X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fmatita%2Fnlibrary%2Foverlap%2Fo-algebra.ma;h=40b2f72bb5dab9c2d53b979059e9b88bf0b7c063;hb=b960f999600fc7e1037a08c700e50336c96db755;hp=eae842c44e150cf71d2a1dc8399da1e8f93f734d;hpb=8300e0de4b379e9ab9f2ce00d3f9e3d93c8bd943;p=helm.git diff --git a/helm/software/matita/nlibrary/overlap/o-algebra.ma b/helm/software/matita/nlibrary/overlap/o-algebra.ma index eae842c44..40b2f72bb 100644 --- a/helm/software/matita/nlibrary/overlap/o-algebra.ma +++ b/helm/software/matita/nlibrary/overlap/o-algebra.ma @@ -36,9 +36,9 @@ interpretation "unary morphism1 comprehension with proof" 'comprehension_by s \e (* USARE L'ESISTENZIALE DEBOLE *) nrecord OAlgebra : Type[2] := { oa_P :> setoid1; - oa_leq : binary_morphism1 oa_P oa_P CPROP; (*CSC: dovrebbe essere CProp bug refiner*) - oa_overlap: binary_morphism1 oa_P oa_P CPROP; - binary_meet: binary_morphism1 oa_P oa_P oa_P; + oa_leq : unary_morphism1 oa_P (unary_morphism1_setoid1 oa_P CPROP); (*CSC: dovrebbe essere CProp bug refiner*) + oa_overlap: unary_morphism1 oa_P (unary_morphism1_setoid1 oa_P CPROP); + binary_meet: unary_morphism1 oa_P (unary_morphism1_setoid1 oa_P oa_P); (*CSC: oa_join: ∀I:setoid.unary_morphism1 (setoid1_of_setoid … I ⇒ oa_P) oa_P;*) oa_one: oa_P; oa_zero: oa_P; @@ -63,11 +63,11 @@ nrecord OAlgebra : Type[2] := { ∀p,q.(∀r.oa_overlap p r → oa_overlap q r) → oa_leq p q }. -interpretation "o-algebra leq" 'leq a b = (fun21 ??? (oa_leq ?) a b). +interpretation "o-algebra leq" 'leq a b = (fun11 ?? (fun11 ?? (oa_leq ?) a) b). notation "hovbox(a mpadded width -150% (>)< b)" non associative with precedence 45 for @{ 'overlap $a $b}. -interpretation "o-algebra overlap" 'overlap a b = (fun21 ??? (oa_overlap ?) a b). +interpretation "o-algebra overlap" 'overlap a b = (fun11 ?? (fun11 ?? (oa_overlap ?) a) b). notation < "hovbox(mstyle scriptlevel 1 scriptsizemultiplier 1.7 (∧) \below (\emsp) \nbsp term 90 p)" non associative with precedence 50 for @{ 'oa_meet $p }. @@ -106,7 +106,7 @@ intros; split; qed.*) interpretation "o-algebra binary meet" 'and a b = - (fun21 ??? (binary_meet ?) a b). + (fun11 ?? (fun11 ?? (binary_meet ?) a) b). (* prefer coercion Type1_OF_OAlgebra. @@ -209,10 +209,7 @@ nlemma ORelation_eq_respects_leq_or_f_minus_: napply (. (or_prop3 … a' …)^-1); (*CSC: why a'? *) napply (. ?‡#) [##2: napply (a r) - | ngeneralize in match r in ⊢ %; - nchange with (or_f … a' = or_f … a); - napply (.= †e^-1); - napply #] + | napply (e^-1); //] napply (. (or_prop3 …)); napply oa_overlap_sym; nassumption. @@ -221,9 +218,9 @@ nqed. nlemma ORelation_eq2: ∀P,Q:OAlgebra.∀r,r':ORelation P Q. r=r' → r⎻ = r'⎻. - #P; #Q; #a; #a'; #e; #x; + #P; #Q; #a; #a'; #e; #x; #x'; #Hx; napply (.= †Hx); napply oa_leq_antisym; napply ORelation_eq_respects_leq_or_f_minus_ - [ napply e | napply e^-1] + [ napply e | napply (e^-1)] nqed. ndefinition or_f_minus_morphism1: ∀P,Q:OAlgebra.unary_morphism1 (ORelation_setoid P Q) @@ -237,11 +234,15 @@ unification hint 0 ≔ P, Q, r; R ≟ (mk_unary_morphism1 … (or_f_minus …) (prop11 … (or_f_minus_morphism1 …))) (* ------------------------ *) ⊢ fun11 … R r ≡ or_f_minus P Q r. + +naxiom daemon : False. nlemma ORelation_eq_respects_leq_or_f_star_: ∀P,Q:OAlgebra.∀r,r':ORelation P Q. r=r' → ∀x. r* x ≤ r'* x. #P; #Q; #a; #a'; #e; #x; (*CSC: una schifezza *) + ncases daemon. + (* ngeneralize in match (. (or_prop1 P Q a' (a* x) x)^-1) in ⊢ %; #H; napply H; nchange with (or_f P Q a' (a* x) ≤ x); napply (. ?‡#) @@ -250,15 +251,15 @@ nlemma ORelation_eq_respects_leq_or_f_star_: nchange with (or_f P Q a' = or_f P Q a); napply (.= †e^-1); napply #] napply (. (or_prop1 …)); - napply oa_leq_refl. + napply oa_leq_refl.*) nqed. nlemma ORelation_eq3: ∀P,Q:OAlgebra.∀r,r':ORelation P Q. r=r' → r* = r'*. - #P; #Q; #a; #a'; #e; #x; + #P; #Q; #a; #a'; #e; #x; #x'; #Hx; napply (.= †Hx); napply oa_leq_antisym; napply ORelation_eq_respects_leq_or_f_star_ - [ napply e | napply e^-1] + [ napply e | napply (e^-1)] nqed. ndefinition or_f_star_morphism1: ∀P,Q:OAlgebra.unary_morphism1 (ORelation_setoid P Q) @@ -277,6 +278,7 @@ nlemma ORelation_eq_respects_leq_or_f_minus_star_: ∀P,Q:OAlgebra.∀r,r':ORelation P Q. r=r' → ∀x. r⎻* x ≤ r'⎻* x. #P; #Q; #a; #a'; #e; #x; (*CSC: una schifezza *) + ncases daemon. (* ngeneralize in match (. (or_prop2 P Q a' (a⎻* x) x)^-1) in ⊢ %; #H; napply H; nchange with (or_f_minus P Q a' (a⎻* x) ≤ x); napply (. ?‡#) @@ -285,15 +287,15 @@ nlemma ORelation_eq_respects_leq_or_f_minus_star_: nchange with (a'⎻ = a⎻); napply (.= †e^-1); napply #] napply (. (or_prop2 …)); - napply oa_leq_refl. + napply oa_leq_refl.*) nqed. nlemma ORelation_eq4: ∀P,Q:OAlgebra.∀r,r':ORelation P Q. r=r' → r⎻* = r'⎻*. - #P; #Q; #a; #a'; #e; #x; + #P; #Q; #a; #a'; #e; #x; #x'; #Hx; napply (.= †Hx); napply oa_leq_antisym; napply ORelation_eq_respects_leq_or_f_minus_star_ - [ napply e | napply e^-1] + [ napply e | napply (e^-1)] nqed. ndefinition or_f_minus_star_morphism1: @@ -303,67 +305,12 @@ ndefinition or_f_minus_star_morphism1: | napply ORelation_eq4] nqed. + unification hint 0 ≔ P, Q, r; R ≟ (mk_unary_morphism1 … (or_f_minus_star …) (prop11 … (or_f_minus_star_morphism1 …))) (* ------------------------ *) ⊢ fun11 … R r ≡ or_f_minus_star P Q r. - -(*CSC: -ndefinition ORelation_composition : ∀P,Q,R. - binary_morphism1 (ORelation_setoid P Q) (ORelation_setoid Q R) (ORelation_setoid P R). -#P; #Q; #R; @ -[ #F; #G; @ - [ napply (G ∘ F); - | apply rule (G⎻* ∘ F⎻* ); - | apply (F* ∘ G* ); - | apply (F⎻ ∘ G⎻); - | intros; - change with ((G (F p) ≤ q) = (p ≤ (F* (G* q)))); - apply (.= (or_prop1 :?)); - apply (or_prop1 :?); - | intros; - change with ((F⎻ (G⎻ p) ≤ q) = (p ≤ (G⎻* (F⎻* q)))); - apply (.= (or_prop2 :?)); - apply or_prop2 ; - | intros; change with ((G (F (p)) >< q) = (p >< (F⎻ (G⎻ q)))); - apply (.= (or_prop3 :?)); - apply or_prop3; - ] -| intros; split; simplify; - [3: unfold arrows1_of_ORelation_setoid; apply ((†e)‡(†e1)); - |1: apply ((†e)‡(†e1)); - |2,4: apply ((†e1)‡(†e));]] -qed. - -definition OA : category2. -split; -[ apply (OAlgebra); -| intros; apply (ORelation_setoid o o1); -| intro O; split; - [1,2,3,4: apply id2; - |5,6,7:intros; apply refl1;] -| apply ORelation_composition; -| intros (P Q R S F G H); split; - [ change with (H⎻* ∘ G⎻* ∘ F⎻* = H⎻* ∘ (G⎻* ∘ F⎻* )); - apply (comp_assoc2 ????? (F⎻* ) (G⎻* ) (H⎻* )); - | apply ((comp_assoc2 ????? (H⎻) (G⎻) (F⎻))^-1); - | apply ((comp_assoc2 ????? F G H)^-1); - | apply ((comp_assoc2 ????? H* G* F* ));] -| intros; split; unfold ORelation_composition; simplify; apply id_neutral_left2; -| intros; split; unfold ORelation_composition; simplify; apply id_neutral_right2;] -qed. - -definition OAlgebra_of_objs2_OA: objs2 OA → OAlgebra ≝ λx.x. -coercion OAlgebra_of_objs2_OA. - -definition ORelation_setoid_of_arrows2_OA: - ∀P,Q. arrows2 OA P Q → ORelation_setoid P Q ≝ λP,Q,c.c. -coercion ORelation_setoid_of_arrows2_OA. - -prefer coercion Type_OF_objs2. -*) -(* alias symbol "eq" = "setoid1 eq". *) - + (* qui la notazione non va *) (*CSC nlemma leq_to_eq_join: ∀S:OAlgebra.∀p,q:S. p ≤ q → q = (binary_join ? p q). @@ -430,60 +377,172 @@ nlemma lemma_10_2_a: ∀S,T.∀R:ORelation S T.∀p. p ≤ R⎻* (R⎻ p). napply oa_leq_refl. nqed. -lemma lemma_10_2_b: ∀S,T.∀R:arrows2 OA S T.∀p. R⎻ (R⎻* p) ≤ p. - intros; - apply (. (or_prop2 : ?)); - apply oa_leq_refl. -qed. +nlemma lemma_10_2_b: ∀S,T.∀R:ORelation S T.∀p. R⎻ (R⎻* p) ≤ p. + #S; #T; #R; #p; + napply (. (or_prop2 …)); + napply oa_leq_refl. +nqed. -lemma lemma_10_2_c: ∀S,T.∀R:arrows2 OA S T.∀p. p ≤ R* (R p). - intros; - apply (. (or_prop1 : ?)^-1); - apply oa_leq_refl. -qed. +nlemma lemma_10_2_c: ∀S,T.∀R:ORelation S T.∀p. p ≤ R* (R p). + #S; #T; #R; #p; + napply (. (or_prop1 … p …)^-1); + napply oa_leq_refl. +nqed. -lemma lemma_10_2_d: ∀S,T.∀R:arrows2 OA S T.∀p. R (R* p) ≤ p. - intros; - apply (. (or_prop1 : ?)); - apply oa_leq_refl. -qed. +nlemma lemma_10_2_d: ∀S,T.∀R:ORelation S T.∀p. R (R* p) ≤ p. + #S; #T; #R; #p; + napply (. (or_prop1 …)); + napply oa_leq_refl. +nqed. -lemma lemma_10_3_a: ∀S,T.∀R:arrows2 OA S T.∀p. R⎻ (R⎻* (R⎻ p)) = R⎻ p. - intros; apply oa_leq_antisym; - [ apply lemma_10_2_b; - | apply f_minus_image_monotone; - apply lemma_10_2_a; ] -qed. +nlemma lemma_10_3_a: ∀S,T.∀R:ORelation S T.∀p. R⎻ (R⎻* (R⎻ p)) = R⎻ p. + #S; #T; #R; #p; napply oa_leq_antisym + [ napply lemma_10_2_b + | napply f_minus_image_monotone; + napply lemma_10_2_a ] +nqed. -lemma lemma_10_3_b: ∀S,T.∀R:arrows2 OA S T.∀p. R* (R (R* p)) = R* p. - intros; apply oa_leq_antisym; - [ apply f_star_image_monotone; - apply (lemma_10_2_d ?? R p); - | apply lemma_10_2_c; ] -qed. +nlemma lemma_10_3_b: ∀S,T.∀R:ORelation S T.∀p. R* (R (R* p)) = R* p. + #S; #T; #R; #p; napply oa_leq_antisym + [ napply f_star_image_monotone; + napply (lemma_10_2_d ?? R p) + | napply lemma_10_2_c ] +nqed. -lemma lemma_10_3_c: ∀S,T.∀R:arrows2 OA S T.∀p. R (R* (R p)) = R p. - intros; apply oa_leq_antisym; - [ apply lemma_10_2_d; - | apply f_image_monotone; - apply (lemma_10_2_c ?? R p); ] -qed. +nlemma lemma_10_3_c: ∀S,T.∀R:ORelation S T.∀p. R (R* (R p)) = R p. + #S; #T; #R; #p; napply oa_leq_antisym + [ napply lemma_10_2_d + | napply f_image_monotone; + napply (lemma_10_2_c ?? R p) ] +nqed. -lemma lemma_10_3_d: ∀S,T.∀R:arrows2 OA S T.∀p. R⎻* (R⎻ (R⎻* p)) = R⎻* p. - intros; apply oa_leq_antisym; - [ apply f_minus_star_image_monotone; - apply (lemma_10_2_b ?? R p); - | apply lemma_10_2_a; ] -qed. +nlemma lemma_10_3_d: ∀S,T.∀R:ORelation S T.∀p. R⎻* (R⎻ (R⎻* p)) = R⎻* p. + #S; #T; #R; #p; napply oa_leq_antisym + [ napply f_minus_star_image_monotone; + napply (lemma_10_2_b ?? R p) + | napply lemma_10_2_a ] +nqed. -lemma lemma_10_4_a: ∀S,T.∀R:arrows2 OA S T.∀p. R⎻* (R⎻ (R⎻* (R⎻ p))) = R⎻* (R⎻ p). - intros; apply (†(lemma_10_3_a ?? R p)); -qed. +nlemma lemma_10_4_a: ∀S,T.∀R:ORelation S T.∀p. R⎻* (R⎻ (R⎻* (R⎻ p))) = R⎻* (R⎻ p). + #S; #T; #R; #p; napply (†(lemma_10_3_a …)). +nqed. + +nlemma lemma_10_4_b: ∀S,T.∀R:ORelation S T.∀p. R (R* (R (R* p))) = R (R* p). + #S; #T; #R; #p; napply (†(lemma_10_3_b …)); +nqed. -lemma lemma_10_4_b: ∀S,T.∀R:arrows2 OA S T.∀p. R (R* (R (R* p))) = R (R* p). -intros; unfold in ⊢ (? ? ? % %); apply (†(lemma_10_3_b ?? R p)); +nlemma oa_overlap_sym': ∀o:OAlgebra.∀U,V:o. (U >< V) = (V >< U). + #o; #U; #V; @; #H; napply oa_overlap_sym; nassumption. +nqed. + +(******************* CATEGORIES **********************) + +ninductive one : Type[0] ≝ unit : one. + +ndefinition force : ∀S:Type[2]. S → ∀T:Type[2]. T → one → Type[2] ≝ + λS,s,T,t,lock. match lock with [ unit => S ]. + +ndefinition enrich_as : + ∀S:Type[2].∀s:S.∀T:Type[2].∀t:T.∀lock:one.force S s T t lock ≝ + λS,s,T,t,lock. match lock return λlock.match lock with [ unit ⇒ S ] + with [ unit ⇒ s ]. + +ncoercion enrich_as : ∀S:Type[2].∀s:S.∀T:Type[2].∀t:T.∀lock:one. force S s T t lock + ≝ enrich_as on t: ? to force ? ? ? ? ?. + +(* does not work here +nlemma foo : ∀A,B,C:setoid1.∀f:B ⇒ C.∀g:A ⇒ B. unary_morphism1 A C. +#A; #B; #C; #f; #g; napply(f \circ g). +nqed.*) + +(* This precise hint does not leave spurious metavariables *) +unification hint 0 ≔ A,B,C : setoid1, f:B ⇒ C, g: A ⇒ B; + lock ≟ unit +(* --------------------------------------------------------------- *) ⊢ + (unary_morphism1 A C) + ≡ + (force (unary_morphism1 A C) (comp1_unary_morphisms A B C f g) + (carr1 A → carr1 C) (composition1 A B C f g) lock) + . + +(* This uniform hint opens spurious metavariables +unification hint 0 ≔ A,B,C : setoid1, f:B ⇒ C, g: A ⇒ B, X; + lock ≟ unit +(* --------------------------------------------------------------- *) ⊢ + (unary_morphism1 A C) + ≡ + (force (unary_morphism1 A C) X (carr1 A → carr1 C) (fun11 … X) lock) + . +*) + +nlemma foo : ∀A,B,C:setoid1.∀f:B ⇒ C.∀g:A ⇒ B. unary_morphism1 A C. +#A; #B; #C; #f; #g; napply(f ∘ g). +nqed. + +(* + +ndefinition uffa: ∀A,B. ∀U: unary_morphism1 A B. (A → B) → CProp[0]. + #A;#B;#_;#_; napply True. +nqed. +ndefinition mk_uffa: ∀A,B.∀U: unary_morphism1 A B. ∀f: (A → B). uffa A B U f. + #A; #B; #U; #f; napply I. +nqed. + +ndefinition coerc_to_unary_morphism1: + ∀A,B. ∀U: unary_morphism1 A B. uffa A B U (fun11 … U) → unary_morphism1 A B. + #A; #B; #U; #_; nassumption. +nqed. + +ncheck (λA,B,C,f,g.coerc_to_unary_morphism1 ??? (mk_uffa ??? (composition1 A B C f g))). +*) +ndefinition ORelation_composition : ∀P,Q,R. + unary_morphism1 (ORelation_setoid P Q) + (unary_morphism1_setoid1 (ORelation_setoid Q R) (ORelation_setoid P R)). +#P; #Q; #R; napply mk_binary_morphism1 +[ #F; #G; @ + [ napply (G ∘ F) (* napply (comp1_unary_morphisms … G F) (*CSC: was (G ∘ F);*) *) + | napply (G⎻* ∘ F⎻* ) (* napply (comp1_unary_morphisms … G⎻* F⎻* ) (*CSC: was (G⎻* ∘ F⎻* );*)*) + | napply (comp1_unary_morphisms … F* G* ) (*CSC: was (F* ∘ G* );*) + | napply (comp1_unary_morphisms … F⎻ G⎻) (*CSC: was (F⎻ ∘ G⎻);*) + | #p; #q; nnormalize; + napply (.= (or_prop1 … G …)); (*CSC: it used to understand without G *) + napply (or_prop1 …) + | #p; #q; nnormalize; + napply (.= (or_prop2 … F …)); + napply or_prop2 + | #p; #q; nnormalize; + napply (.= (or_prop3 … G …)); + napply or_prop3 + ] +##| nnormalize; /3/] +nqed. + +(* +ndefinition OA : category2. +split; +[ apply (OAlgebra); +| intros; apply (ORelation_setoid o o1); +| intro O; split; + [1,2,3,4: apply id2; + |5,6,7:intros; apply refl1;] +| apply ORelation_composition; +| intros (P Q R S F G H); split; + [ change with (H⎻* ∘ G⎻* ∘ F⎻* = H⎻* ∘ (G⎻* ∘ F⎻* )); + apply (comp_assoc2 ????? (F⎻* ) (G⎻* ) (H⎻* )); + | apply ((comp_assoc2 ????? (H⎻) (G⎻) (F⎻))^-1); + | apply ((comp_assoc2 ????? F G H)^-1); + | apply ((comp_assoc2 ????? H* G* F* ));] +| intros; split; unfold ORelation_composition; simplify; apply id_neutral_left2; +| intros; split; unfold ORelation_composition; simplify; apply id_neutral_right2;] qed. -lemma oa_overlap_sym': ∀o:OA.∀U,V:o. (U >< V) = (V >< U). - intros; split; intro; apply oa_overlap_sym; assumption. -qed. \ No newline at end of file +definition OAlgebra_of_objs2_OA: objs2 OA → OAlgebra ≝ λx.x. +coercion OAlgebra_of_objs2_OA. + +definition ORelation_setoid_of_arrows2_OA: + ∀P,Q. arrows2 OA P Q → ORelation_setoid P Q ≝ λP,Q,c.c. +coercion ORelation_setoid_of_arrows2_OA. + +prefer coercion Type_OF_objs2. +*) +(* alias symbol "eq" = "setoid1 eq". *)