//+--------------------------------------------------------------------------- // // Microsoft Windows // Copyright (C) Microsoft Corporation, 1992 - 1995. // // File: ssl2msg.c // // Contents: // // Classes: // // Functions: // // History: 10-21-97 jbanes Added CAPI integration // //---------------------------------------------------------------------------- #include #if 0 Ssl2CipherMap Ssl2CipherRank[] = { {SSL_CK_RC4_128_WITH_MD5, CALG_MD5, CALG_RC4, 128, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_DES_192_EDE3_CBC_WITH_MD5, CALG_MD5, CALG_3DES, 168, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_RC2_128_CBC_WITH_MD5, CALG_MD5, CALG_RC2, 128, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_RC4_128_FINANCE64_WITH_MD5, CALG_MD5, CALG_RC4, 64, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_DES_64_CBC_WITH_MD5, CALG_MD5, CALG_DES, 56, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_RC4_128_EXPORT40_WITH_MD5, CALG_MD5, CALG_RC4, 40, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX}, {SSL_CK_RC2_128_CBC_EXPORT40_WITH_MD5, CALG_MD5, CALG_RC2, 40, SP_EXCH_RSA_PKCS1, CALG_RSA_KEYX} }; DWORD Ssl2NumCipherRanks = sizeof(Ssl2CipherRank)/sizeof(Ssl2CipherMap); #endif CertTypeMap aSsl2CertEncodingPref[] = { { X509_ASN_ENCODING, 0} }; DWORD cSsl2CertEncodingPref = sizeof(aSsl2CertEncodingPref)/sizeof(CertTypeMap); SP_STATUS WINAPI Ssl2DecryptHandler( PSPContext pContext, PSPBuffer pCommInput, PSPBuffer pAppOutput) { SP_STATUS pctRet = PCT_ERR_OK; if (pCommInput->cbData > 0) { // First, we'll handle incoming data packets: if ((pContext->State & SP_STATE_CONNECTED) && pContext->Decrypt) { pctRet = pContext->Decrypt( pContext, pCommInput, // message pAppOutput); // Unpacked Message if (PCT_ERR_OK == pctRet) { /* look for escapes */ } return(pctRet); } else { return(SP_LOG_RESULT(PCT_INT_ILLEGAL_MSG)); } } return (PCT_INT_INCOMPLETE_MSG); } //+--------------------------------------------------------------------------- // // Function: Ssl2ComputeMac // // Synopsis: Compute an SSL2 message MAC. // // Arguments: [pContext] -- Schannel context. // // History: 10-22-97 jbanes Created. // // Notes: MAC_DATA := Hash(key + data + sequence_number) // //---------------------------------------------------------------------------- static SP_STATUS Ssl2ComputeMac( PSPContext pContext, // in BOOL fWriteMAC, // in DWORD dwSequence, // in PSPBuffer pData, // in PBYTE pbMac, // out DWORD cbMac) // in { DWORD dwReverseSequence; BYTE rgbSalt[SP_MAX_MASTER_KEY]; DWORD cbSalt; HCRYPTHASH hHash; HCRYPTKEY hKey; // Make sure output buffer is big enough. if(cbMac < pContext->pHashInfo->cbCheckSum) { return SP_LOG_RESULT(PCT_INT_BUFF_TOO_SMALL); } dwReverseSequence = htonl(dwSequence); hKey = fWriteMAC ? pContext->hWriteKey : pContext->hReadKey; if(!SchCryptCreateHash(pContext->RipeZombie->hMasterProv, pContext->pHashInfo->aiHash, 0, 0, &hHash, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SP_RETURN(PCT_INT_INTERNAL_ERROR); } if(!SchCryptHashSessionKey(hHash, hKey, CRYPT_LITTLE_ENDIAN, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } cbSalt = sizeof(rgbSalt); if(!SchCryptGetKeyParam(hKey, KP_SALT, rgbSalt, &cbSalt, 0, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } if(!SchCryptHashData(hHash, rgbSalt, cbSalt, 0, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } if(!SchCryptHashData(hHash, pData->pvBuffer, pData->cbData, 0, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } if(!SchCryptHashData(hHash, (PBYTE)&dwReverseSequence, sizeof(DWORD), 0, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } if(!SchCryptGetHashParam(hHash, HP_HASHVAL, pbMac, &cbMac, 0, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); SP_RETURN(PCT_INT_INTERNAL_ERROR); } SchCryptDestroyHash(hHash, pContext->RipeZombie->dwCapiFlags); return PCT_ERR_OK; } //+--------------------------------------------------------------------------- // // Function: Ssl2EncryptMessage // // Synopsis: Encode a block of data as an SSL2 record. // // Arguments: [pContext] -- Schannel context. // [pAppInput] -- Data to be encrypted. // [pCommOutput] -- (output) Completed SSL2 record. // // History: 10-22-97 jbanes CAPI integrated. // // Notes: An SSL2 record is usually formatted as: // // BYTE header[2]; // BYTE mac[mac_size]; // BYTE data[pAppInput->cbData]; // // If a block cipher is used, and the data to be encrypted // consists of a partial number of blocks, then the following // format is used: // // BYTE header[3]; // BYTE mac[mac_size]; // BYTE data[pAppInput->cbData]; // BYTE padding[padding_size]; // //---------------------------------------------------------------------------- SP_STATUS WINAPI Ssl2EncryptMessage( PSPContext pContext, PSPBuffer pAppInput, PSPBuffer pCommOutput) { SP_STATUS pctRet; DWORD cPadding, cPad2; SPBuffer Clean; SPBuffer Encrypted; DWORD ReverseSequence; SP_BEGIN("Ssl2EncryptMessage"); /* Estimate if we have padding or not */ Encrypted.cbData = pAppInput->cbData + pContext->pHashInfo->cbCheckSum; cPadding = (Encrypted.cbData % pContext->pCipherInfo->dwBlockSize); if(cPadding) { cPadding = pContext->pCipherInfo->dwBlockSize - cPadding; } Encrypted.cbData += cPadding; if(cPadding) { if(pCommOutput->cbBuffer + Encrypted.cbData + cPadding < 3) { SP_RETURN(SP_LOG_RESULT(PCT_INT_BUFF_TOO_SMALL)); } Encrypted.pvBuffer = (PUCHAR)pCommOutput->pvBuffer + 3; Encrypted.cbBuffer = pCommOutput->cbBuffer - 3; } else { if(pCommOutput->cbBuffer + Encrypted.cbData + cPadding < 2) { SP_RETURN(SP_LOG_RESULT(PCT_INT_BUFF_TOO_SMALL)); } Encrypted.pvBuffer = (PUCHAR)pCommOutput->pvBuffer + 2; Encrypted.cbBuffer = pCommOutput->cbBuffer - 2; } DebugLog((DEB_TRACE, "Sealing message %x\n", pContext->WriteCounter)); /* Move data out of the way if necessary */ if((PUCHAR)Encrypted.pvBuffer + pContext->pHashInfo->cbCheckSum != pAppInput->pvBuffer) { DebugLog((DEB_WARN, "SSL2EncryptMessage: Unnecessary Move, performance hog\n")); /* if caller wasn't being smart, then we must copy memory here */ MoveMemory((PUCHAR)Encrypted.pvBuffer + pContext->pHashInfo->cbCheckSum, pAppInput->pvBuffer, pAppInput->cbData); } // Initialize pad if(cPadding) { FillMemory((PUCHAR)Encrypted.pvBuffer + pContext->pHashInfo->cbCheckSum + pAppInput->cbData, cPadding, 0); } // Compute MAC. Clean.pvBuffer = (PBYTE)Encrypted.pvBuffer + pContext->pHashInfo->cbCheckSum; Clean.cbData = Encrypted.cbData - pContext->pHashInfo->cbCheckSum; Clean.cbBuffer = Clean.cbData; pctRet = Ssl2ComputeMac(pContext, TRUE, pContext->WriteCounter, &Clean, Encrypted.pvBuffer, pContext->pHashInfo->cbCheckSum); if(pctRet != PCT_ERR_OK) { SP_RETURN(pctRet); } // Encrypt buffer. if(!SchCryptEncrypt(pContext->hWriteKey, 0, FALSE, 0, Encrypted.pvBuffer, &Encrypted.cbData, Encrypted.cbBuffer, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SP_RETURN(PCT_INT_INTERNAL_ERROR); } /* set sizes */ if(cPadding) { if(Encrypted.cbData > 0x3fff) { SP_RETURN(SP_LOG_RESULT(PCT_INT_DATA_OVERFLOW)); } ((PUCHAR)pCommOutput->pvBuffer)[0]= (UCHAR)(0x3f & (Encrypted.cbData>>8)); ((PUCHAR)pCommOutput->pvBuffer)[1]= (UCHAR)(0xff & Encrypted.cbData); ((PUCHAR)pCommOutput->pvBuffer)[2]= (UCHAR)cPadding; } else { if(Encrypted.cbData > 0x7fff) { SP_RETURN(SP_LOG_RESULT(PCT_INT_DATA_OVERFLOW)); } ((PUCHAR)pCommOutput->pvBuffer)[0]= (UCHAR)(0x7f & (Encrypted.cbData>>8)) | 0x80; ((PUCHAR)pCommOutput->pvBuffer)[1]= (UCHAR)(0xff & Encrypted.cbData); } pCommOutput->cbData = Encrypted.cbData + (cPadding?3:2); pContext->WriteCounter ++ ; SP_RETURN( PCT_ERR_OK ); } SP_STATUS WINAPI Ssl2GetHeaderSize( PSPContext pContext, PSPBuffer pCommInput, DWORD * pcbHeaderSize) { if(pcbHeaderSize == NULL) { return SP_LOG_RESULT(PCT_INT_INTERNAL_ERROR); } if(pCommInput->cbData < 1) { return (PCT_INT_INCOMPLETE_MSG); } if( ((PUCHAR)pCommInput->pvBuffer)[0]&0x80 ) { *pcbHeaderSize = 2 + pContext->pHashInfo->cbCheckSum; } else { *pcbHeaderSize = 3 + pContext->pHashInfo->cbCheckSum; } return PCT_ERR_OK; } //+--------------------------------------------------------------------------- // // Function: Ssl2DecryptMessage // // Synopsis: Decode an SSL2 record. // // Arguments: [pContext] -- Schannel context. // [pMessage] -- Data from the remote party. // [pAppOutput] -- (output) Decrypted data. // // History: 10-22-97 jbanes CAPI integrated. // // Notes: An SSL2 record is usually formatted as: // // BYTE header[2]; // BYTE mac[mac_size]; // BYTE data[pAppInput->cbData]; // // If a block cipher is used, and the data to be encrypted // consists of a partial number of blocks, then the following // format is used: // // BYTE header[3]; // BYTE mac[mac_size]; // BYTE data[pAppInput->cbData]; // BYTE padding[padding_size]; // // The number of input data bytes consumed by this function // is returned in pMessage->cbData. // //---------------------------------------------------------------------------- SP_STATUS WINAPI Ssl2DecryptMessage( PSPContext pContext, PSPBuffer pMessage, PSPBuffer pAppOutput) { SP_STATUS pctRet; DWORD cPadding; DWORD dwLength; SPBuffer Encrypted; SPBuffer Clean; DWORD cbActualData; UCHAR Digest[SP_MAX_DIGEST_LEN]; SP_BEGIN("Ssl2DecryptMessage"); /* First determine the length of data, the length of padding, * and the location of data, and the location of MAC */ cbActualData = pMessage->cbData; pMessage->cbData = 2; /* minimum amount of data we need */ if(pMessage->cbData > cbActualData) { SP_RETURN(PCT_INT_INCOMPLETE_MSG); } DebugLog((DEB_TRACE, " Incomming Buffer: %lx, size %ld (%lx)\n", pMessage->pvBuffer, cbActualData, cbActualData)); if(((PUCHAR)pMessage->pvBuffer)[0] & 0x80) { /* 2 byte header */ cPadding = 0; dwLength = ((((PUCHAR)pMessage->pvBuffer)[0] & 0x7f) << 8) | ((PUCHAR)pMessage->pvBuffer)[1]; Encrypted.pvBuffer = (PUCHAR)pMessage->pvBuffer + 2; Encrypted.cbBuffer = pMessage->cbBuffer - 2; } else { pMessage->cbData++; if(pMessage->cbData > cbActualData) { SP_RETURN(PCT_INT_INCOMPLETE_MSG); } /* 3 byte header */ cPadding = ((PUCHAR)pMessage->pvBuffer)[2]; dwLength = ((((PUCHAR)pMessage->pvBuffer)[0] & 0x3f) << 8) | ((PUCHAR)pMessage->pvBuffer)[1]; Encrypted.pvBuffer = (PUCHAR)pMessage->pvBuffer + 3; Encrypted.cbBuffer = pMessage->cbBuffer - 3; } /* Now we know how mutch data we will eat, so set cbData on the Input to be that size */ pMessage->cbData += dwLength; /* do we have enough bytes for the reported data */ if(pMessage->cbData > cbActualData) { SP_RETURN(PCT_INT_INCOMPLETE_MSG); } /* do we have enough data for our checksum */ if(dwLength < pContext->pHashInfo->cbCheckSum) { SP_RETURN(SP_LOG_RESULT(PCT_INT_MSG_ALTERED)); } Encrypted.cbData = dwLength; /* encrypted data size */ Encrypted.cbBuffer = Encrypted.cbData; /* check to see if we have a block size violation */ if(Encrypted.cbData % pContext->pCipherInfo->dwBlockSize) { SP_RETURN(SP_LOG_RESULT(PCT_INT_MSG_ALTERED)); } /* Decrypt */ if(!SchCryptDecrypt(pContext->hReadKey, 0, FALSE, 0, Encrypted.pvBuffer, &Encrypted.cbData, pContext->RipeZombie->dwCapiFlags)) { SP_LOG_RESULT(GetLastError()); SP_RETURN(PCT_INT_INTERNAL_ERROR); } // Compute MAC. Clean.pvBuffer = (PBYTE)Encrypted.pvBuffer + pContext->pHashInfo->cbCheckSum; Clean.cbData = Encrypted.cbData - pContext->pHashInfo->cbCheckSum; Clean.cbBuffer = Clean.cbData; pctRet = Ssl2ComputeMac(pContext, FALSE, pContext->ReadCounter, &Clean, Digest, sizeof(Digest)); if(pctRet != PCT_ERR_OK) { SP_RETURN(pctRet); } // the padding is computed in the hash but is not needed after this Clean.cbData -= cPadding; DebugLog((DEB_TRACE, "Unsealing message %x\n", pContext->ReadCounter)); pContext->ReadCounter++; if(memcmp(Digest, Encrypted.pvBuffer, pContext->pHashInfo->cbCheckSum ) ) { SP_RETURN(SP_LOG_RESULT(PCT_INT_MSG_ALTERED)); } if(pAppOutput->pvBuffer != Clean.pvBuffer) { DebugLog((DEB_WARN, "SSL2DecryptMessage: Unnecessary Move, performance hog\n")); MoveMemory(pAppOutput->pvBuffer, Clean.pvBuffer, Clean.cbData); } pAppOutput->cbData = Clean.cbData; DebugLog((DEB_TRACE, " TotalData: size %ld (%lx)\n", pMessage->cbData, pMessage->cbData)); SP_RETURN( PCT_ERR_OK ); } #if 0 SP_STATUS Ssl2MakeMasterKeyBlock(PSPContext pContext) { MD5_CTX Md5Hash; UCHAR cSalt; UCHAR ib; //pContext->RipeZombe->pMasterKey containst the master secret. #if DBG DebugLog((DEB_TRACE, " Master Secret\n")); DBG_HEX_STRING(DEB_TRACE,pContext->RipeZombie->pMasterKey, pContext->RipeZombie->cbMasterKey); #endif for(ib=0 ; ib<3 ; ib++) { // MD5(master_secret + SHA-hash) MD5Init (&Md5Hash); MD5Update(&Md5Hash, pContext->RipeZombie->pMasterKey, pContext->RipeZombie->cbMasterKey); // We're going to be bug-for-bug compatable with netscape, so // we always add the digit into the hash, instead of following // the spec which says don't add the digit for DES //if(pContext->RipeZombie->aiCipher != CALG_DES) { cSalt = ib+'0'; MD5Update(&Md5Hash, &cSalt, 1); } MD5Update(&Md5Hash, pContext->pChallenge, pContext->cbChallenge); MD5Update(&Md5Hash, pContext->pConnectionID, pContext->cbConnectionID); MD5Final (&Md5Hash); CopyMemory(pContext->Ssl3MasterKeyBlock + ib * MD5DIGESTLEN, Md5Hash.digest, MD5DIGESTLEN); } #if DBG DebugLog((DEB_TRACE, " Master Key Block\n")); DBG_HEX_STRING(DEB_TRACE,pContext->Ssl3MasterKeyBlock, MD5DIGESTLEN*3); #endif return( PCT_ERR_OK ); } #endif