void loop() { // if there's data available, read a packet int packetSize = Udp.parsePacket(); char Size[4]; if(packetSize) { if(packetSize == 4) { IPAddress remote = Udp.remoteIP(); // read the packet into packetBufffer Udp.read(packetBuffer,UDP_TX_PACKET_MAX_SIZE); char Command[4]; for(int nCom = 0; nCom < 4; nCom++) { Command[nCom] = packetBuffer[nCom]; } if (Command[0] == 't') { digitalWrite(13, HIGH); } else if (Command[0] == 'r') { digitalWrite(12, HIGH); } else if (Command[0] == 'e') { digitalWrite(10, HIGH); } else if (Command[0] == 'w') { analogWrite(11, 65); } else { digitalWrite(13, LOW); digitalWrite(12, LOW); analogWrite(11, 0); } // send a reply, to the IP address and port that sent us the packet we received itoa(packetSize, Size, 10); Udp.beginPacket(Udp.remoteIP(), Udp.remotePort()); Udp.write(ReplyBuffer); Udp.write(packetBuffer); Udp.write(Size); Udp.endPacket(); delay(1000); } else { Udp.beginPacket(Udp.remoteIP(), Udp.remotePort()); Udp.write("NOPE"); Udp.endPacket(); } } }
void uartToUdp() { bool sendIt = false; if (Serial.available() > 0) { uartBuffer[uartCounter] = Serial.read(); if (uartBuffer[uartCounter] == HDLC_SS_BYTE) { if (hdlcStart)sendIt = true; else { hdlcStart = true; Timer1.start(); } } else if (hdlcStart) { ++uartCounter; } } if (sendIt) { Udp.beginPacket(Udp.remoteIP(), Udp.remotePort()); Udp.write(uartBuffer, uartCounter); Udp.endPacket(); resetUartBuffer(); } }
// This function's purpose is to receive data and prepare it for parsing void RobotOpenClass::handleData() { _packetBufferSize = Udp.parsePacket(); // If there's data, read the packet in if (_packetBufferSize > 0) { _remotePort = Udp.remotePort(); _remoteIp = Udp.remoteIP(); Udp.read(_packetBufferAccessor, 256); parsePacket(); // Data is all set, time to parse through it } }
roveEthernet_Error roveEthernet_GetUdpMsg(roveIP* senderIP, void* buffer, size_t bufferSize) { int packetSize = udpReceiver.parsePacket(); if (packetSize > 0) //if there is a packet available { udpReceiver.read((char*)buffer, bufferSize); *senderIP = udpReceiver.remoteIP(); return ROVE_ETHERNET_ERROR_SUCCESS; } else { return ROVE_ETHERNET_ERROR_WOULD_BLOCK; } }
void Notification::sendUDPNotification(EthernetUDP &udpSocket, aJsonObject *pushurl_channel, char *payload1, extData payload2) { Serial.print(F("Sending a UDP response: ")); Serial.println(payload1); udpSocket.beginPacket(udpSocket.remoteIP(), udpSocket.remotePort()); // The actual payload udpSocket.write(payload1); // Extra payload is generated by running a callback function if (payload2 != NULL) { (*payload2)(&udpSocket); } udpSocket.write("}"); // The end of the JSON data, i.e. '}' udpSocket.endPacket(); }
void commandInterfaceTick() { int packetSize = cmdsock.parsePacket(); if(cmdsock.available()) { // read the packet into packetBufffer cmdsock.read(udpPacketBuffer, PACKET_SIZE); if(memcmp("INGV\0", udpPacketBuffer, 5) != 0) { return; } bool reboot = false; unsigned long unixTimeM = getUNIXTime(); unsigned long uptime = getUNIXTime() - getBootTime(); byte macaddress[6] = { 0 }; getMACAddress(macaddress); uint32_t probeSpeed = getProbeSpeedStatistic(); uint32_t freeramkb = freeMemory(); float latency = 0; if(udpPacketBuffer[5] == PKTTYPE_GETINFO) { latency = tcpLatency(); } float longitude = 0; float latitude = 0; switch(udpPacketBuffer[5]) { case PKTTYPE_DISCOVERY: // Reply to discovery udpPacketBuffer[5] = PKTTYPE_DISCOVERY_REPLY; memcpy(udpPacketBuffer + 6, macaddress, 6); memcpy(udpPacketBuffer + 12, getVersionAsString().c_str(), 4); memcpy(udpPacketBuffer + 16, "uno", 3); break; case PKYTYPE_PING: // Reply to ping udpPacketBuffer[5] = PKYTYPE_PONG; break; case PKTTYPE_SENDGPS: // Get coords udpPacketBuffer[5] = PKTTYPE_OK; memcpy(&latitude, udpPacketBuffer + 12, 4); memcpy(&longitude, udpPacketBuffer + 16, 4); reverse4bytes((byte*)&latitude); reverse4bytes((byte*)&longitude); break; case PKTTYPE_REBOOT: // Reboot // Reply with OK udpPacketBuffer[5] = PKTTYPE_OK; reboot = true; break; case PKTTYPE_GETINFO: udpPacketBuffer[5] = PKTTYPE_GETINFO_REPLY; memcpy(udpPacketBuffer + 6, macaddress, 6); memcpy(udpPacketBuffer + 28, &uptime, 4); memcpy(udpPacketBuffer + 32, &unixTimeM, 4); memcpy(udpPacketBuffer + 36, VERSION, 4); memcpy(udpPacketBuffer + 40, &freeramkb, 4); memcpy(udpPacketBuffer + 44, &latency, 4); memcpy(udpPacketBuffer + 53, "uno", 3); memcpy(udpPacketBuffer + 57, "MMA7361", 7); memcpy(udpPacketBuffer + 65, &probeSpeed, 4); break; #ifdef RESET_ENABLED case PKTTYPE_RESET: initEEPROM(); reboot = true; break; #endif default: // Unknown packet or invalid command return; } if(longitude != 0 && latitude != 0) { setLongitude(longitude); setLatitude(latitude); } cmdsock.beginPacket(cmdsock.remoteIP(), cmdsock.remotePort()); cmdsock.write(udpPacketBuffer, PACKET_SIZE); cmdsock.endPacket(); cmdsock.flush(); if(reboot) { soft_restart(); } } }
SNMP_API_STAT_CODES AgentuinoClass::responsePdu(SNMP_PDU *pdu) { int32_u u; byte i; // // Length of entire SNMP packet _packetPos = 0; // 23 _packetSize = 25 + sizeof(pdu->requestId) + sizeof(pdu->error) + sizeof(pdu->errorIndex) + pdu->OID.size + pdu->VALUE.size; // memset(_packet, 0, SNMP_MAX_PACKET_LEN); // if ( _dstType == SNMP_PDU_SET ) { _packetSize += _setSize; } else { _packetSize += _getSize; } // _packet[_packetPos++] = (byte)SNMP_SYNTAX_SEQUENCE; // type _packet[_packetPos++] = (byte)_packetSize - 2; // length // // SNMP version _packet[_packetPos++] = (byte)SNMP_SYNTAX_INT; // type _packet[_packetPos++] = 0x01; // length _packet[_packetPos++] = 0x00; // value // // SNMP community string _packet[_packetPos++] = (byte)SNMP_SYNTAX_OCTETS; // type if ( _dstType == SNMP_PDU_SET ) { _packet[_packetPos++] = (byte)_setSize; // length for ( i = 0; i < _setSize; i++ ) { _packet[_packetPos++] = (byte)_setCommName[i]; } } else { _packet[_packetPos++] = (byte)_getSize; // length for ( i = 0; i < _getSize; i++ ) { _packet[_packetPos++] = (byte)_getCommName[i]; } } // // SNMP PDU _packet[_packetPos++] = (byte)pdu->type; _packet[_packetPos++] = (byte)( sizeof(pdu->requestId) + sizeof((int32_t)pdu->error) + sizeof(pdu->errorIndex) + pdu->OID.size + pdu->VALUE.size + 14 ); // // Request ID (size always 4 e.g. 4-byte int) _packet[_packetPos++] = (byte)SNMP_SYNTAX_INT; // type _packet[_packetPos++] = (byte)sizeof(pdu->requestId); u.int32 = pdu->requestId; _packet[_packetPos++] = u.data[3]; _packet[_packetPos++] = u.data[2]; _packet[_packetPos++] = u.data[1]; _packet[_packetPos++] = u.data[0]; // // Error (size always 4 e.g. 4-byte int) _packet[_packetPos++] = (byte)SNMP_SYNTAX_INT; // type _packet[_packetPos++] = (byte)sizeof((int32_t)pdu->error); u.int32 = pdu->error; _packet[_packetPos++] = u.data[3]; _packet[_packetPos++] = u.data[2]; _packet[_packetPos++] = u.data[1]; _packet[_packetPos++] = u.data[0]; // // Error Index (size always 4 e.g. 4-byte int) _packet[_packetPos++] = (byte)SNMP_SYNTAX_INT; // type _packet[_packetPos++] = (byte)sizeof(pdu->errorIndex); u.int32 = pdu->errorIndex; _packet[_packetPos++] = u.data[3]; _packet[_packetPos++] = u.data[2]; _packet[_packetPos++] = u.data[1]; _packet[_packetPos++] = u.data[0]; // // Varbind List _packet[_packetPos++] = (byte)SNMP_SYNTAX_SEQUENCE; // type _packet[_packetPos++] = (byte)( pdu->OID.size + pdu->VALUE.size + 6 ); //4 // // Varbind _packet[_packetPos++] = (byte)SNMP_SYNTAX_SEQUENCE; // type _packet[_packetPos++] = (byte)( pdu->OID.size + pdu->VALUE.size + 4 ); //2 // // ObjectIdentifier _packet[_packetPos++] = (byte)SNMP_SYNTAX_OID; // type _packet[_packetPos++] = (byte)(pdu->OID.size); for ( i = 0; i < pdu->OID.size; i++ ) { _packet[_packetPos++] = pdu->OID.data[i]; } // // Value _packet[_packetPos++] = (byte)pdu->VALUE.syntax; // type _packet[_packetPos++] = (byte)(pdu->VALUE.size); for ( i = 0; i < pdu->VALUE.size; i++ ) { _packet[_packetPos++] = pdu->VALUE.data[i]; } // Udp.beginPacket(Udp.remoteIP(), Udp.remotePort()); Udp.write(_packet, _packetSize); Udp.endPacket(); // Udp.write(_packet, _packetSize, _dstIp, _dstPort); // return SNMP_API_STAT_SUCCESS; }
void loop() { if ((unsigned long) (millis() - previousEth) >= interval_ethernet) { //entra a cada 50ms previousEth = millis(); if(count_eth == 0) { //espera completar um ciclo de todas as funções chamadas int packetSize = Udp.parsePacket(); count_eth = 2; Serial.println("entrou eth"); received = 0; if (packetSize) { set_debug(PC3); #ifdef debug Serial.println("entrou eth RX "); Serial.print("Received packet of size "); Serial.println(packetSize); Serial.print("From "); IPAddress remote = Udp.remoteIP(); for (int i =0; i < 4; i++) { Serial.print(remote[i], DEC); if (i < 3) { Serial.print("."); } } Serial.print(", port "); Serial.println(Udp.remotePort()); Serial.println("Contents:"); Serial.println(packetBuffer); #endif received = Udp.read(); charBuffer.put(received); #ifdef debug Serial.println("\rchar recebido:"); Serial.write(received); #endif ///////////////////////////// clear_debug(PC3); } } else { count_eth--; Serial.println("entrou eth NADA"); if (charBuffer.getSize() > 5) charBuffer.clear(); if( charBuffer.getSize() > 0 ) received = charBuffer.get(); Serial.println("received:"); Serial.println(received); } } #ifdef debug Serial.println("client disconnected"); #endif /****************FIM ROTINA ETHERNET ***************************************************/ if ((unsigned long) (millis() - previousADC) >= interval_adc) { //entra a cada 60ms previousADC = millis(); set_debug(PC4); if (count_adc == 0) { count_adc = 1; /*testa obstaculo IR*/ Serial.println("entrou adc OBSTACULO "); IR_obstaculo = 0; IR_obstaculo = verificaObstaculoIR(); #ifdef debug Serial.println("distancia_ir"); Serial.println(IR_obstaculo); Serial.println("\r"); #endif if (IR_obstaculo > IR_OBSTACLE_THRESHOLD) obstacle_flag = 0; else if (IR_obstaculo > IR_OBSTACLE_THRESHOLD && IR_obstaculo < IR_OBSTACLE_UPPER_THRESHOLD) obstacle_flag = 1; else if (IR_obstaculo <= IR_OBSTACLE_THRESHOLD) obstacle_flag = 2; clear_debug(PC4); } else { count_adc=0; Serial.println("entrou adc NADA "); } } /***************** FIM ROTINA ADC********************************/ if ((unsigned long) (millis() - previousMotores) >= interval_motores) { //entra a cada 100ms previousMotores = millis(); if (ciclosClock_motor == 2) { //duas bordas de subida depois de acionar o motor (200ms depois de acionar o motor) Serial.println("motor stop "); stopMove(); ciclosClock_motor = 0; } if (count_motor == 0) { Serial.println("motor ANDA "); if (obstacle_flag == 0 || obstacle_flag == 1) { count_motor = 1; /*move motores*/ switch (received) { case 'u': goForward(obstacle_flag); break; case 'd': goBack(obstacle_flag); break; case 'l': goLeft(obstacle_flag); break; case 'r': goRight(obstacle_flag); break; default: received = 0; stopMove(); break; } } else { if (received == 'd') { goBack(WITH_CARE); } else { stopMove(); } } } else { ciclosClock_motor++; count_motor = 0; Serial.println("ciclosClock_motor++ "); } } // _delay_ms(500); }
IPAddress SNMPClass::remoteIP(){ return Udp.remoteIP(); }