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// THIS FILE HAS BEEN GENERATED BY A PREPROCESSOR.
/* +=======================================================================
* |
* | PlantUML : a free UML diagram generator
* |
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* (C) Copyright 2009-2024, Arnaud Roques
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* Licensed under the Apache License, Version 2.0 (the "License");
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* are owned by the author of their corresponding sources code (that is, their
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* The generated images can then be used without any reference to the APACHE license.
* It is not even necessary to stipulate that they have been generated with PlantUML,
* although this will be appreciated by the PlantUML team.
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* There is an exception : if the textual description in PlantUML language is also covered
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* by the very same license.
*
* This is the IGY distribution (Install GraphViz by Yourself).
* You have to install GraphViz and to setup the GRAPHVIZ_DOT environment variable
* (see https://plantuml.com/graphviz-dot )
*
* Icons provided by OpenIconic : https://useiconic.com/open
* Archimate sprites provided by Archi : http://www.archimatetool.com
* Stdlib AWS provided by https://github.com/milo-minderbinder/AWS-PlantUML
* Stdlib Icons provided https://github.com/tupadr3/plantuml-icon-font-sprites
* ASCIIMathML (c) Peter Jipsen http://www.chapman.edu/~jipsen
* ASCIIMathML (c) David Lippman http://www.pierce.ctc.edu/dlippman
* CafeUndZopfli ported by Eugene Klyuchnikov https://github.com/eustas/CafeUndZopfli
* Brotli (c) by the Brotli Authors https://github.com/google/brotli
* Themes (c) by Brett Schwarz https://github.com/bschwarz/puml-themes
* Twemoji (c) by Twitter at https://twemoji.twitter.com/
*
*/
package net.sourceforge.plantuml.zopfli;
class Deflate {
static enum BlockType {
DYNAMIC, FIXED
}
// final static int WINDOW_SIZE = 0x8000;
// final static int WINDOW_MASK = 0x7FFF;
// final static int MAX_MATCH = 258;
// final static int MIN_MATCH = 3;
// final static int MAX_CHAIN_HITS = 8192; // Should be less than WINDOW_SIZE
private static void getFixedTree(int[] llLengths, int[] dLengths) {
for (int i = 0; i < 144; i++) {
llLengths[i] = 8;
}
for (int i = 144; i < 256; i++) {
llLengths[i] = 9;
}
for (int i = 256; i < 280; i++) {
llLengths[i] = 7;
}
for (int i = 280; i < 288; i++) {
llLengths[i] = 8;
}
for (int i = 0; i < 32; i++) {
dLengths[i] = 5;
}
}
public static void greedy(Cookie cookie, LongestMatchCache lmc, byte[] input, int from, int to, LzStore store) {
Hash h = cookie.h;
h.init(input, Math.max(from - 0x8000, 0), from, to);
int prevLength = 0;
int prevMatch = 0;
char[] dummySubLen = cookie.c259a;
boolean matchAvailable = false;
for (int i = from; i < to; i++) {
h.updateHash(input, i, to);
findLongestMatch(cookie, lmc, from, h, input, i, to, 258, dummySubLen);
int len = cookie.lenVal;
int dist = cookie.distVal;
int lengthScore = dist > 1024 ? len - 1 : len;
int prevLengthScore = prevMatch > 1024 ? prevLength - 1 : prevLength;
if (matchAvailable) {
matchAvailable = false;
if (lengthScore > prevLengthScore + 1) {
store.append((char) (input[i - 1] & 0xFF), (char) 0);
if (lengthScore >= 3 && len < 258) {
matchAvailable = true;
prevLength = len;
prevMatch = dist;
continue;
}
} else {
store.append((char) prevLength, (char) prevMatch);
for (int j = 2; j < prevLength; j++) {
i++;
h.updateHash(input, i, to);
}
continue;
}
} else if (lengthScore >= 3 && len < 258) {
matchAvailable = true;
prevLength = len;
prevMatch = dist;
continue;
}
if (lengthScore >= 3) {
store.append((char) len, (char) dist);
} else {
len = 1;
store.append((char) (input[i] & 0xFF), (char) 0);
}
for (int j = 1; j < len; j++) {
i++;
h.updateHash(input, i, to);
}
}
}
static void findLongestMatch(Cookie cookie, LongestMatchCache lmc, int blockStart, Hash h, byte[] array, int pos,
int size, int limit, char[] subLen) {
// # WINDOW_SIZE = 0x8000
// # WINDOW_MASK = 0x7FFF
// # MIN_MATCH = 3
// # MAX_MATCH = 258
int offset = pos - blockStart;
char[] lmcLength = lmc != null ? lmc.length : null;
if (lmc != null && ((lmcLength[offset] == 0 || lmc.dist[offset] != 0)) && (limit == 258
|| lmcLength[offset] <= limit || subLen != null && lmc.maxCachedSubLen(offset) >= limit)) {
if (subLen == null || lmcLength[offset] <= lmc.maxCachedSubLen(offset)) {
cookie.lenVal = lmcLength[offset];
if (cookie.lenVal > limit) {
cookie.lenVal = limit;
}
if (subLen != null) {
lmc.cacheToSubLen(offset, cookie.lenVal, subLen);
cookie.distVal = subLen[cookie.lenVal];
} else {
cookie.distVal = lmc.dist[offset];
}
return;
}
limit = lmcLength[offset];
}
if (size - pos < 3) {
cookie.lenVal = 0;
cookie.distVal = 0;
return;
}
if (pos + limit > size) {
limit = size - pos;
}
int bestDist = 0;
int bestLength = 1;
int arrayEnd = pos + limit;
int chainCounter = 8192;
int[] hPrev = h.prev;
int[] hPrev2 = h.prev2;
int pp = h.head[h.val];
int threshold = h.same[pp];
int[] hashVal2 = h.hashVal2;
int marker = hashVal2[pp];
int p = hPrev[pp];
pp -= p;
int dist = pp > 0 ? pp : pp + 0x8000;
while (dist < 0x8000 && chainCounter > 0) {
int scan = pos;
int match = pos - dist;
if (array[scan + bestLength] == array[match + bestLength]) {
int same0 = h.same[pos & 0x7FFF];
if (same0 > 2 && array[scan] == array[match]) {
int same1 = h.same[match & 0x7FFF];
int same = same0 < same1 ? same0 : same1;
if (same > limit) {
same = limit;
}
scan += same;
match += same;
}
while (scan != arrayEnd && array[scan] == array[match]) {
scan++;
match++;
}
scan -= pos;
if (scan > bestLength) {
if (subLen != null) {
for (int j = bestLength + 1; j <= scan; j++) {
subLen[j] = (char) dist;
}
}
bestDist = dist;
bestLength = scan;
if (scan >= limit) {
break;
}
}
}
if (hPrev != hPrev2 && bestLength >= threshold && marker == hashVal2[p]) {
hPrev = hPrev2;
}
pp = p;
p = hPrev[p];
if (p == pp) {
break;
}
pp -= p;
dist += pp > 0 ? pp : 0x8000 + pp;
--chainCounter;
}
if (lmc != null && limit == 258 && subLen != null && lmcLength[offset] != 0 && lmc.dist[offset] == 0) {
if (bestLength < 3) {
lmc.dist[offset] = 0;
lmcLength[offset] = 0;
} else {
lmc.dist[offset] = (char) bestDist;
lmcLength[offset] = (char) bestLength;
}
lmc.subLenToCache(subLen, offset, bestLength);
}
cookie.distVal = bestDist;
cookie.lenVal = bestLength;
}
private static void deflatePart(Cookie cookie, Options options, byte[] input, int from, int to, boolean flush,
Buffer output) {
// assert from != to
switch (options.blockSplitting) {
case FIRST:
deflateSplittingFirst(cookie, options, flush, input, from, to, output);
break;
case LAST:
deflateSplittingLast(cookie, options, flush, input, from, to, output);
break;
case NONE:
deflateDynamicBlock(cookie, options, flush, input, from, to, output);
break;
}
}
private static void deflateDynamicBlock(Cookie cookie, Options options, boolean flush, byte[] input, int from,
int to, Buffer output) {
// assert from != to
LongestMatchCache lmc = cookie.lmc;
lmc.init(to - from);
BlockType type = BlockType.DYNAMIC;
LzStore store = Squeeze.optimal(cookie, options.numIterations, lmc, input, from, to);
if (store.size < 1000) {
LzStore fixedStore = cookie.store1;
fixedStore.reset();
Squeeze.bestFixedLengths(cookie, lmc, input, from, to, cookie.lengthArray, cookie.costs);
Squeeze.optimalRun(cookie, lmc, input, from, to, cookie.lengthArray, fixedStore);
int dynCost = calculateBlockSize(cookie, store.litLens, store.dists, 0, store.size);
int fixedCost = calculateFixedBlockSize(cookie, fixedStore.litLens, fixedStore.dists, fixedStore.size);
if (fixedCost < dynCost) {
type = BlockType.FIXED;
store = fixedStore;
}
}
addLzBlock(cookie, type, flush, store.litLens, store.dists, 0, store.size, output);
}
private static void deflateSplittingLast(Cookie cookie, Options options, boolean flush, byte[] input, int from,
int to, Buffer output) {
// assert from != to
LongestMatchCache lmc = cookie.lmc;
lmc.init(to - from);
LzStore store = Squeeze.optimal(cookie, options.numIterations, lmc, input, from, to);
int nPoints = BlockSplitter.splitLz(cookie, store.litLens, store.dists, store.size);
int[] splitPoints = cookie.splitPoints;
for (int i = 1; i <= nPoints; i++) {
int start = splitPoints[i - 1];
int end = splitPoints[i];
addLzBlock(cookie, BlockType.DYNAMIC, i == nPoints && flush, store.litLens, store.dists, start, end,
output);
}
}
private static void deflateSplittingFirst(Cookie cookie, Options options, boolean flush, byte[] input, int from,
int to, Buffer output) {
// assert from != to
int nPoints = BlockSplitter.split(cookie, input, from, to);
int[] splitPoints = cookie.splitPoints;
for (int i = 1; i <= nPoints; ++i) {
deflateDynamicBlock(cookie, options, i == nPoints && flush, input, splitPoints[i - 1], splitPoints[i],
output);
}
}
static int calculateBlockSize(Cookie cookie, char[] litLens, char[] dists, int lStart, int lEnd) {
int[] llLengths = cookie.i288a;
System.arraycopy(Cookie.intZeroes, 0, llLengths, 0, 288);
int[] dLengths = cookie.i32a;
System.arraycopy(Cookie.intZeroes, 0, dLengths, 0, 32);
int result = 3;
int[] llCounts = cookie.i288b;
System.arraycopy(Cookie.intZeroes, 0, llCounts, 0, 288);
int[] dCounts = cookie.i32b;
System.arraycopy(Cookie.intZeroes, 0, dCounts, 0, 32);
int[] lengthSymbol = Util.LENGTH_SYMBOL;
int[] cachedDistSymbol = Util.CACHED_DIST_SYMBOL;
int[] lengthExtraBits = Util.LENGTH_EXTRA_BITS;
for (int i = lStart; i < lEnd; i++) {
int d = dists[i];
int l = litLens[i];
if (d == 0) {
llCounts[l]++;
} else {
llCounts[lengthSymbol[l]]++;
int distSymbol = cachedDistSymbol[d];
dCounts[distSymbol]++;
result += lengthExtraBits[l];
if (distSymbol > 3) {
result += (distSymbol / 2) - 1;
}
}
}
llCounts[256] = 1;
int[] llCountsCopy = cookie.i288c;
System.arraycopy(llCounts, 0, llCountsCopy, 0, 288);
optimizeHuffmanForRle(cookie, llCountsCopy);
Katajainen.lengthLimitedCodeLengths(cookie, llCountsCopy, 15, llLengths);
int[] dCountsCopy = cookie.i32c;
System.arraycopy(dCounts, 0, dCountsCopy, 0, 32);
optimizeHuffmanForRle(cookie, dCountsCopy);
Katajainen.lengthLimitedCodeLengths(cookie, dCountsCopy, 15, dLengths);
patchDistanceCodesForBuggyDecoders(dLengths);
result += simulateAddDynamicTree(cookie, llLengths, dLengths);
for (int i = 0; i < 288; ++i) {
result += llCounts[i] * llLengths[i];
}
for (int i = 0; i < 32; ++i) {
result += dCounts[i] * dLengths[i];
}
return result;
}
private static int calculateFixedBlockSize(Cookie cookie, char[] litLens, char[] dists, int size) {
int[] llLengths = cookie.i288a;
int[] dLengths = cookie.i32a;
getFixedTree(llLengths, dLengths);
int result = 3;
int[] cachedDistExtraBits = Util.CACHED_DIST_EXTRA_BITS;
int[] lengthExtraBits = Util.LENGTH_EXTRA_BITS;
int[] lengthSymbol = Util.LENGTH_SYMBOL;
for (int i = 0; i < size; i++) {
int d = dists[i];
int l = litLens[i];
if (d == 0) {
result += llLengths[l];
} else {
result += llLengths[lengthSymbol[l]];
result += lengthExtraBits[l];
result += 5;
result += d < 4097 ? cachedDistExtraBits[d] : d < 16385 ? d < 8193 ? 11 : 12 : 13;
}
}
result += llLengths[256];
return result;
}
private static void lzCounts(char[] litLens, char[] dists, int start, int end, int[] llCount, int[] dCount) {
int[] lengthSymbol = Util.LENGTH_SYMBOL;
int[] cachedDistSymbol = Util.CACHED_DIST_SYMBOL;
for (int i = start; i < end; i++) {
int d = dists[i];
int l = litLens[i];
if (d == 0) {
llCount[l]++;
} else {
llCount[lengthSymbol[l]]++;
dCount[cachedDistSymbol[d]]++;
}
}
llCount[256] = 1;
}
static void compress(Cookie cookie, Options options, byte[] input, Buffer output) {
int i = 0;
while (i < input.length) {
int j = Math.min(i + cookie.masterBlockSize, input.length);
deflatePart(cookie, options, input, i, j, j == input.length, output);
i = j;
}
}
private static void patchDistanceCodesForBuggyDecoders(int[] dLengths) {
int numDistCodes = 0;
for (int i = 0; i < 30; i++) {
if (dLengths[i] != 0) {
numDistCodes++;
if (numDistCodes == 2) {
return;
}
}
}
if (numDistCodes == 0) {
dLengths[0] = 1;
dLengths[1] = 1;
} else if (numDistCodes == 1) {
dLengths[dLengths[0] != 0 ? 1 : 0] = 1;
}
}
private static void addDynamicTree(Cookie cookie, int[] llLengths, int[] dLengths, Buffer output) {
int best = 0;
int bestSize = Integer.MAX_VALUE;
for (int i = 0; i < 8; i++) {
int size = simulateEncodeTree(cookie, llLengths, dLengths, (i & 1) != 0, (i & 2) != 0, (i & 4) != 0);
if (size < bestSize) {
bestSize = size;
best = i;
}
}
encodeTree(cookie, llLengths, dLengths, (best & 1) != 0, (best & 2) != 0, (best & 4) != 0, output);
}
private static void encodeTree(Cookie cookie, int[] llLengths, int[] dLengths, boolean use16, boolean use17,
boolean use18, Buffer output) {
int hLit = 29;
int hDist = 29;
while (hLit > 0 && llLengths[256 + hLit] == 0) {
hLit--;
}
while (hDist > 0 && dLengths[hDist] == 0) {
hDist--;
}
int lldTotal = hLit + 258 + hDist;
int[] lldLengths = cookie.i320b;
System.arraycopy(llLengths, 0, lldLengths, 0, 257 + hLit);
System.arraycopy(dLengths, 0, lldLengths, 257 + hLit, hDist + 1);
int rleSize = 0;
int[] rle = cookie.i320a;
int[] rleBits = cookie.i320c;
for (int i = 0; i < lldTotal; i++) {
int count = 1;
int symbol = lldLengths[i];
if (use16 || (symbol == 0 && (use17 || use18))) {
for (int j = i + 1; j < lldTotal && symbol == lldLengths[j]; j++) {
count++;
}
}
i += count - 1;
if (symbol == 0 && count > 2) {
if (use18) {
while (count > 10) {
int delta = count > 138 ? 138 : count;
rle[rleSize] = 18;
rleBits[rleSize++] = delta - 11;
count -= delta;
}
}
if (use17) {
while (count > 2) {
int delta = count > 10 ? 10 : count;
rle[rleSize] = 17;
rleBits[rleSize++] = delta - 3;
count -= delta;
}
}
}
if (use16 && count > 3) {
count--;
rle[rleSize] = symbol;
rleBits[rleSize++] = 0;
while (count > 2) {
int delta = count > 6 ? 6 : count;
rle[rleSize] = 16;
rleBits[rleSize++] = delta - 3;
count -= delta;
}
}
while (count != 0) {
rle[rleSize] = symbol;
rleBits[rleSize++] = 0;
count--;
}
}
int[] clCounts = cookie.i19a;
System.arraycopy(Cookie.intZeroes, 0, clCounts, 0, 19);
for (int i = 0; i < rleSize; ++i) {
clCounts[rle[i]]++;
}
int[] clCl = cookie.i19b;
System.arraycopy(Cookie.intZeroes, 0, clCl, 0, 19);
Katajainen.lengthLimitedCodeLengths(cookie, clCounts, 7, clCl);
int[] clSymbols = cookie.i19c;
lengthsToSymbols(clCl, 19, 7, clSymbols, cookie.i16a, cookie.i16b);
int[] order = Util.ORDER;
int hcLen = 15;
while (hcLen > 0 && clCounts[order[hcLen + 3]] == 0) {
hcLen--;
}
output.addBits(hLit, 5);
output.addBits(hDist, 5);
output.addBits(hcLen, 4);
for (int i = 0; i < hcLen + 4; i++) {
output.addBits(clCl[order[i]], 3);
}
for (int i = 0; i < rleSize; i++) {
int symbol = clSymbols[rle[i]];
output.addHuffmanBits(symbol, clCl[rle[i]]);
if (rle[i] == 16) {
output.addBits(rleBits[i], 2);
} else if (rle[i] == 17) {
output.addBits(rleBits[i], 3);
} else if (rle[i] == 18) {
output.addBits(rleBits[i], 7);
}
}
}
private static int simulateAddDynamicTree(Cookie cookie, int[] llLengths, int[] dLengths) {
int bestSize = Integer.MAX_VALUE;
for (int i = 0; i < 8; i++) {
int size = simulateEncodeTree(cookie, llLengths, dLengths, (i & 1) != 0, (i & 2) != 0, (i & 4) != 0);
if (size < bestSize) {
bestSize = size;
}
}
return bestSize;
}
// TODO: GetRid of RLE
private static int simulateEncodeTree(Cookie cookie, int[] llLengths, int[] dLengths, boolean use16, boolean use17,
boolean use18) {
int hLit = 29;
int hDist = 29;
while (hLit > 0 && llLengths[256 + hLit] == 0) {
hLit--;
}
while (hDist > 0 && dLengths[hDist] == 0) {
hDist--;
}
int lldTotal = hLit + 258 + hDist;
int[] lldLengths = cookie.i320b;
System.arraycopy(llLengths, 0, lldLengths, 0, 257 + hLit);
System.arraycopy(dLengths, 0, lldLengths, 257 + hLit, hDist + 1);
int[] rle = cookie.i320a;
int rleSize = 0;
for (int i = 0; i < lldTotal; i++) {
int count = 1;
int symbol = lldLengths[i];
if (use16 || (symbol == 0 && (use17 || use18))) {
for (int j = i + 1; j < lldTotal && symbol == lldLengths[j]; j++) {
count++;
}
}
i += count - 1;
if (symbol == 0 && count > 2) {
if (use18) {
while (count > 10) {
rle[rleSize++] = 18;
count -= count > 138 ? 138 : count;
}
}
if (use17) {
while (count > 2) {
rle[rleSize++] = 17;
count -= count > 10 ? 10 : count;
}
}
}
if (use16 && count > 3) {
count--;
rle[rleSize++] = symbol;
while (count > 2) {
rle[rleSize++] = 16;
count -= count > 6 ? 6 : count;
}
}
while (count != 0) {
rle[rleSize++] = symbol;
count--;
}
}
int[] clCounts = cookie.i19a;
System.arraycopy(Cookie.intZeroes, 0, clCounts, 0, 19);
for (int i = 0; i < rleSize; ++i) {
clCounts[rle[i]]++;
}
int[] clCl = cookie.i19b;
System.arraycopy(Cookie.intZeroes, 0, clCl, 0, 19);
Katajainen.lengthLimitedCodeLengths(cookie, clCounts, 7, clCl);
clCl[16] += 2;
clCl[17] += 3;
clCl[18] += 7;
int[] order = Util.ORDER;
int hcLen = 15;
while (hcLen > 0 && clCounts[order[hcLen + 3]] == 0) {
hcLen--;
}
int result = 5 + 5 + 4 + (hcLen + 4) * 3;
for (int i = 0; i < 19; i++) {
result += clCl[i] * clCounts[i];
}
return result;
}
private static void addLzBlock(Cookie cookie, BlockType type, boolean last, char[] litLens, char[] dists,
int lStart, int lEnd, Buffer output) {
int[] llLengths = cookie.i288a;
System.arraycopy(Cookie.intZeroes, 0, llLengths, 0, 288);
int[] dLengths = cookie.i32a;
System.arraycopy(Cookie.intZeroes, 0, dLengths, 0, 32);
int[] llCounts = cookie.i288b;
System.arraycopy(Cookie.intZeroes, 0, llCounts, 0, 288);
int[] dCounts = cookie.i32b;
System.arraycopy(Cookie.intZeroes, 0, dCounts, 0, 32);
output.addHuffmanBits(last ? 1 : 0, 1);
if (type == BlockType.FIXED) {
output.addHuffmanBits(2, 2); // 1, 0
} else { // DYNAMIC
output.addHuffmanBits(1, 2); // 0, 1
}
if (type == BlockType.FIXED) {
getFixedTree(llLengths, dLengths);
} else { // DYNAMIC
lzCounts(litLens, dists, lStart, lEnd, llCounts, dCounts);
optimizeHuffmanForRle(cookie, llCounts);
Katajainen.lengthLimitedCodeLengths(cookie, llCounts, 15, llLengths);
optimizeHuffmanForRle(cookie, dCounts);
Katajainen.lengthLimitedCodeLengths(cookie, dCounts, 15, dLengths);
patchDistanceCodesForBuggyDecoders(dLengths);
addDynamicTree(cookie, llLengths, dLengths, output);
}
int[] llSymbols = cookie.i288c;
System.arraycopy(Cookie.intZeroes, 0, llSymbols, 0, 288);
lengthsToSymbols(llLengths, 288, 15, llSymbols, cookie.i16a, cookie.i16b);
int[] dSymbols = cookie.i32b;
System.arraycopy(Cookie.intZeroes, 0, dSymbols, 0, 32);
lengthsToSymbols(dLengths, 32, 15, dSymbols, cookie.i16a, cookie.i16b);
addLzData(litLens, dists, lStart, lEnd, llSymbols, llLengths, dSymbols, dLengths, output);
output.addHuffmanBits(llSymbols[256], llLengths[256]);
}
private static void addLzData(char[] litLens, char[] dists, int lStart, int lEnd, int[] llSymbols, int[] llLengths,
int[] dSymbols, int[] dLengths, Buffer output) {
int[] cachedDistExtraBits = Util.CACHED_DIST_EXTRA_BITS;
int[] lengthExtraBits = Util.LENGTH_EXTRA_BITS;
int[] lengthExtraBitsValue = Util.LENGTH_EXTRA_BITS_VALUE;
int[] lengthSymbol = Util.LENGTH_SYMBOL;
int[] cachedDistSymbol = Util.CACHED_DIST_SYMBOL;
for (int i = lStart; i < lEnd; i++) {
int dist = dists[i];
int litLen = litLens[i];
if (dist == 0) {
output.addHuffmanBits(llSymbols[litLen], llLengths[litLen]);
} else {
int lls = lengthSymbol[litLen];
int ds = cachedDistSymbol[dist];
output.addHuffmanBits(llSymbols[lls], llLengths[lls]);
output.addBits(lengthExtraBitsValue[litLen], lengthExtraBits[litLen]);
output.addHuffmanBits(dSymbols[ds], dLengths[ds]);
output.addBits(Util.distExtraBitsValue(dist),
dist < 4097 ? cachedDistExtraBits[dist] : dist < 16385 ? dist < 8193 ? 11 : 12 : 13);
}
}
}
private static void lengthsToSymbols(int[] lengths, int n, int maxBits, int[] symbols, int[] blCount,
int[] nextCode) {
System.arraycopy(Cookie.intZeroes, 0, blCount, 0, maxBits + 1);
System.arraycopy(Cookie.intZeroes, 0, nextCode, 0, maxBits + 1);
for (int i = 0; i < n; ++i) {
blCount[lengths[i]]++;
}
int code = 0;
blCount[0] = 0;
for (int bits = 1; bits <= maxBits; bits++) {
code = (code + blCount[bits - 1]) << 1;
nextCode[bits] = code;
}
for (int i = 0; i < n; i++) {
int len = lengths[i];
if (len != 0) {
symbols[i] = nextCode[len];
nextCode[len]++;
}
}
}
private static void optimizeHuffmanForRle(Cookie cookie, int[] counts) {
int[] goodForRle = cookie.i289a;
int length = counts.length;
for (; length >= 0; --length) {
if (length == 0) {
return;
}
if (counts[length - 1] != 0) {
break;
}
}
System.arraycopy(Cookie.intZeroes, 0, goodForRle, 0, length + 1);
int symbol = counts[0];
int stride = 0;
for (int i = 0; i < length + 1; ++i) {
if (i == length || counts[i] != symbol) {
if ((symbol == 0 && stride >= 5) || (symbol != 0 && stride >= 7)) {
for (int k = 0; k < stride; ++k) {
goodForRle[i - k - 1] = 1;
}
}
stride = 1;
if (i != length) {
symbol = counts[i];
}
} else {
++stride;
}
}
stride = 0;
int limit = counts[0];
int sum = 0;
for (int i = 0; i < length + 1; ++i) {
if ((i == length) || (goodForRle[i] != 0) || (counts[i] - limit >= 4) || (limit - counts[i] >= 4)) {
if ((stride >= 4) || ((stride >= 3) && (sum == 0))) {
int count = (sum + stride / 2) / stride;
if (count < 1)
count = 1;
if (sum == 0) {
count = 0;
}
for (int k = 0; k < stride; ++k) {
counts[i - k - 1] = count;
}
}
stride = 0;
sum = 0;
if (i < length - 3) {
limit = (counts[i] + counts[i + 1] + counts[i + 2] + counts[i + 3] + 2) / 4;
} else if (i < length) {
limit = counts[i];
} else {
limit = 0;
}
}
++stride;
if (i != length) {
sum += counts[i];
}
}
}
}