As the title suggests, my question concerns proving the correctness and totality of lazy evaluation of arithmetic expressions in Coq. The theorems that I would like to prove are three in total:

Computations only give canonical expressions as results

Theorem Only_canonical_results: (forall x y: Aexp, Comp x y -> Canonical y).

Correctness: the computation relation preserves denotation of expressions

Theorem correct_wrt_semantics: (forall x y: Aexp, Comp x y -> I N (denotation x) (denotation y)).

Every input leads to some result.

Theorem Comp_is_total: (forall x:Aexp, (Sigma Aexp (fun y => prod (Comp x y) (Canonical y)))).

The necessary definitions are to be found in the code attached below. I should make it clear I am a novice when it comes to Coq; which more experienced users will probably notice right away. It is most certainly the case that the majority, or perhaps even all of the background material I have written can be found in the standard library. But, then again, if I knew exactly what to import from the standard library in order to prove the desired results, I would most probably not be here bothering you. That is why I submit to you the material I have so far, in the hope that some kind spirited person/s may help me. Thanks!

```
(* Sigma types *)
Inductive Sigma (A:Set)(B:A -> Set) :Set :=
Spair: forall a:A, forall b : B a,Sigma A B.
Definition E (A:Set)(B:A -> Set)
(C: Sigma A B -> Set)
(c: Sigma A B)
(d: (forall x:A, forall y:B x,
C (Spair A B x y))): C c :=
match c as c0 return (C c0) with
| Spair a b => d a b
end.
Definition project1 (A:Set)(B:A -> Set)(c: Sigma A B):=
E A B (fun z => A) c (fun x y => x).
(* Binary sum type *)
Inductive sum' (A B:Set):Set :=
inl': A -> sum' A B | inr': B -> sum' A B.
Print sum'_rect.
Definition D (A B : Set)(C: sum' A B -> Set)
(c: sum' A B)
(d: (forall x:A, C (inl' A B x)))
(e: (forall y:B, C (inr' A B y))): C c :=
match c as c0 return C c0 with
| inl' x => d x
| inr' y => e y
end.
(* Three useful finite sets *)
Inductive N_0: Set :=.
Definition R_0
(C:N_0 -> Set)
(c: N_0): C c :=
match c as c0 return (C c0) with
end.
Inductive N_1: Set := zero_1:N_1.
Definition R_1
(C:N_1 -> Set)
(c: N_1)
(d_zero: C zero_1): C c :=
match c as c0 return (C c0) with
| zero_1 => d_zero
end.
Inductive N_2: Set := zero_2:N_2 | one_2:N_2.
Definition R_2
(C:N_2 -> Set)
(c: N_2)
(d_zero: C zero_2)
(d_one: C one_2): C c :=
match c as c0 return (C c0) with
| zero_2 => d_zero
| one_2 => d_one
end.
(* Natural numbers *)
Inductive N:Set :=
zero: N | succ : N -> N.
Print N.
Print N_rect.
Definition R
(C:N -> Set)
(d: C zero)
(e: (forall x:N, C x -> C (succ x))):
(forall n:N, C n) :=
fix F (n: N): C n :=
match n as n0 return (C n0) with
| zero => d
| succ n0 => e n0 (F n0)
end.
(* Boolean to truth-value converter *)
Definition Tr (c:N_2) : Set :=
match c as c0 with
| zero_2 => N_0
| one_2 => N_1
end.
(* Identity type *)
Inductive I (A: Set)(x: A) : A -> Set :=
r : I A x x.
Print I_rect.
Theorem J
(A:Set)
(C: (forall x y:A,
forall z: I A x y, Set))
(d: (forall x:A, C x x (r A x)))
(a:A)(b:A)(c:I A a b): C a b c.
induction c.
apply d.
Defined.
(* functions are extensional wrt
identity types *)
Theorem I_I_extensionality (A B: Set)(f: A -> B):
(forall x y:A, I A x y -> I B (f x) (f y)).
Proof.
intros x y P.
induction P.
apply r.
Defined.
(* addition *)
Definition add (m n:N) : N
:= R (fun z=> N) m (fun x y => succ y) n.
(* multiplication *)
Definition mul (m n:N) : N
:= R (fun z=> N) zero (fun x y => add y m) n.
(* Axioms of Peano verified *)
Theorem P1a: (forall x: N, I N (add x zero) x).
intro x.
(* force use of definitional equality
by applying reflexivity *)
apply r.
Defined.
Theorem P1b: (forall x y: N,
I N (add x (succ y)) (succ (add x y))).
intros.
apply r.
Defined.
Theorem P2a: (forall x: N, I N (mul x zero) zero).
intros.
apply r.
Defined.
Theorem P2b: (forall x y: N,
I N (mul x (succ y)) (add (mul x y) x)).
intros.
apply r.
Defined.
Definition pd (n: N): N :=
R (fun _=> N) zero (fun x y=> x) n.
(* alternatively
Definition pd (x: N): N :=
match x as x0 with
| zero => zero
| succ n0 => n0
end.
*)
Theorem P3: (forall x y:N,
I N (succ x) (succ y) -> I N x y).
intros x y p.
apply (I_I_extensionality N N pd (succ x) (succ y)).
apply p.
Defined.
Definition not (A:Set): Set:= (A -> N_0).
Definition isnonzero (n: N): N_2:=
R (fun _ => N_2) zero_2 (fun x y => one_2) n.
Theorem P4 : (forall x:N,
not (I N (succ x) zero)).
intro x.
intro p.
apply (J N (fun x y z =>
Tr (isnonzero x) -> Tr (isnonzero y))
(fun x => (fun t => t)) (succ x) zero)
.
apply p.
simpl.
apply zero_1.
Defined.
Theorem P5 (P:N -> Set):
P zero -> (forall x:N, P x -> P (succ x))
-> (forall x:N, P x).
intros base step n.
apply R.
apply base.
apply step.
Defined.
(* I(A,-,-) is an equivalence relation *)
Lemma Ireflexive (A:Set): (forall x:A, I A x x).
intro x.
apply r.
Defined.
Lemma Isymmetric (A:Set): (forall x y:A, I A x y -> I A y x).
intros x y P.
induction P.
apply r.
Defined.
Lemma Itransitive (A:Set):
(forall x y z:A, I A x y -> I A y z -> I A x z).
intros x y z P Q.
induction P.
assumption.
Defined.
Definition or (A B : Set):= sum' A B.
(* arithmetical expressions *)
Inductive Aexp :Set :=
zer: Aexp
| suc: Aexp -> Aexp
| pls: Aexp -> Aexp -> Aexp.
(* denotation of an expression *)
Definition denotation: Aexp->N:=
fix F (a: Aexp): N :=
match a as a0 with
| zer => zero
| suc a1 => succ (F a1)
| pls a1 a2 => add (F a1) (F a2)
end.
(* predicate for distinguishing
canonical expressions *)
Definition Canonical (x:Aexp):Set :=
or (I Aexp x zer)
(Sigma Aexp (fun y =>
I Aexp x (suc y))).
(* the computation relation is
an inductively defined relation *)
Inductive Comp : Aexp -> Aexp -> Set
:=
refrule: forall a: Aexp,
forall p: Canonical a, Comp a a
| zerrule: forall a b c:Aexp,
forall p: Comp b zer,
forall q: Comp a c,
Comp (pls a b) c
| sucrule: forall a b c:Aexp,
forall p: Comp b (suc c),
Comp (pls a b) (suc (pls a c)).
(* Computations only give canonical
expressions as results *)
Theorem Only_canonical_results:
(forall x y: Aexp, Comp x y -> Canonical y).
admit.
Defined.
(* Here is where help is needed *)
(* Correctness: the computation relation
preserves denotation of expressions *)
Theorem correct_wrt_semantics:
(forall x y: Aexp, Comp x y ->
I N (denotation x) (denotation y)).
admit.
(* Here is where help is need*)
Defined.
(* every input leads to some result *)
Theorem Comp_is_total: (forall x:Aexp,
(Sigma Aexp (fun y =>
prod (Comp x y) (Canonical y)))).
admit.
(* Proof required *)
Defined.
```

`_rect`

eliminators Coq defines automatically for your inductive datatypes, yet you reimplement all of them. Is it for an educative purpose? – Ptival Dec 20 '13 at 4:13