#include #include #include #include #include #include #include #include #include #include #include #if (defined(OS_DARWIN) || defined(OS_FREEBSD)) && defined(__GNUC__) # include #else # include #endif #if defined OS_DARWIN # include // define 64 bit macros # define htole64(x) OSSwapHostToLittleInt64(x) #endif #include "types.h" /// blocking write ssize_t write_data(int fd, const void *buf, size_t count) { for (size_t n = 0; n < count;) { ssize_t sz = write(fd, reinterpret_cast(buf) + n, count - n); if (sz < 0) { if (errno == EINTR) continue; return sz; } n += sz; } return count; } /// blocking read ssize_t read_data(int fd, void *buf, size_t count) { for (size_t n = 0; n < count;) { ssize_t sz = read(fd, reinterpret_cast(buf) + n, count - n); if (sz < 0) { if (errno == EINTR) continue; return sz; } if (sz == 0) return count - n; n += sz; } return count; } /// Main compression part int doCompress(char * input, char * output, off_t & in_offset, off_t & out_offset, off_t input_size, off_t output_size, ZSTD_CCtx * cctx) { size_t compressed_size = ZSTD_compress2(cctx, output + out_offset, output_size, input + in_offset, input_size); if (ZSTD_isError(compressed_size)) { std::cerr << "Error (ZSTD): " << compressed_size << " " << ZSTD_getErrorName(compressed_size) << std::endl; return 1; } in_offset += input_size; out_offset += compressed_size; return 0; } /// compress data from opened file into output file int compress(int in_fd, int out_fd, int level, off_t & pointer, const struct stat & info_in, uint64_t & compressed_size) { off_t in_offset = 0; compressed_size = 0; /// mmap files char * input = static_cast(mmap(nullptr, info_in.st_size, PROT_READ, MAP_PRIVATE, in_fd, 0)); if (input == MAP_FAILED) { perror(nullptr); return 1; } /// Create context ZSTD_CCtx * cctx = ZSTD_createCCtx(); if (cctx == nullptr) { std::cerr << "Error (ZSTD): failed to create compression context" << std::endl; return 1; } size_t check_result; /// Set level and enable checksums check_result = ZSTD_CCtx_setParameter(cctx, ZSTD_c_compressionLevel, level); if (ZSTD_isError(check_result)) { std::cerr << "Error (ZSTD): " << check_result << " " << ZSTD_getErrorName(check_result) << std::endl; ZSTD_freeCCtx(cctx); return 1; } check_result = ZSTD_CCtx_setParameter(cctx, ZSTD_c_checksumFlag, 1); if (ZSTD_isError(check_result)) { std::cerr << "Error (ZSTD): " << check_result << " " << ZSTD_getErrorName(check_result) << std::endl; ZSTD_freeCCtx(cctx); return 1; } /// limits for size of block to prevent high memory usage or bad compression off_t max_block_size = 1ull<<27; off_t min_block_size = 1ull<<23; off_t size = 0; off_t current_block_size = 0; /// Create buffer for compression /// Block can't become much bigger after compression. char * output = static_cast( mmap(nullptr, 2 * max_block_size, PROT_READ | PROT_WRITE, MAP_ANON | MAP_PRIVATE, -1, 0) ); if (output == MAP_FAILED) { perror(nullptr); ZSTD_freeCCtx(cctx); return 1; } if (-1 == lseek(out_fd, 0, SEEK_END)) { perror(nullptr); ZSTD_freeCCtx(cctx); return 1; } uint64_t total_size = 0; /// Compress data while (in_offset < info_in.st_size) { /// take blocks of maximum size /// optimize last block (it can be bigger, if it is not too huge) if (info_in.st_size - in_offset < max_block_size || info_in.st_size - in_offset < max_block_size + min_block_size) size = info_in.st_size - in_offset; else size = max_block_size; /// Compress data or exit if error happens if (0 != doCompress(input, output, in_offset, current_block_size, size, ZSTD_compressBound(size), cctx)) { if (0 != munmap(input, info_in.st_size)) perror(nullptr); if (0 != munmap(output, 2 * max_block_size)) perror(nullptr); ZSTD_freeCCtx(cctx); return 1; } /// Save data into file and refresh pointer if (current_block_size != write_data(out_fd, output, current_block_size)) { perror(nullptr); ZSTD_freeCCtx(cctx); return 1; } pointer += current_block_size; printf("...block compression rate: %.2f%%\n", static_cast(current_block_size) / size * 100); total_size += size; compressed_size += current_block_size; current_block_size = 0; } std::cout << "Compressed size: " << compressed_size << ", compression rate: " << std::fixed << std::setprecision(2) << static_cast(compressed_size) / total_size * 100 << "%" << std::endl; if (0 != munmap(input, info_in.st_size) || 0 != munmap(output, 2 * max_block_size)) { perror(nullptr); ZSTD_freeCCtx(cctx); return 1; } ZSTD_freeCCtx(cctx); return 0; } /// Save Metadata at the end of file int saveMetaData(const char* filenames[], int count, int output_fd, const MetaData& metadata, FileData* files_data, size_t pointer, size_t sum_file_size) { /// Allocate memory for metadata if (0 != ftruncate(output_fd, pointer + count * sizeof(FileData) + sum_file_size + sizeof(MetaData))) { perror(nullptr); return 1; } char * output = static_cast( mmap(nullptr, pointer + count * sizeof(FileData) + sum_file_size + sizeof(MetaData), PROT_READ | PROT_WRITE, MAP_SHARED, output_fd, 0) ); if (output == MAP_FAILED) { perror(nullptr); return 1; } /// save information about files and their names for (int i = 0; i < count; ++i) { /// Save file data memcpy(output + pointer, reinterpret_cast(files_data + i), sizeof(FileData)); pointer += sizeof(FileData); /// Save file name memcpy(output + pointer, filenames[i], files_data[i].name_length); pointer += files_data[i].name_length; } /// Save metadata memcpy(output + pointer, reinterpret_cast(&metadata), sizeof(MetaData)); return 0; } /// Fills metadata and calls compression function for each file int compressFiles(const char* out_name, const char* exec, char* filenames[], int count, int output_fd, int level, const struct stat& info_out) { MetaData metadata; size_t sum_file_size = 0; int is_exec = exec && *exec ? 1 : 0; metadata.number_of_files = htole64(count + is_exec); off_t pointer = info_out.st_size; uint64_t total_size = 0; uint64_t total_compressed_size = 0; /// Store information about each file and compress it FileData* files_data = new FileData[count + is_exec]; const char * names[count + is_exec]; for (int i = 0; i <= count; ++i) { const char* filename = nullptr; if (i == count) { if (!is_exec) continue; filename = exec; files_data[i].exec = true; } else filename = filenames[i]; printf("Compressing: %s\n", filename); int input_fd = open(filename, O_RDONLY); if (input_fd == -1) { perror(nullptr); delete [] files_data; return 1; } /// Remember information about file name /// This should be made after the file is opened /// because filename should be extracted from path names[i] = strrchr(filename, '/'); if (names[i]) ++names[i]; else names[i] = filename; size_t nlen = strlen(names[i]) + 1; files_data[i].name_length = htole64(nlen); sum_file_size += nlen; /// if no --exec is specified nor it's empty - file which is matching output name is executable if (!is_exec && !exec && strcmp(names[i], out_name) == 0) files_data[i].exec = true; /// read data about input file struct stat info_in; if (0 != fstat(input_fd, &info_in)) { perror(nullptr); delete [] files_data; return 1; } if (info_in.st_size == 0) { printf("...empty file, skipped.\n"); continue; } std::cout << "Size: " << info_in.st_size << std::endl; total_size += info_in.st_size; /// Save umask files_data[i].umask = htole64(info_in.st_mode); /// Remember information about uncompressed size of file and /// start of it's compression version files_data[i].uncompressed_size = htole64(info_in.st_size); files_data[i].start = htole64(pointer); uint64_t compressed_size = 0; /// Compressed data will be added to the end of file /// It will allow to create self extracting executable from file if (0 != compress(input_fd, output_fd, level, pointer, info_in, compressed_size)) { perror(nullptr); delete [] files_data; return 1; } total_compressed_size += compressed_size; /// This error is less important, than others. /// If file cannot be closed, in some cases it will lead to /// error in other function that will stop compression process if (0 != close(input_fd)) perror(nullptr); files_data[i].end = htole64(pointer); } /// save location of files information metadata.start_of_files_data = htole64(pointer); if (0 != saveMetaData(names, count + is_exec, output_fd, metadata, files_data, pointer, sum_file_size)) { delete [] files_data; return 1; } std::cout << "Compression rate: " << std::fixed << std::setprecision(2) << static_cast(total_compressed_size) / total_size * 100 << "%" << std::endl; delete [] files_data; return 0; } int copy_decompressor(int input_fd, int decompressor_size, int output_fd) { const ssize_t buf_size = 1ul<<19; auto buf_memory = std::make_unique(buf_size); char * buf = buf_memory.get(); while (decompressor_size > 0) { ssize_t read_size = decompressor_size > buf_size ? buf_size : decompressor_size; ssize_t n = read_data(input_fd, buf, read_size); if (n < read_size) { perror(nullptr); return 1; } decompressor_size -= n; if (n != write_data(output_fd, buf, n)) { perror(nullptr); return 1; } } return 0; } int copy_decompressor_self(const char *self, int output_fd) { int input_fd = open(self, O_RDONLY); if (input_fd == -1) { perror(nullptr); return 1; } if (-1 == lseek(input_fd, -15, SEEK_END)) { perror(nullptr); close(input_fd); return 1; } char size_str[16] = {0}; if (ssize_t sz = read_data(input_fd, size_str, 15); sz < 15) { if (sz < 0) perror(nullptr); else std::cerr << "Error: unable to extract decompressor" << std::endl; close(input_fd); return 1; } char * end = nullptr; int decompressor_size = strtol(size_str, &end, 10); if (*end != 0) { std::cerr << "Error: unable to extract decompressor" << std::endl; close(input_fd); return 1; } if (-1 == lseek(input_fd, -(decompressor_size + 15), SEEK_END)) { perror(nullptr); close(input_fd); return 1; } int ret = copy_decompressor(input_fd, decompressor_size, output_fd); close(input_fd); return ret; } int copy_decompressor_file(const char *path, int output_fd) { struct stat info_in; if (stat(path, &info_in) != 0) { std::cerr << "Error: decompressor file [" << path << "]." << std::endl; perror(nullptr); return 1; } if (!S_ISREG(info_in.st_mode)) { std::cerr << "Error: decompressor path [" << path << "] is not a file." << std::endl; return 1; } int input_fd = open(path, O_RDONLY); if (input_fd == -1) { perror(nullptr); return 1; } int ret = copy_decompressor(input_fd, info_in.st_size, output_fd); close(input_fd); return ret; } inline void usage(FILE * out, const char * name) { (void)fprintf(out, "%s [--level=] [--decompressor=] [--exec=] [ [... ]]\n" "\t--level - compression level, max is %d, negative - prefer speed over compression\n" "\t default is 5\n" "\t--decompressor - path to decompressor\n" "\t--exec - path to an input file to execute after decompression, if omitted then\n" "\t an having the same name as becomes such executable.\n" "\t This executable upon decompression will substitute started compressed preserving compressed name.\n" "\t If no is specified - nothing will be run - only decompression will be performed.\n", name, ZSTD_maxCLevel()); } const char * get_param(int argc, char * const argv[], const char * name) { if (nullptr == name || name[0] == 0) return nullptr; for (int i = 1; i < argc; ++i) { const char * arg = argv[i]; if (arg[0] != '-' || arg[1] != '-') return nullptr; size_t arg_len = strlen(arg); size_t name_len = strlen(name); const char * eq = strchr(arg + 2, '='); if (nullptr == eq) eq = arg + arg_len; if (name_len != static_cast(eq - arg - 2)) continue; if (0 == memcmp(name, arg + 2, name_len)) return *eq == 0 ? eq : eq + 1; } return nullptr; } int main(int argc, char* argv[]) { if (argc == 1) { usage(stdout, argv[0]); return 0; } int start_of_files = 1; /// Set compression level int level = 5; const char * p = get_param(argc, argv, "level"); if (p != nullptr) { if (p[0] != 0) { char * end = nullptr; level = strtol(p, &end, 10); if (*end != 0) { std::cerr << "Error: level [" << p << "] is not valid" << std::endl; usage(stderr, argv[0]); return 1; } } ++start_of_files; } /// Set decompressor const char * decompressor = get_param(argc, argv, "decompressor"); if (decompressor != nullptr) { if (decompressor[0] == 0) decompressor = nullptr; ++start_of_files; } /// Specified executable const char * exec = get_param(argc, argv, "exec"); if (exec != nullptr) ++start_of_files; if (argc < start_of_files + (exec == nullptr || *exec == 0 ? 1 : 0)) { usage(stderr, argv[0]); return 1; } struct stat info_out; if (stat(argv[start_of_files], &info_out) != -1 || errno != ENOENT) { std::cerr << "Error: output file [" << argv[start_of_files] << "] already exists" << std::endl; return 1; } int output_fd = open(argv[start_of_files], O_RDWR | O_CREAT, 0775); if (output_fd == -1) { perror(nullptr); return 1; } const char* out_name = strrchr(argv[start_of_files], '/'); if (out_name) ++out_name; else out_name = argv[start_of_files]; ++start_of_files; if (decompressor != nullptr) { if (copy_decompressor_file(decompressor, output_fd)) return 1; } else { if (copy_decompressor_self(argv[0], output_fd)) return 1; } if (0 != fstat(output_fd, &info_out)) { perror(nullptr); return 1; } std::cout << "Compression with level: " << level << std::endl; if (0 != compressFiles(out_name, exec, &argv[start_of_files], argc - start_of_files, output_fd, level, info_out)) { printf("Compression failed.\n"); close(output_fd); unlink(argv[start_of_files - 1]); return 1; } printf("Successfully compressed.\n"); if (0 != close(output_fd)) perror(nullptr); return 0; }