Let vs. Where
Haskell programmers often wonder whether to use let or where.
This seems to be only a matter of taste in the sense of "Declaration vs. expression_style",
however there is more about it.
It is important to know that let ... in ... is an expression,
that is, it can be written wherever expressions are allowed.
In contrast to that, where is bound to a surrounding syntactic construct,
like the pattern matching line of a function definition.
Advantages of let
Consider you have the function
f :: s -> (a,s)
f x = y
where y = ... x ...
and later you decide to put this into the Control.Monad.State monad.
However, transforming to
f :: State s a
f = State $ \x -> y
where y = ... x ...
will not work, because where refers to the pattern matching f =,
where no x is in scope.
In contrast, if you had started with let, then you wouldn't have trouble.
f :: s -> (a,s)
f x =
let y = ... x ...
in y
This is easily transformed to:
f :: State s a
f = State $ \x ->
let y = ... x ...
in y
Advantages of where
Because "where" blocks are bound to a syntactic construct, they can be used to share bindings between parts of a function that are not syntactically expressions. For example:
f x
| cond1 x = a
| cond2 x = g a
| otherwise = f (h x a)
where
a = w x
In expression style, you might use an explicit case:
f x
= let a = w x
in case () of
_ | cond1 x = a
| cond2 x = g a
| otherwise = f (h x a)
or a functional equivalent:
f x =
let a = w x
in select (f (h x a))
[(cond1 x, a),
(cond2 x, g a)]
or a series of if-then-else expressions:
f x
= let a = w x
in if cond1 x
then a
else if cond2 x
then g a
else f (h x a)
These alternatives are arguably less readable and hide the structure of the function more than simply using where.
Lambda Lifting
One other approach to consider is that let or where can often be implemented using lambda lifting and let floating, incurring at least the cost of introducing a new name. The above example:
f x
| cond1 x = a
| cond2 x = g a
| otherwise = f (h x a)
where
a = w x
could be implemented as:
f x = f' (w x) x
f' a x
| cond1 x = a
| cond2 x = g a
| otherwise = f (h x a)
The auxiliary definition can either be a top-level binding, or included in f using let or where.