Here is Explanation of Monad laws in Haskell.
How do explain Monad laws in F#?
bind (M, return) is equivalent to M.
bind ((return x), f) is equivalent to f x.
bind (bind (m, f),g) is equivalent to bind(m, (fun x -> bind (f x, g))).
Here is Explanation of Monad laws in Haskell.
How do explain Monad laws in F#?
bind (M, return) is equivalent to M.
bind ((return x), f) is equivalent to f x.
bind (bind (m, f),g) is equivalent to bind(m, (fun x -> bind (f x, g))).
I think that a good way to understand them in F# is to look at what they mean using the computation expression syntax. I'll write m
for some computation builder, but you can imagine that this is async
or any other computation type.
Left identity
m { let! x' = m { return x } = m { let x' = x
return! f x' } return! f x' }
Right identity
m { let! x = comp = m { return! comp }
return x }
Associativity
m { let! x = comp = m { let! y = m { let! x = comp
let! y = f x return! f x }
return! g y } return! g y }
The laws essentially tell you that you should be able to refactor one version of the program to the other without changing the meaning - just like you can refactor ordinary F# programs.
g
in the right code example? Should the last line be return! g y
?
Jul 8 '14 at 20:01
bind (M, return)
isn't exactlyM
, remember that F# is impure so the binding could cause side effects and mutation.bind
-- that is, a side effect other than the one you're handling via the monad. There are very few good reasons to implement such a thing. Ramon's point is that, unlike Haskell, the F# type system can't stop you from implementing an arbitrary side effect in yourbind
; if you did, the monad laws wouldn't quite hold.