This is probably language agnostic, but I'm asking from a C++ background.
I am hacking together a ring buffer for an embedded system (AVR, 8-bit). Let's assume:
const uint8_t size = /* something > 0 */; uint8_t buffer[size]; uint8_t write_pointer;
There's this neat trick of
&ing the write and read pointers with
size-1 to do an efficient, branchless rollover if the buffer's
size is a power of two, like so:
// value = buffer[write_pointer]; write_pointer = (write_pointer+1) & (size-1);
If, however, the size is not a power of two, the fallback would probably be a compare of the pointer (i.e. index) to the size and do a conditional reset:
// value = buffer[write_pointer]; if (++write_pointer == size) write_pointer ^= write_pointer;
Since the reset occurs rather rarely, this should be easy for any branch prediction.
This assumes though that the pointers need to be advancing foreward in memory. While this is intuitive, it requires a load of
size in every iteration. I assume that reversing the order (advancing backwards) would yield better CPU instructions (i.e.
jump if not zero) in the regular case, since
size is only required during the reset.
// value = buffer[--write_pointer]; if (write_pointer == 0) write_pointer = size;
TL;DR: My question is: Does marching backwards through memory have a negative effect on the execution time due to cache misses (since memory cannot simply be read forward) or is this a valid optimization?