X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fmatita%2Fcontribs%2Fformal_topology%2Foverlap%2Fcategories.ma;h=2582167dc8bcd65a76a1c6a4d591f234d8159662;hb=a799c56fa883a1318cb42e185c0d0929b368a961;hp=ea246ef6c8e501c58a50b571763ccb50ee693812;hpb=d93c87f76076e1ad4b6a87e45d0322eb72f7e492;p=helm.git diff --git a/helm/software/matita/contribs/formal_topology/overlap/categories.ma b/helm/software/matita/contribs/formal_topology/overlap/categories.ma index ea246ef6c..2582167dc 100644 --- a/helm/software/matita/contribs/formal_topology/overlap/categories.ma +++ b/helm/software/matita/contribs/formal_topology/overlap/categories.ma @@ -12,34 +12,7 @@ (* *) (**************************************************************************) -include "logic/cprop_connectives.ma". - -definition Type0 := Type. -definition Type1 := Type. -definition Type2 := Type. -definition Type3 := Type. -definition Type0_lt_Type1 := (Type0 : Type1). -definition Type1_lt_Type2 := (Type1 : Type2). -definition Type2_lt_Type3 := (Type2 : Type3). - -definition Type_OF_Type0: Type0 → Type := λx.x. -definition Type_OF_Type1: Type1 → Type := λx.x. -definition Type_OF_Type2: Type2 → Type := λx.x. -definition Type_OF_Type3: Type3 → Type := λx.x. -coercion Type_OF_Type0. -coercion Type_OF_Type1. -coercion Type_OF_Type2. -coercion Type_OF_Type3. - -definition CProp0 := CProp. -definition CProp1 := CProp. -definition CProp2 := CProp. -definition CProp0_lt_CProp1 := (CProp0 : CProp1). -definition CProp1_lt_CProp2 := (CProp1 : CProp2). - -definition CProp_OF_CProp0: CProp0 → CProp := λx.x. -definition CProp_OF_CProp1: CProp1 → CProp := λx.x. -definition CProp_OF_CProp2: CProp2 → CProp := λx.x. +include "cprop_connectives.ma". record equivalence_relation (A:Type0) : Type1 ≝ { eq_rel:2> A → A → CProp0; @@ -53,9 +26,9 @@ record setoid : Type1 ≝ eq: equivalence_relation carr }. -definition reflexive1 ≝ λA:Type1.λR:A→A→CProp1.∀x:A.R x x. -definition symmetric1 ≝ λC:Type1.λlt:C→C→CProp1. ∀x,y:C.lt x y → lt y x. -definition transitive1 ≝ λA:Type1.λR:A→A→CProp1.∀x,y,z:A.R x y → R y z → R x z. +definition reflexive1: ∀A:Type1.∀R:A→A→CProp1.CProp1 ≝ λA:Type1.λR:A→A→CProp1.∀x:A.R x x. +definition symmetric1: ∀A:Type1.∀R:A→A→CProp1.CProp1 ≝ λC:Type1.λlt:C→C→CProp1. ∀x,y:C.lt x y → lt y x. +definition transitive1: ∀A:Type1.∀R:A→A→CProp1.CProp1 ≝ λA:Type1.λR:A→A→CProp1.∀x,y,z:A.R x y → R y z → R x z. record equivalence_relation1 (A:Type1) : Type2 ≝ { eq_rel1:2> A → A → CProp1; @@ -84,9 +57,9 @@ qed. (* questa coercion e' necessaria per problemi di unificazione *) coercion setoid1_of_setoid. -definition reflexive2 ≝ λA:Type2.λR:A→A→CProp2.∀x:A.R x x. -definition symmetric2 ≝ λC:Type2.λlt:C→C→CProp2. ∀x,y:C.lt x y → lt y x. -definition transitive2 ≝ λA:Type2.λR:A→A→CProp2.∀x,y,z:A.R x y → R y z → R x z. +definition reflexive2: ∀A:Type2.∀R:A→A→CProp2.CProp2 ≝ λA:Type2.λR:A→A→CProp2.∀x:A.R x x. +definition symmetric2: ∀A:Type2.∀R:A→A→CProp2.CProp2 ≝ λC:Type2.λlt:C→C→CProp2. ∀x,y:C.lt x y → lt y x. +definition transitive2: ∀A:Type2.∀R:A→A→CProp2.CProp2 ≝ λA:Type2.λR:A→A→CProp2.∀x,y,z:A.R x y → R y z → R x z. record equivalence_relation2 (A:Type2) : Type3 ≝ { eq_rel2:2> A → A → CProp2; @@ -112,7 +85,7 @@ definition setoid2_of_setoid1: setoid1 → setoid2. | apply (trans1 s)]] qed. -(*coercion setoid2_of_setoid1.*) +coercion setoid2_of_setoid1. (* definition Leibniz: Type → setoid. @@ -181,6 +154,7 @@ interpretation "prop11" 'prop1 c = (prop11 _____ c). interpretation "prop12" 'prop1 c = (prop12 _____ c). interpretation "prop2" 'prop2 l r = (prop2 ________ l r). interpretation "prop21" 'prop2 l r = (prop21 ________ l r). +interpretation "prop22" 'prop2 l r = (prop22 ________ l r). interpretation "refl" 'refl = (refl ___). interpretation "refl1" 'refl = (refl1 ___). interpretation "refl2" 'refl = (refl2 ___). @@ -191,26 +165,26 @@ definition CPROP: setoid1. | constructor 1; [ apply Iff | intros 1; split; intro; assumption - | intros 3; cases H; split; assumption - | intros 5; cases H; cases H1; split; intro; - [ apply (H4 (H2 x1)) | apply (H3 (H5 z1))]]] + | intros 3; cases i; split; assumption + | intros 5; cases i; cases i1; split; intro; + [ apply (f2 (f x1)) | apply (f1 (f3 z1))]]] qed. alias symbol "eq" = "setoid1 eq". -definition if': ∀A,B:CPROP. A = B → A → B. - intros; apply (if ?? e); assumption. +definition fi': ∀A,B:CPROP. A = B → B → A. + intros; apply (fi ?? e); assumption. qed. -notation ". r" with precedence 50 for @{'if $r}. -interpretation "if" 'if r = (if' __ r). +notation ". r" with precedence 50 for @{'fi $r}. +interpretation "fi" 'fi r = (fi' __ r). definition and_morphism: binary_morphism1 CPROP CPROP CPROP. constructor 1; [ apply And - | intros; split; intro; cases H; split; - [ apply (if ?? e a1) + | intros; split; intro; cases a1; split; + [ apply (if ?? e a2) | apply (if ?? e1 b1) - | apply (fi ?? e a1) + | apply (fi ?? e a2) | apply (fi ?? e1 b1)]] qed. @@ -219,7 +193,7 @@ interpretation "and_morphism" 'and a b = (fun21 ___ and_morphism a b). definition or_morphism: binary_morphism1 CPROP CPROP CPROP. constructor 1; [ apply Or - | intros; split; intro; cases H; [1,3:left |2,4: right] + | intros; split; intro; cases o; [1,3:left |2,4: right] [ apply (if ?? e a1) | apply (fi ?? e a1) | apply (if ?? e1 b1) @@ -232,8 +206,8 @@ definition if_morphism: binary_morphism1 CPROP CPROP CPROP. constructor 1; [ apply (λA,B. A → B) | intros; split; intros; - [ apply (if ?? e1); apply H; apply (fi ?? e); assumption - | apply (fi ?? e1); apply H; apply (if ?? e); assumption]] + [ apply (if ?? e1); apply f; apply (fi ?? e); assumption + | apply (fi ?? e1); apply f; apply (if ?? e); assumption]] qed. (* @@ -285,27 +259,25 @@ record category2 : Type3 ≝ }. notation "'ASSOC'" with precedence 90 for @{'assoc}. -notation "'ASSOC1'" with precedence 90 for @{'assoc1}. -notation "'ASSOC2'" with precedence 90 for @{'assoc2}. -interpretation "category1 composition" 'compose x y = (fun22 ___ (comp2 ____) y x). -interpretation "category1 assoc" 'assoc1 = (comp_assoc2 ________). +interpretation "category2 composition" 'compose x y = (fun22 ___ (comp2 ____) y x). +interpretation "category2 assoc" 'assoc = (comp_assoc2 ________). interpretation "category1 composition" 'compose x y = (fun21 ___ (comp1 ____) y x). -interpretation "category1 assoc" 'assoc1 = (comp_assoc1 ________). +interpretation "category1 assoc" 'assoc = (comp_assoc1 ________). interpretation "category composition" 'compose x y = (fun2 ___ (comp ____) y x). interpretation "category assoc" 'assoc = (comp_assoc ________). (* bug grande come una casa? Ma come fa a passare la quantificazione larga??? *) -definition unary_morphism_setoid: setoid → setoid → setoid1. +definition unary_morphism_setoid: setoid → setoid → setoid. intros; constructor 1; [ apply (unary_morphism s s1); | constructor 1; [ intros (f g); apply (∀a:s. eq ? (f a) (g a)); | intros 1; simplify; intros; apply refl; - | simplify; intros; apply sym; apply H; - | simplify; intros; apply trans; [2: apply H; | skip | apply H1]]] + | simplify; intros; apply sym; apply f; + | simplify; intros; apply trans; [2: apply f; | skip | apply f1]]] qed. definition SET: category1. @@ -346,7 +318,7 @@ notation "hbox(a break ⇒ b)" right associative with precedence 20 for @{ 'Impl interpretation "unary morphism" 'Imply a b = (arrows1 SET a b). interpretation "SET eq" 'eq x y = (eq_rel _ (eq' _) x y). -definition unary_morphism1_setoid1: setoid1 → setoid1 → setoid2. +definition unary_morphism1_setoid1: setoid1 → setoid1 → setoid1. intros; constructor 1; [ apply (unary_morphism1 s s1); @@ -355,8 +327,8 @@ definition unary_morphism1_setoid1: setoid1 → setoid1 → setoid2. alias symbol "eq" = "setoid1 eq". apply (∀a: carr1 s. f a = g a); | intros 1; simplify; intros; apply refl1; - | simplify; intros; apply sym1; apply H; - | simplify; intros; apply trans1; [2: apply H; | skip | apply H1]]] + | simplify; intros; apply sym1; apply f; + | simplify; intros; apply trans1; [2: apply f; | skip | apply f1]]] qed. definition SET1: category2. @@ -387,11 +359,30 @@ definition prop11_SET1 : intros; apply (prop11 A B w a b e); qed. -definition hint: Type_OF_category2 SET1 → Type1. +definition setoid2_OF_category2: Type_OF_category2 SET1 → setoid2. + intro; apply (setoid2_of_setoid1 t); qed. +coercion setoid2_OF_category2. + +definition objs2_OF_category1: Type_OF_category1 SET → objs2 SET1. + intro; apply (setoid1_of_setoid t); qed. +coercion objs2_OF_category1. + +definition Type1_OF_SET1: Type_OF_category2 SET1 → Type1. intro; whd in t; apply (carr1 t); qed. -coercion hint. +coercion Type1_OF_SET1. + +definition Type_OF_setoid1_of_carr: ∀U. carr U → Type_OF_setoid1 ?(*(setoid1_of_SET U)*). + [ apply setoid1_of_SET; apply U + | intros; apply c;] +qed. +coercion Type_OF_setoid1_of_carr. interpretation "SET dagger" 'prop1 h = (prop11_SET1 _ _ _ _ _ h). interpretation "unary morphism1" 'Imply a b = (arrows2 SET1 a b). interpretation "SET1 eq" 'eq x y = (eq_rel1 _ (eq'' _) x y). + +lemma unary_morphism1_of_arrows1_SET1: ∀S,T. (S ⇒ T) → unary_morphism1 S T. + intros; apply t; +qed. +coercion unary_morphism1_of_arrows1_SET1.