Mercurial > jhg
view src/org/tmatesoft/hg/repo/HgParentChildMap.java @ 690:b286222158be
Fix file.isCopy() use for status and cat commands
author | Artem Tikhomirov <tikhomirov.artem@gmail.com> |
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date | Thu, 01 Aug 2013 21:45:47 +0200 |
parents | 19f5167c2155 |
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/* * Copyright (c) 2011-2013 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.repo; import java.util.ArrayList; import java.util.Arrays; import java.util.BitSet; import java.util.Collection; import java.util.Collections; import java.util.HashSet; import java.util.LinkedList; import java.util.List; import org.tmatesoft.hg.core.Nodeid; import org.tmatesoft.hg.internal.ArrayHelper; import org.tmatesoft.hg.internal.IntMap; import org.tmatesoft.hg.repo.Revlog.ParentInspector; /** * Helper class to deal with parent-child relationship between revisions <i>en masse</i>. * Works in terms of {@link Nodeid nodeids}, there's no need to deal with revision indexes. * For a given revision, answers questions like "who's my parent and what are my immediate children". * * <p>Comes handy when multiple revisions are analyzed and distinct {@link Revlog#parents(int, int[], byte[], byte[])} * queries are ineffective. * * <p>Next code snippet shows typical use: * <pre> * HgChangelog clog = repo.getChangelog(); * ParentWalker<HgChangelog> pw = new ParentWalker<HgChangelog>(clog); * pw.init(); * * Nodeid me = Nodeid.fromAscii("..."); * List<Nodei> immediateChildren = pw.directChildren(me); * </pre> * * <p>Note, this map represents a snapshot of repository state at specific point, and is not automatically * updated/refreshed along with repository changes. I.e. any revision committed after this map was initialized * won't be recognized as known. * * <p> Perhaps, later may add alternative way to access (and reuse) map instance, Revlog#getParentWalker(), * that instantiates and initializes ParentWalker, and keep SoftReference to allow its reuse. * * @see HgRevisionMap * * @author Artem Tikhomirov * @author TMate Software Ltd. */ public final class HgParentChildMap<T extends Revlog> implements ParentInspector { // IMPORTANT: Nodeid instances shall be shared between all arrays private final T revlog; private Nodeid[] sequential; // natural repository order, childrenOf rely on ordering private Nodeid[] sorted; // for binary search, just an origin of the actual value in use, the one inside seqWrapper private Nodeid[] firstParent; // parents by natural order (i.e. firstParent[A] is parent of revision with index A) private Nodeid[] secondParent; private IntMap<Nodeid> heads; private BitSet headsBitSet; // 1 indicates revision got children, != null only during init; private HgRevisionMap<T> revisionIndexMap; private ArrayHelper<Nodeid> seqWrapper; public HgParentChildMap(T owner) { revlog = owner; } public HgRepository getRepo() { return revlog.getRepo(); } public void next(int revisionNumber, Nodeid revision, int parent1Revision, int parent2Revision, Nodeid nidParent1, Nodeid nidParent2) { if (parent1Revision >= revisionNumber || parent2Revision >= revisionNumber) { throw new IllegalStateException(); // sanity, revisions are sequential } int ix = revisionNumber; sequential[ix] = sorted[ix] = revision; if (parent1Revision != -1) { firstParent[ix] = sequential[parent1Revision]; headsBitSet.set(parent1Revision); } if (parent2Revision != -1) { // revlog of DataAccess.java has p2 set when p1 is -1 secondParent[ix] = sequential[parent2Revision]; headsBitSet.set(parent2Revision); } } /** * Prepare (initialize or update) the map. Once {@link HgParentChildMap} was initialized, it keeps snapshot * of repository state. New revisions committed to the repository are not visible. To update the map, call * {@link #init()} once again, it tries to refresh in effective way, and to bring in only relevant changes. * * @throws HgInvalidControlFileException if failed to access revlog index/data entry. <em>Runtime exception</em> * @throws HgRuntimeException subclass thereof to indicate other issues with the library. <em>Runtime exception</em> */ public void init() throws HgRuntimeException { final int revisionCount = revlog.getRevisionCount(); Nodeid[] oldSequential = null, oldFirstParent = null, oldSecondParent = null, oldSorted = null; if (sequential != null && sequential.length > 0 && sequential.length < revisionCount) { int lastRecordedRevIndex = sequential.length-1; if (sequential[lastRecordedRevIndex].equals(revlog.getRevision(lastRecordedRevIndex))) { oldSequential = sequential; oldFirstParent = firstParent; oldSecondParent = secondParent; oldSorted = sorted; // not sure if there's a benefit in keeping sorted. assume quite some of them // might end up on the same place and thus minimize rearrangements } } firstParent = new Nodeid[revisionCount]; // TODO [post 1.1] Branches/merges are less frequent, and most of secondParent would be -1/null, hence // IntMap might be better alternative here, but need to carefully analyze (test) whether this brings // real improvement (IntMap has 2n capacity, and element lookup is log(n) instead of array's constant). // FWIW: in cpython's repo, with 70k+ revisions, there are 2618 values in secondParent secondParent = new Nodeid[revisionCount]; // sequential = new Nodeid[revisionCount]; sorted = new Nodeid[revisionCount]; headsBitSet = new BitSet(revisionCount); if (oldSequential != null) { assert oldFirstParent.length == oldSequential.length; assert oldSecondParent.length == oldSequential.length; assert oldSorted.length == oldSequential.length; System.arraycopy(oldSequential, 0, sequential, 0, oldSequential.length); System.arraycopy(oldFirstParent, 0, firstParent, 0, oldFirstParent.length); System.arraycopy(oldSecondParent, 0, secondParent, 0, oldSecondParent.length); System.arraycopy(oldSorted, 0, sorted, 0, oldSorted.length); // restore old heads so that new one are calculated correctly headsBitSet.set(0, oldSequential.length); for (int headIndex : heads.keys()) { headsBitSet.clear(headIndex); } } revlog.indexWalk(oldSequential == null ? 0 : oldSequential.length, revisionCount-1, this); seqWrapper = new ArrayHelper<Nodeid>(sequential); // HgRevisionMap doesn't keep sorted, try alternative here. // reference this.sorted (not only from ArrayHelper) helps to track ownership in hprof/mem dumps seqWrapper.sort(sorted, false, true); // no reason to keep BitSet, number of heads is usually small IntMap<Nodeid> _heads = new IntMap<Nodeid>(revisionCount - headsBitSet.cardinality()); int index = 0; while (index < sequential.length) { index = headsBitSet.nextClearBit(index); // nextClearBit(length-1) gives length when bit is set, // however, last revision can't be a parent of any other, and // the last bit would be always 0, and no AIOOBE _heads.put(index, sequential[index]); index++; } headsBitSet = null; heads = _heads; } private static void assertSortedIndex(int x) { if (x < 0) { throw new HgInvalidStateException(String.format("Bad index %d", x)); } } /** * Tells whether supplied revision is from the walker's associated revlog. * Note, {@link Nodeid#NULL}, although implicitly present as parent of a first revision, is not recognized as known. * @param nid revision to check, not <code>null</code> * @return <code>true</code> if revision matches any revision in this revlog */ public boolean knownNode(Nodeid nid) { return seqWrapper.binarySearchSorted(nid) >= 0; } /** * null if none. only known nodes (as per #knownNode) are accepted as arguments */ public Nodeid firstParent(Nodeid nid) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); return firstParent[i]; } // never null, Nodeid.NULL if none known public Nodeid safeFirstParent(Nodeid nid) { Nodeid rv = firstParent(nid); return rv == null ? Nodeid.NULL : rv; } public Nodeid secondParent(Nodeid nid) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); return secondParent[i]; } public Nodeid safeSecondParent(Nodeid nid) { Nodeid rv = secondParent(nid); return rv == null ? Nodeid.NULL : rv; } public boolean appendParentsOf(Nodeid nid, Collection<Nodeid> c) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); Nodeid p1 = firstParent[i]; boolean modified = false; if (p1 != null) { modified = c.add(p1); } Nodeid p2 = secondParent[i]; if (p2 != null) { modified = c.add(p2) || modified; } return modified; } // XXX alternative (and perhaps more reliable) approach would be to make a copy of allNodes and remove // nodes, their parents and so on. // @return ordered collection of all children rooted at supplied nodes. Nodes shall not be descendants of each other! // Nodeids shall belong to this revlog public List<Nodeid> childrenOf(Collection<Nodeid> roots) { if (roots.isEmpty()) { return Collections.emptyList(); } HashSet<Nodeid> parents = new HashSet<Nodeid>(); LinkedList<Nodeid> result = new LinkedList<Nodeid>(); int earliestRevision = Integer.MAX_VALUE; assert sequential.length == firstParent.length && firstParent.length == secondParent.length; // first, find earliest index of roots in question, as there's no sense // to check children among nodes prior to branch's root node for (Nodeid r : roots) { int x = seqWrapper.binarySearchSorted(r); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); if (i < earliestRevision) { earliestRevision = i; } parents.add(sequential[i]); // add canonical instance in hope equals() is bit faster when can do a == } for (int i = earliestRevision + 1; i < sequential.length; i++) { if (parents.contains(firstParent[i]) || parents.contains(secondParent[i])) { parents.add(sequential[i]); // to find next child result.add(sequential[i]); } } return result; } /** * @return revisions that have supplied revision as their immediate parent */ public List<Nodeid> directChildren(Nodeid nid) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int start = seqWrapper.getReverseIndex(x); nid = sequential[start]; // canonical instance if (!hasChildren(start)) { return Collections.emptyList(); } ArrayList<Nodeid> result = new ArrayList<Nodeid>(5); for (int i = start + 1; i < sequential.length; i++) { if (nid == firstParent[i] || nid == secondParent[i]) { result.add(sequential[i]); } } return result; } /** * @param nid possibly parent node, shall be {@link #knownNode(Nodeid) known} in this revlog. * @return <code>true</code> if there's any node in this revlog that has specified node as one of its parents. */ public boolean hasChildren(Nodeid nid) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); return hasChildren(i); } /** * @return all revisions this map knows about */ public List<Nodeid> all() { return Arrays.asList(sequential); } /** * Find out whether a given node is among descendants of another. * * @param root revision to check for being (grand-)*parent of a child * @param wannaBeChild candidate descendant revision * @return <code>true</code> if <code>wannaBeChild</code> is among children of <code>root</code> */ public boolean isChild(Nodeid root, Nodeid wannaBeChild) { int x = seqWrapper.binarySearchSorted(root); assertSortedIndex(x); final int start = seqWrapper.getReverseIndex(x); root = sequential[start]; // canonical instance if (!hasChildren(start)) { return false; // root got no children at all } int y = seqWrapper.binarySearchSorted(wannaBeChild); if (y < 0) { return false; // not found } final int end = seqWrapper.getReverseIndex(y); wannaBeChild = sequential[end]; // canonicalize if (end <= start) { return false; // potential child was in repository earlier than root } HashSet<Nodeid> parents = new HashSet<Nodeid>(); parents.add(root); for (int i = start + 1; i < end; i++) { if (parents.contains(firstParent[i]) || parents.contains(secondParent[i])) { parents.add(sequential[i]); // collect ancestors line } } return parents.contains(firstParent[end]) || parents.contains(secondParent[end]); } /** * @return elements of this map that do not have a child recorded therein. */ public Collection<Nodeid> heads() { return heads.values(); } /** * @return map of revision to indexes */ public HgRevisionMap<T> getRevisionMap() { if (revisionIndexMap == null) { revisionIndexMap = new HgRevisionMap<T>(revlog); revisionIndexMap.init(seqWrapper); } return revisionIndexMap; } /** * @return common ancestor of two revisions */ public Nodeid ancestor(Nodeid r1, Nodeid r2) { if (r1.equals(r2)) { return r1; } BitSet a1 = buildAncestors(r1); BitSet a2 = buildAncestors(r2); // BitSet.and() trims to shorter bitset, it's ok as we are not // interested in bits that are part of one bitset only a1.and(a2); final int cardinality = a1.cardinality(); if (cardinality == 1) { return sequential[a1.nextSetBit(0)]; } assert cardinality > 0; // every revision is child of at least rev0 final int length = sequential.length; int index = length / 2; int lastBitSet = -1; do { int nextSetBit = a1.nextSetBit(index); int nextIndex; if (nextSetBit == -1) { assert lastBitSet == -1 || lastBitSet <= index; nextIndex = index - (index - (lastBitSet == -1 ? 0 : lastBitSet)) / 2; } else { lastBitSet = nextSetBit; nextIndex = lastBitSet + (length - lastBitSet) / 2; } if (nextIndex == index) { break; } index = nextIndex; } while (true); if (lastBitSet == -1) { assert false; // likely error in the algorithm above (e.g. can't reach index==0) return sequential[0]; } return sequential[lastBitSet]; } private boolean hasChildren(int sequentialIndex) { return !heads.containsKey(sequentialIndex); } private BitSet buildAncestors(Nodeid nid) { int x = seqWrapper.binarySearchSorted(nid); assertSortedIndex(x); int i = seqWrapper.getReverseIndex(x); BitSet rv = new BitSet(sequential.length); HashSet<Nodeid> ancestors = new HashSet<Nodeid>(); ancestors.add(nid); do { if (ancestors.contains(sequential[i])) { rv.set(i); if(firstParent[i] != null) { ancestors.add(firstParent[i]); } if (secondParent[i] != null) { ancestors.add(secondParent[i]); } } i--; } while (i >= 0); return rv; } }