/*------------------------------------------------------------------------- * * lmgr.c * POSTGRES lock manager code * * Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/storage/lmgr/lmgr.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/subtrans.h" #include "access/transam.h" #include "access/xact.h" #include "catalog/catalog.h" #include "commands/progress.h" #include "miscadmin.h" #include "pgstat.h" #include "storage/lmgr.h" #include "storage/proc.h" #include "storage/procarray.h" #include "storage/sinvaladt.h" #include "utils/inval.h" /* * Per-backend counter for generating speculative insertion tokens. * * This may wrap around, but that's OK as it's only used for the short * duration between inserting a tuple and checking that there are no (unique) * constraint violations. It's theoretically possible that a backend sees a * tuple that was speculatively inserted by another backend, but before it has * started waiting on the token, the other backend completes its insertion, * and then performs 2^32 unrelated insertions. And after all that, the * first backend finally calls SpeculativeInsertionLockAcquire(), with the * intention of waiting for the first insertion to complete, but ends up * waiting for the latest unrelated insertion instead. Even then, nothing * particularly bad happens: in the worst case they deadlock, causing one of * the transactions to abort. */ static uint32 speculativeInsertionToken = 0; /* * Struct to hold context info for transaction lock waits. * * 'oper' is the operation that needs to wait for the other transaction; 'rel' * and 'ctid' specify the address of the tuple being waited for. */ typedef struct XactLockTableWaitInfo { XLTW_Oper oper; Relation rel; ItemPointer ctid; } XactLockTableWaitInfo; static void XactLockTableWaitErrorCb(void *arg); /* * RelationInitLockInfo * Initializes the lock information in a relation descriptor. * * relcache.c must call this during creation of any reldesc. */ void RelationInitLockInfo(Relation relation) { Assert(RelationIsValid(relation)); Assert(OidIsValid(RelationGetRelid(relation))); relation->rd_lockInfo.lockRelId.relId = RelationGetRelid(relation); if (relation->rd_rel->relisshared) relation->rd_lockInfo.lockRelId.dbId = InvalidOid; else relation->rd_lockInfo.lockRelId.dbId = MyDatabaseId; } /* * SetLocktagRelationOid * Set up a locktag for a relation, given only relation OID */ static inline void SetLocktagRelationOid(LOCKTAG *tag, Oid relid) { Oid dbid; if (IsSharedRelation(relid)) dbid = InvalidOid; else dbid = MyDatabaseId; SET_LOCKTAG_RELATION(*tag, dbid, relid); } /* * LockRelationOid * * Lock a relation given only its OID. This should generally be used * before attempting to open the relation's relcache entry. */ void LockRelationOid(Oid relid, LOCKMODE lockmode) { LOCKTAG tag; LOCALLOCK *locallock; LockAcquireResult res; SetLocktagRelationOid(&tag, relid); res = LockAcquireExtended(&tag, lockmode, false, false, true, &locallock); /* * Now that we have the lock, check for invalidation messages, so that we * will update or flush any stale relcache entry before we try to use it. * RangeVarGetRelid() specifically relies on us for this. We can skip * this in the not-uncommon case that we already had the same type of lock * being requested, since then no one else could have modified the * relcache entry in an undesirable way. (In the case where our own xact * modifies the rel, the relcache update happens via * CommandCounterIncrement, not here.) * * However, in corner cases where code acts on tables (usually catalogs) * recursively, we might get here while still processing invalidation * messages in some outer execution of this function or a sibling. The * "cleared" status of the lock tells us whether we really are done * absorbing relevant inval messages. */ if (res != LOCKACQUIRE_ALREADY_CLEAR) { AcceptInvalidationMessages(); MarkLockClear(locallock); } } /* * ConditionalLockRelationOid * * As above, but only lock if we can get the lock without blocking. * Returns true iff the lock was acquired. * * NOTE: we do not currently need conditional versions of all the * LockXXX routines in this file, but they could easily be added if needed. */ bool ConditionalLockRelationOid(Oid relid, LOCKMODE lockmode) { LOCKTAG tag; LOCALLOCK *locallock; LockAcquireResult res; SetLocktagRelationOid(&tag, relid); res = LockAcquireExtended(&tag, lockmode, false, true, true, &locallock); if (res == LOCKACQUIRE_NOT_AVAIL) return false; /* * Now that we have the lock, check for invalidation messages; see notes * in LockRelationOid. */ if (res != LOCKACQUIRE_ALREADY_CLEAR) { AcceptInvalidationMessages(); MarkLockClear(locallock); } return true; } /* * LockRelationId * * Lock, given a LockRelId. Same as LockRelationOid but take LockRelId as an * input. */ void LockRelationId(LockRelId *relid, LOCKMODE lockmode) { LOCKTAG tag; LOCALLOCK *locallock; LockAcquireResult res; SET_LOCKTAG_RELATION(tag, relid->dbId, relid->relId); res = LockAcquireExtended(&tag, lockmode, false, false, true, &locallock); /* * Now that we have the lock, check for invalidation messages; see notes * in LockRelationOid. */ if (res != LOCKACQUIRE_ALREADY_CLEAR) { AcceptInvalidationMessages(); MarkLockClear(locallock); } } /* * UnlockRelationId * * Unlock, given a LockRelId. This is preferred over UnlockRelationOid * for speed reasons. */ void UnlockRelationId(LockRelId *relid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relid->dbId, relid->relId); LockRelease(&tag, lockmode, false); } /* * UnlockRelationOid * * Unlock, given only a relation Oid. Use UnlockRelationId if you can. */ void UnlockRelationOid(Oid relid, LOCKMODE lockmode) { LOCKTAG tag; SetLocktagRelationOid(&tag, relid); LockRelease(&tag, lockmode, false); } /* * LockRelation * * This is a convenience routine for acquiring an additional lock on an * already-open relation. Never try to do "relation_open(foo, NoLock)" * and then lock with this. */ void LockRelation(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; LOCALLOCK *locallock; LockAcquireResult res; SET_LOCKTAG_RELATION(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); res = LockAcquireExtended(&tag, lockmode, false, false, true, &locallock); /* * Now that we have the lock, check for invalidation messages; see notes * in LockRelationOid. */ if (res != LOCKACQUIRE_ALREADY_CLEAR) { AcceptInvalidationMessages(); MarkLockClear(locallock); } } /* * ConditionalLockRelation * * This is a convenience routine for acquiring an additional lock on an * already-open relation. Never try to do "relation_open(foo, NoLock)" * and then lock with this. */ bool ConditionalLockRelation(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; LOCALLOCK *locallock; LockAcquireResult res; SET_LOCKTAG_RELATION(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); res = LockAcquireExtended(&tag, lockmode, false, true, true, &locallock); if (res == LOCKACQUIRE_NOT_AVAIL) return false; /* * Now that we have the lock, check for invalidation messages; see notes * in LockRelationOid. */ if (res != LOCKACQUIRE_ALREADY_CLEAR) { AcceptInvalidationMessages(); MarkLockClear(locallock); } return true; } /* * UnlockRelation * * This is a convenience routine for unlocking a relation without also * closing it. */ void UnlockRelation(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); LockRelease(&tag, lockmode, false); } /* * CheckRelationLockedByMe * * Returns true if current transaction holds a lock on 'relation' of mode * 'lockmode'. If 'orstronger' is true, a stronger lockmode is also OK. * ("Stronger" is defined as "numerically higher", which is a bit * semantically dubious but is OK for the purposes we use this for.) */ bool CheckRelationLockedByMe(Relation relation, LOCKMODE lockmode, bool orstronger) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); if (LockHeldByMe(&tag, lockmode)) return true; if (orstronger) { LOCKMODE slockmode; for (slockmode = lockmode + 1; slockmode <= MaxLockMode; slockmode++) { if (LockHeldByMe(&tag, slockmode)) { #ifdef NOT_USED /* Sometimes this might be useful for debugging purposes */ elog(WARNING, "lock mode %s substituted for %s on relation %s", GetLockmodeName(tag.locktag_lockmethodid, slockmode), GetLockmodeName(tag.locktag_lockmethodid, lockmode), RelationGetRelationName(relation)); #endif return true; } } } return false; } /* * LockHasWaitersRelation * * This is a function to check whether someone else is waiting for a * lock which we are currently holding. */ bool LockHasWaitersRelation(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); return LockHasWaiters(&tag, lockmode, false); } /* * LockRelationIdForSession * * This routine grabs a session-level lock on the target relation. The * session lock persists across transaction boundaries. It will be removed * when UnlockRelationIdForSession() is called, or if an ereport(ERROR) occurs, * or if the backend exits. * * Note that one should also grab a transaction-level lock on the rel * in any transaction that actually uses the rel, to ensure that the * relcache entry is up to date. */ void LockRelationIdForSession(LockRelId *relid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relid->dbId, relid->relId); (void) LockAcquire(&tag, lockmode, true, false); } /* * UnlockRelationIdForSession */ void UnlockRelationIdForSession(LockRelId *relid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION(tag, relid->dbId, relid->relId); LockRelease(&tag, lockmode, true); } /* * LockRelationForExtension * * This lock tag is used to interlock addition of pages to relations. * We need such locking because bufmgr/smgr definition of P_NEW is not * race-condition-proof. * * We assume the caller is already holding some type of regular lock on * the relation, so no AcceptInvalidationMessages call is needed here. */ void LockRelationForExtension(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION_EXTEND(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); (void) LockAcquire(&tag, lockmode, false, false); } /* * ConditionalLockRelationForExtension * * As above, but only lock if we can get the lock without blocking. * Returns true iff the lock was acquired. */ bool ConditionalLockRelationForExtension(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION_EXTEND(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); return (LockAcquire(&tag, lockmode, false, true) != LOCKACQUIRE_NOT_AVAIL); } /* * RelationExtensionLockWaiterCount * * Count the number of processes waiting for the given relation extension lock. */ int RelationExtensionLockWaiterCount(Relation relation) { LOCKTAG tag; SET_LOCKTAG_RELATION_EXTEND(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); return LockWaiterCount(&tag); } /* * UnlockRelationForExtension */ void UnlockRelationForExtension(Relation relation, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_RELATION_EXTEND(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId); LockRelease(&tag, lockmode, false); } /* * LockDatabaseFrozenIds * * This allows one backend per database to execute vac_update_datfrozenxid(). */ void LockDatabaseFrozenIds(LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_DATABASE_FROZEN_IDS(tag, MyDatabaseId); (void) LockAcquire(&tag, lockmode, false, false); } /* * LockPage * * Obtain a page-level lock. This is currently used by some index access * methods to lock individual index pages. */ void LockPage(Relation relation, BlockNumber blkno, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_PAGE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, blkno); (void) LockAcquire(&tag, lockmode, false, false); } /* * ConditionalLockPage * * As above, but only lock if we can get the lock without blocking. * Returns true iff the lock was acquired. */ bool ConditionalLockPage(Relation relation, BlockNumber blkno, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_PAGE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, blkno); return (LockAcquire(&tag, lockmode, false, true) != LOCKACQUIRE_NOT_AVAIL); } /* * UnlockPage */ void UnlockPage(Relation relation, BlockNumber blkno, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_PAGE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, blkno); LockRelease(&tag, lockmode, false); } /* * LockTuple * * Obtain a tuple-level lock. This is used in a less-than-intuitive fashion * because we can't afford to keep a separate lock in shared memory for every * tuple. See heap_lock_tuple before using this! */ void LockTuple(Relation relation, ItemPointer tid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_TUPLE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, ItemPointerGetBlockNumber(tid), ItemPointerGetOffsetNumber(tid)); (void) LockAcquire(&tag, lockmode, false, false); } /* * ConditionalLockTuple * * As above, but only lock if we can get the lock without blocking. * Returns true iff the lock was acquired. */ bool ConditionalLockTuple(Relation relation, ItemPointer tid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_TUPLE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, ItemPointerGetBlockNumber(tid), ItemPointerGetOffsetNumber(tid)); return (LockAcquire(&tag, lockmode, false, true) != LOCKACQUIRE_NOT_AVAIL); } /* * UnlockTuple */ void UnlockTuple(Relation relation, ItemPointer tid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_TUPLE(tag, relation->rd_lockInfo.lockRelId.dbId, relation->rd_lockInfo.lockRelId.relId, ItemPointerGetBlockNumber(tid), ItemPointerGetOffsetNumber(tid)); LockRelease(&tag, lockmode, false); } /* * XactLockTableInsert * * Insert a lock showing that the given transaction ID is running --- * this is done when an XID is acquired by a transaction or subtransaction. * The lock can then be used to wait for the transaction to finish. */ void XactLockTableInsert(TransactionId xid) { LOCKTAG tag; SET_LOCKTAG_TRANSACTION(tag, xid); (void) LockAcquire(&tag, ExclusiveLock, false, false); } /* * XactLockTableDelete * * Delete the lock showing that the given transaction ID is running. * (This is never used for main transaction IDs; those locks are only * released implicitly at transaction end. But we do use it for subtrans IDs.) */ void XactLockTableDelete(TransactionId xid) { LOCKTAG tag; SET_LOCKTAG_TRANSACTION(tag, xid); LockRelease(&tag, ExclusiveLock, false); } /* * XactLockTableWait * * Wait for the specified transaction to commit or abort. If an operation * is specified, an error context callback is set up. If 'oper' is passed as * None, no error context callback is set up. * * Note that this does the right thing for subtransactions: if we wait on a * subtransaction, we will exit as soon as it aborts or its top parent commits. * It takes some extra work to ensure this, because to save on shared memory * the XID lock of a subtransaction is released when it ends, whether * successfully or unsuccessfully. So we have to check if it's "still running" * and if so wait for its parent. */ void XactLockTableWait(TransactionId xid, Relation rel, ItemPointer ctid, XLTW_Oper oper) { LOCKTAG tag; XactLockTableWaitInfo info; ErrorContextCallback callback; bool first = true; /* * If an operation is specified, set up our verbose error context * callback. */ if (oper != XLTW_None) { Assert(RelationIsValid(rel)); Assert(ItemPointerIsValid(ctid)); info.rel = rel; info.ctid = ctid; info.oper = oper; callback.callback = XactLockTableWaitErrorCb; callback.arg = &info; callback.previous = error_context_stack; error_context_stack = &callback; } for (;;) { Assert(TransactionIdIsValid(xid)); Assert(!TransactionIdEquals(xid, GetTopTransactionIdIfAny())); SET_LOCKTAG_TRANSACTION(tag, xid); (void) LockAcquire(&tag, ShareLock, false, false); LockRelease(&tag, ShareLock, false); if (!TransactionIdIsInProgress(xid)) break; /* * If the Xid belonged to a subtransaction, then the lock would have * gone away as soon as it was finished; for correct tuple visibility, * the right action is to wait on its parent transaction to go away. * But instead of going levels up one by one, we can just wait for the * topmost transaction to finish with the same end result, which also * incurs less locktable traffic. * * Some uses of this function don't involve tuple visibility -- such * as when building snapshots for logical decoding. It is possible to * see a transaction in ProcArray before it registers itself in the * locktable. The topmost transaction in that case is the same xid, * so we try again after a short sleep. (Don't sleep the first time * through, to avoid slowing down the normal case.) */ if (!first) pg_usleep(1000L); first = false; xid = SubTransGetTopmostTransaction(xid); } if (oper != XLTW_None) error_context_stack = callback.previous; } /* * ConditionalXactLockTableWait * * As above, but only lock if we can get the lock without blocking. * Returns true if the lock was acquired. */ bool ConditionalXactLockTableWait(TransactionId xid) { LOCKTAG tag; bool first = true; for (;;) { Assert(TransactionIdIsValid(xid)); Assert(!TransactionIdEquals(xid, GetTopTransactionIdIfAny())); SET_LOCKTAG_TRANSACTION(tag, xid); if (LockAcquire(&tag, ShareLock, false, true) == LOCKACQUIRE_NOT_AVAIL) return false; LockRelease(&tag, ShareLock, false); if (!TransactionIdIsInProgress(xid)) break; /* See XactLockTableWait about this case */ if (!first) pg_usleep(1000L); first = false; xid = SubTransGetTopmostTransaction(xid); } return true; } /* * SpeculativeInsertionLockAcquire * * Insert a lock showing that the given transaction ID is inserting a tuple, * but hasn't yet decided whether it's going to keep it. The lock can then be * used to wait for the decision to go ahead with the insertion, or aborting * it. * * The token is used to distinguish multiple insertions by the same * transaction. It is returned to caller. */ uint32 SpeculativeInsertionLockAcquire(TransactionId xid) { LOCKTAG tag; speculativeInsertionToken++; /* * Check for wrap-around. Zero means no token is held, so don't use that. */ if (speculativeInsertionToken == 0) speculativeInsertionToken = 1; SET_LOCKTAG_SPECULATIVE_INSERTION(tag, xid, speculativeInsertionToken); (void) LockAcquire(&tag, ExclusiveLock, false, false); return speculativeInsertionToken; } /* * SpeculativeInsertionLockRelease * * Delete the lock showing that the given transaction is speculatively * inserting a tuple. */ void SpeculativeInsertionLockRelease(TransactionId xid) { LOCKTAG tag; SET_LOCKTAG_SPECULATIVE_INSERTION(tag, xid, speculativeInsertionToken); LockRelease(&tag, ExclusiveLock, false); } /* * SpeculativeInsertionWait * * Wait for the specified transaction to finish or abort the insertion of a * tuple. */ void SpeculativeInsertionWait(TransactionId xid, uint32 token) { LOCKTAG tag; SET_LOCKTAG_SPECULATIVE_INSERTION(tag, xid, token); Assert(TransactionIdIsValid(xid)); Assert(token != 0); (void) LockAcquire(&tag, ShareLock, false, false); LockRelease(&tag, ShareLock, false); } /* * XactLockTableWaitErrorCb * Error context callback for transaction lock waits. */ static void XactLockTableWaitErrorCb(void *arg) { XactLockTableWaitInfo *info = (XactLockTableWaitInfo *) arg; /* * We would like to print schema name too, but that would require a * syscache lookup. */ if (info->oper != XLTW_None && ItemPointerIsValid(info->ctid) && RelationIsValid(info->rel)) { const char *cxt; switch (info->oper) { case XLTW_Update: cxt = gettext_noop("while updating tuple (%u,%u) in relation \"%s\""); break; case XLTW_Delete: cxt = gettext_noop("while deleting tuple (%u,%u) in relation \"%s\""); break; case XLTW_Lock: cxt = gettext_noop("while locking tuple (%u,%u) in relation \"%s\""); break; case XLTW_LockUpdated: cxt = gettext_noop("while locking updated version (%u,%u) of tuple in relation \"%s\""); break; case XLTW_InsertIndex: cxt = gettext_noop("while inserting index tuple (%u,%u) in relation \"%s\""); break; case XLTW_InsertIndexUnique: cxt = gettext_noop("while checking uniqueness of tuple (%u,%u) in relation \"%s\""); break; case XLTW_FetchUpdated: cxt = gettext_noop("while rechecking updated tuple (%u,%u) in relation \"%s\""); break; case XLTW_RecheckExclusionConstr: cxt = gettext_noop("while checking exclusion constraint on tuple (%u,%u) in relation \"%s\""); break; default: return; } errcontext(cxt, ItemPointerGetBlockNumber(info->ctid), ItemPointerGetOffsetNumber(info->ctid), RelationGetRelationName(info->rel)); } } /* * WaitForLockersMultiple * Wait until no transaction holds locks that conflict with the given * locktags at the given lockmode. * * To do this, obtain the current list of lockers, and wait on their VXIDs * until they are finished. * * Note we don't try to acquire the locks on the given locktags, only the * VXIDs and XIDs of their lock holders; if somebody grabs a conflicting lock * on the objects after we obtained our initial list of lockers, we will not * wait for them. */ void WaitForLockersMultiple(List *locktags, LOCKMODE lockmode, bool progress) { List *holders = NIL; ListCell *lc; int total = 0; int done = 0; /* Done if no locks to wait for */ if (locktags == NIL) return; /* Collect the transactions we need to wait on */ foreach(lc, locktags) { LOCKTAG *locktag = lfirst(lc); int count; holders = lappend(holders, GetLockConflicts(locktag, lockmode, progress ? &count : NULL)); if (progress) total += count; } if (progress) pgstat_progress_update_param(PROGRESS_WAITFOR_TOTAL, total); /* * Note: GetLockConflicts() never reports our own xid, hence we need not * check for that. Also, prepared xacts are reported and awaited. */ /* Finally wait for each such transaction to complete */ foreach(lc, holders) { VirtualTransactionId *lockholders = lfirst(lc); while (VirtualTransactionIdIsValid(*lockholders)) { /* If requested, publish who we're going to wait for. */ if (progress) { PGPROC *holder = BackendIdGetProc(lockholders->backendId); if (holder) pgstat_progress_update_param(PROGRESS_WAITFOR_CURRENT_PID, holder->pid); } VirtualXactLock(*lockholders, true); lockholders++; if (progress) pgstat_progress_update_param(PROGRESS_WAITFOR_DONE, ++done); } } if (progress) { const int index[] = { PROGRESS_WAITFOR_TOTAL, PROGRESS_WAITFOR_DONE, PROGRESS_WAITFOR_CURRENT_PID }; const int64 values[] = { 0, 0, 0 }; pgstat_progress_update_multi_param(3, index, values); } list_free_deep(holders); } /* * WaitForLockers * * Same as WaitForLockersMultiple, for a single lock tag. */ void WaitForLockers(LOCKTAG heaplocktag, LOCKMODE lockmode, bool progress) { List *l; l = list_make1(&heaplocktag); WaitForLockersMultiple(l, lockmode, progress); list_free(l); } /* * LockDatabaseObject * * Obtain a lock on a general object of the current database. Don't use * this for shared objects (such as tablespaces). It's unwise to apply it * to relations, also, since a lock taken this way will NOT conflict with * locks taken via LockRelation and friends. */ void LockDatabaseObject(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, MyDatabaseId, classid, objid, objsubid); (void) LockAcquire(&tag, lockmode, false, false); /* Make sure syscaches are up-to-date with any changes we waited for */ AcceptInvalidationMessages(); } /* * UnlockDatabaseObject */ void UnlockDatabaseObject(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, MyDatabaseId, classid, objid, objsubid); LockRelease(&tag, lockmode, false); } /* * LockSharedObject * * Obtain a lock on a shared-across-databases object. */ void LockSharedObject(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, InvalidOid, classid, objid, objsubid); (void) LockAcquire(&tag, lockmode, false, false); /* Make sure syscaches are up-to-date with any changes we waited for */ AcceptInvalidationMessages(); } /* * UnlockSharedObject */ void UnlockSharedObject(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, InvalidOid, classid, objid, objsubid); LockRelease(&tag, lockmode, false); } /* * LockSharedObjectForSession * * Obtain a session-level lock on a shared-across-databases object. * See LockRelationIdForSession for notes about session-level locks. */ void LockSharedObjectForSession(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, InvalidOid, classid, objid, objsubid); (void) LockAcquire(&tag, lockmode, true, false); } /* * UnlockSharedObjectForSession */ void UnlockSharedObjectForSession(Oid classid, Oid objid, uint16 objsubid, LOCKMODE lockmode) { LOCKTAG tag; SET_LOCKTAG_OBJECT(tag, InvalidOid, classid, objid, objsubid); LockRelease(&tag, lockmode, true); } /* * Append a description of a lockable object to buf. * * Ideally we would print names for the numeric values, but that requires * getting locks on system tables, which might cause problems since this is * typically used to report deadlock situations. */ void DescribeLockTag(StringInfo buf, const LOCKTAG *tag) { switch ((LockTagType) tag->locktag_type) { case LOCKTAG_RELATION: appendStringInfo(buf, _("relation %u of database %u"), tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_RELATION_EXTEND: appendStringInfo(buf, _("extension of relation %u of database %u"), tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_DATABASE_FROZEN_IDS: appendStringInfo(buf, _("pg_database.datfrozenxid of database %u"), tag->locktag_field1); break; case LOCKTAG_PAGE: appendStringInfo(buf, _("page %u of relation %u of database %u"), tag->locktag_field3, tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_TUPLE: appendStringInfo(buf, _("tuple (%u,%u) of relation %u of database %u"), tag->locktag_field3, tag->locktag_field4, tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_TRANSACTION: appendStringInfo(buf, _("transaction %u"), tag->locktag_field1); break; case LOCKTAG_VIRTUALTRANSACTION: appendStringInfo(buf, _("virtual transaction %d/%u"), tag->locktag_field1, tag->locktag_field2); break; case LOCKTAG_SPECULATIVE_TOKEN: appendStringInfo(buf, _("speculative token %u of transaction %u"), tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_OBJECT: appendStringInfo(buf, _("object %u of class %u of database %u"), tag->locktag_field3, tag->locktag_field2, tag->locktag_field1); break; case LOCKTAG_USERLOCK: /* reserved for old contrib code, now on pgfoundry */ appendStringInfo(buf, _("user lock [%u,%u,%u]"), tag->locktag_field1, tag->locktag_field2, tag->locktag_field3); break; case LOCKTAG_ADVISORY: appendStringInfo(buf, _("advisory lock [%u,%u,%u,%u]"), tag->locktag_field1, tag->locktag_field2, tag->locktag_field3, tag->locktag_field4); break; default: appendStringInfo(buf, _("unrecognized locktag type %d"), (int) tag->locktag_type); break; } } /* * GetLockNameFromTagType * * Given locktag type, return the corresponding lock name. */ const char * GetLockNameFromTagType(uint16 locktag_type) { if (locktag_type > LOCKTAG_LAST_TYPE) return "???"; return LockTagTypeNames[locktag_type]; }