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/*
 * Copyright 2014 The Netty Project
 *
 * The Netty Project licenses this file to you under the Apache License,
 * version 2.0 (the "License"); you may not use this file except in compliance
 * with the License. You may obtain a copy of the License at:
 *
 *   http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License 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 io.netty.handler.codec.compression;

import io.netty.buffer.ByteBuf;
import io.netty.channel.ChannelHandlerContext;
import io.netty.handler.codec.ByteToMessageDecoder;

import java.util.List;

import static io.netty.handler.codec.compression.Bzip2Constants.*;

/**
 * Uncompresses a {@link ByteBuf} encoded with the Bzip2 format.
 *
 * See Bzip2.
 */
public class Bzip2Decoder extends ByteToMessageDecoder {
    /**
     * Current state of stream.
     */
    private enum State {
        INIT,
        INIT_BLOCK,
        INIT_BLOCK_PARAMS,
        RECEIVE_HUFFMAN_USED_MAP,
        RECEIVE_HUFFMAN_USED_BITMAPS,
        RECEIVE_SELECTORS_NUMBER,
        RECEIVE_SELECTORS,
        RECEIVE_HUFFMAN_LENGTH,
        DECODE_HUFFMAN_DATA,
        EOF
    }
    private State currentState = State.INIT;

    /**
     * A reader that provides bit-level reads.
     */
    private final Bzip2BitReader reader = new Bzip2BitReader();

    /**
     * The decompressor for the current block.
     */
    private Bzip2BlockDecompressor blockDecompressor;

    /**
     * Bzip2 Huffman coding stage.
     */
    private Bzip2HuffmanStageDecoder huffmanStageDecoder;

    /**
     * Always: in the range 0 .. 9. The current block size is 100000 * this number.
     */
    private int blockSize;

    /**
     * The CRC of the current block as read from the block header.
     */
    private int blockCRC;

    /**
     * The merged CRC of all blocks decompressed so far.
     */
    private int streamCRC;

    @Override
    protected void decode(ChannelHandlerContext ctx, ByteBuf in, List out) throws Exception {
        if (!in.isReadable()) {
            return;
        }

        final Bzip2BitReader reader = this.reader;
        reader.setByteBuf(in);

        for (;;) {
            switch (currentState) {
            case INIT:
                if (in.readableBytes() < 4) {
                    return;
                }
                int magicNumber = in.readUnsignedMedium();
                if (magicNumber != MAGIC_NUMBER) {
                    throw new DecompressionException("Unexpected stream identifier contents. Mismatched bzip2 " +
                            "protocol version?");
                }
                int blockSize = in.readByte() - '0';
                if (blockSize < MIN_BLOCK_SIZE || blockSize > MAX_BLOCK_SIZE) {
                    throw new DecompressionException("block size is invalid");
                }
                this.blockSize = blockSize * BASE_BLOCK_SIZE;

                streamCRC = 0;
                currentState = State.INIT_BLOCK;
            case INIT_BLOCK:
                if (!reader.hasReadableBytes(10)) {
                    return;
                }
                // Get the block magic bytes.
                final int magic1 = reader.readBits(24);
                final int magic2 = reader.readBits(24);
                if (magic1 == END_OF_STREAM_MAGIC_1 && magic2 == END_OF_STREAM_MAGIC_2) {
                    // End of stream was reached. Check the combined CRC.
                    final int storedCombinedCRC = reader.readInt();
                    if (storedCombinedCRC != streamCRC) {
                        throw new DecompressionException("stream CRC error");
                    }
                    currentState = State.EOF;
                    break;
                }
                if (magic1 != BLOCK_HEADER_MAGIC_1 || magic2 != BLOCK_HEADER_MAGIC_2) {
                    throw new DecompressionException("bad block header");
                }
                blockCRC = reader.readInt();
                currentState = State.INIT_BLOCK_PARAMS;
            case INIT_BLOCK_PARAMS:
                if (!reader.hasReadableBits(25)) {
                    return;
                }
                final boolean blockRandomised = reader.readBoolean();
                final int bwtStartPointer = reader.readBits(24);

                blockDecompressor = new Bzip2BlockDecompressor(this.blockSize, blockCRC,
                                                                blockRandomised, bwtStartPointer, reader);
                currentState = State.RECEIVE_HUFFMAN_USED_MAP;
            case RECEIVE_HUFFMAN_USED_MAP:
                if (!reader.hasReadableBits(16)) {
                    return;
                }
                blockDecompressor.huffmanInUse16 = reader.readBits(16);
                currentState = State.RECEIVE_HUFFMAN_USED_BITMAPS;
            case RECEIVE_HUFFMAN_USED_BITMAPS:
                Bzip2BlockDecompressor blockDecompressor = this.blockDecompressor;
                final int inUse16 = blockDecompressor.huffmanInUse16;
                final int bitNumber = Integer.bitCount(inUse16);
                final byte[] huffmanSymbolMap = blockDecompressor.huffmanSymbolMap;

                if (!reader.hasReadableBits(bitNumber * HUFFMAN_SYMBOL_RANGE_SIZE + 3)) {
                    return;
                }

                int huffmanSymbolCount = 0;
                if (bitNumber > 0) {
                    for (int i = 0; i < 16; i++) {
                        if ((inUse16 & 1 << 15 >>> i) != 0) {
                            for (int j = 0, k = i << 4; j < HUFFMAN_SYMBOL_RANGE_SIZE; j++, k++) {
                                if (reader.readBoolean()) {
                                    huffmanSymbolMap[huffmanSymbolCount++] = (byte) k;
                                }
                            }
                        }
                    }
                }
                blockDecompressor.huffmanEndOfBlockSymbol = huffmanSymbolCount + 1;

                int totalTables = reader.readBits(3);
                if (totalTables < HUFFMAN_MINIMUM_TABLES || totalTables > HUFFMAN_MAXIMUM_TABLES) {
                    throw new DecompressionException("incorrect huffman groups number");
                }
                int alphaSize = huffmanSymbolCount + 2;
                if (alphaSize > HUFFMAN_MAX_ALPHABET_SIZE) {
                    throw new DecompressionException("incorrect alphabet size");
                }
                huffmanStageDecoder = new Bzip2HuffmanStageDecoder(reader, totalTables, alphaSize);
                currentState = State.RECEIVE_SELECTORS_NUMBER;
            case RECEIVE_SELECTORS_NUMBER:
                if (!reader.hasReadableBits(15)) {
                    return;
                }
                int totalSelectors = reader.readBits(15);
                if (totalSelectors < 1 || totalSelectors > MAX_SELECTORS) {
                    throw new DecompressionException("incorrect selectors number");
                }
                huffmanStageDecoder.selectors = new byte[totalSelectors];

                currentState = State.RECEIVE_SELECTORS;
            case RECEIVE_SELECTORS:
                Bzip2HuffmanStageDecoder huffmanStageDecoder = this.huffmanStageDecoder;
                byte[] selectors = huffmanStageDecoder.selectors;
                totalSelectors = selectors.length;
                final Bzip2MoveToFrontTable tableMtf = huffmanStageDecoder.tableMTF;

                int currSelector;
                // Get zero-terminated bit runs (0..62) of MTF'ed Huffman table. length = 1..6
                for (currSelector = huffmanStageDecoder.currentSelector;
                            currSelector < totalSelectors; currSelector++) {
                    if (!reader.hasReadableBits(HUFFMAN_SELECTOR_LIST_MAX_LENGTH)) {
                        // Save state if end of current ByteBuf was reached
                        huffmanStageDecoder.currentSelector = currSelector;
                        return;
                    }
                    int index = 0;
                    while (reader.readBoolean()) {
                        index++;
                    }
                    selectors[currSelector] = tableMtf.indexToFront(index);
                }

                currentState = State.RECEIVE_HUFFMAN_LENGTH;
            case RECEIVE_HUFFMAN_LENGTH:
                huffmanStageDecoder = this.huffmanStageDecoder;
                totalTables = huffmanStageDecoder.totalTables;
                final byte[][] codeLength = huffmanStageDecoder.tableCodeLengths;
                alphaSize = huffmanStageDecoder.alphabetSize;

                /* Now the coding tables */
                int currGroup;
                int currLength = huffmanStageDecoder.currentLength;
                int currAlpha = 0;
                boolean modifyLength = huffmanStageDecoder.modifyLength;
                boolean saveStateAndReturn = false;
                loop: for (currGroup = huffmanStageDecoder.currentGroup; currGroup < totalTables; currGroup++) {
                    // start_huffman_length
                    if (!reader.hasReadableBits(5)) {
                        saveStateAndReturn = true;
                        break;
                    }
                    if (currLength < 0) {
                        currLength = reader.readBits(5);
                    }
                    for (currAlpha = huffmanStageDecoder.currentAlpha; currAlpha < alphaSize; currAlpha++) {
                        // delta_bit_length: 1..40
                        if (!reader.isReadable()) {
                            saveStateAndReturn = true;
                            break loop;
                        }
                        while (modifyLength || reader.readBoolean()) {  // 0=>next symbol; 1=>alter length
                            if (!reader.isReadable()) {
                                modifyLength = true;
                                saveStateAndReturn = true;
                                break loop;
                            }
                            // 1=>decrement length;  0=>increment length
                            currLength += reader.readBoolean() ? -1 : 1;
                            modifyLength = false;
                            if (!reader.isReadable()) {
                                saveStateAndReturn = true;
                                break loop;
                            }
                        }
                        codeLength[currGroup][currAlpha] = (byte) currLength;
                    }
                    currLength = -1;
                    currAlpha = huffmanStageDecoder.currentAlpha = 0;
                    modifyLength = false;
                }
                if (saveStateAndReturn) {
                    // Save state if end of current ByteBuf was reached
                    huffmanStageDecoder.currentGroup = currGroup;
                    huffmanStageDecoder.currentLength = currLength;
                    huffmanStageDecoder.currentAlpha = currAlpha;
                    huffmanStageDecoder.modifyLength = modifyLength;
                    return;
                }

                // Finally create the Huffman tables
                huffmanStageDecoder.createHuffmanDecodingTables();
                currentState = State.DECODE_HUFFMAN_DATA;
            case DECODE_HUFFMAN_DATA:
                blockDecompressor = this.blockDecompressor;
                final int oldReaderIndex = in.readerIndex();
                final boolean decoded = blockDecompressor.decodeHuffmanData(this.huffmanStageDecoder);
                if (!decoded) {
                    return;
                }
                // It used to avoid "Bzip2Decoder.decode() did not read anything but decoded a message" exception.
                // Because previous operation may read only a few bits from Bzip2BitReader.bitBuffer and
                // don't read incomming ByteBuf.
                if (in.readerIndex() == oldReaderIndex && in.isReadable()) {
                    reader.refill();
                }

                final int blockLength = blockDecompressor.blockLength();
                final ByteBuf uncompressed = ctx.alloc().buffer(blockLength);
                boolean success = false;
                try {
                    int uncByte;
                    while ((uncByte = blockDecompressor.read()) >= 0) {
                        uncompressed.writeByte(uncByte);
                    }

                    int currentBlockCRC = blockDecompressor.checkCRC();
                    streamCRC = (streamCRC << 1 | streamCRC >>> 31) ^ currentBlockCRC;

                    out.add(uncompressed);
                    success = true;
                } finally {
                    if (!success) {
                        uncompressed.release();
                    }
                }
                currentState = State.INIT_BLOCK;
                break;
            case EOF:
                in.skipBytes(in.readableBytes());
                return;
            default:
                throw new IllegalStateException();
            }
        }
    }

    /**
     * Returns {@code true} if and only if the end of the compressed stream
     * has been reached.
     */
    public boolean isClosed() {
        return currentState == State.EOF;
    }
}
    

    

    
            
    
            







    
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