predicate.c File Reference

#include "postgres.h"
#include "access/parallel.h"
#include "access/slru.h"
#include "access/transam.h"
#include "access/twophase.h"
#include "access/twophase_rmgr.h"
#include "access/xact.h"
#include "access/xlog.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "port/pg_lfind.h"
#include "storage/predicate.h"
#include "storage/predicate_internals.h"
#include "storage/proc.h"
#include "storage/procarray.h"
#include "storage/shmem.h"
#include "storage/subsystems.h"
#include "utils/guc_hooks.h"
#include "utils/rel.h"
#include "utils/snapmgr.h"
#include "utils/wait_event.h"

Include dependency graph for predicate.c:

Go to the source code of this file.

Data Structures
struct	SerialControlData

Macros
#define	TargetTagIsCoveredBy(covered_target, covering_target)
#define	PredicateLockHashPartition(hashcode)    ((hashcode) % NUM_PREDICATELOCK_PARTITIONS)
#define	PredicateLockHashPartitionLock(hashcode)
#define	PredicateLockHashPartitionLockByIndex(i)    (&MainLWLockArray[PREDICATELOCK_MANAGER_LWLOCK_OFFSET + (i)].lock)
#define	NPREDICATELOCKTARGETENTS()    mul_size(max_predicate_locks_per_xact, add_size(MaxBackends, max_prepared_xacts))
#define	SxactIsOnFinishedList(sxact)   (!dlist_node_is_detached(&(sxact)->finishedLink))
#define	SxactIsCommitted(sxact)   (((sxact)->flags & SXACT_FLAG_COMMITTED) != 0)
#define	SxactIsPrepared(sxact)   (((sxact)->flags & SXACT_FLAG_PREPARED) != 0)
#define	SxactIsRolledBack(sxact)   (((sxact)->flags & SXACT_FLAG_ROLLED_BACK) != 0)
#define	SxactIsDoomed(sxact)   (((sxact)->flags & SXACT_FLAG_DOOMED) != 0)
#define	SxactIsReadOnly(sxact)   (((sxact)->flags & SXACT_FLAG_READ_ONLY) != 0)
#define	SxactHasSummaryConflictIn(sxact)   (((sxact)->flags & SXACT_FLAG_SUMMARY_CONFLICT_IN) != 0)
#define	SxactHasSummaryConflictOut(sxact)   (((sxact)->flags & SXACT_FLAG_SUMMARY_CONFLICT_OUT) != 0)
#define	SxactHasConflictOut(sxact)   (((sxact)->flags & SXACT_FLAG_CONFLICT_OUT) != 0)
#define	SxactIsDeferrableWaiting(sxact)   (((sxact)->flags & SXACT_FLAG_DEFERRABLE_WAITING) != 0)
#define	SxactIsROSafe(sxact)   (((sxact)->flags & SXACT_FLAG_RO_SAFE) != 0)
#define	SxactIsROUnsafe(sxact)   (((sxact)->flags & SXACT_FLAG_RO_UNSAFE) != 0)
#define	SxactIsPartiallyReleased(sxact)   (((sxact)->flags & SXACT_FLAG_PARTIALLY_RELEASED) != 0)
#define	PredicateLockTargetTagHashCode(predicatelocktargettag)    get_hash_value(PredicateLockTargetHash, predicatelocktargettag)
#define	PredicateLockHashCodeFromTargetHashCode(predicatelocktag, targethash)
#define	SerialSlruCtl   (&SerialSlruDesc)
#define	SERIAL_PAGESIZE   BLCKSZ
#define	SERIAL_ENTRYSIZE   sizeof(SerCommitSeqNo)
#define	SERIAL_ENTRIESPERPAGE   (SERIAL_PAGESIZE / SERIAL_ENTRYSIZE)
#define	SERIAL_MAX_PAGE   (MaxTransactionId / SERIAL_ENTRIESPERPAGE)
#define	SerialNextPage(page)   (((page) >= SERIAL_MAX_PAGE) ? 0 : (page) + 1)
#define	SerialValue(slotno, xid)
#define	SerialPage(xid)   (((uint32) (xid)) / SERIAL_ENTRIESPERPAGE)

Typedefs
typedef struct SerialControlData	SerialControlData
typedef struct SerialControlData *	SerialControl

Functions
static bool	SerialPagePrecedesLogically (int64 page1, int64 page2)
static int	serial_errdetail_for_io_error (const void *opaque_data)
static void	PredicateLockShmemRequest (void *arg)
static void	PredicateLockShmemInit (void *arg)
static void	PredicateLockShmemAttach (void *arg)
static SERIALIZABLEXACT *	CreatePredXact (void)
static void	ReleasePredXact (SERIALIZABLEXACT *sxact)
static bool	RWConflictExists (const SERIALIZABLEXACT *reader, const SERIALIZABLEXACT *writer)
static void	SetRWConflict (SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer)
static void	SetPossibleUnsafeConflict (SERIALIZABLEXACT *roXact, SERIALIZABLEXACT *activeXact)
static void	ReleaseRWConflict (RWConflict conflict)
static void	FlagSxactUnsafe (SERIALIZABLEXACT *sxact)
static void	SerialAdd (TransactionId xid, SerCommitSeqNo minConflictCommitSeqNo)
static SerCommitSeqNo	SerialGetMinConflictCommitSeqNo (TransactionId xid)
static void	SerialSetActiveSerXmin (TransactionId xid)
static uint32	predicatelock_hash (const void *key, Size keysize)
static void	SummarizeOldestCommittedSxact (void)
static Snapshot	GetSafeSnapshot (Snapshot origSnapshot)
static Snapshot	GetSerializableTransactionSnapshotInt (Snapshot snapshot, VirtualTransactionId *sourcevxid, int sourcepid)
static bool	PredicateLockExists (const PREDICATELOCKTARGETTAG *targettag)
static bool	GetParentPredicateLockTag (const PREDICATELOCKTARGETTAG *tag, PREDICATELOCKTARGETTAG *parent)
static bool	CoarserLockCovers (const PREDICATELOCKTARGETTAG *newtargettag)
static void	RemoveScratchTarget (bool lockheld)
static void	RestoreScratchTarget (bool lockheld)
static void	RemoveTargetIfNoLongerUsed (PREDICATELOCKTARGET *target, uint32 targettaghash)
static void	DeleteChildTargetLocks (const PREDICATELOCKTARGETTAG *newtargettag)
static int	MaxPredicateChildLocks (const PREDICATELOCKTARGETTAG *tag)
static bool	CheckAndPromotePredicateLockRequest (const PREDICATELOCKTARGETTAG *reqtag)
static void	DecrementParentLocks (const PREDICATELOCKTARGETTAG *targettag)
static void	CreatePredicateLock (const PREDICATELOCKTARGETTAG *targettag, uint32 targettaghash, SERIALIZABLEXACT *sxact)
static void	DeleteLockTarget (PREDICATELOCKTARGET *target, uint32 targettaghash)
static bool	TransferPredicateLocksToNewTarget (PREDICATELOCKTARGETTAG oldtargettag, PREDICATELOCKTARGETTAG newtargettag, bool removeOld)
static void	PredicateLockAcquire (const PREDICATELOCKTARGETTAG *targettag)
static void	DropAllPredicateLocksFromTable (Relation relation, bool transfer)
static void	SetNewSxactGlobalXmin (void)
static void	ClearOldPredicateLocks (void)
static void	ReleaseOneSerializableXact (SERIALIZABLEXACT *sxact, bool partial, bool summarize)
static bool	XidIsConcurrent (TransactionId xid)
static void	CheckTargetForConflictsIn (PREDICATELOCKTARGETTAG *targettag)
static void	FlagRWConflict (SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer)
static void	OnConflict_CheckForSerializationFailure (const SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer)
static void	CreateLocalPredicateLockHash (void)
static void	ReleasePredicateLocksLocal (void)
static bool	PredicateLockingNeededForRelation (Relation relation)
static bool	SerializationNeededForRead (Relation relation, Snapshot snapshot)
static bool	SerializationNeededForWrite (Relation relation)
bool	check_serial_buffers (int *newval, void **extra, GucSource source)
void	CheckPointPredicate (void)
PredicateLockData *	GetPredicateLockStatusData (void)
int	GetSafeSnapshotBlockingPids (int blocked_pid, int *output, int output_size)
Snapshot	GetSerializableTransactionSnapshot (Snapshot snapshot)
void	SetSerializableTransactionSnapshot (Snapshot snapshot, VirtualTransactionId *sourcevxid, int sourcepid)
void	RegisterPredicateLockingXid (TransactionId xid)
bool	PageIsPredicateLocked (Relation relation, BlockNumber blkno)
void	PredicateLockRelation (Relation relation, Snapshot snapshot)
void	PredicateLockPage (Relation relation, BlockNumber blkno, Snapshot snapshot)
void	PredicateLockTID (Relation relation, const ItemPointerData *tid, Snapshot snapshot, TransactionId tuple_xid)
void	TransferPredicateLocksToHeapRelation (Relation relation)
void	PredicateLockPageSplit (Relation relation, BlockNumber oldblkno, BlockNumber newblkno)
void	PredicateLockPageCombine (Relation relation, BlockNumber oldblkno, BlockNumber newblkno)
void	ReleasePredicateLocks (bool isCommit, bool isReadOnlySafe)
bool	CheckForSerializableConflictOutNeeded (Relation relation, Snapshot snapshot)
void	CheckForSerializableConflictOut (Relation relation, TransactionId xid, Snapshot snapshot)
void	CheckForSerializableConflictIn (Relation relation, const ItemPointerData *tid, BlockNumber blkno)
void	CheckTableForSerializableConflictIn (Relation relation)
void	PreCommit_CheckForSerializationFailure (void)
void	AtPrepare_PredicateLocks (void)
void	PostPrepare_PredicateLocks (FullTransactionId fxid)
void	PredicateLockTwoPhaseFinish (FullTransactionId fxid, bool isCommit)
void	predicatelock_twophase_recover (FullTransactionId fxid, uint16 info, void *recdata, uint32 len)
SerializableXactHandle	ShareSerializableXact (void)
void	AttachSerializableXact (SerializableXactHandle handle)

Variables
static SlruDesc	SerialSlruDesc
static SerialControl	serialControl
static SERIALIZABLEXACT *	OldCommittedSxact
int	max_predicate_locks_per_xact
int	max_predicate_locks_per_relation
int	max_predicate_locks_per_page
static PredXactList	PredXact
const ShmemCallbacks	PredicateLockShmemCallbacks
static RWConflictPoolHeader	RWConflictPool
static HTAB *	SerializableXidHash
static HTAB *	PredicateLockTargetHash
static HTAB *	PredicateLockHash
static dlist_head *	FinishedSerializableTransactions
static const PREDICATELOCKTARGETTAG	ScratchTargetTag = {0, 0, 0, 0}
static uint32	ScratchTargetTagHash
static LWLock *	ScratchPartitionLock
static HTAB *	LocalPredicateLockHash = NULL
static SERIALIZABLEXACT *	MySerializableXact = InvalidSerializableXact
static bool	MyXactDidWrite = false
static SERIALIZABLEXACT *	SavedSerializableXact = InvalidSerializableXact
static int64	max_serializable_xacts

Macro Definition Documentation

NPREDICATELOCKTARGETENTS

#define NPREDICATELOCKTARGETENTS

(

)

mul_size(max_predicate_locks_per_xact, add_size(MaxBackends, max_prepared_xacts))

Definition at line 263 of file predicate.c.

                                                              : (page) + 1)
 
#define SerialValue(slotno, xid) (*((SerCommitSeqNo *) \
    (SerialSlruCtl->shared->page_buffer[slotno] + \
    ((((uint32) (xid)) % SERIAL_ENTRIESPERPAGE) * SERIAL_ENTRYSIZE))))
 
#define SerialPage(xid) (((uint32) (xid)) / SERIAL_ENTRIESPERPAGE)
 
typedef struct SerialControlData
{
    int64       headPage;       /* newest initialized page */
    TransactionId headXid;      /* newest valid Xid in the SLRU */
    TransactionId tailXid;      /* oldest xmin we might be interested in */
}           SerialControlData;
 
typedef struct SerialControlData *SerialControl;
 
static SerialControl serialControl;
 
/*
 * When the oldest committed transaction on the "finished" list is moved to
 * SLRU, its predicate locks will be moved to this "dummy" transaction,
 * collapsing duplicate targets.  When a duplicate is found, the later
 * commitSeqNo is used.
 */
static SERIALIZABLEXACT *OldCommittedSxact;
 
 
/*
 * These configuration variables are used to set the predicate lock table size
 * and to control promotion of predicate locks to coarser granularity in an
 * attempt to degrade performance (mostly as false positive serialization
 * failure) gracefully in the face of memory pressure.
 */
int         max_predicate_locks_per_xact;   /* in guc_tables.c */
int         max_predicate_locks_per_relation;   /* in guc_tables.c */
int         max_predicate_locks_per_page;   /* in guc_tables.c */
 
/*
 * This provides a list of objects in order to track transactions
 * participating in predicate locking.  Entries in the list are fixed size,
 * and reside in shared memory.  The memory address of an entry must remain
 * fixed during its lifetime.  The list will be protected from concurrent
 * update externally; no provision is made in this code to manage that.  The
 * number of entries in the list, and the size allowed for each entry is
 * fixed upon creation.
 */
static PredXactList PredXact;
 
static void PredicateLockShmemRequest(void *arg);
static void PredicateLockShmemInit(void *arg);
static void PredicateLockShmemAttach(void *arg);
 
const ShmemCallbacks PredicateLockShmemCallbacks = {
    .request_fn = PredicateLockShmemRequest,
    .init_fn = PredicateLockShmemInit,
    .attach_fn = PredicateLockShmemAttach,
};
 
 
/*
 * This provides a pool of RWConflict data elements to use in conflict lists
 * between transactions.
 */
static RWConflictPoolHeader RWConflictPool;
 
/*
 * The predicate locking hash tables are in shared memory.
 * Each backend keeps pointers to them.
 */
static HTAB *SerializableXidHash;
static HTAB *PredicateLockTargetHash;
static HTAB *PredicateLockHash;
static dlist_head *FinishedSerializableTransactions;
 
/*
 * Tag for a dummy entry in PredicateLockTargetHash. By temporarily removing
 * this entry, you can ensure that there's enough scratch space available for
 * inserting one entry in the hash table. This is an otherwise-invalid tag.
 */
static const PREDICATELOCKTARGETTAG ScratchTargetTag = {0, 0, 0, 0};
static uint32 ScratchTargetTagHash;
static LWLock *ScratchPartitionLock;
 
/*
 * The local hash table used to determine when to combine multiple fine-
 * grained locks into a single courser-grained lock.
 */
static HTAB *LocalPredicateLockHash = NULL;
 
/*
 * Keep a pointer to the currently-running serializable transaction (if any)
 * for quick reference. Also, remember if we have written anything that could
 * cause a rw-conflict.
 */
static SERIALIZABLEXACT *MySerializableXact = InvalidSerializableXact;
static bool MyXactDidWrite = false;
 
/*
 * The SXACT_FLAG_RO_UNSAFE optimization might lead us to release
 * MySerializableXact early.  If that happens in a parallel query, the leader
 * needs to defer the destruction of the SERIALIZABLEXACT until end of
 * transaction, because the workers still have a reference to it.  In that
 * case, the leader stores it here.
 */
static SERIALIZABLEXACT *SavedSerializableXact = InvalidSerializableXact;
 
static int64 max_serializable_xacts;
 
/* local functions */
 
static SERIALIZABLEXACT *CreatePredXact(void);
static void ReleasePredXact(SERIALIZABLEXACT *sxact);
 
static bool RWConflictExists(const SERIALIZABLEXACT *reader, const SERIALIZABLEXACT *writer);
static void SetRWConflict(SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer);
static void SetPossibleUnsafeConflict(SERIALIZABLEXACT *roXact, SERIALIZABLEXACT *activeXact);
static void ReleaseRWConflict(RWConflict conflict);
static void FlagSxactUnsafe(SERIALIZABLEXACT *sxact);
 
static void SerialAdd(TransactionId xid, SerCommitSeqNo minConflictCommitSeqNo);
static SerCommitSeqNo SerialGetMinConflictCommitSeqNo(TransactionId xid);
static void SerialSetActiveSerXmin(TransactionId xid);
 
static uint32 predicatelock_hash(const void *key, Size keysize);
 
static void SummarizeOldestCommittedSxact(void);
static Snapshot GetSafeSnapshot(Snapshot origSnapshot);
static Snapshot GetSerializableTransactionSnapshotInt(Snapshot snapshot,
                                                      VirtualTransactionId *sourcevxid,
                                                      int sourcepid);
static bool PredicateLockExists(const PREDICATELOCKTARGETTAG *targettag);
static bool GetParentPredicateLockTag(const PREDICATELOCKTARGETTAG *tag,
                                      PREDICATELOCKTARGETTAG *parent);
static bool CoarserLockCovers(const PREDICATELOCKTARGETTAG *newtargettag);
static void RemoveScratchTarget(bool lockheld);
static void RestoreScratchTarget(bool lockheld);
static void RemoveTargetIfNoLongerUsed(PREDICATELOCKTARGET *target,
                                       uint32 targettaghash);
static void DeleteChildTargetLocks(const PREDICATELOCKTARGETTAG *newtargettag);
static int  MaxPredicateChildLocks(const PREDICATELOCKTARGETTAG *tag);
static bool CheckAndPromotePredicateLockRequest(const PREDICATELOCKTARGETTAG *reqtag);
static void DecrementParentLocks(const PREDICATELOCKTARGETTAG *targettag);
static void CreatePredicateLock(const PREDICATELOCKTARGETTAG *targettag,
                                uint32 targettaghash,
                                SERIALIZABLEXACT *sxact);
static void DeleteLockTarget(PREDICATELOCKTARGET *target, uint32 targettaghash);
static bool TransferPredicateLocksToNewTarget(PREDICATELOCKTARGETTAG oldtargettag,
                                              PREDICATELOCKTARGETTAG newtargettag,
                                              bool removeOld);
static void PredicateLockAcquire(const PREDICATELOCKTARGETTAG *targettag);
static void DropAllPredicateLocksFromTable(Relation relation,
                                           bool transfer);
static void SetNewSxactGlobalXmin(void);
static void ClearOldPredicateLocks(void);
static void ReleaseOneSerializableXact(SERIALIZABLEXACT *sxact, bool partial,
                                       bool summarize);
static bool XidIsConcurrent(TransactionId xid);
static void CheckTargetForConflictsIn(PREDICATELOCKTARGETTAG *targettag);
static void FlagRWConflict(SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer);
static void OnConflict_CheckForSerializationFailure(const SERIALIZABLEXACT *reader,
                                                    SERIALIZABLEXACT *writer);
static void CreateLocalPredicateLockHash(void);
static void ReleasePredicateLocksLocal(void);
 
 
/*------------------------------------------------------------------------*/
 
/*
 * Does this relation participate in predicate locking? Temporary and system
 * relations are exempt.
 */
static inline bool
PredicateLockingNeededForRelation(Relation relation)
{
    return !(relation->rd_id < FirstUnpinnedObjectId ||
             RelationUsesLocalBuffers(relation));
}
 
/*
 * When a public interface method is called for a read, this is the test to
 * see if we should do a quick return.
 *
 * Note: this function has side-effects! If this transaction has been flagged
 * as RO-safe since the last call, we release all predicate locks and reset
 * MySerializableXact. That makes subsequent calls to return quickly.
 *
 * This is marked as 'inline' to eliminate the function call overhead in the
 * common case that serialization is not needed.
 */
static inline bool
SerializationNeededForRead(Relation relation, Snapshot snapshot)
{
    /* Nothing to do if this is not a serializable transaction */
    if (MySerializableXact == InvalidSerializableXact)
        return false;
 
    /*
     * Don't acquire locks or conflict when scanning with a special snapshot.
     * This excludes things like CLUSTER and REINDEX. They use the wholesale
     * functions TransferPredicateLocksToHeapRelation() and
     * CheckTableForSerializableConflictIn() to participate in serialization,
     * but the scans involved don't need serialization.
     */
    if (!IsMVCCSnapshot(snapshot))
        return false;
 
    /*
     * Check if we have just become "RO-safe". If we have, immediately release
     * all locks as they're not needed anymore. This also resets
     * MySerializableXact, so that subsequent calls to this function can exit
     * quickly.
     *
     * A transaction is flagged as RO_SAFE if all concurrent R/W transactions
     * commit without having conflicts out to an earlier snapshot, thus
     * ensuring that no conflicts are possible for this transaction.
     */
    if (SxactIsROSafe(MySerializableXact))
    {
        ReleasePredicateLocks(false, true);
        return false;
    }
 
    /* Check if the relation doesn't participate in predicate locking */
    if (!PredicateLockingNeededForRelation(relation))
        return false;
 
    return true;                /* no excuse to skip predicate locking */
}
 
/*
 * Like SerializationNeededForRead(), but called on writes.
 * The logic is the same, but there is no snapshot and we can't be RO-safe.
 */
static inline bool
SerializationNeededForWrite(Relation relation)
{
    /* Nothing to do if this is not a serializable transaction */
    if (MySerializableXact == InvalidSerializableXact)
        return false;
 
    /* Check if the relation doesn't participate in predicate locking */
    if (!PredicateLockingNeededForRelation(relation))
        return false;
 
    return true;                /* no excuse to skip predicate locking */
}
 
 
/*------------------------------------------------------------------------*/
 
/*
 * These functions are a simple implementation of a list for this specific
 * type of struct.  If there is ever a generalized shared memory list, we
 * should probably switch to that.
 */
static SERIALIZABLEXACT *
CreatePredXact(void)
{
    SERIALIZABLEXACT *sxact;
 
    if (dlist_is_empty(&PredXact->availableList))
        return NULL;
 
    sxact = dlist_container(SERIALIZABLEXACT, xactLink,
                            dlist_pop_head_node(&PredXact->availableList));
    dlist_push_tail(&PredXact->activeList, &sxact->xactLink);
    return sxact;
}
 
static void
ReleasePredXact(SERIALIZABLEXACT *sxact)
{
    Assert(ShmemAddrIsValid(sxact));
 
    dlist_delete(&sxact->xactLink);
    dlist_push_tail(&PredXact->availableList, &sxact->xactLink);
}
 
/*------------------------------------------------------------------------*/
 
/*
 * These functions manage primitive access to the RWConflict pool and lists.
 */
static bool
RWConflictExists(const SERIALIZABLEXACT *reader, const SERIALIZABLEXACT *writer)
{
    dlist_iter  iter;
 
    Assert(reader != writer);
 
    /* Check the ends of the purported conflict first. */
    if (SxactIsDoomed(reader)
        || SxactIsDoomed(writer)
        || dlist_is_empty(&reader->outConflicts)
        || dlist_is_empty(&writer->inConflicts))
        return false;
 
    /*
     * A conflict is possible; walk the list to find out.
     *
     * The unconstify is needed as we have no const version of
     * dlist_foreach().
     */
    dlist_foreach(iter, &unconstify(SERIALIZABLEXACT *, reader)->outConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, outLink, iter.cur);
 
        if (conflict->sxactIn == writer)
            return true;
    }
 
    /* No conflict found. */
    return false;
}
 
static void
SetRWConflict(SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer)
{
    RWConflict  conflict;
 
    Assert(reader != writer);
    Assert(!RWConflictExists(reader, writer));
 
    if (dlist_is_empty(&RWConflictPool->availableList))
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("not enough elements in RWConflictPool to record a read/write conflict"),
                 errhint("You might need to run fewer transactions at a time or increase \"max_connections\".")));
 
    conflict = dlist_head_element(RWConflictData, outLink, &RWConflictPool->availableList);
    dlist_delete(&conflict->outLink);
 
    conflict->sxactOut = reader;
    conflict->sxactIn = writer;
    dlist_push_tail(&reader->outConflicts, &conflict->outLink);
    dlist_push_tail(&writer->inConflicts, &conflict->inLink);
}
 
static void
SetPossibleUnsafeConflict(SERIALIZABLEXACT *roXact,
                          SERIALIZABLEXACT *activeXact)
{
    RWConflict  conflict;
 
    Assert(roXact != activeXact);
    Assert(SxactIsReadOnly(roXact));
    Assert(!SxactIsReadOnly(activeXact));
 
    if (dlist_is_empty(&RWConflictPool->availableList))
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("not enough elements in RWConflictPool to record a potential read/write conflict"),
                 errhint("You might need to run fewer transactions at a time or increase \"max_connections\".")));
 
    conflict = dlist_head_element(RWConflictData, outLink, &RWConflictPool->availableList);
    dlist_delete(&conflict->outLink);
 
    conflict->sxactOut = activeXact;
    conflict->sxactIn = roXact;
    dlist_push_tail(&activeXact->possibleUnsafeConflicts, &conflict->outLink);
    dlist_push_tail(&roXact->possibleUnsafeConflicts, &conflict->inLink);
}
 
static void
ReleaseRWConflict(RWConflict conflict)
{
    dlist_delete(&conflict->inLink);
    dlist_delete(&conflict->outLink);
    dlist_push_tail(&RWConflictPool->availableList, &conflict->outLink);
}
 
static void
FlagSxactUnsafe(SERIALIZABLEXACT *sxact)
{
    dlist_mutable_iter iter;
 
    Assert(SxactIsReadOnly(sxact));
    Assert(!SxactIsROSafe(sxact));
 
    sxact->flags |= SXACT_FLAG_RO_UNSAFE;
 
    /*
     * We know this isn't a safe snapshot, so we can stop looking for other
     * potential conflicts.
     */
    dlist_foreach_modify(iter, &sxact->possibleUnsafeConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        Assert(!SxactIsReadOnly(conflict->sxactOut));
        Assert(sxact == conflict->sxactIn);
 
        ReleaseRWConflict(conflict);
    }
}
 
/*------------------------------------------------------------------------*/
 
/*
 * Decide whether a Serial page number is "older" for truncation purposes.
 * Analogous to CLOGPagePrecedes().
 */
static bool
SerialPagePrecedesLogically(int64 page1, int64 page2)
{
    TransactionId xid1;
    TransactionId xid2;
 
    xid1 = ((TransactionId) page1) * SERIAL_ENTRIESPERPAGE;
    xid1 += FirstNormalTransactionId + 1;
    xid2 = ((TransactionId) page2) * SERIAL_ENTRIESPERPAGE;
    xid2 += FirstNormalTransactionId + 1;
 
    return (TransactionIdPrecedes(xid1, xid2) &&
            TransactionIdPrecedes(xid1, xid2 + SERIAL_ENTRIESPERPAGE - 1));
}
 
static int
serial_errdetail_for_io_error(const void *opaque_data)
{
    TransactionId xid = *(const TransactionId *) opaque_data;
 
    return errdetail("Could not access serializable CSN of transaction %u.", xid);
}
 
#ifdef USE_ASSERT_CHECKING
static void
SerialPagePrecedesLogicallyUnitTests(void)
{
    int         per_page = SERIAL_ENTRIESPERPAGE,
                offset = per_page / 2;
    int64       newestPage,
                oldestPage,
                headPage,
                targetPage;
    TransactionId newestXact,
                oldestXact;
 
    /* GetNewTransactionId() has assigned the last XID it can safely use. */
    newestPage = 2 * SLRU_PAGES_PER_SEGMENT - 1;    /* nothing special */
    newestXact = newestPage * per_page + offset;
    Assert(newestXact / per_page == newestPage);
    oldestXact = newestXact + 1;
    oldestXact -= 1U << 31;
    oldestPage = oldestXact / per_page;
 
    /*
     * In this scenario, the SLRU headPage pertains to the last ~1000 XIDs
     * assigned.  oldestXact finishes, ~2B XIDs having elapsed since it
     * started.  Further transactions cause us to summarize oldestXact to
     * tailPage.  Function must return false so SerialAdd() doesn't zero
     * tailPage (which may contain entries for other old, recently-finished
     * XIDs) and half the SLRU.  Reaching this requires burning ~2B XIDs in
     * single-user mode, a negligible possibility.
     */
    headPage = newestPage;
    targetPage = oldestPage;
    Assert(!SerialPagePrecedesLogically(headPage, targetPage));
 
    /*
     * In this scenario, the SLRU headPage pertains to oldestXact.  We're
     * summarizing an XID near newestXact.  (Assume few other XIDs used
     * SERIALIZABLE, hence the minimal headPage advancement.  Assume
     * oldestXact was long-running and only recently reached the SLRU.)
     * Function must return true to make SerialAdd() create targetPage.
     *
     * Today's implementation mishandles this case, but it doesn't matter
     * enough to fix.  Verify that the defect affects just one page by
     * asserting correct treatment of its prior page.  Reaching this case
     * requires burning ~2B XIDs in single-user mode, a negligible
     * possibility.  Moreover, if it does happen, the consequence would be
     * mild, namely a new transaction failing in SimpleLruReadPage().
     */
    headPage = oldestPage;
    targetPage = newestPage;
    Assert(SerialPagePrecedesLogically(headPage, targetPage - 1));
#if 0
    Assert(SerialPagePrecedesLogically(headPage, targetPage));
#endif
}
#endif
 
/*
 * GUC check_hook for serializable_buffers
 */
bool
check_serial_buffers(int *newval, void **extra, GucSource source)
{
    return check_slru_buffers("serializable_buffers", newval);
}
 
/*
 * Record a committed read write serializable xid and the minimum
 * commitSeqNo of any transactions to which this xid had a rw-conflict out.
 * An invalid commitSeqNo means that there were no conflicts out from xid.
 */
static void
SerialAdd(TransactionId xid, SerCommitSeqNo minConflictCommitSeqNo)
{
    TransactionId tailXid;
    int64       targetPage;
    int         slotno;
    int64       firstZeroPage;
    bool        isNewPage;
    LWLock     *lock;
 
    Assert(TransactionIdIsValid(xid));
 
    targetPage = SerialPage(xid);
    lock = SimpleLruGetBankLock(SerialSlruCtl, targetPage);
 
    /*
     * In this routine, we must hold both SerialControlLock and the SLRU bank
     * lock simultaneously while making the SLRU data catch up with the new
     * state that we determine.
     */
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /*
     * If 'xid' is older than the global xmin (== tailXid), there's no need to
     * store it, after all. This can happen if the oldest transaction holding
     * back the global xmin just finished, making 'xid' uninteresting, but
     * ClearOldPredicateLocks() has not yet run.
     */
    tailXid = serialControl->tailXid;
    if (!TransactionIdIsValid(tailXid) || TransactionIdPrecedes(xid, tailXid))
    {
        LWLockRelease(SerialControlLock);
        return;
    }
 
    /*
     * If the SLRU is currently unused, zero out the whole active region from
     * tailXid to headXid before taking it into use. Otherwise zero out only
     * any new pages that enter the tailXid-headXid range as we advance
     * headXid.
     */
    if (serialControl->headPage < 0)
    {
        firstZeroPage = SerialPage(tailXid);
        isNewPage = true;
    }
    else
    {
        firstZeroPage = SerialNextPage(serialControl->headPage);
        isNewPage = SerialPagePrecedesLogically(serialControl->headPage,
                                                targetPage);
    }
 
    if (!TransactionIdIsValid(serialControl->headXid)
        || TransactionIdFollows(xid, serialControl->headXid))
        serialControl->headXid = xid;
    if (isNewPage)
        serialControl->headPage = targetPage;
 
    if (isNewPage)
    {
        /* Initialize intervening pages; might involve trading locks */
        for (;;)
        {
            lock = SimpleLruGetBankLock(SerialSlruCtl, firstZeroPage);
            LWLockAcquire(lock, LW_EXCLUSIVE);
            slotno = SimpleLruZeroPage(SerialSlruCtl, firstZeroPage);
            if (firstZeroPage == targetPage)
                break;
            firstZeroPage = SerialNextPage(firstZeroPage);
            LWLockRelease(lock);
        }
    }
    else
    {
        LWLockAcquire(lock, LW_EXCLUSIVE);
        slotno = SimpleLruReadPage(SerialSlruCtl, targetPage, true, &xid);
    }
 
    SerialValue(slotno, xid) = minConflictCommitSeqNo;
    SerialSlruCtl->shared->page_dirty[slotno] = true;
 
    LWLockRelease(lock);
    LWLockRelease(SerialControlLock);
}
 
/*
 * Get the minimum commitSeqNo for any conflict out for the given xid.  For
 * a transaction which exists but has no conflict out, InvalidSerCommitSeqNo
 * will be returned.
 */
static SerCommitSeqNo
SerialGetMinConflictCommitSeqNo(TransactionId xid)
{
    TransactionId headXid;
    TransactionId tailXid;
    SerCommitSeqNo val;
    int         slotno;
 
    Assert(TransactionIdIsValid(xid));
 
    LWLockAcquire(SerialControlLock, LW_SHARED);
    headXid = serialControl->headXid;
    tailXid = serialControl->tailXid;
    LWLockRelease(SerialControlLock);
 
    if (!TransactionIdIsValid(headXid))
        return 0;
 
    Assert(TransactionIdIsValid(tailXid));
 
    if (TransactionIdPrecedes(xid, tailXid)
        || TransactionIdFollows(xid, headXid))
        return 0;
 
    /*
     * The following function must be called without holding SLRU bank lock,
     * but will return with that lock held, which must then be released.
     */
    slotno = SimpleLruReadPage_ReadOnly(SerialSlruCtl,
                                        SerialPage(xid), &xid);
    val = SerialValue(slotno, xid);
    LWLockRelease(SimpleLruGetBankLock(SerialSlruCtl, SerialPage(xid)));
    return val;
}
 
/*
 * Call this whenever there is a new xmin for active serializable
 * transactions.  We don't need to keep information on transactions which
 * precede that.  InvalidTransactionId means none active, so everything in
 * the SLRU can be discarded.
 */
static void
SerialSetActiveSerXmin(TransactionId xid)
{
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /*
     * When no sxacts are active, nothing overlaps, set the xid values to
     * invalid to show that there are no valid entries.  Don't clear headPage,
     * though.  A new xmin might still land on that page, and we don't want to
     * repeatedly zero out the same page.
     */
    if (!TransactionIdIsValid(xid))
    {
        serialControl->tailXid = InvalidTransactionId;
        serialControl->headXid = InvalidTransactionId;
        LWLockRelease(SerialControlLock);
        return;
    }
 
    /*
     * When we're recovering prepared transactions, the global xmin might move
     * backwards depending on the order they're recovered. Normally that's not
     * OK, but during recovery no serializable transactions will commit, so
     * the SLRU is empty and we can get away with it.
     */
    if (RecoveryInProgress())
    {
        Assert(serialControl->headPage < 0);
        if (!TransactionIdIsValid(serialControl->tailXid)
            || TransactionIdPrecedes(xid, serialControl->tailXid))
        {
            serialControl->tailXid = xid;
        }
        LWLockRelease(SerialControlLock);
        return;
    }
 
    Assert(!TransactionIdIsValid(serialControl->tailXid)
           || TransactionIdFollows(xid, serialControl->tailXid));
 
    serialControl->tailXid = xid;
 
    LWLockRelease(SerialControlLock);
}
 
/*
 * Perform a checkpoint --- either during shutdown, or on-the-fly
 *
 * We don't have any data that needs to survive a restart, but this is a
 * convenient place to truncate the SLRU.
 */
void
CheckPointPredicate(void)
{
    int64       truncateCutoffPage;
 
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /* Exit quickly if the SLRU is currently not in use. */
    if (serialControl->headPage < 0)
    {
        LWLockRelease(SerialControlLock);
        return;
    }
 
    if (TransactionIdIsValid(serialControl->tailXid))
    {
        int64       tailPage;
 
        tailPage = SerialPage(serialControl->tailXid);
 
        /*
         * It is possible for the tailXid to be ahead of the headXid.  This
         * occurs if we checkpoint while there are in-progress serializable
         * transaction(s) advancing the tail but we are yet to summarize the
         * transactions.  In this case, we cutoff up to the headPage and the
         * next summary will advance the headXid.
         */
        if (SerialPagePrecedesLogically(tailPage, serialControl->headPage))
        {
            /* We can truncate the SLRU up to the page containing tailXid */
            truncateCutoffPage = tailPage;
        }
        else
            truncateCutoffPage = serialControl->headPage;
    }
    else
    {
        /*----------
         * The SLRU is no longer needed. Truncate to head before we set head
         * invalid.
         *
         * XXX: It's possible that the SLRU is not needed again until XID
         * wrap-around has happened, so that the segment containing headPage
         * that we leave behind will appear to be new again. In that case it
         * won't be removed until XID horizon advances enough to make it
         * current again.
         *
         * XXX: This should happen in vac_truncate_clog(), not in checkpoints.
         * Consider this scenario, starting from a system with no in-progress
         * transactions and VACUUM FREEZE having maximized oldestXact:
         * - Start a SERIALIZABLE transaction.
         * - Start, finish, and summarize a SERIALIZABLE transaction, creating
         *   one SLRU page.
         * - Consume XIDs to reach xidStopLimit.
         * - Finish all transactions.  Due to the long-running SERIALIZABLE
         *   transaction, earlier checkpoints did not touch headPage.  The
         *   next checkpoint will change it, but that checkpoint happens after
         *   the end of the scenario.
         * - VACUUM to advance XID limits.
         * - Consume ~2M XIDs, crossing the former xidWrapLimit.
         * - Start, finish, and summarize a SERIALIZABLE transaction.
         *   SerialAdd() declines to create the targetPage, because headPage
         *   is not regarded as in the past relative to that targetPage.  The
         *   transaction instigating the summarize fails in
         *   SimpleLruReadPage().
         */
        truncateCutoffPage = serialControl->headPage;
        serialControl->headPage = -1;
    }
 
    LWLockRelease(SerialControlLock);
 
    /*
     * Truncate away pages that are no longer required.  Note that no
     * additional locking is required, because this is only called as part of
     * a checkpoint, and the validity limits have already been determined.
     */
    SimpleLruTruncate(SerialSlruCtl, truncateCutoffPage);
 
    /*
     * Write dirty SLRU pages to disk
     *
     * This is not actually necessary from a correctness point of view. We do
     * it merely as a debugging aid.
     *
     * We're doing this after the truncation to avoid writing pages right
     * before deleting the file in which they sit, which would be completely
     * pointless.
     */
    SimpleLruWriteAll(SerialSlruCtl, true);
}
 
/*------------------------------------------------------------------------*/
 
/*
 * PredicateLockShmemRequest -- Register the predicate locking data structures.
 */
static void
PredicateLockShmemRequest(void *arg)
{
    int64       max_predicate_lock_targets;
    int64       max_predicate_locks;
    int64       max_rw_conflicts;
 
    /*
     * Register hash table for PREDICATELOCKTARGET structs.  This stores
     * per-predicate-lock-target information.
     */
    max_predicate_lock_targets = NPREDICATELOCKTARGETENTS();
 
    ShmemRequestHash(.name = "PREDICATELOCKTARGET hash",
                     .nelems = max_predicate_lock_targets,
                     .ptr = &PredicateLockTargetHash,
                     .hash_info.keysize = sizeof(PREDICATELOCKTARGETTAG),
                     .hash_info.entrysize = sizeof(PREDICATELOCKTARGET),
                     .hash_info.num_partitions = NUM_PREDICATELOCK_PARTITIONS,
                     .hash_flags = HASH_ELEM | HASH_BLOBS | HASH_PARTITION | HASH_FIXED_SIZE,
        );
 
    /*
     * Allocate hash table for PREDICATELOCK structs.  This stores per
     * xact-lock-of-a-target information.
     *
     * Assume an average of 2 xacts per target.
     */
    max_predicate_locks = max_predicate_lock_targets * 2;
 
    ShmemRequestHash(.name = "PREDICATELOCK hash",
                     .nelems = max_predicate_locks,
                     .ptr = &PredicateLockHash,
                     .hash_info.keysize = sizeof(PREDICATELOCKTAG),
                     .hash_info.entrysize = sizeof(PREDICATELOCK),
                     .hash_info.hash = predicatelock_hash,
                     .hash_info.num_partitions = NUM_PREDICATELOCK_PARTITIONS,
                     .hash_flags = HASH_ELEM | HASH_FUNCTION | HASH_PARTITION | HASH_FIXED_SIZE,
        );
 
    /*
     * Compute size for serializable transaction hashtable. Note these
     * calculations must agree with PredicateLockShmemSize!
     *
     * Assume an average of 10 predicate locking transactions per backend.
     * This allows aggressive cleanup while detail is present before data must
     * be summarized for storage in SLRU and the "dummy" transaction.
     */
    max_serializable_xacts = (MaxBackends + max_prepared_xacts) * 10;
 
    /*
     * Register a list to hold information on transactions participating in
     * predicate locking.
     */
    ShmemRequestStruct(.name = "PredXactList",
                       .size = add_size(PredXactListDataSize,
                                        (mul_size((Size) max_serializable_xacts,
                                                  sizeof(SERIALIZABLEXACT)))),
                       .ptr = (void **) &PredXact,
        );
 
    /*
     * Register hash table for SERIALIZABLEXID structs.  This stores per-xid
     * information for serializable transactions which have accessed data.
     */
    ShmemRequestHash(.name = "SERIALIZABLEXID hash",
                     .nelems = max_serializable_xacts,
                     .ptr = &SerializableXidHash,
                     .hash_info.keysize = sizeof(SERIALIZABLEXIDTAG),
                     .hash_info.entrysize = sizeof(SERIALIZABLEXID),
                     .hash_flags = HASH_ELEM | HASH_BLOBS | HASH_FIXED_SIZE,
        );
 
    /*
     * Allocate space for tracking rw-conflicts in lists attached to the
     * transactions.
     *
     * Assume an average of 5 conflicts per transaction.  Calculations suggest
     * that this will prevent resource exhaustion in even the most pessimal
     * loads up to max_connections = 200 with all 200 connections pounding the
     * database with serializable transactions.  Beyond that, there may be
     * occasional transactions canceled when trying to flag conflicts. That's
     * probably OK.
     */
    max_rw_conflicts = max_serializable_xacts * 5;
 
    ShmemRequestStruct(.name = "RWConflictPool",
                       .size = RWConflictPoolHeaderDataSize + mul_size((Size) max_rw_conflicts,
                                                                       RWConflictDataSize),
                       .ptr = (void **) &RWConflictPool,
        );
 
    ShmemRequestStruct(.name = "FinishedSerializableTransactions",
                       .size = sizeof(dlist_head),
                       .ptr = (void **) &FinishedSerializableTransactions,
        );
 
    /*
     * Initialize the SLRU storage for old committed serializable
     * transactions.
     */
    SimpleLruRequest(.desc = &SerialSlruDesc,
                     .name = "serializable",
                     .Dir = "pg_serial",
                     .long_segment_names = false,
 
                     .nslots = serializable_buffers,
 
                     .sync_handler = SYNC_HANDLER_NONE,
                     .PagePrecedes = SerialPagePrecedesLogically,
                     .errdetail_for_io_error = serial_errdetail_for_io_error,
 
                     .buffer_tranche_id = LWTRANCHE_SERIAL_BUFFER,
                     .bank_tranche_id = LWTRANCHE_SERIAL_SLRU,
        );
#ifdef USE_ASSERT_CHECKING
    SerialPagePrecedesLogicallyUnitTests();
#endif
 
    ShmemRequestStruct(.name = "SerialControlData",
                       .size = sizeof(SerialControlData),
                       .ptr = (void **) &serialControl,
        );
}
 
static void
PredicateLockShmemInit(void *arg)
{
    int         max_rw_conflicts;
    bool        found;
 
    /*
     * Reserve a dummy entry in the hash table; we use it to make sure there's
     * always one entry available when we need to split or combine a page,
     * because running out of space there could mean aborting a
     * non-serializable transaction.
     */
    (void) hash_search(PredicateLockTargetHash, &ScratchTargetTag,
                       HASH_ENTER, &found);
    Assert(!found);
 
    dlist_init(&PredXact->availableList);
    dlist_init(&PredXact->activeList);
    PredXact->SxactGlobalXmin = InvalidTransactionId;
    PredXact->SxactGlobalXminCount = 0;
    PredXact->WritableSxactCount = 0;
    PredXact->LastSxactCommitSeqNo = FirstNormalSerCommitSeqNo - 1;
    PredXact->CanPartialClearThrough = 0;
    PredXact->HavePartialClearedThrough = 0;
    PredXact->element
        = (SERIALIZABLEXACT *) ((char *) PredXact + PredXactListDataSize);
    /* Add all elements to available list, clean. */
    for (int i = 0; i < max_serializable_xacts; i++)
    {
        LWLockInitialize(&PredXact->element[i].perXactPredicateListLock,
                         LWTRANCHE_PER_XACT_PREDICATE_LIST);
        dlist_push_tail(&PredXact->availableList, &PredXact->element[i].xactLink);
    }
    PredXact->OldCommittedSxact = CreatePredXact();
    SetInvalidVirtualTransactionId(PredXact->OldCommittedSxact->vxid);
    PredXact->OldCommittedSxact->prepareSeqNo = 0;
    PredXact->OldCommittedSxact->commitSeqNo = 0;
    PredXact->OldCommittedSxact->SeqNo.lastCommitBeforeSnapshot = 0;
    dlist_init(&PredXact->OldCommittedSxact->outConflicts);
    dlist_init(&PredXact->OldCommittedSxact->inConflicts);
    dlist_init(&PredXact->OldCommittedSxact->predicateLocks);
    dlist_node_init(&PredXact->OldCommittedSxact->finishedLink);
    dlist_init(&PredXact->OldCommittedSxact->possibleUnsafeConflicts);
    PredXact->OldCommittedSxact->topXid = InvalidTransactionId;
    PredXact->OldCommittedSxact->finishedBefore = InvalidTransactionId;
    PredXact->OldCommittedSxact->xmin = InvalidTransactionId;
    PredXact->OldCommittedSxact->flags = SXACT_FLAG_COMMITTED;
    PredXact->OldCommittedSxact->pid = 0;
    PredXact->OldCommittedSxact->pgprocno = INVALID_PROC_NUMBER;
 
    /* Initialize the rw-conflict pool */
    dlist_init(&RWConflictPool->availableList);
    RWConflictPool->element = (RWConflict) ((char *) RWConflictPool +
                                            RWConflictPoolHeaderDataSize);
 
    max_rw_conflicts = max_serializable_xacts * 5;
 
    /* Add all elements to available list, clean. */
    for (int i = 0; i < max_rw_conflicts; i++)
    {
        dlist_push_tail(&RWConflictPool->availableList,
                        &RWConflictPool->element[i].outLink);
    }
 
    /* Initialize the list of finished serializable transactions */
    dlist_init(FinishedSerializableTransactions);
 
    /* Initialize SerialControl to reflect empty SLRU. */
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
    serialControl->headPage = -1;
    serialControl->headXid = InvalidTransactionId;
    serialControl->tailXid = InvalidTransactionId;
    LWLockRelease(SerialControlLock);
 
    SlruPagePrecedesUnitTests(SerialSlruCtl, SERIAL_ENTRIESPERPAGE);
 
    /* This never changes, so let's keep a local copy. */
    OldCommittedSxact = PredXact->OldCommittedSxact;
 
    /* Pre-calculate the hash and partition lock of the scratch entry */
    ScratchTargetTagHash = PredicateLockTargetTagHashCode(&ScratchTargetTag);
    ScratchPartitionLock = PredicateLockHashPartitionLock(ScratchTargetTagHash);
}
 
static void
PredicateLockShmemAttach(void *arg)
{
    /* This never changes, so let's keep a local copy. */
    OldCommittedSxact = PredXact->OldCommittedSxact;
 
    /* Pre-calculate the hash and partition lock of the scratch entry */
    ScratchTargetTagHash = PredicateLockTargetTagHashCode(&ScratchTargetTag);
    ScratchPartitionLock = PredicateLockHashPartitionLock(ScratchTargetTagHash);
}
 
/*
 * Compute the hash code associated with a PREDICATELOCKTAG.
 *
 * Because we want to use just one set of partition locks for both the
 * PREDICATELOCKTARGET and PREDICATELOCK hash tables, we have to make sure
 * that PREDICATELOCKs fall into the same partition number as their
 * associated PREDICATELOCKTARGETs.  dynahash.c expects the partition number
 * to be the low-order bits of the hash code, and therefore a
 * PREDICATELOCKTAG's hash code must have the same low-order bits as the
 * associated PREDICATELOCKTARGETTAG's hash code.  We achieve this with this
 * specialized hash function.
 */
static uint32
predicatelock_hash(const void *key, Size keysize)
{
    const PREDICATELOCKTAG *predicatelocktag = (const PREDICATELOCKTAG *) key;
    uint32      targethash;
 
    Assert(keysize == sizeof(PREDICATELOCKTAG));
 
    /* Look into the associated target object, and compute its hash code */
    targethash = PredicateLockTargetTagHashCode(&predicatelocktag->myTarget->tag);
 
    return PredicateLockHashCodeFromTargetHashCode(predicatelocktag, targethash);
}
 
 
/*
 * GetPredicateLockStatusData
 *      Return a table containing the internal state of the predicate
 *      lock manager for use in pg_lock_status.
 *
 * Like GetLockStatusData, this function tries to hold the partition LWLocks
 * for as short a time as possible by returning two arrays that simply
 * contain the PREDICATELOCKTARGETTAG and SERIALIZABLEXACT for each lock
 * table entry. Multiple copies of the same PREDICATELOCKTARGETTAG and
 * SERIALIZABLEXACT will likely appear.
 */
PredicateLockData *
GetPredicateLockStatusData(void)
{
    PredicateLockData *data;
    int         i;
    int         els,
                el;
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCK *predlock;
 
    data = palloc_object(PredicateLockData);
 
    /*
     * To ensure consistency, take simultaneous locks on all partition locks
     * in ascending order, then SerializableXactHashLock.
     */
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_SHARED);
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    /* Get number of locks and allocate appropriately-sized arrays. */
    els = hash_get_num_entries(PredicateLockHash);
    data->nelements = els;
    data->locktags = palloc_array(PREDICATELOCKTARGETTAG, els);
    data->xacts = palloc_array(SERIALIZABLEXACT, els);
 
 
    /* Scan through PredicateLockHash and copy contents */
    hash_seq_init(&seqstat, PredicateLockHash);
 
    el = 0;
 
    while ((predlock = (PREDICATELOCK *) hash_seq_search(&seqstat)))
    {
        data->locktags[el] = predlock->tag.myTarget->tag;
        data->xacts[el] = *predlock->tag.myXact;
        el++;
    }
 
    Assert(el == els);
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
 
    return data;
}
 
/*
 * Free up shared memory structures by pushing the oldest sxact (the one at
 * the front of the SummarizeOldestCommittedSxact queue) into summary form.
 * Each call will free exactly one SERIALIZABLEXACT structure and may also
 * free one or more of these structures: SERIALIZABLEXID, PREDICATELOCK,
 * PREDICATELOCKTARGET, RWConflictData.
 */
static void
SummarizeOldestCommittedSxact(void)
{
    SERIALIZABLEXACT *sxact;
 
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
 
    /*
     * This function is only called if there are no sxact slots available.
     * Some of them must belong to old, already-finished transactions, so
     * there should be something in FinishedSerializableTransactions list that
     * we can summarize. However, there's a race condition: while we were not
     * holding any locks, a transaction might have ended and cleaned up all
     * the finished sxact entries already, freeing up their sxact slots. In
     * that case, we have nothing to do here. The caller will find one of the
     * slots released by the other backend when it retries.
     */
    if (dlist_is_empty(FinishedSerializableTransactions))
    {
        LWLockRelease(SerializableFinishedListLock);
        return;
    }
 
    /*
     * Grab the first sxact off the finished list -- this will be the earliest
     * commit.  Remove it from the list.
     */
    sxact = dlist_head_element(SERIALIZABLEXACT, finishedLink,
                               FinishedSerializableTransactions);
    dlist_delete_thoroughly(&sxact->finishedLink);
 
    /* Add to SLRU summary information. */
    if (TransactionIdIsValid(sxact->topXid) && !SxactIsReadOnly(sxact))
        SerialAdd(sxact->topXid, SxactHasConflictOut(sxact)
                  ? sxact->SeqNo.earliestOutConflictCommit : InvalidSerCommitSeqNo);
 
    /* Summarize and release the detail. */
    ReleaseOneSerializableXact(sxact, false, true);
 
    LWLockRelease(SerializableFinishedListLock);
}
 
/*
 * GetSafeSnapshot
 *      Obtain and register a snapshot for a READ ONLY DEFERRABLE
 *      transaction. Ensures that the snapshot is "safe", i.e. a
 *      read-only transaction running on it can execute serializably
 *      without further checks. This requires waiting for concurrent
 *      transactions to complete, and retrying with a new snapshot if
 *      one of them could possibly create a conflict.
 *
 *      As with GetSerializableTransactionSnapshot (which this is a subroutine
 *      for), the passed-in Snapshot pointer should reference a static data
 *      area that can safely be passed to GetSnapshotData.
 */
static Snapshot
GetSafeSnapshot(Snapshot origSnapshot)
{
    Snapshot    snapshot;
 
    Assert(XactReadOnly && XactDeferrable);
 
    while (true)
    {
        /*
         * GetSerializableTransactionSnapshotInt is going to call
         * GetSnapshotData, so we need to provide it the static snapshot area
         * our caller passed to us.  The pointer returned is actually the same
         * one passed to it, but we avoid assuming that here.
         */
        snapshot = GetSerializableTransactionSnapshotInt(origSnapshot,
                                                         NULL, InvalidPid);
 
        if (MySerializableXact == InvalidSerializableXact)
            return snapshot;    /* no concurrent r/w xacts; it's safe */
 
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        /*
         * Wait for concurrent transactions to finish. Stop early if one of
         * them marked us as conflicted.
         */
        MySerializableXact->flags |= SXACT_FLAG_DEFERRABLE_WAITING;
        while (!(dlist_is_empty(&MySerializableXact->possibleUnsafeConflicts) ||
                 SxactIsROUnsafe(MySerializableXact)))
        {
            LWLockRelease(SerializableXactHashLock);
            ProcWaitForSignal(WAIT_EVENT_SAFE_SNAPSHOT);
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        }
        MySerializableXact->flags &= ~SXACT_FLAG_DEFERRABLE_WAITING;
 
        if (!SxactIsROUnsafe(MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            break;              /* success */
        }
 
        LWLockRelease(SerializableXactHashLock);
 
        /* else, need to retry... */
        ereport(DEBUG2,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg_internal("deferrable snapshot was unsafe; trying a new one")));
        ReleasePredicateLocks(false, false);
    }
 
    /*
     * Now we have a safe snapshot, so we don't need to do any further checks.
     */
    Assert(SxactIsROSafe(MySerializableXact));
    ReleasePredicateLocks(false, true);
 
    return snapshot;
}
 
/*
 * GetSafeSnapshotBlockingPids
 *      If the specified process is currently blocked in GetSafeSnapshot,
 *      write the process IDs of all processes that it is blocked by
 *      into the caller-supplied buffer output[].  The list is truncated at
 *      output_size, and the number of PIDs written into the buffer is
 *      returned.  Returns zero if the given PID is not currently blocked
 *      in GetSafeSnapshot.
 */
int
GetSafeSnapshotBlockingPids(int blocked_pid, int *output, int output_size)
{
    int         num_written = 0;
    dlist_iter  iter;
    SERIALIZABLEXACT *blocking_sxact = NULL;
 
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    /* Find blocked_pid's SERIALIZABLEXACT by linear search. */
    dlist_foreach(iter, &PredXact->activeList)
    {
        SERIALIZABLEXACT *sxact =
            dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
        if (sxact->pid == blocked_pid)
        {
            blocking_sxact = sxact;
            break;
        }
    }
 
    /* Did we find it, and is it currently waiting in GetSafeSnapshot? */
    if (blocking_sxact != NULL && SxactIsDeferrableWaiting(blocking_sxact))
    {
        /* Traverse the list of possible unsafe conflicts collecting PIDs. */
        dlist_foreach(iter, &blocking_sxact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, inLink, iter.cur);
 
            output[num_written++] = possibleUnsafeConflict->sxactOut->pid;
 
            if (num_written >= output_size)
                break;
        }
    }
 
    LWLockRelease(SerializableXactHashLock);
 
    return num_written;
}
 
/*
 * Acquire a snapshot that can be used for the current transaction.
 *
 * Make sure we have a SERIALIZABLEXACT reference in MySerializableXact.
 * It should be current for this process and be contained in PredXact.
 *
 * The passed-in Snapshot pointer should reference a static data area that
 * can safely be passed to GetSnapshotData.  The return value is actually
 * always this same pointer; no new snapshot data structure is allocated
 * within this function.
 */
Snapshot
GetSerializableTransactionSnapshot(Snapshot snapshot)
{
    Assert(IsolationIsSerializable());
 
    /*
     * Can't use serializable mode while recovery is still active, as it is,
     * for example, on a hot standby.  We could get here despite the check in
     * check_transaction_isolation() if default_transaction_isolation is set
     * to serializable, so phrase the hint accordingly.
     */
    if (RecoveryInProgress())
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot use serializable mode in a hot standby"),
                 errdetail("\"default_transaction_isolation\" is set to \"serializable\"."),
                 errhint("You can use \"SET default_transaction_isolation = 'repeatable read'\" to change the default.")));
 
    /*
     * A special optimization is available for SERIALIZABLE READ ONLY
     * DEFERRABLE transactions -- we can wait for a suitable snapshot and
     * thereby avoid all SSI overhead once it's running.
     */
    if (XactReadOnly && XactDeferrable)
        return GetSafeSnapshot(snapshot);
 
    return GetSerializableTransactionSnapshotInt(snapshot,
                                                 NULL, InvalidPid);
}
 
/*
 * Import a snapshot to be used for the current transaction.
 *
 * This is nearly the same as GetSerializableTransactionSnapshot, except that
 * we don't take a new snapshot, but rather use the data we're handed.
 *
 * The caller must have verified that the snapshot came from a serializable
 * transaction; and if we're read-write, the source transaction must not be
 * read-only.
 */
void
SetSerializableTransactionSnapshot(Snapshot snapshot,
                                   VirtualTransactionId *sourcevxid,
                                   int sourcepid)
{
    Assert(IsolationIsSerializable());
 
    /*
     * If this is called by parallel.c in a parallel worker, we don't want to
     * create a SERIALIZABLEXACT just yet because the leader's
     * SERIALIZABLEXACT will be installed with AttachSerializableXact().  We
     * also don't want to reject SERIALIZABLE READ ONLY DEFERRABLE in this
     * case, because the leader has already determined that the snapshot it
     * has passed us is safe.  So there is nothing for us to do.
     */
    if (IsParallelWorker())
        return;
 
    /*
     * We do not allow SERIALIZABLE READ ONLY DEFERRABLE transactions to
     * import snapshots, since there's no way to wait for a safe snapshot when
     * we're using the snap we're told to.  (XXX instead of throwing an error,
     * we could just ignore the XactDeferrable flag?)
     */
    if (XactReadOnly && XactDeferrable)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("a snapshot-importing transaction must not be READ ONLY DEFERRABLE")));
 
    (void) GetSerializableTransactionSnapshotInt(snapshot, sourcevxid,
                                                 sourcepid);
}
 
/*
 * Guts of GetSerializableTransactionSnapshot
 *
 * If sourcevxid is valid, this is actually an import operation and we should
 * skip calling GetSnapshotData, because the snapshot contents are already
 * loaded up.  HOWEVER: to avoid race conditions, we must check that the
 * source xact is still running after we acquire SerializableXactHashLock.
 * We do that by calling ProcArrayInstallImportedXmin.
 */
static Snapshot
GetSerializableTransactionSnapshotInt(Snapshot snapshot,
                                      VirtualTransactionId *sourcevxid,
                                      int sourcepid)
{
    PGPROC     *proc;
    VirtualTransactionId vxid;
    SERIALIZABLEXACT *sxact,
               *othersxact;
 
    /* We only do this for serializable transactions.  Once. */
    Assert(MySerializableXact == InvalidSerializableXact);
 
    Assert(!RecoveryInProgress());
 
    /*
     * Since all parts of a serializable transaction must use the same
     * snapshot, it is too late to establish one after a parallel operation
     * has begun.
     */
    if (IsInParallelMode())
        elog(ERROR, "cannot establish serializable snapshot during a parallel operation");
 
    proc = MyProc;
    Assert(proc != NULL);
    GET_VXID_FROM_PGPROC(vxid, *proc);
 
    /*
     * First we get the sxact structure, which may involve looping and access
     * to the "finished" list to free a structure for use.
     *
     * We must hold SerializableXactHashLock when taking/checking the snapshot
     * to avoid race conditions, for much the same reasons that
     * GetSnapshotData takes the ProcArrayLock.  Since we might have to
     * release SerializableXactHashLock to call SummarizeOldestCommittedSxact,
     * this means we have to create the sxact first, which is a bit annoying
     * (in particular, an elog(ERROR) in procarray.c would cause us to leak
     * the sxact).  Consider refactoring to avoid this.
     */
#ifdef TEST_SUMMARIZE_SERIAL
    SummarizeOldestCommittedSxact();
#endif
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
    do
    {
        sxact = CreatePredXact();
        /* If null, push out committed sxact to SLRU summary & retry. */
        if (!sxact)
        {
            LWLockRelease(SerializableXactHashLock);
            SummarizeOldestCommittedSxact();
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        }
    } while (!sxact);
 
    /* Get the snapshot, or check that it's safe to use */
    if (!sourcevxid)
        snapshot = GetSnapshotData(snapshot);
    else if (!ProcArrayInstallImportedXmin(snapshot->xmin, sourcevxid))
    {
        ReleasePredXact(sxact);
        LWLockRelease(SerializableXactHashLock);
        ereport(ERROR,
                (errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
                 errmsg("could not import the requested snapshot"),
                 errdetail("The source process with PID %d is not running anymore.",
                           sourcepid)));
    }
 
    /*
     * If there are no serializable transactions which are not read-only, we
     * can "opt out" of predicate locking and conflict checking for a
     * read-only transaction.
     *
     * The reason this is safe is that a read-only transaction can only become
     * part of a dangerous structure if it overlaps a writable transaction
     * which in turn overlaps a writable transaction which committed before
     * the read-only transaction started.  A new writable transaction can
     * overlap this one, but it can't meet the other condition of overlapping
     * a transaction which committed before this one started.
     */
    if (XactReadOnly && PredXact->WritableSxactCount == 0)
    {
        ReleasePredXact(sxact);
        LWLockRelease(SerializableXactHashLock);
        return snapshot;
    }
 
    /* Initialize the structure. */
    sxact->vxid = vxid;
    sxact->SeqNo.lastCommitBeforeSnapshot = PredXact->LastSxactCommitSeqNo;
    sxact->prepareSeqNo = InvalidSerCommitSeqNo;
    sxact->commitSeqNo = InvalidSerCommitSeqNo;
    dlist_init(&(sxact->outConflicts));
    dlist_init(&(sxact->inConflicts));
    dlist_init(&(sxact->possibleUnsafeConflicts));
    sxact->topXid = GetTopTransactionIdIfAny();
    sxact->finishedBefore = InvalidTransactionId;
    sxact->xmin = snapshot->xmin;
    sxact->pid = MyProcPid;
    sxact->pgprocno = MyProcNumber;
    dlist_init(&sxact->predicateLocks);
    dlist_node_init(&sxact->finishedLink);
    sxact->flags = 0;
    if (XactReadOnly)
    {
        dlist_iter  iter;
 
        sxact->flags |= SXACT_FLAG_READ_ONLY;
 
        /*
         * Register all concurrent r/w transactions as possible conflicts; if
         * all of them commit without any outgoing conflicts to earlier
         * transactions then this snapshot can be deemed safe (and we can run
         * without tracking predicate locks).
         */
        dlist_foreach(iter, &PredXact->activeList)
        {
            othersxact = dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
            if (!SxactIsCommitted(othersxact)
                && !SxactIsDoomed(othersxact)
                && !SxactIsReadOnly(othersxact))
            {
                SetPossibleUnsafeConflict(sxact, othersxact);
            }
        }
 
        /*
         * If we didn't find any possibly unsafe conflicts because every
         * uncommitted writable transaction turned out to be doomed, then we
         * can "opt out" immediately.  See comments above the earlier check
         * for PredXact->WritableSxactCount == 0.
         */
        if (dlist_is_empty(&sxact->possibleUnsafeConflicts))
        {
            ReleasePredXact(sxact);
            LWLockRelease(SerializableXactHashLock);
            return snapshot;
        }
    }
    else
    {
        ++(PredXact->WritableSxactCount);
        Assert(PredXact->WritableSxactCount <=
               (MaxBackends + max_prepared_xacts));
    }
 
    /* Maintain serializable global xmin info. */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount == 0);
        PredXact->SxactGlobalXmin = snapshot->xmin;
        PredXact->SxactGlobalXminCount = 1;
        SerialSetActiveSerXmin(snapshot->xmin);
    }
    else if (TransactionIdEquals(snapshot->xmin, PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount > 0);
        PredXact->SxactGlobalXminCount++;
    }
    else
    {
        Assert(TransactionIdFollows(snapshot->xmin, PredXact->SxactGlobalXmin));
    }
 
    MySerializableXact = sxact;
    MyXactDidWrite = false;     /* haven't written anything yet */
 
    LWLockRelease(SerializableXactHashLock);
 
    CreateLocalPredicateLockHash();
 
    return snapshot;
}
 
static void
CreateLocalPredicateLockHash(void)
{
    HASHCTL     hash_ctl;
 
    /* Initialize the backend-local hash table of parent locks */
    Assert(LocalPredicateLockHash == NULL);
    hash_ctl.keysize = sizeof(PREDICATELOCKTARGETTAG);
    hash_ctl.entrysize = sizeof(LOCALPREDICATELOCK);
    LocalPredicateLockHash = hash_create("Local predicate lock",
                                         max_predicate_locks_per_xact,
                                         &hash_ctl,
                                         HASH_ELEM | HASH_BLOBS);
}
 
/*
 * Register the top level XID in SerializableXidHash.
 * Also store it for easy reference in MySerializableXact.
 */
void
RegisterPredicateLockingXid(TransactionId xid)
{
    SERIALIZABLEXIDTAG sxidtag;
    SERIALIZABLEXID *sxid;
    bool        found;
 
    /*
     * If we're not tracking predicate lock data for this transaction, we
     * should ignore the request and return quickly.
     */
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    /* We should have a valid XID and be at the top level. */
    Assert(TransactionIdIsValid(xid));
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* This should only be done once per transaction. */
    Assert(MySerializableXact->topXid == InvalidTransactionId);
 
    MySerializableXact->topXid = xid;
 
    sxidtag.xid = xid;
    sxid = (SERIALIZABLEXID *) hash_search(SerializableXidHash,
                                           &sxidtag,
                                           HASH_ENTER, &found);
    Assert(!found);
 
    /* Initialize the structure. */
    sxid->myXact = MySerializableXact;
    LWLockRelease(SerializableXactHashLock);
}
 
 
/*
 * Check whether there are any predicate locks held by any transaction
 * for the page at the given block number.
 *
 * Note that the transaction may be completed but not yet subject to
 * cleanup due to overlapping serializable transactions.  This must
 * return valid information regardless of transaction isolation level.
 *
 * Also note that this doesn't check for a conflicting relation lock,
 * just a lock specifically on the given page.
 *
 * One use is to support proper behavior during GiST index vacuum.
 */
bool
PageIsPredicateLocked(Relation relation, BlockNumber blkno)
{
    PREDICATELOCKTARGETTAG targettag;
    uint32      targettaghash;
    LWLock     *partitionLock;
    PREDICATELOCKTARGET *target;
 
    SET_PREDICATELOCKTARGETTAG_PAGE(targettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    blkno);
 
    targettaghash = PredicateLockTargetTagHashCode(&targettag);
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
    LWLockAcquire(partitionLock, LW_SHARED);
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    &targettag, targettaghash,
                                    HASH_FIND, NULL);
    LWLockRelease(partitionLock);
 
    return (target != NULL);
}
 
 
/*
 * Check whether a particular lock is held by this transaction.
 *
 * Important note: this function may return false even if the lock is
 * being held, because it uses the local lock table which is not
 * updated if another transaction modifies our lock list (e.g. to
 * split an index page). It can also return true when a coarser
 * granularity lock that covers this target is being held. Be careful
 * to only use this function in circumstances where such errors are
 * acceptable!
 */
static bool
PredicateLockExists(const PREDICATELOCKTARGETTAG *targettag)
{
    LOCALPREDICATELOCK *lock;
 
    /* check local hash table */
    lock = (LOCALPREDICATELOCK *) hash_search(LocalPredicateLockHash,
                                              targettag,
                                              HASH_FIND, NULL);
 
    if (!lock)
        return false;
 
    /*
     * Found entry in the table, but still need to check whether it's actually
     * held -- it could just be a parent of some held lock.
     */
    return lock->held;
}
 
/*
 * Return the parent lock tag in the lock hierarchy: the next coarser
 * lock that covers the provided tag.
 *
 * Returns true and sets *parent to the parent tag if one exists,
 * returns false if none exists.
 */
static bool
GetParentPredicateLockTag(const PREDICATELOCKTARGETTAG *tag,
                          PREDICATELOCKTARGETTAG *parent)
{
    switch (GET_PREDICATELOCKTARGETTAG_TYPE(*tag))
    {
        case PREDLOCKTAG_RELATION:
            /* relation locks have no parent lock */
            return false;
 
        case PREDLOCKTAG_PAGE:
            /* parent lock is relation lock */
            SET_PREDICATELOCKTARGETTAG_RELATION(*parent,
                                                GET_PREDICATELOCKTARGETTAG_DB(*tag),
                                                GET_PREDICATELOCKTARGETTAG_RELATION(*tag));
 
            return true;
 
        case PREDLOCKTAG_TUPLE:
            /* parent lock is page lock */
            SET_PREDICATELOCKTARGETTAG_PAGE(*parent,
                                            GET_PREDICATELOCKTARGETTAG_DB(*tag),
                                            GET_PREDICATELOCKTARGETTAG_RELATION(*tag),
                                            GET_PREDICATELOCKTARGETTAG_PAGE(*tag));
            return true;
    }
 
    /* not reachable */
    Assert(false);
    return false;
}
 
/*
 * Check whether the lock we are considering is already covered by a
 * coarser lock for our transaction.
 *
 * Like PredicateLockExists, this function might return a false
 * negative, but it will never return a false positive.
 */
static bool
CoarserLockCovers(const PREDICATELOCKTARGETTAG *newtargettag)
{
    PREDICATELOCKTARGETTAG targettag,
                parenttag;
 
    targettag = *newtargettag;
 
    /* check parents iteratively until no more */
    while (GetParentPredicateLockTag(&targettag, &parenttag))
    {
        targettag = parenttag;
        if (PredicateLockExists(&targettag))
            return true;
    }
 
    /* no more parents to check; lock is not covered */
    return false;
}
 
/*
 * Remove the dummy entry from the predicate lock target hash, to free up some
 * scratch space. The caller must be holding SerializablePredicateListLock,
 * and must restore the entry with RestoreScratchTarget() before releasing the
 * lock.
 *
 * If lockheld is true, the caller is already holding the partition lock
 * of the partition containing the scratch entry.
 */
static void
RemoveScratchTarget(bool lockheld)
{
    bool        found;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    if (!lockheld)
        LWLockAcquire(ScratchPartitionLock, LW_EXCLUSIVE);
    hash_search_with_hash_value(PredicateLockTargetHash,
                                &ScratchTargetTag,
                                ScratchTargetTagHash,
                                HASH_REMOVE, &found);
    Assert(found);
    if (!lockheld)
        LWLockRelease(ScratchPartitionLock);
}
 
/*
 * Re-insert the dummy entry in predicate lock target hash.
 */
static void
RestoreScratchTarget(bool lockheld)
{
    bool        found;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    if (!lockheld)
        LWLockAcquire(ScratchPartitionLock, LW_EXCLUSIVE);
    hash_search_with_hash_value(PredicateLockTargetHash,
                                &ScratchTargetTag,
                                ScratchTargetTagHash,
                                HASH_ENTER, &found);
    Assert(!found);
    if (!lockheld)
        LWLockRelease(ScratchPartitionLock);
}
 
/*
 * Check whether the list of related predicate locks is empty for a
 * predicate lock target, and remove the target if it is.
 */
static void
RemoveTargetIfNoLongerUsed(PREDICATELOCKTARGET *target, uint32 targettaghash)
{
    PREDICATELOCKTARGET *rmtarget PG_USED_FOR_ASSERTS_ONLY;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    /* Can't remove it until no locks at this target. */
    if (!dlist_is_empty(&target->predicateLocks))
        return;
 
    /* Actually remove the target. */
    rmtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                           &target->tag,
                                           targettaghash,
                                           HASH_REMOVE, NULL);
    Assert(rmtarget == target);
}
 
/*
 * Delete child target locks owned by this process.
 * This implementation is assuming that the usage of each target tag field
 * is uniform.  No need to make this hard if we don't have to.
 *
 * We acquire an LWLock in the case of parallel mode, because worker
 * backends have access to the leader's SERIALIZABLEXACT.  Otherwise,
 * we aren't acquiring LWLocks for the predicate lock or lock
 * target structures associated with this transaction unless we're going
 * to modify them, because no other process is permitted to modify our
 * locks.
 */
static void
DeleteChildTargetLocks(const PREDICATELOCKTARGETTAG *newtargettag)
{
    SERIALIZABLEXACT *sxact;
    PREDICATELOCK *predlock;
    dlist_mutable_iter iter;
 
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    sxact = MySerializableXact;
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
 
    dlist_foreach_modify(iter, &sxact->predicateLocks)
    {
        PREDICATELOCKTAG oldlocktag;
        PREDICATELOCKTARGET *oldtarget;
        PREDICATELOCKTARGETTAG oldtargettag;
 
        predlock = dlist_container(PREDICATELOCK, xactLink, iter.cur);
 
        oldlocktag = predlock->tag;
        Assert(oldlocktag.myXact == sxact);
        oldtarget = oldlocktag.myTarget;
        oldtargettag = oldtarget->tag;
 
        if (TargetTagIsCoveredBy(oldtargettag, *newtargettag))
        {
            uint32      oldtargettaghash;
            LWLock     *partitionLock;
            PREDICATELOCK *rmpredlock PG_USED_FOR_ASSERTS_ONLY;
 
            oldtargettaghash = PredicateLockTargetTagHashCode(&oldtargettag);
            partitionLock = PredicateLockHashPartitionLock(oldtargettaghash);
 
            LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
            dlist_delete(&predlock->xactLink);
            dlist_delete(&predlock->targetLink);
            rmpredlock = hash_search_with_hash_value
                (PredicateLockHash,
                 &oldlocktag,
                 PredicateLockHashCodeFromTargetHashCode(&oldlocktag,
                                                         oldtargettaghash),
                 HASH_REMOVE, NULL);
            Assert(rmpredlock == predlock);
 
            RemoveTargetIfNoLongerUsed(oldtarget, oldtargettaghash);
 
            LWLockRelease(partitionLock);
 
            DecrementParentLocks(&oldtargettag);
        }
    }
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
}
 
/*
 * Returns the promotion limit for a given predicate lock target.  This is the
 * max number of descendant locks allowed before promoting to the specified
 * tag. Note that the limit includes non-direct descendants (e.g., both tuples
 * and pages for a relation lock).
 *
 * Currently the default limit is 2 for a page lock, and half of the value of
 * max_pred_locks_per_transaction - 1 for a relation lock, to match behavior
 * of earlier releases when upgrading.
 *
 * TODO SSI: We should probably add additional GUCs to allow a maximum ratio
 * of page and tuple locks based on the pages in a relation, and the maximum
 * ratio of tuple locks to tuples in a page.  This would provide more
 * generally "balanced" allocation of locks to where they are most useful,
 * while still allowing the absolute numbers to prevent one relation from
 * tying up all predicate lock resources.
 */
static int
MaxPredicateChildLocks(const PREDICATELOCKTARGETTAG *tag)
{
    switch (GET_PREDICATELOCKTARGETTAG_TYPE(*tag))
    {
        case PREDLOCKTAG_RELATION:
            return max_predicate_locks_per_relation < 0
                ? (max_predicate_locks_per_xact
                   / (-max_predicate_locks_per_relation)) - 1
                : max_predicate_locks_per_relation;
 
        case PREDLOCKTAG_PAGE:
            return max_predicate_locks_per_page;
 
        case PREDLOCKTAG_TUPLE:
 
            /*
             * not reachable: nothing is finer-granularity than a tuple, so we
             * should never try to promote to it.
             */
            Assert(false);
            return 0;
    }
 
    /* not reachable */
    Assert(false);
    return 0;
}
 
/*
 * For all ancestors of a newly-acquired predicate lock, increment
 * their child count in the parent hash table. If any of them have
 * more descendants than their promotion threshold, acquire the
 * coarsest such lock.
 *
 * Returns true if a parent lock was acquired and false otherwise.
 */
static bool
CheckAndPromotePredicateLockRequest(const PREDICATELOCKTARGETTAG *reqtag)
{
    PREDICATELOCKTARGETTAG targettag,
                nexttag,
                promotiontag;
    LOCALPREDICATELOCK *parentlock;
    bool        found,
                promote;
 
    promote = false;
 
    targettag = *reqtag;
 
    /* check parents iteratively */
    while (GetParentPredicateLockTag(&targettag, &nexttag))
    {
        targettag = nexttag;
        parentlock = (LOCALPREDICATELOCK *) hash_search(LocalPredicateLockHash,
                                                        &targettag,
                                                        HASH_ENTER,
                                                        &found);
        if (!found)
        {
            parentlock->held = false;
            parentlock->childLocks = 1;
        }
        else
            parentlock->childLocks++;
 
        if (parentlock->childLocks >
            MaxPredicateChildLocks(&targettag))
        {
            /*
             * We should promote to this parent lock. Continue to check its
             * ancestors, however, both to get their child counts right and to
             * check whether we should just go ahead and promote to one of
             * them.
             */
            promotiontag = targettag;
            promote = true;
        }
    }
 
    if (promote)
    {
        /* acquire coarsest ancestor eligible for promotion */
        PredicateLockAcquire(&promotiontag);
        return true;
    }
    else
        return false;
}
 
/*
 * When releasing a lock, decrement the child count on all ancestor
 * locks.
 *
 * This is called only when releasing a lock via
 * DeleteChildTargetLocks (i.e. when a lock becomes redundant because
 * we've acquired its parent, possibly due to promotion) or when a new
 * MVCC write lock makes the predicate lock unnecessary. There's no
 * point in calling it when locks are released at transaction end, as
 * this information is no longer needed.
 */
static void
DecrementParentLocks(const PREDICATELOCKTARGETTAG *targettag)
{
    PREDICATELOCKTARGETTAG parenttag,
                nexttag;
 
    parenttag = *targettag;
 
    while (GetParentPredicateLockTag(&parenttag, &nexttag))
    {
        uint32      targettaghash;
        LOCALPREDICATELOCK *parentlock,
                   *rmlock PG_USED_FOR_ASSERTS_ONLY;
 
        parenttag = nexttag;
        targettaghash = PredicateLockTargetTagHashCode(&parenttag);
        parentlock = (LOCALPREDICATELOCK *)
            hash_search_with_hash_value(LocalPredicateLockHash,
                                        &parenttag, targettaghash,
                                        HASH_FIND, NULL);
 
        /*
         * There's a small chance the parent lock doesn't exist in the lock
         * table. This can happen if we prematurely removed it because an
         * index split caused the child refcount to be off.
         */
        if (parentlock == NULL)
            continue;
 
        parentlock->childLocks--;
 
        /*
         * Under similar circumstances the parent lock's refcount might be
         * zero. This only happens if we're holding that lock (otherwise we
         * would have removed the entry).
         */
        if (parentlock->childLocks < 0)
        {
            Assert(parentlock->held);
            parentlock->childLocks = 0;
        }
 
        if ((parentlock->childLocks == 0) && (!parentlock->held))
        {
            rmlock = (LOCALPREDICATELOCK *)
                hash_search_with_hash_value(LocalPredicateLockHash,
                                            &parenttag, targettaghash,
                                            HASH_REMOVE, NULL);
            Assert(rmlock == parentlock);
        }
    }
}
 
/*
 * Indicate that a predicate lock on the given target is held by the
 * specified transaction. Has no effect if the lock is already held.
 *
 * This updates the lock table and the sxact's lock list, and creates
 * the lock target if necessary, but does *not* do anything related to
 * granularity promotion or the local lock table. See
 * PredicateLockAcquire for that.
 */
static void
CreatePredicateLock(const PREDICATELOCKTARGETTAG *targettag,
                    uint32 targettaghash,
                    SERIALIZABLEXACT *sxact)
{
    PREDICATELOCKTARGET *target;
    PREDICATELOCKTAG locktag;
    PREDICATELOCK *lock;
    LWLock     *partitionLock;
    bool        found;
 
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
    LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
    /* Make sure that the target is represented. */
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    targettag, targettaghash,
                                    HASH_ENTER_NULL, &found);
    if (!target)
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("out of shared memory"),
                 errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
    if (!found)
        dlist_init(&target->predicateLocks);
 
    /* We've got the sxact and target, make sure they're joined. */
    locktag.myTarget = target;
    locktag.myXact = sxact;
    lock = (PREDICATELOCK *)
        hash_search_with_hash_value(PredicateLockHash, &locktag,
                                    PredicateLockHashCodeFromTargetHashCode(&locktag, targettaghash),
                                    HASH_ENTER_NULL, &found);
    if (!lock)
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("out of shared memory"),
                 errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
 
    if (!found)
    {
        dlist_push_tail(&target->predicateLocks, &lock->targetLink);
        dlist_push_tail(&sxact->predicateLocks, &lock->xactLink);
        lock->commitSeqNo = InvalidSerCommitSeqNo;
    }
 
    LWLockRelease(partitionLock);
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
}
 
/*
 * Acquire a predicate lock on the specified target for the current
 * connection if not already held. This updates the local lock table
 * and uses it to implement granularity promotion. It will consolidate
 * multiple locks into a coarser lock if warranted, and will release
 * any finer-grained locks covered by the new one.
 */
static void
PredicateLockAcquire(const PREDICATELOCKTARGETTAG *targettag)
{
    uint32      targettaghash;
    bool        found;
    LOCALPREDICATELOCK *locallock;
 
    /* Do we have the lock already, or a covering lock? */
    if (PredicateLockExists(targettag))
        return;
 
    if (CoarserLockCovers(targettag))
        return;
 
    /* the same hash and LW lock apply to the lock target and the local lock. */
    targettaghash = PredicateLockTargetTagHashCode(targettag);
 
    /* Acquire lock in local table */
    locallock = (LOCALPREDICATELOCK *)
        hash_search_with_hash_value(LocalPredicateLockHash,
                                    targettag, targettaghash,
                                    HASH_ENTER, &found);
    locallock->held = true;
    if (!found)
        locallock->childLocks = 0;
 
    /* Actually create the lock */
    CreatePredicateLock(targettag, targettaghash, MySerializableXact);
 
    /*
     * Lock has been acquired. Check whether it should be promoted to a
     * coarser granularity, or whether there are finer-granularity locks to
     * clean up.
     */
    if (CheckAndPromotePredicateLockRequest(targettag))
    {
        /*
         * Lock request was promoted to a coarser-granularity lock, and that
         * lock was acquired. It will delete this lock and any of its
         * children, so we're done.
         */
    }
    else
    {
        /* Clean up any finer-granularity locks */
        if (GET_PREDICATELOCKTARGETTAG_TYPE(*targettag) != PREDLOCKTAG_TUPLE)
            DeleteChildTargetLocks(targettag);
    }
}
 
 
/*
 *      PredicateLockRelation
 *
 * Gets a predicate lock at the relation level.
 * Skip if not in full serializable transaction isolation level.
 * Skip if this is a temporary table.
 * Clear any finer-grained predicate locks this session has on the relation.
 */
void
PredicateLockRelation(Relation relation, Snapshot snapshot)
{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    SET_PREDICATELOCKTARGETTAG_RELATION(tag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    PredicateLockAcquire(&tag);
}
 
/*
 *      PredicateLockPage
 *
 * Gets a predicate lock at the page level.
 * Skip if not in full serializable transaction isolation level.
 * Skip if this is a temporary table.
 * Skip if a coarser predicate lock already covers this page.
 * Clear any finer-grained predicate locks this session has on the relation.
 */
void
PredicateLockPage(Relation relation, BlockNumber blkno, Snapshot snapshot)
{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    SET_PREDICATELOCKTARGETTAG_PAGE(tag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    blkno);
    PredicateLockAcquire(&tag);
}
 
/*
 *      PredicateLockTID
 *
 * Gets a predicate lock at the tuple level.
 * Skip if not in full serializable transaction isolation level.
 * Skip if this is a temporary table.
 */
void
PredicateLockTID(Relation relation, const ItemPointerData *tid, Snapshot snapshot,
                 TransactionId tuple_xid)
{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    /*
     * Return if this xact wrote it.
     */
    if (relation->rd_index == NULL)
    {
        /* If we wrote it; we already have a write lock. */
        if (TransactionIdIsCurrentTransactionId(tuple_xid))
            return;
    }
 
    /*
     * Do quick-but-not-definitive test for a relation lock first.  This will
     * never cause a return when the relation is *not* locked, but will
     * occasionally let the check continue when there really *is* a relation
     * level lock.
     */
    SET_PREDICATELOCKTARGETTAG_RELATION(tag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    if (PredicateLockExists(&tag))
        return;
 
    SET_PREDICATELOCKTARGETTAG_TUPLE(tag,
                                     relation->rd_locator.dbOid,
                                     relation->rd_id,
                                     ItemPointerGetBlockNumber(tid),
                                     ItemPointerGetOffsetNumber(tid));
    PredicateLockAcquire(&tag);
}
 
 
/*
 *      DeleteLockTarget
 *
 * Remove a predicate lock target along with any locks held for it.
 *
 * Caller must hold SerializablePredicateListLock and the
 * appropriate hash partition lock for the target.
 */
static void
DeleteLockTarget(PREDICATELOCKTARGET *target, uint32 targettaghash)
{
    dlist_mutable_iter iter;
 
    Assert(LWLockHeldByMeInMode(SerializablePredicateListLock,
                                LW_EXCLUSIVE));
    Assert(LWLockHeldByMe(PredicateLockHashPartitionLock(targettaghash)));
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    dlist_foreach_modify(iter, &target->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, targetLink, iter.cur);
        bool        found;
 
        dlist_delete(&(predlock->xactLink));
        dlist_delete(&(predlock->targetLink));
 
        hash_search_with_hash_value
            (PredicateLockHash,
             &predlock->tag,
             PredicateLockHashCodeFromTargetHashCode(&predlock->tag,
                                                     targettaghash),
             HASH_REMOVE, &found);
        Assert(found);
    }
    LWLockRelease(SerializableXactHashLock);
 
    /* Remove the target itself, if possible. */
    RemoveTargetIfNoLongerUsed(target, targettaghash);
}
 
 
/*
 *      TransferPredicateLocksToNewTarget
 *
 * Move or copy all the predicate locks for a lock target, for use by
 * index page splits/combines and other things that create or replace
 * lock targets. If 'removeOld' is true, the old locks and the target
 * will be removed.
 *
 * Returns true on success, or false if we ran out of shared memory to
 * allocate the new target or locks. Guaranteed to always succeed if
 * removeOld is set (by using the scratch entry in PredicateLockTargetHash
 * for scratch space).
 *
 * Warning: the "removeOld" option should be used only with care,
 * because this function does not (indeed, can not) update other
 * backends' LocalPredicateLockHash. If we are only adding new
 * entries, this is not a problem: the local lock table is used only
 * as a hint, so missing entries for locks that are held are
 * OK. Having entries for locks that are no longer held, as can happen
 * when using "removeOld", is not in general OK. We can only use it
 * safely when replacing a lock with a coarser-granularity lock that
 * covers it, or if we are absolutely certain that no one will need to
 * refer to that lock in the future.
 *
 * Caller must hold SerializablePredicateListLock exclusively.
 */
static bool
TransferPredicateLocksToNewTarget(PREDICATELOCKTARGETTAG oldtargettag,
                                  PREDICATELOCKTARGETTAG newtargettag,
                                  bool removeOld)
{
    uint32      oldtargettaghash;
    LWLock     *oldpartitionLock;
    PREDICATELOCKTARGET *oldtarget;
    uint32      newtargettaghash;
    LWLock     *newpartitionLock;
    bool        found;
    bool        outOfShmem = false;
 
    Assert(LWLockHeldByMeInMode(SerializablePredicateListLock,
                                LW_EXCLUSIVE));
 
    oldtargettaghash = PredicateLockTargetTagHashCode(&oldtargettag);
    newtargettaghash = PredicateLockTargetTagHashCode(&newtargettag);
    oldpartitionLock = PredicateLockHashPartitionLock(oldtargettaghash);
    newpartitionLock = PredicateLockHashPartitionLock(newtargettaghash);
 
    if (removeOld)
    {
        /*
         * Remove the dummy entry to give us scratch space, so we know we'll
         * be able to create the new lock target.
         */
        RemoveScratchTarget(false);
    }
 
    /*
     * We must get the partition locks in ascending sequence to avoid
     * deadlocks. If old and new partitions are the same, we must request the
     * lock only once.
     */
    if (oldpartitionLock < newpartitionLock)
    {
        LWLockAcquire(oldpartitionLock,
                      (removeOld ? LW_EXCLUSIVE : LW_SHARED));
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
    }
    else if (oldpartitionLock > newpartitionLock)
    {
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
        LWLockAcquire(oldpartitionLock,
                      (removeOld ? LW_EXCLUSIVE : LW_SHARED));
    }
    else
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
 
    /*
     * Look for the old target.  If not found, that's OK; no predicate locks
     * are affected, so we can just clean up and return. If it does exist,
     * walk its list of predicate locks and move or copy them to the new
     * target.
     */
    oldtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                            &oldtargettag,
                                            oldtargettaghash,
                                            HASH_FIND, NULL);
 
    if (oldtarget)
    {
        PREDICATELOCKTARGET *newtarget;
        PREDICATELOCKTAG newpredlocktag;
        dlist_mutable_iter iter;
 
        newtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                                &newtargettag,
                                                newtargettaghash,
                                                HASH_ENTER_NULL, &found);
 
        if (!newtarget)
        {
            /* Failed to allocate due to insufficient shmem */
            outOfShmem = true;
            goto exit;
        }
 
        /* If we created a new entry, initialize it */
        if (!found)
            dlist_init(&newtarget->predicateLocks);
 
        newpredlocktag.myTarget = newtarget;
 
        /*
         * Loop through all the locks on the old target, replacing them with
         * locks on the new target.
         */
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        dlist_foreach_modify(iter, &oldtarget->predicateLocks)
        {
            PREDICATELOCK *oldpredlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
            PREDICATELOCK *newpredlock;
            SerCommitSeqNo oldCommitSeqNo = oldpredlock->commitSeqNo;
 
            newpredlocktag.myXact = oldpredlock->tag.myXact;
 
            if (removeOld)
            {
                dlist_delete(&(oldpredlock->xactLink));
                dlist_delete(&(oldpredlock->targetLink));
 
                hash_search_with_hash_value
                    (PredicateLockHash,
                     &oldpredlock->tag,
                     PredicateLockHashCodeFromTargetHashCode(&oldpredlock->tag,
                                                             oldtargettaghash),
                     HASH_REMOVE, &found);
                Assert(found);
            }
 
            newpredlock = (PREDICATELOCK *)
                hash_search_with_hash_value(PredicateLockHash,
                                            &newpredlocktag,
                                            PredicateLockHashCodeFromTargetHashCode(&newpredlocktag,
                                                                                    newtargettaghash),
                                            HASH_ENTER_NULL,
                                            &found);
            if (!newpredlock)
            {
                /* Out of shared memory. Undo what we've done so far. */
                LWLockRelease(SerializableXactHashLock);
                DeleteLockTarget(newtarget, newtargettaghash);
                outOfShmem = true;
                goto exit;
            }
            if (!found)
            {
                dlist_push_tail(&(newtarget->predicateLocks),
                                &(newpredlock->targetLink));
                dlist_push_tail(&(newpredlocktag.myXact->predicateLocks),
                                &(newpredlock->xactLink));
                newpredlock->commitSeqNo = oldCommitSeqNo;
            }
            else
            {
                if (newpredlock->commitSeqNo < oldCommitSeqNo)
                    newpredlock->commitSeqNo = oldCommitSeqNo;
            }
 
            Assert(newpredlock->commitSeqNo != 0);
            Assert((newpredlock->commitSeqNo == InvalidSerCommitSeqNo)
                   || (newpredlock->tag.myXact == OldCommittedSxact));
        }
        LWLockRelease(SerializableXactHashLock);
 
        if (removeOld)
        {
            Assert(dlist_is_empty(&oldtarget->predicateLocks));
            RemoveTargetIfNoLongerUsed(oldtarget, oldtargettaghash);
        }
    }
 
 
exit:
    /* Release partition locks in reverse order of acquisition. */
    if (oldpartitionLock < newpartitionLock)
    {
        LWLockRelease(newpartitionLock);
        LWLockRelease(oldpartitionLock);
    }
    else if (oldpartitionLock > newpartitionLock)
    {
        LWLockRelease(oldpartitionLock);
        LWLockRelease(newpartitionLock);
    }
    else
        LWLockRelease(newpartitionLock);
 
    if (removeOld)
    {
        /* We shouldn't run out of memory if we're moving locks */
        Assert(!outOfShmem);
 
        /* Put the scratch entry back */
        RestoreScratchTarget(false);
    }
 
    return !outOfShmem;
}
 
/*
 * Drop all predicate locks of any granularity from the specified relation,
 * which can be a heap relation or an index relation.  If 'transfer' is true,
 * acquire a relation lock on the heap for any transactions with any lock(s)
 * on the specified relation.
 *
 * This requires grabbing a lot of LW locks and scanning the entire lock
 * target table for matches.  That makes this more expensive than most
 * predicate lock management functions, but it will only be called for DDL
 * type commands that are expensive anyway, and there are fast returns when
 * no serializable transactions are active or the relation is temporary.
 *
 * We don't use the TransferPredicateLocksToNewTarget function because it
 * acquires its own locks on the partitions of the two targets involved,
 * and we'll already be holding all partition locks.
 *
 * We can't throw an error from here, because the call could be from a
 * transaction which is not serializable.
 *
 * NOTE: This is currently only called with transfer set to true, but that may
 * change.  If we decide to clean up the locks from a table on commit of a
 * transaction which executed DROP TABLE, the false condition will be useful.
 */
static void
DropAllPredicateLocksFromTable(Relation relation, bool transfer)
{
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCKTARGET *oldtarget;
    PREDICATELOCKTARGET *heaptarget;
    Oid         dbId;
    Oid         relId;
    Oid         heapId;
    int         i;
    bool        isIndex;
    bool        found;
    uint32      heaptargettaghash;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     * It's safe to check this without taking locks because the caller is
     * holding an ACCESS EXCLUSIVE lock on the relation.  No new locks which
     * would matter here can be acquired while that is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!PredicateLockingNeededForRelation(relation))
        return;
 
    dbId = relation->rd_locator.dbOid;
    relId = relation->rd_id;
    if (relation->rd_index == NULL)
    {
        isIndex = false;
        heapId = relId;
    }
    else
    {
        isIndex = true;
        heapId = relation->rd_index->indrelid;
    }
    Assert(heapId != InvalidOid);
    Assert(transfer || !isIndex);   /* index OID only makes sense with
                                     * transfer */
 
    /* Retrieve first time needed, then keep. */
    heaptargettaghash = 0;
    heaptarget = NULL;
 
    /* Acquire locks on all lock partitions */
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_EXCLUSIVE);
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * Remove the dummy entry to give us scratch space, so we know we'll be
     * able to create the new lock target.
     */
    if (transfer)
        RemoveScratchTarget(true);
 
    /* Scan through target map */
    hash_seq_init(&seqstat, PredicateLockTargetHash);
 
    while ((oldtarget = (PREDICATELOCKTARGET *) hash_seq_search(&seqstat)))
    {
        dlist_mutable_iter iter;
 
        /*
         * Check whether this is a target which needs attention.
         */
        if (GET_PREDICATELOCKTARGETTAG_RELATION(oldtarget->tag) != relId)
            continue;           /* wrong relation id */
        if (GET_PREDICATELOCKTARGETTAG_DB(oldtarget->tag) != dbId)
            continue;           /* wrong database id */
        if (transfer && !isIndex
            && GET_PREDICATELOCKTARGETTAG_TYPE(oldtarget->tag) == PREDLOCKTAG_RELATION)
            continue;           /* already the right lock */
 
        /*
         * If we made it here, we have work to do.  We make sure the heap
         * relation lock exists, then we walk the list of predicate locks for
         * the old target we found, moving all locks to the heap relation lock
         * -- unless they already hold that.
         */
 
        /*
         * First make sure we have the heap relation target.  We only need to
         * do this once.
         */
        if (transfer && heaptarget == NULL)
        {
            PREDICATELOCKTARGETTAG heaptargettag;
 
            SET_PREDICATELOCKTARGETTAG_RELATION(heaptargettag, dbId, heapId);
            heaptargettaghash = PredicateLockTargetTagHashCode(&heaptargettag);
            heaptarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                                     &heaptargettag,
                                                     heaptargettaghash,
                                                     HASH_ENTER, &found);
            if (!found)
                dlist_init(&heaptarget->predicateLocks);
        }
 
        /*
         * Loop through all the locks on the old target, replacing them with
         * locks on the new target.
         */
        dlist_foreach_modify(iter, &oldtarget->predicateLocks)
        {
            PREDICATELOCK *oldpredlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
            PREDICATELOCK *newpredlock;
            SerCommitSeqNo oldCommitSeqNo;
            SERIALIZABLEXACT *oldXact;
 
            /*
             * Remove the old lock first. This avoids the chance of running
             * out of lock structure entries for the hash table.
             */
            oldCommitSeqNo = oldpredlock->commitSeqNo;
            oldXact = oldpredlock->tag.myXact;
 
            dlist_delete(&(oldpredlock->xactLink));
 
            /*
             * No need for retail delete from oldtarget list, we're removing
             * the whole target anyway.
             */
            hash_search(PredicateLockHash,
                        &oldpredlock->tag,
                        HASH_REMOVE, &found);
            Assert(found);
 
            if (transfer)
            {
                PREDICATELOCKTAG newpredlocktag;
 
                newpredlocktag.myTarget = heaptarget;
                newpredlocktag.myXact = oldXact;
                newpredlock = (PREDICATELOCK *)
                    hash_search_with_hash_value(PredicateLockHash,
                                                &newpredlocktag,
                                                PredicateLockHashCodeFromTargetHashCode(&newpredlocktag,
                                                                                        heaptargettaghash),
                                                HASH_ENTER,
                                                &found);
                if (!found)
                {
                    dlist_push_tail(&(heaptarget->predicateLocks),
                                    &(newpredlock->targetLink));
                    dlist_push_tail(&(newpredlocktag.myXact->predicateLocks),
                                    &(newpredlock->xactLink));
                    newpredlock->commitSeqNo = oldCommitSeqNo;
                }
                else
                {
                    if (newpredlock->commitSeqNo < oldCommitSeqNo)
                        newpredlock->commitSeqNo = oldCommitSeqNo;
                }
 
                Assert(newpredlock->commitSeqNo != 0);
                Assert((newpredlock->commitSeqNo == InvalidSerCommitSeqNo)
                       || (newpredlock->tag.myXact == OldCommittedSxact));
            }
        }
 
        hash_search(PredicateLockTargetHash, &oldtarget->tag, HASH_REMOVE,
                    &found);
        Assert(found);
    }
 
    /* Put the scratch entry back */
    if (transfer)
        RestoreScratchTarget(true);
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
    LWLockRelease(SerializablePredicateListLock);
}
 
/*
 * TransferPredicateLocksToHeapRelation
 *      For all transactions, transfer all predicate locks for the given
 *      relation to a single relation lock on the heap.
 */
void
TransferPredicateLocksToHeapRelation(Relation relation)
{
    DropAllPredicateLocksFromTable(relation, true);
}
 
 
/*
 *      PredicateLockPageSplit
 *
 * Copies any predicate locks for the old page to the new page.
 * Skip if this is a temporary table or toast table.
 *
 * NOTE: A page split (or overflow) affects all serializable transactions,
 * even if it occurs in the context of another transaction isolation level.
 *
 * NOTE: This currently leaves the local copy of the locks without
 * information on the new lock which is in shared memory.  This could cause
 * problems if enough page splits occur on locked pages without the processes
 * which hold the locks getting in and noticing.
 */
void
PredicateLockPageSplit(Relation relation, BlockNumber oldblkno,
                       BlockNumber newblkno)
{
    PREDICATELOCKTARGETTAG oldtargettag;
    PREDICATELOCKTARGETTAG newtargettag;
    bool        success;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     *
     * It's safe to do this check without taking any additional locks. Even if
     * a serializable transaction starts concurrently, we know it can't take
     * any SIREAD locks on the page being split because the caller is holding
     * the associated buffer page lock. Memory reordering isn't an issue; the
     * memory barrier in the LWLock acquisition guarantees that this read
     * occurs while the buffer page lock is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!PredicateLockingNeededForRelation(relation))
        return;
 
    Assert(oldblkno != newblkno);
    Assert(BlockNumberIsValid(oldblkno));
    Assert(BlockNumberIsValid(newblkno));
 
    SET_PREDICATELOCKTARGETTAG_PAGE(oldtargettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    oldblkno);
    SET_PREDICATELOCKTARGETTAG_PAGE(newtargettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    newblkno);
 
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
 
    /*
     * Try copying the locks over to the new page's tag, creating it if
     * necessary.
     */
    success = TransferPredicateLocksToNewTarget(oldtargettag,
                                                newtargettag,
                                                false);
 
    if (!success)
    {
        /*
         * No more predicate lock entries are available. Failure isn't an
         * option here, so promote the page lock to a relation lock.
         */
 
        /* Get the parent relation lock's lock tag */
        success = GetParentPredicateLockTag(&oldtargettag,
                                            &newtargettag);
        Assert(success);
 
        /*
         * Move the locks to the parent. This shouldn't fail.
         *
         * Note that here we are removing locks held by other backends,
         * leading to a possible inconsistency in their local lock hash table.
         * This is OK because we're replacing it with a lock that covers the
         * old one.
         */
        success = TransferPredicateLocksToNewTarget(oldtargettag,
                                                    newtargettag,
                                                    true);
        Assert(success);
    }
 
    LWLockRelease(SerializablePredicateListLock);
}
 
/*
 *      PredicateLockPageCombine
 *
 * Combines predicate locks for two existing pages.
 * Skip if this is a temporary table or toast table.
 *
 * NOTE: A page combine affects all serializable transactions, even if it
 * occurs in the context of another transaction isolation level.
 */
void
PredicateLockPageCombine(Relation relation, BlockNumber oldblkno,
                         BlockNumber newblkno)
{
    /*
     * Page combines differ from page splits in that we ought to be able to
     * remove the locks on the old page after transferring them to the new
     * page, instead of duplicating them. However, because we can't edit other
     * backends' local lock tables, removing the old lock would leave them
     * with an entry in their LocalPredicateLockHash for a lock they're not
     * holding, which isn't acceptable. So we wind up having to do the same
     * work as a page split, acquiring a lock on the new page and keeping the
     * old page locked too. That can lead to some false positives, but should
     * be rare in practice.
     */
    PredicateLockPageSplit(relation, oldblkno, newblkno);
}
 
/*
 * Walk the list of in-progress serializable transactions and find the new
 * xmin.
 */
static void
SetNewSxactGlobalXmin(void)
{
    dlist_iter  iter;
 
    Assert(LWLockHeldByMe(SerializableXactHashLock));
 
    PredXact->SxactGlobalXmin = InvalidTransactionId;
    PredXact->SxactGlobalXminCount = 0;
 
    dlist_foreach(iter, &PredXact->activeList)
    {
        SERIALIZABLEXACT *sxact =
            dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
        if (!SxactIsRolledBack(sxact)
            && !SxactIsCommitted(sxact)
            && sxact != OldCommittedSxact)
        {
            Assert(sxact->xmin != InvalidTransactionId);
            if (!TransactionIdIsValid(PredXact->SxactGlobalXmin)
                || TransactionIdPrecedes(sxact->xmin,
                                         PredXact->SxactGlobalXmin))
            {
                PredXact->SxactGlobalXmin = sxact->xmin;
                PredXact->SxactGlobalXminCount = 1;
            }
            else if (TransactionIdEquals(sxact->xmin,
                                         PredXact->SxactGlobalXmin))
                PredXact->SxactGlobalXminCount++;
        }
    }
 
    SerialSetActiveSerXmin(PredXact->SxactGlobalXmin);
}
 
/*
 *      ReleasePredicateLocks
 *
 * Releases predicate locks based on completion of the current transaction,
 * whether committed or rolled back.  It can also be called for a read only
 * transaction when it becomes impossible for the transaction to become
 * part of a dangerous structure.
 *
 * We do nothing unless this is a serializable transaction.
 *
 * This method must ensure that shared memory hash tables are cleaned
 * up in some relatively timely fashion.
 *
 * If this transaction is committing and is holding any predicate locks,
 * it must be added to a list of completed serializable transactions still
 * holding locks.
 *
 * If isReadOnlySafe is true, then predicate locks are being released before
 * the end of the transaction because MySerializableXact has been determined
 * to be RO_SAFE.  In non-parallel mode we can release it completely, but it
 * in parallel mode we partially release the SERIALIZABLEXACT and keep it
 * around until the end of the transaction, allowing each backend to clear its
 * MySerializableXact variable and benefit from the optimization in its own
 * time.
 */
void
ReleasePredicateLocks(bool isCommit, bool isReadOnlySafe)
{
    bool        partiallyReleasing = false;
    bool        needToClear;
    SERIALIZABLEXACT *roXact;
    dlist_mutable_iter iter;
 
    /*
     * We can't trust XactReadOnly here, because a transaction which started
     * as READ WRITE can show as READ ONLY later, e.g., within
     * subtransactions.  We want to flag a transaction as READ ONLY if it
     * commits without writing so that de facto READ ONLY transactions get the
     * benefit of some RO optimizations, so we will use this local variable to
     * get some cleanup logic right which is based on whether the transaction
     * was declared READ ONLY at the top level.
     */
    bool        topLevelIsDeclaredReadOnly;
 
    /* We can't be both committing and releasing early due to RO_SAFE. */
    Assert(!(isCommit && isReadOnlySafe));
 
    /* Are we at the end of a transaction, that is, a commit or abort? */
    if (!isReadOnlySafe)
    {
        /*
         * Parallel workers mustn't release predicate locks at the end of
         * their transaction.  The leader will do that at the end of its
         * transaction.
         */
        if (IsParallelWorker())
        {
            ReleasePredicateLocksLocal();
            return;
        }
 
        /*
         * By the time the leader in a parallel query reaches end of
         * transaction, it has waited for all workers to exit.
         */
        Assert(!ParallelContextActive());
 
        /*
         * If the leader in a parallel query earlier stashed a partially
         * released SERIALIZABLEXACT for final clean-up at end of transaction
         * (because workers might still have been accessing it), then it's
         * time to restore it.
         */
        if (SavedSerializableXact != InvalidSerializableXact)
        {
            Assert(MySerializableXact == InvalidSerializableXact);
            MySerializableXact = SavedSerializableXact;
            SavedSerializableXact = InvalidSerializableXact;
            Assert(SxactIsPartiallyReleased(MySerializableXact));
        }
    }
 
    if (MySerializableXact == InvalidSerializableXact)
    {
        Assert(LocalPredicateLockHash == NULL);
        return;
    }
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * If the transaction is committing, but it has been partially released
     * already, then treat this as a roll back.  It was marked as rolled back.
     */
    if (isCommit && SxactIsPartiallyReleased(MySerializableXact))
        isCommit = false;
 
    /*
     * If we're called in the middle of a transaction because we discovered
     * that the SXACT_FLAG_RO_SAFE flag was set, then we'll partially release
     * it (that is, release the predicate locks and conflicts, but not the
     * SERIALIZABLEXACT itself) if we're the first backend to have noticed.
     */
    if (isReadOnlySafe && IsInParallelMode())
    {
        /*
         * The leader needs to stash a pointer to it, so that it can
         * completely release it at end-of-transaction.
         */
        if (!IsParallelWorker())
            SavedSerializableXact = MySerializableXact;
 
        /*
         * The first backend to reach this condition will partially release
         * the SERIALIZABLEXACT.  All others will just clear their
         * backend-local state so that they stop doing SSI checks for the rest
         * of the transaction.
         */
        if (SxactIsPartiallyReleased(MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            ReleasePredicateLocksLocal();
            return;
        }
        else
        {
            MySerializableXact->flags |= SXACT_FLAG_PARTIALLY_RELEASED;
            partiallyReleasing = true;
            /* ... and proceed to perform the partial release below. */
        }
    }
    Assert(!isCommit || SxactIsPrepared(MySerializableXact));
    Assert(!isCommit || !SxactIsDoomed(MySerializableXact));
    Assert(!SxactIsCommitted(MySerializableXact));
    Assert(SxactIsPartiallyReleased(MySerializableXact)
           || !SxactIsRolledBack(MySerializableXact));
 
    /* may not be serializable during COMMIT/ROLLBACK PREPARED */
    Assert(MySerializableXact->pid == 0 || IsolationIsSerializable());
 
    /* We'd better not already be on the cleanup list. */
    Assert(!SxactIsOnFinishedList(MySerializableXact));
 
    topLevelIsDeclaredReadOnly = SxactIsReadOnly(MySerializableXact);
 
    /*
     * We don't hold XidGenLock lock here, assuming that TransactionId is
     * atomic!
     *
     * If this value is changing, we don't care that much whether we get the
     * old or new value -- it is just used to determine how far
     * SxactGlobalXmin must advance before this transaction can be fully
     * cleaned up.  The worst that could happen is we wait for one more
     * transaction to complete before freeing some RAM; correctness of visible
     * behavior is not affected.
     */
    MySerializableXact->finishedBefore = XidFromFullTransactionId(TransamVariables->nextXid);
 
    /*
     * If it's not a commit it's either a rollback or a read-only transaction
     * flagged SXACT_FLAG_RO_SAFE, and we can clear our locks immediately.
     */
    if (isCommit)
    {
        MySerializableXact->flags |= SXACT_FLAG_COMMITTED;
        MySerializableXact->commitSeqNo = ++(PredXact->LastSxactCommitSeqNo);
        /* Recognize implicit read-only transaction (commit without write). */
        if (!MyXactDidWrite)
            MySerializableXact->flags |= SXACT_FLAG_READ_ONLY;
    }
    else
    {
        /*
         * The DOOMED flag indicates that we intend to roll back this
         * transaction and so it should not cause serialization failures for
         * other transactions that conflict with it. Note that this flag might
         * already be set, if another backend marked this transaction for
         * abort.
         *
         * The ROLLED_BACK flag further indicates that ReleasePredicateLocks
         * has been called, and so the SerializableXact is eligible for
         * cleanup. This means it should not be considered when calculating
         * SxactGlobalXmin.
         */
        MySerializableXact->flags |= SXACT_FLAG_DOOMED;
        MySerializableXact->flags |= SXACT_FLAG_ROLLED_BACK;
 
        /*
         * If the transaction was previously prepared, but is now failing due
         * to a ROLLBACK PREPARED or (hopefully very rare) error after the
         * prepare, clear the prepared flag.  This simplifies conflict
         * checking.
         */
        MySerializableXact->flags &= ~SXACT_FLAG_PREPARED;
    }
 
    if (!topLevelIsDeclaredReadOnly)
    {
        Assert(PredXact->WritableSxactCount > 0);
        if (--(PredXact->WritableSxactCount) == 0)
        {
            /*
             * Release predicate locks and rw-conflicts in for all committed
             * transactions.  There are no longer any transactions which might
             * conflict with the locks and no chance for new transactions to
             * overlap.  Similarly, existing conflicts in can't cause pivots,
             * and any conflicts in which could have completed a dangerous
             * structure would already have caused a rollback, so any
             * remaining ones must be benign.
             */
            PredXact->CanPartialClearThrough = PredXact->LastSxactCommitSeqNo;
        }
    }
    else
    {
        /*
         * Read-only transactions: clear the list of transactions that might
         * make us unsafe. Note that we use 'inLink' for the iteration as
         * opposed to 'outLink' for the r/w xacts.
         */
        dlist_foreach_modify(iter, &MySerializableXact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, inLink, iter.cur);
 
            Assert(!SxactIsReadOnly(possibleUnsafeConflict->sxactOut));
            Assert(MySerializableXact == possibleUnsafeConflict->sxactIn);
 
            ReleaseRWConflict(possibleUnsafeConflict);
        }
    }
 
    /* Check for conflict out to old committed transactions. */
    if (isCommit
        && !SxactIsReadOnly(MySerializableXact)
        && SxactHasSummaryConflictOut(MySerializableXact))
    {
        /*
         * we don't know which old committed transaction we conflicted with,
         * so be conservative and use FirstNormalSerCommitSeqNo here
         */
        MySerializableXact->SeqNo.earliestOutConflictCommit =
            FirstNormalSerCommitSeqNo;
        MySerializableXact->flags |= SXACT_FLAG_CONFLICT_OUT;
    }
 
    /*
     * Release all outConflicts to committed transactions.  If we're rolling
     * back clear them all.  Set SXACT_FLAG_CONFLICT_OUT if any point to
     * previously committed transactions.
     */
    dlist_foreach_modify(iter, &MySerializableXact->outConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, outLink, iter.cur);
 
        if (isCommit
            && !SxactIsReadOnly(MySerializableXact)
            && SxactIsCommitted(conflict->sxactIn))
        {
            if ((MySerializableXact->flags & SXACT_FLAG_CONFLICT_OUT) == 0
                || conflict->sxactIn->prepareSeqNo < MySerializableXact->SeqNo.earliestOutConflictCommit)
                MySerializableXact->SeqNo.earliestOutConflictCommit = conflict->sxactIn->prepareSeqNo;
            MySerializableXact->flags |= SXACT_FLAG_CONFLICT_OUT;
        }
 
        if (!isCommit
            || SxactIsCommitted(conflict->sxactIn)
            || (conflict->sxactIn->SeqNo.lastCommitBeforeSnapshot >= PredXact->LastSxactCommitSeqNo))
            ReleaseRWConflict(conflict);
    }
 
    /*
     * Release all inConflicts from committed and read-only transactions. If
     * we're rolling back, clear them all.
     */
    dlist_foreach_modify(iter, &MySerializableXact->inConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        if (!isCommit
            || SxactIsCommitted(conflict->sxactOut)
            || SxactIsReadOnly(conflict->sxactOut))
            ReleaseRWConflict(conflict);
    }
 
    if (!topLevelIsDeclaredReadOnly)
    {
        /*
         * Remove ourselves from the list of possible conflicts for concurrent
         * READ ONLY transactions, flagging them as unsafe if we have a
         * conflict out. If any are waiting DEFERRABLE transactions, wake them
         * up if they are known safe or known unsafe.
         */
        dlist_foreach_modify(iter, &MySerializableXact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, outLink, iter.cur);
 
            roXact = possibleUnsafeConflict->sxactIn;
            Assert(MySerializableXact == possibleUnsafeConflict->sxactOut);
            Assert(SxactIsReadOnly(roXact));
 
            /* Mark conflicted if necessary. */
            if (isCommit
                && MyXactDidWrite
                && SxactHasConflictOut(MySerializableXact)
                && (MySerializableXact->SeqNo.earliestOutConflictCommit
                    <= roXact->SeqNo.lastCommitBeforeSnapshot))
            {
                /*
                 * This releases possibleUnsafeConflict (as well as all other
                 * possible conflicts for roXact)
                 */
                FlagSxactUnsafe(roXact);
            }
            else
            {
                ReleaseRWConflict(possibleUnsafeConflict);
 
                /*
                 * If we were the last possible conflict, flag it safe. The
                 * transaction can now safely release its predicate locks (but
                 * that transaction's backend has to do that itself).
                 */
                if (dlist_is_empty(&roXact->possibleUnsafeConflicts))
                    roXact->flags |= SXACT_FLAG_RO_SAFE;
            }
 
            /*
             * Wake up the process for a waiting DEFERRABLE transaction if we
             * now know it's either safe or conflicted.
             */
            if (SxactIsDeferrableWaiting(roXact) &&
                (SxactIsROUnsafe(roXact) || SxactIsROSafe(roXact)))
                ProcSendSignal(roXact->pgprocno);
        }
    }
 
    /*
     * Check whether it's time to clean up old transactions. This can only be
     * done when the last serializable transaction with the oldest xmin among
     * serializable transactions completes.  We then find the "new oldest"
     * xmin and purge any transactions which finished before this transaction
     * was launched.
     *
     * For parallel queries in read-only transactions, it might run twice. We
     * only release the reference on the first call.
     */
    needToClear = false;
    if ((partiallyReleasing ||
         !SxactIsPartiallyReleased(MySerializableXact)) &&
        TransactionIdEquals(MySerializableXact->xmin,
                            PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount > 0);
        if (--(PredXact->SxactGlobalXminCount) == 0)
        {
            SetNewSxactGlobalXmin();
            needToClear = true;
        }
    }
 
    LWLockRelease(SerializableXactHashLock);
 
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
 
    /* Add this to the list of transactions to check for later cleanup. */
    if (isCommit)
        dlist_push_tail(FinishedSerializableTransactions,
                        &MySerializableXact->finishedLink);
 
    /*
     * If we're releasing a RO_SAFE transaction in parallel mode, we'll only
     * partially release it.  That's necessary because other backends may have
     * a reference to it.  The leader will release the SERIALIZABLEXACT itself
     * at the end of the transaction after workers have stopped running.
     */
    if (!isCommit)
        ReleaseOneSerializableXact(MySerializableXact,
                                   isReadOnlySafe && IsInParallelMode(),
                                   false);
 
    LWLockRelease(SerializableFinishedListLock);
 
    if (needToClear)
        ClearOldPredicateLocks();
 
    ReleasePredicateLocksLocal();
}
 
static void
ReleasePredicateLocksLocal(void)
{
    MySerializableXact = InvalidSerializableXact;
    MyXactDidWrite = false;
 
    /* Delete per-transaction lock table */
    if (LocalPredicateLockHash != NULL)
    {
        hash_destroy(LocalPredicateLockHash);
        LocalPredicateLockHash = NULL;
    }
}
 
/*
 * Clear old predicate locks, belonging to committed transactions that are no
 * longer interesting to any in-progress transaction.
 */
static void
ClearOldPredicateLocks(void)
{
    dlist_mutable_iter iter;
 
    /*
     * Loop through finished transactions. They are in commit order, so we can
     * stop as soon as we find one that's still interesting.
     */
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
    dlist_foreach_modify(iter, FinishedSerializableTransactions)
    {
        SERIALIZABLEXACT *finishedSxact =
            dlist_container(SERIALIZABLEXACT, finishedLink, iter.cur);
 
        if (!TransactionIdIsValid(PredXact->SxactGlobalXmin)
            || TransactionIdPrecedesOrEquals(finishedSxact->finishedBefore,
                                             PredXact->SxactGlobalXmin))
        {
            /*
             * This transaction committed before any in-progress transaction
             * took its snapshot. It's no longer interesting.
             */
            LWLockRelease(SerializableXactHashLock);
            dlist_delete_thoroughly(&finishedSxact->finishedLink);
            ReleaseOneSerializableXact(finishedSxact, false, false);
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
        else if (finishedSxact->commitSeqNo > PredXact->HavePartialClearedThrough
                 && finishedSxact->commitSeqNo <= PredXact->CanPartialClearThrough)
        {
            /*
             * Any active transactions that took their snapshot before this
             * transaction committed are read-only, so we can clear part of
             * its state.
             */
            LWLockRelease(SerializableXactHashLock);
 
            if (SxactIsReadOnly(finishedSxact))
            {
                /* A read-only transaction can be removed entirely */
                dlist_delete_thoroughly(&(finishedSxact->finishedLink));
                ReleaseOneSerializableXact(finishedSxact, false, false);
            }
            else
            {
                /*
                 * A read-write transaction can only be partially cleared. We
                 * need to keep the SERIALIZABLEXACT but can release the
                 * SIREAD locks and conflicts in.
                 */
                ReleaseOneSerializableXact(finishedSxact, true, false);
            }
 
            PredXact->HavePartialClearedThrough = finishedSxact->commitSeqNo;
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
        else
        {
            /* Still interesting. */
            break;
        }
    }
    LWLockRelease(SerializableXactHashLock);
 
    /*
     * Loop through predicate locks on dummy transaction for summarized data.
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    dlist_foreach_modify(iter, &OldCommittedSxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
        bool        canDoPartialCleanup;
 
        LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        Assert(predlock->commitSeqNo != 0);
        Assert(predlock->commitSeqNo != InvalidSerCommitSeqNo);
        canDoPartialCleanup = (predlock->commitSeqNo <= PredXact->CanPartialClearThrough);
        LWLockRelease(SerializableXactHashLock);
 
        /*
         * If this lock originally belonged to an old enough transaction, we
         * can release it.
         */
        if (canDoPartialCleanup)
        {
            PREDICATELOCKTAG tag;
            PREDICATELOCKTARGET *target;
            PREDICATELOCKTARGETTAG targettag;
            uint32      targettaghash;
            LWLock     *partitionLock;
 
            tag = predlock->tag;
            target = tag.myTarget;
            targettag = target->tag;
            targettaghash = PredicateLockTargetTagHashCode(&targettag);
            partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
            LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
            dlist_delete(&(predlock->targetLink));
            dlist_delete(&(predlock->xactLink));
 
            hash_search_with_hash_value(PredicateLockHash, &tag,
                                        PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                                targettaghash),
                                        HASH_REMOVE, NULL);
            RemoveTargetIfNoLongerUsed(target, targettaghash);
 
            LWLockRelease(partitionLock);
        }
    }
 
    LWLockRelease(SerializablePredicateListLock);
    LWLockRelease(SerializableFinishedListLock);
}
 
/*
 * This is the normal way to delete anything from any of the predicate
 * locking hash tables.  Given a transaction which we know can be deleted:
 * delete all predicate locks held by that transaction and any predicate
 * lock targets which are now unreferenced by a lock; delete all conflicts
 * for the transaction; delete all xid values for the transaction; then
 * delete the transaction.
 *
 * When the partial flag is set, we can release all predicate locks and
 * in-conflict information -- we've established that there are no longer
 * any overlapping read write transactions for which this transaction could
 * matter -- but keep the transaction entry itself and any outConflicts.
 *
 * When the summarize flag is set, we've run short of room for sxact data
 * and must summarize to the SLRU.  Predicate locks are transferred to a
 * dummy "old" transaction, with duplicate locks on a single target
 * collapsing to a single lock with the "latest" commitSeqNo from among
 * the conflicting locks..
 */
static void
ReleaseOneSerializableXact(SERIALIZABLEXACT *sxact, bool partial,
                           bool summarize)
{
    SERIALIZABLEXIDTAG sxidtag;
    dlist_mutable_iter iter;
 
    Assert(sxact != NULL);
    Assert(SxactIsRolledBack(sxact) || SxactIsCommitted(sxact));
    Assert(partial || !SxactIsOnFinishedList(sxact));
    Assert(LWLockHeldByMe(SerializableFinishedListLock));
 
    /*
     * First release all the predicate locks held by this xact (or transfer
     * them to OldCommittedSxact if summarize is true)
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
    dlist_foreach_modify(iter, &sxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
        PREDICATELOCKTAG tag;
        PREDICATELOCKTARGET *target;
        PREDICATELOCKTARGETTAG targettag;
        uint32      targettaghash;
        LWLock     *partitionLock;
 
        tag = predlock->tag;
        target = tag.myTarget;
        targettag = target->tag;
        targettaghash = PredicateLockTargetTagHashCode(&targettag);
        partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
        LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
        dlist_delete(&predlock->targetLink);
 
        hash_search_with_hash_value(PredicateLockHash, &tag,
                                    PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                            targettaghash),
                                    HASH_REMOVE, NULL);
        if (summarize)
        {
            bool        found;
 
            /* Fold into dummy transaction list. */
            tag.myXact = OldCommittedSxact;
            predlock = hash_search_with_hash_value(PredicateLockHash, &tag,
                                                   PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                                           targettaghash),
                                                   HASH_ENTER_NULL, &found);
            if (!predlock)
                ereport(ERROR,
                        (errcode(ERRCODE_OUT_OF_MEMORY),
                         errmsg("out of shared memory"),
                         errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
            if (found)
            {
                Assert(predlock->commitSeqNo != 0);
                Assert(predlock->commitSeqNo != InvalidSerCommitSeqNo);
                if (predlock->commitSeqNo < sxact->commitSeqNo)
                    predlock->commitSeqNo = sxact->commitSeqNo;
            }
            else
            {
                dlist_push_tail(&target->predicateLocks,
                                &predlock->targetLink);
                dlist_push_tail(&OldCommittedSxact->predicateLocks,
                                &predlock->xactLink);
                predlock->commitSeqNo = sxact->commitSeqNo;
            }
        }
        else
            RemoveTargetIfNoLongerUsed(target, targettaghash);
 
        LWLockRelease(partitionLock);
    }
 
    /*
     * Rather than retail removal, just re-init the head after we've run
     * through the list.
     */
    dlist_init(&sxact->predicateLocks);
 
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
 
    sxidtag.xid = sxact->topXid;
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* Release all outConflicts (unless 'partial' is true) */
    if (!partial)
    {
        dlist_foreach_modify(iter, &sxact->outConflicts)
        {
            RWConflict  conflict =
                dlist_container(RWConflictData, outLink, iter.cur);
 
            if (summarize)
                conflict->sxactIn->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
            ReleaseRWConflict(conflict);
        }
    }
 
    /* Release all inConflicts. */
    dlist_foreach_modify(iter, &sxact->inConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        if (summarize)
            conflict->sxactOut->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
        ReleaseRWConflict(conflict);
    }
 
    /* Finally, get rid of the xid and the record of the transaction itself. */
    if (!partial)
    {
        if (sxidtag.xid != InvalidTransactionId)
            hash_search(SerializableXidHash, &sxidtag, HASH_REMOVE, NULL);
        ReleasePredXact(sxact);
    }
 
    LWLockRelease(SerializableXactHashLock);
}
 
/*
 * Tests whether the given top level transaction is concurrent with
 * (overlaps) our current transaction.
 *
 * We need to identify the top level transaction for SSI, anyway, so pass
 * that to this function to save the overhead of checking the snapshot's
 * subxip array.
 */
static bool
XidIsConcurrent(TransactionId xid)
{
    Snapshot    snap;
 
    Assert(TransactionIdIsValid(xid));
    Assert(!TransactionIdEquals(xid, GetTopTransactionIdIfAny()));
 
    snap = GetTransactionSnapshot();
 
    if (TransactionIdPrecedes(xid, snap->xmin))
        return false;
 
    if (TransactionIdFollowsOrEquals(xid, snap->xmax))
        return true;
 
    return pg_lfind32(xid, snap->xip, snap->xcnt);
}
 
bool
CheckForSerializableConflictOutNeeded(Relation relation, Snapshot snapshot)
{
    if (!SerializationNeededForRead(relation, snapshot))
        return false;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
    {
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict out checking."),
                 errhint("The transaction might succeed if retried.")));
    }
 
    return true;
}
 
/*
 * CheckForSerializableConflictOut
 *      A table AM is reading a tuple that has been modified.  If it determines
 *      that the tuple version it is reading is not visible to us, it should
 *      pass in the top level xid of the transaction that created it.
 *      Otherwise, if it determines that it is visible to us but it has been
 *      deleted or there is a newer version available due to an update, it
 *      should pass in the top level xid of the modifying transaction.
 *
 * This function will check for overlap with our own transaction.  If the given
 * xid is also serializable and the transactions overlap (i.e., they cannot see
 * each other's writes), then we have a conflict out.
 */
void
CheckForSerializableConflictOut(Relation relation, TransactionId xid, Snapshot snapshot)
{
    SERIALIZABLEXIDTAG sxidtag;
    SERIALIZABLEXID *sxid;
    SERIALIZABLEXACT *sxact;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
    {
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict out checking."),
                 errhint("The transaction might succeed if retried.")));
    }
    Assert(TransactionIdIsValid(xid));
 
    if (TransactionIdEquals(xid, GetTopTransactionIdIfAny()))
        return;
 
    /*
     * Find sxact or summarized info for the top level xid.
     */
    sxidtag.xid = xid;
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
    sxid = (SERIALIZABLEXID *)
        hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
    if (!sxid)
    {
        /*
         * Transaction not found in "normal" SSI structures.  Check whether it
         * got pushed out to SLRU storage for "old committed" transactions.
         */
        SerCommitSeqNo conflictCommitSeqNo;
 
        conflictCommitSeqNo = SerialGetMinConflictCommitSeqNo(xid);
        if (conflictCommitSeqNo != 0)
        {
            if (conflictCommitSeqNo != InvalidSerCommitSeqNo
                && (!SxactIsReadOnly(MySerializableXact)
                    || conflictCommitSeqNo
                    <= MySerializableXact->SeqNo.lastCommitBeforeSnapshot))
                ereport(ERROR,
                        (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                         errmsg("could not serialize access due to read/write dependencies among transactions"),
                         errdetail_internal("Reason code: Canceled on conflict out to old pivot %u.", xid),
                         errhint("The transaction might succeed if retried.")));
 
            if (SxactHasSummaryConflictIn(MySerializableXact)
                || !dlist_is_empty(&MySerializableXact->inConflicts))
                ereport(ERROR,
                        (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                         errmsg("could not serialize access due to read/write dependencies among transactions"),
                         errdetail_internal("Reason code: Canceled on identification as a pivot, with conflict out to old committed transaction %u.", xid),
                         errhint("The transaction might succeed if retried.")));
 
            MySerializableXact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
        }
 
        /* It's not serializable or otherwise not important. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
    sxact = sxid->myXact;
    Assert(TransactionIdEquals(sxact->topXid, xid));
    if (sxact == MySerializableXact || SxactIsDoomed(sxact))
    {
        /* Can't conflict with ourself or a transaction that will roll back. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    /*
     * We have a conflict out to a transaction which has a conflict out to a
     * summarized transaction.  That summarized transaction must have
     * committed first, and we can't tell when it committed in relation to our
     * snapshot acquisition, so something needs to be canceled.
     */
    if (SxactHasSummaryConflictOut(sxact))
    {
        if (!SxactIsPrepared(sxact))
        {
            sxact->flags |= SXACT_FLAG_DOOMED;
            LWLockRelease(SerializableXactHashLock);
            return;
        }
        else
        {
            LWLockRelease(SerializableXactHashLock);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on conflict out to old pivot."),
                     errhint("The transaction might succeed if retried.")));
        }
    }
 
    /*
     * If this is a read-only transaction and the writing transaction has
     * committed, and it doesn't have a rw-conflict to a transaction which
     * committed before it, no conflict.
     */
    if (SxactIsReadOnly(MySerializableXact)
        && SxactIsCommitted(sxact)
        && !SxactHasSummaryConflictOut(sxact)
        && (!SxactHasConflictOut(sxact)
            || MySerializableXact->SeqNo.lastCommitBeforeSnapshot < sxact->SeqNo.earliestOutConflictCommit))
    {
        /* Read-only transaction will appear to run first.  No conflict. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    if (!XidIsConcurrent(xid))
    {
        /* This write was already in our snapshot; no conflict. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    if (RWConflictExists(MySerializableXact, sxact))
    {
        /* We don't want duplicate conflict records in the list. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    /*
     * Flag the conflict.  But first, if this conflict creates a dangerous
     * structure, ereport an error.
     */
    FlagRWConflict(MySerializableXact, sxact);
    LWLockRelease(SerializableXactHashLock);
}
 
/*
 * Check a particular target for rw-dependency conflict in. A subroutine of
 * CheckForSerializableConflictIn().
 */
static void
CheckTargetForConflictsIn(PREDICATELOCKTARGETTAG *targettag)
{
    uint32      targettaghash;
    LWLock     *partitionLock;
    PREDICATELOCKTARGET *target;
    PREDICATELOCK *mypredlock = NULL;
    PREDICATELOCKTAG mypredlocktag;
    dlist_mutable_iter iter;
 
    Assert(MySerializableXact != InvalidSerializableXact);
 
    /*
     * The same hash and LW lock apply to the lock target and the lock itself.
     */
    targettaghash = PredicateLockTargetTagHashCode(targettag);
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
    LWLockAcquire(partitionLock, LW_SHARED);
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    targettag, targettaghash,
                                    HASH_FIND, NULL);
    if (!target)
    {
        /* Nothing has this target locked; we're done here. */
        LWLockRelease(partitionLock);
        return;
    }
 
    /*
     * Each lock for an overlapping transaction represents a conflict: a
     * rw-dependency in to this transaction.
     */
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    dlist_foreach_modify(iter, &target->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, targetLink, iter.cur);
        SERIALIZABLEXACT *sxact = predlock->tag.myXact;
 
        if (sxact == MySerializableXact)
        {
            /*
             * If we're getting a write lock on a tuple, we don't need a
             * predicate (SIREAD) lock on the same tuple. We can safely remove
             * our SIREAD lock, but we'll defer doing so until after the loop
             * because that requires upgrading to an exclusive partition lock.
             *
             * We can't use this optimization within a subtransaction because
             * the subtransaction could roll back, and we would be left
             * without any lock at the top level.
             */
            if (!IsSubTransaction()
                && GET_PREDICATELOCKTARGETTAG_OFFSET(*targettag))
            {
                mypredlock = predlock;
                mypredlocktag = predlock->tag;
            }
        }
        else if (!SxactIsDoomed(sxact)
                 && (!SxactIsCommitted(sxact)
                     || TransactionIdPrecedes(GetTransactionSnapshot()->xmin,
                                              sxact->finishedBefore))
                 && !RWConflictExists(sxact, MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
            /*
             * Re-check after getting exclusive lock because the other
             * transaction may have flagged a conflict.
             */
            if (!SxactIsDoomed(sxact)
                && (!SxactIsCommitted(sxact)
                    || TransactionIdPrecedes(GetTransactionSnapshot()->xmin,
                                             sxact->finishedBefore))
                && !RWConflictExists(sxact, MySerializableXact))
            {
                FlagRWConflict(sxact, MySerializableXact);
            }
 
            LWLockRelease(SerializableXactHashLock);
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
    }
    LWLockRelease(SerializableXactHashLock);
    LWLockRelease(partitionLock);
 
    /*
     * If we found one of our own SIREAD locks to remove, remove it now.
     *
     * At this point our transaction already has a RowExclusiveLock on the
     * relation, so we are OK to drop the predicate lock on the tuple, if
     * found, without fearing that another write against the tuple will occur
     * before the MVCC information makes it to the buffer.
     */
    if (mypredlock != NULL)
    {
        uint32      predlockhashcode;
        PREDICATELOCK *rmpredlock;
 
        LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
        if (IsInParallelMode())
            LWLockAcquire(&MySerializableXact->perXactPredicateListLock, LW_EXCLUSIVE);
        LWLockAcquire(partitionLock, LW_EXCLUSIVE);
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        /*
         * Remove the predicate lock from shared memory, if it wasn't removed
         * while the locks were released.  One way that could happen is from
         * autovacuum cleaning up an index.
         */
        predlockhashcode = PredicateLockHashCodeFromTargetHashCode
            (&mypredlocktag, targettaghash);
        rmpredlock = (PREDICATELOCK *)
            hash_search_with_hash_value(PredicateLockHash,
                                        &mypredlocktag,
                                        predlockhashcode,
                                        HASH_FIND, NULL);
        if (rmpredlock != NULL)
        {
            Assert(rmpredlock == mypredlock);
 
            dlist_delete(&(mypredlock->targetLink));
            dlist_delete(&(mypredlock->xactLink));
 
            rmpredlock = (PREDICATELOCK *)
                hash_search_with_hash_value(PredicateLockHash,
                                            &mypredlocktag,
                                            predlockhashcode,
                                            HASH_REMOVE, NULL);
            Assert(rmpredlock == mypredlock);
 
            RemoveTargetIfNoLongerUsed(target, targettaghash);
        }
 
        LWLockRelease(SerializableXactHashLock);
        LWLockRelease(partitionLock);
        if (IsInParallelMode())
            LWLockRelease(&MySerializableXact->perXactPredicateListLock);
        LWLockRelease(SerializablePredicateListLock);
 
        if (rmpredlock != NULL)
        {
            /*
             * Remove entry in local lock table if it exists. It's OK if it
             * doesn't exist; that means the lock was transferred to a new
             * target by a different backend.
             */
            hash_search_with_hash_value(LocalPredicateLockHash,
                                        targettag, targettaghash,
                                        HASH_REMOVE, NULL);
 
            DecrementParentLocks(targettag);
        }
    }
}
 
/*
 * CheckForSerializableConflictIn
 *      We are writing the given tuple.  If that indicates a rw-conflict
 *      in from another serializable transaction, take appropriate action.
 *
 * Skip checking for any granularity for which a parameter is missing.
 *
 * A tuple update or delete is in conflict if we have a predicate lock
 * against the relation or page in which the tuple exists, or against the
 * tuple itself.
 */
void
CheckForSerializableConflictIn(Relation relation, const ItemPointerData *tid, BlockNumber blkno)
{
    PREDICATELOCKTARGETTAG targettag;
 
    if (!SerializationNeededForWrite(relation))
        return;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict in checking."),
                 errhint("The transaction might succeed if retried.")));
 
    /*
     * We're doing a write which might cause rw-conflicts now or later.
     * Memorize that fact.
     */
    MyXactDidWrite = true;
 
    /*
     * It is important that we check for locks from the finest granularity to
     * the coarsest granularity, so that granularity promotion doesn't cause
     * us to miss a lock.  The new (coarser) lock will be acquired before the
     * old (finer) locks are released.
     *
     * It is not possible to take and hold a lock across the checks for all
     * granularities because each target could be in a separate partition.
     */
    if (tid != NULL)
    {
        SET_PREDICATELOCKTARGETTAG_TUPLE(targettag,
                                         relation->rd_locator.dbOid,
                                         relation->rd_id,
                                         ItemPointerGetBlockNumber(tid),
                                         ItemPointerGetOffsetNumber(tid));
        CheckTargetForConflictsIn(&targettag);
    }
 
    if (blkno != InvalidBlockNumber)
    {
        SET_PREDICATELOCKTARGETTAG_PAGE(targettag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id,
                                        blkno);
        CheckTargetForConflictsIn(&targettag);
    }
 
    SET_PREDICATELOCKTARGETTAG_RELATION(targettag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    CheckTargetForConflictsIn(&targettag);
}
 
/*
 * CheckTableForSerializableConflictIn
 *      The entire table is going through a DDL-style logical mass delete
 *      like TRUNCATE or DROP TABLE.  If that causes a rw-conflict in from
 *      another serializable transaction, take appropriate action.
 *
 * While these operations do not operate entirely within the bounds of
 * snapshot isolation, they can occur inside a serializable transaction, and
 * will logically occur after any reads which saw rows which were destroyed
 * by these operations, so we do what we can to serialize properly under
 * SSI.
 *
 * The relation passed in must be a heap relation. Any predicate lock of any
 * granularity on the heap will cause a rw-conflict in to this transaction.
 * Predicate locks on indexes do not matter because they only exist to guard
 * against conflicting inserts into the index, and this is a mass *delete*.
 * When a table is truncated or dropped, the index will also be truncated
 * or dropped, and we'll deal with locks on the index when that happens.
 *
 * Dropping or truncating a table also needs to drop any existing predicate
 * locks on heap tuples or pages, because they're about to go away. This
 * should be done before altering the predicate locks because the transaction
 * could be rolled back because of a conflict, in which case the lock changes
 * are not needed. (At the moment, we don't actually bother to drop the
 * existing locks on a dropped or truncated table at the moment. That might
 * lead to some false positives, but it doesn't seem worth the trouble.)
 */
void
CheckTableForSerializableConflictIn(Relation relation)
{
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCKTARGET *target;
    Oid         dbId;
    Oid         heapId;
    int         i;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     * It's safe to check this without taking locks because the caller is
     * holding an ACCESS EXCLUSIVE lock on the relation.  No new locks which
     * would matter here can be acquired while that is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!SerializationNeededForWrite(relation))
        return;
 
    /*
     * We're doing a write which might cause rw-conflicts now or later.
     * Memorize that fact.
     */
    MyXactDidWrite = true;
 
    Assert(relation->rd_index == NULL); /* not an index relation */
 
    dbId = relation->rd_locator.dbOid;
    heapId = relation->rd_id;
 
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_SHARED);
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* Scan through target list */
    hash_seq_init(&seqstat, PredicateLockTargetHash);
 
    while ((target = (PREDICATELOCKTARGET *) hash_seq_search(&seqstat)))
    {
        dlist_mutable_iter iter;
 
        /*
         * Check whether this is a target which needs attention.
         */
        if (GET_PREDICATELOCKTARGETTAG_RELATION(target->tag) != heapId)
            continue;           /* wrong relation id */
        if (GET_PREDICATELOCKTARGETTAG_DB(target->tag) != dbId)
            continue;           /* wrong database id */
 
        /*
         * Loop through locks for this target and flag conflicts.
         */
        dlist_foreach_modify(iter, &target->predicateLocks)
        {
            PREDICATELOCK *predlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
 
            if (predlock->tag.myXact != MySerializableXact
                && !RWConflictExists(predlock->tag.myXact, MySerializableXact))
            {
                FlagRWConflict(predlock->tag.myXact, MySerializableXact);
            }
        }
    }
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
    LWLockRelease(SerializablePredicateListLock);
}
 
 
/*
 * Flag a rw-dependency between two serializable transactions.
 *
 * The caller is responsible for ensuring that we have a LW lock on
 * the transaction hash table.
 */
static void
FlagRWConflict(SERIALIZABLEXACT *reader, SERIALIZABLEXACT *writer)
{
    Assert(reader != writer);
 
    /* First, see if this conflict causes failure. */
    OnConflict_CheckForSerializationFailure(reader, writer);
 
    /* Actually do the conflict flagging. */
    if (reader == OldCommittedSxact)
        writer->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
    else if (writer == OldCommittedSxact)
        reader->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
    else
        SetRWConflict(reader, writer);
}
 
/*----------------------------------------------------------------------------
 * We are about to add a RW-edge to the dependency graph - check that we don't
 * introduce a dangerous structure by doing so, and abort one of the
 * transactions if so.
 *
 * A serialization failure can only occur if there is a dangerous structure
 * in the dependency graph:
 *
 *      Tin ------> Tpivot ------> Tout
 *            rw             rw
 *
 * Furthermore, Tout must commit first.
 *
 * One more optimization is that if Tin is declared READ ONLY (or commits
 * without writing), we can only have a problem if Tout committed before Tin
 * acquired its snapshot.
 *----------------------------------------------------------------------------
 */
static void
OnConflict_CheckForSerializationFailure(const SERIALIZABLEXACT *reader,
                                        SERIALIZABLEXACT *writer)
{
    bool        failure;
 
    Assert(LWLockHeldByMe(SerializableXactHashLock));
 
    failure = false;
 
    /*------------------------------------------------------------------------
     * Check for already-committed writer with rw-conflict out flagged
     * (conflict-flag on W means that T2 committed before W):
     *
     *      R ------> W ------> T2
     *          rw        rw
     *
     * That is a dangerous structure, so we must abort. (Since the writer
     * has already committed, we must be the reader)
     *------------------------------------------------------------------------
     */
    if (SxactIsCommitted(writer)
        && (SxactHasConflictOut(writer) || SxactHasSummaryConflictOut(writer)))
        failure = true;
 
    /*------------------------------------------------------------------------
     * Check whether the writer has become a pivot with an out-conflict
     * committed transaction (T2), and T2 committed first:
     *
     *      R ------> W ------> T2
     *          rw        rw
     *
     * Because T2 must've committed first, there is no anomaly if:
     * - the reader committed before T2
     * - the writer committed before T2
     * - the reader is a READ ONLY transaction and the reader was concurrent
     *   with T2 (= reader acquired its snapshot before T2 committed)
     *
     * We also handle the case that T2 is prepared but not yet committed
     * here. In that case T2 has already checked for conflicts, so if it
     * commits first, making the above conflict real, it's too late for it
     * to abort.
     *------------------------------------------------------------------------
     */
    if (!failure && SxactHasSummaryConflictOut(writer))
        failure = true;
    else if (!failure)
    {
        dlist_iter  iter;
 
        dlist_foreach(iter, &writer->outConflicts)
        {
            RWConflict  conflict =
                dlist_container(RWConflictData, outLink, iter.cur);
            SERIALIZABLEXACT *t2 = conflict->sxactIn;
 
            if (SxactIsPrepared(t2)
                && (!SxactIsCommitted(reader)
                    || t2->prepareSeqNo <= reader->commitSeqNo)
                && (!SxactIsCommitted(writer)
                    || t2->prepareSeqNo <= writer->commitSeqNo)
                && (!SxactIsReadOnly(reader)
                    || t2->prepareSeqNo <= reader->SeqNo.lastCommitBeforeSnapshot))
            {
                failure = true;
                break;
            }
        }
    }
 
    /*------------------------------------------------------------------------
     * Check whether the reader has become a pivot with a writer
     * that's committed (or prepared):
     *
     *      T0 ------> R ------> W
     *           rw        rw
     *
     * Because W must've committed first for an anomaly to occur, there is no
     * anomaly if:
     * - T0 committed before the writer
     * - T0 is READ ONLY, and overlaps the writer
     *------------------------------------------------------------------------
     */
    if (!failure && SxactIsPrepared(writer) && !SxactIsReadOnly(reader))
    {
        if (SxactHasSummaryConflictIn(reader))
        {
            failure = true;
        }
        else
        {
            dlist_iter  iter;
 
            /*
             * The unconstify is needed as we have no const version of
             * dlist_foreach().
             */
            dlist_foreach(iter, &unconstify(SERIALIZABLEXACT *, reader)->inConflicts)
            {
                const RWConflict conflict =
                    dlist_container(RWConflictData, inLink, iter.cur);
                const SERIALIZABLEXACT *t0 = conflict->sxactOut;
 
                if (!SxactIsDoomed(t0)
                    && (!SxactIsCommitted(t0)
                        || t0->commitSeqNo >= writer->prepareSeqNo)
                    && (!SxactIsReadOnly(t0)
                        || t0->SeqNo.lastCommitBeforeSnapshot >= writer->prepareSeqNo))
                {
                    failure = true;
                    break;
                }
            }
        }
    }
 
    if (failure)
    {
        /*
         * We have to kill a transaction to avoid a possible anomaly from
         * occurring. If the writer is us, we can just ereport() to cause a
         * transaction abort. Otherwise we flag the writer for termination,
         * causing it to abort when it tries to commit. However, if the writer
         * is a prepared transaction, already prepared, we can't abort it
         * anymore, so we have to kill the reader instead.
         */
        if (MySerializableXact == writer)
        {
            LWLockRelease(SerializableXactHashLock);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on identification as a pivot, during write."),
                     errhint("The transaction might succeed if retried.")));
        }
        else if (SxactIsPrepared(writer))
        {
            LWLockRelease(SerializableXactHashLock);
 
            /* if we're not the writer, we have to be the reader */
            Assert(MySerializableXact == reader);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on conflict out to pivot %u, during read.", writer->topXid),
                     errhint("The transaction might succeed if retried.")));
        }
        writer->flags |= SXACT_FLAG_DOOMED;
    }
}
 
/*
 * PreCommit_CheckForSerializationFailure
 *      Check for dangerous structures in a serializable transaction
 *      at commit.
 *
 * We're checking for a dangerous structure as each conflict is recorded.
 * The only way we could have a problem at commit is if this is the "out"
 * side of a pivot, and neither the "in" side nor the pivot has yet
 * committed.
 *
 * If a dangerous structure is found, the pivot (the near conflict) is
 * marked for death, because rolling back another transaction might mean
 * that we fail without ever making progress.  This transaction is
 * committing writes, so letting it commit ensures progress.  If we
 * canceled the far conflict, it might immediately fail again on retry.
 */
void
PreCommit_CheckForSerializationFailure(void)
{
    dlist_iter  near_iter;
 
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    Assert(IsolationIsSerializable());
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * Check if someone else has already decided that we need to die.  Since
     * we set our own DOOMED flag when partially releasing, ignore in that
     * case.
     */
    if (SxactIsDoomed(MySerializableXact) &&
        !SxactIsPartiallyReleased(MySerializableXact))
    {
        LWLockRelease(SerializableXactHashLock);
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during commit attempt."),
                 errhint("The transaction might succeed if retried.")));
    }
 
    dlist_foreach(near_iter, &MySerializableXact->inConflicts)
    {
        RWConflict  nearConflict =
            dlist_container(RWConflictData, inLink, near_iter.cur);
 
        if (!SxactIsCommitted(nearConflict->sxactOut)
            && !SxactIsDoomed(nearConflict->sxactOut))
        {
            dlist_iter  far_iter;
 
            dlist_foreach(far_iter, &nearConflict->sxactOut->inConflicts)
            {
                RWConflict  farConflict =
                    dlist_container(RWConflictData, inLink, far_iter.cur);
 
                if (farConflict->sxactOut == MySerializableXact
                    || (!SxactIsCommitted(farConflict->sxactOut)
                        && !SxactIsReadOnly(farConflict->sxactOut)
                        && !SxactIsDoomed(farConflict->sxactOut)))
                {
                    /*
                     * Normally, we kill the pivot transaction to make sure we
                     * make progress if the failing transaction is retried.
                     * However, we can't kill it if it's already prepared, so
                     * in that case we commit suicide instead.
                     */
                    if (SxactIsPrepared(nearConflict->sxactOut))
                    {
                        LWLockRelease(SerializableXactHashLock);
                        ereport(ERROR,
                                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                                 errdetail_internal("Reason code: Canceled on commit attempt with conflict in from prepared pivot."),
                                 errhint("The transaction might succeed if retried.")));
                    }
                    nearConflict->sxactOut->flags |= SXACT_FLAG_DOOMED;
                    break;
                }
            }
        }
    }
 
    MySerializableXact->prepareSeqNo = ++(PredXact->LastSxactCommitSeqNo);
    MySerializableXact->flags |= SXACT_FLAG_PREPARED;
 
    LWLockRelease(SerializableXactHashLock);
}
 
/*------------------------------------------------------------------------*/
 
/*
 * Two-phase commit support
 */
 
/*
 * AtPrepare_Locks
 *      Do the preparatory work for a PREPARE: make 2PC state file
 *      records for all predicate locks currently held.
 */
void
AtPrepare_PredicateLocks(void)
{
    SERIALIZABLEXACT *sxact;
    TwoPhasePredicateRecord record;
    TwoPhasePredicateXactRecord *xactRecord;
    TwoPhasePredicateLockRecord *lockRecord;
    dlist_iter  iter;
 
    sxact = MySerializableXact;
    xactRecord = &(record.data.xactRecord);
    lockRecord = &(record.data.lockRecord);
 
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    /* Generate an xact record for our SERIALIZABLEXACT */
    record.type = TWOPHASEPREDICATERECORD_XACT;
    xactRecord->xmin = MySerializableXact->xmin;
    xactRecord->flags = MySerializableXact->flags;
 
    /*
     * Note that we don't include the list of conflicts in our out in the
     * statefile, because new conflicts can be added even after the
     * transaction prepares. We'll just make a conservative assumption during
     * recovery instead.
     */
 
    RegisterTwoPhaseRecord(TWOPHASE_RM_PREDICATELOCK_ID, 0,
                           &record, sizeof(record));
 
    /*
     * Generate a lock record for each lock.
     *
     * To do this, we need to walk the predicate lock list in our sxact rather
     * than using the local predicate lock table because the latter is not
     * guaranteed to be accurate.
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
 
    /*
     * No need to take sxact->perXactPredicateListLock in parallel mode
     * because there cannot be any parallel workers running while we are
     * preparing a transaction.
     */
    Assert(!IsParallelWorker() && !ParallelContextActive());
 
    dlist_foreach(iter, &sxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
 
        record.type = TWOPHASEPREDICATERECORD_LOCK;
        lockRecord->target = predlock->tag.myTarget->tag;
 
        RegisterTwoPhaseRecord(TWOPHASE_RM_PREDICATELOCK_ID, 0,
                               &record, sizeof(record));
    }
 
    LWLockRelease(SerializablePredicateListLock);
}
 
/*
 * PostPrepare_Locks
 *      Clean up after successful PREPARE. Unlike the non-predicate
 *      lock manager, we do not need to transfer locks to a dummy
 *      PGPROC because our SERIALIZABLEXACT will stay around
 *      anyway. We only need to clean up our local state.
 */
void
PostPrepare_PredicateLocks(FullTransactionId fxid)
{
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    Assert(SxactIsPrepared(MySerializableXact));
 
    MySerializableXact->pid = 0;
    MySerializableXact->pgprocno = INVALID_PROC_NUMBER;
 
    hash_destroy(LocalPredicateLockHash);
    LocalPredicateLockHash = NULL;
 
    MySerializableXact = InvalidSerializableXact;
    MyXactDidWrite = false;
}
 
/*
 * PredicateLockTwoPhaseFinish
 *      Release a prepared transaction's predicate locks once it
 *      commits or aborts.
 */
void
PredicateLockTwoPhaseFinish(FullTransactionId fxid, bool isCommit)
{
    SERIALIZABLEXID *sxid;
    SERIALIZABLEXIDTAG sxidtag;
 
    sxidtag.xid = XidFromFullTransactionId(fxid);
 
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
    sxid = (SERIALIZABLEXID *)
        hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
    LWLockRelease(SerializableXactHashLock);
 
    /* xid will not be found if it wasn't a serializable transaction */
    if (sxid == NULL)
        return;
 
    /* Release its locks */
    MySerializableXact = sxid->myXact;
    MyXactDidWrite = true;      /* conservatively assume that we wrote
                                 * something */
    ReleasePredicateLocks(isCommit, false);
}
 
/*
 * Re-acquire a predicate lock belonging to a transaction that was prepared.
 */
void
predicatelock_twophase_recover(FullTransactionId fxid, uint16 info,
                               void *recdata, uint32 len)
{
    TwoPhasePredicateRecord *record;
    TransactionId xid = XidFromFullTransactionId(fxid);
 
    Assert(len == sizeof(TwoPhasePredicateRecord));
 
    record = (TwoPhasePredicateRecord *) recdata;
 
    Assert((record->type == TWOPHASEPREDICATERECORD_XACT) ||
           (record->type == TWOPHASEPREDICATERECORD_LOCK));
 
    if (record->type == TWOPHASEPREDICATERECORD_XACT)
    {
        /* Per-transaction record. Set up a SERIALIZABLEXACT. */
        TwoPhasePredicateXactRecord *xactRecord;
        SERIALIZABLEXACT *sxact;
        SERIALIZABLEXID *sxid;
        SERIALIZABLEXIDTAG sxidtag;
        bool        found;
 
        xactRecord = (TwoPhasePredicateXactRecord *) &record->data.xactRecord;
 
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        sxact = CreatePredXact();
        if (!sxact)
            ereport(ERROR,
                    (errcode(ERRCODE_OUT_OF_MEMORY),
                     errmsg("out of shared memory")));
 
        /* vxid for a prepared xact is INVALID_PROC_NUMBER/xid; no pid */
        sxact->vxid.procNumber = INVALID_PROC_NUMBER;
        sxact->vxid.localTransactionId = (LocalTransactionId) xid;
        sxact->pid = 0;
        sxact->pgprocno = INVALID_PROC_NUMBER;
 
        /* a prepared xact hasn't committed yet */
        sxact->prepareSeqNo = RecoverySerCommitSeqNo;
        sxact->commitSeqNo = InvalidSerCommitSeqNo;
        sxact->finishedBefore = InvalidTransactionId;
 
        sxact->SeqNo.lastCommitBeforeSnapshot = RecoverySerCommitSeqNo;
 
        /*
         * Don't need to track this; no transactions running at the time the
         * recovered xact started are still active, except possibly other
         * prepared xacts and we don't care whether those are RO_SAFE or not.
         */
        dlist_init(&(sxact->possibleUnsafeConflicts));
 
        dlist_init(&(sxact->predicateLocks));
        dlist_node_init(&sxact->finishedLink);
 
        sxact->topXid = xid;
        sxact->xmin = xactRecord->xmin;
        sxact->flags = xactRecord->flags;
        Assert(SxactIsPrepared(sxact));
        if (!SxactIsReadOnly(sxact))
        {
            ++(PredXact->WritableSxactCount);
            Assert(PredXact->WritableSxactCount <=
                   (MaxBackends + max_prepared_xacts));
        }
 
        /*
         * We don't know whether the transaction had any conflicts or not, so
         * we'll conservatively assume that it had both a conflict in and a
         * conflict out, and represent that with the summary conflict flags.
         */
        dlist_init(&(sxact->outConflicts));
        dlist_init(&(sxact->inConflicts));
        sxact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
        sxact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
 
        /* Register the transaction's xid */
        sxidtag.xid = xid;
        sxid = (SERIALIZABLEXID *) hash_search(SerializableXidHash,
                                               &sxidtag,
                                               HASH_ENTER, &found);
        Assert(sxid != NULL);
        Assert(!found);
        sxid->myXact = sxact;
 
        /*
         * Update global xmin. Note that this is a special case compared to
         * registering a normal transaction, because the global xmin might go
         * backwards. That's OK, because until recovery is over we're not
         * going to complete any transactions or create any non-prepared
         * transactions, so there's no danger of throwing away.
         */
        if ((!TransactionIdIsValid(PredXact->SxactGlobalXmin)) ||
            (TransactionIdFollows(PredXact->SxactGlobalXmin, sxact->xmin)))
        {
            PredXact->SxactGlobalXmin = sxact->xmin;
            PredXact->SxactGlobalXminCount = 1;
            SerialSetActiveSerXmin(sxact->xmin);
        }
        else if (TransactionIdEquals(sxact->xmin, PredXact->SxactGlobalXmin))
        {
            Assert(PredXact->SxactGlobalXminCount > 0);
            PredXact->SxactGlobalXminCount++;
        }
 
        LWLockRelease(SerializableXactHashLock);
    }
    else if (record->type == TWOPHASEPREDICATERECORD_LOCK)
    {
        /* Lock record. Recreate the PREDICATELOCK */
        TwoPhasePredicateLockRecord *lockRecord;
        SERIALIZABLEXID *sxid;
        SERIALIZABLEXACT *sxact;
        SERIALIZABLEXIDTAG sxidtag;
        uint32      targettaghash;
 
        lockRecord = (TwoPhasePredicateLockRecord *) &record->data.lockRecord;
        targettaghash = PredicateLockTargetTagHashCode(&lockRecord->target);
 
        LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        sxidtag.xid = xid;
        sxid = (SERIALIZABLEXID *)
            hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
        LWLockRelease(SerializableXactHashLock);
 
        Assert(sxid != NULL);
        sxact = sxid->myXact;
        Assert(sxact != InvalidSerializableXact);
 
        CreatePredicateLock(&lockRecord->target, targettaghash, sxact);
    }
}
 
/*
 * Prepare to share the current SERIALIZABLEXACT with parallel workers.
 * Return a handle object that can be used by AttachSerializableXact() in a
 * parallel worker.
 */
SerializableXactHandle
ShareSerializableXact(void)
{
    return MySerializableXact;
}
 
/*
 * Allow parallel workers to import the leader's SERIALIZABLEXACT.
 */
void
AttachSerializableXact(SerializableXactHandle handle)
{
 
    Assert(MySerializableXact == InvalidSerializableXact);
 
    MySerializableXact = (SERIALIZABLEXACT *) handle;
    if (MySerializableXact != InvalidSerializableXact)
        CreateLocalPredicateLockHash();
}

PredicateLockHashCodeFromTargetHashCode

#define PredicateLockHashCodeFromTargetHashCode	(		predicatelocktag,
			targethash
	)

Value:

    ((targethash) ^ ((uint32) PointerGetDatum((predicatelocktag)->myXact)) \
     << LOG2_NUM_PREDICATELOCK_PARTITIONS)

Definition at line 315 of file predicate.c.

PredicateLockHashPartition

#define PredicateLockHashPartition

(

hashcode

)

((hashcode) % NUM_PREDICATELOCK_PARTITIONS)

Definition at line 255 of file predicate.c.

PredicateLockHashPartitionLock

#define PredicateLockHashPartitionLock

(

hashcode

)

Value:

    (&MainLWLockArray[PREDICATELOCK_MANAGER_LWLOCK_OFFSET + \
		PredicateLockHashPartition(hashcode)].lock)

Definition at line 257 of file predicate.c.

PredicateLockHashPartitionLockByIndex

#define PredicateLockHashPartitionLockByIndex

(

i

)

(&MainLWLockArray[PREDICATELOCK_MANAGER_LWLOCK_OFFSET + (i)].lock)

Definition at line 260 of file predicate.c.

PredicateLockTargetTagHashCode

#define PredicateLockTargetTagHashCode

(

predicatelocktargettag

)

get_hash_value(PredicateLockTargetHash, predicatelocktargettag)

Definition at line 302 of file predicate.c.

SERIAL_ENTRIESPERPAGE

#define SERIAL_ENTRIESPERPAGE   (SERIAL_PAGESIZE / SERIAL_ENTRYSIZE)

Definition at line 332 of file predicate.c.

SERIAL_ENTRYSIZE

#define SERIAL_ENTRYSIZE   sizeof(SerCommitSeqNo)

Definition at line 331 of file predicate.c.

SERIAL_MAX_PAGE

#define SERIAL_MAX_PAGE   (MaxTransactionId / SERIAL_ENTRIESPERPAGE)

Definition at line 337 of file predicate.c.

SERIAL_PAGESIZE

#define SERIAL_PAGESIZE   BLCKSZ

Definition at line 330 of file predicate.c.

SerialNextPage

#define SerialNextPage

(

page

)

(((page) >= SERIAL_MAX_PAGE) ? 0 : (page) + 1)

Definition at line 339 of file predicate.c.

SerialPage

#define SerialPage

(

xid

)

(((uint32) (xid)) / SERIAL_ENTRIESPERPAGE)

Definition at line 345 of file predicate.c.

SerialSlruCtl

#define SerialSlruCtl   (&SerialSlruDesc)

Definition at line 328 of file predicate.c.

SerialValue

#define SerialValue	(		slotno,
			xid
	)

Value:

    (*((SerCommitSeqNo *) \
    (SerialSlruCtl->shared->page_buffer[slotno] + \
    ((((uint32) (xid)) % SERIAL_ENTRIESPERPAGE) * SERIAL_ENTRYSIZE))))

Definition at line 341 of file predicate.c.

SxactHasConflictOut

#define SxactHasConflictOut

(

sxact

)

(((sxact)->flags & SXACT_FLAG_CONFLICT_OUT) != 0)

Definition at line 288 of file predicate.c.

SxactHasSummaryConflictIn

#define SxactHasSummaryConflictIn

(

sxact

)

(((sxact)->flags & SXACT_FLAG_SUMMARY_CONFLICT_IN) != 0)

Definition at line 281 of file predicate.c.

SxactHasSummaryConflictOut

#define SxactHasSummaryConflictOut

(

sxact

)

(((sxact)->flags & SXACT_FLAG_SUMMARY_CONFLICT_OUT) != 0)

Definition at line 282 of file predicate.c.

SxactIsCommitted

#define SxactIsCommitted

(

sxact

)

(((sxact)->flags & SXACT_FLAG_COMMITTED) != 0)

Definition at line 276 of file predicate.c.

SxactIsDeferrableWaiting

#define SxactIsDeferrableWaiting

(

sxact

)

(((sxact)->flags & SXACT_FLAG_DEFERRABLE_WAITING) != 0)

Definition at line 289 of file predicate.c.

SxactIsDoomed

#define SxactIsDoomed

(

sxact

)

(((sxact)->flags & SXACT_FLAG_DOOMED) != 0)

Definition at line 279 of file predicate.c.

SxactIsOnFinishedList

#define SxactIsOnFinishedList

(

sxact

)

(!dlist_node_is_detached(&(sxact)->finishedLink))

Definition at line 266 of file predicate.c.

SxactIsPartiallyReleased

#define SxactIsPartiallyReleased

(

sxact

)

(((sxact)->flags & SXACT_FLAG_PARTIALLY_RELEASED) != 0)

Definition at line 292 of file predicate.c.

SxactIsPrepared

#define SxactIsPrepared

(

sxact

)

(((sxact)->flags & SXACT_FLAG_PREPARED) != 0)

Definition at line 277 of file predicate.c.

SxactIsReadOnly

#define SxactIsReadOnly

(

sxact

)

(((sxact)->flags & SXACT_FLAG_READ_ONLY) != 0)

Definition at line 280 of file predicate.c.

SxactIsRolledBack

#define SxactIsRolledBack

(

sxact

)

(((sxact)->flags & SXACT_FLAG_ROLLED_BACK) != 0)

Definition at line 278 of file predicate.c.

SxactIsROSafe

#define SxactIsROSafe

(

sxact

)

(((sxact)->flags & SXACT_FLAG_RO_SAFE) != 0)

Definition at line 290 of file predicate.c.

SxactIsROUnsafe

#define SxactIsROUnsafe

(

sxact

)

(((sxact)->flags & SXACT_FLAG_RO_UNSAFE) != 0)

Definition at line 291 of file predicate.c.

TargetTagIsCoveredBy

#define TargetTagIsCoveredBy	(		covered_target,
			covering_target
	)

Value:

    ((GET_PREDICATELOCKTARGETTAG_RELATION(covered_target) == /* (2) */  \
	  GET_PREDICATELOCKTARGETTAG_RELATION(covering_target))                \
     && (GET_PREDICATELOCKTARGETTAG_OFFSET(covering_target) ==          \
         InvalidOffsetNumber)                                /* (3) */  \
     && (((GET_PREDICATELOCKTARGETTAG_OFFSET(covered_target) !=         \
           InvalidOffsetNumber)                              /* (4a) */ \
          && (GET_PREDICATELOCKTARGETTAG_PAGE(covering_target) ==       \
              GET_PREDICATELOCKTARGETTAG_PAGE(covered_target)))         \
         || ((GET_PREDICATELOCKTARGETTAG_PAGE(covering_target) ==       \
              InvalidBlockNumber)                            /* (4b) */ \
             && (GET_PREDICATELOCKTARGETTAG_PAGE(covered_target)        \
                 != InvalidBlockNumber)))                               \
     && (GET_PREDICATELOCKTARGETTAG_DB(covered_target) ==    /* (1) */  \
		 GET_PREDICATELOCKTARGETTAG_DB(covering_target)))

Definition at line 232 of file predicate.c.

Typedef Documentation

SerialControl

typedef struct SerialControlData* SerialControl

Definition at line 354 of file predicate.c.

SerialControlData

typedef struct SerialControlData SerialControlData

Function Documentation

AtPrepare_PredicateLocks()

void AtPrepare_PredicateLocks

(

void

)

Definition at line 4720 of file predicate.c.

{
    SERIALIZABLEXACT *sxact;
    TwoPhasePredicateRecord record;
    TwoPhasePredicateXactRecord *xactRecord;
    TwoPhasePredicateLockRecord *lockRecord;
    dlist_iter  iter;
 
    sxact = MySerializableXact;
    xactRecord = &(record.data.xactRecord);
    lockRecord = &(record.data.lockRecord);
 
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    /* Generate an xact record for our SERIALIZABLEXACT */
    record.type = TWOPHASEPREDICATERECORD_XACT;
    xactRecord->xmin = MySerializableXact->xmin;
    xactRecord->flags = MySerializableXact->flags;
 
    /*
     * Note that we don't include the list of conflicts in our out in the
     * statefile, because new conflicts can be added even after the
     * transaction prepares. We'll just make a conservative assumption during
     * recovery instead.
     */
 
    RegisterTwoPhaseRecord(TWOPHASE_RM_PREDICATELOCK_ID, 0,
                           &record, sizeof(record));
 
    /*
     * Generate a lock record for each lock.
     *
     * To do this, we need to walk the predicate lock list in our sxact rather
     * than using the local predicate lock table because the latter is not
     * guaranteed to be accurate.
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
 
    /*
     * No need to take sxact->perXactPredicateListLock in parallel mode
     * because there cannot be any parallel workers running while we are
     * preparing a transaction.
     */
    Assert(!IsParallelWorker() && !ParallelContextActive());
 
    dlist_foreach(iter, &sxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
 
        record.type = TWOPHASEPREDICATERECORD_LOCK;
        lockRecord->target = predlock->tag.myTarget->tag;
 
        RegisterTwoPhaseRecord(TWOPHASE_RM_PREDICATELOCK_ID, 0,
                               &record, sizeof(record));
    }
 
    LWLockRelease(SerializablePredicateListLock);
}

References Assert, dlist_iter::cur, TwoPhasePredicateRecord::data, dlist_container, dlist_foreach, fb(), SERIALIZABLEXACT::flags, TwoPhasePredicateXactRecord::flags, InvalidSerializableXact, IsParallelWorker, TwoPhasePredicateRecord::lockRecord, LW_SHARED, LWLockAcquire(), LWLockRelease(), MySerializableXact, ParallelContextActive(), RegisterTwoPhaseRecord(), TwoPhasePredicateLockRecord::target, TWOPHASE_RM_PREDICATELOCK_ID, TWOPHASEPREDICATERECORD_LOCK, TWOPHASEPREDICATERECORD_XACT, TwoPhasePredicateRecord::type, TwoPhasePredicateRecord::xactRecord, SERIALIZABLEXACT::xmin, and TwoPhasePredicateXactRecord::xmin.

Referenced by PrepareTransaction().

AttachSerializableXact()

void AttachSerializableXact

(

SerializableXactHandle

handle

)

Definition at line 4986 of file predicate.c.

{
 
    Assert(MySerializableXact == InvalidSerializableXact);
 
    MySerializableXact = (SERIALIZABLEXACT *) handle;
    if (MySerializableXact != InvalidSerializableXact)
        CreateLocalPredicateLockHash();
}

References Assert, CreateLocalPredicateLockHash(), InvalidSerializableXact, and MySerializableXact.

Referenced by ParallelWorkerMain().

check_serial_buffers()

bool check_serial_buffers	(	int *	newval,
		void **	extra,
		GucSource	source
	)

Definition at line 828 of file predicate.c.

{
    return check_slru_buffers("serializable_buffers", newval);
}

References check_slru_buffers(), and newval.

CheckAndPromotePredicateLockRequest()

static bool CheckAndPromotePredicateLockRequest ( const PREDICATELOCKTARGETTAG *  reqtag )

static

Definition at line 2256 of file predicate.c.

{
    PREDICATELOCKTARGETTAG targettag,
                nexttag,
                promotiontag;
    LOCALPREDICATELOCK *parentlock;
    bool        found,
                promote;
 
    promote = false;
 
    targettag = *reqtag;
 
    /* check parents iteratively */
    while (GetParentPredicateLockTag(&targettag, &nexttag))
    {
        targettag = nexttag;
        parentlock = (LOCALPREDICATELOCK *) hash_search(LocalPredicateLockHash,
                                                        &targettag,
                                                        HASH_ENTER,
                                                        &found);
        if (!found)
        {
            parentlock->held = false;
            parentlock->childLocks = 1;
        }
        else
            parentlock->childLocks++;
 
        if (parentlock->childLocks >
            MaxPredicateChildLocks(&targettag))
        {
            /*
             * We should promote to this parent lock. Continue to check its
             * ancestors, however, both to get their child counts right and to
             * check whether we should just go ahead and promote to one of
             * them.
             */
            promotiontag = targettag;
            promote = true;
        }
    }
 
    if (promote)
    {
        /* acquire coarsest ancestor eligible for promotion */
        PredicateLockAcquire(&promotiontag);
        return true;
    }
    else
        return false;
}

References fb(), GetParentPredicateLockTag(), HASH_ENTER, hash_search(), LOCALPREDICATELOCK::held, LocalPredicateLockHash, MaxPredicateChildLocks(), and PredicateLockAcquire().

Referenced by PredicateLockAcquire().

CheckForSerializableConflictIn()

void CheckForSerializableConflictIn	(	Relation	relation,
		const ItemPointerData *	tid,
		BlockNumber	blkno
	)

Definition at line 4266 of file predicate.c.

{
    PREDICATELOCKTARGETTAG targettag;
 
    if (!SerializationNeededForWrite(relation))
        return;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict in checking."),
                 errhint("The transaction might succeed if retried.")));
 
    /*
     * We're doing a write which might cause rw-conflicts now or later.
     * Memorize that fact.
     */
    MyXactDidWrite = true;
 
    /*
     * It is important that we check for locks from the finest granularity to
     * the coarsest granularity, so that granularity promotion doesn't cause
     * us to miss a lock.  The new (coarser) lock will be acquired before the
     * old (finer) locks are released.
     *
     * It is not possible to take and hold a lock across the checks for all
     * granularities because each target could be in a separate partition.
     */
    if (tid != NULL)
    {
        SET_PREDICATELOCKTARGETTAG_TUPLE(targettag,
                                         relation->rd_locator.dbOid,
                                         relation->rd_id,
                                         ItemPointerGetBlockNumber(tid),
                                         ItemPointerGetOffsetNumber(tid));
        CheckTargetForConflictsIn(&targettag);
    }
 
    if (blkno != InvalidBlockNumber)
    {
        SET_PREDICATELOCKTARGETTAG_PAGE(targettag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id,
                                        blkno);
        CheckTargetForConflictsIn(&targettag);
    }
 
    SET_PREDICATELOCKTARGETTAG_RELATION(targettag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    CheckTargetForConflictsIn(&targettag);
}

References CheckTargetForConflictsIn(), RelFileLocator::dbOid, ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errdetail_internal(), errhint(), errmsg, ERROR, fb(), InvalidBlockNumber, ItemPointerGetBlockNumber(), ItemPointerGetOffsetNumber(), MySerializableXact, MyXactDidWrite, RelationData::rd_id, RelationData::rd_locator, SerializationNeededForWrite(), SET_PREDICATELOCKTARGETTAG_PAGE, SET_PREDICATELOCKTARGETTAG_RELATION, SET_PREDICATELOCKTARGETTAG_TUPLE, and SxactIsDoomed.

Referenced by _bt_check_unique(), _bt_doinsert(), _hash_doinsert(), ginEntryInsert(), ginFindLeafPage(), ginHeapTupleFastInsert(), gistinserttuples(), heap_delete(), heap_insert(), heap_multi_insert(), heap_update(), and index_insert().

CheckForSerializableConflictOut()

void CheckForSerializableConflictOut	(	Relation	relation,
		TransactionId	xid,
		Snapshot	snapshot
	)

Definition at line 3953 of file predicate.c.

{
    SERIALIZABLEXIDTAG sxidtag;
    SERIALIZABLEXID *sxid;
    SERIALIZABLEXACT *sxact;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
    {
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict out checking."),
                 errhint("The transaction might succeed if retried.")));
    }
    Assert(TransactionIdIsValid(xid));
 
    if (TransactionIdEquals(xid, GetTopTransactionIdIfAny()))
        return;
 
    /*
     * Find sxact or summarized info for the top level xid.
     */
    sxidtag.xid = xid;
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
    sxid = (SERIALIZABLEXID *)
        hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
    if (!sxid)
    {
        /*
         * Transaction not found in "normal" SSI structures.  Check whether it
         * got pushed out to SLRU storage for "old committed" transactions.
         */
        SerCommitSeqNo conflictCommitSeqNo;
 
        conflictCommitSeqNo = SerialGetMinConflictCommitSeqNo(xid);
        if (conflictCommitSeqNo != 0)
        {
            if (conflictCommitSeqNo != InvalidSerCommitSeqNo
                && (!SxactIsReadOnly(MySerializableXact)
                    || conflictCommitSeqNo
                    <= MySerializableXact->SeqNo.lastCommitBeforeSnapshot))
                ereport(ERROR,
                        (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                         errmsg("could not serialize access due to read/write dependencies among transactions"),
                         errdetail_internal("Reason code: Canceled on conflict out to old pivot %u.", xid),
                         errhint("The transaction might succeed if retried.")));
 
            if (SxactHasSummaryConflictIn(MySerializableXact)
                || !dlist_is_empty(&MySerializableXact->inConflicts))
                ereport(ERROR,
                        (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                         errmsg("could not serialize access due to read/write dependencies among transactions"),
                         errdetail_internal("Reason code: Canceled on identification as a pivot, with conflict out to old committed transaction %u.", xid),
                         errhint("The transaction might succeed if retried.")));
 
            MySerializableXact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
        }
 
        /* It's not serializable or otherwise not important. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
    sxact = sxid->myXact;
    Assert(TransactionIdEquals(sxact->topXid, xid));
    if (sxact == MySerializableXact || SxactIsDoomed(sxact))
    {
        /* Can't conflict with ourself or a transaction that will roll back. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    /*
     * We have a conflict out to a transaction which has a conflict out to a
     * summarized transaction.  That summarized transaction must have
     * committed first, and we can't tell when it committed in relation to our
     * snapshot acquisition, so something needs to be canceled.
     */
    if (SxactHasSummaryConflictOut(sxact))
    {
        if (!SxactIsPrepared(sxact))
        {
            sxact->flags |= SXACT_FLAG_DOOMED;
            LWLockRelease(SerializableXactHashLock);
            return;
        }
        else
        {
            LWLockRelease(SerializableXactHashLock);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on conflict out to old pivot."),
                     errhint("The transaction might succeed if retried.")));
        }
    }
 
    /*
     * If this is a read-only transaction and the writing transaction has
     * committed, and it doesn't have a rw-conflict to a transaction which
     * committed before it, no conflict.
     */
    if (SxactIsReadOnly(MySerializableXact)
        && SxactIsCommitted(sxact)
        && !SxactHasSummaryConflictOut(sxact)
        && (!SxactHasConflictOut(sxact)
            || MySerializableXact->SeqNo.lastCommitBeforeSnapshot < sxact->SeqNo.earliestOutConflictCommit))
    {
        /* Read-only transaction will appear to run first.  No conflict. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    if (!XidIsConcurrent(xid))
    {
        /* This write was already in our snapshot; no conflict. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    if (RWConflictExists(MySerializableXact, sxact))
    {
        /* We don't want duplicate conflict records in the list. */
        LWLockRelease(SerializableXactHashLock);
        return;
    }
 
    /*
     * Flag the conflict.  But first, if this conflict creates a dangerous
     * structure, ereport an error.
     */
    FlagRWConflict(MySerializableXact, sxact);
    LWLockRelease(SerializableXactHashLock);
}

References Assert, dlist_is_empty(), ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errdetail_internal(), errhint(), errmsg, ERROR, fb(), FlagRWConflict(), SERIALIZABLEXACT::flags, GetTopTransactionIdIfAny(), HASH_FIND, hash_search(), SERIALIZABLEXACT::inConflicts, InvalidSerCommitSeqNo, SERIALIZABLEXACT::lastCommitBeforeSnapshot, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MySerializableXact, RWConflictExists(), SERIALIZABLEXACT::SeqNo, SerialGetMinConflictCommitSeqNo(), SerializableXidHash, SerializationNeededForRead(), SXACT_FLAG_DOOMED, SXACT_FLAG_SUMMARY_CONFLICT_OUT, SxactHasConflictOut, SxactHasSummaryConflictIn, SxactHasSummaryConflictOut, SxactIsCommitted, SxactIsDoomed, SxactIsPrepared, SxactIsReadOnly, TransactionIdEquals, TransactionIdIsValid, and XidIsConcurrent().

Referenced by HeapCheckForSerializableConflictOut().

CheckForSerializableConflictOutNeeded()

bool CheckForSerializableConflictOutNeeded	(	Relation	relation,
		Snapshot	snapshot
	)

Definition at line 3921 of file predicate.c.

{
    if (!SerializationNeededForRead(relation, snapshot))
        return false;
 
    /* Check if someone else has already decided that we need to die */
    if (SxactIsDoomed(MySerializableXact))
    {
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during conflict out checking."),
                 errhint("The transaction might succeed if retried.")));
    }
 
    return true;
}

References ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errdetail_internal(), errhint(), errmsg, ERROR, MySerializableXact, SerializationNeededForRead(), and SxactIsDoomed.

Referenced by heap_prepare_pagescan(), and HeapCheckForSerializableConflictOut().

CheckPointPredicate()

void CheckPointPredicate

(

void

)

Definition at line 1022 of file predicate.c.

{
    int64       truncateCutoffPage;
 
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /* Exit quickly if the SLRU is currently not in use. */
    if (serialControl->headPage < 0)
    {
        LWLockRelease(SerialControlLock);
        return;
    }
 
    if (TransactionIdIsValid(serialControl->tailXid))
    {
        int64       tailPage;
 
        tailPage = SerialPage(serialControl->tailXid);
 
        /*
         * It is possible for the tailXid to be ahead of the headXid.  This
         * occurs if we checkpoint while there are in-progress serializable
         * transaction(s) advancing the tail but we are yet to summarize the
         * transactions.  In this case, we cutoff up to the headPage and the
         * next summary will advance the headXid.
         */
        if (SerialPagePrecedesLogically(tailPage, serialControl->headPage))
        {
            /* We can truncate the SLRU up to the page containing tailXid */
            truncateCutoffPage = tailPage;
        }
        else
            truncateCutoffPage = serialControl->headPage;
    }
    else
    {
        /*----------
         * The SLRU is no longer needed. Truncate to head before we set head
         * invalid.
         *
         * XXX: It's possible that the SLRU is not needed again until XID
         * wrap-around has happened, so that the segment containing headPage
         * that we leave behind will appear to be new again. In that case it
         * won't be removed until XID horizon advances enough to make it
         * current again.
         *
         * XXX: This should happen in vac_truncate_clog(), not in checkpoints.
         * Consider this scenario, starting from a system with no in-progress
         * transactions and VACUUM FREEZE having maximized oldestXact:
         * - Start a SERIALIZABLE transaction.
         * - Start, finish, and summarize a SERIALIZABLE transaction, creating
         *   one SLRU page.
         * - Consume XIDs to reach xidStopLimit.
         * - Finish all transactions.  Due to the long-running SERIALIZABLE
         *   transaction, earlier checkpoints did not touch headPage.  The
         *   next checkpoint will change it, but that checkpoint happens after
         *   the end of the scenario.
         * - VACUUM to advance XID limits.
         * - Consume ~2M XIDs, crossing the former xidWrapLimit.
         * - Start, finish, and summarize a SERIALIZABLE transaction.
         *   SerialAdd() declines to create the targetPage, because headPage
         *   is not regarded as in the past relative to that targetPage.  The
         *   transaction instigating the summarize fails in
         *   SimpleLruReadPage().
         */
        truncateCutoffPage = serialControl->headPage;
        serialControl->headPage = -1;
    }
 
    LWLockRelease(SerialControlLock);
 
    /*
     * Truncate away pages that are no longer required.  Note that no
     * additional locking is required, because this is only called as part of
     * a checkpoint, and the validity limits have already been determined.
     */
    SimpleLruTruncate(SerialSlruCtl, truncateCutoffPage);
 
    /*
     * Write dirty SLRU pages to disk
     *
     * This is not actually necessary from a correctness point of view. We do
     * it merely as a debugging aid.
     *
     * We're doing this after the truncation to avoid writing pages right
     * before deleting the file in which they sit, which would be completely
     * pointless.
     */
    SimpleLruWriteAll(SerialSlruCtl, true);
}

References fb(), SerialControlData::headPage, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), serialControl, SerialPage, SerialPagePrecedesLogically(), SerialSlruCtl, SimpleLruTruncate(), SimpleLruWriteAll(), SerialControlData::tailXid, and TransactionIdIsValid.

Referenced by CheckPointGuts().

CheckTableForSerializableConflictIn()

void CheckTableForSerializableConflictIn

(

Relation

relation

)

Definition at line 4349 of file predicate.c.

{
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCKTARGET *target;
    Oid         dbId;
    Oid         heapId;
    int         i;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     * It's safe to check this without taking locks because the caller is
     * holding an ACCESS EXCLUSIVE lock on the relation.  No new locks which
     * would matter here can be acquired while that is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!SerializationNeededForWrite(relation))
        return;
 
    /*
     * We're doing a write which might cause rw-conflicts now or later.
     * Memorize that fact.
     */
    MyXactDidWrite = true;
 
    Assert(relation->rd_index == NULL); /* not an index relation */
 
    dbId = relation->rd_locator.dbOid;
    heapId = relation->rd_id;
 
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_SHARED);
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* Scan through target list */
    hash_seq_init(&seqstat, PredicateLockTargetHash);
 
    while ((target = (PREDICATELOCKTARGET *) hash_seq_search(&seqstat)))
    {
        dlist_mutable_iter iter;
 
        /*
         * Check whether this is a target which needs attention.
         */
        if (GET_PREDICATELOCKTARGETTAG_RELATION(target->tag) != heapId)
            continue;           /* wrong relation id */
        if (GET_PREDICATELOCKTARGETTAG_DB(target->tag) != dbId)
            continue;           /* wrong database id */
 
        /*
         * Loop through locks for this target and flag conflicts.
         */
        dlist_foreach_modify(iter, &target->predicateLocks)
        {
            PREDICATELOCK *predlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
 
            if (predlock->tag.myXact != MySerializableXact
                && !RWConflictExists(predlock->tag.myXact, MySerializableXact))
            {
                FlagRWConflict(predlock->tag.myXact, MySerializableXact);
            }
        }
    }
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
    LWLockRelease(SerializablePredicateListLock);
}

References Assert, dlist_mutable_iter::cur, RelFileLocator::dbOid, dlist_container, dlist_foreach_modify, fb(), FlagRWConflict(), GET_PREDICATELOCKTARGETTAG_DB, GET_PREDICATELOCKTARGETTAG_RELATION, hash_seq_init(), hash_seq_search(), i, LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), MySerializableXact, MyXactDidWrite, NUM_PREDICATELOCK_PARTITIONS, PredicateLockHashPartitionLockByIndex, PREDICATELOCKTARGET::predicateLocks, PredicateLockTargetHash, PredXact, RelationData::rd_id, RelationData::rd_index, RelationData::rd_locator, RWConflictExists(), SerializationNeededForWrite(), PredXactListData::SxactGlobalXmin, PREDICATELOCKTARGET::tag, and TransactionIdIsValid.

Referenced by ExecuteTruncateGuts(), and heap_drop_with_catalog().

CheckTargetForConflictsIn()

static void CheckTargetForConflictsIn ( PREDICATELOCKTARGETTAG *  targettag )

static

Definition at line 4096 of file predicate.c.

{
    uint32      targettaghash;
    LWLock     *partitionLock;
    PREDICATELOCKTARGET *target;
    PREDICATELOCK *mypredlock = NULL;
    PREDICATELOCKTAG mypredlocktag;
    dlist_mutable_iter iter;
 
    Assert(MySerializableXact != InvalidSerializableXact);
 
    /*
     * The same hash and LW lock apply to the lock target and the lock itself.
     */
    targettaghash = PredicateLockTargetTagHashCode(targettag);
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
    LWLockAcquire(partitionLock, LW_SHARED);
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    targettag, targettaghash,
                                    HASH_FIND, NULL);
    if (!target)
    {
        /* Nothing has this target locked; we're done here. */
        LWLockRelease(partitionLock);
        return;
    }
 
    /*
     * Each lock for an overlapping transaction represents a conflict: a
     * rw-dependency in to this transaction.
     */
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    dlist_foreach_modify(iter, &target->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, targetLink, iter.cur);
        SERIALIZABLEXACT *sxact = predlock->tag.myXact;
 
        if (sxact == MySerializableXact)
        {
            /*
             * If we're getting a write lock on a tuple, we don't need a
             * predicate (SIREAD) lock on the same tuple. We can safely remove
             * our SIREAD lock, but we'll defer doing so until after the loop
             * because that requires upgrading to an exclusive partition lock.
             *
             * We can't use this optimization within a subtransaction because
             * the subtransaction could roll back, and we would be left
             * without any lock at the top level.
             */
            if (!IsSubTransaction()
                && GET_PREDICATELOCKTARGETTAG_OFFSET(*targettag))
            {
                mypredlock = predlock;
                mypredlocktag = predlock->tag;
            }
        }
        else if (!SxactIsDoomed(sxact)
                 && (!SxactIsCommitted(sxact)
                     || TransactionIdPrecedes(GetTransactionSnapshot()->xmin,
                                              sxact->finishedBefore))
                 && !RWConflictExists(sxact, MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
            /*
             * Re-check after getting exclusive lock because the other
             * transaction may have flagged a conflict.
             */
            if (!SxactIsDoomed(sxact)
                && (!SxactIsCommitted(sxact)
                    || TransactionIdPrecedes(GetTransactionSnapshot()->xmin,
                                             sxact->finishedBefore))
                && !RWConflictExists(sxact, MySerializableXact))
            {
                FlagRWConflict(sxact, MySerializableXact);
            }
 
            LWLockRelease(SerializableXactHashLock);
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
    }
    LWLockRelease(SerializableXactHashLock);
    LWLockRelease(partitionLock);
 
    /*
     * If we found one of our own SIREAD locks to remove, remove it now.
     *
     * At this point our transaction already has a RowExclusiveLock on the
     * relation, so we are OK to drop the predicate lock on the tuple, if
     * found, without fearing that another write against the tuple will occur
     * before the MVCC information makes it to the buffer.
     */
    if (mypredlock != NULL)
    {
        uint32      predlockhashcode;
        PREDICATELOCK *rmpredlock;
 
        LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
        if (IsInParallelMode())
            LWLockAcquire(&MySerializableXact->perXactPredicateListLock, LW_EXCLUSIVE);
        LWLockAcquire(partitionLock, LW_EXCLUSIVE);
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        /*
         * Remove the predicate lock from shared memory, if it wasn't removed
         * while the locks were released.  One way that could happen is from
         * autovacuum cleaning up an index.
         */
        predlockhashcode = PredicateLockHashCodeFromTargetHashCode
            (&mypredlocktag, targettaghash);
        rmpredlock = (PREDICATELOCK *)
            hash_search_with_hash_value(PredicateLockHash,
                                        &mypredlocktag,
                                        predlockhashcode,
                                        HASH_FIND, NULL);
        if (rmpredlock != NULL)
        {
            Assert(rmpredlock == mypredlock);
 
            dlist_delete(&(mypredlock->targetLink));
            dlist_delete(&(mypredlock->xactLink));
 
            rmpredlock = (PREDICATELOCK *)
                hash_search_with_hash_value(PredicateLockHash,
                                            &mypredlocktag,
                                            predlockhashcode,
                                            HASH_REMOVE, NULL);
            Assert(rmpredlock == mypredlock);
 
            RemoveTargetIfNoLongerUsed(target, targettaghash);
        }
 
        LWLockRelease(SerializableXactHashLock);
        LWLockRelease(partitionLock);
        if (IsInParallelMode())
            LWLockRelease(&MySerializableXact->perXactPredicateListLock);
        LWLockRelease(SerializablePredicateListLock);
 
        if (rmpredlock != NULL)
        {
            /*
             * Remove entry in local lock table if it exists. It's OK if it
             * doesn't exist; that means the lock was transferred to a new
             * target by a different backend.
             */
            hash_search_with_hash_value(LocalPredicateLockHash,
                                        targettag, targettaghash,
                                        HASH_REMOVE, NULL);
 
            DecrementParentLocks(targettag);
        }
    }
}

References Assert, dlist_mutable_iter::cur, DecrementParentLocks(), dlist_container, dlist_delete(), dlist_foreach_modify, fb(), FlagRWConflict(), GET_PREDICATELOCKTARGETTAG_OFFSET, GetTransactionSnapshot(), HASH_FIND, HASH_REMOVE, hash_search_with_hash_value(), InvalidSerializableXact, IsInParallelMode(), IsSubTransaction(), LocalPredicateLockHash, LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), MySerializableXact, SERIALIZABLEXACT::perXactPredicateListLock, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, PREDICATELOCKTARGET::predicateLocks, PredicateLockTargetHash, PredicateLockTargetTagHashCode, RemoveTargetIfNoLongerUsed(), RWConflictExists(), SxactIsCommitted, SxactIsDoomed, and TransactionIdPrecedes().

Referenced by CheckForSerializableConflictIn().

ClearOldPredicateLocks()

static void ClearOldPredicateLocks ( void  )

static

Definition at line 3627 of file predicate.c.

{
    dlist_mutable_iter iter;
 
    /*
     * Loop through finished transactions. They are in commit order, so we can
     * stop as soon as we find one that's still interesting.
     */
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
    dlist_foreach_modify(iter, FinishedSerializableTransactions)
    {
        SERIALIZABLEXACT *finishedSxact =
            dlist_container(SERIALIZABLEXACT, finishedLink, iter.cur);
 
        if (!TransactionIdIsValid(PredXact->SxactGlobalXmin)
            || TransactionIdPrecedesOrEquals(finishedSxact->finishedBefore,
                                             PredXact->SxactGlobalXmin))
        {
            /*
             * This transaction committed before any in-progress transaction
             * took its snapshot. It's no longer interesting.
             */
            LWLockRelease(SerializableXactHashLock);
            dlist_delete_thoroughly(&finishedSxact->finishedLink);
            ReleaseOneSerializableXact(finishedSxact, false, false);
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
        else if (finishedSxact->commitSeqNo > PredXact->HavePartialClearedThrough
                 && finishedSxact->commitSeqNo <= PredXact->CanPartialClearThrough)
        {
            /*
             * Any active transactions that took their snapshot before this
             * transaction committed are read-only, so we can clear part of
             * its state.
             */
            LWLockRelease(SerializableXactHashLock);
 
            if (SxactIsReadOnly(finishedSxact))
            {
                /* A read-only transaction can be removed entirely */
                dlist_delete_thoroughly(&(finishedSxact->finishedLink));
                ReleaseOneSerializableXact(finishedSxact, false, false);
            }
            else
            {
                /*
                 * A read-write transaction can only be partially cleared. We
                 * need to keep the SERIALIZABLEXACT but can release the
                 * SIREAD locks and conflicts in.
                 */
                ReleaseOneSerializableXact(finishedSxact, true, false);
            }
 
            PredXact->HavePartialClearedThrough = finishedSxact->commitSeqNo;
            LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        }
        else
        {
            /* Still interesting. */
            break;
        }
    }
    LWLockRelease(SerializableXactHashLock);
 
    /*
     * Loop through predicate locks on dummy transaction for summarized data.
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    dlist_foreach_modify(iter, &OldCommittedSxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
        bool        canDoPartialCleanup;
 
        LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        Assert(predlock->commitSeqNo != 0);
        Assert(predlock->commitSeqNo != InvalidSerCommitSeqNo);
        canDoPartialCleanup = (predlock->commitSeqNo <= PredXact->CanPartialClearThrough);
        LWLockRelease(SerializableXactHashLock);
 
        /*
         * If this lock originally belonged to an old enough transaction, we
         * can release it.
         */
        if (canDoPartialCleanup)
        {
            PREDICATELOCKTAG tag;
            PREDICATELOCKTARGET *target;
            PREDICATELOCKTARGETTAG targettag;
            uint32      targettaghash;
            LWLock     *partitionLock;
 
            tag = predlock->tag;
            target = tag.myTarget;
            targettag = target->tag;
            targettaghash = PredicateLockTargetTagHashCode(&targettag);
            partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
            LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
            dlist_delete(&(predlock->targetLink));
            dlist_delete(&(predlock->xactLink));
 
            hash_search_with_hash_value(PredicateLockHash, &tag,
                                        PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                                targettaghash),
                                        HASH_REMOVE, NULL);
            RemoveTargetIfNoLongerUsed(target, targettaghash);
 
            LWLockRelease(partitionLock);
        }
    }
 
    LWLockRelease(SerializablePredicateListLock);
    LWLockRelease(SerializableFinishedListLock);
}

References Assert, PredXactListData::CanPartialClearThrough, dlist_mutable_iter::cur, dlist_container, dlist_delete(), dlist_delete_thoroughly(), dlist_foreach_modify, fb(), FinishedSerializableTransactions, HASH_REMOVE, hash_search_with_hash_value(), PredXactListData::HavePartialClearedThrough, InvalidSerCommitSeqNo, LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), PREDICATELOCKTAG::myTarget, OldCommittedSxact, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, SERIALIZABLEXACT::predicateLocks, PredicateLockTargetTagHashCode, PredXact, ReleaseOneSerializableXact(), RemoveTargetIfNoLongerUsed(), PredXactListData::SxactGlobalXmin, SxactIsReadOnly, PREDICATELOCKTARGET::tag, TransactionIdIsValid, and TransactionIdPrecedesOrEquals().

Referenced by ReleasePredicateLocks().

CoarserLockCovers()

static bool CoarserLockCovers ( const PREDICATELOCKTARGETTAG *  newtargettag )

static

Definition at line 2041 of file predicate.c.

{
    PREDICATELOCKTARGETTAG targettag,
                parenttag;
 
    targettag = *newtargettag;
 
    /* check parents iteratively until no more */
    while (GetParentPredicateLockTag(&targettag, &parenttag))
    {
        targettag = parenttag;
        if (PredicateLockExists(&targettag))
            return true;
    }
 
    /* no more parents to check; lock is not covered */
    return false;
}

References fb(), GetParentPredicateLockTag(), and PredicateLockExists().

Referenced by PredicateLockAcquire().

CreateLocalPredicateLockHash()

static void CreateLocalPredicateLockHash ( void  )

static

Definition at line 1870 of file predicate.c.

{
    HASHCTL     hash_ctl;
 
    /* Initialize the backend-local hash table of parent locks */
    Assert(LocalPredicateLockHash == NULL);
    hash_ctl.keysize = sizeof(PREDICATELOCKTARGETTAG);
    hash_ctl.entrysize = sizeof(LOCALPREDICATELOCK);
    LocalPredicateLockHash = hash_create("Local predicate lock",
                                         max_predicate_locks_per_xact,
                                         &hash_ctl,
                                         HASH_ELEM | HASH_BLOBS);
}

References Assert, fb(), HASH_BLOBS, hash_create(), HASH_ELEM, LocalPredicateLockHash, and max_predicate_locks_per_xact.

Referenced by AttachSerializableXact(), and GetSerializableTransactionSnapshotInt().

CreatePredicateLock()

static void CreatePredicateLock ( const PREDICATELOCKTARGETTAG *  targettag, uint32  targettaghash, SERIALIZABLEXACT *  sxact  )

static

Definition at line 2383 of file predicate.c.

{
    PREDICATELOCKTARGET *target;
    PREDICATELOCKTAG locktag;
    PREDICATELOCK *lock;
    LWLock     *partitionLock;
    bool        found;
 
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
    LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
    /* Make sure that the target is represented. */
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    targettag, targettaghash,
                                    HASH_ENTER_NULL, &found);
    if (!target)
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("out of shared memory"),
                 errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
    if (!found)
        dlist_init(&target->predicateLocks);
 
    /* We've got the sxact and target, make sure they're joined. */
    locktag.myTarget = target;
    locktag.myXact = sxact;
    lock = (PREDICATELOCK *)
        hash_search_with_hash_value(PredicateLockHash, &locktag,
                                    PredicateLockHashCodeFromTargetHashCode(&locktag, targettaghash),
                                    HASH_ENTER_NULL, &found);
    if (!lock)
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("out of shared memory"),
                 errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
 
    if (!found)
    {
        dlist_push_tail(&target->predicateLocks, &lock->targetLink);
        dlist_push_tail(&sxact->predicateLocks, &lock->xactLink);
        lock->commitSeqNo = InvalidSerCommitSeqNo;
    }
 
    LWLockRelease(partitionLock);
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
}

References PREDICATELOCK::commitSeqNo, dlist_init(), dlist_push_tail(), ereport, errcode(), errhint(), errmsg, ERROR, fb(), HASH_ENTER_NULL, hash_search_with_hash_value(), InvalidSerCommitSeqNo, IsInParallelMode(), LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), PREDICATELOCKTAG::myTarget, PREDICATELOCKTAG::myXact, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, PREDICATELOCKTARGET::predicateLocks, PredicateLockTargetHash, PREDICATELOCK::targetLink, and PREDICATELOCK::xactLink.

Referenced by predicatelock_twophase_recover(), and PredicateLockAcquire().

CreatePredXact()

static SERIALIZABLEXACT * CreatePredXact ( void  )

static

Definition at line 596 of file predicate.c.

{
    SERIALIZABLEXACT *sxact;
 
    if (dlist_is_empty(&PredXact->availableList))
        return NULL;
 
    sxact = dlist_container(SERIALIZABLEXACT, xactLink,
                            dlist_pop_head_node(&PredXact->availableList));
    dlist_push_tail(&PredXact->activeList, &sxact->xactLink);
    return sxact;
}

References PredXactListData::activeList, PredXactListData::availableList, dlist_container, dlist_is_empty(), dlist_pop_head_node(), dlist_push_tail(), fb(), and PredXact.

Referenced by GetSerializableTransactionSnapshotInt(), predicatelock_twophase_recover(), and PredicateLockShmemInit().

DecrementParentLocks()

static void DecrementParentLocks ( const PREDICATELOCKTARGETTAG *  targettag )

static

Definition at line 2321 of file predicate.c.

{
    PREDICATELOCKTARGETTAG parenttag,
                nexttag;
 
    parenttag = *targettag;
 
    while (GetParentPredicateLockTag(&parenttag, &nexttag))
    {
        uint32      targettaghash;
        LOCALPREDICATELOCK *parentlock,
                   *rmlock PG_USED_FOR_ASSERTS_ONLY;
 
        parenttag = nexttag;
        targettaghash = PredicateLockTargetTagHashCode(&parenttag);
        parentlock = (LOCALPREDICATELOCK *)
            hash_search_with_hash_value(LocalPredicateLockHash,
                                        &parenttag, targettaghash,
                                        HASH_FIND, NULL);
 
        /*
         * There's a small chance the parent lock doesn't exist in the lock
         * table. This can happen if we prematurely removed it because an
         * index split caused the child refcount to be off.
         */
        if (parentlock == NULL)
            continue;
 
        parentlock->childLocks--;
 
        /*
         * Under similar circumstances the parent lock's refcount might be
         * zero. This only happens if we're holding that lock (otherwise we
         * would have removed the entry).
         */
        if (parentlock->childLocks < 0)
        {
            Assert(parentlock->held);
            parentlock->childLocks = 0;
        }
 
        if ((parentlock->childLocks == 0) && (!parentlock->held))
        {
            rmlock = (LOCALPREDICATELOCK *)
                hash_search_with_hash_value(LocalPredicateLockHash,
                                            &parenttag, targettaghash,
                                            HASH_REMOVE, NULL);
            Assert(rmlock == parentlock);
        }
    }
}

References Assert, fb(), GetParentPredicateLockTag(), HASH_FIND, HASH_REMOVE, hash_search_with_hash_value(), LocalPredicateLockHash, PG_USED_FOR_ASSERTS_ONLY, and PredicateLockTargetTagHashCode.

Referenced by CheckTargetForConflictsIn(), and DeleteChildTargetLocks().

DeleteChildTargetLocks()

static void DeleteChildTargetLocks ( const PREDICATELOCKTARGETTAG *  newtargettag )

static

Definition at line 2144 of file predicate.c.

{
    SERIALIZABLEXACT *sxact;
    PREDICATELOCK *predlock;
    dlist_mutable_iter iter;
 
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    sxact = MySerializableXact;
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
 
    dlist_foreach_modify(iter, &sxact->predicateLocks)
    {
        PREDICATELOCKTAG oldlocktag;
        PREDICATELOCKTARGET *oldtarget;
        PREDICATELOCKTARGETTAG oldtargettag;
 
        predlock = dlist_container(PREDICATELOCK, xactLink, iter.cur);
 
        oldlocktag = predlock->tag;
        Assert(oldlocktag.myXact == sxact);
        oldtarget = oldlocktag.myTarget;
        oldtargettag = oldtarget->tag;
 
        if (TargetTagIsCoveredBy(oldtargettag, *newtargettag))
        {
            uint32      oldtargettaghash;
            LWLock     *partitionLock;
            PREDICATELOCK *rmpredlock PG_USED_FOR_ASSERTS_ONLY;
 
            oldtargettaghash = PredicateLockTargetTagHashCode(&oldtargettag);
            partitionLock = PredicateLockHashPartitionLock(oldtargettaghash);
 
            LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
            dlist_delete(&predlock->xactLink);
            dlist_delete(&predlock->targetLink);
            rmpredlock = hash_search_with_hash_value
                (PredicateLockHash,
                 &oldlocktag,
                 PredicateLockHashCodeFromTargetHashCode(&oldlocktag,
                                                         oldtargettaghash),
                 HASH_REMOVE, NULL);
            Assert(rmpredlock == predlock);
 
            RemoveTargetIfNoLongerUsed(oldtarget, oldtargettaghash);
 
            LWLockRelease(partitionLock);
 
            DecrementParentLocks(&oldtargettag);
        }
    }
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
}

References Assert, dlist_mutable_iter::cur, DecrementParentLocks(), dlist_container, dlist_delete(), dlist_foreach_modify, fb(), HASH_REMOVE, hash_search_with_hash_value(), IsInParallelMode(), LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), MySerializableXact, PG_USED_FOR_ASSERTS_ONLY, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, PredicateLockTargetTagHashCode, RemoveTargetIfNoLongerUsed(), and TargetTagIsCoveredBy.

Referenced by PredicateLockAcquire().

DeleteLockTarget()

static void DeleteLockTarget ( PREDICATELOCKTARGET *  target, uint32  targettaghash  )

static

Definition at line 2599 of file predicate.c.

{
    dlist_mutable_iter iter;
 
    Assert(LWLockHeldByMeInMode(SerializablePredicateListLock,
                                LW_EXCLUSIVE));
    Assert(LWLockHeldByMe(PredicateLockHashPartitionLock(targettaghash)));
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    dlist_foreach_modify(iter, &target->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, targetLink, iter.cur);
        bool        found;
 
        dlist_delete(&(predlock->xactLink));
        dlist_delete(&(predlock->targetLink));
 
        hash_search_with_hash_value
            (PredicateLockHash,
             &predlock->tag,
             PredicateLockHashCodeFromTargetHashCode(&predlock->tag,
                                                     targettaghash),
             HASH_REMOVE, &found);
        Assert(found);
    }
    LWLockRelease(SerializableXactHashLock);
 
    /* Remove the target itself, if possible. */
    RemoveTargetIfNoLongerUsed(target, targettaghash);
}

References Assert, dlist_mutable_iter::cur, dlist_container, dlist_delete(), dlist_foreach_modify, fb(), HASH_REMOVE, hash_search_with_hash_value(), LW_EXCLUSIVE, LWLockAcquire(), LWLockHeldByMe(), LWLockHeldByMeInMode(), LWLockRelease(), PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, PREDICATELOCKTARGET::predicateLocks, and RemoveTargetIfNoLongerUsed().

Referenced by TransferPredicateLocksToNewTarget().

DropAllPredicateLocksFromTable()

static void DropAllPredicateLocksFromTable ( Relation  relation, bool  transfer  )

static

Definition at line 2867 of file predicate.c.

{
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCKTARGET *oldtarget;
    PREDICATELOCKTARGET *heaptarget;
    Oid         dbId;
    Oid         relId;
    Oid         heapId;
    int         i;
    bool        isIndex;
    bool        found;
    uint32      heaptargettaghash;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     * It's safe to check this without taking locks because the caller is
     * holding an ACCESS EXCLUSIVE lock on the relation.  No new locks which
     * would matter here can be acquired while that is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!PredicateLockingNeededForRelation(relation))
        return;
 
    dbId = relation->rd_locator.dbOid;
    relId = relation->rd_id;
    if (relation->rd_index == NULL)
    {
        isIndex = false;
        heapId = relId;
    }
    else
    {
        isIndex = true;
        heapId = relation->rd_index->indrelid;
    }
    Assert(heapId != InvalidOid);
    Assert(transfer || !isIndex);   /* index OID only makes sense with
                                     * transfer */
 
    /* Retrieve first time needed, then keep. */
    heaptargettaghash = 0;
    heaptarget = NULL;
 
    /* Acquire locks on all lock partitions */
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_EXCLUSIVE);
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * Remove the dummy entry to give us scratch space, so we know we'll be
     * able to create the new lock target.
     */
    if (transfer)
        RemoveScratchTarget(true);
 
    /* Scan through target map */
    hash_seq_init(&seqstat, PredicateLockTargetHash);
 
    while ((oldtarget = (PREDICATELOCKTARGET *) hash_seq_search(&seqstat)))
    {
        dlist_mutable_iter iter;
 
        /*
         * Check whether this is a target which needs attention.
         */
        if (GET_PREDICATELOCKTARGETTAG_RELATION(oldtarget->tag) != relId)
            continue;           /* wrong relation id */
        if (GET_PREDICATELOCKTARGETTAG_DB(oldtarget->tag) != dbId)
            continue;           /* wrong database id */
        if (transfer && !isIndex
            && GET_PREDICATELOCKTARGETTAG_TYPE(oldtarget->tag) == PREDLOCKTAG_RELATION)
            continue;           /* already the right lock */
 
        /*
         * If we made it here, we have work to do.  We make sure the heap
         * relation lock exists, then we walk the list of predicate locks for
         * the old target we found, moving all locks to the heap relation lock
         * -- unless they already hold that.
         */
 
        /*
         * First make sure we have the heap relation target.  We only need to
         * do this once.
         */
        if (transfer && heaptarget == NULL)
        {
            PREDICATELOCKTARGETTAG heaptargettag;
 
            SET_PREDICATELOCKTARGETTAG_RELATION(heaptargettag, dbId, heapId);
            heaptargettaghash = PredicateLockTargetTagHashCode(&heaptargettag);
            heaptarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                                     &heaptargettag,
                                                     heaptargettaghash,
                                                     HASH_ENTER, &found);
            if (!found)
                dlist_init(&heaptarget->predicateLocks);
        }
 
        /*
         * Loop through all the locks on the old target, replacing them with
         * locks on the new target.
         */
        dlist_foreach_modify(iter, &oldtarget->predicateLocks)
        {
            PREDICATELOCK *oldpredlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
            PREDICATELOCK *newpredlock;
            SerCommitSeqNo oldCommitSeqNo;
            SERIALIZABLEXACT *oldXact;
 
            /*
             * Remove the old lock first. This avoids the chance of running
             * out of lock structure entries for the hash table.
             */
            oldCommitSeqNo = oldpredlock->commitSeqNo;
            oldXact = oldpredlock->tag.myXact;
 
            dlist_delete(&(oldpredlock->xactLink));
 
            /*
             * No need for retail delete from oldtarget list, we're removing
             * the whole target anyway.
             */
            hash_search(PredicateLockHash,
                        &oldpredlock->tag,
                        HASH_REMOVE, &found);
            Assert(found);
 
            if (transfer)
            {
                PREDICATELOCKTAG newpredlocktag;
 
                newpredlocktag.myTarget = heaptarget;
                newpredlocktag.myXact = oldXact;
                newpredlock = (PREDICATELOCK *)
                    hash_search_with_hash_value(PredicateLockHash,
                                                &newpredlocktag,
                                                PredicateLockHashCodeFromTargetHashCode(&newpredlocktag,
                                                                                        heaptargettaghash),
                                                HASH_ENTER,
                                                &found);
                if (!found)
                {
                    dlist_push_tail(&(heaptarget->predicateLocks),
                                    &(newpredlock->targetLink));
                    dlist_push_tail(&(newpredlocktag.myXact->predicateLocks),
                                    &(newpredlock->xactLink));
                    newpredlock->commitSeqNo = oldCommitSeqNo;
                }
                else
                {
                    if (newpredlock->commitSeqNo < oldCommitSeqNo)
                        newpredlock->commitSeqNo = oldCommitSeqNo;
                }
 
                Assert(newpredlock->commitSeqNo != 0);
                Assert((newpredlock->commitSeqNo == InvalidSerCommitSeqNo)
                       || (newpredlock->tag.myXact == OldCommittedSxact));
            }
        }
 
        hash_search(PredicateLockTargetHash, &oldtarget->tag, HASH_REMOVE,
                    &found);
        Assert(found);
    }
 
    /* Put the scratch entry back */
    if (transfer)
        RestoreScratchTarget(true);
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
    LWLockRelease(SerializablePredicateListLock);
}

References Assert, SERIALIZABLEXACT::commitSeqNo, dlist_mutable_iter::cur, RelFileLocator::dbOid, dlist_container, dlist_delete(), dlist_foreach_modify, dlist_init(), dlist_push_tail(), fb(), GET_PREDICATELOCKTARGETTAG_DB, GET_PREDICATELOCKTARGETTAG_RELATION, GET_PREDICATELOCKTARGETTAG_TYPE, HASH_ENTER, HASH_REMOVE, hash_search(), hash_search_with_hash_value(), hash_seq_init(), hash_seq_search(), i, InvalidOid, InvalidSerCommitSeqNo, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), PREDICATELOCKTAG::myTarget, NUM_PREDICATELOCK_PARTITIONS, OldCommittedSxact, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLockByIndex, PredicateLockingNeededForRelation(), PredicateLockTargetHash, PredicateLockTargetTagHashCode, PREDLOCKTAG_RELATION, PredXact, RelationData::rd_id, RelationData::rd_index, RelationData::rd_locator, RemoveScratchTarget(), RestoreScratchTarget(), SET_PREDICATELOCKTARGETTAG_RELATION, PredXactListData::SxactGlobalXmin, and TransactionIdIsValid.

Referenced by TransferPredicateLocksToHeapRelation().

FlagRWConflict()

static void FlagRWConflict ( SERIALIZABLEXACT *  reader, SERIALIZABLEXACT *  writer  )

static

Definition at line 4431 of file predicate.c.

{
    Assert(reader != writer);
 
    /* First, see if this conflict causes failure. */
    OnConflict_CheckForSerializationFailure(reader, writer);
 
    /* Actually do the conflict flagging. */
    if (reader == OldCommittedSxact)
        writer->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
    else if (writer == OldCommittedSxact)
        reader->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
    else
        SetRWConflict(reader, writer);
}

References Assert, fb(), SERIALIZABLEXACT::flags, OldCommittedSxact, OnConflict_CheckForSerializationFailure(), SetRWConflict(), SXACT_FLAG_SUMMARY_CONFLICT_IN, and SXACT_FLAG_SUMMARY_CONFLICT_OUT.

Referenced by CheckForSerializableConflictOut(), CheckTableForSerializableConflictIn(), and CheckTargetForConflictsIn().

FlagSxactUnsafe()

static void FlagSxactUnsafe ( SERIALIZABLEXACT *  sxact )

static

Definition at line 713 of file predicate.c.

{
    dlist_mutable_iter iter;
 
    Assert(SxactIsReadOnly(sxact));
    Assert(!SxactIsROSafe(sxact));
 
    sxact->flags |= SXACT_FLAG_RO_UNSAFE;
 
    /*
     * We know this isn't a safe snapshot, so we can stop looking for other
     * potential conflicts.
     */
    dlist_foreach_modify(iter, &sxact->possibleUnsafeConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        Assert(!SxactIsReadOnly(conflict->sxactOut));
        Assert(sxact == conflict->sxactIn);
 
        ReleaseRWConflict(conflict);
    }
}

References Assert, dlist_mutable_iter::cur, dlist_container, dlist_foreach_modify, fb(), ReleaseRWConflict(), SXACT_FLAG_RO_UNSAFE, SxactIsReadOnly, and SxactIsROSafe.

Referenced by ReleasePredicateLocks().

GetParentPredicateLockTag()

static bool GetParentPredicateLockTag ( const PREDICATELOCKTARGETTAG *  tag, PREDICATELOCKTARGETTAG *  parent  )

static

Definition at line 2002 of file predicate.c.

{
    switch (GET_PREDICATELOCKTARGETTAG_TYPE(*tag))
    {
        case PREDLOCKTAG_RELATION:
            /* relation locks have no parent lock */
            return false;
 
        case PREDLOCKTAG_PAGE:
            /* parent lock is relation lock */
            SET_PREDICATELOCKTARGETTAG_RELATION(*parent,
                                                GET_PREDICATELOCKTARGETTAG_DB(*tag),
                                                GET_PREDICATELOCKTARGETTAG_RELATION(*tag));
 
            return true;
 
        case PREDLOCKTAG_TUPLE:
            /* parent lock is page lock */
            SET_PREDICATELOCKTARGETTAG_PAGE(*parent,
                                            GET_PREDICATELOCKTARGETTAG_DB(*tag),
                                            GET_PREDICATELOCKTARGETTAG_RELATION(*tag),
                                            GET_PREDICATELOCKTARGETTAG_PAGE(*tag));
            return true;
    }
 
    /* not reachable */
    Assert(false);
    return false;
}

References Assert, GET_PREDICATELOCKTARGETTAG_DB, GET_PREDICATELOCKTARGETTAG_PAGE, GET_PREDICATELOCKTARGETTAG_RELATION, GET_PREDICATELOCKTARGETTAG_TYPE, PREDLOCKTAG_PAGE, PREDLOCKTAG_RELATION, PREDLOCKTAG_TUPLE, SET_PREDICATELOCKTARGETTAG_PAGE, and SET_PREDICATELOCKTARGETTAG_RELATION.

Referenced by CheckAndPromotePredicateLockRequest(), CoarserLockCovers(), DecrementParentLocks(), and PredicateLockPageSplit().

GetPredicateLockStatusData()

PredicateLockData * GetPredicateLockStatusData

(

void

)

Definition at line 1377 of file predicate.c.

{
    PredicateLockData *data;
    int         i;
    int         els,
                el;
    HASH_SEQ_STATUS seqstat;
    PREDICATELOCK *predlock;
 
    data = palloc_object(PredicateLockData);
 
    /*
     * To ensure consistency, take simultaneous locks on all partition locks
     * in ascending order, then SerializableXactHashLock.
     */
    for (i = 0; i < NUM_PREDICATELOCK_PARTITIONS; i++)
        LWLockAcquire(PredicateLockHashPartitionLockByIndex(i), LW_SHARED);
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    /* Get number of locks and allocate appropriately-sized arrays. */
    els = hash_get_num_entries(PredicateLockHash);
    data->nelements = els;
    data->locktags = palloc_array(PREDICATELOCKTARGETTAG, els);
    data->xacts = palloc_array(SERIALIZABLEXACT, els);
 
 
    /* Scan through PredicateLockHash and copy contents */
    hash_seq_init(&seqstat, PredicateLockHash);
 
    el = 0;
 
    while ((predlock = (PREDICATELOCK *) hash_seq_search(&seqstat)))
    {
        data->locktags[el] = predlock->tag.myTarget->tag;
        data->xacts[el] = *predlock->tag.myXact;
        el++;
    }
 
    Assert(el == els);
 
    /* Release locks in reverse order */
    LWLockRelease(SerializableXactHashLock);
    for (i = NUM_PREDICATELOCK_PARTITIONS - 1; i >= 0; i--)
        LWLockRelease(PredicateLockHashPartitionLockByIndex(i));
 
    return data;
}

References Assert, data, fb(), hash_get_num_entries(), hash_seq_init(), hash_seq_search(), i, LW_SHARED, LWLockAcquire(), LWLockRelease(), NUM_PREDICATELOCK_PARTITIONS, palloc_array, palloc_object, PredicateLockHash, and PredicateLockHashPartitionLockByIndex.

Referenced by pg_lock_status().

GetSafeSnapshot()

static Snapshot GetSafeSnapshot ( Snapshot  origSnapshot )

static

Definition at line 1488 of file predicate.c.

{
    Snapshot    snapshot;
 
    Assert(XactReadOnly && XactDeferrable);
 
    while (true)
    {
        /*
         * GetSerializableTransactionSnapshotInt is going to call
         * GetSnapshotData, so we need to provide it the static snapshot area
         * our caller passed to us.  The pointer returned is actually the same
         * one passed to it, but we avoid assuming that here.
         */
        snapshot = GetSerializableTransactionSnapshotInt(origSnapshot,
                                                         NULL, InvalidPid);
 
        if (MySerializableXact == InvalidSerializableXact)
            return snapshot;    /* no concurrent r/w xacts; it's safe */
 
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        /*
         * Wait for concurrent transactions to finish. Stop early if one of
         * them marked us as conflicted.
         */
        MySerializableXact->flags |= SXACT_FLAG_DEFERRABLE_WAITING;
        while (!(dlist_is_empty(&MySerializableXact->possibleUnsafeConflicts) ||
                 SxactIsROUnsafe(MySerializableXact)))
        {
            LWLockRelease(SerializableXactHashLock);
            ProcWaitForSignal(WAIT_EVENT_SAFE_SNAPSHOT);
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        }
        MySerializableXact->flags &= ~SXACT_FLAG_DEFERRABLE_WAITING;
 
        if (!SxactIsROUnsafe(MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            break;              /* success */
        }
 
        LWLockRelease(SerializableXactHashLock);
 
        /* else, need to retry... */
        ereport(DEBUG2,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg_internal("deferrable snapshot was unsafe; trying a new one")));
        ReleasePredicateLocks(false, false);
    }
 
    /*
     * Now we have a safe snapshot, so we don't need to do any further checks.
     */
    Assert(SxactIsROSafe(MySerializableXact));
    ReleasePredicateLocks(false, true);
 
    return snapshot;
}

References Assert, DEBUG2, dlist_is_empty(), ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errmsg_internal(), fb(), SERIALIZABLEXACT::flags, GetSerializableTransactionSnapshotInt(), InvalidPid, InvalidSerializableXact, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MySerializableXact, SERIALIZABLEXACT::possibleUnsafeConflicts, ProcWaitForSignal(), ReleasePredicateLocks(), SXACT_FLAG_DEFERRABLE_WAITING, SxactIsROSafe, SxactIsROUnsafe, XactDeferrable, and XactReadOnly.

Referenced by GetSerializableTransactionSnapshot().

GetSafeSnapshotBlockingPids()

int GetSafeSnapshotBlockingPids	(	int	blocked_pid,
		int *	output,
		int	output_size
	)

Definition at line 1558 of file predicate.c.

{
    int         num_written = 0;
    dlist_iter  iter;
    SERIALIZABLEXACT *blocking_sxact = NULL;
 
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
 
    /* Find blocked_pid's SERIALIZABLEXACT by linear search. */
    dlist_foreach(iter, &PredXact->activeList)
    {
        SERIALIZABLEXACT *sxact =
            dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
        if (sxact->pid == blocked_pid)
        {
            blocking_sxact = sxact;
            break;
        }
    }
 
    /* Did we find it, and is it currently waiting in GetSafeSnapshot? */
    if (blocking_sxact != NULL && SxactIsDeferrableWaiting(blocking_sxact))
    {
        /* Traverse the list of possible unsafe conflicts collecting PIDs. */
        dlist_foreach(iter, &blocking_sxact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, inLink, iter.cur);
 
            output[num_written++] = possibleUnsafeConflict->sxactOut->pid;
 
            if (num_written >= output_size)
                break;
        }
    }
 
    LWLockRelease(SerializableXactHashLock);
 
    return num_written;
}

References PredXactListData::activeList, dlist_iter::cur, dlist_container, dlist_foreach, fb(), LW_SHARED, LWLockAcquire(), LWLockRelease(), output, PredXact, and SxactIsDeferrableWaiting.

Referenced by pg_isolation_test_session_is_blocked(), and pg_safe_snapshot_blocking_pids().

GetSerializableTransactionSnapshot()

Snapshot GetSerializableTransactionSnapshot

(

Snapshot

snapshot

)

Definition at line 1612 of file predicate.c.

{
    Assert(IsolationIsSerializable());
 
    /*
     * Can't use serializable mode while recovery is still active, as it is,
     * for example, on a hot standby.  We could get here despite the check in
     * check_transaction_isolation() if default_transaction_isolation is set
     * to serializable, so phrase the hint accordingly.
     */
    if (RecoveryInProgress())
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot use serializable mode in a hot standby"),
                 errdetail("\"default_transaction_isolation\" is set to \"serializable\"."),
                 errhint("You can use \"SET default_transaction_isolation = 'repeatable read'\" to change the default.")));
 
    /*
     * A special optimization is available for SERIALIZABLE READ ONLY
     * DEFERRABLE transactions -- we can wait for a suitable snapshot and
     * thereby avoid all SSI overhead once it's running.
     */
    if (XactReadOnly && XactDeferrable)
        return GetSafeSnapshot(snapshot);
 
    return GetSerializableTransactionSnapshotInt(snapshot,
                                                 NULL, InvalidPid);
}

References Assert, ereport, errcode(), errdetail(), errhint(), errmsg, ERROR, fb(), GetSafeSnapshot(), GetSerializableTransactionSnapshotInt(), InvalidPid, IsolationIsSerializable, RecoveryInProgress(), XactDeferrable, and XactReadOnly.

Referenced by GetTransactionSnapshot().

GetSerializableTransactionSnapshotInt()

static Snapshot GetSerializableTransactionSnapshotInt ( Snapshot  snapshot, VirtualTransactionId *  sourcevxid, int  sourcepid  )

static

Definition at line 1694 of file predicate.c.

{
    PGPROC     *proc;
    VirtualTransactionId vxid;
    SERIALIZABLEXACT *sxact,
               *othersxact;
 
    /* We only do this for serializable transactions.  Once. */
    Assert(MySerializableXact == InvalidSerializableXact);
 
    Assert(!RecoveryInProgress());
 
    /*
     * Since all parts of a serializable transaction must use the same
     * snapshot, it is too late to establish one after a parallel operation
     * has begun.
     */
    if (IsInParallelMode())
        elog(ERROR, "cannot establish serializable snapshot during a parallel operation");
 
    proc = MyProc;
    Assert(proc != NULL);
    GET_VXID_FROM_PGPROC(vxid, *proc);
 
    /*
     * First we get the sxact structure, which may involve looping and access
     * to the "finished" list to free a structure for use.
     *
     * We must hold SerializableXactHashLock when taking/checking the snapshot
     * to avoid race conditions, for much the same reasons that
     * GetSnapshotData takes the ProcArrayLock.  Since we might have to
     * release SerializableXactHashLock to call SummarizeOldestCommittedSxact,
     * this means we have to create the sxact first, which is a bit annoying
     * (in particular, an elog(ERROR) in procarray.c would cause us to leak
     * the sxact).  Consider refactoring to avoid this.
     */
#ifdef TEST_SUMMARIZE_SERIAL
    SummarizeOldestCommittedSxact();
#endif
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
    do
    {
        sxact = CreatePredXact();
        /* If null, push out committed sxact to SLRU summary & retry. */
        if (!sxact)
        {
            LWLockRelease(SerializableXactHashLock);
            SummarizeOldestCommittedSxact();
            LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        }
    } while (!sxact);
 
    /* Get the snapshot, or check that it's safe to use */
    if (!sourcevxid)
        snapshot = GetSnapshotData(snapshot);
    else if (!ProcArrayInstallImportedXmin(snapshot->xmin, sourcevxid))
    {
        ReleasePredXact(sxact);
        LWLockRelease(SerializableXactHashLock);
        ereport(ERROR,
                (errcode(ERRCODE_OBJECT_NOT_IN_PREREQUISITE_STATE),
                 errmsg("could not import the requested snapshot"),
                 errdetail("The source process with PID %d is not running anymore.",
                           sourcepid)));
    }
 
    /*
     * If there are no serializable transactions which are not read-only, we
     * can "opt out" of predicate locking and conflict checking for a
     * read-only transaction.
     *
     * The reason this is safe is that a read-only transaction can only become
     * part of a dangerous structure if it overlaps a writable transaction
     * which in turn overlaps a writable transaction which committed before
     * the read-only transaction started.  A new writable transaction can
     * overlap this one, but it can't meet the other condition of overlapping
     * a transaction which committed before this one started.
     */
    if (XactReadOnly && PredXact->WritableSxactCount == 0)
    {
        ReleasePredXact(sxact);
        LWLockRelease(SerializableXactHashLock);
        return snapshot;
    }
 
    /* Initialize the structure. */
    sxact->vxid = vxid;
    sxact->SeqNo.lastCommitBeforeSnapshot = PredXact->LastSxactCommitSeqNo;
    sxact->prepareSeqNo = InvalidSerCommitSeqNo;
    sxact->commitSeqNo = InvalidSerCommitSeqNo;
    dlist_init(&(sxact->outConflicts));
    dlist_init(&(sxact->inConflicts));
    dlist_init(&(sxact->possibleUnsafeConflicts));
    sxact->topXid = GetTopTransactionIdIfAny();
    sxact->finishedBefore = InvalidTransactionId;
    sxact->xmin = snapshot->xmin;
    sxact->pid = MyProcPid;
    sxact->pgprocno = MyProcNumber;
    dlist_init(&sxact->predicateLocks);
    dlist_node_init(&sxact->finishedLink);
    sxact->flags = 0;
    if (XactReadOnly)
    {
        dlist_iter  iter;
 
        sxact->flags |= SXACT_FLAG_READ_ONLY;
 
        /*
         * Register all concurrent r/w transactions as possible conflicts; if
         * all of them commit without any outgoing conflicts to earlier
         * transactions then this snapshot can be deemed safe (and we can run
         * without tracking predicate locks).
         */
        dlist_foreach(iter, &PredXact->activeList)
        {
            othersxact = dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
            if (!SxactIsCommitted(othersxact)
                && !SxactIsDoomed(othersxact)
                && !SxactIsReadOnly(othersxact))
            {
                SetPossibleUnsafeConflict(sxact, othersxact);
            }
        }
 
        /*
         * If we didn't find any possibly unsafe conflicts because every
         * uncommitted writable transaction turned out to be doomed, then we
         * can "opt out" immediately.  See comments above the earlier check
         * for PredXact->WritableSxactCount == 0.
         */
        if (dlist_is_empty(&sxact->possibleUnsafeConflicts))
        {
            ReleasePredXact(sxact);
            LWLockRelease(SerializableXactHashLock);
            return snapshot;
        }
    }
    else
    {
        ++(PredXact->WritableSxactCount);
        Assert(PredXact->WritableSxactCount <=
               (MaxBackends + max_prepared_xacts));
    }
 
    /* Maintain serializable global xmin info. */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount == 0);
        PredXact->SxactGlobalXmin = snapshot->xmin;
        PredXact->SxactGlobalXminCount = 1;
        SerialSetActiveSerXmin(snapshot->xmin);
    }
    else if (TransactionIdEquals(snapshot->xmin, PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount > 0);
        PredXact->SxactGlobalXminCount++;
    }
    else
    {
        Assert(TransactionIdFollows(snapshot->xmin, PredXact->SxactGlobalXmin));
    }
 
    MySerializableXact = sxact;
    MyXactDidWrite = false;     /* haven't written anything yet */
 
    LWLockRelease(SerializableXactHashLock);
 
    CreateLocalPredicateLockHash();
 
    return snapshot;
}

References PredXactListData::activeList, Assert, CreateLocalPredicateLockHash(), CreatePredXact(), dlist_iter::cur, dlist_container, dlist_foreach, dlist_init(), dlist_is_empty(), dlist_node_init(), elog, ereport, errcode(), errdetail(), errmsg, ERROR, fb(), GET_VXID_FROM_PGPROC, GetSnapshotData(), GetTopTransactionIdIfAny(), InvalidSerCommitSeqNo, InvalidSerializableXact, InvalidTransactionId, IsInParallelMode(), PredXactListData::LastSxactCommitSeqNo, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), max_prepared_xacts, MaxBackends, MyProc, MyProcNumber, MyProcPid, MySerializableXact, MyXactDidWrite, PredXact, ProcArrayInstallImportedXmin(), RecoveryInProgress(), ReleasePredXact(), SerialSetActiveSerXmin(), SetPossibleUnsafeConflict(), SummarizeOldestCommittedSxact(), SXACT_FLAG_READ_ONLY, PredXactListData::SxactGlobalXmin, PredXactListData::SxactGlobalXminCount, SxactIsCommitted, SxactIsDoomed, SxactIsReadOnly, TransactionIdEquals, TransactionIdFollows(), TransactionIdIsValid, PredXactListData::WritableSxactCount, XactReadOnly, and SnapshotData::xmin.

Referenced by GetSafeSnapshot(), GetSerializableTransactionSnapshot(), and SetSerializableTransactionSnapshot().

MaxPredicateChildLocks()

static int MaxPredicateChildLocks ( const PREDICATELOCKTARGETTAG *  tag )

static

Definition at line 2219 of file predicate.c.

{
    switch (GET_PREDICATELOCKTARGETTAG_TYPE(*tag))
    {
        case PREDLOCKTAG_RELATION:
            return max_predicate_locks_per_relation < 0
                ? (max_predicate_locks_per_xact
                   / (-max_predicate_locks_per_relation)) - 1
                : max_predicate_locks_per_relation;
 
        case PREDLOCKTAG_PAGE:
            return max_predicate_locks_per_page;
 
        case PREDLOCKTAG_TUPLE:
 
            /*
             * not reachable: nothing is finer-granularity than a tuple, so we
             * should never try to promote to it.
             */
            Assert(false);
            return 0;
    }
 
    /* not reachable */
    Assert(false);
    return 0;
}

References Assert, GET_PREDICATELOCKTARGETTAG_TYPE, max_predicate_locks_per_page, max_predicate_locks_per_relation, max_predicate_locks_per_xact, PREDLOCKTAG_PAGE, PREDLOCKTAG_RELATION, and PREDLOCKTAG_TUPLE.

Referenced by CheckAndPromotePredicateLockRequest().

OnConflict_CheckForSerializationFailure()

static void OnConflict_CheckForSerializationFailure ( const SERIALIZABLEXACT *  reader, SERIALIZABLEXACT *  writer  )

static

Definition at line 4466 of file predicate.c.

{
    bool        failure;
 
    Assert(LWLockHeldByMe(SerializableXactHashLock));
 
    failure = false;
 
    /*------------------------------------------------------------------------
     * Check for already-committed writer with rw-conflict out flagged
     * (conflict-flag on W means that T2 committed before W):
     *
     *      R ------> W ------> T2
     *          rw        rw
     *
     * That is a dangerous structure, so we must abort. (Since the writer
     * has already committed, we must be the reader)
     *------------------------------------------------------------------------
     */
    if (SxactIsCommitted(writer)
        && (SxactHasConflictOut(writer) || SxactHasSummaryConflictOut(writer)))
        failure = true;
 
    /*------------------------------------------------------------------------
     * Check whether the writer has become a pivot with an out-conflict
     * committed transaction (T2), and T2 committed first:
     *
     *      R ------> W ------> T2
     *          rw        rw
     *
     * Because T2 must've committed first, there is no anomaly if:
     * - the reader committed before T2
     * - the writer committed before T2
     * - the reader is a READ ONLY transaction and the reader was concurrent
     *   with T2 (= reader acquired its snapshot before T2 committed)
     *
     * We also handle the case that T2 is prepared but not yet committed
     * here. In that case T2 has already checked for conflicts, so if it
     * commits first, making the above conflict real, it's too late for it
     * to abort.
     *------------------------------------------------------------------------
     */
    if (!failure && SxactHasSummaryConflictOut(writer))
        failure = true;
    else if (!failure)
    {
        dlist_iter  iter;
 
        dlist_foreach(iter, &writer->outConflicts)
        {
            RWConflict  conflict =
                dlist_container(RWConflictData, outLink, iter.cur);
            SERIALIZABLEXACT *t2 = conflict->sxactIn;
 
            if (SxactIsPrepared(t2)
                && (!SxactIsCommitted(reader)
                    || t2->prepareSeqNo <= reader->commitSeqNo)
                && (!SxactIsCommitted(writer)
                    || t2->prepareSeqNo <= writer->commitSeqNo)
                && (!SxactIsReadOnly(reader)
                    || t2->prepareSeqNo <= reader->SeqNo.lastCommitBeforeSnapshot))
            {
                failure = true;
                break;
            }
        }
    }
 
    /*------------------------------------------------------------------------
     * Check whether the reader has become a pivot with a writer
     * that's committed (or prepared):
     *
     *      T0 ------> R ------> W
     *           rw        rw
     *
     * Because W must've committed first for an anomaly to occur, there is no
     * anomaly if:
     * - T0 committed before the writer
     * - T0 is READ ONLY, and overlaps the writer
     *------------------------------------------------------------------------
     */
    if (!failure && SxactIsPrepared(writer) && !SxactIsReadOnly(reader))
    {
        if (SxactHasSummaryConflictIn(reader))
        {
            failure = true;
        }
        else
        {
            dlist_iter  iter;
 
            /*
             * The unconstify is needed as we have no const version of
             * dlist_foreach().
             */
            dlist_foreach(iter, &unconstify(SERIALIZABLEXACT *, reader)->inConflicts)
            {
                const RWConflict conflict =
                    dlist_container(RWConflictData, inLink, iter.cur);
                const SERIALIZABLEXACT *t0 = conflict->sxactOut;
 
                if (!SxactIsDoomed(t0)
                    && (!SxactIsCommitted(t0)
                        || t0->commitSeqNo >= writer->prepareSeqNo)
                    && (!SxactIsReadOnly(t0)
                        || t0->SeqNo.lastCommitBeforeSnapshot >= writer->prepareSeqNo))
                {
                    failure = true;
                    break;
                }
            }
        }
    }
 
    if (failure)
    {
        /*
         * We have to kill a transaction to avoid a possible anomaly from
         * occurring. If the writer is us, we can just ereport() to cause a
         * transaction abort. Otherwise we flag the writer for termination,
         * causing it to abort when it tries to commit. However, if the writer
         * is a prepared transaction, already prepared, we can't abort it
         * anymore, so we have to kill the reader instead.
         */
        if (MySerializableXact == writer)
        {
            LWLockRelease(SerializableXactHashLock);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on identification as a pivot, during write."),
                     errhint("The transaction might succeed if retried.")));
        }
        else if (SxactIsPrepared(writer))
        {
            LWLockRelease(SerializableXactHashLock);
 
            /* if we're not the writer, we have to be the reader */
            Assert(MySerializableXact == reader);
            ereport(ERROR,
                    (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                     errmsg("could not serialize access due to read/write dependencies among transactions"),
                     errdetail_internal("Reason code: Canceled on conflict out to pivot %u, during read.", writer->topXid),
                     errhint("The transaction might succeed if retried.")));
        }
        writer->flags |= SXACT_FLAG_DOOMED;
    }
}

References Assert, SERIALIZABLEXACT::commitSeqNo, dlist_iter::cur, dlist_container, dlist_foreach, ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errdetail_internal(), errhint(), errmsg, ERROR, fb(), SERIALIZABLEXACT::lastCommitBeforeSnapshot, LWLockHeldByMe(), LWLockRelease(), MySerializableXact, SERIALIZABLEXACT::SeqNo, SXACT_FLAG_DOOMED, SxactHasConflictOut, SxactHasSummaryConflictIn, SxactHasSummaryConflictOut, SxactIsCommitted, SxactIsDoomed, SxactIsPrepared, SxactIsReadOnly, and unconstify.

Referenced by FlagRWConflict().

PageIsPredicateLocked()

bool PageIsPredicateLocked	(	Relation	relation,
		BlockNumber	blkno
	)

Definition at line 1938 of file predicate.c.

{
    PREDICATELOCKTARGETTAG targettag;
    uint32      targettaghash;
    LWLock     *partitionLock;
    PREDICATELOCKTARGET *target;
 
    SET_PREDICATELOCKTARGETTAG_PAGE(targettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    blkno);
 
    targettaghash = PredicateLockTargetTagHashCode(&targettag);
    partitionLock = PredicateLockHashPartitionLock(targettaghash);
    LWLockAcquire(partitionLock, LW_SHARED);
    target = (PREDICATELOCKTARGET *)
        hash_search_with_hash_value(PredicateLockTargetHash,
                                    &targettag, targettaghash,
                                    HASH_FIND, NULL);
    LWLockRelease(partitionLock);
 
    return (target != NULL);
}

References RelFileLocator::dbOid, fb(), HASH_FIND, hash_search_with_hash_value(), LW_SHARED, LWLockAcquire(), LWLockRelease(), PredicateLockHashPartitionLock, PredicateLockTargetHash, PredicateLockTargetTagHashCode, RelationData::rd_id, RelationData::rd_locator, and SET_PREDICATELOCKTARGETTAG_PAGE.

PostPrepare_PredicateLocks()

void PostPrepare_PredicateLocks

(

FullTransactionId

fxid

)

Definition at line 4789 of file predicate.c.

{
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    Assert(SxactIsPrepared(MySerializableXact));
 
    MySerializableXact->pid = 0;
    MySerializableXact->pgprocno = INVALID_PROC_NUMBER;
 
    hash_destroy(LocalPredicateLockHash);
    LocalPredicateLockHash = NULL;
 
    MySerializableXact = InvalidSerializableXact;
    MyXactDidWrite = false;
}

References Assert, fb(), hash_destroy(), INVALID_PROC_NUMBER, InvalidSerializableXact, LocalPredicateLockHash, MySerializableXact, MyXactDidWrite, SERIALIZABLEXACT::pgprocno, SERIALIZABLEXACT::pid, and SxactIsPrepared.

Referenced by PrepareTransaction().

PreCommit_CheckForSerializationFailure()

void PreCommit_CheckForSerializationFailure

(

void

)

Definition at line 4633 of file predicate.c.

{
    dlist_iter  near_iter;
 
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    Assert(IsolationIsSerializable());
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * Check if someone else has already decided that we need to die.  Since
     * we set our own DOOMED flag when partially releasing, ignore in that
     * case.
     */
    if (SxactIsDoomed(MySerializableXact) &&
        !SxactIsPartiallyReleased(MySerializableXact))
    {
        LWLockRelease(SerializableXactHashLock);
        ereport(ERROR,
                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                 errdetail_internal("Reason code: Canceled on identification as a pivot, during commit attempt."),
                 errhint("The transaction might succeed if retried.")));
    }
 
    dlist_foreach(near_iter, &MySerializableXact->inConflicts)
    {
        RWConflict  nearConflict =
            dlist_container(RWConflictData, inLink, near_iter.cur);
 
        if (!SxactIsCommitted(nearConflict->sxactOut)
            && !SxactIsDoomed(nearConflict->sxactOut))
        {
            dlist_iter  far_iter;
 
            dlist_foreach(far_iter, &nearConflict->sxactOut->inConflicts)
            {
                RWConflict  farConflict =
                    dlist_container(RWConflictData, inLink, far_iter.cur);
 
                if (farConflict->sxactOut == MySerializableXact
                    || (!SxactIsCommitted(farConflict->sxactOut)
                        && !SxactIsReadOnly(farConflict->sxactOut)
                        && !SxactIsDoomed(farConflict->sxactOut)))
                {
                    /*
                     * Normally, we kill the pivot transaction to make sure we
                     * make progress if the failing transaction is retried.
                     * However, we can't kill it if it's already prepared, so
                     * in that case we commit suicide instead.
                     */
                    if (SxactIsPrepared(nearConflict->sxactOut))
                    {
                        LWLockRelease(SerializableXactHashLock);
                        ereport(ERROR,
                                (errcode(ERRCODE_T_R_SERIALIZATION_FAILURE),
                                 errmsg("could not serialize access due to read/write dependencies among transactions"),
                                 errdetail_internal("Reason code: Canceled on commit attempt with conflict in from prepared pivot."),
                                 errhint("The transaction might succeed if retried.")));
                    }
                    nearConflict->sxactOut->flags |= SXACT_FLAG_DOOMED;
                    break;
                }
            }
        }
    }
 
    MySerializableXact->prepareSeqNo = ++(PredXact->LastSxactCommitSeqNo);
    MySerializableXact->flags |= SXACT_FLAG_PREPARED;
 
    LWLockRelease(SerializableXactHashLock);
}

References Assert, dlist_container, dlist_foreach, ereport, errcode(), ERRCODE_T_R_SERIALIZATION_FAILURE, errdetail_internal(), errhint(), errmsg, ERROR, fb(), SERIALIZABLEXACT::flags, SERIALIZABLEXACT::inConflicts, InvalidSerializableXact, IsolationIsSerializable, PredXactListData::LastSxactCommitSeqNo, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MySerializableXact, PredXact, SERIALIZABLEXACT::prepareSeqNo, SXACT_FLAG_DOOMED, SXACT_FLAG_PREPARED, SxactIsCommitted, SxactIsDoomed, SxactIsPartiallyReleased, SxactIsPrepared, and SxactIsReadOnly.

Referenced by CommitTransaction(), and PrepareTransaction().

predicatelock_hash()

static uint32 predicatelock_hash ( const void *  key, Size  keysize  )

static

Definition at line 1351 of file predicate.c.

{
    const PREDICATELOCKTAG *predicatelocktag = (const PREDICATELOCKTAG *) key;
    uint32      targethash;
 
    Assert(keysize == sizeof(PREDICATELOCKTAG));
 
    /* Look into the associated target object, and compute its hash code */
    targethash = PredicateLockTargetTagHashCode(&predicatelocktag->myTarget->tag);
 
    return PredicateLockHashCodeFromTargetHashCode(predicatelocktag, targethash);
}

References Assert, fb(), PredicateLockHashCodeFromTargetHashCode, and PredicateLockTargetTagHashCode.

Referenced by PredicateLockShmemRequest().

predicatelock_twophase_recover()

void predicatelock_twophase_recover	(	FullTransactionId	fxid,
		uint16	info,
		void *	recdata,
		uint32	len
	)

Definition at line 4839 of file predicate.c.

{
    TwoPhasePredicateRecord *record;
    TransactionId xid = XidFromFullTransactionId(fxid);
 
    Assert(len == sizeof(TwoPhasePredicateRecord));
 
    record = (TwoPhasePredicateRecord *) recdata;
 
    Assert((record->type == TWOPHASEPREDICATERECORD_XACT) ||
           (record->type == TWOPHASEPREDICATERECORD_LOCK));
 
    if (record->type == TWOPHASEPREDICATERECORD_XACT)
    {
        /* Per-transaction record. Set up a SERIALIZABLEXACT. */
        TwoPhasePredicateXactRecord *xactRecord;
        SERIALIZABLEXACT *sxact;
        SERIALIZABLEXID *sxid;
        SERIALIZABLEXIDTAG sxidtag;
        bool        found;
 
        xactRecord = (TwoPhasePredicateXactRecord *) &record->data.xactRecord;
 
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
        sxact = CreatePredXact();
        if (!sxact)
            ereport(ERROR,
                    (errcode(ERRCODE_OUT_OF_MEMORY),
                     errmsg("out of shared memory")));
 
        /* vxid for a prepared xact is INVALID_PROC_NUMBER/xid; no pid */
        sxact->vxid.procNumber = INVALID_PROC_NUMBER;
        sxact->vxid.localTransactionId = (LocalTransactionId) xid;
        sxact->pid = 0;
        sxact->pgprocno = INVALID_PROC_NUMBER;
 
        /* a prepared xact hasn't committed yet */
        sxact->prepareSeqNo = RecoverySerCommitSeqNo;
        sxact->commitSeqNo = InvalidSerCommitSeqNo;
        sxact->finishedBefore = InvalidTransactionId;
 
        sxact->SeqNo.lastCommitBeforeSnapshot = RecoverySerCommitSeqNo;
 
        /*
         * Don't need to track this; no transactions running at the time the
         * recovered xact started are still active, except possibly other
         * prepared xacts and we don't care whether those are RO_SAFE or not.
         */
        dlist_init(&(sxact->possibleUnsafeConflicts));
 
        dlist_init(&(sxact->predicateLocks));
        dlist_node_init(&sxact->finishedLink);
 
        sxact->topXid = xid;
        sxact->xmin = xactRecord->xmin;
        sxact->flags = xactRecord->flags;
        Assert(SxactIsPrepared(sxact));
        if (!SxactIsReadOnly(sxact))
        {
            ++(PredXact->WritableSxactCount);
            Assert(PredXact->WritableSxactCount <=
                   (MaxBackends + max_prepared_xacts));
        }
 
        /*
         * We don't know whether the transaction had any conflicts or not, so
         * we'll conservatively assume that it had both a conflict in and a
         * conflict out, and represent that with the summary conflict flags.
         */
        dlist_init(&(sxact->outConflicts));
        dlist_init(&(sxact->inConflicts));
        sxact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
        sxact->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
 
        /* Register the transaction's xid */
        sxidtag.xid = xid;
        sxid = (SERIALIZABLEXID *) hash_search(SerializableXidHash,
                                               &sxidtag,
                                               HASH_ENTER, &found);
        Assert(sxid != NULL);
        Assert(!found);
        sxid->myXact = sxact;
 
        /*
         * Update global xmin. Note that this is a special case compared to
         * registering a normal transaction, because the global xmin might go
         * backwards. That's OK, because until recovery is over we're not
         * going to complete any transactions or create any non-prepared
         * transactions, so there's no danger of throwing away.
         */
        if ((!TransactionIdIsValid(PredXact->SxactGlobalXmin)) ||
            (TransactionIdFollows(PredXact->SxactGlobalXmin, sxact->xmin)))
        {
            PredXact->SxactGlobalXmin = sxact->xmin;
            PredXact->SxactGlobalXminCount = 1;
            SerialSetActiveSerXmin(sxact->xmin);
        }
        else if (TransactionIdEquals(sxact->xmin, PredXact->SxactGlobalXmin))
        {
            Assert(PredXact->SxactGlobalXminCount > 0);
            PredXact->SxactGlobalXminCount++;
        }
 
        LWLockRelease(SerializableXactHashLock);
    }
    else if (record->type == TWOPHASEPREDICATERECORD_LOCK)
    {
        /* Lock record. Recreate the PREDICATELOCK */
        TwoPhasePredicateLockRecord *lockRecord;
        SERIALIZABLEXID *sxid;
        SERIALIZABLEXACT *sxact;
        SERIALIZABLEXIDTAG sxidtag;
        uint32      targettaghash;
 
        lockRecord = (TwoPhasePredicateLockRecord *) &record->data.lockRecord;
        targettaghash = PredicateLockTargetTagHashCode(&lockRecord->target);
 
        LWLockAcquire(SerializableXactHashLock, LW_SHARED);
        sxidtag.xid = xid;
        sxid = (SERIALIZABLEXID *)
            hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
        LWLockRelease(SerializableXactHashLock);
 
        Assert(sxid != NULL);
        sxact = sxid->myXact;
        Assert(sxact != InvalidSerializableXact);
 
        CreatePredicateLock(&lockRecord->target, targettaghash, sxact);
    }
}

References Assert, CreatePredicateLock(), CreatePredXact(), TwoPhasePredicateRecord::data, dlist_init(), dlist_node_init(), ereport, errcode(), errmsg, ERROR, fb(), TwoPhasePredicateXactRecord::flags, HASH_ENTER, HASH_FIND, hash_search(), INVALID_PROC_NUMBER, InvalidSerCommitSeqNo, InvalidSerializableXact, InvalidTransactionId, len, TwoPhasePredicateRecord::lockRecord, LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockRelease(), max_prepared_xacts, MaxBackends, PredicateLockTargetTagHashCode, PredXact, RecoverySerCommitSeqNo, SerializableXidHash, SerialSetActiveSerXmin(), SXACT_FLAG_SUMMARY_CONFLICT_IN, SXACT_FLAG_SUMMARY_CONFLICT_OUT, PredXactListData::SxactGlobalXmin, PredXactListData::SxactGlobalXminCount, SxactIsPrepared, SxactIsReadOnly, TwoPhasePredicateLockRecord::target, TransactionIdEquals, TransactionIdFollows(), TransactionIdIsValid, TWOPHASEPREDICATERECORD_LOCK, TWOPHASEPREDICATERECORD_XACT, TwoPhasePredicateRecord::type, PredXactListData::WritableSxactCount, TwoPhasePredicateRecord::xactRecord, XidFromFullTransactionId, and TwoPhasePredicateXactRecord::xmin.

PredicateLockAcquire()

static void PredicateLockAcquire ( const PREDICATELOCKTARGETTAG *  targettag )

static

Definition at line 2447 of file predicate.c.

{
    uint32      targettaghash;
    bool        found;
    LOCALPREDICATELOCK *locallock;
 
    /* Do we have the lock already, or a covering lock? */
    if (PredicateLockExists(targettag))
        return;
 
    if (CoarserLockCovers(targettag))
        return;
 
    /* the same hash and LW lock apply to the lock target and the local lock. */
    targettaghash = PredicateLockTargetTagHashCode(targettag);
 
    /* Acquire lock in local table */
    locallock = (LOCALPREDICATELOCK *)
        hash_search_with_hash_value(LocalPredicateLockHash,
                                    targettag, targettaghash,
                                    HASH_ENTER, &found);
    locallock->held = true;
    if (!found)
        locallock->childLocks = 0;
 
    /* Actually create the lock */
    CreatePredicateLock(targettag, targettaghash, MySerializableXact);
 
    /*
     * Lock has been acquired. Check whether it should be promoted to a
     * coarser granularity, or whether there are finer-granularity locks to
     * clean up.
     */
    if (CheckAndPromotePredicateLockRequest(targettag))
    {
        /*
         * Lock request was promoted to a coarser-granularity lock, and that
         * lock was acquired. It will delete this lock and any of its
         * children, so we're done.
         */
    }
    else
    {
        /* Clean up any finer-granularity locks */
        if (GET_PREDICATELOCKTARGETTAG_TYPE(*targettag) != PREDLOCKTAG_TUPLE)
            DeleteChildTargetLocks(targettag);
    }
}

References CheckAndPromotePredicateLockRequest(), CoarserLockCovers(), CreatePredicateLock(), DeleteChildTargetLocks(), fb(), GET_PREDICATELOCKTARGETTAG_TYPE, HASH_ENTER, hash_search_with_hash_value(), LocalPredicateLockHash, MySerializableXact, PredicateLockExists(), PredicateLockTargetTagHashCode, and PREDLOCKTAG_TUPLE.

Referenced by CheckAndPromotePredicateLockRequest(), PredicateLockPage(), PredicateLockRelation(), and PredicateLockTID().

PredicateLockExists()

static bool PredicateLockExists ( const PREDICATELOCKTARGETTAG *  targettag )

static

Definition at line 1975 of file predicate.c.

{
    LOCALPREDICATELOCK *lock;
 
    /* check local hash table */
    lock = (LOCALPREDICATELOCK *) hash_search(LocalPredicateLockHash,
                                              targettag,
                                              HASH_FIND, NULL);
 
    if (!lock)
        return false;
 
    /*
     * Found entry in the table, but still need to check whether it's actually
     * held -- it could just be a parent of some held lock.
     */
    return lock->held;
}

References fb(), HASH_FIND, hash_search(), LOCALPREDICATELOCK::held, and LocalPredicateLockHash.

Referenced by CoarserLockCovers(), PredicateLockAcquire(), and PredicateLockTID().

PredicateLockingNeededForRelation()

static bool PredicateLockingNeededForRelation ( Relation  relation )

inlinestatic

Definition at line 512 of file predicate.c.

{
    return !(relation->rd_id < FirstUnpinnedObjectId ||
             RelationUsesLocalBuffers(relation));
}

References FirstUnpinnedObjectId, RelationData::rd_id, and RelationUsesLocalBuffers.

Referenced by DropAllPredicateLocksFromTable(), PredicateLockPageSplit(), SerializationNeededForRead(), and SerializationNeededForWrite().

PredicateLockPage()

void PredicateLockPage	(	Relation	relation,
		BlockNumber	blkno,
		Snapshot	snapshot
	)

Definition at line 2529 of file predicate.c.

{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    SET_PREDICATELOCKTARGETTAG_PAGE(tag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    blkno);
    PredicateLockAcquire(&tag);
}

References RelFileLocator::dbOid, PredicateLockAcquire(), RelationData::rd_id, RelationData::rd_locator, SerializationNeededForRead(), and SET_PREDICATELOCKTARGETTAG_PAGE.

Referenced by _bt_readpage(), _hash_first(), _hash_readnext(), collectMatchBitmap(), gistScanPage(), IndexOnlyNext(), moveRightIfItNeeded(), scanPendingInsert(), and startScanEntry().

PredicateLockPageCombine()

void PredicateLockPageCombine	(	Relation	relation,
		BlockNumber	oldblkno,
		BlockNumber	newblkno
	)

Definition at line 3159 of file predicate.c.

{
    /*
     * Page combines differ from page splits in that we ought to be able to
     * remove the locks on the old page after transferring them to the new
     * page, instead of duplicating them. However, because we can't edit other
     * backends' local lock tables, removing the old lock would leave them
     * with an entry in their LocalPredicateLockHash for a lock they're not
     * holding, which isn't acceptable. So we wind up having to do the same
     * work as a page split, acquiring a lock on the new page and keeping the
     * old page locked too. That can lead to some false positives, but should
     * be rare in practice.
     */
    PredicateLockPageSplit(relation, oldblkno, newblkno);
}

References fb(), and PredicateLockPageSplit().

Referenced by _bt_mark_page_halfdead(), and ginDeletePostingPage().

PredicateLockPageSplit()

void PredicateLockPageSplit	(	Relation	relation,
		BlockNumber	oldblkno,
		BlockNumber	newblkno
	)

Definition at line 3074 of file predicate.c.

{
    PREDICATELOCKTARGETTAG oldtargettag;
    PREDICATELOCKTARGETTAG newtargettag;
    bool        success;
 
    /*
     * Bail out quickly if there are no serializable transactions running.
     *
     * It's safe to do this check without taking any additional locks. Even if
     * a serializable transaction starts concurrently, we know it can't take
     * any SIREAD locks on the page being split because the caller is holding
     * the associated buffer page lock. Memory reordering isn't an issue; the
     * memory barrier in the LWLock acquisition guarantees that this read
     * occurs while the buffer page lock is held.
     */
    if (!TransactionIdIsValid(PredXact->SxactGlobalXmin))
        return;
 
    if (!PredicateLockingNeededForRelation(relation))
        return;
 
    Assert(oldblkno != newblkno);
    Assert(BlockNumberIsValid(oldblkno));
    Assert(BlockNumberIsValid(newblkno));
 
    SET_PREDICATELOCKTARGETTAG_PAGE(oldtargettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    oldblkno);
    SET_PREDICATELOCKTARGETTAG_PAGE(newtargettag,
                                    relation->rd_locator.dbOid,
                                    relation->rd_id,
                                    newblkno);
 
    LWLockAcquire(SerializablePredicateListLock, LW_EXCLUSIVE);
 
    /*
     * Try copying the locks over to the new page's tag, creating it if
     * necessary.
     */
    success = TransferPredicateLocksToNewTarget(oldtargettag,
                                                newtargettag,
                                                false);
 
    if (!success)
    {
        /*
         * No more predicate lock entries are available. Failure isn't an
         * option here, so promote the page lock to a relation lock.
         */
 
        /* Get the parent relation lock's lock tag */
        success = GetParentPredicateLockTag(&oldtargettag,
                                            &newtargettag);
        Assert(success);
 
        /*
         * Move the locks to the parent. This shouldn't fail.
         *
         * Note that here we are removing locks held by other backends,
         * leading to a possible inconsistency in their local lock hash table.
         * This is OK because we're replacing it with a lock that covers the
         * old one.
         */
        success = TransferPredicateLocksToNewTarget(oldtargettag,
                                                    newtargettag,
                                                    true);
        Assert(success);
    }
 
    LWLockRelease(SerializablePredicateListLock);
}

References Assert, BlockNumberIsValid(), RelFileLocator::dbOid, fb(), GetParentPredicateLockTag(), LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), PredicateLockingNeededForRelation(), PredXact, RelationData::rd_id, RelationData::rd_locator, SET_PREDICATELOCKTARGETTAG_PAGE, success, PredXactListData::SxactGlobalXmin, TransactionIdIsValid, and TransferPredicateLocksToNewTarget().

Referenced by _bt_insertonpg(), _hash_splitbucket(), createPostingTree(), ginPlaceToPage(), gistplacetopage(), and PredicateLockPageCombine().

PredicateLockRelation()

void PredicateLockRelation	(	Relation	relation,
		Snapshot	snapshot
	)

Definition at line 2506 of file predicate.c.

{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    SET_PREDICATELOCKTARGETTAG_RELATION(tag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    PredicateLockAcquire(&tag);
}

References RelFileLocator::dbOid, PredicateLockAcquire(), RelationData::rd_id, RelationData::rd_locator, SerializationNeededForRead(), and SET_PREDICATELOCKTARGETTAG_RELATION.

Referenced by _bt_endpoint(), _bt_first(), heap_beginscan(), and index_beginscan_internal().

PredicateLockShmemAttach()

static void PredicateLockShmemAttach ( void *  arg )

static

Definition at line 1328 of file predicate.c.

{
    /* This never changes, so let's keep a local copy. */
    OldCommittedSxact = PredXact->OldCommittedSxact;
 
    /* Pre-calculate the hash and partition lock of the scratch entry */
    ScratchTargetTagHash = PredicateLockTargetTagHashCode(&ScratchTargetTag);
    ScratchPartitionLock = PredicateLockHashPartitionLock(ScratchTargetTagHash);
}

References OldCommittedSxact, PredXactListData::OldCommittedSxact, PredicateLockHashPartitionLock, PredicateLockTargetTagHashCode, PredXact, ScratchPartitionLock, ScratchTargetTag, and ScratchTargetTagHash.

PredicateLockShmemInit()

static void PredicateLockShmemInit ( void *  arg )

static

Definition at line 1244 of file predicate.c.

{
    int         max_rw_conflicts;
    bool        found;
 
    /*
     * Reserve a dummy entry in the hash table; we use it to make sure there's
     * always one entry available when we need to split or combine a page,
     * because running out of space there could mean aborting a
     * non-serializable transaction.
     */
    (void) hash_search(PredicateLockTargetHash, &ScratchTargetTag,
                       HASH_ENTER, &found);
    Assert(!found);
 
    dlist_init(&PredXact->availableList);
    dlist_init(&PredXact->activeList);
    PredXact->SxactGlobalXmin = InvalidTransactionId;
    PredXact->SxactGlobalXminCount = 0;
    PredXact->WritableSxactCount = 0;
    PredXact->LastSxactCommitSeqNo = FirstNormalSerCommitSeqNo - 1;
    PredXact->CanPartialClearThrough = 0;
    PredXact->HavePartialClearedThrough = 0;
    PredXact->element
        = (SERIALIZABLEXACT *) ((char *) PredXact + PredXactListDataSize);
    /* Add all elements to available list, clean. */
    for (int i = 0; i < max_serializable_xacts; i++)
    {
        LWLockInitialize(&PredXact->element[i].perXactPredicateListLock,
                         LWTRANCHE_PER_XACT_PREDICATE_LIST);
        dlist_push_tail(&PredXact->availableList, &PredXact->element[i].xactLink);
    }
    PredXact->OldCommittedSxact = CreatePredXact();
    SetInvalidVirtualTransactionId(PredXact->OldCommittedSxact->vxid);
    PredXact->OldCommittedSxact->prepareSeqNo = 0;
    PredXact->OldCommittedSxact->commitSeqNo = 0;
    PredXact->OldCommittedSxact->SeqNo.lastCommitBeforeSnapshot = 0;
    dlist_init(&PredXact->OldCommittedSxact->outConflicts);
    dlist_init(&PredXact->OldCommittedSxact->inConflicts);
    dlist_init(&PredXact->OldCommittedSxact->predicateLocks);
    dlist_node_init(&PredXact->OldCommittedSxact->finishedLink);
    dlist_init(&PredXact->OldCommittedSxact->possibleUnsafeConflicts);
    PredXact->OldCommittedSxact->topXid = InvalidTransactionId;
    PredXact->OldCommittedSxact->finishedBefore = InvalidTransactionId;
    PredXact->OldCommittedSxact->xmin = InvalidTransactionId;
    PredXact->OldCommittedSxact->flags = SXACT_FLAG_COMMITTED;
    PredXact->OldCommittedSxact->pid = 0;
    PredXact->OldCommittedSxact->pgprocno = INVALID_PROC_NUMBER;
 
    /* Initialize the rw-conflict pool */
    dlist_init(&RWConflictPool->availableList);
    RWConflictPool->element = (RWConflict) ((char *) RWConflictPool +
                                            RWConflictPoolHeaderDataSize);
 
    max_rw_conflicts = max_serializable_xacts * 5;
 
    /* Add all elements to available list, clean. */
    for (int i = 0; i < max_rw_conflicts; i++)
    {
        dlist_push_tail(&RWConflictPool->availableList,
                        &RWConflictPool->element[i].outLink);
    }
 
    /* Initialize the list of finished serializable transactions */
    dlist_init(FinishedSerializableTransactions);
 
    /* Initialize SerialControl to reflect empty SLRU. */
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
    serialControl->headPage = -1;
    serialControl->headXid = InvalidTransactionId;
    serialControl->tailXid = InvalidTransactionId;
    LWLockRelease(SerialControlLock);
 
    SlruPagePrecedesUnitTests(SerialSlruCtl, SERIAL_ENTRIESPERPAGE);
 
    /* This never changes, so let's keep a local copy. */
    OldCommittedSxact = PredXact->OldCommittedSxact;
 
    /* Pre-calculate the hash and partition lock of the scratch entry */
    ScratchTargetTagHash = PredicateLockTargetTagHashCode(&ScratchTargetTag);
    ScratchPartitionLock = PredicateLockHashPartitionLock(ScratchTargetTagHash);
}

References PredXactListData::activeList, Assert, PredXactListData::availableList, RWConflictPoolHeaderData::availableList, PredXactListData::CanPartialClearThrough, SERIALIZABLEXACT::commitSeqNo, CreatePredXact(), dlist_init(), dlist_node_init(), dlist_push_tail(), PredXactListData::element, RWConflictPoolHeaderData::element, fb(), SERIALIZABLEXACT::finishedBefore, SERIALIZABLEXACT::finishedLink, FinishedSerializableTransactions, FirstNormalSerCommitSeqNo, SERIALIZABLEXACT::flags, HASH_ENTER, hash_search(), PredXactListData::HavePartialClearedThrough, SerialControlData::headPage, SerialControlData::headXid, i, SERIALIZABLEXACT::inConflicts, INVALID_PROC_NUMBER, InvalidTransactionId, SERIALIZABLEXACT::lastCommitBeforeSnapshot, PredXactListData::LastSxactCommitSeqNo, LW_EXCLUSIVE, LWLockAcquire(), LWLockInitialize(), LWLockRelease(), max_serializable_xacts, OldCommittedSxact, PredXactListData::OldCommittedSxact, SERIALIZABLEXACT::outConflicts, RWConflictData::outLink, SERIALIZABLEXACT::perXactPredicateListLock, SERIALIZABLEXACT::pgprocno, SERIALIZABLEXACT::pid, SERIALIZABLEXACT::possibleUnsafeConflicts, PredicateLockHashPartitionLock, SERIALIZABLEXACT::predicateLocks, PredicateLockTargetHash, PredicateLockTargetTagHashCode, PredXact, PredXactListDataSize, SERIALIZABLEXACT::prepareSeqNo, RWConflictPool, RWConflictPoolHeaderDataSize, ScratchPartitionLock, ScratchTargetTag, ScratchTargetTagHash, SERIALIZABLEXACT::SeqNo, SERIAL_ENTRIESPERPAGE, serialControl, SerialSlruCtl, SetInvalidVirtualTransactionId, SlruPagePrecedesUnitTests, SXACT_FLAG_COMMITTED, PredXactListData::SxactGlobalXmin, PredXactListData::SxactGlobalXminCount, SerialControlData::tailXid, SERIALIZABLEXACT::topXid, SERIALIZABLEXACT::vxid, PredXactListData::WritableSxactCount, SERIALIZABLEXACT::xactLink, and SERIALIZABLEXACT::xmin.

PredicateLockShmemRequest()

static void PredicateLockShmemRequest ( void *  arg )

static

Definition at line 1119 of file predicate.c.

{
    int64       max_predicate_lock_targets;
    int64       max_predicate_locks;
    int64       max_rw_conflicts;
 
    /*
     * Register hash table for PREDICATELOCKTARGET structs.  This stores
     * per-predicate-lock-target information.
     */
    max_predicate_lock_targets = NPREDICATELOCKTARGETENTS();
 
    ShmemRequestHash(.name = "PREDICATELOCKTARGET hash",
                     .nelems = max_predicate_lock_targets,
                     .ptr = &PredicateLockTargetHash,
                     .hash_info.keysize = sizeof(PREDICATELOCKTARGETTAG),
                     .hash_info.entrysize = sizeof(PREDICATELOCKTARGET),
                     .hash_info.num_partitions = NUM_PREDICATELOCK_PARTITIONS,
                     .hash_flags = HASH_ELEM | HASH_BLOBS | HASH_PARTITION | HASH_FIXED_SIZE,
        );
 
    /*
     * Allocate hash table for PREDICATELOCK structs.  This stores per
     * xact-lock-of-a-target information.
     *
     * Assume an average of 2 xacts per target.
     */
    max_predicate_locks = max_predicate_lock_targets * 2;
 
    ShmemRequestHash(.name = "PREDICATELOCK hash",
                     .nelems = max_predicate_locks,
                     .ptr = &PredicateLockHash,
                     .hash_info.keysize = sizeof(PREDICATELOCKTAG),
                     .hash_info.entrysize = sizeof(PREDICATELOCK),
                     .hash_info.hash = predicatelock_hash,
                     .hash_info.num_partitions = NUM_PREDICATELOCK_PARTITIONS,
                     .hash_flags = HASH_ELEM | HASH_FUNCTION | HASH_PARTITION | HASH_FIXED_SIZE,
        );
 
    /*
     * Compute size for serializable transaction hashtable. Note these
     * calculations must agree with PredicateLockShmemSize!
     *
     * Assume an average of 10 predicate locking transactions per backend.
     * This allows aggressive cleanup while detail is present before data must
     * be summarized for storage in SLRU and the "dummy" transaction.
     */
    max_serializable_xacts = (MaxBackends + max_prepared_xacts) * 10;
 
    /*
     * Register a list to hold information on transactions participating in
     * predicate locking.
     */
    ShmemRequestStruct(.name = "PredXactList",
                       .size = add_size(PredXactListDataSize,
                                        (mul_size((Size) max_serializable_xacts,
                                                  sizeof(SERIALIZABLEXACT)))),
                       .ptr = (void **) &PredXact,
        );
 
    /*
     * Register hash table for SERIALIZABLEXID structs.  This stores per-xid
     * information for serializable transactions which have accessed data.
     */
    ShmemRequestHash(.name = "SERIALIZABLEXID hash",
                     .nelems = max_serializable_xacts,
                     .ptr = &SerializableXidHash,
                     .hash_info.keysize = sizeof(SERIALIZABLEXIDTAG),
                     .hash_info.entrysize = sizeof(SERIALIZABLEXID),
                     .hash_flags = HASH_ELEM | HASH_BLOBS | HASH_FIXED_SIZE,
        );
 
    /*
     * Allocate space for tracking rw-conflicts in lists attached to the
     * transactions.
     *
     * Assume an average of 5 conflicts per transaction.  Calculations suggest
     * that this will prevent resource exhaustion in even the most pessimal
     * loads up to max_connections = 200 with all 200 connections pounding the
     * database with serializable transactions.  Beyond that, there may be
     * occasional transactions canceled when trying to flag conflicts. That's
     * probably OK.
     */
    max_rw_conflicts = max_serializable_xacts * 5;
 
    ShmemRequestStruct(.name = "RWConflictPool",
                       .size = RWConflictPoolHeaderDataSize + mul_size((Size) max_rw_conflicts,
                                                                       RWConflictDataSize),
                       .ptr = (void **) &RWConflictPool,
        );
 
    ShmemRequestStruct(.name = "FinishedSerializableTransactions",
                       .size = sizeof(dlist_head),
                       .ptr = (void **) &FinishedSerializableTransactions,
        );
 
    /*
     * Initialize the SLRU storage for old committed serializable
     * transactions.
     */
    SimpleLruRequest(.desc = &SerialSlruDesc,
                     .name = "serializable",
                     .Dir = "pg_serial",
                     .long_segment_names = false,
 
                     .nslots = serializable_buffers,
 
                     .sync_handler = SYNC_HANDLER_NONE,
                     .PagePrecedes = SerialPagePrecedesLogically,
                     .errdetail_for_io_error = serial_errdetail_for_io_error,
 
                     .buffer_tranche_id = LWTRANCHE_SERIAL_BUFFER,
                     .bank_tranche_id = LWTRANCHE_SERIAL_SLRU,
        );
#ifdef USE_ASSERT_CHECKING
    SerialPagePrecedesLogicallyUnitTests();
#endif
 
    ShmemRequestStruct(.name = "SerialControlData",
                       .size = sizeof(SerialControlData),
                       .ptr = (void **) &serialControl,
        );
}

References add_size(), fb(), FinishedSerializableTransactions, HASH_BLOBS, HASH_ELEM, HASH_FIXED_SIZE, HASH_FUNCTION, HASH_PARTITION, HTAB::keysize, max_prepared_xacts, max_serializable_xacts, MaxBackends, mul_size(), name, NPREDICATELOCKTARGETENTS, NUM_PREDICATELOCK_PARTITIONS, predicatelock_hash(), PredicateLockHash, PredicateLockTargetHash, PredXact, PredXactListDataSize, RWConflictDataSize, RWConflictPool, RWConflictPoolHeaderDataSize, serial_errdetail_for_io_error(), serialControl, serializable_buffers, SerializableXidHash, SerialPagePrecedesLogically(), SerialSlruDesc, ShmemRequestHash, ShmemRequestStruct, SimpleLruRequest, and SYNC_HANDLER_NONE.

PredicateLockTID()

void PredicateLockTID	(	Relation	relation,
		const ItemPointerData *	tid,
		Snapshot	snapshot,
		TransactionId	tuple_xid
	)

Definition at line 2551 of file predicate.c.

{
    PREDICATELOCKTARGETTAG tag;
 
    if (!SerializationNeededForRead(relation, snapshot))
        return;
 
    /*
     * Return if this xact wrote it.
     */
    if (relation->rd_index == NULL)
    {
        /* If we wrote it; we already have a write lock. */
        if (TransactionIdIsCurrentTransactionId(tuple_xid))
            return;
    }
 
    /*
     * Do quick-but-not-definitive test for a relation lock first.  This will
     * never cause a return when the relation is *not* locked, but will
     * occasionally let the check continue when there really *is* a relation
     * level lock.
     */
    SET_PREDICATELOCKTARGETTAG_RELATION(tag,
                                        relation->rd_locator.dbOid,
                                        relation->rd_id);
    if (PredicateLockExists(&tag))
        return;
 
    SET_PREDICATELOCKTARGETTAG_TUPLE(tag,
                                     relation->rd_locator.dbOid,
                                     relation->rd_id,
                                     ItemPointerGetBlockNumber(tid),
                                     ItemPointerGetOffsetNumber(tid));
    PredicateLockAcquire(&tag);
}

References RelFileLocator::dbOid, fb(), ItemPointerGetBlockNumber(), ItemPointerGetOffsetNumber(), PredicateLockAcquire(), PredicateLockExists(), RelationData::rd_id, RelationData::rd_index, RelationData::rd_locator, SerializationNeededForRead(), SET_PREDICATELOCKTARGETTAG_RELATION, SET_PREDICATELOCKTARGETTAG_TUPLE, and TransactionIdIsCurrentTransactionId().

Referenced by BitmapHeapScanNextBlock(), heap_fetch(), and heap_hot_search_buffer().

PredicateLockTwoPhaseFinish()

void PredicateLockTwoPhaseFinish	(	FullTransactionId	fxid,
		bool	isCommit
	)

Definition at line 4812 of file predicate.c.

{
    SERIALIZABLEXID *sxid;
    SERIALIZABLEXIDTAG sxidtag;
 
    sxidtag.xid = XidFromFullTransactionId(fxid);
 
    LWLockAcquire(SerializableXactHashLock, LW_SHARED);
    sxid = (SERIALIZABLEXID *)
        hash_search(SerializableXidHash, &sxidtag, HASH_FIND, NULL);
    LWLockRelease(SerializableXactHashLock);
 
    /* xid will not be found if it wasn't a serializable transaction */
    if (sxid == NULL)
        return;
 
    /* Release its locks */
    MySerializableXact = sxid->myXact;
    MyXactDidWrite = true;      /* conservatively assume that we wrote
                                 * something */
    ReleasePredicateLocks(isCommit, false);
}

References fb(), HASH_FIND, hash_search(), LW_SHARED, LWLockAcquire(), LWLockRelease(), MySerializableXact, MyXactDidWrite, ReleasePredicateLocks(), SerializableXidHash, SERIALIZABLEXIDTAG::xid, and XidFromFullTransactionId.

Referenced by FinishPreparedTransaction().

RegisterPredicateLockingXid()

void RegisterPredicateLockingXid

(

TransactionId

xid

)

Definition at line 1889 of file predicate.c.

{
    SERIALIZABLEXIDTAG sxidtag;
    SERIALIZABLEXID *sxid;
    bool        found;
 
    /*
     * If we're not tracking predicate lock data for this transaction, we
     * should ignore the request and return quickly.
     */
    if (MySerializableXact == InvalidSerializableXact)
        return;
 
    /* We should have a valid XID and be at the top level. */
    Assert(TransactionIdIsValid(xid));
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* This should only be done once per transaction. */
    Assert(MySerializableXact->topXid == InvalidTransactionId);
 
    MySerializableXact->topXid = xid;
 
    sxidtag.xid = xid;
    sxid = (SERIALIZABLEXID *) hash_search(SerializableXidHash,
                                           &sxidtag,
                                           HASH_ENTER, &found);
    Assert(!found);
 
    /* Initialize the structure. */
    sxid->myXact = MySerializableXact;
    LWLockRelease(SerializableXactHashLock);
}

References Assert, fb(), HASH_ENTER, hash_search(), InvalidSerializableXact, InvalidTransactionId, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MySerializableXact, SerializableXidHash, SERIALIZABLEXACT::topXid, and TransactionIdIsValid.

Referenced by AssignTransactionId().

ReleaseOneSerializableXact()

static void ReleaseOneSerializableXact ( SERIALIZABLEXACT *  sxact, bool  partial, bool  summarize  )

static

Definition at line 3765 of file predicate.c.

{
    SERIALIZABLEXIDTAG sxidtag;
    dlist_mutable_iter iter;
 
    Assert(sxact != NULL);
    Assert(SxactIsRolledBack(sxact) || SxactIsCommitted(sxact));
    Assert(partial || !SxactIsOnFinishedList(sxact));
    Assert(LWLockHeldByMe(SerializableFinishedListLock));
 
    /*
     * First release all the predicate locks held by this xact (or transfer
     * them to OldCommittedSxact if summarize is true)
     */
    LWLockAcquire(SerializablePredicateListLock, LW_SHARED);
    if (IsInParallelMode())
        LWLockAcquire(&sxact->perXactPredicateListLock, LW_EXCLUSIVE);
    dlist_foreach_modify(iter, &sxact->predicateLocks)
    {
        PREDICATELOCK *predlock =
            dlist_container(PREDICATELOCK, xactLink, iter.cur);
        PREDICATELOCKTAG tag;
        PREDICATELOCKTARGET *target;
        PREDICATELOCKTARGETTAG targettag;
        uint32      targettaghash;
        LWLock     *partitionLock;
 
        tag = predlock->tag;
        target = tag.myTarget;
        targettag = target->tag;
        targettaghash = PredicateLockTargetTagHashCode(&targettag);
        partitionLock = PredicateLockHashPartitionLock(targettaghash);
 
        LWLockAcquire(partitionLock, LW_EXCLUSIVE);
 
        dlist_delete(&predlock->targetLink);
 
        hash_search_with_hash_value(PredicateLockHash, &tag,
                                    PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                            targettaghash),
                                    HASH_REMOVE, NULL);
        if (summarize)
        {
            bool        found;
 
            /* Fold into dummy transaction list. */
            tag.myXact = OldCommittedSxact;
            predlock = hash_search_with_hash_value(PredicateLockHash, &tag,
                                                   PredicateLockHashCodeFromTargetHashCode(&tag,
                                                                                           targettaghash),
                                                   HASH_ENTER_NULL, &found);
            if (!predlock)
                ereport(ERROR,
                        (errcode(ERRCODE_OUT_OF_MEMORY),
                         errmsg("out of shared memory"),
                         errhint("You might need to increase \"%s\".", "max_pred_locks_per_transaction")));
            if (found)
            {
                Assert(predlock->commitSeqNo != 0);
                Assert(predlock->commitSeqNo != InvalidSerCommitSeqNo);
                if (predlock->commitSeqNo < sxact->commitSeqNo)
                    predlock->commitSeqNo = sxact->commitSeqNo;
            }
            else
            {
                dlist_push_tail(&target->predicateLocks,
                                &predlock->targetLink);
                dlist_push_tail(&OldCommittedSxact->predicateLocks,
                                &predlock->xactLink);
                predlock->commitSeqNo = sxact->commitSeqNo;
            }
        }
        else
            RemoveTargetIfNoLongerUsed(target, targettaghash);
 
        LWLockRelease(partitionLock);
    }
 
    /*
     * Rather than retail removal, just re-init the head after we've run
     * through the list.
     */
    dlist_init(&sxact->predicateLocks);
 
    if (IsInParallelMode())
        LWLockRelease(&sxact->perXactPredicateListLock);
    LWLockRelease(SerializablePredicateListLock);
 
    sxidtag.xid = sxact->topXid;
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /* Release all outConflicts (unless 'partial' is true) */
    if (!partial)
    {
        dlist_foreach_modify(iter, &sxact->outConflicts)
        {
            RWConflict  conflict =
                dlist_container(RWConflictData, outLink, iter.cur);
 
            if (summarize)
                conflict->sxactIn->flags |= SXACT_FLAG_SUMMARY_CONFLICT_IN;
            ReleaseRWConflict(conflict);
        }
    }
 
    /* Release all inConflicts. */
    dlist_foreach_modify(iter, &sxact->inConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        if (summarize)
            conflict->sxactOut->flags |= SXACT_FLAG_SUMMARY_CONFLICT_OUT;
        ReleaseRWConflict(conflict);
    }
 
    /* Finally, get rid of the xid and the record of the transaction itself. */
    if (!partial)
    {
        if (sxidtag.xid != InvalidTransactionId)
            hash_search(SerializableXidHash, &sxidtag, HASH_REMOVE, NULL);
        ReleasePredXact(sxact);
    }
 
    LWLockRelease(SerializableXactHashLock);
}

References Assert, dlist_mutable_iter::cur, dlist_container, dlist_delete(), dlist_foreach_modify, dlist_init(), dlist_push_tail(), ereport, errcode(), errhint(), errmsg, ERROR, fb(), HASH_ENTER_NULL, HASH_REMOVE, hash_search(), hash_search_with_hash_value(), InvalidSerCommitSeqNo, InvalidTransactionId, IsInParallelMode(), LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockHeldByMe(), LWLockRelease(), PREDICATELOCKTAG::myTarget, PREDICATELOCKTAG::myXact, OldCommittedSxact, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, SERIALIZABLEXACT::predicateLocks, PREDICATELOCKTARGET::predicateLocks, PredicateLockTargetTagHashCode, ReleasePredXact(), ReleaseRWConflict(), RemoveTargetIfNoLongerUsed(), SerializableXidHash, SXACT_FLAG_SUMMARY_CONFLICT_IN, SXACT_FLAG_SUMMARY_CONFLICT_OUT, SxactIsCommitted, SxactIsOnFinishedList, SxactIsRolledBack, and PREDICATELOCKTARGET::tag.

Referenced by ClearOldPredicateLocks(), ReleasePredicateLocks(), and SummarizeOldestCommittedSxact().

ReleasePredicateLocks()

void ReleasePredicateLocks	(	bool	isCommit,
		bool	isReadOnlySafe
	)

Definition at line 3242 of file predicate.c.

{
    bool        partiallyReleasing = false;
    bool        needToClear;
    SERIALIZABLEXACT *roXact;
    dlist_mutable_iter iter;
 
    /*
     * We can't trust XactReadOnly here, because a transaction which started
     * as READ WRITE can show as READ ONLY later, e.g., within
     * subtransactions.  We want to flag a transaction as READ ONLY if it
     * commits without writing so that de facto READ ONLY transactions get the
     * benefit of some RO optimizations, so we will use this local variable to
     * get some cleanup logic right which is based on whether the transaction
     * was declared READ ONLY at the top level.
     */
    bool        topLevelIsDeclaredReadOnly;
 
    /* We can't be both committing and releasing early due to RO_SAFE. */
    Assert(!(isCommit && isReadOnlySafe));
 
    /* Are we at the end of a transaction, that is, a commit or abort? */
    if (!isReadOnlySafe)
    {
        /*
         * Parallel workers mustn't release predicate locks at the end of
         * their transaction.  The leader will do that at the end of its
         * transaction.
         */
        if (IsParallelWorker())
        {
            ReleasePredicateLocksLocal();
            return;
        }
 
        /*
         * By the time the leader in a parallel query reaches end of
         * transaction, it has waited for all workers to exit.
         */
        Assert(!ParallelContextActive());
 
        /*
         * If the leader in a parallel query earlier stashed a partially
         * released SERIALIZABLEXACT for final clean-up at end of transaction
         * (because workers might still have been accessing it), then it's
         * time to restore it.
         */
        if (SavedSerializableXact != InvalidSerializableXact)
        {
            Assert(MySerializableXact == InvalidSerializableXact);
            MySerializableXact = SavedSerializableXact;
            SavedSerializableXact = InvalidSerializableXact;
            Assert(SxactIsPartiallyReleased(MySerializableXact));
        }
    }
 
    if (MySerializableXact == InvalidSerializableXact)
    {
        Assert(LocalPredicateLockHash == NULL);
        return;
    }
 
    LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
    /*
     * If the transaction is committing, but it has been partially released
     * already, then treat this as a roll back.  It was marked as rolled back.
     */
    if (isCommit && SxactIsPartiallyReleased(MySerializableXact))
        isCommit = false;
 
    /*
     * If we're called in the middle of a transaction because we discovered
     * that the SXACT_FLAG_RO_SAFE flag was set, then we'll partially release
     * it (that is, release the predicate locks and conflicts, but not the
     * SERIALIZABLEXACT itself) if we're the first backend to have noticed.
     */
    if (isReadOnlySafe && IsInParallelMode())
    {
        /*
         * The leader needs to stash a pointer to it, so that it can
         * completely release it at end-of-transaction.
         */
        if (!IsParallelWorker())
            SavedSerializableXact = MySerializableXact;
 
        /*
         * The first backend to reach this condition will partially release
         * the SERIALIZABLEXACT.  All others will just clear their
         * backend-local state so that they stop doing SSI checks for the rest
         * of the transaction.
         */
        if (SxactIsPartiallyReleased(MySerializableXact))
        {
            LWLockRelease(SerializableXactHashLock);
            ReleasePredicateLocksLocal();
            return;
        }
        else
        {
            MySerializableXact->flags |= SXACT_FLAG_PARTIALLY_RELEASED;
            partiallyReleasing = true;
            /* ... and proceed to perform the partial release below. */
        }
    }
    Assert(!isCommit || SxactIsPrepared(MySerializableXact));
    Assert(!isCommit || !SxactIsDoomed(MySerializableXact));
    Assert(!SxactIsCommitted(MySerializableXact));
    Assert(SxactIsPartiallyReleased(MySerializableXact)
           || !SxactIsRolledBack(MySerializableXact));
 
    /* may not be serializable during COMMIT/ROLLBACK PREPARED */
    Assert(MySerializableXact->pid == 0 || IsolationIsSerializable());
 
    /* We'd better not already be on the cleanup list. */
    Assert(!SxactIsOnFinishedList(MySerializableXact));
 
    topLevelIsDeclaredReadOnly = SxactIsReadOnly(MySerializableXact);
 
    /*
     * We don't hold XidGenLock lock here, assuming that TransactionId is
     * atomic!
     *
     * If this value is changing, we don't care that much whether we get the
     * old or new value -- it is just used to determine how far
     * SxactGlobalXmin must advance before this transaction can be fully
     * cleaned up.  The worst that could happen is we wait for one more
     * transaction to complete before freeing some RAM; correctness of visible
     * behavior is not affected.
     */
    MySerializableXact->finishedBefore = XidFromFullTransactionId(TransamVariables->nextXid);
 
    /*
     * If it's not a commit it's either a rollback or a read-only transaction
     * flagged SXACT_FLAG_RO_SAFE, and we can clear our locks immediately.
     */
    if (isCommit)
    {
        MySerializableXact->flags |= SXACT_FLAG_COMMITTED;
        MySerializableXact->commitSeqNo = ++(PredXact->LastSxactCommitSeqNo);
        /* Recognize implicit read-only transaction (commit without write). */
        if (!MyXactDidWrite)
            MySerializableXact->flags |= SXACT_FLAG_READ_ONLY;
    }
    else
    {
        /*
         * The DOOMED flag indicates that we intend to roll back this
         * transaction and so it should not cause serialization failures for
         * other transactions that conflict with it. Note that this flag might
         * already be set, if another backend marked this transaction for
         * abort.
         *
         * The ROLLED_BACK flag further indicates that ReleasePredicateLocks
         * has been called, and so the SerializableXact is eligible for
         * cleanup. This means it should not be considered when calculating
         * SxactGlobalXmin.
         */
        MySerializableXact->flags |= SXACT_FLAG_DOOMED;
        MySerializableXact->flags |= SXACT_FLAG_ROLLED_BACK;
 
        /*
         * If the transaction was previously prepared, but is now failing due
         * to a ROLLBACK PREPARED or (hopefully very rare) error after the
         * prepare, clear the prepared flag.  This simplifies conflict
         * checking.
         */
        MySerializableXact->flags &= ~SXACT_FLAG_PREPARED;
    }
 
    if (!topLevelIsDeclaredReadOnly)
    {
        Assert(PredXact->WritableSxactCount > 0);
        if (--(PredXact->WritableSxactCount) == 0)
        {
            /*
             * Release predicate locks and rw-conflicts in for all committed
             * transactions.  There are no longer any transactions which might
             * conflict with the locks and no chance for new transactions to
             * overlap.  Similarly, existing conflicts in can't cause pivots,
             * and any conflicts in which could have completed a dangerous
             * structure would already have caused a rollback, so any
             * remaining ones must be benign.
             */
            PredXact->CanPartialClearThrough = PredXact->LastSxactCommitSeqNo;
        }
    }
    else
    {
        /*
         * Read-only transactions: clear the list of transactions that might
         * make us unsafe. Note that we use 'inLink' for the iteration as
         * opposed to 'outLink' for the r/w xacts.
         */
        dlist_foreach_modify(iter, &MySerializableXact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, inLink, iter.cur);
 
            Assert(!SxactIsReadOnly(possibleUnsafeConflict->sxactOut));
            Assert(MySerializableXact == possibleUnsafeConflict->sxactIn);
 
            ReleaseRWConflict(possibleUnsafeConflict);
        }
    }
 
    /* Check for conflict out to old committed transactions. */
    if (isCommit
        && !SxactIsReadOnly(MySerializableXact)
        && SxactHasSummaryConflictOut(MySerializableXact))
    {
        /*
         * we don't know which old committed transaction we conflicted with,
         * so be conservative and use FirstNormalSerCommitSeqNo here
         */
        MySerializableXact->SeqNo.earliestOutConflictCommit =
            FirstNormalSerCommitSeqNo;
        MySerializableXact->flags |= SXACT_FLAG_CONFLICT_OUT;
    }
 
    /*
     * Release all outConflicts to committed transactions.  If we're rolling
     * back clear them all.  Set SXACT_FLAG_CONFLICT_OUT if any point to
     * previously committed transactions.
     */
    dlist_foreach_modify(iter, &MySerializableXact->outConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, outLink, iter.cur);
 
        if (isCommit
            && !SxactIsReadOnly(MySerializableXact)
            && SxactIsCommitted(conflict->sxactIn))
        {
            if ((MySerializableXact->flags & SXACT_FLAG_CONFLICT_OUT) == 0
                || conflict->sxactIn->prepareSeqNo < MySerializableXact->SeqNo.earliestOutConflictCommit)
                MySerializableXact->SeqNo.earliestOutConflictCommit = conflict->sxactIn->prepareSeqNo;
            MySerializableXact->flags |= SXACT_FLAG_CONFLICT_OUT;
        }
 
        if (!isCommit
            || SxactIsCommitted(conflict->sxactIn)
            || (conflict->sxactIn->SeqNo.lastCommitBeforeSnapshot >= PredXact->LastSxactCommitSeqNo))
            ReleaseRWConflict(conflict);
    }
 
    /*
     * Release all inConflicts from committed and read-only transactions. If
     * we're rolling back, clear them all.
     */
    dlist_foreach_modify(iter, &MySerializableXact->inConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, inLink, iter.cur);
 
        if (!isCommit
            || SxactIsCommitted(conflict->sxactOut)
            || SxactIsReadOnly(conflict->sxactOut))
            ReleaseRWConflict(conflict);
    }
 
    if (!topLevelIsDeclaredReadOnly)
    {
        /*
         * Remove ourselves from the list of possible conflicts for concurrent
         * READ ONLY transactions, flagging them as unsafe if we have a
         * conflict out. If any are waiting DEFERRABLE transactions, wake them
         * up if they are known safe or known unsafe.
         */
        dlist_foreach_modify(iter, &MySerializableXact->possibleUnsafeConflicts)
        {
            RWConflict  possibleUnsafeConflict =
                dlist_container(RWConflictData, outLink, iter.cur);
 
            roXact = possibleUnsafeConflict->sxactIn;
            Assert(MySerializableXact == possibleUnsafeConflict->sxactOut);
            Assert(SxactIsReadOnly(roXact));
 
            /* Mark conflicted if necessary. */
            if (isCommit
                && MyXactDidWrite
                && SxactHasConflictOut(MySerializableXact)
                && (MySerializableXact->SeqNo.earliestOutConflictCommit
                    <= roXact->SeqNo.lastCommitBeforeSnapshot))
            {
                /*
                 * This releases possibleUnsafeConflict (as well as all other
                 * possible conflicts for roXact)
                 */
                FlagSxactUnsafe(roXact);
            }
            else
            {
                ReleaseRWConflict(possibleUnsafeConflict);
 
                /*
                 * If we were the last possible conflict, flag it safe. The
                 * transaction can now safely release its predicate locks (but
                 * that transaction's backend has to do that itself).
                 */
                if (dlist_is_empty(&roXact->possibleUnsafeConflicts))
                    roXact->flags |= SXACT_FLAG_RO_SAFE;
            }
 
            /*
             * Wake up the process for a waiting DEFERRABLE transaction if we
             * now know it's either safe or conflicted.
             */
            if (SxactIsDeferrableWaiting(roXact) &&
                (SxactIsROUnsafe(roXact) || SxactIsROSafe(roXact)))
                ProcSendSignal(roXact->pgprocno);
        }
    }
 
    /*
     * Check whether it's time to clean up old transactions. This can only be
     * done when the last serializable transaction with the oldest xmin among
     * serializable transactions completes.  We then find the "new oldest"
     * xmin and purge any transactions which finished before this transaction
     * was launched.
     *
     * For parallel queries in read-only transactions, it might run twice. We
     * only release the reference on the first call.
     */
    needToClear = false;
    if ((partiallyReleasing ||
         !SxactIsPartiallyReleased(MySerializableXact)) &&
        TransactionIdEquals(MySerializableXact->xmin,
                            PredXact->SxactGlobalXmin))
    {
        Assert(PredXact->SxactGlobalXminCount > 0);
        if (--(PredXact->SxactGlobalXminCount) == 0)
        {
            SetNewSxactGlobalXmin();
            needToClear = true;
        }
    }
 
    LWLockRelease(SerializableXactHashLock);
 
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
 
    /* Add this to the list of transactions to check for later cleanup. */
    if (isCommit)
        dlist_push_tail(FinishedSerializableTransactions,
                        &MySerializableXact->finishedLink);
 
    /*
     * If we're releasing a RO_SAFE transaction in parallel mode, we'll only
     * partially release it.  That's necessary because other backends may have
     * a reference to it.  The leader will release the SERIALIZABLEXACT itself
     * at the end of the transaction after workers have stopped running.
     */
    if (!isCommit)
        ReleaseOneSerializableXact(MySerializableXact,
                                   isReadOnlySafe && IsInParallelMode(),
                                   false);
 
    LWLockRelease(SerializableFinishedListLock);
 
    if (needToClear)
        ClearOldPredicateLocks();
 
    ReleasePredicateLocksLocal();
}

References Assert, PredXactListData::CanPartialClearThrough, ClearOldPredicateLocks(), SERIALIZABLEXACT::commitSeqNo, dlist_mutable_iter::cur, dlist_container, dlist_foreach_modify, dlist_is_empty(), dlist_push_tail(), SERIALIZABLEXACT::earliestOutConflictCommit, fb(), SERIALIZABLEXACT::finishedBefore, SERIALIZABLEXACT::finishedLink, FinishedSerializableTransactions, FirstNormalSerCommitSeqNo, SERIALIZABLEXACT::flags, FlagSxactUnsafe(), SERIALIZABLEXACT::inConflicts, InvalidSerializableXact, IsInParallelMode(), IsolationIsSerializable, IsParallelWorker, PredXactListData::LastSxactCommitSeqNo, LocalPredicateLockHash, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), MySerializableXact, MyXactDidWrite, TransamVariablesData::nextXid, SERIALIZABLEXACT::outConflicts, ParallelContextActive(), SERIALIZABLEXACT::pid, SERIALIZABLEXACT::possibleUnsafeConflicts, PredXact, ProcSendSignal(), ReleaseOneSerializableXact(), ReleasePredicateLocksLocal(), ReleaseRWConflict(), SavedSerializableXact, SERIALIZABLEXACT::SeqNo, SetNewSxactGlobalXmin(), SXACT_FLAG_COMMITTED, SXACT_FLAG_CONFLICT_OUT, SXACT_FLAG_DOOMED, SXACT_FLAG_PARTIALLY_RELEASED, SXACT_FLAG_READ_ONLY, SXACT_FLAG_RO_SAFE, SXACT_FLAG_ROLLED_BACK, PredXactListData::SxactGlobalXmin, PredXactListData::SxactGlobalXminCount, SxactHasConflictOut, SxactHasSummaryConflictOut, SxactIsCommitted, SxactIsDeferrableWaiting, SxactIsDoomed, SxactIsOnFinishedList, SxactIsPartiallyReleased, SxactIsPrepared, SxactIsReadOnly, SxactIsRolledBack, SxactIsROSafe, SxactIsROUnsafe, TransactionIdEquals, TransamVariables, PredXactListData::WritableSxactCount, XidFromFullTransactionId, and SERIALIZABLEXACT::xmin.

Referenced by GetSafeSnapshot(), PredicateLockTwoPhaseFinish(), ResourceOwnerReleaseInternal(), and SerializationNeededForRead().

ReleasePredicateLocksLocal()

static void ReleasePredicateLocksLocal ( void  )

static

Definition at line 3609 of file predicate.c.

{
    MySerializableXact = InvalidSerializableXact;
    MyXactDidWrite = false;
 
    /* Delete per-transaction lock table */
    if (LocalPredicateLockHash != NULL)
    {
        hash_destroy(LocalPredicateLockHash);
        LocalPredicateLockHash = NULL;
    }
}

References fb(), hash_destroy(), InvalidSerializableXact, LocalPredicateLockHash, MySerializableXact, and MyXactDidWrite.

Referenced by ReleasePredicateLocks().

ReleasePredXact()

static void ReleasePredXact ( SERIALIZABLEXACT *  sxact )

static

Definition at line 610 of file predicate.c.

{
    Assert(ShmemAddrIsValid(sxact));
 
    dlist_delete(&sxact->xactLink);
    dlist_push_tail(&PredXact->availableList, &sxact->xactLink);
}

References Assert, PredXactListData::availableList, dlist_delete(), dlist_push_tail(), fb(), PredXact, and ShmemAddrIsValid().

Referenced by GetSerializableTransactionSnapshotInt(), and ReleaseOneSerializableXact().

ReleaseRWConflict()

static void ReleaseRWConflict ( RWConflict  conflict )

static

Definition at line 705 of file predicate.c.

{
    dlist_delete(&conflict->inLink);
    dlist_delete(&conflict->outLink);
    dlist_push_tail(&RWConflictPool->availableList, &conflict->outLink);
}

References RWConflictPoolHeaderData::availableList, dlist_delete(), dlist_push_tail(), fb(), and RWConflictPool.

Referenced by FlagSxactUnsafe(), ReleaseOneSerializableXact(), and ReleasePredicateLocks().

RemoveScratchTarget()

static void RemoveScratchTarget ( bool  lockheld )

static

Definition at line 2070 of file predicate.c.

{
    bool        found;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    if (!lockheld)
        LWLockAcquire(ScratchPartitionLock, LW_EXCLUSIVE);
    hash_search_with_hash_value(PredicateLockTargetHash,
                                &ScratchTargetTag,
                                ScratchTargetTagHash,
                                HASH_REMOVE, &found);
    Assert(found);
    if (!lockheld)
        LWLockRelease(ScratchPartitionLock);
}

References Assert, fb(), HASH_REMOVE, hash_search_with_hash_value(), LW_EXCLUSIVE, LWLockAcquire(), LWLockHeldByMe(), LWLockRelease(), PredicateLockTargetHash, ScratchPartitionLock, ScratchTargetTag, and ScratchTargetTagHash.

Referenced by DropAllPredicateLocksFromTable(), and TransferPredicateLocksToNewTarget().

RemoveTargetIfNoLongerUsed()

static void RemoveTargetIfNoLongerUsed ( PREDICATELOCKTARGET *  target, uint32  targettaghash  )

static

Definition at line 2113 of file predicate.c.

{
    PREDICATELOCKTARGET *rmtarget PG_USED_FOR_ASSERTS_ONLY;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    /* Can't remove it until no locks at this target. */
    if (!dlist_is_empty(&target->predicateLocks))
        return;
 
    /* Actually remove the target. */
    rmtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                           &target->tag,
                                           targettaghash,
                                           HASH_REMOVE, NULL);
    Assert(rmtarget == target);
}

References Assert, dlist_is_empty(), fb(), HASH_REMOVE, hash_search_with_hash_value(), LWLockHeldByMe(), PG_USED_FOR_ASSERTS_ONLY, PREDICATELOCKTARGET::predicateLocks, PredicateLockTargetHash, and PREDICATELOCKTARGET::tag.

Referenced by CheckTargetForConflictsIn(), ClearOldPredicateLocks(), DeleteChildTargetLocks(), DeleteLockTarget(), ReleaseOneSerializableXact(), and TransferPredicateLocksToNewTarget().

RestoreScratchTarget()

static void RestoreScratchTarget ( bool  lockheld )

static

Definition at line 2091 of file predicate.c.

{
    bool        found;
 
    Assert(LWLockHeldByMe(SerializablePredicateListLock));
 
    if (!lockheld)
        LWLockAcquire(ScratchPartitionLock, LW_EXCLUSIVE);
    hash_search_with_hash_value(PredicateLockTargetHash,
                                &ScratchTargetTag,
                                ScratchTargetTagHash,
                                HASH_ENTER, &found);
    Assert(!found);
    if (!lockheld)
        LWLockRelease(ScratchPartitionLock);
}

References Assert, fb(), HASH_ENTER, hash_search_with_hash_value(), LW_EXCLUSIVE, LWLockAcquire(), LWLockHeldByMe(), LWLockRelease(), PredicateLockTargetHash, ScratchPartitionLock, ScratchTargetTag, and ScratchTargetTagHash.

Referenced by DropAllPredicateLocksFromTable(), and TransferPredicateLocksToNewTarget().

RWConflictExists()

static bool RWConflictExists ( const SERIALIZABLEXACT *  reader, const SERIALIZABLEXACT *  writer  )

static

Definition at line 624 of file predicate.c.

{
    dlist_iter  iter;
 
    Assert(reader != writer);
 
    /* Check the ends of the purported conflict first. */
    if (SxactIsDoomed(reader)
        || SxactIsDoomed(writer)
        || dlist_is_empty(&reader->outConflicts)
        || dlist_is_empty(&writer->inConflicts))
        return false;
 
    /*
     * A conflict is possible; walk the list to find out.
     *
     * The unconstify is needed as we have no const version of
     * dlist_foreach().
     */
    dlist_foreach(iter, &unconstify(SERIALIZABLEXACT *, reader)->outConflicts)
    {
        RWConflict  conflict =
            dlist_container(RWConflictData, outLink, iter.cur);
 
        if (conflict->sxactIn == writer)
            return true;
    }
 
    /* No conflict found. */
    return false;
}

References Assert, dlist_iter::cur, dlist_container, dlist_foreach, dlist_is_empty(), fb(), SERIALIZABLEXACT::outConflicts, SxactIsDoomed, and unconstify.

Referenced by CheckForSerializableConflictOut(), CheckTableForSerializableConflictIn(), CheckTargetForConflictsIn(), and SetRWConflict().

serial_errdetail_for_io_error()

static int serial_errdetail_for_io_error ( const void *  opaque_data )

static

Definition at line 760 of file predicate.c.

{
    TransactionId xid = *(const TransactionId *) opaque_data;
 
    return errdetail("Could not access serializable CSN of transaction %u.", xid);
}

References errdetail(), and fb().

Referenced by PredicateLockShmemRequest().

SerialAdd()

static void SerialAdd ( TransactionId  xid, SerCommitSeqNo  minConflictCommitSeqNo  )

static

Definition at line 839 of file predicate.c.

{
    TransactionId tailXid;
    int64       targetPage;
    int         slotno;
    int64       firstZeroPage;
    bool        isNewPage;
    LWLock     *lock;
 
    Assert(TransactionIdIsValid(xid));
 
    targetPage = SerialPage(xid);
    lock = SimpleLruGetBankLock(SerialSlruCtl, targetPage);
 
    /*
     * In this routine, we must hold both SerialControlLock and the SLRU bank
     * lock simultaneously while making the SLRU data catch up with the new
     * state that we determine.
     */
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /*
     * If 'xid' is older than the global xmin (== tailXid), there's no need to
     * store it, after all. This can happen if the oldest transaction holding
     * back the global xmin just finished, making 'xid' uninteresting, but
     * ClearOldPredicateLocks() has not yet run.
     */
    tailXid = serialControl->tailXid;
    if (!TransactionIdIsValid(tailXid) || TransactionIdPrecedes(xid, tailXid))
    {
        LWLockRelease(SerialControlLock);
        return;
    }
 
    /*
     * If the SLRU is currently unused, zero out the whole active region from
     * tailXid to headXid before taking it into use. Otherwise zero out only
     * any new pages that enter the tailXid-headXid range as we advance
     * headXid.
     */
    if (serialControl->headPage < 0)
    {
        firstZeroPage = SerialPage(tailXid);
        isNewPage = true;
    }
    else
    {
        firstZeroPage = SerialNextPage(serialControl->headPage);
        isNewPage = SerialPagePrecedesLogically(serialControl->headPage,
                                                targetPage);
    }
 
    if (!TransactionIdIsValid(serialControl->headXid)
        || TransactionIdFollows(xid, serialControl->headXid))
        serialControl->headXid = xid;
    if (isNewPage)
        serialControl->headPage = targetPage;
 
    if (isNewPage)
    {
        /* Initialize intervening pages; might involve trading locks */
        for (;;)
        {
            lock = SimpleLruGetBankLock(SerialSlruCtl, firstZeroPage);
            LWLockAcquire(lock, LW_EXCLUSIVE);
            slotno = SimpleLruZeroPage(SerialSlruCtl, firstZeroPage);
            if (firstZeroPage == targetPage)
                break;
            firstZeroPage = SerialNextPage(firstZeroPage);
            LWLockRelease(lock);
        }
    }
    else
    {
        LWLockAcquire(lock, LW_EXCLUSIVE);
        slotno = SimpleLruReadPage(SerialSlruCtl, targetPage, true, &xid);
    }
 
    SerialValue(slotno, xid) = minConflictCommitSeqNo;
    SerialSlruCtl->shared->page_dirty[slotno] = true;
 
    LWLockRelease(lock);
    LWLockRelease(SerialControlLock);
}

References Assert, fb(), SerialControlData::headPage, SerialControlData::headXid, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), serialControl, SerialNextPage, SerialPage, SerialPagePrecedesLogically(), SerialSlruCtl, SerialValue, SimpleLruGetBankLock(), SimpleLruReadPage(), SimpleLruZeroPage(), SerialControlData::tailXid, TransactionIdFollows(), TransactionIdIsValid, and TransactionIdPrecedes().

Referenced by SummarizeOldestCommittedSxact().

SerialGetMinConflictCommitSeqNo()

static SerCommitSeqNo SerialGetMinConflictCommitSeqNo ( TransactionId  xid )

static

Definition at line 930 of file predicate.c.

{
    TransactionId headXid;
    TransactionId tailXid;
    SerCommitSeqNo val;
    int         slotno;
 
    Assert(TransactionIdIsValid(xid));
 
    LWLockAcquire(SerialControlLock, LW_SHARED);
    headXid = serialControl->headXid;
    tailXid = serialControl->tailXid;
    LWLockRelease(SerialControlLock);
 
    if (!TransactionIdIsValid(headXid))
        return 0;
 
    Assert(TransactionIdIsValid(tailXid));
 
    if (TransactionIdPrecedes(xid, tailXid)
        || TransactionIdFollows(xid, headXid))
        return 0;
 
    /*
     * The following function must be called without holding SLRU bank lock,
     * but will return with that lock held, which must then be released.
     */
    slotno = SimpleLruReadPage_ReadOnly(SerialSlruCtl,
                                        SerialPage(xid), &xid);
    val = SerialValue(slotno, xid);
    LWLockRelease(SimpleLruGetBankLock(SerialSlruCtl, SerialPage(xid)));
    return val;
}

References Assert, fb(), SerialControlData::headXid, LW_SHARED, LWLockAcquire(), LWLockRelease(), serialControl, SerialPage, SerialSlruCtl, SerialValue, SimpleLruGetBankLock(), SimpleLruReadPage_ReadOnly(), SerialControlData::tailXid, TransactionIdFollows(), TransactionIdIsValid, TransactionIdPrecedes(), and val.

Referenced by CheckForSerializableConflictOut().

SerializationNeededForRead()

static bool SerializationNeededForRead ( Relation  relation, Snapshot  snapshot  )

inlinestatic

Definition at line 530 of file predicate.c.

{
    /* Nothing to do if this is not a serializable transaction */
    if (MySerializableXact == InvalidSerializableXact)
        return false;
 
    /*
     * Don't acquire locks or conflict when scanning with a special snapshot.
     * This excludes things like CLUSTER and REINDEX. They use the wholesale
     * functions TransferPredicateLocksToHeapRelation() and
     * CheckTableForSerializableConflictIn() to participate in serialization,
     * but the scans involved don't need serialization.
     */
    if (!IsMVCCSnapshot(snapshot))
        return false;
 
    /*
     * Check if we have just become "RO-safe". If we have, immediately release
     * all locks as they're not needed anymore. This also resets
     * MySerializableXact, so that subsequent calls to this function can exit
     * quickly.
     *
     * A transaction is flagged as RO_SAFE if all concurrent R/W transactions
     * commit without having conflicts out to an earlier snapshot, thus
     * ensuring that no conflicts are possible for this transaction.
     */
    if (SxactIsROSafe(MySerializableXact))
    {
        ReleasePredicateLocks(false, true);
        return false;
    }
 
    /* Check if the relation doesn't participate in predicate locking */
    if (!PredicateLockingNeededForRelation(relation))
        return false;
 
    return true;                /* no excuse to skip predicate locking */
}

References InvalidSerializableXact, IsMVCCSnapshot, MySerializableXact, PredicateLockingNeededForRelation(), ReleasePredicateLocks(), and SxactIsROSafe.

Referenced by CheckForSerializableConflictOut(), CheckForSerializableConflictOutNeeded(), PredicateLockPage(), PredicateLockRelation(), and PredicateLockTID().

SerializationNeededForWrite()

static bool SerializationNeededForWrite ( Relation  relation )

inlinestatic

Definition at line 574 of file predicate.c.

{
    /* Nothing to do if this is not a serializable transaction */
    if (MySerializableXact == InvalidSerializableXact)
        return false;
 
    /* Check if the relation doesn't participate in predicate locking */
    if (!PredicateLockingNeededForRelation(relation))
        return false;
 
    return true;                /* no excuse to skip predicate locking */
}

References InvalidSerializableXact, MySerializableXact, and PredicateLockingNeededForRelation().

Referenced by CheckForSerializableConflictIn(), and CheckTableForSerializableConflictIn().

SerialPagePrecedesLogically()

static bool SerialPagePrecedesLogically ( int64  page1, int64  page2  )

static

Definition at line 745 of file predicate.c.

{
    TransactionId xid1;
    TransactionId xid2;
 
    xid1 = ((TransactionId) page1) * SERIAL_ENTRIESPERPAGE;
    xid1 += FirstNormalTransactionId + 1;
    xid2 = ((TransactionId) page2) * SERIAL_ENTRIESPERPAGE;
    xid2 += FirstNormalTransactionId + 1;
 
    return (TransactionIdPrecedes(xid1, xid2) &&
            TransactionIdPrecedes(xid1, xid2 + SERIAL_ENTRIESPERPAGE - 1));
}

References fb(), FirstNormalTransactionId, SERIAL_ENTRIESPERPAGE, and TransactionIdPrecedes().

Referenced by CheckPointPredicate(), PredicateLockShmemRequest(), and SerialAdd().

SerialSetActiveSerXmin()

static void SerialSetActiveSerXmin ( TransactionId  xid )

static

Definition at line 971 of file predicate.c.

{
    LWLockAcquire(SerialControlLock, LW_EXCLUSIVE);
 
    /*
     * When no sxacts are active, nothing overlaps, set the xid values to
     * invalid to show that there are no valid entries.  Don't clear headPage,
     * though.  A new xmin might still land on that page, and we don't want to
     * repeatedly zero out the same page.
     */
    if (!TransactionIdIsValid(xid))
    {
        serialControl->tailXid = InvalidTransactionId;
        serialControl->headXid = InvalidTransactionId;
        LWLockRelease(SerialControlLock);
        return;
    }
 
    /*
     * When we're recovering prepared transactions, the global xmin might move
     * backwards depending on the order they're recovered. Normally that's not
     * OK, but during recovery no serializable transactions will commit, so
     * the SLRU is empty and we can get away with it.
     */
    if (RecoveryInProgress())
    {
        Assert(serialControl->headPage < 0);
        if (!TransactionIdIsValid(serialControl->tailXid)
            || TransactionIdPrecedes(xid, serialControl->tailXid))
        {
            serialControl->tailXid = xid;
        }
        LWLockRelease(SerialControlLock);
        return;
    }
 
    Assert(!TransactionIdIsValid(serialControl->tailXid)
           || TransactionIdFollows(xid, serialControl->tailXid));
 
    serialControl->tailXid = xid;
 
    LWLockRelease(SerialControlLock);
}

References Assert, fb(), SerialControlData::headPage, SerialControlData::headXid, InvalidTransactionId, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), RecoveryInProgress(), serialControl, SerialControlData::tailXid, TransactionIdFollows(), TransactionIdIsValid, and TransactionIdPrecedes().

Referenced by GetSerializableTransactionSnapshotInt(), predicatelock_twophase_recover(), and SetNewSxactGlobalXmin().

SetNewSxactGlobalXmin()

static void SetNewSxactGlobalXmin ( void  )

static

Definition at line 3181 of file predicate.c.

{
    dlist_iter  iter;
 
    Assert(LWLockHeldByMe(SerializableXactHashLock));
 
    PredXact->SxactGlobalXmin = InvalidTransactionId;
    PredXact->SxactGlobalXminCount = 0;
 
    dlist_foreach(iter, &PredXact->activeList)
    {
        SERIALIZABLEXACT *sxact =
            dlist_container(SERIALIZABLEXACT, xactLink, iter.cur);
 
        if (!SxactIsRolledBack(sxact)
            && !SxactIsCommitted(sxact)
            && sxact != OldCommittedSxact)
        {
            Assert(sxact->xmin != InvalidTransactionId);
            if (!TransactionIdIsValid(PredXact->SxactGlobalXmin)
                || TransactionIdPrecedes(sxact->xmin,
                                         PredXact->SxactGlobalXmin))
            {
                PredXact->SxactGlobalXmin = sxact->xmin;
                PredXact->SxactGlobalXminCount = 1;
            }
            else if (TransactionIdEquals(sxact->xmin,
                                         PredXact->SxactGlobalXmin))
                PredXact->SxactGlobalXminCount++;
        }
    }
 
    SerialSetActiveSerXmin(PredXact->SxactGlobalXmin);
}

References PredXactListData::activeList, Assert, dlist_iter::cur, dlist_container, dlist_foreach, fb(), InvalidTransactionId, LWLockHeldByMe(), OldCommittedSxact, PredXact, SerialSetActiveSerXmin(), PredXactListData::SxactGlobalXmin, PredXactListData::SxactGlobalXminCount, SxactIsCommitted, SxactIsRolledBack, TransactionIdEquals, TransactionIdIsValid, and TransactionIdPrecedes().

Referenced by ReleasePredicateLocks().

SetPossibleUnsafeConflict()

static void SetPossibleUnsafeConflict ( SERIALIZABLEXACT *  roXact, SERIALIZABLEXACT *  activeXact  )

static

Definition at line 680 of file predicate.c.

{
    RWConflict  conflict;
 
    Assert(roXact != activeXact);
    Assert(SxactIsReadOnly(roXact));
    Assert(!SxactIsReadOnly(activeXact));
 
    if (dlist_is_empty(&RWConflictPool->availableList))
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("not enough elements in RWConflictPool to record a potential read/write conflict"),
                 errhint("You might need to run fewer transactions at a time or increase \"max_connections\".")));
 
    conflict = dlist_head_element(RWConflictData, outLink, &RWConflictPool->availableList);
    dlist_delete(&conflict->outLink);
 
    conflict->sxactOut = activeXact;
    conflict->sxactIn = roXact;
    dlist_push_tail(&activeXact->possibleUnsafeConflicts, &conflict->outLink);
    dlist_push_tail(&roXact->possibleUnsafeConflicts, &conflict->inLink);
}

References Assert, RWConflictPoolHeaderData::availableList, dlist_delete(), dlist_head_element, dlist_is_empty(), dlist_push_tail(), ereport, errcode(), errhint(), errmsg, ERROR, fb(), RWConflictPool, and SxactIsReadOnly.

Referenced by GetSerializableTransactionSnapshotInt().

SetRWConflict()

static void SetRWConflict ( SERIALIZABLEXACT *  reader, SERIALIZABLEXACT *  writer  )

static

Definition at line 657 of file predicate.c.

{
    RWConflict  conflict;
 
    Assert(reader != writer);
    Assert(!RWConflictExists(reader, writer));
 
    if (dlist_is_empty(&RWConflictPool->availableList))
        ereport(ERROR,
                (errcode(ERRCODE_OUT_OF_MEMORY),
                 errmsg("not enough elements in RWConflictPool to record a read/write conflict"),
                 errhint("You might need to run fewer transactions at a time or increase \"max_connections\".")));
 
    conflict = dlist_head_element(RWConflictData, outLink, &RWConflictPool->availableList);
    dlist_delete(&conflict->outLink);
 
    conflict->sxactOut = reader;
    conflict->sxactIn = writer;
    dlist_push_tail(&reader->outConflicts, &conflict->outLink);
    dlist_push_tail(&writer->inConflicts, &conflict->inLink);
}

References Assert, RWConflictPoolHeaderData::availableList, dlist_delete(), dlist_head_element, dlist_is_empty(), dlist_push_tail(), ereport, errcode(), errhint(), errmsg, ERROR, fb(), SERIALIZABLEXACT::outConflicts, RWConflictExists(), and RWConflictPool.

Referenced by FlagRWConflict().

SetSerializableTransactionSnapshot()

void SetSerializableTransactionSnapshot	(	Snapshot	snapshot,
		VirtualTransactionId *	sourcevxid,
		int	sourcepid
	)

Definition at line 1652 of file predicate.c.

{
    Assert(IsolationIsSerializable());
 
    /*
     * If this is called by parallel.c in a parallel worker, we don't want to
     * create a SERIALIZABLEXACT just yet because the leader's
     * SERIALIZABLEXACT will be installed with AttachSerializableXact().  We
     * also don't want to reject SERIALIZABLE READ ONLY DEFERRABLE in this
     * case, because the leader has already determined that the snapshot it
     * has passed us is safe.  So there is nothing for us to do.
     */
    if (IsParallelWorker())
        return;
 
    /*
     * We do not allow SERIALIZABLE READ ONLY DEFERRABLE transactions to
     * import snapshots, since there's no way to wait for a safe snapshot when
     * we're using the snap we're told to.  (XXX instead of throwing an error,
     * we could just ignore the XactDeferrable flag?)
     */
    if (XactReadOnly && XactDeferrable)
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("a snapshot-importing transaction must not be READ ONLY DEFERRABLE")));
 
    (void) GetSerializableTransactionSnapshotInt(snapshot, sourcevxid,
                                                 sourcepid);
}

References Assert, ereport, errcode(), errmsg, ERROR, fb(), GetSerializableTransactionSnapshotInt(), IsolationIsSerializable, IsParallelWorker, XactDeferrable, and XactReadOnly.

Referenced by SetTransactionSnapshot().

ShareSerializableXact()

SerializableXactHandle ShareSerializableXact

(

void

)

Definition at line 4977 of file predicate.c.

{
    return MySerializableXact;
}

References MySerializableXact.

Referenced by InitializeParallelDSM().

SummarizeOldestCommittedSxact()

static void SummarizeOldestCommittedSxact ( void  )

static

Definition at line 1433 of file predicate.c.

{
    SERIALIZABLEXACT *sxact;
 
    LWLockAcquire(SerializableFinishedListLock, LW_EXCLUSIVE);
 
    /*
     * This function is only called if there are no sxact slots available.
     * Some of them must belong to old, already-finished transactions, so
     * there should be something in FinishedSerializableTransactions list that
     * we can summarize. However, there's a race condition: while we were not
     * holding any locks, a transaction might have ended and cleaned up all
     * the finished sxact entries already, freeing up their sxact slots. In
     * that case, we have nothing to do here. The caller will find one of the
     * slots released by the other backend when it retries.
     */
    if (dlist_is_empty(FinishedSerializableTransactions))
    {
        LWLockRelease(SerializableFinishedListLock);
        return;
    }
 
    /*
     * Grab the first sxact off the finished list -- this will be the earliest
     * commit.  Remove it from the list.
     */
    sxact = dlist_head_element(SERIALIZABLEXACT, finishedLink,
                               FinishedSerializableTransactions);
    dlist_delete_thoroughly(&sxact->finishedLink);
 
    /* Add to SLRU summary information. */
    if (TransactionIdIsValid(sxact->topXid) && !SxactIsReadOnly(sxact))
        SerialAdd(sxact->topXid, SxactHasConflictOut(sxact)
                  ? sxact->SeqNo.earliestOutConflictCommit : InvalidSerCommitSeqNo);
 
    /* Summarize and release the detail. */
    ReleaseOneSerializableXact(sxact, false, true);
 
    LWLockRelease(SerializableFinishedListLock);
}

References dlist_delete_thoroughly(), dlist_head_element, dlist_is_empty(), fb(), FinishedSerializableTransactions, InvalidSerCommitSeqNo, LW_EXCLUSIVE, LWLockAcquire(), LWLockRelease(), ReleaseOneSerializableXact(), SerialAdd(), SxactHasConflictOut, SxactIsReadOnly, and TransactionIdIsValid.

Referenced by GetSerializableTransactionSnapshotInt().

TransferPredicateLocksToHeapRelation()

void TransferPredicateLocksToHeapRelation

(

Relation

relation

)

Definition at line 3053 of file predicate.c.

{
    DropAllPredicateLocksFromTable(relation, true);
}

References DropAllPredicateLocksFromTable().

Referenced by ATRewriteTable(), cluster_rel(), index_concurrently_set_dead(), index_drop(), rebuild_relation_finish_concurrent(), and reindex_index().

TransferPredicateLocksToNewTarget()

static bool TransferPredicateLocksToNewTarget ( PREDICATELOCKTARGETTAG  oldtargettag, PREDICATELOCKTARGETTAG  newtargettag, bool  removeOld  )

static

Definition at line 2660 of file predicate.c.

{
    uint32      oldtargettaghash;
    LWLock     *oldpartitionLock;
    PREDICATELOCKTARGET *oldtarget;
    uint32      newtargettaghash;
    LWLock     *newpartitionLock;
    bool        found;
    bool        outOfShmem = false;
 
    Assert(LWLockHeldByMeInMode(SerializablePredicateListLock,
                                LW_EXCLUSIVE));
 
    oldtargettaghash = PredicateLockTargetTagHashCode(&oldtargettag);
    newtargettaghash = PredicateLockTargetTagHashCode(&newtargettag);
    oldpartitionLock = PredicateLockHashPartitionLock(oldtargettaghash);
    newpartitionLock = PredicateLockHashPartitionLock(newtargettaghash);
 
    if (removeOld)
    {
        /*
         * Remove the dummy entry to give us scratch space, so we know we'll
         * be able to create the new lock target.
         */
        RemoveScratchTarget(false);
    }
 
    /*
     * We must get the partition locks in ascending sequence to avoid
     * deadlocks. If old and new partitions are the same, we must request the
     * lock only once.
     */
    if (oldpartitionLock < newpartitionLock)
    {
        LWLockAcquire(oldpartitionLock,
                      (removeOld ? LW_EXCLUSIVE : LW_SHARED));
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
    }
    else if (oldpartitionLock > newpartitionLock)
    {
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
        LWLockAcquire(oldpartitionLock,
                      (removeOld ? LW_EXCLUSIVE : LW_SHARED));
    }
    else
        LWLockAcquire(newpartitionLock, LW_EXCLUSIVE);
 
    /*
     * Look for the old target.  If not found, that's OK; no predicate locks
     * are affected, so we can just clean up and return. If it does exist,
     * walk its list of predicate locks and move or copy them to the new
     * target.
     */
    oldtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                            &oldtargettag,
                                            oldtargettaghash,
                                            HASH_FIND, NULL);
 
    if (oldtarget)
    {
        PREDICATELOCKTARGET *newtarget;
        PREDICATELOCKTAG newpredlocktag;
        dlist_mutable_iter iter;
 
        newtarget = hash_search_with_hash_value(PredicateLockTargetHash,
                                                &newtargettag,
                                                newtargettaghash,
                                                HASH_ENTER_NULL, &found);
 
        if (!newtarget)
        {
            /* Failed to allocate due to insufficient shmem */
            outOfShmem = true;
            goto exit;
        }
 
        /* If we created a new entry, initialize it */
        if (!found)
            dlist_init(&newtarget->predicateLocks);
 
        newpredlocktag.myTarget = newtarget;
 
        /*
         * Loop through all the locks on the old target, replacing them with
         * locks on the new target.
         */
        LWLockAcquire(SerializableXactHashLock, LW_EXCLUSIVE);
 
        dlist_foreach_modify(iter, &oldtarget->predicateLocks)
        {
            PREDICATELOCK *oldpredlock =
                dlist_container(PREDICATELOCK, targetLink, iter.cur);
            PREDICATELOCK *newpredlock;
            SerCommitSeqNo oldCommitSeqNo = oldpredlock->commitSeqNo;
 
            newpredlocktag.myXact = oldpredlock->tag.myXact;
 
            if (removeOld)
            {
                dlist_delete(&(oldpredlock->xactLink));
                dlist_delete(&(oldpredlock->targetLink));
 
                hash_search_with_hash_value
                    (PredicateLockHash,
                     &oldpredlock->tag,
                     PredicateLockHashCodeFromTargetHashCode(&oldpredlock->tag,
                                                             oldtargettaghash),
                     HASH_REMOVE, &found);
                Assert(found);
            }
 
            newpredlock = (PREDICATELOCK *)
                hash_search_with_hash_value(PredicateLockHash,
                                            &newpredlocktag,
                                            PredicateLockHashCodeFromTargetHashCode(&newpredlocktag,
                                                                                    newtargettaghash),
                                            HASH_ENTER_NULL,
                                            &found);
            if (!newpredlock)
            {
                /* Out of shared memory. Undo what we've done so far. */
                LWLockRelease(SerializableXactHashLock);
                DeleteLockTarget(newtarget, newtargettaghash);
                outOfShmem = true;
                goto exit;
            }
            if (!found)
            {
                dlist_push_tail(&(newtarget->predicateLocks),
                                &(newpredlock->targetLink));
                dlist_push_tail(&(newpredlocktag.myXact->predicateLocks),
                                &(newpredlock->xactLink));
                newpredlock->commitSeqNo = oldCommitSeqNo;
            }
            else
            {
                if (newpredlock->commitSeqNo < oldCommitSeqNo)
                    newpredlock->commitSeqNo = oldCommitSeqNo;
            }
 
            Assert(newpredlock->commitSeqNo != 0);
            Assert((newpredlock->commitSeqNo == InvalidSerCommitSeqNo)
                   || (newpredlock->tag.myXact == OldCommittedSxact));
        }
        LWLockRelease(SerializableXactHashLock);
 
        if (removeOld)
        {
            Assert(dlist_is_empty(&oldtarget->predicateLocks));
            RemoveTargetIfNoLongerUsed(oldtarget, oldtargettaghash);
        }
    }
 
 
exit:
    /* Release partition locks in reverse order of acquisition. */
    if (oldpartitionLock < newpartitionLock)
    {
        LWLockRelease(newpartitionLock);
        LWLockRelease(oldpartitionLock);
    }
    else if (oldpartitionLock > newpartitionLock)
    {
        LWLockRelease(oldpartitionLock);
        LWLockRelease(newpartitionLock);
    }
    else
        LWLockRelease(newpartitionLock);
 
    if (removeOld)
    {
        /* We shouldn't run out of memory if we're moving locks */
        Assert(!outOfShmem);
 
        /* Put the scratch entry back */
        RestoreScratchTarget(false);
    }
 
    return !outOfShmem;
}

References Assert, PREDICATELOCK::commitSeqNo, dlist_mutable_iter::cur, DeleteLockTarget(), dlist_container, dlist_delete(), dlist_foreach_modify, dlist_init(), dlist_is_empty(), dlist_push_tail(), fb(), HASH_ENTER_NULL, HASH_FIND, HASH_REMOVE, hash_search_with_hash_value(), InvalidSerCommitSeqNo, LW_EXCLUSIVE, LW_SHARED, LWLockAcquire(), LWLockHeldByMeInMode(), LWLockRelease(), OldCommittedSxact, PredicateLockHash, PredicateLockHashCodeFromTargetHashCode, PredicateLockHashPartitionLock, PredicateLockTargetHash, PredicateLockTargetTagHashCode, RemoveScratchTarget(), RemoveTargetIfNoLongerUsed(), and RestoreScratchTarget().

Referenced by PredicateLockPageSplit().

XidIsConcurrent()

static bool XidIsConcurrent ( TransactionId  xid )

static

Definition at line 3902 of file predicate.c.

{
    Snapshot    snap;
 
    Assert(TransactionIdIsValid(xid));
    Assert(!TransactionIdEquals(xid, GetTopTransactionIdIfAny()));
 
    snap = GetTransactionSnapshot();
 
    if (TransactionIdPrecedes(xid, snap->xmin))
        return false;
 
    if (TransactionIdFollowsOrEquals(xid, snap->xmax))
        return true;
 
    return pg_lfind32(xid, snap->xip, snap->xcnt);
}

References Assert, fb(), GetTopTransactionIdIfAny(), GetTransactionSnapshot(), pg_lfind32(), TransactionIdEquals, TransactionIdFollowsOrEquals(), TransactionIdIsValid, and TransactionIdPrecedes().

Referenced by CheckForSerializableConflictOut().

Variable Documentation

FinishedSerializableTransactions

dlist_head* FinishedSerializableTransactions

static

Definition at line 412 of file predicate.c.

Referenced by ClearOldPredicateLocks(), PredicateLockShmemInit(), PredicateLockShmemRequest(), ReleasePredicateLocks(), and SummarizeOldestCommittedSxact().

LocalPredicateLockHash

HTAB* LocalPredicateLockHash = NULL

static

Definition at line 427 of file predicate.c.

Referenced by CheckAndPromotePredicateLockRequest(), CheckTargetForConflictsIn(), CreateLocalPredicateLockHash(), DecrementParentLocks(), PostPrepare_PredicateLocks(), PredicateLockAcquire(), PredicateLockExists(), ReleasePredicateLocks(), and ReleasePredicateLocksLocal().

max_predicate_locks_per_page

int max_predicate_locks_per_page

Definition at line 375 of file predicate.c.

Referenced by MaxPredicateChildLocks().

max_predicate_locks_per_relation

int max_predicate_locks_per_relation

Definition at line 374 of file predicate.c.

Referenced by MaxPredicateChildLocks().

max_predicate_locks_per_xact

int max_predicate_locks_per_xact

Definition at line 373 of file predicate.c.

Referenced by CreateLocalPredicateLockHash(), and MaxPredicateChildLocks().

max_serializable_xacts

int64 max_serializable_xacts

static

Definition at line 446 of file predicate.c.

Referenced by PredicateLockShmemInit(), and PredicateLockShmemRequest().

MySerializableXact

SERIALIZABLEXACT* MySerializableXact = InvalidSerializableXact

static

Definition at line 434 of file predicate.c.

Referenced by AtPrepare_PredicateLocks(), AttachSerializableXact(), CheckForSerializableConflictIn(), CheckForSerializableConflictOut(), CheckForSerializableConflictOutNeeded(), CheckTableForSerializableConflictIn(), CheckTargetForConflictsIn(), DeleteChildTargetLocks(), GetSafeSnapshot(), GetSerializableTransactionSnapshotInt(), OnConflict_CheckForSerializationFailure(), PostPrepare_PredicateLocks(), PreCommit_CheckForSerializationFailure(), PredicateLockAcquire(), PredicateLockTwoPhaseFinish(), RegisterPredicateLockingXid(), ReleasePredicateLocks(), ReleasePredicateLocksLocal(), SerializationNeededForRead(), SerializationNeededForWrite(), and ShareSerializableXact().

MyXactDidWrite

bool MyXactDidWrite = false

static

Definition at line 435 of file predicate.c.

Referenced by CheckForSerializableConflictIn(), CheckTableForSerializableConflictIn(), GetSerializableTransactionSnapshotInt(), PostPrepare_PredicateLocks(), PredicateLockTwoPhaseFinish(), ReleasePredicateLocks(), and ReleasePredicateLocksLocal().

OldCommittedSxact

SERIALIZABLEXACT* OldCommittedSxact

static

Definition at line 364 of file predicate.c.

Referenced by ClearOldPredicateLocks(), DropAllPredicateLocksFromTable(), FlagRWConflict(), PredicateLockShmemAttach(), PredicateLockShmemInit(), ReleaseOneSerializableXact(), SetNewSxactGlobalXmin(), and TransferPredicateLocksToNewTarget().

PredicateLockHash

HTAB* PredicateLockHash

static

Definition at line 411 of file predicate.c.

Referenced by CheckTargetForConflictsIn(), ClearOldPredicateLocks(), CreatePredicateLock(), DeleteChildTargetLocks(), DeleteLockTarget(), DropAllPredicateLocksFromTable(), GetPredicateLockStatusData(), PredicateLockShmemRequest(), ReleaseOneSerializableXact(), and TransferPredicateLocksToNewTarget().

PredicateLockShmemCallbacks

const ShmemCallbacks PredicateLockShmemCallbacks

Initial value:

= {
    .request_fn = PredicateLockShmemRequest,
    .init_fn = PredicateLockShmemInit,
    .attach_fn = PredicateLockShmemAttach,
}

Definition at line 392 of file predicate.c.

                                                   {
    .request_fn = PredicateLockShmemRequest,
    .init_fn = PredicateLockShmemInit,
    .attach_fn = PredicateLockShmemAttach,
};

PredicateLockTargetHash

HTAB* PredicateLockTargetHash

static

Definition at line 410 of file predicate.c.

Referenced by CheckTableForSerializableConflictIn(), CheckTargetForConflictsIn(), CreatePredicateLock(), DropAllPredicateLocksFromTable(), PageIsPredicateLocked(), PredicateLockShmemInit(), PredicateLockShmemRequest(), RemoveScratchTarget(), RemoveTargetIfNoLongerUsed(), RestoreScratchTarget(), and TransferPredicateLocksToNewTarget().

PredXact

PredXactList PredXact

static

Definition at line 386 of file predicate.c.

Referenced by CheckTableForSerializableConflictIn(), ClearOldPredicateLocks(), CreatePredXact(), DropAllPredicateLocksFromTable(), GetSafeSnapshotBlockingPids(), GetSerializableTransactionSnapshotInt(), PreCommit_CheckForSerializationFailure(), predicatelock_twophase_recover(), PredicateLockPageSplit(), PredicateLockShmemAttach(), PredicateLockShmemInit(), PredicateLockShmemRequest(), ReleasePredicateLocks(), ReleasePredXact(), and SetNewSxactGlobalXmin().

RWConflictPool

RWConflictPoolHeader RWConflictPool

static

Definition at line 403 of file predicate.c.

Referenced by PredicateLockShmemInit(), PredicateLockShmemRequest(), ReleaseRWConflict(), SetPossibleUnsafeConflict(), and SetRWConflict().

SavedSerializableXact

SERIALIZABLEXACT* SavedSerializableXact = InvalidSerializableXact

static

Definition at line 444 of file predicate.c.

Referenced by ReleasePredicateLocks().

ScratchPartitionLock

LWLock* ScratchPartitionLock

static

Definition at line 421 of file predicate.c.

Referenced by PredicateLockShmemAttach(), PredicateLockShmemInit(), RemoveScratchTarget(), and RestoreScratchTarget().

ScratchTargetTag

const PREDICATELOCKTARGETTAG ScratchTargetTag = {0, 0, 0, 0}

static

Definition at line 419 of file predicate.c.

{0, 0, 0, 0};

Referenced by PredicateLockShmemAttach(), PredicateLockShmemInit(), RemoveScratchTarget(), and RestoreScratchTarget().

ScratchTargetTagHash

uint32 ScratchTargetTagHash

static

Definition at line 420 of file predicate.c.

Referenced by PredicateLockShmemAttach(), PredicateLockShmemInit(), RemoveScratchTarget(), and RestoreScratchTarget().

serialControl

SerialControl serialControl

static

Definition at line 356 of file predicate.c.

Referenced by CheckPointPredicate(), PredicateLockShmemInit(), PredicateLockShmemRequest(), SerialAdd(), SerialGetMinConflictCommitSeqNo(), and SerialSetActiveSerXmin().

SerializableXidHash

HTAB* SerializableXidHash

static

Definition at line 409 of file predicate.c.

Referenced by CheckForSerializableConflictOut(), predicatelock_twophase_recover(), PredicateLockShmemRequest(), PredicateLockTwoPhaseFinish(), RegisterPredicateLockingXid(), and ReleaseOneSerializableXact().

SerialSlruDesc

SlruDesc SerialSlruDesc

static

Definition at line 326 of file predicate.c.

Referenced by PredicateLockShmemRequest().