Removed some useless files

FiniteSets/implementations/interface.v

@@ -1,331 +0,0 @@
-Require Import HoTT.
-Require Import FSets.
-
-Section interface.
-  Context `{Univalence}.
-  Variable (T : Type -> Type)
-           (f : forall A, T A -> FSet A).
-  Context `{forall A, hasMembership (T A) A
-          , forall A, hasEmpty (T A)
-          , forall A, hasSingleton (T A) A
-          , forall A, hasUnion (T A)
-          , forall A, hasComprehension (T A) A}.
-
-  Class sets :=
-    {
-      f_empty : forall A, f A ∅ = ∅ ;
-      f_singleton : forall A a, f A (singleton a) = {|a|};
-      f_union : forall A X Y, f A (union X Y) = (f A X) ∪ (f A Y);
-      f_filter : forall A φ X, f A (filter φ X) = {| f A X & φ |};
-      f_member : forall A a X, member a X = a ∈ (f A X)
-    }.
-
-  Global Instance f_surjective A `{sets} : IsSurjection (f A).
-  Proof.
-    unfold IsSurjection.
-    hinduction ; try (intros ; apply path_ishprop).
-    - simple refine (BuildContr _ _ _).
-      * refine (tr(∅;_)).
-        apply f_empty.
-      * intros ; apply path_ishprop.
-    - intro a.
-      simple refine (BuildContr _ _ _).
-      * refine (tr({|a|};_)).
-        apply f_singleton.
-      * intros ; apply path_ishprop.
-    - intros Y1 Y2 [X1' ?] [X2' ?].
-      simple refine (BuildContr _ _ _).
-      * simple refine (Trunc_rec _ X1') ; intros [X1 fX1].
-        simple refine (Trunc_rec _ X2') ; intros [X2 fX2].
-        refine (tr(X1 ∪ X2;_)).
-        rewrite f_union, fX1, fX2.
-        reflexivity.
-      * intros ; apply path_ishprop.
-  Defined.
-
-End interface.
-
-Section quotient_surjection.
-  Variable (A B : Type)
-           (f : A -> B)
-           (H : IsSurjection f).
-  Context `{IsHSet B} `{Univalence}.
-
-  Definition f_eq : relation A := fun a1 a2 => f a1 = f a2.
-  Definition quotientB : Type := quotient f_eq.
-
-  Global Instance quotientB_recursion : HitRecursion quotientB :=
-    {
-      indTy := _;
-      recTy :=
-        forall (P : Type) (HP: IsHSet P) (u : A -> P),
-          (forall x y : A, f_eq x y -> u x = u y) -> quotientB -> P;
-      H_inductor := quotient_ind f_eq ;
-      H_recursor := @quotient_rec _ f_eq _
-    }.
-
-  Global Instance R_refl : Reflexive f_eq.
-  Proof.
-    intro.
-    reflexivity.
-  Defined.
-
-  Global Instance R_sym : Symmetric f_eq.
-  Proof.
-    intros a b Hab.
-    apply (Hab^).
-  Defined.
-
-  Global Instance R_trans : Transitive f_eq.
-  Proof.
-    intros a b c Hab Hbc.
-    apply (Hab @ Hbc).
-  Defined.
-
-  Definition quotientB_to_B : quotientB -> B.
-  Proof.
-    hrecursion.
-    - apply f.
-    - done.
-  Defined.
-    
-  Instance quotientB_emb : IsEmbedding (quotientB_to_B).
-  Proof.
-    apply isembedding_isinj_hset.
-    unfold isinj.
-    hrecursion ; [ | intros; apply path_ishprop ].
-    intro.
-    hrecursion ; [ | intros; apply path_ishprop ].
-    intros.
-      by apply related_classes_eq.
-  Defined.
-
-  Instance quotientB_surj : IsSurjection (quotientB_to_B).
-  Proof.
-    apply BuildIsSurjection.
-    intros Y.
-    destruct (H Y).
-    simple refine (Trunc_rec _ center) ; intros [a fa].
-    apply (tr(class_of _ a;fa)).
-  Defined.
-
-  Definition quotient_iso : quotientB <~> B.
-  Proof.
-    refine (BuildEquiv _ _ quotientB_to_B _).
-    apply isequiv_surj_emb ; apply _.
-  Defined.
-
-  Definition reflect_eq : forall (X Y : A),
-      f X = f Y -> f_eq X Y.
-  Proof.
-    done.
-  Defined.
-
-  Lemma same_class : forall (X Y : A),
-      class_of f_eq X = class_of f_eq Y -> f_eq X Y.
-  Proof.
-    intros.
-    simple refine (classes_eq_related _ _ _ _) ; assumption.
-  Defined.
-
-End quotient_surjection.
-
-Arguments quotient_iso {_} {_} _ {_} {_} {_}.
-  
-Ltac reduce T :=
-  intros ;
-  repeat (rewrite (f_empty T _)
-          || rewrite (f_singleton T _)
-          || rewrite (f_union T _)
-          || rewrite (f_filter T _)
-          || rewrite (f_member T _)).
-
-Section quotient_properties.
-  Variable (T : Type -> Type).
-  Variable (f : forall {A : Type}, T A -> FSet A).
-  Context `{sets T f}.
-
-  Definition set_eq A := f_eq (T A) (FSet A) (f A).
-  Definition View A : Type := quotientB (T A) (FSet A) (f A).
-
-  Instance f_is_surjective A : IsSurjection (f A).
-  Proof.
-    apply (f_surjective T f A).
-  Defined.
-    
-  Global Instance view_union (A : Type) : hasUnion (View A).
-  Proof.
-    intros X Y.
-    apply (quotient_iso _)^-1.
-    simple refine (union _ _).
-    - simple refine (quotient_iso (f A) X).
-    - simple refine (quotient_iso (f A) Y).
-  Defined.
-
-  Definition well_defined_union (A : Type) (X Y : T A) :
-    (class_of _ X) ∪ (class_of _ Y) = class_of _ (X ∪ Y).
-  Proof.
-    rewrite <- (eissect (quotient_iso _)).
-    simpl.
-    rewrite (f_union T _).
-    reflexivity.
-  Defined.
-
-  Global Instance view_comprehension (A : Type) : hasComprehension (View A) A.
-  Proof.
-    intros ϕ X.
-    apply (quotient_iso _)^-1.
-    simple refine ({|_ & ϕ|}).
-    apply (quotient_iso (f A) X).
-  Defined.
-
-  Definition well_defined_filter (A : Type) (ϕ : A -> Bool) (X : T A) :
-    {|class_of _ X & ϕ|} = class_of _ {|X & ϕ|}.
-  Proof.
-    rewrite <- (eissect (quotient_iso _)).
-    simpl.
-    rewrite (f_filter T _).
-    reflexivity.
-  Defined.
-
-  Global Instance View_empty A : hasEmpty (View A).
-  Proof.
-    apply ((quotient_iso _)^-1 ∅).
-  Defined.
-
-  Definition well_defined_empty A : ∅ = class_of (set_eq A) ∅.
-  Proof.
-    rewrite <- (eissect (quotient_iso _)).
-    simpl.
-    rewrite (f_empty T _).
-    reflexivity.
-  Defined.  
-
-  Global Instance View_singleton A: hasSingleton (View A) A.
-  Proof.
-    intro a ; apply ((quotient_iso _)^-1 {|a|}).
-  Defined.
-
-  Definition well_defined_sungleton A (a : A) : {|a|} = class_of _ {|a|}.
-  Proof.
-    rewrite <- (eissect (quotient_iso _)).
-    simpl.
-    rewrite (f_singleton T _).
-    reflexivity.
-  Defined.  
-  
-  Global Instance View_member A : hasMembership (View A) A.
-  Proof.
-    intros a ; unfold View.
-    hrecursion.
-    - apply (member a).
-    - intros X Y HXY.
-      reduce T.
-      apply (ap _ HXY).
-  Defined.
-
-  Instance View_max A : maximum (View A).
-  Proof.
-    apply view_union.
-  Defined.
-
-  Hint Unfold Commutative Associative Idempotent NeutralL NeutralR View_max view_union.
-
-  Instance bottom_view A : bottom (View A).
-  Proof.
-    apply View_empty.
-  Defined.
-
-  Ltac sq1 := autounfold ; intros ; try f_ap
-                         ; rewrite ?(eisretr (quotient_iso _))
-                         ; eauto with lattice_hints typeclass_instances.
-
-  Ltac sq2 := autounfold ; intros
-              ; rewrite <- (eissect (quotient_iso _)), ?(eisretr (quotient_iso _))
-              ; f_ap ; simpl
-              ; reduce T ; eauto with lattice_hints typeclass_instances.
-
-  Global Instance view_lattice A : JoinSemiLattice (View A).
-  Proof.
-    split ; try sq1 ; try sq2.
-  Defined.
-
-End quotient_properties.
-
-Arguments set_eq {_} _ {_} _ _.
-
-Section properties.
-  Context `{Univalence}.
-  Variable (T : Type -> Type) (f : forall A, T A -> FSet A).
-  Context `{sets T f}.
-
-  Definition set_subset : forall A, T A -> T A -> hProp :=
-    fun A X Y => (f A X) ⊆ (f A Y).
-
-  Definition empty_isIn : forall (A : Type) (a : A),
-    a ∈ ∅ = False_hp.
-  Proof.
-    by (reduce T).
-  Defined.
-
-  Definition singleton_isIn : forall (A : Type) (a b : A),
-    a ∈ {|b|} = merely (a = b).
-  Proof.
-    by (reduce T).
-  Defined.
-
-  Definition union_isIn : forall (A : Type) (a : A) (X Y : T A),
-    a ∈ (X ∪ Y) = lor (a ∈ X) (a ∈ Y).
-  Proof.
-    by (reduce T).
-  Defined.
-
-  Definition filter_isIn : forall (A : Type) (a : A) (ϕ : A -> Bool) (X : T A),
-    member a (filter ϕ X) = if ϕ a then member a X else False_hp.
-  Proof.
-    reduce T.
-    apply properties.comprehension_isIn.
-  Defined.
-
-  Definition reflect_f_eq : forall (A : Type) (X Y : T A),
-      class_of (set_eq f) X = class_of (set_eq f) Y -> set_eq f X Y.
-  Proof.
-    intros.
-    refine (same_class _ _ _ _ _ _) ; assumption.
-  Defined.
-
-  Ltac via_quotient := intros ; apply reflect_f_eq ; simpl
-                       ; rewrite <- ?(well_defined_union T _), <- ?(well_defined_empty T _)
-                       ; eauto with lattice_hints typeclass_instances.  
-
-  Lemma union_comm : forall A (X Y : T A),
-      set_eq f (X ∪ Y) (Y ∪ X).
-  Proof.
-    via_quotient.
-  Defined.
-
-  Lemma union_assoc : forall A (X Y Z : T A),
-    set_eq f ((X ∪ Y) ∪ Z) (X ∪ (Y ∪ Z)).
-  Proof.
-    via_quotient.
-  Defined.
-
-  Lemma union_idem : forall A (X : T A),
-    set_eq f (X ∪ X) X.
-  Proof.
-    via_quotient.
-  Defined.
-
-  Lemma union_neutralL : forall A (X : T A),
-    set_eq f (∅ ∪ X) X.
-  Proof.
-    via_quotient.
-  Defined.
-
-  Lemma union_neutralR : forall A (X : T A),
-    set_eq f (X ∪ ∅) X.
-  Proof.
-    via_quotient.
-  Defined.
-  
-End properties.