set "baseuri" "cic:/matita/groups/".
-include "higher_order_defs/functions.ma".
-include "nat/nat.ma".
-include "nat/orders.ma".
-include "constructive_connectives.ma".
+include "excedence.ma".
-definition left_neutral \def λC,op.λe:C. ∀x:C. op e x = x.
-
-definition right_neutral \def λC,op. λe:C. ∀x:C. op x e=x.
-
-definition left_inverse \def λC,op.λe:C.λinv:C→C. ∀x:C. op (inv x) x = e.
-
-definition right_inverse \def λC,op.λe:C.λ inv: C→ C. ∀x:C. op x (inv x)=e.
+definition left_neutral ≝ λC:apartness.λop.λe:C. ∀x:C. op e x ≈ x.
+definition right_neutral ≝ λC:apartness.λop. λe:C. ∀x:C. op x e ≈ x.
+definition left_inverse ≝ λC:apartness.λop.λe:C.λinv:C→C. ∀x:C. op (inv x) x ≈ e.
+definition right_inverse ≝ λC:apartness.λop.λe:C.λ inv: C→ C. ∀x:C. op x (inv x) ≈ e.
+definition strong_ext ≝ λA:apartness.λop:A→A.∀x,y. op x # op y → x # y.
+(* ALLOW DEFINITION WITH SOME METAS *)
definition distributive_left ≝
- λA:Type.λf:A→A→A.λg:A→A→A.
- ∀x,y,z. f x (g y z) = g (f x y) (f x z).
+ λA:apartness.λf:A→A→A.λg:A→A→A.
+ ∀x,y,z. f x (g y z) ≈ g (f x y) (f x z).
definition distributive_right ≝
- λA:Type.λf:A→A→A.λg:A→A→A.
- ∀x,y,z. f (g x y) z = g (f x z) (f y z).
-
-record is_abelian_group (C:Type) (plus:C→C→C) (zero:C) (opp:C→C) : Prop \def
- { (* abelian additive semigroup properties *)
- plus_assoc_: associative ? plus;
- plus_comm_: symmetric ? plus;
- (* additive monoid properties *)
- zero_neutral_: left_neutral ? plus zero;
- (* additive group properties *)
- opp_inverse_: left_inverse ? plus zero opp
- }.
-
-record abelian_group : Type \def
- { carrier:> Type;
- plus: carrier → carrier → carrier;
- zero: carrier;
- opp: carrier → carrier;
- ag_abelian_group_properties: is_abelian_group ? plus zero opp
- }.
+ λA:apartness.λf:A→A→A.λg:A→A→A.
+ ∀x,y,z. f (g x y) z ≈ g (f x z) (f y z).
+
+record abelian_group : Type ≝
+ { carr:> apartness;
+ plus: carr → carr → carr;
+ zero: carr;
+ opp: carr → carr;
+ plus_assoc: associative ? plus (eq carr);
+ plus_comm: commutative ? plus (eq carr);
+ zero_neutral: left_neutral ? plus zero;
+ opp_inverse: left_inverse ? plus zero opp;
+ plus_strong_ext: ∀z.strong_ext ? (plus z)
+}.
-notation "0" with precedence 89
-for @{ 'zero }.
+notation "0" with precedence 89 for @{ 'zero }.
interpretation "Abelian group zero" 'zero =
(cic:/matita/groups/zero.con _).
interpretation "Abelian group minus" 'minus a b =
(cic:/matita/groups/minus.con _ a b).
-theorem plus_assoc: ∀G:abelian_group. associative ? (plus G).
- intro;
- apply (plus_assoc_ ? ? ? ? (ag_abelian_group_properties G)).
+lemma ap_rewl: ∀A:apartness.∀x,z,y:A. x ≈ y → y # z → x # z.
+intros (A x z y Exy Ayz); cases (ap_cotransitive ???x Ayz); [2:assumption]
+cases (Exy (ap_symmetric ??? a));
qed.
-
-theorem plus_comm: ∀G:abelian_group. symmetric ? (plus G).
- intro;
- apply (plus_comm_ ? ? ? ? (ag_abelian_group_properties G)).
+
+lemma ap_rewr: ∀A:apartness.∀x,z,y:A. x ≈ y → z # y → z # x.
+intros (A x z y Exy Azy); apply ap_symmetric; apply (ap_rewl ???? Exy);
+apply ap_symmetric; assumption;
qed.
-theorem zero_neutral: ∀G:abelian_group. left_neutral ? (plus G) 0.
- intro;
- apply (zero_neutral_ ? ? ? ? (ag_abelian_group_properties G)).
+definition ext ≝ λA:apartness.λop:A→A. ∀x,y. x ≈ y → op x ≈ op y.
+
+lemma strong_ext_to_ext: ∀A:apartness.∀op:A→A. strong_ext ? op → ext ? op.
+intros 6 (A op SEop x y Exy); intro Axy; apply Exy; apply SEop; assumption;
+qed.
+
+lemma feq_plusl: ∀G:abelian_group.∀x,y,z:G. y ≈ z → x+y ≈ x+z.
+intros (G x y z Eyz); apply (strong_ext_to_ext ?? (plus_strong_ext ? x));
+assumption;
+qed.
+
+lemma plus_strong_extr: ∀G:abelian_group.∀z:G.strong_ext ? (λx.x + z).
+intros 5 (G z x y A); simplify in A;
+lapply (plus_comm ? z x) as E1; lapply (plus_comm ? z y) as E2;
+lapply (ap_rewl ???? E1 A) as A1; lapply (ap_rewr ???? E2 A1) as A2;
+apply (plus_strong_ext ???? A2);
+qed.
+
+lemma feq_plusr: ∀G:abelian_group.∀x,y,z:G. y ≈ z → y+x ≈ z+x.
+intros (G x y z Eyz); apply (strong_ext_to_ext ?? (plus_strong_extr ? x));
+assumption;
+qed.
+
+lemma fap_plusl: ∀G:abelian_group.∀x,y,z:G. y # z → x+y # x+z.
+intros (G x y z Ayz); apply (plus_strong_ext ? (-x));
+apply (ap_rewl ??? ((-x + x) + y));
+[1: apply plus_assoc;
+|2: apply (ap_rewr ??? ((-x +x) +z));
+ [1: apply plus_assoc;
+ |2: apply (ap_rewl ??? (0 + y));
+ [1: apply (feq_plusr ???? (opp_inverse ??));
+ |2: apply (ap_rewl ???? (zero_neutral ? y)); apply (ap_rewr ??? (0 + z));
+ [1: apply (feq_plusr ???? (opp_inverse ??));
+ |2: apply (ap_rewr ???? (zero_neutral ??)); assumption;]]]]
qed.
-theorem opp_inverse: ∀G:abelian_group. left_inverse ? (plus G) 0 (opp G).
- intro;
- apply (opp_inverse_ ? ? ? ? (ag_abelian_group_properties G)).
+lemma fap_plusr: ∀G:abelian_group.∀x,y,z:G. y # z → y+x # z+x.
+intros (G x y z Ayz); apply (plus_strong_extr ? (-x));
+apply (ap_rewl ??? (y + (x + -x)));
+[1: apply (eq_symmetric ??? (plus_assoc ????));
+|2: apply (ap_rewr ??? (z + (x + -x)));
+ [1: apply (eq_symmetric ??? (plus_assoc ????));
+ |2: apply (ap_rewl ??? (y + (-x+x)) (feq_plusl ???? (plus_comm ???)));
+ apply (ap_rewl ??? (y + 0) (feq_plusl ???? (opp_inverse ??)));
+ apply (ap_rewl ??? (0 + y) (plus_comm ???));
+ apply (ap_rewl ??? y (zero_neutral ??));
+ apply (ap_rewr ??? (z + (-x+x)) (feq_plusl ???? (plus_comm ???)));
+ apply (ap_rewr ??? (z + 0) (feq_plusl ???? (opp_inverse ??)));
+ apply (ap_rewr ??? (0 + z) (plus_comm ???));
+ apply (ap_rewr ??? z (zero_neutral ??));
+ assumption]]
+qed.
+
+lemma plus_cancl: ∀G:abelian_group.∀y,z,x:G. x+y ≈ x+z → y ≈ z.
+intros 6 (G y z x E Ayz); apply E; apply fap_plusl; assumption;
qed.
-lemma cancellationlaw: ∀G:abelian_group.∀x,y,z:G. x+y=x+z → y=z.
-intros;
-generalize in match (eq_f ? ? (λa.-x +a) ? ? H);
-intros; clear H;
-rewrite < plus_assoc in H1;
-rewrite < plus_assoc in H1;
-rewrite > opp_inverse in H1;
-rewrite > zero_neutral in H1;
-rewrite > zero_neutral in H1;
-assumption.
+lemma plus_cancr: ∀G:abelian_group.∀y,z,x:G. y+x ≈ z+x → y ≈ z.
+intros 6 (G y z x E Ayz); apply E; apply fap_plusr; assumption;
qed.
-theorem eq_opp_plus_plus_opp_opp: ∀G:abelian_group.∀x,y:G. -(x+y) = -x + -y.
- intros;
- apply (cancellationlaw ? (x+y));
- rewrite < plus_comm;
- rewrite > opp_inverse;
- rewrite > plus_assoc;
- rewrite > plus_comm in ⊢ (? ? ? (? ? ? (? ? ? %)));
- rewrite < plus_assoc in ⊢ (? ? ? (? ? ? %));
- rewrite > plus_comm;
- rewrite > plus_comm in ⊢ (? ? ? (? ? (? ? % ?) ?));
- rewrite > opp_inverse;
- rewrite > zero_neutral;
- rewrite > opp_inverse;
- reflexivity.
+theorem eq_opp_plus_plus_opp_opp:
+ ∀G:abelian_group.∀x,y:G. -(x+y) ≈ -x + -y.
+intros (G x y); apply (plus_cancr ??? (x+y));
+apply (eq_transitive ?? 0); [apply (opp_inverse ??)]
+apply (eq_transitive ?? (-x + -y + x + y)); [2: apply (eq_symmetric ??? (plus_assoc ????))]
+apply (eq_transitive ?? (-y + -x + x + y)); [2: repeat apply feq_plusr; apply plus_comm]
+apply (eq_transitive ?? (-y + (-x + x) + y)); [2: apply feq_plusr; apply plus_assoc;]
+apply (eq_transitive ?? (-y + 0 + y));
+ [2: apply feq_plusr; apply feq_plusl; apply eq_symmetric; apply opp_inverse]
+apply (eq_transitive ?? (-y + y));
+ [2: apply feq_plusr; apply eq_symmetric;
+ apply (eq_transitive ?? (0+-y)); [apply plus_comm|apply zero_neutral]]
+apply eq_symmetric; apply opp_inverse.
qed.
-theorem eq_opp_opp_x_x: ∀G:abelian_group.∀x:G.--x=x.
- intros;
- apply (cancellationlaw ? (-x));
- rewrite > opp_inverse;
- rewrite > plus_comm;
- rewrite > opp_inverse;
- reflexivity.
+theorem eq_opp_opp_x_x: ∀G:abelian_group.∀x:G.--x ≈ x.
+intros (G x); apply (plus_cancl ??? (-x));
+apply (eq_transitive ?? (--x + -x)); [apply plus_comm]
+apply (eq_transitive (carr G) (plus G (opp G (opp G x)) (opp G x)) (zero G) (plus G (opp G x) x) ? ?);
+ [apply (opp_inverse G (opp G x)).
+ |apply (eq_symmetric (carr G) (plus G (opp G x) x) (zero G) ?).
+ apply (opp_inverse G x).
+ ]
qed.
-theorem eq_zero_opp_zero: ∀G:abelian_group.0=-0.
+theorem eq_zero_opp_zero: ∀G:abelian_group.0 ≈ -0.
[ assumption
| intros;
- apply (cancellationlaw ? 0);
- rewrite < plus_comm in ⊢ (? ? ? %);
- rewrite > opp_inverse;
- rewrite > zero_neutral;
- reflexivity
- ].
-qed.
\ No newline at end of file
+apply (eq_transitive (carr G) (zero G) (plus G (opp G (zero G)) (zero G)) (opp G (zero G)) ? ?);
+ [apply (eq_symmetric (carr G) (plus G (opp G (zero G)) (zero G)) (zero G) ?).
+ apply (opp_inverse G (zero G)).
+ |apply (eq_transitive (carr G) (plus G (opp G (zero G)) (zero G)) (plus G (zero G) (opp G (zero G))) (opp G (zero G)) ? ?);
+ [apply (plus_comm G (opp G (zero G)) (zero G)).
+ |apply (zero_neutral G (opp G (zero G))).
+ ]
+ ]]
+qed.