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I've been trying my hand at optimising some code I have using microsoft's sse intrinsics. One of the biggest problems when optimising my code is the LHS that happens whenever I want to use a constant. There seems to be some info on generating certain constants (here and here - section 13.4), but its all assembly (which I would rather avoid).

The problem is when I try to implement the same thing with intrinsics, msvc complains about incompatible types etc. Does anyone know of any equivalent tricks using intrinsics?

Example - Generate {1.0,1.0,1.0,1.0}

//pcmpeqw xmm0,xmm0 
__m128 t = _mm_cmpeq_epi16( t, t );

//pslld xmm0,25 
_mm_slli_epi32(t, 25);

//psrld xmm0,2
return _mm_srli_epi32(t, 2);

This generates a bunch of errors about incompatible type (__m128 vs _m128i). I'm pretty new to this, so I'm pretty sure I'm missing something obvious. Can anyone help?

tldr - How do I generate an __m128 vec filled with single precision constant floats with ms intrinsics?

Thanks for reading :)

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What makes you think you need to do this ? Typically constants are loaded only once, prior to a computational loop, so the relative cost of a memory access is negligible. –  Paul R Jul 3 '11 at 21:33
    
I have several constants, all of which are used within a loop which unfortunately already seems to use all 8 xmm registers. Within vtune I get a very high CPI at the point at which some of these constants are used. I figured maybe if I could reduce the number of constants I'm accessing, and generate some instead, that might reduce the cost as one would hide the cost of the other. Also, weirdly, using the using the register keyword on one of the constants helped quite a bit (Even though that just resulted in some other value being pushed out of the xmm regs instead). –  JBeFat Jul 4 '11 at 16:29
2  
Use x86-64 if you can - that way you get 16 XMM registers. Also note that even if you get one or more cache misses the first time these constants are loaded this should get amortised over a large number of iterations where the constants will subsequently be in L1 cache. (Unless of course you only have a small number of loop iterations ?) –  Paul R Jul 4 '11 at 18:00

2 Answers 2

up vote 2 down vote accepted

Simply cast __m128i to __m128 using _mm_castsi128_ps. Also, the second line should be

t = _mm_slli_epi32(t, 25)
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Thanks! I had a feeling it would be something simple like that. –  JBeFat Jul 4 '11 at 16:22

Try __mm_set_ps or __mm_set_ps1.

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0x1a11 251 movaps xmm6, xmmword ptr [0x414890] 0x1a18 251 xorps xmm5, xmm5 Hi, thanks for taking the time to answer :) As you can see from the (Badly formatted, sorry) listing above __mm_set_ps doesn't really help me as it still uses movaps to load the constants from somewhere in memory. What I'd like is to use existing methods for generating constants directly within the xmm registers. –  JBeFat Jul 3 '11 at 21:18
    
@JBeFat: Have you tried simply casting the result? Those tricks are using integer instructions to create floating-point values, so I'm not surprised that the compiler complains about a type mismatch. –  Ben Voigt Jul 3 '11 at 21:36
1  
Also note that there's no LHS store with __mm_set_ps, since the FPU isn't involved. –  Ben Voigt Jul 3 '11 at 21:38
    
MOVAPS is actually as fast or faster nowadays on most CPUs, when reading from a warm cache. Also, int/float conversions can come with some hard to predict extra latencies on some (mostly AMD) processors, too. And lastly, the code is just abysmal. _mm_set_ps is descriptive and unambiguous. Some weird sequence of bit hacks will make you wonder what the hell you intended to do there, if you read your code 5 years from now. –  Damon Jul 4 '11 at 9:57
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@Ben Voigt: Yes, and that is the problem. Quoting The microarchitecture of Intel, AMD and VIA CPUs: "The XMM registers have some tag bits that are used for remembering whether floating point values are normal, denormal or zero. These tag bits have to be set when the output of an integer instruction is used as input for a single or double precision floating point instruction. This causes a so-called reformatting delay." –  Damon Jul 4 '11 at 14:10

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