# Universally quantified modus ponens in Coq

I’m rather new to the Coq theorem prover. So I may very well have missed something fundamental when going through the tutorials.

Before I ask my question, let me assume some assumptions and recap modus ponens.

Coq < Parameter Antecedent : Prop .
Coq < Parameter Consequent : Prop .
Coq < Conjecture Minor : Antecedent .
Coq < Conjecture Major : Antecedent -> Consequent .


With these assumptions, modus ponens can be applied: a proof for the inferred Consequent can be constructed based on the Minor premisse and the Major premisse. Such a proof is simply the function application of Major with argument Minor.

Coq < Theorem ConsequentProof : Consequent . Proof . exact (Major Minor) . Qed .


That’s pretty neat.

So, now I wonder: is such modus ponens inference possible in Coq with universally quantified propositions?

In my example, I let the variable range over nat, but this is an arbitrary choice. Any Set (any combination of Sets?) (any Type?) will do.

Coq < Parameter FunctionAntecedent : nat -> Prop .
Coq < Parameter FunctionConsequent : nat -> Prop .
Coq < Conjecture QuantifiedMinor : forall n
: nat, FunctionAntecedent n .
Coq < Conjecture QuantifiedMajor : forall n
: nat, FunctionAntecedent n -> FunctionConsequent n .


Can I now proof forall n : nat, FunctionConsequent n? My attempt does not work:

Coq < Theorem QuantifiedConsequentProof : forall n : nat, FunctionConsequent n .
QuantifiedConsequentProof < Proof .
QuantifiedConsequentProof < exact (forall n : nat,
QuantifiedMajor n (QuantifiedMinor n)) .
QuantifiedConsequentProof < Abort .


This is the error output:

> exact (forall n : nat, QuantifiedMajor n (QuantifiedMinor n)) .
>                        ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Error: In environment
n : nat
The term "QuantifiedMajor n (QuantifiedMinor n)" has type
"FunctionConsequent n" which should be Set, Prop or Type.


My questions:

1. Is this QuantifiedConsequent provable? How, with which tactics?
2. Or do I need additional assumptions?
3. Also: what is the rationale for the type restriction (Set, Prop or Type, unquantified)? Are there any inconsistencies that could arise if Coq were more lenient?
4. Finally, as a catch-all question for any enlightening explanation: did I miss something?
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Certainly, the trick is that forall is the wrong thing to use here, forall builds up a type abstracting over something, but the corresponding term is a function.

 Theorem fancy : forall (p q : nat -> Prop),
(forall n, p n) -> (forall n, p n -> p q) -> (forall n, q n).
exact (fun P Q pproof impl =>
fun n => impl _ (pproof n)).
Qed.


This can also just be solved with good old auto. And you can derive a Russels paradox-esque paradox if you don't stratify typing a little bit, if we allowed Set : Set instead of Set : Type then we'd have big issues.

The only thing you seem to be missing here is that forall is just the generalized version of ->, to witness some universally quantified statement will be some lambda. The reason you avoided it before was due to the Conjecture's instead of having everything inside of one term.

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Thank you, jozefg. In general, I quite like your idea of “unlifting” the premisses (assumed conjectures) and turning them into additional antecedents in the theorem; and then proving that. But in this question, that wasn’t what I was trying to accomplish; and that approach did not help me figure out what I was doing wrong. Still I figured it out. The forall/fun distinction turned out to be key. – user3608323 May 6 '14 at 23:50

Thank you, jozefg. I figured it out.

The tactic that I needed to use is intro.

Coq < Theorem QuantifiedConsequentProof : forall n : nat, FunctionConsequent n .
QuantifiedConsequentProof < Proof .
QuantifiedConsequentProof < intro .
QuantifiedConsequentProof < exact (QuantifiedMajor n (QuantifiedMinor n)) .
QuantifiedConsequentProof < Qed .


The tactic intro lifts the universally quantified variable from the proposition to the working hypotheses.

Using

Coq < Print QuantifiedConsequentProof .


I can then see this constructed proof, from which I can deduce the alternative exact way to define it:

Coq < Theorem QuantifiedConsequentProof : forall n : nat, FunctionConsequent n .
QuantifiedConsequentProof < Proof .
QuantifiedConsequentProof < exact (fun n : nat =>
QuantifiedMajor n (QuantifiedMinor n)) .
QuantifiedConsequentProof < Qed .


So, basically my mistake was that the proof is supposed to be a function, not a forall-expression. The type of the proof is a forall-proposition, but the proof itself is a function.

Actually, the more I think about it, the more it makes sense: this proof, being a function, can in turn be applied to an argument, resulting in a new proof. When applied to an expression that has type nat, this results in the proof of the instantiated theorem.

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