Current Path : /usr/src/usr.sbin/makefs/cd9660/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/usr.sbin/makefs/cd9660/cd9660_write.c |
/* $NetBSD: cd9660_write.c,v 1.14 2011/01/04 09:48:21 wiz Exp $ */ /* * Copyright (c) 2005 Daniel Watt, Walter Deignan, Ryan Gabrys, Alan * Perez-Rathke and Ram Vedam. All rights reserved. * * This code was written by Daniel Watt, Walter Deignan, Ryan Gabrys, * Alan Perez-Rathke and Ram Vedam. * * 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 DANIEL WATT, WALTER DEIGNAN, RYAN * GABRYS, ALAN PEREZ-RATHKE AND RAM VEDAM ``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 DANIEL WATT, WALTER DEIGNAN, RYAN * GABRYS, ALAN PEREZ-RATHKE AND RAM VEDAM 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. */ #include "cd9660.h" #include "iso9660_rrip.h" #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/usr.sbin/makefs/cd9660/cd9660_write.c 231942 2012-02-20 18:49:11Z jkim $"); static int cd9660_write_volume_descriptors(FILE *); static int cd9660_write_path_table(FILE *, off_t, int); static int cd9660_write_path_tables(FILE *); static int cd9660_write_file(FILE *, cd9660node *); static int cd9660_write_filedata(FILE *, off_t, const unsigned char *, int); #if 0 static int cd9660_write_buffered(FILE *, off_t, int, const unsigned char *); #endif static void cd9660_write_rr(FILE *, cd9660node *, off_t, off_t); /* * Write the image * Writes the entire image * @param const char* The filename for the image * @returns int 1 on success, 0 on failure */ int cd9660_write_image(const char* image) { FILE *fd; int status; char buf[CD9660_SECTOR_SIZE]; if ((fd = fopen(image, "w+")) == NULL) { err(EXIT_FAILURE, "%s: Can't open `%s' for writing", __func__, image); } if (diskStructure.verbose_level > 0) printf("Writing image\n"); if (diskStructure.has_generic_bootimage) { status = cd9660_copy_file(fd, 0, diskStructure.generic_bootimage); if (status == 0) { warnx("%s: Error writing generic boot image", __func__); goto cleanup_bad_image; } } /* Write the volume descriptors */ status = cd9660_write_volume_descriptors(fd); if (status == 0) { warnx("%s: Error writing volume descriptors to image", __func__); goto cleanup_bad_image; } if (diskStructure.verbose_level > 0) printf("Volume descriptors written\n"); /* * Write the path tables: there are actually four, but right * now we are only concearned with two. */ status = cd9660_write_path_tables(fd); if (status == 0) { warnx("%s: Error writing path tables to image", __func__); goto cleanup_bad_image; } if (diskStructure.verbose_level > 0) printf("Path tables written\n"); /* Write the directories and files */ status = cd9660_write_file(fd, diskStructure.rootNode); if (status == 0) { warnx("%s: Error writing files to image", __func__); goto cleanup_bad_image; } if (diskStructure.is_bootable) { cd9660_write_boot(fd); } /* Write padding bits. This is temporary */ memset(buf, 0, CD9660_SECTOR_SIZE); cd9660_write_filedata(fd, diskStructure.totalSectors - 1, buf, 1); if (diskStructure.verbose_level > 0) printf("Files written\n"); fclose(fd); if (diskStructure.verbose_level > 0) printf("Image closed\n"); return 1; cleanup_bad_image: fclose(fd); if (!diskStructure.keep_bad_images) unlink(image); if (diskStructure.verbose_level > 0) printf("Bad image cleaned up\n"); return 0; } static int cd9660_write_volume_descriptors(FILE *fd) { volume_descriptor *vd_temp = diskStructure.firstVolumeDescriptor; int pos; while (vd_temp != NULL) { pos = vd_temp->sector * diskStructure.sectorSize; cd9660_write_filedata(fd, vd_temp->sector, vd_temp->volumeDescriptorData, 1); vd_temp = vd_temp->next; } return 1; } /* * Write out an individual path table * Used just to keep redundant code to a minimum * @param FILE *fd Valid file pointer * @param int Sector to start writing path table to * @param int Endian mode : BIG_ENDIAN or LITTLE_ENDIAN * @returns int 1 on success, 0 on failure */ static int cd9660_write_path_table(FILE *fd, off_t sector, int mode) { int path_table_sectors = CD9660_BLOCKS(diskStructure.sectorSize, diskStructure.pathTableLength); unsigned char *buffer; unsigned char *buffer_head; int len; path_table_entry temp_entry; cd9660node *ptcur; buffer = malloc(diskStructure.sectorSize * path_table_sectors); if (buffer == NULL) { warnx("%s: Memory allocation error allocating buffer", __func__); return 0; } buffer_head = buffer; memset(buffer, 0, diskStructure.sectorSize * path_table_sectors); ptcur = diskStructure.rootNode; while (ptcur != NULL) { memset(&temp_entry, 0, sizeof(path_table_entry)); temp_entry.length[0] = ptcur->isoDirRecord->name_len[0]; temp_entry.extended_attribute_length[0] = ptcur->isoDirRecord->ext_attr_length[0]; memcpy(temp_entry.name, ptcur->isoDirRecord->name, temp_entry.length[0] + 1); /* round up */ len = temp_entry.length[0] + 8 + (temp_entry.length[0] & 0x01); /* todo: function pointers instead */ if (mode == LITTLE_ENDIAN) { cd9660_731(ptcur->fileDataSector, temp_entry.first_sector); cd9660_721((ptcur->parent == NULL ? 1 : ptcur->parent->ptnumber), temp_entry.parent_number); } else { cd9660_732(ptcur->fileDataSector, temp_entry.first_sector); cd9660_722((ptcur->parent == NULL ? 1 : ptcur->parent->ptnumber), temp_entry.parent_number); } memcpy(buffer, &temp_entry, len); buffer += len; ptcur = ptcur->ptnext; } return cd9660_write_filedata(fd, sector, buffer_head, path_table_sectors); } /* * Write out the path tables to disk * Each file descriptor should be pointed to by the PVD, so we know which * sector to copy them to. One thing to watch out for: the only path tables * stored are in the endian mode that the application is compiled for. So, * the first thing to do is write out that path table, then to write the one * in the other endian mode requires to convert the endianness of each entry * in the table. The best way to do this would be to create a temporary * path_table_entry structure, then for each path table entry, copy it to * the temporary entry, translate, then copy that to disk. * * @param FILE* Valid file descriptor * @returns int 0 on failure, 1 on success */ static int cd9660_write_path_tables(FILE *fd) { if (cd9660_write_path_table(fd, diskStructure.primaryLittleEndianTableSector, LITTLE_ENDIAN) == 0) return 0; if (cd9660_write_path_table(fd, diskStructure.primaryBigEndianTableSector, BIG_ENDIAN) == 0) return 0; /* @TODO: handle remaining two path tables */ return 1; } /* * Write a file to disk * Writes a file, its directory record, and its data to disk * This file is designed to be called RECURSIVELY, so initially call it * with the root node. All of the records should store what sector the * file goes in, so no computation should be necessary. * * @param int fd Valid file descriptor * @param struct cd9660node* writenode Pointer to the file to be written * @returns int 0 on failure, 1 on success */ static int cd9660_write_file(FILE *fd, cd9660node *writenode) { char *buf; char *temp_file_name; int ret; off_t working_sector; int cur_sector_offset; int written; iso_directory_record_cd9660 temp_record; cd9660node *temp; int rv = 0; /* Todo : clean up variables */ temp_file_name = malloc(CD9660MAXPATH + 1); if (temp_file_name == NULL) err(EXIT_FAILURE, "%s: malloc", __func__); memset(temp_file_name, 0, CD9660MAXPATH + 1); buf = malloc(diskStructure.sectorSize); if (buf == NULL) err(EXIT_FAILURE, "%s: malloc", __func__); if ((writenode->level != 0) && !(writenode->node->type & S_IFDIR)) { fsinode *inode = writenode->node->inode; /* Only attempt to write unwritten files that have length. */ if ((inode->flags & FI_WRITTEN) != 0) { INODE_WARNX(("%s: skipping written inode %d", __func__, (int)inode->st.st_ino)); } else if (writenode->fileDataLength > 0) { INODE_WARNX(("%s: writing inode %d blocks at %" PRIu32, __func__, (int)inode->st.st_ino, inode->ino)); inode->flags |= FI_WRITTEN; if (writenode->node->contents == NULL) cd9660_compute_full_filename(writenode, temp_file_name); ret = cd9660_copy_file(fd, writenode->fileDataSector, (writenode->node->contents != NULL) ? writenode->node->contents : temp_file_name); if (ret == 0) goto out; } } else { /* * Here is a new revelation that ECMA didnt explain * (at least not well). * ALL . and .. records store the name "\0" and "\1" * resepctively. So, for each directory, we have to * make a new node. * * This is where it gets kinda messy, since we have to * be careful of sector boundaries */ cur_sector_offset = 0; working_sector = writenode->fileDataSector; if (fseeko(fd, working_sector * diskStructure.sectorSize, SEEK_SET) == -1) err(1, "fseeko"); /* * Now loop over children, writing out their directory * records - beware of sector boundaries */ TAILQ_FOREACH(temp, &writenode->cn_children, cn_next_child) { /* * Copy the temporary record and adjust its size * if necessary */ memcpy(&temp_record, temp->isoDirRecord, sizeof(iso_directory_record_cd9660)); temp_record.length[0] = cd9660_compute_record_size(temp); if (temp_record.length[0] + cur_sector_offset >= diskStructure.sectorSize) { cur_sector_offset = 0; working_sector++; /* Seek to the next sector. */ if (fseeko(fd, working_sector * diskStructure.sectorSize, SEEK_SET) == -1) err(1, "fseeko"); } /* Write out the basic ISO directory record */ written = fwrite(&temp_record, 1, temp->isoDirRecord->length[0], fd); if (diskStructure.rock_ridge_enabled) { cd9660_write_rr(fd, temp, cur_sector_offset, working_sector); } if (fseeko(fd, working_sector * diskStructure.sectorSize + cur_sector_offset + temp_record.length[0] - temp->su_tail_size, SEEK_SET) == -1) err(1, "fseeko"); if (temp->su_tail_size > 0) fwrite(temp->su_tail_data, 1, temp->su_tail_size, fd); if (ferror(fd)) { warnx("%s: write error", __func__); goto out; } cur_sector_offset += temp_record.length[0]; } /* * Recurse on children. */ TAILQ_FOREACH(temp, &writenode->cn_children, cn_next_child) { if ((ret = cd9660_write_file(fd, temp)) == 0) goto out; } } rv = 1; out: free(temp_file_name); free(buf); return rv; } /* * Wrapper function to write a buffer (one sector) to disk. * Seeks and writes the buffer. * NOTE: You dont NEED to use this function, but it might make your * life easier if you have to write things that align to a sector * (such as volume descriptors). * * @param int fd Valid file descriptor * @param int sector Sector number to write to * @param const unsigned char* Buffer to write. This should be the * size of a sector, and if only a portion * is written, the rest should be set to 0. */ static int cd9660_write_filedata(FILE *fd, off_t sector, const unsigned char *buf, int numsecs) { off_t curpos; size_t success; curpos = ftello(fd); if (fseeko(fd, sector * diskStructure.sectorSize, SEEK_SET) == -1) err(1, "fseeko"); success = fwrite(buf, diskStructure.sectorSize * numsecs, 1, fd); if (fseeko(fd, curpos, SEEK_SET) == -1) err(1, "fseeko"); if (success == 1) success = diskStructure.sectorSize * numsecs; return success; } #if 0 static int cd9660_write_buffered(FILE *fd, off_t offset, int buff_len, const unsigned char* buffer) { static int working_sector = -1; static char buf[CD9660_SECTOR_SIZE]; return 0; } #endif int cd9660_copy_file(FILE *fd, off_t start_sector, const char *filename) { FILE *rf; int bytes_read; off_t sector = start_sector; int buf_size = diskStructure.sectorSize; char *buf; buf = malloc(buf_size); if (buf == NULL) err(EXIT_FAILURE, "%s: malloc", __func__); if ((rf = fopen(filename, "rb")) == NULL) { warn("%s: cannot open %s", __func__, filename); free(buf); return 0; } if (diskStructure.verbose_level > 1) printf("Writing file: %s\n",filename); if (fseeko(fd, start_sector * diskStructure.sectorSize, SEEK_SET) == -1) err(1, "fseeko"); while (!feof(rf)) { bytes_read = fread(buf,1,buf_size,rf); if (ferror(rf)) { warn("%s: fread", __func__); free(buf); (void)fclose(rf); return 0; } fwrite(buf,1,bytes_read,fd); if (ferror(fd)) { warn("%s: fwrite", __func__); free(buf); (void)fclose(rf); return 0; } sector++; } fclose(rf); free(buf); return 1; } static void cd9660_write_rr(FILE *fd, cd9660node *writenode, off_t offset, off_t sector) { int in_ca = 0; struct ISO_SUSP_ATTRIBUTES *myattr; offset += writenode->isoDirRecord->length[0]; if (fseeko(fd, sector * diskStructure.sectorSize + offset, SEEK_SET) == -1) err(1, "fseeko"); /* Offset now points at the end of the record */ TAILQ_FOREACH(myattr, &writenode->head, rr_ll) { fwrite(&(myattr->attr), CD9660_SUSP_ENTRY_SIZE(myattr), 1, fd); if (!in_ca) { offset += CD9660_SUSP_ENTRY_SIZE(myattr); if (myattr->last_in_suf) { /* * Point the offset to the start of this * record's CE area */ if (fseeko(fd, ((off_t)diskStructure. susp_continuation_area_start_sector * diskStructure.sectorSize) + writenode->susp_entry_ce_start, SEEK_SET) == -1) err(1, "fseeko"); in_ca = 1; } } } /* * If we had to go to the continuation area, head back to * where we should be. */ if (in_ca) if (fseeko(fd, sector * diskStructure.sectorSize + offset, SEEK_SET) == -1) err(1, "fseeko"); }