Let's consider a type t and two variables x,y of type t.
Will the call compare x y be valid for any type t? I couldn't find any counterexample.
The polymorphic compare function works by recursively exploring the structure of values, providing an ad-hoc total ordering on OCaml values, used to define structural equality tested by the polymorphic = operator.
It is, by design, not defined on functions and closures, as observed by @antron. The recursive nature of the definition implies that structural equality is not defined on values containing a function or a closure. This recursive nature also imply that the compare function is not defined on recursive values, as mentioned by a @antron as well.
Structural equality, and therefore the compare function and the comparison operators, is not aware of structure invariants and cannot be used to compare (mildly) advanced data structures such as Sets, Maps, HashTbls and so on. If comparison of these structures is desired, a specialised function has to be written, this is why Set and Map define such a function.
When defining your own structures, a good rule of thumb is to distinguish between
concrete types, which are defined only in terms of primitive types and other concrete types. Concrete types should not be used for structures whose processing expects some invariants, because it is easy to create arbitrary values of this type breaking these invariants. For these types, the polymorphic comparison function and operators are appropriate.
abstract types, whose concrete definition is hidden. For these types, it is best to provide specialised comparison function. The mixture library defines a compare mixin that can be used to derive comparison operators from the implementation of a specialised compare function. Its use is illustrated in the README.
answered Jan 5 '16 at 8:37
Michael Le Barbier GrünewaldMichael Le Barbier Grünewald
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It doesn't work for function types:
# compare (fun x -> x) (fun x -> x);;
Exception: Invalid_argument "equal: functional value".
Likewise, it won't (generally) work for other types whose values can contain functions:
# type t = A | B of (int -> int);;
type t = A | B of (int -> int)
# compare A A;;
- : int = 0
# compare (B (fun x -> x)) A;;
- : int = 1
# compare (B (fun x -> x)) (B (fun x -> x));;
Exception: Invalid_argument "equal: functional value".
It also doesn't (generally) work for recursive values:
# type t = {self : t};;
type t = { self : t; }
# let rec v = {self = v};;
val v : t = {self = <cycle>}
# let rec v' = {self = v'};;
val v' : t = {self = <cycle>}
# compare v v;;
- : int = 0
# compare v v';;
(* Does not terminate. *)
These cases are also listed in the documentation for compare in Pervasives.
-
4Also the polymorphic
compareand=do not “work” for values that can have different representations, for instance types resulting from the application ofSetorMap. – Pascal Cuoq Dec 29 '15 at 16:38 -
It doesn't really work for objects either. It compares the unique numeric ID of each object. So the comparison of two objects that are physically distinct such as
compare (object end) (object end)never returns 0. – Martin Jambon Dec 29 '15 at 19:52 -
@PascalCuoq, MartinJambon: But that depends on your definition of "work". They never guaranteed it would follow your concept of equality. It just need to follow some (unspecified) consistent ordering. – newacct Dec 29 '15 at 22:49
