Fundamentally, if class-type fields (or variables, array slots, etc.)
Y each hold a reference to a class object, there are two logical questions that
(Object)X.Equals(Y) can answer:
- If the reference in `Y` were copied to `X` (meaning the reference is copied), would the class have any reason to expect such a change to affect program semantics in any way (e.g. by affecting the present *or future* behavior of any members of `X` or `Y`)
- If *all* references to the target of `X` were instantaneously magically made to point to the target of `Y`, *and vice versa*`, should the class expect such a change to alter program behavior (e.g. by altering behavior of any member *other than an identity-based `GetHashCode`*, or by causing a storage location to refer to an object of incompatible type).
Note that if
Y refer to objects of different types, neither function may legitimately return true unless both classes know that there cannot be any storage locations holding a reference to one which could not also hold a reference to the other [e.g. because both types are private classes derived from a common base, and neither is ever stored in any storage location (other than
this) whose type can't hold references to both].
Object.Equals method answers the first question;
ValueType.Equals answers the second. The first question is generally the appropriate one to ask of object instances whose observable state may be mutated; the second is appropriate to ask of object instances whose observable state will not be mutated even if their types would allow it. If
Y each hold a reference to a distinct
int, and both arrays hold 23 in their first element, the first equality relation should define them as distinct [copying
Y would alter the behavior of
Y were modified], but the second should regard them as equivalent (swapping all references to the targets of
Y wouldn't affect anything). Note that if the arrays held different values, the second test should regard the arrays as distinct, since swapping the objects would mean
X would now report the value that
Y used to report).
There's a pretty strong convention that mutable types (other than
System.ValueType and its descendants) should override
Object.Equals to implement the first type of equivalence relation; since it's impossible for
System.ValueType or its descendants to implement the first relation, they generally implement the second. Unfortunately, there's no standard convention by which objects which override
Object.Equals() for the first kind of relation should expose a method which tests for the second, even though an equivalence relation could be defined which allowed comparison between any two objects of any arbitrary type. The second relation would be useful in the standard pattern wherein an immutable class
Imm holds a private reference to a mutable type
Mut but doesn't expose that object to any code that could actually mutate it [making the instance immutable]. In such a case, there's no way for class
Mut to know that an instance will never be written, but it would be helpful to have a standard means by which two instances of
Imm could ask the
Muts to which they hold references whether they would be equivalent if the holders of the references never mutated them. Note that the equivalence relation defined above makes no reference to mutation, nor to any particular means which
Imm must use to ensure that an instance won't be mutated, but its meaning is well-defined in any case. The object which holds a reference to
Mut should know whether that reference encapsulates identity, mutable state, or immutable state, and should thus be able to implement its own equality relation suitably.