notation made half decent

[helm.git] / helm / software / matita / contribs / formal_topology / overlap / relations.ma

(**************************************************************************)
(*       ___                                                              *)
(*      ||M||                                                             *)
(*      ||A||       A project by Andrea Asperti                           *)
(*      ||T||                                                             *)
(*      ||I||       Developers:                                           *)
(*      ||T||         The HELM team.                                      *)
(*      ||A||         http://helm.cs.unibo.it                             *)
(*      \   /                                                             *)
(*       \ /        This file is distributed under the terms of the       *)
(*        v         GNU General Public License Version 2                  *)
(*                                                                        *)
(**************************************************************************)

include "subsets.ma".

record binary_relation (A,B: SET) : Type1 ≝
 { satisfy:> binary_morphism1 A B CPROP }.

notation < "hvbox (x \nbsp \natur term 90 r \nbsp y)"  with precedence 45 for @{'satisfy $r $x $y}.
notation > "hvbox (x \natur term 90 r y)"  with precedence 45 for @{'satisfy $r $x $y}.
interpretation "relation applied" 'satisfy r x y = (fun21 ??? (satisfy ?? r) x y).

definition binary_relation_setoid: SET → SET → setoid1.
 intros (A B);
 constructor 1;
  [ apply (binary_relation A B)
  | constructor 1;
     [ apply (λA,B.λr,r': binary_relation A B. ∀x,y. r x y ↔ r' x y)
     | simplify; intros 3; split; intro; assumption
     | simplify; intros 5; split; intro;
       [ apply (fi ?? (f ??)) | apply (if ?? (f ??))] assumption
     | simplify;  intros 7; split; intro;
        [ apply (if ?? (f1 ??)) | apply (fi ?? (f ??)) ]
        [ apply (if ?? (f ??)) | apply (fi ?? (f1 ??)) ]
       assumption]]
qed.

definition binary_relation_of_binary_relation_setoid : 
  ∀A,B.binary_relation_setoid A B → binary_relation A B ≝ λA,B,c.c.
coercion binary_relation_of_binary_relation_setoid.

definition composition:
 ∀A,B,C.
  (binary_relation_setoid A B) × (binary_relation_setoid B C) ⇒_1 (binary_relation_setoid A C).
 intros;
 constructor 1;
  [ intros (R12 R23);
    constructor 1;
    constructor 1;
     [ apply (λs1:A.λs3:C.∃s2:B. s1 ♮R12 s2 ∧ s2 ♮R23 s3);
     | intros;
       split; intro; cases e2 (w H3); clear e2; exists; [1,3: apply w ]
        [ apply (. (e^-1‡#)‡(#‡e1^-1)); assumption
        | apply (. (e‡#)‡(#‡e1)); assumption]]
  | intros 8; split; intro H2; simplify in H2 ⊢ %;
    cases H2 (w H3); clear H2; exists [1,3: apply w] cases H3 (H2 H4); clear H3;
    [ lapply (if ?? (e x w) H2) | lapply (fi ?? (e x w) H2) ]
    [ lapply (if ?? (e1 w y) H4)| lapply (fi ?? (e1 w y) H4) ]
    exists; try assumption;
    split; assumption]
qed.

definition REL: category1.
 constructor 1;
  [ apply setoid
  | intros (T T1); apply (binary_relation_setoid T T1)
  | intros; constructor 1;
    constructor 1; unfold setoid1_of_setoid; simplify;
     [ (* changes required to avoid universe inconsistency *)
       change with (carr o → carr o → CProp); intros; apply (eq ? c c1)
     | intros; split; intro; change in a a' b b' with (carr o);
       change in e with (eq ? a a'); change in e1 with (eq ? b b');
        [ apply (.= (e ^ -1));
          apply (.= e2);
          apply e1
        | apply (.= e);
          apply (.= e2);
          apply (e1 ^ -1)]]
  | apply composition
  | intros 9;
    split; intro;
    cases f (w H); clear f; cases H; clear H;
    [cases f (w1 H); clear f | cases f1 (w1 H); clear f1]
    cases H; clear H;
    exists; try assumption;
    split; try assumption;
    exists; try assumption;
    split; assumption
  |6,7: intros 5; unfold composition; simplify; split; intro;
        unfold setoid1_of_setoid in x y; simplify in x y;
        [1,3: cases e (w H1); clear e; cases H1; clear H1; unfold;
          [ apply (. (e : eq1 ? x w)‡#); assumption
          | apply (. #‡(e : eq1 ? w y)^-1); assumption]
        |2,4: exists; try assumption; split;
          (* change required to avoid universe inconsistency *)
          change in x with (carr o1); change in y with (carr o2);
          first [apply refl | assumption]]]
qed.

definition setoid_of_REL : objs1 REL → setoid ≝ λx.x.
coercion setoid_of_REL.

definition binary_relation_setoid_of_arrow1_REL : 
  ∀P,Q. arrows1 REL P Q → binary_relation_setoid P Q ≝ λP,Q,x.x.
coercion binary_relation_setoid_of_arrow1_REL.

definition full_subset: ∀s:REL. Ω^s.
 apply (λs.{x | True});
 intros; simplify; split; intro; assumption.
qed.

coercion full_subset.

alias symbol "arrows1_SET" (instance 2) = "'arrows1_SET low".
definition comprehension: ∀b:REL. (b ⇒_1 CPROP) → Ω^b.
 apply (λb:REL. λP: b ⇒_1 CPROP. {x | P x});
 intros; simplify;
 apply (.= †e); apply refl1.
qed.

interpretation "subset comprehension" 'comprehension s p =
 (comprehension s (mk_unary_morphism1 ?? p ?)).

definition ext: ∀X,S:REL. (arrows1 ? X S) × S ⇒_1 (Ω^X).
 apply (λX,S.mk_binary_morphism1 ??? (λr:arrows1 REL X S.λf:S.{x ∈ X | x ♮r f}) ?);
  [ intros; simplify; apply (.= (e‡#)); apply refl1
  | intros; simplify; split; intros; simplify;
     [ change with (∀x. x ♮a b → x ♮a' b'); intros;
       apply (. (#‡e1^-1)); whd in e; apply (if ?? (e ??)); assumption
     | change with (∀x. x ♮a' b' → x ♮a b); intros;
       apply (. (#‡e1)); whd in e; apply (fi ?? (e ??));assumption]]
qed.
(*
definition extS: ∀X,S:REL. ∀r: arrows1 ? X S. Ω \sup S ⇒ Ω \sup X.
 (* ∃ is not yet a morphism apply (λX,S,r,F.{x ∈ X | ∃a. a ∈ F ∧ x ♮r a});*)
 intros (X S r); constructor 1;
  [ intro F; constructor 1; constructor 1;
    [ apply (λx. x ∈ X ∧ ∃a:S. a ∈ F ∧ x ♮r a);
    | intros; split; intro; cases f (H1 H2); clear f; split;
       [ apply (. (H‡#)); assumption
       |3: apply (. (H\sup -1‡#)); assumption
       |2,4: cases H2 (w H3); exists; [1,3: apply w]
         [ apply (. (#‡(H‡#))); assumption
         | apply (. (#‡(H \sup -1‡#))); assumption]]]
  | intros; split; simplify; intros; cases f; cases H1; split;
     [1,3: assumption
     |2,4: exists; [1,3: apply w]
      [ apply (. (#‡H)‡#); assumption
      | apply (. (#‡H\sup -1)‡#); assumption]]]
qed.

lemma equalset_extS_id_X_X: ∀o:REL.∀X.extS ?? (id1 ? o) X = X.
 intros;
 unfold extS; simplify;
 split; simplify;
  [ intros 2; change with (a ∈ X);
    cases f; clear f;
    cases H; clear H;
    cases x; clear x;
    change in f2 with (eq1 ? a w);
    apply (. (f2\sup -1‡#));
    assumption
  | intros 2; change in f with (a ∈ X);
    split;
     [ whd; exact I 
     | exists; [ apply a ]
       split;
        [ assumption
        | change with (a = a); apply refl]]]
qed.

lemma extS_com: ∀o1,o2,o3,c1,c2,S. extS o1 o3 (c2 ∘ c1) S = extS o1 o2 c1 (extS o2 o3 c2 S).
 intros; unfold extS; simplify; split; intros; simplify; intros;
  [ cases f (H1 H2); cases H2 (w H3); clear f H2; split; [assumption]
    cases H3 (H4 H5); cases H5 (w1 H6); clear H3 H5; cases H6 (H7 H8); clear H6;
    exists; [apply w1] split [2: assumption] constructor 1; [assumption]
    exists; [apply w] split; assumption
  | cases f (H1 H2); cases H2 (w H3); clear f H2; split; [assumption]
    cases H3 (H4 H5); cases H4 (w1 H6); clear H3 H4; cases H6 (w2 H7); clear H6;
    cases H7; clear H7; exists; [apply w2] split; [assumption] exists [apply w] split;
    assumption]
qed.
*)

(* the same as ⋄ for a basic pair *)
definition image: ∀U,V:REL. (arrows1 ? U V) × Ω^U ⇒_1 Ω^V.
 intros; constructor 1;
  [ apply (λr: arrows1 ? U V.λS: Ω \sup U. {y | ∃x:U. x ♮r y ∧ x ∈ S });
    intros; simplify; split; intro; cases e1; exists [1,3: apply w]
     [ apply (. (#‡e^-1)‡#); assumption
     | apply (. (#‡e)‡#); assumption]
  | intros; split; simplify; intros; cases e2; exists [1,3: apply w]
     [ apply (. #‡(#‡e1^-1)); cases x; split; try assumption;
       apply (if ?? (e ??)); assumption
     | apply (. #‡(#‡e1)); cases x; split; try assumption;
       apply (if ?? (e ^ -1 ??)); assumption]]
qed.

(* the same as □ for a basic pair *)
definition minus_star_image: ∀U,V:REL. (arrows1 ? U V) × Ω^U ⇒_1 Ω^V.
 intros; constructor 1;
  [ apply (λr: arrows1 ? U V.λS: Ω \sup U. {y | ∀x:U. x ♮r y → x ∈ S});
    intros; simplify; split; intros; apply f;
     [ apply (. #‡e); assumption
     | apply (. #‡e ^ -1); assumption]
  | intros; split; simplify; intros; [ apply (. #‡e1^ -1); | apply (. #‡e1 )]
    apply f; [ apply (if ?? (e ^ -1 ??)); | apply (if ?? (e ??)) ] assumption]
qed.

(* the same as Rest for a basic pair *)
definition star_image: ∀U,V:REL. (arrows1 ? U V) × Ω^V ⇒_1 Ω^U.
 intros; constructor 1;
  [ apply (λr: arrows1 ? U V.λS: Ω \sup V. {x | ∀y:V. x ♮r y → y ∈ S});
    intros; simplify; split; intros; apply f;
     [ apply (. e ‡#); assumption
     | apply (. e^ -1‡#); assumption]
  | intros; split; simplify; intros; [ apply (. #‡e1 ^ -1); | apply (. #‡e1)]
    apply f; [ apply (if ?? (e ^ -1 ??)); | apply (if ?? (e ??)) ] assumption]
qed.

(* the same as Ext for a basic pair *)
definition minus_image: ∀U,V:REL. (arrows1 ? U V) × Ω^V ⇒_1 Ω^U.
 intros; constructor 1;
  [ apply (λr: arrows1 ? U V.λS: Ω \sup V. {x | (*∃x:U. x ♮r y ∧ x ∈ S*)
      exT ? (λy:V.x ♮r y ∧ y ∈ S) });
    intros; simplify; split; intro; cases e1; exists [1,3: apply w]
     [ apply (. (e ^ -1‡#)‡#); assumption
     | apply (. (e‡#)‡#); assumption]
  | intros; split; simplify; intros; cases e2; exists [1,3: apply w]
     [ apply (. #‡(#‡e1 ^ -1)); cases x; split; try assumption;
       apply (if ?? (e ??)); assumption
     | apply (. #‡(#‡e1)); cases x; split; try assumption;
       apply (if ?? (e ^ -1 ??)); assumption]]
qed.

(*
(* minus_image is the same as ext *)

theorem image_id: ∀o,U. image o o (id1 REL o) U = U.
 intros; unfold image; simplify; split; simplify; intros;
  [ change with (a ∈ U);
    cases H; cases x; change in f with (eq1 ? w a); apply (. f‡#); assumption
  | change in f with (a ∈ U);
    exists; [apply a] split; [ change with (a = a); apply refl | assumption]]
qed.

theorem minus_star_image_id: ∀o,U. minus_star_image o o (id1 REL o) U = U.
 intros; unfold minus_star_image; simplify; split; simplify; intros;
  [ change with (a ∈ U); apply H; change with (a=a); apply refl
  | change in f1 with (eq1 ? x a); apply (. f1 \sup -1‡#); apply f]
qed.

theorem image_comp: ∀A,B,C,r,s,X. image A C (r ∘ s) X = image B C r (image A B s X).
 intros; unfold image; simplify; split; simplify; intros; cases H; clear H; cases x;
 clear x; [ cases f; clear f; | cases f1; clear f1 ]
 exists; try assumption; cases x; clear x; split; try assumption;
 exists; try assumption; split; assumption.
qed.

theorem minus_star_image_comp:
 ∀A,B,C,r,s,X.
  minus_star_image A C (r ∘ s) X = minus_star_image B C r (minus_star_image A B s X).
 intros; unfold minus_star_image; simplify; split; simplify; intros; whd; intros;
  [ apply H; exists; try assumption; split; assumption
  | change with (x ∈ X); cases f; cases x1; apply H; assumption]
qed.

(*CSC: unused! *)
theorem ext_comp:
 ∀o1,o2,o3: REL.
  ∀a: arrows1 ? o1 o2.
   ∀b: arrows1 ? o2 o3.
    ∀x. ext ?? (b∘a) x = extS ?? a (ext ?? b x).
 intros;
 unfold ext; unfold extS; simplify; split; intro; simplify; intros;
 cases f; clear f; split; try assumption;
  [ cases f2; clear f2; cases x1; clear x1; exists; [apply w] split;
     [1: split] assumption;
  | cases H; clear H; cases x1; clear x1; exists [apply w]; split;
     [2: cases f] assumption]
qed.

theorem extS_singleton:
 ∀o1,o2.∀a:arrows1 ? o1 o2.∀x.extS o1 o2 a (singleton o2 x) = ext o1 o2 a x.
 intros; unfold extS; unfold ext; unfold singleton; simplify;
 split; intros 2; simplify; cases f; split; try assumption;
  [ cases H; cases x1; change in f2 with (eq1 ? x w); apply (. #‡f2 \sup -1);
    assumption
  | exists; try assumption; split; try assumption; change with (x = x); apply refl]
qed.
*)