// Key factory
bool OSSLRSA::generateKeyPair(AsymmetricKeyPair** ppKeyPair, AsymmetricParameters* parameters, RNG* /*rng = NULL */)
{
// Check parameters
if ((ppKeyPair == NULL) ||
(parameters == NULL))
{
return false;
}
if (!parameters->areOfType(RSAParameters::type))
{
ERROR_MSG("Invalid parameters supplied for RSA key generation");
return false;
}
RSAParameters* params = (RSAParameters*) parameters;
if (params->getBitLength() < getMinKeySize() || params->getBitLength() > getMaxKeySize())
{
ERROR_MSG("This RSA key size (%lu) is not supported", params->getBitLength());
return false;
}
if (params->getBitLength() < 1024)
{
WARNING_MSG("Using an RSA key size < 1024 bits is not recommended");
}
// Retrieve the desired public exponent
unsigned long e = params->getE().long_val();
// Check the public exponent
if ((e == 0) || (e % 2 != 1))
{
ERROR_MSG("Invalid RSA public exponent %d", e);
return false;
}
// Generate the key-pair
RSA* rsa = RSA_generate_key(params->getBitLength(), e, NULL, NULL);
// Check if the key was successfully generated
if (rsa == NULL)
{
ERROR_MSG("RSA key generation failed (0x%08X)", ERR_get_error());
return false;
}
// Create an asymmetric key-pair object to return
OSSLRSAKeyPair* kp = new OSSLRSAKeyPair();
((OSSLRSAPublicKey*) kp->getPublicKey())->setFromOSSL(rsa);
((OSSLRSAPrivateKey*) kp->getPrivateKey())->setFromOSSL(rsa);
*ppKeyPair = kp;
// Release the key
RSA_free(rsa);
return true;
}
// Key factory
bool BotanRSA::generateKeyPair(AsymmetricKeyPair** ppKeyPair, AsymmetricParameters* parameters, RNG* /*rng = NULL */)
{
// Check parameters
if ((ppKeyPair == NULL) ||
(parameters == NULL))
{
return false;
}
if (!parameters->areOfType(RSAParameters::type))
{
ERROR_MSG("Invalid parameters supplied for RSA key generation");
return false;
}
RSAParameters* params = (RSAParameters*) parameters;
if (params->getBitLength() < getMinKeySize() || params->getBitLength() > getMaxKeySize())
{
ERROR_MSG("This RSA key size (%lu) is not supported", params->getBitLength());
return false;
}
// Retrieve the desired public exponent
unsigned long e = params->getE().long_val();
// Check the public exponent
if ((e == 0) || (e % 2 != 1))
{
ERROR_MSG("Invalid RSA public exponent %d", e);
return false;
}
// Create an asymmetric key-pair object to return
BotanRSAKeyPair* kp = new BotanRSAKeyPair();
// Generate the key-pair
Botan::RSA_PrivateKey* rsa = NULL;
try {
BotanRNG* rng = (BotanRNG*)BotanCryptoFactory::i()->getRNG();
rsa = new Botan::RSA_PrivateKey(*rng->getRNG(), params->getBitLength(), e);
}
catch (std::exception& ex) {
ERROR_MSG("RSA key generation failed: %s", ex.what());
delete kp;
return false;
}
((BotanRSAPublicKey*) kp->getPublicKey())->setFromBotan(rsa);
((BotanRSAPrivateKey*) kp->getPrivateKey())->setFromBotan(rsa);
*ppKeyPair = kp;
// Release the key
delete rsa;
return true;
}
void RSATests::testSerialisation()
{
// Generate a 1024-bit key-pair for testing
AsymmetricKeyPair* kp;
RSAParameters p;
p.setE("010001");
p.setBitLength(1024);
CPPUNIT_ASSERT(rsa->generateKeyPair(&kp, &p));
CPPUNIT_ASSERT(kp != NULL);
// Serialise the parameters
ByteString serialisedParams = p.serialise();
// Deserialise the parameters
AsymmetricParameters* dP;
CPPUNIT_ASSERT(rsa->reconstructParameters(&dP, serialisedParams));
CPPUNIT_ASSERT(dP->areOfType(RSAParameters::type));
RSAParameters* ddP = (RSAParameters*) dP;
CPPUNIT_ASSERT(p.getE() == ddP->getE());
CPPUNIT_ASSERT(p.getBitLength() == ddP->getBitLength());
rsa->recycleParameters(dP);
// Serialise the key-pair
ByteString serialisedKP = kp->serialise();
CPPUNIT_ASSERT(serialisedKP.size() != 0);
// Deserialise the key-pair
AsymmetricKeyPair* dKP;
CPPUNIT_ASSERT(rsa->reconstructKeyPair(&dKP, serialisedKP));
CPPUNIT_ASSERT(serialisedKP.size() == 0);
CPPUNIT_ASSERT(dKP != NULL);
RSAPublicKey* pub = (RSAPublicKey*) kp->getPublicKey();
RSAPrivateKey* priv = (RSAPrivateKey*) kp->getPrivateKey();
RSAPublicKey* dPub = (RSAPublicKey*) dKP->getPublicKey();
RSAPrivateKey* dPriv = (RSAPrivateKey*) dKP->getPrivateKey();
CPPUNIT_ASSERT(pub->getN() == dPub->getN());
CPPUNIT_ASSERT(pub->getE() == dPub->getE());
CPPUNIT_ASSERT(priv->getP() == dPriv->getP());
CPPUNIT_ASSERT(priv->getQ() == dPriv->getQ());
CPPUNIT_ASSERT(priv->getPQ() == dPriv->getPQ());
CPPUNIT_ASSERT(priv->getDP1() == dPriv->getDP1());
CPPUNIT_ASSERT(priv->getDQ1() == dPriv->getDQ1());
CPPUNIT_ASSERT(priv->getD() == dPriv->getD());
CPPUNIT_ASSERT(priv->getN() == dPriv->getN());
CPPUNIT_ASSERT(priv->getE() == dPriv->getE());
// Serialise and deserialise the public key
ByteString serialisedPub = pub->serialise();
RSAPublicKey* desPub;
CPPUNIT_ASSERT(rsa->reconstructPublicKey((PublicKey**) &desPub, serialisedPub));
CPPUNIT_ASSERT(serialisedPub.size() == 0);
CPPUNIT_ASSERT(desPub != NULL);
CPPUNIT_ASSERT(pub->getN() == desPub->getN());
CPPUNIT_ASSERT(pub->getE() == desPub->getE());
// Serialise and deserialise the private key
ByteString serialisedPriv = priv->serialise();
RSAPrivateKey* desPriv;
CPPUNIT_ASSERT(rsa->reconstructPrivateKey((PrivateKey**) &desPriv, serialisedPriv));
CPPUNIT_ASSERT(serialisedPriv.size() == 0);
CPPUNIT_ASSERT(desPriv != NULL);
CPPUNIT_ASSERT(priv->getP() == desPriv->getP());
CPPUNIT_ASSERT(priv->getQ() == desPriv->getQ());
CPPUNIT_ASSERT(priv->getPQ() == desPriv->getPQ());
CPPUNIT_ASSERT(priv->getDP1() == desPriv->getDP1());
CPPUNIT_ASSERT(priv->getDQ1() == desPriv->getDQ1());
CPPUNIT_ASSERT(priv->getD() == desPriv->getD());
CPPUNIT_ASSERT(priv->getN() == desPriv->getN());
CPPUNIT_ASSERT(priv->getE() == desPriv->getE());
rsa->recycleKeyPair(kp);
rsa->recycleKeyPair(dKP);
rsa->recyclePublicKey(desPub);
rsa->recyclePrivateKey(desPriv);
}
