/************************************************************************* * Arduino Library for OBD-II UART/I2C Adapter * Distributed under GPL v2.0 * Visit http://freematics.com for more information * (C)2012-2015 Stanley Huang *************************************************************************/ #include #include #include "OBD.h" //#define DEBUG Serial uint16_t hex2uint16(const char *p) { char c = *p; uint16_t i = 0; for (char n = 0; c && n < 4; c = *(++p)) { if (c >= 'A' && c <= 'F') { c -= 7; } else if (c>='a' && c<='f') { c -= 39; } else if (c == ' ') { continue; } else if (c < '0' || c > '9') { break; } i = (i << 4) | (c & 0xF); n++; } return i; } byte hex2uint8(const char *p) { byte c1 = *p; byte c2 = *(p + 1); if (c1 >= 'A' && c1 <= 'F') c1 -= 7; else if (c1 >='a' && c1 <= 'f') c1 -= 39; else if (c1 < '0' || c1 > '9') return 0; if (c2 >= 'A' && c2 <= 'F') c2 -= 7; else if (c2 >= 'a' && c2 <= 'f') c2 -= 39; else if (c2 < '0' || c2 > '9') return 0; return c1 << 4 | (c2 & 0xf); } /************************************************************************* * OBD-II UART Adapter *************************************************************************/ byte COBD::sendCommand(const char* cmd, char* buf, byte bufsize, int timeout) { write(cmd); dataIdleLoop(); return receive(buf, bufsize, timeout); } void COBD::sendQuery(byte pid) { char cmd[8]; sprintf(cmd, "%02X%02X\r", dataMode, pid); #ifdef DEBUG debugOutput(cmd); #endif write(cmd); } bool COBD::read(byte pid, int& result) { // send a query command sendQuery(pid); // receive and parse the response return getResult(pid, result); } void COBD::clearDTC() { char buffer[32]; write("04\r"); receive(buffer, sizeof(buffer)); } void COBD::write(const char* s) { OBDUART.write(s); } int COBD::normalizeData(byte pid, char* data) { int result; switch (pid) { case PID_RPM: case PID_EVAP_SYS_VAPOR_PRESSURE: result = getLargeValue(data) >> 2; break; case PID_FUEL_PRESSURE: result = getSmallValue(data) * 3; break; case PID_COOLANT_TEMP: case PID_INTAKE_TEMP: case PID_AMBIENT_TEMP: case PID_ENGINE_OIL_TEMP: result = getTemperatureValue(data); break; case PID_THROTTLE: case PID_COMMANDED_EGR: case PID_COMMANDED_EVAPORATIVE_PURGE: case PID_FUEL_LEVEL: case PID_RELATIVE_THROTTLE_POS: case PID_ABSOLUTE_THROTTLE_POS_B: case PID_ABSOLUTE_THROTTLE_POS_C: case PID_ACC_PEDAL_POS_D: case PID_ACC_PEDAL_POS_E: case PID_ACC_PEDAL_POS_F: case PID_COMMANDED_THROTTLE_ACTUATOR: case PID_ENGINE_LOAD: case PID_ABSOLUTE_ENGINE_LOAD: case PID_ETHANOL_FUEL: case PID_HYBRID_BATTERY_PERCENTAGE: result = getPercentageValue(data); break; case PID_MAF_FLOW: result = getLargeValue(data) / 100; break; case PID_TIMING_ADVANCE: result = (int)(getSmallValue(data) / 2) - 64; break; case PID_DISTANCE: // km case PID_DISTANCE_WITH_MIL: // km case PID_TIME_WITH_MIL: // minute case PID_TIME_SINCE_CODES_CLEARED: // minute case PID_RUNTIME: // second case PID_FUEL_RAIL_PRESSURE: // kPa case PID_ENGINE_REF_TORQUE: // Nm result = getLargeValue(data); break; case PID_CONTROL_MODULE_VOLTAGE: // V result = getLargeValue(data) / 1000; break; case PID_ENGINE_FUEL_RATE: // L/h result = getLargeValue(data) / 20; break; case PID_ENGINE_TORQUE_DEMANDED: // % case PID_ENGINE_TORQUE_PERCENTAGE: // % result = (int)getSmallValue(data) - 125; break; case PID_SHORT_TERM_FUEL_TRIM_1: case PID_LONG_TERM_FUEL_TRIM_1: case PID_SHORT_TERM_FUEL_TRIM_2: case PID_LONG_TERM_FUEL_TRIM_2: case PID_EGR_ERROR: result = ((int)getSmallValue(data) - 128) * 100 / 128; break; case PID_FUEL_INJECTION_TIMING: result = ((int32_t)getLargeValue(data) - 26880) / 128; break; case PID_CATALYST_TEMP_B1S1: case PID_CATALYST_TEMP_B2S1: case PID_CATALYST_TEMP_B1S2: case PID_CATALYST_TEMP_B2S2: result = getLargeValue(data) / 10 - 40; break; default: result = getSmallValue(data); } return result; } char* COBD::getResponse(byte& pid, char* buffer, byte bufsize) { while (receive(buffer, bufsize) > 0) { char *p = buffer; while ((p = strstr(p, "41 "))) { p += 3; byte curpid = hex2uint8(p); if (pid == 0) pid = curpid; if (curpid == pid) { errors = 0; p += 2; if (*p == ' ') return p + 1; } } } return 0; } bool COBD::getResult(byte& pid, int& result) { char buffer[64]; char* data = getResponse(pid, buffer, sizeof(buffer)); if (!data) { recover(); errors++; return false; } result = normalizeData(pid, data); return true; } bool COBD::setProtocol(OBD_PROTOCOLS h) { char buf[32]; if (h == PROTO_AUTO) { write("ATSP00\r"); } else { sprintf(buf, "ATSP%d\r", h); write(buf); } if (receive(buf, sizeof(buf), OBD_TIMEOUT_LONG) > 0 && strstr(buf, "OK")) return true; else return false; } void COBD::sleep() { char buf[32]; sendCommand("ATLP\r", buf, sizeof(buf)); } float COBD::getVoltage() { char buf[32]; if (sendCommand("ATRV\r", buf, sizeof(buf)) > 0) { return atof(buf); } return 0; } bool COBD::getVIN(char* buffer, byte bufsize) { if (sendCommand("0902\r", buffer, bufsize)) { char *p = strstr(buffer, "49 02"); if (p) { char *q = buffer; p += 10; do { for (++p; *p == ' '; p += 3) { if (*q = hex2uint8(p + 1)) q++; } p = strchr(p, ':'); } while(p); *q = 0; return true; } } return false; } bool COBD::isValidPID(byte pid) { if (pid >= 0x7f) return true; pid--; byte i = pid >> 3; byte b = 0x80 >> (pid & 0x7); return pidmap[i] & b; } void COBD::begin() { OBDUART.begin(OBD_SERIAL_BAUDRATE); #ifdef DEBUG DEBUG.begin(115200); #endif recover(); } byte COBD::receive(char* buffer, byte bufsize, int timeout) { unsigned char n = 0; unsigned long startTime = millis(); for (;;) { if (OBDUART.available()) { char c = OBDUART.read(); if (n > 2 && c == '>') { // prompt char received break; } else if (!buffer) { n++; } else if (n < bufsize - 1) { if (c == '.' && n > 2 && buffer[n - 1] == '.' && buffer[n - 2] == '.') { // waiting siginal n = 0; timeout = OBD_TIMEOUT_LONG; } else { buffer[n++] = c; } } } else { if (millis() - startTime > timeout) { // timeout break; } dataIdleLoop(); } } if (buffer) buffer[n] = 0; return n; } void COBD::recover() { char buf[16]; sendCommand("AT\r", buf, sizeof(buf)); } bool COBD::init(OBD_PROTOCOLS protocol) { const char *initcmd[] = {"ATZ\r","ATE0\r","ATL1\r","0100\r"}; char buffer[64]; m_state = OBD_CONNECTING; for (unsigned char i = 0; i < sizeof(initcmd) / sizeof(initcmd[0]); i++) { #ifdef DEBUG debugOutput(initcmd[i]); #endif write(initcmd[i]); if (receive(buffer, sizeof(buffer), OBD_TIMEOUT_LONG) == 0) { if (i == 0) { // workaround for longer initialization time delay(2000); } else { m_state = OBD_DISCONNECTED; return false; } } delay(50); } //while (available()) read(); if (protocol != PROTO_AUTO) { setProtocol(protocol); } // load pid map memset(pidmap, 0, sizeof(pidmap)); for (byte i = 0; i < 4; i++) { byte pid = i * 0x20; sendQuery(pid); char* data = getResponse(pid, buffer, sizeof(buffer)); if (!data) break; data--; for (byte n = 0; n < 4; n++) { if (data[n * 3] != ' ') break; pidmap[i * 4 + n] = hex2uint8(data + n * 3 + 1); } delay(100); } //while (available()) read(); m_state = OBD_CONNECTED; errors = 0; return true; } void COBD::end() { m_state = OBD_DISCONNECTED; OBDUART.end(); } bool COBD::setBaudRate(unsigned long baudrate) { OBDUART.print("ATBR1 "); OBDUART.print(baudrate); OBDUART.print('\r'); delay(50); OBDUART.end(); OBDUART.begin(baudrate); recover(); return true; } #ifdef DEBUG void COBD::debugOutput(const char *s) { DEBUG.print('['); DEBUG.print(millis()); DEBUG.print(']'); DEBUG.print(s); } #endif /************************************************************************* * OBD-II I2C Adapter *************************************************************************/ void COBDI2C::begin() { Wire.begin(); #ifdef DEBUG DEBUG.begin(115200); #endif recover(); } void COBDI2C::end() { m_state = OBD_DISCONNECTED; } bool COBDI2C::read(byte pid, int& result) { sendQuery(pid); dataIdleLoop(); return getResult(pid, result); } void COBDI2C::write(const char* s) { COMMAND_BLOCK cmdblock = {millis(), CMD_SEND_AT_COMMAND}; Wire.beginTransmission(I2C_ADDR); Wire.write((byte*)&cmdblock, sizeof(cmdblock)); Wire.write(s); Wire.endTransmission(); } bool COBDI2C::sendCommandBlock(byte cmd, uint8_t data, byte* payload, byte payloadBytes) { COMMAND_BLOCK cmdblock = {millis(), cmd, data}; Wire.beginTransmission(I2C_ADDR); bool success = Wire.write((byte*)&cmdblock, sizeof(COMMAND_BLOCK)) == sizeof(COMMAND_BLOCK); if (payload) Wire.write(payload, payloadBytes); Wire.endTransmission(); return success; } byte COBDI2C::receive(char* buffer, byte bufsize, int timeout) { uint32_t start = millis(); byte offset = 0; do { Wire.requestFrom((byte)I2C_ADDR, (byte)MAX_PAYLOAD_SIZE, (byte)1); int c = Wire.read(); if (offset == 0 && (c == 0 || c == -1)) { // data not ready dataIdleLoop(); continue; } if (buffer) buffer[offset++] = c; for (byte i = 1; i < MAX_PAYLOAD_SIZE && Wire.available(); i++) { char c = Wire.read(); if (c == '.' && offset > 2 && buffer[offset - 1] == '.' && buffer[offset - 2] == '.') { // waiting signal offset = 0; timeout = OBD_TIMEOUT_LONG; } else if (c == 0 || offset == bufsize - 1) { // string terminator encountered or buffer full if (buffer) buffer[offset] = 0; // discard the remaining data while (Wire.available()) Wire.read(); return offset; } else { if (buffer) buffer[offset++] = c; } } } while(millis() - start < timeout); return 0; } void COBDI2C::setPID(byte pid, byte obdPid[]) { byte n = 0; for (; n < MAX_PIDS && obdPid[n]; n++) { if (obdPid[n] == pid) return; } if (n == MAX_PIDS) { memmove(obdPid, obdPid + 1, sizeof(obdPid[0]) * (MAX_PIDS - 1)); n = MAX_PIDS - 1; } obdPid[n] = pid; } void COBDI2C::applyPIDs(byte obdPid[]) { sendCommandBlock(CMD_APPLY_OBD_PIDS, 0, (byte*)obdPid, sizeof(obdPid[0])* MAX_PIDS); delay(200); } void COBDI2C::loadData(PID_INFO obdInfo[]) { sendCommandBlock(CMD_LOAD_OBD_DATA); dataIdleLoop(); Wire.requestFrom((byte)I2C_ADDR, (byte)MAX_PAYLOAD_SIZE, (byte)0); Wire.readBytes((char*)obdInfo, sizeof(obdInfo[0]) * MAX_PIDS); }