/* ** zipdir.c ** Copyright (C) 2008-2009 Randy Heit ** ** 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; either version 2 of the License, or ** (at your option) any later version. ** ** This program is distributed in the hope that it will be useful, ** but WITHOUT ANY WARRANTY; without even the implied warranty of ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ** GNU General Public License for more details. ** ** You should have received a copy of the GNU General Public License ** along with this program; if not, write to the Free Software ** Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. ** **************************************************************************** ** ** Usage: zipdir [-dfuq] ... ** ** Given one or more directories, their contents are scanned recursively. ** If any files are newer than the zip file or the zip file does not exist, ** then everything in the specified directories is stored in the zip. The ** base directory names are not stored in the zip file, but subdirectories ** recursed into are stored. */ // HEADER FILES ------------------------------------------------------------ #include #include #ifdef _WIN32 #include #define stat _stat #else #include #if !defined(__sun) #include #endif #endif #include #include #include #include #include #include #include "zlib.h" #include "bzlib.h" #include "LzmaEnc.h" #include "7zVersion.h" #ifdef PPMD #include "../../ppmd/PPMd.h" #endif // MACROS ------------------------------------------------------------------ #ifdef __GNUC__ // With versions of GCC newer than 4.2, it appears it was determined that the // cost of an unaligned pointer on PPC was high enough to add padding to the // end of packed structs. For whatever reason __packed__ and pragma pack are // handled differently in this regard. Note that this only needs to be applied // to types which are used in arrays. #define FORCE_PACKED __attribute__((__packed__)) #else #define FORCE_PACKED #endif #ifndef __BIG_ENDIAN__ #define MAKE_ID(a,b,c,d) ((a)|((b)<<8)|((c)<<16)|((d)<<24)) #define LittleShort(x) (x) #define LittleLong(x) (x) #else #define MAKE_ID(a,b,c,d) ((d)|((c)<<8)|((b)<<16)|((a)<<24)) static unsigned short LittleShort(unsigned short x) { return (x>>8) | (x<<8); } static unsigned int LittleLong(unsigned int x) { return (x>>24) | ((x>>8) & 0xff00) | ((x<<8) & 0xff0000) | (x<<24); } #endif #define ZIP_LOCALFILE MAKE_ID('P','K',3,4) #define ZIP_CENTRALFILE MAKE_ID('P','K',1,2) #define ZIP_ENDOFDIR MAKE_ID('P','K',5,6) #define METHOD_STORED 0 #define METHOD_DEFLATE 8 #define METHOD_BZIP2 12 #define METHOD_LZMA 14 #define METHOD_PPMD 98 // Buffer size for central directory search #define BUFREADCOMMENT (0x400) #ifndef PATH_MAX #define PATH_MAX 4096 #endif // TYPES ------------------------------------------------------------------- typedef struct file_entry_s { struct file_entry_s *next; time_t time_write; unsigned int uncompressed_size; unsigned int compressed_size; unsigned int crc32; unsigned int zip_offset; short date, time; short method; char path[]; } file_entry_t; typedef struct dir_tree_s { struct dir_tree_s *next; file_entry_t *files; size_t path_size; char path[]; } dir_tree_t; typedef struct file_sorted_s { file_entry_t *file; char *path_in_zip; } file_sorted_t; typedef struct compressor_s { int (*compress)(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen); int method; } compressor_t; typedef unsigned int UINT32; typedef unsigned short WORD; typedef unsigned char BYTE; // [BL] Solaris (well GCC on Solaris) doesn't seem to support pack(push/pop, 1) so we'll need to use use it // on the whole file. #pragma pack(1) //#pragma pack(push,1) typedef struct { UINT32 Magic; // 0 BYTE VersionToExtract[2]; // 4 WORD Flags; // 6 WORD Method; // 8 WORD ModTime; // 10 WORD ModDate; // 12 UINT32 CRC32; // 14 UINT32 CompressedSize; // 18 UINT32 UncompressedSize; // 22 WORD NameLength; // 26 WORD ExtraLength; // 28 } FORCE_PACKED LocalFileHeader; typedef struct { UINT32 Magic; BYTE VersionMadeBy[2]; BYTE VersionToExtract[2]; WORD Flags; WORD Method; WORD ModTime; WORD ModDate; UINT32 CRC32; UINT32 CompressedSize; UINT32 UncompressedSize; WORD NameLength; WORD ExtraLength; WORD CommentLength; WORD StartingDiskNumber; WORD InternalAttributes; UINT32 ExternalAttributes; UINT32 LocalHeaderOffset; } FORCE_PACKED CentralDirectoryEntry; typedef struct { UINT32 Magic; WORD DiskNumber; WORD FirstDisk; WORD NumEntries; WORD NumEntriesOnAllDisks; UINT32 DirectorySize; UINT32 DirectoryOffset; WORD ZipCommentLength; } FORCE_PACKED EndOfCentralDirectory; //#pragma pack(pop) // EXTERNAL FUNCTION PROTOTYPES -------------------------------------------- // PUBLIC FUNCTION PROTOTYPES ---------------------------------------------- void print_usage(const char *cmdname); dir_tree_t *alloc_dir_tree(const char *dir); file_entry_t *alloc_file_entry(const char *prefix, const char *path, time_t last_written); void free_dir_tree(dir_tree_t *tree); void free_dir_trees(dir_tree_t *tree); #ifdef _WIN32 void recurse_dir(dir_tree_t *tree, const char *dirpath); dir_tree_t *add_dir(const char *dirpath); #endif dir_tree_t *add_dirs(char **argv); int count_files(dir_tree_t *trees); int sort_cmp(const void *a, const void *b); file_sorted_t *sort_files(dir_tree_t *trees, int num_files); void write_zip(const char *zipname, dir_tree_t *trees, int update); int append_to_zip(FILE *zip_file, file_sorted_t *file, FILE *ozip, BYTE *odir); int write_central_dir(FILE *zip, file_sorted_t *file); void time_to_dos(struct tm *time, short *dosdate, short *dostime); int method_to_version(int method); const char *method_name(int method); int compress_lzma(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen); int compress_bzip2(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen); int compress_ppmd(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen); int compress_deflate(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen); BYTE *find_central_dir(FILE *fin); CentralDirectoryEntry *find_file_in_zip(BYTE *dir, const char *path, unsigned int len, unsigned int crc, short date, short time); int copy_zip_file(FILE *zip, file_entry_t *file, FILE *ozip, CentralDirectoryEntry *dirent); // PRIVATE FUNCTION PROTOTYPES --------------------------------------------- static void *SzAlloc(ISzAllocPtr p, size_t size) { p = p; return malloc(size); } static void SzFree(ISzAllocPtr p, void *address) { p = p; free(address); } // EXTERNAL DATA DECLARATIONS ---------------------------------------------- // PUBLIC DATA DEFINITIONS ------------------------------------------------- int DeflateOnly; int UpdateCount; int Quiet; // PRIVATE DATA DEFINITIONS ------------------------------------------------ static const UINT32 centralfile = ZIP_CENTRALFILE; static const UINT32 endofdir = ZIP_ENDOFDIR; static int no_mem; static ISzAlloc Alloc = { SzAlloc, SzFree }; static compressor_t Compressors[] = { { compress_lzma, METHOD_LZMA }, { compress_bzip2, METHOD_BZIP2 }, #ifdef PPMD { compress_ppmd, METHOD_PPMD }, #endif { compress_deflate, METHOD_DEFLATE }, { NULL, 0 } }; // CODE -------------------------------------------------------------------- //========================================================================== // // print_usage // //========================================================================== void print_usage(const char *cmdname) { #ifdef _WIN32 const char *rchar = strrchr(cmdname, '\\'); if (rchar != NULL) { cmdname = rchar+1; } #endif fprintf(stderr, "Usage: %s [options] ...\n" "Options: -d Use deflate compression only\n" " -f Force creation of archive\n" " -u Only update changed files\n" " -q Do not list files\n", cmdname); } //========================================================================== // // alloc_dir_tree // //========================================================================== dir_tree_t *alloc_dir_tree(const char *dir) { dir_tree_t *tree; size_t dirlen; dirlen = strlen(dir); tree = malloc(sizeof(dir_tree_t) + dirlen + 2); if (tree != NULL) { strcpy(tree->path, dir); tree->path_size = dirlen; if (dir[dirlen - 1] != '/') { tree->path_size++; tree->path[dirlen] = '/'; tree->path[dirlen + 1] = '\0'; } tree->files = NULL; tree->next = NULL; } return tree; } //========================================================================== // // alloc_file_entry // //========================================================================== file_entry_t *alloc_file_entry(const char *prefix, const char *path, time_t last_written) { file_entry_t *entry; entry = malloc(sizeof(file_entry_t) + strlen(prefix) + strlen(path) + 1); if (entry != NULL) { strcpy(entry->path, prefix); strcat(entry->path, path); entry->next = NULL; entry->time_write = last_written; } return entry; } //========================================================================== // // free_dir_tree // //========================================================================== void free_dir_tree(dir_tree_t *tree) { file_entry_t *entry, *next; if (tree != NULL) { for (entry = tree->files; entry != NULL; entry = next) { next = entry->next; free(entry); } free(tree); } } //========================================================================== // // free_dir_trees // //========================================================================== void free_dir_trees(dir_tree_t *tree) { dir_tree_t *next; for (; tree != NULL; tree = next) { next = tree->next; free_dir_tree(tree); } } #ifdef _WIN32 //========================================================================== // // recurse_dir // //========================================================================== void recurse_dir(dir_tree_t *tree, const char *dirpath) { struct _finddata_t fileinfo; intptr_t handle; char *dirmatch; dirmatch = malloc(strlen(dirpath) + 2); if (dirmatch == NULL) { no_mem = 1; return; } strcpy(dirmatch, dirpath); strcat(dirmatch, "*"); if ((handle = _findfirst(dirmatch, &fileinfo)) == -1) { fprintf(stderr, "Could not scan '%s': %s\n", dirpath, strerror(errno)); } else { do { if (fileinfo.attrib & _A_HIDDEN) { // Skip hidden files and directories. (Prevents SVN bookkeeping // info from being included.) continue; } if (fileinfo.attrib & _A_SUBDIR) { char *newdir; if (fileinfo.name[0] == '.' && (fileinfo.name[1] == '\0' || (fileinfo.name[1] == '.' && fileinfo.name[2] == '\0'))) { // Do not record . and .. directories. continue; } newdir = malloc(strlen(dirpath) + strlen(fileinfo.name) + 2); strcpy(newdir, dirpath); strcat(newdir, fileinfo.name); strcat(newdir, "/"); recurse_dir(tree, newdir); } else { file_entry_t *entry; if (strstr(fileinfo.name, ".orig")) { // .orig files are left behind by patch.exe and should never be // added to zdoom.pk3 continue; } entry = alloc_file_entry(dirpath, fileinfo.name, fileinfo.time_write); if (entry == NULL) { no_mem = 1; break; } entry->next = tree->files; tree->files = entry; } } while (_findnext(handle, &fileinfo) == 0); _findclose(handle); } free(dirmatch); } //========================================================================== // // add_dir // //========================================================================== dir_tree_t *add_dir(const char *dirpath) { dir_tree_t *tree = alloc_dir_tree(dirpath); if (tree != NULL) { recurse_dir(tree, tree->path); } return tree; } //========================================================================== // // add_dirs // Windows version // // Given NULL-terminated array of directory paths, create trees for them. // //========================================================================== dir_tree_t *add_dirs(char **argv) { dir_tree_t *tree, *trees = NULL; char *s; while (*argv != NULL) { for (s = *argv; *s != '\0'; ++s) { if (*s == '\\') { *s = '/'; } } tree = add_dir(*argv); tree->next = trees; trees = tree; if (no_mem) { break; } argv++; } return trees; } #elif defined(__sun) //========================================================================== // // add_dirs // Solaris version // // Given NULL-terminated array of directory paths, create trees for them. // //========================================================================== void add_dir(dir_tree_t *tree, char* dirpath) { DIR *directory = opendir(dirpath); if(directory == NULL) return; struct dirent *file; while((file = readdir(directory)) != NULL) { if(file->d_name[0] == '.') //File is hidden or ./.. directory so ignore it. continue; int isDirectory = 0; int time = 0; char* fullFileName = malloc(strlen(dirpath) + strlen(file->d_name) + 1); strcpy(fullFileName, dirpath); strcat(fullFileName, file->d_name); struct stat *fileStat; fileStat = malloc(sizeof(struct stat)); stat(fullFileName, fileStat); isDirectory = S_ISDIR(fileStat->st_mode); time = fileStat->st_mtime; free(stat); free(fullFileName); if(isDirectory) { char* newdir; newdir = malloc(strlen(dirpath) + strlen(file->d_name) + 2); strcpy(newdir, dirpath); strcat(newdir, file->d_name); strcat(newdir, "/"); add_dir(tree, newdir); free(newdir); continue; } file_entry_t *entry; entry = alloc_file_entry(dirpath, file->d_name, time); if (entry == NULL) { //no_mem = 1; break; } entry->next = tree->files; tree->files = entry; } closedir(directory); } dir_tree_t *add_dirs(char **argv) { dir_tree_t *tree, *trees = NULL; int i = 0; while(argv[i] != NULL) { tree = alloc_dir_tree(argv[i]); tree->next = trees; trees = tree; if(tree != NULL) { char* dirpath = malloc(sizeof(argv[i]) + 2); strcpy(dirpath, argv[i]); if(dirpath[strlen(dirpath)] != '/') strcat(dirpath, "/"); add_dir(tree, dirpath); free(dirpath); } i++; } return trees; } #else //========================================================================== // // add_dirs // 4.4BSD version // // Given NULL-terminated array of directory paths, create trees for them. // //========================================================================== dir_tree_t *add_dirs(char **argv) { FTS *fts; FTSENT *ent; dir_tree_t *tree, *trees = NULL; file_entry_t *file; fts = fts_open(argv, FTS_LOGICAL, NULL); if (fts == NULL) { fprintf(stderr, "Failed to start directory traversal: %s\n", strerror(errno)); return NULL; } while ((ent = fts_read(fts)) != NULL) { if (ent->fts_info == FTS_D && ent->fts_name[0] == '.') { // Skip hidden directories. (Prevents SVN bookkeeping // info from being included.) // [BL] Also skip backup files. fts_set(fts, ent, FTS_SKIP); } if (ent->fts_info == FTS_D && ent->fts_level == 0) { tree = alloc_dir_tree(ent->fts_path); if (tree == NULL) { no_mem = 1; break; } tree->next = trees; trees = tree; } if (ent->fts_info != FTS_F) { // We're only interested in remembering files. continue; } else if(ent->fts_name[strlen(ent->fts_name)-1] == '~') { // Don't remember backup files. continue; } file = alloc_file_entry("", ent->fts_path, ent->fts_statp->st_mtime); if (file == NULL) { no_mem = 1; break; } file->next = tree->files; tree->files = file; } fts_close(fts); return trees; } #endif //========================================================================== // // count_files // //========================================================================== int count_files(dir_tree_t *trees) { dir_tree_t *tree; file_entry_t *file; int count; for (count = 0, tree = trees; tree != NULL; tree = tree->next) { for (file = tree->files; file != NULL; file = file->next) { count++; } } return count; } //========================================================================== // // sort_cmp // // Arbitrarily-selected sorting for the zip files: Files in the root // directory sort after files in subdirectories. Otherwise, everything // sorts by name. // //========================================================================== int sort_cmp(const void *a, const void *b) { const file_sorted_t *sort1 = (const file_sorted_t *)a; const file_sorted_t *sort2 = (const file_sorted_t *)b; int in_dir1, in_dir2; in_dir1 = (strchr(sort1->path_in_zip, '/') != NULL); in_dir2 = (strchr(sort2->path_in_zip, '/') != NULL); if (in_dir1 == 1 && in_dir2 == 0) { return -1; } if (in_dir1 == 0 && in_dir2 == 1) { return 1; } return strcmp(((const file_sorted_t *)a)->path_in_zip, ((const file_sorted_t *)b)->path_in_zip); } //========================================================================== // // sort_files // //========================================================================== file_sorted_t *sort_files(dir_tree_t *trees, int num_files) { file_sorted_t *sorter; dir_tree_t *tree; file_entry_t *file; int i; sorter = malloc(sizeof(*sorter) * num_files); if (sorter != NULL) { for (i = 0, tree = trees; tree != NULL; tree = tree->next) { for (file = tree->files; file != NULL; file = file->next) { sorter[i].file = file; sorter[i].path_in_zip = file->path + tree->path_size; i++; } } qsort(sorter, num_files, sizeof(*sorter), sort_cmp); } return sorter; } //========================================================================== // // write_zip // //========================================================================== void write_zip(const char *zipname, dir_tree_t *trees, int update) { #ifdef _WIN32 char tempname[_MAX_PATH]; #else char tempname[PATH_MAX]; #endif EndOfCentralDirectory dirend; int i, num_files; file_sorted_t *sorted; FILE *zip, *ozip = NULL; void *central_dir = NULL; num_files = count_files(trees); sorted = sort_files(trees, num_files); if (sorted == NULL) { no_mem = 1; return; } if (update) { sprintf(tempname, "%s.temp", zipname); ozip = fopen(zipname, "rb"); if (ozip == NULL) { fprintf(stderr, "Could not open %s for updating: %s\n", zipname, strerror(errno)); update = 0; } else { central_dir = find_central_dir(ozip); if (central_dir == NULL) { fprintf(stderr, "Could not read central directory from %s. (Is it a zipfile?)\n", zipname); fclose(ozip); ozip = NULL; update = 0; } } if (!update) { fprintf(stderr, "Will proceed as if -u had not been specified.\n"); } } if (update) { zip = fopen(tempname, "wb"); } else { zip = fopen(zipname, "wb"); } if (zip == NULL) { fprintf(stderr, "Could not open %s: %s\n", zipname, strerror(errno)); } else { // Write each file. for (i = 0; i < num_files; ++i) { if (append_to_zip(zip, sorted + i, ozip, central_dir)) { break; } } if (i == num_files) { // Write central directory. dirend.DirectoryOffset = LittleLong(ftell(zip)); for (i = 0; i < num_files; ++i) { write_central_dir(zip, sorted + i); } // Write the directory terminator. dirend.Magic = ZIP_ENDOFDIR; dirend.DiskNumber = 0; dirend.FirstDisk = 0; dirend.NumEntriesOnAllDisks = dirend.NumEntries = LittleShort(i); // In this case LittleLong(dirend.DirectoryOffset) is undoing the transformation done above. dirend.DirectorySize = LittleLong(ftell(zip) - LittleLong(dirend.DirectoryOffset)); dirend.ZipCommentLength = 0; if (fwrite(&dirend, sizeof(dirend), 1, zip) != 1) { fprintf(stderr, "Failed writing zip directory terminator: %s\n", strerror(errno)); } printf("%s contains %d files (updated %d)\n", zipname, num_files, UpdateCount); fclose(zip); if (ozip != NULL) { // Delete original, and rename temp to take its place fclose(ozip); ozip = NULL; if (remove(zipname)) { fprintf(stderr, "Could not delete old zip: %s\nUpdated zip can be found at %s\n", strerror(errno), tempname); } else if (rename(tempname, zipname)) { fprintf(stderr, "Could not rename %s to %s: %s\n", tempname, zipname, strerror(errno)); } } } } free(sorted); if (ozip != NULL) { fclose(ozip); } if (central_dir != NULL) { free(central_dir); } } //========================================================================== // // append_to_zip // // Write a given file to the zipFile. // // zipfile: zip object to be written to // file: file to read data from // // returns: 0 = success, 1 = error // //========================================================================== int append_to_zip(FILE *zip_file, file_sorted_t *filep, FILE *ozip, BYTE *odir) { LocalFileHeader local; uLong crc; file_entry_t *file; Byte *readbuf; Byte *compbuf[2]; unsigned int comp_len[2]; int offset[2]; int method[2]; int best; int slot; FILE *lumpfile; unsigned int readlen; unsigned int len; int i; struct tm *ltime; file = filep->file; // try to determine local time ltime = localtime(&file->time_write); time_to_dos(ltime, &file->date, &file->time); // lumpfile = source file lumpfile = fopen(file->path, "rb"); if (lumpfile == NULL) { fprintf(stderr, "Could not open %s: %s\n", file->path, strerror(errno)); return 1; } // len = source size fseek (lumpfile, 0, SEEK_END); len = ftell(lumpfile); fseek (lumpfile, 0, SEEK_SET); // allocate a buffer for the whole source file readbuf = malloc(len); if (readbuf == NULL) { fclose(lumpfile); fprintf(stderr, "Could not allocate %u bytes\n", (int)len); return 1; } // read the whole source file into buffer readlen = (unsigned int)fread(readbuf, 1, len, lumpfile); fclose(lumpfile); // if read less bytes than expected, if (readlen != len) { // diagnose and return error free(readbuf); fprintf(stderr, "Unable to read %s\n", file->path); return 1; } // file loaded file->uncompressed_size = len; file->compressed_size = len; file->method = METHOD_STORED; // Calculate CRC32 for file. crc = crc32(0, NULL, 0); crc = crc32(crc, readbuf, (uInt)len); file->crc32 = LittleLong(crc); // Can we save time and just copy the file from the old zip? if (odir != NULL && ozip != NULL) { CentralDirectoryEntry *dirent; dirent = find_file_in_zip(odir, filep->path_in_zip, len, crc, file->date, file->time); if (dirent != NULL) { i = copy_zip_file(zip_file, file, ozip, dirent); if (i > 0) { free(readbuf); return 0; } if (i < 0) { free(readbuf); fprintf(stderr, "Unable to write %s to zip\n", file->path); return 1; } } } if (!Quiet) { if (ozip != NULL) { printf("Updating %-40s", filep->path_in_zip); } else { printf("Adding %-40s", filep->path_in_zip); } } UpdateCount++; // Allocate a buffer for compression, one byte less than the source buffer. // If it doesn't fit in that space, then skip compression and store it as-is. compbuf[0] = malloc(len - 1); compbuf[1] = malloc(len - 1); best = -1; // best slot slot = 0; // slot we are compressing to now // Find best compression method. We have two output buffers. One to hold the // best compression method, and the other to hold the compression we are trying // now. for (i = 0; Compressors[i].compress != NULL; ++i) { if (DeflateOnly && Compressors[i].method != METHOD_DEFLATE) { continue; } comp_len[slot] = len - 1; method[slot] = Compressors[i].method; offset[slot] = Compressors[i].compress(compbuf[slot], &comp_len[slot], readbuf, len); if (offset[slot] >= 0) { if (best < 0 || comp_len[slot] <= comp_len[best]) { best = slot; slot ^= 1; } } } if (best >= 0) { file->method = method[best]; file->compressed_size = comp_len[best]; } // printf("%s -> method %d -> slot %d\n", filep->path_in_zip, file->method, best); // Fill in local directory header. local.Magic = ZIP_LOCALFILE; local.VersionToExtract[0] = method_to_version(file->method); local.VersionToExtract[1] = 0; local.Flags = file->method == METHOD_DEFLATE ? LittleShort(2) : 0; local.Method = LittleShort(file->method); local.ModTime = file->time; local.ModDate = file->date; local.CRC32 = file->crc32; local.UncompressedSize = LittleLong(file->uncompressed_size); local.CompressedSize = LittleLong(file->compressed_size); local.NameLength = LittleShort((unsigned short)strlen(filep->path_in_zip)); local.ExtraLength = 0; file->zip_offset = ftell(zip_file); // Write out the header, file name, and file data. if (fwrite(&local, sizeof(local), 1, zip_file) != 1 || fwrite(filep->path_in_zip, strlen(filep->path_in_zip), 1, zip_file) != 1 || (file->method ? fwrite(compbuf[best] + offset[best], 1, comp_len[best], zip_file) != comp_len[best] : fwrite(readbuf, 1, len, zip_file) != len)) { if (!Quiet) { printf("\n"); } fprintf(stderr, "Unable to write %s to zip\n", file->path); free(readbuf); if (compbuf[0] != NULL) { free(compbuf[0]); } if (compbuf[1] != NULL) { free(compbuf[1]); } return 1; } // all done free(readbuf); if (compbuf[0] != NULL) { free(compbuf[0]); } if (compbuf[1] != NULL) { free(compbuf[1]); } if (!Quiet) { printf("%5.1f%% [%6u/%6u] %s\n", 100.0 - 100.0 * file->compressed_size / file->uncompressed_size, file->compressed_size, file->uncompressed_size, method_name(file->method)); } return 0; } //========================================================================== // // write_central_dir // // Writes the central directory entry for a file. // //========================================================================== int write_central_dir(FILE *zip, file_sorted_t *filep) { CentralDirectoryEntry dir; file_entry_t *file; file = filep->file; dir.Magic = ZIP_CENTRALFILE; dir.VersionMadeBy[0] = 20; dir.VersionMadeBy[1] = 0; dir.VersionToExtract[0] = method_to_version(file->method); dir.VersionToExtract[1] = 0; dir.Flags = file->method == METHOD_DEFLATE ? LittleShort(2) : 0; dir.Method = LittleShort(file->method); dir.ModTime = file->time; dir.ModDate = file->date; dir.CRC32 = file->crc32; dir.CompressedSize = LittleLong(file->compressed_size); dir.UncompressedSize = LittleLong(file->uncompressed_size); dir.NameLength = LittleShort((unsigned short)strlen(filep->path_in_zip)); dir.ExtraLength = 0; dir.CommentLength = 0; dir.StartingDiskNumber = 0; dir.InternalAttributes = 0; dir.ExternalAttributes = 0; dir.LocalHeaderOffset = LittleLong(file->zip_offset); if (fwrite(&dir, sizeof(dir), 1, zip) != 1 || fwrite(filep->path_in_zip, strlen(filep->path_in_zip), 1, zip) != 1) { fprintf(stderr, "Error writing central directory header for %s: %s\n", file->path, strerror(errno)); return 1; } return 0; } //========================================================================== // // time_to_dos // // Converts time from struct tm to the DOS format used by zip files. // //========================================================================== void time_to_dos(struct tm *time, short *dosdate, short *dostime) { if (time == NULL || time->tm_year < 80) { *dosdate = *dostime = 0; } else { *dosdate = LittleShort((time->tm_year - 80) * 512 + (time->tm_mon + 1) * 32 + time->tm_mday); *dostime = LittleShort(time->tm_hour * 2048 + time->tm_min * 32 + time->tm_sec / 2); } } //========================================================================== // // method_to_version // // Given a compression method, returns the version of the ZIP appnote // required to decompress it, for filling in the directory information. // //========================================================================== int method_to_version(int method) { // Apparently, real-world programs get confused by setting the version // to extract field to something other than 2.0. #if 0 if (method == METHOD_LZMA || method == METHOD_PPMD) return 63; if (method == METHOD_BZIP2) return 46; #endif // Default anything else to PKZIP 2.0. return 20; } //========================================================================== // // method_name // // Returns the name of the compression method. If the method is unknown, // this will point to a static buffer. // //========================================================================== const char *method_name(int method) { static char unkn[16]; if (method == METHOD_STORED) { return "Stored"; } if (method == METHOD_DEFLATE) { return "Deflate"; } if (method == METHOD_LZMA) { return "LZMA"; } if (method == METHOD_PPMD) { return "PPMd"; } if (method == METHOD_BZIP2) { return "BZip2"; } sprintf(unkn, "Unk:%03d", method); return unkn; } //========================================================================== // // compress_lzma // // Returns non-negative offset to start of data stream on success. Barring // any strange changes to the LZMA library in the future, success should // always return 0. // //========================================================================== int compress_lzma(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen) { CLzmaEncProps lzma_props; size_t props_size; size_t comp_len; int offset; if (*outlen < 1 + 4 + LZMA_PROPS_SIZE) { // Not enough room for LZMA properties header + compressed data. return -1; } if (out == NULL || in == NULL || inlen == 0) { return -1; } LzmaEncProps_Init(&lzma_props); // lzma_props.level = 9; props_size = LZMA_PROPS_SIZE; comp_len = *outlen - 4 - LZMA_PROPS_SIZE; if (SZ_OK != LzmaEncode(out + 4 + LZMA_PROPS_SIZE, &comp_len, in, inlen, &lzma_props, out + 4, &props_size, 0, NULL, &Alloc, &Alloc)) { return -1; } // Fill in LZMA properties header offset = 0; if (props_size != LZMA_PROPS_SIZE) { // Move LZMA properties to be adjacent to the compressed data, because for // some reaseon the library didn't use all the space provided. int i; offset = (int)(LZMA_PROPS_SIZE - props_size); for (i = 4 + LZMA_PROPS_SIZE - 1; i > 4 + offset; --i) { out[i] = out[i - offset]; } } out[offset] = MY_VER_MAJOR; out[offset+1] = MY_VER_MINOR; out[offset+2] = (Byte)props_size; out[offset+3] = 0; // Add header length to outlen *outlen = (unsigned int)(comp_len + 4 + props_size); return offset; } //========================================================================== // // compress_bzip2 // // Returns 0 on success, negative on failure. // //========================================================================== int compress_bzip2(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen) { if (BZ_OK == BZ2_bzBuffToBuffCompress((char *)out, outlen, (char *)in, inlen, 9, 0, 0)) { return 0; } return -1; } #ifdef PPMD //========================================================================== // // compress_ppmd // // Returns 0 on success, negative on failure. // // Big problem here: The zip format only allows for PPMd I rev. 1. This // version of the code is incompatible with 64-bit processors. PPMd J rev. 1 // corrects this and also compresses slightly better, but it also changes // the data format and is incompatible with I rev. 1. The PPMd source code // is a tangled mass that I cannot comprehend, so fixing I rev. 1 to work // on 64-bit processors is well beyond my means. Hence, I cannot currently // support PPMd in zips. If the zip spec gets updated to allow J rev. 1, // then I can, but not any sooner. // //========================================================================== int compress_ppmd(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen) { int maxorder = 8; int sasize = 8; int cutoff = 0; _PPMD_FILE ppsin = { (char *)in, inlen, 0 }; _PPMD_FILE ppsout = { out + 2, *outlen - 2, 0}; if (!PPMd_StartSubAllocator(sasize)) { return -1; } PPMd_EncodeFile(&ppsout, &ppsin, maxorder, cutoff); PPMd_StopSubAllocator(); if (ppsout.eof) { return -1; } if (!ppsin.eof) { return -1; } const short outval = LittleShort((maxorder - 1) + ((sasize - 1) << 4) + (cutoff << 12)); memcpy(out, (const Byte *)&outval, sizeof(short)); *outlen = *outlen - ppsout.buffersize; return 0; } #endif //========================================================================== // // compress_deflate // // Returns 0 on success, negative on failure. // //========================================================================== int compress_deflate(Byte *out, unsigned int *outlen, const Byte *in, unsigned int inlen) { z_stream stream; int err; stream.next_in = (Bytef *)in; stream.avail_in = inlen; stream.next_out = out; stream.avail_out = *outlen; stream.zalloc = (alloc_func)0; stream.zfree = (free_func)0; stream.opaque = (voidpf)0; err = deflateInit2(&stream, 9, Z_DEFLATED, -15, 9, Z_DEFAULT_STRATEGY); if (err != Z_OK) return -1; err = deflate(&stream, Z_FINISH); if (err != Z_STREAM_END) { deflateEnd(&stream); return -1; } *outlen = stream.total_out; err = deflateEnd(&stream); return err == Z_OK ? 0 : -1; } //========================================================================== // // find_central_dir // // Finds and loads the central directory records in the file. // Taken from Quake3 source and modified. // //========================================================================== BYTE *find_central_dir(FILE *fin) { unsigned char buf[BUFREADCOMMENT + 4]; EndOfCentralDirectory eod; BYTE *dir; long file_size; long back_read; long max_back; // maximum size of global comment long pos_found = 0; fseek(fin, 0, SEEK_END); file_size = ftell(fin); max_back = 0xffff > file_size ? file_size : 0xffff; back_read = 4; while (back_read < max_back) { UINT32 read_size, read_pos; int i; if (back_read + BUFREADCOMMENT > max_back) back_read = max_back; else back_read += BUFREADCOMMENT; read_pos = file_size - back_read; read_size = (BUFREADCOMMENT + 4) < (file_size - read_pos) ? (BUFREADCOMMENT + 4) : (file_size - read_pos); if (fseek(fin, read_pos, SEEK_SET) != 0) return NULL; if (fread(buf, 1, read_size, fin) != read_size) return NULL; for (i = (int)read_size - 3; (i--) > 0;) { if (buf[i] == 'P' && buf[i+1] == 'K' && buf[i+2] == 5 && buf[i+3] == 6) { pos_found = read_pos + i; break; } } if (pos_found != 0) break; } if (pos_found == 0 || fseek(fin, pos_found, SEEK_SET) != 0 || fread(&eod, sizeof(eod), 1, fin) != 1 || fseek(fin, LittleLong(eod.DirectoryOffset), SEEK_SET) != 0) { return NULL; } dir = malloc(LittleLong(eod.DirectorySize) + 4); if (dir == NULL) { no_mem = 1; return NULL; } if (fread(dir, 1, LittleLong(eod.DirectorySize), fin) != LittleLong(eod.DirectorySize)) { free(dir); return NULL; } if (memcmp(dir, (const BYTE *)¢ralfile, sizeof(UINT32)) != 0) { free(dir); return NULL; } memcpy(dir + LittleLong(eod.DirectorySize), (const BYTE *)&endofdir, sizeof(UINT32)); return dir; } //========================================================================== // // find_file_in_zip // // Returns a pointer to a central directory entry to a file, if it was // found in the zip's directory. Data endianness is in zip order. // //========================================================================== CentralDirectoryEntry *find_file_in_zip(BYTE *dir, const char *path, unsigned int len, unsigned int crc, short date, short time) { int pathlen = (int)strlen(path); CentralDirectoryEntry *ent; int flags; while (memcmp(dir, (const BYTE *)¢ralfile, sizeof(UINT32)) == 0) { ent = (CentralDirectoryEntry *)dir; if (pathlen == LittleShort(ent->NameLength) && strncmp((char *)(ent + 1), path, pathlen) == 0) { // Found something that matches by name. break; } dir += sizeof(*ent) + LittleShort(ent->NameLength) + LittleShort(ent->ExtraLength) + LittleShort(ent->CommentLength); } if (memcmp(dir, (const BYTE *)¢ralfile, sizeof(UINT32)) != 0) { return NULL; } if (crc != LittleLong(ent->CRC32)) { return NULL; } if (len != LittleLong(ent->UncompressedSize)) { return NULL; } // Should I check modification date and time here? flags = LittleShort(ent->Flags); if (flags & 1) { // Don't want to deal with encryption. return NULL; } if (ent->ExtraLength != 0) { // Don't want to deal with extra data. return NULL; } // Okay, looks good. return ent; } //========================================================================== // // copy_zip_file // // Copies one file from ozip to zip. Returns positive on success, zero if // the file could not be found, and negative if it failed while writing the // file. // //========================================================================== int copy_zip_file(FILE *zip, file_entry_t *file, FILE *ozip, CentralDirectoryEntry *ent) { LocalFileHeader lfh; BYTE *buf; UINT32 buf_size; if (fseek(ozip, LittleLong(ent->LocalHeaderOffset), SEEK_SET) != 0) { return 0; } if (fread(&lfh, sizeof(lfh), 1, ozip) != 1) { return 0; } // Check to make sure the local header matches the central directory. if (lfh.Flags != ent->Flags || lfh.Method != ent->Method || lfh.CRC32 != ent->CRC32 || lfh.CompressedSize != ent->CompressedSize || lfh.UncompressedSize != ent->UncompressedSize || lfh.NameLength != ent->NameLength || lfh.ExtraLength != ent->ExtraLength) { return 0; } buf_size = LittleShort(lfh.NameLength) + LittleLong(lfh.CompressedSize); buf = malloc(buf_size); if (buf == NULL) { return 0; } if (fread(buf, 1, buf_size, ozip) != buf_size) { free(buf); return 0; } // Check to be sure name matches. if (strncmp((char *)buf, (char *)(ent + 1), LittleShort(lfh.NameLength)) != 0) { free(buf); return 0; } // Looks good. Let's write it in. file->zip_offset = ftell(zip); if (fwrite(&lfh, sizeof(lfh), 1, zip) != 1 || fwrite(buf, 1, buf_size, zip) != buf_size) { free(buf); return -1; } free(buf); file->date = lfh.ModDate; file->time = lfh.ModTime; file->uncompressed_size = LittleLong(lfh.UncompressedSize); file->compressed_size = LittleLong(lfh.CompressedSize); file->method = LittleShort(lfh.Method); file->crc32 = lfh.CRC32; return 1; } //========================================================================== // // main // //========================================================================== int main (int argc, char **argv) { dir_tree_t *tree, *trees; file_entry_t *file; struct stat zipstat; int needwrite; int i, j, k; int force = 0; int update = 0; // Find options. Options are removed from the array. for (i = k = 1; i < argc; ++i) { if (argv[i][0] == '-') { if (argv[i][1] == '-') { if (argv[i][2] == '\0') { // -- terminates option handling for the rest of the command line break; } } for (j = 1; argv[i][j] != '\0'; ++j) { if (argv[i][j] == 'f') { force = 1; } else if (argv[i][j] == 'd') { DeflateOnly = 1; } else if (argv[i][j] == 'u') { update = 1; } else if (argv[i][j] == 'q') { Quiet = 1; } else { fprintf(stderr, "Unknown option '%c'\n", argv[i][j]); print_usage(argv[0]); return 1; } } } else { argv[k++] = argv[i]; } } for (; i <= argc; ++i) { argv[k++] = argv[i]; } argc -= i - k; if (argc < 3) { print_usage(argv[0]); return 1; } trees = add_dirs(&argv[2]); if (no_mem) { free_dir_trees(trees); fprintf(stderr, "Out of memory.\n"); return 1; } needwrite = force; if (stat(argv[1], &zipstat) != 0) { if (errno == ENOENT) { needwrite = 1; update = 0; // Can't update what's not there. } else { fprintf(stderr, "Could not stat %s: %s\n", argv[1], strerror(errno)); } } else if (!needwrite) { // Check the files in each tree. If any one of them was modified more // recently than the zip, then it needs to be recreated. for (tree = trees; tree != NULL; tree = tree->next) { for (file = tree->files; file != NULL; file = file->next) { if (file->time_write > zipstat.st_mtime) { needwrite = 1; break; } } } } if (force || needwrite) { write_zip(argv[1], trees, update); } free_dir_trees(trees); if (no_mem) { fprintf(stderr, "Out of memory.\n"); return 1; } return 0; } //========================================================================== // // bz_internal_error // // libbzip2 wants this, since we build it with BZ_NO_STDIO set. // //========================================================================== void bz_internal_error (int errcode) { fprintf(stderr, "libbzip2: internal error number %d\n", errcode); exit(3); }