This is clzip.info, produced by makeinfo version 4.13+ from clzip.texi. INFO-DIR-SECTION Data Compression START-INFO-DIR-ENTRY * Clzip: (clzip). LZMA lossless data compressor END-INFO-DIR-ENTRY  File: clzip.info, Node: Top, Next: Introduction, Up: (dir) Clzip Manual ************ This manual is for Clzip (version 1.6-pre2, 6 May 2014). * Menu: * Introduction:: Purpose and features of clzip * Algorithm:: How clzip compresses the data * Invoking clzip:: Command line interface * File format:: Detailed format of the compressed file * Examples:: A small tutorial with examples * Problems:: Reporting bugs * Concept index:: Index of concepts Copyright (C) 2010, 2011, 2012, 2013, 2014 Antonio Diaz Diaz. This manual is free documentation: you have unlimited permission to copy, distribute and modify it.  File: clzip.info, Node: Introduction, Next: Algorithm, Prev: Top, Up: Top 1 Introduction ************** Clzip is a lossless data compressor with a user interface similar to the one of gzip or bzip2. Clzip decompresses almost as fast as gzip, compresses most files more than bzip2, and is better than both from a data recovery perspective. Clzip is a clean implementation of the LZMA (Lempel-Ziv-Markov chain-Algorithm) algorithm. Clzip uses the lzip file format; the files produced by clzip are fully compatible with lzip-1.4 or newer, and can be rescued with lziprecover. Clzip is in fact a C language version of lzip, intended for embedded devices or systems lacking a C++ compiler. The lzip file format is designed for long-term data archiving, taking into account both data integrity and decoder availability: * The lzip format provides very safe integrity checking and some data recovery means. The lziprecover program can repair bit-flip errors (one of the most common forms of data corruption) in lzip files, and provides data recovery capabilities, including error-checked merging of damaged copies of a file. * The lzip format is as simple as possible (but not simpler). The lzip manual provides the code of a simple decompressor along with a detailed explanation of how it works, so that with the only help of the lzip manual it would be possible for a digital archaeologist to extract the data from a lzip file long after quantum computers eventually render LZMA obsolete. * Additionally lzip is copylefted, which guarantees that it will remain free forever. The member trailer stores the 32-bit CRC of the original data, the size of the original data and the size of the member. These values, together with the value remaining in the range decoder and the end-of-stream marker, provide a 4 factor integrity checking which guarantees that the decompressed version of the data is identical to the original. This guards against corruption of the compressed data, and against undetected bugs in clzip (hopefully very unlikely). The chances of data corruption going undetected are microscopic. Be aware, though, that the check occurs upon decompression, so it can only tell you that something is wrong. It can't help you recover the original uncompressed data. Clzip uses the same well-defined exit status values used by lzip and bzip2, which makes it safer than compressors returning ambiguous warning values (like gzip) when it is used as a back end for tar or zutils. The amount of memory required for compression is about 1 or 2 times the dictionary size limit (1 if input file size is less than dictionary size limit, else 2) plus 9 times the dictionary size really used. The amount of memory required for decompression is about 46 kB larger than the dictionary size really used. Clzip will automatically use the smallest possible dictionary size for each file without exceeding the given limit. Keep in mind that the decompression memory requirement is affected at compression time by the choice of dictionary size limit. When compressing, clzip replaces every file given in the command line with a compressed version of itself, with the name "original_name.lz". When decompressing, clzip attempts to guess the name for the decompressed file from that of the compressed file as follows: filename.lz becomes filename filename.tlz becomes filename.tar anyothername becomes anyothername.out (De)compressing a file is much like copying or moving it; therefore clzip preserves the access and modification dates, permissions, and, when possible, ownership of the file just as "cp -p" does. (If the user ID or the group ID can't be duplicated, the file permission bits S_ISUID and S_ISGID are cleared). Clzip is able to read from some types of non regular files if the '--stdout' option is specified. If no file names are specified, clzip compresses (or decompresses) from standard input to standard output. In this case, clzip will decline to write compressed output to a terminal, as this would be entirely incomprehensible and therefore pointless. Clzip will correctly decompress a file which is the concatenation of two or more compressed files. The result is the concatenation of the corresponding uncompressed files. Integrity testing of concatenated compressed files is also supported. Clzip can produce multi-member files and safely recover, with lziprecover, the undamaged members in case of file damage. Clzip can also split the compressed output in volumes of a given size, even when reading from standard input. This allows the direct creation of multivolume compressed tar archives. Clzip is able to compress and decompress streams of unlimited size by automatically creating multi-member output. The members so created are large, about 64 PiB each.  File: clzip.info, Node: Algorithm, Next: Invoking clzip, Prev: Introduction, Up: Top 2 Algorithm *********** There is no such thing as a "LZMA algorithm"; it is more like a "LZMA coding scheme". For example, the option '-0' of lzip uses the scheme in almost the simplest way possible; issuing the longest match it can find, or a literal byte if it can't find a match. Inversely, a much more elaborated way of finding coding sequences of minimum price than the one currently used by lzip could be developed, and the resulting sequence could also be coded using the LZMA coding scheme. Lzip currently implements two variants of the LZMA algorithm; fast (used by option -0) and normal (used by all other compression levels). Clzip just implements the "normal" variant. The high compression of LZMA comes from combining two basic, well-proven compression ideas: sliding dictionaries (LZ77/78) and markov models (the thing used by every compression algorithm that uses a range encoder or similar order-0 entropy coder as its last stage) with segregation of contexts according to what the bits are used for. Clzip is a two stage compressor. The first stage is a Lempel-Ziv coder, which reduces redundancy by translating chunks of data to their corresponding distance-length pairs. The second stage is a range encoder that uses a different probability model for each type of data; distances, lengths, literal bytes, etc. Here is how it works, step by step: 1) The member header is written to the output stream. 2) The first byte is coded literally, because there are no previous bytes to which the match finder can refer to. 3) The main encoder advances to the next byte in the input data and calls the match finder. 4) The match finder fills an array with the minimum distances before the current byte where a match of a given length can be found. 5) Go back to step 3 until a sequence (formed of pairs, repeated distances and literal bytes) of minimum price has been formed. Where the price represents the number of output bits produced. 6) The range encoder encodes the sequence produced by the main encoder and sends the produced bytes to the output stream. 7) Go back to step 3 until the input data are finished or until the member or volume size limits are reached. 8) The range encoder is flushed. 9) The member trailer is written to the output stream. 10) If there are more data to compress, go back to step 1. The ideas embodied in clzip are due to (at least) the following people: Abraham Lempel and Jacob Ziv (for the LZ algorithm), Andrey Markov (for the definition of Markov chains), G.N.N. Martin (for the definition of range encoding), Igor Pavlov (for putting all the above together in LZMA), and Julian Seward (for bzip2's CLI).  File: clzip.info, Node: Invoking clzip, Next: File format, Prev: Algorithm, Up: Top 3 Invoking clzip **************** The format for running clzip is: clzip [OPTIONS] [FILES] Clzip supports the following options: '-h' '--help' Print an informative help message describing the options and exit. '-V' '--version' Print the version number of clzip on the standard output and exit. '-b BYTES' '--member-size=BYTES' Set the member size limit to BYTES. A small member size may degrade compression ratio, so use it only when needed. Valid values range from 100 kB to 64 PiB. Defaults to 64 PiB. '-c' '--stdout' Compress or decompress to standard output. Needed when reading from a named pipe (fifo) or from a device. Use it to recover as much of the uncompressed data as possible when decompressing a corrupt file. '-d' '--decompress' Decompress. '-f' '--force' Force overwrite of output files. '-F' '--recompress' Force recompression of files whose name already has the '.lz' or '.tlz' suffix. '-k' '--keep' Keep (don't delete) input files during compression or decompression. '-m BYTES' '--match-length=BYTES' Set the match length limit in bytes. After a match this long is found, the search is finished. Valid values range from 5 to 273. Larger values usually give better compression ratios but longer compression times. '-o FILE' '--output=FILE' When reading from standard input and '--stdout' has not been specified, use 'FILE' as the virtual name of the uncompressed file. This produces a file named 'FILE' when decompressing, a file named 'FILE.lz' when compressing, and several files named 'FILE00001.lz', 'FILE00002.lz', etc, when compressing and splitting the output in volumes. '-q' '--quiet' Quiet operation. Suppress all messages. '-s BYTES' '--dictionary-size=BYTES' Set the dictionary size limit in bytes. Valid values range from 4 KiB to 512 MiB. Clzip will use the smallest possible dictionary size for each file without exceeding this limit. Note that dictionary sizes are quantized. If the specified size does not match one of the valid sizes, it will be rounded upwards by adding up to (BYTES / 16) to it. For maximum compression you should use a dictionary size limit as large as possible, but keep in mind that the decompression memory requirement is affected at compression time by the choice of dictionary size limit. '-S BYTES' '--volume-size=BYTES' Split the compressed output into several volume files with names 'original_name00001.lz', 'original_name00002.lz', etc, and set the volume size limit to BYTES. Each volume is a complete, maybe multi-member, lzip file. A small volume size may degrade compression ratio, so use it only when needed. Valid values range from 100 kB to 4 EiB. '-t' '--test' Check integrity of the specified file(s), but don't decompress them. This really performs a trial decompression and throws away the result. Use it together with '-v' to see information about the file. '-v' '--verbose' Verbose mode. When compressing, show the compression ratio for each file processed. A second '-v' shows the progress of compression. When decompressing or testing, further -v's (up to 4) increase the verbosity level, showing status, compression ratio, dictionary size, and trailer contents (CRC, data size, member size). '-1 .. -9' Set the compression parameters (dictionary size and match length limit) as shown in the table below. Note that '-9' can be much slower than '-1'. These options have no effect when decompressing. The bidimensional parameter space of LZMA can't be mapped to a linear scale optimal for all files. If your files are large, very repetitive, etc, you may need to use the '--match-length' and '--dictionary-size' options directly to achieve optimal performance. For example, '-9m64' usually compresses executables more (and faster) than '-9'. Level Dictionary size Match length limit -1 1 MiB 5 bytes -2 1.5 MiB 6 bytes -3 2 MiB 8 bytes -4 3 MiB 12 bytes -5 4 MiB 20 bytes -6 8 MiB 36 bytes -7 16 MiB 68 bytes -8 24 MiB 132 bytes -9 32 MiB 273 bytes '--fast' '--best' Aliases for GNU gzip compatibility. Numbers given as arguments to options may be followed by a multiplier and an optional 'B' for "byte". Table of SI and binary prefixes (unit multipliers): Prefix Value | Prefix Value k kilobyte (10^3 = 1000) | Ki kibibyte (2^10 = 1024) M megabyte (10^6) | Mi mebibyte (2^20) G gigabyte (10^9) | Gi gibibyte (2^30) T terabyte (10^12) | Ti tebibyte (2^40) P petabyte (10^15) | Pi pebibyte (2^50) E exabyte (10^18) | Ei exbibyte (2^60) Z zettabyte (10^21) | Zi zebibyte (2^70) Y yottabyte (10^24) | Yi yobibyte (2^80) Exit status: 0 for a normal exit, 1 for environmental problems (file not found, invalid flags, I/O errors, etc), 2 to indicate a corrupt or invalid input file, 3 for an internal consistency error (eg, bug) which caused clzip to panic.  File: clzip.info, Node: File format, Next: Examples, Prev: Invoking clzip, Up: Top 4 File format ************* Perfection is reached, not when there is no longer anything to add, but when there is no longer anything to take away. -- Antoine de Saint-Exupery In the diagram below, a box like this: +---+ | | <-- the vertical bars might be missing +---+ represents one byte; a box like this: +==============+ | | +==============+ represents a variable number of bytes. A lzip file consists of a series of "members" (compressed data sets). The members simply appear one after another in the file, with no additional information before, between, or after them. Each member has the following structure: +--+--+--+--+----+----+=============+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | ID string | VN | DS | Lzma stream | CRC32 | Data size | Member size | +--+--+--+--+----+----+=============+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ All multibyte values are stored in little endian order. 'ID string' A four byte string, identifying the lzip format, with the value "LZIP" (0x4C, 0x5A, 0x49, 0x50). 'VN (version number, 1 byte)' Just in case something needs to be modified in the future. 1 for now. 'DS (coded dictionary size, 1 byte)' Lzip divides the distance between any two powers of 2 into 8 equally spaced intervals, named "wedges". The dictionary size is calculated by taking a power of 2 (the base size) and substracting from it a number of wedges between 0 and 7. The size of a wedge is (base_size / 16). Bits 4-0 contain the base 2 logarithm of the base size (12 to 29). Bits 7-5 contain the number of wedges (0 to 7) to substract from the base size to obtain the dictionary size. Example: 0xD3 = 2^19 - 6 * 2^15 = 512 KiB - 6 * 32 KiB = 320 KiB Valid values for dictionary size range from 4 KiB to 512 MiB. 'Lzma stream' The lzma stream, finished by an end of stream marker. Uses default values for encoder properties. See the lzip manual for a full description. 'CRC32 (4 bytes)' CRC of the uncompressed original data. 'Data size (8 bytes)' Size of the uncompressed original data. 'Member size (8 bytes)' Total size of the member, including header and trailer. This field acts as a distributed index, allows the verification of stream integrity, and facilitates safe recovery of undamaged members from multi-member files.  File: clzip.info, Node: Examples, Next: Problems, Prev: File format, Up: Top 5 A small tutorial with examples ******************************** WARNING! Even if clzip is bug-free, other causes may result in a corrupt compressed file (bugs in the system libraries, memory errors, etc). Therefore, if the data you are going to compress are important, give the '--keep' option to clzip and do not remove the original file until you verify the compressed file with a command like 'clzip -cd file.lz | cmp file -'. Example 1: Replace a regular file with its compressed version 'file.lz' and show the compression ratio. clzip -v file Example 2: Like example 1 but the created 'file.lz' is multi-member with a member size of 1 MiB. The compression ratio is not shown. clzip -b 1MiB file Example 3: Restore a regular file from its compressed version 'file.lz'. If the operation is successful, 'file.lz' is removed. clzip -d file.lz Example 4: Verify the integrity of the compressed file 'file.lz' and show status. clzip -tv file.lz Example 5: Compress a whole floppy in /dev/fd0 and send the output to 'file.lz'. clzip -c /dev/fd0 > file.lz Example 6: Decompress 'file.lz' partially until 10 KiB of decompressed data are produced. clzip -cd file.lz | dd bs=1024 count=10 Example 7: Decompress 'file.lz' partially from decompressed byte 10000 to decompressed byte 15000 (5000 bytes are produced). clzip -cd file.lz | dd bs=1000 skip=10 count=5 Example 8: Create a multivolume compressed tar archive with a volume size of 1440 KiB. tar -c some_directory | clzip -S 1440KiB -o volume_name Example 9: Extract a multivolume compressed tar archive. clzip -cd volume_name*.lz | tar -xf - Example 10: Create a multivolume compressed backup of a large database file with a volume size of 650 MB, where each volume is a multi-member file with a member size of 32 MiB. clzip -b 32MiB -S 650MB big_db  File: clzip.info, Node: Problems, Next: Concept index, Prev: Examples, Up: Top 6 Reporting bugs **************** There are probably bugs in clzip. There are certainly errors and omissions in this manual. If you report them, they will get fixed. If you don't, no one will ever know about them and they will remain unfixed for all eternity, if not longer. If you find a bug in clzip, please send electronic mail to . Include the version number, which you can find by running 'clzip --version'.  File: clzip.info, Node: Concept index, Prev: Problems, Up: Top Concept index ************* [index] * Menu: * algorithm: Algorithm. (line 6) * bugs: Problems. (line 6) * examples: Examples. (line 6) * file format: File format. (line 6) * getting help: Problems. (line 6) * introduction: Introduction. (line 6) * invoking: Invoking clzip. (line 6) * options: Invoking clzip. (line 6) * usage: Invoking clzip. (line 6) * version: Invoking clzip. 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