Strange tilde syntax

GHC accepts this code, but it ought to be illegal syntax(?) Any guesses as to what's going on?

module Tilde  where

~ x = x + 2             -- huh?

~ x +++ y = y * 3       -- this makes sense

The (+++) equation makes sense: it's declaring an operator, using infix syntax, and using an irrefutable pattern match on the first argument.

The first 'equation' looks like the same to start with. But there's no operator. If I ask

λ> :i ~
===> <interactive>:1:1: error: parse error on input `~'

λ> :i (~)
===> class (a ~ b) => (~) (a :: k) (b :: k)
-- Defined in `Data.Type.Equality'
instance [incoherent] forall k (a :: k) (b :: k). (a ~ b) => a ~ b
-- Defined in `Data.Type.Equality'

which is a bemusing discovery, but nothing to do with it(?) I can't define my own class or operator (~) -- Illegal binding of built-in syntax, not surprisingly.

Oh:

λ> :i x
===> x :: Integer         -- GHCi defaulting, presumably

and trying to run x loops for ever. So the strangeness is actually defining

x = x + 2

Then what's the ~ doing?

Writing

x = 5

creates a global variable named x, bound to the value 5. Adding a tilde makes the pattern match irrefutable, but it was already irrefutable, so that doesn't make much sense. But it's legal to write something like

(xs, ys) = span odd [1..10]

This defines two global variables, xs and ys, containing all the odd numbers and all the even numbers between 1 and 10. You could even make this irrefutable if you want by adding a tilde. Of course, this pattern can't fail (if the expression is well-typed), so there's no point to that. But consider:

~(x:xs) = filter odd [1..10]

This defines two global variables, x and xs, if the filter returns at least one result. If the filter were to return zero results, the pattern match would fail. (In practice, this means that accessing x or xs would throw a pattern match failure exception.)

You can even write utterly bizarre stuff like

False = True

This seemingly nonsensical declaration pattern-matches the pattern False against the value True, and does nothing either way. It's one of those obscure corners of the language.

• (...but top-level bindings are already irrefutable anyway, so even in your examples the ~s are completely unnecessary.) – Daniel Wagner Apr 9 at 16:00
• @DanielWagner Really? Interesting... I didn't know that. – MathematicalOrchid Apr 9 at 17:41
• If they weren't, at what moment should they fail? @MathematicalOrchid – luqui Apr 9 at 17:46
• @luqui When you first try to use the binding, I suppose... Hmm, but that only works if they're irrefutable... I see your point. – MathematicalOrchid Apr 9 at 18:25
• OK so if I want to give an equation to define ~ as a (unary, prefix) operator, that would be (~) x = x + 2. ;-) – AntC Apr 10 at 3:01

The tilde is doing exactly what it did in your other example: it makes the pattern irrefutable (so the pattern match can not fail). The pattern already was irrefutable, of course, in both cases (being a plain variable, which always matches), but that doesn't make the tilde illegal, just unnecessary.

• Um? x is a niladic function, so what is (irrefutably) matching to what? I can't for example write an equivalent lambda expression. – AntC Apr 9 at 12:29
• @AntC It's not a function at all, it's an Integer, as you observed. You definitely can't write an equivalent lambda expression; all lambda expressions are functions. The pattern x matches any Integer, binding that Integer to the name x; so in ~x = x+2 the name x is bound to the expression x+2. – Daniel Wagner Apr 9 at 12:42
• @AntC Concepts like a "niladic function" are alien to Haskell. In Haskell, all functions take exactly one argument. – AJFarmar Apr 9 at 13:27
• @AntC let bindings are either pattern bindings, or function bindings (in case it's got some arguments). When there's no arguments, it's a pattern, either simple single-variable pattern (already irrefutable), or a more complex pattern like (a,b) = (1,2) or (x:xs) = [1..] or ~(x:xs) = []. – Will Ness Apr 9 at 13:55
• @AntC see 4.4.3 Function and Pattern Bindings in the report. – Will Ness Apr 9 at 14:06