/**************************************************************************** * tools/gencromfs.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #define _GNU_SOURCE 1 #include #include #include #include #include #include #include #include #include #include /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* HOST_BIGENDIAN or TGT_BIGENDIAN may be defined on the command line to * adapt to different host/target combinations. Otherwise, both are assumed * to be the same endian-ness. */ #undef HOST_TGTSWAP #if (defined(HOST_BIGENDIAN) && !defined(TGT_BIGENDIAN)) || \ (!defined(HOST_BIGENDIAN) && defined(TGT_BIGENDIAN)) # define HOST_TGTSWAP 1 #endif #define UNUSED(a) ((void)(a)) /* mkstemp() has been giving me errors on Cygwin */ #undef USE_MKSTEMP #define TMP_NAMLEN 32 /* Actually only 22 */ #ifdef USE_MKSTEMP # define TMP_NAME "/tmp/gencromfs-XXXXXX" #else # define TMP_NAME "/tmp/gencromfs-%06u" #endif #define NUTTX_IXOTH (1 << 0) /* Must match NuttX's S_IXOTH */ #define NUTTX_IWOTH (1 << 1) /* Must match NuttX's S_IWOTH */ #define NUTTX_IROTH (1 << 2) /* Must match NuttX's S_IROTH */ #define NUTTX_IRXOTH (NUTTX_IROTH | NUTTX_IXOTH) #define NUTTX_IXGRP (1 << 3) /* Must match NuttX's S_IXGRP */ #define NUTTX_IWGRP (1 << 4) /* Must match NuttX's S_IWGRP */ #define NUTTX_IRGRP (1 << 5) /* Must match NuttX's S_IRGRP */ #define NUTTX_IRXGRP (NUTTX_IRGRP | NUTTX_IXGRP) #define NUTTX_IXUSR (1 << 6) /* Must match NuttX's S_IXUSR */ #define NUTTX_IWUSR (1 << 7) /* Must match NuttX's S_IWUSR */ #define NUTTX_IRUSR (1 << 8) /* Must match NuttX's S_IRUSR */ #define NUTTX_IRXUSR (NUTTX_IRUSR | NUTTX_IXUSR) #define NUTTX_IFDIR (4 << 12) /* Must match NuttX's S_IFDIR */ #define NUTTX_IFREG (8 << 12) /* Must match NuttX's S_IFREG */ #define NUTTX_IFLNK (10 << 12) /* Must match NuttX's S_IFLNK */ #define DIR_MODEFLAGS (NUTTX_IFDIR | NUTTX_IRXUSR | NUTTX_IRXGRP | NUTTX_IRXOTH) #define DIRLINK_MODEFLAGS (NUTTX_IFLNK | NUTTX_IRXUSR | NUTTX_IRXGRP | NUTTX_IRXOTH) #define FILE_MODEFLAGS (NUTTX_IFREG | NUTTX_IRUSR | NUTTX_IRGRP | NUTTX_IROTH) #define CROMFS_MAGIC 0x4d4f5243 #define CROMFS_BLOCKSIZE 512 #define LZF_BUFSIZE 512 #define LZF_HLOG 13 #define LZF_HSIZE (1 << LZF_HLOG) #define LZF_TYPE0_HDR 0 #define LZF_TYPE1_HDR 1 #define LZF_TYPE0_HDR_SIZE 5 #define LZF_TYPE1_HDR_SIZE 7 #define LZF_FRST(p) (((p[0]) << 8) | p[1]) #define LZF_NEXT(v,p) (((v) << 8) | p[2]) #define LZF_NDX(h) ((((h ^ (h << 5)) >> (3*8 - LZF_HLOG)) - h*5) & (LZF_HSIZE - 1)) #define LZF_MAX_LIT (1 << 5) #define LZF_MAX_OFF (1 << LZF_HLOG) #define LZF_MAX_REF ((1 << 8) + (1 << 3)) #define HEX_PER_LINE 8 /**************************************************************************** * Private Types ****************************************************************************/ /* Maximum size of an offset. This should normally be size_t since this is * an in-memory file system. However, size_t is 32-bits on most 32-bit * target machines but 64-bits on 64-host machines. We restrict offsets to * 32-bits for commonality (limiting the size of the CROMFS image to 4Gb) * * Similarly, the NuttX mode_t is only 16-bits so uint16_t is explicitly used * for NuttX file modes. */ /* CROMFS structures */ struct cromfs_volume_s { uint32_t cv_magic; /* Must be first. Must be CROMFS_MAGIC */ uint16_t cv_nnodes; /* Total number of nodes in-use */ uint16_t cv_nblocks; /* Total number of data blocks in-use */ uint32_t cv_root; /* Offset to the first node in the root file system */ uint32_t cv_fsize; /* Size of the compressed file system image */ uint32_t cv_bsize; /* Optimal block size for transfers */ }; struct cromfs_node_s { uint16_t cn_mode; /* File type, attributes, and access mode bits */ uint16_t cn_pad; /* Not used */ uint32_t cn_name; /* Offset from the beginning of the volume header to the * node name string. NUL-terminated. */ uint32_t cn_size; /* Size of the uncompressed data (in bytes) */ uint32_t cn_peer; /* Offset to next node in this directory (for readdir()) */ union { uint32_t cn_child; /* Offset to first node in sub-directory (directories only) */ uint32_t cn_link; /* Offset to an arbitrary node (for hard link) */ uint32_t cn_blocks; /* Offset to first block of compressed data (for read) */ } u; }; /* LZF headers */ struct lzf_header_s /* Common data header */ { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE0_HDR or LZF_TYPE1_HDR */ }; struct lzf_type0_header_s /* Uncompressed data header */ { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE0_HDR */ uint8_t lzf_len[2]; /* Data length (big-endian) */ }; struct lzf_type1_header_s /* Compressed data header */ { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE1_HDR */ uint8_t lzf_clen[2]; /* Compressed data length (big-endian) */ uint8_t lzf_ulen[2]; /* Uncompressed data length (big-endian) */ }; /* LZF data buffer */ union lzf_result_u { struct { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE0_HDR or LZF_TYPE1_HDR */ } cmn; /* Common data header */ struct { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE0_HDR */ uint8_t lzf_len[2]; /* Data length (big-endian) */ uint8_t lzf_buffer[LZF_BUFSIZE]; } uncompressed; /* Uncompressed data header */ struct { uint8_t lzf_magic[2]; /* [0]='Z', [1]='V' */ uint8_t lzf_type; /* LZF_TYPE1_HDR */ uint8_t lzf_clen[2]; /* Compressed data length (big-endian) */ uint8_t lzf_ulen[2]; /* Uncompressed data length (big-endian) */ uint8_t lzf_buffer[LZF_BUFSIZE + 16]; } compressed; }; /* LZF hash table */ static uint8_t *g_lzf_hashtab[LZF_HSIZE]; /* Type of the callback from traverse_directory() */ typedef int (*traversal_callback_t)(const char *dirpath, const char *name, void *arg, bool lastentry); /**************************************************************************** * Private Data ****************************************************************************/ static char *g_progname; /* Name of this program */ static char *g_dirname; /* Source directory path */ static char *g_outname; /* Output file path */ static FILE *g_outstream; /* Main output stream */ static FILE *g_tmpstream; /* Temporary file output stream */ static const char g_delim[] = "**************************************" "**************************************"; static const char g_license[] = " *\n" " * Licensed to the Apache Software Foundation (ASF) under one or more\n" " * contributor license agreements. See the NOTICE file distributed with\n" " * this work for additional information regarding copyright ownership.\n" " * The ASF licenses this file to you under the Apache License, Version\n" " * 2.0 (the \"License\"); you mayn`t use this file except in compliance\n" " * with the License. You may obtain a copy of the License at\n" " *\n" " * http://www.apache.org/licenses/LICENSE-2.0\n" " *\n" " * Unless required by applicable law or agreed to in writing, software\n" " * distributed under the License is distributed on an \"AS IS\" BASIS,\n" " * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or\n" " * implied. See the License for the specific language governing\n" " * permissions and limitations under the License.\n" " *\n"; static uint32_t g_offset; /* Current image offset */ static uint32_t g_diroffset; /* Offset for '.' */ static uint32_t g_parent_offset; /* Offset for '..' */ static unsigned int g_nnodes; /* Number of nodes generated */ static unsigned int g_nblocks; /* Number of blocks of data generated */ static unsigned int g_nhex; /* Number of hex characters on output line */ #ifndef USE_MKSTEMP static unsigned int g_ntmps; /* Number temporary files */ #endif /**************************************************************************** * Private Function Prototypes ****************************************************************************/ static void show_usage(void); static void verify_directory(void); static void verify_outfile(void); static void init_outfile(void); static FILE *open_tmpfile(void); #ifndef USE_MKSTEMP static void unlink_tmpfiles(void); #endif static void append_tmpfile(FILE *dest, FILE *src); static void dump_hexbuffer(FILE *stream, const void *buffer, unsigned int nbytes); static void dump_nextline(FILE *stream); static size_t lzf_compress(const uint8_t *inbuffer, unsigned int inlen, union lzf_result_u *result); static uint16_t get_mode(mode_t mode); #ifdef HOST_TGTSWAP static inline uint16_t tgt_uint16(uint16_t a); static inline uint32_t tgt_uint32(uint32_t a); # define TGT_UINT16(a) tgt_uint16(a) # define TGT_UINT32(a) tgt_uint32(a) #else # define TGT_UINT16(a) (a) # define TGT_UINT32(a) (a) #endif static void gen_dirlink(const char *name, uint32_t tgtoffs, bool dirempty); static void gen_directory(const char *path, const char *name, mode_t mode, bool lastentry); static void gen_file(const char *path, const char *name, mode_t mode, bool lastentry); static int dir_notempty(const char *dirpath, const char *name, void *arg, bool lastentry); static int process_direntry(const char *dirpath, const char *name, void *arg, bool lastentry); static int traverse_directory(const char *dirpath, traversal_callback_t callback, void *arg); /**************************************************************************** * Private Functions ****************************************************************************/ static void show_usage(void) { fprintf(stderr, "USAGE: %s \n", g_progname); exit(1); } static void verify_directory(void) { struct stat buf; int len; int ret; /* Trim any trailing '/' characters from the directory path. */ len = strlen(g_dirname); while (len > 1 && g_dirname[len - 1] == '/') { g_dirname[len - 1] = '\0'; len--; } if (len < 1) { fprintf(stderr, "ERROR: Source %s is invalid\n", g_dirname); show_usage(); } /* stat the source directory containing the file system image */ ret = stat(g_dirname, &buf); if (ret < 0) { int errcode = errno; if (errcode == ENOENT) { fprintf(stderr, "ERROR: Source %s does not exist\n", g_dirname); } else { fprintf(stderr, "ERROR: stat(%s) failed: %s\n", g_dirname, strerror(errcode)); } show_usage(); } /* Verify that the source is, indeed, a directory */ else if (!S_ISDIR(buf.st_mode)) { fprintf(stderr, "ERROR: Source %s is not a directory\n", g_dirname); } } static void verify_outfile(void) { struct stat buf; int ret; /* stat the destination file */ ret = stat(g_outname, &buf); if (ret < 0) { int errcode = errno; if (errcode != ENOENT) { fprintf(stderr, "ERROR: stat(%s) failed: %s\n", g_outname, strerror(errcode)); show_usage(); } } /* Something exists at this path. Verify that the destination is a regular * file */ else if (!S_ISREG(buf.st_mode)) { fprintf(stderr, "ERROR: Destination %s exists\n", g_outname); show_usage(); } else { printf("Existing file %s will be replaced\n", g_outname); } } static void init_outfile(void) { fprintf(g_outstream, "/%s\n", g_delim); fprintf(g_outstream, " * %s\n", g_outname); fprintf(g_outstream, "%s", g_license); fprintf(g_outstream, " %s/\n\n", g_delim); fprintf(g_outstream, "/%s\n", g_delim); fprintf(g_outstream, " * Included Files\n"); fprintf(g_outstream, " %s/\n\n", g_delim); fprintf(g_outstream, "#include \n\n"); fprintf(g_outstream, "/%s\n", g_delim); fprintf(g_outstream, " * Private Data\n"); fprintf(g_outstream, " %s/\n\n", g_delim); } static FILE *open_tmpfile(void) { FILE *tmpstream; #ifdef USE_MKSTEMP int fd; fd = mkstemp(TMP_NAME); if (fd < 0) { fprintf(stderr, "Failed to create temporary file: %s\n", strerror(errno)); exit(1); } tmpstream = fdopen(fd, "w+"); if (!tmpstream) { fprintf(stderr, "fdopen for tmp file failed: %s\n", strerror(errno)); exit(1); } #else char tmpname[TMP_NAMLEN]; snprintf(tmpname, TMP_NAMLEN, TMP_NAME, g_ntmps); g_ntmps++; tmpstream = fopen(tmpname, "w+"); if (!tmpstream) { fprintf(stderr, "fopen for tmp file %s failed: %s\n", tmpname, strerror(errno)); exit(1); } #endif return tmpstream; } #ifndef USE_MKSTEMP static void unlink_tmpfiles(void) { char tmpname[TMP_NAMLEN]; unsigned int i; for (i = 0; i < g_ntmps; i++) { snprintf(tmpname, TMP_NAMLEN, TMP_NAME, i); unlink(tmpname); } } #endif static void append_tmpfile(FILE *dest, FILE *src) { uint8_t iobuffer[1024]; size_t nread; /* Rewind the source directory to be beginning. We assume that the dest * is already at the end. */ rewind(src); /* Then append the source to the destination */ do { nread = fread(iobuffer, 1, 1024, src); if (nread > 0) { fwrite(iobuffer, 1, nread, dest); } } while (nread > 0); /* We can now close the src temporary file */ fclose(src); } static void dump_hexbuffer(FILE *stream, const void *buffer, unsigned int nbytes) { uint8_t *ptr = (uint8_t *)buffer; while (nbytes > 0) { if (g_nhex == 0) { fprintf(stream, " "); } fprintf(stream, " 0x%02x,", *ptr++); if (++g_nhex >= HEX_PER_LINE) { fprintf(stream, "\n"); g_nhex = 0; } nbytes--; } } static void dump_nextline(FILE *stream) { if (g_nhex > 0) { fprintf(stream, "\n"); g_nhex = 0; } } static size_t lzf_compress(const uint8_t *inbuffer, unsigned int inlen, union lzf_result_u *result) { const uint8_t *inptr = inbuffer; uint8_t *outptr = result->compressed.lzf_buffer; const uint8_t *inend = inptr + inlen; uint8_t *outend = outptr + LZF_BUFSIZE; const uint8_t *ref; uintptr_t off; ssize_t cs; ssize_t retlen; unsigned int hval; int lit; if (inlen == 0) { cs = 0; goto genhdr; } memset(g_lzf_hashtab, 0, sizeof(g_lzf_hashtab)); lit = 0; /* Start run */ outptr++; hval = LZF_FRST(inptr); while (inptr < inend - 2) { uint8_t **hslot; hval = LZF_NEXT(hval, inptr); hslot = &g_lzf_hashtab[LZF_NDX(hval)]; ref = *hslot; *hslot = (uint8_t *)inptr; if (ref < inptr && /* the next test will actually take care of this, but this is faster */ (off = inptr - ref - 1) < LZF_MAX_OFF && ref > (uint8_t *)inbuffer && ref[2] == inptr[2] && ((ref[1] << 8) | ref[0]) == ((inptr[1] << 8) | inptr[0])) { /* Match found at *ref++ */ unsigned int len = 2; unsigned int maxlen = inend - inptr - len; maxlen = maxlen > LZF_MAX_REF ? LZF_MAX_REF : maxlen; /* First a faster conservative test */ if ((outptr + 3 + 1) >= outend) { /* Second the exact but rare test */ if (outptr - !lit + 3 + 1 >= outend) { cs = 0; goto genhdr; } } outptr[(-lit) - 1] = lit - 1; /* Stop run */ outptr -= !lit; /* Undo run if length is zero */ for (; ; ) { if (maxlen > 16) { len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } len++; if (ref[len] != inptr[len]) { break; } } do { len++; } while (len < maxlen && ref[len] == inptr[len]); break; } len -= 2; /* len is now #octets - 1 */ inptr++; if (len < 7) { *outptr++ = (off >> 8) + (len << 5); } else { *outptr++ = (off >> 8) + (7 << 5); *outptr++ = len - 7; } *outptr++ = off; lit = 0; outptr++; /* start run */ inptr += len + 1; if (inptr >= inend - 2) { break; } inptr -= len + 1; do { hval = LZF_NEXT(hval, inptr); g_lzf_hashtab[LZF_NDX(hval)] = (uint8_t *)inptr; inptr++; } while (len--); } else { /* One more literal byte we must copy */ if (outptr >= outend) { cs = 0; goto genhdr; } lit++; *outptr++ = *inptr++; if (lit == LZF_MAX_LIT) { outptr[(-lit) - 1] = lit - 1; /* Stop run */ lit = 0; /* Start run */ outptr++; } } } /* At most 3 bytes can be missing here */ if (outptr + 3 > outend) { cs = 0; goto genhdr; } while (inptr < inend) { lit++; *outptr++ = *inptr++; if (lit == LZF_MAX_LIT) { outptr[(-lit) - 1] = lit - 1; /* Stop run */ lit = 0; /* Start run */ outptr++; } } outptr[(-lit) - 1] = lit - 1; /* End run */ outptr -= !lit; /* Undo run if length is zero */ cs = outptr - (uint8_t *)result->compressed.lzf_buffer; genhdr: if (cs > 0) { /* Write compressed header */ result->compressed.lzf_magic[0] = 'Z'; result->compressed.lzf_magic[1] = 'V'; result->compressed.lzf_type = LZF_TYPE1_HDR; result->compressed.lzf_clen[0] = cs >> 8; result->compressed.lzf_clen[1] = cs & 0xff; result->compressed.lzf_ulen[0] = inlen >> 8; result->compressed.lzf_ulen[1] = inlen & 0xff; retlen = cs + LZF_TYPE1_HDR_SIZE; } else { /* Write uncompressed header */ result->uncompressed.lzf_magic[0] = 'Z'; result->uncompressed.lzf_magic[1] = 'V'; result->uncompressed.lzf_type = LZF_TYPE0_HDR; result->uncompressed.lzf_len[0] = inlen >> 8; result->uncompressed.lzf_len[1] = inlen & 0xff; /* Copy uncompressed data into the result buffer */ memcpy(result->uncompressed.lzf_buffer, inbuffer, inlen); retlen = inlen + LZF_TYPE0_HDR_SIZE; } return retlen; } static uint16_t get_mode(mode_t mode) { uint16_t ret = 0; /* Convert mode to CROMFS NuttX read-only mode */ if ((mode & S_IXOTH) != 0) { ret |= NUTTX_IXOTH; } if ((mode & S_IROTH) != 0) { ret |= NUTTX_IROTH; } if ((mode & S_IXGRP) != 0) { ret |= NUTTX_IXGRP; } if ((mode & S_IRGRP) != 0) { ret |= NUTTX_IRGRP; } if ((mode & S_IXUSR) != 0) { ret |= NUTTX_IXUSR; } if ((mode & S_IRUSR) != 0) { ret |= NUTTX_IRUSR; } return ret; } #ifdef HOST_TGTSWAP static inline uint16_t tgt_uint16(uint16_t a) { /* [15:8][7:0] -> [7:0][15:8] */ return (a >> 8) | (a << 8); } static inline uint32_t tgt_uint32(uint32_t a) { /* [31:24][23:16][15:8][7:0] -> [7:0][15:8][23:16][31:24] */ return (a >> 24) | ((a >> 8) & 0x0000ff00) | ((a << 8) & 0x00ff0000) | (a << 24); } #endif static void gen_dirlink(const char *name, uint32_t tgtoffs, bool dirempty) { struct cromfs_node_s node; int namlen; namlen = strlen(name) + 1; /* Generate the hardlink node */ fprintf(g_tmpstream, "\n /* Offset %6lu: Hard link %s */\n\n", (unsigned long)g_offset, name); node.cn_mode = TGT_UINT16(DIRLINK_MODEFLAGS); node.cn_pad = 0; g_offset += sizeof(struct cromfs_node_s); node.cn_name = TGT_UINT32(g_offset); node.cn_size = 0; g_offset += namlen; node.cn_peer = TGT_UINT32(dirempty ? 0 : g_offset); node.u.cn_link = TGT_UINT32(tgtoffs); dump_hexbuffer(g_tmpstream, &node, sizeof(struct cromfs_node_s)); dump_hexbuffer(g_tmpstream, name, namlen); dump_nextline(g_tmpstream); g_nnodes++; } static void gen_directory(const char *path, const char *name, mode_t mode, bool lastentry) { struct cromfs_node_s node; uint32_t save_offset = g_offset; uint32_t save_diroffset = g_diroffset; uint32_t save_parent_offset = g_parent_offset; FILE *save_tmpstream = g_tmpstream; FILE *subtree_stream; int namlen; int result; namlen = strlen(name) + 1; /* Open a new temporary file */ subtree_stream = open_tmpfile(); g_tmpstream = subtree_stream; /* Update the offset to account for the file node which we have not yet * written (we can't, we don't have enough information yet) */ g_offset += sizeof(struct cromfs_node_s) + namlen; /* Update offsets for the subdirectory */ g_parent_offset = g_diroffset; /* New offset for '..' */ g_diroffset = g_offset; /* New offset for '.' */ /* We are going to traverse the new directory twice; the first time just * see if the directory is empty. The second time is the real thing. */ result = traverse_directory(path, dir_notempty, NULL); /* Generate the '.' and '..' links for the directory (in the new temporary * file). */ gen_dirlink(".", g_diroffset, false); gen_dirlink("..", g_parent_offset, result == 0); if (result != 0) { /* Then recurse to generate all of the nodes for the subtree */ traverse_directory(path, process_direntry, NULL); } /* When traverse_directory() returns, all of the nodes in the sub-tree * under 'name' will have been written to the new tmpfile. g_offset is * correct, but other settings are not. * * Restore the state. */ g_tmpstream = save_tmpstream; g_diroffset = save_diroffset; g_parent_offset = save_parent_offset; /* Generate the directory node */ fprintf(g_tmpstream, "\n /* Offset %6lu: Directory %s */\n\n", (unsigned long)save_offset, path); node.cn_mode = TGT_UINT16(NUTTX_IFDIR | get_mode(mode)); node.cn_pad = 0; save_offset += sizeof(struct cromfs_node_s); node.cn_name = TGT_UINT32(save_offset); node.cn_size = 0; save_offset += namlen; node.cn_peer = TGT_UINT32(lastentry ? 0 : g_offset); node.u.cn_child = TGT_UINT32(save_offset); dump_hexbuffer(g_tmpstream, &node, sizeof(struct cromfs_node_s)); dump_hexbuffer(g_tmpstream, name, namlen); dump_nextline(g_tmpstream); g_nnodes++; /* Now append the sub-tree nodes in the new tmpfile to the previous * tmpfile */ append_tmpfile(g_tmpstream, subtree_stream); } static void gen_file(const char *path, const char *name, mode_t mode, bool lastentry) { struct cromfs_node_s node; union lzf_result_u result; uint32_t nodeoffs = g_offset; FILE *save_tmpstream = g_tmpstream; FILE *outstream; FILE *instream; uint8_t iobuffer[LZF_BUFSIZE]; size_t nread; size_t ntotal; size_t blklen; size_t blktotal; unsigned int blkno; int namlen; namlen = strlen(name) + 1; /* Open a new temporary file */ outstream = open_tmpfile(); g_tmpstream = outstream; g_offset = nodeoffs + sizeof(struct cromfs_node_s) + namlen; /* Open the source data file */ instream = fopen(path, "r"); if (!instream) { fprintf(stderr, "fopen for source file %s failed: %s\n", path, strerror(errno)); exit(1); } /* Then read data from the file, compress it, and write it to the new * temporary file */ blkno = 0; ntotal = 0; blktotal = 0; do { /* Read the next chunk from the file */ nread = fread(iobuffer, 1, LZF_BUFSIZE, instream); if (nread > 0) { uint16_t clen; /* Compress the chunk */ blklen = lzf_compress(iobuffer, nread, &result); if (result.cmn.lzf_type == LZF_TYPE0_HDR) { clen = nread; } else { clen = (uint16_t)result.compressed.lzf_clen[0] << 8 | (uint16_t)result.compressed.lzf_clen[1]; } fprintf(g_tmpstream, "\n /* Offset %6lu: " "Block %u blklen=%lu Uncompressed=%lu Compressed=%u " "*/\n\n", (unsigned long)g_offset, blkno, (long)blklen, (long)nread, clen); dump_hexbuffer(g_tmpstream, &result, blklen); dump_nextline(g_tmpstream); ntotal += nread; blktotal += blklen; g_offset += blklen; g_nblocks++; blkno++; } } while (nread > 0); /* Restore the old tmpfile context */ g_tmpstream = save_tmpstream; /* Now we have enough information to generate the file node */ fprintf(g_tmpstream, "\n /* Offset %6lu: File %s: " "Uncompressed=%lu Compressed=%lu */\n\n", (unsigned long)nodeoffs, path, (unsigned long)ntotal, (unsigned long)blktotal); node.cn_mode = TGT_UINT16(NUTTX_IFREG | get_mode(mode)); node.cn_pad = 0; nodeoffs += sizeof(struct cromfs_node_s); node.cn_name = TGT_UINT32(nodeoffs); node.cn_size = TGT_UINT32(ntotal); nodeoffs += namlen; node.u.cn_blocks = TGT_UINT32(nodeoffs); nodeoffs += blktotal; node.cn_peer = TGT_UINT32(lastentry ? 0 : nodeoffs); dump_hexbuffer(g_tmpstream, &node, sizeof(struct cromfs_node_s)); dump_hexbuffer(g_tmpstream, name, namlen); dump_nextline(g_tmpstream); g_nnodes++; /* Now append the sub-tree nodes in the new tmpfile to the previous * tmpfiles */ append_tmpfile(g_tmpstream, outstream); } static int dir_notempty(const char *dirpath, const char *name, void *arg, bool lastentry) { struct stat buf; char *path; int ret; ret = asprintf(&path, "%s/%s", dirpath, name); if (ret < 0) { fprintf(stderr, "ERROR: asprintf() failed\n"); exit(1); } /* stat() should not fail for any reason */ ret = stat(path, &buf); if (ret < 0) { int errcode = errno; fprintf(stderr, "ERROR: stat(%s) failed: %s\n", path, strerror(errcode)); exit(1); } /* The directory is not empty if it contains with a file or a directory * entry. Anything else will be ignored and the directly may be * effectively empty. */ free(path); return (S_ISREG(buf.st_mode) || S_ISDIR(buf.st_mode)); } static int process_direntry(const char *dirpath, const char *name, void *arg, bool lastentry) { struct stat buf; char *path; int ret; ret = asprintf(&path, "%s/%s", dirpath, name); if (ret < 0) { fprintf(stderr, "ERROR: asprintf() failed\n"); exit(1); } ret = stat(path, &buf); if (ret < 0) { int errcode = errno; if (errcode == ENOENT) { fprintf(stderr, "ERROR: Directory entry %s does not exist\n", path); } else { fprintf(stderr, "ERROR: stat(%s) failed: %s\n", path, strerror(errcode)); } show_usage(); } /* Verify that the source is, indeed, a directory */ else if (S_ISDIR(buf.st_mode)) { gen_directory(path, name, buf.st_mode, lastentry); } else if (S_ISREG(buf.st_mode)) { gen_file(path, name, buf.st_mode, lastentry); } else { fprintf(stderr, "Omitting entry %s\n", path); } free(path); return 0; } static int traverse_directory(const char *dirpath, traversal_callback_t callback, void *arg) { DIR *dirp; struct dirent *direntry; char name[NAME_MAX + 1]; int ret = 0; /* Open the directory */ dirp = opendir(dirpath); if (dirp == NULL) { fprintf(stderr, "ERROR: opendir(%s) failed: %s\n", dirpath, strerror(errno)); show_usage(); } /* Visit each entry in the directory */ direntry = readdir(dirp); while (direntry != NULL) { /* Preserve the name from the directory entry. The return value * from readdir() only persists until the next time that readdir() * is called (alternatively, use readdir_r). */ strncpy(name, direntry->d_name, NAME_MAX + 1); /* Get the next entry in advance so that we can anticipate the end of * the directory. */ direntry = readdir(dirp); /* Skip the '.' and '..' hard links */ if (strcmp(name, ".") != 0 && strcmp(name, "..") != 0) { /* Process the directory entry */ ret = callback(dirpath, name, arg, direntry == NULL); if (ret != 0) { break; } } } closedir(dirp); return ret; } /**************************************************************************** * Public Functions ****************************************************************************/ int main(int argc, char **argv, char **envp) { struct cromfs_volume_s vol; char *ptr; int result; /* Verify arguments */ ptr = strrchr(argv[0], '/'); g_progname = ptr == NULL ? argv[0] : ptr + 1; if (argc != 3) { fprintf(stderr, "Unexpected number of arguments\n"); show_usage(); } g_dirname = argv[1]; g_outname = argv[2]; verify_directory(); verify_outfile(); g_outstream = fopen(g_outname, "w"); if (!g_outstream) { fprintf(stderr, "open %s failed: %s\n", g_outname, strerror(errno)); exit(1); } g_tmpstream = open_tmpfile(); /* Set up the initial boilerplate at the beginning of each file */ init_outfile(); /* Set up some initial offsets */ g_offset = sizeof(struct cromfs_volume_s); /* Current image offset */ g_diroffset = sizeof(struct cromfs_volume_s); /* Offset for '.' */ g_parent_offset = sizeof(struct cromfs_volume_s); /* Offset for '..' */ /* We are going to traverse the new directory twice; the first time just * see if the directory is empty. The second time is the real thing. */ result = traverse_directory(g_dirname, dir_notempty, NULL); /* Generate the '.' link for the root directory (it can't have a '..') */ gen_dirlink(".", g_diroffset, result == 0); if (result != 0) { /* Then traverse each entry in the directory, generating node data for * each directory entry encountered. */ traverse_directory(g_dirname, process_direntry, NULL); } /* Now append the volume header to output file */ fprintf(g_outstream, "/* CROMFS image */\n\n"); fprintf(g_outstream, "const uint8_t aligned_data(4) g_cromfs_image[] =\n"); fprintf(g_outstream, "{\n"); fprintf(g_outstream, " /* Offset %6lu: Volume header */\n\n", 0ul); vol.cv_magic = TGT_UINT32(CROMFS_MAGIC); vol.cv_nnodes = TGT_UINT16(g_nnodes); vol.cv_nblocks = TGT_UINT16(g_nblocks); vol.cv_root = TGT_UINT32(sizeof(struct cromfs_volume_s)); vol.cv_fsize = TGT_UINT32(g_offset); vol.cv_bsize = TGT_UINT32(CROMFS_BLOCKSIZE); dump_hexbuffer(g_outstream, &vol, sizeof(struct cromfs_volume_s)); dump_nextline(g_outstream); fprintf(g_outstream, "\n /* Offset %6lu: Root directory */\n", (unsigned long)sizeof(struct cromfs_volume_s)); /* Finally append the nodes to the output file */ append_tmpfile(g_outstream, g_tmpstream); fprintf(g_outstream, "};\n"); fclose(g_outstream); #ifndef USE_MKSTEMP unlink_tmpfiles(); #endif return 0; }