I want to write a function to calculate the square root of a s15.16 fixed point number. I know its a signed number with 15 digit int and 16 digit fraction. Is there anyway to do it without any libraries? Any other languages is fine too.

I prefer Java but it doesn't matter – AliBZ Mar 2 '13 at 23:08

1Out of curiosity, why are you working with a S15.16 in Java? Seems like you might be able to get away with BigDecimal depending on the situation? – Corbin Mar 3 '13 at 0:11

The thing is I have to write a function to calculate the root of an s15.16 fixed point number. I don't know which language to use. It doesn't matter that much. – AliBZ Mar 3 '13 at 0:19

Thanx for the tip, I just did. – AliBZ Mar 3 '13 at 1:02

I would think the old plug&chug square root method would work. Though virtually all standard algorithms use an approximation technique such as Newton's Method (and I recall having that as a class assignment in Programming 101, so it's not that difficult to implement). – Hot Licks Mar 3 '13 at 1:11
I assume you are asking this question because the platform you are on does not provide floatingpoint, otherwise you can implement 15.16 fixedpoint square root via the floatingpoint square root as follows (this is C code, I assume Java code will look very similar):
int x, r;
r = (int)(sqrt (x / 65536.0) * 65536.0 + 0.5);
If your target platform provides a fast integer multiply (in particular, either a multiply with doublewidth result or a multiplyhigh instruction), and you can spare some memory for a small table, use of NewtonRaphson iterations plus a tablebased starting approximation is typically the way to go. Typically, one approximates the reciprocal square root because it has a more convenient NR iteration. This gives rsqrt(x) = 1 / sqrt(x). By multiplying it with x one then gets the square root, i.e. sqrt(x) = rsqrt(x) * x. The following code shows how to compute a correctly rounded 16.16 fixedpoint square root in this fashion (since the argument to the square root must be positive, this works just as well for s15.16 fixedpoint). Rounding is performed by minimizing the residual x  sqrt(x)*sqrt(x).
I apologize that the square root function itself is 32bit x86 inline assembly code but I last needed this about 10 years ago and this is all I have. I hope you can extract relevant operations from the fairly extensive comments. I included the generation of the table for the starting approximation as well as a test framework that tests the function exhaustively.
#include <stdlib.h>
#include <math.h>
unsigned int tab[96];
__declspec(naked) unsigned int __stdcall fxsqrt (unsigned int x)
{
__asm {
mov edx, [esp + 4] ;// x
mov ecx, 31 ;// 31
bsr eax, edx ;// bsr(x)
jz $done ;// if (!x) return x, avoid outofbounds access
push ebx ;// save per calling convention
push esi ;// save per calling convention
sub ecx, eax ;// leading zeros = lz = 31  bsr(x)
// compute table index
and ecx, 0xfffffffe ;// lz & 0xfffffffe
shl edx, cl ;// z = x << (lz & 0xfffffffe)
mov esi, edx ;// z
mov eax, edx ;// z
shr edx, 25 ;// z >> 25
// retrieve initial approximation from table
mov edx, [tab+4*edx128];// r = tab[(z >> 25)  32]
// first NewtonRaphson iteration
lea ebx, [edx*2+edx] ;// 3 * r
mul edx ;// f = (((unsigned __int64)z) * r) >> 32
mov eax, esi ;// z
shl ebx, 22 ;// r = (3 * r) << 22
sub ebx, edx ;// r = r  f
// second NewtonRaphson iteration
mul ebx ;// prod = ((unsigned __int64)r) * z
mov eax, edx ;// s = prod >> 32
mul ebx ;// prod = ((unsigned __int64)r) * s
mov eax, 0x30000000 ;// 0x30000000
sub eax, edx ;// s = 0x30000000  (prod >> 32)
mul ebx ;// prod = ((unsigned __int64)r) * s
mov eax, edx ;// r = prod >> 32
mul esi ;// prod = ((unsigned __int64)r) * z;
pop esi ;// restore per calling convention
pop ebx ;// restore per calling convention
mov eax, [esp + 4] ;// x
shl eax, 17 ;// x << 17
// denormalize
shr ecx, 1 ;// lz >> 1
shr edx, 3 ;// r = (unsigned)(prod >> 32); r >> 3
shr edx, cl ;// r = (r >> (lz >> 1)) >> 3
// round to nearest; remainder can be negative
lea ecx, [edx+edx] ;// 2*r
imul ecx, edx ;// 2*r*r
sub eax, ecx ;// rem = (x << 17)  (2*r*r))
lea ecx, [edx+edx+1] ;// 2*r+1
cmp ecx, eax ;// ((int)(2*r+1)) < rem))
lea ecx, [edx+1] ;// r++
cmovl edx, ecx ;// if (((int)(2*r+1)) < rem) r++
$done:
mov eax, edx ;// result in EAX per calling convention
ret 4 ;// pop function argument and return
}
}
int main (void)
{
unsigned int i, r;
// build table of reciprocal square roots and their (rounded) cubes
for (i = 0; i < 96; i++) {
r = (unsigned int)(sqrt (1.0 / (1.0 + (i + 0.5) / 32.0)) * 256.0 + 0.5);
tab[i] = ((r * r * r + 4) & 0x00ffffff8) * 256 + r;
}
// exhaustive test of 16.16 fixedpoint square root
i = 0;
do {
r = (unsigned int)(sqrt (i / 65536.0) * 65536.0 + 0.5);
if (r != fxsqrt (i)) {
printf ("error @ %08x: ref = %08x res=%08x\n", i, r, fxsqrt (i));
break;
}
i++;
} while (i);
}
Use your favourite integer square root algorithm, with the simple observation that √(2^{16}a) = 2^{8}√a.