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xz, unxz, xzcat, lzma, unlzma, lzcat - Compress or decompress .xz and .lzma files


xz [option]... [file]...

unxz is equivalent to xz --decompress.
xzcat is equivalent to xz --decompress --stdout.
lzma is equivalent to xz --format=lzma.
unlzma is equivalent to xz --format=lzma --decompress.
lzcat is equivalent to xz --format=lzma --decompress --stdout.

When writing scripts that need to decompress files, it is recommended to always use the
name xz with appropriate arguments (xz -d or xz -dc) instead of the names unxz and xzcat.


xz is a general-purpose data compression tool with command line syntax similar to gzip(1)
and bzip2(1). The native file format is the .xz format, but the legacy .lzma format used
by LZMA Utils and raw compressed streams with no container format headers are also

xz compresses or decompresses each file according to the selected operation mode. If no
files are given or file is -, xz reads from standard input and writes the processed data
to standard output. xz will refuse (display an error and skip the file) to write
compressed data to standard output if it is a terminal. Similarly, xz will refuse to read
compressed data from standard input if it is a terminal.

Unless --stdout is specified, files other than - are written to a new file whose name is
derived from the source file name:

· When compressing, the suffix of the target file format (.xz or .lzma) is appended to
the source filename to get the target filename.

· When decompressing, the .xz or .lzma suffix is removed from the filename to get the
target filename. xz also recognizes the suffixes .txz and .tlz, and replaces them with
the .tar suffix.

If the target file already exists, an error is displayed and the file is skipped.

Unless writing to standard output, xz will display a warning and skip the file if any of
the following applies:

· File is not a regular file. Symbolic links are not followed, and thus they are not
considered to be regular files.

· File has more than one hard link.

· File has setuid, setgid, or sticky bit set.

· The operation mode is set to compress and the file already has a suffix of the target
file format (.xz or .txz when compressing to the .xz format, and .lzma or .tlz when
compressing to the .lzma format).

· The operation mode is set to decompress and the file doesn't have a suffix of any of
the supported file formats (.xz, .txz, .lzma, or .tlz).

After successfully compressing or decompressing the file, xz copies the owner, group,
permissions, access time, and modification time from the source file to the target file.
If copying the group fails, the permissions are modified so that the target file doesn't
become accessible to users who didn't have permission to access the source file. xz
doesn't support copying other metadata like access control lists or extended attributes

Once the target file has been successfully closed, the source file is removed unless
--keep was specified. The source file is never removed if the output is written to
standard output.

Sending SIGINFO or SIGUSR1 to the xz process makes it print progress information to
standard error. This has only limited use since when standard error is a terminal, using
--verbose will display an automatically updating progress indicator.

Memory usage
The memory usage of xz varies from a few hundred kilobytes to several gigabytes depending
on the compression settings. The settings used when compressing a file determine the
memory requirements of the decompressor. Typically the decompressor needs 5 % to 20 % of
the amount of memory that the compressor needed when creating the file. For example,
decompressing a file created with xz -9 currently requires 65 MiB of memory. Still, it is
possible to have .xz files that require several gigabytes of memory to decompress.

Especially users of older systems may find the possibility of very large memory usage
annoying. To prevent uncomfortable surprises, xz has a built-in memory usage limiter,
which is disabled by default. While some operating systems provide ways to limit the
memory usage of processes, relying on it wasn't deemed to be flexible enough (e.g. using
ulimit(1) to limit virtual memory tends to cripple mmap(2)).

The memory usage limiter can be enabled with the command line option --memlimit=limit.
Often it is more convenient to enable the limiter by default by setting the environment
variable XZ_DEFAULTS, e.g. XZ_DEFAULTS=--memlimit=150MiB. It is possible to set the
limits separately for compression and decompression by using --memlimit-compress=limit and
--memlimit-decompress=limit. Using these two options outside XZ_DEFAULTS is rarely useful
because a single run of xz cannot do both compression and decompression and
--memlimit=limit (or -M limit) is shorter to type on the command line.

If the specified memory usage limit is exceeded when decompressing, xz will display an
error and decompressing the file will fail. If the limit is exceeded when compressing, xz
will try to scale the settings down so that the limit is no longer exceeded (except when
using --format=raw or --no-adjust). This way the operation won't fail unless the limit is
very small. The scaling of the settings is done in steps that don't match the compression
level presets, e.g. if the limit is only slightly less than the amount required for xz -9,
the settings will be scaled down only a little, not all the way down to xz -8.

Concatenation and padding with .xz files
It is possible to concatenate .xz files as is. xz will decompress such files as if they
were a single .xz file.

It is possible to insert padding between the concatenated parts or after the last part.
The padding must consist of null bytes and the size of the padding must be a multiple of
four bytes. This can be useful e.g. if the .xz file is stored on a medium that measures
file sizes in 512-byte blocks.

Concatenation and padding are not allowed with .lzma files or raw streams.


Integer suffixes and special values
In most places where an integer argument is expected, an optional suffix is supported to
easily indicate large integers. There must be no space between the integer and the

KiB Multiply the integer by 1,024 (2^10). Ki, k, kB, K, and KB are accepted as
synonyms for KiB.

MiB Multiply the integer by 1,048,576 (2^20). Mi, m, M, and MB are accepted as
synonyms for MiB.

GiB Multiply the integer by 1,073,741,824 (2^30). Gi, g, G, and GB are accepted as
synonyms for GiB.

The special value max can be used to indicate the maximum integer value supported by the

Operation mode
If multiple operation mode options are given, the last one takes effect.

-z, --compress
Compress. This is the default operation mode when no operation mode option is
specified and no other operation mode is implied from the command name (for
example, unxz implies --decompress).

-d, --decompress, --uncompress

-t, --test
Test the integrity of compressed files. This option is equivalent to --decompress
--stdout except that the decompressed data is discarded instead of being written to
standard output. No files are created or removed.

-l, --list
Print information about compressed files. No uncompressed output is produced, and
no files are created or removed. In list mode, the program cannot read the
compressed data from standard input or from other unseekable sources.

The default listing shows basic information about files, one file per line. To get
more detailed information, use also the --verbose option. For even more
information, use --verbose twice, but note that this may be slow, because getting
all the extra information requires many seeks. The width of verbose output exceeds
80 characters, so piping the output to e.g. less -S may be convenient if the
terminal isn't wide enough.

The exact output may vary between xz versions and different locales. For machine-
readable output, --robot --list should be used.

Operation modifiers
-k, --keep
Don't delete the input files.

-f, --force
This option has several effects:

· If the target file already exists, delete it before compressing or

· Compress or decompress even if the input is a symbolic link to a regular file,
has more than one hard link, or has the setuid, setgid, or sticky bit set. The
setuid, setgid, and sticky bits are not copied to the target file.

· When used with --decompress --stdout and xz cannot recognize the type of the
source file, copy the source file as is to standard output. This allows xzcat
--force to be used like cat(1) for files that have not been compressed with xz.
Note that in future, xz might support new compressed file formats, which may
make xz decompress more types of files instead of copying them as is to standard
output. --format=format can be used to restrict xz to decompress only a single
file format.

-c, --stdout, --to-stdout
Write the compressed or decompressed data to standard output instead of a file.
This implies --keep.

Decompress only the first .xz stream, and silently ignore possible remaining input
data following the stream. Normally such trailing garbage makes xz display an

xz never decompresses more than one stream from .lzma files or raw streams, but
this option still makes xz ignore the possible trailing data after the .lzma file
or raw stream.

This option has no effect if the operation mode is not --decompress or --test.

Disable creation of sparse files. By default, if decompressing into a regular
file, xz tries to make the file sparse if the decompressed data contains long
sequences of binary zeros. It also works when writing to standard output as long
as standard output is connected to a regular file and certain additional conditions
are met to make it safe. Creating sparse files may save disk space and speed up
the decompression by reducing the amount of disk I/O.

-S .suf, --suffix=.suf
When compressing, use .suf as the suffix for the target file instead of .xz or
.lzma. If not writing to standard output and the source file already has the
suffix .suf, a warning is displayed and the file is skipped.

When decompressing, recognize files with the suffix .suf in addition to files with
the .xz, .txz, .lzma, or .tlz suffix. If the source file has the suffix .suf, the
suffix is removed to get the target filename.

When compressing or decompressing raw streams (--format=raw), the suffix must
always be specified unless writing to standard output, because there is no default
suffix for raw streams.

Read the filenames to process from file; if file is omitted, filenames are read
from standard input. Filenames must be terminated with the newline character. A
dash (-) is taken as a regular filename; it doesn't mean standard input. If
filenames are given also as command line arguments, they are processed before the
filenames read from file.

This is identical to --files[=file] except that each filename must be terminated
with the null character.

Basic file format and compression options
-F format, --format=format
Specify the file format to compress or decompress:

auto This is the default. When compressing, auto is equivalent to xz. When
decompressing, the format of the input file is automatically detected. Note
that raw streams (created with --format=raw) cannot be auto-detected.

xz Compress to the .xz file format, or accept only .xz files when

lzma, alone
Compress to the legacy .lzma file format, or accept only .lzma files when
decompressing. The alternative name alone is provided for backwards
compatibility with LZMA Utils.

raw Compress or uncompress a raw stream (no headers). This is meant for
advanced users only. To decode raw streams, you need use --format=raw and
explicitly specify the filter chain, which normally would have been stored
in the container headers.

-C check, --check=check
Specify the type of the integrity check. The check is calculated from the
uncompressed data and stored in the .xz file. This option has an effect only when
compressing into the .xz format; the .lzma format doesn't support integrity checks.
The integrity check (if any) is verified when the .xz file is decompressed.

Supported check types:

none Don't calculate an integrity check at all. This is usually a bad idea.
This can be useful when integrity of the data is verified by other means

crc32 Calculate CRC32 using the polynomial from IEEE-802.3 (Ethernet).

crc64 Calculate CRC64 using the polynomial from ECMA-182. This is the default,
since it is slightly better than CRC32 at detecting damaged files and the
speed difference is negligible.

sha256 Calculate SHA-256. This is somewhat slower than CRC32 and CRC64.

Integrity of the .xz headers is always verified with CRC32. It is not possible to
change or disable it.

-0 ... -9
Select a compression preset level. The default is -6. If multiple preset levels
are specified, the last one takes effect. If a custom filter chain was already
specified, setting a compression preset level clears the custom filter chain.

The differences between the presets are more significant than with gzip(1) and
bzip2(1). The selected compression settings determine the memory requirements of
the decompressor, thus using a too high preset level might make it painful to
decompress the file on an old system with little RAM. Specifically, it's not a
good idea to blindly use -9 for everything like it often is with gzip(1) and

-0 ... -3
These are somewhat fast presets. -0 is sometimes faster than gzip -9 while
compressing much better. The higher ones often have speed comparable to
bzip2(1) with comparable or better compression ratio, although the results
depend a lot on the type of data being compressed.

-4 ... -6
Good to very good compression while keeping decompressor memory usage
reasonable even for old systems. -6 is the default, which is usually a good
choice e.g. for distributing files that need to be decompressible even on
systems with only 16 MiB RAM. (-5e or -6e may be worth considering too.
See --extreme.)

-7 ... -9
These are like -6 but with higher compressor and decompressor memory
requirements. These are useful only when compressing files bigger than
8 MiB, 16 MiB, and 32 MiB, respectively.

On the same hardware, the decompression speed is approximately a constant number of
bytes of compressed data per second. In other words, the better the compression,
the faster the decompression will usually be. This also means that the amount of
uncompressed output produced per second can vary a lot.

The following table summarises the features of the presets:

Preset DictSize CompCPU CompMem DecMem
-0 256 KiB 0 3 MiB 1 MiB
-1 1 MiB 1 9 MiB 2 MiB
-2 2 MiB 2 17 MiB 3 MiB
-3 4 MiB 3 32 MiB 5 MiB
-4 4 MiB 4 48 MiB 5 MiB
-5 8 MiB 5 94 MiB 9 MiB
-6 8 MiB 6 94 MiB 9 MiB
-7 16 MiB 6 186 MiB 17 MiB
-8 32 MiB 6 370 MiB 33 MiB
-9 64 MiB 6 674 MiB 65 MiB

Column descriptions:

· DictSize is the LZMA2 dictionary size. It is waste of memory to use a
dictionary bigger than the size of the uncompressed file. This is why it is
good to avoid using the presets -7 ... -9 when there's no real need for them.
At -6 and lower, the amount of memory wasted is usually low enough to not

· CompCPU is a simplified representation of the LZMA2 settings that affect
compression speed. The dictionary size affects speed too, so while CompCPU is
the same for levels -6 ... -9, higher levels still tend to be a little slower.
To get even slower and thus possibly better compression, see --extreme.

· CompMem contains the compressor memory requirements in the single-threaded mode.
It may vary slightly between xz versions. Memory requirements of some of the
future multithreaded modes may be dramatically higher than that of the single-
threaded mode.

· DecMem contains the decompressor memory requirements. That is, the compression
settings determine the memory requirements of the decompressor. The exact
decompressor memory usage is slighly more than the LZMA2 dictionary size, but
the values in the table have been rounded up to the next full MiB.

-e, --extreme
Use a slower variant of the selected compression preset level (-0 ... -9) to
hopefully get a little bit better compression ratio, but with bad luck this can
also make it worse. Decompressor memory usage is not affected, but compressor
memory usage increases a little at preset levels -0 ... -3.

Since there are two presets with dictionary sizes 4 MiB and 8 MiB, the presets -3e
and -5e use slightly faster settings (lower CompCPU) than -4e and -6e,
respectively. That way no two presets are identical.

Preset DictSize CompCPU CompMem DecMem
-0e 256 KiB 8 4 MiB 1 MiB
-1e 1 MiB 8 13 MiB 2 MiB
-2e 2 MiB 8 25 MiB 3 MiB
-3e 4 MiB 7 48 MiB 5 MiB
-4e 4 MiB 8 48 MiB 5 MiB
-5e 8 MiB 7 94 MiB 9 MiB
-6e 8 MiB 8 94 MiB 9 MiB
-7e 16 MiB 8 186 MiB 17 MiB
-8e 32 MiB 8 370 MiB 33 MiB
-9e 64 MiB 8 674 MiB 65 MiB

For example, there are a total of four presets that use 8 MiB dictionary, whose
order from the fastest to the slowest is -5, -6, -5e, and -6e.

--best These are somewhat misleading aliases for -0 and -9, respectively. These are
provided only for backwards compatibility with LZMA Utils. Avoid using these

When compressing to the .xz format, split the input data into blocks of size bytes.
The blocks are compressed independently from each other.

Set a memory usage limit for compression. If this option is specified multiple
times, the last one takes effect.

If the compression settings exceed the limit, xz will adjust the settings downwards
so that the limit is no longer exceeded and display a notice that automatic
adjustment was done. Such adjustments are not made when compressing with
--format=raw or if --no-adjust has been specified. In those cases, an error is
displayed and xz will exit with exit status 1.

The limit can be specified in multiple ways:

· The limit can be an absolute value in bytes. Using an integer suffix like MiB
can be useful. Example: --memlimit-compress=80MiB

· The limit can be specified as a percentage of total physical memory (RAM). This
can be useful especially when setting the XZ_DEFAULTS environment variable in a
shell initialization script that is shared between different computers. That
way the limit is automatically bigger on systems with more memory. Example:

· The limit can be reset back to its default value by setting it to 0. This is
currently equivalent to setting the limit to max (no memory usage limit). Once
multithreading support has been implemented, there may be a difference between 0
and max for the multithreaded case, so it is recommended to use 0 instead of max
until the details have been decided.

See also the section Memory usage.

Set a memory usage limit for decompression. This also affects the --list mode. If
the operation is not possible without exceeding the limit, xz will display an error
and decompressing the file will fail. See --memlimit-compress=limit for possible
ways to specify the limit.

-M limit, --memlimit=limit, --memory=limit
This is equivalent to specifying --memlimit-compress=limit

Display an error and exit if the compression settings exceed the memory usage
limit. The default is to adjust the settings downwards so that the memory usage
limit is not exceeded. Automatic adjusting is always disabled when creating raw
streams (--format=raw).

-T threads, --threads=threads
Specify the number of worker threads to use. The actual number of threads can be
less than threads if using more threads would exceed the memory usage limit.

Multithreaded compression and decompression are not implemented yet, so this option
has no effect for now.

As of writing (2010-09-27), it hasn't been decided if threads will be used by
default on multicore systems once support for threading has been implemented.
Comments are welcome. The complicating factor is that using many threads will
increase the memory usage dramatically. Note that if multithreading will be the
default, it will probably be done so that single-threaded and multithreaded modes
produce the same output, so compression ratio won't be significantly affected if
threading will be enabled by default.

Custom compressor filter chains
A custom filter chain allows specifying the compression settings in detail instead of
relying on the settings associated to the preset levels. When a custom filter chain is
specified, the compression preset level options (-0 ... -9 and --extreme) are silently

A filter chain is comparable to piping on the command line. When compressing, the
uncompressed input goes to the first filter, whose output goes to the next filter (if
any). The output of the last filter gets written to the compressed file. The maximum
number of filters in the chain is four, but typically a filter chain has only one or two

Many filters have limitations on where they can be in the filter chain: some filters can
work only as the last filter in the chain, some only as a non-last filter, and some work
in any position in the chain. Depending on the filter, this limitation is either inherent
to the filter design or exists to prevent security issues.

A custom filter chain is specified by using one or more filter options in the order they
are wanted in the filter chain. That is, the order of filter options is significant!
When decoding raw streams (--format=raw), the filter chain is specified in the same order
as it was specified when compressing.

Filters take filter-specific options as a comma-separated list. Extra commas in options
are ignored. Every option has a default value, so you need to specify only those you want
to change.

Add LZMA1 or LZMA2 filter to the filter chain. These filters can be used only as
the last filter in the chain.

LZMA1 is a legacy filter, which is supported almost solely due to the legacy .lzma
file format, which supports only LZMA1. LZMA2 is an updated version of LZMA1 to
fix some practical issues of LZMA1. The .xz format uses LZMA2 and doesn't support
LZMA1 at all. Compression speed and ratios of LZMA1 and LZMA2 are practically the

LZMA1 and LZMA2 share the same set of options:

Reset all LZMA1 or LZMA2 options to preset. Preset consist of an integer,
which may be followed by single-letter preset modifiers. The integer can be
from 0 to 9, matching the command line options -0 ... -9. The only
supported modifier is currently e, which matches --extreme. The default
preset is 6, from which the default values for the rest of the LZMA1 or
LZMA2 options are taken.

Dictionary (history buffer) size indicates how many bytes of the recently
processed uncompressed data is kept in memory. The algorithm tries to find
repeating byte sequences (matches) in the uncompressed data, and replace
them with references to the data currently in the dictionary. The bigger
the dictionary, the higher is the chance to find a match. Thus, increasing
dictionary size usually improves compression ratio, but a dictionary bigger
than the uncompressed file is waste of memory.

Typical dictionary size is from 64 KiB to 64 MiB. The minimum is 4 KiB.
The maximum for compression is currently 1.5 GiB (1536 MiB). The
decompressor already supports dictionaries up to one byte less than 4 GiB,
which is the maximum for the LZMA1 and LZMA2 stream formats.

Dictionary size and match finder (mf) together determine the memory usage of
the LZMA1 or LZMA2 encoder. The same (or bigger) dictionary size is
required for decompressing that was used when compressing, thus the memory
usage of the decoder is determined by the dictionary size used when
compressing. The .xz headers store the dictionary size either as 2^n or 2^n
+ 2^(n-1), so these sizes are somewhat preferred for compression. Other
sizes will get rounded up when stored in the .xz headers.

lc=lc Specify the number of literal context bits. The minimum is 0 and the
maximum is 4; the default is 3. In addition, the sum of lc and lp must not
exceed 4.

All bytes that cannot be encoded as matches are encoded as literals. That
is, literals are simply 8-bit bytes that are encoded one at a time.

The literal coding makes an assumption that the highest lc bits of the
previous uncompressed byte correlate with the next byte. E.g. in typical
English text, an upper-case letter is often followed by a lower-case letter,
and a lower-case letter is usually followed by another lower-case letter.
In the US-ASCII character set, the highest three bits are 010 for upper-case
letters and 011 for lower-case letters. When lc is at least 3, the literal
coding can take advantage of this property in the uncompressed data.

The default value (3) is usually good. If you want maximum compression,
test lc=4. Sometimes it helps a little, and sometimes it makes compression
worse. If it makes it worse, test e.g. lc=2 too.

lp=lp Specify the number of literal position bits. The minimum is 0 and the
maximum is 4; the default is 0.

Lp affects what kind of alignment in the uncompressed data is assumed when
encoding literals. See pb below for more information about alignment.

pb=pb Specify the number of position bits. The minimum is 0 and the maximum is 4;
the default is 2.

Pb affects what kind of alignment in the uncompressed data is assumed in
general. The default means four-byte alignment (2^pb=2^2=4), which is often
a good choice when there's no better guess.

When the aligment is known, setting pb accordingly may reduce the file size
a little. E.g. with text files having one-byte alignment (US-ASCII,
ISO-8859-*, UTF-8), setting pb=0 can improve compression slightly. For
UTF-16 text, pb=1 is a good choice. If the alignment is an odd number like
3 bytes, pb=0 might be the best choice.

Even though the assumed alignment can be adjusted with pb and lp, LZMA1 and
LZMA2 still slightly favor 16-byte alignment. It might be worth taking into
account when designing file formats that are likely to be often compressed
with LZMA1 or LZMA2.

mf=mf Match finder has a major effect on encoder speed, memory usage, and
compression ratio. Usually Hash Chain match finders are faster than Binary
Tree match finders. The default depends on the preset: 0 uses hc3, 1-3 use
hc4, and the rest use bt4.

The following match finders are supported. The memory usage formulas below
are rough approximations, which are closest to the reality when dict is a
power of two.

hc3 Hash Chain with 2- and 3-byte hashing
Minimum value for nice: 3
Memory usage:
dict * 7.5 (if dict <= 16 MiB);
dict * 5.5 + 64 MiB (if dict > 16 MiB)

hc4 Hash Chain with 2-, 3-, and 4-byte hashing
Minimum value for nice: 4
Memory usage:
dict * 7.5 (if dict <= 32 MiB);
dict * 6.5 (if dict > 32 MiB)

bt2 Binary Tree with 2-byte hashing
Minimum value for nice: 2
Memory usage: dict * 9.5

bt3 Binary Tree with 2- and 3-byte hashing
Minimum value for nice: 3
Memory usage:
dict * 11.5 (if dict <= 16 MiB);
dict * 9.5 + 64 MiB (if dict > 16 MiB)

bt4 Binary Tree with 2-, 3-, and 4-byte hashing
Minimum value for nice: 4
Memory usage:
dict * 11.5 (if dict <= 32 MiB);
dict * 10.5 (if dict > 32 MiB)

Compression mode specifies the method to analyze the data produced by the
match finder. Supported modes are fast and normal. The default is fast for
presets 0-3 and normal for presets 4-9.

Usually fast is used with Hash Chain match finders and normal with Binary
Tree match finders. This is also what the presets do.

Specify what is considered to be a nice length for a match. Once a match of
at least nice bytes is found, the algorithm stops looking for possibly
better matches.

Nice can be 2-273 bytes. Higher values tend to give better compression
ratio at the expense of speed. The default depends on the preset.

Specify the maximum search depth in the match finder. The default is the
special value of 0, which makes the compressor determine a reasonable depth
from mf and nice.

Reasonable depth for Hash Chains is 4-100 and 16-1000 for Binary Trees.
Using very high values for depth can make the encoder extremely slow with
some files. Avoid setting the depth over 1000 unless you are prepared to
interrupt the compression in case it is taking far too long.

When decoding raw streams (--format=raw), LZMA2 needs only the dictionary size.
LZMA1 needs also lc, lp, and pb.

Add a branch/call/jump (BCJ) filter to the filter chain. These filters can be used
only as a non-last filter in the filter chain.

A BCJ filter converts relative addresses in the machine code to their absolute
counterparts. This doesn't change the size of the data, but it increases
redundancy, which can help LZMA2 to produce 0-15 % smaller .xz file. The BCJ
filters are always reversible, so using a BCJ filter for wrong type of data doesn't
cause any data loss, although it may make the compression ratio slightly worse.

It is fine to apply a BCJ filter on a whole executable; there's no need to apply it
only on the executable section. Applying a BCJ filter on an archive that contains
both executable and non-executable files may or may not give good results, so it
generally isn't good to blindly apply a BCJ filter when compressing binary packages
for distribution.

These BCJ filters are very fast and use insignificant amount of memory. If a BCJ
filter improves compression ratio of a file, it can improve decompression speed at
the same time. This is because, on the same hardware, the decompression speed of
LZMA2 is roughly a fixed number of bytes of compressed data per second.

These BCJ filters have known problems related to the compression ratio:

· Some types of files containing executable code (e.g. object files, static
libraries, and Linux kernel modules) have the addresses in the instructions
filled with filler values. These BCJ filters will still do the address
conversion, which will make the compression worse with these files.

· Applying a BCJ filter on an archive containing multiple similar executables can
make the compression ratio worse than not using a BCJ filter. This is because
the BCJ filter doesn't detect the boundaries of the executable files, and
doesn't reset the address conversion counter for each executable.

Both of the above problems will be fixed in the future in a new filter. The old
BCJ filters will still be useful in embedded systems, because the decoder of the
new filter will be bigger and use more memory.

Different instruction sets have have different alignment:

Filter Alignment Notes
x86 1 32-bit or 64-bit x86
PowerPC 4 Big endian only
ARM 4 Little endian only
ARM-Thumb 2 Little endian only
IA-64 16 Big or little endian
SPARC 4 Big or little endian

Since the BCJ-filtered data is usually compressed with LZMA2, the compression ratio
may be improved slightly if the LZMA2 options are set to match the alignment of the
selected BCJ filter. For example, with the IA-64 filter, it's good to set pb=4
with LZMA2 (2^4=16). The x86 filter is an exception; it's usually good to stick to
LZMA2's default four-byte alignment when compressing x86 executables.

All BCJ filters support the same options:

Specify the start offset that is used when converting between relative and
absolute addresses. The offset must be a multiple of the alignment of the
filter (see the table above). The default is zero. In practice, the
default is good; specifying a custom offset is almost never useful.

Add the Delta filter to the filter chain. The Delta filter can be only used as a
non-last filter in the filter chain.

Currently only simple byte-wise delta calculation is supported. It can be useful
when compressing e.g. uncompressed bitmap images or uncompressed PCM audio.
However, special purpose algorithms may give significantly better results than
Delta + LZMA2. This is true especially with audio, which compresses faster and
better e.g. with flac(1).

Supported options:

Specify the distance of the delta calculation in bytes. distance must be
1-256. The default is 1.

For example, with dist=2 and eight-byte input A1 B1 A2 B3 A3 B5 A4 B7, the
output will be A1 B1 01 02 01 02 01 02.

Other options
-q, --quiet
Suppress warnings and notices. Specify this twice to suppress errors too. This
option has no effect on the exit status. That is, even if a warning was
suppressed, the exit status to indicate a warning is still used.

-v, --verbose
Be verbose. If standard error is connected to a terminal, xz will display a
progress indicator. Specifying --verbose twice will give even more verbose output.

The progress indicator shows the following information:

· Completion percentage is shown if the size of the input file is known. That is,
the percentage cannot be shown in pipes.

· Amount of compressed data produced (compressing) or consumed (decompressing).

· Amount of uncompressed data consumed (compressing) or produced (decompressing).

· Compression ratio, which is calculated by dividing the amount of compressed data
processed so far by the amount of uncompressed data processed so far.

· Compression or decompression speed. This is measured as the amount of
uncompressed data consumed (compression) or produced (decompression) per second.
It is shown after a few seconds have passed since xz started processing the

· Elapsed time in the format M:SS or H:MM:SS.

· Estimated remaining time is shown only when the size of the input file is known
and a couple of seconds have already passed since xz started processing the
file. The time is shown in a less precise format which never has any colons,
e.g. 2 min 30 s.

When standard error is not a terminal, --verbose will make xz print the filename,
compressed size, uncompressed size, compression ratio, and possibly also the speed
and elapsed time on a single line to standard error after compressing or
decompressing the file. The speed and elapsed time are included only when the
operation took at least a few seconds. If the operation didn't finish, e.g. due to
user interruption, also the completion percentage is printed if the size of the
input file is known.

-Q, --no-warn
Don't set the exit status to 2 even if a condition worth a warning was detected.
This option doesn't affect the verbosity level, thus both --quiet and --no-warn
have to be used to not display warnings and to not alter the exit status.

Print messages in a machine-parsable format. This is intended to ease writing
frontends that want to use xz instead of liblzma, which may be the case with
various scripts. The output with this option enabled is meant to be stable across
xz releases. See the section ROBOT MODE for details.

Display, in human-readable format, how much physical memory (RAM) xz thinks the
system has and the memory usage limits for compression and decompression, and exit

-h, --help
Display a help message describing the most commonly used options, and exit

-H, --long-help
Display a help message describing all features of xz, and exit successfully

-V, --version
Display the version number of xz and liblzma in human readable format. To get
machine-parsable output, specify --robot before --version.


The robot mode is activated with the --robot option. It makes the output of xz easier to
parse by other programs. Currently --robot is supported only together with --version,
--info-memory, and --list. It will be supported for normal compression and decompression
in the future.

xz --robot --version will print the version number of xz and liblzma in the following


X Major version.

YYY Minor version. Even numbers are stable. Odd numbers are alpha or beta versions.

ZZZ Patch level for stable releases or just a counter for development releases.

S Stability. 0 is alpha, 1 is beta, and 2 is stable. S should be always 2 when YYY
is even.

XYYYZZZS are the same on both lines if xz and liblzma are from the same XZ Utils release.

Examples: 4.999.9beta is 49990091 and 5.0.0 is 50000002.

Memory limit information
xz --robot --info-memory prints a single line with three tab-separated columns:

1. Total amount of physical memory (RAM) in bytes

2. Memory usage limit for compression in bytes. A special value of zero indicates the
default setting, which for single-threaded mode is the same as no limit.

3. Memory usage limit for decompression in bytes. A special value of zero indicates the
default setting, which for single-threaded mode is the same as no limit.

In the future, the output of xz --robot --info-memory may have more columns, but never
more than a single line.

List mode
xz --robot --list uses tab-separated output. The first column of every line has a string
that indicates the type of the information found on that line:

name This is always the first line when starting to list a file. The second column on
the line is the filename.

file This line contains overall information about the .xz file. This line is always
printed after the name line.

stream This line type is used only when --verbose was specified. There are as many stream
lines as there are streams in the .xz file.

block This line type is used only when --verbose was specified. There are as many block
lines as there are blocks in the .xz file. The block lines are shown after all the
stream lines; different line types are not interleaved.

This line type is used only when --verbose was specified twice. This line is
printed after all block lines. Like the file line, the summary line contains
overall information about the .xz file.

totals This line is always the very last line of the list output. It shows the total
counts and sizes.

The columns of the file lines:
2. Number of streams in the file
3. Total number of blocks in the stream(s)
4. Compressed size of the file
5. Uncompressed size of the file
6. Compression ratio, for example 0.123. If ratio is over 9.999, three dashes
(---) are displayed instead of the ratio.
7. Comma-separated list of integrity check names. The following strings are used
for the known check types: None, CRC32, CRC64, and SHA-256. For unknown check
types, Unknown-N is used, where N is the Check ID as a decimal number (one or
two digits).
8. Total size of stream padding in the file

The columns of the stream lines:
2. Stream number (the first stream is 1)
3. Number of blocks in the stream
4. Compressed start offset
5. Uncompressed start offset
6. Compressed size (does not include stream padding)
7. Uncompressed size
8. Compression ratio
9. Name of the integrity check
10. Size of stream padding

The columns of the block lines:
2. Number of the stream containing this block
3. Block number relative to the beginning of the stream (the first block is 1)
4. Block number relative to the beginning of the file
5. Compressed start offset relative to the beginning of the file
6. Uncompressed start offset relative to the beginning of the file
7. Total compressed size of the block (includes headers)
8. Uncompressed size
9. Compression ratio
10. Name of the integrity check

If --verbose was specified twice, additional columns are included on the block lines.
These are not displayed with a single --verbose, because getting this information requires
many seeks and can thus be slow:
11. Value of the integrity check in hexadecimal
12. Block header size
13. Block flags: c indicates that compressed size is present, and u indicates that
uncompressed size is present. If the flag is not set, a dash (-) is shown
instead to keep the string length fixed. New flags may be added to the end of
the string in the future.
14. Size of the actual compressed data in the block (this excludes the block
header, block padding, and check fields)
15. Amount of memory (in bytes) required to decompress this block with this xz
16. Filter chain. Note that most of the options used at compression time cannot be
known, because only the options that are needed for decompression are stored in
the .xz headers.

The columns of the summary lines:
2. Amount of memory (in bytes) required to decompress this file with this xz
3. yes or no indicating if all block headers have both compressed size and
uncompressed size stored in them
Since xz 5.1.2alpha:
4. Minimum xz version required to decompress the file

The columns of the totals line:
2. Number of streams
3. Number of blocks
4. Compressed size
5. Uncompressed size
6. Average compression ratio
7. Comma-separated list of integrity check names that were present in the files
8. Stream padding size
9. Number of files. This is here to keep the order of the earlier columns the
same as on file lines.

If --verbose was specified twice, additional columns are included on the totals line:
10. Maximum amount of memory (in bytes) required to decompress the files with this
xz version
11. yes or no indicating if all block headers have both compressed size and
uncompressed size stored in them
Since xz 5.1.2alpha:
12. Minimum xz version required to decompress the file

Future versions may add new line types and new columns can be added to the existing line
types, but the existing columns won't be changed.


0 All is good.

1 An error occurred.

2 Something worth a warning occurred, but no actual errors occurred.

Notices (not warnings or errors) printed on standard error don't affect the exit status.


xz parses space-separated lists of options from the environment variables XZ_DEFAULTS and
XZ_OPT, in this order, before parsing the options from the command line. Note that only
options are parsed from the environment variables; all non-options are silently ignored.
Parsing is done with getopt_long(3) which is used also for the command line arguments.

User-specific or system-wide default options. Typically this is set in a shell
initialization script to enable xz's memory usage limiter by default. Excluding
shell initialization scripts and similar special cases, scripts must never set or

XZ_OPT This is for passing options to xz when it is not possible to set the options
directly on the xz command line. This is the case e.g. when xz is run by a script
or tool, e.g. GNU tar(1):

XZ_OPT=-2v tar caf foo.tar.xz foo

Scripts may use XZ_OPT e.g. to set script-specific default compression options. It
is still recommended to allow users to override XZ_OPT if that is reasonable, e.g.
in sh(1) scripts one may use something like this:

export XZ_OPT


The command line syntax of xz is practically a superset of lzma, unlzma, and lzcat as
found from LZMA Utils 4.32.x. In most cases, it is possible to replace LZMA Utils with XZ
Utils without breaking existing scripts. There are some incompatibilities though, which
may sometimes cause problems.

Compression preset levels
The numbering of the compression level presets is not identical in xz and LZMA Utils. The
most important difference is how dictionary sizes are mapped to different presets.
Dictionary size is roughly equal to the decompressor memory usage.

Level xz LZMA Utils
-0 256 KiB N/A
-1 1 MiB 64 KiB
-2 2 MiB 1 MiB
-3 4 MiB 512 KiB
-4 4 MiB 1 MiB
-5 8 MiB 2 MiB
-6 8 MiB 4 MiB
-7 16 MiB 8 MiB
-8 32 MiB 16 MiB
-9 64 MiB 32 MiB

The dictionary size differences affect the compressor memory usage too, but there are some
other differences between LZMA Utils and XZ Utils, which make the difference even bigger:

Level xz LZMA Utils 4.32.x
-0 3 MiB N/A
-1 9 MiB 2 MiB
-2 17 MiB 12 MiB
-3 32 MiB 12 MiB
-4 48 MiB 16 MiB
-5 94 MiB 26 MiB
-6 94 MiB 45 MiB
-7 186 MiB 83 MiB
-8 370 MiB 159 MiB
-9 674 MiB 311 MiB

The default preset level in LZMA Utils is -7 while in XZ Utils it is -6, so both use an 8
MiB dictionary by default.

Streamed vs. non-streamed .lzma files
The uncompressed size of the file can be stored in the .lzma header. LZMA Utils does that
when compressing regular files. The alternative is to mark that uncompressed size is
unknown and use end-of-payload marker to indicate where the decompressor should stop.
LZMA Utils uses this method when uncompressed size isn't known, which is the case for
example in pipes.

xz supports decompressing .lzma files with or without end-of-payload marker, but all .lzma
files created by xz will use end-of-payload marker and have uncompressed size marked as
unknown in the .lzma header. This may be a problem in some uncommon situations. For
example, a .lzma decompressor in an embedded device might work only with files that have
known uncompressed size. If you hit this problem, you need to use LZMA Utils or LZMA SDK
to create .lzma files with known uncompressed size.

Unsupported .lzma files
The .lzma format allows lc values up to 8, and lp values up to 4. LZMA Utils can
decompress files with any lc and lp, but always creates files with lc=3 and lp=0.
Creating files with other lc and lp is possible with xz and with LZMA SDK.

The implementation of the LZMA1 filter in liblzma requires that the sum of lc and lp must
not exceed 4. Thus, .lzma files, which exceed this limitation, cannot be decompressed
with xz.

LZMA Utils creates only .lzma files which have a dictionary size of 2^n (a power of 2) but
accepts files with any dictionary size. liblzma accepts only .lzma files which have a
dictionary size of 2^n or 2^n + 2^(n-1). This is to decrease false positives when
detecting .lzma files.

These limitations shouldn't be a problem in practice, since practically all .lzma files
have been compressed with settings that liblzma will accept.

Trailing garbage
When decompressing, LZMA Utils silently ignore everything after the first .lzma stream.
In most situations, this is a bug. This also means that LZMA Utils don't support
decompressing concatenated .lzma files.

If there is data left after the first .lzma stream, xz considers the file to be corrupt
unless --single-stream was used. This may break obscure scripts which have assumed that
trailing garbage is ignored.


Compressed output may vary
The exact compressed output produced from the same uncompressed input file may vary
between XZ Utils versions even if compression options are identical. This is because the
encoder can be improved (faster or better compression) without affecting the file format.
The output can vary even between different builds of the same XZ Utils version, if
different build options are used.

The above means that implementing --rsyncable to create rsyncable .xz files is not going
to happen without freezing a part of the encoder implementation, which can then be used
with --rsyncable.

Embedded .xz decompressors
Embedded .xz decompressor implementations like XZ Embedded don't necessarily support files
created with integrity check types other than none and crc32. Since the default is
--check=crc64, you must use --check=none or --check=crc32 when creating files for embedded

Outside embedded systems, all .xz format decompressors support all the check types, or at
least are able to decompress the file without verifying the integrity check if the
particular check is not supported.

XZ Embedded supports BCJ filters, but only with the default start offset.


Compress the file foo into foo.xz using the default compression level (-6), and remove foo
if compression is successful:

xz foo

Decompress bar.xz into bar and don't remove bar.xz even if decompression is successful:

xz -dk bar.xz

Create baz.tar.xz with the preset -4e (-4 --extreme), which is slower than e.g. the
default -6, but needs less memory for compression and decompression (48 MiB and 5 MiB,

tar cf - baz | xz -4e > baz.tar.xz

A mix of compressed and uncompressed files can be decompressed to standard output with a
single command:

xz -dcf a.txt b.txt.xz c.txt d.txt.lzma > abcd.txt

Parallel compression of many files
On GNU and *BSD, find(1) and xargs(1) can be used to parallelize compression of many

find . -type f \! -name '*.xz' -print0 \
| xargs -0r -P4 -n16 xz -T1

The -P option to xargs(1) sets the number of parallel xz processes. The best value for
the -n option depends on how many files there are to be compressed. If there are only a
couple of files, the value should probably be 1; with tens of thousands of files, 100 or
even more may be appropriate to reduce the number of xz processes that xargs(1) will
eventually create.

The option -T1 for xz is there to force it to single-threaded mode, because xargs(1) is
used to control the amount of parallelization.

Robot mode
Calculate how many bytes have been saved in total after compressing multiple files:

xz --robot --list *.xz | awk '/^totals/{print $5-$4}'

A script may want to know that it is using new enough xz. The following sh(1) script
checks that the version number of the xz tool is at least 5.0.0. This method is
compatible with old beta versions, which didn't support the --robot option:

if ! eval "$(xz --robot --version 2> /dev/null)" ||
[ "$XZ_VERSION" -lt 50000002 ]; then
echo "Your xz is too old."

Set a memory usage limit for decompression using XZ_OPT, but if a limit has already been
set, don't increase it:

NEWLIM=$((123 << 20)) # 123 MiB
OLDLIM=$(xz --robot --info-memory | cut -f3)
if [ $OLDLIM -eq 0 -o $OLDLIM -gt $NEWLIM ]; then
XZ_OPT="$XZ_OPT --memlimit-decompress=$NEWLIM"
export XZ_OPT

Custom compressor filter chains
The simplest use for custom filter chains is customizing a LZMA2 preset. This can be
useful, because the presets cover only a subset of the potentially useful combinations of
compression settings.

The CompCPU columns of the tables from the descriptions of the options -0 ... -9 and
--extreme are useful when customizing LZMA2 presets. Here are the relevant parts
collected from those two tables:

Preset CompCPU
-0 0
-1 1
-2 2
-3 3
-4 4
-5 5
-6 6
-5e 7
-6e 8

If you know that a file requires somewhat big dictionary (e.g. 32 MiB) to compress well,
but you want to compress it quicker than xz -8 would do, a preset with a low CompCPU value
(e.g. 1) can be modified to use a bigger dictionary:

xz --lzma2=preset=1,dict=32MiB foo.tar

With certain files, the above command may be faster than xz -6 while compressing
significantly better. However, it must be emphasized that only some files benefit from a
big dictionary while keeping the CompCPU value low. The most obvious situation, where a
big dictionary can help a lot, is an archive containing very similar files of at least a
few megabytes each. The dictionary size has to be significantly bigger than any
individual file to allow LZMA2 to take full advantage of the similarities between
consecutive files.

If very high compressor and decompressor memory usage is fine, and the file being
compressed is at least several hundred megabytes, it may be useful to use an even bigger
dictionary than the 64 MiB that xz -9 would use:

xz -vv --lzma2=dict=192MiB big_foo.tar

Using -vv (--verbose --verbose) like in the above example can be useful to see the memory
requirements of the compressor and decompressor. Remember that using a dictionary bigger
than the size of the uncompressed file is waste of memory, so the above command isn't
useful for small files.

Sometimes the compression time doesn't matter, but the decompressor memory usage has to be
kept low e.g. to make it possible to decompress the file on an embedded system. The
following command uses -6e (-6 --extreme) as a base and sets the dictionary to only
64 KiB. The resulting file can be decompressed with XZ Embedded (that's why there is
--check=crc32) using about 100 KiB of memory.

xz --check=crc32 --lzma2=preset=6e,dict=64KiB foo

If you want to squeeze out as many bytes as possible, adjusting the number of literal
context bits (lc) and number of position bits (pb) can sometimes help. Adjusting the
number of literal position bits (lp) might help too, but usually lc and pb are more
important. E.g. a source code archive contains mostly US-ASCII text, so something like
the following might give slightly (like 0.1 %) smaller file than xz -6e (try also without

xz --lzma2=preset=6e,pb=0,lc=4 source_code.tar

Using another filter together with LZMA2 can improve compression with certain file types.
E.g. to compress a x86-32 or x86-64 shared library using the x86 BCJ filter:

xz --x86 --lzma2 libfoo.so

Note that the order of the filter options is significant. If --x86 is specified after
--lzma2, xz will give an error, because there cannot be any filter after LZMA2, and also
because the x86 BCJ filter cannot be used as the last filter in the chain.

The Delta filter together with LZMA2 can give good results with bitmap images. It should
usually beat PNG, which has a few more advanced filters than simple delta but uses Deflate
for the actual compression.

The image has to be saved in uncompressed format, e.g. as uncompressed TIFF. The distance
parameter of the Delta filter is set to match the number of bytes per pixel in the image.
E.g. 24-bit RGB bitmap needs dist=3, and it is also good to pass pb=0 to LZMA2 to
accommodate the three-byte alignment:

xz --delta=dist=3 --lzma2=pb=0 foo.tiff

If multiple images have been put into a single archive (e.g. .tar), the Delta filter will
work on that too as long as all images have the same number of bytes per pixel.

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