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x86 does not have an SSE instruction to convert from unsigned int32 to floating point. What would be the most efficient instruction sequence for achieving this?

EDIT: To clarify, i want to do the vector sequence of the following scalar operation:

unsigned int x = ...
float res = (float)x;

EDIT2: Here is a naive algorithm for doing a scalar conversion.

unsigned int x = ...
float bias = 0.f;
if (x > 0x7fffffff) {
    bias = (float)0x80000000;
    x -= 0x80000000;
}
res = signed_convert(x) + bias;
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Do you mean truncating/rounding/...? Could you give a minimal example of the desired input/output? –  Joachim Isaksson Feb 5 '12 at 18:20
    
Added EDIT to clarify –  zr. Feb 5 '12 at 18:48
    
I'm confused, do you want to convert int to float or float to int or both? Could you correct the question title and/or body to make it less ambiguous? –  Alexey Frunze Feb 5 '12 at 19:08
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3 Answers

up vote 3 down vote accepted

Your naive scalar algorithm doesn't deliver a correctly-rounded conversion -- it will suffer from double rounding on certain inputs. As an example: if x is 0x88000081, then the correctly-rounded result of conversion to float is 2281701632.0f, but your scalar algorithm will return 2281701376.0f instead.

Off the top of my head, you can do a correct conversion as follows (as I said, this is off the top of my head, so it's likely possible to save an instruction somewhere):

movdqa   xmm1,  xmm0    // make a copy of x
psrld    xmm0,  16      // high 16 bits of x
pand     xmm1, [mask]   // low 16 bits of x
orps     xmm0, [onep39] // float(2^39 + high 16 bits of x)
cvtdq2ps xmm1, xmm1     // float(low 16 bits of x)
subps    xmm0, [onep39] // float(high 16 bits of x)
addps    xmm0,  xmm1    // float(x)

where the constants have the following values:

mask:   0000ffff 0000ffff 0000ffff 0000ffff
onep39: 53000000 53000000 53000000 53000000

What this does is separately convert the high- and low-halves of each lane to floating-point, then add these converted values together. Because each half is only 16 bits wide, the conversion to float does not incur any rounding. Rounding only occurs when the two halves are added; because addition is a correctly-rounded operation, the entire conversion is correctly rounded.

By contrast, your naive implementation first converts the low 31 bits to float, which incurs a rounding, then conditionally adds 2^31 to that result, which may cause a second rounding. Any time you have two separate rounding points in a conversion, unless you are exceedingly careful about how they occur, you should not expect the result to be correctly rounded.

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Could you please explain your answer? –  zr. Feb 5 '12 at 20:39
    
@zr.: what confuses you about it? –  Stephen Canon Feb 5 '12 at 20:39
    
At first glance, I don't understand the math. Why does your recipe give the correct answer? Not that I am saying it is incorrect... –  zr. Feb 5 '12 at 20:41
    
@zr. Each individual step is pretty straightforward, so if you sit down and follow it through it should be fairly self-explanatory. That said, if there's a specific step that you're having trouble with, I'd be happy to clarify why it does what the comments say it does. –  Stephen Canon Feb 5 '12 at 21:02
    
Would you please explain how the upper 16-bits are handled? I don't understand the OR followed by the SUB –  zr. Feb 5 '12 at 21:13
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This is based on an example from the old but useful Apple AltiVec-SSE migration documentation which unfortunately is now no longer available at http://developer.apple.com:

inline __m128 _mm_ctf_epu32(const __m128i v)
{
    const __m128 two16 = _mm_set1_ps(0x1.0p16f);

    // Avoid double rounding by doing two exact conversions
    // of high and low 16-bit segments
    const __m128i hi = _mm_srli_epi32((__m128i)v, 16);
    const __m128i lo = _mm_srli_epi32(_mm_slli_epi32((__m128i)v, 16), 16);
    const __m128 fHi = _mm_mul_ps(_mm_cvtepi32_ps(hi), two16);
    const __m128 fLo = _mm_cvtepi32_ps(lo);

    // do single rounding according to current rounding mode
    return _mm_add_ps(fHi, fLo);
}
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This, too, is a great answer. I wonder how it compares to Stephen Canon's solution in terms of accuracy and performance. –  zr. Feb 6 '12 at 11:21
    
The other solution looks good, but the code above has the advantage of having been tested, and furthermore it uses intrinsics, which makes it a little more portable. Probably not much difference when it comes to performance though. –  Paul R Feb 6 '12 at 11:31
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If I understood you correctly, you want to cast the 32-bit floats to unsigned integers, simply throwing away the sign of the floats. In that case, this should work (NASM syntax) :

section .data
mask : dd 0x7fffffff, 0x7fffffff, 0x7fffffff, 0x7fffffff

section .text
to_unsigned:
; assume the floats are in xmm0 at this point
pand xmm0, [mask] ; mask out the sign bits
cvtps2dq xmm1, xmm0 ; xmm1 has the unsigned integers at this point
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Thanks but your solution will not give a correct result for the following input vector [0x80000000, 0x80000000, 0x80000000, 0x80000000] –  zr. Feb 5 '12 at 18:46
    
These are simply negative zeros. They get converted to normal zeros by the cvtps2dq instruction. I don't see how that's incorrect, seeing how there's no way to represent a negative zero in two's complement. –  Daniel Kamil Kozar Feb 5 '12 at 18:52
    
I misunderstood you, since I thought you wanted to convert floats to unsigned integers, while what you want is to have the conversion the other way around. Unfortunately, in that case there's no easy way to do this with SSE. The only conversion instructions supported by SSE assume that the integers are signed, i.e. the most significant bit is the sign bit. I'd say there's nothing you can do about it. –  Daniel Kamil Kozar Feb 5 '12 at 19:02
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