pthread_mutex.cpp revision 624996026b844ff2eba2283f4dc83ec363d85a11
1/* 2 * Copyright (C) 2008 The Android Open Source Project 3 * All rights reserved. 4 * 5 * Redistribution and use in source and binary forms, with or without 6 * modification, are permitted provided that the following conditions 7 * are met: 8 * * Redistributions of source code must retain the above copyright 9 * notice, this list of conditions and the following disclaimer. 10 * * Redistributions in binary form must reproduce the above copyright 11 * notice, this list of conditions and the following disclaimer in 12 * the documentation and/or other materials provided with the 13 * distribution. 14 * 15 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 16 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 17 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS 18 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE 19 * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, 20 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 21 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS 22 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 23 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 24 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT 25 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 26 * SUCH DAMAGE. 27 */ 28 29#include <pthread.h> 30 31#include <errno.h> 32#include <limits.h> 33#include <sys/mman.h> 34#include <unistd.h> 35 36#include "pthread_internal.h" 37 38#include "private/bionic_atomic_inline.h" 39#include "private/bionic_futex.h" 40#include "private/bionic_tls.h" 41 42extern void pthread_debug_mutex_lock_check(pthread_mutex_t *mutex); 43extern void pthread_debug_mutex_unlock_check(pthread_mutex_t *mutex); 44 45/* a mutex is implemented as a 32-bit integer holding the following fields 46 * 47 * bits: name description 48 * 31-16 tid owner thread's tid (recursive and errorcheck only) 49 * 15-14 type mutex type 50 * 13 shared process-shared flag 51 * 12-2 counter counter of recursive mutexes 52 * 1-0 state lock state (0, 1 or 2) 53 */ 54 55/* Convenience macro, creates a mask of 'bits' bits that starts from 56 * the 'shift'-th least significant bit in a 32-bit word. 57 * 58 * Examples: FIELD_MASK(0,4) -> 0xf 59 * FIELD_MASK(16,9) -> 0x1ff0000 60 */ 61#define FIELD_MASK(shift,bits) (((1 << (bits))-1) << (shift)) 62 63/* This one is used to create a bit pattern from a given field value */ 64#define FIELD_TO_BITS(val,shift,bits) (((val) & ((1 << (bits))-1)) << (shift)) 65 66/* And this one does the opposite, i.e. extract a field's value from a bit pattern */ 67#define FIELD_FROM_BITS(val,shift,bits) (((val) >> (shift)) & ((1 << (bits))-1)) 68 69/* Mutex state: 70 * 71 * 0 for unlocked 72 * 1 for locked, no waiters 73 * 2 for locked, maybe waiters 74 */ 75#define MUTEX_STATE_SHIFT 0 76#define MUTEX_STATE_LEN 2 77 78#define MUTEX_STATE_MASK FIELD_MASK(MUTEX_STATE_SHIFT, MUTEX_STATE_LEN) 79#define MUTEX_STATE_FROM_BITS(v) FIELD_FROM_BITS(v, MUTEX_STATE_SHIFT, MUTEX_STATE_LEN) 80#define MUTEX_STATE_TO_BITS(v) FIELD_TO_BITS(v, MUTEX_STATE_SHIFT, MUTEX_STATE_LEN) 81 82#define MUTEX_STATE_UNLOCKED 0 /* must be 0 to match __PTHREAD_MUTEX_INIT_VALUE */ 83#define MUTEX_STATE_LOCKED_UNCONTENDED 1 /* must be 1 due to atomic dec in unlock operation */ 84#define MUTEX_STATE_LOCKED_CONTENDED 2 /* must be 1 + LOCKED_UNCONTENDED due to atomic dec */ 85 86#define MUTEX_STATE_FROM_BITS(v) FIELD_FROM_BITS(v, MUTEX_STATE_SHIFT, MUTEX_STATE_LEN) 87#define MUTEX_STATE_TO_BITS(v) FIELD_TO_BITS(v, MUTEX_STATE_SHIFT, MUTEX_STATE_LEN) 88 89#define MUTEX_STATE_BITS_UNLOCKED MUTEX_STATE_TO_BITS(MUTEX_STATE_UNLOCKED) 90#define MUTEX_STATE_BITS_LOCKED_UNCONTENDED MUTEX_STATE_TO_BITS(MUTEX_STATE_LOCKED_UNCONTENDED) 91#define MUTEX_STATE_BITS_LOCKED_CONTENDED MUTEX_STATE_TO_BITS(MUTEX_STATE_LOCKED_CONTENDED) 92 93/* return true iff the mutex if locked with no waiters */ 94#define MUTEX_STATE_BITS_IS_LOCKED_UNCONTENDED(v) (((v) & MUTEX_STATE_MASK) == MUTEX_STATE_BITS_LOCKED_UNCONTENDED) 95 96/* return true iff the mutex if locked with maybe waiters */ 97#define MUTEX_STATE_BITS_IS_LOCKED_CONTENDED(v) (((v) & MUTEX_STATE_MASK) == MUTEX_STATE_BITS_LOCKED_CONTENDED) 98 99/* used to flip from LOCKED_UNCONTENDED to LOCKED_CONTENDED */ 100#define MUTEX_STATE_BITS_FLIP_CONTENTION(v) ((v) ^ (MUTEX_STATE_BITS_LOCKED_CONTENDED ^ MUTEX_STATE_BITS_LOCKED_UNCONTENDED)) 101 102/* Mutex counter: 103 * 104 * We need to check for overflow before incrementing, and we also need to 105 * detect when the counter is 0 106 */ 107#define MUTEX_COUNTER_SHIFT 2 108#define MUTEX_COUNTER_LEN 11 109#define MUTEX_COUNTER_MASK FIELD_MASK(MUTEX_COUNTER_SHIFT, MUTEX_COUNTER_LEN) 110 111#define MUTEX_COUNTER_BITS_WILL_OVERFLOW(v) (((v) & MUTEX_COUNTER_MASK) == MUTEX_COUNTER_MASK) 112#define MUTEX_COUNTER_BITS_IS_ZERO(v) (((v) & MUTEX_COUNTER_MASK) == 0) 113 114/* Used to increment the counter directly after overflow has been checked */ 115#define MUTEX_COUNTER_BITS_ONE FIELD_TO_BITS(1,MUTEX_COUNTER_SHIFT,MUTEX_COUNTER_LEN) 116 117/* Returns true iff the counter is 0 */ 118#define MUTEX_COUNTER_BITS_ARE_ZERO(v) (((v) & MUTEX_COUNTER_MASK) == 0) 119 120/* Mutex shared bit flag 121 * 122 * This flag is set to indicate that the mutex is shared among processes. 123 * This changes the futex opcode we use for futex wait/wake operations 124 * (non-shared operations are much faster). 125 */ 126#define MUTEX_SHARED_SHIFT 13 127#define MUTEX_SHARED_MASK FIELD_MASK(MUTEX_SHARED_SHIFT,1) 128 129/* Mutex type: 130 * 131 * We support normal, recursive and errorcheck mutexes. 132 * 133 * The constants defined here *cannot* be changed because they must match 134 * the C library ABI which defines the following initialization values in 135 * <pthread.h>: 136 * 137 * __PTHREAD_MUTEX_INIT_VALUE 138 * __PTHREAD_RECURSIVE_MUTEX_VALUE 139 * __PTHREAD_ERRORCHECK_MUTEX_INIT_VALUE 140 */ 141#define MUTEX_TYPE_SHIFT 14 142#define MUTEX_TYPE_LEN 2 143#define MUTEX_TYPE_MASK FIELD_MASK(MUTEX_TYPE_SHIFT,MUTEX_TYPE_LEN) 144 145#define MUTEX_TYPE_NORMAL 0 /* Must be 0 to match __PTHREAD_MUTEX_INIT_VALUE */ 146#define MUTEX_TYPE_RECURSIVE 1 147#define MUTEX_TYPE_ERRORCHECK 2 148 149#define MUTEX_TYPE_TO_BITS(t) FIELD_TO_BITS(t, MUTEX_TYPE_SHIFT, MUTEX_TYPE_LEN) 150 151#define MUTEX_TYPE_BITS_NORMAL MUTEX_TYPE_TO_BITS(MUTEX_TYPE_NORMAL) 152#define MUTEX_TYPE_BITS_RECURSIVE MUTEX_TYPE_TO_BITS(MUTEX_TYPE_RECURSIVE) 153#define MUTEX_TYPE_BITS_ERRORCHECK MUTEX_TYPE_TO_BITS(MUTEX_TYPE_ERRORCHECK) 154 155/* Mutex owner field: 156 * 157 * This is only used for recursive and errorcheck mutexes. It holds the 158 * tid of the owning thread. Note that this works because the Linux 159 * kernel _only_ uses 16-bit values for tids. 160 * 161 * More specifically, it will wrap to 10000 when it reaches over 32768 for 162 * application processes. You can check this by running the following inside 163 * an adb shell session: 164 * 165 OLDPID=$$; 166 while true; do 167 NEWPID=$(sh -c 'echo $$') 168 if [ "$NEWPID" -gt 32768 ]; then 169 echo "AARGH: new PID $NEWPID is too high!" 170 exit 1 171 fi 172 if [ "$NEWPID" -lt "$OLDPID" ]; then 173 echo "****** Wrapping from PID $OLDPID to $NEWPID. *******" 174 else 175 echo -n "$NEWPID!" 176 fi 177 OLDPID=$NEWPID 178 done 179 180 * Note that you can run the same example on a desktop Linux system, 181 * the wrapping will also happen at 32768, but will go back to 300 instead. 182 */ 183#define MUTEX_OWNER_SHIFT 16 184#define MUTEX_OWNER_LEN 16 185 186#define MUTEX_OWNER_FROM_BITS(v) FIELD_FROM_BITS(v,MUTEX_OWNER_SHIFT,MUTEX_OWNER_LEN) 187#define MUTEX_OWNER_TO_BITS(v) FIELD_TO_BITS(v,MUTEX_OWNER_SHIFT,MUTEX_OWNER_LEN) 188 189/* Convenience macros. 190 * 191 * These are used to form or modify the bit pattern of a given mutex value 192 */ 193 194 195 196/* a mutex attribute holds the following fields 197 * 198 * bits: name description 199 * 0-3 type type of mutex 200 * 4 shared process-shared flag 201 */ 202#define MUTEXATTR_TYPE_MASK 0x000f 203#define MUTEXATTR_SHARED_MASK 0x0010 204 205 206int pthread_mutexattr_init(pthread_mutexattr_t *attr) 207{ 208 *attr = PTHREAD_MUTEX_DEFAULT; 209 return 0; 210} 211 212int pthread_mutexattr_destroy(pthread_mutexattr_t *attr) 213{ 214 *attr = -1; 215 return 0; 216} 217 218int pthread_mutexattr_gettype(const pthread_mutexattr_t *attr, int *type_p) 219{ 220 int type = (*attr & MUTEXATTR_TYPE_MASK); 221 222 if (type < PTHREAD_MUTEX_NORMAL || type > PTHREAD_MUTEX_ERRORCHECK) { 223 return EINVAL; 224 } 225 226 *type_p = type; 227 return 0; 228} 229 230int pthread_mutexattr_settype(pthread_mutexattr_t *attr, int type) 231{ 232 if (type < PTHREAD_MUTEX_NORMAL || type > PTHREAD_MUTEX_ERRORCHECK ) { 233 return EINVAL; 234 } 235 236 *attr = (*attr & ~MUTEXATTR_TYPE_MASK) | type; 237 return 0; 238} 239 240/* process-shared mutexes are not supported at the moment */ 241 242int pthread_mutexattr_setpshared(pthread_mutexattr_t *attr, int pshared) 243{ 244 switch (pshared) { 245 case PTHREAD_PROCESS_PRIVATE: 246 *attr &= ~MUTEXATTR_SHARED_MASK; 247 return 0; 248 249 case PTHREAD_PROCESS_SHARED: 250 /* our current implementation of pthread actually supports shared 251 * mutexes but won't cleanup if a process dies with the mutex held. 252 * Nevertheless, it's better than nothing. Shared mutexes are used 253 * by surfaceflinger and audioflinger. 254 */ 255 *attr |= MUTEXATTR_SHARED_MASK; 256 return 0; 257 } 258 return EINVAL; 259} 260 261int pthread_mutexattr_getpshared(const pthread_mutexattr_t* attr, int* pshared) { 262 *pshared = (*attr & MUTEXATTR_SHARED_MASK) ? PTHREAD_PROCESS_SHARED : PTHREAD_PROCESS_PRIVATE; 263 return 0; 264} 265 266int pthread_mutex_init(pthread_mutex_t* mutex, const pthread_mutexattr_t* attr) { 267 if (__predict_true(attr == NULL)) { 268 mutex->value = MUTEX_TYPE_BITS_NORMAL; 269 return 0; 270 } 271 272 int value = 0; 273 if ((*attr & MUTEXATTR_SHARED_MASK) != 0) { 274 value |= MUTEX_SHARED_MASK; 275 } 276 277 switch (*attr & MUTEXATTR_TYPE_MASK) { 278 case PTHREAD_MUTEX_NORMAL: 279 value |= MUTEX_TYPE_BITS_NORMAL; 280 break; 281 case PTHREAD_MUTEX_RECURSIVE: 282 value |= MUTEX_TYPE_BITS_RECURSIVE; 283 break; 284 case PTHREAD_MUTEX_ERRORCHECK: 285 value |= MUTEX_TYPE_BITS_ERRORCHECK; 286 break; 287 default: 288 return EINVAL; 289 } 290 291 mutex->value = value; 292 return 0; 293} 294 295 296/* 297 * Lock a non-recursive mutex. 298 * 299 * As noted above, there are three states: 300 * 0 (unlocked, no contention) 301 * 1 (locked, no contention) 302 * 2 (locked, contention) 303 * 304 * Non-recursive mutexes don't use the thread-id or counter fields, and the 305 * "type" value is zero, so the only bits that will be set are the ones in 306 * the lock state field. 307 */ 308static inline void _normal_lock(pthread_mutex_t* mutex, int shared) { 309 /* convenience shortcuts */ 310 const int unlocked = shared | MUTEX_STATE_BITS_UNLOCKED; 311 const int locked_uncontended = shared | MUTEX_STATE_BITS_LOCKED_UNCONTENDED; 312 /* 313 * The common case is an unlocked mutex, so we begin by trying to 314 * change the lock's state from 0 (UNLOCKED) to 1 (LOCKED). 315 * __bionic_cmpxchg() returns 0 if it made the swap successfully. 316 * If the result is nonzero, this lock is already held by another thread. 317 */ 318 if (__bionic_cmpxchg(unlocked, locked_uncontended, &mutex->value) != 0) { 319 const int locked_contended = shared | MUTEX_STATE_BITS_LOCKED_CONTENDED; 320 /* 321 * We want to go to sleep until the mutex is available, which 322 * requires promoting it to state 2 (CONTENDED). We need to 323 * swap in the new state value and then wait until somebody wakes us up. 324 * 325 * __bionic_swap() returns the previous value. We swap 2 in and 326 * see if we got zero back; if so, we have acquired the lock. If 327 * not, another thread still holds the lock and we wait again. 328 * 329 * The second argument to the __futex_wait() call is compared 330 * against the current value. If it doesn't match, __futex_wait() 331 * returns immediately (otherwise, it sleeps for a time specified 332 * by the third argument; 0 means sleep forever). This ensures 333 * that the mutex is in state 2 when we go to sleep on it, which 334 * guarantees a wake-up call. 335 */ 336 while (__bionic_swap(locked_contended, &mutex->value) != unlocked) { 337 __futex_wait_ex(&mutex->value, shared, locked_contended, NULL); 338 } 339 } 340 ANDROID_MEMBAR_FULL(); 341} 342 343/* 344 * Release a non-recursive mutex. The caller is responsible for determining 345 * that we are in fact the owner of this lock. 346 */ 347static inline void _normal_unlock(pthread_mutex_t* mutex, int shared) { 348 ANDROID_MEMBAR_FULL(); 349 350 /* 351 * The mutex state will be 1 or (rarely) 2. We use an atomic decrement 352 * to release the lock. __bionic_atomic_dec() returns the previous value; 353 * if it wasn't 1 we have to do some additional work. 354 */ 355 if (__bionic_atomic_dec(&mutex->value) != (shared|MUTEX_STATE_BITS_LOCKED_UNCONTENDED)) { 356 /* 357 * Start by releasing the lock. The decrement changed it from 358 * "contended lock" to "uncontended lock", which means we still 359 * hold it, and anybody who tries to sneak in will push it back 360 * to state 2. 361 * 362 * Once we set it to zero the lock is up for grabs. We follow 363 * this with a __futex_wake() to ensure that one of the waiting 364 * threads has a chance to grab it. 365 * 366 * This doesn't cause a race with the swap/wait pair in 367 * _normal_lock(), because the __futex_wait() call there will 368 * return immediately if the mutex value isn't 2. 369 */ 370 mutex->value = shared; 371 372 /* 373 * Wake up one waiting thread. We don't know which thread will be 374 * woken or when it'll start executing -- futexes make no guarantees 375 * here. There may not even be a thread waiting. 376 * 377 * The newly-woken thread will replace the 0 we just set above 378 * with 2, which means that when it eventually releases the mutex 379 * it will also call FUTEX_WAKE. This results in one extra wake 380 * call whenever a lock is contended, but lets us avoid forgetting 381 * anyone without requiring us to track the number of sleepers. 382 * 383 * It's possible for another thread to sneak in and grab the lock 384 * between the zero assignment above and the wake call below. If 385 * the new thread is "slow" and holds the lock for a while, we'll 386 * wake up a sleeper, which will swap in a 2 and then go back to 387 * sleep since the lock is still held. If the new thread is "fast", 388 * running to completion before we call wake, the thread we 389 * eventually wake will find an unlocked mutex and will execute. 390 * Either way we have correct behavior and nobody is orphaned on 391 * the wait queue. 392 */ 393 __futex_wake_ex(&mutex->value, shared, 1); 394 } 395} 396 397/* This common inlined function is used to increment the counter of an 398 * errorcheck or recursive mutex. 399 * 400 * For errorcheck mutexes, it will return EDEADLK 401 * If the counter overflows, it will return EAGAIN 402 * Otherwise, it atomically increments the counter and returns 0 403 * after providing an acquire barrier. 404 * 405 * mtype is the current mutex type 406 * mvalue is the current mutex value (already loaded) 407 * mutex pointers to the mutex. 408 */ 409static inline __always_inline int _recursive_increment(pthread_mutex_t* mutex, int mvalue, int mtype) { 410 if (mtype == MUTEX_TYPE_BITS_ERRORCHECK) { 411 /* trying to re-lock a mutex we already acquired */ 412 return EDEADLK; 413 } 414 415 /* Detect recursive lock overflow and return EAGAIN. 416 * This is safe because only the owner thread can modify the 417 * counter bits in the mutex value. 418 */ 419 if (MUTEX_COUNTER_BITS_WILL_OVERFLOW(mvalue)) { 420 return EAGAIN; 421 } 422 423 /* We own the mutex, but other threads are able to change 424 * the lower bits (e.g. promoting it to "contended"), so we 425 * need to use an atomic cmpxchg loop to update the counter. 426 */ 427 for (;;) { 428 /* increment counter, overflow was already checked */ 429 int newval = mvalue + MUTEX_COUNTER_BITS_ONE; 430 if (__predict_true(__bionic_cmpxchg(mvalue, newval, &mutex->value) == 0)) { 431 /* mutex is still locked, not need for a memory barrier */ 432 return 0; 433 } 434 /* the value was changed, this happens when another thread changes 435 * the lower state bits from 1 to 2 to indicate contention. This 436 * cannot change the counter, so simply reload and try again. 437 */ 438 mvalue = mutex->value; 439 } 440} 441 442int pthread_mutex_lock(pthread_mutex_t* mutex) { 443 int mvalue, mtype, tid, shared; 444 445 mvalue = mutex->value; 446 mtype = (mvalue & MUTEX_TYPE_MASK); 447 shared = (mvalue & MUTEX_SHARED_MASK); 448 449 /* Handle non-recursive case first */ 450 if ( __predict_true(mtype == MUTEX_TYPE_BITS_NORMAL) ) { 451 _normal_lock(mutex, shared); 452 return 0; 453 } 454 455 /* Do we already own this recursive or error-check mutex ? */ 456 tid = __get_thread()->tid; 457 if ( tid == MUTEX_OWNER_FROM_BITS(mvalue) ) 458 return _recursive_increment(mutex, mvalue, mtype); 459 460 /* Add in shared state to avoid extra 'or' operations below */ 461 mtype |= shared; 462 463 /* First, if the mutex is unlocked, try to quickly acquire it. 464 * In the optimistic case where this works, set the state to 1 to 465 * indicate locked with no contention */ 466 if (mvalue == mtype) { 467 int newval = MUTEX_OWNER_TO_BITS(tid) | mtype | MUTEX_STATE_BITS_LOCKED_UNCONTENDED; 468 if (__bionic_cmpxchg(mvalue, newval, &mutex->value) == 0) { 469 ANDROID_MEMBAR_FULL(); 470 return 0; 471 } 472 /* argh, the value changed, reload before entering the loop */ 473 mvalue = mutex->value; 474 } 475 476 for (;;) { 477 int newval; 478 479 /* if the mutex is unlocked, its value should be 'mtype' and 480 * we try to acquire it by setting its owner and state atomically. 481 * NOTE: We put the state to 2 since we _know_ there is contention 482 * when we are in this loop. This ensures all waiters will be 483 * unlocked. 484 */ 485 if (mvalue == mtype) { 486 newval = MUTEX_OWNER_TO_BITS(tid) | mtype | MUTEX_STATE_BITS_LOCKED_CONTENDED; 487 /* TODO: Change this to __bionic_cmpxchg_acquire when we 488 * implement it to get rid of the explicit memory 489 * barrier below. 490 */ 491 if (__predict_false(__bionic_cmpxchg(mvalue, newval, &mutex->value) != 0)) { 492 mvalue = mutex->value; 493 continue; 494 } 495 ANDROID_MEMBAR_FULL(); 496 return 0; 497 } 498 499 /* the mutex is already locked by another thread, if its state is 1 500 * we will change it to 2 to indicate contention. */ 501 if (MUTEX_STATE_BITS_IS_LOCKED_UNCONTENDED(mvalue)) { 502 newval = MUTEX_STATE_BITS_FLIP_CONTENTION(mvalue); /* locked state 1 => state 2 */ 503 if (__predict_false(__bionic_cmpxchg(mvalue, newval, &mutex->value) != 0)) { 504 mvalue = mutex->value; 505 continue; 506 } 507 mvalue = newval; 508 } 509 510 /* wait until the mutex is unlocked */ 511 __futex_wait_ex(&mutex->value, shared, mvalue, NULL); 512 513 mvalue = mutex->value; 514 } 515 /* NOTREACHED */ 516} 517 518int pthread_mutex_unlock(pthread_mutex_t* mutex) { 519 int mvalue, mtype, tid, shared; 520 521 mvalue = mutex->value; 522 mtype = (mvalue & MUTEX_TYPE_MASK); 523 shared = (mvalue & MUTEX_SHARED_MASK); 524 525 /* Handle common case first */ 526 if (__predict_true(mtype == MUTEX_TYPE_BITS_NORMAL)) { 527 _normal_unlock(mutex, shared); 528 return 0; 529 } 530 531 /* Do we already own this recursive or error-check mutex ? */ 532 tid = __get_thread()->tid; 533 if ( tid != MUTEX_OWNER_FROM_BITS(mvalue) ) 534 return EPERM; 535 536 /* If the counter is > 0, we can simply decrement it atomically. 537 * Since other threads can mutate the lower state bits (and only the 538 * lower state bits), use a cmpxchg to do it. 539 */ 540 if (!MUTEX_COUNTER_BITS_IS_ZERO(mvalue)) { 541 for (;;) { 542 int newval = mvalue - MUTEX_COUNTER_BITS_ONE; 543 if (__predict_true(__bionic_cmpxchg(mvalue, newval, &mutex->value) == 0)) { 544 /* success: we still own the mutex, so no memory barrier */ 545 return 0; 546 } 547 /* the value changed, so reload and loop */ 548 mvalue = mutex->value; 549 } 550 } 551 552 /* the counter is 0, so we're going to unlock the mutex by resetting 553 * its value to 'unlocked'. We need to perform a swap in order 554 * to read the current state, which will be 2 if there are waiters 555 * to awake. 556 * 557 * TODO: Change this to __bionic_swap_release when we implement it 558 * to get rid of the explicit memory barrier below. 559 */ 560 ANDROID_MEMBAR_FULL(); /* RELEASE BARRIER */ 561 mvalue = __bionic_swap(mtype | shared | MUTEX_STATE_BITS_UNLOCKED, &mutex->value); 562 563 /* Wake one waiting thread, if any */ 564 if (MUTEX_STATE_BITS_IS_LOCKED_CONTENDED(mvalue)) { 565 __futex_wake_ex(&mutex->value, shared, 1); 566 } 567 return 0; 568} 569 570int pthread_mutex_trylock(pthread_mutex_t* mutex) { 571 int mvalue, mtype, tid, shared; 572 573 mvalue = mutex->value; 574 mtype = (mvalue & MUTEX_TYPE_MASK); 575 shared = (mvalue & MUTEX_SHARED_MASK); 576 577 /* Handle common case first */ 578 if ( __predict_true(mtype == MUTEX_TYPE_BITS_NORMAL) ) 579 { 580 if (__bionic_cmpxchg(shared|MUTEX_STATE_BITS_UNLOCKED, 581 shared|MUTEX_STATE_BITS_LOCKED_UNCONTENDED, 582 &mutex->value) == 0) { 583 ANDROID_MEMBAR_FULL(); 584 return 0; 585 } 586 587 return EBUSY; 588 } 589 590 /* Do we already own this recursive or error-check mutex ? */ 591 tid = __get_thread()->tid; 592 if ( tid == MUTEX_OWNER_FROM_BITS(mvalue) ) 593 return _recursive_increment(mutex, mvalue, mtype); 594 595 /* Same as pthread_mutex_lock, except that we don't want to wait, and 596 * the only operation that can succeed is a single cmpxchg to acquire the 597 * lock if it is released / not owned by anyone. No need for a complex loop. 598 */ 599 mtype |= shared | MUTEX_STATE_BITS_UNLOCKED; 600 mvalue = MUTEX_OWNER_TO_BITS(tid) | mtype | MUTEX_STATE_BITS_LOCKED_UNCONTENDED; 601 602 if (__predict_true(__bionic_cmpxchg(mtype, mvalue, &mutex->value) == 0)) { 603 ANDROID_MEMBAR_FULL(); 604 return 0; 605 } 606 607 return EBUSY; 608} 609 610static int __pthread_mutex_timedlock(pthread_mutex_t* mutex, const timespec* abs_timeout, clockid_t clock) { 611 timespec ts; 612 613 int mvalue = mutex->value; 614 int mtype = (mvalue & MUTEX_TYPE_MASK); 615 int shared = (mvalue & MUTEX_SHARED_MASK); 616 617 // Handle common case first. 618 if (__predict_true(mtype == MUTEX_TYPE_BITS_NORMAL)) { 619 const int unlocked = shared | MUTEX_STATE_BITS_UNLOCKED; 620 const int locked_uncontended = shared | MUTEX_STATE_BITS_LOCKED_UNCONTENDED; 621 const int locked_contended = shared | MUTEX_STATE_BITS_LOCKED_CONTENDED; 622 623 // Fast path for uncontended lock. Note: MUTEX_TYPE_BITS_NORMAL is 0. 624 if (__bionic_cmpxchg(unlocked, locked_uncontended, &mutex->value) == 0) { 625 ANDROID_MEMBAR_FULL(); 626 return 0; 627 } 628 629 // Loop while needed. 630 while (__bionic_swap(locked_contended, &mutex->value) != unlocked) { 631 if (__timespec_from_absolute(&ts, abs_timeout, clock) < 0) { 632 return ETIMEDOUT; 633 } 634 __futex_wait_ex(&mutex->value, shared, locked_contended, &ts); 635 } 636 ANDROID_MEMBAR_FULL(); 637 return 0; 638 } 639 640 // Do we already own this recursive or error-check mutex? 641 pid_t tid = __get_thread()->tid; 642 if (tid == MUTEX_OWNER_FROM_BITS(mvalue)) { 643 return _recursive_increment(mutex, mvalue, mtype); 644 } 645 646 // The following implements the same loop as pthread_mutex_lock_impl 647 // but adds checks to ensure that the operation never exceeds the 648 // absolute expiration time. 649 mtype |= shared; 650 651 // First try a quick lock. 652 if (mvalue == mtype) { 653 mvalue = MUTEX_OWNER_TO_BITS(tid) | mtype | MUTEX_STATE_BITS_LOCKED_UNCONTENDED; 654 if (__predict_true(__bionic_cmpxchg(mtype, mvalue, &mutex->value) == 0)) { 655 ANDROID_MEMBAR_FULL(); 656 return 0; 657 } 658 mvalue = mutex->value; 659 } 660 661 while (true) { 662 // If the value is 'unlocked', try to acquire it directly. 663 // NOTE: put state to 2 since we know there is contention. 664 if (mvalue == mtype) { // Unlocked. 665 mvalue = MUTEX_OWNER_TO_BITS(tid) | mtype | MUTEX_STATE_BITS_LOCKED_CONTENDED; 666 if (__bionic_cmpxchg(mtype, mvalue, &mutex->value) == 0) { 667 ANDROID_MEMBAR_FULL(); 668 return 0; 669 } 670 // The value changed before we could lock it. We need to check 671 // the time to avoid livelocks, reload the value, then loop again. 672 if (__timespec_from_absolute(&ts, abs_timeout, clock) < 0) { 673 return ETIMEDOUT; 674 } 675 676 mvalue = mutex->value; 677 continue; 678 } 679 680 // The value is locked. If 'uncontended', try to switch its state 681 // to 'contented' to ensure we get woken up later. 682 if (MUTEX_STATE_BITS_IS_LOCKED_UNCONTENDED(mvalue)) { 683 int newval = MUTEX_STATE_BITS_FLIP_CONTENTION(mvalue); 684 if (__bionic_cmpxchg(mvalue, newval, &mutex->value) != 0) { 685 // This failed because the value changed, reload it. 686 mvalue = mutex->value; 687 } else { 688 // This succeeded, update mvalue. 689 mvalue = newval; 690 } 691 } 692 693 // Check time and update 'ts'. 694 if (__timespec_from_absolute(&ts, abs_timeout, clock) < 0) { 695 return ETIMEDOUT; 696 } 697 698 // Only wait to be woken up if the state is '2', otherwise we'll 699 // simply loop right now. This can happen when the second cmpxchg 700 // in our loop failed because the mutex was unlocked by another thread. 701 if (MUTEX_STATE_BITS_IS_LOCKED_CONTENDED(mvalue)) { 702 if (__futex_wait_ex(&mutex->value, shared, mvalue, &ts) == -ETIMEDOUT) { 703 return ETIMEDOUT; 704 } 705 mvalue = mutex->value; 706 } 707 } 708 /* NOTREACHED */ 709} 710 711#if !defined(__LP64__) 712extern "C" int pthread_mutex_lock_timeout_np(pthread_mutex_t* mutex, unsigned ms) { 713 timespec abs_timeout; 714 clock_gettime(CLOCK_MONOTONIC, &abs_timeout); 715 abs_timeout.tv_sec += ms / 1000; 716 abs_timeout.tv_nsec += (ms % 1000) * 1000000; 717 if (abs_timeout.tv_nsec >= 1000000000) { 718 abs_timeout.tv_sec++; 719 abs_timeout.tv_nsec -= 1000000000; 720 } 721 722 int error = __pthread_mutex_timedlock(mutex, &abs_timeout, CLOCK_MONOTONIC); 723 if (error == ETIMEDOUT) { 724 error = EBUSY; 725 } 726 return error; 727} 728#endif 729 730int pthread_mutex_timedlock(pthread_mutex_t* mutex, const timespec* abs_timeout) { 731 return __pthread_mutex_timedlock(mutex, abs_timeout, CLOCK_REALTIME); 732} 733 734int pthread_mutex_destroy(pthread_mutex_t* mutex) { 735 // Use trylock to ensure that the mutex is valid and not already locked. 736 int error = pthread_mutex_trylock(mutex); 737 if (error != 0) { 738 return error; 739 } 740 mutex->value = 0xdead10cc; 741 return 0; 742} 743