It may be helpful to think of each class-type storage location (a variable of type
object or any other class type would qualify as such) as holding "object IDs", rather than holding objects [the term "reference" has a number of meanings; the term "object ID" would avoid that ambiguity]. Because there isn't really much one can do with an object ID, but there myriad things one may want to do with the object referred to by an ID, in many .net languages, applying the
. operator to an object ID will access a member of the object referred to by that ID.
Note that object IDs have no textual representation, but conceptually it may be useful to assign them arbitrary numbers. Suppose
Car is a class type, and
FordFocus is a class type which derives from it. A statement
Car Fred = new FordFocus();
will pick an unused object ID (let's say it picks #42), generate a new instance of the FordFocus class with that ID, and store that ID in
Fred. Note that
Fred cannot and does not hold an instance of
FordFocus, nor an instance of
Car. Instead, all it can hold is an object ID which, if it identifies anything, is guaranteed to identify an instance of either
Car or a class derived therefrom; in this particular scenario, it holds #42. If code then says:
Object Barney = Fred;
the code will check to see whether any object ID that might be stored in Fred could safely be stored in Barney, determine that it can, and proceed to set Barney to #42.
If code then says
Fred.Color = Blue;
the code won't actually affect
Fred (which held "#42" before the statement, and will continue to hold "#42" after), but it will affect object #42--turning it into a blue car.
At that point, if code says:
Fred = new HyundaiSonata();
the system would generate a new ID (e.g. #57), create an instance of HyundaiSonata with that ID, and store #57 into Fred. That statement would overwrite the value in Fred (it used to hold #42, but now it holds #57) but it would have no effect on Object #42 (which would still be a blue FordFocus).