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authorDaniel Baumann <daniel.baumann@progress-linux.org>2021-01-25 12:43:54 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2021-01-25 12:43:54 +0000
commitdc114ed0e55813f66a71a56276bc81db6dfa16f1 (patch)
treed3c0b53871caf5f90bb4397ed72533601bb38f6d /doc/clzip.info
parentAdding upstream version 1.11. (diff)
downloadclzip-dc114ed0e55813f66a71a56276bc81db6dfa16f1.tar.xz
clzip-dc114ed0e55813f66a71a56276bc81db6dfa16f1.zip
Adding upstream version 1.12.upstream/1.12
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r--doc/clzip.info1330
1 files changed, 698 insertions, 632 deletions
diff --git a/doc/clzip.info b/doc/clzip.info
index 81b0a3f..d4bed66 100644
--- a/doc/clzip.info
+++ b/doc/clzip.info
@@ -11,14 +11,14 @@ File: clzip.info, Node: Top, Next: Introduction, Up: (dir)
Clzip Manual
************
-This manual is for Clzip (version 1.11, 3 January 2019).
+This manual is for Clzip (version 1.12, 4 January 2021).
* Menu:
* Introduction:: Purpose and features of clzip
* Output:: Meaning of clzip's output
* Invoking clzip:: Command line interface
-* Quality assurance:: Design, development and testing of lzip
+* Quality assurance:: Design, development, and testing of lzip
* File format:: Detailed format of the compressed file
* Algorithm:: How clzip compresses the data
* Stream format:: Format of the LZMA stream in lzip files
@@ -29,10 +29,10 @@ This manual is for Clzip (version 1.11, 3 January 2019).
* Concept index:: Index of concepts
- Copyright (C) 2010-2019 Antonio Diaz Diaz.
+ Copyright (C) 2010-2021 Antonio Diaz Diaz.
- This manual is free documentation: you have unlimited permission to
-copy, distribute and modify it.
+ This manual is free documentation: you have unlimited permission to copy,
+distribute, and modify it.

File: clzip.info, Node: Introduction, Next: Output, Prev: Top, Up: Top
@@ -40,108 +40,117 @@ File: clzip.info, Node: Introduction, Next: Output, Prev: Top, Up: Top
1 Introduction
**************
-Clzip is a C language version of lzip, fully compatible with lzip 1.4
-or newer. As clzip is written in C, it may be easier to integrate in
-applications like package managers, embedded devices, or systems
-lacking a C++ compiler.
-
- Lzip is a lossless data compressor with a user interface similar to
-the one of gzip or bzip2. Lzip can compress about as fast as gzip
-(lzip -0) or compress most files more than bzip2 (lzip -9).
-Decompression speed is intermediate between gzip and bzip2. Lzip is
-better than gzip and bzip2 from a data recovery perspective.
+Clzip is a C language version of lzip, fully compatible with lzip 1.4 or
+newer. As clzip is written in C, it may be easier to integrate in
+applications like package managers, embedded devices, or systems lacking a
+C++ compiler.
+
+ Lzip is a lossless data compressor with a user interface similar to the
+one of gzip or bzip2. Lzip uses a simplified form of the 'Lempel-Ziv-Markov
+chain-Algorithm' (LZMA) stream format, chosen to maximize safety and
+interoperability. Lzip can compress about as fast as gzip (lzip -0) or
+compress most files more than bzip2 (lzip -9). Decompression speed is
+intermediate between gzip and bzip2. Lzip is better than gzip and bzip2 from
+a data recovery perspective. Lzip has been designed, written, and tested
+with great care to replace gzip and bzip2 as the standard general-purpose
+compressed format for unix-like systems.
+
+ For compressing/decompressing large files on multiprocessor machines
+plzip can be much faster than lzip at the cost of a slightly reduced
+compression ratio. *Note plzip manual: (plzip)Top.
+
+ For creation and manipulation of compressed tar archives tarlz can be
+more efficient than using tar and plzip because tarlz is able to keep the
+alignment between tar members and lzip members. *Note tarlz manual:
+(tarlz)Top.
The lzip file format is designed for data sharing and long-term
-archiving, taking into account both data integrity and decoder
-availability:
+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. *Note Data safety:
- (lziprecover)Data safety.
-
- * The lzip format is as simple as possible (but not simpler). The
- lzip manual provides the source 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.
+ recovery means. The program lziprecover 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. *Note Data safety: (lziprecover)Data
+ safety.
+
+ * The lzip format is as simple as possible (but not simpler). The lzip
+ manual provides the source 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 the lzip reference implementation is copylefted, which
guarantees that it will remain free forever.
A nice feature of the lzip format is that a corrupt byte is easier to
-repair the nearer it is from the beginning of the file. Therefore, with
-the help of lziprecover, losing an entire archive just because of a
-corrupt byte near the beginning is a thing of the past.
-
- 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 end-of-stream marker, provide a 3 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,
-which makes it safer than compressors returning ambiguous warning
-values (like gzip) when it is used as a back end for other programs
-like tar or zutils.
-
- Clzip will automatically use for each file the largest dictionary
-size that does not exceed neither the file size nor the limit given.
-Keep in mind that the decompression memory requirement is affected at
-compression time by the choice of dictionary size limit.
-
- 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
-option '-0' is special and only requires about 1.5 MiB at most. The
-amount of memory required for decompression is about 46 kB larger than
-the dictionary size really used.
+repair the nearer it is from the beginning of the file. Therefore, with the
+help of lziprecover, losing an entire archive just because of a corrupt
+byte near the beginning is a thing of the past.
+
+ 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 end-of-stream marker, provide a 3 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 bzip2, which
+makes it safer than compressors returning ambiguous warning values (like
+gzip) when it is used as a back end for other programs like tar or zutils.
+
+ Clzip will automatically use for each file the largest dictionary size
+that does not exceed neither the file size nor the limit given. Keep in
+mind that the decompression memory requirement is affected at compression
+time by the choice of dictionary size limit.
+
+ 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 option
+'-0' is special and only requires about 1.5 MiB at most. The amount of
+memory required for decompression is about 46 kB larger than the dictionary
+size really used.
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:
+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).
+ (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.
+ Clzip is able to read from some types of non-regular files if either the
+option '-c' or the option '-o' 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 refuse to read compressed data from a terminal or write
+compressed data to a terminal, as this would be entirely incomprehensible
+and might leave the terminal in an abnormal state.
- Clzip will correctly decompress a file which is the concatenation of
-two or more compressed files. The result is the concatenation of the
+ Clzip will correctly decompress a file which is the concatenation of two
+or more compressed files. The result is the concatenation of the
corresponding decompressed files. Integrity testing of concatenated
compressed files is also supported.
- Clzip can produce multimember files, and lziprecover can safely
-recover 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 can produce multimember files, and lziprecover can safely recover
+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 multimember output. The members so created are
-large, about 2 PiB each.
+automatically creating multimember output. The members so created are large,
+about 2 PiB each.

File: clzip.info, Node: Output, Next: Invoking clzip, Prev: Introduction, Up: Top
@@ -154,42 +163,41 @@ The output of clzip looks like this:
clzip -v foo
foo: 6.676:1, 14.98% ratio, 85.02% saved, 450560 in, 67493 out.
- clzip -tvv foo.lz
- foo.lz: 6.676:1, 14.98% ratio, 85.02% saved. ok
+ clzip -tvvv foo.lz
+ foo.lz: 6.676:1, 14.98% ratio, 85.02% saved. 450560 out, 67493 in. ok
The meaning of each field is as follows:
'N:1'
- The compression ratio (uncompressed_size / compressed_size), shown
- as N to 1.
+ The compression ratio (uncompressed_size / compressed_size), shown as
+ N to 1.
'ratio'
- The inverse compression ratio
- (compressed_size / uncompressed_size), shown as a percentage. A
- decimal ratio is easily obtained by moving the decimal point two
- places to the left; 14.98% = 0.1498.
+ The inverse compression ratio (compressed_size / uncompressed_size),
+ shown as a percentage. A decimal ratio is easily obtained by moving the
+ decimal point two places to the left; 14.98% = 0.1498.
'saved'
The space saved by compression (1 - ratio), shown as a percentage.
'in'
- The size of the uncompressed data. When decompressing or testing,
- it is shown as 'decompressed'. Note that clzip always prints the
- uncompressed size before the compressed size when compressing,
- decompressing, testing or listing.
+ Size of the input data. This is the uncompressed size when
+ compressing, or the compressed size when decompressing or testing.
+ Note that clzip always prints the uncompressed size before the
+ compressed size when compressing, decompressing, testing, or listing.
'out'
- The size of the compressed data. When decompressing or testing, it
- is shown as 'compressed'.
+ Size of the output data. This is the compressed size when compressing,
+ or the decompressed size when decompressing or testing.
When decompressing or testing at verbosity level 4 (-vvvv), the
-dictionary size used to compress the file and the CRC32 of the
-uncompressed data are also shown.
+dictionary size used to compress the file and the CRC32 of the uncompressed
+data are also shown.
- LANGUAGE NOTE: Uncompressed = not compressed = plain data; it may
-never have been compressed. Decompressed is used to refer to data which
-have undergone the process of decompression.
+ LANGUAGE NOTE: Uncompressed = not compressed = plain data; it may never
+have been compressed. Decompressed is used to refer to data which have
+undergone the process of decompression.

File: clzip.info, Node: Invoking clzip, Next: Quality assurance, Prev: Output, Up: Top
@@ -201,11 +209,13 @@ The format for running clzip is:
clzip [OPTIONS] [FILES]
-'-' used as a FILE argument means standard input. It can be mixed with
-other FILES and is read just once, the first time it appears in the
-command line.
+If no file names are specified, clzip compresses (or decompresses) from
+standard input to standard output. A hyphen '-' used as a FILE argument
+means standard input. It can be mixed with other FILES and is read just
+once, the first time it appears in the command line.
- clzip supports the following options:
+ clzip supports the following options: *Note Argument syntax:
+(arg_parser)Argument syntax.
'-h'
'--help'
@@ -219,32 +229,33 @@ command line.
'-a'
'--trailing-error'
Exit with error status 2 if any remaining input is detected after
- decompressing the last member. Such remaining input is usually
- trailing garbage that can be safely ignored. *Note
- concat-example::.
+ decompressing the last member. Such remaining input is usually trailing
+ garbage that can be safely ignored. *Note concat-example::.
'-b BYTES'
'--member-size=BYTES'
- When compressing, 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 2 PiB. Defaults to
- 2 PiB.
+ When compressing, set the member size limit to BYTES. It is advisable
+ to keep members smaller than RAM size so that they can be repaired with
+ lziprecover in case of corruption. A small member size may degrade
+ compression ratio, so use it only when needed. Valid values range from
+ 100 kB to 2 PiB. Defaults to 2 PiB.
'-c'
'--stdout'
- Compress or decompress to standard output; keep input files
- unchanged. If compressing several files, each file is compressed
- independently. This option is needed when reading from a named
- pipe (fifo) or from a device. Use it also to recover as much of
- the decompressed data as possible when decompressing a corrupt
- file.
+ Compress or decompress to standard output; keep input files unchanged.
+ If compressing several files, each file is compressed independently.
+ (The output consists of a sequence of independently compressed
+ members). This option (or '-o') is needed when reading from a named
+ pipe (fifo) or from a device. Use it also to recover as much of the
+ decompressed data as possible when decompressing a corrupt file. '-c'
+ overrides '-o' and '-S'. '-c' has no effect when testing or listing.
'-d'
'--decompress'
- Decompress the specified files. If a file does not exist or can't
- be opened, clzip continues decompressing the rest of the files. If
- a file fails to decompress, or is a terminal, clzip exits
- immediately without decompressing the rest of the files.
+ Decompress the files specified. If a file does not exist or can't be
+ opened, clzip continues decompressing the rest of the files. If a file
+ fails to decompress, or is a terminal, clzip exits immediately without
+ decompressing the rest of the files.
'-f'
'--force'
@@ -252,45 +263,56 @@ command line.
'-F'
'--recompress'
- When compressing, force re-compression of files whose name already
- has the '.lz' or '.tlz' suffix.
+ When compressing, force re-compression of files whose name already has
+ the '.lz' or '.tlz' suffix.
'-k'
'--keep'
- Keep (don't delete) input files during compression or
- decompression.
+ Keep (don't delete) input files during compression or decompression.
'-l'
'--list'
- Print the uncompressed size, compressed size and percentage saved
- of the specified files. Trailing data are ignored. The values
- produced are correct even for multimember files. If more than one
- file is given, a final line containing the cumulative sizes is
- printed. With '-v', the dictionary size, the number of members in
- the file, and the amount of trailing data (if any) are also
- printed. With '-vv', the positions and sizes of each member in
- multimember files are also printed. '-lq' can be used to verify
- quickly (without decompressing) the structural integrity of the
- specified files. (Use '--test' to verify the data integrity).
- '-alq' additionally verifies that none of the specified files
- contain trailing data.
+ Print the uncompressed size, compressed size, and percentage saved of
+ the files specified. Trailing data are ignored. The values produced
+ are correct even for multimember files. If more than one file is
+ given, a final line containing the cumulative sizes is printed. With
+ '-v', the dictionary size, the number of members in the file, and the
+ amount of trailing data (if any) are also printed. With '-vv', the
+ positions and sizes of each member in multimember files are also
+ printed.
+
+ '-lq' can be used to verify quickly (without decompressing) the
+ structural integrity of the files specified. (Use '--test' to verify
+ the data integrity). '-alq' additionally verifies that none of the
+ files specified contain trailing data.
'-m BYTES'
'--match-length=BYTES'
- When compressing, 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.
+ When compressing, 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, or a
- file named 'FILE.lz' when compressing. A second '.lz' extension is
- not added if 'FILE' already ends in '.lz' or '.tlz'. When
- compressing and splitting the output in volumes, several files
- named 'FILE00001.lz', 'FILE00002.lz', etc, are created.
+ If '-c' has not been also specified, write the (de)compressed output to
+ FILE; keep input files unchanged. If compressing several files, each
+ file is compressed independently. (The output consists of a sequence of
+ independently compressed members). This option (or '-c') is needed when
+ reading from a named pipe (fifo) or from a device. '-o -' is
+ equivalent to '-c'. '-o' has no effect when testing or listing.
+
+ In order to keep backward compatibility with clzip versions prior to
+ 1.12, when compressing from standard input and no other file names are
+ given, the extension '.lz' is appended to FILE unless it already ends
+ in '.lz' or '.tlz'. This feature will be removed in a future version
+ of clzip. Meanwhile, redirection may be used instead of '-o' to write
+ the compressed output to a file without the extension '.lz' in its
+ name: 'clzip < file > foo'.
+
+ When compressing and splitting the output in volumes, FILE is used as
+ a prefix, and several files named 'FILE00001.lz', 'FILE00002.lz', etc,
+ are created. In this case, only one input file is allowed.
'-q'
'--quiet'
@@ -298,39 +320,38 @@ command line.
'-s BYTES'
'--dictionary-size=BYTES'
- When compressing, set the dictionary size limit in bytes. Clzip
- will use for each file the largest dictionary size that does not
- exceed neither the file size nor this limit. Valid values range
- from 4 KiB to 512 MiB. Values 12 to 29 are interpreted as powers
- of two, meaning 2^12 to 2^29 bytes. Dictionary sizes are quantized
- so that they can be coded in just one byte (*note
- coded-dict-size::). If the specified size does not match one of
- the valid sizes, it will be rounded upwards by adding up to
- (BYTES / 8) 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.
+ When compressing, set the dictionary size limit in bytes. Clzip will
+ use for each file the largest dictionary size that does not exceed
+ neither the file size nor this limit. Valid values range from 4 KiB to
+ 512 MiB. Values 12 to 29 are interpreted as powers of two, meaning
+ 2^12 to 2^29 bytes. Dictionary sizes are quantized so that they can be
+ coded in just one byte (*note coded-dict-size::). If the size specified
+ does not match one of the valid sizes, it will be rounded upwards by
+ adding up to (BYTES / 8) 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'
- When compressing, 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. Input files are kept
- unchanged. Each volume is a complete, maybe multimember, 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.
+ When compressing, and '-c' has not been also specified, 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. Input files are kept unchanged. Each
+ volume is a complete, maybe multimember, 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 files, 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
- files. If a file fails the test, does not exist, can't be opened,
- or is a terminal, clzip continues checking the rest of the files.
- A final diagnostic is shown at verbosity level 1 or higher if any
- file fails the test when testing multiple files.
+ Check integrity of the files specified, 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 files. If a file
+ fails the test, does not exist, can't be opened, or is a terminal,
+ clzip continues checking the rest of the files. A final diagnostic is
+ shown at verbosity level 1 or higher if any file fails the test when
+ testing multiple files.
'-v'
'--verbose'
@@ -338,27 +359,27 @@ command line.
When compressing, show the compression ratio and size for each file
processed.
When decompressing or testing, further -v's (up to 4) increase the
- verbosity level, showing status, compression ratio, dictionary
- size, trailer contents (CRC, data size, member size), and up to 6
- bytes of trailing data (if any) both in hexadecimal and as a
- string of printable ASCII characters.
+ verbosity level, showing status, compression ratio, dictionary size,
+ trailer contents (CRC, data size, member size), and up to 6 bytes of
+ trailing data (if any) both in hexadecimal and as a string of printable
+ ASCII characters.
Two or more '-v' options show the progress of (de)compression.
'-0 .. -9'
- Compression level. Set the compression parameters (dictionary size
- and match length limit) as shown in the table below. The default
- compression level is '-6', equivalent to '-s8MiB -m36'. Note that
- '-9' can be much slower than '-0'. These options have no effect
- when decompressing, testing or listing.
+ Compression level. Set the compression parameters (dictionary size and
+ match length limit) as shown in the table below. The default
+ compression level is '-6', equivalent to '-s8MiB -m36'. Note that '-9'
+ can be much slower than '-0'. These options have no effect when
+ decompressing, testing, or listing.
- 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 '--dictionary-size' and
- '--match-length' options directly to achieve optimal performance.
+ 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 options '--dictionary-size' and
+ '--match-length' directly to achieve optimal performance.
- If several compression levels or '-s' or '-m' options are given,
- the last setting is used. For example '-9 -s64MiB' is equivalent
- to '-s64MiB -m273'
+ If several compression levels or '-s' or '-m' options are given, the
+ last setting is used. For example '-9 -s64MiB' is equivalent to
+ '-s64MiB -m273'
Level Dictionary size (-s) Match length limit (-m)
-0 64 KiB 16 bytes
@@ -377,11 +398,11 @@ command line.
Aliases for GNU gzip compatibility.
'--loose-trailing'
- When decompressing, testing or listing, allow trailing data whose
- first bytes are so similar to the magic bytes of a lzip header
- that they can be confused with a corrupt header. Use this option
- if a file triggers a "corrupt header" error and the cause is not
- indeed a corrupt header.
+ When decompressing, testing, or listing, allow trailing data whose
+ first bytes are so similar to the magic bytes of a lzip header that
+ they can be confused with a corrupt header. Use this option if a file
+ triggers a "corrupt header" error and the cause is not indeed a
+ corrupt header.
Numbers given as arguments to options may be followed by a multiplier
@@ -400,83 +421,87 @@ 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.
+ 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: Quality assurance, Next: File format, Prev: Invoking clzip, Up: Top
-4 Design, development and testing of lzip
-*****************************************
+4 Design, development, and testing of lzip
+******************************************
-There are two ways of constructing a software design: One way is to make
-it so simple that there are obviously no deficiencies and the other way
-is to make it so complicated that there are no obvious deficiencies. The
-first method is far more difficult.
+There are two ways of constructing a software design: One way is to make it
+so simple that there are obviously no deficiencies and the other way is to
+make it so complicated that there are no obvious deficiencies. The first
+method is far more difficult.
-- C.A.R. Hoare
- Lzip has been designed, written and tested with great care to replace
+ Lzip is developed by volunteers who lack the resources required for
+extensive testing in all circumstances. It is up to you to test lzip before
+using it in mission-critical applications. However, a compressor like lzip
+is not a toy, and maintaining it is not a hobby. Many people's data depend
+on it. Therefore the lzip file format has been reviewed carefully and is
+believed to be free from negligent design errors.
+
+ Lzip has been designed, written, and tested with great care to replace
gzip and bzip2 as the standard general-purpose compressed format for
-unix-like systems. This chapter describes the lessons learned from
-these previous formats, and their application to the design of lzip.
+unix-like systems. This chapter describes the lessons learned from these
+previous formats, and their application to the design of lzip.
4.1 Format design
=================
-When gzip was designed in 1992, computers and operating systems were
-much less capable than they are today. Gzip tried to work around some of
-those limitations, like 8.3 file names, with additional fields in its
-file format.
+When gzip was designed in 1992, computers and operating systems were much
+less capable than they are today. The designers of gzip tried to work around
+some of those limitations, like 8.3 file names, with additional fields in
+the file format.
- Today those limitations have mostly disappeared, and the format of
-gzip has proved to be unnecessarily complicated. It includes fields
-that were never used, others that have lost their usefulness, and
-finally others that have become too limited.
+ Today those limitations have mostly disappeared, and the format of gzip
+has proved to be unnecessarily complicated. It includes fields that were
+never used, others that have lost their usefulness, and finally others that
+have become too limited.
- Bzip2 was designed 5 years later, and its format is simpler than the
-one of gzip.
+ Bzip2 was designed 5 years later, and its format is simpler than the one
+of gzip.
- Probably the worst defect of the gzip format from the point of view
-of data safety is the variable size of its header. If the byte at
-offset 3 (flags) of a gzip member gets corrupted, it may become
-difficult to recover the data, even if the compressed blocks are
-intact, because it can't be known with certainty where the compressed
-blocks begin.
+ Probably the worst defect of the gzip format from the point of view of
+data safety is the variable size of its header. If the byte at offset 3
+(flags) of a gzip member gets corrupted, it may become difficult to recover
+the data, even if the compressed blocks are intact, because it can't be
+known with certainty where the compressed blocks begin.
By contrast, the header of a lzip member has a fixed length of 6. The
-LZMA stream in a lzip member always starts at offset 6, making it
-trivial to recover the data even if the whole header becomes corrupt.
-
- Bzip2 also provides a header of fixed length and marks the begin and
-end of each compressed block with six magic bytes, making it possible to
-find the compressed blocks even in case of file damage. But bzip2 does
-not store the size of each compressed block, as lzip does.
-
- Lzip provides better data recovery capabilities than any other
-gzip-like compressor because its format has been designed from the
-beginning to be simple and safe. It also helps that the LZMA data
-stream as used by lzip is extraordinarily safe. It provides embedded
-error detection. Any distance larger than the dictionary size acts as a
+LZMA stream in a lzip member always starts at offset 6, making it trivial to
+recover the data even if the whole header becomes corrupt.
+
+ Bzip2 also provides a header of fixed length and marks the begin and end
+of each compressed block with six magic bytes, making it possible to find
+the compressed blocks even in case of file damage. But bzip2 does not store
+the size of each compressed block, as lzip does.
+
+ Lziprecover is able to provide unique data recovery capabilities because
+the lzip format is extraordinarily safe. The simple and safe design of the
+file format complements the embedded error detection provided by the LZMA
+data stream. Any distance larger than the dictionary size acts as a
forbidden symbol, allowing the decompressor to detect the approximate
position of errors, and leaving very little work for the check sequence
-(CRC and data sizes) in the detection of errors. Lzip is usually able
-to detect all possible bit flips in the compressed data without
-resorting to the check sequence. It would be difficult to write an
-automatic recovery tool like lziprecover for the gzip format. And, as
-far as I know, it has never been written.
+(CRC and data sizes) in the detection of errors. Lzip is usually able to
+detect all possible bit flips in the compressed data without resorting to
+the check sequence. It would be difficult to write an automatic recovery
+tool like lziprecover for the gzip format. And, as far as I know, it has
+never been written.
Lzip, like gzip and bzip2, uses a CRC32 to check the integrity of the
-decompressed data because it provides optimal accuracy in the detection
-of errors up to a compressed size of about 16 GiB, a size larger than
-that of most files. In the case of lzip, the additional detection
-capability of the decompressor reduces the probability of undetected
-errors about four million times more, resulting in a combined integrity
-checking optimally accurate for any member size produced by lzip.
-Preliminary results suggest that the lzip format is safe enough to be
-used in critical safety avionics systems.
+decompressed data because it provides optimal accuracy in the detection of
+errors up to a compressed size of about 16 GiB, a size larger than that of
+most files. In the case of lzip, the additional detection capability of the
+decompressor reduces the probability of undetected errors several million
+times more, resulting in a combined integrity checking optimally accurate
+for any member size produced by lzip. Preliminary results suggest that the
+lzip format is safe enough to be used in critical safety avionics systems.
The lzip format is designed for long-term archiving. Therefore it
excludes any unneeded features that may interfere with the future
@@ -487,64 +512,63 @@ extraction of the decompressed data.
---------------------------------------------------
'Multiple algorithms'
- Gzip provides a CM (Compression Method) field that has never been
- used because it is a bad idea to begin with. New compression
- methods may require additional fields, making it impossible to
- implement new methods and, at the same time, keep the same format.
- This field does not solve the problem of format proliferation; it
- just makes the problem less obvious.
+ Gzip provides a CM (Compression Method) field that has never been used
+ because it is a bad idea to begin with. New compression methods may
+ require additional fields, making it impossible to implement new
+ methods and, at the same time, keep the same format. This field does
+ not solve the problem of format proliferation; it just makes the
+ problem less obvious.
'Optional fields in header'
- Unless special precautions are taken, optional fields are
- generally a bad idea because they produce a header of variable
- size. The gzip header has 2 fields that, in addition to being
- optional, are zero-terminated. This means that if any byte inside
- the field gets zeroed, or if the terminating zero gets altered,
- gzip won't be able to find neither the header CRC nor the
- compressed blocks.
+ Unless special precautions are taken, optional fields are generally a
+ bad idea because they produce a header of variable size. The gzip
+ header has 2 fields that, in addition to being optional, are
+ zero-terminated. This means that if any byte inside the field gets
+ zeroed, or if the terminating zero gets altered, gzip won't be able to
+ find neither the header CRC nor the compressed blocks.
'Optional CRC for the header'
- Using an optional CRC for the header is not only a bad idea, it is
- an error; it circumvents the HD of the CRC and may prevent the
- extraction of perfectly good data. For example, if the CRC is used
- and the bit enabling it is reset by a bit flip, the header will
- appear to be intact (in spite of being corrupt) while the
- compressed blocks will appear to be totally unrecoverable (in
- spite of being intact). Very misleading indeed.
+ Using an optional CRC for the header is not only a bad idea, it is an
+ error; it circumvents the Hamming distance (HD) of the CRC and may
+ prevent the extraction of perfectly good data. For example, if the CRC
+ is used and the bit enabling it is reset by a bit flip, the header
+ will appear to be intact (in spite of being corrupt) while the
+ compressed blocks will appear to be totally unrecoverable (in spite of
+ being intact). Very misleading indeed.
'Metadata'
- The gzip format stores some metadata, like the modification time
- of the original file or the operating system on which compression
- took place. This complicates reproducible compression (obtaining
- identical compressed output from identical input).
+ The gzip format stores some metadata, like the modification time of the
+ original file or the operating system on which compression took place.
+ This complicates reproducible compression (obtaining identical
+ compressed output from identical input).
4.1.2 Lzip format improvements over gzip and bzip2
--------------------------------------------------
'64-bit size field'
- Probably the most frequently reported shortcoming of the gzip
- format is that it only stores the least significant 32 bits of the
+ Probably the most frequently reported shortcoming of the gzip format
+ is that it only stores the least significant 32 bits of the
uncompressed size. The size of any file larger than 4 GiB gets
truncated.
Bzip2 does not store the uncompressed size of the file.
The lzip format provides a 64-bit field for the uncompressed size.
- Additionally, lzip produces multimember output automatically when
- the size is too large for a single member, allowing for an
- unlimited uncompressed size.
+ Additionally, lzip produces multimember output automatically when the
+ size is too large for a single member, allowing for an unlimited
+ uncompressed size.
'Distributed index'
- The lzip format provides a distributed index that, among other
- things, helps plzip to decompress several times faster than pigz
- and helps lziprecover do its job. Neither the gzip format nor the
- bzip2 format do provide an index.
+ The lzip format provides a distributed index that, among other things,
+ helps plzip to decompress several times faster than pigz and helps
+ lziprecover do its job. Neither the gzip format nor the bzip2 format
+ do provide an index.
A distributed index is safer and more scalable than a monolithic
- index. The monolithic index introduces a single point of failure
- in the compressed file and may limit the number of members or the
- total uncompressed size.
+ index. The monolithic index introduces a single point of failure in
+ the compressed file and may limit the number of members or the total
+ uncompressed size.
4.2 Quality of implementation
@@ -552,42 +576,41 @@ extraction of the decompressed data.
'Accurate and robust error detection'
The lzip format provides 3 factor integrity checking and the
- decompressors report mismatches in each factor separately. This
- way if just one byte in one factor fails but the other two factors
- match the data, it probably means that the data are intact and the
- corruption just affects the mismatching factor (CRC or data size)
- in the check sequence.
+ decompressors report mismatches in each factor separately. This way if
+ just one byte in one factor fails but the other two factors match the
+ data, it probably means that the data are intact and the corruption
+ just affects the mismatching factor (CRC or data size) in the check
+ sequence.
'Multiple implementations'
Just like the lzip format provides 3 factor protection against
undetected data corruption, the development methodology of the lzip
- family of compressors provides 3 factor protection against
- undetected programming errors.
-
- Three related but independent compressor implementations, lzip,
- clzip and minilzip/lzlib, are developed concurrently. Every stable
- release of any of them is subjected to a hundred hours of
- intensive testing to verify that it produces identical output to
- the other two. This guarantees that all three implement the same
- algorithm, and makes it unlikely that any of them may contain
- serious undiscovered errors. In fact, no errors have been
- discovered in lzip since 2009.
-
- Additionally, the three implementations have been extensively
- tested with unzcrash, valgrind and 'american fuzzy lop' without
- finding a single vulnerability or false negative. *Note Unzcrash:
+ family of compressors provides 3 factor protection against undetected
+ programming errors.
+
+ Three related but independent compressor implementations, lzip, clzip,
+ and minilzip/lzlib, are developed concurrently. Every stable release
+ of any of them is tested to verify that it produces identical output
+ to the other two. This guarantees that all three implement the same
+ algorithm, and makes it unlikely that any of them may contain serious
+ undiscovered errors. In fact, no errors have been discovered in lzip
+ since 2009.
+
+ Additionally, the three implementations have been extensively tested
+ with unzcrash, valgrind, and 'american fuzzy lop' without finding a
+ single vulnerability or false negative. *Note Unzcrash:
(lziprecover)Unzcrash.
'Dictionary size'
- Lzip automatically adapts the dictionary size to the size of each
- file. In addition to reducing the amount of memory required for
- decompression, this feature also minimizes the probability of
- being affected by RAM errors during compression.
+ Lzip automatically adapts the dictionary size to the size of each file.
+ In addition to reducing the amount of memory required for
+ decompression, this feature also minimizes the probability of being
+ affected by RAM errors during compression.
'Exit status'
Returning a warning status of 2 is a design flaw of compress that
- leaked into the design of gzip. Both bzip2 and lzip are free from
- this flaw.
+ leaked into the design of gzip. Both bzip2 and lzip are free from this
+ flaw.

@@ -602,11 +625,13 @@ when there is no longer anything to take away.
In the diagram below, a box like this:
+
+---+
| | <-- the vertical bars might be missing
+---+
represents one byte; a box like this:
+
+==============+
| |
+==============+
@@ -615,10 +640,11 @@ when there is no longer anything to take away.
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.
+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 |
+--+--+--+--+----+----+=============+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
@@ -626,17 +652,16 @@ additional information before, between, or after them.
All multibyte values are stored in little endian order.
'ID string (the "magic" bytes)'
- A four byte string, identifying the lzip format, with the value
- "LZIP" (0x4C, 0x5A, 0x49, 0x50).
+ 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.
+ Just in case something needs to be modified in the future. 1 for now.
'DS (coded dictionary size, 1 byte)'
The dictionary size is calculated by taking a power of 2 (the base
- size) and subtracting from it a fraction between 0/16 and 7/16 of
- the base size.
+ size) and subtracting from it a fraction between 0/16 and 7/16 of the
+ base size.
Bits 4-0 contain the base 2 logarithm of the base size (12 to 29).
Bits 7-5 contain the numerator of the fraction (0 to 7) to subtract
from the base size to obtain the dictionary size.
@@ -645,20 +670,20 @@ additional information before, between, or after them.
'LZMA stream'
The LZMA stream, finished by an end of stream marker. Uses default
- values for encoder properties. *Note Stream format::, for a
- complete description.
+ values for encoder properties. *Note Stream format::, for a complete
+ description.
'CRC32 (4 bytes)'
- CRC of the uncompressed original data.
+ Cyclic Redundancy Check (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
- multimember files.
+ 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 multimember
+ files.

@@ -669,27 +694,30 @@ File: clzip.info, Node: Algorithm, Next: Stream format, Prev: File format, U
In spite of its name (Lempel-Ziv-Markov chain-Algorithm), LZMA is not a
concrete algorithm; it is more like "any algorithm using the LZMA coding
-scheme". For example, the option '-0' of lzip uses the scheme in almost
+scheme". LZMA compression consists in describing the uncompressed data as a
+succession of coding sequences from the set shown in Section 'What is
+coded' (*note what-is-coded::), and then encoding them using a range
+encoder. For example, the option '-0' of clzip 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 size than the one currently
-used by lzip could be developed, and the resulting sequence could also
-be coded using the LZMA coding scheme.
+literal byte if it can't find a match. Inversely, a much more elaborated way
+of finding coding sequences of minimum size than the one currently used by
+clzip could be developed, and the resulting sequence could also be coded
+using the LZMA coding scheme.
Clzip currently implements two variants of the LZMA algorithm; fast
(used by option '-0') and normal (used by all other compression levels).
- 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.
+ 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
+ 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.
+that uses a different probability model for each type of data; distances,
+lengths, literal bytes, etc.
Here is how it works, step by step:
@@ -701,15 +729,15 @@ 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.
+ 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
+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.
+ 6) The range encoder encodes the sequence produced by the main encoder
+and sends the bytes produced 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.
@@ -721,11 +749,17 @@ member or volume size limits are reached.
10) If there are more data to compress, go back to step 1.
+ During compression, clzip reads data in large blocks (one dictionary
+size at a time). Therefore it may block for up to tens of seconds any
+process feeding data to it through a pipe. This is normal. The blocking
+intervals get longer with higher compression levels because dictionary size
+increases (and compression speed decreases) with compression level.
+
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).
+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: Stream format, Next: Trailing data, Prev: Algorithm, Up: Top
@@ -733,116 +767,118 @@ File: clzip.info, Node: Stream format, Next: Trailing data, Prev: Algorithm,
7 Format of the LZMA stream in lzip files
*****************************************
-The LZMA algorithm has three parameters, called "special LZMA
-properties", to adjust it for some kinds of binary data. These
-parameters are; 'literal_context_bits' (with a default value of 3),
-'literal_pos_state_bits' (with a default value of 0), and
-'pos_state_bits' (with a default value of 2). As a general purpose
-compressor, lzip only uses the default values for these parameters. In
-particular 'literal_pos_state_bits' has been optimized away and does
-not even appear in the code.
-
- Lzip also finishes the LZMA stream with an "End Of Stream" marker
-(the distance-length pair 0xFFFFFFFFU, 2), which in conjunction with the
-"member size" field in the member trailer allows the verification of
-stream integrity. The LZMA stream in lzip files always has these two
-features (default properties and EOS marker) and is referred to in this
-document as LZMA-302eos or LZMA-lzip.
+Lzip uses a simplified form of the LZMA stream format chosen to maximize
+safety and interoperability.
+
+ The LZMA algorithm has three parameters, called "special LZMA
+properties", to adjust it for some kinds of binary data. These parameters
+are; 'literal_context_bits' (with a default value of 3),
+'literal_pos_state_bits' (with a default value of 0), and 'pos_state_bits'
+(with a default value of 2). As a general purpose compressor, lzip only
+uses the default values for these parameters. In particular
+'literal_pos_state_bits' has been optimized away and does not even appear
+in the code.
+
+ Lzip finishes the LZMA stream with an "End Of Stream" (EOS) marker (the
+distance-length pair 0xFFFFFFFFU, 2), which in conjunction with the 'member
+size' field in the member trailer allows the verification of stream
+integrity. The LZMA stream in lzip files always has these two features
+(default properties and EOS marker) and is referred to in this document as
+LZMA-302eos. The EOS marker is the only marker allowed in lzip files.
The second stage of LZMA is a range encoder that uses a different
probability model for each type of symbol; distances, lengths, literal
bytes, etc. Range encoding conceptually encodes all the symbols of the
message into one number. Unlike Huffman coding, which assigns to each
-symbol a bit-pattern and concatenates all the bit-patterns together,
-range encoding can compress one symbol to less than one bit. Therefore
-the compressed data produced by a range encoder can't be split in pieces
-that could be individually described.
+symbol a bit-pattern and concatenates all the bit-patterns together, range
+encoding can compress one symbol to less than one bit. Therefore the
+compressed data produced by a range encoder can't be split in pieces that
+could be described individually.
It seems that the only way of describing the LZMA-302eos stream is
-describing the algorithm that decodes it. And given the many details
-about the range decoder that need to be described accurately, the source
-code of a real decoder seems the only appropriate reference to use.
+describing the algorithm that decodes it. And given the many details about
+the range decoder that need to be described accurately, the source code of
+a real decoder seems the only appropriate reference to use.
- What follows is a description of the decoding algorithm for
-LZMA-302eos streams using as reference the source code of "lzd", an
-educational decompressor for lzip files which can be downloaded from
-the lzip download directory. The source code of lzd is included in
-appendix A. *Note Reference source code::.
+ What follows is a description of the decoding algorithm for LZMA-302eos
+streams using as reference the source code of "lzd", an educational
+decompressor for lzip files which can be downloaded from the lzip download
+directory. The source code of lzd is included in appendix A. *Note
+Reference source code::.
7.1 What is coded
=================
-The LZMA stream includes literals, matches and repeated matches (matches
-reusing a recently used distance). There are 7 different coding
-sequences:
+The LZMA stream includes literals, matches, and repeated matches (matches
+reusing a recently used distance). There are 7 different coding sequences:
-Bit sequence Name Description
-------------------------------------------------------------------------
-0 + byte literal literal byte
-1 + 0 + len + dis match distance-length pair
-1 + 1 + 0 + 0 shortrep 1 byte match at latest used distance
-1 + 1 + 0 + 1 + len rep0 len bytes match at latest used
- distance
-1 + 1 + 1 + 0 + len rep1 len bytes match at second latest
- used distance
-1 + 1 + 1 + 1 + 0 + len rep2 len bytes match at third latest used
- distance
-1 + 1 + 1 + 1 + 1 + len rep3 len bytes match at fourth latest
- used distance
+Bit sequence Name Description
+-----------------------------------------------------------------------------
+0 + byte literal literal byte
+1 + 0 + len + dis match distance-length pair
+1 + 1 + 0 + 0 shortrep 1 byte match at latest used distance
+1 + 1 + 0 + 1 + len rep0 len bytes match at latest used distance
+1 + 1 + 1 + 0 + len rep1 len bytes match at second latest used
+ distance
+1 + 1 + 1 + 1 + 0 + len rep2 len bytes match at third latest used
+ distance
+1 + 1 + 1 + 1 + 1 + len rep3 len bytes match at fourth latest used
+ distance
- In the following tables, multibit sequences are coded in normal
-order, from MSB to LSB, except where noted otherwise.
+ In the following tables, multibit sequences are coded in normal order,
+from most significant bit (MSB) to least significant bit (LSB), except
+where noted otherwise.
Lengths (the 'len' in the table above) are coded as follows:
-Bit sequence Description
-------------------------------------------------------------------------
-0 + 3 bits lengths from 2 to 9
-1 + 0 + 3 bits lengths from 10 to 17
-1 + 1 + 8 bits lengths from 18 to 273
+Bit sequence Description
+----------------------------------------------------------------------------
+0 + 3 bits lengths from 2 to 9
+1 + 0 + 3 bits lengths from 10 to 17
+1 + 1 + 8 bits lengths from 18 to 273
The coding of distances is a little more complicated, so I'll begin
explaining a simpler version of the encoding.
- Imagine you need to code a number from 0 to 2^32 - 1, and you want
-to do it in a way that produces shorter codes for the smaller numbers.
-You may first send the position of the most significant bit that is set
-to 1, which you may find by making a bit scan from the left (from the
-MSB). A position of 0 means that the number is 0 (no bit is set), 1
-means the LSB is the first bit set (the number is 1), and 32 means the
-MSB is set (i.e., the number is >= 0x80000000). Let's call this bit
-position a "slot". Then, if slot is > 1, you send the remaining
-slot - 1 bits. Let's call these bits "direct_bits" because they are
-coded directly by value instead of indirectly by position.
-
- The inconvenient of this simple method is that it needs 6 bits to
-code the slot, but it just uses 33 of the 64 possible values, wasting
-almost half of the codes.
-
- The intelligent trick of LZMA is that it encodes the position of the
-most significant bit set, along with the value of the next bit, in the
-same 6 bits that would take to encode the position alone. This seems to
-need 66 slots (2 * position + next_bit), but for slots 0 and 1 there is
-no next bit, so the number of needed slots is 64 (0 to 63).
+ Imagine you need to encode a number from 0 to 2^32 - 1, and you want to
+do it in a way that produces shorter codes for the smaller numbers. You may
+first encode the position of the most significant bit that is set to 1,
+which you may find by making a bit scan from the left (from the MSB). A
+position of 0 means that the number is 0 (no bit is set), 1 means the LSB is
+the first bit set (the number is 1), and 32 means the MSB is set (i.e., the
+number is >= 0x80000000). Then, if the position is >= 2, you encode the
+remaining position - 1 bits. Let's call these bits "direct_bits" because
+they are coded directly by value instead of indirectly by position.
+
+ The inconvenient of this simple method is that it needs 6 bits to encode
+the position, but it just uses 33 of the 64 possible values, wasting almost
+half of the codes.
+
+ The intelligent trick of LZMA is that it encodes in what it calls a
+"slot" the position of the most significant bit set, along with the value
+of the next bit, using the same 6 bits that would take to encode the
+position alone. This seems to need 66 slots (twice the number of
+positions), but for positions 0 and 1 there is no next bit, so the number
+of slots needed is 64 (0 to 63).
The 6 bits representing this "slot number" are then context-coded. If
-the distance is >= 4, the remaining bits are coded as follows.
-'direct_bits' is the amount of remaining bits (from 0 to 30) needed to
-form a complete distance, and is calculated as (slot >> 1) - 1. If a
-distance needs 6 or more direct_bits, the last 4 bits are coded
-separately. The last piece (all the direct_bits for distances 4 to 127
-or the last 4 bits for distances >= 128) is context-coded in reverse
-order (from LSB to MSB). For distances >= 128, the 'direct_bits - 4'
-part is coded with fixed 0.5 probability.
-
-Bit sequence Description
-------------------------------------------------------------------------
-slot distances from 0 to 3
-slot + direct_bits distances from 4 to 127
-slot + (direct_bits - 4) + 4 bits distances from 128 to 2^32 - 1
+the distance is >= 4, the remaining bits are encoded as follows.
+'direct_bits' is the amount of remaining bits (from 1 to 30) needed to form
+a complete distance, and is calculated as (slot >> 1) - 1. If a distance
+needs 6 or more direct_bits, the last 4 bits are encoded separately. The
+last piece (all the direct_bits for distances 4 to 127, or the last 4 bits
+for distances >= 128) is context-coded in reverse order (from LSB to MSB).
+For distances >= 128, the 'direct_bits - 4' part is encoded with fixed 0.5
+probability.
+
+Bit sequence Description
+----------------------------------------------------------------------------
+slot distances from 0 to 3
+slot + direct_bits distances from 4 to 127
+slot + (direct_bits - 4) + 4 bits distances from 128 to 2^32 - 1
7.2 The coding contexts
@@ -859,20 +895,20 @@ integers representing the probability of the corresponding bit being 0.
state is 0.
'pos_state'
- Value of the 2 least significant bits of the current position in
- the decoded data.
+ Value of the 2 least significant bits of the current position in the
+ decoded data.
'literal_state'
Value of the 3 most significant bits of the latest byte decoded.
'len_state'
- Coded value of length (length - 2), with a maximum of 3. The
- resulting value is in the range 0 to 3.
+ Coded value of the current match length (length - 2), with a maximum
+ of 3. The resulting value is in the range 0 to 3.
In the following table, '!literal' is any sequence except a literal
-byte. 'rep' is any one of 'rep0', 'rep1', 'rep2' or 'rep3'. The types
-of previous sequences corresponding to each state are:
+byte. 'rep' is any one of 'rep0', 'rep1', 'rep2', or 'rep3'. The types of
+previous sequences corresponding to each state are:
State Types of previous sequences
------------------------------------------------------
@@ -892,78 +928,81 @@ State Types of previous sequences
The contexts for decoding the type of coding sequence are:
-Name Indices Used when
------------------------------------------------------------------------
-bm_match state, pos_state sequence start
-bm_rep state after sequence 1
-bm_rep0 state after sequence 11
-bm_rep1 state after sequence 111
-bm_rep2 state after sequence 1111
-bm_len state, pos_state after sequence 110
+Name Indices Used when
+----------------------------------------------------------------------------
+bm_match state, pos_state sequence start
+bm_rep state after sequence 1
+bm_rep0 state after sequence 11
+bm_rep1 state after sequence 111
+bm_rep2 state after sequence 1111
+bm_len state, pos_state after sequence 110
The contexts for decoding distances are:
-Name Indices Used when
-------------------------------------------------------------------------
-bm_dis_slot len_state, bit tree distance start
-bm_dis reverse bit tree after slots 4 to 13
-bm_align reverse bit tree for distances >= 128, after fixed
- probability bits
+Name Indices Used when
+----------------------------------------------------------------------------
+bm_dis_slot len_state, bit tree distance start
+bm_dis reverse bit tree after slots 4 to 13
+bm_align reverse bit tree for distances >= 128, after fixed
+ probability bits
- There are two separate sets of contexts for lengths ('Len_model' in
-the source). One for normal matches, the other for repeated matches. The
+ There are two separate sets of contexts for lengths ('Len_model' in the
+source). One for normal matches, the other for repeated matches. The
contexts in each Len_model are (see 'decode_len' in the source):
-Name Indices Used when
-------------------------------------------------------------------------
-choice1 none length start
-choice2 none after sequence 1
-bm_low pos_state, bit tree after sequence 0
-bm_mid pos_state, bit tree after sequence 10
-bm_high bit tree after sequence 11
+Name Indices Used when
+---------------------------------------------------------------------------
+choice1 none length start
+choice2 none after sequence 1
+bm_low pos_state, bit tree after sequence 0
+bm_mid pos_state, bit tree after sequence 10
+bm_high bit tree after sequence 11
The context array 'bm_literal' is special. In principle it acts as a
-normal bit tree context, the one selected by 'literal_state'. But if
-the previous decoded byte was not a literal, two other bit tree
-contexts are used depending on the value of each bit in 'match_byte'
-(the byte at the latest used distance), until a bit is decoded that is
-different from its corresponding bit in 'match_byte'. After the first
-difference is found, the rest of the byte is decoded using the normal
-bit tree context. (See 'decode_matched' in the source).
+normal bit tree context, the one selected by 'literal_state'. But if the
+previous decoded byte was not a literal, two other bit tree contexts are
+used depending on the value of each bit in 'match_byte' (the byte at the
+latest used distance), until a bit is decoded that is different from its
+corresponding bit in 'match_byte'. After the first difference is found, the
+rest of the byte is decoded using the normal bit tree context. (See
+'decode_matched' in the source).
7.3 The range decoder
=====================
-The LZMA stream is consumed one byte at a time by the range decoder.
-(See 'normalize' in the source). Every byte consumed produces a
-variable number of decoded bits, depending on how well these bits agree
-with their context. (See 'decode_bit' in the source).
+The LZMA stream is consumed one byte at a time by the range decoder. (See
+'normalize' in the source). Every byte consumed produces a variable number
+of decoded bits, depending on how well these bits agree with their context.
+(See 'decode_bit' in the source).
The range decoder state consists of two unsigned 32-bit variables;
-'range' (representing the most significant part of the range size not
-yet decoded), and 'code' (representing the current point within
-'range'). 'range' is initialized to (2^32 - 1), and 'code' is
-initialized to 0.
+'range' (representing the most significant part of the range size not yet
+decoded), and 'code' (representing the current point within 'range').
+'range' is initialized to 2^32 - 1, and 'code' is initialized to 0.
The range encoder produces a first 0 byte that must be ignored by the
range decoder. This is done by shifting 5 bytes in the initialization of
-'code' instead of 4. (See the 'Range_decoder' constructor in the
-source).
+'code' instead of 4. (See the 'Range_decoder' constructor in the source).
-7.4 Decoding the LZMA stream
-============================
+7.4 Decoding and verifying the LZMA stream
+==========================================
After decoding the member header and obtaining the dictionary size, the
-range decoder is initialized and then the LZMA decoder enters a loop
-(See 'decode_member' in the source) where it invokes the range decoder
-with the appropriate contexts to decode the different coding sequences
-(matches, repeated matches, and literal bytes), until the "End Of
-Stream" marker is decoded.
+range decoder is initialized and then the LZMA decoder enters a loop (See
+'decode_member' in the source) where it invokes the range decoder with the
+appropriate contexts to decode the different coding sequences (matches,
+repeated matches, and literal bytes), until the "End Of Stream" marker is
+decoded.
+
+ Once the "End Of Stream" marker has been decoded, the decompressor reads
+and decodes the member trailer, and verifies that the three integrity
+factors (CRC, data size, and member size) match those calculated by the
+LZMA decoder.

File: clzip.info, Node: Trailing data, Next: Examples, Prev: Stream format, Up: Top
@@ -974,43 +1013,40 @@ File: clzip.info, Node: Trailing data, Next: Examples, Prev: Stream format,
Sometimes extra data are found appended to a lzip file after the last
member. Such trailing data may be:
- * Padding added to make the file size a multiple of some block size,
- for example when writing to a tape. It is safe to append any
- amount of padding zero bytes to a lzip file.
+ * Padding added to make the file size a multiple of some block size, for
+ example when writing to a tape. It is safe to append any amount of
+ padding zero bytes to a lzip file.
* Useful data added by the user; a cryptographically secure hash, a
- description of file contents, etc. It is safe to append any amount
- of text to a lzip file as long as none of the first four bytes of
- the text match the corresponding byte in the string "LZIP", and
- the text does not contain any zero bytes (null characters).
- Nonzero bytes and zero bytes can't be safely mixed in trailing
- data.
+ description of file contents, etc. It is safe to append any amount of
+ text to a lzip file as long as none of the first four bytes of the text
+ match the corresponding byte in the string "LZIP", and the text does
+ not contain any zero bytes (null characters). Nonzero bytes and zero
+ bytes can't be safely mixed in trailing data.
* Garbage added by some not totally successful copy operation.
- * Malicious data added to the file in order to make its total size
- and hash value (for a chosen hash) coincide with those of another
- file.
+ * Malicious data added to the file in order to make its total size and
+ hash value (for a chosen hash) coincide with those of another file.
* In rare cases, trailing data could be the corrupt header of another
member. In multimember or concatenated files the probability of
corruption happening in the magic bytes is 5 times smaller than the
- probability of getting a false positive caused by the corruption
- of the integrity information itself. Therefore it can be
- considered to be below the noise level. Additionally, the test
- used by clzip to discriminate trailing data from a corrupt header
- has a Hamming distance (HD) of 3, and the 3 bit flips must happen
- in different magic bytes for the test to fail. In any case, the
- option '--trailing-error' guarantees that any corrupt header will
- be detected.
+ probability of getting a false positive caused by the corruption of the
+ integrity information itself. Therefore it can be considered to be
+ below the noise level. Additionally, the test used by clzip to
+ discriminate trailing data from a corrupt header has a Hamming
+ distance (HD) of 3, and the 3 bit flips must happen in different magic
+ bytes for the test to fail. In any case, the option '--trailing-error'
+ guarantees that any corrupt header will be detected.
Trailing data are in no way part of the lzip file format, but tools
reading lzip files are expected to behave as correctly and usefully as
possible in the presence of trailing data.
- Trailing data can be safely ignored in most cases. In some cases,
-like that of user-added data, they are expected to be ignored. In those
-cases where a file containing trailing data must be rejected, the option
+ Trailing data can be safely ignored in most cases. In some cases, like
+that of user-added data, they are expected to be ignored. In those cases
+where a file containing trailing data must be rejected, the option
'--trailing-error' can be used. *Note --trailing-error::.

@@ -1022,80 +1058,88 @@ File: clzip.info, Node: Examples, Next: Problems, Prev: Trailing data, Up: T
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 don't remove the original file until you
+option '--keep' to clzip and don't remove the original file until you
verify the compressed file with a command like
'clzip -cd file.lz | cmp file -'. Most RAM errors happening during
-compression can only be detected by comparing the compressed file with
-the original because the corruption happens before clzip compresses the
-RAM contents, resulting in a valid compressed file containing wrong
-data.
+compression can only be detected by comparing the compressed file with the
+original because the corruption happens before clzip compresses the RAM
+contents, resulting in a valid compressed file containing wrong data.
+
+
+Example 1: Extract all the files from archive 'foo.tar.lz'.
+ tar -xf foo.tar.lz
+ or
+ clzip -cd foo.tar.lz | tar -xf -
-Example 1: Replace a regular file with its compressed version 'file.lz'
-and show the compression ratio.
+
+Example 2: 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 multimember with
-a member size of 1 MiB. The compression ratio is not shown.
+Example 3: Like example 1 but the created 'file.lz' is multimember 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.
+Example 4: 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.
+Example 5: Verify the integrity of the compressed file 'file.lz' and show
+status.
clzip -tv file.lz
-Example 5: Compress a whole device in /dev/sdc and send the output to
+Example 6: Compress a whole device in /dev/sdc and send the output to
'file.lz'.
- clzip -c /dev/sdc > file.lz
+ clzip -c /dev/sdc > file.lz
+ or
+ clzip /dev/sdc -o file.lz
-Example 6: The right way of concatenating the decompressed output of two
-or more compressed files. *Note Trailing data::.
+Example 7: The right way of concatenating the decompressed output of two or
+more compressed files. *Note Trailing data::.
Don't do this
- cat file1.lz file2.lz file3.lz | clzip -d
+ cat file1.lz file2.lz file3.lz | clzip -d -
Do this instead
clzip -cd file1.lz file2.lz file3.lz
-Example 7: Decompress 'file.lz' partially until 10 KiB of decompressed
-data are produced.
+Example 8: Decompress 'file.lz' partially until 10 KiB of decompressed data
+are produced.
clzip -cd file.lz | dd bs=1024 count=10
-Example 8: Decompress 'file.lz' partially from decompressed byte 10000
-to decompressed byte 15000 (5000 bytes are produced).
+Example 9: Decompress 'file.lz' partially from decompressed byte at offset
+10000 to decompressed byte at offset 14999 (5000 bytes are produced).
clzip -cd file.lz | dd bs=1000 skip=10 count=5
-Example 9: Create a multivolume compressed tar archive with a volume
-size of 1440 KiB.
+Example 10: Create a multivolume compressed tar archive with a volume size
+of 1440 KiB.
- tar -c some_directory | clzip -S 1440KiB -o volume_name
+ tar -c some_directory | clzip -S 1440KiB -o volume_name -
-Example 10: Extract a multivolume compressed tar archive.
+Example 11: Extract a multivolume compressed tar archive.
clzip -cd volume_name*.lz | tar -xf -
-Example 11: Create a multivolume compressed backup of a large database
-file with a volume size of 650 MB, where each volume is a multimember
-file with a member size of 32 MiB.
+Example 12: Create a multivolume compressed backup of a large database file
+with a volume size of 650 MB, where each volume is a multimember file with
+a member size of 32 MiB.
clzip -b 32MiB -S 650MB big_db
@@ -1105,14 +1149,14 @@ File: clzip.info, Node: Problems, Next: Reference source code, Prev: Examples
10 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.
+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
-<lzip-bug@nongnu.org>. Include the version number, which you can find
-by running 'clzip --version'.
+<lzip-bug@nongnu.org>. Include the version number, which you can find by
+running 'clzip --version'.

File: clzip.info, Node: Reference source code, Next: Concept index, Prev: Problems, Up: Top
@@ -1120,28 +1164,28 @@ File: clzip.info, Node: Reference source code, Next: Concept index, Prev: Pro
Appendix A Reference source code
********************************
-/* Lzd - Educational decompressor for the lzip format
- Copyright (C) 2013-2019 Antonio Diaz Diaz.
+/* Lzd - Educational decompressor for the lzip format
+ Copyright (C) 2013-2021 Antonio Diaz Diaz.
- This program is free software. Redistribution and use in source and
- binary forms, with or without modification, are permitted provided
- that the following conditions are met:
+ This program is free software. Redistribution and use in source and
+ binary forms, with or without modification, are permitted provided
+ that the following conditions are met:
- 1. Redistributions of source code must retain the above copyright
- notice, this list of conditions and the following disclaimer.
+ 1. Redistributions of source code must retain the above copyright
+ notice, this list of conditions, and the following disclaimer.
- 2. Redistributions in binary form must reproduce the above copyright
- notice, this list of conditions and the following disclaimer in the
- documentation and/or other materials provided with the distribution.
+ 2. Redistributions in binary form must reproduce the above copyright
+ notice, this list of conditions, and the following disclaimer in the
+ documentation and/or other materials provided with the distribution.
- 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.
+ 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.
*/
/*
- 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.
+ 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.
*/
#include <algorithm>
@@ -1169,7 +1213,7 @@ public:
void set_char()
{
- static const int next[states] = { 0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 4, 5 };
+ const int next[states] = { 0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 4, 5 };
st = next[st];
}
void set_match() { st = ( st < 7 ) ? 7 : 10; }
@@ -1191,7 +1235,7 @@ enum {
dis_slot_bits = 6,
start_dis_model = 4,
end_dis_model = 14,
- modeled_distances = 1 << (end_dis_model / 2), // 128
+ modeled_distances = 1 << ( end_dis_model / 2 ), // 128
dis_align_bits = 4,
dis_align_size = 1 << dis_align_bits,
@@ -1252,8 +1296,9 @@ public:
const CRC32 crc32;
-typedef uint8_t Lzip_header[6]; // 0-3 magic, 4 version, 5 coded_dict_size
-
+typedef uint8_t Lzip_header[6]; // 0-3 magic bytes
+ // 4 version
+ // 5 coded dictionary size
typedef uint8_t Lzip_trailer[20];
// 0-3 CRC32 of the uncompressed data
// 4-11 size of the uncompressed data
@@ -1261,16 +1306,18 @@ typedef uint8_t Lzip_trailer[20];
class Range_decoder
{
+ unsigned long long member_pos;
uint32_t code;
uint32_t range;
public:
- Range_decoder() : code( 0 ), range( 0xFFFFFFFFU )
+ Range_decoder() : member_pos( 6 ), code( 0 ), range( 0xFFFFFFFFU )
{
- for( int i = 0; i < 5; ++i ) code = (code << 8) | get_byte();
+ for( int i = 0; i < 5; ++i ) code = ( code << 8 ) | get_byte();
}
- uint8_t get_byte() { return std::getc( stdin ); }
+ uint8_t get_byte() { ++member_pos; return std::getc( stdin ); }
+ unsigned long long member_position() const { return member_pos; }
unsigned decode( const int num_bits )
{
@@ -1281,7 +1328,7 @@ public:
symbol <<= 1;
if( code >= range ) { code -= range; symbol |= 1; }
if( range <= 0x00FFFFFFU ) // normalize
- { range <<= 8; code = (code << 8) | get_byte(); }
+ { range <<= 8; code = ( code << 8 ) | get_byte(); }
}
return symbol;
}
@@ -1293,7 +1340,8 @@ public:
if( code < bound )
{
range = bound;
- bm.probability += (bit_model_total - bm.probability) >> bit_model_move_bits;
+ bm.probability +=
+ ( bit_model_total - bm.probability ) >> bit_model_move_bits;
symbol = 0;
}
else
@@ -1304,7 +1352,7 @@ public:
symbol = 1;
}
if( range <= 0x00FFFFFFU ) // normalize
- { range <<= 8; code = (code << 8) | get_byte(); }
+ { range <<= 8; code = ( code << 8 ) | get_byte(); }
return symbol;
}
@@ -1313,7 +1361,7 @@ public:
unsigned symbol = 1;
for( int i = 0; i < num_bits; ++i )
symbol = ( symbol << 1 ) | decode_bit( bm[symbol] );
- return symbol - (1 << num_bits);
+ return symbol - ( 1 << num_bits );
}
unsigned decode_tree_reversed( Bit_model bm[], const int num_bits )
@@ -1400,7 +1448,11 @@ public:
~LZ_decoder() { delete[] buffer; }
unsigned crc() const { return crc_ ^ 0xFFFFFFFFU; }
- unsigned long long data_position() const { return partial_data_pos + pos; }
+ unsigned long long data_position() const
+ { return partial_data_pos + pos; }
+ uint8_t get_byte() { return rdec.get_byte(); }
+ unsigned long long member_position() const
+ { return rdec.member_position(); }
bool decode_member();
};
@@ -1412,7 +1464,6 @@ void LZ_decoder::flush_data()
{
const unsigned size = pos - stream_pos;
crc32.update_buf( crc_, buffer + stream_pos, size );
- errno = 0;
if( std::fwrite( buffer + stream_pos, 1, size, stdout ) != size )
{ std::fprintf( stderr, "Write error: %s\n", std::strerror( errno ) );
std::exit( 1 ); }
@@ -1423,7 +1474,7 @@ void LZ_decoder::flush_data()
}
-bool LZ_decoder::decode_member() // Returns false if error
+bool LZ_decoder::decode_member() // Returns false if error
{
Bit_model bm_literal[1<<literal_context_bits][0x300];
Bit_model bm_match[State::states][pos_states];
@@ -1503,7 +1554,8 @@ bool LZ_decoder::decode_member() // Returns false if error
direct_bits );
else
{
- rep0 += rdec.decode( direct_bits - dis_align_bits ) << dis_align_bits;
+ rep0 +=
+ rdec.decode( direct_bits - dis_align_bits ) << dis_align_bits;
rep0 += rdec.decode_tree_reversed( bm_align, dis_align_bits );
if( rep0 == 0xFFFFFFFFU ) // marker found
{
@@ -1525,20 +1577,21 @@ bool LZ_decoder::decode_member() // Returns false if error
int main( const int argc, const char * const argv[] )
{
- if( argc > 1 )
+ if( argc > 2 || ( argc == 2 && std::strcmp( argv[1], "-d" ) != 0 ) )
{
- std::printf( "Lzd %s - Educational decompressor for the lzip format.\n",
- PROGVERSION );
- std::printf( "Study the source to learn how a lzip decompressor works.\n"
- "See the lzip manual for an explanation of the code.\n"
- "It is not safe to use lzd for any real work.\n"
- "\nUsage: %s < file.lz > file\n", argv[0] );
- std::printf( "Lzd decompresses from standard input to standard output.\n"
- "\nCopyright (C) 2019 Antonio Diaz Diaz.\n"
- "This is free software: you are free to change and redistribute it.\n"
- "There is NO WARRANTY, to the extent permitted by law.\n"
- "Report bugs to lzip-bug@nongnu.org\n"
- "Lzd home page: http://www.nongnu.org/lzip/lzd.html\n" );
+ std::printf(
+ "Lzd %s - Educational decompressor for the lzip format.\n"
+ "Study the source to learn how a lzip decompressor works.\n"
+ "See the lzip manual for an explanation of the code.\n"
+ "\nUsage: %s [-d] < file.lz > file\n"
+ "Lzd decompresses from standard input to standard output.\n"
+ "\nCopyright (C) 2021 Antonio Diaz Diaz.\n"
+ "License 2-clause BSD.\n"
+ "This is free software: you are free to change and redistribute it.\n"
+ "There is NO WARRANTY, to the extent permitted by law.\n"
+ "Report bugs to lzip-bug@nongnu.org\n"
+ "Lzd home page: http://www.nongnu.org/lzip/lzd.html\n",
+ PROGVERSION, argv[0] );
return 0;
}
@@ -1554,9 +1607,9 @@ int main( const int argc, const char * const argv[] )
if( std::feof( stdin ) || std::memcmp( header, "LZIP\x01", 5 ) != 0 )
{
if( first_member )
- { std::fputs( "Bad magic number (file not in lzip format).\n", stderr );
- return 2; }
- break;
+ { std::fputs( "Bad magic number (file not in lzip format).\n",
+ stderr ); return 2; }
+ break; // ignore trailing data
}
unsigned dict_size = 1 << ( header[5] & 0x1F );
dict_size -= ( dict_size / 16 ) * ( ( header[5] >> 5 ) & 7 );
@@ -1569,18 +1622,30 @@ int main( const int argc, const char * const argv[] )
{ std::fputs( "Data error\n", stderr ); return 2; }
Lzip_trailer trailer; // verify trailer
- for( int i = 0; i < 20; ++i ) trailer[i] = std::getc( stdin );
+ for( int i = 0; i < 20; ++i ) trailer[i] = decoder.get_byte();
+ int retval = 0;
unsigned crc = 0;
- for( int i = 3; i >= 0; --i ) { crc <<= 8; crc += trailer[i]; }
+ for( int i = 3; i >= 0; --i ) crc = ( crc << 8 ) + trailer[i];
+ if( crc != decoder.crc() )
+ { std::fputs( "CRC mismatch\n", stderr ); retval = 2; }
+
unsigned long long data_size = 0;
- for( int i = 11; i >= 4; --i ) { data_size <<= 8; data_size += trailer[i]; }
- if( crc != decoder.crc() || data_size != decoder.data_position() )
- { std::fputs( "CRC error\n", stderr ); return 2; }
+ for( int i = 11; i >= 4; --i )
+ data_size = ( data_size << 8 ) + trailer[i];
+ if( data_size != decoder.data_position() )
+ { std::fputs( "Data size mismatch\n", stderr ); retval = 2; }
+
+ unsigned long long member_size = 0;
+ for( int i = 19; i >= 12; --i )
+ member_size = ( member_size << 8 ) + trailer[i];
+ if( member_size != decoder.member_position() )
+ { std::fputs( "Member size mismatch\n", stderr ); retval = 2; }
+ if( retval ) return retval;
}
if( std::fclose( stdout ) != 0 )
- { std::fprintf( stderr, "Error closing stdout: %s\n", std::strerror( errno ) );
- return 1; }
+ { std::fprintf( stderr, "Error closing stdout: %s\n",
+ std::strerror( errno ) ); return 1; }
return 0;
}
@@ -1593,41 +1658,42 @@ Concept index
* Menu:
-* algorithm: Algorithm. (line 6)
-* bugs: Problems. (line 6)
-* examples: Examples. (line 6)
-* file format: File format. (line 6)
-* format of the LZMA stream: Stream format. (line 6)
-* getting help: Problems. (line 6)
-* introduction: Introduction. (line 6)
-* invoking: Invoking clzip. (line 6)
-* options: Invoking clzip. (line 6)
-* output: Output. (line 6)
-* quality assurance: Quality assurance. (line 6)
-* reference source code: Reference source code. (line 6)
-* trailing data: Trailing data. (line 6)
-* usage: Invoking clzip. (line 6)
-* version: Invoking clzip. (line 6)
+* algorithm: Algorithm. (line 6)
+* bugs: Problems. (line 6)
+* examples: Examples. (line 6)
+* file format: File format. (line 6)
+* format of the LZMA stream: Stream format. (line 6)
+* getting help: Problems. (line 6)
+* introduction: Introduction. (line 6)
+* invoking: Invoking clzip. (line 6)
+* options: Invoking clzip. (line 6)
+* output: Output. (line 6)
+* quality assurance: Quality assurance. (line 6)
+* reference source code: Reference source code. (line 6)
+* trailing data: Trailing data. (line 6)
+* usage: Invoking clzip. (line 6)
+* version: Invoking clzip. (line 6)

Tag Table:
Node: Top210
-Node: Introduction1209
-Node: Output6498
-Node: Invoking clzip8018
-Ref: --trailing-error8648
-Node: Quality assurance16666
-Node: File format25271
-Ref: coded-dict-size26564
-Node: Algorithm27674
-Node: Stream format30504
-Node: Trailing data41156
-Node: Examples43434
-Ref: concat-example44866
-Node: Problems45911
-Node: Reference source code46447
-Node: Concept index60660
+Node: Introduction1211
+Node: Output7184
+Node: Invoking clzip8787
+Ref: --trailing-error9585
+Node: Quality assurance18586
+Node: File format27545
+Ref: coded-dict-size28836
+Node: Algorithm29972
+Node: Stream format33379
+Ref: what-is-coded35749
+Node: Trailing data44618
+Node: Examples46881
+Ref: concat-example48493
+Node: Problems49563
+Node: Reference source code50099
+Node: Concept index64964

End Tag Table