//#include #include "AdmtCrypt.h" #include #pragma comment( lib, "AdvApi32.lib" ) namespace { void __stdcall CreateByteArray(DWORD cb, _variant_t& vntByteArray) { vntByteArray.Clear(); vntByteArray.parray = SafeArrayCreateVector(VT_UI1, 0, cb); if (vntByteArray.parray == NULL) { _com_issue_error(E_OUTOFMEMORY); } vntByteArray.vt = VT_UI1|VT_ARRAY; } _variant_t operator +(const _variant_t& vntByteArrayA, const _variant_t& vntByteArrayB) { _variant_t vntByteArrayC; // validate parameters if ((vntByteArrayA.vt != (VT_UI1|VT_ARRAY)) || ((vntByteArrayA.parray == NULL))) { _com_issue_error(E_INVALIDARG); } if ((vntByteArrayB.vt != (VT_UI1|VT_ARRAY)) || ((vntByteArrayB.parray == NULL))) { _com_issue_error(E_INVALIDARG); } // concatenate byte arrays DWORD cbA = vntByteArrayA.parray->rgsabound[0].cElements; DWORD cbB = vntByteArrayB.parray->rgsabound[0].cElements; CreateByteArray(cbA + cbB, vntByteArrayC); memcpy(vntByteArrayC.parray->pvData, vntByteArrayA.parray->pvData, cbA); memcpy((BYTE*)vntByteArrayC.parray->pvData + cbA, vntByteArrayB.parray->pvData, cbB); return vntByteArrayC; } #ifdef _DEBUG _bstr_t __stdcall DebugByteArray(const _variant_t& vnt) { _bstr_t strArray; if ((vnt.vt == (VT_UI1|VT_ARRAY)) && ((vnt.parray != NULL))) { _TCHAR szArray[256] = _T(""); DWORD c = vnt.parray->rgsabound[0].cElements; BYTE* pb = (BYTE*) vnt.parray->pvData; for (DWORD i = 0; i < c; i++, pb++) { _TCHAR sz[48]; wsprintf(sz, _T("%02X"), (UINT)(USHORT)*pb); if (i > 0) { _tcscat(szArray, _T(" ")); } _tcscat(szArray, sz); } strArray = szArray; } return strArray; } #define TRACE_BUFFER_SIZE 1024 void _cdecl Trace(LPCTSTR pszFormat, ...) { _TCHAR szMessage[TRACE_BUFFER_SIZE]; if (pszFormat) { va_list args; va_start(args, pszFormat); _vsntprintf(szMessage, TRACE_BUFFER_SIZE, pszFormat, args); va_end(args); #if 0 OutputDebugString(szMessage); #else HANDLE hFile = CreateFile(L"C:\\AdmtCrypt.log", GENERIC_WRITE, FILE_SHARE_READ, NULL, OPEN_ALWAYS, FILE_ATTRIBUTE_NORMAL, NULL); if (hFile != INVALID_HANDLE_VALUE) { SetFilePointer(hFile, 0, NULL, FILE_END); DWORD dwWritten; WriteFile(hFile, szMessage, _tcslen(szMessage) * sizeof(_TCHAR), &dwWritten, NULL); CloseHandle(hFile); } #endif } } #else _bstr_t __stdcall DebugByteArray(const _variant_t& vnt) { return _T(""); } void _cdecl Trace(LPCTSTR pszFormat, ...) { } #endif } //--------------------------------------------------------------------------- // Target Crypt Class //--------------------------------------------------------------------------- // Constructor CTargetCrypt::CTargetCrypt() { Trace(_T("CTargetCrypt::CTargetCrypt()\r\n")); } // Destructor CTargetCrypt::~CTargetCrypt() { Trace(_T("CTargetCrypt::~CTargetCrypt()\r\n")); } // CreateEncryptionKey Method _variant_t CTargetCrypt::CreateEncryptionKey(LPCTSTR pszKeyId, LPCTSTR pszPassword) { Trace(_T("CreateEncryptionKey(pszKeyId='%s', pszPassword='%s')\r\n"), pszKeyId, pszPassword); // generate encryption key bytes _variant_t vntBytes = GenerateRandom(ENCRYPTION_KEY_SIZE); Trace(_T(" vntBytes={ %s }\r\n"), (LPCTSTR)DebugByteArray(vntBytes)); // store encryption key bytes StoreBytes(pszKeyId, vntBytes); // create key from password CCryptHash hashPassword(CreateHash(CALG_SHA1)); if (pszPassword && pszPassword[0]) { hashPassword.Hash(pszPassword); } else { BYTE b = 0; hashPassword.Hash(&b, 1); } CCryptKey keyPassword(DeriveKey(CALG_3DES, hashPassword)); _variant_t vntPasswordFlag; CreateByteArray(1, vntPasswordFlag); *((BYTE*)vntPasswordFlag.parray->pvData) = (pszPassword && pszPassword[0]) ? 0xFF : 0x00; // concatenate encryption key bytes and hash of encryption key bytes CCryptHash hashBytes(CreateHash(CALG_SHA1)); hashBytes.Hash(vntBytes); _variant_t vntDecrypted = vntBytes + hashBytes.GetValue(); // Trace(_T(" vntDecrypted={ %s }\n"), (LPCTSTR)DebugByteArray(vntDecrypted)); // encrypt bytes / hash pair _variant_t vntEncrypted = keyPassword.Encrypt(NULL, true, vntDecrypted); // Trace(_T(" vntEncrypted={ %s }\n"), (LPCTSTR)DebugByteArray(vntEncrypted)); return vntPasswordFlag + vntEncrypted; } // CreateSession Method _variant_t CTargetCrypt::CreateSession(LPCTSTR pszKeyId) { Trace(_T("CreateSession(pszKeyId='%s')\r\n"), pszKeyId); // get encryption key CCryptHash hashEncryption(CreateHash(CALG_SHA1)); hashEncryption.Hash(RetrieveBytes(pszKeyId)); CCryptKey keyEncryption(DeriveKey(CALG_3DES, hashEncryption)); // generate session key bytes _variant_t vntBytes = GenerateRandom(SESSION_KEY_SIZE); // create session key CCryptHash hash(CreateHash(CALG_SHA1)); hash.Hash(vntBytes); m_keySession.Attach(DeriveKey(CALG_3DES, hash)); // concatenate session key bytes and hash of session key bytes _variant_t vntDecrypted = vntBytes + hash.GetValue(); // encrypt session bytes and include hash return keyEncryption.Encrypt(NULL, true, vntDecrypted); } // Encrypt Method _variant_t CTargetCrypt::Encrypt(_bstr_t strData) { Trace(_T("Encrypt(strData='%s')\r\n"), (LPCTSTR)strData); // convert string to byte array _variant_t vnt; HRESULT hr = VectorFromBstr(strData, &vnt.parray); if (FAILED(hr)) { _com_issue_error(hr); } vnt.vt = VT_UI1|VT_ARRAY; // encrypt data return m_keySession.Encrypt(NULL, true, vnt); } //--------------------------------------------------------------------------- // Source Crypt Class //--------------------------------------------------------------------------- // Constructor CSourceCrypt::CSourceCrypt() { Trace(_T("CSourceCrypt::CSourceCrypt()\r\n")); } // Destructor CSourceCrypt::~CSourceCrypt() { Trace(_T("CSourceCrypt::~CSourceCrypt()\r\n")); } // ImportEncryptionKey Method void CSourceCrypt::ImportEncryptionKey(const _variant_t& vntEncryptedKey, LPCTSTR pszPassword) { Trace(_T("ImportEncryptionKey(vntEncryptedKey={ %s }, pszPassword='%s')\r\n"), (LPCTSTR)DebugByteArray(vntEncryptedKey), pszPassword); // validate parameters if ((vntEncryptedKey.vt != (VT_UI1|VT_ARRAY)) || ((vntEncryptedKey.parray == NULL))) { _com_issue_error(E_INVALIDARG); } // extract password flag and verify with password bool bPassword = *((BYTE*)vntEncryptedKey.parray->pvData) ? true : false; if (bPassword) { if ((pszPassword == NULL) || (pszPassword[0] == NULL)) { _com_issue_error(HRESULT_FROM_WIN32(ERROR_INVALID_PASSWORD)); } } else { if (pszPassword && pszPassword[0]) { _com_issue_error(HRESULT_FROM_WIN32(ERROR_INVALID_PASSWORD)); } } // create key from password CCryptHash hashPassword(CreateHash(CALG_SHA1)); if (pszPassword && pszPassword[0]) { hashPassword.Hash(pszPassword); } else { BYTE b = 0; hashPassword.Hash(&b, 1); } CCryptKey keyPassword(DeriveKey(CALG_3DES, hashPassword)); // encrypted data _variant_t vntEncrypted; DWORD cbEncrypted = vntEncryptedKey.parray->rgsabound[0].cElements - 1; CreateByteArray(cbEncrypted, vntEncrypted); memcpy(vntEncrypted.parray->pvData, (BYTE*)vntEncryptedKey.parray->pvData + 1, cbEncrypted); // Trace(_T(" vntEncrypted={ %s }\n"), (LPCTSTR)DebugByteArray(vntEncrypted)); // decrypt encryption key bytes plus hash _variant_t vntDecrypted = keyPassword.Decrypt(NULL, true, vntEncrypted); // Trace(_T(" vntDecrypted={ %s }\n"), (LPCTSTR)DebugByteArray(vntDecrypted)); // extract encryption key bytes _variant_t vntBytes; CreateByteArray(ENCRYPTION_KEY_SIZE, vntBytes); memcpy(vntBytes.parray->pvData, (BYTE*)vntDecrypted.parray->pvData, ENCRYPTION_KEY_SIZE); Trace(_T(" vntBytes={ %s }\r\n"), (LPCTSTR)DebugByteArray(vntBytes)); // extract hash of encryption key bytes _variant_t vntHashValue; DWORD cbHashValue = vntDecrypted.parray->rgsabound[0].cElements - ENCRYPTION_KEY_SIZE; CreateByteArray(cbHashValue, vntHashValue); memcpy(vntHashValue.parray->pvData, (BYTE*)vntDecrypted.parray->pvData + ENCRYPTION_KEY_SIZE, cbHashValue); // Trace(_T(" vntHashValue={ %s }\n"), (LPCTSTR)DebugByteArray(vntHashValue)); // create hash from bytes and create hash from hash value CCryptHash hashA(CreateHash(CALG_SHA1)); hashA.Hash(vntBytes); CCryptHash hashB(CreateHash(CALG_SHA1)); hashB.SetValue(vntHashValue); // if hashes compare store encryption key bytes if (hashA == hashB) { StoreBytes(m_szIdPrefix, vntBytes); } else { _com_issue_error(HRESULT_FROM_WIN32(ERROR_INVALID_PASSWORD)); } } // ImportSessionKey Method void CSourceCrypt::ImportSessionKey(const _variant_t& vntEncryptedKey) { Trace(_T("ImportSessionKey(vntEncryptedKey={ %s })\r\n"), (LPCTSTR)DebugByteArray(vntEncryptedKey)); // validate parameters if ((vntEncryptedKey.vt != (VT_UI1|VT_ARRAY)) || ((vntEncryptedKey.parray == NULL))) { _com_issue_error(E_INVALIDARG); } // get encryption key CCryptKey keyEncryption(GetEncryptionKey(m_szIdPrefix)); // decrypt session key bytes plus hash _variant_t vntDecrypted = keyEncryption.Decrypt(NULL, true, vntEncryptedKey); // extract session key bytes _variant_t vntBytes; CreateByteArray(SESSION_KEY_SIZE, vntBytes); memcpy(vntBytes.parray->pvData, vntDecrypted.parray->pvData, SESSION_KEY_SIZE); // extract hash of session key bytes _variant_t vntHashValue; DWORD cbHashValue = vntDecrypted.parray->rgsabound[0].cElements - SESSION_KEY_SIZE; CreateByteArray(cbHashValue, vntHashValue); memcpy(vntHashValue.parray->pvData, (BYTE*)vntDecrypted.parray->pvData + SESSION_KEY_SIZE, cbHashValue); // create hash from bytes and create hash from hash value CCryptHash hashA(CreateHash(CALG_SHA1)); hashA.Hash(vntBytes); CCryptHash hashB(CreateHash(CALG_SHA1)); hashB.SetValue(vntHashValue); // if hashes compare if (hashA == hashB) { // derive session key from session key bytes hash m_keySession.Attach(DeriveKey(CALG_3DES, hashA)); } else { _com_issue_error(E_FAIL); } } // Decrypt Method _bstr_t CSourceCrypt::Decrypt(const _variant_t& vntData) { Trace(_T("Decrypt(vntData={ %s })\r\n"), (LPCTSTR)DebugByteArray(vntData)); // decrypt data _variant_t vnt = m_keySession.Decrypt(NULL, true, vntData); // convert into string BSTR bstr; HRESULT hr = BstrFromVector(vnt.parray, &bstr); if (FAILED(hr)) { _com_issue_error(hr); } return bstr; } //--------------------------------------------------------------------------- // Domain Crypt Class //--------------------------------------------------------------------------- // Constructor CDomainCrypt::CDomainCrypt() { Trace(_T("CDomainCrypt::CDomainCrypt()\r\n")); } // Destructor CDomainCrypt::~CDomainCrypt() { Trace(_T("CDomainCrypt::~CDomainCrypt()\r\n")); } // GetEncryptionKey Method HCRYPTKEY CDomainCrypt::GetEncryptionKey(LPCTSTR pszKeyId) { // retrieve bytes _variant_t vntBytes = RetrieveBytes(pszKeyId); // set hash value CCryptHash hash; hash.Attach(CreateHash(CALG_SHA1)); hash.Hash(vntBytes); // create encryption key derived from bytes return DeriveKey(CALG_3DES, hash); } // StoreBytes Method void CDomainCrypt::StoreBytes(LPCTSTR pszId, const _variant_t& vntBytes) { // validate parameters if ((pszId == NULL) || (pszId[0] == NULL)) { _com_issue_error(E_INVALIDARG); } if ((vntBytes.vt != VT_EMPTY) && (vntBytes.vt != (VT_UI1|VT_ARRAY))) { _com_issue_error(E_INVALIDARG); } if ((vntBytes.vt == (VT_UI1|VT_ARRAY)) && (vntBytes.parray == NULL)) { _com_issue_error(E_INVALIDARG); } LSA_HANDLE hPolicy = NULL; try { // open policy object LSA_OBJECT_ATTRIBUTES loa = { sizeof(LSA_OBJECT_ATTRIBUTES), NULL, NULL, 0, NULL, NULL }; NTSTATUS ntsStatus = LsaOpenPolicy(NULL, &loa, POLICY_CREATE_SECRET, &hPolicy); if (!LSA_SUCCESS(ntsStatus)) { _com_issue_error(HRESULT_FROM_WIN32(LsaNtStatusToWinError(ntsStatus))); } // store data PWSTR pwsKey = const_cast(pszId); USHORT cbKey = _tcslen(pszId) * sizeof(_TCHAR); PWSTR pwsData = NULL; USHORT cbData = 0; if (vntBytes.vt != VT_EMPTY) { pwsData = reinterpret_cast(vntBytes.parray->pvData); cbData = (USHORT) vntBytes.parray->rgsabound[0].cElements; } LSA_UNICODE_STRING lusKey = { cbKey, cbKey, pwsKey }; LSA_UNICODE_STRING lusData = { cbData, cbData, pwsData }; ntsStatus = LsaStorePrivateData(hPolicy, &lusKey, &lusData); if (!LSA_SUCCESS(ntsStatus)) { _com_issue_error(HRESULT_FROM_WIN32(LsaNtStatusToWinError(ntsStatus))); } // close policy object LsaClose(hPolicy); } catch (...) { if (hPolicy) { LsaClose(hPolicy); } throw; } } // RetrievePrivateData Method _variant_t CDomainCrypt::RetrieveBytes(LPCTSTR pszId) { _variant_t vntBytes; // validate parameters if ((pszId == NULL) || (pszId[0] == NULL)) { _com_issue_error(E_INVALIDARG); } LSA_HANDLE hPolicy = NULL; try { // open policy object LSA_OBJECT_ATTRIBUTES loa = { sizeof(LSA_OBJECT_ATTRIBUTES), NULL, NULL, 0, NULL, NULL }; NTSTATUS ntsStatus = LsaOpenPolicy(NULL, &loa, POLICY_GET_PRIVATE_INFORMATION, &hPolicy); if (!LSA_SUCCESS(ntsStatus)) { _com_issue_error(HRESULT_FROM_WIN32(LsaNtStatusToWinError(ntsStatus))); } // retrieve data PWSTR pwsKey = const_cast(pszId); USHORT cbKey = _tcslen(pszId) * sizeof(_TCHAR); LSA_UNICODE_STRING lusKey = { cbKey, cbKey, pwsKey }; PLSA_UNICODE_STRING plusData; ntsStatus = LsaRetrievePrivateData(hPolicy, &lusKey, &plusData); if (!LSA_SUCCESS(ntsStatus)) { _com_issue_error(HRESULT_FROM_WIN32(LsaNtStatusToWinError(ntsStatus))); } vntBytes.parray = SafeArrayCreateVector(VT_UI1, 0, plusData->Length); if (vntBytes.parray == NULL) { LsaFreeMemory(plusData); _com_issue_error(E_OUTOFMEMORY); } vntBytes.vt = VT_UI1|VT_ARRAY; memcpy(vntBytes.parray->pvData, plusData->Buffer, plusData->Length); LsaFreeMemory(plusData); // close policy object LsaClose(hPolicy); } catch (...) { if (hPolicy) { LsaClose(hPolicy); } throw; } return vntBytes; } // private data key identifier _TCHAR CDomainCrypt::m_szIdPrefix[] = _T("L$6A2899C0-CECE-459A-B5EB-7ED04DE61388"); //--------------------------------------------------------------------------- // Crypt Provider Class //--------------------------------------------------------------------------- // Constructors // // Notes: // If the enhanced provider is not installed, CryptAcquireContext() generates // the following error: (0x80090019) The keyset is not defined. CCryptProvider::CCryptProvider() : m_hProvider(NULL) { Trace(_T("E CCryptProvider::CCryptProvider(this=0x%p)\r\n"), this); if (!CryptAcquireContext(&m_hProvider, NULL, MS_ENHANCED_PROV, PROV_RSA_FULL, CRYPT_MACHINE_KEYSET|CRYPT_VERIFYCONTEXT)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } #ifdef _DEBUG char szProvider[256]; DWORD cbProvider = sizeof(szProvider); if (CryptGetProvParam(m_hProvider, PP_NAME, (BYTE*) szProvider, &cbProvider, 0)) { } DWORD dwVersion; DWORD cbVersion = sizeof(dwVersion); if (CryptGetProvParam(m_hProvider, PP_VERSION, (BYTE*) &dwVersion, &cbVersion, 0)) { } // char szContainer[256]; // DWORD cbContainer = sizeof(szContainer); // if (CryptGetProvParam(m_hProvider, PP_CONTAINER, (BYTE*) szContainer, &cbContainer, 0)) // { // } #endif Trace(_T("L CCryptProvider::CCryptProvider()\r\n")); } CCryptProvider::CCryptProvider(const CCryptProvider& r) : m_hProvider(r.m_hProvider) { // if (!CryptContextAddRef(r.m_hProvider, NULL, 0)) // { // _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); // } } // Destructor CCryptProvider::~CCryptProvider() { Trace(_T("E CCryptProvider::~CCryptProvider()\r\n")); if (m_hProvider) { if (!CryptReleaseContext(m_hProvider, 0)) { #ifdef _DEBUG DebugBreak(); #endif } } Trace(_T("L CCryptProvider::~CCryptProvider()\r\n")); } // assignment operators CCryptProvider& CCryptProvider::operator =(const CCryptProvider& r) { m_hProvider = r.m_hProvider; // if (!CryptContextAddRef(r.m_hProvider, NULL, 0)) // { // _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); // } return *this; } // CreateHash Method HCRYPTHASH CCryptProvider::CreateHash(ALG_ID aid) { HCRYPTHASH hHash; if (!CryptCreateHash(m_hProvider, aid, 0, 0, &hHash)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } return hHash; } // DeriveKey Method HCRYPTKEY CCryptProvider::DeriveKey(ALG_ID aid, HCRYPTHASH hHash, DWORD dwFlags) { HCRYPTKEY hKey; if (!CryptDeriveKey(m_hProvider, aid, hHash, dwFlags, &hKey)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } return hKey; } // GenerateRandom Method // // Generates a specified number of random bytes. _variant_t CCryptProvider::GenerateRandom(DWORD dwNumberOfBytes) const { _variant_t vntRandom; // create byte array of specified length vntRandom.parray = SafeArrayCreateVector(VT_UI1, 0, dwNumberOfBytes); if (vntRandom.parray == NULL) { _com_issue_error(E_OUTOFMEMORY); } vntRandom.vt = VT_UI1|VT_ARRAY; // generate specified number of random bytes GenerateRandom((BYTE*)vntRandom.parray->pvData, dwNumberOfBytes); return vntRandom; } // GenerateRandom Method // // Generates a specified number of random bytes. void CCryptProvider::GenerateRandom(BYTE* pbData, DWORD cbData) const { // generate specified number of random bytes if (!CryptGenRandom(m_hProvider, cbData, pbData)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } } //--------------------------------------------------------------------------- // Crypt Key Class //--------------------------------------------------------------------------- // Constructor CCryptKey::CCryptKey(HCRYPTKEY hKey) : m_hKey(hKey) { } // Destructor CCryptKey::~CCryptKey() { if (m_hKey) { if (!CryptDestroyKey(m_hKey)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } } } // Encrypt Method _variant_t CCryptKey::Encrypt(HCRYPTHASH hHash, bool bFinal, const _variant_t& vntData) { _variant_t vntEncrypted; // validate parameters if ((vntData.vt != (VT_UI1|VT_ARRAY)) || ((vntData.parray == NULL))) { _com_issue_error(E_INVALIDARG); } // get encrypted data size DWORD cbData = vntData.parray->rgsabound[0].cElements; DWORD cbBuffer = cbData; if (!CryptEncrypt(m_hKey, hHash, bFinal ? TRUE : FALSE, 0, NULL, &cbBuffer, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } // create encrypted data buffer vntEncrypted.parray = SafeArrayCreateVector(VT_UI1, 0, cbBuffer); if (vntEncrypted.parray == NULL) { _com_issue_error(E_OUTOFMEMORY); } vntEncrypted.vt = VT_UI1|VT_ARRAY; // copy data to encrypted buffer memcpy(vntEncrypted.parray->pvData, vntData.parray->pvData, cbData); // encrypt data BYTE* pbData = (BYTE*) vntEncrypted.parray->pvData; if (!CryptEncrypt(m_hKey, hHash, bFinal ? TRUE : FALSE, 0, pbData, &cbData, cbBuffer)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } return vntEncrypted; } // Decrypt Method _variant_t CCryptKey::Decrypt(HCRYPTHASH hHash, bool bFinal, const _variant_t& vntData) { _variant_t vntDecrypted; // validate parameters if ((vntData.vt != (VT_UI1|VT_ARRAY)) || ((vntData.parray == NULL))) { _com_issue_error(E_INVALIDARG); } // decrypt data _variant_t vnt = vntData; BYTE* pb = (BYTE*) vnt.parray->pvData; DWORD cb = vnt.parray->rgsabound[0].cElements; if (!CryptDecrypt(m_hKey, hHash, bFinal ? TRUE : FALSE, 0, pb, &cb)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } // create decrypted byte array // the number of decrypted bytes may be less than // the number of encrypted bytes vntDecrypted.parray = SafeArrayCreateVector(VT_UI1, 0, cb); if (vntDecrypted.parray == NULL) { _com_issue_error(E_OUTOFMEMORY); } vntDecrypted.vt = VT_UI1|VT_ARRAY; memcpy(vntDecrypted.parray->pvData, vnt.parray->pvData, cb); return vntDecrypted; } //--------------------------------------------------------------------------- // Crypt Hash Class //--------------------------------------------------------------------------- // Constructor CCryptHash::CCryptHash(HCRYPTHASH hHash) : m_hHash(hHash) { } // Destructor CCryptHash::~CCryptHash() { if (m_hHash) { if (!CryptDestroyHash(m_hHash)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } } } // GetValue Method _variant_t CCryptHash::GetValue() const { _variant_t vntValue; // get hash size DWORD dwHashSize; DWORD cbHashSize = sizeof(DWORD); if (!CryptGetHashParam(m_hHash, HP_HASHSIZE, (BYTE*)&dwHashSize, &cbHashSize, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } // allocate buffer vntValue.parray = SafeArrayCreateVector(VT_UI1, 0, dwHashSize); if (vntValue.parray == NULL) { _com_issue_error(E_OUTOFMEMORY); } vntValue.vt = VT_UI1|VT_ARRAY; // get hash value if (!CryptGetHashParam(m_hHash, HP_HASHVAL, (BYTE*)vntValue.parray->pvData, &dwHashSize, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } return vntValue; } // SetValue Method void CCryptHash::SetValue(const _variant_t& vntValue) { // if parameter is valid if ((vntValue.vt == (VT_UI1|VT_ARRAY)) && ((vntValue.parray != NULL))) { // get hash size DWORD dwHashSize; DWORD cbHashSize = sizeof(DWORD); if (!CryptGetHashParam(m_hHash, HP_HASHSIZE, (BYTE*)&dwHashSize, &cbHashSize, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } // validate hash size BYTE* pbValue = (BYTE*)vntValue.parray->pvData; DWORD cbValue = vntValue.parray->rgsabound[0].cElements; if (cbValue != dwHashSize) { _com_issue_error(E_INVALIDARG); } // set hash value if (!CryptSetHashParam(m_hHash, HP_HASHVAL, (BYTE*)pbValue, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } } else { _com_issue_error(E_INVALIDARG); } } // Hash Method void CCryptHash::Hash(LPCTSTR pszData) { if (pszData && pszData[0]) { Hash((BYTE*)pszData, _tcslen(pszData) * sizeof(_TCHAR)); } else { _com_issue_error(E_INVALIDARG); } } // Hash Method void CCryptHash::Hash(const _variant_t& vntData) { if ((vntData.vt == (VT_UI1|VT_ARRAY)) && ((vntData.parray != NULL))) { Hash((BYTE*)vntData.parray->pvData, vntData.parray->rgsabound[0].cElements); } else { _com_issue_error(E_INVALIDARG); } } // Hash Method void CCryptHash::Hash(BYTE* pbData, DWORD cbData) { if ((pbData != NULL) && (cbData > 0)) { if (!CryptHashData(m_hHash, pbData, cbData, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } } else { _com_issue_error(E_INVALIDARG); } } bool CCryptHash::operator ==(const CCryptHash& hash) { bool bEqual = false; DWORD cbSize = sizeof(DWORD); // compare hash sizes DWORD dwSizeA; DWORD dwSizeB; if (!CryptGetHashParam(m_hHash, HP_HASHSIZE, (BYTE*)&dwSizeA, &cbSize, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } if (!CryptGetHashParam(hash.m_hHash, HP_HASHSIZE, (BYTE*)&dwSizeB, &cbSize, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } // if sizes are equal if (dwSizeA == dwSizeB) { // compare hashes BYTE* pbA; BYTE* pbB; try { pbA = (BYTE*) _alloca(dwSizeA); pbB = (BYTE*) _alloca(dwSizeB); } catch (...) { _com_issue_error(E_OUTOFMEMORY); } if (!CryptGetHashParam(m_hHash, HP_HASHVAL, pbA, &dwSizeA, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } if (!CryptGetHashParam(hash.m_hHash, HP_HASHVAL, pbB, &dwSizeB, 0)) { _com_issue_error(HRESULT_FROM_WIN32(GetLastError())); } if (memcmp(pbA, pbB, dwSizeA) == 0) { bEqual = true; } } return bEqual; }