I am trying to build an inductive type for cobordism using Coq in such way that some properties of cobordism (1-groupoid and 2-groupoid) can be proved. I am using the following Coq code:

```
Unset Automatic Introduction.
Inductive Topo : Set := t | nt.
Definition F (i j : Topo) :=
match i, j with
| t, t => t
| t, nt => nt
| nt, t => nt
| nt, nt => nt
end.
```

I am considering two kinds of topologies for the cobordisms : trivial (t) and nontrivial (nt). The trivial cobordisms is the cylinder considered like the unit in the 1-groupoid. The function F gives the composition of topologies.

The inductive type of cobordism is assumed as:

```
Inductive cobordisms {A} : A -> A -> Topo -> Type := idcobordism : forall
x : A, cobordisms x x t.
```

with the tactics:

```
Hint Resolve @idcobordism.
Ltac cobordism_induction :=
intros; repeat progress (
match goal with
| [ p : cobordisms _ _ _ |- _ ] => induction p
| _ => idtac
end
); auto.
```

The composition of cobordisms is introduced according with:

```
Definition concat {A} {x y z : A} {i j : Topo} : cobordisms x y i -> cobordisms y z j
-> cobordisms x z (F i j) .
Proof.
cobordism_induction.
Defined.
Notation "p @ q" := (concat p q) (at level 60).
```

The inverse of a given cobordism is defined by:

```
Definition opposite {A} {x y : A} {i : Topo} : cobordisms x y i -> cobordisms y x i .
Proof.
cobordism_induction.
Defined.
Notation "! p" := (opposite p) (at level 50).
```

Until now all is okay. But when I am trying to prove the firs property of the 1-groupid, namely, left unity:

```
Lemma idcobordism_left_unit A (x y : A) (i : Topo) (p : cobordisms x y i) :
(idcobordism x) @ p = p.
```

I am obtaining the following error message:

```
Error: In environment
A : Type
x : A
y : A
i : Topo
p : cobordisms x y i
The term "p" has type "cobordisms x y i" while it is expected to have type
"cobordisms x y (F t i)".
```

Then my question is, how to make that Coq consider that `(F t i)`

is equivalent to `i`

for all `i`

according with the previous definition of `F`

?