# Fast Arc Cos algorithm?

I have my own, very fast cos function:

``````float sine(float x)
{
const float B = 4/pi;
const float C = -4/(pi*pi);

float y = B * x + C * x * abs(x);

//  const float Q = 0.775;
const float P = 0.225;

y = P * (y * abs(y) - y) + y;   // Q * y + P * y * abs(y)

return y;
}

float cosine(float x)
{
return sine(x + (pi / 2));
}
``````

But now when I profile, I see that acos() is killing the processor. I don't need instense precision. What is a fast way to calculate acos(x) Thanks.

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Your very fast function has a mean error of 16% in [-pi,pi] and is entirely unusable outside that interval. The standard `sinf` from `math.h` on my system takes only about 2.5x as much time as your approximation. Considering your function is inlined and the lib call is not, this is really not much difference. My guess is if you added range reduction so it was usuable in the same way as the standard function, you would have exactly the same speed. –  Damon Jul 5 '12 at 14:50
No, the maximum error is 0.001 (1/10th %). Did you forget to apply the correction? (y = P * bla...) Look at the original source and discussion here: devmaster.net/forums/topic/4648-fast-and-accurate-sinecosine Second, sin and cos pre-bounded by +-pi is a VERY common case, especially in graphics and simulation, both of which often require a fast approximate sin/cos. –  jcwenger Oct 18 '12 at 20:15

A simple cubic approximation, the Lagrange polynomial for x ∈ {-1, -½, 0, ½, 1}, is:

``````double acos(x) {
return (-0.69813170079773212 * x * x - 0.87266462599716477) * x + 1.5707963267948966;
}
``````

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Maximum error is 10.31 in degrees. Rather big, but in some solutions may be enough. Suitable where computational speed is more important than precision. May be quartic approximation would produce more precision and still be faster than native acos? –  Timo Feb 2 at 17:22
Sure there isn't a mistake in this formular? Just tried it with Wolfram Alpha and it doesn't look right: wolframalpha.com/input/?i=y%3D%282%2F9*pi*x*x-5*pi%2F18%29*x%2Bpi%2F2 –  miho Apr 26 at 14:29

Got spare memory? A lookup table (with interpolation, if required) is gonna be fastest.

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How could I implement this as a C function? –  Milo Aug 1 '10 at 3:42
@Jex: bounds-check your argument (it must be between -1 and 1). Then multiply by a nice power of 2, say 64, yielding the range (-64, 64). Add 64 to make it non-negative (0, 128). Use the integer part to index a lookup table, if desired use the fractional part for interpolation between the two closest entries. If you don't want interpolation, try adding 64.5 and take the floor, this is the same as round-to-nearest. –  Ben Voigt Aug 1 '10 at 5:42
Lookup tables require an index, which is going to require a float to int conversion, which will probably kill performance. –  phkahler Aug 2 '10 at 13:15

I see approximate routines for sine and cosine that could, as @dan04 says, be done better.

I don't see acos.

Besides, what do you mean "killing the processor"? No matter how fast you make it, it is going to take 100% of processor time if you do nothing else.

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Another approach you could take is to use complex numbers. From de Moivre's formula,

x = cos(π/2*x) + ⅈ*sin(π/2*x)

Let θ = π/2*x. Then x = 2θ/π, so

• sin(θ) = ℑ(ⅈ^2θ/π)
• cos(θ) = ℜ(ⅈ^2θ/π)

How can you calculate powers of ⅈ without sin and cos? Start with a precomputed table for powers of 2:

• 4 = 1
• 2 = -1
• 1 = ⅈ
• 1/2 = 0.7071067811865476 + 0.7071067811865475*ⅈ
• 1/4 = 0.9238795325112867 + 0.3826834323650898*ⅈ
• 1/8 = 0.9807852804032304 + 0.19509032201612825*ⅈ
• 1/16 = 0.9951847266721969 + 0.0980171403295606*ⅈ
• 1/32 = 0.9987954562051724 + 0.049067674327418015*ⅈ
• 1/64 = 0.9996988186962042 + 0.024541228522912288*ⅈ
• 1/128 = 0.9999247018391445 + 0.012271538285719925*ⅈ
• 1/256 = 0.9999811752826011 + 0.006135884649154475*ⅈ

To calculate arbitrary values of ⅈx, approximate the exponent as a binary fraction, and then multiply together the corresponding values from the table.

For example, to find sin and cos of 72° = 0.8π/2:

0.8 ≈ ⅈ205/256 = ⅈ0b11001101 = ⅈ1/2 * ⅈ1/4 * ⅈ1/32 * ⅈ1/64 * ⅈ1/256
= 0.3078496400415349 + 0.9514350209690084*ⅈ

• sin(72°) ≈ 0.9514350209690084 ("exact" value is 0.9510565162951535)
• cos(72°) ≈ 0.3078496400415349 ("exact" value is 0.30901699437494745).

To find asin and acos, you can use this table with the Bisection Method:

For example, to find asin(0.6) (the smallest angle in a 3-4-5 triangle):

• 0 = 1 + 0*ⅈ. The sin is too small, so increase x by 1/2.
• 1/2 = 0.7071067811865476 + 0.7071067811865475*ⅈ . The sin is too big, so decrease x by 1/4.
• 1/4 = 0.9238795325112867 + 0.3826834323650898*ⅈ. The sin is too small, so increase x by 1/8.
• 3/8 = 0.8314696123025452 + 0.5555702330196022*ⅈ. The sin is still too small, so increase x by 1/16.
• 7/16 = 0.773010453362737 + 0.6343932841636455*ⅈ. The sin is too big, so decrease x by 1/32.
• 13/32 = 0.8032075314806449 + 0.5956993044924334*ⅈ.

Each time you increase x, multiply by the corresponding power of ⅈ. Each time you decrease x, divide by the corresponding power of ⅈ.

If we stop here, we obtain acos(0.6) ≈ 13/32*π/2 = 0.6381360077604268 (The "exact" value is 0.6435011087932844.)

The accuracy, of course, depends on the number of iterations. For a quick-and-dirty approximation, use 10 iterations. For "intense precision", use 50-60 iterations.

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