Team Fortress 2 Source Code as on 22/4/2020
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// fipstest.cpp - written and placed in the public domain by Wei Dai
#include "pch.h"
#ifndef CRYPTOPP_IMPORTS
#define CRYPTOPP_DEFAULT_NO_DLL
#include "dll.h"
#ifdef CRYPTOPP_WIN32_AVAILABLE
#define _WIN32_WINNT 0x0400
#include <windows.h>
#if defined(_MSC_VER) && _MSC_VER >= 1400
#ifdef _M_IX86
#define _CRT_DEBUGGER_HOOK _crt_debugger_hook
#else
#define _CRT_DEBUGGER_HOOK __crt_debugger_hook
#endif
extern "C" {_CRTIMP void __cdecl _CRT_DEBUGGER_HOOK(int);}
#endif
#endif
#include <iostream>
NAMESPACE_BEGIN(CryptoPP)
extern PowerUpSelfTestStatus g_powerUpSelfTestStatus;
SecByteBlock g_actualMac;
unsigned long g_macFileLocation = 0;
// use a random dummy string here, to be searched/replaced later with the real MAC
static const byte s_moduleMac[CryptoPP::HMAC<CryptoPP::SHA1>::DIGESTSIZE] = CRYPTOPP_DUMMY_DLL_MAC;
CRYPTOPP_COMPILE_ASSERT(sizeof(s_moduleMac) == CryptoPP::SHA1::DIGESTSIZE);
#ifdef CRYPTOPP_WIN32_AVAILABLE
static HMODULE s_hModule = NULL;
#endif
const byte * CRYPTOPP_API GetActualMacAndLocation(unsigned int &macSize, unsigned int &fileLocation)
{
macSize = (unsigned int)g_actualMac.size();
fileLocation = g_macFileLocation;
return g_actualMac;
}
void KnownAnswerTest(RandomNumberGenerator &rng, const char *output)
{
EqualityComparisonFilter comparison;
RandomNumberStore(rng, strlen(output)/2).TransferAllTo(comparison, "0");
StringSource(output, true, new HexDecoder(new ChannelSwitch(comparison, "1")));
comparison.ChannelMessageSeriesEnd("0");
comparison.ChannelMessageSeriesEnd("1");
}
template <class CIPHER>
void X917RNG_KnownAnswerTest(
const char *key,
const char *seed,
const char *deterministicTimeVector,
const char *output,
CIPHER *dummy = NULL)
{
#ifdef OS_RNG_AVAILABLE
std::string decodedKey, decodedSeed, decodedDeterministicTimeVector;
StringSource(key, true, new HexDecoder(new StringSink(decodedKey)));
StringSource(seed, true, new HexDecoder(new StringSink(decodedSeed)));
StringSource(deterministicTimeVector, true, new HexDecoder(new StringSink(decodedDeterministicTimeVector)));
AutoSeededX917RNG<CIPHER> rng(false, false);
rng.Reseed((const byte *)decodedKey.data(), decodedKey.size(), (const byte *)decodedSeed.data(), (const byte *)decodedDeterministicTimeVector.data());
KnownAnswerTest(rng, output);
#else
throw 0;
#endif
}
void KnownAnswerTest(StreamTransformation &encryption, StreamTransformation &decryption, const char *plaintext, const char *ciphertext)
{
EqualityComparisonFilter comparison;
StringSource(plaintext, true, new HexDecoder(new StreamTransformationFilter(encryption, new ChannelSwitch(comparison, "0"), StreamTransformationFilter::NO_PADDING)));
StringSource(ciphertext, true, new HexDecoder(new ChannelSwitch(comparison, "1")));
StringSource(ciphertext, true, new HexDecoder(new StreamTransformationFilter(decryption, new ChannelSwitch(comparison, "0"), StreamTransformationFilter::NO_PADDING)));
StringSource(plaintext, true, new HexDecoder(new ChannelSwitch(comparison, "1")));
comparison.ChannelMessageSeriesEnd("0");
comparison.ChannelMessageSeriesEnd("1");
}
template <class CIPHER>
void SymmetricEncryptionKnownAnswerTest(
const char *key,
const char *hexIV,
const char *plaintext,
const char *ecb,
const char *cbc,
const char *cfb,
const char *ofb,
const char *ctr,
CIPHER *dummy = NULL)
{
std::string decodedKey;
StringSource(key, true, new HexDecoder(new StringSink(decodedKey)));
typename CIPHER::Encryption encryption((const byte *)decodedKey.data(), decodedKey.size());
typename CIPHER::Decryption decryption((const byte *)decodedKey.data(), decodedKey.size());
SecByteBlock iv(encryption.BlockSize());
StringSource(hexIV, true, new HexDecoder(new ArraySink(iv, iv.size())));
if (ecb)
KnownAnswerTest(ECB_Mode_ExternalCipher::Encryption(encryption).Ref(), ECB_Mode_ExternalCipher::Decryption(decryption).Ref(), plaintext, ecb);
if (cbc)
KnownAnswerTest(CBC_Mode_ExternalCipher::Encryption(encryption, iv).Ref(), CBC_Mode_ExternalCipher::Decryption(decryption, iv).Ref(), plaintext, cbc);
if (cfb)
KnownAnswerTest(CFB_Mode_ExternalCipher::Encryption(encryption, iv).Ref(), CFB_Mode_ExternalCipher::Decryption(encryption, iv).Ref(), plaintext, cfb);
if (ofb)
KnownAnswerTest(OFB_Mode_ExternalCipher::Encryption(encryption, iv).Ref(), OFB_Mode_ExternalCipher::Decryption(encryption, iv).Ref(), plaintext, ofb);
if (ctr)
KnownAnswerTest(CTR_Mode_ExternalCipher::Encryption(encryption, iv).Ref(), CTR_Mode_ExternalCipher::Decryption(encryption, iv).Ref(), plaintext, ctr);
}
void KnownAnswerTest(HashTransformation &hash, const char *message, const char *digest)
{
EqualityComparisonFilter comparison;
StringSource(digest, true, new HexDecoder(new ChannelSwitch(comparison, "1")));
StringSource(message, true, new HashFilter(hash, new ChannelSwitch(comparison, "0")));
comparison.ChannelMessageSeriesEnd("0");
comparison.ChannelMessageSeriesEnd("1");
}
template <class HASH>
void SecureHashKnownAnswerTest(const char *message, const char *digest, HASH *dummy = NULL)
{
HASH hash;
KnownAnswerTest(hash, message, digest);
}
template <class MAC>
void MAC_KnownAnswerTest(const char *key, const char *message, const char *digest, MAC *dummy = NULL)
{
std::string decodedKey;
StringSource(key, true, new HexDecoder(new StringSink(decodedKey)));
MAC mac((const byte *)decodedKey.data(), decodedKey.size());
KnownAnswerTest(mac, message, digest);
}
template <class SCHEME>
void SignatureKnownAnswerTest(const char *key, const char *message, const char *signature, SCHEME *dummy = NULL)
{
typename SCHEME::Signer signer(StringSource(key, true, new HexDecoder).Ref());
typename SCHEME::Verifier verifier(signer);
RandomPool rng;
EqualityComparisonFilter comparison;
StringSource(message, true, new SignerFilter(rng, signer, new ChannelSwitch(comparison, "0")));
StringSource(signature, true, new HexDecoder(new ChannelSwitch(comparison, "1")));
comparison.ChannelMessageSeriesEnd("0");
comparison.ChannelMessageSeriesEnd("1");
VerifierFilter verifierFilter(verifier, NULL, VerifierFilter::SIGNATURE_AT_BEGIN | VerifierFilter::THROW_EXCEPTION);
StringSource(signature, true, new HexDecoder(new Redirector(verifierFilter, Redirector::DATA_ONLY)));
StringSource(message, true, new Redirector(verifierFilter));
}
void EncryptionPairwiseConsistencyTest(const PK_Encryptor &encryptor, const PK_Decryptor &decryptor)
{
try
{
RandomPool rng;
const char *testMessage ="test message";
std::string ciphertext, decrypted;
StringSource(
testMessage,
true,
new PK_EncryptorFilter(
rng,
encryptor,
new StringSink(ciphertext)));
if (ciphertext == testMessage)
throw 0;
StringSource(
ciphertext,
true,
new PK_DecryptorFilter(
rng,
decryptor,
new StringSink(decrypted)));
if (decrypted != testMessage)
throw 0;
}
catch (...)
{
throw SelfTestFailure(encryptor.AlgorithmName() + ": pairwise consistency test failed");
}
}
void SignaturePairwiseConsistencyTest(const PK_Signer &signer, const PK_Verifier &verifier)
{
try
{
RandomPool rng;
StringSource(
"test message",
true,
new SignerFilter(
rng,
signer,
new VerifierFilter(verifier, NULL, VerifierFilter::THROW_EXCEPTION),
true));
}
catch (...)
{
throw SelfTestFailure(signer.AlgorithmName() + ": pairwise consistency test failed");
}
}
template <class SCHEME>
void SignaturePairwiseConsistencyTest(const char *key, SCHEME *dummy = NULL)
{
typename SCHEME::Signer signer(StringSource(key, true, new HexDecoder).Ref());
typename SCHEME::Verifier verifier(signer);
SignaturePairwiseConsistencyTest(signer, verifier);
}
MessageAuthenticationCode * NewIntegrityCheckingMAC()
{
byte key[] = {0x47, 0x1E, 0x33, 0x96, 0x65, 0xB1, 0x6A, 0xED, 0x0B, 0xF8, 0x6B, 0xFD, 0x01, 0x65, 0x05, 0xCC};
return new HMAC<SHA1>(key, sizeof(key));
}
bool IntegrityCheckModule(const char *moduleFilename, const byte *expectedModuleMac, SecByteBlock *pActualMac, unsigned long *pMacFileLocation)
{
std::auto_ptr<MessageAuthenticationCode> mac(NewIntegrityCheckingMAC());
unsigned int macSize = mac->DigestSize();
SecByteBlock tempMac;
SecByteBlock &actualMac = pActualMac ? *pActualMac : tempMac;
actualMac.resize(macSize);
unsigned long tempLocation;
unsigned long &macFileLocation = pMacFileLocation ? *pMacFileLocation : tempLocation;
macFileLocation = 0;
MeterFilter verifier(new HashFilter(*mac, new ArraySink(actualMac, actualMac.size())));
// MeterFilter verifier(new FileSink("c:\\dt.tmp"));
std::ifstream moduleStream;
#ifdef CRYPTOPP_WIN32_AVAILABLE
HMODULE h;
{
char moduleFilenameBuf[MAX_PATH] = "";
if (moduleFilename == NULL)
{
#if (_MSC_VER >= 1400 && !defined(_STLPORT_VERSION)) // ifstream doesn't support wide filename on other compilers
wchar_t wideModuleFilename[MAX_PATH];
if (GetModuleFileNameW(s_hModule, wideModuleFilename, MAX_PATH) > 0)
{
moduleStream.open(wideModuleFilename, std::ios::in | std::ios::binary);
h = GetModuleHandleW(wideModuleFilename);
}
else
#endif
{
GetModuleFileNameA(s_hModule, moduleFilenameBuf, MAX_PATH);
moduleFilename = moduleFilenameBuf;
}
}
#endif
if (moduleFilename != NULL)
{
moduleStream.open(moduleFilename, std::ios::in | std::ios::binary);
#ifdef CRYPTOPP_WIN32_AVAILABLE
h = GetModuleHandleA(moduleFilename);
moduleFilename = NULL;
}
#endif
}
if (!moduleStream)
{
#ifdef CRYPTOPP_WIN32_AVAILABLE
OutputDebugString("Crypto++ DLL integrity check failed. Cannot open file for reading.");
#endif
return false;
}
FileStore file(moduleStream);
#ifdef CRYPTOPP_WIN32_AVAILABLE
// try to hash from memory first
const byte *memBase = (const byte *)h;
const IMAGE_DOS_HEADER *ph = (IMAGE_DOS_HEADER *)memBase;
const IMAGE_NT_HEADERS *phnt = (IMAGE_NT_HEADERS *)(memBase + ph->e_lfanew);
const IMAGE_SECTION_HEADER *phs = IMAGE_FIRST_SECTION(phnt);
DWORD nSections = phnt->FileHeader.NumberOfSections;
size_t currentFilePos = 0;
size_t checksumPos = (byte *)&phnt->OptionalHeader.CheckSum - memBase;
size_t checksumSize = sizeof(phnt->OptionalHeader.CheckSum);
size_t certificateTableDirectoryPos = (byte *)&phnt->OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_SECURITY] - memBase;
size_t certificateTableDirectorySize = sizeof(phnt->OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_SECURITY]);
size_t certificateTablePos = phnt->OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_SECURITY].VirtualAddress;
size_t certificateTableSize = phnt->OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_SECURITY].Size;
verifier.AddRangeToSkip(0, checksumPos, checksumSize);
verifier.AddRangeToSkip(0, certificateTableDirectoryPos, certificateTableDirectorySize);
verifier.AddRangeToSkip(0, certificateTablePos, certificateTableSize);
while (nSections--)
{
switch (phs->Characteristics)
{
default:
break;
case IMAGE_SCN_CNT_CODE | IMAGE_SCN_MEM_EXECUTE | IMAGE_SCN_MEM_READ:
case IMAGE_SCN_CNT_INITIALIZED_DATA | IMAGE_SCN_MEM_READ:
unsigned int sectionSize = STDMIN(phs->SizeOfRawData, phs->Misc.VirtualSize);
const byte *sectionMemStart = memBase + phs->VirtualAddress;
unsigned int sectionFileStart = phs->PointerToRawData;
size_t subSectionStart = 0, nextSubSectionStart;
do
{
const byte *subSectionMemStart = sectionMemStart + subSectionStart;
size_t subSectionFileStart = sectionFileStart + subSectionStart;
size_t subSectionSize = sectionSize - subSectionStart;
nextSubSectionStart = 0;
unsigned int entriesToReadFromDisk[] = {IMAGE_DIRECTORY_ENTRY_IMPORT, IMAGE_DIRECTORY_ENTRY_IAT};
for (unsigned int i=0; i<sizeof(entriesToReadFromDisk)/sizeof(entriesToReadFromDisk[0]); i++)
{
const IMAGE_DATA_DIRECTORY &entry = phnt->OptionalHeader.DataDirectory[entriesToReadFromDisk[i]];
const byte *entryMemStart = memBase + entry.VirtualAddress;
if (subSectionMemStart <= entryMemStart && entryMemStart < subSectionMemStart + subSectionSize)
{
subSectionSize = entryMemStart - subSectionMemStart;
nextSubSectionStart = entryMemStart - sectionMemStart + entry.Size;
}
}
#if defined(_MSC_VER) && _MSC_VER >= 1400
// first byte of _CRT_DEBUGGER_HOOK gets modified in memory by the debugger invisibly, so read it from file
if (IsDebuggerPresent())
{
if (subSectionMemStart <= (byte *)&_CRT_DEBUGGER_HOOK && (byte *)&_CRT_DEBUGGER_HOOK < subSectionMemStart + subSectionSize)
{
subSectionSize = (byte *)&_CRT_DEBUGGER_HOOK - subSectionMemStart;
nextSubSectionStart = (byte *)&_CRT_DEBUGGER_HOOK - sectionMemStart + 1;
}
}
#endif
if (subSectionMemStart <= expectedModuleMac && expectedModuleMac < subSectionMemStart + subSectionSize)
{
// found stored MAC
macFileLocation = (unsigned long)(subSectionFileStart + (expectedModuleMac - subSectionMemStart));
verifier.AddRangeToSkip(0, macFileLocation, macSize);
}
file.TransferTo(verifier, subSectionFileStart - currentFilePos);
verifier.Put(subSectionMemStart, subSectionSize);
file.Skip(subSectionSize);
currentFilePos = subSectionFileStart + subSectionSize;
subSectionStart = nextSubSectionStart;
} while (nextSubSectionStart != 0);
}
phs++;
}
#endif
file.TransferAllTo(verifier);
#ifdef CRYPTOPP_WIN32_AVAILABLE
// if that fails (could be caused by debug breakpoints or DLL base relocation modifying image in memory),
// hash from disk instead
if (!VerifyBufsEqual(expectedModuleMac, actualMac, macSize))
{
OutputDebugString("In memory integrity check failed. This may be caused by debug breakpoints or DLL relocation.\n");
moduleStream.clear();
moduleStream.seekg(0);
verifier.Initialize(MakeParameters(Name::OutputBuffer(), ByteArrayParameter(actualMac, (unsigned int)actualMac.size())));
// verifier.Initialize(MakeParameters(Name::OutputFileName(), (const char *)"c:\\dt2.tmp"));
verifier.AddRangeToSkip(0, checksumPos, checksumSize);
verifier.AddRangeToSkip(0, certificateTableDirectoryPos, certificateTableDirectorySize);
verifier.AddRangeToSkip(0, certificateTablePos, certificateTableSize);
verifier.AddRangeToSkip(0, macFileLocation, macSize);
FileStore(moduleStream).TransferAllTo(verifier);
}
#endif
if (VerifyBufsEqual(expectedModuleMac, actualMac, macSize))
return true;
#ifdef CRYPTOPP_WIN32_AVAILABLE
std::string hexMac;
HexEncoder(new StringSink(hexMac)).PutMessageEnd(actualMac, actualMac.size());
OutputDebugString((("Crypto++ DLL integrity check failed. Actual MAC is: " + hexMac) + "\n").c_str());
#endif
return false;
}
void DoPowerUpSelfTest(const char *moduleFilename, const byte *expectedModuleMac)
{
g_powerUpSelfTestStatus = POWER_UP_SELF_TEST_NOT_DONE;
SetPowerUpSelfTestInProgressOnThisThread(true);
try
{
if (FIPS_140_2_ComplianceEnabled() || expectedModuleMac != NULL)
{
if (!IntegrityCheckModule(moduleFilename, expectedModuleMac, &g_actualMac, &g_macFileLocation))
throw 0; // throw here so we break in the debugger, this will be caught right away
}
// algorithm tests
X917RNG_KnownAnswerTest<AES>(
"2b7e151628aed2a6abf7158809cf4f3c", // key
"000102030405060708090a0b0c0d0e0f", // seed
"00000000000000000000000000000001", // time vector
"D176EDD27493B0395F4D10546232B0693DC7061C03C3A554F09CECF6F6B46D945A"); // output
SymmetricEncryptionKnownAnswerTest<DES_EDE3>(
"385D7189A5C3D485E1370AA5D408082B5CCCCB5E19F2D90E",
"C141B5FCCD28DC8A",
"6E1BD7C6120947A464A6AAB293A0F89A563D8D40D3461B68",
"64EAAD4ACBB9CEAD6C7615E7C7E4792FE587D91F20C7D2F4",
"6235A461AFD312973E3B4F7AA7D23E34E03371F8E8C376C9",
"E26BA806A59B0330DE40CA38E77A3E494BE2B212F6DD624B",
"E26BA806A59B03307DE2BCC25A08BA40A8BA335F5D604C62",
"E26BA806A59B03303C62C2EFF32D3ACDD5D5F35EBCC53371");
SymmetricEncryptionKnownAnswerTest<SKIPJACK>(
"1555E5531C3A169B2D65",
"6EC9795701F49864",
"00AFA48E9621E52E8CBDA312660184EDDB1F33D9DACDA8DA",
"DBEC73562EFCAEB56204EB8AE9557EBF77473FBB52D17CD1",
"0C7B0B74E21F99B8F2C8DF37879F6C044967F42A796DCA8B",
"79FDDA9724E36CC2E023E9A5C717A8A8A7FDA465CADCBF63",
"79FDDA9724E36CC26CACBD83C1ABC06EAF5B249BE5B1E040",
"79FDDA9724E36CC211B0AEC607B95A96BCDA318440B82F49");
SymmetricEncryptionKnownAnswerTest<AES>(
"2b7e151628aed2a6abf7158809cf4f3c",
"000102030405060708090a0b0c0d0e0f",
"6bc1bee22e409f96e93d7e117393172aae2d8a571e03ac9c9eb76fac45af8e5130c81c46a35ce411e5fbc1191a0a52eff69f2445df4f9b17ad2b417be66c3710", // plaintext
"3ad77bb40d7a3660a89ecaf32466ef97f5d3d58503b9699de785895a96fdbaaf43b1cd7f598ece23881b00e3ed0306887b0c785e27e8ad3f8223207104725dd4", // ecb
"7649abac8119b246cee98e9b12e9197d5086cb9b507219ee95db113a917678b273bed6b8e3c1743b7116e69e222295163ff1caa1681fac09120eca307586e1a7", // cbc
"3b3fd92eb72dad20333449f8e83cfb4ac8a64537a0b3a93fcde3cdad9f1ce58b26751f67a3cbb140b1808cf187a4f4dfc04b05357c5d1c0eeac4c66f9ff7f2e6", // cfb
"3b3fd92eb72dad20333449f8e83cfb4a7789508d16918f03f53c52dac54ed8259740051e9c5fecf64344f7a82260edcc304c6528f659c77866a510d9c1d6ae5e", // ofb
NULL);
SymmetricEncryptionKnownAnswerTest<AES>(
"2b7e151628aed2a6abf7158809cf4f3c",
"f0f1f2f3f4f5f6f7f8f9fafbfcfdfeff",
"6bc1bee22e409f96e93d7e117393172aae2d8a571e03ac9c9eb76fac45af8e5130c81c46a35ce411e5fbc1191a0a52eff69f2445df4f9b17ad2b417be66c3710",
NULL,
NULL,
NULL,
NULL,
"874d6191b620e3261bef6864990db6ce9806f66b7970fdff8617187bb9fffdff5ae4df3edbd5d35e5b4f09020db03eab1e031dda2fbe03d1792170a0f3009cee"); // ctr
SecureHashKnownAnswerTest<SHA1>(
"abc",
"A9993E364706816ABA3E25717850C26C9CD0D89D");
SecureHashKnownAnswerTest<SHA224>(
"abc",
"23097d223405d8228642a477bda255b32aadbce4bda0b3f7e36c9da7");
SecureHashKnownAnswerTest<SHA256>(
"abc",
"ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad");
SecureHashKnownAnswerTest<SHA384>(
"abc",
"cb00753f45a35e8bb5a03d699ac65007272c32ab0eded1631a8b605a43ff5bed8086072ba1e7cc2358baeca134c825a7");
SecureHashKnownAnswerTest<SHA512>(
"abc",
"ddaf35a193617abacc417349ae20413112e6fa4e89a97ea20a9eeee64b55d39a2192992a274fc1a836ba3c23a3feebbd454d4423643ce80e2a9ac94fa54ca49f");
MAC_KnownAnswerTest<HMAC<SHA1> >(
"303132333435363738393a3b3c3d3e3f40414243",
"Sample #2",
"0922d3405faa3d194f82a45830737d5cc6c75d24");
const char *keyRSA1 =
"30820150020100300d06092a864886f70d01010105000482013a3082013602010002400a66791dc6988168de7ab77419bb7fb0"
"c001c62710270075142942e19a8d8c51d053b3e3782a1de5dc5af4ebe99468170114a1dfe67cdc9a9af55d655620bbab0203010001"
"02400123c5b61ba36edb1d3679904199a89ea80c09b9122e1400c09adcf7784676d01d23356a7d44d6bd8bd50e94bfc723fa"
"87d8862b75177691c11d757692df8881022033d48445c859e52340de704bcdda065fbb4058d740bd1d67d29e9c146c11cf61"
"0220335e8408866b0fd38dc7002d3f972c67389a65d5d8306566d5c4f2a5aa52628b0220045ec90071525325d3d46db79695e9af"
"acc4523964360e02b119baa366316241022015eb327360c7b60d12e5e2d16bdcd97981d17fba6b70db13b20b436e24eada590220"
"2ca6366d72781dfa24d34a9a24cbc2ae927a9958af426563ff63fb11658a461d";
const char *keyRSA2 =
"30820273020100300D06092A864886F70D01010105000482025D3082025902010002818100D40AF9"
"A2B713034249E5780056D70FC7DE75D76E44565AA6A6B8ED9646F3C19F9E254D72D7DE6E49DB2264"
"0C1D05AB9E2A5F901D8F3FE1F7AE02CEE2ECCE54A40ABAE55A004692752E70725AEEE7CDEA67628A"
"82A9239B4AB660C2BC56D9F01E90CBAAB9BF0FC8E17173CEFC5709A29391A7DDF3E0B758691AAF30"
"725B292F4F020111027F18C0BA087D082C45D75D3594E0767E4820818EB35612B80CEAB8C880ACA5"
"44B6876DFFEF85A576C0D45B551AFAA1FD63209CD745DF75C5A0F0B580296EA466CD0338207E4752"
"FF4E7DB724D8AE18CE5CF4153BB94C27869FBB50E64F02546E4B02997A0B8623E64017CC770759C6"
"695DB649EEFD829D688D441BCC4E7348F1024100EF86DD7AF3F32CDE8A9F6564E43A559A0C9F8BAD"
"36CC25330548B347AC158A345631FA90F7B873C36EFFAE2F7823227A3F580B5DD18304D5932751E7"
"43E9234F024100E2A039854B55688740E32A51DF4AF88613D91A371CF8DDD95D780A89D7CF2119A9"
"54F1AC0F3DCDB2F6959926E6D9D37D8BC07A4C634DE6F16315BD5F0DAC340102407ECEEDB9903572"
"1B76909F174BA6698DCA72953D957B22C0A871C8531EDE3A1BB52984A719BC010D1CA57A555DB83F"
"6DE54CBAB932AEC652F38D497A6F3F30CF024100854F30E4FF232E6DADB2CD99926855F484255AB7"
"01FBCDCB27EC426F33A7046972AA700ADBCA008763DF87440F52F4E070531AC385B55AAC1C2AE7DD"
"8F9278F1024100C313F4AF9E4A9DE1253C21080CE524251560C111550772FD08690F13FBE658342E"
"BD2D41C9DCB12374E871B1839E26CAE252E1AE3DAAD5F1EE1F42B4D0EE7581";
SignatureKnownAnswerTest<RSASS<PKCS1v15, SHA1> >(
keyRSA1,
"Everyone gets Friday off.",
"0610761F95FFD1B8F29DA34212947EC2AA0E358866A722F03CC3C41487ADC604A48FF54F5C6BEDB9FB7BD59F82D6E55D8F3174BA361B2214B2D74E8825E04E81");
SignatureKnownAnswerTest<RSASS_ISO<SHA1> >(
keyRSA2,
"test",
"32F6BA41C8930DE71EE67F2627172CC539EDE04267FDE03AC295E3C50311F26C3B275D3AF513AC96"
"8EE493BAB7DA3A754661D1A7C4A0D1A2B7EE8B313AACD8CB8BFBC5C15EFB0EF15C86A9334A1E87AD"
"291EB961B5CA0E84930429B28780816AA94F96FC2367B71E2D2E4866FA966795B147F00600E5207E"
"2F189C883B37477C");
SignaturePairwiseConsistencyTest<DSA>(
"3082014A0201003082012B06072A8648CE3804013082011E02818100F468699A6F6EBCC0120D3B34C8E007F125EC7D81F763B8D0F33869AE3BD6B9F2ECCC7DF34DF84C0307449E9B85D30D57194BCCEB310F48141914DD13A077AAF9B624A6CBE666BBA1D7EBEA95B5BA6F54417FD5D4E4220C601E071D316A24EA814E8B0122DBF47EE8AEEFD319EBB01DD95683F10DBB4FEB023F8262A07EAEB7FD02150082AD4E034DA6EEACDFDAE68C36F2BAD614F9E53B02818071AAF73361A26081529F7D84078ADAFCA48E031DB54AD57FB1A833ADBD8672328AABAA0C756247998D7A5B10DACA359D231332CE8120B483A784FE07D46EEBFF0D7D374A10691F78653E6DC29E27CCB1B174923960DFE5B959B919B2C3816C19251832AFD8E35D810E598F82877ABF7D40A041565168BD7F0E21E3FE2A8D8C1C0416021426EBA66E846E755169F84A1DA981D86502405DDF");
SignaturePairwiseConsistencyTest<ECDSA<EC2N, SHA1> >(
"302D020100301006072A8648CE3D020106052B8104000404163014020101040F0070337065E1E196980A9D00E37211");
SignaturePairwiseConsistencyTest<ECDSA<ECP, SHA1> >(
"3039020100301306072A8648CE3D020106082A8648CE3D030101041F301D02010104182BB8A13C8B867010BD9471D9E81FDB01ABD0538C64D6249A");
SignaturePairwiseConsistencyTest<RSASS<PSS, SHA1> >(keyRSA1);
}
catch (...)
{
g_powerUpSelfTestStatus = POWER_UP_SELF_TEST_FAILED;
goto done;
}
g_powerUpSelfTestStatus = POWER_UP_SELF_TEST_PASSED;
done:
SetPowerUpSelfTestInProgressOnThisThread(false);
return;
}
#ifdef CRYPTOPP_WIN32_AVAILABLE
void DoDllPowerUpSelfTest()
{
CryptoPP::DoPowerUpSelfTest(NULL, s_moduleMac);
}
#else
void DoDllPowerUpSelfTest()
{
throw NotImplemented("DoDllPowerUpSelfTest() only available on Windows");
}
#endif // #ifdef CRYPTOPP_WIN32_AVAILABLE
NAMESPACE_END
#ifdef CRYPTOPP_WIN32_AVAILABLE
// DllMain needs to be in the global namespace
BOOL APIENTRY DllMain(HANDLE hModule,
DWORD ul_reason_for_call,
LPVOID lpReserved)
{
if (ul_reason_for_call == DLL_PROCESS_ATTACH)
{
CryptoPP::s_hModule = (HMODULE)hModule;
CryptoPP::DoDllPowerUpSelfTest();
}
return TRUE;
}
#endif // #ifdef CRYPTOPP_WIN32_AVAILABLE
#endif // #ifndef CRYPTOPP_IMPORTS