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When implementing "Carmack's Inverse Square Root" algorithm I noticed that the results seem biased. The following code seems to give better results:

float InvSqrtF(float x)
    // Initial approximation by Greg Walsh.
    int i  = * ( int* ) &x;
    i  = 0x5f3759df - ( i >> 1 );
    float y  = * ( float * ) &i;
    // Two iterations of Newton-Raphson's method to refine the initial estimate.
    x *= 0.5f;
    float f = 1.5F;
    y  = y * ( f - ( x * y * y ) );
    y  = y * ( f - ( x * y * y ) );
    * ( int * )(&y) += 0x13; // More magic.
    return y;

The key difference is in the penultimate "more magic" line. Since the initial results were too low by a fairly constant factor, this adds 19 * 2^(exponent(y)-bias) to the result with just a single instruction. It seems to give me about 3 extra bits, but am I overlooking something?

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Exactly what is your question? "Is 19 the right number to add?" or something else? –  Mats Petersson Feb 7 '13 at 10:35
Isn't this code doomed to undefined behaviour by the strict aliasing rule? –  comocomocomocomo Feb 7 '13 at 10:58
@comocomocomocomo You can safely type-pun with a union. –  Daniel Fischer Feb 7 '13 at 11:15
@MatsPetersson: No idea, target is ARM. –  MSalters Feb 7 '13 at 11:31
Ah, OK - then I have no further to add to this... And I'm not sure type punning is ever "safe" - you are in the hands of the compiler doing the right thing - someone said in another thread that "you can only have one active member in a union at any time", so type punning through union seems to be off as well - or I've misunderstood that comment. –  Mats Petersson Feb 7 '13 at 11:36

2 Answers 2

up vote 2 down vote accepted

Newton's method produces a bias. The function whose zero is to be found,

f(y) = x - 1/y²

is concave, so - unless you start with an y ≥ √(3/x) - the Newton method only produces approximations ≤ 1/√x (and strictly smaller, unless you start with the exact result) with exact arithmetic.

Floating point arithmetic occasionally produces too large approximations, but typically not in the first two iterations (since the initial guess usually isn't close enough).

So yes, there is a bias, and adding a small quantity generally improves the result. But not always. In the region around 1.25 or 0.85 for example, the results without the adjustment are better than with. In other regions, the adjustment yields one bit of additional precision, in yet others more.

In any case, the magic constant to add should be adjusted to the region from which x is most often taken for the best results.

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As this method is an approximation, the result will be overestimated some times and underestimated some others. You can find on McEniry's paper some nice figures about how this error is distributed for different configurations, and the math behind them.

So, unless you have solid proofs that in your domain of application the result is clearly biased, I would prefer tuning the magic constant as suggested in Lomont's document :-)

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+1. Really like Lomont's analysis for the 0x5f375a86 constant. –  Brett Hale Feb 8 '13 at 4:21
Actually, with 0x5f3759df and 0x5f375a86 I get the exact same bias. –  MSalters Feb 8 '13 at 8:44
OK, I maintain what I said: if in your specific domain of application you know that bias exist, you can compensate it. Daniel Fisher answer is very clear about that ^_^ –  dunadar Feb 8 '13 at 9:35

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