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by kmill
343 days ago
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In Lean's parsed `Syntax`, binders are plain identifiers. The way this works is that identifiers can be annotated with the module it was parsed in as well as a "macro scope", which is a number that's used to make identifiers created by macros be distinct from any previously created identifiers (the current macro scope is some global state that's incremented whenever a macro is being expanded) — an identifier with this annotation is called a hygienic identifier, and when identifiers are tested for equality the annotations are tested too. With this system in place, there's nothing special you need to do to elaborate binders (and it also lets you splice together syntaxes without any regard for hygiene!). For example, `fun x => b x` elaborates by (1) adding a variable `x` to the local scope, (2) elaborating `b x` in that scope, and then (3) abstracting `x` to make the lambda. The key here is that `x` is a hygienic identifier, so an `x` that's from a different module or macro scope won't be captured by the binder `x`. Yes you can define the syntax that's in the article in Lean. A version of this is the Mathlib `notation3` command, but it's for defining notation rather than re-using the function name (e.g. using a union symbol for `Set.iUnion`), and also the syntax is a bit odd:
notation3 "⋃ "(...)", "r:60:(scoped f => iUnion f) => r The ideas in the article are neat, and I'll have to think about whether it's something Lean could adopt in some way... Support for nested binders would be cool too. For example, I might be able to see something like `List.all (x in xs) (y in ys) => x + y < 10` for `List.all (fun x => List.all (fun y => x + y < 10) ys) xs`. |
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