freebsd-nq/lib/isc/rwlock.c
2009-05-31 00:11:36 +00:00

809 lines
22 KiB
C

/*
* Copyright (C) 2004, 2005, 2007, 2009 Internet Systems Consortium, Inc. ("ISC")
* Copyright (C) 1998-2001, 2003 Internet Software Consortium.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES WITH
* REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR ANY SPECIAL, DIRECT,
* INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM
* LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE
* OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
* PERFORMANCE OF THIS SOFTWARE.
*/
/* $Id: rwlock.c,v 1.44.332.2 2009/01/18 23:47:41 tbox Exp $ */
/*! \file */
#include <config.h>
#include <stddef.h>
#include <isc/atomic.h>
#include <isc/magic.h>
#include <isc/msgs.h>
#include <isc/platform.h>
#include <isc/rwlock.h>
#include <isc/util.h>
#define RWLOCK_MAGIC ISC_MAGIC('R', 'W', 'L', 'k')
#define VALID_RWLOCK(rwl) ISC_MAGIC_VALID(rwl, RWLOCK_MAGIC)
#ifdef ISC_PLATFORM_USETHREADS
#ifndef RWLOCK_DEFAULT_READ_QUOTA
#define RWLOCK_DEFAULT_READ_QUOTA 4
#endif
#ifndef RWLOCK_DEFAULT_WRITE_QUOTA
#define RWLOCK_DEFAULT_WRITE_QUOTA 4
#endif
#ifdef ISC_RWLOCK_TRACE
#include <stdio.h> /* Required for fprintf/stderr. */
#include <isc/thread.h> /* Required for isc_thread_self(). */
static void
print_lock(const char *operation, isc_rwlock_t *rwl, isc_rwlocktype_t type) {
fprintf(stderr,
isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PRINTLOCK,
"rwlock %p thread %lu %s(%s): %s, %u active, "
"%u granted, %u rwaiting, %u wwaiting\n"),
rwl, isc_thread_self(), operation,
(type == isc_rwlocktype_read ?
isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_READ, "read") :
isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_WRITE, "write")),
(rwl->type == isc_rwlocktype_read ?
isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_READING, "reading") :
isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_WRITING, "writing")),
rwl->active, rwl->granted, rwl->readers_waiting,
rwl->writers_waiting);
}
#endif
isc_result_t
isc_rwlock_init(isc_rwlock_t *rwl, unsigned int read_quota,
unsigned int write_quota)
{
isc_result_t result;
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;
#if defined(ISC_PLATFORM_HAVEXADD) && defined(ISC_PLATFORM_HAVECMPXCHG)
rwl->write_requests = 0;
rwl->write_completions = 0;
rwl->cnt_and_flag = 0;
rwl->readers_waiting = 0;
rwl->write_granted = 0;
if (read_quota != 0) {
UNEXPECTED_ERROR(__FILE__, __LINE__,
"read quota is not supported");
}
if (write_quota == 0)
write_quota = RWLOCK_DEFAULT_WRITE_QUOTA;
rwl->write_quota = write_quota;
#else
rwl->type = isc_rwlocktype_read;
rwl->original = isc_rwlocktype_none;
rwl->active = 0;
rwl->granted = 0;
rwl->readers_waiting = 0;
rwl->writers_waiting = 0;
if (read_quota == 0)
read_quota = RWLOCK_DEFAULT_READ_QUOTA;
rwl->read_quota = read_quota;
if (write_quota == 0)
write_quota = RWLOCK_DEFAULT_WRITE_QUOTA;
rwl->write_quota = write_quota;
#endif
result = isc_mutex_init(&rwl->lock);
if (result != ISC_R_SUCCESS)
return (result);
result = isc_condition_init(&rwl->readable);
if (result != ISC_R_SUCCESS) {
UNEXPECTED_ERROR(__FILE__, __LINE__,
"isc_condition_init(readable) %s: %s",
isc_msgcat_get(isc_msgcat, ISC_MSGSET_GENERAL,
ISC_MSG_FAILED, "failed"),
isc_result_totext(result));
result = ISC_R_UNEXPECTED;
goto destroy_lock;
}
result = isc_condition_init(&rwl->writeable);
if (result != ISC_R_SUCCESS) {
UNEXPECTED_ERROR(__FILE__, __LINE__,
"isc_condition_init(writeable) %s: %s",
isc_msgcat_get(isc_msgcat, ISC_MSGSET_GENERAL,
ISC_MSG_FAILED, "failed"),
isc_result_totext(result));
result = ISC_R_UNEXPECTED;
goto destroy_rcond;
}
rwl->magic = RWLOCK_MAGIC;
return (ISC_R_SUCCESS);
destroy_rcond:
(void)isc_condition_destroy(&rwl->readable);
destroy_lock:
DESTROYLOCK(&rwl->lock);
return (result);
}
void
isc_rwlock_destroy(isc_rwlock_t *rwl) {
REQUIRE(VALID_RWLOCK(rwl));
#if defined(ISC_PLATFORM_HAVEXADD) && defined(ISC_PLATFORM_HAVECMPXCHG)
REQUIRE(rwl->write_requests == rwl->write_completions &&
rwl->cnt_and_flag == 0 && rwl->readers_waiting == 0);
#else
LOCK(&rwl->lock);
REQUIRE(rwl->active == 0 &&
rwl->readers_waiting == 0 &&
rwl->writers_waiting == 0);
UNLOCK(&rwl->lock);
#endif
rwl->magic = 0;
(void)isc_condition_destroy(&rwl->readable);
(void)isc_condition_destroy(&rwl->writeable);
DESTROYLOCK(&rwl->lock);
}
#if defined(ISC_PLATFORM_HAVEXADD) && defined(ISC_PLATFORM_HAVECMPXCHG)
/*
* 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
isc_result_t
isc_rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
isc_int32_t cntflag;
REQUIRE(VALID_RWLOCK(rwl));
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PRELOCK, "prelock"), rwl, type);
#endif
if (type == isc_rwlocktype_read) {
if (rwl->write_requests != rwl->write_completions) {
/* there is a waiting or active writer */
LOCK(&rwl->lock);
if (rwl->write_requests != rwl->write_completions) {
rwl->readers_waiting++;
WAIT(&rwl->readable, &rwl->lock);
rwl->readers_waiting--;
}
UNLOCK(&rwl->lock);
}
cntflag = isc_atomic_xadd(&rwl->cnt_and_flag, READER_INCR);
while (1) {
if ((rwl->cnt_and_flag & WRITER_ACTIVE) == 0)
break;
/* A writer is still working */
LOCK(&rwl->lock);
rwl->readers_waiting++;
if ((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).
*/
rwl->write_granted = 0;
} else {
isc_int32_t prev_writer;
/* enter the waiting queue, and wait for our turn */
prev_writer = isc_atomic_xadd(&rwl->write_requests, 1);
while (rwl->write_completions != prev_writer) {
LOCK(&rwl->lock);
if (rwl->write_completions != prev_writer) {
WAIT(&rwl->writeable, &rwl->lock);
UNLOCK(&rwl->lock);
continue;
}
UNLOCK(&rwl->lock);
break;
}
while (1) {
cntflag = isc_atomic_cmpxchg(&rwl->cnt_and_flag, 0,
WRITER_ACTIVE);
if (cntflag == 0)
break;
/* Another active reader or writer is working. */
LOCK(&rwl->lock);
if (rwl->cnt_and_flag != 0)
WAIT(&rwl->writeable, &rwl->lock);
UNLOCK(&rwl->lock);
}
INSIST((rwl->cnt_and_flag & WRITER_ACTIVE) != 0);
rwl->write_granted++;
}
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_POSTLOCK, "postlock"), rwl, type);
#endif
return (ISC_R_SUCCESS);
}
isc_result_t
isc_rwlock_trylock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
isc_int32_t cntflag;
REQUIRE(VALID_RWLOCK(rwl));
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PRELOCK, "prelock"), rwl, type);
#endif
if (type == isc_rwlocktype_read) {
/* If a writer is waiting or working, we fail. */
if (rwl->write_requests != rwl->write_completions)
return (ISC_R_LOCKBUSY);
/* Otherwise, be ready for reading. */
cntflag = isc_atomic_xadd(&rwl->cnt_and_flag, READER_INCR);
if ((cntflag & WRITER_ACTIVE) != 0) {
/*
* A writer is working. We lose, and cancel the read
* request.
*/
cntflag = isc_atomic_xadd(&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 &&
rwl->write_completions != rwl->write_requests) {
LOCK(&rwl->lock);
BROADCAST(&rwl->writeable);
UNLOCK(&rwl->lock);
}
return (ISC_R_LOCKBUSY);
}
} else {
/* Try locking without entering the waiting queue. */
cntflag = isc_atomic_cmpxchg(&rwl->cnt_and_flag, 0,
WRITER_ACTIVE);
if (cntflag != 0)
return (ISC_R_LOCKBUSY);
/*
* XXXJT: jump into the queue, possibly breaking the writer
* order.
*/
(void)isc_atomic_xadd(&rwl->write_completions, -1);
rwl->write_granted++;
}
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_POSTLOCK, "postlock"), rwl, type);
#endif
return (ISC_R_SUCCESS);
}
isc_result_t
isc_rwlock_tryupgrade(isc_rwlock_t *rwl) {
isc_int32_t prevcnt;
REQUIRE(VALID_RWLOCK(rwl));
/* Try to acquire write access. */
prevcnt = isc_atomic_cmpxchg(&rwl->cnt_and_flag,
READER_INCR, WRITER_ACTIVE);
/*
* There must have been no writer, and there must have been at least
* one reader.
*/
INSIST((prevcnt & WRITER_ACTIVE) == 0 &&
(prevcnt & ~WRITER_ACTIVE) != 0);
if (prevcnt == READER_INCR) {
/*
* We are the only reader and have been upgraded.
* Now jump into the head of the writer waiting queue.
*/
(void)isc_atomic_xadd(&rwl->write_completions, -1);
} else
return (ISC_R_LOCKBUSY);
return (ISC_R_SUCCESS);
}
void
isc_rwlock_downgrade(isc_rwlock_t *rwl) {
isc_int32_t prev_readers;
REQUIRE(VALID_RWLOCK(rwl));
/* Become an active reader. */
prev_readers = isc_atomic_xadd(&rwl->cnt_and_flag, READER_INCR);
/* We must have been a writer. */
INSIST((prev_readers & WRITER_ACTIVE) != 0);
/* Complete write */
(void)isc_atomic_xadd(&rwl->cnt_and_flag, -WRITER_ACTIVE);
(void)isc_atomic_xadd(&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) {
isc_int32_t prev_cnt;
REQUIRE(VALID_RWLOCK(rwl));
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PREUNLOCK, "preunlock"), rwl, type);
#endif
if (type == isc_rwlocktype_read) {
prev_cnt = isc_atomic_xadd(&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 &&
rwl->write_completions != rwl->write_requests) {
LOCK(&rwl->lock);
BROADCAST(&rwl->writeable);
UNLOCK(&rwl->lock);
}
} else {
isc_boolean_t wakeup_writers = ISC_TRUE;
/*
* Reset the flag, and (implicitly) tell other writers
* we are done.
*/
(void)isc_atomic_xadd(&rwl->cnt_and_flag, -WRITER_ACTIVE);
(void)isc_atomic_xadd(&rwl->write_completions, 1);
if (rwl->write_granted >= rwl->write_quota ||
rwl->write_requests == rwl->write_completions ||
(rwl->cnt_and_flag & ~WRITER_ACTIVE) != 0) {
/*
* 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 = ISC_FALSE;
BROADCAST(&rwl->readable);
}
UNLOCK(&rwl->lock);
}
if (rwl->write_requests != rwl->write_completions &&
wakeup_writers) {
LOCK(&rwl->lock);
BROADCAST(&rwl->writeable);
UNLOCK(&rwl->lock);
}
}
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_POSTUNLOCK, "postunlock"),
rwl, type);
#endif
return (ISC_R_SUCCESS);
}
#else /* ISC_PLATFORM_HAVEXADD && ISC_PLATFORM_HAVECMPXCHG */
static isc_result_t
doit(isc_rwlock_t *rwl, isc_rwlocktype_t type, isc_boolean_t nonblock) {
isc_boolean_t skip = ISC_FALSE;
isc_boolean_t done = ISC_FALSE;
isc_result_t result = ISC_R_SUCCESS;
REQUIRE(VALID_RWLOCK(rwl));
LOCK(&rwl->lock);
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PRELOCK, "prelock"), rwl, type);
#endif
if (type == isc_rwlocktype_read) {
if (rwl->readers_waiting != 0)
skip = ISC_TRUE;
while (!done) {
if (!skip &&
((rwl->active == 0 ||
(rwl->type == isc_rwlocktype_read &&
(rwl->writers_waiting == 0 ||
rwl->granted < rwl->read_quota)))))
{
rwl->type = isc_rwlocktype_read;
rwl->active++;
rwl->granted++;
done = ISC_TRUE;
} else if (nonblock) {
result = ISC_R_LOCKBUSY;
done = ISC_TRUE;
} else {
skip = ISC_FALSE;
rwl->readers_waiting++;
WAIT(&rwl->readable, &rwl->lock);
rwl->readers_waiting--;
}
}
} else {
if (rwl->writers_waiting != 0)
skip = ISC_TRUE;
while (!done) {
if (!skip && rwl->active == 0) {
rwl->type = isc_rwlocktype_write;
rwl->active = 1;
rwl->granted++;
done = ISC_TRUE;
} else if (nonblock) {
result = ISC_R_LOCKBUSY;
done = ISC_TRUE;
} else {
skip = ISC_FALSE;
rwl->writers_waiting++;
WAIT(&rwl->writeable, &rwl->lock);
rwl->writers_waiting--;
}
}
}
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_POSTLOCK, "postlock"), rwl, type);
#endif
UNLOCK(&rwl->lock);
return (result);
}
isc_result_t
isc_rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
return (doit(rwl, type, ISC_FALSE));
}
isc_result_t
isc_rwlock_trylock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
return (doit(rwl, type, ISC_TRUE));
}
isc_result_t
isc_rwlock_tryupgrade(isc_rwlock_t *rwl) {
isc_result_t result = ISC_R_SUCCESS;
REQUIRE(VALID_RWLOCK(rwl));
LOCK(&rwl->lock);
REQUIRE(rwl->type == isc_rwlocktype_read);
REQUIRE(rwl->active != 0);
/* If we are the only reader then succeed. */
if (rwl->active == 1) {
rwl->original = (rwl->original == isc_rwlocktype_none) ?
isc_rwlocktype_read : isc_rwlocktype_none;
rwl->type = isc_rwlocktype_write;
} else
result = ISC_R_LOCKBUSY;
UNLOCK(&rwl->lock);
return (result);
}
void
isc_rwlock_downgrade(isc_rwlock_t *rwl) {
REQUIRE(VALID_RWLOCK(rwl));
LOCK(&rwl->lock);
REQUIRE(rwl->type == isc_rwlocktype_write);
REQUIRE(rwl->active == 1);
rwl->type = isc_rwlocktype_read;
rwl->original = (rwl->original == isc_rwlocktype_none) ?
isc_rwlocktype_write : isc_rwlocktype_none;
/*
* Resume processing any read request that were blocked when
* we upgraded.
*/
if (rwl->original == isc_rwlocktype_none &&
(rwl->writers_waiting == 0 || rwl->granted < rwl->read_quota) &&
rwl->readers_waiting > 0)
BROADCAST(&rwl->readable);
UNLOCK(&rwl->lock);
}
isc_result_t
isc_rwlock_unlock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
REQUIRE(VALID_RWLOCK(rwl));
LOCK(&rwl->lock);
REQUIRE(rwl->type == type);
UNUSED(type);
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_PREUNLOCK, "preunlock"), rwl, type);
#endif
INSIST(rwl->active > 0);
rwl->active--;
if (rwl->active == 0) {
if (rwl->original != isc_rwlocktype_none) {
rwl->type = rwl->original;
rwl->original = isc_rwlocktype_none;
}
if (rwl->type == isc_rwlocktype_read) {
rwl->granted = 0;
if (rwl->writers_waiting > 0) {
rwl->type = isc_rwlocktype_write;
SIGNAL(&rwl->writeable);
} else if (rwl->readers_waiting > 0) {
/* Does this case ever happen? */
BROADCAST(&rwl->readable);
}
} else {
if (rwl->readers_waiting > 0) {
if (rwl->writers_waiting > 0 &&
rwl->granted < rwl->write_quota) {
SIGNAL(&rwl->writeable);
} else {
rwl->granted = 0;
rwl->type = isc_rwlocktype_read;
BROADCAST(&rwl->readable);
}
} else if (rwl->writers_waiting > 0) {
rwl->granted = 0;
SIGNAL(&rwl->writeable);
} else {
rwl->granted = 0;
}
}
}
INSIST(rwl->original == isc_rwlocktype_none);
#ifdef ISC_RWLOCK_TRACE
print_lock(isc_msgcat_get(isc_msgcat, ISC_MSGSET_RWLOCK,
ISC_MSG_POSTUNLOCK, "postunlock"),
rwl, type);
#endif
UNLOCK(&rwl->lock);
return (ISC_R_SUCCESS);
}
#endif /* ISC_PLATFORM_HAVEXADD && ISC_PLATFORM_HAVECMPXCHG */
#else /* ISC_PLATFORM_USETHREADS */
isc_result_t
isc_rwlock_init(isc_rwlock_t *rwl, unsigned int read_quota,
unsigned int write_quota)
{
REQUIRE(rwl != NULL);
UNUSED(read_quota);
UNUSED(write_quota);
rwl->type = isc_rwlocktype_read;
rwl->active = 0;
rwl->magic = RWLOCK_MAGIC;
return (ISC_R_SUCCESS);
}
isc_result_t
isc_rwlock_lock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
REQUIRE(VALID_RWLOCK(rwl));
if (type == isc_rwlocktype_read) {
if (rwl->type != isc_rwlocktype_read && rwl->active != 0)
return (ISC_R_LOCKBUSY);
rwl->type = isc_rwlocktype_read;
rwl->active++;
} else {
if (rwl->active != 0)
return (ISC_R_LOCKBUSY);
rwl->type = isc_rwlocktype_write;
rwl->active = 1;
}
return (ISC_R_SUCCESS);
}
isc_result_t
isc_rwlock_trylock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
return (isc_rwlock_lock(rwl, type));
}
isc_result_t
isc_rwlock_tryupgrade(isc_rwlock_t *rwl) {
isc_result_t result = ISC_R_SUCCESS;
REQUIRE(VALID_RWLOCK(rwl));
REQUIRE(rwl->type == isc_rwlocktype_read);
REQUIRE(rwl->active != 0);
/* If we are the only reader then succeed. */
if (rwl->active == 1)
rwl->type = isc_rwlocktype_write;
else
result = ISC_R_LOCKBUSY;
return (result);
}
void
isc_rwlock_downgrade(isc_rwlock_t *rwl) {
REQUIRE(VALID_RWLOCK(rwl));
REQUIRE(rwl->type == isc_rwlocktype_write);
REQUIRE(rwl->active == 1);
rwl->type = isc_rwlocktype_read;
}
isc_result_t
isc_rwlock_unlock(isc_rwlock_t *rwl, isc_rwlocktype_t type) {
REQUIRE(VALID_RWLOCK(rwl));
REQUIRE(rwl->type == type);
UNUSED(type);
INSIST(rwl->active > 0);
rwl->active--;
return (ISC_R_SUCCESS);
}
void
isc_rwlock_destroy(isc_rwlock_t *rwl) {
REQUIRE(rwl != NULL);
REQUIRE(rwl->active == 0);
rwl->magic = 0;
}
#endif /* ISC_PLATFORM_USETHREADS */