lowlevellock.h source code [glibc/sysdeps/nptl/lowlevellock.h]

1	/ Low-level lock implementation. Generic futex-based version.*
2	Copyright (C) 2005-2022 Free Software Foundation, Inc.
3	This file is part of the GNU C Library.
4
5	The GNU C Library is free software; you can redistribute it and/or
6	modify it under the terms of the GNU Lesser General Public
7	License as published by the Free Software Foundation; either
8	version 2.1 of the License, or (at your option) any later version.
9
10	The GNU C Library is distributed in the hope that it will be useful,
11	but WITHOUT ANY WARRANTY; without even the implied warranty of
12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13	Lesser General Public License for more details.
14
15	You should have received a copy of the GNU Lesser General Public
16	License along with the GNU C Library. If not, see
17	<https://www.gnu.org/licenses/>. /*
18
19	#ifndef _LOWLEVELLOCK_H
20	#define _LOWLEVELLOCK_H 1
21
22	#include <atomic.h>
23	#include <elision-conf.h>
24	#include <lowlevellock-futex.h>
25	#include <time.h>
26
27	/ Low-level locks use a combination of atomic operations (to acquire and*
28	release lock ownership) and futex operations (to block until the state
29	of a lock changes). A lock can be in one of three states:
30	0: not acquired,
31	1: acquired with no waiters; no other threads are blocked or about to block
32	for changes to the lock state,
33	>1: acquired, possibly with waiters; there may be other threads blocked or
34	about to block for changes to the lock state.
35
36	We expect that the common case is an uncontended lock, so we just need
37	to transition the lock between states 0 and 1; releasing the lock does
38	not need to wake any other blocked threads. If the lock is contended
39	and a thread decides to block using a futex operation, then this thread
40	needs to first change the state to >1; if this state is observed during
41	lock release, the releasing thread will wake one of the potentially
42	blocked threads.
43
44	Much of this code takes a 'private' parameter. This may be:
45	LLL_PRIVATE: lock only shared within a process
46	LLL_SHARED: lock may be shared across processes.
47
48	Condition variables contain an optimization for broadcasts that requeues
49	waiting threads on a lock's futex. Therefore, there is a special
50	variant of the locks (whose name contains "cond") that makes sure to
51	always set the lock state to >1 and not just 1.
52
53	Robust locks set the lock to the id of the owner. This allows detection
54	of the case where the owner exits without releasing the lock. Flags are
55	OR'd with the owner id to record additional information about lock state.
56	Therefore the states of robust locks are:
57	0: not acquired
58	id: acquired (by user identified by id & FUTEX_TID_MASK)
59
60	The following flags may be set in the robust lock value:
61	FUTEX_WAITERS - possibly has waiters
62	FUTEX_OWNER_DIED - owning user has exited without releasing the futex. /*
63
64
65	/ If LOCK is 0 (not acquired), set to 1 (acquired with no waiters) and return*
66	0. Otherwise leave lock unchanged and return non-zero to indicate that the
67	lock was not acquired. /*
68	#define __lll_trylock(lock) \
69	__glibc_unlikely (atomic_compare_and_exchange_bool_acq ((lock), 1, 0))
70	#define lll_trylock(lock) \
71	__lll_trylock (&(lock))
72
73	/ If LOCK is 0 (not acquired), set to 2 (acquired, possibly with waiters) and*
74	return 0. Otherwise leave lock unchanged and return non-zero to indicate
75	that the lock was not acquired. /*
76	#define lll_cond_trylock(lock) \
77	__glibc_unlikely (atomic_compare_and_exchange_bool_acq (&(lock), 2, 0))
78
79	extern void __lll_lock_wait_private (int *futex);
80	libc_hidden_proto (__lll_lock_wait_private)
81	extern void __lll_lock_wait (int futex, int* private);
82	libc_hidden_proto (__lll_lock_wait)
83
84	/ This is an expression rather than a statement even though its value is*
85	void, so that it can be used in a comma expression or as an expression
86	that's cast to void. /*
87	/ The inner conditional compiles to a call to __lll_lock_wait_private if*
88	private is known at compile time to be LLL_PRIVATE, and to a call to
89	__lll_lock_wait otherwise. /*
90	/ If FUTEX is 0 (not acquired), set to 1 (acquired with no waiters) and*
91	return. Otherwise, ensure that it is >1 (acquired, possibly with waiters)
92	and then block until we acquire the lock, at which point FUTEX will still be
93	>1. The lock is always acquired on return. /*
94	#define __lll_lock(futex, private) \
95	((void) \
96	({ \
97	int *__futex = (futex); \
98	if (__glibc_unlikely \
99	(atomic_compare_and_exchange_bool_acq (__futex, 1, 0))) \
100	{ \
101	if (__builtin_constant_p (private) && (private) == LLL_PRIVATE) \
102	__lll_lock_wait_private (__futex); \
103	else \
104	__lll_lock_wait (__futex, private); \
105	} \
106	}))
107	#define lll_lock(futex, private) \
108	__lll_lock (&(futex), private)
109
110
111	/ This is an expression rather than a statement even though its value is*
112	void, so that it can be used in a comma expression or as an expression
113	that's cast to void. /*
114	/ Unconditionally set FUTEX to 2 (acquired, possibly with waiters). If FUTEX*
115	was 0 (not acquired) then return. Otherwise, block until the lock is
116	acquired, at which point FUTEX is 2 (acquired, possibly with waiters). The
117	lock is always acquired on return. /*
118	#define __lll_cond_lock(futex, private) \
119	((void) \
120	({ \
121	int *__futex = (futex); \
122	if (__glibc_unlikely (atomic_exchange_acq (__futex, 2) != 0)) \
123	__lll_lock_wait (__futex, private); \
124	}))
125	#define lll_cond_lock(futex, private) __lll_cond_lock (&(futex), private)
126
127
128	extern void __lll_lock_wake_private (int *futex);
129	libc_hidden_proto (__lll_lock_wake_private)
130	extern void __lll_lock_wake (int futex, int* private);
131	libc_hidden_proto (__lll_lock_wake)
132
133	/ This is an expression rather than a statement even though its value is*
134	void, so that it can be used in a comma expression or as an expression
135	that's cast to void. /*
136	/ Unconditionally set FUTEX to 0 (not acquired), releasing the lock. If FUTEX*
137	was >1 (acquired, possibly with waiters), then wake any waiters. The waiter
138	that acquires the lock will set FUTEX to >1.
139	Evaluate PRIVATE before releasing the lock so that we do not violate the
140	mutex destruction requirements. Specifically, we need to ensure that
141	another thread can destroy the mutex (and reuse its memory) once it
142	acquires the lock and when there will be no further lock acquisitions;
143	thus, we must not access the lock after releasing it, or those accesses
144	could be concurrent with mutex destruction or reuse of the memory. /*
145	#define __lll_unlock(futex, private) \
146	((void) \
147	({ \
148	int *__futex = (futex); \
149	int __private = (private); \
150	int __oldval = atomic_exchange_rel (__futex, 0); \
151	if (__glibc_unlikely (__oldval > 1)) \
152	{ \
153	if (__builtin_constant_p (private) && (private) == LLL_PRIVATE) \
154	__lll_lock_wake_private (__futex); \
155	else \
156	__lll_lock_wake (__futex, __private); \
157	} \
158	}))
159	#define lll_unlock(futex, private) \
160	__lll_unlock (&(futex), private)
161
162
163	#define lll_islocked(futex) \
164	((futex) != LLL_LOCK_INITIALIZER)
165
166
167	/ Our internal lock implementation is identical to the binary-compatible*
168	mutex implementation. /*
169
170	/ Initializers for lock. /
171	#define LLL_LOCK_INITIALIZER (0)
172	#define LLL_LOCK_INITIALIZER_LOCKED (1)
173
174	/ Elision support. /
175
176	#if ENABLE_ELISION_SUPPORT
177	/ Force elision for all new locks. This is used to decide whether*
178	existing DEFAULT locks should be automatically upgraded to elision
179	in pthread_mutex_lock. Disabled for suid programs. Only used when
180	elision is available. /*
181	extern int __pthread_force_elision;
182	libc_hidden_proto (__pthread_force_elision)
183
184	extern void __lll_elision_init (void) attribute_hidden;
185	extern int __lll_clocklock_elision (int futex, short* *adapt_count,
186	clockid_t clockid,
187	const struct __timespec64 *timeout,
188	int private);
189	libc_hidden_proto (__lll_clocklock_elision)
190
191	extern int __lll_lock_elision (int futex, short* adapt_count, int* private);
192	libc_hidden_proto (__lll_lock_elision)
193
194	# if ELISION_UNLOCK_NEEDS_ADAPT_COUNT
195	extern int __lll_unlock_elision (int lock, short* adapt_count, int* private);
196	# else
197	extern int __lll_unlock_elision (int lock, int* private);
198	# endif
199	libc_hidden_proto (__lll_unlock_elision)
200
201	extern int __lll_trylock_elision (int lock, short* *adapt_count);
202	libc_hidden_proto (__lll_trylock_elision)
203
204	# define lll_clocklock_elision(futex, adapt_count, clockid, timeout, private) \
205	__lll_clocklock_elision (&(futex), &(adapt_count), clockid, timeout, private)
206	# define lll_lock_elision(futex, adapt_count, private) \
207	__lll_lock_elision (&(futex), &(adapt_count), private)
208	# define lll_trylock_elision(futex, adapt_count) \
209	__lll_trylock_elision (&(futex), &(adapt_count))
210	# if ELISION_UNLOCK_NEEDS_ADAPT_COUNT
211	# define lll_unlock_elision(futex, adapt_count, private) \
212	__lll_unlock_elision (&(futex), &(adapt_count), private)
213	# else
214	# define lll_unlock_elision(futex, adapt_count, private) \
215	__lll_unlock_elision (&(futex), private)
216	# endif
217
218	/ Automatically enable elision for existing user lock kinds. /
219	# define FORCE_ELISION(m, s) \
220	if (__pthread_force_elision) \
221	{ \
222	/* See concurrency notes regarding __kind in \
223	struct __pthread_mutex_s in \
224	sysdeps/nptl/bits/thread-shared-types.h. \
225	\
226	There are the following cases for the kind of a mutex \
227	(The mask PTHREAD_MUTEX_ELISION_FLAGS_NP covers the flags \
228	PTHREAD_MUTEX_ELISION_NP and PTHREAD_MUTEX_NO_ELISION_NP where \
229	only one of both flags can be set): \
230	- both flags are not set: \
231	This is the first lock operation for this mutex. Enable \
232	elision as it is not enabled so far. \
233	Note: It can happen that multiple threads are calling e.g. \
234	pthread_mutex_lock at the same time as the first lock \
235	operation for this mutex. Then elision is enabled for this \
236	mutex by multiple threads. Storing with relaxed MO is enough \
237	as all threads will store the same new value for the kind of \
238	the mutex. But we have to ensure that we always use the \
239	elision path regardless if this thread has enabled elision or \
240	another one. \
241	\
242	- PTHREAD_MUTEX_ELISION_NP flag is set: \
243	Elision was already enabled for this mutex by a previous lock \
244	operation. See case above. Just use the elision path. \
245	\
246	- PTHREAD_MUTEX_NO_ELISION_NP flag is set: \
247	Elision was explicitly disabled by pthread_mutexattr_settype. \
248	Do not use the elision path. \
249	Note: The flag PTHREAD_MUTEX_NO_ELISION_NP will never be \
250	changed after mutex initialization. */ \
251	int mutex_kind = atomic_load_relaxed (&((m)->__data.__kind)); \
252	if ((mutex_kind & PTHREAD_MUTEX_ELISION_FLAGS_NP) == 0) \
253	{ \
254	mutex_kind \|= PTHREAD_MUTEX_ELISION_NP; \
255	atomic_store_relaxed (&((m)->__data.__kind), mutex_kind); \
256	} \
257	if ((mutex_kind & PTHREAD_MUTEX_ELISION_NP) != 0) \
258	{ \
259	s; \
260	} \
261	}
262
263	#else /* !ENABLE_ELISION_SUPPORT */
264
265	# define lll_clocklock_elision(futex, adapt_count, clockid, abstime, private) \
266	__futex_clocklock64 (&(futex), clockid, abstime, private)
267	# define lll_lock_elision(lock, try_lock, private) \
268	({ lll_lock (lock, private); 0; })
269	# define lll_trylock_elision(a,t) lll_trylock(a)
270	# define lll_unlock_elision(a,b,c) ({ lll_unlock (a,c); 0; })
271	# define FORCE_ELISION(m, s)
272
273	#endif /* !ENABLE_ELISION_SUPPORT */
274
275	#endif /* lowlevellock.h */
276

source code of glibc/sysdeps/nptl/lowlevellock.h