Certified Programming with Dependent Types: src/Extensional.v annotate

annotate src/Extensional.v @ 179:8f3fc56b90d4

PatMatch Elaborate_correct

author	Adam Chlipala <adamc@hcoop.net>
date	Mon, 10 Nov 2008 14:12:22 -0500
parents	f41d4e43fd30
children	de33d1ed7c63

rev	line source
adamc@175	1 (* Copyright (c) 2008, Adam Chlipala
adamc@175	2 *
adamc@175	3 * This work is licensed under a
adamc@175	4 * Creative Commons Attribution-Noncommercial-No Derivative Works 3.0
adamc@175	5 * Unported License.
adamc@175	6 * The license text is available at:
adamc@175	7 * http://creativecommons.org/licenses/by-nc-nd/3.0/
adamc@175	8 *)
adamc@175	9
adamc@175	10 (* begin hide *)
adamc@175	11 Require Import String List.
adamc@175	12
adamc@177	13 Require Import AxiomsImpred Tactics DepList.
adamc@175	14
adamc@175	15 Set Implicit Arguments.
adamc@175	16 (* end hide *)
adamc@175	17
adamc@175	18
adamc@175	19 (** %\chapter{Certifying Extensional Transformations}% *)
adamc@175	20
adamc@175	21 (** TODO: Prose for this chapter *)
adamc@175	22
adamc@175	23
adamc@175	24 (** * Simply-Typed Lambda Calculus *)
adamc@175	25
adamc@175	26 Module STLC.
adamc@175	27 Module Source.
adamc@175	28 Inductive type : Type :=
adamc@175	29 \| TNat : type
adamc@175	30 \| Arrow : type -> type -> type.
adamc@175	31
adamc@175	32 Notation "'Nat'" := TNat : source_scope.
adamc@175	33 Infix "-->" := Arrow (right associativity, at level 60) : source_scope.
adamc@175	34
adamc@175	35 Open Scope source_scope.
adamc@175	36 Bind Scope source_scope with type.
adamc@175	37 Delimit Scope source_scope with source.
adamc@175	38
adamc@175	39 Section vars.
adamc@175	40 Variable var : type -> Type.
adamc@175	41
adamc@175	42 Inductive exp : type -> Type :=
adamc@175	43 \| Var : forall t,
adamc@175	44 var t
adamc@175	45 -> exp t
adamc@175	46
adamc@175	47 \| Const : nat -> exp Nat
adamc@175	48 \| Plus : exp Nat -> exp Nat -> exp Nat
adamc@175	49
adamc@175	50 \| App : forall t1 t2,
adamc@175	51 exp (t1 --> t2)
adamc@175	52 -> exp t1
adamc@175	53 -> exp t2
adamc@175	54 \| Abs : forall t1 t2,
adamc@175	55 (var t1 -> exp t2)
adamc@175	56 -> exp (t1 --> t2).
adamc@175	57 End vars.
adamc@175	58
adamc@175	59 Definition Exp t := forall var, exp var t.
adamc@175	60
adamc@175	61 Implicit Arguments Var [var t].
adamc@175	62 Implicit Arguments Const [var].
adamc@175	63 Implicit Arguments Plus [var].
adamc@175	64 Implicit Arguments App [var t1 t2].
adamc@175	65 Implicit Arguments Abs [var t1 t2].
adamc@175	66
adamc@175	67 Notation "# v" := (Var v) (at level 70) : source_scope.
adamc@175	68
adamc@175	69 Notation "^ n" := (Const n) (at level 70) : source_scope.
adamc@175	70 Infix "+^" := Plus (left associativity, at level 79) : source_scope.
adamc@175	71
adamc@175	72 Infix "@" := App (left associativity, at level 77) : source_scope.
adamc@175	73 Notation "\ x , e" := (Abs (fun x => e)) (at level 78) : source_scope.
adamc@175	74 Notation "\ ! , e" := (Abs (fun _ => e)) (at level 78) : source_scope.
adamc@175	75
adamc@175	76 Bind Scope source_scope with exp.
adamc@175	77
adamc@175	78 Definition zero : Exp Nat := fun _ => ^0.
adamc@175	79 Definition one : Exp Nat := fun _ => ^1.
adamc@175	80 Definition zpo : Exp Nat := fun _ => zero _ +^ one _.
adamc@175	81 Definition ident : Exp (Nat --> Nat) := fun _ => \x, #x.
adamc@175	82 Definition app_ident : Exp Nat := fun _ => ident _ @ zpo _.
adamc@175	83 Definition app : Exp ((Nat --> Nat) --> Nat --> Nat) := fun _ =>
adamc@175	84 \f, \x, #f @ #x.
adamc@175	85 Definition app_ident' : Exp Nat := fun _ => app _ @ ident _ @ zpo _.
adamc@175	86
adamc@175	87 Fixpoint typeDenote (t : type) : Set :=
adamc@175	88 match t with
adamc@175	89 \| Nat => nat
adamc@175	90 \| t1 --> t2 => typeDenote t1 -> typeDenote t2
adamc@175	91 end.
adamc@175	92
adamc@175	93 Fixpoint expDenote t (e : exp typeDenote t) {struct e} : typeDenote t :=
adamc@175	94 match e in (exp _ t) return (typeDenote t) with
adamc@175	95 \| Var _ v => v
adamc@175	96
adamc@175	97 \| Const n => n
adamc@175	98 \| Plus e1 e2 => expDenote e1 + expDenote e2
adamc@175	99
adamc@175	100 \| App _ _ e1 e2 => (expDenote e1) (expDenote e2)
adamc@175	101 \| Abs _ _ e' => fun x => expDenote (e' x)
adamc@175	102 end.
adamc@175	103
adamc@175	104 Definition ExpDenote t (e : Exp t) := expDenote (e _).
adamc@176	105
adamc@176	106 Section exp_equiv.
adamc@176	107 Variables var1 var2 : type -> Type.
adamc@176	108
adamc@176	109 Inductive exp_equiv : list { t : type & var1 t * var2 t }%type -> forall t, exp var1 t -> exp var2 t -> Prop :=
adamc@176	110 \| EqEVar : forall G t (v1 : var1 t) v2,
adamc@176	111 In (existT _ t (v1, v2)) G
adamc@176	112 -> exp_equiv G (#v1) (#v2)
adamc@176	113
adamc@176	114 \| EqEConst : forall G n,
adamc@176	115 exp_equiv G (^n) (^n)
adamc@176	116 \| EqEPlus : forall G x1 y1 x2 y2,
adamc@176	117 exp_equiv G x1 x2
adamc@176	118 -> exp_equiv G y1 y2
adamc@176	119 -> exp_equiv G (x1 +^ y1) (x2 +^ y2)
adamc@176	120
adamc@176	121 \| EqEApp : forall G t1 t2 (f1 : exp _ (t1 --> t2)) (x1 : exp _ t1) f2 x2,
adamc@176	122 exp_equiv G f1 f2
adamc@176	123 -> exp_equiv G x1 x2
adamc@176	124 -> exp_equiv G (f1 @ x1) (f2 @ x2)
adamc@176	125 \| EqEAbs : forall G t1 t2 (f1 : var1 t1 -> exp var1 t2) f2,
adamc@176	126 (forall v1 v2, exp_equiv (existT _ t1 (v1, v2) :: G) (f1 v1) (f2 v2))
adamc@176	127 -> exp_equiv G (Abs f1) (Abs f2).
adamc@176	128 End exp_equiv.
adamc@176	129
adamc@176	130 Axiom Exp_equiv : forall t (E : Exp t) var1 var2,
adamc@176	131 exp_equiv nil (E var1) (E var2).
adamc@175	132 End Source.
adamc@175	133
adamc@175	134 Module CPS.
adamc@175	135 Inductive type : Type :=
adamc@175	136 \| TNat : type
adamc@175	137 \| Cont : type -> type
adamc@175	138 \| TUnit : type
adamc@175	139 \| Prod : type -> type -> type.
adamc@175	140
adamc@175	141 Notation "'Nat'" := TNat : cps_scope.
adamc@175	142 Notation "'Unit'" := TUnit : cps_scope.
adamc@175	143 Notation "t --->" := (Cont t) (at level 61) : cps_scope.
adamc@175	144 Infix "**" := Prod (right associativity, at level 60) : cps_scope.
adamc@175	145
adamc@175	146 Bind Scope cps_scope with type.
adamc@175	147 Delimit Scope cps_scope with cps.
adamc@175	148
adamc@175	149 Section vars.
adamc@175	150 Variable var : type -> Type.
adamc@175	151
adamc@175	152 Inductive prog : Type :=
adamc@175	153 \| PHalt :
adamc@175	154 var Nat
adamc@175	155 -> prog
adamc@175	156 \| App : forall t,
adamc@175	157 var (t --->)
adamc@175	158 -> var t
adamc@175	159 -> prog
adamc@175	160 \| Bind : forall t,
adamc@175	161 primop t
adamc@175	162 -> (var t -> prog)
adamc@175	163 -> prog
adamc@175	164
adamc@175	165 with primop : type -> Type :=
adamc@175	166 \| Var : forall t,
adamc@175	167 var t
adamc@175	168 -> primop t
adamc@175	169
adamc@175	170 \| Const : nat -> primop Nat
adamc@175	171 \| Plus : var Nat -> var Nat -> primop Nat
adamc@175	172
adamc@175	173 \| Abs : forall t,
adamc@175	174 (var t -> prog)
adamc@175	175 -> primop (t --->)
adamc@175	176
adamc@175	177 \| Pair : forall t1 t2,
adamc@175	178 var t1
adamc@175	179 -> var t2
adamc@175	180 -> primop (t1 ** t2)
adamc@175	181 \| Fst : forall t1 t2,
adamc@175	182 var (t1 ** t2)
adamc@175	183 -> primop t1
adamc@175	184 \| Snd : forall t1 t2,
adamc@175	185 var (t1 ** t2)
adamc@175	186 -> primop t2.
adamc@175	187 End vars.
adamc@175	188
adamc@175	189 Implicit Arguments PHalt [var].
adamc@175	190 Implicit Arguments App [var t].
adamc@175	191
adamc@175	192 Implicit Arguments Var [var t].
adamc@175	193 Implicit Arguments Const [var].
adamc@175	194 Implicit Arguments Plus [var].
adamc@175	195 Implicit Arguments Abs [var t].
adamc@175	196 Implicit Arguments Pair [var t1 t2].
adamc@175	197 Implicit Arguments Fst [var t1 t2].
adamc@175	198 Implicit Arguments Snd [var t1 t2].
adamc@175	199
adamc@175	200 Notation "'Halt' x" := (PHalt x) (no associativity, at level 75) : cps_scope.
adamc@175	201 Infix "@@" := App (no associativity, at level 75) : cps_scope.
adamc@175	202 Notation "x <- p ; e" := (Bind p (fun x => e))
adamc@175	203 (right associativity, at level 76, p at next level) : cps_scope.
adamc@175	204 Notation "! <- p ; e" := (Bind p (fun _ => e))
adamc@175	205 (right associativity, at level 76, p at next level) : cps_scope.
adamc@175	206
adamc@175	207 Notation "# v" := (Var v) (at level 70) : cps_scope.
adamc@175	208
adamc@175	209 Notation "^ n" := (Const n) (at level 70) : cps_scope.
adamc@175	210 Infix "+^" := Plus (left associativity, at level 79) : cps_scope.
adamc@175	211
adamc@175	212 Notation "\ x , e" := (Abs (fun x => e)) (at level 78) : cps_scope.
adamc@175	213 Notation "\ ! , e" := (Abs (fun _ => e)) (at level 78) : cps_scope.
adamc@175	214
adamc@179	215 Notation "[ x1 , x2 ]" := (Pair x1 x2) : cps_scope.
adamc@175	216 Notation "#1 x" := (Fst x) (at level 72) : cps_scope.
adamc@175	217 Notation "#2 x" := (Snd x) (at level 72) : cps_scope.
adamc@175	218
adamc@175	219 Bind Scope cps_scope with prog primop.
adamc@175	220
adamc@175	221 Open Scope cps_scope.
adamc@175	222
adamc@175	223 Fixpoint typeDenote (t : type) : Set :=
adamc@175	224 match t with
adamc@175	225 \| Nat => nat
adamc@175	226 \| t' ---> => typeDenote t' -> nat
adamc@175	227 \| Unit => unit
adamc@175	228 \| t1 ** t2 => (typeDenote t1 * typeDenote t2)%type
adamc@175	229 end.
adamc@175	230
adamc@175	231 Fixpoint progDenote (e : prog typeDenote) : nat :=
adamc@175	232 match e with
adamc@175	233 \| PHalt n => n
adamc@175	234 \| App _ f x => f x
adamc@175	235 \| Bind _ p x => progDenote (x (primopDenote p))
adamc@175	236 end
adamc@175	237
adamc@175	238 with primopDenote t (p : primop typeDenote t) {struct p} : typeDenote t :=
adamc@175	239 match p in (primop _ t) return (typeDenote t) with
adamc@175	240 \| Var _ v => v
adamc@175	241
adamc@175	242 \| Const n => n
adamc@175	243 \| Plus n1 n2 => n1 + n2
adamc@175	244
adamc@175	245 \| Abs _ e => fun x => progDenote (e x)
adamc@175	246
adamc@175	247 \| Pair _ _ v1 v2 => (v1, v2)
adamc@175	248 \| Fst _ _ v => fst v
adamc@175	249 \| Snd _ _ v => snd v
adamc@175	250 end.
adamc@175	251
adamc@175	252 Definition Prog := forall var, prog var.
adamc@175	253 Definition Primop t := forall var, primop var t.
adamc@175	254 Definition ProgDenote (E : Prog) := progDenote (E _).
adamc@175	255 Definition PrimopDenote t (P : Primop t) := primopDenote (P _).
adamc@175	256 End CPS.
adamc@175	257
adamc@175	258 Import Source CPS.
adamc@175	259
adamc@175	260 Fixpoint cpsType (t : Source.type) : CPS.type :=
adamc@175	261 match t with
adamc@175	262 \| Nat => Nat%cps
adamc@175	263 \| t1 --> t2 => (cpsType t1 ** (cpsType t2 --->) --->)%cps
adamc@175	264 end%source.
adamc@175	265
adamc@175	266 Reserved Notation "x <-- e1 ; e2" (right associativity, at level 76, e1 at next level).
adamc@175	267
adamc@175	268 Section cpsExp.
adamc@175	269 Variable var : CPS.type -> Type.
adamc@175	270
adamc@175	271 Import Source.
adamc@175	272 Open Scope cps_scope.
adamc@175	273
adamc@175	274 Fixpoint cpsExp t (e : exp (fun t => var (cpsType t)) t) {struct e}
adamc@175	275 : (var (cpsType t) -> prog var) -> prog var :=
adamc@175	276 match e in (exp _ t) return ((var (cpsType t) -> prog var) -> prog var) with
adamc@175	277 \| Var _ v => fun k => k v
adamc@175	278
adamc@175	279 \| Const n => fun k =>
adamc@175	280 x <- ^n;
adamc@175	281 k x
adamc@175	282 \| Plus e1 e2 => fun k =>
adamc@175	283 x1 <-- e1;
adamc@175	284 x2 <-- e2;
adamc@175	285 x <- x1 +^ x2;
adamc@175	286 k x
adamc@175	287
adamc@175	288 \| App _ _ e1 e2 => fun k =>
adamc@175	289 f <-- e1;
adamc@175	290 x <-- e2;
adamc@175	291 kf <- \r, k r;
adamc@175	292 p <- [x, kf];
adamc@175	293 f @@ p
adamc@175	294 \| Abs _ _ e' => fun k =>
adamc@175	295 f <- CPS.Abs (var := var) (fun p =>
adamc@175	296 x <- #1 p;
adamc@175	297 kf <- #2 p;
adamc@175	298 r <-- e' x;
adamc@175	299 kf @@ r);
adamc@175	300 k f
adamc@175	301 end
adamc@175	302
adamc@175	303 where "x <-- e1 ; e2" := (cpsExp e1 (fun x => e2)).
adamc@175	304 End cpsExp.
adamc@175	305
adamc@175	306 Notation "x <-- e1 ; e2" := (cpsExp e1 (fun x => e2)) : cps_scope.
adamc@175	307 Notation "! <-- e1 ; e2" := (cpsExp e1 (fun _ => e2))
adamc@175	308 (right associativity, at level 76, e1 at next level) : cps_scope.
adamc@175	309
adamc@175	310 Implicit Arguments cpsExp [var t].
adamc@175	311 Definition CpsExp (E : Exp Nat) : Prog :=
adamc@175	312 fun var => cpsExp (E _) (PHalt (var := _)).
adamc@175	313
adamc@175	314 Eval compute in CpsExp zero.
adamc@175	315 Eval compute in CpsExp one.
adamc@175	316 Eval compute in CpsExp zpo.
adamc@175	317 Eval compute in CpsExp app_ident.
adamc@175	318 Eval compute in CpsExp app_ident'.
adamc@175	319
adamc@175	320 Eval compute in ProgDenote (CpsExp zero).
adamc@175	321 Eval compute in ProgDenote (CpsExp one).
adamc@175	322 Eval compute in ProgDenote (CpsExp zpo).
adamc@175	323 Eval compute in ProgDenote (CpsExp app_ident).
adamc@175	324 Eval compute in ProgDenote (CpsExp app_ident').
adamc@175	325
adamc@176	326 Fixpoint lr (t : Source.type) : Source.typeDenote t -> CPS.typeDenote (cpsType t) -> Prop :=
adamc@176	327 match t return (Source.typeDenote t -> CPS.typeDenote (cpsType t) -> Prop) with
adamc@176	328 \| Nat => fun n1 n2 => n1 = n2
adamc@176	329 \| t1 --> t2 => fun f1 f2 =>
adamc@176	330 forall x1 x2, lr _ x1 x2
adamc@176	331 -> forall k, exists r,
adamc@176	332 f2 (x2, k) = k r
adamc@176	333 /\ lr _ (f1 x1) r
adamc@176	334 end%source.
adamc@176	335
adamc@176	336 Lemma cpsExp_correct : forall G t (e1 : exp _ t) (e2 : exp _ t),
adamc@176	337 exp_equiv G e1 e2
adamc@176	338 -> (forall t v1 v2, In (existT _ t (v1, v2)) G -> lr t v1 v2)
adamc@176	339 -> forall k, exists r,
adamc@176	340 progDenote (cpsExp e2 k) = progDenote (k r)
adamc@176	341 /\ lr t (expDenote e1) r.
adamc@176	342 induction 1; crush; fold typeDenote in *;
adamc@176	343 repeat (match goal with
adamc@176	344 \| [ H : forall k, exists r, progDenote (cpsExp ?E k) = _ /\ _
adamc@176	345 \|- context[cpsExp ?E ?K] ] =>
adamc@176	346 generalize (H K); clear H
adamc@176	347 \| [ \|- exists r, progDenote (_ ?R) = progDenote (_ r) /\ _ ] =>
adamc@176	348 exists R
adamc@176	349 \| [ t1 : Source.type \|- _ ] =>
adamc@176	350 match goal with
adamc@176	351 \| [ Hlr : lr t1 ?X1 ?X2, IH : forall v1 v2, _ \|- _ ] =>
adamc@176	352 generalize (IH X1 X2); clear IH; intro IH;
adamc@176	353 match type of IH with
adamc@176	354 \| ?P -> _ => assert P
adamc@176	355 end
adamc@176	356 end
adamc@176	357 end; crush); eauto.
adamc@176	358 Qed.
adamc@176	359
adamc@176	360 Lemma vars_easy : forall (t : Source.type) (v1 : Source.typeDenote t)
adamc@176	361 (v2 : typeDenote (cpsType t)),
adamc@176	362 In
adamc@176	363 (existT
adamc@176	364 (fun t0 : Source.type =>
adamc@176	365 (Source.typeDenote t0 * typeDenote (cpsType t0))%type) t
adamc@176	366 (v1, v2)) nil -> lr t v1 v2.
adamc@176	367 crush.
adamc@176	368 Qed.
adamc@176	369
adamc@176	370 Theorem CpsExp_correct : forall (E : Exp Nat),
adamc@176	371 ProgDenote (CpsExp E) = ExpDenote E.
adamc@176	372 unfold ProgDenote, CpsExp, ExpDenote; intros;
adamc@176	373 generalize (cpsExp_correct (e1 := E _) (e2 := E _)
adamc@176	374 (Exp_equiv _ _ _) vars_easy (PHalt (var := _))); crush.
adamc@176	375 Qed.
adamc@176	376
adamc@175	377 End STLC.
adamc@177	378
adamc@177	379
adamc@177	380 (** * A Pattern Compiler *)
adamc@177	381
adamc@177	382 Module PatMatch.
adamc@177	383 Module Source.
adamc@177	384 Inductive type : Type :=
adamc@177	385 \| Unit : type
adamc@177	386 \| Arrow : type -> type -> type
adamc@177	387 \| Prod : type -> type -> type
adamc@177	388 \| Sum : type -> type -> type.
adamc@177	389
adamc@177	390 Infix "-->" := Arrow (right associativity, at level 61).
adamc@177	391 Infix "++" := Sum (right associativity, at level 60).
adamc@177	392 Infix "**" := Prod (right associativity, at level 59).
adamc@177	393
adamc@177	394 Inductive pat : type -> list type -> Type :=
adamc@177	395 \| PVar : forall t,
adamc@177	396 pat t (t :: nil)
adamc@177	397 \| PPair : forall t1 t2 ts1 ts2,
adamc@177	398 pat t1 ts1
adamc@177	399 -> pat t2 ts2
adamc@177	400 -> pat (t1 ** t2) (ts1 ++ ts2)
adamc@177	401 \| PInl : forall t1 t2 ts,
adamc@177	402 pat t1 ts
adamc@177	403 -> pat (t1 ++ t2) ts
adamc@177	404 \| PInr : forall t1 t2 ts,
adamc@177	405 pat t2 ts
adamc@177	406 -> pat (t1 ++ t2) ts.
adamc@177	407
adamc@177	408 Implicit Arguments PVar [t].
adamc@177	409 Implicit Arguments PInl [t1 t2 ts].
adamc@177	410 Implicit Arguments PInr [t1 t2 ts].
adamc@177	411
adamc@177	412 Notation "##" := PVar (at level 70) : pat_scope.
adamc@179	413 Notation "[ p1 , p2 ]" := (PPair p1 p2) : pat_scope.
adamc@177	414 Notation "'Inl' p" := (PInl p) (at level 71) : pat_scope.
adamc@177	415 Notation "'Inr' p" := (PInr p) (at level 71) : pat_scope.
adamc@177	416
adamc@177	417 Bind Scope pat_scope with pat.
adamc@177	418 Delimit Scope pat_scope with pat.
adamc@177	419
adamc@177	420 Section vars.
adamc@177	421 Variable var : type -> Type.
adamc@177	422
adamc@177	423 Inductive exp : type -> Type :=
adamc@177	424 \| Var : forall t,
adamc@177	425 var t
adamc@177	426 -> exp t
adamc@177	427
adamc@177	428 \| EUnit : exp Unit
adamc@177	429
adamc@177	430 \| App : forall t1 t2,
adamc@177	431 exp (t1 --> t2)
adamc@177	432 -> exp t1
adamc@177	433 -> exp t2
adamc@177	434 \| Abs : forall t1 t2,
adamc@177	435 (var t1 -> exp t2)
adamc@177	436 -> exp (t1 --> t2)
adamc@177	437
adamc@177	438 \| Pair : forall t1 t2,
adamc@177	439 exp t1
adamc@177	440 -> exp t2
adamc@177	441 -> exp (t1 ** t2)
adamc@177	442
adamc@177	443 \| EInl : forall t1 t2,
adamc@177	444 exp t1
adamc@177	445 -> exp (t1 ++ t2)
adamc@177	446 \| EInr : forall t1 t2,
adamc@177	447 exp t2
adamc@177	448 -> exp (t1 ++ t2)
adamc@177	449
adamc@177	450 \| Case : forall t1 t2 (tss : list (list type)),
adamc@177	451 exp t1
adamc@177	452 -> (forall ts, member ts tss -> pat t1 ts)
adamc@177	453 -> (forall ts, member ts tss -> hlist var ts -> exp t2)
adamc@177	454 -> exp t2
adamc@177	455 -> exp t2.
adamc@177	456 End vars.
adamc@177	457
adamc@177	458 Definition Exp t := forall var, exp var t.
adamc@177	459
adamc@177	460 Implicit Arguments Var [var t].
adamc@177	461 Implicit Arguments EUnit [var].
adamc@177	462 Implicit Arguments App [var t1 t2].
adamc@177	463 Implicit Arguments Abs [var t1 t2].
adamc@177	464 Implicit Arguments Pair [var t1 t2].
adamc@177	465 Implicit Arguments EInl [var t1 t2].
adamc@177	466 Implicit Arguments EInr [var t1 t2].
adamc@177	467 Implicit Arguments Case [var t1 t2].
adamc@177	468
adamc@177	469 Notation "# v" := (Var v) (at level 70) : source_scope.
adamc@177	470
adamc@177	471 Notation "()" := EUnit : source_scope.
adamc@177	472
adamc@177	473 Infix "@" := App (left associativity, at level 77) : source_scope.
adamc@177	474 Notation "\ x , e" := (Abs (fun x => e)) (at level 78) : source_scope.
adamc@177	475
adamc@179	476 Notation "[ x , y ]" := (Pair x y) : source_scope.
adamc@177	477
adamc@177	478 Notation "'Inl' e" := (EInl e) (at level 71) : source_scope.
adamc@177	479 Notation "'Inr' e" := (EInr e) (at level 71) : source_scope.
adamc@177	480
adamc@178	481 Delimit Scope source_scope with source.
adamc@177	482 Bind Scope source_scope with exp.
adamc@177	483
adamc@177	484 Open Local Scope source_scope.
adamc@177	485
adamc@177	486 Fixpoint typeDenote (t : type) : Set :=
adamc@177	487 match t with
adamc@177	488 \| Unit => unit
adamc@177	489 \| t1 --> t2 => typeDenote t1 -> typeDenote t2
adamc@177	490 \| t1 ** t2 => (typeDenote t1 * typeDenote t2)%type
adamc@177	491 \| t1 ++ t2 => (typeDenote t1 + typeDenote t2)%type
adamc@177	492 end.
adamc@177	493
adamc@177	494 Fixpoint patDenote t ts (p : pat t ts) {struct p} : typeDenote t -> option (hlist typeDenote ts) :=
adamc@177	495 match p in (pat t ts) return (typeDenote t -> option (hlist typeDenote ts)) with
adamc@177	496 \| PVar _ => fun v => Some (v, tt)
adamc@177	497 \| PPair _ _ _ _ p1 p2 => fun v =>
adamc@177	498 match patDenote p1 (fst v), patDenote p2 (snd v) with
adamc@177	499 \| Some tup1, Some tup2 => Some (happ tup1 tup2)
adamc@177	500 \| _, _ => None
adamc@177	501 end
adamc@177	502 \| PInl _ _ _ p' => fun v =>
adamc@177	503 match v with
adamc@177	504 \| inl v' => patDenote p' v'
adamc@177	505 \| _ => None
adamc@177	506 end
adamc@177	507 \| PInr _ _ _ p' => fun v =>
adamc@177	508 match v with
adamc@177	509 \| inr v' => patDenote p' v'
adamc@177	510 \| _ => None
adamc@177	511 end
adamc@177	512 end.
adamc@177	513
adamc@177	514 Section matchesDenote.
adamc@177	515 Variables t2 : type.
adamc@177	516 Variable default : typeDenote t2.
adamc@177	517
adamc@177	518 Fixpoint matchesDenote (tss : list (list type))
adamc@177	519 : (forall ts, member ts tss -> option (hlist typeDenote ts))
adamc@177	520 -> (forall ts, member ts tss -> hlist typeDenote ts -> typeDenote t2)
adamc@177	521 -> typeDenote t2 :=
adamc@177	522 match tss return (forall ts, member ts tss -> _)
adamc@177	523 -> (forall ts, member ts tss -> _)
adamc@177	524 -> _ with
adamc@177	525 \| nil => fun _ _ =>
adamc@177	526 default
adamc@177	527 \| ts :: tss' => fun (envs : forall ts', member ts' (ts :: tss') -> option (hlist typeDenote ts'))
adamc@177	528 (bodies : forall ts', member ts' (ts :: tss') -> hlist typeDenote ts' -> typeDenote t2) =>
adamc@177	529 match envs _ (hfirst (refl_equal _)) with
adamc@177	530 \| None => matchesDenote tss'
adamc@177	531 (fun _ mem => envs _ (hnext mem))
adamc@177	532 (fun _ mem => bodies _ (hnext mem))
adamc@177	533 \| Some env => (bodies _ (hfirst (refl_equal _))) env
adamc@177	534 end
adamc@177	535 end.
adamc@177	536 End matchesDenote.
adamc@177	537
adamc@177	538 Implicit Arguments matchesDenote [t2 tss].
adamc@177	539
adamc@177	540 Fixpoint expDenote t (e : exp typeDenote t) {struct e} : typeDenote t :=
adamc@177	541 match e in (exp _ t) return (typeDenote t) with
adamc@177	542 \| Var _ v => v
adamc@177	543
adamc@177	544 \| EUnit => tt
adamc@177	545
adamc@177	546 \| App _ _ e1 e2 => (expDenote e1) (expDenote e2)
adamc@177	547 \| Abs _ _ e' => fun x => expDenote (e' x)
adamc@177	548
adamc@177	549 \| Pair _ _ e1 e2 => (expDenote e1, expDenote e2)
adamc@177	550
adamc@177	551 \| EInl _ _ e' => inl _ (expDenote e')
adamc@177	552 \| EInr _ _ e' => inr _ (expDenote e')
adamc@177	553
adamc@177	554 \| Case _ _ _ e ps es def =>
adamc@177	555 matchesDenote (expDenote def)
adamc@177	556 (fun _ mem => patDenote (ps _ mem) (expDenote e))
adamc@177	557 (fun _ mem env => expDenote (es _ mem env))
adamc@177	558 end.
adamc@177	559
adamc@177	560 Definition ExpDenote t (E : Exp t) := expDenote (E _).
adamc@177	561 End Source.
adamc@177	562
adamc@177	563 Import Source.
adamc@177	564
adamc@178	565 Module Elab.
adamc@177	566 Section vars.
adamc@177	567 Variable var : type -> Type.
adamc@177	568
adamc@177	569 Inductive exp : type -> Type :=
adamc@177	570 \| Var : forall t,
adamc@177	571 var t
adamc@177	572 -> exp t
adamc@177	573
adamc@177	574 \| EUnit : exp Unit
adamc@177	575
adamc@177	576 \| App : forall t1 t2,
adamc@177	577 exp (t1 --> t2)
adamc@177	578 -> exp t1
adamc@177	579 -> exp t2
adamc@177	580 \| Abs : forall t1 t2,
adamc@177	581 (var t1 -> exp t2)
adamc@177	582 -> exp (t1 --> t2)
adamc@177	583
adamc@177	584 \| Pair : forall t1 t2,
adamc@177	585 exp t1
adamc@177	586 -> exp t2
adamc@177	587 -> exp (t1 ** t2)
adamc@177	588 \| Fst : forall t1 t2,
adamc@177	589 exp (t1 ** t2)
adamc@177	590 -> exp t1
adamc@177	591 \| Snd : forall t1 t2,
adamc@177	592 exp (t1 ** t2)
adamc@177	593 -> exp t2
adamc@177	594
adamc@177	595 \| EInl : forall t1 t2,
adamc@177	596 exp t1
adamc@177	597 -> exp (t1 ++ t2)
adamc@177	598 \| EInr : forall t1 t2,
adamc@177	599 exp t2
adamc@177	600 -> exp (t1 ++ t2)
adamc@177	601 \| Case : forall t1 t2 t,
adamc@177	602 exp (t1 ++ t2)
adamc@177	603 -> (var t1 -> exp t)
adamc@177	604 -> (var t2 -> exp t)
adamc@177	605 -> exp t.
adamc@177	606 End vars.
adamc@177	607
adamc@177	608 Definition Exp t := forall var, exp var t.
adamc@177	609
adamc@177	610 Implicit Arguments Var [var t].
adamc@177	611 Implicit Arguments EUnit [var].
adamc@177	612 Implicit Arguments App [var t1 t2].
adamc@177	613 Implicit Arguments Abs [var t1 t2].
adamc@177	614 Implicit Arguments Pair [var t1 t2].
adamc@177	615 Implicit Arguments Fst [var t1 t2].
adamc@177	616 Implicit Arguments Snd [var t1 t2].
adamc@177	617 Implicit Arguments EInl [var t1 t2].
adamc@177	618 Implicit Arguments EInr [var t1 t2].
adamc@177	619 Implicit Arguments Case [var t1 t2 t].
adamc@177	620
adamc@177	621
adamc@177	622 Notation "# v" := (Var v) (at level 70) : elab_scope.
adamc@177	623
adamc@177	624 Notation "()" := EUnit : elab_scope.
adamc@177	625
adamc@177	626 Infix "@" := App (left associativity, at level 77) : elab_scope.
adamc@177	627 Notation "\ x , e" := (Abs (fun x => e)) (at level 78) : elab_scope.
adamc@177	628 Notation "\ ? , e" := (Abs (fun _ => e)) (at level 78) : elab_scope.
adamc@177	629
adamc@179	630 Notation "[ x , y ]" := (Pair x y) : elab_scope.
adamc@177	631 Notation "#1 e" := (Fst e) (at level 72) : elab_scope.
adamc@177	632 Notation "#2 e" := (Snd e) (at level 72) : elab_scope.
adamc@177	633
adamc@177	634 Notation "'Inl' e" := (EInl e) (at level 71) : elab_scope.
adamc@177	635 Notation "'Inr' e" := (EInr e) (at level 71) : elab_scope.
adamc@177	636
adamc@177	637 Bind Scope elab_scope with exp.
adamc@177	638 Delimit Scope elab_scope with elab.
adamc@177	639
adamc@177	640 Open Scope elab_scope.
adamc@177	641
adamc@177	642 Fixpoint expDenote t (e : exp typeDenote t) {struct e} : typeDenote t :=
adamc@177	643 match e in (exp _ t) return (typeDenote t) with
adamc@177	644 \| Var _ v => v
adamc@177	645
adamc@177	646 \| EUnit => tt
adamc@177	647
adamc@177	648 \| App _ _ e1 e2 => (expDenote e1) (expDenote e2)
adamc@177	649 \| Abs _ _ e' => fun x => expDenote (e' x)
adamc@177	650
adamc@177	651 \| Pair _ _ e1 e2 => (expDenote e1, expDenote e2)
adamc@177	652 \| Fst _ _ e' => fst (expDenote e')
adamc@177	653 \| Snd _ _ e' => snd (expDenote e')
adamc@177	654
adamc@177	655 \| EInl _ _ e' => inl _ (expDenote e')
adamc@177	656 \| EInr _ _ e' => inr _ (expDenote e')
adamc@177	657 \| Case _ _ _ e' e1 e2 =>
adamc@177	658 match expDenote e' with
adamc@177	659 \| inl v => expDenote (e1 v)
adamc@177	660 \| inr v => expDenote (e2 v)
adamc@177	661 end
adamc@177	662 end.
adamc@177	663
adamc@177	664 Definition ExpDenote t (E : Exp t) := expDenote (E _).
adamc@177	665 End Elab.
adamc@177	666
adamc@178	667 Import Elab.
adamc@178	668
adamc@178	669 Notation "x <- e1 ; e2" := ((\x, e2) @ e1)%source
adamc@178	670 (right associativity, at level 76, e1 at next level) : source_scope.
adamc@178	671 Notation "x <- e1 ; e2" := ((\x, e2) @ e1)%elab
adamc@178	672 (right associativity, at level 76, e1 at next level) : elab_scope.
adamc@178	673
adamc@178	674 Section choice_tree.
adamc@178	675 Open Scope source_scope.
adamc@178	676
adamc@178	677 Fixpoint choice_tree var (t : type) (result : Type) : Type :=
adamc@178	678 match t with
adamc@178	679 \| t1 ** t2 =>
adamc@178	680 choice_tree var t1
adamc@178	681 (choice_tree var t2
adamc@178	682 result)
adamc@178	683 \| t1 ++ t2 =>
adamc@178	684 choice_tree var t1 result
adamc@178	685 * choice_tree var t2 result
adamc@178	686 \| t => exp var t -> result
adamc@178	687 end%type.
adamc@178	688
adamc@178	689 Fixpoint merge var t result {struct t}
adamc@178	690 : (result -> result -> result)
adamc@178	691 -> choice_tree var t result -> choice_tree var t result -> choice_tree var t result :=
adamc@178	692 match t return ((result -> result -> result)
adamc@178	693 -> choice_tree var t result -> choice_tree var t result -> choice_tree var t result) with
adamc@178	694 \| _ ** _ => fun mr ct1 ct2 =>
adamc@178	695 merge _ _
adamc@178	696 (merge _ _ mr)
adamc@178	697 ct1 ct2
adamc@178	698
adamc@178	699 \| _ ++ _ => fun mr ct1 ct2 =>
adamc@178	700 (merge var _ mr (fst ct1) (fst ct2),
adamc@178	701 merge var _ mr (snd ct1) (snd ct2))
adamc@178	702
adamc@178	703 \| _ => fun mr ct1 ct2 e => mr (ct1 e) (ct2 e)
adamc@178	704 end.
adamc@178	705
adamc@178	706 Fixpoint everywhere var t result {struct t}
adamc@178	707 : (exp var t -> result) -> choice_tree var t result :=
adamc@178	708 match t return ((exp var t -> result) -> choice_tree var t result) with
adamc@178	709 \| t1 ** t2 => fun r =>
adamc@178	710 everywhere (t := t1) (fun e1 =>
adamc@178	711 everywhere (t := t2) (fun e2 =>
adamc@178	712 r ([e1, e2])%elab))
adamc@178	713
adamc@178	714 \| _ ++ _ => fun r =>
adamc@178	715 (everywhere (fun e => r (Inl e)%elab),
adamc@178	716 everywhere (fun e => r (Inr e)%elab))
adamc@178	717
adamc@178	718 \| _ => fun r => r
adamc@178	719 end.
adamc@178	720 End choice_tree.
adamc@178	721
adamc@178	722 Implicit Arguments merge [var t result].
adamc@178	723
adamc@178	724 Section elaborate.
adamc@178	725 Open Local Scope elab_scope.
adamc@178	726
adamc@178	727 Fixpoint elaboratePat var t1 ts result (p : pat t1 ts) {struct p} :
adamc@178	728 (hlist (exp var) ts -> result) -> result -> choice_tree var t1 result :=
adamc@178	729 match p in (pat t1 ts) return ((hlist (exp var) ts -> result)
adamc@178	730 -> result -> choice_tree var t1 result) with
adamc@178	731 \| PVar _ => fun succ fail =>
adamc@178	732 everywhere (fun disc => succ (disc, tt))
adamc@178	733
adamc@178	734 \| PPair _ _ _ _ p1 p2 => fun succ fail =>
adamc@178	735 elaboratePat _ p1
adamc@178	736 (fun tup1 =>
adamc@178	737 elaboratePat _ p2
adamc@178	738 (fun tup2 =>
adamc@178	739 succ (happ tup1 tup2))
adamc@178	740 fail)
adamc@178	741 (everywhere (fun _ => fail))
adamc@178	742
adamc@178	743 \| PInl _ _ _ p' => fun succ fail =>
adamc@178	744 (elaboratePat _ p' succ fail,
adamc@178	745 everywhere (fun _ => fail))
adamc@178	746 \| PInr _ _ _ p' => fun succ fail =>
adamc@178	747 (everywhere (fun _ => fail),
adamc@178	748 elaboratePat _ p' succ fail)
adamc@178	749 end.
adamc@178	750
adamc@178	751 Implicit Arguments elaboratePat [var t1 ts result].
adamc@178	752
adamc@178	753 Fixpoint letify var t ts {struct ts} : (hlist var ts -> exp var t)
adamc@178	754 -> hlist (exp var) ts -> exp var t :=
adamc@178	755 match ts return ((hlist var ts -> exp var t)
adamc@178	756 -> hlist (exp var) ts -> exp var t) with
adamc@178	757 \| nil => fun f _ => f tt
adamc@178	758 \| _ :: _ => fun f tup => letify _ (fun tup' => x <- fst tup; f (x, tup')) (snd tup)
adamc@178	759 end.
adamc@178	760
adamc@178	761 Implicit Arguments letify [var t ts].
adamc@178	762
adamc@178	763 Fixpoint expand var result t1 t2
adamc@178	764 (out : result -> exp var t2) {struct t1}
adamc@178	765 : forall ct : choice_tree var t1 result,
adamc@178	766 exp var t1
adamc@178	767 -> exp var t2 :=
adamc@178	768 match t1 return (forall ct : choice_tree var t1 result, exp var t1
adamc@178	769 -> exp var t2) with
adamc@178	770 \| (_ ** _)%source => fun ct disc =>
adamc@178	771 expand
adamc@178	772 (fun ct' => expand out ct' (#2 disc)%source)
adamc@178	773 ct
adamc@178	774 (#1 disc)
adamc@178	775
adamc@178	776 \| (_ ++ _)%source => fun ct disc =>
adamc@178	777 Case disc
adamc@178	778 (fun x => expand out (fst ct) (#x))
adamc@178	779 (fun y => expand out (snd ct) (#y))
adamc@178	780
adamc@178	781 \| _ => fun ct disc =>
adamc@178	782 x <- disc; out (ct (#x))
adamc@178	783 end.
adamc@178	784
adamc@178	785 Definition mergeOpt A (o1 o2 : option A) :=
adamc@178	786 match o1 with
adamc@178	787 \| None => o2
adamc@178	788 \| _ => o1
adamc@178	789 end.
adamc@178	790
adamc@178	791 Import Source.
adamc@178	792
adamc@178	793 Fixpoint elaborateMatches var t1 t2
adamc@178	794 (tss : list (list type)) {struct tss}
adamc@178	795 : (forall ts, member ts tss -> pat t1 ts)
adamc@178	796 -> (forall ts, member ts tss -> hlist var ts -> Elab.exp var t2)
adamc@178	797 -> choice_tree var t1 (option (Elab.exp var t2)) :=
adamc@178	798 match tss return (forall ts, member ts tss -> pat t1 ts)
adamc@178	799 -> (forall ts, member ts tss -> _)
adamc@178	800 -> _ with
adamc@178	801 \| nil => fun _ _ =>
adamc@178	802 everywhere (fun _ => None)
adamc@178	803 \| ts :: tss' => fun (ps : forall ts', member ts' (ts :: tss') -> pat t1 ts')
adamc@178	804 (es : forall ts', member ts' (ts :: tss') -> hlist var ts' -> Elab.exp var t2) =>
adamc@178	805 merge (@mergeOpt _)
adamc@178	806 (elaboratePat (ps _ (hfirst (refl_equal _)))
adamc@178	807 (fun ts => Some (letify
adamc@178	808 (fun ts' => es _ (hfirst (refl_equal _)) ts')
adamc@178	809 ts))
adamc@178	810 None)
adamc@178	811 (elaborateMatches tss'
adamc@178	812 (fun _ mem => ps _ (hnext mem))
adamc@178	813 (fun _ mem => es _ (hnext mem)))
adamc@178	814 end.
adamc@178	815
adamc@178	816 Implicit Arguments elaborateMatches [var t1 t2 tss].
adamc@178	817
adamc@178	818 Open Scope cps_scope.
adamc@178	819
adamc@178	820 Fixpoint elaborate var t (e : Source.exp var t) {struct e} : Elab.exp var t :=
adamc@178	821 match e in (Source.exp _ t) return (Elab.exp var t) with
adamc@178	822 \| Var _ v => #v
adamc@178	823
adamc@178	824 \| EUnit => ()
adamc@178	825
adamc@178	826 \| App _ _ e1 e2 => elaborate e1 @ elaborate e2
adamc@178	827 \| Abs _ _ e' => \x, elaborate (e' x)
adamc@178	828
adamc@178	829 \| Pair _ _ e1 e2 => [elaborate e1, elaborate e2]
adamc@178	830 \| EInl _ _ e' => Inl (elaborate e')
adamc@178	831 \| EInr _ _ e' => Inr (elaborate e')
adamc@178	832
adamc@178	833 \| Case _ _ _ e' ps es def =>
adamc@178	834 expand
adamc@178	835 (fun eo => match eo with
adamc@178	836 \| None => elaborate def
adamc@178	837 \| Some e => e
adamc@178	838 end)
adamc@178	839 (elaborateMatches ps (fun _ mem env => elaborate (es _ mem env)))
adamc@178	840 (elaborate e')
adamc@178	841 end.
adamc@178	842 End elaborate.
adamc@178	843
adamc@178	844 Definition Elaborate t (E : Source.Exp t) : Elab.Exp t :=
adamc@178	845 fun _ => elaborate (E _).
adamc@178	846
adamc@179	847 Fixpoint grab t result : choice_tree typeDenote t result -> typeDenote t -> result :=
adamc@179	848 match t return (choice_tree typeDenote t result -> typeDenote t -> result) with
adamc@179	849 \| t1 ** t2 => fun ct v =>
adamc@179	850 grab t2 _ (grab t1 _ ct (fst v)) (snd v)
adamc@179	851 \| t1 ++ t2 => fun ct v =>
adamc@179	852 match v with
adamc@179	853 \| inl v' => grab t1 _ (fst ct) v'
adamc@179	854 \| inr v' => grab t2 _ (snd ct) v'
adamc@179	855 end
adamc@179	856 \| t => fun ct v => ct (#v)%elab
adamc@179	857 end%source%type.
adamc@179	858
adamc@179	859 Implicit Arguments grab [t result].
adamc@179	860
adamc@179	861 Ltac my_crush :=
adamc@179	862 crush;
adamc@179	863 repeat (match goal with
adamc@179	864 \| [ \|- context[match ?E with inl _ => _ \| inr _ => _ end] ] =>
adamc@179	865 destruct E
adamc@179	866 end; crush).
adamc@179	867
adamc@179	868 Lemma expand_grab : forall t2 t1 result
adamc@179	869 (out : result -> Elab.exp typeDenote t2)
adamc@179	870 (ct : choice_tree typeDenote t1 result)
adamc@179	871 (disc : Elab.exp typeDenote t1),
adamc@179	872 Elab.expDenote (expand out ct disc) = Elab.expDenote (out (grab ct (Elab.expDenote disc))).
adamc@179	873 induction t1; my_crush.
adamc@179	874 Qed.
adamc@179	875
adamc@179	876 Lemma recreate_pair : forall t1 t2
adamc@179	877 (x : Elab.exp typeDenote t1)
adamc@179	878 (x0 : Elab.exp typeDenote t2)
adamc@179	879 (v : typeDenote (t1 ** t2)),
adamc@179	880 expDenote x = fst v
adamc@179	881 -> expDenote x0 = snd v
adamc@179	882 -> @eq (typeDenote t1 * typeDenote t2) (expDenote [x, x0]) v.
adamc@179	883 destruct v; crush.
adamc@179	884 Qed.
adamc@179	885
adamc@179	886 Lemma everywhere_correct : forall t1 result
adamc@179	887 (succ : Elab.exp typeDenote t1 -> result) disc,
adamc@179	888 exists disc', grab (everywhere succ) (Elab.expDenote disc) = succ disc'
adamc@179	889 /\ Elab.expDenote disc' = Elab.expDenote disc.
adamc@179	890 Hint Resolve recreate_pair.
adamc@179	891
adamc@179	892 induction t1; my_crush; eauto; fold choice_tree;
adamc@179	893 repeat (fold typeDenote in *; crush;
adamc@179	894 match goal with
adamc@179	895 \| [ IH : forall result succ, _ \|- context[grab (everywhere ?S) _] ] =>
adamc@179	896 generalize (IH _ S); clear IH
adamc@179	897 \| [ e : exp typeDenote (?T ** _), IH : forall _ : exp typeDenote ?T, _ \|- _ ] =>
adamc@179	898 generalize (IH (#1 e)); clear IH
adamc@179	899 \| [ e : exp typeDenote (_ ** ?T), IH : forall _ : exp typeDenote ?T, _ \|- _ ] =>
adamc@179	900 generalize (IH (#2 e)); clear IH
adamc@179	901 \| [ e : typeDenote ?T, IH : forall _ : exp typeDenote ?T, _ \|- _ ] =>
adamc@179	902 generalize (IH (#e)); clear IH
adamc@179	903 end; crush); eauto.
adamc@179	904 Qed.
adamc@179	905
adamc@179	906 Lemma merge_correct : forall t result
adamc@179	907 (ct1 ct2 : choice_tree typeDenote t result)
adamc@179	908 (mr : result -> result -> result) v,
adamc@179	909 grab (merge mr ct1 ct2) v = mr (grab ct1 v) (grab ct2 v).
adamc@179	910 induction t; crush.
adamc@179	911 Qed.
adamc@179	912
adamc@179	913 Lemma everywhere_fail : forall t result
adamc@179	914 (fail : result) v,
adamc@179	915 grab (everywhere (fun _ : Elab.exp typeDenote t => fail)) v = fail.
adamc@179	916 induction t; crush.
adamc@179	917 Qed.
adamc@179	918
adamc@179	919 Lemma elaboratePat_correct : forall t1 ts (p : pat t1 ts)
adamc@179	920 result (succ : hlist (Elab.exp typeDenote) ts -> result)
adamc@179	921 (fail : result) v env,
adamc@179	922 patDenote p v = Some env
adamc@179	923 -> exists env', grab (elaboratePat typeDenote p succ fail) v = succ env'
adamc@179	924 /\ env = hmap Elab.expDenote env'.
adamc@179	925 Hint Resolve hmap_happ.
adamc@179	926
adamc@179	927 induction p; crush; fold choice_tree;
adamc@179	928 repeat (match goal with
adamc@179	929 \| [ \|- context[grab (everywhere ?succ) ?v] ] =>
adamc@179	930 generalize (everywhere_correct succ (#v)%elab)
adamc@179	931
adamc@179	932 \| [ H : forall result sudc fail, _ \|- context[grab (elaboratePat _ _ ?S ?F) ?V] ] =>
adamc@179	933 generalize (H _ S F V); clear H
adamc@179	934 \| [ H1 : context[match ?E with Some _ => _ \| None => _ end],
adamc@179	935 H2 : forall env, ?E = Some env -> _ \|- _ ] =>
adamc@179	936 destruct E
adamc@179	937 \| [ H : forall env, Some ?E = Some env -> _ \|- _ ] =>
adamc@179	938 generalize (H _ (refl_equal _)); clear H
adamc@179	939 end; crush); eauto.
adamc@179	940 Qed.
adamc@179	941
adamc@179	942 Lemma elaboratePat_fails : forall t1 ts (p : pat t1 ts)
adamc@179	943 result (succ : hlist (Elab.exp typeDenote) ts -> result)
adamc@179	944 (fail : result) v,
adamc@179	945 patDenote p v = None
adamc@179	946 -> grab (elaboratePat typeDenote p succ fail) v = fail.
adamc@179	947 Hint Resolve everywhere_fail.
adamc@179	948
adamc@179	949 induction p; try solve [ crush ];
adamc@179	950 simpl; fold choice_tree; intuition; simpl in *;
adamc@179	951 repeat match goal with
adamc@179	952 \| [ IH : forall result succ fail v, patDenote ?P v = _ -> _
adamc@179	953 \|- context[grab (elaboratePat _ ?P ?S ?F) ?V] ] =>
adamc@179	954 generalize (IH _ S F V); clear IH; intro IH;
adamc@179	955 generalize (elaboratePat_correct P S F V); intros;
adamc@179	956 destruct (patDenote P V); try discriminate
adamc@179	957 \| [ H : forall env, Some _ = Some env -> _ \|- _ ] =>
adamc@179	958 destruct (H _ (refl_equal _)); clear H; intuition
adamc@179	959 \| [ H : _ \|- _ ] => rewrite H; intuition
adamc@179	960 end.
adamc@179	961 Qed.
adamc@179	962
adamc@179	963 Implicit Arguments letify [var t ts].
adamc@179	964
adamc@179	965 Lemma letify_correct : forall t ts (f : hlist typeDenote ts -> Elab.exp typeDenote t)
adamc@179	966 (env : hlist (Elab.exp typeDenote) ts),
adamc@179	967 Elab.expDenote (letify f env)
adamc@179	968 = Elab.expDenote (f (hmap Elab.expDenote env)).
adamc@179	969 induction ts; crush.
adamc@179	970 Qed.
adamc@179	971
adamc@179	972 Theorem elaborate_correct : forall t (e : Source.exp typeDenote t),
adamc@179	973 Elab.expDenote (elaborate e) = Source.expDenote e.
adamc@179	974 Hint Rewrite expand_grab merge_correct letify_correct : cpdt.
adamc@179	975 Hint Rewrite everywhere_fail elaboratePat_fails using assumption : cpdt.
adamc@179	976
adamc@179	977 induction e; crush; try (ext_eq; crush);
adamc@179	978 match goal with
adamc@179	979 \| [ tss : list (list type) \|- _ ] =>
adamc@179	980 induction tss; crush;
adamc@179	981 match goal with
adamc@179	982 \| [ \|- context[grab (elaboratePat _ ?P ?S ?F) ?V] ] =>
adamc@179	983 case_eq (patDenote P V); [intros env Heq;
adamc@179	984 destruct (elaboratePat_correct P S F _ Heq); crush;
adamc@179	985 match goal with
adamc@179	986 \| [ H : _ \|- _ ] => rewrite <- H; crush
adamc@179	987 end
adamc@179	988 \| crush ]
adamc@179	989 end
adamc@179	990 end.
adamc@179	991 Qed.
adamc@179	992
adamc@179	993 Theorem Elaborate_correct : forall t (E : Source.Exp t),
adamc@179	994 Elab.ExpDenote (Elaborate E) = Source.ExpDenote E.
adamc@179	995 unfold Elab.ExpDenote, Elaborate, Source.ExpDenote;
adamc@179	996 intros; apply elaborate_correct.
adamc@179	997 Qed.
adamc@179	998
adamc@177	999 End PatMatch.

Mercurial > cpdt > repo

annotate src/Extensional.v @ 179:8f3fc56b90d4