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Add bzip2, zlib, liblo, portaudio sources
author Chris Cannam
date Wed, 20 Mar 2013 13:59:52 +0000
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Chris@4 1 bzip2(1) bzip2(1)
Chris@4 2
Chris@4 3
Chris@4 4
Chris@4 5 NNAAMMEE
Chris@4 6 bzip2, bunzip2 − a block‐sorting file compressor, v1.0.6
Chris@4 7 bzcat − decompresses files to stdout
Chris@4 8 bzip2recover − recovers data from damaged bzip2 files
Chris@4 9
Chris@4 10
Chris@4 11 SSYYNNOOPPSSIISS
Chris@4 12 bbzziipp22 [ −−ccddffkkqqssttvvzzVVLL112233445566778899 ] [ _f_i_l_e_n_a_m_e_s _._._. ]
Chris@4 13 bbuunnzziipp22 [ −−ffkkvvssVVLL ] [ _f_i_l_e_n_a_m_e_s _._._. ]
Chris@4 14 bbzzccaatt [ −−ss ] [ _f_i_l_e_n_a_m_e_s _._._. ]
Chris@4 15 bbzziipp22rreeccoovveerr _f_i_l_e_n_a_m_e
Chris@4 16
Chris@4 17
Chris@4 18 DDEESSCCRRIIPPTTIIOONN
Chris@4 19 _b_z_i_p_2 compresses files using the Burrows‐Wheeler block
Chris@4 20 sorting text compression algorithm, and Huffman coding.
Chris@4 21 Compression is generally considerably better than that
Chris@4 22 achieved by more conventional LZ77/LZ78‐based compressors,
Chris@4 23 and approaches the performance of the PPM family of sta­
Chris@4 24 tistical compressors.
Chris@4 25
Chris@4 26 The command‐line options are deliberately very similar to
Chris@4 27 those of _G_N_U _g_z_i_p_, but they are not identical.
Chris@4 28
Chris@4 29 _b_z_i_p_2 expects a list of file names to accompany the com­
Chris@4 30 mand‐line flags. Each file is replaced by a compressed
Chris@4 31 version of itself, with the name "original_name.bz2".
Chris@4 32 Each compressed file has the same modification date, per­
Chris@4 33 missions, and, when possible, ownership as the correspond­
Chris@4 34 ing original, so that these properties can be correctly
Chris@4 35 restored at decompression time. File name handling is
Chris@4 36 naive in the sense that there is no mechanism for preserv­
Chris@4 37 ing original file names, permissions, ownerships or dates
Chris@4 38 in filesystems which lack these concepts, or have serious
Chris@4 39 file name length restrictions, such as MS‐DOS.
Chris@4 40
Chris@4 41 _b_z_i_p_2 and _b_u_n_z_i_p_2 will by default not overwrite existing
Chris@4 42 files. If you want this to happen, specify the −f flag.
Chris@4 43
Chris@4 44 If no file names are specified, _b_z_i_p_2 compresses from
Chris@4 45 standard input to standard output. In this case, _b_z_i_p_2
Chris@4 46 will decline to write compressed output to a terminal, as
Chris@4 47 this would be entirely incomprehensible and therefore
Chris@4 48 pointless.
Chris@4 49
Chris@4 50 _b_u_n_z_i_p_2 (or _b_z_i_p_2 _−_d_) decompresses all specified files.
Chris@4 51 Files which were not created by _b_z_i_p_2 will be detected and
Chris@4 52 ignored, and a warning issued. _b_z_i_p_2 attempts to guess
Chris@4 53 the filename for the decompressed file from that of the
Chris@4 54 compressed file as follows:
Chris@4 55
Chris@4 56 filename.bz2 becomes filename
Chris@4 57 filename.bz becomes filename
Chris@4 58 filename.tbz2 becomes filename.tar
Chris@4 59 filename.tbz becomes filename.tar
Chris@4 60 anyothername becomes anyothername.out
Chris@4 61
Chris@4 62 If the file does not end in one of the recognised endings,
Chris@4 63 _._b_z_2_, _._b_z_, _._t_b_z_2 or _._t_b_z_, _b_z_i_p_2 complains that it cannot
Chris@4 64 guess the name of the original file, and uses the original
Chris@4 65 name with _._o_u_t appended.
Chris@4 66
Chris@4 67 As with compression, supplying no filenames causes decom­
Chris@4 68 pression from standard input to standard output.
Chris@4 69
Chris@4 70 _b_u_n_z_i_p_2 will correctly decompress a file which is the con­
Chris@4 71 catenation of two or more compressed files. The result is
Chris@4 72 the concatenation of the corresponding uncompressed files.
Chris@4 73 Integrity testing (−t) of concatenated compressed files is
Chris@4 74 also supported.
Chris@4 75
Chris@4 76 You can also compress or decompress files to the standard
Chris@4 77 output by giving the −c flag. Multiple files may be com­
Chris@4 78 pressed and decompressed like this. The resulting outputs
Chris@4 79 are fed sequentially to stdout. Compression of multiple
Chris@4 80 files in this manner generates a stream containing multi­
Chris@4 81 ple compressed file representations. Such a stream can be
Chris@4 82 decompressed correctly only by _b_z_i_p_2 version 0.9.0 or
Chris@4 83 later. Earlier versions of _b_z_i_p_2 will stop after decom­
Chris@4 84 pressing the first file in the stream.
Chris@4 85
Chris@4 86 _b_z_c_a_t (or _b_z_i_p_2 _‐_d_c_) decompresses all specified files to
Chris@4 87 the standard output.
Chris@4 88
Chris@4 89 _b_z_i_p_2 will read arguments from the environment variables
Chris@4 90 _B_Z_I_P_2 and _B_Z_I_P_, in that order, and will process them
Chris@4 91 before any arguments read from the command line. This
Chris@4 92 gives a convenient way to supply default arguments.
Chris@4 93
Chris@4 94 Compression is always performed, even if the compressed
Chris@4 95 file is slightly larger than the original. Files of less
Chris@4 96 than about one hundred bytes tend to get larger, since the
Chris@4 97 compression mechanism has a constant overhead in the
Chris@4 98 region of 50 bytes. Random data (including the output of
Chris@4 99 most file compressors) is coded at about 8.05 bits per
Chris@4 100 byte, giving an expansion of around 0.5%.
Chris@4 101
Chris@4 102 As a self‐check for your protection, _b_z_i_p_2 uses 32‐bit
Chris@4 103 CRCs to make sure that the decompressed version of a file
Chris@4 104 is identical to the original. This guards against corrup­
Chris@4 105 tion of the compressed data, and against undetected bugs
Chris@4 106 in _b_z_i_p_2 (hopefully very unlikely). The chances of data
Chris@4 107 corruption going undetected is microscopic, about one
Chris@4 108 chance in four billion for each file processed. Be aware,
Chris@4 109 though, that the check occurs upon decompression, so it
Chris@4 110 can only tell you that something is wrong. It can’t help
Chris@4 111 you recover the original uncompressed data. You can use
Chris@4 112 _b_z_i_p_2_r_e_c_o_v_e_r to try to recover data from damaged files.
Chris@4 113
Chris@4 114 Return values: 0 for a normal exit, 1 for environmental
Chris@4 115 problems (file not found, invalid flags, I/O errors, &c),
Chris@4 116 2 to indicate a corrupt compressed file, 3 for an internal
Chris@4 117 consistency error (eg, bug) which caused _b_z_i_p_2 to panic.
Chris@4 118
Chris@4 119
Chris@4 120 OOPPTTIIOONNSS
Chris@4 121 −−cc ‐‐‐‐ssttddoouutt
Chris@4 122 Compress or decompress to standard output.
Chris@4 123
Chris@4 124 −−dd ‐‐‐‐ddeeccoommpprreessss
Chris@4 125 Force decompression. _b_z_i_p_2_, _b_u_n_z_i_p_2 and _b_z_c_a_t are
Chris@4 126 really the same program, and the decision about
Chris@4 127 what actions to take is done on the basis of which
Chris@4 128 name is used. This flag overrides that mechanism,
Chris@4 129 and forces _b_z_i_p_2 to decompress.
Chris@4 130
Chris@4 131 −−zz ‐‐‐‐ccoommpprreessss
Chris@4 132 The complement to −d: forces compression,
Chris@4 133 regardless of the invocation name.
Chris@4 134
Chris@4 135 −−tt ‐‐‐‐tteesstt
Chris@4 136 Check integrity of the specified file(s), but don’t
Chris@4 137 decompress them. This really performs a trial
Chris@4 138 decompression and throws away the result.
Chris@4 139
Chris@4 140 −−ff ‐‐‐‐ffoorrccee
Chris@4 141 Force overwrite of output files. Normally, _b_z_i_p_2
Chris@4 142 will not overwrite existing output files. Also
Chris@4 143 forces _b_z_i_p_2 to break hard links to files, which it
Chris@4 144 otherwise wouldn’t do.
Chris@4 145
Chris@4 146 bzip2 normally declines to decompress files which
Chris@4 147 don’t have the correct magic header bytes. If
Chris@4 148 forced (‐f), however, it will pass such files
Chris@4 149 through unmodified. This is how GNU gzip behaves.
Chris@4 150
Chris@4 151 −−kk ‐‐‐‐kkeeeepp
Chris@4 152 Keep (don’t delete) input files during compression
Chris@4 153 or decompression.
Chris@4 154
Chris@4 155 −−ss ‐‐‐‐ssmmaallll
Chris@4 156 Reduce memory usage, for compression, decompression
Chris@4 157 and testing. Files are decompressed and tested
Chris@4 158 using a modified algorithm which only requires 2.5
Chris@4 159 bytes per block byte. This means any file can be
Chris@4 160 decompressed in 2300k of memory, albeit at about
Chris@4 161 half the normal speed.
Chris@4 162
Chris@4 163 During compression, −s selects a block size of
Chris@4 164 200k, which limits memory use to around the same
Chris@4 165 figure, at the expense of your compression ratio.
Chris@4 166 In short, if your machine is low on memory (8
Chris@4 167 megabytes or less), use −s for everything. See
Chris@4 168 MEMORY MANAGEMENT below.
Chris@4 169
Chris@4 170 −−qq ‐‐‐‐qquuiieett
Chris@4 171 Suppress non‐essential warning messages. Messages
Chris@4 172 pertaining to I/O errors and other critical events
Chris@4 173 will not be suppressed.
Chris@4 174
Chris@4 175 −−vv ‐‐‐‐vveerrbboossee
Chris@4 176 Verbose mode ‐‐ show the compression ratio for each
Chris@4 177 file processed. Further −v’s increase the ver­
Chris@4 178 bosity level, spewing out lots of information which
Chris@4 179 is primarily of interest for diagnostic purposes.
Chris@4 180
Chris@4 181 −−LL ‐‐‐‐lliicceennssee ‐‐VV ‐‐‐‐vveerrssiioonn
Chris@4 182 Display the software version, license terms and
Chris@4 183 conditions.
Chris@4 184
Chris@4 185 −−11 ((oorr −−−−ffaasstt)) ttoo −−99 ((oorr −−−−bbeesstt))
Chris@4 186 Set the block size to 100 k, 200 k .. 900 k when
Chris@4 187 compressing. Has no effect when decompressing.
Chris@4 188 See MEMORY MANAGEMENT below. The −−fast and −−best
Chris@4 189 aliases are primarily for GNU gzip compatibility.
Chris@4 190 In particular, −−fast doesn’t make things signifi­
Chris@4 191 cantly faster. And −−best merely selects the
Chris@4 192 default behaviour.
Chris@4 193
Chris@4 194 −−‐‐ Treats all subsequent arguments as file names, even
Chris@4 195 if they start with a dash. This is so you can han­
Chris@4 196 dle files with names beginning with a dash, for
Chris@4 197 example: bzip2 −‐ −myfilename.
Chris@4 198
Chris@4 199 −−‐‐rreeppeettiittiivvee‐‐ffaasstt ‐‐‐‐rreeppeettiittiivvee‐‐bbeesstt
Chris@4 200 These flags are redundant in versions 0.9.5 and
Chris@4 201 above. They provided some coarse control over the
Chris@4 202 behaviour of the sorting algorithm in earlier ver­
Chris@4 203 sions, which was sometimes useful. 0.9.5 and above
Chris@4 204 have an improved algorithm which renders these
Chris@4 205 flags irrelevant.
Chris@4 206
Chris@4 207
Chris@4 208 MMEEMMOORRYY MMAANNAAGGEEMMEENNTT
Chris@4 209 _b_z_i_p_2 compresses large files in blocks. The block size
Chris@4 210 affects both the compression ratio achieved, and the
Chris@4 211 amount of memory needed for compression and decompression.
Chris@4 212 The flags −1 through −9 specify the block size to be
Chris@4 213 100,000 bytes through 900,000 bytes (the default) respec­
Chris@4 214 tively. At decompression time, the block size used for
Chris@4 215 compression is read from the header of the compressed
Chris@4 216 file, and _b_u_n_z_i_p_2 then allocates itself just enough memory
Chris@4 217 to decompress the file. Since block sizes are stored in
Chris@4 218 compressed files, it follows that the flags −1 to −9 are
Chris@4 219 irrelevant to and so ignored during decompression.
Chris@4 220
Chris@4 221 Compression and decompression requirements, in bytes, can
Chris@4 222 be estimated as:
Chris@4 223
Chris@4 224 Compression: 400k + ( 8 x block size )
Chris@4 225
Chris@4 226 Decompression: 100k + ( 4 x block size ), or
Chris@4 227 100k + ( 2.5 x block size )
Chris@4 228
Chris@4 229 Larger block sizes give rapidly diminishing marginal
Chris@4 230 returns. Most of the compression comes from the first two
Chris@4 231 or three hundred k of block size, a fact worth bearing in
Chris@4 232 mind when using _b_z_i_p_2 on small machines. It is also
Chris@4 233 important to appreciate that the decompression memory
Chris@4 234 requirement is set at compression time by the choice of
Chris@4 235 block size.
Chris@4 236
Chris@4 237 For files compressed with the default 900k block size,
Chris@4 238 _b_u_n_z_i_p_2 will require about 3700 kbytes to decompress. To
Chris@4 239 support decompression of any file on a 4 megabyte machine,
Chris@4 240 _b_u_n_z_i_p_2 has an option to decompress using approximately
Chris@4 241 half this amount of memory, about 2300 kbytes. Decompres­
Chris@4 242 sion speed is also halved, so you should use this option
Chris@4 243 only where necessary. The relevant flag is ‐s.
Chris@4 244
Chris@4 245 In general, try and use the largest block size memory con­
Chris@4 246 straints allow, since that maximises the compression
Chris@4 247 achieved. Compression and decompression speed are virtu­
Chris@4 248 ally unaffected by block size.
Chris@4 249
Chris@4 250 Another significant point applies to files which fit in a
Chris@4 251 single block ‐‐ that means most files you’d encounter
Chris@4 252 using a large block size. The amount of real memory
Chris@4 253 touched is proportional to the size of the file, since the
Chris@4 254 file is smaller than a block. For example, compressing a
Chris@4 255 file 20,000 bytes long with the flag ‐9 will cause the
Chris@4 256 compressor to allocate around 7600k of memory, but only
Chris@4 257 touch 400k + 20000 * 8 = 560 kbytes of it. Similarly, the
Chris@4 258 decompressor will allocate 3700k but only touch 100k +
Chris@4 259 20000 * 4 = 180 kbytes.
Chris@4 260
Chris@4 261 Here is a table which summarises the maximum memory usage
Chris@4 262 for different block sizes. Also recorded is the total
Chris@4 263 compressed size for 14 files of the Calgary Text Compres­
Chris@4 264 sion Corpus totalling 3,141,622 bytes. This column gives
Chris@4 265 some feel for how compression varies with block size.
Chris@4 266 These figures tend to understate the advantage of larger
Chris@4 267 block sizes for larger files, since the Corpus is domi­
Chris@4 268 nated by smaller files.
Chris@4 269
Chris@4 270 Compress Decompress Decompress Corpus
Chris@4 271 Flag usage usage ‐s usage Size
Chris@4 272
Chris@4 273 ‐1 1200k 500k 350k 914704
Chris@4 274 ‐2 2000k 900k 600k 877703
Chris@4 275 ‐3 2800k 1300k 850k 860338
Chris@4 276 ‐4 3600k 1700k 1100k 846899
Chris@4 277 ‐5 4400k 2100k 1350k 845160
Chris@4 278 ‐6 5200k 2500k 1600k 838626
Chris@4 279 ‐7 6100k 2900k 1850k 834096
Chris@4 280 ‐8 6800k 3300k 2100k 828642
Chris@4 281 ‐9 7600k 3700k 2350k 828642
Chris@4 282
Chris@4 283
Chris@4 284 RREECCOOVVEERRIINNGG DDAATTAA FFRROOMM DDAAMMAAGGEEDD FFIILLEESS
Chris@4 285 _b_z_i_p_2 compresses files in blocks, usually 900kbytes long.
Chris@4 286 Each block is handled independently. If a media or trans­
Chris@4 287 mission error causes a multi‐block .bz2 file to become
Chris@4 288 damaged, it may be possible to recover data from the
Chris@4 289 undamaged blocks in the file.
Chris@4 290
Chris@4 291 The compressed representation of each block is delimited
Chris@4 292 by a 48‐bit pattern, which makes it possible to find the
Chris@4 293 block boundaries with reasonable certainty. Each block
Chris@4 294 also carries its own 32‐bit CRC, so damaged blocks can be
Chris@4 295 distinguished from undamaged ones.
Chris@4 296
Chris@4 297 _b_z_i_p_2_r_e_c_o_v_e_r is a simple program whose purpose is to
Chris@4 298 search for blocks in .bz2 files, and write each block out
Chris@4 299 into its own .bz2 file. You can then use _b_z_i_p_2 −t to test
Chris@4 300 the integrity of the resulting files, and decompress those
Chris@4 301 which are undamaged.
Chris@4 302
Chris@4 303 _b_z_i_p_2_r_e_c_o_v_e_r takes a single argument, the name of the dam­
Chris@4 304 aged file, and writes a number of files
Chris@4 305 "rec00001file.bz2", "rec00002file.bz2", etc, containing
Chris@4 306 the extracted blocks. The output filenames are
Chris@4 307 designed so that the use of wildcards in subsequent pro­
Chris@4 308 cessing ‐‐ for example, "bzip2 ‐dc rec*file.bz2 > recov­
Chris@4 309 ered_data" ‐‐ processes the files in the correct order.
Chris@4 310
Chris@4 311 _b_z_i_p_2_r_e_c_o_v_e_r should be of most use dealing with large .bz2
Chris@4 312 files, as these will contain many blocks. It is clearly
Chris@4 313 futile to use it on damaged single‐block files, since a
Chris@4 314 damaged block cannot be recovered. If you wish to min­
Chris@4 315 imise any potential data loss through media or transmis­
Chris@4 316 sion errors, you might consider compressing with a smaller
Chris@4 317 block size.
Chris@4 318
Chris@4 319
Chris@4 320 PPEERRFFOORRMMAANNCCEE NNOOTTEESS
Chris@4 321 The sorting phase of compression gathers together similar
Chris@4 322 strings in the file. Because of this, files containing
Chris@4 323 very long runs of repeated symbols, like "aabaabaabaab
Chris@4 324 ..." (repeated several hundred times) may compress more
Chris@4 325 slowly than normal. Versions 0.9.5 and above fare much
Chris@4 326 better than previous versions in this respect. The ratio
Chris@4 327 between worst‐case and average‐case compression time is in
Chris@4 328 the region of 10:1. For previous versions, this figure
Chris@4 329 was more like 100:1. You can use the −vvvv option to mon­
Chris@4 330 itor progress in great detail, if you want.
Chris@4 331
Chris@4 332 Decompression speed is unaffected by these phenomena.
Chris@4 333
Chris@4 334 _b_z_i_p_2 usually allocates several megabytes of memory to
Chris@4 335 operate in, and then charges all over it in a fairly ran­
Chris@4 336 dom fashion. This means that performance, both for com­
Chris@4 337 pressing and decompressing, is largely determined by the
Chris@4 338 speed at which your machine can service cache misses.
Chris@4 339 Because of this, small changes to the code to reduce the
Chris@4 340 miss rate have been observed to give disproportionately
Chris@4 341 large performance improvements. I imagine _b_z_i_p_2 will per­
Chris@4 342 form best on machines with very large caches.
Chris@4 343
Chris@4 344
Chris@4 345 CCAAVVEEAATTSS
Chris@4 346 I/O error messages are not as helpful as they could be.
Chris@4 347 _b_z_i_p_2 tries hard to detect I/O errors and exit cleanly,
Chris@4 348 but the details of what the problem is sometimes seem
Chris@4 349 rather misleading.
Chris@4 350
Chris@4 351 This manual page pertains to version 1.0.6 of _b_z_i_p_2_. Com­
Chris@4 352 pressed data created by this version is entirely forwards
Chris@4 353 and backwards compatible with the previous public
Chris@4 354 releases, versions 0.1pl2, 0.9.0, 0.9.5, 1.0.0, 1.0.1,
Chris@4 355 1.0.2 and above, but with the following exception: 0.9.0
Chris@4 356 and above can correctly decompress multiple concatenated
Chris@4 357 compressed files. 0.1pl2 cannot do this; it will stop
Chris@4 358 after decompressing just the first file in the stream.
Chris@4 359
Chris@4 360 _b_z_i_p_2_r_e_c_o_v_e_r versions prior to 1.0.2 used 32‐bit integers
Chris@4 361 to represent bit positions in compressed files, so they
Chris@4 362 could not handle compressed files more than 512 megabytes
Chris@4 363 long. Versions 1.0.2 and above use 64‐bit ints on some
Chris@4 364 platforms which support them (GNU supported targets, and
Chris@4 365 Windows). To establish whether or not bzip2recover was
Chris@4 366 built with such a limitation, run it without arguments.
Chris@4 367 In any event you can build yourself an unlimited version
Chris@4 368 if you can recompile it with MaybeUInt64 set to be an
Chris@4 369 unsigned 64‐bit integer.
Chris@4 370
Chris@4 371
Chris@4 372
Chris@4 373
Chris@4 374 AAUUTTHHOORR
Chris@4 375 Julian Seward, jsewardbzip.org.
Chris@4 376
Chris@4 377 http://www.bzip.org
Chris@4 378
Chris@4 379 The ideas embodied in _b_z_i_p_2 are due to (at least) the fol­
Chris@4 380 lowing people: Michael Burrows and David Wheeler (for the
Chris@4 381 block sorting transformation), David Wheeler (again, for
Chris@4 382 the Huffman coder), Peter Fenwick (for the structured cod­
Chris@4 383 ing model in the original _b_z_i_p_, and many refinements), and
Chris@4 384 Alistair Moffat, Radford Neal and Ian Witten (for the
Chris@4 385 arithmetic coder in the original _b_z_i_p_)_. I am much
Chris@4 386 indebted for their help, support and advice. See the man­
Chris@4 387 ual in the source distribution for pointers to sources of
Chris@4 388 documentation. Christian von Roques encouraged me to look
Chris@4 389 for faster sorting algorithms, so as to speed up compres­
Chris@4 390 sion. Bela Lubkin encouraged me to improve the worst‐case
Chris@4 391 compression performance. Donna Robinson XMLised the docu­
Chris@4 392 mentation. The bz* scripts are derived from those of GNU
Chris@4 393 gzip. Many people sent patches, helped with portability
Chris@4 394 problems, lent machines, gave advice and were generally
Chris@4 395 helpful.
Chris@4 396
Chris@4 397
Chris@4 398
Chris@4 399 bzip2(1)