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/*
 * Copyright 2016 The Netty Project
 *
 * The Netty Project 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:
 *
 *   https://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 io.netty.handler.ssl;

import io.netty.buffer.ByteBuf;
import io.netty.buffer.ByteBufAllocator;
import io.netty.handler.ssl.util.LazyX509Certificate;
import io.netty.internal.tcnative.AsyncSSLPrivateKeyMethod;
import io.netty.internal.tcnative.CertificateCompressionAlgo;
import io.netty.internal.tcnative.CertificateVerifier;
import io.netty.internal.tcnative.ResultCallback;
import io.netty.internal.tcnative.SSL;
import io.netty.internal.tcnative.SSLContext;
import io.netty.internal.tcnative.SSLPrivateKeyMethod;
import io.netty.util.AbstractReferenceCounted;
import io.netty.util.ReferenceCounted;
import io.netty.util.ResourceLeakDetector;
import io.netty.util.ResourceLeakDetectorFactory;
import io.netty.util.ResourceLeakTracker;
import io.netty.util.concurrent.Future;
import io.netty.util.concurrent.FutureListener;
import io.netty.util.concurrent.ImmediateExecutor;
import io.netty.util.internal.EmptyArrays;
import io.netty.util.internal.PlatformDependent;
import io.netty.util.internal.StringUtil;
import io.netty.util.internal.SystemPropertyUtil;
import io.netty.util.internal.UnstableApi;
import io.netty.util.internal.logging.InternalLogger;
import io.netty.util.internal.logging.InternalLoggerFactory;

import java.security.PrivateKey;
import java.security.SignatureException;
import java.security.cert.CertPathValidatorException;
import java.security.cert.Certificate;
import java.security.cert.CertificateExpiredException;
import java.security.cert.CertificateNotYetValidException;
import java.security.cert.CertificateRevokedException;
import java.security.cert.X509Certificate;
import java.util.ArrayList;
import java.util.Collections;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.concurrent.Executor;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReadWriteLock;
import java.util.concurrent.locks.ReentrantReadWriteLock;
import javax.net.ssl.KeyManager;
import javax.net.ssl.KeyManagerFactory;
import javax.net.ssl.SSLEngine;
import javax.net.ssl.SSLException;
import javax.net.ssl.SSLHandshakeException;
import javax.net.ssl.TrustManager;
import javax.net.ssl.X509ExtendedTrustManager;
import javax.net.ssl.X509KeyManager;
import javax.net.ssl.X509TrustManager;

import static io.netty.handler.ssl.OpenSsl.DEFAULT_CIPHERS;
import static io.netty.handler.ssl.OpenSsl.availableJavaCipherSuites;
import static io.netty.util.internal.ObjectUtil.checkNonEmpty;
import static io.netty.util.internal.ObjectUtil.checkNotNull;
import static io.netty.util.internal.ObjectUtil.checkPositiveOrZero;

/**
 * An implementation of {@link SslContext} which works with libraries that support the
 * OpenSsl C library API.
 * 

Instances of this class must be {@link #release() released} or else native memory will leak! * *

Instances of this class must not be released before any {@link ReferenceCountedOpenSslEngine} * which depends upon the instance of this class is released. Otherwise if any method of * {@link ReferenceCountedOpenSslEngine} is called which uses this class's JNI resources the JVM may crash. */ public abstract class ReferenceCountedOpenSslContext extends SslContext implements ReferenceCounted { private static final InternalLogger logger = InternalLoggerFactory.getInstance(ReferenceCountedOpenSslContext.class); private static final int DEFAULT_BIO_NON_APPLICATION_BUFFER_SIZE = Math.max(1, SystemPropertyUtil.getInt("io.netty.handler.ssl.openssl.bioNonApplicationBufferSize", 2048)); // Let's use tasks by default but still allow the user to disable it via system property just in case. static final boolean USE_TASKS = SystemPropertyUtil.getBoolean("io.netty.handler.ssl.openssl.useTasks", true); private static final Integer DH_KEY_LENGTH; private static final ResourceLeakDetector leakDetector = ResourceLeakDetectorFactory.instance().newResourceLeakDetector(ReferenceCountedOpenSslContext.class); // TODO: Maybe make configurable ? protected static final int VERIFY_DEPTH = 10; static final boolean CLIENT_ENABLE_SESSION_TICKET = SystemPropertyUtil.getBoolean("jdk.tls.client.enableSessionTicketExtension", false); static final boolean CLIENT_ENABLE_SESSION_TICKET_TLSV13 = SystemPropertyUtil.getBoolean("jdk.tls.client.enableSessionTicketExtension", true); static final boolean SERVER_ENABLE_SESSION_TICKET = SystemPropertyUtil.getBoolean("jdk.tls.server.enableSessionTicketExtension", false); static final boolean SERVER_ENABLE_SESSION_TICKET_TLSV13 = SystemPropertyUtil.getBoolean("jdk.tls.server.enableSessionTicketExtension", true); static final boolean SERVER_ENABLE_SESSION_CACHE = SystemPropertyUtil.getBoolean("io.netty.handler.ssl.openssl.sessionCacheServer", true); static final boolean CLIENT_ENABLE_SESSION_CACHE = SystemPropertyUtil.getBoolean("io.netty.handler.ssl.openssl.sessionCacheClient", true); /** * The OpenSSL SSL_CTX object. * * {@link #ctxLock} must be hold while using ctx! */ protected long ctx; private final List unmodifiableCiphers; private final OpenSslApplicationProtocolNegotiator apn; private final int mode; // Reference Counting private final ResourceLeakTracker leak; private final AbstractReferenceCounted refCnt = new AbstractReferenceCounted() { @Override public ReferenceCounted touch(Object hint) { if (leak != null) { leak.record(hint); } return ReferenceCountedOpenSslContext.this; } @Override protected void deallocate() { destroy(); if (leak != null) { boolean closed = leak.close(ReferenceCountedOpenSslContext.this); assert closed; } } }; final Certificate[] keyCertChain; final ClientAuth clientAuth; final String[] protocols; final String endpointIdentificationAlgorithm; final boolean hasTLSv13Cipher; final boolean enableOcsp; final OpenSslEngineMap engineMap = new DefaultOpenSslEngineMap(); final ReadWriteLock ctxLock = new ReentrantReadWriteLock(); private volatile int bioNonApplicationBufferSize = DEFAULT_BIO_NON_APPLICATION_BUFFER_SIZE; @SuppressWarnings("deprecation") static final OpenSslApplicationProtocolNegotiator NONE_PROTOCOL_NEGOTIATOR = new OpenSslApplicationProtocolNegotiator() { @Override public ApplicationProtocolConfig.Protocol protocol() { return ApplicationProtocolConfig.Protocol.NONE; } @Override public List protocols() { return Collections.emptyList(); } @Override public ApplicationProtocolConfig.SelectorFailureBehavior selectorFailureBehavior() { return ApplicationProtocolConfig.SelectorFailureBehavior.CHOOSE_MY_LAST_PROTOCOL; } @Override public ApplicationProtocolConfig.SelectedListenerFailureBehavior selectedListenerFailureBehavior() { return ApplicationProtocolConfig.SelectedListenerFailureBehavior.ACCEPT; } }; static { Integer dhLen = null; try { String dhKeySize = SystemPropertyUtil.get("jdk.tls.ephemeralDHKeySize"); if (dhKeySize != null) { try { dhLen = Integer.valueOf(dhKeySize); } catch (NumberFormatException e) { logger.debug("ReferenceCountedOpenSslContext supports -Djdk.tls.ephemeralDHKeySize={int}, but got: " + dhKeySize); } } } catch (Throwable ignore) { // ignore } DH_KEY_LENGTH = dhLen; } final boolean tlsFalseStart; ReferenceCountedOpenSslContext(Iterable ciphers, CipherSuiteFilter cipherFilter, OpenSslApplicationProtocolNegotiator apn, int mode, Certificate[] keyCertChain, ClientAuth clientAuth, String[] protocols, boolean startTls, String endpointIdentificationAlgorithm, boolean enableOcsp, boolean leakDetection, ResumptionController resumptionController, Map.Entry, Object>... ctxOptions) throws SSLException { super(startTls, resumptionController); OpenSsl.ensureAvailability(); if (enableOcsp && !OpenSsl.isOcspSupported()) { throw new IllegalStateException("OCSP is not supported."); } if (mode != SSL.SSL_MODE_SERVER && mode != SSL.SSL_MODE_CLIENT) { throw new IllegalArgumentException("mode most be either SSL.SSL_MODE_SERVER or SSL.SSL_MODE_CLIENT"); } boolean tlsFalseStart = false; boolean useTasks = USE_TASKS; OpenSslPrivateKeyMethod privateKeyMethod = null; OpenSslAsyncPrivateKeyMethod asyncPrivateKeyMethod = null; OpenSslCertificateCompressionConfig certCompressionConfig = null; Integer maxCertificateList = null; if (ctxOptions != null) { for (Map.Entry, Object> ctxOpt : ctxOptions) { SslContextOption option = ctxOpt.getKey(); if (option == OpenSslContextOption.TLS_FALSE_START) { tlsFalseStart = (Boolean) ctxOpt.getValue(); } else if (option == OpenSslContextOption.USE_TASKS) { useTasks = (Boolean) ctxOpt.getValue(); } else if (option == OpenSslContextOption.PRIVATE_KEY_METHOD) { privateKeyMethod = (OpenSslPrivateKeyMethod) ctxOpt.getValue(); } else if (option == OpenSslContextOption.ASYNC_PRIVATE_KEY_METHOD) { asyncPrivateKeyMethod = (OpenSslAsyncPrivateKeyMethod) ctxOpt.getValue(); } else if (option == OpenSslContextOption.CERTIFICATE_COMPRESSION_ALGORITHMS) { certCompressionConfig = (OpenSslCertificateCompressionConfig) ctxOpt.getValue(); } else if (option == OpenSslContextOption.MAX_CERTIFICATE_LIST_BYTES) { maxCertificateList = (Integer) ctxOpt.getValue(); } else { logger.debug("Skipping unsupported " + SslContextOption.class.getSimpleName() + ": " + ctxOpt.getKey()); } } } if (privateKeyMethod != null && asyncPrivateKeyMethod != null) { throw new IllegalArgumentException("You can either only use " + OpenSslAsyncPrivateKeyMethod.class.getSimpleName() + " or " + OpenSslPrivateKeyMethod.class.getSimpleName()); } this.tlsFalseStart = tlsFalseStart; leak = leakDetection ? leakDetector.track(this) : null; this.mode = mode; this.clientAuth = isServer() ? checkNotNull(clientAuth, "clientAuth") : ClientAuth.NONE; this.protocols = protocols == null ? OpenSsl.defaultProtocols(mode == SSL.SSL_MODE_CLIENT) : protocols; this.endpointIdentificationAlgorithm = endpointIdentificationAlgorithm; this.enableOcsp = enableOcsp; this.keyCertChain = keyCertChain == null ? null : keyCertChain.clone(); String[] suites = checkNotNull(cipherFilter, "cipherFilter").filterCipherSuites( ciphers, DEFAULT_CIPHERS, availableJavaCipherSuites()); // Filter out duplicates. LinkedHashSet suitesSet = new LinkedHashSet(suites.length); Collections.addAll(suitesSet, suites); unmodifiableCiphers = new ArrayList(suitesSet); this.apn = checkNotNull(apn, "apn"); // Create a new SSL_CTX and configure it. boolean success = false; try { boolean tlsv13Supported = OpenSsl.isTlsv13Supported(); boolean anyTlsv13Ciphers = false; try { int protocolOpts = SSL.SSL_PROTOCOL_SSLV3 | SSL.SSL_PROTOCOL_TLSV1 | SSL.SSL_PROTOCOL_TLSV1_1 | SSL.SSL_PROTOCOL_TLSV1_2; if (tlsv13Supported) { protocolOpts |= SSL.SSL_PROTOCOL_TLSV1_3; } ctx = SSLContext.make(protocolOpts, mode); } catch (Exception e) { throw new SSLException("failed to create an SSL_CTX", e); } StringBuilder cipherBuilder = new StringBuilder(); StringBuilder cipherTLSv13Builder = new StringBuilder(); /* List the ciphers that are permitted to negotiate. */ try { if (unmodifiableCiphers.isEmpty()) { // Set non TLSv1.3 ciphers. SSLContext.setCipherSuite(ctx, StringUtil.EMPTY_STRING, false); if (tlsv13Supported) { // Set TLSv1.3 ciphers. SSLContext.setCipherSuite(ctx, StringUtil.EMPTY_STRING, true); } } else { CipherSuiteConverter.convertToCipherStrings( unmodifiableCiphers, cipherBuilder, cipherTLSv13Builder, OpenSsl.isBoringSSL()); // Set non TLSv1.3 ciphers. SSLContext.setCipherSuite(ctx, cipherBuilder.toString(), false); if (tlsv13Supported) { // Set TLSv1.3 ciphers. String tlsv13Ciphers = OpenSsl.checkTls13Ciphers(logger, cipherTLSv13Builder.toString()); SSLContext.setCipherSuite(ctx, tlsv13Ciphers, true); if (!tlsv13Ciphers.isEmpty()) { anyTlsv13Ciphers = true; } } } } catch (SSLException e) { throw e; } catch (Exception e) { throw new SSLException("failed to set cipher suite: " + unmodifiableCiphers, e); } int options = SSLContext.getOptions(ctx) | SSL.SSL_OP_NO_SSLv2 | SSL.SSL_OP_NO_SSLv3 | // Disable TLSv1 and TLSv1.1 by default as these are not considered secure anymore // and the JDK is doing the same: // https://www.oracle.com/java/technologies/javase/8u291-relnotes.html SSL.SSL_OP_NO_TLSv1 | SSL.SSL_OP_NO_TLSv1_1 | SSL.SSL_OP_CIPHER_SERVER_PREFERENCE | // We do not support compression at the moment so we should explicitly disable it. SSL.SSL_OP_NO_COMPRESSION | // Disable ticket support by default to be more inline with SSLEngineImpl of the JDK. // This also let SSLSession.getId() work the same way for the JDK implementation and the // OpenSSLEngine. If tickets are supported SSLSession.getId() will only return an ID on the // server-side if it could make use of tickets. SSL.SSL_OP_NO_TICKET; if (cipherBuilder.length() == 0) { // No ciphers that are compatible with SSLv2 / SSLv3 / TLSv1 / TLSv1.1 / TLSv1.2 options |= SSL.SSL_OP_NO_SSLv2 | SSL.SSL_OP_NO_SSLv3 | SSL.SSL_OP_NO_TLSv1 | SSL.SSL_OP_NO_TLSv1_1 | SSL.SSL_OP_NO_TLSv1_2; } if (!tlsv13Supported) { // Explicit disable TLSv1.3 // See: // - https://github.com/netty/netty/issues/12968 options |= SSL.SSL_OP_NO_TLSv1_3; } hasTLSv13Cipher = anyTlsv13Ciphers; SSLContext.setOptions(ctx, options); // We need to enable SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER as the memory address may change between // calling OpenSSLEngine.wrap(...). // See https://github.com/netty/netty-tcnative/issues/100 SSLContext.setMode(ctx, SSLContext.getMode(ctx) | SSL.SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER); if (DH_KEY_LENGTH != null) { SSLContext.setTmpDHLength(ctx, DH_KEY_LENGTH); } List nextProtoList = apn.protocols(); /* Set next protocols for next protocol negotiation extension, if specified */ if (!nextProtoList.isEmpty()) { String[] appProtocols = nextProtoList.toArray(EmptyArrays.EMPTY_STRINGS); int selectorBehavior = opensslSelectorFailureBehavior(apn.selectorFailureBehavior()); switch (apn.protocol()) { case NPN: SSLContext.setNpnProtos(ctx, appProtocols, selectorBehavior); break; case ALPN: SSLContext.setAlpnProtos(ctx, appProtocols, selectorBehavior); break; case NPN_AND_ALPN: SSLContext.setNpnProtos(ctx, appProtocols, selectorBehavior); SSLContext.setAlpnProtos(ctx, appProtocols, selectorBehavior); break; default: throw new Error(); } } if (enableOcsp) { SSLContext.enableOcsp(ctx, isClient()); } SSLContext.setUseTasks(ctx, useTasks); if (privateKeyMethod != null) { SSLContext.setPrivateKeyMethod(ctx, new PrivateKeyMethod(engineMap, privateKeyMethod)); } if (asyncPrivateKeyMethod != null) { SSLContext.setPrivateKeyMethod(ctx, new AsyncPrivateKeyMethod(engineMap, asyncPrivateKeyMethod)); } if (certCompressionConfig != null) { for (OpenSslCertificateCompressionConfig.AlgorithmConfig configPair : certCompressionConfig) { final CertificateCompressionAlgo algo = new CompressionAlgorithm(engineMap, configPair.algorithm()); switch (configPair.mode()) { case Decompress: SSLContext.addCertificateCompressionAlgorithm( ctx, SSL.SSL_CERT_COMPRESSION_DIRECTION_DECOMPRESS, algo); break; case Compress: SSLContext.addCertificateCompressionAlgorithm( ctx, SSL.SSL_CERT_COMPRESSION_DIRECTION_COMPRESS, algo); break; case Both: SSLContext.addCertificateCompressionAlgorithm( ctx, SSL.SSL_CERT_COMPRESSION_DIRECTION_BOTH, algo); break; default: throw new IllegalStateException(); } } } if (maxCertificateList != null) { SSLContext.setMaxCertList(ctx, maxCertificateList); } // Set the curves. SSLContext.setCurvesList(ctx, OpenSsl.NAMED_GROUPS); success = true; } finally { if (!success) { release(); } } } private static int opensslSelectorFailureBehavior(ApplicationProtocolConfig.SelectorFailureBehavior behavior) { switch (behavior) { case NO_ADVERTISE: return SSL.SSL_SELECTOR_FAILURE_NO_ADVERTISE; case CHOOSE_MY_LAST_PROTOCOL: return SSL.SSL_SELECTOR_FAILURE_CHOOSE_MY_LAST_PROTOCOL; default: throw new Error(); } } @Override public final List cipherSuites() { return unmodifiableCiphers; } @Override public ApplicationProtocolNegotiator applicationProtocolNegotiator() { return apn; } @Override public final boolean isClient() { return mode == SSL.SSL_MODE_CLIENT; } @Override public final SSLEngine newEngine(ByteBufAllocator alloc, String peerHost, int peerPort) { return newEngine0(alloc, peerHost, peerPort, true); } @Override protected final SslHandler newHandler(ByteBufAllocator alloc, boolean startTls) { return new SslHandler(newEngine0(alloc, null, -1, false), startTls, ImmediateExecutor.INSTANCE, resumptionController); } @Override protected final SslHandler newHandler(ByteBufAllocator alloc, String peerHost, int peerPort, boolean startTls) { return new SslHandler(newEngine0(alloc, peerHost, peerPort, false), startTls, ImmediateExecutor.INSTANCE, resumptionController); } @Override protected SslHandler newHandler(ByteBufAllocator alloc, boolean startTls, Executor executor) { return new SslHandler(newEngine0(alloc, null, -1, false), startTls, executor, resumptionController); } @Override protected SslHandler newHandler(ByteBufAllocator alloc, String peerHost, int peerPort, boolean startTls, Executor executor) { return new SslHandler(newEngine0(alloc, peerHost, peerPort, false), false, executor, resumptionController); } SSLEngine newEngine0(ByteBufAllocator alloc, String peerHost, int peerPort, boolean jdkCompatibilityMode) { return new ReferenceCountedOpenSslEngine(this, alloc, peerHost, peerPort, jdkCompatibilityMode, true, endpointIdentificationAlgorithm); } /** * Returns a new server-side {@link SSLEngine} with the current configuration. */ @Override public final SSLEngine newEngine(ByteBufAllocator alloc) { return newEngine(alloc, null, -1); } /** * Returns the pointer to the {@code SSL_CTX} object for this {@link ReferenceCountedOpenSslContext}. * Be aware that it is freed as soon as the {@link #finalize()} method is called. * At this point {@code 0} will be returned. * * @deprecated this method is considered unsafe as the returned pointer may be released later. Dont use it! */ @Deprecated public final long context() { return sslCtxPointer(); } /** * Returns the stats of this context. * * @deprecated use {@link #sessionContext#stats()} */ @Deprecated public final OpenSslSessionStats stats() { return sessionContext().stats(); } /** * {@deprecated Renegotiation is not supported} * Specify if remote initiated renegotiation is supported or not. If not supported and the remote side tries * to initiate a renegotiation a {@link SSLHandshakeException} will be thrown during decoding. */ @Deprecated public void setRejectRemoteInitiatedRenegotiation(boolean rejectRemoteInitiatedRenegotiation) { if (!rejectRemoteInitiatedRenegotiation) { throw new UnsupportedOperationException("Renegotiation is not supported"); } } /** * {@deprecated Renegotiation is not supported} * @return {@code true} because renegotiation is not supported. */ @Deprecated public boolean getRejectRemoteInitiatedRenegotiation() { return true; } /** * Set the size of the buffer used by the BIO for non-application based writes * (e.g. handshake, renegotiation, etc...). */ public void setBioNonApplicationBufferSize(int bioNonApplicationBufferSize) { this.bioNonApplicationBufferSize = checkPositiveOrZero(bioNonApplicationBufferSize, "bioNonApplicationBufferSize"); } /** * Returns the size of the buffer used by the BIO for non-application based writes */ public int getBioNonApplicationBufferSize() { return bioNonApplicationBufferSize; } /** * Sets the SSL session ticket keys of this context. * * @deprecated use {@link OpenSslSessionContext#setTicketKeys(byte[])} */ @Deprecated public final void setTicketKeys(byte[] keys) { sessionContext().setTicketKeys(keys); } @Override public abstract OpenSslSessionContext sessionContext(); /** * Returns the pointer to the {@code SSL_CTX} object for this {@link ReferenceCountedOpenSslContext}. * Be aware that it is freed as soon as the {@link #release()} method is called. * At this point {@code 0} will be returned. * * @deprecated this method is considered unsafe as the returned pointer may be released later. Dont use it! */ @Deprecated public final long sslCtxPointer() { Lock readerLock = ctxLock.readLock(); readerLock.lock(); try { return SSLContext.getSslCtx(ctx); } finally { readerLock.unlock(); } } /** * Set the {@link OpenSslPrivateKeyMethod} to use. This allows to offload private-key operations * if needed. * * This method is currently only supported when {@code BoringSSL} is used. * * @param method method to use. * @deprecated use {@link SslContextBuilder#option(SslContextOption, Object)} with * {@link OpenSslContextOption#PRIVATE_KEY_METHOD}. */ @Deprecated @UnstableApi public final void setPrivateKeyMethod(OpenSslPrivateKeyMethod method) { checkNotNull(method, "method"); Lock writerLock = ctxLock.writeLock(); writerLock.lock(); try { SSLContext.setPrivateKeyMethod(ctx, new PrivateKeyMethod(engineMap, method)); } finally { writerLock.unlock(); } } /** * @deprecated use {@link SslContextBuilder#option(SslContextOption, Object)} with * {@link OpenSslContextOption#USE_TASKS}. */ @Deprecated public final void setUseTasks(boolean useTasks) { Lock writerLock = ctxLock.writeLock(); writerLock.lock(); try { SSLContext.setUseTasks(ctx, useTasks); } finally { writerLock.unlock(); } } // IMPORTANT: This method must only be called from either the constructor or the finalizer as a user MUST never // get access to an OpenSslSessionContext after this method was called to prevent the user from // producing a segfault. private void destroy() { Lock writerLock = ctxLock.writeLock(); writerLock.lock(); try { if (ctx != 0) { if (enableOcsp) { SSLContext.disableOcsp(ctx); } SSLContext.free(ctx); ctx = 0; OpenSslSessionContext context = sessionContext(); if (context != null) { context.destroy(); } } } finally { writerLock.unlock(); } } protected static X509Certificate[] certificates(byte[][] chain) { X509Certificate[] peerCerts = new X509Certificate[chain.length]; for (int i = 0; i < peerCerts.length; i++) { peerCerts[i] = new LazyX509Certificate(chain[i]); } return peerCerts; } /** * @deprecated This method is kept for API backwards compatibility. */ @Deprecated protected static X509TrustManager chooseTrustManager(TrustManager[] managers) { return chooseTrustManager(managers, null); } static X509TrustManager chooseTrustManager(TrustManager[] managers, ResumptionController resumptionController) { for (TrustManager m : managers) { if (m instanceof X509TrustManager) { X509TrustManager tm = (X509TrustManager) m; if (resumptionController != null) { tm = (X509TrustManager) resumptionController.wrapIfNeeded(tm); } tm = OpenSslX509TrustManagerWrapper.wrapIfNeeded((X509TrustManager) m); if (useExtendedTrustManager(tm)) { // Wrap the TrustManager to provide a better exception message for users to debug hostname // validation failures. tm = new EnhancingX509ExtendedTrustManager(tm); } return tm; } } throw new IllegalStateException("no X509TrustManager found"); } protected static X509KeyManager chooseX509KeyManager(KeyManager[] kms) { for (KeyManager km : kms) { if (km instanceof X509KeyManager) { return (X509KeyManager) km; } } throw new IllegalStateException("no X509KeyManager found"); } /** * Translate a {@link ApplicationProtocolConfig} object to a * {@link OpenSslApplicationProtocolNegotiator} object. * * @param config The configuration which defines the translation * @return The results of the translation */ @SuppressWarnings("deprecation") static OpenSslApplicationProtocolNegotiator toNegotiator(ApplicationProtocolConfig config) { if (config == null) { return NONE_PROTOCOL_NEGOTIATOR; } switch (config.protocol()) { case NONE: return NONE_PROTOCOL_NEGOTIATOR; case ALPN: case NPN: case NPN_AND_ALPN: switch (config.selectedListenerFailureBehavior()) { case CHOOSE_MY_LAST_PROTOCOL: case ACCEPT: switch (config.selectorFailureBehavior()) { case CHOOSE_MY_LAST_PROTOCOL: case NO_ADVERTISE: return new OpenSslDefaultApplicationProtocolNegotiator( config); default: throw new UnsupportedOperationException( new StringBuilder("OpenSSL provider does not support ") .append(config.selectorFailureBehavior()) .append(" behavior").toString()); } default: throw new UnsupportedOperationException( new StringBuilder("OpenSSL provider does not support ") .append(config.selectedListenerFailureBehavior()) .append(" behavior").toString()); } default: throw new Error(); } } static boolean useExtendedTrustManager(X509TrustManager trustManager) { return trustManager instanceof X509ExtendedTrustManager; } @Override public final int refCnt() { return refCnt.refCnt(); } @Override public final ReferenceCounted retain() { refCnt.retain(); return this; } @Override public final ReferenceCounted retain(int increment) { refCnt.retain(increment); return this; } @Override public final ReferenceCounted touch() { refCnt.touch(); return this; } @Override public final ReferenceCounted touch(Object hint) { refCnt.touch(hint); return this; } @Override public final boolean release() { return refCnt.release(); } @Override public final boolean release(int decrement) { return refCnt.release(decrement); } abstract static class AbstractCertificateVerifier extends CertificateVerifier { private final OpenSslEngineMap engineMap; AbstractCertificateVerifier(OpenSslEngineMap engineMap) { this.engineMap = engineMap; } @Override public final int verify(long ssl, byte[][] chain, String auth) { final ReferenceCountedOpenSslEngine engine = engineMap.get(ssl); if (engine == null) { // May be null if it was destroyed in the meantime. return CertificateVerifier.X509_V_ERR_UNSPECIFIED; } X509Certificate[] peerCerts = certificates(chain); try { verify(engine, peerCerts, auth); return CertificateVerifier.X509_V_OK; } catch (Throwable cause) { logger.debug("verification of certificate failed", cause); engine.initHandshakeException(cause); // Try to extract the correct error code that should be used. if (cause instanceof OpenSslCertificateException) { // This will never return a negative error code as its validated when constructing the // OpenSslCertificateException. return ((OpenSslCertificateException) cause).errorCode(); } if (cause instanceof CertificateExpiredException) { return CertificateVerifier.X509_V_ERR_CERT_HAS_EXPIRED; } if (cause instanceof CertificateNotYetValidException) { return CertificateVerifier.X509_V_ERR_CERT_NOT_YET_VALID; } return translateToError(cause); } } private static int translateToError(Throwable cause) { if (cause instanceof CertificateRevokedException) { return CertificateVerifier.X509_V_ERR_CERT_REVOKED; } // The X509TrustManagerImpl uses a Validator which wraps a CertPathValidatorException into // an CertificateException. So we need to handle the wrapped CertPathValidatorException to be // able to send the correct alert. Throwable wrapped = cause.getCause(); while (wrapped != null) { if (wrapped instanceof CertPathValidatorException) { CertPathValidatorException ex = (CertPathValidatorException) wrapped; CertPathValidatorException.Reason reason = ex.getReason(); if (reason == CertPathValidatorException.BasicReason.EXPIRED) { return CertificateVerifier.X509_V_ERR_CERT_HAS_EXPIRED; } if (reason == CertPathValidatorException.BasicReason.NOT_YET_VALID) { return CertificateVerifier.X509_V_ERR_CERT_NOT_YET_VALID; } if (reason == CertPathValidatorException.BasicReason.REVOKED) { return CertificateVerifier.X509_V_ERR_CERT_REVOKED; } } wrapped = wrapped.getCause(); } return CertificateVerifier.X509_V_ERR_UNSPECIFIED; } abstract void verify(ReferenceCountedOpenSslEngine engine, X509Certificate[] peerCerts, String auth) throws Exception; } private static final class DefaultOpenSslEngineMap implements OpenSslEngineMap { private final Map engines = PlatformDependent.newConcurrentHashMap(); @Override public ReferenceCountedOpenSslEngine remove(long ssl) { return engines.remove(ssl); } @Override public void add(ReferenceCountedOpenSslEngine engine) { engines.put(engine.sslPointer(), engine); } @Override public ReferenceCountedOpenSslEngine get(long ssl) { return engines.get(ssl); } } static void setKeyMaterial(long ctx, X509Certificate[] keyCertChain, PrivateKey key, String keyPassword) throws SSLException { /* Load the certificate file and private key. */ long keyBio = 0; long keyCertChainBio = 0; long keyCertChainBio2 = 0; PemEncoded encoded = null; try { // Only encode one time encoded = PemX509Certificate.toPEM(ByteBufAllocator.DEFAULT, true, keyCertChain); keyCertChainBio = toBIO(ByteBufAllocator.DEFAULT, encoded.retain()); keyCertChainBio2 = toBIO(ByteBufAllocator.DEFAULT, encoded.retain()); if (key != null) { keyBio = toBIO(ByteBufAllocator.DEFAULT, key); } SSLContext.setCertificateBio( ctx, keyCertChainBio, keyBio, keyPassword == null ? StringUtil.EMPTY_STRING : keyPassword); // We may have more then one cert in the chain so add all of them now. SSLContext.setCertificateChainBio(ctx, keyCertChainBio2, true); } catch (SSLException e) { throw e; } catch (Exception e) { throw new SSLException("failed to set certificate and key", e); } finally { freeBio(keyBio); freeBio(keyCertChainBio); freeBio(keyCertChainBio2); if (encoded != null) { encoded.release(); } } } static void freeBio(long bio) { if (bio != 0) { SSL.freeBIO(bio); } } /** * Return the pointer to a in-memory BIO * or {@code 0} if the {@code key} is {@code null}. The BIO contains the content of the {@code key}. */ static long toBIO(ByteBufAllocator allocator, PrivateKey key) throws Exception { if (key == null) { return 0; } PemEncoded pem = PemPrivateKey.toPEM(allocator, true, key); try { return toBIO(allocator, pem.retain()); } finally { pem.release(); } } /** * Return the pointer to a in-memory BIO * or {@code 0} if the {@code certChain} is {@code null}. The BIO contains the content of the {@code certChain}. */ static long toBIO(ByteBufAllocator allocator, X509Certificate... certChain) throws Exception { if (certChain == null) { return 0; } checkNonEmpty(certChain, "certChain"); PemEncoded pem = PemX509Certificate.toPEM(allocator, true, certChain); try { return toBIO(allocator, pem.retain()); } finally { pem.release(); } } static long toBIO(ByteBufAllocator allocator, PemEncoded pem) throws Exception { try { // We can turn direct buffers straight into BIOs. No need to // make a yet another copy. ByteBuf content = pem.content(); if (content.isDirect()) { return newBIO(content.retainedSlice()); } ByteBuf buffer = allocator.directBuffer(content.readableBytes()); try { buffer.writeBytes(content, content.readerIndex(), content.readableBytes()); return newBIO(buffer.retainedSlice()); } finally { try { // If the contents of the ByteBuf is sensitive (e.g. a PrivateKey) we // need to zero out the bytes of the copy before we're releasing it. if (pem.isSensitive()) { SslUtils.zeroout(buffer); } } finally { buffer.release(); } } } finally { pem.release(); } } private static long newBIO(ByteBuf buffer) throws Exception { try { long bio = SSL.newMemBIO(); int readable = buffer.readableBytes(); if (SSL.bioWrite(bio, OpenSsl.memoryAddress(buffer) + buffer.readerIndex(), readable) != readable) { SSL.freeBIO(bio); throw new IllegalStateException("Could not write data to memory BIO"); } return bio; } finally { buffer.release(); } } /** * Returns the {@link OpenSslKeyMaterialProvider} that should be used for OpenSSL. Depending on the given * {@link KeyManagerFactory} this may cache the {@link OpenSslKeyMaterial} for better performance if it can * ensure that the same material is always returned for the same alias. */ static OpenSslKeyMaterialProvider providerFor(KeyManagerFactory factory, String password) { if (factory instanceof OpenSslX509KeyManagerFactory) { return ((OpenSslX509KeyManagerFactory) factory).newProvider(); } if (factory instanceof OpenSslCachingX509KeyManagerFactory) { // The user explicit used OpenSslCachingX509KeyManagerFactory which signals us that its fine to cache. return ((OpenSslCachingX509KeyManagerFactory) factory).newProvider(password); } // We can not be sure if the material may change at runtime so we will not cache it. return new OpenSslKeyMaterialProvider(chooseX509KeyManager(factory.getKeyManagers()), password); } private static ReferenceCountedOpenSslEngine retrieveEngine(OpenSslEngineMap engineMap, long ssl) throws SSLException { ReferenceCountedOpenSslEngine engine = engineMap.get(ssl); if (engine == null) { throw new SSLException("Could not find a " + StringUtil.simpleClassName(ReferenceCountedOpenSslEngine.class) + " for sslPointer " + ssl); } return engine; } private static final class PrivateKeyMethod implements SSLPrivateKeyMethod { private final OpenSslEngineMap engineMap; private final OpenSslPrivateKeyMethod keyMethod; PrivateKeyMethod(OpenSslEngineMap engineMap, OpenSslPrivateKeyMethod keyMethod) { this.engineMap = engineMap; this.keyMethod = keyMethod; } @Override public byte[] sign(long ssl, int signatureAlgorithm, byte[] digest) throws Exception { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); try { return verifyResult(keyMethod.sign(engine, signatureAlgorithm, digest)); } catch (Exception e) { engine.initHandshakeException(e); throw e; } } @Override public byte[] decrypt(long ssl, byte[] input) throws Exception { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); try { return verifyResult(keyMethod.decrypt(engine, input)); } catch (Exception e) { engine.initHandshakeException(e); throw e; } } } private static final class AsyncPrivateKeyMethod implements AsyncSSLPrivateKeyMethod { private final OpenSslEngineMap engineMap; private final OpenSslAsyncPrivateKeyMethod keyMethod; AsyncPrivateKeyMethod(OpenSslEngineMap engineMap, OpenSslAsyncPrivateKeyMethod keyMethod) { this.engineMap = engineMap; this.keyMethod = keyMethod; } @Override public void sign(long ssl, int signatureAlgorithm, byte[] bytes, ResultCallback resultCallback) { try { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); keyMethod.sign(engine, signatureAlgorithm, bytes) .addListener(new ResultCallbackListener(engine, ssl, resultCallback)); } catch (SSLException e) { resultCallback.onError(ssl, e); } } @Override public void decrypt(long ssl, byte[] bytes, ResultCallback resultCallback) { try { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); keyMethod.decrypt(engine, bytes) .addListener(new ResultCallbackListener(engine, ssl, resultCallback)); } catch (SSLException e) { resultCallback.onError(ssl, e); } } private static final class ResultCallbackListener implements FutureListener { private final ReferenceCountedOpenSslEngine engine; private final long ssl; private final ResultCallback resultCallback; ResultCallbackListener(ReferenceCountedOpenSslEngine engine, long ssl, ResultCallback resultCallback) { this.engine = engine; this.ssl = ssl; this.resultCallback = resultCallback; } @Override public void operationComplete(Future future) { Throwable cause = future.cause(); if (cause == null) { try { byte[] result = verifyResult(future.getNow()); resultCallback.onSuccess(ssl, result); return; } catch (SignatureException e) { cause = e; engine.initHandshakeException(e); } } resultCallback.onError(ssl, cause); } } } private static byte[] verifyResult(byte[] result) throws SignatureException { if (result == null) { throw new SignatureException(); } return result; } private static final class CompressionAlgorithm implements CertificateCompressionAlgo { private final OpenSslEngineMap engineMap; private final OpenSslCertificateCompressionAlgorithm compressionAlgorithm; CompressionAlgorithm(OpenSslEngineMap engineMap, OpenSslCertificateCompressionAlgorithm compressionAlgorithm) { this.engineMap = engineMap; this.compressionAlgorithm = compressionAlgorithm; } @Override public byte[] compress(long ssl, byte[] bytes) throws Exception { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); return compressionAlgorithm.compress(engine, bytes); } @Override public byte[] decompress(long ssl, int len, byte[] bytes) throws Exception { ReferenceCountedOpenSslEngine engine = retrieveEngine(engineMap, ssl); return compressionAlgorithm.decompress(engine, len, bytes); } @Override public int algorithmId() { return compressionAlgorithm.algorithmId(); } } }





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