Stylistic improvements.
(*
Title: HOL/Algebra/Lattice.thy
Id: $Id$
Author: Clemens Ballarin, started 7 November 2003
Copyright: Clemens Ballarin
*)
theory Lattice imports Main begin
section {* Orders and Lattices *}
text {* Object with a carrier set. *}
record 'a partial_object =
carrier :: "'a set"
subsection {* Partial Orders *}
text {* Locale @{text order_syntax} is required since we want to refer
to definitions (and their derived theorems) outside of @{text partial_order}.
*}
locale order_syntax =
fixes L :: "'a set" and le :: "['a, 'a] => bool" (infix "\<sqsubseteq>" 50)
text {* Note that the type constraints above are necessary, because the
definition command cannot specialise the types. *}
definition (in order_syntax)
less (infixl "\<sqsubset>" 50) "x \<sqsubset> y == x \<sqsubseteq> y & x ~= y"
text {* Upper and lower bounds of a set. *}
definition (in order_syntax)
Upper where
"Upper A == {u. (ALL x. x \<in> A \<inter> L --> x \<sqsubseteq> u)} \<inter> L"
definition (in order_syntax)
Lower :: "'a set => 'a set"
"Lower A == {l. (ALL x. x \<in> A \<inter> L --> l \<sqsubseteq> x)} \<inter> L"
text {* Least and greatest, as predicate. *}
definition (in order_syntax)
least :: "['a, 'a set] => bool"
"least l A == A \<subseteq> L & l \<in> A & (ALL x : A. l \<sqsubseteq> x)"
definition (in order_syntax)
greatest :: "['a, 'a set] => bool"
"greatest g A == A \<subseteq> L & g \<in> A & (ALL x : A. x \<sqsubseteq> g)"
text {* Supremum and infimum *}
definition (in order_syntax)
sup :: "'a set => 'a" ("\<Squnion>_" [90] 90)
"\<Squnion>A == THE x. least x (Upper A)"
definition (in order_syntax)
inf :: "'a set => 'a" ("\<Sqinter>_" [90] 90)
"\<Sqinter>A == THE x. greatest x (Lower A)"
definition (in order_syntax)
join :: "['a, 'a] => 'a" (infixl "\<squnion>" 65)
"x \<squnion> y == sup {x, y}"
definition (in order_syntax)
meet :: "['a, 'a] => 'a" (infixl "\<sqinter>" 70)
"x \<sqinter> y == inf {x, y}"
locale partial_order = order_syntax +
assumes refl [intro, simp]:
"x \<in> L ==> x \<sqsubseteq> x"
and anti_sym [intro]:
"[| x \<sqsubseteq> y; y \<sqsubseteq> x; x \<in> L; y \<in> L |] ==> x = y"
and trans [trans]:
"[| x \<sqsubseteq> y; y \<sqsubseteq> z;
x \<in> L; y \<in> L; z \<in> L |] ==> x \<sqsubseteq> z"
abbreviation (in partial_order)
less (infixl "\<sqsubset>" 50) "less == order_syntax.less le"
abbreviation (in partial_order)
Upper where "Upper == order_syntax.Upper L le"
abbreviation (in partial_order)
Lower where "Lower == order_syntax.Lower L le"
abbreviation (in partial_order)
least where "least == order_syntax.least L le"
abbreviation (in partial_order)
greatest where "greatest == order_syntax.greatest L le"
abbreviation (in partial_order)
sup ("\<Squnion>_" [90] 90) "sup == order_syntax.sup L le"
abbreviation (in partial_order)
inf ("\<Sqinter>_" [90] 90) "inf == order_syntax.inf L le"
abbreviation (in partial_order)
join (infixl "\<squnion>" 65) "join == order_syntax.join L le"
abbreviation (in partial_order)
meet (infixl "\<sqinter>" 70) "meet == order_syntax.meet L le"
subsubsection {* Upper *}
lemma (in order_syntax) Upper_closed [intro, simp]:
"Upper A \<subseteq> L"
by (unfold Upper_def) clarify
lemma (in order_syntax) UpperD [dest]:
"[| u \<in> Upper A; x \<in> A; A \<subseteq> L |] ==> x \<sqsubseteq> u"
by (unfold Upper_def) blast
lemma (in order_syntax) Upper_memI:
"[| !! y. y \<in> A ==> y \<sqsubseteq> x; x \<in> L |] ==> x \<in> Upper A"
by (unfold Upper_def) blast
lemma (in order_syntax) Upper_antimono:
"A \<subseteq> B ==> Upper B \<subseteq> Upper A"
by (unfold Upper_def) blast
subsubsection {* Lower *}
lemma (in order_syntax) Lower_closed [intro, simp]:
"Lower A \<subseteq> L"
by (unfold Lower_def) clarify
lemma (in order_syntax) LowerD [dest]:
"[| l \<in> Lower A; x \<in> A; A \<subseteq> L |] ==> l \<sqsubseteq> x"
by (unfold Lower_def) blast
lemma (in order_syntax) Lower_memI:
"[| !! y. y \<in> A ==> x \<sqsubseteq> y; x \<in> L |] ==> x \<in> Lower A"
by (unfold Lower_def) blast
lemma (in order_syntax) Lower_antimono:
"A \<subseteq> B ==> Lower B \<subseteq> Lower A"
by (unfold Lower_def) blast
subsubsection {* least *}
lemma (in order_syntax) least_closed [intro, simp]:
"least l A ==> l \<in> L"
by (unfold least_def) fast
lemma (in order_syntax) least_mem:
"least l A ==> l \<in> A"
by (unfold least_def) fast
lemma (in partial_order) least_unique:
"[| least x A; least y A |] ==> x = y"
by (unfold least_def) blast
lemma (in order_syntax) least_le:
"[| least x A; a \<in> A |] ==> x \<sqsubseteq> a"
by (unfold least_def) fast
lemma (in order_syntax) least_UpperI:
assumes above: "!! x. x \<in> A ==> x \<sqsubseteq> s"
and below: "!! y. y \<in> Upper A ==> s \<sqsubseteq> y"
and L: "A \<subseteq> L" "s \<in> L"
shows "least s (Upper A)"
proof -
have "Upper A \<subseteq> L" by simp
moreover from above L have "s \<in> Upper A" by (simp add: Upper_def)
moreover from below have "ALL x : Upper A. s \<sqsubseteq> x" by fast
ultimately show ?thesis by (simp add: least_def)
qed
subsubsection {* greatest *}
lemma (in order_syntax) greatest_closed [intro, simp]:
"greatest l A ==> l \<in> L"
by (unfold greatest_def) fast
lemma (in order_syntax) greatest_mem:
"greatest l A ==> l \<in> A"
by (unfold greatest_def) fast
lemma (in partial_order) greatest_unique:
"[| greatest x A; greatest y A |] ==> x = y"
by (unfold greatest_def) blast
lemma (in order_syntax) greatest_le:
"[| greatest x A; a \<in> A |] ==> a \<sqsubseteq> x"
by (unfold greatest_def) fast
lemma (in order_syntax) greatest_LowerI:
assumes below: "!! x. x \<in> A ==> i \<sqsubseteq> x"
and above: "!! y. y \<in> Lower A ==> y \<sqsubseteq> i"
and L: "A \<subseteq> L" "i \<in> L"
shows "greatest i (Lower A)"
proof -
have "Lower A \<subseteq> L" by simp
moreover from below L have "i \<in> Lower A" by (simp add: Lower_def)
moreover from above have "ALL x : Lower A. x \<sqsubseteq> i" by fast
ultimately show ?thesis by (simp add: greatest_def)
qed
subsection {* Lattices *}
locale lattice = partial_order +
assumes sup_of_two_exists:
"[| x \<in> L; y \<in> L |] ==> EX s. order_syntax.least L le s (order_syntax.Upper L le {x, y})"
and inf_of_two_exists:
"[| x \<in> L; y \<in> L |] ==> EX s. order_syntax.greatest L le s (order_syntax.Lower L le {x, y})"
abbreviation (in lattice)
less (infixl "\<sqsubset>" 50) "less == order_syntax.less le"
abbreviation (in lattice)
Upper where "Upper == order_syntax.Upper L le"
abbreviation (in lattice)
Lower where "Lower == order_syntax.Lower L le"
abbreviation (in lattice)
least where "least == order_syntax.least L le"
abbreviation (in lattice)
greatest where "greatest == order_syntax.greatest L le"
abbreviation (in lattice)
sup ("\<Squnion>_" [90] 90) "sup == order_syntax.sup L le"
abbreviation (in lattice)
inf ("\<Sqinter>_" [90] 90) "inf == order_syntax.inf L le"
abbreviation (in lattice)
join (infixl "\<squnion>" 65) "join == order_syntax.join L le"
abbreviation (in lattice)
meet (infixl "\<sqinter>" 70) "meet == order_syntax.meet L le"
lemma (in order_syntax) least_Upper_above:
"[| least s (Upper A); x \<in> A; A \<subseteq> L |] ==> x \<sqsubseteq> s"
by (unfold least_def) blast
lemma (in order_syntax) greatest_Lower_above:
"[| greatest i (Lower A); x \<in> A; A \<subseteq> L |] ==> i \<sqsubseteq> x"
by (unfold greatest_def) blast
subsubsection {* Supremum *}
lemma (in lattice) joinI:
"[| !!l. least l (Upper {x, y}) ==> P l; x \<in> L; y \<in> L |]
==> P (x \<squnion> y)"
proof (unfold join_def sup_def)
assume L: "x \<in> L" "y \<in> L"
and P: "!!l. least l (Upper {x, y}) ==> P l"
with sup_of_two_exists obtain s where "least s (Upper {x, y})" by fast
with L show "P (THE l. least l (Upper {x, y}))"
by (fast intro: theI2 least_unique P)
qed
lemma (in lattice) join_closed [simp]:
"[| x \<in> L; y \<in> L |] ==> x \<squnion> y \<in> L"
by (rule joinI) (rule least_closed)
lemma (in partial_order) sup_of_singletonI: (* only reflexivity needed ? *)
"x \<in> L ==> least x (Upper {x})"
by (rule least_UpperI) fast+
lemma (in partial_order) sup_of_singleton [simp]:
"x \<in> L ==> \<Squnion>{x} = x"
by (unfold sup_def) (blast intro: least_unique least_UpperI sup_of_singletonI)
text {* Condition on @{text A}: supremum exists. *}
lemma (in lattice) sup_insertI:
"[| !!s. least s (Upper (insert x A)) ==> P s;
least a (Upper A); x \<in> L; A \<subseteq> L |]
==> P (\<Squnion>(insert x A))"
proof (unfold sup_def)
assume L: "x \<in> L" "A \<subseteq> L"
and P: "!!l. least l (Upper (insert x A)) ==> P l"
and least_a: "least a (Upper A)"
from least_a have La: "a \<in> L" by simp
from L sup_of_two_exists least_a
obtain s where least_s: "least s (Upper {a, x})" by blast
show "P (THE l. least l (Upper (insert x A)))"
proof (rule theI2)
show "least s (Upper (insert x A))"
proof (rule least_UpperI)
fix z
assume "z \<in> insert x A"
then show "z \<sqsubseteq> s"
proof
assume "z = x" then show ?thesis
by (simp add: least_Upper_above [OF least_s] L La)
next
assume "z \<in> A"
with L least_s least_a show ?thesis
by (rule_tac trans [where y = a]) (auto dest: least_Upper_above)
qed
next
fix y
assume y: "y \<in> Upper (insert x A)"
show "s \<sqsubseteq> y"
proof (rule least_le [OF least_s], rule Upper_memI)
fix z
assume z: "z \<in> {a, x}"
then show "z \<sqsubseteq> y"
proof
have y': "y \<in> Upper A"
apply (rule subsetD [where A = "Upper (insert x A)"])
apply (rule Upper_antimono) apply clarify apply assumption
done
assume "z = a"
with y' least_a show ?thesis by (fast dest: least_le)
next
assume "z \<in> {x}" (* FIXME "z = x"; declare specific elim rule for "insert x {}" (!?) *)
with y L show ?thesis by blast
qed
qed (rule Upper_closed [THEN subsetD])
next
from L show "insert x A \<subseteq> L" by simp
from least_s show "s \<in> L" by simp
qed
next
fix l
assume least_l: "least l (Upper (insert x A))"
show "l = s"
proof (rule least_unique)
show "least s (Upper (insert x A))"
proof (rule least_UpperI)
fix z
assume "z \<in> insert x A"
then show "z \<sqsubseteq> s"
proof
assume "z = x" then show ?thesis
by (simp add: least_Upper_above [OF least_s] L La)
next
assume "z \<in> A"
with L least_s least_a show ?thesis
by (rule_tac trans [where y = a]) (auto dest: least_Upper_above)
qed
next
fix y
assume y: "y \<in> Upper (insert x A)"
show "s \<sqsubseteq> y"
proof (rule least_le [OF least_s], rule Upper_memI)
fix z
assume z: "z \<in> {a, x}"
then show "z \<sqsubseteq> y"
proof
have y': "y \<in> Upper A"
apply (rule subsetD [where A = "Upper (insert x A)"])
apply (rule Upper_antimono) apply clarify apply assumption
done
assume "z = a"
with y' least_a show ?thesis by (fast dest: least_le)
next
assume "z \<in> {x}"
with y L show ?thesis by blast
qed
qed (rule Upper_closed [THEN subsetD])
next
from L show "insert x A \<subseteq> L" by simp
from least_s show "s \<in> L" by simp
qed
qed
qed
qed
lemma (in lattice) finite_sup_least:
"[| finite A; A \<subseteq> L; A ~= {} |] ==> least (\<Squnion>A) (Upper A)"
proof (induct set: Finites)
case empty
then show ?case by simp
next
case (insert x A)
show ?case
proof (cases "A = {}")
case True
with insert show ?thesis by (simp add: sup_of_singletonI)
next
case False
with insert have "least (\<Squnion>A) (Upper A)" by simp
with _ show ?thesis
by (rule sup_insertI) (simp_all add: insert [simplified])
qed
qed
lemma (in lattice) finite_sup_insertI:
assumes P: "!!l. least l (Upper (insert x A)) ==> P l"
and xA: "finite A" "x \<in> L" "A \<subseteq> L"
shows "P (\<Squnion> (insert x A))"
proof (cases "A = {}")
case True with P and xA show ?thesis
by (simp add: sup_of_singletonI)
next
case False with P and xA show ?thesis
by (simp add: sup_insertI finite_sup_least)
qed
lemma (in lattice) finite_sup_closed:
"[| finite A; A \<subseteq> L; A ~= {} |] ==> \<Squnion>A \<in> L"
proof (induct set: Finites)
case empty then show ?case by simp
next
case insert then show ?case
by - (rule finite_sup_insertI, simp_all)
qed
lemma (in lattice) join_left:
"[| x \<in> L; y \<in> L |] ==> x \<sqsubseteq> x \<squnion> y"
by (rule joinI [folded join_def]) (blast dest: least_mem)
lemma (in lattice) join_right:
"[| x \<in> L; y \<in> L |] ==> y \<sqsubseteq> x \<squnion> y"
by (rule joinI [folded join_def]) (blast dest: least_mem)
lemma (in lattice) sup_of_two_least:
"[| x \<in> L; y \<in> L |] ==> least (\<Squnion>{x, y}) (Upper {x, y})"
proof (unfold sup_def)
assume L: "x \<in> L" "y \<in> L"
with sup_of_two_exists obtain s where "least s (Upper {x, y})" by fast
with L show "least (THE xa. least xa (Upper {x, y})) (Upper {x, y})"
by (fast intro: theI2 least_unique) (* blast fails *)
qed
lemma (in lattice) join_le:
assumes sub: "x \<sqsubseteq> z" "y \<sqsubseteq> z"
and L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "x \<squnion> y \<sqsubseteq> z"
proof (rule joinI)
fix s
assume "least s (Upper {x, y})"
with sub L show "s \<sqsubseteq> z" by (fast elim: least_le intro: Upper_memI)
qed
lemma (in lattice) join_assoc_lemma:
assumes L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "x \<squnion> (y \<squnion> z) = \<Squnion>{x, y, z}"
proof (rule finite_sup_insertI)
-- {* The textbook argument in Jacobson I, p 457 *}
fix s
assume sup: "least s (Upper {x, y, z})"
show "x \<squnion> (y \<squnion> z) = s"
proof (rule anti_sym)
from sup L show "x \<squnion> (y \<squnion> z) \<sqsubseteq> s"
by (fastsimp intro!: join_le elim: least_Upper_above)
next
from sup L show "s \<sqsubseteq> x \<squnion> (y \<squnion> z)"
by (erule_tac least_le)
(blast intro!: Upper_memI intro: trans join_left join_right join_closed)
qed (simp_all add: L least_closed [OF sup])
qed (simp_all add: L)
lemma (in order_syntax) join_comm:
"x \<squnion> y = y \<squnion> x"
by (unfold join_def) (simp add: insert_commute)
lemma (in lattice) join_assoc:
assumes L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "(x \<squnion> y) \<squnion> z = x \<squnion> (y \<squnion> z)"
proof -
have "(x \<squnion> y) \<squnion> z = z \<squnion> (x \<squnion> y)" by (simp only: join_comm)
also from L have "... = \<Squnion>{z, x, y}" by (simp add: join_assoc_lemma)
also from L have "... = \<Squnion>{x, y, z}" by (simp add: insert_commute)
also from L have "... = x \<squnion> (y \<squnion> z)" by (simp add: join_assoc_lemma)
finally show ?thesis .
qed
subsubsection {* Infimum *}
lemma (in lattice) meetI:
"[| !!i. greatest i (Lower {x, y}) ==> P i; x \<in> L; y \<in> L |]
==> P (x \<sqinter> y)"
proof (unfold meet_def inf_def)
assume L: "x \<in> L" "y \<in> L"
and P: "!!g. greatest g (Lower {x, y}) ==> P g"
with inf_of_two_exists obtain i where "greatest i (Lower {x, y})" by fast
with L show "P (THE g. greatest g (Lower {x, y}))"
by (fast intro: theI2 greatest_unique P)
qed
lemma (in lattice) meet_closed [simp]:
"[| x \<in> L; y \<in> L |] ==> x \<sqinter> y \<in> L"
by (rule meetI) (rule greatest_closed)
lemma (in partial_order) inf_of_singletonI: (* only reflexivity needed ? *)
"x \<in> L ==> greatest x (Lower {x})"
by (rule greatest_LowerI) fast+
lemma (in partial_order) inf_of_singleton [simp]:
"x \<in> L ==> \<Sqinter> {x} = x"
by (unfold inf_def) (blast intro: greatest_unique greatest_LowerI inf_of_singletonI)
text {* Condition on A: infimum exists. *}
lemma (in lattice) inf_insertI:
"[| !!i. greatest i (Lower (insert x A)) ==> P i;
greatest a (Lower A); x \<in> L; A \<subseteq> L |]
==> P (\<Sqinter>(insert x A))"
proof (unfold inf_def)
assume L: "x \<in> L" "A \<subseteq> L"
and P: "!!g. greatest g (Lower (insert x A)) ==> P g"
and greatest_a: "greatest a (Lower A)"
from greatest_a have La: "a \<in> L" by simp
from L inf_of_two_exists greatest_a
obtain i where greatest_i: "greatest i (Lower {a, x})" by blast
show "P (THE g. greatest g (Lower (insert x A)))"
proof (rule theI2)
show "greatest i (Lower (insert x A))"
proof (rule greatest_LowerI)
fix z
assume "z \<in> insert x A"
then show "i \<sqsubseteq> z"
proof
assume "z = x" then show ?thesis
by (simp add: greatest_Lower_above [OF greatest_i] L La)
next
assume "z \<in> A"
with L greatest_i greatest_a show ?thesis
by (rule_tac trans [where y = a]) (auto dest: greatest_Lower_above)
qed
next
fix y
assume y: "y \<in> Lower (insert x A)"
show "y \<sqsubseteq> i"
proof (rule greatest_le [OF greatest_i], rule Lower_memI)
fix z
assume z: "z \<in> {a, x}"
then show "y \<sqsubseteq> z"
proof
have y': "y \<in> Lower A"
apply (rule subsetD [where A = "Lower (insert x A)"])
apply (rule Lower_antimono) apply clarify apply assumption
done
assume "z = a"
with y' greatest_a show ?thesis by (fast dest: greatest_le)
next
assume "z \<in> {x}"
with y L show ?thesis by blast
qed
qed (rule Lower_closed [THEN subsetD])
next
from L show "insert x A \<subseteq> L" by simp
from greatest_i show "i \<in> L" by simp
qed
next
fix g
assume greatest_g: "greatest g (Lower (insert x A))"
show "g = i"
proof (rule greatest_unique)
show "greatest i (Lower (insert x A))"
proof (rule greatest_LowerI)
fix z
assume "z \<in> insert x A"
then show "i \<sqsubseteq> z"
proof
assume "z = x" then show ?thesis
by (simp add: greatest_Lower_above [OF greatest_i] L La)
next
assume "z \<in> A"
with L greatest_i greatest_a show ?thesis
by (rule_tac trans [where y = a]) (auto dest: greatest_Lower_above)
qed
next
fix y
assume y: "y \<in> Lower (insert x A)"
show "y \<sqsubseteq> i"
proof (rule greatest_le [OF greatest_i], rule Lower_memI)
fix z
assume z: "z \<in> {a, x}"
then show "y \<sqsubseteq> z"
proof
have y': "y \<in> Lower A"
apply (rule subsetD [where A = "Lower (insert x A)"])
apply (rule Lower_antimono) apply clarify apply assumption
done
assume "z = a"
with y' greatest_a show ?thesis by (fast dest: greatest_le)
next
assume "z \<in> {x}"
with y L show ?thesis by blast
qed
qed (rule Lower_closed [THEN subsetD])
next
from L show "insert x A \<subseteq> L" by simp
from greatest_i show "i \<in> L" by simp
qed
qed
qed
qed
lemma (in lattice) finite_inf_greatest:
"[| finite A; A \<subseteq> L; A ~= {} |] ==> greatest (\<Sqinter>A) (Lower A)"
proof (induct set: Finites)
case empty then show ?case by simp
next
case (insert x A)
show ?case
proof (cases "A = {}")
case True
with insert show ?thesis by (simp add: inf_of_singletonI)
next
case False
from insert show ?thesis
proof (rule_tac inf_insertI)
from False insert show "greatest (\<Sqinter>A) (Lower A)" by simp
qed simp_all
qed
qed
lemma (in lattice) finite_inf_insertI:
assumes P: "!!i. greatest i (Lower (insert x A)) ==> P i"
and xA: "finite A" "x \<in> L" "A \<subseteq> L"
shows "P (\<Sqinter> (insert x A))"
proof (cases "A = {}")
case True with P and xA show ?thesis
by (simp add: inf_of_singletonI)
next
case False with P and xA show ?thesis
by (simp add: inf_insertI finite_inf_greatest)
qed
lemma (in lattice) finite_inf_closed:
"[| finite A; A \<subseteq> L; A ~= {} |] ==> \<Sqinter>A \<in> L"
proof (induct set: Finites)
case empty then show ?case by simp
next
case insert then show ?case
by (rule_tac finite_inf_insertI) (simp_all)
qed
lemma (in lattice) meet_left:
"[| x \<in> L; y \<in> L |] ==> x \<sqinter> y \<sqsubseteq> x"
by (rule meetI [folded meet_def]) (blast dest: greatest_mem)
lemma (in lattice) meet_right:
"[| x \<in> L; y \<in> L |] ==> x \<sqinter> y \<sqsubseteq> y"
by (rule meetI [folded meet_def]) (blast dest: greatest_mem)
lemma (in lattice) inf_of_two_greatest:
"[| x \<in> L; y \<in> L |] ==> greatest (\<Sqinter> {x, y}) (Lower {x, y})"
proof (unfold inf_def)
assume L: "x \<in> L" "y \<in> L"
with inf_of_two_exists obtain s where "greatest s (Lower {x, y})" by fast
with L
show "greatest (THE xa. greatest xa (Lower {x, y})) (Lower {x, y})"
by (fast intro: theI2 greatest_unique) (* blast fails *)
qed
lemma (in lattice) meet_le:
assumes sub: "z \<sqsubseteq> x" "z \<sqsubseteq> y"
and L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "z \<sqsubseteq> x \<sqinter> y"
proof (rule meetI)
fix i
assume "greatest i (Lower {x, y})"
with sub L show "z \<sqsubseteq> i" by (fast elim: greatest_le intro: Lower_memI)
qed
lemma (in lattice) meet_assoc_lemma:
assumes L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "x \<sqinter> (y \<sqinter> z) = \<Sqinter>{x, y, z}"
proof (rule finite_inf_insertI)
txt {* The textbook argument in Jacobson I, p 457 *}
fix i
assume inf: "greatest i (Lower {x, y, z})"
show "x \<sqinter> (y \<sqinter> z) = i"
proof (rule anti_sym)
from inf L show "i \<sqsubseteq> x \<sqinter> (y \<sqinter> z)"
by (fastsimp intro!: meet_le elim: greatest_Lower_above)
next
from inf L show "x \<sqinter> (y \<sqinter> z) \<sqsubseteq> i"
by (erule_tac greatest_le)
(blast intro!: Lower_memI intro: trans meet_left meet_right meet_closed)
qed (simp_all add: L greatest_closed [OF inf])
qed (simp_all add: L)
lemma (in order_syntax) meet_comm:
"x \<sqinter> y = y \<sqinter> x"
by (unfold meet_def) (simp add: insert_commute)
lemma (in lattice) meet_assoc:
assumes L: "x \<in> L" "y \<in> L" "z \<in> L"
shows "(x \<sqinter> y) \<sqinter> z = x \<sqinter> (y \<sqinter> z)"
proof -
have "(x \<sqinter> y) \<sqinter> z = z \<sqinter> (x \<sqinter> y)" by (simp only: meet_comm)
also from L have "... = \<Sqinter> {z, x, y}" by (simp add: meet_assoc_lemma)
also from L have "... = \<Sqinter> {x, y, z}" by (simp add: insert_commute)
also from L have "... = x \<sqinter> (y \<sqinter> z)" by (simp add: meet_assoc_lemma)
finally show ?thesis .
qed
subsection {* Total Orders *}
locale total_order = lattice +
assumes total: "[| x \<in> L; y \<in> L |] ==> x \<sqsubseteq> y | y \<sqsubseteq> x"
abbreviation (in total_order)
less (infixl "\<sqsubset>" 50) "less == order_syntax.less le"
abbreviation (in total_order)
Upper where "Upper == order_syntax.Upper L le"
abbreviation (in total_order)
Lower where "Lower == order_syntax.Lower L le"
abbreviation (in total_order)
least where "least == order_syntax.least L le"
abbreviation (in total_order)
greatest where "greatest == order_syntax.greatest L le"
abbreviation (in total_order)
sup ("\<Squnion>_" [90] 90) "sup == order_syntax.sup L le"
abbreviation (in total_order)
inf ("\<Sqinter>_" [90] 90) "inf == order_syntax.inf L le"
abbreviation (in total_order)
join (infixl "\<squnion>" 65) "join == order_syntax.join L le"
abbreviation (in total_order)
meet (infixl "\<sqinter>" 70) "meet == order_syntax.meet L le"
text {* Introduction rule: the usual definition of total order *}
lemma (in partial_order) total_orderI:
assumes total: "!!x y. [| x \<in> L; y \<in> L |] ==> x \<sqsubseteq> y | y \<sqsubseteq> x"
shows "total_order L le"
proof intro_locales
show "lattice_axioms L le"
proof (rule lattice_axioms.intro)
fix x y
assume L: "x \<in> L" "y \<in> L"
show "EX s. least s (Upper {x, y})"
proof -
note total L
moreover
{
assume "x \<sqsubseteq> y"
with L have "least y (Upper {x, y})"
by (rule_tac least_UpperI) auto
}
moreover
{
assume "y \<sqsubseteq> x"
with L have "least x (Upper {x, y})"
by (rule_tac least_UpperI) auto
}
ultimately show ?thesis by blast
qed
next
fix x y
assume L: "x \<in> L" "y \<in> L"
show "EX i. greatest i (Lower {x, y})"
proof -
note total L
moreover
{
assume "y \<sqsubseteq> x"
with L have "greatest y (Lower {x, y})"
by (rule_tac greatest_LowerI) auto
}
moreover
{
assume "x \<sqsubseteq> y"
with L have "greatest x (Lower {x, y})"
by (rule_tac greatest_LowerI) auto
}
ultimately show ?thesis by blast
qed
qed
qed (assumption | rule total_order_axioms.intro)+
subsection {* Complete lattices *}
locale complete_lattice = lattice +
assumes sup_exists:
"[| A \<subseteq> L |] ==> EX s. order_syntax.least L le s (order_syntax.Upper L le A)"
and inf_exists:
"[| A \<subseteq> L |] ==> EX i. order_syntax.greatest L le i (order_syntax.Lower L le A)"
abbreviation (in complete_lattice)
less (infixl "\<sqsubset>" 50) "less == order_syntax.less le"
abbreviation (in complete_lattice)
Upper where "Upper == order_syntax.Upper L le"
abbreviation (in complete_lattice)
Lower where "Lower == order_syntax.Lower L le"
abbreviation (in complete_lattice)
least where "least == order_syntax.least L le"
abbreviation (in complete_lattice)
greatest where "greatest == order_syntax.greatest L le"
abbreviation (in complete_lattice)
sup ("\<Squnion>_" [90] 90) "sup == order_syntax.sup L le"
abbreviation (in complete_lattice)
inf ("\<Sqinter>_" [90] 90) "inf == order_syntax.inf L le"
abbreviation (in complete_lattice)
join (infixl "\<squnion>" 65) "join == order_syntax.join L le"
abbreviation (in complete_lattice)
meet (infixl "\<sqinter>" 70) "meet == order_syntax.meet L le"
text {* Introduction rule: the usual definition of complete lattice *}
lemma (in partial_order) complete_latticeI:
assumes sup_exists:
"!!A. [| A \<subseteq> L |] ==> EX s. least s (Upper A)"
and inf_exists:
"!!A. [| A \<subseteq> L |] ==> EX i. greatest i (Lower A)"
shows "complete_lattice L le"
proof intro_locales
show "lattice_axioms L le"
by (rule lattice_axioms.intro) (blast intro: sup_exists inf_exists)+
qed (assumption | rule complete_lattice_axioms.intro)+
definition (in order_syntax)
top ("\<top>")
"\<top> == sup L"
definition (in order_syntax)
bottom ("\<bottom>")
"\<bottom> == inf L"
abbreviation (in partial_order)
top ("\<top>") "top == order_syntax.top L le"
abbreviation (in partial_order)
bottom ("\<bottom>") "bottom == order_syntax.bottom L le"
abbreviation (in lattice)
top ("\<top>") "top == order_syntax.top L le"
abbreviation (in lattice)
bottom ("\<bottom>") "bottom == order_syntax.bottom L le"
abbreviation (in total_order)
top ("\<top>") "top == order_syntax.top L le"
abbreviation (in total_order)
bottom ("\<bottom>") "bottom == order_syntax.bottom L le"
abbreviation (in complete_lattice)
top ("\<top>") "top == order_syntax.top L le"
abbreviation (in complete_lattice)
bottom ("\<bottom>") "bottom == order_syntax.bottom L le"
lemma (in complete_lattice) supI:
"[| !!l. least l (Upper A) ==> P l; A \<subseteq> L |]
==> P (\<Squnion>A)"
proof (unfold sup_def)
assume L: "A \<subseteq> L"
and P: "!!l. least l (Upper A) ==> P l"
with sup_exists obtain s where "least s (Upper A)" by blast
with L show "P (THE l. least l (Upper A))"
by (fast intro: theI2 least_unique P)
qed
lemma (in complete_lattice) sup_closed [simp]:
"A \<subseteq> L ==> \<Squnion>A \<in> L"
by (rule supI) simp_all
lemma (in complete_lattice) top_closed [simp, intro]:
"\<top> \<in> L"
by (unfold top_def) simp
lemma (in complete_lattice) infI:
"[| !!i. greatest i (Lower A) ==> P i; A \<subseteq> L |]
==> P (\<Sqinter>A)"
proof (unfold inf_def)
assume L: "A \<subseteq> L"
and P: "!!l. greatest l (Lower A) ==> P l"
with inf_exists obtain s where "greatest s (Lower A)" by blast
with L show "P (THE l. greatest l (Lower A))"
by (fast intro: theI2 greatest_unique P)
qed
lemma (in complete_lattice) inf_closed [simp]:
"A \<subseteq> L ==> \<Sqinter>A \<in> L"
by (rule infI) simp_all
lemma (in complete_lattice) bottom_closed [simp, intro]:
"\<bottom> \<in> L"
by (unfold bottom_def) simp
text {* Jacobson: Theorem 8.1 *}
lemma (in order_syntax) Lower_empty [simp]:
"Lower {} = L"
by (unfold Lower_def) simp
lemma (in order_syntax) Upper_empty [simp]:
"Upper {} = L"
by (unfold Upper_def) simp
theorem (in partial_order) complete_lattice_criterion1:
assumes top_exists: "EX g. greatest g L"
and inf_exists:
"!!A. [| A \<subseteq> L; A ~= {} |] ==> EX i. greatest i (Lower A)"
shows "complete_lattice L le"
proof (rule complete_latticeI)
from top_exists obtain top where top: "greatest top L" ..
fix A
assume L: "A \<subseteq> L"
let ?B = "Upper A"
from L top have "top \<in> ?B" by (fast intro!: Upper_memI intro: greatest_le)
then have B_non_empty: "?B ~= {}" by fast
have B_L: "?B \<subseteq> L" by simp
from inf_exists [OF B_L B_non_empty]
obtain b where b_inf_B: "greatest b (Lower ?B)" ..
have "least b (Upper A)"
apply (rule least_UpperI)
apply (rule greatest_le [where A = "Lower ?B"])
apply (rule b_inf_B)
apply (rule Lower_memI)
apply (erule UpperD)
apply assumption
apply (rule L)
apply (fast intro: L [THEN subsetD])
apply (erule greatest_Lower_above [OF b_inf_B])
apply simp
apply (rule L)
apply (rule greatest_closed [OF b_inf_B]) (* rename rule: _closed *)
done
then show "EX s. least s (Upper A)" ..
next
fix A
assume L: "A \<subseteq> L"
show "EX i. greatest i (Lower A)"
proof (cases "A = {}")
case True then show ?thesis
by (simp add: top_exists)
next
case False with L show ?thesis
by (rule inf_exists)
qed
qed
(* TODO: prove dual version *)
subsection {* Examples *}
subsubsection {* Powerset of a Set is a Complete Lattice *}
theorem powerset_is_complete_lattice:
"complete_lattice (Pow A) (op \<subseteq>)"
(is "complete_lattice ?L ?le")
proof (rule partial_order.complete_latticeI)
show "partial_order ?L ?le"
by (rule partial_order.intro) auto
next
fix B
assume "B \<subseteq> ?L"
then have "order_syntax.least ?L ?le (\<Union> B) (order_syntax.Upper ?L ?le B)"
by (fastsimp intro!: order_syntax.least_UpperI simp: order_syntax.Upper_def)
then show "EX s. order_syntax.least ?L ?le s (order_syntax.Upper ?L ?le B)" ..
next
fix B
assume "B \<subseteq> ?L"
then have "order_syntax.greatest ?L ?le (\<Inter> B \<inter> A) (order_syntax.Lower ?L ?le B)"
txt {* @{term "\<Inter> B"} is not the infimum of @{term B}:
@{term "\<Inter> {} = UNIV"} which is in general bigger than @{term "A"}! *}
by (fastsimp intro!: order_syntax.greatest_LowerI simp: order_syntax.Lower_def)
then show "EX i. order_syntax.greatest ?L ?le i (order_syntax.Lower ?L ?le B)" ..
qed
text {* An other example, that of the lattice of subgroups of a group,
can be found in Group theory (Section~\ref{sec:subgroup-lattice}). *}
end