// Copyright 2009 Kwiirk // Licensed under the terms of the GNU GPL, version 2 // http://www.gnu.org/licenses/old-licenses/gpl-2.0.txt // Modified by oggzee #include #include #include "libwbfs.h" #include "gecko/gecko.h" #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #define read_le32_unaligned(x) ((x)[0]|((x)[1]<<8)|((x)[2]<<16)|((x)[3]<<24)) #define ERROR(x) do {wbfs_error(x);goto error;}while(0) #define ALIGN_LBA(x) (((x)+p->hd_sec_sz-1)&(~(p->hd_sec_sz-1))) wbfs_t wbfs_iso_file; static int force_mode=0; void wbfs_set_force_mode(int force) { force_mode = force; } static u8 size_to_shift(u32 size) { u8 ret = 0; while(size) { ret++; size >>= 1; } return ret - 1; } wbfs_t *wbfs_open_hd(rw_sector_callback_t read_hdsector, rw_sector_callback_t write_hdsector, void *callback_data, int hd_sector_size, int num_hd_sector __attribute((unused)), int reset) { int i=num_hd_sector,ret; u8 *ptr,*tmp_buffer = wbfs_ioalloc(hd_sector_size); u8 part_table[16*4]; ret = read_hdsector(callback_data,0,1,tmp_buffer); if(ret) return 0; //find wbfs partition wbfs_memcpy(part_table, tmp_buffer + 0x1be, 16 * 4); ptr = part_table; for(i = 0; i < 4; i++, ptr += 16) { u32 part_lba = read_le32_unaligned(ptr + 0x8); wbfs_head_t *head = (wbfs_head_t *)tmp_buffer; ret = read_hdsector(callback_data, part_lba, 1, tmp_buffer); // verify there is the magic. if (head->magic == wbfs_htonl(WBFS_MAGIC)) { wbfs_t *p = wbfs_open_partition(read_hdsector, write_hdsector, callback_data, hd_sector_size, 0, part_lba,reset); wbfs_iofree(tmp_buffer); return p; } } wbfs_iofree(tmp_buffer); if(reset)// XXX make a empty hd partition.. { } return 0; } wbfs_t *wbfs_open_partition(rw_sector_callback_t read_hdsector, rw_sector_callback_t write_hdsector, void *callback_data, int hd_sector_size, int num_hd_sector, u32 part_lba, int reset) { wbfs_t *p = wbfs_malloc(sizeof(wbfs_t)); wbfs_head_t *head = wbfs_ioalloc( hd_sector_size ? hd_sector_size : 512 ); //constants, but put here for consistancy p->wii_sec_sz = 0x8000; p->wii_sec_sz_s = size_to_shift(0x8000); p->n_wii_sec = (num_hd_sector / 0x8000) * hd_sector_size; p->n_wii_sec_per_disc = 143432 * 2; //support for double layers discs.. p->head = head; p->part_lba = part_lba; // init the partition if (reset) { u8 sz_s; wbfs_memset(head, 0, hd_sector_size); head->magic = wbfs_htonl(WBFS_MAGIC); head->hd_sec_sz_s = size_to_shift(hd_sector_size); head->n_hd_sec = wbfs_htonl(num_hd_sector); // choose minimum wblk_sz that fits this partition size for(sz_s = 6; sz_s < 11; sz_s++) { // ensure that wbfs_sec_sz is big enough to address every blocks using 16 bits if(p->n_wii_sec < ((1U << 16) * (1 << sz_s))) break; } head->wbfs_sec_sz_s = sz_s + p->wii_sec_sz_s; } else read_hdsector(callback_data, p->part_lba, 1, head); if (head->magic != wbfs_htonl( WBFS_MAGIC )) ERROR( "bad magic\n" ); if (!force_mode && hd_sector_size && head->hd_sec_sz_s != size_to_shift(hd_sector_size)) ERROR( "hd sector size doesn't match\n" ); if (!force_mode && num_hd_sector && head->n_hd_sec != (u32) wbfs_htonl( num_hd_sector )) ERROR( "hd num sector doesn't match\n" ); p->hd_sec_sz = 1 << head->hd_sec_sz_s; p->hd_sec_sz_s = head->hd_sec_sz_s; p->n_hd_sec = wbfs_ntohl(head->n_hd_sec); p->n_wii_sec = (p->n_hd_sec / p->wii_sec_sz) * (p->hd_sec_sz); p->wbfs_sec_sz_s = head->wbfs_sec_sz_s; p->wbfs_sec_sz = 1 << p->wbfs_sec_sz_s; p->n_wbfs_sec = p->n_wii_sec >> (p->wbfs_sec_sz_s - p->wii_sec_sz_s); p->n_wbfs_sec_per_disc = p->n_wii_sec_per_disc >> (p->wbfs_sec_sz_s - p->wii_sec_sz_s); p->disc_info_sz = ALIGN_LBA(sizeof(wbfs_disc_info_t) + p->n_wbfs_sec_per_disc * 2); //gprintf("hd_sector_size %X wii_sector size %X wbfs sector_size %X\n", p->hd_sec_sz, p->wii_sec_sz, p->wbfs_sec_sz); p->read_hdsector = read_hdsector; p->write_hdsector = write_hdsector; p->callback_data = callback_data; p->freeblks_lba = (p->wbfs_sec_sz - p->n_wbfs_sec / 8) >> p->hd_sec_sz_s; if (!reset) p->freeblks = 0; // will alloc and read only if needed else { // init with all free blocks p->freeblks = wbfs_ioalloc(ALIGN_LBA( p->n_wbfs_sec / 8)); wbfs_memset(p->freeblks, 0xff, p->n_wbfs_sec / 8); } p->max_disc = (p->freeblks_lba - 1) / (p->disc_info_sz >> p->hd_sec_sz_s); if(p->max_disc > p->hd_sec_sz - sizeof(wbfs_head_t)) p->max_disc = p->hd_sec_sz - sizeof(wbfs_head_t); p->tmp_buffer = wbfs_ioalloc(p->hd_sec_sz); p->n_disc_open = 0; return p; error: wbfs_free(p); wbfs_iofree(head); return 0; } void wbfs_sync(wbfs_t *p) { // copy back descriptors if(p->write_hdsector) { p->write_hdsector(p->callback_data, p->part_lba + 0, 1, p->head); if(p->freeblks) p->write_hdsector(p->callback_data, p->part_lba + p->freeblks_lba, ALIGN_LBA(p->n_wbfs_sec / 8) >> p->hd_sec_sz_s, p->freeblks); } } void wbfs_close(wbfs_t *p) { wbfs_sync(p); if(p->n_disc_open) ERROR("trying to close wbfs while discs still open\n"); wbfs_iofree(p->head); wbfs_iofree(p->tmp_buffer); if(p->freeblks) wbfs_iofree(p->freeblks); wbfs_free(p); error: return; } wbfs_disc_t *wbfs_open_disc(wbfs_t* p, const u8 *discid) { u32 i; int disc_info_sz_lba = p->disc_info_sz>>p->hd_sec_sz_s; wbfs_disc_t *d = 0; for(i = 0; i < p->max_disc; i++) { if (p->head->disc_table[i]) { p->read_hdsector(p->callback_data, p->part_lba + 1 + i * disc_info_sz_lba, 1, p->tmp_buffer); if(wbfs_memcmp(discid,p->tmp_buffer,6)==0) { d = wbfs_malloc(sizeof(*d)); if(!d) ERROR("allocating memory\n"); d->p = p; d->i = i; d->header = wbfs_ioalloc(p->disc_info_sz); if(!d->header) ERROR("allocating memory\n"); p->read_hdsector(p->callback_data, p->part_lba + 1 + i * disc_info_sz_lba, disc_info_sz_lba, d->header); p->n_disc_open ++; //for(i = 0; i < p->n_wbfs_sec_per_disc; i++) //printf("%d,", wbfs_ntohs(d->header->wlba_table[i])); return d; } } } return 0; error: if(d) wbfs_iofree(d); return 0; } void wbfs_close_disc(wbfs_disc_t*d) { d->p->n_disc_open --; wbfs_iofree(d->header); wbfs_free(d); } // offset is pointing 32bit words to address the whole dvd, although len is in bytes int wbfs_disc_read(wbfs_disc_t *d, u32 offset, u32 len, u8 *data) { if (d->p == &wbfs_iso_file) return wbfs_iso_file_read(d, offset, data, len); wbfs_t *p = d->p; u16 wlba = offset>>(p->wbfs_sec_sz_s-2); u32 iwlba_shift = p->wbfs_sec_sz_s - p->hd_sec_sz_s; u32 lba_mask = (p->wbfs_sec_sz-1)>>(p->hd_sec_sz_s); u32 lba = (offset>>(p->hd_sec_sz_s-2))&lba_mask; u32 off = offset&((p->hd_sec_sz>>2)-1); u16 iwlba = wbfs_ntohs(d->header->wlba_table[wlba]); u32 len_copied; int err = 0; u8 *ptr = data; if(unlikely(iwlba==0)) return 1; if(unlikely(off)) { off *= 4; err = p->read_hdsector(p->callback_data, p->part_lba + (iwlba<tmp_buffer); if(err) return err; len_copied = p->hd_sec_sz - off; if(likely(len < len_copied)) len_copied = len; wbfs_memcpy(ptr, p->tmp_buffer + off, len_copied); len -= len_copied; ptr += len_copied; lba++; if(unlikely(lba>lba_mask && len)) { lba=0; iwlba = wbfs_ntohs(d->header->wlba_table[++wlba]); if(unlikely(iwlba==0)) return 1; } } while(likely(len>=p->hd_sec_sz)) { u32 nlb = len>>(p->hd_sec_sz_s); if(unlikely(lba + nlb > p->wbfs_sec_sz)) // dont cross wbfs sectors.. nlb = p->wbfs_sec_sz-lba; err = p->read_hdsector(p->callback_data, p->part_lba + (iwlba<hd_sec_sz_s; ptr += nlb << p->hd_sec_sz_s; lba += nlb; if(unlikely(lba > lba_mask && len)) { lba = 0; iwlba = wbfs_ntohs(d->header->wlba_table[++wlba]); if(unlikely(iwlba==0)) return 1; } } if(unlikely(len)) { err = p->read_hdsector(p->callback_data, p->part_lba + (iwlba << iwlba_shift) + lba, 1, p->tmp_buffer); if(err) return err; wbfs_memcpy(ptr, p->tmp_buffer, len); } return 0; } // disc listing u32 wbfs_count_discs(wbfs_t *p) { u32 i,count=0; for(i = 0; i < p->max_disc; i++) { if (p->head->disc_table[i]) count++; } return count; } u32 wbfs_sector_used(wbfs_t *p, wbfs_disc_info_t *di) { u32 tot_blk = 0, j; for(j = 0; j < p->n_wbfs_sec_per_disc; j++) { if(wbfs_ntohs(di->wlba_table[j])) tot_blk++; } return tot_blk; } u32 wbfs_sector_used2(wbfs_t *p, wbfs_disc_info_t *di, u32 *last_blk) { u32 tot_blk = 0, j; for(j = 0; j < p->n_wbfs_sec_per_disc; j++) { if(wbfs_ntohs(di->wlba_table[j])) { if (last_blk) *last_blk = j; tot_blk++; } } return tot_blk; } u32 wbfs_get_disc_info(wbfs_t *p, u32 index,u8 *header,int header_size,u32 *size)//size in 32 bit { u32 i,count=0; if (!p) return 1; int disc_info_sz_lba = p->disc_info_sz >> p->hd_sec_sz_s; for(i = 0; i < p->max_disc; i++) { if (p->head->disc_table[i]) { if(count++ == index) { p->read_hdsector(p->callback_data, p->part_lba + 1 + i * disc_info_sz_lba, 1, p->tmp_buffer); if(header_size > (int)p->hd_sec_sz) header_size = p->hd_sec_sz; u32 magic = wbfs_ntohl(*(u32*)(p->tmp_buffer + 24)); if(magic != WII_MAGIC) { p->head->disc_table[i]=0; return 1; } memcpy(header, p->tmp_buffer, header_size); if(size) { u8 *header = wbfs_ioalloc(p->disc_info_sz); p->read_hdsector(p->callback_data, p->part_lba + 1 + i * disc_info_sz_lba, disc_info_sz_lba, header); u32 sec_used = wbfs_sector_used(p,(wbfs_disc_info_t *)header); wbfs_iofree(header); *size = sec_used<<(p->wbfs_sec_sz_s-2); } return 0; } } } return 1; } static void load_freeblocks(wbfs_t *p) { if(p->freeblks) return; // XXX should handle malloc error.. p->freeblks = wbfs_ioalloc(ALIGN_LBA(p->n_wbfs_sec/8)); p->read_hdsector(p->callback_data, p->part_lba + p->freeblks_lba, ALIGN_LBA(p->n_wbfs_sec / 8) >> p->hd_sec_sz_s, p->freeblks); } u32 wbfs_count_usedblocks(wbfs_t *p) { u32 i, j, count = 0; load_freeblocks(p); for(i = 0; i < p->n_wbfs_sec / (8 * 4); i++) { u32 v = wbfs_ntohl(p->freeblks[i]); if(v == ~0U) count += 32; else if(v != 0) { for(j = 0; j < 32; j++) { if (v & (1 << j)) count++; } } } return count; } // write access // static int block_used(u8 *used, u32 i, u32 wblk_sz) { u32 k; i *= wblk_sz; for(k = 0; k < wblk_sz; k++) { if(i + k < 143432 * 2 && used[i + k]) return 1; } return 0; } static u32 alloc_block(wbfs_t *p) { u32 i,j; for(i = 0; i < p->n_wbfs_sec / (8 * 4); i++) { u32 v = wbfs_ntohl(p->freeblks[i]); if(v != 0) { for(j = 0; j < 32; j++) { if (v & (1 << j)) { p->freeblks[i] = wbfs_htonl(v & ~(1<freeblks[i]); p->freeblks[i] = wbfs_htonl(v | 1 << j); } u32 wbfs_add_disc(wbfs_t *p, read_wiidisc_callback_t read_src_wii_disc, void *callback_data, progress_callback_t spinner,void *spinner_data,partition_selector_t sel,int copy_1_1) { int i,discn; u32 tot,cur; u32 wii_sec_per_wbfs_sect = 1 << (p->wbfs_sec_sz_s - p->wii_sec_sz_s); wiidisc_t *d = 0; u8 *used = 0; wbfs_disc_info_t *info = 0; u8* copy_buffer = 0; int retval = -1; int num_wbfs_sect_to_copy; u32 last_used; used = wbfs_malloc(p->n_wii_sec_per_disc); if(!used) ERROR("unable to alloc memory\n"); // copy_1_1 needs disk usage for layers detection //if(!copy_1_1) { d = wd_open_disc(read_src_wii_disc, callback_data); if(!d) ERROR("unable to open wii disc\n"); wd_build_disc_usage(d, sel, used); wd_close_disc(d); d = 0; } for(i = 0; i < p->max_disc; i++)// find a free slot. { if(p->head->disc_table[i]==0) break; } if(i == p->max_disc) ERROR("no space left on device (table full)\n"); p->head->disc_table[i] = 1; discn = i; load_freeblocks(p); // build disc info info = wbfs_ioalloc(p->disc_info_sz); read_src_wii_disc(callback_data, 0, 0x100, info->disc_header_copy); copy_buffer = wbfs_ioalloc(p->wii_sec_sz); if(!copy_buffer) ERROR("alloc memory\n"); tot = 0; cur = 0; num_wbfs_sect_to_copy = p->n_wbfs_sec_per_disc; // count total number of sectors to write last_used = 0; for(i = 0; i < num_wbfs_sect_to_copy; i++) { if(block_used(used, i, wii_sec_per_wbfs_sect)) { tot += wii_sec_per_wbfs_sect; last_used = i; } } if (copy_1_1) { // detect single or dual layer if((last_used + 1) > (p->n_wbfs_sec_per_disc / 2)) num_wbfs_sect_to_copy = p->n_wbfs_sec_per_disc; else num_wbfs_sect_to_copy = p->n_wbfs_sec_per_disc / 2; tot = num_wbfs_sect_to_copy * wii_sec_per_wbfs_sect; } /* // num of hd sectors to copy could be specified directly if (copy_1_1 > 1) { u32 hd_sec_per_wii_sec = p->wii_sec_sz / p->hd_sec_sz; num_wbfs_sect_to_copy = copy_1_1 / hd_sec_per_wii_sec / wii_sec_per_wbfs_sect; tot = num_wbfs_sect_to_copy * wii_sec_per_wbfs_sect; }*/ int ret = 0; if(spinner) spinner(0, tot, spinner_data); for(i=0; i < num_wbfs_sect_to_copy; i++) { u16 bl = 0; if(copy_1_1 || block_used(used,i, wii_sec_per_wbfs_sect)) { u16 j; bl = alloc_block(p); if (bl==0xffff) ERROR("no space left on device (disc full)\n"); for(j = 0; j < wii_sec_per_wbfs_sect; j++) { u32 offset = (i * (p->wbfs_sec_sz >> 2)) + (j * (p->wii_sec_sz >> 2)); ret = read_src_wii_disc(callback_data, offset, p->wii_sec_sz, copy_buffer); if (ret) { if (copy_1_1 && i > p->n_wbfs_sec_per_disc / 2) { // end of dual layer data if(j > 0) info->wlba_table[i] = wbfs_htons(bl); spinner(tot,tot,spinner_data); break; } //ERROR("read error"); gprintf("\rWARNING: read (%u) error (%d)\n", offset, ret); } //fix the partition table if(offset == (0x40000>>2)) wd_fix_partition_table(sel, copy_buffer); p->write_hdsector(p->callback_data, p->part_lba + bl * (p->wbfs_sec_sz / p->hd_sec_sz) + j * (p->wii_sec_sz / p->hd_sec_sz), p->wii_sec_sz / p->hd_sec_sz, copy_buffer); cur++; if(spinner) spinner(cur,tot,spinner_data); } } if(ret) break; info->wlba_table[i] = wbfs_htons(bl); } // write disc info int disc_info_sz_lba = p->disc_info_sz>>p->hd_sec_sz_s; p->write_hdsector(p->callback_data, p->part_lba+1+discn*disc_info_sz_lba,disc_info_sz_lba,info); wbfs_sync(p); retval = 0; error: if(d) wd_close_disc(d); if(used) wbfs_free(used); if(info) wbfs_iofree(info); if(copy_buffer) wbfs_iofree(copy_buffer); // init with all free blocks return retval; } u32 wbfs_rm_disc(wbfs_t *p, u8* discid) { wbfs_disc_t *d = wbfs_open_disc(p,discid); int i; int discn = 0; int disc_info_sz_lba = p->disc_info_sz>>p->hd_sec_sz_s; if(!d) return 1; load_freeblocks(p); discn = d->i; for( i=0; i< p->n_wbfs_sec_per_disc; i++) { u32 iwlba = wbfs_ntohs(d->header->wlba_table[i]); if(iwlba) free_block(p,iwlba); } memset(d->header,0,p->disc_info_sz); p->write_hdsector(p->callback_data, p->part_lba+1+discn*disc_info_sz_lba,disc_info_sz_lba,d->header); p->head->disc_table[discn] = 0; wbfs_close_disc(d); wbfs_sync(p); return 0; } // trim the file-system to its minimum size u32 wbfs_trim(wbfs_t *p) { u32 maxbl; load_freeblocks(p); maxbl = alloc_block(p); p->n_hd_sec = maxbl << (p->wbfs_sec_sz_s - p->hd_sec_sz_s); p->head->n_hd_sec = wbfs_htonl(p->n_hd_sec); // make all block full memset(p->freeblks, 0, p->n_wbfs_sec / 8); wbfs_sync(p); // os layer will truncate the file. return maxbl; } u32 wbfs_size_disc(wbfs_t *p,read_wiidisc_callback_t read_src_wii_disc, void *callback_data,partition_selector_t sel, u32 *comp_size, u32 *real_size) { int i; u32 tot = 0, last = 0; u32 wii_sec_per_wbfs_sect = 1 << (p->wbfs_sec_sz_s - p->wii_sec_sz_s); wiidisc_t *d = 0; u8 *used = wbfs_malloc(p->n_wii_sec_per_disc); if(!used) ERROR("unable to alloc memory\n"); d = wd_open_disc(read_src_wii_disc,callback_data); if(!d) ERROR("unable to open wii disc\n"); wd_build_disc_usage(d, sel, used); wd_close_disc(d); d = 0; // count total number to write for spinner for (i = 0; i < p->n_wbfs_sec_per_disc; i++) { if (block_used(used, i, wii_sec_per_wbfs_sect)) { tot += wii_sec_per_wbfs_sect; last = i * wii_sec_per_wbfs_sect; } } error: if(d) wd_close_disc(d); if(used) wbfs_free(used); *comp_size = tot; *real_size = last; return 0; } // offset is pointing 32bit words to address the whole dvd, although len is in bytes //int wbfs_disc_read(wbfs_disc_t*d,u32 offset, u8 *data, u32 len) // offset points 32bit words, count counts bytes //int (*read_wiidisc_callback_t)(void*fp,u32 offset,u32 count,void*iobuf); // connect wiidisc to wbfs_disc int read_wiidisc_wbfsdisc(void *fp, u32 offset, u32 count, void *iobuf) { return wbfs_disc_read((wbfs_disc_t *)fp, offset, count, iobuf); } u32 wbfs_extract_file(wbfs_disc_t *d, char *path, void **data) { wiidisc_t *wd = 0; u32 ret = 0; wd = wd_open_disc(read_wiidisc_wbfsdisc, d); if (!wd) { wbfs_error( "opening wbfs disc\n" ); return -1; } *data = wd_extract_file(wd, &ret, ONLY_GAME_PARTITION, path); if (!*data) { //ERROR("file not found"); ret = 0; } wd_close_disc(wd); return ret; } int wbfs_get_fragments(wbfs_disc_t *d, _frag_append_t append_fragment, void *callback_data, u32 hdd_sector_size) { if (!d) return -1; wbfs_t *p = d->p; int src_wbs_nlb = p->wbfs_sec_sz / hdd_sector_size; int i, ret, last = 0; for( i=0; i< p->n_wbfs_sec_per_disc; i++) { u32 iwlba = wbfs_ntohs(d->header->wlba_table[i]); if (iwlba) { ret = append_fragment(callback_data, i * src_wbs_nlb, // offset p->part_lba + iwlba * src_wbs_nlb, // sector src_wbs_nlb); // count if (ret) return ret; // error last = i; } } if(last < p->n_wbfs_sec_per_disc / 2) last = p->n_wbfs_sec_per_disc / 2; u32 size = last * src_wbs_nlb; append_fragment(callback_data, size, 0, 0); // set size return 0; } // wrapper for reading .iso files using wbfs apis // offset is pointing 32bit words to address the whole dvd, although len is in bytes int wbfs_iso_file_read(wbfs_disc_t*d,u32 offset, u8 *data, u32 len) { if (!d || d->p != &wbfs_iso_file) return -1; int fd = (int)d->header; //HMM? //int fd = d->i; off_t off = ((u64)offset) << 2; off_t ret_off; ret_off = lseek(fd, off, SEEK_SET); if (ret_off != off) return -1; u32 ret = read(fd, data, len); if (ret != len) return -2; return 0; } u32 wbfs_disc_sector_used(wbfs_disc_t *d, u32 *num_blk) { if(!d) return 0; if (d->p == &wbfs_iso_file) { int fd = (int)d->header; //HMM? //int fd = d->i; struct stat st; if (fstat(fd, &st) == -1) return 0; if (num_blk) *num_blk = (st.st_size >> 9); // in 512 units return st.st_blocks; // in 512 units (can be sparse) } u32 last_blk = 0; u32 ret; ret = wbfs_sector_used2(d->p, d->header, &last_blk); if (num_blk) *num_blk = last_blk + 1; return ret; }