My goal is to run a simulation that requires non-integral numbers across different machines that might have a varying CPU architectures and OSes. The main priority is that given the same initial state, each machine should reproduce the simulation exactly the same. Secondary priority is that I'd like the calculations to have performance and precision as close as realistically possible to double-precision floats.
As far as I can tell, there doesn't seem to be any way to affect the determinism of floating
point calculations from within a Haskell program, similar to the
_FPU_SETCW macros in C. So, at the moment I consider my options to be
- Use Data.Ratio
- Use Data.Fixed
- Use Data.Fixed.Binary from the fixed-point package
- Write a module to call
_ controlfp(or the equivivalent for each platform) via FFI.
- Possibly, something else?
One problem with the fixed point arithmetic libraries is that they don't have e.g. trigonometric functions or logarithms defined for them (as they don't implement the
Floating type-class) so I guess I would need to provide lookup tables for all the functions in the simulation seed data. Or is there some better way?
Both of the fixed point libraries also hide the
newtype constructor, so any (de-)serialization would need to be done via
fromRational as far as I can tell, and that feels like it would add unnecessary overhead.
My next step is to benchmark the different fixed-point solutions to see the real world performance, but meanwhile, I'd gladly take any advice you have on this subject.