xact.c

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/*-------------------------------------------------------------------------
 *
 * xact.c
 *    top level transaction system support routines
 *
 * See src/backend/access/transam/README for more information.
 *
 * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *    src/backend/access/transam/xact.c
 *
 *-------------------------------------------------------------------------
 */
 
#include "postgres.h"
 
#include <time.h>
#include <unistd.h>
 
#include "access/commit_ts.h"
#include "access/multixact.h"
#include "access/parallel.h"
#include "access/subtrans.h"
#include "access/transam.h"
#include "access/twophase.h"
#include "access/xact.h"
#include "access/xlog.h"
#include "access/xloginsert.h"
#include "access/xlogrecovery.h"
#include "access/xlogutils.h"
#include "access/xlogwait.h"
#include "catalog/index.h"
#include "catalog/namespace.h"
#include "catalog/pg_enum.h"
#include "catalog/storage.h"
#include "commands/async.h"
#include "commands/tablecmds.h"
#include "commands/trigger.h"
#include "common/pg_prng.h"
#include "executor/spi.h"
#include "libpq/be-fsstubs.h"
#include "libpq/pqsignal.h"
#include "miscadmin.h"
#include "pg_trace.h"
#include "pgstat.h"
#include "replication/logical.h"
#include "replication/logicallauncher.h"
#include "replication/logicalworker.h"
#include "replication/origin.h"
#include "replication/snapbuild.h"
#include "replication/syncrep.h"
#include "storage/aio_subsys.h"
#include "storage/condition_variable.h"
#include "storage/fd.h"
#include "storage/lmgr.h"
#include "storage/md.h"
#include "storage/predicate.h"
#include "storage/proc.h"
#include "storage/procarray.h"
#include "storage/sinvaladt.h"
#include "storage/smgr.h"
#include "utils/builtins.h"
#include "utils/combocid.h"
#include "utils/guc.h"
#include "utils/inval.h"
#include "utils/memutils.h"
#include "utils/relmapper.h"
#include "utils/snapmgr.h"
#include "utils/timeout.h"
#include "utils/timestamp.h"
#include "utils/typcache.h"
#include "utils/wait_event.h"
 
/*
 *  User-tweakable parameters
 */
int         DefaultXactIsoLevel = XACT_READ_COMMITTED;
int         XactIsoLevel = XACT_READ_COMMITTED;
 
bool        DefaultXactReadOnly = false;
bool        XactReadOnly;
 
bool        DefaultXactDeferrable = false;
bool        XactDeferrable;
 
int         synchronous_commit = SYNCHRONOUS_COMMIT_ON;
 
/*
 * CheckXidAlive is a xid value pointing to a possibly ongoing (sub)
 * transaction.  Currently, it is used in logical decoding.  It's possible
 * that such transactions can get aborted while the decoding is ongoing in
 * which case we skip decoding that particular transaction.  To ensure that we
 * check whether the CheckXidAlive is aborted after fetching the tuple from
 * system tables.  We also ensure that during logical decoding we never
 * directly access the tableam or heap APIs because we are checking for the
 * concurrent aborts only in systable_* APIs.
 */
TransactionId CheckXidAlive = InvalidTransactionId;
bool        bsysscan = false;
 
/*
 * When running as a parallel worker, we place only a single
 * TransactionStateData on the parallel worker's state stack, and the XID
 * reflected there will be that of the *innermost* currently-active
 * subtransaction in the backend that initiated parallelism.  However,
 * GetTopTransactionId() and TransactionIdIsCurrentTransactionId()
 * need to return the same answers in the parallel worker as they would have
 * in the user backend, so we need some additional bookkeeping.
 *
 * XactTopFullTransactionId stores the XID of our toplevel transaction, which
 * will be the same as TopTransactionStateData.fullTransactionId in an
 * ordinary backend; but in a parallel backend, which does not have the entire
 * transaction state, it will instead be copied from the backend that started
 * the parallel operation.
 *
 * nParallelCurrentXids will be 0 and ParallelCurrentXids NULL in an ordinary
 * backend, but in a parallel backend, nParallelCurrentXids will contain the
 * number of XIDs that need to be considered current, and ParallelCurrentXids
 * will contain the XIDs themselves.  This includes all XIDs that were current
 * or sub-committed in the parent at the time the parallel operation began.
 * The XIDs are stored sorted in numerical order (not logical order) to make
 * lookups as fast as possible.
 */
static FullTransactionId XactTopFullTransactionId = {InvalidTransactionId};
static int  nParallelCurrentXids = 0;
static TransactionId *ParallelCurrentXids;
 
/*
 * Miscellaneous flag bits to record events which occur on the top level
 * transaction. These flags are only persisted in MyXactFlags and are intended
 * so we remember to do certain things later on in the transaction. This is
 * globally accessible, so can be set from anywhere in the code that requires
 * recording flags.
 */
int         MyXactFlags;
 
/*
 *  transaction states - transaction state from server perspective
 */
typedef enum TransState
{
    TRANS_DEFAULT,              /* idle */
    TRANS_START,                /* transaction starting */
    TRANS_INPROGRESS,           /* inside a valid transaction */
    TRANS_COMMIT,               /* commit in progress */
    TRANS_ABORT,                /* abort in progress */
    TRANS_PREPARE,              /* prepare in progress */
} TransState;
 
/*
 *  transaction block states - transaction state of client queries
 *
 * Note: the subtransaction states are used only for non-topmost
 * transactions; the others appear only in the topmost transaction.
 */
typedef enum TBlockState
{
    /* not-in-transaction-block states */
    TBLOCK_DEFAULT,             /* idle */
    TBLOCK_STARTED,             /* running single-query transaction */
 
    /* transaction block states */
    TBLOCK_BEGIN,               /* starting transaction block */
    TBLOCK_INPROGRESS,          /* live transaction */
    TBLOCK_IMPLICIT_INPROGRESS, /* live transaction after implicit BEGIN */
    TBLOCK_PARALLEL_INPROGRESS, /* live transaction inside parallel worker */
    TBLOCK_END,                 /* COMMIT received */
    TBLOCK_ABORT,               /* failed xact, awaiting ROLLBACK */
    TBLOCK_ABORT_END,           /* failed xact, ROLLBACK received */
    TBLOCK_ABORT_PENDING,       /* live xact, ROLLBACK received */
    TBLOCK_PREPARE,             /* live xact, PREPARE received */
 
    /* subtransaction states */
    TBLOCK_SUBBEGIN,            /* starting a subtransaction */
    TBLOCK_SUBINPROGRESS,       /* live subtransaction */
    TBLOCK_SUBRELEASE,          /* RELEASE received */
    TBLOCK_SUBCOMMIT,           /* COMMIT received while TBLOCK_SUBINPROGRESS */
    TBLOCK_SUBABORT,            /* failed subxact, awaiting ROLLBACK */
    TBLOCK_SUBABORT_END,        /* failed subxact, ROLLBACK received */
    TBLOCK_SUBABORT_PENDING,    /* live subxact, ROLLBACK received */
    TBLOCK_SUBRESTART,          /* live subxact, ROLLBACK TO received */
    TBLOCK_SUBABORT_RESTART,    /* failed subxact, ROLLBACK TO received */
} TBlockState;
 
/*
 *  transaction state structure
 *
 * Note: parallelModeLevel counts the number of unmatched EnterParallelMode
 * calls done at this transaction level.  parallelChildXact is true if any
 * upper transaction level has nonzero parallelModeLevel.
 */
typedef struct TransactionStateData
{
    FullTransactionId fullTransactionId;    /* my FullTransactionId */
    SubTransactionId subTransactionId;  /* my subxact ID */
    char       *name;           /* savepoint name, if any */
    int         savepointLevel; /* savepoint level */
    TransState  state;          /* low-level state */
    TBlockState blockState;     /* high-level state */
    int         nestingLevel;   /* transaction nesting depth */
    int         gucNestLevel;   /* GUC context nesting depth */
    MemoryContext curTransactionContext;    /* my xact-lifetime context */
    ResourceOwner curTransactionOwner;  /* my query resources */
    MemoryContext priorContext; /* CurrentMemoryContext before xact started */
    TransactionId *childXids;   /* subcommitted child XIDs, in XID order */
    int         nChildXids;     /* # of subcommitted child XIDs */
    int         maxChildXids;   /* allocated size of childXids[] */
    Oid         prevUser;       /* previous CurrentUserId setting */
    int         prevSecContext; /* previous SecurityRestrictionContext */
    bool        prevXactReadOnly;   /* entry-time xact r/o state */
    bool        startedInRecovery;  /* did we start in recovery? */
    bool        didLogXid;      /* has xid been included in WAL record? */
    int         parallelModeLevel;  /* Enter/ExitParallelMode counter */
    bool        parallelChildXact;  /* is any parent transaction parallel? */
    bool        chain;          /* start a new block after this one */
    bool        topXidLogged;   /* for a subxact: is top-level XID logged? */
    struct TransactionStateData *parent;    /* back link to parent */
} TransactionStateData;
 
typedef TransactionStateData *TransactionState;
 
/*
 * Serialized representation used to transmit transaction state to parallel
 * workers through shared memory.
 */
typedef struct SerializedTransactionState
{
    int         xactIsoLevel;
    bool        xactDeferrable;
    FullTransactionId topFullTransactionId;
    FullTransactionId currentFullTransactionId;
    CommandId   currentCommandId;
    int         nParallelCurrentXids;
    TransactionId parallelCurrentXids[FLEXIBLE_ARRAY_MEMBER];
} SerializedTransactionState;
 
/* The size of SerializedTransactionState, not including the final array. */
#define SerializedTransactionStateHeaderSize \
    offsetof(SerializedTransactionState, parallelCurrentXids)
 
/*
 * CurrentTransactionState always points to the current transaction state
 * block.  It will point to TopTransactionStateData when not in a
 * transaction at all, or when in a top-level transaction.
 */
static TransactionStateData TopTransactionStateData = {
    .state = TRANS_DEFAULT,
    .blockState = TBLOCK_DEFAULT,
    .topXidLogged = false,
};
 
/*
 * unreportedXids holds XIDs of all subtransactions that have not yet been
 * reported in an XLOG_XACT_ASSIGNMENT record.
 */
static int  nUnreportedXids;
static TransactionId unreportedXids[PGPROC_MAX_CACHED_SUBXIDS];
 
static TransactionState CurrentTransactionState = &TopTransactionStateData;
 
/*
 * The subtransaction ID and command ID assignment counters are global
 * to a whole transaction, so we do not keep them in the state stack.
 */
static SubTransactionId currentSubTransactionId;
static CommandId currentCommandId;
static bool currentCommandIdUsed;
 
/*
 * xactStartTimestamp is the value of transaction_timestamp().
 * stmtStartTimestamp is the value of statement_timestamp().
 * xactStopTimestamp is the time at which we log a commit / abort WAL record,
 * or if that was skipped, the time of the first subsequent
 * GetCurrentTransactionStopTimestamp() call.
 *
 * These do not change as we enter and exit subtransactions, so we don't
 * keep them inside the TransactionState stack.
 */
static TimestampTz xactStartTimestamp;
static TimestampTz stmtStartTimestamp;
static TimestampTz xactStopTimestamp;
 
/*
 * GID to be used for preparing the current transaction.  This is also
 * global to a whole transaction, so we don't keep it in the state stack.
 */
static char *prepareGID;
 
/*
 * Some commands want to force synchronous commit.
 */
static bool forceSyncCommit = false;
 
/* Flag for logging statements in a transaction. */
bool        xact_is_sampled = false;
 
/*
 * Private context for transaction-abort work --- we reserve space for this
 * at startup to ensure that AbortTransaction and AbortSubTransaction can work
 * when we've run out of memory.
 */
static MemoryContext TransactionAbortContext = NULL;
 
/*
 * List of add-on start- and end-of-xact callbacks
 */
typedef struct XactCallbackItem
{
    struct XactCallbackItem *next;
    XactCallback callback;
    void       *arg;
} XactCallbackItem;
 
static XactCallbackItem *Xact_callbacks = NULL;
 
/*
 * List of add-on start- and end-of-subxact callbacks
 */
typedef struct SubXactCallbackItem
{
    struct SubXactCallbackItem *next;
    SubXactCallback callback;
    void       *arg;
} SubXactCallbackItem;
 
static SubXactCallbackItem *SubXact_callbacks = NULL;
 
 
/* local function prototypes */
static void AssignTransactionId(TransactionState s);
static void AbortTransaction(void);
static void AtAbort_Memory(void);
static void AtCleanup_Memory(void);
static void AtAbort_ResourceOwner(void);
static void AtCCI_LocalCache(void);
static void AtCommit_Memory(void);
static void AtStart_Cache(void);
static void AtStart_Memory(void);
static void AtStart_ResourceOwner(void);
static void CallXactCallbacks(XactEvent event);
static void CallSubXactCallbacks(SubXactEvent event,
                                 SubTransactionId mySubid,
                                 SubTransactionId parentSubid);
static void CleanupTransaction(void);
static void CheckTransactionBlock(bool isTopLevel, bool throwError,
                                  const char *stmtType);
static void CommitTransaction(void);
static TransactionId RecordTransactionAbort(bool isSubXact);
static void StartTransaction(void);
 
static bool CommitTransactionCommandInternal(void);
static bool AbortCurrentTransactionInternal(void);
 
static void StartSubTransaction(void);
static void CommitSubTransaction(void);
static void AbortSubTransaction(void);
static void CleanupSubTransaction(void);
static void PushTransaction(void);
static void PopTransaction(void);
 
static void AtSubAbort_Memory(void);
static void AtSubCleanup_Memory(void);
static void AtSubAbort_ResourceOwner(void);
static void AtSubCommit_Memory(void);
static void AtSubStart_Memory(void);
static void AtSubStart_ResourceOwner(void);
 
static void ShowTransactionState(const char *str);
static void ShowTransactionStateRec(const char *str, TransactionState s);
static const char *BlockStateAsString(TBlockState blockState);
static const char *TransStateAsString(TransState state);
 
 
/* ----------------------------------------------------------------
 *  transaction state accessors
 * ----------------------------------------------------------------
 */
 
/*
 *  IsTransactionState
 *
 *  This returns true if we are inside a valid transaction; that is,
 *  it is safe to initiate database access, take heavyweight locks, etc.
 */
bool
IsTransactionState(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * TRANS_DEFAULT and TRANS_ABORT are obviously unsafe states.  However, we
     * also reject the startup/shutdown states TRANS_START, TRANS_COMMIT,
     * TRANS_PREPARE since it might be too soon or too late within those
     * transition states to do anything interesting.  Hence, the only "valid"
     * state is TRANS_INPROGRESS.
     */
    return (s->state == TRANS_INPROGRESS);
}
 
/*
 *  IsAbortedTransactionBlockState
 *
 *  This returns true if we are within an aborted transaction block.
 */
bool
IsAbortedTransactionBlockState(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->blockState == TBLOCK_ABORT ||
        s->blockState == TBLOCK_SUBABORT)
        return true;
 
    return false;
}
 
 
/*
 *  GetTopTransactionId
 *
 * This will return the XID of the main transaction, assigning one if
 * it's not yet set.  Be careful to call this only inside a valid xact.
 */
TransactionId
GetTopTransactionId(void)
{
    if (!FullTransactionIdIsValid(XactTopFullTransactionId))
        AssignTransactionId(&TopTransactionStateData);
    return XidFromFullTransactionId(XactTopFullTransactionId);
}
 
/*
 *  GetTopTransactionIdIfAny
 *
 * This will return the XID of the main transaction, if one is assigned.
 * It will return InvalidTransactionId if we are not currently inside a
 * transaction, or inside a transaction that hasn't yet been assigned an XID.
 */
TransactionId
GetTopTransactionIdIfAny(void)
{
    return XidFromFullTransactionId(XactTopFullTransactionId);
}
 
/*
 *  GetCurrentTransactionId
 *
 * This will return the XID of the current transaction (main or sub
 * transaction), assigning one if it's not yet set.  Be careful to call this
 * only inside a valid xact.
 */
TransactionId
GetCurrentTransactionId(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (!FullTransactionIdIsValid(s->fullTransactionId))
        AssignTransactionId(s);
    return XidFromFullTransactionId(s->fullTransactionId);
}
 
/*
 *  GetCurrentTransactionIdIfAny
 *
 * This will return the XID of the current sub xact, if one is assigned.
 * It will return InvalidTransactionId if we are not currently inside a
 * transaction, or inside a transaction that hasn't been assigned an XID yet.
 */
TransactionId
GetCurrentTransactionIdIfAny(void)
{
    return XidFromFullTransactionId(CurrentTransactionState->fullTransactionId);
}
 
/*
 *  GetTopFullTransactionId
 *
 * This will return the FullTransactionId of the main transaction, assigning
 * one if it's not yet set.  Be careful to call this only inside a valid xact.
 */
FullTransactionId
GetTopFullTransactionId(void)
{
    if (!FullTransactionIdIsValid(XactTopFullTransactionId))
        AssignTransactionId(&TopTransactionStateData);
    return XactTopFullTransactionId;
}
 
/*
 *  GetTopFullTransactionIdIfAny
 *
 * This will return the FullTransactionId of the main transaction, if one is
 * assigned.  It will return InvalidFullTransactionId if we are not currently
 * inside a transaction, or inside a transaction that hasn't yet been assigned
 * one.
 */
FullTransactionId
GetTopFullTransactionIdIfAny(void)
{
    return XactTopFullTransactionId;
}
 
/*
 *  GetCurrentFullTransactionId
 *
 * This will return the FullTransactionId of the current transaction (main or
 * sub transaction), assigning one if it's not yet set.  Be careful to call
 * this only inside a valid xact.
 */
FullTransactionId
GetCurrentFullTransactionId(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (!FullTransactionIdIsValid(s->fullTransactionId))
        AssignTransactionId(s);
    return s->fullTransactionId;
}
 
/*
 *  GetCurrentFullTransactionIdIfAny
 *
 * This will return the FullTransactionId of the current sub xact, if one is
 * assigned.  It will return InvalidFullTransactionId if we are not currently
 * inside a transaction, or inside a transaction that hasn't been assigned one
 * yet.
 */
FullTransactionId
GetCurrentFullTransactionIdIfAny(void)
{
    return CurrentTransactionState->fullTransactionId;
}
 
/*
 *  MarkCurrentTransactionIdLoggedIfAny
 *
 * Remember that the current xid - if it is assigned - now has been wal logged.
 */
void
MarkCurrentTransactionIdLoggedIfAny(void)
{
    if (FullTransactionIdIsValid(CurrentTransactionState->fullTransactionId))
        CurrentTransactionState->didLogXid = true;
}
 
/*
 * IsSubxactTopXidLogPending
 *
 * This is used to decide whether we need to WAL log the top-level XID for
 * operation in a subtransaction.  We require that for logical decoding, see
 * LogicalDecodingProcessRecord.
 *
 * This returns true if effective_wal_level is logical and we are inside
 * a valid subtransaction, for which the assignment was not yet written to
 * any WAL record.
 */
bool
IsSubxactTopXidLogPending(void)
{
    /* check whether it is already logged */
    if (CurrentTransactionState->topXidLogged)
        return false;
 
    /* effective_wal_level has to be logical */
    if (!XLogLogicalInfoActive())
        return false;
 
    /* we need to be in a transaction state */
    if (!IsTransactionState())
        return false;
 
    /* it has to be a subtransaction */
    if (!IsSubTransaction())
        return false;
 
    /* the subtransaction has to have a XID assigned */
    if (!TransactionIdIsValid(GetCurrentTransactionIdIfAny()))
        return false;
 
    return true;
}
 
/*
 * MarkSubxactTopXidLogged
 *
 * Remember that the top transaction id for the current subtransaction is WAL
 * logged now.
 */
void
MarkSubxactTopXidLogged(void)
{
    Assert(IsSubxactTopXidLogPending());
 
    CurrentTransactionState->topXidLogged = true;
}
 
/*
 *  GetStableLatestTransactionId
 *
 * Get the transaction's XID if it has one, else read the next-to-be-assigned
 * XID.  Once we have a value, return that same value for the remainder of the
 * current transaction.  This is meant to provide the reference point for the
 * age(xid) function, but might be useful for other maintenance tasks as well.
 */
TransactionId
GetStableLatestTransactionId(void)
{
    static LocalTransactionId lxid = InvalidLocalTransactionId;
    static TransactionId stablexid = InvalidTransactionId;
 
    if (lxid != MyProc->vxid.lxid)
    {
        lxid = MyProc->vxid.lxid;
        stablexid = GetTopTransactionIdIfAny();
        if (!TransactionIdIsValid(stablexid))
            stablexid = ReadNextTransactionId();
    }
 
    Assert(TransactionIdIsValid(stablexid));
 
    return stablexid;
}
 
/*
 * AssignTransactionId
 *
 * Assigns a new permanent FullTransactionId to the given TransactionState.
 * We do not assign XIDs to transactions until/unless this is called.
 * Also, any parent TransactionStates that don't yet have XIDs are assigned
 * one; this maintains the invariant that a child transaction has an XID
 * following its parent's.
 */
static void
AssignTransactionId(TransactionState s)
{
    bool        isSubXact = (s->parent != NULL);
    ResourceOwner currentOwner;
    bool        log_unknown_top = false;
 
    /* Assert that caller didn't screw up */
    Assert(!FullTransactionIdIsValid(s->fullTransactionId));
    Assert(s->state == TRANS_INPROGRESS);
 
    /*
     * Workers synchronize transaction state at the beginning of each parallel
     * operation, so we can't account for new XIDs at this point.
     */
    if (IsInParallelMode() || IsParallelWorker())
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                 errmsg("cannot assign transaction IDs during a parallel operation")));
 
    /*
     * Ensure parent(s) have XIDs, so that a child always has an XID later
     * than its parent.  Mustn't recurse here, or we might get a stack
     * overflow if we're at the bottom of a huge stack of subtransactions none
     * of which have XIDs yet.
     */
    if (isSubXact && !FullTransactionIdIsValid(s->parent->fullTransactionId))
    {
        TransactionState p = s->parent;
        TransactionState *parents;
        size_t      parentOffset = 0;
 
        parents = palloc_array(TransactionState, s->nestingLevel);
        while (p != NULL && !FullTransactionIdIsValid(p->fullTransactionId))
        {
            parents[parentOffset++] = p;
            p = p->parent;
        }
 
        /*
         * This is technically a recursive call, but the recursion will never
         * be more than one layer deep.
         */
        while (parentOffset != 0)
            AssignTransactionId(parents[--parentOffset]);
 
        pfree(parents);
    }
 
    /*
     * When effective_wal_level is logical, guarantee that a subtransaction's
     * xid can only be seen in the WAL stream if its toplevel xid has been
     * logged before. If necessary we log an xact_assignment record with fewer
     * than PGPROC_MAX_CACHED_SUBXIDS. Note that it is fine if didLogXid isn't
     * set for a transaction even though it appears in a WAL record, we just
     * might superfluously log something. That can happen when an xid is
     * included somewhere inside a wal record, but not in XLogRecord->xl_xid,
     * like in xl_standby_locks.
     */
    if (isSubXact && XLogLogicalInfoActive() &&
        !TopTransactionStateData.didLogXid)
        log_unknown_top = true;
 
    /*
     * Generate a new FullTransactionId and record its xid in PGPROC and
     * pg_subtrans.
     *
     * NB: we must make the subtrans entry BEFORE the Xid appears anywhere in
     * shared storage other than PGPROC; because if there's no room for it in
     * PGPROC, the subtrans entry is needed to ensure that other backends see
     * the Xid as "running".  See GetNewTransactionId.
     */
    s->fullTransactionId = GetNewTransactionId(isSubXact);
    if (!isSubXact)
        XactTopFullTransactionId = s->fullTransactionId;
 
    if (isSubXact)
        SubTransSetParent(XidFromFullTransactionId(s->fullTransactionId),
                          XidFromFullTransactionId(s->parent->fullTransactionId));
 
    /*
     * If it's a top-level transaction, the predicate locking system needs to
     * be told about it too.
     */
    if (!isSubXact)
        RegisterPredicateLockingXid(XidFromFullTransactionId(s->fullTransactionId));
 
    /*
     * Acquire lock on the transaction XID.  (We assume this cannot block.) We
     * have to ensure that the lock is assigned to the transaction's own
     * ResourceOwner.
     */
    currentOwner = CurrentResourceOwner;
    CurrentResourceOwner = s->curTransactionOwner;
 
    XactLockTableInsert(XidFromFullTransactionId(s->fullTransactionId));
 
    CurrentResourceOwner = currentOwner;
 
    /*
     * Every PGPROC_MAX_CACHED_SUBXIDS assigned transaction ids within each
     * top-level transaction we issue a WAL record for the assignment. We
     * include the top-level xid and all the subxids that have not yet been
     * reported using XLOG_XACT_ASSIGNMENT records.
     *
     * This is required to limit the amount of shared memory required in a hot
     * standby server to keep track of in-progress XIDs. See notes for
     * RecordKnownAssignedTransactionIds().
     *
     * We don't keep track of the immediate parent of each subxid, only the
     * top-level transaction that each subxact belongs to. This is correct in
     * recovery only because aborted subtransactions are separately WAL
     * logged.
     *
     * This is correct even for the case where several levels above us didn't
     * have an xid assigned as we recursed up to them beforehand.
     */
    if (isSubXact && XLogStandbyInfoActive())
    {
        unreportedXids[nUnreportedXids] = XidFromFullTransactionId(s->fullTransactionId);
        nUnreportedXids++;
 
        /*
         * ensure this test matches similar one in
         * RecoverPreparedTransactions()
         */
        if (nUnreportedXids >= PGPROC_MAX_CACHED_SUBXIDS ||
            log_unknown_top)
        {
            xl_xact_assignment xlrec;
 
            /*
             * xtop is always set by now because we recurse up transaction
             * stack to the highest unassigned xid and then come back down
             */
            xlrec.xtop = GetTopTransactionId();
            Assert(TransactionIdIsValid(xlrec.xtop));
            xlrec.nsubxacts = nUnreportedXids;
 
            XLogBeginInsert();
            XLogRegisterData(&xlrec, MinSizeOfXactAssignment);
            XLogRegisterData(unreportedXids,
                             nUnreportedXids * sizeof(TransactionId));
 
            (void) XLogInsert(RM_XACT_ID, XLOG_XACT_ASSIGNMENT);
 
            nUnreportedXids = 0;
            /* mark top, not current xact as having been logged */
            TopTransactionStateData.didLogXid = true;
        }
    }
}
 
/*
 *  GetCurrentSubTransactionId
 */
SubTransactionId
GetCurrentSubTransactionId(void)
{
    TransactionState s = CurrentTransactionState;
 
    return s->subTransactionId;
}
 
/*
 *  SubTransactionIsActive
 *
 * Test if the specified subxact ID is still active.  Note caller is
 * responsible for checking whether this ID is relevant to the current xact.
 */
bool
SubTransactionIsActive(SubTransactionId subxid)
{
    TransactionState s;
 
    for (s = CurrentTransactionState; s != NULL; s = s->parent)
    {
        if (s->state == TRANS_ABORT)
            continue;
        if (s->subTransactionId == subxid)
            return true;
    }
    return false;
}
 
 
/*
 *  GetCurrentCommandId
 *
 * "used" must be true if the caller intends to use the command ID to mark
 * inserted/updated/deleted tuples.  false means the ID is being fetched
 * for read-only purposes (ie, as a snapshot validity cutoff).  See
 * CommandCounterIncrement() for discussion.
 */
CommandId
GetCurrentCommandId(bool used)
{
    /* this is global to a transaction, not subtransaction-local */
    if (used)
    {
        /*
         * Forbid setting currentCommandIdUsed in a parallel worker, because
         * we have no provision for communicating this back to the leader.  We
         * could relax this restriction when currentCommandIdUsed was already
         * true at the start of the parallel operation.
         */
        if (IsParallelWorker())
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                     errmsg("cannot modify data in a parallel worker")));
 
        currentCommandIdUsed = true;
    }
    return currentCommandId;
}
 
/*
 *  SetParallelStartTimestamps
 *
 * In a parallel worker, we should inherit the parent transaction's
 * timestamps rather than setting our own.  The parallel worker
 * infrastructure must call this to provide those values before
 * calling StartTransaction() or SetCurrentStatementStartTimestamp().
 */
void
SetParallelStartTimestamps(TimestampTz xact_ts, TimestampTz stmt_ts)
{
    Assert(IsParallelWorker());
    xactStartTimestamp = xact_ts;
    stmtStartTimestamp = stmt_ts;
}
 
/*
 *  GetCurrentTransactionStartTimestamp
 */
TimestampTz
GetCurrentTransactionStartTimestamp(void)
{
    return xactStartTimestamp;
}
 
/*
 *  GetCurrentStatementStartTimestamp
 */
TimestampTz
GetCurrentStatementStartTimestamp(void)
{
    return stmtStartTimestamp;
}
 
/*
 *  GetCurrentTransactionStopTimestamp
 *
 * If the transaction stop time hasn't already been set, which can happen if
 * we decided we don't need to log an XLOG record, set xactStopTimestamp.
 */
TimestampTz
GetCurrentTransactionStopTimestamp(void)
{
    TransactionState s PG_USED_FOR_ASSERTS_ONLY = CurrentTransactionState;
 
    /* should only be called after commit / abort processing */
    Assert(s->state == TRANS_DEFAULT ||
           s->state == TRANS_COMMIT ||
           s->state == TRANS_ABORT ||
           s->state == TRANS_PREPARE);
 
    if (xactStopTimestamp == 0)
        xactStopTimestamp = GetCurrentTimestamp();
 
    return xactStopTimestamp;
}
 
/*
 *  SetCurrentStatementStartTimestamp
 *
 * In a parallel worker, this should already have been provided by a call
 * to SetParallelStartTimestamps().
 */
void
SetCurrentStatementStartTimestamp(void)
{
    if (!IsParallelWorker())
        stmtStartTimestamp = GetCurrentTimestamp();
    else
        Assert(stmtStartTimestamp != 0);
}
 
/*
 *  GetCurrentTransactionNestLevel
 *
 * Note: this will return zero when not inside any transaction, one when
 * inside a top-level transaction, etc.
 */
int
GetCurrentTransactionNestLevel(void)
{
    TransactionState s = CurrentTransactionState;
 
    return s->nestingLevel;
}
 
 
/*
 *  TransactionIdIsCurrentTransactionId
 */
bool
TransactionIdIsCurrentTransactionId(TransactionId xid)
{
    TransactionState s;
 
    /*
     * We always say that BootstrapTransactionId is "not my transaction ID"
     * even when it is (ie, during bootstrap).  Along with the fact that
     * transam.c always treats BootstrapTransactionId as already committed,
     * this causes the heapam_visibility.c routines to see all tuples as
     * committed, which is what we need during bootstrap.  (Bootstrap mode
     * only inserts tuples, it never updates or deletes them, so all tuples
     * can be presumed good immediately.)
     *
     * Likewise, InvalidTransactionId and FrozenTransactionId are certainly
     * not my transaction ID, so we can just return "false" immediately for
     * any non-normal XID.
     */
    if (!TransactionIdIsNormal(xid))
        return false;
 
    if (TransactionIdEquals(xid, GetTopTransactionIdIfAny()))
        return true;
 
    /*
     * In parallel workers, the XIDs we must consider as current are stored in
     * ParallelCurrentXids rather than the transaction-state stack.  Note that
     * the XIDs in this array are sorted numerically rather than according to
     * transactionIdPrecedes order.
     */
    if (nParallelCurrentXids > 0)
    {
        int         low,
                    high;
 
        low = 0;
        high = nParallelCurrentXids - 1;
        while (low <= high)
        {
            int         middle;
            TransactionId probe;
 
            middle = low + (high - low) / 2;
            probe = ParallelCurrentXids[middle];
            if (probe == xid)
                return true;
            else if (probe < xid)
                low = middle + 1;
            else
                high = middle - 1;
        }
        return false;
    }
 
    /*
     * We will return true for the Xid of the current subtransaction, any of
     * its subcommitted children, any of its parents, or any of their
     * previously subcommitted children.  However, a transaction being aborted
     * is no longer "current", even though it may still have an entry on the
     * state stack.
     */
    for (s = CurrentTransactionState; s != NULL; s = s->parent)
    {
        int         low,
                    high;
 
        if (s->state == TRANS_ABORT)
            continue;
        if (!FullTransactionIdIsValid(s->fullTransactionId))
            continue;           /* it can't have any child XIDs either */
        if (TransactionIdEquals(xid, XidFromFullTransactionId(s->fullTransactionId)))
            return true;
        /* As the childXids array is ordered, we can use binary search */
        low = 0;
        high = s->nChildXids - 1;
        while (low <= high)
        {
            int         middle;
            TransactionId probe;
 
            middle = low + (high - low) / 2;
            probe = s->childXids[middle];
            if (TransactionIdEquals(probe, xid))
                return true;
            else if (TransactionIdPrecedes(probe, xid))
                low = middle + 1;
            else
                high = middle - 1;
        }
    }
 
    return false;
}
 
/*
 *  TransactionStartedDuringRecovery
 *
 * Returns true if the current transaction started while recovery was still
 * in progress. Recovery might have ended since so RecoveryInProgress() might
 * return false already.
 */
bool
TransactionStartedDuringRecovery(void)
{
    return CurrentTransactionState->startedInRecovery;
}
 
/*
 *  EnterParallelMode
 */
void
EnterParallelMode(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(s->parallelModeLevel >= 0);
 
    ++s->parallelModeLevel;
}
 
/*
 *  ExitParallelMode
 */
void
ExitParallelMode(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(s->parallelModeLevel > 0);
    Assert(s->parallelModeLevel > 1 || s->parallelChildXact ||
           !ParallelContextActive());
 
    --s->parallelModeLevel;
}
 
/*
 *  IsInParallelMode
 *
 * Are we in a parallel operation, as either the leader or a worker?  Check
 * this to prohibit operations that change backend-local state expected to
 * match across all workers.  Mere caches usually don't require such a
 * restriction.  State modified in a strict push/pop fashion, such as the
 * active snapshot stack, is often fine.
 *
 * We say we are in parallel mode if we are in a subxact of a transaction
 * that's initiated a parallel operation; for most purposes that context
 * has all the same restrictions.
 */
bool
IsInParallelMode(void)
{
    TransactionState s = CurrentTransactionState;
 
    return s->parallelModeLevel != 0 || s->parallelChildXact;
}
 
/*
 *  CommandCounterIncrement
 */
void
CommandCounterIncrement(void)
{
    /*
     * If the current value of the command counter hasn't been "used" to mark
     * tuples, we need not increment it, since there's no need to distinguish
     * a read-only command from others.  This helps postpone command counter
     * overflow, and keeps no-op CommandCounterIncrement operations cheap.
     */
    if (currentCommandIdUsed)
    {
        /*
         * Workers synchronize transaction state at the beginning of each
         * parallel operation, so we can't account for new commands after that
         * point.
         */
        if (IsInParallelMode() || IsParallelWorker())
            ereport(ERROR,
                    (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                     errmsg("cannot start commands during a parallel operation")));
 
        currentCommandId += 1;
        if (currentCommandId == InvalidCommandId)
        {
            currentCommandId -= 1;
            ereport(ERROR,
                    (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
                     errmsg("cannot have more than 2^32-2 commands in a transaction")));
        }
        currentCommandIdUsed = false;
 
        /* Propagate new command ID into static snapshots */
        SnapshotSetCommandId(currentCommandId);
 
        /*
         * Make any catalog changes done by the just-completed command visible
         * in the local syscache.  We obviously don't need to do this after a
         * read-only command.  (But see hacks in inval.c to make real sure we
         * don't think a command that queued inval messages was read-only.)
         */
        AtCCI_LocalCache();
    }
}
 
/*
 * ForceSyncCommit
 *
 * Interface routine to allow commands to force a synchronous commit of the
 * current top-level transaction.  Currently, two-phase commit does not
 * persist and restore this variable.  So long as all callers use
 * PreventInTransactionBlock(), that omission has no consequences.
 */
void
ForceSyncCommit(void)
{
    forceSyncCommit = true;
}
 
 
/* ----------------------------------------------------------------
 *                      StartTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 *  AtStart_Cache
 */
static void
AtStart_Cache(void)
{
    AcceptInvalidationMessages();
}
 
/*
 *  AtStart_Memory
 */
static void
AtStart_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * Remember the memory context that was active prior to transaction start.
     */
    s->priorContext = CurrentMemoryContext;
 
    /*
     * If this is the first time through, create a private context for
     * AbortTransaction to work in.  By reserving some space now, we can
     * insulate AbortTransaction from out-of-memory scenarios.  Like
     * ErrorContext, we set it up with slow growth rate and a nonzero minimum
     * size, so that space will be reserved immediately.
     */
    if (TransactionAbortContext == NULL)
        TransactionAbortContext =
            AllocSetContextCreate(TopMemoryContext,
                                  "TransactionAbortContext",
                                  32 * 1024,
                                  32 * 1024,
                                  32 * 1024);
 
    /*
     * Likewise, if this is the first time through, create a top-level context
     * for transaction-local data.  This context will be reset at transaction
     * end, and then re-used in later transactions.
     */
    if (TopTransactionContext == NULL)
        TopTransactionContext =
            AllocSetContextCreate(TopMemoryContext,
                                  "TopTransactionContext",
                                  ALLOCSET_DEFAULT_SIZES);
 
    /*
     * In a top-level transaction, CurTransactionContext is the same as
     * TopTransactionContext.
     */
    CurTransactionContext = TopTransactionContext;
    s->curTransactionContext = CurTransactionContext;
 
    /* Make the CurTransactionContext active. */
    MemoryContextSwitchTo(CurTransactionContext);
}
 
/*
 *  AtStart_ResourceOwner
 */
static void
AtStart_ResourceOwner(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * We shouldn't have a transaction resource owner already.
     */
    Assert(TopTransactionResourceOwner == NULL);
 
    /*
     * Create a toplevel resource owner for the transaction.
     */
    s->curTransactionOwner = ResourceOwnerCreate(NULL, "TopTransaction");
 
    TopTransactionResourceOwner = s->curTransactionOwner;
    CurTransactionResourceOwner = s->curTransactionOwner;
    CurrentResourceOwner = s->curTransactionOwner;
}
 
/* ----------------------------------------------------------------
 *                      StartSubTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 * AtSubStart_Memory
 */
static void
AtSubStart_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(CurTransactionContext != NULL);
 
    /*
     * Remember the context that was active prior to subtransaction start.
     */
    s->priorContext = CurrentMemoryContext;
 
    /*
     * Create a CurTransactionContext, which will be used to hold data that
     * survives subtransaction commit but disappears on subtransaction abort.
     * We make it a child of the immediate parent's CurTransactionContext.
     */
    CurTransactionContext = AllocSetContextCreate(CurTransactionContext,
                                                  "CurTransactionContext",
                                                  ALLOCSET_DEFAULT_SIZES);
    s->curTransactionContext = CurTransactionContext;
 
    /* Make the CurTransactionContext active. */
    MemoryContextSwitchTo(CurTransactionContext);
}
 
/*
 * AtSubStart_ResourceOwner
 */
static void
AtSubStart_ResourceOwner(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(s->parent != NULL);
 
    /*
     * Create a resource owner for the subtransaction.  We make it a child of
     * the immediate parent's resource owner.
     */
    s->curTransactionOwner =
        ResourceOwnerCreate(s->parent->curTransactionOwner,
                            "SubTransaction");
 
    CurTransactionResourceOwner = s->curTransactionOwner;
    CurrentResourceOwner = s->curTransactionOwner;
}
 
/* ----------------------------------------------------------------
 *                      CommitTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 *  RecordTransactionCommit
 *
 * Returns latest XID among xact and its children, or InvalidTransactionId
 * if the xact has no XID.  (We compute that here just because it's easier.)
 *
 * If you change this function, see RecordTransactionCommitPrepared also.
 */
static TransactionId
RecordTransactionCommit(void)
{
    TransactionId xid = GetTopTransactionIdIfAny();
    bool        markXidCommitted = TransactionIdIsValid(xid);
    TransactionId latestXid = InvalidTransactionId;
    int         nrels;
    RelFileLocator *rels;
    int         nchildren;
    TransactionId *children;
    int         ndroppedstats = 0;
    xl_xact_stats_item *droppedstats = NULL;
    int         nmsgs = 0;
    SharedInvalidationMessage *invalMessages = NULL;
    bool        RelcacheInitFileInval = false;
    bool        wrote_xlog;
 
    /*
     * Log pending invalidations for logical decoding of in-progress
     * transactions.  Normally for DDLs, we log this at each command end,
     * however, for certain cases where we directly update the system table
     * without a transaction block, the invalidations are not logged till this
     * time.
     */
    if (XLogLogicalInfoActive())
        LogLogicalInvalidations();
 
    /* Get data needed for commit record */
    nrels = smgrGetPendingDeletes(true, &rels);
    nchildren = xactGetCommittedChildren(&children);
    ndroppedstats = pgstat_get_transactional_drops(true, &droppedstats);
    if (XLogStandbyInfoActive())
        nmsgs = xactGetCommittedInvalidationMessages(&invalMessages,
                                                     &RelcacheInitFileInval);
    wrote_xlog = (XactLastRecEnd != 0);
 
    /*
     * If we haven't been assigned an XID yet, we neither can, nor do we want
     * to write a COMMIT record.
     */
    if (!markXidCommitted)
    {
        /*
         * We expect that every RelationDropStorage is followed by a catalog
         * update, and hence XID assignment, so we shouldn't get here with any
         * pending deletes. Same is true for dropping stats.
         *
         * Use a real test not just an Assert to check this, since it's a bit
         * fragile.
         */
        if (nrels != 0 || ndroppedstats != 0)
            elog(ERROR, "cannot commit a transaction that deleted files but has no xid");
 
        /* Can't have child XIDs either; AssignTransactionId enforces this */
        Assert(nchildren == 0);
 
        /*
         * Transactions without an assigned xid can contain invalidation
         * messages.  While inplace updates do this, this is not known to be
         * necessary; see comment at inplace CacheInvalidateHeapTuple().
         * Extensions might still rely on this capability, and standbys may
         * need to process those invals.  We can't emit a commit record
         * without an xid, and we don't want to force assigning an xid,
         * because that'd be problematic for e.g. vacuum.  Hence we emit a
         * bespoke record for the invalidations. We don't want to use that in
         * case a commit record is emitted, so they happen synchronously with
         * commits (besides not wanting to emit more WAL records).
         *
         * XXX Every known use of this capability is a defect.  Since an XID
         * isn't controlling visibility of the change that prompted invals,
         * other sessions need the inval even if this transactions aborts.
         *
         * ON COMMIT DELETE ROWS does a nontransactional index_build(), which
         * queues a relcache inval, including in transactions without an xid
         * that had read the (empty) table.  Standbys don't need any ON COMMIT
         * DELETE ROWS invals, but we've not done the work to withhold them.
         */
        if (nmsgs != 0)
        {
            LogStandbyInvalidations(nmsgs, invalMessages,
                                    RelcacheInitFileInval);
            wrote_xlog = true;  /* not strictly necessary */
        }
 
        /*
         * If we didn't create XLOG entries, we're done here; otherwise we
         * should trigger flushing those entries the same as a commit record
         * would.  This will primarily happen for HOT pruning and the like; we
         * want these to be flushed to disk in due time.
         */
        if (!wrote_xlog)
            goto cleanup;
    }
    else
    {
        bool        replorigin;
 
        /*
         * Are we using the replication origins feature?  Or, in other words,
         * are we replaying remote actions?
         */
        replorigin = (replorigin_xact_state.origin != InvalidReplOriginId &&
                      replorigin_xact_state.origin != DoNotReplicateId);
 
        /*
         * Mark ourselves as within our "commit critical section".  This
         * forces any concurrent checkpoint to wait until we've updated
         * pg_xact.  Without this, it is possible for the checkpoint to set
         * REDO after the XLOG record but fail to flush the pg_xact update to
         * disk, leading to loss of the transaction commit if the system
         * crashes a little later.
         *
         * Note: we could, but don't bother to, set this flag in
         * RecordTransactionAbort.  That's because loss of a transaction abort
         * is noncritical; the presumption would be that it aborted, anyway.
         *
         * It's safe to change the delayChkptFlags flag of our own backend
         * without holding the ProcArrayLock, since we're the only one
         * modifying it.  This makes checkpoint's determination of which xacts
         * are delaying the checkpoint a bit fuzzy, but it doesn't matter.
         *
         * Note, it is important to get the commit timestamp after marking the
         * transaction in the commit critical section. See
         * RecordTransactionCommitPrepared.
         */
        Assert((MyProc->delayChkptFlags & DELAY_CHKPT_IN_COMMIT) == 0);
        START_CRIT_SECTION();
        MyProc->delayChkptFlags |= DELAY_CHKPT_IN_COMMIT;
 
        Assert(xactStopTimestamp == 0);
 
        /*
         * Ensures the DELAY_CHKPT_IN_COMMIT flag write is globally visible
         * before commit time is written.
         */
        pg_write_barrier();
 
        /*
         * Insert the commit XLOG record.
         */
        XactLogCommitRecord(GetCurrentTransactionStopTimestamp(),
                            nchildren, children, nrels, rels,
                            ndroppedstats, droppedstats,
                            nmsgs, invalMessages,
                            RelcacheInitFileInval,
                            MyXactFlags,
                            InvalidTransactionId, NULL /* plain commit */ );
 
        if (replorigin)
            /* Move LSNs forward for this replication origin */
            replorigin_session_advance(replorigin_xact_state.origin_lsn,
                                       XactLastRecEnd);
 
        /*
         * Record commit timestamp.  The value comes from plain commit
         * timestamp if there's no replication origin; otherwise, the
         * timestamp was already set in replorigin_xact_state.origin_timestamp
         * by replication.
         *
         * We don't need to WAL-log anything here, as the commit record
         * written above already contains the data.
         */
 
        if (!replorigin || replorigin_xact_state.origin_timestamp == 0)
            replorigin_xact_state.origin_timestamp = GetCurrentTransactionStopTimestamp();
 
        TransactionTreeSetCommitTsData(xid, nchildren, children,
                                       replorigin_xact_state.origin_timestamp,
                                       replorigin_xact_state.origin);
    }
 
    /*
     * Check if we want to commit asynchronously.  We can allow the XLOG flush
     * to happen asynchronously if synchronous_commit=off, or if the current
     * transaction has not performed any WAL-logged operation or didn't assign
     * an xid.  The transaction can end up not writing any WAL, even if it has
     * an xid, if it only wrote to temporary and/or unlogged tables.  It can
     * end up having written WAL without an xid if it did HOT pruning.  In
     * case of a crash, the loss of such a transaction will be irrelevant;
     * temp tables will be lost anyway, unlogged tables will be truncated and
     * HOT pruning will be done again later. (Given the foregoing, you might
     * think that it would be unnecessary to emit the XLOG record at all in
     * this case, but we don't currently try to do that.  It would certainly
     * cause problems at least in Hot Standby mode, where the
     * KnownAssignedXids machinery requires tracking every XID assignment.  It
     * might be OK to skip it only when wal_level < replica, but for now we
     * don't.)
     *
     * However, if we're doing cleanup of any non-temp rels or committing any
     * command that wanted to force sync commit, then we must flush XLOG
     * immediately.  (We must not allow asynchronous commit if there are any
     * non-temp tables to be deleted, because we might delete the files before
     * the COMMIT record is flushed to disk.  We do allow asynchronous commit
     * if all to-be-deleted tables are temporary though, since they are lost
     * anyway if we crash.)
     */
    if ((wrote_xlog && markXidCommitted &&
         synchronous_commit > SYNCHRONOUS_COMMIT_OFF) ||
        forceSyncCommit || nrels > 0)
    {
        XLogFlush(XactLastRecEnd);
 
        /*
         * Now we may update the CLOG, if we wrote a COMMIT record above
         */
        if (markXidCommitted)
            TransactionIdCommitTree(xid, nchildren, children);
    }
    else
    {
        /*
         * Asynchronous commit case:
         *
         * This enables possible committed transaction loss in the case of a
         * postmaster crash because WAL buffers are left unwritten. Ideally we
         * could issue the WAL write without the fsync, but some
         * wal_sync_methods do not allow separate write/fsync.
         *
         * Report the latest async commit LSN, so that the WAL writer knows to
         * flush this commit.
         */
        XLogSetAsyncXactLSN(XactLastRecEnd);
 
        /*
         * We must not immediately update the CLOG, since we didn't flush the
         * XLOG. Instead, we store the LSN up to which the XLOG must be
         * flushed before the CLOG may be updated.
         */
        if (markXidCommitted)
            TransactionIdAsyncCommitTree(xid, nchildren, children, XactLastRecEnd);
    }
 
    /*
     * If we entered a commit critical section, leave it now, and let
     * checkpoints proceed.
     */
    if (markXidCommitted)
    {
        MyProc->delayChkptFlags &= ~DELAY_CHKPT_IN_COMMIT;
        END_CRIT_SECTION();
    }
 
    /* Compute latestXid while we have the child XIDs handy */
    latestXid = TransactionIdLatest(xid, nchildren, children);
 
    /*
     * Wait for synchronous replication, if required. Similar to the decision
     * above about using committing asynchronously we only want to wait if
     * this backend assigned an xid and wrote WAL.  No need to wait if an xid
     * was assigned due to temporary/unlogged tables or due to HOT pruning.
     *
     * Note that at this stage we have marked clog, but still show as running
     * in the procarray and continue to hold locks.
     */
    if (wrote_xlog && markXidCommitted)
        SyncRepWaitForLSN(XactLastRecEnd, true);
 
    /* remember end of last commit record */
    XactLastCommitEnd = XactLastRecEnd;
 
    /* Reset XactLastRecEnd until the next transaction writes something */
    XactLastRecEnd = 0;
cleanup:
    /* Clean up local data */
    if (rels)
        pfree(rels);
    if (ndroppedstats)
        pfree(droppedstats);
 
    return latestXid;
}
 
 
/*
 *  AtCCI_LocalCache
 */
static void
AtCCI_LocalCache(void)
{
    /*
     * Make any pending relation map changes visible.  We must do this before
     * processing local sinval messages, so that the map changes will get
     * reflected into the relcache when relcache invals are processed.
     */
    AtCCI_RelationMap();
 
    /*
     * Make catalog changes visible to me for the next command.
     */
    CommandEndInvalidationMessages();
}
 
/*
 *  AtCommit_Memory
 */
static void
AtCommit_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * Return to the memory context that was current before we started the
     * transaction.  (In principle, this could not be any of the contexts we
     * are about to delete.  If it somehow is, assertions in mcxt.c will
     * complain.)
     */
    MemoryContextSwitchTo(s->priorContext);
 
    /*
     * Release all transaction-local memory.  TopTransactionContext survives
     * but becomes empty; any sub-contexts go away.
     */
    Assert(TopTransactionContext != NULL);
    MemoryContextReset(TopTransactionContext);
 
    /*
     * Clear these pointers as a pro-forma matter.  (Notionally, while
     * TopTransactionContext still exists, it's currently not associated with
     * this TransactionState struct.)
     */
    CurTransactionContext = NULL;
    s->curTransactionContext = NULL;
}
 
/* ----------------------------------------------------------------
 *                      CommitSubTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 * AtSubCommit_Memory
 */
static void
AtSubCommit_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(s->parent != NULL);
 
    /* Return to parent transaction level's memory context. */
    CurTransactionContext = s->parent->curTransactionContext;
    MemoryContextSwitchTo(CurTransactionContext);
 
    /*
     * Ordinarily we cannot throw away the child's CurTransactionContext,
     * since the data it contains will be needed at upper commit.  However, if
     * there isn't actually anything in it, we can throw it away.  This avoids
     * a small memory leak in the common case of "trivial" subxacts.
     */
    if (MemoryContextIsEmpty(s->curTransactionContext))
    {
        MemoryContextDelete(s->curTransactionContext);
        s->curTransactionContext = NULL;
    }
}
 
/*
 * AtSubCommit_childXids
 *
 * Pass my own XID and my child XIDs up to my parent as committed children.
 */
static void
AtSubCommit_childXids(void)
{
    TransactionState s = CurrentTransactionState;
    int         new_nChildXids;
 
    Assert(s->parent != NULL);
 
    /*
     * The parent childXids array will need to hold my XID and all my
     * childXids, in addition to the XIDs already there.
     */
    new_nChildXids = s->parent->nChildXids + s->nChildXids + 1;
 
    /* Allocate or enlarge the parent array if necessary */
    if (s->parent->maxChildXids < new_nChildXids)
    {
        int         new_maxChildXids;
        TransactionId *new_childXids;
 
        /*
         * Make it 2x what's needed right now, to avoid having to enlarge it
         * repeatedly. But we can't go above MaxAllocSize.  (The latter limit
         * is what ensures that we don't need to worry about integer overflow
         * here or in the calculation of new_nChildXids.)
         */
        new_maxChildXids = Min(new_nChildXids * 2,
                               (int) (MaxAllocSize / sizeof(TransactionId)));
 
        if (new_maxChildXids < new_nChildXids)
            ereport(ERROR,
                    (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
                     errmsg("maximum number of committed subtransactions (%d) exceeded",
                            (int) (MaxAllocSize / sizeof(TransactionId)))));
 
        /*
         * We keep the child-XID arrays in TopTransactionContext; this avoids
         * setting up child-transaction contexts for what might be just a few
         * bytes of grandchild XIDs.
         */
        if (s->parent->childXids == NULL)
            new_childXids =
                MemoryContextAlloc(TopTransactionContext,
                                   new_maxChildXids * sizeof(TransactionId));
        else
            new_childXids = repalloc(s->parent->childXids,
                                     new_maxChildXids * sizeof(TransactionId));
 
        s->parent->childXids = new_childXids;
        s->parent->maxChildXids = new_maxChildXids;
    }
 
    /*
     * Copy all my XIDs to parent's array.
     *
     * Note: We rely on the fact that the XID of a child always follows that
     * of its parent.  By copying the XID of this subtransaction before the
     * XIDs of its children, we ensure that the array stays ordered. Likewise,
     * all XIDs already in the array belong to subtransactions started and
     * subcommitted before us, so their XIDs must precede ours.
     */
    s->parent->childXids[s->parent->nChildXids] = XidFromFullTransactionId(s->fullTransactionId);
 
    if (s->nChildXids > 0)
        memcpy(&s->parent->childXids[s->parent->nChildXids + 1],
               s->childXids,
               s->nChildXids * sizeof(TransactionId));
 
    s->parent->nChildXids = new_nChildXids;
 
    /* Release child's array to avoid leakage */
    if (s->childXids != NULL)
        pfree(s->childXids);
    /* We must reset these to avoid double-free if fail later in commit */
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
}
 
/* ----------------------------------------------------------------
 *                      AbortTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 *  RecordTransactionAbort
 *
 * Returns latest XID among xact and its children, or InvalidTransactionId
 * if the xact has no XID.  (We compute that here just because it's easier.)
 */
static TransactionId
RecordTransactionAbort(bool isSubXact)
{
    TransactionId xid = GetCurrentTransactionIdIfAny();
    TransactionId latestXid;
    int         nrels;
    RelFileLocator *rels;
    int         ndroppedstats = 0;
    xl_xact_stats_item *droppedstats = NULL;
    int         nchildren;
    TransactionId *children;
    TimestampTz xact_time;
    bool        replorigin;
 
    /*
     * If we haven't been assigned an XID, nobody will care whether we aborted
     * or not.  Hence, we're done in that case.  It does not matter if we have
     * rels to delete (note that this routine is not responsible for actually
     * deleting 'em).  We cannot have any child XIDs, either.
     */
    if (!TransactionIdIsValid(xid))
    {
        /* Reset XactLastRecEnd until the next transaction writes something */
        if (!isSubXact)
            XactLastRecEnd = 0;
        return InvalidTransactionId;
    }
 
    /*
     * We have a valid XID, so we should write an ABORT record for it.
     *
     * We do not flush XLOG to disk here, since the default assumption after a
     * crash would be that we aborted, anyway.  For the same reason, we don't
     * need to worry about interlocking against checkpoint start.
     */
 
    /*
     * Check that we haven't aborted halfway through RecordTransactionCommit.
     */
    if (TransactionIdDidCommit(xid))
        elog(PANIC, "cannot abort transaction %u, it was already committed",
             xid);
 
    /*
     * Are we using the replication origins feature?  Or, in other words, are
     * we replaying remote actions?
     */
    replorigin = (replorigin_xact_state.origin != InvalidReplOriginId &&
                  replorigin_xact_state.origin != DoNotReplicateId);
 
    /* Fetch the data we need for the abort record */
    nrels = smgrGetPendingDeletes(false, &rels);
    nchildren = xactGetCommittedChildren(&children);
    ndroppedstats = pgstat_get_transactional_drops(false, &droppedstats);
 
    /* XXX do we really need a critical section here? */
    START_CRIT_SECTION();
 
    /* Write the ABORT record */
    if (isSubXact)
        xact_time = GetCurrentTimestamp();
    else
    {
        xact_time = GetCurrentTransactionStopTimestamp();
    }
 
    XactLogAbortRecord(xact_time,
                       nchildren, children,
                       nrels, rels,
                       ndroppedstats, droppedstats,
                       MyXactFlags, InvalidTransactionId,
                       NULL);
 
    if (replorigin)
        /* Move LSNs forward for this replication origin */
        replorigin_session_advance(replorigin_xact_state.origin_lsn,
                                   XactLastRecEnd);
 
    /*
     * Report the latest async abort LSN, so that the WAL writer knows to
     * flush this abort. There's nothing to be gained by delaying this, since
     * WALWriter may as well do this when it can. This is important with
     * streaming replication because if we don't flush WAL regularly we will
     * find that large aborts leave us with a long backlog for when commits
     * occur after the abort, increasing our window of data loss should
     * problems occur at that point.
     */
    if (!isSubXact)
        XLogSetAsyncXactLSN(XactLastRecEnd);
 
    /*
     * Mark the transaction aborted in clog.  This is not absolutely necessary
     * but we may as well do it while we are here; also, in the subxact case
     * it is helpful because XactLockTableWait makes use of it to avoid
     * waiting for already-aborted subtransactions.  It is OK to do it without
     * having flushed the ABORT record to disk, because in event of a crash
     * we'd be assumed to have aborted anyway.
     */
    TransactionIdAbortTree(xid, nchildren, children);
 
    END_CRIT_SECTION();
 
    /* Compute latestXid while we have the child XIDs handy */
    latestXid = TransactionIdLatest(xid, nchildren, children);
 
    /*
     * If we're aborting a subtransaction, we can immediately remove failed
     * XIDs from PGPROC's cache of running child XIDs.  We do that here for
     * subxacts, because we already have the child XID array at hand.  For
     * main xacts, the equivalent happens just after this function returns.
     */
    if (isSubXact)
        XidCacheRemoveRunningXids(xid, nchildren, children, latestXid);
 
    /* Reset XactLastRecEnd until the next transaction writes something */
    if (!isSubXact)
        XactLastRecEnd = 0;
 
    /* And clean up local data */
    if (rels)
        pfree(rels);
    if (ndroppedstats)
        pfree(droppedstats);
 
    return latestXid;
}
 
/*
 *  AtAbort_Memory
 */
static void
AtAbort_Memory(void)
{
    /*
     * Switch into TransactionAbortContext, which should have some free space
     * even if nothing else does.  We'll work in this context until we've
     * finished cleaning up.
     *
     * It is barely possible to get here when we've not been able to create
     * TransactionAbortContext yet; if so use TopMemoryContext.
     */
    if (TransactionAbortContext != NULL)
        MemoryContextSwitchTo(TransactionAbortContext);
    else
        MemoryContextSwitchTo(TopMemoryContext);
}
 
/*
 * AtSubAbort_Memory
 */
static void
AtSubAbort_Memory(void)
{
    Assert(TransactionAbortContext != NULL);
 
    MemoryContextSwitchTo(TransactionAbortContext);
}
 
 
/*
 *  AtAbort_ResourceOwner
 */
static void
AtAbort_ResourceOwner(void)
{
    /*
     * Make sure we have a valid ResourceOwner, if possible (else it will be
     * NULL, which is OK)
     */
    CurrentResourceOwner = TopTransactionResourceOwner;
}
 
/*
 * AtSubAbort_ResourceOwner
 */
static void
AtSubAbort_ResourceOwner(void)
{
    TransactionState s = CurrentTransactionState;
 
    /* Make sure we have a valid ResourceOwner */
    CurrentResourceOwner = s->curTransactionOwner;
}
 
 
/*
 * AtSubAbort_childXids
 */
static void
AtSubAbort_childXids(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * We keep the child-XID arrays in TopTransactionContext (see
     * AtSubCommit_childXids).  This means we'd better free the array
     * explicitly at abort to avoid leakage.
     */
    if (s->childXids != NULL)
        pfree(s->childXids);
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
 
    /*
     * We could prune the unreportedXids array here. But we don't bother. That
     * would potentially reduce number of XLOG_XACT_ASSIGNMENT records but it
     * would likely introduce more CPU time into the more common paths, so we
     * choose not to do that.
     */
}
 
/* ----------------------------------------------------------------
 *                      CleanupTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 *  AtCleanup_Memory
 */
static void
AtCleanup_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    /* Should be at top level */
    Assert(s->parent == NULL);
 
    /*
     * Return to the memory context that was current before we started the
     * transaction.  (In principle, this could not be any of the contexts we
     * are about to delete.  If it somehow is, assertions in mcxt.c will
     * complain.)
     */
    MemoryContextSwitchTo(s->priorContext);
 
    /*
     * Clear the special abort context for next time.
     */
    if (TransactionAbortContext != NULL)
        MemoryContextReset(TransactionAbortContext);
 
    /*
     * Release all transaction-local memory, the same as in AtCommit_Memory,
     * except we must cope with the possibility that we didn't get as far as
     * creating TopTransactionContext.
     */
    if (TopTransactionContext != NULL)
        MemoryContextReset(TopTransactionContext);
 
    /*
     * Clear these pointers as a pro-forma matter.  (Notionally, while
     * TopTransactionContext still exists, it's currently not associated with
     * this TransactionState struct.)
     */
    CurTransactionContext = NULL;
    s->curTransactionContext = NULL;
}
 
 
/* ----------------------------------------------------------------
 *                      CleanupSubTransaction stuff
 * ----------------------------------------------------------------
 */
 
/*
 * AtSubCleanup_Memory
 */
static void
AtSubCleanup_Memory(void)
{
    TransactionState s = CurrentTransactionState;
 
    Assert(s->parent != NULL);
 
    /*
     * Return to the memory context that was current before we started the
     * subtransaction.  (In principle, this could not be any of the contexts
     * we are about to delete.  If it somehow is, assertions in mcxt.c will
     * complain.)
     */
    MemoryContextSwitchTo(s->priorContext);
 
    /* Update CurTransactionContext (might not be same as priorContext) */
    CurTransactionContext = s->parent->curTransactionContext;
 
    /*
     * Clear the special abort context for next time.
     */
    if (TransactionAbortContext != NULL)
        MemoryContextReset(TransactionAbortContext);
 
    /*
     * Delete the subxact local memory contexts. Its CurTransactionContext can
     * go too (note this also kills CurTransactionContexts from any children
     * of the subxact).
     */
    if (s->curTransactionContext)
        MemoryContextDelete(s->curTransactionContext);
    s->curTransactionContext = NULL;
}
 
/* ----------------------------------------------------------------
 *                      interface routines
 * ----------------------------------------------------------------
 */
 
/*
 *  StartTransaction
 */
static void
StartTransaction(void)
{
    TransactionState s;
    VirtualTransactionId vxid;
 
    /*
     * Let's just make sure the state stack is empty
     */
    s = &TopTransactionStateData;
    CurrentTransactionState = s;
 
    Assert(!FullTransactionIdIsValid(XactTopFullTransactionId));
 
    /* check the current transaction state */
    Assert(s->state == TRANS_DEFAULT);
 
    /*
     * Set the current transaction state information appropriately during
     * start processing.  Note that once the transaction status is switched
     * this process cannot fail until the user ID and the security context
     * flags are fetched below.
     */
    s->state = TRANS_START;
    s->fullTransactionId = InvalidFullTransactionId;    /* until assigned */
 
    /* Determine if statements are logged in this transaction */
    xact_is_sampled = log_xact_sample_rate != 0 &&
        (log_xact_sample_rate == 1 ||
         pg_prng_double(&pg_global_prng_state) <= log_xact_sample_rate);
 
    /*
     * initialize current transaction state fields
     *
     * note: prevXactReadOnly is not used at the outermost level
     */
    s->nestingLevel = 1;
    s->gucNestLevel = 1;
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
 
    /*
     * Once the current user ID and the security context flags are fetched,
     * both will be properly reset even if transaction startup fails.
     */
    GetUserIdAndSecContext(&s->prevUser, &s->prevSecContext);
 
    /* SecurityRestrictionContext should never be set outside a transaction */
    Assert(s->prevSecContext == 0);
 
    /*
     * Make sure we've reset xact state variables
     *
     * If recovery is still in progress, mark this transaction as read-only.
     * We have lower level defences in XLogInsert and elsewhere to stop us
     * from modifying data during recovery, but this gives the normal
     * indication to the user that the transaction is read-only.
     */
    if (RecoveryInProgress())
    {
        s->startedInRecovery = true;
        XactReadOnly = true;
    }
    else
    {
        s->startedInRecovery = false;
        XactReadOnly = DefaultXactReadOnly;
    }
    XactDeferrable = DefaultXactDeferrable;
    XactIsoLevel = DefaultXactIsoLevel;
    forceSyncCommit = false;
    MyXactFlags = 0;
 
    /*
     * reinitialize within-transaction counters
     */
    s->subTransactionId = TopSubTransactionId;
    currentSubTransactionId = TopSubTransactionId;
    currentCommandId = FirstCommandId;
    currentCommandIdUsed = false;
 
    /*
     * initialize reported xid accounting
     */
    nUnreportedXids = 0;
    s->didLogXid = false;
 
    /*
     * must initialize resource-management stuff first
     */
    AtStart_Memory();
    AtStart_ResourceOwner();
 
    /*
     * Assign a new LocalTransactionId, and combine it with the proc number to
     * form a virtual transaction id.
     */
    vxid.procNumber = MyProcNumber;
    vxid.localTransactionId = GetNextLocalTransactionId();
 
    /*
     * Lock the virtual transaction id before we announce it in the proc array
     */
    VirtualXactLockTableInsert(vxid);
 
    /*
     * Advertise it in the proc array.  We assume assignment of
     * localTransactionId is atomic, and the proc number should be set
     * already.
     */
    Assert(MyProc->vxid.procNumber == vxid.procNumber);
    MyProc->vxid.lxid = vxid.localTransactionId;
 
    TRACE_POSTGRESQL_TRANSACTION_START(vxid.localTransactionId);
 
    /*
     * set transaction_timestamp() (a/k/a now()).  Normally, we want this to
     * be the same as the first command's statement_timestamp(), so don't do a
     * fresh GetCurrentTimestamp() call (which'd be expensive anyway).  But
     * for transactions started inside procedures (i.e., nonatomic SPI
     * contexts), we do need to advance the timestamp.  Also, in a parallel
     * worker, the timestamp should already have been provided by a call to
     * SetParallelStartTimestamps().
     */
    if (!IsParallelWorker())
    {
        if (!SPI_inside_nonatomic_context())
            xactStartTimestamp = stmtStartTimestamp;
        else
            xactStartTimestamp = GetCurrentTimestamp();
    }
    else
        Assert(xactStartTimestamp != 0);
    pgstat_report_xact_timestamp(xactStartTimestamp);
    /* Mark xactStopTimestamp as unset. */
    xactStopTimestamp = 0;
 
    /*
     * initialize other subsystems for new transaction
     */
    AtStart_GUC();
    AtStart_Cache();
    AfterTriggerBeginXact();
 
    /*
     * done with start processing, set current transaction state to "in
     * progress"
     */
    s->state = TRANS_INPROGRESS;
 
    /* Schedule transaction timeout */
    if (TransactionTimeout > 0)
        enable_timeout_after(TRANSACTION_TIMEOUT, TransactionTimeout);
 
    ShowTransactionState("StartTransaction");
}
 
 
/*
 *  CommitTransaction
 *
 * NB: if you change this routine, better look at PrepareTransaction too!
 */
static void
CommitTransaction(void)
{
    TransactionState s = CurrentTransactionState;
    TransactionId latestXid;
    bool        is_parallel_worker;
 
    is_parallel_worker = (s->blockState == TBLOCK_PARALLEL_INPROGRESS);
 
    /* Enforce parallel mode restrictions during parallel worker commit. */
    if (is_parallel_worker)
        EnterParallelMode();
 
    ShowTransactionState("CommitTransaction");
 
    /*
     * check the current transaction state
     */
    if (s->state != TRANS_INPROGRESS)
        elog(WARNING, "CommitTransaction while in %s state",
             TransStateAsString(s->state));
    Assert(s->parent == NULL);
 
    /*
     * Do pre-commit processing that involves calling user-defined code, such
     * as triggers.  SECURITY_RESTRICTED_OPERATION contexts must not queue an
     * action that would run here, because that would bypass the sandbox.
     * Since closing cursors could queue trigger actions, triggers could open
     * cursors, etc, we have to keep looping until there's nothing left to do.
     */
    for (;;)
    {
        /*
         * Fire all currently pending deferred triggers.
         */
        AfterTriggerFireDeferred();
 
        /*
         * Close open portals (converting holdable ones into static portals).
         * If there weren't any, we are done ... otherwise loop back to check
         * if they queued deferred triggers.  Lather, rinse, repeat.
         */
        if (!PreCommit_Portals(false))
            break;
    }
 
    /*
     * The remaining actions cannot call any user-defined code, so it's safe
     * to start shutting down within-transaction services.  But note that most
     * of this stuff could still throw an error, which would switch us into
     * the transaction-abort path.
     */
 
    CallXactCallbacks(is_parallel_worker ? XACT_EVENT_PARALLEL_PRE_COMMIT
                      : XACT_EVENT_PRE_COMMIT);
 
    /*
     * If this xact has started any unfinished parallel operation, clean up
     * its workers, warning about leaked resources.  (But we don't actually
     * reset parallelModeLevel till entering TRANS_COMMIT, a bit below.  This
     * keeps parallel mode restrictions active as long as possible in a
     * parallel worker.)
     */
    AtEOXact_Parallel(true);
    if (is_parallel_worker)
    {
        if (s->parallelModeLevel != 1)
            elog(WARNING, "parallelModeLevel is %d not 1 at end of parallel worker transaction",
                 s->parallelModeLevel);
    }
    else
    {
        if (s->parallelModeLevel != 0)
            elog(WARNING, "parallelModeLevel is %d not 0 at end of transaction",
                 s->parallelModeLevel);
    }
 
    /* Shut down the deferred-trigger manager */
    AfterTriggerEndXact(true);
 
    /*
     * Let ON COMMIT management do its thing (must happen after closing
     * cursors, to avoid dangling-reference problems)
     */
    PreCommit_on_commit_actions();
 
    /*
     * Synchronize files that are created and not WAL-logged during this
     * transaction. This must happen before AtEOXact_RelationMap(), so that we
     * don't see committed-but-broken files after a crash.
     */
    smgrDoPendingSyncs(true, is_parallel_worker);
 
    /* close large objects before lower-level cleanup */
    AtEOXact_LargeObject(true);
 
    /*
     * Insert notifications sent by NOTIFY commands into the queue.  This
     * should be late in the pre-commit sequence to minimize time spent
     * holding the notify-insertion lock.  However, this could result in
     * creating a snapshot, so we must do it before serializable cleanup.
     */
    PreCommit_Notify();
 
    /*
     * Mark serializable transaction as complete for predicate locking
     * purposes.  This should be done as late as we can put it and still allow
     * errors to be raised for failure patterns found at commit.  This is not
     * appropriate in a parallel worker however, because we aren't committing
     * the leader's transaction and its serializable state will live on.
     */
    if (!is_parallel_worker)
        PreCommit_CheckForSerializationFailure();
 
    /* Prevent cancel/die interrupt while cleaning up */
    HOLD_INTERRUPTS();
 
    /* Commit updates to the relation map --- do this as late as possible */
    AtEOXact_RelationMap(true, is_parallel_worker);
 
    /*
     * set the current transaction state information appropriately during
     * commit processing
     */
    s->state = TRANS_COMMIT;
    s->parallelModeLevel = 0;
    s->parallelChildXact = false;   /* should be false already */
 
    /* Disable transaction timeout */
    if (TransactionTimeout > 0)
        disable_timeout(TRANSACTION_TIMEOUT, false);
 
    if (!is_parallel_worker)
    {
        /*
         * We need to mark our XIDs as committed in pg_xact.  This is where we
         * durably commit.
         */
        latestXid = RecordTransactionCommit();
    }
    else
    {
        /*
         * We must not mark our XID committed; the parallel leader is
         * responsible for that.
         */
        latestXid = InvalidTransactionId;
 
        /*
         * Make sure the leader will know about any WAL we wrote before it
         * commits.
         */
        ParallelWorkerReportLastRecEnd(XactLastRecEnd);
    }
 
    TRACE_POSTGRESQL_TRANSACTION_COMMIT(MyProc->vxid.lxid);
 
    /*
     * Let others know about no transaction in progress by me. Note that this
     * must be done _before_ releasing locks we hold and _after_
     * RecordTransactionCommit.
     */
    ProcArrayEndTransaction(MyProc, latestXid);
 
    /*
     * This is all post-commit cleanup.  Note that if an error is raised here,
     * it's too late to abort the transaction.  This should be just
     * noncritical resource releasing.
     *
     * The ordering of operations is not entirely random.  The idea is:
     * release resources visible to other backends (eg, files, buffer pins);
     * then release locks; then release backend-local resources. We want to
     * release locks at the point where any backend waiting for us will see
     * our transaction as being fully cleaned up.
     *
     * Resources that can be associated with individual queries are handled by
     * the ResourceOwner mechanism.  The other calls here are for backend-wide
     * state.
     */
 
    CallXactCallbacks(is_parallel_worker ? XACT_EVENT_PARALLEL_COMMIT
                      : XACT_EVENT_COMMIT);
 
    CurrentResourceOwner = NULL;
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_BEFORE_LOCKS,
                         true, true);
 
    AtEOXact_Aio(true);
 
    /* Check we've released all buffer pins */
    AtEOXact_Buffers(true);
 
    /* Clean up the relation cache */
    AtEOXact_RelationCache(true);
 
    /* Clean up the type cache */
    AtEOXact_TypeCache();
 
    /*
     * Make catalog changes visible to all backends.  This has to happen after
     * relcache references are dropped (see comments for
     * AtEOXact_RelationCache), but before locks are released (if anyone is
     * waiting for lock on a relation we've modified, we want them to know
     * about the catalog change before they start using the relation).
     */
    AtEOXact_Inval(true);
 
    AtEOXact_MultiXact();
 
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_LOCKS,
                         true, true);
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_AFTER_LOCKS,
                         true, true);
 
    /*
     * Likewise, dropping of files deleted during the transaction is best done
     * after releasing relcache and buffer pins.  (This is not strictly
     * necessary during commit, since such pins should have been released
     * already, but this ordering is definitely critical during abort.)  Since
     * this may take many seconds, also delay until after releasing locks.
     * Other backends will observe the attendant catalog changes and not
     * attempt to access affected files.
     */
    smgrDoPendingDeletes(true);
 
    /*
     * Send out notification signals to other backends (and do other
     * post-commit NOTIFY cleanup).  This must not happen until after our
     * transaction is fully done from the viewpoint of other backends.
     */
    AtCommit_Notify();
 
    /*
     * Everything after this should be purely internal-to-this-backend
     * cleanup.
     */
    AtEOXact_GUC(true, 1);
    AtEOXact_SPI(true);
    AtEOXact_Enum();
    AtEOXact_on_commit_actions(true);
    AtEOXact_Namespace(true, is_parallel_worker);
    AtEOXact_SMgr();
    AtEOXact_Files(true);
    AtEOXact_ComboCid();
    AtEOXact_HashTables(true);
    AtEOXact_PgStat(true, is_parallel_worker);
    AtEOXact_Snapshot(true, false);
    AtEOXact_ApplyLauncher(true);
    AtEOXact_LogicalRepWorkers(true);
    AtEOXact_LogicalCtl();
    pgstat_report_xact_timestamp(0);
 
    ResourceOwnerDelete(TopTransactionResourceOwner);
    s->curTransactionOwner = NULL;
    CurTransactionResourceOwner = NULL;
    TopTransactionResourceOwner = NULL;
 
    AtCommit_Memory();
 
    s->fullTransactionId = InvalidFullTransactionId;
    s->subTransactionId = InvalidSubTransactionId;
    s->nestingLevel = 0;
    s->gucNestLevel = 0;
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
 
    XactTopFullTransactionId = InvalidFullTransactionId;
    nParallelCurrentXids = 0;
 
    /*
     * done with commit processing, set current transaction state back to
     * default
     */
    s->state = TRANS_DEFAULT;
 
    RESUME_INTERRUPTS();
}
 
 
/*
 *  PrepareTransaction
 *
 * NB: if you change this routine, better look at CommitTransaction too!
 */
static void
PrepareTransaction(void)
{
    TransactionState s = CurrentTransactionState;
    FullTransactionId fxid = GetCurrentFullTransactionId();
    GlobalTransaction gxact;
    TimestampTz prepared_at;
 
    Assert(!IsInParallelMode());
 
    ShowTransactionState("PrepareTransaction");
 
    /*
     * check the current transaction state
     */
    if (s->state != TRANS_INPROGRESS)
        elog(WARNING, "PrepareTransaction while in %s state",
             TransStateAsString(s->state));
    Assert(s->parent == NULL);
 
    /*
     * Do pre-commit processing that involves calling user-defined code, such
     * as triggers.  Since closing cursors could queue trigger actions,
     * triggers could open cursors, etc, we have to keep looping until there's
     * nothing left to do.
     */
    for (;;)
    {
        /*
         * Fire all currently pending deferred triggers.
         */
        AfterTriggerFireDeferred();
 
        /*
         * Close open portals (converting holdable ones into static portals).
         * If there weren't any, we are done ... otherwise loop back to check
         * if they queued deferred triggers.  Lather, rinse, repeat.
         */
        if (!PreCommit_Portals(true))
            break;
    }
 
    CallXactCallbacks(XACT_EVENT_PRE_PREPARE);
 
    /*
     * The remaining actions cannot call any user-defined code, so it's safe
     * to start shutting down within-transaction services.  But note that most
     * of this stuff could still throw an error, which would switch us into
     * the transaction-abort path.
     */
 
    /* Shut down the deferred-trigger manager */
    AfterTriggerEndXact(true);
 
    /*
     * Let ON COMMIT management do its thing (must happen after closing
     * cursors, to avoid dangling-reference problems)
     */
    PreCommit_on_commit_actions();
 
    /*
     * Synchronize files that are created and not WAL-logged during this
     * transaction. This must happen before EndPrepare(), so that we don't see
     * committed-but-broken files after a crash and COMMIT PREPARED.
     */
    smgrDoPendingSyncs(true, false);
 
    /* close large objects before lower-level cleanup */
    AtEOXact_LargeObject(true);
 
    /* NOTIFY requires no work at this point */
 
    /*
     * Mark serializable transaction as complete for predicate locking
     * purposes.  This should be done as late as we can put it and still allow
     * errors to be raised for failure patterns found at commit.
     */
    PreCommit_CheckForSerializationFailure();
 
    /*
     * Don't allow PREPARE TRANSACTION if we've accessed a temporary table in
     * this transaction.  Having the prepared xact hold locks on another
     * backend's temp table seems a bad idea --- for instance it would prevent
     * the backend from exiting.  There are other problems too, such as how to
     * clean up the source backend's local buffers and ON COMMIT state if the
     * prepared xact includes a DROP of a temp table.
     *
     * Other objects types, like functions, operators or extensions, share the
     * same restriction as they should not be created, locked or dropped as
     * this can mess up with this session or even a follow-up session trying
     * to use the same temporary namespace.
     *
     * We must check this after executing any ON COMMIT actions, because they
     * might still access a temp relation.
     *
     * XXX In principle this could be relaxed to allow some useful special
     * cases, such as a temp table created and dropped all within the
     * transaction.  That seems to require much more bookkeeping though.
     */
    if ((MyXactFlags & XACT_FLAGS_ACCESSEDTEMPNAMESPACE))
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot PREPARE a transaction that has operated on temporary objects")));
 
    /*
     * Likewise, don't allow PREPARE after pg_export_snapshot.  This could be
     * supported if we added cleanup logic to twophase.c, but for now it
     * doesn't seem worth the trouble.
     */
    if (XactHasExportedSnapshots())
        ereport(ERROR,
                (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                 errmsg("cannot PREPARE a transaction that has exported snapshots")));
 
    /* Prevent cancel/die interrupt while cleaning up */
    HOLD_INTERRUPTS();
 
    /*
     * set the current transaction state information appropriately during
     * prepare processing
     */
    s->state = TRANS_PREPARE;
 
    /* Disable transaction timeout */
    if (TransactionTimeout > 0)
        disable_timeout(TRANSACTION_TIMEOUT, false);
 
    prepared_at = GetCurrentTimestamp();
 
    /*
     * Reserve the GID for this transaction. This could fail if the requested
     * GID is invalid or already in use.
     */
    gxact = MarkAsPreparing(fxid, prepareGID, prepared_at,
                            GetUserId(), MyDatabaseId);
    prepareGID = NULL;
 
    /*
     * Collect data for the 2PC state file.  Note that in general, no actual
     * state change should happen in the called modules during this step,
     * since it's still possible to fail before commit, and in that case we
     * want transaction abort to be able to clean up.  (In particular, the
     * AtPrepare routines may error out if they find cases they cannot
     * handle.)  State cleanup should happen in the PostPrepare routines
     * below.  However, some modules can go ahead and clear state here because
     * they wouldn't do anything with it during abort anyway.
     *
     * Note: because the 2PC state file records will be replayed in the same
     * order they are made, the order of these calls has to match the order in
     * which we want things to happen during COMMIT PREPARED or ROLLBACK
     * PREPARED; in particular, pay attention to whether things should happen
     * before or after releasing the transaction's locks.
     */
    StartPrepare(gxact);
 
    AtPrepare_Notify();
    AtPrepare_Locks();
    AtPrepare_PredicateLocks();
    AtPrepare_PgStat();
    AtPrepare_MultiXact();
    AtPrepare_RelationMap();
 
    /*
     * Here is where we really truly prepare.
     *
     * We have to record transaction prepares even if we didn't make any
     * updates, because the transaction manager might get confused if we lose
     * a global transaction.
     */
    EndPrepare(gxact);
 
    /*
     * Now we clean up backend-internal state and release internal resources.
     */
 
    /* Reset XactLastRecEnd until the next transaction writes something */
    XactLastRecEnd = 0;
 
    /*
     * Transfer our locks to a dummy PGPROC.  This has to be done before
     * ProcArrayClearTransaction().  Otherwise, a GetLockConflicts() would
     * conclude "xact already committed or aborted" for our locks.
     */
    PostPrepare_Locks(fxid);
 
    /*
     * Let others know about no transaction in progress by me.  This has to be
     * done *after* the prepared transaction has been marked valid, else
     * someone may think it is unlocked and recyclable.
     */
    ProcArrayClearTransaction(MyProc);
 
    /*
     * In normal commit-processing, this is all non-critical post-transaction
     * cleanup.  When the transaction is prepared, however, it's important
     * that the locks and other per-backend resources are transferred to the
     * prepared transaction's PGPROC entry.  Note that if an error is raised
     * here, it's too late to abort the transaction. XXX: This probably should
     * be in a critical section, to force a PANIC if any of this fails, but
     * that cure could be worse than the disease.
     */
 
    CallXactCallbacks(XACT_EVENT_PREPARE);
 
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_BEFORE_LOCKS,
                         true, true);
 
    AtEOXact_Aio(true);
 
    /* Check we've released all buffer pins */
    AtEOXact_Buffers(true);
 
    /* Clean up the relation cache */
    AtEOXact_RelationCache(true);
 
    /* Clean up the type cache */
    AtEOXact_TypeCache();
 
    /* notify doesn't need a postprepare call */
 
    PostPrepare_PgStat();
 
    PostPrepare_Inval();
 
    PostPrepare_smgr();
 
    PostPrepare_MultiXact(fxid);
 
    PostPrepare_PredicateLocks(fxid);
 
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_LOCKS,
                         true, true);
    ResourceOwnerRelease(TopTransactionResourceOwner,
                         RESOURCE_RELEASE_AFTER_LOCKS,
                         true, true);
 
    /*
     * Allow another backend to finish the transaction.  After
     * PostPrepare_Twophase(), the transaction is completely detached from our
     * backend.  The rest is just non-critical cleanup of backend-local state.
     */
    PostPrepare_Twophase();
 
    /* PREPARE acts the same as COMMIT as far as GUC is concerned */
    AtEOXact_GUC(true, 1);
    AtEOXact_SPI(true);
    AtEOXact_Enum();
    AtEOXact_on_commit_actions(true);
    AtEOXact_Namespace(true, false);
    AtEOXact_SMgr();
    AtEOXact_Files(true);
    AtEOXact_ComboCid();
    AtEOXact_HashTables(true);
    /* don't call AtEOXact_PgStat here; we fixed pgstat state above */
    AtEOXact_Snapshot(true, true);
    /* we treat PREPARE as ROLLBACK so far as waking workers goes */
    AtEOXact_ApplyLauncher(false);
    AtEOXact_LogicalRepWorkers(false);
    AtEOXact_LogicalCtl();
    pgstat_report_xact_timestamp(0);
 
    CurrentResourceOwner = NULL;
    ResourceOwnerDelete(TopTransactionResourceOwner);
    s->curTransactionOwner = NULL;
    CurTransactionResourceOwner = NULL;
    TopTransactionResourceOwner = NULL;
 
    AtCommit_Memory();
 
    s->fullTransactionId = InvalidFullTransactionId;
    s->subTransactionId = InvalidSubTransactionId;
    s->nestingLevel = 0;
    s->gucNestLevel = 0;
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
 
    XactTopFullTransactionId = InvalidFullTransactionId;
    nParallelCurrentXids = 0;
 
    /*
     * done with 1st phase commit processing, set current transaction state
     * back to default
     */
    s->state = TRANS_DEFAULT;
 
    RESUME_INTERRUPTS();
}
 
 
/*
 *  AbortTransaction
 */
static void
AbortTransaction(void)
{
    TransactionState s = CurrentTransactionState;
    TransactionId latestXid;
    bool        is_parallel_worker;
 
    /* Prevent cancel/die interrupt while cleaning up */
    HOLD_INTERRUPTS();
 
    /* Disable transaction timeout */
    if (TransactionTimeout > 0)
        disable_timeout(TRANSACTION_TIMEOUT, false);
 
    /* Make sure we have a valid memory context and resource owner */
    AtAbort_Memory();
    AtAbort_ResourceOwner();
 
    /*
     * Release any LW locks we might be holding as quickly as possible.
     * (Regular locks, however, must be held till we finish aborting.)
     * Releasing LW locks is critical since we might try to grab them again
     * while cleaning up!
     */
    LWLockReleaseAll();
 
    /*
     * Cleanup waiting for LSN if any.
     */
    WaitLSNCleanup();
 
    /* Clear wait information and command progress indicator */
    pgstat_report_wait_end();
    pgstat_progress_end_command();
 
    pgaio_error_cleanup();
 
    /* Clean up buffer content locks, too */
    UnlockBuffers();
 
    /* Reset WAL record construction state */
    XLogResetInsertion();
 
    /* Cancel condition variable sleep */
    ConditionVariableCancelSleep();
 
    /*
     * Also clean up any open wait for lock, since the lock manager will choke
     * if we try to wait for another lock before doing this.
     */
    LockErrorCleanup();
 
    /*
     * If any timeout events are still active, make sure the timeout interrupt
     * is scheduled.  This covers possible loss of a timeout interrupt due to
     * longjmp'ing out of the SIGINT handler (see notes in handle_sig_alarm).
     * We delay this till after LockErrorCleanup so that we don't uselessly
     * reschedule lock or deadlock check timeouts.
     */
    reschedule_timeouts();
 
    /*
     * Re-enable signals, in case we got here by longjmp'ing out of a signal
     * handler.  We do this fairly early in the sequence so that the timeout
     * infrastructure will be functional if needed while aborting.
     */
    sigprocmask(SIG_SETMASK, &UnBlockSig, NULL);
 
    /*
     * check the current transaction state
     */
    is_parallel_worker = (s->blockState == TBLOCK_PARALLEL_INPROGRESS);
    if (s->state != TRANS_INPROGRESS && s->state != TRANS_PREPARE)
        elog(WARNING, "AbortTransaction while in %s state",
             TransStateAsString(s->state));
    Assert(s->parent == NULL);
 
    /*
     * set the current transaction state information appropriately during the
     * abort processing
     */
    s->state = TRANS_ABORT;
 
    /*
     * Reset user ID which might have been changed transiently.  We need this
     * to clean up in case control escaped out of a SECURITY DEFINER function
     * or other local change of CurrentUserId; therefore, the prior value of
     * SecurityRestrictionContext also needs to be restored.
     *
     * (Note: it is not necessary to restore session authorization or role
     * settings here because those can only be changed via GUC, and GUC will
     * take care of rolling them back if need be.)
     */
    SetUserIdAndSecContext(s->prevUser, s->prevSecContext);
 
    /* Forget about any active REINDEX. */
    ResetReindexState(s->nestingLevel);
 
    /* Reset logical streaming state. */
    ResetLogicalStreamingState();
 
    /* Reset snapshot export state. */
    SnapBuildResetExportedSnapshotState();
 
    /*
     * If this xact has started any unfinished parallel operation, clean up
     * its workers and exit parallel mode.  Don't warn about leaked resources.
     */
    AtEOXact_Parallel(false);
    s->parallelModeLevel = 0;
    s->parallelChildXact = false;   /* should be false already */
 
    /*
     * do abort processing
     */
    AfterTriggerEndXact(false); /* 'false' means it's abort */
    AtAbort_Portals();
    smgrDoPendingSyncs(false, is_parallel_worker);
    AtEOXact_LargeObject(false);
    AtAbort_Notify();
    AtEOXact_RelationMap(false, is_parallel_worker);
    AtAbort_Twophase();
 
    /*
     * Advertise the fact that we aborted in pg_xact (assuming that we got as
     * far as assigning an XID to advertise).  But if we're inside a parallel
     * worker, skip this; the user backend must be the one to write the abort
     * record.
     */
    if (!is_parallel_worker)
        latestXid = RecordTransactionAbort(false);
    else
    {
        latestXid = InvalidTransactionId;
 
        /*
         * Since the parallel leader won't get our value of XactLastRecEnd in
         * this case, we nudge WAL-writer ourselves in this case.  See related
         * comments in RecordTransactionAbort for why this matters.
         */
        XLogSetAsyncXactLSN(XactLastRecEnd);
    }
 
    TRACE_POSTGRESQL_TRANSACTION_ABORT(MyProc->vxid.lxid);
 
    /*
     * Let others know about no transaction in progress by me. Note that this
     * must be done _before_ releasing locks we hold and _after_
     * RecordTransactionAbort.
     */
    ProcArrayEndTransaction(MyProc, latestXid);
 
    /*
     * Post-abort cleanup.  See notes in CommitTransaction() concerning
     * ordering.  We can skip all of it if the transaction failed before
     * creating a resource owner.
     */
    if (TopTransactionResourceOwner != NULL)
    {
        if (is_parallel_worker)
            CallXactCallbacks(XACT_EVENT_PARALLEL_ABORT);
        else
            CallXactCallbacks(XACT_EVENT_ABORT);
 
        ResourceOwnerRelease(TopTransactionResourceOwner,
                             RESOURCE_RELEASE_BEFORE_LOCKS,
                             false, true);
        AtEOXact_Aio(false);
        AtEOXact_Buffers(false);
        AtEOXact_RelationCache(false);
        AtEOXact_TypeCache();
        AtEOXact_Inval(false);
        AtEOXact_MultiXact();
        ResourceOwnerRelease(TopTransactionResourceOwner,
                             RESOURCE_RELEASE_LOCKS,
                             false, true);
        ResourceOwnerRelease(TopTransactionResourceOwner,
                             RESOURCE_RELEASE_AFTER_LOCKS,
                             false, true);
        smgrDoPendingDeletes(false);
 
        AtEOXact_GUC(false, 1);
        AtEOXact_SPI(false);
        AtEOXact_Enum();
        AtEOXact_on_commit_actions(false);
        AtEOXact_Namespace(false, is_parallel_worker);
        AtEOXact_SMgr();
        AtEOXact_Files(false);
        AtEOXact_ComboCid();
        AtEOXact_HashTables(false);
        AtEOXact_PgStat(false, is_parallel_worker);
        AtEOXact_ApplyLauncher(false);
        AtEOXact_LogicalRepWorkers(false);
        AtEOXact_LogicalCtl();
        pgstat_report_xact_timestamp(0);
    }
 
    /*
     * State remains TRANS_ABORT until CleanupTransaction().
     */
    RESUME_INTERRUPTS();
}
 
/*
 *  CleanupTransaction
 */
static void
CleanupTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * State should still be TRANS_ABORT from AbortTransaction().
     */
    if (s->state != TRANS_ABORT)
        elog(FATAL, "CleanupTransaction: unexpected state %s",
             TransStateAsString(s->state));
 
    /*
     * do abort cleanup processing
     */
    AtCleanup_Portals();        /* now safe to release portal memory */
    AtEOXact_Snapshot(false, true); /* and release the transaction's snapshots */
 
    CurrentResourceOwner = NULL;    /* and resource owner */
    if (TopTransactionResourceOwner)
        ResourceOwnerDelete(TopTransactionResourceOwner);
    s->curTransactionOwner = NULL;
    CurTransactionResourceOwner = NULL;
    TopTransactionResourceOwner = NULL;
 
    AtCleanup_Memory();         /* and transaction memory */
 
    s->fullTransactionId = InvalidFullTransactionId;
    s->subTransactionId = InvalidSubTransactionId;
    s->nestingLevel = 0;
    s->gucNestLevel = 0;
    s->childXids = NULL;
    s->nChildXids = 0;
    s->maxChildXids = 0;
    s->parallelModeLevel = 0;
    s->parallelChildXact = false;
 
    XactTopFullTransactionId = InvalidFullTransactionId;
    nParallelCurrentXids = 0;
 
    /*
     * done with abort processing, set current transaction state back to
     * default
     */
    s->state = TRANS_DEFAULT;
}
 
/*
 *  StartTransactionCommand
 */
void
StartTransactionCommand(void)
{
    TransactionState s = CurrentTransactionState;
 
    switch (s->blockState)
    {
            /*
             * if we aren't in a transaction block, we just do our usual start
             * transaction.
             */
        case TBLOCK_DEFAULT:
            StartTransaction();
            s->blockState = TBLOCK_STARTED;
            break;
 
            /*
             * We are somewhere in a transaction block or subtransaction and
             * about to start a new command.  For now we do nothing, but
             * someday we may do command-local resource initialization. (Note
             * that any needed CommandCounterIncrement was done by the
             * previous CommitTransactionCommand.)
             */
        case TBLOCK_INPROGRESS:
        case TBLOCK_IMPLICIT_INPROGRESS:
        case TBLOCK_SUBINPROGRESS:
            break;
 
            /*
             * Here we are in a failed transaction block (one of the commands
             * caused an abort) so we do nothing but remain in the abort
             * state.  Eventually we will get a ROLLBACK command which will
             * get us out of this state.  (It is up to other code to ensure
             * that no commands other than ROLLBACK will be processed in these
             * states.)
             */
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
            break;
 
            /* These cases are invalid. */
        case TBLOCK_STARTED:
        case TBLOCK_BEGIN:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(ERROR, "StartTransactionCommand: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    /*
     * We must switch to CurTransactionContext before returning. This is
     * already done if we called StartTransaction, otherwise not.
     */
    Assert(CurTransactionContext != NULL);
    MemoryContextSwitchTo(CurTransactionContext);
}
 
 
/*
 * Simple system for saving and restoring transaction characteristics
 * (isolation level, read only, deferrable).  We need this for transaction
 * chaining, so that we can set the characteristics of the new transaction to
 * be the same as the previous one.  (We need something like this because the
 * GUC system resets the characteristics at transaction end, so for example
 * just skipping the reset in StartTransaction() won't work.)
 */
void
SaveTransactionCharacteristics(SavedTransactionCharacteristics *s)
{
    s->save_XactIsoLevel = XactIsoLevel;
    s->save_XactReadOnly = XactReadOnly;
    s->save_XactDeferrable = XactDeferrable;
}
 
void
RestoreTransactionCharacteristics(const SavedTransactionCharacteristics *s)
{
    XactIsoLevel = s->save_XactIsoLevel;
    XactReadOnly = s->save_XactReadOnly;
    XactDeferrable = s->save_XactDeferrable;
}
 
/*
 *  CommitTransactionCommand -- a wrapper function handling the
 *      loop over subtransactions to avoid a potentially dangerous recursion
 *      in CommitTransactionCommandInternal().
 */
void
CommitTransactionCommand(void)
{
    /*
     * Repeatedly call CommitTransactionCommandInternal() until all the work
     * is done.
     */
    while (!CommitTransactionCommandInternal())
    {
    }
}
 
/*
 *  CommitTransactionCommandInternal - a function doing an iteration of work
 *      regarding handling the commit transaction command.  In the case of
 *      subtransactions more than one iterations could be required.  Returns
 *      true when no more iterations required, false otherwise.
 */
static bool
CommitTransactionCommandInternal(void)
{
    TransactionState s = CurrentTransactionState;
    SavedTransactionCharacteristics savetc;
 
    /* Must save in case we need to restore below */
    SaveTransactionCharacteristics(&savetc);
 
    switch (s->blockState)
    {
            /*
             * These shouldn't happen.  TBLOCK_DEFAULT means the previous
             * StartTransactionCommand didn't set the STARTED state
             * appropriately, while TBLOCK_PARALLEL_INPROGRESS should be ended
             * by EndParallelWorkerTransaction(), not this function.
             */
        case TBLOCK_DEFAULT:
        case TBLOCK_PARALLEL_INPROGRESS:
            elog(FATAL, "CommitTransactionCommand: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
 
            /*
             * If we aren't in a transaction block, just do our usual
             * transaction commit, and return to the idle state.
             */
        case TBLOCK_STARTED:
            CommitTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * We are completing a "BEGIN TRANSACTION" command, so we change
             * to the "transaction block in progress" state and return.  (We
             * assume the BEGIN did nothing to the database, so we need no
             * CommandCounterIncrement.)
             */
        case TBLOCK_BEGIN:
            s->blockState = TBLOCK_INPROGRESS;
            break;
 
            /*
             * This is the case when we have finished executing a command
             * someplace within a transaction block.  We increment the command
             * counter and return.
             */
        case TBLOCK_INPROGRESS:
        case TBLOCK_IMPLICIT_INPROGRESS:
        case TBLOCK_SUBINPROGRESS:
            CommandCounterIncrement();
            break;
 
            /*
             * We are completing a "COMMIT" command.  Do it and return to the
             * idle state.
             */
        case TBLOCK_END:
            CommitTransaction();
            s->blockState = TBLOCK_DEFAULT;
            if (s->chain)
            {
                StartTransaction();
                s->blockState = TBLOCK_INPROGRESS;
                s->chain = false;
                RestoreTransactionCharacteristics(&savetc);
            }
            break;
 
            /*
             * Here we are in the middle of a transaction block but one of the
             * commands caused an abort so we do nothing but remain in the
             * abort state.  Eventually we will get a ROLLBACK command.
             */
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
            break;
 
            /*
             * Here we were in an aborted transaction block and we just got
             * the ROLLBACK command from the user, so clean up the
             * already-aborted transaction and return to the idle state.
             */
        case TBLOCK_ABORT_END:
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            if (s->chain)
            {
                StartTransaction();
                s->blockState = TBLOCK_INPROGRESS;
                s->chain = false;
                RestoreTransactionCharacteristics(&savetc);
            }
            break;
 
            /*
             * Here we were in a perfectly good transaction block but the user
             * told us to ROLLBACK anyway.  We have to abort the transaction
             * and then clean up.
             */
        case TBLOCK_ABORT_PENDING:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            if (s->chain)
            {
                StartTransaction();
                s->blockState = TBLOCK_INPROGRESS;
                s->chain = false;
                RestoreTransactionCharacteristics(&savetc);
            }
            break;
 
            /*
             * We are completing a "PREPARE TRANSACTION" command.  Do it and
             * return to the idle state.
             */
        case TBLOCK_PREPARE:
            PrepareTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * The user issued a SAVEPOINT inside a transaction block. Start a
             * subtransaction.  (DefineSavepoint already did PushTransaction,
             * so as to have someplace to put the SUBBEGIN state.)
             */
        case TBLOCK_SUBBEGIN:
            StartSubTransaction();
            s->blockState = TBLOCK_SUBINPROGRESS;
            break;
 
            /*
             * The user issued a RELEASE command, so we end the current
             * subtransaction and return to the parent transaction. The parent
             * might be ended too, so repeat till we find an INPROGRESS
             * transaction or subtransaction.
             */
        case TBLOCK_SUBRELEASE:
            do
            {
                CommitSubTransaction();
                s = CurrentTransactionState;    /* changed by pop */
            } while (s->blockState == TBLOCK_SUBRELEASE);
 
            Assert(s->blockState == TBLOCK_INPROGRESS ||
                   s->blockState == TBLOCK_SUBINPROGRESS);
            break;
 
            /*
             * The user issued a COMMIT, so we end the current subtransaction
             * hierarchy and perform final commit. We do this by rolling up
             * any subtransactions into their parent, which leads to O(N^2)
             * operations with respect to resource owners - this isn't that
             * bad until we approach a thousands of savepoints but is
             * necessary for correctness should after triggers create new
             * resource owners.
             */
        case TBLOCK_SUBCOMMIT:
            do
            {
                CommitSubTransaction();
                s = CurrentTransactionState;    /* changed by pop */
            } while (s->blockState == TBLOCK_SUBCOMMIT);
            /* If we had a COMMIT command, finish off the main xact too */
            if (s->blockState == TBLOCK_END)
            {
                Assert(s->parent == NULL);
                CommitTransaction();
                s->blockState = TBLOCK_DEFAULT;
                if (s->chain)
                {
                    StartTransaction();
                    s->blockState = TBLOCK_INPROGRESS;
                    s->chain = false;
                    RestoreTransactionCharacteristics(&savetc);
                }
            }
            else if (s->blockState == TBLOCK_PREPARE)
            {
                Assert(s->parent == NULL);
                PrepareTransaction();
                s->blockState = TBLOCK_DEFAULT;
            }
            else
                elog(ERROR, "CommitTransactionCommand: unexpected state %s",
                     BlockStateAsString(s->blockState));
            break;
 
            /*
             * The current already-failed subtransaction is ending due to a
             * ROLLBACK or ROLLBACK TO command, so pop it and recursively
             * examine the parent (which could be in any of several states).
             * As we need to examine the parent, return false to request the
             * caller to do the next iteration.
             */
        case TBLOCK_SUBABORT_END:
            CleanupSubTransaction();
            return false;
 
            /*
             * As above, but it's not dead yet, so abort first.
             */
        case TBLOCK_SUBABORT_PENDING:
            AbortSubTransaction();
            CleanupSubTransaction();
            return false;
 
            /*
             * The current subtransaction is the target of a ROLLBACK TO
             * command.  Abort and pop it, then start a new subtransaction
             * with the same name.
             */
        case TBLOCK_SUBRESTART:
            {
                char       *name;
                int         savepointLevel;
 
                /* save name and keep Cleanup from freeing it */
                name = s->name;
                s->name = NULL;
                savepointLevel = s->savepointLevel;
 
                AbortSubTransaction();
                CleanupSubTransaction();
 
                DefineSavepoint(NULL);
                s = CurrentTransactionState;    /* changed by push */
                s->name = name;
                s->savepointLevel = savepointLevel;
 
                /* This is the same as TBLOCK_SUBBEGIN case */
                Assert(s->blockState == TBLOCK_SUBBEGIN);
                StartSubTransaction();
                s->blockState = TBLOCK_SUBINPROGRESS;
            }
            break;
 
            /*
             * Same as above, but the subtransaction had already failed, so we
             * don't need AbortSubTransaction.
             */
        case TBLOCK_SUBABORT_RESTART:
            {
                char       *name;
                int         savepointLevel;
 
                /* save name and keep Cleanup from freeing it */
                name = s->name;
                s->name = NULL;
                savepointLevel = s->savepointLevel;
 
                CleanupSubTransaction();
 
                DefineSavepoint(NULL);
                s = CurrentTransactionState;    /* changed by push */
                s->name = name;
                s->savepointLevel = savepointLevel;
 
                /* This is the same as TBLOCK_SUBBEGIN case */
                Assert(s->blockState == TBLOCK_SUBBEGIN);
                StartSubTransaction();
                s->blockState = TBLOCK_SUBINPROGRESS;
            }
            break;
    }
 
    /* Done, no more iterations required */
    return true;
}
 
/*
 *  AbortCurrentTransaction -- a wrapper function handling the
 *      loop over subtransactions to avoid potentially dangerous recursion in
 *      AbortCurrentTransactionInternal().
 */
void
AbortCurrentTransaction(void)
{
    /*
     * Repeatedly call AbortCurrentTransactionInternal() until all the work is
     * done.
     */
    while (!AbortCurrentTransactionInternal())
    {
    }
}
 
/*
 *  AbortCurrentTransactionInternal - a function doing an iteration of work
 *      regarding handling the current transaction abort.  In the case of
 *      subtransactions more than one iterations could be required.  Returns
 *      true when no more iterations required, false otherwise.
 */
static bool
AbortCurrentTransactionInternal(void)
{
    TransactionState s = CurrentTransactionState;
 
    switch (s->blockState)
    {
        case TBLOCK_DEFAULT:
            if (s->state == TRANS_DEFAULT)
            {
                /* we are idle, so nothing to do */
            }
            else
            {
                /*
                 * We can get here after an error during transaction start
                 * (state will be TRANS_START).  Need to clean up the
                 * incompletely started transaction.  First, adjust the
                 * low-level state to suppress warning message from
                 * AbortTransaction.
                 */
                if (s->state == TRANS_START)
                    s->state = TRANS_INPROGRESS;
                AbortTransaction();
                CleanupTransaction();
            }
            break;
 
            /*
             * If we aren't in a transaction block, we just do the basic abort
             * & cleanup transaction.  For this purpose, we treat an implicit
             * transaction block as if it were a simple statement.
             */
        case TBLOCK_STARTED:
        case TBLOCK_IMPLICIT_INPROGRESS:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * If we are in TBLOCK_BEGIN it means something screwed up right
             * after reading "BEGIN TRANSACTION".  We assume that the user
             * will interpret the error as meaning the BEGIN failed to get him
             * into a transaction block, so we should abort and return to idle
             * state.
             */
        case TBLOCK_BEGIN:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * We are somewhere in a transaction block and we've gotten a
             * failure, so we abort the transaction and set up the persistent
             * ABORT state.  We will stay in ABORT until we get a ROLLBACK.
             */
        case TBLOCK_INPROGRESS:
        case TBLOCK_PARALLEL_INPROGRESS:
            AbortTransaction();
            s->blockState = TBLOCK_ABORT;
            /* CleanupTransaction happens when we exit TBLOCK_ABORT_END */
            break;
 
            /*
             * Here, we failed while trying to COMMIT.  Clean up the
             * transaction and return to idle state (we do not want to stay in
             * the transaction).
             */
        case TBLOCK_END:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * Here, we are already in an aborted transaction state and are
             * waiting for a ROLLBACK, but for some reason we failed again! So
             * we just remain in the abort state.
             */
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
            break;
 
            /*
             * We are in a failed transaction and we got the ROLLBACK command.
             * We have already aborted, we just need to cleanup and go to idle
             * state.
             */
        case TBLOCK_ABORT_END:
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * We are in a live transaction and we got a ROLLBACK command.
             * Abort, cleanup, go to idle state.
             */
        case TBLOCK_ABORT_PENDING:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * Here, we failed while trying to PREPARE.  Clean up the
             * transaction and return to idle state (we do not want to stay in
             * the transaction).
             */
        case TBLOCK_PREPARE:
            AbortTransaction();
            CleanupTransaction();
            s->blockState = TBLOCK_DEFAULT;
            break;
 
            /*
             * We got an error inside a subtransaction.  Abort just the
             * subtransaction, and go to the persistent SUBABORT state until
             * we get ROLLBACK.
             */
        case TBLOCK_SUBINPROGRESS:
            AbortSubTransaction();
            s->blockState = TBLOCK_SUBABORT;
            break;
 
            /*
             * If we failed while trying to create a subtransaction, clean up
             * the broken subtransaction and abort the parent.  The same
             * applies if we get a failure while ending a subtransaction.  As
             * we need to abort the parent, return false to request the caller
             * to do the next iteration.
             */
        case TBLOCK_SUBBEGIN:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
            AbortSubTransaction();
            CleanupSubTransaction();
            return false;
 
            /*
             * Same as above, except the Abort() was already done.
             */
        case TBLOCK_SUBABORT_END:
        case TBLOCK_SUBABORT_RESTART:
            CleanupSubTransaction();
            return false;
    }
 
    /* Done, no more iterations required */
    return true;
}
 
/*
 *  PreventInTransactionBlock
 *
 *  This routine is to be called by statements that must not run inside
 *  a transaction block, typically because they have non-rollback-able
 *  side effects or do internal commits.
 *
 *  If this routine completes successfully, then the calling statement is
 *  guaranteed that if it completes without error, its results will be
 *  committed immediately.
 *
 *  If we have already started a transaction block, issue an error; also issue
 *  an error if we appear to be running inside a user-defined function (which
 *  could issue more commands and possibly cause a failure after the statement
 *  completes).  Subtransactions are verboten too.
 *
 *  We must also set XACT_FLAGS_NEEDIMMEDIATECOMMIT in MyXactFlags, to ensure
 *  that postgres.c follows through by committing after the statement is done.
 *
 *  isTopLevel: passed down from ProcessUtility to determine whether we are
 *  inside a function.  (We will always fail if this is false, but it's
 *  convenient to centralize the check here instead of making callers do it.)
 *  stmtType: statement type name, for error messages.
 */
void
PreventInTransactionBlock(bool isTopLevel, const char *stmtType)
{
    /*
     * xact block already started?
     */
    if (IsTransactionBlock())
        ereport(ERROR,
                (errcode(ERRCODE_ACTIVE_SQL_TRANSACTION),
        /* translator: %s represents an SQL statement name */
                 errmsg("%s cannot run inside a transaction block",
                        stmtType)));
 
    /*
     * subtransaction?
     */
    if (IsSubTransaction())
        ereport(ERROR,
                (errcode(ERRCODE_ACTIVE_SQL_TRANSACTION),
        /* translator: %s represents an SQL statement name */
                 errmsg("%s cannot run inside a subtransaction",
                        stmtType)));
 
    /*
     * inside a function call?
     */
    if (!isTopLevel)
        ereport(ERROR,
                (errcode(ERRCODE_ACTIVE_SQL_TRANSACTION),
        /* translator: %s represents an SQL statement name */
                 errmsg("%s cannot be executed from a function or procedure",
                        stmtType)));
 
    /* If we got past IsTransactionBlock test, should be in default state */
    if (CurrentTransactionState->blockState != TBLOCK_DEFAULT &&
        CurrentTransactionState->blockState != TBLOCK_STARTED)
        elog(FATAL, "cannot prevent transaction chain");
 
    /* All okay.  Set the flag to make sure the right thing happens later. */
    MyXactFlags |= XACT_FLAGS_NEEDIMMEDIATECOMMIT;
}
 
/*
 *  WarnNoTransactionBlock
 *  RequireTransactionBlock
 *
 *  These two functions allow for warnings or errors if a command is executed
 *  outside of a transaction block.  This is useful for commands that have no
 *  effects that persist past transaction end (and so calling them outside a
 *  transaction block is presumably an error).  DECLARE CURSOR is an example.
 *  While top-level transaction control commands (BEGIN/COMMIT/ABORT) and SET
 *  that have no effect issue warnings, all other no-effect commands generate
 *  errors.
 *
 *  If we appear to be running inside a user-defined function, we do not
 *  issue anything, since the function could issue more commands that make
 *  use of the current statement's results.  Likewise subtransactions.
 *  Thus these are inverses for PreventInTransactionBlock.
 *
 *  isTopLevel: passed down from ProcessUtility to determine whether we are
 *  inside a function.
 *  stmtType: statement type name, for warning or error messages.
 */
void
WarnNoTransactionBlock(bool isTopLevel, const char *stmtType)
{
    CheckTransactionBlock(isTopLevel, false, stmtType);
}
 
void
RequireTransactionBlock(bool isTopLevel, const char *stmtType)
{
    CheckTransactionBlock(isTopLevel, true, stmtType);
}
 
/*
 * This is the implementation of the above two.
 */
static void
CheckTransactionBlock(bool isTopLevel, bool throwError, const char *stmtType)
{
    /*
     * xact block already started?
     */
    if (IsTransactionBlock())
        return;
 
    /*
     * subtransaction?
     */
    if (IsSubTransaction())
        return;
 
    /*
     * inside a function call?
     */
    if (!isTopLevel)
        return;
 
    ereport(throwError ? ERROR : WARNING,
            (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
    /* translator: %s represents an SQL statement name */
             errmsg("%s can only be used in transaction blocks",
                    stmtType)));
}
 
/*
 *  IsInTransactionBlock
 *
 *  This routine is for statements that need to behave differently inside
 *  a transaction block than when running as single commands.  ANALYZE is
 *  currently the only example.
 *
 *  If this routine returns "false", then the calling statement is allowed
 *  to perform internal transaction-commit-and-start cycles; there is not a
 *  risk of messing up any transaction already in progress.  (Note that this
 *  is not the identical guarantee provided by PreventInTransactionBlock,
 *  since we will not force a post-statement commit.)
 *
 *  isTopLevel: passed down from ProcessUtility to determine whether we are
 *  inside a function.
 */
bool
IsInTransactionBlock(bool isTopLevel)
{
    /*
     * Return true on same conditions that would make
     * PreventInTransactionBlock error out
     */
    if (IsTransactionBlock())
        return true;
 
    if (IsSubTransaction())
        return true;
 
    if (!isTopLevel)
        return true;
 
    if (CurrentTransactionState->blockState != TBLOCK_DEFAULT &&
        CurrentTransactionState->blockState != TBLOCK_STARTED)
        return true;
 
    return false;
}
 
 
/*
 * Register or deregister callback functions for start- and end-of-xact
 * operations.
 *
 * These functions are intended for use by dynamically loaded modules.
 * For built-in modules we generally just hardwire the appropriate calls
 * (mainly because it's easier to control the order that way, where needed).
 *
 * At transaction end, the callback occurs post-commit or post-abort, so the
 * callback functions can only do noncritical cleanup.
 */
void
RegisterXactCallback(XactCallback callback, void *arg)
{
    XactCallbackItem *item;
 
    item = (XactCallbackItem *)
        MemoryContextAlloc(TopMemoryContext, sizeof(XactCallbackItem));
    item->callback = callback;
    item->arg = arg;
    item->next = Xact_callbacks;
    Xact_callbacks = item;
}
 
void
UnregisterXactCallback(XactCallback callback, void *arg)
{
    XactCallbackItem *item;
    XactCallbackItem *prev;
 
    prev = NULL;
    for (item = Xact_callbacks; item; prev = item, item = item->next)
    {
        if (item->callback == callback && item->arg == arg)
        {
            if (prev)
                prev->next = item->next;
            else
                Xact_callbacks = item->next;
            pfree(item);
            break;
        }
    }
}
 
static void
CallXactCallbacks(XactEvent event)
{
    XactCallbackItem *item;
    XactCallbackItem *next;
 
    for (item = Xact_callbacks; item; item = next)
    {
        /* allow callbacks to unregister themselves when called */
        next = item->next;
        item->callback(event, item->arg);
    }
}
 
 
/*
 * Register or deregister callback functions for start- and end-of-subxact
 * operations.
 *
 * Pretty much same as above, but for subtransaction events.
 *
 * At subtransaction end, the callback occurs post-subcommit or post-subabort,
 * so the callback functions can only do noncritical cleanup.  At
 * subtransaction start, the callback is called when the subtransaction has
 * finished initializing.
 */
void
RegisterSubXactCallback(SubXactCallback callback, void *arg)
{
    SubXactCallbackItem *item;
 
    item = (SubXactCallbackItem *)
        MemoryContextAlloc(TopMemoryContext, sizeof(SubXactCallbackItem));
    item->callback = callback;
    item->arg = arg;
    item->next = SubXact_callbacks;
    SubXact_callbacks = item;
}
 
void
UnregisterSubXactCallback(SubXactCallback callback, void *arg)
{
    SubXactCallbackItem *item;
    SubXactCallbackItem *prev;
 
    prev = NULL;
    for (item = SubXact_callbacks; item; prev = item, item = item->next)
    {
        if (item->callback == callback && item->arg == arg)
        {
            if (prev)
                prev->next = item->next;
            else
                SubXact_callbacks = item->next;
            pfree(item);
            break;
        }
    }
}
 
static void
CallSubXactCallbacks(SubXactEvent event,
                     SubTransactionId mySubid,
                     SubTransactionId parentSubid)
{
    SubXactCallbackItem *item;
    SubXactCallbackItem *next;
 
    for (item = SubXact_callbacks; item; item = next)
    {
        /* allow callbacks to unregister themselves when called */
        next = item->next;
        item->callback(event, mySubid, parentSubid, item->arg);
    }
}
 
 
/* ----------------------------------------------------------------
 *                     transaction block support
 * ----------------------------------------------------------------
 */
 
/*
 *  BeginTransactionBlock
 *      This executes a BEGIN command.
 */
void
BeginTransactionBlock(void)
{
    TransactionState s = CurrentTransactionState;
 
    switch (s->blockState)
    {
            /*
             * We are not inside a transaction block, so allow one to begin.
             */
        case TBLOCK_STARTED:
            s->blockState = TBLOCK_BEGIN;
            break;
 
            /*
             * BEGIN converts an implicit transaction block to a regular one.
             * (Note that we allow this even if we've already done some
             * commands, which is a bit odd but matches historical practice.)
             */
        case TBLOCK_IMPLICIT_INPROGRESS:
            s->blockState = TBLOCK_BEGIN;
            break;
 
            /*
             * Already a transaction block in progress.
             */
        case TBLOCK_INPROGRESS:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBINPROGRESS:
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
            ereport(WARNING,
                    (errcode(ERRCODE_ACTIVE_SQL_TRANSACTION),
                     errmsg("there is already a transaction in progress")));
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_BEGIN:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "BeginTransactionBlock: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
}
 
/*
 *  PrepareTransactionBlock
 *      This executes a PREPARE command.
 *
 * Since PREPARE may actually do a ROLLBACK, the result indicates what
 * happened: true for PREPARE, false for ROLLBACK.
 *
 * Note that we don't actually do anything here except change blockState.
 * The real work will be done in the upcoming PrepareTransaction().
 * We do it this way because it's not convenient to change memory context,
 * resource owner, etc while executing inside a Portal.
 */
bool
PrepareTransactionBlock(const char *gid)
{
    TransactionState s;
    bool        result;
 
    /* Set up to commit the current transaction */
    result = EndTransactionBlock(false);
 
    /* If successful, change outer tblock state to PREPARE */
    if (result)
    {
        s = CurrentTransactionState;
 
        while (s->parent != NULL)
            s = s->parent;
 
        if (s->blockState == TBLOCK_END)
        {
            /* Save GID where PrepareTransaction can find it again */
            prepareGID = MemoryContextStrdup(TopTransactionContext, gid);
 
            s->blockState = TBLOCK_PREPARE;
        }
        else
        {
            /*
             * ignore case where we are not in a transaction;
             * EndTransactionBlock already issued a warning.
             */
            Assert(s->blockState == TBLOCK_STARTED ||
                   s->blockState == TBLOCK_IMPLICIT_INPROGRESS);
            /* Don't send back a PREPARE result tag... */
            result = false;
        }
    }
 
    return result;
}
 
/*
 *  EndTransactionBlock
 *      This executes a COMMIT command.
 *
 * Since COMMIT may actually do a ROLLBACK, the result indicates what
 * happened: true for COMMIT, false for ROLLBACK.
 *
 * Note that we don't actually do anything here except change blockState.
 * The real work will be done in the upcoming CommitTransactionCommand().
 * We do it this way because it's not convenient to change memory context,
 * resource owner, etc while executing inside a Portal.
 */
bool
EndTransactionBlock(bool chain)
{
    TransactionState s = CurrentTransactionState;
    bool        result = false;
 
    switch (s->blockState)
    {
            /*
             * We are in a transaction block, so tell CommitTransactionCommand
             * to COMMIT.
             */
        case TBLOCK_INPROGRESS:
            s->blockState = TBLOCK_END;
            result = true;
            break;
 
            /*
             * We are in an implicit transaction block.  If AND CHAIN was
             * specified, error.  Otherwise commit, but issue a warning
             * because there was no explicit BEGIN before this.
             */
        case TBLOCK_IMPLICIT_INPROGRESS:
            if (chain)
                ereport(ERROR,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                /* translator: %s represents an SQL statement name */
                         errmsg("%s can only be used in transaction blocks",
                                "COMMIT AND CHAIN")));
            else
                ereport(WARNING,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                         errmsg("there is no transaction in progress")));
            s->blockState = TBLOCK_END;
            result = true;
            break;
 
            /*
             * We are in a failed transaction block.  Tell
             * CommitTransactionCommand it's time to exit the block.
             */
        case TBLOCK_ABORT:
            s->blockState = TBLOCK_ABORT_END;
            break;
 
            /*
             * We are in a live subtransaction block.  Set up to subcommit all
             * open subtransactions and then commit the main transaction.
             */
        case TBLOCK_SUBINPROGRESS:
            while (s->parent != NULL)
            {
                if (s->blockState == TBLOCK_SUBINPROGRESS)
                    s->blockState = TBLOCK_SUBCOMMIT;
                else
                    elog(FATAL, "EndTransactionBlock: unexpected state %s",
                         BlockStateAsString(s->blockState));
                s = s->parent;
            }
            if (s->blockState == TBLOCK_INPROGRESS)
                s->blockState = TBLOCK_END;
            else
                elog(FATAL, "EndTransactionBlock: unexpected state %s",
                     BlockStateAsString(s->blockState));
            result = true;
            break;
 
            /*
             * Here we are inside an aborted subtransaction.  Treat the COMMIT
             * as ROLLBACK: set up to abort everything and exit the main
             * transaction.
             */
        case TBLOCK_SUBABORT:
            while (s->parent != NULL)
            {
                if (s->blockState == TBLOCK_SUBINPROGRESS)
                    s->blockState = TBLOCK_SUBABORT_PENDING;
                else if (s->blockState == TBLOCK_SUBABORT)
                    s->blockState = TBLOCK_SUBABORT_END;
                else
                    elog(FATAL, "EndTransactionBlock: unexpected state %s",
                         BlockStateAsString(s->blockState));
                s = s->parent;
            }
            if (s->blockState == TBLOCK_INPROGRESS)
                s->blockState = TBLOCK_ABORT_PENDING;
            else if (s->blockState == TBLOCK_ABORT)
                s->blockState = TBLOCK_ABORT_END;
            else
                elog(FATAL, "EndTransactionBlock: unexpected state %s",
                     BlockStateAsString(s->blockState));
            break;
 
            /*
             * The user issued COMMIT when not inside a transaction.  For
             * COMMIT without CHAIN, issue a WARNING, staying in
             * TBLOCK_STARTED state.  The upcoming call to
             * CommitTransactionCommand() will then close the transaction and
             * put us back into the default state.  For COMMIT AND CHAIN,
             * error.
             */
        case TBLOCK_STARTED:
            if (chain)
                ereport(ERROR,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                /* translator: %s represents an SQL statement name */
                         errmsg("%s can only be used in transaction blocks",
                                "COMMIT AND CHAIN")));
            else
                ereport(WARNING,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                         errmsg("there is no transaction in progress")));
            result = true;
            break;
 
            /*
             * The user issued a COMMIT that somehow ran inside a parallel
             * worker.  We can't cope with that.
             */
        case TBLOCK_PARALLEL_INPROGRESS:
            ereport(FATAL,
                    (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                     errmsg("cannot commit during a parallel operation")));
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_BEGIN:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "EndTransactionBlock: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    Assert(s->blockState == TBLOCK_STARTED ||
           s->blockState == TBLOCK_END ||
           s->blockState == TBLOCK_ABORT_END ||
           s->blockState == TBLOCK_ABORT_PENDING);
 
    s->chain = chain;
 
    return result;
}
 
/*
 *  UserAbortTransactionBlock
 *      This executes a ROLLBACK command.
 *
 * As above, we don't actually do anything here except change blockState.
 */
void
UserAbortTransactionBlock(bool chain)
{
    TransactionState s = CurrentTransactionState;
 
    switch (s->blockState)
    {
            /*
             * We are inside a transaction block and we got a ROLLBACK command
             * from the user, so tell CommitTransactionCommand to abort and
             * exit the transaction block.
             */
        case TBLOCK_INPROGRESS:
            s->blockState = TBLOCK_ABORT_PENDING;
            break;
 
            /*
             * We are inside a failed transaction block and we got a ROLLBACK
             * command from the user.  Abort processing is already done, so
             * CommitTransactionCommand just has to cleanup and go back to
             * idle state.
             */
        case TBLOCK_ABORT:
            s->blockState = TBLOCK_ABORT_END;
            break;
 
            /*
             * We are inside a subtransaction.  Mark everything up to top
             * level as exitable.
             */
        case TBLOCK_SUBINPROGRESS:
        case TBLOCK_SUBABORT:
            while (s->parent != NULL)
            {
                if (s->blockState == TBLOCK_SUBINPROGRESS)
                    s->blockState = TBLOCK_SUBABORT_PENDING;
                else if (s->blockState == TBLOCK_SUBABORT)
                    s->blockState = TBLOCK_SUBABORT_END;
                else
                    elog(FATAL, "UserAbortTransactionBlock: unexpected state %s",
                         BlockStateAsString(s->blockState));
                s = s->parent;
            }
            if (s->blockState == TBLOCK_INPROGRESS)
                s->blockState = TBLOCK_ABORT_PENDING;
            else if (s->blockState == TBLOCK_ABORT)
                s->blockState = TBLOCK_ABORT_END;
            else
                elog(FATAL, "UserAbortTransactionBlock: unexpected state %s",
                     BlockStateAsString(s->blockState));
            break;
 
            /*
             * The user issued ABORT when not inside a transaction.  For
             * ROLLBACK without CHAIN, issue a WARNING and go to abort state.
             * The upcoming call to CommitTransactionCommand() will then put
             * us back into the default state.  For ROLLBACK AND CHAIN, error.
             *
             * We do the same thing with ABORT inside an implicit transaction,
             * although in this case we might be rolling back actual database
             * state changes.  (It's debatable whether we should issue a
             * WARNING in this case, but we have done so historically.)
             */
        case TBLOCK_STARTED:
        case TBLOCK_IMPLICIT_INPROGRESS:
            if (chain)
                ereport(ERROR,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                /* translator: %s represents an SQL statement name */
                         errmsg("%s can only be used in transaction blocks",
                                "ROLLBACK AND CHAIN")));
            else
                ereport(WARNING,
                        (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
                         errmsg("there is no transaction in progress")));
            s->blockState = TBLOCK_ABORT_PENDING;
            break;
 
            /*
             * The user issued an ABORT that somehow ran inside a parallel
             * worker.  We can't cope with that.
             */
        case TBLOCK_PARALLEL_INPROGRESS:
            ereport(FATAL,
                    (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                     errmsg("cannot abort during a parallel operation")));
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_BEGIN:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "UserAbortTransactionBlock: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    Assert(s->blockState == TBLOCK_ABORT_END ||
           s->blockState == TBLOCK_ABORT_PENDING);
 
    s->chain = chain;
}
 
/*
 * BeginImplicitTransactionBlock
 *      Start an implicit transaction block if we're not already in one.
 *
 * Unlike BeginTransactionBlock, this is called directly from the main loop
 * in postgres.c, not within a Portal.  So we can just change blockState
 * without a lot of ceremony.  We do not expect caller to do
 * CommitTransactionCommand/StartTransactionCommand.
 */
void
BeginImplicitTransactionBlock(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * If we are in STARTED state (that is, no transaction block is open),
     * switch to IMPLICIT_INPROGRESS state, creating an implicit transaction
     * block.
     *
     * For caller convenience, we consider all other transaction states as
     * legal here; otherwise the caller would need its own state check, which
     * seems rather pointless.
     */
    if (s->blockState == TBLOCK_STARTED)
        s->blockState = TBLOCK_IMPLICIT_INPROGRESS;
}
 
/*
 * EndImplicitTransactionBlock
 *      End an implicit transaction block, if we're in one.
 *
 * Like EndTransactionBlock, we just make any needed blockState change here.
 * The real work will be done in the upcoming CommitTransactionCommand().
 */
void
EndImplicitTransactionBlock(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * If we are in IMPLICIT_INPROGRESS state, switch back to STARTED state,
     * allowing CommitTransactionCommand to commit whatever happened during
     * the implicit transaction block as though it were a single statement.
     *
     * For caller convenience, we consider all other transaction states as
     * legal here; otherwise the caller would need its own state check, which
     * seems rather pointless.
     */
    if (s->blockState == TBLOCK_IMPLICIT_INPROGRESS)
        s->blockState = TBLOCK_STARTED;
}
 
/*
 * DefineSavepoint
 *      This executes a SAVEPOINT command.
 */
void
DefineSavepoint(const char *name)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * Workers synchronize transaction state at the beginning of each parallel
     * operation, so we can't account for new subtransactions after that
     * point.  (Note that this check will certainly error out if s->blockState
     * is TBLOCK_PARALLEL_INPROGRESS, so we can treat that as an invalid case
     * below.)
     */
    if (IsInParallelMode() || IsParallelWorker())
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                 errmsg("cannot define savepoints during a parallel operation")));
 
    switch (s->blockState)
    {
        case TBLOCK_INPROGRESS:
        case TBLOCK_SUBINPROGRESS:
            /* Normal subtransaction start */
            PushTransaction();
            s = CurrentTransactionState;    /* changed by push */
 
            /*
             * Savepoint names, like the TransactionState block itself, live
             * in TopTransactionContext.
             */
            if (name)
                s->name = MemoryContextStrdup(TopTransactionContext, name);
            break;
 
            /*
             * We disallow savepoint commands in implicit transaction blocks.
             * There would be no great difficulty in allowing them so far as
             * this module is concerned, but a savepoint seems inconsistent
             * with exec_simple_query's behavior of abandoning the whole query
             * string upon error.  Also, the point of an implicit transaction
             * block (as opposed to a regular one) is to automatically close
             * after an error, so it's hard to see how a savepoint would fit
             * into that.
             *
             * The error messages for this are phrased as if there were no
             * active transaction block at all, which is historical but
             * perhaps could be improved.
             */
        case TBLOCK_IMPLICIT_INPROGRESS:
            ereport(ERROR,
                    (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
            /* translator: %s represents an SQL statement name */
                     errmsg("%s can only be used in transaction blocks",
                            "SAVEPOINT")));
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_STARTED:
        case TBLOCK_BEGIN:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "DefineSavepoint: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
}
 
/*
 * ReleaseSavepoint
 *      This executes a RELEASE command.
 *
 * As above, we don't actually do anything here except change blockState.
 */
void
ReleaseSavepoint(const char *name)
{
    TransactionState s = CurrentTransactionState;
    TransactionState target,
                xact;
 
    /*
     * Workers synchronize transaction state at the beginning of each parallel
     * operation, so we can't account for transaction state change after that
     * point.  (Note that this check will certainly error out if s->blockState
     * is TBLOCK_PARALLEL_INPROGRESS, so we can treat that as an invalid case
     * below.)
     */
    if (IsInParallelMode() || IsParallelWorker())
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                 errmsg("cannot release savepoints during a parallel operation")));
 
    switch (s->blockState)
    {
            /*
             * We can't release a savepoint if there is no savepoint defined.
             */
        case TBLOCK_INPROGRESS:
            ereport(ERROR,
                    (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                     errmsg("savepoint \"%s\" does not exist", name)));
            break;
 
        case TBLOCK_IMPLICIT_INPROGRESS:
            /* See comment about implicit transactions in DefineSavepoint */
            ereport(ERROR,
                    (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
            /* translator: %s represents an SQL statement name */
                     errmsg("%s can only be used in transaction blocks",
                            "RELEASE SAVEPOINT")));
            break;
 
            /*
             * We are in a non-aborted subtransaction.  This is the only valid
             * case.
             */
        case TBLOCK_SUBINPROGRESS:
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_STARTED:
        case TBLOCK_BEGIN:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "ReleaseSavepoint: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    for (target = s; target; target = target->parent)
    {
        if (target->name && strcmp(target->name, name) == 0)
            break;
    }
 
    if (!target)
        ereport(ERROR,
                (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                 errmsg("savepoint \"%s\" does not exist", name)));
 
    /* disallow crossing savepoint level boundaries */
    if (target->savepointLevel != s->savepointLevel)
        ereport(ERROR,
                (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                 errmsg("savepoint \"%s\" does not exist within current savepoint level", name)));
 
    /*
     * Mark "commit pending" all subtransactions up to the target
     * subtransaction.  The actual commits will happen when control gets to
     * CommitTransactionCommand.
     */
    xact = CurrentTransactionState;
    for (;;)
    {
        Assert(xact->blockState == TBLOCK_SUBINPROGRESS);
        xact->blockState = TBLOCK_SUBRELEASE;
        if (xact == target)
            break;
        xact = xact->parent;
        Assert(xact);
    }
}
 
/*
 * RollbackToSavepoint
 *      This executes a ROLLBACK TO <savepoint> command.
 *
 * As above, we don't actually do anything here except change blockState.
 */
void
RollbackToSavepoint(const char *name)
{
    TransactionState s = CurrentTransactionState;
    TransactionState target,
                xact;
 
    /*
     * Workers synchronize transaction state at the beginning of each parallel
     * operation, so we can't account for transaction state change after that
     * point.  (Note that this check will certainly error out if s->blockState
     * is TBLOCK_PARALLEL_INPROGRESS, so we can treat that as an invalid case
     * below.)
     */
    if (IsInParallelMode() || IsParallelWorker())
        ereport(ERROR,
                (errcode(ERRCODE_INVALID_TRANSACTION_STATE),
                 errmsg("cannot rollback to savepoints during a parallel operation")));
 
    switch (s->blockState)
    {
            /*
             * We can't rollback to a savepoint if there is no savepoint
             * defined.
             */
        case TBLOCK_INPROGRESS:
        case TBLOCK_ABORT:
            ereport(ERROR,
                    (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                     errmsg("savepoint \"%s\" does not exist", name)));
            break;
 
        case TBLOCK_IMPLICIT_INPROGRESS:
            /* See comment about implicit transactions in DefineSavepoint */
            ereport(ERROR,
                    (errcode(ERRCODE_NO_ACTIVE_SQL_TRANSACTION),
            /* translator: %s represents an SQL statement name */
                     errmsg("%s can only be used in transaction blocks",
                            "ROLLBACK TO SAVEPOINT")));
            break;
 
            /*
             * There is at least one savepoint, so proceed.
             */
        case TBLOCK_SUBINPROGRESS:
        case TBLOCK_SUBABORT:
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_STARTED:
        case TBLOCK_BEGIN:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "RollbackToSavepoint: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    for (target = s; target; target = target->parent)
    {
        if (target->name && strcmp(target->name, name) == 0)
            break;
    }
 
    if (!target)
        ereport(ERROR,
                (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                 errmsg("savepoint \"%s\" does not exist", name)));
 
    /* disallow crossing savepoint level boundaries */
    if (target->savepointLevel != s->savepointLevel)
        ereport(ERROR,
                (errcode(ERRCODE_S_E_INVALID_SPECIFICATION),
                 errmsg("savepoint \"%s\" does not exist within current savepoint level", name)));
 
    /*
     * Mark "abort pending" all subtransactions up to the target
     * subtransaction.  The actual aborts will happen when control gets to
     * CommitTransactionCommand.
     */
    xact = CurrentTransactionState;
    for (;;)
    {
        if (xact == target)
            break;
        if (xact->blockState == TBLOCK_SUBINPROGRESS)
            xact->blockState = TBLOCK_SUBABORT_PENDING;
        else if (xact->blockState == TBLOCK_SUBABORT)
            xact->blockState = TBLOCK_SUBABORT_END;
        else
            elog(FATAL, "RollbackToSavepoint: unexpected state %s",
                 BlockStateAsString(xact->blockState));
        xact = xact->parent;
        Assert(xact);
    }
 
    /* And mark the target as "restart pending" */
    if (xact->blockState == TBLOCK_SUBINPROGRESS)
        xact->blockState = TBLOCK_SUBRESTART;
    else if (xact->blockState == TBLOCK_SUBABORT)
        xact->blockState = TBLOCK_SUBABORT_RESTART;
    else
        elog(FATAL, "RollbackToSavepoint: unexpected state %s",
             BlockStateAsString(xact->blockState));
}
 
/*
 * BeginInternalSubTransaction
 *      This is the same as DefineSavepoint except it allows TBLOCK_STARTED,
 *      TBLOCK_IMPLICIT_INPROGRESS, TBLOCK_PARALLEL_INPROGRESS, TBLOCK_END,
 *      and TBLOCK_PREPARE states, and therefore it can safely be used in
 *      functions that might be called when not inside a BEGIN block or when
 *      running deferred triggers at COMMIT/PREPARE time.  Also, it
 *      automatically does CommitTransactionCommand/StartTransactionCommand
 *      instead of expecting the caller to do it.
 */
void
BeginInternalSubTransaction(const char *name)
{
    TransactionState s = CurrentTransactionState;
    bool        save_ExitOnAnyError = ExitOnAnyError;
 
    /*
     * Errors within this function are improbable, but if one does happen we
     * force a FATAL exit.  Callers generally aren't prepared to handle losing
     * control, and moreover our transaction state is probably corrupted if we
     * fail partway through; so an ordinary ERROR longjmp isn't okay.
     */
    ExitOnAnyError = true;
 
    /*
     * We do not check for parallel mode here.  It's permissible to start and
     * end "internal" subtransactions while in parallel mode, so long as no
     * new XIDs or command IDs are assigned.  Enforcement of that occurs in
     * AssignTransactionId() and CommandCounterIncrement().
     */
 
    switch (s->blockState)
    {
        case TBLOCK_STARTED:
        case TBLOCK_INPROGRESS:
        case TBLOCK_IMPLICIT_INPROGRESS:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_END:
        case TBLOCK_PREPARE:
        case TBLOCK_SUBINPROGRESS:
            /* Normal subtransaction start */
            PushTransaction();
            s = CurrentTransactionState;    /* changed by push */
 
            /*
             * Savepoint names, like the TransactionState block itself, live
             * in TopTransactionContext.
             */
            if (name)
                s->name = MemoryContextStrdup(TopTransactionContext, name);
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_BEGIN:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
            elog(FATAL, "BeginInternalSubTransaction: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    CommitTransactionCommand();
    StartTransactionCommand();
 
    ExitOnAnyError = save_ExitOnAnyError;
}
 
/*
 * ReleaseCurrentSubTransaction
 *
 * RELEASE (ie, commit) the innermost subtransaction, regardless of its
 * savepoint name (if any).
 * NB: do NOT use CommitTransactionCommand/StartTransactionCommand with this.
 */
void
ReleaseCurrentSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * We do not check for parallel mode here.  It's permissible to start and
     * end "internal" subtransactions while in parallel mode, so long as no
     * new XIDs or command IDs are assigned.
     */
 
    if (s->blockState != TBLOCK_SUBINPROGRESS)
        elog(ERROR, "ReleaseCurrentSubTransaction: unexpected state %s",
             BlockStateAsString(s->blockState));
    Assert(s->state == TRANS_INPROGRESS);
    MemoryContextSwitchTo(CurTransactionContext);
    CommitSubTransaction();
    s = CurrentTransactionState;    /* changed by pop */
    Assert(s->state == TRANS_INPROGRESS);
}
 
/*
 * RollbackAndReleaseCurrentSubTransaction
 *
 * ROLLBACK and RELEASE (ie, abort) the innermost subtransaction, regardless
 * of its savepoint name (if any).
 * NB: do NOT use CommitTransactionCommand/StartTransactionCommand with this.
 */
void
RollbackAndReleaseCurrentSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    /*
     * We do not check for parallel mode here.  It's permissible to start and
     * end "internal" subtransactions while in parallel mode, so long as no
     * new XIDs or command IDs are assigned.
     */
 
    switch (s->blockState)
    {
            /* Must be in a subtransaction */
        case TBLOCK_SUBINPROGRESS:
        case TBLOCK_SUBABORT:
            break;
 
            /* These cases are invalid. */
        case TBLOCK_DEFAULT:
        case TBLOCK_STARTED:
        case TBLOCK_BEGIN:
        case TBLOCK_IMPLICIT_INPROGRESS:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_INPROGRESS:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_ABORT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
        case TBLOCK_PREPARE:
            elog(FATAL, "RollbackAndReleaseCurrentSubTransaction: unexpected state %s",
                 BlockStateAsString(s->blockState));
            break;
    }
 
    /*
     * Abort the current subtransaction, if needed.
     */
    if (s->blockState == TBLOCK_SUBINPROGRESS)
        AbortSubTransaction();
 
    /* And clean it up, too */
    CleanupSubTransaction();
 
    s = CurrentTransactionState;    /* changed by pop */
    Assert(s->blockState == TBLOCK_SUBINPROGRESS ||
           s->blockState == TBLOCK_INPROGRESS ||
           s->blockState == TBLOCK_IMPLICIT_INPROGRESS ||
           s->blockState == TBLOCK_PARALLEL_INPROGRESS ||
           s->blockState == TBLOCK_STARTED);
}
 
/*
 *  AbortOutOfAnyTransaction
 *
 *  This routine is provided for error recovery purposes.  It aborts any
 *  active transaction or transaction block, leaving the system in a known
 *  idle state.
 */
void
AbortOutOfAnyTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    /* Ensure we're not running in a doomed memory context */
    AtAbort_Memory();
 
    /*
     * Get out of any transaction or nested transaction
     */
    do
    {
        switch (s->blockState)
        {
            case TBLOCK_DEFAULT:
                if (s->state == TRANS_DEFAULT)
                {
                    /* Not in a transaction, do nothing */
                }
                else
                {
                    /*
                     * We can get here after an error during transaction start
                     * (state will be TRANS_START).  Need to clean up the
                     * incompletely started transaction.  First, adjust the
                     * low-level state to suppress warning message from
                     * AbortTransaction.
                     */
                    if (s->state == TRANS_START)
                        s->state = TRANS_INPROGRESS;
                    AbortTransaction();
                    CleanupTransaction();
                }
                break;
            case TBLOCK_STARTED:
            case TBLOCK_BEGIN:
            case TBLOCK_INPROGRESS:
            case TBLOCK_IMPLICIT_INPROGRESS:
            case TBLOCK_PARALLEL_INPROGRESS:
            case TBLOCK_END:
            case TBLOCK_ABORT_PENDING:
            case TBLOCK_PREPARE:
                /* In a transaction, so clean up */
                AbortTransaction();
                CleanupTransaction();
                s->blockState = TBLOCK_DEFAULT;
                break;
            case TBLOCK_ABORT:
            case TBLOCK_ABORT_END:
 
                /*
                 * AbortTransaction is already done, still need Cleanup.
                 * However, if we failed partway through running ROLLBACK,
                 * there will be an active portal running that command, which
                 * we need to shut down before doing CleanupTransaction.
                 */
                AtAbort_Portals();
                CleanupTransaction();
                s->blockState = TBLOCK_DEFAULT;
                break;
 
                /*
                 * In a subtransaction, so clean it up and abort parent too
                 */
            case TBLOCK_SUBBEGIN:
            case TBLOCK_SUBINPROGRESS:
            case TBLOCK_SUBRELEASE:
            case TBLOCK_SUBCOMMIT:
            case TBLOCK_SUBABORT_PENDING:
            case TBLOCK_SUBRESTART:
                AbortSubTransaction();
                CleanupSubTransaction();
                s = CurrentTransactionState;    /* changed by pop */
                break;
 
            case TBLOCK_SUBABORT:
            case TBLOCK_SUBABORT_END:
            case TBLOCK_SUBABORT_RESTART:
                /* As above, but AbortSubTransaction already done */
                if (s->curTransactionOwner)
                {
                    /* As in TBLOCK_ABORT, might have a live portal to zap */
                    AtSubAbort_Portals(s->subTransactionId,
                                       s->parent->subTransactionId,
                                       s->curTransactionOwner,
                                       s->parent->curTransactionOwner);
                }
                CleanupSubTransaction();
                s = CurrentTransactionState;    /* changed by pop */
                break;
        }
    } while (s->blockState != TBLOCK_DEFAULT);
 
    /* Should be out of all subxacts now */
    Assert(s->parent == NULL);
 
    /*
     * Revert to TopMemoryContext, to ensure we exit in a well-defined state
     * whether there were any transactions to close or not.  (Callers that
     * don't intend to exit soon should switch to some other context to avoid
     * long-term memory leaks.)
     */
    MemoryContextSwitchTo(TopMemoryContext);
}
 
/*
 * IsTransactionBlock --- are we within a transaction block?
 */
bool
IsTransactionBlock(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->blockState == TBLOCK_DEFAULT || s->blockState == TBLOCK_STARTED)
        return false;
 
    return true;
}
 
/*
 * IsTransactionOrTransactionBlock --- are we within either a transaction
 * or a transaction block?  (The backend is only really "idle" when this
 * returns false.)
 *
 * This should match up with IsTransactionBlock and IsTransactionState.
 */
bool
IsTransactionOrTransactionBlock(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->blockState == TBLOCK_DEFAULT)
        return false;
 
    return true;
}
 
/*
 * TransactionBlockStatusCode - return status code to send in ReadyForQuery
 */
char
TransactionBlockStatusCode(void)
{
    TransactionState s = CurrentTransactionState;
 
    switch (s->blockState)
    {
        case TBLOCK_DEFAULT:
        case TBLOCK_STARTED:
            return 'I';         /* idle --- not in transaction */
        case TBLOCK_BEGIN:
        case TBLOCK_SUBBEGIN:
        case TBLOCK_INPROGRESS:
        case TBLOCK_IMPLICIT_INPROGRESS:
        case TBLOCK_PARALLEL_INPROGRESS:
        case TBLOCK_SUBINPROGRESS:
        case TBLOCK_END:
        case TBLOCK_SUBRELEASE:
        case TBLOCK_SUBCOMMIT:
        case TBLOCK_PREPARE:
            return 'T';         /* in transaction */
        case TBLOCK_ABORT:
        case TBLOCK_SUBABORT:
        case TBLOCK_ABORT_END:
        case TBLOCK_SUBABORT_END:
        case TBLOCK_ABORT_PENDING:
        case TBLOCK_SUBABORT_PENDING:
        case TBLOCK_SUBRESTART:
        case TBLOCK_SUBABORT_RESTART:
            return 'E';         /* in failed transaction */
    }
 
    /* should never get here */
    elog(FATAL, "invalid transaction block state: %s",
         BlockStateAsString(s->blockState));
    return 0;                   /* keep compiler quiet */
}
 
/*
 * IsSubTransaction
 */
bool
IsSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->nestingLevel >= 2)
        return true;
 
    return false;
}
 
/*
 * StartSubTransaction
 *
 * If you're wondering why this is separate from PushTransaction: it's because
 * we can't conveniently do this stuff right inside DefineSavepoint.  The
 * SAVEPOINT utility command will be executed inside a Portal, and if we
 * muck with CurrentMemoryContext or CurrentResourceOwner then exit from
 * the Portal will undo those settings.  So we make DefineSavepoint just
 * push a dummy transaction block, and when control returns to the main
 * idle loop, CommitTransactionCommand will be called, and we'll come here
 * to finish starting the subtransaction.
 */
static void
StartSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->state != TRANS_DEFAULT)
        elog(WARNING, "StartSubTransaction while in %s state",
             TransStateAsString(s->state));
 
    s->state = TRANS_START;
 
    /*
     * Initialize subsystems for new subtransaction
     *
     * must initialize resource-management stuff first
     */
    AtSubStart_Memory();
    AtSubStart_ResourceOwner();
    AfterTriggerBeginSubXact();
 
    s->state = TRANS_INPROGRESS;
 
    /*
     * Call start-of-subxact callbacks
     */
    CallSubXactCallbacks(SUBXACT_EVENT_START_SUB, s->subTransactionId,
                         s->parent->subTransactionId);
 
    ShowTransactionState("StartSubTransaction");
}
 
/*
 * CommitSubTransaction
 *
 *  The caller has to make sure to always reassign CurrentTransactionState
 *  if it has a local pointer to it after calling this function.
 */
static void
CommitSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    ShowTransactionState("CommitSubTransaction");
 
    if (s->state != TRANS_INPROGRESS)
        elog(WARNING, "CommitSubTransaction while in %s state",
             TransStateAsString(s->state));
 
    /* Pre-commit processing goes here */
 
    CallSubXactCallbacks(SUBXACT_EVENT_PRE_COMMIT_SUB, s->subTransactionId,
                         s->parent->subTransactionId);
 
    /*
     * If this subxact has started any unfinished parallel operation, clean up
     * its workers and exit parallel mode.  Warn about leaked resources.
     */
    AtEOSubXact_Parallel(true, s->subTransactionId);
    if (s->parallelModeLevel != 0)
    {
        elog(WARNING, "parallelModeLevel is %d not 0 at end of subtransaction",
             s->parallelModeLevel);
        s->parallelModeLevel = 0;
    }
 
    /* Do the actual "commit", such as it is */
    s->state = TRANS_COMMIT;
 
    /* Must CCI to ensure commands of subtransaction are seen as done */
    CommandCounterIncrement();
 
    /*
     * Prior to 8.4 we marked subcommit in clog at this point.  We now only
     * perform that step, if required, as part of the atomic update of the
     * whole transaction tree at top level commit or abort.
     */
 
    /* Post-commit cleanup */
    if (FullTransactionIdIsValid(s->fullTransactionId))
        AtSubCommit_childXids();
    AfterTriggerEndSubXact(true);
    AtSubCommit_Portals(s->subTransactionId,
                        s->parent->subTransactionId,
                        s->parent->nestingLevel,
                        s->parent->curTransactionOwner);
    AtEOSubXact_LargeObject(true, s->subTransactionId,
                            s->parent->subTransactionId);
    AtSubCommit_Notify();
 
    CallSubXactCallbacks(SUBXACT_EVENT_COMMIT_SUB, s->subTransactionId,
                         s->parent->subTransactionId);
 
    ResourceOwnerRelease(s->curTransactionOwner,
                         RESOURCE_RELEASE_BEFORE_LOCKS,
                         true, false);
    AtEOSubXact_RelationCache(true, s->subTransactionId,
                              s->parent->subTransactionId);
    AtEOSubXact_TypeCache();
    AtEOSubXact_Inval(true);
    AtSubCommit_smgr();
 
    /*
     * The only lock we actually release here is the subtransaction XID lock.
     */
    CurrentResourceOwner = s->curTransactionOwner;
    if (FullTransactionIdIsValid(s->fullTransactionId))
        XactLockTableDelete(XidFromFullTransactionId(s->fullTransactionId));
 
    /*
     * Other locks should get transferred to their parent resource owner.
     */
    ResourceOwnerRelease(s->curTransactionOwner,
                         RESOURCE_RELEASE_LOCKS,
                         true, false);
    ResourceOwnerRelease(s->curTransactionOwner,
                         RESOURCE_RELEASE_AFTER_LOCKS,
                         true, false);
 
    AtEOXact_GUC(true, s->gucNestLevel);
    AtEOSubXact_SPI(true, s->subTransactionId);
    AtEOSubXact_on_commit_actions(true, s->subTransactionId,
                                  s->parent->subTransactionId);
    AtEOSubXact_Namespace(true, s->subTransactionId,
                          s->parent->subTransactionId);
    AtEOSubXact_Files(true, s->subTransactionId,
                      s->parent->subTransactionId);
    AtEOSubXact_HashTables(true, s->nestingLevel);
    AtEOSubXact_PgStat(true, s->nestingLevel);
    AtSubCommit_Snapshot(s->nestingLevel);
 
    /*
     * We need to restore the upper transaction's read-only state, in case the
     * upper is read-write while the child is read-only; GUC will incorrectly
     * think it should leave the child state in place.
     */
    XactReadOnly = s->prevXactReadOnly;
 
    CurrentResourceOwner = s->parent->curTransactionOwner;
    CurTransactionResourceOwner = s->parent->curTransactionOwner;
    ResourceOwnerDelete(s->curTransactionOwner);
    s->curTransactionOwner = NULL;
 
    AtSubCommit_Memory();
 
    s->state = TRANS_DEFAULT;
 
    PopTransaction();
}
 
/*
 * AbortSubTransaction
 */
static void
AbortSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    /* Prevent cancel/die interrupt while cleaning up */
    HOLD_INTERRUPTS();
 
    /* Make sure we have a valid memory context and resource owner */
    AtSubAbort_Memory();
    AtSubAbort_ResourceOwner();
 
    /*
     * Release any LW locks we might be holding as quickly as possible.
     * (Regular locks, however, must be held till we finish aborting.)
     * Releasing LW locks is critical since we might try to grab them again
     * while cleaning up!
     *
     * FIXME This may be incorrect --- Are there some locks we should keep?
     * Buffer locks, for example?  I don't think so but I'm not sure.
     */
    LWLockReleaseAll();
 
    pgstat_report_wait_end();
    pgstat_progress_end_command();
 
    pgaio_error_cleanup();
 
    UnlockBuffers();
 
    /* Reset WAL record construction state */
    XLogResetInsertion();
 
    /* Cancel condition variable sleep */
    ConditionVariableCancelSleep();
 
    /*
     * Also clean up any open wait for lock, since the lock manager will choke
     * if we try to wait for another lock before doing this.
     */
    LockErrorCleanup();
 
    /*
     * If any timeout events are still active, make sure the timeout interrupt
     * is scheduled.  This covers possible loss of a timeout interrupt due to
     * longjmp'ing out of the SIGINT handler (see notes in handle_sig_alarm).
     * We delay this till after LockErrorCleanup so that we don't uselessly
     * reschedule lock or deadlock check timeouts.
     */
    reschedule_timeouts();
 
    /*
     * Re-enable signals, in case we got here by longjmp'ing out of a signal
     * handler.  We do this fairly early in the sequence so that the timeout
     * infrastructure will be functional if needed while aborting.
     */
    sigprocmask(SIG_SETMASK, &UnBlockSig, NULL);
 
    /*
     * check the current transaction state
     */
    ShowTransactionState("AbortSubTransaction");
 
    if (s->state != TRANS_INPROGRESS)
        elog(WARNING, "AbortSubTransaction while in %s state",
             TransStateAsString(s->state));
 
    s->state = TRANS_ABORT;
 
    /*
     * Reset user ID which might have been changed transiently.  (See notes in
     * AbortTransaction.)
     */
    SetUserIdAndSecContext(s->prevUser, s->prevSecContext);
 
    /* Forget about any active REINDEX. */
    ResetReindexState(s->nestingLevel);
 
    /* Reset logical streaming state. */
    ResetLogicalStreamingState();
 
    /*
     * No need for SnapBuildResetExportedSnapshotState() here, snapshot
     * exports are not supported in subtransactions.
     */
 
    /*
     * If this subxact has started any unfinished parallel operation, clean up
     * its workers and exit parallel mode.  Don't warn about leaked resources.
     */
    AtEOSubXact_Parallel(false, s->subTransactionId);
    s->parallelModeLevel = 0;
 
    /*
     * We can skip all this stuff if the subxact failed before creating a
     * ResourceOwner...
     */
    if (s->curTransactionOwner)
    {
        AfterTriggerEndSubXact(false);
        AtSubAbort_Portals(s->subTransactionId,
                           s->parent->subTransactionId,
                           s->curTransactionOwner,
                           s->parent->curTransactionOwner);
        AtEOSubXact_LargeObject(false, s->subTransactionId,
                                s->parent->subTransactionId);
        AtSubAbort_Notify();
 
        /* Advertise the fact that we aborted in pg_xact. */
        (void) RecordTransactionAbort(true);
 
        /* Post-abort cleanup */
        if (FullTransactionIdIsValid(s->fullTransactionId))
            AtSubAbort_childXids();
 
        CallSubXactCallbacks(SUBXACT_EVENT_ABORT_SUB, s->subTransactionId,
                             s->parent->subTransactionId);
 
        ResourceOwnerRelease(s->curTransactionOwner,
                             RESOURCE_RELEASE_BEFORE_LOCKS,
                             false, false);
 
        AtEOXact_Aio(false);
        AtEOSubXact_RelationCache(false, s->subTransactionId,
                                  s->parent->subTransactionId);
        AtEOSubXact_TypeCache();
        AtEOSubXact_Inval(false);
        ResourceOwnerRelease(s->curTransactionOwner,
                             RESOURCE_RELEASE_LOCKS,
                             false, false);
        ResourceOwnerRelease(s->curTransactionOwner,
                             RESOURCE_RELEASE_AFTER_LOCKS,
                             false, false);
        AtSubAbort_smgr();
 
        AtEOXact_GUC(false, s->gucNestLevel);
        AtEOSubXact_SPI(false, s->subTransactionId);
        AtEOSubXact_on_commit_actions(false, s->subTransactionId,
                                      s->parent->subTransactionId);
        AtEOSubXact_Namespace(false, s->subTransactionId,
                              s->parent->subTransactionId);
        AtEOSubXact_Files(false, s->subTransactionId,
                          s->parent->subTransactionId);
        AtEOSubXact_HashTables(false, s->nestingLevel);
        AtEOSubXact_PgStat(false, s->nestingLevel);
        AtSubAbort_Snapshot(s->nestingLevel);
    }
 
    /*
     * Restore the upper transaction's read-only state, too.  This should be
     * redundant with GUC's cleanup but we may as well do it for consistency
     * with the commit case.
     */
    XactReadOnly = s->prevXactReadOnly;
 
    RESUME_INTERRUPTS();
}
 
/*
 * CleanupSubTransaction
 *
 *  The caller has to make sure to always reassign CurrentTransactionState
 *  if it has a local pointer to it after calling this function.
 */
static void
CleanupSubTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    ShowTransactionState("CleanupSubTransaction");
 
    if (s->state != TRANS_ABORT)
        elog(WARNING, "CleanupSubTransaction while in %s state",
             TransStateAsString(s->state));
 
    AtSubCleanup_Portals(s->subTransactionId);
 
    CurrentResourceOwner = s->parent->curTransactionOwner;
    CurTransactionResourceOwner = s->parent->curTransactionOwner;
    if (s->curTransactionOwner)
        ResourceOwnerDelete(s->curTransactionOwner);
    s->curTransactionOwner = NULL;
 
    AtSubCleanup_Memory();
 
    s->state = TRANS_DEFAULT;
 
    PopTransaction();
}
 
/*
 * PushTransaction
 *      Create transaction state stack entry for a subtransaction
 *
 *  The caller has to make sure to always reassign CurrentTransactionState
 *  if it has a local pointer to it after calling this function.
 */
static void
PushTransaction(void)
{
    TransactionState p = CurrentTransactionState;
    TransactionState s;
 
    /*
     * We keep subtransaction state nodes in TopTransactionContext.
     */
    s = (TransactionState)
        MemoryContextAllocZero(TopTransactionContext,
                               sizeof(TransactionStateData));
 
    /*
     * Assign a subtransaction ID, watching out for counter wraparound.
     */
    currentSubTransactionId += 1;
    if (currentSubTransactionId == InvalidSubTransactionId)
    {
        currentSubTransactionId -= 1;
        pfree(s);
        ereport(ERROR,
                (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED),
                 errmsg("cannot have more than 2^32-1 subtransactions in a transaction")));
    }
 
    /*
     * We can now stack a minimally valid subtransaction without fear of
     * failure.
     */
    s->fullTransactionId = InvalidFullTransactionId;    /* until assigned */
    s->subTransactionId = currentSubTransactionId;
    s->parent = p;
    s->nestingLevel = p->nestingLevel + 1;
    s->gucNestLevel = NewGUCNestLevel();
    s->savepointLevel = p->savepointLevel;
    s->state = TRANS_DEFAULT;
    s->blockState = TBLOCK_SUBBEGIN;
    GetUserIdAndSecContext(&s->prevUser, &s->prevSecContext);
    s->prevXactReadOnly = XactReadOnly;
    s->startedInRecovery = p->startedInRecovery;
    s->parallelModeLevel = 0;
    s->parallelChildXact = (p->parallelModeLevel != 0 || p->parallelChildXact);
    s->topXidLogged = false;
 
    CurrentTransactionState = s;
 
    /*
     * AbortSubTransaction and CleanupSubTransaction have to be able to cope
     * with the subtransaction from here on out; in particular they should not
     * assume that it necessarily has a transaction context, resource owner,
     * or XID.
     */
}
 
/*
 * PopTransaction
 *      Pop back to parent transaction state
 *
 *  The caller has to make sure to always reassign CurrentTransactionState
 *  if it has a local pointer to it after calling this function.
 */
static void
PopTransaction(void)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->state != TRANS_DEFAULT)
        elog(WARNING, "PopTransaction while in %s state",
             TransStateAsString(s->state));
 
    if (s->parent == NULL)
        elog(FATAL, "PopTransaction with no parent");
 
    CurrentTransactionState = s->parent;
 
    /* Let's just make sure CurTransactionContext is good */
    CurTransactionContext = s->parent->curTransactionContext;
    MemoryContextSwitchTo(CurTransactionContext);
 
    /* Ditto for ResourceOwner links */
    CurTransactionResourceOwner = s->parent->curTransactionOwner;
    CurrentResourceOwner = s->parent->curTransactionOwner;
 
    /* Free the old child structure */
    if (s->name)
        pfree(s->name);
    pfree(s);
}
 
/*
 * EstimateTransactionStateSpace
 *      Estimate the amount of space that will be needed by
 *      SerializeTransactionState.  It would be OK to overestimate slightly,
 *      but it's simple for us to work out the precise value, so we do.
 */
Size
EstimateTransactionStateSpace(void)
{
    TransactionState s;
    Size        nxids = 0;
    Size        size = SerializedTransactionStateHeaderSize;
 
    for (s = CurrentTransactionState; s != NULL; s = s->parent)
    {
        if (FullTransactionIdIsValid(s->fullTransactionId))
            nxids = add_size(nxids, 1);
        nxids = add_size(nxids, s->nChildXids);
    }
 
    return add_size(size, mul_size(sizeof(TransactionId), nxids));
}
 
/*
 * SerializeTransactionState
 *      Write out relevant details of our transaction state that will be
 *      needed by a parallel worker.
 *
 * We need to save and restore XactDeferrable, XactIsoLevel, and the XIDs
 * associated with this transaction.  These are serialized into a
 * caller-supplied buffer big enough to hold the number of bytes reported by
 * EstimateTransactionStateSpace().  We emit the XIDs in sorted order for the
 * convenience of the receiving process.
 */
void
SerializeTransactionState(Size maxsize, char *start_address)
{
    TransactionState s;
    Size        nxids = 0;
    Size        i = 0;
    TransactionId *workspace;
    SerializedTransactionState *result;
 
    result = (SerializedTransactionState *) start_address;
 
    result->xactIsoLevel = XactIsoLevel;
    result->xactDeferrable = XactDeferrable;
    result->topFullTransactionId = XactTopFullTransactionId;
    result->currentFullTransactionId =
        CurrentTransactionState->fullTransactionId;
    result->currentCommandId = currentCommandId;
 
    /*
     * If we're running in a parallel worker and launching a parallel worker
     * of our own, we can just pass along the information that was passed to
     * us.
     */
    if (nParallelCurrentXids > 0)
    {
        result->nParallelCurrentXids = nParallelCurrentXids;
        memcpy(&result->parallelCurrentXids[0], ParallelCurrentXids,
               nParallelCurrentXids * sizeof(TransactionId));
        return;
    }
 
    /*
     * OK, we need to generate a sorted list of XIDs that our workers should
     * view as current.  First, figure out how many there are.
     */
    for (s = CurrentTransactionState; s != NULL; s = s->parent)
    {
        if (FullTransactionIdIsValid(s->fullTransactionId))
            nxids = add_size(nxids, 1);
        nxids = add_size(nxids, s->nChildXids);
    }
    Assert(SerializedTransactionStateHeaderSize + nxids * sizeof(TransactionId)
           <= maxsize);
 
    /* Copy them to our scratch space. */
    workspace = palloc(nxids * sizeof(TransactionId));
    for (s = CurrentTransactionState; s != NULL; s = s->parent)
    {
        if (FullTransactionIdIsValid(s->fullTransactionId))
            workspace[i++] = XidFromFullTransactionId(s->fullTransactionId);
        if (s->nChildXids > 0)
            memcpy(&workspace[i], s->childXids,
                   s->nChildXids * sizeof(TransactionId));
        i += s->nChildXids;
    }
    Assert(i == nxids);
 
    /* Sort them. */
    qsort(workspace, nxids, sizeof(TransactionId), xidComparator);
 
    /* Copy data into output area. */
    result->nParallelCurrentXids = nxids;
    memcpy(&result->parallelCurrentXids[0], workspace,
           nxids * sizeof(TransactionId));
}
 
/*
 * StartParallelWorkerTransaction
 *      Start a parallel worker transaction, restoring the relevant
 *      transaction state serialized by SerializeTransactionState.
 */
void
StartParallelWorkerTransaction(char *tstatespace)
{
    SerializedTransactionState *tstate;
 
    Assert(CurrentTransactionState->blockState == TBLOCK_DEFAULT);
    StartTransaction();
 
    tstate = (SerializedTransactionState *) tstatespace;
    XactIsoLevel = tstate->xactIsoLevel;
    XactDeferrable = tstate->xactDeferrable;
    XactTopFullTransactionId = tstate->topFullTransactionId;
    CurrentTransactionState->fullTransactionId =
        tstate->currentFullTransactionId;
    currentCommandId = tstate->currentCommandId;
    nParallelCurrentXids = tstate->nParallelCurrentXids;
    ParallelCurrentXids = &tstate->parallelCurrentXids[0];
 
    CurrentTransactionState->blockState = TBLOCK_PARALLEL_INPROGRESS;
}
 
/*
 * EndParallelWorkerTransaction
 *      End a parallel worker transaction.
 */
void
EndParallelWorkerTransaction(void)
{
    Assert(CurrentTransactionState->blockState == TBLOCK_PARALLEL_INPROGRESS);
    CommitTransaction();
    CurrentTransactionState->blockState = TBLOCK_DEFAULT;
}
 
/*
 * ShowTransactionState
 *      Debug support
 */
static void
ShowTransactionState(const char *str)
{
    /* skip work if message will definitely not be printed */
    if (message_level_is_interesting(DEBUG5))
        ShowTransactionStateRec(str, CurrentTransactionState);
}
 
/*
 * ShowTransactionStateRec
 *      Recursive subroutine for ShowTransactionState
 */
static void
ShowTransactionStateRec(const char *str, TransactionState s)
{
    StringInfoData buf;
 
    if (s->parent)
    {
        /*
         * Since this function recurses, it could be driven to stack overflow.
         * This is just a debugging aid, so we can leave out some details
         * instead of erroring out with check_stack_depth().
         */
        if (stack_is_too_deep())
            ereport(DEBUG5,
                    (errmsg_internal("%s(%d): parent omitted to avoid stack overflow",
                                     str, s->nestingLevel)));
        else
            ShowTransactionStateRec(str, s->parent);
    }
 
    initStringInfo(&buf);
    if (s->nChildXids > 0)
    {
        int         i;
 
        appendStringInfo(&buf, ", children: %u", s->childXids[0]);
        for (i = 1; i < s->nChildXids; i++)
            appendStringInfo(&buf, " %u", s->childXids[i]);
    }
    ereport(DEBUG5,
            (errmsg_internal("%s(%d) name: %s; blockState: %s; state: %s, xid/subid/cid: %u/%u/%u%s%s",
                             str, s->nestingLevel,
                             s->name ? s->name : "unnamed",
                             BlockStateAsString(s->blockState),
                             TransStateAsString(s->state),
                             XidFromFullTransactionId(s->fullTransactionId),
                             s->subTransactionId,
                             currentCommandId,
                             currentCommandIdUsed ? " (used)" : "",
                             buf.data)));
    pfree(buf.data);
}
 
/*
 * BlockStateAsString
 *      Debug support
 */
static const char *
BlockStateAsString(TBlockState blockState)
{
    switch (blockState)
    {
        case TBLOCK_DEFAULT:
            return "DEFAULT";
        case TBLOCK_STARTED:
            return "STARTED";
        case TBLOCK_BEGIN:
            return "BEGIN";
        case TBLOCK_INPROGRESS:
            return "INPROGRESS";
        case TBLOCK_IMPLICIT_INPROGRESS:
            return "IMPLICIT_INPROGRESS";
        case TBLOCK_PARALLEL_INPROGRESS:
            return "PARALLEL_INPROGRESS";
        case TBLOCK_END:
            return "END";
        case TBLOCK_ABORT:
            return "ABORT";
        case TBLOCK_ABORT_END:
            return "ABORT_END";
        case TBLOCK_ABORT_PENDING:
            return "ABORT_PENDING";
        case TBLOCK_PREPARE:
            return "PREPARE";
        case TBLOCK_SUBBEGIN:
            return "SUBBEGIN";
        case TBLOCK_SUBINPROGRESS:
            return "SUBINPROGRESS";
        case TBLOCK_SUBRELEASE:
            return "SUBRELEASE";
        case TBLOCK_SUBCOMMIT:
            return "SUBCOMMIT";
        case TBLOCK_SUBABORT:
            return "SUBABORT";
        case TBLOCK_SUBABORT_END:
            return "SUBABORT_END";
        case TBLOCK_SUBABORT_PENDING:
            return "SUBABORT_PENDING";
        case TBLOCK_SUBRESTART:
            return "SUBRESTART";
        case TBLOCK_SUBABORT_RESTART:
            return "SUBABORT_RESTART";
    }
    return "UNRECOGNIZED";
}
 
/*
 * TransStateAsString
 *      Debug support
 */
static const char *
TransStateAsString(TransState state)
{
    switch (state)
    {
        case TRANS_DEFAULT:
            return "DEFAULT";
        case TRANS_START:
            return "START";
        case TRANS_INPROGRESS:
            return "INPROGRESS";
        case TRANS_COMMIT:
            return "COMMIT";
        case TRANS_ABORT:
            return "ABORT";
        case TRANS_PREPARE:
            return "PREPARE";
    }
    return "UNRECOGNIZED";
}
 
/*
 * xactGetCommittedChildren
 *
 * Gets the list of committed children of the current transaction.  The return
 * value is the number of child transactions.  *ptr is set to point to an
 * array of TransactionIds.  The array is allocated in TopTransactionContext;
 * the caller should *not* pfree() it (this is a change from pre-8.4 code!).
 * If there are no subxacts, *ptr is set to NULL.
 */
int
xactGetCommittedChildren(TransactionId **ptr)
{
    TransactionState s = CurrentTransactionState;
 
    if (s->nChildXids == 0)
        *ptr = NULL;
    else
        *ptr = s->childXids;
 
    return s->nChildXids;
}
 
/*
 *  XLOG support routines
 */
 
 
/*
 * Log the commit record for a plain or twophase transaction commit.
 *
 * A 2pc commit will be emitted when twophase_xid is valid, a plain one
 * otherwise.
 */
XLogRecPtr
XactLogCommitRecord(TimestampTz commit_time,
                    int nsubxacts, TransactionId *subxacts,
                    int nrels, RelFileLocator *rels,
                    int ndroppedstats, xl_xact_stats_item *droppedstats,
                    int nmsgs, SharedInvalidationMessage *msgs,
                    bool relcacheInval,
                    int xactflags, TransactionId twophase_xid,
                    const char *twophase_gid)
{
    xl_xact_commit xlrec;
    xl_xact_xinfo xl_xinfo;
    xl_xact_dbinfo xl_dbinfo;
    xl_xact_subxacts xl_subxacts;
    xl_xact_relfilelocators xl_relfilelocators;
    xl_xact_stats_items xl_dropped_stats;
    xl_xact_invals xl_invals;
    xl_xact_twophase xl_twophase;
    xl_xact_origin xl_origin;
    uint8       info;
 
    Assert(CritSectionCount > 0);
 
    xl_xinfo.xinfo = 0;
 
    /* decide between a plain and 2pc commit */
    if (!TransactionIdIsValid(twophase_xid))
        info = XLOG_XACT_COMMIT;
    else
        info = XLOG_XACT_COMMIT_PREPARED;
 
    /* First figure out and collect all the information needed */
 
    xlrec.xact_time = commit_time;
 
    if (relcacheInval)
        xl_xinfo.xinfo |= XACT_COMPLETION_UPDATE_RELCACHE_FILE;
    if (forceSyncCommit)
        xl_xinfo.xinfo |= XACT_COMPLETION_FORCE_SYNC_COMMIT;
    if ((xactflags & XACT_FLAGS_ACQUIREDACCESSEXCLUSIVELOCK))
        xl_xinfo.xinfo |= XACT_XINFO_HAS_AE_LOCKS;
 
    /*
     * Check if the caller would like to ask standbys for immediate feedback
     * once this commit is applied.
     */
    if (synchronous_commit >= SYNCHRONOUS_COMMIT_REMOTE_APPLY)
        xl_xinfo.xinfo |= XACT_COMPLETION_APPLY_FEEDBACK;
 
    /*
     * Relcache invalidations requires information about the current database
     * and so does logical decoding.
     */
    if (nmsgs > 0 || XLogLogicalInfoActive())
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_DBINFO;
        xl_dbinfo.dbId = MyDatabaseId;
        xl_dbinfo.tsId = MyDatabaseTableSpace;
    }
 
    if (nsubxacts > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_SUBXACTS;
        xl_subxacts.nsubxacts = nsubxacts;
    }
 
    if (nrels > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_RELFILELOCATORS;
        xl_relfilelocators.nrels = nrels;
        info |= XLR_SPECIAL_REL_UPDATE;
    }
 
    if (ndroppedstats > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_DROPPED_STATS;
        xl_dropped_stats.nitems = ndroppedstats;
    }
 
    if (nmsgs > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_INVALS;
        xl_invals.nmsgs = nmsgs;
    }
 
    if (TransactionIdIsValid(twophase_xid))
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_TWOPHASE;
        xl_twophase.xid = twophase_xid;
        Assert(twophase_gid != NULL);
 
        if (XLogLogicalInfoActive())
            xl_xinfo.xinfo |= XACT_XINFO_HAS_GID;
    }
 
    /* dump transaction origin information */
    if (replorigin_xact_state.origin != InvalidReplOriginId)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_ORIGIN;
 
        xl_origin.origin_lsn = replorigin_xact_state.origin_lsn;
        xl_origin.origin_timestamp = replorigin_xact_state.origin_timestamp;
    }
 
    if (xl_xinfo.xinfo != 0)
        info |= XLOG_XACT_HAS_INFO;
 
    /* Then include all the collected data into the commit record. */
 
    XLogBeginInsert();
 
    XLogRegisterData(&xlrec, sizeof(xl_xact_commit));
 
    if (xl_xinfo.xinfo != 0)
        XLogRegisterData(&xl_xinfo.xinfo, sizeof(xl_xinfo.xinfo));
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_DBINFO)
        XLogRegisterData(&xl_dbinfo, sizeof(xl_dbinfo));
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_SUBXACTS)
    {
        XLogRegisterData(&xl_subxacts,
                         MinSizeOfXactSubxacts);
        XLogRegisterData(subxacts,
                         nsubxacts * sizeof(TransactionId));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_RELFILELOCATORS)
    {
        XLogRegisterData(&xl_relfilelocators,
                         MinSizeOfXactRelfileLocators);
        XLogRegisterData(rels,
                         nrels * sizeof(RelFileLocator));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_DROPPED_STATS)
    {
        XLogRegisterData(&xl_dropped_stats,
                         MinSizeOfXactStatsItems);
        XLogRegisterData(droppedstats,
                         ndroppedstats * sizeof(xl_xact_stats_item));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_INVALS)
    {
        XLogRegisterData(&xl_invals, MinSizeOfXactInvals);
        XLogRegisterData(msgs,
                         nmsgs * sizeof(SharedInvalidationMessage));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_TWOPHASE)
    {
        XLogRegisterData(&xl_twophase, sizeof(xl_xact_twophase));
        if (xl_xinfo.xinfo & XACT_XINFO_HAS_GID)
            XLogRegisterData(twophase_gid, strlen(twophase_gid) + 1);
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_ORIGIN)
        XLogRegisterData(&xl_origin, sizeof(xl_xact_origin));
 
    /* we allow filtering by xacts */
    XLogSetRecordFlags(XLOG_INCLUDE_ORIGIN);
 
    return XLogInsert(RM_XACT_ID, info);
}
 
/*
 * Log the commit record for a plain or twophase transaction abort.
 *
 * A 2pc abort will be emitted when twophase_xid is valid, a plain one
 * otherwise.
 */
XLogRecPtr
XactLogAbortRecord(TimestampTz abort_time,
                   int nsubxacts, TransactionId *subxacts,
                   int nrels, RelFileLocator *rels,
                   int ndroppedstats, xl_xact_stats_item *droppedstats,
                   int xactflags, TransactionId twophase_xid,
                   const char *twophase_gid)
{
    xl_xact_abort xlrec;
    xl_xact_xinfo xl_xinfo;
    xl_xact_subxacts xl_subxacts;
    xl_xact_relfilelocators xl_relfilelocators;
    xl_xact_stats_items xl_dropped_stats;
    xl_xact_twophase xl_twophase;
    xl_xact_dbinfo xl_dbinfo;
    xl_xact_origin xl_origin;
 
    uint8       info;
 
    Assert(CritSectionCount > 0);
 
    xl_xinfo.xinfo = 0;
 
    /* decide between a plain and 2pc abort */
    if (!TransactionIdIsValid(twophase_xid))
        info = XLOG_XACT_ABORT;
    else
        info = XLOG_XACT_ABORT_PREPARED;
 
 
    /* First figure out and collect all the information needed */
 
    xlrec.xact_time = abort_time;
 
    if ((xactflags & XACT_FLAGS_ACQUIREDACCESSEXCLUSIVELOCK))
        xl_xinfo.xinfo |= XACT_XINFO_HAS_AE_LOCKS;
 
    if (nsubxacts > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_SUBXACTS;
        xl_subxacts.nsubxacts = nsubxacts;
    }
 
    if (nrels > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_RELFILELOCATORS;
        xl_relfilelocators.nrels = nrels;
        info |= XLR_SPECIAL_REL_UPDATE;
    }
 
    if (ndroppedstats > 0)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_DROPPED_STATS;
        xl_dropped_stats.nitems = ndroppedstats;
    }
 
    if (TransactionIdIsValid(twophase_xid))
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_TWOPHASE;
        xl_twophase.xid = twophase_xid;
        Assert(twophase_gid != NULL);
 
        if (XLogLogicalInfoActive())
            xl_xinfo.xinfo |= XACT_XINFO_HAS_GID;
    }
 
    if (TransactionIdIsValid(twophase_xid) && XLogLogicalInfoActive())
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_DBINFO;
        xl_dbinfo.dbId = MyDatabaseId;
        xl_dbinfo.tsId = MyDatabaseTableSpace;
    }
 
    /*
     * Dump transaction origin information. We need this during recovery to
     * update the replication origin progress.
     */
    if (replorigin_xact_state.origin != InvalidReplOriginId)
    {
        xl_xinfo.xinfo |= XACT_XINFO_HAS_ORIGIN;
 
        xl_origin.origin_lsn = replorigin_xact_state.origin_lsn;
        xl_origin.origin_timestamp = replorigin_xact_state.origin_timestamp;
    }
 
    if (xl_xinfo.xinfo != 0)
        info |= XLOG_XACT_HAS_INFO;
 
    /* Then include all the collected data into the abort record. */
 
    XLogBeginInsert();
 
    XLogRegisterData(&xlrec, MinSizeOfXactAbort);
 
    if (xl_xinfo.xinfo != 0)
        XLogRegisterData(&xl_xinfo, sizeof(xl_xinfo));
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_DBINFO)
        XLogRegisterData(&xl_dbinfo, sizeof(xl_dbinfo));
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_SUBXACTS)
    {
        XLogRegisterData(&xl_subxacts,
                         MinSizeOfXactSubxacts);
        XLogRegisterData(subxacts,
                         nsubxacts * sizeof(TransactionId));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_RELFILELOCATORS)
    {
        XLogRegisterData(&xl_relfilelocators,
                         MinSizeOfXactRelfileLocators);
        XLogRegisterData(rels,
                         nrels * sizeof(RelFileLocator));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_DROPPED_STATS)
    {
        XLogRegisterData(&xl_dropped_stats,
                         MinSizeOfXactStatsItems);
        XLogRegisterData(droppedstats,
                         ndroppedstats * sizeof(xl_xact_stats_item));
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_TWOPHASE)
    {
        XLogRegisterData(&xl_twophase, sizeof(xl_xact_twophase));
        if (xl_xinfo.xinfo & XACT_XINFO_HAS_GID)
            XLogRegisterData(twophase_gid, strlen(twophase_gid) + 1);
    }
 
    if (xl_xinfo.xinfo & XACT_XINFO_HAS_ORIGIN)
        XLogRegisterData(&xl_origin, sizeof(xl_xact_origin));
 
    /* Include the replication origin */
    XLogSetRecordFlags(XLOG_INCLUDE_ORIGIN);
 
    return XLogInsert(RM_XACT_ID, info);
}
 
/*
 * Before 9.0 this was a fairly short function, but now it performs many
 * actions for which the order of execution is critical.
 */
static void
xact_redo_commit(xl_xact_parsed_commit *parsed,
                 TransactionId xid,
                 XLogRecPtr lsn,
                 ReplOriginId origin_id)
{
    TransactionId max_xid;
    TimestampTz commit_time;
 
    Assert(TransactionIdIsValid(xid));
 
    max_xid = TransactionIdLatest(xid, parsed->nsubxacts, parsed->subxacts);
 
    /* Make sure nextXid is beyond any XID mentioned in the record. */
    AdvanceNextFullTransactionIdPastXid(max_xid);
 
    Assert(((parsed->xinfo & XACT_XINFO_HAS_ORIGIN) == 0) ==
           (origin_id == InvalidReplOriginId));
 
    if (parsed->xinfo & XACT_XINFO_HAS_ORIGIN)
        commit_time = parsed->origin_timestamp;
    else
        commit_time = parsed->xact_time;
 
    /* Set the transaction commit timestamp and metadata */
    TransactionTreeSetCommitTsData(xid, parsed->nsubxacts, parsed->subxacts,
                                   commit_time, origin_id);
 
    if (standbyState == STANDBY_DISABLED)
    {
        /*
         * Mark the transaction committed in pg_xact.
         */
        TransactionIdCommitTree(xid, parsed->nsubxacts, parsed->subxacts);
    }
    else
    {
        /*
         * If a transaction completion record arrives that has as-yet
         * unobserved subtransactions then this will not have been fully
         * handled by the call to RecordKnownAssignedTransactionIds() in the
         * main recovery loop in xlog.c. So we need to do bookkeeping again to
         * cover that case. This is confusing and it is easy to think this
         * call is irrelevant, which has happened three times in development
         * already. Leave it in.
         */
        RecordKnownAssignedTransactionIds(max_xid);
 
        /*
         * Mark the transaction committed in pg_xact. We use async commit
         * protocol during recovery to provide information on database
         * consistency for when users try to set hint bits. It is important
         * that we do not set hint bits until the minRecoveryPoint is past
         * this commit record. This ensures that if we crash we don't see hint
         * bits set on changes made by transactions that haven't yet
         * recovered. It's unlikely but it's good to be safe.
         */
        TransactionIdAsyncCommitTree(xid, parsed->nsubxacts, parsed->subxacts, lsn);
 
        /*
         * We must mark clog before we update the ProcArray.
         */
        ExpireTreeKnownAssignedTransactionIds(xid, parsed->nsubxacts, parsed->subxacts, max_xid);
 
        /*
         * Send any cache invalidations attached to the commit. We must
         * maintain the same order of invalidation then release locks as
         * occurs in CommitTransaction().
         */
        ProcessCommittedInvalidationMessages(parsed->msgs, parsed->nmsgs,
                                             XactCompletionRelcacheInitFileInval(parsed->xinfo),
                                             parsed->dbId, parsed->tsId);
 
        /*
         * Release locks, if any. We do this for both two phase and normal one
         * phase transactions. In effect we are ignoring the prepare phase and
         * just going straight to lock release.
         */
        if (parsed->xinfo & XACT_XINFO_HAS_AE_LOCKS)
            StandbyReleaseLockTree(xid, parsed->nsubxacts, parsed->subxacts);
    }
 
    if (parsed->xinfo & XACT_XINFO_HAS_ORIGIN)
    {
        /* recover apply progress */
        replorigin_advance(origin_id, parsed->origin_lsn, lsn,
                           false /* backward */ , false /* WAL */ );
    }
 
    /* Make sure files supposed to be dropped are dropped */
    if (parsed->nrels > 0)
    {
        /*
         * First update minimum recovery point to cover this WAL record. Once
         * a relation is deleted, there's no going back. The buffer manager
         * enforces the WAL-first rule for normal updates to relation files,
         * so that the minimum recovery point is always updated before the
         * corresponding change in the data file is flushed to disk, but we
         * have to do the same here since we're bypassing the buffer manager.
         *
         * Doing this before deleting the files means that if a deletion fails
         * for some reason, you cannot start up the system even after restart,
         * until you fix the underlying situation so that the deletion will
         * succeed. Alternatively, we could update the minimum recovery point
         * after deletion, but that would leave a small window where the
         * WAL-first rule would be violated.
         */
        XLogFlush(lsn);
 
        /* Make sure files supposed to be dropped are dropped */
        DropRelationFiles(parsed->xlocators, parsed->nrels, true);
    }
 
    if (parsed->nstats > 0)
    {
        /* see equivalent call for relations above */
        XLogFlush(lsn);
 
        pgstat_execute_transactional_drops(parsed->nstats, parsed->stats, true);
    }
 
    /*
     * We issue an XLogFlush() for the same reason we emit ForceSyncCommit()
     * in normal operation. For example, in CREATE DATABASE, we copy all files
     * from the template database, and then commit the transaction. If we
     * crash after all the files have been copied but before the commit, you
     * have files in the data directory without an entry in pg_database. To
     * minimize the window for that, we use ForceSyncCommit() to rush the
     * commit record to disk as quick as possible. We have the same window
     * during recovery, and forcing an XLogFlush() (which updates
     * minRecoveryPoint during recovery) helps to reduce that problem window,
     * for any user that requested ForceSyncCommit().
     */
    if (XactCompletionForceSyncCommit(parsed->xinfo))
        XLogFlush(lsn);
 
    /*
     * If asked by the primary (because someone is waiting for a synchronous
     * commit = remote_apply), we will need to ask walreceiver to send a reply
     * immediately.
     */
    if (XactCompletionApplyFeedback(parsed->xinfo))
        XLogRequestWalReceiverReply();
}
 
/*
 * Be careful with the order of execution, as with xact_redo_commit().
 * The two functions are similar but differ in key places.
 *
 * Note also that an abort can be for a subtransaction and its children,
 * not just for a top level abort. That means we have to consider
 * topxid != xid, whereas in commit we would find topxid == xid always
 * because subtransaction commit is never WAL logged.
 */
static void
xact_redo_abort(xl_xact_parsed_abort *parsed, TransactionId xid,
                XLogRecPtr lsn, ReplOriginId origin_id)
{
    TransactionId max_xid;
 
    Assert(TransactionIdIsValid(xid));
 
    /* Make sure nextXid is beyond any XID mentioned in the record. */
    max_xid = TransactionIdLatest(xid,
                                  parsed->nsubxacts,
                                  parsed->subxacts);
    AdvanceNextFullTransactionIdPastXid(max_xid);
 
    if (standbyState == STANDBY_DISABLED)
    {
        /* Mark the transaction aborted in pg_xact, no need for async stuff */
        TransactionIdAbortTree(xid, parsed->nsubxacts, parsed->subxacts);
    }
    else
    {
        /*
         * If a transaction completion record arrives that has as-yet
         * unobserved subtransactions then this will not have been fully
         * handled by the call to RecordKnownAssignedTransactionIds() in the
         * main recovery loop in xlog.c. So we need to do bookkeeping again to
         * cover that case. This is confusing and it is easy to think this
         * call is irrelevant, which has happened three times in development
         * already. Leave it in.
         */
        RecordKnownAssignedTransactionIds(max_xid);
 
        /* Mark the transaction aborted in pg_xact, no need for async stuff */
        TransactionIdAbortTree(xid, parsed->nsubxacts, parsed->subxacts);
 
        /*
         * We must update the ProcArray after we have marked clog.
         */
        ExpireTreeKnownAssignedTransactionIds(xid, parsed->nsubxacts, parsed->subxacts, max_xid);
 
        /*
         * There are no invalidation messages to send or undo.
         */
 
        /*
         * Release locks, if any. There are no invalidations to send.
         */
        if (parsed->xinfo & XACT_XINFO_HAS_AE_LOCKS)
            StandbyReleaseLockTree(xid, parsed->nsubxacts, parsed->subxacts);
    }
 
    if (parsed->xinfo & XACT_XINFO_HAS_ORIGIN)
    {
        /* recover apply progress */
        replorigin_advance(origin_id, parsed->origin_lsn, lsn,
                           false /* backward */ , false /* WAL */ );
    }
 
    /* Make sure files supposed to be dropped are dropped */
    if (parsed->nrels > 0)
    {
        /*
         * See comments about update of minimum recovery point on truncation,
         * in xact_redo_commit().
         */
        XLogFlush(lsn);
 
        DropRelationFiles(parsed->xlocators, parsed->nrels, true);
    }
 
    if (parsed->nstats > 0)
    {
        /* see equivalent call for relations above */
        XLogFlush(lsn);
 
        pgstat_execute_transactional_drops(parsed->nstats, parsed->stats, true);
    }
}
 
void
xact_redo(XLogReaderState *record)
{
    uint8       info = XLogRecGetInfo(record) & XLOG_XACT_OPMASK;
 
    /* Backup blocks are not used in xact records */
    Assert(!XLogRecHasAnyBlockRefs(record));
 
    if (info == XLOG_XACT_COMMIT)
    {
        xl_xact_commit *xlrec = (xl_xact_commit *) XLogRecGetData(record);
        xl_xact_parsed_commit parsed;
 
        ParseCommitRecord(XLogRecGetInfo(record), xlrec, &parsed);
        xact_redo_commit(&parsed, XLogRecGetXid(record),
                         record->EndRecPtr, XLogRecGetOrigin(record));
    }
    else if (info == XLOG_XACT_COMMIT_PREPARED)
    {
        xl_xact_commit *xlrec = (xl_xact_commit *) XLogRecGetData(record);
        xl_xact_parsed_commit parsed;
 
        ParseCommitRecord(XLogRecGetInfo(record), xlrec, &parsed);
        xact_redo_commit(&parsed, parsed.twophase_xid,
                         record->EndRecPtr, XLogRecGetOrigin(record));
 
        /* Delete TwoPhaseState gxact entry and/or 2PC file. */
        LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
        PrepareRedoRemove(parsed.twophase_xid, false);
        LWLockRelease(TwoPhaseStateLock);
    }
    else if (info == XLOG_XACT_ABORT)
    {
        xl_xact_abort *xlrec = (xl_xact_abort *) XLogRecGetData(record);
        xl_xact_parsed_abort parsed;
 
        ParseAbortRecord(XLogRecGetInfo(record), xlrec, &parsed);
        xact_redo_abort(&parsed, XLogRecGetXid(record),
                        record->EndRecPtr, XLogRecGetOrigin(record));
    }
    else if (info == XLOG_XACT_ABORT_PREPARED)
    {
        xl_xact_abort *xlrec = (xl_xact_abort *) XLogRecGetData(record);
        xl_xact_parsed_abort parsed;
 
        ParseAbortRecord(XLogRecGetInfo(record), xlrec, &parsed);
        xact_redo_abort(&parsed, parsed.twophase_xid,
                        record->EndRecPtr, XLogRecGetOrigin(record));
 
        /* Delete TwoPhaseState gxact entry and/or 2PC file. */
        LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
        PrepareRedoRemove(parsed.twophase_xid, false);
        LWLockRelease(TwoPhaseStateLock);
    }
    else if (info == XLOG_XACT_PREPARE)
    {
        /*
         * Store xid and start/end pointers of the WAL record in TwoPhaseState
         * gxact entry.
         */
        LWLockAcquire(TwoPhaseStateLock, LW_EXCLUSIVE);
        PrepareRedoAdd(InvalidFullTransactionId,
                       XLogRecGetData(record),
                       record->ReadRecPtr,
                       record->EndRecPtr,
                       XLogRecGetOrigin(record));
        LWLockRelease(TwoPhaseStateLock);
    }
    else if (info == XLOG_XACT_ASSIGNMENT)
    {
        xl_xact_assignment *xlrec = (xl_xact_assignment *) XLogRecGetData(record);
 
        if (standbyState >= STANDBY_INITIALIZED)
            ProcArrayApplyXidAssignment(xlrec->xtop,
                                        xlrec->nsubxacts, xlrec->xsub);
    }
    else if (info == XLOG_XACT_INVALIDATIONS)
    {
        /*
         * XXX we do ignore this for now, what matters are invalidations
         * written into the commit record.
         */
    }
    else
        elog(PANIC, "xact_redo: unknown op code %u", info);
}