deadprogram/StandardFirmataForATH0.ino

## StandardFirmataForATH0.ino
/*
 * Firmata is a generic protocol for communicating with microcontrollers
 * from software on a host computer. It is intended to work with
 * any host computer software package.
 *
 * To download a host software package, please clink on the following link
 * to open the download page in your default browser.
 *
 * http://firmata.org/wiki/Download
 */

/*
  Copyright (C) 2006-2008 Hans-Christoph Steiner.  All rights reserved.
  Copyright (C) 2010-2011 Paul Stoffregen.  All rights reserved.
  Copyright (C) 2009 Shigeru Kobayashi.  All rights reserved.
  Copyright (C) 2009-2011 Jeff Hoefs.  All rights reserved.

  This library is free software; you can redistribute it and/or
  modify it under the terms of the GNU Lesser General Public
  License as published by the Free Software Foundation; either
  version 2.1 of the License, or (at your option) any later version.

  See file LICENSE.txt for further informations on licensing terms.

  formatted using the GNU C formatting and indenting
*/

/*
 * TODO: use Program Control to load stored profiles from EEPROM
 */

#include <Servo.h>
#include <Wire.h>
#include <Firmata.h>

// move the following defines to Firmata.h?
#define I2C_WRITE B00000000
#define I2C_READ B00001000
#define I2C_READ_CONTINUOUSLY B00010000
#define I2C_STOP_READING B00011000
#define I2C_READ_WRITE_MODE_MASK B00011000
#define I2C_10BIT_ADDRESS_MODE_MASK B00100000

#define MAX_QUERIES 8
#define MINIMUM_SAMPLING_INTERVAL 10

#define REGISTER_NOT_SPECIFIED -1

/*==============================================================================
 * GLOBAL VARIABLES
 *============================================================================*/

/* analog inputs */
int analogInputsToReport = 0; // bitwise array to store pin reporting

/* digital input ports */
byte reportPINs[TOTAL_PORTS];       // 1 = report this port, 0 = silence
byte previousPINs[TOTAL_PORTS];     // previous 8 bits sent

/* pins configuration */
byte pinConfig[TOTAL_PINS];         // configuration of every pin
byte portConfigInputs[TOTAL_PORTS]; // each bit: 1 = pin in INPUT, 0 = anything else
int pinState[TOTAL_PINS];           // any value that has been written

/* timer variables */
unsigned long currentMillis;        // store the current value from millis()
unsigned long previousMillis;       // for comparison with currentMillis
int samplingInterval = 19;          // how often to run the main loop (in ms)

/* i2c data */
struct i2c_device_info {
  byte addr;
  byte reg;
  byte bytes;
};

/* for i2c read continuous more */
i2c_device_info query[MAX_QUERIES];

byte i2cRxData[32];
boolean isI2CEnabled = false;
signed char queryIndex = -1;
unsigned int i2cReadDelayTime = 0;  // default delay time between i2c read request and Wire.requestFrom()

Servo servos[MAX_SERVOS];
/*==============================================================================
 * FUNCTIONS
 *============================================================================*/

void readAndReportData(byte address, int theRegister, byte numBytes) {
  // allow I2C requests that don't require a register read
  // for example, some devices using an interrupt pin to signify new data available
  // do not always require the register read so upon interrupt you call Wire.requestFrom()
  if (theRegister != REGISTER_NOT_SPECIFIED) {
    Wire.beginTransmission(address);
#if ARDUINO >= 100
    Wire.write((byte)theRegister);
#else
    Wire.send((byte)theRegister);
#endif
    Wire.endTransmission();
    // do not set a value of 0
    if (i2cReadDelayTime > 0) {
      // delay is necessary for some devices such as WiiNunchuck
      delayMicroseconds(i2cReadDelayTime);
    }
  } else {
    theRegister = 0;  // fill the register with a dummy value
  }

  Wire.requestFrom(address, numBytes);  // all bytes are returned in requestFrom

  // check to be sure correct number of bytes were returned by slave
  if (numBytes == Wire.available()) {
    i2cRxData[0] = address;
    i2cRxData[1] = theRegister;
    for (int i = 0; i < numBytes; i++) {
#if ARDUINO >= 100
      i2cRxData[2 + i] = Wire.read();
#else
      i2cRxData[2 + i] = Wire.receive();
#endif
    }
  }
  else {
    if (numBytes > Wire.available()) {
      Firmata.sendString("I2C Read Error: Too many bytes received");
    } else {
      Firmata.sendString("I2C Read Error: Too few bytes received");
    }
  }

  // send slave address, register and received bytes
  Firmata.sendSysex(SYSEX_I2C_REPLY, numBytes + 2, i2cRxData);
}

void outputPort(byte portNumber, byte portValue, byte forceSend)
{
  // pins not configured as INPUT are cleared to zeros
  portValue = portValue & portConfigInputs[portNumber];
  // only send if the value is different than previously sent
  if (forceSend || previousPINs[portNumber] != portValue) {
    Firmata.sendDigitalPort(portNumber, portValue);
    previousPINs[portNumber] = portValue;
  }
}

/* -----------------------------------------------------------------------------
 * check all the active digital inputs for change of state, then add any events
 * to the Serial output queue using Serial.print() */
void checkDigitalInputs(void)
{
  /* Using non-looping code allows constants to be given to readPort().
   * The compiler will apply substantial optimizations if the inputs
   * to readPort() are compile-time constants. */
  if (TOTAL_PORTS > 0 && reportPINs[0]) outputPort(0, readPort(0, portConfigInputs[0]), false);
  if (TOTAL_PORTS > 1 && reportPINs[1]) outputPort(1, readPort(1, portConfigInputs[1]), false);
  if (TOTAL_PORTS > 2 && reportPINs[2]) outputPort(2, readPort(2, portConfigInputs[2]), false);
  if (TOTAL_PORTS > 3 && reportPINs[3]) outputPort(3, readPort(3, portConfigInputs[3]), false);
  if (TOTAL_PORTS > 4 && reportPINs[4]) outputPort(4, readPort(4, portConfigInputs[4]), false);
  if (TOTAL_PORTS > 5 && reportPINs[5]) outputPort(5, readPort(5, portConfigInputs[5]), false);
  if (TOTAL_PORTS > 6 && reportPINs[6]) outputPort(6, readPort(6, portConfigInputs[6]), false);
  if (TOTAL_PORTS > 7 && reportPINs[7]) outputPort(7, readPort(7, portConfigInputs[7]), false);
  if (TOTAL_PORTS > 8 && reportPINs[8]) outputPort(8, readPort(8, portConfigInputs[8]), false);
  if (TOTAL_PORTS > 9 && reportPINs[9]) outputPort(9, readPort(9, portConfigInputs[9]), false);
  if (TOTAL_PORTS > 10 && reportPINs[10]) outputPort(10, readPort(10, portConfigInputs[10]), false);
  if (TOTAL_PORTS > 11 && reportPINs[11]) outputPort(11, readPort(11, portConfigInputs[11]), false);
  if (TOTAL_PORTS > 12 && reportPINs[12]) outputPort(12, readPort(12, portConfigInputs[12]), false);
  if (TOTAL_PORTS > 13 && reportPINs[13]) outputPort(13, readPort(13, portConfigInputs[13]), false);
  if (TOTAL_PORTS > 14 && reportPINs[14]) outputPort(14, readPort(14, portConfigInputs[14]), false);
  if (TOTAL_PORTS > 15 && reportPINs[15]) outputPort(15, readPort(15, portConfigInputs[15]), false);
}

// -----------------------------------------------------------------------------
/* sets the pin mode to the correct state and sets the relevant bits in the
 * two bit-arrays that track Digital I/O and PWM status
 */
void setPinModeCallback(byte pin, int mode)
{
  if (pinConfig[pin] == I2C && isI2CEnabled && mode != I2C) {
    // disable i2c so pins can be used for other functions
    // the following if statements should reconfigure the pins properly
    disableI2CPins();
  }
  if (IS_PIN_SERVO(pin) && mode != SERVO && servos[PIN_TO_SERVO(pin)].attached()) {
    servos[PIN_TO_SERVO(pin)].detach();
  }
  if (IS_PIN_ANALOG(pin)) {
    reportAnalogCallback(PIN_TO_ANALOG(pin), mode == ANALOG ? 1 : 0); // turn on/off reporting
  }
  if (IS_PIN_DIGITAL(pin)) {
    if (mode == INPUT) {
      portConfigInputs[pin / 8] |= (1 << (pin & 7));
    } else {
      portConfigInputs[pin / 8] &= ~(1 << (pin & 7));
    }
  }
  pinState[pin] = 0;
  switch (mode) {
    case ANALOG:
      if (IS_PIN_ANALOG(pin)) {
        if (IS_PIN_DIGITAL(pin)) {
          pinMode(PIN_TO_DIGITAL(pin), INPUT); // disable output driver
          digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable internal pull-ups
        }
        pinConfig[pin] = ANALOG;
      }
      break;
    case INPUT:
      if (IS_PIN_DIGITAL(pin)) {
        pinMode(PIN_TO_DIGITAL(pin), INPUT); // disable output driver
        digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable internal pull-ups
        pinConfig[pin] = INPUT;
      }
      break;
    case OUTPUT:
      if (IS_PIN_DIGITAL(pin)) {
        digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable PWM
        pinMode(PIN_TO_DIGITAL(pin), OUTPUT);
        pinConfig[pin] = OUTPUT;
      }
      break;
    case PWM:
      if (IS_PIN_PWM(pin)) {
        pinMode(PIN_TO_PWM(pin), OUTPUT);
        analogWrite(PIN_TO_PWM(pin), 0);
        pinConfig[pin] = PWM;
      }
      break;
    case SERVO:
      if (IS_PIN_SERVO(pin)) {
        pinConfig[pin] = SERVO;
        if (!servos[PIN_TO_SERVO(pin)].attached()) {
          servos[PIN_TO_SERVO(pin)].attach(PIN_TO_DIGITAL(pin));
        }
      }
      break;
    case I2C:
      if (IS_PIN_I2C(pin)) {
        // mark the pin as i2c
        // the user must call I2C_CONFIG to enable I2C for a device
        pinConfig[pin] = I2C;
      }
      break;
    default:
      Firmata.sendString("Unknown pin mode"); // TODO: put error msgs in EEPROM
  }
  // TODO: save status to EEPROM here, if changed
}

void analogWriteCallback(byte pin, int value)
{
  if (pin < TOTAL_PINS) {
    switch (pinConfig[pin]) {
      case SERVO:
        if (IS_PIN_SERVO(pin))
          servos[PIN_TO_SERVO(pin)].write(value);
        pinState[pin] = value;
        break;
      case PWM:
        if (IS_PIN_PWM(pin))
          analogWrite(PIN_TO_PWM(pin), value);
        pinState[pin] = value;
        break;
    }
  }
}

void digitalWriteCallback(byte port, int value)
{
  byte pin, lastPin, mask = 1, pinWriteMask = 0;

  if (port < TOTAL_PORTS) {
    // create a mask of the pins on this port that are writable.
    lastPin = port * 8 + 8;
    if (lastPin > TOTAL_PINS) lastPin = TOTAL_PINS;
    for (pin = port * 8; pin < lastPin; pin++) {
      // do not disturb non-digital pins (eg, Rx & Tx)
      if (IS_PIN_DIGITAL(pin)) {
        // only write to OUTPUT and INPUT (enables pullup)
        // do not touch pins in PWM, ANALOG, SERVO or other modes
        if (pinConfig[pin] == OUTPUT || pinConfig[pin] == INPUT) {
          pinWriteMask |= mask;
          pinState[pin] = ((byte)value & mask) ? 1 : 0;
        }
      }
      mask = mask << 1;
    }
    writePort(port, (byte)value, pinWriteMask);
  }
}


// -----------------------------------------------------------------------------
/* sets bits in a bit array (int) to toggle the reporting of the analogIns
 */
//void FirmataClass::setAnalogPinReporting(byte pin, byte state) {
//}
void reportAnalogCallback(byte analogPin, int value)
{
  if (analogPin < TOTAL_ANALOG_PINS) {
    if (value == 0) {
      analogInputsToReport = analogInputsToReport &~ (1 << analogPin);
    } else {
      analogInputsToReport = analogInputsToReport | (1 << analogPin);
    }
  }
  // TODO: save status to EEPROM here, if changed
}

void reportDigitalCallback(byte port, int value)
{
  if (port < TOTAL_PORTS) {
    reportPINs[port] = (byte)value;
  }
  // do not disable analog reporting on these 8 pins, to allow some
  // pins used for digital, others analog.  Instead, allow both types
  // of reporting to be enabled, but check if the pin is configured
  // as analog when sampling the analog inputs.  Likewise, while
  // scanning digital pins, portConfigInputs will mask off values from any
  // pins configured as analog
}

/*==============================================================================
 * SYSEX-BASED commands
 *============================================================================*/

void sysexCallback(byte command, byte argc, byte *argv)
{
  byte mode;
  byte slaveAddress;
  byte slaveRegister;
  byte data;
  unsigned int delayTime;

  switch (command) {
    case I2C_REQUEST:
      mode = argv[1] & I2C_READ_WRITE_MODE_MASK;
      if (argv[1] & I2C_10BIT_ADDRESS_MODE_MASK) {
        Firmata.sendString("10-bit addressing mode is not yet supported");
        return;
      }
      else {
        slaveAddress = argv[0];
      }

      switch (mode) {
        case I2C_WRITE:
          Wire.beginTransmission(slaveAddress);
          for (byte i = 2; i < argc; i += 2) {
            data = argv[i] + (argv[i + 1] << 7);
#if ARDUINO >= 100
            Wire.write(data);
#else
            Wire.send(data);
#endif
          }
          Wire.endTransmission();
          delayMicroseconds(70);
          break;
        case I2C_READ:
          if (argc == 6) {
            // a slave register is specified
            slaveRegister = argv[2] + (argv[3] << 7);
            data = argv[4] + (argv[5] << 7);  // bytes to read
            readAndReportData(slaveAddress, (int)slaveRegister, data);
          }
          else {
            // a slave register is NOT specified
            data = argv[2] + (argv[3] << 7);  // bytes to read
            readAndReportData(slaveAddress, (int)REGISTER_NOT_SPECIFIED, data);
          }
          break;
        case I2C_READ_CONTINUOUSLY:
          if ((queryIndex + 1) >= MAX_QUERIES) {
            // too many queries, just ignore
            Firmata.sendString("too many queries");
            break;
          }
          queryIndex++;
          query[queryIndex].addr = slaveAddress;
          query[queryIndex].reg = argv[2] + (argv[3] << 7);
          query[queryIndex].bytes = argv[4] + (argv[5] << 7);
          break;
        case I2C_STOP_READING:
          byte queryIndexToSkip;
          // if read continuous mode is enabled for only 1 i2c device, disable
          // read continuous reporting for that device
          if (queryIndex <= 0) {
            queryIndex = -1;
          } else {
            // if read continuous mode is enabled for multiple devices,
            // determine which device to stop reading and remove it's data from
            // the array, shifiting other array data to fill the space
            for (byte i = 0; i < queryIndex + 1; i++) {
              if (query[i].addr = slaveAddress) {
                queryIndexToSkip = i;
                break;
              }
            }

            for (byte i = queryIndexToSkip; i < queryIndex + 1; i++) {
              if (i < MAX_QUERIES) {
                query[i].addr = query[i + 1].addr;
                query[i].reg = query[i + 1].addr;
                query[i].bytes = query[i + 1].bytes;
              }
            }
            queryIndex--;
          }
          break;
        default:
          break;
      }
      break;
    case I2C_CONFIG:
      delayTime = (argv[0] + (argv[1] << 7));

      if (delayTime > 0) {
        i2cReadDelayTime = delayTime;
      }

      if (!isI2CEnabled) {
        enableI2CPins();
      }

      break;
    case SERVO_CONFIG:
      if (argc > 4) {
        // these vars are here for clarity, they'll optimized away by the compiler
        byte pin = argv[0];
        int minPulse = argv[1] + (argv[2] << 7);
        int maxPulse = argv[3] + (argv[4] << 7);

        if (IS_PIN_SERVO(pin)) {
          if (servos[PIN_TO_SERVO(pin)].attached())
            servos[PIN_TO_SERVO(pin)].detach();
          servos[PIN_TO_SERVO(pin)].attach(PIN_TO_DIGITAL(pin), minPulse, maxPulse);
          setPinModeCallback(pin, SERVO);
        }
      }
      break;
    case SAMPLING_INTERVAL:
      if (argc > 1) {
        samplingInterval = argv[0] + (argv[1] << 7);
        if (samplingInterval < MINIMUM_SAMPLING_INTERVAL) {
          samplingInterval = MINIMUM_SAMPLING_INTERVAL;
        }
      } else {
        //Firmata.sendString("Not enough data");
      }
      break;
    case EXTENDED_ANALOG:
      if (argc > 1) {
        int val = argv[1];
        if (argc > 2) val |= (argv[2] << 7);
        if (argc > 3) val |= (argv[3] << 14);
        analogWriteCallback(argv[0], val);
      }
      break;
    case CAPABILITY_QUERY:
      Firmata.write(START_SYSEX);
      Firmata.write(CAPABILITY_RESPONSE);
      for (byte pin = 0; pin < TOTAL_PINS; pin++) {
        if (IS_PIN_DIGITAL(pin)) {
          Firmata.write((byte)INPUT);
          Firmata.write(1);
          Firmata.write((byte)OUTPUT);
          Firmata.write(1);
        }
        if (IS_PIN_ANALOG(pin)) {
          Firmata.write(ANALOG);
          Firmata.write(10);
        }
        if (IS_PIN_PWM(pin)) {
          Firmata.write(PWM);
          Firmata.write(8);
        }
        if (IS_PIN_SERVO(pin)) {
          Firmata.write(SERVO);
          Firmata.write(14);
        }
        if (IS_PIN_I2C(pin)) {
          Firmata.write(I2C);
          Firmata.write(1);  // to do: determine appropriate value
        }
        Firmata.write(127);
      }
      Firmata.write(END_SYSEX);
      break;
    case PIN_STATE_QUERY:
      if (argc > 0) {
        byte pin = argv[0];
        Firmata.write(START_SYSEX);
        Firmata.write(PIN_STATE_RESPONSE);
        Firmata.write(pin);
        if (pin < TOTAL_PINS) {
          Firmata.write((byte)pinConfig[pin]);
          Firmata.write((byte)pinState[pin] & 0x7F);
          if (pinState[pin] & 0xFF80) Firmata.write((byte)(pinState[pin] >> 7) & 0x7F);
          if (pinState[pin] & 0xC000) Firmata.write((byte)(pinState[pin] >> 14) & 0x7F);
        }
        Firmata.write(END_SYSEX);
      }
      break;
    case ANALOG_MAPPING_QUERY:
      Firmata.write(START_SYSEX);
      Firmata.write(ANALOG_MAPPING_RESPONSE);
      for (byte pin = 0; pin < TOTAL_PINS; pin++) {
        Firmata.write(IS_PIN_ANALOG(pin) ? PIN_TO_ANALOG(pin) : 127);
      }
      Firmata.write(END_SYSEX);
      break;
  }
}

void enableI2CPins()
{
  byte i;
  // is there a faster way to do this? would probaby require importing
  // Arduino.h to get SCL and SDA pins
  for (i = 0; i < TOTAL_PINS; i++) {
    if (IS_PIN_I2C(i)) {
      // mark pins as i2c so they are ignore in non i2c data requests
      setPinModeCallback(i, I2C);
    }
  }

  isI2CEnabled = true;

  // is there enough time before the first I2C request to call this here?
  Wire.begin();
}

/* disable the i2c pins so they can be used for other functions */
void disableI2CPins() {
  isI2CEnabled = false;
  // disable read continuous mode for all devices
  queryIndex = -1;
  // uncomment the following if or when the end() method is added to Wire library
  // Wire.end();
}

/*==============================================================================
 * SETUP()
 *============================================================================*/

void systemResetCallback()
{
  // initialize a defalt state
  // TODO: option to load config from EEPROM instead of default
  if (isI2CEnabled) {
    disableI2CPins();
  }
  for (byte i = 0; i < TOTAL_PORTS; i++) {
    reportPINs[i] = false;      // by default, reporting off
    portConfigInputs[i] = 0;	// until activated
    previousPINs[i] = 0;
  }
  // pins with analog capability default to analog input
  // otherwise, pins default to digital output
  for (byte i = 0; i < TOTAL_PINS; i++) {
    if (IS_PIN_ANALOG(i)) {
      // turns off pullup, configures everything
      setPinModeCallback(i, ANALOG);
    } else {
      // sets the output to 0, configures portConfigInputs
      setPinModeCallback(i, OUTPUT);
    }
  }
  // by default, do not report any analog inputs
  analogInputsToReport = 0;

  /* send digital inputs to set the initial state on the host computer,
   * since once in the loop(), this firmware will only send on change */
  /*
  TODO: this can never execute, since no pins default to digital input
        but it will be needed when/if we support EEPROM stored config
  for (byte i=0; i < TOTAL_PORTS; i++) {
    outputPort(i, readPort(i, portConfigInputs[i]), true);
  }
  */
}

void setup()
{
  Firmata.setFirmwareVersion(FIRMATA_MAJOR_VERSION, FIRMATA_MINOR_VERSION);

  Firmata.attach(ANALOG_MESSAGE, analogWriteCallback);
  Firmata.attach(DIGITAL_MESSAGE, digitalWriteCallback);
  Firmata.attach(REPORT_ANALOG, reportAnalogCallback);
  Firmata.attach(REPORT_DIGITAL, reportDigitalCallback);
  Firmata.attach(SET_PIN_MODE, setPinModeCallback);
  Firmata.attach(START_SYSEX, sysexCallback);
  Firmata.attach(SYSTEM_RESET, systemResetCallback);

  Serial1.begin(57600); // Set the baud.
  Firmata.begin(Serial1);
  //Firmata.begin(57600);
  systemResetCallback();  // reset to default config
}

/*==============================================================================
 * LOOP()
 *============================================================================*/
void loop()
{
  byte pin, analogPin;

  /* DIGITALREAD - as fast as possible, check for changes and output them to the
   * FTDI buffer using Serial.print()  */
  checkDigitalInputs();

  /* SERIALREAD - processing incoming messagse as soon as possible, while still
   * checking digital inputs.  */
  while (Firmata.available())
    Firmata.processInput();

  /* SEND FTDI WRITE BUFFER - make sure that the FTDI buffer doesn't go over
   * 60 bytes. use a timer to sending an event character every 4 ms to
   * trigger the buffer to dump. */

  currentMillis = millis();
  if (currentMillis - previousMillis > samplingInterval) {
    previousMillis += samplingInterval;
    /* ANALOGREAD - do all analogReads() at the configured sampling interval */
    for (pin = 0; pin < TOTAL_PINS; pin++) {
      if (IS_PIN_ANALOG(pin) && pinConfig[pin] == ANALOG) {
        analogPin = PIN_TO_ANALOG(pin);
        if (analogInputsToReport & (1 << analogPin)) {
          Firmata.sendAnalog(analogPin, analogRead(analogPin));
        }
      }
    }
    // report i2c data for all device with read continuous mode enabled
    if (queryIndex > -1) {
      for (byte i = 0; i < queryIndex + 1; i++) {
        readAndReportData(query[i].addr, query[i].reg, query[i].bytes);
      }
    }
  }
}
	/*
	* Firmata is a generic protocol for communicating with microcontrollers
	* from software on a host computer. It is intended to work with
	* any host computer software package.
	*
	* To download a host software package, please clink on the following link
	* to open the download page in your default browser.
	*
	* http://firmata.org/wiki/Download
	*/

	/*
	Copyright (C) 2006-2008 Hans-Christoph Steiner. All rights reserved.
	Copyright (C) 2010-2011 Paul Stoffregen. All rights reserved.
	Copyright (C) 2009 Shigeru Kobayashi. All rights reserved.
	Copyright (C) 2009-2011 Jeff Hoefs. All rights reserved.

	This library is free software; you can redistribute it and/or
	modify it under the terms of the GNU Lesser General Public
	License as published by the Free Software Foundation; either
	version 2.1 of the License, or (at your option) any later version.

	See file LICENSE.txt for further informations on licensing terms.

	formatted using the GNU C formatting and indenting
	*/

	/*
	* TODO: use Program Control to load stored profiles from EEPROM
	*/

	#include <Servo.h>
	#include <Wire.h>
	#include <Firmata.h>

	// move the following defines to Firmata.h?
	#define I2C_WRITE B00000000
	#define I2C_READ B00001000
	#define I2C_READ_CONTINUOUSLY B00010000
	#define I2C_STOP_READING B00011000
	#define I2C_READ_WRITE_MODE_MASK B00011000
	#define I2C_10BIT_ADDRESS_MODE_MASK B00100000

	#define MAX_QUERIES 8
	#define MINIMUM_SAMPLING_INTERVAL 10

	#define REGISTER_NOT_SPECIFIED -1

	/*==============================================================================
	* GLOBAL VARIABLES
	============================================================================/

	/* analog inputs */
	int analogInputsToReport = 0; // bitwise array to store pin reporting

	/* digital input ports */
	byte reportPINs[TOTAL_PORTS]; // 1 = report this port, 0 = silence
	byte previousPINs[TOTAL_PORTS]; // previous 8 bits sent

	/* pins configuration */
	byte pinConfig[TOTAL_PINS]; // configuration of every pin
	byte portConfigInputs[TOTAL_PORTS]; // each bit: 1 = pin in INPUT, 0 = anything else
	int pinState[TOTAL_PINS]; // any value that has been written

	/* timer variables */
	unsigned long currentMillis; // store the current value from millis()
	unsigned long previousMillis; // for comparison with currentMillis
	int samplingInterval = 19; // how often to run the main loop (in ms)

	/* i2c data */
	struct i2c_device_info {
	byte addr;
	byte reg;
	byte bytes;
	};

	/* for i2c read continuous more */
	i2c_device_info query[MAX_QUERIES];

	byte i2cRxData[32];
	boolean isI2CEnabled = false;
	signed char queryIndex = -1;
	unsigned int i2cReadDelayTime = 0; // default delay time between i2c read request and Wire.requestFrom()

	Servo servos[MAX_SERVOS];
	/*==============================================================================
	* FUNCTIONS
	============================================================================/

	void readAndReportData(byte address, int theRegister, byte numBytes) {
	// allow I2C requests that don't require a register read
	// for example, some devices using an interrupt pin to signify new data available
	// do not always require the register read so upon interrupt you call Wire.requestFrom()
	if (theRegister != REGISTER_NOT_SPECIFIED) {
	Wire.beginTransmission(address);
	#if ARDUINO >= 100
	Wire.write((byte)theRegister);
	#else
	Wire.send((byte)theRegister);
	#endif
	Wire.endTransmission();
	// do not set a value of 0
	if (i2cReadDelayTime > 0) {
	// delay is necessary for some devices such as WiiNunchuck
	delayMicroseconds(i2cReadDelayTime);
	}
	} else {
	theRegister = 0; // fill the register with a dummy value
	}

	Wire.requestFrom(address, numBytes); // all bytes are returned in requestFrom

	// check to be sure correct number of bytes were returned by slave
	if (numBytes == Wire.available()) {
	i2cRxData[0] = address;
	i2cRxData[1] = theRegister;
	for (int i = 0; i < numBytes; i++) {
	#if ARDUINO >= 100
	i2cRxData[2 + i] = Wire.read();
	#else
	i2cRxData[2 + i] = Wire.receive();
	#endif
	}
	}
	else {
	if (numBytes > Wire.available()) {
	Firmata.sendString("I2C Read Error: Too many bytes received");
	} else {
	Firmata.sendString("I2C Read Error: Too few bytes received");
	}
	}

	// send slave address, register and received bytes
	Firmata.sendSysex(SYSEX_I2C_REPLY, numBytes + 2, i2cRxData);
	}

	void outputPort(byte portNumber, byte portValue, byte forceSend)
	{
	// pins not configured as INPUT are cleared to zeros
	portValue = portValue & portConfigInputs[portNumber];
	// only send if the value is different than previously sent
	if (forceSend \|\| previousPINs[portNumber] != portValue) {
	Firmata.sendDigitalPort(portNumber, portValue);
	previousPINs[portNumber] = portValue;
	}
	}

	/* -----------------------------------------------------------------------------
	* check all the active digital inputs for change of state, then add any events
	* to the Serial output queue using Serial.print() */
	void checkDigitalInputs(void)
	{
	/* Using non-looping code allows constants to be given to readPort().
	* The compiler will apply substantial optimizations if the inputs
	* to readPort() are compile-time constants. */
	if (TOTAL_PORTS > 0 && reportPINs[0]) outputPort(0, readPort(0, portConfigInputs[0]), false);
	if (TOTAL_PORTS > 1 && reportPINs[1]) outputPort(1, readPort(1, portConfigInputs[1]), false);
	if (TOTAL_PORTS > 2 && reportPINs[2]) outputPort(2, readPort(2, portConfigInputs[2]), false);
	if (TOTAL_PORTS > 3 && reportPINs[3]) outputPort(3, readPort(3, portConfigInputs[3]), false);
	if (TOTAL_PORTS > 4 && reportPINs[4]) outputPort(4, readPort(4, portConfigInputs[4]), false);
	if (TOTAL_PORTS > 5 && reportPINs[5]) outputPort(5, readPort(5, portConfigInputs[5]), false);
	if (TOTAL_PORTS > 6 && reportPINs[6]) outputPort(6, readPort(6, portConfigInputs[6]), false);
	if (TOTAL_PORTS > 7 && reportPINs[7]) outputPort(7, readPort(7, portConfigInputs[7]), false);
	if (TOTAL_PORTS > 8 && reportPINs[8]) outputPort(8, readPort(8, portConfigInputs[8]), false);
	if (TOTAL_PORTS > 9 && reportPINs[9]) outputPort(9, readPort(9, portConfigInputs[9]), false);
	if (TOTAL_PORTS > 10 && reportPINs[10]) outputPort(10, readPort(10, portConfigInputs[10]), false);
	if (TOTAL_PORTS > 11 && reportPINs[11]) outputPort(11, readPort(11, portConfigInputs[11]), false);
	if (TOTAL_PORTS > 12 && reportPINs[12]) outputPort(12, readPort(12, portConfigInputs[12]), false);
	if (TOTAL_PORTS > 13 && reportPINs[13]) outputPort(13, readPort(13, portConfigInputs[13]), false);
	if (TOTAL_PORTS > 14 && reportPINs[14]) outputPort(14, readPort(14, portConfigInputs[14]), false);
	if (TOTAL_PORTS > 15 && reportPINs[15]) outputPort(15, readPort(15, portConfigInputs[15]), false);
	}

	// -----------------------------------------------------------------------------
	/* sets the pin mode to the correct state and sets the relevant bits in the
	* two bit-arrays that track Digital I/O and PWM status
	*/
	void setPinModeCallback(byte pin, int mode)
	{
	if (pinConfig[pin] == I2C && isI2CEnabled && mode != I2C) {
	// disable i2c so pins can be used for other functions
	// the following if statements should reconfigure the pins properly
	disableI2CPins();
	}
	if (IS_PIN_SERVO(pin) && mode != SERVO && servos[PIN_TO_SERVO(pin)].attached()) {
	servos[PIN_TO_SERVO(pin)].detach();
	}
	if (IS_PIN_ANALOG(pin)) {
	reportAnalogCallback(PIN_TO_ANALOG(pin), mode == ANALOG ? 1 : 0); // turn on/off reporting
	}
	if (IS_PIN_DIGITAL(pin)) {
	if (mode == INPUT) {
	portConfigInputs[pin / 8] \|= (1 << (pin & 7));
	} else {
	portConfigInputs[pin / 8] &= ~(1 << (pin & 7));
	}
	}
	pinState[pin] = 0;
	switch (mode) {
	case ANALOG:
	if (IS_PIN_ANALOG(pin)) {
	if (IS_PIN_DIGITAL(pin)) {
	pinMode(PIN_TO_DIGITAL(pin), INPUT); // disable output driver
	digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable internal pull-ups
	}
	pinConfig[pin] = ANALOG;
	}
	break;
	case INPUT:
	if (IS_PIN_DIGITAL(pin)) {
	pinMode(PIN_TO_DIGITAL(pin), INPUT); // disable output driver
	digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable internal pull-ups
	pinConfig[pin] = INPUT;
	}
	break;
	case OUTPUT:
	if (IS_PIN_DIGITAL(pin)) {
	digitalWrite(PIN_TO_DIGITAL(pin), LOW); // disable PWM
	pinMode(PIN_TO_DIGITAL(pin), OUTPUT);
	pinConfig[pin] = OUTPUT;
	}
	break;
	case PWM:
	if (IS_PIN_PWM(pin)) {
	pinMode(PIN_TO_PWM(pin), OUTPUT);
	analogWrite(PIN_TO_PWM(pin), 0);
	pinConfig[pin] = PWM;
	}
	break;
	case SERVO:
	if (IS_PIN_SERVO(pin)) {
	pinConfig[pin] = SERVO;
	if (!servos[PIN_TO_SERVO(pin)].attached()) {
	servos[PIN_TO_SERVO(pin)].attach(PIN_TO_DIGITAL(pin));
	}
	}
	break;
	case I2C:
	if (IS_PIN_I2C(pin)) {
	// mark the pin as i2c
	// the user must call I2C_CONFIG to enable I2C for a device
	pinConfig[pin] = I2C;
	}
	break;
	default:
	Firmata.sendString("Unknown pin mode"); // TODO: put error msgs in EEPROM
	}
	// TODO: save status to EEPROM here, if changed
	}

	void analogWriteCallback(byte pin, int value)
	{
	if (pin < TOTAL_PINS) {
	switch (pinConfig[pin]) {
	case SERVO:
	if (IS_PIN_SERVO(pin))
	servos[PIN_TO_SERVO(pin)].write(value);
	pinState[pin] = value;
	break;
	case PWM:
	if (IS_PIN_PWM(pin))
	analogWrite(PIN_TO_PWM(pin), value);
	pinState[pin] = value;
	break;
	}
	}
	}

	void digitalWriteCallback(byte port, int value)
	{
	byte pin, lastPin, mask = 1, pinWriteMask = 0;

	if (port < TOTAL_PORTS) {
	// create a mask of the pins on this port that are writable.
	lastPin = port * 8 + 8;
	if (lastPin > TOTAL_PINS) lastPin = TOTAL_PINS;
	for (pin = port * 8; pin < lastPin; pin++) {
	// do not disturb non-digital pins (eg, Rx & Tx)
	if (IS_PIN_DIGITAL(pin)) {
	// only write to OUTPUT and INPUT (enables pullup)
	// do not touch pins in PWM, ANALOG, SERVO or other modes
	if (pinConfig[pin] == OUTPUT \|\| pinConfig[pin] == INPUT) {
	pinWriteMask \|= mask;
	pinState[pin] = ((byte)value & mask) ? 1 : 0;
	}
	}
	mask = mask << 1;
	}
	writePort(port, (byte)value, pinWriteMask);
	}
	}


	// -----------------------------------------------------------------------------
	/* sets bits in a bit array (int) to toggle the reporting of the analogIns
	*/
	//void FirmataClass::setAnalogPinReporting(byte pin, byte state) {
	//}
	void reportAnalogCallback(byte analogPin, int value)
	{
	if (analogPin < TOTAL_ANALOG_PINS) {
	if (value == 0) {
	analogInputsToReport = analogInputsToReport &~ (1 << analogPin);
	} else {
	analogInputsToReport = analogInputsToReport \| (1 << analogPin);
	}
	}
	// TODO: save status to EEPROM here, if changed
	}

	void reportDigitalCallback(byte port, int value)
	{
	if (port < TOTAL_PORTS) {
	reportPINs[port] = (byte)value;
	}
	// do not disable analog reporting on these 8 pins, to allow some
	// pins used for digital, others analog. Instead, allow both types
	// of reporting to be enabled, but check if the pin is configured
	// as analog when sampling the analog inputs. Likewise, while
	// scanning digital pins, portConfigInputs will mask off values from any
	// pins configured as analog
	}

	/*==============================================================================
	* SYSEX-BASED commands
	============================================================================/

	void sysexCallback(byte command, byte argc, byte *argv)
	{
	byte mode;
	byte slaveAddress;
	byte slaveRegister;
	byte data;
	unsigned int delayTime;

	switch (command) {
	case I2C_REQUEST:
	mode = argv[1] & I2C_READ_WRITE_MODE_MASK;
	if (argv[1] & I2C_10BIT_ADDRESS_MODE_MASK) {
	Firmata.sendString("10-bit addressing mode is not yet supported");
	return;
	}
	else {
	slaveAddress = argv[0];
	}

	switch (mode) {
	case I2C_WRITE:
	Wire.beginTransmission(slaveAddress);
	for (byte i = 2; i < argc; i += 2) {
	data = argv[i] + (argv[i + 1] << 7);
	#if ARDUINO >= 100
	Wire.write(data);
	#else
	Wire.send(data);
	#endif
	}
	Wire.endTransmission();
	delayMicroseconds(70);
	break;
	case I2C_READ:
	if (argc == 6) {
	// a slave register is specified
	slaveRegister = argv[2] + (argv[3] << 7);
	data = argv[4] + (argv[5] << 7); // bytes to read
	readAndReportData(slaveAddress, (int)slaveRegister, data);
	}
	else {
	// a slave register is NOT specified
	data = argv[2] + (argv[3] << 7); // bytes to read
	readAndReportData(slaveAddress, (int)REGISTER_NOT_SPECIFIED, data);
	}
	break;
	case I2C_READ_CONTINUOUSLY:
	if ((queryIndex + 1) >= MAX_QUERIES) {
	// too many queries, just ignore
	Firmata.sendString("too many queries");
	break;
	}
	queryIndex++;
	query[queryIndex].addr = slaveAddress;
	query[queryIndex].reg = argv[2] + (argv[3] << 7);
	query[queryIndex].bytes = argv[4] + (argv[5] << 7);
	break;
	case I2C_STOP_READING:
	byte queryIndexToSkip;
	// if read continuous mode is enabled for only 1 i2c device, disable
	// read continuous reporting for that device
	if (queryIndex <= 0) {
	queryIndex = -1;
	} else {
	// if read continuous mode is enabled for multiple devices,
	// determine which device to stop reading and remove it's data from
	// the array, shifiting other array data to fill the space
	for (byte i = 0; i < queryIndex + 1; i++) {
	if (query[i].addr = slaveAddress) {
	queryIndexToSkip = i;
	break;
	}
	}

	for (byte i = queryIndexToSkip; i < queryIndex + 1; i++) {
	if (i < MAX_QUERIES) {
	query[i].addr = query[i + 1].addr;
	query[i].reg = query[i + 1].addr;
	query[i].bytes = query[i + 1].bytes;
	}
	}
	queryIndex--;
	}
	break;
	default:
	break;
	}
	break;
	case I2C_CONFIG:
	delayTime = (argv[0] + (argv[1] << 7));

	if (delayTime > 0) {
	i2cReadDelayTime = delayTime;
	}

	if (!isI2CEnabled) {
	enableI2CPins();
	}

	break;
	case SERVO_CONFIG:
	if (argc > 4) {
	// these vars are here for clarity, they'll optimized away by the compiler
	byte pin = argv[0];
	int minPulse = argv[1] + (argv[2] << 7);
	int maxPulse = argv[3] + (argv[4] << 7);

	if (IS_PIN_SERVO(pin)) {
	if (servos[PIN_TO_SERVO(pin)].attached())
	servos[PIN_TO_SERVO(pin)].detach();
	servos[PIN_TO_SERVO(pin)].attach(PIN_TO_DIGITAL(pin), minPulse, maxPulse);
	setPinModeCallback(pin, SERVO);
	}
	}
	break;
	case SAMPLING_INTERVAL:
	if (argc > 1) {
	samplingInterval = argv[0] + (argv[1] << 7);
	if (samplingInterval < MINIMUM_SAMPLING_INTERVAL) {
	samplingInterval = MINIMUM_SAMPLING_INTERVAL;
	}
	} else {
	//Firmata.sendString("Not enough data");
	}
	break;
	case EXTENDED_ANALOG:
	if (argc > 1) {
	int val = argv[1];
	if (argc > 2) val \|= (argv[2] << 7);
	if (argc > 3) val \|= (argv[3] << 14);
	analogWriteCallback(argv[0], val);
	}
	break;
	case CAPABILITY_QUERY:
	Firmata.write(START_SYSEX);
	Firmata.write(CAPABILITY_RESPONSE);
	for (byte pin = 0; pin < TOTAL_PINS; pin++) {
	if (IS_PIN_DIGITAL(pin)) {
	Firmata.write((byte)INPUT);
	Firmata.write(1);
	Firmata.write((byte)OUTPUT);
	Firmata.write(1);
	}
	if (IS_PIN_ANALOG(pin)) {
	Firmata.write(ANALOG);
	Firmata.write(10);
	}
	if (IS_PIN_PWM(pin)) {
	Firmata.write(PWM);
	Firmata.write(8);
	}
	if (IS_PIN_SERVO(pin)) {
	Firmata.write(SERVO);
	Firmata.write(14);
	}
	if (IS_PIN_I2C(pin)) {
	Firmata.write(I2C);
	Firmata.write(1); // to do: determine appropriate value
	}
	Firmata.write(127);
	}
	Firmata.write(END_SYSEX);
	break;
	case PIN_STATE_QUERY:
	if (argc > 0) {
	byte pin = argv[0];
	Firmata.write(START_SYSEX);
	Firmata.write(PIN_STATE_RESPONSE);
	Firmata.write(pin);
	if (pin < TOTAL_PINS) {
	Firmata.write((byte)pinConfig[pin]);
	Firmata.write((byte)pinState[pin] & 0x7F);
	if (pinState[pin] & 0xFF80) Firmata.write((byte)(pinState[pin] >> 7) & 0x7F);
	if (pinState[pin] & 0xC000) Firmata.write((byte)(pinState[pin] >> 14) & 0x7F);
	}
	Firmata.write(END_SYSEX);
	}
	break;
	case ANALOG_MAPPING_QUERY:
	Firmata.write(START_SYSEX);
	Firmata.write(ANALOG_MAPPING_RESPONSE);
	for (byte pin = 0; pin < TOTAL_PINS; pin++) {
	Firmata.write(IS_PIN_ANALOG(pin) ? PIN_TO_ANALOG(pin) : 127);
	}
	Firmata.write(END_SYSEX);
	break;
	}
	}

	void enableI2CPins()
	{
	byte i;
	// is there a faster way to do this? would probaby require importing
	// Arduino.h to get SCL and SDA pins
	for (i = 0; i < TOTAL_PINS; i++) {
	if (IS_PIN_I2C(i)) {
	// mark pins as i2c so they are ignore in non i2c data requests
	setPinModeCallback(i, I2C);
	}
	}

	isI2CEnabled = true;

	// is there enough time before the first I2C request to call this here?
	Wire.begin();
	}

	/* disable the i2c pins so they can be used for other functions */
	void disableI2CPins() {
	isI2CEnabled = false;
	// disable read continuous mode for all devices
	queryIndex = -1;
	// uncomment the following if or when the end() method is added to Wire library
	// Wire.end();
	}

	/*==============================================================================
	* SETUP()
	============================================================================/

	void systemResetCallback()
	{
	// initialize a defalt state
	// TODO: option to load config from EEPROM instead of default
	if (isI2CEnabled) {
	disableI2CPins();
	}
	for (byte i = 0; i < TOTAL_PORTS; i++) {
	reportPINs[i] = false; // by default, reporting off
	portConfigInputs[i] = 0; // until activated
	previousPINs[i] = 0;
	}
	// pins with analog capability default to analog input
	// otherwise, pins default to digital output
	for (byte i = 0; i < TOTAL_PINS; i++) {
	if (IS_PIN_ANALOG(i)) {
	// turns off pullup, configures everything
	setPinModeCallback(i, ANALOG);
	} else {
	// sets the output to 0, configures portConfigInputs
	setPinModeCallback(i, OUTPUT);
	}
	}
	// by default, do not report any analog inputs
	analogInputsToReport = 0;

	/* send digital inputs to set the initial state on the host computer,
	* since once in the loop(), this firmware will only send on change */
	/*
	TODO: this can never execute, since no pins default to digital input
	but it will be needed when/if we support EEPROM stored config
	for (byte i=0; i < TOTAL_PORTS; i++) {
	outputPort(i, readPort(i, portConfigInputs[i]), true);
	}
	*/
	}

	void setup()
	{
	Firmata.setFirmwareVersion(FIRMATA_MAJOR_VERSION, FIRMATA_MINOR_VERSION);

	Firmata.attach(ANALOG_MESSAGE, analogWriteCallback);
	Firmata.attach(DIGITAL_MESSAGE, digitalWriteCallback);
	Firmata.attach(REPORT_ANALOG, reportAnalogCallback);
	Firmata.attach(REPORT_DIGITAL, reportDigitalCallback);
	Firmata.attach(SET_PIN_MODE, setPinModeCallback);
	Firmata.attach(START_SYSEX, sysexCallback);
	Firmata.attach(SYSTEM_RESET, systemResetCallback);

	Serial1.begin(57600); // Set the baud.
	Firmata.begin(Serial1);
	//Firmata.begin(57600);
	systemResetCallback(); // reset to default config
	}

	/*==============================================================================
	* LOOP()
	============================================================================/
	void loop()
	{
	byte pin, analogPin;

	/* DIGITALREAD - as fast as possible, check for changes and output them to the
	* FTDI buffer using Serial.print() */
	checkDigitalInputs();

	/* SERIALREAD - processing incoming messagse as soon as possible, while still
	* checking digital inputs. */
	while (Firmata.available())
	Firmata.processInput();

	/* SEND FTDI WRITE BUFFER - make sure that the FTDI buffer doesn't go over
	* 60 bytes. use a timer to sending an event character every 4 ms to
	* trigger the buffer to dump. */

	currentMillis = millis();
	if (currentMillis - previousMillis > samplingInterval) {
	previousMillis += samplingInterval;
	/* ANALOGREAD - do all analogReads() at the configured sampling interval */
	for (pin = 0; pin < TOTAL_PINS; pin++) {
	if (IS_PIN_ANALOG(pin) && pinConfig[pin] == ANALOG) {
	analogPin = PIN_TO_ANALOG(pin);
	if (analogInputsToReport & (1 << analogPin)) {
	Firmata.sendAnalog(analogPin, analogRead(analogPin));
	}
	}
	}
	// report i2c data for all device with read continuous mode enabled
	if (queryIndex > -1) {
	for (byte i = 0; i < queryIndex + 1; i++) {
	readAndReportData(query[i].addr, query[i].reg, query[i].bytes);
	}
	}
	}
	}