// DHCP Library v0.3 - April 25, 2009 // Author: Jordan Terrell - blog.jordanterrell.com #include "w5100.h" #include #include #include "Dhcp.h" #include "Arduino.h" #include "util.h" int DhcpClass::beginWithDHCP(uint8_t *mac, unsigned long timeout, unsigned long responseTimeout) { uint8_t dhcp_state = STATE_DHCP_START; uint8_t messageType = 0; // zero out _dhcpMacAddr, _dhcpSubnetMask, _dhcpGatewayIp, _dhcpLocalIp, _dhcpDhcpServerIp, _dhcpDnsServerIp memset(_dhcpMacAddr, 0, 26); memcpy((void*)_dhcpMacAddr, (void*)mac, 6); // Pick an initial transaction ID _dhcpTransactionId = random(1UL, 2000UL); _dhcpInitialTransactionId = _dhcpTransactionId; if (_dhcpUdpSocket.begin(DHCP_CLIENT_PORT) == 0) { // Couldn't get a socket return 0; } presend_DHCP(); int result = 0; unsigned long startTime = millis(); while(dhcp_state != STATE_DHCP_LEASED) { if(dhcp_state == STATE_DHCP_START) { _dhcpTransactionId++; send_DHCP_MESSAGE(DHCP_DISCOVER, ((millis() - startTime) / 1000)); dhcp_state = STATE_DHCP_DISCOVER; } else if(dhcp_state == STATE_DHCP_DISCOVER) { uint32_t respId; messageType = parseDHCPResponse(responseTimeout, respId); if(messageType == DHCP_OFFER) { // We'll use the transaction ID that the offer came with, // rather than the one we were up to _dhcpTransactionId = respId; send_DHCP_MESSAGE(DHCP_REQUEST, ((millis() - startTime) / 1000)); dhcp_state = STATE_DHCP_REQUEST; } } else if(dhcp_state == STATE_DHCP_REQUEST) { uint32_t respId; messageType = parseDHCPResponse(responseTimeout, respId); if(messageType == DHCP_ACK) { dhcp_state = STATE_DHCP_LEASED; result = 1; } else if(messageType == DHCP_NAK) dhcp_state = STATE_DHCP_START; } if(messageType == 255) { messageType = 0; dhcp_state = STATE_DHCP_START; } if(result != 1 && ((millis() - startTime) > timeout)) break; } // We're done with the socket now _dhcpUdpSocket.stop(); _dhcpTransactionId++; return result; } void DhcpClass::presend_DHCP() { } void DhcpClass::send_DHCP_MESSAGE(uint8_t messageType, uint16_t secondsElapsed) { uint8_t buffer[32]; memset(buffer, 0, 32); IPAddress dest_addr( 255, 255, 255, 255 ); // Broadcast address if (-1 == _dhcpUdpSocket.beginPacket(dest_addr, DHCP_SERVER_PORT)) { // FIXME Need to return errors return; } buffer[0] = DHCP_BOOTREQUEST; // op buffer[1] = DHCP_HTYPE10MB; // htype buffer[2] = DHCP_HLENETHERNET; // hlen buffer[3] = DHCP_HOPS; // hops // xid unsigned long xid = htonl(_dhcpTransactionId); memcpy(buffer + 4, &(xid), 4); // 8, 9 - seconds elapsed buffer[8] = ((secondsElapsed & 0xff00) >> 8); buffer[9] = (secondsElapsed & 0x00ff); // flags unsigned short flags = htons(DHCP_FLAGSBROADCAST); memcpy(buffer + 10, &(flags), 2); // ciaddr: already zeroed // yiaddr: already zeroed // siaddr: already zeroed // giaddr: already zeroed //put data in W5100 transmit buffer _dhcpUdpSocket.write(buffer, 28); memset(buffer, 0, 32); // clear local buffer memcpy(buffer, _dhcpMacAddr, 6); // chaddr //put data in W5100 transmit buffer _dhcpUdpSocket.write(buffer, 16); memset(buffer, 0, 32); // clear local buffer // leave zeroed out for sname && file // put in W5100 transmit buffer x 6 (192 bytes) for(int i = 0; i < 6; i++) { _dhcpUdpSocket.write(buffer, 32); } // OPT - Magic Cookie buffer[0] = (uint8_t)((MAGIC_COOKIE >> 24)& 0xFF); buffer[1] = (uint8_t)((MAGIC_COOKIE >> 16)& 0xFF); buffer[2] = (uint8_t)((MAGIC_COOKIE >> 8)& 0xFF); buffer[3] = (uint8_t)(MAGIC_COOKIE& 0xFF); // OPT - message type buffer[4] = dhcpMessageType; buffer[5] = 0x01; buffer[6] = messageType; //DHCP_REQUEST; // OPT - client identifier buffer[7] = dhcpClientIdentifier; buffer[8] = 0x07; buffer[9] = 0x01; memcpy(buffer + 10, _dhcpMacAddr, 6); // OPT - host name buffer[16] = hostName; buffer[17] = strlen(HOST_NAME) + 3; // length of hostname + last 3 bytes of mac address strcpy((char*)&(buffer[18]), HOST_NAME); buffer[24] = _dhcpMacAddr[3]; buffer[25] = _dhcpMacAddr[4]; buffer[26] = _dhcpMacAddr[5]; //put data in W5100 transmit buffer _dhcpUdpSocket.write(buffer, 27); if(messageType == DHCP_REQUEST) { buffer[0] = dhcpRequestedIPaddr; buffer[1] = 0x04; buffer[2] = _dhcpLocalIp[0]; buffer[3] = _dhcpLocalIp[1]; buffer[4] = _dhcpLocalIp[2]; buffer[5] = _dhcpLocalIp[3]; buffer[6] = dhcpServerIdentifier; buffer[7] = 0x04; buffer[8] = _dhcpDhcpServerIp[0]; buffer[9] = _dhcpDhcpServerIp[1]; buffer[10] = _dhcpDhcpServerIp[2]; buffer[11] = _dhcpDhcpServerIp[3]; //put data in W5100 transmit buffer _dhcpUdpSocket.write(buffer, 12); } buffer[0] = dhcpParamRequest; buffer[1] = 0x06; buffer[2] = subnetMask; buffer[3] = routersOnSubnet; buffer[4] = dns; buffer[5] = domainName; buffer[6] = dhcpT1value; buffer[7] = dhcpT2value; buffer[8] = endOption; //put data in W5100 transmit buffer _dhcpUdpSocket.write(buffer, 9); _dhcpUdpSocket.endPacket(); } uint8_t DhcpClass::parseDHCPResponse(unsigned long responseTimeout, uint32_t& transactionId) { uint8_t type = 0; uint8_t opt_len = 0; unsigned long startTime = millis(); while(_dhcpUdpSocket.parsePacket() <= 0) { if((millis() - startTime) > responseTimeout) { return 255; } delay(50); } // start reading in the packet RIP_MSG_FIXED fixedMsg; _dhcpUdpSocket.read((uint8_t*)&fixedMsg, sizeof(RIP_MSG_FIXED)); if(fixedMsg.op == DHCP_BOOTREPLY && _dhcpUdpSocket.remotePort() == DHCP_SERVER_PORT) { transactionId = ntohl(fixedMsg.xid); if(memcmp(fixedMsg.chaddr, _dhcpMacAddr, 6) != 0 || (transactionId < _dhcpInitialTransactionId) || (transactionId > _dhcpTransactionId)) { // Need to read the rest of the packet here regardless _dhcpUdpSocket.flush(); return 0; } memcpy(_dhcpLocalIp, fixedMsg.yiaddr, 4); // Skip to the option part // Doing this a byte at a time so we don't have to put a big buffer // on the stack (as we don't have lots of memory lying around) for (int i =0; i < (240 - (int)sizeof(RIP_MSG_FIXED)); i++) { _dhcpUdpSocket.read(); // we don't care about the returned byte } while (_dhcpUdpSocket.available() > 0) { switch (_dhcpUdpSocket.read()) { case endOption : break; case padOption : break; case dhcpMessageType : opt_len = _dhcpUdpSocket.read(); type = _dhcpUdpSocket.read(); break; case subnetMask : opt_len = _dhcpUdpSocket.read(); _dhcpUdpSocket.read(_dhcpSubnetMask, 4); break; case routersOnSubnet : opt_len = _dhcpUdpSocket.read(); _dhcpUdpSocket.read(_dhcpGatewayIp, 4); for (int i = 0; i < opt_len-4; i++) { _dhcpUdpSocket.read(); } break; case dns : opt_len = _dhcpUdpSocket.read(); _dhcpUdpSocket.read(_dhcpDnsServerIp, 4); for (int i = 0; i < opt_len-4; i++) { _dhcpUdpSocket.read(); } break; case dhcpServerIdentifier : opt_len = _dhcpUdpSocket.read(); if( *((uint32_t*)_dhcpDhcpServerIp) == 0 || IPAddress(_dhcpDhcpServerIp) == _dhcpUdpSocket.remoteIP() ) { _dhcpUdpSocket.read(_dhcpDhcpServerIp, sizeof(_dhcpDhcpServerIp)); } else { // Skip over the rest of this option while (opt_len--) { _dhcpUdpSocket.read(); } } break; case dhcpIPaddrLeaseTime : default : opt_len = _dhcpUdpSocket.read(); // Skip over the rest of this option while (opt_len--) { _dhcpUdpSocket.read(); } break; } } } // Need to skip to end of the packet regardless here _dhcpUdpSocket.flush(); return type; } IPAddress DhcpClass::getLocalIp() { return IPAddress(_dhcpLocalIp); } IPAddress DhcpClass::getSubnetMask() { return IPAddress(_dhcpSubnetMask); } IPAddress DhcpClass::getGatewayIp() { return IPAddress(_dhcpGatewayIp); } IPAddress DhcpClass::getDhcpServerIp() { return IPAddress(_dhcpDhcpServerIp); } IPAddress DhcpClass::getDnsServerIp() { return IPAddress(_dhcpDnsServerIp); }