in this particular example any compiler should be able to tranform it into the second form
because 0.5 is a power of two
maybe some compiler in the very strictest IEEE compatibility can't translate an arbitrary constant division to a multiplication because of rounding errors
@Mgetz I actually saw this "FMA everything" thing coming a mile away after I worked with the Power7 in grad school. Since the latencies of FP add and FP mul were so close anyway, you're not losing much by making an FP add as slow as an FP mul. So you can save a shit-ton of area by shoving everything through a generic FMA.
@Mysticial yeah, and you can take intel's standard "Throw silicon at it" fix to make it fast while still using less silicon than if they were independent
@Mgetz That's what they're doing with wider and wider vectors. Simplifying the building blocks (like having only an FMA unit), lets them do more copy-pasting. :)
@Mgetz I certainly liked it (and yes, the Alpha was what I was referring to--off on the corner of the die, several (21064, 21068 and 21164, at least) had a picture of an Energizer Bunny in the mask. One (the 068, if memory serves) also listed the names of all the designers.
@Mysticial Lower design cost at the expense of only a few million extra transistors. Perfectly reasonable trade-off in a 10 nm process.
@JerryCoffin Haswell came pretty close to the FMA-only approach. FP mul and FMA went through the same FMA with 5 cycle latency. But they weren't willing to increase the latency of FP add from 3 to 5 cycles. So they kept the 3-cycle FP adder on one port. On the other hand, there are 2 ports with the FMA. So you could do 2 mul/FMA/cycle, but only one FP add/cycle.
Skylake brought the FMA latency down to 4. That was a good enough compromise. So they went ahead and upped the latency of FP add from 3 to 4 cycles. And now they can go into either port for 2/cycle.
Broadwell is weird though. They have 3 cycle latency FP add. But the FMA is still 5 cycles. Which means the FP mul isn't implemented as a*b + 0.
Make me wonder if they decided to toss in a dedicated FP mul because of all the extra area they gained from going 22 -> 14nm.
@orlp I'm looking at Agner's tables for Skylake. The x87 FP add goes into a different port than the SIMD FP. So it might be possible to exceed Skylake's theoretical peak FLOPS.
I'm attempted to write a benchmark to do that just to prove it can be done. But I'd need to drop down to assembly since I can't get a compiler to generate any x87 FPU instructions.
@JerryCoffin well it depends. I did write the Mandelbrot set algorithm in inline asm, and it wasn't easy to keep all the temp. variables only in 8 registers
There and back again: an incremental C++ modules design.
@zygoloid's best hobbit face! #CppCon
Don't throw them in… https://twitter.com/i/web/status/779081618279374848
@Puppy If you're looking for gaems, I've been playing subnautica. Gorgeous and a bit scary at times. Progress is coming along well on it and the dev team is great at integrating feedback