]> Joshua Wise's Git repositories - dumload.git/blame - src/com/jcraft/jzlib/Deflate.java
Fix port usage and always try to add the generated key
[dumload.git] / src / com / jcraft / jzlib / Deflate.java
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1/* -*-mode:java; c-basic-offset:2; -*- */
2/*
3Copyright (c) 2000,2001,2002,2003 ymnk, JCraft,Inc. All rights reserved.
4
5Redistribution and use in source and binary forms, with or without
6modification, are permitted provided that the following conditions are met:
7
8 1. Redistributions of source code must retain the above copyright notice,
9 this list of conditions and the following disclaimer.
10
11 2. Redistributions in binary form must reproduce the above copyright
12 notice, this list of conditions and the following disclaimer in
13 the documentation and/or other materials provided with the distribution.
14
15 3. The names of the authors may not be used to endorse or promote products
16 derived from this software without specific prior written permission.
17
18THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED WARRANTIES,
19INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
20FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL JCRAFT,
21INC. OR ANY CONTRIBUTORS TO THIS SOFTWARE BE LIABLE FOR ANY DIRECT, INDIRECT,
22INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
23LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
24OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
25LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
26NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
27EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28 */
29/*
30 * This program is based on zlib-1.1.3, so all credit should go authors
31 * Jean-loup Gailly(jloup@gzip.org) and Mark Adler(madler@alumni.caltech.edu)
32 * and contributors of zlib.
33 */
34
35package com.jcraft.jzlib;
36
37public
38final class Deflate{
39
40 static final private int MAX_MEM_LEVEL=9;
41
42 static final private int Z_DEFAULT_COMPRESSION=-1;
43
44 static final private int MAX_WBITS=15; // 32K LZ77 window
45 static final private int DEF_MEM_LEVEL=8;
46
47 static class Config{
48 int good_length; // reduce lazy search above this match length
49 int max_lazy; // do not perform lazy search above this match length
50 int nice_length; // quit search above this match length
51 int max_chain;
52 int func;
53 Config(int good_length, int max_lazy,
54 int nice_length, int max_chain, int func){
55 this.good_length=good_length;
56 this.max_lazy=max_lazy;
57 this.nice_length=nice_length;
58 this.max_chain=max_chain;
59 this.func=func;
60 }
61 }
62
63 static final private int STORED=0;
64 static final private int FAST=1;
65 static final private int SLOW=2;
66 static final private Config[] config_table;
67 static{
68 config_table=new Config[10];
69 // good lazy nice chain
70 config_table[0]=new Config(0, 0, 0, 0, STORED);
71 config_table[1]=new Config(4, 4, 8, 4, FAST);
72 config_table[2]=new Config(4, 5, 16, 8, FAST);
73 config_table[3]=new Config(4, 6, 32, 32, FAST);
74
75 config_table[4]=new Config(4, 4, 16, 16, SLOW);
76 config_table[5]=new Config(8, 16, 32, 32, SLOW);
77 config_table[6]=new Config(8, 16, 128, 128, SLOW);
78 config_table[7]=new Config(8, 32, 128, 256, SLOW);
79 config_table[8]=new Config(32, 128, 258, 1024, SLOW);
80 config_table[9]=new Config(32, 258, 258, 4096, SLOW);
81 }
82
83 static final private String[] z_errmsg = {
84 "need dictionary", // Z_NEED_DICT 2
85 "stream end", // Z_STREAM_END 1
86 "", // Z_OK 0
87 "file error", // Z_ERRNO (-1)
88 "stream error", // Z_STREAM_ERROR (-2)
89 "data error", // Z_DATA_ERROR (-3)
90 "insufficient memory", // Z_MEM_ERROR (-4)
91 "buffer error", // Z_BUF_ERROR (-5)
92 "incompatible version",// Z_VERSION_ERROR (-6)
93 ""
94 };
95
96 // block not completed, need more input or more output
97 static final private int NeedMore=0;
98
99 // block flush performed
100 static final private int BlockDone=1;
101
102 // finish started, need only more output at next deflate
103 static final private int FinishStarted=2;
104
105 // finish done, accept no more input or output
106 static final private int FinishDone=3;
107
108 // preset dictionary flag in zlib header
109 static final private int PRESET_DICT=0x20;
110
111 static final private int Z_FILTERED=1;
112 static final private int Z_HUFFMAN_ONLY=2;
113 static final private int Z_DEFAULT_STRATEGY=0;
114
115 static final private int Z_NO_FLUSH=0;
116 static final private int Z_PARTIAL_FLUSH=1;
117 static final private int Z_SYNC_FLUSH=2;
118 static final private int Z_FULL_FLUSH=3;
119 static final private int Z_FINISH=4;
120
121 static final private int Z_OK=0;
122 static final private int Z_STREAM_END=1;
123 static final private int Z_NEED_DICT=2;
124 static final private int Z_ERRNO=-1;
125 static final private int Z_STREAM_ERROR=-2;
126 static final private int Z_DATA_ERROR=-3;
127 static final private int Z_MEM_ERROR=-4;
128 static final private int Z_BUF_ERROR=-5;
129 static final private int Z_VERSION_ERROR=-6;
130
131 static final private int INIT_STATE=42;
132 static final private int BUSY_STATE=113;
133 static final private int FINISH_STATE=666;
134
135 // The deflate compression method
136 static final private int Z_DEFLATED=8;
137
138 static final private int STORED_BLOCK=0;
139 static final private int STATIC_TREES=1;
140 static final private int DYN_TREES=2;
141
142 // The three kinds of block type
143 static final private int Z_BINARY=0;
144 static final private int Z_ASCII=1;
145 static final private int Z_UNKNOWN=2;
146
147 static final private int Buf_size=8*2;
148
149 // repeat previous bit length 3-6 times (2 bits of repeat count)
150 static final private int REP_3_6=16;
151
152 // repeat a zero length 3-10 times (3 bits of repeat count)
153 static final private int REPZ_3_10=17;
154
155 // repeat a zero length 11-138 times (7 bits of repeat count)
156 static final private int REPZ_11_138=18;
157
158 static final private int MIN_MATCH=3;
159 static final private int MAX_MATCH=258;
160 static final private int MIN_LOOKAHEAD=(MAX_MATCH+MIN_MATCH+1);
161
162 static final private int MAX_BITS=15;
163 static final private int D_CODES=30;
164 static final private int BL_CODES=19;
165 static final private int LENGTH_CODES=29;
166 static final private int LITERALS=256;
167 static final private int L_CODES=(LITERALS+1+LENGTH_CODES);
168 static final private int HEAP_SIZE=(2*L_CODES+1);
169
170 static final private int END_BLOCK=256;
171
172 ZStream strm; // pointer back to this zlib stream
173 int status; // as the name implies
174 byte[] pending_buf; // output still pending
175 int pending_buf_size; // size of pending_buf
176 int pending_out; // next pending byte to output to the stream
177 int pending; // nb of bytes in the pending buffer
178 int noheader; // suppress zlib header and adler32
179 byte data_type; // UNKNOWN, BINARY or ASCII
180 byte method; // STORED (for zip only) or DEFLATED
181 int last_flush; // value of flush param for previous deflate call
182
183 int w_size; // LZ77 window size (32K by default)
184 int w_bits; // log2(w_size) (8..16)
185 int w_mask; // w_size - 1
186
187 byte[] window;
188 // Sliding window. Input bytes are read into the second half of the window,
189 // and move to the first half later to keep a dictionary of at least wSize
190 // bytes. With this organization, matches are limited to a distance of
191 // wSize-MAX_MATCH bytes, but this ensures that IO is always
192 // performed with a length multiple of the block size. Also, it limits
193 // the window size to 64K, which is quite useful on MSDOS.
194 // To do: use the user input buffer as sliding window.
195
196 int window_size;
197 // Actual size of window: 2*wSize, except when the user input buffer
198 // is directly used as sliding window.
199
200 short[] prev;
201 // Link to older string with same hash index. To limit the size of this
202 // array to 64K, this link is maintained only for the last 32K strings.
203 // An index in this array is thus a window index modulo 32K.
204
205 short[] head; // Heads of the hash chains or NIL.
206
207 int ins_h; // hash index of string to be inserted
208 int hash_size; // number of elements in hash table
209 int hash_bits; // log2(hash_size)
210 int hash_mask; // hash_size-1
211
212 // Number of bits by which ins_h must be shifted at each input
213 // step. It must be such that after MIN_MATCH steps, the oldest
214 // byte no longer takes part in the hash key, that is:
215 // hash_shift * MIN_MATCH >= hash_bits
216 int hash_shift;
217
218 // Window position at the beginning of the current output block. Gets
219 // negative when the window is moved backwards.
220
221 int block_start;
222
223 int match_length; // length of best match
224 int prev_match; // previous match
225 int match_available; // set if previous match exists
226 int strstart; // start of string to insert
227 int match_start; // start of matching string
228 int lookahead; // number of valid bytes ahead in window
229
230 // Length of the best match at previous step. Matches not greater than this
231 // are discarded. This is used in the lazy match evaluation.
232 int prev_length;
233
234 // To speed up deflation, hash chains are never searched beyond this
235 // length. A higher limit improves compression ratio but degrades the speed.
236 int max_chain_length;
237
238 // Attempt to find a better match only when the current match is strictly
239 // smaller than this value. This mechanism is used only for compression
240 // levels >= 4.
241 int max_lazy_match;
242
243 // Insert new strings in the hash table only if the match length is not
244 // greater than this length. This saves time but degrades compression.
245 // max_insert_length is used only for compression levels <= 3.
246
247 int level; // compression level (1..9)
248 int strategy; // favor or force Huffman coding
249
250 // Use a faster search when the previous match is longer than this
251 int good_match;
252
253 // Stop searching when current match exceeds this
254 int nice_match;
255
256 short[] dyn_ltree; // literal and length tree
257 short[] dyn_dtree; // distance tree
258 short[] bl_tree; // Huffman tree for bit lengths
259
260 Tree l_desc=new Tree(); // desc for literal tree
261 Tree d_desc=new Tree(); // desc for distance tree
262 Tree bl_desc=new Tree(); // desc for bit length tree
263
264 // number of codes at each bit length for an optimal tree
265 short[] bl_count=new short[MAX_BITS+1];
266
267 // heap used to build the Huffman trees
268 int[] heap=new int[2*L_CODES+1];
269
270 int heap_len; // number of elements in the heap
271 int heap_max; // element of largest frequency
272 // The sons of heap[n] are heap[2*n] and heap[2*n+1]. heap[0] is not used.
273 // The same heap array is used to build all trees.
274
275 // Depth of each subtree used as tie breaker for trees of equal frequency
276 byte[] depth=new byte[2*L_CODES+1];
277
278 int l_buf; // index for literals or lengths */
279
280 // Size of match buffer for literals/lengths. There are 4 reasons for
281 // limiting lit_bufsize to 64K:
282 // - frequencies can be kept in 16 bit counters
283 // - if compression is not successful for the first block, all input
284 // data is still in the window so we can still emit a stored block even
285 // when input comes from standard input. (This can also be done for
286 // all blocks if lit_bufsize is not greater than 32K.)
287 // - if compression is not successful for a file smaller than 64K, we can
288 // even emit a stored file instead of a stored block (saving 5 bytes).
289 // This is applicable only for zip (not gzip or zlib).
290 // - creating new Huffman trees less frequently may not provide fast
291 // adaptation to changes in the input data statistics. (Take for
292 // example a binary file with poorly compressible code followed by
293 // a highly compressible string table.) Smaller buffer sizes give
294 // fast adaptation but have of course the overhead of transmitting
295 // trees more frequently.
296 // - I can't count above 4
297 int lit_bufsize;
298
299 int last_lit; // running index in l_buf
300
301 // Buffer for distances. To simplify the code, d_buf and l_buf have
302 // the same number of elements. To use different lengths, an extra flag
303 // array would be necessary.
304
305 int d_buf; // index of pendig_buf
306
307 int opt_len; // bit length of current block with optimal trees
308 int static_len; // bit length of current block with static trees
309 int matches; // number of string matches in current block
310 int last_eob_len; // bit length of EOB code for last block
311
312 // Output buffer. bits are inserted starting at the bottom (least
313 // significant bits).
314 short bi_buf;
315
316 // Number of valid bits in bi_buf. All bits above the last valid bit
317 // are always zero.
318 int bi_valid;
319
320 Deflate(){
321 dyn_ltree=new short[HEAP_SIZE*2];
322 dyn_dtree=new short[(2*D_CODES+1)*2]; // distance tree
323 bl_tree=new short[(2*BL_CODES+1)*2]; // Huffman tree for bit lengths
324 }
325
326 void lm_init() {
327 window_size=2*w_size;
328
329 head[hash_size-1]=0;
330 for(int i=0; i<hash_size-1; i++){
331 head[i]=0;
332 }
333
334 // Set the default configuration parameters:
335 max_lazy_match = Deflate.config_table[level].max_lazy;
336 good_match = Deflate.config_table[level].good_length;
337 nice_match = Deflate.config_table[level].nice_length;
338 max_chain_length = Deflate.config_table[level].max_chain;
339
340 strstart = 0;
341 block_start = 0;
342 lookahead = 0;
343 match_length = prev_length = MIN_MATCH-1;
344 match_available = 0;
345 ins_h = 0;
346 }
347
348 // Initialize the tree data structures for a new zlib stream.
349 void tr_init(){
350
351 l_desc.dyn_tree = dyn_ltree;
352 l_desc.stat_desc = StaticTree.static_l_desc;
353
354 d_desc.dyn_tree = dyn_dtree;
355 d_desc.stat_desc = StaticTree.static_d_desc;
356
357 bl_desc.dyn_tree = bl_tree;
358 bl_desc.stat_desc = StaticTree.static_bl_desc;
359
360 bi_buf = 0;
361 bi_valid = 0;
362 last_eob_len = 8; // enough lookahead for inflate
363
364 // Initialize the first block of the first file:
365 init_block();
366 }
367
368 void init_block(){
369 // Initialize the trees.
370 for(int i = 0; i < L_CODES; i++) dyn_ltree[i*2] = 0;
371 for(int i= 0; i < D_CODES; i++) dyn_dtree[i*2] = 0;
372 for(int i= 0; i < BL_CODES; i++) bl_tree[i*2] = 0;
373
374 dyn_ltree[END_BLOCK*2] = 1;
375 opt_len = static_len = 0;
376 last_lit = matches = 0;
377 }
378
379 // Restore the heap property by moving down the tree starting at node k,
380 // exchanging a node with the smallest of its two sons if necessary, stopping
381 // when the heap property is re-established (each father smaller than its
382 // two sons).
383 void pqdownheap(short[] tree, // the tree to restore
384 int k // node to move down
385 ){
386 int v = heap[k];
387 int j = k << 1; // left son of k
388 while (j <= heap_len) {
389 // Set j to the smallest of the two sons:
390 if (j < heap_len &&
391 smaller(tree, heap[j+1], heap[j], depth)){
392 j++;
393 }
394 // Exit if v is smaller than both sons
395 if(smaller(tree, v, heap[j], depth)) break;
396
397 // Exchange v with the smallest son
398 heap[k]=heap[j]; k = j;
399 // And continue down the tree, setting j to the left son of k
400 j <<= 1;
401 }
402 heap[k] = v;
403 }
404
405 static boolean smaller(short[] tree, int n, int m, byte[] depth){
406 short tn2=tree[n*2];
407 short tm2=tree[m*2];
408 return (tn2<tm2 ||
409 (tn2==tm2 && depth[n] <= depth[m]));
410 }
411
412 // Scan a literal or distance tree to determine the frequencies of the codes
413 // in the bit length tree.
414 void scan_tree (short[] tree,// the tree to be scanned
415 int max_code // and its largest code of non zero frequency
416 ){
417 int n; // iterates over all tree elements
418 int prevlen = -1; // last emitted length
419 int curlen; // length of current code
420 int nextlen = tree[0*2+1]; // length of next code
421 int count = 0; // repeat count of the current code
422 int max_count = 7; // max repeat count
423 int min_count = 4; // min repeat count
424
425 if (nextlen == 0){ max_count = 138; min_count = 3; }
426 tree[(max_code+1)*2+1] = (short)0xffff; // guard
427
428 for(n = 0; n <= max_code; n++) {
429 curlen = nextlen; nextlen = tree[(n+1)*2+1];
430 if(++count < max_count && curlen == nextlen) {
431 continue;
432 }
433 else if(count < min_count) {
434 bl_tree[curlen*2] += count;
435 }
436 else if(curlen != 0) {
437 if(curlen != prevlen) bl_tree[curlen*2]++;
438 bl_tree[REP_3_6*2]++;
439 }
440 else if(count <= 10) {
441 bl_tree[REPZ_3_10*2]++;
442 }
443 else{
444 bl_tree[REPZ_11_138*2]++;
445 }
446 count = 0; prevlen = curlen;
447 if(nextlen == 0) {
448 max_count = 138; min_count = 3;
449 }
450 else if(curlen == nextlen) {
451 max_count = 6; min_count = 3;
452 }
453 else{
454 max_count = 7; min_count = 4;
455 }
456 }
457 }
458
459 // Construct the Huffman tree for the bit lengths and return the index in
460 // bl_order of the last bit length code to send.
461 int build_bl_tree(){
462 int max_blindex; // index of last bit length code of non zero freq
463
464 // Determine the bit length frequencies for literal and distance trees
465 scan_tree(dyn_ltree, l_desc.max_code);
466 scan_tree(dyn_dtree, d_desc.max_code);
467
468 // Build the bit length tree:
469 bl_desc.build_tree(this);
470 // opt_len now includes the length of the tree representations, except
471 // the lengths of the bit lengths codes and the 5+5+4 bits for the counts.
472
473 // Determine the number of bit length codes to send. The pkzip format
474 // requires that at least 4 bit length codes be sent. (appnote.txt says
475 // 3 but the actual value used is 4.)
476 for (max_blindex = BL_CODES-1; max_blindex >= 3; max_blindex--) {
477 if (bl_tree[Tree.bl_order[max_blindex]*2+1] != 0) break;
478 }
479 // Update opt_len to include the bit length tree and counts
480 opt_len += 3*(max_blindex+1) + 5+5+4;
481
482 return max_blindex;
483 }
484
485
486 // Send the header for a block using dynamic Huffman trees: the counts, the
487 // lengths of the bit length codes, the literal tree and the distance tree.
488 // IN assertion: lcodes >= 257, dcodes >= 1, blcodes >= 4.
489 void send_all_trees(int lcodes, int dcodes, int blcodes){
490 int rank; // index in bl_order
491
492 send_bits(lcodes-257, 5); // not +255 as stated in appnote.txt
493 send_bits(dcodes-1, 5);
494 send_bits(blcodes-4, 4); // not -3 as stated in appnote.txt
495 for (rank = 0; rank < blcodes; rank++) {
496 send_bits(bl_tree[Tree.bl_order[rank]*2+1], 3);
497 }
498 send_tree(dyn_ltree, lcodes-1); // literal tree
499 send_tree(dyn_dtree, dcodes-1); // distance tree
500 }
501
502 // Send a literal or distance tree in compressed form, using the codes in
503 // bl_tree.
504 void send_tree (short[] tree,// the tree to be sent
505 int max_code // and its largest code of non zero frequency
506 ){
507 int n; // iterates over all tree elements
508 int prevlen = -1; // last emitted length
509 int curlen; // length of current code
510 int nextlen = tree[0*2+1]; // length of next code
511 int count = 0; // repeat count of the current code
512 int max_count = 7; // max repeat count
513 int min_count = 4; // min repeat count
514
515 if (nextlen == 0){ max_count = 138; min_count = 3; }
516
517 for (n = 0; n <= max_code; n++) {
518 curlen = nextlen; nextlen = tree[(n+1)*2+1];
519 if(++count < max_count && curlen == nextlen) {
520 continue;
521 }
522 else if(count < min_count) {
523 do { send_code(curlen, bl_tree); } while (--count != 0);
524 }
525 else if(curlen != 0){
526 if(curlen != prevlen){
527 send_code(curlen, bl_tree); count--;
528 }
529 send_code(REP_3_6, bl_tree);
530 send_bits(count-3, 2);
531 }
532 else if(count <= 10){
533 send_code(REPZ_3_10, bl_tree);
534 send_bits(count-3, 3);
535 }
536 else{
537 send_code(REPZ_11_138, bl_tree);
538 send_bits(count-11, 7);
539 }
540 count = 0; prevlen = curlen;
541 if(nextlen == 0){
542 max_count = 138; min_count = 3;
543 }
544 else if(curlen == nextlen){
545 max_count = 6; min_count = 3;
546 }
547 else{
548 max_count = 7; min_count = 4;
549 }
550 }
551 }
552
553 // Output a byte on the stream.
554 // IN assertion: there is enough room in pending_buf.
555 final void put_byte(byte[] p, int start, int len){
556 System.arraycopy(p, start, pending_buf, pending, len);
557 pending+=len;
558 }
559
560 final void put_byte(byte c){
561 pending_buf[pending++]=c;
562 }
563 final void put_short(int w) {
564 put_byte((byte)(w/*&0xff*/));
565 put_byte((byte)(w>>>8));
566 }
567 final void putShortMSB(int b){
568 put_byte((byte)(b>>8));
569 put_byte((byte)(b/*&0xff*/));
570 }
571
572 final void send_code(int c, short[] tree){
573 int c2=c*2;
574 send_bits((tree[c2]&0xffff), (tree[c2+1]&0xffff));
575 }
576
577 void send_bits(int value, int length){
578 int len = length;
579 if (bi_valid > (int)Buf_size - len) {
580 int val = value;
581// bi_buf |= (val << bi_valid);
582 bi_buf |= ((val << bi_valid)&0xffff);
583 put_short(bi_buf);
584 bi_buf = (short)(val >>> (Buf_size - bi_valid));
585 bi_valid += len - Buf_size;
586 } else {
587// bi_buf |= (value) << bi_valid;
588 bi_buf |= (((value) << bi_valid)&0xffff);
589 bi_valid += len;
590 }
591 }
592
593 // Send one empty static block to give enough lookahead for inflate.
594 // This takes 10 bits, of which 7 may remain in the bit buffer.
595 // The current inflate code requires 9 bits of lookahead. If the
596 // last two codes for the previous block (real code plus EOB) were coded
597 // on 5 bits or less, inflate may have only 5+3 bits of lookahead to decode
598 // the last real code. In this case we send two empty static blocks instead
599 // of one. (There are no problems if the previous block is stored or fixed.)
600 // To simplify the code, we assume the worst case of last real code encoded
601 // on one bit only.
602 void _tr_align(){
603 send_bits(STATIC_TREES<<1, 3);
604 send_code(END_BLOCK, StaticTree.static_ltree);
605
606 bi_flush();
607
608 // Of the 10 bits for the empty block, we have already sent
609 // (10 - bi_valid) bits. The lookahead for the last real code (before
610 // the EOB of the previous block) was thus at least one plus the length
611 // of the EOB plus what we have just sent of the empty static block.
612 if (1 + last_eob_len + 10 - bi_valid < 9) {
613 send_bits(STATIC_TREES<<1, 3);
614 send_code(END_BLOCK, StaticTree.static_ltree);
615 bi_flush();
616 }
617 last_eob_len = 7;
618 }
619
620
621 // Save the match info and tally the frequency counts. Return true if
622 // the current block must be flushed.
623 boolean _tr_tally (int dist, // distance of matched string
624 int lc // match length-MIN_MATCH or unmatched char (if dist==0)
625 ){
626
627 pending_buf[d_buf+last_lit*2] = (byte)(dist>>>8);
628 pending_buf[d_buf+last_lit*2+1] = (byte)dist;
629
630 pending_buf[l_buf+last_lit] = (byte)lc; last_lit++;
631
632 if (dist == 0) {
633 // lc is the unmatched char
634 dyn_ltree[lc*2]++;
635 }
636 else {
637 matches++;
638 // Here, lc is the match length - MIN_MATCH
639 dist--; // dist = match distance - 1
640 dyn_ltree[(Tree._length_code[lc]+LITERALS+1)*2]++;
641 dyn_dtree[Tree.d_code(dist)*2]++;
642 }
643
644 if ((last_lit & 0x1fff) == 0 && level > 2) {
645 // Compute an upper bound for the compressed length
646 int out_length = last_lit*8;
647 int in_length = strstart - block_start;
648 int dcode;
649 for (dcode = 0; dcode < D_CODES; dcode++) {
650 out_length += (int)dyn_dtree[dcode*2] *
651 (5L+Tree.extra_dbits[dcode]);
652 }
653 out_length >>>= 3;
654 if ((matches < (last_lit/2)) && out_length < in_length/2) return true;
655 }
656
657 return (last_lit == lit_bufsize-1);
658 // We avoid equality with lit_bufsize because of wraparound at 64K
659 // on 16 bit machines and because stored blocks are restricted to
660 // 64K-1 bytes.
661 }
662
663 // Send the block data compressed using the given Huffman trees
664 void compress_block(short[] ltree, short[] dtree){
665 int dist; // distance of matched string
666 int lc; // match length or unmatched char (if dist == 0)
667 int lx = 0; // running index in l_buf
668 int code; // the code to send
669 int extra; // number of extra bits to send
670
671 if (last_lit != 0){
672 do{
673 dist=((pending_buf[d_buf+lx*2]<<8)&0xff00)|
674 (pending_buf[d_buf+lx*2+1]&0xff);
675 lc=(pending_buf[l_buf+lx])&0xff; lx++;
676
677 if(dist == 0){
678 send_code(lc, ltree); // send a literal byte
679 }
680 else{
681 // Here, lc is the match length - MIN_MATCH
682 code = Tree._length_code[lc];
683
684 send_code(code+LITERALS+1, ltree); // send the length code
685 extra = Tree.extra_lbits[code];
686 if(extra != 0){
687 lc -= Tree.base_length[code];
688 send_bits(lc, extra); // send the extra length bits
689 }
690 dist--; // dist is now the match distance - 1
691 code = Tree.d_code(dist);
692
693 send_code(code, dtree); // send the distance code
694 extra = Tree.extra_dbits[code];
695 if (extra != 0) {
696 dist -= Tree.base_dist[code];
697 send_bits(dist, extra); // send the extra distance bits
698 }
699 } // literal or match pair ?
700
701 // Check that the overlay between pending_buf and d_buf+l_buf is ok:
702 }
703 while (lx < last_lit);
704 }
705
706 send_code(END_BLOCK, ltree);
707 last_eob_len = ltree[END_BLOCK*2+1];
708 }
709
710 // Set the data type to ASCII or BINARY, using a crude approximation:
711 // binary if more than 20% of the bytes are <= 6 or >= 128, ascii otherwise.
712 // IN assertion: the fields freq of dyn_ltree are set and the total of all
713 // frequencies does not exceed 64K (to fit in an int on 16 bit machines).
714 void set_data_type(){
715 int n = 0;
716 int ascii_freq = 0;
717 int bin_freq = 0;
718 while(n<7){ bin_freq += dyn_ltree[n*2]; n++;}
719 while(n<128){ ascii_freq += dyn_ltree[n*2]; n++;}
720 while(n<LITERALS){ bin_freq += dyn_ltree[n*2]; n++;}
721 data_type=(byte)(bin_freq > (ascii_freq >>> 2) ? Z_BINARY : Z_ASCII);
722 }
723
724 // Flush the bit buffer, keeping at most 7 bits in it.
725 void bi_flush(){
726 if (bi_valid == 16) {
727 put_short(bi_buf);
728 bi_buf=0;
729 bi_valid=0;
730 }
731 else if (bi_valid >= 8) {
732 put_byte((byte)bi_buf);
733 bi_buf>>>=8;
734 bi_valid-=8;
735 }
736 }
737
738 // Flush the bit buffer and align the output on a byte boundary
739 void bi_windup(){
740 if (bi_valid > 8) {
741 put_short(bi_buf);
742 } else if (bi_valid > 0) {
743 put_byte((byte)bi_buf);
744 }
745 bi_buf = 0;
746 bi_valid = 0;
747 }
748
749 // Copy a stored block, storing first the length and its
750 // one's complement if requested.
751 void copy_block(int buf, // the input data
752 int len, // its length
753 boolean header // true if block header must be written
754 ){
755 int index=0;
756 bi_windup(); // align on byte boundary
757 last_eob_len = 8; // enough lookahead for inflate
758
759 if (header) {
760 put_short((short)len);
761 put_short((short)~len);
762 }
763
764 // while(len--!=0) {
765 // put_byte(window[buf+index]);
766 // index++;
767 // }
768 put_byte(window, buf, len);
769 }
770
771 void flush_block_only(boolean eof){
772 _tr_flush_block(block_start>=0 ? block_start : -1,
773 strstart-block_start,
774 eof);
775 block_start=strstart;
776 strm.flush_pending();
777 }
778
779 // Copy without compression as much as possible from the input stream, return
780 // the current block state.
781 // This function does not insert new strings in the dictionary since
782 // uncompressible data is probably not useful. This function is used
783 // only for the level=0 compression option.
784 // NOTE: this function should be optimized to avoid extra copying from
785 // window to pending_buf.
786 int deflate_stored(int flush){
787 // Stored blocks are limited to 0xffff bytes, pending_buf is limited
788 // to pending_buf_size, and each stored block has a 5 byte header:
789
790 int max_block_size = 0xffff;
791 int max_start;
792
793 if(max_block_size > pending_buf_size - 5) {
794 max_block_size = pending_buf_size - 5;
795 }
796
797 // Copy as much as possible from input to output:
798 while(true){
799 // Fill the window as much as possible:
800 if(lookahead<=1){
801 fill_window();
802 if(lookahead==0 && flush==Z_NO_FLUSH) return NeedMore;
803 if(lookahead==0) break; // flush the current block
804 }
805
806 strstart+=lookahead;
807 lookahead=0;
808
809 // Emit a stored block if pending_buf will be full:
810 max_start=block_start+max_block_size;
811 if(strstart==0|| strstart>=max_start) {
812 // strstart == 0 is possible when wraparound on 16-bit machine
813 lookahead = (int)(strstart-max_start);
814 strstart = (int)max_start;
815
816 flush_block_only(false);
817 if(strm.avail_out==0) return NeedMore;
818
819 }
820
821 // Flush if we may have to slide, otherwise block_start may become
822 // negative and the data will be gone:
823 if(strstart-block_start >= w_size-MIN_LOOKAHEAD) {
824 flush_block_only(false);
825 if(strm.avail_out==0) return NeedMore;
826 }
827 }
828
829 flush_block_only(flush == Z_FINISH);
830 if(strm.avail_out==0)
831 return (flush == Z_FINISH) ? FinishStarted : NeedMore;
832
833 return flush == Z_FINISH ? FinishDone : BlockDone;
834 }
835
836 // Send a stored block
837 void _tr_stored_block(int buf, // input block
838 int stored_len, // length of input block
839 boolean eof // true if this is the last block for a file
840 ){
841 send_bits((STORED_BLOCK<<1)+(eof?1:0), 3); // send block type
842 copy_block(buf, stored_len, true); // with header
843 }
844
845 // Determine the best encoding for the current block: dynamic trees, static
846 // trees or store, and output the encoded block to the zip file.
847 void _tr_flush_block(int buf, // input block, or NULL if too old
848 int stored_len, // length of input block
849 boolean eof // true if this is the last block for a file
850 ) {
851 int opt_lenb, static_lenb;// opt_len and static_len in bytes
852 int max_blindex = 0; // index of last bit length code of non zero freq
853
854 // Build the Huffman trees unless a stored block is forced
855 if(level > 0) {
856 // Check if the file is ascii or binary
857 if(data_type == Z_UNKNOWN) set_data_type();
858
859 // Construct the literal and distance trees
860 l_desc.build_tree(this);
861
862 d_desc.build_tree(this);
863
864 // At this point, opt_len and static_len are the total bit lengths of
865 // the compressed block data, excluding the tree representations.
866
867 // Build the bit length tree for the above two trees, and get the index
868 // in bl_order of the last bit length code to send.
869 max_blindex=build_bl_tree();
870
871 // Determine the best encoding. Compute first the block length in bytes
872 opt_lenb=(opt_len+3+7)>>>3;
873 static_lenb=(static_len+3+7)>>>3;
874
875 if(static_lenb<=opt_lenb) opt_lenb=static_lenb;
876 }
877 else {
878 opt_lenb=static_lenb=stored_len+5; // force a stored block
879 }
880
881 if(stored_len+4<=opt_lenb && buf != -1){
882 // 4: two words for the lengths
883 // The test buf != NULL is only necessary if LIT_BUFSIZE > WSIZE.
884 // Otherwise we can't have processed more than WSIZE input bytes since
885 // the last block flush, because compression would have been
886 // successful. If LIT_BUFSIZE <= WSIZE, it is never too late to
887 // transform a block into a stored block.
888 _tr_stored_block(buf, stored_len, eof);
889 }
890 else if(static_lenb == opt_lenb){
891 send_bits((STATIC_TREES<<1)+(eof?1:0), 3);
892 compress_block(StaticTree.static_ltree, StaticTree.static_dtree);
893 }
894 else{
895 send_bits((DYN_TREES<<1)+(eof?1:0), 3);
896 send_all_trees(l_desc.max_code+1, d_desc.max_code+1, max_blindex+1);
897 compress_block(dyn_ltree, dyn_dtree);
898 }
899
900 // The above check is made mod 2^32, for files larger than 512 MB
901 // and uLong implemented on 32 bits.
902
903 init_block();
904
905 if(eof){
906 bi_windup();
907 }
908 }
909
910 // Fill the window when the lookahead becomes insufficient.
911 // Updates strstart and lookahead.
912 //
913 // IN assertion: lookahead < MIN_LOOKAHEAD
914 // OUT assertions: strstart <= window_size-MIN_LOOKAHEAD
915 // At least one byte has been read, or avail_in == 0; reads are
916 // performed for at least two bytes (required for the zip translate_eol
917 // option -- not supported here).
918 void fill_window(){
919 int n, m;
920 int p;
921 int more; // Amount of free space at the end of the window.
922
923 do{
924 more = (window_size-lookahead-strstart);
925
926 // Deal with !@#$% 64K limit:
927 if(more==0 && strstart==0 && lookahead==0){
928 more = w_size;
929 }
930 else if(more==-1) {
931 // Very unlikely, but possible on 16 bit machine if strstart == 0
932 // and lookahead == 1 (input done one byte at time)
933 more--;
934
935 // If the window is almost full and there is insufficient lookahead,
936 // move the upper half to the lower one to make room in the upper half.
937 }
938 else if(strstart >= w_size+ w_size-MIN_LOOKAHEAD) {
939 System.arraycopy(window, w_size, window, 0, w_size);
940 match_start-=w_size;
941 strstart-=w_size; // we now have strstart >= MAX_DIST
942 block_start-=w_size;
943
944 // Slide the hash table (could be avoided with 32 bit values
945 // at the expense of memory usage). We slide even when level == 0
946 // to keep the hash table consistent if we switch back to level > 0
947 // later. (Using level 0 permanently is not an optimal usage of
948 // zlib, so we don't care about this pathological case.)
949
950 n = hash_size;
951 p=n;
952 do {
953 m = (head[--p]&0xffff);
954 head[p]=(m>=w_size ? (short)(m-w_size) : 0);
955 }
956 while (--n != 0);
957
958 n = w_size;
959 p = n;
960 do {
961 m = (prev[--p]&0xffff);
962 prev[p] = (m >= w_size ? (short)(m-w_size) : 0);
963 // If n is not on any hash chain, prev[n] is garbage but
964 // its value will never be used.
965 }
966 while (--n!=0);
967 more += w_size;
968 }
969
970 if (strm.avail_in == 0) return;
971
972 // If there was no sliding:
973 // strstart <= WSIZE+MAX_DIST-1 && lookahead <= MIN_LOOKAHEAD - 1 &&
974 // more == window_size - lookahead - strstart
975 // => more >= window_size - (MIN_LOOKAHEAD-1 + WSIZE + MAX_DIST-1)
976 // => more >= window_size - 2*WSIZE + 2
977 // In the BIG_MEM or MMAP case (not yet supported),
978 // window_size == input_size + MIN_LOOKAHEAD &&
979 // strstart + s->lookahead <= input_size => more >= MIN_LOOKAHEAD.
980 // Otherwise, window_size == 2*WSIZE so more >= 2.
981 // If there was sliding, more >= WSIZE. So in all cases, more >= 2.
982
983 n = strm.read_buf(window, strstart + lookahead, more);
984 lookahead += n;
985
986 // Initialize the hash value now that we have some input:
987 if(lookahead >= MIN_MATCH) {
988 ins_h = window[strstart]&0xff;
989 ins_h=(((ins_h)<<hash_shift)^(window[strstart+1]&0xff))&hash_mask;
990 }
991 // If the whole input has less than MIN_MATCH bytes, ins_h is garbage,
992 // but this is not important since only literal bytes will be emitted.
993 }
994 while (lookahead < MIN_LOOKAHEAD && strm.avail_in != 0);
995 }
996
997 // Compress as much as possible from the input stream, return the current
998 // block state.
999 // This function does not perform lazy evaluation of matches and inserts
1000 // new strings in the dictionary only for unmatched strings or for short
1001 // matches. It is used only for the fast compression options.
1002 int deflate_fast(int flush){
1003// short hash_head = 0; // head of the hash chain
1004 int hash_head = 0; // head of the hash chain
1005 boolean bflush; // set if current block must be flushed
1006
1007 while(true){
1008 // Make sure that we always have enough lookahead, except
1009 // at the end of the input file. We need MAX_MATCH bytes
1010 // for the next match, plus MIN_MATCH bytes to insert the
1011 // string following the next match.
1012 if(lookahead < MIN_LOOKAHEAD){
1013 fill_window();
1014 if(lookahead < MIN_LOOKAHEAD && flush == Z_NO_FLUSH){
1015 return NeedMore;
1016 }
1017 if(lookahead == 0) break; // flush the current block
1018 }
1019
1020 // Insert the string window[strstart .. strstart+2] in the
1021 // dictionary, and set hash_head to the head of the hash chain:
1022 if(lookahead >= MIN_MATCH){
1023 ins_h=(((ins_h)<<hash_shift)^(window[(strstart)+(MIN_MATCH-1)]&0xff))&hash_mask;
1024
1025// prev[strstart&w_mask]=hash_head=head[ins_h];
1026 hash_head=(head[ins_h]&0xffff);
1027 prev[strstart&w_mask]=head[ins_h];
1028 head[ins_h]=(short)strstart;
1029 }
1030
1031 // Find the longest match, discarding those <= prev_length.
1032 // At this point we have always match_length < MIN_MATCH
1033
1034 if(hash_head!=0L &&
1035 ((strstart-hash_head)&0xffff) <= w_size-MIN_LOOKAHEAD
1036 ){
1037 // To simplify the code, we prevent matches with the string
1038 // of window index 0 (in particular we have to avoid a match
1039 // of the string with itself at the start of the input file).
1040 if(strategy != Z_HUFFMAN_ONLY){
1041 match_length=longest_match (hash_head);
1042 }
1043 // longest_match() sets match_start
1044 }
1045 if(match_length>=MIN_MATCH){
1046 // check_match(strstart, match_start, match_length);
1047
1048 bflush=_tr_tally(strstart-match_start, match_length-MIN_MATCH);
1049
1050 lookahead -= match_length;
1051
1052 // Insert new strings in the hash table only if the match length
1053 // is not too large. This saves time but degrades compression.
1054 if(match_length <= max_lazy_match &&
1055 lookahead >= MIN_MATCH) {
1056 match_length--; // string at strstart already in hash table
1057 do{
1058 strstart++;
1059
1060 ins_h=((ins_h<<hash_shift)^(window[(strstart)+(MIN_MATCH-1)]&0xff))&hash_mask;
1061// prev[strstart&w_mask]=hash_head=head[ins_h];
1062 hash_head=(head[ins_h]&0xffff);
1063 prev[strstart&w_mask]=head[ins_h];
1064 head[ins_h]=(short)strstart;
1065
1066 // strstart never exceeds WSIZE-MAX_MATCH, so there are
1067 // always MIN_MATCH bytes ahead.
1068 }
1069 while (--match_length != 0);
1070 strstart++;
1071 }
1072 else{
1073 strstart += match_length;
1074 match_length = 0;
1075 ins_h = window[strstart]&0xff;
1076
1077 ins_h=(((ins_h)<<hash_shift)^(window[strstart+1]&0xff))&hash_mask;
1078 // If lookahead < MIN_MATCH, ins_h is garbage, but it does not
1079 // matter since it will be recomputed at next deflate call.
1080 }
1081 }
1082 else {
1083 // No match, output a literal byte
1084
1085 bflush=_tr_tally(0, window[strstart]&0xff);
1086 lookahead--;
1087 strstart++;
1088 }
1089 if (bflush){
1090
1091 flush_block_only(false);
1092 if(strm.avail_out==0) return NeedMore;
1093 }
1094 }
1095
1096 flush_block_only(flush == Z_FINISH);
1097 if(strm.avail_out==0){
1098 if(flush == Z_FINISH) return FinishStarted;
1099 else return NeedMore;
1100 }
1101 return flush==Z_FINISH ? FinishDone : BlockDone;
1102 }
1103
1104 // Same as above, but achieves better compression. We use a lazy
1105 // evaluation for matches: a match is finally adopted only if there is
1106 // no better match at the next window position.
1107 int deflate_slow(int flush){
1108// short hash_head = 0; // head of hash chain
1109 int hash_head = 0; // head of hash chain
1110 boolean bflush; // set if current block must be flushed
1111
1112 // Process the input block.
1113 while(true){
1114 // Make sure that we always have enough lookahead, except
1115 // at the end of the input file. We need MAX_MATCH bytes
1116 // for the next match, plus MIN_MATCH bytes to insert the
1117 // string following the next match.
1118
1119 if (lookahead < MIN_LOOKAHEAD) {
1120 fill_window();
1121 if(lookahead < MIN_LOOKAHEAD && flush == Z_NO_FLUSH) {
1122 return NeedMore;
1123 }
1124 if(lookahead == 0) break; // flush the current block
1125 }
1126
1127 // Insert the string window[strstart .. strstart+2] in the
1128 // dictionary, and set hash_head to the head of the hash chain:
1129
1130 if(lookahead >= MIN_MATCH) {
1131 ins_h=(((ins_h)<<hash_shift)^(window[(strstart)+(MIN_MATCH-1)]&0xff)) & hash_mask;
1132// prev[strstart&w_mask]=hash_head=head[ins_h];
1133 hash_head=(head[ins_h]&0xffff);
1134 prev[strstart&w_mask]=head[ins_h];
1135 head[ins_h]=(short)strstart;
1136 }
1137
1138 // Find the longest match, discarding those <= prev_length.
1139 prev_length = match_length; prev_match = match_start;
1140 match_length = MIN_MATCH-1;
1141
1142 if (hash_head != 0 && prev_length < max_lazy_match &&
1143 ((strstart-hash_head)&0xffff) <= w_size-MIN_LOOKAHEAD
1144 ){
1145 // To simplify the code, we prevent matches with the string
1146 // of window index 0 (in particular we have to avoid a match
1147 // of the string with itself at the start of the input file).
1148
1149 if(strategy != Z_HUFFMAN_ONLY) {
1150 match_length = longest_match(hash_head);
1151 }
1152 // longest_match() sets match_start
1153
1154 if (match_length <= 5 && (strategy == Z_FILTERED ||
1155 (match_length == MIN_MATCH &&
1156 strstart - match_start > 4096))) {
1157
1158 // If prev_match is also MIN_MATCH, match_start is garbage
1159 // but we will ignore the current match anyway.
1160 match_length = MIN_MATCH-1;
1161 }
1162 }
1163
1164 // If there was a match at the previous step and the current
1165 // match is not better, output the previous match:
1166 if(prev_length >= MIN_MATCH && match_length <= prev_length) {
1167 int max_insert = strstart + lookahead - MIN_MATCH;
1168 // Do not insert strings in hash table beyond this.
1169
1170 // check_match(strstart-1, prev_match, prev_length);
1171
1172 bflush=_tr_tally(strstart-1-prev_match, prev_length - MIN_MATCH);
1173
1174 // Insert in hash table all strings up to the end of the match.
1175 // strstart-1 and strstart are already inserted. If there is not
1176 // enough lookahead, the last two strings are not inserted in
1177 // the hash table.
1178 lookahead -= prev_length-1;
1179 prev_length -= 2;
1180 do{
1181 if(++strstart <= max_insert) {
1182 ins_h=(((ins_h)<<hash_shift)^(window[(strstart)+(MIN_MATCH-1)]&0xff))&hash_mask;
1183 //prev[strstart&w_mask]=hash_head=head[ins_h];
1184 hash_head=(head[ins_h]&0xffff);
1185 prev[strstart&w_mask]=head[ins_h];
1186 head[ins_h]=(short)strstart;
1187 }
1188 }
1189 while(--prev_length != 0);
1190 match_available = 0;
1191 match_length = MIN_MATCH-1;
1192 strstart++;
1193
1194 if (bflush){
1195 flush_block_only(false);
1196 if(strm.avail_out==0) return NeedMore;
1197 }
1198 } else if (match_available!=0) {
1199
1200 // If there was no match at the previous position, output a
1201 // single literal. If there was a match but the current match
1202 // is longer, truncate the previous match to a single literal.
1203
1204 bflush=_tr_tally(0, window[strstart-1]&0xff);
1205
1206 if (bflush) {
1207 flush_block_only(false);
1208 }
1209 strstart++;
1210 lookahead--;
1211 if(strm.avail_out == 0) return NeedMore;
1212 } else {
1213 // There is no previous match to compare with, wait for
1214 // the next step to decide.
1215
1216 match_available = 1;
1217 strstart++;
1218 lookahead--;
1219 }
1220 }
1221
1222 if(match_available!=0) {
1223 bflush=_tr_tally(0, window[strstart-1]&0xff);
1224 match_available = 0;
1225 }
1226 flush_block_only(flush == Z_FINISH);
1227
1228 if(strm.avail_out==0){
1229 if(flush == Z_FINISH) return FinishStarted;
1230 else return NeedMore;
1231 }
1232
1233 return flush == Z_FINISH ? FinishDone : BlockDone;
1234 }
1235
1236 int longest_match(int cur_match){
1237 int chain_length = max_chain_length; // max hash chain length
1238 int scan = strstart; // current string
1239 int match; // matched string
1240 int len; // length of current match
1241 int best_len = prev_length; // best match length so far
1242 int limit = strstart>(w_size-MIN_LOOKAHEAD) ?
1243 strstart-(w_size-MIN_LOOKAHEAD) : 0;
1244 int nice_match=this.nice_match;
1245
1246 // Stop when cur_match becomes <= limit. To simplify the code,
1247 // we prevent matches with the string of window index 0.
1248
1249 int wmask = w_mask;
1250
1251 int strend = strstart + MAX_MATCH;
1252 byte scan_end1 = window[scan+best_len-1];
1253 byte scan_end = window[scan+best_len];
1254
1255 // The code is optimized for HASH_BITS >= 8 and MAX_MATCH-2 multiple of 16.
1256 // It is easy to get rid of this optimization if necessary.
1257
1258 // Do not waste too much time if we already have a good match:
1259 if (prev_length >= good_match) {
1260 chain_length >>= 2;
1261 }
1262
1263 // Do not look for matches beyond the end of the input. This is necessary
1264 // to make deflate deterministic.
1265 if (nice_match > lookahead) nice_match = lookahead;
1266
1267 do {
1268 match = cur_match;
1269
1270 // Skip to next match if the match length cannot increase
1271 // or if the match length is less than 2:
1272 if (window[match+best_len] != scan_end ||
1273 window[match+best_len-1] != scan_end1 ||
1274 window[match] != window[scan] ||
1275 window[++match] != window[scan+1]) continue;
1276
1277 // The check at best_len-1 can be removed because it will be made
1278 // again later. (This heuristic is not always a win.)
1279 // It is not necessary to compare scan[2] and match[2] since they
1280 // are always equal when the other bytes match, given that
1281 // the hash keys are equal and that HASH_BITS >= 8.
1282 scan += 2; match++;
1283
1284 // We check for insufficient lookahead only every 8th comparison;
1285 // the 256th check will be made at strstart+258.
1286 do {
1287 } while (window[++scan] == window[++match] &&
1288 window[++scan] == window[++match] &&
1289 window[++scan] == window[++match] &&
1290 window[++scan] == window[++match] &&
1291 window[++scan] == window[++match] &&
1292 window[++scan] == window[++match] &&
1293 window[++scan] == window[++match] &&
1294 window[++scan] == window[++match] &&
1295 scan < strend);
1296
1297 len = MAX_MATCH - (int)(strend - scan);
1298 scan = strend - MAX_MATCH;
1299
1300 if(len>best_len) {
1301 match_start = cur_match;
1302 best_len = len;
1303 if (len >= nice_match) break;
1304 scan_end1 = window[scan+best_len-1];
1305 scan_end = window[scan+best_len];
1306 }
1307
1308 } while ((cur_match = (prev[cur_match & wmask]&0xffff)) > limit
1309 && --chain_length != 0);
1310
1311 if (best_len <= lookahead) return best_len;
1312 return lookahead;
1313 }
1314
1315 int deflateInit(ZStream strm, int level, int bits){
1316 return deflateInit2(strm, level, Z_DEFLATED, bits, DEF_MEM_LEVEL,
1317 Z_DEFAULT_STRATEGY);
1318 }
1319 int deflateInit(ZStream strm, int level){
1320 return deflateInit(strm, level, MAX_WBITS);
1321 }
1322 int deflateInit2(ZStream strm, int level, int method, int windowBits,
1323 int memLevel, int strategy){
1324 int noheader = 0;
1325 // byte[] my_version=ZLIB_VERSION;
1326
1327 //
1328 // if (version == null || version[0] != my_version[0]
1329 // || stream_size != sizeof(z_stream)) {
1330 // return Z_VERSION_ERROR;
1331 // }
1332
1333 strm.msg = null;
1334
1335 if (level == Z_DEFAULT_COMPRESSION) level = 6;
1336
1337 if (windowBits < 0) { // undocumented feature: suppress zlib header
1338 noheader = 1;
1339 windowBits = -windowBits;
1340 }
1341
1342 if (memLevel < 1 || memLevel > MAX_MEM_LEVEL ||
1343 method != Z_DEFLATED ||
1344 windowBits < 9 || windowBits > 15 || level < 0 || level > 9 ||
1345 strategy < 0 || strategy > Z_HUFFMAN_ONLY) {
1346 return Z_STREAM_ERROR;
1347 }
1348
1349 strm.dstate = (Deflate)this;
1350
1351 this.noheader = noheader;
1352 w_bits = windowBits;
1353 w_size = 1 << w_bits;
1354 w_mask = w_size - 1;
1355
1356 hash_bits = memLevel + 7;
1357 hash_size = 1 << hash_bits;
1358 hash_mask = hash_size - 1;
1359 hash_shift = ((hash_bits+MIN_MATCH-1)/MIN_MATCH);
1360
1361 window = new byte[w_size*2];
1362 prev = new short[w_size];
1363 head = new short[hash_size];
1364
1365 lit_bufsize = 1 << (memLevel + 6); // 16K elements by default
1366
1367 // We overlay pending_buf and d_buf+l_buf. This works since the average
1368 // output size for (length,distance) codes is <= 24 bits.
1369 pending_buf = new byte[lit_bufsize*4];
1370 pending_buf_size = lit_bufsize*4;
1371
1372 d_buf = lit_bufsize/2;
1373 l_buf = (1+2)*lit_bufsize;
1374
1375 this.level = level;
1376
1377//System.out.println("level="+level);
1378
1379 this.strategy = strategy;
1380 this.method = (byte)method;
1381
1382 return deflateReset(strm);
1383 }
1384
1385 int deflateReset(ZStream strm){
1386 strm.total_in = strm.total_out = 0;
1387 strm.msg = null; //
1388 strm.data_type = Z_UNKNOWN;
1389
1390 pending = 0;
1391 pending_out = 0;
1392
1393 if(noheader < 0) {
1394 noheader = 0; // was set to -1 by deflate(..., Z_FINISH);
1395 }
1396 status = (noheader!=0) ? BUSY_STATE : INIT_STATE;
1397 strm.adler=strm._adler.adler32(0, null, 0, 0);
1398
1399 last_flush = Z_NO_FLUSH;
1400
1401 tr_init();
1402 lm_init();
1403 return Z_OK;
1404 }
1405
1406 int deflateEnd(){
1407 if(status!=INIT_STATE && status!=BUSY_STATE && status!=FINISH_STATE){
1408 return Z_STREAM_ERROR;
1409 }
1410 // Deallocate in reverse order of allocations:
1411 pending_buf=null;
1412 head=null;
1413 prev=null;
1414 window=null;
1415 // free
1416 // dstate=null;
1417 return status == BUSY_STATE ? Z_DATA_ERROR : Z_OK;
1418 }
1419
1420 int deflateParams(ZStream strm, int _level, int _strategy){
1421 int err=Z_OK;
1422
1423 if(_level == Z_DEFAULT_COMPRESSION){
1424 _level = 6;
1425 }
1426 if(_level < 0 || _level > 9 ||
1427 _strategy < 0 || _strategy > Z_HUFFMAN_ONLY) {
1428 return Z_STREAM_ERROR;
1429 }
1430
1431 if(config_table[level].func!=config_table[_level].func &&
1432 strm.total_in != 0) {
1433 // Flush the last buffer:
1434 err = strm.deflate(Z_PARTIAL_FLUSH);
1435 }
1436
1437 if(level != _level) {
1438 level = _level;
1439 max_lazy_match = config_table[level].max_lazy;
1440 good_match = config_table[level].good_length;
1441 nice_match = config_table[level].nice_length;
1442 max_chain_length = config_table[level].max_chain;
1443 }
1444 strategy = _strategy;
1445 return err;
1446 }
1447
1448 int deflateSetDictionary (ZStream strm, byte[] dictionary, int dictLength){
1449 int length = dictLength;
1450 int index=0;
1451
1452 if(dictionary == null || status != INIT_STATE)
1453 return Z_STREAM_ERROR;
1454
1455 strm.adler=strm._adler.adler32(strm.adler, dictionary, 0, dictLength);
1456
1457 if(length < MIN_MATCH) return Z_OK;
1458 if(length > w_size-MIN_LOOKAHEAD){
1459 length = w_size-MIN_LOOKAHEAD;
1460 index=dictLength-length; // use the tail of the dictionary
1461 }
1462 System.arraycopy(dictionary, index, window, 0, length);
1463 strstart = length;
1464 block_start = length;
1465
1466 // Insert all strings in the hash table (except for the last two bytes).
1467 // s->lookahead stays null, so s->ins_h will be recomputed at the next
1468 // call of fill_window.
1469
1470 ins_h = window[0]&0xff;
1471 ins_h=(((ins_h)<<hash_shift)^(window[1]&0xff))&hash_mask;
1472
1473 for(int n=0; n<=length-MIN_MATCH; n++){
1474 ins_h=(((ins_h)<<hash_shift)^(window[(n)+(MIN_MATCH-1)]&0xff))&hash_mask;
1475 prev[n&w_mask]=head[ins_h];
1476 head[ins_h]=(short)n;
1477 }
1478 return Z_OK;
1479 }
1480
1481 int deflate(ZStream strm, int flush){
1482 int old_flush;
1483
1484 if(flush>Z_FINISH || flush<0){
1485 return Z_STREAM_ERROR;
1486 }
1487
1488 if(strm.next_out == null ||
1489 (strm.next_in == null && strm.avail_in != 0) ||
1490 (status == FINISH_STATE && flush != Z_FINISH)) {
1491 strm.msg=z_errmsg[Z_NEED_DICT-(Z_STREAM_ERROR)];
1492 return Z_STREAM_ERROR;
1493 }
1494 if(strm.avail_out == 0){
1495 strm.msg=z_errmsg[Z_NEED_DICT-(Z_BUF_ERROR)];
1496 return Z_BUF_ERROR;
1497 }
1498
1499 this.strm = strm; // just in case
1500 old_flush = last_flush;
1501 last_flush = flush;
1502
1503 // Write the zlib header
1504 if(status == INIT_STATE) {
1505 int header = (Z_DEFLATED+((w_bits-8)<<4))<<8;
1506 int level_flags=((level-1)&0xff)>>1;
1507
1508 if(level_flags>3) level_flags=3;
1509 header |= (level_flags<<6);
1510 if(strstart!=0) header |= PRESET_DICT;
1511 header+=31-(header % 31);
1512
1513 status=BUSY_STATE;
1514 putShortMSB(header);
1515
1516
1517 // Save the adler32 of the preset dictionary:
1518 if(strstart!=0){
1519 putShortMSB((int)(strm.adler>>>16));
1520 putShortMSB((int)(strm.adler&0xffff));
1521 }
1522 strm.adler=strm._adler.adler32(0, null, 0, 0);
1523 }
1524
1525 // Flush as much pending output as possible
1526 if(pending != 0) {
1527 strm.flush_pending();
1528 if(strm.avail_out == 0) {
1529 //System.out.println(" avail_out==0");
1530 // Since avail_out is 0, deflate will be called again with
1531 // more output space, but possibly with both pending and
1532 // avail_in equal to zero. There won't be anything to do,
1533 // but this is not an error situation so make sure we
1534 // return OK instead of BUF_ERROR at next call of deflate:
1535 last_flush = -1;
1536 return Z_OK;
1537 }
1538
1539 // Make sure there is something to do and avoid duplicate consecutive
1540 // flushes. For repeated and useless calls with Z_FINISH, we keep
1541 // returning Z_STREAM_END instead of Z_BUFF_ERROR.
1542 }
1543 else if(strm.avail_in==0 && flush <= old_flush &&
1544 flush != Z_FINISH) {
1545 strm.msg=z_errmsg[Z_NEED_DICT-(Z_BUF_ERROR)];
1546 return Z_BUF_ERROR;
1547 }
1548
1549 // User must not provide more input after the first FINISH:
1550 if(status == FINISH_STATE && strm.avail_in != 0) {
1551 strm.msg=z_errmsg[Z_NEED_DICT-(Z_BUF_ERROR)];
1552 return Z_BUF_ERROR;
1553 }
1554
1555 // Start a new block or continue the current one.
1556 if(strm.avail_in!=0 || lookahead!=0 ||
1557 (flush != Z_NO_FLUSH && status != FINISH_STATE)) {
1558 int bstate=-1;
1559 switch(config_table[level].func){
1560 case STORED:
1561 bstate = deflate_stored(flush);
1562 break;
1563 case FAST:
1564 bstate = deflate_fast(flush);
1565 break;
1566 case SLOW:
1567 bstate = deflate_slow(flush);
1568 break;
1569 default:
1570 }
1571
1572 if (bstate==FinishStarted || bstate==FinishDone) {
1573 status = FINISH_STATE;
1574 }
1575 if (bstate==NeedMore || bstate==FinishStarted) {
1576 if(strm.avail_out == 0) {
1577 last_flush = -1; // avoid BUF_ERROR next call, see above
1578 }
1579 return Z_OK;
1580 // If flush != Z_NO_FLUSH && avail_out == 0, the next call
1581 // of deflate should use the same flush parameter to make sure
1582 // that the flush is complete. So we don't have to output an
1583 // empty block here, this will be done at next call. This also
1584 // ensures that for a very small output buffer, we emit at most
1585 // one empty block.
1586 }
1587
1588 if (bstate==BlockDone) {
1589 if(flush == Z_PARTIAL_FLUSH) {
1590 _tr_align();
1591 }
1592 else { // FULL_FLUSH or SYNC_FLUSH
1593 _tr_stored_block(0, 0, false);
1594 // For a full flush, this empty block will be recognized
1595 // as a special marker by inflate_sync().
1596 if(flush == Z_FULL_FLUSH) {
1597 //state.head[s.hash_size-1]=0;
1598 for(int i=0; i<hash_size/*-1*/; i++) // forget history
1599 head[i]=0;
1600 }
1601 }
1602 strm.flush_pending();
1603 if(strm.avail_out == 0) {
1604 last_flush = -1; // avoid BUF_ERROR at next call, see above
1605 return Z_OK;
1606 }
1607 }
1608 }
1609
1610 if(flush!=Z_FINISH) return Z_OK;
1611 if(noheader!=0) return Z_STREAM_END;
1612
1613 // Write the zlib trailer (adler32)
1614 putShortMSB((int)(strm.adler>>>16));
1615 putShortMSB((int)(strm.adler&0xffff));
1616 strm.flush_pending();
1617
1618 // If avail_out is zero, the application will call deflate again
1619 // to flush the rest.
1620 noheader = -1; // write the trailer only once!
1621 return pending != 0 ? Z_OK : Z_STREAM_END;
1622 }
1623}
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