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/**
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF 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 org.apache.avro.io;

import java.io.EOFException;
import java.io.IOException;
import java.io.InputStream;
import java.nio.ByteBuffer;

import org.apache.avro.AvroRuntimeException;
import org.apache.avro.util.Utf8;

/** An {@link Decoder} for binary-format data.
 * 

* Instances are created using {@link DecoderFactory}. *

* This class may read-ahead and buffer bytes from the source beyond what is * required to serve its read methods. * The number of unused bytes in the buffer can be accessed by * inputStream().remaining(), if the BinaryDecoder is not 'direct'. * * @see Encoder */ public class BinaryDecoder extends Decoder { private ByteSource source = null; // we keep the buffer and its state variables in this class and not in a // container class for performance reasons. This improves performance // over a container object by about 5% to 15% // for example, we could have a FastBuffer class with these state variables // and keep a private FastBuffer member here. This simplifies the // "detach source" code and source access to the buffer, but // hurts performance. private byte[] buf = null; private int minPos = 0; private int pos = 0; private int limit = 0; byte[] getBuf() { return buf; } int getPos() { return pos; } int getLimit() { return limit; } void setBuf(byte[] buf, int pos, int len) { this.buf = buf; this.pos = pos; this.limit = pos+len; } void clearBuf() { this.buf = null; } /** protected constructor for child classes */ protected BinaryDecoder() { } BinaryDecoder(InputStream in, int bufferSize) { super(); configure(in, bufferSize); } BinaryDecoder(byte[] data, int offset, int length) { super(); configure(data, offset, length); } BinaryDecoder configure(InputStream in, int bufferSize) { configureSource(bufferSize, new InputStreamByteSource(in)); return this; } BinaryDecoder configure(byte[] data, int offset, int length) { configureSource(DecoderFactory.DEFAULT_BUFFER_SIZE, new ByteArrayByteSource( data, offset, length)); return this; } /** * Initializes this decoder with a new ByteSource. Detaches the old source (if * it exists) from this Decoder. The old source's state no longer depends on * this Decoder and its InputStream interface will continue to drain the * remaining buffer and source data. *

* The decoder will read from the new source. The source will generally * replace the buffer with its own. If the source allocates a new buffer, it * will create it with size bufferSize. */ private void configureSource(int bufferSize, ByteSource source) { if (null != this.source) { this.source.detach(); } source.attach(bufferSize, this); this.source = source; } @Override public void readNull() throws IOException { } @Override public boolean readBoolean() throws IOException { // inlined, shorter version of ensureBounds if (limit == pos) { limit = source.tryReadRaw(buf, 0, buf.length); pos = 0; if (limit == 0) { throw new EOFException(); } } int n = buf[pos++] & 0xff; return n == 1; } @Override public int readInt() throws IOException { ensureBounds(5); // won't throw index out of bounds int len = 1; int b = buf[pos] & 0xff; int n = b & 0x7f; if (b > 0x7f) { b = buf[pos + len++] & 0xff; n ^= (b & 0x7f) << 7; if (b > 0x7f) { b = buf[pos + len++] & 0xff; n ^= (b & 0x7f) << 14; if (b > 0x7f) { b = buf[pos + len++] & 0xff; n ^= (b & 0x7f) << 21; if (b > 0x7f) { b = buf[pos + len++] & 0xff; n ^= (b & 0x7f) << 28; if (b > 0x7f) { throw new IOException("Invalid int encoding"); } } } } } pos += len; if (pos > limit) { throw new EOFException(); } return (n >>> 1) ^ -(n & 1); // back to two's-complement } @Override public long readLong() throws IOException { ensureBounds(10); int b = buf[pos++] & 0xff; int n = b & 0x7f; long l; if (b > 0x7f) { b = buf[pos++] & 0xff; n ^= (b & 0x7f) << 7; if (b > 0x7f) { b = buf[pos++] & 0xff; n ^= (b & 0x7f) << 14; if (b > 0x7f) { b = buf[pos++] & 0xff; n ^= (b & 0x7f) << 21; if (b > 0x7f) { // only the low 28 bits can be set, so this won't carry // the sign bit to the long l = innerLongDecode((long)n); } else { l = n; } } else { l = n; } } else { l = n; } } else { l = n; } if (pos > limit) { throw new EOFException(); } return (l >>> 1) ^ -(l & 1); // back to two's-complement } // splitting readLong up makes it faster because of the JVM does more // optimizations on small methods private long innerLongDecode(long l) throws IOException { int len = 1; int b = buf[pos] & 0xff; l ^= (b & 0x7fL) << 28; if (b > 0x7f) { b = buf[pos + len++] & 0xff; l ^= (b & 0x7fL) << 35; if (b > 0x7f) { b = buf[pos + len++] & 0xff; l ^= (b & 0x7fL) << 42; if (b > 0x7f) { b = buf[pos + len++] & 0xff; l ^= (b & 0x7fL) << 49; if (b > 0x7f) { b = buf[pos + len++] & 0xff; l ^= (b & 0x7fL) << 56; if (b > 0x7f) { b = buf[pos + len++] & 0xff; l ^= (b & 0x7fL) << 63; if (b > 0x7f) { throw new IOException("Invalid long encoding"); } } } } } } pos += len; return l; } @Override public float readFloat() throws IOException { ensureBounds(4); int len = 1; int n = (buf[pos] & 0xff) | ((buf[pos + len++] & 0xff) << 8) | ((buf[pos + len++] & 0xff) << 16) | ((buf[pos + len++] & 0xff) << 24); if ((pos + 4) > limit) { throw new EOFException(); } pos += 4; return Float.intBitsToFloat(n); } @Override public double readDouble() throws IOException { ensureBounds(8); int len = 1; int n1 = (buf[pos] & 0xff) | ((buf[pos + len++] & 0xff) << 8) | ((buf[pos + len++] & 0xff) << 16) | ((buf[pos + len++] & 0xff) << 24); int n2 = (buf[pos + len++] & 0xff) | ((buf[pos + len++] & 0xff) << 8) | ((buf[pos + len++] & 0xff) << 16) | ((buf[pos + len++] & 0xff) << 24); if ((pos + 8) > limit) { throw new EOFException(); } pos += 8; return Double.longBitsToDouble((((long) n1) & 0xffffffffL) | (((long) n2) << 32)); } @Override public Utf8 readString(Utf8 old) throws IOException { int length = readInt(); Utf8 result = (old != null ? old : new Utf8()); result.setByteLength(length); if (0 != length) { doReadBytes(result.getBytes(), 0, length); } return result; } private final Utf8 scratchUtf8 = new Utf8(); @Override public String readString() throws IOException { return readString(scratchUtf8).toString(); } @Override public void skipString() throws IOException { doSkipBytes(readInt()); } @Override public ByteBuffer readBytes(ByteBuffer old) throws IOException { int length = readInt(); ByteBuffer result; if (old != null && length <= old.capacity()) { result = old; result.clear(); } else { result = ByteBuffer.allocate(length); } doReadBytes(result.array(), result.position(), length); result.limit(length); return result; } @Override public void skipBytes() throws IOException { doSkipBytes(readInt()); } @Override public void readFixed(byte[] bytes, int start, int length) throws IOException { doReadBytes(bytes, start, length); } @Override public void skipFixed(int length) throws IOException { doSkipBytes(length); } @Override public int readEnum() throws IOException { return readInt(); } protected void doSkipBytes(long length) throws IOException { int remaining = limit - pos; if (length <= remaining) { pos += length; } else { limit = pos = 0; length -= remaining; source.skipSourceBytes(length); } } /** * Reads length bytes into bytes starting at start. * * @throws EOFException * If there are not enough number of bytes in the source. * @throws IOException */ protected void doReadBytes(byte[] bytes, int start, int length) throws IOException { if (length < 0) throw new AvroRuntimeException("Malformed data. Length is negative: " + length); int remaining = limit - pos; if (length <= remaining) { System.arraycopy(buf, pos, bytes, start, length); pos += length; } else { // read the rest of the buffer System.arraycopy(buf, pos, bytes, start, remaining); start += remaining; length -= remaining; pos = limit; // finish from the byte source source.readRaw(bytes, start, length); } } /** * Returns the number of items to follow in the current array or map. Returns * 0 if there are no more items in the current array and the array/map has * ended. * * @throws IOException */ protected long doReadItemCount() throws IOException { long result = readLong(); if (result < 0) { readLong(); // Consume byte-count if present result = -result; } return result; } /** * Reads the count of items in the current array or map and skip those items, * if possible. If it could skip the items, keep repeating until there are no * more items left in the array or map. If items cannot be skipped (because * byte count to skip is not found in the stream) return the count of the * items found. The client needs to skip the items individually. * * @return Zero if there are no more items to skip and end of array/map is * reached. Positive number if some items are found that cannot be * skipped and the client needs to skip them individually. * @throws IOException */ private long doSkipItems() throws IOException { long result = readInt(); while (result < 0) { long bytecount = readLong(); doSkipBytes(bytecount); result = readInt(); } return result; } @Override public long readArrayStart() throws IOException { return doReadItemCount(); } @Override public long arrayNext() throws IOException { return doReadItemCount(); } @Override public long skipArray() throws IOException { return doSkipItems(); } @Override public long readMapStart() throws IOException { return doReadItemCount(); } @Override public long mapNext() throws IOException { return doReadItemCount(); } @Override public long skipMap() throws IOException { return doSkipItems(); } @Override public int readIndex() throws IOException { return readInt(); } /** * Returns true if the current BinaryDecoder is at the end of its source data and * cannot read any further without throwing an EOFException or other * IOException. *

* Not all implementations of BinaryDecoder support isEnd(). Implementations that do * not support isEnd() will throw a * {@link java.lang.UnsupportedOperationException}. */ public boolean isEnd() throws IOException { if (limit - pos > 0) { // buffer not empty, not at end. return false; } else { if (source.isEof()) { return true; } // read from source. int read = source.tryReadRaw(buf, 0, buf.length); pos = 0; limit = read; if (0 == read) { // nothing left return true; } return false; } } /** * Ensures that buf[pos + num - 1] is not out of the buffer array bounds. * However, buf[pos + num -1] may be >= limit if there is not enough data left * in the source to fill the array with num bytes. *

* This method allows readers to read ahead by num bytes safely without * checking for EOF at each byte. However, readers must ensure that their * reads are valid by checking that their read did not advance past the limit * before adjusting pos. *

* num must be less than the buffer size and greater than 0 */ private void ensureBounds(int num) throws IOException { int remaining = limit - pos; if (remaining < num) { // move remaining to front source.compactAndFill(buf, pos, minPos, remaining); if (pos >= limit) throw new EOFException(); } } /** * Returns an {@link java.io.InputStream} that is aware of any buffering that * may occur in this BinaryDecoder. Readers that need to interleave decoding * Avro data with other reads must access this InputStream to do so unless * the implementation is 'direct' and does not read beyond the minimum bytes * necessary from the source. */ public InputStream inputStream() { return source; } /** * BufferAccessor is used by BinaryEncoder to enable {@link ByteSource}s and * the InputStream returned by {@link BinaryDecoder.inputStream} to access the * BinaryEncoder's buffer. When a BufferAccessor is created, it is attached to * a BinaryDecoder and its buffer. Its accessors directly reference the * BinaryDecoder's buffer. When detach() is called, it stores references to * the BinaryDecoder's buffer directly. The BinaryDecoder only detaches a * BufferAccessor when it is initializing to a new ByteSource. Therefore, a * client that is using the InputStream returned by BinaryDecoder.inputStream * can continue to use that stream after a BinaryDecoder has been * reinitialized to read from new data. */ static class BufferAccessor { private final BinaryDecoder decoder; private byte[] buf; private int pos; private int limit; boolean detached = false; private BufferAccessor(BinaryDecoder decoder) { this.decoder = decoder; } void detach() { this.buf = decoder.buf; this.pos = decoder.pos; this.limit = decoder.limit; detached = true; } int getPos() { if (detached) return this.pos; else return decoder.pos; } int getLim() { if (detached) return this.limit; else return decoder.limit; } byte[] getBuf() { if (detached) return this.buf; else return decoder.buf; } void setPos(int pos) { if (detached) this.pos = pos; else decoder.pos = pos; } void setLimit(int limit) { if (detached) this.limit = limit; else decoder.limit = limit; } void setBuf(byte[] buf, int offset, int length) { if (detached) { this.buf = buf; this.limit = offset + length; this.pos = offset; } else { decoder.buf = buf; decoder.limit = offset + length; decoder.pos = offset; decoder.minPos = offset; } } } /** * ByteSource abstracts the source of data from the core workings of * BinaryDecoder. This is very important for performance reasons because * InputStream's API is a barrier to performance due to several quirks: * InputStream does not in general require that as many bytes as possible have * been read when filling a buffer. *

* InputStream's terminating conditions for a read are two-fold: EOFException * and '-1' on the return from read(). Implementations are supposed to return * '-1' on EOF but often do not. The extra terminating conditions cause extra * conditionals on both sides of the API, and slow performance significantly. *

* ByteSource implementations provide read() and skip() variants that have * stronger guarantees than InputStream, freeing client code to be simplified * and faster. *

* {@link skipSourceBytes} and {@link readRaw} are guaranteed to have read or * skipped as many bytes as possible, or throw EOFException. * {@link trySkipBytes} and {@link tryRead} are guaranteed to attempt to read * or skip as many bytes as possible and never throw EOFException, while * returning the exact number of bytes skipped or read. {@link isEof} returns * true if all the source bytes have been read or skipped. This condition can * also be detected by a client if an EOFException is thrown from * {@link skipSourceBytes} or {@link readRaw}, or if {@link trySkipBytes} or * {@link tryRead} return 0; *

* A ByteSource also implements the InputStream contract for use by APIs that * require it. The InputStream interface must take into account buffering in * any decoder that this ByteSource is attached to. The other methods do not * account for buffering. */ abstract static class ByteSource extends InputStream { // maintain a reference to the buffer, so that if this // source is detached from the Decoder, and a client still // has a reference to it via inputStream(), bytes are not // lost protected BufferAccessor ba; protected ByteSource() { } abstract boolean isEof(); protected void attach(int bufferSize, BinaryDecoder decoder) { decoder.buf = new byte[bufferSize]; decoder.pos = 0; decoder.minPos = 0; decoder.limit = 0; this.ba = new BufferAccessor(decoder); return; } protected void detach() { ba.detach(); } /** * Skips length bytes from the source. If length bytes cannot be skipped due * to end of file/stream/channel/etc an EOFException is thrown * * @param length * the number of bytes to attempt to skip * @throws IOException * if an error occurs * @throws EOFException * if length bytes cannot be skipped */ protected abstract void skipSourceBytes(long length) throws IOException; /** * Attempts to skip skipLength bytes from the source. Returns the * actual number of bytes skipped. This method must attempt to skip as many * bytes as possible up to skipLength bytes. Skipping 0 bytes signals * end of stream/channel/file/etc * * @param skipLength * the number of bytes to attempt to skip * @return the count of actual bytes skipped. */ protected abstract long trySkipBytes(long skipLength) throws IOException; /** * Reads raw from the source, into a byte[]. Used for reads that are larger * than the buffer, or otherwise unbuffered. This is a mandatory read -- if * there is not enough bytes in the source, EOFException is thrown. * * @throws IOException * if an error occurs * @throws EOFException * if len bytes cannot be read * */ protected abstract void readRaw(byte[] data, int off, int len) throws IOException; /** * Attempts to copy up to len bytes from the source into data, * starting at index off. Returns the actual number of bytes copied * which may be between 0 and len. *

* This method must attempt to read as much as possible from the source. * Returns 0 when at the end of stream/channel/file/etc. * * @throws IOException * if an error occurs reading **/ protected abstract int tryReadRaw(byte[] data, int off, int len) throws IOException; /** * If this source buffers, compacts the buffer by placing the * remaining bytes starting at pos at minPos. This may * be done in the current buffer, or may replace the buffer with a new one. * * The end result must be a buffer with at least 16 bytes of remaining space. * * @param pos * @param minPos * @param remaining * @throws IOException */ protected void compactAndFill(byte[] buf, int pos, int minPos, int remaining) throws IOException { System.arraycopy(buf, pos, buf, minPos, remaining); ba.setPos(minPos); int newLimit = remaining + tryReadRaw(buf, minPos + remaining, buf.length - remaining); ba.setLimit(newLimit); } @Override public int read(byte[] b, int off, int len) throws IOException { int lim = ba.getLim(); int pos = ba.getPos(); byte[] buf = ba.getBuf(); int remaining = (lim - pos); if (remaining >= len) { System.arraycopy(buf, pos, b, off, len); pos = pos + len; ba.setPos(pos); return len; } else { // flush buffer to array System.arraycopy(buf, pos, b, off, remaining); pos = pos + remaining; ba.setPos(pos); // get the rest from the stream (skip array) int inputRead = remaining + tryReadRaw(b, off + remaining, len - remaining); if (inputRead == 0) { return -1; } else { return inputRead; } } } @Override public long skip(long n) throws IOException { int lim = ba.getLim(); int pos = ba.getPos(); int remaining = lim - pos; if (remaining > n) { pos += n; ba.setPos(pos); return n; } else { pos = lim; ba.setPos(pos); long isSkipCount = trySkipBytes(n - remaining); return isSkipCount + remaining; } } /** * returns the number of bytes remaining that this BinaryDecoder has * buffered from its source */ @Override public int available() throws IOException { return (ba.getLim() - ba.getPos()); } } private static class InputStreamByteSource extends ByteSource { private InputStream in; protected boolean isEof = false; private InputStreamByteSource(InputStream in) { super(); this.in = in; } @Override protected void skipSourceBytes(long length) throws IOException { boolean readZero = false; while (length > 0) { long n = in.skip(length); if (n > 0) { length -= n; continue; } // The inputStream contract is evil. // zero "might" mean EOF. So check for 2 in a row, we will // infinite loop waiting for -1 with some classes others // spuriously will return 0 on occasion without EOF if (n == 0) { if (readZero) { isEof = true; throw new EOFException(); } readZero = true; continue; } // read negative isEof = true; throw new EOFException(); } } @Override protected long trySkipBytes(long length) throws IOException { long leftToSkip = length; try { boolean readZero = false; while (leftToSkip > 0) { long n = in.skip(length); if (n > 0) { leftToSkip -= n; continue; } // The inputStream contract is evil. // zero "might" mean EOF. So check for 2 in a row, we will // infinite loop waiting for -1 with some classes others // spuriously will return 0 on occasion without EOF if (n == 0) { if (readZero) { isEof = true; break; } readZero = true; continue; } // read negative isEof = true; break; } } catch (EOFException eof) { isEof = true; } return length - leftToSkip; } @Override protected void readRaw(byte[] data, int off, int len) throws IOException { while (len > 0) { int read = in.read(data, off, len); if (read < 0) { isEof = true; throw new EOFException(); } len -= read; off += read; } } @Override protected int tryReadRaw(byte[] data, int off, int len) throws IOException { int leftToCopy = len; try { while (leftToCopy > 0) { int read = in.read(data, off, leftToCopy); if (read < 0) { isEof = true; break; } leftToCopy -= read; off += read; } } catch (EOFException eof) { isEof = true; } return len - leftToCopy; } @Override public int read() throws IOException { if (ba.getLim() - ba.getPos() == 0) { return in.read(); } else { int position = ba.getPos(); int result = ba.getBuf()[position] & 0xff; ba.setPos(position + 1); return result; } } @Override public boolean isEof() { return isEof; } @Override public void close() throws IOException { in.close(); } } /** * This byte source is special. It will avoid copying data by using the * source's byte[] as a buffer in the decoder. * */ private static class ByteArrayByteSource extends ByteSource { private byte[] data; private int position; private int max; private boolean compacted = false; private ByteArrayByteSource(byte[] data, int start, int len) { super(); // make sure data is not too small, otherwise getLong may try and // read 10 bytes and get index out of bounds. if (data.length < 16 || len < 16) { this.data = new byte[16]; System.arraycopy(data, start, this.data, 0, len); this.position = 0; this.max = len; } else { // use the array passed in this.data = data; this.position = start; this.max = start + len; } } @Override protected void attach(int bufferSize, BinaryDecoder decoder) { // buffer size is not used here, the byte[] source is the buffer. decoder.buf = this.data; decoder.pos = this.position; decoder.minPos = this.position; decoder.limit = this.max; this.ba = new BufferAccessor(decoder); return; } @Override protected void skipSourceBytes(long length) throws IOException { long skipped = trySkipBytes(length); if (skipped < length) { throw new EOFException(); } } @Override protected long trySkipBytes(long length) throws IOException { // the buffer is shared, so this should return 0 max = ba.getLim(); position = ba.getPos(); long remaining = max - position; if (remaining >= length) { position += length; ba.setPos(position); return length; } else { position += remaining; ba.setPos(position); return remaining; } } @Override protected void readRaw(byte[] data, int off, int len) throws IOException { int read = tryReadRaw(data, off, len); if (read < len) { throw new EOFException(); } } @Override protected int tryReadRaw(byte[] data, int off, int len) throws IOException { // the buffer is shared, nothing to read return 0; } @Override protected void compactAndFill(byte[] buf, int pos, int minPos, int remaining) throws IOException { // this implementation does not want to mutate the array passed in, // so it makes a new tiny buffer unless it has been compacted once before if (!compacted) { // assumes ensureCapacity is never called with a size more than 16 byte[] tinybuf = new byte[remaining + 16]; System.arraycopy(buf, pos, tinybuf, 0, remaining); ba.setBuf(tinybuf, 0, remaining); compacted = true; } } @Override public int read() throws IOException { max = ba.getLim(); position = ba.getPos(); if (position >= max) { return -1; } else { int result = ba.getBuf()[position++] & 0xff; ba.setPos(position); return result; } } @Override public void close() throws IOException { ba.setPos(ba.getLim()); // effectively set isEof to false } @Override public boolean isEof() { int remaining = ba.getLim() - ba.getPos(); return (remaining == 0); } } }





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