I think @HTNW's answer probably covers it, but for completeness, here's how the `inContext`

solution works in detail.

The type signature of the function:

```
inContext :: a -> (a -> b) -> a
```

means that, if you have a thing you want to type, and a "context" in which it's used (expressible as a lambda that takes it as an argument), say with types:

```
thing :: a1
context :: a2 -> b
```

You can force unification of `a1`

(the general type of `thing`

) with `a2`

(the constraints of the context) simply by constructing the expression:

```
thing `inContext` context
```

Normally, the unified type `thing :: a`

would be lost, but the type signature of `inContext`

implies that the type of this whole resulting expression will also be unified with the desired type `a`

, and GHCi will happily tell you the type of that expression.

So the expression:

```
(.) `inContext` \hole -> hole digitToInt
```

ends up getting assigned the type that `(.)`

would have within the specified context. You can write this, somewhat misleadingly, as:

```
(.) `inContext` \(.) -> (.) digitToInt
```

since `(.)`

is as good an argument name for an anonymous lambda as `hole`

is. This is potentially confusing, since we're creating a local binding that shadows the top-level definition of `(.)`

, but it's still naming the same thing (with a refined type), and this abuse of lambdas allowed us to write the original expression `(.) digitToInt`

verbatim, with the appropriate boilerplate.

It's actually irrelevant how `inContext`

is defined, if you're just asking GHCi for its type, so `inContext = undefined`

would have worked. But, just looking at the type signature, it's easy enough to give `inContext`

a working definition:

```
inContext :: a -> (a -> b) -> a
inContext a _ = a
```

It turns out that this is just the definition of `const`

, so `inContext = const`

works, too.

You can use `inContext`

to type multiple things at once, and they can be expressions instead of names. To accommodate the former, you can use tuples; for the latter to work, you have use more sensible argument names in your lambas.

So, for example:

```
λ> :t (fromJust, fmap length) `inContext` \(a,b) -> a . b
(fromJust, fmap length) `inContext` \(a,b) -> a . b
:: Foldable t => (Maybe Int -> Int, Maybe (t a) -> Maybe Int)
```

tells you that in the expression `fromJust . fmap length`

, the types have been specialized to:

```
fromJust :: Maybe Int -> Int
fmap length :: Foldable t => Maybe (t a) -> Maybe Int
```

`> :t (.) Data.Char.digitToInt`

? – Will Ness Dec 11 '20 at 20:34`:t undefined :: ((b -> c) -> (a -> b) -> a -> c) ~ ((Char -> Int) -> d) => ((b -> c) -> (a -> b) -> a -> c)`

, which replies`... :: (Char -> Int) -> (a -> Char) -> a -> Int`

. – Daniel Wagner Dec 11 '20 at 21:06`:t undefined :: (type of function) ~ (type of argument -> fresh variable) => (comma separated unknowns)`

(where the unknown could be, say, another copy of the function's type signature). If both the function and the argument are polymorphic, you should make sure to rename the variables in one or the other so there are no accidental equalities. – Daniel Wagner Dec 11 '20 at 21:32`inContext :: a -> (a -> b) -> a`

defined by`inContext = const`

. Then, at the GHCi prompt, the expression`inContext (.) $ \(.) -> (.) digitToInt`

gives the inferred type directly, so you don't have to copy type signatures and make up fresh variables. Note that`inContext`

can be used infix, but I always mess up writing code with backticks in comments. – K. A. Buhr Dec 11 '20 at 21:5110more comments