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Are there any asm instructions that can speed up computation of min/max of vector of doubles/integers on Core i7 architecture?


I didn't expect such rich answers, thank you. So I see that max/min is possible to do without branching. I have sub-question:

Is there an efficient way to get the index of the biggest double in array?

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What is the host language? If it is c/c++ I wouldn't worry about it too much. –  Daniel A. White Dec 28 '09 at 14:48
max of around 300 doubles is in the most inner loop of large program. 85% of time is spent in about 10 out of 8'000 lines of code. Host language doesn't matter just because of that. But yes it is C++ –  Łukasz Lew Dec 28 '09 at 14:51

5 Answers 5

up vote 10 down vote accepted

SSE4 has PMAXSD or PMAXUD for 32 bit signed/unsigned integers, which might be useful.

SSE2 has MAXPD and MAXSD which compare between and across pairs of doubles, so you follow n/2-1 MAXPDs with one MAXSD to get the max of a vector of n, with the usual interlacing of loads and operations.

There are MIN equivalents of the above.

For the double case, you're probably not going to do better in assembler than a half-decent C++ compiler in SSE mode:

peregrino:$ g++ -O3 src/min_max.cpp -o bin/min_max
peregrino:$ g++ -O3 -msse4 -mfpmath=sse src/min_max.cpp -o bin/min_max_sse
peregrino:$ time bin/min_max

real    0m0.874s
user    0m0.796s
sys 0m0.004s
peregrino:$ time bin/min_max_sse 

real    0m0.457s
user    0m0.404s
sys 0m0.000s

where min_max computes min and max of an array of 500 doubles 100,000 times using a naive loop:

bool min_max ( double array[], size_t len, double& min, double& max )
    double min_value = array [ 0 ];
    double max_value = array [ 0 ];

    for ( size_t index = 1; index < len; ++index ) {
        if ( array [ index ] < min_value ) min_value = array [ index ];
        if ( array [ index ] > max_value ) max_value = array [ index ];

    min = min_value;
    max = max_value;

In response to part two, the traditional optimisation to remove branching from a max operation is to compare the values, get the flag as a single bit ( giving 0 or 1 ), subtract one ( giving 0 or 0xffff_ffff) and 'and' it with the xor of the two possible results, so you get the equivalent of ( a > best ? ( current_index ^ best_index ) : 0 ) ^ best_index ). I doubt there's a simple SSE way of doing that, simply because SSE tends to operate on packed values rather than tagged values; there are some horizontal index operations, so you could try finding the max, then subtracting that from all elements in the original vector, then gather the sign bit, and the zero signed one would correspond to the index of the max, but that would probably not be an improvement unless you were using shorts or bytes.

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MAXPS and MINPS from SSE both operate on packed single-precision floating point numbers. PMAXSW, PMINSW, PMAXUB and PMINUB all operate on packed 8-bit words, either signed or unsigned. Please note that these compare the two input SSE registers or address locations element-wise and store the result into an SSE register or memory location.

The SSE2 versions of MAXPS and MINPS should work on double-precision floats.

What compiler and optimization flags are you using? gcc 4.0 and better should automatically vectorize operations if your target supports them, earlier versions may need a specific flag.

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if your are using Intel's IPP library you can use the vector statistical functions to calculate vector min/max (among other things)

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In response to your second question: on most platforms, there are libraries that already contained optimized implementations of this very operation (and most other simple vector operations). Use them.

  • On OS X, there is vDSP_maxviD( ) and cblas_idamax( ) in the Accelerate.framework
  • The Intel compilers include the IPP and MKL libraries, which have high performance implementations, including cblas_idamax( )
  • Most Linux systems will have cblas_idamax( ) in the BLAS library, which may or may not be well-tuned depending on its provenance; users who care about performance will generally have a good implementation (or can be persuaded to install one)
  • If all else fails, you can use ATLAS (Automatically Tuned Linear Algebra Software) to get a decent performance implementation on the target platform
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In response to your second question, it may be worthwhile to you to think about the way you collect and store this data.

You may store the data in a B-tree that keeps the data sorted at all times, requiring only logarithmic compare operations.

Then you know at all times where the maximum is.


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Since you are dealing with only 300 doubles, a self-balanced binary tree is probably best. en.wikipedia.org/wiki/Self-balancing_binary_search_tree –  Drew Feb 16 '12 at 3:29
Why not a binary heap? Constant time better than logarithmic... –  vp_arth Apr 13 '14 at 20:34

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