com.alibaba.nacos.shaded.io.grpc.internal.GzipInflatingBuffer Maven / Gradle / Ivy
/*
* Copyright 2017 The gRPC Authors
*
* Licensed 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 com.alibaba.nacos.shaded.io.grpc.internal;
import static com.alibaba.nacos.shaded.com.google.common.base.Preconditions.checkState;
import java.io.Closeable;
import java.util.zip.CRC32;
import java.util.zip.DataFormatException;
import java.util.zip.Inflater;
import java.util.zip.ZipException;
import com.alibaba.nacos.shaded.javax.annotation.concurrent.NotThreadSafe;
/**
* Processes gzip streams, delegating to {@link Inflater} to perform on-demand inflation of the
* deflated blocks. Like {@link java.util.zip.GZIPInputStream}, this handles concatenated gzip
* streams. Unlike {@link java.util.zip.GZIPInputStream}, this allows for incremental processing of
* gzip streams, allowing data to be inflated as it arrives over the wire.
*
* This also frees the inflate context when the end of a gzip stream is reached without another
* concatenated stream available to inflate.
*/
@NotThreadSafe
class GzipInflatingBuffer implements Closeable {
private static final int INFLATE_BUFFER_SIZE = 512;
private static final int UNSIGNED_SHORT_SIZE = 2;
private static final int GZIP_MAGIC = 0x8b1f;
private static final int GZIP_HEADER_MIN_SIZE = 10;
private static final int GZIP_TRAILER_SIZE = 8;
private static final int HEADER_CRC_FLAG = 2;
private static final int HEADER_EXTRA_FLAG = 4;
private static final int HEADER_NAME_FLAG = 8;
private static final int HEADER_COMMENT_FLAG = 16;
/**
* Reads gzip header and trailer bytes from the inflater's buffer (if bytes beyond the inflate
* block were given to the inflater) and then from {@code gzippedData}, and handles updating the
* CRC and the count of gzipped bytes consumed.
*/
private class GzipMetadataReader {
/**
* Returns the next unsigned byte, adding it the CRC and incrementing {@code bytesConsumed}.
*
*
It is the responsibility of the caller to verify and reset the CRC as needed, as well as
* caching the current CRC value when necessary before invoking this method.
*/
private int readUnsignedByte() {
int bytesRemainingInInflaterInput = inflaterInputEnd - inflaterInputStart;
int b;
if (bytesRemainingInInflaterInput > 0) {
b = inflaterInput[inflaterInputStart] & 0xFF;
inflaterInputStart += 1;
} else {
b = gzippedData.readUnsignedByte();
}
crc.update(b);
bytesConsumed += 1;
return b;
}
/**
* Skips {@code length} bytes, adding them to the CRC and adding {@code length} to {@code
* bytesConsumed}.
*
*
It is the responsibility of the caller to verify and reset the CRC as needed, as well as
* caching the current CRC value when necessary before invoking this method.
*/
private void skipBytes(int length) {
int bytesToSkip = length;
int bytesRemainingInInflaterInput = inflaterInputEnd - inflaterInputStart;
if (bytesRemainingInInflaterInput > 0) {
int bytesToGetFromInflaterInput = Math.min(bytesRemainingInInflaterInput, bytesToSkip);
crc.update(inflaterInput, inflaterInputStart, bytesToGetFromInflaterInput);
inflaterInputStart += bytesToGetFromInflaterInput;
bytesToSkip -= bytesToGetFromInflaterInput;
}
if (bytesToSkip > 0) {
byte[] buf = new byte[512];
int total = 0;
while (total < bytesToSkip) {
int toRead = Math.min(bytesToSkip - total, buf.length);
gzippedData.readBytes(buf, 0, toRead);
crc.update(buf, 0, toRead);
total += toRead;
}
}
bytesConsumed += length;
}
private int readableBytes() {
return (inflaterInputEnd - inflaterInputStart) + gzippedData.readableBytes();
}
/** Skip over a zero-terminated byte sequence. Returns true when the zero byte is read. */
private boolean readBytesUntilZero() {
while (readableBytes() > 0) {
if (readUnsignedByte() == 0) {
return true;
}
}
return false;
}
/** Reads unsigned short in Little-Endian byte order. */
private int readUnsignedShort() {
return readUnsignedByte() | (readUnsignedByte() << 8);
}
/** Reads unsigned integer in Little-Endian byte order. */
private long readUnsignedInt() {
long s = readUnsignedShort();
return ((long) readUnsignedShort() << 16) | s;
}
}
private enum State {
HEADER,
HEADER_EXTRA_LEN,
HEADER_EXTRA,
HEADER_NAME,
HEADER_COMMENT,
HEADER_CRC,
INITIALIZE_INFLATER,
INFLATING,
INFLATER_NEEDS_INPUT,
TRAILER
}
/**
* This buffer holds all input gzipped data, consisting of blocks of deflated data and the
* surrounding gzip headers and trailers. All access to the Gzip headers and trailers must be made
* via {@link GzipMetadataReader}.
*/
private final CompositeReadableBuffer gzippedData = new CompositeReadableBuffer();
private final CRC32 crc = new CRC32();
private final GzipMetadataReader gzipMetadataReader = new GzipMetadataReader();
private final byte[] inflaterInput = new byte[INFLATE_BUFFER_SIZE];
private int inflaterInputStart;
private int inflaterInputEnd;
private Inflater inflater;
private State state = State.HEADER;
private boolean closed = false;
/** Extra state variables for parsing gzip header flags. */
private int gzipHeaderFlag;
private int headerExtraToRead;
/* Number of inflated bytes per gzip stream, used to validate the gzip trailer. */
private long expectedGzipTrailerIsize;
/**
* Tracks gzipped bytes (including gzip metadata and deflated blocks) consumed during {@link
* #inflateBytes} calls.
*/
private int bytesConsumed = 0;
/** Tracks deflated bytes (excluding gzip metadata) consumed by the inflater. */
private int deflatedBytesConsumed = 0;
private boolean isStalled = true;
/**
* Returns true when more bytes must be added via {@link #addGzippedBytes} to enable additional
* calls to {@link #inflateBytes} to make progress.
*/
boolean isStalled() {
checkState(!closed, "GzipInflatingBuffer is closed");
return isStalled;
}
/**
* Returns true when there is gzippedData that has not been input to the inflater or the inflater
* has not consumed all of its input, or all data has been consumed but we are at not at the
* boundary between gzip streams.
*/
boolean hasPartialData() {
checkState(!closed, "GzipInflatingBuffer is closed");
return gzipMetadataReader.readableBytes() != 0 || state != State.HEADER;
}
/**
* Adds more gzipped data, which will be consumed only when needed to fulfill requests made via
* {@link #inflateBytes}.
*/
void addGzippedBytes(ReadableBuffer buffer) {
checkState(!closed, "GzipInflatingBuffer is closed");
gzippedData.addBuffer(buffer);
isStalled = false;
}
@Override
public void close() {
if (!closed) {
closed = true;
gzippedData.close();
if (inflater != null) {
inflater.end();
inflater = null;
}
}
}
/**
* Reports bytes consumed by calls to {@link #inflateBytes} since the last invocation of this
* method, then resets the count to zero.
*/
int getAndResetBytesConsumed() {
int savedBytesConsumed = bytesConsumed;
bytesConsumed = 0;
return savedBytesConsumed;
}
/**
* Reports bytes consumed by the inflater since the last invocation of this method, then resets
* the count to zero.
*/
int getAndResetDeflatedBytesConsumed() {
int savedDeflatedBytesConsumed = deflatedBytesConsumed;
deflatedBytesConsumed = 0;
return savedDeflatedBytesConsumed;
}
/**
* Attempts to inflate {@code length} bytes of data into {@code b}.
*
*
Any gzipped bytes consumed by this method will be added to the counter returned by {@link
* #getAndResetBytesConsumed()}. This method may consume gzipped bytes without writing any data to
* {@code b}, and may also write data to {@code b} without consuming additional gzipped bytes (if
* the inflater on an earlier call consumed the bytes necessary to produce output).
*
* @param b the destination array to receive the bytes.
* @param offset the starting offset in the destination array.
* @param length the number of bytes to be copied.
* @throws IndexOutOfBoundsException if {@code b} is too small to hold the requested bytes.
*/
int inflateBytes(byte[] b, int offset, int length) throws DataFormatException, ZipException {
checkState(!closed, "GzipInflatingBuffer is closed");
int bytesRead = 0;
int missingBytes;
boolean madeProgress = true;
while (madeProgress && (missingBytes = length - bytesRead) > 0) {
switch (state) {
case HEADER:
madeProgress = processHeader();
break;
case HEADER_EXTRA_LEN:
madeProgress = processHeaderExtraLen();
break;
case HEADER_EXTRA:
madeProgress = processHeaderExtra();
break;
case HEADER_NAME:
madeProgress = processHeaderName();
break;
case HEADER_COMMENT:
madeProgress = processHeaderComment();
break;
case HEADER_CRC:
madeProgress = processHeaderCrc();
break;
case INITIALIZE_INFLATER:
madeProgress = initializeInflater();
break;
case INFLATING:
bytesRead += inflate(b, offset + bytesRead, missingBytes);
if (state == State.TRAILER) {
// Eagerly process trailer, if available, to validate CRC.
madeProgress = processTrailer();
} else {
// Continue in INFLATING until we have the required bytes or we transition to
// INFLATER_NEEDS_INPUT
madeProgress = true;
}
break;
case INFLATER_NEEDS_INPUT:
madeProgress = fill();
break;
case TRAILER:
madeProgress = processTrailer();
break;
default:
throw new AssertionError("Invalid state: " + state);
}
}
// If we finished a gzip block, check if we have enough bytes to read another header
isStalled =
!madeProgress
|| (state == State.HEADER && gzipMetadataReader.readableBytes() < GZIP_HEADER_MIN_SIZE);
return bytesRead;
}
private boolean processHeader() throws ZipException {
if (gzipMetadataReader.readableBytes() < GZIP_HEADER_MIN_SIZE) {
return false;
}
if (gzipMetadataReader.readUnsignedShort() != GZIP_MAGIC) {
throw new ZipException("Not in GZIP format");
}
if (gzipMetadataReader.readUnsignedByte() != 8) {
throw new ZipException("Unsupported compression method");
}
gzipHeaderFlag = gzipMetadataReader.readUnsignedByte();
gzipMetadataReader.skipBytes(6 /* remaining header bytes */);
state = State.HEADER_EXTRA_LEN;
return true;
}
private boolean processHeaderExtraLen() {
if ((gzipHeaderFlag & HEADER_EXTRA_FLAG) != HEADER_EXTRA_FLAG) {
state = State.HEADER_NAME;
return true;
}
if (gzipMetadataReader.readableBytes() < UNSIGNED_SHORT_SIZE) {
return false;
}
headerExtraToRead = gzipMetadataReader.readUnsignedShort();
state = State.HEADER_EXTRA;
return true;
}
private boolean processHeaderExtra() {
if (gzipMetadataReader.readableBytes() < headerExtraToRead) {
return false;
}
gzipMetadataReader.skipBytes(headerExtraToRead);
state = State.HEADER_NAME;
return true;
}
private boolean processHeaderName() {
if ((gzipHeaderFlag & HEADER_NAME_FLAG) != HEADER_NAME_FLAG) {
state = State.HEADER_COMMENT;
return true;
}
if (!gzipMetadataReader.readBytesUntilZero()) {
return false;
}
state = State.HEADER_COMMENT;
return true;
}
private boolean processHeaderComment() {
if ((gzipHeaderFlag & HEADER_COMMENT_FLAG) != HEADER_COMMENT_FLAG) {
state = State.HEADER_CRC;
return true;
}
if (!gzipMetadataReader.readBytesUntilZero()) {
return false;
}
state = State.HEADER_CRC;
return true;
}
private boolean processHeaderCrc() throws ZipException {
if ((gzipHeaderFlag & HEADER_CRC_FLAG) != HEADER_CRC_FLAG) {
state = State.INITIALIZE_INFLATER;
return true;
}
if (gzipMetadataReader.readableBytes() < UNSIGNED_SHORT_SIZE) {
return false;
}
int desiredCrc16 = (int) crc.getValue() & 0xffff;
if (desiredCrc16 != gzipMetadataReader.readUnsignedShort()) {
throw new ZipException("Corrupt GZIP header");
}
state = State.INITIALIZE_INFLATER;
return true;
}
private boolean initializeInflater() {
if (inflater == null) {
inflater = new Inflater(true);
} else {
inflater.reset();
}
crc.reset();
int bytesRemainingInInflaterInput = inflaterInputEnd - inflaterInputStart;
if (bytesRemainingInInflaterInput > 0) {
inflater.setInput(inflaterInput, inflaterInputStart, bytesRemainingInInflaterInput);
state = State.INFLATING;
} else {
state = State.INFLATER_NEEDS_INPUT;
}
return true;
}
private int inflate(byte[] b, int off, int len) throws DataFormatException, ZipException {
checkState(inflater != null, "inflater is null");
try {
int inflaterTotalIn = inflater.getTotalIn();
int n = inflater.inflate(b, off, len);
int bytesConsumedDelta = inflater.getTotalIn() - inflaterTotalIn;
bytesConsumed += bytesConsumedDelta;
deflatedBytesConsumed += bytesConsumedDelta;
inflaterInputStart += bytesConsumedDelta;
crc.update(b, off, n);
if (inflater.finished()) {
// Save bytes written to check against the trailer ISIZE
expectedGzipTrailerIsize = (inflater.getBytesWritten() & 0xffffffffL);
state = State.TRAILER;
} else if (inflater.needsInput()) {
state = State.INFLATER_NEEDS_INPUT;
}
return n;
} catch (DataFormatException e) {
// Wrap the exception so tests can check for a specific prefix
throw new DataFormatException("Inflater data format exception: " + e.getMessage());
}
}
private boolean fill() {
checkState(inflater != null, "inflater is null");
checkState(inflaterInputStart == inflaterInputEnd, "inflaterInput has unconsumed bytes");
int bytesToAdd = Math.min(gzippedData.readableBytes(), INFLATE_BUFFER_SIZE);
if (bytesToAdd == 0) {
return false;
}
inflaterInputStart = 0;
inflaterInputEnd = bytesToAdd;
gzippedData.readBytes(inflaterInput, inflaterInputStart, bytesToAdd);
inflater.setInput(inflaterInput, inflaterInputStart, bytesToAdd);
state = State.INFLATING;
return true;
}
private boolean processTrailer() throws ZipException {
if (inflater != null
&& gzipMetadataReader.readableBytes() <= GZIP_HEADER_MIN_SIZE + GZIP_TRAILER_SIZE) {
// We don't have enough bytes to begin inflating a concatenated gzip stream, drop context
inflater.end();
inflater = null;
}
if (gzipMetadataReader.readableBytes() < GZIP_TRAILER_SIZE) {
return false;
}
if (crc.getValue() != gzipMetadataReader.readUnsignedInt()
|| expectedGzipTrailerIsize != gzipMetadataReader.readUnsignedInt()) {
throw new ZipException("Corrupt GZIP trailer");
}
crc.reset();
state = State.HEADER;
return true;
}
}