I am using the Coq Proof Assistant to implement a model of a (small) programming language (extending an implementation of Featherweight Java by Bruno De Fraine, Erik Ernst, Mario Südholt). One thing that keeps coming up when using the `induction`

tactic is how to preserve the information wrapped in type constructors.

I have a sub typing Prop implemented as

```
Inductive sub_type : typ -> typ -> Prop :=
| st_refl : forall t, sub_type t t
| st_trans : forall t1 t2 t3, sub_type t1 t2 -> sub_type t2 t3 -> sub_type t1 t3
| st_extends : forall C D,
extends C D ->
sub_type (c_typ C) (c_typ D).
Hint Constructors sub_type.
```

where `extends`

is the class extension mechanism as seen in Java, and `typ`

represents the two different kinds of types available,

```
Inductive typ : Set :=
| c_typ : cname -> typ
| r_typ : rname -> typ.
```

An example of where I would like type information to be preserved is when using the `induction`

tactic on a hypothesis like

```
H: sub_type (c_typ u) (c_typ v)
```

E.g. in

```
u : cname
v : cname
fsv : flds
H : sub_type (c_typ u) (c_typ v)
H0 : fields v fsv
============================
exists fs : flds, fields u (fsv ++ fs)
```

using `induction H.`

discards all information about `u`

and `v`

. The `st_refl`

case becomes

```
u : cname
v : cname
fsv : flds
t : typ
H0 : fields v fsv
============================
exists fs : flds, fields u (fsv ++ fs)
```

As you can see the information that `u`

and `v`

are related to the `typ`

constructors in `H`

, and thus to `t`

, is lost. What is worse is that due to this Coq is unable to see that `u`

and `v`

must in fact be the same in this case.

When using the `inversion`

tactic on `H`

Coq succeeds in seeing that `u`

and `v`

are the same. That tactic is not applicable here however, as I need the induction hypotheses that `induction`

generates to prove the `st_trans`

and `st_extends`

cases.

Is there a tactic that combines the best of `inversion`

and `induction`

to both generate induction hypotheses and derive equalities without destroying information about what is wrapped in the constructors? Alternatively, is there a way to manually derive the information I need? `info inversion H`

and `info induction H`

both show that a lot of transformations are applied automatically (especially with `inversion`

). These have led me to experiment with the `change`

tactic along with `let ... in`

construction, but without any progress.