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MessageEncoder
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debug: Logger
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maskingKeySource: SecureRandom
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headerWriter: HeaderWriter
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payloadMasker: Masker
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charsetEncoder: CharsetEncoder
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intermediateBuffer: ByteBuffer
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headerBuffer: ByteBuffer
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started: boolean
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flushing: boolean
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moreText: boolean
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headerCount: long
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previousFin: boolean
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previousText: boolean
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closed: boolean
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actualLen: int
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expectedLen: int
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createIntermediateBuffer(int): ByteBuffer
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reset(): void
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encodeText(CharBuffer, boolean, ByteBuffer): boolean
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putAvailable(ByteBuffer, ByteBuffer): boolean
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encodeBinary(ByteBuffer, boolean, ByteBuffer): boolean
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maskAvailable(ByteBuffer, ByteBuffer): int
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encodePing(ByteBuffer, ByteBuffer): boolean
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encodePong(ByteBuffer, ByteBuffer): boolean
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encodeClose(int, CharBuffer, ByteBuffer): boolean
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setupHeader(Opcode, boolean, long): void
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/*
* Copyright (c) 2018, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package jdk.internal.net.http.websocket;
import jdk.internal.net.http.common.Logger;
import jdk.internal.net.http.common.Utils;
import jdk.internal.net.http.websocket.Frame.Opcode;
import java.io.IOException;
import java.nio.ByteBuffer;
import java.nio.CharBuffer;
import java.nio.charset.CharacterCodingException;
import java.nio.charset.CharsetEncoder;
import java.nio.charset.CoderResult;
import java.nio.charset.CodingErrorAction;
import java.nio.charset.StandardCharsets;
import java.security.SecureRandom;
/*
* A stateful producer of binary representations of WebSocket messages being
* sent from the client to the server.
*
* An encoding method is given an original message and a byte buffer to put the
* resulting bytes to. The method is called until it returns true. Then the
* reset method is called. The whole sequence repeats with next message.
*/
public class MessageEncoder {
private static final Logger debug =
Utils.getWebSocketLogger("[Output]"::toString, Utils.DEBUG_WS);
private final SecureRandom maskingKeySource = new SecureRandom();
private final Frame.HeaderWriter headerWriter = new Frame.HeaderWriter();
private final Frame.Masker payloadMasker = new Frame.Masker();
private final CharsetEncoder charsetEncoder
= StandardCharsets.UTF_8.newEncoder()
.onMalformedInput(CodingErrorAction.REPORT)
.onUnmappableCharacter(CodingErrorAction.REPORT);
/*
* This buffer is used both to encode characters to UTF-8 and to calculate
* the length of the resulting frame's payload. The length of the payload
* must be known before the frame's header can be written.
* For implementation reasons, this buffer must have a capacity of at least
* the maximum size of a Close frame payload, which is 125 bytes
* (or Frame.MAX_CONTROL_FRAME_PAYLOAD_LENGTH).
*/
private final ByteBuffer intermediateBuffer = createIntermediateBuffer(
Frame.MAX_CONTROL_FRAME_PAYLOAD_LENGTH);
private final ByteBuffer headerBuffer = ByteBuffer.allocate(
Frame.MAX_HEADER_SIZE_BYTES);
private boolean started;
private boolean flushing;
private boolean moreText = true;
private long headerCount;
/* Has the previous frame got its fin flag set? */
private boolean previousFin = true;
/* Was the previous frame TEXT or a CONTINUATION thereof? */
private boolean previousText;
private boolean closed;
/*
* How many bytes of the current message have been already encoded.
*
* Even though the user hands their buffers over to us, they still can
* manipulate these buffers while we are getting data out of them.
* The number of produced bytes guards us from such behaviour in the
* case of messages that must be restricted in size (Ping, Pong and Close).
* For other messages this measure provides a best-effort attempt to detect
* concurrent changes to buffer.
*
* Making a shallow copy (duplicate/slice) and then checking the size
* precondition on it would also solve the problem, but at the cost of this
* extra copy.
*/
private int actualLen;
/*
* How many bytes were originally there in the message, before the encoding
* started.
*/
private int expectedLen;
/* Exposed for testing purposes */
protected ByteBuffer createIntermediateBuffer(int minSize) {
int capacity = Utils.getIntegerNetProperty(
"jdk.httpclient.websocket.intermediateBufferSize", 16384);
return ByteBuffer.allocate(Math.max(minSize, capacity));
}
public void reset() {
// Do not reset the message stream state fields, e.g. previousFin,
// previousText. Just an individual message state:
started = false;
flushing = false;
moreText = true;
headerCount = 0;
actualLen = 0;
}
/*
* Encodes text messages by cutting them into fragments of maximum size of
* intermediateBuffer.capacity()
*/
public boolean encodeText(CharBuffer src, boolean last, ByteBuffer dst)
throws IOException
{
if (debug.on()) {
debug.log("encode text src=[pos=%s lim=%s cap=%s] last=%s dst=%s",
src.position(), src.limit(), src.capacity(), last, dst);
}
if (closed) {
throw new IOException("Output closed");
}
if (!started) {
if (!previousText && !previousFin) {
// Previous data message was a partial binary message
throw new IllegalStateException("Unexpected text message");
}
started = true;
headerBuffer.position(0).limit(0);
intermediateBuffer.position(0).limit(0);
charsetEncoder.reset();
}
while (true) {
if (debug.on()) {
debug.log("put");
}
if (!putAvailable(headerBuffer, dst)) {
return false;
}
if (debug.on()) {
debug.log("mask");
}
if (maskAvailable(intermediateBuffer, dst) < 0) {
return false;
}
if (debug.on()) {
debug.log("moreText");
}
if (!moreText) {
previousFin = last;
previousText = true;
return true;
}
intermediateBuffer.clear();
CoderResult r = null;
if (!flushing) {
r = charsetEncoder.encode(src, intermediateBuffer, true);
if (r.isUnderflow()) {
flushing = true;
}
}
if (flushing) {
r = charsetEncoder.flush(intermediateBuffer);
if (r.isUnderflow()) {
moreText = false;
}
}
if (r.isError()) {
try {
r.throwException();
} catch (CharacterCodingException e) {
throw new IOException("Malformed text message", e);
}
}
if (debug.on()) {
debug.log("frame #%s", headerCount);
}
intermediateBuffer.flip();
Opcode opcode = previousFin && headerCount == 0
? Opcode.TEXT : Opcode.CONTINUATION;
boolean fin = last && !moreText;
setupHeader(opcode, fin, intermediateBuffer.remaining());
headerCount++;
}
}
private boolean putAvailable(ByteBuffer src, ByteBuffer dst) {
int available = dst.remaining();
if (available >= src.remaining()) {
dst.put(src);
return true;
} else {
int lim = src.limit(); // save the limit
src.limit(src.position() + available);
dst.put(src);
src.limit(lim); // restore the limit
return false;
}
}
public boolean encodeBinary(ByteBuffer src, boolean last, ByteBuffer dst)
throws IOException
{
if (debug.on()) {
debug.log("encode binary src=%s last=%s dst=%s",
src, last, dst);
}
if (closed) {
throw new IOException("Output closed");
}
if (!started) {
if (previousText && !previousFin) {
// Previous data message was a partial text message
throw new IllegalStateException("Unexpected binary message");
}
expectedLen = src.remaining();
Opcode opcode = previousFin ? Opcode.BINARY : Opcode.CONTINUATION;
setupHeader(opcode, last, expectedLen);
previousFin = last;
previousText = false;
started = true;
}
if (!putAvailable(headerBuffer, dst)) {
return false;
}
int count = maskAvailable(src, dst);
actualLen += Math.abs(count);
if (count >= 0 && actualLen != expectedLen) {
throw new IOException("Concurrent message modification");
}
return count >= 0;
}
private int maskAvailable(ByteBuffer src, ByteBuffer dst) {
int r0 = dst.remaining();
payloadMasker.transferMasking(src, dst);
int masked = r0 - dst.remaining();
return src.hasRemaining() ? -masked : masked;
}
public boolean encodePing(ByteBuffer src, ByteBuffer dst)
throws IOException
{
if (debug.on()) {
debug.log("encode ping src=%s dst=%s", src, dst);
}
if (closed) {
throw new IOException("Output closed");
}
if (!started) {
expectedLen = src.remaining();
if (expectedLen > Frame.MAX_CONTROL_FRAME_PAYLOAD_LENGTH) {
throw new IllegalArgumentException("Long message: " + expectedLen);
}
setupHeader(Opcode.PING, true, expectedLen);
started = true;
}
if (!putAvailable(headerBuffer, dst)) {
return false;
}
int count = maskAvailable(src, dst);
actualLen += Math.abs(count);
if (count >= 0 && actualLen != expectedLen) {
throw new IOException("Concurrent message modification");
}
return count >= 0;
}
public boolean encodePong(ByteBuffer src, ByteBuffer dst)
throws IOException
{
if (debug.on()) {
debug.log("encode pong src=%s dst=%s",
src, dst);
}
if (closed) {
throw new IOException("Output closed");
}
if (!started) {
expectedLen = src.remaining();
if (expectedLen > Frame.MAX_CONTROL_FRAME_PAYLOAD_LENGTH) {
throw new IllegalArgumentException("Long message: " + expectedLen);
}
setupHeader(Opcode.PONG, true, expectedLen);
started = true;
}
if (!putAvailable(headerBuffer, dst)) {
return false;
}
int count = maskAvailable(src, dst);
actualLen += Math.abs(count);
if (count >= 0 && actualLen != expectedLen) {
throw new IOException("Concurrent message modification");
}
return count >= 0;
}
public boolean encodeClose(int statusCode, CharBuffer reason, ByteBuffer dst)
throws IOException
{
if (debug.on()) {
debug.log("encode close statusCode=%s reason=[pos=%s lim=%s cap=%s] dst=%s",
statusCode, reason.position(), reason.limit(), reason.capacity(), dst);
}
if (closed) {
throw new IOException("Output closed");
}
if (!started) {
if (debug.on()) {
debug.log("reason [pos=%s lim=%s cap=%s]",
reason.position(), reason.limit(), reason.capacity());
}
intermediateBuffer.position(0).limit(Frame.MAX_CONTROL_FRAME_PAYLOAD_LENGTH);
intermediateBuffer.putChar((char) statusCode);
CoderResult r = charsetEncoder.reset().encode(reason, intermediateBuffer, true);
if (r.isUnderflow()) {
if (debug.on()) {
debug.log("flushing");
}
r = charsetEncoder.flush(intermediateBuffer);
}
if (debug.on()) {
debug.log("encoding result: %s", r);
}
if (r.isError()) {
try {
r.throwException();
} catch (CharacterCodingException e) {
throw new IOException("Malformed reason", e);
}
} else if (r.isOverflow()) {
// Here the 125 bytes size is ensured by the check for overflow
throw new IOException("Long reason");
} else if (!r.isUnderflow()) {
throw new InternalError(); // assertion
}
intermediateBuffer.flip();
setupHeader(Opcode.CLOSE, true, intermediateBuffer.remaining());
started = true;
closed = true;
if (debug.on()) {
debug.log("intermediateBuffer=%s", intermediateBuffer);
}
}
if (!putAvailable(headerBuffer, dst)) {
return false;
}
return maskAvailable(intermediateBuffer, dst) >= 0;
}
private void setupHeader(Opcode opcode, boolean fin, long payloadLen) {
if (debug.on()) {
debug.log("frame opcode=%s fin=%s len=%s",
opcode, fin, payloadLen);
}
headerBuffer.clear();
int mask = maskingKeySource.nextInt();
headerWriter.fin(fin)
.opcode(opcode)
.payloadLen(payloadLen)
.mask(mask)
.write(headerBuffer);
headerBuffer.flip();
payloadMasker.mask(mask);
}
}