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I am running a C program on an AVR chip. Whenever a serial signal is heard, it runs the serial interrupt ISR (USART_RX_vect). In this method it should turn on change to = 1;. Then in my main while loop, it should clear the LCD and display it and then set change = 0 again.

This is to stop it continually doing the calulations, and displaying the result on the LCD a million times a minute..

However, when the interrupt method changes the change variable to 1, it does not seem to change it "globally" and in the main method it is always 0..

There is a bit of stuff in here that is for debugging purposes.

#define LED PB5
#define output_low(port,pin) port &= ~(1<<pin)
#define output_high(port,pin) port |= (1<<pin)
#define set_input(portdir,pin) portdir &= ~(1<<pin)
#define set_output(portdir,pin) portdir |= (1<<pin)

#define F_CPU 16000000UL
#define BAUD 9600
#define MYUBRR F_CPU/16/BAUD-1

#define STARTCHAR 'R'
#define ENDCHAR 'E'

char reading;
char inputBuffer[12];
char readStatus;
uint8_t position;
int change;

char output;
int result;

struct Axis
    uint8_t axisNumber;
    uint16_t position;
    uint16_t oldPosition;

} axis1, axis2, axis3;


void USART_Init( unsigned int ubrr)
   /*Set baud rate */
   UBRR0H = (unsigned char)(ubrr>>8);
   UBRR0L = (unsigned char)ubrr;

  /*Enable receiver and transmitter */
   UCSR0B = (1<<RXEN0)|(1<<TXEN0);

   /* Set frame format: 8data, 2stop bit */
   UCSR0C = (1<<USBS0)|(3<<UCSZ00);

void USART_Transmit( unsigned char data )
    UDR0 = data;

unsigned char USART_Receive( void )
   return UDR0;


int main(void)

    /* Turn on Receive Complete Interrupt */
    UCSR0B |= (1 << RXCIE0);

    /* Turn On GLobal Interrupts */

    position = 0;
    change = 0;

    /* Initialise LCD */
    lcd_init(LCD_DISP_ON);  /* Initialize display, cursor off. */

    //Turn on LED 13

    while (1)               /* Loop forever */
        if (change == 1)
            //If not reading, display the result on the LCD display.
            axis1.position  = (inputBuffer[0]<< 8) | inputBuffer[1];
            axis2.position  = (inputBuffer[2]<< 8) | inputBuffer[3];
            axis3.position  = (inputBuffer[4]<< 8) | inputBuffer[5];

            char axis1Printout[12];
            char axis2Printout[12];
            char axis3Printout[12];

            sprintf(axis1Printout,"%u ", axis1.position);
            sprintf(axis2Printout,"%u ", axis2.position);
            sprintf(axis3Printout,"%u ", axis3.position);

            char output[40] = "";
            strcat(output, axis1Printout);
            strcat(output, axis2Printout);
            //strcat(output, axis3Printout);

            lcd_clrscr();  /* Clear the screen*/
            change = 0;


    change = 1;
    unsigned char input = USART_Receive();

    if (input == 'R')
        readStatus = 0; //Reading
        position = 0;
    else if ((input != 'E') && (position < 12) && (position > -1))
        inputBuffer[position] = input;
    else if (input == 'E')
        readStatus = 1; //Stop Reading
        position = -1;
share|improve this question
Are you sure the ISR is actually getting called? –  NPE Feb 10 '12 at 13:24

3 Answers 3

up vote 6 down vote accepted

You need to declare change using the volatile keyword:

volatile int change;

This tells the two 'threads' (main execution loop and your ISR code) to not 'cache' the value in a register, but always retrieve it from memory.

Edit: There's another problem with the code - in your main loop, by the time you set changed to 0, you may have already had another interrupt which should have triggered your loop to run again. The easy-but-not-guaranteed fix is to immediately set changed to 0 straight after you check it. The proper way would be to use a lock - but depending on your situation, the first option might do.

share|improve this answer
I would leave the change at the end and make sure the interrupt does not update the values until change is 0. This will prevent the interrupt from corrupting the values while the main routine is reading them. –  Jeff Feb 10 '12 at 18:59
Another option is to leave the interrupt flag cleared in the interrupt itself, and leave the main routine to re-enable interrupts. I'm not familiar with the AVRs myself, but don't processors normally clear the interrupt flag on interrupt, and you need to call sei() at the end of the interrupt routine? You could just leave that for the main routine after you've done your processing - on most processors I've used, it will queue interrupts while global interrupts are disabled, so if data arrives while you're processing it will interrupt when you re-enable them. Buffer length might be a concern. –  Rophuine Feb 10 '12 at 22:43

Make the variable declaration volatile to ensure that a changed value is written imediately to the variable in memory.

share|improve this answer

An object shared by an interrupt handler and the application code should be qualified as volatile in the declaration.

Without the qualifier, the implementation can assume the object cannot change unexpectedly in the application code and can cache the variable (in a register for example) for optimizations while executing the application code.

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