This works because of operator precedence. The function application operator, juxtaposition or

(the space), has the highest precedence, so `take 34 fibseq |> filter even`

parses as `((take 34) fibseq) |> (filter even)`

, which is equivalent to `(filter even) ((take 34) fibseq)`

; since function application is left-associative, this is then equivalent to `filter even (take 34 fibseq)`

.

In general, any binary operator can be given a precedence with a fixity declaration, such as

```
infixl 0 |>
infixr 9 .
```

The `l`

or `r`

says whether the operation is left- or right-associative (that is, whether `a • b • c`

groups as `(a • b) • c`

or `a • (b • c)`

); the number—an integer between 0 and 9—specifies the precedence level. Higher numbers mean higher precedence (with application having an effective precedence of ∞); for instance, `*`

and `/`

have precedence 7, and `+`

and `-`

have precedence 6. To check the precedence of an operator in ghci, just type `:info $`

(or whichever operator) at the prompt.

And just as a note: your code will work, but it's not how I would typically write it. If you're curious, in Haskell, I would write that code with the `$`

operator, which just performs function application but is low precedence: `filter even $ take 34 fibseq`

. If I had more functions to apply, I would use the composition operator: `fun1 arg1 . fun2 . fun3 arg2 arg3 . filter even $ take 34 fibseq`

. It reads the other way, but it's what you typically find in Haskell.

definefunctions in infix notation:`x |> f = f x`

– Tom Lokhorst Jul 24 '10 at 7:05