```
Inductive my_type :=
| Type_pol : Z -> my_type
| Type_matrix : Z -> my_type.
Inductive redPair :=
| RedPair_interpretation : my_type -> redPair.
Inductive orderingProof :=
| OrderingProof_redPair : redPair -> orderingProof.
Inductive trsTerminationProof :=
| TrsTerminationProof_ruleRemoval :
orderingProof -> trsTerminationProof -> trsTerminationProof.
```

I want to write a function that

```
Definition return_mytype (t : my_type) : option nat :=
match t with
| Type_pol _ => None
| Type_matrix i => Some (Z.to_nat i)
end.
Definition return_redPair (r : redPair ) : option nat :=
match r with
| RedPair_interpretation mty => return_mytype mty
end.
Definition return_orderProof (d : orderingProof) : option nat :=
match d with
| OrderingProof_redPair r => return_redPair r
end.
Definition return_trsTermProof (t : trsTerminationProof) : option nat :=
match t with
| TrsTerminationProof_ruleRemoval d _t => return_orderProof d
end.
```

I want to write the function `return_trsTermProof`

that also work in the case not only take an argument `d`

but also if there is an `t:trsTerminationProof`

for example

```
Fixpoint return_trsTermProof (t : trsTerminationProof) : option nat :=
match t with
| TrsTerminationProof_ruleRemoval d t =>
(* I don't know how can I take the function (return_orderProof d) *) ...
return_trsTermProof t
end.
```