示例#1
0
void AgentuinoClass::listen(void) {
    // if bytes are available in receive buffer
    // and pointer to a function (delegate function)
    // isn't null, trigger the function
    Udp.parsePacket();
    if (Udp.available() && _callback != NULL) (*_callback)();
}
unsigned long getNtpTime()
{
	// We need to call the begin to reset the socket.
	// Because localClient.connect() may occupy the same socket.
	EthernetUDP theUDP;
	theUDP.begin(localPort);

	Serial.println("Sending time sync request to NTP server.");
	sendNTPpacket(timeServer); // send an NTP packet to a time server

	unsigned long startMillis = millis();
	int tryCounter = 1;
	while( millis() - startMillis < 1000)  // wait up to one second for the response
	{  // wait to see if a reply is available
		if ( theUDP.available() )
		{
			theUDP.readPacket(packetBuffer,NTP_PACKET_SIZE);  // read the packet into the buffer

			//the timestamp starts at byte 40 of the received packet and is four bytes,
			// or two words, long. First, esxtract the two words:
			unsigned long highWord = word(packetBuffer[40], packetBuffer[41]);
			unsigned long lowWord = word(packetBuffer[42], packetBuffer[43]);
			// combine the four bytes (two words) into a long integer
			// this is NTP time (seconds since Jan 1 1900):
			unsigned long secsSince1900 = highWord << 16 | lowWord;
			// now convert NTP time into Arduino Time format:
			// Time starts on Jan 1 1970. In seconds, that's 2208988800:
			const unsigned long seventyYears = 2208988800UL;
			// subtract seventy years:
			unsigned long epoch = secsSince1900 - seventyYears;

			Serial.println("Time sync successfully.");

			return epoch;
		}

		Serial.print("No date data available. Try counter: .");
		Serial.println(tryCounter++);
		delay(100);
	}

	Serial.println("Time sync failed.");

	return 0;   // return 0 if unable to get the time
}
示例#3
0
boolean SNMPClass::listen(void)
{
  // if bytes are available in receive buffer
  // and pointer to a function (delegate function)
  // isn't null, trigger the function
  
  if(Udp.parsePacket() > 1024){
    _udp_extra_data_packet = true;
  }else{
    _udp_extra_data_packet = false;
  }
  
  if (Udp.available()){
    if(_callback != NULL){
      (*_callback)();
    }else{
      return true;
    }
  }
  
  return false;
}
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();
    }
  }
}
示例#5
0
uint64_t getNTPtime()
{
    // send an NTP packet to a time server
    sendNTPpacket(timeServer);

    // wait to see if a reply is available
    delay(1000);
    if ( Udp.available() )
    {
        // read the packet into the buffer
        Udp.read(pb, NTP_PACKET_SIZE);      // New from IDE 1.0,

        // NTP contains four timestamps with an integer part and a fraction part
        // we only use the integer part here
        unsigned long t1, t2, t3, t4;
        t1 = t2 = t3 = t4 = 0;
        for (int i=0; i< 4; i++)
        {
            t1 = t1 << 8 | pb[16+i];
            t2 = t2 << 8 | pb[24+i];
            t3 = t3 << 8 | pb[32+i];
            t4 = t4 << 8 | pb[40+i];
        }

        // part of the fractional part
        // could be 4 bytes but this is more precise than the 1307 RTC
        // which has a precision of ONE second
        // in fact one byte is sufficient for 1307
        float f1,f2,f3,f4;
        f1 = ((long)pb[20] * 256 + pb[21]) / 65536.0;
        f2 = ((long)pb[28] * 256 + pb[29]) / 65536.0;
        f3 = ((long)pb[36] * 256 + pb[37]) / 65536.0;
        f4 = ((long)pb[44] * 256 + pb[45]) / 65536.0;

        // NOTE:
        // one could use the fractional part to set the RTC more precise
        // 1) at the right (calculated) moment to the NEXT second!
        //    t4++;
        //    delay(1000 - f4*1000);
        //    RTC.adjust(DateTime(t4));
        //    keep in mind that the time in the packet was the time at
        //    the NTP server at sending time so one should take into account
        //    the network latency (try ping!) and the processing of the data
        //    ==> delay (850 - f4*1000);
        // 2) simply use it to round up the second
        //    f > 0.5 => add 1 to the second before adjusting the RTC
        //   (or lower threshold eg 0.4 if one keeps network latency etc in mind)
        // 3) a SW RTC might be more precise, => ardomic clock :)


        // convert NTP to UNIX time, differs seventy years = 2208988800 seconds
        // NTP starts Jan 1, 1900
        // Unix time starts on Jan 1 1970.
        const unsigned long seventyYears = 2208988800UL;
        t1 -= seventyYears;
        t2 -= seventyYears;
        t3 -= seventyYears;
        t4 -= seventyYears;


        //Serial.println("T1 .. T4 && fractional parts");
        //PrintDateTime(DateTime(t1)); Serial.println(f1,4);
        //PrintDateTime(DateTime(t2)); Serial.println(f2,4);
        //PrintDateTime(DateTime(t3)); Serial.println(f3,4);

        //PrintDateTime(t4);
        char ntpTime[21];
        //GetDatetimeString(t4, ntpTime);
        Serial.println(f4,4);
        Serial.println();

        // Adjust timezone and DST... in my case substract 4 hours for Chile Time
        // or work in UTC?
        t4 -= (3 * 3600L);     // Notice the L for long calculations!!
        t4 += 1;               // adjust the delay(1000) at begin of loop!
        if (f4 > 0.4) t4++;    // adjust fractional part, see above
    }

    else
    {
        Serial.println("Failed to get NTP UDP packet!");
    }
}
bool gatewayTransportSend(MyMessage &message)
{
	bool ret = true;
	char *_ethernetMsg = protocolFormat(message);

    setIndication(INDICATION_GW_TX);

	_w5100_spi_en(true);
	#if defined(MY_CONTROLLER_IP_ADDRESS)
		#if defined(MY_USE_UDP)
			_ethernetServer.beginPacket(_ethernetControllerIP, MY_PORT);
			_ethernetServer.write(_ethernetMsg, strlen(_ethernetMsg));
			// returns 1 if the packet was sent successfully
			ret = _ethernetServer.endPacket();
		#else
			EthernetClient client;
			#if defined(MY_CONTROLLER_URL_ADDRESS)
	                	if (client.connected() || client.connect(MY_CONTROLLER_URL_ADDRESS, MY_PORT)) {
	        	#else
	                	if (client.connected() || client.connect(_ethernetControllerIP, MY_PORT)) {
	        	#endif
	                	client.write(_ethernetMsg, strlen(_ethernetMsg));
	                }
	                else {
	                	// connecting to the server failed!
	                	ret = false;
	                }
		#endif
	#else
		// Send message to connected clients
		#if defined(MY_GATEWAY_ESP8266)
			for (uint8_t i = 0; i < ARRAY_SIZE(clients); i++)
			{
				if (clients[i] && clients[i].connected())
				{
					clients[i].write((uint8_t*)_ethernetMsg, strlen(_ethernetMsg));
				}
			}
		#else
			_ethernetServer.write(_ethernetMsg);
		#endif
	#endif
	_w5100_spi_en(false);
	return ret;

}


#if defined(MY_GATEWAY_ESP8266)
	bool _readFromClient(uint8_t i) {
		while (clients[i].connected() && clients[i].available()) {
			char inChar = clients[i].read();
			if (inputString[i].idx < MY_GATEWAY_MAX_RECEIVE_LENGTH - 1) {
				// if newline then command is complete
				if (inChar == '\n' || inChar == '\r') {
					// Add string terminator and prepare for the next message
					inputString[i].string[inputString[i].idx] = 0;
					debug(PSTR("Client %d: %s\n"), i, inputString[i].string);
					inputString[i].idx = 0;
					if (protocolParse(_ethernetMsg, inputString[i].string)) {
						return true;
					}

				} else {
					// add it to the inputString:
					inputString[i].string[inputString[i].idx++] = inChar;
				}
			} else {
				// Incoming message too long. Throw away
				debug(PSTR("Client %d: Message too long\n"), i);
				inputString[i].idx = 0;
				// Finished with this client's message. Next loop() we'll see if there's more to read.
				break;
			}
		}
		return false;
	}
#else
	bool _readFromClient() {
		while (client.connected() && client.available()) {
			char inChar = client.read();
			if (inputString.idx < MY_GATEWAY_MAX_RECEIVE_LENGTH - 1) {
				// if newline then command is complete
				if (inChar == '\n' || inChar == '\r') {
					// Add string terminator and prepare for the next message
					inputString.string[inputString.idx] = 0;
					debug(PSTR("Eth: %s\n"), inputString.string);
					inputString.idx = 0;
					if (protocolParse(_ethernetMsg, inputString.string)) {
						return true;
					}

				} else {
					// add it to the inputString:
					inputString.string[inputString.idx++] = inChar;
				}
			} else {
				// Incoming message too long. Throw away
				debug(PSTR("Eth: Message too long\n"));
				inputString.idx = 0;
				// Finished with this client's message. Next loop() we'll see if there's more to read.
				break;
			}
		}
		return false;
	}
#endif


bool gatewayTransportAvailable()
{
	_w5100_spi_en(true);
	#if !defined(MY_IP_ADDRESS) && defined(MY_GATEWAY_W5100)
		// renew IP address using DHCP
		gatewayTransportRenewIP();
	#endif

	#ifdef MY_USE_UDP

		int packet_size = _ethernetServer.parsePacket();

		if (packet_size) {
			//debug(PSTR("UDP packet available. Size:%d\n"), packet_size);
            setIndication(INDICATION_GW_RX);
			#if defined(MY_GATEWAY_ESP8266)
				_ethernetServer.read(inputString[0].string, MY_GATEWAY_MAX_RECEIVE_LENGTH);
				inputString[0].string[packet_size] = 0;
				debug(PSTR("UDP packet received: %s\n"), inputString[0].string);
				return protocolParse(_ethernetMsg, inputString[0].string);
			#else
				_ethernetServer.read(inputString.string, MY_GATEWAY_MAX_RECEIVE_LENGTH);
				inputString.string[packet_size] = 0;
				debug(PSTR("UDP packet received: %s\n"), inputString.string);
				_w5100_spi_en(false);
				return protocolParse(_ethernetMsg, inputString.string);
			#endif
		}
	#else
		#if defined(MY_GATEWAY_ESP8266)
			// ESP8266: Go over list of clients and stop any that are no longer connected.
			// If the server has a new client connection it will be assigned to a free slot.
			bool allSlotsOccupied = true;
			for (uint8_t i = 0; i < ARRAY_SIZE(clients); i++) {
				if (!clients[i].connected()) {
					if (clientsConnected[i]) {
						debug(PSTR("Client %d disconnected\n"), i);
						clients[i].stop();
					}
					//check if there are any new clients
					if (_ethernetServer.hasClient()) {
						clients[i] = _ethernetServer.available();
						inputString[i].idx = 0;
						debug(PSTR("Client %d connected\n"), i);
						gatewayTransportSend(buildGw(_msg, I_GATEWAY_READY).set("Gateway startup complete."));
						if (presentation)
							presentation();
					}
				}
				bool connected = clients[i].connected();
				clientsConnected[i] = connected;
				allSlotsOccupied &= connected;
			}
			if (allSlotsOccupied && _ethernetServer.hasClient()) {
				//no free/disconnected spot so reject
				debug(PSTR("No free slot available\n"));
				EthernetClient c = _ethernetServer.available();
				c.stop();
			}
				// Loop over clients connect and read available data
			for (uint8_t i = 0; i < ARRAY_SIZE(clients); i++) {
				if (_readFromClient(i)) {
                    setIndication(INDICATION_GW_RX);
					_w5100_spi_en(false);
					return true;
				}
			}
		#else
			// W5100/ENC module does not have hasClient-method. We can only serve one client at the time.
			EthernetClient newclient = _ethernetServer.available();
			// if a new client connects make sure to dispose any previous existing sockets
			if (newclient) {
				if (client != newclient) {
					client.stop();
					client = newclient;
					debug(PSTR("Eth: connect\n"));
					_w5100_spi_en(false);
					gatewayTransportSend(buildGw(_msg, I_GATEWAY_READY).set("Gateway startup complete."));
					_w5100_spi_en(true);
					if (presentation)
						presentation();
				}
			}
			if (client) {
				if (!client.connected()) {
					debug(PSTR("Eth: disconnect\n"));
					client.stop();
				} else {
					if (_readFromClient()) {
                        setIndication(INDICATION_GW_RX);
						_w5100_spi_en(false);
						return true;
					}
				}
			}
		#endif
	#endif
	_w5100_spi_en(false);
	return false;
}
示例#7
0
SNMP_API_STAT_CODES AgentuinoClass::requestPdu(SNMP_PDU *pdu)
{
	char *community;
	// sequence length
	byte seqLen;
	// version
	byte verLen, verEnd;
	// community string
	byte comLen, comEnd;
	// pdu
	byte pduTyp, pduLen;
	byte ridLen, ridEnd;
	byte errLen, errEnd;
	byte eriLen, eriEnd;
	byte vblTyp, vblLen;
	byte vbiTyp, vbiLen;
	byte obiLen, obiEnd;
	byte valTyp, valLen, valEnd;
	byte i;
	//
	// set packet packet size (skip UDP header)
	_packetSize = Udp.available();
	//
	// reset packet array
	memset(_packet, 0, SNMP_MAX_PACKET_LEN);
	//
	// validate packet
	if ( _packetSize != 0 && _packetSize > SNMP_MAX_PACKET_LEN ) {
		//
		//SNMP_FREE(_packet);

		return SNMP_API_STAT_PACKET_TOO_BIG;
	}
	//
	// get UDP packet
	//Udp.parsePacket();
	Udp.read(_packet, _packetSize);
// 	Udp.readPacket(_packet, _packetSize, _dstIp, &_dstPort);
	//
	// packet check 1
	if ( _packet[0] != 0x30 ) {
		//
		//SNMP_FREE(_packet);

		return SNMP_API_STAT_PACKET_INVALID;
	}
	//
	// sequence length
	seqLen = _packet[1];
	// version
	verLen = _packet[3];
	verEnd = 3 + verLen;
	// community string
	comLen = _packet[verEnd + 2];
	comEnd = verEnd + 2 + comLen;
	// pdu
	pduTyp = _packet[comEnd + 1];
	pduLen = _packet[comEnd + 2];
	ridLen = _packet[comEnd + 4];
	ridEnd = comEnd + 4 + ridLen;
	errLen = _packet[ridEnd + 2];
	errEnd = ridEnd + 2 + errLen;
	eriLen = _packet[errEnd + 2];
	eriEnd = errEnd + 2 + eriLen;
	vblTyp = _packet[eriEnd + 1];
	vblLen = _packet[eriEnd + 2];
	vbiTyp = _packet[eriEnd + 3];
	vbiLen = _packet[eriEnd + 4];
	obiLen = _packet[eriEnd + 6];
	obiEnd = eriEnd + obiLen + 6;
	valTyp = _packet[obiEnd + 1];
	valLen = _packet[obiEnd + 2];
	valEnd = obiEnd + 2 + valLen;
	//
	// extract version
	pdu->version = 0;
	for ( i = 0; i < verLen; i++ ) {
		pdu->version = (pdu->version << 8) | _packet[5 + i];
	}
	//
	// validate version
	//
	// pdu-type
	pdu->type = (SNMP_PDU_TYPES)pduTyp;
	_dstType = pdu->type;
	//
	// validate community size
	if ( comLen > SNMP_MAX_NAME_LEN ) {
		// set pdu error
		pdu->error = SNMP_ERR_TOO_BIG;
		//
		return SNMP_API_STAT_NAME_TOO_BIG;
	}
	//
	//
	// validate community name
	if ( pdu->type == SNMP_PDU_SET && comLen == _setSize ) {
		//
		for ( i = 0; i < _setSize; i++ ) {
			if( _packet[verEnd + 3 + i] != (byte)_setCommName[i] ) {
				// set pdu error
				pdu->error = SNMP_ERR_NO_SUCH_NAME;
				//
				return SNMP_API_STAT_NO_SUCH_NAME;
			}
		}
	} else if ( pdu->type == SNMP_PDU_GET && comLen == _getSize ) {
		//
		for ( i = 0; i < _getSize; i++ ) {
			if( _packet[verEnd + 3 + i] != (byte)_getCommName[i] ) {
				// set pdu error
				pdu->error = SNMP_ERR_NO_SUCH_NAME;
				//
				return SNMP_API_STAT_NO_SUCH_NAME;
			}
		}
	} else if ( pdu->type == SNMP_PDU_GET_NEXT && comLen == _getSize ) {
		//
		for ( i = 0; i < _getSize; i++ ) {
			if( _packet[verEnd + 3 + i] != (byte)_getCommName[i] ) {
				// set pdu error
				pdu->error = SNMP_ERR_NO_SUCH_NAME;
				//
				return SNMP_API_STAT_NO_SUCH_NAME;
			}
		}
	} else {
		// set pdu error
		pdu->error = SNMP_ERR_NO_SUCH_NAME;
		//
		return SNMP_API_STAT_NO_SUCH_NAME;
	}
	//
	//
	// extract reqiest-id 0x00 0x00 0x00 0x01 (4-byte int aka int32)
	pdu->requestId = 0;
	for ( i = 0; i < ridLen; i++ ) {
		pdu->requestId = (pdu->requestId << 8) | _packet[comEnd + 5 + i];
	}
	//
	// extract error 
	pdu->error = SNMP_ERR_NO_ERROR;
	int32_t err = 0;
	for ( i = 0; i < errLen; i++ ) {
		err = (err << 8) | _packet[ridEnd + 3 + i];
	}
	pdu->error = (SNMP_ERR_CODES)err;
	//
	// extract error-index 
	pdu->errorIndex = 0;
	for ( i = 0; i < eriLen; i++ ) {
		pdu->errorIndex = (pdu->errorIndex << 8) | _packet[errEnd + 3 + i];
	}
	//
	//
	// validate object-identifier size
	if ( obiLen > SNMP_MAX_OID_LEN ) {
		// set pdu error
		pdu->error = SNMP_ERR_TOO_BIG;

		return SNMP_API_STAT_OID_TOO_BIG;
	}
	//
	// extract and contruct object-identifier
	memset(pdu->OID.data, 0, SNMP_MAX_OID_LEN);
	pdu->OID.size = obiLen;
	for ( i = 0; i < obiLen; i++ ) {
		pdu->OID.data[i] = _packet[eriEnd + 7 + i];
	}
	//
	// value-type
	pdu->VALUE.syntax = (SNMP_SYNTAXES)valTyp;
	//
	// validate value size
	if ( obiLen > SNMP_MAX_VALUE_LEN ) {
		// set pdu error
		pdu->error = SNMP_ERR_TOO_BIG;

		return SNMP_API_STAT_VALUE_TOO_BIG;
	}
	//
	// value-size
	pdu->VALUE.size = valLen;
	//
	// extract value
	memset(pdu->VALUE.data, 0, SNMP_MAX_VALUE_LEN);
	for ( i = 0; i < valLen; i++ ) {
		pdu->VALUE.data[i] = _packet[obiEnd + 3 + i];
	}
	//
	return SNMP_API_STAT_SUCCESS;
}
示例#8
0
/**
   * Parses incoming SNMP messages.
   *
   * Original Auther: Rex Park
   * Updated: November 7, 2015 (Added support for Inform responses (SNMP_PDU_RESPONSE)
   */
SNMP_API_STAT_CODES SNMPClass::requestPdu(SNMP_PDU *pdu, char *extra_data, int extra_data_max_size)
{
  // sequence length
  uint16_t seqLen, valLen, vblLen, pduLen;
  // version
  byte verLen, verEnd;
  // community string
  byte comLen, comEnd;
  // pdu
  byte pduTyp, pduEnd;
  byte ridLen, ridEnd;
  byte errLen, errEnd;
  byte eriLen, eriEnd;
  byte vblTyp;
  byte vbiTyp, vbiLen;
  byte obiLen, obiEnd;
  byte valTyp, valEnd;
  int i;

  // set packet packet size (skip UDP header)
  _packetSize = Udp.available();
  _packetPos = 0;

  // reset packet array
  memset(_packet, 0, SNMP_MAX_PACKET_LEN);
  //
  // validate packet
  if ( _packetSize <= 0) {
    return SNMP_API_STAT_PACKET_TOO_BIG;
  }
  
  // get UDP packet
  if(_udp_extra_data_packet == true){

    if(extra_data != NULL){
      memset(extra_data, 0, extra_data_max_size);
    }
    
    Udp.read(_packet, _packetSize - extra_data_max_size);

    if(extra_data != NULL){
      Udp.read((byte*)extra_data, extra_data_max_size);
    }
  }else{
    Udp.read(_packet, _packetSize);
  }
  
//  Serial.println("Incomming: ");
//  for(int i = 0; i < _packetSize; i++){
//    Serial.print(_packet[i],HEX);
//    Serial.print(" ");
//  }
//  Serial.println();

  // packet check 1
  if ( _packet[0] != 0x30 ) {
    return SNMP_API_STAT_PACKET_INVALID;
  }
  

  // sequence length
  if(_packet[1] >= 0x82){
    seqLen = combine_msb_lsb(_packet[2], _packet[3]);
    _packetPos = 4;
  }
  else if(_packet[1] == 0x81){
    seqLen = _packet[2];
    _packetPos = 3;
  }else{
    seqLen = _packet[1];
    _packetPos = 2;
  }
  
  // version
  if(_packet[_packetPos] != 0x02){
    return SNMP_API_STAT_PACKET_INVALID;
  }
  
  verLen = _packet[_packetPos+1];//used to be hard coded as index 3
  verEnd = _packetPos+1 + verLen;
  
  // community string
  comLen = _packet[verEnd + 2];
  comEnd = verEnd + 2 + comLen;
  
  // pdu
  pduTyp = _packet[comEnd + 1];
  if(_packet[comEnd + 2] >= 0x82){
    pduLen = combine_msb_lsb(_packet[comEnd +3], _packet[comEnd +4]);
    pduEnd = comEnd + 2 + pduLen + 2;
    _packetPos = comEnd + 2 + 2;
  }
  else if(_packet[comEnd + 2] == 0x81){
    pduLen = _packet[comEnd +3];
    pduEnd = comEnd + 2 + pduLen + 1;
    _packetPos = comEnd + 2 + 1;
  }else{
    pduLen = _packet[comEnd + 2];
    pduEnd = comEnd + 2 + pduLen;
    _packetPos = comEnd + 2;
  }
  
  //request id
  ridLen = _packet[_packetPos + 2];
  ridEnd = _packetPos + 2 + ridLen;
  
  //error
  errLen = _packet[ridEnd + 2];
  errEnd = ridEnd + 2 + errLen;
  
  //error index
  eriLen = _packet[errEnd + 2];
  eriEnd = errEnd + 2 + eriLen;
  
  //variable bindings
  vblTyp = _packet[eriEnd + 1];
  if(_packet[eriEnd + 2] >= 0x82){
    vblLen = combine_msb_lsb(_packet[eriEnd +3], _packet[eriEnd +4]);
    _packetPos = eriEnd + 2 + 2;
  }
  else if(_packet[eriEnd + 2] == 0x81){
    vblLen = _packet[eriEnd +3];
    _packetPos = eriEnd + 2 + 1;
  }else{
    vblLen = _packet[eriEnd + 2];
    _packetPos = eriEnd + 2;
  }
  
  //variable bindings id
  vbiTyp = _packet[_packetPos + 1];
  if(_packet[_packetPos + 2] > 0x80){
    vbiLen = combine_msb_lsb(_packet[_packetPos +3], _packet[_packetPos +4]);
    _packetPos = _packetPos + 2 + 2;
  }else{
    vbiLen = _packet[_packetPos + 2];
    _packetPos = _packetPos + 2;
  }
  
  //object identifier
  obiLen = _packet[_packetPos + 2];
  obiEnd = _packetPos + 2 + obiLen;
  
  //unknown
  valTyp = _packet[obiEnd + 1];

  if(_packet[obiEnd + 2] >= 0x82){
    valLen = combine_msb_lsb(_packet[obiEnd +3], _packet[obiEnd +4]);
    valEnd = obiEnd + 2 + valLen + 2;
  }
  else if(_packet[obiEnd + 2] == 0x81){
    valLen = _packet[obiEnd + 3];
    valEnd = obiEnd + 2 + valLen + 1;
  }else{
    valLen = _packet[obiEnd + 2];
    valEnd = obiEnd + 2 + valLen;
  }
  
//  Serial.println(verEnd);
//  Serial.println(comEnd);
//  Serial.println(ridEnd);
//  Serial.println(errEnd);
//  Serial.println(eriEnd);
//  Serial.println(obiEnd);
//  Serial.println(pduEnd);
//  Serial.println(pduTyp,HEX);

  // extract version
  pdu->version = _packet[verEnd];
//  Serial.println(pdu->version,HEX);
  // validate version
  if(pdu->version != 0x0 && pdu->version != 0x1){
    return SNMP_API_STAT_PACKET_INVALID;
  }

  // pdu-type
  pdu->type = (SNMP_PDU_TYPES)pduTyp;
  _dstType = pdu->type;
  
  // validate community size
  if ( comLen > SNMP_MAX_NAME_LEN ) {
    // set pdu error
    pdu->error = SNMP_ERR_TOO_BIG;
    //
    return SNMP_API_STAT_NAME_TOO_BIG;
  }

  // validate community name
  if ( pdu->type == SNMP_PDU_SET && comLen == _setSize ) {
  	if(memcmp(_setCommName,_packet+verEnd+3,_setSize) != 0){
  		pdu->error = SNMP_ERR_NO_SUCH_NAME;
  		return SNMP_API_STAT_NO_SUCH_NAME;
  	}
  } else if ( pdu->type == SNMP_PDU_GET) {
  	if(memcmp(_getCommName,_packet+verEnd+3,comLen) != 0 && memcmp(_setCommName,_packet+verEnd+3,comLen) != 0){
  		pdu->error = SNMP_ERR_NO_SUCH_NAME;
  		return SNMP_API_STAT_NO_SUCH_NAME;
  	}
  } else if (pdu->type == SNMP_PDU_RESPONSE){
    if(memcmp(_trapCommName,_packet+verEnd+3,comLen) != 0){
      pdu->error = SNMP_ERR_NO_SUCH_NAME;
      return SNMP_API_STAT_NO_SUCH_NAME;
    }
  }
  else {
    // set pdu error
    pdu->error = SNMP_ERR_NO_SUCH_NAME;
    //
    return SNMP_API_STAT_NO_SUCH_NAME;
  }

  // extract reqiest-id 0x00 0x00 0x00 0x01 (4-byte int aka int32)
  pdu->requestId = 0;
  for ( i = 0; i < ridLen; i++ ) {
    pdu->requestId = (pdu->requestId << 8) | _packet[ridEnd-ridLen+1 + i];
  }

  // extract error 
  pdu->error = SNMP_ERR_NO_ERROR;
  int32_t err = 0;
  for ( i = 0; i < errLen; i++ ) {
    err = (err << 8) | _packet[errEnd-errLen+1 + i];
  }
  pdu->error = (SNMP_ERR_CODES)err;

  // extract error-index 
  pdu->errorIndex = 0;
  for ( i = 0; i < eriLen; i++ ) {
    pdu->errorIndex = (pdu->errorIndex << 8) | _packet[eriEnd-eriLen+1 + i];
  }

  /**
   * OID 
   */
  //validate length
  if ( obiLen > SNMP_MAX_OID_LEN ) {
    pdu->error = SNMP_ERR_TOO_BIG;
    return SNMP_API_STAT_OID_TOO_BIG;
  }
  //decode OID
  memset(pdu->value.OID.data, 0, SNMP_MAX_OID_LEN);
  if(pdu->value.OID.decode(_packet + (obiEnd-obiLen+1), obiLen) != SNMP_API_STAT_SUCCESS){
    return SNMP_API_STAT_MALLOC_ERR;
  }

  /**
   * Value 
   */
  //syntax type
  pdu->value.syntax = (SNMP_SYNTAXES)valTyp;
  //check length of data

  if ( valLen > SNMP_MAX_VALUE_LEN && _udp_extra_data_packet == false) {
    pdu->error = SNMP_ERR_TOO_BIG;
    return SNMP_API_STAT_VALUE_TOO_BIG;
  }
  //set value size
  pdu->value.size = valLen;
  
  if(_udp_extra_data_packet == true){
//    memset(extra_data, '\0', extra_data_max_size);
//    for ( i = 0; i < valLen; i++ ) {
//      extra_data[i] = _packet[obiEnd+3 + i];
//    }    
  }else{
    memset(pdu->value.data, 0, SNMP_MAX_VALUE_LEN);
    for ( i = 0; i < valLen; i++ ) {
      pdu->value.data[i] = _packet[obiEnd+3 + i];
    }    
  }

  return SNMP_API_STAT_SUCCESS;
}