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Apr
13
comment Optimising this C (AVR) code
And of course, freq <= 64 must hold in order to keep the & ~64 trick working.
Apr
13
comment Optimising this C (AVR) code
I like the i = (i+1) & ~64; idea, and the idea of skipping samples. Only freq values (for i = (i+freq) & ~64) which are powers of two will avoid the rounding errors which will become noticeable in certain freq/timer combinations.
Apr
13
comment Optimising this C (AVR) code
avr-gcc only pushes the registers that its generated code actually clobbers. So any savings in push/pop instructions by manually writing assembly would have to be in more register efficient code, not in just deleting a bunch of useless push/pop instructions.
Apr
13
comment Optimising this C (AVR) code
Also note that changing the interrupt pointer on the AVR is not trivial, as it requires you to change the program memory in Flash, i.e. you need to deal with flash page erase and stuff. Not trivial either might be to just copy over the data of the new wave form into the single SRAM wave form sample buffer - but you could then keep the new wave form in program memory aka flash which is much more extensive than SRAM!
Apr
13
comment Optimising this C (AVR) code
Choose the address of your table such that (table & 64) == 0, you can get away with a single pointer, increment it, & it with ~64.
Apr
13
comment Erlang Bubble sort
This answer was not intended to be an actual "answer", but to help with the finding of alternative ways. It is much better readable and thus should cause less headaches for people who might want to examine the "efficiency" of the algorithm. Even though I have no idea how "efficient" and "bubblesort" would ever end up in the same sentence except for "bubblesort is not efficient, use a better algorithm".
Apr
13
revised Erlang Bubble sort
fix comparison operator > instead of <
Apr
13
revised Optimising this C (AVR) code
note on startup code and register use
Apr
13
answered Erlang Bubble sort
Apr
13
revised Optimising this C (AVR) code
Quickest known version: 8 cycles.
Apr
13
revised Optimising this C (AVR) code
powers of two need to be considered with timing
Apr
13
revised Optimising this C (AVR) code
powers of two
Apr
13
revised Optimising this C (AVR) code
update cycle estimate
Apr
13
revised Optimising this C (AVR) code
note on reachable cycle number
Apr
13
comment Optimising this C (AVR) code
@Sam: Don't forget that entering and leaving the ISR takes 4 cycles each if you have a 16MHz AVR (5 cycles in case of 20MHz model).
Apr
13
comment Optimising this C (AVR) code
@Sam: The *.lss file objdump can generate contains an assembly language listing of all code in the firmware. You can then grep through that code for rN. I think I have answered the other ones in my last edit to the answer.
Apr
13
revised Optimising this C (AVR) code
elaborate a bit
Apr
13
revised Optimising this C (AVR) code
illustrative code
Apr
13
revised Optimising this C (AVR) code
example code
Apr
13
comment Optimising this C (AVR) code
Just out of curiosity: Would you mind posting the eventual source code and generated assembly as an answer when this question has been answered and your project finished?