/* ** zipdir.c ** Copyright (C) 2008 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 ... ** ** 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 #include #include #include #include #include #include #include #include "zip.h" // MACROS ------------------------------------------------------------------ #ifndef _WIN32 #define __cdecl #endif // TYPES ------------------------------------------------------------------- typedef struct file_entry_s { struct file_entry_s *next; time_t time_write; 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; // 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); void recurse_dir(dir_tree_t *tree, const char *dirpath); dir_tree_t *add_dir(const char *dirpath); int count_files(dir_tree_t *trees); int __cdecl 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 append_to_zip(zipFile zipfile, const file_sorted_t *file); // PRIVATE FUNCTION PROTOTYPES --------------------------------------------- // EXTERNAL DATA DECLARATIONS ---------------------------------------------- // PUBLIC DATA DEFINITIONS ------------------------------------------------- // PRIVATE DATA DEFINITIONS ------------------------------------------------ static int no_mem; // 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 ...\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); strlwr(entry->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); } } //========================================================================== // // recurse_dir // //========================================================================== void recurse_dir(dir_tree_t *tree, const char *dirpath) { struct _finddata_t fileinfo; char *dirmatch; intptr_t handle; 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; 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; } //========================================================================== // // 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 __cdecl 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 i, num_files; file_sorted_t *sorted; zipFile zip; num_files = count_files(trees); sorted = sort_files(trees, num_files); if (sorted == NULL) { no_mem = 1; return; } zip = zipOpen(zipname, APPEND_STATUS_CREATE); if (zip == NULL) { fprintf(stderr, "Could not open %s: %s\n", zipname, strerror(errno)); } else { for (i = 0; i < num_files; ++i) { append_to_zip(zip, sorted + i); } zipClose(zip, NULL); printf("Wrote %d/%d files to %s\n", i, num_files, zipname); } free(sorted); } //========================================================================== // // 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(zipFile zipfile, const file_sorted_t *file) { char *readbuf; FILE *lumpfile; size_t readlen; size_t len; zip_fileinfo zip_inf; struct tm *ltime; // clear zip_inf structure memset(&zip_inf, 0, sizeof(zip_inf)); // try to determine local time ltime = localtime(&file->file->time_write); // if succeeded, if (ltime != NULL) { // put it into the zip_inf structure zip_inf.tmz_date.tm_sec = ltime->tm_sec; zip_inf.tmz_date.tm_min = ltime->tm_min; zip_inf.tmz_date.tm_hour = ltime->tm_hour; zip_inf.tmz_date.tm_mday = ltime->tm_mday; zip_inf.tmz_date.tm_mon = ltime->tm_mon; zip_inf.tmz_date.tm_year = ltime->tm_year; } // lumpfile = source file lumpfile = fopen(file->file->path, "rb"); if (lumpfile == NULL) { fprintf(stderr, "Could not open %s: %s\n", file->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 = 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->file->path); return 1; } // file loaded // create zip entry, giving entry name and zip_inf data, // write data into zipfile, and close the zip entry if (Z_OK != zipAddFileToZip(zipfile, file->path_in_zip, &zip_inf, readbuf, (unsigned)len)) { free(readbuf); fprintf(stderr, "Unable to write %s to zip\n", file->file->path); return 1; } // all done free(readbuf); return 0; } int __cdecl main (int argc, char **argv) { int i; dir_tree_t *tree, *trees; file_entry_t *file; struct _stat zipstat; int needwrite; char *s; if (argc < 3) { print_usage(argv[0]); return 1; } trees = NULL; for (i = 2; i < argc; ++i) { #ifdef _WIN32 for (s = argv[i]; *s != '\0'; ++s) { if (*s == '\\') { *s = '/'; } } #endif tree = add_dir(argv[i]); tree->next = trees; trees = tree; if(no_mem) { free_dir_trees(trees); fprintf(stderr, "Out of memory.\n"); return 1; } } needwrite = 0; if (_stat(argv[1], &zipstat) != 0) { if (errno == ENOENT) { needwrite = 1; } else { fprintf(stderr, "Could not stat %s: %s\n", argv[1], strerror(errno)); } } else { // 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 (needwrite) { write_zip(argv[1], trees); } free_dir_trees(trees); if (no_mem) { fprintf(stderr, "Out of memory.\n"); return 1; } return 0; }