/*------------------------------------------------------------------------- * * xlogutils.c * * PostgreSQL write-ahead log manager utility routines * * This file contains support routines that are used by XLOG replay functions. * None of this code is used during normal system operation. * * * Portions Copyright (c) 1996-2017, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * src/backend/access/transam/xlogutils.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include "access/timeline.h" #include "access/xlog.h" #include "access/xlog_internal.h" #include "access/xlogutils.h" #include "catalog/catalog.h" #include "miscadmin.h" #include "pgstat.h" #include "storage/smgr.h" #include "utils/guc.h" #include "utils/hsearch.h" #include "utils/rel.h" /* * During XLOG replay, we may see XLOG records for incremental updates of * pages that no longer exist, because their relation was later dropped or * truncated. (Note: this is only possible when full_page_writes = OFF, * since when it's ON, the first reference we see to a page should always * be a full-page rewrite not an incremental update.) Rather than simply * ignoring such records, we make a note of the referenced page, and then * complain if we don't actually see a drop or truncate covering the page * later in replay. */ typedef struct xl_invalid_page_key { RelFileNode node; /* the relation */ ForkNumber forkno; /* the fork number */ BlockNumber blkno; /* the page */ } xl_invalid_page_key; typedef struct xl_invalid_page { xl_invalid_page_key key; /* hash key ... must be first */ bool present; /* page existed but contained zeroes */ } xl_invalid_page; static HTAB *invalid_page_tab = NULL; /* Report a reference to an invalid page */ static void report_invalid_page(int elevel, RelFileNode node, ForkNumber forkno, BlockNumber blkno, bool present) { char *path = relpathperm(node, forkno); if (present) elog(elevel, "page %u of relation %s is uninitialized", blkno, path); else elog(elevel, "page %u of relation %s does not exist", blkno, path); pfree(path); } /* Log a reference to an invalid page */ static void log_invalid_page(RelFileNode node, ForkNumber forkno, BlockNumber blkno, bool present) { xl_invalid_page_key key; xl_invalid_page *hentry; bool found; /* * Once recovery has reached a consistent state, the invalid-page table * should be empty and remain so. If a reference to an invalid page is * found after consistency is reached, PANIC immediately. This might seem * aggressive, but it's better than letting the invalid reference linger * in the hash table until the end of recovery and PANIC there, which * might come only much later if this is a standby server. */ if (reachedConsistency) { report_invalid_page(WARNING, node, forkno, blkno, present); elog(PANIC, "WAL contains references to invalid pages"); } /* * Log references to invalid pages at DEBUG1 level. This allows some * tracing of the cause (note the elog context mechanism will tell us * something about the XLOG record that generated the reference). */ if (log_min_messages <= DEBUG1 || client_min_messages <= DEBUG1) report_invalid_page(DEBUG1, node, forkno, blkno, present); if (invalid_page_tab == NULL) { /* create hash table when first needed */ HASHCTL ctl; memset(&ctl, 0, sizeof(ctl)); ctl.keysize = sizeof(xl_invalid_page_key); ctl.entrysize = sizeof(xl_invalid_page); invalid_page_tab = hash_create("XLOG invalid-page table", 100, &ctl, HASH_ELEM | HASH_BLOBS); } /* we currently assume xl_invalid_page_key contains no padding */ key.node = node; key.forkno = forkno; key.blkno = blkno; hentry = (xl_invalid_page *) hash_search(invalid_page_tab, (void *) &key, HASH_ENTER, &found); if (!found) { /* hash_search already filled in the key */ hentry->present = present; } else { /* repeat reference ... leave "present" as it was */ } } /* Forget any invalid pages >= minblkno, because they've been dropped */ static void forget_invalid_pages(RelFileNode node, ForkNumber forkno, BlockNumber minblkno) { HASH_SEQ_STATUS status; xl_invalid_page *hentry; if (invalid_page_tab == NULL) return; /* nothing to do */ hash_seq_init(&status, invalid_page_tab); while ((hentry = (xl_invalid_page *) hash_seq_search(&status)) != NULL) { if (RelFileNodeEquals(hentry->key.node, node) && hentry->key.forkno == forkno && hentry->key.blkno >= minblkno) { if (log_min_messages <= DEBUG2 || client_min_messages <= DEBUG2) { char *path = relpathperm(hentry->key.node, forkno); elog(DEBUG2, "page %u of relation %s has been dropped", hentry->key.blkno, path); pfree(path); } if (hash_search(invalid_page_tab, (void *) &hentry->key, HASH_REMOVE, NULL) == NULL) elog(ERROR, "hash table corrupted"); } } } /* Forget any invalid pages in a whole database */ static void forget_invalid_pages_db(Oid dbid) { HASH_SEQ_STATUS status; xl_invalid_page *hentry; if (invalid_page_tab == NULL) return; /* nothing to do */ hash_seq_init(&status, invalid_page_tab); while ((hentry = (xl_invalid_page *) hash_seq_search(&status)) != NULL) { if (hentry->key.node.dbNode == dbid) { if (log_min_messages <= DEBUG2 || client_min_messages <= DEBUG2) { char *path = relpathperm(hentry->key.node, hentry->key.forkno); elog(DEBUG2, "page %u of relation %s has been dropped", hentry->key.blkno, path); pfree(path); } if (hash_search(invalid_page_tab, (void *) &hentry->key, HASH_REMOVE, NULL) == NULL) elog(ERROR, "hash table corrupted"); } } } /* Are there any unresolved references to invalid pages? */ bool XLogHaveInvalidPages(void) { if (invalid_page_tab != NULL && hash_get_num_entries(invalid_page_tab) > 0) return true; return false; } /* Complain about any remaining invalid-page entries */ void XLogCheckInvalidPages(void) { HASH_SEQ_STATUS status; xl_invalid_page *hentry; bool foundone = false; if (invalid_page_tab == NULL) return; /* nothing to do */ hash_seq_init(&status, invalid_page_tab); /* * Our strategy is to emit WARNING messages for all remaining entries and * only PANIC after we've dumped all the available info. */ while ((hentry = (xl_invalid_page *) hash_seq_search(&status)) != NULL) { report_invalid_page(WARNING, hentry->key.node, hentry->key.forkno, hentry->key.blkno, hentry->present); foundone = true; } if (foundone) elog(PANIC, "WAL contains references to invalid pages"); hash_destroy(invalid_page_tab); invalid_page_tab = NULL; } /* * XLogReadBufferForRedo * Read a page during XLOG replay * * Reads a block referenced by a WAL record into shared buffer cache, and * determines what needs to be done to redo the changes to it. If the WAL * record includes a full-page image of the page, it is restored. * * 'lsn' is the LSN of the record being replayed. It is compared with the * page's LSN to determine if the record has already been replayed. * 'block_id' is the ID number the block was registered with, when the WAL * record was created. * * Returns one of the following: * * BLK_NEEDS_REDO - changes from the WAL record need to be applied * BLK_DONE - block doesn't need replaying * BLK_RESTORED - block was restored from a full-page image included in * the record * BLK_NOTFOUND - block was not found (because it was truncated away by * an operation later in the WAL stream) * * On return, the buffer is locked in exclusive-mode, and returned in *buf. * Note that the buffer is locked and returned even if it doesn't need * replaying. (Getting the buffer lock is not really necessary during * single-process crash recovery, but some subroutines such as MarkBufferDirty * will complain if we don't have the lock. In hot standby mode it's * definitely necessary.) * * Note: when a backup block is available in XLOG with the BKPIMAGE_APPLY flag * set, we restore it, even if the page in the database appears newer. This * is to protect ourselves against database pages that were partially or * incorrectly written during a crash. We assume that the XLOG data must be * good because it has passed a CRC check, while the database page might not * be. This will force us to replay all subsequent modifications of the page * that appear in XLOG, rather than possibly ignoring them as already * applied, but that's not a huge drawback. */ XLogRedoAction XLogReadBufferForRedo(XLogReaderState *record, uint8 block_id, Buffer *buf) { return XLogReadBufferForRedoExtended(record, block_id, RBM_NORMAL, false, buf); } /* * Pin and lock a buffer referenced by a WAL record, for the purpose of * re-initializing it. */ Buffer XLogInitBufferForRedo(XLogReaderState *record, uint8 block_id) { Buffer buf; XLogReadBufferForRedoExtended(record, block_id, RBM_ZERO_AND_LOCK, false, &buf); return buf; } /* * XLogReadBufferForRedoExtended * Like XLogReadBufferForRedo, but with extra options. * * In RBM_ZERO_* modes, if the page doesn't exist, the relation is extended * with all-zeroes pages up to the referenced block number. In * RBM_ZERO_AND_LOCK and RBM_ZERO_AND_CLEANUP_LOCK modes, the return value * is always BLK_NEEDS_REDO. * * (The RBM_ZERO_AND_CLEANUP_LOCK mode is redundant with the get_cleanup_lock * parameter. Do not use an inconsistent combination!) * * If 'get_cleanup_lock' is true, a "cleanup lock" is acquired on the buffer * using LockBufferForCleanup(), instead of a regular exclusive lock. */ XLogRedoAction XLogReadBufferForRedoExtended(XLogReaderState *record, uint8 block_id, ReadBufferMode mode, bool get_cleanup_lock, Buffer *buf) { XLogRecPtr lsn = record->EndRecPtr; RelFileNode rnode; ForkNumber forknum; BlockNumber blkno; Page page; bool zeromode; bool willinit; if (!XLogRecGetBlockTag(record, block_id, &rnode, &forknum, &blkno)) { /* Caller specified a bogus block_id */ elog(PANIC, "failed to locate backup block with ID %d", block_id); } /* * Make sure that if the block is marked with WILL_INIT, the caller is * going to initialize it. And vice versa. */ zeromode = (mode == RBM_ZERO_AND_LOCK || mode == RBM_ZERO_AND_CLEANUP_LOCK); willinit = (record->blocks[block_id].flags & BKPBLOCK_WILL_INIT) != 0; if (willinit && !zeromode) elog(PANIC, "block with WILL_INIT flag in WAL record must be zeroed by redo routine"); if (!willinit && zeromode) elog(PANIC, "block to be initialized in redo routine must be marked with WILL_INIT flag in the WAL record"); /* If it has a full-page image and it should be restored, do it. */ if (XLogRecBlockImageApply(record, block_id)) { Assert(XLogRecHasBlockImage(record, block_id)); *buf = XLogReadBufferExtended(rnode, forknum, blkno, get_cleanup_lock ? RBM_ZERO_AND_CLEANUP_LOCK : RBM_ZERO_AND_LOCK); page = BufferGetPage(*buf); if (!RestoreBlockImage(record, block_id, page)) elog(ERROR, "failed to restore block image"); /* * The page may be uninitialized. If so, we can't set the LSN because * that would corrupt the page. */ if (!PageIsNew(page)) { PageSetLSN(page, lsn); } MarkBufferDirty(*buf); /* * At the end of crash recovery the init forks of unlogged relations * are copied, without going through shared buffers. So we need to * force the on-disk state of init forks to always be in sync with the * state in shared buffers. */ if (forknum == INIT_FORKNUM) FlushOneBuffer(*buf); return BLK_RESTORED; } else { *buf = XLogReadBufferExtended(rnode, forknum, blkno, mode); if (BufferIsValid(*buf)) { if (mode != RBM_ZERO_AND_LOCK && mode != RBM_ZERO_AND_CLEANUP_LOCK) { if (get_cleanup_lock) LockBufferForCleanup(*buf); else LockBuffer(*buf, BUFFER_LOCK_EXCLUSIVE); } if (lsn <= PageGetLSN(BufferGetPage(*buf))) return BLK_DONE; else return BLK_NEEDS_REDO; } else return BLK_NOTFOUND; } } /* * XLogReadBufferExtended * Read a page during XLOG replay * * This is functionally comparable to ReadBufferExtended. There's some * differences in the behavior wrt. the "mode" argument: * * In RBM_NORMAL mode, if the page doesn't exist, or contains all-zeroes, we * return InvalidBuffer. In this case the caller should silently skip the * update on this page. (In this situation, we expect that the page was later * dropped or truncated. If we don't see evidence of that later in the WAL * sequence, we'll complain at the end of WAL replay.) * * In RBM_ZERO_* modes, if the page doesn't exist, the relation is extended * with all-zeroes pages up to the given block number. * * In RBM_NORMAL_NO_LOG mode, we return InvalidBuffer if the page doesn't * exist, and we don't check for all-zeroes. Thus, no log entry is made * to imply that the page should be dropped or truncated later. * * NB: A redo function should normally not call this directly. To get a page * to modify, use XLogReadBufferForRedoExtended instead. It is important that * all pages modified by a WAL record are registered in the WAL records, or * they will be invisible to tools that that need to know which pages are * modified. */ Buffer XLogReadBufferExtended(RelFileNode rnode, ForkNumber forknum, BlockNumber blkno, ReadBufferMode mode) { BlockNumber lastblock; Buffer buffer; SMgrRelation smgr; Assert(blkno != P_NEW); /* Open the relation at smgr level */ smgr = smgropen(rnode, InvalidBackendId); /* * Create the target file if it doesn't already exist. This lets us cope * if the replay sequence contains writes to a relation that is later * deleted. (The original coding of this routine would instead suppress * the writes, but that seems like it risks losing valuable data if the * filesystem loses an inode during a crash. Better to write the data * until we are actually told to delete the file.) */ smgrcreate(smgr, forknum, true); lastblock = smgrnblocks(smgr, forknum); if (blkno < lastblock) { /* page exists in file */ buffer = ReadBufferWithoutRelcache(rnode, forknum, blkno, mode, NULL); } else { /* hm, page doesn't exist in file */ if (mode == RBM_NORMAL) { log_invalid_page(rnode, forknum, blkno, false); return InvalidBuffer; } if (mode == RBM_NORMAL_NO_LOG) return InvalidBuffer; /* OK to extend the file */ /* we do this in recovery only - no rel-extension lock needed */ Assert(InRecovery); buffer = InvalidBuffer; do { if (buffer != InvalidBuffer) { if (mode == RBM_ZERO_AND_LOCK || mode == RBM_ZERO_AND_CLEANUP_LOCK) LockBuffer(buffer, BUFFER_LOCK_UNLOCK); ReleaseBuffer(buffer); } buffer = ReadBufferWithoutRelcache(rnode, forknum, P_NEW, mode, NULL); } while (BufferGetBlockNumber(buffer) < blkno); /* Handle the corner case that P_NEW returns non-consecutive pages */ if (BufferGetBlockNumber(buffer) != blkno) { if (mode == RBM_ZERO_AND_LOCK || mode == RBM_ZERO_AND_CLEANUP_LOCK) LockBuffer(buffer, BUFFER_LOCK_UNLOCK); ReleaseBuffer(buffer); buffer = ReadBufferWithoutRelcache(rnode, forknum, blkno, mode, NULL); } } if (mode == RBM_NORMAL) { /* check that page has been initialized */ Page page = (Page) BufferGetPage(buffer); /* * We assume that PageIsNew is safe without a lock. During recovery, * there should be no other backends that could modify the buffer at * the same time. */ if (PageIsNew(page)) { ReleaseBuffer(buffer); log_invalid_page(rnode, forknum, blkno, true); return InvalidBuffer; } } return buffer; } /* * Struct actually returned by XLogFakeRelcacheEntry, though the declared * return type is Relation. */ typedef struct { RelationData reldata; /* Note: this must be first */ FormData_pg_class pgc; } FakeRelCacheEntryData; typedef FakeRelCacheEntryData *FakeRelCacheEntry; /* * Create a fake relation cache entry for a physical relation * * It's often convenient to use the same functions in XLOG replay as in the * main codepath, but those functions typically work with a relcache entry. * We don't have a working relation cache during XLOG replay, but this * function can be used to create a fake relcache entry instead. Only the * fields related to physical storage, like rd_rel, are initialized, so the * fake entry is only usable in low-level operations like ReadBuffer(). * * Caller must free the returned entry with FreeFakeRelcacheEntry(). */ Relation CreateFakeRelcacheEntry(RelFileNode rnode) { FakeRelCacheEntry fakeentry; Relation rel; Assert(InRecovery); /* Allocate the Relation struct and all related space in one block. */ fakeentry = palloc0(sizeof(FakeRelCacheEntryData)); rel = (Relation) fakeentry; rel->rd_rel = &fakeentry->pgc; rel->rd_node = rnode; /* We will never be working with temp rels during recovery */ rel->rd_backend = InvalidBackendId; /* It must be a permanent table if we're in recovery. */ rel->rd_rel->relpersistence = RELPERSISTENCE_PERMANENT; /* We don't know the name of the relation; use relfilenode instead */ sprintf(RelationGetRelationName(rel), "%u", rnode.relNode); /* * We set up the lockRelId in case anything tries to lock the dummy * relation. Note that this is fairly bogus since relNode may be * different from the relation's OID. It shouldn't really matter though, * since we are presumably running by ourselves and can't have any lock * conflicts ... */ rel->rd_lockInfo.lockRelId.dbId = rnode.dbNode; rel->rd_lockInfo.lockRelId.relId = rnode.relNode; rel->rd_smgr = NULL; return rel; } /* * Free a fake relation cache entry. */ void FreeFakeRelcacheEntry(Relation fakerel) { /* make sure the fakerel is not referenced by the SmgrRelation anymore */ if (fakerel->rd_smgr != NULL) smgrclearowner(&fakerel->rd_smgr, fakerel->rd_smgr); pfree(fakerel); } /* * Drop a relation during XLOG replay * * This is called when the relation is about to be deleted; we need to remove * any open "invalid-page" records for the relation. */ void XLogDropRelation(RelFileNode rnode, ForkNumber forknum) { forget_invalid_pages(rnode, forknum, 0); } /* * Drop a whole database during XLOG replay * * As above, but for DROP DATABASE instead of dropping a single rel */ void XLogDropDatabase(Oid dbid) { /* * This is unnecessarily heavy-handed, as it will close SMgrRelation * objects for other databases as well. DROP DATABASE occurs seldom enough * that it's not worth introducing a variant of smgrclose for just this * purpose. XXX: Or should we rather leave the smgr entries dangling? */ smgrcloseall(); forget_invalid_pages_db(dbid); } /* * Truncate a relation during XLOG replay * * We need to clean up any open "invalid-page" records for the dropped pages. */ void XLogTruncateRelation(RelFileNode rnode, ForkNumber forkNum, BlockNumber nblocks) { forget_invalid_pages(rnode, forkNum, nblocks); } /* * Read 'count' bytes from WAL into 'buf', starting at location 'startptr' * in timeline 'tli'. * * Will open, and keep open, one WAL segment stored in the static file * descriptor 'sendFile'. This means if XLogRead is used once, there will * always be one descriptor left open until the process ends, but never * more than one. * * XXX This is very similar to pg_waldump's XLogDumpXLogRead and to XLogRead * in walsender.c but for small differences (such as lack of elog() in * frontend). Probably these should be merged at some point. */ static void XLogRead(char *buf, TimeLineID tli, XLogRecPtr startptr, Size count) { char *p; XLogRecPtr recptr; Size nbytes; /* state maintained across calls */ static int sendFile = -1; static XLogSegNo sendSegNo = 0; static TimeLineID sendTLI = 0; static uint32 sendOff = 0; p = buf; recptr = startptr; nbytes = count; while (nbytes > 0) { uint32 startoff; int segbytes; int readbytes; startoff = recptr % XLogSegSize; /* Do we need to switch to a different xlog segment? */ if (sendFile < 0 || !XLByteInSeg(recptr, sendSegNo) || sendTLI != tli) { char path[MAXPGPATH]; if (sendFile >= 0) close(sendFile); XLByteToSeg(recptr, sendSegNo); XLogFilePath(path, tli, sendSegNo); sendFile = BasicOpenFile(path, O_RDONLY | PG_BINARY, 0); if (sendFile < 0) { if (errno == ENOENT) ereport(ERROR, (errcode_for_file_access(), errmsg("requested WAL segment %s has already been removed", path))); else ereport(ERROR, (errcode_for_file_access(), errmsg("could not open file \"%s\": %m", path))); } sendOff = 0; sendTLI = tli; } /* Need to seek in the file? */ if (sendOff != startoff) { if (lseek(sendFile, (off_t) startoff, SEEK_SET) < 0) { char path[MAXPGPATH]; XLogFilePath(path, tli, sendSegNo); ereport(ERROR, (errcode_for_file_access(), errmsg("could not seek in log segment %s to offset %u: %m", path, startoff))); } sendOff = startoff; } /* How many bytes are within this segment? */ if (nbytes > (XLogSegSize - startoff)) segbytes = XLogSegSize - startoff; else segbytes = nbytes; pgstat_report_wait_start(WAIT_EVENT_WAL_READ); readbytes = read(sendFile, p, segbytes); pgstat_report_wait_end(); if (readbytes <= 0) { char path[MAXPGPATH]; XLogFilePath(path, tli, sendSegNo); ereport(ERROR, (errcode_for_file_access(), errmsg("could not read from log segment %s, offset %u, length %lu: %m", path, sendOff, (unsigned long) segbytes))); } /* Update state for read */ recptr += readbytes; sendOff += readbytes; nbytes -= readbytes; p += readbytes; } } /* * Determine which timeline to read an xlog page from and set the * XLogReaderState's currTLI to that timeline ID. * * We care about timelines in xlogreader when we might be reading xlog * generated prior to a promotion, either if we're currently a standby in * recovery or if we're a promoted master reading xlogs generated by the old * master before our promotion. * * wantPage must be set to the start address of the page to read and * wantLength to the amount of the page that will be read, up to * XLOG_BLCKSZ. If the amount to be read isn't known, pass XLOG_BLCKSZ. * * We switch to an xlog segment from the new timeline eagerly when on a * historical timeline, as soon as we reach the start of the xlog segment * containing the timeline switch. The server copied the segment to the new * timeline so all the data up to the switch point is the same, but there's no * guarantee the old segment will still exist. It may have been deleted or * renamed with a .partial suffix so we can't necessarily keep reading from * the old TLI even though tliSwitchPoint says it's OK. * * We can't just check the timeline when we read a page on a different segment * to the last page. We could've received a timeline switch from a cascading * upstream, so the current segment ends abruptly (possibly getting renamed to * .partial) and we have to switch to a new one. Even in the middle of reading * a page we could have to dump the cached page and switch to a new TLI. * * Because of this, callers MAY NOT assume that currTLI is the timeline that * will be in a page's xlp_tli; the page may begin on an older timeline or we * might be reading from historical timeline data on a segment that's been * copied to a new timeline. * * The caller must also make sure it doesn't read past the current replay * position (using GetWalRcvWriteRecPtr) if executing in recovery, so it * doesn't fail to notice that the current timeline became historical. The * caller must also update ThisTimeLineID with the result of * GetWalRcvWriteRecPtr and must check RecoveryInProgress(). */ void XLogReadDetermineTimeline(XLogReaderState *state, XLogRecPtr wantPage, uint32 wantLength) { const XLogRecPtr lastReadPage = state->readSegNo * XLogSegSize + state->readOff; Assert(wantPage != InvalidXLogRecPtr && wantPage % XLOG_BLCKSZ == 0); Assert(wantLength <= XLOG_BLCKSZ); Assert(state->readLen == 0 || state->readLen <= XLOG_BLCKSZ); /* * If the desired page is currently read in and valid, we have nothing to * do. * * The caller should've ensured that it didn't previously advance readOff * past the valid limit of this timeline, so it doesn't matter if the * current TLI has since become historical. */ if (lastReadPage == wantPage && state->readLen != 0 && lastReadPage + state->readLen >= wantPage + Min(wantLength, XLOG_BLCKSZ - 1)) return; /* * If we're reading from the current timeline, it hasn't become historical * and the page we're reading is after the last page read, we can again * just carry on. (Seeking backwards requires a check to make sure the * older page isn't on a prior timeline). * * ThisTimeLineID might've become historical since we last looked, but the * caller is required not to read past the flush limit it saw at the time * it looked up the timeline. There's nothing we can do about it if * StartupXLOG() renames it to .partial concurrently. */ if (state->currTLI == ThisTimeLineID && wantPage >= lastReadPage) { Assert(state->currTLIValidUntil == InvalidXLogRecPtr); return; } /* * If we're just reading pages from a previously validated historical * timeline and the timeline we're reading from is valid until the end of * the current segment we can just keep reading. */ if (state->currTLIValidUntil != InvalidXLogRecPtr && state->currTLI != ThisTimeLineID && state->currTLI != 0 && (wantPage + wantLength) / XLogSegSize < state->currTLIValidUntil / XLogSegSize) return; /* * If we reach this point we're either looking up a page for random * access, the current timeline just became historical, or we're reading * from a new segment containing a timeline switch. In all cases we need * to determine the newest timeline on the segment. * * If it's the current timeline we can just keep reading from here unless * we detect a timeline switch that makes the current timeline historical. * If it's a historical timeline we can read all the segment on the newest * timeline because it contains all the old timelines' data too. So only * one switch check is required. */ { /* * We need to re-read the timeline history in case it's been changed * by a promotion or replay from a cascaded replica. */ List *timelineHistory = readTimeLineHistory(ThisTimeLineID); XLogRecPtr endOfSegment = (((wantPage / XLogSegSize) + 1) * XLogSegSize) - 1; Assert(wantPage / XLogSegSize == endOfSegment / XLogSegSize); /* * Find the timeline of the last LSN on the segment containing * wantPage. */ state->currTLI = tliOfPointInHistory(endOfSegment, timelineHistory); state->currTLIValidUntil = tliSwitchPoint(state->currTLI, timelineHistory, &state->nextTLI); Assert(state->currTLIValidUntil == InvalidXLogRecPtr || wantPage + wantLength < state->currTLIValidUntil); list_free_deep(timelineHistory); elog(DEBUG3, "switched to timeline %u valid until %X/%X", state->currTLI, (uint32) (state->currTLIValidUntil >> 32), (uint32) (state->currTLIValidUntil)); } } /* * read_page callback for reading local xlog files * * Public because it would likely be very helpful for someone writing another * output method outside walsender, e.g. in a bgworker. * * TODO: The walsender has its own version of this, but it relies on the * walsender's latch being set whenever WAL is flushed. No such infrastructure * exists for normal backends, so we have to do a check/sleep/repeat style of * loop for now. */ int read_local_xlog_page(XLogReaderState *state, XLogRecPtr targetPagePtr, int reqLen, XLogRecPtr targetRecPtr, char *cur_page, TimeLineID *pageTLI) { XLogRecPtr read_upto, loc; int count; loc = targetPagePtr + reqLen; /* Loop waiting for xlog to be available if necessary */ while (1) { /* * Determine the limit of xlog we can currently read to, and what the * most recent timeline is. * * RecoveryInProgress() will update ThisTimeLineID when it first * notices recovery finishes, so we only have to maintain it for the * local process until recovery ends. */ if (!RecoveryInProgress()) read_upto = GetFlushRecPtr(); else read_upto = GetXLogReplayRecPtr(&ThisTimeLineID); *pageTLI = ThisTimeLineID; /* * Check which timeline to get the record from. * * We have to do it each time through the loop because if we're in * recovery as a cascading standby, the current timeline might've * become historical. We can't rely on RecoveryInProgress() because in * a standby configuration like * * A => B => C * * if we're a logical decoding session on C, and B gets promoted, our * timeline will change while we remain in recovery. * * We can't just keep reading from the old timeline as the last WAL * archive in the timeline will get renamed to .partial by * StartupXLOG(). * * If that happens after our caller updated ThisTimeLineID but before * we actually read the xlog page, we might still try to read from the * old (now renamed) segment and fail. There's not much we can do * about this, but it can only happen when we're a leaf of a cascading * standby whose master gets promoted while we're decoding, so a * one-off ERROR isn't too bad. */ XLogReadDetermineTimeline(state, targetPagePtr, reqLen); if (state->currTLI == ThisTimeLineID) { if (loc <= read_upto) break; CHECK_FOR_INTERRUPTS(); pg_usleep(1000L); } else { /* * We're on a historical timeline, so limit reading to the switch * point where we moved to the next timeline. * * We don't need to GetFlushRecPtr or GetXLogReplayRecPtr. We know * about the new timeline, so we must've received past the end of * it. */ read_upto = state->currTLIValidUntil; /* * Setting pageTLI to our wanted record's TLI is slightly wrong; * the page might begin on an older timeline if it contains a * timeline switch, since its xlog segment will have been copied * from the prior timeline. This is pretty harmless though, as * nothing cares so long as the timeline doesn't go backwards. We * should read the page header instead; FIXME someday. */ *pageTLI = state->currTLI; /* No need to wait on a historical timeline */ break; } } if (targetPagePtr + XLOG_BLCKSZ <= read_upto) { /* * more than one block available; read only that block, have caller * come back if they need more. */ count = XLOG_BLCKSZ; } else if (targetPagePtr + reqLen > read_upto) { /* not enough data there */ return -1; } else { /* enough bytes available to satisfy the request */ count = read_upto - targetPagePtr; } /* * Even though we just determined how much of the page can be validly read * as 'count', read the whole page anyway. It's guaranteed to be * zero-padded up to the page boundary if it's incomplete. */ XLogRead(cur_page, *pageTLI, targetPagePtr, XLOG_BLCKSZ); /* number of valid bytes in the buffer */ return count; }