/* vi: set sw=8 ts=8: */ // genext2fs.c // // ext2 filesystem generator for embedded systems // Copyright (C) 2000 Xavier Bestel <xavier.bestel@free.fr> // // Please direct support requests to genext2fs-devel@lists.sourceforge.net // // 'du' portions taken from coreutils/du.c in busybox: // Copyright (C) 1999,2000 by Lineo, inc. and John Beppu // Copyright (C) 1999,2000,2001 by John Beppu <beppu@codepoet.org> // Copyright (C) 2002 Edward Betts <edward@debian.org> // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License // as published by the Free Software Foundation; version // 2 of the License. // // Changes: // 3 Jun 2000 Initial release // 6 Jun 2000 Bugfix: fs size multiple of 8 // Bugfix: fill blocks with inodes // 14 Jun 2000 Bugfix: bad chdir() with -d option // Bugfix: removed size=8n constraint // Changed -d file to -f file // Added -e option // 22 Jun 2000 Changed types for 64bits archs // 24 Jun 2000 Added endianness swap // Bugfix: bad dir name lookup // 03 Aug 2000 Bugfix: ind. blocks endian swap // 09 Aug 2000 Bugfix: symlinks endian swap // 01 Sep 2000 Bugfix: getopt returns int, not char proski@gnu.org // 10 Sep 2000 Bugfix: device nodes endianness xavier.gueguen@col.bsf.alcatel.fr // Bugfix: getcwd values for Solaris xavier.gueguen@col.bsf.alcatel.fr // Bugfix: ANSI scanf for non-GNU C xavier.gueguen@col.bsf.alcatel.fr // 28 Jun 2001 Bugfix: getcwd differs for Solaris/GNU mike@sowbug.com // 8 Mar 2002 Bugfix: endianness swap of x-indirects // 23 Mar 2002 Bugfix: test for IFCHR or IFBLK was flawed // 10 Oct 2002 Added comments,makefile targets, vsundar@ixiacom.com // endianess swap assert check. // Copyright (C) 2002 Ixia communications // 12 Oct 2002 Added support for triple indirection vsundar@ixiacom.com // Copyright (C) 2002 Ixia communications // 14 Oct 2002 Added support for groups vsundar@ixiacom.com // Copyright (C) 2002 Ixia communications // 5 Jan 2003 Bugfixes: reserved inodes should be set vsundar@usc.edu // only in the first group; directory names // need to be null padded at the end; and // number of blocks per group should be a // multiple of 8. Updated md5 values. // 6 Jan 2003 Erik Andersen <andersee@debian.org> added // mkfs.jffs2 compatible device table support, // along with -q, -P, -U #include <config.h> #include <stdio.h> #if HAVE_SYS_TYPES_H # include <sys/types.h> #endif #if MAJOR_IN_MKDEV # include <sys/mkdev.h> #elif MAJOR_IN_SYSMACROS # include <sys/sysmacros.h> #endif #if HAVE_SYS_STAT_H # include <sys/stat.h> #endif #if STDC_HEADERS # include <stdlib.h> # include <stddef.h> #else # if HAVE_STDLIB_H # include <stdlib.h> # endif # if HAVE_STDDEF_H # include <stddef.h> # endif #endif #if HAVE_STRING_H # if !STDC_HEADERS && HAVE_MEMORY_H # include <memory.h> # endif # include <string.h> #endif #if HAVE_STRINGS_H # include <strings.h> #endif #if HAVE_INTTYPES_H # include <inttypes.h> #else # if HAVE_STDINT_H # include <stdint.h> # endif #endif #if HAVE_UNISTD_H # include <unistd.h> #endif #if HAVE_DIRENT_H # include <dirent.h> # define NAMLEN(dirent) strlen((dirent)->d_name) #else # define dirent direct # define NAMLEN(dirent) (dirent)->d_namlen # if HAVE_SYS_NDIR_H # include <sys/ndir.h> # endif # if HAVE_SYS_DIR_H # include <sys/dir.h> # endif # if HAVE_NDIR_H # include <ndir.h> # endif #endif #if HAVE_LIBGEN_H # include <libgen.h> #endif #include <stdarg.h> #include <assert.h> #include <time.h> #include <ctype.h> #include <errno.h> #if HAVE_FCNTL_H # include <fcntl.h> #endif #if HAVE_GETOPT_H # include <getopt.h> #endif #if HAVE_LIMITS_H # include <limits.h> #endif #include <private/android_filesystem_config.h> unsigned source_path_len = 0; struct stats { unsigned long nblocks; unsigned long ninodes; }; // block size #define BLOCKSIZE 1024 #define BLOCKS_PER_GROUP 8192 #define INODES_PER_GROUP 8192 /* Percentage of blocks that are reserved.*/ #define RESERVED_BLOCKS 5/100 #define MAX_RESERVED_BLOCKS 25/100 // inode block size (why is it != BLOCKSIZE ?!?) /* The field i_blocks in the ext2 inode stores the number of data blocks but in terms of 512 bytes. That is what INODE_BLOCKSIZE represents. INOBLK is the number of such blocks in an actual disk block */ #define INODE_BLOCKSIZE 512 #define INOBLK (BLOCKSIZE / INODE_BLOCKSIZE) // reserved inodes #define EXT2_BAD_INO 1 // Bad blocks inode #define EXT2_ROOT_INO 2 // Root inode #define EXT2_ACL_IDX_INO 3 // ACL inode #define EXT2_ACL_DATA_INO 4 // ACL inode #define EXT2_BOOT_LOADER_INO 5 // Boot loader inode #define EXT2_UNDEL_DIR_INO 6 // Undelete directory inode #define EXT2_FIRST_INO 11 // First non reserved inode // magic number for ext2 #define EXT2_MAGIC_NUMBER 0xEF53 // direct/indirect block addresses #define EXT2_NDIR_BLOCKS 11 // direct blocks #define EXT2_IND_BLOCK 12 // indirect block #define EXT2_DIND_BLOCK 13 // double indirect block #define EXT2_TIND_BLOCK 14 // triple indirect block #define EXT2_INIT_BLOCK 0xFFFFFFFF // just initialized (not really a block address) // end of a block walk #define WALK_END 0xFFFFFFFE // file modes #define FM_IFMT 0170000 // format mask #define FM_IFSOCK 0140000 // socket #define FM_IFLNK 0120000 // symbolic link #define FM_IFREG 0100000 // regular file #define FM_IFBLK 0060000 // block device #define FM_IFDIR 0040000 // directory #define FM_IFCHR 0020000 // character device #define FM_IFIFO 0010000 // fifo #define FM_IMASK 0007777 // *all* perms mask for everything below #define FM_ISUID 0004000 // SUID #define FM_ISGID 0002000 // SGID #define FM_ISVTX 0001000 // sticky bit #define FM_IRWXU 0000700 // entire "user" mask #define FM_IRUSR 0000400 // read #define FM_IWUSR 0000200 // write #define FM_IXUSR 0000100 // execute #define FM_IRWXG 0000070 // entire "group" mask #define FM_IRGRP 0000040 // read #define FM_IWGRP 0000020 // write #define FM_IXGRP 0000010 // execute #define FM_IRWXO 0000007 // entire "other" mask #define FM_IROTH 0000004 // read #define FM_IWOTH 0000002 // write #define FM_IXOTH 0000001 // execute // options #define OP_HOLES 0x01 // make files with holes /* Defines for accessing group details */ // Number of groups in the filesystem #define GRP_NBGROUPS(fs) \ (((fs)->sb.s_blocks_count - fs->sb.s_first_data_block + \ (fs)->sb.s_blocks_per_group - 1) / (fs)->sb.s_blocks_per_group) // Get group block bitmap (bbm) given the group number #define GRP_GET_GROUP_BBM(fs,grp) ( get_blk((fs),(fs)->gd[(grp)].bg_block_bitmap) ) // Get group inode bitmap (ibm) given the group number #define GRP_GET_GROUP_IBM(fs,grp) ( get_blk((fs),(fs)->gd[(grp)].bg_inode_bitmap) ) // Given an inode number find the group it belongs to #define GRP_GROUP_OF_INODE(fs,nod) ( ((nod)-1) / (fs)->sb.s_inodes_per_group) //Given an inode number get the inode bitmap that covers it #define GRP_GET_INODE_BITMAP(fs,nod) \ ( GRP_GET_GROUP_IBM((fs),GRP_GROUP_OF_INODE((fs),(nod))) ) //Given an inode number find its offset within the inode bitmap that covers it #define GRP_IBM_OFFSET(fs,nod) \ ( (nod) - GRP_GROUP_OF_INODE((fs),(nod))*(fs)->sb.s_inodes_per_group ) // Given a block number find the group it belongs to #define GRP_GROUP_OF_BLOCK(fs,blk) ( ((blk)-1) / (fs)->sb.s_blocks_per_group) //Given a block number get the block bitmap that covers it #define GRP_GET_BLOCK_BITMAP(fs,blk) \ ( GRP_GET_GROUP_BBM((fs),GRP_GROUP_OF_BLOCK((fs),(blk))) ) //Given a block number find its offset within the block bitmap that covers it #define GRP_BBM_OFFSET(fs,blk) \ ( (blk) - GRP_GROUP_OF_BLOCK((fs),(blk))*(fs)->sb.s_blocks_per_group ) // used types typedef signed char int8; typedef unsigned char uint8; typedef signed short int16; typedef unsigned short uint16; typedef signed int int32; typedef unsigned int uint32; // the GNU C library has a wonderful scanf("%as", string) which will // allocate the string with the right size, good to avoid buffer // overruns. the following macros use it if available or use a // hacky workaround // moreover it will define a snprintf() like a sprintf(), i.e. // without the buffer overrun checking, to work around bugs in // older solaris. Note that this is still not very portable, in that // the return value cannot be trusted. #if 0 // SCANF_CAN_MALLOC // C99 define "a" for floating point, so you can have runtime surprise // according the library versions # define SCANF_PREFIX "a" # define SCANF_STRING(s) (&s) #else # define SCANF_PREFIX "511" # define SCANF_STRING(s) (s = malloc(512)) #endif /* SCANF_CAN_MALLOC */ #if PREFER_PORTABLE_SNPRINTF static inline int portable_snprintf(char *str, size_t n, const char *fmt, ...) { int ret; va_list ap; va_start(ap, fmt); ret = vsprintf(str, fmt, ap); va_end(ap); return ret; } # define SNPRINTF portable_snprintf #else # define SNPRINTF snprintf #endif /* PREFER_PORTABLE_SNPRINTF */ #if !HAVE_GETLINE // getline() replacement for Darwin and Solaris etc. // This code uses backward seeks (unless rchunk is set to 1) which can't work // on pipes etc. However, add2fs_from_file() only calls getline() for // regular files, so a larger rchunk and backward seeks are okay. ssize_t getdelim(char **lineptr, size_t *n, int delim, FILE *stream) { char *p; // reads stored here size_t const rchunk = 512; // number of bytes to read size_t const mchunk = 512; // number of extra bytes to malloc size_t m = rchunk + 1; // initial buffer size if (*lineptr) { if (*n < m) { *lineptr = (char*)realloc(*lineptr, m); if (!*lineptr) return -1; *n = m; } } else { *lineptr = (char*)malloc(m); if (!*lineptr) return -1; *n = m; } m = 0; // record length including seperator do { size_t i; // number of bytes read etc size_t j = 0; // number of bytes searched p = *lineptr + m; i = fread(p, 1, rchunk, stream); if (i < rchunk && ferror(stream)) return -1; while (j < i) { ++j; if (*p++ == (char)delim) { *p = '\0'; if (j != i) { if (fseek(stream, j - i, SEEK_CUR)) return -1; if (feof(stream)) clearerr(stream); } m += j; return m; } } m += j; if (feof(stream)) { if (m) return m; if (!i) return -1; } // allocate space for next read plus possible null terminator i = ((m + (rchunk + 1 > mchunk ? rchunk + 1 : mchunk) + mchunk - 1) / mchunk) * mchunk; if (i != *n) { *lineptr = (char*)realloc(*lineptr, i); if (!*lineptr) return -1; *n = i; } } while (1); } #define getline(a,b,c) getdelim(a,b,'\n',c) #endif /* HAVE_GETLINE */ // Convert a numerical string to a float, and multiply the result by an // IEC or SI multiplier if provided; supported multipliers are Ki, Mi, Gi, k, M // and G. float SI_atof(const char *nptr) { float f = 0; float m = 1; char *suffixptr; #if HAVE_STRTOF f = strtof(nptr, &suffixptr); #else f = (float)strtod(nptr, &suffixptr); #endif /* HAVE_STRTOF */ if (*suffixptr) { if (!strcmp(suffixptr, "Ki")) m = 1 << 10; else if (!strcmp(suffixptr, "Mi")) m = 1 << 20; else if (!strcmp(suffixptr, "Gi")) m = 1 << 30; else if (!strcmp(suffixptr, "k")) m = 1000; else if (!strcmp(suffixptr, "M")) m = 1000 * 1000; else if (!strcmp(suffixptr, "G")) m = 1000 * 1000 * 1000; } return f * m; } // endianness swap static inline uint16 swab16(uint16 val) { return (val >> 8) | (val << 8); } static inline uint32 swab32(uint32 val) { return ((val>>24) | ((val>>8)&0xFF00) | ((val<<8)&0xFF0000) | (val<<24)); } // on-disk structures // this trick makes me declare things only once // (once for the structures, once for the endianness swap) #define superblock_decl \ udecl32(s_inodes_count) /* Count of inodes in the filesystem */ \ udecl32(s_blocks_count) /* Count of blocks in the filesystem */ \ udecl32(s_r_blocks_count) /* Count of the number of reserved blocks */ \ udecl32(s_free_blocks_count) /* Count of the number of free blocks */ \ udecl32(s_free_inodes_count) /* Count of the number of free inodes */ \ udecl32(s_first_data_block) /* The first block which contains data */ \ udecl32(s_log_block_size) /* Indicator of the block size */ \ decl32(s_log_frag_size) /* Indicator of the size of the fragments */ \ udecl32(s_blocks_per_group) /* Count of the number of blocks in each block group */ \ udecl32(s_frags_per_group) /* Count of the number of fragments in each block group */ \ udecl32(s_inodes_per_group) /* Count of the number of inodes in each block group */ \ udecl32(s_mtime) /* The time that the filesystem was last mounted */ \ udecl32(s_wtime) /* The time that the filesystem was last written to */ \ udecl16(s_mnt_count) /* The number of times the file system has been mounted */ \ decl16(s_max_mnt_count) /* The number of times the file system can be mounted */ \ udecl16(s_magic) /* Magic number indicating ex2fs */ \ udecl16(s_state) /* Flags indicating the current state of the filesystem */ \ udecl16(s_errors) /* Flags indicating the procedures for error reporting */ \ udecl16(s_minor_rev_level) /* The minor revision level of the filesystem */ \ udecl32(s_lastcheck) /* The time that the filesystem was last checked */ \ udecl32(s_checkinterval) /* The maximum time permissable between checks */ \ udecl32(s_creator_os) /* Indicator of which OS created the filesystem */ \ udecl32(s_rev_level) /* The revision level of the filesystem */ \ udecl16(s_def_resuid) /* The default uid for reserved blocks */ \ udecl16(s_def_resgid) /* The default gid for reserved blocks */ #define groupdescriptor_decl \ udecl32(bg_block_bitmap) /* Block number of the block bitmap */ \ udecl32(bg_inode_bitmap) /* Block number of the inode bitmap */ \ udecl32(bg_inode_table) /* Block number of the inode table */ \ udecl16(bg_free_blocks_count) /* Free blocks in the group */ \ udecl16(bg_free_inodes_count) /* Free inodes in the group */ \ udecl16(bg_used_dirs_count) /* Number of directories in the group */ \ udecl16(bg_pad) #define inode_decl \ udecl16(i_mode) /* Entry type and file mode */ \ udecl16(i_uid) /* User id */ \ udecl32(i_size) /* File/dir size in bytes */ \ udecl32(i_atime) /* Last access time */ \ udecl32(i_ctime) /* Creation time */ \ udecl32(i_mtime) /* Last modification time */ \ udecl32(i_dtime) /* Deletion time */ \ udecl16(i_gid) /* Group id */ \ udecl16(i_links_count) /* Number of (hard) links to this inode */ \ udecl32(i_blocks) /* Number of blocks used (1 block = 512 bytes) */ \ udecl32(i_flags) /* ??? */ \ udecl32(i_reserved1) \ utdecl32(i_block,15) /* Blocks table */ \ udecl32(i_version) /* ??? */ \ udecl32(i_file_acl) /* File access control list */ \ udecl32(i_dir_acl) /* Directory access control list */ \ udecl32(i_faddr) /* Fragment address */ \ udecl8(i_frag) /* Fragments count*/ \ udecl8(i_fsize) /* Fragment size */ \ udecl16(i_pad1) #define directory_decl \ udecl32(d_inode) /* Inode entry */ \ udecl16(d_rec_len) /* Total size on record */ \ udecl16(d_name_len) /* Size of entry name */ #define decl8(x) int8 x; #define udecl8(x) uint8 x; #define decl16(x) int16 x; #define udecl16(x) uint16 x; #define decl32(x) int32 x; #define udecl32(x) uint32 x; #define utdecl32(x,n) uint32 x[n]; typedef struct { superblock_decl uint32 s_reserved[235]; // Reserved } superblock; typedef struct { groupdescriptor_decl uint32 bg_reserved[3]; } groupdescriptor; typedef struct { inode_decl uint32 i_reserved2[2]; } inode; typedef struct { directory_decl char d_name[0]; } directory; typedef uint8 block[BLOCKSIZE]; /* blockwalker fields: The blockwalker is used to access all the blocks of a file (including the indirection blocks) through repeated calls to walk_bw. bpdir -> index into the inode->i_block[]. Indicates level of indirection. bnum -> total number of blocks so far accessed. including indirection blocks. bpind,bpdind,bptind -> index into indirection blocks. bpind, bpdind, bptind do *NOT* index into single, double and triple indirect blocks resp. as you might expect from their names. Instead they are in order the 1st, 2nd & 3rd index to be used As an example.. To access data block number 70000: bpdir: 15 (we are doing triple indirection) bpind: 0 ( index into the triple indirection block) bpdind: 16 ( index into the double indirection block) bptind: 99 ( index into the single indirection block) 70000 = 12 + 256 + 256*256 + 16*256 + 100 (indexing starts from zero) So,for double indirection bpind will index into the double indirection block and bpdind into the single indirection block. For single indirection only bpind will be used. */ typedef struct { uint32 bnum; uint32 bpdir; uint32 bpind; uint32 bpdind; uint32 bptind; } blockwalker; /* Filesystem structure that support groups */ #if BLOCKSIZE == 1024 typedef struct { block zero; // The famous block 0 superblock sb; // The superblock groupdescriptor gd[0]; // The group descriptors } filesystem; #else #error UNHANDLED BLOCKSIZE #endif // now the endianness swap #undef decl8 #undef udecl8 #undef decl16 #undef udecl16 #undef decl32 #undef udecl32 #undef utdecl32 #define decl8(x) #define udecl8(x) #define decl16(x) this->x = swab16(this->x); #define udecl16(x) this->x = swab16(this->x); #define decl32(x) this->x = swab32(this->x); #define udecl32(x) this->x = swab32(this->x); #define utdecl32(x,n) { int i; for(i=0; i<n; i++) this->x[i] = swab32(this->x[i]); } #define HDLINK_CNT 16 static int32 hdlink_cnt = HDLINK_CNT; struct hdlink_s { uint32 src_inode; uint32 dst_nod; }; struct hdlinks_s { int32 count; struct hdlink_s *hdl; }; static struct hdlinks_s hdlinks; static void swap_sb(superblock *sb) { #define this sb superblock_decl #undef this } static void swap_gd(groupdescriptor *gd) { #define this gd groupdescriptor_decl #undef this } static void swap_nod(inode *nod) { #define this nod inode_decl #undef this } static void swap_dir(directory *dir) { #define this dir directory_decl #undef this } static void swap_block(block b) { int i; uint32 *blk = (uint32*)b; for(i = 0; i < BLOCKSIZE/4; i++) blk[i] = swab32(blk[i]); } #undef decl8 #undef udecl8 #undef decl16 #undef udecl16 #undef decl32 #undef udecl32 #undef utdecl32 static char * app_name; static const char *const memory_exhausted = "memory exhausted"; // error (un)handling static void verror_msg(const char *s, va_list p) { fflush(stdout); fprintf(stderr, "%s: ", app_name); vfprintf(stderr, s, p); } static void error_msg(const char *s, ...) { va_list p; va_start(p, s); verror_msg(s, p); va_end(p); putc('\n', stderr); } static void error_msg_and_die(const char *s, ...) { va_list p; va_start(p, s); verror_msg(s, p); va_end(p); putc('\n', stderr); exit(EXIT_FAILURE); } static void vperror_msg(const char *s, va_list p) { int err = errno; if (s == 0) s = ""; verror_msg(s, p); if (*s) s = ": "; fprintf(stderr, "%s%s\n", s, strerror(err)); } static void perror_msg_and_die(const char *s, ...) { va_list p; va_start(p, s); vperror_msg(s, p); va_end(p); exit(EXIT_FAILURE); } static FILE * xfopen(const char *path, const char *mode) { FILE *fp; if ((fp = fopen(path, mode)) == NULL) perror_msg_and_die("%s", path); return fp; } static char * xstrdup(const char *s) { char *t; if (s == NULL) return NULL; t = strdup(s); if (t == NULL) error_msg_and_die(memory_exhausted); return t; } static void * xrealloc(void *ptr, size_t size) { ptr = realloc(ptr, size); if (ptr == NULL && size != 0) error_msg_and_die(memory_exhausted); return ptr; } static char * xreadlink(const char *path) { static const int GROWBY = 80; /* how large we will grow strings by */ char *buf = NULL; int bufsize = 0, readsize = 0; do { buf = xrealloc(buf, bufsize += GROWBY); readsize = readlink(path, buf, bufsize); /* 1st try */ if (readsize == -1) { perror_msg_and_die("%s:%s", app_name, path); } } while (bufsize < readsize + 1); buf[readsize] = '\0'; return buf; } int is_hardlink(ino_t inode) { int i; for(i = 0; i < hdlinks.count; i++) { if(hdlinks.hdl[i].src_inode == inode) return i; } return -1; } // printf helper macro #define plural(a) (a), ((a) > 1) ? "s" : "" // temporary working block static inline uint8 * get_workblk(void) { unsigned char* b=calloc(1,BLOCKSIZE); return b; } static inline void free_workblk(block b) { free(b); } /* Rounds qty upto a multiple of siz. siz should be a power of 2 */ static inline uint32 rndup(uint32 qty, uint32 siz) { return (qty + (siz - 1)) & ~(siz - 1); } // check if something is allocated in the bitmap static inline uint32 allocated(block b, uint32 item) { return b[(item-1) / 8] & (1 << ((item-1) % 8)); } // return a given block from a filesystem static inline uint8 * get_blk(filesystem *fs, uint32 blk) { return (uint8*)fs + blk*BLOCKSIZE; } // return a given inode from a filesystem static inline inode * get_nod(filesystem *fs, uint32 nod) { int grp,offset; inode *itab; offset = GRP_IBM_OFFSET(fs,nod); grp = GRP_GROUP_OF_INODE(fs,nod); itab = (inode *)get_blk(fs, fs->gd[grp].bg_inode_table); return itab+offset-1; } // allocate a given block/inode in the bitmap // allocate first free if item == 0 static uint32 allocate(block b, uint32 item) { if(!item) { int i; uint8 bits; for(i = 0; i < BLOCKSIZE; i++) if((bits = b[i]) != (uint8)-1) { int j; for(j = 0; j < 8; j++) if(!(bits & (1 << j))) break; item = i * 8 + j + 1; break; } if(i == BLOCKSIZE) return 0; } b[(item-1) / 8] |= (1 << ((item-1) % 8)); return item; } // deallocate a given block/inode static void deallocate(block b, uint32 item) { b[(item-1) / 8] &= ~(1 << ((item-1) % 8)); } // allocate a block static uint32 alloc_blk(filesystem *fs, uint32 nod) { uint32 bk=0; uint32 grp,nbgroups; grp = GRP_GROUP_OF_INODE(fs,nod); nbgroups = GRP_NBGROUPS(fs); if(!(bk = allocate(get_blk(fs,fs->gd[grp].bg_block_bitmap), 0))) { for(grp=0;grp<nbgroups && !bk;grp++) bk=allocate(get_blk(fs,fs->gd[grp].bg_block_bitmap),0); grp--; } if (!bk) error_msg_and_die("couldn't allocate a block (no free space)"); if(!(fs->gd[grp].bg_free_blocks_count--)) error_msg_and_die("group descr %d. free blocks count == 0 (corrupted fs?)",grp); if(!(fs->sb.s_free_blocks_count--)) error_msg_and_die("superblock free blocks count == 0 (corrupted fs?)"); return fs->sb.s_blocks_per_group*grp + bk; } // free a block static void free_blk(filesystem *fs, uint32 bk) { uint32 grp; grp = bk / fs->sb.s_blocks_per_group; bk %= fs->sb.s_blocks_per_group; deallocate(get_blk(fs,fs->gd[grp].bg_block_bitmap), bk); fs->gd[grp].bg_free_blocks_count++; fs->sb.s_free_blocks_count++; } // allocate an inode static uint32 alloc_nod(filesystem *fs) { uint32 nod,best_group=0; uint32 grp,nbgroups,avefreei; nbgroups = GRP_NBGROUPS(fs); /* Distribute inodes amongst all the blocks */ /* For every block group with more than average number of free inodes */ /* find the one with the most free blocks and allocate node there */ /* Idea from find_group_dir in fs/ext2/ialloc.c in 2.4.19 kernel */ /* We do it for all inodes. */ avefreei = fs->sb.s_free_inodes_count / nbgroups; for(grp=0; grp<nbgroups; grp++) { if (fs->gd[grp].bg_free_inodes_count < avefreei || fs->gd[grp].bg_free_inodes_count == 0) continue; if (!best_group || fs->gd[grp].bg_free_blocks_count > fs->gd[best_group].bg_free_blocks_count) best_group = grp; } if (!(nod = allocate(get_blk(fs,fs->gd[best_group].bg_inode_bitmap),0))) error_msg_and_die("couldn't allocate an inode (no free inode)"); if(!(fs->gd[best_group].bg_free_inodes_count--)) error_msg_and_die("group descr. free blocks count == 0 (corrupted fs?)"); if(!(fs->sb.s_free_inodes_count--)) error_msg_and_die("superblock free blocks count == 0 (corrupted fs?)"); return fs->sb.s_inodes_per_group*best_group+nod; } // print a bitmap allocation static void print_bm(block b, uint32 max) { uint32 i; printf("----+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0\n"); for(i=1; i <= max; i++) { putchar(allocated(b, i) ? '*' : '.'); if(!(i % 100)) printf("\n"); } if((i-1) % 100) printf("\n"); } // initalize a blockwalker (iterator for blocks list) static inline void init_bw(blockwalker *bw) { bw->bnum = 0; bw->bpdir = EXT2_INIT_BLOCK; } // return next block of inode (WALK_END for end) // if *create>0, append a newly allocated block at the end // if *create<0, free the block - warning, the metadata blocks contents is // used after being freed, so once you start // freeing blocks don't stop until the end of // the file. moreover, i_blocks isn't updated. // in fact, don't do that, just use extend_blk // if hole!=0, create a hole in the file static uint32 walk_bw(filesystem *fs, uint32 nod, blockwalker *bw, int32 *create, uint32 hole) { uint32 *bkref = 0; uint32 *b; int extend = 0, reduce = 0; if(create && (*create) < 0) reduce = 1; if(bw->bnum >= get_nod(fs, nod)->i_blocks / INOBLK) { if(create && (*create) > 0) { (*create)--; extend = 1; } else return WALK_END; } // first direct block if(bw->bpdir == EXT2_INIT_BLOCK) { bkref = &get_nod(fs, nod)->i_block[bw->bpdir = 0]; if(extend) // allocate first block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } // direct block else if(bw->bpdir < EXT2_NDIR_BLOCKS) { bkref = &get_nod(fs, nod)->i_block[++bw->bpdir]; if(extend) // allocate block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free block free_blk(fs, *bkref); } // first block in indirect block else if(bw->bpdir == EXT2_NDIR_BLOCKS) { bw->bnum++; bw->bpdir = EXT2_IND_BLOCK; bw->bpind = 0; if(extend) // allocate indirect block get_nod(fs, nod)->i_block[bw->bpdir] = alloc_blk(fs,nod); if(reduce) // free indirect block free_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); bkref = &b[bw->bpind]; if(extend) // allocate first block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } // block in indirect block else if((bw->bpdir == EXT2_IND_BLOCK) && (bw->bpind < BLOCKSIZE/4 - 1)) { bw->bpind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); bkref = &b[bw->bpind]; if(extend) // allocate block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free block free_blk(fs, *bkref); } // first block in first indirect block in first double indirect block else if(bw->bpdir == EXT2_IND_BLOCK) { bw->bnum += 2; bw->bpdir = EXT2_DIND_BLOCK; bw->bpind = 0; bw->bpdind = 0; if(extend) // allocate double indirect block get_nod(fs, nod)->i_block[bw->bpdir] = alloc_blk(fs,nod); if(reduce) // free double indirect block free_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); if(extend) // allocate first indirect block b[bw->bpind] = alloc_blk(fs,nod); if(reduce) // free firstindirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpind]); bkref = &b[bw->bpdind]; if(extend) // allocate first block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } // block in indirect block in double indirect block else if((bw->bpdir == EXT2_DIND_BLOCK) && (bw->bpdind < BLOCKSIZE/4 - 1)) { bw->bpdind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, b[bw->bpind]); bkref = &b[bw->bpdind]; if(extend) // allocate block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free block free_blk(fs, *bkref); } // first block in indirect block in double indirect block else if((bw->bpdir == EXT2_DIND_BLOCK) && (bw->bpind < BLOCKSIZE/4 - 1)) { bw->bnum++; bw->bpdind = 0; bw->bpind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); if(extend) // allocate indirect block b[bw->bpind] = alloc_blk(fs,nod); if(reduce) // free indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpind]); bkref = &b[bw->bpdind]; if(extend) // allocate first block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } /* Adding support for triple indirection */ /* Just starting triple indirection. Allocate the indirection blocks and the first data block */ else if (bw->bpdir == EXT2_DIND_BLOCK) { bw->bnum += 3; bw->bpdir = EXT2_TIND_BLOCK; bw->bpind = 0; bw->bpdind = 0; bw->bptind = 0; if(extend) // allocate triple indirect block get_nod(fs, nod)->i_block[bw->bpdir] = alloc_blk(fs,nod); if(reduce) // free triple indirect block free_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); if(extend) // allocate first double indirect block b[bw->bpind] = alloc_blk(fs,nod); if(reduce) // free first double indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpind]); if(extend) // allocate first indirect block b[bw->bpdind] = alloc_blk(fs,nod); if(reduce) // free first indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpdind]); bkref = &b[bw->bptind]; if(extend) // allocate first data block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } /* Still processing a single indirect block down the indirection chain.Allocate a data block for it */ else if ( (bw->bpdir == EXT2_TIND_BLOCK) && (bw->bptind < BLOCKSIZE/4 -1) ) { bw->bptind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpdind]); bkref = &b[bw->bptind]; if(extend) // allocate data block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free block free_blk(fs, *bkref); } /* Finished processing a single indirect block. But still in the same double indirect block. Allocate new single indirect block for it and a data block */ else if ( (bw->bpdir == EXT2_TIND_BLOCK) && (bw->bpdind < BLOCKSIZE/4 -1) ) { bw->bnum++; bw->bptind = 0; bw->bpdind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); b = (uint32*)get_blk(fs, b[bw->bpind]); if(extend) // allocate single indirect block b[bw->bpdind] = alloc_blk(fs,nod); if(reduce) // free indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpdind]); bkref = &b[bw->bptind]; if(extend) // allocate first data block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } /* Finished processing a double indirect block. Allocate the next double indirect block and the single,data blocks for it */ else if ( (bw->bpdir == EXT2_TIND_BLOCK) && (bw->bpind < BLOCKSIZE/4 - 1) ) { bw->bnum += 2; bw->bpdind = 0; bw->bptind = 0; bw->bpind++; b = (uint32*)get_blk(fs, get_nod(fs, nod)->i_block[bw->bpdir]); if(extend) // allocate double indirect block b[bw->bpind] = alloc_blk(fs,nod); if(reduce) // free double indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpind]); if(extend) // allocate single indirect block b[bw->bpdind] = alloc_blk(fs,nod); if(reduce) // free indirect block free_blk(fs, b[bw->bpind]); b = (uint32*)get_blk(fs, b[bw->bpdind]); bkref = &b[bw->bptind]; if(extend) // allocate first block *bkref = hole ? 0 : alloc_blk(fs,nod); if(reduce) // free first block free_blk(fs, *bkref); } else error_msg_and_die("file too big !"); /* End change for walking triple indirection */ if(*bkref) { bw->bnum++; if(!reduce && !allocated(GRP_GET_BLOCK_BITMAP(fs,*bkref), GRP_BBM_OFFSET(fs,*bkref))) error_msg_and_die("[block %d of inode %d is unallocated !]", *bkref, nod); } if(extend) get_nod(fs, nod)->i_blocks = bw->bnum * INOBLK; return *bkref; } // add blocks to an inode (file/dir/etc...) static void extend_blk(filesystem *fs, uint32 nod, block b, int amount) { int create = amount; blockwalker bw, lbw; uint32 bk; init_bw(&bw); if(amount < 0) { uint32 i; for(i = 0; i < get_nod(fs, nod)->i_blocks / INOBLK + amount; i++) walk_bw(fs, nod, &bw, 0, 0); while(walk_bw(fs, nod, &bw, &create, 0) != WALK_END) /*nop*/; get_nod(fs, nod)->i_blocks += amount * INOBLK; } else { lbw = bw; while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) lbw = bw; bw = lbw; while(create) { int i, copyb = 0; if(!(fs->sb.s_reserved[200] & OP_HOLES)) copyb = 1; else for(i = 0; i < BLOCKSIZE / 4; i++) if(((int32*)(b + BLOCKSIZE * (amount - create)))[i]) { copyb = 1; break; } if((bk = walk_bw(fs, nod, &bw, &create, !copyb)) == WALK_END) break; if(copyb) memcpy(get_blk(fs, bk), b + BLOCKSIZE * (amount - create - 1), BLOCKSIZE); } } } // link an entry (inode #) to a directory static void add2dir(filesystem *fs, uint32 dnod, uint32 nod, const char* name) { blockwalker bw; uint32 bk; uint8 *b; directory *d; int reclen, nlen; inode *node; inode *pnode; pnode = get_nod(fs, dnod); if((pnode->i_mode & FM_IFMT) != FM_IFDIR) error_msg_and_die("can't add '%s' to a non-directory", name); if(!*name) error_msg_and_die("can't create an inode with an empty name"); if(strchr(name, '/')) error_msg_and_die("bad name '%s' (contains a slash)", name); nlen = strlen(name); reclen = sizeof(directory) + rndup(nlen, 4); if(reclen > BLOCKSIZE) error_msg_and_die("bad name '%s' (too long)", name); init_bw(&bw); while((bk = walk_bw(fs, dnod, &bw, 0, 0)) != WALK_END) // for all blocks in dir { b = get_blk(fs, bk); // for all dir entries in block for(d = (directory*)b; (int8*)d + sizeof(*d) < (int8*)b + BLOCKSIZE; d = (directory*)((int8*)d + d->d_rec_len)) { // if empty dir entry, large enough, use it if((!d->d_inode) && (d->d_rec_len >= reclen)) { d->d_inode = nod; node = get_nod(fs, nod); node->i_links_count++; d->d_name_len = nlen; strncpy(d->d_name, name, nlen); return; } // if entry with enough room (last one?), shrink it & use it if(d->d_rec_len >= (sizeof(directory) + rndup(d->d_name_len, 4) + reclen)) { reclen = d->d_rec_len; d->d_rec_len = sizeof(directory) + rndup(d->d_name_len, 4); reclen -= d->d_rec_len; d = (directory*) (((int8*)d) + d->d_rec_len); d->d_rec_len = reclen; d->d_inode = nod; node = get_nod(fs, nod); node->i_links_count++; d->d_name_len = nlen; strncpy(d->d_name, name, nlen); return; } } } // we found no free entry in the directory, so we add a block if(!(b = get_workblk())) error_msg_and_die("get_workblk() failed."); d = (directory*)b; d->d_inode = nod; node = get_nod(fs, nod); node->i_links_count++; d->d_rec_len = BLOCKSIZE; d->d_name_len = nlen; strncpy(d->d_name, name, nlen); extend_blk(fs, dnod, b, 1); get_nod(fs, dnod)->i_size += BLOCKSIZE; free_workblk(b); } // find an entry in a directory static uint32 find_dir(filesystem *fs, uint32 nod, const char * name) { blockwalker bw; uint32 bk; int nlen = strlen(name); init_bw(&bw); while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) { directory *d; uint8 *b; b = get_blk(fs, bk); for(d = (directory*)b; (int8*)d + sizeof(*d) < (int8*)b + BLOCKSIZE; d = (directory*)((int8*)d + d->d_rec_len)) if(d->d_inode && (nlen == d->d_name_len) && !strncmp(d->d_name, name, nlen)) return d->d_inode; } return 0; } // find the inode of a full path static uint32 find_path(filesystem *fs, uint32 nod, const char * name) { char *p, *n, *n2 = xstrdup(name); n = n2; while(*n == '/') { nod = EXT2_ROOT_INO; n++; } while(*n) { if((p = strchr(n, '/'))) (*p) = 0; if(!(nod = find_dir(fs, nod, n))) break; if(p) n = p + 1; else break; } free(n2); return nod; } // chmod an inode void chmod_fs(filesystem *fs, uint32 nod, uint16 mode, uint16 uid, uint16 gid) { inode *node; node = get_nod(fs, nod); node->i_mode = (node->i_mode & ~FM_IMASK) | (mode & FM_IMASK); node->i_uid = uid; node->i_gid = gid; } // create a simple inode static uint32 mknod_fs(filesystem *fs, uint32 parent_nod, const char *name, uint16 mode, uint16 uid, uint16 gid, uint8 major, uint8 minor, uint32 ctime, uint32 mtime) { uint32 nod; inode *node; { nod = alloc_nod(fs); node = get_nod(fs, nod); node->i_mode = mode; add2dir(fs, parent_nod, nod, name); switch(mode & FM_IFMT) { case FM_IFLNK: mode = FM_IFLNK | FM_IRWXU | FM_IRWXG | FM_IRWXO; break; case FM_IFBLK: case FM_IFCHR: ((uint8*)get_nod(fs, nod)->i_block)[0] = minor; ((uint8*)get_nod(fs, nod)->i_block)[1] = major; break; case FM_IFDIR: add2dir(fs, nod, nod, "."); add2dir(fs, nod, parent_nod, ".."); fs->gd[GRP_GROUP_OF_INODE(fs,nod)].bg_used_dirs_count++; break; } } node->i_uid = uid; node->i_gid = gid; node->i_atime = mtime; node->i_ctime = ctime; node->i_mtime = mtime; return nod; } // make a full-fledged directory (i.e. with "." & "..") static inline uint32 mkdir_fs(filesystem *fs, uint32 parent_nod, const char *name, uint32 mode, uid_t uid, gid_t gid, uint32 ctime, uint32 mtime) { return mknod_fs(fs, parent_nod, name, mode|FM_IFDIR, uid, gid, 0, 0, ctime, mtime); } // make a symlink static uint32 mklink_fs(filesystem *fs, uint32 parent_nod, const char *name, size_t size, uint8 *b, uid_t uid, gid_t gid, uint32 ctime, uint32 mtime) { uint32 nod = mknod_fs(fs, parent_nod, name, FM_IFLNK | FM_IRWXU | FM_IRWXG | FM_IRWXO, uid, gid, 0, 0, ctime, mtime); extend_blk(fs, nod, 0, - (int)get_nod(fs, nod)->i_blocks / INOBLK); get_nod(fs, nod)->i_size = size; if(size <= 4 * (EXT2_TIND_BLOCK+1)) { strncpy((char*)get_nod(fs, nod)->i_block, (char*)b, size); return nod; } extend_blk(fs, nod, b, rndup(size, BLOCKSIZE) / BLOCKSIZE); return nod; } // make a file from a FILE* static uint32 mkfile_fs(filesystem *fs, uint32 parent_nod, const char *name, uint32 mode, size_t size, FILE *f, uid_t uid, gid_t gid, uint32 ctime, uint32 mtime) { uint8 * b; uint32 nod = mknod_fs(fs, parent_nod, name, mode|FM_IFREG, uid, gid, 0, 0, ctime, mtime); extend_blk(fs, nod, 0, - (int)get_nod(fs, nod)->i_blocks / INOBLK); get_nod(fs, nod)->i_size = size; if (size) { if(!(b = (uint8*)calloc(rndup(size, BLOCKSIZE), 1))) error_msg_and_die("not enough mem to read file '%s'", name); if(f) fread(b, size, 1, f); // FIXME: ugly. use mmap() ... extend_blk(fs, nod, b, rndup(size, BLOCKSIZE) / BLOCKSIZE); free(b); } return nod; } // retrieves a mode info from a struct stat static uint32 get_mode(struct stat *st) { uint32 mode = 0; if(st->st_mode & S_IRUSR) mode |= FM_IRUSR; if(st->st_mode & S_IWUSR) mode |= FM_IWUSR; if(st->st_mode & S_IXUSR) mode |= FM_IXUSR; if(st->st_mode & S_IRGRP) mode |= FM_IRGRP; if(st->st_mode & S_IWGRP) mode |= FM_IWGRP; if(st->st_mode & S_IXGRP) mode |= FM_IXGRP; if(st->st_mode & S_IROTH) mode |= FM_IROTH; if(st->st_mode & S_IWOTH) mode |= FM_IWOTH; if(st->st_mode & S_IXOTH) mode |= FM_IXOTH; if(st->st_mode & S_ISUID) mode |= FM_ISUID; if(st->st_mode & S_ISGID) mode |= FM_ISGID; if(st->st_mode & S_ISVTX) mode |= FM_ISVTX; return mode; } // add or fixup entries to the filesystem from a text file /* device table entries take the form of: <path> <type> <mode> <uid> <gid> <major> <minor> <start> <inc> <count> /dev/mem c 640 0 0 1 1 0 0 - type can be one of: f A regular file d Directory c Character special device file b Block special device file p Fifo (named pipe) I don't bother with symlinks (permissions are irrelevant), hard links (special cases of regular files), or sockets (why bother). Regular files must exist in the target root directory. If a char, block, fifo, or directory does not exist, it will be created. */ static void add2fs_from_file(filesystem *fs, uint32 this_nod, FILE * fh, uint32 fs_timestamp, struct stats *stats) { unsigned long mode, uid, gid, major, minor; unsigned long start, increment, count; uint32 nod, ctime, mtime; char *c, type, *path = NULL, *path2 = NULL, *dir, *name, *line = NULL; size_t len; struct stat st; int nbargs, lineno = 0; fstat(fileno(fh), &st); ctime = fs_timestamp; mtime = st.st_mtime; while(getline(&line, &len, fh) >= 0) { mode = uid = gid = major = minor = 0; start = 0; increment = 1; count = 0; lineno++; if((c = strchr(line, '#'))) *c = 0; if (path) { free(path); path = NULL; } if (path2) { free(path2); path2 = NULL; } nbargs = sscanf (line, "%" SCANF_PREFIX "s %c %lo %lu %lu %lu %lu %lu %lu %lu", SCANF_STRING(path), &type, &mode, &uid, &gid, &major, &minor, &start, &increment, &count); if(nbargs < 3) { if(nbargs > 0) error_msg("device table line %d skipped: bad format for entry '%s'", lineno, path); continue; } mode &= FM_IMASK; path2 = strdup(path); name = basename(path); dir = dirname(path2); if((!strcmp(name, ".")) || (!strcmp(name, ".."))) { error_msg("device table line %d skipped", lineno); continue; } if(fs) { if(!(nod = find_path(fs, this_nod, dir))) { error_msg("device table line %d skipped: can't find directory '%s' to create '%s''", lineno, dir, name); continue; } } else nod = 0; switch (type) { case 'd': mode |= FM_IFDIR; break; case 'f': mode |= FM_IFREG; break; case 'p': mode |= FM_IFIFO; break; case 's': mode |= FM_IFSOCK; break; case 'c': mode |= FM_IFCHR; break; case 'b': mode |= FM_IFBLK; break; default: error_msg("device table line %d skipped: bad type '%c' for entry '%s'", lineno, type, name); continue; } if(stats) { if(count > 0) stats->ninodes += count - start; else stats->ninodes++; } else { if(count > 0) { char *dname; unsigned long i; unsigned len; len = strlen(name) + 10; dname = malloc(len + 1); for(i = start; i < count; i++) { uint32 oldnod; SNPRINTF(dname, len, "%s%lu", name, i); oldnod = find_dir(fs, nod, dname); if(oldnod) chmod_fs(fs, oldnod, mode, uid, gid); else mknod_fs(fs, nod, dname, mode, uid, gid, major, minor + (i * increment - start), ctime, mtime); } free(dname); } else { uint32 oldnod = find_dir(fs, nod, name); if(oldnod) chmod_fs(fs, oldnod, mode, uid, gid); else mknod_fs(fs, nod, name, mode, uid, gid, major, minor, ctime, mtime); } } } if (line) free(line); if (path) free(path); if (path2) free(path2); } static void prep_stat(const char *root_path) { int len = strlen(root_path); if((len >= 4) && (!strcmp(root_path + len - 4, "data"))) { source_path_len = len - 4; } else if((len >= 7) && (!strcmp(root_path + len - 6, "system"))) { source_path_len = len - 6; } else { error_msg_and_die("Fixstats (-a) option requested but " "filesystem is not data or android!"); } } static void fix_stat(const char *path, struct stat *s) { path += source_path_len; fs_config(path, S_ISDIR(s->st_mode), &s->st_uid, &s->st_gid, &s->st_mode); } // adds a tree of entries to the filesystem from current dir static void add2fs_from_dir(filesystem *fs, const char *path, uint32 this_nod, int squash_uids, int squash_perms, int fixstats, uint32 fs_timestamp, struct stats *stats) { uint32 nod; uint32 uid, gid, mode, ctime, mtime; const char *name; FILE *fh; DIR *dh; struct dirent *dent; struct stat st; char *lnk; uint32 save_nod; char full_name[2048]; if(!(dh = opendir("."))) perror_msg_and_die("."); while((dent = readdir(dh))) { if((!strcmp(dent->d_name, ".")) || (!strcmp(dent->d_name, ".."))) continue; lstat(dent->d_name, &st); if(fixstats) { int tmp = snprintf(full_name, sizeof(full_name), "%s/%s", path, dent->d_name); if(tmp >= (int)sizeof(full_name)) error_msg_and_die("Path too long!"); fix_stat(full_name, &st); } else full_name[0] = '\0'; uid = st.st_uid; gid = st.st_gid; ctime = fs_timestamp; mtime = st.st_mtime; name = dent->d_name; mode = get_mode(&st); if(squash_uids) uid = gid = 0; if(squash_perms) mode &= ~(FM_IRWXG | FM_IRWXO); if(stats) switch(st.st_mode & S_IFMT) { case S_IFLNK: case S_IFREG: if((st.st_mode & S_IFMT) == S_IFREG || st.st_size > 4 * (EXT2_TIND_BLOCK+1)) stats->nblocks += (st.st_size + BLOCKSIZE - 1) / BLOCKSIZE; case S_IFCHR: case S_IFBLK: case S_IFIFO: case S_IFSOCK: stats->ninodes++; break; case S_IFDIR: stats->ninodes++; if(chdir(dent->d_name) < 0) perror_msg_and_die(dent->d_name); add2fs_from_dir(fs, full_name, this_nod, squash_uids, squash_perms, fixstats, fs_timestamp, stats); chdir(".."); break; default: break; } else { if((nod = find_dir(fs, this_nod, name))) { error_msg("ignoring duplicate entry %s", name); if(S_ISDIR(st.st_mode)) { if(chdir(dent->d_name) < 0) perror_msg_and_die(name); add2fs_from_dir(fs, full_name, nod, squash_uids, squash_perms, fixstats, fs_timestamp, stats); chdir(".."); } continue; } save_nod = 0; /* Check for hardlinks */ if (!S_ISDIR(st.st_mode) && !S_ISLNK(st.st_mode) && st.st_nlink > 1) { int32 hdlink = is_hardlink(st.st_ino); if (hdlink >= 0) { add2dir(fs, this_nod, hdlinks.hdl[hdlink].dst_nod, name); continue; } else { save_nod = 1; } } switch(st.st_mode & S_IFMT) { #if HAVE_STRUCT_STAT_ST_RDEV case S_IFCHR: nod = mknod_fs(fs, this_nod, name, mode|FM_IFCHR, uid, gid, major(st.st_rdev), minor(st.st_rdev), ctime, mtime); break; case S_IFBLK: nod = mknod_fs(fs, this_nod, name, mode|FM_IFBLK, uid, gid, major(st.st_rdev), minor(st.st_rdev), ctime, mtime); break; #endif case S_IFIFO: nod = mknod_fs(fs, this_nod, name, mode|FM_IFIFO, uid, gid, 0, 0, ctime, mtime); break; case S_IFSOCK: nod = mknod_fs(fs, this_nod, name, mode|FM_IFSOCK, uid, gid, 0, 0, ctime, mtime); break; case S_IFLNK: lnk = xreadlink(dent->d_name); mklink_fs(fs, this_nod, name, st.st_size, (uint8*)lnk, uid, gid, ctime, mtime); free(lnk); break; case S_IFREG: fh = xfopen(dent->d_name, "rb"); nod = mkfile_fs(fs, this_nod, name, mode, st.st_size, fh, uid, gid, ctime, mtime); fclose(fh); break; case S_IFDIR: nod = mkdir_fs(fs, this_nod, name, mode, uid, gid, ctime, mtime); if(chdir(dent->d_name) < 0) perror_msg_and_die(name); add2fs_from_dir(fs, full_name, nod, squash_uids, squash_perms, fixstats, fs_timestamp, stats); chdir(".."); break; default: error_msg("ignoring entry %s", name); } if (save_nod) { if (hdlinks.count == hdlink_cnt) { if ((hdlinks.hdl = realloc (hdlinks.hdl, (hdlink_cnt + HDLINK_CNT) * sizeof (struct hdlink_s))) == NULL) { error_msg_and_die("Not enough memory"); } hdlink_cnt += HDLINK_CNT; } hdlinks.hdl[hdlinks.count].src_inode = st.st_ino; hdlinks.hdl[hdlinks.count].dst_nod = nod; hdlinks.count++; } } } closedir(dh); } // endianness swap of x-indirect blocks static void swap_goodblocks(filesystem *fs, inode *nod) { uint32 i,j; int done=0; uint32 *b,*b2; uint32 nblk = nod->i_blocks / INOBLK; if((nod->i_size && !nblk) || ((nod->i_mode & FM_IFBLK) == FM_IFBLK) || ((nod->i_mode & FM_IFCHR) == FM_IFCHR)) for(i = 0; i <= EXT2_TIND_BLOCK; i++) nod->i_block[i] = swab32(nod->i_block[i]); if(nblk <= EXT2_IND_BLOCK) return; swap_block(get_blk(fs, nod->i_block[EXT2_IND_BLOCK])); if(nblk <= EXT2_DIND_BLOCK + BLOCKSIZE/4) return; /* Currently this will fail b'cos the number of blocks as stored in i_blocks also includes the indirection blocks (see walk_bw). But this function assumes that i_blocks only stores the count of data blocks ( Actually according to "Understanding the Linux Kernel" (Table 17-3 p502 1st Ed) i_blocks IS supposed to store the count of data blocks). so with a file of size 268K nblk would be 269.The above check will be false even though double indirection hasn't been started.This is benign as 0 means block 0 which has been zeroed out and therefore points back to itself from any offset */ // FIXME: I have fixed that, but I have the feeling the rest of // ths function needs to be fixed for the same reasons - Xav assert(nod->i_block[EXT2_DIND_BLOCK] != 0); for(i = 0; i < BLOCKSIZE/4; i++) if(nblk > EXT2_IND_BLOCK + BLOCKSIZE/4 + (BLOCKSIZE/4)*i ) swap_block(get_blk(fs, ((uint32*)get_blk(fs, nod->i_block[EXT2_DIND_BLOCK]))[i])); swap_block(get_blk(fs, nod->i_block[EXT2_DIND_BLOCK])); if(nblk <= EXT2_IND_BLOCK + BLOCKSIZE/4 + BLOCKSIZE/4 * BLOCKSIZE/4) return; /* Adding support for triple indirection */ b = (uint32*)get_blk(fs,nod->i_block[EXT2_TIND_BLOCK]); for(i=0;i < BLOCKSIZE/4 && !done ; i++) { b2 = (uint32*)get_blk(fs,b[i]); for(j=0; j<BLOCKSIZE/4;j++) { if (nblk > ( EXT2_IND_BLOCK + BLOCKSIZE/4 + (BLOCKSIZE/4)*(BLOCKSIZE/4) + i*(BLOCKSIZE/4)*(BLOCKSIZE/4) + j*(BLOCKSIZE/4)) ) swap_block(get_blk(fs,b2[j])); else { done = 1; break; } } swap_block((uint8 *)b2); } swap_block((uint8 *)b); return; } static void swap_badblocks(filesystem *fs, inode *nod) { uint32 i,j; int done=0; uint32 *b,*b2; uint32 nblk = nod->i_blocks / INOBLK; if((nod->i_size && !nblk) || ((nod->i_mode & FM_IFBLK) == FM_IFBLK) || ((nod->i_mode & FM_IFCHR) == FM_IFCHR)) for(i = 0; i <= EXT2_TIND_BLOCK; i++) nod->i_block[i] = swab32(nod->i_block[i]); if(nblk <= EXT2_IND_BLOCK) return; swap_block(get_blk(fs, nod->i_block[EXT2_IND_BLOCK])); if(nblk <= EXT2_DIND_BLOCK + BLOCKSIZE/4) return; /* See comment in swap_goodblocks */ assert(nod->i_block[EXT2_DIND_BLOCK] != 0); swap_block(get_blk(fs, nod->i_block[EXT2_DIND_BLOCK])); for(i = 0; i < BLOCKSIZE/4; i++) if(nblk > EXT2_IND_BLOCK + BLOCKSIZE/4 + (BLOCKSIZE/4)*i ) swap_block(get_blk(fs, ((uint32*)get_blk(fs, nod->i_block[EXT2_DIND_BLOCK]))[i])); if(nblk <= EXT2_IND_BLOCK + BLOCKSIZE/4 + BLOCKSIZE/4 * BLOCKSIZE/4) return; /* Adding support for triple indirection */ b = (uint32*)get_blk(fs,nod->i_block[EXT2_TIND_BLOCK]); swap_block((uint8 *)b); for(i=0;i < BLOCKSIZE/4 && !done ; i++) { b2 = (uint32*)get_blk(fs,b[i]); swap_block((uint8 *)b2); for(j=0; j<BLOCKSIZE/4;j++) { if (nblk > ( EXT2_IND_BLOCK + BLOCKSIZE/4 + (BLOCKSIZE/4)*(BLOCKSIZE/4) + i*(BLOCKSIZE/4)*(BLOCKSIZE/4) + j*(BLOCKSIZE/4)) ) swap_block(get_blk(fs,b2[j])); else { done = 1; break; } } } return; } // endianness swap of the whole filesystem static void swap_goodfs(filesystem *fs) { uint32 i; for(i = 1; i < fs->sb.s_inodes_count; i++) { inode *nod = get_nod(fs, i); if(nod->i_mode & FM_IFDIR) { blockwalker bw; uint32 bk; init_bw(&bw); while((bk = walk_bw(fs, i, &bw, 0, 0)) != WALK_END) { directory *d; uint8 *b; b = get_blk(fs, bk); for(d = (directory*)b; (int8*)d + sizeof(*d) < (int8*)b + BLOCKSIZE; d = (directory*)((int8*)d + swab16(d->d_rec_len))) swap_dir(d); } } swap_goodblocks(fs, nod); swap_nod(nod); } for(i=0;i<GRP_NBGROUPS(fs);i++) swap_gd(&(fs->gd[i])); swap_sb(&fs->sb); } static void swap_badfs(filesystem *fs) { uint32 i; swap_sb(&fs->sb); for(i=0;i<GRP_NBGROUPS(fs);i++) swap_gd(&(fs->gd[i])); for(i = 1; i < fs->sb.s_inodes_count; i++) { inode *nod = get_nod(fs, i); swap_nod(nod); swap_badblocks(fs, nod); if(nod->i_mode & FM_IFDIR) { blockwalker bw; uint32 bk; init_bw(&bw); while((bk = walk_bw(fs, i, &bw, 0, 0)) != WALK_END) { directory *d; uint8 *b; b = get_blk(fs, bk); for(d = (directory*)b; (int8*)d + sizeof(*d) < (int8*)b + BLOCKSIZE; d = (directory*)((int8*)d + d->d_rec_len)) swap_dir(d); } } } } // initialize an empty filesystem static filesystem * init_fs(int nbblocks, int nbinodes, int nbresrvd, int holes, uint32 fs_timestamp) { uint32 i; filesystem *fs; directory *d; uint8 * b; uint32 nod, first_block; uint32 nbgroups,nbinodes_per_group,overhead_per_group,free_blocks, free_blocks_per_group,nbblocks_per_group,min_nbgroups; uint32 gdsz,itblsz,bbmpos,ibmpos,itblpos; uint32 j; uint8 *bbm,*ibm; inode *itab0; if(nbresrvd < 0) error_msg_and_die("reserved blocks value is invalid. Note: options have changed, see --help or the man page."); if(nbinodes < EXT2_FIRST_INO - 1 + (nbresrvd ? 1 : 0)) error_msg_and_die("too few inodes. Note: options have changed, see --help or the man page."); if(nbblocks < 8) error_msg_and_die("too few blocks. Note: options have changed, see --help or the man page."); /* nbinodes is the total number of inodes in the system. * a block group can have no more than 8192 inodes. */ min_nbgroups = (nbinodes + INODES_PER_GROUP - 1) / INODES_PER_GROUP; /* nbblocks is the total number of blocks in the filesystem. * a block group can have no more than 8192 blocks. */ first_block = (BLOCKSIZE == 1024); nbgroups = (nbblocks - first_block + BLOCKS_PER_GROUP - 1) / BLOCKS_PER_GROUP; if(nbgroups < min_nbgroups) nbgroups = min_nbgroups; nbblocks_per_group = rndup((nbblocks - first_block + nbgroups - 1)/nbgroups, 8); nbinodes_per_group = rndup((nbinodes + nbgroups - 1)/nbgroups, (BLOCKSIZE/sizeof(inode))); if (nbinodes_per_group < 16) nbinodes_per_group = 16; //minimum number b'cos the first 10 are reserved gdsz = rndup(nbgroups*sizeof(groupdescriptor),BLOCKSIZE)/BLOCKSIZE; itblsz = nbinodes_per_group * sizeof(inode)/BLOCKSIZE; overhead_per_group = 3 /*sb,bbm,ibm*/ + gdsz + itblsz; if((uint32)nbblocks - 1 < overhead_per_group * nbgroups) error_msg_and_die("too much overhead, try fewer inodes or more blocks. Note: options have changed, see --help or the man page."); free_blocks = nbblocks - overhead_per_group*nbgroups - 1 /*boot block*/; free_blocks_per_group = nbblocks_per_group - overhead_per_group; if(!(fs = (filesystem*)calloc(nbblocks, BLOCKSIZE))) error_msg_and_die("not enough memory for filesystem"); // create the superblock for an empty filesystem fs->sb.s_inodes_count = nbinodes_per_group * nbgroups; fs->sb.s_blocks_count = nbblocks; fs->sb.s_r_blocks_count = nbresrvd; fs->sb.s_free_blocks_count = free_blocks; fs->sb.s_free_inodes_count = fs->sb.s_inodes_count - EXT2_FIRST_INO + 1; fs->sb.s_first_data_block = first_block; fs->sb.s_log_block_size = BLOCKSIZE >> 11; fs->sb.s_log_frag_size = BLOCKSIZE >> 11; fs->sb.s_blocks_per_group = nbblocks_per_group; fs->sb.s_frags_per_group = nbblocks_per_group; fs->sb.s_inodes_per_group = nbinodes_per_group; fs->sb.s_wtime = fs_timestamp; fs->sb.s_magic = EXT2_MAGIC_NUMBER; fs->sb.s_lastcheck = fs_timestamp; // set up groupdescriptors for(i=0, bbmpos=gdsz+2, ibmpos=bbmpos+1, itblpos=ibmpos+1; i<nbgroups; i++, bbmpos+=nbblocks_per_group, ibmpos+=nbblocks_per_group, itblpos+=nbblocks_per_group) { if(free_blocks > free_blocks_per_group) { fs->gd[i].bg_free_blocks_count = free_blocks_per_group; free_blocks -= free_blocks_per_group; } else { fs->gd[i].bg_free_blocks_count = free_blocks; free_blocks = 0; // this is the last block group } if(i) fs->gd[i].bg_free_inodes_count = nbinodes_per_group; else fs->gd[i].bg_free_inodes_count = nbinodes_per_group - EXT2_FIRST_INO + 2; fs->gd[i].bg_used_dirs_count = 0; fs->gd[i].bg_block_bitmap = bbmpos; fs->gd[i].bg_inode_bitmap = ibmpos; fs->gd[i].bg_inode_table = itblpos; } /* Mark non-filesystem blocks and inodes as allocated */ /* Mark system blocks and inodes as allocated */ for(i = 0; i<nbgroups;i++) { /* Block bitmap */ bbm = get_blk(fs,fs->gd[i].bg_block_bitmap); //non-filesystem blocks for(j = fs->gd[i].bg_free_blocks_count + overhead_per_group + 1; j <= BLOCKSIZE * 8; j++) allocate(bbm, j); //system blocks for(j = 1; j <= overhead_per_group; j++) allocate(bbm, j); /* Inode bitmap */ ibm = get_blk(fs,fs->gd[i].bg_inode_bitmap); //non-filesystem inodes for(j = fs->sb.s_inodes_per_group+1; j <= BLOCKSIZE * 8; j++) allocate(ibm, j); //system inodes if(i == 0) for(j = 1; j < EXT2_FIRST_INO; j++) allocate(ibm, j); } // make root inode and directory /* We have groups now. Add the root filesystem in group 0 */ /* Also increment the directory count for group 0 */ fs->gd[0].bg_free_inodes_count--; fs->gd[0].bg_used_dirs_count = 1; itab0 = (inode *)get_blk(fs,fs->gd[0].bg_inode_table); itab0[EXT2_ROOT_INO-1].i_mode = FM_IFDIR | FM_IRWXU | FM_IRGRP | FM_IROTH | FM_IXGRP | FM_IXOTH; itab0[EXT2_ROOT_INO-1].i_ctime = fs_timestamp; itab0[EXT2_ROOT_INO-1].i_mtime = fs_timestamp; itab0[EXT2_ROOT_INO-1].i_atime = fs_timestamp; itab0[EXT2_ROOT_INO-1].i_size = BLOCKSIZE; itab0[EXT2_ROOT_INO-1].i_links_count = 2; if(!(b = get_workblk())) error_msg_and_die("get_workblk() failed."); d = (directory*)b; d->d_inode = EXT2_ROOT_INO; d->d_rec_len = sizeof(directory)+4; d->d_name_len = 1; strcpy(d->d_name, "."); d = (directory*)(b + d->d_rec_len); d->d_inode = EXT2_ROOT_INO; d->d_rec_len = BLOCKSIZE - (sizeof(directory)+4); d->d_name_len = 2; strcpy(d->d_name, ".."); extend_blk(fs, EXT2_ROOT_INO, b, 1); // make lost+found directory and reserve blocks if(fs->sb.s_r_blocks_count) { nod = mkdir_fs(fs, EXT2_ROOT_INO, "lost+found", FM_IRWXU, 0, 0, fs_timestamp, fs_timestamp); memset(b, 0, BLOCKSIZE); ((directory*)b)->d_rec_len = BLOCKSIZE; /* We run into problems with e2fsck if directory lost+found grows * bigger than this. Need to find out why this happens - sundar */ if (fs->sb.s_r_blocks_count > fs->sb.s_blocks_count * MAX_RESERVED_BLOCKS ) fs->sb.s_r_blocks_count = fs->sb.s_blocks_count * MAX_RESERVED_BLOCKS; for(i = 1; i < fs->sb.s_r_blocks_count; i++) extend_blk(fs, nod, b, 1); get_nod(fs, nod)->i_size = fs->sb.s_r_blocks_count * BLOCKSIZE; } free_workblk(b); // administrative info fs->sb.s_state = 1; fs->sb.s_max_mnt_count = 20; // options for me if(holes) fs->sb.s_reserved[200] |= OP_HOLES; return fs; } // loads a filesystem from disk static filesystem * load_fs(FILE * fh, int swapit) { size_t fssize; filesystem *fs; if((fseek(fh, 0, SEEK_END) < 0) || ((ssize_t)(fssize = ftell(fh)) == -1)) perror_msg_and_die("input filesystem image"); rewind(fh); fssize = (fssize + BLOCKSIZE - 1) / BLOCKSIZE; if(fssize < 16) // totally arbitrary error_msg_and_die("too small filesystem"); if(!(fs = (filesystem*)calloc(fssize, BLOCKSIZE))) error_msg_and_die("not enough memory for filesystem"); if(fread(fs, BLOCKSIZE, fssize, fh) != fssize) perror_msg_and_die("input filesystem image"); if(swapit) swap_badfs(fs); if(fs->sb.s_rev_level || (fs->sb.s_magic != EXT2_MAGIC_NUMBER)) error_msg_and_die("not a suitable ext2 filesystem"); return fs; } static void free_fs(filesystem *fs) { free(fs); } // just walk through blocks list static void flist_blocks(filesystem *fs, uint32 nod, FILE *fh) { blockwalker bw; uint32 bk; init_bw(&bw); while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) fprintf(fh, " %d", bk); fprintf(fh, "\n"); } // walk through blocks list static void list_blocks(filesystem *fs, uint32 nod) { int bn = 0; blockwalker bw; uint32 bk; init_bw(&bw); printf("blocks in inode %d:", nod); while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) printf(" %d", bk), bn++; printf("\n%d blocks (%d bytes)\n", bn, bn * BLOCKSIZE); } // saves blocks to FILE* static void write_blocks(filesystem *fs, uint32 nod, FILE* f) { blockwalker bw; uint32 bk; int32 fsize = get_nod(fs, nod)->i_size; init_bw(&bw); while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) { if(fsize <= 0) error_msg_and_die("wrong size while saving inode %d", nod); if(fwrite(get_blk(fs, bk), (fsize > BLOCKSIZE) ? BLOCKSIZE : fsize, 1, f) != 1) error_msg_and_die("error while saving inode %d", nod); fsize -= BLOCKSIZE; } } // print block/char device minor and major static void print_dev(filesystem *fs, uint32 nod) { int minor, major; minor = ((uint8*)get_nod(fs, nod)->i_block)[0]; major = ((uint8*)get_nod(fs, nod)->i_block)[1]; printf("major: %d, minor: %d\n", major, minor); } // print an inode as a directory static void print_dir(filesystem *fs, uint32 nod) { blockwalker bw; uint32 bk; init_bw(&bw); printf("directory for inode %d:\n", nod); while((bk = walk_bw(fs, nod, &bw, 0, 0)) != WALK_END) { directory *d; uint8 *b; b = get_blk(fs, bk); for(d = (directory*)b; (int8*)d + sizeof(*d) < (int8*)b + BLOCKSIZE; d = (directory*)((int8*)d + d->d_rec_len)) if(d->d_inode) { int i; printf("entry '"); for(i = 0; i < d->d_name_len; i++) putchar(d->d_name[i]); printf("' (inode %d): rec_len: %d (name_len: %d)\n", d->d_inode, d->d_rec_len, d->d_name_len); } } } // print a symbolic link static void print_link(filesystem *fs, uint32 nod) { if(!get_nod(fs, nod)->i_blocks) printf("links to '%s'\n", (char*)get_nod(fs, nod)->i_block); else { printf("links to '"); write_blocks(fs, nod, stdout); printf("'\n"); } } // make a ls-like printout of permissions static void make_perms(uint32 mode, char perms[11]) { strcpy(perms, "----------"); if(mode & FM_IRUSR) perms[1] = 'r'; if(mode & FM_IWUSR) perms[2] = 'w'; if(mode & FM_IXUSR) perms[3] = 'x'; if(mode & FM_IRGRP) perms[4] = 'r'; if(mode & FM_IWGRP) perms[5] = 'w'; if(mode & FM_IXGRP) perms[6] = 'x'; if(mode & FM_IROTH) perms[7] = 'r'; if(mode & FM_IWOTH) perms[8] = 'w'; if(mode & FM_IXOTH) perms[9] = 'x'; if(mode & FM_ISUID) perms[3] = 's'; if(mode & FM_ISGID) perms[6] = 's'; if(mode & FM_ISVTX) perms[9] = 't'; switch(mode & FM_IFMT) { case 0: *perms = '0'; break; case FM_IFSOCK: *perms = 's'; break; case FM_IFLNK: *perms = 'l'; break; case FM_IFREG: *perms = '-'; break; case FM_IFBLK: *perms = 'b'; break; case FM_IFDIR: *perms = 'd'; break; case FM_IFCHR: *perms = 'c'; break; case FM_IFIFO: *perms = 'p'; break; default: *perms = '?'; } } // print an inode static void print_inode(filesystem *fs, uint32 nod) { char *s; char perms[11]; if(!get_nod(fs, nod)->i_mode) return; switch(nod) { case EXT2_BAD_INO: s = "bad blocks"; break; case EXT2_ROOT_INO: s = "root"; break; case EXT2_ACL_IDX_INO: case EXT2_ACL_DATA_INO: s = "ACL"; break; case EXT2_BOOT_LOADER_INO: s = "boot loader"; break; case EXT2_UNDEL_DIR_INO: s = "undelete directory"; break; default: s = (nod >= EXT2_FIRST_INO) ? "normal" : "unknown reserved"; } printf("inode %d (%s, %d links): ", nod, s, get_nod(fs, nod)->i_links_count); if(!allocated(GRP_GET_INODE_BITMAP(fs,nod), GRP_IBM_OFFSET(fs,nod))) { printf("unallocated\n"); return; } make_perms(get_nod(fs, nod)->i_mode, perms); printf("%s, size: %d byte%s (%d block%s)\n", perms, plural(get_nod(fs, nod)->i_size), plural(get_nod(fs, nod)->i_blocks / INOBLK)); switch(get_nod(fs, nod)->i_mode & FM_IFMT) { case FM_IFSOCK: list_blocks(fs, nod); break; case FM_IFLNK: print_link(fs, nod); break; case FM_IFREG: list_blocks(fs, nod); break; case FM_IFBLK: print_dev(fs, nod); break; case FM_IFDIR: list_blocks(fs, nod); print_dir(fs, nod); break; case FM_IFCHR: print_dev(fs, nod); break; case FM_IFIFO: list_blocks(fs, nod); break; default: list_blocks(fs, nod); } printf("Done with inode %d\n",nod); } // describes various fields in a filesystem static void print_fs(filesystem *fs) { uint32 i; uint8 *ibm; printf("%d blocks (%d free, %d reserved), first data block: %d\n", fs->sb.s_blocks_count, fs->sb.s_free_blocks_count, fs->sb.s_r_blocks_count, fs->sb.s_first_data_block); printf("%d inodes (%d free)\n", fs->sb.s_inodes_count, fs->sb.s_free_inodes_count); printf("block size = %d, frag size = %d\n", fs->sb.s_log_block_size ? (fs->sb.s_log_block_size << 11) : 1024, fs->sb.s_log_frag_size ? (fs->sb.s_log_frag_size << 11) : 1024); printf("number of groups: %d\n",GRP_NBGROUPS(fs)); printf("%d blocks per group,%d frags per group,%d inodes per group\n", fs->sb.s_blocks_per_group, fs->sb.s_frags_per_group, fs->sb.s_inodes_per_group); printf("Size of inode table: %d blocks\n", (int)(fs->sb.s_inodes_per_group * sizeof(inode) / BLOCKSIZE)); for (i = 0; i < GRP_NBGROUPS(fs); i++) { printf("Group No: %d\n", i+1); printf("block bitmap: block %d,inode bitmap: block %d, inode table: block %d\n", fs->gd[i].bg_block_bitmap, fs->gd[i].bg_inode_bitmap, fs->gd[i].bg_inode_table); printf("block bitmap allocation:\n"); print_bm(GRP_GET_GROUP_BBM(fs, i),fs->sb.s_blocks_per_group); printf("inode bitmap allocation:\n"); ibm = GRP_GET_GROUP_IBM(fs, i); print_bm(ibm, fs->sb.s_inodes_per_group); for (i = 1; i <= fs->sb.s_inodes_per_group; i++) if (allocated(ibm, i)) print_inode(fs, i); } } static void dump_fs(filesystem *fs, FILE * fh, int swapit) { uint32 nbblocks = fs->sb.s_blocks_count; fs->sb.s_reserved[200] = 0; if(swapit) swap_goodfs(fs); if(fwrite(fs, BLOCKSIZE, nbblocks, fh) < nbblocks) perror_msg_and_die("output filesystem image"); if(swapit) swap_badfs(fs); } static void populate_fs(filesystem *fs, char **dopt, int didx, int squash_uids, int squash_perms, int fixstats, uint32 fs_timestamp, struct stats *stats) { int i; for(i = 0; i < didx; i++) { struct stat st; FILE *fh; int pdir; char *pdest; uint32 nod = EXT2_ROOT_INO; if(fs) if((pdest = strchr(dopt[i], ':'))) { *(pdest++) = 0; if(!(nod = find_path(fs, EXT2_ROOT_INO, pdest))) error_msg_and_die("path %s not found in filesystem", pdest); } stat(dopt[i], &st); switch(st.st_mode & S_IFMT) { case S_IFREG: fh = xfopen(dopt[i], "rb"); add2fs_from_file(fs, nod, fh, fs_timestamp, stats); fclose(fh); break; case S_IFDIR: if((pdir = open(".", O_RDONLY)) < 0) perror_msg_and_die("."); if(chdir(dopt[i]) < 0) perror_msg_and_die(dopt[i]); if (fixstats) prep_stat(dopt[i]); add2fs_from_dir(fs, dopt[i], nod, squash_uids, squash_perms, fixstats, fs_timestamp, stats); if(fchdir(pdir) < 0) perror_msg_and_die("fchdir"); if(close(pdir) < 0) perror_msg_and_die("close"); break; default: error_msg_and_die("%s is neither a file nor a directory", dopt[i]); } } } static void showversion(void) { printf("genext2fs " VERSION "\n"); } static void showhelp(void) { fprintf(stderr, "Usage: %s [options] image\n" "Create an ext2 filesystem image from directories/files\n\n" " -x, --starting-image <image>\n" " -d, --root <directory>\n" " -D, --devtable <file>\n" " -b, --size-in-blocks <blocks>\n" " -i, --bytes-per-inode <bytes per inode>\n" " -N, --number-of-inodes <number of inodes>\n" " -m, --reserved-percentage <percentage of blocks to reserve>\n" " -g, --block-map <path> Generate a block map file for this path.\n" " -e, --fill-value <value> Fill unallocated blocks with value.\n" " -z, --allow-holes Allow files with holes.\n" " -f, --faketime Set filesystem timestamps to 0 (for testing).\n" " -q, --squash Same as \"-U -P\".\n" " -U, --squash-uids Squash owners making all files be owned by root.\n" " -P, --squash-perms Squash permissions on all files.\n" " -a, --fix-android-stats Fix-up file stats (user, perms, ...)\n" " -h, --help\n" " -V, --version\n" " -v, --verbose\n\n" "Report bugs to genext2fs-devel@lists.sourceforge.net\n", app_name); } #define MAX_DOPT 128 #define MAX_GOPT 128 #define MAX_FILENAME 255 extern char* optarg; extern int optind, opterr, optopt; int main(int argc, char **argv) { int nbblocks = -1; int nbinodes = -1; int nbresrvd = -1; float bytes_per_inode = -1; float reserved_frac = -1; int fs_timestamp = -1; char * fsout = "-"; char * fsin = 0; char * dopt[MAX_DOPT]; int didx = 0; char * gopt[MAX_GOPT]; int gidx = 0; int verbose = 0; int holes = 0; int emptyval = 0; int squash_uids = 0; int squash_perms = 0; int fix_android_stats = 0; uint16 endian = 1; int bigendian = !*(char*)&endian; filesystem *fs; int i; int c; struct stats stats; #if HAVE_GETOPT_LONG struct option longopts[] = { { "starting-image", required_argument, NULL, 'x' }, { "root", required_argument, NULL, 'd' }, { "devtable", required_argument, NULL, 'D' }, { "size-in-blocks", required_argument, NULL, 'b' }, { "bytes-per-inode", required_argument, NULL, 'i' }, { "number-of-inodes", required_argument, NULL, 'N' }, { "reserved-percentage", required_argument, NULL, 'm' }, { "block-map", required_argument, NULL, 'g' }, { "fill-value", required_argument, NULL, 'e' }, { "allow-holes", no_argument, NULL, 'z' }, { "faketime", no_argument, NULL, 'f' }, { "squash", no_argument, NULL, 'q' }, { "squash-uids", no_argument, NULL, 'U' }, { "squash-perms", no_argument, NULL, 'P' }, { "fix-android-stats",no_argument, NULL, 'a' }, { "help", no_argument, NULL, 'h' }, { "version", no_argument, NULL, 'V' }, { "verbose", no_argument, NULL, 'v' }, { 0, 0, 0, 0} } ; app_name = argv[0]; while((c = getopt_long(argc, argv, "x:d:D:b:i:N:m:g:e:zfqUPahVv", longopts, NULL)) != EOF) { #else app_name = argv[0]; while((c = getopt(argc, argv, "x:d:D:b:i:N:m:g:e:zfqUPahVv")) != EOF) { #endif /* HAVE_GETOPT_LONG */ switch(c) { case 'x': fsin = optarg; break; case 'd': case 'D': dopt[didx++] = optarg; break; case 'b': nbblocks = SI_atof(optarg); break; case 'i': bytes_per_inode = SI_atof(optarg); break; case 'N': nbinodes = SI_atof(optarg); break; case 'm': reserved_frac = SI_atof(optarg) / 100; break; case 'g': gopt[gidx++] = optarg; break; case 'e': emptyval = atoi(optarg); break; case 'z': holes = 1; break; case 'f': fs_timestamp = 0; break; case 'q': squash_uids = 1; squash_perms = 1; break; case 'U': squash_uids = 1; break; case 'P': squash_perms = 1; break; case 'a': fix_android_stats = 1; break; case 'h': showhelp(); exit(0); case 'V': showversion(); exit(0); case 'v': verbose = 1; showversion(); break; default: error_msg_and_die("Note: options have changed, see --help or the man page."); } } if(optind < (argc - 1)) error_msg_and_die("Too many arguments. Try --help or else see the man page."); if(optind > (argc - 1)) error_msg_and_die("Not enough arguments. Try --help or else see the man page."); if(fix_android_stats && (squash_uids || squash_perms)) error_msg_and_die("Cannot squash uid/perms and fix them up for Android at the same time."); fsout = argv[optind]; hdlinks.hdl = (struct hdlink_s *)malloc(hdlink_cnt * sizeof(struct hdlink_s)); if (!hdlinks.hdl) error_msg_and_die("Not enough memory"); hdlinks.count = 0 ; if(fsin) { if(strcmp(fsin, "-")) { FILE * fh = xfopen(fsin, "rb"); fs = load_fs(fh, bigendian); fclose(fh); } else fs = load_fs(stdin, bigendian); } else { if(reserved_frac == -1) nbresrvd = nbblocks * RESERVED_BLOCKS; else nbresrvd = nbblocks * reserved_frac; stats.ninodes = EXT2_FIRST_INO - 1 + (nbresrvd ? 1 : 0); stats.nblocks = 0; populate_fs(NULL, dopt, didx, squash_uids, squash_perms, 0, fs_timestamp, &stats); if(nbinodes == -1) nbinodes = stats.ninodes; else if(stats.ninodes > (unsigned long)nbinodes) { fprintf(stderr, "number of inodes too low, increasing to %ld\n", stats.ninodes); nbinodes = stats.ninodes; } if(bytes_per_inode != -1) { int tmp_nbinodes = nbblocks * BLOCKSIZE / bytes_per_inode; if(tmp_nbinodes > nbinodes) nbinodes = tmp_nbinodes; } if(fs_timestamp == -1) fs_timestamp = time(NULL); fs = init_fs(nbblocks, nbinodes, nbresrvd, holes, fs_timestamp); } populate_fs(fs, dopt, didx, squash_uids, squash_perms, fix_android_stats, fs_timestamp, NULL); if(emptyval) { uint32 b; for(b = 1; b < fs->sb.s_blocks_count; b++) if(!allocated(GRP_GET_BLOCK_BITMAP(fs,b),GRP_BBM_OFFSET(fs,b))) memset(get_blk(fs, b), emptyval, BLOCKSIZE); } if(verbose) print_fs(fs); for(i = 0; i < gidx; i++) { uint32 nod; char fname[MAX_FILENAME]; char *p; FILE *fh; if(!(nod = find_path(fs, EXT2_ROOT_INO, gopt[i]))) error_msg_and_die("path %s not found in filesystem", gopt[i]); while((p = strchr(gopt[i], '/'))) *p = '_'; SNPRINTF(fname, MAX_FILENAME-1, "%s.blk", gopt[i]); fh = xfopen(fname, "wb"); fprintf(fh, "%d:", get_nod(fs, nod)->i_size); flist_blocks(fs, nod, fh); fclose(fh); } if(strcmp(fsout, "-")) { FILE * fh = xfopen(fsout, "wb"); dump_fs(fs, fh, bigendian); fclose(fh); } else dump_fs(fs, stdout, bigendian); free_fs(fs); return 0; }