/*------------------------------------------------------------------------- * * md.c * This code manages relations that reside on magnetic disk. * * Portions Copyright (c) 1996-2003, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/storage/smgr/md.c,v 1.98 2003/08/04 02:40:04 momjian Exp $ * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include #include #include "catalog/catalog.h" #include "miscadmin.h" #include "storage/smgr.h" #include "utils/inval.h" #include "utils/memutils.h" #undef DIAGNOSTIC /* * The magnetic disk storage manager keeps track of open file descriptors * in its own descriptor pool. This happens for two reasons. First, at * transaction boundaries, we walk the list of descriptors and flush * anything that we've dirtied in the current transaction. Second, we want * to support relations larger than the OS' file size limit (often 2GBytes). * In order to do that, we break relations up into chunks of < 2GBytes * and store one chunk in each of several files that represent the relation. * See the BLCKSZ and RELSEG_SIZE configuration constants in include/pg_config.h. * * The file descriptor stored in the relation cache (see RelationGetFile()) * is actually an index into the Md_fdvec array. -1 indicates not open. * * When a relation is broken into multiple chunks, only the first chunk * has its own entry in the Md_fdvec array; the remaining chunks have * palloc'd MdfdVec objects that are chained onto the first chunk via the * mdfd_chain links. All chunks except the last MUST have size exactly * equal to RELSEG_SIZE blocks --- see mdnblocks() and mdtruncate(). */ typedef struct _MdfdVec { int mdfd_vfd; /* fd number in vfd pool */ int mdfd_flags; /* fd status flags */ /* these are the assigned bits in mdfd_flags: */ #define MDFD_FREE (1 << 0) /* unused entry */ int mdfd_nextFree; /* link to next freelist member, if free */ #ifndef LET_OS_MANAGE_FILESIZE struct _MdfdVec *mdfd_chain; /* for large relations */ #endif } MdfdVec; static int Nfds = 100; /* initial/current size of Md_fdvec array */ static MdfdVec *Md_fdvec = (MdfdVec *) NULL; static int Md_Free = -1; /* head of freelist of unused fdvec * entries */ static int CurFd = 0; /* first never-used fdvec index */ static MemoryContext MdCxt; /* context for all my allocations */ /* routines declared here */ static void mdclose_fd(int fd); static int _mdfd_getrelnfd(Relation reln); static MdfdVec *_mdfd_openseg(Relation reln, BlockNumber segno, int oflags); static MdfdVec *_mdfd_getseg(Relation reln, BlockNumber blkno); static int _mdfd_blind_getseg(RelFileNode rnode, BlockNumber blkno); static int _fdvec_alloc(void); static void _fdvec_free(int); static BlockNumber _mdnblocks(File file, Size blcksz); /* * mdinit() -- Initialize private state for magnetic disk storage manager. * * We keep a private table of all file descriptors. Whenever we do * a write to one, we mark it dirty in our table. Whenever we force * changes to disk, we mark the file descriptor clean. At transaction * commit, we force changes to disk for all dirty file descriptors. * This routine allocates and initializes the table. * * Returns SM_SUCCESS or SM_FAIL with errno set as appropriate. */ int mdinit(void) { int i; MdCxt = AllocSetContextCreate(TopMemoryContext, "MdSmgr", ALLOCSET_DEFAULT_MINSIZE, ALLOCSET_DEFAULT_INITSIZE, ALLOCSET_DEFAULT_MAXSIZE); Md_fdvec = (MdfdVec *) MemoryContextAlloc(MdCxt, Nfds * sizeof(MdfdVec)); MemSet(Md_fdvec, 0, Nfds * sizeof(MdfdVec)); /* Set free list */ for (i = 0; i < Nfds; i++) { Md_fdvec[i].mdfd_nextFree = i + 1; Md_fdvec[i].mdfd_flags = MDFD_FREE; } Md_Free = 0; Md_fdvec[Nfds - 1].mdfd_nextFree = -1; return SM_SUCCESS; } int mdcreate(Relation reln) { char *path; int fd, vfd; Assert(reln->rd_fd < 0); path = relpath(reln->rd_node); fd = FileNameOpenFile(path, O_RDWR | O_CREAT | O_EXCL | PG_BINARY, 0600); if (fd < 0) { int save_errno = errno; /* * During bootstrap, there are cases where a system relation will * be accessed (by internal backend processes) before the * bootstrap script nominally creates it. Therefore, allow the * file to exist already, but in bootstrap mode only. (See also * mdopen) */ if (IsBootstrapProcessingMode()) fd = FileNameOpenFile(path, O_RDWR | PG_BINARY, 0600); if (fd < 0) { pfree(path); /* be sure to return the error reported by create, not open */ errno = save_errno; return -1; } errno = 0; } pfree(path); vfd = _fdvec_alloc(); if (vfd < 0) return -1; Md_fdvec[vfd].mdfd_vfd = fd; Md_fdvec[vfd].mdfd_flags = (uint16) 0; #ifndef LET_OS_MANAGE_FILESIZE Md_fdvec[vfd].mdfd_chain = (MdfdVec *) NULL; #endif return vfd; } /* * mdunlink() -- Unlink a relation. */ int mdunlink(RelFileNode rnode) { int status = SM_SUCCESS; int save_errno = 0; char *path; path = relpath(rnode); /* Delete the first segment, or only segment if not doing segmenting */ if (unlink(path) < 0) { status = SM_FAIL; save_errno = errno; } #ifndef LET_OS_MANAGE_FILESIZE /* Get the additional segments, if any */ if (status == SM_SUCCESS) { char *segpath = (char *) palloc(strlen(path) + 12); BlockNumber segno; for (segno = 1;; segno++) { sprintf(segpath, "%s.%u", path, segno); if (unlink(segpath) < 0) { /* ENOENT is expected after the last segment... */ if (errno != ENOENT) { status = SM_FAIL; save_errno = errno; } break; } } pfree(segpath); } #endif pfree(path); errno = save_errno; return status; } /* * mdextend() -- Add a block to the specified relation. * * The semantics are basically the same as mdwrite(): write at the * specified position. However, we are expecting to extend the * relation (ie, blocknum is the current EOF), and so in case of * failure we clean up by truncating. * * This routine returns SM_FAIL or SM_SUCCESS, with errno set as * appropriate. * * Note: this routine used to call mdnblocks() to get the block position * to write at, but that's pretty silly since the caller needs to know where * the block will be written, and accordingly must have done mdnblocks() * already. Might as well pass in the position and save a seek. */ int mdextend(Relation reln, BlockNumber blocknum, char *buffer) { long seekpos; int nbytes; MdfdVec *v; v = _mdfd_getseg(reln, blocknum); #ifndef LET_OS_MANAGE_FILESIZE seekpos = (long) (BLCKSZ * (blocknum % ((BlockNumber) RELSEG_SIZE))); #ifdef DIAGNOSTIC if (seekpos >= BLCKSZ * RELSEG_SIZE) elog(FATAL, "seekpos too big"); #endif #else seekpos = (long) (BLCKSZ * (blocknum)); #endif /* * Note: because caller obtained blocknum by calling mdnblocks, which * did a seek(SEEK_END), this seek is often redundant and will be * optimized away by fd.c. It's not redundant, however, if there is a * partial page at the end of the file. In that case we want to try * to overwrite the partial page with a full page. It's also not * redundant if bufmgr.c had to dump another buffer of the same file * to make room for the new page's buffer. */ if (FileSeek(v->mdfd_vfd, seekpos, SEEK_SET) != seekpos) return SM_FAIL; if ((nbytes = FileWrite(v->mdfd_vfd, buffer, BLCKSZ)) != BLCKSZ) { if (nbytes > 0) { int save_errno = errno; /* Remove the partially-written page */ FileTruncate(v->mdfd_vfd, seekpos); FileSeek(v->mdfd_vfd, seekpos, SEEK_SET); errno = save_errno; } return SM_FAIL; } #ifndef LET_OS_MANAGE_FILESIZE #ifdef DIAGNOSTIC if (_mdnblocks(v->mdfd_vfd, BLCKSZ) > ((BlockNumber) RELSEG_SIZE)) elog(FATAL, "segment too big"); #endif #endif return SM_SUCCESS; } /* * mdopen() -- Open the specified relation. */ int mdopen(Relation reln) { char *path; int fd; int vfd; Assert(reln->rd_fd < 0); path = relpath(reln->rd_node); fd = FileNameOpenFile(path, O_RDWR | PG_BINARY, 0600); if (fd < 0) { /* * During bootstrap, there are cases where a system relation will * be accessed (by internal backend processes) before the * bootstrap script nominally creates it. Therefore, accept * mdopen() as a substitute for mdcreate() in bootstrap mode only. * (See mdcreate) */ if (IsBootstrapProcessingMode()) fd = FileNameOpenFile(path, O_RDWR | O_CREAT | O_EXCL | PG_BINARY, 0600); if (fd < 0) { pfree(path); return -1; } } pfree(path); vfd = _fdvec_alloc(); if (vfd < 0) return -1; Md_fdvec[vfd].mdfd_vfd = fd; Md_fdvec[vfd].mdfd_flags = (uint16) 0; #ifndef LET_OS_MANAGE_FILESIZE Md_fdvec[vfd].mdfd_chain = (MdfdVec *) NULL; #ifdef DIAGNOSTIC if (_mdnblocks(fd, BLCKSZ) > ((BlockNumber) RELSEG_SIZE)) elog(FATAL, "segment too big"); #endif #endif return vfd; } /* * mdclose() -- Close the specified relation, if it isn't closed already. * * AND FREE fd vector! It may be re-used for other relation! * reln should be flushed from cache after closing !.. * * Returns SM_SUCCESS or SM_FAIL with errno set as appropriate. */ int mdclose(Relation reln) { int fd; fd = RelationGetFile(reln); if (fd < 0) return SM_SUCCESS; /* already closed, so no work */ mdclose_fd(fd); reln->rd_fd = -1; return SM_SUCCESS; } static void mdclose_fd(int fd) { MdfdVec *v; #ifndef LET_OS_MANAGE_FILESIZE for (v = &Md_fdvec[fd]; v != (MdfdVec *) NULL;) { MdfdVec *ov = v; /* if not closed already */ if (v->mdfd_vfd >= 0) FileClose(v->mdfd_vfd); /* Now free vector */ v = v->mdfd_chain; if (ov != &Md_fdvec[fd]) pfree(ov); } Md_fdvec[fd].mdfd_chain = (MdfdVec *) NULL; #else v = &Md_fdvec[fd]; if (v != (MdfdVec *) NULL) { if (v->mdfd_vfd >= 0) FileClose(v->mdfd_vfd); } #endif _fdvec_free(fd); } /* * mdread() -- Read the specified block from a relation. * * Returns SM_SUCCESS or SM_FAIL. */ int mdread(Relation reln, BlockNumber blocknum, char *buffer) { int status; long seekpos; int nbytes; MdfdVec *v; v = _mdfd_getseg(reln, blocknum); #ifndef LET_OS_MANAGE_FILESIZE seekpos = (long) (BLCKSZ * (blocknum % ((BlockNumber) RELSEG_SIZE))); #ifdef DIAGNOSTIC if (seekpos >= BLCKSZ * RELSEG_SIZE) elog(FATAL, "seekpos too big"); #endif #else seekpos = (long) (BLCKSZ * (blocknum)); #endif if (FileSeek(v->mdfd_vfd, seekpos, SEEK_SET) != seekpos) return SM_FAIL; status = SM_SUCCESS; if ((nbytes = FileRead(v->mdfd_vfd, buffer, BLCKSZ)) != BLCKSZ) { /* * If we are at or past EOF, return zeroes without complaining. * Also substitute zeroes if we found a partial block at EOF. * * XXX this is really ugly, bad design. However the current * implementation of hash indexes requires it, because hash index * pages are initialized out-of-order. */ if (nbytes == 0 || (nbytes > 0 && mdnblocks(reln) == blocknum)) MemSet(buffer, 0, BLCKSZ); else status = SM_FAIL; } return status; } /* * mdwrite() -- Write the supplied block at the appropriate location. * * Returns SM_SUCCESS or SM_FAIL. */ int mdwrite(Relation reln, BlockNumber blocknum, char *buffer) { long seekpos; MdfdVec *v; v = _mdfd_getseg(reln, blocknum); #ifndef LET_OS_MANAGE_FILESIZE seekpos = (long) (BLCKSZ * (blocknum % ((BlockNumber) RELSEG_SIZE))); #ifdef DIAGNOSTIC if (seekpos >= BLCKSZ * RELSEG_SIZE) elog(FATAL, "seekpos too big"); #endif #else seekpos = (long) (BLCKSZ * (blocknum)); #endif if (FileSeek(v->mdfd_vfd, seekpos, SEEK_SET) != seekpos) return SM_FAIL; if (FileWrite(v->mdfd_vfd, buffer, BLCKSZ) != BLCKSZ) return SM_FAIL; return SM_SUCCESS; } /* * mdblindwrt() -- Write a block to disk blind. * * We have to be able to do this using only the rnode of the relation * in which the block belongs. Otherwise this is much like mdwrite(). */ int mdblindwrt(RelFileNode rnode, BlockNumber blkno, char *buffer) { int status; long seekpos; int fd; fd = _mdfd_blind_getseg(rnode, blkno); if (fd < 0) return SM_FAIL; #ifndef LET_OS_MANAGE_FILESIZE seekpos = (long) (BLCKSZ * (blkno % ((BlockNumber) RELSEG_SIZE))); #ifdef DIAGNOSTIC if (seekpos >= BLCKSZ * RELSEG_SIZE) elog(FATAL, "seekpos too big"); #endif #else seekpos = (long) (BLCKSZ * (blkno)); #endif errno = 0; if (lseek(fd, seekpos, SEEK_SET) != seekpos) { elog(LOG, "lseek(%ld) failed: %m", seekpos); close(fd); return SM_FAIL; } status = SM_SUCCESS; /* write the block */ errno = 0; if (write(fd, buffer, BLCKSZ) != BLCKSZ) { /* if write didn't set errno, assume problem is no disk space */ if (errno == 0) errno = ENOSPC; elog(LOG, "write() failed: %m"); status = SM_FAIL; } if (close(fd) < 0) { elog(LOG, "close() failed: %m"); status = SM_FAIL; } return status; } /* * mdnblocks() -- Get the number of blocks stored in a relation. * * Important side effect: all segments of the relation are opened * and added to the mdfd_chain list. If this routine has not been * called, then only segments up to the last one actually touched * are present in the chain... * * Returns # of blocks, ereport's on error. */ BlockNumber mdnblocks(Relation reln) { int fd; MdfdVec *v; #ifndef LET_OS_MANAGE_FILESIZE BlockNumber nblocks; BlockNumber segno; #endif fd = _mdfd_getrelnfd(reln); v = &Md_fdvec[fd]; #ifndef LET_OS_MANAGE_FILESIZE segno = 0; /* * Skip through any segments that aren't the last one, to avoid * redundant seeks on them. We have previously verified that these * segments are exactly RELSEG_SIZE long, and it's useless to recheck * that each time. (NOTE: this assumption could only be wrong if * another backend has truncated the relation. We rely on higher code * levels to handle that scenario by closing and re-opening the md * fd.) */ while (v->mdfd_chain != (MdfdVec *) NULL) { segno++; v = v->mdfd_chain; } for (;;) { nblocks = _mdnblocks(v->mdfd_vfd, BLCKSZ); if (nblocks > ((BlockNumber) RELSEG_SIZE)) elog(FATAL, "segment too big"); if (nblocks < ((BlockNumber) RELSEG_SIZE)) return (segno * ((BlockNumber) RELSEG_SIZE)) + nblocks; /* * If segment is exactly RELSEG_SIZE, advance to next one. */ segno++; if (v->mdfd_chain == (MdfdVec *) NULL) { /* * Because we pass O_CREAT, we will create the next segment * (with zero length) immediately, if the last segment is of * length REL_SEGSIZE. This is unnecessary but harmless, and * testing for the case would take more cycles than it seems * worth. */ v->mdfd_chain = _mdfd_openseg(reln, segno, O_CREAT); if (v->mdfd_chain == (MdfdVec *) NULL) elog(ERROR, "could not count blocks of \"%s\": %m", RelationGetRelationName(reln)); } v = v->mdfd_chain; } #else return _mdnblocks(v->mdfd_vfd, BLCKSZ); #endif } /* * mdtruncate() -- Truncate relation to specified number of blocks. * * Returns # of blocks or InvalidBlockNumber on error. */ BlockNumber mdtruncate(Relation reln, BlockNumber nblocks) { int fd; MdfdVec *v; BlockNumber curnblk; #ifndef LET_OS_MANAGE_FILESIZE BlockNumber priorblocks; #endif /* * NOTE: mdnblocks makes sure we have opened all existing segments, so * that truncate/delete loop will get them all! */ curnblk = mdnblocks(reln); if (nblocks > curnblk) return InvalidBlockNumber; /* bogus request */ if (nblocks == curnblk) return nblocks; /* no work */ fd = _mdfd_getrelnfd(reln); v = &Md_fdvec[fd]; #ifndef LET_OS_MANAGE_FILESIZE priorblocks = 0; while (v != (MdfdVec *) NULL) { MdfdVec *ov = v; if (priorblocks > nblocks) { /* * This segment is no longer wanted at all (and has already * been unlinked from the mdfd_chain). We truncate the file * before deleting it because if other backends are holding * the file open, the unlink will fail on some platforms. * Better a zero-size file gets left around than a big file... */ FileTruncate(v->mdfd_vfd, 0); FileUnlink(v->mdfd_vfd); v = v->mdfd_chain; Assert(ov != &Md_fdvec[fd]); /* we never drop the 1st * segment */ pfree(ov); } else if (priorblocks + ((BlockNumber) RELSEG_SIZE) > nblocks) { /* * This is the last segment we want to keep. Truncate the file * to the right length, and clear chain link that points to * any remaining segments (which we shall zap). NOTE: if * nblocks is exactly a multiple K of RELSEG_SIZE, we will * truncate the K+1st segment to 0 length but keep it. This is * mainly so that the right thing happens if nblocks==0. */ BlockNumber lastsegblocks = nblocks - priorblocks; if (FileTruncate(v->mdfd_vfd, lastsegblocks * BLCKSZ) < 0) return InvalidBlockNumber; v = v->mdfd_chain; ov->mdfd_chain = (MdfdVec *) NULL; } else { /* * We still need this segment and 0 or more blocks beyond it, * so nothing to do here. */ v = v->mdfd_chain; } priorblocks += RELSEG_SIZE; } #else if (FileTruncate(v->mdfd_vfd, nblocks * BLCKSZ) < 0) return InvalidBlockNumber; #endif return nblocks; } /* * mdcommit() -- Commit a transaction. * * Returns SM_SUCCESS or SM_FAIL with errno set as appropriate. */ int mdcommit(void) { /* * We don't actually have to do anything here... */ return SM_SUCCESS; } /* * mdabort() -- Abort a transaction. * * Changes need not be forced to disk at transaction abort. */ int mdabort(void) { /* * We don't actually have to do anything here... */ return SM_SUCCESS; } /* * mdsync() -- Sync previous writes to stable storage. */ int mdsync(void) { sync(); if (IsUnderPostmaster) sleep(2); sync(); return SM_SUCCESS; } /* * _fdvec_alloc () -- grab a free (or new) md file descriptor vector. */ static int _fdvec_alloc(void) { MdfdVec *nvec; int fdvec, i; if (Md_Free >= 0) /* get from free list */ { fdvec = Md_Free; Md_Free = Md_fdvec[fdvec].mdfd_nextFree; Assert(Md_fdvec[fdvec].mdfd_flags == MDFD_FREE); Md_fdvec[fdvec].mdfd_flags = 0; if (fdvec >= CurFd) { Assert(fdvec == CurFd); CurFd++; } return fdvec; } /* Must allocate more room */ if (Nfds != CurFd) elog(FATAL, "_fdvec_alloc error"); Nfds *= 2; nvec = (MdfdVec *) MemoryContextAlloc(MdCxt, Nfds * sizeof(MdfdVec)); MemSet(nvec, 0, Nfds * sizeof(MdfdVec)); memcpy(nvec, (char *) Md_fdvec, CurFd * sizeof(MdfdVec)); pfree(Md_fdvec); Md_fdvec = nvec; /* Set new free list */ for (i = CurFd; i < Nfds; i++) { Md_fdvec[i].mdfd_nextFree = i + 1; Md_fdvec[i].mdfd_flags = MDFD_FREE; } Md_fdvec[Nfds - 1].mdfd_nextFree = -1; Md_Free = CurFd + 1; fdvec = CurFd; CurFd++; Md_fdvec[fdvec].mdfd_flags = 0; return fdvec; } /* * _fdvec_free () -- free md file descriptor vector. * */ static void _fdvec_free(int fdvec) { Assert(Md_Free < 0 || Md_fdvec[Md_Free].mdfd_flags == MDFD_FREE); Assert(Md_fdvec[fdvec].mdfd_flags != MDFD_FREE); Md_fdvec[fdvec].mdfd_nextFree = Md_Free; Md_fdvec[fdvec].mdfd_flags = MDFD_FREE; Md_Free = fdvec; } static MdfdVec * _mdfd_openseg(Relation reln, BlockNumber segno, int oflags) { MdfdVec *v; int fd; char *path, *fullpath; /* be sure we have enough space for the '.segno', if any */ path = relpath(reln->rd_node); if (segno > 0) { fullpath = (char *) palloc(strlen(path) + 12); sprintf(fullpath, "%s.%u", path, segno); pfree(path); } else fullpath = path; /* open the file */ fd = FileNameOpenFile(fullpath, O_RDWR | PG_BINARY | oflags, 0600); pfree(fullpath); if (fd < 0) return (MdfdVec *) NULL; /* allocate an mdfdvec entry for it */ v = (MdfdVec *) MemoryContextAlloc(MdCxt, sizeof(MdfdVec)); /* fill the entry */ v->mdfd_vfd = fd; v->mdfd_flags = (uint16) 0; #ifndef LET_OS_MANAGE_FILESIZE v->mdfd_chain = (MdfdVec *) NULL; #ifdef DIAGNOSTIC if (_mdnblocks(fd, BLCKSZ) > ((BlockNumber) RELSEG_SIZE)) elog(FATAL, "segment too big"); #endif #endif /* all done */ return v; } /* Get the fd for the relation, opening it if it's not already open */ static int _mdfd_getrelnfd(Relation reln) { int fd; fd = RelationGetFile(reln); if (fd < 0) { if ((fd = mdopen(reln)) < 0) elog(ERROR, "could not open relation \"%s\": %m", RelationGetRelationName(reln)); reln->rd_fd = fd; } return fd; } /* Find the segment of the relation holding the specified block */ static MdfdVec * _mdfd_getseg(Relation reln, BlockNumber blkno) { MdfdVec *v; int fd; #ifndef LET_OS_MANAGE_FILESIZE BlockNumber segno; BlockNumber i; #endif fd = _mdfd_getrelnfd(reln); #ifndef LET_OS_MANAGE_FILESIZE for (v = &Md_fdvec[fd], segno = blkno / ((BlockNumber) RELSEG_SIZE), i = 1; segno > 0; i++, segno--) { if (v->mdfd_chain == (MdfdVec *) NULL) { /* * We will create the next segment only if the target block is * within it. This prevents Sorcerer's Apprentice syndrome if * a bug at higher levels causes us to be handed a * ridiculously large blkno --- otherwise we could create many * thousands of empty segment files before reaching the * "target" block. We should never need to create more than * one new segment per call, so this restriction seems * reasonable. */ v->mdfd_chain = _mdfd_openseg(reln, i, (segno == 1) ? O_CREAT : 0); if (v->mdfd_chain == (MdfdVec *) NULL) elog(ERROR, "could not open segment %u of relation \"%s\" (target block %u): %m", i, RelationGetRelationName(reln), blkno); } v = v->mdfd_chain; } #else v = &Md_fdvec[fd]; #endif return v; } /* * Find the segment of the relation holding the specified block. * * This performs the same work as _mdfd_getseg() except that we must work * "blind" with no Relation struct. We assume that we are not likely to * touch the same relation again soon, so we do not create an FD entry for * the relation --- we just open a kernel file descriptor which will be * used and promptly closed. We also assume that the target block already * exists, ie, we need not extend the relation. * * The return value is the kernel descriptor, or -1 on failure. */ static int _mdfd_blind_getseg(RelFileNode rnode, BlockNumber blkno) { char *path; int fd; #ifndef LET_OS_MANAGE_FILESIZE BlockNumber segno; #endif path = relpath(rnode); #ifndef LET_OS_MANAGE_FILESIZE /* append the '.segno', if needed */ segno = blkno / ((BlockNumber) RELSEG_SIZE); if (segno > 0) { char *segpath = (char *) palloc(strlen(path) + 12); sprintf(segpath, "%s.%u", path, segno); pfree(path); path = segpath; } #endif /* call fd.c to allow other FDs to be closed if needed */ fd = BasicOpenFile(path, O_RDWR | PG_BINARY, 0600); if (fd < 0) elog(LOG, "could not open \"%s\": %m", path); pfree(path); return fd; } static BlockNumber _mdnblocks(File file, Size blcksz) { long len; len = FileSeek(file, 0L, SEEK_END); if (len < 0) return 0; /* on failure, assume file is empty */ return (BlockNumber) (len / blcksz); }