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(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
(** * Compatibility functors between FSetInterface and MSetInterface. *)
Require Import FSetInterface FSetFacts MSetInterface MSetFacts.
Set Implicit Arguments.
Unset Strict Implicit.
(** * From new Weak Sets to old ones *)
Module Backport_WSets
(E:DecidableType.DecidableType)
(M:MSetInterface.WSets with Definition E.t := E.t
with Definition E.eq := E.eq)
<: FSetInterface.WSfun E.
Definition elt := E.t.
Definition t := M.t.
Implicit Type s : t.
Implicit Type x y : elt.
Implicit Type f : elt -> bool.
Definition In : elt -> t -> Prop := M.In.
Definition Equal s s' := forall a : elt, In a s <-> In a s'.
Definition Subset s s' := forall a : elt, In a s -> In a s'.
Definition Empty s := forall a : elt, ~ In a s.
Definition For_all (P : elt -> Prop) s := forall x, In x s -> P x.
Definition Exists (P : elt -> Prop) s := exists x, In x s /\ P x.
Definition empty : t := M.empty.
Definition is_empty : t -> bool := M.is_empty.
Definition mem : elt -> t -> bool := M.mem.
Definition add : elt -> t -> t := M.add.
Definition singleton : elt -> t := M.singleton.
Definition remove : elt -> t -> t := M.remove.
Definition union : t -> t -> t := M.union.
Definition inter : t -> t -> t := M.inter.
Definition diff : t -> t -> t := M.diff.
Definition eq : t -> t -> Prop := M.eq.
Definition eq_dec : forall s s', {eq s s'}+{~eq s s'}:= M.eq_dec.
Definition equal : t -> t -> bool := M.equal.
Definition subset : t -> t -> bool := M.subset.
Definition fold : forall A : Type, (elt -> A -> A) -> t -> A -> A := M.fold.
Definition for_all : (elt -> bool) -> t -> bool := M.for_all.
Definition exists_ : (elt -> bool) -> t -> bool := M.exists_.
Definition filter : (elt -> bool) -> t -> t := M.filter.
Definition partition : (elt -> bool) -> t -> t * t:= M.partition.
Definition cardinal : t -> nat := M.cardinal.
Definition elements : t -> list elt := M.elements.
Definition choose : t -> option elt := M.choose.
Module MF := MSetFacts.WFacts M.
Definition In_1 : forall s x y, E.eq x y -> In x s -> In y s
:= MF.In_1.
Definition eq_refl : forall s, eq s s
:= @Equivalence_Reflexive _ _ M.eq_equiv.
Definition eq_sym : forall s s', eq s s' -> eq s' s
:= @Equivalence_Symmetric _ _ M.eq_equiv.
Definition eq_trans : forall s s' s'', eq s s' -> eq s' s'' -> eq s s''
:= @Equivalence_Transitive _ _ M.eq_equiv.
Definition mem_1 : forall s x, In x s -> mem x s = true
:= MF.mem_1.
Definition mem_2 : forall s x, mem x s = true -> In x s
:= MF.mem_2.
Definition equal_1 : forall s s', Equal s s' -> equal s s' = true
:= MF.equal_1.
Definition equal_2 : forall s s', equal s s' = true -> Equal s s'
:= MF.equal_2.
Definition subset_1 : forall s s', Subset s s' -> subset s s' = true
:= MF.subset_1.
Definition subset_2 : forall s s', subset s s' = true -> Subset s s'
:= MF.subset_2.
Definition empty_1 : Empty empty := MF.empty_1.
Definition is_empty_1 : forall s, Empty s -> is_empty s = true
:= MF.is_empty_1.
Definition is_empty_2 : forall s, is_empty s = true -> Empty s
:= MF.is_empty_2.
Definition add_1 : forall s x y, E.eq x y -> In y (add x s)
:= MF.add_1.
Definition add_2 : forall s x y, In y s -> In y (add x s)
:= MF.add_2.
Definition add_3 : forall s x y, ~ E.eq x y -> In y (add x s) -> In y s
:= MF.add_3.
Definition remove_1 : forall s x y, E.eq x y -> ~ In y (remove x s)
:= MF.remove_1.
Definition remove_2 : forall s x y, ~ E.eq x y -> In y s -> In y (remove x s)
:= MF.remove_2.
Definition remove_3 : forall s x y, In y (remove x s) -> In y s
:= MF.remove_3.
Definition union_1 : forall s s' x, In x (union s s') -> In x s \/ In x s'
:= MF.union_1.
Definition union_2 : forall s s' x, In x s -> In x (union s s')
:= MF.union_2.
Definition union_3 : forall s s' x, In x s' -> In x (union s s')
:= MF.union_3.
Definition inter_1 : forall s s' x, In x (inter s s') -> In x s
:= MF.inter_1.
Definition inter_2 : forall s s' x, In x (inter s s') -> In x s'
:= MF.inter_2.
Definition inter_3 : forall s s' x, In x s -> In x s' -> In x (inter s s')
:= MF.inter_3.
Definition diff_1 : forall s s' x, In x (diff s s') -> In x s
:= MF.diff_1.
Definition diff_2 : forall s s' x, In x (diff s s') -> ~ In x s'
:= MF.diff_2.
Definition diff_3 : forall s s' x, In x s -> ~ In x s' -> In x (diff s s')
:= MF.diff_3.
Definition singleton_1 : forall x y, In y (singleton x) -> E.eq x y
:= MF.singleton_1.
Definition singleton_2 : forall x y, E.eq x y -> In y (singleton x)
:= MF.singleton_2.
Definition fold_1 : forall s (A : Type) (i : A) (f : elt -> A -> A),
fold f s i = fold_left (fun a e => f e a) (elements s) i
:= MF.fold_1.
Definition cardinal_1 : forall s, cardinal s = length (elements s)
:= MF.cardinal_1.
Definition filter_1 : forall s x f, compat_bool E.eq f ->
In x (filter f s) -> In x s
:= MF.filter_1.
Definition filter_2 : forall s x f, compat_bool E.eq f ->
In x (filter f s) -> f x = true
:= MF.filter_2.
Definition filter_3 : forall s x f, compat_bool E.eq f ->
In x s -> f x = true -> In x (filter f s)
:= MF.filter_3.
Definition for_all_1 : forall s f, compat_bool E.eq f ->
For_all (fun x => f x = true) s -> for_all f s = true
:= MF.for_all_1.
Definition for_all_2 : forall s f, compat_bool E.eq f ->
for_all f s = true -> For_all (fun x => f x = true) s
:= MF.for_all_2.
Definition exists_1 : forall s f, compat_bool E.eq f ->
Exists (fun x => f x = true) s -> exists_ f s = true
:= MF.exists_1.
Definition exists_2 : forall s f, compat_bool E.eq f ->
exists_ f s = true -> Exists (fun x => f x = true) s
:= MF.exists_2.
Definition partition_1 : forall s f, compat_bool E.eq f ->
Equal (fst (partition f s)) (filter f s)
:= MF.partition_1.
Definition partition_2 : forall s f, compat_bool E.eq f ->
Equal (snd (partition f s)) (filter (fun x => negb (f x)) s)
:= MF.partition_2.
Definition choose_1 : forall s x, choose s = Some x -> In x s
:= MF.choose_1.
Definition choose_2 : forall s, choose s = None -> Empty s
:= MF.choose_2.
Definition elements_1 : forall s x, In x s -> InA E.eq x (elements s)
:= MF.elements_1.
Definition elements_2 : forall s x, InA E.eq x (elements s) -> In x s
:= MF.elements_2.
Definition elements_3w : forall s, NoDupA E.eq (elements s)
:= MF.elements_3w.
End Backport_WSets.
(** * From new Sets to new ones *)
Module Backport_Sets
(E:OrderedType.OrderedType)
(M:MSetInterface.Sets with Definition E.t := E.t
with Definition E.eq := E.eq
with Definition E.lt := E.lt)
<: FSetInterface.S with Module E:=E.
Include Backport_WSets E M.
Implicit Type s : t.
Implicit Type x y : elt.
Definition lt : t -> t -> Prop := M.lt.
Definition min_elt : t -> option elt := M.min_elt.
Definition max_elt : t -> option elt := M.max_elt.
Definition min_elt_1 : forall s x, min_elt s = Some x -> In x s
:= M.min_elt_spec1.
Definition min_elt_2 : forall s x y,
min_elt s = Some x -> In y s -> ~ E.lt y x
:= M.min_elt_spec2.
Definition min_elt_3 : forall s, min_elt s = None -> Empty s
:= M.min_elt_spec3.
Definition max_elt_1 : forall s x, max_elt s = Some x -> In x s
:= M.max_elt_spec1.
Definition max_elt_2 : forall s x y,
max_elt s = Some x -> In y s -> ~ E.lt x y
:= M.max_elt_spec2.
Definition max_elt_3 : forall s, max_elt s = None -> Empty s
:= M.max_elt_spec3.
Definition elements_3 : forall s, sort E.lt (elements s)
:= M.elements_spec2.
Definition choose_3 : forall s s' x y,
choose s = Some x -> choose s' = Some y -> Equal s s' -> E.eq x y
:= M.choose_spec3.
Definition lt_trans : forall s s' s'', lt s s' -> lt s' s'' -> lt s s''
:= @StrictOrder_Transitive _ _ M.lt_strorder.
Lemma lt_not_eq : forall s s', lt s s' -> ~ eq s s'.
Proof.
unfold lt, eq. intros s s' Hlt Heq. rewrite Heq in Hlt.
apply (StrictOrder_Irreflexive s'); auto.
Qed.
Definition compare : forall s s', Compare lt eq s s'.
Proof.
intros s s'; destruct (CompSpec2Type (M.compare_spec s s'));
[ apply EQ | apply LT | apply GT ]; auto.
Defined.
Module E := E.
End Backport_Sets.
(** * From old Weak Sets to new ones. *)
Module Update_WSets
(E:Equalities.DecidableType)
(M:FSetInterface.WS with Definition E.t := E.t
with Definition E.eq := E.eq)
<: MSetInterface.WSetsOn E.
Definition elt := E.t.
Definition t := M.t.
Implicit Type s : t.
Implicit Type x y : elt.
Implicit Type f : elt -> bool.
Definition In : elt -> t -> Prop := M.In.
Definition Equal s s' := forall a : elt, In a s <-> In a s'.
Definition Subset s s' := forall a : elt, In a s -> In a s'.
Definition Empty s := forall a : elt, ~ In a s.
Definition For_all (P : elt -> Prop) s := forall x, In x s -> P x.
Definition Exists (P : elt -> Prop) s := exists x, In x s /\ P x.
Definition empty : t := M.empty.
Definition is_empty : t -> bool := M.is_empty.
Definition mem : elt -> t -> bool := M.mem.
Definition add : elt -> t -> t := M.add.
Definition singleton : elt -> t := M.singleton.
Definition remove : elt -> t -> t := M.remove.
Definition union : t -> t -> t := M.union.
Definition inter : t -> t -> t := M.inter.
Definition diff : t -> t -> t := M.diff.
Definition eq : t -> t -> Prop := M.eq.
Definition eq_dec : forall s s', {eq s s'}+{~eq s s'}:= M.eq_dec.
Definition equal : t -> t -> bool := M.equal.
Definition subset : t -> t -> bool := M.subset.
Definition fold : forall A : Type, (elt -> A -> A) -> t -> A -> A := M.fold.
Definition for_all : (elt -> bool) -> t -> bool := M.for_all.
Definition exists_ : (elt -> bool) -> t -> bool := M.exists_.
Definition filter : (elt -> bool) -> t -> t := M.filter.
Definition partition : (elt -> bool) -> t -> t * t:= M.partition.
Definition cardinal : t -> nat := M.cardinal.
Definition elements : t -> list elt := M.elements.
Definition choose : t -> option elt := M.choose.
Module MF := FSetFacts.WFacts M.
Instance In_compat : Proper (E.eq==>Logic.eq==>iff) In.
Proof. intros x x' Hx s s' Hs. subst. apply MF.In_eq_iff; auto. Qed.
Instance eq_equiv : Equivalence eq.
Section Spec.
Variable s s': t.
Variable x y : elt.
Lemma mem_spec : mem x s = true <-> In x s.
Proof. intros; symmetry; apply MF.mem_iff. Qed.
Lemma equal_spec : equal s s' = true <-> Equal s s'.
Proof. intros; symmetry; apply MF.equal_iff. Qed.
Lemma subset_spec : subset s s' = true <-> Subset s s'.
Proof. intros; symmetry; apply MF.subset_iff. Qed.
Definition empty_spec : Empty empty := M.empty_1.
Lemma is_empty_spec : is_empty s = true <-> Empty s.
Proof. intros; symmetry; apply MF.is_empty_iff. Qed.
Lemma add_spec : In y (add x s) <-> E.eq y x \/ In y s.
Proof. intros. rewrite MF.add_iff. intuition. Qed.
Lemma remove_spec : In y (remove x s) <-> In y s /\ ~E.eq y x.
Proof. intros. rewrite MF.remove_iff. intuition. Qed.
Lemma singleton_spec : In y (singleton x) <-> E.eq y x.
Proof. intros; rewrite MF.singleton_iff. intuition. Qed.
Definition union_spec : In x (union s s') <-> In x s \/ In x s'
:= @MF.union_iff s s' x.
Definition inter_spec : In x (inter s s') <-> In x s /\ In x s'
:= @MF.inter_iff s s' x.
Definition diff_spec : In x (diff s s') <-> In x s /\ ~In x s'
:= @MF.diff_iff s s' x.
Definition fold_spec : forall (A : Type) (i : A) (f : elt -> A -> A),
fold f s i = fold_left (flip f) (elements s) i
:= @M.fold_1 s.
Definition cardinal_spec : cardinal s = length (elements s)
:= @M.cardinal_1 s.
Lemma elements_spec1 : InA E.eq x (elements s) <-> In x s.
Proof. intros; symmetry; apply MF.elements_iff. Qed.
Definition elements_spec2w : NoDupA E.eq (elements s)
:= @M.elements_3w s.
Definition choose_spec1 : choose s = Some x -> In x s
:= @M.choose_1 s x.
Definition choose_spec2 : choose s = None -> Empty s
:= @M.choose_2 s.
Definition filter_spec : forall f, Proper (E.eq==>Logic.eq) f ->
(In x (filter f s) <-> In x s /\ f x = true)
:= @MF.filter_iff s x.
Definition partition_spec1 : forall f, Proper (E.eq==>Logic.eq) f ->
Equal (fst (partition f s)) (filter f s)
:= @M.partition_1 s.
Definition partition_spec2 : forall f, Proper (E.eq==>Logic.eq) f ->
Equal (snd (partition f s)) (filter (fun x => negb (f x)) s)
:= @M.partition_2 s.
Lemma for_all_spec : forall f, Proper (E.eq==>Logic.eq) f ->
(for_all f s = true <-> For_all (fun x => f x = true) s).
Proof. intros; symmetry; apply MF.for_all_iff; auto. Qed.
Lemma exists_spec : forall f, Proper (E.eq==>Logic.eq) f ->
(exists_ f s = true <-> Exists (fun x => f x = true) s).
Proof. intros; symmetry; apply MF.exists_iff; auto. Qed.
End Spec.
End Update_WSets.
(** * From old Sets to new ones. *)
Module Update_Sets
(E:Orders.OrderedType)
(M:FSetInterface.S with Definition E.t := E.t
with Definition E.eq := E.eq
with Definition E.lt := E.lt)
<: MSetInterface.Sets with Module E:=E.
Include Update_WSets E M.
Implicit Type s : t.
Implicit Type x y : elt.
Definition lt : t -> t -> Prop := M.lt.
Definition min_elt : t -> option elt := M.min_elt.
Definition max_elt : t -> option elt := M.max_elt.
Definition min_elt_spec1 : forall s x, min_elt s = Some x -> In x s
:= M.min_elt_1.
Definition min_elt_spec2 : forall s x y,
min_elt s = Some x -> In y s -> ~ E.lt y x
:= M.min_elt_2.
Definition min_elt_spec3 : forall s, min_elt s = None -> Empty s
:= M.min_elt_3.
Definition max_elt_spec1 : forall s x, max_elt s = Some x -> In x s
:= M.max_elt_1.
Definition max_elt_spec2 : forall s x y,
max_elt s = Some x -> In y s -> ~ E.lt x y
:= M.max_elt_2.
Definition max_elt_spec3 : forall s, max_elt s = None -> Empty s
:= M.max_elt_3.
Definition elements_spec2 : forall s, sort E.lt (elements s)
:= M.elements_3.
Definition choose_spec3 : forall s s' x y,
choose s = Some x -> choose s' = Some y -> Equal s s' -> E.eq x y
:= M.choose_3.
Instance lt_strorder : StrictOrder lt.
Proof.
split.
intros x Hx. apply (M.lt_not_eq Hx); auto with *.
exact M.lt_trans.
Qed.
Instance lt_compat : Proper (eq==>eq==>iff) lt.
Proof.
apply proper_sym_impl_iff_2; auto with *.
intros s s' Hs u u' Hu H.
assert (H0 : lt s' u).
destruct (M.compare s' u) as [H'|H'|H']; auto.
elim (M.lt_not_eq H). transitivity s'; auto with *.
elim (M.lt_not_eq (M.lt_trans H H')); auto.
destruct (M.compare s' u') as [H'|H'|H']; auto.
elim (M.lt_not_eq H).
transitivity u'; auto with *. transitivity s'; auto with *.
elim (M.lt_not_eq (M.lt_trans H' H0)); auto with *.
Qed.
Definition compare s s' :=
match M.compare s s' with
| EQ _ => Eq
| LT _ => Lt
| GT _ => Gt
end.
Lemma compare_spec : forall s s', CompSpec eq lt s s' (compare s s').
Proof. intros; unfold compare; destruct M.compare; auto. Qed.
Module E := E.
End Update_Sets.
|