For a hobby project I'm working on, I need to emulate certain 64-bit integer operations on a x86 CPU, and it needs to be fast.
Currently, I'm doing this via MMX instructions, but that's really a pain to work with, because I have to flush the fp register state all the time (and because most MMX instructions deal with signed integers, and I need unsigned behavior).
So I'm wondering if the SSE/optimization gurus here on SO can come up with a better implementation using SSE.
The operations I need are the following (quite specific) ones:
uint64_t X, Y; X = 0; X = 1; X << 1; X != Y; X + 1; X & 0x1 // get lsb X | 0x1 // set lsb X > Y;
Specifically, I don't need general-purpose addition or shifting, for example, just add one and left-shift one. Really, just the exact operations shown here.
Except, of course, on x86,
uint64_t is emulated by using two 32-bit scalars, which is slow (and, in my case, simply doesn't work, because I need loads/stores to be atomic, which they won't be when loading/storing two separate registers).
Hence, I need a SIMD solution.
Some of these operations are trivial, supported by SSE2 already. Others (
<) require a bit more work.
Suggestions? SSE and SSE2 are fine. It'd take some persuasion to permit SSE3, and SSE4 is probably out of the question (A CPU which supports SSE4 is likely to run 64-bit anyway, and so I don't need these workarounds)