Is there a function for integer exponentiation in OCaml? ** is only for floats. Although it seems to be mostly accurate, isn't there a possibility of precision errors, something like 2. ** 3. = 8. returning false sometimes? Is there a library function for integer exponentiation? I could write my own, but efficiency concerns come into that, and also I'd be surprised if there isn't such a function already.
Regarding the floating-point part of your question: OCaml calls the underlying system's
pow() function. Floating-point exponentiation is a difficult function to implement, but it only needs to be faithful (that is, accurate to one Unit in the Last Place) to make
2. ** 3. = 8. evaluate to
8.0 is the only
float within one ULP of the mathematically correct result 8.
All math libraries should(*) be faithful, so you should not have to worry about this particular example. But not all of them actually are, so you are right to worry.
A better reason to worry would be, if you are using 63-bit integers or wider, that the arguments or the result of the exponentiation cannot be represented exactly as OCaml floats (actually IEEE 754 double-precision numbers that cannot represent
9_007_199_254_740_993 or 253 + 1). In this case, floating-point exponentiation is a bad substitute for integer exponentiation, not because of a weakness in a particular implementation, but because it is not designed to represent exactly integers that big.
(*) Another fun reference to read on this subject is “A Logarithm Too Clever by Half” by William Kahan.
Below is a proposed implementation:
let rec pow a = function | 0 -> 1 | 1 -> a | n -> let b = pow a (n / 2) in b * b * (if n mod 2 = 0 then 1 else a)
If there is a risk of overflow because you're manipulating very big numbers, you should probably use a big-integer library such as Zarith, which provides all sorts of exponentiation functions.
(You may need the "modular exponentiation", computing
(a^n) mod p; this can be done in a way that avoids overflows by applying the mod in the intermediary computations, for example in the function
Here's another implementation which uses exponentiation by squaring (like the one provided by @gasche), but this one is tail-recursive
let is_even n = n mod 2 = 0 (* https://en.wikipedia.org/wiki/Exponentiation_by_squaring *) let pow base exponent = if exponent < 0 then invalid_arg "exponent can not be negative" else let rec aux accumulator base = function | 0 -> accumulator | 1 -> base * accumulator | e when is_even e -> aux accumulator (base * base) (e / 2) | e -> aux (base * accumulator) (base * base) ((e - 1) / 2) in aux 1 base exponent
A simpler formulation of the solution above:
let pow = let rec pow' a x n = if n = 0 then a else pow' (a * (if n mod 2 = 0 then 1 else x)) (x * x) (n / 2) in pow' 1
pow' a x n computes
x to the