# Coq — understanding `forall` syntax

I'm learning Coq by reading the book "Certified Programming with Dependent Types" and I'm having trouble udnerstanding `forall` syntax.

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 `P ENil`, `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
``````

and

``````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?

Thanks,

-

In fact, `even_list_mut` takes 6 arguments:

``````even_list_mut
: forall
(P : even_list -> Prop)                                      (* 1 *)
(P0 : odd_list -> Prop),                                     (* 2 *)
P ENil ->                                                    (* 3 *)
(forall (n : nat) (o : odd_list), P0 o -> P (ECons n o)) ->  (* 4 *)
(forall (n : nat) (e : even_list), P e -> P0 (OCons n e)) -> (* 5 *)
forall e : even_list,                                        (* 6 *)
P e
``````

You can think of the arrow as just syntactic sugar:

``````A -> B
===
forall _ : A, B
``````

So you could rewrite `even_list_mut` this way:

``````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))
(e : even_list),
P e
``````

Sometimes when you apply such a term, some of the arguments can be inferred by unification (comparing the return type of the term with your goal), so these arguments do not become goals because Coq figured it out. For instance, say I have:

``````div_not_zero :
forall (a b : Z) (Anot0 : a <> 0), a / b <> 0
``````

And I apply it to the goal `42 / 23 <> 0`. Coq is able to figure out that `a` ought to be `42` and `b` ought to be `23`. The only goal left is to prove `42 <> 0`. But indeed, Coq implicitly passes `42` and `23` as arguments to `div_not_zero`.

I hope this helps.

EDIT 1:

``````fun (el1 : even_list) =>
forall (el2 : even_list), elength (eapp el1 el2) = elength el1 + elength el2
: even_list -> Prop
``````

is a function of one argument, `el1 : even_list`, which returns the type `forall el2 : even_list, elength (eapp el1 el2) = elength el1 + elength el2`. Informally, given a list `el1`, it constructs the statement `for every list el2, the length of appending it to el1 is the sum of its length and el1's length`.

``````fun (el1 el2 : even_list) =>
elength (eapp el1 el2) = elength el1 + elength el2
: even_list -> even_list -> Prop
``````

is a function of two arguments `el1 : even_list` and `el2 : even_list`, which returns the type `elength (eapp el1 el2) = elength el1 + elength el2`. Informally, given two lists, it constructs the statement `for these particular two lists, the length of appending them is the sum of their length`.

Notice two things: - first I said "construct the statement", which is very different from "constructing a proof of the statement". These two functions just return types/propositions/statements, that may be true or false, may be provable or unprovable. - the first one, once fed some list `el1`, returns a quite interesting type. If you had a proof of that statement, you would know that for any choice of `el2`, the length of appending it to `el1` is the sum of lengths.

In fact, here is another type/statement to consider:

``````forall (el1 el2 : even_list), elength (eapp el1 el2) = elength el1 + elength el2
: Prop
``````

This statement says that for any two lists, the length of appending is the sum of the lengths.

One thing that may be confusing you too is that this is going on:

``````fun (el1 el2 : even_list) =>
(* some proof of elength (eapp el1 el2) = elength el1 + elength el2 *)
``````

is a term whose type is

``````forall (el1 el2 : even_list),
elength (eapp el1 el2) = elength el1 + elength el2
``````

which is a statement whose type is

``````Prop
``````

So you see that `fun` and `forall` are two things related but very different. In fact, everything of the form `fun (t : T) => p t` is a term whose type is `forall (t : T), P t`, assuming `p t` has type `P t`.

Therefore, the confusion arises when you write:

``````fun (t : T) => forall (q : Q), foo
^^^^^^^^^^^^^^^^^^^
this has type  Prop
``````

because this has type:

``````forall (t : T), Prop (* just apply the rule *)
``````

So `forall` can indeed appear in two contexts, because this calculus is able to compute types. Therefore, you might see `forall` within a computation (which hints at the fact that this is a type-building computation), or you might see it within a type (which is where you usually see it). But it is the same `forall` for all intents and purposes. On the other hand, `fun` only appears in computations.

-
Thanks for your answer, I still don't understand though, are there two kinds of `forall` keywords? One to be used in type syntax and one to be used in term syntax? You examples show it's use in type syntax but in this example: `fun el1 : even_list => forall el2 : even_list, elength (eapp el1 el2) = elength el1 + elength el2` it's used in term syntax? –  sinan Jul 4 '13 at 11:48
No, it is the same `forall`. The term you mention is a type-building term: its type is `... -> Type` (or rather `Prop`, which is also a universe of types). Therefore, it uses `forall` to build the type that it computes. –  Ptival Jul 4 '13 at 12:22
in my original post, why are last two code different? –  sinan Jul 4 '13 at 13:54
Addressed your question by editing my post since the answer was too lengthy for a comment. –  Ptival Jul 4 '13 at 14:37
to me this type `forall el2 : even_list, elength (eapp el1 el2) = elength el1 + elength el2.` looks like a type of a function with one parameter of type `even_list`, and I don't understand how can this work otherwise. Maybe I should continue reading the book and come back to this question later. –  sinan Jul 4 '13 at 15:24
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