/* $OpenBSD: rf_stripelocks.c,v 1.4 2000/01/11 18:02:23 peter Exp $ */ /* $NetBSD: rf_stripelocks.c,v 1.5 2000/01/08 23:45:05 oster Exp $ */ /* * Copyright (c) 1995 Carnegie-Mellon University. * All rights reserved. * * Authors: Mark Holland, Jim Zelenka * * Permission to use, copy, modify and distribute this software and * its documentation is hereby granted, provided that both the copyright * notice and this permission notice appear in all copies of the * software, derivative works or modified versions, and any portions * thereof, and that both notices appear in supporting documentation. * * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. * * Carnegie Mellon requests users of this software to return to * * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU * School of Computer Science * Carnegie Mellon University * Pittsburgh PA 15213-3890 * * any improvements or extensions that they make and grant Carnegie the * rights to redistribute these changes. */ /* * stripelocks.c -- code to lock stripes for read and write access * * The code distinguishes between read locks and write locks. There can be * as many readers to given stripe as desired. When a write request comes * in, no further readers are allowed to enter, and all subsequent requests * are queued in FIFO order. When a the number of readers goes to zero, the * writer is given the lock. When a writer releases the lock, the list of * queued requests is scanned, and all readersq up to the next writer are * given the lock. * * The lock table size must be one less than a power of two, but HASH_STRIPEID * is the only function that requires this. * * The code now supports "range locks". When you ask to lock a stripe, you * specify a range of addresses in that stripe that you want to lock. When * you acquire the lock, you've locked only this range of addresses, and * other threads can concurrently read/write any non-overlapping portions * of the stripe. The "addresses" that you lock are abstract in that you * can pass in anything you like. The expectation is that you'll pass in * the range of physical disk offsets of the parity bits you're planning * to update. The idea behind this, of course, is to allow sub-stripe * locking. The implementation is perhaps not the best imaginable; in the * worst case a lock release is O(n^2) in the total number of outstanding * requests to a given stripe. Note that if you're striping with a * stripe unit size equal to an entire disk (i.e. not striping), there will * be only one stripe and you may spend some significant number of cycles * searching through stripe lock descriptors. */ #include "rf_types.h" #include "rf_raid.h" #include "rf_stripelocks.h" #include "rf_alloclist.h" #include "rf_general.h" #include "rf_freelist.h" #include "rf_debugprint.h" #include "rf_driver.h" #include "rf_shutdown.h" #define Dprintf1(s,a) rf_debug_printf(s,(void *)((unsigned long)a),NULL,NULL,NULL,NULL,NULL,NULL,NULL) #define Dprintf2(s,a,b) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),NULL,NULL,NULL,NULL,NULL,NULL) #define Dprintf3(s,a,b,c) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),NULL,NULL,NULL,NULL,NULL) #define Dprintf4(s,a,b,c,d) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),(void *)((unsigned long)d),NULL,NULL,NULL,NULL) #define Dprintf5(s,a,b,c,d,e) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),(void *)((unsigned long)d),(void *)((unsigned long)e),NULL,NULL,NULL) #define Dprintf6(s,a,b,c,d,e,f) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),(void *)((unsigned long)d),(void *)((unsigned long)e),(void *)((unsigned long)f),NULL,NULL) #define Dprintf7(s,a,b,c,d,e,f,g) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),(void *)((unsigned long)d),(void *)((unsigned long)e),(void *)((unsigned long)f),(void *)((unsigned long)g),NULL) #define Dprintf8(s,a,b,c,d,e,f,g,h) rf_debug_printf(s,(void *)((unsigned long)a),(void *)((unsigned long)b),(void *)((unsigned long)c),(void *)((unsigned long)d),(void *)((unsigned long)e),(void *)((unsigned long)f),(void *)((unsigned long)g),(void *)((unsigned long)h)) #define FLUSH #define HASH_STRIPEID(_sid_) ( (_sid_) & (rf_lockTableSize-1) ) static void AddToWaitersQueue(RF_LockTableEntry_t * lockTable, RF_StripeLockDesc_t * lockDesc, RF_LockReqDesc_t * lockReqDesc); static RF_StripeLockDesc_t *AllocStripeLockDesc(RF_StripeNum_t stripeID); static void FreeStripeLockDesc(RF_StripeLockDesc_t * p); static void PrintLockedStripes(RF_LockTableEntry_t * lockTable); /* determines if two ranges overlap. always yields false if either start value is negative */ #define SINGLE_RANGE_OVERLAP(_strt1, _stop1, _strt2, _stop2) \ ( (_strt1 >= 0) && (_strt2 >= 0) && (RF_MAX(_strt1, _strt2) <= RF_MIN(_stop1, _stop2)) ) /* determines if any of the ranges specified in the two lock descriptors overlap each other */ #define RANGE_OVERLAP(_cand, _pred) \ ( SINGLE_RANGE_OVERLAP((_cand)->start, (_cand)->stop, (_pred)->start, (_pred)->stop ) || \ SINGLE_RANGE_OVERLAP((_cand)->start2, (_cand)->stop2, (_pred)->start, (_pred)->stop ) || \ SINGLE_RANGE_OVERLAP((_cand)->start, (_cand)->stop, (_pred)->start2, (_pred)->stop2) || \ SINGLE_RANGE_OVERLAP((_cand)->start2, (_cand)->stop2, (_pred)->start2, (_pred)->stop2) ) /* Determines if a candidate lock request conflicts with a predecessor lock req. * Note that the arguments are not interchangeable. * The rules are: * a candidate read conflicts with a predecessor write if any ranges overlap * a candidate write conflicts with a predecessor read if any ranges overlap * a candidate write conflicts with a predecessor write if any ranges overlap */ #define STRIPELOCK_CONFLICT(_cand, _pred) \ RANGE_OVERLAP((_cand), (_pred)) && \ ( ( (((_cand)->type == RF_IO_TYPE_READ) && ((_pred)->type == RF_IO_TYPE_WRITE)) || \ (((_cand)->type == RF_IO_TYPE_WRITE) && ((_pred)->type == RF_IO_TYPE_READ)) || \ (((_cand)->type == RF_IO_TYPE_WRITE) && ((_pred)->type == RF_IO_TYPE_WRITE)) \ ) \ ) static RF_FreeList_t *rf_stripelock_freelist; #define RF_MAX_FREE_STRIPELOCK 128 #define RF_STRIPELOCK_INC 8 #define RF_STRIPELOCK_INITIAL 32 static void rf_ShutdownStripeLockFreeList(void *); static void rf_RaidShutdownStripeLocks(void *); static void rf_ShutdownStripeLockFreeList(ignored) void *ignored; { RF_FREELIST_DESTROY(rf_stripelock_freelist, next, (RF_StripeLockDesc_t *)); } int rf_ConfigureStripeLockFreeList(listp) RF_ShutdownList_t **listp; { unsigned mask; int rc; RF_FREELIST_CREATE(rf_stripelock_freelist, RF_MAX_FREE_STRIPELOCK, RF_STRIPELOCK_INITIAL, sizeof(RF_StripeLockDesc_t)); rc = rf_ShutdownCreate(listp, rf_ShutdownStripeLockFreeList, NULL); if (rc) { RF_ERRORMSG3("Unable to add to shutdown list file %s line %d rc=%d\n", __FILE__, __LINE__, rc); rf_ShutdownStripeLockFreeList(NULL); return (rc); } RF_FREELIST_PRIME(rf_stripelock_freelist, RF_STRIPELOCK_INITIAL, next, (RF_StripeLockDesc_t *)); for (mask = 0x1; mask; mask <<= 1) if (rf_lockTableSize == mask) break; if (!mask) { printf("[WARNING: lock table size must be a power of two. Setting to %d.]\n", RF_DEFAULT_LOCK_TABLE_SIZE); rf_lockTableSize = RF_DEFAULT_LOCK_TABLE_SIZE; } return (0); } RF_LockTableEntry_t * rf_MakeLockTable() { RF_LockTableEntry_t *lockTable; int i, rc; RF_Calloc(lockTable, ((int) rf_lockTableSize), sizeof(RF_LockTableEntry_t), (RF_LockTableEntry_t *)); if (lockTable == NULL) return (NULL); for (i = 0; i < rf_lockTableSize; i++) { rc = rf_mutex_init(&lockTable[i].mutex); if (rc) { RF_ERRORMSG3("Unable to init mutex file %s line %d rc=%d\n", __FILE__, __LINE__, rc); /* XXX clean up other mutexes */ return (NULL); } } return (lockTable); } void rf_ShutdownStripeLocks(RF_LockTableEntry_t * lockTable) { int i; if (rf_stripeLockDebug) { PrintLockedStripes(lockTable); } for (i = 0; i < rf_lockTableSize; i++) { rf_mutex_destroy(&lockTable[i].mutex); } RF_Free(lockTable, rf_lockTableSize * sizeof(RF_LockTableEntry_t)); } static void rf_RaidShutdownStripeLocks(arg) void *arg; { RF_Raid_t *raidPtr = (RF_Raid_t *) arg; rf_ShutdownStripeLocks(raidPtr->lockTable); } int rf_ConfigureStripeLocks( RF_ShutdownList_t ** listp, RF_Raid_t * raidPtr, RF_Config_t * cfgPtr) { int rc; raidPtr->lockTable = rf_MakeLockTable(); if (raidPtr->lockTable == NULL) return (ENOMEM); rc = rf_ShutdownCreate(listp, rf_RaidShutdownStripeLocks, raidPtr); if (rc) { RF_ERRORMSG3("Unable to add to shutdown list file %s line %d rc=%d\n", __FILE__, __LINE__, rc); rf_ShutdownStripeLocks(raidPtr->lockTable); return (rc); } return (0); } /* returns 0 if you've got the lock, and non-zero if you have to wait. * if and only if you have to wait, we'll cause cbFunc to get invoked * with cbArg when you are granted the lock. We store a tag in *releaseTag * that you need to give back to us when you release the lock. */ int rf_AcquireStripeLock( RF_LockTableEntry_t * lockTable, RF_StripeNum_t stripeID, RF_LockReqDesc_t * lockReqDesc) { RF_StripeLockDesc_t *lockDesc; RF_LockReqDesc_t *p; int tid = 0, hashval = HASH_STRIPEID(stripeID); int retcode = 0; RF_ASSERT(RF_IO_IS_R_OR_W(lockReqDesc->type)); if (rf_stripeLockDebug) { if (stripeID == -1) Dprintf1("[%d] Lock acquisition supressed (stripeID == -1)\n", tid); else { Dprintf8("[%d] Trying to acquire stripe lock table 0x%lx SID %ld type %c range %ld-%ld, range2 %ld-%ld hashval %d\n", tid, (unsigned long) lockTable, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, lockReqDesc->start2, lockReqDesc->stop2); Dprintf3("[%d] lock %ld hashval %d\n", tid, stripeID, hashval); FLUSH; } } if (stripeID == -1) return (0); lockReqDesc->next = NULL; /* just to be sure */ RF_LOCK_MUTEX(lockTable[hashval].mutex); for (lockDesc = lockTable[hashval].descList; lockDesc; lockDesc = lockDesc->next) { if (lockDesc->stripeID == stripeID) break; } if (!lockDesc) { /* no entry in table => no one reading or * writing */ lockDesc = AllocStripeLockDesc(stripeID); lockDesc->next = lockTable[hashval].descList; lockTable[hashval].descList = lockDesc; if (lockReqDesc->type == RF_IO_TYPE_WRITE) lockDesc->nWriters++; lockDesc->granted = lockReqDesc; if (rf_stripeLockDebug) { Dprintf7("[%d] no one waiting: lock %ld %c %ld-%ld %ld-%ld granted\n", tid, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, lockReqDesc->start2, lockReqDesc->stop2); FLUSH; } } else { if (lockReqDesc->type == RF_IO_TYPE_WRITE) lockDesc->nWriters++; if (lockDesc->nWriters == 0) { /* no need to search any lists * if there are no writers * anywhere */ lockReqDesc->next = lockDesc->granted; lockDesc->granted = lockReqDesc; if (rf_stripeLockDebug) { Dprintf7("[%d] no writers: lock %ld %c %ld-%ld %ld-%ld granted\n", tid, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, lockReqDesc->start2, lockReqDesc->stop2); FLUSH; } } else { /* search the granted & waiting lists for a conflict. * stop searching as soon as we find one */ retcode = 0; for (p = lockDesc->granted; p; p = p->next) if (STRIPELOCK_CONFLICT(lockReqDesc, p)) { retcode = 1; break; } if (!retcode) for (p = lockDesc->waitersH; p; p = p->next) if (STRIPELOCK_CONFLICT(lockReqDesc, p)) { retcode = 2; break; } if (!retcode) { lockReqDesc->next = lockDesc->granted; /* no conflicts found => * grant lock */ lockDesc->granted = lockReqDesc; if (rf_stripeLockDebug) { Dprintf7("[%d] no conflicts: lock %ld %c %ld-%ld %ld-%ld granted\n", tid, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, lockReqDesc->start2, lockReqDesc->stop2); FLUSH; } } else { if (rf_stripeLockDebug) { Dprintf6("[%d] conflict: lock %ld %c %ld-%ld hashval=%d not granted\n", tid, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, hashval); Dprintf3("[%d] lock %ld retcode=%d\n", tid, stripeID, retcode); FLUSH; } AddToWaitersQueue(lockTable, lockDesc, lockReqDesc); /* conflict => the * current access must * wait */ } } } RF_UNLOCK_MUTEX(lockTable[hashval].mutex); return (retcode); } void rf_ReleaseStripeLock( RF_LockTableEntry_t * lockTable, RF_StripeNum_t stripeID, RF_LockReqDesc_t * lockReqDesc) { RF_StripeLockDesc_t *lockDesc, *ld_t; RF_LockReqDesc_t *lr, *lr_t, *callbacklist, *t; RF_IoType_t type = lockReqDesc->type; int tid = 0, hashval = HASH_STRIPEID(stripeID); int release_it, consider_it; RF_LockReqDesc_t *candidate, *candidate_t, *predecessor; RF_ASSERT(RF_IO_IS_R_OR_W(type)); if (rf_stripeLockDebug) { if (stripeID == -1) Dprintf1("[%d] Lock release supressed (stripeID == -1)\n", tid); else { Dprintf8("[%d] Releasing stripe lock on stripe ID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, lockReqDesc->type, lockReqDesc->start, lockReqDesc->stop, lockReqDesc->start2, lockReqDesc->stop2, lockTable); FLUSH; } } if (stripeID == -1) return; RF_LOCK_MUTEX(lockTable[hashval].mutex); /* find the stripe lock descriptor */ for (ld_t = NULL, lockDesc = lockTable[hashval].descList; lockDesc; ld_t = lockDesc, lockDesc = lockDesc->next) { if (lockDesc->stripeID == stripeID) break; } RF_ASSERT(lockDesc); /* major error to release a lock that doesn't * exist */ /* find the stripe lock request descriptor & delete it from the list */ for (lr_t = NULL, lr = lockDesc->granted; lr; lr_t = lr, lr = lr->next) if (lr == lockReqDesc) break; RF_ASSERT(lr && (lr == lockReqDesc)); /* major error to release a * lock that hasn't been * granted */ if (lr_t) lr_t->next = lr->next; else { RF_ASSERT(lr == lockDesc->granted); lockDesc->granted = lr->next; } lr->next = NULL; if (lockReqDesc->type == RF_IO_TYPE_WRITE) lockDesc->nWriters--; /* search through the waiters list to see if anyone needs to be woken * up. for each such descriptor in the wait list, we check it against * everything granted and against everything _in front_ of it in the * waiters queue. If it conflicts with none of these, we release it. * * DON'T TOUCH THE TEMPLINK POINTER OF ANYTHING IN THE GRANTED LIST HERE. * This will roach the case where the callback tries to acquire a new * lock in the same stripe. There are some asserts to try and detect * this. * * We apply 2 performance optimizations: (1) if releasing this lock * results in no more writers to this stripe, we just release * everybody waiting, since we place no restrictions on the number of * concurrent reads. (2) we consider as candidates for wakeup only * those waiters that have a range overlap with either the descriptor * being woken up or with something in the callbacklist (i.e. * something we've just now woken up). This allows us to avoid the * long evaluation for some descriptors. */ callbacklist = NULL; if (lockDesc->nWriters == 0) { /* performance tweak (1) */ while (lockDesc->waitersH) { lr = lockDesc->waitersH; /* delete from waiters * list */ lockDesc->waitersH = lr->next; RF_ASSERT(lr->type == RF_IO_TYPE_READ); lr->next = lockDesc->granted; /* add to granted list */ lockDesc->granted = lr; RF_ASSERT(!lr->templink); lr->templink = callbacklist; /* put on callback list * so that we'll invoke * callback below */ callbacklist = lr; if (rf_stripeLockDebug) { Dprintf8("[%d] No writers: granting lock stripe ID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, lr->type, lr->start, lr->stop, lr->start2, lr->stop2, (unsigned long) lockTable); FLUSH; } } lockDesc->waitersT = NULL; /* we've purged the whole * waiters list */ } else for (candidate_t = NULL, candidate = lockDesc->waitersH; candidate;) { /* performance tweak (2) */ consider_it = 0; if (RANGE_OVERLAP(lockReqDesc, candidate)) consider_it = 1; else for (t = callbacklist; t; t = t->templink) if (RANGE_OVERLAP(t, candidate)) { consider_it = 1; break; } if (!consider_it) { if (rf_stripeLockDebug) { Dprintf8("[%d] No overlap: rejecting candidate stripeID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, candidate->type, candidate->start, candidate->stop, candidate->start2, candidate->stop2, (unsigned long) lockTable); FLUSH; } candidate_t = candidate; candidate = candidate->next; continue; } /* we have a candidate for release. check to make * sure it is not blocked by any granted locks */ release_it = 1; for (predecessor = lockDesc->granted; predecessor; predecessor = predecessor->next) { if (STRIPELOCK_CONFLICT(candidate, predecessor)) { if (rf_stripeLockDebug) { Dprintf8("[%d] Conflicts with granted lock: rejecting candidate stripeID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, candidate->type, candidate->start, candidate->stop, candidate->start2, candidate->stop2, (unsigned long) lockTable); FLUSH; } release_it = 0; break; } } /* now check to see if the candidate is blocked by any * waiters that occur before it it the wait queue */ if (release_it) for (predecessor = lockDesc->waitersH; predecessor != candidate; predecessor = predecessor->next) { if (STRIPELOCK_CONFLICT(candidate, predecessor)) { if (rf_stripeLockDebug) { Dprintf8("[%d] Conflicts with waiting lock: rejecting candidate stripeID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, candidate->type, candidate->start, candidate->stop, candidate->start2, candidate->stop2, (unsigned long) lockTable); FLUSH; } release_it = 0; break; } } /* release it if indicated */ if (release_it) { if (rf_stripeLockDebug) { Dprintf8("[%d] Granting lock to candidate stripeID %ld, type %c range %ld-%ld %ld-%ld table 0x%lx\n", tid, stripeID, candidate->type, candidate->start, candidate->stop, candidate->start2, candidate->stop2, (unsigned long) lockTable); FLUSH; } if (candidate_t) { candidate_t->next = candidate->next; if (lockDesc->waitersT == candidate) lockDesc->waitersT = candidate_t; /* cannot be waitersH * since candidate_t is * not NULL */ } else { RF_ASSERT(candidate == lockDesc->waitersH); lockDesc->waitersH = lockDesc->waitersH->next; if (!lockDesc->waitersH) lockDesc->waitersT = NULL; } candidate->next = lockDesc->granted; /* move it to the * granted list */ lockDesc->granted = candidate; RF_ASSERT(!candidate->templink); candidate->templink = callbacklist; /* put it on the list of * things to be called * after we release the * mutex */ callbacklist = candidate; if (!candidate_t) candidate = lockDesc->waitersH; else candidate = candidate_t->next; /* continue with the * rest of the list */ } else { candidate_t = candidate; candidate = candidate->next; /* continue with the * rest of the list */ } } /* delete the descriptor if no one is waiting or active */ if (!lockDesc->granted && !lockDesc->waitersH) { RF_ASSERT(lockDesc->nWriters == 0); if (rf_stripeLockDebug) { Dprintf3("[%d] Last lock released (table 0x%lx): deleting desc for stripeID %ld\n", tid, (unsigned long) lockTable, stripeID); FLUSH; } if (ld_t) ld_t->next = lockDesc->next; else { RF_ASSERT(lockDesc == lockTable[hashval].descList); lockTable[hashval].descList = lockDesc->next; } FreeStripeLockDesc(lockDesc); lockDesc = NULL;/* only for the ASSERT below */ } RF_UNLOCK_MUTEX(lockTable[hashval].mutex); /* now that we've unlocked the mutex, invoke the callback on all the * descriptors in the list */ RF_ASSERT(!((callbacklist) && (!lockDesc))); /* if we deleted the * descriptor, we should * have no callbacks to * do */ for (candidate = callbacklist; candidate;) { t = candidate; candidate = candidate->templink; t->templink = NULL; (t->cbFunc) (t->cbArg); } } /* must have the indicated lock table mutex upon entry */ static void AddToWaitersQueue( RF_LockTableEntry_t * lockTable, RF_StripeLockDesc_t * lockDesc, RF_LockReqDesc_t * lockReqDesc) { int tid; if (rf_stripeLockDebug) { Dprintf3("[%d] Waiting on lock for stripe %ld table 0x%lx\n", tid, lockDesc->stripeID, (unsigned long) lockTable); FLUSH; } if (!lockDesc->waitersH) { lockDesc->waitersH = lockDesc->waitersT = lockReqDesc; } else { lockDesc->waitersT->next = lockReqDesc; lockDesc->waitersT = lockReqDesc; } } static RF_StripeLockDesc_t * AllocStripeLockDesc(RF_StripeNum_t stripeID) { RF_StripeLockDesc_t *p; RF_FREELIST_GET(rf_stripelock_freelist, p, next, (RF_StripeLockDesc_t *)); if (p) { p->stripeID = stripeID; } return (p); } static void FreeStripeLockDesc(RF_StripeLockDesc_t * p) { RF_FREELIST_FREE(rf_stripelock_freelist, p, next); } static void PrintLockedStripes(lockTable) RF_LockTableEntry_t *lockTable; { int i, j, foundone = 0, did; RF_StripeLockDesc_t *p; RF_LockReqDesc_t *q; RF_LOCK_MUTEX(rf_printf_mutex); printf("Locked stripes:\n"); for (i = 0; i < rf_lockTableSize; i++) if (lockTable[i].descList) { foundone = 1; for (p = lockTable[i].descList; p; p = p->next) { printf("Stripe ID 0x%lx (%d) nWriters %d\n", (long) p->stripeID, (int) p->stripeID, p->nWriters); if (!(p->granted)) printf("Granted: (none)\n"); else printf("Granted:\n"); for (did = 1, j = 0, q = p->granted; q; j++, q = q->next) { printf(" %c(%ld-%ld", q->type, (long) q->start, (long) q->stop); if (q->start2 != -1) printf(",%ld-%ld) ", (long) q->start2, (long) q->stop2); else printf(") "); if (j && !(j % 4)) { printf("\n"); did = 1; } else did = 0; } if (!did) printf("\n"); if (!(p->waitersH)) printf("Waiting: (none)\n"); else printf("Waiting:\n"); for (did = 1, j = 0, q = p->waitersH; q; j++, q = q->next) { printf("%c(%ld-%ld", q->type, (long) q->start, (long) q->stop); if (q->start2 != -1) printf(",%ld-%ld) ", (long) q->start2, (long) q->stop2); else printf(") "); if (j && !(j % 4)) { printf("\n "); did = 1; } else did = 0; } if (!did) printf("\n"); } } if (!foundone) printf("(none)\n"); else printf("\n"); RF_UNLOCK_MUTEX(rf_printf_mutex); }