ndefinition full_set: ∀A. Ω^A ≝ λA.{ x | True }.
nlemma subseteq_refl: ∀A.∀S: Ω^A. S ⊆ S.
- #A; #S; #x; #H; nassumption.
-nqed.
+//.nqed.
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.
+/3/.nqed.
include "properties/relations1.ma".
ndefinition seteq: ∀A. equivalence_relation1 (Ω^A).
#A; @
[ napply (λS,S'. S ⊆ S' ∧ S' ⊆ S)
- | #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]##]
+ | /2/
+ | #S; #S'; *; /3/
+ | #S; #T; #U; *; #H1; #H2; *; /4/]
nqed.
include "sets/setoids1.ma".
ncoercion full_set : ∀A:Type[0]. Ω^A ≝ full_set on A: Type[0] to (Ω^?).
ndefinition powerclass_setoid: Type[0] → setoid1.
- #A; @[ napply (Ω^A)| napply seteq ]
+ #A; @(Ω^A);//.
nqed.
include "hints_declaration.ma".
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))]
+ #A; @ [ napply (λS,S'. S = S') ] /2/.
nqed.
ndefinition ext_powerclass_setoid: setoid → setoid1.
- #A; @
- [ napply (ext_powerclass A)
- | napply (ext_seteq A) ]
+ #A; @ (ext_seteq A).
nqed.
unification hint 0 ≔ A;
(* ----------------------------------------------------- *) ⊢
carr1 R ≡ ext_powerclass A.
-
+(*
+interpretation "prop21 mem" 'prop2 l r = (prop21 (setoid1_of_setoid ?) (ext_powerclass_setoid ?) ? ? ???? l r).
+*)
+
(*
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;
- ##]
- ##]
+ ∀A. unary_morphism1 (setoid1_of_setoid A) (unary_morphism1_setoid1 (ext_powerclass_setoid A) CPROP).
+ #A; napply (mk_binary_morphism1 … (λx:setoid1_of_setoid A.λS: 𝛀^A. x ∈ S));
+ #a; #a'; #b; #b'; #Ha; *; #Hb1; #Hb2; @; #H
+ [ napply (. (ext_prop … Ha^-1)) | napply (. (ext_prop … Ha)) ] /2/.
nqed.
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))),
- M1 ≟ ?,
- M2 ≟ ?,
- M3 ≟ ?
+ TT ≟ (mk_unary_morphism1 …
+ (λx:setoid1_of_setoid ?.
+ mk_unary_morphism1 …
+ (λS:ext_powerclass_setoid ?. x ∈ S)
+ (prop11 … (mem_ext_powerclass_setoid_is_morph A x)))
+ (prop11 … (mem_ext_powerclass_setoid_is_morph A))),
+ XX ≟ (ext_powerclass_setoid A)
(*-------------------------------------*) ⊢
- fun21 M1 M2 M3 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 ] ##]
+ fun11 (setoid1_of_setoid A)
+ (unary_morphism1_setoid1 XX CPROP) TT x S
+ ≡ mem A SS x.
+
+nlemma subseteq_is_morph: ∀A. unary_morphism1 (ext_powerclass_setoid A)
+ (unary_morphism1_setoid1 (ext_powerclass_setoid A) CPROP).
+ #A; napply (mk_binary_morphism1 … (λS,S':𝛀^A. S ⊆ S'));
+ #a; #a'; #b; #b'; *; #H1; #H2; *; /5/.
nqed.
unification hint 0 ≔ A,a,a'
nlemma intersect_is_ext: ∀A. 𝛀^A → 𝛀^A → 𝛀^A.
#A; #S; #S'; @ (S ∩ S');
- #a; #a'; #Ha; @; *; #H1; #H2; @
+ #a; #a'; #Ha; @; *; #H1; #H2; @
[##1,2: napply (. Ha^-1‡#); nassumption;
##|##3,4: napply (. Ha‡#); nassumption]
nqed.
(* ------------------------------------------*) ⊢
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]
+nlemma intersect_is_morph:
+ ∀A. unary_morphism1 (powerclass_setoid A) (unary_morphism1_setoid1 (powerclass_setoid A) (powerclass_setoid A)).
+ #A; napply (mk_binary_morphism1 … (λS,S'. S ∩ S'));
+ #a; #a'; #b; #b'; *; #Ha1; #Ha2; *; #Hb1; #Hb2; @; #x; nnormalize; *;/3/.
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)))
+ R ≟ (mk_unary_morphism1 …
+ (λS. mk_unary_morphism1 … (λS'.S ∩ S') (prop11 … (intersect_is_morph A S)))
+ (prop11 … (intersect_is_morph A)))
⊢
- fun21 (powerclass_setoid A) (powerclass_setoid A) (powerclass_setoid A) R B C
- ≡ intersect ? B C.
-
-ndefinition prop21_mem :
- ∀A,C.∀f:binary_morphism1 (setoid1_of_setoid A) (ext_powerclass_setoid A) C.
- ∀a,a':setoid1_of_setoid A.
- ∀b,b':ext_powerclass_setoid A.a = a' → b = b' → f a b = f a' b'.
-#A; #C; #f; #a; #a'; #b; #b'; #H1; #H2; napply prop21; nassumption;
-nqed.
-
-interpretation "prop21 mem" 'prop2 l r = (prop21_mem ??????? l r).
+ R B C ≡ intersect ? B C.
+
+interpretation "prop21 ext" 'prop2 l r =
+ (prop11 (ext_powerclass_setoid ?)
+ (unary_morphism1_setoid1 (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;
+ ∀A. unary_morphism1 (ext_powerclass_setoid A)
+ (unary_morphism1_setoid1 (ext_powerclass_setoid A) (ext_powerclass_setoid A)).
+ #A; napply (mk_binary_morphism1 … (intersect_is_ext …));
+ #a; #a'; #b; #b'; #Ha; #Hb; napply (prop11 … (intersect_is_morph A)); 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))) ,
+ R ≟ (mk_unary_morphism1 …
+ (λS:ext_powerclass_setoid A.
+ mk_unary_morphism1 ??
+ (λS':ext_powerclass_setoid A.
+ mk_ext_powerclass A (S∩S') (ext_prop A (intersect_is_ext ? S S')))
+ (prop11 … (intersect_is_ext_morph A S)))
+ (prop11 … (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.
+ ext_carr 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:qpowerclass U. A ∩ B = A →
+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 (. #‡(?));
-##[ nchange with (A ∩ B = ?);
- napply (prop21 ??? (mk_binary_morphism1 … (λS,S'.S ∩ S') (prop21 … (intersect_ok' U))) A A B B ##);
- #H; napply H;
+ #U; #A; #B; #H; #x; #y; #K; #K2;
+ alias symbol "prop2" = "prop21 mem".
+ alias symbol "invert" = "setoid1 symmetry".
+ napply (. K^-1‡H);
nassumption;
nqed.
-(*
-nlemma intersect_ok: ∀A. binary_morphism1 (qpowerclass_setoid A) (qpowerclass_setoid A) (qpowerclass_setoid A).
+
+nlemma intersect_ok: ∀A. binary_morphism1 (ext_powerclass_setoid A) (ext_powerclass_setoid A) (ext_powerclass_setoid A).
#A; @
[ #S; #S'; @
[ napply (S ∩ S')
##|##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
+ alias symbol "refl" = "refl".
+alias symbol "prop2" = "prop21".
+napply (. ((#‡Ha^-1)‡(#‡Hb^-1))); nassumption
| napply (. ((#‡Ha)‡(#‡Hb))); nassumption ]##]
nqed.
(* unfold if intersect, exposing fun21 *)
alias symbol "hint_decl" = "hint_decl_Type1".
unification hint 0 ≔
- A : setoid, B,C : qpowerclass A ⊢
+ A : setoid, B,C : ext_powerclass A ⊢
pc A (fun21 …
(mk_binary_morphism1 …
(λS,S':qpowerclass_setoid A.mk_qpowerclass ? (S ∩ S') (mem_ok' ? (intersect_ok ? S S')))
#A; #U; #V; #x; #x'; #H; #p; napply (. (H^-1‡#)); nassumption.
nqed.
*)
-*)
ndefinition image: ∀A,B. (carr A → carr B) → Ω^A → Ω^B ≝
λA,B:setoid.λf:carr A → carr B.λSa:Ω^A.
ndefinition eqrel_of_morphism:
∀A,B. unary_morphism A B → compatible_equivalence_relation A.
#A; #B; #f; @
- [ @
- [ napply (λx,y. f x = f y)
- | #x; napply refl | #x; #y; napply sym | #x; #y; #z; napply trans]
+ [ @ [ napply (λx,y. f x = f y) ] /2/;
##| #x; #x'; #H; nwhd; alias symbol "prop1" = "prop1".
-napply (.= (†H)); napply refl ]
+napply (.= (†H)); // ]
nqed.
ndefinition canonical_proj: ∀A,R. unary_morphism A (quotient A R).
#A; #R; @
- [ napply (λx.x) | #a; #a'; #H; napply (compatibility … R … H) ]
+ [ 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 f | #a; #a'; #H; nassumption]
+ #A; #B; #f; @ [ napply f ] //.
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).
- #A; #B; #f; #x; napply refl;
-nqed.
+//. nqed.
+alias symbol "eq" = "setoid eq".
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.
nlemma first_omomorphism_theorem_functions2:
∀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.
+/3/. nqed.
nlemma first_omomorphism_theorem_functions3:
∀A,B.∀f: unary_morphism A B.
f_inj: injective … S iso_f
}.
+nlemma subseteq_intersection_l: ∀A.∀U,V,W:Ω^A.U ⊆ W ∨ V ⊆ W → U ∩ V ⊆ W.
+#A; #U; #V; #W; *; #H; #x; *; /2/.
+nqed.
+
+nlemma subseteq_union_l: ∀A.∀U,V,W:Ω^A.U ⊆ W → V ⊆ W → U ∪ V ⊆ W.
+#A; #U; #V; #W; #H; #H1; #x; *; /2/.
+nqed.
+
+nlemma subseteq_intersection_r: ∀A.∀U,V,W:Ω^A.W ⊆ U → W ⊆ V → W ⊆ U ∩ V.
+/3/. nqed.
+
(*
nrecord isomorphism (A, B : setoid) (S: qpowerclass A) (T: qpowerclass B) : CProp[0] ≝
{ iso_f:> unary_morphism A B;
;
}.
-*)
+*)
\ No newline at end of file