I have an interrupt handler that just isn't running fast enough for what I want to do. Basically I'm using it to generate sine waves by outputting a value from a look up table to a PORT on an AVR microncontroller but, unfortunately, this isn't happening fast enough for me to get the frequency of the wave that I want. I was told that I should look at implementing it in assembly as the compiler generated assembly might be slightly inefficient and may be able to be optimised but after looking at the assembly code I really can't see what I could do any better.
This is the C code:
const uint8_t amplitudes60[60] = {127, 140, 153, 166, 176, 191, 202, 212, 221, 230, 237, 243, 248, 251, 253, 254, 253, 251, 248, 243, 237, 230, 221, 212, 202, 191, 179, 166, 153, 140, 127, 114, 101, 88, 75, 63, 52, 42, 33, 24, 17, 11, 6, 3, 1, 0, 1, 3, 6, 11, 17, 24, 33, 42, 52, 63, 75, 88, 101, 114};
const uint8_t amplitudes13[13] = {127, 176, 221, 248, 202, 153, 101, 52, 17, 1, 6, 33, 75};
const uint8_t amplitudes10[10] = {127, 176, 248, 202, 101, 52, 17, 1, 33, 75};
volatile uint8_t numOfAmps = 60;
volatile uint8_t *amplitudes = amplitudes60;
volatile uint8_t amplitudePlace = 0;
ISR(TIMER1_COMPA_vect)
{
PORTD = amplitudes[amplitudePlace];
amplitudePlace++;
if(amplitudePlace == numOfAmps)
{
amplitudePlace = 0;
}
}
amplitudes and numOfAmps are both changed by another interrupt routine that runs much slower than this one (it basically is run to change the frequencies that are being played). At the end of the day I won't be using those exact arrays but it will be a very similar set up. I'll most likely have an array with 60 values and another with just 30. This is because I'm building a frequency sweeper and at the lower frequencies I can afford to give it more samples as I have more clock cycles to play with but at the higher frequencies I'm very much strapped for time.
I do realise that I can get it to work with a lower sampling rate but I don't want to go under 30 samples per period. I don't think having the pointer to the array makes it any slower as the assembly to get a value from an array and the assembly to get a value from a pointer to an array seems the same (which makes sense).
At the highest frequency that I have to produce I've been told I should be able to get it working with about 30 samples per sine wave period. At the moment with 30 samples the fastest it will run is at about half the required max frequency which I think means that my interrupt needs to run twice as fast.
So that code there when simulated takes 65 cycles to complete. Again, I've been told I should be able to get it down to about 30 cycles at best.
This is the ASM code produced, with my thinking of what each line does next to it:
ISR(TIMER1_COMPA_vect)
{
push r1
push r0
in r0, 0x3f ; save status reg
push r0
eor r1, r1 ; generates a 0 in r1, used much later
push r24
push r25
push r30
push r31 ; all regs saved
PORTD = amplitudes[amplitudePlace];
lds r24, 0x00C8 ; r24 <- amplitudePlace I’m pretty sure
lds r30, 0x00B4 ; these two lines load in the address of the
lds r31, 0x00B5 ; array which would explain why it’d a 16 bit number
; if the atmega8 uses 16 bit addresses
add r30, r24 ; aha, this must be getting the ADDRESS OF THE element
adc r31, r1 ; at amplitudePlace in the array.
ld r24, Z ; Z low is r30, makes sense. I think this is loading
; the memory located at the address in r30/r31 and
; putting it into r24
out 0x12, r24 ; fairly sure this is putting the amplitude into PORTD
amplitudePlace++;
lds r24, 0x011C ; r24 <- amplitudePlace
subi r24, 0xFF ; subi is subtract imediate.. 0xFF = 255 so I’m
; thinking with an 8 bit value x, x+1 = x - 255;
; I might just trust that the compiler knows what it’s
; doing here rather than try to change it to an ADDI
sts 0x011C, r24 ; puts the new value back to the address of the
; variable
if(amplitudePlace == numOfAmps)
lds r25, 0x00C8 ; r24 <- amplitudePlace
lds r24, 0x00B3 ; r25 <- numOfAmps
cp r24, r24 ; compares them
brne .+4 ; 0xdc <__vector_6+0x54>
{
amplitudePlace = 0;
sts 0x011C, r1 ; oh, this is why r1 was set to 0 earlier
}
}
pop r31 ; restores the registers
pop r30
pop r25
pop r24
pop r19
pop r18
pop r0
out 0x3f, r0 ; 63
pop r0
pop r1
reti
Apart from maybe using less registers in the interrupt so that I have less push/pops I really can't see where this assembly code is inefficient.
My only other thought is maybe the if statement could be gotten rid of if I could work out how to get a n bit int datatype in C so that the number will wrap around when it reaches the end? By this I mean I would have 2^n - 1 samples and then have the amplitudePlace variable just keep counting up so that when it reaches 2^n it'll overflow and will be reset to zero.
I did try simulating the code without the if bit completely and while it did improve the speed, it only took about 10 cycles off so that it was at about 55 cycles for one execution which still isn't quite fast enough unfortunately so I do need to optimise the code even further which is hard considering without that it's only 2 lines!!
My only other real thought is to see if I can store the static look up tables somewhere that takes less clock cycles to access? The LDS instructions it uses to access the array I think all take 2 cycles so I probably wouldn't really be saving much time there but at this stage I'm willing to try anything.
I'm totally at a loss of where to go from here. I can't see how I could make my C code any more efficient but I'm only fairly new to this sort of thing so I could be missing something. I would love any sort of help.. I realise this is a pretty particular and involved problem and normally I'd try to avoid asking those sort of questions here but I've been working on this for ages and am at a total loss so I'll really take any help that I can get.
r19
andr18
being popped at the end of the ISR when they weren't pushed (or otherwise used)? And why isamplitudePlace
sometimes apparently at address 0x00c8 and sometimes at 0x011c?