1 /*
2 * Copyright 2012 The Netty Project
3 *
4 * The Netty Project licenses this file to you under the Apache License,
5 * version 2.0 (the "License"); you may not use this file except in compliance
6 * with the License. You may obtain a copy of the License at:
7 *
8 * https://www.apache.org/licenses/LICENSE-2.0
9 *
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
12 * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
13 * License for the specific language governing permissions and limitations
14 * under the License.
15 */
16 package io.netty.handler.ssl;
17
18 import io.netty.buffer.ByteBuf;
19 import io.netty.buffer.ByteBufAllocator;
20 import io.netty.buffer.ByteBufUtil;
21 import io.netty.buffer.CompositeByteBuf;
22 import io.netty.buffer.Unpooled;
23 import io.netty.channel.AbstractCoalescingBufferQueue;
24 import io.netty.channel.Channel;
25 import io.netty.channel.ChannelConfig;
26 import io.netty.channel.ChannelException;
27 import io.netty.channel.ChannelFuture;
28 import io.netty.channel.ChannelFutureListener;
29 import io.netty.channel.ChannelHandlerContext;
30 import io.netty.channel.ChannelInboundHandler;
31 import io.netty.channel.ChannelOption;
32 import io.netty.channel.ChannelOutboundBuffer;
33 import io.netty.channel.ChannelOutboundHandler;
34 import io.netty.channel.ChannelPipeline;
35 import io.netty.channel.ChannelPromise;
36 import io.netty.channel.unix.UnixChannel;
37 import io.netty.handler.codec.ByteToMessageDecoder;
38 import io.netty.handler.codec.DecoderException;
39 import io.netty.handler.codec.UnsupportedMessageTypeException;
40 import io.netty.util.ReferenceCountUtil;
41 import io.netty.util.concurrent.DefaultPromise;
42 import io.netty.util.concurrent.EventExecutor;
43 import io.netty.util.concurrent.Future;
44 import io.netty.util.concurrent.FutureListener;
45 import io.netty.util.concurrent.ImmediateExecutor;
46 import io.netty.util.concurrent.Promise;
47 import io.netty.util.concurrent.PromiseNotifier;
48 import io.netty.util.internal.ObjectUtil;
49 import io.netty.util.internal.PlatformDependent;
50 import io.netty.util.internal.UnstableApi;
51 import io.netty.util.internal.logging.InternalLogger;
52 import io.netty.util.internal.logging.InternalLoggerFactory;
53
54 import java.io.IOException;
55 import java.net.SocketAddress;
56 import java.nio.ByteBuffer;
57 import java.nio.channels.ClosedChannelException;
58 import java.nio.channels.DatagramChannel;
59 import java.nio.channels.SocketChannel;
60 import java.util.List;
61 import java.util.concurrent.Executor;
62 import java.util.concurrent.RejectedExecutionException;
63 import java.util.concurrent.TimeUnit;
64 import java.util.regex.Pattern;
65
66 import javax.net.ssl.SSLEngine;
67 import javax.net.ssl.SSLEngineResult;
68 import javax.net.ssl.SSLEngineResult.HandshakeStatus;
69 import javax.net.ssl.SSLEngineResult.Status;
70 import javax.net.ssl.SSLException;
71 import javax.net.ssl.SSLHandshakeException;
72 import javax.net.ssl.SSLSession;
73
74 import static io.netty.buffer.ByteBufUtil.ensureWritableSuccess;
75 import static io.netty.handler.ssl.SslUtils.getEncryptedPacketLength;
76 import static io.netty.util.internal.ObjectUtil.checkNotNull;
77 import static io.netty.util.internal.ObjectUtil.checkPositiveOrZero;
78
79 /**
80 * Adds <a href="https://en.wikipedia.org/wiki/Transport_Layer_Security">SSL
81 * · TLS</a> and StartTLS support to a {@link Channel}. Please refer
82 * to the <strong>"SecureChat"</strong> example in the distribution or the web
83 * site for the detailed usage.
84 *
85 * <h3>Beginning the handshake</h3>
86 * <p>
87 * Beside using the handshake {@link ChannelFuture} to get notified about the completion of the handshake it's
88 * also possible to detect it by implement the
89 * {@link ChannelInboundHandler#userEventTriggered(ChannelHandlerContext, Object)}
90 * method and check for a {@link SslHandshakeCompletionEvent}.
91 *
92 * <h3>Handshake</h3>
93 * <p>
94 * The handshake will be automatically issued for you once the {@link Channel} is active and
95 * {@link SSLEngine#getUseClientMode()} returns {@code true}.
96 * So no need to bother with it by your self.
97 *
98 * <h3>Closing the session</h3>
99 * <p>
100 * To close the SSL session, the {@link #closeOutbound()} method should be
101 * called to send the {@code close_notify} message to the remote peer. One
102 * exception is when you close the {@link Channel} - {@link SslHandler}
103 * intercepts the close request and send the {@code close_notify} message
104 * before the channel closure automatically. Once the SSL session is closed,
105 * it is not reusable, and consequently you should create a new
106 * {@link SslHandler} with a new {@link SSLEngine} as explained in the
107 * following section.
108 *
109 * <h3>Restarting the session</h3>
110 * <p>
111 * To restart the SSL session, you must remove the existing closed
112 * {@link SslHandler} from the {@link ChannelPipeline}, insert a new
113 * {@link SslHandler} with a new {@link SSLEngine} into the pipeline,
114 * and start the handshake process as described in the first section.
115 *
116 * <h3>Implementing StartTLS</h3>
117 * <p>
118 * <a href="https://en.wikipedia.org/wiki/STARTTLS">StartTLS</a> is the
119 * communication pattern that secures the wire in the middle of the plaintext
120 * connection. Please note that it is different from SSL · TLS, that
121 * secures the wire from the beginning of the connection. Typically, StartTLS
122 * is composed of three steps:
123 * <ol>
124 * <li>Client sends a StartTLS request to server.</li>
125 * <li>Server sends a StartTLS response to client.</li>
126 * <li>Client begins SSL handshake.</li>
127 * </ol>
128 * If you implement a server, you need to:
129 * <ol>
130 * <li>create a new {@link SslHandler} instance with {@code startTls} flag set
131 * to {@code true},</li>
132 * <li>insert the {@link SslHandler} to the {@link ChannelPipeline}, and</li>
133 * <li>write a StartTLS response.</li>
134 * </ol>
135 * Please note that you must insert {@link SslHandler} <em>before</em> sending
136 * the StartTLS response. Otherwise the client can send begin SSL handshake
137 * before {@link SslHandler} is inserted to the {@link ChannelPipeline}, causing
138 * data corruption.
139 * <p>
140 * The client-side implementation is much simpler.
141 * <ol>
142 * <li>Write a StartTLS request,</li>
143 * <li>wait for the StartTLS response,</li>
144 * <li>create a new {@link SslHandler} instance with {@code startTls} flag set
145 * to {@code false},</li>
146 * <li>insert the {@link SslHandler} to the {@link ChannelPipeline}, and</li>
147 * <li>Initiate SSL handshake.</li>
148 * </ol>
149 *
150 * <h3>Known issues</h3>
151 * <p>
152 * Because of a known issue with the current implementation of the SslEngine that comes
153 * with Java it may be possible that you see blocked IO-Threads while a full GC is done.
154 * <p>
155 * So if you are affected you can workaround this problem by adjust the cache settings
156 * like shown below:
157 *
158 * <pre>
159 * SslContext context = ...;
160 * context.getServerSessionContext().setSessionCacheSize(someSaneSize);
161 * context.getServerSessionContext().setSessionTime(someSameTimeout);
162 * </pre>
163 * <p>
164 * What values to use here depends on the nature of your application and should be set
165 * based on monitoring and debugging of it.
166 * For more details see
167 * <a href="https://github.com/netty/netty/issues/832">#832</a> in our issue tracker.
168 */
169 public class SslHandler extends ByteToMessageDecoder implements ChannelOutboundHandler {
170 private static final InternalLogger logger =
171 InternalLoggerFactory.getInstance(SslHandler.class);
172 private static final Pattern IGNORABLE_CLASS_IN_STACK = Pattern.compile(
173 "^.*(?:Socket|Datagram|Sctp|Udt)Channel.*$");
174 private static final Pattern IGNORABLE_ERROR_MESSAGE = Pattern.compile(
175 "^.*(?:connection.*(?:reset|closed|abort|broken)|broken.*pipe).*$", Pattern.CASE_INSENSITIVE);
176 private static final int STATE_SENT_FIRST_MESSAGE = 1;
177 private static final int STATE_FLUSHED_BEFORE_HANDSHAKE = 1 << 1;
178 private static final int STATE_READ_DURING_HANDSHAKE = 1 << 2;
179 private static final int STATE_HANDSHAKE_STARTED = 1 << 3;
180 /**
181 * Set by wrap*() methods when something is produced.
182 * {@link #channelReadComplete(ChannelHandlerContext)} will check this flag, clear it, and call ctx.flush().
183 */
184 private static final int STATE_NEEDS_FLUSH = 1 << 4;
185 private static final int STATE_OUTBOUND_CLOSED = 1 << 5;
186 private static final int STATE_CLOSE_NOTIFY = 1 << 6;
187 private static final int STATE_PROCESS_TASK = 1 << 7;
188 /**
189 * This flag is used to determine if we need to call {@link ChannelHandlerContext#read()} to consume more data
190 * when {@link ChannelConfig#isAutoRead()} is {@code false}.
191 */
192 private static final int STATE_FIRE_CHANNEL_READ = 1 << 8;
193 private static final int STATE_UNWRAP_REENTRY = 1 << 9;
194
195 /**
196 * <a href="https://tools.ietf.org/html/rfc5246#section-6.2">2^14</a> which is the maximum sized plaintext chunk
197 * allowed by the TLS RFC.
198 */
199 private static final int MAX_PLAINTEXT_LENGTH = 16 * 1024;
200
201 private enum SslEngineType {
202 TCNATIVE(true, COMPOSITE_CUMULATOR) {
203 @Override
204 SSLEngineResult unwrap(SslHandler handler, ByteBuf in, int len, ByteBuf out) throws SSLException {
205 int nioBufferCount = in.nioBufferCount();
206 int writerIndex = out.writerIndex();
207 final SSLEngineResult result;
208 if (nioBufferCount > 1) {
209 /*
210 * If {@link OpenSslEngine} is in use,
211 * we can use a special {@link OpenSslEngine#unwrap(ByteBuffer[], ByteBuffer[])} method
212 * that accepts multiple {@link ByteBuffer}s without additional memory copies.
213 */
214 ReferenceCountedOpenSslEngine opensslEngine = (ReferenceCountedOpenSslEngine) handler.engine;
215 try {
216 handler.singleBuffer[0] = toByteBuffer(out, writerIndex, out.writableBytes());
217 result = opensslEngine.unwrap(in.nioBuffers(in.readerIndex(), len), handler.singleBuffer);
218 } finally {
219 handler.singleBuffer[0] = null;
220 }
221 } else {
222 result = handler.engine.unwrap(toByteBuffer(in, in.readerIndex(), len),
223 toByteBuffer(out, writerIndex, out.writableBytes()));
224 }
225 out.writerIndex(writerIndex + result.bytesProduced());
226 return result;
227 }
228
229 @Override
230 ByteBuf allocateWrapBuffer(SslHandler handler, ByteBufAllocator allocator,
231 int pendingBytes, int numComponents) {
232 return allocator.directBuffer(((ReferenceCountedOpenSslEngine) handler.engine)
233 .calculateMaxLengthForWrap(pendingBytes, numComponents));
234 }
235
236 @Override
237 int calculatePendingData(SslHandler handler, int guess) {
238 int sslPending = ((ReferenceCountedOpenSslEngine) handler.engine).sslPending();
239 return sslPending > 0 ? sslPending : guess;
240 }
241
242 @Override
243 boolean jdkCompatibilityMode(SSLEngine engine) {
244 return ((ReferenceCountedOpenSslEngine) engine).jdkCompatibilityMode;
245 }
246 },
247 CONSCRYPT(true, COMPOSITE_CUMULATOR) {
248 @Override
249 SSLEngineResult unwrap(SslHandler handler, ByteBuf in, int len, ByteBuf out) throws SSLException {
250 int nioBufferCount = in.nioBufferCount();
251 int writerIndex = out.writerIndex();
252 final SSLEngineResult result;
253 if (nioBufferCount > 1) {
254 /*
255 * Use a special unwrap method without additional memory copies.
256 */
257 try {
258 handler.singleBuffer[0] = toByteBuffer(out, writerIndex, out.writableBytes());
259 result = ((ConscryptAlpnSslEngine) handler.engine).unwrap(
260 in.nioBuffers(in.readerIndex(), len),
261 handler.singleBuffer);
262 } finally {
263 handler.singleBuffer[0] = null;
264 }
265 } else {
266 result = handler.engine.unwrap(toByteBuffer(in, in.readerIndex(), len),
267 toByteBuffer(out, writerIndex, out.writableBytes()));
268 }
269 out.writerIndex(writerIndex + result.bytesProduced());
270 return result;
271 }
272
273 @Override
274 ByteBuf allocateWrapBuffer(SslHandler handler, ByteBufAllocator allocator,
275 int pendingBytes, int numComponents) {
276 return allocator.directBuffer(
277 ((ConscryptAlpnSslEngine) handler.engine).calculateOutNetBufSize(pendingBytes, numComponents));
278 }
279
280 @Override
281 int calculatePendingData(SslHandler handler, int guess) {
282 return guess;
283 }
284
285 @Override
286 boolean jdkCompatibilityMode(SSLEngine engine) {
287 return true;
288 }
289 },
290 JDK(false, MERGE_CUMULATOR) {
291 @Override
292 SSLEngineResult unwrap(SslHandler handler, ByteBuf in, int len, ByteBuf out) throws SSLException {
293 int writerIndex = out.writerIndex();
294 ByteBuffer inNioBuffer = toByteBuffer(in, in.readerIndex(), len);
295 int position = inNioBuffer.position();
296 final SSLEngineResult result = handler.engine.unwrap(inNioBuffer,
297 toByteBuffer(out, writerIndex, out.writableBytes()));
298 out.writerIndex(writerIndex + result.bytesProduced());
299
300 // This is a workaround for a bug in Android 5.0. Android 5.0 does not correctly update the
301 // SSLEngineResult.bytesConsumed() in some cases and just return 0.
302 //
303 // See:
304 // - https://android-review.googlesource.com/c/platform/external/conscrypt/+/122080
305 // - https://github.com/netty/netty/issues/7758
306 if (result.bytesConsumed() == 0) {
307 int consumed = inNioBuffer.position() - position;
308 if (consumed != result.bytesConsumed()) {
309 // Create a new SSLEngineResult with the correct bytesConsumed().
310 return new SSLEngineResult(
311 result.getStatus(), result.getHandshakeStatus(), consumed, result.bytesProduced());
312 }
313 }
314 return result;
315 }
316
317 @Override
318 ByteBuf allocateWrapBuffer(SslHandler handler, ByteBufAllocator allocator,
319 int pendingBytes, int numComponents) {
320 // As for the JDK SSLEngine we always need to allocate buffers of the size required by the SSLEngine
321 // (normally ~16KB). This is required even if the amount of data to encrypt is very small. Use heap
322 // buffers to reduce the native memory usage.
323 //
324 // Beside this the JDK SSLEngine also (as of today) will do an extra heap to direct buffer copy
325 // if a direct buffer is used as its internals operate on byte[].
326 return allocator.heapBuffer(handler.engine.getSession().getPacketBufferSize());
327 }
328
329 @Override
330 int calculatePendingData(SslHandler handler, int guess) {
331 return guess;
332 }
333
334 @Override
335 boolean jdkCompatibilityMode(SSLEngine engine) {
336 return true;
337 }
338 };
339
340 static SslEngineType forEngine(SSLEngine engine) {
341 return engine instanceof ReferenceCountedOpenSslEngine ? TCNATIVE :
342 engine instanceof ConscryptAlpnSslEngine ? CONSCRYPT : JDK;
343 }
344
345 SslEngineType(boolean wantsDirectBuffer, Cumulator cumulator) {
346 this.wantsDirectBuffer = wantsDirectBuffer;
347 this.cumulator = cumulator;
348 }
349
350 abstract SSLEngineResult unwrap(SslHandler handler, ByteBuf in, int len, ByteBuf out) throws SSLException;
351
352 abstract int calculatePendingData(SslHandler handler, int guess);
353
354 abstract boolean jdkCompatibilityMode(SSLEngine engine);
355
356 abstract ByteBuf allocateWrapBuffer(SslHandler handler, ByteBufAllocator allocator,
357 int pendingBytes, int numComponents);
358
359 // BEGIN Platform-dependent flags
360
361 /**
362 * {@code true} if and only if {@link SSLEngine} expects a direct buffer and so if a heap buffer
363 * is given will make an extra memory copy.
364 */
365 final boolean wantsDirectBuffer;
366
367 // END Platform-dependent flags
368
369 /**
370 * When using JDK {@link SSLEngine}, we use {@link #MERGE_CUMULATOR} because it works only with
371 * one {@link ByteBuffer}.
372 *
373 * When using {@link OpenSslEngine}, we can use {@link #COMPOSITE_CUMULATOR} because it has
374 * {@link OpenSslEngine#unwrap(ByteBuffer[], ByteBuffer[])} which works with multiple {@link ByteBuffer}s
375 * and which does not need to do extra memory copies.
376 */
377 final Cumulator cumulator;
378 }
379
380 private volatile ChannelHandlerContext ctx;
381 private final SSLEngine engine;
382 private final SslEngineType engineType;
383 private final Executor delegatedTaskExecutor;
384 private final boolean jdkCompatibilityMode;
385
386 /**
387 * Used if {@link SSLEngine#wrap(ByteBuffer[], ByteBuffer)} and {@link SSLEngine#unwrap(ByteBuffer, ByteBuffer[])}
388 * should be called with a {@link ByteBuf} that is only backed by one {@link ByteBuffer} to reduce the object
389 * creation.
390 */
391 private final ByteBuffer[] singleBuffer = new ByteBuffer[1];
392
393 private final boolean startTls;
394
395 private final SslTasksRunner sslTaskRunnerForUnwrap = new SslTasksRunner(true);
396 private final SslTasksRunner sslTaskRunner = new SslTasksRunner(false);
397
398 private SslHandlerCoalescingBufferQueue pendingUnencryptedWrites;
399 private Promise<Channel> handshakePromise = new LazyChannelPromise();
400 private final LazyChannelPromise sslClosePromise = new LazyChannelPromise();
401
402 private int packetLength;
403 private short state;
404
405 private volatile long handshakeTimeoutMillis = 10000;
406 private volatile long closeNotifyFlushTimeoutMillis = 3000;
407 private volatile long closeNotifyReadTimeoutMillis;
408 volatile int wrapDataSize = MAX_PLAINTEXT_LENGTH;
409
410 /**
411 * Creates a new instance which runs all delegated tasks directly on the {@link EventExecutor}.
412 *
413 * @param engine the {@link SSLEngine} this handler will use
414 */
415 public SslHandler(SSLEngine engine) {
416 this(engine, false);
417 }
418
419 /**
420 * Creates a new instance which runs all delegated tasks directly on the {@link EventExecutor}.
421 *
422 * @param engine the {@link SSLEngine} this handler will use
423 * @param startTls {@code true} if the first write request shouldn't be
424 * encrypted by the {@link SSLEngine}
425 */
426 public SslHandler(SSLEngine engine, boolean startTls) {
427 this(engine, startTls, ImmediateExecutor.INSTANCE);
428 }
429
430 /**
431 * Creates a new instance.
432 *
433 * @param engine the {@link SSLEngine} this handler will use
434 * @param delegatedTaskExecutor the {@link Executor} that will be used to execute tasks that are returned by
435 * {@link SSLEngine#getDelegatedTask()}.
436 */
437 public SslHandler(SSLEngine engine, Executor delegatedTaskExecutor) {
438 this(engine, false, delegatedTaskExecutor);
439 }
440
441 /**
442 * Creates a new instance.
443 *
444 * @param engine the {@link SSLEngine} this handler will use
445 * @param startTls {@code true} if the first write request shouldn't be
446 * encrypted by the {@link SSLEngine}
447 * @param delegatedTaskExecutor the {@link Executor} that will be used to execute tasks that are returned by
448 * {@link SSLEngine#getDelegatedTask()}.
449 */
450 public SslHandler(SSLEngine engine, boolean startTls, Executor delegatedTaskExecutor) {
451 this.engine = ObjectUtil.checkNotNull(engine, "engine");
452 this.delegatedTaskExecutor = ObjectUtil.checkNotNull(delegatedTaskExecutor, "delegatedTaskExecutor");
453 engineType = SslEngineType.forEngine(engine);
454 this.startTls = startTls;
455 this.jdkCompatibilityMode = engineType.jdkCompatibilityMode(engine);
456 setCumulator(engineType.cumulator);
457 }
458
459 public long getHandshakeTimeoutMillis() {
460 return handshakeTimeoutMillis;
461 }
462
463 public void setHandshakeTimeout(long handshakeTimeout, TimeUnit unit) {
464 checkNotNull(unit, "unit");
465 setHandshakeTimeoutMillis(unit.toMillis(handshakeTimeout));
466 }
467
468 public void setHandshakeTimeoutMillis(long handshakeTimeoutMillis) {
469 this.handshakeTimeoutMillis = checkPositiveOrZero(handshakeTimeoutMillis, "handshakeTimeoutMillis");
470 }
471
472 /**
473 * Sets the number of bytes to pass to each {@link SSLEngine#wrap(ByteBuffer[], int, int, ByteBuffer)} call.
474 * <p>
475 * This value will partition data which is passed to write
476 * {@link #write(ChannelHandlerContext, Object, ChannelPromise)}. The partitioning will work as follows:
477 * <ul>
478 * <li>If {@code wrapDataSize <= 0} then we will write each data chunk as is.</li>
479 * <li>If {@code wrapDataSize > data size} then we will attempt to aggregate multiple data chunks together.</li>
480 * <li>If {@code wrapDataSize > data size} Else if {@code wrapDataSize <= data size} then we will divide the data
481 * into chunks of {@code wrapDataSize} when writing.</li>
482 * </ul>
483 * <p>
484 * If the {@link SSLEngine} doesn't support a gather wrap operation (e.g. {@link SslProvider#OPENSSL}) then
485 * aggregating data before wrapping can help reduce the ratio between TLS overhead vs data payload which will lead
486 * to better goodput. Writing fixed chunks of data can also help target the underlying transport's (e.g. TCP)
487 * frame size. Under lossy/congested network conditions this may help the peer get full TLS packets earlier and
488 * be able to do work sooner, as opposed to waiting for the all the pieces of the TLS packet to arrive.
489 * @param wrapDataSize the number of bytes which will be passed to each
490 * {@link SSLEngine#wrap(ByteBuffer[], int, int, ByteBuffer)} call.
491 */
492 @UnstableApi
493 public final void setWrapDataSize(int wrapDataSize) {
494 this.wrapDataSize = wrapDataSize;
495 }
496
497 /**
498 * @deprecated use {@link #getCloseNotifyFlushTimeoutMillis()}
499 */
500 @Deprecated
501 public long getCloseNotifyTimeoutMillis() {
502 return getCloseNotifyFlushTimeoutMillis();
503 }
504
505 /**
506 * @deprecated use {@link #setCloseNotifyFlushTimeout(long, TimeUnit)}
507 */
508 @Deprecated
509 public void setCloseNotifyTimeout(long closeNotifyTimeout, TimeUnit unit) {
510 setCloseNotifyFlushTimeout(closeNotifyTimeout, unit);
511 }
512
513 /**
514 * @deprecated use {@link #setCloseNotifyFlushTimeoutMillis(long)}
515 */
516 @Deprecated
517 public void setCloseNotifyTimeoutMillis(long closeNotifyFlushTimeoutMillis) {
518 setCloseNotifyFlushTimeoutMillis(closeNotifyFlushTimeoutMillis);
519 }
520
521 /**
522 * Gets the timeout for flushing the close_notify that was triggered by closing the
523 * {@link Channel}. If the close_notify was not flushed in the given timeout the {@link Channel} will be closed
524 * forcibly.
525 */
526 public final long getCloseNotifyFlushTimeoutMillis() {
527 return closeNotifyFlushTimeoutMillis;
528 }
529
530 /**
531 * Sets the timeout for flushing the close_notify that was triggered by closing the
532 * {@link Channel}. If the close_notify was not flushed in the given timeout the {@link Channel} will be closed
533 * forcibly.
534 */
535 public final void setCloseNotifyFlushTimeout(long closeNotifyFlushTimeout, TimeUnit unit) {
536 setCloseNotifyFlushTimeoutMillis(unit.toMillis(closeNotifyFlushTimeout));
537 }
538
539 /**
540 * See {@link #setCloseNotifyFlushTimeout(long, TimeUnit)}.
541 */
542 public final void setCloseNotifyFlushTimeoutMillis(long closeNotifyFlushTimeoutMillis) {
543 this.closeNotifyFlushTimeoutMillis = checkPositiveOrZero(closeNotifyFlushTimeoutMillis,
544 "closeNotifyFlushTimeoutMillis");
545 }
546
547 /**
548 * Gets the timeout (in ms) for receiving the response for the close_notify that was triggered by closing the
549 * {@link Channel}. This timeout starts after the close_notify message was successfully written to the
550 * remote peer. Use {@code 0} to directly close the {@link Channel} and not wait for the response.
551 */
552 public final long getCloseNotifyReadTimeoutMillis() {
553 return closeNotifyReadTimeoutMillis;
554 }
555
556 /**
557 * Sets the timeout for receiving the response for the close_notify that was triggered by closing the
558 * {@link Channel}. This timeout starts after the close_notify message was successfully written to the
559 * remote peer. Use {@code 0} to directly close the {@link Channel} and not wait for the response.
560 */
561 public final void setCloseNotifyReadTimeout(long closeNotifyReadTimeout, TimeUnit unit) {
562 setCloseNotifyReadTimeoutMillis(unit.toMillis(closeNotifyReadTimeout));
563 }
564
565 /**
566 * See {@link #setCloseNotifyReadTimeout(long, TimeUnit)}.
567 */
568 public final void setCloseNotifyReadTimeoutMillis(long closeNotifyReadTimeoutMillis) {
569 this.closeNotifyReadTimeoutMillis = checkPositiveOrZero(closeNotifyReadTimeoutMillis,
570 "closeNotifyReadTimeoutMillis");
571 }
572
573 /**
574 * Returns the {@link SSLEngine} which is used by this handler.
575 */
576 public SSLEngine engine() {
577 return engine;
578 }
579
580 /**
581 * Returns the name of the current application-level protocol.
582 *
583 * @return the protocol name or {@code null} if application-level protocol has not been negotiated
584 */
585 public String applicationProtocol() {
586 SSLEngine engine = engine();
587 if (!(engine instanceof ApplicationProtocolAccessor)) {
588 return null;
589 }
590
591 return ((ApplicationProtocolAccessor) engine).getNegotiatedApplicationProtocol();
592 }
593
594 /**
595 * Returns a {@link Future} that will get notified once the current TLS handshake completes.
596 *
597 * @return the {@link Future} for the initial TLS handshake if {@link #renegotiate()} was not invoked.
598 * The {@link Future} for the most recent {@linkplain #renegotiate() TLS renegotiation} otherwise.
599 */
600 public Future<Channel> handshakeFuture() {
601 return handshakePromise;
602 }
603
604 /**
605 * Use {@link #closeOutbound()}
606 */
607 @Deprecated
608 public ChannelFuture close() {
609 return closeOutbound();
610 }
611
612 /**
613 * Use {@link #closeOutbound(ChannelPromise)}
614 */
615 @Deprecated
616 public ChannelFuture close(ChannelPromise promise) {
617 return closeOutbound(promise);
618 }
619
620 /**
621 * Sends an SSL {@code close_notify} message to the specified channel and
622 * destroys the underlying {@link SSLEngine}. This will <strong>not</strong> close the underlying
623 * {@link Channel}. If you want to also close the {@link Channel} use {@link Channel#close()} or
624 * {@link ChannelHandlerContext#close()}
625 */
626 public ChannelFuture closeOutbound() {
627 return closeOutbound(ctx.newPromise());
628 }
629
630 /**
631 * Sends an SSL {@code close_notify} message to the specified channel and
632 * destroys the underlying {@link SSLEngine}. This will <strong>not</strong> close the underlying
633 * {@link Channel}. If you want to also close the {@link Channel} use {@link Channel#close()} or
634 * {@link ChannelHandlerContext#close()}
635 */
636 public ChannelFuture closeOutbound(final ChannelPromise promise) {
637 final ChannelHandlerContext ctx = this.ctx;
638 if (ctx.executor().inEventLoop()) {
639 closeOutbound0(promise);
640 } else {
641 ctx.executor().execute(new Runnable() {
642 @Override
643 public void run() {
644 closeOutbound0(promise);
645 }
646 });
647 }
648 return promise;
649 }
650
651 private void closeOutbound0(ChannelPromise promise) {
652 setState(STATE_OUTBOUND_CLOSED);
653 engine.closeOutbound();
654 try {
655 flush(ctx, promise);
656 } catch (Exception e) {
657 if (!promise.tryFailure(e)) {
658 logger.warn("{} flush() raised a masked exception.", ctx.channel(), e);
659 }
660 }
661 }
662
663 /**
664 * Return the {@link Future} that will get notified if the inbound of the {@link SSLEngine} is closed.
665 *
666 * This method will return the same {@link Future} all the time.
667 *
668 * @see SSLEngine
669 */
670 public Future<Channel> sslCloseFuture() {
671 return sslClosePromise;
672 }
673
674 @Override
675 public void handlerRemoved0(ChannelHandlerContext ctx) throws Exception {
676 try {
677 if (pendingUnencryptedWrites != null && !pendingUnencryptedWrites.isEmpty()) {
678 // Check if queue is not empty first because create a new ChannelException is expensive
679 pendingUnencryptedWrites.releaseAndFailAll(ctx,
680 new ChannelException("Pending write on removal of SslHandler"));
681 }
682 pendingUnencryptedWrites = null;
683
684 SSLException cause = null;
685
686 // If the handshake or SSLEngine closure is not done yet we should fail corresponding promise and
687 // notify the rest of the
688 // pipeline.
689 if (!handshakePromise.isDone()) {
690 cause = new SSLHandshakeException("SslHandler removed before handshake completed");
691 if (handshakePromise.tryFailure(cause)) {
692 ctx.fireUserEventTriggered(new SslHandshakeCompletionEvent(cause));
693 }
694 }
695 if (!sslClosePromise.isDone()) {
696 if (cause == null) {
697 cause = new SSLException("SslHandler removed before SSLEngine was closed");
698 }
699 notifyClosePromise(cause);
700 }
701 } finally {
702 ReferenceCountUtil.release(engine);
703 }
704 }
705
706 @Override
707 public void bind(ChannelHandlerContext ctx, SocketAddress localAddress, ChannelPromise promise) throws Exception {
708 ctx.bind(localAddress, promise);
709 }
710
711 @Override
712 public void connect(ChannelHandlerContext ctx, SocketAddress remoteAddress, SocketAddress localAddress,
713 ChannelPromise promise) throws Exception {
714 ctx.connect(remoteAddress, localAddress, promise);
715 }
716
717 @Override
718 public void deregister(ChannelHandlerContext ctx, ChannelPromise promise) throws Exception {
719 ctx.deregister(promise);
720 }
721
722 @Override
723 public void disconnect(final ChannelHandlerContext ctx,
724 final ChannelPromise promise) throws Exception {
725 closeOutboundAndChannel(ctx, promise, true);
726 }
727
728 @Override
729 public void close(final ChannelHandlerContext ctx,
730 final ChannelPromise promise) throws Exception {
731 closeOutboundAndChannel(ctx, promise, false);
732 }
733
734 @Override
735 public void read(ChannelHandlerContext ctx) throws Exception {
736 if (!handshakePromise.isDone()) {
737 setState(STATE_READ_DURING_HANDSHAKE);
738 }
739
740 ctx.read();
741 }
742
743 private static IllegalStateException newPendingWritesNullException() {
744 return new IllegalStateException("pendingUnencryptedWrites is null, handlerRemoved0 called?");
745 }
746
747 @Override
748 public void write(final ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception {
749 if (!(msg instanceof ByteBuf)) {
750 UnsupportedMessageTypeException exception = new UnsupportedMessageTypeException(msg, ByteBuf.class);
751 ReferenceCountUtil.safeRelease(msg);
752 promise.setFailure(exception);
753 } else if (pendingUnencryptedWrites == null) {
754 ReferenceCountUtil.safeRelease(msg);
755 promise.setFailure(newPendingWritesNullException());
756 } else {
757 pendingUnencryptedWrites.add((ByteBuf) msg, promise);
758 }
759 }
760
761 @Override
762 public void flush(ChannelHandlerContext ctx) throws Exception {
763 // Do not encrypt the first write request if this handler is
764 // created with startTLS flag turned on.
765 if (startTls && !isStateSet(STATE_SENT_FIRST_MESSAGE)) {
766 setState(STATE_SENT_FIRST_MESSAGE);
767 pendingUnencryptedWrites.writeAndRemoveAll(ctx);
768 forceFlush(ctx);
769 // Explicit start handshake processing once we send the first message. This will also ensure
770 // we will schedule the timeout if needed.
771 startHandshakeProcessing(true);
772 return;
773 }
774
775 if (isStateSet(STATE_PROCESS_TASK)) {
776 return;
777 }
778
779 try {
780 wrapAndFlush(ctx);
781 } catch (Throwable cause) {
782 setHandshakeFailure(ctx, cause);
783 PlatformDependent.throwException(cause);
784 }
785 }
786
787 private void wrapAndFlush(ChannelHandlerContext ctx) throws SSLException {
788 if (pendingUnencryptedWrites.isEmpty()) {
789 // It's important to NOT use a voidPromise here as the user
790 // may want to add a ChannelFutureListener to the ChannelPromise later.
791 //
792 // See https://github.com/netty/netty/issues/3364
793 pendingUnencryptedWrites.add(Unpooled.EMPTY_BUFFER, ctx.newPromise());
794 }
795 if (!handshakePromise.isDone()) {
796 setState(STATE_FLUSHED_BEFORE_HANDSHAKE);
797 }
798 try {
799 wrap(ctx, false);
800 } finally {
801 // We may have written some parts of data before an exception was thrown so ensure we always flush.
802 // See https://github.com/netty/netty/issues/3900#issuecomment-172481830
803 forceFlush(ctx);
804 }
805 }
806
807 // This method will not call setHandshakeFailure(...) !
808 private void wrap(ChannelHandlerContext ctx, boolean inUnwrap) throws SSLException {
809 ByteBuf out = null;
810 ByteBufAllocator alloc = ctx.alloc();
811 try {
812 final int wrapDataSize = this.wrapDataSize;
813 // Only continue to loop if the handler was not removed in the meantime.
814 // See https://github.com/netty/netty/issues/5860
815 outer: while (!ctx.isRemoved()) {
816 ChannelPromise promise = ctx.newPromise();
817 ByteBuf buf = wrapDataSize > 0 ?
818 pendingUnencryptedWrites.remove(alloc, wrapDataSize, promise) :
819 pendingUnencryptedWrites.removeFirst(promise);
820 if (buf == null) {
821 break;
822 }
823
824 if (out == null) {
825 out = allocateOutNetBuf(ctx, buf.readableBytes(), buf.nioBufferCount());
826 }
827
828 SSLEngineResult result = wrap(alloc, engine, buf, out);
829 if (buf.isReadable()) {
830 pendingUnencryptedWrites.addFirst(buf, promise);
831 // When we add the buffer/promise pair back we need to be sure we don't complete the promise
832 // later. We only complete the promise if the buffer is completely consumed.
833 promise = null;
834 } else {
835 buf.release();
836 }
837
838 // We need to write any data before we invoke any methods which may trigger re-entry, otherwise
839 // writes may occur out of order and TLS sequencing may be off (e.g. SSLV3_ALERT_BAD_RECORD_MAC).
840 if (out.isReadable()) {
841 final ByteBuf b = out;
842 out = null;
843 if (promise != null) {
844 ctx.write(b, promise);
845 } else {
846 ctx.write(b);
847 }
848 } else if (promise != null) {
849 ctx.write(Unpooled.EMPTY_BUFFER, promise);
850 }
851 // else out is not readable we can re-use it and so save an extra allocation
852
853 if (result.getStatus() == Status.CLOSED) {
854 // Make a best effort to preserve any exception that way previously encountered from the handshake
855 // or the transport, else fallback to a general error.
856 Throwable exception = handshakePromise.cause();
857 if (exception == null) {
858 exception = sslClosePromise.cause();
859 if (exception == null) {
860 exception = new SslClosedEngineException("SSLEngine closed already");
861 }
862 }
863 pendingUnencryptedWrites.releaseAndFailAll(ctx, exception);
864 return;
865 } else {
866 switch (result.getHandshakeStatus()) {
867 case NEED_TASK:
868 if (!runDelegatedTasks(inUnwrap)) {
869 // We scheduled a task on the delegatingTaskExecutor, so stop processing as we will
870 // resume once the task completes.
871 break outer;
872 }
873 break;
874 case FINISHED:
875 case NOT_HANDSHAKING: // work around for android bug that skips the FINISHED state.
876 setHandshakeSuccess();
877 break;
878 case NEED_WRAP:
879 // If we are expected to wrap again and we produced some data we need to ensure there
880 // is something in the queue to process as otherwise we will not try again before there
881 // was more added. Failing to do so may fail to produce an alert that can be
882 // consumed by the remote peer.
883 if (result.bytesProduced() > 0 && pendingUnencryptedWrites.isEmpty()) {
884 pendingUnencryptedWrites.add(Unpooled.EMPTY_BUFFER);
885 }
886 break;
887 case NEED_UNWRAP:
888 // The underlying engine is starving so we need to feed it with more data.
889 // See https://github.com/netty/netty/pull/5039
890 readIfNeeded(ctx);
891 return;
892 default:
893 throw new IllegalStateException(
894 "Unknown handshake status: " + result.getHandshakeStatus());
895 }
896 }
897 }
898 } finally {
899 if (out != null) {
900 out.release();
901 }
902 if (inUnwrap) {
903 setState(STATE_NEEDS_FLUSH);
904 }
905 }
906 }
907
908 /**
909 * This method will not call
910 * {@link #setHandshakeFailure(ChannelHandlerContext, Throwable, boolean, boolean, boolean)} or
911 * {@link #setHandshakeFailure(ChannelHandlerContext, Throwable)}.
912 * @return {@code true} if this method ends on {@link SSLEngineResult.HandshakeStatus#NOT_HANDSHAKING}.
913 */
914 private boolean wrapNonAppData(final ChannelHandlerContext ctx, boolean inUnwrap) throws SSLException {
915 ByteBuf out = null;
916 ByteBufAllocator alloc = ctx.alloc();
917 try {
918 // Only continue to loop if the handler was not removed in the meantime.
919 // See https://github.com/netty/netty/issues/5860
920 outer: while (!ctx.isRemoved()) {
921 if (out == null) {
922 // As this is called for the handshake we have no real idea how big the buffer needs to be.
923 // That said 2048 should give us enough room to include everything like ALPN / NPN data.
924 // If this is not enough we will increase the buffer in wrap(...).
925 out = allocateOutNetBuf(ctx, 2048, 1);
926 }
927 SSLEngineResult result = wrap(alloc, engine, Unpooled.EMPTY_BUFFER, out);
928 if (result.bytesProduced() > 0) {
929 ctx.write(out).addListener(new ChannelFutureListener() {
930 @Override
931 public void operationComplete(ChannelFuture future) {
932 Throwable cause = future.cause();
933 if (cause != null) {
934 setHandshakeFailureTransportFailure(ctx, cause);
935 }
936 }
937 });
938 if (inUnwrap) {
939 setState(STATE_NEEDS_FLUSH);
940 }
941 out = null;
942 }
943
944 HandshakeStatus status = result.getHandshakeStatus();
945 switch (status) {
946 case FINISHED:
947 // We may be here because we read data and discovered the remote peer initiated a renegotiation
948 // and this write is to complete the new handshake. The user may have previously done a
949 // writeAndFlush which wasn't able to wrap data due to needing the pending handshake, so we
950 // attempt to wrap application data here if any is pending.
951 if (setHandshakeSuccess() && inUnwrap && !pendingUnencryptedWrites.isEmpty()) {
952 wrap(ctx, true);
953 }
954 return false;
955 case NEED_TASK:
956 if (!runDelegatedTasks(inUnwrap)) {
957 // We scheduled a task on the delegatingTaskExecutor, so stop processing as we will
958 // resume once the task completes.
959 break outer;
960 }
961 break;
962 case NEED_UNWRAP:
963 if (inUnwrap || unwrapNonAppData(ctx) <= 0) {
964 // If we asked for a wrap, the engine requested an unwrap, and we are in unwrap there is
965 // no use in trying to call wrap again because we have already attempted (or will after we
966 // return) to feed more data to the engine.
967 return false;
968 }
969 break;
970 case NEED_WRAP:
971 break;
972 case NOT_HANDSHAKING:
973 if (setHandshakeSuccess() && inUnwrap && !pendingUnencryptedWrites.isEmpty()) {
974 wrap(ctx, true);
975 }
976 // Workaround for TLS False Start problem reported at:
977 // https://github.com/netty/netty/issues/1108#issuecomment-14266970
978 if (!inUnwrap) {
979 unwrapNonAppData(ctx);
980 }
981 return true;
982 default:
983 throw new IllegalStateException("Unknown handshake status: " + result.getHandshakeStatus());
984 }
985
986 // Check if did not produce any bytes and if so break out of the loop, but only if we did not process
987 // a task as last action. It's fine to not produce any data as part of executing a task.
988 if (result.bytesProduced() == 0 && status != HandshakeStatus.NEED_TASK) {
989 break;
990 }
991
992 // It should not consume empty buffers when it is not handshaking
993 // Fix for Android, where it was encrypting empty buffers even when not handshaking
994 if (result.bytesConsumed() == 0 && result.getHandshakeStatus() == HandshakeStatus.NOT_HANDSHAKING) {
995 break;
996 }
997 }
998 } finally {
999 if (out != null) {
1000 out.release();
1001 }
1002 }
1003 return false;
1004 }
1005
1006 private SSLEngineResult wrap(ByteBufAllocator alloc, SSLEngine engine, ByteBuf in, ByteBuf out)
1007 throws SSLException {
1008 ByteBuf newDirectIn = null;
1009 try {
1010 int readerIndex = in.readerIndex();
1011 int readableBytes = in.readableBytes();
1012
1013 // We will call SslEngine.wrap(ByteBuffer[], ByteBuffer) to allow efficient handling of
1014 // CompositeByteBuf without force an extra memory copy when CompositeByteBuffer.nioBuffer() is called.
1015 final ByteBuffer[] in0;
1016 if (in.isDirect() || !engineType.wantsDirectBuffer) {
1017 // As CompositeByteBuf.nioBufferCount() can be expensive (as it needs to check all composed ByteBuf
1018 // to calculate the count) we will just assume a CompositeByteBuf contains more then 1 ByteBuf.
1019 // The worst that can happen is that we allocate an extra ByteBuffer[] in CompositeByteBuf.nioBuffers()
1020 // which is better then walking the composed ByteBuf in most cases.
1021 if (!(in instanceof CompositeByteBuf) && in.nioBufferCount() == 1) {
1022 in0 = singleBuffer;
1023 // We know its only backed by 1 ByteBuffer so use internalNioBuffer to keep object allocation
1024 // to a minimum.
1025 in0[0] = in.internalNioBuffer(readerIndex, readableBytes);
1026 } else {
1027 in0 = in.nioBuffers();
1028 }
1029 } else {
1030 // We could even go further here and check if its a CompositeByteBuf and if so try to decompose it and
1031 // only replace the ByteBuffer that are not direct. At the moment we just will replace the whole
1032 // CompositeByteBuf to keep the complexity to a minimum
1033 newDirectIn = alloc.directBuffer(readableBytes);
1034 newDirectIn.writeBytes(in, readerIndex, readableBytes);
1035 in0 = singleBuffer;
1036 in0[0] = newDirectIn.internalNioBuffer(newDirectIn.readerIndex(), readableBytes);
1037 }
1038
1039 for (;;) {
1040 ByteBuffer out0 = out.nioBuffer(out.writerIndex(), out.writableBytes());
1041 SSLEngineResult result = engine.wrap(in0, out0);
1042 in.skipBytes(result.bytesConsumed());
1043 out.writerIndex(out.writerIndex() + result.bytesProduced());
1044
1045 if (result.getStatus() == Status.BUFFER_OVERFLOW) {
1046 out.ensureWritable(engine.getSession().getPacketBufferSize());
1047 } else {
1048 return result;
1049 }
1050 }
1051 } finally {
1052 // Null out to allow GC of ByteBuffer
1053 singleBuffer[0] = null;
1054
1055 if (newDirectIn != null) {
1056 newDirectIn.release();
1057 }
1058 }
1059 }
1060
1061 @Override
1062 public void channelInactive(ChannelHandlerContext ctx) throws Exception {
1063 boolean handshakeFailed = handshakePromise.cause() != null;
1064
1065 ClosedChannelException exception = new ClosedChannelException();
1066 // Make sure to release SSLEngine,
1067 // and notify the handshake future if the connection has been closed during handshake.
1068 setHandshakeFailure(ctx, exception, !isStateSet(STATE_OUTBOUND_CLOSED), isStateSet(STATE_HANDSHAKE_STARTED),
1069 false);
1070
1071 // Ensure we always notify the sslClosePromise as well
1072 notifyClosePromise(exception);
1073
1074 try {
1075 super.channelInactive(ctx);
1076 } catch (DecoderException e) {
1077 if (!handshakeFailed || !(e.getCause() instanceof SSLException)) {
1078 // We only rethrow the exception if the handshake did not fail before channelInactive(...) was called
1079 // as otherwise this may produce duplicated failures as super.channelInactive(...) will also call
1080 // channelRead(...).
1081 //
1082 // See https://github.com/netty/netty/issues/10119
1083 throw e;
1084 }
1085 }
1086 }
1087
1088 @Override
1089 public void exceptionCaught(ChannelHandlerContext ctx, Throwable cause) throws Exception {
1090 if (ignoreException(cause)) {
1091 // It is safe to ignore the 'connection reset by peer' or
1092 // 'broken pipe' error after sending close_notify.
1093 if (logger.isDebugEnabled()) {
1094 logger.debug(
1095 "{} Swallowing a harmless 'connection reset by peer / broken pipe' error that occurred " +
1096 "while writing close_notify in response to the peer's close_notify", ctx.channel(), cause);
1097 }
1098
1099 // Close the connection explicitly just in case the transport
1100 // did not close the connection automatically.
1101 if (ctx.channel().isActive()) {
1102 ctx.close();
1103 }
1104 } else {
1105 ctx.fireExceptionCaught(cause);
1106 }
1107 }
1108
1109 /**
1110 * Checks if the given {@link Throwable} can be ignore and just "swallowed"
1111 *
1112 * When an ssl connection is closed a close_notify message is sent.
1113 * After that the peer also sends close_notify however, it's not mandatory to receive
1114 * the close_notify. The party who sent the initial close_notify can close the connection immediately
1115 * then the peer will get connection reset error.
1116 *
1117 */
1118 private boolean ignoreException(Throwable t) {
1119 if (!(t instanceof SSLException) && t instanceof IOException && sslClosePromise.isDone()) {
1120 String message = t.getMessage();
1121
1122 // first try to match connection reset / broke peer based on the regex. This is the fastest way
1123 // but may fail on different jdk impls or OS's
1124 if (message != null && IGNORABLE_ERROR_MESSAGE.matcher(message).matches()) {
1125 return true;
1126 }
1127
1128 // Inspect the StackTraceElements to see if it was a connection reset / broken pipe or not
1129 StackTraceElement[] elements = t.getStackTrace();
1130 for (StackTraceElement element: elements) {
1131 String classname = element.getClassName();
1132 String methodname = element.getMethodName();
1133
1134 // skip all classes that belong to the io.netty package
1135 if (classname.startsWith("io.netty.")) {
1136 continue;
1137 }
1138
1139 // check if the method name is read if not skip it
1140 if (!"read".equals(methodname)) {
1141 continue;
1142 }
1143
1144 // This will also match against SocketInputStream which is used by openjdk 7 and maybe
1145 // also others
1146 if (IGNORABLE_CLASS_IN_STACK.matcher(classname).matches()) {
1147 return true;
1148 }
1149
1150 try {
1151 // No match by now.. Try to load the class via classloader and inspect it.
1152 // This is mainly done as other JDK implementations may differ in name of
1153 // the impl.
1154 Class<?> clazz = PlatformDependent.getClassLoader(getClass()).loadClass(classname);
1155
1156 if (SocketChannel.class.isAssignableFrom(clazz)
1157 || DatagramChannel.class.isAssignableFrom(clazz)) {
1158 return true;
1159 }
1160
1161 // also match against SctpChannel via String matching as it may not present.
1162 if (PlatformDependent.javaVersion() >= 7
1163 && "com.sun.nio.sctp.SctpChannel".equals(clazz.getSuperclass().getName())) {
1164 return true;
1165 }
1166 } catch (Throwable cause) {
1167 if (logger.isDebugEnabled()) {
1168 logger.debug("Unexpected exception while loading class {} classname {}",
1169 getClass(), classname, cause);
1170 }
1171 }
1172 }
1173 }
1174
1175 return false;
1176 }
1177
1178 /**
1179 * Returns {@code true} if the given {@link ByteBuf} is encrypted. Be aware that this method
1180 * will not increase the readerIndex of the given {@link ByteBuf}.
1181 *
1182 * @param buffer
1183 * The {@link ByteBuf} to read from. Be aware that it must have at least 5 bytes to read,
1184 * otherwise it will throw an {@link IllegalArgumentException}.
1185 * @return encrypted
1186 * {@code true} if the {@link ByteBuf} is encrypted, {@code false} otherwise.
1187 * @throws IllegalArgumentException
1188 * Is thrown if the given {@link ByteBuf} has not at least 5 bytes to read.
1189 */
1190 public static boolean isEncrypted(ByteBuf buffer) {
1191 if (buffer.readableBytes() < SslUtils.SSL_RECORD_HEADER_LENGTH) {
1192 throw new IllegalArgumentException(
1193 "buffer must have at least " + SslUtils.SSL_RECORD_HEADER_LENGTH + " readable bytes");
1194 }
1195 return getEncryptedPacketLength(buffer, buffer.readerIndex()) != SslUtils.NOT_ENCRYPTED;
1196 }
1197
1198 private void decodeJdkCompatible(ChannelHandlerContext ctx, ByteBuf in) throws NotSslRecordException {
1199 int packetLength = this.packetLength;
1200 // If we calculated the length of the current SSL record before, use that information.
1201 if (packetLength > 0) {
1202 if (in.readableBytes() < packetLength) {
1203 return;
1204 }
1205 } else {
1206 // Get the packet length and wait until we get a packets worth of data to unwrap.
1207 final int readableBytes = in.readableBytes();
1208 if (readableBytes < SslUtils.SSL_RECORD_HEADER_LENGTH) {
1209 return;
1210 }
1211 packetLength = getEncryptedPacketLength(in, in.readerIndex());
1212 if (packetLength == SslUtils.NOT_ENCRYPTED) {
1213 // Not an SSL/TLS packet
1214 NotSslRecordException e = new NotSslRecordException(
1215 "not an SSL/TLS record: " + ByteBufUtil.hexDump(in));
1216 in.skipBytes(in.readableBytes());
1217
1218 // First fail the handshake promise as we may need to have access to the SSLEngine which may
1219 // be released because the user will remove the SslHandler in an exceptionCaught(...) implementation.
1220 setHandshakeFailure(ctx, e);
1221
1222 throw e;
1223 }
1224 assert packetLength > 0;
1225 if (packetLength > readableBytes) {
1226 // wait until the whole packet can be read
1227 this.packetLength = packetLength;
1228 return;
1229 }
1230 }
1231
1232 // Reset the state of this class so we can get the length of the next packet. We assume the entire packet will
1233 // be consumed by the SSLEngine.
1234 this.packetLength = 0;
1235 try {
1236 final int bytesConsumed = unwrap(ctx, in, packetLength);
1237 assert bytesConsumed == packetLength || engine.isInboundDone() :
1238 "we feed the SSLEngine a packets worth of data: " + packetLength + " but it only consumed: " +
1239 bytesConsumed;
1240 } catch (Throwable cause) {
1241 handleUnwrapThrowable(ctx, cause);
1242 }
1243 }
1244
1245 private void decodeNonJdkCompatible(ChannelHandlerContext ctx, ByteBuf in) {
1246 try {
1247 unwrap(ctx, in, in.readableBytes());
1248 } catch (Throwable cause) {
1249 handleUnwrapThrowable(ctx, cause);
1250 }
1251 }
1252
1253 private void handleUnwrapThrowable(ChannelHandlerContext ctx, Throwable cause) {
1254 try {
1255 // We should attempt to notify the handshake failure before writing any pending data. If we are in unwrap
1256 // and failed during the handshake process, and we attempt to wrap, then promises will fail, and if
1257 // listeners immediately close the Channel then we may end up firing the handshake event after the Channel
1258 // has been closed.
1259 if (handshakePromise.tryFailure(cause)) {
1260 ctx.fireUserEventTriggered(new SslHandshakeCompletionEvent(cause));
1261 }
1262
1263 // Let's check if the handler was removed in the meantime and so pendingUnencryptedWrites is null.
1264 if (pendingUnencryptedWrites != null) {
1265 // We need to flush one time as there may be an alert that we should send to the remote peer because
1266 // of the SSLException reported here.
1267 wrapAndFlush(ctx);
1268 }
1269 } catch (SSLException ex) {
1270 logger.debug("SSLException during trying to call SSLEngine.wrap(...)" +
1271 " because of an previous SSLException, ignoring...", ex);
1272 } finally {
1273 // ensure we always flush and close the channel.
1274 setHandshakeFailure(ctx, cause, true, false, true);
1275 }
1276 PlatformDependent.throwException(cause);
1277 }
1278
1279 @Override
1280 protected void decode(ChannelHandlerContext ctx, ByteBuf in, List<Object> out) throws SSLException {
1281 if (isStateSet(STATE_PROCESS_TASK)) {
1282 return;
1283 }
1284 if (jdkCompatibilityMode) {
1285 decodeJdkCompatible(ctx, in);
1286 } else {
1287 decodeNonJdkCompatible(ctx, in);
1288 }
1289 }
1290
1291 @Override
1292 public void channelReadComplete(ChannelHandlerContext ctx) throws Exception {
1293 channelReadComplete0(ctx);
1294 }
1295
1296 private void channelReadComplete0(ChannelHandlerContext ctx) {
1297 // Discard bytes of the cumulation buffer if needed.
1298 discardSomeReadBytes();
1299
1300 flushIfNeeded(ctx);
1301 readIfNeeded(ctx);
1302
1303 clearState(STATE_FIRE_CHANNEL_READ);
1304 ctx.fireChannelReadComplete();
1305 }
1306
1307 private void readIfNeeded(ChannelHandlerContext ctx) {
1308 // If handshake is not finished yet, we need more data.
1309 if (!ctx.channel().config().isAutoRead() &&
1310 (!isStateSet(STATE_FIRE_CHANNEL_READ) || !handshakePromise.isDone())) {
1311 // No auto-read used and no message passed through the ChannelPipeline or the handshake was not complete
1312 // yet, which means we need to trigger the read to ensure we not encounter any stalls.
1313 ctx.read();
1314 }
1315 }
1316
1317 private void flushIfNeeded(ChannelHandlerContext ctx) {
1318 if (isStateSet(STATE_NEEDS_FLUSH)) {
1319 forceFlush(ctx);
1320 }
1321 }
1322
1323 /**
1324 * Calls {@link SSLEngine#unwrap(ByteBuffer, ByteBuffer)} with an empty buffer to handle handshakes, etc.
1325 */
1326 private int unwrapNonAppData(ChannelHandlerContext ctx) throws SSLException {
1327 return unwrap(ctx, Unpooled.EMPTY_BUFFER, 0);
1328 }
1329
1330 /**
1331 * Unwraps inbound SSL records.
1332 */
1333 private int unwrap(ChannelHandlerContext ctx, ByteBuf packet, int length) throws SSLException {
1334 final int originalLength = length;
1335 boolean wrapLater = false;
1336 boolean notifyClosure = false;
1337 boolean executedRead = false;
1338 ByteBuf decodeOut = allocate(ctx, length);
1339 try {
1340 // Only continue to loop if the handler was not removed in the meantime.
1341 // See https://github.com/netty/netty/issues/5860
1342 do {
1343 final SSLEngineResult result = engineType.unwrap(this, packet, length, decodeOut);
1344 final Status status = result.getStatus();
1345 final HandshakeStatus handshakeStatus = result.getHandshakeStatus();
1346 final int produced = result.bytesProduced();
1347 final int consumed = result.bytesConsumed();
1348
1349 // Skip bytes now in case unwrap is called in a re-entry scenario. For example LocalChannel.read()
1350 // may entry this method in a re-entry fashion and if the peer is writing into a shared buffer we may
1351 // unwrap the same data multiple times.
1352 packet.skipBytes(consumed);
1353 length -= consumed;
1354
1355 // The expected sequence of events is:
1356 // 1. Notify of handshake success
1357 // 2. fireChannelRead for unwrapped data
1358 if (handshakeStatus == HandshakeStatus.FINISHED || handshakeStatus == HandshakeStatus.NOT_HANDSHAKING) {
1359 wrapLater |= (decodeOut.isReadable() ?
1360 setHandshakeSuccessUnwrapMarkReentry() : setHandshakeSuccess()) ||
1361 handshakeStatus == HandshakeStatus.FINISHED;
1362 }
1363
1364 // Dispatch decoded data after we have notified of handshake success. If this method has been invoked
1365 // in a re-entry fashion we execute a task on the executor queue to process after the stack unwinds
1366 // to preserve order of events.
1367 if (decodeOut.isReadable()) {
1368 setState(STATE_FIRE_CHANNEL_READ);
1369 if (isStateSet(STATE_UNWRAP_REENTRY)) {
1370 executedRead = true;
1371 executeChannelRead(ctx, decodeOut);
1372 } else {
1373 ctx.fireChannelRead(decodeOut);
1374 }
1375 decodeOut = null;
1376 }
1377
1378 if (status == Status.CLOSED) {
1379 notifyClosure = true; // notify about the CLOSED state of the SSLEngine. See #137
1380 } else if (status == Status.BUFFER_OVERFLOW) {
1381 if (decodeOut != null) {
1382 decodeOut.release();
1383 }
1384 final int applicationBufferSize = engine.getSession().getApplicationBufferSize();
1385 // Allocate a new buffer which can hold all the rest data and loop again.
1386 // It may happen that applicationBufferSize < produced while there is still more to unwrap, in this
1387 // case we will just allocate a new buffer with the capacity of applicationBufferSize and call
1388 // unwrap again.
1389 decodeOut = allocate(ctx, engineType.calculatePendingData(this, applicationBufferSize < produced ?
1390 applicationBufferSize : applicationBufferSize - produced));
1391 continue;
1392 }
1393
1394 if (handshakeStatus == HandshakeStatus.NEED_TASK) {
1395 boolean pending = runDelegatedTasks(true);
1396 if (!pending) {
1397 // We scheduled a task on the delegatingTaskExecutor, so stop processing as we will
1398 // resume once the task completes.
1399 //
1400 // We break out of the loop only and do NOT return here as we still may need to notify
1401 // about the closure of the SSLEngine.
1402 wrapLater = false;
1403 break;
1404 }
1405 } else if (handshakeStatus == HandshakeStatus.NEED_WRAP) {
1406 // If the wrap operation transitions the status to NOT_HANDSHAKING and there is no more data to
1407 // unwrap then the next call to unwrap will not produce any data. We can avoid the potentially
1408 // costly unwrap operation and break out of the loop.
1409 if (wrapNonAppData(ctx, true) && length == 0) {
1410 break;
1411 }
1412 }
1413
1414 if (status == Status.BUFFER_UNDERFLOW ||
1415 // If we processed NEED_TASK we should try again even we did not consume or produce anything.
1416 handshakeStatus != HandshakeStatus.NEED_TASK && (consumed == 0 && produced == 0 ||
1417 (length == 0 && handshakeStatus == HandshakeStatus.NOT_HANDSHAKING))) {
1418 if (handshakeStatus == HandshakeStatus.NEED_UNWRAP) {
1419 // The underlying engine is starving so we need to feed it with more data.
1420 // See https://github.com/netty/netty/pull/5039
1421 readIfNeeded(ctx);
1422 }
1423
1424 break;
1425 } else if (decodeOut == null) {
1426 decodeOut = allocate(ctx, length);
1427 }
1428 } while (!ctx.isRemoved());
1429
1430 if (isStateSet(STATE_FLUSHED_BEFORE_HANDSHAKE) && handshakePromise.isDone()) {
1431 // We need to call wrap(...) in case there was a flush done before the handshake completed to ensure
1432 // we do not stale.
1433 //
1434 // See https://github.com/netty/netty/pull/2437
1435 clearState(STATE_FLUSHED_BEFORE_HANDSHAKE);
1436 wrapLater = true;
1437 }
1438
1439 if (wrapLater) {
1440 wrap(ctx, true);
1441 }
1442 } finally {
1443 if (decodeOut != null) {
1444 decodeOut.release();
1445 }
1446
1447 if (notifyClosure) {
1448 if (executedRead) {
1449 executeNotifyClosePromise(ctx);
1450 } else {
1451 notifyClosePromise(null);
1452 }
1453 }
1454 }
1455 return originalLength - length;
1456 }
1457
1458 private boolean setHandshakeSuccessUnwrapMarkReentry() {
1459 // setHandshakeSuccess calls out to external methods which may trigger re-entry. We need to preserve ordering of
1460 // fireChannelRead for decodeOut relative to re-entry data.
1461 final boolean setReentryState = !isStateSet(STATE_UNWRAP_REENTRY);
1462 if (setReentryState) {
1463 setState(STATE_UNWRAP_REENTRY);
1464 }
1465 try {
1466 return setHandshakeSuccess();
1467 } finally {
1468 // It is unlikely this specific method will be re-entry because handshake completion is infrequent, but just
1469 // in case we only clear the state if we set it in the first place.
1470 if (setReentryState) {
1471 clearState(STATE_UNWRAP_REENTRY);
1472 }
1473 }
1474 }
1475
1476 private void executeNotifyClosePromise(final ChannelHandlerContext ctx) {
1477 try {
1478 ctx.executor().execute(new Runnable() {
1479 @Override
1480 public void run() {
1481 notifyClosePromise(null);
1482 }
1483 });
1484 } catch (RejectedExecutionException e) {
1485 notifyClosePromise(e);
1486 }
1487 }
1488
1489 private void executeChannelRead(final ChannelHandlerContext ctx, final ByteBuf decodedOut) {
1490 try {
1491 ctx.executor().execute(new Runnable() {
1492 @Override
1493 public void run() {
1494 ctx.fireChannelRead(decodedOut);
1495 }
1496 });
1497 } catch (RejectedExecutionException e) {
1498 decodedOut.release();
1499 throw e;
1500 }
1501 }
1502
1503 private static ByteBuffer toByteBuffer(ByteBuf out, int index, int len) {
1504 return out.nioBufferCount() == 1 ? out.internalNioBuffer(index, len) :
1505 out.nioBuffer(index, len);
1506 }
1507
1508 private static boolean inEventLoop(Executor executor) {
1509 return executor instanceof EventExecutor && ((EventExecutor) executor).inEventLoop();
1510 }
1511
1512 /**
1513 * Will either run the delegated task directly calling {@link Runnable#run()} and return {@code true} or will
1514 * offload the delegated task using {@link Executor#execute(Runnable)} and return {@code false}.
1515 *
1516 * If the task is offloaded it will take care to resume its work on the {@link EventExecutor} once there are no
1517 * more tasks to process.
1518 */
1519 private boolean runDelegatedTasks(boolean inUnwrap) {
1520 if (delegatedTaskExecutor == ImmediateExecutor.INSTANCE || inEventLoop(delegatedTaskExecutor)) {
1521 // We should run the task directly in the EventExecutor thread and not offload at all. As we are on the
1522 // EventLoop we can just run all tasks at once.
1523 for (;;) {
1524 Runnable task = engine.getDelegatedTask();
1525 if (task == null) {
1526 return true;
1527 }
1528 setState(STATE_PROCESS_TASK);
1529 if (task instanceof AsyncRunnable) {
1530 // Let's set the task to processing task before we try to execute it.
1531 boolean pending = false;
1532 try {
1533 AsyncRunnable asyncTask = (AsyncRunnable) task;
1534 AsyncTaskCompletionHandler completionHandler = new AsyncTaskCompletionHandler(inUnwrap);
1535 asyncTask.run(completionHandler);
1536 pending = completionHandler.resumeLater();
1537 if (pending) {
1538 return false;
1539 }
1540 } finally {
1541 if (!pending) {
1542 // The task has completed, lets clear the state. If it is not completed we will clear the
1543 // state once it is.
1544 clearState(STATE_PROCESS_TASK);
1545 }
1546 }
1547 } else {
1548 try {
1549 task.run();
1550 } finally {
1551 clearState(STATE_PROCESS_TASK);
1552 }
1553 }
1554 }
1555 } else {
1556 executeDelegatedTask(inUnwrap);
1557 return false;
1558 }
1559 }
1560
1561 private SslTasksRunner getTaskRunner(boolean inUnwrap) {
1562 return inUnwrap ? sslTaskRunnerForUnwrap : sslTaskRunner;
1563 }
1564
1565 private void executeDelegatedTask(boolean inUnwrap) {
1566 executeDelegatedTask(getTaskRunner(inUnwrap));
1567 }
1568
1569 private void executeDelegatedTask(SslTasksRunner task) {
1570 setState(STATE_PROCESS_TASK);
1571 try {
1572 delegatedTaskExecutor.execute(task);
1573 } catch (RejectedExecutionException e) {
1574 clearState(STATE_PROCESS_TASK);
1575 throw e;
1576 }
1577 }
1578
1579 private final class AsyncTaskCompletionHandler implements Runnable {
1580 private final boolean inUnwrap;
1581 boolean didRun;
1582 boolean resumeLater;
1583
1584 AsyncTaskCompletionHandler(boolean inUnwrap) {
1585 this.inUnwrap = inUnwrap;
1586 }
1587
1588 @Override
1589 public void run() {
1590 didRun = true;
1591 if (resumeLater) {
1592 getTaskRunner(inUnwrap).runComplete();
1593 }
1594 }
1595
1596 boolean resumeLater() {
1597 if (!didRun) {
1598 resumeLater = true;
1599 return true;
1600 }
1601 return false;
1602 }
1603 }
1604
1605 /**
1606 * {@link Runnable} that will be scheduled on the {@code delegatedTaskExecutor} and will take care
1607 * of resume work on the {@link EventExecutor} once the task was executed.
1608 */
1609 private final class SslTasksRunner implements Runnable {
1610 private final boolean inUnwrap;
1611 private final Runnable runCompleteTask = new Runnable() {
1612 @Override
1613 public void run() {
1614 runComplete();
1615 }
1616 };
1617
1618 SslTasksRunner(boolean inUnwrap) {
1619 this.inUnwrap = inUnwrap;
1620 }
1621
1622 // Handle errors which happened during task processing.
1623 private void taskError(Throwable e) {
1624 if (inUnwrap) {
1625 // As the error happened while the task was scheduled as part of unwrap(...) we also need to ensure
1626 // we fire it through the pipeline as inbound error to be consistent with what we do in decode(...).
1627 //
1628 // This will also ensure we fail the handshake future and flush all produced data.
1629 try {
1630 handleUnwrapThrowable(ctx, e);
1631 } catch (Throwable cause) {
1632 safeExceptionCaught(cause);
1633 }
1634 } else {
1635 setHandshakeFailure(ctx, e);
1636 forceFlush(ctx);
1637 }
1638 }
1639
1640 // Try to call exceptionCaught(...)
1641 private void safeExceptionCaught(Throwable cause) {
1642 try {
1643 exceptionCaught(ctx, wrapIfNeeded(cause));
1644 } catch (Throwable error) {
1645 ctx.fireExceptionCaught(error);
1646 }
1647 }
1648
1649 private Throwable wrapIfNeeded(Throwable cause) {
1650 if (!inUnwrap) {
1651 // If we are not in unwrap(...) we can just rethrow without wrapping at all.
1652 return cause;
1653 }
1654 // As the exception would have been triggered by an inbound operation we will need to wrap it in a
1655 // DecoderException to mimic what a decoder would do when decode(...) throws.
1656 return cause instanceof DecoderException ? cause : new DecoderException(cause);
1657 }
1658
1659 private void tryDecodeAgain() {
1660 try {
1661 channelRead(ctx, Unpooled.EMPTY_BUFFER);
1662 } catch (Throwable cause) {
1663 safeExceptionCaught(cause);
1664 } finally {
1665 // As we called channelRead(...) we also need to call channelReadComplete(...) which
1666 // will ensure we either call ctx.fireChannelReadComplete() or will trigger a ctx.read() if
1667 // more data is needed.
1668 channelReadComplete0(ctx);
1669 }
1670 }
1671
1672 /**
1673 * Executed after the wrapped {@code task} was executed via {@code delegatedTaskExecutor} to resume work
1674 * on the {@link EventExecutor}.
1675 */
1676 private void resumeOnEventExecutor() {
1677 assert ctx.executor().inEventLoop();
1678 clearState(STATE_PROCESS_TASK);
1679 try {
1680 HandshakeStatus status = engine.getHandshakeStatus();
1681 switch (status) {
1682 // There is another task that needs to be executed and offloaded to the delegatingTaskExecutor as
1683 // a result of this. Let's reschedule....
1684 case NEED_TASK:
1685 executeDelegatedTask(this);
1686
1687 break;
1688
1689 // The handshake finished, lets notify about the completion of it and resume processing.
1690 case FINISHED:
1691 // Not handshaking anymore, lets notify about the completion if not done yet and resume processing.
1692 case NOT_HANDSHAKING:
1693 setHandshakeSuccess(); // NOT_HANDSHAKING -> workaround for android skipping FINISHED state.
1694 try {
1695 // Lets call wrap to ensure we produce the alert if there is any pending and also to
1696 // ensure we flush any queued data..
1697 wrap(ctx, inUnwrap);
1698 } catch (Throwable e) {
1699 taskError(e);
1700 return;
1701 }
1702 if (inUnwrap) {
1703 // If we were in the unwrap call when the task was processed we should also try to unwrap
1704 // non app data first as there may not anything left in the inbound buffer to process.
1705 unwrapNonAppData(ctx);
1706 }
1707
1708 // Flush now as we may have written some data as part of the wrap call.
1709 forceFlush(ctx);
1710
1711 tryDecodeAgain();
1712 break;
1713
1714 // We need more data so lets try to unwrap first and then call decode again which will feed us
1715 // with buffered data (if there is any).
1716 case NEED_UNWRAP:
1717 try {
1718 unwrapNonAppData(ctx);
1719 } catch (SSLException e) {
1720 handleUnwrapThrowable(ctx, e);
1721 return;
1722 }
1723 tryDecodeAgain();
1724 break;
1725
1726 // To make progress we need to call SSLEngine.wrap(...) which may produce more output data
1727 // that will be written to the Channel.
1728 case NEED_WRAP:
1729 try {
1730 if (!wrapNonAppData(ctx, false) && inUnwrap) {
1731 // The handshake finished in wrapNonAppData(...), we need to try call
1732 // unwrapNonAppData(...) as we may have some alert that we should read.
1733 //
1734 // This mimics what we would do when we are calling this method while in unwrap(...).
1735 unwrapNonAppData(ctx);
1736 }
1737
1738 // Flush now as we may have written some data as part of the wrap call.
1739 forceFlush(ctx);
1740 } catch (Throwable e) {
1741 taskError(e);
1742 return;
1743 }
1744
1745 // Now try to feed in more data that we have buffered.
1746 tryDecodeAgain();
1747 break;
1748
1749 default:
1750 // Should never reach here as we handle all cases.
1751 throw new AssertionError();
1752 }
1753 } catch (Throwable cause) {
1754 safeExceptionCaught(cause);
1755 }
1756 }
1757
1758 void runComplete() {
1759 EventExecutor executor = ctx.executor();
1760 // Jump back on the EventExecutor. We do this even if we are already on the EventLoop to guard against
1761 // reentrancy issues. Failing to do so could lead to the situation of tryDecode(...) be called and so
1762 // channelRead(...) while still in the decode loop. In this case channelRead(...) might release the input
1763 // buffer if its empty which would then result in an IllegalReferenceCountException when we try to continue
1764 // decoding.
1765 //
1766 // See https://github.com/netty/netty-tcnative/issues/680
1767 executor.execute(new Runnable() {
1768 @Override
1769 public void run() {
1770 resumeOnEventExecutor();
1771 }
1772 });
1773 }
1774
1775 @Override
1776 public void run() {
1777 try {
1778 Runnable task = engine.getDelegatedTask();
1779 if (task == null) {
1780 // The task was processed in the meantime. Let's just return.
1781 return;
1782 }
1783 if (task instanceof AsyncRunnable) {
1784 AsyncRunnable asyncTask = (AsyncRunnable) task;
1785 asyncTask.run(runCompleteTask);
1786 } else {
1787 task.run();
1788 runComplete();
1789 }
1790 } catch (final Throwable cause) {
1791 handleException(cause);
1792 }
1793 }
1794
1795 private void handleException(final Throwable cause) {
1796 EventExecutor executor = ctx.executor();
1797 if (executor.inEventLoop()) {
1798 clearState(STATE_PROCESS_TASK);
1799 safeExceptionCaught(cause);
1800 } else {
1801 try {
1802 executor.execute(new Runnable() {
1803 @Override
1804 public void run() {
1805 clearState(STATE_PROCESS_TASK);
1806 safeExceptionCaught(cause);
1807 }
1808 });
1809 } catch (RejectedExecutionException ignore) {
1810 clearState(STATE_PROCESS_TASK);
1811 // the context itself will handle the rejected exception when try to schedule the operation so
1812 // ignore the RejectedExecutionException
1813 ctx.fireExceptionCaught(cause);
1814 }
1815 }
1816 }
1817 }
1818
1819 /**
1820 * Notify all the handshake futures about the successfully handshake
1821 * @return {@code true} if {@link #handshakePromise} was set successfully and a {@link SslHandshakeCompletionEvent}
1822 * was fired. {@code false} otherwise.
1823 */
1824 private boolean setHandshakeSuccess() {
1825 // Our control flow may invoke this method multiple times for a single FINISHED event. For example
1826 // wrapNonAppData may drain pendingUnencryptedWrites in wrap which transitions to handshake from FINISHED to
1827 // NOT_HANDSHAKING which invokes setHandshakeSuccess, and then wrapNonAppData also directly invokes this method.
1828 final boolean notified;
1829 if (notified = !handshakePromise.isDone() && handshakePromise.trySuccess(ctx.channel())) {
1830 if (logger.isDebugEnabled()) {
1831 SSLSession session = engine.getSession();
1832 logger.debug(
1833 "{} HANDSHAKEN: protocol:{} cipher suite:{}",
1834 ctx.channel(),
1835 session.getProtocol(),
1836 session.getCipherSuite());
1837 }
1838 ctx.fireUserEventTriggered(SslHandshakeCompletionEvent.SUCCESS);
1839 }
1840 if (isStateSet(STATE_READ_DURING_HANDSHAKE)) {
1841 clearState(STATE_READ_DURING_HANDSHAKE);
1842 if (!ctx.channel().config().isAutoRead()) {
1843 ctx.read();
1844 }
1845 }
1846 return notified;
1847 }
1848
1849 /**
1850 * Notify all the handshake futures about the failure during the handshake.
1851 */
1852 private void setHandshakeFailure(ChannelHandlerContext ctx, Throwable cause) {
1853 setHandshakeFailure(ctx, cause, true, true, false);
1854 }
1855
1856 /**
1857 * Notify all the handshake futures about the failure during the handshake.
1858 */
1859 private void setHandshakeFailure(ChannelHandlerContext ctx, Throwable cause, boolean closeInbound,
1860 boolean notify, boolean alwaysFlushAndClose) {
1861 try {
1862 // Release all resources such as internal buffers that SSLEngine is managing.
1863 setState(STATE_OUTBOUND_CLOSED);
1864 engine.closeOutbound();
1865
1866 if (closeInbound) {
1867 try {
1868 engine.closeInbound();
1869 } catch (SSLException e) {
1870 if (logger.isDebugEnabled()) {
1871 // only log in debug mode as it most likely harmless and latest chrome still trigger
1872 // this all the time.
1873 //
1874 // See https://github.com/netty/netty/issues/1340
1875 String msg = e.getMessage();
1876 if (msg == null || !(msg.contains("possible truncation attack") ||
1877 msg.contains("closing inbound before receiving peer's close_notify"))) {
1878 logger.debug("{} SSLEngine.closeInbound() raised an exception.", ctx.channel(), e);
1879 }
1880 }
1881 }
1882 }
1883 if (handshakePromise.tryFailure(cause) || alwaysFlushAndClose) {
1884 SslUtils.handleHandshakeFailure(ctx, cause, notify);
1885 }
1886 } finally {
1887 // Ensure we remove and fail all pending writes in all cases and so release memory quickly.
1888 releaseAndFailAll(ctx, cause);
1889 }
1890 }
1891
1892 private void setHandshakeFailureTransportFailure(ChannelHandlerContext ctx, Throwable cause) {
1893 // If TLS control frames fail to write we are in an unknown state and may become out of
1894 // sync with our peer. We give up and close the channel. This will also take care of
1895 // cleaning up any outstanding state (e.g. handshake promise, queued unencrypted data).
1896 try {
1897 SSLException transportFailure = new SSLException("failure when writing TLS control frames", cause);
1898 releaseAndFailAll(ctx, transportFailure);
1899 if (handshakePromise.tryFailure(transportFailure)) {
1900 ctx.fireUserEventTriggered(new SslHandshakeCompletionEvent(transportFailure));
1901 }
1902 } finally {
1903 ctx.close();
1904 }
1905 }
1906
1907 private void releaseAndFailAll(ChannelHandlerContext ctx, Throwable cause) {
1908 if (pendingUnencryptedWrites != null) {
1909 pendingUnencryptedWrites.releaseAndFailAll(ctx, cause);
1910 }
1911 }
1912
1913 private void notifyClosePromise(Throwable cause) {
1914 if (cause == null) {
1915 if (sslClosePromise.trySuccess(ctx.channel())) {
1916 ctx.fireUserEventTriggered(SslCloseCompletionEvent.SUCCESS);
1917 }
1918 } else {
1919 if (sslClosePromise.tryFailure(cause)) {
1920 ctx.fireUserEventTriggered(new SslCloseCompletionEvent(cause));
1921 }
1922 }
1923 }
1924
1925 private void closeOutboundAndChannel(
1926 final ChannelHandlerContext ctx, final ChannelPromise promise, boolean disconnect) throws Exception {
1927 setState(STATE_OUTBOUND_CLOSED);
1928 engine.closeOutbound();
1929
1930 if (!ctx.channel().isActive()) {
1931 if (disconnect) {
1932 ctx.disconnect(promise);
1933 } else {
1934 ctx.close(promise);
1935 }
1936 return;
1937 }
1938
1939 ChannelPromise closeNotifyPromise = ctx.newPromise();
1940 try {
1941 flush(ctx, closeNotifyPromise);
1942 } finally {
1943 if (!isStateSet(STATE_CLOSE_NOTIFY)) {
1944 setState(STATE_CLOSE_NOTIFY);
1945 // It's important that we do not pass the original ChannelPromise to safeClose(...) as when flush(....)
1946 // throws an Exception it will be propagated to the AbstractChannelHandlerContext which will try
1947 // to fail the promise because of this. This will then fail as it was already completed by
1948 // safeClose(...). We create a new ChannelPromise and try to notify the original ChannelPromise
1949 // once it is complete. If we fail to do so we just ignore it as in this case it was failed already
1950 // because of a propagated Exception.
1951 //
1952 // See https://github.com/netty/netty/issues/5931
1953 safeClose(ctx, closeNotifyPromise, PromiseNotifier.cascade(false, ctx.newPromise(), promise));
1954 } else {
1955 /// We already handling the close_notify so just attach the promise to the sslClosePromise.
1956 sslClosePromise.addListener(new FutureListener<Channel>() {
1957 @Override
1958 public void operationComplete(Future<Channel> future) {
1959 promise.setSuccess();
1960 }
1961 });
1962 }
1963 }
1964 }
1965
1966 private void flush(ChannelHandlerContext ctx, ChannelPromise promise) throws Exception {
1967 if (pendingUnencryptedWrites != null) {
1968 pendingUnencryptedWrites.add(Unpooled.EMPTY_BUFFER, promise);
1969 } else {
1970 promise.setFailure(newPendingWritesNullException());
1971 }
1972 flush(ctx);
1973 }
1974
1975 @Override
1976 public void handlerAdded(final ChannelHandlerContext ctx) throws Exception {
1977 this.ctx = ctx;
1978 Channel channel = ctx.channel();
1979 pendingUnencryptedWrites = new SslHandlerCoalescingBufferQueue(channel, 16);
1980
1981 setOpensslEngineSocketFd(channel);
1982 boolean fastOpen = Boolean.TRUE.equals(channel.config().getOption(ChannelOption.TCP_FASTOPEN_CONNECT));
1983 boolean active = channel.isActive();
1984 if (active || fastOpen) {
1985 // Explicitly flush the handshake only if the channel is already active.
1986 // With TCP Fast Open, we write to the outbound buffer before the TCP connect is established.
1987 // The buffer will then be flushed as part of establishing the connection, saving us a round-trip.
1988 startHandshakeProcessing(active);
1989 // If we weren't able to include client_hello in the TCP SYN (e.g. no token, disabled at the OS) we have to
1990 // flush pending data in the outbound buffer later in channelActive().
1991 final ChannelOutboundBuffer outboundBuffer;
1992 if (fastOpen && ((outboundBuffer = channel.unsafe().outboundBuffer()) == null ||
1993 outboundBuffer.totalPendingWriteBytes() > 0)) {
1994 setState(STATE_NEEDS_FLUSH);
1995 }
1996 }
1997 }
1998
1999 private void startHandshakeProcessing(boolean flushAtEnd) {
2000 if (!isStateSet(STATE_HANDSHAKE_STARTED)) {
2001 setState(STATE_HANDSHAKE_STARTED);
2002 if (engine.getUseClientMode()) {
2003 // Begin the initial handshake.
2004 // channelActive() event has been fired already, which means this.channelActive() will
2005 // not be invoked. We have to initialize here instead.
2006 handshake(flushAtEnd);
2007 }
2008 applyHandshakeTimeout();
2009 } else if (isStateSet(STATE_NEEDS_FLUSH)) {
2010 forceFlush(ctx);
2011 }
2012 }
2013
2014 /**
2015 * Performs TLS renegotiation.
2016 */
2017 public Future<Channel> renegotiate() {
2018 ChannelHandlerContext ctx = this.ctx;
2019 if (ctx == null) {
2020 throw new IllegalStateException();
2021 }
2022
2023 return renegotiate(ctx.executor().<Channel>newPromise());
2024 }
2025
2026 /**
2027 * Performs TLS renegotiation.
2028 */
2029 public Future<Channel> renegotiate(final Promise<Channel> promise) {
2030 ObjectUtil.checkNotNull(promise, "promise");
2031
2032 ChannelHandlerContext ctx = this.ctx;
2033 if (ctx == null) {
2034 throw new IllegalStateException();
2035 }
2036
2037 EventExecutor executor = ctx.executor();
2038 if (!executor.inEventLoop()) {
2039 executor.execute(new Runnable() {
2040 @Override
2041 public void run() {
2042 renegotiateOnEventLoop(promise);
2043 }
2044 });
2045 return promise;
2046 }
2047
2048 renegotiateOnEventLoop(promise);
2049 return promise;
2050 }
2051
2052 private void renegotiateOnEventLoop(final Promise<Channel> newHandshakePromise) {
2053 final Promise<Channel> oldHandshakePromise = handshakePromise;
2054 if (!oldHandshakePromise.isDone()) {
2055 // There's no need to handshake because handshake is in progress already.
2056 // Merge the new promise into the old one.
2057 PromiseNotifier.cascade(oldHandshakePromise, newHandshakePromise);
2058 } else {
2059 handshakePromise = newHandshakePromise;
2060 handshake(true);
2061 applyHandshakeTimeout();
2062 }
2063 }
2064
2065 /**
2066 * Performs TLS (re)negotiation.
2067 * @param flushAtEnd Set to {@code true} if the outbound buffer should be flushed (written to the network) at the
2068 * end. Set to {@code false} if the handshake will be flushed later, e.g. as part of TCP Fast Open
2069 * connect.
2070 */
2071 private void handshake(boolean flushAtEnd) {
2072 if (engine.getHandshakeStatus() != HandshakeStatus.NOT_HANDSHAKING) {
2073 // Not all SSLEngine implementations support calling beginHandshake multiple times while a handshake
2074 // is in progress. See https://github.com/netty/netty/issues/4718.
2075 return;
2076 }
2077 if (handshakePromise.isDone()) {
2078 // If the handshake is done already lets just return directly as there is no need to trigger it again.
2079 // This can happen if the handshake(...) was triggered before we called channelActive(...) by a
2080 // flush() that was triggered by a ChannelFutureListener that was added to the ChannelFuture returned
2081 // from the connect(...) method. In this case we will see the flush() happen before we had a chance to
2082 // call fireChannelActive() on the pipeline.
2083 return;
2084 }
2085
2086 // Begin handshake.
2087 final ChannelHandlerContext ctx = this.ctx;
2088 try {
2089 engine.beginHandshake();
2090 wrapNonAppData(ctx, false);
2091 } catch (Throwable e) {
2092 setHandshakeFailure(ctx, e);
2093 } finally {
2094 if (flushAtEnd) {
2095 forceFlush(ctx);
2096 }
2097 }
2098 }
2099
2100 private void applyHandshakeTimeout() {
2101 final Promise<Channel> localHandshakePromise = this.handshakePromise;
2102
2103 // Set timeout if necessary.
2104 final long handshakeTimeoutMillis = this.handshakeTimeoutMillis;
2105 if (handshakeTimeoutMillis <= 0 || localHandshakePromise.isDone()) {
2106 return;
2107 }
2108
2109 final Future<?> timeoutFuture = ctx.executor().schedule(new Runnable() {
2110 @Override
2111 public void run() {
2112 if (localHandshakePromise.isDone()) {
2113 return;
2114 }
2115 SSLException exception =
2116 new SslHandshakeTimeoutException("handshake timed out after " + handshakeTimeoutMillis + "ms");
2117 try {
2118 if (localHandshakePromise.tryFailure(exception)) {
2119 SslUtils.handleHandshakeFailure(ctx, exception, true);
2120 }
2121 } finally {
2122 releaseAndFailAll(ctx, exception);
2123 }
2124 }
2125 }, handshakeTimeoutMillis, TimeUnit.MILLISECONDS);
2126
2127 // Cancel the handshake timeout when handshake is finished.
2128 localHandshakePromise.addListener(new FutureListener<Channel>() {
2129 @Override
2130 public void operationComplete(Future<Channel> f) throws Exception {
2131 timeoutFuture.cancel(false);
2132 }
2133 });
2134 }
2135
2136 private void forceFlush(ChannelHandlerContext ctx) {
2137 clearState(STATE_NEEDS_FLUSH);
2138 ctx.flush();
2139 }
2140
2141 private void setOpensslEngineSocketFd(Channel c) {
2142 if (c instanceof UnixChannel && engine instanceof ReferenceCountedOpenSslEngine) {
2143 ((ReferenceCountedOpenSslEngine) engine).bioSetFd(((UnixChannel) c).fd().intValue());
2144 }
2145 }
2146
2147 /**
2148 * Issues an initial TLS handshake once connected when used in client-mode
2149 */
2150 @Override
2151 public void channelActive(final ChannelHandlerContext ctx) throws Exception {
2152 setOpensslEngineSocketFd(ctx.channel());
2153 if (!startTls) {
2154 startHandshakeProcessing(true);
2155 }
2156 ctx.fireChannelActive();
2157 }
2158
2159 private void safeClose(
2160 final ChannelHandlerContext ctx, final ChannelFuture flushFuture,
2161 final ChannelPromise promise) {
2162 if (!ctx.channel().isActive()) {
2163 ctx.close(promise);
2164 return;
2165 }
2166
2167 final Future<?> timeoutFuture;
2168 if (!flushFuture.isDone()) {
2169 long closeNotifyTimeout = closeNotifyFlushTimeoutMillis;
2170 if (closeNotifyTimeout > 0) {
2171 // Force-close the connection if close_notify is not fully sent in time.
2172 timeoutFuture = ctx.executor().schedule(new Runnable() {
2173 @Override
2174 public void run() {
2175 // May be done in the meantime as cancel(...) is only best effort.
2176 if (!flushFuture.isDone()) {
2177 logger.warn("{} Last write attempt timed out; force-closing the connection.",
2178 ctx.channel());
2179 addCloseListener(ctx.close(ctx.newPromise()), promise);
2180 }
2181 }
2182 }, closeNotifyTimeout, TimeUnit.MILLISECONDS);
2183 } else {
2184 timeoutFuture = null;
2185 }
2186 } else {
2187 timeoutFuture = null;
2188 }
2189
2190 // Close the connection if close_notify is sent in time.
2191 flushFuture.addListener(new ChannelFutureListener() {
2192 @Override
2193 public void operationComplete(ChannelFuture f) {
2194 if (timeoutFuture != null) {
2195 timeoutFuture.cancel(false);
2196 }
2197 final long closeNotifyReadTimeout = closeNotifyReadTimeoutMillis;
2198 if (closeNotifyReadTimeout <= 0) {
2199 // Trigger the close in all cases to make sure the promise is notified
2200 // See https://github.com/netty/netty/issues/2358
2201 addCloseListener(ctx.close(ctx.newPromise()), promise);
2202 } else {
2203 final Future<?> closeNotifyReadTimeoutFuture;
2204
2205 if (!sslClosePromise.isDone()) {
2206 closeNotifyReadTimeoutFuture = ctx.executor().schedule(new Runnable() {
2207 @Override
2208 public void run() {
2209 if (!sslClosePromise.isDone()) {
2210 logger.debug(
2211 "{} did not receive close_notify in {}ms; force-closing the connection.",
2212 ctx.channel(), closeNotifyReadTimeout);
2213
2214 // Do the close now...
2215 addCloseListener(ctx.close(ctx.newPromise()), promise);
2216 }
2217 }
2218 }, closeNotifyReadTimeout, TimeUnit.MILLISECONDS);
2219 } else {
2220 closeNotifyReadTimeoutFuture = null;
2221 }
2222
2223 // Do the close once the we received the close_notify.
2224 sslClosePromise.addListener(new FutureListener<Channel>() {
2225 @Override
2226 public void operationComplete(Future<Channel> future) throws Exception {
2227 if (closeNotifyReadTimeoutFuture != null) {
2228 closeNotifyReadTimeoutFuture.cancel(false);
2229 }
2230 addCloseListener(ctx.close(ctx.newPromise()), promise);
2231 }
2232 });
2233 }
2234 }
2235 });
2236 }
2237
2238 private static void addCloseListener(ChannelFuture future, ChannelPromise promise) {
2239 // We notify the promise in the ChannelPromiseNotifier as there is a "race" where the close(...) call
2240 // by the timeoutFuture and the close call in the flushFuture listener will be called. Because of
2241 // this we need to use trySuccess() and tryFailure(...) as otherwise we can cause an
2242 // IllegalStateException.
2243 // Also we not want to log if the notification happens as this is expected in some cases.
2244 // See https://github.com/netty/netty/issues/5598
2245 PromiseNotifier.cascade(false, future, promise);
2246 }
2247
2248 /**
2249 * Always prefer a direct buffer when it's pooled, so that we reduce the number of memory copies
2250 * in {@link OpenSslEngine}.
2251 */
2252 private ByteBuf allocate(ChannelHandlerContext ctx, int capacity) {
2253 ByteBufAllocator alloc = ctx.alloc();
2254 if (engineType.wantsDirectBuffer) {
2255 return alloc.directBuffer(capacity);
2256 } else {
2257 return alloc.buffer(capacity);
2258 }
2259 }
2260
2261 /**
2262 * Allocates an outbound network buffer for {@link SSLEngine#wrap(ByteBuffer, ByteBuffer)} which can encrypt
2263 * the specified amount of pending bytes.
2264 */
2265 private ByteBuf allocateOutNetBuf(ChannelHandlerContext ctx, int pendingBytes, int numComponents) {
2266 return engineType.allocateWrapBuffer(this, ctx.alloc(), pendingBytes, numComponents);
2267 }
2268
2269 private boolean isStateSet(int bit) {
2270 return (state & bit) == bit;
2271 }
2272
2273 private void setState(int bit) {
2274 state |= bit;
2275 }
2276
2277 private void clearState(int bit) {
2278 state &= ~bit;
2279 }
2280
2281 /**
2282 * Each call to SSL_write will introduce about ~100 bytes of overhead. This coalescing queue attempts to increase
2283 * goodput by aggregating the plaintext in chunks of {@link #wrapDataSize}. If many small chunks are written
2284 * this can increase goodput, decrease the amount of calls to SSL_write, and decrease overall encryption operations.
2285 */
2286 private final class SslHandlerCoalescingBufferQueue extends AbstractCoalescingBufferQueue {
2287
2288 SslHandlerCoalescingBufferQueue(Channel channel, int initSize) {
2289 super(channel, initSize);
2290 }
2291
2292 @Override
2293 protected ByteBuf compose(ByteBufAllocator alloc, ByteBuf cumulation, ByteBuf next) {
2294 final int wrapDataSize = SslHandler.this.wrapDataSize;
2295 if (cumulation instanceof CompositeByteBuf) {
2296 CompositeByteBuf composite = (CompositeByteBuf) cumulation;
2297 int numComponents = composite.numComponents();
2298 if (numComponents == 0 ||
2299 !attemptCopyToCumulation(composite.internalComponent(numComponents - 1), next, wrapDataSize)) {
2300 composite.addComponent(true, next);
2301 }
2302 return composite;
2303 }
2304 return attemptCopyToCumulation(cumulation, next, wrapDataSize) ? cumulation :
2305 copyAndCompose(alloc, cumulation, next);
2306 }
2307
2308 @Override
2309 protected ByteBuf composeFirst(ByteBufAllocator allocator, ByteBuf first) {
2310 if (first instanceof CompositeByteBuf) {
2311 CompositeByteBuf composite = (CompositeByteBuf) first;
2312 if (engineType.wantsDirectBuffer) {
2313 first = allocator.directBuffer(composite.readableBytes());
2314 } else {
2315 first = allocator.heapBuffer(composite.readableBytes());
2316 }
2317 try {
2318 first.writeBytes(composite);
2319 } catch (Throwable cause) {
2320 first.release();
2321 PlatformDependent.throwException(cause);
2322 }
2323 composite.release();
2324 }
2325 return first;
2326 }
2327
2328 @Override
2329 protected ByteBuf removeEmptyValue() {
2330 return null;
2331 }
2332 }
2333
2334 private static boolean attemptCopyToCumulation(ByteBuf cumulation, ByteBuf next, int wrapDataSize) {
2335 final int inReadableBytes = next.readableBytes();
2336 final int cumulationCapacity = cumulation.capacity();
2337 if (wrapDataSize - cumulation.readableBytes() >= inReadableBytes &&
2338 // Avoid using the same buffer if next's data would make cumulation exceed the wrapDataSize.
2339 // Only copy if there is enough space available and the capacity is large enough, and attempt to
2340 // resize if the capacity is small.
2341 (cumulation.isWritable(inReadableBytes) && cumulationCapacity >= wrapDataSize ||
2342 cumulationCapacity < wrapDataSize &&
2343 ensureWritableSuccess(cumulation.ensureWritable(inReadableBytes, false)))) {
2344 cumulation.writeBytes(next);
2345 next.release();
2346 return true;
2347 }
2348 return false;
2349 }
2350
2351 private final class LazyChannelPromise extends DefaultPromise<Channel> {
2352
2353 @Override
2354 protected EventExecutor executor() {
2355 if (ctx == null) {
2356 throw new IllegalStateException();
2357 }
2358 return ctx.executor();
2359 }
2360
2361 @Override
2362 protected void checkDeadLock() {
2363 if (ctx == null) {
2364 // If ctx is null the handlerAdded(...) callback was not called, in this case the checkDeadLock()
2365 // method was called from another Thread then the one that is used by ctx.executor(). We need to
2366 // guard against this as a user can see a race if handshakeFuture().sync() is called but the
2367 // handlerAdded(..) method was not yet as it is called from the EventExecutor of the
2368 // ChannelHandlerContext. If we not guard against this super.checkDeadLock() would cause an
2369 // IllegalStateException when trying to call executor().
2370 return;
2371 }
2372 super.checkDeadLock();
2373 }
2374 }
2375 }