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Consider the following Coq program:

Inductive foo : nat -> Type :=
| nil : foo 0
| succ{n:nat} : foo n -> foo n.

Fixpoint bar {n:nat}(A:foo n)(B:foo n) : Prop :=
  match B with
  | nil => False
  | succ C => bar A C
  end.

Coq complains on the definition of bar:

In environment
bar : forall n : nat, foo n -> foo n -> Prop
n : nat
A : foo n
B : foo n
n0 : nat
C : foo n0
The term "C" has type "foo n0" while it is expected to have type "foo n".

But for B : foo n to be a succ C, C must also be a foo n. Why can't Coq infer this, and how can I fix the definition of bar?

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When you match on B, the type system "forgets" that the new n' inside B's type is the same as n. There is a trick to add that information to the context (there are many ways, plugins, etc. but it is good to know how to do it "by hand"). It is called "The convoy pattern" by Adam Chlipala and every coq user must post a question about that once in his/her life (your's truly included).

You make the body be not just a value but a function that takes an additional input with the type n=n' and adds an eq_refl term at the end. This plays well with how Coq's type system can break down terms.

You can either rewrite the A type to change its type from foo n to foo n' with tactics, like this:


Fixpoint bar (n:nat) (A:foo n) (B:foo n) : Prop.
  refine (
  match B in (foo m) return  (n=m -> _) with
  | nil => fun _ =>  False
  | @succ n' B' => fun (E : n = n') => bar n' _ B'
  end  eq_refl).
  rewrite E in A.
  apply A.
Defined.

or directly with eq_rect

Fixpoint bar {n:nat} (A:foo n) (B:foo n) : Prop :=
  match B in (foo m) return  (n=m -> _) with
  | nil => fun _ =>  False
  | succ B' => fun E => bar (eq_rect _ _ A _ E) B'
  end  eq_refl.

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