Theory HOL-Algebra.Left_Coset

theory Left_Coset
imports Coset

(*This instance of Coset.thy but for left cosets is due to Jonas Rädle and has been imported
  from the AFP entry Orbit_Stabiliser. *)

begin

definition
  LCOSETS  :: "[_, 'a set]  ('a set)set"   ("lcosetsı _" [81] 80)
  where "lcosetsGH = (acarrier G. {a <#GH})"

definition
  LFactGroup :: "[('a,'b) monoid_scheme, 'a set]  ('a set) monoid" (infixl "LMod" 65)
    ― ‹Actually defined for groups rather than monoids›
   where "LFactGroup G H = carrier = lcosetsGH, mult = set_mult G, one = H"

lemma (in group) lcos_self: "[| x  carrier G; subgroup H G |] ==> x  x <# H"
  by (simp add: group_l_invI subgroup.lcos_module_rev subgroup.one_closed)

text ‹Elements of a left coset are in the carrier›
lemma (in subgroup) elemlcos_carrier:
  assumes "group G" "a  carrier G" "a'  a <# H"
  shows "a'  carrier G"
  by (meson assms group.l_coset_carrier subgroup_axioms)

text ‹Step one for lemma rcos_module›
lemma (in subgroup) lcos_module_imp:
  assumes "group G"
  assumes xcarr: "x  carrier G"
      and x'cos: "x'  x <# H"
  shows "(inv x  x')  H"
proof -
  interpret group G by fact
  obtain h
    where hH: "h  H" and x': "x' = x  h" and hcarr: "h  carrier G"
    using assms by (auto simp: l_coset_def)
  have "(inv x)  x' = (inv x)  (x  h)"
    by (simp add: x')
  have " = (x  inv x)  h"
    by (metis hcarr inv_closed inv_inv l_inv m_assoc xcarr)
  also have " = h"
    by (simp add: hcarr xcarr)
  finally have "(inv x)  x' = h"
    using x' by metis
  then show "(inv x)  x'  H"
    using hH by force
qed

text ‹Left cosets are subsets of the carrier.› 
lemma (in subgroup) lcosets_carrier:
  assumes "group G"
  assumes XH: "X  lcosets H"
  shows "X  carrier G"
proof -
  interpret group G by fact
  show "X  carrier G"
    using XH l_coset_subset_G subset by (auto simp: LCOSETS_def)
qed

lemma (in group) lcosets_part_G:
  assumes "subgroup H G"
  shows "(lcosets H) = carrier G"
proof -
  interpret subgroup H G by fact
  show ?thesis
  proof
    show " (lcosets H)  carrier G"
      by (force simp add: LCOSETS_def l_coset_def)
    show "carrier G   (lcosets H)"
      by (auto simp add: LCOSETS_def intro: lcos_self assms)
  qed
qed

lemma (in group) lcosets_subset_PowG:
     "subgroup H G   lcosets H  Pow(carrier G)"
  using lcosets_part_G subset_Pow_Union by blast

lemma (in group) lcos_disjoint:
  assumes "subgroup H G"
  assumes p: "a  lcosets H" "b  lcosets H" "ab"
  shows "a  b = {}"
proof -
  interpret subgroup H G by fact
  show ?thesis
    using p l_repr_independence subgroup_axioms unfolding LCOSETS_def disjoint_iff
    by blast
qed

text‹The next two lemmas support the proof of card_cosets_equal›.›
lemma (in group) inj_on_f':
    "H  carrier G;  a  carrier G  inj_on (λy. y  inv a) (a <# H)"
  by (simp add: inj_on_g l_coset_subset_G)

lemma (in group) inj_on_f'':
    "H  carrier G;  a  carrier G  inj_on (λy. inv a  y) (a <# H)"
  by (meson inj_on_cmult inv_closed l_coset_subset_G subset_inj_on)

lemma (in group) inj_on_g':
    "H  carrier G;  a  carrier G  inj_on (λy. a  y) H"
  using inj_on_cmult inj_on_subset by blast

lemma (in group) l_card_cosets_equal:
  assumes "c  lcosets H" and H: "H  carrier G" and fin: "finite(carrier G)"
  shows "card H = card c"
proof -
  obtain x where x: "x  carrier G" and c: "c = x <# H"
    using assms by (auto simp add: LCOSETS_def)
  have "inj_on ((⊗) x) H"
    by (simp add: H group.inj_on_g' x)
  moreover
  have "(⊗) x ` H  x <# H"
    by (force simp add: m_assoc subsetD l_coset_def)
  moreover
  have "inj_on ((⊗) (inv x)) (x <# H)"
    by (simp add: H group.inj_on_f'' x)
  moreover
  have "h. h  H  inv x  (x  h)  H"
    by (metis H in_mono inv_solve_left m_closed x)
  then have "(⊗) (inv x) ` (x <# H)  H"
    by (auto simp: l_coset_def)
  ultimately show ?thesis
    by (metis H fin c card_bij_eq finite_imageD finite_subset)
qed

theorem (in group) l_lagrange:
  assumes "finite(carrier G)" "subgroup H G"
  shows "card(lcosets H) * card(H) = order(G)"
proof -
  have "card H * card (lcosets H) = card ( (lcosets H))"
    using card_partition
    by (metis (no_types, lifting) assms finite_UnionD l_card_cosets_equal lcos_disjoint lcosets_part_G subgroup.subset)
  then show ?thesis
    by (simp add: assms(2) lcosets_part_G mult.commute order_def)
qed

end