#include "fsinit.h" #include "fsperm.h" #include "ifat_common.h" #include "bdri.h" #include "image.h" #include "language.h" #include "nandcmac.h" #include "ui.h" #include "vff.h" #define FAT_ENTRY_SIZE sizeof(IFatEntry) #define REPLACE_SIZE_MISMATCH 2 #define getfatflag(uv) (((uv) & 0x80000000UL) != 0) #define getfatindex(uv) ((uv) & 0x7FFFFFFFUL) #define buildfatuv(index, flag) ((index) | ((flag) ? 0x80000000UL : 0)) typedef struct { IFatPreHeader pre_header; IFatFsInfo fs_info; } PACKED_STRUCT BDRIFsHeader; typedef struct { char magic[8]; // varies based on media type and importdb vs titledb u32 version; // should always be 0 u8 reserved[0x74]; } PACKED_STRUCT TitleDBPreHeader; typedef struct { TitleDBPreHeader pre_header; BDRIFsHeader fs_header; } PACKED_STRUCT TitleDBHeader; typedef struct { char magic[4]; // "TICK" u32 version; // always 1 u8 padding[8]; } PACKED_STRUCT TickDBPreHeader; typedef struct { TickDBPreHeader pre_header; BDRIFsHeader fs_header; } PACKED_STRUCT TickDBHeader; typedef struct { u32 parent_index; u8 title_id[8]; u32 next_sibling_index; u8 padding1[4]; u32 start_block_index; u64 size; // in bytes u8 padding2[8]; u32 hash_bucket_next_index; } __attribute__((packed)) BDRIFileEntry; typedef struct { u32 total_entry_count; u32 max_entry_count; // == max_file_count + 1 u8 padding[32]; u32 next_dummy_index; } __attribute__((packed)) BDRIDummyFileEntry; typedef struct { u64 id; u32 next_sibling_index; u32 first_subdir_index; u32 first_subfile_index; u8 pad0[4]; u32 hash_bucket_next_index; } __attribute__((packed)) BDRIDirectoryEntry; typedef struct { u32 total_entry_count; u32 max_entry_count; u8 padding[16]; u32 next_dummy_index; } __attribute__((packed)) BDRIDummyDirectoryEntry; typedef struct { u32 ticket_count; // usually == 1 u32 ticket_size; // usually == 0x350 == sizeof(Ticket) Ticket ticket; } __attribute__((packed, aligned(4))) TicketEntry; static FIL* bdrifp; static FRESULT BDRIRead(UINT ofs, UINT btr, void* buf) { if (bdrifp) { FRESULT res; UINT br; if ((fvx_tell(bdrifp) != ofs) && (fvx_lseek(bdrifp, ofs) != FR_OK)) return FR_DENIED; res = fvx_read(bdrifp, buf, btr, &br); if ((res == FR_OK) && (br != btr)) res = FR_DENIED; return res; } else return FR_DENIED; } static FRESULT BDRIWrite(UINT ofs, UINT btw, const void* buf) { if (bdrifp) { FRESULT res; UINT bw; if ((fvx_tell(bdrifp) != ofs) && (fvx_lseek(bdrifp, ofs) != FR_OK)) return FR_DENIED; res = fvx_write(bdrifp, buf, btw, &bw); if ((res == FR_OK) && (bw != btw)) res = FR_DENIED; return res; } else return FR_DENIED; } bool CheckDBMagic(const u8* pre_header, bool tickdb) { const TitleDBHeader* title = (TitleDBHeader*) (void *) pre_header; const TickDBHeader* tick = (TickDBHeader*) (void *) pre_header; return (tickdb ? ((strncmp(tick->pre_header.magic, "TICK", 4) == 0) && (tick->pre_header.version == 1)) : ((strcmp(title->pre_header.magic, "NANDIDB") == 0) || (strcmp(title->pre_header.magic, "NANDTDB") == 0) || (strcmp(title->pre_header.magic, "TEMPIDB") == 0) || (strcmp(title->pre_header.magic, "TEMPTDB") == 0))) && (strcmp((tickdb ? tick->fs_header : title->fs_header).pre_header.magic_str, "BDRI") == 0) && ((tickdb ? tick->fs_header : title->fs_header).pre_header.version == 0x30000); } // This function was taken, with slight modification, from https://3dbrew.org/wiki/Inner_FAT static u32 GetHashBucket(const u8* tid, u32 parent_dir_index, u32 bucket_count) { u32 hash = parent_dir_index ^ 0x091A2B3C; for (u8 i = 0; i < 2; ++i) { hash = (hash >> 1) | (hash << 31); hash ^= (u32)tid[i * 4]; hash ^= (u32)tid[i * 4 + 1] << 8; hash ^= (u32)tid[i * 4 + 2] << 16; hash ^= (u32)tid[i * 4 + 3] << 24; } return hash % bucket_count; } static u32 GetBDRIEntrySize(const BDRIFsHeader* fs_header, const u32 fs_header_offset, const u8* title_id, u32* size) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) // Could be more thorough return 1; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fht_offset = fs_header_offset + fs_header->fs_info.file_hashtbl.outfat_offset; u32 index = 0; BDRIFileEntry file_entry; u64 tid_be = getbe64(title_id); u8* title_id_be = (u8*) &tid_be; const u32 hash_bucket = GetHashBucket(title_id_be, 1, fs_header->fs_info.file_hashtbl.outfat_count); if (BDRIRead(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &(file_entry.hash_bucket_next_index)) != FR_OK) return 1; // Find the file entry for the tid specified, fail if it doesn't exist do { if (file_entry.hash_bucket_next_index == 0) return 1; index = file_entry.hash_bucket_next_index; if (BDRIRead(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; } while (memcmp(title_id_be, file_entry.title_id, 8) != 0); *size = file_entry.size; return 0; } static u32 ReadBDRIEntry(const BDRIFsHeader* fs_header, const u32 fs_header_offset, const u8* title_id, u8* entry, const u32 expected_size) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) // Could be more thorough return 1; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fht_offset = fs_header_offset + fs_header->fs_info.file_hashtbl.outfat_offset; const u32 fat_offset = fs_header_offset + fs_header->fs_info.fat.outfat_offset; u32 index = 0; BDRIFileEntry file_entry; u64 tid_be = getbe64(title_id); u8* title_id_be = (u8*) &tid_be; const u32 hash_bucket = GetHashBucket(title_id_be, 1, fs_header->fs_info.file_hashtbl.outfat_count); if (BDRIRead(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &(file_entry.hash_bucket_next_index)) != FR_OK) return 1; // Find the file entry for the tid specified, fail if it doesn't exist do { if (file_entry.hash_bucket_next_index == 0) return 1; index = file_entry.hash_bucket_next_index; if (BDRIRead(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; } while (memcmp(title_id_be, file_entry.title_id, 8) != 0); if (expected_size && (file_entry.size != expected_size)) return 1; index = file_entry.start_block_index + 1; // FAT entry index u32 bytes_read = 0; u32 fat_entry[2]; while (bytes_read < file_entry.size) { // Read the full entry, walking the FAT node chain u32 read_start = index - 1; // Data region block index u32 read_count = 0; if (BDRIRead(fat_offset + index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if ((bytes_read == 0) && !getfatflag(fat_entry[0])) return 1; u32 next_index = getfatindex(fat_entry[1]); if (getfatflag(fat_entry[1])) { // Multi-entry node if (BDRIRead(fat_offset + (index + 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (!getfatflag(fat_entry[0]) || getfatflag(fat_entry[1]) || (getfatindex(fat_entry[0]) != index) || (getfatindex(fat_entry[0]) >= getfatindex(fat_entry[1]))) return 1; read_count = getfatindex(fat_entry[1]) + 1 - index; } else { // Single-entry node read_count = 1; } index = next_index; u32 btr = min(file_entry.size - bytes_read, read_count * fs_header->fs_info.data_region_blocksize); if (entry && (BDRIRead(data_offset + read_start * fs_header->fs_info.data_region_blocksize, btr, entry + bytes_read) != FR_OK)) return 1; bytes_read += btr; } return 0; } static u32 RemoveBDRIEntry(const BDRIFsHeader* fs_header, const u32 fs_header_offset, const u8* title_id) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) // Could be more thorough return 1; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 det_offset = data_offset + fs_header->fs_info.dirtable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fht_offset = fs_header_offset + fs_header->fs_info.file_hashtbl.outfat_offset; const u32 fat_offset = fs_header_offset + fs_header->fs_info.fat.outfat_offset; u32 index = 0, previous_index = 0; BDRIFileEntry file_entry; u64 tid_be = getbe64(title_id); u8* title_id_be = (u8*) &tid_be; // Read the index of the first file entry from the directory entry table if (BDRIRead(det_offset + 0x2C, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK) return 1; // Find the file entry for the tid specified, fail if it doesn't exist do { previous_index = index; index = file_entry.next_sibling_index; if (index == 0) return 1; if (BDRIRead(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; } while (memcmp(title_id_be, file_entry.title_id, 8) != 0); BDRIDummyFileEntry dummy_entry; // Read the 0th entry in the FET, which is always a dummy entry if (BDRIRead(fet_offset, sizeof(BDRIDummyFileEntry), &dummy_entry) != FR_OK) return 1; if (dummy_entry.max_entry_count != fs_header->fs_info.filetable_info.max_entry_count + 1) return 1; if ((BDRIWrite(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &dummy_entry) != FR_OK) || (BDRIWrite(fet_offset + 0x28, sizeof(u32), &index) != FR_OK) || (BDRIWrite((previous_index == 0) ? det_offset + 0x2C : fet_offset + previous_index * sizeof(BDRIFileEntry) + 0xC, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK)) return 1; const u32 hash_bucket = GetHashBucket(file_entry.title_id, file_entry.parent_index, fs_header->fs_info.file_hashtbl.outfat_count); u32 index_hash = 0; if (BDRIRead(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &index_hash) != FR_OK) return 1; if (index_hash == index) { if (BDRIWrite(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &(file_entry.hash_bucket_next_index)) != FR_OK) return 1; } else { u32 prev_hash_index = 0; do { if (index_hash == 0) // This shouldn't happen if the entry was properly added break; prev_hash_index = index_hash; if (BDRIRead(fet_offset + index_hash * sizeof(BDRIFileEntry) + 0x28, sizeof(u32), &index_hash) != FR_OK) return 1; } while (index_hash != index); if ((prev_hash_index != 0) && BDRIWrite(fet_offset + prev_hash_index * sizeof(BDRIFileEntry) + 0x28, sizeof(u32), &(file_entry.hash_bucket_next_index)) != FR_OK) return 1; } u32 fat_entry[2]; if (BDRIRead(fat_offset, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (getfatflag(fat_entry[1]) || (fat_entry[0] != 0)) return 1; u32 next_free_index = getfatindex(fat_entry[1]), fat_index = file_entry.start_block_index + 1; if (BDRIWrite(fat_offset + sizeof(u32), sizeof(u32), &fat_index) != FR_OK) return 1; fat_entry[1] = fat_index; do { fat_index = getfatindex(fat_entry[1]); if (BDRIRead(fat_offset + FAT_ENTRY_SIZE * fat_index, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; } while (getfatindex(fat_entry[1]) != 0); // Bug fix: use buildfatuv to explicitly clear Bit 31 (the multi-block flag). // If the tail of the freed chain is a multi-block node start, Bit 31 is already // set in fat_entry[1]. A plain |= would keep it set, corrupting the free list. fat_entry[1] = buildfatuv(next_free_index, false); if (BDRIWrite(fat_offset + fat_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; // Bug fix: guard against next_free_index == 0 (freed entry was the last free // block). Without this guard, FAT[0] (the free-list sentinel) gets corrupted // by a stray back-pointer write. if (next_free_index != 0) { if (BDRIRead(fat_offset + next_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; fat_entry[0] = buildfatuv(fat_index, false); if (BDRIWrite(fat_offset + next_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; } return 0; } static u32 AllocateBDRIBlocks(const BDRIFsHeader* fs_header, const u32 fs_header_offset, const u32 size_blocks, u32 *out_fat_index) { u32 fat_entry[2]; u32 fat_index = 0; const u32 fat_offset = fs_header_offset + fs_header->fs_info.fat.outfat_offset; if (BDRIRead(fat_offset, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (getfatflag(fat_entry[1]) || (fat_entry[0] != 0)) return 1; u32 next_fat_index = getfatindex(fat_entry[1]), node_size = 0; // Find contiguous free space in the FAT for the entry. Technically there could be a case of enough space existing, but not in a contiguous fasion, but this would never realistically happen do { if (next_fat_index == 0) return 1; // Reached the end of the free node chain without finding enough contiguous free space - this should never realistically happen fat_index = next_fat_index; if (BDRIRead(fat_offset + fat_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; next_fat_index = getfatindex(fat_entry[1]); if (getfatflag(fat_entry[1])) { // Multi-entry node if (BDRIRead(fat_offset + (fat_index + 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (!getfatflag(fat_entry[0]) || getfatflag(fat_entry[1]) || (getfatindex(fat_entry[0]) != fat_index) || (getfatindex(fat_entry[0]) >= getfatindex(fat_entry[1]))) return 1; node_size = getfatindex(fat_entry[1]) + 1 - fat_index; } else { // Single-entry node node_size = 1; } } while (node_size < size_blocks); const bool shrink_free_node = node_size > size_blocks; if (shrink_free_node) { if (BDRIRead(fat_offset + fat_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (node_size - size_blocks == 1) fat_entry[1] = buildfatuv(getfatindex(fat_entry[1]), false); if (BDRIWrite(fat_offset + (fat_index + size_blocks) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (node_size - size_blocks > 1) { if (BDRIRead(fat_offset + (fat_index + node_size - 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; fat_entry[0] = buildfatuv(fat_index + size_blocks, true); if ((BDRIWrite(fat_offset + (fat_index + node_size - 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) || (BDRIWrite(fat_offset + (fat_index + size_blocks + 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK)) return 1; } } if (BDRIRead(fat_offset + fat_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; const u32 previous_free_index = getfatindex(fat_entry[0]), next_free_index = getfatindex(fat_entry[1]); fat_entry[0] = buildfatuv(0, true); fat_entry[1] = buildfatuv(0, size_blocks > 1); if (BDRIWrite(fat_offset + fat_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (size_blocks > 1) { fat_entry[0] = buildfatuv(fat_index, true); fat_entry[1] = buildfatuv(fat_index + size_blocks - 1, false); if ((BDRIWrite(fat_offset + (fat_index + size_blocks - 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) || (BDRIWrite(fat_offset + (fat_index + 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK)) return 1; } if (next_free_index != 0) { if (BDRIRead(fat_offset + next_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; fat_entry[0] = buildfatuv(shrink_free_node ? fat_index + size_blocks : previous_free_index, (!shrink_free_node && (previous_free_index == 0))); if (BDRIWrite(fat_offset + next_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; } if (BDRIRead(fat_offset + previous_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; fat_entry[1] = buildfatuv(shrink_free_node ? fat_index + size_blocks : next_free_index, getfatflag(fat_entry[1])); if (BDRIWrite(fat_offset + previous_free_index * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; *out_fat_index = fat_index; return 0; } static u32 AddBDRIEntry(const BDRIFsHeader* fs_header, const u32 fs_header_offset, const u8* title_id, const u8* entry, const u32 size, bool replace) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) // Could be more thorough return 1; if (!entry || !size) return 1; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 det_offset = data_offset + fs_header->fs_info.dirtable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fht_offset = fs_header_offset + fs_header->fs_info.file_hashtbl.outfat_offset; const u32 fat_offset = fs_header_offset + fs_header->fs_info.fat.outfat_offset; const u32 size_blocks = (size / fs_header->fs_info.data_region_blocksize) + (((size % fs_header->fs_info.data_region_blocksize) == 0) ? 0 : 1); u32 index = 0, max_index = 0; BDRIFileEntry file_entry; u64 tid_be = getbe64(title_id); u8* title_id_be = (u8*) &tid_be; bool do_replace = false; // Read the index of the first file entry from the directory entry table if (BDRIRead(det_offset + 0x2C, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK) return 1; // Try to find the file entry for the tid specified while (file_entry.next_sibling_index != 0) { index = file_entry.next_sibling_index; max_index = max(index, max_index); if (BDRIRead(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; // If an entry for the tid already existed that is already the specified size and replace was specified, just replace the existing entry if (memcmp(title_id_be, file_entry.title_id, 8) == 0) { if (!replace) return 1; else if (file_entry.size != size) return REPLACE_SIZE_MISMATCH; else { do_replace = true; break; } } } u32 fat_entry[2]; u32 fat_index = 0; if (!do_replace) { if (AllocateBDRIBlocks(fs_header, fs_header_offset, size_blocks, &fat_index) != 0) return 1; } else { fat_index = file_entry.start_block_index + 1; } u32 bytes_written = 0, fat_index_write = fat_index; while (bytes_written < size) { // Write the full entry, walking the FAT node chain // Can't assume contiguity here, because we might be replacing an existing entry u32 write_start = fat_index_write - 1; // Data region block index u32 write_count = 0; if (BDRIRead(fat_offset + fat_index_write * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if ((bytes_written == 0) && !getfatflag(fat_entry[0])) return 1; u32 next_index = getfatindex(fat_entry[1]); if (getfatflag(fat_entry[1])) { // Multi-entry node if (BDRIRead(fat_offset + (fat_index_write + 1) * FAT_ENTRY_SIZE, FAT_ENTRY_SIZE, fat_entry) != FR_OK) return 1; if (!getfatflag(fat_entry[0]) || getfatflag(fat_entry[1]) || (getfatindex(fat_entry[0]) != fat_index_write) || (getfatindex(fat_entry[0]) >= getfatindex(fat_entry[1]))) return 1; write_count = getfatindex(fat_entry[1]) + 1 - fat_index_write; } else { // Single-entry node write_count = 1; } fat_index_write = next_index; u32 btw = min(size - bytes_written, write_count * fs_header->fs_info.data_region_blocksize); if (BDRIWrite(data_offset + write_start * fs_header->fs_info.data_region_blocksize, btw, entry + bytes_written) != FR_OK) return 1; bytes_written += btw; } if (!do_replace) { BDRIDummyFileEntry dummy_entry; // Read the 0th entry in the FET, which is always a dummy entry if (BDRIRead(fet_offset, sizeof(BDRIDummyFileEntry), &dummy_entry) != FR_OK) return 1; if (dummy_entry.max_entry_count != fs_header->fs_info.filetable_info.max_entry_count + 1) return 1; if (dummy_entry.next_dummy_index == 0) { // If the 0th entry is the only dummy entry, make a new entry file_entry.next_sibling_index = max_index + 1; dummy_entry.total_entry_count++; if (BDRIWrite(fet_offset, sizeof(u32), &(dummy_entry.total_entry_count)) != FR_OK) return 1; } else { // If there's at least one extraneous dummy entry, replace it file_entry.next_sibling_index = dummy_entry.next_dummy_index; if ((BDRIRead(fet_offset + dummy_entry.next_dummy_index * sizeof(BDRIDummyFileEntry), sizeof(BDRIDummyFileEntry), &dummy_entry) != FR_OK) || (BDRIWrite(fet_offset, sizeof(BDRIDummyFileEntry), &dummy_entry) != FR_OK)) return 1; } if (BDRIWrite((index == 0) ? det_offset + 0x2C : fet_offset + index * sizeof(BDRIFileEntry) + 0xC, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK) return 1; index = file_entry.next_sibling_index; const u32 hash_bucket = GetHashBucket(title_id_be, 1, fs_header->fs_info.file_hashtbl.outfat_count); u32 index_hash = 0; if ((BDRIRead(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &index_hash) != FR_OK) || (BDRIWrite(fht_offset + hash_bucket * sizeof(u32), sizeof(u32), &index) != FR_OK)) return 1; memset(&file_entry, 0, sizeof(BDRIFileEntry)); file_entry.parent_index = 1; memcpy(file_entry.title_id, title_id_be, 8); file_entry.start_block_index = fat_index - 1; file_entry.size = (u64) size; file_entry.hash_bucket_next_index = index_hash; if (BDRIWrite(fet_offset + index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; } return 0; } static u32 GetNumBDRIEntries(const BDRIFsHeader* fs_header, const u32 fs_header_offset) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) // Could be more thorough return 0; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 det_offset = data_offset + fs_header->fs_info.dirtable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; u32 num_entries = 0; BDRIFileEntry file_entry; // Read the index of the first file entry from the directory entry table if (BDRIRead(det_offset + 0x2C, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK) return 0; while (file_entry.next_sibling_index != 0) { num_entries++; if (BDRIRead(fet_offset + file_entry.next_sibling_index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 0; } return num_entries; } static u32 ListBDRIEntryTitleIDs(const BDRIFsHeader* fs_header, const u32 fs_header_offset, u8* title_ids, u32 max_title_ids) { if ((fs_header->pre_header.fs_info_offset != 0x20) || (fs_header->fs_info.fat.outfat_count != fs_header->fs_info.data_region.outfat_count)) return 0; const u32 data_offset = fs_header_offset + fs_header->fs_info.data_region.outfat_offset; const u32 det_offset = data_offset + fs_header->fs_info.dirtable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; const u32 fet_offset = data_offset + fs_header->fs_info.filetable_info.starting_block_index * fs_header->fs_info.data_region_blocksize; u32 num_entries = 0; BDRIFileEntry file_entry; for (u32 i = 0; i < max_title_ids; i++) memset(title_ids, 0, max_title_ids * 8); // Read the index of the first file entry from the directory entry table if (BDRIRead(det_offset + 0x2C, sizeof(u32), &(file_entry.next_sibling_index)) != FR_OK) return 1; while ((file_entry.next_sibling_index != 0) && (num_entries < max_title_ids)) { if (BDRIRead(fet_offset + file_entry.next_sibling_index * sizeof(BDRIFileEntry), sizeof(BDRIFileEntry), &file_entry) != FR_OK) return 1; u64 tid_be = getbe64(file_entry.title_id); memcpy(title_ids + num_entries * 8, (u8*) &tid_be, 8); num_entries++; } return 0; } u32 GetNumTitleInfoEntries(const char* path) { FIL file; TitleDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 0; bdrifp = &file; if ((BDRIRead(0, sizeof(TitleDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, false)) { fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 num = GetNumBDRIEntries(&(pre_header.fs_header), sizeof(TitleDBHeader) - sizeof(BDRIFsHeader)); fvx_close(bdrifp); bdrifp = NULL; return num; } u32 GetNumTickets(const char* path) { FIL file; TickDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 0; bdrifp = &file; if ((BDRIRead(0, sizeof(TickDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, true)) { fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 num = GetNumBDRIEntries(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader)); fvx_close(bdrifp); bdrifp = NULL; return num; } u32 ListTitleInfoEntryTitleIDs(const char* path, u8* title_ids, u32 max_title_ids) { FIL file; TitleDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TitleDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, false) || (ListBDRIEntryTitleIDs(&(pre_header.fs_header), sizeof(TitleDBHeader) - sizeof(BDRIFsHeader), title_ids, max_title_ids) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 ListTicketTitleIDs(const char* path, u8* title_ids, u32 max_title_ids) { FIL file; TickDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TickDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, true) || (ListBDRIEntryTitleIDs(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_ids, max_title_ids) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 ReadTitleInfoEntryFromDB(const char* path, const u8* title_id, TitleInfoEntry* tie) { FIL file; TitleDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TitleDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, false) || (ReadBDRIEntry(&(pre_header.fs_header), sizeof(TitleDBHeader) - sizeof(BDRIFsHeader), title_id, (u8*) tie, sizeof(TitleInfoEntry)) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 ReadTicketFromDB(const char* path, const u8* title_id, Ticket** ticket) { FIL file; TickDBHeader pre_header; TicketEntry* te = NULL; u32 entry_size; *ticket = NULL; if (fvx_open(&file, path, FA_READ | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TickDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, true) || (GetBDRIEntrySize(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id, &entry_size) != 0) || entry_size < sizeof(TicketEntry) + 0x14 || (te = (TicketEntry*)malloc(entry_size), te == NULL) || (ReadBDRIEntry(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id, (u8*) te, entry_size) != 0)) { free(te); // if allocated fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; if (te->ticket_size != GetTicketSize(&te->ticket)) { free(te); return 1; } if (ticket) { u32 size = te->ticket_size; memmove(te, &te->ticket, size); // recycle this memory, instead of allocating another Ticket* tik = realloc(te, size); if(!tik) tik = (Ticket*)te; *ticket = tik; return 0; } free(te); return 0; } u32 RemoveTitleInfoEntryFromDB(const char* path, const u8* title_id) { FIL file; TitleDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_WRITE | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TitleDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, false) || (RemoveBDRIEntry(&(pre_header.fs_header), sizeof(TitleDBHeader) - sizeof(BDRIFsHeader), title_id) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 RemoveTicketFromDB(const char* path, const u8* title_id) { FIL file; TickDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_WRITE | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TickDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, true) || (RemoveBDRIEntry(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(&file); bdrifp = NULL; return 0; } u32 AddTitleInfoEntryToDB(const char* path, const u8* title_id, const TitleInfoEntry* tie, bool replace) { FIL file; TitleDBHeader pre_header; if (fvx_open(&file, path, FA_READ | FA_WRITE | FA_OPEN_EXISTING) != FR_OK) return 1; bdrifp = &file; if ((BDRIRead(0, sizeof(TitleDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, false) || (AddBDRIEntry(&(pre_header.fs_header), sizeof(TitleDBHeader) - sizeof(BDRIFsHeader), title_id, (const u8*) tie, sizeof(TitleInfoEntry), replace) != 0)) { fvx_close(bdrifp); bdrifp = NULL; return 1; } fvx_close(bdrifp); bdrifp = NULL; return 0; } u32 AddTicketToDB(const char* path, const u8* title_id, const Ticket* ticket, bool replace) { FIL file; TickDBHeader pre_header; u32 entry_size = sizeof(TicketEntry) + GetTicketContentIndexSize(ticket); TicketEntry* te = (TicketEntry*)malloc(entry_size); if (!te) { return 1; } te->ticket_count = 1; te->ticket_size = GetTicketSize(ticket); memcpy(&te->ticket, ticket, te->ticket_size); if (fvx_open(&file, path, FA_READ | FA_WRITE | FA_OPEN_EXISTING) != FR_OK) { free(te); return 1; } bdrifp = &file; u32 add_bdri_res = 0; if ((BDRIRead(0, sizeof(TickDBHeader), &pre_header) != FR_OK) || !CheckDBMagic((u8*) &pre_header, true) || ((add_bdri_res = AddBDRIEntry(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id, (const u8*) te, entry_size, replace)) == 1) || (add_bdri_res == REPLACE_SIZE_MISMATCH && ((RemoveBDRIEntry(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id) != 0) || (AddBDRIEntry(&(pre_header.fs_header), sizeof(TickDBHeader) - sizeof(BDRIFsHeader), title_id, (const u8*) te, entry_size, replace) != 0)))) { free(te); fvx_close(bdrifp); bdrifp = NULL; return 1; } free(te); fvx_close(bdrifp); bdrifp = NULL; return 0; } static u32 CalcNumHashBuckets(u32 num_entries) { if (num_entries <= 3) return 3; if (num_entries <= 19) return num_entries | 1; for (int i = 0; i < 100; ++i) { u32 ret = num_entries + i; if (ret & 1 && ret % 3 && ret % 5 && ret % 7 && ret % 11 && ret % 13 && ret % 17) return ret; } return num_entries | 1; } u32 CreateBDRI(const char *path, u64 image_offset, u64 image_size, u32 blocksize, u32 num_files) { BDRIFsHeader bdri; memset(&bdri, 0, sizeof(BDRIFsHeader)); IFatPreHeader *pre_header = &bdri.pre_header; IFatFsInfo *fs_info = &bdri.fs_info; const u64 img_num_blocks = image_size / blocksize; const u32 file_hashbucket_count = CalcNumHashBuckets(num_files); memcpy(pre_header->magic_str, "BDRI", 4); pre_header->version = 0x30000; pre_header->fs_image_blocksize = blocksize; pre_header->fs_image_size_blocks = img_num_blocks; pre_header->fs_info_offset = sizeof(IFatPreHeader); const u64 full_image_size = pre_header->fs_image_blocksize * pre_header->fs_image_size_blocks; u32 num_data_blocks = img_num_blocks; u32 data_region_offs = 0; // dynamically adjust the number of data region blocks to fit inside the given image size while (1) { if (!num_data_blocks) return 1; // image will not fit inside given size data_region_offs = align_pow2( sizeof(IFatPreHeader) + sizeof(IFatFsInfo) + /* headers */ (4 * 1) + (4 * file_hashbucket_count) + /* hashtables (dir, file) */ (num_data_blocks + 1) * sizeof(IFatEntry), /* FAT entries, including the freelist entry */ blocksize); if (full_image_size >= (num_data_blocks * blocksize) + data_region_offs) break; // found a satisfactory number of data blocks --num_data_blocks; } // create file system info fs_info->data_region_blocksize = blocksize; fs_info->dir_hashtbl.outfat_offset = pre_header->fs_info_offset + sizeof(IFatFsInfo); fs_info->dir_hashtbl.outfat_count = 1; fs_info->file_hashtbl.outfat_offset = fs_info->dir_hashtbl.outfat_offset + 4; fs_info->file_hashtbl.outfat_count = file_hashbucket_count; fs_info->fat.outfat_offset = fs_info->file_hashtbl.outfat_offset + file_hashbucket_count * 4; fs_info->fat.outfat_count = num_data_blocks; fs_info->data_region.outfat_offset = data_region_offs; fs_info->data_region.outfat_count = num_data_blocks; // dummy freelist dir entry [0] + root dir entry [1] uint32_t dir_entries_num_blocks = ceil_div(2 * sizeof(BDRIDirectoryEntry), blocksize); // dummy freelist file entry [0] + file entries [n] uint32_t file_entries_num_blocks = ceil_div((num_files + 1) * sizeof(BDRIFileEntry), blocksize); fs_info->dirtable_info.max_entry_count = 1; fs_info->dirtable_info.block_count = dir_entries_num_blocks; fs_info->dirtable_info.starting_block_index = 0xFFFFFFFF; // to be allocated in FAT later using above block_count fs_info->filetable_info.max_entry_count = num_files; fs_info->filetable_info.block_count = file_entries_num_blocks; fs_info->filetable_info.starting_block_index = 0xFFFFFFFF; // to be allocated in FAT later using above block_count FIL file; if (fvx_open(&file, path, FA_READ | FA_WRITE | FA_OPEN_EXISTING) != FR_OK) { bdrifp = NULL; return 1; } bdrifp = &file; // create new FAT u32 fatentries[2][2]; fatentries[0][0] = buildfatuv(0, 0); fatentries[0][1] = buildfatuv(1, 0); fatentries[1][0] = buildfatuv(0, true); fatentries[1][1] = buildfatuv(0, num_data_blocks > 1); #define FATOFFSET(n) (image_offset + fs_info->fat.outfat_offset + (n) * FAT_ENTRY_SIZE) if (BDRIWrite(FATOFFSET(0), FAT_ENTRY_SIZE * 2, fatentries) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } if (num_data_blocks > 1) { u32 *fatentry = fatentries[0]; fatentry[0] = buildfatuv(1, true); fatentry[1] = buildfatuv(num_data_blocks, false); if (BDRIWrite(FATOFFSET(2), FAT_ENTRY_SIZE, fatentry) != FR_OK || BDRIWrite(FATOFFSET(num_data_blocks), FAT_ENTRY_SIZE, fatentry) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } } // allocate file and directory entry tables in FAT if (AllocateBDRIBlocks(&bdri, image_offset, dir_entries_num_blocks, &fs_info->dirtable_info.starting_block_index) != 0 || AllocateBDRIBlocks(&bdri, image_offset, file_entries_num_blocks, &fs_info->filetable_info.starting_block_index) != 0) { fvx_close(&file); bdrifp = NULL; return 1; } // because of the extra freelist sentinel in fat[0], the actual data region index is fat_index - 1 fs_info->dirtable_info.starting_block_index -= 1; fs_info->filetable_info.starting_block_index -= 1; if (BDRIWrite(image_offset, sizeof(BDRIFsHeader), &bdri) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } // initialize file/dir hash tables & entries // the directory hashtable has just one entry, pointing to the root directory // no need to do the calculation u32 dir_hash_value = 1; if (BDRIWrite(image_offset + fs_info->dir_hashtbl.outfat_offset, sizeof(u32), &dir_hash_value) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } u8 zero[0x200]; memset(zero, 0, sizeof(zero)); u32 remaining_fht = file_hashbucket_count * 4; u32 fht_cur_offset = fs_info->file_hashtbl.outfat_offset; // fill the file hashtable with zeros while (remaining_fht) { u32 writesize = min(remaining_fht, sizeof(zero)); if (BDRIWrite(image_offset + fht_cur_offset, writesize, zero) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } remaining_fht -= writesize; fht_cur_offset += writesize; } // initialize directory entry table BDRIDummyDirectoryEntry dummy_dir; BDRIDirectoryEntry root_dir; memset(&dummy_dir, 0, sizeof(dummy_dir)); memset(&root_dir, 0, sizeof(root_dir)); dummy_dir.next_dummy_index = 0; dummy_dir.total_entry_count = 2; // this (dummy), and root (the entry after) dummy_dir.max_entry_count = 3; // even though only two are "used" u64 det_offset = fs_info->data_region.outfat_offset + fs_info->dirtable_info.starting_block_index * fs_info->data_region_blocksize; if (BDRIWrite(image_offset + det_offset, sizeof(dummy_dir), &dummy_dir) != FR_OK || BDRIWrite(image_offset + det_offset + sizeof(dummy_dir), sizeof(root_dir), &root_dir) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } // initialize file entry table BDRIDummyFileEntry dummy_file; memset(&dummy_file, 0, sizeof(dummy_file)); dummy_file.next_dummy_index = 0; dummy_file.total_entry_count = 1; // currently, just this (dummy) dummy_file.max_entry_count = num_files + 1; // this (dummy), and however many file entries should exist u64 fet_offset = fs_info->data_region.outfat_offset + fs_info->filetable_info.starting_block_index * fs_info->data_region_blocksize; if (BDRIWrite(image_offset + fet_offset, sizeof(dummy_file), &dummy_file) != FR_OK) { fvx_close(&file); bdrifp = NULL; return 1; } fvx_close(&file); bdrifp = NULL; return 0; } typedef struct DbFileConfig { const char *path; const char *magic; u32 version; u32 full_data_size; u32 image_offset; // also pre-header size u32 image_size; u32 image_blocksize; u32 num_entries; } DbFileConfig; typedef enum DbType { NAND_TICKET_DB = 0, NAND_IMPORT_DB, NAND_TITLE_DB, NAND_TMP_I_DB, NAND_TMP_T_DB, SDMC_TITLE_DB, SDMC_IMPORT_DB, } DbType; static const DbFileConfig DbConfigs[7] = { // NAND dbs { "/dbs/ticket.db", "TICK" , 1, 0x10A2010, 0x10, 0x10A2000, 0x200, 8192 }, // ticket.db is the only db where the image size is correct... { "/dbs/import.db", "NANDIDB", 0, 0x17800 , 0x80, 0x17800 , 0x80 , 512 }, // --- { "/dbs/title.db" , "NANDTDB", 0, 0x2ED80 , 0x80, 0x2ED80 , 0x80, 1024 }, // | *all* of these are missing 0x80 bytes at the end. { "/dbs/tmp_i.db" , "TEMPIDB", 0, 0xE00 , 0x80, 0xE00 , 0x80, 16 }, // | the image size should be file size - 0x80 because { "/dbs/tmp_t.db" , "TEMPIDB", 0, 0x6000 , 0x80, 0x6000 , 0x80, 128 }, // | of the pre-header. keeping it the same just for // SDMC dbs // | consistency with Process9, really. { "/dbs/title.db" , "TEMPTDB", 0, 0x175A80 , 0x80, 0x175A80 , 0x80, 8192 }, // | { "/dbs/import.db", "TEMPTDB", 0, 0x175A80 , 0x80, 0x175A80 , 0x80 , 8192 }, // --- }; static const DbFileConfig *GetDbFileConfigBuildPath(char *outpath, u32 pathsize, u32 type, bool emunand) { if (type >= countof(DbConfigs)) return NULL; bool nand = type <= NAND_TMP_T_DB; char dest_drive = nand ? emunand ? '4' : '1' : emunand ? 'B' : 'A'; const DbFileConfig *config = &DbConfigs[type]; snprintf(outpath, pathsize, "%c:%s", dest_drive, config->path); return config; } u32 CreateDbFile(u32 type, bool emunand) { char path[256] = { 0 }; const DbFileConfig *config = GetDbFileConfigBuildPath(path, sizeof(path), type, emunand); if (!config) return 1; u64 reqsize = BuildDiffCalcRequiredSize(config->full_data_size, false, true); if (!CheckWritePermissions(path)) return 1; // ensure remounting the old mount path char path_store[256] = { 0 }; char* path_bak = NULL; strncpy(path_store, GetMountPath(), 256); if (*path_store) path_bak = path_store; // unmount any mounted image since we're about to create a DIFF that will need to be mounted InitImgFS(NULL); // create the raw file if (fvx_qcreate(path, reqsize) != FR_OK) { InitImgFS(path_bak); return 1; } // create the DIFF container and mount it if (CreateDiff(path, config->full_data_size, false, true, NULL) != 0 || !InitImgFS(path)) { InitImgFS(path_bak); fvx_unlink(path); return 1; } char db_hdr[0x80]; memset(db_hdr, 0, sizeof(db_hdr)); u32 version_offset = align_pow2(strlen(config->magic), 4); memcpy(db_hdr, config->magic, strlen(config->magic)); memcpy(&db_hdr[version_offset], &config->version, 4); UINT written = 0; // write the BDRI filesystem image if (fvx_qwrite("D:/partitionA.bin", db_hdr, 0, config->image_offset, &written) != 0 || CreateBDRI("D:/partitionA.bin", config->image_offset, config->image_size, config->image_blocksize, config->num_entries) != 0) { InitImgFS(path_bak); fvx_unlink(path); return 1; } // remount previously mounted image, if there was one InitImgFS(path_bak); // make sure CMAC is fixed if (FixFileCmac(path, true) != 0) { fvx_unlink(path); return 1; } return 0; } u32 CreateDbFilesForDrive(const char *destdrv, bool silent, bool force_overwrite) { static const DbType db_types_nand[5] = { NAND_TICKET_DB, NAND_IMPORT_DB, NAND_TITLE_DB, NAND_TMP_I_DB, NAND_TMP_T_DB }; static const DbType db_types_sdmc[2] = { SDMC_TITLE_DB, SDMC_IMPORT_DB }; if (*destdrv != 'A' && *destdrv != 'B' && *destdrv != '1' && *destdrv != '4') { return 1; } bool emunand = *destdrv == 'B' /* EmuNAND SD */ || *destdrv == '4' /* EmuNAND CTRNAND */; bool sd = *destdrv == 'A' || *destdrv == 'B' /* Sys/EmuNAND SD */; const DbType *dbs_to_check = sd ? db_types_sdmc : db_types_nand; u32 db_count = sd ? countof(db_types_sdmc) : countof(db_types_nand); u32 num_to_create = db_count; u32 num_already_exist = 0; u32 num_failed = 0; u32 num_created_ok = 0; char db_path[256] = { 0 }; const DbFileConfig *config = NULL; for (u32 i = 0; i < db_count; i++) { if (!(config = GetDbFileConfigBuildPath(db_path, sizeof(db_path), dbs_to_check[i], emunand))) { return 1; } if (fvx_stat(db_path, NULL) == FR_OK) { if (!force_overwrite && fvx_qsize(db_path) == BuildDiffCalcRequiredSize(config->full_data_size, false, true)) { ++num_already_exist; --num_to_create; continue; } } if (CreateDbFile(dbs_to_check[i], emunand) == 0) { ++num_created_ok; } else { ++num_failed; if (!silent) { ShowPrompt(false, STR_PATH_CREATE_DB_FILE_FAILED, db_path); } } } if (!silent) { if (num_already_exist) { if (num_already_exist == db_count) { ShowPrompt(false, "%s", STR_NO_MISSING_DB_FILES_DETECTED); } else { ShowPrompt(false, STR_CREATE_DB_FILES_N_N_N_OK_FAILED_ALREADY_EXIST, num_created_ok, num_failed, num_already_exist); } } else { if (num_created_ok == db_count) { ShowPrompt(false, "%s", STR_SUCCESSFULLY_CREATED_DB_FILES_FOR_DRIVE); } else { ShowPrompt(false, STR_CREATE_DB_FILES_N_N_OK_FAILED, num_created_ok, num_failed); } } } return num_to_create == num_created_ok ? 0 : 1; }