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/*
 * Copyright 2007-2019 Amazon.com, Inc. or its affiliates. All Rights Reserved.
 *
 * Licensed under the Apache License, Version 2.0 (the "License").
 * You may not use this file except in compliance with the License.
 * A copy of the License is located at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * or in the "license" file accompanying this file. This file is distributed
 * on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
 * express or implied. See the License for the specific language governing
 * permissions and limitations under the License.
 */

package com.amazon.ion.impl;
import com.amazon.ion.IonException;
import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.util.ArrayList;
import java.util.Comparator;
import java.util.SortedSet;
import java.util.TreeSet;
/**
 * This implements a blocked byte buffer and both an input and output stream
 * that operates over it. It is designed to be able to be randomly accessed.
 * The output steam supports both inserting data (with "stretching") in the
 * middle of the stream and over-write.  The output steam also supports remove
 * which shrinks the overall data buffer. The underlying buffer is backed by
 * one or more byte arrays to minimize data movement.
 * 

* It is also meant to be reused, so that it does not have to pressure the * GC, if that is desirable. */ final class BlockedBuffer { /////////////////////////////////////////////////////////////////////////////// // // updatable, insertable, and possibly fragmented byte buffer // // these manage the set of memory (byte) buffers ArrayList _blocks; int _next_block_position; // next position in _blocks for active block, may be less than _blocks.size() int _lastCapacity; // used to allocate new blocks int _buf_limit; // high water mark of _position int _version; int _mutation_version; Object _mutator; // BUGBUG - this is just a test, it shouldn't be in checked in code static final boolean test_with_no_version_checking = false; void start_mutate(Object caller, int version) { if (test_with_no_version_checking) return; if (_mutation_version != 0 || _mutator != null) throw new BlockedBufferException("lock conflict"); if (version != _version) throw new BlockedBufferException("version conflict on update"); _mutator = caller; _mutation_version = version; } int end_mutate(Object caller) { if (test_with_no_version_checking) return _version; if (_version != _mutation_version) throw new BlockedBufferException("version mismatch failure"); if (caller != _mutator) throw new BlockedBufferException("caller mismatch failure"); _version = _mutation_version + 1; _mutation_version = 0; _mutator = null; return _version; } boolean mutation_in_progress(Object caller, int version) { if (test_with_no_version_checking) return false; if (_mutation_version != version) throw new BlockedBufferException("unexpected update lock conflict"); if (caller != _mutator) throw new BlockedBufferException("caller mismatch failure"); return true; } int getVersion() { return _version; } static boolean debugValidation = false; static int _defaultBlockSizeMin; static int _defaultBlockSizeUpperLimit; static { resetParameters(); } public static void resetParameters() { debugValidation = false; _defaultBlockSizeMin = 4096 * 8; _defaultBlockSizeUpperLimit = 4096 * 8; } public int _blockSizeMin = _defaultBlockSizeMin; public int _blockSizeUpperLimit = _defaultBlockSizeUpperLimit; static void setBlockSizeParameters(int min, int max, boolean intenseValidation) { debugValidation = intenseValidation; setBlockSizeParameters(min, max); } public static void setBlockSizeParameters(int min, int max) { if (min < 0 || max < min) { throw new IllegalArgumentException(); } _defaultBlockSizeMin = min; _defaultBlockSizeUpperLimit = max; return; } /////////////////////////////////////////////////////////////////////////// /** * Creates a new buffer without preallocating any space. */ public BlockedBuffer() { start_mutate(this, 0); init(0, null); end_mutate(this); } /** * Creates a new buffer, preallocating some initial capacity. * * @param initialSize the number of bytes to allocate. */ public BlockedBuffer(int initialSize) { start_mutate(this, 0); init(initialSize, null); end_mutate(this); } /** * Creates a new buffer, assuming ownership of given data. * This method assumes ownership of the data array * and will modify it at will. * * @param data the initial data to be buffered. * * @throws NullPointerException if buffer is null. */ public BlockedBuffer(byte[] data) { start_mutate(this, 0); init(0, new bbBlock(data)); _buf_limit = data.length; end_mutate(this); } /** * Creates a new buffer containing all data remaining on an * {@link InputStream}. The stream is closed before returning. * * @param data must not be null. * * @throws IOException */ public BlockedBuffer(InputStream data) throws IOException { IonBinary.Writer writer = new IonBinary.Writer(this); try { writer.write(data); } finally { data.close(); } } /** * creates a logical copy of the buffer. This does not preserve * the position state and is equivalent to constructing a new * buffer from the old by getting the bytes from the original * and writing them to a new buffer. */ @Override public BlockedBuffer clone() { BlockedBuffer clone = new BlockedBuffer(this._buf_limit); int end = this._buf_limit; bbBlock dst_block = clone._blocks.get(0); int dst_offset = 0; int dst_limit = dst_block.blockCapacity(); for (int ii=0; ii dst_limit - dst_offset) { to_copy = dst_limit - dst_offset; } System.arraycopy(src_block._buffer, 0, dst_block._buffer, dst_offset, to_copy); dst_offset += to_copy; // the cloned BlockedBuffer should be able to hold all the data // in it's single block assert dst_offset <= dst_limit; // see if we're done (and break out in that case) if (src_end >= end) break; } dst_block._limit = dst_offset; clone._buf_limit = dst_offset; return clone; } /** * Initializes the various members such as the block arraylist * the initial block and the various values like the block size upper limit. * @param initialSize or 0 * @param initialBlock or null * @return bbBlock the initial current block */ private bbBlock init(int initialSize, bbBlock initialBlock) { this._lastCapacity = BlockedBuffer._defaultBlockSizeMin; this._blockSizeUpperLimit = BlockedBuffer._defaultBlockSizeUpperLimit; while (this._lastCapacity < initialSize && this._lastCapacity < this._blockSizeUpperLimit) { this.nextBlockSize(this, 0); } int count = initialSize / this._lastCapacity; if (initialBlock != null) count = 1; this._blocks = new ArrayList(count); if (initialBlock == null) { initialBlock = new bbBlock(this.nextBlockSize(this, 0)); } this._blocks.add(initialBlock); this._next_block_position = 1; // create any preallocated blocks (following _next_block_position) bbBlock b; for (int need = initialSize - initialBlock.blockCapacity() ; need > 0 ; need -= b.blockCapacity() ) { b = new bbBlock(this.nextBlockSize(this, 0)); b._idx = -1; this._blocks.add(b); } return initialBlock; } /** * Gets the number of bytes of content in this buffer. * This isn't the same as its capacity. */ public final int size() { return _buf_limit; } /** * empties the entire contents of the buffer */ private void clear(Object caller, int version) { assert mutation_in_progress(caller, version); _buf_limit = 0; for (int ii=0; ii<_blocks.size(); ii++) { _blocks.get(ii).clearBlock(); // _blocks.get(ii)._idx = -1; this is done in clearBlock() } bbBlock first = _blocks.get(0); first._idx = 0; // cas: 26 dec 2008 first._offset = 0; first._limit = 0; _next_block_position = 1; return; } /** * treat the limit as the end of file */ bbBlock truncate(Object caller, int version, int pos) { assert mutation_in_progress(caller, version); if (0 > pos || pos > this._buf_limit ) throw new IllegalArgumentException(); // clear out all the blocks in use from the last in use // to the block where the eof will be located bbBlock b = null; for (int idx = this._next_block_position - 1; idx >= 0; idx--) { b = this._blocks.get(idx); if (b._offset <= pos) break; b.clearBlock(); } if (b == null) { throw new IllegalStateException("block missing at position "+pos); } // reset the next block position to account for this. this._next_block_position = b._idx + 1; // on the block where eof is, set it's limit appropriately b._limit = pos - b._offset; // set the overall buffer limits this._buf_limit = pos; b = this.findBlockForRead(pos, version, b, pos); return b; } private bbBlock addBlock(Object caller, int version, int idx, int offset, int needed) { assert mutation_in_progress(caller, version); bbBlock newblock = null; for (int ii=this._next_block_position; ii < this._blocks.size(); ii++) { bbBlock tmpblock = this._blocks.get(this._next_block_position); if (tmpblock._buffer.length >= needed) { this._blocks.remove(this._next_block_position); newblock = tmpblock; break; } } if (newblock == null) { // if there's nothing big enough to recycle // so we have to really make more space int bufcapacity = 0; if (needed > _blockSizeUpperLimit) { bufcapacity = needed; } else { while (bufcapacity < needed) { bufcapacity = this.nextBlockSize(caller, version); } } newblock = new bbBlock(bufcapacity); } // if the caller didn't specify an index // we'll have to find out where this goes if (idx == -1) { for (idx = 0; idx < this._next_block_position; idx++) { if (this._blocks.get(idx)._offset < 0) { break; } if (offset >= this._blocks.get(idx)._offset) { break; } } } // initialize the buffer and add it to the list in the right spot newblock._idx = idx; newblock._offset = offset; _blocks.add(idx, newblock); _next_block_position++; // if this isn't the last buffer, bump the idx of the trailing buffers for (int ii = idx + 1; ii < _next_block_position; ii++) { this._blocks.get(ii)._idx = ii; } return newblock; } private int nextBlockSize(Object caller, int version) { assert mutation_in_progress(caller, version); if (_lastCapacity == 0) { _lastCapacity = _blockSizeMin; } else if (_lastCapacity < _blockSizeUpperLimit) { _lastCapacity *= 2; } return _lastCapacity; } // starts with (pos, 0, _next_block_position) so we're really // looking in blocks with indices from lo to (hi-1) inclusive final bbBlock findBlockHelper(int pos, int lo, int hi) { bbBlock block; int ii; if ((hi - lo) <= 3) { for (ii=lo; ii block._offset + block._limit) continue; if (block.containsForRead(pos)) { return block; } if (block._offset >= pos) break; } return this._blocks.get(ii - 1); // this will always be > 0 } int mid = (hi + lo) / 2; block = this._blocks.get(mid); assert block != null; if (block._offset > pos) { return findBlockHelper(pos, lo, mid); } return findBlockHelper(pos, mid, hi); } /** * find the block where this offset (newPosition) has already * been written. Typically the caller will set _curr to be the * returned block. * @param pos global position to be read from * @return curr block ready to be read from */ bbBlock findBlockForRead(Object caller, int version, bbBlock curr, int pos) { assert pos >= 0 && "buffer positions are never negative".length() > 0; if (pos > this._buf_limit) { throw new BlockedBufferException("invalid position"); } assert _validate(); if (curr != null) { if (curr.containsForRead(pos)) { return curr; } if (pos == this._buf_limit && (pos - curr._offset) == curr._limit) { return curr; } } boolean at_eof = (pos == this._buf_limit); if (at_eof) { // if this is the last block actually in use // and we're looking for the eof position then // we can check for the "last byte not quite // written yet" case, which is fine bbBlock block = this._blocks.get(this._next_block_position - 1); if (block.containsForWrite(pos)) return block; } else { bbBlock block = this.findBlockHelper(pos, 0, this._next_block_position); return block; } throw new BlockedBufferException("valid position can't be found!"); } /** * find the block where this offset (newPosition) should be written. * typicall the caller will set _curr to be the returned block. * @param pos global position to be written to * @return curr block ready to be written to */ bbBlock findBlockForWrite(Object caller, int version, bbBlock curr, int pos) { assert mutation_in_progress(caller, version); assert (pos >= 0 && "invalid position, positions must be >= 0".length() > 0); if (pos > this._buf_limit + 1) { throw new BlockedBufferException("writes must be contiguous"); } assert _validate(); if (curr != null && curr.hasRoomToWrite(pos, 1) == true) { if (curr._offset + curr._limit == pos && curr._idx < this._next_block_position) { bbBlock b = this._blocks.get(curr._idx + 1); if (b.containsForWrite(pos)) { curr = b; } } return curr; } // we're not going to write into curr, so find out the right block bbBlock block; if (pos == this._buf_limit) { // if we're at the limit the only possible (existing) block // will be the very last block - shortcut to optimize append assert this._next_block_position > 0; block = this._blocks.get(this._next_block_position - 1); } else if (curr != null && pos == curr._offset + curr._limit) { // if our current position is exactly at the end (and we already know // we can't write into this block if we can write at all we'll have // to write into the next block (inner blocks can't be 0 bytes long) block = this._blocks.get(curr._idx + 1); } else { // since we're not at the limit and we don't have a current block // we'll go find the block in the list (this is an abnormal case) // since append if usual for writing block = findBlockHelper(pos, 0, this._next_block_position); } assert block != null; assert block.containsForWrite(pos); // chech our candidate block to see if it's the one we'd write into if (block.hasRoomToWrite(pos, 1)) { return block; } // at this point, we can't use _curr in any event so we can just // move on to the next block since findHelper will have returned // either the right block (which it didn't) or the one just in // front of the right block - so let's see if there is an allocated // block just following this if (block._idx < this._next_block_position - 1) { block = this._blocks.get(block._idx + 1); return block; } // there wasn't a following block (actually a common case when // you're appending) so we have to go ahead an actually add a new block int newIdx = block._idx + 1; assert newIdx == this._next_block_position; bbBlock ret = this.addBlock(caller ,version ,newIdx ,pos ,this.nextBlockSize(caller, version) ); return ret; } /** * dispatcher for the various forms of insert we encounter * calls one of the four helpers depending on the case * that is needed to inser here * @param len number of bytes to make space for * @return int number of bytes inserted */ int insert(Object caller, int version, bbBlock curr, int pos, int len) { assert mutation_in_progress(caller, version); // DEBUG: int amountMoved = 0; // DEBUG: int before = this._buf_limit; // DEBUG: assert _validate(); // if there's room in the current block - just // move the "trailing" bytes down and we're done int neededSpace = len - curr.unusedBlockCapacity(); if (neededSpace <= 0) { // we have all the space we need in the current block // DEBUG: amountMoved = insertInCurrOnly(caller, version, curr, pos, len); } else { // we'll need at least some additional space beyond the curr // block, see if there's room in the // next one, otherwise we'll make more (blocks) bbBlock next = null; if (curr._idx < this._next_block_position - 1) { // if there is another block next = this._blocks.get(curr._idx + 1); } if (next != null && (neededSpace <= next.unusedBlockCapacity()) ) { // with the addition of the free space in the following block we have enough // DEBUG: amountMoved = insertInCurrAndNext(caller, version, curr, pos, len, next); } else { // we'll have to make one or more new blocks // first figure out much will be in the first // and last blocks (i.e. ignoring the whole // blocks int lenNeededInLastAddedBlock = neededSpace % _blockSizeUpperLimit; int tailLen = curr.bytesAvailableToRead(pos); if (lenNeededInLastAddedBlock < tailLen) lenNeededInLastAddedBlock = tailLen; if (lenNeededInLastAddedBlock < neededSpace && neededSpace < this._blockSizeUpperLimit) { // if we need less than the largest block then we should // make *one* block with all of the needed space lenNeededInLastAddedBlock = neededSpace; } bbBlock newblock = insertMakeNewTailBlock(caller, version, curr, lenNeededInLastAddedBlock); // now see if the curr block and this newblock have enough // available space to do the job, and if there's some trailing // data from curr that will end up staying in curr if (len <= (curr.unusedBlockCapacity() + newblock.unusedBlockCapacity()) ) { // insert this as a zero length block immediately after _curr // insertBlock also adjusts the trailing blocks idx values insertBlock(newblock); // now pretend we just have the "push into the next block" case // DEBUG: amountMoved = insertInCurrAndNext(caller, version, curr, pos, len, newblock); } else { // and last we have the case of having to insert more than 1 block // which means all of the trailing bytes in _curr move into the last // block // DEBUG: amountMoved = insertAsManyBlocksAsNeeded(caller, version, curr, pos, len, newblock); } } } // DEBUG: if (this._buf_limit - before != len // DEBUG: || amountMoved != len) { // DEBUG: throw new BlockedBufferException("insert went wrong #1 !!!"); // DEBUG: } assert _validate(); return len; } /** * this handles insert when there's enough room in the * current block */ private int insertInCurrOnly(Object caller, int version, bbBlock curr, int pos, int len) { assert mutation_in_progress(caller, version); // the space we need is available right in the block assert curr.unusedBlockCapacity() >= len; System.arraycopy(curr._buffer, curr.blockOffsetFromAbsolute(pos) ,curr._buffer, curr.blockOffsetFromAbsolute(pos) + len, curr.bytesAvailableToRead(pos)); curr._limit += len; this.adjustOffsets(curr._idx, len, 0); notifyInsert(pos, len); return len; } private int insertInCurrAndNext(Object caller, int version, bbBlock curr, int pos, int len, bbBlock next) { assert mutation_in_progress(caller, version); // DEBUG: int amountMoved = 0; // all the space we need (len) fits in these two blocks assert curr.unusedBlockCapacity() + next.unusedBlockCapacity() >= len; // and we need to use space in both of these blocks assert curr.unusedBlockCapacity() < len; int availableToRead = curr.bytesAvailableToRead(pos); int tailInCurr = availableToRead; int deltaOfNextData = len - curr.unusedBlockCapacity(); int tailCopiedToNext = deltaOfNextData; if (tailCopiedToNext > availableToRead) { tailCopiedToNext = availableToRead; } // first we copy the data in the next block down to make room // for data we're pushing off the end of the _curr block // if we need to, there may not be any data in the next block if (next._limit > 0) { System.arraycopy(next._buffer, 0, next._buffer, deltaOfNextData, next._limit); } next._limit += deltaOfNextData; // DEBUG: amountMoved += deltaOfNextData; // next we copy the data from the tail of _curr into the front of next // since we don't have room for it any longer in the _curr block // but it is possible that there is not tail at all (pos == limit) if (tailCopiedToNext > 0) { System.arraycopy(curr._buffer, curr._limit - tailCopiedToNext , next._buffer, deltaOfNextData - tailCopiedToNext, tailCopiedToNext); } // finally if there's any tail left in the _curr block we copy that // down to the end of the _curr block (if all of the tail moved into // the next block nothing happens here int leftInCurr = tailInCurr - tailCopiedToNext; if (leftInCurr > 0) { int blockPosition = curr.blockOffsetFromAbsolute(pos); System.arraycopy(curr._buffer, blockPosition ,curr._buffer, blockPosition + len, leftInCurr); } // finally if we reused from space in _curr (between _limit and the unreserved capacity) // we adjust for that as well as the space adjusted in the newblock int addedInCurr = curr.unusedBlockCapacity(); if (addedInCurr > 0) { curr._limit += addedInCurr; // DEBUG: amountMoved += addedInCurr; next._offset += addedInCurr; } assert (curr.blockOffsetFromAbsolute(pos) + tailCopiedToNext + addedInCurr + leftInCurr) == curr._limit; this.adjustOffsets(next._idx, len, 0); notifyInsert(pos, len); // DEBUG: if (amountMoved != len) { // DEBUG: throw new BlockedBufferException("insert went wrong #4 !!!"); // DEBUG: } return len; } private bbBlock insertMakeNewTailBlock(Object caller, int version, bbBlock curr, int minimumBlockSize) { assert mutation_in_progress(caller, version); // needed is the amount of data we'll put into the // final added block (which is actually added first) int newblocksize = minimumBlockSize; if (newblocksize < _blockSizeUpperLimit) { // if we don't need an oversize block then find a block // size that will be big enough while ((newblocksize = this.nextBlockSize(caller, version)) < minimumBlockSize) { // bump up requested block capacity until we get // at least enough to hold the request, or we // hit the max blocksize whichever comes first } } // allocate and initialize a new block that will be the // tail of our interesting blocks bbBlock newblock = new bbBlock(newblocksize); newblock._idx = curr._idx + 1; newblock._offset = curr._offset + curr._limit; // we'll adjust this later like any existing block return newblock; } private int insertAsManyBlocksAsNeeded(Object caller, int version, bbBlock curr, int pos, int len, bbBlock newLastBlock) { assert mutation_in_progress(caller, version); // DEBUG: int amountAllocated = 0; // DEBUG: int origPos = this._buf_position; // this is the case where the old tail is pushed entirely out of the // old block into a new trailing block and then as many whole new // blocks as needed (which maybe none) are inserted between these two bbBlock oldCurr = curr; int oldPosition = curr.blockOffsetFromAbsolute(pos); int oldBlockTail = curr._limit - oldPosition; int newSpaceInCurr = curr.unusedBlockCapacity(); // adjust the curr blocks limit curr._limit += newSpaceInCurr; // DEBUG: amountAllocated += newSpaceInCurr; int newoffset = curr._offset + curr._limit; int spaceNeededInMiddle = len - newSpaceInCurr - newLastBlock._buffer.length; int addedblocks = 0; bbBlock newblock = null; assert (spaceNeededInMiddle > 0); // this is the "as many as needed" case not "this and next" // add blocks until we're ready for the last block while (spaceNeededInMiddle > 0) { addedblocks++; newblock = new bbBlock(this.nextBlockSize(caller, version)); newblock._limit = newblock._buffer.length; if (newblock._limit > spaceNeededInMiddle) newblock._limit = spaceNeededInMiddle; // DEBUG: amountAllocated += newblock._limit; newblock._idx = curr._idx + addedblocks; newblock._offset = newoffset; this._blocks.add(newblock._idx, newblock); spaceNeededInMiddle -= newblock._limit; newoffset += newblock._limit; } // add the last block addedblocks++; newblock = newLastBlock; newblock._limit = newblock._buffer.length; // DEBUG: amountAllocated += newblock._limit; newblock._idx = curr._idx + addedblocks; newblock._offset = newoffset; this._blocks.add(newblock._idx, newblock); // DEBUG: assert (amountAllocated == len); // now adjust the trailing blocks adjustOffsets(newblock._idx, len, addedblocks); notifyInsert(pos, len); // now we copy the tail of the _curr block to the end of the space // note that this only works because the tail is being copied to // an altogether different block in the buffer, so it can't overlap if (oldBlockTail > 0) { System.arraycopy(oldCurr._buffer, oldPosition, newLastBlock._buffer, newLastBlock._limit - oldBlockTail, oldBlockTail); } // DEBUG: assert this.position() == origPos; // DEBUG: assert (amountAllocated == len); return len; } private void insertBlock(bbBlock newblock) { // in both cases we need to insert the new block after _curr // and adjust the idx values to go with that this._blocks.add(newblock._idx, newblock); _next_block_position++; for (int ii=newblock._idx + 1; ii < this._next_block_position; ii++) { this._blocks.get(ii)._idx++; } } private void adjustOffsets(int lastidx, int addedBytes, int addedBlocks) { bbBlock b; // now we adjust the trailing offsets if (addedBytes != 0 || addedBlocks != 0) { this._next_block_position += addedBlocks; for (int ii=lastidx + 1; ii < this._next_block_position; ii++) { b = this._blocks.get(ii); b._offset += addedBytes; b._idx += addedBlocks; } this._buf_limit += addedBytes; } } bbBlock remove(Object caller, int version, bbBlock curr, int pos, int len) { assert mutation_in_progress(caller, version); if (len == 0) return curr; if (len < 0 || (pos + len) > this._buf_limit) { throw new IllegalArgumentException(); } int amountToRemove = len; int removedBlocks = 0; int startingIdx = curr._idx; int currIdx = curr._idx; bbBlock currBlock = curr; assert (curr._offset <= pos); assert (pos - curr._offset <= curr._limit); assert _validate(); // this is to simply eliminate a big edge case if (pos == 0 && len == this._buf_limit) { this.clear(caller, version); notifyRemove(0, len); return null; } // remove from the initial block int currBlockPosition = currBlock.blockOffsetFromAbsolute(pos); int removedFromThisBlock = currBlock._limit - currBlockPosition; if (removedFromThisBlock > amountToRemove) removedFromThisBlock = amountToRemove; if (removedFromThisBlock == currBlock._limit) { // we'll be removing the whole block in the whole block loop below startingIdx--; // so we have to back up on to fix the next block that will // "fall" down into the soon to be emptied slot here } else { // we always copy into position, and we copy whatever is still // left in the end of the block int moveAmount = currBlock._limit - currBlockPosition - removedFromThisBlock; if (moveAmount > 0) { System.arraycopy(currBlock._buffer, currBlock._limit - moveAmount ,currBlock._buffer, currBlockPosition, moveAmount); } amountToRemove -= removedFromThisBlock; currBlock._limit -= removedFromThisBlock; if (amountToRemove > 0) { // when we're on the last block, there'll be nothing to remove, // and no block to get either currIdx = currBlock._idx + 1; currBlock = this._blocks.get(currIdx); } } while (amountToRemove > 0 && amountToRemove >= currBlock._limit) { amountToRemove -= currBlock._limit; // remove the whole block - so first hang onto a reference bbBlock temp = currBlock; this._blocks.remove(currIdx); removedBlocks++; temp.clearBlock(); this._blocks.add(temp); // dump it at the end (marked as not in use) // and we don't move currIdx because we bumped it out of the whole array if (currIdx < this._next_block_position - removedBlocks) { currBlock = this._blocks.get(currIdx); } else if (currIdx > 0) { currIdx--; currBlock = this._blocks.get(currIdx); } else { throw new BlockedBufferException("fatal - no current block!"); } } if (amountToRemove > 0) { assert amountToRemove < currBlock._limit; System.arraycopy(currBlock._buffer, amountToRemove ,currBlock._buffer, 0, currBlock._limit - amountToRemove); assert amountToRemove < currBlock._limit; currBlock._limit -= amountToRemove; currBlock._offset += amountToRemove; } // we'll even adjust the offset of the first block (if it's the last as well) adjustOffsets(startingIdx, -len, -removedBlocks); notifyRemove(pos, len); // DEBUG: int shouldBe = 0; // DEBUG: int is = currBlock._offset; // DEBUG: if (currBlock._idx > 0) { // DEBUG: shouldBe = this._blocks.get(currBlock._idx - 1)._offset + this._blocks.get(currBlock._idx - 1)._limit; // DEBUG: if (currIdx != startingIdx) assert (shouldBe == this._buf_position); // DEBUG: } // DEBUG: int delta = shouldBe - is; // DEBUG: assert(delta == 0); assert _validate(); return currBlock; } static int _validate_count; public boolean _validate() { int pos = 0; int idx; boolean err = false; _validate_count++; if ((_validate_count % 128) != 0) return true; // you can change the 0 below (in from of the -2) to be the validation counter // which reported the failure and the test will be true when _validate() is // called on the last GOOD check. if (_validate_count == 30 -2) { // used to set breakpoints on particular calls for validation err = (_validate_count < 0); } for (idx=0; idx b._buffer.length /* - b._reserved */ ) { System.out.println("block "+idx+": "+ "limit is out of range"+ ", it is "+b._limit+ " should be between 0 and "+ (b._buffer.length /* - b._reserved */)); err = true; } else if (b._limit == 0) { if ( ! (b._idx == (this._next_block_position - 1) && b._offset == this._buf_limit) ) { System.out.println("block "+idx+": "+ "has a ZERO limit"); err = true; } } pos += b._limit; } if (idx != this._next_block_position) { System.out.println("next block position is wrong, is "+this._next_block_position+" should be "+idx); err = true; } for (idx++; idx 0) { bbBlock last = this._blocks.get(this._next_block_position - 1); if (last._offset + last._limit != this._buf_limit){ System.out.println("last block "+last._idx+" limit isn't "+ "_buf_limit ("+this._buf_limit+"): "+ " calc'd last block limit is " + last._offset +" + "+ last._limit +" = "+(last._offset + last._limit) ); err = true; } } if (this._buf_limit < 0 || (this._buf_limit > 0 && this._next_block_position < 1)){ System.out.println("this._buf_limit "+ this._buf_limit+ " is invalid"); err = true; } if (err == true) { System.out.println("failed with validation count = " + _validate_count); } return err == false; // validate is true if all is ok so that assert _validate(); works as expected } final static class bbBlock { public int _idx; public int _offset; public int _limit; public byte[] _buffer; public bbBlock(int capacity) { _buffer = new byte[capacity]; } /** * Assumes ownership of an array to create a new block. The data * within the buffer is maintained. * * @param buffer contains the data for the block. * * @throws NullPointerException if buffer is null. */ bbBlock(byte[] buffer) { _buffer = buffer; _limit = buffer.length; } public bbBlock clearBlock() { _idx = -1; _offset = -1; _limit = 0; return this; } /** * maximimum number of bytes that can be held in this block. */ final int blockCapacity() { assert this._offset >= 0; return this._buffer.length ; } /** * maximimum number of bytes that can be appended in this block currently. */ final int unusedBlockCapacity() { assert this._offset >= 0; return this._buffer.length - this._limit; } /** * Gets the number of bytes between the current position and the * writable capacity of this block. * @param pos absolute position */ final int bytesAvailableToWrite(int pos) { assert this._offset >= 0; return this._buffer.length - (pos - _offset); } /** * Gets the number of, as yet, unused bytes in this block. That's the number * of bytes that can be inserted into this block without overflowing, or the * number of bytes between the current position and the end of the written bytes * in this block * @param pos absolute position */ public final int bytesAvailableToRead(int pos) { assert this._offset >= 0; return this._limit - (pos - _offset); } /** * is there space between position and capacity? * @param pos absolute position * @param needed * @return boolean */ final boolean hasRoomToWrite(int pos, int needed) { assert this._offset >= 0; return (needed <= (this._buffer.length - (pos - _offset))); } final boolean containsForRead(int pos) { assert this._offset >= 0; return (pos >= _offset && pos < _offset + _limit); } final boolean containsForWrite(int pos) { assert this._offset >= 0; return (pos >= _offset && pos <= _offset + _limit); } final int blockOffsetFromAbsolute(int pos) { assert this._offset >= 0; return pos - _offset; } } public interface Monitor { public boolean notifyInsert(int pos, int len); public boolean notifyRemove(int pos, int len); public int getMemberIdOffset(); } private final static class PositionMonitor implements Monitor { int _pos; PositionMonitor(int pos) { _pos = pos; } public int getMemberIdOffset() { return _pos; } public boolean notifyInsert(int pos, int len) { return false; } public boolean notifyRemove(int pos, int len) { return false; } } private final static class CompareMonitor implements Comparator { static CompareMonitor instance = new CompareMonitor(); private CompareMonitor() {} static CompareMonitor getComparator() { return instance; } public int compare(Monitor arg0, Monitor arg1) { return arg0.getMemberIdOffset() - arg1.getMemberIdOffset(); } } TreeSet _updatelist = new TreeSet(CompareMonitor.getComparator()); public void notifyRegister(Monitor item) { _updatelist.add(item); } public void notifyUnregister(Monitor item) { _updatelist.remove(item); } public void notifyInsert(int pos, int len) { if (len == 0) return; PositionMonitor pm = new PositionMonitor(pos); SortedSet follows = _updatelist.tailSet(pm); for (Monitor m : follows) { if (m.notifyInsert(pos, len)) { follows.remove(m); } } } public void notifyRemove(int pos, int len) { if (len == 0) return; PositionMonitor pm = new PositionMonitor(pos); SortedSet follows = _updatelist.tailSet(pm); for (Monitor m : follows) { if (m.notifyRemove(pos, len)) { follows.remove(m); } } } /** * Reads data from a byte buffer, keeps a local position and * a current block. Snaps a buffer length on creation; */ public static class BlockedByteInputStream extends java.io.InputStream { BlockedBuffer _buf; int _pos; int _mark; bbBlock _curr; int _blockPosition; int _version; /** * @param bb blocked buffer to read from */ public BlockedByteInputStream(BlockedBuffer bb) { this(0, bb); } /** * @param bb blocked buffer to read from * @param pos initial offset to read */ public BlockedByteInputStream(BlockedBuffer bb, int pos) { this(pos, bb); } /** * @param pos initial offset to read * @param end is the local limit, or -1 (_end_unspecified) * @param bb blocked buffer to read from */ private BlockedByteInputStream(int pos, BlockedBuffer bb) { if (bb == null) throw new IllegalArgumentException(); _version = bb.getVersion(); _buf = bb; _set_position(pos); _mark = -1; } @Override public final void mark(int readlimit) { this._mark = this._pos; } @Override public final void reset() throws IOException { if (this._mark == -1) throw new IOException("mark not set"); _set_position(this._mark); } /** * the current offset in the buffer */ public final int position() { return this._pos; } /** * this forces a version sync with the underlying blocked buffer. * The current position is lost during this call. * */ public final void sync() throws IOException { if (_buf == null) throw new IOException("stream is closed"); _version = _buf.getVersion(); _curr = null; _pos = 0; } /** * debug api to force check for internal validity of the * underlying buffer */ public final boolean _validate() { return this._buf._validate(); } /** * sets the position of the stream to be pos. The next operation * (such as read) will return the byte at that offset. * @param pos new offset to read from * @return this stream */ public final BlockedByteInputStream setPosition(int pos) throws IOException { if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (pos < 0 || pos > _buf.size()) { throw new IllegalArgumentException(); } // call our unfailing private method to do the real work _set_position(pos); fail_on_version_change(); return this; } private final void _set_position(int pos) { _pos = pos; _curr = _buf.findBlockForRead(this, _version, _curr, pos); _blockPosition = _pos - _curr._offset; } /** * closes the steam and clears its reference to the * byte buffer. Once closed it cannot be used. */ @Override public final void close() throws IOException { this._buf = null; this._pos = -1; } public final int writeTo(OutputStream out, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (_pos > _buf.size()) throw new IllegalArgumentException(); int startingPos = _pos; int localEnd = _pos + len; if (localEnd > _buf.size()) localEnd = _buf.size(); assert(_curr.blockOffsetFromAbsolute(_pos) == _blockPosition); while (_pos < localEnd) { int available = _curr._limit - _blockPosition; boolean partial_read = available > localEnd - _pos; if (partial_read) { available = localEnd - _pos; } out.write(_curr._buffer, _blockPosition, available); _pos += available; if (partial_read) { _blockPosition += available; break; } _curr = _buf.findBlockForRead(this, _version, _curr, _pos); _blockPosition =_curr.blockOffsetFromAbsolute(_pos); } fail_on_version_change(); return _pos - startingPos; } public final int writeTo(ByteWriter out, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (_pos > _buf.size()) throw new IllegalArgumentException(); int startingPos = _pos; int localEnd = _pos + len; if (localEnd > _buf.size()) localEnd = _buf.size(); assert(_curr.blockOffsetFromAbsolute(_pos) == _blockPosition); while (_pos < localEnd) { int available = _curr._limit - _blockPosition; boolean partial_read = available > localEnd - _pos; if (partial_read) { available = localEnd - _pos; } out.write(_curr._buffer, _blockPosition, available); _pos += available; if (partial_read) { _blockPosition += available; break; } _curr = _buf.findBlockForRead(this, _version, _curr, _pos); _blockPosition =_curr.blockOffsetFromAbsolute(_pos); } fail_on_version_change(); return _pos - startingPos; } /** * reads (up to) {@code len} bytes from the buffer and copies them into * the user supplied byte array (bytes) starting at offset * off in the users array. This returns the number of bytes * read, which may be less than the number requested if * there is not enough data available in the buffer. * * @throws IndexOutOfBoundsException * if {@code (dst.length - offset) < len} */ @Override public final int read(byte[] bytes, int offset, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (_pos > _buf.size()) throw new IllegalArgumentException(); int startingPos = _pos; int localEnd = _pos + len; if (localEnd > _buf.size()) localEnd = _buf.size(); while (_pos < localEnd) { bbBlock block = _curr; int block_offset = _blockPosition; int available = block._limit - _blockPosition; if (available > localEnd - _pos) { // we aren't emptying this block so adjust our location available = localEnd - _pos; _blockPosition += available; } else { // TODO can't we just move to the next block? _curr = _buf.findBlockForRead(this, _version, _curr, _pos + available); _blockPosition = 0; } System.arraycopy(block._buffer, block_offset, bytes, offset, available); _pos += available; offset += available; } fail_on_version_change(); return _pos - startingPos; } /** * reads the next byte in the buffer. This returns -1 * if there is no data available to be read. */ @Override public final int read() throws IOException { if (_buf == null) { throw new IOException("input stream is closed"); } fail_on_version_change(); if (_pos >= _buf.size()) return -1; if (_blockPosition >= _curr._limit) { _curr = this._buf.findBlockForRead(this, _version, _curr, _pos); _blockPosition = 0; } int nextByte = (0xff & _curr._buffer[_blockPosition]); _blockPosition++; _pos++; fail_on_version_change(); return nextByte; } private final void fail_on_version_change() throws IOException { if (_buf.getVersion() != _version) { this.close(); throw new BlockedBufferException("buffer has been changed!"); } } @Override public final long skip(long n) throws IOException { if (n < 0 || n > _Private_IonConstants.ARRAY_MAXIMUM_SIZE) throw new IllegalArgumentException("we only handle buffer less than "+_Private_IonConstants.ARRAY_MAXIMUM_SIZE+" bytes in length"); if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (_pos >= _buf.size()) return -1; int len = (int)n; if (len == 0) return 0; int startingPos = _pos; int localEnd = _pos + len; if (localEnd > _buf.size()) localEnd = _buf.size(); // if we run off the end of this block, we need to update // our current block ( _curr ) we'll update the block position // in any event (once we know the right block, of course) if (localEnd > _blockPosition + _curr._offset) { _curr = _buf.findBlockForRead(this, _version, _curr, localEnd); } _blockPosition = localEnd - _curr._offset; _pos = localEnd; fail_on_version_change(); return _pos - startingPos; } } /** * Reads data from a byte buffer, keeps a local position and * a current block. Snaps a buffer length on creation; */ public static class BlockedByteOutputStream extends java.io.OutputStream { BlockedBuffer _buf; int _pos; bbBlock _curr; int _blockPosition; int _version; /** * creates writable stream (OutputStream) that writes * to a fresh blocked buffer. The stream is initially * position at offset 0. */ public BlockedByteOutputStream() { _buf = new BlockedBuffer(); _version = _buf.getVersion(); _set_position(0); } /** * creates writable stream (OutputStream) that writes * to the supplied byte buffer. The stream is initially * position at offset 0. * @param bb blocked buffer to write to */ public BlockedByteOutputStream(BlockedBuffer bb) { _buf = bb; _version = _buf.getVersion(); _set_position(0); } /** * creates writable stream (OutputStream) that can write * to the supplied byte buffer. The stream is initially * position at offset off. * @param bb blocked buffer to write to * @param off initial offset to write to */ public BlockedByteOutputStream(BlockedBuffer bb, int off) { if (bb == null || off < 0 || off > bb.size() ) { throw new IllegalArgumentException(); } _buf = bb; _version = _buf.getVersion(); _set_position(0); } /** * the current offset in the buffer */ public final int position() { return this._pos; } /** * this forces a version sync with the underlying blocked buffer. * The current position is lost during this call. * */ public final void sync() throws IOException { if (_buf == null) throw new IOException("stream is closed"); _version = _buf.getVersion(); _pos = 0; _curr = null; } /** * debug api to force check for internal validity of the * underlying buffer */ public final boolean _validate() { return this._buf._validate(); } /** * repositions this stream in the buffer. The next * read, write, or insert operation will take place * at the specified position. The position must * be within the contiguous range of written bytes, * including the pseudo end of file character just * past the end, which can be written on and returns * -1 if read. */ public final BlockedByteOutputStream setPosition(int pos) throws IOException { if (_buf == null) throw new IOException("stream is closed"); fail_on_version_change(); if (pos < 0 || pos > _buf.size()) { throw new IllegalArgumentException(); } this._set_position(pos); fail_on_version_change(); return this; } private final void _set_position(int pos) { _pos = pos; _curr = _buf.findBlockForRead(this, _version, _curr, pos); _blockPosition = _pos - _curr._offset; return; } /** * closes the steam and clears its reference to the * byte buffer. Once closed it cannot be used. */ @Override public final void close() throws IOException { this._buf = null; this._pos = -1; return; } /** * Inserts space and writes 1 byte to the current * position in this output stream. Only the low * order byte of the passed in int is written the * high order bits are ignored. */ @Override public final void write(int b) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _write(b); _version = _buf.end_mutate(this); return; } final void start_write() { _buf.start_mutate(this, _version); } final void end_write() { _version = _buf.end_mutate(this); } final void _write(int b) throws IOException { if (bytesAvailableToWriteInCurr(_pos) < 1) { _curr = _buf.findBlockForWrite(this, _version, _curr, _pos); assert _curr._offset == _pos; _blockPosition = 0; } _curr._buffer[_blockPosition++] = (byte)(b & 0xff); _pos++; if (_blockPosition > _curr._limit) { _curr._limit = _blockPosition; if (_pos > _buf._buf_limit ) _buf._buf_limit = _pos; } } private final int bytesAvailableToWriteInCurr(int pos) { assert _curr != null; assert _curr._offset <= pos; assert _curr._offset + _curr._limit >= pos; if (_curr._idx < this._buf._next_block_position - 1) { return _curr.bytesAvailableToRead(pos); } int ret = _curr._buffer.length - (pos - _curr._offset); return ret; // _curr.bytesAvailableToWrite(pos); } /** * Writes len bytes from the specified byte array starting * at in the user array at offset off to the current position * in this output stream. */ @Override public final void write(byte[] b, int off, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _write(b, off, len); _version = _buf.end_mutate(this); } private final void _write(byte[] b, int off, int len) { int end_b = off + len; while (off < end_b) { int writeInThisBlock = bytesAvailableToWriteInCurr(_pos); if (writeInThisBlock > end_b - off) { writeInThisBlock = end_b - off; } assert writeInThisBlock >= 0; if (writeInThisBlock > 0) { System.arraycopy(b, off, _curr._buffer, _blockPosition, writeInThisBlock); off += writeInThisBlock; _pos += writeInThisBlock; _blockPosition += writeInThisBlock; if (_blockPosition > _curr._limit) { _curr._limit = _blockPosition; if (_pos > _buf._buf_limit) _buf._buf_limit = _pos; } else { assert _pos <= _buf._buf_limit; } } if (off >= end_b) break; _curr = _buf.findBlockForWrite(this, _version, _curr, _pos); _blockPosition = _curr.blockOffsetFromAbsolute(_pos); assert _curr._offset == _pos || off >= end_b; } } /** * Writes bytes from the specified byte stream from its current * stream position to the end of the stream. Writing the bytes * to the current position in this output stream. * @throws IOException */ public final void write(InputStream bytestream) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _write(bytestream, -1); _version = _buf.end_mutate(this); } /** * Writes bytes from the specified byte stream from its current * stream position up to length bytes from the stream. Writing the * bytes to the current position in this output stream. * @throws IOException */ public final void write(InputStream bytestream, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _write(bytestream, len); _version = _buf.end_mutate(this); } /** * helper to write data. This does not check input arguments. * @param bytestream source of the data * @param len number of bytes to read from the input stream, -1 for all * @throws IOException */ private final void _write(InputStream bytestream, int len) throws IOException { if (len == 0) return; int written = 0; boolean read_all = (len == -1); for (;;) { int writeInThisBlock = bytesAvailableToWriteInCurr(_pos); assert writeInThisBlock >= 0; int to_read = read_all ? writeInThisBlock : len; if (to_read > writeInThisBlock) { to_read = writeInThisBlock; } int len_read = bytestream.read(_curr._buffer, _blockPosition, to_read); if (len_read == -1) break; if (len_read > 0) { _pos += len_read; _blockPosition += len_read; if (_blockPosition > _curr._limit) { _curr._limit = _blockPosition; if (_pos > _buf._buf_limit) _buf._buf_limit = _pos; } else { assert _pos <= _buf._buf_limit; } } if (len_read == writeInThisBlock) { _curr = _buf.findBlockForWrite(this, _version, _curr, _pos); _blockPosition = _curr.blockOffsetFromAbsolute(_pos); assert _curr._offset == _pos || written < len_read; } else { assert len_read < writeInThisBlock; } if (!read_all) { len -= len_read; if (len < 1) break; } } } /** * Inserts the amount space requested at the current * position in this output stream. No data is written * into the output stream. */ public final void insert(int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); if (len < 0) { throw new IllegalArgumentException(); } if (len > 0) { _buf.start_mutate(this, _version); _buf.insert(this, _version, _curr, _pos, len); _version = _buf.end_mutate(this); } return; } /** * Inserts space and writes 1 byte to the current * position in this output stream. Only the low * order byte of the passed in int is written the * high order bits are ignored. */ public final void insert(byte b) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _buf.insert(this, _version, _curr, _pos, 1); _write(b); _version = _buf.end_mutate(this); } /** * Inserts space and writes len bytes from the specified * byte array starting at in the user array at offset off * to the current position in this output stream. */ public final void insert(byte[] b, int off, int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _buf.insert(this, _version, _curr, _pos, len); _write(b, off, len); _version = _buf.end_mutate(this); } /** * Inserts space and writes len bytes from the specified * byte array starting at in the user array at offset off * to the current position in this output stream. */ public final void remove(int len) throws IOException { if (_buf == null) throw new IOException("stream is closed"); _buf.start_mutate(this, _version); _curr = _buf.remove(this, _version, _curr, _pos, len); _version = _buf.end_mutate(this); } /** * trucates the buffer at the current location after this * call the last previously written or read byte will be * the end of the buffer. */ public final void truncate() throws IOException { if (_buf == null) throw new IOException("stream is closed"); if (this._buf._buf_limit == _pos) return; _buf.start_mutate(this, _version); _curr = _buf.truncate(this, _version, _pos); _version = _buf.end_mutate(this); } private final void fail_on_version_change() throws IOException { if (_buf.getVersion() != _version) { this.close(); throw new BlockedBufferException("buffer has been changed!"); } } } public static class BlockedBufferException extends IonException { private static final long serialVersionUID = 1582507845614969389L; public BlockedBufferException() { super(); } public BlockedBufferException(String message) { super(message); } public BlockedBufferException(String message, Throwable cause) { super(message, cause); } public BlockedBufferException(Throwable cause) { super(cause); } } public static class BufferedOutputStream extends OutputStream { BlockedBuffer _buffer; BlockedByteOutputStream _writer; public BufferedOutputStream() { this(new BlockedBuffer()); } public BufferedOutputStream(BlockedBuffer buffer) { _buffer = buffer; _writer = new BlockedByteOutputStream(_buffer); } /** * Gets the size in bytes of this binary data. * This is generally needed before calling {@link #getBytes()} or * {@link #getBytes(byte[], int, int)}. * * @return the size in bytes. */ public int byteSize() { return _buffer.size(); } /** * Copies the current contents of this writer as a new byte array holding * Ion binary-encoded data. * This allocates an array of the size needed to exactly * hold the output and copies the entire value to it. * * @return the byte array with the writers output * @throws IOException */ public byte[] getBytes() throws IOException { int size = byteSize(); ByteArrayOutputStream byteStream = new ByteArrayOutputStream(size); writeBytes(byteStream); byte[] bytes = byteStream.toByteArray(); return bytes; } /** * Copies the current contents of the writer to a given byte array * array. This starts writing to the array at offset and writes * up to len bytes. * If this writer is not able to stop in the middle of its * work this may overwrite the array and later throw and exception. * * @param bytes users byte array to write into * @param offset initial offset in the array to write into * @param len maximum number of bytes to write from offset on * @return number of bytes written * @throws IOException */ public int getBytes(byte[] bytes, int offset, int len) throws IOException { SimpleByteBuffer outbuf = new SimpleByteBuffer(bytes, offset, len); OutputStream writer = (OutputStream)outbuf.getWriter(); int written = writeBytes(writer); return written; } /** * Writes the current contents of the writer to the output * stream. This is only valid if the writer is not in the * middle of writing a container. * * @param userstream OutputStream to write the bytes to * @return int length of bytes written * @throws IOException */ public int writeBytes(OutputStream userstream) throws IOException { int limit = _buffer.size(); int pos = 0; int version = _buffer.getVersion(); bbBlock curr = null; _buffer.start_mutate(this, version); while (pos < limit) { curr = _buffer.findBlockForRead(this, version, curr, pos); if (curr == null) { throw new IOException("buffer missing expected bytes"); } int len = curr.bytesAvailableToRead(pos); if (len <= 0) { throw new IOException("buffer missing expected bytes"); } userstream.write(curr._buffer, 0, len); pos += len; } _buffer.end_mutate(this); return pos; } @Override public void write(int b) throws IOException { _writer.write(b); } @Override public void write(byte[] bytes) throws IOException { write(bytes, 0, bytes.length); } @Override public void write(byte[] bytes, int off, int len) throws IOException { _writer.write(bytes, off, len); } } }





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