mirror of
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905 lines
22 KiB
Coq
905 lines
22 KiB
Coq
(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 6: Operational Semantics
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* Author: Adam Chlipala
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* License: https://creativecommons.org/licenses/by-nc-nd/4.0/ *)
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Require Import Frap.
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Set Implicit Arguments.
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(* OK, enough with defining transition relations manually. Let's return to our
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* syntax of imperative programs from Chapter 3. *)
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Inductive arith : Set :=
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| Const (n : nat)
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| Var (x : var)
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| Plus (e1 e2 : arith)
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| Minus (e1 e2 : arith)
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| Times (e1 e2 : arith).
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Inductive cmd :=
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| Skip
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| Assign (x : var) (e : arith)
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| Sequence (c1 c2 : cmd)
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| If (e : arith) (then_ else_ : cmd)
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| While (e : arith) (body : cmd).
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(* Important differences: we added [If] and switched [Repeat] to general
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* [While]. *)
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(* Here are some notations for the language, which again we won't really
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* explain. *)
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Coercion Const : nat >-> arith.
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Coercion Var : var >-> arith.
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Infix "+" := Plus : arith_scope.
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Infix "-" := Minus : arith_scope.
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Infix "*" := Times : arith_scope.
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Delimit Scope arith_scope with arith.
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Notation "x <- e" := (Assign x e%arith) (at level 75).
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Infix ";;" := Sequence (at level 76). (* This one changed slightly, to avoid parsing clashes. *)
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Notation "'when' e 'then' then_ 'else' else_ 'done'" := (If e%arith then_ else_) (at level 75, e at level 0).
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Notation "'while' e 'loop' body 'done'" := (While e%arith body) (at level 75).
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(* Here's an adaptation of our factorial example from Chapter 3. *)
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Example factorial :=
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"output" <- 1;;
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while "input" loop
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"output" <- "output" * "input";;
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"input" <- "input" - 1
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done.
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(* Recall our use of a recursive function to interpret expressions. *)
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Definition valuation := fmap var nat.
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Fixpoint interp (e : arith) (v : valuation) : nat :=
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match e with
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| Const n => n
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| Var x =>
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match v $? x with
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| None => 0
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| Some n => n
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end
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| Plus e1 e2 => interp e1 v + interp e2 v
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| Minus e1 e2 => interp e1 v - interp e2 v
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| Times e1 e2 => interp e1 v * interp e2 v
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end.
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(* Our old trick of interpreters won't work for this new language, because of
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* the general "while" loops. No such interpreter could terminate for all
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* programs. Instead, we will use inductive predicates to explain program
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* meanings. First, let's apply the most intuitive method, called
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* *big-step operational semantics*. *)
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Inductive eval : valuation -> cmd -> valuation -> Prop :=
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| EvalSkip : forall v,
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eval v Skip v
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| EvalAssign : forall v x e,
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eval v (Assign x e) (v $+ (x, interp e v))
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| EvalSeq : forall v c1 v1 c2 v2,
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eval v c1 v1
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-> eval v1 c2 v2
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-> eval v (Sequence c1 c2) v2
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| EvalIfTrue : forall v e then_ else_ v',
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interp e v <> 0
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-> eval v then_ v'
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-> eval v (If e then_ else_) v'
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| EvalIfFalse : forall v e then_ else_ v',
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interp e v = 0
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-> eval v else_ v'
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-> eval v (If e then_ else_) v'
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| EvalWhileTrue : forall v e body v' v'',
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interp e v <> 0
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-> eval v body v'
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-> eval v' (While e body) v''
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-> eval v (While e body) v''
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| EvalWhileFalse : forall v e body,
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interp e v = 0
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-> eval v (While e body) v.
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(* Let's run the factorial program on a few inputs. *)
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Theorem factorial_2 : exists v, eval ($0 $+ ("input", 2)) factorial v
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/\ v $? "output" = Some 2.
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Proof.
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eexists; propositional.
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(* [eexists]: to prove [exists x, P(x)], switch to proving [P(?y)], for a new
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* existential variable [?y]. *)
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econstructor.
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econstructor.
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econstructor.
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simplify.
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equality.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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simplify.
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equality.
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econstructor.
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econstructor.
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econstructor.
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apply EvalWhileFalse.
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(* Note that, for this step, we had to specify which rule to use, since
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* otherwise [econstructor] incorrectly guesses [EvalWhileTrue]. *)
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simplify.
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equality.
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simplify.
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equality.
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Qed.
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(* That was rather repetitive. It's easy to automate. *)
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Ltac eval1 :=
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apply EvalSkip || apply EvalAssign || eapply EvalSeq
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|| (apply EvalIfTrue; [ simplify; equality | ])
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|| (apply EvalIfFalse; [ simplify; equality | ])
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|| (eapply EvalWhileTrue; [ simplify; equality | | ])
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|| (apply EvalWhileFalse; [ simplify; equality ]).
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Ltac evaluate := simplify; try equality; repeat eval1.
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Theorem factorial_2_snazzy : exists v, eval ($0 $+ ("input", 2)) factorial v
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/\ v $? "output" = Some 2.
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Proof.
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eexists; propositional.
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evaluate.
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evaluate.
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Qed.
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Theorem factorial_3 : exists v, eval ($0 $+ ("input", 3)) factorial v
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/\ v $? "output" = Some 6.
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Proof.
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eexists; propositional.
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evaluate.
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evaluate.
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Qed.
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(* Instead of chugging through these relatively slow individual executions,
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* let's prove once and for all that [factorial] is correct. *)
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Fixpoint fact (n : nat) : nat :=
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match n with
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| O => 1
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| S n' => n * fact n'
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end.
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Example factorial_loop :=
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while "input" loop
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"output" <- "output" * "input";;
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"input" <- "input" - 1
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done.
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Lemma factorial_loop_correct : forall n v out, v $? "input" = Some n
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-> v $? "output" = Some out
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-> exists v', eval v factorial_loop v'
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/\ v' $? "output" = Some (fact n * out).
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Proof.
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induct n; simplify.
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exists v; propositional.
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apply EvalWhileFalse.
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simplify.
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rewrite H.
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equality.
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rewrite H0.
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f_equal.
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ring.
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assert (exists v', eval (v $+ ("output", out * S n) $+ ("input", n)) factorial_loop v'
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/\ v' $? "output" = Some (fact n * (out * S n))).
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apply IHn.
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simplify; equality.
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simplify; equality.
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first_order.
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eexists; propositional.
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econstructor.
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simplify.
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rewrite H.
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equality.
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econstructor.
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econstructor.
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econstructor.
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simplify.
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rewrite H, H0.
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replace (S n - 1) with n by linear_arithmetic.
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(* [replace e1 with e2 by tac]: replace occurrences of [e1] with [e2], proving
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* [e2 = e1] with tactic [tac]. *)
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apply H1.
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rewrite H2.
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f_equal.
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ring.
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Qed.
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Theorem factorial_correct : forall n v, v $? "input" = Some n
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-> exists v', eval v factorial v'
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/\ v' $? "output" = Some (fact n).
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Proof.
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simplify.
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assert (exists v', eval (v $+ ("output", 1)) factorial_loop v'
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/\ v' $? "output" = Some (fact n * 1)).
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apply factorial_loop_correct.
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simplify; equality.
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simplify; equality.
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first_order.
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eexists; propositional.
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econstructor.
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econstructor.
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simplify.
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apply H0.
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rewrite H1.
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f_equal.
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ring.
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Qed.
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(** * Small-step semantics *)
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(* Big-step semantics only tells us something about the behavior of terminating
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* programs. Our imperative language clearly supports nontermination, thanks to
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* the inclusion of general "while" loops. A switch to *small-step* semantics
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* lets us also explain what happens with nonterminating executions, and this
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* style will also come in handy for more advanced features like concurrency. *)
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Inductive step : valuation * cmd -> valuation * cmd -> Prop :=
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| StepAssign : forall v x e,
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step (v, Assign x e) (v $+ (x, interp e v), Skip)
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| StepSeq1 : forall v c1 c2 v' c1',
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step (v, c1) (v', c1')
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-> step (v, Sequence c1 c2) (v', Sequence c1' c2)
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| StepSeq2 : forall v c2,
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step (v, Sequence Skip c2) (v, c2)
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| StepIfTrue : forall v e then_ else_,
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interp e v <> 0
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-> step (v, If e then_ else_) (v, then_)
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| StepIfFalse : forall v e then_ else_,
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interp e v = 0
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-> step (v, If e then_ else_) (v, else_)
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| StepWhileTrue : forall v e body,
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interp e v <> 0
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-> step (v, While e body) (v, Sequence body (While e body))
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| StepWhileFalse : forall v e body,
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interp e v = 0
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-> step (v, While e body) (v, Skip).
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(* Here's a small-step factorial execution. *)
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Theorem factorial_2_small : exists v, step^* ($0 $+ ("input", 2), factorial) (v, Skip)
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/\ v $? "output" = Some 2.
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Proof.
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eexists; propositional.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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apply StepSeq2.
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econstructor.
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econstructor.
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simplify.
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equality.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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apply StepSeq2.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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apply StepSeq2.
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econstructor.
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econstructor.
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simplify.
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equality.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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apply StepSeq2.
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econstructor.
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econstructor.
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econstructor.
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econstructor.
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apply StepSeq2.
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econstructor.
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apply StepWhileFalse.
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simplify.
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equality.
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econstructor.
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simplify.
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equality.
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Qed.
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Ltac step1 :=
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apply TrcRefl || eapply TrcFront
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|| apply StepAssign || apply StepSeq2 || eapply StepSeq1
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|| (apply StepIfTrue; [ simplify; equality ])
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|| (apply StepIfFalse; [ simplify; equality ])
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|| (eapply StepWhileTrue; [ simplify; equality ])
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|| (apply StepWhileFalse; [ simplify; equality ]).
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Ltac stepper := simplify; try equality; repeat step1.
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Theorem factorial_2_small_snazzy : exists v, step^* ($0 $+ ("input", 2), factorial) (v, Skip)
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/\ v $? "output" = Some 2.
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Proof.
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eexists; propositional.
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stepper.
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stepper.
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Qed.
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(* It turns out that these two semantics styles are equivalent. Let's prove
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* it. *)
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(* Automated proofs used here, if only to save time in class.
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* See book code for more manual proofs, too. *)
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Hint Constructors trc step eval.
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Theorem big_small : forall v c v', eval v c v'
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-> step^* (v, c) (v', Skip).
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Proof.
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Admitted.
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Theorem small_big_snazzy : forall v c v', step^* (v, c) (v', Skip)
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-> eval v c v'.
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Proof.
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Admitted.
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(** * Small-step semantics gives rise to transition systems. *)
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Definition trsys_of (v : valuation) (c : cmd) : trsys (valuation * cmd) := {|
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Initial := {(v, c)};
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Step := step
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|}.
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Theorem simple_invariant :
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invariantFor (trsys_of ($0 $+ ("a", 1)) ("b" <- "a" + 1;; "c" <- "b" + "b"))
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(fun s => snd s = Skip -> fst s $? "c" = Some 4).
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Proof.
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model_check.
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Qed.
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Inductive isEven : nat -> Prop :=
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| EvenO : isEven 0
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| EvenSS : forall n, isEven n -> isEven (S (S n)).
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Lemma isEven_minus2 : forall n, isEven n -> isEven (n - 2).
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Proof.
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induct 1; simplify.
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constructor.
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replace (n - 0) with n by linear_arithmetic.
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assumption.
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Qed.
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Lemma isEven_plus : forall n m,
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isEven n
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-> isEven m
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-> isEven (n + m).
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Proof.
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induct 1; simplify.
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assumption.
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constructor.
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apply IHisEven.
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assumption.
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Qed.
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Hint Constructors isEven.
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Hint Resolve isEven_minus2 isEven_plus.
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Definition my_loop :=
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while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done.
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Theorem manually_proved_invariant : forall n,
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isEven n
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-> invariantFor (trsys_of ($0 $+ ("n", n) $+ ("a", 0)) (while "n" loop "a" <- "a" + "n";; "n" <- "n" - 2 done))
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(fun s => exists a, fst s $? "a" = Some a /\ isEven a).
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Proof.
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Admitted.
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Definition all_programs := {
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(while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done),
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("a" <- "a" + "n";;
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"n" <- "n" - 2),
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(Skip;;
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"n" <- "n" - 2),
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("n" <- "n" - 2),
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(("a" <- "a" + "n";;
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"n" <- "n" - 2);;
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while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done),
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((Skip;;
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"n" <- "n" - 2);;
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while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done),
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("n" <- "n" - 2;;
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while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done),
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(Skip;;
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while "n" loop
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"a" <- "a" + "n";;
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"n" <- "n" - 2
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done),
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Skip
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}.
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Lemma manually_proved_invariant' : forall n,
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isEven n
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-> invariantFor (trsys_of ($0 $+ ("n", n) $+ ("a", 0)) (while "n" loop "a" <- "a" + "n";; "n" <- "n" - 2 done))
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(fun s => all_programs (snd s)
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/\ exists n a, fst s $? "n" = Some n
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/\ fst s $? "a" = Some a
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/\ isEven n
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/\ isEven a).
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Proof.
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simplify; apply invariant_induction; simplify; unfold all_programs in *; first_order; subst; simplify;
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try match goal with
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| [ H : step _ _ |- _ ] => invert H; simplify
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end;
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repeat (match goal with
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| [ H : _ = Some _ |- _ ] => rewrite H
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| [ H : @eq cmd (_ _ _) _ |- _ ] => invert H
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| [ H : @eq cmd (_ _ _ _) _ |- _ ] => invert H
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| [ H : step _ _ |- _ ] => invert2 H
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end; simplify); equality || eauto 7.
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Qed.
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(* We'll return to these systems and their abstractions in the next few
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* chapters. *)
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(** * Contextual small-step semantics *)
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(* There is a common way to factor a small-step semantics into different parts,
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* to make the semantics easier to understand and extend. First, we define a
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* notion of *evaluation contexts*, which are commands with *holes* in them. *)
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Inductive context :=
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| Hole
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| CSeq (C : context) (c : cmd).
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(* This relation explains how to plug the hole in a context with a specific
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* term. Note that we use an inductive relation instead of a recursive
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* definition, because Coq's proof automation is better at working with
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* relations. *)
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Inductive plug : context -> cmd -> cmd -> Prop :=
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| PlugHole : forall c, plug Hole c c
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| PlugSeq : forall c C c' c2,
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plug C c c'
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-> plug (CSeq C c2) c (Sequence c' c2).
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(* Now we define almost the same step relation as before, with one omission:
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* only the more trivial of the [Sequence] rules remains. *)
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Inductive step0 : valuation * cmd -> valuation * cmd -> Prop :=
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| Step0Assign : forall v x e,
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step0 (v, Assign x e) (v $+ (x, interp e v), Skip)
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| Step0Seq : forall v c2,
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step0 (v, Sequence Skip c2) (v, c2)
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| Step0IfTrue : forall v e then_ else_,
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interp e v <> 0
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-> step0 (v, If e then_ else_) (v, then_)
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| Step0IfFalse : forall v e then_ else_,
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interp e v = 0
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-> step0 (v, If e then_ else_) (v, else_)
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| Step0WhileTrue : forall v e body,
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interp e v <> 0
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-> step0 (v, While e body) (v, Sequence body (While e body))
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| Step0WhileFalse : forall v e body,
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interp e v = 0
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-> step0 (v, While e body) (v, Skip).
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(* We recover the meaning of the original with one top-level rule, combining
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* plugging of contexts with basic steps. *)
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Inductive cstep : valuation * cmd -> valuation * cmd -> Prop :=
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| CStep : forall C v c v' c' c1 c2,
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plug C c c1
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-> step0 (v, c) (v', c')
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-> plug C c' c2
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-> cstep (v, c1) (v', c2).
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(* We can prove equivalence between the two formulations. *)
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Hint Constructors plug step0 cstep.
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Theorem step_cstep : forall v c v' c',
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step (v, c) (v', c')
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-> cstep (v, c) (v', c').
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Proof.
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Admitted.
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Theorem cstep_step : forall v c v' c',
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cstep (v, c) (v', c')
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-> step (v, c) (v', c').
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Proof.
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Admitted.
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(** * Example of how easy it is to add concurrency to a contextual semantics *)
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Module Concurrent.
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(* Let's add a construct for *parallel execution* of two commands. Such
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* parallelism may be nested arbitrarily. *)
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Inductive cmd :=
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| Skip
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| Assign (x : var) (e : arith)
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| Sequence (c1 c2 : cmd)
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| If (e : arith) (then_ else_ : cmd)
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| While (e : arith) (body : cmd)
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| Parallel (c1 c2 : cmd).
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|
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Notation "x <- e" := (Assign x e%arith) (at level 75).
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Infix ";;" := Sequence (at level 76). (* This one changed slightly, to avoid parsing clashes. *)
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Notation "'when' e 'then' then_ 'else' else_ 'done'" := (If e%arith then_ else_) (at level 75, e at level 0).
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Notation "'while' e 'loop' body 'done'" := (While e%arith body) (at level 75).
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Infix "||" := Parallel.
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(* We need surprisingly few changes to the contextual semantics, to explain
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* this new feature. First, we allow a hole to appear on *either side* of a
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* [Parallel]. In other words, the "scheduler" may choose either "thread" to
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* run next. *)
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Inductive context :=
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| Hole
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|
| CSeq (C : context) (c : cmd)
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| CPar1 (C : context) (c : cmd)
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| CPar2 (c : cmd) (C : context).
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|
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(* We explain the meaning of plugging the new contexts in the obvious way. *)
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Inductive plug : context -> cmd -> cmd -> Prop :=
|
|
| PlugHole : forall c, plug Hole c c
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|
| PlugSeq : forall c C c' c2,
|
|
plug C c c'
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-> plug (CSeq C c2) c (Sequence c' c2)
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|
| PlugPar1 : forall c C c' c2,
|
|
plug C c c'
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|
-> plug (CPar1 C c2) c (Parallel c' c2)
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|
| PlugPar2 : forall c C c' c1,
|
|
plug C c c'
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|
-> plug (CPar2 c1 C) c (Parallel c1 c').
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|
|
(* The only new step rules are for "cleaning up" finished "threads," which
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|
* have reached the point of being [Skip] commands. *)
|
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Inductive step0 : valuation * cmd -> valuation * cmd -> Prop :=
|
|
| Step0Assign : forall v x e,
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|
step0 (v, Assign x e) (v $+ (x, interp e v), Skip)
|
|
| Step0Seq : forall v c2,
|
|
step0 (v, Sequence Skip c2) (v, c2)
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|
| Step0IfTrue : forall v e then_ else_,
|
|
interp e v <> 0
|
|
-> step0 (v, If e then_ else_) (v, then_)
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|
| Step0IfFalse : forall v e then_ else_,
|
|
interp e v = 0
|
|
-> step0 (v, If e then_ else_) (v, else_)
|
|
| Step0WhileTrue : forall v e body,
|
|
interp e v <> 0
|
|
-> step0 (v, While e body) (v, Sequence body (While e body))
|
|
| Step0WhileFalse : forall v e body,
|
|
interp e v = 0
|
|
-> step0 (v, While e body) (v, Skip)
|
|
| Step0Par1 : forall v c,
|
|
step0 (v, Parallel Skip c) (v, c).
|
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|
|
Inductive cstep : valuation * cmd -> valuation * cmd -> Prop :=
|
|
| CStep : forall C v c v' c' c1 c2,
|
|
plug C c c1
|
|
-> step0 (v, c) (v', c')
|
|
-> plug C c' c2
|
|
-> cstep (v, c1) (v', c2).
|
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|
|
(** Example: stepping a specific program. *)
|
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|
|
(* Here's the classic cautionary-tale program about remembering to lock your
|
|
* concurrent threads. *)
|
|
Definition prog :=
|
|
("a" <- "n";;
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|
"n" <- "a" + 1)
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|| ("b" <- "n";;
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|
"n" <- "b" + 1).
|
|
|
|
Hint Constructors plug step0 cstep.
|
|
|
|
(* The naive "expected" answer is attainable. *)
|
|
Theorem correctAnswer : forall n, exists v, cstep^* ($0 $+ ("n", n), prog) (v, Skip)
|
|
/\ v $? "n" = Some (n + 2).
|
|
Proof.
|
|
eexists; propositional.
|
|
unfold prog.
|
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|
|
econstructor.
|
|
eapply CStep with (C := CPar1 (CSeq Hole _) _); eauto.
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|
|
econstructor.
|
|
eapply CStep with (C := CPar1 Hole _); eauto.
|
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|
|
econstructor.
|
|
eapply CStep with (C := CPar1 Hole _); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := Hole); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CSeq Hole _); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := Hole); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := Hole); eauto.
|
|
|
|
econstructor.
|
|
|
|
simplify.
|
|
f_equal.
|
|
ring.
|
|
Qed.
|
|
|
|
(* But so is the "wrong" answer! *)
|
|
Theorem wrongAnswer : forall n, exists v, cstep^* ($0 $+ ("n", n), prog) (v, Skip)
|
|
/\ v $? "n" = Some (n + 1).
|
|
Proof.
|
|
eexists; propositional.
|
|
unfold prog.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CPar1 (CSeq Hole _) _); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CPar2 _ (CSeq Hole _)); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CPar1 Hole _); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CPar2 _ Hole); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := CPar1 Hole _); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := Hole); eauto.
|
|
|
|
econstructor.
|
|
eapply CStep with (C := Hole); eauto.
|
|
|
|
econstructor.
|
|
|
|
simplify.
|
|
equality.
|
|
Qed.
|
|
|
|
(** Proving equivalence with non-contextual semantics *)
|
|
|
|
(* To give us something interesting to prove, let's also define a
|
|
* non-contextual small-step semantics. Note how we have to do some more
|
|
* explicit threading of mutable state through recursive invocations. *)
|
|
Inductive step : valuation * cmd -> valuation * cmd -> Prop :=
|
|
| StepAssign : forall v x e,
|
|
step (v, Assign x e) (v $+ (x, interp e v), Skip)
|
|
| StepSeq1 : forall v c1 c2 v' c1',
|
|
step (v, c1) (v', c1')
|
|
-> step (v, Sequence c1 c2) (v', Sequence c1' c2)
|
|
| StepSeq2 : forall v c2,
|
|
step (v, Sequence Skip c2) (v, c2)
|
|
| StepIfTrue : forall v e then_ else_,
|
|
interp e v <> 0
|
|
-> step (v, If e then_ else_) (v, then_)
|
|
| StepIfFalse : forall v e then_ else_,
|
|
interp e v = 0
|
|
-> step (v, If e then_ else_) (v, else_)
|
|
| StepWhileTrue : forall v e body,
|
|
interp e v <> 0
|
|
-> step (v, While e body) (v, Sequence body (While e body))
|
|
| StepWhileFalse : forall v e body,
|
|
interp e v = 0
|
|
-> step (v, While e body) (v, Skip)
|
|
| StepParSkip1 : forall v c,
|
|
step (v, Parallel Skip c) (v, c)
|
|
| StepPar1 : forall v c1 c2 v' c1',
|
|
step (v, c1) (v', c1')
|
|
-> step (v, Parallel c1 c2) (v', Parallel c1' c2)
|
|
| StepPar2 : forall v c1 c2 v' c2',
|
|
step (v, c2) (v', c2')
|
|
-> step (v, Parallel c1 c2) (v', Parallel c1 c2').
|
|
|
|
Hint Constructors step.
|
|
|
|
(* Now, an automated proof of equivalence. Actually, it's *exactly* the same
|
|
* proof we used for the old feature set! *)
|
|
|
|
Theorem step_cstep : forall v c v' c',
|
|
step (v, c) (v', c')
|
|
-> cstep (v, c) (v', c').
|
|
Proof.
|
|
induct 1; repeat match goal with
|
|
| [ H : forall a b c d, _ = _ -> _ = _ -> _ |- _ ] =>
|
|
specialize (H _ _ _ _ eq_refl eq_refl)
|
|
| [ H : cstep _ _ |- _ ] => invert H
|
|
end; eauto.
|
|
Qed.
|
|
|
|
Hint Resolve step_cstep.
|
|
|
|
Lemma step0_step : forall v c v' c',
|
|
step0 (v, c) (v', c')
|
|
-> step (v, c) (v', c').
|
|
Proof.
|
|
induct 1; eauto.
|
|
Qed.
|
|
|
|
Hint Resolve step0_step.
|
|
|
|
Lemma cstep_step' : forall C c0 c,
|
|
plug C c0 c
|
|
-> forall v' c'0 v c', step0 (v, c0) (v', c'0)
|
|
-> plug C c'0 c'
|
|
-> step (v, c) (v', c').
|
|
Proof.
|
|
induct 1; simplify; repeat match goal with
|
|
| [ H : plug _ _ _ |- _ ] => invert1 H
|
|
end; eauto.
|
|
Qed.
|
|
|
|
Hint Resolve cstep_step'.
|
|
|
|
Theorem cstep_step : forall v c v' c',
|
|
cstep (v, c) (v', c')
|
|
-> step (v, c) (v', c').
|
|
Proof.
|
|
induct 1; eauto.
|
|
Qed.
|
|
End Concurrent.
|
|
|
|
|
|
(** * Determinism *)
|
|
|
|
(* Each of the relations we have defined turns out to be deterministic. Let's
|
|
* prove it. *)
|
|
|
|
Theorem eval_det : forall v c v1,
|
|
eval v c v1
|
|
-> forall v2, eval v c v2
|
|
-> v1 = v2.
|
|
Proof.
|
|
induct 1; invert 1; try first_order.
|
|
|
|
apply IHeval2.
|
|
apply IHeval1 in H5.
|
|
subst.
|
|
assumption.
|
|
|
|
apply IHeval2.
|
|
apply IHeval1 in H7.
|
|
subst.
|
|
assumption.
|
|
Qed.
|
|
|
|
Theorem step_det : forall s out1,
|
|
step s out1
|
|
-> forall out2, step s out2
|
|
-> out1 = out2.
|
|
Proof.
|
|
induct 1; invert 1; try first_order.
|
|
|
|
apply IHstep in H5.
|
|
equality.
|
|
|
|
invert H.
|
|
|
|
invert H4.
|
|
Qed.
|
|
|
|
Theorem cstep_det : forall s out1,
|
|
cstep s out1
|
|
-> forall out2, cstep s out2
|
|
-> out1 = out2.
|
|
Proof.
|
|
simplify.
|
|
cases s; cases out1; cases out2.
|
|
eapply step_det.
|
|
apply cstep_step.
|
|
eassumption.
|
|
apply cstep_step.
|
|
eassumption.
|
|
Qed.
|