# Define a function based on a relation in Coq

I'm working on a theory in which there is a relation C defined as

``````Parameter Entity: Set.
Parameter C : Entity -> Entity -> Entity -> Prop.
``````

The relation C is a relation of composition of some entities. Instead of `C z x y`, I want to be able to write `x o y = z`. So I have two questions:

• I think I should define a "function" (the word is perhaps not the right one) named fC that takes x and y and returns z. This way, I could use it in the Notation. But I don't know how to define this "function". Is it possible?
• I find that I can use the command `Notation` to define an operator. Something like `Notation "x o y" := fC x y.`. Is this the good way to do it?

I tried `Notation "x o y" := exists u, C u x y.` but it didn't work. Is there a way to do what I want to do?

Unless your relation `C` has the property that, given `x` and `y`, there is a unique `z` such that `C z x y`, you cannot view it as representing a full-fledged function the way you suggest. This is why the notion of a relation is needed in that case.

As for defining a notation for the relation property, you can use:

``````Notation "x 'o y" := (exists u, C u x y) (at level 10).
``````

Note the `'` before the `o` to help the parser handle the notation and the parentheses after the `:=` sign. The level can be changed to suit your parsing preferences.

• I thought about it, but I forgot to mention it. There is an axiom of uniqueness in the theory. Apr 1 at 23:55
• If you don't have an explicit, constructive way to define `fC`, you can always add another axiom, as suggested by Pierre. A simple version could be:: `Axiom functionalC : exists fC, forall x y z, C x y z <-> fC x y = z`. Then you can use that in your proofs to go back and forth between the functional and relational points of view. `. Apr 2 at 8:36
• In Coq FAQ you have a useful list of axioms which can safely added to Coq. In general, admitting a new ad-hoc axiom may make a development inconsistent. Apr 2 at 10:18

If you define `x 'o y` as a proposition, you will lose the intuition of `o` being a binary operation on `Entity` (i.e `x `o `y` should have type `Entity`).

You may write some variation like

``````Notation "x 'o y '= z" := (unique (fun t => C t x y)) (at level 10).
``````

``````Hypothesis C_fun: forall x y,  {z : Entity | unique  (fun t => C t x y) z}.
``````Notation "x 'o y" := (proj1_sig (C_fun x y)) (at level 10).
Otherwise (if you have only have a weaker version of `C_fun`, with `exists`instead of `sig`) and accept to use classical logic and axioms), you may use the `Epsilon` operator https://coq.inria.fr/distrib/current/stdlib/Coq.Logic.ClassicalEpsilon.html