ndefinition overlaps ≝ λA.λU,V.∃x:A.x ∈ U ∧ x ∈ V.
interpretation "overlaps" 'overlaps U V = (overlaps ? U V).
-ndefinition intersect ≝ λA.λU,V:Ω \sup A.{ x | x ∈ U ∧ x ∈ V }.
+ndefinition intersect ≝ λA.λU,V:Ω^A.{ x | x ∈ U ∧ x ∈ V }.
interpretation "intersect" 'intersects U V = (intersect ? U V).
-ndefinition union ≝ λA.λU,V:Ω \sup A.{ x | x ∈ U ∨ x ∈ V }.
+ndefinition union ≝ λA.λU,V:Ω^A.{ x | x ∈ U ∨ x ∈ V }.
interpretation "union" 'union U V = (union ? U V).
-ndefinition big_union ≝ λA.λT:Type[0].λf:T → Ω \sup A.{ x | ∃i. x ∈ f i }.
+ndefinition big_union ≝ λA,B.λT:Ω^A.λf:A → Ω^B.{ x | ∃i. i ∈ T ∧ x ∈ f i }.
-ndefinition big_intersection ≝ λA.λT:Type[0].λf:T → Ω \sup A.{ x | ∀i. x ∈ f i }.
+ndefinition big_intersection ≝ λA,B.λT:Ω^A.λf:A → Ω^B.{ x | ∀i. i ∈ T → x ∈ f i }.
-ndefinition full_set: ∀A. Ω \sup A ≝ λA.{ x | True }.
-(* bug dichiarazione coercion qui *)
-(* ncoercion full_set : ∀A:Type[0]. Ω \sup A ≝ full_set on _A: Type[0] to (Ω \sup ?). *)
+ndefinition full_set: ∀A. Ω^A ≝ λA.{ x | True }.
-nlemma subseteq_refl: ∀A.∀S: Ω \sup A. S ⊆ S.
+nlemma subseteq_refl: ∀A.∀S: Ω^A. S ⊆ S.
#A; #S; #x; #H; nassumption.
nqed.
-nlemma subseteq_trans: ∀A.∀S,T,U: Ω \sup A. S ⊆ T → T ⊆ U → S ⊆ U.
+nlemma subseteq_trans: ∀A.∀S,T,U: Ω^A. S ⊆ T → T ⊆ U → S ⊆ U.
#A; #S; #T; #U; #H1; #H2; #x; #P; napply H2; napply H1; nassumption.
nqed.
include "properties/relations1.ma".
-ndefinition seteq: ∀A. equivalence_relation1 (Ω \sup A).
- #A; napply mk_equivalence_relation1
+ndefinition seteq: ∀A. equivalence_relation1 (Ω^A).
+ #A; @
[ napply (λS,S'. S ⊆ S' ∧ S' ⊆ S)
- | #S; napply conj; napply subseteq_refl
- | #S; #S'; *; #H1; #H2; napply conj; nassumption
- | #S; #T; #U; *; #H1; #H2; *; #H3; #H4; napply conj; napply subseteq_trans;
+ | #S; @; napply subseteq_refl
+ | #S; #S'; *; #H1; #H2; @; nassumption
+ | #S; #T; #U; *; #H1; #H2; *; #H3; #H4; @; napply subseteq_trans;
##[##2,5: nassumption |##1,4: ##skip |##*: nassumption]##]
-nqed.
+nqed.
include "sets/setoids1.ma".
+(* this has to be declared here, so that it is combined with carr *)
+ncoercion full_set : ∀A:Type[0]. Ω^A ≝ full_set on A: Type[0] to (Ω^?).
+
ndefinition powerclass_setoid: Type[0] → setoid1.
- #A; napply mk_setoid1
- [ napply (Ω \sup A)
- | napply seteq ]
+ #A; @[ napply (Ω^A)| napply seteq ]
nqed.
-unification hint 0 (∀A. (λx,y.True) (carr1 (powerclass_setoid A)) (Ω \sup A)).
+include "hints_declaration.ma".
+
+alias symbol "hint_decl" = "hint_decl_Type2".
+unification hint 0 ≔ A ⊢ carr1 (mk_setoid1 (Ω^A) (eq1 (powerclass_setoid A))) ≡ Ω^A.
(************ SETS OVER SETOIDS ********************)
include "logic/cprop.ma".
-nrecord qpowerclass (A: setoid) : Type[1] ≝
- { pc:> Ω \sup A;
- mem_ok': ∀x,x':A. x=x' → (x ∈ pc) = (x' ∈ pc)
+nrecord ext_powerclass (A: setoid) : Type[1] ≝
+ { ext_carr:> Ω^A; (* qui pc viene dichiarato con un target preciso...
+ forse lo si vorrebbe dichiarato con un target più lasco
+ ma la sintassi :> non lo supporta *)
+ ext_prop: ∀x,x':A. x=x' → (x ∈ ext_carr) = (x' ∈ ext_carr)
}.
+
+notation > "𝛀 ^ term 90 A" non associative with precedence 70
+for @{ 'ext_powerclass $A }.
+
+notation "Ω term 90 A \atop ≈" non associative with precedence 70
+for @{ 'ext_powerclass $A }.
-ndefinition qseteq: ∀A. equivalence_relation1 (qpowerclass A).
- #A; napply mk_equivalence_relation1
- [ napply (λS,S':qpowerclass A. eq_rel1 ? (eq1 (powerclass_setoid A)) S S')
+interpretation "extensional powerclass" 'ext_powerclass a = (ext_powerclass a).
+
+ndefinition Full_set: ∀A. 𝛀^A.
+ #A; @[ napply A | #x; #x'; #H; napply refl1]
+nqed.
+ncoercion Full_set: ∀A. ext_powerclass A ≝ Full_set on A: setoid to ext_powerclass ?.
+
+ndefinition ext_seteq: ∀A. equivalence_relation1 (𝛀^A).
+ #A; @
+ [ napply (λS,S'. S = S')
| #S; napply (refl1 ? (seteq A))
| #S; #S'; napply (sym1 ? (seteq A))
| #S; #T; #U; napply (trans1 ? (seteq A))]
nqed.
-ndefinition qpowerclass_setoid: setoid → setoid1.
- #A; napply mk_setoid1
- [ napply (qpowerclass A)
- | napply (qseteq A) ]
+ndefinition ext_powerclass_setoid: setoid → setoid1.
+ #A; @
+ [ napply (ext_powerclass A)
+ | napply (ext_seteq A) ]
+nqed.
+
+unification hint 0 ≔ A;
+ R ≟ (mk_setoid1 (𝛀^A) (eq1 (ext_powerclass_setoid A)))
+ (* ----------------------------------------------------- *) ⊢
+ carr1 R ≡ ext_powerclass A.
+
+
+(*
+ncoercion ext_carr' : ∀A.∀x:ext_powerclass_setoid A. Ω^A ≝ ext_carr
+on _x : (carr1 (ext_powerclass_setoid ?)) to (Ω^?).
+*)
+
+nlemma mem_ext_powerclass_setoid_is_morph:
+ ∀A. binary_morphism1 (setoid1_of_setoid A) (ext_powerclass_setoid A) CPROP.
+ #A; @
+ [ napply (λx,S. x ∈ S)
+ | #a; #a'; #b; #b'; #Ha; *; #Hb1; #Hb2; @; #H;
+ ##[ napply Hb1; napply (. (ext_prop … Ha^-1)); nassumption;
+ ##| napply Hb2; napply (. (ext_prop … Ha)); nassumption;
+ ##]
+ ##]
nqed.
-unification hint 0 (∀A. (λx,y.True) (carr1 (qpowerclass_setoid A)) (qpowerclass A)).
-ncoercion qpowerclass_hint: ∀A: setoid. ∀S: qpowerclass_setoid A. Ω \sup A ≝ λA.λS.S
- on _S: (carr1 (qpowerclass_setoid ?)) to (Ω \sup ?).
+unification hint 0 ≔ A:setoid, x, S;
+ SS ≟ (ext_carr ? S),
+ TT ≟ (mk_binary_morphism1 ???
+ (λx:setoid1_of_setoid ?.λS:ext_powerclass_setoid ?. x ∈ S)
+ (prop21 ??? (mem_ext_powerclass_setoid_is_morph A))),
+ XX ≟ (ext_powerclass_setoid A)
+ (*-------------------------------------*) ⊢
+ fun21 (setoid1_of_setoid A) XX CPROP TT x S
+ ≡ mem A SS x.
+
+nlemma subseteq_is_morph: ∀A. binary_morphism1 (ext_powerclass_setoid A) (ext_powerclass_setoid A) CPROP.
+ #A; @
+ [ napply (λS,S'. S ⊆ S')
+ | #a; #a'; #b; #b'; *; #Ha1; #Ha2; *; #Hb1; #Hb2; @; #H
+ [ napply (subseteq_trans … a)
+ [ nassumption | napply (subseteq_trans … b); nassumption ]
+ ##| napply (subseteq_trans … a')
+ [ nassumption | napply (subseteq_trans … b'); nassumption ] ##]
+nqed.
-nlemma mem_ok: ∀A. binary_morphism1 (setoid1_of_setoid A) (qpowerclass_setoid A) CPROP.
- #A; napply mk_binary_morphism1
- [ napply (λx.λS: qpowerclass_setoid A. x ∈ S) (* CSC: ??? *)
- | #a; #a'; #b; #b'; #Ha; #Hb; (* CSC: qui *; non funziona *)
- nwhd; nwhd in ⊢ (? (? % ??) (? % ??)); napply mk_iff; #H
- [ ncases Hb; #Hb1; #_; napply Hb1; napply (. (mem_ok' …))
- [ nassumption | napply Ha^-1 | ##skip ]
- ##| ncases Hb; #_; #Hb2; napply Hb2; napply (. (mem_ok' …))
- [ nassumption | napply Ha | ##skip ]##]
+unification hint 0 ≔ A,a,a'
+ (*-----------------------------------------------------------------*) ⊢
+ eq_rel ? (eq A) a a' ≡ eq_rel1 ? (eq1 (setoid1_of_setoid A)) a a'.
+
+nlemma intersect_is_ext: ∀A. 𝛀^A → 𝛀^A → 𝛀^A.
+ #A; #S; #S'; @ (S ∩ S');
+ #a; #a'; #Ha; @; *; #H1; #H2; @
+ [##1,2: napply (. Ha^-1‡#); nassumption;
+##|##3,4: napply (. Ha‡#); nassumption]
nqed.
-unification hint 0 (∀A,x,S. (λx,y.True) (fun21 ??? (mem_ok A) x S) (mem A S x)).
+alias symbol "hint_decl" = "hint_decl_Type1".
+unification hint 0 ≔
+ A : setoid, B,C : ext_powerclass A;
+ R ≟ (mk_ext_powerclass ? (B ∩ C) (ext_prop ? (intersect_is_ext ? B C)))
-nlemma subseteq_ok: ∀A. binary_morphism1 (qpowerclass_setoid A) (qpowerclass_setoid A) CPROP.
- #A; napply mk_binary_morphism1
- [ napply (λS,S': qpowerclass_setoid ?. S ⊆ S')
- | #a; #a'; #b; #b'; *; #Ha1; #Ha2; *; #Hb1; #Hb2; napply mk_iff; #H
- [ napply (subseteq_trans … a' a) (* anche qui, perche' serve a'? *)
- [ nassumption | napply (subseteq_trans … a b); nassumption ]
- ##| napply (subseteq_trans … a a') (* anche qui, perche' serve a'? *)
- [ nassumption | napply (subseteq_trans … a' b'); nassumption ] ##]
-nqed.
-
-nlemma intersect_ok: ∀A. binary_morphism1 (qpowerclass_setoid A) (qpowerclass_setoid A) (qpowerclass_setoid A).
- #A; napply mk_binary_morphism1
- [ #S; #S'; napply mk_qpowerclass
+ (* ------------------------------------------*) ⊢
+ ext_carr A R ≡ intersect ? (ext_carr ? B) (ext_carr ? C).
+
+nlemma intersect_is_morph:
+ ∀A. binary_morphism1 (powerclass_setoid A) (powerclass_setoid A) (powerclass_setoid A).
+ #A; @ (λS,S'. S ∩ S');
+ #a; #a'; #b; #b'; *; #Ha1; #Ha2; *; #Hb1; #Hb2; @; #x; nnormalize; *; #Ka; #Kb; @
+ [ napply Ha1; nassumption
+ | napply Hb1; nassumption
+ | napply Ha2; nassumption
+ | napply Hb2; nassumption]
+nqed.
+
+alias symbol "hint_decl" = "hint_decl_Type1".
+unification hint 0 ≔
+ A : Type[0], B,C : Ω^A;
+ R ≟ (mk_binary_morphism1 …
+ (λS,S'.S ∩ S')
+ (prop21 … (intersect_is_morph A)))
+ ⊢
+ fun21 (powerclass_setoid A) (powerclass_setoid A) (powerclass_setoid A) R B C
+ ≡ intersect ? B C.
+
+interpretation "prop21 mem" 'prop2 l r = (prop21 (setoid1_of_setoid ?) (ext_powerclass_setoid ?) ? ???? l r).
+interpretation "prop21 ext" 'prop2 l r = (prop21 (ext_powerclass_setoid ?) (ext_powerclass_setoid ?) ? ???? l r).
+
+nlemma intersect_is_ext_morph:
+ ∀A. binary_morphism1 (ext_powerclass_setoid A) (ext_powerclass_setoid A) (ext_powerclass_setoid A).
+ #A; @ (intersect_is_ext …); nlapply (prop21 … (intersect_is_morph A));
+#H; #a; #a'; #b; #b'; #H1; #H2; napply H; nassumption;
+nqed.
+
+unification hint 1 ≔
+ A:setoid, B,C : 𝛀^A;
+ R ≟ (mk_binary_morphism1 (ext_powerclass_setoid A) (ext_powerclass_setoid A) (ext_powerclass_setoid A)
+ (λS,S':carr1 (ext_powerclass_setoid A).
+ mk_ext_powerclass A (S∩S') (ext_prop A (intersect_is_ext ? S S')))
+ (prop21 … (intersect_is_ext_morph A))) ,
+ BB ≟ (ext_carr ? B),
+ CC ≟ (ext_carr ? C)
+ (* ------------------------------------------------------*) ⊢
+ ext_carr A
+ (fun21
+ (ext_powerclass_setoid A)
+ (ext_powerclass_setoid A)
+ (ext_powerclass_setoid A) R B C) ≡
+ intersect (carr A) BB CC.
+
+(*
+alias symbol "hint_decl" = "hint_decl_Type2".
+unification hint 0 ≔
+ A : setoid, B,C : 𝛀^A ;
+ CC ≟ (ext_carr ? C),
+ BB ≟ (ext_carr ? B),
+ C1 ≟ (carr1 (powerclass_setoid (carr A))),
+ C2 ≟ (carr1 (ext_powerclass_setoid A))
+ ⊢
+ eq_rel1 C1 (eq1 (powerclass_setoid (carr A))) BB CC ≡
+ eq_rel1 C2 (eq1 (ext_powerclass_setoid A)) B C.
+
+unification hint 0 ≔
+ A, B : CPROP ⊢ iff A B ≡ eq_rel1 ? (eq1 CPROP) A B.
+*)
+
+nlemma test: ∀U.∀A,B:𝛀^U. A ∩ B = A →
+ ∀x,y. x=y → x ∈ A → y ∈ A ∩ B.
+ #U; #A; #B; #H; #x; #y; #K; #K2;
+napply (. (prop21 ??? ? ???? K^-1 (H^-1‡#)));
+ nassumption;
+nqed.
+
+
+nlemma intersect_ok: ∀A. binary_morphism1 (ext_powerclass_setoid A) (ext_powerclass_setoid A) (ext_powerclass_setoid A).
+ #A; @
+ [ #S; #S'; @
[ napply (S ∩ S')
- | #a; #a'; #Ha; nwhd in ⊢ (? ? ? % %); napply mk_iff; *; #H1; #H2; napply conj
- [##1,2: napply (. (mem_ok' …)^-1) [##3,6: nassumption |##1,4: nassumption |##*: ##skip]
- ##|##3,4: napply (. (mem_ok' …)) [##2,5: nassumption |##1,4: nassumption |##*: ##skip]##]##]
- ##| #a; #a'; #b; #b'; #Ha; #Hb; nwhd; napply conj; #x; nwhd in ⊢ (% → %); #H
- [ napply (. ((#‡Ha^-1)‡(#‡Hb^-1))); nassumption
+ | #a; #a'; #Ha;
+ nwhd in ⊢ (? ? ? % %); @; *; #H1; #H2; @
+ [##1,2: napply (. Ha^-1‡#); nassumption;
+ ##|##3,4: napply (. Ha‡#); nassumption]##]
+ ##| #a; #a'; #b; #b'; #Ha; #Hb; nwhd; @; #x; nwhd in ⊢ (% → %); #H
+ [ alias symbol "invert" = "setoid1 symmetry".
+ napply (. ((#‡Ha^-1)‡(#‡Hb^-1))); nassumption
| napply (. ((#‡Ha)‡(#‡Hb))); nassumption ]##]
nqed.
-unification hint 0 (∀A.∀U,V.(λx,y.True) (fun21 ??? (intersect_ok A) U V) (intersect A U V)).
+(* unfold if intersect, exposing fun21 *)
+alias symbol "hint_decl" = "hint_decl_Type1".
+unification hint 0 ≔
+ A : setoid, B,C : qpowerclass A ⊢
+ pc A (fun21 …
+ (mk_binary_morphism1 …
+ (λS,S':qpowerclass_setoid A.mk_qpowerclass ? (S ∩ S') (mem_ok' ? (intersect_ok ? S S')))
+ (prop21 … (intersect_ok A)))
+ B
+ C)
+ ≡ intersect ? (pc ? B) (pc ? C).
nlemma test: ∀A:setoid. ∀U,V:qpowerclass A. ∀x,x':setoid1_of_setoid A. x=x' → x ∈ U ∩ V → x' ∈ U ∩ V.
- #A; #U; #V; #x; #x'; #H; #p;
- (* CSC: senza la change non funziona! *)
- nchange with (x' ∈ (fun21 ??? (intersect_ok A) U V));
- napply (. (H^-1‡#)); nassumption.
+ #A; #U; #V; #x; #x'; #H; #p; napply (. (H^-1‡#)); nassumption.
nqed.
+*)
+*)
-(*
-(* qui non funziona una cippa *)
-ndefinition image: ∀A,B. (carr A → carr B) → Ω \sup A → Ω \sup B ≝
- λA,B:setoid.λf:carr A → carr B.λSa:Ω \sup A.
- {y | ∃x. x ∈ Sa ∧ eq_rel (carr B) (eq B) ? ?(*(f x) y*)}.
- ##[##2: napply (f x); ##|##3: napply y]
- #a; #a'; #H; nwhd; nnormalize; (* per togliere setoid1_of_setoid *) napply (mk_iff ????);
- *; #x; #Hx; napply (ex_intro … x)
- [ napply (. (#‡(#‡#)));
-
-ndefinition counter_image: ∀A,B. (A → B) → Ω \sup B → Ω \sup A ≝
+ndefinition image: ∀A,B. (carr A → carr B) → Ω^A → Ω^B ≝
+ λA,B:setoid.λf:carr A → carr B.λSa:Ω^A.
+ {y | ∃x. x ∈ Sa ∧ eq_rel (carr B) (eq B) (f x) y}.
+
+ndefinition counter_image: ∀A,B. (carr A → carr B) → Ω^B → Ω^A ≝
λA,B,f,Sb. {x | ∃y. y ∈ Sb ∧ f x = y}.
-*)
(******************* compatible equivalence relations **********************)
nrecord compatible_equivalence_relation (A: setoid) : Type[1] ≝
{ rel:> equivalence_relation A;
- compatibility: ∀x,x':A. x=x' → eq_rel ? rel x x' (* coercion qui non va *)
+ compatibility: ∀x,x':A. x=x' → rel x x'
}.
ndefinition quotient: ∀A. compatible_equivalence_relation A → setoid.
- #A; #R; napply mk_setoid
- [ napply A
- | napply R]
+ #A; #R; @ A R;
nqed.
(******************* first omomorphism theorem for sets **********************)
ndefinition eqrel_of_morphism:
∀A,B. unary_morphism A B → compatible_equivalence_relation A.
- #A; #B; #f; napply mk_compatible_equivalence_relation
- [ napply mk_equivalence_relation
+ #A; #B; #f; @
+ [ @
[ napply (λx,y. f x = f y)
| #x; napply refl | #x; #y; napply sym | #x; #y; #z; napply trans]
-##| #x; #x'; #H; nwhd; napply (.= (†H)); napply refl ]
+##| #x; #x'; #H; nwhd; alias symbol "prop1" = "prop1".
+napply (.= (†H)); napply refl ]
nqed.
ndefinition canonical_proj: ∀A,R. unary_morphism A (quotient A R).
- #A; #R; napply mk_unary_morphism
- [ napply (λx.x) | #a; #a'; #H; napply (compatibility ? R … H) ]
+ #A; #R; @
+ [ napply (λx.x) | #a; #a'; #H; napply (compatibility … R … H) ]
nqed.
ndefinition quotiented_mor:
∀A,B.∀f:unary_morphism A B.
- unary_morphism (quotient ? (eqrel_of_morphism ?? f)) B.
- #A; #B; #f; napply mk_unary_morphism
+ unary_morphism (quotient … (eqrel_of_morphism … f)) B.
+ #A; #B; #f; @
[ napply f | #a; #a'; #H; nassumption]
nqed.
nlemma first_omomorphism_theorem_functions1:
∀A,B.∀f: unary_morphism A B.
- ∀x. f x = quotiented_mor ??? (canonical_proj ? (eqrel_of_morphism ?? f) x).
+ ∀x. f x = quotiented_mor … (canonical_proj … (eqrel_of_morphism … f) x).
#A; #B; #f; #x; napply refl;
nqed.
-ndefinition surjective ≝ λA,B.λf:unary_morphism A B. ∀y.∃x. f x = y.
+ndefinition surjective ≝
+ λA,B.λS: ext_powerclass A.λT: ext_powerclass B.λf:unary_morphism A B.
+ ∀y. y ∈ T → ∃x. x ∈ S ∧ f x = y.
-ndefinition injective ≝ λA,B.λf:unary_morphism A B. ∀x,x'. f x = f x' → x = x'.
+ndefinition injective ≝
+ λA,B.λS: ext_powerclass A.λf:unary_morphism A B.
+ ∀x,x'. x ∈ S → x' ∈ S → f x = f x' → x = x'.
nlemma first_omomorphism_theorem_functions2:
- ∀A,B.∀f: unary_morphism A B. surjective ?? (canonical_proj ? (eqrel_of_morphism ?? f)).
- #A; #B; #f; nwhd; #y; napply (ex_intro … y); napply refl.
+ ∀A,B.∀f: unary_morphism A B.
+ surjective … (Full_set ?) (Full_set ?) (canonical_proj ? (eqrel_of_morphism … f)).
+ #A; #B; #f; nwhd; #y; #Hy; @ y; @ I ; napply refl;
+ (* bug, prova @ I refl *)
nqed.
nlemma first_omomorphism_theorem_functions3:
- ∀A,B.∀f: unary_morphism A B. injective ?? (quotiented_mor ?? f).
- #A; #B; #f; nwhd; #x; #x'; #H; nassumption.
+ ∀A,B.∀f: unary_morphism A B.
+ injective … (Full_set ?) (quotiented_mor … f).
+ #A; #B; #f; nwhd; #x; #x'; #Hx; #Hx'; #K; nassumption.
nqed.
-(************************** partitions ****************************)
-
-nrecord partition (A: Type[0]) : Type[1] ≝
- { index_set: setoid;
- class: index_set → Ω \sup A;
- disjoint: ∀i,j. ¬ (i = j) → ¬(class i ≬ class j);
- covers: big_union ?? class = full_set A
+nrecord isomorphism (A, B : setoid) (S: ext_powerclass A) (T: ext_powerclass B) : Type[0] ≝
+ { iso_f:> unary_morphism A B;
+ f_closed: ∀x. x ∈ S → iso_f x ∈ T;
+ f_sur: surjective … S T iso_f;
+ f_inj: injective … S iso_f
}.
(*
-nrecord has_card (A: Type[0]) (S: Ω \sup A) (n: nat) : Prop ≝
- { f: ∀m:nat. m < n → S;
- f_inj: injective ?? f;
- f_sur: surjective ?? f
+nrecord isomorphism (A, B : setoid) (S: qpowerclass A) (T: qpowerclass B) : CProp[0] ≝
+ { iso_f:> unary_morphism A B;
+ f_closed: ∀x. x ∈ pc A S → fun1 ?? iso_f x ∈ pc B T}.
+
+
+ncheck (λA:?.
+ λB:?.
+ λS:?.
+ λT:?.
+ λxxx:isomorphism A B S T.
+ match xxx
+ return λxxx:isomorphism A B S T.
+ ∀x: carr A.
+ ∀x_72: mem (carr A) (pc A S) x.
+ mem (carr B) (pc B T) (fun1 A B ((λ_.?) A B S T xxx) x)
+ with [ mk_isomorphism _ yyy ⇒ yyy ] ).
+
+ ;
}.
-
-nlemma subset_of_finite:
- ∀A. ∃n. has_card ? (full_subset A) n → ∀S. ∃m. has_card ? S m.
-nqed.
-
-nlemma partition_splits_card:
- ∀A. ∀P: partition A. ∀s: index_set P → nat.
- (∀i. has_card ? (class i) = s i) →
- has_card ? (full_subset A) (big_plus ? (λi. s i)).
-nqed.
-*)
\ No newline at end of file
+*)