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Commit e09f7ce3 authored by Robbert Krebbers's avatar Robbert Krebbers
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Add class `TopSet` for sets with ⊤ element.

This closes issue #49.
parent ddfcc76c
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......@@ -1202,16 +1202,18 @@ Notation "⊥" := bottom (format "⊥") : stdpp_scope.
(** * Axiomatization of sets *)
(** The classes [SemiSet A C] and [Set_ A C] axiomatize sset of type [C] with
elements of type [A]. The first class, [SemiSet] does not include intersection
and difference. It is useful for the case of lists, where decidable equality
is needed to implement intersection and difference, but not union.
(** The classes [SemiSet A C], [Set_ A C], and [TopSet A C] axiomatize sets of
type [C] with elements of type [A]. The first class, [SemiSet] does not include
intersection and difference. It is useful for the case of lists, where decidable
equality is needed to implement intersection and difference, but not union.
Note that we cannot use the name [Set] since that is a reserved keyword. Hence
we use [Set_]. *)
Class SemiSet A C `{ElemOf A C,
Empty C, Singleton A C, Union C} : Prop := {
not_elem_of_empty (x : A) : x ∉@{C} ;
not_elem_of_empty (x : A) : x ∉@{C} ; (* We prove
[elem_of_empty : x ∈@{C} ∅ ↔ False] in [sets.v], which is more convenient for
rewriting. *)
elem_of_singleton (x y : A) : x ∈@{C} {[ y ]} x = y;
elem_of_union (X Y : C) (x : A) : x X Y x X x Y
}.
......@@ -1221,6 +1223,12 @@ Class Set_ A C `{ElemOf A C, Empty C, Singleton A C,
elem_of_intersection (X Y : C) (x : A) : x X Y x X x Y;
elem_of_difference (X Y : C) (x : A) : x X Y x X x Y
}.
Class TopSet A C `{ElemOf A C, Empty C, Top C, Singleton A C,
Union C, Intersection C, Difference C} : Prop := {
top_set_set :> Set_ A C;
elem_of_top' (x : A) : x ∈@{C} ; (* We prove [elem_of_top : x ∈@{C} ⊤ ↔ True]
in [sets.v], which is more convenient for rewriting. *)
}.
(** We axiomative a finite set as a set whose elements can be
enumerated as a list. These elements, given by the [elements] function, may be
......
......@@ -169,9 +169,9 @@ Instance coPset_difference : Difference coPset := λ X Y,
let (t1,Ht1) := X in let (t2,Ht2) := Y in
(t1 coPset_opp_raw t2) coPset_intersection_wf _ _ Ht1 (coPset_opp_wf _).
Instance coPset_set : Set_ positive coPset.
Instance coPset_top_set : TopSet positive coPset.
Proof.
split; [split| |].
split; [split; [split| |]|].
- by intros ??.
- intros p q. apply coPset_elem_of_singleton.
- intros [t] [t'] p; unfold elem_of, coPset_elem_of, coPset_union; simpl.
......@@ -181,6 +181,7 @@ Proof.
- intros [t] [t'] p; unfold elem_of, coPset_elem_of, coPset_difference; simpl.
by rewrite coPset_elem_of_intersection,
coPset_elem_of_opp, andb_True, negb_True.
- done.
Qed.
Instance coPset_leibniz : LeibnizEquiv coPset.
......@@ -204,11 +205,6 @@ Proof.
refine (λ X Y, cast_if (decide (X Y = Y))); abstract (by rewrite subseteq_union_L).
Defined.
(** * Top *)
Lemma coPset_top_subseteq (X : coPset) : X .
Proof. done. Qed.
Hint Resolve coPset_top_subseteq : core.
(** * Finite sets *)
Fixpoint coPset_finite (t : coPset_raw) : bool :=
match t with
......
......@@ -80,6 +80,7 @@ Create HintDb ndisj.
considering they are. *)
Hint Resolve (subseteq_difference_r (A:=positive) (C:=coPset)) : ndisj.
Hint Resolve (empty_subseteq (A:=positive) (C:=coPset)) : ndisj.
Hint Resolve (top_subseteq (A:=positive) (C:=coPset)) : ndisj.
Hint Resolve (union_least (A:=positive) (C:=coPset)) : ndisj.
(** Fallback, loses lots of information but lets other rules make progress. *)
Hint Resolve (subseteq_difference_l (A:=positive) (C:=coPset)) | 100 : ndisj.
......
......@@ -21,18 +21,13 @@ Instance propset_intersection {A} : Intersection (propset A) := λ X1 X2,
{[ x | x X1 x X2 ]}.
Instance propset_difference {A} : Difference (propset A) := λ X1 X2,
{[ x | x X1 x X2 ]}.
Instance propset_set : Set_ A (propset A).
Proof. split; [split | |]; by repeat intro. Qed.
Instance propset_top_set {A} : TopSet A (propset A).
Proof. split; [split; [split| |]|]; by repeat intro. Qed.
Lemma elem_of_top {A} (x : A) : x ( : propset A) True.
Proof. done. Qed.
Lemma elem_of_PropSet {A} (P : A Prop) x : x {[ x | P x ]} P x.
Proof. done. Qed.
Lemma not_elem_of_PropSet {A} (P : A Prop) x : x {[ x | P x ]} ¬P x.
Proof. done. Qed.
Lemma top_subseteq {A} (X : propset A) : X .
Proof. done. Qed.
Hint Resolve top_subseteq : core.
Definition set_to_propset `{ElemOf A C} (X : C) : propset A :=
{[ x | x X ]}.
......@@ -50,8 +45,6 @@ Instance propset_join : MJoin propset := λ A (XX : propset (propset A)),
Instance propset_monad_set : MonadSet propset.
Proof. by split; try apply _. Qed.
Instance set_unfold_propset_top {A} (x : A) : SetUnfoldElemOf x ( : propset A) True.
Proof. by constructor. Qed.
Instance set_unfold_PropSet {A} (P : A Prop) x Q :
SetUnfoldSimpl (P x) Q SetUnfoldElemOf x (PropSet P) Q.
Proof. intros HPQ. constructor. apply HPQ. Qed.
......
......@@ -242,6 +242,10 @@ Section set_unfold.
Qed.
End set_unfold.
Instance set_unfold_top `{TopSet A C} (x : A) :
SetUnfoldElemOf x ( : C) True.
Proof. constructor. split; [done|intros; apply elem_of_top']. Qed.
Section set_unfold_monad.
Context `{MonadSet M}.
......@@ -793,6 +797,19 @@ Section set.
End set.
(** * Sets with [∪], [∩], [∖], [∅], [{[_]}], and [⊤] *)
Section top_set.
Context `{TopSet A C}.
Implicit Types x y : A.
Implicit Types X Y : C.
Lemma elem_of_top x : x ∈@{C} True.
Proof. split; [done|intros; apply elem_of_top']. Qed.
Lemma top_subseteq X : X .
Proof. intros x. by rewrite elem_of_top. Qed.
End top_set.
(** * Conversion of option and list *)
Section option_and_list_to_set.
Context `{SemiSet A C}.
......
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