source: s10k/CommonLibs/zlib-1.2.8/doc/rfc1951.txt@ 1109

Last change on this file since 1109 was 1096, checked in by s10k, 7 years ago

Added zlib, quazip, basicxmlsyntaxhighlighter, conditionalsemaphore and linenumberdisplay libraries. zlib and quazip are pre-compiled, but you can compile them yourself, just delete the dll files (or equivalent binary files to your OS)

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7Network Working Group P. Deutsch
8Request for Comments: 1951 Aladdin Enterprises
9Category: Informational May 1996
10
11
12 DEFLATE Compressed Data Format Specification version 1.3
13
14Status of This Memo
15
16 This memo provides information for the Internet community. This memo
17 does not specify an Internet standard of any kind. Distribution of
18 this memo is unlimited.
19
20IESG Note:
21
22 The IESG takes no position on the validity of any Intellectual
23 Property Rights statements contained in this document.
24
25Notices
26
27 Copyright (c) 1996 L. Peter Deutsch
28
29 Permission is granted to copy and distribute this document for any
30 purpose and without charge, including translations into other
31 languages and incorporation into compilations, provided that the
32 copyright notice and this notice are preserved, and that any
33 substantive changes or deletions from the original are clearly
34 marked.
35
36 A pointer to the latest version of this and related documentation in
37 HTML format can be found at the URL
38 <ftp://ftp.uu.net/graphics/png/documents/zlib/zdoc-index.html>.
39
40Abstract
41
42 This specification defines a lossless compressed data format that
43 compresses data using a combination of the LZ77 algorithm and Huffman
44 coding, with efficiency comparable to the best currently available
45 general-purpose compression methods. The data can be produced or
46 consumed, even for an arbitrarily long sequentially presented input
47 data stream, using only an a priori bounded amount of intermediate
48 storage. The format can be implemented readily in a manner not
49 covered by patents.
50
51
52
53
54
55
56
57
58Deutsch Informational [Page 1]
59
60
61RFC 1951 DEFLATE Compressed Data Format Specification May 1996
62
63
64Table of Contents
65
66 1. Introduction ................................................... 2
67 1.1. Purpose ................................................... 2
68 1.2. Intended audience ......................................... 3
69 1.3. Scope ..................................................... 3
70 1.4. Compliance ................................................ 3
71 1.5. Definitions of terms and conventions used ................ 3
72 1.6. Changes from previous versions ............................ 4
73 2. Compressed representation overview ............................. 4
74 3. Detailed specification ......................................... 5
75 3.1. Overall conventions ....................................... 5
76 3.1.1. Packing into bytes .................................. 5
77 3.2. Compressed block format ................................... 6
78 3.2.1. Synopsis of prefix and Huffman coding ............... 6
79 3.2.2. Use of Huffman coding in the "deflate" format ....... 7
80 3.2.3. Details of block format ............................. 9
81 3.2.4. Non-compressed blocks (BTYPE=00) ................... 11
82 3.2.5. Compressed blocks (length and distance codes) ...... 11
83 3.2.6. Compression with fixed Huffman codes (BTYPE=01) .... 12
84 3.2.7. Compression with dynamic Huffman codes (BTYPE=10) .. 13
85 3.3. Compliance ............................................... 14
86 4. Compression algorithm details ................................. 14
87 5. References .................................................... 16
88 6. Security Considerations ....................................... 16
89 7. Source code ................................................... 16
90 8. Acknowledgements .............................................. 16
91 9. Author's Address .............................................. 17
92
931. Introduction
94
95 1.1. Purpose
96
97 The purpose of this specification is to define a lossless
98 compressed data format that:
99 * Is independent of CPU type, operating system, file system,
100 and character set, and hence can be used for interchange;
101 * Can be produced or consumed, even for an arbitrarily long
102 sequentially presented input data stream, using only an a
103 priori bounded amount of intermediate storage, and hence
104 can be used in data communications or similar structures
105 such as Unix filters;
106 * Compresses data with efficiency comparable to the best
107 currently available general-purpose compression methods,
108 and in particular considerably better than the "compress"
109 program;
110 * Can be implemented readily in a manner not covered by
111 patents, and hence can be practiced freely;
112
113
114
115Deutsch Informational [Page 2]
116
117
118RFC 1951 DEFLATE Compressed Data Format Specification May 1996
119
120
121 * Is compatible with the file format produced by the current
122 widely used gzip utility, in that conforming decompressors
123 will be able to read data produced by the existing gzip
124 compressor.
125
126 The data format defined by this specification does not attempt to:
127
128 * Allow random access to compressed data;
129 * Compress specialized data (e.g., raster graphics) as well
130 as the best currently available specialized algorithms.
131
132 A simple counting argument shows that no lossless compression
133 algorithm can compress every possible input data set. For the
134 format defined here, the worst case expansion is 5 bytes per 32K-
135 byte block, i.e., a size increase of 0.015% for large data sets.
136 English text usually compresses by a factor of 2.5 to 3;
137 executable files usually compress somewhat less; graphical data
138 such as raster images may compress much more.
139
140 1.2. Intended audience
141
142 This specification is intended for use by implementors of software
143 to compress data into "deflate" format and/or decompress data from
144 "deflate" format.
145
146 The text of the specification assumes a basic background in
147 programming at the level of bits and other primitive data
148 representations. Familiarity with the technique of Huffman coding
149 is helpful but not required.
150
151 1.3. Scope
152
153 The specification specifies a method for representing a sequence
154 of bytes as a (usually shorter) sequence of bits, and a method for
155 packing the latter bit sequence into bytes.
156
157 1.4. Compliance
158
159 Unless otherwise indicated below, a compliant decompressor must be
160 able to accept and decompress any data set that conforms to all
161 the specifications presented here; a compliant compressor must
162 produce data sets that conform to all the specifications presented
163 here.
164
165 1.5. Definitions of terms and conventions used
166
167 Byte: 8 bits stored or transmitted as a unit (same as an octet).
168 For this specification, a byte is exactly 8 bits, even on machines
169
170
171
172Deutsch Informational [Page 3]
173
174
175RFC 1951 DEFLATE Compressed Data Format Specification May 1996
176
177
178 which store a character on a number of bits different from eight.
179 See below, for the numbering of bits within a byte.
180
181 String: a sequence of arbitrary bytes.
182
183 1.6. Changes from previous versions
184
185 There have been no technical changes to the deflate format since
186 version 1.1 of this specification. In version 1.2, some
187 terminology was changed. Version 1.3 is a conversion of the
188 specification to RFC style.
189
1902. Compressed representation overview
191
192 A compressed data set consists of a series of blocks, corresponding
193 to successive blocks of input data. The block sizes are arbitrary,
194 except that non-compressible blocks are limited to 65,535 bytes.
195
196 Each block is compressed using a combination of the LZ77 algorithm
197 and Huffman coding. The Huffman trees for each block are independent
198 of those for previous or subsequent blocks; the LZ77 algorithm may
199 use a reference to a duplicated string occurring in a previous block,
200 up to 32K input bytes before.
201
202 Each block consists of two parts: a pair of Huffman code trees that
203 describe the representation of the compressed data part, and a
204 compressed data part. (The Huffman trees themselves are compressed
205 using Huffman encoding.) The compressed data consists of a series of
206 elements of two types: literal bytes (of strings that have not been
207 detected as duplicated within the previous 32K input bytes), and
208 pointers to duplicated strings, where a pointer is represented as a
209 pair <length, backward distance>. The representation used in the
210 "deflate" format limits distances to 32K bytes and lengths to 258
211 bytes, but does not limit the size of a block, except for
212 uncompressible blocks, which are limited as noted above.
213
214 Each type of value (literals, distances, and lengths) in the
215 compressed data is represented using a Huffman code, using one code
216 tree for literals and lengths and a separate code tree for distances.
217 The code trees for each block appear in a compact form just before
218 the compressed data for that block.
219
220
221
222
223
224
225
226
227
228
229Deutsch Informational [Page 4]
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231
232RFC 1951 DEFLATE Compressed Data Format Specification May 1996
233
234
2353. Detailed specification
236
237 3.1. Overall conventions In the diagrams below, a box like this:
238
239 +---+
240 | | <-- the vertical bars might be missing
241 +---+
242
243 represents one byte; a box like this:
244
245 +==============+
246 | |
247 +==============+
248
249 represents a variable number of bytes.
250
251 Bytes stored within a computer do not have a "bit order", since
252 they are always treated as a unit. However, a byte considered as
253 an integer between 0 and 255 does have a most- and least-
254 significant bit, and since we write numbers with the most-
255 significant digit on the left, we also write bytes with the most-
256 significant bit on the left. In the diagrams below, we number the
257 bits of a byte so that bit 0 is the least-significant bit, i.e.,
258 the bits are numbered:
259
260 +--------+
261 |76543210|
262 +--------+
263
264 Within a computer, a number may occupy multiple bytes. All
265 multi-byte numbers in the format described here are stored with
266 the least-significant byte first (at the lower memory address).
267 For example, the decimal number 520 is stored as:
268
269 0 1
270 +--------+--------+
271 |00001000|00000010|
272 +--------+--------+
273 ^ ^
274 | |
275 | + more significant byte = 2 x 256
276 + less significant byte = 8
277
278 3.1.1. Packing into bytes
279
280 This document does not address the issue of the order in which
281 bits of a byte are transmitted on a bit-sequential medium,
282 since the final data format described here is byte- rather than
283
284
285
286Deutsch Informational [Page 5]
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289RFC 1951 DEFLATE Compressed Data Format Specification May 1996
290
291
292 bit-oriented. However, we describe the compressed block format
293 in below, as a sequence of data elements of various bit
294 lengths, not a sequence of bytes. We must therefore specify
295 how to pack these data elements into bytes to form the final
296 compressed byte sequence:
297
298 * Data elements are packed into bytes in order of
299 increasing bit number within the byte, i.e., starting
300 with the least-significant bit of the byte.
301 * Data elements other than Huffman codes are packed
302 starting with the least-significant bit of the data
303 element.
304 * Huffman codes are packed starting with the most-
305 significant bit of the code.
306
307 In other words, if one were to print out the compressed data as
308 a sequence of bytes, starting with the first byte at the
309 *right* margin and proceeding to the *left*, with the most-
310 significant bit of each byte on the left as usual, one would be
311 able to parse the result from right to left, with fixed-width
312 elements in the correct MSB-to-LSB order and Huffman codes in
313 bit-reversed order (i.e., with the first bit of the code in the
314 relative LSB position).
315
316 3.2. Compressed block format
317
318 3.2.1. Synopsis of prefix and Huffman coding
319
320 Prefix coding represents symbols from an a priori known
321 alphabet by bit sequences (codes), one code for each symbol, in
322 a manner such that different symbols may be represented by bit
323 sequences of different lengths, but a parser can always parse
324 an encoded string unambiguously symbol-by-symbol.
325
326 We define a prefix code in terms of a binary tree in which the
327 two edges descending from each non-leaf node are labeled 0 and
328 1 and in which the leaf nodes correspond one-for-one with (are
329 labeled with) the symbols of the alphabet; then the code for a
330 symbol is the sequence of 0's and 1's on the edges leading from
331 the root to the leaf labeled with that symbol. For example:
332
333
334
335
336
337
338
339
340
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343Deutsch Informational [Page 6]
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346RFC 1951 DEFLATE Compressed Data Format Specification May 1996
347
348
349 /\ Symbol Code
350 0 1 ------ ----
351 / \ A 00
352 /\ B B 1
353 0 1 C 011
354 / \ D 010
355 A /\
356 0 1
357 / \
358 D C
359
360 A parser can decode the next symbol from an encoded input
361 stream by walking down the tree from the root, at each step
362 choosing the edge corresponding to the next input bit.
363
364 Given an alphabet with known symbol frequencies, the Huffman
365 algorithm allows the construction of an optimal prefix code
366 (one which represents strings with those symbol frequencies
367 using the fewest bits of any possible prefix codes for that
368 alphabet). Such a code is called a Huffman code. (See
369 reference [1] in Chapter 5, references for additional
370 information on Huffman codes.)
371
372 Note that in the "deflate" format, the Huffman codes for the
373 various alphabets must not exceed certain maximum code lengths.
374 This constraint complicates the algorithm for computing code
375 lengths from symbol frequencies. Again, see Chapter 5,
376 references for details.
377
378 3.2.2. Use of Huffman coding in the "deflate" format
379
380 The Huffman codes used for each alphabet in the "deflate"
381 format have two additional rules:
382
383 * All codes of a given bit length have lexicographically
384 consecutive values, in the same order as the symbols
385 they represent;
386
387 * Shorter codes lexicographically precede longer codes.
388
389
390
391
392
393
394
395
396
397
398
399
400Deutsch Informational [Page 7]
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402
403RFC 1951 DEFLATE Compressed Data Format Specification May 1996
404
405
406 We could recode the example above to follow this rule as
407 follows, assuming that the order of the alphabet is ABCD:
408
409 Symbol Code
410 ------ ----
411 A 10
412 B 0
413 C 110
414 D 111
415
416 I.e., 0 precedes 10 which precedes 11x, and 110 and 111 are
417 lexicographically consecutive.
418
419 Given this rule, we can define the Huffman code for an alphabet
420 just by giving the bit lengths of the codes for each symbol of
421 the alphabet in order; this is sufficient to determine the
422 actual codes. In our example, the code is completely defined
423 by the sequence of bit lengths (2, 1, 3, 3). The following
424 algorithm generates the codes as integers, intended to be read
425 from most- to least-significant bit. The code lengths are
426 initially in tree[I].Len; the codes are produced in
427 tree[I].Code.
428
429 1) Count the number of codes for each code length. Let
430 bl_count[N] be the number of codes of length N, N >= 1.
431
432 2) Find the numerical value of the smallest code for each
433 code length:
434
435 code = 0;
436 bl_count[0] = 0;
437 for (bits = 1; bits <= MAX_BITS; bits++) {
438 code = (code + bl_count[bits-1]) << 1;
439 next_code[bits] = code;
440 }
441
442 3) Assign numerical values to all codes, using consecutive
443 values for all codes of the same length with the base
444 values determined at step 2. Codes that are never used
445 (which have a bit length of zero) must not be assigned a
446 value.
447
448 for (n = 0; n <= max_code; n++) {
449 len = tree[n].Len;
450 if (len != 0) {
451 tree[n].Code = next_code[len];
452 next_code[len]++;
453 }
454
455
456
457Deutsch Informational [Page 8]
458
459
460RFC 1951 DEFLATE Compressed Data Format Specification May 1996
461
462
463 }
464
465 Example:
466
467 Consider the alphabet ABCDEFGH, with bit lengths (3, 3, 3, 3,
468 3, 2, 4, 4). After step 1, we have:
469
470 N bl_count[N]
471 - -----------
472 2 1
473 3 5
474 4 2
475
476 Step 2 computes the following next_code values:
477
478 N next_code[N]
479 - ------------
480 1 0
481 2 0
482 3 2
483 4 14
484
485 Step 3 produces the following code values:
486
487 Symbol Length Code
488 ------ ------ ----
489 A 3 010
490 B 3 011
491 C 3 100
492 D 3 101
493 E 3 110
494 F 2 00
495 G 4 1110
496 H 4 1111
497
498 3.2.3. Details of block format
499
500 Each block of compressed data begins with 3 header bits
501 containing the following data:
502
503 first bit BFINAL
504 next 2 bits BTYPE
505
506 Note that the header bits do not necessarily begin on a byte
507 boundary, since a block does not necessarily occupy an integral
508 number of bytes.
509
510
511
512
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514Deutsch Informational [Page 9]
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517RFC 1951 DEFLATE Compressed Data Format Specification May 1996
518
519
520 BFINAL is set if and only if this is the last block of the data
521 set.
522
523 BTYPE specifies how the data are compressed, as follows:
524
525 00 - no compression
526 01 - compressed with fixed Huffman codes
527 10 - compressed with dynamic Huffman codes
528 11 - reserved (error)
529
530 The only difference between the two compressed cases is how the
531 Huffman codes for the literal/length and distance alphabets are
532 defined.
533
534 In all cases, the decoding algorithm for the actual data is as
535 follows:
536
537 do
538 read block header from input stream.
539 if stored with no compression
540 skip any remaining bits in current partially
541 processed byte
542 read LEN and NLEN (see next section)
543 copy LEN bytes of data to output
544 otherwise
545 if compressed with dynamic Huffman codes
546 read representation of code trees (see
547 subsection below)
548 loop (until end of block code recognized)
549 decode literal/length value from input stream
550 if value < 256
551 copy value (literal byte) to output stream
552 otherwise
553 if value = end of block (256)
554 break from loop
555 otherwise (value = 257..285)
556 decode distance from input stream
557
558 move backwards distance bytes in the output
559 stream, and copy length bytes from this
560 position to the output stream.
561 end loop
562 while not last block
563
564 Note that a duplicated string reference may refer to a string
565 in a previous block; i.e., the backward distance may cross one
566 or more block boundaries. However a distance cannot refer past
567 the beginning of the output stream. (An application using a
568
569
570
571Deutsch Informational [Page 10]
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574RFC 1951 DEFLATE Compressed Data Format Specification May 1996
575
576
577 preset dictionary might discard part of the output stream; a
578 distance can refer to that part of the output stream anyway)
579 Note also that the referenced string may overlap the current
580 position; for example, if the last 2 bytes decoded have values
581 X and Y, a string reference with <length = 5, distance = 2>
582 adds X,Y,X,Y,X to the output stream.
583
584 We now specify each compression method in turn.
585
586 3.2.4. Non-compressed blocks (BTYPE=00)
587
588 Any bits of input up to the next byte boundary are ignored.
589 The rest of the block consists of the following information:
590
591 0 1 2 3 4...
592 +---+---+---+---+================================+
593 | LEN | NLEN |... LEN bytes of literal data...|
594 +---+---+---+---+================================+
595
596 LEN is the number of data bytes in the block. NLEN is the
597 one's complement of LEN.
598
599 3.2.5. Compressed blocks (length and distance codes)
600
601 As noted above, encoded data blocks in the "deflate" format
602 consist of sequences of symbols drawn from three conceptually
603 distinct alphabets: either literal bytes, from the alphabet of
604 byte values (0..255), or <length, backward distance> pairs,
605 where the length is drawn from (3..258) and the distance is
606 drawn from (1..32,768). In fact, the literal and length
607 alphabets are merged into a single alphabet (0..285), where
608 values 0..255 represent literal bytes, the value 256 indicates
609 end-of-block, and values 257..285 represent length codes
610 (possibly in conjunction with extra bits following the symbol
611 code) as follows:
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628Deutsch Informational [Page 11]
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630
631RFC 1951 DEFLATE Compressed Data Format Specification May 1996
632
633
634 Extra Extra Extra
635 Code Bits Length(s) Code Bits Lengths Code Bits Length(s)
636 ---- ---- ------ ---- ---- ------- ---- ---- -------
637 257 0 3 267 1 15,16 277 4 67-82
638 258 0 4 268 1 17,18 278 4 83-98
639 259 0 5 269 2 19-22 279 4 99-114
640 260 0 6 270 2 23-26 280 4 115-130
641 261 0 7 271 2 27-30 281 5 131-162
642 262 0 8 272 2 31-34 282 5 163-194
643 263 0 9 273 3 35-42 283 5 195-226
644 264 0 10 274 3 43-50 284 5 227-257
645 265 1 11,12 275 3 51-58 285 0 258
646 266 1 13,14 276 3 59-66
647
648 The extra bits should be interpreted as a machine integer
649 stored with the most-significant bit first, e.g., bits 1110
650 represent the value 14.
651
652 Extra Extra Extra
653 Code Bits Dist Code Bits Dist Code Bits Distance
654 ---- ---- ---- ---- ---- ------ ---- ---- --------
655 0 0 1 10 4 33-48 20 9 1025-1536
656 1 0 2 11 4 49-64 21 9 1537-2048
657 2 0 3 12 5 65-96 22 10 2049-3072
658 3 0 4 13 5 97-128 23 10 3073-4096
659 4 1 5,6 14 6 129-192 24 11 4097-6144
660 5 1 7,8 15 6 193-256 25 11 6145-8192
661 6 2 9-12 16 7 257-384 26 12 8193-12288
662 7 2 13-16 17 7 385-512 27 12 12289-16384
663 8 3 17-24 18 8 513-768 28 13 16385-24576
664 9 3 25-32 19 8 769-1024 29 13 24577-32768
665
666 3.2.6. Compression with fixed Huffman codes (BTYPE=01)
667
668 The Huffman codes for the two alphabets are fixed, and are not
669 represented explicitly in the data. The Huffman code lengths
670 for the literal/length alphabet are:
671
672 Lit Value Bits Codes
673 --------- ---- -----
674 0 - 143 8 00110000 through
675 10111111
676 144 - 255 9 110010000 through
677 111111111
678 256 - 279 7 0000000 through
679 0010111
680 280 - 287 8 11000000 through
681 11000111
682
683
684
685Deutsch Informational [Page 12]
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688RFC 1951 DEFLATE Compressed Data Format Specification May 1996
689
690
691 The code lengths are sufficient to generate the actual codes,
692 as described above; we show the codes in the table for added
693 clarity. Literal/length values 286-287 will never actually
694 occur in the compressed data, but participate in the code
695 construction.
696
697 Distance codes 0-31 are represented by (fixed-length) 5-bit
698 codes, with possible additional bits as shown in the table
699 shown in Paragraph 3.2.5, above. Note that distance codes 30-
700 31 will never actually occur in the compressed data.
701
702 3.2.7. Compression with dynamic Huffman codes (BTYPE=10)
703
704 The Huffman codes for the two alphabets appear in the block
705 immediately after the header bits and before the actual
706 compressed data, first the literal/length code and then the
707 distance code. Each code is defined by a sequence of code
708 lengths, as discussed in Paragraph 3.2.2, above. For even
709 greater compactness, the code length sequences themselves are
710 compressed using a Huffman code. The alphabet for code lengths
711 is as follows:
712
713 0 - 15: Represent code lengths of 0 - 15
714 16: Copy the previous code length 3 - 6 times.
715 The next 2 bits indicate repeat length
716 (0 = 3, ... , 3 = 6)
717 Example: Codes 8, 16 (+2 bits 11),
718 16 (+2 bits 10) will expand to
719 12 code lengths of 8 (1 + 6 + 5)
720 17: Repeat a code length of 0 for 3 - 10 times.
721 (3 bits of length)
722 18: Repeat a code length of 0 for 11 - 138 times
723 (7 bits of length)
724
725 A code length of 0 indicates that the corresponding symbol in
726 the literal/length or distance alphabet will not occur in the
727 block, and should not participate in the Huffman code
728 construction algorithm given earlier. If only one distance
729 code is used, it is encoded using one bit, not zero bits; in
730 this case there is a single code length of one, with one unused
731 code. One distance code of zero bits means that there are no
732 distance codes used at all (the data is all literals).
733
734 We can now define the format of the block:
735
736 5 Bits: HLIT, # of Literal/Length codes - 257 (257 - 286)
737 5 Bits: HDIST, # of Distance codes - 1 (1 - 32)
738 4 Bits: HCLEN, # of Code Length codes - 4 (4 - 19)
739
740
741
742Deutsch Informational [Page 13]
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745RFC 1951 DEFLATE Compressed Data Format Specification May 1996
746
747
748 (HCLEN + 4) x 3 bits: code lengths for the code length
749 alphabet given just above, in the order: 16, 17, 18,
750 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15
751
752 These code lengths are interpreted as 3-bit integers
753 (0-7); as above, a code length of 0 means the
754 corresponding symbol (literal/length or distance code
755 length) is not used.
756
757 HLIT + 257 code lengths for the literal/length alphabet,
758 encoded using the code length Huffman code
759
760 HDIST + 1 code lengths for the distance alphabet,
761 encoded using the code length Huffman code
762
763 The actual compressed data of the block,
764 encoded using the literal/length and distance Huffman
765 codes
766
767 The literal/length symbol 256 (end of data),
768 encoded using the literal/length Huffman code
769
770 The code length repeat codes can cross from HLIT + 257 to the
771 HDIST + 1 code lengths. In other words, all code lengths form
772 a single sequence of HLIT + HDIST + 258 values.
773
774 3.3. Compliance
775
776 A compressor may limit further the ranges of values specified in
777 the previous section and still be compliant; for example, it may
778 limit the range of backward pointers to some value smaller than
779 32K. Similarly, a compressor may limit the size of blocks so that
780 a compressible block fits in memory.
781
782 A compliant decompressor must accept the full range of possible
783 values defined in the previous section, and must accept blocks of
784 arbitrary size.
785
7864. Compression algorithm details
787
788 While it is the intent of this document to define the "deflate"
789 compressed data format without reference to any particular
790 compression algorithm, the format is related to the compressed
791 formats produced by LZ77 (Lempel-Ziv 1977, see reference [2] below);
792 since many variations of LZ77 are patented, it is strongly
793 recommended that the implementor of a compressor follow the general
794 algorithm presented here, which is known not to be patented per se.
795 The material in this section is not part of the definition of the
796
797
798
799Deutsch Informational [Page 14]
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802RFC 1951 DEFLATE Compressed Data Format Specification May 1996
803
804
805 specification per se, and a compressor need not follow it in order to
806 be compliant.
807
808 The compressor terminates a block when it determines that starting a
809 new block with fresh trees would be useful, or when the block size
810 fills up the compressor's block buffer.
811
812 The compressor uses a chained hash table to find duplicated strings,
813 using a hash function that operates on 3-byte sequences. At any
814 given point during compression, let XYZ be the next 3 input bytes to
815 be examined (not necessarily all different, of course). First, the
816 compressor examines the hash chain for XYZ. If the chain is empty,
817 the compressor simply writes out X as a literal byte and advances one
818 byte in the input. If the hash chain is not empty, indicating that
819 the sequence XYZ (or, if we are unlucky, some other 3 bytes with the
820 same hash function value) has occurred recently, the compressor
821 compares all strings on the XYZ hash chain with the actual input data
822 sequence starting at the current point, and selects the longest
823 match.
824
825 The compressor searches the hash chains starting with the most recent
826 strings, to favor small distances and thus take advantage of the
827 Huffman encoding. The hash chains are singly linked. There are no
828 deletions from the hash chains; the algorithm simply discards matches
829 that are too old. To avoid a worst-case situation, very long hash
830 chains are arbitrarily truncated at a certain length, determined by a
831 run-time parameter.
832
833 To improve overall compression, the compressor optionally defers the
834 selection of matches ("lazy matching"): after a match of length N has
835 been found, the compressor searches for a longer match starting at
836 the next input byte. If it finds a longer match, it truncates the
837 previous match to a length of one (thus producing a single literal
838 byte) and then emits the longer match. Otherwise, it emits the
839 original match, and, as described above, advances N bytes before
840 continuing.
841
842 Run-time parameters also control this "lazy match" procedure. If
843 compression ratio is most important, the compressor attempts a
844 complete second search regardless of the length of the first match.
845 In the normal case, if the current match is "long enough", the
846 compressor reduces the search for a longer match, thus speeding up
847 the process. If speed is most important, the compressor inserts new
848 strings in the hash table only when no match was found, or when the
849 match is not "too long". This degrades the compression ratio but
850 saves time since there are both fewer insertions and fewer searches.
851
852
853
854
855
856Deutsch Informational [Page 15]
857
858
859RFC 1951 DEFLATE Compressed Data Format Specification May 1996
860
861
8625. References
863
864 [1] Huffman, D. A., "A Method for the Construction of Minimum
865 Redundancy Codes", Proceedings of the Institute of Radio
866 Engineers, September 1952, Volume 40, Number 9, pp. 1098-1101.
867
868 [2] Ziv J., Lempel A., "A Universal Algorithm for Sequential Data
869 Compression", IEEE Transactions on Information Theory, Vol. 23,
870 No. 3, pp. 337-343.
871
872 [3] Gailly, J.-L., and Adler, M., ZLIB documentation and sources,
873 available in ftp://ftp.uu.net/pub/archiving/zip/doc/
874
875 [4] Gailly, J.-L., and Adler, M., GZIP documentation and sources,
876 available as gzip-*.tar in ftp://prep.ai.mit.edu/pub/gnu/
877
878 [5] Schwartz, E. S., and Kallick, B. "Generating a canonical prefix
879 encoding." Comm. ACM, 7,3 (Mar. 1964), pp. 166-169.
880
881 [6] Hirschberg and Lelewer, "Efficient decoding of prefix codes,"
882 Comm. ACM, 33,4, April 1990, pp. 449-459.
883
8846. Security Considerations
885
886 Any data compression method involves the reduction of redundancy in
887 the data. Consequently, any corruption of the data is likely to have
888 severe effects and be difficult to correct. Uncompressed text, on
889 the other hand, will probably still be readable despite the presence
890 of some corrupted bytes.
891
892 It is recommended that systems using this data format provide some
893 means of validating the integrity of the compressed data. See
894 reference [3], for example.
895
8967. Source code
897
898 Source code for a C language implementation of a "deflate" compliant
899 compressor and decompressor is available within the zlib package at
900 ftp://ftp.uu.net/pub/archiving/zip/zlib/.
901
9028. Acknowledgements
903
904 Trademarks cited in this document are the property of their
905 respective owners.
906
907 Phil Katz designed the deflate format. Jean-Loup Gailly and Mark
908 Adler wrote the related software described in this specification.
909 Glenn Randers-Pehrson converted this document to RFC and HTML format.
910
911
912
913Deutsch Informational [Page 16]
914
915
916RFC 1951 DEFLATE Compressed Data Format Specification May 1996
917
918
9199. Author's Address
920
921 L. Peter Deutsch
922 Aladdin Enterprises
923 203 Santa Margarita Ave.
924 Menlo Park, CA 94025
925
926 Phone: (415) 322-0103 (AM only)
927 FAX: (415) 322-1734
928 EMail: <ghost@aladdin.com>
929
930 Questions about the technical content of this specification can be
931 sent by email to:
932
933 Jean-Loup Gailly <gzip@prep.ai.mit.edu> and
934 Mark Adler <madler@alumni.caltech.edu>
935
936 Editorial comments on this specification can be sent by email to:
937
938 L. Peter Deutsch <ghost@aladdin.com> and
939 Glenn Randers-Pehrson <randeg@alumni.rpi.edu>
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
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970Deutsch Informational [Page 17]
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972
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