mirror of
https://github.com/wiidev/usbloadergx.git
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dbe694cedf
*Rearranged the libs location a bit
319 lines
10 KiB
C
319 lines
10 KiB
C
/*
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partition.c
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Functions for mounting and dismounting partitions
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on various block devices.
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Copyright (c) 2006 Michael "Chishm" Chisholm
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Redistribution and use in source and binary forms, with or without modification,
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are permitted provided that the following conditions are met:
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1. Redistributions of source code must retain the above copyright notice,
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this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright notice,
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this list of conditions and the following disclaimer in the documentation and/or
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other materials provided with the distribution.
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3. The name of the author may not be used to endorse or promote products derived
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from this software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
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WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
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AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE
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LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
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EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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#include "partition.h"
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#include "bit_ops.h"
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#include "file_allocation_table.h"
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#include "directory.h"
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#include "mem_allocate.h"
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#include "fatfile.h"
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#include <string.h>
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#include <ctype.h>
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#include <sys/iosupport.h>
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sec_t _FAT_startSector;
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/*
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This device name, as known by devkitPro toolchains
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*/
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const char* DEVICE_NAME = "fat";
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/*
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Data offsets
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*/
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// BIOS Parameter Block offsets
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enum BPB {
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BPB_jmpBoot = 0x00,
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BPB_OEMName = 0x03,
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// BIOS Parameter Block
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BPB_bytesPerSector = 0x0B,
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BPB_sectorsPerCluster = 0x0D,
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BPB_reservedSectors = 0x0E,
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BPB_numFATs = 0x10,
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BPB_rootEntries = 0x11,
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BPB_numSectorsSmall = 0x13,
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BPB_mediaDesc = 0x15,
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BPB_sectorsPerFAT = 0x16,
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BPB_sectorsPerTrk = 0x18,
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BPB_numHeads = 0x1A,
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BPB_numHiddenSectors = 0x1C,
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BPB_numSectors = 0x20,
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// Ext BIOS Parameter Block for FAT16
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BPB_FAT16_driveNumber = 0x24,
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BPB_FAT16_reserved1 = 0x25,
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BPB_FAT16_extBootSig = 0x26,
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BPB_FAT16_volumeID = 0x27,
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BPB_FAT16_volumeLabel = 0x2B,
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BPB_FAT16_fileSysType = 0x36,
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// Bootcode
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BPB_FAT16_bootCode = 0x3E,
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// FAT32 extended block
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BPB_FAT32_sectorsPerFAT32 = 0x24,
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BPB_FAT32_extFlags = 0x28,
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BPB_FAT32_fsVer = 0x2A,
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BPB_FAT32_rootClus = 0x2C,
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BPB_FAT32_fsInfo = 0x30,
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BPB_FAT32_bkBootSec = 0x32,
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// Ext BIOS Parameter Block for FAT32
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BPB_FAT32_driveNumber = 0x40,
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BPB_FAT32_reserved1 = 0x41,
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BPB_FAT32_extBootSig = 0x42,
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BPB_FAT32_volumeID = 0x43,
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BPB_FAT32_volumeLabel = 0x47,
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BPB_FAT32_fileSysType = 0x52,
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// Bootcode
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BPB_FAT32_bootCode = 0x5A,
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BPB_bootSig_55 = 0x1FE,
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BPB_bootSig_AA = 0x1FF
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};
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static const char FAT_SIG[3] = {'F', 'A', 'T'};
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sec_t FindFirstValidPartition(const DISC_INTERFACE* disc)
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{
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uint8_t part_table[16*4];
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uint8_t *ptr;
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int i;
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uint8_t sectorBuffer[BYTES_PER_READ] = {0};
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// Read first sector of disc
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if (!_FAT_disc_readSectors (disc, 0, 1, sectorBuffer)) {
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return 0;
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}
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memcpy(part_table,sectorBuffer+0x1BE,16*4);
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ptr = part_table;
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for(i=0;i<4;i++,ptr+=16) {
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sec_t part_lba = u8array_to_u32(ptr, 0x8);
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if (!memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG)) ||
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!memcmp(sectorBuffer + BPB_FAT32_fileSysType, FAT_SIG, sizeof(FAT_SIG))) {
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return part_lba;
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}
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if(ptr[4]==0) continue;
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if(ptr[4]==0x0F) {
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sec_t part_lba2=part_lba;
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sec_t next_lba2=0;
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int n;
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for(n=0;n<8;n++) // max 8 logic partitions
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{
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if(!_FAT_disc_readSectors (disc, part_lba+next_lba2, 1, sectorBuffer)) return 0;
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part_lba2 = part_lba + next_lba2 + u8array_to_u32(sectorBuffer, 0x1C6) ;
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next_lba2 = u8array_to_u32(sectorBuffer, 0x1D6);
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if(!_FAT_disc_readSectors (disc, part_lba2, 1, sectorBuffer)) return 0;
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if (!memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG)) ||
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!memcmp(sectorBuffer + BPB_FAT32_fileSysType, FAT_SIG, sizeof(FAT_SIG)))
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{
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return part_lba2;
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}
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if(next_lba2==0) break;
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}
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} else {
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if(!_FAT_disc_readSectors (disc, part_lba, 1, sectorBuffer)) return 0;
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if (!memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG)) ||
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!memcmp(sectorBuffer + BPB_FAT32_fileSysType, FAT_SIG, sizeof(FAT_SIG))) {
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return part_lba;
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}
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}
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}
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return 0;
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}
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PARTITION* _FAT_partition_constructor (const DISC_INTERFACE* disc, uint32_t cacheSize, uint32_t sectorsPerPage, sec_t startSector) {
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PARTITION* partition;
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uint8_t sectorBuffer[BYTES_PER_READ] = {0};
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// Read first sector of disc
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if (!_FAT_disc_readSectors (disc, startSector, 1, sectorBuffer)) {
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return NULL;
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}
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// Make sure it is a valid MBR or boot sector
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if ( (sectorBuffer[BPB_bootSig_55] != 0x55) || (sectorBuffer[BPB_bootSig_AA] != 0xAA)) {
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return NULL;
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}
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if (startSector != 0) {
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// We're told where to start the partition, so just accept it
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} else if (!memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG))) {
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// Check if there is a FAT string, which indicates this is a boot sector
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startSector = 0;
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} else if (!memcmp(sectorBuffer + BPB_FAT32_fileSysType, FAT_SIG, sizeof(FAT_SIG))) {
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// Check for FAT32
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startSector = 0;
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} else {
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startSector = FindFirstValidPartition(disc);
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if (!_FAT_disc_readSectors (disc, startSector, 1, sectorBuffer)) {
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return NULL;
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}
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}
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// Now verify that this is indeed a FAT partition
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if (memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG)) &&
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memcmp(sectorBuffer + BPB_FAT32_fileSysType, FAT_SIG, sizeof(FAT_SIG)))
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{
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return NULL;
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}
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// check again for the last two cases to make sure that we really have a FAT filesystem here
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// and won't corrupt any data
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if(memcmp(sectorBuffer + BPB_FAT16_fileSysType, "FAT", 3) != 0 && memcmp(sectorBuffer + BPB_FAT32_fileSysType, "FAT32", 5) != 0)
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{
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return NULL;
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}
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partition = (PARTITION*) _FAT_mem_allocate (sizeof(PARTITION));
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if (partition == NULL) {
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return NULL;
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}
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// Init the partition lock
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_FAT_lock_init(&partition->lock);
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_FAT_startSector = startSector;
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if (!memcmp(sectorBuffer + BPB_FAT16_fileSysType, FAT_SIG, sizeof(FAT_SIG)))
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strncpy(partition->label, (char*)(sectorBuffer + BPB_FAT16_volumeLabel), 11);
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else
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strncpy(partition->label, (char*)(sectorBuffer + BPB_FAT32_volumeLabel), 11);
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partition->label[11] = '\0';
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// Set partition's disc interface
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partition->disc = disc;
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// Store required information about the file system
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partition->fat.sectorsPerFat = u8array_to_u16(sectorBuffer, BPB_sectorsPerFAT);
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if (partition->fat.sectorsPerFat == 0) {
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partition->fat.sectorsPerFat = u8array_to_u32( sectorBuffer, BPB_FAT32_sectorsPerFAT32);
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}
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partition->numberOfSectors = u8array_to_u16( sectorBuffer, BPB_numSectorsSmall);
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if (partition->numberOfSectors == 0) {
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partition->numberOfSectors = u8array_to_u32( sectorBuffer, BPB_numSectors);
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}
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partition->bytesPerSector = BYTES_PER_READ; // Sector size is redefined to be 512 bytes
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partition->sectorsPerCluster = sectorBuffer[BPB_sectorsPerCluster] * u8array_to_u16(sectorBuffer, BPB_bytesPerSector) / BYTES_PER_READ;
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partition->bytesPerCluster = partition->bytesPerSector * partition->sectorsPerCluster;
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partition->fat.fatStart = startSector + u8array_to_u16(sectorBuffer, BPB_reservedSectors);
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partition->rootDirStart = partition->fat.fatStart + (sectorBuffer[BPB_numFATs] * partition->fat.sectorsPerFat);
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partition->dataStart = partition->rootDirStart +
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(( u8array_to_u16(sectorBuffer, BPB_rootEntries) * DIR_ENTRY_DATA_SIZE) / partition->bytesPerSector);
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partition->totalSize = ((uint64_t)partition->numberOfSectors - (partition->dataStart - startSector)) * (uint64_t)partition->bytesPerSector;
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// Store info about FAT
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uint32_t clusterCount = (partition->numberOfSectors - (uint32_t)(partition->dataStart - startSector)) / partition->sectorsPerCluster;
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partition->fat.lastCluster = clusterCount + CLUSTER_FIRST - 1;
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partition->fat.firstFree = CLUSTER_FIRST;
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if (clusterCount < CLUSTERS_PER_FAT12) {
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partition->filesysType = FS_FAT12; // FAT12 volume
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} else if (clusterCount < CLUSTERS_PER_FAT16) {
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partition->filesysType = FS_FAT16; // FAT16 volume
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} else {
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partition->filesysType = FS_FAT32; // FAT32 volume
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}
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if (partition->filesysType != FS_FAT32) {
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partition->rootDirCluster = FAT16_ROOT_DIR_CLUSTER;
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} else {
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// Set up for the FAT32 way
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partition->rootDirCluster = u8array_to_u32(sectorBuffer, BPB_FAT32_rootClus);
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// Check if FAT mirroring is enabled
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if (!(sectorBuffer[BPB_FAT32_extFlags] & 0x80)) {
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// Use the active FAT
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partition->fat.fatStart = partition->fat.fatStart + ( partition->fat.sectorsPerFat * (sectorBuffer[BPB_FAT32_extFlags] & 0x0F));
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}
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}
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// Create a cache to use
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partition->cache = _FAT_cache_constructor (cacheSize, sectorsPerPage, partition->disc, startSector+partition->numberOfSectors);
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// Set current directory to the root
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partition->cwdCluster = partition->rootDirCluster;
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// Check if this disc is writable, and set the readOnly property appropriately
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partition->readOnly = !(_FAT_disc_features(disc) & FEATURE_MEDIUM_CANWRITE);
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// There are currently no open files on this partition
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partition->openFileCount = 0;
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partition->firstOpenFile = NULL;
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return partition;
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}
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void _FAT_partition_destructor (PARTITION* partition) {
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FILE_STRUCT* nextFile;
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_FAT_lock(&partition->lock);
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// Synchronize open files
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nextFile = partition->firstOpenFile;
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while (nextFile) {
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_FAT_syncToDisc (nextFile);
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nextFile = nextFile->nextOpenFile;
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}
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// Free memory used by the cache, writing it to disc at the same time
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_FAT_cache_destructor (partition->cache);
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// Unlock the partition and destroy the lock
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_FAT_unlock(&partition->lock);
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_FAT_lock_deinit(&partition->lock);
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// Free memory used by the partition
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_FAT_mem_free (partition);
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}
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PARTITION* _FAT_partition_getPartitionFromPath (const char* path) {
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const devoptab_t *devops;
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devops = GetDeviceOpTab (path);
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if (!devops) {
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return NULL;
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}
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return (PARTITION*)devops->deviceData;
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}
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