One type of operation which is guaranteed not to be available with a mutable class and may sometimes be available with a mutable struct is the ability to copy the state of a thing using the assignment operator. Using mutating interfaces with structures is tricky, since attempting to use a mutating interface on a structure in a read-only context will yield code that compiles cleanly but does not work (I really wish compilers would recognize an attribute on struct and interface members that would indicate that they should not be usable on read-only structures). Nonetheless, there are some contexts where such a thing can be useful.
For example, if an algorithm required the ability to store the state of an enumerator and revert the enumerator to its saved state, and if the enumerator was a generic type
TEnum constrained to both
IEnumerator<T>, it may be possible to copy theTEnum
to a local variable of that type and then later copy it back. Note that this would work with some but not allstruct
types which implementIEnumerable
; such a technique should in practice probably only be used with interfaces that explicitly document a requirement that all legitimate struct-type implementations must exhibit value semantics (IEnumerator` does not have such a documented requirement).
Note that the fact that code may use the ability to copy structs by value when it exists, that does preclude the possibility of a slightly-different (perhaps less-efficient) method using a class-type implementation of the interface. The function signatures:
void ActOnSequence<T>(T theEnumerator) where T:struct, IEnumerator<String>;
void ActOnSequence(IEnumerator<String> theEnumerator);
can co-exist and be used without difficulty. The former will be invoked on value-type implementations of the interface, while the latter will be invoked on heap-type implementations. Note that without the
struct constraint, it would not be possible to have both of the above methods in scope and have the correct method invoked automatically.