section ‹Classes cpo and pcpo›
theory Pcpo
imports Porder
begin
subsection ‹Complete partial orders›
text ‹The class cpo of chain complete partial orders›
class cpo = po +
assumes cpo: "chain S ⟹ ∃x. range S <<| x"
begin
text ‹in cpo's everthing equal to THE lub has lub properties for every chain›
lemma cpo_lubI: "chain S ⟹ range S <<| (⨆i. S i)"
by (fast dest: cpo elim: is_lub_lub)
lemma thelubE: "⟦chain S; (⨆i. S i) = l⟧ ⟹ range S <<| l"
by (blast dest: cpo intro: is_lub_lub)
text ‹Properties of the lub›
lemma is_ub_thelub: "chain S ⟹ S x ⊑ (⨆i. S i)"
by (blast dest: cpo intro: is_lub_lub [THEN is_lub_rangeD1])
lemma is_lub_thelub:
"⟦chain S; range S <| x⟧ ⟹ (⨆i. S i) ⊑ x"
by (blast dest: cpo intro: is_lub_lub [THEN is_lubD2])
lemma lub_below_iff: "chain S ⟹ (⨆i. S i) ⊑ x ⟷ (∀i. S i ⊑ x)"
by (simp add: is_lub_below_iff [OF cpo_lubI] is_ub_def)
lemma lub_below: "⟦chain S; ⋀i. S i ⊑ x⟧ ⟹ (⨆i. S i) ⊑ x"
by (simp add: lub_below_iff)
lemma below_lub: "⟦chain S; x ⊑ S i⟧ ⟹ x ⊑ (⨆i. S i)"
by (erule below_trans, erule is_ub_thelub)
lemma lub_range_mono:
"⟦range X ⊆ range Y; chain Y; chain X⟧
⟹ (⨆i. X i) ⊑ (⨆i. Y i)"
apply (erule lub_below)
apply (subgoal_tac "∃j. X i = Y j")
apply clarsimp
apply (erule is_ub_thelub)
apply auto
done
lemma lub_range_shift:
"chain Y ⟹ (⨆i. Y (i + j)) = (⨆i. Y i)"
apply (rule below_antisym)
apply (rule lub_range_mono)
apply fast
apply assumption
apply (erule chain_shift)
apply (rule lub_below)
apply assumption
apply (rule_tac i="i" in below_lub)
apply (erule chain_shift)
apply (erule chain_mono)
apply (rule le_add1)
done
lemma maxinch_is_thelub:
"chain Y ⟹ max_in_chain i Y = ((⨆i. Y i) = Y i)"
apply (rule iffI)
apply (fast intro!: lub_eqI lub_finch1)
apply (unfold max_in_chain_def)
apply (safe intro!: below_antisym)
apply (fast elim!: chain_mono)
apply (drule sym)
apply (force elim!: is_ub_thelub)
done
text ‹the ‹⊑› relation between two chains is preserved by their lubs›
lemma lub_mono:
"⟦chain X; chain Y; ⋀i. X i ⊑ Y i⟧
⟹ (⨆i. X i) ⊑ (⨆i. Y i)"
by (fast elim: lub_below below_lub)
text ‹the = relation between two chains is preserved by their lubs›
lemma lub_eq:
"(⋀i. X i = Y i) ⟹ (⨆i. X i) = (⨆i. Y i)"
by simp
lemma ch2ch_lub:
assumes 1: "⋀j. chain (λi. Y i j)"
assumes 2: "⋀i. chain (λj. Y i j)"
shows "chain (λi. ⨆j. Y i j)"
apply (rule chainI)
apply (rule lub_mono [OF 2 2])
apply (rule chainE [OF 1])
done
lemma diag_lub:
assumes 1: "⋀j. chain (λi. Y i j)"
assumes 2: "⋀i. chain (λj. Y i j)"
shows "(⨆i. ⨆j. Y i j) = (⨆i. Y i i)"
proof (rule below_antisym)
have 3: "chain (λi. Y i i)"
apply (rule chainI)
apply (rule below_trans)
apply (rule chainE [OF 1])
apply (rule chainE [OF 2])
done
have 4: "chain (λi. ⨆j. Y i j)"
by (rule ch2ch_lub [OF 1 2])
show "(⨆i. ⨆j. Y i j) ⊑ (⨆i. Y i i)"
apply (rule lub_below [OF 4])
apply (rule lub_below [OF 2])
apply (rule below_lub [OF 3])
apply (rule below_trans)
apply (rule chain_mono [OF 1 max.cobounded1])
apply (rule chain_mono [OF 2 max.cobounded2])
done
show "(⨆i. Y i i) ⊑ (⨆i. ⨆j. Y i j)"
apply (rule lub_mono [OF 3 4])
apply (rule is_ub_thelub [OF 2])
done
qed
lemma ex_lub:
assumes 1: "⋀j. chain (λi. Y i j)"
assumes 2: "⋀i. chain (λj. Y i j)"
shows "(⨆i. ⨆j. Y i j) = (⨆j. ⨆i. Y i j)"
by (simp add: diag_lub 1 2)
end
subsection ‹Pointed cpos›
text ‹The class pcpo of pointed cpos›
class pcpo = cpo +
assumes least: "∃x. ∀y. x ⊑ y"
begin
definition bottom :: "'a" ("⊥")
where "bottom = (THE x. ∀y. x ⊑ y)"
lemma minimal [iff]: "⊥ ⊑ x"
unfolding bottom_def
apply (rule the1I2)
apply (rule ex_ex1I)
apply (rule least)
apply (blast intro: below_antisym)
apply simp
done
end
text ‹Old "UU" syntax:›
syntax UU :: logic
translations "UU" => "CONST bottom"
text ‹Simproc to rewrite @{term "⊥ = x"} to @{term "x = ⊥"}.›
setup ‹
Reorient_Proc.add
(fn Const(@{const_name bottom}, _) => true | _ => false)
›
simproc_setup reorient_bottom ("⊥ = x") = Reorient_Proc.proc
text ‹useful lemmas about @{term ⊥}›
lemma below_bottom_iff [simp]: "(x ⊑ ⊥) = (x = ⊥)"
by (simp add: po_eq_conv)
lemma eq_bottom_iff: "(x = ⊥) = (x ⊑ ⊥)"
by simp
lemma bottomI: "x ⊑ ⊥ ⟹ x = ⊥"
by (subst eq_bottom_iff)
lemma lub_eq_bottom_iff: "chain Y ⟹ (⨆i. Y i) = ⊥ ⟷ (∀i. Y i = ⊥)"
by (simp only: eq_bottom_iff lub_below_iff)
subsection ‹Chain-finite and flat cpos›
text ‹further useful classes for HOLCF domains›
class chfin = po +
assumes chfin: "chain Y ⟹ ∃n. max_in_chain n Y"
begin
subclass cpo
apply standard
apply (frule chfin)
apply (blast intro: lub_finch1)
done
lemma chfin2finch: "chain Y ⟹ finite_chain Y"
by (simp add: chfin finite_chain_def)
end
class flat = pcpo +
assumes ax_flat: "x ⊑ y ⟹ x = ⊥ ∨ x = y"
begin
subclass chfin
apply standard
apply (unfold max_in_chain_def)
apply (case_tac "∀i. Y i = ⊥")
apply simp
apply simp
apply (erule exE)
apply (rule_tac x="i" in exI)
apply clarify
apply (blast dest: chain_mono ax_flat)
done
lemma flat_below_iff:
shows "(x ⊑ y) = (x = ⊥ ∨ x = y)"
by (safe dest!: ax_flat)
lemma flat_eq: "a ≠ ⊥ ⟹ a ⊑ b = (a = b)"
by (safe dest!: ax_flat)
end
subsection ‹Discrete cpos›
class discrete_cpo = below +
assumes discrete_cpo [simp]: "x ⊑ y ⟷ x = y"
begin
subclass po
proof qed simp_all
text ‹In a discrete cpo, every chain is constant›
lemma discrete_chain_const:
assumes S: "chain S"
shows "∃x. S = (λi. x)"
proof (intro exI ext)
fix i :: nat
have "S 0 ⊑ S i" using S le0 by (rule chain_mono)
hence "S 0 = S i" by simp
thus "S i = S 0" by (rule sym)
qed
subclass chfin
proof
fix S :: "nat ⇒ 'a"
assume S: "chain S"
hence "∃x. S = (λi. x)" by (rule discrete_chain_const)
hence "max_in_chain 0 S"
unfolding max_in_chain_def by auto
thus "∃i. max_in_chain i S" ..
qed
end
end