/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #define atomic_cas_64 _atomic_cas_64 #include "lint.h" #include "thr_uberdata.h" #include #include #include #if defined(THREAD_DEBUG) #define INCR32(x) (((x) != UINT32_MAX)? (x)++ : 0) #define INCR(x) ((x)++) #define DECR(x) ((x)--) #define MAXINCR(m, x) ((m < ++x)? (m = x) : 0) #else #define INCR32(x) #define INCR(x) #define DECR(x) #define MAXINCR(m, x) #endif /* * This mutex is initialized to be held by lwp#1. * It is used to block a thread that has returned from a mutex_lock() * of a LOCK_PRIO_INHERIT mutex with an unrecoverable error. */ mutex_t stall_mutex = DEFAULTMUTEX; static int shared_mutex_held(mutex_t *); static int mutex_queuelock_adaptive(mutex_t *); static void mutex_wakeup_all(mutex_t *); /* * Lock statistics support functions. */ void record_begin_hold(tdb_mutex_stats_t *msp) { tdb_incr(msp->mutex_lock); msp->mutex_begin_hold = gethrtime(); } hrtime_t record_hold_time(tdb_mutex_stats_t *msp) { hrtime_t now = gethrtime(); if (msp->mutex_begin_hold) msp->mutex_hold_time += now - msp->mutex_begin_hold; msp->mutex_begin_hold = 0; return (now); } /* * Called once at library initialization. */ void mutex_setup(void) { if (set_lock_byte(&stall_mutex.mutex_lockw)) thr_panic("mutex_setup() cannot acquire stall_mutex"); stall_mutex.mutex_owner = (uintptr_t)curthread; } /* * The default spin count of 1000 is experimentally determined. * On sun4u machines with any number of processors it could be raised * to 10,000 but that (experimentally) makes almost no difference. * The environment variable: * _THREAD_ADAPTIVE_SPIN=count * can be used to override and set the count in the range [0 .. 1,000,000]. */ int thread_adaptive_spin = 1000; uint_t thread_max_spinners = 100; int thread_queue_verify = 0; static int ncpus; /* * Distinguish spinning for queue locks from spinning for regular locks. * We try harder to acquire queue locks by spinning. * The environment variable: * _THREAD_QUEUE_SPIN=count * can be used to override and set the count in the range [0 .. 1,000,000]. */ int thread_queue_spin = 10000; #define ALL_ATTRIBUTES \ (LOCK_RECURSIVE | LOCK_ERRORCHECK | \ LOCK_PRIO_INHERIT | LOCK_PRIO_PROTECT | \ LOCK_ROBUST) /* * 'type' can be one of USYNC_THREAD, USYNC_PROCESS, or USYNC_PROCESS_ROBUST, * augmented by zero or more the flags: * LOCK_RECURSIVE * LOCK_ERRORCHECK * LOCK_PRIO_INHERIT * LOCK_PRIO_PROTECT * LOCK_ROBUST */ #pragma weak mutex_init = __mutex_init #pragma weak _mutex_init = __mutex_init /* ARGSUSED2 */ int __mutex_init(mutex_t *mp, int type, void *arg) { int basetype = (type & ~ALL_ATTRIBUTES); const pcclass_t *pccp; int error = 0; int ceil; if (basetype == USYNC_PROCESS_ROBUST) { /* * USYNC_PROCESS_ROBUST is a deprecated historical type. * We change it into (USYNC_PROCESS | LOCK_ROBUST) but * retain the USYNC_PROCESS_ROBUST flag so we can return * ELOCKUNMAPPED when necessary (only USYNC_PROCESS_ROBUST * mutexes will ever draw ELOCKUNMAPPED). */ type |= (USYNC_PROCESS | LOCK_ROBUST); basetype = USYNC_PROCESS; } if (type & LOCK_PRIO_PROTECT) pccp = get_info_by_policy(SCHED_FIFO); if ((basetype != USYNC_THREAD && basetype != USYNC_PROCESS) || (type & (LOCK_PRIO_INHERIT | LOCK_PRIO_PROTECT)) == (LOCK_PRIO_INHERIT | LOCK_PRIO_PROTECT) || ((type & LOCK_PRIO_PROTECT) && ((ceil = *(int *)arg) < pccp->pcc_primin || ceil > pccp->pcc_primax))) { error = EINVAL; } else if (type & LOCK_ROBUST) { /* * Callers of mutex_init() with the LOCK_ROBUST attribute * are required to pass an initially all-zero mutex. * Multiple calls to mutex_init() are allowed; all but * the first return EBUSY. A call to mutex_init() is * allowed to make an inconsistent robust lock consistent * (for historical usage, even though the proper interface * for this is mutex_consistent()). Note that we use * atomic_or_16() to set the LOCK_INITED flag so as * not to disturb surrounding bits (LOCK_OWNERDEAD, etc). */ extern void _atomic_or_16(volatile uint16_t *, uint16_t); if (!(mp->mutex_flag & LOCK_INITED)) { mp->mutex_type = (uint8_t)type; _atomic_or_16(&mp->mutex_flag, LOCK_INITED); mp->mutex_magic = MUTEX_MAGIC; } else if (type != mp->mutex_type || ((type & LOCK_PRIO_PROTECT) && mp->mutex_ceiling != ceil)) { error = EINVAL; } else if (__mutex_consistent(mp) != 0) { error = EBUSY; } /* register a process robust mutex with the kernel */ if (basetype == USYNC_PROCESS) register_lock(mp); } else { (void) memset(mp, 0, sizeof (*mp)); mp->mutex_type = (uint8_t)type; mp->mutex_flag = LOCK_INITED; mp->mutex_magic = MUTEX_MAGIC; } if (error == 0 && (type & LOCK_PRIO_PROTECT)) { mp->mutex_ceiling = ceil; } return (error); } /* * Delete mp from list of ceiling mutexes owned by curthread. * Return 1 if the head of the chain was updated. */ int _ceil_mylist_del(mutex_t *mp) { ulwp_t *self = curthread; mxchain_t **mcpp; mxchain_t *mcp; for (mcpp = &self->ul_mxchain; (mcp = *mcpp) != NULL; mcpp = &mcp->mxchain_next) { if (mcp->mxchain_mx == mp) { *mcpp = mcp->mxchain_next; lfree(mcp, sizeof (*mcp)); return (mcpp == &self->ul_mxchain); } } return (0); } /* * Add mp to the list of ceiling mutexes owned by curthread. * Return ENOMEM if no memory could be allocated. */ int _ceil_mylist_add(mutex_t *mp) { ulwp_t *self = curthread; mxchain_t *mcp; if ((mcp = lmalloc(sizeof (*mcp))) == NULL) return (ENOMEM); mcp->mxchain_mx = mp; mcp->mxchain_next = self->ul_mxchain; self->ul_mxchain = mcp; return (0); } /* * Helper function for _ceil_prio_inherit() and _ceil_prio_waive(), below. */ static void set_rt_priority(ulwp_t *self, int prio) { pcparms_t pcparm; pcparm.pc_cid = self->ul_rtclassid; ((rtparms_t *)pcparm.pc_clparms)->rt_tqnsecs = RT_NOCHANGE; ((rtparms_t *)pcparm.pc_clparms)->rt_pri = prio; (void) priocntl(P_LWPID, self->ul_lwpid, PC_SETPARMS, &pcparm); } /* * Inherit priority from ceiling. * This changes the effective priority, not the assigned priority. */ void _ceil_prio_inherit(int prio) { ulwp_t *self = curthread; self->ul_epri = prio; set_rt_priority(self, prio); } /* * Waive inherited ceiling priority. Inherit from head of owned ceiling locks * if holding at least one ceiling lock. If no ceiling locks are held at this * point, disinherit completely, reverting back to assigned priority. */ void _ceil_prio_waive(void) { ulwp_t *self = curthread; mxchain_t *mcp = self->ul_mxchain; int prio; if (mcp == NULL) { prio = self->ul_pri; self->ul_epri = 0; } else { prio = mcp->mxchain_mx->mutex_ceiling; self->ul_epri = prio; } set_rt_priority(self, prio); } /* * Clear the lock byte. Retain the waiters byte and the spinners byte. * Return the old value of the lock word. */ static uint32_t clear_lockbyte(volatile uint32_t *lockword) { uint32_t old; uint32_t new; do { old = *lockword; new = old & ~LOCKMASK; } while (atomic_cas_32(lockword, old, new) != old); return (old); } /* * Same as clear_lockbyte(), but operates on mutex_lockword64. * The mutex_ownerpid field is cleared along with the lock byte. */ static uint64_t clear_lockbyte64(volatile uint64_t *lockword64) { uint64_t old; uint64_t new; do { old = *lockword64; new = old & ~LOCKMASK64; } while (atomic_cas_64(lockword64, old, new) != old); return (old); } /* * Similar to set_lock_byte(), which only tries to set the lock byte. * Here, we attempt to set the lock byte AND the mutex_ownerpid, * keeping the remaining bytes constant. */ static int set_lock_byte64(volatile uint64_t *lockword64, pid_t ownerpid) { uint64_t old; uint64_t new; old = *lockword64 & ~LOCKMASK64; new = old | ((uint64_t)(uint_t)ownerpid << PIDSHIFT) | LOCKBYTE64; if (atomic_cas_64(lockword64, old, new) == old) return (LOCKCLEAR); return (LOCKSET); } /* * Increment the spinners count in the mutex lock word. * Return 0 on success. Return -1 if the count would overflow. */ static int spinners_incr(volatile uint32_t *lockword, uint8_t max_spinners) { uint32_t old; uint32_t new; do { old = *lockword; if (((old & SPINNERMASK) >> SPINNERSHIFT) >= max_spinners) return (-1); new = old + (1 << SPINNERSHIFT); } while (atomic_cas_32(lockword, old, new) != old); return (0); } /* * Decrement the spinners count in the mutex lock word. * Return the new value of the lock word. */ static uint32_t spinners_decr(volatile uint32_t *lockword) { uint32_t old; uint32_t new; do { new = old = *lockword; if (new & SPINNERMASK) new -= (1 << SPINNERSHIFT); } while (atomic_cas_32(lockword, old, new) != old); return (new); } /* * Non-preemptive spin locks. Used by queue_lock(). * No lock statistics are gathered for these locks. * No DTrace probes are provided for these locks. */ void spin_lock_set(mutex_t *mp) { ulwp_t *self = curthread; no_preempt(self); if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; return; } /* * Spin for a while, attempting to acquire the lock. */ INCR32(self->ul_spin_lock_spin); if (mutex_queuelock_adaptive(mp) == 0 || set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; return; } /* * Try harder if we were previously at a no premption level. */ if (self->ul_preempt > 1) { INCR32(self->ul_spin_lock_spin2); if (mutex_queuelock_adaptive(mp) == 0 || set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; return; } } /* * Give up and block in the kernel for the mutex. */ INCR32(self->ul_spin_lock_sleep); (void) ___lwp_mutex_timedlock(mp, NULL); mp->mutex_owner = (uintptr_t)self; } void spin_lock_clear(mutex_t *mp) { ulwp_t *self = curthread; mp->mutex_owner = 0; if (atomic_swap_32(&mp->mutex_lockword, 0) & WAITERMASK) { (void) ___lwp_mutex_wakeup(mp, 0); INCR32(self->ul_spin_lock_wakeup); } preempt(self); } /* * Allocate the sleep queue hash table. */ void queue_alloc(void) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; queue_head_t *qp; void *data; int i; /* * No locks are needed; we call here only when single-threaded. */ ASSERT(self == udp->ulwp_one); ASSERT(!udp->uberflags.uf_mt); if ((data = mmap(NULL, 2 * QHASHSIZE * sizeof (queue_head_t), PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANON, -1, (off_t)0)) == MAP_FAILED) thr_panic("cannot allocate thread queue_head table"); udp->queue_head = qp = (queue_head_t *)data; for (i = 0; i < 2 * QHASHSIZE; qp++, i++) { qp->qh_type = (i < QHASHSIZE)? MX : CV; qp->qh_lock.mutex_flag = LOCK_INITED; qp->qh_lock.mutex_magic = MUTEX_MAGIC; qp->qh_hlist = &qp->qh_def_root; #if defined(THREAD_DEBUG) qp->qh_hlen = 1; qp->qh_hmax = 1; #endif } } #if defined(THREAD_DEBUG) /* * Debugging: verify correctness of a sleep queue. */ void QVERIFY(queue_head_t *qp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; queue_root_t *qrp; ulwp_t *ulwp; ulwp_t *prev; uint_t index; uint32_t cnt; char qtype; void *wchan; ASSERT(qp >= udp->queue_head && (qp - udp->queue_head) < 2 * QHASHSIZE); ASSERT(MUTEX_OWNED(&qp->qh_lock, self)); for (cnt = 0, qrp = qp->qh_hlist; qrp != NULL; qrp = qrp->qr_next) { cnt++; ASSERT((qrp->qr_head != NULL && qrp->qr_tail != NULL) || (qrp->qr_head == NULL && qrp->qr_tail == NULL)); } ASSERT(qp->qh_hlen == cnt && qp->qh_hmax >= cnt); qtype = ((qp - udp->queue_head) < QHASHSIZE)? MX : CV; ASSERT(qp->qh_type == qtype); if (!thread_queue_verify) return; /* real expensive stuff, only for _THREAD_QUEUE_VERIFY */ for (cnt = 0, qrp = qp->qh_hlist; qrp != NULL; qrp = qrp->qr_next) { for (prev = NULL, ulwp = qrp->qr_head; ulwp != NULL; prev = ulwp, ulwp = ulwp->ul_link) { cnt++; if (ulwp->ul_writer) ASSERT(prev == NULL || prev->ul_writer); ASSERT(ulwp->ul_qtype == qtype); ASSERT(ulwp->ul_wchan != NULL); ASSERT(ulwp->ul_sleepq == qp); wchan = ulwp->ul_wchan; ASSERT(qrp->qr_wchan == wchan); index = QUEUE_HASH(wchan, qtype); ASSERT(&udp->queue_head[index] == qp); } ASSERT(qrp->qr_tail == prev); } ASSERT(qp->qh_qlen == cnt); } #else /* THREAD_DEBUG */ #define QVERIFY(qp) #endif /* THREAD_DEBUG */ /* * Acquire a queue head. */ queue_head_t * queue_lock(void *wchan, int qtype) { uberdata_t *udp = curthread->ul_uberdata; queue_head_t *qp; queue_root_t *qrp; ASSERT(qtype == MX || qtype == CV); /* * It is possible that we could be called while still single-threaded. * If so, we call queue_alloc() to allocate the queue_head[] array. */ if ((qp = udp->queue_head) == NULL) { queue_alloc(); qp = udp->queue_head; } qp += QUEUE_HASH(wchan, qtype); spin_lock_set(&qp->qh_lock); for (qrp = qp->qh_hlist; qrp != NULL; qrp = qrp->qr_next) if (qrp->qr_wchan == wchan) break; if (qrp == NULL && qp->qh_def_root.qr_head == NULL) { /* the default queue root is available; use it */ qrp = &qp->qh_def_root; qrp->qr_wchan = wchan; ASSERT(qrp->qr_next == NULL); ASSERT(qrp->qr_tail == NULL && qrp->qr_rtcount == 0 && qrp->qr_qlen == 0); } qp->qh_wchan = wchan; /* valid until queue_unlock() is called */ qp->qh_root = qrp; /* valid until queue_unlock() is called */ INCR32(qp->qh_lockcount); QVERIFY(qp); return (qp); } /* * Release a queue head. */ void queue_unlock(queue_head_t *qp) { QVERIFY(qp); spin_lock_clear(&qp->qh_lock); } /* * For rwlock queueing, we must queue writers ahead of readers of the * same priority. We do this by making writers appear to have a half * point higher priority for purposes of priority comparisons below. */ #define CMP_PRIO(ulwp) ((real_priority(ulwp) << 1) + (ulwp)->ul_writer) void enqueue(queue_head_t *qp, ulwp_t *ulwp, int force_fifo) { queue_root_t *qrp; ulwp_t **ulwpp; ulwp_t *next; int pri = CMP_PRIO(ulwp); ASSERT(MUTEX_OWNED(&qp->qh_lock, curthread)); ASSERT(ulwp->ul_sleepq != qp); if ((qrp = qp->qh_root) == NULL) { /* use the thread's queue root for the linkage */ qrp = &ulwp->ul_queue_root; qrp->qr_next = qp->qh_hlist; qrp->qr_prev = NULL; qrp->qr_head = NULL; qrp->qr_tail = NULL; qrp->qr_wchan = qp->qh_wchan; qrp->qr_rtcount = 0; qrp->qr_qlen = 0; qrp->qr_qmax = 0; qp->qh_hlist->qr_prev = qrp; qp->qh_hlist = qrp; qp->qh_root = qrp; MAXINCR(qp->qh_hmax, qp->qh_hlen); } /* * LIFO queue ordering is unfair and can lead to starvation, * but it gives better performance for heavily contended locks. * We use thread_queue_fifo (range is 0..8) to determine * the frequency of FIFO vs LIFO queuing: * 0 : every 256th time (almost always LIFO) * 1 : every 128th time * 2 : every 64th time * 3 : every 32nd time * 4 : every 16th time (the default value, mostly LIFO) * 5 : every 8th time * 6 : every 4th time * 7 : every 2nd time * 8 : every time (never LIFO, always FIFO) * Note that there is always some degree of FIFO ordering. * This breaks live lock conditions that occur in applications * that are written assuming (incorrectly) that threads acquire * locks fairly, that is, in roughly round-robin order. * In any event, the queue is maintained in kernel priority order. * * If force_fifo is non-zero, fifo queueing is forced. * SUSV3 requires this for semaphores. */ if (qrp->qr_head == NULL) { /* * The queue is empty. LIFO/FIFO doesn't matter. */ ASSERT(qrp->qr_tail == NULL); ulwpp = &qrp->qr_head; } else if (force_fifo | (((++qp->qh_qcnt << curthread->ul_queue_fifo) & 0xff) == 0)) { /* * Enqueue after the last thread whose priority is greater * than or equal to the priority of the thread being queued. * Attempt first to go directly onto the tail of the queue. */ if (pri <= CMP_PRIO(qrp->qr_tail)) ulwpp = &qrp->qr_tail->ul_link; else { for (ulwpp = &qrp->qr_head; (next = *ulwpp) != NULL; ulwpp = &next->ul_link) if (pri > CMP_PRIO(next)) break; } } else { /* * Enqueue before the first thread whose priority is less * than or equal to the priority of the thread being queued. * Hopefully we can go directly onto the head of the queue. */ for (ulwpp = &qrp->qr_head; (next = *ulwpp) != NULL; ulwpp = &next->ul_link) if (pri >= CMP_PRIO(next)) break; } if ((ulwp->ul_link = *ulwpp) == NULL) qrp->qr_tail = ulwp; *ulwpp = ulwp; ulwp->ul_sleepq = qp; ulwp->ul_wchan = qp->qh_wchan; ulwp->ul_qtype = qp->qh_type; if ((ulwp->ul_schedctl != NULL && ulwp->ul_schedctl->sc_cid == ulwp->ul_rtclassid) | ulwp->ul_pilocks) { ulwp->ul_rtqueued = 1; qrp->qr_rtcount++; } MAXINCR(qrp->qr_qmax, qrp->qr_qlen); MAXINCR(qp->qh_qmax, qp->qh_qlen); } /* * Helper function for queue_slot() and queue_slot_rt(). * Try to find a non-suspended thread on the queue. */ static ulwp_t ** queue_slot_runnable(ulwp_t **ulwpp, ulwp_t **prevp, int rt) { ulwp_t *ulwp; ulwp_t **foundpp = NULL; int priority = -1; ulwp_t *prev; int tpri; for (prev = NULL; (ulwp = *ulwpp) != NULL; prev = ulwp, ulwpp = &ulwp->ul_link) { if (ulwp->ul_stop) /* skip suspended threads */ continue; tpri = rt? CMP_PRIO(ulwp) : 0; if (tpri > priority) { foundpp = ulwpp; *prevp = prev; priority = tpri; if (!rt) break; } } return (foundpp); } /* * For real-time, we search the entire queue because the dispatch * (kernel) priorities may have changed since enqueueing. */ static ulwp_t ** queue_slot_rt(ulwp_t **ulwpp_org, ulwp_t **prevp) { ulwp_t **ulwpp = ulwpp_org; ulwp_t *ulwp = *ulwpp; ulwp_t **foundpp = ulwpp; int priority = CMP_PRIO(ulwp); ulwp_t *prev; int tpri; for (prev = ulwp, ulwpp = &ulwp->ul_link; (ulwp = *ulwpp) != NULL; prev = ulwp, ulwpp = &ulwp->ul_link) { tpri = CMP_PRIO(ulwp); if (tpri > priority) { foundpp = ulwpp; *prevp = prev; priority = tpri; } } ulwp = *foundpp; /* * Try not to return a suspended thread. * This mimics the old libthread's behavior. */ if (ulwp->ul_stop && (ulwpp = queue_slot_runnable(ulwpp_org, prevp, 1)) != NULL) { foundpp = ulwpp; ulwp = *foundpp; } ulwp->ul_rt = 1; return (foundpp); } ulwp_t ** queue_slot(queue_head_t *qp, ulwp_t **prevp, int *more) { queue_root_t *qrp; ulwp_t **ulwpp; ulwp_t *ulwp; int rt; ASSERT(MUTEX_OWNED(&qp->qh_lock, curthread)); if ((qrp = qp->qh_root) == NULL || (ulwp = qrp->qr_head) == NULL) { *more = 0; return (NULL); /* no lwps on the queue */ } rt = (qrp->qr_rtcount != 0); *prevp = NULL; if (ulwp->ul_link == NULL) { /* only one lwp on the queue */ *more = 0; ulwp->ul_rt = rt; return (&qrp->qr_head); } *more = 1; if (rt) /* real-time queue */ return (queue_slot_rt(&qrp->qr_head, prevp)); /* * Try not to return a suspended thread. * This mimics the old libthread's behavior. */ if (ulwp->ul_stop && (ulwpp = queue_slot_runnable(&qrp->qr_head, prevp, 0)) != NULL) { ulwp = *ulwpp; ulwp->ul_rt = 0; return (ulwpp); } /* * The common case; just pick the first thread on the queue. */ ulwp->ul_rt = 0; return (&qrp->qr_head); } /* * Common code for unlinking an lwp from a user-level sleep queue. */ void queue_unlink(queue_head_t *qp, ulwp_t **ulwpp, ulwp_t *prev) { queue_root_t *qrp = qp->qh_root; queue_root_t *nqrp; ulwp_t *ulwp = *ulwpp; ulwp_t *next; ASSERT(MUTEX_OWNED(&qp->qh_lock, curthread)); ASSERT(qp->qh_wchan != NULL && ulwp->ul_wchan == qp->qh_wchan); DECR(qp->qh_qlen); DECR(qrp->qr_qlen); if (ulwp->ul_rtqueued) { ulwp->ul_rtqueued = 0; qrp->qr_rtcount--; } next = ulwp->ul_link; *ulwpp = next; ulwp->ul_link = NULL; if (qrp->qr_tail == ulwp) qrp->qr_tail = prev; if (qrp == &ulwp->ul_queue_root) { /* * We can't continue to use the unlinked thread's * queue root for the linkage. */ queue_root_t *qr_next = qrp->qr_next; queue_root_t *qr_prev = qrp->qr_prev; if (qrp->qr_tail) { /* switch to using the last thread's queue root */ ASSERT(qrp->qr_qlen != 0); nqrp = &qrp->qr_tail->ul_queue_root; *nqrp = *qrp; if (qr_next) qr_next->qr_prev = nqrp; if (qr_prev) qr_prev->qr_next = nqrp; else qp->qh_hlist = nqrp; qp->qh_root = nqrp; } else { /* empty queue root; just delete from the hash list */ ASSERT(qrp->qr_qlen == 0); if (qr_next) qr_next->qr_prev = qr_prev; if (qr_prev) qr_prev->qr_next = qr_next; else qp->qh_hlist = qr_next; qp->qh_root = NULL; DECR(qp->qh_hlen); } } } ulwp_t * dequeue(queue_head_t *qp, int *more) { ulwp_t **ulwpp; ulwp_t *ulwp; ulwp_t *prev; if ((ulwpp = queue_slot(qp, &prev, more)) == NULL) return (NULL); ulwp = *ulwpp; queue_unlink(qp, ulwpp, prev); ulwp->ul_sleepq = NULL; ulwp->ul_wchan = NULL; return (ulwp); } /* * Return a pointer to the highest priority thread sleeping on wchan. */ ulwp_t * queue_waiter(queue_head_t *qp) { ulwp_t **ulwpp; ulwp_t *prev; int more; if ((ulwpp = queue_slot(qp, &prev, &more)) == NULL) return (NULL); return (*ulwpp); } int dequeue_self(queue_head_t *qp) { ulwp_t *self = curthread; queue_root_t *qrp; ulwp_t **ulwpp; ulwp_t *ulwp; ulwp_t *prev; int found = 0; ASSERT(MUTEX_OWNED(&qp->qh_lock, self)); /* find self on the sleep queue */ if ((qrp = qp->qh_root) != NULL) { for (prev = NULL, ulwpp = &qrp->qr_head; (ulwp = *ulwpp) != NULL; prev = ulwp, ulwpp = &ulwp->ul_link) { if (ulwp == self) { queue_unlink(qp, ulwpp, prev); self->ul_cvmutex = NULL; self->ul_sleepq = NULL; self->ul_wchan = NULL; found = 1; break; } } } if (!found) thr_panic("dequeue_self(): curthread not found on queue"); return ((qrp = qp->qh_root) != NULL && qrp->qr_head != NULL); } /* * Called from call_user_handler() and _thrp_suspend() to take * ourself off of our sleep queue so we can grab locks. */ void unsleep_self(void) { ulwp_t *self = curthread; queue_head_t *qp; /* * Calling enter_critical()/exit_critical() here would lead * to recursion. Just manipulate self->ul_critical directly. */ self->ul_critical++; while (self->ul_sleepq != NULL) { qp = queue_lock(self->ul_wchan, self->ul_qtype); /* * We may have been moved from a CV queue to a * mutex queue while we were attempting queue_lock(). * If so, just loop around and try again. * dequeue_self() clears self->ul_sleepq. */ if (qp == self->ul_sleepq) (void) dequeue_self(qp); queue_unlock(qp); } self->ul_writer = 0; self->ul_critical--; } /* * Common code for calling the the ___lwp_mutex_timedlock() system call. * Returns with mutex_owner and mutex_ownerpid set correctly. */ static int mutex_lock_kernel(mutex_t *mp, timespec_t *tsp, tdb_mutex_stats_t *msp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int mtype = mp->mutex_type; hrtime_t begin_sleep; int acquired; int error; self->ul_sp = stkptr(); self->ul_wchan = mp; if (__td_event_report(self, TD_SLEEP, udp)) { self->ul_td_evbuf.eventnum = TD_SLEEP; self->ul_td_evbuf.eventdata = mp; tdb_event(TD_SLEEP, udp); } if (msp) { tdb_incr(msp->mutex_sleep); begin_sleep = gethrtime(); } DTRACE_PROBE1(plockstat, mutex__block, mp); for (;;) { /* * A return value of EOWNERDEAD or ELOCKUNMAPPED * means we successfully acquired the lock. */ if ((error = ___lwp_mutex_timedlock(mp, tsp)) != 0 && error != EOWNERDEAD && error != ELOCKUNMAPPED) { acquired = 0; break; } if (mtype & USYNC_PROCESS) { /* * Defend against forkall(). We may be the child, * in which case we don't actually own the mutex. */ enter_critical(self); if (mp->mutex_ownerpid == udp->pid) { mp->mutex_owner = (uintptr_t)self; exit_critical(self); acquired = 1; break; } exit_critical(self); } else { mp->mutex_owner = (uintptr_t)self; acquired = 1; break; } } if (msp) msp->mutex_sleep_time += gethrtime() - begin_sleep; self->ul_wchan = NULL; self->ul_sp = 0; if (acquired) { DTRACE_PROBE2(plockstat, mutex__blocked, mp, 1); DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); } else { DTRACE_PROBE2(plockstat, mutex__blocked, mp, 0); DTRACE_PROBE2(plockstat, mutex__error, mp, error); } return (error); } /* * Common code for calling the ___lwp_mutex_trylock() system call. * Returns with mutex_owner and mutex_ownerpid set correctly. */ int mutex_trylock_kernel(mutex_t *mp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int mtype = mp->mutex_type; int error; int acquired; for (;;) { /* * A return value of EOWNERDEAD or ELOCKUNMAPPED * means we successfully acquired the lock. */ if ((error = ___lwp_mutex_trylock(mp)) != 0 && error != EOWNERDEAD && error != ELOCKUNMAPPED) { acquired = 0; break; } if (mtype & USYNC_PROCESS) { /* * Defend against forkall(). We may be the child, * in which case we don't actually own the mutex. */ enter_critical(self); if (mp->mutex_ownerpid == udp->pid) { mp->mutex_owner = (uintptr_t)self; exit_critical(self); acquired = 1; break; } exit_critical(self); } else { mp->mutex_owner = (uintptr_t)self; acquired = 1; break; } } if (acquired) { DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); } else if (error != EBUSY) { DTRACE_PROBE2(plockstat, mutex__error, mp, error); } return (error); } volatile sc_shared_t * setup_schedctl(void) { ulwp_t *self = curthread; volatile sc_shared_t *scp; sc_shared_t *tmp; if ((scp = self->ul_schedctl) == NULL && /* no shared state yet */ !self->ul_vfork && /* not a child of vfork() */ !self->ul_schedctl_called) { /* haven't been called before */ enter_critical(self); self->ul_schedctl_called = &self->ul_uberdata->uberflags; if ((tmp = __schedctl()) != (sc_shared_t *)(-1)) self->ul_schedctl = scp = tmp; exit_critical(self); } /* * Unless the call to setup_schedctl() is surrounded * by enter_critical()/exit_critical(), the address * we are returning could be invalid due to a forkall() * having occurred in another thread. */ return (scp); } /* * Interfaces from libsched, incorporated into libc. * libsched.so.1 is now a filter library onto libc. */ #pragma weak schedctl_lookup = _schedctl_init #pragma weak _schedctl_lookup = _schedctl_init #pragma weak schedctl_init = _schedctl_init schedctl_t * _schedctl_init(void) { volatile sc_shared_t *scp = setup_schedctl(); return ((scp == NULL)? NULL : (schedctl_t *)&scp->sc_preemptctl); } #pragma weak schedctl_exit = _schedctl_exit void _schedctl_exit(void) { } /* * Contract private interface for java. * Set up the schedctl data if it doesn't exist yet. * Return a pointer to the pointer to the schedctl data. */ volatile sc_shared_t *volatile * _thr_schedctl(void) { ulwp_t *self = curthread; volatile sc_shared_t *volatile *ptr; if (self->ul_vfork) return (NULL); if (*(ptr = &self->ul_schedctl) == NULL) (void) setup_schedctl(); return (ptr); } /* * Block signals and attempt to block preemption. * no_preempt()/preempt() must be used in pairs but can be nested. */ void no_preempt(ulwp_t *self) { volatile sc_shared_t *scp; if (self->ul_preempt++ == 0) { enter_critical(self); if ((scp = self->ul_schedctl) != NULL || (scp = setup_schedctl()) != NULL) { /* * Save the pre-existing preempt value. */ self->ul_savpreempt = scp->sc_preemptctl.sc_nopreempt; scp->sc_preemptctl.sc_nopreempt = 1; } } } /* * Undo the effects of no_preempt(). */ void preempt(ulwp_t *self) { volatile sc_shared_t *scp; ASSERT(self->ul_preempt > 0); if (--self->ul_preempt == 0) { if ((scp = self->ul_schedctl) != NULL) { /* * Restore the pre-existing preempt value. */ scp->sc_preemptctl.sc_nopreempt = self->ul_savpreempt; if (scp->sc_preemptctl.sc_yield && scp->sc_preemptctl.sc_nopreempt == 0) { yield(); if (scp->sc_preemptctl.sc_yield) { /* * Shouldn't happen. This is either * a race condition or the thread * just entered the real-time class. */ yield(); scp->sc_preemptctl.sc_yield = 0; } } } exit_critical(self); } } /* * If a call to preempt() would cause the current thread to yield or to * take deferred actions in exit_critical(), then unpark the specified * lwp so it can run while we delay. Return the original lwpid if the * unpark was not performed, else return zero. The tests are a repeat * of some of the tests in preempt(), above. This is a statistical * optimization solely for cond_sleep_queue(), below. */ static lwpid_t preempt_unpark(ulwp_t *self, lwpid_t lwpid) { volatile sc_shared_t *scp = self->ul_schedctl; ASSERT(self->ul_preempt == 1 && self->ul_critical > 0); if ((scp != NULL && scp->sc_preemptctl.sc_yield) || (self->ul_curplease && self->ul_critical == 1)) { (void) __lwp_unpark(lwpid); lwpid = 0; } return (lwpid); } /* * Spin for a while (if 'tryhard' is true), trying to grab the lock. * If this fails, return EBUSY and let the caller deal with it. * If this succeeds, return 0 with mutex_owner set to curthread. */ static int mutex_trylock_adaptive(mutex_t *mp, int tryhard) { ulwp_t *self = curthread; int error = EBUSY; ulwp_t *ulwp; volatile sc_shared_t *scp; volatile uint8_t *lockp = (volatile uint8_t *)&mp->mutex_lockw; volatile uint64_t *ownerp = (volatile uint64_t *)&mp->mutex_owner; uint32_t new_lockword; int count = 0; int max_count; uint8_t max_spinners; ASSERT(!(mp->mutex_type & USYNC_PROCESS)); if (MUTEX_OWNER(mp) == self) return (EBUSY); /* short-cut, not definitive (see below) */ if (mp->mutex_flag & LOCK_NOTRECOVERABLE) { ASSERT(mp->mutex_type & LOCK_ROBUST); error = ENOTRECOVERABLE; goto done; } /* * Make one attempt to acquire the lock before * incurring the overhead of the spin loop. */ if (set_lock_byte(lockp) == 0) { *ownerp = (uintptr_t)self; error = 0; goto done; } if (!tryhard) goto done; if (ncpus == 0) ncpus = (int)_sysconf(_SC_NPROCESSORS_ONLN); if ((max_spinners = self->ul_max_spinners) >= ncpus) max_spinners = ncpus - 1; max_count = (max_spinners != 0)? self->ul_adaptive_spin : 0; if (max_count == 0) goto done; /* * This spin loop is unfair to lwps that have already dropped into * the kernel to sleep. They will starve on a highly-contended mutex. * This is just too bad. The adaptive spin algorithm is intended * to allow programs with highly-contended locks (that is, broken * programs) to execute with reasonable speed despite their contention. * Being fair would reduce the speed of such programs and well-written * programs will not suffer in any case. */ enter_critical(self); if (spinners_incr(&mp->mutex_lockword, max_spinners) == -1) { exit_critical(self); goto done; } DTRACE_PROBE1(plockstat, mutex__spin, mp); for (count = 1; ; count++) { if (*lockp == 0 && set_lock_byte(lockp) == 0) { *ownerp = (uintptr_t)self; error = 0; break; } if (count == max_count) break; SMT_PAUSE(); /* * Stop spinning if the mutex owner is not running on * a processor; it will not drop the lock any time soon * and we would just be wasting time to keep spinning. * * Note that we are looking at another thread (ulwp_t) * without ensuring that the other thread does not exit. * The scheme relies on ulwp_t structures never being * deallocated by the library (the library employs a free * list of ulwp_t structs that are reused when new threads * are created) and on schedctl shared memory never being * deallocated once created via __schedctl(). * * Thus, the worst that can happen when the spinning thread * looks at the owner's schedctl data is that it is looking * at some other thread's schedctl data. This almost never * happens and is benign when it does. */ if ((ulwp = (ulwp_t *)(uintptr_t)*ownerp) != NULL && ((scp = ulwp->ul_schedctl) == NULL || scp->sc_state != SC_ONPROC)) break; } new_lockword = spinners_decr(&mp->mutex_lockword); if (error && (new_lockword & (LOCKMASK | SPINNERMASK)) == 0) { /* * We haven't yet acquired the lock, the lock * is free, and there are no other spinners. * Make one final attempt to acquire the lock. * * This isn't strictly necessary since mutex_lock_queue() * (the next action this thread will take if it doesn't * acquire the lock here) makes one attempt to acquire * the lock before putting the thread to sleep. * * If the next action for this thread (on failure here) * were not to call mutex_lock_queue(), this would be * necessary for correctness, to avoid ending up with an * unheld mutex with waiters but no one to wake them up. */ if (set_lock_byte(lockp) == 0) { *ownerp = (uintptr_t)self; error = 0; } count++; } exit_critical(self); done: if (error == 0 && (mp->mutex_flag & LOCK_NOTRECOVERABLE)) { ASSERT(mp->mutex_type & LOCK_ROBUST); /* * We shouldn't own the mutex. * Just clear the lock; everyone has already been waked up. */ mp->mutex_owner = 0; (void) clear_lockbyte(&mp->mutex_lockword); error = ENOTRECOVERABLE; } if (error) { if (count) { DTRACE_PROBE2(plockstat, mutex__spun, 0, count); } if (error != EBUSY) { DTRACE_PROBE2(plockstat, mutex__error, mp, error); } } else { if (count) { DTRACE_PROBE2(plockstat, mutex__spun, 1, count); } DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, count); if (mp->mutex_flag & LOCK_OWNERDEAD) { ASSERT(mp->mutex_type & LOCK_ROBUST); error = EOWNERDEAD; } } return (error); } /* * Same as mutex_trylock_adaptive(), except specifically for queue locks. * The owner field is not set here; the caller (spin_lock_set()) sets it. */ static int mutex_queuelock_adaptive(mutex_t *mp) { ulwp_t *ulwp; volatile sc_shared_t *scp; volatile uint8_t *lockp; volatile uint64_t *ownerp; int count = curthread->ul_queue_spin; ASSERT(mp->mutex_type == USYNC_THREAD); if (count == 0) return (EBUSY); lockp = (volatile uint8_t *)&mp->mutex_lockw; ownerp = (volatile uint64_t *)&mp->mutex_owner; while (--count >= 0) { if (*lockp == 0 && set_lock_byte(lockp) == 0) return (0); SMT_PAUSE(); if ((ulwp = (ulwp_t *)(uintptr_t)*ownerp) != NULL && ((scp = ulwp->ul_schedctl) == NULL || scp->sc_state != SC_ONPROC)) break; } return (EBUSY); } /* * Like mutex_trylock_adaptive(), but for process-shared mutexes. * Spin for a while (if 'tryhard' is true), trying to grab the lock. * If this fails, return EBUSY and let the caller deal with it. * If this succeeds, return 0 with mutex_owner set to curthread * and mutex_ownerpid set to the current pid. */ static int mutex_trylock_process(mutex_t *mp, int tryhard) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int error = EBUSY; volatile uint64_t *lockp = (volatile uint64_t *)&mp->mutex_lockword64; uint32_t new_lockword; int count = 0; int max_count; uint8_t max_spinners; ASSERT(mp->mutex_type & USYNC_PROCESS); if (shared_mutex_held(mp)) return (EBUSY); /* short-cut, not definitive (see below) */ if (mp->mutex_flag & LOCK_NOTRECOVERABLE) { ASSERT(mp->mutex_type & LOCK_ROBUST); error = ENOTRECOVERABLE; goto done; } /* * Make one attempt to acquire the lock before * incurring the overhead of the spin loop. */ enter_critical(self); if (set_lock_byte64(lockp, udp->pid) == 0) { mp->mutex_owner = (uintptr_t)self; /* mp->mutex_ownerpid was set by set_lock_byte64() */ exit_critical(self); error = 0; goto done; } exit_critical(self); if (!tryhard) goto done; if (ncpus == 0) ncpus = (int)_sysconf(_SC_NPROCESSORS_ONLN); if ((max_spinners = self->ul_max_spinners) >= ncpus) max_spinners = ncpus - 1; max_count = (max_spinners != 0)? self->ul_adaptive_spin : 0; if (max_count == 0) goto done; /* * This is a process-shared mutex. * We cannot know if the owner is running on a processor. * We just spin and hope that it is on a processor. */ enter_critical(self); if (spinners_incr(&mp->mutex_lockword, max_spinners) == -1) { exit_critical(self); goto done; } DTRACE_PROBE1(plockstat, mutex__spin, mp); for (count = 1; ; count++) { if ((*lockp & LOCKMASK64) == 0 && set_lock_byte64(lockp, udp->pid) == 0) { mp->mutex_owner = (uintptr_t)self; /* mp->mutex_ownerpid was set by set_lock_byte64() */ error = 0; break; } if (count == max_count) break; SMT_PAUSE(); } new_lockword = spinners_decr(&mp->mutex_lockword); if (error && (new_lockword & (LOCKMASK | SPINNERMASK)) == 0) { /* * We haven't yet acquired the lock, the lock * is free, and there are no other spinners. * Make one final attempt to acquire the lock. * * This isn't strictly necessary since mutex_lock_kernel() * (the next action this thread will take if it doesn't * acquire the lock here) makes one attempt to acquire * the lock before putting the thread to sleep. * * If the next action for this thread (on failure here) * were not to call mutex_lock_kernel(), this would be * necessary for correctness, to avoid ending up with an * unheld mutex with waiters but no one to wake them up. */ if (set_lock_byte64(lockp, udp->pid) == 0) { mp->mutex_owner = (uintptr_t)self; /* mp->mutex_ownerpid was set by set_lock_byte64() */ error = 0; } count++; } exit_critical(self); done: if (error == 0 && (mp->mutex_flag & LOCK_NOTRECOVERABLE)) { ASSERT(mp->mutex_type & LOCK_ROBUST); /* * We shouldn't own the mutex. * Just clear the lock; everyone has already been waked up. */ mp->mutex_owner = 0; /* mp->mutex_ownerpid is cleared by clear_lockbyte64() */ (void) clear_lockbyte64(&mp->mutex_lockword64); error = ENOTRECOVERABLE; } if (error) { if (count) { DTRACE_PROBE2(plockstat, mutex__spun, 0, count); } if (error != EBUSY) { DTRACE_PROBE2(plockstat, mutex__error, mp, error); } } else { if (count) { DTRACE_PROBE2(plockstat, mutex__spun, 1, count); } DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, count); if (mp->mutex_flag & (LOCK_OWNERDEAD | LOCK_UNMAPPED)) { ASSERT(mp->mutex_type & LOCK_ROBUST); if (mp->mutex_flag & LOCK_OWNERDEAD) error = EOWNERDEAD; else if (mp->mutex_type & USYNC_PROCESS_ROBUST) error = ELOCKUNMAPPED; else error = EOWNERDEAD; } } return (error); } /* * Mutex wakeup code for releasing a USYNC_THREAD mutex. * Returns the lwpid of the thread that was dequeued, if any. * The caller of mutex_wakeup() must call __lwp_unpark(lwpid) * to wake up the specified lwp. */ static lwpid_t mutex_wakeup(mutex_t *mp) { lwpid_t lwpid = 0; int more; queue_head_t *qp; ulwp_t *ulwp; /* * Dequeue a waiter from the sleep queue. Don't touch the mutex * waiters bit if no one was found on the queue because the mutex * might have been deallocated or reallocated for another purpose. */ qp = queue_lock(mp, MX); if ((ulwp = dequeue(qp, &more)) != NULL) { lwpid = ulwp->ul_lwpid; mp->mutex_waiters = more; } queue_unlock(qp); return (lwpid); } /* * Mutex wakeup code for releasing all waiters on a USYNC_THREAD mutex. */ static void mutex_wakeup_all(mutex_t *mp) { queue_head_t *qp; queue_root_t *qrp; int nlwpid = 0; int maxlwps = MAXLWPS; ulwp_t *ulwp; lwpid_t buffer[MAXLWPS]; lwpid_t *lwpid = buffer; /* * Walk the list of waiters and prepare to wake up all of them. * The waiters flag has already been cleared from the mutex. * * We keep track of lwpids that are to be unparked in lwpid[]. * __lwp_unpark_all() is called to unpark all of them after * they have been removed from the sleep queue and the sleep * queue lock has been dropped. If we run out of space in our * on-stack buffer, we need to allocate more but we can't call * lmalloc() because we are holding a queue lock when the overflow * occurs and lmalloc() acquires a lock. We can't use alloca() * either because the application may have allocated a small * stack and we don't want to overrun the stack. So we call * alloc_lwpids() to allocate a bigger buffer using the mmap() * system call directly since that path acquires no locks. */ qp = queue_lock(mp, MX); for (;;) { if ((qrp = qp->qh_root) == NULL || (ulwp = qrp->qr_head) == NULL) break; ASSERT(ulwp->ul_wchan == mp); queue_unlink(qp, &qrp->qr_head, NULL); ulwp->ul_sleepq = NULL; ulwp->ul_wchan = NULL; if (nlwpid == maxlwps) lwpid = alloc_lwpids(lwpid, &nlwpid, &maxlwps); lwpid[nlwpid++] = ulwp->ul_lwpid; } if (nlwpid == 0) { queue_unlock(qp); } else { mp->mutex_waiters = 0; no_preempt(curthread); queue_unlock(qp); if (nlwpid == 1) (void) __lwp_unpark(lwpid[0]); else (void) __lwp_unpark_all(lwpid, nlwpid); preempt(curthread); } if (lwpid != buffer) (void) munmap((caddr_t)lwpid, maxlwps * sizeof (lwpid_t)); } /* * Release a process-private mutex. * As an optimization, if there are waiters but there are also spinners * attempting to acquire the mutex, then don't bother waking up a waiter; * one of the spinners will acquire the mutex soon and it would be a waste * of resources to wake up some thread just to have it spin for a while * and then possibly go back to sleep. See mutex_trylock_adaptive(). */ static lwpid_t mutex_unlock_queue(mutex_t *mp, int release_all) { lwpid_t lwpid = 0; uint32_t old_lockword; DTRACE_PROBE2(plockstat, mutex__release, mp, 0); mp->mutex_owner = 0; old_lockword = clear_lockbyte(&mp->mutex_lockword); if ((old_lockword & WAITERMASK) && (release_all || (old_lockword & SPINNERMASK) == 0)) { ulwp_t *self = curthread; no_preempt(self); /* ensure a prompt wakeup */ if (release_all) mutex_wakeup_all(mp); else lwpid = mutex_wakeup(mp); if (lwpid == 0) preempt(self); } return (lwpid); } /* * Like mutex_unlock_queue(), but for process-shared mutexes. */ static void mutex_unlock_process(mutex_t *mp, int release_all) { uint64_t old_lockword64; DTRACE_PROBE2(plockstat, mutex__release, mp, 0); mp->mutex_owner = 0; /* mp->mutex_ownerpid is cleared by clear_lockbyte64() */ old_lockword64 = clear_lockbyte64(&mp->mutex_lockword64); if ((old_lockword64 & WAITERMASK64) && (release_all || (old_lockword64 & SPINNERMASK64) == 0)) { ulwp_t *self = curthread; no_preempt(self); /* ensure a prompt wakeup */ (void) ___lwp_mutex_wakeup(mp, release_all); preempt(self); } } void stall(void) { for (;;) (void) mutex_lock_kernel(&stall_mutex, NULL, NULL); } /* * Acquire a USYNC_THREAD mutex via user-level sleep queues. * We failed set_lock_byte(&mp->mutex_lockw) before coming here. * If successful, returns with mutex_owner set correctly. */ int mutex_lock_queue(ulwp_t *self, tdb_mutex_stats_t *msp, mutex_t *mp, timespec_t *tsp) { uberdata_t *udp = curthread->ul_uberdata; queue_head_t *qp; hrtime_t begin_sleep; int error = 0; self->ul_sp = stkptr(); if (__td_event_report(self, TD_SLEEP, udp)) { self->ul_wchan = mp; self->ul_td_evbuf.eventnum = TD_SLEEP; self->ul_td_evbuf.eventdata = mp; tdb_event(TD_SLEEP, udp); } if (msp) { tdb_incr(msp->mutex_sleep); begin_sleep = gethrtime(); } DTRACE_PROBE1(plockstat, mutex__block, mp); /* * Put ourself on the sleep queue, and while we are * unable to grab the lock, go park in the kernel. * Take ourself off the sleep queue after we acquire the lock. * The waiter bit can be set/cleared only while holding the queue lock. */ qp = queue_lock(mp, MX); enqueue(qp, self, 0); mp->mutex_waiters = 1; for (;;) { if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; mp->mutex_waiters = dequeue_self(qp); break; } set_parking_flag(self, 1); queue_unlock(qp); /* * __lwp_park() will return the residual time in tsp * if we are unparked before the timeout expires. */ error = __lwp_park(tsp, 0); set_parking_flag(self, 0); /* * We could have taken a signal or suspended ourself. * If we did, then we removed ourself from the queue. * Someone else may have removed us from the queue * as a consequence of mutex_unlock(). We may have * gotten a timeout from __lwp_park(). Or we may still * be on the queue and this is just a spurious wakeup. */ qp = queue_lock(mp, MX); if (self->ul_sleepq == NULL) { if (error) { mp->mutex_waiters = queue_waiter(qp)? 1 : 0; if (error != EINTR) break; error = 0; } if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; break; } enqueue(qp, self, 0); mp->mutex_waiters = 1; } ASSERT(self->ul_sleepq == qp && self->ul_qtype == MX && self->ul_wchan == mp); if (error) { if (error != EINTR) { mp->mutex_waiters = dequeue_self(qp); break; } error = 0; } } ASSERT(self->ul_sleepq == NULL && self->ul_link == NULL && self->ul_wchan == NULL); self->ul_sp = 0; queue_unlock(qp); if (msp) msp->mutex_sleep_time += gethrtime() - begin_sleep; ASSERT(error == 0 || error == EINVAL || error == ETIME); if (error == 0 && (mp->mutex_flag & LOCK_NOTRECOVERABLE)) { ASSERT(mp->mutex_type & LOCK_ROBUST); /* * We shouldn't own the mutex. * Just clear the lock; everyone has already been waked up. */ mp->mutex_owner = 0; (void) clear_lockbyte(&mp->mutex_lockword); error = ENOTRECOVERABLE; } if (error) { DTRACE_PROBE2(plockstat, mutex__blocked, mp, 0); DTRACE_PROBE2(plockstat, mutex__error, mp, error); } else { DTRACE_PROBE2(plockstat, mutex__blocked, mp, 1); DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); if (mp->mutex_flag & LOCK_OWNERDEAD) { ASSERT(mp->mutex_type & LOCK_ROBUST); error = EOWNERDEAD; } } return (error); } static int mutex_recursion(mutex_t *mp, int mtype, int try) { ASSERT(mutex_is_held(mp)); ASSERT(mtype & (LOCK_RECURSIVE|LOCK_ERRORCHECK)); ASSERT(try == MUTEX_TRY || try == MUTEX_LOCK); if (mtype & LOCK_RECURSIVE) { if (mp->mutex_rcount == RECURSION_MAX) { DTRACE_PROBE2(plockstat, mutex__error, mp, EAGAIN); return (EAGAIN); } mp->mutex_rcount++; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 1, 0); return (0); } if (try == MUTEX_LOCK) { DTRACE_PROBE2(plockstat, mutex__error, mp, EDEADLK); return (EDEADLK); } return (EBUSY); } /* * Register this USYNC_PROCESS|LOCK_ROBUST mutex with the kernel so * it can apply LOCK_OWNERDEAD|LOCK_UNMAPPED if it becomes necessary. * We use tdb_hash_lock here and in the synch object tracking code in * the tdb_agent.c file. There is no conflict between these two usages. */ void register_lock(mutex_t *mp) { uberdata_t *udp = curthread->ul_uberdata; uint_t hash = LOCK_HASH(mp); robust_t *rlp; robust_t **rlpp; robust_t **table; if ((table = udp->robustlocks) == NULL) { lmutex_lock(&udp->tdb_hash_lock); if ((table = udp->robustlocks) == NULL) { table = lmalloc(LOCKHASHSZ * sizeof (robust_t *)); _membar_producer(); udp->robustlocks = table; } lmutex_unlock(&udp->tdb_hash_lock); } _membar_consumer(); /* * First search the registered table with no locks held. * This is safe because the table never shrinks * and we can only get a false negative. */ for (rlp = table[hash]; rlp != NULL; rlp = rlp->robust_next) { if (rlp->robust_lock == mp) /* already registered */ return; } /* * The lock was not found. * Repeat the operation with tdb_hash_lock held. */ lmutex_lock(&udp->tdb_hash_lock); for (rlpp = &table[hash]; (rlp = *rlpp) != NULL; rlpp = &rlp->robust_next) { if (rlp->robust_lock == mp) { /* already registered */ lmutex_unlock(&udp->tdb_hash_lock); return; } } /* * The lock has never been registered. * Register it now and add it to the table. */ (void) ___lwp_mutex_register(mp); rlp = lmalloc(sizeof (*rlp)); rlp->robust_lock = mp; _membar_producer(); *rlpp = rlp; lmutex_unlock(&udp->tdb_hash_lock); } /* * This is called in the child of fork()/forkall() to start over * with a clean slate. (Each process must register its own locks.) * No locks are needed because all other threads are suspended or gone. */ void unregister_locks(void) { uberdata_t *udp = curthread->ul_uberdata; uint_t hash; robust_t **table; robust_t *rlp; robust_t *next; if ((table = udp->robustlocks) != NULL) { for (hash = 0; hash < LOCKHASHSZ; hash++) { rlp = table[hash]; while (rlp != NULL) { next = rlp->robust_next; lfree(rlp, sizeof (*rlp)); rlp = next; } } lfree(table, LOCKHASHSZ * sizeof (robust_t *)); udp->robustlocks = NULL; } } /* * Returns with mutex_owner set correctly. */ int mutex_lock_internal(mutex_t *mp, timespec_t *tsp, int try) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int mtype = mp->mutex_type; tdb_mutex_stats_t *msp = MUTEX_STATS(mp, udp); int error = 0; int noceil = try & MUTEX_NOCEIL; uint8_t ceil; int myprio; try &= ~MUTEX_NOCEIL; ASSERT(try == MUTEX_TRY || try == MUTEX_LOCK); if (!self->ul_schedctl_called) (void) setup_schedctl(); if (msp && try == MUTEX_TRY) tdb_incr(msp->mutex_try); if ((mtype & (LOCK_RECURSIVE|LOCK_ERRORCHECK)) && mutex_is_held(mp)) return (mutex_recursion(mp, mtype, try)); if (self->ul_error_detection && try == MUTEX_LOCK && tsp == NULL && mutex_is_held(mp)) lock_error(mp, "mutex_lock", NULL, NULL); if ((mtype & LOCK_PRIO_PROTECT) && noceil == 0) { update_sched(self); if (self->ul_cid != self->ul_rtclassid) { DTRACE_PROBE2(plockstat, mutex__error, mp, EPERM); return (EPERM); } ceil = mp->mutex_ceiling; myprio = self->ul_epri? self->ul_epri : self->ul_pri; if (myprio > ceil) { DTRACE_PROBE2(plockstat, mutex__error, mp, EINVAL); return (EINVAL); } if ((error = _ceil_mylist_add(mp)) != 0) { DTRACE_PROBE2(plockstat, mutex__error, mp, error); return (error); } if (myprio < ceil) _ceil_prio_inherit(ceil); } if ((mtype & (USYNC_PROCESS | LOCK_ROBUST)) == (USYNC_PROCESS | LOCK_ROBUST)) register_lock(mp); if (mtype & LOCK_PRIO_INHERIT) { /* go straight to the kernel */ if (try == MUTEX_TRY) error = mutex_trylock_kernel(mp); else /* MUTEX_LOCK */ error = mutex_lock_kernel(mp, tsp, msp); /* * The kernel never sets or clears the lock byte * for LOCK_PRIO_INHERIT mutexes. * Set it here for consistency. */ switch (error) { case 0: self->ul_pilocks++; mp->mutex_lockw = LOCKSET; break; case EOWNERDEAD: case ELOCKUNMAPPED: self->ul_pilocks++; mp->mutex_lockw = LOCKSET; /* FALLTHROUGH */ case ENOTRECOVERABLE: ASSERT(mtype & LOCK_ROBUST); break; case EDEADLK: if (try == MUTEX_LOCK) stall(); error = EBUSY; break; } } else if (mtype & USYNC_PROCESS) { error = mutex_trylock_process(mp, try == MUTEX_LOCK); if (error == EBUSY && try == MUTEX_LOCK) error = mutex_lock_kernel(mp, tsp, msp); } else { /* USYNC_THREAD */ error = mutex_trylock_adaptive(mp, try == MUTEX_LOCK); if (error == EBUSY && try == MUTEX_LOCK) error = mutex_lock_queue(self, msp, mp, tsp); } switch (error) { case 0: case EOWNERDEAD: case ELOCKUNMAPPED: if (mtype & LOCK_ROBUST) remember_lock(mp); if (msp) record_begin_hold(msp); break; default: if ((mtype & LOCK_PRIO_PROTECT) && noceil == 0) { (void) _ceil_mylist_del(mp); if (myprio < ceil) _ceil_prio_waive(); } if (try == MUTEX_TRY) { if (msp) tdb_incr(msp->mutex_try_fail); if (__td_event_report(self, TD_LOCK_TRY, udp)) { self->ul_td_evbuf.eventnum = TD_LOCK_TRY; tdb_event(TD_LOCK_TRY, udp); } } break; } return (error); } int fast_process_lock(mutex_t *mp, timespec_t *tsp, int mtype, int try) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; /* * We know that USYNC_PROCESS is set in mtype and that * zero, one, or both of the flags LOCK_RECURSIVE and * LOCK_ERRORCHECK are set, and that no other flags are set. */ ASSERT((mtype & ~(USYNC_PROCESS|LOCK_RECURSIVE|LOCK_ERRORCHECK)) == 0); enter_critical(self); if (set_lock_byte64(&mp->mutex_lockword64, udp->pid) == 0) { mp->mutex_owner = (uintptr_t)self; /* mp->mutex_ownerpid was set by set_lock_byte64() */ exit_critical(self); DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); return (0); } exit_critical(self); if ((mtype & (LOCK_RECURSIVE|LOCK_ERRORCHECK)) && shared_mutex_held(mp)) return (mutex_recursion(mp, mtype, try)); if (try == MUTEX_LOCK) { if (mutex_trylock_process(mp, 1) == 0) return (0); return (mutex_lock_kernel(mp, tsp, NULL)); } if (__td_event_report(self, TD_LOCK_TRY, udp)) { self->ul_td_evbuf.eventnum = TD_LOCK_TRY; tdb_event(TD_LOCK_TRY, udp); } return (EBUSY); } static int mutex_lock_impl(mutex_t *mp, timespec_t *tsp) { ulwp_t *self = curthread; int mtype = mp->mutex_type; uberflags_t *gflags; /* * Optimize the case of USYNC_THREAD, including * the LOCK_RECURSIVE and LOCK_ERRORCHECK cases, * no error detection, no lock statistics, * and the process has only a single thread. * (Most likely a traditional single-threaded application.) */ if (((mtype & ~(LOCK_RECURSIVE|LOCK_ERRORCHECK)) | self->ul_uberdata->uberflags.uf_all) == 0) { /* * Only one thread exists so we don't need an atomic operation. */ if (mp->mutex_lockw == 0) { mp->mutex_lockw = LOCKSET; mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); return (0); } if (mtype && MUTEX_OWNER(mp) == self) return (mutex_recursion(mp, mtype, MUTEX_LOCK)); /* * We have reached a deadlock, probably because the * process is executing non-async-signal-safe code in * a signal handler and is attempting to acquire a lock * that it already owns. This is not surprising, given * bad programming practices over the years that has * resulted in applications calling printf() and such * in their signal handlers. Unless the user has told * us that the signal handlers are safe by setting: * export _THREAD_ASYNC_SAFE=1 * we return EDEADLK rather than actually deadlocking. */ if (tsp == NULL && MUTEX_OWNER(mp) == self && !self->ul_async_safe) { DTRACE_PROBE2(plockstat, mutex__error, mp, EDEADLK); return (EDEADLK); } } /* * Optimize the common cases of USYNC_THREAD or USYNC_PROCESS, * no error detection, and no lock statistics. * Include LOCK_RECURSIVE and LOCK_ERRORCHECK cases. */ if ((gflags = self->ul_schedctl_called) != NULL && (gflags->uf_trs_ted | (mtype & ~(USYNC_PROCESS|LOCK_RECURSIVE|LOCK_ERRORCHECK))) == 0) { if (mtype & USYNC_PROCESS) return (fast_process_lock(mp, tsp, mtype, MUTEX_LOCK)); if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); return (0); } if (mtype && MUTEX_OWNER(mp) == self) return (mutex_recursion(mp, mtype, MUTEX_LOCK)); if (mutex_trylock_adaptive(mp, 1) != 0) return (mutex_lock_queue(self, NULL, mp, tsp)); return (0); } /* else do it the long way */ return (mutex_lock_internal(mp, tsp, MUTEX_LOCK)); } #pragma weak mutex_lock = __mutex_lock #pragma weak _mutex_lock = __mutex_lock #pragma weak pthread_mutex_lock = __mutex_lock #pragma weak _pthread_mutex_lock = __mutex_lock int __mutex_lock(mutex_t *mp) { ASSERT(!curthread->ul_critical || curthread->ul_bindflags); return (mutex_lock_impl(mp, NULL)); } #pragma weak pthread_mutex_timedlock = _pthread_mutex_timedlock int _pthread_mutex_timedlock(mutex_t *mp, const timespec_t *abstime) { timespec_t tslocal; int error; ASSERT(!curthread->ul_critical || curthread->ul_bindflags); abstime_to_reltime(CLOCK_REALTIME, abstime, &tslocal); error = mutex_lock_impl(mp, &tslocal); if (error == ETIME) error = ETIMEDOUT; return (error); } #pragma weak pthread_mutex_reltimedlock_np = _pthread_mutex_reltimedlock_np int _pthread_mutex_reltimedlock_np(mutex_t *mp, const timespec_t *reltime) { timespec_t tslocal; int error; ASSERT(!curthread->ul_critical || curthread->ul_bindflags); tslocal = *reltime; error = mutex_lock_impl(mp, &tslocal); if (error == ETIME) error = ETIMEDOUT; return (error); } #pragma weak mutex_trylock = __mutex_trylock #pragma weak _mutex_trylock = __mutex_trylock #pragma weak pthread_mutex_trylock = __mutex_trylock #pragma weak _pthread_mutex_trylock = __mutex_trylock int __mutex_trylock(mutex_t *mp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int mtype = mp->mutex_type; uberflags_t *gflags; ASSERT(!curthread->ul_critical || curthread->ul_bindflags); /* * Optimize the case of USYNC_THREAD, including * the LOCK_RECURSIVE and LOCK_ERRORCHECK cases, * no error detection, no lock statistics, * and the process has only a single thread. * (Most likely a traditional single-threaded application.) */ if (((mtype & ~(LOCK_RECURSIVE|LOCK_ERRORCHECK)) | udp->uberflags.uf_all) == 0) { /* * Only one thread exists so we don't need an atomic operation. */ if (mp->mutex_lockw == 0) { mp->mutex_lockw = LOCKSET; mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); return (0); } if (mtype && MUTEX_OWNER(mp) == self) return (mutex_recursion(mp, mtype, MUTEX_TRY)); return (EBUSY); } /* * Optimize the common cases of USYNC_THREAD or USYNC_PROCESS, * no error detection, and no lock statistics. * Include LOCK_RECURSIVE and LOCK_ERRORCHECK cases. */ if ((gflags = self->ul_schedctl_called) != NULL && (gflags->uf_trs_ted | (mtype & ~(USYNC_PROCESS|LOCK_RECURSIVE|LOCK_ERRORCHECK))) == 0) { if (mtype & USYNC_PROCESS) return (fast_process_lock(mp, NULL, mtype, MUTEX_TRY)); if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); return (0); } if (mtype && MUTEX_OWNER(mp) == self) return (mutex_recursion(mp, mtype, MUTEX_TRY)); if (__td_event_report(self, TD_LOCK_TRY, udp)) { self->ul_td_evbuf.eventnum = TD_LOCK_TRY; tdb_event(TD_LOCK_TRY, udp); } return (EBUSY); } /* else do it the long way */ return (mutex_lock_internal(mp, NULL, MUTEX_TRY)); } int mutex_unlock_internal(mutex_t *mp, int retain_robust_flags) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; int mtype = mp->mutex_type; tdb_mutex_stats_t *msp; int error = 0; int release_all; lwpid_t lwpid; if ((mtype & LOCK_ERRORCHECK) && !mutex_is_held(mp)) return (EPERM); if (self->ul_error_detection && !mutex_is_held(mp)) lock_error(mp, "mutex_unlock", NULL, NULL); if ((mtype & LOCK_RECURSIVE) && mp->mutex_rcount != 0) { mp->mutex_rcount--; DTRACE_PROBE2(plockstat, mutex__release, mp, 1); return (0); } if ((msp = MUTEX_STATS(mp, udp)) != NULL) (void) record_hold_time(msp); if (!retain_robust_flags && !(mtype & LOCK_PRIO_INHERIT) && (mp->mutex_flag & (LOCK_OWNERDEAD | LOCK_UNMAPPED))) { ASSERT(mp->mutex_type & LOCK_ROBUST); mp->mutex_flag &= ~(LOCK_OWNERDEAD | LOCK_UNMAPPED); mp->mutex_flag |= LOCK_NOTRECOVERABLE; } release_all = ((mp->mutex_flag & LOCK_NOTRECOVERABLE) != 0); if (mtype & LOCK_PRIO_INHERIT) { no_preempt(self); mp->mutex_owner = 0; /* mp->mutex_ownerpid is cleared by ___lwp_mutex_unlock() */ DTRACE_PROBE2(plockstat, mutex__release, mp, 0); mp->mutex_lockw = LOCKCLEAR; self->ul_pilocks--; error = ___lwp_mutex_unlock(mp); preempt(self); } else if (mtype & USYNC_PROCESS) { mutex_unlock_process(mp, release_all); } else { /* USYNC_THREAD */ if ((lwpid = mutex_unlock_queue(mp, release_all)) != 0) { (void) __lwp_unpark(lwpid); preempt(self); } } if (mtype & LOCK_ROBUST) forget_lock(mp); if ((mtype & LOCK_PRIO_PROTECT) && _ceil_mylist_del(mp)) _ceil_prio_waive(); return (error); } #pragma weak mutex_unlock = __mutex_unlock #pragma weak _mutex_unlock = __mutex_unlock #pragma weak pthread_mutex_unlock = __mutex_unlock #pragma weak _pthread_mutex_unlock = __mutex_unlock int __mutex_unlock(mutex_t *mp) { ulwp_t *self = curthread; int mtype = mp->mutex_type; uberflags_t *gflags; lwpid_t lwpid; short el; /* * Optimize the case of USYNC_THREAD, including * the LOCK_RECURSIVE and LOCK_ERRORCHECK cases, * no error detection, no lock statistics, * and the process has only a single thread. * (Most likely a traditional single-threaded application.) */ if (((mtype & ~(LOCK_RECURSIVE|LOCK_ERRORCHECK)) | self->ul_uberdata->uberflags.uf_all) == 0) { if (mtype) { /* * At this point we know that one or both of the * flags LOCK_RECURSIVE or LOCK_ERRORCHECK is set. */ if ((mtype & LOCK_ERRORCHECK) && !MUTEX_OWNED(mp, self)) return (EPERM); if ((mtype & LOCK_RECURSIVE) && mp->mutex_rcount != 0) { mp->mutex_rcount--; DTRACE_PROBE2(plockstat, mutex__release, mp, 1); return (0); } } /* * Only one thread exists so we don't need an atomic operation. * Also, there can be no waiters. */ mp->mutex_owner = 0; mp->mutex_lockword = 0; DTRACE_PROBE2(plockstat, mutex__release, mp, 0); return (0); } /* * Optimize the common cases of USYNC_THREAD or USYNC_PROCESS, * no error detection, and no lock statistics. * Include LOCK_RECURSIVE and LOCK_ERRORCHECK cases. */ if ((gflags = self->ul_schedctl_called) != NULL) { if (((el = gflags->uf_trs_ted) | mtype) == 0) { fast_unlock: if ((lwpid = mutex_unlock_queue(mp, 0)) != 0) { (void) __lwp_unpark(lwpid); preempt(self); } return (0); } if (el) /* error detection or lock statistics */ goto slow_unlock; if ((mtype & ~(LOCK_RECURSIVE|LOCK_ERRORCHECK)) == 0) { /* * At this point we know that one or both of the * flags LOCK_RECURSIVE or LOCK_ERRORCHECK is set. */ if ((mtype & LOCK_ERRORCHECK) && !MUTEX_OWNED(mp, self)) return (EPERM); if ((mtype & LOCK_RECURSIVE) && mp->mutex_rcount != 0) { mp->mutex_rcount--; DTRACE_PROBE2(plockstat, mutex__release, mp, 1); return (0); } goto fast_unlock; } if ((mtype & ~(USYNC_PROCESS|LOCK_RECURSIVE|LOCK_ERRORCHECK)) == 0) { /* * At this point we know that zero, one, or both of the * flags LOCK_RECURSIVE or LOCK_ERRORCHECK is set and * that the USYNC_PROCESS flag is set. */ if ((mtype & LOCK_ERRORCHECK) && !shared_mutex_held(mp)) return (EPERM); if ((mtype & LOCK_RECURSIVE) && mp->mutex_rcount != 0) { mp->mutex_rcount--; DTRACE_PROBE2(plockstat, mutex__release, mp, 1); return (0); } mutex_unlock_process(mp, 0); return (0); } } /* else do it the long way */ slow_unlock: return (mutex_unlock_internal(mp, 0)); } /* * Internally to the library, almost all mutex lock/unlock actions * go through these lmutex_ functions, to protect critical regions. * We replicate a bit of code from __mutex_lock() and __mutex_unlock() * to make these functions faster since we know that the mutex type * of all internal locks is USYNC_THREAD. We also know that internal * locking can never fail, so we panic if it does. */ void lmutex_lock(mutex_t *mp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; ASSERT(mp->mutex_type == USYNC_THREAD); enter_critical(self); /* * Optimize the case of no lock statistics and only a single thread. * (Most likely a traditional single-threaded application.) */ if (udp->uberflags.uf_all == 0) { /* * Only one thread exists; the mutex must be free. */ ASSERT(mp->mutex_lockw == 0); mp->mutex_lockw = LOCKSET; mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); } else { tdb_mutex_stats_t *msp = MUTEX_STATS(mp, udp); if (!self->ul_schedctl_called) (void) setup_schedctl(); if (set_lock_byte(&mp->mutex_lockw) == 0) { mp->mutex_owner = (uintptr_t)self; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); } else if (mutex_trylock_adaptive(mp, 1) != 0) { (void) mutex_lock_queue(self, msp, mp, NULL); } if (msp) record_begin_hold(msp); } } void lmutex_unlock(mutex_t *mp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; ASSERT(mp->mutex_type == USYNC_THREAD); /* * Optimize the case of no lock statistics and only a single thread. * (Most likely a traditional single-threaded application.) */ if (udp->uberflags.uf_all == 0) { /* * Only one thread exists so there can be no waiters. */ mp->mutex_owner = 0; mp->mutex_lockword = 0; DTRACE_PROBE2(plockstat, mutex__release, mp, 0); } else { tdb_mutex_stats_t *msp = MUTEX_STATS(mp, udp); lwpid_t lwpid; if (msp) (void) record_hold_time(msp); if ((lwpid = mutex_unlock_queue(mp, 0)) != 0) { (void) __lwp_unpark(lwpid); preempt(self); } } exit_critical(self); } /* * For specialized code in libc, like the asynchronous i/o code, * the following sig_*() locking primitives are used in order * to make the code asynchronous signal safe. Signals are * deferred while locks acquired by these functions are held. */ void sig_mutex_lock(mutex_t *mp) { sigoff(curthread); (void) mutex_lock(mp); } void sig_mutex_unlock(mutex_t *mp) { (void) mutex_unlock(mp); sigon(curthread); } int sig_mutex_trylock(mutex_t *mp) { int error; sigoff(curthread); if ((error = mutex_trylock(mp)) != 0) sigon(curthread); return (error); } /* * sig_cond_wait() is a cancellation point. */ int sig_cond_wait(cond_t *cv, mutex_t *mp) { int error; ASSERT(curthread->ul_sigdefer != 0); pthread_testcancel(); error = __cond_wait(cv, mp); if (error == EINTR && curthread->ul_cursig) { sig_mutex_unlock(mp); /* take the deferred signal here */ sig_mutex_lock(mp); } pthread_testcancel(); return (error); } /* * sig_cond_reltimedwait() is a cancellation point. */ int sig_cond_reltimedwait(cond_t *cv, mutex_t *mp, const timespec_t *ts) { int error; ASSERT(curthread->ul_sigdefer != 0); pthread_testcancel(); error = __cond_reltimedwait(cv, mp, ts); if (error == EINTR && curthread->ul_cursig) { sig_mutex_unlock(mp); /* take the deferred signal here */ sig_mutex_lock(mp); } pthread_testcancel(); return (error); } /* * For specialized code in libc, like the stdio code. * the following cancel_safe_*() locking primitives are used in * order to make the code cancellation-safe. Cancellation is * deferred while locks acquired by these functions are held. */ void cancel_safe_mutex_lock(mutex_t *mp) { (void) mutex_lock(mp); curthread->ul_libc_locks++; } int cancel_safe_mutex_trylock(mutex_t *mp) { int error; if ((error = mutex_trylock(mp)) == 0) curthread->ul_libc_locks++; return (error); } void cancel_safe_mutex_unlock(mutex_t *mp) { ulwp_t *self = curthread; ASSERT(self->ul_libc_locks != 0); (void) mutex_unlock(mp); /* * Decrement the count of locks held by cancel_safe_mutex_lock(). * If we are then in a position to terminate cleanly and * if there is a pending cancellation and cancellation * is not disabled and we received EINTR from a recent * system call then perform the cancellation action now. */ if (--self->ul_libc_locks == 0 && !(self->ul_vfork | self->ul_nocancel | self->ul_critical | self->ul_sigdefer) && cancel_active()) _pthread_exit(PTHREAD_CANCELED); } static int shared_mutex_held(mutex_t *mparg) { /* * The 'volatile' is necessary to make sure the compiler doesn't * reorder the tests of the various components of the mutex. * They must be tested in this order: * mutex_lockw * mutex_owner * mutex_ownerpid * This relies on the fact that everywhere mutex_lockw is cleared, * mutex_owner and mutex_ownerpid are cleared before mutex_lockw * is cleared, and that everywhere mutex_lockw is set, mutex_owner * and mutex_ownerpid are set after mutex_lockw is set, and that * mutex_lockw is set or cleared with a memory barrier. */ volatile mutex_t *mp = (volatile mutex_t *)mparg; ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; return (MUTEX_OWNED(mp, self) && mp->mutex_ownerpid == udp->pid); } /* * Some crufty old programs define their own version of _mutex_held() * to be simply return(1). This breaks internal libc logic, so we * define a private version for exclusive use by libc, mutex_is_held(), * and also a new public function, __mutex_held(), to be used in new * code to circumvent these crufty old programs. */ #pragma weak mutex_held = mutex_is_held #pragma weak _mutex_held = mutex_is_held #pragma weak __mutex_held = mutex_is_held int mutex_is_held(mutex_t *mparg) { volatile mutex_t *mp = (volatile mutex_t *)mparg; if (mparg->mutex_type & USYNC_PROCESS) return (shared_mutex_held(mparg)); return (MUTEX_OWNED(mp, curthread)); } #pragma weak mutex_destroy = __mutex_destroy #pragma weak _mutex_destroy = __mutex_destroy #pragma weak pthread_mutex_destroy = __mutex_destroy #pragma weak _pthread_mutex_destroy = __mutex_destroy int __mutex_destroy(mutex_t *mp) { if (mp->mutex_type & USYNC_PROCESS) forget_lock(mp); (void) memset(mp, 0, sizeof (*mp)); tdb_sync_obj_deregister(mp); return (0); } #pragma weak mutex_consistent = __mutex_consistent #pragma weak _mutex_consistent = __mutex_consistent #pragma weak pthread_mutex_consistent_np = __mutex_consistent #pragma weak _pthread_mutex_consistent_np = __mutex_consistent int __mutex_consistent(mutex_t *mp) { /* * Do this only for an inconsistent, initialized robust lock * that we hold. For all other cases, return EINVAL. */ if (mutex_is_held(mp) && (mp->mutex_type & LOCK_ROBUST) && (mp->mutex_flag & LOCK_INITED) && (mp->mutex_flag & (LOCK_OWNERDEAD | LOCK_UNMAPPED))) { mp->mutex_flag &= ~(LOCK_OWNERDEAD | LOCK_UNMAPPED); mp->mutex_rcount = 0; return (0); } return (EINVAL); } /* * Spin locks are separate from ordinary mutexes, * but we use the same data structure for them. */ #pragma weak pthread_spin_init = _pthread_spin_init int _pthread_spin_init(pthread_spinlock_t *lock, int pshared) { mutex_t *mp = (mutex_t *)lock; (void) memset(mp, 0, sizeof (*mp)); if (pshared == PTHREAD_PROCESS_SHARED) mp->mutex_type = USYNC_PROCESS; else mp->mutex_type = USYNC_THREAD; mp->mutex_flag = LOCK_INITED; mp->mutex_magic = MUTEX_MAGIC; return (0); } #pragma weak pthread_spin_destroy = _pthread_spin_destroy int _pthread_spin_destroy(pthread_spinlock_t *lock) { (void) memset(lock, 0, sizeof (*lock)); return (0); } #pragma weak pthread_spin_trylock = _pthread_spin_trylock int _pthread_spin_trylock(pthread_spinlock_t *lock) { mutex_t *mp = (mutex_t *)lock; ulwp_t *self = curthread; int error = 0; no_preempt(self); if (set_lock_byte(&mp->mutex_lockw) != 0) error = EBUSY; else { mp->mutex_owner = (uintptr_t)self; if (mp->mutex_type == USYNC_PROCESS) mp->mutex_ownerpid = self->ul_uberdata->pid; DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, 0); } preempt(self); return (error); } #pragma weak pthread_spin_lock = _pthread_spin_lock int _pthread_spin_lock(pthread_spinlock_t *lock) { mutex_t *mp = (mutex_t *)lock; ulwp_t *self = curthread; volatile uint8_t *lockp = (volatile uint8_t *)&mp->mutex_lockw; int count = 0; ASSERT(!self->ul_critical || self->ul_bindflags); DTRACE_PROBE1(plockstat, mutex__spin, mp); /* * We don't care whether the owner is running on a processor. * We just spin because that's what this interface requires. */ for (;;) { if (*lockp == 0) { /* lock byte appears to be clear */ no_preempt(self); if (set_lock_byte(lockp) == 0) break; preempt(self); } if (count < INT_MAX) count++; SMT_PAUSE(); } mp->mutex_owner = (uintptr_t)self; if (mp->mutex_type == USYNC_PROCESS) mp->mutex_ownerpid = self->ul_uberdata->pid; preempt(self); if (count) { DTRACE_PROBE2(plockstat, mutex__spun, 1, count); } DTRACE_PROBE3(plockstat, mutex__acquire, mp, 0, count); return (0); } #pragma weak pthread_spin_unlock = _pthread_spin_unlock int _pthread_spin_unlock(pthread_spinlock_t *lock) { mutex_t *mp = (mutex_t *)lock; ulwp_t *self = curthread; no_preempt(self); mp->mutex_owner = 0; mp->mutex_ownerpid = 0; DTRACE_PROBE2(plockstat, mutex__release, mp, 0); (void) atomic_swap_32(&mp->mutex_lockword, 0); preempt(self); return (0); } #define INITIAL_LOCKS 8 /* initial size of ul_heldlocks.array */ /* * Find/allocate an entry for 'lock' in our array of held locks. */ static mutex_t ** find_lock_entry(mutex_t *lock) { ulwp_t *self = curthread; mutex_t **remembered = NULL; mutex_t **lockptr; uint_t nlocks; if ((nlocks = self->ul_heldlockcnt) != 0) lockptr = self->ul_heldlocks.array; else { nlocks = 1; lockptr = &self->ul_heldlocks.single; } for (; nlocks; nlocks--, lockptr++) { if (*lockptr == lock) return (lockptr); if (*lockptr == NULL && remembered == NULL) remembered = lockptr; } if (remembered != NULL) { *remembered = lock; return (remembered); } /* * No entry available. Allocate more space, converting * the single entry into an array of entries if necessary. */ if ((nlocks = self->ul_heldlockcnt) == 0) { /* * Initial allocation of the array. * Convert the single entry into an array. */ self->ul_heldlockcnt = nlocks = INITIAL_LOCKS; lockptr = lmalloc(nlocks * sizeof (mutex_t *)); /* * The single entry becomes the first entry in the array. */ *lockptr = self->ul_heldlocks.single; self->ul_heldlocks.array = lockptr; /* * Return the next available entry in the array. */ *++lockptr = lock; return (lockptr); } /* * Reallocate the array, double the size each time. */ lockptr = lmalloc(nlocks * 2 * sizeof (mutex_t *)); (void) memcpy(lockptr, self->ul_heldlocks.array, nlocks * sizeof (mutex_t *)); lfree(self->ul_heldlocks.array, nlocks * sizeof (mutex_t *)); self->ul_heldlocks.array = lockptr; self->ul_heldlockcnt *= 2; /* * Return the next available entry in the newly allocated array. */ *(lockptr += nlocks) = lock; return (lockptr); } /* * Insert 'lock' into our list of held locks. * Currently only used for LOCK_ROBUST mutexes. */ void remember_lock(mutex_t *lock) { (void) find_lock_entry(lock); } /* * Remove 'lock' from our list of held locks. * Currently only used for LOCK_ROBUST mutexes. */ void forget_lock(mutex_t *lock) { *find_lock_entry(lock) = NULL; } /* * Free the array of held locks. */ void heldlock_free(ulwp_t *ulwp) { uint_t nlocks; if ((nlocks = ulwp->ul_heldlockcnt) != 0) lfree(ulwp->ul_heldlocks.array, nlocks * sizeof (mutex_t *)); ulwp->ul_heldlockcnt = 0; ulwp->ul_heldlocks.array = NULL; } /* * Mark all held LOCK_ROBUST mutexes LOCK_OWNERDEAD. * Called from _thrp_exit() to deal with abandoned locks. */ void heldlock_exit(void) { ulwp_t *self = curthread; mutex_t **lockptr; uint_t nlocks; mutex_t *mp; if ((nlocks = self->ul_heldlockcnt) != 0) lockptr = self->ul_heldlocks.array; else { nlocks = 1; lockptr = &self->ul_heldlocks.single; } for (; nlocks; nlocks--, lockptr++) { /* * The kernel takes care of transitioning held * LOCK_PRIO_INHERIT mutexes to LOCK_OWNERDEAD. * We avoid that case here. */ if ((mp = *lockptr) != NULL && mutex_is_held(mp) && (mp->mutex_type & (LOCK_ROBUST | LOCK_PRIO_INHERIT)) == LOCK_ROBUST) { mp->mutex_rcount = 0; if (!(mp->mutex_flag & LOCK_UNMAPPED)) mp->mutex_flag |= LOCK_OWNERDEAD; (void) mutex_unlock_internal(mp, 1); } } heldlock_free(self); } #pragma weak cond_init = _cond_init /* ARGSUSED2 */ int _cond_init(cond_t *cvp, int type, void *arg) { if (type != USYNC_THREAD && type != USYNC_PROCESS) return (EINVAL); (void) memset(cvp, 0, sizeof (*cvp)); cvp->cond_type = (uint16_t)type; cvp->cond_magic = COND_MAGIC; return (0); } /* * cond_sleep_queue(): utility function for cond_wait_queue(). * * Go to sleep on a condvar sleep queue, expect to be waked up * by someone calling cond_signal() or cond_broadcast() or due * to receiving a UNIX signal or being cancelled, or just simply * due to a spurious wakeup (like someome calling forkall()). * * The associated mutex is *not* reacquired before returning. * That must be done by the caller of cond_sleep_queue(). */ static int cond_sleep_queue(cond_t *cvp, mutex_t *mp, timespec_t *tsp) { ulwp_t *self = curthread; queue_head_t *qp; queue_head_t *mqp; lwpid_t lwpid; int signalled; int error; int cv_wake; int release_all; /* * Put ourself on the CV sleep queue, unlock the mutex, then * park ourself and unpark a candidate lwp to grab the mutex. * We must go onto the CV sleep queue before dropping the * mutex in order to guarantee atomicity of the operation. */ self->ul_sp = stkptr(); qp = queue_lock(cvp, CV); enqueue(qp, self, 0); cvp->cond_waiters_user = 1; self->ul_cvmutex = mp; self->ul_cv_wake = cv_wake = (tsp != NULL); self->ul_signalled = 0; if (mp->mutex_flag & LOCK_OWNERDEAD) { mp->mutex_flag &= ~LOCK_OWNERDEAD; mp->mutex_flag |= LOCK_NOTRECOVERABLE; } release_all = ((mp->mutex_flag & LOCK_NOTRECOVERABLE) != 0); lwpid = mutex_unlock_queue(mp, release_all); for (;;) { set_parking_flag(self, 1); queue_unlock(qp); if (lwpid != 0) { lwpid = preempt_unpark(self, lwpid); preempt(self); } /* * We may have a deferred signal present, * in which case we should return EINTR. * Also, we may have received a SIGCANCEL; if so * and we are cancelable we should return EINTR. * We force an immediate EINTR return from * __lwp_park() by turning our parking flag off. */ if (self->ul_cursig != 0 || (self->ul_cancelable && self->ul_cancel_pending)) set_parking_flag(self, 0); /* * __lwp_park() will return the residual time in tsp * if we are unparked before the timeout expires. */ error = __lwp_park(tsp, lwpid); set_parking_flag(self, 0); lwpid = 0; /* unpark the other lwp only once */ /* * We were waked up by cond_signal(), cond_broadcast(), * by an interrupt or timeout (EINTR or ETIME), * or we may just have gotten a spurious wakeup. */ qp = queue_lock(cvp, CV); if (!cv_wake) mqp = queue_lock(mp, MX); if (self->ul_sleepq == NULL) break; /* * We are on either the condvar sleep queue or the * mutex sleep queue. Break out of the sleep if we * were interrupted or we timed out (EINTR or ETIME). * Else this is a spurious wakeup; continue the loop. */ if (!cv_wake && self->ul_sleepq == mqp) { /* mutex queue */ if (error) { mp->mutex_waiters = dequeue_self(mqp); break; } tsp = NULL; /* no more timeout */ } else if (self->ul_sleepq == qp) { /* condvar queue */ if (error) { cvp->cond_waiters_user = dequeue_self(qp); break; } /* * Else a spurious wakeup on the condvar queue. * __lwp_park() has already adjusted the timeout. */ } else { thr_panic("cond_sleep_queue(): thread not on queue"); } if (!cv_wake) queue_unlock(mqp); } self->ul_sp = 0; self->ul_cv_wake = 0; ASSERT(self->ul_cvmutex == NULL); ASSERT(self->ul_sleepq == NULL && self->ul_link == NULL && self->ul_wchan == NULL); signalled = self->ul_signalled; self->ul_signalled = 0; queue_unlock(qp); if (!cv_wake) queue_unlock(mqp); /* * If we were concurrently cond_signal()d and any of: * received a UNIX signal, were cancelled, or got a timeout, * then perform another cond_signal() to avoid consuming it. */ if (error && signalled) (void) cond_signal_internal(cvp); return (error); } int cond_wait_queue(cond_t *cvp, mutex_t *mp, timespec_t *tsp) { ulwp_t *self = curthread; int error; int merror; /* * The old thread library was programmed to defer signals * while in cond_wait() so that the associated mutex would * be guaranteed to be held when the application signal * handler was invoked. * * We do not behave this way by default; the state of the * associated mutex in the signal handler is undefined. * * To accommodate applications that depend on the old * behavior, the _THREAD_COND_WAIT_DEFER environment * variable can be set to 1 and we will behave in the * old way with respect to cond_wait(). */ if (self->ul_cond_wait_defer) sigoff(self); error = cond_sleep_queue(cvp, mp, tsp); /* * Reacquire the mutex. */ if ((merror = mutex_lock_impl(mp, NULL)) != 0) error = merror; /* * Take any deferred signal now, after we have reacquired the mutex. */ if (self->ul_cond_wait_defer) sigon(self); return (error); } /* * cond_sleep_kernel(): utility function for cond_wait_kernel(). * See the comment ahead of cond_sleep_queue(), above. */ static int cond_sleep_kernel(cond_t *cvp, mutex_t *mp, timespec_t *tsp) { int mtype = mp->mutex_type; ulwp_t *self = curthread; int error; if ((mtype & LOCK_PRIO_PROTECT) && _ceil_mylist_del(mp)) _ceil_prio_waive(); self->ul_sp = stkptr(); self->ul_wchan = cvp; mp->mutex_owner = 0; /* mp->mutex_ownerpid is cleared by ___lwp_cond_wait() */ if (mtype & LOCK_PRIO_INHERIT) { mp->mutex_lockw = LOCKCLEAR; self->ul_pilocks--; } /* * ___lwp_cond_wait() returns immediately with EINTR if * set_parking_flag(self,0) is called on this lwp before it * goes to sleep in the kernel. sigacthandler() calls this * when a deferred signal is noted. This assures that we don't * get stuck in ___lwp_cond_wait() with all signals blocked * due to taking a deferred signal before going to sleep. */ set_parking_flag(self, 1); if (self->ul_cursig != 0 || (self->ul_cancelable && self->ul_cancel_pending)) set_parking_flag(self, 0); error = ___lwp_cond_wait(cvp, mp, tsp, 1); set_parking_flag(self, 0); self->ul_sp = 0; self->ul_wchan = NULL; return (error); } int cond_wait_kernel(cond_t *cvp, mutex_t *mp, timespec_t *tsp) { ulwp_t *self = curthread; int error; int merror; /* * See the large comment in cond_wait_queue(), above. */ if (self->ul_cond_wait_defer) sigoff(self); error = cond_sleep_kernel(cvp, mp, tsp); /* * Override the return code from ___lwp_cond_wait() * with any non-zero return code from mutex_lock(). * This addresses robust lock failures in particular; * the caller must see the EOWNERDEAD or ENOTRECOVERABLE * errors in order to take corrective action. */ if ((merror = mutex_lock_impl(mp, NULL)) != 0) error = merror; /* * Take any deferred signal now, after we have reacquired the mutex. */ if (self->ul_cond_wait_defer) sigon(self); return (error); } /* * Common code for _cond_wait() and _cond_timedwait() */ int cond_wait_common(cond_t *cvp, mutex_t *mp, timespec_t *tsp) { int mtype = mp->mutex_type; hrtime_t begin_sleep = 0; ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; tdb_cond_stats_t *csp = COND_STATS(cvp, udp); tdb_mutex_stats_t *msp = MUTEX_STATS(mp, udp); uint8_t rcount; int error = 0; /* * The SUSV3 Posix spec for pthread_cond_timedwait() states: * Except in the case of [ETIMEDOUT], all these error checks * shall act as if they were performed immediately at the * beginning of processing for the function and shall cause * an error return, in effect, prior to modifying the state * of the mutex specified by mutex or the condition variable * specified by cond. * Therefore, we must return EINVAL now if the timout is invalid. */ if (tsp != NULL && (tsp->tv_sec < 0 || (ulong_t)tsp->tv_nsec >= NANOSEC)) return (EINVAL); if (__td_event_report(self, TD_SLEEP, udp)) { self->ul_sp = stkptr(); self->ul_wchan = cvp; self->ul_td_evbuf.eventnum = TD_SLEEP; self->ul_td_evbuf.eventdata = cvp; tdb_event(TD_SLEEP, udp); self->ul_sp = 0; } if (csp) { if (tsp) tdb_incr(csp->cond_timedwait); else tdb_incr(csp->cond_wait); } if (msp) begin_sleep = record_hold_time(msp); else if (csp) begin_sleep = gethrtime(); if (self->ul_error_detection) { if (!mutex_is_held(mp)) lock_error(mp, "cond_wait", cvp, NULL); if ((mtype & LOCK_RECURSIVE) && mp->mutex_rcount != 0) lock_error(mp, "recursive mutex in cond_wait", cvp, NULL); if (cvp->cond_type & USYNC_PROCESS) { if (!(mtype & USYNC_PROCESS)) lock_error(mp, "cond_wait", cvp, "condvar process-shared, " "mutex process-private"); } else { if (mtype & USYNC_PROCESS) lock_error(mp, "cond_wait", cvp, "condvar process-private, " "mutex process-shared"); } } /* * We deal with recursive mutexes by completely * dropping the lock and restoring the recursion * count after waking up. This is arguably wrong, * but it obeys the principle of least astonishment. */ rcount = mp->mutex_rcount; mp->mutex_rcount = 0; if ((mtype & (USYNC_PROCESS | LOCK_PRIO_INHERIT | LOCK_PRIO_PROTECT)) | (cvp->cond_type & USYNC_PROCESS)) error = cond_wait_kernel(cvp, mp, tsp); else error = cond_wait_queue(cvp, mp, tsp); mp->mutex_rcount = rcount; if (csp) { hrtime_t lapse = gethrtime() - begin_sleep; if (tsp == NULL) csp->cond_wait_sleep_time += lapse; else { csp->cond_timedwait_sleep_time += lapse; if (error == ETIME) tdb_incr(csp->cond_timedwait_timeout); } } return (error); } /* * cond_wait() and _cond_wait() are cancellation points but __cond_wait() * is not. Internally, libc calls the non-cancellation version. * Other libraries need to use pthread_setcancelstate(), as appropriate, * since __cond_wait() is not exported from libc. */ int __cond_wait(cond_t *cvp, mutex_t *mp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; uberflags_t *gflags; /* * Optimize the common case of USYNC_THREAD plus * no error detection, no lock statistics, and no event tracing. */ if ((gflags = self->ul_schedctl_called) != NULL && (cvp->cond_type | mp->mutex_type | gflags->uf_trs_ted | self->ul_td_events_enable | udp->tdb.tdb_ev_global_mask.event_bits[0]) == 0) return (cond_wait_queue(cvp, mp, NULL)); /* * Else do it the long way. */ return (cond_wait_common(cvp, mp, NULL)); } #pragma weak cond_wait = _cond_wait int _cond_wait(cond_t *cvp, mutex_t *mp) { int error; _cancelon(); error = __cond_wait(cvp, mp); if (error == EINTR) _canceloff(); else _canceloff_nocancel(); return (error); } /* * pthread_cond_wait() is a cancellation point. */ #pragma weak pthread_cond_wait = _pthread_cond_wait int _pthread_cond_wait(cond_t *cvp, mutex_t *mp) { int error; error = _cond_wait(cvp, mp); return ((error == EINTR)? 0 : error); } /* * cond_timedwait() and _cond_timedwait() are cancellation points * but __cond_timedwait() is not. */ int __cond_timedwait(cond_t *cvp, mutex_t *mp, const timespec_t *abstime) { clockid_t clock_id = cvp->cond_clockid; timespec_t reltime; int error; if (clock_id != CLOCK_REALTIME && clock_id != CLOCK_HIGHRES) clock_id = CLOCK_REALTIME; abstime_to_reltime(clock_id, abstime, &reltime); error = cond_wait_common(cvp, mp, &reltime); if (error == ETIME && clock_id == CLOCK_HIGHRES) { /* * Don't return ETIME if we didn't really get a timeout. * This can happen if we return because someone resets * the system clock. Just return zero in this case, * giving a spurious wakeup but not a timeout. */ if ((hrtime_t)(uint32_t)abstime->tv_sec * NANOSEC + abstime->tv_nsec > gethrtime()) error = 0; } return (error); } #pragma weak cond_timedwait = _cond_timedwait int _cond_timedwait(cond_t *cvp, mutex_t *mp, const timespec_t *abstime) { int error; _cancelon(); error = __cond_timedwait(cvp, mp, abstime); if (error == EINTR) _canceloff(); else _canceloff_nocancel(); return (error); } /* * pthread_cond_timedwait() is a cancellation point. */ #pragma weak pthread_cond_timedwait = _pthread_cond_timedwait int _pthread_cond_timedwait(cond_t *cvp, mutex_t *mp, const timespec_t *abstime) { int error; error = _cond_timedwait(cvp, mp, abstime); if (error == ETIME) error = ETIMEDOUT; else if (error == EINTR) error = 0; return (error); } /* * cond_reltimedwait() and _cond_reltimedwait() are cancellation points * but __cond_reltimedwait() is not. */ int __cond_reltimedwait(cond_t *cvp, mutex_t *mp, const timespec_t *reltime) { timespec_t tslocal = *reltime; return (cond_wait_common(cvp, mp, &tslocal)); } #pragma weak cond_reltimedwait = _cond_reltimedwait int _cond_reltimedwait(cond_t *cvp, mutex_t *mp, const timespec_t *reltime) { int error; _cancelon(); error = __cond_reltimedwait(cvp, mp, reltime); if (error == EINTR) _canceloff(); else _canceloff_nocancel(); return (error); } #pragma weak pthread_cond_reltimedwait_np = _pthread_cond_reltimedwait_np int _pthread_cond_reltimedwait_np(cond_t *cvp, mutex_t *mp, const timespec_t *reltime) { int error; error = _cond_reltimedwait(cvp, mp, reltime); if (error == ETIME) error = ETIMEDOUT; else if (error == EINTR) error = 0; return (error); } #pragma weak pthread_cond_signal = cond_signal_internal #pragma weak _pthread_cond_signal = cond_signal_internal #pragma weak cond_signal = cond_signal_internal #pragma weak _cond_signal = cond_signal_internal int cond_signal_internal(cond_t *cvp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; tdb_cond_stats_t *csp = COND_STATS(cvp, udp); int error = 0; int more; lwpid_t lwpid; queue_head_t *qp; mutex_t *mp; queue_head_t *mqp; ulwp_t **ulwpp; ulwp_t *ulwp; ulwp_t *prev; if (csp) tdb_incr(csp->cond_signal); if (cvp->cond_waiters_kernel) /* someone sleeping in the kernel? */ error = __lwp_cond_signal(cvp); if (!cvp->cond_waiters_user) /* no one sleeping at user-level */ return (error); /* * Move someone from the condvar sleep queue to the mutex sleep * queue for the mutex that he will acquire on being waked up. * We can do this only if we own the mutex he will acquire. * If we do not own the mutex, or if his ul_cv_wake flag * is set, just dequeue and unpark him. */ qp = queue_lock(cvp, CV); ulwpp = queue_slot(qp, &prev, &more); cvp->cond_waiters_user = more; if (ulwpp == NULL) { /* no one on the sleep queue */ queue_unlock(qp); return (error); } ulwp = *ulwpp; /* * Inform the thread that he was the recipient of a cond_signal(). * This lets him deal with cond_signal() and, concurrently, * one or more of a cancellation, a UNIX signal, or a timeout. * These latter conditions must not consume a cond_signal(). */ ulwp->ul_signalled = 1; /* * Dequeue the waiter but leave his ul_sleepq non-NULL * while we move him to the mutex queue so that he can * deal properly with spurious wakeups. */ queue_unlink(qp, ulwpp, prev); mp = ulwp->ul_cvmutex; /* the mutex he will acquire */ ulwp->ul_cvmutex = NULL; ASSERT(mp != NULL); if (ulwp->ul_cv_wake || !MUTEX_OWNED(mp, self)) { /* just wake him up */ lwpid = ulwp->ul_lwpid; no_preempt(self); ulwp->ul_sleepq = NULL; ulwp->ul_wchan = NULL; queue_unlock(qp); (void) __lwp_unpark(lwpid); preempt(self); } else { /* move him to the mutex queue */ mqp = queue_lock(mp, MX); enqueue(mqp, ulwp, 0); mp->mutex_waiters = 1; queue_unlock(mqp); queue_unlock(qp); } return (error); } /* * Utility function called by mutex_wakeup_all(), cond_broadcast(), * and rw_queue_release() to (re)allocate a big buffer to hold the * lwpids of all the threads to be set running after they are removed * from their sleep queues. Since we are holding a queue lock, we * cannot call any function that might acquire a lock. mmap(), munmap(), * lwp_unpark_all() are simple system calls and are safe in this regard. */ lwpid_t * alloc_lwpids(lwpid_t *lwpid, int *nlwpid_ptr, int *maxlwps_ptr) { /* * Allocate NEWLWPS ids on the first overflow. * Double the allocation each time after that. */ int nlwpid = *nlwpid_ptr; int maxlwps = *maxlwps_ptr; int first_allocation; int newlwps; void *vaddr; ASSERT(nlwpid == maxlwps); first_allocation = (maxlwps == MAXLWPS); newlwps = first_allocation? NEWLWPS : 2 * maxlwps; vaddr = mmap(NULL, newlwps * sizeof (lwpid_t), PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, (off_t)0); if (vaddr == MAP_FAILED) { /* * Let's hope this never happens. * If it does, then we have a terrible * thundering herd on our hands. */ (void) __lwp_unpark_all(lwpid, nlwpid); *nlwpid_ptr = 0; } else { (void) memcpy(vaddr, lwpid, maxlwps * sizeof (lwpid_t)); if (!first_allocation) (void) munmap((caddr_t)lwpid, maxlwps * sizeof (lwpid_t)); lwpid = vaddr; *maxlwps_ptr = newlwps; } return (lwpid); } #pragma weak pthread_cond_broadcast = cond_broadcast_internal #pragma weak _pthread_cond_broadcast = cond_broadcast_internal #pragma weak cond_broadcast = cond_broadcast_internal #pragma weak _cond_broadcast = cond_broadcast_internal int cond_broadcast_internal(cond_t *cvp) { ulwp_t *self = curthread; uberdata_t *udp = self->ul_uberdata; tdb_cond_stats_t *csp = COND_STATS(cvp, udp); int error = 0; queue_head_t *qp; queue_root_t *qrp; mutex_t *mp; mutex_t *mp_cache = NULL; queue_head_t *mqp = NULL; ulwp_t *ulwp; int nlwpid = 0; int maxlwps = MAXLWPS; lwpid_t buffer[MAXLWPS]; lwpid_t *lwpid = buffer; if (csp) tdb_incr(csp->cond_broadcast); if (cvp->cond_waiters_kernel) /* someone sleeping in the kernel? */ error = __lwp_cond_broadcast(cvp); if (!cvp->cond_waiters_user) /* no one sleeping at user-level */ return (error); /* * Move everyone from the condvar sleep queue to the mutex sleep * queue for the mutex that they will acquire on being waked up. * We can do this only if we own the mutex they will acquire. * If we do not own the mutex, or if their ul_cv_wake flag * is set, just dequeue and unpark them. * * We keep track of lwpids that are to be unparked in lwpid[]. * __lwp_unpark_all() is called to unpark all of them after * they have been removed from the sleep queue and the sleep * queue lock has been dropped. If we run out of space in our * on-stack buffer, we need to allocate more but we can't call * lmalloc() because we are holding a queue lock when the overflow * occurs and lmalloc() acquires a lock. We can't use alloca() * either because the application may have allocated a small * stack and we don't want to overrun the stack. So we call * alloc_lwpids() to allocate a bigger buffer using the mmap() * system call directly since that path acquires no locks. */ qp = queue_lock(cvp, CV); cvp->cond_waiters_user = 0; for (;;) { if ((qrp = qp->qh_root) == NULL || (ulwp = qrp->qr_head) == NULL) break; ASSERT(ulwp->ul_wchan == cvp); queue_unlink(qp, &qrp->qr_head, NULL); mp = ulwp->ul_cvmutex; /* his mutex */ ulwp->ul_cvmutex = NULL; ASSERT(mp != NULL); if (ulwp->ul_cv_wake || !MUTEX_OWNED(mp, self)) { /* just wake him up */ ulwp->ul_sleepq = NULL; ulwp->ul_wchan = NULL; if (nlwpid == maxlwps) lwpid = alloc_lwpids(lwpid, &nlwpid, &maxlwps); lwpid[nlwpid++] = ulwp->ul_lwpid; } else { /* move him to the mutex queue */ if (mp != mp_cache) { mp_cache = mp; if (mqp != NULL) queue_unlock(mqp); mqp = queue_lock(mp, MX); } enqueue(mqp, ulwp, 0); mp->mutex_waiters = 1; } } if (mqp != NULL) queue_unlock(mqp); if (nlwpid == 0) { queue_unlock(qp); } else { no_preempt(self); queue_unlock(qp); if (nlwpid == 1) (void) __lwp_unpark(lwpid[0]); else (void) __lwp_unpark_all(lwpid, nlwpid); preempt(self); } if (lwpid != buffer) (void) munmap((caddr_t)lwpid, maxlwps * sizeof (lwpid_t)); return (error); } #pragma weak pthread_cond_destroy = _cond_destroy #pragma weak _pthread_cond_destroy = _cond_destroy #pragma weak cond_destroy = _cond_destroy int _cond_destroy(cond_t *cvp) { cvp->cond_magic = 0; tdb_sync_obj_deregister(cvp); return (0); } #if defined(THREAD_DEBUG) void assert_no_libc_locks_held(void) { ASSERT(!curthread->ul_critical || curthread->ul_bindflags); } /* protected by link_lock */ uint64_t spin_lock_spin; uint64_t spin_lock_spin2; uint64_t spin_lock_sleep; uint64_t spin_lock_wakeup; /* * Record spin lock statistics. * Called by a thread exiting itself in thrp_exit(). * Also called via atexit() from the thread calling * exit() to do all the other threads as well. */ void record_spin_locks(ulwp_t *ulwp) { spin_lock_spin += ulwp->ul_spin_lock_spin; spin_lock_spin2 += ulwp->ul_spin_lock_spin2; spin_lock_sleep += ulwp->ul_spin_lock_sleep; spin_lock_wakeup += ulwp->ul_spin_lock_wakeup; ulwp->ul_spin_lock_spin = 0; ulwp->ul_spin_lock_spin2 = 0; ulwp->ul_spin_lock_sleep = 0; ulwp->ul_spin_lock_wakeup = 0; } /* * atexit function: dump the queue statistics to stderr. */ #if !defined(__lint) #define fprintf _fprintf #endif #include void dump_queue_statistics(void) { uberdata_t *udp = curthread->ul_uberdata; queue_head_t *qp; int qn; uint64_t spin_lock_total = 0; if (udp->queue_head == NULL || thread_queue_dump == 0) return; if (fprintf(stderr, "\n%5d mutex queues:\n", QHASHSIZE) < 0 || fprintf(stderr, "queue# lockcount max qlen max hlen\n") < 0) return; for (qn = 0, qp = udp->queue_head; qn < QHASHSIZE; qn++, qp++) { if (qp->qh_lockcount == 0) continue; spin_lock_total += qp->qh_lockcount; if (fprintf(stderr, "%5d %12llu%12u%12u\n", qn, (u_longlong_t)qp->qh_lockcount, qp->qh_qmax, qp->qh_hmax) < 0) return; } if (fprintf(stderr, "\n%5d condvar queues:\n", QHASHSIZE) < 0 || fprintf(stderr, "queue# lockcount max qlen max hlen\n") < 0) return; for (qn = 0; qn < QHASHSIZE; qn++, qp++) { if (qp->qh_lockcount == 0) continue; spin_lock_total += qp->qh_lockcount; if (fprintf(stderr, "%5d %12llu%12u%12u\n", qn, (u_longlong_t)qp->qh_lockcount, qp->qh_qmax, qp->qh_hmax) < 0) return; } (void) fprintf(stderr, "\n spin_lock_total = %10llu\n", (u_longlong_t)spin_lock_total); (void) fprintf(stderr, " spin_lock_spin = %10llu\n", (u_longlong_t)spin_lock_spin); (void) fprintf(stderr, " spin_lock_spin2 = %10llu\n", (u_longlong_t)spin_lock_spin2); (void) fprintf(stderr, " spin_lock_sleep = %10llu\n", (u_longlong_t)spin_lock_sleep); (void) fprintf(stderr, " spin_lock_wakeup = %10llu\n", (u_longlong_t)spin_lock_wakeup); } #endif