40

I have learned that some Intel/AMD CPUs can do simultanous multiply and add with SSE/AVX:
FLOPS per cycle for sandy-bridge and haswell SSE2/AVX/AVX2.

I like to know how to do this best in code and I also want to know how it's done internally in the CPU. I mean with the super-scalar architecture. Let's say I want to do a long sum such as the following in SSE:

//sum = a1*b1 + a2*b2 + a3*b3 +... where a is a scalar and b is a SIMD vector (e.g. from matrix multiplication)
sum = _mm_set1_ps(0.0f);
a1  = _mm_set1_ps(a[0]); 
b1  = _mm_load_ps(&b[0]);
sum = _mm_add_ps(sum, _mm_mul_ps(a1, b1));

a2  = _mm_set1_ps(a[1]); 
b2  = _mm_load_ps(&b[4]);
sum = _mm_add_ps(sum, _mm_mul_ps(a2, b2));

a3  = _mm_set1_ps(a[2]); 
b3  = _mm_load_ps(&b[8]);
sum = _mm_add_ps(sum, _mm_mul_ps(a3, b3));
...

My question is how does this get converted to simultaneous multiply and add? Can the data be dependent? I mean can the CPU do _mm_add_ps(sum, _mm_mul_ps(a1, b1)) simultaneously or do the registers used in the multiplication and add have to be independent?

Lastly how does this apply to FMA (with Haswell)? Is _mm_add_ps(sum, _mm_mul_ps(a1, b1)) automatically converted to a single FMA instruction or micro-operation?

41

The compiler is allowed to fuse a separated add and multiply, even though this changes the final result (by making it more accurate).

An FMA has only one rounding (it effectively keeps infinite precision for the internal temporary multiply result), while an ADD + MUL has two.

The IEEE and C standards allow this when #pragma STDC FP_CONTRACT ON is in effect, and compilers are allowed to have it ON by default (but not all do). Gcc contracts into FMA by default (with the default -std=gnu*, but not -std=c*, e.g. -std=c++14). For Clang, it's only enabled with -ffp-contract=fast. (With just the #pragma enabled, only within a single expression like a+b*c, not across separate C++ statements.).

This is different from strict vs. relaxed floating point (or in gcc terms, -ffast-math vs. -fno-fast-math) that would allow other kinds of optimizations that could increase the rounding error depending on the input values. This one is special because of the infinite precision of the FMA internal temporary; if there was any rounding at all in the internal temporary, this wouldn't be allowed in strict FP.

Even if you enable relaxed floating-point, the compiler might still choose not to fuse since it might expect you to know what you're doing if you're already using intrinsics.


So the best way to make sure you actually get the FMA instructions you want is you actually use the provided intrinsics for them:

FMA3 Intrinsics: (AVX2 - Intel Haswell)

  • _mm_fmadd_pd(), _mm256_fmadd_pd()
  • _mm_fmadd_ps(), _mm256_fmadd_ps()
  • and about a gazillion other variations...

FMA4 Intrinsics: (XOP - AMD Bulldozer)

  • _mm_macc_pd(), _mm256_macc_pd()
  • _mm_macc_ps(), _mm256_macc_ps()
  • and about a gazillion other variations...
  • Thanks, that more or less answers my question about FMA. I should really spend some time learning some x86 assembly. That would probably answer most of my questions. – user2088790 Apr 10 '13 at 18:39
  • As for your question about whether a multiply and an add can be done simultaneously (FMA). The answer is no since the add uses the result of the multiply. So you eat the latency of add + multiply. An FMA instruction does both instructions together - usually with the same latency as a single muliply. So the add is free. – Mysticial Apr 10 '13 at 18:45
  • 1
    Thanks, that's what I thought. Now I just need to figure out how to organize my code so that the sum like I defined above does independent adds and multiplies simultaneously (so I avoid latencies). – user2088790 Apr 10 '13 at 19:10
  • 1
    You only need to separate them as much as it takes to reach the max throughput. The critical path is on the additions. The latency of an addps is 3 cycles. But the throughput is 1. So you need a minimum of 3 separate sum chains to fully utilize it. You currently have 4, so that's sufficient. – Mysticial Apr 10 '13 at 19:41
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    I think your answer is misleading since a compiler can uses FMA by default without breaking IEEE rules stackoverflow.com/a/34817983/2542702 – Z boson Jan 19 '16 at 12:55
14

I tested the following code in GCC 5.3, Clang 3.7, ICC 13.0.1 and MSVC 2015 (compiler version 19.00).

float mul_add(float a, float b, float c) {
    return a*b + c;
}

__m256 mul_addv(__m256 a, __m256 b, __m256 c) {
    return _mm256_add_ps(_mm256_mul_ps(a, b), c);
}

With the right compiler options (see below) every compiler will generate a vfmadd instruction (e.g. vfmadd213ss) from mul_add. However, only MSVC fails to contract mul_addv to a single vfmadd instruction (e.g. vfmadd213ps).

The following compiler options are sufficient to generate vfmadd instructions (except with mul_addv with MSVC).

GCC:   -O2 -mavx2 -mfma
Clang: -O1 -mavx2 -mfma -ffp-contract=fast
ICC:   -O1 -march=core-avx2
MSVC:  /O1 /arch:AVX2 /fp:fast

GCC 4.9 will not contract mul_addv to a single fma instruction but since at least GCC 5.1 it does. I don't know when the other compilers started doing this.

  • See also #pragma STDC FP_CONTRACT ON. Stephen Canon points out that it allows contraction only within a single statement, not across statements. (lists.llvm.org/pipermail/cfe-dev/2015-September/045110.html). Also note that gcc enables contraction only with -std=gnu*, not with -std=c11 or whatever. (And then it enables contraction across statements, beyond what IEEE + ISO C strictly allow). Another test function that uses separate variables might be worth trying. – Peter Cordes Sep 8 '17 at 19:37
  • @PeterCordes, see this stackoverflow.com/q/34436233/2542702 and Stephen Canon's answer. I think what GCC is doing is okay according toe Stephen's answer (assuming that GCC did not ignore STDC FP_CONTRACT which is unfortunately does last time I checked). – Z boson Sep 11 '17 at 11:17
  • Your question there only asks about return a*b + c;, not about float mul = a*b; return mul + c;. Read Stephen's mailing-list post carefully: he mentions that clang's STDC FP_CONTRACT ON only enables contraction within an expression, unlike clangs -ffp-contract=fast which would enable it for my second example in this comment, too. That's why clang has separate on vs. fast settings for the command-line option. See my recent edits to Mysticial's answer on this question. It's messier than I thought at first :( – Peter Cordes Sep 11 '17 at 17:19
  • @PeterCordes, one of my points is that GCC ignores #pragma STDC FP_CONTRACT. At least last time I checked. I should check this again (for e.g. gnuc99 and c99 or whatever). – Z boson Sep 13 '17 at 10:51
  • I think that's still true. And its actual behaviour goes beyond what #pragma STDC FP_CONTRACT ON allows, so it's not quite like defaulting that to ON and failing to provide a way to turn it off. I think from what I've read that IEEE + C doesn't specify a #pragma STDC FP_CONTRACT FAST, even though that is a useful setting. – Peter Cordes Sep 13 '17 at 15:28

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