I have a coprocessor which does not have floating point support. I tried to use 32 bit fix point, but it is unable to work on very small numbers. My numbers range from 1 to 1e18. One way is to use floating point emulation, but it is too slow. Can we make it faster in this case where we know the numbers won't be greater than 1 and smaller than 1e18. Or is there a way to make fix point work on very small numbers.

It is not possible for a 32bit fixedpoint encoding to represent numbers from 10^{–18} to 1. This is immediately obvious from the fact that the span from 10^{18} is a ratio of 10^{18}, but the nonzero encodings of a 32bit integer span a ratio of less than 2^{32}, which is much less than 10^{18}. Therefore, no choice of scale for the fixedpoint encoding will provide the desired span. So a 32bit fixedpoint encoding will not work, and you must use some other technique. In some applications, it may be suitable to use multiple fixedpoint encodings. That is, various input values would be encoded with a fixedpoint encoding but each with a scale suitable to it, and intermediate values and the outputs would also have customized scales. Obviously, this is possible only if suitable scales can be determined at design time. Otherwise, you should abandon 32bit fixedpoint encodings and consider alternatives. 


Use 64 bit fixed point and be done with it. Compared with 32 bit fixed point it will be four times slower for multiplication, but it will still be far more efficient than float emulation. 


In embedded systems I'd suggest using 16+32, 16+16, 8+16 or 8+24 bit redundant floating point representation, where each number is simply M * 2^exp. In this case you can choose to represent zero with both M=0 and exp=0; There are 1632 representations for each power of 2  and that mainly makes comparison a bit harder than typically. Also one can postpone normalization e.g. after subtraction. 


Will simplified 24bit floating point be fast enough and accurate enough?:
Output (ideone):
Subtraction is left as an exercise. Ditto for better conversion routines. 

