/////////////////////////////////////////////////////////////////////////////// // /// \file list.c /// \brief Listing information about .xz files // // Author: Lasse Collin // // This file has been put into the public domain. // You can do whatever you want with this file. // /////////////////////////////////////////////////////////////////////////////// #include "private.h" #include "tuklib_integer.h" /// Information about a .xz file typedef struct { /// Combined Index of all Streams in the file lzma_index *idx; /// Total amount of Stream Padding uint64_t stream_padding; /// Highest memory usage so far uint64_t memusage_max; /// True if all Blocks so far have Compressed Size and /// Uncompressed Size fields bool all_have_sizes; /// Oldest XZ Utils version that will decompress the file uint32_t min_version; } xz_file_info; #define XZ_FILE_INFO_INIT { NULL, 0, 0, true, 50000002 } /// Information about a .xz Block typedef struct { /// Size of the Block Header uint32_t header_size; /// A few of the Block Flags as a string char flags[3]; /// Size of the Compressed Data field in the Block lzma_vli compressed_size; /// Decoder memory usage for this Block uint64_t memusage; /// The filter chain of this Block in human-readable form char filter_chain[FILTERS_STR_SIZE]; } block_header_info; /// Strings ending in a colon. These are used for lines like /// " Foo: 123 MiB". These are grouped because translated strings /// may have different maximum string length, and we want to pad all /// strings so that the values are aligned nicely. static const char *colon_strs[] = { N_("Streams:"), N_("Blocks:"), N_("Compressed size:"), N_("Uncompressed size:"), N_("Ratio:"), N_("Check:"), N_("Stream Padding:"), N_("Memory needed:"), N_("Sizes in headers:"), // This won't be aligned because it's so long: //N_("Minimum XZ Utils version:"), N_("Number of files:"), }; /// Enum matching the above strings. enum { COLON_STR_STREAMS, COLON_STR_BLOCKS, COLON_STR_COMPRESSED_SIZE, COLON_STR_UNCOMPRESSED_SIZE, COLON_STR_RATIO, COLON_STR_CHECK, COLON_STR_STREAM_PADDING, COLON_STR_MEMORY_NEEDED, COLON_STR_SIZES_IN_HEADERS, //COLON_STR_MINIMUM_XZ_VERSION, COLON_STR_NUMBER_OF_FILES, }; /// Field widths to use with printf to pad the strings to use the same number /// of columns on a terminal. static int colon_strs_fw[ARRAY_SIZE(colon_strs)]; /// Convenience macro to get the translated string and its field width /// using a COLON_STR_foo enum. #define COLON_STR(num) colon_strs_fw[num], _(colon_strs[num]) /// Column headings struct { /// Table column heading string const char *str; /// Number of terminal-columns to use for this table-column. /// If a translated string is longer than the initial value, /// this value will be increased in init_headings(). int columns; /// Field width to use for printf() to pad "str" to use "columns" /// number of columns on a terminal. This is calculated in /// init_headings(). int fw; } headings[] = { { N_("Stream"), 6, 0 }, { N_("Block"), 9, 0 }, { N_("Blocks"), 9, 0 }, { N_("CompOffset"), 15, 0 }, { N_("UncompOffset"), 15, 0 }, { N_("CompSize"), 15, 0 }, { N_("UncompSize"), 15, 0 }, { N_("TotalSize"), 15, 0 }, { N_("Ratio"), 5, 0 }, { N_("Check"), 10, 0 }, { N_("CheckVal"), 1, 0 }, { N_("Padding"), 7, 0 }, { N_("Header"), 5, 0 }, { N_("Flags"), 2, 0 }, { N_("MemUsage"), 7 + 4, 0 }, // +4 is for " MiB" { N_("Filters"), 1, 0 }, }; /// Enum matching the above strings. enum { HEADING_STREAM, HEADING_BLOCK, HEADING_BLOCKS, HEADING_COMPOFFSET, HEADING_UNCOMPOFFSET, HEADING_COMPSIZE, HEADING_UNCOMPSIZE, HEADING_TOTALSIZE, HEADING_RATIO, HEADING_CHECK, HEADING_CHECKVAL, HEADING_PADDING, HEADING_HEADERSIZE, HEADING_HEADERFLAGS, HEADING_MEMUSAGE, HEADING_FILTERS, }; #define HEADING_STR(num) headings[num].fw, _(headings[num].str) /// Check ID to string mapping static const char check_names[LZMA_CHECK_ID_MAX + 1][12] = { // TRANSLATORS: Indicates that there is no integrity check. // This string is used in tables. In older xz version this // string was limited to ten columns in a fixed-width font, but // nowadays there is no strict length restriction anymore. N_("None"), "CRC32", // TRANSLATORS: Indicates that integrity check name is not known, // but the Check ID is known (here 2). In older xz version these // strings were limited to ten columns in a fixed-width font, but // nowadays there is no strict length restriction anymore. N_("Unknown-2"), N_("Unknown-3"), "CRC64", N_("Unknown-5"), N_("Unknown-6"), N_("Unknown-7"), N_("Unknown-8"), N_("Unknown-9"), "SHA-256", N_("Unknown-11"), N_("Unknown-12"), N_("Unknown-13"), N_("Unknown-14"), N_("Unknown-15"), }; /// Buffer size for get_check_names(). This may be a bit ridiculous, /// but at least it's enough if some language needs many multibyte chars. #define CHECKS_STR_SIZE 1024 /// Value of the Check field as hexadecimal string. /// This is set by parse_check_value(). static char check_value[2 * LZMA_CHECK_SIZE_MAX + 1]; /// Totals that are displayed if there was more than one file. /// The "files" counter is also used in print_info_adv() to show /// the file number. static struct { uint64_t files; uint64_t streams; uint64_t blocks; uint64_t compressed_size; uint64_t uncompressed_size; uint64_t stream_padding; uint64_t memusage_max; uint32_t checks; uint32_t min_version; bool all_have_sizes; } totals = { 0, 0, 0, 0, 0, 0, 0, 0, 50000002, true }; /// Initialize colon_strs_fw[]. static void init_colon_strs(void) { // Lengths of translated strings as bytes. size_t lens[ARRAY_SIZE(colon_strs)]; // Lengths of translated strings as columns. size_t widths[ARRAY_SIZE(colon_strs)]; // Maximum number of columns needed by a translated string. size_t width_max = 0; for (unsigned i = 0; i < ARRAY_SIZE(colon_strs); ++i) { widths[i] = tuklib_mbstr_width(_(colon_strs[i]), &lens[i]); // If debugging is enabled, catch invalid strings with // an assertion. However, when not debugging, use the // byte count as the fallback width. This shouldn't // ever happen unless there is a bad string in the // translations, but in such case I guess it's better // to try to print something useful instead of failing // completely. assert(widths[i] != (size_t)-1); if (widths[i] == (size_t)-1) widths[i] = lens[i]; if (widths[i] > width_max) width_max = widths[i]; } // Calculate the field width for printf("%*s") so that the strings // will use width_max columns on a terminal. for (unsigned i = 0; i < ARRAY_SIZE(colon_strs); ++i) colon_strs_fw[i] = (int)(lens[i] + width_max - widths[i]); return; } /// Initialize headings[]. static void init_headings(void) { // Before going through the heading strings themselves, treat // the Check heading specially: Look at the widths of the various // check names and increase the width of the Check column if needed. // The width of the heading name "Check" will then be handled normally // with other heading names in the second loop in this function. for (unsigned i = 0; i < ARRAY_SIZE(check_names); ++i) { size_t len; size_t w = tuklib_mbstr_width(_(check_names[i]), &len); // Error handling like in init_colon_strs(). assert(w != (size_t)-1); if (w == (size_t)-1) w = len; // If the translated string is wider than the minimum width // set at compile time, increase the width. if ((size_t)(headings[HEADING_CHECK].columns) < w) headings[HEADING_CHECK].columns = w; } for (unsigned i = 0; i < ARRAY_SIZE(headings); ++i) { size_t len; size_t w = tuklib_mbstr_width(_(headings[i].str), &len); // Error handling like in init_colon_strs(). assert(w != (size_t)-1); if (w == (size_t)-1) w = len; // If the translated string is wider than the minimum width // set at compile time, increase the width. if ((size_t)(headings[i].columns) < w) headings[i].columns = w; // Calculate the field width for printf("%*s") so that // the string uses .columns number of columns on a terminal. headings[i].fw = (int)(len + (size_t)headings[i].columns - w); } return; } /// Initialize the printf field widths that are needed to get nicely aligned /// output with translated strings. static void init_field_widths(void) { init_colon_strs(); init_headings(); return; } /// Convert XZ Utils version number to a string. static const char * xz_ver_to_str(uint32_t ver) { static char buf[32]; unsigned int major = ver / 10000000U; ver -= major * 10000000U; unsigned int minor = ver / 10000U; ver -= minor * 10000U; unsigned int patch = ver / 10U; ver -= patch * 10U; const char *stability = ver == 0 ? "alpha" : ver == 1 ? "beta" : ""; snprintf(buf, sizeof(buf), "%u.%u.%u%s", major, minor, patch, stability); return buf; } /// \brief Parse the Index(es) from the given .xz file /// /// \param xfi Pointer to structure where the decoded information /// is stored. /// \param pair Input file /// /// \return On success, false is returned. On error, true is returned. /// static bool parse_indexes(xz_file_info *xfi, file_pair *pair) { if (pair->src_st.st_size <= 0) { message_error(_("%s: File is empty"), pair->src_name); return true; } if (pair->src_st.st_size < 2 * LZMA_STREAM_HEADER_SIZE) { message_error(_("%s: Too small to be a valid .xz file"), pair->src_name); return true; } io_buf buf; lzma_stream strm = LZMA_STREAM_INIT; lzma_index *idx = NULL; lzma_ret ret = lzma_file_info_decoder(&strm, &idx, hardware_memlimit_get(MODE_LIST), (uint64_t)(pair->src_st.st_size)); if (ret != LZMA_OK) { message_error("%s: %s", pair->src_name, message_strm(ret)); return true; } while (true) { if (strm.avail_in == 0) { strm.next_in = buf.u8; strm.avail_in = io_read(pair, &buf, IO_BUFFER_SIZE); if (strm.avail_in == SIZE_MAX) goto error; } ret = lzma_code(&strm, LZMA_RUN); switch (ret) { case LZMA_OK: break; case LZMA_SEEK_NEEDED: // liblzma won't ask us to seek past the known size // of the input file. assert(strm.seek_pos <= (uint64_t)(pair->src_st.st_size)); if (io_seek_src(pair, strm.seek_pos)) goto error; // avail_in must be zero so that we will read new // input. strm.avail_in = 0; break; case LZMA_STREAM_END: { lzma_end(&strm); xfi->idx = idx; // Calculate xfi->stream_padding. lzma_index_iter iter; lzma_index_iter_init(&iter, xfi->idx); while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)) xfi->stream_padding += iter.stream.padding; return false; } default: message_error("%s: %s", pair->src_name, message_strm(ret)); // If the error was too low memory usage limit, // show also how much memory would have been needed. if (ret == LZMA_MEMLIMIT_ERROR) message_mem_needed(V_ERROR, lzma_memusage(&strm)); goto error; } } error: lzma_end(&strm); return true; } /// \brief Parse the Block Header /// /// The result is stored into *bhi. The caller takes care of initializing it. /// /// \return False on success, true on error. static bool parse_block_header(file_pair *pair, const lzma_index_iter *iter, block_header_info *bhi, xz_file_info *xfi) { #if IO_BUFFER_SIZE < LZMA_BLOCK_HEADER_SIZE_MAX # error IO_BUFFER_SIZE < LZMA_BLOCK_HEADER_SIZE_MAX #endif // Get the whole Block Header with one read, but don't read past // the end of the Block (or even its Check field). const uint32_t size = my_min(iter->block.total_size - lzma_check_size(iter->stream.flags->check), LZMA_BLOCK_HEADER_SIZE_MAX); io_buf buf; if (io_pread(pair, &buf, size, iter->block.compressed_file_offset)) return true; // Zero would mean Index Indicator and thus not a valid Block. if (buf.u8[0] == 0) goto data_error; // Initialize the block structure and decode Block Header Size. lzma_filter filters[LZMA_FILTERS_MAX + 1]; lzma_block block; block.version = 0; block.check = iter->stream.flags->check; block.filters = filters; block.header_size = lzma_block_header_size_decode(buf.u8[0]); if (block.header_size > size) goto data_error; // Decode the Block Header. switch (lzma_block_header_decode(&block, NULL, buf.u8)) { case LZMA_OK: break; case LZMA_OPTIONS_ERROR: message_error("%s: %s", pair->src_name, message_strm(LZMA_OPTIONS_ERROR)); return true; case LZMA_DATA_ERROR: goto data_error; default: message_bug(); } // Check the Block Flags. These must be done before calling // lzma_block_compressed_size(), because it overwrites // block.compressed_size. // // NOTE: If you add new characters here, update the minimum number of // columns in headings[HEADING_HEADERFLAGS] to match the number of // characters used here. bhi->flags[0] = block.compressed_size != LZMA_VLI_UNKNOWN ? 'c' : '-'; bhi->flags[1] = block.uncompressed_size != LZMA_VLI_UNKNOWN ? 'u' : '-'; bhi->flags[2] = '\0'; // Collect information if all Blocks have both Compressed Size // and Uncompressed Size fields. They can be useful e.g. for // multi-threaded decompression so it can be useful to know it. xfi->all_have_sizes &= block.compressed_size != LZMA_VLI_UNKNOWN && block.uncompressed_size != LZMA_VLI_UNKNOWN; // Validate or set block.compressed_size. switch (lzma_block_compressed_size(&block, iter->block.unpadded_size)) { case LZMA_OK: // Validate also block.uncompressed_size if it is present. // If it isn't present, there's no need to set it since // we aren't going to actually decompress the Block; if // we were decompressing, then we should set it so that // the Block decoder could validate the Uncompressed Size // that was stored in the Index. if (block.uncompressed_size == LZMA_VLI_UNKNOWN || block.uncompressed_size == iter->block.uncompressed_size) break; // If the above fails, the file is corrupt so // LZMA_DATA_ERROR is a good error code. // Fall through case LZMA_DATA_ERROR: // Free the memory allocated by lzma_block_header_decode(). for (size_t i = 0; filters[i].id != LZMA_VLI_UNKNOWN; ++i) free(filters[i].options); goto data_error; default: message_bug(); } // Copy the known sizes. bhi->header_size = block.header_size; bhi->compressed_size = block.compressed_size; // Calculate the decoder memory usage and update the maximum // memory usage of this Block. bhi->memusage = lzma_raw_decoder_memusage(filters); if (xfi->memusage_max < bhi->memusage) xfi->memusage_max = bhi->memusage; // Determine the minimum XZ Utils version that supports this Block. // // Currently the only thing that 5.0.0 doesn't support is empty // LZMA2 Block. This decoder bug was fixed in 5.0.2. { size_t i = 0; while (filters[i + 1].id != LZMA_VLI_UNKNOWN) ++i; if (filters[i].id == LZMA_FILTER_LZMA2 && iter->block.uncompressed_size == 0 && xfi->min_version < 50000022U) xfi->min_version = 50000022U; } // Convert the filter chain to human readable form. message_filters_to_str(bhi->filter_chain, filters, false); // Free the memory allocated by lzma_block_header_decode(). for (size_t i = 0; filters[i].id != LZMA_VLI_UNKNOWN; ++i) free(filters[i].options); return false; data_error: // Show the error message. message_error("%s: %s", pair->src_name, message_strm(LZMA_DATA_ERROR)); return true; } /// \brief Parse the Check field and put it into check_value[] /// /// \return False on success, true on error. static bool parse_check_value(file_pair *pair, const lzma_index_iter *iter) { // Don't read anything from the file if there is no integrity Check. if (iter->stream.flags->check == LZMA_CHECK_NONE) { snprintf(check_value, sizeof(check_value), "---"); return false; } // Locate and read the Check field. const uint32_t size = lzma_check_size(iter->stream.flags->check); const uint64_t offset = iter->block.compressed_file_offset + iter->block.total_size - size; io_buf buf; if (io_pread(pair, &buf, size, offset)) return true; // CRC32 and CRC64 are in little endian. Guess that all the future // 32-bit and 64-bit Check values are little endian too. It shouldn't // be a too big problem if this guess is wrong. if (size == 4) snprintf(check_value, sizeof(check_value), "%08" PRIx32, conv32le(buf.u32[0])); else if (size == 8) snprintf(check_value, sizeof(check_value), "%016" PRIx64, conv64le(buf.u64[0])); else for (size_t i = 0; i < size; ++i) snprintf(check_value + i * 2, 3, "%02x", buf.u8[i]); return false; } /// \brief Parse detailed information about a Block /// /// Since this requires seek(s), listing information about all Blocks can /// be slow. /// /// \param pair Input file /// \param iter Location of the Block whose Check value should /// be printed. /// \param bhi Pointer to structure where to store the information /// about the Block Header field. /// /// \return False on success, true on error. If an error occurs, /// the error message is printed too so the caller doesn't /// need to worry about that. static bool parse_details(file_pair *pair, const lzma_index_iter *iter, block_header_info *bhi, xz_file_info *xfi) { if (parse_block_header(pair, iter, bhi, xfi)) return true; if (parse_check_value(pair, iter)) return true; return false; } /// \brief Get the compression ratio /// /// This has slightly different format than that is used in message.c. static const char * get_ratio(uint64_t compressed_size, uint64_t uncompressed_size) { if (uncompressed_size == 0) return "---"; const double ratio = (double)(compressed_size) / (double)(uncompressed_size); if (ratio > 9.999) return "---"; static char buf[16]; snprintf(buf, sizeof(buf), "%.3f", ratio); return buf; } /// \brief Get a comma-separated list of Check names /// /// The check names are translated with gettext except when in robot mode. /// /// \param buf Buffer to hold the resulting string /// \param checks Bit mask of Checks to print /// \param space_after_comma /// It's better to not use spaces in table-like listings, /// but in more verbose formats a space after a comma /// is good for readability. static void get_check_names(char buf[CHECKS_STR_SIZE], uint32_t checks, bool space_after_comma) { // If we get called when there are no Checks to print, set checks // to 1 so that we print "None". This can happen in the robot mode // when printing the totals line if there are no valid input files. if (checks == 0) checks = 1; char *pos = buf; size_t left = CHECKS_STR_SIZE; const char *sep = space_after_comma ? ", " : ","; bool comma = false; for (size_t i = 0; i <= LZMA_CHECK_ID_MAX; ++i) { if (checks & (UINT32_C(1) << i)) { my_snprintf(&pos, &left, "%s%s", comma ? sep : "", opt_robot ? check_names[i] : _(check_names[i])); comma = true; } } return; } static bool print_info_basic(const xz_file_info *xfi, file_pair *pair) { static bool headings_displayed = false; if (!headings_displayed) { headings_displayed = true; // TRANSLATORS: These are column headings. From Strms (Streams) // to Ratio, the columns are right aligned. Check and Filename // are left aligned. If you need longer words, it's OK to // use two lines here. Test with "xz -l foo.xz". puts(_("Strms Blocks Compressed Uncompressed Ratio " "Check Filename")); } char checks[CHECKS_STR_SIZE]; get_check_names(checks, lzma_index_checks(xfi->idx), false); const char *cols[7] = { uint64_to_str(lzma_index_stream_count(xfi->idx), 0), uint64_to_str(lzma_index_block_count(xfi->idx), 1), uint64_to_nicestr(lzma_index_file_size(xfi->idx), NICESTR_B, NICESTR_TIB, false, 2), uint64_to_nicestr(lzma_index_uncompressed_size(xfi->idx), NICESTR_B, NICESTR_TIB, false, 3), get_ratio(lzma_index_file_size(xfi->idx), lzma_index_uncompressed_size(xfi->idx)), checks, pair->src_name, }; printf("%*s %*s %*s %*s %*s %-*s %s\n", tuklib_mbstr_fw(cols[0], 5), cols[0], tuklib_mbstr_fw(cols[1], 7), cols[1], tuklib_mbstr_fw(cols[2], 11), cols[2], tuklib_mbstr_fw(cols[3], 11), cols[3], tuklib_mbstr_fw(cols[4], 5), cols[4], tuklib_mbstr_fw(cols[5], 7), cols[5], cols[6]); return false; } static void print_adv_helper(uint64_t stream_count, uint64_t block_count, uint64_t compressed_size, uint64_t uncompressed_size, uint32_t checks, uint64_t stream_padding) { char checks_str[CHECKS_STR_SIZE]; get_check_names(checks_str, checks, true); printf(" %-*s %s\n", COLON_STR(COLON_STR_STREAMS), uint64_to_str(stream_count, 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_BLOCKS), uint64_to_str(block_count, 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_COMPRESSED_SIZE), uint64_to_nicestr(compressed_size, NICESTR_B, NICESTR_TIB, true, 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_UNCOMPRESSED_SIZE), uint64_to_nicestr(uncompressed_size, NICESTR_B, NICESTR_TIB, true, 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_RATIO), get_ratio(compressed_size, uncompressed_size)); printf(" %-*s %s\n", COLON_STR(COLON_STR_CHECK), checks_str); printf(" %-*s %s\n", COLON_STR(COLON_STR_STREAM_PADDING), uint64_to_nicestr(stream_padding, NICESTR_B, NICESTR_TIB, true, 0)); return; } static bool print_info_adv(xz_file_info *xfi, file_pair *pair) { // Print the overall information. print_adv_helper(lzma_index_stream_count(xfi->idx), lzma_index_block_count(xfi->idx), lzma_index_file_size(xfi->idx), lzma_index_uncompressed_size(xfi->idx), lzma_index_checks(xfi->idx), xfi->stream_padding); // Size of the biggest Check. This is used to calculate the width // of the CheckVal field. The table would get insanely wide if // we always reserved space for 64-byte Check (128 chars as hex). uint32_t check_max = 0; // Print information about the Streams. // // All except Check are right aligned; Check is left aligned. // Test with "xz -lv foo.xz". printf(" %s\n %*s %*s %*s %*s %*s %*s %*s %-*s %*s\n", _(colon_strs[COLON_STR_STREAMS]), HEADING_STR(HEADING_STREAM), HEADING_STR(HEADING_BLOCKS), HEADING_STR(HEADING_COMPOFFSET), HEADING_STR(HEADING_UNCOMPOFFSET), HEADING_STR(HEADING_COMPSIZE), HEADING_STR(HEADING_UNCOMPSIZE), HEADING_STR(HEADING_RATIO), HEADING_STR(HEADING_CHECK), HEADING_STR(HEADING_PADDING)); lzma_index_iter iter; lzma_index_iter_init(&iter, xfi->idx); while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)) { const char *cols1[4] = { uint64_to_str(iter.stream.number, 0), uint64_to_str(iter.stream.block_count, 1), uint64_to_str(iter.stream.compressed_offset, 2), uint64_to_str(iter.stream.uncompressed_offset, 3), }; printf(" %*s %*s %*s %*s ", tuklib_mbstr_fw(cols1[0], headings[HEADING_STREAM].columns), cols1[0], tuklib_mbstr_fw(cols1[1], headings[HEADING_BLOCKS].columns), cols1[1], tuklib_mbstr_fw(cols1[2], headings[HEADING_COMPOFFSET].columns), cols1[2], tuklib_mbstr_fw(cols1[3], headings[HEADING_UNCOMPOFFSET].columns), cols1[3]); const char *cols2[5] = { uint64_to_str(iter.stream.compressed_size, 0), uint64_to_str(iter.stream.uncompressed_size, 1), get_ratio(iter.stream.compressed_size, iter.stream.uncompressed_size), _(check_names[iter.stream.flags->check]), uint64_to_str(iter.stream.padding, 2), }; printf("%*s %*s %*s %-*s %*s\n", tuklib_mbstr_fw(cols2[0], headings[HEADING_COMPSIZE].columns), cols2[0], tuklib_mbstr_fw(cols2[1], headings[HEADING_UNCOMPSIZE].columns), cols2[1], tuklib_mbstr_fw(cols2[2], headings[HEADING_RATIO].columns), cols2[2], tuklib_mbstr_fw(cols2[3], headings[HEADING_CHECK].columns), cols2[3], tuklib_mbstr_fw(cols2[4], headings[HEADING_PADDING].columns), cols2[4]); // Update the maximum Check size. if (lzma_check_size(iter.stream.flags->check) > check_max) check_max = lzma_check_size(iter.stream.flags->check); } // Cache the verbosity level to a local variable. const bool detailed = message_verbosity_get() >= V_DEBUG; // Information collected from Block Headers block_header_info bhi; // Print information about the Blocks but only if there is // at least one Block. if (lzma_index_block_count(xfi->idx) > 0) { // Calculate the width of the CheckVal column. This can be // used as is as the field width for printf() when printing // the actual check value as it is hexadecimal. However, to // print the column heading, further calculation is needed // to handle a translated string (it's done a few lines later). assert(check_max <= LZMA_CHECK_SIZE_MAX); const int checkval_width = my_max( headings[HEADING_CHECKVAL].columns, (int)(2 * check_max)); // All except Check are right aligned; Check is left aligned. printf(" %s\n %*s %*s %*s %*s %*s %*s %*s %-*s", _(colon_strs[COLON_STR_BLOCKS]), HEADING_STR(HEADING_STREAM), HEADING_STR(HEADING_BLOCK), HEADING_STR(HEADING_COMPOFFSET), HEADING_STR(HEADING_UNCOMPOFFSET), HEADING_STR(HEADING_TOTALSIZE), HEADING_STR(HEADING_UNCOMPSIZE), HEADING_STR(HEADING_RATIO), detailed ? headings[HEADING_CHECK].fw : 1, _(headings[HEADING_CHECK].str)); if (detailed) { // CheckVal (Check value), Flags, and Filters are // left aligned. Block Header Size, CompSize, and // MemUsage are right aligned. Test with // "xz -lvv foo.xz". printf(" %-*s %*s %-*s %*s %*s %s", headings[HEADING_CHECKVAL].fw + checkval_width - headings[HEADING_CHECKVAL].columns, _(headings[HEADING_CHECKVAL].str), HEADING_STR(HEADING_HEADERSIZE), HEADING_STR(HEADING_HEADERFLAGS), HEADING_STR(HEADING_COMPSIZE), HEADING_STR(HEADING_MEMUSAGE), _(headings[HEADING_FILTERS].str)); } putchar('\n'); lzma_index_iter_init(&iter, xfi->idx); // Iterate over the Blocks. while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)) { if (detailed && parse_details(pair, &iter, &bhi, xfi)) return true; const char *cols1[4] = { uint64_to_str(iter.stream.number, 0), uint64_to_str( iter.block.number_in_stream, 1), uint64_to_str( iter.block.compressed_file_offset, 2), uint64_to_str( iter.block.uncompressed_file_offset, 3) }; printf(" %*s %*s %*s %*s ", tuklib_mbstr_fw(cols1[0], headings[HEADING_STREAM].columns), cols1[0], tuklib_mbstr_fw(cols1[1], headings[HEADING_BLOCK].columns), cols1[1], tuklib_mbstr_fw(cols1[2], headings[HEADING_COMPOFFSET].columns), cols1[2], tuklib_mbstr_fw(cols1[3], headings[ HEADING_UNCOMPOFFSET].columns), cols1[3]); const char *cols2[4] = { uint64_to_str(iter.block.total_size, 0), uint64_to_str(iter.block.uncompressed_size, 1), get_ratio(iter.block.total_size, iter.block.uncompressed_size), _(check_names[iter.stream.flags->check]) }; printf("%*s %*s %*s %-*s", tuklib_mbstr_fw(cols2[0], headings[HEADING_TOTALSIZE].columns), cols2[0], tuklib_mbstr_fw(cols2[1], headings[HEADING_UNCOMPSIZE].columns), cols2[1], tuklib_mbstr_fw(cols2[2], headings[HEADING_RATIO].columns), cols2[2], tuklib_mbstr_fw(cols2[3], detailed ? headings[HEADING_CHECK].columns : 1), cols2[3]); if (detailed) { const lzma_vli compressed_size = iter.block.unpadded_size - bhi.header_size - lzma_check_size( iter.stream.flags->check); const char *cols3[6] = { check_value, uint64_to_str(bhi.header_size, 0), bhi.flags, uint64_to_str(compressed_size, 1), uint64_to_str( round_up_to_mib(bhi.memusage), 2), bhi.filter_chain }; // Show MiB for memory usage, because it // is the only size which is not in bytes. printf(" %-*s %*s %-*s %*s %*s MiB %s", checkval_width, cols3[0], tuklib_mbstr_fw(cols3[1], headings[ HEADING_HEADERSIZE].columns), cols3[1], tuklib_mbstr_fw(cols3[2], headings[ HEADING_HEADERFLAGS].columns), cols3[2], tuklib_mbstr_fw(cols3[3], headings[ HEADING_COMPSIZE].columns), cols3[3], tuklib_mbstr_fw(cols3[4], headings[ HEADING_MEMUSAGE].columns - 4), cols3[4], cols3[5]); } putchar('\n'); } } if (detailed) { printf(" %-*s %s MiB\n", COLON_STR(COLON_STR_MEMORY_NEEDED), uint64_to_str( round_up_to_mib(xfi->memusage_max), 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_SIZES_IN_HEADERS), xfi->all_have_sizes ? _("Yes") : _("No")); //printf(" %-*s %s\n", COLON_STR(COLON_STR_MINIMUM_XZ_VERSION), printf(_(" Minimum XZ Utils version: %s\n"), xz_ver_to_str(xfi->min_version)); } return false; } static bool print_info_robot(xz_file_info *xfi, file_pair *pair) { char checks[CHECKS_STR_SIZE]; get_check_names(checks, lzma_index_checks(xfi->idx), false); printf("name\t%s\n", pair->src_name); printf("file\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%s\t%s\t%" PRIu64 "\n", lzma_index_stream_count(xfi->idx), lzma_index_block_count(xfi->idx), lzma_index_file_size(xfi->idx), lzma_index_uncompressed_size(xfi->idx), get_ratio(lzma_index_file_size(xfi->idx), lzma_index_uncompressed_size(xfi->idx)), checks, xfi->stream_padding); if (message_verbosity_get() >= V_VERBOSE) { lzma_index_iter iter; lzma_index_iter_init(&iter, xfi->idx); while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_STREAM)) printf("stream\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%s\t%s\t%" PRIu64 "\n", iter.stream.number, iter.stream.block_count, iter.stream.compressed_offset, iter.stream.uncompressed_offset, iter.stream.compressed_size, iter.stream.uncompressed_size, get_ratio(iter.stream.compressed_size, iter.stream.uncompressed_size), check_names[iter.stream.flags->check], iter.stream.padding); lzma_index_iter_rewind(&iter); block_header_info bhi; while (!lzma_index_iter_next(&iter, LZMA_INDEX_ITER_BLOCK)) { if (message_verbosity_get() >= V_DEBUG && parse_details( pair, &iter, &bhi, xfi)) return true; printf("block\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%s\t%s", iter.stream.number, iter.block.number_in_stream, iter.block.number_in_file, iter.block.compressed_file_offset, iter.block.uncompressed_file_offset, iter.block.total_size, iter.block.uncompressed_size, get_ratio(iter.block.total_size, iter.block.uncompressed_size), check_names[iter.stream.flags->check]); if (message_verbosity_get() >= V_DEBUG) printf("\t%s\t%" PRIu32 "\t%s\t%" PRIu64 "\t%" PRIu64 "\t%s", check_value, bhi.header_size, bhi.flags, bhi.compressed_size, bhi.memusage, bhi.filter_chain); putchar('\n'); } } if (message_verbosity_get() >= V_DEBUG) printf("summary\t%" PRIu64 "\t%s\t%" PRIu32 "\n", xfi->memusage_max, xfi->all_have_sizes ? "yes" : "no", xfi->min_version); return false; } static void update_totals(const xz_file_info *xfi) { // TODO: Integer overflow checks ++totals.files; totals.streams += lzma_index_stream_count(xfi->idx); totals.blocks += lzma_index_block_count(xfi->idx); totals.compressed_size += lzma_index_file_size(xfi->idx); totals.uncompressed_size += lzma_index_uncompressed_size(xfi->idx); totals.stream_padding += xfi->stream_padding; totals.checks |= lzma_index_checks(xfi->idx); if (totals.memusage_max < xfi->memusage_max) totals.memusage_max = xfi->memusage_max; if (totals.min_version < xfi->min_version) totals.min_version = xfi->min_version; totals.all_have_sizes &= xfi->all_have_sizes; return; } static void print_totals_basic(void) { // Print a separator line. char line[80]; memset(line, '-', sizeof(line)); line[sizeof(line) - 1] = '\0'; puts(line); // Get the check names. char checks[CHECKS_STR_SIZE]; get_check_names(checks, totals.checks, false); // Print the totals except the file count, which needs // special handling. printf("%5s %7s %11s %11s %5s %-7s ", uint64_to_str(totals.streams, 0), uint64_to_str(totals.blocks, 1), uint64_to_nicestr(totals.compressed_size, NICESTR_B, NICESTR_TIB, false, 2), uint64_to_nicestr(totals.uncompressed_size, NICESTR_B, NICESTR_TIB, false, 3), get_ratio(totals.compressed_size, totals.uncompressed_size), checks); // Since we print totals only when there are at least two files, // the English message will always use "%s files". But some other // languages need different forms for different plurals so we // have to translate this with ngettext(). // // TRANSLATORS: %s is an integer. Only the plural form of this // message is used (e.g. "2 files"). Test with "xz -l foo.xz bar.xz". printf(ngettext("%s file\n", "%s files\n", totals.files <= ULONG_MAX ? totals.files : (totals.files % 1000000) + 1000000), uint64_to_str(totals.files, 0)); return; } static void print_totals_adv(void) { putchar('\n'); puts(_("Totals:")); printf(" %-*s %s\n", COLON_STR(COLON_STR_NUMBER_OF_FILES), uint64_to_str(totals.files, 0)); print_adv_helper(totals.streams, totals.blocks, totals.compressed_size, totals.uncompressed_size, totals.checks, totals.stream_padding); if (message_verbosity_get() >= V_DEBUG) { printf(" %-*s %s MiB\n", COLON_STR(COLON_STR_MEMORY_NEEDED), uint64_to_str( round_up_to_mib(totals.memusage_max), 0)); printf(" %-*s %s\n", COLON_STR(COLON_STR_SIZES_IN_HEADERS), totals.all_have_sizes ? _("Yes") : _("No")); //printf(" %-*s %s\n", COLON_STR(COLON_STR_MINIMUM_XZ_VERSION), printf(_(" Minimum XZ Utils version: %s\n"), xz_ver_to_str(totals.min_version)); } return; } static void print_totals_robot(void) { char checks[CHECKS_STR_SIZE]; get_check_names(checks, totals.checks, false); printf("totals\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%" PRIu64 "\t%s\t%s\t%" PRIu64 "\t%" PRIu64, totals.streams, totals.blocks, totals.compressed_size, totals.uncompressed_size, get_ratio(totals.compressed_size, totals.uncompressed_size), checks, totals.stream_padding, totals.files); if (message_verbosity_get() >= V_DEBUG) printf("\t%" PRIu64 "\t%s\t%" PRIu32, totals.memusage_max, totals.all_have_sizes ? "yes" : "no", totals.min_version); putchar('\n'); return; } extern void list_totals(void) { if (opt_robot) { // Always print totals in --robot mode. It can be convenient // in some cases and doesn't complicate usage of the // single-file case much. print_totals_robot(); } else if (totals.files > 1) { // For non-robot mode, totals are printed only if there // is more than one file. if (message_verbosity_get() <= V_WARNING) print_totals_basic(); else print_totals_adv(); } return; } extern void list_file(const char *filename) { if (opt_format != FORMAT_XZ && opt_format != FORMAT_AUTO) message_fatal(_("--list works only on .xz files " "(--format=xz or --format=auto)")); message_filename(filename); if (filename == stdin_filename) { message_error(_("--list does not support reading from " "standard input")); return; } init_field_widths(); // Unset opt_stdout so that io_open_src() won't accept special files. // Set opt_force so that io_open_src() will follow symlinks. opt_stdout = false; opt_force = true; file_pair *pair = io_open_src(filename); if (pair == NULL) return; xz_file_info xfi = XZ_FILE_INFO_INIT; if (!parse_indexes(&xfi, pair)) { bool fail; // We have three main modes: // - --robot, which has submodes if --verbose is specified // once or twice // - Normal --list without --verbose // - --list with one or two --verbose if (opt_robot) fail = print_info_robot(&xfi, pair); else if (message_verbosity_get() <= V_WARNING) fail = print_info_basic(&xfi, pair); else fail = print_info_adv(&xfi, pair); // Update the totals that are displayed after all // the individual files have been listed. Don't count // broken files. if (!fail) update_totals(&xfi); lzma_index_end(xfi.idx, NULL); } io_close(pair, false); return; }