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In an app I'm profiling, I found that in some scenarios this function is able to take over 10% of total execution time.

I've seen discussion over the years of faster sqrt implementations using sneaky floating-point trickery, but I don't know if such things are outdated on modern CPUs.

MSVC++ 2008 compiler is being used, for reference... though I'd assume sqrt is not going to add much overhead though.

See also here for similar discussion on modf function.

EDIT: for reference, this is one widely-used method, but is it actually much quicker? How many cycles is SQRT anyway these days?

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How are you using it? Built-in functions are likely to be pretty well optimal for the general case, but if you're using it in a more specialized way there's more scope for improvement. – David Thornley Apr 14 '10 at 13:36
2  
Can you post some code? The best way of optimizing sqrt is to get rid of it, or at least reduce the number of calls to it, which may be be possible. – IVlad Apr 14 '10 at 13:36
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Code is long and complex, soft-body physical modelling from a 3rd party. Not a couple of inner loops doing sqrt where length^2 could be used instead of length :) – Mr. Boy Apr 14 '10 at 13:41
1  
Single or double precision ? What accuracy do you need ? – Paul R Apr 14 '10 at 13:46
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Don't use the "fast inverse square root". If you're willing to settle for an approximation, the hardware rsqrtss (approximate reciprocal square root) is much faster. – Stephen Canon Apr 14 '10 at 18:22
up vote 20 down vote accepted

Yes, it is possible even without trickery:

1) sacrifice accuracy for speed: the sqrt algorithm is iterative, re-implement with fewer iterations.

2) lookup tables: either just for the start point of the iteration, or combined with interpolation to get you all the way there.

3) caching: are you always sqrting the same limited set of values? if so, caching can work well. I've found this useful in graphics applications where the same thing is being calculated for lots of shapes the same size, so results can be usefully cached.

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1  
I always find it hard to believe that manually doing even a small number of iterations could be faster than a built-in SQRT instruction... but then I guess SQRT isn't magic, it still does iterations inside. – Mr. Boy Apr 14 '10 at 13:46
    
Do you have any kind of metrics... how much improvement you have seen? – Mr. Boy Apr 14 '10 at 13:47
4  
Milage varies with usage :) You really have to profile your own usage scenario to see what works. Regarding the fsqrt instruction, you might be able to still use it, but speed things up a tiny bit by not checking for error conditions: depends on exactly what assembler your compiler is generating though. – James Apr 14 '10 at 14:08
    
Use quake sqrt algorithm. It's magic is not in the iteration but the choice of an initial value. However gcc at O3 level implements it so my recommendation is to use that. – rytis Jan 18 at 6:36
    
@rytis The famous quake algorithm is for the inverse square root (1/sqrt(x)), not for sqrt(x) – James Jan 18 at 14:23

You're very likely to gain more speed improvements by changing your algorithms than by changing their implementations: Try to call sqrt() less instead of making calls faster. (And if you think this isn't possible - the improvements for sqrt() you mention are just that: improvements of the algorithm used to calculate a square root.)

Since it is used very often, it is likely that your standard library's implementation of sqrt() is nearly optimal for the general case. Unless you have a restricted domain (e.g., if you need less precision) where the algorithm can take some shortcuts, it's very unlikely someone comes up with an implementation that's faster.

Note that, since that function uses 10% of your execution time, even if you manage to come up with an implementation that only takes 75% of the time of std::sqrt(), this still will only bring your execution time down by 2,5%. For most applications users wouldn't even notice this, except if they use a watch to measure.

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An example of this might be: if you want to find the nearest thing to you, you can compare the distances squared instead of taking the sqrt of each, since distance*distance > distance. Or you might be able to run a pre-process step which calculates the distance pairs of everything in advance. (Obviously I'm imagining some sort of 2-D or 3-D data structure). – stusmith Apr 14 '10 at 13:40
    
we're a bit beyond such trivialities in this case, I think actual values are genuinely needed rather than only being used in comparisons. – Mr. Boy Apr 14 '10 at 13:45
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+1 For the realization that a big improvement to a piece of code used less frequently ends up with almost a negligible improvement in the Big Picture. – Thomas Matthews Apr 14 '10 at 17:20
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Why do people seem to assume that the original poster is retarded? Just answer their question instead of telling them that they shouldn't try to do what they are doing. Maybe they have a good reason for doing what they are doing. 10% of code time is a big chunk of time for one function and deserves optimization if it is simple to do. I can't believe that this unhelpful response got upvoted so much. – Joe Jun 11 '12 at 22:13
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Actually I found this reply to be very well thought out, explained the possibilities well and weighed the pros and cons of improving an implementation vs choosing a different approach that may work better. +1 for a genuinely helpful and well put together answer. – leeor_net Jun 2 '13 at 11:49

There's a great comparison table here: http://assemblyrequired.crashworks.org/timing-square-root/

Long story short, SSE2's ssqrts is about 2x faster than FPU fsqrt, and an approximation + iteration is about 4x faster than that (8x overall).

Also, if you're trying to take a single-precision sqrt, make sure that's actually what you're getting. I've heard of at least one compiler that would convert the float argument to a double, call double-precision sqrt, then convert back to float.

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Fixed the link. – celion Nov 11 '15 at 13:51

How accurate do you need your sqrt to be? You can get reasonable approximations very quickly: see Quake3's excellent inverse square root function for inspiration (note that the code is GPL'ed, so you may not want to integrate it directly).

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How fast is it though? If 1/sqrt is no good and you need sqrt, is the additional division still faster than the normal version? – Mr. Boy Apr 14 '10 at 13:54
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Try it and see. – jemfinch Apr 14 '10 at 15:03
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I figured someone might already have done that before they recommend it... – Mr. Boy Apr 14 '10 at 15:36
    
@John: They have. That's why they created that function, after all. But that doesn't mean it would help (much) in your case. – sbi Apr 14 '10 at 15:45
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The so-called "fast inverse square root" is not "fast" on modern hardware. On nearly any processor designed in the last 10 years, there is a faster alternative. On many, the hardware square root instruction will be faster. Many have an even faster hardware inverse square root estimate (rsqrtss on SSE, rsqrte on ARMv7, etc). – Stephen Canon Apr 14 '10 at 18:20

Don't know if you fixed this, but I've read about it before, and it seems that the fastest thing to do is replace the sqrt function with an inline assembly version;

you can see a description of a load of alternatives here.

The best is this snippet of magic:

double inline __declspec (naked) __fastcall sqrt(double n)
{
    _asm fld qword ptr [esp+4]
    _asm fsqrt
    _asm ret 8
} 

It's about 4.7x faster than the standard sqrt call with the same precision.

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Could you please suggest also the implementation in GCC? How should this modified for a float type? Thanks! – rytis Apr 30 '14 at 7:01
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Then why isn't the compiler doing this? – Mr. Boy Oct 2 '14 at 10:29
    
I really don't know. – will Oct 2 '14 at 15:48
    
What the hell? That won't autovectorize, and will probably break when inlined (esp+4 might not be n, and there's a ret inside the inline asm). It forces your input to go through a store/reload. That's another ~5 cycles of latency on top of 10-23 cycles for fsqrt on Haswell. sqrtpd (double) is 16c latency, while sqrtps (single) is 11c latency. Your compiler would have to really suck for this to be a win (maybe you compiled without optimization on?) Also, ret 8? That's a 3uop instruction. – Peter Cordes Mar 2 at 1:40
    
I didn't write the artical, so i'm not sure at the moment (not without going back and checking it) how he compiled and ran the tests. It surprises me too. – will Mar 3 at 16:10

Here is a fast way with a look up table of only 8KB. Mistake is ~0.5% of the result. You can easily enlarge the table, thus reducing the mistake. Runs about 5 times faster than the regular sqrt()

// LUT for fast sqrt of floats. Table will be consist of 2 parts, half for sqrt(X) and half for sqrt(2X).
const int nBitsForSQRTprecision = 11;                       // Use only 11 most sagnificant bits from the 23 of float. We can use 15 bits instead. It will produce less error but take more place in a memory. 
const int nUnusedBits   = 23 - nBitsForSQRTprecision;       // Amount of bits we will disregard
const int tableSize     = (1 << (nBitsForSQRTprecision+1)); // 2^nBits*2 because we have 2 halves of the table.
static short sqrtTab[tableSize]; 
static unsigned char is_sqrttab_initialized = FALSE;        // Once initialized will be true

// Table of precalculated sqrt() for future fast calculation. Approximates the exact with an error of about 0.5%
// Note: To access the bits of a float in C quickly we must misuse pointers.
// More info in: http://en.wikipedia.org/wiki/Single_precision
void build_fsqrt_table(void){
    unsigned short i;
    float f;
    UINT32 *fi = (UINT32*)&f;

    if (is_sqrttab_initialized)
        return;

    const int halfTableSize = (tableSize>>1);
    for (i=0; i < halfTableSize; i++){
         *fi = 0;
         *fi = (i << nUnusedBits) | (127 << 23); // Build a float with the bit pattern i as mantissa, and an exponent of 0, stored as 127

         // Take the square root then strip the first 'nBitsForSQRTprecision' bits of the mantissa into the table
         f = sqrtf(f);
         sqrtTab[i] = (short)((*fi & 0x7fffff) >> nUnusedBits);

         // Repeat the process, this time with an exponent of 1, stored as 128
         *fi = 0;
         *fi = (i << nUnusedBits) | (128 << 23);
         f = sqrtf(f);
         sqrtTab[i+halfTableSize] = (short)((*fi & 0x7fffff) >> nUnusedBits);
    }
    is_sqrttab_initialized = TRUE;
}

// Calculation of a square root. Divide the exponent of float by 2 and sqrt() its mantissa using the precalculated table.
float fast_float_sqrt(float n){
    if (n <= 0.f) 
        return 0.f;                           // On 0 or negative return 0.
    UINT32 *num = (UINT32*)&n;
    short e;                                  // Exponent
    e = (*num >> 23) - 127;                   // In 'float' the exponent is stored with 127 added.
    *num &= 0x7fffff;                         // leave only the mantissa 

    // If the exponent is odd so we have to look it up in the second half of the lookup table, so we set the high bit.
    const int halfTableSize = (tableSize>>1);
    const int secondHalphTableIdBit = halfTableSize << nUnusedBits;
    if (e & 0x01) 
        *num |= secondHalphTableIdBit;  
    e >>= 1;                                  // Divide the exponent by two (note that in C the shift operators are sign preserving for signed operands

    // Do the table lookup, based on the quaternary mantissa, then reconstruct the result back into a float
    *num = ((sqrtTab[*num >> nUnusedBits]) << nUnusedBits) | ((e + 127) << 23);
    return n;
}
share|improve this answer
    
I expect cache misses will make this worse than sqrt for use in real code, rather than code that tests the throughput of sqrt in a microbenchmark. x86 has very fast sqrt in hardware, and even faster rsqrt (approximate reciprocal sqrt), which you can refine with a newton-raphson step. – Peter Cordes Mar 2 at 1:42

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