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The intention of the program below is to periodically output a dataframe on serial. The period is defined by a timed interrupt, every second.

The code worked on Arduino IDE version 0022, but on 1.0 I can't get it working. When using the timer routine and maxFrameLength is set to 0x40 or higher, the controller locks up. When using 0x39 or lower, the program keeps running (indicated by the flashing LED).

What's going wrong here and why? Is it a bug? Am I doing something wrong?

I'm using http://code.google.com/p/arduino-timerone/downloads/detail?name=TimerOne-v9.zip for the timer routine on a Mega1280.

#include "TimerOne.h"

#define LED 13
#define maxFrameLength 0x40

boolean stateLED = true;
byte frame[ maxFrameLength ];

void sendFrame() {
  digitalWrite( LED , stateLED );
  stateLED = !stateLED;
  Serial.write( frame, maxFrameLength ); // ptr + bytes to send
}

void setup() {
  pinMode( LED , OUTPUT );
  Timer1.initialize( 1000000 );  // initialize timer1 with 1 second period
  Timer1.attachInterrupt( sendFrame );
  Serial.begin( 9600 );
};

void loop() {
};
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What is the flow control setup on the serial port? Hardware? Software? None? –  stark May 12 '12 at 18:03
    
Flow control "None". –  jippie May 12 '12 at 18:32
    
Shouldn't you call Serial.begin before initialisng the timer? –  Alan Stokes May 12 '12 at 20:35
    
@AlanStokes: Correct, but doesn't solve the issue. Thxn –  jippie May 13 '12 at 13:35

2 Answers 2

up vote 7 down vote accepted

There are a number of issues that may or may not be causing a problem, but it should be fixed in any case. These comments are general in nature; I am not familiar with Arduino or its library specifically.

It is almost certainly inappropriate to issue a Serial.write() call in an interrupt handler (ISR). If the Serial object is interrupt driven, it will have an associated buffer. If that buffer is not large enough to take all the data, the function may block, which is a no no in an interrupt handler. Moreover, if the timer interrupt is a higher priority that the serial interrupt, you will cause a deadlock when Serial.write() blocks. 0x40 (64 bytes) seems like a likely buffer size for serial output, so that is likely the primary cause. If you can increase the buffer size that may make it work, but it remains a bad idea to perform potentially blocking operations in an ISR.

Even if serial output is polled rather than interrupt driven, your interrupt handler will take rather long, which is also a bad idea, but probably not the issue in this case, but at 9600,n,8,1, 64 characters will take 67 milliseconds to clear the transmit register.

stateLED and frame are shared variables (between interrupt and main contexts) and should therefore be declared volatile.

It is not shown in your fragment how and where frame is updated, but since the interrupt will occur asynchronously, any update to frame should be in a critical section - with at least the timer1 interrupt disabled.


Update

In the light of A.H.'s response I downloaded the source code and took a look. Serial is a static object of class HardwareSerial defined in \arduino-1.0\hardware\arduino\cores\arduino\hardwareSerial.cpp/.h. The transmit buffer length is indeed 64 bytes, and the HardwareSerial::write() function does "busy-wait" if the buffer is full. You will need to modify and re-build the source to extend the buffer or add a non-blocking version of write().

This is however certainly the cause of the lock-up - the buffer will never empty because the transmit interrupt cannot be serviced while the timer1 interrupt is running.

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"It is not shown in your fragment how and where frame is updated," I tried to find the smallest piece of code with wich I can reproduce the problem and I it turned out unnecessary to add that piece of the code. You make a valid point about disabling the interrupts for Timer1. I need to figure out the 'volatile' part too, I remember reading about it, but I'm not sure if it is supported by Arduino. –  jippie May 13 '12 at 13:47
    
@jippie: The word volatile in my answer is a link to an embedded.com article on the subject. Note that I have changed the link in the edit to the article I had originally intended but could not find at the time. So if you followed it before, take another look. –  Clifford May 13 '12 at 16:46
    
@jippie: A.H.'s answer shows that the 1.0 behaviour is as I suggested in the second paragraph and was previously as in teh third. Both are undesirable behaviour - an ISR busy-waiting, or blocking. The new library has not so much broken your code as exposed an existing flaw in a more visible fashion. –  Clifford May 13 '12 at 17:01
    
Don't know where I read it, but a little while ago I read that Arduino's serial buffer was 128 bytes. That must have been documentation to an old version. Anyway, this update looks like pin pointing the problem and at least I now know why my code fails and in what direction I need to rethink my design. –  jippie May 13 '12 at 18:14
1  
@Jippie: I believe that prior to 1.0 only the receive was buffered and that buffer was 128 bytes. In the 1.0 code both Tx and Rx are buffered and are either 16 to 64 depending on the amount of target RAM available. Note that I have never used Arduino; all I know is what I researched for this question. I urge you to take a look at the source yourself: arduino.googlecode.com/files/arduino-1.0-src.tar.gz –  Clifford May 13 '12 at 19:12

The release notes for 1.0 tell you:

  • Serial transmission is now asynchronous - that is, calls to Serial.print(), etc. add data to an outgoing buffer which is transmitted in the background. Also, the Serial.flush() command has been repurposed to wait for outgoing data to be transmitted, rather than dropping received incoming data.

Therefore your code worked before 1.0, because HardwareSerial::write(uint8_t) (which is the foundation for all output) had no buffer and returned only after the byte has been transmitted.

I find it astonishing, that the reference page for Serial does not mention this behaviour.

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That is an interesting find, I need to check that in more detail. Thnx –  jippie May 13 '12 at 13:48
    
Good spot. I downloaded the source to confirm my hypothesis and added to my answer accordingly. –  Clifford May 13 '12 at 17:31

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