# Partial Application with Infix Functions

While I understand a little about currying in the mathematical sense, partially applying an infix function was a new concept which I discovered after diving into the book Learn You a Haskell for Great Good.

Given this function:

``````applyTwice :: (a -> a) -> a -> a
applyTwice f x = f (f x)
``````

The author uses it in a interesting way:

``````ghci> applyTwice (++ [0]) [1]
[1,0,0]
ghci> applyTwice ([0] ++) [1]
[0,0,1]
``````

Here I can see clearly that the resulting function had different parameters passed, which would not happen by normal means considering it is a curried function (would it?). So, is there any special treatment on infix sectioning by Haskell? Is it generic to all infix functions?

As a side note, this is my first week with Haskell and functional programming, and I'm still reading the book.

-

Yes, you can partially apply an infix operator by specifying either its left or right operand, just leaving the other one blank (exactly in the two examples you wrote).

So, `([0] ++)` is the same as `(++) [0]` or `\x -> [0] ++ x` (remember you can turn an infix operator into a standard function by means of parenthesis), while `(++ [0])` equals to `\x -> x ++ [0]`.

It is useful to know also the usage of backticks, ( `` ), that enable you to turn any standard function with two arguments in an infix operator:

``````Prelude> elem 2 [1,2,3]
True
Prelude> 2 `elem` [1,2,3] -- this is the same as before
True
Prelude> let f = (`elem` [1,2,3]) -- partial application, second operand
Prelude> f 1
True
Prelude> f 4
False
Prelude> let g = (1 `elem`) -- partial application, first operand
Prelude> g [1,2]
True
Prelude> g [2,3]
False
``````
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So, I don't know Haskell, but is `(1 `elem`)` the same as `elem 1`? – Neil Apr 12 '12 at 20:49
@Neil: Yes, it is. – Riccardo Apr 12 '12 at 20:50
I like to think of `(++)` as a section where you omit both inputs. – Dan Burton Apr 12 '12 at 22:11
@DanBurton: that's a good explanation for `(op)` indeed. – Riccardo Apr 12 '12 at 22:44

Yes, this is the section syntax at work.

Sections are written as `( op e )` or `( e op )`, where op is a binary operator and e is an expression. Sections are a convenient syntax for partial application of binary operators.

The following identities hold:

``````(op e)  =   \ x -> x op e
(e op)  =   \ x -> e op x
``````
-

All infix operators can be used in sections in Haskell - except for `-` due to strangeness with unary negation. This even includes non-infix functions converted to infix by use of backticks. You can even think of the formulation for making operators into normal functions as a double-sided section:

`(x + y)` -> `(+ y)` -> `(+)`

Sections are (mostly, with some rare corner cases) treated as simple lambdas. `(/ 2)` is the same as:

`\x -> (x / 2)`

and `(2 /)` is the same as `\x -> (2 / x)`, for an example with a non-commutative operator.

There's nothing deeply interesting theoretically going on here. It's just syntactic sugar for partial application of infix operators. It makes code a little bit prettier, often. (There are counterexamples, of course.)

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Note that the "strangeness with unary negation" is due to the fact that it is ambiguous whether `(- 1)` should be interpreted as the numeric literal -1 or as the function `\x -> x - 1`. The choice of the creators of Haskell was to interpret it as a numeric literal, and provide the function `subtract`, which satisfies `subtract x = \y -> y - x`. They also provide `negate` which acts as the unary minus function, i.e. `negate x = -x` – Chris Taylor Apr 12 '12 at 23:03
@ChrisTaylor: Almost. `(- x)` translates to `negate x`, so `(- 1)` is `negate (fromInteger 1)`, not `fromInteger (-1)`. Of course, the two should be equivalent for well-behaved `Num` instances. – hammar Apr 13 '12 at 2:13
@hammar Ah ok, little bit of backwards logic there. Thanks for the correction! – Chris Taylor Apr 13 '12 at 7:06