# Precedence and `$`

So Haskell has a very regular syntax. At the highest priority is parentheses; then comes applying a function to its argument. Function application is left-associative, or, as I prefer to call it, **greedy nom**: meaning that a function "eats up" the very first thing that it sees after it as its argument. So, if you write `f g h`

this becomes `(f g) h`

: `f`

eats `g`

first, and the return value eats `h`

afterward. Often, especially when you're defining a function, you want to write something like `f (Constructor parameter1 parameter2) = ...`

where you really need the explicit parentheses so that you're not accidentally writing `((f Constructor) parameter1) parameter2`

.

After parentheses and applications, we have operators: these which have a whole hierarchy of priorities and associativities given by the "infix directives". The lowest-priority operator is defined as:

```
f $ g = f g
infixr 0 $
```

This operator is a totally normal operator which seemingly does nothing at all: more precisely it applies the function on its left to the argument on its right. It is low-priority right-associative, so it is "lazy nom" (the function before the `$`

is applied to everything after that `$`

). There is an interesting syntax dispute over whether `f . g . h $ i`

is more or less correct than `f $ g $ h $ i`

, which does the same thing in a different way.

Remember that `$`

is actually just an ordinary operator/function. For example you can do things like this:

```
Prelude> let factorial n = product [1..n]
Prelude> map ($ 3) [(5 +), (3 *), (3 +) . factorial . (2 *)]
[8,9,723]
```

Here we are creating a function `($ 3)`

which takes a function as its argument, applying it to 3. We map the resulting function over several other functions. We could also write this as `zipWith ($) functions (repeat 3)`

if you really wanted, passing `($)`

as the combining function that zipWith will use to zip two lists together. They're the same thing, and they're both fun tricks. You might even someday want to `map (flip ($))`

over a list of values, to get a list of values in the form of functions. It's an isomorphism; you can get the values back with `id = map ($ id) . map (flip ($))`

, but maybe that format will be more convenient for you someday.

Lower priority than this are special forms like `if`

, `let`

, `case`

, `do`

, `where`

, and `\`

. In general Haskell requires that these cannot appear immediately after a value or `)`

, but may appear after a `(`

or an operator. So if you want to write `f \x -> 3 + 2 * x`

Haskell will complain until you make this into one of the following:

```
f ((3 +) . (2 *)) -- no special forms
f (\x -> 3 + 2 * x) -- parenthesize the sub-expression
f $ \x -> 3 + 2 * x -- use $ to make the syntax "work" effortlessly.
```

Similarly you might see things like:

```
main = complicatedProcessingStep . preprocessing $ do
input <- io_input
...
```

where the `$`

is being used to avoid putting parentheses around the `do`

so that you don't have to dangle a `)`

token somewhere in the whitespace.

# Functions have one argument

One huge way that Haskell differs from other languages is that *every function has exactly one argument*. This is probably going to confuse you at first: aren't operators functions of two arguments, and what about `\a b c -> ...`

, doesn't it have three?

The answer is no: `\a b c -> ...`

is syntactic sugar for `\a -> \b -> \c -> ...`

(this is not to mention the fact that you can pattern match on those arguments, too, so secretly `\a -> ...`

is syntactic sugar for `\random_token -> case random_token of a -> ...`

). Each function has one argument, but some functions return a function. In Haskell we *can* do what other languages do, and accept a tuple; `\(a, b) -> a + b`

works fine, and is equivalent to `uncurry (+)`

. We just usually don't do that -- we usually pass `\a b -> a + b`

.

You can make an operator out of any function which returns a function. The resulting operator takes its left-hand-side as an argument for the first function and its right-hand-side for an argument to the second. The canonical way to do this is with backticks:

```
13 `mod` 7 == mod 13 7
```

but if the types are not polymorphic, or if you write an explicit type signature or disable the "monomorphism restriction", you can also write things like `(%%%) = mod`

.

# Three-argument operators.

So there's your answer about "three-argument operators": it returns a function which can then be applied to other values. When you write:

```
a x $|| b y $ c z
```

because of the above rules this parses as:

```
($) (($||) (a x) (b y)) (c z)
```

which by the definition of `($)`

becomes:

```
($||) (a x) (b y) (c z)
```

Just using the operator on the sub-expression, `ax $|| b y`

, produces a function, which could either be applied using parentheses, as in `(a x $|| b y) (c z)`

, or with the `$`

operator which applies its left-hand side to its right-hand-side.

`p .&&. q = \x -> p x && q x`

and then write my filters in a readable way`filter (even .&&. (<10))`

. I have never seen them used anywhere else, but then I also haven't seen that much Haskell code. – ThreeFx May 7 '15 at 11:55`$`

(as in my example) is a bit surprizing for a reader who expects to see some form of function application. The reader must learn that now function application can be written not with a single`$`

, but with`$|| strategy`

inserted in the middle. So, I thought perhaps, there was another clear way to write this down. – imz -- Ivan Zakharyaschev May 7 '15 at 12:47`(f $|| strategy) expr`

. – ThreeFx May 7 '15 at 17:51`$`

, which would "read" better, in the context (e.g.`f ~~> h ||~ g == (f ~~> h) g`

from here). Give it the appropriately low precedence, maybe 1. – Will Ness May 8 '15 at 0:11