/* * Copyright (c) 1996, 2012, 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.math.BigInteger; import java.security.*; import java.security.interfaces.*; import java.security.spec.*; import java.security.cert.*; import java.security.cert.Certificate; import java.util.*; import java.util.concurrent.ConcurrentHashMap; import java.lang.reflect.*; import javax.security.auth.x500.X500Principal; import javax.crypto.KeyGenerator; import javax.crypto.SecretKey; import javax.crypto.spec.DHPublicKeySpec; import javax.net.ssl.*; import sun.security.internal.spec.TlsPrfParameterSpec; import sun.security.ssl.CipherSuite.*; import static sun.security.ssl.CipherSuite.PRF.*; import sun.security.util.KeyUtil; /** * Many data structures are involved in the handshake messages. These * classes are used as structures, with public data members. They are * not visible outside the SSL package. * * Handshake messages all have a common header format, and they are all * encoded in a "handshake data" SSL record substream. The base class * here (HandshakeMessage) provides a common framework and records the * SSL record type of the particular handshake message. * * This file contains subclasses for all the basic handshake messages. * All handshake messages know how to encode and decode themselves on * SSL streams; this facilitates using the same code on SSL client and * server sides, although they don't send and receive the same messages. * * Messages also know how to print themselves, which is quite handy * for debugging. They always identify their type, and can optionally * dump all of their content. * * @author David Brownell */ public abstract class HandshakeMessage { HandshakeMessage() { } // enum HandshakeType: static final byte ht_hello_request = 0; static final byte ht_client_hello = 1; static final byte ht_server_hello = 2; static final byte ht_certificate = 11; static final byte ht_server_key_exchange = 12; static final byte ht_certificate_request = 13; static final byte ht_server_hello_done = 14; static final byte ht_certificate_verify = 15; static final byte ht_client_key_exchange = 16; static final byte ht_finished = 20; /* Class and subclass dynamic debugging support */ public static final Debug debug = Debug.getInstance("ssl"); /** * Utility method to convert a BigInteger to a byte array in unsigned * format as needed in the handshake messages. BigInteger uses * 2's complement format, i.e. it prepends an extra zero if the MSB * is set. We remove that. */ static byte[] toByteArray(BigInteger bi) { byte[] b = bi.toByteArray(); if ((b.length > 1) && (b[0] == 0)) { int n = b.length - 1; byte[] newarray = new byte[n]; System.arraycopy(b, 1, newarray, 0, n); b = newarray; } return b; } /* * SSL 3.0 MAC padding constants. * Also used by CertificateVerify and Finished during the handshake. */ static final byte[] MD5_pad1 = genPad(0x36, 48); static final byte[] MD5_pad2 = genPad(0x5c, 48); static final byte[] SHA_pad1 = genPad(0x36, 40); static final byte[] SHA_pad2 = genPad(0x5c, 40); private static byte[] genPad(int b, int count) { byte[] padding = new byte[count]; Arrays.fill(padding, (byte)b); return padding; } /* * Write a handshake message on the (handshake) output stream. * This is just a four byte header followed by the data. * * NOTE that huge messages -- notably, ones with huge cert * chains -- are handled correctly. */ final void write(HandshakeOutStream s) throws IOException { int len = messageLength(); if (len >= Record.OVERFLOW_OF_INT24) { throw new SSLException("Handshake message too big" + ", type = " + messageType() + ", len = " + len); } s.write(messageType()); s.putInt24(len); send(s); } /* * Subclasses implement these methods so those kinds of * messages can be emitted. Base class delegates to subclass. */ abstract int messageType(); abstract int messageLength(); abstract void send(HandshakeOutStream s) throws IOException; /* * Write a descriptive message on the output stream; for debugging. */ abstract void print(PrintStream p) throws IOException; // // NOTE: the rest of these classes are nested within this one, and are // imported by other classes in this package. There are a few other // handshake message classes, not neatly nested here because of current // licensing requirement for native (RSA) methods. They belong here, // but those native methods complicate things a lot! // /* * HelloRequest ... SERVER --> CLIENT * * Server can ask the client to initiate a new handshake, e.g. to change * session parameters after a connection has been (re)established. */ static final class HelloRequest extends HandshakeMessage { @Override int messageType() { return ht_hello_request; } HelloRequest() { } HelloRequest(HandshakeInStream in) throws IOException { // nothing in this message } @Override int messageLength() { return 0; } @Override void send(HandshakeOutStream out) throws IOException { // nothing in this messaage } @Override void print(PrintStream out) throws IOException { out.println("*** HelloRequest (empty)"); } } /* * ClientHello ... CLIENT --> SERVER * * Client initiates handshake by telling server what it wants, and what it * can support (prioritized by what's first in the ciphe suite list). * * By RFC2246:7.4.1.2 it's explicitly anticipated that this message * will have more data added at the end ... e.g. what CAs the client trusts. * Until we know how to parse it, we will just read what we know * about, and let our caller handle the jumps over unknown data. */ static final class ClientHello extends HandshakeMessage { ProtocolVersion protocolVersion; RandomCookie clnt_random; SessionId sessionId; private CipherSuiteList cipherSuites; byte[] compression_methods; HelloExtensions extensions = new HelloExtensions(); private final static byte[] NULL_COMPRESSION = new byte[] {0}; ClientHello(SecureRandom generator, ProtocolVersion protocolVersion, SessionId sessionId, CipherSuiteList cipherSuites) { this.protocolVersion = protocolVersion; this.sessionId = sessionId; this.cipherSuites = cipherSuites; if (cipherSuites.containsEC()) { extensions.add(SupportedEllipticCurvesExtension.DEFAULT); extensions.add(SupportedEllipticPointFormatsExtension.DEFAULT); } clnt_random = new RandomCookie(generator); compression_methods = NULL_COMPRESSION; } ClientHello(HandshakeInStream s, int messageLength) throws IOException { protocolVersion = ProtocolVersion.valueOf(s.getInt8(), s.getInt8()); clnt_random = new RandomCookie(s); sessionId = new SessionId(s.getBytes8()); cipherSuites = new CipherSuiteList(s); compression_methods = s.getBytes8(); if (messageLength() != messageLength) { extensions = new HelloExtensions(s); } } CipherSuiteList getCipherSuites() { return cipherSuites; } // add renegotiation_info extension void addRenegotiationInfoExtension(byte[] clientVerifyData) { HelloExtension renegotiationInfo = new RenegotiationInfoExtension( clientVerifyData, new byte[0]); extensions.add(renegotiationInfo); } // add server_name extension void addSNIExtension(List serverNames) { try { extensions.add(new ServerNameExtension(serverNames)); } catch (IOException ioe) { // ignore the exception and return } } // add signature_algorithm extension void addSignatureAlgorithmsExtension( Collection algorithms) { HelloExtension signatureAlgorithm = new SignatureAlgorithmsExtension(algorithms); extensions.add(signatureAlgorithm); } @Override int messageType() { return ht_client_hello; } @Override int messageLength() { /* * Add fixed size parts of each field... * version + random + session + cipher + compress */ return (2 + 32 + 1 + 2 + 1 + sessionId.length() /* ... + variable parts */ + (cipherSuites.size() * 2) + compression_methods.length) + extensions.length(); } @Override void send(HandshakeOutStream s) throws IOException { s.putInt8(protocolVersion.major); s.putInt8(protocolVersion.minor); clnt_random.send(s); s.putBytes8(sessionId.getId()); cipherSuites.send(s); s.putBytes8(compression_methods); extensions.send(s); } @Override void print(PrintStream s) throws IOException { s.println("*** ClientHello, " + protocolVersion); if (debug != null && Debug.isOn("verbose")) { s.print("RandomCookie: "); clnt_random.print(s); s.print("Session ID: "); s.println(sessionId); s.println("Cipher Suites: " + cipherSuites); Debug.println(s, "Compression Methods", compression_methods); extensions.print(s); s.println("***"); } } } /* * ServerHello ... SERVER --> CLIENT * * Server chooses protocol options from among those it supports and the * client supports. Then it sends the basic session descriptive parameters * back to the client. */ static final class ServerHello extends HandshakeMessage { @Override int messageType() { return ht_server_hello; } ProtocolVersion protocolVersion; RandomCookie svr_random; SessionId sessionId; CipherSuite cipherSuite; byte compression_method; HelloExtensions extensions = new HelloExtensions(); ServerHello() { // empty } ServerHello(HandshakeInStream input, int messageLength) throws IOException { protocolVersion = ProtocolVersion.valueOf(input.getInt8(), input.getInt8()); svr_random = new RandomCookie(input); sessionId = new SessionId(input.getBytes8()); cipherSuite = CipherSuite.valueOf(input.getInt8(), input.getInt8()); compression_method = (byte)input.getInt8(); if (messageLength() != messageLength) { extensions = new HelloExtensions(input); } } @Override int messageLength() { // almost fixed size, except session ID and extensions: // major + minor = 2 // random = 32 // session ID len field = 1 // cipher suite + compression = 3 // extensions: if present, 2 + length of extensions return 38 + sessionId.length() + extensions.length(); } @Override void send(HandshakeOutStream s) throws IOException { s.putInt8(protocolVersion.major); s.putInt8(protocolVersion.minor); svr_random.send(s); s.putBytes8(sessionId.getId()); s.putInt8(cipherSuite.id >> 8); s.putInt8(cipherSuite.id & 0xff); s.putInt8(compression_method); extensions.send(s); } @Override void print(PrintStream s) throws IOException { s.println("*** ServerHello, " + protocolVersion); if (debug != null && Debug.isOn("verbose")) { s.print("RandomCookie: "); svr_random.print(s); s.print("Session ID: "); s.println(sessionId); s.println("Cipher Suite: " + cipherSuite); s.println("Compression Method: " + compression_method); extensions.print(s); s.println("***"); } } } /* * CertificateMsg ... send by both CLIENT and SERVER * * Each end of a connection may need to pass its certificate chain to * the other end. Such chains are intended to validate an identity with * reference to some certifying authority. Examples include companies * like Verisign, or financial institutions. There's some control over * the certifying authorities which are sent. * * NOTE: that these messages might be huge, taking many handshake records. * Up to 2^48 bytes of certificate may be sent, in records of at most 2^14 * bytes each ... up to 2^32 records sent on the output stream. */ static final class CertificateMsg extends HandshakeMessage { @Override int messageType() { return ht_certificate; } private X509Certificate[] chain; private List encodedChain; private int messageLength; CertificateMsg(X509Certificate[] certs) { chain = certs; } CertificateMsg(HandshakeInStream input) throws IOException { int chainLen = input.getInt24(); List v = new ArrayList<>(4); CertificateFactory cf = null; while (chainLen > 0) { byte[] cert = input.getBytes24(); chainLen -= (3 + cert.length); try { if (cf == null) { cf = CertificateFactory.getInstance("X.509"); } v.add(cf.generateCertificate(new ByteArrayInputStream(cert))); } catch (CertificateException e) { throw (SSLProtocolException)new SSLProtocolException( e.getMessage()).initCause(e); } } chain = v.toArray(new X509Certificate[v.size()]); } @Override int messageLength() { if (encodedChain == null) { messageLength = 3; encodedChain = new ArrayList(chain.length); try { for (X509Certificate cert : chain) { byte[] b = cert.getEncoded(); encodedChain.add(b); messageLength += b.length + 3; } } catch (CertificateEncodingException e) { encodedChain = null; throw new RuntimeException("Could not encode certificates", e); } } return messageLength; } @Override void send(HandshakeOutStream s) throws IOException { s.putInt24(messageLength() - 3); for (byte[] b : encodedChain) { s.putBytes24(b); } } @Override void print(PrintStream s) throws IOException { s.println("*** Certificate chain"); if (debug != null && Debug.isOn("verbose")) { for (int i = 0; i < chain.length; i++) s.println("chain [" + i + "] = " + chain[i]); s.println("***"); } } X509Certificate[] getCertificateChain() { return chain.clone(); } } /* * ServerKeyExchange ... SERVER --> CLIENT * * The cipher suite selected, when combined with the certificate exchanged, * implies one of several different kinds of key exchange. Most current * cipher suites require the server to send more than its certificate. * * The primary exceptions are when a server sends an encryption-capable * RSA public key in its cert, to be used with RSA (or RSA_export) key * exchange; and when a server sends its Diffie-Hellman cert. Those kinds * of key exchange do not require a ServerKeyExchange message. * * Key exchange can be viewed as having three modes, which are explicit * for the Diffie-Hellman flavors and poorly specified for RSA ones: * * - "Ephemeral" keys. Here, a "temporary" key is allocated by the * server, and signed. Diffie-Hellman keys signed using RSA or * DSS are ephemeral (DHE flavor). RSA keys get used to do the same * thing, to cut the key size down to 512 bits (export restrictions) * or for signing-only RSA certificates. * * - Anonymity. Here no server certificate is sent, only the public * key of the server. This case is subject to man-in-the-middle * attacks. This can be done with Diffie-Hellman keys (DH_anon) or * with RSA keys, but is only used in SSLv3 for DH_anon. * * - "Normal" case. Here a server certificate is sent, and the public * key there is used directly in exchanging the premaster secret. * For example, Diffie-Hellman "DH" flavor, and any RSA flavor with * only 512 bit keys. * * If a server certificate is sent, there is no anonymity. However, * when a certificate is sent, ephemeral keys may still be used to * exchange the premaster secret. That's how RSA_EXPORT often works, * as well as how the DHE_* flavors work. */ static abstract class ServerKeyExchange extends HandshakeMessage { @Override int messageType() { return ht_server_key_exchange; } } /* * Using RSA for Key Exchange: exchange a session key that's not as big * as the signing-only key. Used for export applications, since exported * RSA encryption keys can't be bigger than 512 bytes. * * This is never used when keys are 512 bits or smaller, and isn't used * on "US Domestic" ciphers in any case. */ static final class RSA_ServerKeyExchange extends ServerKeyExchange { private byte rsa_modulus[]; // 1 to 2^16 - 1 bytes private byte rsa_exponent[]; // 1 to 2^16 - 1 bytes private Signature signature; private byte[] signatureBytes; /* * Hash the nonces and the ephemeral RSA public key. */ private void updateSignature(byte clntNonce[], byte svrNonce[]) throws SignatureException { int tmp; signature.update(clntNonce); signature.update(svrNonce); tmp = rsa_modulus.length; signature.update((byte)(tmp >> 8)); signature.update((byte)(tmp & 0x0ff)); signature.update(rsa_modulus); tmp = rsa_exponent.length; signature.update((byte)(tmp >> 8)); signature.update((byte)(tmp & 0x0ff)); signature.update(rsa_exponent); } /* * Construct an RSA server key exchange message, using data * known _only_ to the server. * * The client knows the public key corresponding to this private * key, from the Certificate message sent previously. To comply * with US export regulations we use short RSA keys ... either * long term ones in the server's X509 cert, or else ephemeral * ones sent using this message. */ RSA_ServerKeyExchange(PublicKey ephemeralKey, PrivateKey privateKey, RandomCookie clntNonce, RandomCookie svrNonce, SecureRandom sr) throws GeneralSecurityException { RSAPublicKeySpec rsaKey = JsseJce.getRSAPublicKeySpec(ephemeralKey); rsa_modulus = toByteArray(rsaKey.getModulus()); rsa_exponent = toByteArray(rsaKey.getPublicExponent()); signature = RSASignature.getInstance(); signature.initSign(privateKey, sr); updateSignature(clntNonce.random_bytes, svrNonce.random_bytes); signatureBytes = signature.sign(); } /* * Parse an RSA server key exchange message, using data known * to the client (and, in some situations, eavesdroppers). */ RSA_ServerKeyExchange(HandshakeInStream input) throws IOException, NoSuchAlgorithmException { signature = RSASignature.getInstance(); rsa_modulus = input.getBytes16(); rsa_exponent = input.getBytes16(); signatureBytes = input.getBytes16(); } /* * Get the ephemeral RSA public key that will be used in this * SSL connection. */ PublicKey getPublicKey() { try { KeyFactory kfac = JsseJce.getKeyFactory("RSA"); // modulus and exponent are always positive RSAPublicKeySpec kspec = new RSAPublicKeySpec( new BigInteger(1, rsa_modulus), new BigInteger(1, rsa_exponent)); return kfac.generatePublic(kspec); } catch (Exception e) { throw new RuntimeException(e); } } /* * Verify the signed temporary key using the hashes computed * from it and the two nonces. This is called by clients * with "exportable" RSA flavors. */ boolean verify(PublicKey certifiedKey, RandomCookie clntNonce, RandomCookie svrNonce) throws GeneralSecurityException { signature.initVerify(certifiedKey); updateSignature(clntNonce.random_bytes, svrNonce.random_bytes); return signature.verify(signatureBytes); } @Override int messageLength() { return 6 + rsa_modulus.length + rsa_exponent.length + signatureBytes.length; } @Override void send(HandshakeOutStream s) throws IOException { s.putBytes16(rsa_modulus); s.putBytes16(rsa_exponent); s.putBytes16(signatureBytes); } @Override void print(PrintStream s) throws IOException { s.println("*** RSA ServerKeyExchange"); if (debug != null && Debug.isOn("verbose")) { Debug.println(s, "RSA Modulus", rsa_modulus); Debug.println(s, "RSA Public Exponent", rsa_exponent); } } } /* * Using Diffie-Hellman algorithm for key exchange. All we really need to * do is securely get Diffie-Hellman keys (using the same P, G parameters) * to our peer, then we automatically have a shared secret without need * to exchange any more data. (D-H only solutions, such as SKIP, could * eliminate key exchange negotiations and get faster connection setup. * But they still need a signature algorithm like DSS/DSA to support the * trusted distribution of keys without relying on unscalable physical * key distribution systems.) * * This class supports several DH-based key exchange algorithms, though * perhaps eventually each deserves its own class. Notably, this has * basic support for DH_anon and its DHE_DSS and DHE_RSA signed variants. */ static final class DH_ServerKeyExchange extends ServerKeyExchange { // Fix message encoding, see 4348279 private final static boolean dhKeyExchangeFix = Debug.getBooleanProperty("com.sun.net.ssl.dhKeyExchangeFix", true); private byte dh_p []; // 1 to 2^16 - 1 bytes private byte dh_g []; // 1 to 2^16 - 1 bytes private byte dh_Ys []; // 1 to 2^16 - 1 bytes private byte signature []; // protocol version being established using this ServerKeyExchange message ProtocolVersion protocolVersion; // the preferable signature algorithm used by this ServerKeyExchange message private SignatureAndHashAlgorithm preferableSignatureAlgorithm; /* * Construct from initialized DH key object, for DH_anon * key exchange. */ DH_ServerKeyExchange(DHCrypt obj, ProtocolVersion protocolVersion) { this.protocolVersion = protocolVersion; this.preferableSignatureAlgorithm = null; // The DH key has been validated in the constructor of DHCrypt. setValues(obj); signature = null; } /* * Construct from initialized DH key object and the key associated * with the cert chain which was sent ... for DHE_DSS and DHE_RSA * key exchange. (Constructor called by server.) */ DH_ServerKeyExchange(DHCrypt obj, PrivateKey key, byte clntNonce[], byte svrNonce[], SecureRandom sr, SignatureAndHashAlgorithm signAlgorithm, ProtocolVersion protocolVersion) throws GeneralSecurityException { this.protocolVersion = protocolVersion; // The DH key has been validated in the constructor of DHCrypt. setValues(obj); Signature sig; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { this.preferableSignatureAlgorithm = signAlgorithm; sig = JsseJce.getSignature(signAlgorithm.getAlgorithmName()); } else { this.preferableSignatureAlgorithm = null; if (key.getAlgorithm().equals("DSA")) { sig = JsseJce.getSignature(JsseJce.SIGNATURE_DSA); } else { sig = RSASignature.getInstance(); } } sig.initSign(key, sr); updateSignature(sig, clntNonce, svrNonce); signature = sig.sign(); } /* * Construct a DH_ServerKeyExchange message from an input * stream, as if sent from server to client for use with * DH_anon key exchange */ DH_ServerKeyExchange(HandshakeInStream input, ProtocolVersion protocolVersion) throws IOException, GeneralSecurityException { this.protocolVersion = protocolVersion; this.preferableSignatureAlgorithm = null; dh_p = input.getBytes16(); dh_g = input.getBytes16(); dh_Ys = input.getBytes16(); KeyUtil.validate(new DHPublicKeySpec(new BigInteger(1, dh_Ys), new BigInteger(1, dh_p), new BigInteger(1, dh_g))); signature = null; } /* * Construct a DH_ServerKeyExchange message from an input stream * and a certificate, as if sent from server to client for use with * DHE_DSS or DHE_RSA key exchange. (Called by client.) */ DH_ServerKeyExchange(HandshakeInStream input, PublicKey publicKey, byte clntNonce[], byte svrNonce[], int messageSize, Collection localSupportedSignAlgs, ProtocolVersion protocolVersion) throws IOException, GeneralSecurityException { this.protocolVersion = protocolVersion; // read params: ServerDHParams dh_p = input.getBytes16(); dh_g = input.getBytes16(); dh_Ys = input.getBytes16(); KeyUtil.validate(new DHPublicKeySpec(new BigInteger(1, dh_Ys), new BigInteger(1, dh_p), new BigInteger(1, dh_g))); // read the signature and hash algorithm if (protocolVersion.v >= ProtocolVersion.TLS12.v) { int hash = input.getInt8(); // hash algorithm int signature = input.getInt8(); // signature algorithm preferableSignatureAlgorithm = SignatureAndHashAlgorithm.valueOf(hash, signature, 0); // Is it a local supported signature algorithm? if (!localSupportedSignAlgs.contains( preferableSignatureAlgorithm)) { throw new SSLHandshakeException( "Unsupported SignatureAndHashAlgorithm in " + "ServerKeyExchange message"); } } else { this.preferableSignatureAlgorithm = null; } // read the signature byte signature[]; if (dhKeyExchangeFix) { signature = input.getBytes16(); } else { messageSize -= (dh_p.length + 2); messageSize -= (dh_g.length + 2); messageSize -= (dh_Ys.length + 2); signature = new byte[messageSize]; input.read(signature); } Signature sig; String algorithm = publicKey.getAlgorithm(); if (protocolVersion.v >= ProtocolVersion.TLS12.v) { sig = JsseJce.getSignature( preferableSignatureAlgorithm.getAlgorithmName()); } else { switch (algorithm) { case "DSA": sig = JsseJce.getSignature(JsseJce.SIGNATURE_DSA); break; case "RSA": sig = RSASignature.getInstance(); break; default: throw new SSLKeyException("neither an RSA or a DSA key"); } } sig.initVerify(publicKey); updateSignature(sig, clntNonce, svrNonce); if (sig.verify(signature) == false ) { throw new SSLKeyException("Server D-H key verification failed"); } } /* Return the Diffie-Hellman modulus */ BigInteger getModulus() { return new BigInteger(1, dh_p); } /* Return the Diffie-Hellman base/generator */ BigInteger getBase() { return new BigInteger(1, dh_g); } /* Return the server's Diffie-Hellman public key */ BigInteger getServerPublicKey() { return new BigInteger(1, dh_Ys); } /* * Update sig with nonces and Diffie-Hellman public key. */ private void updateSignature(Signature sig, byte clntNonce[], byte svrNonce[]) throws SignatureException { int tmp; sig.update(clntNonce); sig.update(svrNonce); tmp = dh_p.length; sig.update((byte)(tmp >> 8)); sig.update((byte)(tmp & 0x0ff)); sig.update(dh_p); tmp = dh_g.length; sig.update((byte)(tmp >> 8)); sig.update((byte)(tmp & 0x0ff)); sig.update(dh_g); tmp = dh_Ys.length; sig.update((byte)(tmp >> 8)); sig.update((byte)(tmp & 0x0ff)); sig.update(dh_Ys); } private void setValues(DHCrypt obj) { dh_p = toByteArray(obj.getModulus()); dh_g = toByteArray(obj.getBase()); dh_Ys = toByteArray(obj.getPublicKey()); } @Override int messageLength() { int temp = 6; // overhead for p, g, y(s) values. temp += dh_p.length; temp += dh_g.length; temp += dh_Ys.length; if (signature != null) { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { temp += SignatureAndHashAlgorithm.sizeInRecord(); } temp += signature.length; if (dhKeyExchangeFix) { temp += 2; } } return temp; } @Override void send(HandshakeOutStream s) throws IOException { s.putBytes16(dh_p); s.putBytes16(dh_g); s.putBytes16(dh_Ys); if (signature != null) { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.putInt8(preferableSignatureAlgorithm.getHashValue()); s.putInt8(preferableSignatureAlgorithm.getSignatureValue()); } if (dhKeyExchangeFix) { s.putBytes16(signature); } else { s.write(signature); } } } @Override void print(PrintStream s) throws IOException { s.println("*** Diffie-Hellman ServerKeyExchange"); if (debug != null && Debug.isOn("verbose")) { Debug.println(s, "DH Modulus", dh_p); Debug.println(s, "DH Base", dh_g); Debug.println(s, "Server DH Public Key", dh_Ys); if (signature == null) { s.println("Anonymous"); } else { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.println("Signature Algorithm " + preferableSignatureAlgorithm.getAlgorithmName()); } s.println("Signed with a DSA or RSA public key"); } } } } /* * ECDH server key exchange message. Sent by the server for ECDHE and ECDH_anon * ciphersuites to communicate its ephemeral public key (including the * EC domain parameters). * * We support named curves only, no explicitly encoded curves. */ static final class ECDH_ServerKeyExchange extends ServerKeyExchange { // constants for ECCurveType private final static int CURVE_EXPLICIT_PRIME = 1; private final static int CURVE_EXPLICIT_CHAR2 = 2; private final static int CURVE_NAMED_CURVE = 3; // id of the curve we are using private int curveId; // encoded public point private byte[] pointBytes; // signature bytes (or null if anonymous) private byte[] signatureBytes; // public key object encapsulated in this message private ECPublicKey publicKey; // protocol version being established using this ServerKeyExchange message ProtocolVersion protocolVersion; // the preferable signature algorithm used by this ServerKeyExchange message private SignatureAndHashAlgorithm preferableSignatureAlgorithm; ECDH_ServerKeyExchange(ECDHCrypt obj, PrivateKey privateKey, byte[] clntNonce, byte[] svrNonce, SecureRandom sr, SignatureAndHashAlgorithm signAlgorithm, ProtocolVersion protocolVersion) throws GeneralSecurityException { this.protocolVersion = protocolVersion; publicKey = (ECPublicKey)obj.getPublicKey(); ECParameterSpec params = publicKey.getParams(); ECPoint point = publicKey.getW(); pointBytes = JsseJce.encodePoint(point, params.getCurve()); curveId = SupportedEllipticCurvesExtension.getCurveIndex(params); if (privateKey == null) { // ECDH_anon return; } Signature sig; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { this.preferableSignatureAlgorithm = signAlgorithm; sig = JsseJce.getSignature(signAlgorithm.getAlgorithmName()); } else { sig = getSignature(privateKey.getAlgorithm()); } sig.initSign(privateKey); // where is the SecureRandom? updateSignature(sig, clntNonce, svrNonce); signatureBytes = sig.sign(); } /* * Parse an ECDH server key exchange message. */ ECDH_ServerKeyExchange(HandshakeInStream input, PublicKey signingKey, byte[] clntNonce, byte[] svrNonce, Collection localSupportedSignAlgs, ProtocolVersion protocolVersion) throws IOException, GeneralSecurityException { this.protocolVersion = protocolVersion; // read params: ServerECDHParams int curveType = input.getInt8(); ECParameterSpec parameters; // These parsing errors should never occur as we negotiated // the supported curves during the exchange of the Hello messages. if (curveType == CURVE_NAMED_CURVE) { curveId = input.getInt16(); if (SupportedEllipticCurvesExtension.isSupported(curveId) == false) { throw new SSLHandshakeException( "Unsupported curveId: " + curveId); } String curveOid = SupportedEllipticCurvesExtension.getCurveOid(curveId); if (curveOid == null) { throw new SSLHandshakeException( "Unknown named curve: " + curveId); } parameters = JsseJce.getECParameterSpec(curveOid); if (parameters == null) { throw new SSLHandshakeException( "Unsupported curve: " + curveOid); } } else { throw new SSLHandshakeException( "Unsupported ECCurveType: " + curveType); } pointBytes = input.getBytes8(); ECPoint point = JsseJce.decodePoint(pointBytes, parameters.getCurve()); KeyFactory factory = JsseJce.getKeyFactory("EC"); publicKey = (ECPublicKey)factory.generatePublic( new ECPublicKeySpec(point, parameters)); if (signingKey == null) { // ECDH_anon return; } // read the signature and hash algorithm if (protocolVersion.v >= ProtocolVersion.TLS12.v) { int hash = input.getInt8(); // hash algorithm int signature = input.getInt8(); // signature algorithm preferableSignatureAlgorithm = SignatureAndHashAlgorithm.valueOf(hash, signature, 0); // Is it a local supported signature algorithm? if (!localSupportedSignAlgs.contains( preferableSignatureAlgorithm)) { throw new SSLHandshakeException( "Unsupported SignatureAndHashAlgorithm in " + "ServerKeyExchange message"); } } // read the signature signatureBytes = input.getBytes16(); // verify the signature Signature sig; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { sig = JsseJce.getSignature( preferableSignatureAlgorithm.getAlgorithmName()); } else { sig = getSignature(signingKey.getAlgorithm()); } sig.initVerify(signingKey); updateSignature(sig, clntNonce, svrNonce); if (sig.verify(signatureBytes) == false ) { throw new SSLKeyException( "Invalid signature on ECDH server key exchange message"); } } /* * Get the ephemeral EC public key encapsulated in this message. */ ECPublicKey getPublicKey() { return publicKey; } private static Signature getSignature(String keyAlgorithm) throws NoSuchAlgorithmException { switch (keyAlgorithm) { case "EC": return JsseJce.getSignature(JsseJce.SIGNATURE_ECDSA); case "RSA": return RSASignature.getInstance(); default: throw new NoSuchAlgorithmException("neither an RSA or a EC key"); } } private void updateSignature(Signature sig, byte clntNonce[], byte svrNonce[]) throws SignatureException { sig.update(clntNonce); sig.update(svrNonce); sig.update((byte)CURVE_NAMED_CURVE); sig.update((byte)(curveId >> 8)); sig.update((byte)curveId); sig.update((byte)pointBytes.length); sig.update(pointBytes); } @Override int messageLength() { int sigLen = 0; if (signatureBytes != null) { sigLen = 2 + signatureBytes.length; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { sigLen += SignatureAndHashAlgorithm.sizeInRecord(); } } return 4 + pointBytes.length + sigLen; } @Override void send(HandshakeOutStream s) throws IOException { s.putInt8(CURVE_NAMED_CURVE); s.putInt16(curveId); s.putBytes8(pointBytes); if (signatureBytes != null) { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.putInt8(preferableSignatureAlgorithm.getHashValue()); s.putInt8(preferableSignatureAlgorithm.getSignatureValue()); } s.putBytes16(signatureBytes); } } @Override void print(PrintStream s) throws IOException { s.println("*** ECDH ServerKeyExchange"); if (debug != null && Debug.isOn("verbose")) { if (signatureBytes == null) { s.println("Anonymous"); } else { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.println("Signature Algorithm " + preferableSignatureAlgorithm.getAlgorithmName()); } } s.println("Server key: " + publicKey); } } } static final class DistinguishedName { /* * DER encoded distinguished name. * TLS requires that its not longer than 65535 bytes. */ byte name[]; DistinguishedName(HandshakeInStream input) throws IOException { name = input.getBytes16(); } DistinguishedName(X500Principal dn) { name = dn.getEncoded(); } X500Principal getX500Principal() throws IOException { try { return new X500Principal(name); } catch (IllegalArgumentException e) { throw (SSLProtocolException)new SSLProtocolException( e.getMessage()).initCause(e); } } int length() { return 2 + name.length; } void send(HandshakeOutStream output) throws IOException { output.putBytes16(name); } void print(PrintStream output) throws IOException { X500Principal principal = new X500Principal(name); output.println("<" + principal.toString() + ">"); } } /* * CertificateRequest ... SERVER --> CLIENT * * Authenticated servers may ask clients to authenticate themselves * in turn, using this message. * * Prior to TLS 1.2, the structure of the message is defined as: * struct { * ClientCertificateType certificate_types<1..2^8-1>; * DistinguishedName certificate_authorities<0..2^16-1>; * } CertificateRequest; * * In TLS 1.2, the structure is changed to: * struct { * ClientCertificateType certificate_types<1..2^8-1>; * SignatureAndHashAlgorithm * supported_signature_algorithms<2^16-1>; * DistinguishedName certificate_authorities<0..2^16-1>; * } CertificateRequest; * */ static final class CertificateRequest extends HandshakeMessage { // enum ClientCertificateType static final int cct_rsa_sign = 1; static final int cct_dss_sign = 2; static final int cct_rsa_fixed_dh = 3; static final int cct_dss_fixed_dh = 4; // The existance of these two values is a bug in the SSL specification. // They are never used in the protocol. static final int cct_rsa_ephemeral_dh = 5; static final int cct_dss_ephemeral_dh = 6; // From RFC 4492 (ECC) static final int cct_ecdsa_sign = 64; static final int cct_rsa_fixed_ecdh = 65; static final int cct_ecdsa_fixed_ecdh = 66; private final static byte[] TYPES_NO_ECC = { cct_rsa_sign, cct_dss_sign }; private final static byte[] TYPES_ECC = { cct_rsa_sign, cct_dss_sign, cct_ecdsa_sign }; byte types []; // 1 to 255 types DistinguishedName authorities []; // 3 to 2^16 - 1 // ... "3" because that's the smallest DER-encoded X500 DN // protocol version being established using this CertificateRequest message ProtocolVersion protocolVersion; // supported_signature_algorithms for TLS 1.2 or later private Collection algorithms; // length of supported_signature_algorithms private int algorithmsLen; CertificateRequest(X509Certificate ca[], KeyExchange keyExchange, Collection signAlgs, ProtocolVersion protocolVersion) throws IOException { this.protocolVersion = protocolVersion; // always use X500Principal authorities = new DistinguishedName[ca.length]; for (int i = 0; i < ca.length; i++) { X500Principal x500Principal = ca[i].getSubjectX500Principal(); authorities[i] = new DistinguishedName(x500Principal); } // we support RSA, DSS, and ECDSA client authentication and they // can be used with all ciphersuites. If this changes, the code // needs to be adapted to take keyExchange into account. // We only request ECDSA client auth if we have ECC crypto available. this.types = JsseJce.isEcAvailable() ? TYPES_ECC : TYPES_NO_ECC; // Use supported_signature_algorithms for TLS 1.2 or later. if (protocolVersion.v >= ProtocolVersion.TLS12.v) { if (signAlgs == null || signAlgs.isEmpty()) { throw new SSLProtocolException( "No supported signature algorithms"); } algorithms = new ArrayList(signAlgs); algorithmsLen = SignatureAndHashAlgorithm.sizeInRecord() * algorithms.size(); } else { algorithms = new ArrayList(); algorithmsLen = 0; } } CertificateRequest(HandshakeInStream input, ProtocolVersion protocolVersion) throws IOException { this.protocolVersion = protocolVersion; // Read the certificate_types. types = input.getBytes8(); // Read the supported_signature_algorithms for TLS 1.2 or later. if (protocolVersion.v >= ProtocolVersion.TLS12.v) { algorithmsLen = input.getInt16(); if (algorithmsLen < 2) { throw new SSLProtocolException( "Invalid supported_signature_algorithms field"); } algorithms = new ArrayList(); int remains = algorithmsLen; int sequence = 0; while (remains > 1) { // needs at least two bytes int hash = input.getInt8(); // hash algorithm int signature = input.getInt8(); // signature algorithm SignatureAndHashAlgorithm algorithm = SignatureAndHashAlgorithm.valueOf(hash, signature, ++sequence); algorithms.add(algorithm); remains -= 2; // one byte for hash, one byte for signature } if (remains != 0) { throw new SSLProtocolException( "Invalid supported_signature_algorithms field"); } } else { algorithms = new ArrayList(); algorithmsLen = 0; } // read the certificate_authorities int len = input.getInt16(); ArrayList v = new ArrayList<>(); while (len >= 3) { DistinguishedName dn = new DistinguishedName(input); v.add(dn); len -= dn.length(); } if (len != 0) { throw new SSLProtocolException("Bad CertificateRequest DN length"); } authorities = v.toArray(new DistinguishedName[v.size()]); } X500Principal[] getAuthorities() throws IOException { X500Principal[] ret = new X500Principal[authorities.length]; for (int i = 0; i < authorities.length; i++) { ret[i] = authorities[i].getX500Principal(); } return ret; } Collection getSignAlgorithms() { return algorithms; } @Override int messageType() { return ht_certificate_request; } @Override int messageLength() { int len = 1 + types.length + 2; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { len += algorithmsLen + 2; } for (int i = 0; i < authorities.length; i++) { len += authorities[i].length(); } return len; } @Override void send(HandshakeOutStream output) throws IOException { // put certificate_types output.putBytes8(types); // put supported_signature_algorithms if (protocolVersion.v >= ProtocolVersion.TLS12.v) { output.putInt16(algorithmsLen); for (SignatureAndHashAlgorithm algorithm : algorithms) { output.putInt8(algorithm.getHashValue()); // hash output.putInt8(algorithm.getSignatureValue()); // signature } } // put certificate_authorities int len = 0; for (int i = 0; i < authorities.length; i++) { len += authorities[i].length(); } output.putInt16(len); for (int i = 0; i < authorities.length; i++) { authorities[i].send(output); } } @Override void print(PrintStream s) throws IOException { s.println("*** CertificateRequest"); if (debug != null && Debug.isOn("verbose")) { s.print("Cert Types: "); for (int i = 0; i < types.length; i++) { switch (types[i]) { case cct_rsa_sign: s.print("RSA"); break; case cct_dss_sign: s.print("DSS"); break; case cct_rsa_fixed_dh: s.print("Fixed DH (RSA sig)"); break; case cct_dss_fixed_dh: s.print("Fixed DH (DSS sig)"); break; case cct_rsa_ephemeral_dh: s.print("Ephemeral DH (RSA sig)"); break; case cct_dss_ephemeral_dh: s.print("Ephemeral DH (DSS sig)"); break; case cct_ecdsa_sign: s.print("ECDSA"); break; case cct_rsa_fixed_ecdh: s.print("Fixed ECDH (RSA sig)"); break; case cct_ecdsa_fixed_ecdh: s.print("Fixed ECDH (ECDSA sig)"); break; default: s.print("Type-" + (types[i] & 0xff)); break; } if (i != types.length - 1) { s.print(", "); } } s.println(); if (protocolVersion.v >= ProtocolVersion.TLS12.v) { StringBuilder sb = new StringBuilder(); boolean opened = false; for (SignatureAndHashAlgorithm signAlg : algorithms) { if (opened) { sb.append(", " + signAlg.getAlgorithmName()); } else { sb.append(signAlg.getAlgorithmName()); opened = true; } } s.println("Supported Signature Algorithms: " + sb); } s.println("Cert Authorities:"); if (authorities.length == 0) { s.println(""); } else { for (int i = 0; i < authorities.length; i++) { authorities[i].print(s); } } } } } /* * ServerHelloDone ... SERVER --> CLIENT * * When server's done sending its messages in response to the client's * "hello" (e.g. its own hello, certificate, key exchange message, perhaps * client certificate request) it sends this message to flag that it's * done that part of the handshake. */ static final class ServerHelloDone extends HandshakeMessage { @Override int messageType() { return ht_server_hello_done; } ServerHelloDone() { } ServerHelloDone(HandshakeInStream input) { // nothing to do } @Override int messageLength() { return 0; } @Override void send(HandshakeOutStream s) throws IOException { // nothing to send } @Override void print(PrintStream s) throws IOException { s.println("*** ServerHelloDone"); } } /* * CertificateVerify ... CLIENT --> SERVER * * Sent after client sends signature-capable certificates (e.g. not * Diffie-Hellman) to verify. */ static final class CertificateVerify extends HandshakeMessage { // the signature bytes private byte[] signature; // protocol version being established using this ServerKeyExchange message ProtocolVersion protocolVersion; // the preferable signature algorithm used by this CertificateVerify message private SignatureAndHashAlgorithm preferableSignatureAlgorithm = null; /* * Create an RSA or DSA signed certificate verify message. */ CertificateVerify(ProtocolVersion protocolVersion, HandshakeHash handshakeHash, PrivateKey privateKey, SecretKey masterSecret, SecureRandom sr, SignatureAndHashAlgorithm signAlgorithm) throws GeneralSecurityException { this.protocolVersion = protocolVersion; String algorithm = privateKey.getAlgorithm(); Signature sig = null; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { this.preferableSignatureAlgorithm = signAlgorithm; sig = JsseJce.getSignature(signAlgorithm.getAlgorithmName()); } else { sig = getSignature(protocolVersion, algorithm); } sig.initSign(privateKey, sr); updateSignature(sig, protocolVersion, handshakeHash, algorithm, masterSecret); signature = sig.sign(); } // // Unmarshal the signed data from the input stream. // CertificateVerify(HandshakeInStream input, Collection localSupportedSignAlgs, ProtocolVersion protocolVersion) throws IOException { this.protocolVersion = protocolVersion; // read the signature and hash algorithm if (protocolVersion.v >= ProtocolVersion.TLS12.v) { int hashAlg = input.getInt8(); // hash algorithm int signAlg = input.getInt8(); // signature algorithm preferableSignatureAlgorithm = SignatureAndHashAlgorithm.valueOf(hashAlg, signAlg, 0); // Is it a local supported signature algorithm? if (!localSupportedSignAlgs.contains( preferableSignatureAlgorithm)) { throw new SSLHandshakeException( "Unsupported SignatureAndHashAlgorithm in " + "ServerKeyExchange message"); } } // read the signature signature = input.getBytes16(); } /* * Get the preferable signature algorithm used by this message */ SignatureAndHashAlgorithm getPreferableSignatureAlgorithm() { return preferableSignatureAlgorithm; } /* * Verify a certificate verify message. Return the result of verification, * if there is a problem throw a GeneralSecurityException. */ boolean verify(ProtocolVersion protocolVersion, HandshakeHash handshakeHash, PublicKey publicKey, SecretKey masterSecret) throws GeneralSecurityException { String algorithm = publicKey.getAlgorithm(); Signature sig = null; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { sig = JsseJce.getSignature( preferableSignatureAlgorithm.getAlgorithmName()); } else { sig = getSignature(protocolVersion, algorithm); } sig.initVerify(publicKey); updateSignature(sig, protocolVersion, handshakeHash, algorithm, masterSecret); return sig.verify(signature); } /* * Get the Signature object appropriate for verification using the * given signature algorithm and protocol version. */ private static Signature getSignature(ProtocolVersion protocolVersion, String algorithm) throws GeneralSecurityException { switch (algorithm) { case "RSA": return RSASignature.getInternalInstance(); case "DSA": return JsseJce.getSignature(JsseJce.SIGNATURE_RAWDSA); case "EC": return JsseJce.getSignature(JsseJce.SIGNATURE_RAWECDSA); default: throw new SignatureException("Unrecognized algorithm: " + algorithm); } } /* * Update the Signature with the data appropriate for the given * signature algorithm and protocol version so that the object is * ready for signing or verifying. */ private static void updateSignature(Signature sig, ProtocolVersion protocolVersion, HandshakeHash handshakeHash, String algorithm, SecretKey masterKey) throws SignatureException { if (algorithm.equals("RSA")) { if (protocolVersion.v < ProtocolVersion.TLS12.v) { // TLS1.1- MessageDigest md5Clone = handshakeHash.getMD5Clone(); MessageDigest shaClone = handshakeHash.getSHAClone(); if (protocolVersion.v < ProtocolVersion.TLS10.v) { // SSLv3 updateDigest(md5Clone, MD5_pad1, MD5_pad2, masterKey); updateDigest(shaClone, SHA_pad1, SHA_pad2, masterKey); } // The signature must be an instance of RSASignature, need // to use these hashes directly. RSASignature.setHashes(sig, md5Clone, shaClone); } else { // TLS1.2+ sig.update(handshakeHash.getAllHandshakeMessages()); } } else { // DSA, ECDSA if (protocolVersion.v < ProtocolVersion.TLS12.v) { // TLS1.1- MessageDigest shaClone = handshakeHash.getSHAClone(); if (protocolVersion.v < ProtocolVersion.TLS10.v) { // SSLv3 updateDigest(shaClone, SHA_pad1, SHA_pad2, masterKey); } sig.update(shaClone.digest()); } else { // TLS1.2+ sig.update(handshakeHash.getAllHandshakeMessages()); } } } /* * Update the MessageDigest for SSLv3 certificate verify or finished * message calculation. The digest must already have been updated with * all preceding handshake messages. * Used by the Finished class as well. */ private static void updateDigest(MessageDigest md, byte[] pad1, byte[] pad2, SecretKey masterSecret) { // Digest the key bytes if available. // Otherwise (sensitive key), try digesting the key directly. // That is currently only implemented in SunPKCS11 using a private // reflection API, so we avoid that if possible. byte[] keyBytes = "RAW".equals(masterSecret.getFormat()) ? masterSecret.getEncoded() : null; if (keyBytes != null) { md.update(keyBytes); } else { digestKey(md, masterSecret); } md.update(pad1); byte[] temp = md.digest(); if (keyBytes != null) { md.update(keyBytes); } else { digestKey(md, masterSecret); } md.update(pad2); md.update(temp); } private final static Class delegate; private final static Field spiField; static { try { delegate = Class.forName("java.security.MessageDigest$Delegate"); spiField = delegate.getDeclaredField("digestSpi"); } catch (Exception e) { throw new RuntimeException("Reflection failed", e); } makeAccessible(spiField); } private static void makeAccessible(final AccessibleObject o) { AccessController.doPrivileged(new PrivilegedAction() { @Override public Object run() { o.setAccessible(true); return null; } }); } // ConcurrentHashMap does not allow null values, use this marker object private final static Object NULL_OBJECT = new Object(); // cache Method objects per Spi class // Note that this will prevent the Spi classes from being GC'd. We assume // that is not a problem. private final static Map,Object> methodCache = new ConcurrentHashMap<>(); private static void digestKey(MessageDigest md, SecretKey key) { try { // Verify that md is implemented via MessageDigestSpi, not // via JDK 1.1 style MessageDigest subclassing. if (md.getClass() != delegate) { throw new Exception("Digest is not a MessageDigestSpi"); } MessageDigestSpi spi = (MessageDigestSpi)spiField.get(md); Class clazz = spi.getClass(); Object r = methodCache.get(clazz); if (r == null) { try { r = clazz.getDeclaredMethod("implUpdate", SecretKey.class); makeAccessible((Method)r); } catch (NoSuchMethodException e) { r = NULL_OBJECT; } methodCache.put(clazz, r); } if (r == NULL_OBJECT) { throw new Exception( "Digest does not support implUpdate(SecretKey)"); } Method update = (Method)r; update.invoke(spi, key); } catch (Exception e) { throw new RuntimeException( "Could not obtain encoded key and " + "MessageDigest cannot digest key", e); } } @Override int messageType() { return ht_certificate_verify; } @Override int messageLength() { int temp = 2; if (protocolVersion.v >= ProtocolVersion.TLS12.v) { temp += SignatureAndHashAlgorithm.sizeInRecord(); } return temp + signature.length; } @Override void send(HandshakeOutStream s) throws IOException { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.putInt8(preferableSignatureAlgorithm.getHashValue()); s.putInt8(preferableSignatureAlgorithm.getSignatureValue()); } s.putBytes16(signature); } @Override void print(PrintStream s) throws IOException { s.println("*** CertificateVerify"); if (debug != null && Debug.isOn("verbose")) { if (protocolVersion.v >= ProtocolVersion.TLS12.v) { s.println("Signature Algorithm " + preferableSignatureAlgorithm.getAlgorithmName()); } } } } /* * FINISHED ... sent by both CLIENT and SERVER * * This is the FINISHED message as defined in the SSL and TLS protocols. * Both protocols define this handshake message slightly differently. * This class supports both formats. * * When handshaking is finished, each side sends a "change_cipher_spec" * record, then immediately sends a "finished" handshake message prepared * according to the newly adopted cipher spec. * * NOTE that until this is sent, no application data may be passed, unless * some non-default cipher suite has already been set up on this connection * connection (e.g. a previous handshake arranged one). */ static final class Finished extends HandshakeMessage { // constant for a Finished message sent by the client final static int CLIENT = 1; // constant for a Finished message sent by the server final static int SERVER = 2; // enum Sender: "CLNT" and "SRVR" private static final byte[] SSL_CLIENT = { 0x43, 0x4C, 0x4E, 0x54 }; private static final byte[] SSL_SERVER = { 0x53, 0x52, 0x56, 0x52 }; /* * Contents of the finished message ("checksum"). For TLS, it * is 12 bytes long, for SSLv3 36 bytes. */ private byte[] verifyData; /* * Current cipher suite we are negotiating. TLS 1.2 has * ciphersuite-defined PRF algorithms. */ private ProtocolVersion protocolVersion; private CipherSuite cipherSuite; /* * Create a finished message to send to the remote peer. */ Finished(ProtocolVersion protocolVersion, HandshakeHash handshakeHash, int sender, SecretKey master, CipherSuite cipherSuite) { this.protocolVersion = protocolVersion; this.cipherSuite = cipherSuite; verifyData = getFinished(handshakeHash, sender, master); } /* * Constructor that reads FINISHED message from stream. */ Finished(ProtocolVersion protocolVersion, HandshakeInStream input, CipherSuite cipherSuite) throws IOException { this.protocolVersion = protocolVersion; this.cipherSuite = cipherSuite; int msgLen = (protocolVersion.v >= ProtocolVersion.TLS10.v) ? 12 : 36; verifyData = new byte[msgLen]; input.read(verifyData); } /* * Verify that the hashes here are what would have been produced * according to a given set of inputs. This is used to ensure that * both client and server are fully in sync, and that the handshake * computations have been successful. */ boolean verify(HandshakeHash handshakeHash, int sender, SecretKey master) { byte[] myFinished = getFinished(handshakeHash, sender, master); return Arrays.equals(myFinished, verifyData); } /* * Perform the actual finished message calculation. */ private byte[] getFinished(HandshakeHash handshakeHash, int sender, SecretKey masterKey) { byte[] sslLabel; String tlsLabel; if (sender == CLIENT) { sslLabel = SSL_CLIENT; tlsLabel = "client finished"; } else if (sender == SERVER) { sslLabel = SSL_SERVER; tlsLabel = "server finished"; } else { throw new RuntimeException("Invalid sender: " + sender); } if (protocolVersion.v >= ProtocolVersion.TLS10.v) { // TLS 1.0+ try { byte [] seed; String prfAlg; PRF prf; // Get the KeyGenerator alg and calculate the seed. if (protocolVersion.v >= ProtocolVersion.TLS12.v) { // TLS 1.2 seed = handshakeHash.getFinishedHash(); prfAlg = "SunTls12Prf"; prf = cipherSuite.prfAlg; } else { // TLS 1.0/1.1 MessageDigest md5Clone = handshakeHash.getMD5Clone(); MessageDigest shaClone = handshakeHash.getSHAClone(); seed = new byte[36]; md5Clone.digest(seed, 0, 16); shaClone.digest(seed, 16, 20); prfAlg = "SunTlsPrf"; prf = P_NONE; } String prfHashAlg = prf.getPRFHashAlg(); int prfHashLength = prf.getPRFHashLength(); int prfBlockSize = prf.getPRFBlockSize(); /* * RFC 5246/7.4.9 says that finished messages can * be ciphersuite-specific in both length/PRF hash * algorithm. If we ever run across a different * length, this call will need to be updated. */ @SuppressWarnings("deprecation") TlsPrfParameterSpec spec = new TlsPrfParameterSpec( masterKey, tlsLabel, seed, 12, prfHashAlg, prfHashLength, prfBlockSize); KeyGenerator kg = JsseJce.getKeyGenerator(prfAlg); kg.init(spec); SecretKey prfKey = kg.generateKey(); if ("RAW".equals(prfKey.getFormat()) == false) { throw new ProviderException( "Invalid PRF output, format must be RAW"); } byte[] finished = prfKey.getEncoded(); return finished; } catch (GeneralSecurityException e) { throw new RuntimeException("PRF failed", e); } } else { // SSLv3 MessageDigest md5Clone = handshakeHash.getMD5Clone(); MessageDigest shaClone = handshakeHash.getSHAClone(); updateDigest(md5Clone, sslLabel, MD5_pad1, MD5_pad2, masterKey); updateDigest(shaClone, sslLabel, SHA_pad1, SHA_pad2, masterKey); byte[] finished = new byte[36]; try { md5Clone.digest(finished, 0, 16); shaClone.digest(finished, 16, 20); } catch (DigestException e) { // cannot occur throw new RuntimeException("Digest failed", e); } return finished; } } /* * Update the MessageDigest for SSLv3 finished message calculation. * The digest must already have been updated with all preceding handshake * messages. This operation is almost identical to the certificate verify * hash, reuse that code. */ private static void updateDigest(MessageDigest md, byte[] sender, byte[] pad1, byte[] pad2, SecretKey masterSecret) { md.update(sender); CertificateVerify.updateDigest(md, pad1, pad2, masterSecret); } // get the verify_data of the finished message byte[] getVerifyData() { return verifyData; } @Override int messageType() { return ht_finished; } @Override int messageLength() { return verifyData.length; } @Override void send(HandshakeOutStream out) throws IOException { out.write(verifyData); } @Override void print(PrintStream s) throws IOException { s.println("*** Finished"); if (debug != null && Debug.isOn("verbose")) { Debug.println(s, "verify_data", verifyData); s.println("***"); } } } // // END of nested classes // }