/* directory.c Reading, writing and manipulation of the directory structure on a FAT partition 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 #include #include #include #include #include #include "directory.h" #include "common.h" #include "partition.h" #include "file_allocation_table.h" #include "bit_ops.h" #include "filetime.h" // Directory entry codes #define DIR_ENTRY_LAST 0x00 #define DIR_ENTRY_FREE 0xE5 #define LAST_LFN_POS (19*13) #define LAST_LFN_POS_CORRECTION (MAX_LFN_LENGTH-15) typedef unsigned short ucs2_t; // Long file name directory entry enum LFN_offset { LFN_offset_ordinal = 0x00, // Position within LFN LFN_offset_char0 = 0x01, LFN_offset_char1 = 0x03, LFN_offset_char2 = 0x05, LFN_offset_char3 = 0x07, LFN_offset_char4 = 0x09, LFN_offset_flag = 0x0B, // Should be equal to ATTRIB_LFN LFN_offset_reserved1 = 0x0C, // Always 0x00 LFN_offset_checkSum = 0x0D, // Checksum of short file name (alias) LFN_offset_char5 = 0x0E, LFN_offset_char6 = 0x10, LFN_offset_char7 = 0x12, LFN_offset_char8 = 0x14, LFN_offset_char9 = 0x16, LFN_offset_char10 = 0x18, LFN_offset_reserved2 = 0x1A, // Always 0x0000 LFN_offset_char11 = 0x1C, LFN_offset_char12 = 0x1E }; static const int LFN_offset_table[13]={0x01,0x03,0x05,0x07,0x09,0x0E,0x10,0x12,0x14,0x16,0x18,0x1C,0x1E}; #define LFN_END 0x40 #define LFN_DEL 0x80 static const char ILLEGAL_ALIAS_CHARACTERS[] = "\\/:;*?\"<>|&+,=[] "; static const char ILLEGAL_LFN_CHARACTERS[] = "\\/:*?\"<>|"; /* Returns number of UCS-2 characters needed to encode an LFN Returns -1 if it is an invalid LFN */ #define ABOVE_UCS_RANGE 0xF0 static int _FAT_directory_lfnLength (const char* name) { unsigned int i; size_t nameLength; int ucsLength; const char* tempName = name; nameLength = strnlen(name, MAX_FILENAME_LENGTH); // Make sure the name is short enough to be valid if ( nameLength >= MAX_FILENAME_LENGTH) { return -1; } // Make sure it doesn't contain any invalid characters if (strpbrk (name, ILLEGAL_LFN_CHARACTERS) != NULL) { return -1; } // Make sure the name doesn't contain any control codes or codes not representable in UCS-2 for (i = 0; i < nameLength; i++) { if (name[i] < 0x20 || name[i] >= ABOVE_UCS_RANGE) { return -1; } } // Convert to UCS-2 and get the resulting length ucsLength = mbsrtowcs(NULL, &tempName, MAX_LFN_LENGTH, NULL); if (ucsLength < 0 || ucsLength >= MAX_LFN_LENGTH) { return -1; } // Otherwise it is valid return ucsLength; } /* Convert a multibyte encoded string into a NUL-terminated UCS-2 string, storing at most len characters return number of characters stored */ static size_t _FAT_directory_mbstoucs2 (ucs2_t* dst, const char* src, size_t len) { mbstate_t ps = {0}; wchar_t tempChar; int bytes; size_t count = 0; while (count < len-1 && *src != '\0') { bytes = mbrtowc (&tempChar, src, MB_CUR_MAX, &ps); if (bytes > 0) { *dst = (ucs2_t)tempChar; src += bytes; dst++; count++; } else if (bytes == 0) { break; } else { return -1; } } *dst = '\0'; return count; } /* Convert a UCS-2 string into a NUL-terminated multibyte string, storing at most len chars return number of chars stored, or (size_t)-1 on error */ static size_t _FAT_directory_ucs2tombs (char* dst, const ucs2_t* src, size_t len) { mbstate_t ps = {0}; size_t count = 0; int bytes; char buff[MB_CUR_MAX]; int i; while (count < len - 1 && *src != '\0') { bytes = wcrtomb (buff, *src, &ps); if (bytes < 0) { return -1; } if (count + bytes < len && bytes > 0) { for (i = 0; i < bytes; i++) { *dst++ = buff[i]; } src++; count += bytes; } else { break; } } *dst = L'\0'; return count; } /* Case-independent comparison of two multibyte encoded strings */ static int _FAT_directory_mbsncasecmp (const char* s1, const char* s2, size_t len1) { wchar_t wc1, wc2; mbstate_t ps1 = {0}; mbstate_t ps2 = {0}; size_t b1 = 0; size_t b2 = 0; if (len1 == 0) { return 0; } do { s1 += b1; s2 += b2; b1 = mbrtowc(&wc1, s1, MB_CUR_MAX, &ps1); b2 = mbrtowc(&wc2, s2, MB_CUR_MAX, &ps2); if ((int)b1 < 0 || (int)b2 < 0) { break; } len1 -= b1; } while (len1 > 0 && towlower(wc1) == towlower(wc2) && wc1 != 0); return towlower(wc1) - towlower(wc2); } static bool _FAT_directory_entryGetAlias (const u8* entryData, char* destName) { char c; bool caseInfo; int i = 0; int j = 0; destName[0] = '\0'; if (entryData[0] != DIR_ENTRY_FREE) { if (entryData[0] == '.') { destName[0] = '.'; if (entryData[1] == '.') { destName[1] = '.'; destName[2] = '\0'; } else { destName[1] = '\0'; } } else { // Copy the filename from the dirEntry to the string caseInfo = entryData[DIR_ENTRY_caseInfo] & CASE_LOWER_BASE; for (i = 0; (i < 8) && (entryData[DIR_ENTRY_name + i] != ' '); i++) { c = entryData[DIR_ENTRY_name + i]; destName[i] = (caseInfo ? tolower((unsigned char)c) : c); } // Copy the extension from the dirEntry to the string if (entryData[DIR_ENTRY_extension] != ' ') { destName[i++] = '.'; caseInfo = entryData[DIR_ENTRY_caseInfo] & CASE_LOWER_EXT; for ( j = 0; (j < 3) && (entryData[DIR_ENTRY_extension + j] != ' '); j++) { c = entryData[DIR_ENTRY_extension + j]; destName[i++] = (caseInfo ? tolower((unsigned char)c) : c); } } destName[i] = '\0'; } } return (destName[0] != '\0'); } uint32_t _FAT_directory_entryGetCluster (PARTITION* partition, const uint8_t* entryData) { if (partition->filesysType == FS_FAT32) { // Only use high 16 bits of start cluster when we are certain they are correctly defined return u8array_to_u16(entryData,DIR_ENTRY_cluster) | (u8array_to_u16(entryData, DIR_ENTRY_clusterHigh) << 16); } else { return u8array_to_u16(entryData,DIR_ENTRY_cluster); } } static bool _FAT_directory_incrementDirEntryPosition (PARTITION* partition, DIR_ENTRY_POSITION* entryPosition, bool extendDirectory) { DIR_ENTRY_POSITION position = *entryPosition; uint32_t tempCluster; // Increment offset, wrapping at the end of a sector ++ position.offset; if (position.offset == partition->bytesPerSector / DIR_ENTRY_DATA_SIZE) { position.offset = 0; // Increment sector when wrapping ++ position.sector; // But wrap at the end of a cluster if ((position.sector == partition->sectorsPerCluster) && (position.cluster != FAT16_ROOT_DIR_CLUSTER)) { position.sector = 0; // Move onto the next cluster, making sure there is another cluster to go to tempCluster = _FAT_fat_nextCluster(partition, position.cluster); if (tempCluster == CLUSTER_EOF) { if (extendDirectory) { tempCluster = _FAT_fat_linkFreeClusterCleared (partition, position.cluster); if (!_FAT_fat_isValidCluster(partition, tempCluster)) { return false; // This will only happen if the disc is full } } else { return false; // Got to the end of the directory, not extending it } } position.cluster = tempCluster; } else if ((position.cluster == FAT16_ROOT_DIR_CLUSTER) && (position.sector == (partition->dataStart - partition->rootDirStart))) { return false; // Got to end of root directory, can't extend it } } *entryPosition = position; return true; } bool _FAT_directory_getNextEntry (PARTITION* partition, DIR_ENTRY* entry) { DIR_ENTRY_POSITION entryStart; DIR_ENTRY_POSITION entryEnd; uint8_t entryData[0x20]; ucs2_t lfn[MAX_LFN_LENGTH]; bool notFound, found; int lfnPos; uint8_t lfnChkSum, chkSum; bool lfnExists; int i; lfnChkSum = 0; entryStart = entry->dataEnd; // Make sure we are using the correct root directory, in case of FAT32 if (entryStart.cluster == FAT16_ROOT_DIR_CLUSTER) { entryStart.cluster = partition->rootDirCluster; } entryEnd = entryStart; lfnExists = false; found = false; notFound = false; while (!found && !notFound) { if (_FAT_directory_incrementDirEntryPosition (partition, &entryEnd, false) == false) { notFound = true; } _FAT_cache_readPartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, entryEnd.cluster) + entryEnd.sector, entryEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); if (entryData[DIR_ENTRY_attributes] == ATTRIB_LFN) { // It's an LFN if (entryData[LFN_offset_ordinal] & LFN_DEL) { lfnExists = false; } else if (entryData[LFN_offset_ordinal] & LFN_END) { // Last part of LFN, make sure it isn't deleted using previous if(Thanks MoonLight) entryStart = entryEnd; // This is the start of a directory entry lfnExists = true; lfnPos = (entryData[LFN_offset_ordinal] & ~LFN_END) * 13; if (lfnPos > MAX_LFN_LENGTH - 1) { lfnPos = MAX_LFN_LENGTH - 1; } lfn[lfnPos] = '\0'; // Set end of lfn to null character lfnChkSum = entryData[LFN_offset_checkSum]; } if (lfnChkSum != entryData[LFN_offset_checkSum]) { lfnExists = false; } if (lfnExists) { lfnPos = ((entryData[LFN_offset_ordinal] & ~LFN_END) - 1) * 13; if (lfnPos > LAST_LFN_POS) { // Force it within the buffer. Will corrupt the filename but prevent buffer overflows lfnPos = LAST_LFN_POS; } for (i = 0; i < 13; i++) { lfn[lfnPos + i] = entryData[LFN_offset_table[i]] | (entryData[LFN_offset_table[i]+1] << 8); } } } else if (entryData[DIR_ENTRY_attributes] & ATTRIB_VOL) { // This is a volume name, don't bother with it } else if (entryData[0] == DIR_ENTRY_LAST) { notFound = true; } else if ((entryData[0] != DIR_ENTRY_FREE) && (entryData[0] > 0x20) && !(entryData[DIR_ENTRY_attributes] & ATTRIB_VOL)) { if (lfnExists) { // Calculate file checksum chkSum = 0; for (i=0; i < 11; i++) { // NOTE: The operation is an unsigned char rotate right chkSum = ((chkSum & 1) ? 0x80 : 0) + (chkSum >> 1) + entryData[i]; } if (chkSum != lfnChkSum) { lfnExists = false; entry->filename[0] = '\0'; } } if (lfnExists) { if (_FAT_directory_ucs2tombs (entry->filename, lfn, MAX_FILENAME_LENGTH) == (size_t)-1) { // Failed to convert the file name to UTF-8. Maybe the wrong locale is set? return false; } } else { entryStart = entryEnd; _FAT_directory_entryGetAlias (entryData, entry->filename); } found = true; } } // If no file is found, return false if (notFound) { return false; } else { // Fill in the directory entry struct entry->dataStart = entryStart; entry->dataEnd = entryEnd; memcpy (entry->entryData, entryData, DIR_ENTRY_DATA_SIZE); return true; } } bool _FAT_directory_getFirstEntry (PARTITION* partition, DIR_ENTRY* entry, uint32_t dirCluster) { entry->dataStart.cluster = dirCluster; entry->dataStart.sector = 0; entry->dataStart.offset = -1; // Start before the beginning of the directory entry->dataEnd = entry->dataStart; return _FAT_directory_getNextEntry (partition, entry); } bool _FAT_directory_getRootEntry (PARTITION* partition, DIR_ENTRY* entry) { entry->dataStart.cluster = 0; entry->dataStart.sector = 0; entry->dataStart.offset = 0; entry->dataEnd = entry->dataStart; memset (entry->filename, '\0', MAX_FILENAME_LENGTH); entry->filename[0] = '.'; memset (entry->entryData, 0, DIR_ENTRY_DATA_SIZE); memset (entry->entryData, ' ', 11); entry->entryData[0] = '.'; entry->entryData[DIR_ENTRY_attributes] = ATTRIB_DIR; u16_to_u8array (entry->entryData, DIR_ENTRY_cluster, partition->rootDirCluster); u16_to_u8array (entry->entryData, DIR_ENTRY_clusterHigh, partition->rootDirCluster >> 16); return true; } bool _FAT_directory_getVolumeLabel (PARTITION* partition, char *label) { DIR_ENTRY entry; DIR_ENTRY_POSITION entryEnd; uint8_t entryData[DIR_ENTRY_DATA_SIZE]; int i; bool end; _FAT_directory_getRootEntry(partition, &entry); entryEnd = entry.dataEnd; // Make sure we are using the correct root directory, in case of FAT32 if (entryEnd.cluster == FAT16_ROOT_DIR_CLUSTER) { entryEnd.cluster = partition->rootDirCluster; } label[0]='\0'; label[11]='\0'; end = false; //this entry should be among the first 3 entries in the root directory table, if not, then system can have trouble displaying the right volume label while(!end) { if(!_FAT_cache_readPartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, entryEnd.cluster) + entryEnd.sector, entryEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE)) { //error reading return false; } if (entryData[DIR_ENTRY_attributes] == ATTRIB_VOL && entryData[0] != DIR_ENTRY_FREE) { for (i = 0; i < 11; i++) { label[i] = entryData[DIR_ENTRY_name + i]; } return true; } else if (entryData[0] == DIR_ENTRY_LAST) { end = true; } if (_FAT_directory_incrementDirEntryPosition (partition, &entryEnd, false) == false) { end = true; } } return false; } bool _FAT_directory_entryFromPosition (PARTITION* partition, DIR_ENTRY* entry) { DIR_ENTRY_POSITION entryStart = entry->dataStart; DIR_ENTRY_POSITION entryEnd = entry->dataEnd; bool entryStillValid; bool finished; ucs2_t lfn[MAX_LFN_LENGTH]; int i; int lfnPos; uint8_t entryData[DIR_ENTRY_DATA_SIZE]; memset (entry->filename, '\0', MAX_FILENAME_LENGTH); // Create an empty directory entry to overwrite the old ones with for ( entryStillValid = true, finished = false; entryStillValid && !finished; entryStillValid = _FAT_directory_incrementDirEntryPosition (partition, &entryStart, false)) { _FAT_cache_readPartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, entryStart.cluster) + entryStart.sector, entryStart.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); if ((entryStart.cluster == entryEnd.cluster) && (entryStart.sector == entryEnd.sector) && (entryStart.offset == entryEnd.offset)) { // Copy the entry data and stop, since this is the last section of the directory entry memcpy (entry->entryData, entryData, DIR_ENTRY_DATA_SIZE); finished = true; } else { // Copy the long file name data lfnPos = ((entryData[LFN_offset_ordinal] & ~LFN_END) - 1) * 13; if (lfnPos > LAST_LFN_POS) { lfnPos = LAST_LFN_POS_CORRECTION; } for (i = 0; i < 13; i++) { lfn[lfnPos + i] = entryData[LFN_offset_table[i]] | (entryData[LFN_offset_table[i]+1] << 8); } } } if (!entryStillValid) { return false; } if ((entryStart.cluster == entryEnd.cluster) && (entryStart.sector == entryEnd.sector) && (entryStart.offset == entryEnd.offset)) { // Since the entry doesn't have a long file name, extract the short filename if (!_FAT_directory_entryGetAlias (entry->entryData, entry->filename)) { return false; } } else { // Encode the long file name into a multibyte string if (_FAT_directory_ucs2tombs (entry->filename, lfn, MAX_FILENAME_LENGTH) == (size_t)-1) { return false; } } return true; } bool _FAT_directory_entryFromPath (PARTITION* partition, DIR_ENTRY* entry, const char* path, const char* pathEnd) { size_t dirnameLength; const char* pathPosition; const char* nextPathPosition; uint32_t dirCluster; bool foundFile; char alias[MAX_ALIAS_LENGTH]; bool found, notFound; pathPosition = path; found = false; notFound = false; if (pathEnd == NULL) { // Set pathEnd to the end of the path string pathEnd = strchr (path, '\0'); } if (pathPosition[0] == DIR_SEPARATOR) { // Start at root directory dirCluster = partition->rootDirCluster; // Consume separator(s) while (pathPosition[0] == DIR_SEPARATOR) { pathPosition++; } // If the path is only specifying a directory in the form of "/" return it if (pathPosition >= pathEnd) { _FAT_directory_getRootEntry (partition, entry); found = true; } } else { // Start in current working directory dirCluster = partition->cwdCluster; } while (!found && !notFound) { // Get the name of the next required subdirectory within the path nextPathPosition = strchr (pathPosition, DIR_SEPARATOR); if (nextPathPosition != NULL) { dirnameLength = nextPathPosition - pathPosition; } else { dirnameLength = strlen(pathPosition); } if (dirnameLength > MAX_FILENAME_LENGTH) { // The path is too long to bother with return false; } // Check for "." or ".." when the dirCluster is root cluster // These entries do not exist, so we must fake it if ((dirCluster == partition->rootDirCluster) && ((strncmp(".", pathPosition, dirnameLength) == 0) || (strncmp("..", pathPosition, dirnameLength) == 0))) { foundFile = true; _FAT_directory_getRootEntry(partition, entry); } else { // Look for the directory within the path foundFile = _FAT_directory_getFirstEntry (partition, entry, dirCluster); while (foundFile && !found && !notFound) { // It hasn't already found the file // Check if the filename matches if ((dirnameLength == strnlen(entry->filename, MAX_FILENAME_LENGTH)) && (_FAT_directory_mbsncasecmp(pathPosition, entry->filename, dirnameLength) == 0)) { found = true; } // Check if the alias matches _FAT_directory_entryGetAlias (entry->entryData, alias); if ((dirnameLength == strnlen(alias, MAX_ALIAS_LENGTH)) && (strncasecmp(pathPosition, alias, dirnameLength) == 0)) { found = true; } if (found && !(entry->entryData[DIR_ENTRY_attributes] & ATTRIB_DIR) && (nextPathPosition != NULL)) { // Make sure that we aren't trying to follow a file instead of a directory in the path found = false; } if (!found) { foundFile = _FAT_directory_getNextEntry (partition, entry); } } } if (!foundFile) { // Check that the search didn't get to the end of the directory notFound = true; found = false; } else if ((nextPathPosition == NULL) || (nextPathPosition >= pathEnd)) { // Check that we reached the end of the path found = true; } else if (entry->entryData[DIR_ENTRY_attributes] & ATTRIB_DIR) { dirCluster = _FAT_directory_entryGetCluster (partition, entry->entryData); if (dirCluster == CLUSTER_ROOT) dirCluster = partition->rootDirCluster; pathPosition = nextPathPosition; // Consume separator(s) while (pathPosition[0] == DIR_SEPARATOR) { pathPosition++; } // The requested directory was found if (pathPosition >= pathEnd) { found = true; } else { found = false; } } } if (found && !notFound) { if (partition->filesysType == FS_FAT32 && (entry->entryData[DIR_ENTRY_attributes] & ATTRIB_DIR) && _FAT_directory_entryGetCluster (partition, entry->entryData) == CLUSTER_ROOT) { // On FAT32 it should specify an actual cluster for the root entry, // not cluster 0 as on FAT16 _FAT_directory_getRootEntry (partition, entry); } return true; } else { return false; } } bool _FAT_directory_removeEntry (PARTITION* partition, DIR_ENTRY* entry) { DIR_ENTRY_POSITION entryStart = entry->dataStart; DIR_ENTRY_POSITION entryEnd = entry->dataEnd; bool entryStillValid; bool finished; uint8_t entryData[DIR_ENTRY_DATA_SIZE]; // Create an empty directory entry to overwrite the old ones with for ( entryStillValid = true, finished = false; entryStillValid && !finished; entryStillValid = _FAT_directory_incrementDirEntryPosition (partition, &entryStart, false)) { _FAT_cache_readPartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, entryStart.cluster) + entryStart.sector, entryStart.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); entryData[0] = DIR_ENTRY_FREE; _FAT_cache_writePartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, entryStart.cluster) + entryStart.sector, entryStart.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); if ((entryStart.cluster == entryEnd.cluster) && (entryStart.sector == entryEnd.sector) && (entryStart.offset == entryEnd.offset)) { finished = true; } } if (!entryStillValid) { return false; } return true; } static bool _FAT_directory_findEntryGap (PARTITION* partition, DIR_ENTRY* entry, uint32_t dirCluster, size_t size) { DIR_ENTRY_POSITION gapStart; DIR_ENTRY_POSITION gapEnd; uint8_t entryData[DIR_ENTRY_DATA_SIZE]; size_t dirEntryRemain; bool endOfDirectory, entryStillValid; // Scan Dir for free entry gapEnd.offset = 0; gapEnd.sector = 0; gapEnd.cluster = dirCluster; gapStart = gapEnd; entryStillValid = true; dirEntryRemain = size; endOfDirectory = false; while (entryStillValid && !endOfDirectory && (dirEntryRemain > 0)) { _FAT_cache_readPartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, gapEnd.cluster) + gapEnd.sector, gapEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); if (entryData[0] == DIR_ENTRY_LAST) { gapStart = gapEnd; -- dirEntryRemain; endOfDirectory = true; } else if (entryData[0] == DIR_ENTRY_FREE) { if (dirEntryRemain == size) { gapStart = gapEnd; } -- dirEntryRemain; } else { dirEntryRemain = size; } if (!endOfDirectory && (dirEntryRemain > 0)) { entryStillValid = _FAT_directory_incrementDirEntryPosition (partition, &gapEnd, true); } } // Make sure the scanning didn't fail if (!entryStillValid) { return false; } // Save the start entry, since we know it is valid entry->dataStart = gapStart; if (endOfDirectory) { memset (entryData, DIR_ENTRY_LAST, DIR_ENTRY_DATA_SIZE); dirEntryRemain += 1; // Increase by one to take account of End Of Directory Marker while ((dirEntryRemain > 0) && entryStillValid) { // Get the gapEnd before incrementing it, so the second to last one is saved entry->dataEnd = gapEnd; // Increment gapEnd, moving onto the next entry entryStillValid = _FAT_directory_incrementDirEntryPosition (partition, &gapEnd, true); -- dirEntryRemain; // Fill the entry with blanks _FAT_cache_writePartialSector (partition->cache, entryData, _FAT_fat_clusterToSector(partition, gapEnd.cluster) + gapEnd.sector, gapEnd.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); } if (!entryStillValid) { return false; } } else { entry->dataEnd = gapEnd; } return true; } static bool _FAT_directory_entryExists (PARTITION* partition, const char* name, uint32_t dirCluster) { DIR_ENTRY tempEntry; bool foundFile; char alias[MAX_ALIAS_LENGTH]; size_t dirnameLength; dirnameLength = strnlen(name, MAX_FILENAME_LENGTH); if (dirnameLength >= MAX_FILENAME_LENGTH) { return false; } // Make sure the entry doesn't already exist foundFile = _FAT_directory_getFirstEntry (partition, &tempEntry, dirCluster); while (foundFile) { // It hasn't already found the file // Check if the filename matches if ((dirnameLength == strnlen(tempEntry.filename, MAX_FILENAME_LENGTH)) && (_FAT_directory_mbsncasecmp(name, tempEntry.filename, dirnameLength) == 0)) { return true; } // Check if the alias matches _FAT_directory_entryGetAlias (tempEntry.entryData, alias); if ((strncasecmp(name, alias, MAX_ALIAS_LENGTH) == 0)) { return true; } foundFile = _FAT_directory_getNextEntry (partition, &tempEntry); } return false; } /* Creates an alias for a long file name. If the alias is not an exact match for the filename, it returns the number of characters in the alias. If the two names match, it returns 0. If there was an error, it returns -1. */ static int _FAT_directory_createAlias (char* alias, const char* lfn) { bool lossyConversion = false; // Set when the alias had to be modified to be valid int lfnPos = 0; int aliasPos = 0; wchar_t lfnChar; int oemChar; mbstate_t ps = {0}; int bytesUsed = 0; const char* lfnExt; int aliasExtLen; // Strip leading periods while (lfn[lfnPos] == '.') { lfnPos ++; lossyConversion = true; } // Primary portion of alias while (aliasPos < 8 && lfn[lfnPos] != '.' && lfn[lfnPos] != '\0') { bytesUsed = mbrtowc(&lfnChar, lfn + lfnPos, MAX_FILENAME_LENGTH - lfnPos, &ps); if (bytesUsed < 0) { return -1; } oemChar = wctob(towupper((wint_t)lfnChar)); if (wctob((wint_t)lfnChar) != oemChar) { // Case of letter was changed lossyConversion = true; } if (oemChar == ' ') { // Skip spaces in filename lossyConversion = true; lfnPos += bytesUsed; continue; } if (oemChar == EOF) { oemChar = '_'; // Replace unconvertable characters with underscores lossyConversion = true; } if (strchr (ILLEGAL_ALIAS_CHARACTERS, oemChar) != NULL) { // Invalid Alias character oemChar = '_'; // Replace illegal characters with underscores lossyConversion = true; } alias[aliasPos] = (char)oemChar; aliasPos++; lfnPos += bytesUsed; } if (lfn[lfnPos] != '.' && lfn[lfnPos] != '\0') { // Name was more than 8 characters long lossyConversion = true; } // Alias extension lfnExt = strrchr (lfn, '.'); if (lfnExt != NULL && lfnExt != strchr (lfn, '.')) { // More than one period in name lossyConversion = true; } if (lfnExt != NULL && lfnExt[1] != '\0') { lfnExt++; alias[aliasPos] = '.'; aliasPos++; memset (&ps, 0, sizeof(ps)); for (aliasExtLen = 0; aliasExtLen < MAX_ALIAS_EXT_LENGTH && *lfnExt != '\0'; aliasExtLen++) { bytesUsed = mbrtowc(&lfnChar, lfnExt, MAX_FILENAME_LENGTH - lfnPos, &ps); if (bytesUsed < 0) { return -1; } oemChar = wctob(towupper((wint_t)lfnChar)); if (wctob((wint_t)lfnChar) != oemChar) { // Case of letter was changed lossyConversion = true; } if (oemChar == ' ') { // Skip spaces in alias lossyConversion = true; lfnExt += bytesUsed; continue; } if (oemChar == EOF) { oemChar = '_'; // Replace unconvertable characters with underscores lossyConversion = true; } if (strchr (ILLEGAL_ALIAS_CHARACTERS, oemChar) != NULL) { // Invalid Alias character oemChar = '_'; // Replace illegal characters with underscores lossyConversion = true; } alias[aliasPos] = (char)oemChar; aliasPos++; lfnExt += bytesUsed; } if (*lfnExt != '\0') { // Extension was more than 3 characters long lossyConversion = true; } } alias[aliasPos] = '\0'; if (lossyConversion) { return aliasPos; } else { return 0; } } bool _FAT_directory_addEntry (PARTITION* partition, DIR_ENTRY* entry, uint32_t dirCluster) { size_t entrySize; uint8_t lfnEntry[DIR_ENTRY_DATA_SIZE]; int i,j; // Must be signed for use when decrementing in for loop char *tmpCharPtr; DIR_ENTRY_POSITION curEntryPos; bool entryStillValid; uint8_t aliasCheckSum = 0; char alias [MAX_ALIAS_LENGTH]; int aliasLen; int lfnLen; // Make sure the filename is not 0 length if (strnlen (entry->filename, MAX_FILENAME_LENGTH) < 1) { return false; } // Make sure the filename is at least a valid LFN lfnLen = _FAT_directory_lfnLength (entry->filename); if (lfnLen < 0) { return false; } // Remove trailing spaces for (i = strlen (entry->filename) - 1; (i > 0) && (entry->filename[i] == ' '); --i) { entry->filename[i] = '\0'; } // Remove leading spaces for (i = 0; (i < (int)strlen (entry->filename)) && (entry->filename[i] == ' '); ++i) ; if (i > 0) { memmove (entry->filename, entry->filename + i, strlen (entry->filename + i)); } // Remove junk in filename i = strlen (entry->filename); memset (entry->filename + i, '\0', MAX_FILENAME_LENGTH - i); // Make sure the entry doesn't already exist if (_FAT_directory_entryExists (partition, entry->filename, dirCluster)) { return false; } // Clear out alias, so we can generate a new one memset (entry->entryData, ' ', 11); if ( strncmp(entry->filename, ".", MAX_FILENAME_LENGTH) == 0) { // "." entry entry->entryData[0] = '.'; entrySize = 1; } else if ( strncmp(entry->filename, "..", MAX_FILENAME_LENGTH) == 0) { // ".." entry entry->entryData[0] = '.'; entry->entryData[1] = '.'; entrySize = 1; } else { // Normal file name aliasLen = _FAT_directory_createAlias (alias, entry->filename); if (aliasLen < 0) { return false; } else if (aliasLen == 0) { // It's a normal short filename entrySize = 1; } else { // It's a long filename with an alias entrySize = ((lfnLen + LFN_ENTRY_LENGTH - 1) / LFN_ENTRY_LENGTH) + 1; // Generate full alias for all cases except when the alias is simply an upper case version of the LFN // and there isn't already a file with that name if (strncasecmp (alias, entry->filename, MAX_ALIAS_LENGTH) != 0 || _FAT_directory_entryExists (partition, alias, dirCluster)) { // expand primary part to 8 characters long by padding the end with underscores i = MAX_ALIAS_PRI_LENGTH - 1; // Move extension to last 3 characters while (alias[i] != '.' && i > 0) i--; if (i > 0) { j = MAX_ALIAS_LENGTH - MAX_ALIAS_EXT_LENGTH - 2; // 1 char for '.', one for NUL, 3 for extension memmove (alias + j, alias + i, strlen(alias) - i); // Pad primary component memset (alias + i, '_', j - i); alias[MAX_ALIAS_LENGTH-1]=0; } // Generate numeric tail for (i = 1; i <= MAX_NUMERIC_TAIL; i++) { j = i; tmpCharPtr = alias + MAX_ALIAS_PRI_LENGTH - 1; while (j > 0) { *tmpCharPtr = '0' + (j % 10); // ASCII numeric value tmpCharPtr--; j /= 10; } *tmpCharPtr = '~'; if (!_FAT_directory_entryExists (partition, alias, dirCluster)) { break; } } if (i > MAX_NUMERIC_TAIL) { // Couldn't get a valid alias return false; } } } // Copy alias or short file name into directory entry data for (i = 0, j = 0; (j < 8) && (alias[i] != '.') && (alias[i] != '\0'); i++, j++) { entry->entryData[j] = alias[i]; } while (j < 8) { entry->entryData[j] = ' '; ++ j; } if (alias[i] == '.') { // Copy extension ++ i; while ((alias[i] != '\0') && (j < 11)) { entry->entryData[j] = alias[i]; ++ i; ++ j; } } while (j < 11) { entry->entryData[j] = ' '; ++ j; } // Generate alias checksum for (i=0; i < ALIAS_ENTRY_LENGTH; i++) { // NOTE: The operation is an unsigned char rotate right aliasCheckSum = ((aliasCheckSum & 1) ? 0x80 : 0) + (aliasCheckSum >> 1) + entry->entryData[i]; } } // Find or create space for the entry if (_FAT_directory_findEntryGap (partition, entry, dirCluster, entrySize) == false) { return false; } // Write out directory entry curEntryPos = entry->dataStart; { // lfn is only pushed onto the stack here, reducing overall stack usage ucs2_t lfn[MAX_LFN_LENGTH] = {0}; _FAT_directory_mbstoucs2 (lfn, entry->filename, MAX_LFN_LENGTH); for (entryStillValid = true, i = entrySize; entryStillValid && i > 0; entryStillValid = _FAT_directory_incrementDirEntryPosition (partition, &curEntryPos, false), -- i ) { if (i > 1) { // Long filename entry lfnEntry[LFN_offset_ordinal] = (i - 1) | ((size_t)i == entrySize ? LFN_END : 0); for (j = 0; j < 13; j++) { if (lfn [(i - 2) * 13 + j] == '\0') { if ((j > 1) && (lfn [(i - 2) * 13 + (j-1)] == '\0')) { u16_to_u8array (lfnEntry, LFN_offset_table[j], 0xffff); // Padding } else { u16_to_u8array (lfnEntry, LFN_offset_table[j], 0x0000); // Terminating null character } } else { u16_to_u8array (lfnEntry, LFN_offset_table[j], lfn [(i - 2) * 13 + j]); } } lfnEntry[LFN_offset_checkSum] = aliasCheckSum; lfnEntry[LFN_offset_flag] = ATTRIB_LFN; lfnEntry[LFN_offset_reserved1] = 0; u16_to_u8array (lfnEntry, LFN_offset_reserved2, 0); _FAT_cache_writePartialSector (partition->cache, lfnEntry, _FAT_fat_clusterToSector(partition, curEntryPos.cluster) + curEntryPos.sector, curEntryPos.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); } else { // Alias & file data _FAT_cache_writePartialSector (partition->cache, entry->entryData, _FAT_fat_clusterToSector(partition, curEntryPos.cluster) + curEntryPos.sector, curEntryPos.offset * DIR_ENTRY_DATA_SIZE, DIR_ENTRY_DATA_SIZE); } } } return true; } bool _FAT_directory_chdir (PARTITION* partition, const char* path) { DIR_ENTRY entry; if (!_FAT_directory_entryFromPath (partition, &entry, path, NULL)) { return false; } if (!(entry.entryData[DIR_ENTRY_attributes] & ATTRIB_DIR)) { return false; } partition->cwdCluster = _FAT_directory_entryGetCluster (partition, entry.entryData); return true; } void _FAT_directory_entryStat (PARTITION* partition, DIR_ENTRY* entry, struct stat *st) { // Fill in the stat struct // Some of the values are faked for the sake of compatibility st->st_dev = _FAT_disc_hostType(partition->disc); // The device is the 32bit ioType value st->st_ino = (ino_t)(_FAT_directory_entryGetCluster(partition, entry->entryData)); // The file serial number is the start cluster st->st_mode = (_FAT_directory_isDirectory(entry) ? S_IFDIR : S_IFREG) | (S_IRUSR | S_IRGRP | S_IROTH) | (_FAT_directory_isWritable (entry) ? (S_IWUSR | S_IWGRP | S_IWOTH) : 0); // Mode bits based on dirEntry ATTRIB byte st->st_nlink = 1; // Always one hard link on a FAT file st->st_uid = 1; // Faked for FAT st->st_gid = 2; // Faked for FAT st->st_rdev = st->st_dev; st->st_size = u8array_to_u32 (entry->entryData, DIR_ENTRY_fileSize); // File size st->st_atime = _FAT_filetime_to_time_t ( 0, u8array_to_u16 (entry->entryData, DIR_ENTRY_aDate) ); st->st_spare1 = 0; st->st_mtime = _FAT_filetime_to_time_t ( u8array_to_u16 (entry->entryData, DIR_ENTRY_mTime), u8array_to_u16 (entry->entryData, DIR_ENTRY_mDate) ); st->st_spare2 = 0; st->st_ctime = _FAT_filetime_to_time_t ( u8array_to_u16 (entry->entryData, DIR_ENTRY_cTime), u8array_to_u16 (entry->entryData, DIR_ENTRY_cDate) ); st->st_spare3 = 0; st->st_blksize = partition->bytesPerSector; // Prefered file I/O block size st->st_blocks = (st->st_size + partition->bytesPerSector - 1) / partition->bytesPerSector; // File size in blocks st->st_spare4[0] = 0; st->st_spare4[1] = 0; }