SecureNioChannel.java
/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The ASF licenses this file to You under the Apache License, Version 2.0
* (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.apache.tomcat.util.net;
import java.io.EOFException;
import java.io.IOException;
import java.net.SocketTimeoutException;
import java.nio.ByteBuffer;
import java.nio.channels.SelectionKey;
import java.nio.channels.Selector;
import java.nio.channels.SocketChannel;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import javax.net.ssl.SSLEngine;
import javax.net.ssl.SSLEngineResult;
import javax.net.ssl.SSLEngineResult.HandshakeStatus;
import javax.net.ssl.SSLEngineResult.Status;
import javax.net.ssl.SSLException;
import javax.net.ssl.SSLSession;
import org.apache.juli.logging.Log;
import org.apache.juli.logging.LogFactory;
import org.apache.tomcat.util.buf.ByteBufferUtils;
import org.apache.tomcat.util.net.NioEndpoint.NioSocketWrapper;
import org.apache.tomcat.util.net.TLSClientHelloExtractor.ExtractorResult;
import org.apache.tomcat.util.net.openssl.ciphers.Cipher;
import org.apache.tomcat.util.res.StringManager;
/**
* Implementation of a secure socket channel
*/
public class SecureNioChannel extends NioChannel {
private static final Log log = LogFactory.getLog(SecureNioChannel.class);
private static final StringManager sm = StringManager.getManager(SecureNioChannel.class);
// Value determined by observation of what the SSL Engine requested in
// various scenarios
private static final int DEFAULT_NET_BUFFER_SIZE = 16921;
private final NioEndpoint endpoint;
protected ByteBuffer netInBuffer;
protected ByteBuffer netOutBuffer;
protected SSLEngine sslEngine;
protected boolean sniComplete = false;
protected boolean handshakeComplete = false;
protected boolean needHandshakeWrap = false;
protected HandshakeStatus handshakeStatus; //gets set by handshake
protected boolean closed = false;
protected boolean closing = false;
private final Map<String,List<String>> additionalTlsAttributes = new HashMap<>();
public SecureNioChannel(SocketBufferHandler bufHandler, NioEndpoint endpoint) {
super(bufHandler);
// Create the network buffers (these hold the encrypted data).
if (endpoint.getSocketProperties().getDirectSslBuffer()) {
netInBuffer = ByteBuffer.allocateDirect(DEFAULT_NET_BUFFER_SIZE);
netOutBuffer = ByteBuffer.allocateDirect(DEFAULT_NET_BUFFER_SIZE);
} else {
netInBuffer = ByteBuffer.allocate(DEFAULT_NET_BUFFER_SIZE);
netOutBuffer = ByteBuffer.allocate(DEFAULT_NET_BUFFER_SIZE);
}
this.endpoint = endpoint;
}
@Override
public void reset(SocketChannel channel, NioSocketWrapper socketWrapper) throws IOException {
super.reset(channel, socketWrapper);
sslEngine = null;
sniComplete = false;
handshakeComplete = false;
closed = false;
closing = false;
netInBuffer.clear();
}
@Override
public void free() {
super.free();
if (endpoint.getSocketProperties().getDirectSslBuffer()) {
ByteBufferUtils.cleanDirectBuffer(netInBuffer);
ByteBufferUtils.cleanDirectBuffer(netOutBuffer);
}
}
//===========================================================================================
// NIO SSL METHODS
//===========================================================================================
/**
* Flushes the buffer to the network, non blocking
* @param buf ByteBuffer
* @return boolean true if the buffer has been emptied out, false otherwise
* @throws IOException An IO error occurred writing data
*/
protected boolean flush(ByteBuffer buf) throws IOException {
int remaining = buf.remaining();
if (remaining > 0) {
return (sc.write(buf) >= remaining);
} else {
return true;
}
}
/**
* Performs SSL handshake, non blocking, but performs NEED_TASK on the same
* thread. Hence, you should never call this method using your Acceptor
* thread, as you would slow down your system significantly. If the return
* value from this method is positive, the selection key should be
* registered interestOps given by the return value.
*
* @param read boolean - true if the underlying channel is readable
* @param write boolean - true if the underlying channel is writable
*
* @return 0 if hand shake is complete, -1 if an error (other than an
* IOException) occurred, otherwise it returns a SelectionKey
* interestOps value
*
* @throws IOException If an I/O error occurs during the handshake or if the
* handshake fails during wrapping or unwrapping
*/
@Override
public int handshake(boolean read, boolean write) throws IOException {
if (handshakeComplete) {
return 0; //we have done our initial handshake
}
if (!sniComplete) {
int sniResult = processSNI();
if (sniResult == 0) {
sniComplete = true;
} else {
return sniResult;
}
}
if (!flush(netOutBuffer)) {
return SelectionKey.OP_WRITE; //we still have data to write
}
SSLEngineResult handshake = null;
while (!handshakeComplete) {
switch (handshakeStatus) {
case NOT_HANDSHAKING:
//should never happen
throw new IOException(sm.getString("channel.nio.ssl.notHandshaking"));
case FINISHED:
if (endpoint.hasNegotiableProtocols()) {
if (sslEngine instanceof SSLUtil.ProtocolInfo) {
socketWrapper.setNegotiatedProtocol(
((SSLUtil.ProtocolInfo) sslEngine).getNegotiatedProtocol());
} else {
socketWrapper.setNegotiatedProtocol(sslEngine.getApplicationProtocol());
}
}
//we are complete if we have delivered the last package
handshakeComplete = !netOutBuffer.hasRemaining();
//return 0 if we are complete, otherwise we still have data to write
return handshakeComplete ? 0 : SelectionKey.OP_WRITE;
case NEED_WRAP:
//perform the wrap function
try {
handshake = handshakeWrap(write);
} catch (SSLException e) {
handshake = handshakeWrap(write);
throw e;
}
if (handshake.getStatus() == Status.OK) {
if (handshakeStatus == HandshakeStatus.NEED_TASK) {
handshakeStatus = tasks();
}
} else if (handshake.getStatus() == Status.CLOSED) {
flush(netOutBuffer);
return -1;
} else {
//wrap should always work with our buffers
throw new IOException(sm.getString("channel.nio.ssl.unexpectedStatusDuringWrap", handshake.getStatus()));
}
if (handshakeStatus != HandshakeStatus.NEED_UNWRAP || (!flush(netOutBuffer))) {
//should actually return OP_READ if we have NEED_UNWRAP
return SelectionKey.OP_WRITE;
}
//fall down to NEED_UNWRAP on the same call, will result in a
//BUFFER_UNDERFLOW if it needs data
//$FALL-THROUGH$
case NEED_UNWRAP:
//perform the unwrap function
handshake = handshakeUnwrap(read);
if (handshake.getStatus() == Status.OK) {
if (handshakeStatus == HandshakeStatus.NEED_TASK) {
handshakeStatus = tasks();
}
} else if ( handshake.getStatus() == Status.BUFFER_UNDERFLOW ){
//read more data, reregister for OP_READ
return SelectionKey.OP_READ;
} else {
throw new IOException(sm.getString("channel.nio.ssl.unexpectedStatusDuringWrap", handshake.getStatus()));
}
break;
case NEED_TASK:
handshakeStatus = tasks();
break;
default:
throw new IllegalStateException(sm.getString("channel.nio.ssl.invalidStatus", handshakeStatus));
}
}
// Handshake is complete if this point is reached
return 0;
}
/*
* Peeks at the initial network bytes to determine if the SNI extension is
* present and, if it is, what host name has been requested. Based on the
* provided host name, configure the SSLEngine for this connection.
*
* @return 0 if SNI processing is complete, -1 if an error (other than an
* IOException) occurred, otherwise it returns a SelectionKey
* interestOps value
*
* @throws IOException If an I/O error occurs during the SNI processing
*/
private int processSNI() throws IOException {
// Read some data into the network input buffer so we can peek at it.
int bytesRead = sc.read(netInBuffer);
if (bytesRead == -1) {
// Reached end of stream before SNI could be processed.
return -1;
}
TLSClientHelloExtractor extractor = new TLSClientHelloExtractor(netInBuffer);
while (extractor.getResult() == ExtractorResult.UNDERFLOW &&
netInBuffer.capacity() < endpoint.getSniParseLimit()) {
// extractor needed more data to process but netInBuffer was full so
// expand the buffer and read some more data.
int newLimit = Math.min(netInBuffer.capacity() * 2, endpoint.getSniParseLimit());
log.info(sm.getString("channel.nio.ssl.expandNetInBuffer",
Integer.toString(newLimit)));
netInBuffer = ByteBufferUtils.expand(netInBuffer, newLimit);
if (sc.read(netInBuffer) < 0) {
return -1;
}
extractor = new TLSClientHelloExtractor(netInBuffer);
}
String hostName = null;
List<Cipher> clientRequestedCiphers = null;
List<String> clientRequestedApplicationProtocols = null;
switch (extractor.getResult()) {
case COMPLETE:
hostName = extractor.getSNIValue();
clientRequestedApplicationProtocols =
extractor.getClientRequestedApplicationProtocols();
//$FALL-THROUGH$ to set the client requested ciphers
case NOT_PRESENT:
clientRequestedCiphers = extractor.getClientRequestedCiphers();
break;
case NEED_READ:
return SelectionKey.OP_READ;
case UNDERFLOW:
// Unable to buffer enough data to read SNI extension data
if (log.isDebugEnabled()) {
log.debug(sm.getString("channel.nio.ssl.sniDefault"));
}
hostName = endpoint.getDefaultSSLHostConfigName();
clientRequestedCiphers = Collections.emptyList();
break;
case NON_SECURE:
netOutBuffer.clear();
netOutBuffer.put(TLSClientHelloExtractor.USE_TLS_RESPONSE);
netOutBuffer.flip();
flushOutbound();
throw new IOException(sm.getString("channel.nio.ssl.foundHttp"));
}
if (log.isTraceEnabled()) {
log.trace(sm.getString("channel.nio.ssl.sniHostName", sc, hostName));
}
sslEngine = endpoint.createSSLEngine(hostName, clientRequestedCiphers,
clientRequestedApplicationProtocols);
// Populate additional TLS attributes obtained from the handshake that
// aren't available from the session
additionalTlsAttributes.put(SSLSupport.REQUESTED_PROTOCOL_VERSIONS_KEY,
extractor.getClientRequestedProtocols());
additionalTlsAttributes.put(SSLSupport.REQUESTED_CIPHERS_KEY,
extractor.getClientRequestedCipherNames());
// Ensure the application buffers (which have to be created earlier) are
// big enough.
getBufHandler().expand(sslEngine.getSession().getApplicationBufferSize());
if (netOutBuffer.capacity() < sslEngine.getSession().getApplicationBufferSize()) {
// Info for now as we may need to increase DEFAULT_NET_BUFFER_SIZE
log.info(sm.getString("channel.nio.ssl.expandNetOutBuffer",
Integer.toString(sslEngine.getSession().getApplicationBufferSize())));
}
netInBuffer = ByteBufferUtils.expand(netInBuffer, sslEngine.getSession().getPacketBufferSize());
netOutBuffer = ByteBufferUtils.expand(netOutBuffer, sslEngine.getSession().getPacketBufferSize());
// Set limit and position to expected values
netOutBuffer.position(0);
netOutBuffer.limit(0);
// Initiate handshake
sslEngine.beginHandshake();
handshakeStatus = sslEngine.getHandshakeStatus();
return 0;
}
/**
* Force a blocking handshake to take place for this key.
* This requires that both network and application buffers have been emptied out prior to this call taking place, or a
* IOException will be thrown.
* @param timeout - timeout in milliseconds for each socket operation
* @throws IOException - if an IO exception occurs or if application or network buffers contain data
* @throws SocketTimeoutException - if a socket operation timed out
*/
@SuppressWarnings("null") // key cannot be null
public void rehandshake(long timeout) throws IOException {
//validate the network buffers are empty
if (netInBuffer.position() > 0 && netInBuffer.position() < netInBuffer.limit()) {
throw new IOException(sm.getString("channel.nio.ssl.netInputNotEmpty"));
}
if (netOutBuffer.position() > 0 && netOutBuffer.position() < netOutBuffer.limit()) {
throw new IOException(sm.getString("channel.nio.ssl.netOutputNotEmpty"));
}
if (!getBufHandler().isReadBufferEmpty()) {
throw new IOException(sm.getString("channel.nio.ssl.appInputNotEmpty"));
}
if (!getBufHandler().isWriteBufferEmpty()) {
throw new IOException(sm.getString("channel.nio.ssl.appOutputNotEmpty"));
}
handshakeComplete = false;
boolean isReadable = false;
boolean isWritable = false;
boolean handshaking = true;
Selector selector = null;
SelectionKey key = null;
try {
sslEngine.beginHandshake();
handshakeStatus = sslEngine.getHandshakeStatus();
while (handshaking) {
int hsStatus = this.handshake(isReadable, isWritable);
switch (hsStatus) {
case -1 :
throw new EOFException(sm.getString("channel.nio.ssl.eofDuringHandshake"));
case 0 :
handshaking = false;
break;
default :
long now = System.currentTimeMillis();
if (selector == null) {
selector = Selector.open();
key = getIOChannel().register(selector, hsStatus);
} else {
key.interestOps(hsStatus); // null warning suppressed
}
int keyCount = selector.select(timeout);
if (keyCount == 0 && ((System.currentTimeMillis()-now) >= timeout)) {
throw new SocketTimeoutException(sm.getString("channel.nio.ssl.timeoutDuringHandshake"));
}
isReadable = key.isReadable();
isWritable = key.isWritable();
}
}
} catch (IOException x) {
closeSilently();
throw x;
} catch (Exception cx) {
closeSilently();
IOException x = new IOException(cx);
throw x;
} finally {
if (key != null) {
try {
key.cancel();
} catch (Exception ignore) {
}
}
if (selector != null) {
try {
selector.close();
} catch (Exception ignore) {
}
}
}
}
/**
* Executes all the tasks needed on the same thread.
* @return the status
*/
protected SSLEngineResult.HandshakeStatus tasks() {
Runnable r = null;
while ((r = sslEngine.getDelegatedTask()) != null) {
r.run();
}
return sslEngine.getHandshakeStatus();
}
/**
* Performs the WRAP function
* @param doWrite boolean
* @return the result
* @throws IOException An IO error occurred
*/
protected SSLEngineResult handshakeWrap(boolean doWrite) throws IOException {
//this should never be called with a network buffer that contains data
//so we can clear it here.
netOutBuffer.clear();
//perform the wrap
getBufHandler().configureWriteBufferForRead();
SSLEngineResult result = sslEngine.wrap(getBufHandler().getWriteBuffer(), netOutBuffer);
//prepare the results to be written
netOutBuffer.flip();
//set the status
handshakeStatus = result.getHandshakeStatus();
//optimization, if we do have a writable channel, write it now
if (doWrite) {
flush(netOutBuffer);
}
return result;
}
/**
* Perform handshake unwrap
* @param doread boolean
* @return the result
* @throws IOException An IO error occurred
*/
protected SSLEngineResult handshakeUnwrap(boolean doread) throws IOException {
if (doread) {
//if we have data to read, read it
int read = sc.read(netInBuffer);
if (read == -1) {
throw new IOException(sm.getString("channel.nio.ssl.eofDuringHandshake"));
}
}
SSLEngineResult result;
boolean cont = false;
//loop while we can perform pure SSLEngine data
do {
//prepare the buffer with the incoming data
netInBuffer.flip();
//call unwrap
getBufHandler().configureReadBufferForWrite();
result = sslEngine.unwrap(netInBuffer, getBufHandler().getReadBuffer());
/*
* ByteBuffer.compact() is an optional method but netInBuffer is created from either ByteBuffer.allocate()
* or ByteBuffer.allocateDirect() and the ByteBuffers returned by those methods do implement compact().
* The ByteBuffer must be in 'read from' mode when compact() is called and will be in 'write to' mode
* afterwards.
*/
netInBuffer.compact();
//read in the status
handshakeStatus = result.getHandshakeStatus();
if (result.getStatus() == SSLEngineResult.Status.OK &&
result.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
//execute tasks if we need to
handshakeStatus = tasks();
}
//perform another unwrap?
cont = result.getStatus() == SSLEngineResult.Status.OK &&
handshakeStatus == HandshakeStatus.NEED_UNWRAP;
} while (cont);
return result;
}
public SSLSupport getSSLSupport() {
if (sslEngine != null) {
SSLSession session = sslEngine.getSession();
return endpoint.getSslImplementation().getSSLSupport(session, additionalTlsAttributes);
}
return null;
}
/**
* Sends an SSL close message, will not physically close the connection here.
* <br>To close the connection, you could do something like
* <pre><code>
* close();
* while (isOpen() && !myTimeoutFunction()) Thread.sleep(25);
* if ( isOpen() ) close(true); //forces a close if you timed out
* </code></pre>
* @throws IOException if an I/O error occurs
* @throws IOException if there is data on the outgoing network buffer and
* we are unable to flush it
*/
@Override
public void close() throws IOException {
if (closing) {
return;
}
closing = true;
if (sslEngine == null) {
netOutBuffer.clear();
closed = true;
return;
}
sslEngine.closeOutbound();
if (!flush(netOutBuffer)) {
throw new IOException(sm.getString("channel.nio.ssl.remainingDataDuringClose"));
}
//prep the buffer for the close message
netOutBuffer.clear();
//perform the close, since we called sslEngine.closeOutbound
SSLEngineResult handshake = sslEngine.wrap(getEmptyBuf(), netOutBuffer);
//we should be in a close state
if (handshake.getStatus() != SSLEngineResult.Status.CLOSED) {
throw new IOException(sm.getString("channel.nio.ssl.invalidCloseState"));
}
//prepare the buffer for writing
netOutBuffer.flip();
//if there is data to be written
flush(netOutBuffer);
//is the channel closed?
closed = (!netOutBuffer.hasRemaining() && (handshake.getHandshakeStatus() != HandshakeStatus.NEED_WRAP));
}
@Override
public void close(boolean force) throws IOException {
try {
close();
} finally {
if (force || closed) {
closed = true;
sc.close();
}
}
}
private void closeSilently() {
try {
close(true);
} catch (IOException ioe) {
// This is expected - swallowing the exception is the reason this
// method exists. Log at debug in case someone is interested.
log.debug(sm.getString("channel.nio.ssl.closeSilentError"), ioe);
}
}
/**
* Reads a sequence of bytes from this channel into the given buffer.
*
* @param dst The buffer into which bytes are to be transferred
* @return The number of bytes read, possibly zero, or <code>-1</code> if
* the channel has reached end-of-stream
* @throws IOException If some other I/O error occurs
* @throws IllegalArgumentException if the destination buffer is different
* than getBufHandler().getReadBuffer()
*/
@Override
public int read(ByteBuffer dst) throws IOException {
//are we in the middle of closing or closed?
if (closing || closed) {
return -1;
}
//did we finish our handshake?
if (!handshakeComplete) {
throw new IllegalStateException(sm.getString("channel.nio.ssl.incompleteHandshake"));
}
//read from the network
int netread = sc.read(netInBuffer);
//did we reach EOF? if so send EOF up one layer.
if (netread == -1) {
return -1;
}
//the data read
int read = 0;
//the SSL engine result
SSLEngineResult unwrap;
do {
//prepare the buffer
netInBuffer.flip();
//unwrap the data
unwrap = sslEngine.unwrap(netInBuffer, dst);
//compact the buffer
netInBuffer.compact();
if (unwrap.getStatus() == Status.OK || unwrap.getStatus() == Status.BUFFER_UNDERFLOW) {
//we did receive some data, add it to our total
read += unwrap.bytesProduced();
//perform any tasks if needed
if (unwrap.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
tasks();
} else if (unwrap.getHandshakeStatus() == HandshakeStatus.NEED_WRAP) {
if (getOutboundRemaining() == 0) {
handshakeWrap(true);
} else if (needHandshakeWrap) {
throw new IOException(sm.getString("channel.nio.ssl.handshakeWrapPending"));
} else {
needHandshakeWrap = true;
}
}
//if we need more network data, then bail out for now.
if (unwrap.getStatus() == Status.BUFFER_UNDERFLOW) {
break;
}
} else if (unwrap.getStatus() == Status.BUFFER_OVERFLOW) {
if (read > 0) {
// Buffer overflow can happen if we have read data. Return
// so the destination buffer can be emptied before another
// read is attempted
break;
} else {
// The SSL session has increased the required buffer size
// since the buffer was created.
if (dst == getBufHandler().getReadBuffer()) {
// This is the normal case for this code
getBufHandler().expand(sslEngine.getSession().getApplicationBufferSize());
dst = getBufHandler().getReadBuffer();
} else if (getAppReadBufHandler() != null && dst == getAppReadBufHandler().getByteBuffer()) {
getAppReadBufHandler().expand(sslEngine.getSession().getApplicationBufferSize());
dst = getAppReadBufHandler().getByteBuffer();
} else {
// Can't expand the buffer as there is no way to signal
// to the caller that the buffer has been replaced.
throw new IOException(
sm.getString("channel.nio.ssl.unwrapFailResize", unwrap.getStatus()));
}
}
} else if (unwrap.getStatus() == Status.CLOSED && netInBuffer.position() == 0 && read > 0) {
// Clean TLS close on input side but there is application data
// to process. Can't tell if the client closed the connection
// mid-request or if the client is performing a half-close after
// a complete request. Assume it is a half-close and allow
// processing to continue. If the connection has been closed
// mid-request then the next attempt to read will trigger an
// EOF.
} else {
// Something else went wrong
throw new IOException(sm.getString("channel.nio.ssl.unwrapFail", unwrap.getStatus()));
}
} while (netInBuffer.position() != 0); //continue to unwrapping as long as the input buffer has stuff
return read;
}
@Override
public long read(ByteBuffer[] dsts, int offset, int length)
throws IOException {
//are we in the middle of closing or closed?
if (closing || closed) {
return -1;
}
//did we finish our handshake?
if (!handshakeComplete) {
throw new IllegalStateException(sm.getString("channel.nio.ssl.incompleteHandshake"));
}
//read from the network
int netread = sc.read(netInBuffer);
//did we reach EOF? if so send EOF up one layer.
if (netread == -1) {
return -1;
}
//the data read
int read = 0;
//the SSL engine result
SSLEngineResult unwrap;
OverflowState overflowState = OverflowState.NONE;
do {
if (overflowState == OverflowState.PROCESSING) {
overflowState = OverflowState.DONE;
}
//prepare the buffer
netInBuffer.flip();
//unwrap the data
unwrap = sslEngine.unwrap(netInBuffer, dsts, offset, length);
//compact the buffer
netInBuffer.compact();
if (unwrap.getStatus() == Status.OK || unwrap.getStatus() == Status.BUFFER_UNDERFLOW) {
//we did receive some data, add it to our total
read += unwrap.bytesProduced();
if (overflowState == OverflowState.DONE) {
// Remove the data read into the overflow buffer
read -= getBufHandler().getReadBuffer().position();
}
//perform any tasks if needed
if (unwrap.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
tasks();
} else if (unwrap.getHandshakeStatus() == HandshakeStatus.NEED_WRAP) {
if (getOutboundRemaining() == 0) {
handshakeWrap(true);
} else if (needHandshakeWrap) {
throw new IOException(sm.getString("channel.nio.ssl.handshakeWrapPending"));
} else {
needHandshakeWrap = true;
}
}
//if we need more network data, then bail out for now.
if (unwrap.getStatus() == Status.BUFFER_UNDERFLOW) {
break;
}
} else if (unwrap.getStatus() == Status.BUFFER_OVERFLOW) {
if (read > 0) {
// Buffer overflow can happen if we have read data. Return
// so the destination buffer can be emptied before another
// read is attempted
break;
} else {
ByteBuffer readBuffer = getBufHandler().getReadBuffer();
boolean found = false;
boolean resized = true;
for (int i = 0; i < length; i++) {
// The SSL session has increased the required buffer size
// since the buffer was created.
if (dsts[offset + i] == getBufHandler().getReadBuffer()) {
getBufHandler().expand(sslEngine.getSession().getApplicationBufferSize());
if (dsts[offset + i] == getBufHandler().getReadBuffer()) {
resized = false;
}
dsts[offset + i] = getBufHandler().getReadBuffer();
found = true;
} else if (getAppReadBufHandler() != null && dsts[offset + i] == getAppReadBufHandler().getByteBuffer()) {
getAppReadBufHandler().expand(sslEngine.getSession().getApplicationBufferSize());
if (dsts[offset + i] == getAppReadBufHandler().getByteBuffer()) {
resized = false;
}
dsts[offset + i] = getAppReadBufHandler().getByteBuffer();
found = true;
}
}
if (found) {
if (!resized) {
throw new IOException(sm.getString("channel.nio.ssl.unwrapFail", unwrap.getStatus()));
}
} else {
// Add the main read buffer in the destinations and try again
ByteBuffer[] dsts2 = new ByteBuffer[dsts.length + 1];
int dstOffset = 0;
for (int i = 0; i < dsts.length + 1; i++) {
if (i == offset + length) {
dsts2[i] = readBuffer;
dstOffset = -1;
} else {
dsts2[i] = dsts[i + dstOffset];
}
}
dsts = dsts2;
length++;
getBufHandler().configureReadBufferForWrite();
overflowState = OverflowState.PROCESSING;
}
}
} else {
// Something else went wrong
throw new IOException(sm.getString("channel.nio.ssl.unwrapFail", unwrap.getStatus()));
}
} while ((netInBuffer.position() != 0 || overflowState == OverflowState.PROCESSING) &&
overflowState != OverflowState.DONE);
return read;
}
/**
* Writes a sequence of bytes to this channel from the given buffer.
*
* @param src The buffer from which bytes are to be retrieved
* @return The number of bytes written, possibly zero
* @throws IOException If some other I/O error occurs
*/
@Override
public int write(ByteBuffer src) throws IOException {
checkInterruptStatus();
if (src == this.netOutBuffer) {
int written = sc.write(src);
return written;
} else {
// Are we closing or closed?
if (closing || closed) {
throw new IOException(sm.getString("channel.nio.ssl.closing"));
}
if (!flush(netOutBuffer)) {
// We haven't emptied out the buffer yet
return 0;
}
if (!src.hasRemaining()) {
// Nothing left to write
return 0;
}
// The data buffer is empty, we can reuse the entire buffer.
netOutBuffer.clear();
SSLEngineResult result = sslEngine.wrap(src, netOutBuffer);
// Call to wrap() will have included any required handshake data
needHandshakeWrap = false;
// The number of bytes written
int written = result.bytesConsumed();
netOutBuffer.flip();
if (result.getStatus() == Status.OK) {
if (result.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
tasks();
}
} else {
throw new IOException(sm.getString("channel.nio.ssl.wrapFail", result.getStatus()));
}
// Force a flush
flush(netOutBuffer);
return written;
}
}
@Override
public long write(ByteBuffer[] srcs, int offset, int length)
throws IOException {
checkInterruptStatus();
// Are we closing or closed?
if (closing || closed) {
throw new IOException(sm.getString("channel.nio.ssl.closing"));
}
if (!flush(netOutBuffer)) {
// We haven't emptied out the buffer yet
return 0;
}
// The data buffer is empty, we can reuse the entire buffer.
netOutBuffer.clear();
SSLEngineResult result = sslEngine.wrap(srcs, offset, length, netOutBuffer);
// The number of bytes written
int written = result.bytesConsumed();
netOutBuffer.flip();
if (result.getStatus() == Status.OK) {
if (result.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
tasks();
}
} else {
throw new IOException(sm.getString("channel.nio.ssl.wrapFail", result.getStatus()));
}
// Force a flush
flush(netOutBuffer);
return written;
}
@Override
public int getOutboundRemaining() {
return netOutBuffer.remaining();
}
@Override
public boolean flushOutbound() throws IOException {
int remaining = netOutBuffer.remaining();
flush(netOutBuffer);
int remaining2 = netOutBuffer.remaining();
return remaining2 < remaining;
}
@Override
public boolean isHandshakeComplete() {
return handshakeComplete;
}
@Override
public boolean isClosing() {
return closing;
}
public SSLEngine getSslEngine() {
return sslEngine;
}
public ByteBuffer getEmptyBuf() {
return emptyBuf;
}
private enum OverflowState {
NONE,
PROCESSING,
DONE;
}
}