Disclaimer: I have not yet used concepts, all I know about them was gleaned from the various proposals and cppreference, so take this answer with a grain of salt.
Rust Traits are used both for Compile-Time Polymorphism and, sometimes, Run-Time Polymorphism; Concepts are only about Compile-Time Polymorphism.
Structural vs Nominal.
The greatest difference between Concepts and Traits is that Concepts use structural typing whereas Traits use nominal typing:
- In C++ a type never explicitly satisfies a Concept; it may "accidentally" satisfy it if it happens to satisfy all requirements.
- In Rust a specific syntactic construct
impl Trait for Type is used to explicitly indicates that a type implements a Trait.
There are a number of consequences; in general Nominal Typing is better from a maintainability point of view -- adding a requirement to a Trait -- whereas Structural Typing is better a bridging 3rd party libraries -- a type from library A can satisfy a Concept from library B without them being aware of each other.
Traits are mandatory:
- No method can be called on a variable of a generic type without this type being required to implement a trait providing the method.
Concepts are entirely optional:
- A method can be called on a variable of a generic type without this type being required to satisfy any Concept, or being constrained in any way.
- A method can be called on a variable of a generic type satisfying a Concept (or several) without that method being specified by any Concept or Constraint.
- Constraints (see note) can be entirely ad-hoc, and specify requirements without using a named Concept; and once again, they are entirely optional.
Note: a Constraint is introduced by a
requires clause and specifies either ad-hoc requirements or requirements based on Concepts.
The set of expressible requirements is different:
- Concepts/Constraints work by substitution, so allow the whole breadth of the languages; requirements include: nested types/constants/variables, methods, fields, ability to be used as an argument of another function/method, ability to used as a generic argument of another type, and combinations thereof.
- Traits, by contrast, only allow a small set of requirements: associated types/constants, and methods.
Rust has no concept of ad-hoc overloading, overloading only occurs by Traits and specialization is not possible yet.
C++ Constraints can be used to "order" overloads from least specific to most specific, so the compiler can automatically select the most specific overload for which requirements are satisfied.
Note: prior to this, either SFINAE or tag-dispatching would be used in C++ to achieve the selection; calisthenics were required to work with open-ended overload sets.
How to use this feature is not quite clear to me yet.
The requirement mechanisms in Rust are purely additive (conjunctions, aka
&&), in contrast, in C++
requires clauses can contain disjunctions (aka