Modified source engine (2017) developed by valve and leaked in 2020. Not for commercial purporses
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// bench3.cpp - originally written and placed in the public domain by Wei Dai
// CryptoPP::Test namespace added by JW in February 2017
#include "cryptlib.h"
#include "bench.h"
#include "validate.h"
#include "cpu.h"
#include "factory.h"
#include "algparam.h"
#include "argnames.h"
#include "smartptr.h"
#include "stdcpp.h"
#include "pubkey.h"
#include "gfpcrypt.h"
#include "eccrypto.h"
#include "pkcspad.h"
#include "files.h"
#include "filters.h"
#include "hex.h"
#include "rsa.h"
#include "nr.h"
#include "dsa.h"
#include "luc.h"
#include "rw.h"
#include "ecp.h"
#include "ec2n.h"
#include "asn.h"
#include "dh.h"
#include "mqv.h"
#include "hmqv.h"
#include "fhmqv.h"
#include "xed25519.h"
#include "xtrcrypt.h"
#include "esign.h"
#include "pssr.h"
#include "oids.h"
#include "randpool.h"
#include "stdcpp.h"
#include "hrtimer.h"
#if CRYPTOPP_MSC_VERSION
# pragma warning(disable: 4505 4355)
#endif
NAMESPACE_BEGIN(CryptoPP)
NAMESPACE_BEGIN(Test)
void BenchMarkEncryption(const char *name, PK_Encryptor &key, double timeTotal, bool pc = false)
{
unsigned int len = 16;
SecByteBlock plaintext(len), ciphertext(key.CiphertextLength(len));
Test::GlobalRNG().GenerateBlock(plaintext, len);
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
key.Encrypt(Test::GlobalRNG(), plaintext, len, ciphertext);
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = key.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Encryption", pc, i, timeTaken);
if (!pc && key.GetMaterial().SupportsPrecomputation())
{
key.AccessMaterial().Precompute(16);
BenchMarkEncryption(name, key, timeTotal, true);
}
}
void BenchMarkDecryption(const char *name, PK_Decryptor &priv, PK_Encryptor &pub, double timeTotal)
{
unsigned int len = 16;
SecByteBlock ciphertext(pub.CiphertextLength(len));
SecByteBlock plaintext(pub.MaxPlaintextLength(ciphertext.size()));
Test::GlobalRNG().GenerateBlock(plaintext, len);
pub.Encrypt(Test::GlobalRNG(), plaintext, len, ciphertext);
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
priv.Decrypt(Test::GlobalRNG(), ciphertext, ciphertext.size(), plaintext);
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = priv.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Decryption", false, i, timeTaken);
}
void BenchMarkSigning(const char *name, PK_Signer &key, double timeTotal, bool pc=false)
{
unsigned int len = 16;
AlignedSecByteBlock message(len), signature(key.SignatureLength());
Test::GlobalRNG().GenerateBlock(message, len);
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
(void)key.SignMessage(Test::GlobalRNG(), message, len, signature);
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = key.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Signature", pc, i, timeTaken);
if (!pc && key.GetMaterial().SupportsPrecomputation())
{
key.AccessMaterial().Precompute(16);
BenchMarkSigning(name, key, timeTotal, true);
}
}
void BenchMarkVerification(const char *name, const PK_Signer &priv, PK_Verifier &pub, double timeTotal, bool pc=false)
{
unsigned int len = 16;
AlignedSecByteBlock message(len), signature(pub.SignatureLength());
Test::GlobalRNG().GenerateBlock(message, len);
priv.SignMessage(Test::GlobalRNG(), message, len, signature);
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
(void)pub.VerifyMessage(message, len, signature, signature.size());
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = pub.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Verification", pc, i, timeTaken);
if (!pc && pub.GetMaterial().SupportsPrecomputation())
{
pub.AccessMaterial().Precompute(16);
BenchMarkVerification(name, priv, pub, timeTotal, true);
}
}
void BenchMarkKeyGen(const char *name, SimpleKeyAgreementDomain &d, double timeTotal, bool pc=false)
{
SecByteBlock priv(d.PrivateKeyLength()), pub(d.PublicKeyLength());
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
d.GenerateKeyPair(Test::GlobalRNG(), priv, pub);
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = d.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Key-Pair Generation", pc, i, timeTaken);
if (!pc && d.GetMaterial().SupportsPrecomputation())
{
d.AccessMaterial().Precompute(16);
BenchMarkKeyGen(name, d, timeTotal, true);
}
}
void BenchMarkKeyGen(const char *name, AuthenticatedKeyAgreementDomain &d, double timeTotal, bool pc=false)
{
SecByteBlock priv(d.EphemeralPrivateKeyLength()), pub(d.EphemeralPublicKeyLength());
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
d.GenerateEphemeralKeyPair(Test::GlobalRNG(), priv, pub);
++i; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = d.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Key-Pair Generation", pc, i, timeTaken);
if (!pc && d.GetMaterial().SupportsPrecomputation())
{
d.AccessMaterial().Precompute(16);
BenchMarkKeyGen(name, d, timeTotal, true);
}
}
void BenchMarkAgreement(const char *name, SimpleKeyAgreementDomain &d, double timeTotal, bool pc=false)
{
SecByteBlock priv1(d.PrivateKeyLength()), priv2(d.PrivateKeyLength());
SecByteBlock pub1(d.PublicKeyLength()), pub2(d.PublicKeyLength());
d.GenerateKeyPair(Test::GlobalRNG(), priv1, pub1);
d.GenerateKeyPair(Test::GlobalRNG(), priv2, pub2);
SecByteBlock val(d.AgreedValueLength());
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
d.Agree(val, priv1, pub2);
d.Agree(val, priv2, pub1);
i+=2; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = d.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Key Agreement", pc, i, timeTaken);
}
void BenchMarkAgreement(const char *name, AuthenticatedKeyAgreementDomain &d, double timeTotal, bool pc=false)
{
SecByteBlock spriv1(d.StaticPrivateKeyLength()), spriv2(d.StaticPrivateKeyLength());
SecByteBlock epriv1(d.EphemeralPrivateKeyLength()), epriv2(d.EphemeralPrivateKeyLength());
SecByteBlock spub1(d.StaticPublicKeyLength()), spub2(d.StaticPublicKeyLength());
SecByteBlock epub1(d.EphemeralPublicKeyLength()), epub2(d.EphemeralPublicKeyLength());
d.GenerateStaticKeyPair(Test::GlobalRNG(), spriv1, spub1);
d.GenerateStaticKeyPair(Test::GlobalRNG(), spriv2, spub2);
d.GenerateEphemeralKeyPair(Test::GlobalRNG(), epriv1, epub1);
d.GenerateEphemeralKeyPair(Test::GlobalRNG(), epriv2, epub2);
SecByteBlock val(d.AgreedValueLength());
unsigned int i = 0;
double timeTaken;
ThreadUserTimer timer;
timer.StartTimer();
do
{
d.Agree(val, spriv1, epriv1, spub2, epub2);
d.Agree(val, spriv2, epriv2, spub1, epub1);
i+=2; timeTaken = timer.ElapsedTimeAsDouble();
}
while (timeTaken < timeTotal);
std::string provider = d.AlgorithmProvider();
OutputResultOperations(name, provider.c_str(), "Key Agreement", pc, i, timeTaken);
}
template <class SCHEME>
void BenchMarkCrypto(const char *filename, const char *name, double timeTotal)
{
FileSource f(DataDir(filename).c_str(), true, new HexDecoder);
typename SCHEME::Decryptor priv(f);
typename SCHEME::Encryptor pub(priv);
BenchMarkEncryption(name, pub, timeTotal);
BenchMarkDecryption(name, priv, pub, timeTotal);
}
template <class SCHEME>
void BenchMarkSignature(const char *filename, const char *name, double timeTotal)
{
FileSource f(DataDir(filename).c_str(), true, new HexDecoder);
typename SCHEME::Signer priv(f);
typename SCHEME::Verifier pub(priv);
BenchMarkSigning(name, priv, timeTotal);
BenchMarkVerification(name, priv, pub, timeTotal);
}
template <class D>
void BenchMarkKeyAgreement(const char *filename, const char *name, double timeTotal)
{
FileSource f(DataDir(filename).c_str(), true, new HexDecoder);
D d(f);
BenchMarkKeyGen(name, d, timeTotal);
BenchMarkAgreement(name, d, timeTotal);
}
void Benchmark3(double t, double hertz)
{
g_allocatedTime = t;
g_hertz = hertz;
const char *mco;
if (g_hertz > 1.0f)
mco = "<TH>Megacycles/Operation";
else
mco = "";
std::cout << "\n<TABLE>";
std::cout << "\n<COLGROUP><COL style=\"text-align: left;\"><COL style=";
std::cout << "\"text-align: right;\"><COL style=\"text-align: right;\">";
std::cout << "\n<THEAD style=\"background: #F0F0F0\">";
std::cout << "\n<TR><TH>Operation<TH>Milliseconds/Operation" << mco;
std::cout << "\n<TBODY style=\"background: white;\">";
{
BenchMarkCrypto<RSAES<OAEP<SHA1> > >("TestData/rsa1024.dat", "RSA 1024", t);
BenchMarkCrypto<LUCES<OAEP<SHA1> > >("TestData/luc1024.dat", "LUC 1024", t);
BenchMarkCrypto<DLIES<> >("TestData/dlie1024.dat", "DLIES 1024", t);
BenchMarkCrypto<LUC_IES<> >("TestData/lucc512.dat", "LUCELG 512", t);
}
std::cout << "\n<TBODY style=\"background: yellow;\">";
{
BenchMarkCrypto<RSAES<OAEP<SHA1> > >("TestData/rsa2048.dat", "RSA 2048", t);
BenchMarkCrypto<LUCES<OAEP<SHA1> > >("TestData/luc2048.dat", "LUC 2048", t);
BenchMarkCrypto<DLIES<> >("TestData/dlie2048.dat", "DLIES 2048", t);
BenchMarkCrypto<LUC_IES<> >("TestData/lucc1024.dat", "LUCELG 1024", t);
}
std::cout << "\n<TBODY style=\"background: white;\">";
{
BenchMarkSignature<RSASS<PSSR, SHA1> >("TestData/rsa1024.dat", "RSA 1024", t);
BenchMarkSignature<RWSS<PSSR, SHA1> >("TestData/rw1024.dat", "RW 1024", t);
BenchMarkSignature<LUCSS<PSSR, SHA1> >("TestData/luc1024.dat", "LUC 1024", t);
BenchMarkSignature<NR<SHA1> >("TestData/nr1024.dat", "NR 1024", t);
BenchMarkSignature<DSA>("TestData/dsa1024.dat", "DSA 1024", t);
BenchMarkSignature<LUC_HMP<SHA1> >("TestData/lucs512.dat", "LUC-HMP 512", t);
BenchMarkSignature<ESIGN<SHA1> >("TestData/esig1023.dat", "ESIGN 1023", t);
BenchMarkSignature<ESIGN<SHA1> >("TestData/esig1536.dat", "ESIGN 1536", t);
}
std::cout << "\n<TBODY style=\"background: yellow;\">";
{
BenchMarkSignature<RSASS<PSSR, SHA1> >("TestData/rsa2048.dat", "RSA 2048", t);
BenchMarkSignature<RWSS<PSSR, SHA1> >("TestData/rw2048.dat", "RW 2048", t);
BenchMarkSignature<LUCSS<PSSR, SHA1> >("TestData/luc2048.dat", "LUC 2048", t);
BenchMarkSignature<NR<SHA1> >("TestData/nr2048.dat", "NR 2048", t);
BenchMarkSignature<LUC_HMP<SHA1> >("TestData/lucs1024.dat", "LUC-HMP 1024", t);
BenchMarkSignature<ESIGN<SHA1> >("TestData/esig2046.dat", "ESIGN 2046", t);
}
std::cout << "\n<TBODY style=\"background: white;\">";
{
BenchMarkKeyAgreement<XTR_DH>("TestData/xtrdh171.dat", "XTR-DH 171", t);
BenchMarkKeyAgreement<XTR_DH>("TestData/xtrdh342.dat", "XTR-DH 342", t);
BenchMarkKeyAgreement<DH>("TestData/dh1024.dat", "DH 1024", t);
BenchMarkKeyAgreement<DH>("TestData/dh2048.dat", "DH 2048", t);
BenchMarkKeyAgreement<LUC_DH>("TestData/lucd512.dat", "LUCDIF 512", t);
BenchMarkKeyAgreement<LUC_DH>("TestData/lucd1024.dat", "LUCDIF 1024", t);
BenchMarkKeyAgreement<MQV>("TestData/mqv1024.dat", "MQV 1024", t);
BenchMarkKeyAgreement<MQV>("TestData/mqv2048.dat", "MQV 2048", t);
}
std::cout << "\n</TABLE>" << std::endl;
}
void Benchmark4(double t, double hertz)
{
g_allocatedTime = t;
g_hertz = hertz;
const char *mco;
if (g_hertz > 1.0f)
mco = "<TH>Megacycles/Operation";
else
mco = "";
std::cout << "\n<TABLE>";
std::cout << "\n<COLGROUP><COL style=\"text-align: left;\"><COL style=";
std::cout << "\"text-align: right;\"><COL style=\"text-align: right;\">";
std::cout << "\n<THEAD style=\"background: #F0F0F0\">";
std::cout << "\n<TR><TH>Operation<TH>Milliseconds/Operation" << mco;
std::cout << "\n<TBODY style=\"background: white;\">";
{
ed25519::Signer sign(Test::GlobalRNG());
ed25519::Verifier verify(sign);
x25519 agree(Test::GlobalRNG());
BenchMarkSigning("ed25519", sign, t);
BenchMarkVerification("ed25519", sign, verify, t);
BenchMarkKeyGen("x25519", agree, t);
BenchMarkAgreement("x25519", agree, t);
}
#if 0
std::cout << "\n<TBODY style=\"background: yellow;\">";
{
BenchMarkKeyAgreement<ECMQV160>("TestData/mqv160.dat", "MQV P-160", t);
BenchMarkKeyAgreement<ECMQV256>("TestData/mqv256.dat", "MQV P-256", t);
BenchMarkKeyAgreement<ECMQV384>("TestData/mqv384.dat", "MQV P-384", t);
BenchMarkKeyAgreement<ECMQV512>("TestData/mqv512.dat", "MQV P-521", t);
BenchMarkKeyAgreement<ECHMQV160>("TestData/hmqv160.dat", "HMQV P-160", t);
BenchMarkKeyAgreement<ECHMQV256>("TestData/hmqv256.dat", "HMQV P-256", t);
BenchMarkKeyAgreement<ECHMQV384>("TestData/hmqv384.dat", "HMQV P-384", t);
BenchMarkKeyAgreement<ECHMQV512>("TestData/hmqv512.dat", "HMQV P-521", t);
BenchMarkKeyAgreement<ECFHMQV160>("TestData/fhmqv160.dat", "FHMQV P-160", t);
BenchMarkKeyAgreement<ECFHMQV256>("TestData/fhmqv256.dat", "FHMQV P-256", t);
BenchMarkKeyAgreement<ECFHMQV384>("TestData/fhmqv384.dat", "FHMQV P-384", t);
BenchMarkKeyAgreement<ECFHMQV512>("TestData/fhmqv512.dat", "FHMQV P-521", t);
}
#endif
std::cout << "\n<TBODY style=\"background: yellow;\">";
{
ECIES<ECP>::Decryptor cpriv(Test::GlobalRNG(), ASN1::secp256k1());
ECIES<ECP>::Encryptor cpub(cpriv);
ECDSA<ECP, SHA1>::Signer spriv(cpriv);
ECDSA<ECP, SHA1>::Verifier spub(spriv);
ECDSA_RFC6979<ECP, SHA1>::Signer spriv2(cpriv);
ECDSA_RFC6979<ECP, SHA1>::Verifier spub2(spriv);
ECGDSA<ECP, SHA1>::Signer spriv3(Test::GlobalRNG(), ASN1::secp256k1());
ECGDSA<ECP, SHA1>::Verifier spub3(spriv3);
ECDH<ECP>::Domain ecdhc(ASN1::secp256k1());
ECMQV<ECP>::Domain ecmqvc(ASN1::secp256k1());
BenchMarkEncryption("ECIES over GF(p) 256", cpub, t);
BenchMarkDecryption("ECIES over GF(p) 256", cpriv, cpub, t);
BenchMarkSigning("ECDSA over GF(p) 256", spriv, t);
BenchMarkVerification("ECDSA over GF(p) 256", spriv, spub, t);
BenchMarkSigning("ECDSA-RFC6979 over GF(p) 256", spriv2, t);
BenchMarkVerification("ECDSA-RFC6979 over GF(p) 256", spriv2, spub2, t);
BenchMarkSigning("ECGDSA over GF(p) 256", spriv3, t);
BenchMarkVerification("ECGDSA over GF(p) 256", spriv3, spub3, t);
BenchMarkKeyGen("ECDHC over GF(p) 256", ecdhc, t);
BenchMarkAgreement("ECDHC over GF(p) 256", ecdhc, t);
BenchMarkKeyGen("ECMQVC over GF(p) 256", ecmqvc, t);
BenchMarkAgreement("ECMQVC over GF(p) 256", ecmqvc, t);
}
std::cout << "\n<TBODY style=\"background: white;\">";
{
ECIES<EC2N>::Decryptor cpriv(Test::GlobalRNG(), ASN1::sect233r1());
ECIES<EC2N>::Encryptor cpub(cpriv);
ECDSA<EC2N, SHA1>::Signer spriv(cpriv);
ECDSA<EC2N, SHA1>::Verifier spub(spriv);
ECDSA_RFC6979<EC2N, SHA1>::Signer spriv2(cpriv);
ECDSA_RFC6979<EC2N, SHA1>::Verifier spub2(spriv);
ECGDSA<EC2N, SHA1>::Signer spriv3(Test::GlobalRNG(), ASN1::sect233r1());
ECGDSA<EC2N, SHA1>::Verifier spub3(spriv3);
ECDH<EC2N>::Domain ecdhc(ASN1::sect233r1());
ECMQV<EC2N>::Domain ecmqvc(ASN1::sect233r1());
BenchMarkEncryption("ECIES over GF(2^n) 233", cpub, t);
BenchMarkDecryption("ECIES over GF(2^n) 233", cpriv, cpub, t);
BenchMarkSigning("ECDSA over GF(2^n) 233", spriv, t);
BenchMarkVerification("ECDSA over GF(2^n) 233", spriv, spub, t);
BenchMarkSigning("ECDSA-RFC6979 over GF(2^n) 233", spriv2, t);
BenchMarkVerification("ECDSA-RFC6979 over GF(2^n) 233", spriv2, spub2, t);
BenchMarkSigning("ECGDSA over GF(2^n) 233", spriv3, t);
BenchMarkVerification("ECGDSA over GF(2^n) 233", spriv3, spub3, t);
BenchMarkKeyGen("ECDHC over GF(2^n) 233", ecdhc, t);
BenchMarkAgreement("ECDHC over GF(2^n) 233", ecdhc, t);
BenchMarkKeyGen("ECMQVC over GF(2^n) 233", ecmqvc, t);
BenchMarkAgreement("ECMQVC over GF(2^n) 233", ecmqvc, t);
}
std::cout << "\n</TABLE>" << std::endl;
}
NAMESPACE_END // Test
NAMESPACE_END // CryptoPP