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|
/*
* Copyright (c) 2010 SURFnet bv
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
* GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
* IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*****************************************************************************
RSATests.cpp
Contains test cases to test the RNG class
*****************************************************************************/
#include <stdlib.h>
#include <vector>
#include <cppunit/extensions/HelperMacros.h>
#include "RSATests.h"
#include "CryptoFactory.h"
#include "RNG.h"
#include "AsymmetricKeyPair.h"
#include "AsymmetricAlgorithm.h"
#include "RSAParameters.h"
#include "RSAPublicKey.h"
#include "RSAPrivateKey.h"
CPPUNIT_TEST_SUITE_REGISTRATION(RSATests);
void RSATests::setUp()
{
rsa = NULL;
rsa = CryptoFactory::i()->getAsymmetricAlgorithm(AsymAlgo::RSA);
// Check the RSA object
CPPUNIT_ASSERT(rsa != NULL);
}
void RSATests::tearDown()
{
if (rsa != NULL)
{
CryptoFactory::i()->recycleAsymmetricAlgorithm(rsa);
}
fflush(stdout);
}
void RSATests::testKeyGeneration()
{
AsymmetricKeyPair* kp;
RSAParameters p;
// Public exponents to test
std::vector<ByteString> exponents;
exponents.push_back("010001");
exponents.push_back("03");
exponents.push_back("0B");
exponents.push_back("11");
// Key sizes to test
std::vector<size_t> keySizes;
keySizes.push_back(1024);
#ifndef WITH_FIPS
keySizes.push_back(1025);
#endif
keySizes.push_back(1280);
keySizes.push_back(2048);
//keySizes.push_back(4096);
for (std::vector<ByteString>::iterator e = exponents.begin(); e != exponents.end(); e++)
{
for (std::vector<size_t>::iterator k = keySizes.begin(); k != keySizes.end(); k++)
{
p.setE(*e);
p.setBitLength(*k);
// Generate key-pair
CPPUNIT_ASSERT(rsa->generateKeyPair(&kp, &p));
RSAPublicKey* pub = (RSAPublicKey*) kp->getPublicKey();
RSAPrivateKey* priv = (RSAPrivateKey*) kp->getPrivateKey();
CPPUNIT_ASSERT(pub->getBitLength() == *k);
CPPUNIT_ASSERT(priv->getBitLength() == *k);
CPPUNIT_ASSERT(pub->getE() == *e);
CPPUNIT_ASSERT(priv->getE() == *e);
rsa->recycleKeyPair(kp);
}
}
}
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);
}
void RSATests::testPKCS8()
{
// 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);
RSAPrivateKey* priv = (RSAPrivateKey*) kp->getPrivateKey();
CPPUNIT_ASSERT(priv != NULL);
// Encode and decode the private key
ByteString pkcs8 = priv->PKCS8Encode();
CPPUNIT_ASSERT(pkcs8.size() != 0);
RSAPrivateKey* dPriv = (RSAPrivateKey*) rsa->newPrivateKey();
CPPUNIT_ASSERT(dPriv != NULL);
CPPUNIT_ASSERT(dPriv->PKCS8Decode(pkcs8));
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());
rsa->recycleKeyPair(kp);
rsa->recyclePrivateKey(dPriv);
}
void RSATests::testSigningVerifying()
{
AsymmetricKeyPair* kp;
RSAParameters p;
// Public exponents to test
std::vector<ByteString> exponents;
exponents.push_back("010001");
exponents.push_back("03");
exponents.push_back("0B");
exponents.push_back("11");
// Key sizes to test
std::vector<size_t> keySizes;
keySizes.push_back(1024);
keySizes.push_back(1280);
keySizes.push_back(2048);
//keySizes.push_back(4096);
// Mechanisms to test
std::vector<AsymMech::Type> mechanisms;
#ifndef WITH_FIPS
mechanisms.push_back(AsymMech::RSA_MD5_PKCS);
#endif
mechanisms.push_back(AsymMech::RSA_SHA1_PKCS);
mechanisms.push_back(AsymMech::RSA_SHA224_PKCS);
mechanisms.push_back(AsymMech::RSA_SHA256_PKCS);
mechanisms.push_back(AsymMech::RSA_SHA384_PKCS);
mechanisms.push_back(AsymMech::RSA_SHA512_PKCS);
mechanisms.push_back(AsymMech::RSA_SHA1_PKCS_PSS);
mechanisms.push_back(AsymMech::RSA_SHA224_PKCS_PSS);
mechanisms.push_back(AsymMech::RSA_SHA256_PKCS_PSS);
mechanisms.push_back(AsymMech::RSA_SHA384_PKCS_PSS);
mechanisms.push_back(AsymMech::RSA_SHA512_PKCS_PSS);
#ifndef WITH_FIPS
mechanisms.push_back(AsymMech::RSA_SSL);
#endif
/* Max salt length for SHA512 and 1024-bit RSA is 62 bytes */
RSA_PKCS_PSS_PARAMS pssParams[] = {
{ HashAlgo::SHA1, AsymRSAMGF::MGF1_SHA1, 20 },
{ HashAlgo::SHA224, AsymRSAMGF::MGF1_SHA224, 0 },
{ HashAlgo::SHA256, AsymRSAMGF::MGF1_SHA256, 0 },
{ HashAlgo::SHA384, AsymRSAMGF::MGF1_SHA384, 48 },
{ HashAlgo::SHA512, AsymRSAMGF::MGF1_SHA512, 62 }
};
for (std::vector<ByteString>::iterator e = exponents.begin(); e != exponents.end(); e++)
{
for (std::vector<size_t>::iterator k = keySizes.begin(); k != keySizes.end(); k++)
{
p.setE(*e);
p.setBitLength(*k);
// Generate key-pair
CPPUNIT_ASSERT(rsa->generateKeyPair(&kp, &p));
// Generate some data to sign
ByteString dataToSign;
RNG* rng = CryptoFactory::i()->getRNG();
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 567));
// Test mechanisms that perform internal hashing
for (std::vector<AsymMech::Type>::iterator m = mechanisms.begin(); m != mechanisms.end(); m++)
{
ByteString blockSignature, singlePartSignature;
void* param = NULL;
size_t paramLen = 0;
bool isPSS = false;
switch (*m)
{
case AsymMech::RSA_SHA1_PKCS_PSS:
param = &pssParams[0];
paramLen = sizeof(pssParams[0]);
isPSS = true;
break;
case AsymMech::RSA_SHA224_PKCS_PSS:
param = &pssParams[1];
paramLen = sizeof(pssParams[1]);
isPSS = true;
break;
case AsymMech::RSA_SHA256_PKCS_PSS:
param = &pssParams[2];
paramLen = sizeof(pssParams[2]);
isPSS = true;
break;
case AsymMech::RSA_SHA384_PKCS_PSS:
param = &pssParams[3];
paramLen = sizeof(pssParams[3]);
isPSS = true;
break;
case AsymMech::RSA_SHA512_PKCS_PSS:
param = &pssParams[4];
paramLen = sizeof(pssParams[4]);
isPSS = true;
break;
default:
break;
}
// Sign the data in blocks
CPPUNIT_ASSERT(rsa->signInit(kp->getPrivateKey(), *m, param, paramLen));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign.substr(0, 134)));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign.substr(134, 289)));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign.substr(134 + 289)));
CPPUNIT_ASSERT(rsa->signFinal(blockSignature));
// Sign the data in one pass
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, singlePartSignature, *m, param, paramLen));
// If it is not a PSS signature, check if the two signatures match
if (!isPSS)
{
// Check if the two signatures match
CPPUNIT_ASSERT(blockSignature == singlePartSignature);
}
// Now perform multi-pass verification
CPPUNIT_ASSERT(rsa->verifyInit(kp->getPublicKey(), *m, param, paramLen));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign.substr(0, 125)));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign.substr(125, 247)));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign.substr(125 + 247)));
CPPUNIT_ASSERT(rsa->verifyFinal(blockSignature));
// And single-pass verification
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, singlePartSignature, *m, param, paramLen));
}
// Test mechanisms that do not perform internal hashing
// Test PKCS #1 signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 35));
// Sign the data
ByteString signature;
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS));
// Verify the signature
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS));
// Test raw RSA signing
size_t byteSize = *k >> 3;
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, byteSize));
// Strip the topmost bit
dataToSign[0] &= 0x7F;
// Sign the data
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA));
// Verify the signature
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA));
#ifdef WITH_RAW_PSS
// Test raw (SHA1) PKCS PSS signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 20));
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[0], sizeof(pssParams[0])));
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[0], sizeof(pssParams[0])));
// Test raw (SHA224) PKCS PSS signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 28));
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[1], sizeof(pssParams[1])));
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[1], sizeof(pssParams[1])));
// Test raw (SHA256) PKCS PSS signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 32));
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[2], sizeof(pssParams[2])));
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[2], sizeof(pssParams[2])));
// Test raw (SHA384) PKCS PSS signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 48));
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[3], sizeof(pssParams[3])));
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[3], sizeof(pssParams[3])));
// Test raw (SHA512) PKCS PSS signing
CPPUNIT_ASSERT(rng->generateRandom(dataToSign, 64));
CPPUNIT_ASSERT(rsa->sign(kp->getPrivateKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[4], sizeof(pssParams[4])));
CPPUNIT_ASSERT(rsa->verify(kp->getPublicKey(), dataToSign, signature, AsymMech::RSA_PKCS_PSS, &pssParams[4], sizeof(pssParams[4])));
#endif
rsa->recycleKeyPair(kp);
}
}
}
void RSATests::testSignVerifyKnownVector()
{
// These test vectors were taken from the Crypto++ set of test vectors
// Crypto++ can be downloaded from www.cryptopp.com
#ifndef WITH_FIPS
RSAPublicKey* pubKey1 = (RSAPublicKey*) rsa->newPublicKey();
RSAPublicKey* pubKey2 = (RSAPublicKey*) rsa->newPublicKey();
#endif
RSAPublicKey* pubKey3 = (RSAPublicKey*) rsa->newPublicKey();
#ifndef WITH_FIPS
RSAPrivateKey* privKey1_1 = (RSAPrivateKey*) rsa->newPrivateKey();
RSAPrivateKey* privKey1_2 = (RSAPrivateKey*) rsa->newPrivateKey();
RSAPrivateKey* privKey2_1 = (RSAPrivateKey*) rsa->newPrivateKey();
RSAPrivateKey* privKey2_2 = (RSAPrivateKey*) rsa->newPrivateKey();
#endif
RSAPrivateKey* privKey3 = (RSAPrivateKey*) rsa->newPrivateKey();
#ifndef WITH_FIPS
// Reconstruct public and private key #1
ByteString n1 = "0A66791DC6988168DE7AB77419BB7FB0C001C62710270075142942E19A8D8C51D053B3E3782A1DE5DC5AF4EBE99468170114A1DFE67CDC9A9AF55D655620BBAB";
ByteString e1 = "010001";
ByteString d1 = "0123C5B61BA36EDB1D3679904199A89EA80C09B9122E1400C09ADCF7784676D01D23356A7D44D6BD8BD50E94BFC723FA87D8862B75177691C11D757692DF8881";
ByteString p1 = "33D48445C859E52340DE704BCDDA065FBB4058D740BD1D67D29E9C146C11CF61";
ByteString q1 = "335E8408866B0FD38DC7002D3F972C67389A65D5D8306566D5C4F2A5AA52628B";
ByteString dp11 = "045EC90071525325D3D46DB79695E9AFACC4523964360E02B119BAA366316241";
ByteString dq11 = "15EB327360C7B60D12E5E2D16BDCD97981D17FBA6B70DB13B20B436E24EADA59";
ByteString pq1 = "2CA6366D72781DFA24D34A9A24CBC2AE927A9958AF426563FF63FB11658A461D";
pubKey1->setN(n1);
pubKey1->setE(e1);
privKey1_1->setN(n1);
privKey1_1->setE(e1);
privKey1_1->setD(d1);
privKey1_1->setP(p1);
privKey1_1->setQ(q1);
privKey1_1->setDP1(dp11);
privKey1_1->setDQ1(dq11);
privKey1_1->setPQ(pq1);
// The same key but without CRT factors
privKey1_2->setN(n1);
privKey1_2->setE(e1);
privKey1_2->setD(d1);
// Reconstruct public and private key #2
ByteString n2 = "A885B6F851A8079AB8A281DB0297148511EE0D8C07C0D4AE6D6FED461488E0D41E3FF8F281B06A3240B5007A5C2AB4FB6BE8AF88F119DB998368DDDC9710ABED";
ByteString e2 = "010001";
ByteString d2 = "2B259D2CA3DF851EE891F6F4678BDDFD9A131C95D3305C63D2723B4A5B9C960F5EC8BB7DCDDBEBD8B6A38767D64AD451E9383E0891E4EE7506100481F2B49323";
ByteString p2 = "D7103CD676E39824E2BE50B8E6533FE7CB7484348E283802AD2B8D00C80D19DF";
ByteString q2 = "C89996DC169CEB3F227958275968804D4BE9FC4012C3219662F1A438C9950BB3";
ByteString dp12 = "5D8EA4C8AF83A70634D5920C3DB66D908AC3AF57A597FD75BC9BBB856181C185";
ByteString dq12 = "C598E54DAEC8ABC1E907769A6C2BD01653ED0C9960E1EDB7E186FDA922883A99";
ByteString pq2 = "7C6F27B5B51B78AD80FB36E700990CF307866F2943124CBD93D97C137794C104";
pubKey2->setN(n2);
pubKey2->setE(e2);
privKey2_1->setN(n2);
privKey2_1->setE(e2);
privKey2_1->setD(d2);
privKey2_1->setP(p2);
privKey2_1->setQ(q2);
privKey2_1->setDP1(dp12);
privKey2_1->setDQ1(dq12);
privKey2_1->setPQ(pq2);
// The same key but without CRT factors
privKey2_2->setN(n2);
privKey2_2->setE(e2);
privKey2_2->setD(d2);
#endif
ByteString n3 = "A8D68ACD413C5E195D5EF04E1B4FAAF242365CB450196755E92E1215BA59802AAFBADBF2564DD550956ABB54F8B1C917844E5F36195D1088C600E07CADA5C080EDE679F50B3DE32CF4026E514542495C54B1903768791AAE9E36F082CD38E941ADA89BAECADA61AB0DD37AD536BCB0A0946271594836E92AB5517301D45176B5";
ByteString e3 = "03";
ByteString d3 = "1C23C1CCE034BA598F8FD2B7AF37F1D30B090F7362AEE68E5187ADAE49B9955C729F24A863B7A38D6E3C748E2972F6D940B7BA89043A2D6C2100256A1CF0F56A8CD35FC6EE205244876642F6F9C3820A3D9D2C8921DF7D82AAADCAF2D7334D398931DDBBA553190B3A416099F3AA07FD5B26214645A828419E122CFB857AD73B";
ByteString p3 = "C107a2fe924b76e206cb9bc4af2ab7008547c00846bf6d0680b3eac3ebcbd0c7fd7a54c2b9899b08f80cde1d3691eaaa2816b1eb11822d6be7beaf4e30977c49";
ByteString q3 = "DFEA984CE4307EAFC0D140C2BB82861E5DBAC4F8567CBC981D70440DD639492079031486315E305EB83E591C4A2E96064966F7C894C3CA351925B5CE82D8EF0D";
pubKey3->setN(n3);
pubKey3->setE(e3);
privKey3->setN(n3);
privKey3->setE(e3);
privKey3->setD(d3);
privKey3->setP(p3);
privKey3->setQ(q3);
#ifndef WITH_FIPS
// Test with key #1
const char* testValue1 = "Everyone gets Friday off.";
ByteString dataToSign1((const unsigned char*) testValue1, strlen(testValue1));
ByteString expectedSignature1 = "0610761F95FFD1B8F29DA34212947EC2AA0E358866A722F03CC3C41487ADC604A48FF54F5C6BEDB9FB7BD59F82D6E55D8F3174BA361B2214B2D74E8825E04E81";
ByteString signature1_1;
ByteString signature1_2;
CPPUNIT_ASSERT(rsa->signInit(privKey1_1, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign1));
CPPUNIT_ASSERT(rsa->signFinal(signature1_1));
#ifndef WITH_BOTAN
CPPUNIT_ASSERT(rsa->signInit(privKey1_2, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign1));
CPPUNIT_ASSERT(rsa->signFinal(signature1_2));
CPPUNIT_ASSERT(signature1_1 == signature1_2);
#endif
CPPUNIT_ASSERT(signature1_1 == expectedSignature1);
CPPUNIT_ASSERT(rsa->verifyInit(pubKey1, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign1));
CPPUNIT_ASSERT(rsa->verifyFinal(expectedSignature1));
// Test with key #2
const char* testValue2 = "test";
ByteString dataToSign2((const unsigned char*) testValue2, strlen(testValue2));
ByteString expectedSignature2 = "A7E00CE4391F914D82158D9B732759808E25A1C6383FE87A5199157650D4296CF612E9FF809E686A0AF328238306E79965F6D0138138829D9A1A22764306F6CE";
ByteString signature2_1;
ByteString signature2_2;
CPPUNIT_ASSERT(rsa->signInit(privKey2_1, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign2));
CPPUNIT_ASSERT(rsa->signFinal(signature2_1));
#ifndef WITH_BOTAN
CPPUNIT_ASSERT(rsa->signInit(privKey2_2, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign2));
CPPUNIT_ASSERT(rsa->signFinal(signature2_2));
CPPUNIT_ASSERT(signature2_1 == signature2_2);
#endif
CPPUNIT_ASSERT(signature2_1 == expectedSignature2);
CPPUNIT_ASSERT(rsa->verifyInit(pubKey2, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign2));
CPPUNIT_ASSERT(rsa->verifyFinal(expectedSignature2));
#endif
// Test with key #3
ByteString dataToSign3 = "D73829497CDDBE41B705FAAC50E7899FDB5A38BF3A459E536357029E64F8796BA47F4FE96BA5A8B9A4396746E2164F55A25368DDD0B9A5188C7AC3DA2D1F742286C3BDEE697F9D546A25EFCFE53191D743FCC6B47833D993D08804DAECA78FB9076C3C017F53E33A90305AF06220974D46BF19ED3C9B84EDBAE98B45A8771258";
ByteString expectedSignature3 = "175015BDA50ABE0FA7D39A8353885CA01BE3A7E7FCC55045744111362EE1914473A48DC537D956294B9E20A1EF661D58537ACDC8DE908FA050630FCC272E6D001045E6FDEED2D10531C8603334C2E8DB39E73E6D9665EE1343F9E4198302D2201B44E8E8D06B3EF49CEE6197582163A8490089CA654C0012FCE1BA6511089750";
ByteString signature3;
CPPUNIT_ASSERT(rsa->signInit(privKey3, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->signUpdate(dataToSign3));
CPPUNIT_ASSERT(rsa->signFinal(signature3));
CPPUNIT_ASSERT(signature3 == expectedSignature3);
CPPUNIT_ASSERT(rsa->verifyInit(pubKey3, AsymMech::RSA_SHA1_PKCS));
CPPUNIT_ASSERT(rsa->verifyUpdate(dataToSign3));
CPPUNIT_ASSERT(rsa->verifyFinal(expectedSignature3));
#ifndef WITH_FIPS
rsa->recyclePublicKey(pubKey1);
rsa->recyclePublicKey(pubKey2);
#endif
rsa->recyclePublicKey(pubKey3);
#ifndef WITH_FIPS
rsa->recyclePrivateKey(privKey1_1);
rsa->recyclePrivateKey(privKey1_2);
rsa->recyclePrivateKey(privKey2_1);
rsa->recyclePrivateKey(privKey2_2);
#endif
rsa->recyclePrivateKey(privKey3);
}
void RSATests::testEncryptDecrypt()
{
AsymmetricKeyPair* kp;
RSAParameters p;
// Public exponents to test
std::vector<ByteString> exponents;
exponents.push_back("010001");
exponents.push_back("03");
exponents.push_back("0B");
exponents.push_back("11");
// Key sizes to test
std::vector<size_t> keySizes;
keySizes.push_back(1024);
keySizes.push_back(1280);
keySizes.push_back(2048);
//keySizes.push_back(4096);
// Paddings to test
std::vector<AsymMech::Type> paddings;
paddings.push_back(AsymMech::RSA_PKCS);
paddings.push_back(AsymMech::RSA_PKCS_OAEP);
paddings.push_back(AsymMech::RSA);
for (std::vector<ByteString>::iterator e = exponents.begin(); e != exponents.end(); e++)
{
for (std::vector<size_t>::iterator k = keySizes.begin(); k != keySizes.end(); k++)
{
p.setE(*e);
p.setBitLength(*k);
// Generate key-pair
CPPUNIT_ASSERT(rsa->generateKeyPair(&kp, &p));
RNG* rng = CryptoFactory::i()->getRNG();
for (std::vector<AsymMech::Type>::iterator pad = paddings.begin(); pad != paddings.end(); pad++)
{
// Generate some test data to encrypt based on the selected padding
ByteString testData;
if (*pad == AsymMech::RSA_PKCS)
{
CPPUNIT_ASSERT(rng->generateRandom(testData, (*k >> 3) - 12));
}
else if (*pad == AsymMech::RSA_PKCS_OAEP)
{
CPPUNIT_ASSERT(rng->generateRandom(testData, (*k >> 3) - 42));
}
else if (*pad == AsymMech::RSA)
{
CPPUNIT_ASSERT(rng->generateRandom(testData, *k >> 3));
testData[0] &= 0x0F;
}
else
{
CPPUNIT_ASSERT(true == false);
}
// Encrypt the data
ByteString encryptedData;
CPPUNIT_ASSERT(rsa->encrypt(kp->getPublicKey(), testData, encryptedData, *pad));
// The encrypted data length should equal the modulus length
CPPUNIT_ASSERT(encryptedData.size() == (*k >> 3));
CPPUNIT_ASSERT(encryptedData != testData);
// Now decrypt the data
ByteString decryptedData;
CPPUNIT_ASSERT(rsa->decrypt(kp->getPrivateKey(), encryptedData, decryptedData, *pad));
// Check that the data was properly decrypted
CPPUNIT_ASSERT(decryptedData == testData);
}
rsa->recycleKeyPair(kp);
}
}
}
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