/* * Copyright (C) 2010, Christian Halstrick , * Copyright (C) 2010-2012, Matthias Sohn * Copyright (C) 2012, Research In Motion Limited * Copyright (C) 2017, Obeo (mathieu.cartaud@obeo.fr) * Copyright (C) 2018, Thomas Wolf and others * * This program and the accompanying materials are made available under the * terms of the Eclipse Distribution License v. 1.0 which is available at * https://www.eclipse.org/org/documents/edl-v10.php. * * SPDX-License-Identifier: BSD-3-Clause */ package org.eclipse.jgit.merge; import static java.nio.charset.StandardCharsets.UTF_8; import static java.time.Instant.EPOCH; import static org.eclipse.jgit.diff.DiffAlgorithm.SupportedAlgorithm.HISTOGRAM; import static org.eclipse.jgit.lib.ConfigConstants.CONFIG_DIFF_SECTION; import static org.eclipse.jgit.lib.ConfigConstants.CONFIG_KEY_ALGORITHM; import static org.eclipse.jgit.lib.Constants.OBJ_BLOB; import java.io.BufferedOutputStream; import java.io.File; import java.io.FileNotFoundException; import java.io.FileOutputStream; import java.io.IOException; import java.io.InputStream; import java.io.OutputStream; import java.time.Instant; import java.util.ArrayList; import java.util.Arrays; import java.util.Collections; import java.util.HashMap; import java.util.Iterator; import java.util.LinkedList; import java.util.List; import java.util.Map; import org.eclipse.jgit.attributes.Attributes; import org.eclipse.jgit.diff.DiffAlgorithm; import org.eclipse.jgit.diff.DiffAlgorithm.SupportedAlgorithm; import org.eclipse.jgit.diff.RawText; import org.eclipse.jgit.diff.RawTextComparator; import org.eclipse.jgit.diff.Sequence; import org.eclipse.jgit.dircache.DirCache; import org.eclipse.jgit.dircache.DirCacheBuildIterator; import org.eclipse.jgit.dircache.DirCacheBuilder; import org.eclipse.jgit.dircache.DirCacheCheckout; import org.eclipse.jgit.dircache.DirCacheCheckout.CheckoutMetadata; import org.eclipse.jgit.dircache.DirCacheEntry; import org.eclipse.jgit.errors.BinaryBlobException; import org.eclipse.jgit.errors.CorruptObjectException; import org.eclipse.jgit.errors.IncorrectObjectTypeException; import org.eclipse.jgit.errors.IndexWriteException; import org.eclipse.jgit.errors.MissingObjectException; import org.eclipse.jgit.errors.NoWorkTreeException; import org.eclipse.jgit.lib.Config; import org.eclipse.jgit.lib.ConfigConstants; import org.eclipse.jgit.lib.Constants; import org.eclipse.jgit.lib.CoreConfig.EolStreamType; import org.eclipse.jgit.lib.FileMode; import org.eclipse.jgit.lib.ObjectId; import org.eclipse.jgit.lib.ObjectInserter; import org.eclipse.jgit.lib.ObjectLoader; import org.eclipse.jgit.lib.Repository; import org.eclipse.jgit.revwalk.RevTree; import org.eclipse.jgit.storage.pack.PackConfig; import org.eclipse.jgit.submodule.SubmoduleConflict; import org.eclipse.jgit.treewalk.AbstractTreeIterator; import org.eclipse.jgit.treewalk.CanonicalTreeParser; import org.eclipse.jgit.treewalk.NameConflictTreeWalk; import org.eclipse.jgit.treewalk.TreeWalk; import org.eclipse.jgit.treewalk.TreeWalk.OperationType; import org.eclipse.jgit.treewalk.WorkingTreeIterator; import org.eclipse.jgit.treewalk.WorkingTreeOptions; import org.eclipse.jgit.treewalk.filter.TreeFilter; import org.eclipse.jgit.util.FS; import org.eclipse.jgit.util.LfsFactory; import org.eclipse.jgit.util.LfsFactory.LfsInputStream; import org.eclipse.jgit.util.TemporaryBuffer; import org.eclipse.jgit.util.io.EolStreamTypeUtil; /** * A three-way merger performing a content-merge if necessary */ public class ResolveMerger extends ThreeWayMerger { /** * If the merge fails (means: not stopped because of unresolved conflicts) * this enum is used to explain why it failed */ public enum MergeFailureReason { /** the merge failed because of a dirty index */ DIRTY_INDEX, /** the merge failed because of a dirty workingtree */ DIRTY_WORKTREE, /** the merge failed because of a file could not be deleted */ COULD_NOT_DELETE } /** * The tree walk which we'll iterate over to merge entries. * * @since 3.4 */ protected NameConflictTreeWalk tw; /** * string versions of a list of commit SHA1s * * @since 3.0 */ protected String[] commitNames; /** * Index of the base tree within the {@link #tw tree walk}. * * @since 3.4 */ protected static final int T_BASE = 0; /** * Index of our tree in withthe {@link #tw tree walk}. * * @since 3.4 */ protected static final int T_OURS = 1; /** * Index of their tree within the {@link #tw tree walk}. * * @since 3.4 */ protected static final int T_THEIRS = 2; /** * Index of the index tree within the {@link #tw tree walk}. * * @since 3.4 */ protected static final int T_INDEX = 3; /** * Index of the working directory tree within the {@link #tw tree walk}. * * @since 3.4 */ protected static final int T_FILE = 4; /** * Builder to update the cache during this merge. * * @since 3.4 */ protected DirCacheBuilder builder; /** * merge result as tree * * @since 3.0 */ protected ObjectId resultTree; /** * Paths that could not be merged by this merger because of an unsolvable * conflict. * * @since 3.4 */ protected List unmergedPaths = new ArrayList<>(); /** * Files modified during this merge operation. * * @since 3.4 */ protected List modifiedFiles = new LinkedList<>(); /** * If the merger has nothing to do for a file but check it out at the end of * the operation, it can be added here. * * @since 3.4 */ protected Map toBeCheckedOut = new HashMap<>(); /** * Paths in this list will be deleted from the local copy at the end of the * operation. * * @since 3.4 */ protected List toBeDeleted = new ArrayList<>(); /** * Low-level textual merge results. Will be passed on to the callers in case * of conflicts. * * @since 3.4 */ protected Map> mergeResults = new HashMap<>(); /** * Paths for which the merge failed altogether. * * @since 3.4 */ protected Map failingPaths = new HashMap<>(); /** * Updated as we merge entries of the tree walk. Tells us whether we should * recurse into the entry if it is a subtree. * * @since 3.4 */ protected boolean enterSubtree; /** * Set to true if this merge should work in-memory. The repos dircache and * workingtree are not touched by this method. Eventually needed files are * created as temporary files and a new empty, in-memory dircache will be * used instead the repo's one. Often used for bare repos where the repo * doesn't even have a workingtree and dircache. * @since 3.0 */ protected boolean inCore; /** * Set to true if this merger should use the default dircache of the * repository and should handle locking and unlocking of the dircache. If * this merger should work in-core or if an explicit dircache was specified * during construction then this field is set to false. * @since 3.0 */ protected boolean implicitDirCache; /** * Directory cache * @since 3.0 */ protected DirCache dircache; /** * The iterator to access the working tree. If set to null this * merger will not touch the working tree. * @since 3.0 */ protected WorkingTreeIterator workingTreeIterator; /** * our merge algorithm * @since 3.0 */ protected MergeAlgorithm mergeAlgorithm; /** * The {@link WorkingTreeOptions} are needed to determine line endings for * merged files. * * @since 4.11 */ protected WorkingTreeOptions workingTreeOptions; /** * The size limit (bytes) which controls a file to be stored in {@code Heap} * or {@code LocalFile} during the merge. */ private int inCoreLimit; /** * Keeps {@link CheckoutMetadata} for {@link #checkout()} and * {@link #cleanUp()}. */ private Map checkoutMetadata; private static MergeAlgorithm getMergeAlgorithm(Config config) { SupportedAlgorithm diffAlg = config.getEnum( CONFIG_DIFF_SECTION, null, CONFIG_KEY_ALGORITHM, HISTOGRAM); return new MergeAlgorithm(DiffAlgorithm.getAlgorithm(diffAlg)); } private static int getInCoreLimit(Config config) { return config.getInt( ConfigConstants.CONFIG_MERGE_SECTION, ConfigConstants.CONFIG_KEY_IN_CORE_LIMIT, 10 << 20); } private static String[] defaultCommitNames() { return new String[] { "BASE", "OURS", "THEIRS" }; //$NON-NLS-1$ //$NON-NLS-2$ //$NON-NLS-3$ } private static final Attributes NO_ATTRIBUTES = new Attributes(); /** * Constructor for ResolveMerger. * * @param local * the {@link org.eclipse.jgit.lib.Repository}. * @param inCore * a boolean. */ protected ResolveMerger(Repository local, boolean inCore) { super(local); Config config = local.getConfig(); mergeAlgorithm = getMergeAlgorithm(config); inCoreLimit = getInCoreLimit(config); commitNames = defaultCommitNames(); this.inCore = inCore; if (inCore) { implicitDirCache = false; dircache = DirCache.newInCore(); } else { implicitDirCache = true; workingTreeOptions = local.getConfig().get(WorkingTreeOptions.KEY); } } /** * Constructor for ResolveMerger. * * @param local * the {@link org.eclipse.jgit.lib.Repository}. */ protected ResolveMerger(Repository local) { this(local, false); } /** * Constructor for ResolveMerger. * * @param inserter * an {@link org.eclipse.jgit.lib.ObjectInserter} object. * @param config * the repository configuration * @since 4.8 */ protected ResolveMerger(ObjectInserter inserter, Config config) { super(inserter); mergeAlgorithm = getMergeAlgorithm(config); commitNames = defaultCommitNames(); inCore = true; implicitDirCache = false; dircache = DirCache.newInCore(); } /** {@inheritDoc} */ @Override protected boolean mergeImpl() throws IOException { if (implicitDirCache) { dircache = nonNullRepo().lockDirCache(); } if (!inCore) { checkoutMetadata = new HashMap<>(); } try { return mergeTrees(mergeBase(), sourceTrees[0], sourceTrees[1], false); } finally { checkoutMetadata = null; if (implicitDirCache) { dircache.unlock(); } } } private void checkout() throws NoWorkTreeException, IOException { // Iterate in reverse so that "folder/file" is deleted before // "folder". Otherwise this could result in a failing path because // of a non-empty directory, for which delete() would fail. for (int i = toBeDeleted.size() - 1; i >= 0; i--) { String fileName = toBeDeleted.get(i); File f = new File(nonNullRepo().getWorkTree(), fileName); if (!f.delete()) if (!f.isDirectory()) failingPaths.put(fileName, MergeFailureReason.COULD_NOT_DELETE); modifiedFiles.add(fileName); } for (Map.Entry entry : toBeCheckedOut .entrySet()) { DirCacheEntry cacheEntry = entry.getValue(); if (cacheEntry.getFileMode() == FileMode.GITLINK) { new File(nonNullRepo().getWorkTree(), entry.getKey()).mkdirs(); } else { DirCacheCheckout.checkoutEntry(db, cacheEntry, reader, false, checkoutMetadata.get(entry.getKey())); modifiedFiles.add(entry.getKey()); } } } /** * Reverts the worktree after an unsuccessful merge. We know that for all * modified files the old content was in the old index and the index * contained only stage 0. In case if inCore operation just clear the * history of modified files. * * @throws java.io.IOException * @throws org.eclipse.jgit.errors.CorruptObjectException * @throws org.eclipse.jgit.errors.NoWorkTreeException * @since 3.4 */ protected void cleanUp() throws NoWorkTreeException, CorruptObjectException, IOException { if (inCore) { modifiedFiles.clear(); return; } DirCache dc = nonNullRepo().readDirCache(); Iterator mpathsIt=modifiedFiles.iterator(); while(mpathsIt.hasNext()) { String mpath = mpathsIt.next(); DirCacheEntry entry = dc.getEntry(mpath); if (entry != null) { DirCacheCheckout.checkoutEntry(db, entry, reader, false, checkoutMetadata.get(mpath)); } mpathsIt.remove(); } } /** * adds a new path with the specified stage to the index builder * * @param path * @param p * @param stage * @param lastMod * @param len * @return the entry which was added to the index */ private DirCacheEntry add(byte[] path, CanonicalTreeParser p, int stage, Instant lastMod, long len) { if (p != null && !p.getEntryFileMode().equals(FileMode.TREE)) { DirCacheEntry e = new DirCacheEntry(path, stage); e.setFileMode(p.getEntryFileMode()); e.setObjectId(p.getEntryObjectId()); e.setLastModified(lastMod); e.setLength(len); builder.add(e); return e; } return null; } /** * adds a entry to the index builder which is a copy of the specified * DirCacheEntry * * @param e * the entry which should be copied * * @return the entry which was added to the index */ private DirCacheEntry keep(DirCacheEntry e) { DirCacheEntry newEntry = new DirCacheEntry(e.getRawPath(), e.getStage()); newEntry.setFileMode(e.getFileMode()); newEntry.setObjectId(e.getObjectId()); newEntry.setLastModified(e.getLastModifiedInstant()); newEntry.setLength(e.getLength()); builder.add(newEntry); return newEntry; } /** * Remembers the {@link CheckoutMetadata} for the given path; it may be * needed in {@link #checkout()} or in {@link #cleanUp()}. * * @param path * of the current node * @param attributes * for the current node * @throws IOException * if the smudge filter cannot be determined * @since 5.1 */ protected void addCheckoutMetadata(String path, Attributes attributes) throws IOException { if (checkoutMetadata != null) { EolStreamType eol = EolStreamTypeUtil.detectStreamType( OperationType.CHECKOUT_OP, workingTreeOptions, attributes); CheckoutMetadata data = new CheckoutMetadata(eol, tw.getFilterCommand(Constants.ATTR_FILTER_TYPE_SMUDGE)); checkoutMetadata.put(path, data); } } /** * Adds a {@link DirCacheEntry} for direct checkout and remembers its * {@link CheckoutMetadata}. * * @param path * of the entry * @param entry * to add * @param attributes * for the current entry * @throws IOException * if the {@link CheckoutMetadata} cannot be determined * @since 5.1 */ protected void addToCheckout(String path, DirCacheEntry entry, Attributes attributes) throws IOException { toBeCheckedOut.put(path, entry); addCheckoutMetadata(path, attributes); } /** * Remember a path for deletion, and remember its {@link CheckoutMetadata} * in case it has to be restored in {@link #cleanUp()}. * * @param path * of the entry * @param isFile * whether it is a file * @param attributes * for the entry * @throws IOException * if the {@link CheckoutMetadata} cannot be determined * @since 5.1 */ protected void addDeletion(String path, boolean isFile, Attributes attributes) throws IOException { toBeDeleted.add(path); if (isFile) { addCheckoutMetadata(path, attributes); } } /** * Processes one path and tries to merge taking git attributes in account. * This method will do all trivial (not content) merges and will also detect * if a merge will fail. The merge will fail when one of the following is * true *
    *
  • the index entry does not match the entry in ours. When merging one * branch into the current HEAD, ours will point to HEAD and theirs will * point to the other branch. It is assumed that the index matches the HEAD * because it will only not match HEAD if it was populated before the merge * operation. But the merge commit should not accidentally contain * modifications done before the merge. Check the git read-tree documentation for further explanations.
    • *
  • A conflict was detected and the working-tree file is dirty. When a * conflict is detected the content-merge algorithm will try to write a * merged version into the working-tree. If the file is dirty we would * override unsaved data.
    • *
* * @param base * the common base for ours and theirs * @param ours * the ours side of the merge. When merging a branch into the * HEAD ours will point to HEAD * @param theirs * the theirs side of the merge. When merging a branch into the * current HEAD theirs will point to the branch which is merged * into HEAD. * @param index * the index entry * @param work * the file in the working tree * @param ignoreConflicts * see * {@link org.eclipse.jgit.merge.ResolveMerger#mergeTrees(AbstractTreeIterator, RevTree, RevTree, boolean)} * @param attributes * the attributes defined for this entry * @return false if the merge will fail because the index entry * didn't match ours or the working-dir file was dirty and a * conflict occurred * @throws org.eclipse.jgit.errors.MissingObjectException * @throws org.eclipse.jgit.errors.IncorrectObjectTypeException * @throws org.eclipse.jgit.errors.CorruptObjectException * @throws java.io.IOException * @since 4.9 */ protected boolean processEntry(CanonicalTreeParser base, CanonicalTreeParser ours, CanonicalTreeParser theirs, DirCacheBuildIterator index, WorkingTreeIterator work, boolean ignoreConflicts, Attributes attributes) throws MissingObjectException, IncorrectObjectTypeException, CorruptObjectException, IOException { enterSubtree = true; final int modeO = tw.getRawMode(T_OURS); final int modeT = tw.getRawMode(T_THEIRS); final int modeB = tw.getRawMode(T_BASE); boolean gitLinkMerging = isGitLink(modeO) || isGitLink(modeT) || isGitLink(modeB); if (modeO == 0 && modeT == 0 && modeB == 0) // File is either untracked or new, staged but uncommitted return true; if (isIndexDirty()) return false; DirCacheEntry ourDce = null; if (index == null || index.getDirCacheEntry() == null) { // create a fake DCE, but only if ours is valid. ours is kept only // in case it is valid, so a null ourDce is ok in all other cases. if (nonTree(modeO)) { ourDce = new DirCacheEntry(tw.getRawPath()); ourDce.setObjectId(tw.getObjectId(T_OURS)); ourDce.setFileMode(tw.getFileMode(T_OURS)); } } else { ourDce = index.getDirCacheEntry(); } if (nonTree(modeO) && nonTree(modeT) && tw.idEqual(T_OURS, T_THEIRS)) { // OURS and THEIRS have equal content. Check the file mode if (modeO == modeT) { // content and mode of OURS and THEIRS are equal: it doesn't // matter which one we choose. OURS is chosen. Since the index // is clean (the index matches already OURS) we can keep the existing one keep(ourDce); // no checkout needed! return true; } // same content but different mode on OURS and THEIRS. // Try to merge the mode and report an error if this is // not possible. int newMode = mergeFileModes(modeB, modeO, modeT); if (newMode != FileMode.MISSING.getBits()) { if (newMode == modeO) { // ours version is preferred keep(ourDce); } else { // the preferred version THEIRS has a different mode // than ours. Check it out! if (isWorktreeDirty(work, ourDce)) { return false; } // we know about length and lastMod only after we have // written the new content. // This will happen later. Set these values to 0 for know. DirCacheEntry e = add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_0, EPOCH, 0); addToCheckout(tw.getPathString(), e, attributes); } return true; } // FileModes are not mergeable. We found a conflict on modes. // For conflicting entries we don't know lastModified and // length. add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); unmergedPaths.add(tw.getPathString()); mergeResults.put(tw.getPathString(), new MergeResult<>(Collections. emptyList())); return true; } if (modeB == modeT && tw.idEqual(T_BASE, T_THEIRS)) { // THEIRS was not changed compared to BASE. All changes must be in // OURS. OURS is chosen. We can keep the existing entry. if (ourDce != null) keep(ourDce); // no checkout needed! return true; } if (modeB == modeO && tw.idEqual(T_BASE, T_OURS)) { // OURS was not changed compared to BASE. All changes must be in // THEIRS. THEIRS is chosen. // Check worktree before checking out THEIRS if (isWorktreeDirty(work, ourDce)) return false; if (nonTree(modeT)) { // we know about length and lastMod only after we have written // the new content. // This will happen later. Set these values to 0 for know. DirCacheEntry e = add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_0, EPOCH, 0); if (e != null) { addToCheckout(tw.getPathString(), e, attributes); } return true; } // we want THEIRS ... but THEIRS contains a folder or the // deletion of the path. Delete what's in the working tree, // which we know to be clean. if (tw.getTreeCount() > T_FILE && tw.getRawMode(T_FILE) == 0) { // Not present in working tree, so nothing to delete return true; } if (modeT != 0 && modeT == modeB) { // Base, ours, and theirs all contain a folder: don't delete return true; } addDeletion(tw.getPathString(), nonTree(modeO), attributes); return true; } if (tw.isSubtree()) { // file/folder conflicts: here I want to detect only file/folder // conflict between ours and theirs. file/folder conflicts between // base/index/workingTree and something else are not relevant or // detected later if (nonTree(modeO) && !nonTree(modeT)) { if (nonTree(modeB)) add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); unmergedPaths.add(tw.getPathString()); enterSubtree = false; return true; } if (nonTree(modeT) && !nonTree(modeO)) { if (nonTree(modeB)) add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); unmergedPaths.add(tw.getPathString()); enterSubtree = false; return true; } // ours and theirs are both folders or both files (and treewalk // tells us we are in a subtree because of index or working-dir). // If they are both folders no content-merge is required - we can // return here. if (!nonTree(modeO)) return true; // ours and theirs are both files, just fall out of the if block // and do the content merge } if (nonTree(modeO) && nonTree(modeT)) { // Check worktree before modifying files boolean worktreeDirty = isWorktreeDirty(work, ourDce); if (!attributes.canBeContentMerged() && worktreeDirty) { return false; } if (gitLinkMerging && ignoreConflicts) { // Always select 'ours' in case of GITLINK merge failures so // a caller can use virtual commit. add(tw.getRawPath(), ours, DirCacheEntry.STAGE_0, EPOCH, 0); return true; } else if (gitLinkMerging) { add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); MergeResult result = createGitLinksMergeResult( base, ours, theirs); result.setContainsConflicts(true); mergeResults.put(tw.getPathString(), result); unmergedPaths.add(tw.getPathString()); return true; } else if (!attributes.canBeContentMerged()) { add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); // attribute merge issues are conflicts but not failures unmergedPaths.add(tw.getPathString()); return true; } // Check worktree before modifying files if (worktreeDirty) { return false; } MergeResult result = contentMerge(base, ours, theirs, attributes); if (ignoreConflicts) { result.setContainsConflicts(false); } updateIndex(base, ours, theirs, result, attributes); String currentPath = tw.getPathString(); if (result.containsConflicts() && !ignoreConflicts) { unmergedPaths.add(currentPath); } modifiedFiles.add(currentPath); addCheckoutMetadata(currentPath, attributes); } else if (modeO != modeT) { // OURS or THEIRS has been deleted if (((modeO != 0 && !tw.idEqual(T_BASE, T_OURS)) || (modeT != 0 && !tw .idEqual(T_BASE, T_THEIRS)))) { if (gitLinkMerging && ignoreConflicts) { add(tw.getRawPath(), ours, DirCacheEntry.STAGE_0, EPOCH, 0); } else if (gitLinkMerging) { add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); MergeResult result = createGitLinksMergeResult( base, ours, theirs); result.setContainsConflicts(true); mergeResults.put(tw.getPathString(), result); unmergedPaths.add(tw.getPathString()); } else { MergeResult result = contentMerge(base, ours, theirs, attributes); if (ignoreConflicts) { // In case a conflict is detected the working tree file // is again filled with new content (containing conflict // markers). But also stage 0 of the index is filled // with that content. result.setContainsConflicts(false); updateIndex(base, ours, theirs, result, attributes); } else { add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); DirCacheEntry e = add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); // OURS was deleted checkout THEIRS if (modeO == 0) { // Check worktree before checking out THEIRS if (isWorktreeDirty(work, ourDce)) { return false; } if (nonTree(modeT)) { if (e != null) { addToCheckout(tw.getPathString(), e, attributes); } } } unmergedPaths.add(tw.getPathString()); // generate a MergeResult for the deleted file mergeResults.put(tw.getPathString(), result); } } } } return true; } private static MergeResult createGitLinksMergeResult( CanonicalTreeParser base, CanonicalTreeParser ours, CanonicalTreeParser theirs) { return new MergeResult<>(Arrays.asList( new SubmoduleConflict( base == null ? null : base.getEntryObjectId()), new SubmoduleConflict( ours == null ? null : ours.getEntryObjectId()), new SubmoduleConflict( theirs == null ? null : theirs.getEntryObjectId()))); } /** * Does the content merge. The three texts base, ours and theirs are * specified with {@link CanonicalTreeParser}. If any of the parsers is * specified as null then an empty text will be used instead. * * @param base * @param ours * @param theirs * @param attributes * * @return the result of the content merge * @throws IOException */ private MergeResult contentMerge(CanonicalTreeParser base, CanonicalTreeParser ours, CanonicalTreeParser theirs, Attributes attributes) throws IOException { RawText baseText; RawText ourText; RawText theirsText; try { baseText = base == null ? RawText.EMPTY_TEXT : getRawText( base.getEntryObjectId(), attributes); ourText = ours == null ? RawText.EMPTY_TEXT : getRawText( ours.getEntryObjectId(), attributes); theirsText = theirs == null ? RawText.EMPTY_TEXT : getRawText( theirs.getEntryObjectId(), attributes); } catch (BinaryBlobException e) { MergeResult r = new MergeResult<>(Collections.emptyList()); r.setContainsConflicts(true); return r; } return (mergeAlgorithm.merge(RawTextComparator.DEFAULT, baseText, ourText, theirsText)); } private boolean isIndexDirty() { if (inCore) return false; final int modeI = tw.getRawMode(T_INDEX); final int modeO = tw.getRawMode(T_OURS); // Index entry has to match ours to be considered clean final boolean isDirty = nonTree(modeI) && !(modeO == modeI && tw.idEqual(T_INDEX, T_OURS)); if (isDirty) failingPaths .put(tw.getPathString(), MergeFailureReason.DIRTY_INDEX); return isDirty; } private boolean isWorktreeDirty(WorkingTreeIterator work, DirCacheEntry ourDce) throws IOException { if (work == null) return false; final int modeF = tw.getRawMode(T_FILE); final int modeO = tw.getRawMode(T_OURS); // Worktree entry has to match ours to be considered clean boolean isDirty; if (ourDce != null) isDirty = work.isModified(ourDce, true, reader); else { isDirty = work.isModeDifferent(modeO); if (!isDirty && nonTree(modeF)) isDirty = !tw.idEqual(T_FILE, T_OURS); } // Ignore existing empty directories if (isDirty && modeF == FileMode.TYPE_TREE && modeO == FileMode.TYPE_MISSING) isDirty = false; if (isDirty) failingPaths.put(tw.getPathString(), MergeFailureReason.DIRTY_WORKTREE); return isDirty; } /** * Updates the index after a content merge has happened. If no conflict has * occurred this includes persisting the merged content to the object * database. In case of conflicts this method takes care to write the * correct stages to the index. * * @param base * @param ours * @param theirs * @param result * @param attributes * @throws FileNotFoundException * @throws IOException */ private void updateIndex(CanonicalTreeParser base, CanonicalTreeParser ours, CanonicalTreeParser theirs, MergeResult result, Attributes attributes) throws FileNotFoundException, IOException { TemporaryBuffer rawMerged = null; try { rawMerged = doMerge(result); File mergedFile = inCore ? null : writeMergedFile(rawMerged, attributes); if (result.containsConflicts()) { // A conflict occurred, the file will contain conflict markers // the index will be populated with the three stages and the // workdir (if used) contains the halfway merged content. add(tw.getRawPath(), base, DirCacheEntry.STAGE_1, EPOCH, 0); add(tw.getRawPath(), ours, DirCacheEntry.STAGE_2, EPOCH, 0); add(tw.getRawPath(), theirs, DirCacheEntry.STAGE_3, EPOCH, 0); mergeResults.put(tw.getPathString(), result); return; } // No conflict occurred, the file will contain fully merged content. // The index will be populated with the new merged version. DirCacheEntry dce = new DirCacheEntry(tw.getPathString()); // Set the mode for the new content. Fall back to REGULAR_FILE if // we can't merge modes of OURS and THEIRS. int newMode = mergeFileModes(tw.getRawMode(0), tw.getRawMode(1), tw.getRawMode(2)); dce.setFileMode(newMode == FileMode.MISSING.getBits() ? FileMode.REGULAR_FILE : FileMode.fromBits(newMode)); if (mergedFile != null) { dce.setLastModified( nonNullRepo().getFS().lastModifiedInstant(mergedFile)); dce.setLength((int) mergedFile.length()); } dce.setObjectId(insertMergeResult(rawMerged, attributes)); builder.add(dce); } finally { if (rawMerged != null) { rawMerged.destroy(); } } } /** * Writes merged file content to the working tree. * * @param rawMerged * the raw merged content * @param attributes * the files .gitattributes entries * @return the working tree file to which the merged content was written. * @throws FileNotFoundException * @throws IOException */ private File writeMergedFile(TemporaryBuffer rawMerged, Attributes attributes) throws FileNotFoundException, IOException { File workTree = nonNullRepo().getWorkTree(); FS fs = nonNullRepo().getFS(); File of = new File(workTree, tw.getPathString()); File parentFolder = of.getParentFile(); if (!fs.exists(parentFolder)) { parentFolder.mkdirs(); } EolStreamType streamType = EolStreamTypeUtil.detectStreamType( OperationType.CHECKOUT_OP, workingTreeOptions, attributes); try (OutputStream os = EolStreamTypeUtil.wrapOutputStream( new BufferedOutputStream(new FileOutputStream(of)), streamType)) { rawMerged.writeTo(os, null); } return of; } private TemporaryBuffer doMerge(MergeResult result) throws IOException { TemporaryBuffer.LocalFile buf = new TemporaryBuffer.LocalFile( db != null ? nonNullRepo().getDirectory() : null, inCoreLimit); boolean success = false; try { new MergeFormatter().formatMerge(buf, result, Arrays.asList(commitNames), UTF_8); buf.close(); success = true; } finally { if (!success) { buf.destroy(); } } return buf; } private ObjectId insertMergeResult(TemporaryBuffer buf, Attributes attributes) throws IOException { InputStream in = buf.openInputStream(); try (LfsInputStream is = LfsFactory.getInstance().applyCleanFilter( getRepository(), in, buf.length(), attributes.get(Constants.ATTR_MERGE))) { return getObjectInserter().insert(OBJ_BLOB, is.getLength(), is); } } /** * Try to merge filemodes. If only ours or theirs have changed the mode * (compared to base) we choose that one. If ours and theirs have equal * modes return that one. If also that is not the case the modes are not * mergeable. Return {@link FileMode#MISSING} int that case. * * @param modeB * filemode found in BASE * @param modeO * filemode found in OURS * @param modeT * filemode found in THEIRS * * @return the merged filemode or {@link FileMode#MISSING} in case of a * conflict */ private int mergeFileModes(int modeB, int modeO, int modeT) { if (modeO == modeT) return modeO; if (modeB == modeO) // Base equal to Ours -> chooses Theirs if that is not missing return (modeT == FileMode.MISSING.getBits()) ? modeO : modeT; if (modeB == modeT) // Base equal to Theirs -> chooses Ours if that is not missing return (modeO == FileMode.MISSING.getBits()) ? modeT : modeO; return FileMode.MISSING.getBits(); } private RawText getRawText(ObjectId id, Attributes attributes) throws IOException, BinaryBlobException { if (id.equals(ObjectId.zeroId())) return new RawText(new byte[] {}); ObjectLoader loader = LfsFactory.getInstance().applySmudgeFilter( getRepository(), reader.open(id, OBJ_BLOB), attributes.get(Constants.ATTR_MERGE)); int threshold = PackConfig.DEFAULT_BIG_FILE_THRESHOLD; return RawText.load(loader, threshold); } private static boolean nonTree(int mode) { return mode != 0 && !FileMode.TREE.equals(mode); } private static boolean isGitLink(int mode) { return FileMode.GITLINK.equals(mode); } /** {@inheritDoc} */ @Override public ObjectId getResultTreeId() { return (resultTree == null) ? null : resultTree.toObjectId(); } /** * Set the names of the commits as they would appear in conflict markers * * @param commitNames * the names of the commits as they would appear in conflict * markers */ public void setCommitNames(String[] commitNames) { this.commitNames = commitNames; } /** * Get the names of the commits as they would appear in conflict markers. * * @return the names of the commits as they would appear in conflict * markers. */ public String[] getCommitNames() { return commitNames; } /** * Get the paths with conflicts. This is a subset of the files listed by * {@link #getModifiedFiles()} * * @return the paths with conflicts. This is a subset of the files listed by * {@link #getModifiedFiles()} */ public List getUnmergedPaths() { return unmergedPaths; } /** * Get the paths of files which have been modified by this merge. * * @return the paths of files which have been modified by this merge. A file * will be modified if a content-merge works on this path or if the * merge algorithm decides to take the theirs-version. This is a * superset of the files listed by {@link #getUnmergedPaths()}. */ public List getModifiedFiles() { return modifiedFiles; } /** * Get a map which maps the paths of files which have to be checked out * because the merge created new fully-merged content for this file into the * index. * * @return a map which maps the paths of files which have to be checked out * because the merge created new fully-merged content for this file * into the index. This means: the merge wrote a new stage 0 entry * for this path. */ public Map getToBeCheckedOut() { return toBeCheckedOut; } /** * Get the mergeResults * * @return the mergeResults */ public Map> getMergeResults() { return mergeResults; } /** * Get list of paths causing this merge to fail (not stopped because of a * conflict). * * @return lists paths causing this merge to fail (not stopped because of a * conflict). null is returned if this merge didn't * fail. */ public Map getFailingPaths() { return failingPaths.isEmpty() ? null : failingPaths; } /** * Returns whether this merge failed (i.e. not stopped because of a * conflict) * * @return true if a failure occurred, false * otherwise */ public boolean failed() { return !failingPaths.isEmpty(); } /** * Sets the DirCache which shall be used by this merger. If the DirCache is * not set explicitly and if this merger doesn't work in-core, this merger * will implicitly get and lock a default DirCache. If the DirCache is * explicitly set the caller is responsible to lock it in advance. Finally * the merger will call {@link org.eclipse.jgit.dircache.DirCache#commit()} * which requires that the DirCache is locked. If the {@link #mergeImpl()} * returns without throwing an exception the lock will be released. In case * of exceptions the caller is responsible to release the lock. * * @param dc * the DirCache to set */ public void setDirCache(DirCache dc) { this.dircache = dc; implicitDirCache = false; } /** * Sets the WorkingTreeIterator to be used by this merger. If no * WorkingTreeIterator is set this merger will ignore the working tree and * fail if a content merge is necessary. *

* TODO: enhance WorkingTreeIterator to support write operations. Then this * merger will be able to merge with a different working tree abstraction. * * @param workingTreeIterator * the workingTreeIt to set */ public void setWorkingTreeIterator(WorkingTreeIterator workingTreeIterator) { this.workingTreeIterator = workingTreeIterator; } /** * The resolve conflict way of three way merging * * @param baseTree * a {@link org.eclipse.jgit.treewalk.AbstractTreeIterator} * object. * @param headTree * a {@link org.eclipse.jgit.revwalk.RevTree} object. * @param mergeTree * a {@link org.eclipse.jgit.revwalk.RevTree} object. * @param ignoreConflicts * Controls what to do in case a content-merge is done and a * conflict is detected. The default setting for this should be * false. In this case the working tree file is * filled with new content (containing conflict markers) and the * index is filled with multiple stages containing BASE, OURS and * THEIRS content. Having such non-0 stages is the sign to git * tools that there are still conflicts for that path. *

* If true is specified the behavior is different. * In case a conflict is detected the working tree file is again * filled with new content (containing conflict markers). But * also stage 0 of the index is filled with that content. No * other stages are filled. Means: there is no conflict on that * path but the new content (including conflict markers) is * stored as successful merge result. This is needed in the * context of {@link org.eclipse.jgit.merge.RecursiveMerger} * where when determining merge bases we don't want to deal with * content-merge conflicts. * @return whether the trees merged cleanly * @throws java.io.IOException * @since 3.5 */ protected boolean mergeTrees(AbstractTreeIterator baseTree, RevTree headTree, RevTree mergeTree, boolean ignoreConflicts) throws IOException { builder = dircache.builder(); DirCacheBuildIterator buildIt = new DirCacheBuildIterator(builder); tw = new NameConflictTreeWalk(db, reader); tw.addTree(baseTree); tw.addTree(headTree); tw.addTree(mergeTree); int dciPos = tw.addTree(buildIt); if (workingTreeIterator != null) { tw.addTree(workingTreeIterator); workingTreeIterator.setDirCacheIterator(tw, dciPos); } else { tw.setFilter(TreeFilter.ANY_DIFF); } if (!mergeTreeWalk(tw, ignoreConflicts)) { return false; } if (!inCore) { // No problem found. The only thing left to be done is to // checkout all files from "theirs" which have been selected to // go into the new index. checkout(); // All content-merges are successfully done. If we can now write the // new index we are on quite safe ground. Even if the checkout of // files coming from "theirs" fails the user can work around such // failures by checking out the index again. if (!builder.commit()) { cleanUp(); throw new IndexWriteException(); } builder = null; } else { builder.finish(); builder = null; } if (getUnmergedPaths().isEmpty() && !failed()) { resultTree = dircache.writeTree(getObjectInserter()); return true; } resultTree = null; return false; } /** * Process the given TreeWalk's entries. * * @param treeWalk * The walk to iterate over. * @param ignoreConflicts * see * {@link org.eclipse.jgit.merge.ResolveMerger#mergeTrees(AbstractTreeIterator, RevTree, RevTree, boolean)} * @return Whether the trees merged cleanly. * @throws java.io.IOException * @since 3.5 */ protected boolean mergeTreeWalk(TreeWalk treeWalk, boolean ignoreConflicts) throws IOException { boolean hasWorkingTreeIterator = tw.getTreeCount() > T_FILE; boolean hasAttributeNodeProvider = treeWalk .getAttributesNodeProvider() != null; while (treeWalk.next()) { if (!processEntry( treeWalk.getTree(T_BASE, CanonicalTreeParser.class), treeWalk.getTree(T_OURS, CanonicalTreeParser.class), treeWalk.getTree(T_THEIRS, CanonicalTreeParser.class), treeWalk.getTree(T_INDEX, DirCacheBuildIterator.class), hasWorkingTreeIterator ? treeWalk.getTree(T_FILE, WorkingTreeIterator.class) : null, ignoreConflicts, hasAttributeNodeProvider ? treeWalk.getAttributes() : NO_ATTRIBUTES)) { cleanUp(); return false; } if (treeWalk.isSubtree() && enterSubtree) treeWalk.enterSubtree(); } return true; } }