/*------------------------------------------------------------------------- * * walsender.c * * The WAL sender process (walsender) is new as of Postgres 9.0. It takes * care of sending XLOG from the primary server to a single recipient. * (Note that there can be more than one walsender process concurrently.) * It is started by the postmaster when the walreceiver of a standby server * connects to the primary server and requests XLOG streaming replication. * It attempts to keep reading XLOG records from the disk and sending them * to the standby server, as long as the connection is alive (i.e., like * any backend, there is a one-to-one relationship between a connection * and a walsender process). * * Normal termination is by SIGTERM, which instructs the walsender to * close the connection and exit(0) at next convenient moment. Emergency * termination is by SIGQUIT; like any backend, the walsender will simply * abort and exit on SIGQUIT. A close of the connection and a FATAL error * are treated as not a crash but approximately normal termination; * the walsender will exit quickly without sending any more XLOG records. * * If the server is shut down, postmaster sends us SIGUSR2 after all * regular backends have exited and the shutdown checkpoint has been written. * This instruct walsender to send any outstanding WAL, including the * shutdown checkpoint record, and then exit. * * * Portions Copyright (c) 2010-2010, PostgreSQL Global Development Group * * IDENTIFICATION * src/backend/replication/walsender.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include "access/xlog_internal.h" #include "catalog/pg_type.h" #include "libpq/libpq.h" #include "libpq/pqformat.h" #include "libpq/pqsignal.h" #include "miscadmin.h" #include "replication/walprotocol.h" #include "replication/walsender.h" #include "storage/fd.h" #include "storage/ipc.h" #include "storage/pmsignal.h" #include "tcop/tcopprot.h" #include "utils/guc.h" #include "utils/memutils.h" #include "utils/ps_status.h" /* Array of WalSnds in shared memory */ WalSndCtlData *WalSndCtl = NULL; /* My slot in the shared memory array */ static WalSnd *MyWalSnd = NULL; /* Global state */ bool am_walsender = false; /* Am I a walsender process ? */ /* User-settable parameters for walsender */ int max_wal_senders = 0; /* the maximum number of concurrent walsenders */ int WalSndDelay = 200; /* max sleep time between some actions */ /* * These variables are used similarly to openLogFile/Id/Seg/Off, * but for walsender to read the XLOG. */ static int sendFile = -1; static uint32 sendId = 0; static uint32 sendSeg = 0; static uint32 sendOff = 0; /* * How far have we sent WAL already? This is also advertised in * MyWalSnd->sentPtr. (Actually, this is the next WAL location to send.) */ static XLogRecPtr sentPtr = {0, 0}; /* Flags set by signal handlers for later service in main loop */ static volatile sig_atomic_t got_SIGHUP = false; static volatile sig_atomic_t shutdown_requested = false; static volatile sig_atomic_t ready_to_stop = false; /* Signal handlers */ static void WalSndSigHupHandler(SIGNAL_ARGS); static void WalSndShutdownHandler(SIGNAL_ARGS); static void WalSndQuickDieHandler(SIGNAL_ARGS); static void WalSndXLogSendHandler(SIGNAL_ARGS); static void WalSndLastCycleHandler(SIGNAL_ARGS); /* Prototypes for private functions */ static int WalSndLoop(void); static void InitWalSnd(void); static void WalSndHandshake(void); static void WalSndKill(int code, Datum arg); static void XLogRead(char *buf, XLogRecPtr recptr, Size nbytes); static bool XLogSend(char *msgbuf, bool *caughtup); static void CheckClosedConnection(void); /* Main entry point for walsender process */ int WalSenderMain(void) { MemoryContext walsnd_context; if (RecoveryInProgress()) ereport(FATAL, (errcode(ERRCODE_CANNOT_CONNECT_NOW), errmsg("recovery is still in progress, can't accept WAL streaming connections"))); /* Create a per-walsender data structure in shared memory */ InitWalSnd(); /* * Create a memory context that we will do all our work in. We do this so * that we can reset the context during error recovery and thereby avoid * possible memory leaks. Formerly this code just ran in * TopMemoryContext, but resetting that would be a really bad idea. * * XXX: we don't actually attempt error recovery in walsender, we just * close the connection and exit. */ walsnd_context = AllocSetContextCreate(TopMemoryContext, "Wal Sender", ALLOCSET_DEFAULT_MINSIZE, ALLOCSET_DEFAULT_INITSIZE, ALLOCSET_DEFAULT_MAXSIZE); MemoryContextSwitchTo(walsnd_context); /* Unblock signals (they were blocked when the postmaster forked us) */ PG_SETMASK(&UnBlockSig); /* Tell the standby that walsender is ready for receiving commands */ ReadyForQuery(DestRemote); /* Handle handshake messages before streaming */ WalSndHandshake(); /* Initialize shared memory status */ { /* use volatile pointer to prevent code rearrangement */ volatile WalSnd *walsnd = MyWalSnd; SpinLockAcquire(&walsnd->mutex); walsnd->sentPtr = sentPtr; SpinLockRelease(&walsnd->mutex); } /* Main loop of walsender */ return WalSndLoop(); } /* * Execute commands from walreceiver, until we enter streaming mode. */ static void WalSndHandshake(void) { StringInfoData input_message; bool replication_started = false; initStringInfo(&input_message); while (!replication_started) { int firstchar; /* Wait for a command to arrive */ firstchar = pq_getbyte(); /* * Emergency bailout if postmaster has died. This is to avoid the * necessity for manual cleanup of all postmaster children. */ if (!PostmasterIsAlive(true)) exit(1); /* * Check for any other interesting events that happened while we * slept. */ if (got_SIGHUP) { got_SIGHUP = false; ProcessConfigFile(PGC_SIGHUP); } if (firstchar != EOF) { /* * Read the message contents. This is expected to be done without * blocking because we've been able to get message type code. */ if (pq_getmessage(&input_message, 0)) firstchar = EOF; /* suitable message already logged */ } /* Handle the very limited subset of commands expected in this phase */ switch (firstchar) { case 'Q': /* Query message */ { const char *query_string; XLogRecPtr recptr; query_string = pq_getmsgstring(&input_message); pq_getmsgend(&input_message); if (strcmp(query_string, "IDENTIFY_SYSTEM") == 0) { StringInfoData buf; char sysid[32]; char tli[11]; /* * Reply with a result set with one row, two columns. * First col is system ID, and second is timeline ID */ snprintf(sysid, sizeof(sysid), UINT64_FORMAT, GetSystemIdentifier()); snprintf(tli, sizeof(tli), "%u", ThisTimeLineID); /* Send a RowDescription message */ pq_beginmessage(&buf, 'T'); pq_sendint(&buf, 2, 2); /* 2 fields */ /* first field */ pq_sendstring(&buf, "systemid"); /* col name */ pq_sendint(&buf, 0, 4); /* table oid */ pq_sendint(&buf, 0, 2); /* attnum */ pq_sendint(&buf, TEXTOID, 4); /* type oid */ pq_sendint(&buf, -1, 2); /* typlen */ pq_sendint(&buf, 0, 4); /* typmod */ pq_sendint(&buf, 0, 2); /* format code */ /* second field */ pq_sendstring(&buf, "timeline"); /* col name */ pq_sendint(&buf, 0, 4); /* table oid */ pq_sendint(&buf, 0, 2); /* attnum */ pq_sendint(&buf, INT4OID, 4); /* type oid */ pq_sendint(&buf, 4, 2); /* typlen */ pq_sendint(&buf, 0, 4); /* typmod */ pq_sendint(&buf, 0, 2); /* format code */ pq_endmessage(&buf); /* Send a DataRow message */ pq_beginmessage(&buf, 'D'); pq_sendint(&buf, 2, 2); /* # of columns */ pq_sendint(&buf, strlen(sysid), 4); /* col1 len */ pq_sendbytes(&buf, (char *) &sysid, strlen(sysid)); pq_sendint(&buf, strlen(tli), 4); /* col2 len */ pq_sendbytes(&buf, (char *) tli, strlen(tli)); pq_endmessage(&buf); /* Send CommandComplete and ReadyForQuery messages */ EndCommand("SELECT", DestRemote); ReadyForQuery(DestRemote); /* ReadyForQuery did pq_flush for us */ } else if (sscanf(query_string, "START_REPLICATION %X/%X", &recptr.xlogid, &recptr.xrecoff) == 2) { StringInfoData buf; /* * Check that we're logging enough information in the * WAL for log-shipping. * * NOTE: This only checks the current value of * wal_level. Even if the current setting is not * 'minimal', there can be old WAL in the pg_xlog * directory that was created with 'minimal'. So this * is not bulletproof, the purpose is just to give a * user-friendly error message that hints how to * configure the system correctly. */ if (wal_level == WAL_LEVEL_MINIMAL) ereport(FATAL, (errcode(ERRCODE_CANNOT_CONNECT_NOW), errmsg("standby connections not allowed because wal_level=minimal"))); /* Send a CopyOutResponse message, and start streaming */ pq_beginmessage(&buf, 'H'); pq_sendbyte(&buf, 0); pq_sendint(&buf, 0, 2); pq_endmessage(&buf); pq_flush(); /* * Initialize position to the received one, then the * xlog records begin to be shipped from that position */ sentPtr = recptr; /* break out of the loop */ replication_started = true; } else { ereport(FATAL, (errcode(ERRCODE_PROTOCOL_VIOLATION), errmsg("invalid standby query string: %s", query_string))); } break; } case 'X': /* standby is closing the connection */ proc_exit(0); case EOF: /* standby disconnected unexpectedly */ ereport(COMMERROR, (errcode(ERRCODE_PROTOCOL_VIOLATION), errmsg("unexpected EOF on standby connection"))); proc_exit(0); default: ereport(FATAL, (errcode(ERRCODE_PROTOCOL_VIOLATION), errmsg("invalid standby handshake message type %d", firstchar))); } } } /* * Check if the remote end has closed the connection. */ static void CheckClosedConnection(void) { unsigned char firstchar; int r; r = pq_getbyte_if_available(&firstchar); if (r < 0) { /* unexpected error or EOF */ ereport(COMMERROR, (errcode(ERRCODE_PROTOCOL_VIOLATION), errmsg("unexpected EOF on standby connection"))); proc_exit(0); } if (r == 0) { /* no data available without blocking */ return; } /* Handle the very limited subset of commands expected in this phase */ switch (firstchar) { /* * 'X' means that the standby is closing down the socket. */ case 'X': proc_exit(0); default: ereport(FATAL, (errcode(ERRCODE_PROTOCOL_VIOLATION), errmsg("invalid standby closing message type %d", firstchar))); } } /* Main loop of walsender process */ static int WalSndLoop(void) { char *output_message; bool caughtup = false; /* * Allocate buffer that will be used for each output message. We do this * just once to reduce palloc overhead. The buffer must be made large * enough for maximum-sized messages. */ output_message = palloc(1 + sizeof(WalDataMessageHeader) + MAX_SEND_SIZE); /* Loop forever, unless we get an error */ for (;;) { /* * Emergency bailout if postmaster has died. This is to avoid the * necessity for manual cleanup of all postmaster children. */ if (!PostmasterIsAlive(true)) exit(1); /* Process any requests or signals received recently */ if (got_SIGHUP) { got_SIGHUP = false; ProcessConfigFile(PGC_SIGHUP); } /* * When SIGUSR2 arrives, we send all outstanding logs up to the * shutdown checkpoint record (i.e., the latest record) and exit. */ if (ready_to_stop) { if (!XLogSend(output_message, &caughtup)) break; if (caughtup) shutdown_requested = true; } /* Normal exit from the walsender is here */ if (shutdown_requested) { /* Inform the standby that XLOG streaming was done */ pq_puttextmessage('C', "COPY 0"); pq_flush(); proc_exit(0); } /* * If we had sent all accumulated WAL in last round, nap for the * configured time before retrying. */ if (caughtup) { /* * Even if we wrote all the WAL that was available when we started * sending, more might have arrived while we were sending this * batch. We had the latch set while sending, so we have not * received any signals from that time. Let's arm the latch * again, and after that check that we're still up-to-date. */ ResetLatch(&MyWalSnd->latch); if (!XLogSend(output_message, &caughtup)) break; if (caughtup && !got_SIGHUP && !ready_to_stop && !shutdown_requested) { /* * XXX: We don't really need the periodic wakeups anymore, * WaitLatchOrSocket should reliably wake up as soon as * something interesting happens. */ /* Sleep */ WaitLatchOrSocket(&MyWalSnd->latch, MyProcPort->sock, WalSndDelay * 1000L); } /* Check if the connection was closed */ CheckClosedConnection(); } else { /* Attempt to send the log once every loop */ if (!XLogSend(output_message, &caughtup)) break; } } /* * Get here on send failure. Clean up and exit. * * Reset whereToSendOutput to prevent ereport from attempting to send any * more messages to the standby. */ if (whereToSendOutput == DestRemote) whereToSendOutput = DestNone; proc_exit(0); return 1; /* keep the compiler quiet */ } /* Initialize a per-walsender data structure for this walsender process */ static void InitWalSnd(void) { int i; /* * WalSndCtl should be set up already (we inherit this by fork() or * EXEC_BACKEND mechanism from the postmaster). */ Assert(WalSndCtl != NULL); Assert(MyWalSnd == NULL); /* * Find a free walsender slot and reserve it. If this fails, we must be * out of WalSnd structures. */ for (i = 0; i < max_wal_senders; i++) { /* use volatile pointer to prevent code rearrangement */ volatile WalSnd *walsnd = &WalSndCtl->walsnds[i]; SpinLockAcquire(&walsnd->mutex); if (walsnd->pid != 0) { SpinLockRelease(&walsnd->mutex); continue; } else { /* * Found a free slot. Reserve it for us. */ walsnd->pid = MyProcPid; MemSet(&walsnd->sentPtr, 0, sizeof(XLogRecPtr)); SpinLockRelease(&walsnd->mutex); /* don't need the lock anymore */ OwnLatch((Latch *) &walsnd->latch); MyWalSnd = (WalSnd *) walsnd; break; } } if (MyWalSnd == NULL) ereport(FATAL, (errcode(ERRCODE_TOO_MANY_CONNECTIONS), errmsg("number of requested standby connections " "exceeds max_wal_senders (currently %d)", max_wal_senders))); /* Arrange to clean up at walsender exit */ on_shmem_exit(WalSndKill, 0); } /* Destroy the per-walsender data structure for this walsender process */ static void WalSndKill(int code, Datum arg) { Assert(MyWalSnd != NULL); /* * Mark WalSnd struct no longer in use. Assume that no lock is required * for this. */ MyWalSnd->pid = 0; DisownLatch(&MyWalSnd->latch); /* WalSnd struct isn't mine anymore */ MyWalSnd = NULL; } /* * Read 'nbytes' bytes from WAL into 'buf', starting at location 'recptr' * * XXX probably this should be improved to suck data directly from the * WAL buffers when possible. */ static void XLogRead(char *buf, XLogRecPtr recptr, Size nbytes) { XLogRecPtr startRecPtr = recptr; char path[MAXPGPATH]; uint32 lastRemovedLog; uint32 lastRemovedSeg; uint32 log; uint32 seg; while (nbytes > 0) { uint32 startoff; int segbytes; int readbytes; startoff = recptr.xrecoff % XLogSegSize; if (sendFile < 0 || !XLByteInSeg(recptr, sendId, sendSeg)) { /* Switch to another logfile segment */ if (sendFile >= 0) close(sendFile); XLByteToSeg(recptr, sendId, sendSeg); XLogFilePath(path, ThisTimeLineID, sendId, sendSeg); sendFile = BasicOpenFile(path, O_RDONLY | PG_BINARY, 0); if (sendFile < 0) { /* * If the file is not found, assume it's because the standby * asked for a too old WAL segment that has already been * removed or recycled. */ if (errno == ENOENT) { char filename[MAXFNAMELEN]; XLogFileName(filename, ThisTimeLineID, sendId, sendSeg); ereport(ERROR, (errcode_for_file_access(), errmsg("requested WAL segment %s has already been removed", filename))); } else ereport(ERROR, (errcode_for_file_access(), errmsg("could not open file \"%s\" (log file %u, segment %u): %m", path, sendId, sendSeg))); } sendOff = 0; } /* Need to seek in the file? */ if (sendOff != startoff) { if (lseek(sendFile, (off_t) startoff, SEEK_SET) < 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not seek in log file %u, segment %u to offset %u: %m", sendId, sendSeg, startoff))); sendOff = startoff; } /* How many bytes are within this segment? */ if (nbytes > (XLogSegSize - startoff)) segbytes = XLogSegSize - startoff; else segbytes = nbytes; readbytes = read(sendFile, buf, segbytes); if (readbytes <= 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not read from log file %u, segment %u, offset %u, " "length %lu: %m", sendId, sendSeg, sendOff, (unsigned long) segbytes))); /* Update state for read */ XLByteAdvance(recptr, readbytes); sendOff += readbytes; nbytes -= readbytes; buf += readbytes; } /* * After reading into the buffer, check that what we read was valid. We do * this after reading, because even though the segment was present when we * opened it, it might get recycled or removed while we read it. The * read() succeeds in that case, but the data we tried to read might * already have been overwritten with new WAL records. */ XLogGetLastRemoved(&lastRemovedLog, &lastRemovedSeg); XLByteToSeg(startRecPtr, log, seg); if (log < lastRemovedLog || (log == lastRemovedLog && seg <= lastRemovedSeg)) { char filename[MAXFNAMELEN]; XLogFileName(filename, ThisTimeLineID, log, seg); ereport(ERROR, (errcode_for_file_access(), errmsg("requested WAL segment %s has already been removed", filename))); } } /* * Read up to MAX_SEND_SIZE bytes of WAL that's been flushed to disk, * but not yet sent to the client, and send it. * * msgbuf is a work area in which the output message is constructed. It's * passed in just so we can avoid re-palloc'ing the buffer on each cycle. * It must be of size 1 + sizeof(WalDataMessageHeader) + MAX_SEND_SIZE. * * If there is no unsent WAL remaining, *caughtup is set to true, otherwise * *caughtup is set to false. * * Returns true if OK, false if trouble. */ static bool XLogSend(char *msgbuf, bool *caughtup) { XLogRecPtr SendRqstPtr; XLogRecPtr startptr; XLogRecPtr endptr; Size nbytes; WalDataMessageHeader msghdr; /* * Attempt to send all data that's already been written out and fsync'd to * disk. We cannot go further than what's been written out given the * current implementation of XLogRead(). And in any case it's unsafe to * send WAL that is not securely down to disk on the master: if the master * subsequently crashes and restarts, slaves must not have applied any WAL * that gets lost on the master. */ SendRqstPtr = GetFlushRecPtr(); /* Quick exit if nothing to do */ if (XLByteLE(SendRqstPtr, sentPtr)) { *caughtup = true; return true; } /* * Figure out how much to send in one message. If there's no more than * MAX_SEND_SIZE bytes to send, send everything. Otherwise send * MAX_SEND_SIZE bytes, but round back to logfile or page boundary. * * The rounding is not only for performance reasons. Walreceiver relies on * the fact that we never split a WAL record across two messages. Since a * long WAL record is split at page boundary into continuation records, * page boundary is always a safe cut-off point. We also assume that * SendRqstPtr never points to the middle of a WAL record. */ startptr = sentPtr; if (startptr.xrecoff >= XLogFileSize) { /* * crossing a logid boundary, skip the non-existent last log segment * in previous logical log file. */ startptr.xlogid += 1; startptr.xrecoff = 0; } endptr = startptr; XLByteAdvance(endptr, MAX_SEND_SIZE); if (endptr.xlogid != startptr.xlogid) { /* Don't cross a logfile boundary within one message */ Assert(endptr.xlogid == startptr.xlogid + 1); endptr.xlogid = startptr.xlogid; endptr.xrecoff = XLogFileSize; } /* if we went beyond SendRqstPtr, back off */ if (XLByteLE(SendRqstPtr, endptr)) { endptr = SendRqstPtr; *caughtup = true; } else { /* round down to page boundary. */ endptr.xrecoff -= (endptr.xrecoff % XLOG_BLCKSZ); *caughtup = false; } nbytes = endptr.xrecoff - startptr.xrecoff; Assert(nbytes <= MAX_SEND_SIZE); /* * OK to read and send the slice. */ msgbuf[0] = 'w'; /* * Read the log directly into the output buffer to avoid extra memcpy * calls. */ XLogRead(msgbuf + 1 + sizeof(WalDataMessageHeader), startptr, nbytes); /* * We fill the message header last so that the send timestamp is taken as * late as possible. */ msghdr.dataStart = startptr; msghdr.walEnd = SendRqstPtr; msghdr.sendTime = GetCurrentTimestamp(); memcpy(msgbuf + 1, &msghdr, sizeof(WalDataMessageHeader)); pq_putmessage('d', msgbuf, 1 + sizeof(WalDataMessageHeader) + nbytes); /* Flush pending output to the client */ if (pq_flush()) return false; sentPtr = endptr; /* Update shared memory status */ { /* use volatile pointer to prevent code rearrangement */ volatile WalSnd *walsnd = MyWalSnd; SpinLockAcquire(&walsnd->mutex); walsnd->sentPtr = sentPtr; SpinLockRelease(&walsnd->mutex); } /* Report progress of XLOG streaming in PS display */ if (update_process_title) { char activitymsg[50]; snprintf(activitymsg, sizeof(activitymsg), "streaming %X/%X", sentPtr.xlogid, sentPtr.xrecoff); set_ps_display(activitymsg, false); } return true; } /* SIGHUP: set flag to re-read config file at next convenient time */ static void WalSndSigHupHandler(SIGNAL_ARGS) { got_SIGHUP = true; if (MyWalSnd) SetLatch(&MyWalSnd->latch); } /* SIGTERM: set flag to shut down */ static void WalSndShutdownHandler(SIGNAL_ARGS) { shutdown_requested = true; if (MyWalSnd) SetLatch(&MyWalSnd->latch); } /* * WalSndQuickDieHandler() occurs when signalled SIGQUIT by the postmaster. * * Some backend has bought the farm, * so we need to stop what we're doing and exit. */ static void WalSndQuickDieHandler(SIGNAL_ARGS) { PG_SETMASK(&BlockSig); /* * We DO NOT want to run proc_exit() callbacks -- we're here because * shared memory may be corrupted, so we don't want to try to clean up our * transaction. Just nail the windows shut and get out of town. Now that * there's an atexit callback to prevent third-party code from breaking * things by calling exit() directly, we have to reset the callbacks * explicitly to make this work as intended. */ on_exit_reset(); /* * Note we do exit(2) not exit(0). This is to force the postmaster into a * system reset cycle if some idiot DBA sends a manual SIGQUIT to a random * backend. This is necessary precisely because we don't clean up our * shared memory state. (The "dead man switch" mechanism in pmsignal.c * should ensure the postmaster sees this as a crash, too, but no harm in * being doubly sure.) */ exit(2); } /* SIGUSR1: set flag to send WAL records */ static void WalSndXLogSendHandler(SIGNAL_ARGS) { latch_sigusr1_handler(); } /* SIGUSR2: set flag to do a last cycle and shut down afterwards */ static void WalSndLastCycleHandler(SIGNAL_ARGS) { ready_to_stop = true; if (MyWalSnd) SetLatch(&MyWalSnd->latch); } /* Set up signal handlers */ void WalSndSignals(void) { /* Set up signal handlers */ pqsignal(SIGHUP, WalSndSigHupHandler); /* set flag to read config * file */ pqsignal(SIGINT, SIG_IGN); /* not used */ pqsignal(SIGTERM, WalSndShutdownHandler); /* request shutdown */ pqsignal(SIGQUIT, WalSndQuickDieHandler); /* hard crash time */ pqsignal(SIGALRM, SIG_IGN); pqsignal(SIGPIPE, SIG_IGN); pqsignal(SIGUSR1, WalSndXLogSendHandler); /* request WAL sending */ pqsignal(SIGUSR2, WalSndLastCycleHandler); /* request a last cycle and * shutdown */ /* Reset some signals that are accepted by postmaster but not here */ pqsignal(SIGCHLD, SIG_DFL); pqsignal(SIGTTIN, SIG_DFL); pqsignal(SIGTTOU, SIG_DFL); pqsignal(SIGCONT, SIG_DFL); pqsignal(SIGWINCH, SIG_DFL); } /* Report shared-memory space needed by WalSndShmemInit */ Size WalSndShmemSize(void) { Size size = 0; size = offsetof(WalSndCtlData, walsnds); size = add_size(size, mul_size(max_wal_senders, sizeof(WalSnd))); return size; } /* Allocate and initialize walsender-related shared memory */ void WalSndShmemInit(void) { bool found; int i; WalSndCtl = (WalSndCtlData *) ShmemInitStruct("Wal Sender Ctl", WalSndShmemSize(), &found); if (!found) { /* First time through, so initialize */ MemSet(WalSndCtl, 0, WalSndShmemSize()); for (i = 0; i < max_wal_senders; i++) { WalSnd *walsnd = &WalSndCtl->walsnds[i]; SpinLockInit(&walsnd->mutex); InitSharedLatch(&walsnd->latch); } } } /* Wake up all walsenders */ void WalSndWakeup(void) { int i; for (i = 0; i < max_wal_senders; i++) SetLatch(&WalSndCtl->walsnds[i].latch); } /* * This isn't currently used for anything. Monitoring tools might be * interested in the future, and we'll need something like this in the * future for synchronous replication. */ #ifdef NOT_USED /* * Returns the oldest Send position among walsenders. Or InvalidXLogRecPtr * if none. */ XLogRecPtr GetOldestWALSendPointer(void) { XLogRecPtr oldest = {0, 0}; int i; bool found = false; for (i = 0; i < max_wal_senders; i++) { /* use volatile pointer to prevent code rearrangement */ volatile WalSnd *walsnd = &WalSndCtl->walsnds[i]; XLogRecPtr recptr; if (walsnd->pid == 0) continue; SpinLockAcquire(&walsnd->mutex); recptr = walsnd->sentPtr; SpinLockRelease(&walsnd->mutex); if (recptr.xlogid == 0 && recptr.xrecoff == 0) continue; if (!found || XLByteLT(recptr, oldest)) oldest = recptr; found = true; } return oldest; } #endif