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/* Pd_firmware
* ------------------
*
*
* It was designed to work with the Pd patch of the same
* name in: Help -> Browser -> examples -> hardware
*
* (cleft) 2006 Hans-Christoph Steiner
* @author: Hans-Christoph Steiner
* @date: 2006-03-10
* @location: Polytechnic University, Brooklyn, New York, USA
*/
/*
* Pduino protocol
* ===============
* data: 0-127
* control: 128-255
*
* Pd->Arduino commands
* --------------------
* 200-213 - set digital pin 0-13 to INPUT
* 214-227 - set digital pin 0-13 to OUTPUT
* 230 - next byte sets PWM0 value
* 231 - next byte sets PWM1 value
* 232 - next byte sets PWM2 value
* 238 - disable all digital inputs
* 239 - enable all digital inputs
* 240 - disable all analog inputs
* 241 - enable 1 analog input (0)
* 242 - enable 2 analog inputs (0,1)
* 243 - enable 3 analog inputs (0-2)
* 244 - enable 4 analog inputs (0-3)
* 245 - enable 5 analog inputs (0-4)
* 246 - enable 6 analog inputs (0-5)
*
* Pd->Arduino byte cycle
* ----------------------
* 0 digitalOut 0-6 bitmask
* 1 digitalOut 7-13 bitmask
* 2 cycle marker (255/11111111)
*
* Arduino->Pd byte cycle
* ----------------------
* 0 digitalIn 0-6 bitmask
* 1 digitalIn 7-13 bitmask
* 2 analogIn0 byte0
* 3 analogIn0 byte1
* 4 analogIn1 byte0
* 5 analogIn1 byte1
* 6 analogIn2 byte0
* 7 analogIn2 byte1
* 8 analogIn3 byte0
* 9 analogIn3 byte1
* 10 analogIn4 byte0
* 11 analogIn4 byte1
* 12 analogIn5 byte0
* 13 analogIn5 byte1
* 14 cycle marker (255/11111111)
*
*
* TX RX
* -----------------------
*
*/
/*
* CAUTION!! Be careful with the Serial Monitor, it could freeze
* your computer with this firmware running! It outputs data
* without a delay() so its very fast.
*/
#define TOTAL_DIGITAL_PINS 14
// for comparing along with INPUT and OUTPUT
#define PWM 2
// this flag says the next serial input will be PWM data
byte waitForPWMData = 0;
// this flag says the first data byte for the digital outs is next
boolean firstInputByte = false;
/* this int serves as an array of bits to store pin status
* 0 = INPUT, 1 = OUTPUT
*/
int digitalPinStatus;
/* this byte stores the status off whether PWM is on or not
* bit 9 = PWM0, bit 10 = PWM1, bit 11 = PWM2
* the rest of the bits are unused and should remain 0
*/
int pwmStatus;
boolean digitalInputsEnabled = true;
byte analogInputsEnabled = 6;
byte analogPin;
int analogData;
// -------------------------------------------------------------------------
void transmitDigitalInput(byte startPin) {
byte i;
byte digitalPin;
byte digitalPinBit;
byte transmitByte;
byte digitalData;
for(i=0;i<7;++i) {
digitalPin = i+startPin;
digitalPinBit = OUTPUT << digitalPin;
// only read the pin if its set to input
if(digitalPinStatus & digitalPinBit) {
digitalData = 0; // pin set to OUTPUT, don't read
}
else if( (digitalPin >= 9) && (pwmStatus & (1 << digitalPin)) ) {
digitalData = 0; // pin set to PWM, don't read
}
else {
// TODO: get digital in working
// digitalData = digitalRead(digitalPin);
digitalData = pwmStatus;
}
transmitByte = transmitByte + (2^(i+1-startPin)*digitalData);
}
printByte(transmitByte);
}
// -------------------------------------------------------------------------
/* this function 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 setPinMode(int pin, int mode) {
if(mode == INPUT) {
digitalPinStatus = digitalPinStatus &~ (1 << pin);
pwmStatus = pwmStatus &~ (1 << pin);
pinMode(pin,INPUT);
}
else if(mode == OUTPUT) {
digitalPinStatus = digitalPinStatus | (1 << pin);
pwmStatus = pwmStatus &~ (1 << pin);
pinMode(pin,OUTPUT);
}
else if( (mode == PWM) && (pin >= 9) && (pin <= 11) ) {
digitalPinStatus = digitalPinStatus | (1 << pin);
pwmStatus = pwmStatus | (1 << pin);
pinMode(pin,OUTPUT);
}
}
// -------------------------------------------------------------------------
void checkForInput() {
if(serialAvailable()) {
while(serialAvailable()) {
processInput( (byte)serialRead() );
}
}
}
// -------------------------------------------------------------------------
void processInput(byte inputData) {
int i;
int mask;
// the PWM commands (230-232) have a byte of data following the command
if (waitForPWMData > 0) {
// printByte(150);
// printByte(inputData);
analogWrite(waitForPWMData,inputData);
waitForPWMData = 0;
}
else if(inputData < 128) {
// printByte(151);
if(firstInputByte) {
// printByte(160);
for(i=0; i<7; ++i) {
mask = 1 << i;
//printByte(254);
//printByte(i);
//printByte(mask);
if(digitalPinStatus & mask) {
digitalWrite(i, inputData & mask);
//printByte(inputData & mask);
}
}
firstInputByte = false;
}
else {
// printByte(161);
// output data for pins 7-13
for(i=7; i<TOTAL_DIGITAL_PINS; ++i) {
mask = 1 << i;
//printByte(254);
//printByte(i);
//printByte(mask);
if( (digitalPinStatus & mask) && !(pwmStatus & mask) ) {
// inputData is a byte and mask is an int, so align the high part of mask
digitalWrite(i, inputData & (mask >> 7));
//printByte(inputData & (mask >> 7));
}
}
}
}
else {
// printByte(152);
// printByte(inputData);
switch (inputData) {
case 200:
case 201:
case 202:
case 203:
case 204:
case 205:
case 206:
case 207:
case 208:
case 209:
case 210:
case 211:
case 212:
case 213:
setPinMode(inputData-200,INPUT);
break;
case 214:
case 215:
case 216:
case 217:
case 218:
case 219:
case 220:
case 221:
case 222:
case 223:
case 224:
case 225:
case 226:
case 227:
setPinMode(inputData-214,OUTPUT);
break;
case 230:
case 231:
case 232:
waitForPWMData = inputData - 221; // set waitForPWMData to the PWM pin number
setPinMode(waitForPWMData, PWM);
break;
case 238:
digitalInputsEnabled = false;
break;
case 239:
digitalInputsEnabled = true;
break;
case 240:
case 241:
case 242:
case 243:
case 244:
case 245:
case 246:
analogInputsEnabled = inputData - 240;
break;
case 255:
firstInputByte = true;
break;
}
}
}
// =========================================================================
// -------------------------------------------------------------------------
void setup() {
byte i;
beginSerial(9600);
for(i=0; i<TOTAL_DIGITAL_PINS; ++i) {
setPinMode(i,INPUT);
}
}
// -------------------------------------------------------------------------
void loop() {
checkForInput();
// read all digital pins, in enabled
if(digitalInputsEnabled) {
transmitDigitalInput(0);
checkForInput();
transmitDigitalInput(7);
checkForInput();
}
else if(analogInputsEnabled) {
// filler bytes, since the first thing sent is always the digitalInputs
printByte(0);
printByte(0);
}
/* get analog in, for the number enabled
*/
for(analogPin=0; analogPin<analogInputsEnabled; ++analogPin) {
analogData = analogRead(analogPin);
// these two bytes get converted back into the whole number in Pd
printByte(analogData >> 7); // bitshift the big stuff into the output byte
printByte(analogData % 128); // mod by 32 for the small byte
checkForInput();
}
/* end with the cycle marker, if any of the inputs are enabled */
if( digitalInputsEnabled || analogInputsEnabled) {
printByte(255);
}
}
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