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I need to know the sign of the value which has the max absolute value stored in an __m128. This is the solution I have now:

int getMaxSign(__m128 const& vec) {
    static const __m128 SIGN_BIT_MASK = 

    // This creates an int, where sign(a) is 1 if a is negative, 0 o.w.:
    // sign(a3)<<3 | sign(a2)<<2 | sign(a1)<<1 | sign(a0)
    const int signMask = _mm_movemask_ps(vec);

    // Get the absolute value of the vector;
    __m128 absValsMMX = _mm_andnot_ps(SIGN_BIT_MASK, vec);

    // Figure out the horizontal max
    __declspec(align(16)) float absVals[4];
    _mm_store_ps(absVals, absValsMMX);

    const float maxVal = std::max(std::max(absVals[0], absVals[1]), absVals[2]);

    return (maxVal == absVals[0] ? signMask & 0x1 : 
      (maxVal == absVals[1] ? signMask & 0x2 : signMask & 0x4));

In this case, sign will be 1 if the value with the maximum absolute value was negative, and 0 otherwise, but I don't actually care what the convention is. Another thing is that I am representing homogenous vectors using these __m128s, so I know that the last value will always be 0.

This seems like a lot of work to do for a relatively simple task. How can I do this faster?


share|improve this question
Please clarify whether you want the sign of the max value or the sign of the value which has the max absolute value ? – Paul R Nov 26 '12 at 14:41
You're right, that was really unclear. I edited the question to clarify. For the sake of redundancy, I want the sign of the value which has the max absolute value. – user220878 Nov 26 '12 at 14:50
Thanks for the clarification! – Paul R Nov 26 '12 at 15:02
Is it OK to use SSSE3 ? SSE4 ? – Paul R Nov 26 '12 at 15:11
Any of the SSE instructions are fine, including SSE4 and SSE3. – user220878 Nov 26 '12 at 15:15
up vote 4 down vote accepted

Here is one possible implementation (in C):

int getMaxSign(const __m128 v)
    __m128 v1, vmax, vmin, vsign;
    float sign;

    v1 = (__m128)_mm_alignr_epi8((__m128i)v, (__m128i)v, 4); // v1 = v rotated by 1 element
    vmax = _mm_max_ps(v, v1);           // generate horizontal max/min
    vmin = _mm_min_ps(v, v1);
    vmax = _mm_max_ps(vmax, (__m128)_mm_alignr_epi8((__m128i)vmax, (__m128i)vmax, 8));
    vmin = _mm_min_ps(vmin, (__m128)_mm_alignr_epi8((__m128i)vmin, (__m128i)vmin, 8));
    vsign = _mm_add_ps(vmax, vmin);     // add max and min to get sign of abs max
    sign = _mm_extract_ps(vsign, 0);
    return (int)(sign < 0.0f);          // return 1 for negative

Although this looks like a lot of code it's only about 9 SSE instructions and there are no memory accesses, no branches and very little scalar code.

Note that both SSSE3 and SSE4.1 instructions are used in the above.

Here is a second version which only requires SSSE3:

int getMaxSign(const __m128 v)
    __m128 v1, vmax, vmin, vsign;
    int mask;

    v1 = (__m128)_mm_alignr_epi8((__m128i)v, (__m128i)v, 4); // v1 = v rotated by 1 element
    vmax = _mm_max_ps(v, v1);           // generate horizontal max/min
    vmin = _mm_min_ps(v, v1);
    vmax = _mm_max_ps(vmax, (__m128)_mm_alignr_epi8((__m128i)vmax, (__m128i)vmax, 8));
    vmin = _mm_min_ps(vmin, (__m128)_mm_alignr_epi8((__m128i)vmin, (__m128i)vmin, 8));
    vsign = _mm_add_ps(vmax, vmin);     // add max and min to get sign of abs max
    mask = _mm_movemask_epi8((__m128i)vsign);
    return (mask & 8) != 0;             // return 1 for negative

This generates 12 instructions:

pshufd  $57, %xmm0, %xmm1
movdqa  %xmm0, %xmm2
minps   %xmm1, %xmm2
pshufd  $78, %xmm2, %xmm3
minps   %xmm3, %xmm2
maxps   %xmm1, %xmm0
pshufd  $78, %xmm0, %xmm1
maxps   %xmm1, %xmm0
addps   %xmm2, %xmm0
pmovmskb    %xmm0, %eax
shrl    $3, %eax
andl    $1, %eax

Note how the compiler craftily changes palignr to pshufd and also implements the final scalar test using just a shrl and an andl.

Note for Visual Studio C/C++: to cast between __m128 and __m128i you'll need to use _mm_castps_si128 and _mm_castsi128_ps, e.g.

    mask = _mm_movemask_epi8((__m128i)vsign);

would need to be changed to:

    mask = _mm_movemask_epi8(_mm_castps_si128(vsign));
share|improve this answer
Thanks! Quick question, though: my compiler (VS10) is telling me that it can't cast between __m128 and __m128i. Is this because I'm using a C++ compiler? – user220878 Nov 26 '12 at 16:20
No - it's because you're using Visual Studio unfortunately, which is just about the worst compiler possible for SSE coding. You'll need to do the casts a little differently - I've added a footnote to the answer now to cover this. – Paul R Nov 26 '12 at 16:21
Gorgeous, thanks so much! – user220878 Nov 26 '12 at 16:32

If your numbers are discrete, and properly spaced, and drawing from a limited subset, there are other possibilities.

If you're guaranteed that a, b, and c are integers for instance, then you can multiply the vector by itself to get an odd power and then dot it with <1, 1, 1>. If we multiply it by itself 4 times, for instance, it will give you < a^5, b^5, c^5 >. If |a| is the largest and |a|=2, then we know that b and c will be 1 or 0, so the value of a^3 will dominate and the dot product will have its sign. For instance, if X= < a=-2, b=1, c=0 > , then X^5 = <-32, 1, 0>. When you dot this with <1, 1, 1> you get -31, whose sign reflects that of the largest absolute value. As the absolute value of the largest number increases, the disparity between it and the other terms will tend to converge - for instance, if we have <-8, 7, 7>, then the algorithm above gives X^5=<-32768, 16807, 16807>, you dot that with <1, 1, 1> and get 846, so the algorithm fails with exponent 5. If we bump the exponent up to 7, we get <-2097152, 823543, 823543>, dotted with <1, 1, 1> gives us -450066, which is the correct answer. Eventually round-off errors will also break this method. But I'm hoping it might give some insights into other alternatives, if you know the limits on your dataset.

As a footnote, remember that X^5 = (X*X) * (X*X) * X, so you do one multiply to get X^2, multiply that by itself to get X^4, and then multiply by X - three multiplies total. You need an odd exponent to preserve sign.

share|improve this answer
m = min(a,b,c);  
M = max(a,b,c);  

// return abs(m)>abs(M) ? sign(m): sign(M);   // was
return sign(m+M);

As correctly noticed by Paul_R, the sign comes simply from the sum of the min and max values. Which ever has larger (opposite signed) absolute value, wins.

But the idea can be exploited more: the sum of min/max is the same, as the sum of all the elements, minus the middle one, which can be found by max 3 comparisons.

return sign(a+b+c - middle(a,b,c));  // or
return sign(a*aw + b*bw + c*cw);     // where aw,bw,cw = [0,1]

aw,bw,cw could be derived from the number of won comparisons (which I think have to planned carefully for the case, when there are 2 or 3 equal values.)

And further:

x = abs(b)>abs(a)?b:a;
return sign(x+c);

Possibly even further:

s = sign(a + b);  // store the sign of larger of a or b  
a = abs(a); b=abs(b);  
a = max(a,b) | s;   // somehow copy the sign.  
return sign(a+c);  
share|improve this answer
So you suggest that there is no advantage to having the vector come in as an SSE intrinsic, and that the best option is to store all the values in a float[4], and do the computation in a serial C++ manner? – user220878 Nov 26 '12 at 15:10
Not necessarily. I'm working on that. What I'm suggesting is that taking the absolute values and storing the sign bits is premature. (+ I'm implicitly suggesting that it's an improvement over the last comparison) – Aki Suihkonen Nov 26 '12 at 15:13
Ok, that makes sense. Thanks! – user220878 Nov 26 '12 at 15:14

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