Theory HOL-Algebra.Order
theory Order
imports
Congruence
begin
section ‹Orders›
subsection ‹Partial Orders›
record 'a gorder = "'a eq_object" +
le :: "['a, 'a] => bool" (infixl ‹⊑ı› 50)
abbreviation inv_gorder :: "_ ⇒ 'a gorder" where
"inv_gorder L ≡
⦇ carrier = carrier L,
eq = (.=⇘L⇙),
le = (λ x y. y ⊑⇘L ⇙x) ⦈"
lemma inv_gorder_inv:
"inv_gorder (inv_gorder L) = L"
by simp
locale weak_partial_order = equivalence L for L (structure) +
assumes le_refl [intro, simp]:
"x ∈ carrier L ⟹ x ⊑ x"
and weak_le_antisym [intro]:
"⟦x ⊑ y; y ⊑ x; x ∈ carrier L; y ∈ carrier L⟧ ⟹ x .= y"
and le_trans [trans]:
"⟦x ⊑ y; y ⊑ z; x ∈ carrier L; y ∈ carrier L; z ∈ carrier L⟧ ⟹ x ⊑ z"
and le_cong:
"⟦x .= y; z .= w; x ∈ carrier L; y ∈ carrier L; z ∈ carrier L; w ∈ carrier L⟧ ⟹
x ⊑ z ⟷ y ⊑ w"
definition
lless :: "[_, 'a, 'a] => bool" (infixl ‹⊏ı› 50)
where "x ⊏⇘L⇙ y ⟷ x ⊑⇘L⇙ y ∧ x .≠⇘L⇙ y"
subsubsection ‹The order relation›
context weak_partial_order
begin
lemma le_cong_l [intro, trans]:
"⟦x .= y; y ⊑ z; x ∈ carrier L; y ∈ carrier L; z ∈ carrier L⟧ ⟹ x ⊑ z"
by (auto intro: le_cong [THEN iffD2])
lemma le_cong_r [intro, trans]:
"⟦x ⊑ y; y .= z; x ∈ carrier L; y ∈ carrier L; z ∈ carrier L⟧ ⟹ x ⊑ z"
by (auto intro: le_cong [THEN iffD1])
lemma weak_refl [intro, simp]: "⟦x .= y; x ∈ carrier L; y ∈ carrier L⟧ ⟹ x ⊑ y"
by (simp add: le_cong_l)
end
lemma weak_llessI:
fixes R (structure)
assumes "x ⊑ y" and "¬(x .= y)"
shows "x ⊏ y"
using assms unfolding lless_def by simp
lemma lless_imp_le:
fixes R (structure)
assumes "x ⊏ y"
shows "x ⊑ y"
using assms unfolding lless_def by simp
lemma weak_lless_imp_not_eq:
fixes R (structure)
assumes "x ⊏ y"
shows "¬ (x .= y)"
using assms unfolding lless_def by simp
lemma weak_llessE:
fixes R (structure)
assumes p: "x ⊏ y" and e: "⟦x ⊑ y; ¬ (x .= y)⟧ ⟹ P"
shows "P"
using p by (blast dest: lless_imp_le weak_lless_imp_not_eq e)
lemma (in weak_partial_order) lless_cong_l [trans]:
assumes xx': "x .= x'"
and xy: "x' ⊏ y"
and carr: "x ∈ carrier L" "x' ∈ carrier L" "y ∈ carrier L"
shows "x ⊏ y"
using assms unfolding lless_def by (auto intro: trans sym)
lemma (in weak_partial_order) lless_cong_r [trans]:
assumes xy: "x ⊏ y"
and yy': "y .= y'"
and carr: "x ∈ carrier L" "y ∈ carrier L" "y' ∈ carrier L"
shows "x ⊏ y'"
using assms unfolding lless_def by (auto intro: trans sym)
lemma (in weak_partial_order) lless_antisym:
assumes "a ∈ carrier L" "b ∈ carrier L"
and "a ⊏ b" "b ⊏ a"
shows "P"
using assms
by (elim weak_llessE) auto
lemma (in weak_partial_order) lless_trans [trans]:
assumes "a ⊏ b" "b ⊏ c"
and carr[simp]: "a ∈ carrier L" "b ∈ carrier L" "c ∈ carrier L"
shows "a ⊏ c"
using assms unfolding lless_def by (blast dest: le_trans intro: sym)
lemma weak_partial_order_subset:
assumes "weak_partial_order L" "A ⊆ carrier L"
shows "weak_partial_order (L⦇ carrier := A ⦈)"
proof -
interpret L: weak_partial_order L
by (simp add: assms)
interpret equivalence "(L⦇ carrier := A ⦈)"
by (simp add: L.equivalence_axioms assms(2) equivalence_subset)
show ?thesis
apply (unfold_locales, simp_all)
using assms(2) apply auto[1]
using assms(2) apply auto[1]
apply (meson L.le_trans assms(2) contra_subsetD)
apply (meson L.le_cong assms(2) subsetCE)
done
qed
subsubsection ‹Upper and lower bounds of a set›
definition
Upper :: "[_, 'a set] => 'a set"
where "Upper L A = {u. (∀x. x ∈ A ∩ carrier L ⟶ x ⊑⇘L⇙ u)} ∩ carrier L"
definition
Lower :: "[_, 'a set] => 'a set"
where "Lower L A = {l. (∀x. x ∈ A ∩ carrier L ⟶ l ⊑⇘L⇙ x)} ∩ carrier L"
lemma Lower_dual [simp]:
"Lower (inv_gorder L) A = Upper L A"
by (simp add:Upper_def Lower_def)
lemma Upper_dual [simp]:
"Upper (inv_gorder L) A = Lower L A"
by (simp add:Upper_def Lower_def)
lemma (in weak_partial_order) equivalence_dual: "equivalence (inv_gorder L)"
by (rule equivalence.intro) (auto simp: intro: sym trans)
lemma (in weak_partial_order) dual_weak_order: "weak_partial_order (inv_gorder L)"
by intro_locales (auto simp add: weak_partial_order_axioms_def le_cong intro: equivalence_dual le_trans)
lemma (in weak_partial_order) dual_eq_iff [simp]: "A {.=}⇘inv_gorder L⇙ A' ⟷ A {.=} A'"
by (auto simp: set_eq_def elem_def)
lemma dual_weak_order_iff:
"weak_partial_order (inv_gorder A) ⟷ weak_partial_order A"
proof
assume "weak_partial_order (inv_gorder A)"
then interpret dpo: weak_partial_order "inv_gorder A"
rewrites "carrier (inv_gorder A) = carrier A"
and "le (inv_gorder A) = (λ x y. le A y x)"
and "eq (inv_gorder A) = eq A"
by (simp_all)
show "weak_partial_order A"
by (unfold_locales, auto intro: dpo.sym dpo.trans dpo.le_trans)
next
assume "weak_partial_order A"
thus "weak_partial_order (inv_gorder A)"
by (metis weak_partial_order.dual_weak_order)
qed
lemma Upper_closed [iff]:
"Upper L A ⊆ carrier L"
by (unfold Upper_def) clarify
lemma Upper_memD [dest]:
fixes L (structure)
shows "⟦u ∈ Upper L A; x ∈ A; A ⊆ carrier L⟧ ⟹ x ⊑ u ∧ u ∈ carrier L"
by (unfold Upper_def) blast
lemma (in weak_partial_order) Upper_elemD [dest]:
"⟦u .∈ Upper L A; u ∈ carrier L; x ∈ A; A ⊆ carrier L⟧ ⟹ x ⊑ u"
unfolding Upper_def elem_def
by (blast dest: sym)
lemma Upper_memI:
fixes L (structure)
shows "⟦!! y. y ∈ A ⟹ y ⊑ x; x ∈ carrier L⟧ ⟹ x ∈ Upper L A"
by (unfold Upper_def) blast
lemma (in weak_partial_order) Upper_elemI:
"⟦!! y. y ∈ A ⟹ y ⊑ x; x ∈ carrier L⟧ ⟹ x .∈ Upper L A"
unfolding Upper_def by blast
lemma Upper_antimono:
"A ⊆ B ⟹ Upper L B ⊆ Upper L A"
by (unfold Upper_def) blast
lemma (in weak_partial_order) Upper_is_closed [simp]:
"A ⊆ carrier L ⟹ is_closed (Upper L A)"
by (rule is_closedI) (blast intro: Upper_memI)+
lemma (in weak_partial_order) Upper_mem_cong:
assumes "a' ∈ carrier L" "A ⊆ carrier L" "a .= a'" "a ∈ Upper L A"
shows "a' ∈ Upper L A"
by (metis assms Upper_closed Upper_is_closed closure_of_eq complete_classes)
lemma (in weak_partial_order) Upper_semi_cong:
assumes "A ⊆ carrier L" "A {.=} A'"
shows "Upper L A ⊆ Upper L A'"
unfolding Upper_def
by clarsimp (meson assms equivalence.refl equivalence_axioms le_cong set_eqD2 subset_eq)
lemma (in weak_partial_order) Upper_cong:
assumes "A ⊆ carrier L" "A' ⊆ carrier L" "A {.=} A'"
shows "Upper L A = Upper L A'"
using assms by (simp add: Upper_semi_cong set_eq_sym subset_antisym)
lemma Lower_closed [intro!, simp]:
"Lower L A ⊆ carrier L"
by (unfold Lower_def) clarify
lemma Lower_memD [dest]:
fixes L (structure)
shows "⟦l ∈ Lower L A; x ∈ A; A ⊆ carrier L⟧ ⟹ l ⊑ x ∧ l ∈ carrier L"
by (unfold Lower_def) blast
lemma Lower_memI:
fixes L (structure)
shows "⟦!! y. y ∈ A ⟹ x ⊑ y; x ∈ carrier L⟧ ⟹ x ∈ Lower L A"
by (unfold Lower_def) blast
lemma Lower_antimono:
"A ⊆ B ⟹ Lower L B ⊆ Lower L A"
by (unfold Lower_def) blast
lemma (in weak_partial_order) Lower_is_closed [simp]:
"A ⊆ carrier L ⟹ is_closed (Lower L A)"
by (rule is_closedI) (blast intro: Lower_memI dest: sym)+
lemma (in weak_partial_order) Lower_mem_cong:
assumes "a' ∈ carrier L" "A ⊆ carrier L" "a .= a'" "a ∈ Lower L A"
shows "a' ∈ Lower L A"
by (meson assms Lower_closed Lower_is_closed is_closed_eq subsetCE)
lemma (in weak_partial_order) Lower_cong:
assumes "A ⊆ carrier L" "A' ⊆ carrier L" "A {.=} A'"
shows "Lower L A = Lower L A'"
unfolding Upper_dual [symmetric]
by (rule weak_partial_order.Upper_cong [OF dual_weak_order]) (simp_all add: assms)
text ‹Jacobson: Theorem 8.1›
lemma Lower_empty [simp]:
"Lower L {} = carrier L"
by (unfold Lower_def) simp
lemma Upper_empty [simp]:
"Upper L {} = carrier L"
by (unfold Upper_def) simp
subsubsection ‹Least and greatest, as predicate›
definition
least :: "[_, 'a, 'a set] => bool"
where "least L l A ⟷ A ⊆ carrier L ∧ l ∈ A ∧ (∀x∈A. l ⊑⇘L⇙ x)"
definition
greatest :: "[_, 'a, 'a set] => bool"
where "greatest L g A ⟷ A ⊆ carrier L ∧ g ∈ A ∧ (∀x∈A. x ⊑⇘L⇙ g)"
text (in weak_partial_order) ‹Could weaken these to \<^term>‹l ∈ carrier L ∧ l .∈ A› and \<^term>‹g ∈ carrier L ∧ g .∈ A›.›
lemma least_dual [simp]:
"least (inv_gorder L) x A = greatest L x A"
by (simp add:least_def greatest_def)
lemma greatest_dual [simp]:
"greatest (inv_gorder L) x A = least L x A"
by (simp add:least_def greatest_def)
lemma least_closed [intro, simp]:
"least L l A ⟹ l ∈ carrier L"
by (unfold least_def) fast
lemma least_mem:
"least L l A ⟹ l ∈ A"
by (unfold least_def) fast
lemma (in weak_partial_order) weak_least_unique:
"⟦least L x A; least L y A⟧ ⟹ x .= y"
by (unfold least_def) blast
lemma least_le:
fixes L (structure)
shows "⟦least L x A; a ∈ A⟧ ⟹ x ⊑ a"
by (unfold least_def) fast
lemma (in weak_partial_order) least_cong:
"⟦x .= x'; x ∈ carrier L; x' ∈ carrier L; is_closed A⟧ ⟹ least L x A = least L x' A"
unfolding least_def
by (meson is_closed_eq is_closed_eq_rev le_cong local.refl subset_iff)
abbreviation is_lub :: "[_, 'a, 'a set] => bool"
where "is_lub L x A ≡ least L x (Upper L A)"
text (in weak_partial_order) ‹\<^const>‹least› is not congruent in the second parameter for
\<^term>‹A {.=} A'››
lemma (in weak_partial_order) least_Upper_cong_l:
assumes "x .= x'"
and "x ∈ carrier L" "x' ∈ carrier L"
and "A ⊆ carrier L"
shows "least L x (Upper L A) = least L x' (Upper L A)"
apply (rule least_cong) using assms by auto
lemma (in weak_partial_order) least_Upper_cong_r:
assumes "A ⊆ carrier L" "A' ⊆ carrier L" "A {.=} A'"
shows "least L x (Upper L A) = least L x (Upper L A')"
using Upper_cong assms by auto
lemma least_UpperI:
fixes L (structure)
assumes above: "!! x. x ∈ A ⟹ x ⊑ s"
and below: "!! y. y ∈ Upper L A ⟹ s ⊑ y"
and L: "A ⊆ carrier L" "s ∈ carrier L"
shows "least L s (Upper L A)"
proof -
have "Upper L A ⊆ carrier L" by simp
moreover from above L have "s ∈ Upper L A" by (simp add: Upper_def)
moreover from below have "∀x ∈ Upper L A. s ⊑ x" by fast
ultimately show ?thesis by (simp add: least_def)
qed
lemma least_Upper_above:
fixes L (structure)
shows "⟦least L s (Upper L A); x ∈ A; A ⊆ carrier L⟧ ⟹ x ⊑ s"
by (unfold least_def) blast
lemma greatest_closed [intro, simp]:
"greatest L l A ⟹ l ∈ carrier L"
by (unfold greatest_def) fast
lemma greatest_mem:
"greatest L l A ⟹ l ∈ A"
by (unfold greatest_def) fast
lemma (in weak_partial_order) weak_greatest_unique:
"⟦greatest L x A; greatest L y A⟧ ⟹ x .= y"
by (unfold greatest_def) blast
lemma greatest_le:
fixes L (structure)
shows "⟦greatest L x A; a ∈ A⟧ ⟹ a ⊑ x"
by (unfold greatest_def) fast
lemma (in weak_partial_order) greatest_cong:
"⟦x .= x'; x ∈ carrier L; x' ∈ carrier L; is_closed A⟧ ⟹
greatest L x A = greatest L x' A"
unfolding greatest_def
by (meson is_closed_eq_rev le_cong_r local.sym subset_eq)
abbreviation is_glb :: "[_, 'a, 'a set] => bool"
where "is_glb L x A ≡ greatest L x (Lower L A)"
text (in weak_partial_order) ‹\<^const>‹greatest› is not congruent in the second parameter for
\<^term>‹A {.=} A'› ›
lemma (in weak_partial_order) greatest_Lower_cong_l:
assumes "x .= x'"
and "x ∈ carrier L" "x' ∈ carrier L"
shows "greatest L x (Lower L A) = greatest L x' (Lower L A)"
proof -
have "∀A. is_closed (Lower L (A ∩ carrier L))"
by simp
then show ?thesis
by (simp add: Lower_def assms greatest_cong)
qed
lemma (in weak_partial_order) greatest_Lower_cong_r:
assumes "A ⊆ carrier L" "A' ⊆ carrier L" "A {.=} A'"
shows "greatest L x (Lower L A) = greatest L x (Lower L A')"
using Lower_cong assms by auto
lemma greatest_LowerI:
fixes L (structure)
assumes below: "!! x. x ∈ A ⟹ i ⊑ x"
and above: "!! y. y ∈ Lower L A ⟹ y ⊑ i"
and L: "A ⊆ carrier L" "i ∈ carrier L"
shows "greatest L i (Lower L A)"
proof -
have "Lower L A ⊆ carrier L" by simp
moreover from below L have "i ∈ Lower L A" by (simp add: Lower_def)
moreover from above have "∀x ∈ Lower L A. x ⊑ i" by fast
ultimately show ?thesis by (simp add: greatest_def)
qed
lemma greatest_Lower_below:
fixes L (structure)
shows "⟦greatest L i (Lower L A); x ∈ A; A ⊆ carrier L⟧ ⟹ i ⊑ x"
by (unfold greatest_def) blast
subsubsection ‹Intervals›
definition
at_least_at_most :: "('a, 'c) gorder_scheme ⇒ 'a => 'a => 'a set"
(‹(‹indent=1 notation=‹mixfix interval››⦃_.._⦄ı)›)
where "⦃l..u⦄⇘A⇙ = {x ∈ carrier A. l ⊑⇘A⇙ x ∧ x ⊑⇘A⇙ u}"
context weak_partial_order
begin
lemma at_least_at_most_upper [dest]:
"x ∈ ⦃a..b⦄ ⟹ x ⊑ b"
by (simp add: at_least_at_most_def)
lemma at_least_at_most_lower [dest]:
"x ∈ ⦃a..b⦄ ⟹ a ⊑ x"
by (simp add: at_least_at_most_def)
lemma at_least_at_most_closed: "⦃a..b⦄ ⊆ carrier L"
by (auto simp add: at_least_at_most_def)
lemma at_least_at_most_member [intro]:
"⟦x ∈ carrier L; a ⊑ x; x ⊑ b⟧ ⟹ x ∈ ⦃a..b⦄"
by (simp add: at_least_at_most_def)
end
subsubsection ‹Isotone functions›
definition isotone :: "('a, 'c) gorder_scheme ⇒ ('b, 'd) gorder_scheme ⇒ ('a ⇒ 'b) ⇒ bool"
where
"isotone A B f ≡
weak_partial_order A ∧ weak_partial_order B ∧
(∀x∈carrier A. ∀y∈carrier A. x ⊑⇘A⇙ y ⟶ f x ⊑⇘B⇙ f y)"
lemma isotoneI [intro?]:
fixes f :: "'a ⇒ 'b"
assumes "weak_partial_order L1"
"weak_partial_order L2"
"(⋀x y. ⟦x ∈ carrier L1; y ∈ carrier L1; x ⊑⇘L1⇙ y⟧
⟹ f x ⊑⇘L2⇙ f y)"
shows "isotone L1 L2 f"
using assms by (auto simp add:isotone_def)
abbreviation Monotone :: "('a, 'b) gorder_scheme ⇒ ('a ⇒ 'a) ⇒ bool"
(‹(‹open_block notation=‹prefix Mono››Monoı)›)
where "Mono⇘L⇙ f ≡ isotone L L f"
lemma use_iso1:
"⟦isotone A A f; x ∈ carrier A; y ∈ carrier A; x ⊑⇘A⇙ y⟧ ⟹
f x ⊑⇘A⇙ f y"
by (simp add: isotone_def)
lemma use_iso2:
"⟦isotone A B f; x ∈ carrier A; y ∈ carrier A; x ⊑⇘A⇙ y⟧ ⟹
f x ⊑⇘B⇙ f y"
by (simp add: isotone_def)
lemma iso_compose:
"⟦f ∈ carrier A → carrier B; isotone A B f; g ∈ carrier B → carrier C; isotone B C g⟧ ⟹
isotone A C (g ∘ f)"
by (simp add: isotone_def, safe, metis Pi_iff)
lemma (in weak_partial_order) inv_isotone [simp]:
"isotone (inv_gorder A) (inv_gorder B) f = isotone A B f"
by (auto simp add:isotone_def dual_weak_order dual_weak_order_iff)
subsubsection ‹Idempotent functions›
definition idempotent ::
"('a, 'b) gorder_scheme ⇒ ('a ⇒ 'a) ⇒ bool"
(‹(‹open_block notation=‹prefix Idem››Idemı)›)
where "Idem⇘L⇙ f ≡ ∀x∈carrier L. f (f x) .=⇘L⇙ f x"
lemma (in weak_partial_order) idempotent:
"⟦Idem f; x ∈ carrier L⟧ ⟹ f (f x) .= f x"
by (auto simp add: idempotent_def)
subsubsection ‹Order embeddings›
definition order_emb :: "('a, 'c) gorder_scheme ⇒ ('b, 'd) gorder_scheme ⇒ ('a ⇒ 'b) ⇒ bool"
where
"order_emb A B f ≡ weak_partial_order A
∧ weak_partial_order B
∧ (∀x∈carrier A. ∀y∈carrier A. f x ⊑⇘B⇙ f y ⟷ x ⊑⇘A⇙ y )"
lemma order_emb_isotone: "order_emb A B f ⟹ isotone A B f"
by (auto simp add: isotone_def order_emb_def)
subsubsection ‹Commuting functions›
definition commuting :: "('a, 'c) gorder_scheme ⇒ ('a ⇒ 'a) ⇒ ('a ⇒ 'a) ⇒ bool" where
"commuting A f g = (∀x∈carrier A. (f ∘ g) x .=⇘A⇙ (g ∘ f) x)"
subsection ‹Partial orders where ‹eq› is the Equality›
locale partial_order = weak_partial_order +
assumes eq_is_equal: "(.=) = (=)"
begin
declare weak_le_antisym [rule del]
lemma le_antisym [intro]:
"⟦x ⊑ y; y ⊑ x; x ∈ carrier L; y ∈ carrier L⟧ ⟹ x = y"
using weak_le_antisym unfolding eq_is_equal .
lemma lless_eq:
"x ⊏ y ⟷ x ⊑ y ∧ x ≠ y"
unfolding lless_def by (simp add: eq_is_equal)
lemma set_eq_is_eq: "A {.=} B ⟷ A = B"
by (auto simp add: set_eq_def elem_def eq_is_equal)
end
lemma (in partial_order) dual_order:
"partial_order (inv_gorder L)"
proof -
interpret dwo: weak_partial_order "inv_gorder L"
by (metis dual_weak_order)
show ?thesis
by (unfold_locales, simp add:eq_is_equal)
qed
lemma dual_order_iff:
"partial_order (inv_gorder A) ⟷ partial_order A"
proof
assume assm:"partial_order (inv_gorder A)"
then interpret po: partial_order "inv_gorder A"
rewrites "carrier (inv_gorder A) = carrier A"
and "le (inv_gorder A) = (λ x y. le A y x)"
and "eq (inv_gorder A) = eq A"
by (simp_all)
show "partial_order A"
apply (unfold_locales, simp_all add: po.sym)
apply (metis po.trans)
apply (metis po.weak_le_antisym, metis po.le_trans)
apply (metis (full_types) po.eq_is_equal, metis po.eq_is_equal)
done
next
assume "partial_order A"
thus "partial_order (inv_gorder A)"
by (metis partial_order.dual_order)
qed
text ‹Least and greatest, as predicate›
lemma (in partial_order) least_unique:
"⟦least L x A; least L y A⟧ ⟹ x = y"
using weak_least_unique unfolding eq_is_equal .
lemma (in partial_order) greatest_unique:
"⟦greatest L x A; greatest L y A⟧ ⟹ x = y"
using weak_greatest_unique unfolding eq_is_equal .
subsection ‹Bounded Orders›
definition
top :: "_ => 'a" (‹⊤ı›) where
"⊤⇘L⇙ = (SOME x. greatest L x (carrier L))"
definition
bottom :: "_ => 'a" (‹⊥ı›) where
"⊥⇘L⇙ = (SOME x. least L x (carrier L))"
locale weak_partial_order_bottom = weak_partial_order L for L (structure) +
assumes bottom_exists: "∃ x. least L x (carrier L)"
begin
lemma bottom_least: "least L ⊥ (carrier L)"
proof -
obtain x where "least L x (carrier L)"
by (metis bottom_exists)
thus ?thesis
by (auto intro:someI2 simp add: bottom_def)
qed
lemma bottom_closed [simp, intro]:
"⊥ ∈ carrier L"
by (metis bottom_least least_mem)
lemma bottom_lower [simp, intro]:
"x ∈ carrier L ⟹ ⊥ ⊑ x"
by (metis bottom_least least_le)
end
locale weak_partial_order_top = weak_partial_order L for L (structure) +
assumes top_exists: "∃ x. greatest L x (carrier L)"
begin
lemma top_greatest: "greatest L ⊤ (carrier L)"
proof -
obtain x where "greatest L x (carrier L)"
by (metis top_exists)
thus ?thesis
by (auto intro:someI2 simp add: top_def)
qed
lemma top_closed [simp, intro]:
"⊤ ∈ carrier L"
by (metis greatest_mem top_greatest)
lemma top_higher [simp, intro]:
"x ∈ carrier L ⟹ x ⊑ ⊤"
by (metis greatest_le top_greatest)
end
subsection ‹Total Orders›
locale weak_total_order = weak_partial_order +
assumes total: "⟦x ∈ carrier L; y ∈ carrier L⟧ ⟹ x ⊑ y ∨ y ⊑ x"
text ‹Introduction rule: the usual definition of total order›
lemma (in weak_partial_order) weak_total_orderI:
assumes total: "!!x y. ⟦x ∈ carrier L; y ∈ carrier L⟧ ⟹ x ⊑ y ∨ y ⊑ x"
shows "weak_total_order L"
by unfold_locales (rule total)
subsection ‹Total orders where ‹eq› is the Equality›
locale total_order = partial_order +
assumes total_order_total: "⟦x ∈ carrier L; y ∈ carrier L⟧ ⟹ x ⊑ y ∨ y ⊑ x"
sublocale total_order < weak?: weak_total_order
by unfold_locales (rule total_order_total)
text ‹Introduction rule: the usual definition of total order›
lemma (in partial_order) total_orderI:
assumes total: "!!x y. ⟦x ∈ carrier L; y ∈ carrier L⟧ ⟹ x ⊑ y ∨ y ⊑ x"
shows "total_order L"
by unfold_locales (rule total)
end