Mercurial > urweb
comparison src/coq/Semantics.v @ 635:75c7a69354d6
Coq formalization uses TDisjoint
| author | Adam Chlipala <adamc@hcoop.net> |
|---|---|
| date | Tue, 24 Feb 2009 16:08:14 -0500 |
| parents | d828b143e147 |
| children | 705cb41ac7d0 |
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| 634:6302b10dbe0e | 635:75c7a69354d6 |
|---|---|
| 46 | KName => name | 46 | KName => name |
| 47 | KArrow k1 k2 => kDen k1 -> kDen k2 | 47 | KArrow k1 k2 => kDen k1 -> kDen k2 |
| 48 | KRecord k1 => row (kDen k1) | 48 | KRecord k1 => row (kDen k1) |
| 49 end. | 49 end. |
| 50 | 50 |
| 51 Fixpoint kDefault (k : kind) : kDen k := | 51 Definition disjoint T (r1 r2 : row T) := |
| 52 match k return kDen k with | 52 forall n, match r1 n, r2 n with |
| 53 | KType => unit | 53 | Some _, Some _ => False |
| 54 | KName => defaultName | 54 | _, _ => True |
| 55 | KArrow _ k2 => fun _ => kDefault k2 | 55 end. |
| 56 | KRecord _ => fun _ => None | |
| 57 end. | |
| 58 | 56 |
| 59 Fixpoint cDen k (c : con kDen k) {struct c} : kDen k := | 57 Fixpoint cDen k (c : con kDen k) {struct c} : kDen k := |
| 60 match c in con _ k return kDen k with | 58 match c in con _ k return kDen k with |
| 61 | CVar _ x => x | 59 | CVar _ x => x |
| 62 | Arrow c1 c2 => cDen c1 -> cDen c2 | 60 | Arrow c1 c2 => cDen c1 -> cDen c2 |
| 73 end | 71 end |
| 74 | CMap k1 k2 => fun f r n => match r n with | 72 | CMap k1 k2 => fun f r n => match r n with |
| 75 | None => None | 73 | None => None |
| 76 | Some T => Some (f T) | 74 | Some T => Some (f T) |
| 77 end | 75 end |
| 78 | CGuarded _ _ c1 c2 c => | 76 | TGuarded _ c1 c2 t => disjoint (cDen c1) (cDen c2) -> cDen t |
| 79 if badName (fun n => match (cDen c1) n, (cDen c2) n with | |
| 80 | Some _, Some _ => false | |
| 81 | _, _ => true | |
| 82 end) | |
| 83 then kDefault _ | |
| 84 else cDen c | |
| 85 end. | 77 end. |
| 86 | 78 |
| 87 Theorem subs_correct : forall k1 (c1 : con kDen k1) k2 (c2 : _ -> con kDen k2) c2', | 79 Theorem subs_correct : forall k1 (c1 : con kDen k1) k2 (c2 : _ -> con kDen k2) c2', |
| 88 subs c1 c2 c2' | 80 subs c1 c2 c2' |
| 89 -> cDen (c2 (cDen c1)) = cDen c2'. | 81 -> cDen (c2 (cDen c1)) = cDen c2'. |
| 91 repeat match goal with | 83 repeat match goal with |
| 92 | [ H : _ |- _ ] => rewrite H | 84 | [ H : _ |- _ ] => rewrite H |
| 93 end; intuition. | 85 end; intuition. |
| 94 Qed. | 86 Qed. |
| 95 | 87 |
| 96 Definition disjoint T (r1 r2 : row T) := | |
| 97 forall n, match r1 n, r2 n with | |
| 98 | Some _, Some _ => False | |
| 99 | _, _ => True | |
| 100 end. | |
| 101 Definition dvar k (c1 c2 : con kDen (KRecord k)) := | 88 Definition dvar k (c1 c2 : con kDen (KRecord k)) := |
| 102 disjoint (cDen c1) (cDen c2). | 89 disjoint (cDen c1) (cDen c2). |
| 103 | 90 |
| 104 Theorem known_badName : forall T (r1 r2 : row T) T' (v1 v2 : T'), | |
| 105 disjoint r1 r2 | |
| 106 -> (if badName (fun n => match r1 n, r2 n with | |
| 107 | Some _, Some _ => false | |
| 108 | _, _ => true | |
| 109 end) | |
| 110 then v1 | |
| 111 else v2) = v2. | |
| 112 intros; match goal with | |
| 113 | [ |- context[if ?E then _ else _] ] => destruct E | |
| 114 end; firstorder; | |
| 115 match goal with | |
| 116 | [ H : disjoint _ _, x : name |- _ ] => | |
| 117 generalize (H x); | |
| 118 repeat match goal with | |
| 119 | [ |- context[match ?E with None => _ | Some _ => _ end] ] => destruct E | |
| 120 end; tauto || congruence | |
| 121 end. | |
| 122 Qed. | |
| 123 | |
| 124 Hint Rewrite known_badName using solve [ auto ] : Semantics. | |
| 125 | |
| 126 Scheme deq_mut := Minimality for deq Sort Prop | 91 Scheme deq_mut := Minimality for deq Sort Prop |
| 127 with disj_mut := Minimality for disj Sort Prop. | 92 with disj_mut := Minimality for disj Sort Prop. |
| 128 | 93 |
| 129 Ltac deq_disj_correct scm := | 94 Ltac deq_disj_correct scm := |
| 130 let t := repeat progress (simpl; intuition; subst; autorewrite with Semantics) in | 95 let t := repeat progress (simpl; intuition; subst) in |
| 131 | 96 |
| 132 let rec use_disjoint' notDone E := | 97 let rec use_disjoint' notDone E := |
| 133 match goal with | 98 match goal with |
| 134 | [ H : disjoint _ _ |- _ ] => | 99 | [ H : disjoint _ _ |- _ ] => |
| 135 notDone H; generalize (H E); use_disjoint' | 100 notDone H; generalize (H E); use_disjoint' |
| 161 | [ _ : context[match cDen ?C ?E with Some _ => _ | None => _ end] |- _ ] => | 126 | [ _ : context[match cDen ?C ?E with Some _ => _ | None => _ end] |- _ ] => |
| 162 use_disjoint E; destruct (cDen C E) | 127 use_disjoint E; destruct (cDen C E) |
| 163 | [ |- context[if ?E then _ else _] ] => destruct E | 128 | [ |- context[if ?E then _ else _] ] => destruct E |
| 164 end; t). | 129 end; t). |
| 165 | 130 |
| 166 Lemma bool_disjoint : forall T (r1 r2 : row T), | |
| 167 (forall nm : name, | |
| 168 match r1 nm with | |
| 169 | Some _ => match r2 nm with | |
| 170 | Some _ => false | |
| 171 | None => true | |
| 172 end | |
| 173 | None => true | |
| 174 end = true) | |
| 175 -> disjoint r1 r2. | |
| 176 intros; intro; | |
| 177 match goal with | |
| 178 | [ H : _, n : name |- _ ] => generalize (H n) | |
| 179 end; | |
| 180 repeat match goal with | |
| 181 | [ |- context[match ?E with Some _ => _ | None => _ end] ] => destruct E | |
| 182 end; tauto || discriminate. | |
| 183 Qed. | |
| 184 | |
| 185 Implicit Arguments bool_disjoint [T r1 r2]. | |
| 186 | |
| 187 Hint Resolve bool_disjoint. | |
| 188 Hint Unfold dvar. | 131 Hint Unfold dvar. |
| 189 | 132 |
| 190 Theorem deq_correct : forall k (c1 c2 : con kDen k), | 133 Theorem deq_correct : forall k (c1 c2 : con kDen k), |
| 191 deq dvar c1 c2 | 134 deq dvar c1 c2 |
| 192 -> cDen c1 = cDen c2. | 135 -> cDen c1 = cDen c2. |
| 222 end; rewrite name_eq_dec_refl; | 165 end; rewrite name_eq_dec_refl; |
| 223 destruct (r n1); intuition. | 166 destruct (r n1); intuition. |
| 224 Qed. | 167 Qed. |
| 225 | 168 |
| 226 Implicit Arguments cut_disjoint [v r]. | 169 Implicit Arguments cut_disjoint [v r]. |
| 227 | |
| 228 Set Printing All. | |
| 229 | 170 |
| 230 Fixpoint eDen t (e : exp dvar tDen t) {struct e} : tDen t := | 171 Fixpoint eDen t (e : exp dvar tDen t) {struct e} : tDen t := |
| 231 match e in exp _ _ t return tDen t with | 172 match e in exp _ _ t return tDen t with |
| 232 | Var _ x => x | 173 | Var _ x => x |
| 233 | App _ _ e1 e2 => (eDen e1) (eDen e2) | 174 | App _ _ e1 e2 => (eDen e1) (eDen e2) |
| 284 end with | 225 end with |
| 285 | None => fun _ => (eDen e2) n | 226 | None => fun _ => (eDen e2) n |
| 286 | _ => fun x => x | 227 | _ => fun x => x |
| 287 end ((eDen e1) n) | 228 end ((eDen e1) n) |
| 288 | 229 |
| 289 | Guarded _ c1 c2 _ e1 => | 230 | Guarded _ _ _ _ e1 => fun pf => eDen (e1 pf) |
| 290 match badName (fun n => match (cDen c1) n, (cDen c2) n with | 231 | GuardedApp _ _ _ _ e1 Hdisj => (eDen e1) (disj_correct Hdisj) |
| 291 | Some _, Some _ => false | |
| 292 | _, _ => true | |
| 293 end) | |
| 294 as BN return (if BN return Set then _ else _) with | |
| 295 | inleft _ => tt | |
| 296 | inright pf => eDen (e1 (bool_disjoint pf)) | |
| 297 end | |
| 298 end. | 232 end. |