Greg Hewgill and IllidanS4 gave a link with excellent mathematical explanation.
I'll try to sum it up here for ones who don't want to go too much into details.
Any mathematical function, with some exceptions, can be represented by a polynomial sum:
y = f(x)
can be exactly transformed into:
y = a0 + a1*x + a2*(x^2) + a3*(x^3) + a4*(x^4) + ...
Where a0, a1, a2,... are constants. The problem is that for many functions, like square root, for exact value this sum has infinite number of members, it does not end at some x^n. But, if we stop at some x^n we would still have a result up to some precision.
So, if we have:
y = 1/sqrt(x)
In this particular case they decided to discard all polynomial members above second, probably because of calculation speed:
y = a0 + a1*x + [...discarded...]
And the task has now came down to calculate a0 and a1 in order for y to have the least difference from the exact value. They have calculated that the most appropriate values are:
a0 = 0x5f375a86
a1 = -0.5
So when you put this into equation you get:
y = 0x5f375a86 - 0.5*x
Which is the same as the line you see in the code:
i = 0x5f375a86 - (i >> 1);
Edit: actually here
y = 0x5f375a86 - 0.5*x is not the same as
i = 0x5f375a86 - (i >> 1); since shifting float as integer not only divides by two but also divides exponent by two and causes some other artifacts, but it still comes down to calculating some coefficients a0, a1, a2... .
At this point they've found out that this result's precision is not enough for the purpose. So they additionally did only one step of Newton's iteration to improve the result accuracy:
x = x * (1.5f - xhalf * x * x)
They could have done some more iterations in a loop, each one improving result, until required accuracy is met. This is exactly how it works in CPU/FPU! But it seems that only one iteration was enough, which was also a blessing for the speed. CPU/FPU does as many iterations as needed to reach the accuracy for the floating point number in which the result is stored and it has more general algorithm which works for all cases.
So in short, what they did is:
Use (almost) the same algorithm as CPU/FPU, exploit the improvement of initial conditions for the special case of 1/sqrt(x) and don't calculate all the way to precision CPU/FPU will go to but stop earlier, thus gaining in calculation speed.
i = * ( long * ) &y;why is the address of y taken as a pointer to a long then dereferenced again?