Commit 6c218a7b authored by Adam Chlipala's avatar Adam Chlipala

Import predicative Impure example

parent fbbdf101
...@@ -2,7 +2,7 @@ MODULES_NODOC := Axioms AxiomsImpred Tactics MoreSpecif DepList ...@@ -2,7 +2,7 @@ MODULES_NODOC := Axioms AxiomsImpred Tactics MoreSpecif DepList
MODULES_PROSE := Intro MODULES_PROSE := Intro
MODULES_CODE := StackMachine InductiveTypes Predicates Coinductive Subset \ MODULES_CODE := StackMachine InductiveTypes Predicates Coinductive Subset \
MoreDep DataStruct Equality Match Reflection Firstorder Hoas Interps \ MoreDep DataStruct Equality Match Reflection Firstorder Hoas Interps \
Extensional Intensional Extensional Intensional Impure
MODULES_DOC := $(MODULES_PROSE) $(MODULES_CODE) MODULES_DOC := $(MODULES_PROSE) $(MODULES_CODE)
MODULES := $(MODULES_NODOC) $(MODULES_DOC) MODULES := $(MODULES_NODOC) $(MODULES_DOC)
VS := $(MODULES:%=src/%.v) VS := $(MODULES:%=src/%.v)
......
...@@ -34,3 +34,9 @@ Qed. ...@@ -34,3 +34,9 @@ Qed.
Ltac ext_eq := (apply ext_eq || apply ext_eq_Set Ltac ext_eq := (apply ext_eq || apply ext_eq_Set
|| apply ext_eq_forall); intro. || apply ext_eq_forall); intro.
Theorem eta : forall (A B : Type) (f : A -> B),
(fun x => f x) = f.
intros; ext_eq; trivial.
Qed.
(* Copyright (c) 2008, Adam Chlipala
*
* This work is licensed under a
* Creative Commons Attribution-Noncommercial-No Derivative Works 3.0
* Unported License.
* The license text is available at:
* http://creativecommons.org/licenses/by-nc-nd/3.0/
*)
(* begin hide *)
Require Import Arith List Omega.
Require Import Axioms Tactics.
Set Implicit Arguments.
(* end hide *)
(** %\chapter{Modeling Impure Languages}% *)
(** TODO: Prose for this chapter *)
Section var.
Variable var : Type.
Inductive term : Type :=
| Var : var -> term
| App : term -> term -> term
| Abs : (var -> term) -> term
| Unit : term.
End var.
Implicit Arguments Unit [var].
Notation "# v" := (Var v) (at level 70).
Notation "()" := Unit.
Infix "@" := App (left associativity, at level 72).
Notation "\ x , e" := (Abs (fun x => e)) (at level 73).
Notation "\ ? , e" := (Abs (fun _ => e)) (at level 73).
Module predicative.
Inductive val : Type :=
| Func : nat -> val
| VUnit.
Inductive computation : Type :=
| Return : val -> computation
| Bind : computation -> (val -> computation) -> computation
| CAbs : (val -> computation) -> computation
| CApp : val -> val -> computation.
Definition func := val -> computation.
Fixpoint get (n : nat) (ls : list func) {struct ls} : option func :=
match ls with
| nil => None
| x :: ls' =>
if eq_nat_dec n (length ls')
then Some x
else get n ls'
end.
Inductive eval : list func -> computation -> list func -> val -> Prop :=
| EvalReturn : forall ds d,
eval ds (Return d) ds d
| EvalBind : forall ds c1 c2 ds' d1 ds'' d2,
eval ds c1 ds' d1
-> eval ds' (c2 d1) ds'' d2
-> eval ds (Bind c1 c2) ds'' d2
| EvalCAbs : forall ds f,
eval ds (CAbs f) (f :: ds) (Func (length ds))
| EvalCApp : forall ds i d2 f ds' d3,
get i ds = Some f
-> eval ds (f d2) ds' d3
-> eval ds (CApp (Func i) d2) ds' d3.
Fixpoint termDenote (e : term val) : computation :=
match e with
| Var v => Return v
| App e1 e2 => Bind (termDenote e1) (fun f =>
Bind (termDenote e2) (fun x =>
CApp f x))
| Abs e' => CAbs (fun x => termDenote (e' x))
| Unit => Return VUnit
end.
Definition Term := forall var, term var.
Definition TermDenote (E : Term) := termDenote (E _).
Definition ident : Term := fun _ => \x, #x.
Eval compute in TermDenote ident.
Definition unite : Term := fun _ => ().
Eval compute in TermDenote unite.
Definition ident_self : Term := fun _ => ident _ @ ident _.
Eval compute in TermDenote ident_self.
Definition ident_unit : Term := fun _ => ident _ @ unite _.
Eval compute in TermDenote ident_unit.
Theorem eval_ident_unit : exists ds, eval nil (TermDenote ident_unit) ds VUnit.
compute.
repeat econstructor.
simpl.
rewrite (eta Return).
reflexivity.
Qed.
Hint Constructors eval.
Lemma app_nil_start : forall A (ls : list A),
ls = nil ++ ls.
reflexivity.
Qed.
Lemma app_cons : forall A (x : A) (ls : list A),
x :: ls = (x :: nil) ++ ls.
reflexivity.
Qed.
Theorem eval_monotone : forall ds c ds' d,
eval ds c ds' d
-> exists ds'', ds' = ds'' ++ ds.
Hint Resolve app_nil_start app_ass app_cons.
induction 1; firstorder; subst; eauto.
Qed.
Lemma length_app : forall A (ds2 ds1 : list A),
length (ds1 ++ ds2) = length ds1 + length ds2.
induction ds1; simpl; intuition.
Qed.
Lemma get_app : forall ds2 d ds1,
get (length ds2) (ds1 ++ d :: ds2) = Some d.
Hint Rewrite length_app : cpdt.
induction ds1; crush;
match goal with
| [ |- context[if ?E then _ else _] ] => destruct E
end; crush.
Qed.
Theorem invert_ident : forall (E : Term) ds ds' d,
eval ds (TermDenote (fun _ => ident _ @ E _)) ds' d
-> eval ((fun x => Return x) :: ds) (TermDenote E) ds' d.
inversion 1; subst.
clear H.
inversion H3; clear H3; subst.
inversion H6; clear H6; subst.
generalize (eval_monotone H2); crush.
inversion H5; clear H5; subst.
rewrite get_app in H3.
inversion H3; clear H3; subst.
inversion H7; clear H7; subst.
assumption.
Qed.
End predicative.
...@@ -213,6 +213,8 @@ Extensional Transformations & \texttt{Extensional.v} \\ ...@@ -213,6 +213,8 @@ Extensional Transformations & \texttt{Extensional.v} \\
\hline \hline
Intensional Transformations & \texttt{Intensional.v} \\ Intensional Transformations & \texttt{Intensional.v} \\
\hline \hline
Modeling Impure Languages & \texttt{Impure.v} \\
\hline
\end{tabular} \end{center} \end{tabular} \end{center}
% *) % *)
...@@ -20,5 +20,6 @@ ...@@ -20,5 +20,6 @@
<li><a href="Interps.html">Type-Theoretic Interpreters</a> <li><a href="Interps.html">Type-Theoretic Interpreters</a>
<li><a href="Extensional.html">Extensional Transformations</a> <li><a href="Extensional.html">Extensional Transformations</a>
<li><a href="Intensional.html">Intensional Transformations</a> <li><a href="Intensional.html">Intensional Transformations</a>
<li><a href="Impure.html">Modeling Impure Languages</a>
</body></html> </body></html>
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