Crate higher

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higher

The functor hierarchy and other terrible ideas for Rust.

Yes, this gives you generalisable monads in Rust. No, they’re not very nice compared to Haskell, because Rust’s functions aren’t quite as first class from the type system’s perspective as you might like them to be, type constraints in trait implementations can be a serious headache when you want to implement, say, Functor for HashSet, and the type system can be particularly obtuse at times and need a lot of additional and extremely verbose guidance to get the type inference right, but they exist now.

What you get from this:

A set of fine grained traits (Functor, Pure, Apply, Bind, Applicative and Monad) for functors, applicatives and monads, inspired by PureScript and Scala’s Cats.
Bifunctors, contravariant functors and profunctors, for completeness.
The run! macro for Haskell style do notation. I’d have preferred to call it do! or for! but unfortunately those are reserved keywords, even for macros.
Derive macros for Functor and Bifunctor.
Semigroups and monoids, because Rust’s Add isn’t quite a semigroup so Add + Default isn’t quite a monoid.
Effect monads that wrap standard Futures and IO monads that wrap futures that can fail.
Most of Foldable, with the ambition of some of Traversable to follow. (It’s always traverse.)
Rings and algebras, just in case.
Not necessarily a lot of good documentation, but like any good Haskell programmer you should be able to immediately infer every function’s purpose from its type signature.

What are your intentions with this?

I wrote this for two reasons: first, to see if it was even possible, and second, as a shitpost with some extremely elaborate type signatures. If you think this is actually useful (and I’m mildly horrified to find that I’m starting to think it might be), you may wish to step up to help maintain it, because I doubt I’ll keep giving it much attention once the novelty wears off.

Licence

This software is subject to the terms of the Mozilla Public License, v. 2.0. If a copy of the MPL was not distributed with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

Code of Conduct

Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms.

Modules

Macros

run

Monadic do notation.

Traits

Applicative

An Applicative functor is anything which implements Functor, Apply and Pure.

Apply

Apply takes an F<Fn(A) -> B> (or, rather, an F<ApplyFn<'a,A, B>> specifically) and applies it to an F<A> to produce an F<B>.

Bifunctor

A Bifunctor lets you change the types of a generic type with two type parameters.

Bind

Bind lets you chain computations together.

Contravariant

A Contravariant functor.

Foldable

Functor

A Functor lets you change the type parameter of a generic type.

Monad

A Monad is like a burrito, and also anything which implements Bind and Applicative.

Monoid

A Monoid consists of a Semigroup and an empty value (the Default trait) plus the following laws:

Profunctor

A Profunctor is just a Bifunctor that is contravariant over its first argument and covariant over its second argument. What’s the problem?

Pure

Pure lets you construct a value of type F<A> from a single value of A.

Semigroup

A Semigroup is a type with an associative operation. In plain terms, this means you can take two values of this type and add them together into a different value of the same type. The most obvious example of this is addition of numbers: 2 + 2 = 4, another is string concatenation: "Hello " + "Joe" = "Hello Joe".

Derive Macros

Bifunctor

Functor