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LambdaCalculusAndTypeSoundness_template
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LambdaCalculusAndTypeSoundness_template.v
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LambdaCalculusAndTypeSoundness_template.v
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(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 8: Lambda Calculus and Simple Type Soundness
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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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(* The last few chapters have focused on small programming languages that are
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* representative of the essence of the imperative languages. We now turn to
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* lambda-calculus, the usual representative of functional languages. *)
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Module Ulc.
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Inductive exp : Set :=
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| Var (x : var)
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| Abs (x : var) (body : exp)
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| App (e1 e2 : exp).
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Fixpoint subst (rep : exp) (x : var) (e : exp) : exp :=
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match e with
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| Var y => if string_dec y x then rep else Var y
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| Abs y e1 => Abs y (if y ==v x then e1 else subst rep x e1)
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| App e1 e2 => App (subst rep x e1) (subst rep x e2)
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end.
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(** * Big-step semantics *)
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Inductive eval : exp -> exp -> Prop :=
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| BigAbs : forall x e,
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eval (Abs x e) (Abs x e)
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| BigApp : forall e1 x e1' e2 v2 v,
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eval e1 (Abs x e1')
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-> eval e2 v2
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-> eval (subst v2 x e1') v
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-> eval (App e1 e2) v.
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Inductive value : exp -> Prop :=
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| Value : forall x e, value (Abs x e).
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Hint Constructors eval value.
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Theorem value_eval : forall v,
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value v
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-> eval v v.
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Proof.
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invert 1; eauto.
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Qed.
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Hint Resolve value_eval.
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Theorem eval_value : forall e v,
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eval e v
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-> value v.
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Proof.
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induct 1; eauto.
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Qed.
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Hint Resolve eval_value.
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(* Some notations, to let us write more normal-looking lambda terms *)
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Coercion Var : var >-> exp.
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Notation "\ x , e" := (Abs x e) (at level 50).
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Infix "@" := App (at level 49, left associativity).
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(* Believe it or not, this is a Turing-complete language! Here's an example
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* nonterminating program. *)
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Example omega := (\"x", "x" @ "x") @ (\"x", "x" @ "x").
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(** * Church Numerals, everyone's favorite example of lambda terms in
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* action *)
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(* Here are two curious definitions. *)
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Definition zero := \"f", \"x", "x".
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Definition plus1 := \"n", \"f", \"x", "f" @ ("n" @ "f" @ "x").
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(* We can build up any natural number [n] as [plus1^n @ zero]. Let's prove
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* that, in fact, these definitions constitute a workable embedding of the
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* natural numbers in lambda-calculus. *)
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(* A term [plus^n @ zero] evaluates to something very close to what this
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* function returns. *)
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Fixpoint canonical' (n : nat) : exp :=
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match n with
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| O => "x"
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| S n' => "f" @ ((\"f", \"x", canonical' n') @ "f" @ "x")
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end.
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(* This missing piece is this wrapper. *)
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Definition canonical n := \"f", \"x", canonical' n.
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(* Let's formalize our definition of what it means to represent a number. *)
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Definition represents (e : exp) (n : nat) :=
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eval e (canonical n).
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(* Zero passes the test. *)
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Theorem zero_ok : represents zero 0.
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Proof.
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unfold zero, represents, canonical.
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simplify.
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econstructor.
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Qed.
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(* So does our successor operation. *)
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Theorem plus1_ok : forall e n, represents e n
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-> represents (plus1 @ e) (S n).
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Proof.
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unfold plus1, represents, canonical; simplify.
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econstructor.
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econstructor.
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eassumption.
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simplify.
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econstructor.
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Qed.
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(* What's basically going on here? The representation of number [n] is [N]
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* such that, for any function [f]:
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* N(f) = f^n
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* That is, we represent a number as its repeated-composition operator.
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* So, given a number, we can use it to repeat any operation. In particular,
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* to implement addition, we can just repeat [plus1]! *)
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Definition add := \"n", \"m", "n" @ plus1 @ "m".
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(* Our addition works properly on this test case. *)
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Example add_1_2 : exists v,
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eval (add @ (plus1 @ zero) @ (plus1 @ (plus1 @ zero))) v
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/\ eval (plus1 @ (plus1 @ (plus1 @ zero))) v.
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Proof.
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eexists; propositional.
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repeat (econstructor; simplify).
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repeat econstructor.
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Qed.
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(* By the way: since [canonical'] doesn't mention variable "m", substituting
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* for "m" has no effect. This fact will come in handy shortly. *)
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Lemma subst_m_canonical' : forall m n,
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subst m "m" (canonical' n) = canonical' n.
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Proof.
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induct n; simplify; equality.
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Qed.
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(* This inductive proof is the workhorse for the next result, so let's skip
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* ahead there. *)
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Lemma add_ok' : forall m n,
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eval
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(subst (\ "f", (\ "x", canonical' m)) "x"
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(subst (\ "n", (\ "f", (\ "x", "f" @ (("n" @ "f") @ "x")))) "f"
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(canonical' n))) (canonical (n + m)).
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Proof.
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induct n; simplify.
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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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econstructor.
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simplify.
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econstructor.
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econstructor.
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simplify.
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eassumption.
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simplify.
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econstructor.
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Qed.
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(* [add] properly encodes the usual addition. *)
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Theorem add_ok : forall n ne m me,
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represents ne n
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-> represents me m
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-> represents (add @ ne @ me) (n + m).
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Proof.
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unfold represents; simplify.
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econstructor.
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econstructor.
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econstructor.
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eassumption.
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simplify.
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econstructor.
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eassumption.
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simplify.
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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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econstructor.
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econstructor.
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rewrite subst_m_canonical'.
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apply add_ok'.
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Qed.
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(* Let's repeat the same exercise for multiplication. *)
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Definition mult := \"n", \"m", "n" @ (add @ "m") @ zero.
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Example mult_1_2 : exists v,
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eval (mult @ (plus1 @ zero) @ (plus1 @ (plus1 @ zero))) v
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/\ eval (plus1 @ (plus1 @ zero)) v.
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Proof.
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eexists; propositional.
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repeat (econstructor; simplify).
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repeat econstructor.
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Qed.
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Lemma mult_ok' : forall m n,
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eval
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(subst (\ "f", (\ "x", "x")) "x"
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(subst
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(\ "m",
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((\ "f", (\ "x", canonical' m)) @
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(\ "n", (\ "f", (\ "x", "f" @ (("n" @ "f") @ "x"))))) @ "m")
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"f" (canonical' n))) (canonical (n * m)).
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Proof.
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induct n; simplify.
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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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econstructor.
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simplify.
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econstructor.
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econstructor.
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simplify.
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eassumption.
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simplify.
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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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econstructor.
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econstructor.
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rewrite subst_m_canonical'.
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apply add_ok'. (* Note the recursive appeal to correctness of [add]. *)
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Qed.
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Theorem mult_ok : forall n ne m me,
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represents ne n
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-> represents me m
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-> represents (mult @ ne @ me) (n * m).
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Proof.
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unfold represents; simplify.
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econstructor.
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econstructor.
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econstructor.
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eassumption.
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simplify.
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econstructor.
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eassumption.
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simplify.
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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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simplify.
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econstructor.
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simplify.
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econstructor.
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econstructor.
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simplify.
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rewrite subst_m_canonical'.
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apply mult_ok'.
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Qed.
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(** * Small-step semantics with evaluation contexts *)
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Inductive context : Set :=
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| Hole : context
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| App1 : context -> exp -> context
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| App2 : exp -> context -> context.
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Inductive plug : context -> exp -> exp -> Prop :=
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| PlugHole : forall e,
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plug Hole e e
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| PlugApp1 : forall c e1 e2 e,
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plug c e1 e
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-> plug (App1 c e2) e1 (App e e2)
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| PlugApp2 : forall c e1 e2 e,
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value e1
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-> plug c e2 e
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-> plug (App2 e1 c) e2 (App e1 e).
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Inductive step : exp -> exp -> Prop :=
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| ContextBeta : forall c x e v e1 e2,
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value v
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-> plug c (App (Abs x e) v) e1
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-> plug c (subst v x e) e2
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-> step e1 e2.
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Hint Constructors plug step.
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(* Here we now go through a proof of equivalence between big- and small-step
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* semantics, though we won't spend any further commentary on it. *)
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Lemma step_eval'' : forall v c x e e1 e2 v0,
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value v
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-> plug c (App (Abs x e) v) e1
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-> plug c (subst v x e) e2
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-> eval e2 v0
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-> eval e1 v0.
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Proof.
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induct c; invert 2; invert 1; simplify; eauto.
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invert H0; eauto.
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invert H0; eauto.
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Qed.
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Hint Resolve step_eval''.
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Lemma step_eval' : forall e1 e2,
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step e1 e2
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-> forall v, eval e2 v
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-> eval e1 v.
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Proof.
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invert 1; simplify; eauto.
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Qed.
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Hint Resolve step_eval'.
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Theorem step_eval : forall e v,
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step^* e v
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-> value v
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-> eval e v.
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Proof.
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induct 1; eauto.
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Qed.
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Lemma plug_functional : forall C e e1,
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plug C e e1
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-> forall e2, plug C e e2
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-> e1 = e2.
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Proof.
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induct 1; invert 1; simplify; try f_equal; eauto.
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Qed.
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Lemma plug_mirror : forall C e e', plug C e e'
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-> forall e1, exists e1', plug C e1 e1'.
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Proof.
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induct 1; simplify; eauto.
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specialize (IHplug e0); first_order; eauto.
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specialize (IHplug e0); first_order; eauto.
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Qed.
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Fixpoint compose (C1 C2 : context) : context :=
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match C2 with
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| Hole => C1
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| App1 C2' e => App1 (compose C1 C2') e
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| App2 v C2' => App2 v (compose C1 C2')
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end.
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Lemma compose_ok : forall C1 C2 e1 e2 e3,
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plug C1 e1 e2
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-> plug C2 e2 e3
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-> plug (compose C1 C2) e1 e3.
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Proof.
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induct 2; simplify; eauto.
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Qed.
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Hint Resolve compose_ok.
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Lemma step_plug : forall e1 e2,
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step e1 e2
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-> forall C e1' e2', plug C e1 e1'
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-> plug C e2 e2'
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-> step e1' e2'.
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Proof.
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invert 1; simplify; eauto.
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Qed.
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Lemma stepStar_plug : forall e1 e2,
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step^* e1 e2
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-> forall C e1' e2', plug C e1 e1'
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-> plug C e2 e2'
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-> step^* e1' e2'.
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Proof.
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induct 1; simplify.
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assert (e1' = e2') by (eapply plug_functional; eassumption).
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subst.
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constructor.
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assert (exists y', plug C y y') by eauto using plug_mirror.
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invert H3.
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eapply step_plug in H.
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econstructor.
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eassumption.
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eapply IHtrc.
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eassumption.
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assumption.
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eassumption.
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assumption.
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Qed.
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Hint Resolve stepStar_plug eval_value.
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Theorem eval_step : forall e v,
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eval e v
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-> step^* e v.
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Proof.
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induct 1; eauto.
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eapply trc_trans.
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eapply stepStar_plug with (e1 := e1) (e2 := Abs x e1') (C := App1 Hole e2); eauto.
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eapply trc_trans.
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eapply stepStar_plug with (e1 := e2) (e2 := v2) (C := App2 (Abs x e1') Hole); eauto.
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eauto.
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Qed.
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End Ulc.
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Module Stlc.
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Inductive exp : Set :=
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| Var (x : var)
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| Const (n : nat)
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| Plus (e1 e2 : exp)
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| Abs (x : var) (e1 : exp)
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| App (e1 e2 : exp).
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Inductive value : exp -> Prop :=
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| VConst : forall n, value (Const n)
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| VAbs : forall x e1, value (Abs x e1).
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Fixpoint subst (e1 : exp) (x : string) (e2 : exp) : exp :=
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match e2 with
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| Var y => if y ==v x then e1 else Var y
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| Const n => Const n
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| Plus e2' e2'' => Plus (subst e1 x e2') (subst e1 x e2'')
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| Abs y e2' => Abs y (if y ==v x then e2' else subst e1 x e2')
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| App e2' e2'' => App (subst e1 x e2') (subst e1 x e2'')
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end.
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Inductive context : Set :=
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| Hole : context
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| Plus1 : context -> exp -> context
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| Plus2 : exp -> context -> context
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| App1 : context -> exp -> context
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| App2 : exp -> context -> context.
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Inductive plug : context -> exp -> exp -> Prop :=
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| PlugHole : forall e, plug Hole e e
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| PlugPlus1 : forall e e' C e2,
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plug C e e'
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-> plug (Plus1 C e2) e (Plus e' e2)
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| PlugPlus2 : forall e e' v1 C,
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value v1
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-> plug C e e'
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-> plug (Plus2 v1 C) e (Plus v1 e')
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| PlugApp1 : forall e e' C e2,
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plug C e e'
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-> plug (App1 C e2) e (App e' e2)
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| PlugApp2 : forall e e' v1 C,
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value v1
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-> plug C e e'
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-> plug (App2 v1 C) e (App v1 e').
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Inductive step0 : exp -> exp -> Prop :=
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| Beta : forall x e v,
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value v
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-> step0 (App (Abs x e) v) (subst v x e)
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| Add : forall n1 n2,
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step0 (Plus (Const n1) (Const n2)) (Const (n1 + n2)).
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Inductive step : exp -> exp -> Prop :=
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| StepRule : forall C e1 e2 e1' e2',
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plug C e1 e1'
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-> plug C e2 e2'
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-> step0 e1 e2
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-> step e1' e2'.
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Definition trsys_of (e : exp) := {|
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Initial := {e};
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Step := step
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|}.
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Inductive type :=
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| Nat (* Numbers *)
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| Fun (dom ran : type) (* Functions *).
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Inductive hasty : fmap var type -> exp -> type -> Prop :=
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| HtVar : forall G x t,
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G $? x = Some t
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-> hasty G (Var x) t
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| HtConst : forall G n,
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hasty G (Const n) Nat
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| HtPlus : forall G e1 e2,
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hasty G e1 Nat
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-> hasty G e2 Nat
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-> hasty G (Plus e1 e2) Nat
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| HtAbs : forall G x e1 t1 t2,
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hasty (G $+ (x, t1)) e1 t2
|
||||
-> hasty G (Abs x e1) (Fun t1 t2)
|
||||
| HtApp : forall G e1 e2 t1 t2,
|
||||
hasty G e1 (Fun t1 t2)
|
||||
-> hasty G e2 t1
|
||||
-> hasty G (App e1 e2) t2.
|
||||
|
||||
Hint Constructors value plug step0 step hasty.
|
||||
|
||||
(* Some notation to make it more pleasant to write programs *)
|
||||
Infix "-->" := Fun (at level 60, right associativity).
|
||||
Coercion Const : nat >-> exp.
|
||||
Infix "^+^" := Plus (at level 50).
|
||||
Coercion Var : var >-> exp.
|
||||
Notation "\ x , e" := (Abs x e) (at level 51).
|
||||
Infix "@" := App (at level 49, left associativity).
|
||||
|
||||
(* Some examples of typed programs *)
|
||||
|
||||
Example one_plus_one : hasty $0 (1 ^+^ 1) Nat.
|
||||
Proof.
|
||||
repeat (econstructor; simplify).
|
||||
Qed.
|
||||
|
||||
Example add : hasty $0 (\"n", \"m", "n" ^+^ "m") (Nat --> Nat --> Nat).
|
||||
Proof.
|
||||
repeat (econstructor; simplify).
|
||||
Qed.
|
||||
|
||||
Example eleven : hasty $0 ((\"n", \"m", "n" ^+^ "m") @ 7 @ 4) Nat.
|
||||
Proof.
|
||||
repeat (econstructor; simplify).
|
||||
Qed.
|
||||
|
||||
Example seven_the_long_way : hasty $0 ((\"x", "x") @ (\"x", "x") @ 7) Nat.
|
||||
Proof.
|
||||
repeat (econstructor; simplify).
|
||||
Qed.
|
||||
|
||||
|
||||
(** * Let's prove type soundness. *)
|
||||
|
||||
Definition unstuck e := value e
|
||||
\/ (exists e' : exp, step e e').
|
||||
|
||||
(* For class, we'll stick with this magic tactic, to save proving time. *)
|
||||
|
||||
Ltac t0 := match goal with
|
||||
| [ H : ex _ |- _ ] => invert H
|
||||
| [ H : _ /\ _ |- _ ] => invert H
|
||||
| [ |- context[?x ==v ?y] ] => cases (x ==v y)
|
||||
| [ H : Some _ = Some _ |- _ ] => invert H
|
||||
|
||||
| [ H : step _ _ |- _ ] => invert H
|
||||
| [ H : step0 _ _ |- _ ] => invert1 H
|
||||
| [ H : hasty _ ?e _, H' : value ?e |- _ ] => invert H'; invert H
|
||||
| [ H : hasty _ _ _ |- _ ] => invert1 H
|
||||
| [ H : plug _ _ _ |- _ ] => invert1 H
|
||||
end; subst.
|
||||
|
||||
Ltac t := simplify; propositional; repeat (t0; simplify); try equality; eauto 6.
|
||||
|
||||
Lemma progress : forall e t,
|
||||
hasty $0 e t
|
||||
-> value e
|
||||
\/ (exists e' : exp, step e e').
|
||||
Proof.
|
||||
Admitted.
|
||||
|
||||
(* Replacing a typing context with an equal one has no effect (useful to guide
|
||||
* proof search as a hint). *)
|
||||
Lemma hasty_change : forall G e t,
|
||||
hasty G e t
|
||||
-> forall G', G' = G
|
||||
-> hasty G' e t.
|
||||
Proof.
|
||||
t.
|
||||
Qed.
|
||||
|
||||
Hint Resolve hasty_change.
|
||||
|
||||
Lemma preservation : forall e1 e2,
|
||||
step e1 e2
|
||||
-> forall t, hasty $0 e1 t
|
||||
-> hasty $0 e2 t.
|
||||
Proof.
|
||||
Admitted.
|
||||
|
||||
Theorem safety_snazzy : forall e t, hasty $0 e t
|
||||
-> invariantFor (trsys_of e) unstuck.
|
||||
Proof.
|
||||
simplify.
|
||||
|
||||
(* Step 1: strengthen the invariant. In particular, the typing relation is
|
||||
* exactly the right stronger invariant! Our progress theorem proves the
|
||||
* required invariant inclusion. *)
|
||||
apply invariant_weaken with (invariant1 := fun e' => hasty $0 e' t).
|
||||
|
||||
(* Step 2: apply invariant induction, whose induction step turns out to match
|
||||
* our preservation theorem exactly! *)
|
||||
apply invariant_induction; simplify.
|
||||
equality.
|
||||
|
||||
eapply preservation.
|
||||
eassumption.
|
||||
assumption.
|
||||
|
||||
simplify.
|
||||
eapply progress.
|
||||
eassumption.
|
||||
Qed.
|
||||
End Stlc.
|
|
@ -19,4 +19,5 @@ ModelChecking.v
|
|||
OperationalSemantics_template.v
|
||||
OperationalSemantics.v
|
||||
AbstractInterpretation.v
|
||||
LambdaCalculusAndTypeSoundness_template.v
|
||||
LambdaCalculusAndTypeSoundness.v
|
||||
|
|
|
@ -2072,7 +2072,7 @@ Notice a peculiar property of this definition when we work with \emph{open} term
|
|||
According to the definition $\subst{\lambda x. \; y}{y}{x} = \lambda x. \; x$.
|
||||
In this example, we say that $\lambda$-bound variable $x$ has been \emph{captured}\index{variable capture} unintentionally, where substitution created a reference to that $\lambda$ where none existed before.
|
||||
Such a problem can only arise when replacing a variable with an open term.
|
||||
In this case, that term is $y$, where $\fv{y} = \{y\} \neq \emptyset$.
|
||||
In this case, that term is $x$, where $\fv{x} = \{x\} \neq \emptyset$.
|
||||
|
||||
More general investigations into $\lambda$-calculus will define a more involved notion of \emph{capture-avoiding} substitution\index{capture-avoiding substitution}.
|
||||
Instead, in this book, we carefully steer clear of the $\lambda$-calculus applications that require substituting open terms for variables, letting us stick with the simpler definiton.
|
||||
|
|
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Reference in a new issue