/*------------------------------------------------------------------------- * * xlogreader.c * Generic XLog reading facility * * Portions Copyright (c) 2013-2023, PostgreSQL Global Development Group * * IDENTIFICATION * src/backend/access/transam/xlogreader.c * * NOTES * See xlogreader.h for more notes on this facility. * * This file is compiled as both front-end and backend code, so it * may not use ereport, server-defined static variables, etc. *------------------------------------------------------------------------- */ #include "postgres.h" #include #ifdef USE_LZ4 #include #endif #ifdef USE_ZSTD #include #endif #include "access/transam.h" #include "access/xlog_internal.h" #include "access/xlogreader.h" #include "access/xlogrecord.h" #include "catalog/pg_control.h" #include "common/pg_lzcompress.h" #include "replication/origin.h" #ifndef FRONTEND #include "miscadmin.h" #include "pgstat.h" #include "utils/memutils.h" #else #include "common/logging.h" #endif static void report_invalid_record(XLogReaderState *state, const char *fmt,...) pg_attribute_printf(2, 3); static bool allocate_recordbuf(XLogReaderState *state, uint32 reclength); static int ReadPageInternal(XLogReaderState *state, XLogRecPtr pageptr, int reqLen); static void XLogReaderInvalReadState(XLogReaderState *state); static XLogPageReadResult XLogDecodeNextRecord(XLogReaderState *state, bool nonblocking); static bool ValidXLogRecordHeader(XLogReaderState *state, XLogRecPtr RecPtr, XLogRecPtr PrevRecPtr, XLogRecord *record, bool randAccess); static bool ValidXLogRecord(XLogReaderState *state, XLogRecord *record, XLogRecPtr recptr); static void ResetDecoder(XLogReaderState *state); static void WALOpenSegmentInit(WALOpenSegment *seg, WALSegmentContext *segcxt, int segsize, const char *waldir); /* size of the buffer allocated for error message. */ #define MAX_ERRORMSG_LEN 1000 /* * Default size; large enough that typical users of XLogReader won't often need * to use the 'oversized' memory allocation code path. */ #define DEFAULT_DECODE_BUFFER_SIZE (64 * 1024) /* * Construct a string in state->errormsg_buf explaining what's wrong with * the current record being read. */ static void report_invalid_record(XLogReaderState *state, const char *fmt,...) { va_list args; fmt = _(fmt); va_start(args, fmt); vsnprintf(state->errormsg_buf, MAX_ERRORMSG_LEN, fmt, args); va_end(args); state->errormsg_deferred = true; } /* * Set the size of the decoding buffer. A pointer to a caller supplied memory * region may also be passed in, in which case non-oversized records will be * decoded there. */ void XLogReaderSetDecodeBuffer(XLogReaderState *state, void *buffer, size_t size) { Assert(state->decode_buffer == NULL); state->decode_buffer = buffer; state->decode_buffer_size = size; state->decode_buffer_tail = buffer; state->decode_buffer_head = buffer; } /* * Allocate and initialize a new XLogReader. * * Returns NULL if the xlogreader couldn't be allocated. */ XLogReaderState * XLogReaderAllocate(int wal_segment_size, const char *waldir, XLogReaderRoutine *routine, void *private_data) { XLogReaderState *state; state = (XLogReaderState *) palloc_extended(sizeof(XLogReaderState), MCXT_ALLOC_NO_OOM | MCXT_ALLOC_ZERO); if (!state) return NULL; /* initialize caller-provided support functions */ state->routine = *routine; /* * Permanently allocate readBuf. We do it this way, rather than just * making a static array, for two reasons: (1) no need to waste the * storage in most instantiations of the backend; (2) a static char array * isn't guaranteed to have any particular alignment, whereas * palloc_extended() will provide MAXALIGN'd storage. */ state->readBuf = (char *) palloc_extended(XLOG_BLCKSZ, MCXT_ALLOC_NO_OOM); if (!state->readBuf) { pfree(state); return NULL; } /* Initialize segment info. */ WALOpenSegmentInit(&state->seg, &state->segcxt, wal_segment_size, waldir); /* system_identifier initialized to zeroes above */ state->private_data = private_data; /* ReadRecPtr, EndRecPtr and readLen initialized to zeroes above */ state->errormsg_buf = palloc_extended(MAX_ERRORMSG_LEN + 1, MCXT_ALLOC_NO_OOM); if (!state->errormsg_buf) { pfree(state->readBuf); pfree(state); return NULL; } state->errormsg_buf[0] = '\0'; /* * Allocate an initial readRecordBuf of minimal size, which can later be * enlarged if necessary. */ if (!allocate_recordbuf(state, 0)) { pfree(state->errormsg_buf); pfree(state->readBuf); pfree(state); return NULL; } return state; } void XLogReaderFree(XLogReaderState *state) { if (state->seg.ws_file != -1) state->routine.segment_close(state); if (state->decode_buffer && state->free_decode_buffer) pfree(state->decode_buffer); pfree(state->errormsg_buf); if (state->readRecordBuf) pfree(state->readRecordBuf); pfree(state->readBuf); pfree(state); } /* * Allocate readRecordBuf to fit a record of at least the given length. * Returns true if successful, false if out of memory. * * readRecordBufSize is set to the new buffer size. * * To avoid useless small increases, round its size to a multiple of * XLOG_BLCKSZ, and make sure it's at least 5*Max(BLCKSZ, XLOG_BLCKSZ) to start * with. (That is enough for all "normal" records, but very large commit or * abort records might need more space.) */ static bool allocate_recordbuf(XLogReaderState *state, uint32 reclength) { uint32 newSize = reclength; newSize += XLOG_BLCKSZ - (newSize % XLOG_BLCKSZ); newSize = Max(newSize, 5 * Max(BLCKSZ, XLOG_BLCKSZ)); #ifndef FRONTEND /* * Note that in much unlucky circumstances, the random data read from a * recycled segment can cause this routine to be called with a size * causing a hard failure at allocation. For a standby, this would cause * the instance to stop suddenly with a hard failure, preventing it to * retry fetching WAL from one of its sources which could allow it to move * on with replay without a manual restart. If the data comes from a past * recycled segment and is still valid, then the allocation may succeed * but record checks are going to fail so this would be short-lived. If * the allocation fails because of a memory shortage, then this is not a * hard failure either per the guarantee given by MCXT_ALLOC_NO_OOM. */ if (!AllocSizeIsValid(newSize)) return false; #endif if (state->readRecordBuf) pfree(state->readRecordBuf); state->readRecordBuf = (char *) palloc_extended(newSize, MCXT_ALLOC_NO_OOM); if (state->readRecordBuf == NULL) { state->readRecordBufSize = 0; return false; } state->readRecordBufSize = newSize; return true; } /* * Initialize the passed segment structs. */ static void WALOpenSegmentInit(WALOpenSegment *seg, WALSegmentContext *segcxt, int segsize, const char *waldir) { seg->ws_file = -1; seg->ws_segno = 0; seg->ws_tli = 0; segcxt->ws_segsize = segsize; if (waldir) snprintf(segcxt->ws_dir, MAXPGPATH, "%s", waldir); } /* * Begin reading WAL at 'RecPtr'. * * 'RecPtr' should point to the beginning of a valid WAL record. Pointing at * the beginning of a page is also OK, if there is a new record right after * the page header, i.e. not a continuation. * * This does not make any attempt to read the WAL yet, and hence cannot fail. * If the starting address is not correct, the first call to XLogReadRecord() * will error out. */ void XLogBeginRead(XLogReaderState *state, XLogRecPtr RecPtr) { Assert(!XLogRecPtrIsInvalid(RecPtr)); ResetDecoder(state); /* Begin at the passed-in record pointer. */ state->EndRecPtr = RecPtr; state->NextRecPtr = RecPtr; state->ReadRecPtr = InvalidXLogRecPtr; state->DecodeRecPtr = InvalidXLogRecPtr; } /* * Release the last record that was returned by XLogNextRecord(), if any, to * free up space. Returns the LSN past the end of the record. */ XLogRecPtr XLogReleasePreviousRecord(XLogReaderState *state) { DecodedXLogRecord *record; XLogRecPtr next_lsn; if (!state->record) return InvalidXLogRecPtr; /* * Remove it from the decoded record queue. It must be the oldest item * decoded, decode_queue_head. */ record = state->record; next_lsn = record->next_lsn; Assert(record == state->decode_queue_head); state->record = NULL; state->decode_queue_head = record->next; /* It might also be the newest item decoded, decode_queue_tail. */ if (state->decode_queue_tail == record) state->decode_queue_tail = NULL; /* Release the space. */ if (unlikely(record->oversized)) { /* It's not in the decode buffer, so free it to release space. */ pfree(record); } else { /* It must be the head (oldest) record in the decode buffer. */ Assert(state->decode_buffer_head == (char *) record); /* * We need to update head to point to the next record that is in the * decode buffer, if any, being careful to skip oversized ones * (they're not in the decode buffer). */ record = record->next; while (unlikely(record && record->oversized)) record = record->next; if (record) { /* Adjust head to release space up to the next record. */ state->decode_buffer_head = (char *) record; } else { /* * Otherwise we might as well just reset head and tail to the * start of the buffer space, because we're empty. This means * we'll keep overwriting the same piece of memory if we're not * doing any prefetching. */ state->decode_buffer_head = state->decode_buffer; state->decode_buffer_tail = state->decode_buffer; } } return next_lsn; } /* * Attempt to read an XLOG record. * * XLogBeginRead() or XLogFindNextRecord() and then XLogReadAhead() must be * called before the first call to XLogNextRecord(). This functions returns * records and errors that were put into an internal queue by XLogReadAhead(). * * On success, a record is returned. * * The returned record (or *errormsg) points to an internal buffer that's * valid until the next call to XLogNextRecord. */ DecodedXLogRecord * XLogNextRecord(XLogReaderState *state, char **errormsg) { /* Release the last record returned by XLogNextRecord(). */ XLogReleasePreviousRecord(state); if (state->decode_queue_head == NULL) { *errormsg = NULL; if (state->errormsg_deferred) { if (state->errormsg_buf[0] != '\0') *errormsg = state->errormsg_buf; state->errormsg_deferred = false; } /* * state->EndRecPtr is expected to have been set by the last call to * XLogBeginRead() or XLogNextRecord(), and is the location of the * error. */ Assert(!XLogRecPtrIsInvalid(state->EndRecPtr)); return NULL; } /* * Record this as the most recent record returned, so that we'll release * it next time. This also exposes it to the traditional * XLogRecXXX(xlogreader) macros, which work with the decoder rather than * the record for historical reasons. */ state->record = state->decode_queue_head; /* * Update the pointers to the beginning and one-past-the-end of this * record, again for the benefit of historical code that expected the * decoder to track this rather than accessing these fields of the record * itself. */ state->ReadRecPtr = state->record->lsn; state->EndRecPtr = state->record->next_lsn; *errormsg = NULL; return state->record; } /* * Attempt to read an XLOG record. * * XLogBeginRead() or XLogFindNextRecord() must be called before the first call * to XLogReadRecord(). * * If the page_read callback fails to read the requested data, NULL is * returned. The callback is expected to have reported the error; errormsg * is set to NULL. * * If the reading fails for some other reason, NULL is also returned, and * *errormsg is set to a string with details of the failure. * * The returned pointer (or *errormsg) points to an internal buffer that's * valid until the next call to XLogReadRecord. */ XLogRecord * XLogReadRecord(XLogReaderState *state, char **errormsg) { DecodedXLogRecord *decoded; /* * Release last returned record, if there is one. We need to do this so * that we can check for empty decode queue accurately. */ XLogReleasePreviousRecord(state); /* * Call XLogReadAhead() in blocking mode to make sure there is something * in the queue, though we don't use the result. */ if (!XLogReaderHasQueuedRecordOrError(state)) XLogReadAhead(state, false /* nonblocking */ ); /* Consume the head record or error. */ decoded = XLogNextRecord(state, errormsg); if (decoded) { /* * This function returns a pointer to the record's header, not the * actual decoded record. The caller will access the decoded record * through the XLogRecGetXXX() macros, which reach the decoded * recorded as xlogreader->record. */ Assert(state->record == decoded); return &decoded->header; } return NULL; } /* * Allocate space for a decoded record. The only member of the returned * object that is initialized is the 'oversized' flag, indicating that the * decoded record wouldn't fit in the decode buffer and must eventually be * freed explicitly. * * The caller is responsible for adjusting decode_buffer_tail with the real * size after successfully decoding a record into this space. This way, if * decoding fails, then there is nothing to undo unless the 'oversized' flag * was set and pfree() must be called. * * Return NULL if there is no space in the decode buffer and allow_oversized * is false, or if memory allocation fails for an oversized buffer. */ static DecodedXLogRecord * XLogReadRecordAlloc(XLogReaderState *state, size_t xl_tot_len, bool allow_oversized) { size_t required_space = DecodeXLogRecordRequiredSpace(xl_tot_len); DecodedXLogRecord *decoded = NULL; /* Allocate a circular decode buffer if we don't have one already. */ if (unlikely(state->decode_buffer == NULL)) { if (state->decode_buffer_size == 0) state->decode_buffer_size = DEFAULT_DECODE_BUFFER_SIZE; state->decode_buffer = palloc(state->decode_buffer_size); state->decode_buffer_head = state->decode_buffer; state->decode_buffer_tail = state->decode_buffer; state->free_decode_buffer = true; } /* Try to allocate space in the circular decode buffer. */ if (state->decode_buffer_tail >= state->decode_buffer_head) { /* Empty, or tail is to the right of head. */ if (state->decode_buffer_tail + required_space <= state->decode_buffer + state->decode_buffer_size) { /* There is space between tail and end. */ decoded = (DecodedXLogRecord *) state->decode_buffer_tail; decoded->oversized = false; return decoded; } else if (state->decode_buffer + required_space < state->decode_buffer_head) { /* There is space between start and head. */ decoded = (DecodedXLogRecord *) state->decode_buffer; decoded->oversized = false; return decoded; } } else { /* Tail is to the left of head. */ if (state->decode_buffer_tail + required_space < state->decode_buffer_head) { /* There is space between tail and head. */ decoded = (DecodedXLogRecord *) state->decode_buffer_tail; decoded->oversized = false; return decoded; } } /* Not enough space in the decode buffer. Are we allowed to allocate? */ if (allow_oversized) { decoded = palloc_extended(required_space, MCXT_ALLOC_NO_OOM); if (decoded == NULL) return NULL; decoded->oversized = true; return decoded; } return NULL; } static XLogPageReadResult XLogDecodeNextRecord(XLogReaderState *state, bool nonblocking) { XLogRecPtr RecPtr; XLogRecord *record; XLogRecPtr targetPagePtr; bool randAccess; uint32 len, total_len; uint32 targetRecOff; uint32 pageHeaderSize; bool assembled; bool gotheader; int readOff; DecodedXLogRecord *decoded; char *errormsg; /* not used */ /* * randAccess indicates whether to verify the previous-record pointer of * the record we're reading. We only do this if we're reading * sequentially, which is what we initially assume. */ randAccess = false; /* reset error state */ state->errormsg_buf[0] = '\0'; decoded = NULL; state->abortedRecPtr = InvalidXLogRecPtr; state->missingContrecPtr = InvalidXLogRecPtr; RecPtr = state->NextRecPtr; if (state->DecodeRecPtr != InvalidXLogRecPtr) { /* read the record after the one we just read */ /* * NextRecPtr is pointing to end+1 of the previous WAL record. If * we're at a page boundary, no more records can fit on the current * page. We must skip over the page header, but we can't do that until * we've read in the page, since the header size is variable. */ } else { /* * Caller supplied a position to start at. * * In this case, NextRecPtr should already be pointing either to a * valid record starting position or alternatively to the beginning of * a page. See the header comments for XLogBeginRead. */ Assert(RecPtr % XLOG_BLCKSZ == 0 || XRecOffIsValid(RecPtr)); randAccess = true; } restart: state->nonblocking = nonblocking; state->currRecPtr = RecPtr; assembled = false; targetPagePtr = RecPtr - (RecPtr % XLOG_BLCKSZ); targetRecOff = RecPtr % XLOG_BLCKSZ; /* * Read the page containing the record into state->readBuf. Request enough * byte to cover the whole record header, or at least the part of it that * fits on the same page. */ readOff = ReadPageInternal(state, targetPagePtr, Min(targetRecOff + SizeOfXLogRecord, XLOG_BLCKSZ)); if (readOff == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readOff < 0) goto err; /* * ReadPageInternal always returns at least the page header, so we can * examine it now. */ pageHeaderSize = XLogPageHeaderSize((XLogPageHeader) state->readBuf); if (targetRecOff == 0) { /* * At page start, so skip over page header. */ RecPtr += pageHeaderSize; targetRecOff = pageHeaderSize; } else if (targetRecOff < pageHeaderSize) { report_invalid_record(state, "invalid record offset at %X/%X: expected at least %u, got %u", LSN_FORMAT_ARGS(RecPtr), pageHeaderSize, targetRecOff); goto err; } if ((((XLogPageHeader) state->readBuf)->xlp_info & XLP_FIRST_IS_CONTRECORD) && targetRecOff == pageHeaderSize) { report_invalid_record(state, "contrecord is requested by %X/%X", LSN_FORMAT_ARGS(RecPtr)); goto err; } /* ReadPageInternal has verified the page header */ Assert(pageHeaderSize <= readOff); /* * Read the record length. * * NB: Even though we use an XLogRecord pointer here, the whole record * header might not fit on this page. xl_tot_len is the first field of the * struct, so it must be on this page (the records are MAXALIGNed), but we * cannot access any other fields until we've verified that we got the * whole header. */ record = (XLogRecord *) (state->readBuf + RecPtr % XLOG_BLCKSZ); total_len = record->xl_tot_len; /* * If the whole record header is on this page, validate it immediately. * Otherwise do just a basic sanity check on xl_tot_len, and validate the * rest of the header after reading it from the next page. The xl_tot_len * check is necessary here to ensure that we enter the "Need to reassemble * record" code path below; otherwise we might fail to apply * ValidXLogRecordHeader at all. */ if (targetRecOff <= XLOG_BLCKSZ - SizeOfXLogRecord) { if (!ValidXLogRecordHeader(state, RecPtr, state->DecodeRecPtr, record, randAccess)) goto err; gotheader = true; } else { /* XXX: more validation should be done here */ if (total_len < SizeOfXLogRecord) { report_invalid_record(state, "invalid record length at %X/%X: expected at least %u, got %u", LSN_FORMAT_ARGS(RecPtr), (uint32) SizeOfXLogRecord, total_len); goto err; } gotheader = false; } /* * Find space to decode this record. Don't allow oversized allocation if * the caller requested nonblocking. Otherwise, we *have* to try to * decode the record now because the caller has nothing else to do, so * allow an oversized record to be palloc'd if that turns out to be * necessary. */ decoded = XLogReadRecordAlloc(state, total_len, !nonblocking /* allow_oversized */ ); if (decoded == NULL) { /* * There is no space in the decode buffer. The caller should help * with that problem by consuming some records. */ if (nonblocking) return XLREAD_WOULDBLOCK; /* We failed to allocate memory for an oversized record. */ report_invalid_record(state, "out of memory while trying to decode a record of length %u", total_len); goto err; } len = XLOG_BLCKSZ - RecPtr % XLOG_BLCKSZ; if (total_len > len) { /* Need to reassemble record */ char *contdata; XLogPageHeader pageHeader; char *buffer; uint32 gotlen; assembled = true; /* * Enlarge readRecordBuf as needed. */ if (total_len > state->readRecordBufSize && !allocate_recordbuf(state, total_len)) { /* We treat this as a "bogus data" condition */ report_invalid_record(state, "record length %u at %X/%X too long", total_len, LSN_FORMAT_ARGS(RecPtr)); goto err; } /* Copy the first fragment of the record from the first page. */ memcpy(state->readRecordBuf, state->readBuf + RecPtr % XLOG_BLCKSZ, len); buffer = state->readRecordBuf + len; gotlen = len; do { /* Calculate pointer to beginning of next page */ targetPagePtr += XLOG_BLCKSZ; /* Wait for the next page to become available */ readOff = ReadPageInternal(state, targetPagePtr, Min(total_len - gotlen + SizeOfXLogShortPHD, XLOG_BLCKSZ)); if (readOff == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readOff < 0) goto err; Assert(SizeOfXLogShortPHD <= readOff); pageHeader = (XLogPageHeader) state->readBuf; /* * If we were expecting a continuation record and got an * "overwrite contrecord" flag, that means the continuation record * was overwritten with a different record. Restart the read by * assuming the address to read is the location where we found * this flag; but keep track of the LSN of the record we were * reading, for later verification. */ if (pageHeader->xlp_info & XLP_FIRST_IS_OVERWRITE_CONTRECORD) { state->overwrittenRecPtr = RecPtr; RecPtr = targetPagePtr; goto restart; } /* Check that the continuation on next page looks valid */ if (!(pageHeader->xlp_info & XLP_FIRST_IS_CONTRECORD)) { report_invalid_record(state, "there is no contrecord flag at %X/%X", LSN_FORMAT_ARGS(RecPtr)); goto err; } /* * Cross-check that xlp_rem_len agrees with how much of the record * we expect there to be left. */ if (pageHeader->xlp_rem_len == 0 || total_len != (pageHeader->xlp_rem_len + gotlen)) { report_invalid_record(state, "invalid contrecord length %u (expected %lld) at %X/%X", pageHeader->xlp_rem_len, ((long long) total_len) - gotlen, LSN_FORMAT_ARGS(RecPtr)); goto err; } /* Append the continuation from this page to the buffer */ pageHeaderSize = XLogPageHeaderSize(pageHeader); if (readOff < pageHeaderSize) readOff = ReadPageInternal(state, targetPagePtr, pageHeaderSize); Assert(pageHeaderSize <= readOff); contdata = (char *) state->readBuf + pageHeaderSize; len = XLOG_BLCKSZ - pageHeaderSize; if (pageHeader->xlp_rem_len < len) len = pageHeader->xlp_rem_len; if (readOff < pageHeaderSize + len) readOff = ReadPageInternal(state, targetPagePtr, pageHeaderSize + len); memcpy(buffer, (char *) contdata, len); buffer += len; gotlen += len; /* If we just reassembled the record header, validate it. */ if (!gotheader) { record = (XLogRecord *) state->readRecordBuf; if (!ValidXLogRecordHeader(state, RecPtr, state->DecodeRecPtr, record, randAccess)) goto err; gotheader = true; } } while (gotlen < total_len); Assert(gotheader); record = (XLogRecord *) state->readRecordBuf; if (!ValidXLogRecord(state, record, RecPtr)) goto err; pageHeaderSize = XLogPageHeaderSize((XLogPageHeader) state->readBuf); state->DecodeRecPtr = RecPtr; state->NextRecPtr = targetPagePtr + pageHeaderSize + MAXALIGN(pageHeader->xlp_rem_len); } else { /* Wait for the record data to become available */ readOff = ReadPageInternal(state, targetPagePtr, Min(targetRecOff + total_len, XLOG_BLCKSZ)); if (readOff == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readOff < 0) goto err; /* Record does not cross a page boundary */ if (!ValidXLogRecord(state, record, RecPtr)) goto err; state->NextRecPtr = RecPtr + MAXALIGN(total_len); state->DecodeRecPtr = RecPtr; } /* * Special processing if it's an XLOG SWITCH record */ if (record->xl_rmid == RM_XLOG_ID && (record->xl_info & ~XLR_INFO_MASK) == XLOG_SWITCH) { /* Pretend it extends to end of segment */ state->NextRecPtr += state->segcxt.ws_segsize - 1; state->NextRecPtr -= XLogSegmentOffset(state->NextRecPtr, state->segcxt.ws_segsize); } if (DecodeXLogRecord(state, decoded, record, RecPtr, &errormsg)) { /* Record the location of the next record. */ decoded->next_lsn = state->NextRecPtr; /* * If it's in the decode buffer, mark the decode buffer space as * occupied. */ if (!decoded->oversized) { /* The new decode buffer head must be MAXALIGNed. */ Assert(decoded->size == MAXALIGN(decoded->size)); if ((char *) decoded == state->decode_buffer) state->decode_buffer_tail = state->decode_buffer + decoded->size; else state->decode_buffer_tail += decoded->size; } /* Insert it into the queue of decoded records. */ Assert(state->decode_queue_tail != decoded); if (state->decode_queue_tail) state->decode_queue_tail->next = decoded; state->decode_queue_tail = decoded; if (!state->decode_queue_head) state->decode_queue_head = decoded; return XLREAD_SUCCESS; } else return XLREAD_FAIL; err: if (assembled) { /* * We get here when a record that spans multiple pages needs to be * assembled, but something went wrong -- perhaps a contrecord piece * was lost. If caller is WAL replay, it will know where the aborted * record was and where to direct followup WAL to be written, marking * the next piece with XLP_FIRST_IS_OVERWRITE_CONTRECORD, which will * in turn signal downstream WAL consumers that the broken WAL record * is to be ignored. */ state->abortedRecPtr = RecPtr; state->missingContrecPtr = targetPagePtr; /* * If we got here without reporting an error, report one now so that * XLogPrefetcherReadRecord() doesn't bring us back a second time and * clobber the above state. Otherwise, the existing error takes * precedence. */ if (!state->errormsg_buf[0]) report_invalid_record(state, "missing contrecord at %X/%X", LSN_FORMAT_ARGS(RecPtr)); } if (decoded && decoded->oversized) pfree(decoded); /* * Invalidate the read state. We might read from a different source after * failure. */ XLogReaderInvalReadState(state); /* * If an error was written to errmsg_buf, it'll be returned to the caller * of XLogReadRecord() after all successfully decoded records from the * read queue. */ return XLREAD_FAIL; } /* * Try to decode the next available record, and return it. The record will * also be returned to XLogNextRecord(), which must be called to 'consume' * each record. * * If nonblocking is true, may return NULL due to lack of data or WAL decoding * space. */ DecodedXLogRecord * XLogReadAhead(XLogReaderState *state, bool nonblocking) { XLogPageReadResult result; if (state->errormsg_deferred) return NULL; result = XLogDecodeNextRecord(state, nonblocking); if (result == XLREAD_SUCCESS) { Assert(state->decode_queue_tail != NULL); return state->decode_queue_tail; } return NULL; } /* * Read a single xlog page including at least [pageptr, reqLen] of valid data * via the page_read() callback. * * Returns XLREAD_FAIL if the required page cannot be read for some * reason; errormsg_buf is set in that case (unless the error occurs in the * page_read callback). * * Returns XLREAD_WOULDBLOCK if the requested data can't be read without * waiting. This can be returned only if the installed page_read callback * respects the state->nonblocking flag, and cannot read the requested data * immediately. * * We fetch the page from a reader-local cache if we know we have the required * data and if there hasn't been any error since caching the data. */ static int ReadPageInternal(XLogReaderState *state, XLogRecPtr pageptr, int reqLen) { int readLen; uint32 targetPageOff; XLogSegNo targetSegNo; XLogPageHeader hdr; Assert((pageptr % XLOG_BLCKSZ) == 0); XLByteToSeg(pageptr, targetSegNo, state->segcxt.ws_segsize); targetPageOff = XLogSegmentOffset(pageptr, state->segcxt.ws_segsize); /* check whether we have all the requested data already */ if (targetSegNo == state->seg.ws_segno && targetPageOff == state->segoff && reqLen <= state->readLen) return state->readLen; /* * Invalidate contents of internal buffer before read attempt. Just set * the length to 0, rather than a full XLogReaderInvalReadState(), so we * don't forget the segment we last successfully read. */ state->readLen = 0; /* * Data is not in our buffer. * * Every time we actually read the segment, even if we looked at parts of * it before, we need to do verification as the page_read callback might * now be rereading data from a different source. * * Whenever switching to a new WAL segment, we read the first page of the * file and validate its header, even if that's not where the target * record is. This is so that we can check the additional identification * info that is present in the first page's "long" header. */ if (targetSegNo != state->seg.ws_segno && targetPageOff != 0) { XLogRecPtr targetSegmentPtr = pageptr - targetPageOff; readLen = state->routine.page_read(state, targetSegmentPtr, XLOG_BLCKSZ, state->currRecPtr, state->readBuf); if (readLen == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readLen < 0) goto err; /* we can be sure to have enough WAL available, we scrolled back */ Assert(readLen == XLOG_BLCKSZ); if (!XLogReaderValidatePageHeader(state, targetSegmentPtr, state->readBuf)) goto err; } /* * First, read the requested data length, but at least a short page header * so that we can validate it. */ readLen = state->routine.page_read(state, pageptr, Max(reqLen, SizeOfXLogShortPHD), state->currRecPtr, state->readBuf); if (readLen == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readLen < 0) goto err; Assert(readLen <= XLOG_BLCKSZ); /* Do we have enough data to check the header length? */ if (readLen <= SizeOfXLogShortPHD) goto err; Assert(readLen >= reqLen); hdr = (XLogPageHeader) state->readBuf; /* still not enough */ if (readLen < XLogPageHeaderSize(hdr)) { readLen = state->routine.page_read(state, pageptr, XLogPageHeaderSize(hdr), state->currRecPtr, state->readBuf); if (readLen == XLREAD_WOULDBLOCK) return XLREAD_WOULDBLOCK; else if (readLen < 0) goto err; } /* * Now that we know we have the full header, validate it. */ if (!XLogReaderValidatePageHeader(state, pageptr, (char *) hdr)) goto err; /* update read state information */ state->seg.ws_segno = targetSegNo; state->segoff = targetPageOff; state->readLen = readLen; return readLen; err: XLogReaderInvalReadState(state); return XLREAD_FAIL; } /* * Invalidate the xlogreader's read state to force a re-read. */ static void XLogReaderInvalReadState(XLogReaderState *state) { state->seg.ws_segno = 0; state->segoff = 0; state->readLen = 0; } /* * Validate an XLOG record header. * * This is just a convenience subroutine to avoid duplicated code in * XLogReadRecord. It's not intended for use from anywhere else. */ static bool ValidXLogRecordHeader(XLogReaderState *state, XLogRecPtr RecPtr, XLogRecPtr PrevRecPtr, XLogRecord *record, bool randAccess) { if (record->xl_tot_len < SizeOfXLogRecord) { report_invalid_record(state, "invalid record length at %X/%X: expected at least %u, got %u", LSN_FORMAT_ARGS(RecPtr), (uint32) SizeOfXLogRecord, record->xl_tot_len); return false; } if (!RmgrIdIsValid(record->xl_rmid)) { report_invalid_record(state, "invalid resource manager ID %u at %X/%X", record->xl_rmid, LSN_FORMAT_ARGS(RecPtr)); return false; } if (randAccess) { /* * We can't exactly verify the prev-link, but surely it should be less * than the record's own address. */ if (!(record->xl_prev < RecPtr)) { report_invalid_record(state, "record with incorrect prev-link %X/%X at %X/%X", LSN_FORMAT_ARGS(record->xl_prev), LSN_FORMAT_ARGS(RecPtr)); return false; } } else { /* * Record's prev-link should exactly match our previous location. This * check guards against torn WAL pages where a stale but valid-looking * WAL record starts on a sector boundary. */ if (record->xl_prev != PrevRecPtr) { report_invalid_record(state, "record with incorrect prev-link %X/%X at %X/%X", LSN_FORMAT_ARGS(record->xl_prev), LSN_FORMAT_ARGS(RecPtr)); return false; } } return true; } /* * CRC-check an XLOG record. We do not believe the contents of an XLOG * record (other than to the minimal extent of computing the amount of * data to read in) until we've checked the CRCs. * * We assume all of the record (that is, xl_tot_len bytes) has been read * into memory at *record. Also, ValidXLogRecordHeader() has accepted the * record's header, which means in particular that xl_tot_len is at least * SizeOfXLogRecord. */ static bool ValidXLogRecord(XLogReaderState *state, XLogRecord *record, XLogRecPtr recptr) { pg_crc32c crc; /* Calculate the CRC */ INIT_CRC32C(crc); COMP_CRC32C(crc, ((char *) record) + SizeOfXLogRecord, record->xl_tot_len - SizeOfXLogRecord); /* include the record header last */ COMP_CRC32C(crc, (char *) record, offsetof(XLogRecord, xl_crc)); FIN_CRC32C(crc); if (!EQ_CRC32C(record->xl_crc, crc)) { report_invalid_record(state, "incorrect resource manager data checksum in record at %X/%X", LSN_FORMAT_ARGS(recptr)); return false; } return true; } /* * Validate a page header. * * Check if 'phdr' is valid as the header of the XLog page at position * 'recptr'. */ bool XLogReaderValidatePageHeader(XLogReaderState *state, XLogRecPtr recptr, char *phdr) { XLogSegNo segno; int32 offset; XLogPageHeader hdr = (XLogPageHeader) phdr; Assert((recptr % XLOG_BLCKSZ) == 0); XLByteToSeg(recptr, segno, state->segcxt.ws_segsize); offset = XLogSegmentOffset(recptr, state->segcxt.ws_segsize); if (hdr->xlp_magic != XLOG_PAGE_MAGIC) { char fname[MAXFNAMELEN]; XLogFileName(fname, state->seg.ws_tli, segno, state->segcxt.ws_segsize); report_invalid_record(state, "invalid magic number %04X in WAL segment %s, LSN %X/%X, offset %u", hdr->xlp_magic, fname, LSN_FORMAT_ARGS(recptr), offset); return false; } if ((hdr->xlp_info & ~XLP_ALL_FLAGS) != 0) { char fname[MAXFNAMELEN]; XLogFileName(fname, state->seg.ws_tli, segno, state->segcxt.ws_segsize); report_invalid_record(state, "invalid info bits %04X in WAL segment %s, LSN %X/%X, offset %u", hdr->xlp_info, fname, LSN_FORMAT_ARGS(recptr), offset); return false; } if (hdr->xlp_info & XLP_LONG_HEADER) { XLogLongPageHeader longhdr = (XLogLongPageHeader) hdr; if (state->system_identifier && longhdr->xlp_sysid != state->system_identifier) { report_invalid_record(state, "WAL file is from different database system: WAL file database system identifier is %llu, pg_control database system identifier is %llu", (unsigned long long) longhdr->xlp_sysid, (unsigned long long) state->system_identifier); return false; } else if (longhdr->xlp_seg_size != state->segcxt.ws_segsize) { report_invalid_record(state, "WAL file is from different database system: incorrect segment size in page header"); return false; } else if (longhdr->xlp_xlog_blcksz != XLOG_BLCKSZ) { report_invalid_record(state, "WAL file is from different database system: incorrect XLOG_BLCKSZ in page header"); return false; } } else if (offset == 0) { char fname[MAXFNAMELEN]; XLogFileName(fname, state->seg.ws_tli, segno, state->segcxt.ws_segsize); /* hmm, first page of file doesn't have a long header? */ report_invalid_record(state, "invalid info bits %04X in WAL segment %s, LSN %X/%X, offset %u", hdr->xlp_info, fname, LSN_FORMAT_ARGS(recptr), offset); return false; } /* * Check that the address on the page agrees with what we expected. This * check typically fails when an old WAL segment is recycled, and hasn't * yet been overwritten with new data yet. */ if (hdr->xlp_pageaddr != recptr) { char fname[MAXFNAMELEN]; XLogFileName(fname, state->seg.ws_tli, segno, state->segcxt.ws_segsize); report_invalid_record(state, "unexpected pageaddr %X/%X in WAL segment %s, LSN %X/%X, offset %u", LSN_FORMAT_ARGS(hdr->xlp_pageaddr), fname, LSN_FORMAT_ARGS(recptr), offset); return false; } /* * Since child timelines are always assigned a TLI greater than their * immediate parent's TLI, we should never see TLI go backwards across * successive pages of a consistent WAL sequence. * * Sometimes we re-read a segment that's already been (partially) read. So * we only verify TLIs for pages that are later than the last remembered * LSN. */ if (recptr > state->latestPagePtr) { if (hdr->xlp_tli < state->latestPageTLI) { char fname[MAXFNAMELEN]; XLogFileName(fname, state->seg.ws_tli, segno, state->segcxt.ws_segsize); report_invalid_record(state, "out-of-sequence timeline ID %u (after %u) in WAL segment %s, LSN %X/%X, offset %u", hdr->xlp_tli, state->latestPageTLI, fname, LSN_FORMAT_ARGS(recptr), offset); return false; } } state->latestPagePtr = recptr; state->latestPageTLI = hdr->xlp_tli; return true; } /* * Forget about an error produced by XLogReaderValidatePageHeader(). */ void XLogReaderResetError(XLogReaderState *state) { state->errormsg_buf[0] = '\0'; state->errormsg_deferred = false; } /* * Find the first record with an lsn >= RecPtr. * * This is different from XLogBeginRead() in that RecPtr doesn't need to point * to a valid record boundary. Useful for checking whether RecPtr is a valid * xlog address for reading, and to find the first valid address after some * address when dumping records for debugging purposes. * * This positions the reader, like XLogBeginRead(), so that the next call to * XLogReadRecord() will read the next valid record. */ XLogRecPtr XLogFindNextRecord(XLogReaderState *state, XLogRecPtr RecPtr) { XLogRecPtr tmpRecPtr; XLogRecPtr found = InvalidXLogRecPtr; XLogPageHeader header; char *errormsg; Assert(!XLogRecPtrIsInvalid(RecPtr)); /* Make sure ReadPageInternal() can't return XLREAD_WOULDBLOCK. */ state->nonblocking = false; /* * skip over potential continuation data, keeping in mind that it may span * multiple pages */ tmpRecPtr = RecPtr; while (true) { XLogRecPtr targetPagePtr; int targetRecOff; uint32 pageHeaderSize; int readLen; /* * Compute targetRecOff. It should typically be equal or greater than * short page-header since a valid record can't start anywhere before * that, except when caller has explicitly specified the offset that * falls somewhere there or when we are skipping multi-page * continuation record. It doesn't matter though because * ReadPageInternal() is prepared to handle that and will read at * least short page-header worth of data */ targetRecOff = tmpRecPtr % XLOG_BLCKSZ; /* scroll back to page boundary */ targetPagePtr = tmpRecPtr - targetRecOff; /* Read the page containing the record */ readLen = ReadPageInternal(state, targetPagePtr, targetRecOff); if (readLen < 0) goto err; header = (XLogPageHeader) state->readBuf; pageHeaderSize = XLogPageHeaderSize(header); /* make sure we have enough data for the page header */ readLen = ReadPageInternal(state, targetPagePtr, pageHeaderSize); if (readLen < 0) goto err; /* skip over potential continuation data */ if (header->xlp_info & XLP_FIRST_IS_CONTRECORD) { /* * If the length of the remaining continuation data is more than * what can fit in this page, the continuation record crosses over * this page. Read the next page and try again. xlp_rem_len in the * next page header will contain the remaining length of the * continuation data * * Note that record headers are MAXALIGN'ed */ if (MAXALIGN(header->xlp_rem_len) >= (XLOG_BLCKSZ - pageHeaderSize)) tmpRecPtr = targetPagePtr + XLOG_BLCKSZ; else { /* * The previous continuation record ends in this page. Set * tmpRecPtr to point to the first valid record */ tmpRecPtr = targetPagePtr + pageHeaderSize + MAXALIGN(header->xlp_rem_len); break; } } else { tmpRecPtr = targetPagePtr + pageHeaderSize; break; } } /* * we know now that tmpRecPtr is an address pointing to a valid XLogRecord * because either we're at the first record after the beginning of a page * or we just jumped over the remaining data of a continuation. */ XLogBeginRead(state, tmpRecPtr); while (XLogReadRecord(state, &errormsg) != NULL) { /* past the record we've found, break out */ if (RecPtr <= state->ReadRecPtr) { /* Rewind the reader to the beginning of the last record. */ found = state->ReadRecPtr; XLogBeginRead(state, found); return found; } } err: XLogReaderInvalReadState(state); return InvalidXLogRecPtr; } /* * Helper function to ease writing of XLogReaderRoutine->page_read callbacks. * If this function is used, caller must supply a segment_open callback in * 'state', as that is used here. * * Read 'count' bytes into 'buf', starting at location 'startptr', from WAL * fetched from timeline 'tli'. * * Returns true if succeeded, false if an error occurs, in which case * 'errinfo' receives error details. * * XXX probably this should be improved to suck data directly from the * WAL buffers when possible. */ bool WALRead(XLogReaderState *state, char *buf, XLogRecPtr startptr, Size count, TimeLineID tli, WALReadError *errinfo) { char *p; XLogRecPtr recptr; Size nbytes; p = buf; recptr = startptr; nbytes = count; while (nbytes > 0) { uint32 startoff; int segbytes; int readbytes; startoff = XLogSegmentOffset(recptr, state->segcxt.ws_segsize); /* * If the data we want is not in a segment we have open, close what we * have (if anything) and open the next one, using the caller's * provided segment_open callback. */ if (state->seg.ws_file < 0 || !XLByteInSeg(recptr, state->seg.ws_segno, state->segcxt.ws_segsize) || tli != state->seg.ws_tli) { XLogSegNo nextSegNo; if (state->seg.ws_file >= 0) state->routine.segment_close(state); XLByteToSeg(recptr, nextSegNo, state->segcxt.ws_segsize); state->routine.segment_open(state, nextSegNo, &tli); /* This shouldn't happen -- indicates a bug in segment_open */ Assert(state->seg.ws_file >= 0); /* Update the current segment info. */ state->seg.ws_tli = tli; state->seg.ws_segno = nextSegNo; } /* How many bytes are within this segment? */ if (nbytes > (state->segcxt.ws_segsize - startoff)) segbytes = state->segcxt.ws_segsize - startoff; else segbytes = nbytes; #ifndef FRONTEND pgstat_report_wait_start(WAIT_EVENT_WAL_READ); #endif /* Reset errno first; eases reporting non-errno-affecting errors */ errno = 0; readbytes = pg_pread(state->seg.ws_file, p, segbytes, (off_t) startoff); #ifndef FRONTEND pgstat_report_wait_end(); #endif if (readbytes <= 0) { errinfo->wre_errno = errno; errinfo->wre_req = segbytes; errinfo->wre_read = readbytes; errinfo->wre_off = startoff; errinfo->wre_seg = state->seg; return false; } /* Update state for read */ recptr += readbytes; nbytes -= readbytes; p += readbytes; } return true; } /* ---------------------------------------- * Functions for decoding the data and block references in a record. * ---------------------------------------- */ /* * Private function to reset the state, forgetting all decoded records, if we * are asked to move to a new read position. */ static void ResetDecoder(XLogReaderState *state) { DecodedXLogRecord *r; /* Reset the decoded record queue, freeing any oversized records. */ while ((r = state->decode_queue_head) != NULL) { state->decode_queue_head = r->next; if (r->oversized) pfree(r); } state->decode_queue_tail = NULL; state->decode_queue_head = NULL; state->record = NULL; /* Reset the decode buffer to empty. */ state->decode_buffer_tail = state->decode_buffer; state->decode_buffer_head = state->decode_buffer; /* Clear error state. */ state->errormsg_buf[0] = '\0'; state->errormsg_deferred = false; } /* * Compute the maximum possible amount of padding that could be required to * decode a record, given xl_tot_len from the record's header. This is the * amount of output buffer space that we need to decode a record, though we * might not finish up using it all. * * This computation is pessimistic and assumes the maximum possible number of * blocks, due to lack of better information. */ size_t DecodeXLogRecordRequiredSpace(size_t xl_tot_len) { size_t size = 0; /* Account for the fixed size part of the decoded record struct. */ size += offsetof(DecodedXLogRecord, blocks[0]); /* Account for the flexible blocks array of maximum possible size. */ size += sizeof(DecodedBkpBlock) * (XLR_MAX_BLOCK_ID + 1); /* Account for all the raw main and block data. */ size += xl_tot_len; /* We might insert padding before main_data. */ size += (MAXIMUM_ALIGNOF - 1); /* We might insert padding before each block's data. */ size += (MAXIMUM_ALIGNOF - 1) * (XLR_MAX_BLOCK_ID + 1); /* We might insert padding at the end. */ size += (MAXIMUM_ALIGNOF - 1); return size; } /* * Decode a record. "decoded" must point to a MAXALIGNed memory area that has * space for at least DecodeXLogRecordRequiredSpace(record) bytes. On * success, decoded->size contains the actual space occupied by the decoded * record, which may turn out to be less. * * Only decoded->oversized member must be initialized already, and will not be * modified. Other members will be initialized as required. * * On error, a human-readable error message is returned in *errormsg, and * the return value is false. */ bool DecodeXLogRecord(XLogReaderState *state, DecodedXLogRecord *decoded, XLogRecord *record, XLogRecPtr lsn, char **errormsg) { /* * read next _size bytes from record buffer, but check for overrun first. */ #define COPY_HEADER_FIELD(_dst, _size) \ do { \ if (remaining < _size) \ goto shortdata_err; \ memcpy(_dst, ptr, _size); \ ptr += _size; \ remaining -= _size; \ } while(0) char *ptr; char *out; uint32 remaining; uint32 datatotal; RelFileLocator *rlocator = NULL; uint8 block_id; decoded->header = *record; decoded->lsn = lsn; decoded->next = NULL; decoded->record_origin = InvalidRepOriginId; decoded->toplevel_xid = InvalidTransactionId; decoded->main_data = NULL; decoded->main_data_len = 0; decoded->max_block_id = -1; ptr = (char *) record; ptr += SizeOfXLogRecord; remaining = record->xl_tot_len - SizeOfXLogRecord; /* Decode the headers */ datatotal = 0; while (remaining > datatotal) { COPY_HEADER_FIELD(&block_id, sizeof(uint8)); if (block_id == XLR_BLOCK_ID_DATA_SHORT) { /* XLogRecordDataHeaderShort */ uint8 main_data_len; COPY_HEADER_FIELD(&main_data_len, sizeof(uint8)); decoded->main_data_len = main_data_len; datatotal += main_data_len; break; /* by convention, the main data fragment is * always last */ } else if (block_id == XLR_BLOCK_ID_DATA_LONG) { /* XLogRecordDataHeaderLong */ uint32 main_data_len; COPY_HEADER_FIELD(&main_data_len, sizeof(uint32)); decoded->main_data_len = main_data_len; datatotal += main_data_len; break; /* by convention, the main data fragment is * always last */ } else if (block_id == XLR_BLOCK_ID_ORIGIN) { COPY_HEADER_FIELD(&decoded->record_origin, sizeof(RepOriginId)); } else if (block_id == XLR_BLOCK_ID_TOPLEVEL_XID) { COPY_HEADER_FIELD(&decoded->toplevel_xid, sizeof(TransactionId)); } else if (block_id <= XLR_MAX_BLOCK_ID) { /* XLogRecordBlockHeader */ DecodedBkpBlock *blk; uint8 fork_flags; /* mark any intervening block IDs as not in use */ for (int i = decoded->max_block_id + 1; i < block_id; ++i) decoded->blocks[i].in_use = false; if (block_id <= decoded->max_block_id) { report_invalid_record(state, "out-of-order block_id %u at %X/%X", block_id, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } decoded->max_block_id = block_id; blk = &decoded->blocks[block_id]; blk->in_use = true; blk->apply_image = false; COPY_HEADER_FIELD(&fork_flags, sizeof(uint8)); blk->forknum = fork_flags & BKPBLOCK_FORK_MASK; blk->flags = fork_flags; blk->has_image = ((fork_flags & BKPBLOCK_HAS_IMAGE) != 0); blk->has_data = ((fork_flags & BKPBLOCK_HAS_DATA) != 0); blk->prefetch_buffer = InvalidBuffer; COPY_HEADER_FIELD(&blk->data_len, sizeof(uint16)); /* cross-check that the HAS_DATA flag is set iff data_length > 0 */ if (blk->has_data && blk->data_len == 0) { report_invalid_record(state, "BKPBLOCK_HAS_DATA set, but no data included at %X/%X", LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } if (!blk->has_data && blk->data_len != 0) { report_invalid_record(state, "BKPBLOCK_HAS_DATA not set, but data length is %u at %X/%X", (unsigned int) blk->data_len, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } datatotal += blk->data_len; if (blk->has_image) { COPY_HEADER_FIELD(&blk->bimg_len, sizeof(uint16)); COPY_HEADER_FIELD(&blk->hole_offset, sizeof(uint16)); COPY_HEADER_FIELD(&blk->bimg_info, sizeof(uint8)); blk->apply_image = ((blk->bimg_info & BKPIMAGE_APPLY) != 0); if (BKPIMAGE_COMPRESSED(blk->bimg_info)) { if (blk->bimg_info & BKPIMAGE_HAS_HOLE) COPY_HEADER_FIELD(&blk->hole_length, sizeof(uint16)); else blk->hole_length = 0; } else blk->hole_length = BLCKSZ - blk->bimg_len; datatotal += blk->bimg_len; /* * cross-check that hole_offset > 0, hole_length > 0 and * bimg_len < BLCKSZ if the HAS_HOLE flag is set. */ if ((blk->bimg_info & BKPIMAGE_HAS_HOLE) && (blk->hole_offset == 0 || blk->hole_length == 0 || blk->bimg_len == BLCKSZ)) { report_invalid_record(state, "BKPIMAGE_HAS_HOLE set, but hole offset %u length %u block image length %u at %X/%X", (unsigned int) blk->hole_offset, (unsigned int) blk->hole_length, (unsigned int) blk->bimg_len, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } /* * cross-check that hole_offset == 0 and hole_length == 0 if * the HAS_HOLE flag is not set. */ if (!(blk->bimg_info & BKPIMAGE_HAS_HOLE) && (blk->hole_offset != 0 || blk->hole_length != 0)) { report_invalid_record(state, "BKPIMAGE_HAS_HOLE not set, but hole offset %u length %u at %X/%X", (unsigned int) blk->hole_offset, (unsigned int) blk->hole_length, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } /* * Cross-check that bimg_len < BLCKSZ if it is compressed. */ if (BKPIMAGE_COMPRESSED(blk->bimg_info) && blk->bimg_len == BLCKSZ) { report_invalid_record(state, "BKPIMAGE_COMPRESSED set, but block image length %u at %X/%X", (unsigned int) blk->bimg_len, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } /* * cross-check that bimg_len = BLCKSZ if neither HAS_HOLE is * set nor COMPRESSED(). */ if (!(blk->bimg_info & BKPIMAGE_HAS_HOLE) && !BKPIMAGE_COMPRESSED(blk->bimg_info) && blk->bimg_len != BLCKSZ) { report_invalid_record(state, "neither BKPIMAGE_HAS_HOLE nor BKPIMAGE_COMPRESSED set, but block image length is %u at %X/%X", (unsigned int) blk->data_len, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } } if (!(fork_flags & BKPBLOCK_SAME_REL)) { COPY_HEADER_FIELD(&blk->rlocator, sizeof(RelFileLocator)); rlocator = &blk->rlocator; } else { if (rlocator == NULL) { report_invalid_record(state, "BKPBLOCK_SAME_REL set but no previous rel at %X/%X", LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } blk->rlocator = *rlocator; } COPY_HEADER_FIELD(&blk->blkno, sizeof(BlockNumber)); } else { report_invalid_record(state, "invalid block_id %u at %X/%X", block_id, LSN_FORMAT_ARGS(state->ReadRecPtr)); goto err; } } if (remaining != datatotal) goto shortdata_err; /* * Ok, we've parsed the fragment headers, and verified that the total * length of the payload in the fragments is equal to the amount of data * left. Copy the data of each fragment to contiguous space after the * blocks array, inserting alignment padding before the data fragments so * they can be cast to struct pointers by REDO routines. */ out = ((char *) decoded) + offsetof(DecodedXLogRecord, blocks) + sizeof(decoded->blocks[0]) * (decoded->max_block_id + 1); /* block data first */ for (block_id = 0; block_id <= decoded->max_block_id; block_id++) { DecodedBkpBlock *blk = &decoded->blocks[block_id]; if (!blk->in_use) continue; Assert(blk->has_image || !blk->apply_image); if (blk->has_image) { /* no need to align image */ blk->bkp_image = out; memcpy(out, ptr, blk->bimg_len); ptr += blk->bimg_len; out += blk->bimg_len; } if (blk->has_data) { out = (char *) MAXALIGN(out); blk->data = out; memcpy(blk->data, ptr, blk->data_len); ptr += blk->data_len; out += blk->data_len; } } /* and finally, the main data */ if (decoded->main_data_len > 0) { out = (char *) MAXALIGN(out); decoded->main_data = out; memcpy(decoded->main_data, ptr, decoded->main_data_len); ptr += decoded->main_data_len; out += decoded->main_data_len; } /* Report the actual size we used. */ decoded->size = MAXALIGN(out - (char *) decoded); Assert(DecodeXLogRecordRequiredSpace(record->xl_tot_len) >= decoded->size); return true; shortdata_err: report_invalid_record(state, "record with invalid length at %X/%X", LSN_FORMAT_ARGS(state->ReadRecPtr)); err: *errormsg = state->errormsg_buf; return false; } /* * Returns information about the block that a block reference refers to. * * This is like XLogRecGetBlockTagExtended, except that the block reference * must exist and there's no access to prefetch_buffer. */ void XLogRecGetBlockTag(XLogReaderState *record, uint8 block_id, RelFileLocator *rlocator, ForkNumber *forknum, BlockNumber *blknum) { if (!XLogRecGetBlockTagExtended(record, block_id, rlocator, forknum, blknum, NULL)) { #ifndef FRONTEND elog(ERROR, "could not locate backup block with ID %d in WAL record", block_id); #else pg_fatal("could not locate backup block with ID %d in WAL record", block_id); #endif } } /* * Returns information about the block that a block reference refers to, * optionally including the buffer that the block may already be in. * * If the WAL record contains a block reference with the given ID, *rlocator, * *forknum, *blknum and *prefetch_buffer are filled in (if not NULL), and * returns true. Otherwise returns false. */ bool XLogRecGetBlockTagExtended(XLogReaderState *record, uint8 block_id, RelFileLocator *rlocator, ForkNumber *forknum, BlockNumber *blknum, Buffer *prefetch_buffer) { DecodedBkpBlock *bkpb; if (!XLogRecHasBlockRef(record, block_id)) return false; bkpb = &record->record->blocks[block_id]; if (rlocator) *rlocator = bkpb->rlocator; if (forknum) *forknum = bkpb->forknum; if (blknum) *blknum = bkpb->blkno; if (prefetch_buffer) *prefetch_buffer = bkpb->prefetch_buffer; return true; } /* * Returns the data associated with a block reference, or NULL if there is * no data (e.g. because a full-page image was taken instead). The returned * pointer points to a MAXALIGNed buffer. */ char * XLogRecGetBlockData(XLogReaderState *record, uint8 block_id, Size *len) { DecodedBkpBlock *bkpb; if (block_id > record->record->max_block_id || !record->record->blocks[block_id].in_use) return NULL; bkpb = &record->record->blocks[block_id]; if (!bkpb->has_data) { if (len) *len = 0; return NULL; } else { if (len) *len = bkpb->data_len; return bkpb->data; } } /* * Restore a full-page image from a backup block attached to an XLOG record. * * Returns true if a full-page image is restored, and false on failure with * an error to be consumed by the caller. */ bool RestoreBlockImage(XLogReaderState *record, uint8 block_id, char *page) { DecodedBkpBlock *bkpb; char *ptr; PGAlignedBlock tmp; if (block_id > record->record->max_block_id || !record->record->blocks[block_id].in_use) { report_invalid_record(record, "could not restore image at %X/%X with invalid block %d specified", LSN_FORMAT_ARGS(record->ReadRecPtr), block_id); return false; } if (!record->record->blocks[block_id].has_image) { report_invalid_record(record, "could not restore image at %X/%X with invalid state, block %d", LSN_FORMAT_ARGS(record->ReadRecPtr), block_id); return false; } bkpb = &record->record->blocks[block_id]; ptr = bkpb->bkp_image; if (BKPIMAGE_COMPRESSED(bkpb->bimg_info)) { /* If a backup block image is compressed, decompress it */ bool decomp_success = true; if ((bkpb->bimg_info & BKPIMAGE_COMPRESS_PGLZ) != 0) { if (pglz_decompress(ptr, bkpb->bimg_len, tmp.data, BLCKSZ - bkpb->hole_length, true) < 0) decomp_success = false; } else if ((bkpb->bimg_info & BKPIMAGE_COMPRESS_LZ4) != 0) { #ifdef USE_LZ4 if (LZ4_decompress_safe(ptr, tmp.data, bkpb->bimg_len, BLCKSZ - bkpb->hole_length) <= 0) decomp_success = false; #else report_invalid_record(record, "could not restore image at %X/%X compressed with %s not supported by build, block %d", LSN_FORMAT_ARGS(record->ReadRecPtr), "LZ4", block_id); return false; #endif } else if ((bkpb->bimg_info & BKPIMAGE_COMPRESS_ZSTD) != 0) { #ifdef USE_ZSTD size_t decomp_result = ZSTD_decompress(tmp.data, BLCKSZ - bkpb->hole_length, ptr, bkpb->bimg_len); if (ZSTD_isError(decomp_result)) decomp_success = false; #else report_invalid_record(record, "could not restore image at %X/%X compressed with %s not supported by build, block %d", LSN_FORMAT_ARGS(record->ReadRecPtr), "zstd", block_id); return false; #endif } else { report_invalid_record(record, "could not restore image at %X/%X compressed with unknown method, block %d", LSN_FORMAT_ARGS(record->ReadRecPtr), block_id); return false; } if (!decomp_success) { report_invalid_record(record, "could not decompress image at %X/%X, block %d", LSN_FORMAT_ARGS(record->ReadRecPtr), block_id); return false; } ptr = tmp.data; } /* generate page, taking into account hole if necessary */ if (bkpb->hole_length == 0) { memcpy(page, ptr, BLCKSZ); } else { memcpy(page, ptr, bkpb->hole_offset); /* must zero-fill the hole */ MemSet(page + bkpb->hole_offset, 0, bkpb->hole_length); memcpy(page + (bkpb->hole_offset + bkpb->hole_length), ptr + bkpb->hole_offset, BLCKSZ - (bkpb->hole_offset + bkpb->hole_length)); } return true; } #ifndef FRONTEND /* * Extract the FullTransactionId from a WAL record. */ FullTransactionId XLogRecGetFullXid(XLogReaderState *record) { TransactionId xid, next_xid; uint32 epoch; /* * This function is only safe during replay, because it depends on the * replay state. See AdvanceNextFullTransactionIdPastXid() for more. */ Assert(AmStartupProcess() || !IsUnderPostmaster); xid = XLogRecGetXid(record); next_xid = XidFromFullTransactionId(ShmemVariableCache->nextXid); epoch = EpochFromFullTransactionId(ShmemVariableCache->nextXid); /* * If xid is numerically greater than next_xid, it has to be from the last * epoch. */ if (unlikely(xid > next_xid)) --epoch; return FullTransactionIdFromEpochAndXid(epoch, xid); } #endif