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/*
 * Copyright (C) 2008-2011, Google Inc.
 * Copyright (C) 2007, Robin Rosenberg 
 * Copyright (C) 2006-2008, Shawn O. Pearce 
 * and other copyright owners as documented in the project's IP log.
 *
 * This program and the accompanying materials are made available
 * under the terms of the Eclipse Distribution License v1.0 which
 * accompanies this distribution, is reproduced below, and is
 * available at http://www.eclipse.org/org/documents/edl-v10.php
 *
 * All rights reserved.
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 * Redistribution and use in source and binary forms, with or
 * without modification, are permitted provided that the following
 * conditions are met:
 *
 * - Redistributions of source code must retain the above copyright
 *   notice, this list of conditions and the following disclaimer.
 *
 * - Redistributions in binary form must reproduce the above
 *   copyright notice, this list of conditions and the following
 *   disclaimer in the documentation and/or other materials provided
 *   with the distribution.
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 * - Neither the name of the Eclipse Foundation, Inc. nor the
 *   names of its contributors may be used to endorse or promote
 *   products derived from this software without specific prior
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 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
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 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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package org.eclipse.jgit.storage.dfs;

import static org.eclipse.jgit.storage.pack.PackExt.PACK;
import static org.eclipse.jgit.storage.pack.PackExt.INDEX;

import java.io.BufferedInputStream;
import java.io.EOFException;
import java.io.IOException;
import java.io.InputStream;
import java.nio.channels.Channels;
import java.text.MessageFormat;
import java.util.Set;
import java.util.zip.CRC32;
import java.util.zip.DataFormatException;
import java.util.zip.Inflater;

import org.eclipse.jgit.errors.CorruptObjectException;
import org.eclipse.jgit.errors.LargeObjectException;
import org.eclipse.jgit.errors.MissingObjectException;
import org.eclipse.jgit.errors.PackInvalidException;
import org.eclipse.jgit.errors.StoredObjectRepresentationNotAvailableException;
import org.eclipse.jgit.internal.JGitText;
import org.eclipse.jgit.lib.AbbreviatedObjectId;
import org.eclipse.jgit.lib.AnyObjectId;
import org.eclipse.jgit.lib.Constants;
import org.eclipse.jgit.lib.ObjectId;
import org.eclipse.jgit.lib.ObjectLoader;
import org.eclipse.jgit.lib.Repository;
import org.eclipse.jgit.storage.file.PackIndex;
import org.eclipse.jgit.storage.file.PackReverseIndex;
import org.eclipse.jgit.storage.pack.BinaryDelta;
import org.eclipse.jgit.storage.pack.PackOutputStream;
import org.eclipse.jgit.storage.pack.StoredObjectRepresentation;
import org.eclipse.jgit.util.IO;
import org.eclipse.jgit.util.LongList;

/**
 * A Git version 2 pack file representation. A pack file contains Git objects in
 * delta packed format yielding high compression of lots of object where some
 * objects are similar.
 */
public final class DfsPackFile {
	/**
	 * File offset used to cache {@link #index} in {@link DfsBlockCache}.
	 * 

* To better manage memory, the forward index is stored as a single block in * the block cache under this file position. A negative value is used * because it cannot occur in a normal pack file, and it is less likely to * collide with a valid data block from the file as the high bits will all * be set when treated as an unsigned long by the cache code. */ private static final long POS_INDEX = -1; /** Offset used to cache {@link #reverseIndex}. See {@link #POS_INDEX}. */ private static final long POS_REVERSE_INDEX = -2; /** Cache that owns this pack file and its data. */ private final DfsBlockCache cache; /** Description of the pack file's storage. */ private final DfsPackDescription packDesc; /** Unique identity of this pack while in-memory. */ final DfsPackKey key; /** * Total number of bytes in this pack file. *

* This field initializes to -1 and gets populated when a block is loaded. */ volatile long length; /** * Preferred alignment for loading blocks from the backing file. *

* It is initialized to 0 and filled in on the first read made from the * file. Block sizes may be odd, e.g. 4091, caused by the underling DFS * storing 4091 user bytes and 5 bytes block metadata into a lower level * 4096 byte block on disk. */ private volatile int blockSize; /** True once corruption has been detected that cannot be worked around. */ private volatile boolean invalid; /** * Lock for initialization of {@link #index} and {@link #corruptObjects}. *

* This lock ensures only one thread can perform the initialization work. */ private final Object initLock = new Object(); /** Index mapping {@link ObjectId} to position within the pack stream. */ private volatile DfsBlockCache.Ref index; /** Reverse version of {@link #index} mapping position to {@link ObjectId}. */ private volatile DfsBlockCache.Ref reverseIndex; /** * Objects we have tried to read, and discovered to be corrupt. *

* The list is allocated after the first corruption is found, and filled in * as more entries are discovered. Typically this list is never used, as * pack files do not usually contain corrupt objects. */ private volatile LongList corruptObjects; /** * Construct a reader for an existing, packfile. * * @param cache * cache that owns the pack data. * @param desc * description of the pack within the DFS. * @param key * interned key used to identify blocks in the block cache. */ DfsPackFile(DfsBlockCache cache, DfsPackDescription desc, DfsPackKey key) { this.cache = cache; this.packDesc = desc; this.key = key; length = desc.getFileSize(PACK); if (length <= 0) length = -1; } /** @return description that was originally used to configure this pack file. */ public DfsPackDescription getPackDescription() { return packDesc; } /** * @return whether the pack index file is loaded and cached in memory. * @since 2.2 */ public boolean isIndexLoaded() { DfsBlockCache.Ref idxref = index; return idxref != null && idxref.get() != null; } /** @return bytes cached in memory for this pack, excluding the index. */ public long getCachedSize() { return key.cachedSize.get(); } private String getPackName() { return packDesc.getFileName(PACK); } void setBlockSize(int newSize) { blockSize = newSize; } void setPackIndex(PackIndex idx) { long objCnt = idx.getObjectCount(); int recSize = Constants.OBJECT_ID_LENGTH + 8; int sz = (int) Math.min(objCnt * recSize, Integer.MAX_VALUE); index = cache.put(key, POS_INDEX, sz, idx); } PackIndex getPackIndex(DfsReader ctx) throws IOException { return idx(ctx); } private PackIndex idx(DfsReader ctx) throws IOException { DfsBlockCache.Ref idxref = index; if (idxref != null) { PackIndex idx = idxref.get(); if (idx != null) return idx; } if (invalid) throw new PackInvalidException(getPackName()); Repository.getGlobalListenerList() .dispatch(new BeforeDfsPackIndexLoadedEvent(this)); synchronized (initLock) { idxref = index; if (idxref != null) { PackIndex idx = idxref.get(); if (idx != null) return idx; } PackIndex idx; try { ReadableChannel rc = ctx.db.openFile(packDesc, INDEX); try { InputStream in = Channels.newInputStream(rc); int wantSize = 8192; int bs = rc.blockSize(); if (0 < bs && bs < wantSize) bs = (wantSize / bs) * bs; else if (bs <= 0) bs = wantSize; in = new BufferedInputStream(in, bs); idx = PackIndex.read(in); } finally { rc.close(); } } catch (EOFException e) { invalid = true; IOException e2 = new IOException(MessageFormat.format( DfsText.get().shortReadOfIndex, packDesc.getFileName(INDEX))); e2.initCause(e); throw e2; } catch (IOException e) { invalid = true; IOException e2 = new IOException(MessageFormat.format( DfsText.get().cannotReadIndex, packDesc.getFileName(INDEX))); e2.initCause(e); throw e2; } setPackIndex(idx); return idx; } } private PackReverseIndex getReverseIdx(DfsReader ctx) throws IOException { DfsBlockCache.Ref revref = reverseIndex; if (revref != null) { PackReverseIndex revidx = revref.get(); if (revidx != null) return revidx; } synchronized (initLock) { revref = reverseIndex; if (revref != null) { PackReverseIndex revidx = revref.get(); if (revidx != null) return revidx; } PackIndex idx = idx(ctx); PackReverseIndex revidx = new PackReverseIndex(idx); int sz = (int) Math.min( idx.getObjectCount() * 8, Integer.MAX_VALUE); reverseIndex = cache.put(key, POS_REVERSE_INDEX, sz, revidx); return revidx; } } /** * Check if an object is stored within this pack. * * @param ctx * reader context to support reading from the backing store if * the index is not already loaded in memory. * @param id * object to be located. * @return true if the object exists in this pack; false if it does not. * @throws IOException * the pack index is not available, or is corrupt. */ public boolean hasObject(DfsReader ctx, AnyObjectId id) throws IOException { final long offset = idx(ctx).findOffset(id); return 0 < offset && !isCorrupt(offset); } /** * Get an object from this pack. * * @param ctx * temporary working space associated with the calling thread. * @param id * the object to obtain from the pack. Must not be null. * @return the object loader for the requested object if it is contained in * this pack; null if the object was not found. * @throws IOException * the pack file or the index could not be read. */ ObjectLoader get(DfsReader ctx, AnyObjectId id) throws IOException { long offset = idx(ctx).findOffset(id); return 0 < offset && !isCorrupt(offset) ? load(ctx, offset) : null; } long findOffset(DfsReader ctx, AnyObjectId id) throws IOException { return idx(ctx).findOffset(id); } void resolve(DfsReader ctx, Set matches, AbbreviatedObjectId id, int matchLimit) throws IOException { idx(ctx).resolve(matches, id, matchLimit); } /** Release all memory used by this DfsPackFile instance. */ public void close() { cache.remove(this); index = null; reverseIndex = null; } /** * Obtain the total number of objects available in this pack. This method * relies on pack index, giving number of effectively available objects. * * @param ctx * current reader for the calling thread. * @return number of objects in index of this pack, likewise in this pack * @throws IOException * the index file cannot be loaded into memory. */ long getObjectCount(DfsReader ctx) throws IOException { return idx(ctx).getObjectCount(); } /** * Search for object id with the specified start offset in associated pack * (reverse) index. * * @param ctx * current reader for the calling thread. * @param offset * start offset of object to find * @return object id for this offset, or null if no object was found * @throws IOException * the index file cannot be loaded into memory. */ ObjectId findObjectForOffset(DfsReader ctx, long offset) throws IOException { return getReverseIdx(ctx).findObject(offset); } private byte[] decompress(long position, int sz, DfsReader ctx) throws IOException, DataFormatException { byte[] dstbuf; try { dstbuf = new byte[sz]; } catch (OutOfMemoryError noMemory) { // The size may be larger than our heap allows, return null to // let the caller know allocation isn't possible and it should // use the large object streaming approach instead. // // For example, this can occur when sz is 640 MB, and JRE // maximum heap size is only 256 MB. Even if the JRE has // 200 MB free, it cannot allocate a 640 MB byte array. return null; } if (ctx.inflate(this, position, dstbuf, false) != sz) throw new EOFException(MessageFormat.format( JGitText.get().shortCompressedStreamAt, Long.valueOf(position))); return dstbuf; } void copyPackAsIs(PackOutputStream out, boolean validate, DfsReader ctx) throws IOException { // Pin the first window, this ensures the length is accurate. ctx.pin(this, 0); ctx.copyPackAsIs(this, length, validate, out); } void copyAsIs(PackOutputStream out, DfsObjectToPack src, boolean validate, DfsReader ctx) throws IOException, StoredObjectRepresentationNotAvailableException { final CRC32 crc1 = validate ? new CRC32() : null; final CRC32 crc2 = validate ? new CRC32() : null; final byte[] buf = out.getCopyBuffer(); // Rip apart the header so we can discover the size. // try { readFully(src.offset, buf, 0, 20, ctx); } catch (IOException ioError) { StoredObjectRepresentationNotAvailableException gone; gone = new StoredObjectRepresentationNotAvailableException(src); gone.initCause(ioError); throw gone; } int c = buf[0] & 0xff; final int typeCode = (c >> 4) & 7; long inflatedLength = c & 15; int shift = 4; int headerCnt = 1; while ((c & 0x80) != 0) { c = buf[headerCnt++] & 0xff; inflatedLength += ((long) (c & 0x7f)) << shift; shift += 7; } if (typeCode == Constants.OBJ_OFS_DELTA) { do { c = buf[headerCnt++] & 0xff; } while ((c & 128) != 0); if (validate) { crc1.update(buf, 0, headerCnt); crc2.update(buf, 0, headerCnt); } } else if (typeCode == Constants.OBJ_REF_DELTA) { if (validate) { crc1.update(buf, 0, headerCnt); crc2.update(buf, 0, headerCnt); } readFully(src.offset + headerCnt, buf, 0, 20, ctx); if (validate) { crc1.update(buf, 0, 20); crc2.update(buf, 0, 20); } headerCnt += 20; } else if (validate) { crc1.update(buf, 0, headerCnt); crc2.update(buf, 0, headerCnt); } final long dataOffset = src.offset + headerCnt; final long dataLength = src.length; final long expectedCRC; final DfsBlock quickCopy; // Verify the object isn't corrupt before sending. If it is, // we report it missing instead. // try { quickCopy = ctx.quickCopy(this, dataOffset, dataLength); if (validate && idx(ctx).hasCRC32Support()) { // Index has the CRC32 code cached, validate the object. // expectedCRC = idx(ctx).findCRC32(src); if (quickCopy != null) { quickCopy.crc32(crc1, dataOffset, (int) dataLength); } else { long pos = dataOffset; long cnt = dataLength; while (cnt > 0) { final int n = (int) Math.min(cnt, buf.length); readFully(pos, buf, 0, n, ctx); crc1.update(buf, 0, n); pos += n; cnt -= n; } } if (crc1.getValue() != expectedCRC) { setCorrupt(src.offset); throw new CorruptObjectException(MessageFormat.format( JGitText.get().objectAtHasBadZlibStream, Long.valueOf(src.offset), getPackName())); } } else if (validate) { // We don't have a CRC32 code in the index, so compute it // now while inflating the raw data to get zlib to tell us // whether or not the data is safe. // Inflater inf = ctx.inflater(); byte[] tmp = new byte[1024]; if (quickCopy != null) { quickCopy.check(inf, tmp, dataOffset, (int) dataLength); } else { long pos = dataOffset; long cnt = dataLength; while (cnt > 0) { final int n = (int) Math.min(cnt, buf.length); readFully(pos, buf, 0, n, ctx); crc1.update(buf, 0, n); inf.setInput(buf, 0, n); while (inf.inflate(tmp, 0, tmp.length) > 0) continue; pos += n; cnt -= n; } } if (!inf.finished() || inf.getBytesRead() != dataLength) { setCorrupt(src.offset); throw new EOFException(MessageFormat.format( JGitText.get().shortCompressedStreamAt, Long.valueOf(src.offset))); } expectedCRC = crc1.getValue(); } else { expectedCRC = -1; } } catch (DataFormatException dataFormat) { setCorrupt(src.offset); CorruptObjectException corruptObject = new CorruptObjectException( MessageFormat.format( JGitText.get().objectAtHasBadZlibStream, Long.valueOf(src.offset), getPackName())); corruptObject.initCause(dataFormat); StoredObjectRepresentationNotAvailableException gone; gone = new StoredObjectRepresentationNotAvailableException(src); gone.initCause(corruptObject); throw gone; } catch (IOException ioError) { StoredObjectRepresentationNotAvailableException gone; gone = new StoredObjectRepresentationNotAvailableException(src); gone.initCause(ioError); throw gone; } if (quickCopy != null) { // The entire object fits into a single byte array window slice, // and we have it pinned. Write this out without copying. // out.writeHeader(src, inflatedLength); quickCopy.write(out, dataOffset, (int) dataLength, null); } else if (dataLength <= buf.length) { // Tiny optimization: Lots of objects are very small deltas or // deflated commits that are likely to fit in the copy buffer. // if (!validate) { long pos = dataOffset; long cnt = dataLength; while (cnt > 0) { final int n = (int) Math.min(cnt, buf.length); readFully(pos, buf, 0, n, ctx); pos += n; cnt -= n; } } out.writeHeader(src, inflatedLength); out.write(buf, 0, (int) dataLength); } else { // Now we are committed to sending the object. As we spool it out, // check its CRC32 code to make sure there wasn't corruption between // the verification we did above, and us actually outputting it. // out.writeHeader(src, inflatedLength); long pos = dataOffset; long cnt = dataLength; while (cnt > 0) { final int n = (int) Math.min(cnt, buf.length); readFully(pos, buf, 0, n, ctx); if (validate) crc2.update(buf, 0, n); out.write(buf, 0, n); pos += n; cnt -= n; } if (validate && crc2.getValue() != expectedCRC) { throw new CorruptObjectException(MessageFormat.format( JGitText.get().objectAtHasBadZlibStream, Long.valueOf(src.offset), getPackName())); } } } boolean invalid() { return invalid; } void setInvalid() { invalid = true; } private void readFully(long position, byte[] dstbuf, int dstoff, int cnt, DfsReader ctx) throws IOException { if (ctx.copy(this, position, dstbuf, dstoff, cnt) != cnt) throw new EOFException(); } long alignToBlock(long pos) { int size = blockSize; if (size == 0) size = cache.getBlockSize(); return (pos / size) * size; } DfsBlock getOrLoadBlock(long pos, DfsReader ctx) throws IOException { return cache.getOrLoad(this, pos, ctx); } DfsBlock readOneBlock(long pos, DfsReader ctx) throws IOException { if (invalid) throw new PackInvalidException(getPackName()); boolean close = true; ReadableChannel rc = ctx.db.openFile(packDesc, PACK); try { // If the block alignment is not yet known, discover it. Prefer the // larger size from either the cache or the file itself. int size = blockSize; if (size == 0) { size = rc.blockSize(); if (size <= 0) size = cache.getBlockSize(); else if (size < cache.getBlockSize()) size = (cache.getBlockSize() / size) * size; blockSize = size; pos = (pos / size) * size; } // If the size of the file is not yet known, try to discover it. // Channels may choose to return -1 to indicate they don't // know the length yet, in this case read up to the size unit // given by the caller, then recheck the length. long len = length; if (len < 0) { len = rc.size(); if (0 <= len) length = len; } if (0 <= len && len < pos + size) size = (int) (len - pos); if (size <= 0) throw new EOFException(MessageFormat.format( DfsText.get().shortReadOfBlock, Long.valueOf(pos), getPackName(), Long.valueOf(0), Long.valueOf(0))); byte[] buf = new byte[size]; rc.position(pos); int cnt = IO.read(rc, buf, 0, size); if (cnt != size) { if (0 <= len) { throw new EOFException(MessageFormat.format( DfsText.get().shortReadOfBlock, Long.valueOf(pos), getPackName(), Integer.valueOf(size), Integer.valueOf(cnt))); } // Assume the entire thing was read in a single shot, compact // the buffer to only the space required. byte[] n = new byte[cnt]; System.arraycopy(buf, 0, n, 0, n.length); buf = n; } else if (len < 0) { // With no length at the start of the read, the channel should // have the length available at the end. length = len = rc.size(); } DfsBlock v = new DfsBlock(key, pos, buf); if (v.end < len) close = !cache.readAhead(rc, key, size, v.end, len, ctx); return v; } finally { if (close) rc.close(); } } ObjectLoader load(DfsReader ctx, long pos) throws IOException { try { final byte[] ib = ctx.tempId; Delta delta = null; byte[] data = null; int type = Constants.OBJ_BAD; boolean cached = false; SEARCH: for (;;) { readFully(pos, ib, 0, 20, ctx); int c = ib[0] & 0xff; final int typeCode = (c >> 4) & 7; long sz = c & 15; int shift = 4; int p = 1; while ((c & 0x80) != 0) { c = ib[p++] & 0xff; sz += ((long) (c & 0x7f)) << shift; shift += 7; } switch (typeCode) { case Constants.OBJ_COMMIT: case Constants.OBJ_TREE: case Constants.OBJ_BLOB: case Constants.OBJ_TAG: { if (delta != null) { data = decompress(pos + p, (int) sz, ctx); type = typeCode; break SEARCH; } if (sz < ctx.getStreamFileThreshold()) { data = decompress(pos + p, (int) sz, ctx); if (data != null) return new ObjectLoader.SmallObject(typeCode, data); } return new LargePackedWholeObject(typeCode, sz, pos, p, this, ctx.db); } case Constants.OBJ_OFS_DELTA: { c = ib[p++] & 0xff; long base = c & 127; while ((c & 128) != 0) { base += 1; c = ib[p++] & 0xff; base <<= 7; base += (c & 127); } base = pos - base; delta = new Delta(delta, pos, (int) sz, p, base); if (sz != delta.deltaSize) break SEARCH; DeltaBaseCache.Entry e = ctx.getDeltaBaseCache().get(key, base); if (e != null) { type = e.type; data = e.data; cached = true; break SEARCH; } pos = base; continue SEARCH; } case Constants.OBJ_REF_DELTA: { readFully(pos + p, ib, 0, 20, ctx); long base = findDeltaBase(ctx, ObjectId.fromRaw(ib)); delta = new Delta(delta, pos, (int) sz, p + 20, base); if (sz != delta.deltaSize) break SEARCH; DeltaBaseCache.Entry e = ctx.getDeltaBaseCache().get(key, base); if (e != null) { type = e.type; data = e.data; cached = true; break SEARCH; } pos = base; continue SEARCH; } default: throw new IOException(MessageFormat.format( JGitText.get().unknownObjectType, Integer.valueOf(typeCode))); } } // At this point there is at least one delta to apply to data. // (Whole objects with no deltas to apply return early above.) if (data == null) throw new LargeObjectException(); do { // Cache only the base immediately before desired object. if (cached) cached = false; else if (delta.next == null) ctx.getDeltaBaseCache().put(key, delta.basePos, type, data); pos = delta.deltaPos; byte[] cmds = decompress(pos + delta.hdrLen, delta.deltaSize, ctx); if (cmds == null) { data = null; // Discard base in case of OutOfMemoryError throw new LargeObjectException(); } final long sz = BinaryDelta.getResultSize(cmds); if (Integer.MAX_VALUE <= sz) throw new LargeObjectException.ExceedsByteArrayLimit(); final byte[] result; try { result = new byte[(int) sz]; } catch (OutOfMemoryError tooBig) { data = null; // Discard base in case of OutOfMemoryError cmds = null; throw new LargeObjectException.OutOfMemory(tooBig); } BinaryDelta.apply(data, cmds, result); data = result; delta = delta.next; } while (delta != null); return new ObjectLoader.SmallObject(type, data); } catch (DataFormatException dfe) { CorruptObjectException coe = new CorruptObjectException( MessageFormat.format( JGitText.get().objectAtHasBadZlibStream, Long.valueOf(pos), getPackName())); coe.initCause(dfe); throw coe; } } private long findDeltaBase(DfsReader ctx, ObjectId baseId) throws IOException, MissingObjectException { long ofs = idx(ctx).findOffset(baseId); if (ofs < 0) throw new MissingObjectException(baseId, JGitText.get().missingDeltaBase); return ofs; } private static class Delta { /** Child that applies onto this object. */ final Delta next; /** Offset of the delta object. */ final long deltaPos; /** Size of the inflated delta stream. */ final int deltaSize; /** Total size of the delta's pack entry header (including base). */ final int hdrLen; /** Offset of the base object this delta applies onto. */ final long basePos; Delta(Delta next, long ofs, int sz, int hdrLen, long baseOffset) { this.next = next; this.deltaPos = ofs; this.deltaSize = sz; this.hdrLen = hdrLen; this.basePos = baseOffset; } } byte[] getDeltaHeader(DfsReader wc, long pos) throws IOException, DataFormatException { // The delta stream starts as two variable length integers. If we // assume they are 64 bits each, we need 16 bytes to encode them, // plus 2 extra bytes for the variable length overhead. So 18 is // the longest delta instruction header. // final byte[] hdr = new byte[32]; wc.inflate(this, pos, hdr, true /* header only */); return hdr; } int getObjectType(DfsReader ctx, long pos) throws IOException { final byte[] ib = ctx.tempId; for (;;) { readFully(pos, ib, 0, 20, ctx); int c = ib[0] & 0xff; final int type = (c >> 4) & 7; switch (type) { case Constants.OBJ_COMMIT: case Constants.OBJ_TREE: case Constants.OBJ_BLOB: case Constants.OBJ_TAG: return type; case Constants.OBJ_OFS_DELTA: { int p = 1; while ((c & 0x80) != 0) c = ib[p++] & 0xff; c = ib[p++] & 0xff; long ofs = c & 127; while ((c & 128) != 0) { ofs += 1; c = ib[p++] & 0xff; ofs <<= 7; ofs += (c & 127); } pos = pos - ofs; continue; } case Constants.OBJ_REF_DELTA: { int p = 1; while ((c & 0x80) != 0) c = ib[p++] & 0xff; readFully(pos + p, ib, 0, 20, ctx); pos = findDeltaBase(ctx, ObjectId.fromRaw(ib)); continue; } default: throw new IOException(MessageFormat.format( JGitText.get().unknownObjectType, Integer.valueOf(type))); } } } long getObjectSize(DfsReader ctx, AnyObjectId id) throws IOException { final long offset = idx(ctx).findOffset(id); return 0 < offset ? getObjectSize(ctx, offset) : -1; } long getObjectSize(DfsReader ctx, long pos) throws IOException { final byte[] ib = ctx.tempId; readFully(pos, ib, 0, 20, ctx); int c = ib[0] & 0xff; final int type = (c >> 4) & 7; long sz = c & 15; int shift = 4; int p = 1; while ((c & 0x80) != 0) { c = ib[p++] & 0xff; sz += ((long) (c & 0x7f)) << shift; shift += 7; } long deltaAt; switch (type) { case Constants.OBJ_COMMIT: case Constants.OBJ_TREE: case Constants.OBJ_BLOB: case Constants.OBJ_TAG: return sz; case Constants.OBJ_OFS_DELTA: c = ib[p++] & 0xff; while ((c & 128) != 0) c = ib[p++] & 0xff; deltaAt = pos + p; break; case Constants.OBJ_REF_DELTA: deltaAt = pos + p + 20; break; default: throw new IOException(MessageFormat.format( JGitText.get().unknownObjectType, Integer.valueOf(type))); } try { return BinaryDelta.getResultSize(getDeltaHeader(ctx, deltaAt)); } catch (DataFormatException dfe) { CorruptObjectException coe = new CorruptObjectException( MessageFormat.format( JGitText.get().objectAtHasBadZlibStream, Long.valueOf(pos), getPackName())); coe.initCause(dfe); throw coe; } } void representation(DfsReader ctx, DfsObjectRepresentation r) throws IOException { final long pos = r.offset; final byte[] ib = ctx.tempId; readFully(pos, ib, 0, 20, ctx); int c = ib[0] & 0xff; int p = 1; final int typeCode = (c >> 4) & 7; while ((c & 0x80) != 0) c = ib[p++] & 0xff; long len = (getReverseIdx(ctx).findNextOffset(pos, length - 20) - pos); switch (typeCode) { case Constants.OBJ_COMMIT: case Constants.OBJ_TREE: case Constants.OBJ_BLOB: case Constants.OBJ_TAG: r.format = StoredObjectRepresentation.PACK_WHOLE; r.length = len - p; return; case Constants.OBJ_OFS_DELTA: { c = ib[p++] & 0xff; long ofs = c & 127; while ((c & 128) != 0) { ofs += 1; c = ib[p++] & 0xff; ofs <<= 7; ofs += (c & 127); } ofs = pos - ofs; r.format = StoredObjectRepresentation.PACK_DELTA; r.baseId = findObjectForOffset(ctx, ofs); r.length = len - p; return; } case Constants.OBJ_REF_DELTA: { len -= p; len -= Constants.OBJECT_ID_LENGTH; readFully(pos + p, ib, 0, 20, ctx); ObjectId id = ObjectId.fromRaw(ib); r.format = StoredObjectRepresentation.PACK_DELTA; r.baseId = id; r.length = len; return; } default: throw new IOException(MessageFormat.format( JGitText.get().unknownObjectType, Integer.valueOf(typeCode))); } } private boolean isCorrupt(long offset) { LongList list = corruptObjects; if (list == null) return false; synchronized (list) { return list.contains(offset); } } private void setCorrupt(long offset) { LongList list = corruptObjects; if (list == null) { synchronized (initLock) { list = corruptObjects; if (list == null) { list = new LongList(); corruptObjects = list; } } } synchronized (list) { list.add(offset); } } }





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