The thing that pissed me off about ICC is that it refuses to produce binaries that will run on non-Intel processors unless AMD has a processor that can run it.
So I can't build a binary that uses auto-generated AVX2 that will run on a future AMD processor.
@Mysticial I've made a heap manager that I think beats existing heap managers in some scenarios
and by some scenarios
I mean those scenarios that aren't best-case for typical heap managers
i.e., its average performance is slightly worse, but its worst case performance is much much better (probably asymptotically, though I haven't proven it)
anyway, I was hoping to have people give it a try, but I'm not quite ready to open-source it yet
I was wondering if you had any advice on how to go about it
I have no idea. If you can find a widely used (performance critical) application, switch it to your memory allocator and show that it is much faster, then people might be interested.
@Mysticial I don't know enough about modern CPU architectures to comment on it from that aspect, but I think it's reasonable that when the compiler has an intrinsic, it's going to be faster than a non-intrinsic approach :-) (as unreasonable as it might be for that particular intrinsic to exist in the first place)
@Mysticial From a compiler standpoint, I think the compiler is getting confused about something (maybe aliasing? not sure)
@Mysticial Oh well I mean the only reason I gave you this code was that I already had it sitting around
it wasn't geared toward this particular scenario
it's just the easiest thing I could use as an example
in a different scenario I might code it differently haha
@Mysticial Compiler confusion :)
@Mysticial I'm pretty sure a similar thing happens when you embed an SSE type inside a struct -- and my best guess is that as soon as the address of an SSE type becomes taken, it defeats the aliasing analysis in the compiler somehow
All processors since Nehalem will do an access on an aligned address just as fast - regardless of whether the instruction is an aligned or unaligned move.
@Mysticial that doesn't mean the compiler is going to generate the same code for aligned and unaligned moves though. If it's aligned the compiler might generate better code.
@Mysticial Also, side note, but I could swear if I post this code as-is on StackOverflow somewhere, people are going to downvote me for not free'ing the memory correctly, for trying to read uninitialized memory, etc.
@Mysticial I think what you said regarding unaligned being just as fast (or just as slow?) might apply to AMD but it obviously doesn't apply to Intel (at least not to Haswell...)
@Mysticial how would you explain what I just showed you then? it slowed by 50 ms
@Mysticial Yeah that's what I said earlier -- even if the instruction is the same speed, the compiler doesn't necessarily generate the same code for both, so you should still have separate aligned and unaligned code regardless
I'm saying that if you took a binary and replaced all the aligned load/stores with unaligned load/stores, it should make no difference in performance on all Intel processors since Nehalem.
That's why Intel says, confirmed by Agner Fog and others.
@Mysticial right but that's impossible in practice lol. all you can do is change the intrinsics in the code which will not necessarily have the same effect :P
@Mysticial Also, why is the Bulldozer so allergic to branches? Isn't that branch ~100% predictable?