/* $NetBSD: udf.c,v 1.17 2015/06/16 23:04:14 christos Exp $ */ /* * Copyright (c) 2006, 2008, 2013 Reinoud Zandijk * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #if HAVE_NBTOOL_CONFIG_H #include "nbtool_config.h" #endif #include __RCSID("$NetBSD: udf.c,v 1.17 2015/06/16 23:04:14 christos Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include #include #if !HAVE_NBTOOL_CONFIG_H #define _EXPOSE_MMC #include #else #include "udf/cdio_mmc_structs.h" #endif #if !HAVE_NBTOOL_CONFIG_H #define HAVE_STRUCT_TM_TM_GMTOFF #endif #include "makefs.h" #include "udf_create.h" #include "udf_write.h" #include "newfs_udf.h" #undef APP_NAME #define APP_NAME "*NetBSD makefs" /* * Note: due to the setup of the newfs code, the current state of the program * and its options are helt in a few global variables. The FS specific parts * are in a global `context' structure. */ /* global variables describing disc and format requests */ int fd; /* device: file descriptor */ char *dev; /* device: name */ struct mmc_discinfo mmc_discinfo; /* device: disc info */ char *format_str; /* format: string representation */ int format_flags; /* format: attribute flags */ int media_accesstype; /* derived from current mmc cap */ int check_surface; /* for rewritables */ int imagefile_secsize; /* for files */ int display_progressbar; int wrtrack_skew; float meta_fract = (float) UDF_META_PERC / 100.0; int mmc_profile; /* emulated profile */ int req_enable, req_disable; /* --------------------------------------------------------------------- */ int udf_write_sector(void *sector, uint64_t location) { uint64_t wpos; ssize_t ret; wpos = (uint64_t) location * context.sector_size; ret = pwrite(fd, sector, context.sector_size, wpos); if (ret == -1) return errno; if (ret < (int) context.sector_size) return EIO; return 0; } /* not implemented for files */ int udf_surface_check(void) { return 0; } /* * mmc_discinfo and mmc_trackinfo readers modified from origional in udf main * code in sys/fs/udf/ */ #ifdef DEBUG static void udf_dump_discinfo(struct mmc_discinfo *di) { char bits[128]; printf("Device/media info :\n"); printf("\tMMC profile 0x%02x\n", di->mmc_profile); printf("\tderived class %d\n", di->mmc_class); printf("\tsector size %d\n", di->sector_size); printf("\tdisc state %d\n", di->disc_state); printf("\tlast ses state %d\n", di->last_session_state); printf("\tbg format state %d\n", di->bg_format_state); printf("\tfrst track %d\n", di->first_track); printf("\tfst on last ses %d\n", di->first_track_last_session); printf("\tlst on last ses %d\n", di->last_track_last_session); printf("\tlink block penalty %d\n", di->link_block_penalty); snprintb(bits, sizeof(bits), MMC_DFLAGS_FLAGBITS, (uint64_t) di->disc_flags); printf("\tdisc flags %s\n", bits); printf("\tdisc id %x\n", di->disc_id); printf("\tdisc barcode %"PRIx64"\n", di->disc_barcode); printf("\tnum sessions %d\n", di->num_sessions); printf("\tnum tracks %d\n", di->num_tracks); snprintb(bits, sizeof(bits), MMC_CAP_FLAGBITS, di->mmc_cur); printf("\tcapabilities cur %s\n", bits); snprintb(bits, sizeof(bits), MMC_CAP_FLAGBITS, di->mmc_cap); printf("\tcapabilities cap %s\n", bits); printf("\n"); printf("\tlast_possible_lba %d\n", di->last_possible_lba); printf("\n"); } #else #define udf_dump_discinfo(a); #endif /* --------------------------------------------------------------------- */ static int udf_emulate_discinfo(fsinfo_t *fsopts, struct mmc_discinfo *di, int mmc_emuprofile) { off_t sectors; memset(di, 0, sizeof(*di)); /* file support */ if ((mmc_emuprofile != 0x01) && (fsopts->sectorsize != 2048)) warnx("cd/dvd/bd sectorsize is not set to default 2048"); sectors = fsopts->size / fsopts->sectorsize; /* commons */ di->mmc_profile = mmc_emuprofile; di->disc_state = MMC_STATE_CLOSED; di->last_session_state = MMC_STATE_CLOSED; di->bg_format_state = MMC_BGFSTATE_COMPLETED; di->link_block_penalty = 0; di->disc_flags = MMC_DFLAGS_UNRESTRICTED; di->last_possible_lba = sectors - 1; di->sector_size = fsopts->sectorsize; di->num_sessions = 1; di->num_tracks = 1; di->first_track = 1; di->first_track_last_session = di->last_track_last_session = 1; di->mmc_cur = MMC_CAP_RECORDABLE | MMC_CAP_ZEROLINKBLK; switch (mmc_emuprofile) { case 0x00: /* unknown, treat as CDROM */ case 0x08: /* CDROM */ case 0x10: /* DVDROM */ case 0x40: /* BDROM */ req_enable |= FORMAT_READONLY; /* FALLTROUGH */ case 0x01: /* disc */ /* set up a disc info profile for partitions/files */ di->mmc_class = MMC_CLASS_DISC; di->mmc_cur |= MMC_CAP_REWRITABLE | MMC_CAP_HW_DEFECTFREE; break; case 0x09: /* CD-R */ di->mmc_class = MMC_CLASS_CD; di->mmc_cur |= MMC_CAP_SEQUENTIAL; di->disc_state = MMC_STATE_EMPTY; break; case 0x0a: /* CD-RW + CD-MRW (regretably) */ di->mmc_class = MMC_CLASS_CD; di->mmc_cur |= MMC_CAP_REWRITABLE; break; case 0x13: /* DVD-RW */ di->mmc_class = MMC_CLASS_DVD; di->mmc_cur |= MMC_CAP_REWRITABLE; break; case 0x11: /* DVD-R */ case 0x14: /* DVD-RW sequential */ case 0x1b: /* DVD+R */ case 0x2b: /* DVD+R DL */ case 0x51: /* HD DVD-R */ di->mmc_class = MMC_CLASS_DVD; di->mmc_cur |= MMC_CAP_SEQUENTIAL; di->disc_state = MMC_STATE_EMPTY; break; case 0x41: /* BD-R */ di->mmc_class = MMC_CLASS_BD; di->mmc_cur |= MMC_CAP_SEQUENTIAL | MMC_CAP_HW_DEFECTFREE; di->disc_state = MMC_STATE_EMPTY; break; case 0x43: /* BD-RE */ di->mmc_class = MMC_CLASS_BD; di->mmc_cur |= MMC_CAP_REWRITABLE | MMC_CAP_HW_DEFECTFREE; break; default: err(EINVAL, "makefs_udf: unknown or unimplemented device type"); return EINVAL; } di->mmc_cap = di->mmc_cur; udf_dump_discinfo(di); return 0; } int udf_update_trackinfo(struct mmc_discinfo *di, struct mmc_trackinfo *ti) { /* discs partition support */ if (ti->tracknr != 1) return EIO; /* create fake ti */ ti->sessionnr = 1; ti->track_mode = 0; /* XXX */ ti->data_mode = 0; /* XXX */ ti->flags = MMC_TRACKINFO_LRA_VALID | MMC_TRACKINFO_NWA_VALID; ti->track_start = 0; ti->packet_size = 32; /* take sensible default */ ti->track_size = di->last_possible_lba; ti->next_writable = di->last_possible_lba; ti->last_recorded = ti->next_writable; ti->free_blocks = 0; return 0; } #define OPT_STR(letter, name, desc) \ { letter, name, NULL, OPT_STRBUF, 0, 0, desc } #define OPT_NUM(letter, name, field, min, max, desc) \ { letter, name, &context.field, \ sizeof(context.field) == 8 ? OPT_INT64 : \ (sizeof(context.field) == 4 ? OPT_INT32 : \ (sizeof(context.field) == 2 ? OPT_INT16 : OPT_INT8)), \ min, max, desc } #define OPT_BOOL(letter, name, field, desc) \ OPT_NUM(letter, name, field, 0, 1, desc) void udf_prep_opts(fsinfo_t *fsopts) { struct tm *tm; time_t now; const option_t udf_options[] = { OPT_STR('T', "disctype", "disc type (cdrom,dvdrom,bdrom," "dvdram,bdre,disk,cdr,dvdr,bdr,cdrw,dvdrw)"), OPT_STR('L', "loglabel", "\"logical volume name\""), OPT_STR('P', "discid", "\"[volset name ':']" "physical volume name\""), OPT_NUM('t', "tz", gmtoff, -24, 24, "timezone"), OPT_STR('v', "minver", "minimum UDF version in either " "``0x201'' or ``2.01'' format"), #if notyet OPT_STR('V', "maxver", "maximum UDF version in either " "``0x201'' or ``2.01'' format"), #endif { .name = NULL } }; /* initialise */ format_str = strdup(""); req_enable = req_disable = 0; format_flags = FORMAT_INVALID; fsopts->sectorsize = 512; /* minimum allowed sector size */ srandom((unsigned long) time(NULL)); mmc_profile = 0x01; /* 'disc'/file */ udf_init_create_context(); context.app_name = "*NetBSD makefs"; context.app_version_main = APP_VERSION_MAIN; context.app_version_sub = APP_VERSION_SUB; context.impl_name = IMPL_NAME; /* minimum and maximum UDF versions we advise */ context.min_udf = 0x102; context.max_udf = 0x201; /* 0x250 and 0x260 are not ready */ /* use user's time zone as default */ (void)time(&now); tm = localtime(&now); #ifdef HAVE_STRUCT_TM_TM_GMTOFF context.gmtoff = tm->tm_gmtoff; #else context.gmtoff = 0; #endif /* return info */ fsopts->fs_specific = NULL; fsopts->fs_options = copy_opts(udf_options); } void udf_cleanup_opts(fsinfo_t *fsopts) { free(fsopts->fs_options); } /* ----- included from newfs_udf.c ------ */ /* ----- */ #define CDRSIZE ((uint64_t) 700*1024*1024) /* small approx */ #define CDRWSIZE ((uint64_t) 576*1024*1024) /* small approx */ #define DVDRSIZE ((uint64_t) 4488*1024*1024) /* small approx */ #define DVDRAMSIZE ((uint64_t) 4330*1024*1024) /* small approx with spare */ #define DVDRWSIZE ((uint64_t) 4482*1024*1024) /* small approx */ #define BDRSIZE ((uint64_t) 23866*1024*1024) /* small approx */ #define BDRESIZE ((uint64_t) 23098*1024*1024) /* small approx */ int udf_parse_opts(const char *option, fsinfo_t *fsopts) { option_t *udf_options = fsopts->fs_options; uint64_t stdsize; uint32_t set_sectorsize; char buffer[1024], *buf, *colon; int i; assert(option != NULL); if (debug & DEBUG_FS_PARSE_OPTS) printf("udf_parse_opts: got `%s'\n", option); i = set_option(udf_options, option, buffer, sizeof(buffer)); if (i == -1) return 0; if (udf_options[i].name == NULL) abort(); set_sectorsize = 0; stdsize = 0; buf = buffer; switch (udf_options[i].letter) { case 'T': if (strcmp(buf, "cdrom") == 0) { mmc_profile = 0x00; } else if (strcmp(buf, "dvdrom") == 0) { mmc_profile = 0x10; } else if (strcmp(buf, "bdrom") == 0) { mmc_profile = 0x40; } else if (strcmp(buf, "dvdram") == 0) { mmc_profile = 0x12; stdsize = DVDRAMSIZE; } else if (strcmp(buf, "bdre") == 0) { mmc_profile = 0x43; stdsize = BDRESIZE; } else if (strcmp(buf, "disk") == 0) { mmc_profile = 0x01; } else if (strcmp(buf, "cdr") == 0) { mmc_profile = 0x09; stdsize = CDRSIZE; } else if (strcmp(buf, "dvdr") == 0) { mmc_profile = 0x1b; stdsize = DVDRSIZE; } else if (strcmp(buf, "bdr") == 0) { mmc_profile = 0x41; stdsize = BDRSIZE; } else if (strcmp(buf, "cdrw") == 0) { mmc_profile = 0x0a; stdsize = CDRWSIZE; } else if (strcmp(buf, "dvdrw") == 0) { mmc_profile = 0x13; stdsize = DVDRWSIZE; } else { errx(EINVAL, "Unknown or unimplemented disc format"); return 0; } if (mmc_profile != 0x01) set_sectorsize = 2048; break; case 'L': if (context.logvol_name) free(context.logvol_name); context.logvol_name = strdup(buf); break; case 'P': if ((colon = strstr(buf, ":"))) { if (context.volset_name) free(context.volset_name); *colon = 0; context.volset_name = strdup(buf); buf = colon+1; } if (context.primary_name) free(context.primary_name); if ((strstr(buf, ":"))) { errx(EINVAL, "primary name can't have ':' in its name"); return 0; } context.primary_name = strdup(buf); break; case 'v': context.min_udf = a_udf_version(buf, "min_udf"); if (context.min_udf > 0x201) { errx(EINVAL, "maximum supported version is UDF 2.01"); return 0; } if (context.min_udf > context.max_udf) context.max_udf = context.min_udf; break; } if (set_sectorsize) fsopts->sectorsize = set_sectorsize; if (stdsize) fsopts->size = stdsize; return 1; } /* --------------------------------------------------------------------- */ struct udf_stats { uint32_t nfiles; uint32_t ndirs; uint32_t ndescr; uint32_t nmetadatablocks; uint32_t ndatablocks; }; /* node reference administration */ static void udf_inc_link(union dscrptr *dscr) { struct file_entry *fe; struct extfile_entry *efe; if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { fe = &dscr->fe; fe->link_cnt = udf_rw16(udf_rw16(fe->link_cnt) + 1); } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { efe = &dscr->efe; efe->link_cnt = udf_rw16(udf_rw16(efe->link_cnt) + 1); } else { errx(1, "Bad tag passed to udf_inc_link"); } } static void udf_set_link_cnt(union dscrptr *dscr, int num) { struct file_entry *fe; struct extfile_entry *efe; if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { fe = &dscr->fe; fe->link_cnt = udf_rw16(num); } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { efe = &dscr->efe; efe->link_cnt = udf_rw16(num); } else { errx(1, "Bad tag passed to udf_set_link_cnt"); } } static uint32_t udf_datablocks(off_t sz) { /* predictor if it can be written inside the node */ if (sz < context.sector_size - UDF_EXTFENTRY_SIZE - 16) return 0; return UDF_ROUNDUP(sz, context.sector_size) / context.sector_size; } static void udf_prepare_fids(struct long_ad *dir_icb, struct long_ad *dirdata_icb, uint8_t *dirdata, uint32_t dirdata_size) { struct fileid_desc *fid; struct long_ad *icb; uint32_t fidsize, offset; uint32_t location; if (udf_datablocks(dirdata_size) == 0) { /* going internal */ icb = dir_icb; } else { /* external blocks to write to */ icb = dirdata_icb; } for (offset = 0; offset < dirdata_size; offset += fidsize) { /* for each FID: */ fid = (struct fileid_desc *) (dirdata + offset); assert(udf_rw16(fid->tag.id) == TAGID_FID); location = udf_rw32(icb->loc.lb_num); location += offset / context.sector_size; fid->tag.tag_loc = udf_rw32(location); udf_validate_tag_and_crc_sums((union dscrptr *) fid); fidsize = udf_fidsize(fid); } } static int udf_file_inject_blob(union dscrptr *dscr, uint8_t *blob, off_t size) { struct icb_tag *icb; struct file_entry *fe; struct extfile_entry *efe; uint64_t inf_len, obj_size; uint32_t l_ea, l_ad; uint32_t free_space, desc_size; uint16_t crclen; uint8_t *data, *pos; fe = NULL; efe = NULL; if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { fe = &dscr->fe; data = fe->data; l_ea = udf_rw32(fe->l_ea); l_ad = udf_rw32(fe->l_ad); icb = &fe->icbtag; inf_len = udf_rw64(fe->inf_len); obj_size = 0; desc_size = sizeof(struct file_entry); } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { efe = &dscr->efe; data = efe->data; l_ea = udf_rw32(efe->l_ea); l_ad = udf_rw32(efe->l_ad); icb = &efe->icbtag; inf_len = udf_rw64(efe->inf_len); obj_size = udf_rw64(efe->obj_size); desc_size = sizeof(struct extfile_entry); } else { errx(1, "Bad tag passed to udf_file_inject_blob"); } crclen = udf_rw16(dscr->tag.desc_crc_len); /* calculate free space */ free_space = context.sector_size - (l_ea + l_ad) - desc_size; if (udf_datablocks(size)) { assert(free_space < size); return 1; } /* going internal */ assert(l_ad == 0); assert((udf_rw16(icb->flags) & UDF_ICB_TAG_FLAGS_ALLOC_MASK) == UDF_ICB_INTERN_ALLOC); // assert(free_space >= size); pos = data + l_ea + l_ad; memcpy(pos, blob, size); l_ad += size; crclen += size; inf_len += size; obj_size += size; if (fe) { fe->l_ad = udf_rw32(l_ad); fe->inf_len = udf_rw64(inf_len); } else if (efe) { efe->l_ad = udf_rw32(l_ad); efe->inf_len = udf_rw64(inf_len); efe->obj_size = udf_rw64(inf_len); } /* make sure the header sums stays correct */ dscr->tag.desc_crc_len = udf_rw16(crclen); udf_validate_tag_and_crc_sums(dscr); return 0; } /* XXX no sparse file support */ static void udf_append_file_mapping(union dscrptr *dscr, struct long_ad *piece) { struct icb_tag *icb; struct file_entry *fe; struct extfile_entry *efe; struct long_ad *last_long, last_piece; struct short_ad *last_short, new_short; uint64_t inf_len, obj_size, logblks_rec; uint32_t l_ea, l_ad, size; uint32_t last_lb_num, piece_lb_num; uint64_t last_len, piece_len, last_flags; uint64_t rest_len, merge_len, last_end; uint16_t last_part_num, piece_part_num; uint16_t crclen, cur_alloc; uint8_t *data, *pos; const int short_len = sizeof(struct short_ad); const int long_len = sizeof(struct long_ad); const int sector_size = context.sector_size; const int use_shorts = (context.data_part == context.metadata_part); uint64_t max_len = UDF_ROUNDDOWN(UDF_EXT_MAXLEN, sector_size); fe = NULL; efe = NULL; if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { fe = &dscr->fe; data = fe->data; l_ea = fe->l_ea; l_ad = udf_rw32(fe->l_ad); icb = &fe->icbtag; inf_len = udf_rw64(fe->inf_len); logblks_rec = udf_rw64(fe->logblks_rec); obj_size = 0; } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { efe = &dscr->efe; data = efe->data; l_ea = efe->l_ea; l_ad = udf_rw32(efe->l_ad); icb = &efe->icbtag; inf_len = udf_rw64(efe->inf_len); obj_size = udf_rw64(efe->obj_size); logblks_rec = udf_rw64(efe->logblks_rec); } else { errx(1, "Bad tag passed to udf_file_append_blob"); } crclen = udf_rw16(dscr->tag.desc_crc_len); pos = data + l_ea; cur_alloc = udf_rw16(icb->flags); size = UDF_EXT_LEN(udf_rw32(piece->len)); /* extract last entry as a long_ad */ memset(&last_piece, 0, sizeof(last_piece)); last_len = 0; last_lb_num = 0; last_part_num = 0; last_flags = 0; last_short = NULL; last_long = NULL; if (l_ad != 0) { if (use_shorts) { assert(cur_alloc == UDF_ICB_SHORT_ALLOC); pos += l_ad - short_len; last_short = (struct short_ad *) pos; last_lb_num = udf_rw32(last_short->lb_num); last_part_num = udf_rw16(piece->loc.part_num); last_len = UDF_EXT_LEN(udf_rw32(last_short->len)); last_flags = UDF_EXT_FLAGS(udf_rw32(last_short->len)); } else { assert(cur_alloc == UDF_ICB_LONG_ALLOC); pos += l_ad - long_len; last_long = (struct long_ad *) pos; last_lb_num = udf_rw32(last_long->loc.lb_num); last_part_num = udf_rw16(last_long->loc.part_num); last_len = UDF_EXT_LEN(udf_rw32(last_long->len)); last_flags = UDF_EXT_FLAGS(udf_rw32(last_long->len)); } } piece_len = UDF_EXT_LEN(udf_rw32(piece->len)); piece_lb_num = udf_rw32(piece->loc.lb_num); piece_part_num = udf_rw16(piece->loc.part_num); /* try merging */ rest_len = max_len - last_len; merge_len = MIN(piece_len, rest_len); last_end = last_lb_num + (last_len / sector_size); if ((piece_lb_num == last_end) && (last_part_num == piece_part_num)) { /* we can merge */ last_len += merge_len; piece_len -= merge_len; /* write back merge result */ if (use_shorts) { last_short->len = udf_rw32(last_len | last_flags); } else { last_long->len = udf_rw32(last_len | last_flags); } piece_lb_num += merge_len / sector_size; } if (piece_len) { /* append new entry */ pos = data + l_ea + l_ad; if (use_shorts) { icb->flags = udf_rw16(UDF_ICB_SHORT_ALLOC); memset(&new_short, 0, short_len); new_short.len = udf_rw32(piece_len); new_short.lb_num = udf_rw32(piece_lb_num); memcpy(pos, &new_short, short_len); l_ad += short_len; crclen += short_len; } else { icb->flags = udf_rw16(UDF_ICB_LONG_ALLOC); piece->len = udf_rw32(piece_len); piece->loc.lb_num = udf_rw32(piece_lb_num); memcpy(pos, piece, long_len); l_ad += long_len; crclen += long_len; } } piece->len = udf_rw32(0); inf_len += size; obj_size += size; logblks_rec += UDF_ROUNDUP(size, sector_size) / sector_size; dscr->tag.desc_crc_len = udf_rw16(crclen); if (udf_rw16(dscr->tag.id) == TAGID_FENTRY) { fe->l_ad = udf_rw32(l_ad); fe->inf_len = udf_rw64(inf_len); fe->logblks_rec = udf_rw64(logblks_rec); } else if (udf_rw16(dscr->tag.id) == TAGID_EXTFENTRY) { efe->l_ad = udf_rw32(l_ad); efe->inf_len = udf_rw64(inf_len); efe->obj_size = udf_rw64(inf_len); efe->logblks_rec = udf_rw64(logblks_rec); } } static int udf_append_file_contents(union dscrptr *dscr, struct long_ad *data_icb, uint8_t *fdata, off_t flen) { struct long_ad icb; uint32_t location; uint64_t phys; uint16_t vpart; uint8_t *bpos; int cnt, sects; int error; if (udf_file_inject_blob(dscr, fdata, flen) == 0) return 0; /* has to be appended in mappings */ icb = *data_icb; icb.len = udf_rw32(flen); while (udf_rw32(icb.len) > 0) udf_append_file_mapping(dscr, &icb); udf_validate_tag_and_crc_sums(dscr); /* write out data piece */ vpart = udf_rw16(data_icb->loc.part_num); location = udf_rw32(data_icb->loc.lb_num); sects = udf_datablocks(flen); for (cnt = 0; cnt < sects; cnt++) { bpos = fdata + cnt*context.sector_size; phys = context.vtop_offset[vpart] + location + cnt; error = udf_write_sector(bpos, phys); if (error) return error; } return 0; } static int udf_create_new_file(struct stat *st, union dscrptr **dscr, int filetype, struct long_ad *icb) { struct file_entry *fe; struct extfile_entry *efe; int error; fe = NULL; efe = NULL; if (context.dscrver == 2) { error = udf_create_new_fe(&fe, filetype, st); if (error) errx(error, "can't create fe"); *dscr = (union dscrptr *) fe; icb->longad_uniqueid = fe->unique_id; } else { error = udf_create_new_efe(&efe, filetype, st); if (error) errx(error, "can't create fe"); *dscr = (union dscrptr *) efe; icb->longad_uniqueid = efe->unique_id; } return 0; } static void udf_estimate_walk(fsinfo_t *fsopts, fsnode *root, char *dir, struct udf_stats *stats) { struct fileid_desc *fid; struct long_ad dummy_ref; fsnode *cur; fsinode *fnode; size_t pathlen = strlen(dir); char *mydir = dir + pathlen; off_t sz; uint32_t nblk, ddoff; uint32_t softlink_len; uint8_t *softlink_buf; int nentries; int error; stats->ndirs++; /* * Count number of directory entries and count directory size; needed * for the reservation of enough space for the directory. Pity we * don't keep the FIDs we created. If it turns out to be a issue we * can cache it later. */ fid = (struct fileid_desc *) malloc(context.sector_size); assert(fid); ddoff = 40; /* '..' entry */ for (cur = root, nentries = 0; cur != NULL; cur = cur->next) { switch (cur->type & S_IFMT) { default: /* what kind of nodes? */ break; case S_IFCHR: case S_IFBLK: /* not supported yet */ continue; case S_IFDIR: if (strcmp(cur->name, ".") == 0) continue; case S_IFLNK: case S_IFREG: /* create dummy FID to see how long name will become */ memset(&dummy_ref, 0, sizeof(dummy_ref)); udf_create_fid(ddoff, fid, cur->name, 0, &dummy_ref); nentries++; ddoff += udf_fidsize(fid); } } sz = ddoff; root->inode->st.st_size = sz; /* max now */ root->inode->flags |= FI_SIZED; nblk = udf_datablocks(sz); stats->nmetadatablocks += nblk; /* for each entry in the directory, there needs to be a (E)FE */ stats->nmetadatablocks += nentries + 1; /* recurse */ for (cur = root; cur != NULL; cur = cur->next) { switch (cur->type & S_IFMT) { default: /* what kind of nodes? */ break; case S_IFCHR: case S_IFBLK: /* not supported yet */ // stats->nfiles++; break; case S_IFDIR: if (strcmp(cur->name, ".") == 0) continue; /* empty dir? */ if (!cur->child) break; mydir[0] = '/'; strncpy(&mydir[1], cur->name, MAXPATHLEN - pathlen); udf_estimate_walk(fsopts, cur->child, dir, stats); mydir[0] = '\0'; break; case S_IFREG: fnode = cur->inode; /* don't double-count hard-links */ if (!(fnode->flags & FI_SIZED)) { sz = fnode->st.st_size; nblk = udf_datablocks(sz); stats->ndatablocks += nblk; /* ... */ fnode->flags |= FI_SIZED; } stats->nfiles++; break; case S_IFLNK: /* softlink */ fnode = cur->inode; /* don't double-count hard-links */ if (!(fnode->flags & FI_SIZED)) { error = udf_encode_symlink(&softlink_buf, &softlink_len, cur->symlink); if (error) { printf("SOFTLINK error %d\n", error); break; } nblk = udf_datablocks(softlink_len); stats->ndatablocks += nblk; fnode->flags |= FI_SIZED; free(softlink_buf); } stats->nfiles++; break; } } } #define UDF_MAX_CHUNK_SIZE (4*1024*1024) static int udf_copy_file(struct stat *st, char *path, fsnode *cur, struct fileid_desc *fid, struct long_ad *icb) { union dscrptr *dscr; struct long_ad data_icb; fsinode *fnode; off_t sz, chunk, rd; uint8_t *data; int nblk; int i, f; int error; fnode = cur->inode; f = open(path, O_RDONLY); if (f < 0) { warn("Can't open file %s for reading", cur->name); return errno; } /* claim disc space for the (e)fe descriptor for this file */ udf_metadata_alloc(1, icb); udf_create_new_file(st, &dscr, UDF_ICB_FILETYPE_RANDOMACCESS, icb); sz = fnode->st.st_size; chunk = MIN(sz, UDF_MAX_CHUNK_SIZE); data = malloc(MAX(chunk, context.sector_size)); assert(data); printf(" "); i = 0; error = 0; while (chunk) { rd = read(f, data, chunk); if (rd != chunk) { warn("Short read of file %s", cur->name); error = errno; break; } printf("\b%c", "\\|/-"[i++ % 4]); fflush(stdout);fflush(stderr); nblk = udf_datablocks(chunk); if (nblk > 0) udf_data_alloc(nblk, &data_icb); udf_append_file_contents(dscr, &data_icb, data, chunk); sz -= chunk; chunk = MIN(sz, UDF_MAX_CHUNK_SIZE); } printf("\b \n"); close(f); free(data); /* write out dscr (e)fe */ udf_set_link_cnt(dscr, fnode->nlink); udf_write_dscr_virt(dscr, udf_rw32(icb->loc.lb_num), udf_rw16(icb->loc.part_num), 1); free(dscr); /* remember our location for hardlinks */ cur->inode->fsuse = malloc(sizeof(struct long_ad)); memcpy(cur->inode->fsuse, icb, sizeof(struct long_ad)); return error; } static int udf_populate_walk(fsinfo_t *fsopts, fsnode *root, char *dir, struct long_ad *parent_icb, struct long_ad *dir_icb) { union dscrptr *dir_dscr, *dscr; struct fileid_desc *fid; struct long_ad icb, data_icb, dirdata_icb; fsnode *cur; fsinode *fnode; size_t pathlen = strlen(dir); size_t dirlen; char *mydir = dir + pathlen; uint32_t nblk, ddoff; uint32_t softlink_len; uint8_t *softlink_buf; uint8_t *dirdata; int error, ret, retval; /* claim disc space for the (e)fe descriptor for this dir */ udf_metadata_alloc(1, dir_icb); /* create new e(fe) */ udf_create_new_file(&root->inode->st, &dir_dscr, UDF_ICB_FILETYPE_DIRECTORY, dir_icb); /* claim space for the directory contents */ dirlen = root->inode->st.st_size; nblk = udf_datablocks(dirlen); if (nblk > 0) { /* claim disc space for the dir contents */ udf_data_alloc(nblk, &dirdata_icb); } /* allocate memory for the directory contents */ nblk++; dirdata = malloc(nblk * context.sector_size); assert(dirdata); memset(dirdata, 0, nblk * context.sector_size); /* create and append '..' */ fid = (struct fileid_desc *) dirdata; ddoff = udf_create_parentfid(fid, parent_icb); /* for '..' */ udf_inc_link(dir_dscr); /* recurse */ retval = 0; for (cur = root; cur != NULL; cur = cur->next) { mydir[0] = '/'; strncpy(&mydir[1], cur->name, MAXPATHLEN - pathlen); fid = (struct fileid_desc *) (dirdata + ddoff); switch (cur->type & S_IFMT) { default: /* what kind of nodes? */ retval = 2; break; case S_IFCHR: case S_IFBLK: /* not supported */ retval = 2; warnx("device node %s not supported", dir); break; case S_IFDIR: /* not an empty dir? */ if (strcmp(cur->name, ".") == 0) break; assert(cur->child); if (cur->child) { ret = udf_populate_walk(fsopts, cur->child, dir, dir_icb, &icb); if (ret) retval = 2; } udf_create_fid(ddoff, fid, cur->name, UDF_FILE_CHAR_DIR, &icb); udf_inc_link(dir_dscr); ddoff += udf_fidsize(fid); break; case S_IFREG: fnode = cur->inode; /* don't re-copy hard-links */ if (!(fnode->flags & FI_WRITTEN)) { printf("%s", dir); error = udf_copy_file(&fnode->st, dir, cur, fid, &icb); if (!error) { fnode->flags |= FI_WRITTEN; udf_create_fid(ddoff, fid, cur->name, 0, &icb); ddoff += udf_fidsize(fid); } else { retval = 2; } } else { /* hardlink! */ printf("%s (hardlink)\n", dir); udf_create_fid(ddoff, fid, cur->name, 0, (struct long_ad *) (fnode->fsuse)); ddoff += udf_fidsize(fid); } fnode->nlink--; if (fnode->nlink == 0) free(fnode->fsuse); break; case S_IFLNK: /* softlink */ fnode = cur->inode; printf("%s -> %s\n", dir, cur->symlink); error = udf_encode_symlink(&softlink_buf, &softlink_len, cur->symlink); if (error) { printf("SOFTLINK error %d\n", error); retval = 2; break; } udf_metadata_alloc(1, &icb); udf_create_new_file(&fnode->st, &dscr, UDF_ICB_FILETYPE_SYMLINK, &icb); nblk = udf_datablocks(softlink_len); if (nblk > 0) udf_data_alloc(nblk, &data_icb); udf_append_file_contents(dscr, &data_icb, softlink_buf, softlink_len); /* write out dscr (e)fe */ udf_inc_link(dscr); udf_write_dscr_virt(dscr, udf_rw32(icb.loc.lb_num), udf_rw16(icb.loc.part_num), 1); free(dscr); free(softlink_buf); udf_create_fid(ddoff, fid, cur->name, 0, &icb); ddoff += udf_fidsize(fid); break; } mydir[0] = '\0'; } /* writeout directory contents */ dirlen = ddoff; /* XXX might bite back */ udf_prepare_fids(dir_icb, &dirdata_icb, dirdata, dirlen); udf_append_file_contents(dir_dscr, &dirdata_icb, dirdata, dirlen); /* write out dir_dscr (e)fe */ udf_write_dscr_virt(dir_dscr, udf_rw32(dir_icb->loc.lb_num), udf_rw16(dir_icb->loc.part_num), 1); free(dirdata); free(dir_dscr); return retval; } static int udf_populate(const char *dir, fsnode *root, fsinfo_t *fsopts, struct udf_stats *stats) { struct long_ad rooticb; static char path[MAXPATHLEN+1]; int error; /* make sure the root gets the rootdir entry */ context.metadata_alloc_pos = layout.rootdir; context.data_alloc_pos = layout.rootdir; strncpy(path, dir, sizeof(path)); error = udf_populate_walk(fsopts, root, path, &rooticb, &rooticb); return error; } static void udf_enumerate_and_estimate(const char *dir, fsnode *root, fsinfo_t *fsopts, struct udf_stats *stats) { char path[MAXPATHLEN + 1]; off_t proposed_size; uint32_t n, nblk; strncpy(path, dir, sizeof(path)); /* calculate strict minimal size */ udf_estimate_walk(fsopts, root, path, stats); printf("ndirs %d\n", stats->ndirs); printf("nfiles %d\n", stats->nfiles); printf("ndata_blocks %d\n", stats->ndatablocks); printf("nmetadata_blocks %d\n", stats->nmetadatablocks); printf("\n"); /* adjust for options : free file nodes */ if (fsopts->freefiles) { /* be mercifull and reserve more for the FID */ stats->nmetadatablocks += fsopts->freefiles * 1.5; } else if ((n = fsopts->freefilepc)) { stats->nmetadatablocks += (stats->nmetadatablocks*n) / (100-n); } /* adjust for options : free data blocks */ if (fsopts->freeblocks) { stats->ndatablocks += fsopts->freeblocks; } else if ((n = fsopts->freeblockpc)) { stats->ndatablocks += (stats->ndatablocks * n) / (100-n); } /* rough predictor of minimum disc size */ nblk = stats->ndatablocks + stats->nmetadatablocks; nblk = (double) nblk * (1.0 + 1.0/8.0); /* free space map */ nblk += 256; /* pre-volume space */ nblk += 256; /* post-volume space */ nblk += 64; /* safeguard */ /* try to honour minimum size */ n = fsopts->minsize / fsopts->sectorsize; if (nblk < n) { stats->ndatablocks += (n - nblk); nblk += n - nblk; } proposed_size = (off_t) nblk * fsopts->sectorsize; /* sanity size */ if (proposed_size < 512*1024) proposed_size = 512*1024; if (fsopts->size) { if (fsopts->size < proposed_size) err(EINVAL, "makefs_udf: won't fit on disc!"); } else { fsopts->size = proposed_size; } fsopts->inodes = stats->nfiles + stats->ndirs; } void udf_makefs(const char *image, const char *dir, fsnode *root, fsinfo_t *fsopts) { struct udf_stats stats; uint64_t truncate_len; char scrap[255]; int error; /* determine format */ udf_emulate_discinfo(fsopts, &mmc_discinfo, mmc_profile); printf("req_enable %d, req_disable %d\n", req_enable, req_disable); context.sector_size = fsopts->sectorsize; error = udf_derive_format(req_enable, req_disable, false); if (error) err(EINVAL, "makefs_udf: can't determine format"); /* names */ error = udf_proces_names(); if (error) err(EINVAL, "makefs_udf: bad names given"); /* set return value to 1 indicating error */ error = 1; /* estimate the amount of space needed */ memset(&stats, 0, sizeof(stats)); udf_enumerate_and_estimate(dir, root, fsopts, &stats); printf("Calculated size of `%s': %lld bytes, %ld inodes\n", image, (long long)fsopts->size, (long)fsopts->inodes); /* create file image */ if ((fd = open(image, O_RDWR | O_CREAT | O_TRUNC, 0666)) == -1) { err(EXIT_FAILURE, "%s", image); } if (lseek(fd, fsopts->size - 1, SEEK_SET) == -1) { goto err_exit; } if (write(fd, &fd, 1) != 1) { goto err_exit; } if (lseek(fd, 0, SEEK_SET) == -1) { goto err_exit; } fsopts->fd = fd; /* calculate metadata percentage */ meta_fract = fsopts->size / (stats.nmetadatablocks*fsopts->sectorsize); meta_fract = ((int) ((meta_fract + 0.005)*100.0)) / 100; /* update mmc info but now with correct size */ udf_emulate_discinfo(fsopts, &mmc_discinfo, mmc_profile); printf("Building disc compatible with UDF version %x to %x\n\n", context.min_udf, context.max_udf); (void)snprintb(scrap, sizeof(scrap), FORMAT_FLAGBITS, (uint64_t) format_flags); printf("UDF properties %s\n", scrap); printf("Volume set `%s'\n", context.volset_name); printf("Primary volume `%s`\n", context.primary_name); printf("Logical volume `%s`\n", context.logvol_name); if (format_flags & FORMAT_META) printf("Metadata percentage %d %%\n", (int) (100.0*stats.ndatablocks/stats.nmetadatablocks)); printf("\n"); udf_do_newfs_prefix(); /* update context */ context.unique_id = 0; /* XXX are the next two needed? or should be re-count them? */ context.num_files = stats.nfiles; context.num_directories = stats.ndirs; error = udf_populate(dir, root, fsopts, &stats); udf_do_newfs_postfix(); if (format_flags & FORMAT_VAT) { truncate_len = context.vtop_offset[context.data_part] + context.data_alloc_pos; truncate_len *= context.sector_size; printf("\nTruncing the disc-image to allow for VAT\n"); printf("Free space left on this volume approx. " "%"PRIu64" KiB, %"PRIu64" MiB\n", (fsopts->size - truncate_len)/1024, (fsopts->size - truncate_len)/1024/1024); ftruncate(fd, truncate_len); } if (error) { error = 2; /* some files couldn't be added */ goto err_exit; } close(fd); return; err_exit: close(fd); if (error == 2) { errx(error, "Not all files could be added"); } else { errx(error, "creation of %s failed", image); } }