Can an analog of the S combinator be expressed in Haskell using only standard functions (without defining it by equation) and without using lambda (anonymous function)? I expect it to by of type `(a -> b -> c) -> (a -> b) -> a -> c`.

For example, an analog of the K combinator is just `const`.

In fact i am trying to express the function `\f x -> f x x` using standard functions, but cannot think of any standard non-linear function to start with (that is a function that uses its argument more than once).

• `\f x -> f x x` is `join` in the function monad. – duplode Apr 15 '14 at 21:59
• what is a standard function? – Sassa NF Apr 16 '14 at 8:45
• @duplode i wonder if that counts as defining it by equation – Sassa NF Apr 16 '14 at 8:47
• @SassaNF, i meant anything fairly standard, like `(.)`, `(\$)`, possibly `flip` :). – Alexey Apr 16 '14 at 9:15

`s = (<*>)` for the `((->) r)` `Applicative` instance.

• Sorry, what is `((->) r)`? – Alexey Apr 16 '14 at 23:22
• @Alexey It is all types `r ->`. Unfortunately, you can't do a section with a type operator in the same way you can with a normal operator. So, though you can do something like `(10*)`, this isn't valid Haskell `(r ->)`. Luckily, we do have a syntax that gives us an equivalent result: `((->) r)`. Note, however, that we cannot do the same with the second argument. This is actually intentionally forbidden (I think it makes type inference impossible in some cases), which is why we can't have type operator sections. – David Apr 16 '14 at 23:55
• @Alexey So, if we have a type synonym `type Function a b = a -> b`, then `((->) r)` is equivalent to `Function r`. – David Apr 16 '14 at 23:56
• So, `r` was just a type variable? – Alexey Apr 16 '14 at 23:59
• Impossibility to have something like `(-> Int)`, is it because Haskell does not allow contravariant functors, by any chance? – Alexey Apr 17 '14 at 0:04

Although it doesn't look like it at first, `ap` is the S combinator (and `join` is the combinator you're really after).

• Thanks, this is helpful. I think i will accept the other answer however because of the title of my question and since `Applicative` seems to be more general than `Monad`. – Alexey Apr 16 '14 at 23:23
• In fact, maybe `Monad` being more restrictive than `Applicative`, your answer is actually better. – Alexey Apr 17 '14 at 8:56

It can also be used `(=<<), (>>=)`.

And they are included in Prelude

``````instance Monad ((->) r) where
return = const
f >>= k = \ r -> k (f r) r
``````