I'm working towards formalising Free Selective Applicative Functors in Coq, but struggling with proofs by induction for inductive data types with non-uniform type parameters.

Let me give a bit of an introduction on the datatype I'm dealing with. In Haskell, we encode Free Selective Functors as a GADT:

```
data Select f a where
Pure :: a -> Select f a
Select :: Select f (Either a b) -> f (a -> b) -> Select f b
```

The crucial thing here is the existential type variable `b`

in the second data constructor.

We can translate this definition to Coq:

```
Inductive Select (F : Type -> Type) (A : Set) : Set :=
Pure : A -> Select F A
| MkSelect : forall (B : Set), Select F (B + A) -> F (B -> A) -> Select F A.
```

As a side note, I use the `-impredicative-set`

option to encode it.

Coq generates the following induction principle for this datatype:

```
Select_ind :
forall (F : Type -> Type) (P : forall A : Set, Select F A -> Prop),
(forall (A : Set) (a : A), P A (Pure a)) ->
(forall (A B : Set) (s : Select F (B + A)), P (B + A)%type s ->
forall f0 : F (B -> A), P A (MkSelect s f0)) ->
forall (A : Set) (s : Select F A), P A s
```

Here, the interesting bit is the predicate `P : forall A : Set, Select F A -> Prop`

which is parametrised not only in the expression, but also in the expressions type parameter. As I understand, the induction principle has this particular form because of the first argument of the `MkSelect`

constructor of type `Select F (B + A)`

.

Now, I would like to prove statements like the third Applicative law for the defined datatype:

```
Theorem Select_Applicative_law3
`{FunctorLaws F} :
forall (A B : Set) (u : Select F (A -> B)) (y : A),
u <*> pure y = pure (fun f => f y) <*> u.
```

Which involve values of type `Select F (A -> B)`

, i.e. expressions containing functions. However,
calling `induction`

on variables of such types produces ill-typed terms. Consider an oversimplified example of an equality that can be trivially proved by `reflexivity`

, but can't be proved using `induction`

:

```
Lemma Select_induction_fail `{Functor F} :
forall (A B : Set) (a : A) (x : Select F (A -> B)),
Select_map (fun f => f a) x = Select_map (fun f => f a) x.
Proof.
induction x.
```

Coq complains with the error:

```
Error: Abstracting over the terms "P" and "x" leads to a term
fun (P0 : Set) (x0 : Select F P0) =>
Select_map (fun f : P0 => f a) x0 = Select_map (fun f : P0 => f a) x0
which is ill-typed.
Reason is: Illegal application (Non-functional construction):
The expression "f" of type "P0" cannot be applied to the term
"a" : "A"
```

Here, Coq can't construct the predicate abstracted over the type variable because the reversed function application from the statement becomes ill-typed.

My question is, how do I use induction on my datatype? I can't see a way how to modify the induction principle in such a way so the predicate would not abstract the type. I tried to use `dependent induction`

, but it has been producing inductive hypothesis constrained by equalities similar to `(A -> B -> C) = (X + (A -> B -> C))`

which I think would not be possible to instantiate.

Please see the complete example on GitHub: https://github.com/tuura/selective-theory-coq/blob/impredicative-set/src/Control/Selective/RigidImpredSetMinimal.v

**UPDATE:**
Following the discussio in the gist I have tried to carry out proofs by induction on depth of expression. Unfortunately, this path was not very fruitful since the induction hypothesis I get in theorems similar to `Select_Applicative_law3`

appear to be unusable. I will leave this problem for now and will give it a try later.

Li-yao, many thanks again for helping me to improve my understanding!