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CompilerCorrectness: simulation_multiple
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2 changed files with 333 additions and 28 deletions
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@ -376,6 +376,49 @@ Fixpoint cfold (c : cmd) : cmd :=
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| Output e => Output (cfoldArith e)
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end.
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Notation silent_cstep := (fun a b => cstep a None b).
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Lemma silent_generate_fwd : forall ns vc vc',
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silent_cstep^* vc vc'
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-> generate vc ns
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-> generate vc' ns.
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Proof.
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induct 1; simplify; eauto.
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invert H1; auto.
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eapply deterministic in H; eauto.
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propositional; subst.
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auto.
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eapply deterministic in H; eauto.
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equality.
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Qed.
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Lemma silent_generate_bwd : forall ns vc vc',
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silent_cstep^* vc vc'
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-> generate vc' ns
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-> generate vc ns.
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Proof.
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induct 1; eauto.
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Qed.
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Lemma generate_Skip : forall v a ns,
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generate (v, Skip) (a :: ns)
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-> False.
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Proof.
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induct 1; simplify.
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invert H.
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invert H3.
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invert H4.
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invert H.
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invert H3.
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invert H4.
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Qed.
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Hint Resolve silent_generate_fwd silent_generate_bwd generate_Skip.
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Section simulation_skipping.
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Variable R : nat -> valuation * cmd -> valuation * cmd -> Prop.
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@ -409,23 +452,6 @@ Section simulation_skipping.
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unfold traceInclusion; eauto using simulation_skipping_fwd'.
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Qed.
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Lemma generate_Skip : forall v a ns,
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generate (v, Skip) (a :: ns)
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-> False.
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Proof.
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induct 1; simplify.
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invert H.
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invert H3.
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invert H4.
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invert H.
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invert H3.
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invert H4.
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Qed.
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Notation silent_cstep := (fun a b => cstep a None b).
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Lemma match_step : forall n vc2 l vc2' vc1,
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cstep vc2 l vc2'
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-> R n vc1 vc2
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@ -467,16 +493,6 @@ Section simulation_skipping.
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eauto 6.
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Qed.
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Lemma silent_generate : forall ns vc vc',
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silent_cstep^* vc vc'
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-> generate vc' ns
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-> generate vc ns.
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Proof.
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induct 1; eauto.
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Qed.
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Hint Resolve silent_generate.
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Lemma simulation_skipping_bwd' : forall ns vc2, generate vc2 ns
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-> forall n vc1, R n vc1 vc2
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-> generate vc1 ns.
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@ -592,3 +608,288 @@ Proof.
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eauto.
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eauto 10.
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Qed.
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(** * Simulations That Allow Taking Multiple Matching Steps *)
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Fixpoint tempVar (n : nat) : string :=
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match n with
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| O => "_tmp"
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| S n' => tempVar n' ++ "'"
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end%string.
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Fixpoint noUnderscoreVar (x : var) : bool :=
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match x with
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| String "_" _ => false
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| _ => true
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end.
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Lemma append_assoc : forall a b c,
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(a ++ (b ++ c) = (a ++ b) ++ c)%string.
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Proof.
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induct a; simplify; equality.
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Qed.
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Lemma append_assoc_String : forall a b,
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(String a b = String a "" ++ b)%string.
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Proof.
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induct b; simplify; equality.
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Qed.
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Lemma noUnderscoreVar_tempVar' : forall n,
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exists s, tempVar n = ("_tmp" ++ s)%string.
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Proof.
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induct n; simplify; first_order.
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exists ""; auto.
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rewrite H.
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exists (x ++ "'")%string.
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repeat match goal with
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| [ |- context[String ?c ?x] ] =>
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match x with
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| "" => fail 1
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| _ => rewrite (append_assoc_String c x)
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end
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end.
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repeat rewrite append_assoc.
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reflexivity.
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Qed.
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Theorem noUnderscoreVar_tempVar : forall x,
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noUnderscoreVar x = true
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-> forall n, x <> tempVar n.
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Proof.
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unfold not; simplify.
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subst.
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pose proof (noUnderscoreVar_tempVar' n).
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first_order.
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rewrite H0 in H.
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simplify.
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equality.
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Qed.
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Lemma tempVar_inj' : forall s1 s2,
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(s1 ++ "'" = s2 ++ "'")%string
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-> s1 = s2.
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Proof.
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induct s1; simplify.
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cases s2; simplify; try equality.
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invert H.
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cases s2; simplify; equality.
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cases s2; simplify.
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invert H.
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cases s1; simplify; equality.
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invert H.
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f_equal; auto.
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Qed.
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Theorem tempVar_inj : forall n1 n2,
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tempVar n1 = tempVar n2
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-> n1 = n2.
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Proof.
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induct n1; simplify; cases n2; simplify; try equality.
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repeat match goal with
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| [ _ : context[(?s ++ "'")%string] |- _ ] => cases s; simplify; try equality
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end.
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repeat match goal with
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| [ _ : context[(?s ++ "'")%string] |- _ ] => cases s; simplify; try equality
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end.
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auto using tempVar_inj'.
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Qed.
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Fixpoint noUnderscoreArith (e : arith) : bool :=
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match e with
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| Const _ => true
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| Var x => noUnderscoreVar x
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| Plus e1 e2 => noUnderscoreArith e1 && noUnderscoreArith e2
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| Minus e1 e2 => noUnderscoreArith e1 && noUnderscoreArith e2
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| Times e1 e2 => noUnderscoreArith e1 && noUnderscoreArith e2
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end.
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Fixpoint noUnderscore (c : cmd) : bool :=
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match c with
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| Skip => true
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| Assign x e => noUnderscoreVar x && noUnderscoreArith e
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| Sequence c1 c2 => noUnderscore c1 && noUnderscore c2
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| If e then_ else_ => noUnderscoreArith e && noUnderscore then_ && noUnderscore else_
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| While e body => noUnderscoreArith e && noUnderscore body
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| Output e => noUnderscoreArith e
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end.
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Fixpoint flattenArith (tempCount : nat) (dst : var) (e : arith) : nat * cmd :=
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match e with
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| Const _
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| Var _ => (tempCount, Assign dst e)
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| Plus e1 e2 =>
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let x1 := tempVar tempCount in
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let (tempCount, c1) := flattenArith (S tempCount) x1 e1 in
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let x2 := tempVar tempCount in
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let (tempCount, c2) := flattenArith (S tempCount) x2 e2 in
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(tempCount, Sequence c1 (Sequence c2 (Assign dst (Plus x1 x2))))
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| Minus e1 e2 =>
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let x1 := tempVar tempCount in
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let (tempCount, c1) := flattenArith (S tempCount) x1 e1 in
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let x2 := tempVar tempCount in
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let (tempCount, c2) := flattenArith (S tempCount) x2 e2 in
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(tempCount, Sequence c1 (Sequence c2 (Assign dst (Minus x1 x2))))
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| Times e1 e2 =>
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let x1 := tempVar tempCount in
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let (tempCount, c1) := flattenArith (S tempCount) x1 e1 in
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let x2 := tempVar tempCount in
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let (tempCount, c2) := flattenArith (S tempCount) x2 e2 in
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(tempCount, Sequence c1 (Sequence c2 (Assign dst (Times x1 x2))))
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end.
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Fixpoint flatten (c : cmd) : cmd :=
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match c with
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| Skip => c
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| Assign x e => snd (flattenArith 0 x e)
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| Sequence c1 c2 => Sequence (flatten c1) (flatten c2)
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| If e then_ else_ => If e (flatten then_) (flatten else_)
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| While e body => While e (flatten body)
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| Output _ => c
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end.
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Section simulation_multiple.
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Variable R : valuation * cmd -> valuation * cmd -> Prop.
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Hypothesis one_step : forall vc1 vc2, R vc1 vc2
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-> forall vc1' l, cstep vc1 l vc1'
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-> exists vc2' vc2'',
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silent_cstep^* vc2 vc2'
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/\ cstep vc2' l vc2''
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/\ R vc1' vc2''.
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Hypothesis agree_on_termination : forall v1 v2 c2, R (v1, Skip) (v2, c2)
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-> c2 = Skip.
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Lemma simulation_multiple_fwd' : forall vc1 ns, generate vc1 ns
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-> forall vc2, R vc1 vc2
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-> generate vc2 ns.
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Proof.
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induct 1; simplify; eauto.
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eapply one_step in H; eauto.
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first_order.
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eauto.
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eapply one_step in H1; eauto.
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first_order.
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eauto.
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Qed.
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Theorem simulation_multiple_fwd : forall vc1 vc2, R vc1 vc2
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-> vc1 <| vc2.
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Proof.
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unfold traceInclusion; eauto using simulation_multiple_fwd'.
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Qed.
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(* A version of [generate] that counts how many steps run *)
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Inductive generateN : nat -> valuation * cmd -> list nat -> Prop :=
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| GenDoneN : forall vc,
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generateN 0 vc []
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| GenSilentN : forall sc vc vc' ns,
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cstep vc None vc'
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-> generateN sc vc' ns
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-> generateN (S sc) vc ns
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| GenOutputN : forall sc vc n vc' ns,
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cstep vc (Some n) vc'
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-> generateN sc vc' ns
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-> generateN (S sc) vc (n :: ns).
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Hint Constructors generateN.
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Lemma generateN_fwd : forall sc vc ns,
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generateN sc vc ns
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-> generate vc ns.
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Proof.
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induct 1; eauto.
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Qed.
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Hint Resolve generateN_fwd.
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Lemma generateN_bwd : forall vc ns,
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generate vc ns
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-> exists sc, generateN sc vc ns.
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Proof.
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induct 1; first_order; eauto.
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Qed.
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Lemma generateN_silent_cstep : forall sc vc ns,
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generateN sc vc ns
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-> forall vc', silent_cstep^* vc vc'
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-> exists sc', sc' <= sc /\ generateN sc' vc' ns.
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Proof.
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clear; induct 1; simplify; eauto.
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invert H1; eauto.
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eapply deterministic in H; eauto.
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propositional; subst.
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apply IHgenerateN in H3.
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first_order.
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eauto.
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invert H1; eauto.
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eapply deterministic in H; eauto.
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equality.
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Qed.
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Lemma simulation_multiple_bwd' : forall sc sc', sc' < sc
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-> forall vc2 ns, generateN sc' vc2 ns
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-> forall vc1, R vc1 vc2
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-> generate vc1 ns.
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Proof.
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induct sc; simplify.
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linear_arithmetic.
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cases sc'.
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invert H0.
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auto.
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cases vc1; cases vc2.
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assert (c = Skip \/ exists v' l c', cstep (v, c) l (v', c')) by apply skip_or_step.
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first_order; subst.
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apply agree_on_termination in H1; subst.
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cases ns; auto.
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exfalso; eauto.
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eapply one_step in H1; eauto.
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first_order.
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eapply generateN_silent_cstep in H0; eauto.
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first_order.
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invert H5; auto.
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eapply deterministic in H3; eauto.
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propositional; subst.
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econstructor.
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eauto.
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eapply IHsc; try eassumption.
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linear_arithmetic.
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eapply deterministic in H3; eauto.
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propositional; subst.
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eapply GenOutput.
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eauto.
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eapply IHsc; try eassumption.
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linear_arithmetic.
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Qed.
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Theorem simulation_multiple_bwd : forall vc1 vc2, R vc1 vc2
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-> vc2 <| vc1.
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Proof.
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unfold traceInclusion; simplify.
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apply generateN_bwd in H0.
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first_order.
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eauto using simulation_multiple_bwd'.
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Qed.
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Theorem simulation_multiple : forall vc1 vc2, R vc1 vc2
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-> vc1 =| vc2.
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Proof.
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simplify; split; auto using simulation_multiple_fwd, simulation_multiple_bwd.
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Qed.
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End simulation_multiple.
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6
Frap.v
6
Frap.v
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@ -87,7 +87,11 @@ Ltac instantiate_obvious1 H :=
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end
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end.
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Ltac instantiate_obvious H := repeat instantiate_obvious1 H.
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Ltac instantiate_obvious H :=
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match type of H with
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| context[@eq string _ _] => idtac
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| _ => repeat instantiate_obvious1 H
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end.
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Ltac instantiate_obviouses :=
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repeat match goal with
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