1XZ(1)                              XZ Utils                              XZ(1)
2
3
4

NAME

6       xz,  unxz,  xzcat, lzma, unlzma, lzcat - Compress or decompress .xz and
7       .lzma files
8

SYNOPSIS

10       xz [option...]  [file...]
11

COMMAND ALIASES

13       unxz is equivalent to xz --decompress.
14       xzcat is equivalent to xz --decompress --stdout.
15       lzma is equivalent to xz --format=lzma.
16       unlzma is equivalent to xz --format=lzma --decompress.
17       lzcat is equivalent to xz --format=lzma --decompress --stdout.
18
19       When writing scripts that need to decompress files, it  is  recommended
20       to  always use the name xz with appropriate arguments (xz -d or xz -dc)
21       instead of the names unxz and xzcat.
22

DESCRIPTION

24       xz is a general-purpose data compression tool with command line  syntax
25       similar  to  gzip(1)  and  bzip2(1).  The native file format is the .xz
26       format, but the legacy .lzma format used by LZMA  Utils  and  raw  com‐
27       pressed streams with no container format headers are also supported.
28
29       xz compresses or decompresses each file according to the selected oper‐
30       ation mode.  If no files are given or file is -, xz reads from standard
31       input and writes the processed data to standard output.  xz will refuse
32       (display an error and skip the file) to write compressed data to  stan‐
33       dard  output  if  it  is a terminal.  Similarly, xz will refuse to read
34       compressed data from standard input if it is a terminal.
35
36       Unless --stdout is specified, files other than - are written to  a  new
37       file whose name is derived from the source file name:
38
39       ·  When  compressing,  the  suffix  of  the  target file format (.xz or
40          .lzma) is appended to the source filename to get  the  target  file‐
41          name.
42
43       ·  When  decompressing,  the  .xz  or  .lzma suffix is removed from the
44          filename to get the target filename.  xz also  recognizes  the  suf‐
45          fixes .txz and .tlz, and replaces them with the .tar suffix.
46
47       If  the  target file already exists, an error is displayed and the file
48       is skipped.
49
50       Unless writing to standard output, xz will display a warning  and  skip
51       the file if any of the following applies:
52
53       ·  File  is  not  a regular file.  Symbolic links are not followed, and
54          thus they are not considered to be regular files.
55
56       ·  File has more than one hard link.
57
58       ·  File has setuid, setgid, or sticky bit set.
59
60       ·  The operation mode is set to compress and the  file  already  has  a
61          suffix  of  the  target file format (.xz or .txz when compressing to
62          the .xz format, and .lzma or .tlz when compressing to the .lzma for‐
63          mat).
64
65       ·  The  operation mode is set to decompress and the file doesn't have a
66          suffix of any of the supported file formats (.xz,  .txz,  .lzma,  or
67          .tlz).
68
69       After successfully compressing or decompressing the file, xz copies the
70       owner, group, permissions, access time, and modification time from  the
71       source  file  to the target file.  If copying the group fails, the per‐
72       missions are modified so that the target file doesn't become accessible
73       to  users  who  didn't  have  permission to access the source file.  xz
74       doesn't support copying other metadata like  access  control  lists  or
75       extended attributes yet.
76
77       Once  the  target file has been successfully closed, the source file is
78       removed unless --keep was specified.  The source file is never  removed
79       if the output is written to standard output.
80
81       Sending  SIGINFO  or  SIGUSR1 to the xz process makes it print progress
82       information to standard error.  This has only limited  use  since  when
83       standard error is a terminal, using --verbose will display an automati‐
84       cally updating progress indicator.
85
86   Memory usage
87       The memory usage of xz varies from a few hundred kilobytes  to  several
88       gigabytes  depending  on  the  compression settings.  The settings used
89       when compressing a file determine the memory requirements of the decom‐
90       pressor.  Typically the decompressor needs 5 % to 20 % of the amount of
91       memory that the compressor needed when creating the file.  For example,
92       decompressing  a  file  created with xz -9 currently requires 65 MiB of
93       memory.  Still, it is possible to have .xz files that  require  several
94       gigabytes of memory to decompress.
95
96       Especially  users  of  older  systems  may find the possibility of very
97       large memory usage annoying.  To prevent  uncomfortable  surprises,  xz
98       has  a  built-in  memory  usage  limiter, which is disabled by default.
99       While some operating systems provide ways to limit the memory usage  of
100       processes,  relying  on  it  wasn't  deemed to be flexible enough (e.g.
101       using ulimit(1) to limit virtual memory tends to cripple mmap(2)).
102
103       The memory usage limiter can be enabled with the  command  line  option
104       --memlimit=limit.  Often it is more convenient to enable the limiter by
105       default  by  setting  the  environment   variable   XZ_DEFAULTS,   e.g.
106       XZ_DEFAULTS=--memlimit=150MiB.   It is possible to set the limits sepa‐
107       rately for  compression  and  decompression  by  using  --memlimit-com‐
108       press=limit  and  --memlimit-decompress=limit.  Using these two options
109       outside XZ_DEFAULTS is rarely useful because a single run of xz  cannot
110       do  both  compression  and  decompression  and  --memlimit=limit (or -M
111       limit) is shorter to type on the command line.
112
113       If the specified memory usage limit is exceeded when decompressing,  xz
114       will  display  an  error  and decompressing the file will fail.  If the
115       limit is exceeded when compressing, xz will try to scale  the  settings
116       down  so that the limit is no longer exceeded (except when using --for‐
117       mat=raw or --no-adjust).  This way the operation won't fail unless  the
118       limit is very small.  The scaling of the settings is done in steps that
119       don't match the compression level presets, e.g. if the  limit  is  only
120       slightly  less than the amount required for xz -9, the settings will be
121       scaled down only a little, not all the way down to xz -8.
122
123   Concatenation and padding with .xz files
124       It is possible to concatenate .xz files as is.  xz will decompress such
125       files as if they were a single .xz file.
126
127       It  is  possible  to  insert  padding between the concatenated parts or
128       after the last part.  The padding must consist of null  bytes  and  the
129       size of the padding must be a multiple of four bytes.  This can be use‐
130       ful e.g. if the .xz file is stored on a medium that measures file sizes
131       in 512-byte blocks.
132
133       Concatenation  and  padding  are  not  allowed  with .lzma files or raw
134       streams.
135

OPTIONS

137   Integer suffixes and special values
138       In most places where an integer argument is expected, an optional  suf‐
139       fix  is  supported to easily indicate large integers.  There must be no
140       space between the integer and the suffix.
141
142       KiB    Multiply the integer by 1,024 (2^10).  Ki, k, kB, K, and KB  are
143              accepted as synonyms for KiB.
144
145       MiB    Multiply  the integer by 1,048,576 (2^20).  Mi, m, M, and MB are
146              accepted as synonyms for MiB.
147
148       GiB    Multiply the integer by 1,073,741,824 (2^30).  Gi, g, G, and  GB
149              are accepted as synonyms for GiB.
150
151       The special value max can be used to indicate the maximum integer value
152       supported by the option.
153
154   Operation mode
155       If multiple operation mode  options  are  given,  the  last  one  takes
156       effect.
157
158       -z, --compress
159              Compress.   This is the default operation mode when no operation
160              mode option is specified and no other operation mode is  implied
161              from the command name (for example, unxz implies --decompress).
162
163       -d, --decompress, --uncompress
164              Decompress.
165
166       -t, --test
167              Test  the integrity of compressed files.  This option is equiva‐
168              lent to --decompress --stdout except that the decompressed  data
169              is  discarded  instead  of being written to standard output.  No
170              files are created or removed.
171
172       -l, --list
173              Print information about compressed files.  No uncompressed  out‐
174              put  is  produced, and no files are created or removed.  In list
175              mode, the program cannot read the compressed data from  standard
176              input or from other unseekable sources.
177
178              The  default  listing  shows  basic information about files, one
179              file per line.  To get more detailed information, use  also  the
180              --verbose  option.   For  even  more  information, use --verbose
181              twice, but note that this may be slow, because getting  all  the
182              extra  information  requires  many  seeks.  The width of verbose
183              output exceeds 80 characters,  so  piping  the  output  to  e.g.
184              less -S may be convenient if the terminal isn't wide enough.
185
186              The  exact  output  may  vary  between xz versions and different
187              locales.  For machine-readable output, --robot --list should  be
188              used.
189
190   Operation modifiers
191       -k, --keep
192              Don't delete the input files.
193
194       -f, --force
195              This option has several effects:
196
197              ·  If the target file already exists, delete it before compress‐
198                 ing or decompressing.
199
200              ·  Compress or decompress even if the input is a  symbolic  link
201                 to  a  regular  file, has more than one hard link, or has the
202                 setuid, setgid, or sticky bit set.  The setuid,  setgid,  and
203                 sticky bits are not copied to the target file.
204
205              ·  When  used with --decompress --stdout and xz cannot recognize
206                 the type of the source file, copy the source file  as  is  to
207                 standard  output.   This allows xzcat --force to be used like
208                 cat(1) for files that have not been compressed with xz.  Note
209                 that in future, xz might support new compressed file formats,
210                 which may make xz decompress more types of files  instead  of
211                 copying  them  as is to standard output.  --format=format can
212                 be used to restrict xz to decompress only a single file  for‐
213                 mat.
214
215       -c, --stdout, --to-stdout
216              Write  the  compressed  or  decompressed data to standard output
217              instead of a file.  This implies --keep.
218
219       --single-stream
220              Decompress only the first .xz stream, and silently ignore possi‐
221              ble  remaining  input  data following the stream.  Normally such
222              trailing garbage makes xz display an error.
223
224              xz never decompresses more than one stream from .lzma  files  or
225              raw  streams, but this option still makes xz ignore the possible
226              trailing data after the .lzma file or raw stream.
227
228              This option has no effect if the operation mode is not  --decom‐
229              press or --test.
230
231       --no-sparse
232              Disable  creation of sparse files.  By default, if decompressing
233              into a regular file, xz tries to make the  file  sparse  if  the
234              decompressed  data  contains long sequences of binary zeros.  It
235              also works when writing to standard output as long  as  standard
236              output  is  connected  to  a regular file and certain additional
237              conditions are met to make it safe.  Creating sparse  files  may
238              save  disk  space and speed up the decompression by reducing the
239              amount of disk I/O.
240
241       -S .suf, --suffix=.suf
242              When compressing, use .suf as the suffix  for  the  target  file
243              instead  of .xz or .lzma.  If not writing to standard output and
244              the source file already has the suffix .suf, a warning  is  dis‐
245              played and the file is skipped.
246
247              When  decompressing,  recognize  files  with  the suffix .suf in
248              addition to files with the .xz, .txz, .lzma, or .tlz suffix.  If
249              the  source  file  has the suffix .suf, the suffix is removed to
250              get the target filename.
251
252              When compressing or decompressing  raw  streams  (--format=raw),
253              the  suffix  must always be specified unless writing to standard
254              output, because there is no default suffix for raw streams.
255
256       --files[=file]
257              Read the filenames to process from file;  if  file  is  omitted,
258              filenames  are read from standard input.  Filenames must be ter‐
259              minated with the newline character.  A dash (-) is  taken  as  a
260              regular  filename; it doesn't mean standard input.  If filenames
261              are given also as command line  arguments,  they  are  processed
262              before the filenames read from file.
263
264       --files0[=file]
265              This  is  identical  to --files[=file] except that each filename
266              must be terminated with the null character.
267
268   Basic file format and compression options
269       -F format, --format=format
270              Specify the file format to compress or decompress:
271
272              auto   This is the default.  When compressing, auto  is  equiva‐
273                     lent  to xz.  When decompressing, the format of the input
274                     file is automatically detected.  Note  that  raw  streams
275                     (created with --format=raw) cannot be auto-detected.
276
277              xz     Compress to the .xz file format, or accept only .xz files
278                     when decompressing.
279
280              lzma, alone
281                     Compress to the legacy .lzma file format, or accept  only
282                     .lzma  files  when  decompressing.   The alternative name
283                     alone is provided for backwards compatibility  with  LZMA
284                     Utils.
285
286              raw    Compress  or  uncompress a raw stream (no headers).  This
287                     is meant for advanced users only.  To decode raw streams,
288                     you need use --format=raw and explicitly specify the fil‐
289                     ter chain, which normally would have been stored  in  the
290                     container headers.
291
292       -C check, --check=check
293              Specify  the  type  of the integrity check.  The check is calcu‐
294              lated from the uncompressed data and stored  in  the  .xz  file.
295              This  option  has  an  effect only when compressing into the .xz
296              format; the .lzma format doesn't support integrity checks.   The
297              integrity check (if any) is verified when the .xz file is decom‐
298              pressed.
299
300              Supported check types:
301
302              none   Don't calculate an integrity check at all.  This is  usu‐
303                     ally  a  bad  idea.  This can be useful when integrity of
304                     the data is verified by other means anyway.
305
306              crc32  Calculate CRC32  using  the  polynomial  from  IEEE-802.3
307                     (Ethernet).
308
309              crc64  Calculate CRC64 using the polynomial from ECMA-182.  This
310                     is the default, since it is slightly better than CRC32 at
311                     detecting  damaged files and the speed difference is neg‐
312                     ligible.
313
314              sha256 Calculate SHA-256.  This is somewhat  slower  than  CRC32
315                     and CRC64.
316
317              Integrity  of the .xz headers is always verified with CRC32.  It
318              is not possible to change or disable it.
319
320       --ignore-check
321              Don't verify the integrity check of  the  compressed  data  when
322              decompressing.   The  CRC32 values in the .xz headers will still
323              be verified normally.
324
325              Do not use this option unless you know what you are doing.  Pos‐
326              sible reasons to use this option:
327
328              ·  Trying to recover data from a corrupt .xz file.
329
330              ·  Speeding  up decompression.  This matters mostly with SHA-256
331                 or with files that have compressed extremely well.  It's rec‐
332                 ommended  to  not use this option for this purpose unless the
333                 file integrity is verified externally in some other way.
334
335       -0 ... -9
336              Select a compression preset level.  The default is -6.  If  mul‐
337              tiple  preset  levels  are specified, the last one takes effect.
338              If a custom filter chain was already specified, setting  a  com‐
339              pression preset level clears the custom filter chain.
340
341              The  differences  between  the presets are more significant than
342              with gzip(1) and bzip2(1).  The  selected  compression  settings
343              determine  the  memory  requirements  of  the decompressor, thus
344              using a too high preset level might make it  painful  to  decom‐
345              press  the file on an old system with little RAM.  Specifically,
346              it's not a good idea to blindly use -9 for  everything  like  it
347              often is with gzip(1) and bzip2(1).
348
349              -0 ... -3
350                     These  are somewhat fast presets.  -0 is sometimes faster
351                     than gzip -9 while compressing much better.   The  higher
352                     ones  often have speed comparable to bzip2(1) with compa‐
353                     rable or better compression ratio, although  the  results
354                     depend a lot on the type of data being compressed.
355
356              -4 ... -6
357                     Good  to very good compression while keeping decompressor
358                     memory usage reasonable even for old systems.  -6 is  the
359                     default,  which  is  usually  a good choice e.g. for dis‐
360                     tributing files that need to be  decompressible  even  on
361                     systems  with  only 16 MiB RAM.  (-5e or -6e may be worth
362                     considering too.  See --extreme.)
363
364              -7 ... -9
365                     These are like -6 but with higher compressor  and  decom‐
366                     pressor  memory requirements.  These are useful only when
367                     compressing files bigger than 8 MiB, 16 MiB, and  32 MiB,
368                     respectively.
369
370              On the same hardware, the decompression speed is approximately a
371              constant number of bytes of  compressed  data  per  second.   In
372              other  words,  the better the compression, the faster the decom‐
373              pression will usually be.  This also means that  the  amount  of
374              uncompressed output produced per second can vary a lot.
375
376              The following table summarises the features of the presets:
377
378                     Preset   DictSize   CompCPU   CompMem   DecMem
379                       -0     256 KiB       0        3 MiB    1 MiB
380                       -1       1 MiB       1        9 MiB    2 MiB
381                       -2       2 MiB       2       17 MiB    3 MiB
382                       -3       4 MiB       3       32 MiB    5 MiB
383                       -4       4 MiB       4       48 MiB    5 MiB
384                       -5       8 MiB       5       94 MiB    9 MiB
385                       -6       8 MiB       6       94 MiB    9 MiB
386                       -7      16 MiB       6      186 MiB   17 MiB
387                       -8      32 MiB       6      370 MiB   33 MiB
388                       -9      64 MiB       6      674 MiB   65 MiB
389
390              Column descriptions:
391
392              ·  DictSize is the LZMA2 dictionary size.  It is waste of memory
393                 to use a dictionary bigger than the size of the  uncompressed
394                 file.   This  is why it is good to avoid using the presets -7
395                 ... -9 when there's no real need for them.  At -6 and  lower,
396                 the amount of memory wasted is usually low enough to not mat‐
397                 ter.
398
399              ·  CompCPU is a simplified representation of the LZMA2  settings
400                 that  affect  compression speed.  The dictionary size affects
401                 speed too, so while CompCPU is the same for levels -6 ... -9,
402                 higher  levels still tend to be a little slower.  To get even
403                 slower and thus possibly better compression, see --extreme.
404
405              ·  CompMem contains the compressor memory  requirements  in  the
406                 single-threaded  mode.   It may vary slightly between xz ver‐
407                 sions.  Memory requirements of  some  of  the  future  multi‐
408                 threaded  modes  may  be dramatically higher than that of the
409                 single-threaded mode.
410
411              ·  DecMem contains the decompressor memory  requirements.   That
412                 is,  the  compression  settings determine the memory require‐
413                 ments of the decompressor.   The  exact  decompressor  memory
414                 usage  is  slightly  more than the LZMA2 dictionary size, but
415                 the values in the table have been rounded up to the next full
416                 MiB.
417
418       -e, --extreme
419              Use  a  slower  variant of the selected compression preset level
420              (-0 ... -9) to hopefully get a  little  bit  better  compression
421              ratio,  but  with  bad luck this can also make it worse.  Decom‐
422              pressor memory usage is  not  affected,  but  compressor  memory
423              usage increases a little at preset levels -0 ... -3.
424
425              Since  there  are  two  presets  with dictionary sizes 4 MiB and
426              8 MiB, the presets -3e and  -5e  use  slightly  faster  settings
427              (lower CompCPU) than -4e and -6e, respectively.  That way no two
428              presets are identical.
429
430                     Preset   DictSize   CompCPU   CompMem   DecMem
431                      -0e     256 KiB       8        4 MiB    1 MiB
432                      -1e       1 MiB       8       13 MiB    2 MiB
433                      -2e       2 MiB       8       25 MiB    3 MiB
434                      -3e       4 MiB       7       48 MiB    5 MiB
435                      -4e       4 MiB       8       48 MiB    5 MiB
436                      -5e       8 MiB       7       94 MiB    9 MiB
437                      -6e       8 MiB       8       94 MiB    9 MiB
438                      -7e      16 MiB       8      186 MiB   17 MiB
439                      -8e      32 MiB       8      370 MiB   33 MiB
440                      -9e      64 MiB       8      674 MiB   65 MiB
441
442              For example, there are a total of four presets  that  use  8 MiB
443              dictionary,  whose  order from the fastest to the slowest is -5,
444              -6, -5e, and -6e.
445
446       --fast
447       --best These are somewhat misleading aliases for  -0  and  -9,  respec‐
448              tively.   These  are  provided  only for backwards compatibility
449              with LZMA Utils.  Avoid using these options.
450
451       --block-size=size
452              When compressing to the .xz format, split the  input  data  into
453              blocks  of  size bytes.  The blocks are compressed independently
454              from each other, which helps with multi-threading and makes lim‐
455              ited random-access decompression possible.  This option is typi‐
456              cally used to override the default block size in  multi-threaded
457              mode, but this option can be used in single-threaded mode too.
458
459              In  multi-threaded  mode  about  three  times size bytes will be
460              allocated in each thread for buffering input  and  output.   The
461              default  size is three times the LZMA2 dictionary size or 1 MiB,
462              whichever is more.  Typically a good value is 2-4 times the size
463              of the LZMA2 dictionary or at least 1 MiB.  Using size less than
464              the LZMA2 dictionary size is waste of RAM because then the LZMA2
465              dictionary  buffer  will never get fully used.  The sizes of the
466              blocks are stored in the block headers, which a  future  version
467              of xz will use for multi-threaded decompression.
468
469              In  single-threaded  mode no block splitting is done by default.
470              Setting this option doesn't affect memory usage.  No size infor‐
471              mation is stored in block headers, thus files created in single-
472              threaded mode won't be identical  to  files  created  in  multi-
473              threaded  mode.   The lack of size information also means that a
474              future version of xz won't  be  able  decompress  the  files  in
475              multi-threaded mode.
476
477       --block-list=sizes
478              When  compressing to the .xz format, start a new block after the
479              given intervals of uncompressed data.
480
481              The uncompressed sizes of the blocks are specified as  a  comma-
482              separated  list.   Omitting a size (two or more consecutive com‐
483              mas) is a shorthand to use the size of the previous block.
484
485              If the input file is bigger than the  sum  of  sizes,  the  last
486              value in sizes is repeated until the end of the file.  A special
487              value of 0 may be used as the last value to  indicate  that  the
488              rest of the file should be encoded as a single block.
489
490              If  one  specifies  sizes  that  exceed the encoder's block size
491              (either the default value in threaded mode or the  value  speci‐
492              fied with --block-size=size), the encoder will create additional
493              blocks while keeping the boundaries  specified  in  sizes.   For
494              example,      if      one      specifies      --block-size=10MiB
495              --block-list=5MiB,10MiB,8MiB,12MiB,24MiB and the input  file  is
496              80  MiB, one will get 11 blocks: 5, 10, 8, 10, 2, 10, 10, 4, 10,
497              10, and 1 MiB.
498
499              In multi-threaded mode the sizes of the blocks are stored in the
500              block  headers.  This isn't done in single-threaded mode, so the
501              encoded output won't be identical to that of the  multi-threaded
502              mode.
503
504       --flush-timeout=timeout
505              When  compressing, if more than timeout milliseconds (a positive
506              integer) has passed since the previous flush  and  reading  more
507              input  would  block,  all the pending input data is flushed from
508              the encoder and made available in the output stream.   This  can
509              be useful if xz is used to compress data that is streamed over a
510              network.  Small timeout values make the data  available  at  the
511              receiving  end with a small delay, but large timeout values give
512              better compression ratio.
513
514              This feature is disabled by default.  If this option  is  speci‐
515              fied  more  than  once,  the last one takes effect.  The special
516              timeout value of 0 can be used to explicitly disable  this  fea‐
517              ture.
518
519              This feature is not available on non-POSIX systems.
520
521              This  feature is still experimental.  Currently xz is unsuitable
522              for decompressing the stream in real time due  to  how  xz  does
523              buffering.
524
525       --memlimit-compress=limit
526              Set  a  memory  usage  limit for compression.  If this option is
527              specified multiple times, the last one takes effect.
528
529              If the compression settings exceed the limit, xz will adjust the
530              settings  downwards  so that the limit is no longer exceeded and
531              display a notice  that  automatic  adjustment  was  done.   Such
532              adjustments  are  not made when compressing with --format=raw or
533              if --no-adjust has been specified.  In those cases, an error  is
534              displayed and xz will exit with exit status 1.
535
536              The limit can be specified in multiple ways:
537
538              ·  The  limit can be an absolute value in bytes.  Using an inte‐
539                 ger suffix like MiB can be useful.  Example:  --memlimit-com‐
540                 press=80MiB
541
542              ·  The  limit can be specified as a percentage of total physical
543                 memory (RAM).  This can be useful especially when setting the
544                 XZ_DEFAULTS  environment  variable  in a shell initialization
545                 script that is shared between different computers.  That  way
546                 the  limit  is automatically bigger on systems with more mem‐
547                 ory.  Example: --memlimit-compress=70%
548
549              ·  The limit can be reset back to its default value  by  setting
550                 it  to  0.  This is currently equivalent to setting the limit
551                 to max (no memory usage limit).  Once multithreading  support
552                 has been implemented, there may be a difference between 0 and
553                 max for the multithreaded case, so it is recommended to use 0
554                 instead of max until the details have been decided.
555
556              For  32-bit  xz  there  is a special case: if the limit would be
557              over 4020 MiB, the limit is set to 4020 MiB.  (The values 0  and
558              max  aren't  affected  by this.  A similar feature doesn't exist
559              for decompression.)  This can be  helpful  when  a  32-bit  exe‐
560              cutable  has access to 4 GiB address space while hopefully doing
561              no harm in other situations.
562
563              See also the section Memory usage.
564
565       --memlimit-decompress=limit
566              Set a memory usage limit for decompression.  This  also  affects
567              the  --list  mode.   If  the  operation  is not possible without
568              exceeding the limit, xz will display an error and  decompressing
569              the  file will fail.  See --memlimit-compress=limit for possible
570              ways to specify the limit.
571
572       -M limit, --memlimit=limit, --memory=limit
573              This  is  equivalent  to  specifying   --memlimit-compress=limit
574              --memlimit-decompress=limit.
575
576       --no-adjust
577              Display an error and exit if the compression settings exceed the
578              memory usage limit.  The default is to adjust the settings down‐
579              wards so that the memory usage limit is not exceeded.  Automatic
580              adjusting is always disabled when creating raw  streams  (--for‐
581              mat=raw).
582
583       -T threads, --threads=threads
584              Specify the number of worker threads to use.  Setting threads to
585              a special value 0 makes xz use as many threads as there are  CPU
586              cores  on  the system.  The actual number of threads can be less
587              than threads if the input file is not big enough  for  threading
588              with  the  given  settings or if using more threads would exceed
589              the memory usage limit.
590
591              Currently the only threading method is to split the  input  into
592              blocks  and  compress  them  independently from each other.  The
593              default block size depends on the compression level and  can  be
594              overridden with the --block-size=size option.
595
596              Threaded  decompression  hasn't  been  implemented yet.  It will
597              only work on files that contain multiple blocks with size infor‐
598              mation in block headers.  All files compressed in multi-threaded
599              mode meet  this  condition,  but  files  compressed  in  single-
600              threaded mode don't even if --block-size=size is used.
601
602   Custom compressor filter chains
603       A  custom  filter  chain  allows specifying the compression settings in
604       detail instead of relying on the settings associated  to  the  presets.
605       When  a custom filter chain is specified, preset options (-0 ... -9 and
606       --extreme) earlier on the command line  are  forgotten.   If  a  preset
607       option  is specified after one or more custom filter chain options, the
608       new preset takes effect and the custom filter chain  options  specified
609       earlier are forgotten.
610
611       A  filter chain is comparable to piping on the command line.  When com‐
612       pressing, the uncompressed input goes to the first filter, whose output
613       goes  to  the next filter (if any).  The output of the last filter gets
614       written to the compressed file.  The maximum number of filters  in  the
615       chain  is  four,  but typically a filter chain has only one or two fil‐
616       ters.
617
618       Many filters have limitations on where they can be in the filter chain:
619       some  filters  can work only as the last filter in the chain, some only
620       as a non-last filter, and some work  in  any  position  in  the  chain.
621       Depending on the filter, this limitation is either inherent to the fil‐
622       ter design or exists to prevent security issues.
623
624       A custom filter chain is specified by using one or more filter  options
625       in  the  order they are wanted in the filter chain.  That is, the order
626       of filter options is significant!  When decoding  raw  streams  (--for‐
627       mat=raw),  the  filter  chain  is specified in the same order as it was
628       specified when compressing.
629
630       Filters take filter-specific options as a comma-separated list.   Extra
631       commas  in  options  are ignored.  Every option has a default value, so
632       you need to specify only those you want to change.
633
634       To see the whole filter chain and options, use xz  -vv  (that  is,  use
635       --verbose twice).  This works also for viewing the filter chain options
636       used by presets.
637
638       --lzma1[=options]
639       --lzma2[=options]
640              Add LZMA1 or LZMA2 filter to the filter  chain.   These  filters
641              can be used only as the last filter in the chain.
642
643              LZMA1  is  a legacy filter, which is supported almost solely due
644              to the legacy .lzma file  format,  which  supports  only  LZMA1.
645              LZMA2  is  an  updated  version  of  LZMA1 to fix some practical
646              issues of LZMA1.  The .xz format uses LZMA2 and doesn't  support
647              LZMA1  at  all.  Compression speed and ratios of LZMA1 and LZMA2
648              are practically the same.
649
650              LZMA1 and LZMA2 share the same set of options:
651
652              preset=preset
653                     Reset all LZMA1 or LZMA2 options to preset.  Preset  con‐
654                     sist  of an integer, which may be followed by single-let‐
655                     ter preset modifiers.  The integer can be from  0  to  9,
656                     matching  the  command  line options -0 ... -9.  The only
657                     supported  modifier  is  currently   e,   which   matches
658                     --extreme.  If no preset is specified, the default values
659                     of LZMA1 or LZMA2 options are taken from the preset 6.
660
661              dict=size
662                     Dictionary (history buffer) size indicates how many bytes
663                     of  the  recently  processed uncompressed data is kept in
664                     memory.  The  algorithm  tries  to  find  repeating  byte
665                     sequences (matches) in the uncompressed data, and replace
666                     them with references to the data currently in the dictio‐
667                     nary.   The  bigger  the  dictionary,  the  higher is the
668                     chance to find a match.  Thus, increasing dictionary size
669                     usually improves compression ratio, but a dictionary big‐
670                     ger than the uncompressed file is waste of memory.
671
672                     Typical dictionary size is from 64 KiB  to  64 MiB.   The
673                     minimum  is  4 KiB.   The maximum for compression is cur‐
674                     rently 1.5 GiB (1536 MiB).  The decompressor already sup‐
675                     ports  dictionaries up to one byte less than 4 GiB, which
676                     is the maximum for the LZMA1 and LZMA2 stream formats.
677
678                     Dictionary size and match finder (mf) together  determine
679                     the memory usage of the LZMA1 or LZMA2 encoder.  The same
680                     (or bigger) dictionary size is required for decompressing
681                     that  was used when compressing, thus the memory usage of
682                     the decoder is determined by  the  dictionary  size  used
683                     when  compressing.   The .xz headers store the dictionary
684                     size either as 2^n or 2^n + 2^(n-1), so these  sizes  are
685                     somewhat preferred for compression.  Other sizes will get
686                     rounded up when stored in the .xz headers.
687
688              lc=lc  Specify the number of literal context bits.  The  minimum
689                     is  0  and  the maximum is 4; the default is 3.  In addi‐
690                     tion, the sum of lc and lp must not exceed 4.
691
692                     All bytes that cannot be encoded as matches  are  encoded
693                     as  literals.   That  is, literals are simply 8-bit bytes
694                     that are encoded one at a time.
695
696                     The literal coding makes an assumption that  the  highest
697                     lc  bits of the previous uncompressed byte correlate with
698                     the next byte.  E.g. in typical English text,  an  upper-
699                     case letter is often followed by a lower-case letter, and
700                     a lower-case letter is usually followed by another lower-
701                     case  letter.  In the US-ASCII character set, the highest
702                     three bits are 010 for upper-case  letters  and  011  for
703                     lower-case  letters.   When lc is at least 3, the literal
704                     coding can take advantage of this property in the  uncom‐
705                     pressed data.
706
707                     The default value (3) is usually good.  If you want maxi‐
708                     mum compression, test lc=4.  Sometimes it helps a little,
709                     and sometimes it makes compression worse.  If it makes it
710                     worse, test e.g. lc=2 too.
711
712              lp=lp  Specify the number of literal position bits.  The minimum
713                     is 0 and the maximum is 4; the default is 0.
714
715                     Lp  affects  what  kind  of alignment in the uncompressed
716                     data is assumed when encoding literals.  See pb below for
717                     more information about alignment.
718
719              pb=pb  Specify  the  number  of position bits.  The minimum is 0
720                     and the maximum is 4; the default is 2.
721
722                     Pb affects what kind of  alignment  in  the  uncompressed
723                     data  is assumed in general.  The default means four-byte
724                     alignment (2^pb=2^2=4), which is often a good choice when
725                     there's no better guess.
726
727                     When  the  aligment  is known, setting pb accordingly may
728                     reduce the file size a little.  E.g. with text files hav‐
729                     ing  one-byte  alignment  (US-ASCII,  ISO-8859-*, UTF-8),
730                     setting  pb=0  can  improve  compression  slightly.   For
731                     UTF-16  text, pb=1 is a good choice.  If the alignment is
732                     an odd number like  3  bytes,  pb=0  might  be  the  best
733                     choice.
734
735                     Even though the assumed alignment can be adjusted with pb
736                     and lp, LZMA1 and  LZMA2  still  slightly  favor  16-byte
737                     alignment.   It  might  be worth taking into account when
738                     designing file formats that are likely to be  often  com‐
739                     pressed with LZMA1 or LZMA2.
740
741              mf=mf  Match  finder has a major effect on encoder speed, memory
742                     usage, and compression ratio.  Usually Hash  Chain  match
743                     finders  are  faster than Binary Tree match finders.  The
744                     default depends on the preset: 0 uses hc3, 1-3  use  hc4,
745                     and the rest use bt4.
746
747                     The  following  match  finders are supported.  The memory
748                     usage formulas below are rough approximations, which  are
749                     closest to the reality when dict is a power of two.
750
751                     hc3    Hash Chain with 2- and 3-byte hashing
752                            Minimum value for nice: 3
753                            Memory usage:
754                            dict * 7.5 (if dict <= 16 MiB);
755                            dict * 5.5 + 64 MiB (if dict > 16 MiB)
756
757                     hc4    Hash Chain with 2-, 3-, and 4-byte hashing
758                            Minimum value for nice: 4
759                            Memory usage:
760                            dict * 7.5 (if dict <= 32 MiB);
761                            dict * 6.5 (if dict > 32 MiB)
762
763                     bt2    Binary Tree with 2-byte hashing
764                            Minimum value for nice: 2
765                            Memory usage: dict * 9.5
766
767                     bt3    Binary Tree with 2- and 3-byte hashing
768                            Minimum value for nice: 3
769                            Memory usage:
770                            dict * 11.5 (if dict <= 16 MiB);
771                            dict * 9.5 + 64 MiB (if dict > 16 MiB)
772
773                     bt4    Binary Tree with 2-, 3-, and 4-byte hashing
774                            Minimum value for nice: 4
775                            Memory usage:
776                            dict * 11.5 (if dict <= 32 MiB);
777                            dict * 10.5 (if dict > 32 MiB)
778
779              mode=mode
780                     Compression mode specifies the method to analyze the data
781                     produced by the match finder.  Supported modes  are  fast
782                     and normal.  The default is fast for presets 0-3 and nor‐
783                     mal for presets 4-9.
784
785                     Usually fast is used with Hash Chain  match  finders  and
786                     normal with Binary Tree match finders.  This is also what
787                     the presets do.
788
789              nice=nice
790                     Specify what is considered to be  a  nice  length  for  a
791                     match.  Once a match of at least nice bytes is found, the
792                     algorithm stops looking for possibly better matches.
793
794                     Nice can be 2-273 bytes.  Higher values tend to give bet‐
795                     ter  compression  ratio  at  the  expense  of speed.  The
796                     default depends on the preset.
797
798              depth=depth
799                     Specify the maximum search depth  in  the  match  finder.
800                     The  default  is  the special value of 0, which makes the
801                     compressor determine a reasonable depth from mf and nice.
802
803                     Reasonable depth for Hash Chains is 4-100 and 16-1000 for
804                     Binary  Trees.  Using very high values for depth can make
805                     the encoder extremely slow with some files.   Avoid  set‐
806                     ting  the  depth  over  1000  unless  you are prepared to
807                     interrupt the compression in case it is  taking  far  too
808                     long.
809
810              When  decoding  raw streams (--format=raw), LZMA2 needs only the
811              dictionary size.  LZMA1 needs also lc, lp, and pb.
812
813       --x86[=options]
814       --powerpc[=options]
815       --ia64[=options]
816       --arm[=options]
817       --armthumb[=options]
818       --sparc[=options]
819              Add a branch/call/jump (BCJ) filter to the filter chain.   These
820              filters  can  be  used  only  as a non-last filter in the filter
821              chain.
822
823              A BCJ filter converts relative addresses in the machine code  to
824              their  absolute  counterparts.   This doesn't change the size of
825              the data, but it increases redundancy, which can help  LZMA2  to
826              produce  0-15 %  smaller  .xz  file.  The BCJ filters are always
827              reversible, so using a BCJ filter for wrong type of data doesn't
828              cause  any data loss, although it may make the compression ratio
829              slightly worse.
830
831              It is fine to apply a BCJ filter on a whole executable;  there's
832              no  need to apply it only on the executable section.  Applying a
833              BCJ filter on an archive that contains both executable and  non-
834              executable  files may or may not give good results, so it gener‐
835              ally isn't good to blindly apply a BCJ filter  when  compressing
836              binary packages for distribution.
837
838              These  BCJ filters are very fast and use insignificant amount of
839              memory.  If a BCJ filter improves compression ratio of  a  file,
840              it  can  improve  decompression speed at the same time.  This is
841              because, on the same hardware, the decompression speed of  LZMA2
842              is  roughly  a fixed number of bytes of compressed data per sec‐
843              ond.
844
845              These BCJ filters have known problems related to the compression
846              ratio:
847
848              ·  Some  types  of files containing executable code (e.g. object
849                 files, static libraries, and Linux kernel modules)  have  the
850                 addresses  in  the  instructions  filled  with filler values.
851                 These BCJ filters will still do the address conversion, which
852                 will make the compression worse with these files.
853
854              ·  Applying a BCJ filter on an archive containing multiple simi‐
855                 lar executables can make the compression ratio worse than not
856                 using  a  BCJ filter.  This is because the BCJ filter doesn't
857                 detect the boundaries of the executable  files,  and  doesn't
858                 reset the address conversion counter for each executable.
859
860              Both  of the above problems will be fixed in the future in a new
861              filter.  The old BCJ filters will still be  useful  in  embedded
862              systems,  because  the  decoder of the new filter will be bigger
863              and use more memory.
864
865              Different instruction sets have different alignment:
866
867                     Filter      Alignment   Notes
868                     x86             1       32-bit or 64-bit x86
869                     PowerPC         4       Big endian only
870                     ARM             4       Little endian only
871                     ARM-Thumb       2       Little endian only
872                     IA-64          16       Big or little endian
873                     SPARC           4       Big or little endian
874
875              Since the BCJ-filtered data is usually  compressed  with  LZMA2,
876              the  compression  ratio  may  be  improved slightly if the LZMA2
877              options are set to match the alignment of the selected BCJ  fil‐
878              ter.   For example, with the IA-64 filter, it's good to set pb=4
879              with LZMA2 (2^4=16).  The x86 filter is an exception; it's  usu‐
880              ally  good  to stick to LZMA2's default four-byte alignment when
881              compressing x86 executables.
882
883              All BCJ filters support the same options:
884
885              start=offset
886                     Specify the start offset that  is  used  when  converting
887                     between relative and absolute addresses.  The offset must
888                     be a multiple of the alignment of the filter (see the ta‐
889                     ble  above).   The  default  is  zero.   In practice, the
890                     default is good; specifying a  custom  offset  is  almost
891                     never useful.
892
893       --delta[=options]
894              Add  the Delta filter to the filter chain.  The Delta filter can
895              be only used as a non-last filter in the filter chain.
896
897              Currently only simple byte-wise delta calculation is  supported.
898              It  can  be  useful  when  compressing  e.g. uncompressed bitmap
899              images or uncompressed  PCM  audio.   However,  special  purpose
900              algorithms  may  give  significantly better results than Delta +
901              LZMA2.  This is true especially  with  audio,  which  compresses
902              faster and better e.g. with flac(1).
903
904              Supported options:
905
906              dist=distance
907                     Specify  the  distance of the delta calculation in bytes.
908                     distance must be 1-256.  The default is 1.
909
910                     For example, with dist=2 and eight-byte input A1 B1 A2 B3
911                     A3 B5 A4 B7, the output will be A1 B1 01 02 01 02 01 02.
912
913   Other options
914       -q, --quiet
915              Suppress  warnings  and notices.  Specify this twice to suppress
916              errors too.  This option has no effect on the exit status.  That
917              is,  even  if a warning was suppressed, the exit status to indi‐
918              cate a warning is still used.
919
920       -v, --verbose
921              Be verbose.  If standard error is connected to  a  terminal,  xz
922              will  display  a progress indicator.  Specifying --verbose twice
923              will give even more verbose output.
924
925              The progress indicator shows the following information:
926
927              ·  Completion percentage is shown if the size of the input  file
928                 is known.  That is, the percentage cannot be shown in pipes.
929
930              ·  Amount  of compressed data produced (compressing) or consumed
931                 (decompressing).
932
933              ·  Amount of uncompressed data consumed  (compressing)  or  pro‐
934                 duced (decompressing).
935
936              ·  Compression ratio, which is calculated by dividing the amount
937                 of compressed data processed so far by the amount  of  uncom‐
938                 pressed data processed so far.
939
940              ·  Compression  or decompression speed.  This is measured as the
941                 amount of uncompressed data consumed  (compression)  or  pro‐
942                 duced  (decompression)  per  second.  It is shown after a few
943                 seconds have passed since xz started processing the file.
944
945              ·  Elapsed time in the format M:SS or H:MM:SS.
946
947              ·  Estimated remaining time is shown only when the size  of  the
948                 input  file  is  known  and  a couple of seconds have already
949                 passed since xz started processing the  file.   The  time  is
950                 shown  in  a  less precise format which never has any colons,
951                 e.g. 2 min 30 s.
952
953              When standard error is not a terminal, --verbose  will  make  xz
954              print the filename, compressed size, uncompressed size, compres‐
955              sion ratio, and possibly also the speed and elapsed  time  on  a
956              single line to standard error after compressing or decompressing
957              the file.  The speed and elapsed time are included only when the
958              operation  took at least a few seconds.  If the operation didn't
959              finish, e.g. due to user interruption, also the completion  per‐
960              centage is printed if the size of the input file is known.
961
962       -Q, --no-warn
963              Don't set the exit status to 2 even if a condition worth a warn‐
964              ing was detected.  This  option  doesn't  affect  the  verbosity
965              level,  thus  both  --quiet and --no-warn have to be used to not
966              display warnings and to not alter the exit status.
967
968       --robot
969              Print messages in a machine-parsable format.  This  is  intended
970              to  ease  writing  frontends  that  want  to  use  xz instead of
971              liblzma, which may be the case with various scripts.  The output
972              with  this  option  enabled  is  meant  to  be  stable across xz
973              releases.  See the section ROBOT MODE for details.
974
975       --info-memory
976              Display, in human-readable  format,  how  much  physical  memory
977              (RAM)  xz  thinks the system has and the memory usage limits for
978              compression and decompression, and exit successfully.
979
980       -h, --help
981              Display  a  help  message  describing  the  most  commonly  used
982              options, and exit successfully.
983
984       -H, --long-help
985              Display  a  help message describing all features of xz, and exit
986              successfully
987
988       -V, --version
989              Display the version number of xz and liblzma in  human  readable
990              format.   To get machine-parsable output, specify --robot before
991              --version.
992

ROBOT MODE

994       The robot mode is activated with the --robot option.  It makes the out‐
995       put of xz easier to parse by other programs.  Currently --robot is sup‐
996       ported only together with --version,  --info-memory,  and  --list.   It
997       will be supported for compression and decompression in the future.
998
999   Version
1000       xz --robot --version will print the version number of xz and liblzma in
1001       the following format:
1002
1003       XZ_VERSION=XYYYZZZS
1004       LIBLZMA_VERSION=XYYYZZZS
1005
1006       X      Major version.
1007
1008       YYY    Minor version.  Even numbers are stable.  Odd numbers are  alpha
1009              or beta versions.
1010
1011       ZZZ    Patch  level  for stable releases or just a counter for develop‐
1012              ment releases.
1013
1014       S      Stability.  0 is alpha, 1 is beta, and 2 is stable.  S should be
1015              always 2 when YYY is even.
1016
1017       XYYYZZZS are the same on both lines if xz and liblzma are from the same
1018       XZ Utils release.
1019
1020       Examples: 4.999.9beta is 49990091 and 5.0.0 is 50000002.
1021
1022   Memory limit information
1023       xz --robot --info-memory prints a single line with three  tab-separated
1024       columns:
1025
1026       1.  Total amount of physical memory (RAM) in bytes
1027
1028       2.  Memory  usage  limit  for compression in bytes.  A special value of
1029           zero indicates the default setting, which for single-threaded  mode
1030           is the same as no limit.
1031
1032       3.  Memory  usage limit for decompression in bytes.  A special value of
1033           zero indicates the default setting, which for single-threaded  mode
1034           is the same as no limit.
1035
1036       In  the  future,  the  output of xz --robot --info-memory may have more
1037       columns, but never more than a single line.
1038
1039   List mode
1040       xz --robot --list uses tab-separated output.  The first column of every
1041       line  has  a string that indicates the type of the information found on
1042       that line:
1043
1044       name   This is always the first line when starting to list a file.  The
1045              second column on the line is the filename.
1046
1047       file   This line contains overall information about the .xz file.  This
1048              line is always printed after the name line.
1049
1050       stream This line type is used only when --verbose was specified.  There
1051              are as many stream lines as there are streams in the .xz file.
1052
1053       block  This line type is used only when --verbose was specified.  There
1054              are as many block lines as there are blocks  in  the  .xz  file.
1055              The  block lines are shown after all the stream lines; different
1056              line types are not interleaved.
1057
1058       summary
1059              This line type is used only when --verbose was specified  twice.
1060              This line is printed after all block lines.  Like the file line,
1061              the summary line contains  overall  information  about  the  .xz
1062              file.
1063
1064       totals This  line  is always the very last line of the list output.  It
1065              shows the total counts and sizes.
1066
1067       The columns of the file lines:
1068              2.  Number of streams in the file
1069              3.  Total number of blocks in the stream(s)
1070              4.  Compressed size of the file
1071              5.  Uncompressed size of the file
1072              6.  Compression ratio, for example  0.123.   If  ratio  is  over
1073                  9.999,  three  dashes  (---)  are  displayed  instead of the
1074                  ratio.
1075              7.  Comma-separated list of integrity check names.  The  follow‐
1076                  ing strings are used for the known check types: None, CRC32,
1077                  CRC64, and SHA-256.  For unknown check types,  Unknown-N  is
1078                  used,  where  N  is the Check ID as a decimal number (one or
1079                  two digits).
1080              8.  Total size of stream padding in the file
1081
1082       The columns of the stream lines:
1083              2.  Stream number (the first stream is 1)
1084              3.  Number of blocks in the stream
1085              4.  Compressed start offset
1086              5.  Uncompressed start offset
1087              6.  Compressed size (does not include stream padding)
1088              7.  Uncompressed size
1089              8.  Compression ratio
1090              9.  Name of the integrity check
1091              10. Size of stream padding
1092
1093       The columns of the block lines:
1094              2.  Number of the stream containing this block
1095              3.  Block number relative to the beginning of  the  stream  (the
1096                  first block is 1)
1097              4.  Block number relative to the beginning of the file
1098              5.  Compressed  start  offset  relative  to the beginning of the
1099                  file
1100              6.  Uncompressed start offset relative to the beginning  of  the
1101                  file
1102              7.  Total compressed size of the block (includes headers)
1103              8.  Uncompressed size
1104              9.  Compression ratio
1105              10. Name of the integrity check
1106
1107       If  --verbose  was  specified twice, additional columns are included on
1108       the block lines.  These are not  displayed  with  a  single  --verbose,
1109       because  getting  this  information requires many seeks and can thus be
1110       slow:
1111              11. Value of the integrity check in hexadecimal
1112              12. Block header size
1113              13. Block flags: c indicates that compressed  size  is  present,
1114                  and  u  indicates that uncompressed size is present.  If the
1115                  flag is not set, a dash (-) is shown  instead  to  keep  the
1116                  string  length  fixed.  New flags may be added to the end of
1117                  the string in the future.
1118              14. Size of the  actual  compressed  data  in  the  block  (this
1119                  excludes the block header, block padding, and check fields)
1120              15. Amount  of  memory  (in  bytes)  required to decompress this
1121                  block with this xz version
1122              16. Filter chain.  Note that most of the options  used  at  com‐
1123                  pression time cannot be known, because only the options that
1124                  are needed for decompression are stored in the .xz headers.
1125
1126       The columns of the summary lines:
1127              2.  Amount of memory (in bytes) required to decompress this file
1128                  with this xz version
1129              3.  yes  or  no  indicating  if all block headers have both com‐
1130                  pressed size and uncompressed size stored in them
1131              Since xz 5.1.2alpha:
1132              4.  Minimum xz version required to decompress the file
1133
1134       The columns of the totals line:
1135              2.  Number of streams
1136              3.  Number of blocks
1137              4.  Compressed size
1138              5.  Uncompressed size
1139              6.  Average compression ratio
1140              7.  Comma-separated list of  integrity  check  names  that  were
1141                  present in the files
1142              8.  Stream padding size
1143              9.  Number of files.  This is here to keep the order of the ear‐
1144                  lier columns the same as on file lines.
1145
1146       If --verbose was specified twice, additional columns  are  included  on
1147       the totals line:
1148              10. Maximum  amount  of memory (in bytes) required to decompress
1149                  the files with this xz version
1150              11. yes or no indicating if all block  headers  have  both  com‐
1151                  pressed size and uncompressed size stored in them
1152              Since xz 5.1.2alpha:
1153              12. Minimum xz version required to decompress the file
1154
1155       Future  versions may add new line types and new columns can be added to
1156       the existing line types, but the existing columns won't be changed.
1157

EXIT STATUS

1159       0      All is good.
1160
1161       1      An error occurred.
1162
1163       2      Something  worth  a  warning  occurred,  but  no  actual  errors
1164              occurred.
1165
1166       Notices (not warnings or errors) printed on standard error don't affect
1167       the exit status.
1168

ENVIRONMENT

1170       xz parses space-separated lists of options from the  environment  vari‐
1171       ables XZ_DEFAULTS and XZ_OPT, in this order, before parsing the options
1172       from the command line.  Note that only  options  are  parsed  from  the
1173       environment  variables;  all non-options are silently ignored.  Parsing
1174       is done with getopt_long(3) which is used also  for  the  command  line
1175       arguments.
1176
1177       XZ_DEFAULTS
1178              User-specific or system-wide default options.  Typically this is
1179              set in a shell initialization script to enable xz's memory usage
1180              limiter  by default.  Excluding shell initialization scripts and
1181              similar  special  cases,  scripts  must  never  set   or   unset
1182              XZ_DEFAULTS.
1183
1184       XZ_OPT This is for passing options to xz when it is not possible to set
1185              the options directly on the xz command line.  This is  the  case
1186              e.g. when xz is run by a script or tool, e.g. GNU tar(1):
1187
1188                     XZ_OPT=-2v tar caf foo.tar.xz foo
1189
1190              Scripts  may use XZ_OPT e.g. to set script-specific default com‐
1191              pression options.  It is still recommended  to  allow  users  to
1192              override XZ_OPT if that is reasonable, e.g. in sh(1) scripts one
1193              may use something like this:
1194
1195                     XZ_OPT=${XZ_OPT-"-7e"}
1196                     export XZ_OPT
1197

LZMA UTILS COMPATIBILITY

1199       The command line syntax of  xz  is  practically  a  superset  of  lzma,
1200       unlzma,  and  lzcat as found from LZMA Utils 4.32.x.  In most cases, it
1201       is possible to replace LZMA Utils with XZ Utils without breaking exist‐
1202       ing  scripts.  There are some incompatibilities though, which may some‐
1203       times cause problems.
1204
1205   Compression preset levels
1206       The numbering of the compression level presets is not identical  in  xz
1207       and  LZMA Utils.  The most important difference is how dictionary sizes
1208       are mapped to different presets.  Dictionary size is roughly  equal  to
1209       the decompressor memory usage.
1210
1211              Level     xz      LZMA Utils
1212               -0     256 KiB      N/A
1213               -1       1 MiB     64 KiB
1214               -2       2 MiB      1 MiB
1215               -3       4 MiB    512 KiB
1216               -4       4 MiB      1 MiB
1217               -5       8 MiB      2 MiB
1218               -6       8 MiB      4 MiB
1219               -7      16 MiB      8 MiB
1220               -8      32 MiB     16 MiB
1221               -9      64 MiB     32 MiB
1222
1223       The dictionary size differences affect the compressor memory usage too,
1224       but there are some other differences between LZMA Utils and  XZ  Utils,
1225       which make the difference even bigger:
1226
1227              Level     xz      LZMA Utils 4.32.x
1228               -0       3 MiB          N/A
1229               -1       9 MiB          2 MiB
1230               -2      17 MiB         12 MiB
1231               -3      32 MiB         12 MiB
1232               -4      48 MiB         16 MiB
1233               -5      94 MiB         26 MiB
1234               -6      94 MiB         45 MiB
1235               -7     186 MiB         83 MiB
1236               -8     370 MiB        159 MiB
1237               -9     674 MiB        311 MiB
1238
1239       The  default  preset  level in LZMA Utils is -7 while in XZ Utils it is
1240       -6, so both use an 8 MiB dictionary by default.
1241
1242   Streamed vs. non-streamed .lzma files
1243       The uncompressed size of the file can be stored in  the  .lzma  header.
1244       LZMA  Utils  does that when compressing regular files.  The alternative
1245       is to mark that uncompressed size is  unknown  and  use  end-of-payload
1246       marker to indicate where the decompressor should stop.  LZMA Utils uses
1247       this method when uncompressed size isn't known, which is the  case  for
1248       example in pipes.
1249
1250       xz  supports  decompressing  .lzma files with or without end-of-payload
1251       marker, but all .lzma files  created  by  xz  will  use  end-of-payload
1252       marker  and  have  uncompressed  size  marked  as  unknown in the .lzma
1253       header.  This may be a problem in some uncommon situations.  For  exam‐
1254       ple,  a  .lzma  decompressor in an embedded device might work only with
1255       files that have known uncompressed size.  If you hit this problem,  you
1256       need  to  use  LZMA  Utils or LZMA SDK to create .lzma files with known
1257       uncompressed size.
1258
1259   Unsupported .lzma files
1260       The .lzma format allows lc values up to 8, and lp values up to 4.  LZMA
1261       Utils can decompress files with any lc and lp, but always creates files
1262       with lc=3 and lp=0.  Creating files with other lc and  lp  is  possible
1263       with xz and with LZMA SDK.
1264
1265       The implementation of the LZMA1 filter in liblzma requires that the sum
1266       of lc and lp must not exceed 4.  Thus, .lzma files, which  exceed  this
1267       limitation, cannot be decompressed with xz.
1268
1269       LZMA Utils creates only .lzma files which have a dictionary size of 2^n
1270       (a power of 2) but accepts files with  any  dictionary  size.   liblzma
1271       accepts  only  .lzma files which have a dictionary size of 2^n or 2^n +
1272       2^(n-1).  This is to decrease  false  positives  when  detecting  .lzma
1273       files.
1274
1275       These limitations shouldn't be a problem in practice, since practically
1276       all .lzma files have been compressed with settings  that  liblzma  will
1277       accept.
1278
1279   Trailing garbage
1280       When  decompressing,  LZMA  Utils  silently ignore everything after the
1281       first .lzma stream.  In most situations, this  is  a  bug.   This  also
1282       means  that  LZMA  Utils don't support decompressing concatenated .lzma
1283       files.
1284
1285       If there is data left after the first .lzma stream,  xz  considers  the
1286       file  to  be  corrupt  unless --single-stream was used.  This may break
1287       obscure scripts which have assumed that trailing garbage is ignored.
1288

NOTES

1290   Compressed output may vary
1291       The exact compressed output produced from the same  uncompressed  input
1292       file may vary between XZ Utils versions even if compression options are
1293       identical.  This is because the encoder can be improved (faster or bet‐
1294       ter  compression)  without  affecting  the file format.  The output can
1295       vary even between different builds of the same  XZ  Utils  version,  if
1296       different build options are used.
1297
1298       The above means that once --rsyncable has been implemented, the result‐
1299       ing files won't necessarily be rsyncable unless both old and new  files
1300       have  been  compressed  with  the same xz version.  This problem can be
1301       fixed if a part of the encoder implementation is frozen to keep rsynca‐
1302       ble output stable across xz versions.
1303
1304   Embedded .xz decompressors
1305       Embedded .xz decompressor implementations like XZ Embedded don't neces‐
1306       sarily support files created with integrity check types other than none
1307       and   crc32.    Since  the  default  is  --check=crc64,  you  must  use
1308       --check=none or --check=crc32 when creating files for embedded systems.
1309
1310       Outside embedded systems, all .xz format decompressors support all  the
1311       check  types, or at least are able to decompress the file without veri‐
1312       fying the integrity check if the particular check is not supported.
1313
1314       XZ Embedded supports BCJ filters, but only with the default start  off‐
1315       set.
1316

EXAMPLES

1318   Basics
1319       Compress  the  file foo into foo.xz using the default compression level
1320       (-6), and remove foo if compression is successful:
1321
1322              xz foo
1323
1324       Decompress bar.xz into bar and don't remove bar.xz even  if  decompres‐
1325       sion is successful:
1326
1327              xz -dk bar.xz
1328
1329       Create  baz.tar.xz  with the preset -4e (-4 --extreme), which is slower
1330       than e.g. the default -6, but needs less  memory  for  compression  and
1331       decompression (48 MiB and 5 MiB, respectively):
1332
1333              tar cf - baz | xz -4e > baz.tar.xz
1334
1335       A mix of compressed and uncompressed files can be decompressed to stan‐
1336       dard output with a single command:
1337
1338              xz -dcf a.txt b.txt.xz c.txt d.txt.lzma > abcd.txt
1339
1340   Parallel compression of many files
1341       On GNU and *BSD, find(1) and xargs(1) can be used to  parallelize  com‐
1342       pression of many files:
1343
1344              find . -type f \! -name '*.xz' -print0 \
1345                  | xargs -0r -P4 -n16 xz -T1
1346
1347       The  -P  option  to  xargs(1) sets the number of parallel xz processes.
1348       The best value for the -n option depends on how many files there are to
1349       be  compressed.   If there are only a couple of files, the value should
1350       probably be 1; with tens of thousands of files, 100 or even more may be
1351       appropriate  to  reduce  the  number of xz processes that xargs(1) will
1352       eventually create.
1353
1354       The option -T1 for xz is there to force  it  to  single-threaded  mode,
1355       because xargs(1) is used to control the amount of parallelization.
1356
1357   Robot mode
1358       Calculate  how  many  bytes  have been saved in total after compressing
1359       multiple files:
1360
1361              xz --robot --list *.xz | awk '/^totals/{print $5-$4}'
1362
1363       A script may want to know that it is using new enough xz.  The  follow‐
1364       ing  sh(1)  script  checks that the version number of the xz tool is at
1365       least 5.0.0.  This method is compatible with old beta  versions,  which
1366       didn't support the --robot option:
1367
1368              if ! eval "$(xz --robot --version 2> /dev/null)" ||
1369                      [ "$XZ_VERSION" -lt 50000002 ]; then
1370                  echo "Your xz is too old."
1371              fi
1372              unset XZ_VERSION LIBLZMA_VERSION
1373
1374       Set a memory usage limit for decompression using XZ_OPT, but if a limit
1375       has already been set, don't increase it:
1376
1377              NEWLIM=$((123 << 20))  # 123 MiB
1378              OLDLIM=$(xz --robot --info-memory | cut -f3)
1379              if [ $OLDLIM -eq 0 -o $OLDLIM -gt $NEWLIM ]; then
1380                  XZ_OPT="$XZ_OPT --memlimit-decompress=$NEWLIM"
1381                  export XZ_OPT
1382              fi
1383
1384   Custom compressor filter chains
1385       The simplest use for custom filter chains is customizing a  LZMA2  pre‐
1386       set.   This  can  be useful, because the presets cover only a subset of
1387       the potentially useful combinations of compression settings.
1388
1389       The CompCPU columns of the tables from the descriptions of the  options
1390       -0  ...  -9  and  --extreme  are useful when customizing LZMA2 presets.
1391       Here are the relevant parts collected from those two tables:
1392
1393              Preset   CompCPU
1394               -0         0
1395               -1         1
1396               -2         2
1397               -3         3
1398               -4         4
1399               -5         5
1400               -6         6
1401               -5e        7
1402               -6e        8
1403
1404       If you know that a file requires somewhat big dictionary (e.g. 32  MiB)
1405       to  compress well, but you want to compress it quicker than xz -8 would
1406       do, a preset with a low CompCPU value (e.g. 1) can be modified to use a
1407       bigger dictionary:
1408
1409              xz --lzma2=preset=1,dict=32MiB foo.tar
1410
1411       With  certain  files,  the above command may be faster than xz -6 while
1412       compressing significantly better.  However, it must be emphasized  that
1413       only some files benefit from a big dictionary while keeping the CompCPU
1414       value low.  The most obvious situation, where a big dictionary can help
1415       a  lot,  is  an archive containing very similar files of at least a few
1416       megabytes each.  The dictionary size has  to  be  significantly  bigger
1417       than  any  individual file to allow LZMA2 to take full advantage of the
1418       similarities between consecutive files.
1419
1420       If very high compressor and decompressor memory usage is fine, and  the
1421       file  being compressed is at least several hundred megabytes, it may be
1422       useful to use an even bigger dictionary than the  64  MiB  that  xz  -9
1423       would use:
1424
1425              xz -vv --lzma2=dict=192MiB big_foo.tar
1426
1427       Using -vv (--verbose --verbose) like in the above example can be useful
1428       to see the memory requirements  of  the  compressor  and  decompressor.
1429       Remember  that  using  a  dictionary bigger than the size of the uncom‐
1430       pressed file is waste of memory, so the above command isn't useful  for
1431       small files.
1432
1433       Sometimes  the  compression  time  doesn't matter, but the decompressor
1434       memory usage has to be kept low e.g. to make it possible to  decompress
1435       the  file  on  an  embedded system.  The following command uses -6e (-6
1436       --extreme) as a base and sets  the  dictionary  to  only  64 KiB.   The
1437       resulting  file  can be decompressed with XZ Embedded (that's why there
1438       is --check=crc32) using about 100 KiB of memory.
1439
1440              xz --check=crc32 --lzma2=preset=6e,dict=64KiB foo
1441
1442       If you want to squeeze out as many bytes  as  possible,  adjusting  the
1443       number  of  literal  context bits (lc) and number of position bits (pb)
1444       can sometimes help.  Adjusting the number of literal position bits (lp)
1445       might  help  too,  but  usually  lc  and pb are more important.  E.g. a
1446       source code archive contains mostly US-ASCII text,  so  something  like
1447       the following might give slightly (like 0.1 %) smaller file than xz -6e
1448       (try also without lc=4):
1449
1450              xz --lzma2=preset=6e,pb=0,lc=4 source_code.tar
1451
1452       Using another filter together with LZMA2 can improve  compression  with
1453       certain file types.  E.g. to compress a x86-32 or x86-64 shared library
1454       using the x86 BCJ filter:
1455
1456              xz --x86 --lzma2 libfoo.so
1457
1458       Note that the order of the filter options is significant.  If --x86  is
1459       specified after --lzma2, xz will give an error, because there cannot be
1460       any filter after LZMA2, and also because the x86 BCJ filter  cannot  be
1461       used as the last filter in the chain.
1462
1463       The  Delta filter together with LZMA2 can give good results with bitmap
1464       images.  It should usually beat PNG, which has a few more advanced fil‐
1465       ters than simple delta but uses Deflate for the actual compression.
1466
1467       The  image has to be saved in uncompressed format, e.g. as uncompressed
1468       TIFF.  The distance parameter of the Delta filter is set to  match  the
1469       number  of  bytes per pixel in the image.  E.g. 24-bit RGB bitmap needs
1470       dist=3, and it is also good to pass pb=0 to LZMA2  to  accommodate  the
1471       three-byte alignment:
1472
1473              xz --delta=dist=3 --lzma2=pb=0 foo.tiff
1474
1475       If multiple images have been put into a single archive (e.g. .tar), the
1476       Delta filter will work on that too as long as all images have the  same
1477       number of bytes per pixel.
1478

SEE ALSO

1480       xzdec(1),   xzdiff(1),   xzgrep(1),   xzless(1),   xzmore(1),  gzip(1),
1481       bzip2(1), 7z(1)
1482
1483       XZ Utils: <https://tukaani.org/xz/>
1484       XZ Embedded: <https://tukaani.org/xz/embedded.html>
1485       LZMA SDK: <http://7-zip.org/sdk.html>
1486
1487
1488
1489Tukaani                           2020-02-01                             XZ(1)
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