/**************************************************************************** * Copyright (C) 2010 by Dimok * (C) 2012 by FIX94 * * This software is provided 'as-is', without any express or implied * warranty. In no event will the authors be held liable for any * damages arising from the use of this software. * * Permission is granted to anyone to use this software for any * purpose, including commercial applications, and to alter it and * redistribute it freely, subject to the following restrictions: * * 1. The origin of this software must not be misrepresented; you * must not claim that you wrote the original software. If you use * this software in a product, an acknowledgment in the product * documentation would be appreciated but is not required. * * 2. Altered source versions must be plainly marked as such, and * must not be misrepresented as being the original software. * * 3. This notice may not be removed or altered from any source * distribution. ***************************************************************************/ #include #include #include #include #include "PartitionHandle.h" #include "ntfs.h" #include "fat.h" #include "ext2.h" #include "sdhc.h" #include "usbstorage.h" #include "gui/text.hpp" #include "loader/nk.h" #include "loader/utils.h" #include "loader/wbfs.h" #include "memory/mem2.hpp" #define PARTITION_TYPE_DOS33_EXTENDED 0x05 /* DOS 3.3+ extended partition */ #define PARTITION_TYPE_WIN95_EXTENDED 0x0F /* Windows 95 extended partition */ //! libfat stuff extern "C" { sec_t FindFirstValidPartition(const DISC_INTERFACE* disc); } #define CACHE 32 #define SECTORS 64 static inline const char *PartFromType(int type) { switch (type) { case 0x00: return "Unused"; case 0x01: return "FAT12"; case 0x04: return "FAT16"; case 0x05: return "Extended"; case 0x06: return "FAT16"; case 0x07: return "NTFS"; case 0x0b: return "FAT32"; case 0x0c: return "FAT32"; case 0x0e: return "FAT16"; case 0x0f: return "Extended"; case 0x82: return "LxSWP"; case 0x83: return "LINUX"; case 0x8e: return "LxLVM"; case 0xa8: return "OSX"; case 0xab: return "OSXBT"; case 0xaf: return "OSXHF"; case 0xbf: return "WBFS"; case 0xe8: return "LUKS"; default: return "Unknown"; } } void PartitionHandle::Init() { interface = NULL; } void PartitionHandle::SetDevice(const DISC_INTERFACE *discio) { Cleanup(); interface = discio; // Sanity check if(!interface) return; // Start the device and check that it is inserted if(!interface->startup()) return; if(!interface->isInserted()) return; FindPartitions(); } void PartitionHandle::Cleanup() { UnMountAll(); if(interface != NULL) interface->shutdown(); interface = NULL; PartitionList.clear(); MountNameList.clear(); } bool PartitionHandle::IsMounted(int pos) { if(pos < 0 || pos >= (int) MountNameList.size()) return false; if(MountNameList[pos].size() == 0) return false; return true; } bool PartitionHandle::Mount(int pos, const char *name, bool forceFAT) { if(valid(pos)) UnMount(pos); if(!name) return false; if(pos >= (int)MountNameList.size()) MountNameList.resize(pos + 1); MountNameList[pos] = name; char DeviceSyn[10]; memcpy(DeviceSyn, name, 8); strcat(DeviceSyn, ":"); DeviceSyn[9] = '\0'; //! Some stupid partition manager think they don't need to edit the freaken MBR. //! So we need to check the first 64 sectors and see if some partition is there. //! libfat does that by default so let's use it. if(forceFAT && (strlen(GetFSName(pos)) == 0 || strcmp(GetFSName(pos), "Unknown") == 0)) { if(fatMount(MountNameList[pos].c_str(), interface, 0, CACHE, SECTORS)) { sec_t FAT_startSector = FindFirstValidPartition(interface); AddPartition("FAT", FAT_startSector, 0xdeadbeaf, true, 0x0c, 0); gprintf("FAT Partition at %s (forceFAT) mounted.\n", DeviceSyn); SetWbfsHandle(pos, NULL); return true; } } if(!valid(pos)) return false; SetWbfsHandle(pos, NULL); if(strncmp(GetFSName(pos), "FAT", 3) == 0 || strcmp(GetFSName(pos), "GUID-Entry") == 0) { if(fatMount(MountNameList[pos].c_str(), interface, GetLBAStart(pos), CACHE, SECTORS)) { gprintf("FAT Partition at %s mounted.\n", DeviceSyn); PartitionList[pos].FSName = "FAT"; return true; } } else if(strncmp(GetFSName(pos), "NTFS", 4) == 0 || strcmp(GetFSName(pos), "GUID-Entry") == 0) { if(ntfsMount(MountNameList[pos].c_str(), interface, GetLBAStart(pos), CACHE, SECTORS, NTFS_SHOW_HIDDEN_FILES | NTFS_RECOVER)) { gprintf("NTFS Partition at %s mounted.\n", DeviceSyn); PartitionList[pos].FSName = "NTFS"; return true; } } else if(strncmp(GetFSName(pos), "LINUX", 5) == 0 || strcmp(GetFSName(pos), "GUID-Entry") == 0) { if(ext2Mount(MountNameList[pos].c_str(), interface, GetLBAStart(pos), CACHE, SECTORS, EXT2_FLAG_DEFAULT)) { gprintf("EXT Partition at %s mounted.\n", DeviceSyn); PartitionList[pos].FSName = "LINUX"; return true; } } else if(strncmp(GetFSName(pos), "WBFS", 4) == 0) { if(interface == &__io_usbstorage2_port0 || interface == &__io_usbstorage2_port1) SetWbfsHandle(pos, wbfs_open_partition(__WBFS_ReadUSB, __WBFS_WriteUSB, NULL, USBStorage2_GetSectorSize(), GetSecCount(pos), GetLBAStart(pos), 0)); else if(interface == &__io_sdhc) SetWbfsHandle(pos, wbfs_open_partition(__WBFS_ReadSDHC, __WBFS_WriteSDHC, NULL, 512, GetSecCount(pos), GetLBAStart(pos), 0)); if(GetWbfsHandle(pos)) { gprintf("WBFS Partition at %s mounted.\n", DeviceSyn); PartitionList[pos].FSName = "WBFS"; return true; } } /* FAIL */ MountNameList[pos].clear(); return false; } void PartitionHandle::UnMount(int pos) { if(!interface || (pos >= (int)MountNameList.size()) || (MountNameList[pos].size() == 0)) return; WBFS_Close(); char DeviceSyn[10]; memcpy(DeviceSyn, MountName(pos), 8); strcat(DeviceSyn, ":"); DeviceSyn[9] = '\0'; if(strncmp(GetFSName(pos), "WBFS", 4) == 0) { wbfs_t *wbfshandle = GetWbfsHandle(pos); if(wbfshandle) wbfs_close(wbfshandle); gprintf("WBFS Partition at %s unmounted.\n", DeviceSyn); } else if(strncmp(GetFSName(pos), "FAT", 3) == 0) { fatUnmount(DeviceSyn); gprintf("FAT Partition at %s unmounted.\n", DeviceSyn); } else if(strncmp(GetFSName(pos), "NTFS", 4) == 0) { ntfsUnmount(DeviceSyn, true); gprintf("NTFS Partition at %s unmounted.\n", DeviceSyn); } else if(strncmp(GetFSName(pos), "LINUX", 5) == 0) { ext2Unmount(DeviceSyn); gprintf("EXT Partition at %s unmounted.\n", DeviceSyn); } /* Remove name from list */ MountNameList[pos].clear(); SetWbfsHandle(pos, NULL); } bool PartitionHandle::IsExisting(u64 lba) { for(u32 i = 0; i < PartitionList.size(); ++i) { if(PartitionList[i].LBA_Start == lba) return true; } return false; } s8 PartitionHandle::FindPartitions() { MASTER_BOOT_RECORD *mbr = (MASTER_BOOT_RECORD*)MEM2_alloc(MAX_BYTES_PER_SECTOR); if(mbr == NULL) return -1; // Read the first sector on the device if(!interface->readSectors(0, 1, mbr)) { MEM2_free(mbr); return -1; } // If this is the devices master boot record if(mbr->signature != MBR_SIGNATURE && mbr->signature != MBR_SIGNATURE_MOD) { MEM2_free(mbr); return -1; } for(u8 i = 0; i < 4; i++) { PARTITION_RECORD *partition = (PARTITION_RECORD *)&mbr->partitions[i]; if(partition->type == PARTITION_TYPE_GPT) { s8 ret = CheckGPT(i); if(ret == 0) // if it's a GPT we don't need to go on looking through the mbr anymore return ret; } if(partition->type == PARTITION_TYPE_DOS33_EXTENDED || partition->type == PARTITION_TYPE_WIN95_EXTENDED) { CheckEBR(i, le32(partition->lba_start)); continue; } if(le32(partition->block_count) > 0 && !IsExisting(le32(partition->lba_start))) { AddPartition(PartFromType(partition->type), le32(partition->lba_start), le32(partition->block_count), (partition->status == PARTITION_BOOTABLE), partition->type, i); } } MEM2_free(mbr); return 0; } void PartitionHandle::CheckEBR(u8 PartNum, sec_t ebr_lba) { EXTENDED_BOOT_RECORD *ebr = (EXTENDED_BOOT_RECORD*)MEM2_alloc(MAX_BYTES_PER_SECTOR); if(ebr == NULL) return; sec_t next_erb_lba = 0; do { // Read and validate the extended boot record if(!interface->readSectors(ebr_lba + next_erb_lba, 1, ebr)) { MEM2_free(ebr); return; } if(ebr->signature != EBR_SIGNATURE && ebr->signature != EBR_SIGNATURE_MOD) { MEM2_free(ebr); return; } if(le32(ebr->partition.block_count) > 0 && !IsExisting(ebr_lba + next_erb_lba + le32(ebr->partition.lba_start))) { AddPartition(PartFromType(ebr->partition.type), ebr_lba + next_erb_lba + le32(ebr->partition.lba_start), le32(ebr->partition.block_count), (ebr->partition.status == PARTITION_BOOTABLE), ebr->partition.type, PartNum); } // Get the start sector of the current partition // and the next extended boot record in the chain next_erb_lba = le32(ebr->next_ebr.lba_start); } while(next_erb_lba > 0); MEM2_free(ebr); } static const u8 TYPE_UNUSED[16] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; static const u8 TYPE_BIOS[16] = { 0x48,0x61,0x68,0x21,0x49,0x64,0x6F,0x6E,0x74,0x4E,0x65,0x65,0x64,0x45,0x46,0x49 }; static const u8 TYPE_LINUX_MS_BASIC_DATA[16] = { 0xA2,0xA0,0xD0,0xEB,0xE5,0xB9,0x33,0x44,0x87,0xC0,0x68,0xB6,0xB7,0x26,0x99,0xC7 }; s8 PartitionHandle::CheckGPT(u8 PartNum) { GPT_HEADER *gpt_header = (GPT_HEADER*)MEM2_alloc(MAX_BYTES_PER_SECTOR); if(gpt_header == NULL) return -1; // Read and validate the extended boot record if(!interface->readSectors(1, 1, gpt_header)) { MEM2_free(gpt_header); return -1; } if(strncmp(gpt_header->magic, "EFI PART", 8) != 0) { MEM2_free(gpt_header); return -1; } gpt_header->part_table_lba = le64(gpt_header->part_table_lba); gpt_header->part_entries = le32(gpt_header->part_entries); gpt_header->part_entry_size = le32(gpt_header->part_entry_size); gpt_header->part_entry_checksum = le32(gpt_header->part_entry_checksum); u8 *sector_buf = (u8*)MEM2_alloc(MAX_BYTES_PER_SECTOR); if(sector_buf == NULL) { MEM2_free(gpt_header); return -1; } u64 next_lba = gpt_header->part_table_lba; for(u32 i = 0; i < gpt_header->part_entries; ++i) { if(!interface->readSectors(next_lba, 1, sector_buf)) break; for(u32 n = 0; n < BYTES_PER_SECTOR/gpt_header->part_entry_size; ++n, ++i) { GUID_PART_ENTRY *part_entry = (GUID_PART_ENTRY*)(sector_buf+gpt_header->part_entry_size*n); if(memcmp(part_entry->part_type_guid, TYPE_UNUSED, 16) == 0) continue; if(IsExisting(le64(part_entry->part_first_lba))) continue; bool bootable = (memcmp(part_entry->part_type_guid, TYPE_BIOS, 16) == 0); AddPartition("GUID-Entry", le64(part_entry->part_first_lba), le64(part_entry->part_last_lba), bootable, PARTITION_TYPE_GPT, PartNum); } next_lba++; } MEM2_free(sector_buf); MEM2_free(gpt_header); return 0; } void PartitionHandle::AddPartition(const char *name, u64 lba_start, u64 sec_count, bool bootable, u8 part_type, u8 part_num) { u8 *buffer = (u8*)MEM2_alloc(MAX_BYTES_PER_SECTOR); if(buffer == NULL) return; if(!interface->readSectors(lba_start, 1, buffer)) { MEM2_free(buffer); return; } wbfs_head_t *head = (wbfs_head_t*)buffer; if(head->magic == wbfs_htonl(WBFS_MAGIC)) { name = "WBFS"; part_type = 0xBF; //Override partition type on WBFS //! correct sector size in physical sectors (512 bytes per sector) sec_count = (u64) head->n_hd_sec * (u64) (1 << head->hd_sec_sz_s) / (u64) BYTES_PER_SECTOR; } else if(*((u16 *)(buffer + 0x1FE)) == 0x55AA) { //! Partition type can be missleading the correct partition format. Stupid lazy ass Partition Editors. if((memcmp(buffer + 0x36, "FAT", 3) == 0 || memcmp(buffer + 0x52, "FAT", 3) == 0) && strncmp(PartFromType(part_type), "FAT", 3) != 0) { name = "FAT32"; part_type = 0x0c; } if(memcmp(buffer + 0x03, "NTFS", 4) == 0) { name = "NTFS"; part_type = 0x07; } } PartitionFS PartitionEntry; PartitionEntry.FSName = name; PartitionEntry.LBA_Start = lba_start; PartitionEntry.SecCount = sec_count; PartitionEntry.Bootable = bootable; PartitionEntry.PartitionType = part_type; PartitionEntry.PartitionNum = part_num; PartitionList.push_back(PartitionEntry); MEM2_free(buffer); } wbfs_t *PartitionHandle::GetWbfsHandle(int pos) { if(valid(pos)) return PartitionList[pos].wbfshandle; return NULL; } bool PartitionHandle::SetWbfsHandle(int pos, wbfs_t *wbfshandle) { if(valid(pos)) { PartitionList[pos].wbfshandle = wbfshandle; return true; } return false; }