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Start of DataAbstraction: queues with rep functions
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@ -731,3 +731,254 @@ Module AlgebraicWithEquivalenceRelation.
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Qed.
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End DelayedSum.
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End AlgebraicWithEquivalenceRelation.
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Module RepFunction.
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Module Type QUEUE.
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Parameter t : Set -> Set.
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Parameter empty : forall A, t A.
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Parameter enqueue : forall A, t A -> A -> t A.
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Parameter dequeue : forall A, t A -> option (t A * A).
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Parameter rep : forall A, t A -> list A.
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Axiom empty_rep : forall A,
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rep (empty A) = [].
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Axiom enqueue_rep : forall A (q : t A) x,
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rep (enqueue q x) = x :: rep q.
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Axiom dequeue_empty : forall A (q : t A),
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rep q = []
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-> dequeue q = None.
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Axiom dequeue_nonempty : forall A (q : t A) xs x,
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rep q = xs ++ [x]
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-> exists q', dequeue q = Some (q', x) /\ rep q' = xs.
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End QUEUE.
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Module ListQueue : QUEUE.
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Definition t : Set -> Set := list.
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Definition empty A : t A := nil.
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Definition enqueue A (q : t A) (x : A) : t A := x :: q.
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Fixpoint dequeue A (q : t A) : option (t A * A) :=
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match q with
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| [] => None
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| x :: q' =>
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match dequeue q' with
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| None => Some ([], x)
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| Some (q'', y) => Some (x :: q'', y)
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end
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end.
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Definition rep A (q : t A) := q.
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Theorem empty_rep : forall A,
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rep (empty A) = [].
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Proof.
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equality.
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Qed.
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Theorem enqueue_rep : forall A (q : t A) x,
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rep (enqueue q x) = x :: rep q.
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Proof.
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equality.
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Qed.
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Theorem dequeue_empty : forall A (q : t A),
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rep q = []
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-> dequeue q = None.
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Proof.
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unfold rep; simplify.
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rewrite H.
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equality.
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Qed.
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Theorem dequeue_nonempty : forall A (q : t A) xs x,
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rep q = xs ++ [x]
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-> exists q', dequeue q = Some (q', x) /\ rep q' = xs.
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Proof.
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unfold rep; induct q.
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simplify.
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cases xs; simplify.
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equality.
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equality.
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simplify.
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cases xs; simplify.
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invert H; simplify.
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exists [].
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equality.
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invert H.
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assert (exists q' : t A, dequeue (xs ++ [x]) = Some (q', x) /\ q' = xs).
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apply IHq.
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equality.
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first_order.
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rewrite H.
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exists (a0 :: x0).
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equality.
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Qed.
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End ListQueue.
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Module TwoStacksQueue : QUEUE.
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Record stackpair (A : Set) := {
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EnqueueHere : list A;
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DequeueHere : list A
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}.
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Definition t := stackpair.
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Definition empty A : t A := {|
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EnqueueHere := [];
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DequeueHere := []
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|}.
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Definition enqueue A (q : t A) (x : A) : t A := {|
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EnqueueHere := x :: q.(EnqueueHere);
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DequeueHere := q.(DequeueHere)
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|}.
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Definition dequeue A (q : t A) : option (t A * A) :=
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match q.(DequeueHere) with
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| x :: dq => Some ({| EnqueueHere := q.(EnqueueHere);
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DequeueHere := dq |}, x)
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| [] =>
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match rev q.(EnqueueHere) with
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| [] => None
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| x :: eq => Some ({| EnqueueHere := [];
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DequeueHere := eq |}, x)
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end
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end.
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Definition rep A (q : t A) : list A :=
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q.(EnqueueHere) ++ rev q.(DequeueHere).
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Theorem empty_rep : forall A,
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rep (empty A) = [].
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Proof.
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equality.
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Qed.
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Theorem enqueue_rep : forall A (q : t A) x,
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rep (enqueue q x) = x :: rep q.
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Proof.
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equality.
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Qed.
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Theorem dequeue_empty : forall A (q : t A),
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rep q = []
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-> dequeue q = None.
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Proof.
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unfold rep, dequeue; simplify.
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cases (DequeueHere q); simplify.
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rewrite app_nil_r in H.
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rewrite H.
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simplify.
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equality.
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cases (EnqueueHere q); simplify.
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cases (rev l); simplify.
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equality.
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equality.
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equality.
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Qed.
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Theorem dequeue_nonempty : forall A (q : t A) xs x,
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rep q = xs ++ [x]
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-> exists q', dequeue q = Some (q', x) /\ rep q' = xs.
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Proof.
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unfold rep, dequeue; simplify.
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cases (DequeueHere q); simplify.
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rewrite app_nil_r in H.
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rewrite H.
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rewrite rev_app_distr; simplify.
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exists {| EnqueueHere := []; DequeueHere := rev xs |}.
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simplify.
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rewrite rev_involutive.
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equality.
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exists {| EnqueueHere := EnqueueHere q; DequeueHere := l |}.
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simplify.
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rewrite app_assoc in H.
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apply app_inj_tail in H.
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propositional.
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rewrite H1.
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equality.
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Qed.
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End TwoStacksQueue.
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Module DelayedSum (Q : QUEUE).
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Fixpoint makeQueue (n : nat) (q : Q.t nat) : Q.t nat :=
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match n with
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| 0 => q
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| S n' => makeQueue n' (Q.enqueue q n')
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end.
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Fixpoint computeSum (n : nat) (q : Q.t nat) : nat :=
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match n with
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| 0 => 0
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| S n' => match Q.dequeue q with
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| None => 0
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| Some (q', v) => v + computeSum n' q'
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end
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end.
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Fixpoint sumUpto (n : nat) : nat :=
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match n with
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| 0 => 0
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| S n' => n' + sumUpto n'
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end.
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Fixpoint upto (n : nat) : list nat :=
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match n with
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| 0 => []
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| S n' => upto n' ++ [n']
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end.
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Lemma makeQueue_rep : forall n q,
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Q.rep (makeQueue n q) = upto n ++ Q.rep q.
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Proof.
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induct n.
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simplify.
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equality.
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simplify.
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rewrite IHn.
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rewrite Q.enqueue_rep.
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rewrite <- app_assoc.
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simplify.
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equality.
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Qed.
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Lemma computeSum_makeQueue' : forall n q,
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Q.rep q = upto n
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-> computeSum n q = sumUpto n.
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Proof.
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induct n.
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simplify.
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equality.
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simplify.
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pose proof (Q.dequeue_nonempty _ _ H).
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first_order.
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rewrite H0.
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rewrite IHn.
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equality.
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assumption.
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Qed.
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Theorem computeSum_ok : forall n,
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computeSum n (makeQueue n (Q.empty nat)) = sumUpto n.
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Proof.
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simplify.
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apply computeSum_makeQueue'.
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rewrite makeQueue_rep.
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rewrite Q.empty_rep.
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apply app_nil_r.
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Qed.
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End DelayedSum.
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End RepFunction.
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