Hashtbl.find function is not free even when applied to an empty hash table because it computes the hash of the provided key. Since you're using a polymorphic hash table implementation, a generic (implemented in C) hash function is used. These all incur some overhead w.r.t to the default payload of a Fibonacci function, which is only three arithmetic operations (i.e., an overhead of 20x3=60 arithmetic operations).
If we will use the functorial interface to provide a more efficient hashing function, we will reduce the overhead to something that is close to x3:
module Table = Hashtbl.Make(struct
type t = int
let equal : int -> int -> bool = fun x y -> x = y [@@inline]
let hash x = x [@@inline]
let table = Table.create 127
let fib1 x =
let rec f n = match n with
| 0 -> 0
| 1 -> 1
| n -> match Table.find_opt table n with
| Some x -> x
| None ->
let r = f (n - 1) + f (n - 2) in
(* Hashtbl.add table n r ; *)
Note, that I also switched from using exceptions to the option type. Setting up exception handlers inside of a recursive function implies extra overhead on each recursive call. Basically, the
try statement has a runtime cost.
If we will compare the running time of implementation with hash tables (
fib1) and without (
fib2), we will get the following numbers (in ms, on mine 2Ghz machine, for n=32)
This gives us an overhead of x3 (6 arithmetic operations on top of the Fibonacci kernel itself), which more or less corresponds to the overhead of the modulo operation (two arithmetic operations) as well as three extra calls (the find itself, our
hash function, and the
You can also try the hash table implementation provided by the Janestreet Core library, which is usually more efficient.