Why not square the result, and if it's not equal to the input, add or subtract (depending on the sign of the difference) a least significant bit, square, and check whether that would have given a better result?

Better here could mean with less absolute difference. The only case where this could get tricky is when "crossing" √2 with the mantissa, but this could be checked once and for all.

**EDIT**

I realize that the above answer is insufficient. Simply squaring in 32-bit FP and comparing to the input doesn't give you enough information. Let's say y = your_sqrt(x). You compare y^{2} to x, find that y^{2}>x, subtract 1 LSB from y obtaining z (y1 in your comments), then compare z^{2} to x and find that not only z^{2}<x, but, within the available bits, y^{2}-x==x-z^{2} - how do you choose between y and z? You should either work with all the bits (I guess this is what you were looking for), or at least with more bits (which I guess is what njuffa is suggesting).

From a comment of yours I suspect you are on strictly 32-bit hardware, but let me suppose that you have a 32-bit by 32-bit integer multiplication with 64-bit result available (if not, it can be constructed). If you take the 23 bits of the mantissa of y as an integer, put a 1 in front, and multiply it by itself, you have a number that, except for a possible extra shift by 1, you can directly compare to the mantissa of x treated the same way. This way you have all 48 bits available for the comparison, and can decide without any approximation whether abs(y^{2}-x)≷abs(z^{2}-x).

If you are not sure to be within one LSB from the final result (but you are sure not to be much farther than that), you should repeat the above until y^{2}-x changes sign or hits 0. Watch out for edge cases, though, which should essentially be the cases when the exponent is adjusted because the mantissa crosses a power of 2.

It can also be helpful to remember that positive floating point numbers can be correctly compared as integers, at least on those machines where 1.0F is 0x3f800000.