| /* |
| * Copyright (c) 1996, 2016, Oracle and/or its affiliates. All rights reserved. |
| * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
| * |
| * This code is free software; you can redistribute it and/or modify it |
| * under the terms of the GNU General Public License version 2 only, as |
| * published by the Free Software Foundation. Oracle designates this |
| * particular file as subject to the "Classpath" exception as provided |
| * by Oracle in the LICENSE file that accompanied this code. |
| * |
| * This code is distributed in the hope that it will be useful, but WITHOUT |
| * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
| * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
| * version 2 for more details (a copy is included in the LICENSE file that |
| * accompanied this code). |
| * |
| * You should have received a copy of the GNU General Public License version |
| * 2 along with this work; if not, write to the Free Software Foundation, |
| * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
| * |
| * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
| * or visit www.oracle.com if you need additional information or have any |
| * questions. |
| */ |
| |
| |
| package sun.security.ssl; |
| |
| import java.io.*; |
| import java.util.*; |
| import java.util.concurrent.TimeUnit; |
| import java.security.*; |
| import java.security.cert.*; |
| import java.security.interfaces.*; |
| import java.security.spec.ECParameterSpec; |
| import java.math.BigInteger; |
| |
| import javax.crypto.SecretKey; |
| import javax.net.ssl.*; |
| |
| import sun.security.action.GetLongAction; |
| import sun.security.util.KeyUtil; |
| import sun.security.util.LegacyAlgorithmConstraints; |
| import sun.security.action.GetPropertyAction; |
| import sun.security.ssl.HandshakeMessage.*; |
| import sun.security.ssl.CipherSuite.*; |
| import sun.security.ssl.SignatureAndHashAlgorithm.*; |
| import static sun.security.ssl.CipherSuite.KeyExchange.*; |
| |
| /** |
| * ServerHandshaker does the protocol handshaking from the point |
| * of view of a server. It is driven asychronously by handshake messages |
| * as delivered by the parent Handshaker class, and also uses |
| * common functionality (e.g. key generation) that is provided there. |
| * |
| * @author David Brownell |
| */ |
| final class ServerHandshaker extends Handshaker { |
| |
| // The default number of milliseconds the handshaker will wait for |
| // revocation status responses. |
| private static final long DEFAULT_STATUS_RESP_DELAY = 5000; |
| |
| // is the server going to require the client to authenticate? |
| private ClientAuthType doClientAuth; |
| |
| // our authentication info |
| private X509Certificate[] certs; |
| private PrivateKey privateKey; |
| |
| private Object serviceCreds; |
| |
| // flag to check for clientCertificateVerify message |
| private boolean needClientVerify = false; |
| |
| /* |
| * For exportable ciphersuites using non-exportable key sizes, we use |
| * ephemeral RSA keys. We could also do anonymous RSA in the same way |
| * but there are no such ciphersuites currently defined. |
| */ |
| private PrivateKey tempPrivateKey; |
| private PublicKey tempPublicKey; |
| |
| /* |
| * For anonymous and ephemeral Diffie-Hellman key exchange, we use |
| * ephemeral Diffie-Hellman keys. |
| */ |
| private DHCrypt dh; |
| |
| // Helper for ECDH based key exchanges |
| private ECDHCrypt ecdh; |
| |
| // version request by the client in its ClientHello |
| // we remember it for the RSA premaster secret version check |
| private ProtocolVersion clientRequestedVersion; |
| |
| private SupportedEllipticCurvesExtension supportedCurves; |
| |
| // the preferable signature algorithm used by ServerKeyExchange message |
| SignatureAndHashAlgorithm preferableSignatureAlgorithm; |
| |
| // Flag to use smart ephemeral DH key which size matches the corresponding |
| // authentication key |
| private static final boolean useSmartEphemeralDHKeys; |
| |
| // Flag to use legacy ephemeral DH key which size is 512 bits for |
| // exportable cipher suites, and 768 bits for others |
| private static final boolean useLegacyEphemeralDHKeys; |
| |
| // The customized ephemeral DH key size for non-exportable cipher suites. |
| private static final int customizedDHKeySize; |
| |
| // legacy algorithm constraints |
| private static final AlgorithmConstraints legacyAlgorithmConstraints = |
| new LegacyAlgorithmConstraints( |
| LegacyAlgorithmConstraints.PROPERTY_TLS_LEGACY_ALGS, |
| new SSLAlgorithmDecomposer()); |
| |
| private long statusRespTimeout; |
| |
| static { |
| String property = |
| GetPropertyAction.getProperty("jdk.tls.ephemeralDHKeySize"); |
| if (property == null || property.length() == 0) { |
| useLegacyEphemeralDHKeys = false; |
| useSmartEphemeralDHKeys = false; |
| customizedDHKeySize = -1; |
| } else if ("matched".equals(property)) { |
| useLegacyEphemeralDHKeys = false; |
| useSmartEphemeralDHKeys = true; |
| customizedDHKeySize = -1; |
| } else if ("legacy".equals(property)) { |
| useLegacyEphemeralDHKeys = true; |
| useSmartEphemeralDHKeys = false; |
| customizedDHKeySize = -1; |
| } else { |
| useLegacyEphemeralDHKeys = false; |
| useSmartEphemeralDHKeys = false; |
| |
| try { |
| // DH parameter generation can be extremely slow, best to |
| // use one of the supported pre-computed DH parameters |
| // (see DHCrypt class). |
| customizedDHKeySize = Integer.parseUnsignedInt(property); |
| if (customizedDHKeySize < 1024 || customizedDHKeySize > 8192 || |
| (customizedDHKeySize & 0x3f) != 0) { |
| throw new IllegalArgumentException( |
| "Unsupported customized DH key size: " + |
| customizedDHKeySize + ". " + |
| "The key size must be multiple of 64, " + |
| "and can only range from 1024 to 8192 (inclusive)"); |
| } |
| } catch (NumberFormatException nfe) { |
| throw new IllegalArgumentException( |
| "Invalid system property jdk.tls.ephemeralDHKeySize"); |
| } |
| } |
| } |
| |
| /* |
| * Constructor ... use the keys found in the auth context. |
| */ |
| ServerHandshaker(SSLSocketImpl socket, SSLContextImpl context, |
| ProtocolList enabledProtocols, ClientAuthType clientAuth, |
| ProtocolVersion activeProtocolVersion, boolean isInitialHandshake, |
| boolean secureRenegotiation, |
| byte[] clientVerifyData, byte[] serverVerifyData) { |
| |
| super(socket, context, enabledProtocols, |
| (clientAuth != ClientAuthType.CLIENT_AUTH_NONE), false, |
| activeProtocolVersion, isInitialHandshake, secureRenegotiation, |
| clientVerifyData, serverVerifyData); |
| doClientAuth = clientAuth; |
| statusRespTimeout = AccessController.doPrivileged( |
| new GetLongAction("jdk.tls.stapling.responseTimeout", |
| DEFAULT_STATUS_RESP_DELAY)); |
| statusRespTimeout = statusRespTimeout >= 0 ? statusRespTimeout : |
| DEFAULT_STATUS_RESP_DELAY; |
| } |
| |
| /* |
| * Constructor ... use the keys found in the auth context. |
| */ |
| ServerHandshaker(SSLEngineImpl engine, SSLContextImpl context, |
| ProtocolList enabledProtocols, ClientAuthType clientAuth, |
| ProtocolVersion activeProtocolVersion, |
| boolean isInitialHandshake, boolean secureRenegotiation, |
| byte[] clientVerifyData, byte[] serverVerifyData, |
| boolean isDTLS) { |
| |
| super(engine, context, enabledProtocols, |
| (clientAuth != ClientAuthType.CLIENT_AUTH_NONE), false, |
| activeProtocolVersion, isInitialHandshake, secureRenegotiation, |
| clientVerifyData, serverVerifyData, isDTLS); |
| doClientAuth = clientAuth; |
| statusRespTimeout = AccessController.doPrivileged( |
| new GetLongAction("jdk.tls.stapling.responseTimeout", |
| DEFAULT_STATUS_RESP_DELAY)); |
| statusRespTimeout = statusRespTimeout >= 0 ? statusRespTimeout : |
| DEFAULT_STATUS_RESP_DELAY; |
| } |
| |
| /* |
| * As long as handshaking has not started, we can change |
| * whether client authentication is required. Otherwise, |
| * we will need to wait for the next handshake. |
| */ |
| void setClientAuth(ClientAuthType clientAuth) { |
| doClientAuth = clientAuth; |
| } |
| |
| /* |
| * This routine handles all the server side handshake messages, one at |
| * a time. Given the message type (and in some cases the pending cipher |
| * spec) it parses the type-specific message. Then it calls a function |
| * that handles that specific message. |
| * |
| * It updates the state machine as each message is processed, and writes |
| * responses as needed using the connection in the constructor. |
| */ |
| @Override |
| void processMessage(byte type, int message_len) |
| throws IOException { |
| |
| // check the handshake state |
| handshakeState.check(type); |
| |
| switch (type) { |
| case HandshakeMessage.ht_client_hello: |
| ClientHello ch = new ClientHello(input, message_len, isDTLS); |
| handshakeState.update(ch, resumingSession); |
| |
| /* |
| * send it off for processing. |
| */ |
| this.clientHello(ch); |
| break; |
| |
| case HandshakeMessage.ht_certificate: |
| if (doClientAuth == ClientAuthType.CLIENT_AUTH_NONE) { |
| fatalSE(Alerts.alert_unexpected_message, |
| "client sent unsolicited cert chain"); |
| // NOTREACHED |
| } |
| CertificateMsg certificateMsg = new CertificateMsg(input); |
| handshakeState.update(certificateMsg, resumingSession); |
| this.clientCertificate(certificateMsg); |
| break; |
| |
| case HandshakeMessage.ht_client_key_exchange: |
| SecretKey preMasterSecret; |
| switch (keyExchange) { |
| case K_RSA: |
| case K_RSA_EXPORT: |
| /* |
| * The client's pre-master secret is decrypted using |
| * either the server's normal private RSA key, or the |
| * temporary one used for non-export or signing-only |
| * certificates/keys. |
| */ |
| RSAClientKeyExchange pms = new RSAClientKeyExchange( |
| protocolVersion, clientRequestedVersion, |
| sslContext.getSecureRandom(), input, |
| message_len, privateKey); |
| handshakeState.update(pms, resumingSession); |
| preMasterSecret = this.clientKeyExchange(pms); |
| break; |
| case K_DHE_RSA: |
| case K_DHE_DSS: |
| case K_DH_ANON: |
| /* |
| * The pre-master secret is derived using the normal |
| * Diffie-Hellman calculation. Note that the main |
| * protocol difference in these five flavors is in how |
| * the ServerKeyExchange message was constructed! |
| */ |
| DHClientKeyExchange dhcke = new DHClientKeyExchange(input); |
| handshakeState.update(dhcke, resumingSession); |
| preMasterSecret = this.clientKeyExchange(dhcke); |
| break; |
| case K_ECDH_RSA: |
| case K_ECDH_ECDSA: |
| case K_ECDHE_RSA: |
| case K_ECDHE_ECDSA: |
| case K_ECDH_ANON: |
| ECDHClientKeyExchange ecdhcke = |
| new ECDHClientKeyExchange(input); |
| handshakeState.update(ecdhcke, resumingSession); |
| preMasterSecret = this.clientKeyExchange(ecdhcke); |
| break; |
| default: |
| ClientKeyExchangeService p = |
| ClientKeyExchangeService.find(keyExchange.name); |
| if (p == null) { |
| throw new SSLProtocolException |
| ("Unrecognized key exchange: " + keyExchange); |
| } |
| byte[] encodedTicket = input.getBytes16(); |
| input.getBytes16(); |
| byte[] secret = input.getBytes16(); |
| ClientKeyExchange cke = p.createServerExchange(protocolVersion, |
| clientRequestedVersion, |
| sslContext.getSecureRandom(), |
| encodedTicket, |
| secret, |
| this.getAccSE(), serviceCreds); |
| handshakeState.update(cke, resumingSession); |
| preMasterSecret = this.clientKeyExchange(cke); |
| break; |
| } |
| |
| // |
| // All keys are calculated from the premaster secret |
| // and the exchanged nonces in the same way. |
| // |
| calculateKeys(preMasterSecret, clientRequestedVersion); |
| break; |
| |
| case HandshakeMessage.ht_certificate_verify: |
| CertificateVerify cvm = |
| new CertificateVerify(input, |
| getLocalSupportedSignAlgs(), protocolVersion); |
| handshakeState.update(cvm, resumingSession); |
| this.clientCertificateVerify(cvm); |
| |
| break; |
| |
| case HandshakeMessage.ht_finished: |
| Finished cfm = |
| new Finished(protocolVersion, input, cipherSuite); |
| handshakeState.update(cfm, resumingSession); |
| this.clientFinished(cfm); |
| |
| break; |
| |
| default: |
| throw new SSLProtocolException( |
| "Illegal server handshake msg, " + type); |
| } |
| |
| } |
| |
| |
| /* |
| * ClientHello presents the server with a bunch of options, to which the |
| * server replies with a ServerHello listing the ones which this session |
| * will use. If needed, it also writes its Certificate plus in some cases |
| * a ServerKeyExchange message. It may also write a CertificateRequest, |
| * to elicit a client certificate. |
| * |
| * All these messages are terminated by a ServerHelloDone message. In |
| * most cases, all this can be sent in a single Record. |
| */ |
| private void clientHello(ClientHello mesg) throws IOException { |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| // Reject client initiated renegotiation? |
| // |
| // If server side should reject client-initiated renegotiation, |
| // send an alert_handshake_failure fatal alert, not a no_renegotiation |
| // warning alert (no_renegotiation must be a warning: RFC 2246). |
| // no_renegotiation might seem more natural at first, but warnings |
| // are not appropriate because the sending party does not know how |
| // the receiving party will behave. This state must be treated as |
| // a fatal server condition. |
| // |
| // This will not have any impact on server initiated renegotiation. |
| if (rejectClientInitiatedRenego && !isInitialHandshake && |
| !serverHelloRequested) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "Client initiated renegotiation is not allowed"); |
| } |
| |
| // check the server name indication if required |
| ServerNameExtension clientHelloSNIExt = (ServerNameExtension) |
| mesg.extensions.get(ExtensionType.EXT_SERVER_NAME); |
| if (!sniMatchers.isEmpty()) { |
| // we do not reject client without SNI extension |
| if (clientHelloSNIExt != null && |
| !clientHelloSNIExt.isMatched(sniMatchers)) { |
| fatalSE(Alerts.alert_unrecognized_name, |
| "Unrecognized server name indication"); |
| } |
| } |
| |
| // Does the message include security renegotiation indication? |
| boolean renegotiationIndicated = false; |
| |
| // check the TLS_EMPTY_RENEGOTIATION_INFO_SCSV |
| CipherSuiteList cipherSuites = mesg.getCipherSuites(); |
| if (cipherSuites.contains(CipherSuite.C_SCSV)) { |
| renegotiationIndicated = true; |
| if (isInitialHandshake) { |
| secureRenegotiation = true; |
| } else { |
| // abort the handshake with a fatal handshake_failure alert |
| if (secureRenegotiation) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "The SCSV is present in a secure renegotiation"); |
| } else { |
| fatalSE(Alerts.alert_handshake_failure, |
| "The SCSV is present in a insecure renegotiation"); |
| } |
| } |
| } |
| |
| // check the "renegotiation_info" extension |
| RenegotiationInfoExtension clientHelloRI = (RenegotiationInfoExtension) |
| mesg.extensions.get(ExtensionType.EXT_RENEGOTIATION_INFO); |
| if (clientHelloRI != null) { |
| renegotiationIndicated = true; |
| if (isInitialHandshake) { |
| // verify the length of the "renegotiated_connection" field |
| if (!clientHelloRI.isEmpty()) { |
| // abort the handshake with a fatal handshake_failure alert |
| fatalSE(Alerts.alert_handshake_failure, |
| "The renegotiation_info field is not empty"); |
| } |
| |
| secureRenegotiation = true; |
| } else { |
| if (!secureRenegotiation) { |
| // unexpected RI extension for insecure renegotiation, |
| // abort the handshake with a fatal handshake_failure alert |
| fatalSE(Alerts.alert_handshake_failure, |
| "The renegotiation_info is present in a insecure " + |
| "renegotiation"); |
| } |
| |
| // verify the client_verify_data value |
| if (!MessageDigest.isEqual(clientVerifyData, |
| clientHelloRI.getRenegotiatedConnection())) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "Incorrect verify data in ClientHello " + |
| "renegotiation_info message"); |
| } |
| } |
| } else if (!isInitialHandshake && secureRenegotiation) { |
| // if the connection's "secure_renegotiation" flag is set to TRUE |
| // and the "renegotiation_info" extension is not present, abort |
| // the handshake. |
| fatalSE(Alerts.alert_handshake_failure, |
| "Inconsistent secure renegotiation indication"); |
| } |
| |
| // if there is no security renegotiation indication or the previous |
| // handshake is insecure. |
| if (!renegotiationIndicated || !secureRenegotiation) { |
| if (isInitialHandshake) { |
| if (!allowLegacyHelloMessages) { |
| // abort the handshake with a fatal handshake_failure alert |
| fatalSE(Alerts.alert_handshake_failure, |
| "Failed to negotiate the use of secure renegotiation"); |
| } |
| |
| // continue with legacy ClientHello |
| if (debug != null && Debug.isOn("handshake")) { |
| System.out.println("Warning: No renegotiation " + |
| "indication in ClientHello, allow legacy ClientHello"); |
| } |
| } else if (!allowUnsafeRenegotiation) { |
| // abort the handshake |
| if (activeProtocolVersion.useTLS10PlusSpec()) { |
| // respond with a no_renegotiation warning |
| warningSE(Alerts.alert_no_renegotiation); |
| |
| // invalidate the handshake so that the caller can |
| // dispose this object. |
| invalidated = true; |
| |
| // If there is still unread block in the handshake |
| // input stream, it would be truncated with the disposal |
| // and the next handshake message will become incomplete. |
| // |
| // However, according to SSL/TLS specifications, no more |
| // handshake message could immediately follow ClientHello |
| // or HelloRequest. But in case of any improper messages, |
| // we'd better check to ensure there is no remaining bytes |
| // in the handshake input stream. |
| if (input.available() > 0) { |
| fatalSE(Alerts.alert_unexpected_message, |
| "ClientHello followed by an unexpected " + |
| "handshake message"); |
| } |
| |
| return; |
| } else { |
| // For SSLv3, send the handshake_failure fatal error. |
| // Note that SSLv3 does not define a no_renegotiation |
| // alert like TLSv1. However we cannot ignore the message |
| // simply, otherwise the other side was waiting for a |
| // response that would never come. |
| fatalSE(Alerts.alert_handshake_failure, |
| "Renegotiation is not allowed"); |
| } |
| } else { // !isInitialHandshake && allowUnsafeRenegotiation |
| // continue with unsafe renegotiation. |
| if (debug != null && Debug.isOn("handshake")) { |
| System.out.println( |
| "Warning: continue with insecure renegotiation"); |
| } |
| } |
| } |
| |
| // check the "max_fragment_length" extension |
| MaxFragmentLengthExtension maxFragLenExt = (MaxFragmentLengthExtension) |
| mesg.extensions.get(ExtensionType.EXT_MAX_FRAGMENT_LENGTH); |
| if ((maxFragLenExt != null) && (maximumPacketSize != 0)) { |
| // Not yet consider the impact of IV/MAC/padding. |
| int estimatedMaxFragSize = maximumPacketSize; |
| if (isDTLS) { |
| estimatedMaxFragSize -= DTLSRecord.headerSize; |
| } else { |
| estimatedMaxFragSize -= SSLRecord.headerSize; |
| } |
| |
| if (maxFragLenExt.getMaxFragLen() > estimatedMaxFragSize) { |
| // For better interoperability, abort the maximum fragment |
| // length negotiation, rather than terminate the connection |
| // with a fatal alert. |
| maxFragLenExt = null; |
| |
| // fatalSE(Alerts.alert_illegal_parameter, |
| // "Not an allowed max_fragment_length value"); |
| } |
| } |
| |
| // check the ALPN extension |
| ALPNExtension clientHelloALPN = (ALPNExtension) |
| mesg.extensions.get(ExtensionType.EXT_ALPN); |
| |
| if ((clientHelloALPN != null) && (localApl.length > 0)) { |
| |
| // Intersect the requested and the locally supported, |
| // and save for later. |
| String negotiatedValue = null; |
| List<String> protocols = clientHelloALPN.getPeerAPs(); |
| |
| // Use server preference order |
| for (String ap : localApl) { |
| if (protocols.contains(ap)) { |
| negotiatedValue = ap; |
| break; |
| } |
| } |
| |
| if (negotiatedValue == null) { |
| fatalSE(Alerts.alert_no_application_protocol, |
| new SSLHandshakeException( |
| "No matching ALPN values")); |
| } |
| applicationProtocol = negotiatedValue; |
| |
| } else { |
| applicationProtocol = ""; |
| } |
| |
| // cookie exchange |
| if (isDTLS) { |
| HelloCookieManager hcMgr = sslContext.getHelloCookieManager(); |
| if ((mesg.cookie == null) || (mesg.cookie.length == 0) || |
| (!hcMgr.isValid(mesg))) { |
| |
| // |
| // Perform cookie exchange for DTLS handshaking if no cookie |
| // or the cookie is invalid in the ClientHello message. |
| // |
| HelloVerifyRequest m0 = new HelloVerifyRequest(hcMgr, mesg); |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| m0.print(System.out); |
| } |
| |
| m0.write(output); |
| handshakeState.update(m0, resumingSession); |
| output.flush(); |
| |
| return; |
| } |
| } |
| |
| /* |
| * FIRST, construct the ServerHello using the options and priorities |
| * from the ClientHello. Update the (pending) cipher spec as we do |
| * so, and save the client's version to protect against rollback |
| * attacks. |
| * |
| * There are a bunch of minor tasks here, and one major one: deciding |
| * if the short or the full handshake sequence will be used. |
| */ |
| ServerHello m1 = new ServerHello(); |
| |
| clientRequestedVersion = mesg.protocolVersion; |
| |
| // select a proper protocol version. |
| ProtocolVersion selectedVersion = |
| selectProtocolVersion(clientRequestedVersion); |
| if (selectedVersion == null || |
| selectedVersion.v == ProtocolVersion.SSL20Hello.v) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "Client requested protocol " + clientRequestedVersion + |
| " not enabled or not supported"); |
| } |
| |
| handshakeHash.protocolDetermined(selectedVersion); |
| setVersion(selectedVersion); |
| |
| m1.protocolVersion = protocolVersion; |
| |
| // |
| // random ... save client and server values for later use |
| // in computing the master secret (from pre-master secret) |
| // and thence the other crypto keys. |
| // |
| // NOTE: this use of three inputs to generating _each_ set |
| // of ciphers slows things down, but it does increase the |
| // security since each connection in the session can hold |
| // its own authenticated (and strong) keys. One could make |
| // creation of a session a rare thing... |
| // |
| clnt_random = mesg.clnt_random; |
| svr_random = new RandomCookie(sslContext.getSecureRandom()); |
| m1.svr_random = svr_random; |
| |
| session = null; // forget about the current session |
| // |
| // Here we go down either of two paths: (a) the fast one, where |
| // the client's asked to rejoin an existing session, and the server |
| // permits this; (b) the other one, where a new session is created. |
| // |
| if (mesg.sessionId.length() != 0) { |
| // client is trying to resume a session, let's see... |
| |
| SSLSessionImpl previous = ((SSLSessionContextImpl)sslContext |
| .engineGetServerSessionContext()) |
| .get(mesg.sessionId.getId()); |
| // |
| // Check if we can use the fast path, resuming a session. We |
| // can do so iff we have a valid record for that session, and |
| // the cipher suite for that session was on the list which the |
| // client requested, and if we're not forgetting any needed |
| // authentication on the part of the client. |
| // |
| if (previous != null) { |
| resumingSession = previous.isRejoinable(); |
| |
| if (resumingSession) { |
| ProtocolVersion oldVersion = previous.getProtocolVersion(); |
| // cannot resume session with different version |
| if (oldVersion != protocolVersion) { |
| resumingSession = false; |
| } |
| } |
| |
| // cannot resume session with different server name indication |
| if (resumingSession) { |
| List<SNIServerName> oldServerNames = |
| previous.getRequestedServerNames(); |
| if (clientHelloSNIExt != null) { |
| if (!clientHelloSNIExt.isIdentical(oldServerNames)) { |
| resumingSession = false; |
| } |
| } else if (!oldServerNames.isEmpty()) { |
| resumingSession = false; |
| } |
| |
| if (!resumingSession && |
| debug != null && Debug.isOn("handshake")) { |
| System.out.println( |
| "The requested server name indication " + |
| "is not identical to the previous one"); |
| } |
| } |
| |
| if (resumingSession && |
| (doClientAuth == ClientAuthType.CLIENT_AUTH_REQUIRED)) { |
| try { |
| previous.getPeerPrincipal(); |
| } catch (SSLPeerUnverifiedException e) { |
| resumingSession = false; |
| } |
| } |
| |
| // validate subject identity |
| if (resumingSession) { |
| CipherSuite suite = previous.getSuite(); |
| ClientKeyExchangeService p = |
| ClientKeyExchangeService.find(suite.keyExchange.name); |
| if (p != null) { |
| Principal localPrincipal = previous.getLocalPrincipal(); |
| |
| if (p.isRelated( |
| false, getAccSE(), localPrincipal)) { |
| if (debug != null && Debug.isOn("session")) |
| System.out.println("Subject can" + |
| " provide creds for princ"); |
| } else { |
| resumingSession = false; |
| if (debug != null && Debug.isOn("session")) |
| System.out.println("Subject cannot" + |
| " provide creds for princ"); |
| } |
| } |
| } |
| |
| if (resumingSession) { |
| CipherSuite suite = previous.getSuite(); |
| // verify that the ciphersuite from the cached session |
| // is in the list of client requested ciphersuites and |
| // we have it enabled |
| if ((isNegotiable(suite) == false) || |
| (mesg.getCipherSuites().contains(suite) == false)) { |
| resumingSession = false; |
| } else { |
| // everything looks ok, set the ciphersuite |
| // this should be done last when we are sure we |
| // will resume |
| setCipherSuite(suite); |
| } |
| } |
| |
| if (resumingSession) { |
| session = previous; |
| if (debug != null && |
| (Debug.isOn("handshake") || Debug.isOn("session"))) { |
| System.out.println("%% Resuming " + session); |
| } |
| } |
| } |
| } // else client did not try to resume |
| |
| // |
| // If client hasn't specified a session we can resume, start a |
| // new one and choose its cipher suite and compression options. |
| // Unless new session creation is disabled for this connection! |
| // |
| if (session == null) { |
| if (!enableNewSession) { |
| throw new SSLException("Client did not resume a session"); |
| } |
| |
| supportedCurves = (SupportedEllipticCurvesExtension) |
| mesg.extensions.get(ExtensionType.EXT_ELLIPTIC_CURVES); |
| |
| // We only need to handle the "signature_algorithm" extension |
| // for full handshakes and TLS 1.2 or later. |
| if (protocolVersion.useTLS12PlusSpec()) { |
| SignatureAlgorithmsExtension signAlgs = |
| (SignatureAlgorithmsExtension)mesg.extensions.get( |
| ExtensionType.EXT_SIGNATURE_ALGORITHMS); |
| if (signAlgs != null) { |
| Collection<SignatureAndHashAlgorithm> peerSignAlgs = |
| signAlgs.getSignAlgorithms(); |
| if (peerSignAlgs == null || peerSignAlgs.isEmpty()) { |
| throw new SSLHandshakeException( |
| "No peer supported signature algorithms"); |
| } |
| |
| Collection<SignatureAndHashAlgorithm> |
| supportedPeerSignAlgs = |
| SignatureAndHashAlgorithm.getSupportedAlgorithms( |
| algorithmConstraints, peerSignAlgs); |
| if (supportedPeerSignAlgs.isEmpty()) { |
| throw new SSLHandshakeException( |
| "No signature and hash algorithm in common"); |
| } |
| |
| setPeerSupportedSignAlgs(supportedPeerSignAlgs); |
| } // else, need to use peer implicit supported signature algs |
| } |
| |
| session = new SSLSessionImpl(protocolVersion, CipherSuite.C_NULL, |
| getLocalSupportedSignAlgs(), |
| sslContext.getSecureRandom(), |
| getHostAddressSE(), getPortSE()); |
| |
| if (protocolVersion.useTLS12PlusSpec()) { |
| if (peerSupportedSignAlgs != null) { |
| session.setPeerSupportedSignatureAlgorithms( |
| peerSupportedSignAlgs); |
| } // else, we will set the implicit peer supported signature |
| // algorithms in chooseCipherSuite() |
| } |
| |
| // set the server name indication in the session |
| List<SNIServerName> clientHelloSNI = |
| Collections.<SNIServerName>emptyList(); |
| if (clientHelloSNIExt != null) { |
| clientHelloSNI = clientHelloSNIExt.getServerNames(); |
| } |
| session.setRequestedServerNames(clientHelloSNI); |
| |
| // set the handshake session |
| setHandshakeSessionSE(session); |
| |
| // choose cipher suite and corresponding private key |
| chooseCipherSuite(mesg); |
| |
| session.setSuite(cipherSuite); |
| session.setLocalPrivateKey(privateKey); |
| |
| // chooseCompression(mesg); |
| |
| // set the negotiated maximum fragment in the session |
| // |
| // The protocol version and cipher suite have been negotiated |
| // in previous processes. |
| if (maxFragLenExt != null) { |
| int maxFragLen = maxFragLenExt.getMaxFragLen(); |
| |
| // More check of the requested "max_fragment_length" extension. |
| if (maximumPacketSize != 0) { |
| int estimatedMaxFragSize = cipherSuite.calculatePacketSize( |
| maxFragLen, protocolVersion, isDTLS); |
| if (estimatedMaxFragSize > maximumPacketSize) { |
| // For better interoperability, abort the maximum |
| // fragment length negotiation, rather than terminate |
| // the connection with a fatal alert. |
| maxFragLenExt = null; |
| |
| // fatalSE(Alerts.alert_illegal_parameter, |
| // "Not an allowed max_fragment_length value"); |
| } |
| } |
| |
| if (maxFragLenExt != null) { |
| session.setNegotiatedMaxFragSize(maxFragLen); |
| } |
| } |
| |
| session.setMaximumPacketSize(maximumPacketSize); |
| } else { |
| // set the handshake session |
| setHandshakeSessionSE(session); |
| } |
| |
| if (protocolVersion.useTLS12PlusSpec()) { |
| handshakeHash.setFinishedAlg(cipherSuite.prfAlg.getPRFHashAlg()); |
| } |
| |
| m1.cipherSuite = cipherSuite; |
| m1.sessionId = session.getSessionId(); |
| m1.compression_method = session.getCompression(); |
| |
| if (secureRenegotiation) { |
| // For ServerHellos that are initial handshakes, then the |
| // "renegotiated_connection" field in "renegotiation_info" |
| // extension is of zero length. |
| // |
| // For ServerHellos that are renegotiating, this field contains |
| // the concatenation of client_verify_data and server_verify_data. |
| // |
| // Note that for initial handshakes, both the clientVerifyData |
| // variable and serverVerifyData variable are of zero length. |
| HelloExtension serverHelloRI = new RenegotiationInfoExtension( |
| clientVerifyData, serverVerifyData); |
| m1.extensions.add(serverHelloRI); |
| } |
| |
| if (!sniMatchers.isEmpty() && clientHelloSNIExt != null) { |
| // When resuming a session, the server MUST NOT include a |
| // server_name extension in the server hello. |
| if (!resumingSession) { |
| ServerNameExtension serverHelloSNI = new ServerNameExtension(); |
| m1.extensions.add(serverHelloSNI); |
| } |
| } |
| |
| if ((maxFragLenExt != null) && !resumingSession) { |
| // When resuming a session, the server MUST NOT include a |
| // max_fragment_length extension in the server hello. |
| // |
| // Otherwise, use the same value as the requested extension. |
| m1.extensions.add(maxFragLenExt); |
| } |
| |
| StaplingParameters staplingParams = processStapling(mesg); |
| if (staplingParams != null) { |
| // We now can safely assert status_request[_v2] in our |
| // ServerHello, and know for certain that we can provide |
| // responses back to this client for this connection. |
| if (staplingParams.statusRespExt == |
| ExtensionType.EXT_STATUS_REQUEST) { |
| m1.extensions.add(new CertStatusReqExtension()); |
| } else if (staplingParams.statusRespExt == |
| ExtensionType.EXT_STATUS_REQUEST_V2) { |
| m1.extensions.add(new CertStatusReqListV2Extension()); |
| } |
| } |
| |
| // Prepare the ALPN response |
| if (applicationProtocol != null && !applicationProtocol.isEmpty()) { |
| m1.extensions.add(new ALPNExtension(applicationProtocol)); |
| } |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| m1.print(System.out); |
| System.out.println("Cipher suite: " + session.getSuite()); |
| } |
| m1.write(output); |
| handshakeState.update(m1, resumingSession); |
| |
| // |
| // If we are resuming a session, we finish writing handshake |
| // messages right now and then finish. |
| // |
| if (resumingSession) { |
| calculateConnectionKeys(session.getMasterSecret()); |
| sendChangeCipherAndFinish(false); |
| |
| // expecting the final ChangeCipherSpec and Finished messages |
| expectingFinishFlightSE(); |
| |
| return; |
| } |
| |
| |
| /* |
| * SECOND, write the server Certificate(s) if we need to. |
| * |
| * NOTE: while an "anonymous RSA" mode is explicitly allowed by |
| * the protocol, we can't support it since all of the SSL flavors |
| * defined in the protocol spec are explicitly stated to require |
| * using RSA certificates. |
| */ |
| if (ClientKeyExchangeService.find(cipherSuite.keyExchange.name) != null) { |
| // No external key exchange provider needs a cert now. |
| } else if ((keyExchange != K_DH_ANON) && (keyExchange != K_ECDH_ANON)) { |
| if (certs == null) { |
| throw new RuntimeException("no certificates"); |
| } |
| |
| CertificateMsg m2 = new CertificateMsg(certs); |
| |
| /* |
| * Set local certs in the SSLSession, output |
| * debug info, and then actually write to the client. |
| */ |
| session.setLocalCertificates(certs); |
| if (debug != null && Debug.isOn("handshake")) { |
| m2.print(System.out); |
| } |
| m2.write(output); |
| handshakeState.update(m2, resumingSession); |
| |
| // XXX has some side effects with OS TCP buffering, |
| // leave it out for now |
| |
| // let client verify chain in the meantime... |
| // output.flush(); |
| } else { |
| if (certs != null) { |
| throw new RuntimeException("anonymous keyexchange with certs"); |
| } |
| } |
| |
| /** |
| * The CertificateStatus message ... only if it is needed. |
| * This would only be needed if we've established that this handshake |
| * supports status stapling and there is at least one response to |
| * return to the client. |
| */ |
| if (staplingParams != null) { |
| CertificateStatus csMsg = new CertificateStatus( |
| staplingParams.statReqType, certs, |
| staplingParams.responseMap); |
| if (debug != null && Debug.isOn("handshake")) { |
| csMsg.print(System.out); |
| } |
| csMsg.write(output); |
| handshakeState.update(csMsg, resumingSession); |
| } |
| |
| /* |
| * THIRD, the ServerKeyExchange message ... iff it's needed. |
| * |
| * It's usually needed unless there's an encryption-capable |
| * RSA cert, or a D-H cert. The notable exception is that |
| * exportable ciphers used with big RSA keys need to downgrade |
| * to use short RSA keys, even when the key/cert encrypts OK. |
| */ |
| |
| ServerKeyExchange m3; |
| switch (keyExchange) { |
| case K_RSA: |
| // no server key exchange for RSA ciphersuites |
| m3 = null; |
| break; |
| case K_RSA_EXPORT: |
| if (JsseJce.getRSAKeyLength(certs[0].getPublicKey()) > 512) { |
| try { |
| m3 = new RSA_ServerKeyExchange( |
| tempPublicKey, privateKey, |
| clnt_random, svr_random, |
| sslContext.getSecureRandom()); |
| privateKey = tempPrivateKey; |
| } catch (GeneralSecurityException e) { |
| m3 = null; // make compiler happy |
| throw new SSLException( |
| "Error generating RSA server key exchange", e); |
| } |
| } else { |
| // RSA_EXPORT with short key, don't need ServerKeyExchange |
| m3 = null; |
| } |
| break; |
| case K_DHE_RSA: |
| case K_DHE_DSS: |
| try { |
| m3 = new DH_ServerKeyExchange(dh, |
| privateKey, |
| clnt_random.random_bytes, |
| svr_random.random_bytes, |
| sslContext.getSecureRandom(), |
| preferableSignatureAlgorithm, |
| protocolVersion); |
| } catch (GeneralSecurityException e) { |
| m3 = null; // make compiler happy |
| throw new SSLException( |
| "Error generating DH server key exchange", e); |
| } |
| break; |
| case K_DH_ANON: |
| m3 = new DH_ServerKeyExchange(dh, protocolVersion); |
| break; |
| case K_ECDHE_RSA: |
| case K_ECDHE_ECDSA: |
| case K_ECDH_ANON: |
| try { |
| m3 = new ECDH_ServerKeyExchange(ecdh, |
| privateKey, |
| clnt_random.random_bytes, |
| svr_random.random_bytes, |
| sslContext.getSecureRandom(), |
| preferableSignatureAlgorithm, |
| protocolVersion); |
| } catch (GeneralSecurityException e) { |
| m3 = null; // make compiler happy |
| throw new SSLException( |
| "Error generating ECDH server key exchange", e); |
| } |
| break; |
| case K_ECDH_RSA: |
| case K_ECDH_ECDSA: |
| // ServerKeyExchange not used for fixed ECDH |
| m3 = null; |
| break; |
| default: |
| ClientKeyExchangeService p = |
| ClientKeyExchangeService.find(keyExchange.name); |
| if (p != null) { |
| // No external key exchange provider needs a cert now. |
| m3 = null; |
| break; |
| } |
| throw new RuntimeException("internal error: " + keyExchange); |
| } |
| if (m3 != null) { |
| if (debug != null && Debug.isOn("handshake")) { |
| m3.print(System.out); |
| } |
| m3.write(output); |
| handshakeState.update(m3, resumingSession); |
| } |
| |
| // |
| // FOURTH, the CertificateRequest message. The details of |
| // the message can be affected by the key exchange algorithm |
| // in use. For example, certs with fixed Diffie-Hellman keys |
| // are only useful with the DH_DSS and DH_RSA key exchange |
| // algorithms. |
| // |
| // Needed only if server requires client to authenticate self. |
| // Illegal for anonymous flavors, so we need to check that. |
| // |
| // No external key exchange provider needs a cert now. |
| if (doClientAuth != ClientAuthType.CLIENT_AUTH_NONE && |
| keyExchange != K_DH_ANON && keyExchange != K_ECDH_ANON && |
| ClientKeyExchangeService.find(keyExchange.name) == null) { |
| |
| CertificateRequest m4; |
| X509Certificate[] caCerts; |
| |
| Collection<SignatureAndHashAlgorithm> localSignAlgs = null; |
| if (protocolVersion.useTLS12PlusSpec()) { |
| // We currently use all local upported signature and hash |
| // algorithms. However, to minimize the computation cost |
| // of requested hash algorithms, we may use a restricted |
| // set of signature algorithms in the future. |
| localSignAlgs = getLocalSupportedSignAlgs(); |
| if (localSignAlgs.isEmpty()) { |
| throw new SSLHandshakeException( |
| "No supported signature algorithm"); |
| } |
| |
| Set<String> localHashAlgs = |
| SignatureAndHashAlgorithm.getHashAlgorithmNames( |
| localSignAlgs); |
| if (localHashAlgs.isEmpty()) { |
| throw new SSLHandshakeException( |
| "No supported signature algorithm"); |
| } |
| } |
| |
| caCerts = sslContext.getX509TrustManager().getAcceptedIssuers(); |
| m4 = new CertificateRequest(caCerts, keyExchange, |
| localSignAlgs, protocolVersion); |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| m4.print(System.out); |
| } |
| m4.write(output); |
| handshakeState.update(m4, resumingSession); |
| } |
| |
| /* |
| * FIFTH, say ServerHelloDone. |
| */ |
| ServerHelloDone m5 = new ServerHelloDone(); |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| m5.print(System.out); |
| } |
| m5.write(output); |
| handshakeState.update(m5, resumingSession); |
| |
| /* |
| * Flush any buffered messages so the client will see them. |
| * Ideally, all the messages above go in a single network level |
| * message to the client. Without big Certificate chains, it's |
| * going to be the common case. |
| */ |
| output.flush(); |
| } |
| |
| /* |
| * Choose cipher suite from among those supported by client. Sets |
| * the cipherSuite and keyExchange variables. |
| */ |
| private void chooseCipherSuite(ClientHello mesg) throws IOException { |
| CipherSuiteList prefered; |
| CipherSuiteList proposed; |
| if (preferLocalCipherSuites) { |
| prefered = getActiveCipherSuites(); |
| proposed = mesg.getCipherSuites(); |
| } else { |
| prefered = mesg.getCipherSuites(); |
| proposed = getActiveCipherSuites(); |
| } |
| |
| List<CipherSuite> legacySuites = new ArrayList<>(); |
| for (CipherSuite suite : prefered.collection()) { |
| if (isNegotiable(proposed, suite) == false) { |
| continue; |
| } |
| |
| if (doClientAuth == ClientAuthType.CLIENT_AUTH_REQUIRED) { |
| if ((suite.keyExchange == K_DH_ANON) || |
| (suite.keyExchange == K_ECDH_ANON)) { |
| continue; |
| } |
| } |
| |
| if (!legacyAlgorithmConstraints.permits(null, suite.name, null)) { |
| legacySuites.add(suite); |
| continue; |
| } |
| |
| if (trySetCipherSuite(suite) == false) { |
| continue; |
| } |
| return; |
| } |
| |
| for (CipherSuite suite : legacySuites) { |
| if (trySetCipherSuite(suite)) { |
| return; |
| } |
| } |
| |
| fatalSE(Alerts.alert_handshake_failure, "no cipher suites in common"); |
| } |
| |
| /** |
| * Set the given CipherSuite, if possible. Return the result. |
| * The call succeeds if the CipherSuite is available and we have |
| * the necessary certificates to complete the handshake. We don't |
| * check if the CipherSuite is actually enabled. |
| * |
| * If successful, this method also generates ephemeral keys if |
| * required for this ciphersuite. This may take some time, so this |
| * method should only be called if you really want to use the |
| * CipherSuite. |
| * |
| * This method is called from chooseCipherSuite() in this class. |
| */ |
| boolean trySetCipherSuite(CipherSuite suite) { |
| /* |
| * If we're resuming a session we know we can |
| * support this key exchange algorithm and in fact |
| * have already cached the result of it in |
| * the session state. |
| */ |
| if (resumingSession) { |
| return true; |
| } |
| |
| if (suite.isNegotiable() == false) { |
| return false; |
| } |
| |
| // must not negotiate the obsoleted weak cipher suites. |
| if (protocolVersion.obsoletes(suite)) { |
| return false; |
| } |
| |
| // must not negotiate unsupported cipher suites. |
| if (!protocolVersion.supports(suite)) { |
| return false; |
| } |
| |
| KeyExchange keyExchange = suite.keyExchange; |
| |
| // null out any existing references |
| privateKey = null; |
| certs = null; |
| dh = null; |
| tempPrivateKey = null; |
| tempPublicKey = null; |
| |
| Collection<SignatureAndHashAlgorithm> supportedSignAlgs = null; |
| if (protocolVersion.useTLS12PlusSpec()) { |
| if (peerSupportedSignAlgs != null) { |
| supportedSignAlgs = peerSupportedSignAlgs; |
| } else { |
| SignatureAndHashAlgorithm algorithm = null; |
| |
| // we may optimize the performance |
| switch (keyExchange) { |
| // If the negotiated key exchange algorithm is one of |
| // (RSA, DHE_RSA, DH_RSA, RSA_PSK, ECDH_RSA, ECDHE_RSA), |
| // behave as if client had sent the value {sha1,rsa}. |
| case K_RSA: |
| case K_DHE_RSA: |
| case K_DH_RSA: |
| // case K_RSA_PSK: |
| case K_ECDH_RSA: |
| case K_ECDHE_RSA: |
| algorithm = SignatureAndHashAlgorithm.valueOf( |
| HashAlgorithm.SHA1.value, |
| SignatureAlgorithm.RSA.value, 0); |
| break; |
| // If the negotiated key exchange algorithm is one of |
| // (DHE_DSS, DH_DSS), behave as if the client had |
| // sent the value {sha1,dsa}. |
| case K_DHE_DSS: |
| case K_DH_DSS: |
| algorithm = SignatureAndHashAlgorithm.valueOf( |
| HashAlgorithm.SHA1.value, |
| SignatureAlgorithm.DSA.value, 0); |
| break; |
| // If the negotiated key exchange algorithm is one of |
| // (ECDH_ECDSA, ECDHE_ECDSA), behave as if the client |
| // had sent value {sha1,ecdsa}. |
| case K_ECDH_ECDSA: |
| case K_ECDHE_ECDSA: |
| algorithm = SignatureAndHashAlgorithm.valueOf( |
| HashAlgorithm.SHA1.value, |
| SignatureAlgorithm.ECDSA.value, 0); |
| break; |
| default: |
| // no peer supported signature algorithms |
| } |
| |
| if (algorithm == null) { |
| supportedSignAlgs = |
| Collections.<SignatureAndHashAlgorithm>emptySet(); |
| } else { |
| supportedSignAlgs = |
| new ArrayList<SignatureAndHashAlgorithm>(1); |
| supportedSignAlgs.add(algorithm); |
| |
| supportedSignAlgs = |
| SignatureAndHashAlgorithm.getSupportedAlgorithms( |
| algorithmConstraints, supportedSignAlgs); |
| |
| // May be no default activated signature algorithm, but |
| // let the following process make the final decision. |
| } |
| |
| // Sets the peer supported signature algorithm to use in KM |
| // temporarily. |
| session.setPeerSupportedSignatureAlgorithms(supportedSignAlgs); |
| } |
| } |
| |
| switch (keyExchange) { |
| case K_RSA: |
| // need RSA certs for authentication |
| if (setupPrivateKeyAndChain("RSA") == false) { |
| return false; |
| } |
| break; |
| case K_RSA_EXPORT: |
| // need RSA certs for authentication |
| if (setupPrivateKeyAndChain("RSA") == false) { |
| return false; |
| } |
| |
| try { |
| if (JsseJce.getRSAKeyLength(certs[0].getPublicKey()) > 512) { |
| if (!setupEphemeralRSAKeys(suite.exportable)) { |
| return false; |
| } |
| } |
| } catch (RuntimeException e) { |
| // could not determine keylength, ignore key |
| return false; |
| } |
| break; |
| case K_DHE_RSA: |
| // need RSA certs for authentication |
| if (setupPrivateKeyAndChain("RSA") == false) { |
| return false; |
| } |
| |
| // get preferable peer signature algorithm for server key exchange |
| if (protocolVersion.useTLS12PlusSpec()) { |
| preferableSignatureAlgorithm = |
| SignatureAndHashAlgorithm.getPreferableAlgorithm( |
| supportedSignAlgs, "RSA", privateKey); |
| if (preferableSignatureAlgorithm == null) { |
| if ((debug != null) && Debug.isOn("handshake")) { |
| System.out.println( |
| "No signature and hash algorithm for cipher " + |
| suite); |
| } |
| return false; |
| } |
| } |
| |
| setupEphemeralDHKeys(suite.exportable, privateKey); |
| break; |
| case K_ECDHE_RSA: |
| // need RSA certs for authentication |
| if (setupPrivateKeyAndChain("RSA") == false) { |
| return false; |
| } |
| |
| // get preferable peer signature algorithm for server key exchange |
| if (protocolVersion.useTLS12PlusSpec()) { |
| preferableSignatureAlgorithm = |
| SignatureAndHashAlgorithm.getPreferableAlgorithm( |
| supportedSignAlgs, "RSA", privateKey); |
| if (preferableSignatureAlgorithm == null) { |
| if ((debug != null) && Debug.isOn("handshake")) { |
| System.out.println( |
| "No signature and hash algorithm for cipher " + |
| suite); |
| } |
| return false; |
| } |
| } |
| |
| if (setupEphemeralECDHKeys() == false) { |
| return false; |
| } |
| break; |
| case K_DHE_DSS: |
| // get preferable peer signature algorithm for server key exchange |
| if (protocolVersion.useTLS12PlusSpec()) { |
| preferableSignatureAlgorithm = |
| SignatureAndHashAlgorithm.getPreferableAlgorithm( |
| supportedSignAlgs, "DSA"); |
| if (preferableSignatureAlgorithm == null) { |
| if ((debug != null) && Debug.isOn("handshake")) { |
| System.out.println( |
| "No signature and hash algorithm for cipher " + |
| suite); |
| } |
| return false; |
| } |
| } |
| |
| // need DSS certs for authentication |
| if (setupPrivateKeyAndChain("DSA") == false) { |
| return false; |
| } |
| |
| setupEphemeralDHKeys(suite.exportable, privateKey); |
| break; |
| case K_ECDHE_ECDSA: |
| // get preferable peer signature algorithm for server key exchange |
| if (protocolVersion.useTLS12PlusSpec()) { |
| preferableSignatureAlgorithm = |
| SignatureAndHashAlgorithm.getPreferableAlgorithm( |
| supportedSignAlgs, "ECDSA"); |
| if (preferableSignatureAlgorithm == null) { |
| if ((debug != null) && Debug.isOn("handshake")) { |
| System.out.println( |
| "No signature and hash algorithm for cipher " + |
| suite); |
| } |
| return false; |
| } |
| } |
| |
| // need EC cert |
| if (setupPrivateKeyAndChain("EC") == false) { |
| return false; |
| } |
| if (setupEphemeralECDHKeys() == false) { |
| return false; |
| } |
| break; |
| case K_ECDH_RSA: |
| // need EC cert |
| if (setupPrivateKeyAndChain("EC") == false) { |
| return false; |
| } |
| setupStaticECDHKeys(); |
| break; |
| case K_ECDH_ECDSA: |
| // need EC cert |
| if (setupPrivateKeyAndChain("EC") == false) { |
| return false; |
| } |
| setupStaticECDHKeys(); |
| break; |
| case K_DH_ANON: |
| // no certs needed for anonymous |
| setupEphemeralDHKeys(suite.exportable, null); |
| break; |
| case K_ECDH_ANON: |
| // no certs needed for anonymous |
| if (setupEphemeralECDHKeys() == false) { |
| return false; |
| } |
| break; |
| default: |
| ClientKeyExchangeService p = |
| ClientKeyExchangeService.find(keyExchange.name); |
| if (p == null) { |
| // internal error, unknown key exchange |
| throw new RuntimeException( |
| "Unrecognized cipherSuite: " + suite); |
| } |
| // need service creds |
| if (serviceCreds == null) { |
| AccessControlContext acc = getAccSE(); |
| serviceCreds = p.getServiceCreds(acc); |
| if (serviceCreds != null) { |
| if (debug != null && Debug.isOn("handshake")) { |
| System.out.println("Using serviceCreds"); |
| } |
| } |
| if (serviceCreds == null) { |
| return false; |
| } |
| } |
| break; |
| } |
| setCipherSuite(suite); |
| |
| // set the peer implicit supported signature algorithms |
| if (protocolVersion.useTLS12PlusSpec()) { |
| if (peerSupportedSignAlgs == null) { |
| setPeerSupportedSignAlgs(supportedSignAlgs); |
| // we had alreay update the session |
| } |
| } |
| return true; |
| } |
| |
| /* |
| * Get some "ephemeral" RSA keys for this context. This means |
| * generating them if it's not already been done. |
| * |
| * Note that we currently do not implement any ciphersuites that use |
| * strong ephemeral RSA. (We do not support the EXPORT1024 ciphersuites |
| * and standard RSA ciphersuites prohibit ephemeral mode for some reason) |
| * This means that export is always true and 512 bit keys are generated. |
| */ |
| private boolean setupEphemeralRSAKeys(boolean export) { |
| KeyPair kp = sslContext.getEphemeralKeyManager(). |
| getRSAKeyPair(export, sslContext.getSecureRandom()); |
| if (kp == null) { |
| return false; |
| } else { |
| tempPublicKey = kp.getPublic(); |
| tempPrivateKey = kp.getPrivate(); |
| return true; |
| } |
| } |
| |
| /* |
| * Acquire some "ephemeral" Diffie-Hellman keys for this handshake. |
| * We don't reuse these, for improved forward secrecy. |
| */ |
| private void setupEphemeralDHKeys(boolean export, Key key) { |
| /* |
| * 768 bits ephemeral DH private keys were used to be used in |
| * ServerKeyExchange except that exportable ciphers max out at 512 |
| * bits modulus values. We still adhere to this behavior in legacy |
| * mode (system property "jdk.tls.ephemeralDHKeySize" is defined |
| * as "legacy"). |
| * |
| * Old JDK (JDK 7 and previous) releases don't support DH keys bigger |
| * than 1024 bits. We have to consider the compatibility requirement. |
| * 1024 bits DH key is always used for non-exportable cipher suites |
| * in default mode (system property "jdk.tls.ephemeralDHKeySize" |
| * is not defined). |
| * |
| * However, if applications want more stronger strength, setting |
| * system property "jdk.tls.ephemeralDHKeySize" to "matched" |
| * is a workaround to use ephemeral DH key which size matches the |
| * corresponding authentication key. For example, if the public key |
| * size of an authentication certificate is 2048 bits, then the |
| * ephemeral DH key size should be 2048 bits accordingly unless |
| * the cipher suite is exportable. This key sizing scheme keeps |
| * the cryptographic strength consistent between authentication |
| * keys and key-exchange keys. |
| * |
| * Applications may also want to customize the ephemeral DH key size |
| * to a fixed length for non-exportable cipher suites. This can be |
| * approached by setting system property "jdk.tls.ephemeralDHKeySize" |
| * to a valid positive integer between 1024 and 8192 bits, inclusive. |
| * |
| * Note that the minimum acceptable key size is 1024 bits except |
| * exportable cipher suites or legacy mode. |
| * |
| * Note that per RFC 2246, the key size limit of DH is 512 bits for |
| * exportable cipher suites. Because of the weakness, exportable |
| * cipher suites are deprecated since TLS v1.1 and they are not |
| * enabled by default in Oracle provider. The legacy behavior is |
| * reserved and 512 bits DH key is always used for exportable |
| * cipher suites. |
| */ |
| int keySize = export ? 512 : 1024; // default mode |
| if (!export) { |
| if (useLegacyEphemeralDHKeys) { // legacy mode |
| keySize = 768; |
| } else if (useSmartEphemeralDHKeys) { // matched mode |
| if (key != null) { |
| int ks = KeyUtil.getKeySize(key); |
| |
| // DH parameter generation can be extremely slow, make |
| // sure to use one of the supported pre-computed DH |
| // parameters (see DHCrypt class). |
| // |
| // Old deployed applications may not be ready to support |
| // DH key sizes bigger than 2048 bits. Please DON'T use |
| // value other than 1024 and 2048 at present. May improve |
| // the underlying providers and key size limit in the |
| // future when the compatibility and interoperability |
| // impact is limited. |
| // |
| // keySize = ks <= 1024 ? 1024 : (ks >= 2048 ? 2048 : ks); |
| keySize = ks <= 1024 ? 1024 : 2048; |
| } // Otherwise, anonymous cipher suites, 1024-bit is used. |
| } else if (customizedDHKeySize > 0) { // customized mode |
| keySize = customizedDHKeySize; |
| } |
| } |
| |
| dh = new DHCrypt(keySize, sslContext.getSecureRandom()); |
| } |
| |
| // Setup the ephemeral ECDH parameters. |
| // If we cannot continue because we do not support any of the curves that |
| // the client requested, return false. Otherwise (all is well), return true. |
| private boolean setupEphemeralECDHKeys() { |
| int index = -1; |
| if (supportedCurves != null) { |
| // if the client sent the supported curves extension, pick the |
| // first one that we support; |
| for (int curveId : supportedCurves.curveIds()) { |
| if (SupportedEllipticCurvesExtension.isSupported(curveId)) { |
| index = curveId; |
| break; |
| } |
| } |
| if (index < 0) { |
| // no match found, cannot use this ciphersuite |
| return false; |
| } |
| } else { |
| // pick our preference |
| index = SupportedEllipticCurvesExtension.DEFAULT.curveIds()[0]; |
| } |
| String oid = SupportedEllipticCurvesExtension.getCurveOid(index); |
| ecdh = new ECDHCrypt(oid, sslContext.getSecureRandom()); |
| return true; |
| } |
| |
| private void setupStaticECDHKeys() { |
| // don't need to check whether the curve is supported, already done |
| // in setupPrivateKeyAndChain(). |
| ecdh = new ECDHCrypt(privateKey, certs[0].getPublicKey()); |
| } |
| |
| /** |
| * Retrieve the server key and certificate for the specified algorithm |
| * from the KeyManager and set the instance variables. |
| * |
| * @return true if successful, false if not available or invalid |
| */ |
| private boolean setupPrivateKeyAndChain(String algorithm) { |
| X509ExtendedKeyManager km = sslContext.getX509KeyManager(); |
| String alias; |
| if (conn != null) { |
| alias = km.chooseServerAlias(algorithm, null, conn); |
| } else { |
| alias = km.chooseEngineServerAlias(algorithm, null, engine); |
| } |
| if (alias == null) { |
| return false; |
| } |
| PrivateKey tempPrivateKey = km.getPrivateKey(alias); |
| if (tempPrivateKey == null) { |
| return false; |
| } |
| X509Certificate[] tempCerts = km.getCertificateChain(alias); |
| if ((tempCerts == null) || (tempCerts.length == 0)) { |
| return false; |
| } |
| String keyAlgorithm = algorithm.split("_")[0]; |
| PublicKey publicKey = tempCerts[0].getPublicKey(); |
| if ((tempPrivateKey.getAlgorithm().equals(keyAlgorithm) == false) |
| || (publicKey.getAlgorithm().equals(keyAlgorithm) == false)) { |
| return false; |
| } |
| // For ECC certs, check whether we support the EC domain parameters. |
| // If the client sent a SupportedEllipticCurves ClientHello extension, |
| // check against that too. |
| if (keyAlgorithm.equals("EC")) { |
| if (publicKey instanceof ECPublicKey == false) { |
| return false; |
| } |
| ECParameterSpec params = ((ECPublicKey)publicKey).getParams(); |
| int index = SupportedEllipticCurvesExtension.getCurveIndex(params); |
| if (SupportedEllipticCurvesExtension.isSupported(index) == false) { |
| return false; |
| } |
| if ((supportedCurves != null) && !supportedCurves.contains(index)) { |
| return false; |
| } |
| } |
| this.privateKey = tempPrivateKey; |
| this.certs = tempCerts; |
| return true; |
| } |
| |
| /* |
| * Returns premaster secret for external key exchange services. |
| */ |
| private SecretKey clientKeyExchange(ClientKeyExchange mesg) |
| throws IOException { |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| // Record the principals involved in exchange |
| session.setPeerPrincipal(mesg.getPeerPrincipal()); |
| session.setLocalPrincipal(mesg.getLocalPrincipal()); |
| |
| return mesg.clientKeyExchange(); |
| } |
| |
| /* |
| * Diffie Hellman key exchange is used when the server presented |
| * D-H parameters in its certificate (signed using RSA or DSS/DSA), |
| * or else the server presented no certificate but sent D-H params |
| * in a ServerKeyExchange message. Use of D-H is specified by the |
| * cipher suite chosen. |
| * |
| * The message optionally contains the client's D-H public key (if |
| * it wasn't not sent in a client certificate). As always with D-H, |
| * if a client and a server have each other's D-H public keys and |
| * they use common algorithm parameters, they have a shared key |
| * that's derived via the D-H calculation. That key becomes the |
| * pre-master secret. |
| */ |
| private SecretKey clientKeyExchange(DHClientKeyExchange mesg) |
| throws IOException { |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| BigInteger publicKeyValue = mesg.getClientPublicKey(); |
| |
| // check algorithm constraints |
| dh.checkConstraints(algorithmConstraints, publicKeyValue); |
| |
| return dh.getAgreedSecret(publicKeyValue, false); |
| } |
| |
| private SecretKey clientKeyExchange(ECDHClientKeyExchange mesg) |
| throws IOException { |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| byte[] publicPoint = mesg.getEncodedPoint(); |
| |
| // check algorithm constraints |
| ecdh.checkConstraints(algorithmConstraints, publicPoint); |
| |
| return ecdh.getAgreedSecret(publicPoint); |
| } |
| |
| /* |
| * Client wrote a message to verify the certificate it sent earlier. |
| * |
| * Note that this certificate isn't involved in key exchange. Client |
| * authentication messages are included in the checksums used to |
| * validate the handshake (e.g. Finished messages). Other than that, |
| * the _exact_ identity of the client is less fundamental to protocol |
| * security than its role in selecting keys via the pre-master secret. |
| */ |
| private void clientCertificateVerify(CertificateVerify mesg) |
| throws IOException { |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| if (protocolVersion.useTLS12PlusSpec()) { |
| SignatureAndHashAlgorithm signAlg = |
| mesg.getPreferableSignatureAlgorithm(); |
| if (signAlg == null) { |
| throw new SSLHandshakeException( |
| "Illegal CertificateVerify message"); |
| } |
| |
| String hashAlg = |
| SignatureAndHashAlgorithm.getHashAlgorithmName(signAlg); |
| if (hashAlg == null || hashAlg.length() == 0) { |
| throw new SSLHandshakeException( |
| "No supported hash algorithm"); |
| } |
| } |
| |
| try { |
| PublicKey publicKey = |
| session.getPeerCertificates()[0].getPublicKey(); |
| |
| boolean valid = mesg.verify(protocolVersion, handshakeHash, |
| publicKey, session.getMasterSecret()); |
| if (valid == false) { |
| fatalSE(Alerts.alert_bad_certificate, |
| "certificate verify message signature error"); |
| } |
| } catch (GeneralSecurityException e) { |
| fatalSE(Alerts.alert_bad_certificate, |
| "certificate verify format error", e); |
| } |
| |
| // reset the flag for clientCertificateVerify message |
| needClientVerify = false; |
| } |
| |
| |
| /* |
| * Client writes "finished" at the end of its handshake, after cipher |
| * spec is changed. We verify it and then send ours. |
| * |
| * When we're resuming a session, we'll have already sent our own |
| * Finished message so just the verification is needed. |
| */ |
| private void clientFinished(Finished mesg) throws IOException { |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| /* |
| * Verify if client did send the certificate when client |
| * authentication was required, otherwise server should not proceed |
| */ |
| if (doClientAuth == ClientAuthType.CLIENT_AUTH_REQUIRED) { |
| // get X500Principal of the end-entity certificate for X509-based |
| // ciphersuites, or Kerberos principal for Kerberos ciphersuites, etc |
| session.getPeerPrincipal(); |
| } |
| |
| /* |
| * Verify if client did send clientCertificateVerify message following |
| * the client Certificate, otherwise server should not proceed |
| */ |
| if (needClientVerify) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "client did not send certificate verify message"); |
| } |
| |
| /* |
| * Verify the client's message with the "before" digest of messages, |
| * and forget about continuing to use that digest. |
| */ |
| boolean verified = mesg.verify(handshakeHash, Finished.CLIENT, |
| session.getMasterSecret()); |
| |
| if (!verified) { |
| fatalSE(Alerts.alert_handshake_failure, |
| "client 'finished' message doesn't verify"); |
| // NOTREACHED |
| } |
| |
| /* |
| * save client verify data for secure renegotiation |
| */ |
| if (secureRenegotiation) { |
| clientVerifyData = mesg.getVerifyData(); |
| } |
| |
| /* |
| * OK, it verified. If we're doing the full handshake, add that |
| * "Finished" message to the hash of handshake messages, then send |
| * the change_cipher_spec and Finished message. |
| */ |
| if (!resumingSession) { |
| sendChangeCipherAndFinish(true); |
| } else { |
| handshakeFinished = true; |
| } |
| |
| /* |
| * Update the session cache only after the handshake completed, else |
| * we're open to an attack against a partially completed handshake. |
| */ |
| session.setLastAccessedTime(System.currentTimeMillis()); |
| if (!resumingSession && session.isRejoinable()) { |
| ((SSLSessionContextImpl)sslContext.engineGetServerSessionContext()) |
| .put(session); |
| if (debug != null && Debug.isOn("session")) { |
| System.out.println( |
| "%% Cached server session: " + session); |
| } |
| } else if (!resumingSession && |
| debug != null && Debug.isOn("session")) { |
| System.out.println( |
| "%% Didn't cache non-resumable server session: " |
| + session); |
| } |
| } |
| |
| /* |
| * Compute finished message with the "server" digest (and then forget |
| * about that digest, it can't be used again). |
| */ |
| private void sendChangeCipherAndFinish(boolean finishedTag) |
| throws IOException { |
| |
| // Reload if this message has been reserved. |
| handshakeHash.reload(); |
| |
| Finished mesg = new Finished(protocolVersion, handshakeHash, |
| Finished.SERVER, session.getMasterSecret(), cipherSuite); |
| |
| /* |
| * Send the change_cipher_spec record; then our Finished handshake |
| * message will be the last handshake message. Flush, and now we |
| * are ready for application data!! |
| */ |
| sendChangeCipherSpec(mesg, finishedTag); |
| |
| /* |
| * save server verify data for secure renegotiation |
| */ |
| if (secureRenegotiation) { |
| serverVerifyData = mesg.getVerifyData(); |
| } |
| } |
| |
| |
| /* |
| * Returns a HelloRequest message to kickstart renegotiations |
| */ |
| @Override |
| HandshakeMessage getKickstartMessage() { |
| return new HelloRequest(); |
| } |
| |
| |
| /* |
| * Fault detected during handshake. |
| */ |
| @Override |
| void handshakeAlert(byte description) throws SSLProtocolException { |
| |
| String message = Alerts.alertDescription(description); |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| System.out.println("SSL -- handshake alert: " |
| + message); |
| } |
| |
| /* |
| * It's ok to get a no_certificate alert from a client of which |
| * we *requested* authentication information. |
| * However, if we *required* it, then this is not acceptable. |
| * |
| * Anyone calling getPeerCertificates() on the |
| * session will get an SSLPeerUnverifiedException. |
| */ |
| if ((description == Alerts.alert_no_certificate) && |
| (doClientAuth == ClientAuthType.CLIENT_AUTH_REQUESTED)) { |
| return; |
| } |
| |
| throw new SSLProtocolException("handshake alert: " + message); |
| } |
| |
| /* |
| * RSA key exchange is normally used. The client encrypts a "pre-master |
| * secret" with the server's public key, from the Certificate (or else |
| * ServerKeyExchange) message that was sent to it by the server. That's |
| * decrypted using the private key before we get here. |
| */ |
| private SecretKey clientKeyExchange(RSAClientKeyExchange mesg) |
| throws IOException { |
| |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| return mesg.preMaster; |
| } |
| |
| /* |
| * Verify the certificate sent by the client. We'll only get one if we |
| * sent a CertificateRequest to request client authentication. If we |
| * are in TLS mode, the client may send a message with no certificates |
| * to indicate it does not have an appropriate chain. (In SSLv3 mode, |
| * it would send a no certificate alert). |
| */ |
| private void clientCertificate(CertificateMsg mesg) throws IOException { |
| if (debug != null && Debug.isOn("handshake")) { |
| mesg.print(System.out); |
| } |
| |
| X509Certificate[] peerCerts = mesg.getCertificateChain(); |
| |
| if (peerCerts.length == 0) { |
| /* |
| * If the client authentication is only *REQUESTED* (e.g. |
| * not *REQUIRED*, this is an acceptable condition.) |
| */ |
| if (doClientAuth == ClientAuthType.CLIENT_AUTH_REQUESTED) { |
| return; |
| } else { |
| fatalSE(Alerts.alert_bad_certificate, |
| "null cert chain"); |
| } |
| } |
| |
| // ask the trust manager to verify the chain |
| X509TrustManager tm = sslContext.getX509TrustManager(); |
| |
| try { |
| // find out the types of client authentication used |
| PublicKey key = peerCerts[0].getPublicKey(); |
| String keyAlgorithm = key.getAlgorithm(); |
| String authType; |
| if (keyAlgorithm.equals("RSA")) { |
| authType = "RSA"; |
| } else if (keyAlgorithm.equals("DSA")) { |
| authType = "DSA"; |
| } else if (keyAlgorithm.equals("EC")) { |
| authType = "EC"; |
| } else { |
| // unknown public key type |
| authType = "UNKNOWN"; |
| } |
| |
| if (tm instanceof X509ExtendedTrustManager) { |
| if (conn != null) { |
| ((X509ExtendedTrustManager)tm).checkClientTrusted( |
| peerCerts.clone(), |
| authType, |
| conn); |
| } else { |
| ((X509ExtendedTrustManager)tm).checkClientTrusted( |
| peerCerts.clone(), |
| authType, |
| engine); |
| } |
| } else { |
| // Unlikely to happen, because we have wrapped the old |
| // X509TrustManager with the new X509ExtendedTrustManager. |
| throw new CertificateException( |
| "Improper X509TrustManager implementation"); |
| } |
| } catch (CertificateException e) { |
| // This will throw an exception, so include the original error. |
| fatalSE(Alerts.alert_certificate_unknown, e); |
| } |
| // set the flag for clientCertificateVerify message |
| needClientVerify = true; |
| |
| session.setPeerCertificates(peerCerts); |
| } |
| |
| private StaplingParameters processStapling(ClientHello mesg) { |
| StaplingParameters params = null; |
| ExtensionType ext; |
| StatusRequestType type = null; |
| StatusRequest req = null; |
| Map<X509Certificate, byte[]> responses; |
| |
| // If this feature has not been enabled, then no more processing |
| // is necessary. Also we will only staple if we're doing a full |
| // handshake. |
| if (!sslContext.isStaplingEnabled(false) || resumingSession) { |
| return null; |
| } |
| |
| // Check if the client has asserted the status_request[_v2] extension(s) |
| CertStatusReqExtension statReqExt = (CertStatusReqExtension) |
| mesg.extensions.get(ExtensionType.EXT_STATUS_REQUEST); |
| CertStatusReqListV2Extension statReqExtV2 = |
| (CertStatusReqListV2Extension)mesg.extensions.get( |
| ExtensionType.EXT_STATUS_REQUEST_V2); |
| // Keep processing only if either status_request or status_request_v2 |
| // has been sent in the ClientHello. |
| if (statReqExt == null && statReqExtV2 == null) { |
| return null; |
| } |
| |
| // Determine which type of stapling we are doing and assert the |
| // proper extension in the server hello. |
| // Favor status_request_v2 over status_request and ocsp_multi |
| // over ocsp. |
| // If multiple ocsp or ocsp_multi types exist, select the first |
| // instance of a given type |
| ext = ExtensionType.EXT_STATUS_REQUEST; |
| if (statReqExtV2 != null) { // RFC 6961 stapling |
| ext = ExtensionType.EXT_STATUS_REQUEST_V2; |
| List<CertStatusReqItemV2> reqItems = |
| statReqExtV2.getRequestItems(); |
| int ocspIdx = -1; |
| int ocspMultiIdx = -1; |
| for (int pos = 0; pos < reqItems.size(); pos++) { |
| CertStatusReqItemV2 item = reqItems.get(pos); |
| if (ocspIdx < 0 && item.getType() == |
| StatusRequestType.OCSP) { |
| ocspIdx = pos; |
| } else if (ocspMultiIdx < 0 && item.getType() == |
| StatusRequestType.OCSP_MULTI) { |
| ocspMultiIdx = pos; |
| } |
| } |
| if (ocspMultiIdx >= 0) { |
| type = reqItems.get(ocspMultiIdx).getType(); |
| req = reqItems.get(ocspMultiIdx).getRequest(); |
| } else if (ocspIdx >= 0) { |
| type = reqItems.get(ocspIdx).getType(); |
| req = reqItems.get(ocspIdx).getRequest(); |
| } |
| } else { // RFC 6066 stapling |
| type = StatusRequestType.OCSP; |
| req = statReqExt.getRequest(); |
| } |
| |
| // If, after walking through the extensions we were unable to |
| // find a suitable StatusRequest, then stapling is disabled. |
| // Both statReqType and statReqData must have been set to continue. |
| if (type == null || req == null) { |
| return null; |
| } |
| |
| // Get the OCSP responses from the StatusResponseManager |
| StatusResponseManager statRespMgr = |
| sslContext.getStatusResponseManager(); |
| if (statRespMgr != null) { |
| responses = statRespMgr.get(type, req, certs, statusRespTimeout, |
| TimeUnit.MILLISECONDS); |
| if (!responses.isEmpty()) { |
| // If this RFC 6066-style stapling (SSL cert only) then the |
| // response cannot be zero length |
| if (type == StatusRequestType.OCSP) { |
| byte[] respDER = responses.get(certs[0]); |
| if (respDER == null || respDER.length <= 0) { |
| return null; |
| } |
| } |
| params = new StaplingParameters(ext, type, req, responses); |
| } |
| } else { |
| // This should not happen, but if lazy initialization of the |
| // StatusResponseManager doesn't occur we should turn off stapling. |
| if (debug != null && Debug.isOn("handshake")) { |
| System.out.println("Warning: lazy initialization " + |
| "of the StatusResponseManager failed. " + |
| "Stapling has been disabled."); |
| } |
| } |
| |
| return params; |
| } |
| |
| /** |
| * Inner class used to hold stapling parameters needed by the handshaker |
| * when stapling is active. |
| */ |
| private class StaplingParameters { |
| private final ExtensionType statusRespExt; |
| private final StatusRequestType statReqType; |
| private final StatusRequest statReqData; |
| private final Map<X509Certificate, byte[]> responseMap; |
| |
| StaplingParameters(ExtensionType ext, StatusRequestType type, |
| StatusRequest req, Map<X509Certificate, byte[]> responses) { |
| statusRespExt = ext; |
| statReqType = type; |
| statReqData = req; |
| responseMap = responses; |
| } |
| } |
| } |