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As a first project I plan on making a teensyduino ambient light with different light modes, which are checked in a big switch statement - now I want to switch from one mode to another by pressing a button.

googling lead me to using interrupts, but there is one point that is not clear - if I press the button during an expensive function, which takes long time and has many variables in use, what happens if i call the main loop from the interrupt, does the remaining state of remain in the ram and leads to a stackoverflow if I do switch too many times or is it cleared.

Here some code:

const int speed = 30 //milliseconds
const int modes = 11; //maximum number of modes
const int red   = 15;
const int green = 14;
const int blue  = 12;

volatile int mode  = 0;

void setup() {
    pinMode(red   , OUTPUT);
    pinMode(green , OUTPUT);
    pinMode(blue  , OUTPUT);
    randomSeed(analogRead(0));
    Serial.begin(9600);
    attachInterrupt(0,incMode,CHANGE); // 0 -> digital pin 2
}
void loop()  {
    switch(mode){
        case 0:{
            Serial.println("powerdown");
            setAll(0);
            delay(1000);
            break;
        }
        \\...
        case modes:{
            \\ expensive long function
        }
    }
}
void blinkAll(int times){
    for(int i=1;i <= times;i++){
        setAll(255);
        delay(speed*17);
        setAll(0);
        delay(speed*17);
    }
}

void setAll(int bright){
        analogWrite(red   , bright);
        analogWrite(green , bright);
        analogWrite(blue  , bright);
}
void incMode(){
    delay(speed);
    blinkAll(2); //to indicate mode has changed
    mode = (mode+1) % (modes+1); //switch starts with 0 so use "% modes+1"!
    Serial.println("mode increased");
    //--> loop();
    //--> would resume the main loop but lead to a stackoverflow i presume
}

How would I break out of the running function without delay and stack pollution. I know I could just set the mode and wait until the function has ended, but if I have a mode that takes minutes to end I want to be able to switch from it immediately.

PS.: Though I am using a teensyduino, I will use the arduino tag, and as I don't know what language the arduinio uses the tags c/c++. Please change this if it is not appropriate.

share|improve this question
    
Don't worry about the tags, you're one of the smart people who use tags appropriately and correctly. :) Programming AVRs is possible both by writing C and writing C++ code, as well as assembly, by the way. –  user529758 Oct 21 '12 at 11:23

1 Answer 1

up vote 1 down vote accepted

You would eventually overflow the stack if you were to reenter main from the interrupt handler multiple times recursively. Additionally, since you'll still be in the interrupt handler as far as the hardware is concerned, you'll have all kinds of weirdness - in particular, interrupts are blocked when you're already in an interrupt, which means delay() won't work and millis() won't count up, and various other things will be broken as well unless you figure out some way to manually re-enable interrupts.

A better way to solve this would be to make your 'expensive long function' instead be a state machine driven by a cheap, short function that is called very frequently. Your interrupt handler can then simply set a flag that is checked on entry into this function, at which point the current mode (ie, current state machine) is changed.

This approach also makes it easier to define new lighting modes. For example, you could define something like this:

struct phase {
  unsigned char r, g, b, delay;
};

unsigned long t_nextPhase;
volatile struct phase *forceMode = NULL;
struct phase *mode = blinkAll;
int nextPhase = 0;

struct phase blinkAll[] = {
  { 255, 255, 255, 17 },
  { 0, 0, 0, 17 },
  { 0, 0, 0, 255 } // loop sentinel
};

void lighting_kernel() {
    noInterrupts(); // ensure we don't race with interrupts
    if (forceMode) {
        mode = forceMode;
        forceMode = NULL;
        t_nextPhase = millis();
        nextPhase = 0;
    }
    interrupts();

    if (t_nextPhase > millis()) {
        return;
    }

    struct phase *cur_phase;
    do {
        cur_phase = mode[nextPhase++];
        if (cur_phase->delay == 255) {
            nextPhase = 0;
        }
    } while (cur_phase->delay == 255);

    analogWrite(red   , cur_phase->r);
    analogWrite(green , cur_phase->g);
    analogWrite(blue  , cur_phase->b);

    t_nextPhase = millis() + cur_phase->delay;    
}

Now to define a new lighting mode you just need a new array of colors and times, rather than writing new code. Adding things like color ramps and other such effects is left as an exercise to the reader.

share|improve this answer
    
but if I tried to add color modes with random numbers i have to use functions again, and if I added a bit more fancy stuff than simple blinking, the phase-Tables would consume all of my available memory, or am I getting something wrong. The device has 32k memory, the binary has now approx. 11k and a simple fadeAllIn-table I wrote has ~8k-plain text (i did not compile it yet). –  epsilonhalbe Oct 22 '12 at 10:55
    
You'll have to make the state transition function cleverer, but you can still do both with a state machine. The table thing was just one example of a way to do it. For example, to do fades, store in a global the before and after colors, plus a counter saying how far faded it is. Each time then calculate the current color using the counter. –  bdonlan Oct 22 '12 at 15:13

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