path: root/libraries/OBD/OBD.cpp

/*************************************************************************
* Arduino Library for OBD-II UART/I2C Adapter
* Distributed under BSD License
* Visit http://freematics.com for more information
* (C)2012-2016 Stanley Huang <stanleyhuangyc@gmail.com>
*************************************************************************/

#include <Arduino.h>
#include <Wire.h>
#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::readPID(byte pid, int& result)
{
	// send a query command
	sendQuery(pid);
	// receive and parse the response
	return getResult(pid, result);
}

byte COBD::readPID(const byte pid[], byte count, int result[])
{
	byte results = 0; 
	for (byte n = 0; n < count; n++) {
		if (readPID(pid[n], result[n])) {
			results++;
		}
	}
	return results;
}

byte COBD::readDTC(uint16_t codes[], byte maxCodes)
{
	/*
	Response example:
	0: 43 04 01 08 01 09 
	1: 01 11 01 15 00 00 00
	*/ 
	byte codesRead = 0;
 	for (byte n = 0; n < 6; n++) {
		char buffer[128];
		sprintf_P(buffer, n == 0 ? PSTR("03\r") : PSTR("03%02X\r"), n);
		write(buffer);
		if (receive(buffer, sizeof(buffer)) > 0) {
			if (!strstr(buffer, "NO DATA")) {
				char *p = strstr(buffer, "43");
				if (p) {
					while (codesRead < maxCodes && *p) {
						p += 6;
						if (*p == '\r') {
							p = strchr(p, ':');
							if (!p) break;
							p += 2; 
						}
						uint16_t code = hex2uint16(p);
						if (code == 0) break;
						codes[codesRead++] = code;
					}
				}
				break;
			}
		}
	}
	return codesRead;
}

void COBD::clearDTC()
{
	char buffer[32];
	write("04\r");
	receive(buffer, sizeof(buffer));
}

void COBD::write(const char* s)
{
#ifdef DEBUG
	DEBUG.print("<<<");
	DEBUG.println(s);
#endif
	OBDUART.write(s);
}

int COBD::normalizeData(byte pid, char* data)
{
	int result;
	switch (pid) {
	case PID_RPM:
	case PID_EVAP_SYS_VAPOR_PRESSURE: // kPa
		result = getLargeValue(data) >> 2;
		break;
	case PID_FUEL_PRESSURE: // kPa
		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: // grams/sec
		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;
	case PID_AIR_FUEL_EQUIV_RATIO: // 0~200
		result = (long)getLargeValue(data) * 200 / 65536;
		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;
}

void COBD::sleep()
{
  	char buf[32];
	sendCommand("ATLP\r", buf, sizeof(buf));
}

char* COBD::getResultValue(char* buf)
{
	char* p = buf;
	for (;;) {
		if (isdigit(*p) || *p == '-') {
			return p;
		}
		p = strchr(p, '\r');
		if (!p) break;
		if (*(++p) == '\n') p++;
	}
	return 0;
}

float COBD::getVoltage()
{
    char buf[32];
	if (sendCommand("ATRV\r", buf, sizeof(buf)) > 0) {
		char* p = getResultValue(buf);
		if (p) return atof(p);
    }
    return 0;
}

bool COBD::getVIN(char* buffer, byte bufsize)
{
	if (sendCommand("0902\r", buffer, bufsize)) {
        char *p = strstr(buffer, "0: 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;
}

byte COBD::begin()
{
	long baudrates[] = {38400, 115200};
	byte version = 0;
	for (byte n = 0; n < sizeof(baudrates) / sizeof(baudrates[0]) && version == 0; n++) {
		OBDUART.begin(baudrates[n]);
		version = getVersion(); 
	}
	return version;	
}

byte COBD::getVersion()
{
	byte version = 0;
	for (byte n = 0; n < 3; n++) {
		char buffer[32];
		if (sendCommand("ATI\r", buffer, sizeof(buffer), 200)) {
			char *p = strchr(buffer, ' ');
			if (p) {
				p += 2;
				version = (*p - '0') * 10 + (*(p + 2) - '0');
				break;
			}
		}
	}
	return version;
}

byte COBD::receive(char* buffer, byte bufsize, int timeout)
{
	unsigned char n = 0;
	unsigned long startTime = millis();
	char c = 0;
	for (;;) {
		if (OBDUART.available()) {
			c = OBDUART.read();
			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 {
					if (c == '\r' || c == '\n' || c == ' ') {
						if (n == 0 || buffer[n - 1] == '\r' || buffer[n - 1] == '\n') continue;
					}
					buffer[n++] = c;
				}
			}
		} else {
			if (c == '>') {
				// prompt char received
				break;
			}
			if (millis() - startTime > timeout) {
			    // timeout
			    break;
			}
			dataIdleLoop();
		}
	}
	if (buffer) {
		buffer[n] = 0;
	}
#ifdef DEBUG
	DEBUG.print(">>>");
	DEBUG.println(buffer);
#endif
	return n;
}

void COBD::recover()
{
	sendCommand("\r", 0, 0);
}

bool COBD::init(OBD_PROTOCOLS protocol)
{
	const char *initcmd[] = {"ATZ\r", "ATE0\r", "ATH0\r"};
	char buffer[64];

	m_state = OBD_DISCONNECTED;
	for (unsigned char i = 0; i < sizeof(initcmd) / sizeof(initcmd[0]); i++) {
		write(initcmd[i]);
		if (receive(buffer, sizeof(buffer), OBD_TIMEOUT_LONG) == 0) {
			return false;
		}
	}
	if (protocol != PROTO_AUTO) {
		sprintf_P(buffer, PSTR("ATSP %u\r"), protocol);
		write(buffer);
		if (receive(buffer, sizeof(buffer), OBD_TIMEOUT_LONG) == 0 && !strstr(buffer, "OK")) {
			return false;
		}
	}

	// load pid map
	memset(pidmap, 0, sizeof(pidmap));
	bool success = false;
	for (byte i = 0; i < 4; i++) {
		byte pid = i * 0x20;
		sendQuery(pid);
		if (receive(buffer, sizeof(buffer), OBD_TIMEOUT_LONG) > 0) {
			char *p = buffer;
			while ((p = strstr(p, "41 "))) {
				p += 3;
				if (hex2uint8(p) == pid) {
					p += 2;
					for (byte n = 0; n < 4 && *(p + n * 3) == ' '; n++) {
						pidmap[i * 4 + n] = hex2uint8(p + n * 3 + 1);
					}
					success = true;
				}
			}
		}
	}

	if (success) {
		m_state = OBD_CONNECTED;
		errors = 0;
	}
	return success;
}

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;
}

bool COBD::memsInit()
{
	char buf[16];
	return sendCommand("ATTEMP\r", buf, sizeof(buf)) > 0 && !strchr(buf, '?');
}

bool COBD::memsRead(int* acc, int* gyr, int* mag, int* temp)
{
	char buf[64];
	bool success;
	if (acc) {
		success = false;
		if (sendCommand("ATACL\r", buf, sizeof(buf)) > 0) do {
			char* p = getResultValue(buf);
			if (!p) break;
			acc[0] = atoi(p++);
			if (!(p = strchr(p, ','))) break;
			acc[1] = atoi(++p);
			if (!(p = strchr(p, ','))) break;
			acc[2] = atoi(++p);
			success = true;
		} while (0);
		if (!success) return false;
	}
	if (gyr) {
		success = false;
		if (sendCommand("ATGYRO\r", buf, sizeof(buf)) > 0) do {
			char* p = getResultValue(buf);
			if (!p) break;
			gyr[0] = atoi(p++);
			if (!(p = strchr(p, ','))) break;
			gyr[1] = atoi(++p);
			if (!(p = strchr(p, ','))) break;
			gyr[2] = atoi(++p);
			success = true;
		} while (0);
		if (!success) return false;
	}
	if (temp) {
		success = false;
		if (sendCommand("ATTEMP\r", buf, sizeof(buf)) > 0) {
			char* p = getResultValue(buf);
			if (p) {
				*temp = (atoi(p) + 12412) / 34;
				success = true;
			}
		}
		if (!success) return false;
	}
	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
*************************************************************************/

byte COBDI2C::begin()
{
	Wire.begin();
#ifdef DEBUG
	DEBUG.begin(115200);
#endif
	recover();
	return getVersion();
}

void COBDI2C::end()
{
	m_state = OBD_DISCONNECTED;
}

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 < 0xa) {
			 // 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);
	if (buffer) buffer[offset] = 0;
	return 0;
}

void COBDI2C::setQueryPID(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::applyQueryPIDs(byte obdPid[])
{
	sendCommandBlock(CMD_APPLY_OBD_PIDS, 0, (byte*)obdPid, sizeof(obdPid[0])* MAX_PIDS);
	delay(200);
}

void COBDI2C::loadQueryData(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);
}

#define MPU6050_I2C_ADDRESS 0x68
#define MPU6050_ACCEL_XOUT_H       0x3B   // R
#define MPU6050_ACCEL_XOUT_L       0x3C   // R
#define MPU6050_ACCEL_YOUT_H       0x3D   // R
#define MPU6050_ACCEL_YOUT_L       0x3E   // R
#define MPU6050_ACCEL_ZOUT_H       0x3F   // R
#define MPU6050_ACCEL_ZOUT_L       0x40   // R
#define MPU6050_TEMP_OUT_H         0x41   // R
#define MPU6050_TEMP_OUT_L         0x42   // R
#define MPU6050_GYRO_XOUT_H        0x43   // R
#define MPU6050_GYRO_XOUT_L        0x44   // R
#define MPU6050_GYRO_YOUT_H        0x45   // R
#define MPU6050_GYRO_YOUT_L        0x46   // R
#define MPU6050_GYRO_ZOUT_H        0x47   // R
#define MPU6050_GYRO_ZOUT_L        0x48   // R
#define MPU6050_PWR_MGMT_1         0x6B   // R/W
#define MPU6050_PWR_MGMT_2         0x6C   // R/W
#define MPU6050_WHO_AM_I           0x75   // R

typedef struct
{
    uint8_t x_accel_h;
    uint8_t x_accel_l;
    uint8_t y_accel_h;
    uint8_t y_accel_l;
    uint8_t z_accel_h;
    uint8_t z_accel_l;
    uint8_t t_h;
    uint8_t t_l;
    uint8_t x_gyro_h;
    uint8_t x_gyro_l;
    uint8_t y_gyro_h;
    uint8_t y_gyro_l;
    uint8_t z_gyro_h;
    uint8_t z_gyro_l;
} MPU6050_READOUT_DATA;

bool COBDI2C::memsInit()
{
	// default at power-up:
	//    Gyro at 250 degrees second
	//    Acceleration at 2g
	//    Clock source at internal 8MHz
	//    The device is in sleep mode.
	//
	uint8_t c;
	bool success;
	success = MPU6050_read (MPU6050_WHO_AM_I, &c, 1);
	if (!success) return false;

	// According to the datasheet, the 'sleep' bit
	// should read a '1'. But I read a '0'.
	// That bit has to be cleared, since the sensor
	// is in sleep mode at power-up. Even if the
	// bit reads '0'.
	success = MPU6050_read (MPU6050_PWR_MGMT_2, &c, 1);
	if (!success) return false;

	// Clear the 'sleep' bit to start the sensor.
	MPU6050_write_reg (MPU6050_PWR_MGMT_1, 0);
	return true;
}

bool COBDI2C::memsRead(int* acc, int* gyr, int* mag, int* temp)
{
	bool success;

	// Read the raw values.
	// Read 14 bytes at once,
	// containing acceleration, temperature and gyro.
	// With the default settings of the MPU-6050,
	// there is no filter enabled, and the values
	// are not very stable.
	
	MPU6050_READOUT_DATA accel_t_gyro;
	success = MPU6050_read (MPU6050_ACCEL_XOUT_H, (uint8_t *)&accel_t_gyro, sizeof(MPU6050_READOUT_DATA));
	if (!success) return false;
	
	if (temp) {
		// 340 per degrees Celsius, -512 at 35 degrees.
		*temp = ((int)(((uint16_t)accel_t_gyro.t_h << 8) | accel_t_gyro.t_l) + 512) / 34 + 350; 
	}

	if (acc) {
		MPU6050_store(acc, accel_t_gyro.x_accel_l, accel_t_gyro.x_accel_h);
		MPU6050_store(acc + 1, accel_t_gyro.y_accel_l, accel_t_gyro.y_accel_h);
		MPU6050_store(acc + 2, accel_t_gyro.z_accel_l, accel_t_gyro.z_accel_h);
	}

	if (gyr) {
		MPU6050_store(gyr, accel_t_gyro.x_gyro_l, accel_t_gyro.x_gyro_h);
		MPU6050_store(gyr + 1, accel_t_gyro.y_gyro_l, accel_t_gyro.y_gyro_h);
		MPU6050_store(gyr + 2, accel_t_gyro.z_gyro_l, accel_t_gyro.z_gyro_h);
	}
	
	if (mag) {
		// no magnetometer
		mag[0] = 0;
		mag[1] = 0;
		mag[2] = 0;
	}
	
	return true;
}

void COBDI2C::MPU6050_store(int* pData, uint8_t data_l, uint8_t data_h)
{
	uint8_t* ptr = (uint8_t*)pData;
	*ptr = data_l;
	*(ptr + 1) = data_h;
}

bool COBDI2C::MPU6050_read(int start, uint8_t* buffer, int size)
{
	int i, n;

	Wire.beginTransmission(MPU6050_I2C_ADDRESS);
	Wire.write(start);
	Wire.endTransmission(false);    // hold the I2C-bus

	// Third parameter is true: relase I2C-bus after data is read.
	Wire.requestFrom(MPU6050_I2C_ADDRESS, size, true);
	while(Wire.available() && i<size)
	{
		buffer[i++]=Wire.read();
	}
	return i == size;
}


bool COBDI2C::MPU6050_write(int start, const uint8_t* pData, int size)
{
	int n;

	Wire.beginTransmission(MPU6050_I2C_ADDRESS);
	Wire.write(start);        // write the start address
	n = Wire.write(pData, size);  // write data bytes
	if (n != size) return false;
	Wire.endTransmission(true); // release the I2C-bus
	return true;
}

bool COBDI2C::MPU6050_write_reg(int reg, uint8_t data)
{
	return MPU6050_write(reg, &data, 1);
}