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Quellcode-Bibliothek
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Datei: DecidableTypeEx.v Sprache: Unknown
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(* * The Coq Proof Assistant / The Coq Development Team *) (* v * INRIA, CNRS and contributors - Copyright 1999-2018 *) (* <O___,, * (see CREDITS file for the list of authors) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) Require Import DecidableType OrderedType OrderedTypeEx. Set Implicit Arguments. Unset Strict Implicit. (** NB: This file is here only for compatibility with earlier version of [FSets] and [FMap]. Please use [Structures/Equalities.v] directly now. *) (** * Examples of Decidable Type structures. *) (** A particular case of [DecidableType] where the equality is the usual one of Coq. *) Module Type UsualDecidableType := Equalities.UsualDecidableTypeOrig. (** a [UsualDecidableType] is in particular an [DecidableType]. *) Module UDT_to_DT (U:UsualDecidableType) <: DecidableType := U. (** an shortcut for easily building a UsualDecidableType *) Module Type MiniDecidableType := Equalities.MiniDecidableType. Module Make_UDT (M:MiniDecidableType) <: UsualDecidableType := Equalities.Make_UDT M. (** An OrderedType can now directly be seen as a DecidableType *) Module OT_as_DT (O:OrderedType) <: DecidableType := O. (** (Usual) Decidable Type for [nat], [positive], [N], [Z] *) Module Nat_as_DT <: UsualDecidableType := Nat_as_OT. Module Positive_as_DT <: UsualDecidableType := Positive_as_OT. Module N_as_DT <: UsualDecidableType := N_as_OT. Module Z_as_DT <: UsualDecidableType := Z_as_OT. (** From two decidable types, we can build a new DecidableType over their cartesian product. *) Module PairDecidableType(D1 D2:DecidableType) <: DecidableType. Definition t := prod D1.t D2.t. Definition eq x y := D1.eq (fst x) (fst y) /\ D2.eq (snd x) (snd y). Lemma eq_refl : forall x : t, eq x x. Proof. intros (x1,x2); red; simpl; auto. Qed. Lemma eq_sym : forall x y : t, eq x y -> eq y x. Proof. intros (x1,x2) (y1,y2); unfold eq; simpl; intuition. Qed. Lemma eq_trans : forall x y z : t, eq x y -> eq y z -> eq x z. Proof. intros (x1,x2) (y1,y2) (z1,z2); unfold eq; simpl; intuition eauto. Qed. Definition eq_dec : forall x y, { eq x y }+{ ~eq x y }. Proof. intros (x1,x2) (y1,y2); unfold eq; simpl. destruct (D1.eq_dec x1 y1); destruct (D2.eq_dec x2 y2); intuition. Defined. End PairDecidableType. (** Similarly for pairs of UsualDecidableType *) Module PairUsualDecidableType(D1 D2:UsualDecidableType) <: UsualDecidableType. Definition t := prod D1.t D2.t. Definition eq := @eq t. Definition eq_refl := @eq_refl t. Definition eq_sym := @eq_sym t. Definition eq_trans := @eq_trans t. Definition eq_dec : forall x y, { eq x y }+{ ~eq x y }. Proof. intros (x1,x2) (y1,y2); destruct (D1.eq_dec x1 y1); destruct (D2.eq_dec x2 y2); unfold eq, D1.eq, D2.eq in *; simpl; (left; f_equal; auto; fail) || (right; injection; auto). Defined. End PairUsualDecidableType. [ Verzeichnis aufwärts0.22unsichere Verbindung Übersetzung europäischer Sprachen durch Browser ] |