mirror of
https://github.com/italicsjenga/rp-hal-boards.git
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e3be4f8025
Bring in line with atsamd-hal GPIO v2 Copied as much as possible. Docs lifted mostly as-is. Also add sample BSP for the Feather RP2040 in boards/feather_rp2040 May include a few random fixes from currently futile attempt to get doctests working.
698 lines
24 KiB
Rust
698 lines
24 KiB
Rust
//! Module supporting type-level programming
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//!
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//! Copied from [atsamd-hal](https://github.com/atsamd-rs/atsamd).
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//!
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//! # Introduction
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//!
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//! Embedded software is often difficult to debug, so there is a strong
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//! motivation to catch as many bugs as possible at compile-time. However, the
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//! performance requirements of embedded software also make it difficult to
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//! justify changes that impose additional overhead in terms of size or speed.
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//! Ideally, we would like to add as many compile-time checks as possible, while
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//! also producing the fewest possible assembly instructions.
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//!
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//! The Rust type system can help accomplish this goal. By expressing software
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//! constraints within the type system, developers can enforce invariants at
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//! compile-time.
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//!
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//! Sometimes this is done using Rust macros. However, that approach can produce
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//! code that is difficult to read and understand. Moreover, macro-generated
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//! code can only be extended by *more* macros, which further spreads the
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//! problem. In `atsamd-hal` specifically, issue
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//! [#214](https://github.com/atsamd-rs/atsamd/issues/214) discussed the extent
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//! to which macros were once used in the repository.
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//!
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//! Alternatively, many of the same goals can be accomplished with the Rust
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//! type & trait system directly, which is quite powerful. In fact, it is
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//! [turing complete](https://sdleffler.github.io/RustTypeSystemTuringComplete/).
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//! By expressing our invariants entirely within the type system, we can encode
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//! the desired compile-time checks in a form that is easier to read, understand
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//! and document.
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//!
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//! This module documents some of the type-level programming techniques used
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//! throughout this HAL, and it contains a few items used to implement them.
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//!
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//! ## Contents
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//!
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//! - [Basics of type-level programming](#basics-of-type-level-programming)
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//! - [Type-level enums](#type-level-enums)
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//! - [Type classes](#type-classes)
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//! - [Type-level containers](#type-level-containers)
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//! - [Type-level functions](#type-level-functions)
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//! - [`OptionalKind` trait pattern](#optionalkind-trait-pattern)
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//! - [`AnyKind` trait pattern](#anykind-trait-pattern)
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//! - [Defining an `AnyKind` trait](#defining-an-anykind-trait)
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//! - [Using an `AnyKind` trait](#using-an-anykind-trait)
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//!
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//! # Basics of type-level programming
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//!
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//! Type-level programming aims to execute a form of compile-time computation.
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//! But to perform such computation, we need to map our traditional notions of
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//! programming to the Rust type system.
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//!
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//! In normal Rust, individual values are grouped or categorized into types. For
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//! example, `0`, `1`, `2`, etc. are all members of the `usize` type. Similarly,
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//! `Enum::A` and `Enum::B` are members of the `Enum` type, defined as
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//!
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//! ```ignore
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//! enum Enum { A, B }
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//! ```
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//!
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//! We use composite types and containers to create more complex data
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//! structures, and we use functions to map between values.
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//!
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//! All of these concepts can also be expressed within the Rust type system.
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//! However, in this case, types are grouped and categorized into traits. For
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//! instance, the [`typenum`](https://docs.rs/typenum/1.13.0/typenum/index.html)
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//! crate provides the types `U0`, `U1`, `U2`, etc., which are all members of
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//! the `Unsigned` trait. Similarly, the following sections will illustrate how
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//! to define type-level enums, containers and functions.
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//!
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//! ## Type-level enums
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//!
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//! Type-level enums are one of the foundational concepts of type-level
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//! programming used in this HAL.
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//!
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//! At the value-level, a typical Rust enum represents some set of variants that
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//! can be assigned to a particular variable. Similarly, a type-level enum
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//! represents some set of types that can be assigned to a particular type
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//! parameter.
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//!
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//! To lift an enum from the value level to the type level, you typically map
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//! the enum variants to types and the enum itself to a trait. For instance, the
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//! value-level enum
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//!
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//! ```ignore
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//! enum Enum {
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//! A,
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//! B,
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//! }
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//! ```
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//!
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//! would be mapped to the type level like so.
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//!
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//! ```ignore
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//! trait Enum {}
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//!
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//! enum A {}
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//! enum B {}
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//!
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//! impl Enum for A {}
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//! impl Enum for B {}
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//! ```
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//!
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//! At the value level, the variants `A` and `B` are grouped by the `Enum` type,
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//! while at the type level, the types `A` and `B` are grouped by the `Enum`
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//! trait.
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//!
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//! ## Type classes
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//!
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//! At the value-level, a type restricts the possible values that can be taken
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//! by some free variable. While at the type-level, a trait bound restricts the
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//! possible types that can be taken by some free type parameter. In effect,
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//! trait bounds can be used to create a kind of meta-type, or type class. The
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//! type-level enums in the previous section represent the most primitive
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//! application of the concept, but type classes can take other forms. The
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//! `OptionalKind` and `AnyKind` trait patterns discussed below are more
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//! advanced applications of the same concept.
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//!
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//! ## Type-level containers
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//!
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//! To represent more complex relationships, we need a way to form composite
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//! data structures at the type level.
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//!
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//! At the value level, a container holds an instance of a particular type. The
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//! exact value of that instance is usually not known to the author, it is only
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//! known at run-time.
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//!
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//! At the type level, we don't have the same notion of "run-time", but we do
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//! have two different notions of "compile-time" that form a similar
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//! relationship. There is compile time for the HAL authors, and there is a
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//! separate compile-time for the HAL users. We want to create a type-level
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//! container where the exact type is not known at author-time, but it is known
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//! at user-time.
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//!
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//! For example, take the following, value-level container struct. It contains
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//! two fields, `a` and `b`, of different types, `EnumOne` and `EnumTwo`.
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//!
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//! ```ignore
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//! struct Container {
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//! a: EnumOne,
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//! b: EnumTwo,
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//! }
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//! ```
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//!
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//! We can create an instance of this container with specific values.
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//!
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//! ```ignore
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//! let x = Container { a: EnumOne::VariantX, b: EnumTwo::VariantY };
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//! ```
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//!
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//! Next, suppose we had already translated `EnumOne` and `EnumTwo` to the type
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//! level using the technique in the previous section. If we wanted to create a
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//! similar, composite data structure at the type level, we could use type
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//! parameters in place of struct fields to represent the unknown types.
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//!
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//! ```ignore
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//! struct Container<A, B>
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//! where
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//! A: EnumOne,
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//! B: EnumTwo,
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//! {
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//! a: PhantomData<A>,
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//! b: PhantomData<B>,
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//! }
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//! ```
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//!
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//! And we could create an instance of this container with specific types.
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//!
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//! ```ignore
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//! type X = Container<VariantX, VariantY>;
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//! ```
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//!
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//! You might notice the use of `PhantomData` in the definition of the
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//! type-level container. Because it is geared more toward value-level
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//! programming, Rust requires all type parameters actually be used by the
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//! corresponding type. However, we don't need to "store" a type in the same way
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//! we store values. The compiler is responsible for tracking the concrete type
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//! for each type parameter. But the language still requires us to act as if we
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//! used each type parameter. `PhantomData` is the solution here, because it
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//! lets us make use of the type parameters without actually storing any values.
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//!
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//! Separately, `PhantomData` also allows us to create "instances" of types that
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//! normally can't be instantiated, like empty enums. For example, instances of
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//! `Enum` below can never exist directly.
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//!
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//! ```ignore
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//! enum Enum {}
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//! ```
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//!
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//! But instances of `PhantomData<Enum>` are perfectly valid. In this way,
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//! library authors can create types that only exist at the type level, which
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//! can sometimes simplify a design.
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//!
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//! ## Type-level functions
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//!
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//! To perform type-level computations, we need some way to map or transform
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//! types into other types.
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//!
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//! At the value level, functions and methods map values of the input types to
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//! values of the output types. The same can be accomplished at the type level
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//! using traits and associated types. Type-level functions are implemented as
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//! traits, where the implementing type and any type parameters are the inputs,
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//! and associated types are the outputs.
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//!
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//! For example, consider the value level `not` method below.
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//!
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//! ```ignore
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//! enum Bool {
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//! False,
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//! True,
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//! }
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//!
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//! impl Bool {
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//! fn not(self) -> Self {
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//! use Bool::*;
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//! match self {
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//! True => False,
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//! False => True,
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//! }
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//! }
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//! }
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//! ```
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//!
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//! We can translate this example to the type level like so.
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//!
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//! ```ignore
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//! trait Bool {}
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//!
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//! enum True {}
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//! enum False {}
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//!
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//! impl Bool for True {}
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//! impl Bool for False {}
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//!
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//! trait Not: Bool {
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//! type Result: Bool;
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//! }
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//!
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//! impl Not for True {
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//! type Result = False;
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//! }
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//!
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//! impl Not for False {
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//! type Result = True;
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//! }
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//! ```
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//!
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//! We can use the `Not` trait bound to transform one type to another. For
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//! instance, we can create a container that accepts one type parameter but
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//! stores a different one.
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//!
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//! ```ignore
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//! struct Container<B: Not> {
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//! not: PhantomData<B::Result>;
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//! }
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//! ```
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//!
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//! Alternatively, we could redefine the trait and declar a corresponding type
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//! alias as
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//!
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//! ```ignore
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//! trait NotFunction: Bool {
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//! type Result: Bool;
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//! }
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//!
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//! type Not<B> = <B as NotFunction>::Result;
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//! ```
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//!
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//! Doing so would allow us to us reframe the last example as
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//!
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//! ```ignore
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//! struct Container<B: NotFunction> {
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//! not: PhantomData<Not<B>>;
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//! }
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//! ```
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//!
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//! Type-level functions can be more complicated than this example, but they
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//! ultimately represent a mapping from a set of input types (the implementing
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//! type and any type parameters) to a set of output types (the associated
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//! types).
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//!
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//! # `OptionalKind` trait pattern
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//!
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//! As mentioned above, traits can be used to define a kind of meta-type or type
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//! class, essentially forming a set of valid types for a given type parameter.
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//! They also represent the concept of types lifted from the value level to the
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//! type level.
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//!
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//! What if we want to define a type class representing either a set of useful
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//! types or some useless, null type? Essentially, how do we take the notion of
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//! an [`Option`] type and raise it to the type level?
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//!
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//! Suppose we have some existing type class, defined by the `Class` trait, that
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//! we want to make optional. We can define a new type class that includes all
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//! instances of `Class` as well as some null type. For the latter we use
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//! [`NoneT`], defined in this module.
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//!
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//! ```ignore
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//! trait OptionalClass {}
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//!
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//! impl OptionalClass for NoneT {}
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//! impl<C: Class> OptionalClass for C {}
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//! ```
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//!
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//! We can use this new type class to store an optional instance of a `Class`
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//! type in a struct.
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//!
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//! ```ignore
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//! struct Container<C: OptionalClass> {
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//! class: PhantomData<C>,
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//! }
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//! ```
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//!
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//! And we can restrict some of its methods to only operate on instances with a
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//! valid `Class`.
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//!
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//! ```ignore
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//! impl<C: Class> Container<C> {
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//! fn method(self) { ... }
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//! }
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//! ```
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//!
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//! Although it is not strictly necessary, we can also introduce a new type
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//! class to differentiate the bare usage of `Class` from instances of some
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//! `Class` where an `OptionalClass` is accepted.
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//!
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//! ```ignore
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//! trait SomeClass: OptionalClass + Class {}
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//!
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//! impl<C: Class> SomeClass for C {}
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//! ```
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//!
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//! This new trait doesn't add any new information, but it can still help
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//! readers understand that a particular type parameter is restricted to an
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//! instances of `Class` when an `OptionalClass` could be accepted.
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//!
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//! Note that when `Class` and `OptionalClass` contain associated types, name
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//! clashes may occur when using `SomeClass` as a trait bound. This can be
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//! avoided by removing the `OptionalClass` super trait from `SomeClass`.
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//! Ultimately, it is redundant anyway, because any implementer of `Class` also
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//! implements `OptionalClass`.
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//!
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//! # `AnyKind` trait pattern
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//!
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//! The `AnyKind` trait pattern allows you to encapsulate types with multiple
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//! type parameters and represent them with only a single type parameter. It
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//! lets you introduce a layer of abstraction, which can simplify interfaces and
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//! make them more readable. But most of all, it does so without sacrificing any
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//! of our normal, type-level abilities.
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//!
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//! ## Defining an `AnyKind` trait
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//!
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//! Suppose you had a composite, type-level data structure. For example, the
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//! GPIO `Pin` struct contains instances of two type-level enums, a `PinId` and
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//! a `PinMode`. It looks something like this.
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//!
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//! ```ignore
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//! struct Pin<I: PinId, M: PinMode> {
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//! // ...
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//! }
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//! ```
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//!
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//! Rust does not provide any way to speak about a `Pin` generally. Any mention
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//! of the `Pin` type must also include its type parameters, i.e. `Pin<I, M>`.
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//! This is not a deal-breaker, but it is less than ideal for type-level
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//! programming. It would be nice if there were a way to succinctly refer to any
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//! `Pin`, regardless of its type parameters.
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//!
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//! We've seen above that we can use traits to form a type class. What if we
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//! were to introduce a new trait to label all instances of `Pin`? It would look
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//! something like this.
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//!
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//! ```ignore
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//! trait AnyPin {}
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//!
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//! impl<I: PinId, M: PinMode> AnyPin for Pin<I, M> {}
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//! ```
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//!
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//! Now, instead of refering to `Pin<I, M>`, we can refer to instances of the
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//! `AnyPin` type class.
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//!
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//! ```ignore
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//! fn example<P: AnyPin>(pin: P) { ... }
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//! ```
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//!
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//! Unfortunately, while this is more ergonomic, it is not very useful. As
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//! authors of the code, we know that `AnyPin` is only implemented for `Pin`
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//! types. But the compiler doesn't know that. Traits in Rust are open, so the
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//! compiler must consider that `AnyPin` could be implemented for other types.
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//!
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//! As a consequence, the compiler knows very little about the type `P` in the
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//! function above. In fact, because the `AnyPin` trait is completely empty, the
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//! compiler knows *absolutely nothing* about the type `P`.
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//!
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//! Is there a way to make the `AnyPin` trait more useful? We can see from the
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//! current implementation that we are throwing away information.
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//!
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//! ```ignore
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//! impl<I: PinId, M: PinMode> AnyPin for Pin<I, M> {}
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//! ```
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//!
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//! The implementation of `AnyPin` is identical for every `Pin`, regardless of
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//! the type parameters `I` and `M`, which erases that information. Instead, we
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//! could choose to save that information in the form of associated types.
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//!
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//! Let's redesign the `AnyPin` trait to record the `PinId` and `PinMode`.
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//!
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//! ```ignore
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//! trait AnyPin {
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//! type Id: PinId;
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//! type Mode: PinMode;
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//! }
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//!
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//! impl<I: PinId, M: PinMode> AnyPin for Pin<I, M> {
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//! type Id = I;
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//! type Mode = M;
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//! }
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//! ```
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//!
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//! This is better. When `P` implements `AnyPin`, we can at least recover the
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//! corresponding `PinId` and `PinMode` types. However, `AnyPin` still doesn't
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//! include any trait methods nor any super traits, so the compiler won't allow
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//! us to do anything useful with an instances of `P`.
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//!
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//! We need some way to tell the compiler that when `P` implements `AnyPin`,
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//! it is equivalent to saying `P` is exactly `Pin<P::Id, P::Mode>`.
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//! Essentially, we want to take a generic type parameter `P` and treat it as if
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//! it were an instance of a specific `Pin` type.
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//!
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//! We can start by defining a trait alias to recover the specific `Pin` type.
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//!
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//! ```ignore
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//! type SpecificPin<P> = Pin<<P as AnyPin>::Id, <P as AnyPin>::Mode>;
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//! ```
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//!
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//! With this new definition, we can rephrase our statement above. We need some
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//! way to tell the compiler that when `P` implements `AnyPin`,
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//! `P == SpecificPin<P>`. There's no way to do that exactly, but we can come
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//! close with some useful trait bounds: [`From`], [`Into`], [`AsRef`] and
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//! [`AsMut`].
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//!
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//! ```ignore
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//! trait AnyPin
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//! where
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//! Self: From<SpecificPin<Self>>,
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//! Self: Into<SpecificPin<Self>>,
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//! Self: AsRef<SpecificPin<Self>>,
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//! Self: AsMut<SpecificPin<Self>>,
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//! {
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//! type Id: PinId;
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//! type Mode: PinMode;
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//! }
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//! ```
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//!
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//! Now we've given the compiler some useful information. When a type implements
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//! `AnyPin`, it can be converted from and into instances of `Pin`. And
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//! references to types that implement `AnyPin` can be converted into references
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//! to `Pin`s.
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//!
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//! ```ignore
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//! fn example<P: AnyPin>(mut any_pin: P) {
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//! // None of the type annotations here are necessary
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//! // Everything can be inferred
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//! // Remember that SpecificPin<P> is Pin<P::Id, P::Mode>
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//! let pin_mut: &mut SpecificPin<P> = any_pin.as_mut();
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//! let pin_ref: &SpecificPin<P> = any_pin.as_ref();
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//! let pin: SpecificPin<P> = any_pin.into();
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//! }
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//! ```
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//!
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//! Finally, to simplify this pattern, we can gather all of the super trait
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//! bounds into a single, reusable trait.
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//!
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//! ```ignore
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//! trait Is
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//! where
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//! Self: From<IsType<Self>>,
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//! Self: Into<IsType<Self>>,
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//! Self: AsRef<IsType<Self>>,
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//! Self: AsMut<IsType<Self>>,
|
|
//! {
|
|
//! type Type;
|
|
//! }
|
|
//!
|
|
//! type IsType<T> = <T as Is>::Type;
|
|
//!
|
|
//! impl<T: AsRef<T> + AsMut<T>> Is for T {
|
|
//! type Type = T;
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! And we can rewrite our `AnyPin` trait as
|
|
//!
|
|
//! ```ignore
|
|
//! trait AnyPin: Is<Type = SpecificPin<Self>> {
|
|
//! type Id: PinId;
|
|
//! type Mode: PinMode;
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! ## Using an `AnyKind` trait
|
|
//!
|
|
//! If a type takes multiple type parameters, storing it within a container
|
|
//! requires repeating all of the corresponding type parameters. For instance,
|
|
//! imagine a container that stores two completely generic `Pin` types.
|
|
//!
|
|
//! ```ignore
|
|
//! struct TwoPins<I1, I2, M1, M2>
|
|
//! where
|
|
//! I1: PinId,
|
|
//! I2: PinId,
|
|
//! M1: PinMode,
|
|
//! M2: PinMode,
|
|
//! {
|
|
//! pin1: Pin<I1, M1>,
|
|
//! pin2: Pin<I2, M2>,
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! This struct has already ballooned to four type parameters, without even
|
|
//! doing much useful work. Given its heavy use of type parameters, this
|
|
//! limitation can make type-level programming tedious, cumbersome and
|
|
//! error-prone.
|
|
//!
|
|
//! Instead, we can use the `AnyKind` trait pattern to encapsulate each `Pin`
|
|
//! with a single type parameter.
|
|
//!
|
|
//! ```ignore
|
|
//! struct TwoPins<P1, P2>
|
|
//! where
|
|
//! P1: AnyPin,
|
|
//! P2: AnyPin,
|
|
//! {
|
|
//! pin1: P1,
|
|
//! pin2: P2,
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! The result is far more readable and generally more comprehensible. Moreover,
|
|
//! although we no longer have direct access to the `PinId` and `PinMode` type
|
|
//! parameters, we haven't actually lost any expressive power.
|
|
//!
|
|
//! In the first version of `TwoPins`, suppose we wanted to implement a method
|
|
//! for pins in `FloatingInput` mode while simultaneously restricting the
|
|
//! possible `PinId`s based on some type class. The result might look like
|
|
//! this.
|
|
//!
|
|
//! ```ignore
|
|
//! impl<I1, I2> for TwoPins<I1, I2, FloatingInput, FloatingInput>
|
|
//! where
|
|
//! I1: PinId + Class,
|
|
//! I2: PinId + Class,
|
|
//! {
|
|
//! fn method(&self) {
|
|
//! // ...
|
|
//! }
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! The same method could be expressed with the `AnyPin` approach like so
|
|
//!
|
|
//! ```ignore
|
|
//! impl<P1, P2> for TwoPins<P1, P2>
|
|
//! where
|
|
//! P1: AnyPin<Mode = FloatingInput>,
|
|
//! P2: AnyPin<Mode = FloatingInput>,
|
|
//! P1::Id: Class,
|
|
//! P2::Id: Class,
|
|
//! {
|
|
//! fn method(&self) {
|
|
//! // ...
|
|
//! }
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! This example demonstrates the simultaneous readability and expressive power
|
|
//! of the `AnyKind` pattern.
|
|
//!
|
|
//! However, remember that when working with a type `P` that implements
|
|
//! `AnyPin`, the compiler can only use what it knows about the `AnyPin` trait.
|
|
//! But all of the functionality for GPIO pins is defined on the `Pin` type. To
|
|
//! make use of a generic type `P` implementing `AnyPin`, you must first convert
|
|
//! it to its corresponding `SpecificPin` using [`Into`], [`AsRef`] or
|
|
//! [`AsMut`]. And, in some instances, you may also need to convert back to the
|
|
//! type `P`.
|
|
//!
|
|
//! Suppose you wanted to store a completely generic `Pin` within a struct.
|
|
//!
|
|
//! ```ignore
|
|
//! pub struct Example<P: AnyPin> {
|
|
//! pin: P,
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! Next, suppose you want to create a method that would take the `Pin` out of
|
|
//! the struct, perform some operations in different `PinMode`s, and put it back
|
|
//! into the struct before returning. The `elided` method below shows such an
|
|
//! example. However, it can be a bit tricky to follow all of the type
|
|
//! conversions here. For clarity, the `expanded` method shows the same behavior
|
|
//! with each transformation given its proper type annotation.
|
|
//!
|
|
//! ```ignore
|
|
//! impl<P: AnyPin> Example<P> {
|
|
//! pub fn elided(mut self) -> Self {
|
|
//! let pin = self.pin.into();
|
|
//! let mut pin = pin.into_push_pull_output();
|
|
//! pin.set_high().ok();
|
|
//! let pin = pin.into_floating_input();
|
|
//! let _bit = pin.is_low().unwrap();
|
|
//! let pin = pin.into_mode();
|
|
//! self.pin = pin.into();
|
|
//! self
|
|
//! }
|
|
//! pub fn expanded(mut self) -> Self {
|
|
//! let pin: SpecificPin<P> = self.pin.into();
|
|
//! let mut pin: Pin<P::Id, PushPullOutput> = pin.into_push_pull_output();
|
|
//! pin.set_high().ok();
|
|
//! let pin: Pin<P::Id, FloatingInput> = pin.into_floating_input();
|
|
//! let _bit = pin.is_low().unwrap();
|
|
//! let pin: SpecificPin<P> = pin.into_mode::<P::Mode>();
|
|
//! self.pin = pin.into();
|
|
//! self
|
|
//! }
|
|
//! }
|
|
//! ```
|
|
//!
|
|
//! Notice that it is not enough to simply put back the correct `SpecificPin`.
|
|
//! Even though the `SpecificPin` implements
|
|
//! `AnyPin<Id = P::Id, Mode = P::Mode>` the compiler doesn't understand that
|
|
//! `SpecificPin<P> == P` for all `P`. As far as the compiler is concerned,
|
|
//! there could be several different types that implement
|
|
//! `AnyPin<Id = P::Id, Mode = P::Mode>`. Instead, the compiler requires that
|
|
//! you put back an instance of `P` exactly. The final use of [`Into`] is key
|
|
//! here. It transforms the `SpecificPin` back into `P` itself.
|
|
|
|
mod private {
|
|
/// Super trait used to mark traits with an exhaustive set of
|
|
/// implementations
|
|
pub trait Sealed {}
|
|
}
|
|
|
|
pub(crate) use private::Sealed;
|
|
|
|
/// Type-level version of the [None] variant
|
|
#[derive(Default)]
|
|
pub struct NoneT;
|
|
impl Sealed for NoneT {}
|
|
|
|
/// Marker trait for type identity
|
|
///
|
|
/// This trait is used as part of the [`AnyKind`] trait pattern. It represents
|
|
/// the concept of type identity, because all implementors have
|
|
/// `<Self as Is>::Type == Self`. When used as a trait bound with a specific
|
|
/// type, it guarantees that the corresponding type parameter is exactly the
|
|
/// specific type. Stated differently, it guarantees that `T == Specific` in
|
|
/// the following example.
|
|
///
|
|
/// ```ignore
|
|
/// where T: Is<Type = Specific>
|
|
/// ```
|
|
///
|
|
/// Moreover, the super traits guarantee that any instance of or reference to a
|
|
/// type `T` can be converted into the `Specific` type.
|
|
///
|
|
/// ```ignore
|
|
/// fn example<T>(mut any: T)
|
|
/// where
|
|
/// T: Is<Type = Specific>,
|
|
/// {
|
|
/// let specific_mut: &mut Specific = any.as_mut();
|
|
/// let specific_ref: &Specific = any.as_ref();
|
|
/// let specific: Specific = any.into();
|
|
/// }
|
|
/// ```
|
|
///
|
|
/// [`AnyKind`]: #anykind-trait-pattern
|
|
pub trait Is
|
|
where
|
|
Self: Sealed,
|
|
Self: From<IsType<Self>>,
|
|
Self: Into<IsType<Self>>,
|
|
Self: AsRef<IsType<Self>>,
|
|
Self: AsMut<IsType<Self>>,
|
|
{
|
|
#[allow(missing_docs)]
|
|
type Type;
|
|
}
|
|
|
|
/// Type alias for [`Is::Type`]
|
|
pub type IsType<T> = <T as Is>::Type;
|
|
|
|
impl<T> Is for T
|
|
where
|
|
T: Sealed + AsRef<T> + AsMut<T>,
|
|
{
|
|
type Type = T;
|
|
}
|