# Partial function application for a non-symmetric operator using point-free style in F#?

How can I create a partial function application for a non-symmetric operator such as the modulus operator with regards to the first argument without any argument names in F#? My first attempt was

`let mod10 = (%) 10` which of course translates to

`mod10(x) = 10 mod x` instead of the desired

`mod10(x) = x mod 10`. Certainly I could write

`let mod10 x = (%)x 10` but I'd like to not have to name the argument so is there some placeholder that can be used, something like

`let mod10 = (%)_ 10`?

-

You can define `flip` function which is common in point-free style:

``````let inline flip f x y = f y x
``````

and use it like this:

``````let (%-) = flip (%)
let mod10 = (%-) 10
``````

or directly like this:

``````let mod10 = flip (%) 10
``````

Point-free style is not always readable (as in this example) and not popular in F# programming.

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Ah nice 'trick'! I agree that point-free style isn't always readable but I guess that goes for all styles. – Christian Jul 7 '12 at 21:00
I, for one, love point-free. ;-] – ildjarn Jul 7 '12 at 21:39
Programming isn't really a popularity contest. Besides, it's hard to make a call on popularity. It might be uncommon but that doesn't mean it's unpopular. I like point-free in many cases, but in others it does reduce readability. – OJ. Jul 9 '12 at 9:33
@OJ: I agree that is a subjective matter. Good point though. – pad Jul 9 '12 at 9:51
@pad: Our programming lives are full of subjectivity aren't they? :) That's what makes the world colourful! – OJ. Jul 14 '12 at 22:45

Here's solution based on functional composition.

``````let mod10 = (%) >> (|>) 10
``````

UPD Here was a wordy explanation, but programmers speak the code, so I guess the following will describe it much better, in a manner of mathematical proof.

The following expressions are equal:

``````let m1 x = x % 10
let m2 x = (%) x 10                  // x (op) y = (op) x y
let m3 x = ((%) x) 10                // f x y = (f x) y
let m4 x = 10 |>         ((%) x)     // f x = x |> f
let m5 x = ((|>) 10)     ((%) x)     // x |> f = (|>) x f
let m6 x = ((%) x)    |> ((|>) 10)   // f x = x |> f
let m7 x = (x |> (%)) |> ((|>) 10)   // (op) x = x |> (op)
let m8 x = x |> ((%)  >> ((|>) 10))  // f(x) |> g = x |> (f >> g)
let m9   =       (%)  >> ((|>) 10)   // remove formal argument
let m10  =       (%)  >>  (|>) 10    // remove unnecessary parenthesis
``````

Alternative syntax:

``````let mod10_2 = (|>) 10 << (%)
``````
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Truly awesome proof! The solution somewhat hard to decipher for a novice like myself but still, very beautiful :) – Christian Jul 8 '12 at 21:25
@Christian: It can be chained as well: `let combinator (b: 'b) (c: 'c) (f: 'a -> 'b -> 'c -> 'd) : ('a -> 'd) = f >> ((|>) b) >> ((|>) c)` – bytebuster Jul 8 '12 at 21:35