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The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.6.
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package org.bouncycastle.crypto.tls;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.math.BigInteger;
import org.bouncycastle.asn1.x509.KeyUsage;
import org.bouncycastle.asn1.x509.SubjectPublicKeyInfo;
import org.bouncycastle.asn1.x509.X509CertificateStructure;
import org.bouncycastle.crypto.AsymmetricCipherKeyPair;
import org.bouncycastle.crypto.agreement.ECDHBasicAgreement;
import org.bouncycastle.crypto.generators.ECKeyPairGenerator;
import org.bouncycastle.crypto.params.AsymmetricKeyParameter;
import org.bouncycastle.crypto.params.ECDomainParameters;
import org.bouncycastle.crypto.params.ECKeyGenerationParameters;
import org.bouncycastle.crypto.params.ECPrivateKeyParameters;
import org.bouncycastle.crypto.params.ECPublicKeyParameters;
import org.bouncycastle.crypto.util.PublicKeyFactory;
import org.bouncycastle.util.BigIntegers;
/**
* ECDH key exchange (see RFC 4492)
*/
class TlsECDHKeyExchange implements TlsKeyExchange
{
protected TlsClientContext context;
protected int keyExchange;
protected TlsSigner tlsSigner;
protected AsymmetricKeyParameter serverPublicKey;
protected ECPublicKeyParameters ecAgreeServerPublicKey;
protected TlsAgreementCredentials agreementCredentials;
protected ECPrivateKeyParameters ecAgreeClientPrivateKey = null;
TlsECDHKeyExchange(TlsClientContext context, int keyExchange)
{
switch (keyExchange)
{
case KeyExchangeAlgorithm.ECDHE_RSA:
this.tlsSigner = new TlsRSASigner();
break;
case KeyExchangeAlgorithm.ECDHE_ECDSA:
this.tlsSigner = new TlsECDSASigner();
break;
case KeyExchangeAlgorithm.ECDH_RSA:
case KeyExchangeAlgorithm.ECDH_ECDSA:
this.tlsSigner = null;
break;
default:
throw new IllegalArgumentException("unsupported key exchange algorithm");
}
this.context = context;
this.keyExchange = keyExchange;
}
public void skipServerCertificate() throws IOException
{
throw new TlsFatalAlert(AlertDescription.unexpected_message);
}
public void processServerCertificate(Certificate serverCertificate) throws IOException
{
X509CertificateStructure x509Cert = serverCertificate.certs[0];
SubjectPublicKeyInfo keyInfo = x509Cert.getSubjectPublicKeyInfo();
try
{
this.serverPublicKey = PublicKeyFactory.createKey(keyInfo);
}
catch (RuntimeException e)
{
throw new TlsFatalAlert(AlertDescription.unsupported_certificate);
}
if (tlsSigner == null)
{
try
{
this.ecAgreeServerPublicKey = validateECPublicKey((ECPublicKeyParameters)this.serverPublicKey);
}
catch (ClassCastException e)
{
throw new TlsFatalAlert(AlertDescription.certificate_unknown);
}
TlsUtils.validateKeyUsage(x509Cert, KeyUsage.keyAgreement);
}
else
{
if (!tlsSigner.isValidPublicKey(this.serverPublicKey))
{
throw new TlsFatalAlert(AlertDescription.certificate_unknown);
}
TlsUtils.validateKeyUsage(x509Cert, KeyUsage.digitalSignature);
}
// TODO
/*
* Perform various checks per RFC2246 7.4.2: "Unless otherwise specified, the
* signing algorithm for the certificate must be the same as the algorithm for the
* certificate key."
*/
}
public void skipServerKeyExchange() throws IOException
{
// do nothing
}
public void processServerKeyExchange(InputStream is)
throws IOException
{
throw new TlsFatalAlert(AlertDescription.unexpected_message);
}
public void validateCertificateRequest(CertificateRequest certificateRequest)
throws IOException
{
/*
* RFC 4492 3. [...] The ECDSA_fixed_ECDH and RSA_fixed_ECDH mechanisms are usable
* with ECDH_ECDSA and ECDH_RSA. Their use with ECDHE_ECDSA and ECDHE_RSA is
* prohibited because the use of a long-term ECDH client key would jeopardize the
* forward secrecy property of these algorithms.
*/
short[] types = certificateRequest.getCertificateTypes();
for (int i = 0; i < types.length; ++i)
{
switch (types[i])
{
case ClientCertificateType.rsa_sign:
case ClientCertificateType.dss_sign:
case ClientCertificateType.ecdsa_sign:
case ClientCertificateType.rsa_fixed_ecdh:
case ClientCertificateType.ecdsa_fixed_ecdh:
break;
default:
throw new TlsFatalAlert(AlertDescription.illegal_parameter);
}
}
}
public void skipClientCredentials() throws IOException
{
this.agreementCredentials = null;
}
public void processClientCredentials(TlsCredentials clientCredentials) throws IOException
{
if (clientCredentials instanceof TlsAgreementCredentials)
{
// TODO Validate client cert has matching parameters (see 'areOnSameCurve')?
this.agreementCredentials = (TlsAgreementCredentials)clientCredentials;
}
else if (clientCredentials instanceof TlsSignerCredentials)
{
// OK
}
else
{
throw new TlsFatalAlert(AlertDescription.internal_error);
}
}
public void generateClientKeyExchange(OutputStream os) throws IOException
{
if (agreementCredentials != null)
{
TlsUtils.writeUint24(0, os);
}
else
{
generateEphemeralClientKeyExchange(ecAgreeServerPublicKey.getParameters(), os);
}
}
public byte[] generatePremasterSecret() throws IOException
{
if (agreementCredentials != null)
{
return agreementCredentials.generateAgreement(ecAgreeServerPublicKey);
}
return calculateECDHBasicAgreement(ecAgreeServerPublicKey, ecAgreeClientPrivateKey);
}
protected boolean areOnSameCurve(ECDomainParameters a, ECDomainParameters b)
{
// TODO Move to ECDomainParameters.equals() or other utility method?
return a.getCurve().equals(b.getCurve()) && a.getG().equals(b.getG())
&& a.getN().equals(b.getN()) && a.getH().equals(b.getH());
}
protected byte[] externalizeKey(ECPublicKeyParameters keyParameters) throws IOException
{
// TODO Add support for compressed encoding and SPF extension
/*
* RFC 4492 5.7. ...an elliptic curve point in uncompressed or compressed format.
* Here, the format MUST conform to what the server has requested through a
* Supported Point Formats Extension if this extension was used, and MUST be
* uncompressed if this extension was not used.
*/
return keyParameters.getQ().getEncoded();
}
protected AsymmetricCipherKeyPair generateECKeyPair(ECDomainParameters ecParams)
{
ECKeyPairGenerator keyPairGenerator = new ECKeyPairGenerator();
ECKeyGenerationParameters keyGenerationParameters = new ECKeyGenerationParameters(ecParams,
context.getSecureRandom());
keyPairGenerator.init(keyGenerationParameters);
return keyPairGenerator.generateKeyPair();
}
protected void generateEphemeralClientKeyExchange(ECDomainParameters ecParams, OutputStream os)
throws IOException
{
AsymmetricCipherKeyPair ecAgreeClientKeyPair = generateECKeyPair(ecParams);
this.ecAgreeClientPrivateKey = (ECPrivateKeyParameters)ecAgreeClientKeyPair.getPrivate();
byte[] keData = externalizeKey((ECPublicKeyParameters)ecAgreeClientKeyPair.getPublic());
TlsUtils.writeUint24(keData.length + 1, os);
TlsUtils.writeOpaque8(keData, os);
}
protected byte[] calculateECDHBasicAgreement(ECPublicKeyParameters publicKey,
ECPrivateKeyParameters privateKey)
{
ECDHBasicAgreement basicAgreement = new ECDHBasicAgreement();
basicAgreement.init(privateKey);
BigInteger agreement = basicAgreement.calculateAgreement(publicKey);
return BigIntegers.asUnsignedByteArray(agreement);
}
protected ECPublicKeyParameters validateECPublicKey(ECPublicKeyParameters key)
throws IOException
{
// TODO Check RFC 4492 for validation
return key;
}
}