136	class __timed_mutex_impl
137	{
138	protected:
139	template<typename _Rep, typename _Period>
140	bool
141	_M_try_lock_for(const chrono::duration<_Rep, _Period>& __rtime)
142	{
143	#if _GLIBCXX_USE_PTHREAD_MUTEX_CLOCKLOCK
144	using __clock = chrono::steady_clock;
145	#else
146	using __clock = chrono::system_clock;
147	#endif
148
149	auto __rt = chrono::duration_cast<__clock::duration>(__rtime);
150	if (ratio_greater<__clock::period, _Period>())
151	++__rt;
152	return _M_try_lock_until(__clock::now() + __rt);
153	}
154
155	template<typename _Duration>
156	bool
157	_M_try_lock_until(const chrono::time_point<chrono::system_clock,
158	_Duration>& __atime)
159	{
160	auto __s = chrono::time_point_cast<chrono::seconds>(__atime);
161	auto __ns = chrono::duration_cast<chrono::nanoseconds>(__atime - __s);
162
163	__gthread_time_t __ts = {
164	.tv_sec: static_cast<std::time_t>(__s.time_since_epoch().count()),
165	.tv_nsec: static_cast<long>(__ns.count())
166	};
167
168	return static_cast<_Derived>(this*)->_M_timedlock(__ts);
169	}
170
171	#ifdef _GLIBCXX_USE_PTHREAD_MUTEX_CLOCKLOCK
172	template<typename _Duration>
173	bool
174	_M_try_lock_until(const chrono::time_point<chrono::steady_clock,
175	_Duration>& __atime)
176	{
177	auto __s = chrono::time_point_cast<chrono::seconds>(__atime);
178	auto __ns = chrono::duration_cast<chrono::nanoseconds>(__atime - __s);
179
180	__gthread_time_t __ts = {
181	.tv_sec: static_cast<std::time_t>(__s.time_since_epoch().count()),
182	.tv_nsec: static_cast<long>(__ns.count())
183	};
184
185	return static_cast<_Derived>(this*)->_M_clocklock(CLOCK_MONOTONIC,
186	__ts);
187	}
188	#endif
189
190	template<typename _Clock, typename _Duration>
191	bool
192	_M_try_lock_until(const chrono::time_point<_Clock, _Duration>& __atime)
193	{
194	#if __cplusplus > 201703L
195	static_assert(chrono::is_clock_v<_Clock>);
196	#endif
197	// The user-supplied clock may not tick at the same rate as
198	// steady_clock, so we must loop in order to guarantee that
199	// the timeout has expired before returning false.
200	auto __now = _Clock::now();
201	do {
202	auto __rtime = __atime - __now;
203	if (_M_try_lock_for(__rtime))
204	return true;
205	__now = _Clock::now();
206	} while (__atime > __now);
207	return false;
208	}
209	};
210
211	/// The standard timed mutex type.
212	class timed_mutex
213	: private __mutex_base, public __timed_mutex_impl<timed_mutex>
214	{
215	public:
216	typedef __native_type* native_handle_type;
217
218	timed_mutex() = default;
219	~timed_mutex() = default;
220
221	timed_mutex(const timed_mutex&) = delete;
222	timed_mutex& operator=(const timed_mutex&) = delete;
223
224	void
225	lock()
226	{
227	int __e = __gthread_mutex_lock(mutex: &_M_mutex);
228
229	// EINVAL, EAGAIN, EBUSY, EINVAL, EDEADLK(may)
230	if (__e)
231	__throw_system_error(__e);
232	}
233
234	bool
235	try_lock() noexcept
236	{
237	// XXX EINVAL, EAGAIN, EBUSY
238	return !__gthread_mutex_trylock(mutex: &_M_mutex);
239	}
240
241	template <class _Rep, class _Period>
242	bool
243	try_lock_for(const chrono::duration<_Rep, _Period>& __rtime)
244	{ return _M_try_lock_for(__rtime); }
245
246	template <class _Clock, class _Duration>
247	bool
248	try_lock_until(const chrono::time_point<_Clock, _Duration>& __atime)
249	{ return _M_try_lock_until(__atime); }
250
251	void
252	unlock()
253	{
254	// XXX EINVAL, EAGAIN, EBUSY
255	__gthread_mutex_unlock(mutex: &_M_mutex);
256	}
257
258	native_handle_type
259	native_handle() noexcept
260	{ return &_M_mutex; }
261
262	private:
263	friend class __timed_mutex_impl<timed_mutex>;
264
265	bool
266	_M_timedlock(const __gthread_time_t& __ts)
267	{ return !__gthread_mutex_timedlock(mutex: &_M_mutex, abs_timeout: &__ts); }
268
269	#if _GLIBCXX_USE_PTHREAD_MUTEX_CLOCKLOCK
270	bool
271	_M_clocklock(clockid_t clockid, const __gthread_time_t& __ts)
272	{ return !pthread_mutex_clocklock(mutex: &_M_mutex, clockid: clockid, abstime: &__ts); }
273	#endif
274	};
275
276	/// recursive_timed_mutex
277	class recursive_timed_mutex
278	: private __recursive_mutex_base,
279	public __timed_mutex_impl<recursive_timed_mutex>
280	{
281	public:
282	typedef __native_type* native_handle_type;
283
284	recursive_timed_mutex() = default;
285	~recursive_timed_mutex() = default;
286
287	recursive_timed_mutex(const recursive_timed_mutex&) = delete;
288	recursive_timed_mutex& operator=(const recursive_timed_mutex&) = delete;
289
290	void
291	lock()
292	{
293	int __e = __gthread_recursive_mutex_lock(mutex: &_M_mutex);
294
295	// EINVAL, EAGAIN, EBUSY, EINVAL, EDEADLK(may)
296	if (__e)
297	__throw_system_error(__e);
298	}
299
300	bool
301	try_lock() noexcept
302	{
303	// XXX EINVAL, EAGAIN, EBUSY
304	return !__gthread_recursive_mutex_trylock(mutex: &_M_mutex);
305	}
306
307	template <class _Rep, class _Period>
308	bool
309	try_lock_for(const chrono::duration<_Rep, _Period>& __rtime)
310	{ return _M_try_lock_for(__rtime); }
311
312	template <class _Clock, class _Duration>
313	bool
314	try_lock_until(const chrono::time_point<_Clock, _Duration>& __atime)
315	{ return _M_try_lock_until(__atime); }
316
317	void
318	unlock()
319	{
320	// XXX EINVAL, EAGAIN, EBUSY
321	__gthread_recursive_mutex_unlock(mutex: &_M_mutex);
322	}
323
324	native_handle_type
325	native_handle() noexcept
326	{ return &_M_mutex; }
327
328	private:
329	friend class __timed_mutex_impl<recursive_timed_mutex>;
330
331	bool
332	_M_timedlock(const __gthread_time_t& __ts)
333	{ return !__gthread_recursive_mutex_timedlock(mutex: &_M_mutex, abs_timeout: &__ts); }
334
335	#ifdef _GLIBCXX_USE_PTHREAD_MUTEX_CLOCKLOCK
336	bool
337	_M_clocklock(clockid_t clockid, const __gthread_time_t& __ts)
338	{ return !pthread_mutex_clocklock(mutex: &_M_mutex, clockid: clockid, abstime: &__ts); }
339	#endif
340	};
341
342	#else // !_GTHREAD_USE_MUTEX_TIMEDLOCK
343
344	/// timed_mutex
345	class timed_mutex
346	{
347	mutex _M_mut;
348	condition_variable _M_cv;
349	bool _M_locked = false;
350
351	public:
352
353	timed_mutex() = default;
354	~timed_mutex() { __glibcxx_assert( !_M_locked ); }
355
356	timed_mutex(const timed_mutex&) = delete;
357	timed_mutex& operator=(const timed_mutex&) = delete;
358
359	void
360	lock()
361	{
362	unique_lock<mutex> __lk(_M_mut);
363	_M_cv.wait(__lk, [&]{ return !_M_locked; });
364	_M_locked = true;
365	}
366
367	bool
368	try_lock()
369	{
370	lock_guard<mutex> __lk(_M_mut);
371	if (_M_locked)
372	return false;
373	_M_locked = true;
374	return true;
375	}
376
377	template<typename _Rep, typename _Period>
378	bool
379	try_lock_for(const chrono::duration<_Rep, _Period>& __rtime)
380	{
381	unique_lock<mutex> __lk(_M_mut);
382	if (!_M_cv.wait_for(__lk, __rtime, [&]{ return !_M_locked; }))
383	return false;
384	_M_locked = true;
385	return true;
386	}
387
388	template<typename _Clock, typename _Duration>
389	bool
390	try_lock_until(const chrono::time_point<_Clock, _Duration>& __atime)
391	{
392	unique_lock<mutex> __lk(_M_mut);
393	if (!_M_cv.wait_until(__lk, __atime, [&]{ return !_M_locked; }))
394	return false;
395	_M_locked = true;
396	return true;
397	}
398
399	void
400	unlock()
401	{
402	lock_guard<mutex> __lk(_M_mut);
403	__glibcxx_assert( _M_locked );
404	_M_locked = false;
405	_M_cv.notify_one();
406	}
407	};
408
409	/// recursive_timed_mutex
410	class recursive_timed_mutex
411	{
412	mutex _M_mut;
413	condition_variable _M_cv;
414	thread::id _M_owner;
415	unsigned _M_count = `0`;
416
417	// Predicate type that tests whether the current thread can lock a mutex.
418	struct _Can_lock
419	{
420	// Returns true if the mutex is unlocked or is locked by _M_caller.
421	bool
422	operator()() const noexcept
423	{ return _M_mx->_M_count == `0` \|\| _M_mx->_M_owner == _M_caller; }
424
425	const recursive_timed_mutex* _M_mx;
426	thread::id _M_caller;
427	};
428
429	public:
430
431	recursive_timed_mutex() = default;
432	~recursive_timed_mutex() { __glibcxx_assert( _M_count == `0` ); }
433
434	recursive_timed_mutex(const recursive_timed_mutex&) = delete;
435	recursive_timed_mutex& operator=(const recursive_timed_mutex&) = delete;
436
437	void
438	lock()
439	{
440	auto __id = this_thread::get_id();
441	_Can_lock __can_lock{this, __id};
442	unique_lock<mutex> __lk(_M_mut);
443	_M_cv.wait(__lk, __can_lock);
444	if (_M_count == -`1u`)
445	__throw_system_error(EAGAIN); // [thread.timedmutex.recursive]/3
446	_M_owner = __id;
447	++_M_count;
448	}
449
450	bool
451	try_lock()
452	{
453	auto __id = this_thread::get_id();
454	_Can_lock __can_lock{this, __id};
455	lock_guard<mutex> __lk(_M_mut);
456	if (!__can_lock())
457	return false;
458	if (_M_count == -`1u`)
459	return false;
460	_M_owner = __id;
461	++_M_count;
462	return true;
463	}
464
465	template<typename _Rep, typename _Period>
466	bool
467	try_lock_for(const chrono::duration<_Rep, _Period>& __rtime)
468	{
469	auto __id = this_thread::get_id();
470	_Can_lock __can_lock{this, __id};
471	unique_lock<mutex> __lk(_M_mut);
472	if (!_M_cv.wait_for(__lk, __rtime, __can_lock))
473	return false;
474	if (_M_count == -`1u`)
475	return false;
476	_M_owner = __id;
477	++_M_count;
478	return true;
479	}
480
481	template<typename _Clock, typename _Duration>
482	bool
483	try_lock_until(const chrono::time_point<_Clock, _Duration>& __atime)
484	{
485	auto __id = this_thread::get_id();
486	_Can_lock __can_lock{this, __id};
487	unique_lock<mutex> __lk(_M_mut);
488	if (!_M_cv.wait_until(__lk, __atime, __can_lock))
489	return false;
490	if (_M_count == -`1u`)
491	return false;
492	_M_owner = __id;
493	++_M_count;
494	return true;
495	}
496
497	void
498	unlock()
499	{
500	lock_guard<mutex> __lk(_M_mut);
501	__glibcxx_assert( _M_owner == this_thread::get_id() );
502	__glibcxx_assert( _M_count > `0` );
503	if (--_M_count == `0`)
504	{
505	_M_owner = {};
506	_M_cv.notify_one();
507	}
508	}
509	};
510
511	#endif
512	#endif // _GLIBCXX_HAS_GTHREADS
513
514	/// @cond undocumented
515	template<typename _Lock>
516	inline unique_lock<_Lock>
517	__try_to_lock(_Lock& __l)
518	{ return unique_lock<_Lock>{__l, try_to_lock}; }
519
520	template<int _Idx, bool _Continue = true>
521	struct __try_lock_impl
522	{
523	template<typename... _Lock>
524	static void
525	__do_try_lock(tuple<_Lock&...>& __locks, int& __idx)
526	{
527	__idx = _Idx;
528	auto __lock = std::__try_to_lock(std::get<_Idx>(__locks));
529	if (__lock.owns_lock())
530	{
531	constexpr bool __cont = _Idx + `2` < sizeof...(_Lock);
532	using __try_locker = __try_lock_impl<_Idx + `1`, __cont>;
533	__try_locker::__do_try_lock(__locks, __idx);
534	if (__idx == -`1`)
535	__lock.release();
536	}
537	}
538	};
539
540	template<int _Idx>
541	struct __try_lock_impl<_Idx, false>
542	{
543	template<typename... _Lock>
544	static void
545	__do_try_lock(tuple<_Lock&...>& __locks, int& __idx)
546	{
547	__idx = _Idx;
548	auto __lock = std::__try_to_lock(std::get<_Idx>(__locks));
549	if (__lock.owns_lock())
550	{
551	__idx = -`1`;
552	__lock.release();
553	}
554	}
555	};
556	/// @endcond
557
558	/* @brief Generic try_lock.*
559	* @param __l1 Meets Lockable requirements (try_lock() may throw).
560	* @param __l2 Meets Lockable requirements (try_lock() may throw).
561	* @param __l3 Meets Lockable requirements (try_lock() may throw).
562	* @return Returns -1 if all try_lock() calls return true. Otherwise returns
563	* a 0-based index corresponding to the argument that returned false.
564	* @post Either all arguments are locked, or none will be.
565	*
566	* Sequentially calls try_lock() on each argument.
567	*/
568	template<typename _Lock1, typename _Lock2, typename... _Lock3>
569	int
570	try_lock(_Lock1& __l1, _Lock2& __l2, _Lock3&... __l3)
571	{
572	int __idx;
573	auto __locks = std::tie(__l1, __l2, __l3...);
574	__try_lock_impl<`0`>::__do_try_lock(__locks, __idx);
575	return __idx;
576	}
577
578	/* @brief Generic lock.*
579	* @param __l1 Meets Lockable requirements (try_lock() may throw).
580	* @param __l2 Meets Lockable requirements (try_lock() may throw).
581	* @param __l3 Meets Lockable requirements (try_lock() may throw).
582	* @throw An exception thrown by an argument's lock() or try_lock() member.
583	* @post All arguments are locked.
584	*
585	* All arguments are locked via a sequence of calls to lock(), try_lock()
586	* and unlock(). If the call exits via an exception any locks that were
587	* obtained will be released.
588	*/
589	template<typename _L1, typename _L2, typename... _L3>
590	void
591	lock(_L1& __l1, _L2& __l2, _L3&... __l3)
592	{
593	while (true)
594	{
595	using __try_locker = __try_lock_impl<`0`, sizeof...(_L3) != `0`>;
596	unique_lock<_L1> __first(__l1);
597	int __idx;
598	auto __locks = std::tie(__l2, __l3...);
599	__try_locker::__do_try_lock(__locks, __idx);
600	if (__idx == -`1`)
601	{
602	__first.release();
603	return;
604	}
605	}
606	}
607
608	#if __cplusplus >= 201703L
609	#define __cpp_lib_scoped_lock 201703
610	/* @brief A scoped lock type for multiple lockable objects.*
611	*
612	* A scoped_lock controls mutex ownership within a scope, releasing
613	* ownership in the destructor.
614	*/
615	template<typename... _MutexTypes>
616	class scoped_lock
617	{
618	public:
619	explicit scoped_lock(_MutexTypes&... __m) : _M_devices(std::tie(__m...))
620	{ std::lock(__m...); }
621
622	explicit scoped_lock(adopt_lock_t, _MutexTypes&... __m) noexcept
623	: _M_devices(std::tie(__m...))
624	{ } // calling thread owns mutex
625
626	~scoped_lock()
627	{ std::apply([](auto&... __m) { (__m.unlock(), ...); }, _M_devices); }
628
629	scoped_lock(const scoped_lock&) = delete;
630	scoped_lock& operator=(const scoped_lock&) = delete;
631
632	private:
633	tuple<_MutexTypes&...> _M_devices;
634	};
635
636	template<>
637	class scoped_lock<>
638	{
639	public:
640	explicit scoped_lock() = default;
641	explicit scoped_lock(adopt_lock_t) noexcept { }
642	~scoped_lock() = default;
643
644	scoped_lock(const scoped_lock&) = delete;
645	scoped_lock& operator=(const scoped_lock&) = delete;
646	};
647
648	template<typename _Mutex>
649	class scoped_lock<_Mutex>
650	{
651	public:
652	using mutex_type = _Mutex;
653
654	explicit scoped_lock(mutex_type& __m) : _M_device(__m)
655	{ _M_device.lock(); }
656
657	explicit scoped_lock(adopt_lock_t, mutex_type& __m) noexcept
658	: _M_device(__m)
659	{ } // calling thread owns mutex
660
661	~scoped_lock()
662	{ _M_device.unlock(); }
663
664	scoped_lock(const scoped_lock&) = delete;
665	scoped_lock& operator=(const scoped_lock&) = delete;
666
667	private:
668	mutex_type& _M_device;
669	};
670	#endif // C++17
671
672	#ifdef _GLIBCXX_HAS_GTHREADS
673	/// Flag type used by std::call_once
674	struct once_flag
675	{
676	constexpr once_flag() noexcept = default;
677
678	/// Deleted copy constructor
679	once_flag(const once_flag&) = delete;
680	/// Deleted assignment operator
681	once_flag& operator=(const once_flag&) = delete;
682
683	private:
684	// For gthreads targets a pthread_once_t is used with pthread_once, but
685	// for most targets this doesn't work correctly for exceptional executions.
686	__gthread_once_t _M_once = __GTHREAD_ONCE_INIT;
687
688	struct _Prepare_execution;
689
690	template<typename _Callable, typename... _Args>
691	friend void
692	call_once(once_flag& __once, _Callable&& __f, _Args&&... __args);
693	};
694
695	/// @cond undocumented
696	# ifdef _GLIBCXX_HAVE_TLS
697	// If TLS is available use thread-local state for the type-erased callable
698	// that is being run by std::call_once in the current thread.
699	extern __thread void* __once_callable;
700	extern __thread void (*__once_call)();
701
702	// RAII type to set up state for pthread_once call.
703	struct once_flag::_Prepare_execution
704	{
705	template<typename _Callable>
706	explicit
707	_Prepare_execution(_Callable& __c)
708	{
709	// Store address in thread-local pointer:
710	__once_callable = std::__addressof(__c);
711	// Trampoline function to invoke the closure via thread-local pointer:
712	__once_call = [] { (*static_cast<_Callable*>(__once_callable))(); };
713	}
714
715	~_Prepare_execution()
716	{
717	// PR libstdc++/82481
718	__once_callable = nullptr;
719	__once_call = nullptr;
720	}
721
722	_Prepare_execution(const _Prepare_execution&) = delete;
723	_Prepare_execution& operator=(const _Prepare_execution&) = delete;
724	};
725
726	# else
727	// Without TLS use a global std::mutex and store the callable in a
728	// global std::function.
729	extern function<void()> __once_functor;
730
731	extern void
732	__set_once_functor_lock_ptr(unique_lock<mutex>*);
733
734	extern mutex&
735	__get_once_mutex();
736
737	// RAII type to set up state for pthread_once call.
738	struct once_flag::_Prepare_execution
739	{
740	template<typename _Callable>
741	explicit
742	_Prepare_execution(_Callable& __c)
743	{
744	// Store the callable in the global std::function
745	__once_functor = __c;
746	__set_once_functor_lock_ptr(&_M_functor_lock);
747	}
748
749	~_Prepare_execution()
750	{
751	if (_M_functor_lock)
752	__set_once_functor_lock_ptr(nullptr);
753	}
754
755	private:
756	// XXX This deadlocks if used recursively (PR 97949)
757	unique_lock<mutex> _M_functor_lock{__get_once_mutex()};
758
759	_Prepare_execution(const _Prepare_execution&) = delete;
760	_Prepare_execution& operator=(const _Prepare_execution&) = delete;
761	};
762	# endif
763	/// @endcond
764
765	// This function is passed to pthread_once by std::call_once.
766	// It runs __once_call() or __once_functor().
767	extern "C" void __once_proxy(void);
768
769	/// Invoke a callable and synchronize with other calls using the same flag
770	template<typename _Callable, typename... _Args>
771	void
772	call_once(once_flag& __once, _Callable&& __f, _Args&&... __args)
773	{
774	// Closure type that runs the function
775	auto __callable = [&] {
776	std::__invoke(std::forward<_Callable>(__f),
777	std::forward<_Args>(__args)...);
778	};
779
780	once_flag::_Prepare_execution __exec(__callable);
781
782	// XXX pthread_once does not reset the flag if an exception is thrown.
783	if (int __e = __gthread_once(once: &__once._M_once, func: &__once_proxy))
784	__throw_system_error(__e);
785	}
786
787	#else // _GLIBCXX_HAS_GTHREADS
788
789	/// Flag type used by std::call_once
790	struct once_flag
791	{
792	constexpr once_flag() noexcept = default;
793
794	/// Deleted copy constructor
795	once_flag(const once_flag&) = delete;
796	/// Deleted assignment operator
797	once_flag& operator=(const once_flag&) = delete;
798
799	private:
800	// There are two different std::once_flag interfaces, abstracting four
801	// different implementations.
802	// The single-threaded interface uses the _M_activate() and _M_finish(bool)
803	// functions, which start and finish an active execution respectively.
804	// See [thread.once.callonce] in C++11 for the definition of
805	// active/passive/returning/exceptional executions.
806	enum _Bits : int { _Init = `0`, _Active = `1`, _Done = `2` };
807
808	int _M_once = _Bits::_Init;
809
810	// Check to see if all executions will be passive now.
811	bool
812	_M_passive() const noexcept;
813
814	// Attempts to begin an active execution.
815	bool _M_activate();
816
817	// Must be called to complete an active execution.
818	// The argument is true if the active execution was a returning execution,
819	// false if it was an exceptional execution.
820	void _M_finish(bool __returning) noexcept;
821
822	// RAII helper to call _M_finish.
823	struct _Active_execution
824	{
825	explicit _Active_execution(once_flag& __flag) : _M_flag(__flag) { }
826
827	~_Active_execution() { _M_flag._M_finish(_M_returning); }
828
829	_Active_execution(const _Active_execution&) = delete;
830	_Active_execution& operator=(const _Active_execution&) = delete;
831
832	once_flag& _M_flag;
833	bool _M_returning = false;
834	};
835
836	template<typename _Callable, typename... _Args>
837	friend void
838	call_once(once_flag& __once, _Callable&& __f, _Args&&... __args);
839	};
840
841	// Inline definitions of std::once_flag members for single-threaded targets.
842
843	inline bool
844	once_flag::_M_passive() const noexcept
845	{ return _M_once == _Bits::_Done; }
846
847	inline bool
848	once_flag::_M_activate()
849	{
850	if (_M_once == _Bits::_Init) [[__likely__]]
851	{
852	_M_once = _Bits::_Active;
853	return true;
854	}
855	else if (_M_passive()) // Caller should have checked this already.
856	return false;
857	else
858	__throw_system_error(EDEADLK);
859	}
860
861	inline void
862	once_flag::_M_finish(bool __returning) noexcept
863	{ _M_once = __returning ? _Bits::_Done : _Bits::_Init; }
864
865	/// Invoke a callable and synchronize with other calls using the same flag
866	template<typename _Callable, typename... _Args>
867	inline void
868	call_once(once_flag& __once, _Callable&& __f, _Args&&... __args)
869	{
870	if (__once._M_passive())
871	return;
872	else if (__once._M_activate())
873	{
874	once_flag::_Active_execution __exec(__once);
875
876	// _GLIBCXX_RESOLVE_LIB_DEFECTS
877	// 2442. call_once() shouldn't DECAY_COPY()
878	std::__invoke(std::forward<_Callable>(__f),
879	std::forward<_Args>(__args)...);
880
881	// __f(__args...) did not throw
882	__exec._M_returning = true;
883	}
884	}
885	#endif // _GLIBCXX_HAS_GTHREADS
886
887	/// @} group mutexes
888	_GLIBCXX_END_NAMESPACE_VERSION
889	} // namespace
890
891	#endif // C++11
892
893	#endif // _GLIBCXX_MUTEX
894

source code of include/c++/11/mutex