There are important reasons why `Haskell`

and other functional languages use `let`

. I'll try to describe them step by step:

# Quantification of type variables

The Damas-Hindley-Milner type system used in Haskell and other functional languages allows polymorphic types, but the type quantifiers are allowed only *in front* of a given type expression. For example, if we write

```
const :: a -> b -> a
const x y = x
```

then the type of `const`

is polymorphic, it is implicitly universally quantified as

```
∀a.∀b. a -> b -> a
```

and `const`

can be specialized to any type that we obtain by substituting two type expressions for `a`

and `b`

.

However, the type system doesn't allow quantifiers inside type expressions, such as

```
(∀a. a -> a) -> (∀b. b -> b)
```

Such types are allowed in System F, but then type checking and type inference is undecidable, which means that the compiler wouldn't be able to infer types for us and we would have to explicitly annotate expressions with types.

(For long time the question of decidability of type-checking in System F had been open, and it had been sometimes addressed as "an embarrassing open problem", because the undecidability had been proven for many other systems but this one, until proved by Joe Wells in 1994.)

(GHC allows you to enable such explicit inner quantifiers using the `RankNTypes`

extension, but as mentioned, the types can't be inferred automatically.)

# Types of lambda abstractions

Consider the expression `λx.M`

, or in Haskell notation `\x -> M`

,
where `M`

is some term containing `x`

. If the type of `x`

is `a`

and the type of `M`

is `b`

, then the type of the whole expression will be `λx.M : a → b`

. Because of the above restriction, `a`

must not contain ∀, therefore *the type of *`x`

can't contain type quantifiers, it can't be polymorphic (or in other words it must be *monomorphic*).

# Why lambda abstraction isn't enough

Consider this simple Haskell program:

```
i :: a -> a
i x = x
foo :: a -> a
foo = i i
```

Let's disregard for now that `foo`

isn't very useful. The main point is that `id`

in the definition of `foo`

is instantiated with two different types. The first one

```
i :: (a -> a) -> (a -> a)
```

and the second one

```
i :: a -> a
```

Now if we try to convert this program into the pure lambda calculus syntax without `let`

, we'd end up with

```
(λi.i i)(λx.x)
```

where the first part is the definition of `foo`

and the second part is the definition of `i`

. But this term will not type check. The problem is that `i`

must have a monomorphic type (as described above), but we need it polymorphic so that we can instantiate `i`

to the two different types.

Indeed, if you try to typecheck `i -> i i`

in Haskell, it will fail. There is no monomorphic type we can assign to `i`

so that `i i`

would typecheck.

`let`

solves the problem

If we write `let i x = x in i i`

, the situation is different. Unlike in the previous paragraph, there is no lambda here, there is no self-contained expression like `λi.i i`

, where we'd need a polymorphic type for the abstracted variable `i`

. Therefore `let`

can allow `i`

to have a polymorhpic type, in this case `∀a.a → a`

and so `i i`

typechecks.

Without `let`

, if we compiled a Haskell program and converted it to a single lambda term, every function would have to be assigned a single monomorphic type! This would be pretty useless.

**So **`let`

is an essential construction that allows polymorhism in languages based on Damas-Hindley-Milner type systems.