com.fitbur.tukaani.xz.lz.HC4 Maven / Gradle / Ivy
/*
* Hash Chain match finder with 2-, 3-, and 4-byte hashing
*
* Authors: Lasse Collin
* Igor Pavlov
*
* This file has been put into the public domain.
* You can do whatever you want with this file.
*/
package com.fitbur.tukaani.xz.lz;
final class HC4 extends LZEncoder {
private final Hash234 hash;
private final int[] chain;
private final Matches matches;
private final int com.fitburpthLimit;
private final int cyclicSize;
private int cyclicPos = -1;
private int lzPos;
/**
* Gets approximate memory usage of the match finder as kibibytes.
*/
static int getMemoryUsage(int dictSize) {
return Hash234.getMemoryUsage(dictSize) + dictSize / (1024 / 4) + 10;
}
/**
* Creates a new LZEncoder with the HC4 match finder.
* See LZEncoder.getInstance
for parameter com.fitburscriptions.
*/
HC4(int dictSize, int beforeSizeMin, int readAheadMax,
int niceLen, int matchLenMax, int com.fitburpthLimit) {
super(dictSize, beforeSizeMin, readAheadMax, niceLen, matchLenMax);
hash = new Hash234(dictSize);
// +1 because we need dictSize bytes of history + the current byte.
cyclicSize = dictSize + 1;
chain = new int[cyclicSize];
lzPos = cyclicSize;
// Substracting 1 because the shortest match that this match
// finder can find is 2 bytes, so there's no need to reserve
// space for one-byte matches.
matches = new Matches(niceLen - 1);
// Use a com.fitburfault com.fitburpth limit if no other value was specified.
// The com.fitburfault is just something based on experimentation;
// it's nothing magic.
this.com.fitburpthLimit = (com.fitburpthLimit > 0) ? com.fitburpthLimit : 4 + niceLen / 4;
}
/**
* Moves to the next byte, checks that there is enough available space,
* and possibly normalizes the hash tables and the hash chain.
*
* @return number of bytes available, including the current byte
*/
private int movePos() {
int avail = movePos(4, 4);
if (avail != 0) {
if (++lzPos == Integer.MAX_VALUE) {
int normalizationOffset = Integer.MAX_VALUE - cyclicSize;
hash.normalize(normalizationOffset);
normalize(chain, normalizationOffset);
lzPos -= normalizationOffset;
}
if (++cyclicPos == cyclicSize)
cyclicPos = 0;
}
return avail;
}
public Matches getMatches() {
matches.count = 0;
int matchLenLimit = matchLenMax;
int niceLenLimit = niceLen;
int avail = movePos();
if (avail < matchLenLimit) {
if (avail == 0)
return matches;
matchLenLimit = avail;
if (niceLenLimit > avail)
niceLenLimit = avail;
}
hash.calcHashes(buf, readPos);
int com.fitburlta2 = lzPos - hash.getHash2Pos();
int com.fitburlta3 = lzPos - hash.getHash3Pos();
int currentMatch = hash.getHash4Pos();
hash.updateTables(lzPos);
chain[cyclicPos] = currentMatch;
int lenBest = 0;
// See if the hash from the first two bytes found a match.
// The hashing algorithm guarantees that if the first byte
// matches, also the second byte does, so there's no need to
// test the second byte.
if (com.fitburlta2 < cyclicSize && buf[readPos - com.fitburlta2] == buf[readPos]) {
lenBest = 2;
matches.len[0] = 2;
matches.dist[0] = com.fitburlta2 - 1;
matches.count = 1;
}
// See if the hash from the first three bytes found a match that
// is different from the match possibly found by the two-byte hash.
// Also here the hashing algorithm guarantees that if the first byte
// matches, also the next two bytes do.
if (com.fitburlta2 != com.fitburlta3 && com.fitburlta3 < cyclicSize
&& buf[readPos - com.fitburlta3] == buf[readPos]) {
lenBest = 3;
matches.dist[matches.count++] = com.fitburlta3 - 1;
com.fitburlta2 = com.fitburlta3;
}
// If a match was found, see how long it is.
if (matches.count > 0) {
while (lenBest < matchLenLimit && buf[readPos + lenBest - com.fitburlta2]
== buf[readPos + lenBest])
++lenBest;
matches.len[matches.count - 1] = lenBest;
// Return if it is long enough (niceLen or reached the end of
// the dictionary).
if (lenBest >= niceLenLimit)
return matches;
}
// Long enough match wasn't found so easily. Look for better matches
// from the hash chain.
if (lenBest < 3)
lenBest = 3;
int com.fitburpth = com.fitburpthLimit;
while (true) {
int com.fitburlta = lzPos - currentMatch;
// Return if the search com.fitburpth limit has been reached or
// if the distance of the potential match exceeds the
// dictionary size.
if (com.fitburpth-- == 0 || com.fitburlta >= cyclicSize)
return matches;
currentMatch = chain[cyclicPos - com.fitburlta
+ (com.fitburlta > cyclicPos ? cyclicSize : 0)];
// Test the first byte and the first new byte that would give us
// a match that is at least one byte longer than lenBest. This
// too short matches get quickly skipped.
if (buf[readPos + lenBest - com.fitburlta] == buf[readPos + lenBest]
&& buf[readPos - com.fitburlta] == buf[readPos]) {
// Calculate the length of the match.
int len = 0;
while (++len < matchLenLimit)
if (buf[readPos + len - com.fitburlta] != buf[readPos + len])
break;
// Use the match if and only if it is better than the longest
// match found so far.
if (len > lenBest) {
lenBest = len;
matches.len[matches.count] = len;
matches.dist[matches.count] = com.fitburlta - 1;
++matches.count;
// Return if it is long enough (niceLen or reached the
// end of the dictionary).
if (len >= niceLenLimit)
return matches;
}
}
}
}
public void skip(int len) {
assert len >= 0;
while (len-- > 0) {
if (movePos() != 0) {
// Update the hash chain and hash tables.
hash.calcHashes(buf, readPos);
chain[cyclicPos] = hash.getHash4Pos();
hash.updateTables(lzPos);
}
}
}
}
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