Mercurial > jhg
view src/org/tmatesoft/hg/internal/PatchGenerator.java @ 534:243202f1bda5
Commit: refactor revision creation code from clone command to work separately, fit into existing library structure
author | Artem Tikhomirov <tikhomirov.artem@gmail.com> |
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date | Mon, 04 Feb 2013 18:00:55 +0100 |
parents | e6f72c9829a6 |
children | dd4f6311af52 |
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/* * Copyright (c) 2013 TMate Software Ltd * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * For information on how to redistribute this software under * the terms of a license other than GNU General Public License * contact TMate Software at support@hg4j.com */ package org.tmatesoft.hg.internal; import java.util.ArrayList; import java.util.HashMap; import java.util.Map; import org.tmatesoft.hg.repo.HgDataFile; import org.tmatesoft.hg.repo.HgLookup; import org.tmatesoft.hg.repo.HgRepository; /** * Mercurial cares about changes only up to the line level, e.g. a simple file version bump in manifest looks like (RevlogDump output): * * 522: 233748 0 103 17438 433 522 521 -1 756073cf2321df44d3ed0585f2a5754bc8a1b2f6 * <PATCH>: * 3487..3578, 91:src/org/tmatesoft/hg/core/HgIterateDirection.java\00add61a8a665c5d8f092210767f812fe0d335ac8 * * I.e. for the {fname}{revision} entry format of manifest, not only {revision} is changed, but the whole line, with unchanged {fname} is recorded * in the patch. * * Mercurial paper describes reasons for choosing this approach to delta generation, too. * * * @author Artem Tikhomirov * @author TMate Software Ltd. */ public class PatchGenerator { private Map<ChunkSequence.ByteChain, IntVector> chunk2UseIndex; private ChunkSequence seq1, seq2; // get filled by #longestMatch, track start of common sequence in seq1 and seq2, respectively private int matchStartS1, matchStartS2; // get filled by #findMatchingBlocks, track start of changed/unknown sequence in seq1 and seq2 private int changeStartS1, changeStartS2; public void init(byte[] data1, byte[] data2) { seq1 = new ChunkSequence(data1); seq1.splitByNewlines(); seq2 = new ChunkSequence(data2); seq2.splitByNewlines(); prepare(seq2); } private void prepare(ChunkSequence s2) { chunk2UseIndex = new HashMap<ChunkSequence.ByteChain, IntVector>(); for (int i = 0, len = s2.chunkCount(); i < len; i++) { ChunkSequence.ByteChain bc = s2.chunk(i); IntVector loc = chunk2UseIndex.get(bc); if (loc == null) { chunk2UseIndex.put(bc, loc = new IntVector()); } loc.add(i); // bc.registerUseIn(i) - BEWARE, use of bc here is incorrect // in this case need to find the only ByteChain to keep indexes // i.e. when there are few equal ByteChain instances, notion of "usedIn" shall be either shared (reference same vector) // or kept within only one of them } // for (ChunkSequence.ByteChain bc : chunk2UseIndex.keySet()) { // System.out.printf("%s: {", new String(bc.data())); // for (int x : chunk2UseIndex.get(bc).toArray()) { // System.out.printf(" %d,", x); // } // System.out.println("}"); // } } public void findMatchingBlocks() { changeStartS1 = changeStartS2 = 0; findMatchingBlocks(0, seq1.chunkCount(), 0, seq2.chunkCount()); if (changeStartS1 < seq1.chunkCount() || changeStartS2 < seq2.chunkCount()) { reportDeltaElement(seq1.chunkCount(), seq2.chunkCount()); } } /** * implementation based on Python's difflib.py and SequenceMatcher */ public int longestMatch(int startS1, int endS1, int startS2, int endS2) { matchStartS1 = matchStartS2 = 0; int maxLength = 0; IntMap<Integer> chunkIndex2MatchCount = new IntMap<Integer>(8); for (int i = startS1; i < endS1; i++) { ChunkSequence.ByteChain bc = seq1.chunk(i); IntMap<Integer> newChunkIndex2MatchCount = new IntMap<Integer>(8); IntVector occurencesInS2 = chunk2UseIndex.get(bc); if (occurencesInS2 == null) { // chunkIndex2MatchCount.clear(); // TODO need clear instead of new instance chunkIndex2MatchCount = newChunkIndex2MatchCount; continue; } for (int j : occurencesInS2.toArray()) { // s1[i] == s2[j] if (j < startS2) { continue; } if (j >= endS2) { break; } int prevChunkMatches = chunkIndex2MatchCount.containsKey(j-1) ? chunkIndex2MatchCount.get(j-1) : 0; int k = prevChunkMatches + 1; newChunkIndex2MatchCount.put(j, k); if (k > maxLength) { matchStartS1 = i-k+1; matchStartS2 = j-k+1; maxLength = k; } } chunkIndex2MatchCount = newChunkIndex2MatchCount; } return maxLength; } public void findMatchingBlocks(int startS1, int endS1, int startS2, int endS2) { int matchLength = longestMatch(startS1, endS1, startS2, endS2); if (matchLength > 0) { final int saveStartS1 = matchStartS1, saveStartS2 = matchStartS2; if (startS1 < matchStartS1 && startS2 < matchStartS2) { findMatchingBlocks(startS1, matchStartS1, startS2, matchStartS2); } reportDeltaElement(saveStartS1, saveStartS2); changeStartS1 = saveStartS1 + matchLength; changeStartS2 = saveStartS2 + matchLength; // System.out.printf("match: from line #%d and line #%d of length %d\n", saveStartS1, saveStartS2, matchLength); if (saveStartS1+matchLength < endS1 && saveStartS2+matchLength < endS2) { findMatchingBlocks(saveStartS1 + matchLength, endS1, saveStartS2 + matchLength, endS2); } } } private Patch deltaCollector; private void reportDeltaElement(int i, int j) { if (changeStartS1 < i) { if (changeStartS2 < j) { System.out.printf("changed [%d..%d) with [%d..%d)\n", changeStartS1, i, changeStartS2, j); } else { assert changeStartS2 == j; System.out.printf("deleted [%d..%d)\n", changeStartS1, i); } if (deltaCollector != null) { int from = seq1.chunk(changeStartS1).getOffset(); int to = seq1.chunk(i).getOffset(); byte[] data = seq2.data(changeStartS2, j); deltaCollector.add(from, to, data); } } else { assert changeStartS1 == i; if(changeStartS2 < j) { System.out.printf("added [%d..%d)\n", changeStartS2, j); } else { assert changeStartS2 == j; System.out.printf("adjustent equal blocks %d, %d and %d,%d\n", changeStartS1, i, changeStartS2, j); } if (deltaCollector != null) { int insPoint = seq1.chunk(changeStartS1).getOffset(); byte[] data = seq2.data(changeStartS2, j); deltaCollector.add(insPoint, insPoint, data); } } } public static void main(String[] args) throws Exception { HgRepository repo = new HgLookup().detectFromWorkingDir(); HgDataFile df = repo.getFileNode("cmdline/org/tmatesoft/hg/console/Main.java"); ByteArrayChannel bac1, bac2; df.content(80, bac1 = new ByteArrayChannel()); df.content(81, bac2 = new ByteArrayChannel()); // String s1 = "line 1\nline 2\r\nline 3\n\nline 1\nline 2"; // String s2 = "abc\ncdef\r\nline 2\r\nline 3\nline 2"; PatchGenerator pg = new PatchGenerator(); pg.init(bac1.toArray(), bac2.toArray()); pg.findMatchingBlocks(); } public Patch delta(byte[] prev, byte[] content) { deltaCollector = new Patch(); init(prev, content); findMatchingBlocks(); return deltaCollector; } private static class ChunkSequence { private final byte[] input; private ArrayList<ByteChain> lines; public ChunkSequence(byte[] data) { input = data; } public void splitByNewlines() { lines = new ArrayList<ByteChain>(); int lastStart = 0; for (int i = 0; i < input.length; i++) { if (input[i] == '\n') { lines.add(new ByteChain(lastStart, i+1)); lastStart = i+1; } else if (input[i] == '\r') { if (i+1 < input.length && input[i+1] == '\n') { i++; } lines.add(new ByteChain(lastStart, i+1)); lastStart = i+1; } } if (lastStart < input.length) { lines.add(new ByteChain(lastStart, input.length)); } } public ByteChain chunk(int index) { return lines.get(index); } public int chunkCount() { return lines.size(); } public byte[] data(int chunkFrom, int chunkTo) { if (chunkFrom == chunkTo) { return new byte[0]; } int from = chunk(chunkFrom).getOffset(), to = chunk(chunkTo).getOffset(); byte[] rv = new byte[to - from]; System.arraycopy(input, from, rv, 0, rv.length); return rv; } final class ByteChain { private final int start, end; private final int hash; ByteChain(int s, int e) { start = s; end = e; hash = calcHash(input, s, e); } /** * byte offset of the this ByteChain inside ChainSequence */ public int getOffset() { return start; } public byte[] data() { byte[] rv = new byte[end - start]; System.arraycopy(input, start, rv, 0, rv.length); return rv; } @Override public boolean equals(Object obj) { if (obj == null || obj.getClass() != ByteChain.class) { return false; } ByteChain other = (ByteChain) obj; if (other.hash != hash || other.end - other.start != end - start) { return false; } return other.match(input, start); } private boolean match(byte[] oi, int from) { for (int i = start, j = from; i < end; i++, j++) { if (ChunkSequence.this.input[i] != oi[j]) { return false; } } return true; } @Override public int hashCode() { return hash; } @Override public String toString() { return String.format("[@%d\"%s\"]", start, new String(data())); } } // same as Arrays.hashCode(byte[]), just for a slice of a bigger array static int calcHash(byte[] data, int from, int to) { int result = 1; for (int i = from; i < to; i++) { result = 31 * result + data[i]; } return result; } } }