/* fatfile.c Functions used by the newlib disc stubs to interface with this library Copyright (c) 2006 Michael "Chishm" Chisholm Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. The name of the author may not be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "fatfile.h" #include #include #include #include #include #include "cache.h" #include "file_allocation_table.h" #include "bit_ops.h" #include "filetime.h" #include "lock.h" int _FAT_open_r (struct _reent *r, void *fileStruct, const char *path, int flags, int mode) { PARTITION* partition = NULL; bool fileExists; DIR_ENTRY dirEntry; const char* pathEnd; uint32_t dirCluster; FILE_STRUCT* file = (FILE_STRUCT*) fileStruct; partition = _FAT_partition_getPartitionFromPath (path); if (partition == NULL) { r->_errno = ENODEV; return -1; } // Move the path pointer to the start of the actual path if (strchr (path, ':') != NULL) { path = strchr (path, ':') + 1; } if (strchr (path, ':') != NULL) { r->_errno = EINVAL; return -1; } // Determine which mode the file is openned for if ((flags & 0x03) == O_RDONLY) { // Open the file for read-only access file->read = true; file->write = false; file->append = false; } else if ((flags & 0x03) == O_WRONLY) { // Open file for write only access file->read = false; file->write = true; file->append = false; } else if ((flags & 0x03) == O_RDWR) { // Open file for read/write access file->read = true; file->write = true; file->append = false; } else { r->_errno = EACCES; return -1; } // Make sure we aren't trying to write to a read-only disc if (file->write && partition->readOnly) { r->_errno = EROFS; return -1; } // Search for the file on the disc _FAT_lock(&partition->lock); fileExists = _FAT_directory_entryFromPath (partition, &dirEntry, path, NULL); // The file shouldn't exist if we are trying to create it if ((flags & O_CREAT) && (flags & O_EXCL) && fileExists) { _FAT_unlock(&partition->lock); r->_errno = EEXIST; return -1; } // It should not be a directory if we're openning a file, if (fileExists && _FAT_directory_isDirectory(&dirEntry)) { _FAT_unlock(&partition->lock); r->_errno = EISDIR; return -1; } // If the file doesn't exist, create it if we're allowed to if (!fileExists) { if (flags & O_CREAT) { if (partition->readOnly) { // We can't write to a read-only partition _FAT_unlock(&partition->lock); r->_errno = EROFS; return -1; } // Create the file // Get the directory it has to go in pathEnd = strrchr (path, DIR_SEPARATOR); if (pathEnd == NULL) { // No path was specified dirCluster = partition->cwdCluster; pathEnd = path; } else { // Path was specified -- get the right dirCluster // Recycling dirEntry, since it needs to be recreated anyway if (!_FAT_directory_entryFromPath (partition, &dirEntry, path, pathEnd) || !_FAT_directory_isDirectory(&dirEntry)) { _FAT_unlock(&partition->lock); r->_errno = ENOTDIR; return -1; } dirCluster = _FAT_directory_entryGetCluster (partition, dirEntry.entryData); // Move the pathEnd past the last DIR_SEPARATOR pathEnd += 1; } // Create the entry data strncpy (dirEntry.filename, pathEnd, MAX_FILENAME_LENGTH - 1); memset (dirEntry.entryData, 0, DIR_ENTRY_DATA_SIZE); // Set the creation time and date dirEntry.entryData[DIR_ENTRY_cTime_ms] = 0; u16_to_u8array (dirEntry.entryData, DIR_ENTRY_cTime, _FAT_filetime_getTimeFromRTC()); u16_to_u8array (dirEntry.entryData, DIR_ENTRY_cDate, _FAT_filetime_getDateFromRTC()); if (!_FAT_directory_addEntry (partition, &dirEntry, dirCluster)) { _FAT_unlock(&partition->lock); r->_errno = ENOSPC; return -1; } } else { // file doesn't exist, and we aren't creating it _FAT_unlock(&partition->lock); r->_errno = ENOENT; return -1; } } file->filesize = u8array_to_u32 (dirEntry.entryData, DIR_ENTRY_fileSize); /* Allow LARGEFILEs with undefined results // Make sure that the file size can fit in the available space if (!(flags & O_LARGEFILE) && (file->filesize >= (1<<31))) { r->_errno = EFBIG; return -1; } */ // Make sure we aren't trying to write to a read-only file if (file->write && !_FAT_directory_isWritable(&dirEntry)) { _FAT_unlock(&partition->lock); r->_errno = EROFS; return -1; } // Associate this file with a particular partition file->partition = partition; file->startCluster = _FAT_directory_entryGetCluster (partition, dirEntry.entryData); // Truncate the file if requested if ((flags & O_TRUNC) && file->write && (file->startCluster != 0)) { _FAT_fat_clearLinks (partition, file->startCluster); file->startCluster = CLUSTER_FREE; file->filesize = 0; } // Remember the position of this file's directory entry file->dirEntryStart = dirEntry.dataStart; // Points to the start of the LFN entries of a file, or the alias for no LFN file->dirEntryEnd = dirEntry.dataEnd; // Reset read/write pointer file->currentPosition = 0; file->rwPosition.cluster = file->startCluster; file->rwPosition.sector = 0; file->rwPosition.byte = 0; if (flags & O_APPEND) { file->append = true; // Set append pointer to the end of the file file->appendPosition.cluster = _FAT_fat_lastCluster (partition, file->startCluster); file->appendPosition.sector = (file->filesize % partition->bytesPerCluster) / BYTES_PER_READ; file->appendPosition.byte = file->filesize % BYTES_PER_READ; // Check if the end of the file is on the end of a cluster if ( (file->filesize > 0) && ((file->filesize % partition->bytesPerCluster)==0) ){ // Set flag to allocate a new cluster file->appendPosition.sector = partition->sectorsPerCluster; file->appendPosition.byte = 0; } } else { file->append = false; // Use something sane for the append pointer, so the whole file struct contains known values file->appendPosition = file->rwPosition; } file->modified = false; file->inUse = true; // Insert this file into the double-linked list of open files partition->openFileCount += 1; if (partition->firstOpenFile) { file->nextOpenFile = partition->firstOpenFile; partition->firstOpenFile->prevOpenFile = file; } else { file->nextOpenFile = NULL; } file->prevOpenFile = NULL; partition->firstOpenFile = file; _FAT_unlock(&partition->lock); return (int) file; } /* Synchronizes the file data to disc. Does no locking of its own -- lock the partition before calling. Returns 0 on success, an error code on failure. */ int _FAT_syncToDisc (FILE_STRUCT* file) { uint8_t dirEntryData[DIR_ENTRY_DATA_SIZE]; if (!file || !file->inUse) { return EBADF; } if (file->write && file->modified) { // Load the old entry _FAT_cache_readPartialSector (file->partition->cache, dirEntryData, _FAT_fat_clusterToSector(file->partition, file->dirEntryEnd.cluster) + file->dirEntryEnd.sector, file->dirEntryEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); // Write new data to the directory entry // File size u32_to_u8array (dirEntryData, DIR_ENTRY_fileSize, file->filesize); // Start cluster u16_to_u8array (dirEntryData, DIR_ENTRY_cluster, file->startCluster); u16_to_u8array (dirEntryData, DIR_ENTRY_clusterHigh, file->startCluster >> 16); // Modification time and date u16_to_u8array (dirEntryData, DIR_ENTRY_mTime, _FAT_filetime_getTimeFromRTC()); u16_to_u8array (dirEntryData, DIR_ENTRY_mDate, _FAT_filetime_getDateFromRTC()); // Access date u16_to_u8array (dirEntryData, DIR_ENTRY_aDate, _FAT_filetime_getDateFromRTC()); // Set archive attribute dirEntryData[DIR_ENTRY_attributes] |= ATTRIB_ARCH; // Write the new entry _FAT_cache_writePartialSector (file->partition->cache, dirEntryData, _FAT_fat_clusterToSector(file->partition, file->dirEntryEnd.cluster) + file->dirEntryEnd.sector, file->dirEntryEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); // Flush any sectors in the disc cache if (!_FAT_cache_flush(file->partition->cache)) { return EIO; } } file->modified = false; return 0; } int _FAT_close_r (struct _reent *r, int fd) { FILE_STRUCT* file = (FILE_STRUCT*) fd; int ret = 0; if (!file->inUse) { r->_errno = EBADF; return -1; } _FAT_lock(&file->partition->lock); ret = _FAT_syncToDisc (file); if (ret != 0) { r->_errno = ret; ret = -1; } file->inUse = false; // Remove this file from the double-linked list of open files file->partition->openFileCount -= 1; if (file->nextOpenFile) { file->nextOpenFile->prevOpenFile = file->prevOpenFile; } if (file->prevOpenFile) { file->prevOpenFile->nextOpenFile = file->nextOpenFile; } else { file->partition->firstOpenFile = file->nextOpenFile; } _FAT_unlock(&file->partition->lock); return ret; } ssize_t _FAT_read_r (struct _reent *r, int fd, char *ptr, size_t len) { FILE_STRUCT* file = (FILE_STRUCT*) fd; PARTITION* partition; CACHE* cache; FILE_POSITION position; uint32_t tempNextCluster; unsigned int tempVar; size_t remain; bool flagNoError = true; // Make sure we can actually read from the file if ((file == NULL) || !file->inUse || !file->read) { r->_errno = EBADF; return -1; } partition = file->partition; _FAT_lock(&partition->lock); // Don't try to read if the read pointer is past the end of file if (file->currentPosition >= file->filesize || file->startCluster == CLUSTER_FREE) { r->_errno = EOVERFLOW; return 0; } // Don't read past end of file if (len + file->currentPosition > file->filesize) { r->_errno = EOVERFLOW; len = file->filesize - file->currentPosition; } // Short circuit cases where len is 0 (or less) if (len <= 0) { return 0; } remain = len; position = file->rwPosition; cache = file->partition->cache; // Align to sector tempVar = BYTES_PER_READ - position.byte; if (tempVar > remain) { tempVar = remain; } if ((tempVar < BYTES_PER_READ) && flagNoError) { _FAT_cache_readPartialSector ( cache, ptr, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, position.byte, tempVar); remain -= tempVar; ptr += tempVar; position.byte += tempVar; if (position.byte >= BYTES_PER_READ) { position.byte = 0; position.sector++; } } // align to cluster // tempVar is number of sectors to read if (remain > (partition->sectorsPerCluster - position.sector) * BYTES_PER_READ) { tempVar = partition->sectorsPerCluster - position.sector; } else { tempVar = remain / BYTES_PER_READ; } if ((tempVar > 0) && flagNoError) { if (! _FAT_disc_readSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, tempVar, ptr)) { flagNoError = false; r->_errno = EIO; } else { ptr += tempVar * BYTES_PER_READ; remain -= tempVar * BYTES_PER_READ; position.sector += tempVar; } } // Move onto next cluster // It should get to here without reading anything if a cluster is due to be allocated if ((position.sector >= partition->sectorsPerCluster) && flagNoError) { tempNextCluster = _FAT_fat_nextCluster(partition, position.cluster); if ((remain == 0) && (tempNextCluster == CLUSTER_EOF)) { position.sector = partition->sectorsPerCluster; } else if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { r->_errno = EIO; flagNoError = false; } else { position.sector = 0; position.cluster = tempNextCluster; } } // Read in whole clusters, contiguous blocks at a time while ((remain >= partition->bytesPerCluster) && flagNoError) { uint32_t chunkEnd; uint32_t nextChunkStart = position.cluster; size_t chunkSize = 0; do { chunkEnd = nextChunkStart; nextChunkStart = _FAT_fat_nextCluster (partition, chunkEnd); chunkSize += partition->bytesPerCluster; } while ((nextChunkStart == chunkEnd + 1) && #ifdef LIMIT_SECTORS (chunkSize + partition->bytesPerCluster <= LIMIT_SECTORS * BYTES_PER_READ) && #endif (chunkSize + partition->bytesPerCluster <= remain)); if (!_FAT_disc_readSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster), chunkSize / BYTES_PER_READ, ptr)) { flagNoError = false; r->_errno = EIO; break; } ptr += chunkSize; remain -= chunkSize; // Advance to next cluster if ((remain == 0) && (nextChunkStart == CLUSTER_EOF)) { position.sector = partition->sectorsPerCluster; position.cluster = chunkEnd; } else if (!_FAT_fat_isValidCluster(partition, nextChunkStart)) { r->_errno = EIO; flagNoError = false; } else { position.sector = 0; position.cluster = nextChunkStart; } } // Read remaining sectors tempVar = remain / BYTES_PER_READ; // Number of sectors left if ((tempVar > 0) && flagNoError) { if (!_FAT_disc_readSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster), tempVar, ptr)) { flagNoError = false; r->_errno = EIO; } else { ptr += tempVar * BYTES_PER_READ; remain -= tempVar * BYTES_PER_READ; position.sector += tempVar; } } // Last remaining sector // Check if anything is left if ((remain > 0) && flagNoError) { _FAT_cache_readPartialSector ( cache, ptr, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, 0, remain); position.byte += remain; remain = 0; } // Length read is the wanted length minus the stuff not read len = len - remain; // Update file information file->rwPosition = position; file->currentPosition += len; _FAT_unlock(&partition->lock); return len; } /* Extend a file so that the size is the same as the rwPosition */ static bool _FAT_file_extend_r (struct _reent *r, FILE_STRUCT* file) { PARTITION* partition = file->partition; CACHE* cache = file->partition->cache; FILE_POSITION position; uint8_t zeroBuffer [BYTES_PER_READ] = {0}; uint32_t remain; uint32_t tempNextCluster; position.byte = file->filesize % BYTES_PER_READ; position.sector = (file->filesize % partition->bytesPerCluster) / BYTES_PER_READ; // It is assumed that there is always a startCluster // This will be true when _FAT_file_extend_r is called from _FAT_write_r position.cluster = _FAT_fat_lastCluster (partition, file->startCluster); remain = file->currentPosition - file->filesize; if ((remain > 0) && (file->filesize > 0) && (position.sector == 0) && (position.byte == 0)) { // Get a new cluster on the edge of a cluster boundary tempNextCluster = _FAT_fat_linkFreeCluster(partition, position.cluster); if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; return false; } position.cluster = tempNextCluster; position.sector = 0; } if (remain + position.byte < BYTES_PER_READ) { // Only need to clear to the end of the sector _FAT_cache_writePartialSector (cache, zeroBuffer, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, position.byte, remain); position.byte += remain; } else { if (position.byte > 0) { _FAT_cache_writePartialSector (cache, zeroBuffer, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, position.byte, BYTES_PER_READ - position.byte); remain -= (BYTES_PER_READ - position.byte); position.byte = 0; position.sector ++; } while (remain >= BYTES_PER_READ) { if (position.sector >= partition->sectorsPerCluster) { position.sector = 0; // Ran out of clusters so get a new one tempNextCluster = _FAT_fat_linkFreeCluster(partition, position.cluster); if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; return false; } position.cluster = tempNextCluster; } _FAT_disc_writeSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, 1, zeroBuffer); remain -= BYTES_PER_READ; position.sector ++; } if (position.sector >= partition->sectorsPerCluster) { position.sector = 0; tempNextCluster = _FAT_fat_nextCluster(partition, position.cluster); if ((tempNextCluster == CLUSTER_EOF) || (tempNextCluster == CLUSTER_FREE)) { // Ran out of clusters so get a new one tempNextCluster = _FAT_fat_linkFreeCluster(partition, position.cluster); } if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; return false; } position.cluster = tempNextCluster; } if (remain > 0) { _FAT_cache_writePartialSector (cache, zeroBuffer, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, 0, remain); position.byte = remain; } } file->rwPosition = position; file->filesize = file->currentPosition; return true; } ssize_t _FAT_write_r (struct _reent *r, int fd, const char *ptr, size_t len) { FILE_STRUCT* file = (FILE_STRUCT*) fd; PARTITION* partition; CACHE* cache; FILE_POSITION position; uint32_t tempNextCluster; unsigned int tempVar; size_t remain; bool flagNoError = true; bool flagAppending = false; // Make sure we can actually write to the file if ((file == NULL) || !file->inUse || !file->write) { r->_errno = EBADF; return -1; } partition = file->partition; cache = file->partition->cache; _FAT_lock(&partition->lock); // Only write up to the maximum file size, taking into account wrap-around of ints if (remain + file->filesize > FILE_MAX_SIZE || len + file->filesize < file->filesize) { len = FILE_MAX_SIZE - file->filesize; } remain = len; // Short circuit cases where len is 0 (or less) if (len <= 0) { _FAT_unlock(&partition->lock); return 0; } // Get a new cluster for the start of the file if required if (file->startCluster == CLUSTER_FREE) { tempNextCluster = _FAT_fat_linkFreeCluster (partition, CLUSTER_FREE); if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort immediately _FAT_unlock(&partition->lock); r->_errno = ENOSPC; return -1; } file->startCluster = tempNextCluster; // Appending starts at the begining for a 0 byte file file->appendPosition.cluster = file->startCluster; file->appendPosition.sector = 0; file->appendPosition.byte = 0; file->rwPosition.cluster = file->startCluster; file->rwPosition.sector = 0; file->rwPosition.byte = 0; } if (file->append) { position = file->appendPosition; flagAppending = true; } else { // If the write pointer is past the end of the file, extend the file to that size if (file->currentPosition > file->filesize) { if (!_FAT_file_extend_r (r, file)) { _FAT_unlock(&partition->lock); return -1; } } // Write at current read pointer position = file->rwPosition; // If it is writing past the current end of file, set appending flag if (len + file->currentPosition > file->filesize) { flagAppending = true; } } // Move onto next cluster if needed if (position.sector >= partition->sectorsPerCluster) { position.sector = 0; tempNextCluster = _FAT_fat_nextCluster(partition, position.cluster); if ((tempNextCluster == CLUSTER_EOF) || (tempNextCluster == CLUSTER_FREE)) { // Ran out of clusters so get a new one tempNextCluster = _FAT_fat_linkFreeCluster(partition, position.cluster); } if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; flagNoError = false; } else { position.cluster = tempNextCluster; } } // Align to sector tempVar = BYTES_PER_READ - position.byte; if (tempVar > remain) { tempVar = remain; } if ((tempVar < BYTES_PER_READ) && flagNoError) { // Write partial sector to disk _FAT_cache_writePartialSector (cache, ptr, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, position.byte, tempVar); remain -= tempVar; ptr += tempVar; position.byte += tempVar; // Move onto next sector if (position.byte >= BYTES_PER_READ) { position.byte = 0; position.sector ++; } } // Align to cluster // tempVar is number of sectors to write if (remain > (partition->sectorsPerCluster - position.sector) * BYTES_PER_READ) { tempVar = partition->sectorsPerCluster - position.sector; } else { tempVar = remain / BYTES_PER_READ; } if ((tempVar > 0) && flagNoError) { if (!_FAT_disc_writeSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, tempVar, ptr)) { flagNoError = false; r->_errno = EIO; } else { ptr += tempVar * BYTES_PER_READ; remain -= tempVar * BYTES_PER_READ; position.sector += tempVar; } } if ((position.sector >= partition->sectorsPerCluster) && flagNoError && (remain > 0)) { position.sector = 0; tempNextCluster = _FAT_fat_nextCluster(partition, position.cluster); if ((tempNextCluster == CLUSTER_EOF) || (tempNextCluster == CLUSTER_FREE)) { // Ran out of clusters so get a new one tempNextCluster = _FAT_fat_linkFreeCluster(partition, position.cluster); } if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; flagNoError = false; } else { position.cluster = tempNextCluster; } } // Write whole clusters while ((remain >= partition->bytesPerCluster) && flagNoError) { uint32_t chunkEnd; uint32_t nextChunkStart = position.cluster; size_t chunkSize = 0; do { chunkEnd = nextChunkStart; nextChunkStart = _FAT_fat_nextCluster (partition, chunkEnd); if ((nextChunkStart == CLUSTER_EOF) || (nextChunkStart == CLUSTER_FREE)) { // Ran out of clusters so get a new one nextChunkStart = _FAT_fat_linkFreeCluster(partition, chunkEnd); } if (!_FAT_fat_isValidCluster(partition, nextChunkStart)) { // Couldn't get a cluster, so abort r->_errno = ENOSPC; flagNoError = false; } else { chunkSize += partition->bytesPerCluster; } } while (flagNoError && (nextChunkStart == chunkEnd + 1) && #ifdef LIMIT_SECTORS (chunkSize + partition->bytesPerCluster <= LIMIT_SECTORS * BYTES_PER_READ) && #endif (chunkSize + partition->bytesPerCluster <= remain)); if ( !_FAT_disc_writeSectors (partition->disc, _FAT_fat_clusterToSector(partition, position.cluster), chunkSize / BYTES_PER_READ, ptr)) { flagNoError = false; r->_errno = EIO; break; } ptr += chunkSize; remain -= chunkSize; if (_FAT_fat_isValidCluster(partition, nextChunkStart)) { position.cluster = nextChunkStart; } else { // Allocate a new cluster when next writing the file position.cluster = chunkEnd; position.sector = partition->sectorsPerCluster; } } // Write remaining sectors tempVar = remain / BYTES_PER_READ; // Number of sectors left if ((tempVar > 0) && flagNoError) { if (!_FAT_disc_writeSectors (partition->disc, _FAT_fat_clusterToSector (partition, position.cluster), tempVar, ptr)) { flagNoError = false; r->_errno = EIO; } else { ptr += tempVar * BYTES_PER_READ; remain -= tempVar * BYTES_PER_READ; position.sector += tempVar; } } // Last remaining sector if ((remain > 0) && flagNoError) { if (flagAppending) { _FAT_cache_eraseWritePartialSector ( cache, ptr, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, 0, remain); } else { _FAT_cache_writePartialSector ( cache, ptr, _FAT_fat_clusterToSector (partition, position.cluster) + position.sector, 0, remain); } position.byte += remain; remain = 0; } // Amount written is the originally requested amount minus stuff remaining len = len - remain; // Update file information file->modified = true; if (file->append) { // Appending doesn't affect the read pointer file->appendPosition = position; file->filesize += len; } else { // Writing also shifts the read pointer file->rwPosition = position; file->currentPosition += len; if (file->filesize < file->currentPosition) { file->filesize = file->currentPosition; } } _FAT_unlock(&partition->lock); return len; } off_t _FAT_seek_r (struct _reent *r, int fd, off_t pos, int dir) { FILE_STRUCT* file = (FILE_STRUCT*) fd; PARTITION* partition; uint32_t cluster, nextCluster; int clusCount; off_t newPosition; uint32_t position; if ((file == NULL) || (file->inUse == false)) { // invalid file r->_errno = EBADF; return -1; } partition = file->partition; _FAT_lock(&partition->lock); switch (dir) { case SEEK_SET: newPosition = pos; break; case SEEK_CUR: newPosition = (off_t)file->currentPosition + pos; break; case SEEK_END: newPosition = (off_t)file->filesize + pos; break; default: _FAT_unlock(&partition->lock); r->_errno = EINVAL; return -1; } if ((pos > 0) && (newPosition < 0)) { _FAT_unlock(&partition->lock); r->_errno = EOVERFLOW; return -1; } // newPosition can only be larger than the FILE_MAX_SIZE on platforms where // off_t is larger than 32 bits. if (newPosition < 0 || ((sizeof(newPosition) > 4) && newPosition > (off_t)FILE_MAX_SIZE)) { _FAT_unlock(&partition->lock); r->_errno = EINVAL; return -1; } position = (uint32_t)newPosition; // Only change the read/write position if it is within the bounds of the current filesize, // or at the very edge of the file if (position <= file->filesize && file->startCluster != CLUSTER_FREE) { // Calculate the sector and byte of the current position, // and store them file->rwPosition.sector = (position % partition->bytesPerCluster) / BYTES_PER_READ; file->rwPosition.byte = position % BYTES_PER_READ; // Calculate where the correct cluster is if ((position >= file->currentPosition) && (file->rwPosition.sector != partition->sectorsPerCluster)) { clusCount = (position / partition->bytesPerCluster) - (file->currentPosition / partition->bytesPerCluster); cluster = file->rwPosition.cluster; } else { clusCount = position / partition->bytesPerCluster; cluster = file->startCluster; } nextCluster = _FAT_fat_nextCluster (partition, cluster); while ((clusCount > 0) && (nextCluster != CLUSTER_FREE) && (nextCluster != CLUSTER_EOF)) { clusCount--; cluster = nextCluster; nextCluster = _FAT_fat_nextCluster (partition, cluster); } // Check if ran out of clusters and it needs to allocate a new one if (clusCount > 0) { if ((clusCount == 1) && (file->filesize == position) && (file->rwPosition.sector == 0)) { // Set flag to allocate a new cluster file->rwPosition.sector = partition->sectorsPerCluster; file->rwPosition.byte = 0; } else { _FAT_unlock(&partition->lock); r->_errno = EINVAL; return -1; } } file->rwPosition.cluster = cluster; } // Save position file->currentPosition = position; _FAT_unlock(&partition->lock); return position; } int _FAT_fstat_r (struct _reent *r, int fd, struct stat *st) { FILE_STRUCT* file = (FILE_STRUCT*) fd; PARTITION* partition; DIR_ENTRY fileEntry; if ((file == NULL) || (file->inUse == false)) { // invalid file r->_errno = EBADF; return -1; } partition = file->partition; _FAT_lock(&partition->lock); // Get the file's entry data fileEntry.dataStart = file->dirEntryStart; fileEntry.dataEnd = file->dirEntryEnd; if (!_FAT_directory_entryFromPosition (partition, &fileEntry)) { _FAT_unlock(&partition->lock); r->_errno = EIO; return -1; } // Fill in the stat struct _FAT_directory_entryStat (partition, &fileEntry, st); // Fix stats that have changed since the file was openned st->st_ino = (ino_t)(file->startCluster); // The file serial number is the start cluster st->st_size = file->filesize; // File size _FAT_unlock(&partition->lock); return 0; } int _FAT_ftruncate_r (struct _reent *r, int fd, off_t len) { FILE_STRUCT* file = (FILE_STRUCT*) fd; PARTITION* partition; int ret=0; uint32_t newSize = (uint32_t)len; if (len < 0) { // Trying to truncate to a negative size r->_errno = EINVAL; return -1; } if ((sizeof(len) > 4) && len > (off_t)FILE_MAX_SIZE) { // Trying to extend the file beyond what FAT supports r->_errno = EFBIG; return -1; } if (!file || !file->inUse) { // invalid file r->_errno = EBADF; return -1; } if (!file->write) { // Read-only file r->_errno = EINVAL; return -1; } partition = file->partition; _FAT_lock(&partition->lock); if (newSize > file->filesize) { // Expanding the file FILE_POSITION savedPosition; uint32_t savedOffset; // Get a new cluster for the start of the file if required if (file->startCluster == CLUSTER_FREE) { uint32_t tempNextCluster = _FAT_fat_linkFreeCluster (partition, CLUSTER_FREE); if (!_FAT_fat_isValidCluster(partition, tempNextCluster)) { // Couldn't get a cluster, so abort immediately _FAT_unlock(&partition->lock); r->_errno = ENOSPC; return -1; } file->startCluster = tempNextCluster; file->rwPosition.cluster = file->startCluster; file->rwPosition.sector = 0; file->rwPosition.byte = 0; } // Save the read/write pointer savedPosition = file->rwPosition; savedOffset = file->currentPosition; // Set the position to the new size file->currentPosition = newSize; // Extend the file to the new position if (!_FAT_file_extend_r (r, file)) { ret = -1; } // Set the append position to the new rwPointer if (file->append) { file->appendPosition = file->rwPosition; } // Restore the old rwPointer; file->rwPosition = savedPosition; file->currentPosition = savedOffset; } else if (newSize < file->filesize){ // Shrinking the file if (len == 0) { // Cutting the file down to nothing, clear all clusters used _FAT_fat_clearLinks (partition, file->startCluster); file->startCluster = CLUSTER_FREE; file->appendPosition.cluster = CLUSTER_FREE; file->appendPosition.sector = 0; file->appendPosition.byte = 0; } else { // Trimming the file down to the required size unsigned int chainLength; uint32_t lastCluster; // Drop the unneeded end of the cluster chain. // If the end falls on a cluster boundary, drop that cluster too, // then set a flag to allocate a cluster as needed chainLength = ((newSize-1) / partition->bytesPerCluster) + 1; lastCluster = _FAT_fat_trimChain (partition, file->startCluster, chainLength); if (file->append) { file->appendPosition.byte = newSize % BYTES_PER_READ; // Does the end of the file fall on the edge of a cluster? if (newSize % partition->bytesPerCluster == 0) { // Set a flag to allocate a new cluster file->appendPosition.sector = partition->sectorsPerCluster; } else { file->appendPosition.sector = (newSize % partition->bytesPerCluster) / BYTES_PER_READ; } file->appendPosition.cluster = lastCluster; } } } else { // Truncating to same length, so don't do anything } file->filesize = newSize; file->modified = true; _FAT_unlock(&partition->lock); return ret; } int _FAT_fsync_r (struct _reent *r, int fd) { FILE_STRUCT* file = (FILE_STRUCT*) fd; int ret = 0; if (!file->inUse) { r->_errno = EBADF; return -1; } _FAT_lock(&file->partition->lock); ret = _FAT_syncToDisc (file); if (ret != 0) { r->_errno = ret; ret = -1; } _FAT_unlock(&file->partition->lock); return ret; }