# Determining Floating Point Square Root

How do I determine the square root of a floating point number? Is the Newton-Raphson method a good way? I have no hardware square root either. I also have no hardware divide (but I have implemented floating point divide).

If possible, I would prefer to reduce the number of divides as much as possible since they are so expensive.

Also, what should be the initial guess to reduce the total number of iterations???

Thank you so much!

• Yes, Newton-Raphson method is fast for finding square roots. – ypercubeᵀᴹ Feb 10 '12 at 22:07
• More suitable to math.stackexchange – Andrey Rubshtein Feb 10 '12 at 22:22
• I was just asking; there's no need to get rude. – Fred Foo Feb 10 '12 at 22:46

When you use Newton-Raphson to compute a square-root, you actually want to use the iteration to find the reciprocal square root (after which you can simply multiply by the input--with some care for rounding--to produce the square root).

More precisely: we use the function `f(x) = x^-2 - n`. Clearly, if `f(x) = 0`, then `x = 1/sqrt(n)`. This gives rise to the newton iteration:

``````x_(i+1) = x_i - f(x_i)/f'(x_i)
= x_i - (x_i^-2 - n)/(-2x_i^-3)
= x_i + (x_i - nx_i^3)/2
= x_i*(3/2 - 1/2 nx_i^2)
``````

Note that (unlike the iteration for the square root), this iteration for the reciprocal square root involves no divisions, so it is generally much more efficient.

I mentioned in your question on divide that you should look at existing soft-float libraries, rather than re-inventing the wheel. That advice applies here as well. This function has already been implemented in existing soft-float libraries.

Edit: the questioner seems to still be confused, so let's work an example: `sqrt(612)`. `612` is `1.1953125 x 2^9` (or `b1.0011001 x 2^9`, if you prefer binary). Pull out the even portion of the exponent (9) to write the input as `f * 2^(2m)`, where `m` is an integer and `f` is in the range [1,4). Then we will have:

``````sqrt(n) = sqrt(f * 2^2m) = sqrt(f)*2^m
``````

applying this reduction to our example gives `f = 1.1953125 * 2 = 2.390625` (`b10.011001`) and `m = 4`. Now do a newton-raphson iteration to find `x = 1/sqrt(f)`, using a starting guess of 0.5 (as I noted in a comment, this guess converges for all `f`, but you can do significantly better using a linear approximation as an initial guess):

``````x_0 = 0.5
x_1 = x_0*(3/2 - 1/2 * 2.390625 * x_0^2)
= 0.6005859...
x_2 = x_1*(3/2 - 1/2 * 2.390625 * x_1^2)
= 0.6419342...
x_3 = 0.6467077...
x_4 = 0.6467616...
``````

So even with a (relatively bad) initial guess, we get rapid convergence to the true value of `1/sqrt(f) = 0.6467616600226026`.

Now we simply assemble the final result:

``````sqrt(f) = x_n * f = 1.5461646...
sqrt(n) = sqrt(f) * 2^m = 24.738633...
``````

And check: sqrt(612) = 24.738633...

Obviously, if you want correct rounding, careful analysis needed to ensure that you carry sufficient precision at each stage of the computation. This requires careful bookkeeping, but it isn't rocket science. You simply keep careful error bounds and propagate them through the algorithm.

If you want to correct rounding without explicitly checking a residual, you need to compute sqrt(f) to a precision of 2p + 2 bits (where p is precision of the source and destination type). However, you can also take the strategy of computing sqrt(f) to a little more than p bits, square that value, and adjust the trailing bit by one if necessary (which is often cheaper).

sqrt is nice in that it is a unary function, which makes exhaustive testing for single-precision feasible on commodity hardware.

You can find the OS X soft-float `sqrtf` function on opensource.apple.com, which uses the algorithm described above (I wrote it, as it happens). It is licensed under the APSL, which may or not be suitable for your needs.

• What is the advantage of using f(x) = x^-2 - n versus f(x) = x^2 - n ?? – ElKamina Feb 10 '12 at 23:45
• @ElKamina: As explained in my answer, using `x^-2 - n` avoids division in the iteration, making it much more efficient on typical hardware, while preserving quadratic convergence. – Stephen Canon Feb 11 '12 at 0:05
• @starbox: I believe you can get the libgcc and compiler_rt sources from the public repositories. compiler_rt is also browsable on the web: llvm.org/viewvc/llvm-project/compiler-rt/trunk/lib/… – Stephen Canon Feb 11 '12 at 0:10
• @StephenCanon, What do you mean a range reduction so that n is in [1,4). I have a 32-bit mantissa, I could just change the exponent to -1 and the number is guaranteed to be in the range of 0.5 to 1. Is that what you mean? But then the number doesn't converge. I tried using n = 612, and I need a starting guess around 0.01 for the algorithm to converge. If you could start with n = 612 as an example, that would work well for me. Thanks man. – Veridian Feb 11 '12 at 3:40
• @starbox: `612 = 2.390625 x 2^8`, so `sqrt(612) = sqrt(2.390625) x sqrt(2^8) = sqrt(2.390625) x 2^4`. Pull out the even portion of the exponent, and you're left with a value in the range [1,4). – Stephen Canon Feb 12 '12 at 23:33

Probably (still) the fastest implementation for finding the inverse square root and the 10 lines of code that I adore the most.

It's based on Newton Approximation, but with a few quirks. There's even a great story around this.

Easiest to implement (you can even implement this in a calculator):

``````def sqrt(x, TOL=0.000001):
y=1.0
while( abs(x/y -y) > TOL ):
y= (y+x/y)/2.0
return y
``````

This is exactly equal to newton raphson:

y(new) = y - f(y)/f'(y)

f(y) = y^2-x and f'(y) = 2y

Substituting these values:

y(new) = y - (y^2-x)/2y = (y^2+x)/2y = (y+x/y)/2

If division is expensive you should consider: http://en.wikipedia.org/wiki/Shifting_nth-root_algorithm .

Shifting algorithms:

Let us assume you have two numbers a and b such that least significant digit (equal to 1) is larger than b and b has only one bit equal to (eg. a=1000 and b=10). Let s(b) = log_2(b) (which is just the location of bit valued 1 in b).

Assume we already know the value of a^2. Now (a+b)^2 = a^2 + 2ab + b^2. a^2 is already known, 2ab: shift a by s(b)+1, b^2: shift b by s(b).

Algorithm:

``````Initialize a such that a has only one bit equal to one and a^2<= n < (2*a)^2.
Let q=s(a).
b=a
sqra = a*a

For i = q-1 to -10 (or whatever significance you want):
b=b/2
sqrab = sqra + 2ab + b^2
if sqrab > n:
continue
sqra = sqrab
a=a+b

n=612
a=10000 (16)

sqra = 256

Iteration 1:
b=01000 (8)
sqrab = (a+b)^2 = 24^2 = 576
sqrab < n => a=a+b = 24

Iteration 2:
b = 4
sqrab = (a+b)^2 = 28^2 = 784
sqrab > n => a=a

Iteration 3:
b = 2
sqrab = (a+b)^2 = 26^2 = 676
sqrab > n => a=a

Iteration 4:
b = 1
sqrab = (a+b)^2 = 25^2 = 625
sqrab > n => a=a

Iteration 5:
b = 0.5
sqrab = (a+b)^2 = 24.5^2 = 600.25
sqrab < n => a=a+b = 24.5

Iteration 6:
b = 0.25
sqrab = (a+b)^2 = 24.75^2 = 612.5625
sqrab < n => a=a

Iteration 7:
b = 0.125
sqrab = (a+b)^2 = 24.625^2 = 606.390625
sqrab < n => a=a+b = 24.625

and so on.
``````
• this is basically a variation of the crossing method, and it is expected to converge much slower than newton raphson – amit Feb 10 '12 at 22:23
• @ElKamina While I have implemented floating point divide, I would like to reduce the number of times I have to execute it since it is extremely expensive. The processor I am using has no hardware floating point divide unit. – Veridian Feb 10 '12 at 22:25
• @amit This method is equivalent to newton raphson method. – ElKamina Feb 10 '12 at 22:43
• @starbox What is the efficiency of your multiplication compared to addition or subtraction? That is, how many additions is equal to multiplication? Does it depend on values that are being multiplied? – ElKamina Feb 10 '12 at 22:51
• @ElKamina Multiplication (in floating point) is slightly more efficient than my addition. I haven't counted it out yet. I'm going to try the answer above and get back to you if it doesn't pan out. Thanks – Veridian Feb 10 '12 at 23:46

A good approximation to square root on the range `[1,4)` is

``````def sqrt(x):
y = x*-0.000267
y = x*(0.004686+y)
y = x*(-0.034810+y)
y = x*(0.144780+y)
y = x*(-0.387893+y)
y = x*(0.958108+y)
return y+0.315413
``````

Normalise your floating point number so the mantissa is in the range `[1,4)`, use the above algorithm on it, and then divide the exponent by 2. No floating point divisions anywhere.

With the same CPU time budget you can probably do much better, but that seems like a good starting point.

• how do you normalize the mantissa so that it is in the range [1,4]? Please use x = 612 as an example. – Veridian Feb 11 '12 at 23:12
• If you're using IEEE floats you can easily pick off the exponent. If it's even then the floating point number is if the form a*2^(2n) where a is in [1,2). So use the above algorithm to give the result sqrt(a)*2^n. If the exponent is odd we have a*2^(2n+1)=(2a)*2^(2n). This time a is in [2,4) and we use the above algorithm to give: sqrt(2*a)*2^n. – sigfpe Feb 13 '12 at 18:18