org.apache.tomcat.util.net.openssl.OpenSSLEngine Maven / Gradle / Ivy
/*
* 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.openssl;
import java.lang.ref.Cleaner;
import java.lang.ref.Cleaner.Cleanable;
import java.nio.ByteBuffer;
import java.nio.ReadOnlyBufferException;
import java.security.Principal;
import java.security.cert.Certificate;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;
import javax.net.ssl.SSLEngine;
import javax.net.ssl.SSLEngineResult;
import javax.net.ssl.SSLException;
import javax.net.ssl.SSLPeerUnverifiedException;
import javax.net.ssl.SSLSession;
import javax.net.ssl.SSLSessionBindingEvent;
import javax.net.ssl.SSLSessionBindingListener;
import javax.net.ssl.SSLSessionContext;
import org.apache.juli.logging.Log;
import org.apache.juli.logging.LogFactory;
import org.apache.tomcat.jni.Buffer;
import org.apache.tomcat.jni.Pool;
import org.apache.tomcat.jni.SSL;
import org.apache.tomcat.jni.SSLContext;
import org.apache.tomcat.util.buf.ByteBufferUtils;
import org.apache.tomcat.util.net.Constants;
import org.apache.tomcat.util.net.SSLUtil;
import org.apache.tomcat.util.net.openssl.ciphers.OpenSSLCipherConfigurationParser;
import org.apache.tomcat.util.res.StringManager;
/**
* Implements a {@link SSLEngine} using
* OpenSSL
* BIO abstractions.
*/
public final class OpenSSLEngine extends SSLEngine implements SSLUtil.ProtocolInfo {
private static final Log logger = LogFactory.getLog(OpenSSLEngine.class);
private static final StringManager sm = StringManager.getManager(OpenSSLEngine.class);
private static final Certificate[] EMPTY_CERTIFICATES = new Certificate[0];
public static final Set AVAILABLE_CIPHER_SUITES;
public static final Set IMPLEMENTED_PROTOCOLS_SET;
static {
final Set availableCipherSuites = new LinkedHashSet<>(128);
final long aprPool = Pool.create(0);
try {
final long sslCtx = SSLContext.make(aprPool, SSL.SSL_PROTOCOL_ALL, SSL.SSL_MODE_SERVER);
try {
SSLContext.setOptions(sslCtx, SSL.SSL_OP_ALL);
SSLContext.setCipherSuite(sslCtx, "ALL");
final long ssl = SSL.newSSL(sslCtx, true);
try {
for (String c: SSL.getCiphers(ssl)) {
// Filter out bad input.
if (c == null || c.length() == 0 || availableCipherSuites.contains(c)) {
continue;
}
availableCipherSuites.add(OpenSSLCipherConfigurationParser.openSSLToJsse(c));
}
} finally {
SSL.freeSSL(ssl);
}
} finally {
SSLContext.free(sslCtx);
}
} catch (Exception e) {
logger.warn(sm.getString("engine.ciphersFailure"), e);
} finally {
Pool.destroy(aprPool);
}
AVAILABLE_CIPHER_SUITES = Collections.unmodifiableSet(availableCipherSuites);
HashSet protocols = new HashSet<>();
protocols.add(Constants.SSL_PROTO_SSLv2Hello);
protocols.add(Constants.SSL_PROTO_SSLv2);
protocols.add(Constants.SSL_PROTO_SSLv3);
protocols.add(Constants.SSL_PROTO_TLSv1);
protocols.add(Constants.SSL_PROTO_TLSv1_1);
protocols.add(Constants.SSL_PROTO_TLSv1_2);
if (SSL.version() >= 0x1010100f) {
protocols.add(Constants.SSL_PROTO_TLSv1_3);
}
IMPLEMENTED_PROTOCOLS_SET = Collections.unmodifiableSet(protocols);
}
private static final int MAX_PLAINTEXT_LENGTH = 16 * 1024; // 2^14
private static final int MAX_COMPRESSED_LENGTH = MAX_PLAINTEXT_LENGTH + 1024;
private static final int MAX_CIPHERTEXT_LENGTH = MAX_COMPRESSED_LENGTH + 1024;
// Protocols
static final int VERIFY_DEPTH = 10;
// Header (5) + Data (2^14) + Compression (1024) + Encryption (1024) + MAC (20) + Padding (256)
static final int MAX_ENCRYPTED_PACKET_LENGTH = MAX_CIPHERTEXT_LENGTH + 5 + 20 + 256;
static final int MAX_ENCRYPTION_OVERHEAD_LENGTH = MAX_ENCRYPTED_PACKET_LENGTH - MAX_PLAINTEXT_LENGTH;
enum ClientAuthMode {
NONE,
OPTIONAL,
REQUIRE,
}
private static final String INVALID_CIPHER = "SSL_NULL_WITH_NULL_NULL";
private static final long EMPTY_ADDR = Buffer.address(ByteBuffer.allocate(0));
private final OpenSSLState state;
private final Cleanable cleanable;
private enum Accepted { NOT, IMPLICIT, EXPLICIT }
private Accepted accepted = Accepted.NOT;
private boolean handshakeFinished;
private int currentHandshake;
private boolean receivedShutdown;
private volatile boolean destroyed;
// Use an invalid cipherSuite until the handshake is completed
// See https://docs.oracle.com/en/java/javase/11/docs/api/java.base/java/net/Socket.html#setPerformancePreferences(int,int,int)
private volatile String version;
private volatile String cipher;
private volatile String applicationProtocol;
private volatile Certificate[] peerCerts;
@Deprecated
private volatile javax.security.cert.X509Certificate[] x509PeerCerts;
private volatile ClientAuthMode clientAuth = ClientAuthMode.NONE;
// SSL Engine status variables
private boolean isInboundDone;
private boolean isOutboundDone;
private boolean engineClosed;
private boolean sendHandshakeError = false;
private final boolean clientMode;
private final String fallbackApplicationProtocol;
private final OpenSSLSessionContext sessionContext;
private final boolean alpn;
private final boolean initialized;
private final int certificateVerificationDepth;
private final boolean certificateVerificationOptionalNoCA;
private String selectedProtocol = null;
private final OpenSSLSession session;
/**
* Creates a new instance
*
* @param cleaner Used to clean up references to instances before they are
* garbage collected
* @param sslCtx an OpenSSL {@code SSL_CTX} object
* @param fallbackApplicationProtocol the fallback application protocol
* @param clientMode {@code true} if this is used for clients, {@code false}
* otherwise
* @param sessionContext the {@link OpenSSLSessionContext} this
* {@link SSLEngine} belongs to.
* @param alpn {@code true} if alpn should be used, {@code false}
* otherwise
* @param initialized {@code true} if this instance gets its protocol,
* cipher and client verification from the {@code SSL_CTX} {@code sslCtx}
* @param certificateVerificationDepth Certificate verification depth
* @param certificateVerificationOptionalNoCA Skip CA verification in
* optional mode
*/
OpenSSLEngine(Cleaner cleaner, long sslCtx, String fallbackApplicationProtocol,
boolean clientMode, OpenSSLSessionContext sessionContext, boolean alpn,
boolean initialized, int certificateVerificationDepth,
boolean certificateVerificationOptionalNoCA) {
if (sslCtx == 0) {
throw new IllegalArgumentException(sm.getString("engine.noSSLContext"));
}
session = new OpenSSLSession();
long ssl = SSL.newSSL(sslCtx, !clientMode);
long networkBIO = SSL.makeNetworkBIO(ssl);
state = new OpenSSLState(ssl, networkBIO);
cleanable = cleaner.register(this, state);
this.fallbackApplicationProtocol = fallbackApplicationProtocol;
this.clientMode = clientMode;
this.sessionContext = sessionContext;
this.alpn = alpn;
this.initialized = initialized;
this.certificateVerificationDepth = certificateVerificationDepth;
this.certificateVerificationOptionalNoCA = certificateVerificationOptionalNoCA;
}
@Override
public String getNegotiatedProtocol() {
return selectedProtocol;
}
/**
* Destroys this engine.
*/
public synchronized void shutdown() {
if (!destroyed) {
destroyed = true;
cleanable.clean();
// internal errors can cause shutdown without marking the engine closed
isInboundDone = isOutboundDone = engineClosed = true;
}
}
/**
* Write plain text data to the OpenSSL internal BIO
*
* Calling this function with src.remaining == 0 is undefined.
* @throws SSLException if the OpenSSL error check fails
*/
private int writePlaintextData(final long ssl, final ByteBuffer src) throws SSLException {
clearLastError();
final int pos = src.position();
final int limit = src.limit();
final int len = Math.min(limit - pos, MAX_PLAINTEXT_LENGTH);
final int sslWrote;
if (src.isDirect()) {
final long addr = Buffer.address(src) + pos;
sslWrote = SSL.writeToSSL(ssl, addr, len);
if (sslWrote <= 0) {
checkLastError();
}
if (sslWrote >= 0) {
src.position(pos + sslWrote);
return sslWrote;
}
} else {
ByteBuffer buf = ByteBuffer.allocateDirect(len);
try {
final long addr = Buffer.address(buf);
src.limit(pos + len);
buf.put(src);
src.limit(limit);
sslWrote = SSL.writeToSSL(ssl, addr, len);
if (sslWrote <= 0) {
checkLastError();
}
if (sslWrote >= 0) {
src.position(pos + sslWrote);
return sslWrote;
} else {
src.position(pos);
}
} finally {
buf.clear();
ByteBufferUtils.cleanDirectBuffer(buf);
}
}
throw new IllegalStateException(
sm.getString("engine.writeToSSLFailed", Integer.toString(sslWrote)));
}
/**
* Write encrypted data to the OpenSSL network BIO.
* @throws SSLException if the OpenSSL error check fails
*/
private int writeEncryptedData(final long networkBIO, final ByteBuffer src) throws SSLException {
clearLastError();
final int pos = src.position();
final int len = src.remaining();
if (src.isDirect()) {
final long addr = Buffer.address(src) + pos;
final int netWrote = SSL.writeToBIO(networkBIO, addr, len);
if (netWrote <= 0) {
checkLastError();
}
if (netWrote >= 0) {
src.position(pos + netWrote);
return netWrote;
}
} else {
ByteBuffer buf = ByteBuffer.allocateDirect(len);
try {
final long addr = Buffer.address(buf);
buf.put(src);
final int netWrote = SSL.writeToBIO(networkBIO, addr, len);
if (netWrote <= 0) {
checkLastError();
}
if (netWrote >= 0) {
src.position(pos + netWrote);
return netWrote;
} else {
src.position(pos);
}
} finally {
buf.clear();
ByteBufferUtils.cleanDirectBuffer(buf);
}
}
return 0;
}
/**
* Read plain text data from the OpenSSL internal BIO
* @throws SSLException if the OpenSSL error check fails
*/
private int readPlaintextData(final long ssl, final ByteBuffer dst) throws SSLException {
clearLastError();
if (dst.isDirect()) {
final int pos = dst.position();
final long addr = Buffer.address(dst) + pos;
final int len = dst.limit() - pos;
final int sslRead = SSL.readFromSSL(ssl, addr, len);
if (sslRead > 0) {
dst.position(pos + sslRead);
return sslRead;
} else {
checkLastError();
}
} else {
final int pos = dst.position();
final int limit = dst.limit();
final int len = Math.min(MAX_ENCRYPTED_PACKET_LENGTH, limit - pos);
final ByteBuffer buf = ByteBuffer.allocateDirect(len);
try {
final long addr = Buffer.address(buf);
final int sslRead = SSL.readFromSSL(ssl, addr, len);
if (sslRead > 0) {
buf.limit(sslRead);
dst.limit(pos + sslRead);
dst.put(buf);
dst.limit(limit);
return sslRead;
} else {
checkLastError();
}
} finally {
buf.clear();
ByteBufferUtils.cleanDirectBuffer(buf);
}
}
return 0;
}
/**
* Read encrypted data from the OpenSSL network BIO
* @throws SSLException if the OpenSSL error check fails
*/
private int readEncryptedData(final long networkBIO, final ByteBuffer dst, final int pending) throws SSLException {
clearLastError();
if (dst.isDirect() && dst.remaining() >= pending) {
final int pos = dst.position();
final long addr = Buffer.address(dst) + pos;
final int bioRead = SSL.readFromBIO(networkBIO, addr, pending);
if (bioRead > 0) {
dst.position(pos + bioRead);
return bioRead;
} else {
checkLastError();
}
} else {
final ByteBuffer buf = ByteBuffer.allocateDirect(pending);
try {
final long addr = Buffer.address(buf);
final int bioRead = SSL.readFromBIO(networkBIO, addr, pending);
if (bioRead > 0) {
buf.limit(bioRead);
int oldLimit = dst.limit();
dst.limit(dst.position() + bioRead);
dst.put(buf);
dst.limit(oldLimit);
return bioRead;
} else {
checkLastError();
}
} finally {
buf.clear();
ByteBufferUtils.cleanDirectBuffer(buf);
}
}
return 0;
}
@Override
public synchronized SSLEngineResult wrap(final ByteBuffer[] srcs, final int offset, final int length, final ByteBuffer dst) throws SSLException {
// Check to make sure the engine has not been closed
if (destroyed) {
return new SSLEngineResult(SSLEngineResult.Status.CLOSED, SSLEngineResult.HandshakeStatus.NOT_HANDSHAKING, 0, 0);
}
// Throw required runtime exceptions
if (srcs == null || dst == null) {
throw new IllegalArgumentException(sm.getString("engine.nullBuffer"));
}
if (offset >= srcs.length || offset + length > srcs.length) {
throw new IndexOutOfBoundsException(sm.getString("engine.invalidBufferArray",
Integer.toString(offset), Integer.toString(length),
Integer.toString(srcs.length)));
}
if (dst.isReadOnly()) {
throw new ReadOnlyBufferException();
}
// Prepare OpenSSL to work in server mode and receive handshake
if (accepted == Accepted.NOT) {
beginHandshakeImplicitly();
}
// In handshake or close_notify stages, check if call to wrap was made
// without regard to the handshake status.
SSLEngineResult.HandshakeStatus handshakeStatus = getHandshakeStatus();
if ((!handshakeFinished || engineClosed) && handshakeStatus == SSLEngineResult.HandshakeStatus.NEED_UNWRAP) {
return new SSLEngineResult(getEngineStatus(), SSLEngineResult.HandshakeStatus.NEED_UNWRAP, 0, 0);
}
int bytesProduced = 0;
int pendingNet;
// Check for pending data in the network BIO
pendingNet = SSL.pendingWrittenBytesInBIO(state.networkBIO);
if (pendingNet > 0) {
// Do we have enough room in destination to write encrypted data?
int capacity = dst.remaining();
if (capacity < pendingNet) {
return new SSLEngineResult(SSLEngineResult.Status.BUFFER_OVERFLOW, handshakeStatus, 0, 0);
}
// Write the pending data from the network BIO into the dst buffer
try {
bytesProduced = readEncryptedData(state.networkBIO, dst, pendingNet);
} catch (Exception e) {
throw new SSLException(e);
}
// If isOutboundDone is set, then the data from the network BIO
// was the close_notify message -- we are not required to wait
// for the receipt of the peer's close_notify message -- shutdown.
if (isOutboundDone()) {
shutdown();
}
return new SSLEngineResult(getEngineStatus(), getHandshakeStatus(), 0, bytesProduced);
}
// There was no pending data in the network BIO -- encrypt any application data
int bytesConsumed = 0;
int endOffset = offset + length;
for (int i = offset; i < endOffset; ++i) {
final ByteBuffer src = srcs[i];
if (src == null) {
throw new IllegalArgumentException(sm.getString("engine.nullBufferInArray"));
}
while (src.hasRemaining()) {
// Write plain text application data to the SSL engine
try {
bytesConsumed += writePlaintextData(state.ssl, src);
} catch (Exception e) {
throw new SSLException(e);
}
// Check to see if the engine wrote data into the network BIO
pendingNet = SSL.pendingWrittenBytesInBIO(state.networkBIO);
if (pendingNet > 0) {
// Do we have enough room in dst to write encrypted data?
int capacity = dst.remaining();
if (capacity < pendingNet) {
return new SSLEngineResult(
SSLEngineResult.Status.BUFFER_OVERFLOW, getHandshakeStatus(), bytesConsumed, bytesProduced);
}
// Write the pending data from the network BIO into the dst buffer
try {
bytesProduced += readEncryptedData(state.networkBIO, dst, pendingNet);
} catch (Exception e) {
throw new SSLException(e);
}
return new SSLEngineResult(getEngineStatus(), getHandshakeStatus(), bytesConsumed, bytesProduced);
}
}
}
return new SSLEngineResult(getEngineStatus(), getHandshakeStatus(), bytesConsumed, bytesProduced);
}
@Override
public synchronized SSLEngineResult unwrap(final ByteBuffer src, final ByteBuffer[] dsts, final int offset, final int length) throws SSLException {
// Check to make sure the engine has not been closed
if (destroyed) {
return new SSLEngineResult(SSLEngineResult.Status.CLOSED, SSLEngineResult.HandshakeStatus.NOT_HANDSHAKING, 0, 0);
}
// Throw required runtime exceptions
if (src == null || dsts == null) {
throw new IllegalArgumentException(sm.getString("engine.nullBuffer"));
}
if (offset >= dsts.length || offset + length > dsts.length) {
throw new IndexOutOfBoundsException(sm.getString("engine.invalidBufferArray",
Integer.toString(offset), Integer.toString(length),
Integer.toString(dsts.length)));
}
int capacity = 0;
final int endOffset = offset + length;
for (int i = offset; i < endOffset; i++) {
ByteBuffer dst = dsts[i];
if (dst == null) {
throw new IllegalArgumentException(sm.getString("engine.nullBufferInArray"));
}
if (dst.isReadOnly()) {
throw new ReadOnlyBufferException();
}
capacity += dst.remaining();
}
// Prepare OpenSSL to work in server mode and receive handshake
if (accepted == Accepted.NOT) {
beginHandshakeImplicitly();
}
// In handshake or close_notify stages, check if call to unwrap was made
// without regard to the handshake status.
SSLEngineResult.HandshakeStatus handshakeStatus = getHandshakeStatus();
if ((!handshakeFinished || engineClosed) && handshakeStatus == SSLEngineResult.HandshakeStatus.NEED_WRAP) {
return new SSLEngineResult(getEngineStatus(), SSLEngineResult.HandshakeStatus.NEED_WRAP, 0, 0);
}
int len = src.remaining();
// protect against protocol overflow attack vector
if (len > MAX_ENCRYPTED_PACKET_LENGTH) {
shutdown();
throw new SSLException(sm.getString("engine.oversizedPacket"));
}
// Write encrypted data to network BIO
int written = 0;
try {
written = writeEncryptedData(state.networkBIO, src);
} catch (Exception e) {
throw new SSLException(e);
}
// There won't be any application data until we're done handshaking
//
// We first check handshakeFinished to eliminate the overhead of extra JNI call if possible.
int pendingApp = pendingReadableBytesInSSL();
if (!handshakeFinished) {
pendingApp = 0;
}
int bytesProduced = 0;
int idx = offset;
// Do we have enough room in dsts to write decrypted data?
if (capacity == 0) {
return new SSLEngineResult(SSLEngineResult.Status.BUFFER_OVERFLOW, getHandshakeStatus(), written, 0);
}
while (pendingApp > 0) {
if (idx == endOffset) {
// Destination buffer state changed (no remaining space although
// capacity is still available), so break loop with an error
throw new IllegalStateException(sm.getString("engine.invalidDestinationBuffersState"));
}
// Write decrypted data to dsts buffers
while (idx < endOffset) {
ByteBuffer dst = dsts[idx];
if (!dst.hasRemaining()) {
idx++;
continue;
}
if (pendingApp <= 0) {
break;
}
int bytesRead;
try {
bytesRead = readPlaintextData(state.ssl, dst);
} catch (Exception e) {
throw new SSLException(e);
}
if (bytesRead == 0) {
// This should not be possible. pendingApp is positive
// therefore the read should have read at least one byte.
throw new IllegalStateException(sm.getString("engine.failedToReadAvailableBytes"));
}
bytesProduced += bytesRead;
pendingApp -= bytesRead;
capacity -= bytesRead;
if (!dst.hasRemaining()) {
idx++;
}
}
if (capacity == 0) {
break;
} else if (pendingApp == 0) {
pendingApp = pendingReadableBytesInSSL();
}
}
// Check to see if we received a close_notify message from the peer
if (!receivedShutdown && (SSL.getShutdown(state.ssl) & SSL.SSL_RECEIVED_SHUTDOWN) == SSL.SSL_RECEIVED_SHUTDOWN) {
receivedShutdown = true;
closeInbound();
}
if (bytesProduced == 0 && (written == 0 || (written > 0 && !src.hasRemaining() && handshakeFinished))) {
return new SSLEngineResult(SSLEngineResult.Status.BUFFER_UNDERFLOW, getHandshakeStatus(), written, 0);
} else {
return new SSLEngineResult(getEngineStatus(), getHandshakeStatus(), written, bytesProduced);
}
}
private int pendingReadableBytesInSSL()
throws SSLException {
// NOTE: Calling a fake read is necessary before calling pendingReadableBytesInSSL because
// SSL_pending will return 0 if OpenSSL has not started the current TLS record
// See https://www.openssl.org/docs/manmaster/man3/SSL_pending.html
clearLastError();
int lastPrimingReadResult = SSL.readFromSSL(state.ssl, EMPTY_ADDR, 0); // priming read
// check if SSL_read returned <= 0. In this case we need to check the error and see if it was something
// fatal.
if (lastPrimingReadResult <= 0) {
checkLastError();
}
int pendingReadableBytesInSSL = SSL.pendingReadableBytesInSSL(state.ssl);
// TLS 1.0 needs additional handling
// TODO Figure out why this is necessary and if a simpler / better
// solution is available
if (Constants.SSL_PROTO_TLSv1.equals(version) && lastPrimingReadResult == 0 &&
pendingReadableBytesInSSL == 0) {
// Perform another priming read
lastPrimingReadResult = SSL.readFromSSL(state.ssl, EMPTY_ADDR, 0);
if (lastPrimingReadResult <= 0) {
checkLastError();
}
pendingReadableBytesInSSL = SSL.pendingReadableBytesInSSL(state.ssl);
}
return pendingReadableBytesInSSL;
}
@Override
public Runnable getDelegatedTask() {
// Currently, we do not delegate SSL computation tasks
return null;
}
@Override
public synchronized void closeInbound() throws SSLException {
if (isInboundDone) {
return;
}
isInboundDone = true;
engineClosed = true;
if (isOutboundDone()) {
// Only call shutdown if there is no outbound data pending.
shutdown();
}
if (accepted != Accepted.NOT && !receivedShutdown) {
throw new SSLException(sm.getString("engine.inboundClose"));
}
}
@Override
public synchronized boolean isInboundDone() {
return isInboundDone || engineClosed;
}
@Override
public synchronized void closeOutbound() {
if (isOutboundDone) {
return;
}
isOutboundDone = true;
engineClosed = true;
if (accepted != Accepted.NOT && !destroyed) {
int mode = SSL.getShutdown(state.ssl);
if ((mode & SSL.SSL_SENT_SHUTDOWN) != SSL.SSL_SENT_SHUTDOWN) {
SSL.shutdownSSL(state.ssl);
}
} else {
// engine closing before initial handshake
shutdown();
}
}
@Override
public synchronized boolean isOutboundDone() {
return isOutboundDone;
}
@Override
public String[] getSupportedCipherSuites() {
Set availableCipherSuites = AVAILABLE_CIPHER_SUITES;
return availableCipherSuites.toArray(new String[0]);
}
@Override
public synchronized String[] getEnabledCipherSuites() {
if (destroyed) {
return new String[0];
}
String[] enabled = SSL.getCiphers(state.ssl);
if (enabled == null) {
return new String[0];
} else {
for (int i = 0; i < enabled.length; i++) {
String mapped = OpenSSLCipherConfigurationParser.openSSLToJsse(enabled[i]);
if (mapped != null) {
enabled[i] = mapped;
}
}
return enabled;
}
}
@Override
public synchronized void setEnabledCipherSuites(String[] cipherSuites) {
if (initialized) {
return;
}
if (cipherSuites == null) {
throw new IllegalArgumentException(sm.getString("engine.nullCipherSuite"));
}
if (destroyed) {
return;
}
final StringBuilder buf = new StringBuilder();
for (String cipherSuite : cipherSuites) {
if (cipherSuite == null) {
break;
}
String converted = OpenSSLCipherConfigurationParser.jsseToOpenSSL(cipherSuite);
if (!AVAILABLE_CIPHER_SUITES.contains(cipherSuite)) {
logger.debug(sm.getString("engine.unsupportedCipher", cipherSuite, converted));
}
if (converted != null) {
cipherSuite = converted;
}
buf.append(cipherSuite);
buf.append(':');
}
if (buf.length() == 0) {
throw new IllegalArgumentException(sm.getString("engine.emptyCipherSuite"));
}
buf.setLength(buf.length() - 1);
final String cipherSuiteSpec = buf.toString();
try {
SSL.setCipherSuites(state.ssl, cipherSuiteSpec);
} catch (Exception e) {
throw new IllegalStateException(sm.getString("engine.failedCipherSuite", cipherSuiteSpec), e);
}
}
@Override
public String[] getSupportedProtocols() {
return IMPLEMENTED_PROTOCOLS_SET.toArray(new String[0]);
}
@Override
public synchronized String[] getEnabledProtocols() {
if (destroyed) {
return new String[0];
}
List enabled = new ArrayList<>();
// Seems like there is no way to explicitly disable SSLv2Hello in OpenSSL so it is always enabled
enabled.add(Constants.SSL_PROTO_SSLv2Hello);
int opts = SSL.getOptions(state.ssl);
if ((opts & SSL.SSL_OP_NO_TLSv1) == 0) {
enabled.add(Constants.SSL_PROTO_TLSv1);
}
if ((opts & SSL.SSL_OP_NO_TLSv1_1) == 0) {
enabled.add(Constants.SSL_PROTO_TLSv1_1);
}
if ((opts & SSL.SSL_OP_NO_TLSv1_2) == 0) {
enabled.add(Constants.SSL_PROTO_TLSv1_2);
}
if ((opts & SSL.SSL_OP_NO_SSLv2) == 0) {
enabled.add(Constants.SSL_PROTO_SSLv2);
}
if ((opts & SSL.SSL_OP_NO_SSLv3) == 0) {
enabled.add(Constants.SSL_PROTO_SSLv3);
}
return enabled.toArray(new String[0]);
}
@Override
public synchronized void setEnabledProtocols(String[] protocols) {
if (initialized) {
return;
}
if (protocols == null) {
// This is correct from the API docs
throw new IllegalArgumentException();
}
if (destroyed) {
return;
}
boolean sslv2 = false;
boolean sslv3 = false;
boolean tlsv1 = false;
boolean tlsv1_1 = false;
boolean tlsv1_2 = false;
for (String p : protocols) {
if (!IMPLEMENTED_PROTOCOLS_SET.contains(p)) {
throw new IllegalArgumentException(sm.getString("engine.unsupportedProtocol", p));
}
if (p.equals(Constants.SSL_PROTO_SSLv2)) {
sslv2 = true;
} else if (p.equals(Constants.SSL_PROTO_SSLv3)) {
sslv3 = true;
} else if (p.equals(Constants.SSL_PROTO_TLSv1)) {
tlsv1 = true;
} else if (p.equals(Constants.SSL_PROTO_TLSv1_1)) {
tlsv1_1 = true;
} else if (p.equals(Constants.SSL_PROTO_TLSv1_2)) {
tlsv1_2 = true;
}
}
// Enable all and then disable what we not want
SSL.setOptions(state.ssl, SSL.SSL_OP_ALL);
if (!sslv2) {
SSL.setOptions(state.ssl, SSL.SSL_OP_NO_SSLv2);
}
if (!sslv3) {
SSL.setOptions(state.ssl, SSL.SSL_OP_NO_SSLv3);
}
if (!tlsv1) {
SSL.setOptions(state.ssl, SSL.SSL_OP_NO_TLSv1);
}
if (!tlsv1_1) {
SSL.setOptions(state.ssl, SSL.SSL_OP_NO_TLSv1_1);
}
if (!tlsv1_2) {
SSL.setOptions(state.ssl, SSL.SSL_OP_NO_TLSv1_2);
}
}
@Override
public SSLSession getSession() {
return session;
}
@Override
public synchronized void beginHandshake() throws SSLException {
if (engineClosed || destroyed) {
throw new SSLException(sm.getString("engine.engineClosed"));
}
switch (accepted) {
case NOT:
handshake();
accepted = Accepted.EXPLICIT;
break;
case IMPLICIT:
// A user did not start handshake by calling this method by themselves,
// but handshake has been started already by wrap() or unwrap() implicitly.
// Because it's the user's first time to call this method, it is unfair to
// raise an exception. From the user's standpoint, they never asked for
// renegotiation.
accepted = Accepted.EXPLICIT; // Next time this method is invoked by the user, we should raise an exception.
break;
case EXPLICIT:
renegotiate();
break;
}
}
private void beginHandshakeImplicitly() throws SSLException {
handshake();
accepted = Accepted.IMPLICIT;
}
private void handshake() throws SSLException {
currentHandshake = SSL.getHandshakeCount(state.ssl);
clearLastError();
int code = SSL.doHandshake(state.ssl);
if (code <= 0) {
checkLastError();
} else {
if (alpn) {
selectedProtocol = SSL.getAlpnSelected(state.ssl);
}
session.lastAccessedTime = System.currentTimeMillis();
// if SSL_do_handshake returns > 0 it means the handshake was finished. This means we can update
// handshakeFinished directly and so eliminate unnecessary calls to SSL.isInInit(...)
handshakeFinished = true;
}
}
private synchronized void renegotiate() throws SSLException {
clearLastError();
int code;
if (SSL.getVersion(state.ssl).equals(Constants.SSL_PROTO_TLSv1_3)) {
code = SSL.verifyClientPostHandshake(state.ssl);
} else {
code = SSL.renegotiate(state.ssl);
}
if (code <= 0) {
checkLastError();
}
handshakeFinished = false;
peerCerts = null;
x509PeerCerts = null;
currentHandshake = SSL.getHandshakeCount(state.ssl);
int code2 = SSL.doHandshake(state.ssl);
if (code2 <= 0) {
checkLastError();
}
}
private void checkLastError() throws SSLException {
String sslError = getLastError();
if (sslError != null) {
// Many errors can occur during handshake and need to be reported
if (!handshakeFinished) {
sendHandshakeError = true;
} else {
throw new SSLException(sslError);
}
}
}
/**
* Clear out any errors, but log a warning.
*/
private static void clearLastError() {
getLastError();
}
/**
* Many calls to SSL methods do not check the last error. Those that do
* check the last error need to ensure that any previously ignored error is
* cleared prior to the method call else errors may be falsely reported.
* Ideally, before any SSL_read, SSL_write, clearLastError should always
* be called, and getLastError should be called after on any negative or
* zero result.
* @return the first error in the stack
*/
private static String getLastError() {
String sslError = null;
long error;
while ((error = SSL.getLastErrorNumber()) != SSL.SSL_ERROR_NONE) {
// Loop until getLastErrorNumber() returns SSL_ERROR_NONE
String err = SSL.getErrorString(error);
if (sslError == null) {
sslError = err;
}
if (logger.isDebugEnabled()) {
logger.debug(sm.getString("engine.openSSLError", Long.toString(error), err));
}
}
return sslError;
}
private SSLEngineResult.Status getEngineStatus() {
return engineClosed ? SSLEngineResult.Status.CLOSED : SSLEngineResult.Status.OK;
}
@Override
public synchronized SSLEngineResult.HandshakeStatus getHandshakeStatus() {
if (accepted == Accepted.NOT || destroyed) {
return SSLEngineResult.HandshakeStatus.NOT_HANDSHAKING;
}
// Check if we are in the initial handshake phase
if (!handshakeFinished) {
// There is pending data in the network BIO -- call wrap
if (sendHandshakeError || SSL.pendingWrittenBytesInBIO(state.networkBIO) != 0) {
if (sendHandshakeError) {
// After a last wrap, consider it is going to be done
sendHandshakeError = false;
currentHandshake++;
}
return SSLEngineResult.HandshakeStatus.NEED_WRAP;
}
/*
* Tomcat Native stores a count of the completed handshakes in the
* SSL instance and increments it every time a handshake is
* completed. Comparing the handshake count when the handshake
* started to the current handshake count enables this code to
* detect when the handshake has completed.
*
* Obtaining client certificates after the connection has been
* established requires additional checks. We need to trigger
* additional reads until the certificates have been read but we
* don't know how many reads we will need as it depends on both
* client and network behaviour.
*
* The additional reads are triggered by returning NEED_UNWRAP
* rather than FINISHED. This allows the standard I/O code to be
* used.
*
* For TLSv1.2 and below, the handshake completes before the
* renegotiation. We therefore use SSL.renegotiatePending() to
* check on the current status of the renegotiation and return
* NEED_UNWRAP until it completes which means the client
* certificates will have been read from the client.
*
* For TLSv1.3, Tomcat Native sets a flag when post handshake
* authentication is started and updates it once the client
* certificate has been received. We therefore use
* SSL.getPostHandshakeAuthInProgress() to check the current status
* and return NEED_UNWRAP until that methods indicates that PHA is
* no longer in progress.
*/
// No pending data to be sent to the peer
// Check to see if we have finished handshaking
int handshakeCount = SSL.getHandshakeCount(state.ssl);
if (handshakeCount != currentHandshake && SSL.renegotiatePending(state.ssl) == 0 &&
(SSL.getPostHandshakeAuthInProgress(state.ssl) == 0)) {
if (alpn) {
selectedProtocol = SSL.getAlpnSelected(state.ssl);
}
session.lastAccessedTime = System.currentTimeMillis();
version = SSL.getVersion(state.ssl);
handshakeFinished = true;
return SSLEngineResult.HandshakeStatus.FINISHED;
}
// No pending data
// Still handshaking / renegotiation / post-handshake auth pending
// Must be waiting on the peer to send more data
return SSLEngineResult.HandshakeStatus.NEED_UNWRAP;
}
// Check if we are in the shutdown phase
if (engineClosed) {
if (SSL.pendingWrittenBytesInBIO(state.networkBIO) != 0) {
// Waiting to send the close_notify message
return SSLEngineResult.HandshakeStatus.NEED_WRAP;
}
if (!isInboundDone()) {
// Must be waiting to receive the close_notify message
return SSLEngineResult.HandshakeStatus.NEED_UNWRAP;
}
}
return SSLEngineResult.HandshakeStatus.NOT_HANDSHAKING;
}
@Override
public void setUseClientMode(boolean clientMode) {
if (clientMode != this.clientMode) {
throw new UnsupportedOperationException();
}
}
@Override
public boolean getUseClientMode() {
return clientMode;
}
@Override
public void setNeedClientAuth(boolean b) {
setClientAuth(b ? ClientAuthMode.REQUIRE : ClientAuthMode.NONE);
}
@Override
public boolean getNeedClientAuth() {
return clientAuth == ClientAuthMode.REQUIRE;
}
@Override
public void setWantClientAuth(boolean b) {
setClientAuth(b ? ClientAuthMode.OPTIONAL : ClientAuthMode.NONE);
}
@Override
public boolean getWantClientAuth() {
return clientAuth == ClientAuthMode.OPTIONAL;
}
private void setClientAuth(ClientAuthMode mode) {
if (clientMode) {
return;
}
synchronized (this) {
if (clientAuth == mode) {
// No need to issue any JNI calls if the mode is the same
return;
}
switch (mode) {
case NONE:
SSL.setVerify(state.ssl, SSL.SSL_CVERIFY_NONE, certificateVerificationDepth);
break;
case REQUIRE:
SSL.setVerify(state.ssl, SSL.SSL_CVERIFY_REQUIRE, certificateVerificationDepth);
break;
case OPTIONAL:
SSL.setVerify(state.ssl,
certificateVerificationOptionalNoCA ? SSL.SSL_CVERIFY_OPTIONAL_NO_CA : SSL.SSL_CVERIFY_OPTIONAL,
certificateVerificationDepth);
break;
}
clientAuth = mode;
}
}
@Override
public void setEnableSessionCreation(boolean b) {
if (!b) {
String msg = sm.getString("engine.noRestrictSessionCreation");
throw new UnsupportedOperationException(msg);
}
}
@Override
public boolean getEnableSessionCreation() {
return true;
}
private class OpenSSLSession implements SSLSession {
// lazy init for memory reasons
private Map values;
// Last accessed time
private long lastAccessedTime = -1;
@Override
public byte[] getId() {
byte[] id = null;
synchronized (OpenSSLEngine.this) {
if (!destroyed) {
id = SSL.getSessionId(state.ssl);
}
}
return id;
}
@Override
public SSLSessionContext getSessionContext() {
return sessionContext;
}
@Override
public long getCreationTime() {
// We need to multiply by 1000 as OpenSSL uses seconds and we need milliseconds.
long creationTime = 0;
synchronized (OpenSSLEngine.this) {
if (!destroyed) {
creationTime = SSL.getTime(state.ssl);
}
}
return creationTime * 1000L;
}
@Override
public long getLastAccessedTime() {
return (lastAccessedTime > 0) ? lastAccessedTime : getCreationTime();
}
@Override
public void invalidate() {
// NOOP
}
@Override
public boolean isValid() {
return false;
}
@Override
public void putValue(String name, Object value) {
if (name == null) {
throw new IllegalArgumentException(sm.getString("engine.nullName"));
}
if (value == null) {
throw new IllegalArgumentException(sm.getString("engine.nullValue"));
}
Map values = this.values;
if (values == null) {
// Use size of 2 to keep the memory overhead small
values = this.values = new HashMap<>(2);
}
Object old = values.put(name, value);
if (value instanceof SSLSessionBindingListener) {
((SSLSessionBindingListener) value).valueBound(new SSLSessionBindingEvent(this, name));
}
notifyUnbound(old, name);
}
@Override
public Object getValue(String name) {
if (name == null) {
throw new IllegalArgumentException(sm.getString("engine.nullName"));
}
if (values == null) {
return null;
}
return values.get(name);
}
@Override
public void removeValue(String name) {
if (name == null) {
throw new IllegalArgumentException(sm.getString("engine.nullName"));
}
Map values = this.values;
if (values == null) {
return;
}
Object old = values.remove(name);
notifyUnbound(old, name);
}
@Override
public String[] getValueNames() {
Map values = this.values;
if (values == null || values.isEmpty()) {
return new String[0];
}
return values.keySet().toArray(new String[0]);
}
private void notifyUnbound(Object value, String name) {
if (value instanceof SSLSessionBindingListener) {
((SSLSessionBindingListener) value).valueUnbound(new SSLSessionBindingEvent(this, name));
}
}
@Override
public Certificate[] getPeerCertificates() throws SSLPeerUnverifiedException {
// these are lazy created to reduce memory overhead
Certificate[] c = peerCerts;
if (c == null) {
byte[] clientCert;
byte[][] chain;
synchronized (OpenSSLEngine.this) {
if (destroyed || SSL.isInInit(state.ssl) != 0) {
throw new SSLPeerUnverifiedException(sm.getString("engine.unverifiedPeer"));
}
chain = SSL.getPeerCertChain(state.ssl);
if (!clientMode) {
// if used on the server side SSL_get_peer_cert_chain(...) will not include the remote peer certificate.
// We use SSL_get_peer_certificate to get it in this case and add it to our array later.
//
// See https://www.openssl.org/docs/ssl/SSL_get_peer_cert_chain.html
clientCert = SSL.getPeerCertificate(state.ssl);
} else {
clientCert = null;
}
}
if (chain == null && clientCert == null) {
return null;
}
int len = 0;
if (chain != null) {
len += chain.length;
}
int i = 0;
Certificate[] certificates;
if (clientCert != null) {
len++;
certificates = new Certificate[len];
certificates[i++] = new OpenSSLX509Certificate(clientCert);
} else {
certificates = new Certificate[len];
}
if (chain != null) {
int a = 0;
for (; i < certificates.length; i++) {
certificates[i] = new OpenSSLX509Certificate(chain[a++]);
}
}
c = peerCerts = certificates;
}
return c;
}
@Override
public Certificate[] getLocalCertificates() {
// FIXME (if possible): Not available in the OpenSSL API
return EMPTY_CERTIFICATES;
}
@Deprecated
@Override
public javax.security.cert.X509Certificate[] getPeerCertificateChain()
throws SSLPeerUnverifiedException {
// these are lazy created to reduce memory overhead
javax.security.cert.X509Certificate[] c = x509PeerCerts;
if (c == null) {
byte[][] chain;
synchronized (OpenSSLEngine.this) {
if (destroyed || SSL.isInInit(state.ssl) != 0) {
throw new SSLPeerUnverifiedException(sm.getString("engine.unverifiedPeer"));
}
chain = SSL.getPeerCertChain(state.ssl);
}
if (chain == null) {
throw new SSLPeerUnverifiedException(sm.getString("engine.unverifiedPeer"));
}
javax.security.cert.X509Certificate[] peerCerts =
new javax.security.cert.X509Certificate[chain.length];
for (int i = 0; i < peerCerts.length; i++) {
try {
peerCerts[i] = javax.security.cert.X509Certificate.getInstance(chain[i]);
} catch (javax.security.cert.CertificateException e) {
throw new IllegalStateException(e);
}
}
c = x509PeerCerts = peerCerts;
}
return c;
}
@Override
public Principal getPeerPrincipal() throws SSLPeerUnverifiedException {
Certificate[] peer = getPeerCertificates();
if (peer == null || peer.length == 0) {
return null;
}
return principal(peer);
}
@Override
public Principal getLocalPrincipal() {
Certificate[] local = getLocalCertificates();
if (local == null || local.length == 0) {
return null;
}
return principal(local);
}
private Principal principal(Certificate[] certs) {
return ((java.security.cert.X509Certificate) certs[0]).getIssuerX500Principal();
}
@Override
public String getCipherSuite() {
if (cipher == null) {
String ciphers;
synchronized (OpenSSLEngine.this) {
if (!handshakeFinished) {
return INVALID_CIPHER;
}
if (destroyed) {
return INVALID_CIPHER;
}
ciphers = SSL.getCipherForSSL(state.ssl);
}
String c = OpenSSLCipherConfigurationParser.openSSLToJsse(ciphers);
if (c != null) {
cipher = c;
}
}
return cipher;
}
@Override
public String getProtocol() {
String applicationProtocol = OpenSSLEngine.this.applicationProtocol;
if (applicationProtocol == null) {
applicationProtocol = fallbackApplicationProtocol;
if (applicationProtocol != null) {
OpenSSLEngine.this.applicationProtocol = applicationProtocol.replace(':', '_');
} else {
OpenSSLEngine.this.applicationProtocol = applicationProtocol = "";
}
}
String version = null;
synchronized (OpenSSLEngine.this) {
if (!destroyed) {
version = SSL.getVersion(state.ssl);
}
}
if (applicationProtocol.isEmpty()) {
return version;
} else {
return version + ':' + applicationProtocol;
}
}
@Override
public String getPeerHost() {
// Not available for now in Tomcat (needs to be passed during engine creation)
return null;
}
@Override
public int getPeerPort() {
// Not available for now in Tomcat (needs to be passed during engine creation)
return 0;
}
@Override
public int getPacketBufferSize() {
return MAX_ENCRYPTED_PACKET_LENGTH;
}
@Override
public int getApplicationBufferSize() {
return MAX_PLAINTEXT_LENGTH;
}
}
private static class OpenSSLState implements Runnable {
private final long ssl;
private final long networkBIO;
private OpenSSLState(long ssl, long networkBIO) {
this.ssl = ssl;
this.networkBIO = networkBIO;
}
@Override
public void run() {
if (networkBIO != 0) {
SSL.freeBIO(networkBIO);
}
if (ssl != 0) {
SSL.freeSSL(ssl);
}
}
}
}
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