/*------------------------------------------------------------------------- * * buffile.c * Management of large buffered temporary files. * * Portions Copyright (c) 1996-2025, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * src/backend/storage/file/buffile.c * * NOTES: * * BufFiles provide a very incomplete emulation of stdio atop virtual Files * (as managed by fd.c). Currently, we only support the buffered-I/O * aspect of stdio: a read or write of the low-level File occurs only * when the buffer is filled or emptied. This is an even bigger win * for virtual Files than for ordinary kernel files, since reducing the * frequency with which a virtual File is touched reduces "thrashing" * of opening/closing file descriptors. * * Note that BufFile structs are allocated with palloc(), and therefore * will go away automatically at query/transaction end. Since the underlying * virtual Files are made with OpenTemporaryFile, all resources for * the file are certain to be cleaned up even if processing is aborted * by ereport(ERROR). The data structures required are made in the * palloc context that was current when the BufFile was created, and * any external resources such as temp files are owned by the ResourceOwner * that was current at that time. * * BufFile also supports temporary files that exceed the OS file size limit * (by opening multiple fd.c temporary files). This is an essential feature * for sorts and hashjoins on large amounts of data. * * BufFile supports temporary files that can be shared with other backends, as * infrastructure for parallel execution. Such files need to be created as a * member of a SharedFileSet that all participants are attached to. * * BufFile also supports temporary files that can be used by the single backend * when the corresponding files need to be survived across the transaction and * need to be opened and closed multiple times. Such files need to be created * as a member of a FileSet. *------------------------------------------------------------------------- */ #include "postgres.h" #include "commands/tablespace.h" #include "executor/instrument.h" #include "miscadmin.h" #include "pgstat.h" #include "storage/buffile.h" #include "storage/bufmgr.h" #include "storage/fd.h" #include "utils/resowner.h" /* * We break BufFiles into gigabyte-sized segments, regardless of RELSEG_SIZE. * The reason is that we'd like large BufFiles to be spread across multiple * tablespaces when available. */ #define MAX_PHYSICAL_FILESIZE 0x40000000 #define BUFFILE_SEG_SIZE (MAX_PHYSICAL_FILESIZE / BLCKSZ) /* * This data structure represents a buffered file that consists of one or * more physical files (each accessed through a virtual file descriptor * managed by fd.c). */ struct BufFile { int numFiles; /* number of physical files in set */ /* all files except the last have length exactly MAX_PHYSICAL_FILESIZE */ File *files; /* palloc'd array with numFiles entries */ bool isInterXact; /* keep open over transactions? */ bool dirty; /* does buffer need to be written? */ bool readOnly; /* has the file been set to read only? */ FileSet *fileset; /* space for fileset based segment files */ const char *name; /* name of fileset based BufFile */ /* * resowner is the ResourceOwner to use for underlying temp files. (We * don't need to remember the memory context we're using explicitly, * because after creation we only repalloc our arrays larger.) */ ResourceOwner resowner; /* * "current pos" is position of start of buffer within the logical file. * Position as seen by user of BufFile is (curFile, curOffset + pos). */ int curFile; /* file index (0..n) part of current pos */ off_t curOffset; /* offset part of current pos */ int pos; /* next read/write position in buffer */ int nbytes; /* total # of valid bytes in buffer */ /* * XXX Should ideally use PGIOAlignedBlock, but might need a way to avoid * wasting per-file alignment padding when some users create many files. */ PGAlignedBlock buffer; }; static BufFile *makeBufFileCommon(int nfiles); static BufFile *makeBufFile(File firstfile); static void extendBufFile(BufFile *file); static void BufFileLoadBuffer(BufFile *file); static void BufFileDumpBuffer(BufFile *file); static void BufFileFlush(BufFile *file); static File MakeNewFileSetSegment(BufFile *buffile, int segment); /* * Create BufFile and perform the common initialization. */ static BufFile * makeBufFileCommon(int nfiles) { BufFile *file = (BufFile *) palloc(sizeof(BufFile)); file->numFiles = nfiles; file->isInterXact = false; file->dirty = false; file->resowner = CurrentResourceOwner; file->curFile = 0; file->curOffset = 0; file->pos = 0; file->nbytes = 0; return file; } /* * Create a BufFile given the first underlying physical file. * NOTE: caller must set isInterXact if appropriate. */ static BufFile * makeBufFile(File firstfile) { BufFile *file = makeBufFileCommon(1); file->files = (File *) palloc(sizeof(File)); file->files[0] = firstfile; file->readOnly = false; file->fileset = NULL; file->name = NULL; return file; } /* * Add another component temp file. */ static void extendBufFile(BufFile *file) { File pfile; ResourceOwner oldowner; /* Be sure to associate the file with the BufFile's resource owner */ oldowner = CurrentResourceOwner; CurrentResourceOwner = file->resowner; if (file->fileset == NULL) pfile = OpenTemporaryFile(file->isInterXact); else pfile = MakeNewFileSetSegment(file, file->numFiles); Assert(pfile >= 0); CurrentResourceOwner = oldowner; file->files = (File *) repalloc(file->files, (file->numFiles + 1) * sizeof(File)); file->files[file->numFiles] = pfile; file->numFiles++; } /* * Create a BufFile for a new temporary file (which will expand to become * multiple temporary files if more than MAX_PHYSICAL_FILESIZE bytes are * written to it). * * If interXact is true, the temp file will not be automatically deleted * at end of transaction. * * Note: if interXact is true, the caller had better be calling us in a * memory context, and with a resource owner, that will survive across * transaction boundaries. */ BufFile * BufFileCreateTemp(bool interXact) { BufFile *file; File pfile; /* * Ensure that temp tablespaces are set up for OpenTemporaryFile to use. * Possibly the caller will have done this already, but it seems useful to * double-check here. Failure to do this at all would result in the temp * files always getting placed in the default tablespace, which is a * pretty hard-to-detect bug. Callers may prefer to do it earlier if they * want to be sure that any required catalog access is done in some other * resource context. */ PrepareTempTablespaces(); pfile = OpenTemporaryFile(interXact); Assert(pfile >= 0); file = makeBufFile(pfile); file->isInterXact = interXact; return file; } /* * Build the name for a given segment of a given BufFile. */ static void FileSetSegmentName(char *name, const char *buffile_name, int segment) { snprintf(name, MAXPGPATH, "%s.%d", buffile_name, segment); } /* * Create a new segment file backing a fileset based BufFile. */ static File MakeNewFileSetSegment(BufFile *buffile, int segment) { char name[MAXPGPATH]; File file; /* * It is possible that there are files left over from before a crash * restart with the same name. In order for BufFileOpenFileSet() not to * get confused about how many segments there are, we'll unlink the next * segment number if it already exists. */ FileSetSegmentName(name, buffile->name, segment + 1); FileSetDelete(buffile->fileset, name, true); /* Create the new segment. */ FileSetSegmentName(name, buffile->name, segment); file = FileSetCreate(buffile->fileset, name); /* FileSetCreate would've errored out */ Assert(file > 0); return file; } /* * Create a BufFile that can be discovered and opened read-only by other * backends that are attached to the same SharedFileSet using the same name. * * The naming scheme for fileset based BufFiles is left up to the calling code. * The name will appear as part of one or more filenames on disk, and might * provide clues to administrators about which subsystem is generating * temporary file data. Since each SharedFileSet object is backed by one or * more uniquely named temporary directory, names don't conflict with * unrelated SharedFileSet objects. */ BufFile * BufFileCreateFileSet(FileSet *fileset, const char *name) { BufFile *file; file = makeBufFileCommon(1); file->fileset = fileset; file->name = pstrdup(name); file->files = (File *) palloc(sizeof(File)); file->files[0] = MakeNewFileSetSegment(file, 0); file->readOnly = false; return file; } /* * Open a file that was previously created in another backend (or this one) * with BufFileCreateFileSet in the same FileSet using the same name. * The backend that created the file must have called BufFileClose() or * BufFileExportFileSet() to make sure that it is ready to be opened by other * backends and render it read-only. If missing_ok is true, which indicates * that missing files can be safely ignored, then return NULL if the BufFile * with the given name is not found, otherwise, throw an error. */ BufFile * BufFileOpenFileSet(FileSet *fileset, const char *name, int mode, bool missing_ok) { BufFile *file; char segment_name[MAXPGPATH]; Size capacity = 16; File *files; int nfiles = 0; files = palloc(sizeof(File) * capacity); /* * We don't know how many segments there are, so we'll probe the * filesystem to find out. */ for (;;) { /* See if we need to expand our file segment array. */ if (nfiles + 1 > capacity) { capacity *= 2; files = repalloc(files, sizeof(File) * capacity); } /* Try to load a segment. */ FileSetSegmentName(segment_name, name, nfiles); files[nfiles] = FileSetOpen(fileset, segment_name, mode); if (files[nfiles] <= 0) break; ++nfiles; CHECK_FOR_INTERRUPTS(); } /* * If we didn't find any files at all, then no BufFile exists with this * name. */ if (nfiles == 0) { /* free the memory */ pfree(files); if (missing_ok) return NULL; ereport(ERROR, (errcode_for_file_access(), errmsg("could not open temporary file \"%s\" from BufFile \"%s\": %m", segment_name, name))); } file = makeBufFileCommon(nfiles); file->files = files; file->readOnly = (mode == O_RDONLY); file->fileset = fileset; file->name = pstrdup(name); return file; } /* * Delete a BufFile that was created by BufFileCreateFileSet in the given * FileSet using the given name. * * It is not necessary to delete files explicitly with this function. It is * provided only as a way to delete files proactively, rather than waiting for * the FileSet to be cleaned up. * * Only one backend should attempt to delete a given name, and should know * that it exists and has been exported or closed otherwise missing_ok should * be passed true. */ void BufFileDeleteFileSet(FileSet *fileset, const char *name, bool missing_ok) { char segment_name[MAXPGPATH]; int segment = 0; bool found = false; /* * We don't know how many segments the file has. We'll keep deleting * until we run out. If we don't manage to find even an initial segment, * raise an error. */ for (;;) { FileSetSegmentName(segment_name, name, segment); if (!FileSetDelete(fileset, segment_name, true)) break; found = true; ++segment; CHECK_FOR_INTERRUPTS(); } if (!found && !missing_ok) elog(ERROR, "could not delete unknown BufFile \"%s\"", name); } /* * BufFileExportFileSet --- flush and make read-only, in preparation for sharing. */ void BufFileExportFileSet(BufFile *file) { /* Must be a file belonging to a FileSet. */ Assert(file->fileset != NULL); /* It's probably a bug if someone calls this twice. */ Assert(!file->readOnly); BufFileFlush(file); file->readOnly = true; } /* * Close a BufFile * * Like fclose(), this also implicitly FileCloses the underlying File. */ void BufFileClose(BufFile *file) { int i; /* flush any unwritten data */ BufFileFlush(file); /* close and delete the underlying file(s) */ for (i = 0; i < file->numFiles; i++) FileClose(file->files[i]); /* release the buffer space */ pfree(file->files); pfree(file); } /* * BufFileLoadBuffer * * Load some data into buffer, if possible, starting from curOffset. * At call, must have dirty = false, pos and nbytes = 0. * On exit, nbytes is number of bytes loaded. */ static void BufFileLoadBuffer(BufFile *file) { File thisfile; instr_time io_start; instr_time io_time; /* * Advance to next component file if necessary and possible. */ if (file->curOffset >= MAX_PHYSICAL_FILESIZE && file->curFile + 1 < file->numFiles) { file->curFile++; file->curOffset = 0; } thisfile = file->files[file->curFile]; if (track_io_timing) INSTR_TIME_SET_CURRENT(io_start); else INSTR_TIME_SET_ZERO(io_start); /* * Read whatever we can get, up to a full bufferload. */ file->nbytes = FileRead(thisfile, file->buffer.data, sizeof(file->buffer.data), file->curOffset, WAIT_EVENT_BUFFILE_READ); if (file->nbytes < 0) { file->nbytes = 0; ereport(ERROR, (errcode_for_file_access(), errmsg("could not read file \"%s\": %m", FilePathName(thisfile)))); } if (track_io_timing) { INSTR_TIME_SET_CURRENT(io_time); INSTR_TIME_ACCUM_DIFF(pgBufferUsage.temp_blk_read_time, io_time, io_start); } /* we choose not to advance curOffset here */ if (file->nbytes > 0) pgBufferUsage.temp_blks_read++; } /* * BufFileDumpBuffer * * Dump buffer contents starting at curOffset. * At call, should have dirty = true, nbytes > 0. * On exit, dirty is cleared if successful write, and curOffset is advanced. */ static void BufFileDumpBuffer(BufFile *file) { int wpos = 0; int bytestowrite; File thisfile; /* * Unlike BufFileLoadBuffer, we must dump the whole buffer even if it * crosses a component-file boundary; so we need a loop. */ while (wpos < file->nbytes) { off_t availbytes; instr_time io_start; instr_time io_time; /* * Advance to next component file if necessary and possible. */ if (file->curOffset >= MAX_PHYSICAL_FILESIZE) { while (file->curFile + 1 >= file->numFiles) extendBufFile(file); file->curFile++; file->curOffset = 0; } /* * Determine how much we need to write into this file. */ bytestowrite = file->nbytes - wpos; availbytes = MAX_PHYSICAL_FILESIZE - file->curOffset; if ((off_t) bytestowrite > availbytes) bytestowrite = (int) availbytes; thisfile = file->files[file->curFile]; if (track_io_timing) INSTR_TIME_SET_CURRENT(io_start); else INSTR_TIME_SET_ZERO(io_start); bytestowrite = FileWrite(thisfile, file->buffer.data + wpos, bytestowrite, file->curOffset, WAIT_EVENT_BUFFILE_WRITE); if (bytestowrite <= 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not write to file \"%s\": %m", FilePathName(thisfile)))); if (track_io_timing) { INSTR_TIME_SET_CURRENT(io_time); INSTR_TIME_ACCUM_DIFF(pgBufferUsage.temp_blk_write_time, io_time, io_start); } file->curOffset += bytestowrite; wpos += bytestowrite; pgBufferUsage.temp_blks_written++; } file->dirty = false; /* * At this point, curOffset has been advanced to the end of the buffer, * ie, its original value + nbytes. We need to make it point to the * logical file position, ie, original value + pos, in case that is less * (as could happen due to a small backwards seek in a dirty buffer!) */ file->curOffset -= (file->nbytes - file->pos); if (file->curOffset < 0) /* handle possible segment crossing */ { file->curFile--; Assert(file->curFile >= 0); file->curOffset += MAX_PHYSICAL_FILESIZE; } /* * Now we can set the buffer empty without changing the logical position */ file->pos = 0; file->nbytes = 0; } /* * BufFileRead variants * * Like fread() except we assume 1-byte element size and report I/O errors via * ereport(). * * If 'exact' is true, then an error is also raised if the number of bytes * read is not exactly 'size' (no short reads). If 'exact' and 'eofOK' are * true, then reading zero bytes is ok. */ static size_t BufFileReadCommon(BufFile *file, void *ptr, size_t size, bool exact, bool eofOK) { size_t start_size = size; size_t nread = 0; size_t nthistime; BufFileFlush(file); while (size > 0) { if (file->pos >= file->nbytes) { /* Try to load more data into buffer. */ file->curOffset += file->pos; file->pos = 0; file->nbytes = 0; BufFileLoadBuffer(file); if (file->nbytes <= 0) break; /* no more data available */ } nthistime = file->nbytes - file->pos; if (nthistime > size) nthistime = size; Assert(nthistime > 0); memcpy(ptr, file->buffer.data + file->pos, nthistime); file->pos += nthistime; ptr = (char *) ptr + nthistime; size -= nthistime; nread += nthistime; } if (exact && (nread != start_size && !(nread == 0 && eofOK))) ereport(ERROR, errcode_for_file_access(), file->name ? errmsg("could not read from file set \"%s\": read only %zu of %zu bytes", file->name, nread, start_size) : errmsg("could not read from temporary file: read only %zu of %zu bytes", nread, start_size)); return nread; } /* * Legacy interface where the caller needs to check for end of file or short * reads. */ size_t BufFileRead(BufFile *file, void *ptr, size_t size) { return BufFileReadCommon(file, ptr, size, false, false); } /* * Require read of exactly the specified size. */ void BufFileReadExact(BufFile *file, void *ptr, size_t size) { BufFileReadCommon(file, ptr, size, true, false); } /* * Require read of exactly the specified size, but optionally allow end of * file (in which case 0 is returned). */ size_t BufFileReadMaybeEOF(BufFile *file, void *ptr, size_t size, bool eofOK) { return BufFileReadCommon(file, ptr, size, true, eofOK); } /* * BufFileWrite * * Like fwrite() except we assume 1-byte element size and report errors via * ereport(). */ void BufFileWrite(BufFile *file, const void *ptr, size_t size) { size_t nthistime; Assert(!file->readOnly); while (size > 0) { if (file->pos >= BLCKSZ) { /* Buffer full, dump it out */ if (file->dirty) BufFileDumpBuffer(file); else { /* Hmm, went directly from reading to writing? */ file->curOffset += file->pos; file->pos = 0; file->nbytes = 0; } } nthistime = BLCKSZ - file->pos; if (nthistime > size) nthistime = size; Assert(nthistime > 0); memcpy(file->buffer.data + file->pos, ptr, nthistime); file->dirty = true; file->pos += nthistime; if (file->nbytes < file->pos) file->nbytes = file->pos; ptr = (const char *) ptr + nthistime; size -= nthistime; } } /* * BufFileFlush * * Like fflush(), except that I/O errors are reported with ereport(). */ static void BufFileFlush(BufFile *file) { if (file->dirty) BufFileDumpBuffer(file); Assert(!file->dirty); } /* * BufFileSeek * * Like fseek(), except that target position needs two values in order to * work when logical filesize exceeds maximum value representable by off_t. * We do not support relative seeks across more than that, however. * I/O errors are reported by ereport(). * * Result is 0 if OK, EOF if not. Logical position is not moved if an * impossible seek is attempted. */ int BufFileSeek(BufFile *file, int fileno, off_t offset, int whence) { int newFile; off_t newOffset; switch (whence) { case SEEK_SET: if (fileno < 0) return EOF; newFile = fileno; newOffset = offset; break; case SEEK_CUR: /* * Relative seek considers only the signed offset, ignoring * fileno. Note that large offsets (> 1 GB) risk overflow in this * add, unless we have 64-bit off_t. */ newFile = file->curFile; newOffset = (file->curOffset + file->pos) + offset; break; case SEEK_END: /* * The file size of the last file gives us the end offset of that * file. */ newFile = file->numFiles - 1; newOffset = FileSize(file->files[file->numFiles - 1]); if (newOffset < 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not determine size of temporary file \"%s\" from BufFile \"%s\": %m", FilePathName(file->files[file->numFiles - 1]), file->name))); break; default: elog(ERROR, "invalid whence: %d", whence); return EOF; } while (newOffset < 0) { if (--newFile < 0) return EOF; newOffset += MAX_PHYSICAL_FILESIZE; } if (newFile == file->curFile && newOffset >= file->curOffset && newOffset <= file->curOffset + file->nbytes) { /* * Seek is to a point within existing buffer; we can just adjust * pos-within-buffer, without flushing buffer. Note this is OK * whether reading or writing, but buffer remains dirty if we were * writing. */ file->pos = (int) (newOffset - file->curOffset); return 0; } /* Otherwise, must reposition buffer, so flush any dirty data */ BufFileFlush(file); /* * At this point and no sooner, check for seek past last segment. The * above flush could have created a new segment, so checking sooner would * not work (at least not with this code). */ /* convert seek to "start of next seg" to "end of last seg" */ if (newFile == file->numFiles && newOffset == 0) { newFile--; newOffset = MAX_PHYSICAL_FILESIZE; } while (newOffset > MAX_PHYSICAL_FILESIZE) { if (++newFile >= file->numFiles) return EOF; newOffset -= MAX_PHYSICAL_FILESIZE; } if (newFile >= file->numFiles) return EOF; /* Seek is OK! */ file->curFile = newFile; file->curOffset = newOffset; file->pos = 0; file->nbytes = 0; return 0; } void BufFileTell(BufFile *file, int *fileno, off_t *offset) { *fileno = file->curFile; *offset = file->curOffset + file->pos; } /* * BufFileSeekBlock --- block-oriented seek * * Performs absolute seek to the start of the n'th BLCKSZ-sized block of * the file. Note that users of this interface will fail if their files * exceed BLCKSZ * PG_INT64_MAX bytes, but that is quite a lot; we don't * work with tables bigger than that, either... * * Result is 0 if OK, EOF if not. Logical position is not moved if an * impossible seek is attempted. */ int BufFileSeekBlock(BufFile *file, int64 blknum) { return BufFileSeek(file, (int) (blknum / BUFFILE_SEG_SIZE), (off_t) (blknum % BUFFILE_SEG_SIZE) * BLCKSZ, SEEK_SET); } /* * Returns the amount of data in the given BufFile, in bytes. * * Returned value includes the size of any holes left behind by BufFileAppend. * ereport()s on failure. */ int64 BufFileSize(BufFile *file) { int64 lastFileSize; /* Get the size of the last physical file. */ lastFileSize = FileSize(file->files[file->numFiles - 1]); if (lastFileSize < 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not determine size of temporary file \"%s\" from BufFile \"%s\": %m", FilePathName(file->files[file->numFiles - 1]), file->name))); return ((file->numFiles - 1) * (int64) MAX_PHYSICAL_FILESIZE) + lastFileSize; } /* * Append the contents of the source file to the end of the target file. * * Note that operation subsumes ownership of underlying resources from * "source". Caller should never call BufFileClose against source having * called here first. Resource owners for source and target must match, * too. * * This operation works by manipulating lists of segment files, so the * file content is always appended at a MAX_PHYSICAL_FILESIZE-aligned * boundary, typically creating empty holes before the boundary. These * areas do not contain any interesting data, and cannot be read from by * caller. * * Returns the block number within target where the contents of source * begins. Caller should apply this as an offset when working off block * positions that are in terms of the original BufFile space. */ int64 BufFileAppend(BufFile *target, BufFile *source) { int64 startBlock = (int64) target->numFiles * BUFFILE_SEG_SIZE; int newNumFiles = target->numFiles + source->numFiles; int i; Assert(source->readOnly); Assert(!source->dirty); if (target->resowner != source->resowner) elog(ERROR, "could not append BufFile with non-matching resource owner"); target->files = (File *) repalloc(target->files, sizeof(File) * newNumFiles); for (i = target->numFiles; i < newNumFiles; i++) target->files[i] = source->files[i - target->numFiles]; target->numFiles = newNumFiles; return startBlock; } /* * Truncate a BufFile created by BufFileCreateFileSet up to the given fileno * and the offset. */ void BufFileTruncateFileSet(BufFile *file, int fileno, off_t offset) { int numFiles = file->numFiles; int newFile = fileno; off_t newOffset = file->curOffset; char segment_name[MAXPGPATH]; int i; /* * Loop over all the files up to the given fileno and remove the files * that are greater than the fileno and truncate the given file up to the * offset. Note that we also remove the given fileno if the offset is 0 * provided it is not the first file in which we truncate it. */ for (i = file->numFiles - 1; i >= fileno; i--) { if ((i != fileno || offset == 0) && i != 0) { FileSetSegmentName(segment_name, file->name, i); FileClose(file->files[i]); if (!FileSetDelete(file->fileset, segment_name, true)) ereport(ERROR, (errcode_for_file_access(), errmsg("could not delete fileset \"%s\": %m", segment_name))); numFiles--; newOffset = MAX_PHYSICAL_FILESIZE; /* * This is required to indicate that we have deleted the given * fileno. */ if (i == fileno) newFile--; } else { if (FileTruncate(file->files[i], offset, WAIT_EVENT_BUFFILE_TRUNCATE) < 0) ereport(ERROR, (errcode_for_file_access(), errmsg("could not truncate file \"%s\": %m", FilePathName(file->files[i])))); newOffset = offset; } } file->numFiles = numFiles; /* * If the truncate point is within existing buffer then we can just adjust * pos within buffer. */ if (newFile == file->curFile && newOffset >= file->curOffset && newOffset <= file->curOffset + file->nbytes) { /* No need to reset the current pos if the new pos is greater. */ if (newOffset <= file->curOffset + file->pos) file->pos = (int) (newOffset - file->curOffset); /* Adjust the nbytes for the current buffer. */ file->nbytes = (int) (newOffset - file->curOffset); } else if (newFile == file->curFile && newOffset < file->curOffset) { /* * The truncate point is within the existing file but prior to the * current position, so we can forget the current buffer and reset the * current position. */ file->curOffset = newOffset; file->pos = 0; file->nbytes = 0; } else if (newFile < file->curFile) { /* * The truncate point is prior to the current file, so need to reset * the current position accordingly. */ file->curFile = newFile; file->curOffset = newOffset; file->pos = 0; file->nbytes = 0; } /* Nothing to do, if the truncate point is beyond current file. */ }