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/*************************************************************************
* Tester sketch for Freematics OBD-II Adapter for Arduino
* Visit http://freematics.com for more information
* Distributed under BSD license
* Written by Stanley Huang <support@freematics.com.au>
*************************************************************************/
#include <Arduino.h>
#include <OBD.h>
#include <SPI.h>
#include <Wire.h>
#include "MultiLCD.h"
#include "config.h"
#if ENABLE_DATA_LOG
#include <SD.h>
#endif
#include "datalogger.h"
#define OBD_MODEL_UART 0
#define OBD_MODEL_I2C 1
#define STATE_MEMS_READY 1
#define STATE_INIT_DONE 2
typedef struct {
uint16_t left;
uint16_t right;
uint16_t bottom;
uint16_t height;
uint16_t pos;
} CHART_DATA;
CHART_DATA chartRPM = {24, 319, 239, 100, 24};
void chartUpdate(CHART_DATA* chart, int value);
void(* resetFunc) (void) = 0; //declare reset function at address 0
static uint32_t lastFileSize = 0;
static int speed = 0;
static uint32_t distance = 0;
static uint16_t fileIndex = 0;
static uint32_t startTime = 0;
static uint16_t elapsed = 0;
static uint8_t lastPid = 0;
static int lastValue = 0;
void chartUpdate(CHART_DATA* chart, int value)
{
if (value > chart->height) value = chart->height;
for (uint16_t n = 0; n < value; n++) {
byte b = n * 255 / chart->height;
lcd.setPixel(chart->pos, chart->bottom - n, RGB16(0, 0, b));
}
if (chart->pos++ == chart->right) {
chart->pos = chart->left;
}
lcd.fill(chart->pos, chart->pos, 239 - chart->height, chart->bottom);
}
#if OBD_MODEL == OBD_MODEL_UART
class COBDDevice : public COBD, public CDataLogger
#else
class COBDDevice : public COBDI2C, public CDataLogger
#endif
{
public:
COBDDevice():state(0) {}
void setup()
{
#if ENABLE_DATA_LOG
lcd.setFontSize(FONT_SIZE_SMALL);
lcd.setColor(RGB16_WHITE);
lcd.setCursor(0, 3);
checkSD();
#endif
#ifdef OBD_ADAPTER_I2C
Wire.begin();
#endif
if (memsInit())
state |= STATE_MEMS_READY;
testOut();
while (!init());
showVIN();
showDTC();
delay(3000);
initScreen();
state |= STATE_INIT_DONE;
}
#if ENABLE_DATA_LOG
bool checkSD()
{
Sd2Card card;
SdVolume volume;
pinMode(SS, OUTPUT);
if (card.init(SPI_FULL_SPEED, SD_CS_PIN)) {
const char* type;
switch(card.type()) {
case SD_CARD_TYPE_SD1:
type = "SD1";
break;
case SD_CARD_TYPE_SD2:
type = "SD2";
break;
case SD_CARD_TYPE_SDHC:
type = "SDHC";
break;
default:
type = "SDx";
}
lcd.print(type);
lcd.write(' ');
if (!volume.init(card)) {
return false;
}
uint32_t volumesize = volume.blocksPerCluster();
volumesize >>= 1; // 512 bytes per block
volumesize *= volume.clusterCount();
volumesize >>= 10;
lcd.print((int)volumesize);
lcd.print("MB");
} else {
return false;
}
if (!SD.begin(SD_CS_PIN)) {
return false;
}
return true;
}
#endif
void testOut()
{
static const char PROGMEM cmds[][6] = {"ATZ\r", "ATH1\r", "ATRV\r", "0100\r", "010C\r", "0902\r"};
char buf[128];
lcd.setColor(RGB16_WHITE);
lcd.setFontSize(FONT_SIZE_SMALL);
lcd.setCursor(0, 4);
// recover from possible previous incomplete communication
recover();
for (byte i = 0; i < sizeof(cmds) / sizeof(cmds[0]); i++) {
char cmd[6];
memcpy_P(cmd, cmds[i], sizeof(cmd));
lcd.setColor(RGB16_WHITE);
lcd.print("Sending ");
lcd.println(cmd);
lcd.setColor(RGB16_CYAN);
if (sendCommand(cmd, buf, sizeof(buf))) {
char *p = strstr(buf, cmd);
if (p)
p += strlen(cmd);
else
p = buf;
while (*p == '\r') p++;
while (*p) {
lcd.write(*p);
if (*p == '\r')
lcd.write('\n');
p++;
}
lcd.println();
} else {
lcd.println("Timeout");
}
delay(500);
}
lcd.println();
}
void showVIN()
{
char buf[255];
lcd.setFontSize(FONT_SIZE_MEDIUM);
if (getVIN(buf, sizeof(buf))) {
lcd.setColor(RGB16_WHITE);
lcd.print("VIN:");
lcd.setColor(RGB16_YELLOW);
lcd.println(buf);
}
}
void showDTC()
{
uint16_t dtc[6];
int num = readDTC(dtc, sizeof(dtc) / sizeof(dtc[0]));
lcd.setColor(RGB16_WHITE);
lcd.print(num);
lcd.println(" DTC found");
if (num > 0) {
lcd.setColor(RGB16_YELLOW);
for (byte i = 0; i < num; i++) {
lcd.print(dtc[i], HEX);
lcd.print(' ');
}
}
}
void loop()
{
static byte index2 = 0;
const byte pids[]= {PID_RPM, PID_SPEED, PID_THROTTLE, PID_ENGINE_LOAD};
int values[sizeof(pids)];
// read multiple OBD-II PIDs
if (readPID(pids, sizeof(pids), values) == sizeof(pids)) {
dataTime = millis();
for (byte n = 0; n < sizeof(pids); n++) {
logData((uint16_t)pids[n] | 0x100, values[n]);
showData(pids[n], values[n]);
}
}
static byte lastSec = 0;
const byte pids2[] = {PID_COOLANT_TEMP, PID_INTAKE_TEMP, PID_AMBIENT_TEMP, PID_DISTANCE};
byte sec = (uint8_t)(millis() >> 10);
if (sec != lastSec) {
// goes in every other second
int value;
byte pid = pids2[index2 = (index2 + 1) % (sizeof(pids2))];
// read single OBD-II PID
if (isValidPID(pid) && readPID(pid, value)) {
dataTime = millis();
logData((uint16_t)pid | 0x100, value);
showData(pid, value);
lastSec = sec;
}
}
if (errors >= 5) {
reconnect();
}
if (state & STATE_MEMS_READY) {
processMEMS();
}
}
void processMEMS()
{
int acc[3];
int gyro[3];
int temp;
if (!memsRead(acc, gyro, 0, &temp)) return;
dataTime = millis();
acc[0] /= ACC_DATA_RATIO;
acc[1] /= ACC_DATA_RATIO;
acc[2] /= ACC_DATA_RATIO;
gyro[0] /= GYRO_DATA_RATIO;
gyro[1] /= GYRO_DATA_RATIO;
gyro[2] /= GYRO_DATA_RATIO;
lcd.setFontSize(FONT_SIZE_SMALL);
lcd.setCursor(24, 14);
lcd.print(acc[0]);
lcd.print('/');
lcd.print(acc[1]);
lcd.print('/');
lcd.print(acc[2]);
lcd.print(' ');
lcd.setCursor(152, 14);
lcd.print(gyro[0]);
lcd.print('/');
lcd.print(gyro[1]);
lcd.print('/');
lcd.print(gyro[2]);
lcd.print(' ');
lcd.setFontSize(FONT_SIZE_MEDIUM);
// log x/y/z of accelerometer
logData(PID_ACC, acc[0], acc[1], acc[2]);
// log x/y/z of gyro meter
logData(PID_GYRO, gyro[0], gyro[1], gyro[2]);
}
void reconnect()
{
lcd.clear();
lcd.setFontSize(FONT_SIZE_MEDIUM);
lcd.print("Reconnecting");
startTime = millis();
//digitalWrite(SD_CS_PIN, LOW);
for (uint16_t i = 0; ; i++) {
if (i == 5) {
lcd.setBackLight(0);
lcd.clear();
}
if (init()) {
lcd.setBackLight(255);
lcd.clear();
lcd.print("Reseting...");
// reset Arduino
resetFunc();
}
}
}
// screen layout related stuff
void showData(byte pid, int value)
{
switch (pid) {
case PID_RPM:
lcd.setCursor(0, 2);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt((unsigned int)value % 10000, 4);
showChart(value);
break;
case PID_SPEED:
lcd.setCursor(90, 2);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt((unsigned int)value % 1000, 3);
break;
case PID_ENGINE_LOAD:
lcd.setCursor(164, 2);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt(value % 100, 3);
break;
case PID_INTAKE_TEMP:
if (value < 0) value = 0;
lcd.setCursor(248, 2);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt(value, 3);
break;
case PID_INTAKE_MAP:
lcd.setCursor(164, 9);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt((uint16_t)value % 1000, 3);
break;
case PID_COOLANT_TEMP:
lcd.setCursor(8, 9);
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.printInt((uint16_t)value % 1000, 3);
break;
case PID_DISTANCE:
lcd.setFontSize(FONT_SIZE_XLARGE);
lcd.setCursor(90, 9);
lcd.printInt((uint16_t)value % 1000, 3);
break;
}
}
void ShowVoltage(float v)
{
lcd.setFontSize(FONT_SIZE_LARGE);
lcd.setCursor(260, 10);
lcd.setFontSize(FONT_SIZE_MEDIUM);
lcd.print(v);
}
void showChart(int value)
{
uint16_t height;
if (value >= 560) {
height = (value - 500) / 60;
} else {
height = 1;
}
chartUpdate(&chartRPM, height);
}
void initScreen()
{
lcd.clear();
lcd.setBackLight(255);
lcd.setFontSize(FONT_SIZE_SMALL);
lcd.setColor(RGB16_CYAN);
lcd.setCursor(4, 0);
lcd.print("ENGINE RPM");
lcd.setCursor(104, 0);
lcd.print("SPEED");
lcd.setCursor(164, 0);
lcd.print("ENGINE LOAD");
lcd.setCursor(248, 0);
lcd.print("INTAKE TEMP");
lcd.setCursor(4, 7);
lcd.print("COOLANT TEMP");
lcd.setCursor(104, 7);
lcd.print("DISTANCE");
lcd.setCursor(164, 7);
lcd.print("INTAKE MAP");
lcd.setCursor(260, 9);
lcd.print("BATTERY");
lcd.setCursor(0, 14);
lcd.print("ACC");
lcd.setCursor(122, 14);
lcd.print("GYRO");
lcd.setColor(RGB16_YELLOW);
lcd.setCursor(24, 5);
lcd.print("rpm");
lcd.setCursor(110, 5);
lcd.print("km/h");
lcd.setCursor(216, 4);
lcd.print("%");
lcd.setCursor(304, 4);
lcd.print("C");
lcd.setCursor(64, 11);
lcd.print("C");
lcd.setCursor(110, 12);
lcd.print("km");
lcd.setCursor(200, 12);
lcd.print("kpa");
lcd.setCursor(296, 12);
lcd.print("V");
lcd.setColor(RGB16_CYAN);
lcd.setXY(0, 140);
lcd.print("6500");
lcd.setXY(0, 186);
lcd.print("3500");
lcd.setXY(0, 232);
lcd.print("500");
lcd.setColor(RGB16_WHITE);
}
byte state;
};
COBDDevice myOBD;
void setup()
{
lcd.begin();
lcd.clear();
lcd.setColor(RGB16_YELLOW);
lcd.println("Freematics OBD-II Adapter Tester");
myOBD.begin();
myOBD.initSender();
myOBD.setup();
}
void loop()
{
myOBD.loop();
}
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