Setup for finite sets library.

2017-05-23 16:30:31 +02:00 · 2017-05-23 16:30:31 +02:00 · 13737556c6
parent c024e27338
commit 13737556c6
4 changed files with 546 additions and 0 deletions
--- a/FiniteSets/_CoqProject
+++ b/FiniteSets/_CoqProject
@ -0,0 +1,5 @@
 -R . "" COQC = hoqc COQDEP = hoqdep
 definition.v
 operations.v
 properties.v
--- a/FiniteSets/definition.v
+++ b/FiniteSets/definition.v
@ -0,0 +1,207 @@
 Require Import HoTT.
 Require Export HoTT.
 Module Export definition.
 Section FSet.
 Variable A : Type.
 Private Inductive FSet : Type :=
  | E : FSet
  | L : A -> FSet
  | U : FSet -> FSet -> FSet.
 Notation "{| x |}" :=  (L x).
 Infix "∪" := U (at level 8, right associativity).
 Notation "∅" := E.
 Axiom assoc : forall (x y z : FSet ),
  x ∪ (y ∪ z) = (x ∪ y) ∪ z.
 Axiom comm : forall (x y : FSet),
  x ∪ y = y ∪ x.
 Axiom nl : forall (x : FSet),
  ∅ ∪ x = x.
 Axiom nr : forall (x : FSet),
  x ∪ ∅ = x.
 Axiom idem : forall (x : A),
  {| x |} ∪ {|x|} = {|x|}.
 Axiom trunc : IsHSet FSet.
 Fixpoint FSet_rec
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x : FSet)
  {struct x}
  : P
  := (match x return _ -> _ -> _ -> _ -> _ -> _ -> P with
        | E => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => e
        | L a => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => l a
        | U y z => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => u 
           (FSet_rec P H e l u assocP commP nlP nrP idemP y)
           (FSet_rec P H e l u assocP commP nlP nrP idemP z)
      end) assocP commP nlP nrP idemP H.
 Axiom FSet_rec_beta_assoc : forall
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x y z : FSet),
  ap (FSet_rec P H e l u assocP commP nlP nrP idemP) (assoc x y z) 
  =
  (assocP (FSet_rec P H e l u assocP commP nlP nrP idemP x)
          (FSet_rec P H e l u assocP commP nlP nrP idemP y)
          (FSet_rec P H e l u assocP commP nlP nrP idemP z)
  ).
 Axiom FSet_rec_beta_comm : forall
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x y : FSet),
  ap (FSet_rec P H e l u assocP commP nlP nrP idemP) (comm x y)
  =
  (commP (FSet_rec P H e l u assocP commP nlP nrP idemP x)
         (FSet_rec P H e l u assocP commP nlP nrP idemP y)
  ).
 Axiom FSet_rec_beta_nl : forall
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x : FSet),
  ap (FSet_rec P H e l u assocP commP nlP nrP idemP) (nl x)
  =
  (nlP (FSet_rec P H e l u assocP commP nlP nrP idemP x)
  ).
 Axiom FSet_rec_beta_nr : forall
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x : FSet),
  ap (FSet_rec P H e l u assocP commP nlP nrP idemP) (nr x)
  =
  (nrP (FSet_rec P H e l u assocP commP nlP nrP idemP x)
  ).
 Axiom FSet_rec_beta_idem : forall
  (P : Type)
  (H: IsHSet P)
  (e : P)
  (l : A -> P)
  (u : P -> P -> P)
  (assocP : forall (x y z : P), u x (u y z) = u (u x y) z)
  (commP : forall (x y : P), u x y = u y x)
  (nlP : forall (x : P), u e x = x)
  (nrP : forall (x : P), u x e = x)
  (idemP : forall (x : A), u (l x) (l x) = l x)
  (x : A),
  ap (FSet_rec P H e l u assocP commP nlP nrP idemP) (idem x)
  =
  idemP x.
 End FSet.
 Section FSet_induction.
 Arguments E {_}.
 Arguments U {_} _ _.
 Arguments L {_} _.
 Arguments assoc {_} _ _ _.
 Arguments comm {_} _ _.
 Arguments nl {_} _.
 Arguments nr {_} _.
 Arguments idem {_} _.
 Variable A: Type.
 Variable  (P : FSet A -> Type).
 Variable  (H :  forall a : FSet A, IsHSet (P a)).
 Variable  (eP : P E).
 Variable  (lP : forall a: A, P (L a)).
 Variable  (uP : forall (x y: FSet A), P x -> P y -> P (U x y)).
 Variable  (assocP : forall (x y z : FSet A) 
                   (px: P x) (py: P y) (pz: P z),
  assoc x y z #
   (uP      x    (U y z)          px        (uP y z py pz)) 
  = 
   (uP   (U x y)    z       (uP x y px py)          pz)).
 Variable  (commP : forall (x y: FSet A) (px: P x) (py: P y),
  comm x y #
  uP x y px py = uP y x py px).
 Variable  (nlP : forall (x : FSet A) (px: P x), 
  nl x # uP E x eP px = px).
 Variable  (nrP : forall (x : FSet A) (px: P x), 
  nr x # uP x E px eP = px).
 Variable  (idemP : forall (x : A), 
  idem x # uP (L x) (L x) (lP x) (lP x) = lP x).
 (* Induction principle *)
 Fixpoint FSet_ind
  (x : FSet A)
  {struct x}
  : P x
  := (match x return _ -> _ -> _ -> _ -> _ -> _ -> P x with
        | E => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => eP
        | L a => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => lP a
        | U y z => fun _ => fun _ => fun _ => fun _ => fun _ => fun _ => uP y z
           (FSet_ind y)
           (FSet_ind z)
      end) H assocP commP nlP nrP idemP.
 Axiom FSet_ind_beta_assoc : forall (x y z : FSet A),
  apD FSet_ind (assoc x y z) =
  (assocP x y z (FSet_ind x)  (FSet_ind y) (FSet_ind z)).
 Axiom FSet_ind_beta_comm : forall (x y : FSet A),
  apD FSet_ind (comm x y) = (commP x y (FSet_ind x) (FSet_ind y)).
 Axiom FSet_ind_beta_nl : forall (x : FSet A),
  apD FSet_ind (nl x) = (nlP x (FSet_ind x)).
 Axiom FSet_ind_beta_nr : forall (x : FSet A),
  apD FSet_ind (nr x) = (nrP x (FSet_ind x)).
 Axiom FSet_ind_beta_idem : forall (x : A), apD FSet_ind (idem x) = idemP x.
 End FSet_induction.
 End definition.
--- a/FiniteSets/operations.v
+++ b/FiniteSets/operations.v
@ -0,0 +1,63 @@
 Require Import HoTT.
 Require Export HoTT.
 Require Import definition.
 (*Set Implicit Arguments.*)
 Arguments E {_}.
 Arguments U {_} _ _.
 Arguments L {_} _.
 Arguments assoc {_} _ _ _.
 Arguments comm {_} _ _.
 Arguments nl {_} _.
 Arguments nr {_} _.
 Arguments idem {_} _.
 Section operations.
 Variable A : Type.
 Parameter A_eqdec : forall (x y : A), Decidable (x = y).
 Definition deceq (x y : A) :=
  if dec (x = y) then true else false.
 Definition isIn : A -> FSet A -> Bool.
 Proof.
 intros a.
 simple refine (FSet_rec A _ _ _ _ _ _ _ _ _ _).
 - exact false.
 - intro a'. apply (deceq a a').
 - apply orb. 
 - intros x y z. destruct x; reflexivity.
 - intros x y. destruct x, y; reflexivity.
 - intros x. reflexivity. 
 - intros x. destruct x; reflexivity.
 - intros a'. destruct (deceq a a'); reflexivity.
 Defined.
 Infix "∈" := isIn (at level 9, right associativity).
 Definition comprehension : 
  (A -> Bool) -> FSet A -> FSet A.
 Proof.
 intros P.
 simple refine (FSet_rec A _ _ _ _ _ _ _ _ _ _).
 - apply E.
 - intro a.
  refine (if (P a) then L a else E).
 - apply U.
 - intros. cbv. apply assoc.
 - intros. cbv. apply comm.
 - intros. cbv. apply nl.
 - intros. cbv. apply nr.
 - intros. cbv. 
  destruct (P x); simpl.
  + apply idem.
  + apply nl.
 Defined.
 Definition intersection : 
  FSet A -> FSet A -> FSet A.
 Proof.
 intros X Y.
 apply (comprehension (fun (a : A) => isIn a X) Y).
 Defined.
 End operations.
--- a/FiniteSets/properties.v
+++ b/FiniteSets/properties.v
@ -0,0 +1,271 @@
 Require Import HoTT.
 Require Export HoTT.
 Require Import definition.
 Require Import operations.
 Section properties.
 Arguments E {_}.
 Arguments U {_} _ _.
 Arguments L {_} _.
 Arguments assoc {_} _ _ _.
 Arguments comm {_} _ _.
 Arguments nl {_} _.
 Arguments nr {_} _.
 Arguments idem {_} _.
 Arguments isIn {_} _ _.
 Arguments comprehension {_} _ _.
 Arguments intersection {_} _ _.
 Variable A : Type.
 Parameter A_eqdec : forall (x y : A), Decidable (x = y).
 Definition deceq (x y : A) :=
  if dec (x = y) then true else false.
 Theorem deceq_sym : forall x y, deceq x y = deceq y x.
 Proof.
 intros x y.
 unfold deceq.
 destruct (dec (x = y)) ; destruct (dec (y = x)) ; cbn.
 - reflexivity. 
 - pose (n (p^)) ; contradiction.
 - pose (n (p^)) ; contradiction.
 - reflexivity.
 Defined.
 Lemma comprehension_false: forall Y: FSet A, 
 	    comprehension (fun a => isIn a E) Y = E.
 Proof.
 simple refine (FSet_ind _ _ _ _ _ _ _ _ _ _ _); 
 try (intros; apply set_path2).
 - cbn. reflexivity.
 - cbn. reflexivity.
 - intros x y IHa IHb.
  cbn.
  rewrite IHa.
  rewrite IHb.
  rewrite nl.
  reflexivity.
 Defined.
 Lemma isIn_singleton_eq (a b: A) : isIn a  (L b) = true -> a = b.
 Proof. unfold isIn. simpl. unfold operations.deceq.
 destruct (dec (a = b)). intro. apply p.
 intro X. 
 contradiction (false_ne_true X).
 Defined.
 Lemma isIn_empty_false (a: A) : isIn a E = true -> Empty.
 Proof. 
 cbv. intro X.
 contradiction (false_ne_true X). 
 Defined.
 Lemma isIn_union (a: A) (X Y: FSet A) : 
 	    isIn a (U X Y) = (isIn a X || isIn a Y)%Bool.
 Proof. reflexivity. Qed. 
 Theorem comprehension_or : forall ϕ ψ (x: FSet A),
    comprehension (fun a => orb (ϕ a) (ψ a)) x = U (comprehension ϕ x) 
    (comprehension ψ x).
 Proof.
 intros ϕ ψ.
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _) ; try (intros ; apply set_path2). 
 - cbn. symmetry ; apply nl.
 - cbn. intros.
  destruct (ϕ a) ; destruct (ψ a) ; symmetry.
  * apply idem.
  * apply nr. 
  * apply nl.
  * apply nl.
 - simpl. intros x y P Q.
  cbn. 
  rewrite P.
  rewrite Q.
  rewrite <- assoc.
  rewrite (assoc  (comprehension ψ x)).
  rewrite (comm  (comprehension ψ x) (comprehension ϕ y)).
  rewrite <- assoc.
  rewrite <- assoc.
  reflexivity.
 Defined.
 Theorem intersection_isIn : forall a (x y: FSet A),
    isIn a (intersection x y) = andb (isIn a x) (isIn a y).
 Proof.
 Admitted.
 (*
 intros a.
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _) ; cbn.
 - intros y.
  rewrite intersection_E.
  reflexivity.
 - intros b y.
  rewrite intersection_La.
  unfold deceq.
  destruct (dec (a = b)) ; cbn.
  * rewrite p.
    destruct (isIn b y).
    + cbn.
      unfold deceq.
      destruct (dec (b = b)).
      { reflexivity. }
      { pose (n idpath). contradiction. }
    + reflexivity.
  * destruct (isIn b y).
    + cbn.
      unfold deceq.
      destruct (dec (a = b)).
      { pose (n p). contradiction. }
      { reflexivity. }
    + reflexivity.
 - intros x y P Q z.
  enough (intersection (U x y) z = U (intersection x z) (intersection y z)).
  rewrite X.
  cbn.
  rewrite P.
  rewrite Q.
  destruct (isIn a x) ; destruct (isIn a y) ; destruct (isIn a z) ; reflexivity.
  admit.
 Admitted.
 *)
 Theorem union_idem : forall x: FSet A, U x x = x.
 Proof.
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _) ; 
 try (intros ; apply set_path2) ; cbn.
 - apply nl.
 - apply idem.
 - intros x y P Q.
  rewrite assoc.
  rewrite (comm x y).
  rewrite <- (assoc y x x).
  rewrite P.
  rewrite (comm y x).
  rewrite <- (assoc x y y).
  rewrite Q.
  reflexivity.
 Defined.
 Lemma intersection_0l: forall X: FSet A, intersection E X = E.
 Proof.       
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _) ; 
 try (intros ; apply set_path2).
 - reflexivity.
 - intro a.
  reflexivity.
 - unfold intersection.
  intros x y P Q.
  cbn.
  rewrite P.
  rewrite Q.
  apply nl.
 Defined.
 Definition intersection_0r (X: FSet A): intersection X E = E := idpath.
 Lemma intersection_comm (X Y: FSet A): intersection X Y = intersection Y X.
 Proof.
 (*
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _ X) ;  
 try (intros; apply set_path2).
 - cbn. unfold intersection. apply comprehension_false.
 - cbn. unfold intersection. intros a.
  hrecursion Y; try (intros; apply set_path2).
  + cbn. reflexivity.
  + cbn. intros.
  		destruct  (dec (a0 = a)). 
  		rewrite p. destruct (dec (a=a)).
  		reflexivity.
  		contradiction n. 
  		reflexivity. 
 		destruct  (dec (a = a0)).
 		contradiction n. apply p^. reflexivity.
 	+ cbn -[isIn]. intros Y1 Y2 IH1 IH2.
 	 	rewrite IH1. 
 	 	rewrite IH2. 	 	
 	 	apply 	(comprehension_union (L a)).
 - intros X1 X2 IH1 IH2.
  cbn.
  unfold intersection in *.
  rewrite <- IH1.
  rewrite <- IH2. symmetry.
 	apply comprehension_union.
 Defined.*)
 Admitted.
 Lemma comprehension_union (X Y Z: FSet A) : 
 	U (comprehension (fun a => isIn a Y) X)
 	  (comprehension (fun a => isIn a Z) X) =
 	  comprehension (fun a => isIn a (U Y Z)) X.
 Proof.
 Admitted.
 (*
 hrecursion X; try (intros; apply set_path2).
 - cbn. apply nl.
 - cbn. intro a. 
 		destruct (isIn a Y); simpl;
 		destruct (isIn a Z); simpl.
 		apply idem.
 		apply nr.
 		apply nl.
 		apply nl.
 - cbn. intros X1 X2 IH1 IH2.
 	rewrite assoc.
 	rewrite (comm _ (comprehension (fun a : A => isIn a Y) X1) 
 				  (comprehension (fun a : A => isIn a Y) X2)).
  rewrite <- (assoc _   
  				  (comprehension (fun a : A => isIn a Y) X2)
       		 (comprehension (fun a : A => isIn a Y) X1)
       		 (comprehension (fun a : A => isIn a Z) X1)
       		 ).
  rewrite IH1.
  rewrite comm.
  rewrite assoc. 
  rewrite (comm _ (comprehension (fun a : A => isIn a Z) X2) _).
  rewrite IH2.
  apply comm.
 Defined.*)
 Theorem intersection_assoc : forall (x y z: FSet A),
    intersection x (intersection y z) = intersection (intersection x y) z.
 Admitted.
 (*
 simple refine (FSet_ind A _ _ _ _ _ _ _ _ _ _) ; try (intros ; apply set_path2).
 - intros y z.
  cbn.
  rewrite intersection_E.
  rewrite intersection_E.
  rewrite intersection_E.
  reflexivity.
 - intros a y z.
  cbn.
  rewrite intersection_La.
  rewrite intersection_La.
  rewrite intersection_isIn.
  destruct (isIn a y).
  * rewrite intersection_La.
    destruct (isIn a z).
    + reflexivity.
    + reflexivity.
  * rewrite intersection_E.
    reflexivity.      
 - unfold intersection. cbn.
  intros x y P Q z z'.
  rewrite comprehension_or.
  rewrite P.
  rewrite Q.
  rewrite comprehension_or.
  cbn.
  rewrite comprehension_or.
  reflexivity.
 *)
 End properties.