int ClientSession::getShellServerResponse(DragonSRP::DatagramEncryptor& encryptor, DragonSRP::DatagramDecryptor& decryptor, const San2::Utils::bytes& shellRequest, San2::Utils::bytes& shellResponse)
{
int rval;
unsigned char errorCode;
San2::Utils::bytes encryptedRequest, serverRequest, serverResponse, encryptedResponse;
std::uint64_t sequenceNumber = m_swtx.getNextSequenceNumber(); // important
unsigned int encpacketLen, decpacketLen;
shellResponse.clear();
if (shellRequest.size() > SH_MAX_MSGLEN)
{
printf("ClientSession::getShellServerResponse:error: Message too big (shellRequest.size() > SH_MAX_MSGLEN)\n");
return -1;
}
encryptedRequest.resize(encryptor.getOverheadLen() + SH_MAX_MSGLEN);
encryptor.encryptAndAuthenticate((unsigned char *)&shellRequest[0], shellRequest.size(), sequenceNumber, &encryptedRequest[0], &encpacketLen); // throws
encryptedRequest.resize(encpacketLen);
rval = enc_construct_C_message(encryptedRequest, serverRequest);
if (rval)
{
printf("ClientSession::getShellServerResponse:enc_construct_C_message failed: %d\n", rval);
return -2;
}
if (m_swtx.sendReliableMessage(serverRequest, serverResponse) == false)
{
printf("Could not send message to terminal server\n");
return -3;
}
rval = enc_parse_R_message(serverResponse, encryptedResponse, errorCode);
if (rval)
{
printf("ClientSession::getShellServerResponse:enc_parse_R_message failed: %d\n", rval);
return -4;
}
if (errorCode != 0)
{
printf("ClientSession::getShellServerResponse: R message errorcode is non zero: %d\n", errorCode);
return -5;
}
shellResponse.resize(decryptor.getOverheadLen() + SH_MAX_MSGLEN);
decryptor.decryptAndVerifyMac(&encryptedResponse[0], encryptedResponse.size(), &shellResponse[0], &decpacketLen, sequenceNumber);
shellResponse.resize(decpacketLen);
return 0;
}
SAN_UINT32 CDataPack::unpackUint32(const San2::Utils::bytes &data, unsigned int position)
{
if (data.size() < position + sizeof(SAN_UINT32)) return 0; // error
SAN_UINT32 num;
memcpy(&num, &data[position], sizeof(SAN_UINT32));
return San2::Utils::Endian::san_u_be32toh(num);
}
SAN_INT64 CDataPack::unpackInt64(const San2::Utils::bytes &data, unsigned int position)
{
if (data.size() < position + sizeof(SAN_INT64)) return 0; // error
SAN_INT64 num;
memcpy(&num, &data[position], sizeof(SAN_INT64));
return San2::Utils::Endian::san_s_be64toh(num);
}
bool GetAddressesOut::pack(San2::Utils::bytes &out)
{
out.clear();
return true;
}
int main(int argc, char *argv[])
{
FILELog::ReportingLevel() = logDEBUG4;
San2::Api::CNodeConnector connector(PIPENAME, 5000, 5000, 5000, 5000);
if (connector.open() != San2::Cppl::ErrorCode::SUCCESS)
{
printf("connection failed\n");
return -1;
}
connector.connect();
if (connector.registerPort(2200) == true)
{
printf("port register: OK\n");
}
else
{
printf("port register: FAILURE\n");
}
San2::Network::SanAddress dstaddr;
if (San2::Utils::string2address("000000000000000000000000000000000000000000000000000000000000FF21", dstaddr) != true)
{
FILE_LOG(logDEBUG4) << "failed to parse destination address";
return -1;
}
San2::Utils::bytes payload;
payload.append("Ahoj, jak se mas");
San2::Network::CCapsule capsule;
capsule.setDSdata(2201, 2200, payload);
capsule.setDestinationAddress(dstaddr);
San2::Utils::bytes serial;
capsule.pack(serial);
connector.sendCapsule(serial);
/*
San2::Network::CCapsule rxcapsule;
printf("awaiting capsule\n");
SAN_INT32 rval = connector.waitForCapsule(rxcapsule, 5000);
switch(rval)
{
case SAN2_WAITFORCAPSULE_SUCCESS:
printf("got: rxcapsule\n");
break;
case SAN2_WAITFORCAPSULE_TIMEOUT:
printf("got: timeout\n");
break;
case SAN2_WAITFORCAPSULE_ERROR_INVALID_RESPONSE:
printf("got: error invalid response\n");
break;
case SAN2_WAITFORCAPSULE_ERROR_CAPSULE_UNPACK:
printf("got: error capsule unpack\n");
break;
case SAN2_WAITFORCAPSULE_ERROR_INVOKE_FAILED:
printf("got: error INVOKE FAILED\n");
break;
case SAN2_WAITFORCAPSULE_ERROR:
printf("got: GENERAL ERROR\n");
break;
default:
printf("got: UNKNOWN ERROR\n");
break;
}
*/
return 0;
}
