I'm learning Coq by reading the book "Certified Programming with Dependent Types" and I'm having trouble udnerstanding
As an example let's think this mutually inductive data type: (code is from the book)
Inductive even_list : Set := | ENil : even_list | ECons : nat -> odd_list -> even_list with odd_list : Set := | OCons : nat -> even_list -> odd_list.
and this mutually recursive function definitions:
Fixpoint elength (el : even_list) : nat := match el with | ENil => O | ECons _ ol => S (olength ol) end with olength (ol : odd_list) : nat := match ol with | OCons _ el => S (elength el) end. Fixpoint eapp (el1 el2 : even_list) : even_list := match el1 with | ENil => el2 | ECons n ol => ECons n (oapp ol el2) end with oapp (ol : odd_list) (el : even_list) : odd_list := match ol with | OCons n el' => OCons n (eapp el' el) end.
and we have induction schemes generated:
Scheme even_list_mut := Induction for even_list Sort Prop with odd_list_mut := Induction for odd_list Sort Prop.
Now what I don't understand is, from the type of
even_list_mut I can see it takes 3 arguments:
even_list_mut : forall (P : even_list -> Prop) (P0 : odd_list -> Prop), P ENil -> (forall (n : nat) (o : odd_list), P0 o -> P (ECons n o)) -> (forall (n : nat) (e : even_list), P e -> P0 (OCons n e)) -> forall e : even_list, P e
But in order to apply it we need to supply it two parameters, and it replaces the goal with 3 premises (for
forall (n : nat) (o : odd_list), P0 o -> P (ECons n o) and
forall (n : nat) (e : even_list), P e -> P0 (OCons n e) cases).
So it's like it actually gets 5 parameters, not 3.
But then this idea fails when we think of this types:
fun el1 : even_list => forall el2 : even_list, elength (eapp el1 el2) = elength el1 + elength el2 : even_list -> Prop
fun el1 el2 : even_list => elength (eapp el1 el2) = elength el1 + elength el2 : even_list -> even_list -> Prop
Can anyone explain how does
forall syntax work?