/* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * SPDX-License-Identifier: MPL-2.0 * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, you can obtain one at https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ /*! \file */ #include #include #include #if defined(sun) && (defined(__sparc) || defined(__sparc__)) #include /* for smt_pause(3c) */ #endif /* if defined(sun) && (defined(__sparc) || defined(__sparc__)) */ #include #include #include #include #include #if USE_PTHREAD_RWLOCK #include #include void isc_rwlock_init(isc_rwlock_t *rwl, unsigned int read_quota, unsigned int write_quota) { UNUSED(read_quota); UNUSED(write_quota); REQUIRE(pthread_rwlock_init(&rwl->rwlock, NULL) == 0); atomic_init(&rwl->downgrade, false); } isc_result_t isc_rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { switch (type) { case isc_rwlocktype_read: REQUIRE(pthread_rwlock_rdlock(&rwl->rwlock) == 0); break; case isc_rwlocktype_write: while (true) { REQUIRE(pthread_rwlock_wrlock(&rwl->rwlock) == 0); /* Unlock if in middle of downgrade operation */ if (atomic_load_acquire(&rwl->downgrade)) { REQUIRE(pthread_rwlock_unlock(&rwl->rwlock) == 0); while (atomic_load_acquire(&rwl->downgrade)) { } continue; } break; } break; default: UNREACHABLE(); } return (ISC_R_SUCCESS); } isc_result_t isc_rwlock_trylock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { int ret = 0; switch (type) { case isc_rwlocktype_read: ret = pthread_rwlock_tryrdlock(&rwl->rwlock); break; case isc_rwlocktype_write: ret = pthread_rwlock_trywrlock(&rwl->rwlock); if ((ret == 0) && atomic_load_acquire(&rwl->downgrade)) { isc_rwlock_unlock(rwl, type); return (ISC_R_LOCKBUSY); } break; default: UNREACHABLE(); } switch (ret) { case 0: return (ISC_R_SUCCESS); case EBUSY: return (ISC_R_LOCKBUSY); case EAGAIN: return (ISC_R_LOCKBUSY); default: UNREACHABLE(); } } isc_result_t isc_rwlock_unlock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { UNUSED(type); REQUIRE(pthread_rwlock_unlock(&rwl->rwlock) == 0); return (ISC_R_SUCCESS); } isc_result_t isc_rwlock_tryupgrade(isc_rwlock_t *rwl) { UNUSED(rwl); return (ISC_R_LOCKBUSY); } void isc_rwlock_downgrade(isc_rwlock_t *rwl) { isc_result_t result; atomic_store_release(&rwl->downgrade, true); result = isc_rwlock_unlock(rwl, isc_rwlocktype_write); RUNTIME_CHECK(result == ISC_R_SUCCESS); result = isc_rwlock_lock(rwl, isc_rwlocktype_read); RUNTIME_CHECK(result == ISC_R_SUCCESS); atomic_store_release(&rwl->downgrade, false); } void isc_rwlock_destroy(isc_rwlock_t *rwl) { pthread_rwlock_destroy(&rwl->rwlock); } #else /* if USE_PTHREAD_RWLOCK */ #define RWLOCK_MAGIC ISC_MAGIC('R', 'W', 'L', 'k') #define VALID_RWLOCK(rwl) ISC_MAGIC_VALID(rwl, RWLOCK_MAGIC) #ifndef RWLOCK_DEFAULT_READ_QUOTA #define RWLOCK_DEFAULT_READ_QUOTA 4 #endif /* ifndef RWLOCK_DEFAULT_READ_QUOTA */ #ifndef RWLOCK_DEFAULT_WRITE_QUOTA #define RWLOCK_DEFAULT_WRITE_QUOTA 4 #endif /* ifndef RWLOCK_DEFAULT_WRITE_QUOTA */ #ifndef RWLOCK_MAX_ADAPTIVE_COUNT #define RWLOCK_MAX_ADAPTIVE_COUNT 100 #endif /* ifndef RWLOCK_MAX_ADAPTIVE_COUNT */ #if defined(_MSC_VER) #include #define isc_rwlock_pause() YieldProcessor() #elif defined(__x86_64__) #include #define isc_rwlock_pause() _mm_pause() #elif defined(__i386__) #define isc_rwlock_pause() __asm__ __volatile__("rep; nop") #elif defined(__ia64__) #define isc_rwlock_pause() __asm__ __volatile__("hint @pause") #elif defined(__arm__) && HAVE_ARM_YIELD #define isc_rwlock_pause() __asm__ __volatile__("yield") #elif defined(sun) && (defined(__sparc) || defined(__sparc__)) #define isc_rwlock_pause() smt_pause() #elif (defined(__sparc) || defined(__sparc__)) && HAVE_SPARC_PAUSE #define isc_rwlock_pause() __asm__ __volatile__("pause") #elif defined(__ppc__) || defined(_ARCH_PPC) || defined(_ARCH_PWR) || \ defined(_ARCH_PWR2) || defined(_POWER) #define isc_rwlock_pause() __asm__ volatile("or 27,27,27") #else /* if defined(_MSC_VER) */ #define isc_rwlock_pause() #endif /* if defined(_MSC_VER) */ static isc_result_t isc__rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type); #ifdef ISC_RWLOCK_TRACE #include /* Required for fprintf/stderr. */ #include /* Required for isc_thread_self(). */ static void print_lock(const char *operation, isc_rwlock_t *rwl, isc_rwlocktype_t type) { fprintf(stderr, "rwlock %p thread %" PRIuPTR " %s(%s): " "write_requests=%u, write_completions=%u, " "cnt_and_flag=0x%x, readers_waiting=%u, " "write_granted=%u, write_quota=%u\n", rwl, isc_thread_self(), operation, (type == isc_rwlocktype_read ? "read" : "write"), atomic_load_acquire(&rwl->write_requests), atomic_load_acquire(&rwl->write_completions), atomic_load_acquire(&rwl->cnt_and_flag), rwl->readers_waiting, atomic_load_acquire(&rwl->write_granted), rwl->write_quota); } #endif /* ISC_RWLOCK_TRACE */ void isc_rwlock_init(isc_rwlock_t *rwl, unsigned int read_quota, unsigned int write_quota) { REQUIRE(rwl != NULL); /* * In case there's trouble initializing, we zero magic now. If all * goes well, we'll set it to RWLOCK_MAGIC. */ rwl->magic = 0; atomic_init(&rwl->spins, 0); atomic_init(&rwl->write_requests, 0); atomic_init(&rwl->write_completions, 0); atomic_init(&rwl->cnt_and_flag, 0); rwl->readers_waiting = 0; atomic_init(&rwl->write_granted, 0); if (read_quota != 0) { UNEXPECTED_ERROR("read quota is not supported"); } if (write_quota == 0) { write_quota = RWLOCK_DEFAULT_WRITE_QUOTA; } rwl->write_quota = write_quota; isc_mutex_init(&rwl->lock); isc_condition_init(&rwl->readable); isc_condition_init(&rwl->writeable); rwl->magic = RWLOCK_MAGIC; } void isc_rwlock_destroy(isc_rwlock_t *rwl) { REQUIRE(VALID_RWLOCK(rwl)); REQUIRE(atomic_load_acquire(&rwl->write_requests) == atomic_load_acquire(&rwl->write_completions) && atomic_load_acquire(&rwl->cnt_and_flag) == 0 && rwl->readers_waiting == 0); rwl->magic = 0; (void)isc_condition_destroy(&rwl->readable); (void)isc_condition_destroy(&rwl->writeable); isc_mutex_destroy(&rwl->lock); } /* * When some architecture-dependent atomic operations are available, * rwlock can be more efficient than the generic algorithm defined below. * The basic algorithm is described in the following URL: * http://www.cs.rochester.edu/u/scott/synchronization/pseudocode/rw.html * * The key is to use the following integer variables modified atomically: * write_requests, write_completions, and cnt_and_flag. * * write_requests and write_completions act as a waiting queue for writers * in order to ensure the FIFO order. Both variables begin with the initial * value of 0. When a new writer tries to get a write lock, it increments * write_requests and gets the previous value of the variable as a "ticket". * When write_completions reaches the ticket number, the new writer can start * writing. When the writer completes its work, it increments * write_completions so that another new writer can start working. If the * write_requests is not equal to write_completions, it means a writer is now * working or waiting. In this case, a new readers cannot start reading, or * in other words, this algorithm basically prefers writers. * * cnt_and_flag is a "lock" shared by all readers and writers. This integer * variable is a kind of structure with two members: writer_flag (1 bit) and * reader_count (31 bits). The writer_flag shows whether a writer is working, * and the reader_count shows the number of readers currently working or almost * ready for working. A writer who has the current "ticket" tries to get the * lock by exclusively setting the writer_flag to 1, provided that the whole * 32-bit is 0 (meaning no readers or writers working). On the other hand, * a new reader tries to increment the "reader_count" field provided that * the writer_flag is 0 (meaning there is no writer working). * * If some of the above operations fail, the reader or the writer sleeps * until the related condition changes. When a working reader or writer * completes its work, some readers or writers are sleeping, and the condition * that suspended the reader or writer has changed, it wakes up the sleeping * readers or writers. * * As already noted, this algorithm basically prefers writers. In order to * prevent readers from starving, however, the algorithm also introduces the * "writer quota" (Q). When Q consecutive writers have completed their work, * suspending readers, the last writer will wake up the readers, even if a new * writer is waiting. * * Implementation specific note: due to the combination of atomic operations * and a mutex lock, ordering between the atomic operation and locks can be * very sensitive in some cases. In particular, it is generally very important * to check the atomic variable that requires a reader or writer to sleep after * locking the mutex and before actually sleeping; otherwise, it could be very * likely to cause a deadlock. For example, assume "var" is a variable * atomically modified, then the corresponding code would be: * if (var == need_sleep) { * LOCK(lock); * if (var == need_sleep) * WAIT(cond, lock); * UNLOCK(lock); * } * The second check is important, since "var" is protected by the atomic * operation, not by the mutex, and can be changed just before sleeping. * (The first "if" could be omitted, but this is also important in order to * make the code efficient by avoiding the use of the mutex unless it is * really necessary.) */ #define WRITER_ACTIVE 0x1 #define READER_INCR 0x2 static isc_result_t isc__rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { int32_t cntflag; REQUIRE(VALID_RWLOCK(rwl)); #ifdef ISC_RWLOCK_TRACE print_lock("prelock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ if (type == isc_rwlocktype_read) { if (atomic_load_acquire(&rwl->write_requests) != atomic_load_acquire(&rwl->write_completions)) { /* there is a waiting or active writer */ LOCK(&rwl->lock); if (atomic_load_acquire(&rwl->write_requests) != atomic_load_acquire(&rwl->write_completions)) { rwl->readers_waiting++; WAIT(&rwl->readable, &rwl->lock); rwl->readers_waiting--; } UNLOCK(&rwl->lock); } cntflag = atomic_fetch_add_release(&rwl->cnt_and_flag, READER_INCR); POST(cntflag); while (1) { if ((atomic_load_acquire(&rwl->cnt_and_flag) & WRITER_ACTIVE) == 0) { break; } /* A writer is still working */ LOCK(&rwl->lock); rwl->readers_waiting++; if ((atomic_load_acquire(&rwl->cnt_and_flag) & WRITER_ACTIVE) != 0) { WAIT(&rwl->readable, &rwl->lock); } rwl->readers_waiting--; UNLOCK(&rwl->lock); /* * Typically, the reader should be able to get a lock * at this stage: * (1) there should have been no pending writer when * the reader was trying to increment the * counter; otherwise, the writer should be in * the waiting queue, preventing the reader from * proceeding to this point. * (2) once the reader increments the counter, no * more writer can get a lock. * Still, it is possible another writer can work at * this point, e.g. in the following scenario: * A previous writer unlocks the writer lock. * This reader proceeds to point (1). * A new writer appears, and gets a new lock before * the reader increments the counter. * The reader then increments the counter. * The previous writer notices there is a waiting * reader who is almost ready, and wakes it up. * So, the reader needs to confirm whether it can now * read explicitly (thus we loop). Note that this is * not an infinite process, since the reader has * incremented the counter at this point. */ } /* * If we are temporarily preferred to writers due to the writer * quota, reset the condition (race among readers doesn't * matter). */ atomic_store_release(&rwl->write_granted, 0); } else { int32_t prev_writer; /* enter the waiting queue, and wait for our turn */ prev_writer = atomic_fetch_add_release(&rwl->write_requests, 1); while (atomic_load_acquire(&rwl->write_completions) != prev_writer) { LOCK(&rwl->lock); if (atomic_load_acquire(&rwl->write_completions) != prev_writer) { WAIT(&rwl->writeable, &rwl->lock); UNLOCK(&rwl->lock); continue; } UNLOCK(&rwl->lock); break; } while (!atomic_compare_exchange_weak_acq_rel( &rwl->cnt_and_flag, &(int_fast32_t){ 0 }, WRITER_ACTIVE)) { /* Another active reader or writer is working. */ LOCK(&rwl->lock); if (atomic_load_acquire(&rwl->cnt_and_flag) != 0) { WAIT(&rwl->writeable, &rwl->lock); } UNLOCK(&rwl->lock); } INSIST((atomic_load_acquire(&rwl->cnt_and_flag) & WRITER_ACTIVE)); atomic_fetch_add_release(&rwl->write_granted, 1); } #ifdef ISC_RWLOCK_TRACE print_lock("postlock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ return (ISC_R_SUCCESS); } isc_result_t isc_rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { int32_t cnt = 0; int32_t spins = atomic_load_acquire(&rwl->spins) * 2 + 10; int32_t max_cnt = ISC_MAX(spins, RWLOCK_MAX_ADAPTIVE_COUNT); isc_result_t result = ISC_R_SUCCESS; do { if (cnt++ >= max_cnt) { result = isc__rwlock_lock(rwl, type); break; } isc_rwlock_pause(); } while (isc_rwlock_trylock(rwl, type) != ISC_R_SUCCESS); atomic_fetch_add_release(&rwl->spins, (cnt - spins) / 8); return (result); } isc_result_t isc_rwlock_trylock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { int32_t cntflag; REQUIRE(VALID_RWLOCK(rwl)); #ifdef ISC_RWLOCK_TRACE print_lock("prelock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ if (type == isc_rwlocktype_read) { /* If a writer is waiting or working, we fail. */ if (atomic_load_acquire(&rwl->write_requests) != atomic_load_acquire(&rwl->write_completions)) { return (ISC_R_LOCKBUSY); } /* Otherwise, be ready for reading. */ cntflag = atomic_fetch_add_release(&rwl->cnt_and_flag, READER_INCR); if ((cntflag & WRITER_ACTIVE) != 0) { /* * A writer is working. We lose, and cancel the read * request. */ cntflag = atomic_fetch_sub_release(&rwl->cnt_and_flag, READER_INCR); /* * If no other readers are waiting and we've suspended * new writers in this short period, wake them up. */ if (cntflag == READER_INCR && atomic_load_acquire(&rwl->write_completions) != atomic_load_acquire(&rwl->write_requests)) { LOCK(&rwl->lock); BROADCAST(&rwl->writeable); UNLOCK(&rwl->lock); } return (ISC_R_LOCKBUSY); } } else { /* Try locking without entering the waiting queue. */ int_fast32_t zero = 0; if (!atomic_compare_exchange_strong_acq_rel( &rwl->cnt_and_flag, &zero, WRITER_ACTIVE)) { return (ISC_R_LOCKBUSY); } /* * XXXJT: jump into the queue, possibly breaking the writer * order. */ atomic_fetch_sub_release(&rwl->write_completions, 1); atomic_fetch_add_release(&rwl->write_granted, 1); } #ifdef ISC_RWLOCK_TRACE print_lock("postlock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ return (ISC_R_SUCCESS); } isc_result_t isc_rwlock_tryupgrade(isc_rwlock_t *rwl) { REQUIRE(VALID_RWLOCK(rwl)); int_fast32_t reader_incr = READER_INCR; /* Try to acquire write access. */ atomic_compare_exchange_strong_acq_rel(&rwl->cnt_and_flag, &reader_incr, WRITER_ACTIVE); /* * There must have been no writer, and there must have * been at least one reader. */ INSIST((reader_incr & WRITER_ACTIVE) == 0 && (reader_incr & ~WRITER_ACTIVE) != 0); if (reader_incr == READER_INCR) { /* * We are the only reader and have been upgraded. * Now jump into the head of the writer waiting queue. */ atomic_fetch_sub_release(&rwl->write_completions, 1); } else { return (ISC_R_LOCKBUSY); } return (ISC_R_SUCCESS); } void isc_rwlock_downgrade(isc_rwlock_t *rwl) { int32_t prev_readers; REQUIRE(VALID_RWLOCK(rwl)); /* Become an active reader. */ prev_readers = atomic_fetch_add_release(&rwl->cnt_and_flag, READER_INCR); /* We must have been a writer. */ INSIST((prev_readers & WRITER_ACTIVE) != 0); /* Complete write */ atomic_fetch_sub_release(&rwl->cnt_and_flag, WRITER_ACTIVE); atomic_fetch_add_release(&rwl->write_completions, 1); /* Resume other readers */ LOCK(&rwl->lock); if (rwl->readers_waiting > 0) { BROADCAST(&rwl->readable); } UNLOCK(&rwl->lock); } isc_result_t isc_rwlock_unlock(isc_rwlock_t *rwl, isc_rwlocktype_t type) { int32_t prev_cnt; REQUIRE(VALID_RWLOCK(rwl)); #ifdef ISC_RWLOCK_TRACE print_lock("preunlock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ if (type == isc_rwlocktype_read) { prev_cnt = atomic_fetch_sub_release(&rwl->cnt_and_flag, READER_INCR); /* * If we're the last reader and any writers are waiting, wake * them up. We need to wake up all of them to ensure the * FIFO order. */ if (prev_cnt == READER_INCR && atomic_load_acquire(&rwl->write_completions) != atomic_load_acquire(&rwl->write_requests)) { LOCK(&rwl->lock); BROADCAST(&rwl->writeable); UNLOCK(&rwl->lock); } } else { bool wakeup_writers = true; /* * Reset the flag, and (implicitly) tell other writers * we are done. */ atomic_fetch_sub_release(&rwl->cnt_and_flag, WRITER_ACTIVE); atomic_fetch_add_release(&rwl->write_completions, 1); if ((atomic_load_acquire(&rwl->write_granted) >= rwl->write_quota) || (atomic_load_acquire(&rwl->write_requests) == atomic_load_acquire(&rwl->write_completions)) || (atomic_load_acquire(&rwl->cnt_and_flag) & ~WRITER_ACTIVE)) { /* * We have passed the write quota, no writer is * waiting, or some readers are almost ready, pending * possible writers. Note that the last case can * happen even if write_requests != write_completions * (which means a new writer in the queue), so we need * to catch the case explicitly. */ LOCK(&rwl->lock); if (rwl->readers_waiting > 0) { wakeup_writers = false; BROADCAST(&rwl->readable); } UNLOCK(&rwl->lock); } if ((atomic_load_acquire(&rwl->write_requests) != atomic_load_acquire(&rwl->write_completions)) && wakeup_writers) { LOCK(&rwl->lock); BROADCAST(&rwl->writeable); UNLOCK(&rwl->lock); } } #ifdef ISC_RWLOCK_TRACE print_lock("postunlock", rwl, type); #endif /* ifdef ISC_RWLOCK_TRACE */ return (ISC_R_SUCCESS); } #endif /* USE_PTHREAD_RWLOCK */