syncrep.c

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/*-------------------------------------------------------------------------
 *
 * syncrep.c
 *
 * Synchronous replication is new as of PostgreSQL 9.1.
 *
 * If requested, transaction commits wait until their commit LSN are
 * acknowledged by the synchronous standbys.
 *
 * This module contains the code for waiting and release of backends.
 * All code in this module executes on the primary. The core streaming
 * replication transport remains within WALreceiver/WALsender modules.
 *
 * The essence of this design is that it isolates all logic about
 * waiting/releasing onto the primary. The primary defines which standbys
 * it wishes to wait for. The standbys are completely unaware of the
 * durability requirements of transactions on the primary, reducing the
 * complexity of the code and streamlining both standby operations and
 * network bandwidth because there is no requirement to ship
 * per-transaction state information.
 *
 * Replication is either synchronous or not synchronous (async). If it is
 * async, we just fastpath out of here. If it is sync, then we wait for
 * the write, flush or apply location on the standby before releasing
 * the waiting backend. Further complexity in that interaction is
 * expected in later releases.
 *
 * The best performing way to manage the waiting backends is to have a
 * single ordered queue of waiting backends, so that we can avoid
 * searching the through all waiters each time we receive a reply.
 *
 * In 9.5 or before only a single standby could be considered as
 * synchronous. In 9.6 we support a priority-based multiple synchronous
 * standbys. In 10.0 a quorum-based multiple synchronous standbys is also
 * supported. The number of synchronous standbys that transactions
 * must wait for replies from is specified in synchronous_standby_names.
 * This parameter also specifies a list of standby names and the method
 * (FIRST and ANY) to choose synchronous standbys from the listed ones.
 *
 * The method FIRST specifies a priority-based synchronous replication
 * and makes transaction commits wait until their WAL records are
 * replicated to the requested number of synchronous standbys chosen based
 * on their priorities. The standbys whose names appear earlier in the list
 * are given higher priority and will be considered as synchronous.
 * Other standby servers appearing later in this list represent potential
 * synchronous standbys. If any of the current synchronous standbys
 * disconnects for whatever reason, it will be replaced immediately with
 * the next-highest-priority standby.
 *
 * The method ANY specifies a quorum-based synchronous replication
 * and makes transaction commits wait until their WAL records are
 * replicated to at least the requested number of synchronous standbys
 * in the list. All the standbys appearing in the list are considered as
 * candidates for quorum synchronous standbys.
 *
 * If neither FIRST nor ANY is specified, FIRST is used as the method.
 * This is for backward compatibility with 9.6 or before where only a
 * priority-based sync replication was supported.
 *
 * Before the standbys chosen from synchronous_standby_names can
 * become the synchronous standbys they must have caught up with
 * the primary; that may take some time. Once caught up,
 * the standbys which are considered as synchronous at that moment
 * will release waiters from the queue.
 *
 * Portions Copyright (c) 2010-2025, PostgreSQL Global Development Group
 *
 * IDENTIFICATION
 *    src/backend/replication/syncrep.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"
 
#include <unistd.h>
 
#include "access/xact.h"
#include "common/int.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "replication/syncrep.h"
#include "replication/walsender.h"
#include "replication/walsender_private.h"
#include "storage/proc.h"
#include "tcop/tcopprot.h"
#include "utils/guc_hooks.h"
#include "utils/ps_status.h"
 
/* User-settable parameters for sync rep */
char       *SyncRepStandbyNames;
 
#define SyncStandbysDefined() \
    (SyncRepStandbyNames != NULL && SyncRepStandbyNames[0] != '\0')
 
static bool announce_next_takeover = true;
 
SyncRepConfigData *SyncRepConfig = NULL;
static int  SyncRepWaitMode = SYNC_REP_NO_WAIT;
 
static void SyncRepQueueInsert(int mode);
static void SyncRepCancelWait(void);
static int  SyncRepWakeQueue(bool all, int mode);
 
static bool SyncRepGetSyncRecPtr(XLogRecPtr *writePtr,
                                 XLogRecPtr *flushPtr,
                                 XLogRecPtr *applyPtr,
                                 bool *am_sync);
static void SyncRepGetOldestSyncRecPtr(XLogRecPtr *writePtr,
                                       XLogRecPtr *flushPtr,
                                       XLogRecPtr *applyPtr,
                                       SyncRepStandbyData *sync_standbys,
                                       int num_standbys);
static void SyncRepGetNthLatestSyncRecPtr(XLogRecPtr *writePtr,
                                          XLogRecPtr *flushPtr,
                                          XLogRecPtr *applyPtr,
                                          SyncRepStandbyData *sync_standbys,
                                          int num_standbys,
                                          uint8 nth);
static int  SyncRepGetStandbyPriority(void);
static int  standby_priority_comparator(const void *a, const void *b);
static int  cmp_lsn(const void *a, const void *b);
 
#ifdef USE_ASSERT_CHECKING
static bool SyncRepQueueIsOrderedByLSN(int mode);
#endif
 
/*
 * ===========================================================
 * Synchronous Replication functions for normal user backends
 * ===========================================================
 */
 
/*
 * Wait for synchronous replication, if requested by user.
 *
 * Initially backends start in state SYNC_REP_NOT_WAITING and then
 * change that state to SYNC_REP_WAITING before adding ourselves
 * to the wait queue. During SyncRepWakeQueue() a WALSender changes
 * the state to SYNC_REP_WAIT_COMPLETE once replication is confirmed.
 * This backend then resets its state to SYNC_REP_NOT_WAITING.
 *
 * 'lsn' represents the LSN to wait for.  'commit' indicates whether this LSN
 * represents a commit record.  If it doesn't, then we wait only for the WAL
 * to be flushed if synchronous_commit is set to the higher level of
 * remote_apply, because only commit records provide apply feedback.
 */
void
SyncRepWaitForLSN(XLogRecPtr lsn, bool commit)
{
    int         mode;
 
    /*
     * This should be called while holding interrupts during a transaction
     * commit to prevent the follow-up shared memory queue cleanups to be
     * influenced by external interruptions.
     */
    Assert(InterruptHoldoffCount > 0);
 
    /*
     * Fast exit if user has not requested sync replication, or there are no
     * sync replication standby names defined.
     *
     * Since this routine gets called every commit time, it's important to
     * exit quickly if sync replication is not requested.
     *
     * We check WalSndCtl->sync_standbys_status flag without the lock and exit
     * immediately if SYNC_STANDBY_INIT is set (the checkpointer has
     * initialized this data) but SYNC_STANDBY_DEFINED is missing (no sync
     * replication requested).
     *
     * If SYNC_STANDBY_DEFINED is set, we need to check the status again later
     * while holding the lock, to check the flag and operate the sync rep
     * queue atomically.  This is necessary to avoid the race condition
     * described in SyncRepUpdateSyncStandbysDefined().  On the other hand, if
     * SYNC_STANDBY_DEFINED is not set, the lock is not necessary because we
     * don't touch the queue.
     */
    if (!SyncRepRequested() ||
        ((((volatile WalSndCtlData *) WalSndCtl)->sync_standbys_status) &
         (SYNC_STANDBY_INIT | SYNC_STANDBY_DEFINED)) == SYNC_STANDBY_INIT)
        return;
 
    /* Cap the level for anything other than commit to remote flush only. */
    if (commit)
        mode = SyncRepWaitMode;
    else
        mode = Min(SyncRepWaitMode, SYNC_REP_WAIT_FLUSH);
 
    Assert(dlist_node_is_detached(&MyProc->syncRepLinks));
    Assert(WalSndCtl != NULL);
 
    LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
    Assert(MyProc->syncRepState == SYNC_REP_NOT_WAITING);
 
    /*
     * We don't wait for sync rep if SYNC_STANDBY_DEFINED is not set.  See
     * SyncRepUpdateSyncStandbysDefined().
     *
     * Also check that the standby hasn't already replied. Unlikely race
     * condition but we'll be fetching that cache line anyway so it's likely
     * to be a low cost check.
     *
     * If the sync standby data has not been initialized yet
     * (SYNC_STANDBY_INIT is not set), fall back to a check based on the LSN,
     * then do a direct GUC check.
     */
    if (WalSndCtl->sync_standbys_status & SYNC_STANDBY_INIT)
    {
        if ((WalSndCtl->sync_standbys_status & SYNC_STANDBY_DEFINED) == 0 ||
            lsn <= WalSndCtl->lsn[mode])
        {
            LWLockRelease(SyncRepLock);
            return;
        }
    }
    else if (lsn <= WalSndCtl->lsn[mode])
    {
        /*
         * The LSN is older than what we need to wait for.  The sync standby
         * data has not been initialized yet, but we are OK to not wait
         * because we know that there is no point in doing so based on the
         * LSN.
         */
        LWLockRelease(SyncRepLock);
        return;
    }
    else if (!SyncStandbysDefined())
    {
        /*
         * If we are here, the sync standby data has not been initialized yet,
         * and the LSN is newer than what need to wait for, so we have fallen
         * back to the best thing we could do in this case: a check on
         * SyncStandbysDefined() to see if the GUC is set or not.
         *
         * When the GUC has a value, we wait until the checkpointer updates
         * the status data because we cannot be sure yet if we should wait or
         * not. Here, the GUC has *no* value, we are sure that there is no
         * point to wait; this matters for example when initializing a
         * cluster, where we should never wait, and no sync standbys is the
         * default behavior.
         */
        LWLockRelease(SyncRepLock);
        return;
    }
 
    /*
     * Set our waitLSN so WALSender will know when to wake us, and add
     * ourselves to the queue.
     */
    MyProc->waitLSN = lsn;
    MyProc->syncRepState = SYNC_REP_WAITING;
    SyncRepQueueInsert(mode);
    Assert(SyncRepQueueIsOrderedByLSN(mode));
    LWLockRelease(SyncRepLock);
 
    /* Alter ps display to show waiting for sync rep. */
    if (update_process_title)
    {
        char        buffer[32];
 
        sprintf(buffer, "waiting for %X/%X", LSN_FORMAT_ARGS(lsn));
        set_ps_display_suffix(buffer);
    }
 
    /*
     * Wait for specified LSN to be confirmed.
     *
     * Each proc has its own wait latch, so we perform a normal latch
     * check/wait loop here.
     */
    for (;;)
    {
        int         rc;
 
        /* Must reset the latch before testing state. */
        ResetLatch(MyLatch);
 
        /*
         * Acquiring the lock is not needed, the latch ensures proper
         * barriers. If it looks like we're done, we must really be done,
         * because once walsender changes the state to SYNC_REP_WAIT_COMPLETE,
         * it will never update it again, so we can't be seeing a stale value
         * in that case.
         */
        if (MyProc->syncRepState == SYNC_REP_WAIT_COMPLETE)
            break;
 
        /*
         * If a wait for synchronous replication is pending, we can neither
         * acknowledge the commit nor raise ERROR or FATAL.  The latter would
         * lead the client to believe that the transaction aborted, which is
         * not true: it's already committed locally. The former is no good
         * either: the client has requested synchronous replication, and is
         * entitled to assume that an acknowledged commit is also replicated,
         * which might not be true. So in this case we issue a WARNING (which
         * some clients may be able to interpret) and shut off further output.
         * We do NOT reset ProcDiePending, so that the process will die after
         * the commit is cleaned up.
         */
        if (ProcDiePending)
        {
            ereport(WARNING,
                    (errcode(ERRCODE_ADMIN_SHUTDOWN),
                     errmsg("canceling the wait for synchronous replication and terminating connection due to administrator command"),
                     errdetail("The transaction has already committed locally, but might not have been replicated to the standby.")));
            whereToSendOutput = DestNone;
            SyncRepCancelWait();
            break;
        }
 
        /*
         * It's unclear what to do if a query cancel interrupt arrives.  We
         * can't actually abort at this point, but ignoring the interrupt
         * altogether is not helpful, so we just terminate the wait with a
         * suitable warning.
         */
        if (QueryCancelPending)
        {
            QueryCancelPending = false;
            ereport(WARNING,
                    (errmsg("canceling wait for synchronous replication due to user request"),
                     errdetail("The transaction has already committed locally, but might not have been replicated to the standby.")));
            SyncRepCancelWait();
            break;
        }
 
        /*
         * Wait on latch.  Any condition that should wake us up will set the
         * latch, so no need for timeout.
         */
        rc = WaitLatch(MyLatch, WL_LATCH_SET | WL_POSTMASTER_DEATH, -1,
                       WAIT_EVENT_SYNC_REP);
 
        /*
         * If the postmaster dies, we'll probably never get an acknowledgment,
         * because all the wal sender processes will exit. So just bail out.
         */
        if (rc & WL_POSTMASTER_DEATH)
        {
            ProcDiePending = true;
            whereToSendOutput = DestNone;
            SyncRepCancelWait();
            break;
        }
    }
 
    /*
     * WalSender has checked our LSN and has removed us from queue. Clean up
     * state and leave.  It's OK to reset these shared memory fields without
     * holding SyncRepLock, because any walsenders will ignore us anyway when
     * we're not on the queue.  We need a read barrier to make sure we see the
     * changes to the queue link (this might be unnecessary without
     * assertions, but better safe than sorry).
     */
    pg_read_barrier();
    Assert(dlist_node_is_detached(&MyProc->syncRepLinks));
    MyProc->syncRepState = SYNC_REP_NOT_WAITING;
    MyProc->waitLSN = 0;
 
    /* reset ps display to remove the suffix */
    if (update_process_title)
        set_ps_display_remove_suffix();
}
 
/*
 * Insert MyProc into the specified SyncRepQueue, maintaining sorted invariant.
 *
 * Usually we will go at tail of queue, though it's possible that we arrive
 * here out of order, so start at tail and work back to insertion point.
 */
static void
SyncRepQueueInsert(int mode)
{
    dlist_head *queue;
    dlist_iter  iter;
 
    Assert(mode >= 0 && mode < NUM_SYNC_REP_WAIT_MODE);
    queue = &WalSndCtl->SyncRepQueue[mode];
 
    dlist_reverse_foreach(iter, queue)
    {
        PGPROC     *proc = dlist_container(PGPROC, syncRepLinks, iter.cur);
 
        /*
         * Stop at the queue element that we should insert after to ensure the
         * queue is ordered by LSN.
         */
        if (proc->waitLSN < MyProc->waitLSN)
        {
            dlist_insert_after(&proc->syncRepLinks, &MyProc->syncRepLinks);
            return;
        }
    }
 
    /*
     * If we get here, the list was either empty, or this process needs to be
     * at the head.
     */
    dlist_push_head(queue, &MyProc->syncRepLinks);
}
 
/*
 * Acquire SyncRepLock and cancel any wait currently in progress.
 */
static void
SyncRepCancelWait(void)
{
    LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
    if (!dlist_node_is_detached(&MyProc->syncRepLinks))
        dlist_delete_thoroughly(&MyProc->syncRepLinks);
    MyProc->syncRepState = SYNC_REP_NOT_WAITING;
    LWLockRelease(SyncRepLock);
}
 
void
SyncRepCleanupAtProcExit(void)
{
    /*
     * First check if we are removed from the queue without the lock to not
     * slow down backend exit.
     */
    if (!dlist_node_is_detached(&MyProc->syncRepLinks))
    {
        LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
 
        /* maybe we have just been removed, so recheck */
        if (!dlist_node_is_detached(&MyProc->syncRepLinks))
            dlist_delete_thoroughly(&MyProc->syncRepLinks);
 
        LWLockRelease(SyncRepLock);
    }
}
 
/*
 * ===========================================================
 * Synchronous Replication functions for wal sender processes
 * ===========================================================
 */
 
/*
 * Take any action required to initialise sync rep state from config
 * data. Called at WALSender startup and after each SIGHUP.
 */
void
SyncRepInitConfig(void)
{
    int         priority;
 
    /*
     * Determine if we are a potential sync standby and remember the result
     * for handling replies from standby.
     */
    priority = SyncRepGetStandbyPriority();
    if (MyWalSnd->sync_standby_priority != priority)
    {
        SpinLockAcquire(&MyWalSnd->mutex);
        MyWalSnd->sync_standby_priority = priority;
        SpinLockRelease(&MyWalSnd->mutex);
 
        ereport(DEBUG1,
                (errmsg_internal("standby \"%s\" now has synchronous standby priority %d",
                                 application_name, priority)));
    }
}
 
/*
 * Update the LSNs on each queue based upon our latest state. This
 * implements a simple policy of first-valid-sync-standby-releases-waiter.
 *
 * Other policies are possible, which would change what we do here and
 * perhaps also which information we store as well.
 */
void
SyncRepReleaseWaiters(void)
{
    volatile WalSndCtlData *walsndctl = WalSndCtl;
    XLogRecPtr  writePtr;
    XLogRecPtr  flushPtr;
    XLogRecPtr  applyPtr;
    bool        got_recptr;
    bool        am_sync;
    int         numwrite = 0;
    int         numflush = 0;
    int         numapply = 0;
 
    /*
     * If this WALSender is serving a standby that is not on the list of
     * potential sync standbys then we have nothing to do. If we are still
     * starting up, still running base backup or the current flush position is
     * still invalid, then leave quickly also.  Streaming or stopping WAL
     * senders are allowed to release waiters.
     */
    if (MyWalSnd->sync_standby_priority == 0 ||
        (MyWalSnd->state != WALSNDSTATE_STREAMING &&
         MyWalSnd->state != WALSNDSTATE_STOPPING) ||
        XLogRecPtrIsInvalid(MyWalSnd->flush))
    {
        announce_next_takeover = true;
        return;
    }
 
    /*
     * We're a potential sync standby. Release waiters if there are enough
     * sync standbys and we are considered as sync.
     */
    LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
 
    /*
     * Check whether we are a sync standby or not, and calculate the synced
     * positions among all sync standbys.  (Note: although this step does not
     * of itself require holding SyncRepLock, it seems like a good idea to do
     * it after acquiring the lock.  This ensures that the WAL pointers we use
     * to release waiters are newer than any previous execution of this
     * routine used.)
     */
    got_recptr = SyncRepGetSyncRecPtr(&writePtr, &flushPtr, &applyPtr, &am_sync);
 
    /*
     * If we are managing a sync standby, though we weren't prior to this,
     * then announce we are now a sync standby.
     */
    if (announce_next_takeover && am_sync)
    {
        announce_next_takeover = false;
 
        if (SyncRepConfig->syncrep_method == SYNC_REP_PRIORITY)
            ereport(LOG,
                    (errmsg("standby \"%s\" is now a synchronous standby with priority %d",
                            application_name, MyWalSnd->sync_standby_priority)));
        else
            ereport(LOG,
                    (errmsg("standby \"%s\" is now a candidate for quorum synchronous standby",
                            application_name)));
    }
 
    /*
     * If the number of sync standbys is less than requested or we aren't
     * managing a sync standby then just leave.
     */
    if (!got_recptr || !am_sync)
    {
        LWLockRelease(SyncRepLock);
        announce_next_takeover = !am_sync;
        return;
    }
 
    /*
     * Set the lsn first so that when we wake backends they will release up to
     * this location.
     */
    if (walsndctl->lsn[SYNC_REP_WAIT_WRITE] < writePtr)
    {
        walsndctl->lsn[SYNC_REP_WAIT_WRITE] = writePtr;
        numwrite = SyncRepWakeQueue(false, SYNC_REP_WAIT_WRITE);
    }
    if (walsndctl->lsn[SYNC_REP_WAIT_FLUSH] < flushPtr)
    {
        walsndctl->lsn[SYNC_REP_WAIT_FLUSH] = flushPtr;
        numflush = SyncRepWakeQueue(false, SYNC_REP_WAIT_FLUSH);
    }
    if (walsndctl->lsn[SYNC_REP_WAIT_APPLY] < applyPtr)
    {
        walsndctl->lsn[SYNC_REP_WAIT_APPLY] = applyPtr;
        numapply = SyncRepWakeQueue(false, SYNC_REP_WAIT_APPLY);
    }
 
    LWLockRelease(SyncRepLock);
 
    elog(DEBUG3, "released %d procs up to write %X/%X, %d procs up to flush %X/%X, %d procs up to apply %X/%X",
         numwrite, LSN_FORMAT_ARGS(writePtr),
         numflush, LSN_FORMAT_ARGS(flushPtr),
         numapply, LSN_FORMAT_ARGS(applyPtr));
}
 
/*
 * Calculate the synced Write, Flush and Apply positions among sync standbys.
 *
 * Return false if the number of sync standbys is less than
 * synchronous_standby_names specifies. Otherwise return true and
 * store the positions into *writePtr, *flushPtr and *applyPtr.
 *
 * On return, *am_sync is set to true if this walsender is connecting to
 * sync standby. Otherwise it's set to false.
 */
static bool
SyncRepGetSyncRecPtr(XLogRecPtr *writePtr, XLogRecPtr *flushPtr,
                     XLogRecPtr *applyPtr, bool *am_sync)
{
    SyncRepStandbyData *sync_standbys;
    int         num_standbys;
    int         i;
 
    /* Initialize default results */
    *writePtr = InvalidXLogRecPtr;
    *flushPtr = InvalidXLogRecPtr;
    *applyPtr = InvalidXLogRecPtr;
    *am_sync = false;
 
    /* Quick out if not even configured to be synchronous */
    if (SyncRepConfig == NULL)
        return false;
 
    /* Get standbys that are considered as synchronous at this moment */
    num_standbys = SyncRepGetCandidateStandbys(&sync_standbys);
 
    /* Am I among the candidate sync standbys? */
    for (i = 0; i < num_standbys; i++)
    {
        if (sync_standbys[i].is_me)
        {
            *am_sync = true;
            break;
        }
    }
 
    /*
     * Nothing more to do if we are not managing a sync standby or there are
     * not enough synchronous standbys.
     */
    if (!(*am_sync) ||
        num_standbys < SyncRepConfig->num_sync)
    {
        pfree(sync_standbys);
        return false;
    }
 
    /*
     * In a priority-based sync replication, the synced positions are the
     * oldest ones among sync standbys. In a quorum-based, they are the Nth
     * latest ones.
     *
     * SyncRepGetNthLatestSyncRecPtr() also can calculate the oldest
     * positions. But we use SyncRepGetOldestSyncRecPtr() for that calculation
     * because it's a bit more efficient.
     *
     * XXX If the numbers of current and requested sync standbys are the same,
     * we can use SyncRepGetOldestSyncRecPtr() to calculate the synced
     * positions even in a quorum-based sync replication.
     */
    if (SyncRepConfig->syncrep_method == SYNC_REP_PRIORITY)
    {
        SyncRepGetOldestSyncRecPtr(writePtr, flushPtr, applyPtr,
                                   sync_standbys, num_standbys);
    }
    else
    {
        SyncRepGetNthLatestSyncRecPtr(writePtr, flushPtr, applyPtr,
                                      sync_standbys, num_standbys,
                                      SyncRepConfig->num_sync);
    }
 
    pfree(sync_standbys);
    return true;
}
 
/*
 * Calculate the oldest Write, Flush and Apply positions among sync standbys.
 */
static void
SyncRepGetOldestSyncRecPtr(XLogRecPtr *writePtr,
                           XLogRecPtr *flushPtr,
                           XLogRecPtr *applyPtr,
                           SyncRepStandbyData *sync_standbys,
                           int num_standbys)
{
    int         i;
 
    /*
     * Scan through all sync standbys and calculate the oldest Write, Flush
     * and Apply positions.  We assume *writePtr et al were initialized to
     * InvalidXLogRecPtr.
     */
    for (i = 0; i < num_standbys; i++)
    {
        XLogRecPtr  write = sync_standbys[i].write;
        XLogRecPtr  flush = sync_standbys[i].flush;
        XLogRecPtr  apply = sync_standbys[i].apply;
 
        if (XLogRecPtrIsInvalid(*writePtr) || *writePtr > write)
            *writePtr = write;
        if (XLogRecPtrIsInvalid(*flushPtr) || *flushPtr > flush)
            *flushPtr = flush;
        if (XLogRecPtrIsInvalid(*applyPtr) || *applyPtr > apply)
            *applyPtr = apply;
    }
}
 
/*
 * Calculate the Nth latest Write, Flush and Apply positions among sync
 * standbys.
 */
static void
SyncRepGetNthLatestSyncRecPtr(XLogRecPtr *writePtr,
                              XLogRecPtr *flushPtr,
                              XLogRecPtr *applyPtr,
                              SyncRepStandbyData *sync_standbys,
                              int num_standbys,
                              uint8 nth)
{
    XLogRecPtr *write_array;
    XLogRecPtr *flush_array;
    XLogRecPtr *apply_array;
    int         i;
 
    /* Should have enough candidates, or somebody messed up */
    Assert(nth > 0 && nth <= num_standbys);
 
    write_array = (XLogRecPtr *) palloc(sizeof(XLogRecPtr) * num_standbys);
    flush_array = (XLogRecPtr *) palloc(sizeof(XLogRecPtr) * num_standbys);
    apply_array = (XLogRecPtr *) palloc(sizeof(XLogRecPtr) * num_standbys);
 
    for (i = 0; i < num_standbys; i++)
    {
        write_array[i] = sync_standbys[i].write;
        flush_array[i] = sync_standbys[i].flush;
        apply_array[i] = sync_standbys[i].apply;
    }
 
    /* Sort each array in descending order */
    qsort(write_array, num_standbys, sizeof(XLogRecPtr), cmp_lsn);
    qsort(flush_array, num_standbys, sizeof(XLogRecPtr), cmp_lsn);
    qsort(apply_array, num_standbys, sizeof(XLogRecPtr), cmp_lsn);
 
    /* Get Nth latest Write, Flush, Apply positions */
    *writePtr = write_array[nth - 1];
    *flushPtr = flush_array[nth - 1];
    *applyPtr = apply_array[nth - 1];
 
    pfree(write_array);
    pfree(flush_array);
    pfree(apply_array);
}
 
/*
 * Compare lsn in order to sort array in descending order.
 */
static int
cmp_lsn(const void *a, const void *b)
{
    XLogRecPtr  lsn1 = *((const XLogRecPtr *) a);
    XLogRecPtr  lsn2 = *((const XLogRecPtr *) b);
 
    return pg_cmp_u64(lsn2, lsn1);
}
 
/*
 * Return data about walsenders that are candidates to be sync standbys.
 *
 * *standbys is set to a palloc'd array of structs of per-walsender data,
 * and the number of valid entries (candidate sync senders) is returned.
 * (This might be more or fewer than num_sync; caller must check.)
 */
int
SyncRepGetCandidateStandbys(SyncRepStandbyData **standbys)
{
    int         i;
    int         n;
 
    /* Create result array */
    *standbys = (SyncRepStandbyData *)
        palloc(max_wal_senders * sizeof(SyncRepStandbyData));
 
    /* Quick exit if sync replication is not requested */
    if (SyncRepConfig == NULL)
        return 0;
 
    /* Collect raw data from shared memory */
    n = 0;
    for (i = 0; i < max_wal_senders; i++)
    {
        volatile WalSnd *walsnd;    /* Use volatile pointer to prevent code
                                     * rearrangement */
        SyncRepStandbyData *stby;
        WalSndState state;      /* not included in SyncRepStandbyData */
 
        walsnd = &WalSndCtl->walsnds[i];
        stby = *standbys + n;
 
        SpinLockAcquire(&walsnd->mutex);
        stby->pid = walsnd->pid;
        state = walsnd->state;
        stby->write = walsnd->write;
        stby->flush = walsnd->flush;
        stby->apply = walsnd->apply;
        stby->sync_standby_priority = walsnd->sync_standby_priority;
        SpinLockRelease(&walsnd->mutex);
 
        /* Must be active */
        if (stby->pid == 0)
            continue;
 
        /* Must be streaming or stopping */
        if (state != WALSNDSTATE_STREAMING &&
            state != WALSNDSTATE_STOPPING)
            continue;
 
        /* Must be synchronous */
        if (stby->sync_standby_priority == 0)
            continue;
 
        /* Must have a valid flush position */
        if (XLogRecPtrIsInvalid(stby->flush))
            continue;
 
        /* OK, it's a candidate */
        stby->walsnd_index = i;
        stby->is_me = (walsnd == MyWalSnd);
        n++;
    }
 
    /*
     * In quorum mode, we return all the candidates.  In priority mode, if we
     * have too many candidates then return only the num_sync ones of highest
     * priority.
     */
    if (SyncRepConfig->syncrep_method == SYNC_REP_PRIORITY &&
        n > SyncRepConfig->num_sync)
    {
        /* Sort by priority ... */
        qsort(*standbys, n, sizeof(SyncRepStandbyData),
              standby_priority_comparator);
        /* ... then report just the first num_sync ones */
        n = SyncRepConfig->num_sync;
    }
 
    return n;
}
 
/*
 * qsort comparator to sort SyncRepStandbyData entries by priority
 */
static int
standby_priority_comparator(const void *a, const void *b)
{
    const SyncRepStandbyData *sa = (const SyncRepStandbyData *) a;
    const SyncRepStandbyData *sb = (const SyncRepStandbyData *) b;
 
    /* First, sort by increasing priority value */
    if (sa->sync_standby_priority != sb->sync_standby_priority)
        return sa->sync_standby_priority - sb->sync_standby_priority;
 
    /*
     * We might have equal priority values; arbitrarily break ties by position
     * in the WalSnd array.  (This is utterly bogus, since that is arrival
     * order dependent, but there are regression tests that rely on it.)
     */
    return sa->walsnd_index - sb->walsnd_index;
}
 
 
/*
 * Check if we are in the list of sync standbys, and if so, determine
 * priority sequence. Return priority if set, or zero to indicate that
 * we are not a potential sync standby.
 *
 * Compare the parameter SyncRepStandbyNames against the application_name
 * for this WALSender, or allow any name if we find a wildcard "*".
 */
static int
SyncRepGetStandbyPriority(void)
{
    const char *standby_name;
    int         priority;
    bool        found = false;
 
    /*
     * Since synchronous cascade replication is not allowed, we always set the
     * priority of cascading walsender to zero.
     */
    if (am_cascading_walsender)
        return 0;
 
    if (!SyncStandbysDefined() || SyncRepConfig == NULL)
        return 0;
 
    standby_name = SyncRepConfig->member_names;
    for (priority = 1; priority <= SyncRepConfig->nmembers; priority++)
    {
        if (pg_strcasecmp(standby_name, application_name) == 0 ||
            strcmp(standby_name, "*") == 0)
        {
            found = true;
            break;
        }
        standby_name += strlen(standby_name) + 1;
    }
 
    if (!found)
        return 0;
 
    /*
     * In quorum-based sync replication, all the standbys in the list have the
     * same priority, one.
     */
    return (SyncRepConfig->syncrep_method == SYNC_REP_PRIORITY) ? priority : 1;
}
 
/*
 * Walk the specified queue from head.  Set the state of any backends that
 * need to be woken, remove them from the queue, and then wake them.
 * Pass all = true to wake whole queue; otherwise, just wake up to
 * the walsender's LSN.
 *
 * The caller must hold SyncRepLock in exclusive mode.
 */
static int
SyncRepWakeQueue(bool all, int mode)
{
    volatile WalSndCtlData *walsndctl = WalSndCtl;
    int         numprocs = 0;
    dlist_mutable_iter iter;
 
    Assert(mode >= 0 && mode < NUM_SYNC_REP_WAIT_MODE);
    Assert(LWLockHeldByMeInMode(SyncRepLock, LW_EXCLUSIVE));
    Assert(SyncRepQueueIsOrderedByLSN(mode));
 
    dlist_foreach_modify(iter, &WalSndCtl->SyncRepQueue[mode])
    {
        PGPROC     *proc = dlist_container(PGPROC, syncRepLinks, iter.cur);
 
        /*
         * Assume the queue is ordered by LSN
         */
        if (!all && walsndctl->lsn[mode] < proc->waitLSN)
            return numprocs;
 
        /*
         * Remove from queue.
         */
        dlist_delete_thoroughly(&proc->syncRepLinks);
 
        /*
         * SyncRepWaitForLSN() reads syncRepState without holding the lock, so
         * make sure that it sees the queue link being removed before the
         * syncRepState change.
         */
        pg_write_barrier();
 
        /*
         * Set state to complete; see SyncRepWaitForLSN() for discussion of
         * the various states.
         */
        proc->syncRepState = SYNC_REP_WAIT_COMPLETE;
 
        /*
         * Wake only when we have set state and removed from queue.
         */
        SetLatch(&(proc->procLatch));
 
        numprocs++;
    }
 
    return numprocs;
}
 
/*
 * The checkpointer calls this as needed to update the shared
 * sync_standbys_status flag, so that backends don't remain permanently wedged
 * if synchronous_standby_names is unset.  It's safe to check the current value
 * without the lock, because it's only ever updated by one process.  But we
 * must take the lock to change it.
 */
void
SyncRepUpdateSyncStandbysDefined(void)
{
    bool        sync_standbys_defined = SyncStandbysDefined();
 
    if (sync_standbys_defined !=
        ((WalSndCtl->sync_standbys_status & SYNC_STANDBY_DEFINED) != 0))
    {
        LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
 
        /*
         * If synchronous_standby_names has been reset to empty, it's futile
         * for backends to continue waiting.  Since the user no longer wants
         * synchronous replication, we'd better wake them up.
         */
        if (!sync_standbys_defined)
        {
            int         i;
 
            for (i = 0; i < NUM_SYNC_REP_WAIT_MODE; i++)
                SyncRepWakeQueue(true, i);
        }
 
        /*
         * Only allow people to join the queue when there are synchronous
         * standbys defined.  Without this interlock, there's a race
         * condition: we might wake up all the current waiters; then, some
         * backend that hasn't yet reloaded its config might go to sleep on
         * the queue (and never wake up).  This prevents that.
         */
        WalSndCtl->sync_standbys_status = SYNC_STANDBY_INIT |
            (sync_standbys_defined ? SYNC_STANDBY_DEFINED : 0);
 
        LWLockRelease(SyncRepLock);
    }
    else if ((WalSndCtl->sync_standbys_status & SYNC_STANDBY_INIT) == 0)
    {
        LWLockAcquire(SyncRepLock, LW_EXCLUSIVE);
 
        /*
         * Note that there is no need to wake up the queues here.  We would
         * reach this path only if SyncStandbysDefined() returns false, or it
         * would mean that some backends are waiting with the GUC set.  See
         * SyncRepWaitForLSN().
         */
        Assert(!SyncStandbysDefined());
 
        /*
         * Even if there is no sync standby defined, let the readers of this
         * information know that the sync standby data has been initialized.
         * This can just be done once, hence the previous check on
         * SYNC_STANDBY_INIT to avoid useless work.
         */
        WalSndCtl->sync_standbys_status |= SYNC_STANDBY_INIT;
 
        LWLockRelease(SyncRepLock);
    }
}
 
#ifdef USE_ASSERT_CHECKING
static bool
SyncRepQueueIsOrderedByLSN(int mode)
{
    XLogRecPtr  lastLSN;
    dlist_iter  iter;
 
    Assert(mode >= 0 && mode < NUM_SYNC_REP_WAIT_MODE);
 
    lastLSN = 0;
 
    dlist_foreach(iter, &WalSndCtl->SyncRepQueue[mode])
    {
        PGPROC     *proc = dlist_container(PGPROC, syncRepLinks, iter.cur);
 
        /*
         * Check the queue is ordered by LSN and that multiple procs don't
         * have matching LSNs
         */
        if (proc->waitLSN <= lastLSN)
            return false;
 
        lastLSN = proc->waitLSN;
    }
 
    return true;
}
#endif
 
/*
 * ===========================================================
 * Synchronous Replication functions executed by any process
 * ===========================================================
 */
 
bool
check_synchronous_standby_names(char **newval, void **extra, GucSource source)
{
    if (*newval != NULL && (*newval)[0] != '\0')
    {
        yyscan_t    scanner;
        int         parse_rc;
        SyncRepConfigData *pconf;
 
        /* Result of parsing is returned in one of these two variables */
        SyncRepConfigData *syncrep_parse_result = NULL;
        char       *syncrep_parse_error_msg = NULL;
 
        /* Parse the synchronous_standby_names string */
        syncrep_scanner_init(*newval, &scanner);
        parse_rc = syncrep_yyparse(&syncrep_parse_result, &syncrep_parse_error_msg, scanner);
        syncrep_scanner_finish(scanner);
 
        if (parse_rc != 0 || syncrep_parse_result == NULL)
        {
            GUC_check_errcode(ERRCODE_SYNTAX_ERROR);
            if (syncrep_parse_error_msg)
                GUC_check_errdetail("%s", syncrep_parse_error_msg);
            else
                GUC_check_errdetail("\"%s\" parser failed.",
                                    "synchronous_standby_names");
            return false;
        }
 
        if (syncrep_parse_result->num_sync <= 0)
        {
            GUC_check_errmsg("number of synchronous standbys (%d) must be greater than zero",
                             syncrep_parse_result->num_sync);
            return false;
        }
 
        /* GUC extra value must be guc_malloc'd, not palloc'd */
        pconf = (SyncRepConfigData *)
            guc_malloc(LOG, syncrep_parse_result->config_size);
        if (pconf == NULL)
            return false;
        memcpy(pconf, syncrep_parse_result, syncrep_parse_result->config_size);
 
        *extra = pconf;
 
        /*
         * We need not explicitly clean up syncrep_parse_result.  It, and any
         * other cruft generated during parsing, will be freed when the
         * current memory context is deleted.  (This code is generally run in
         * a short-lived context used for config file processing, so that will
         * not be very long.)
         */
    }
    else
        *extra = NULL;
 
    return true;
}
 
void
assign_synchronous_standby_names(const char *newval, void *extra)
{
    SyncRepConfig = (SyncRepConfigData *) extra;
}
 
void
assign_synchronous_commit(int newval, void *extra)
{
    switch (newval)
    {
        case SYNCHRONOUS_COMMIT_REMOTE_WRITE:
            SyncRepWaitMode = SYNC_REP_WAIT_WRITE;
            break;
        case SYNCHRONOUS_COMMIT_REMOTE_FLUSH:
            SyncRepWaitMode = SYNC_REP_WAIT_FLUSH;
            break;
        case SYNCHRONOUS_COMMIT_REMOTE_APPLY:
            SyncRepWaitMode = SYNC_REP_WAIT_APPLY;
            break;
        default:
            SyncRepWaitMode = SYNC_REP_NO_WAIT;
            break;
    }
}