header {* The cpo of cartesian products *}
theory Product_Cpo
imports Adm
begin
default_sort cpo
subsection {* Unit type is a pcpo *}
instantiation unit :: discrete_cpo
begin
definition
below_unit_def [simp]: "x \<sqsubseteq> (y::unit) <-> True"
instance proof
qed simp
end
instance unit :: pcpo
by intro_classes simp
subsection {* Product type is a partial order *}
instantiation prod :: (below, below) below
begin
definition
below_prod_def: "(op \<sqsubseteq>) ≡ λp1 p2. (fst p1 \<sqsubseteq> fst p2 ∧ snd p1 \<sqsubseteq> snd p2)"
instance ..
end
instance prod :: (po, po) po
proof
fix x :: "'a × 'b"
show "x \<sqsubseteq> x"
unfolding below_prod_def by simp
next
fix x y :: "'a × 'b"
assume "x \<sqsubseteq> y" "y \<sqsubseteq> x" thus "x = y"
unfolding below_prod_def prod_eq_iff
by (fast intro: below_antisym)
next
fix x y z :: "'a × 'b"
assume "x \<sqsubseteq> y" "y \<sqsubseteq> z" thus "x \<sqsubseteq> z"
unfolding below_prod_def
by (fast intro: below_trans)
qed
subsection {* Monotonicity of \emph{Pair}, \emph{fst}, \emph{snd} *}
lemma prod_belowI: "[|fst p \<sqsubseteq> fst q; snd p \<sqsubseteq> snd q|] ==> p \<sqsubseteq> q"
unfolding below_prod_def by simp
lemma Pair_below_iff [simp]: "(a, b) \<sqsubseteq> (c, d) <-> a \<sqsubseteq> c ∧ b \<sqsubseteq> d"
unfolding below_prod_def by simp
text {* Pair @{text "(_,_)"} is monotone in both arguments *}
lemma monofun_pair1: "monofun (λx. (x, y))"
by (simp add: monofun_def)
lemma monofun_pair2: "monofun (λy. (x, y))"
by (simp add: monofun_def)
lemma monofun_pair:
"[|x1 \<sqsubseteq> x2; y1 \<sqsubseteq> y2|] ==> (x1, y1) \<sqsubseteq> (x2, y2)"
by simp
lemma ch2ch_Pair [simp]:
"chain X ==> chain Y ==> chain (λi. (X i, Y i))"
by (rule chainI, simp add: chainE)
text {* @{term fst} and @{term snd} are monotone *}
lemma fst_monofun: "x \<sqsubseteq> y ==> fst x \<sqsubseteq> fst y"
unfolding below_prod_def by simp
lemma snd_monofun: "x \<sqsubseteq> y ==> snd x \<sqsubseteq> snd y"
unfolding below_prod_def by simp
lemma monofun_fst: "monofun fst"
by (simp add: monofun_def below_prod_def)
lemma monofun_snd: "monofun snd"
by (simp add: monofun_def below_prod_def)
lemmas ch2ch_fst [simp] = ch2ch_monofun [OF monofun_fst]
lemmas ch2ch_snd [simp] = ch2ch_monofun [OF monofun_snd]
lemma prod_chain_cases:
assumes "chain Y"
obtains A B
where "chain A" and "chain B" and "Y = (λi. (A i, B i))"
proof
from `chain Y` show "chain (λi. fst (Y i))" by (rule ch2ch_fst)
from `chain Y` show "chain (λi. snd (Y i))" by (rule ch2ch_snd)
show "Y = (λi. (fst (Y i), snd (Y i)))" by simp
qed
subsection {* Product type is a cpo *}
lemma is_lub_Pair:
"[|range A <<| x; range B <<| y|] ==> range (λi. (A i, B i)) <<| (x, y)"
unfolding is_lub_def is_ub_def ball_simps below_prod_def by simp
lemma lub_Pair:
"[|chain (A::nat => 'a::cpo); chain (B::nat => 'b::cpo)|]
==> (\<Squnion>i. (A i, B i)) = (\<Squnion>i. A i, \<Squnion>i. B i)"
by (fast intro: lub_eqI is_lub_Pair elim: thelubE)
lemma is_lub_prod:
fixes S :: "nat => ('a::cpo × 'b::cpo)"
assumes S: "chain S"
shows "range S <<| (\<Squnion>i. fst (S i), \<Squnion>i. snd (S i))"
using S by (auto elim: prod_chain_cases simp add: is_lub_Pair cpo_lubI)
lemma lub_prod:
"chain (S::nat => 'a::cpo × 'b::cpo)
==> (\<Squnion>i. S i) = (\<Squnion>i. fst (S i), \<Squnion>i. snd (S i))"
by (rule is_lub_prod [THEN lub_eqI])
instance prod :: (cpo, cpo) cpo
proof
fix S :: "nat => ('a × 'b)"
assume "chain S"
hence "range S <<| (\<Squnion>i. fst (S i), \<Squnion>i. snd (S i))"
by (rule is_lub_prod)
thus "∃x. range S <<| x" ..
qed
instance prod :: (discrete_cpo, discrete_cpo) discrete_cpo
proof
fix x y :: "'a × 'b"
show "x \<sqsubseteq> y <-> x = y"
unfolding below_prod_def prod_eq_iff
by simp
qed
subsection {* Product type is pointed *}
lemma minimal_prod: "(⊥, ⊥) \<sqsubseteq> p"
by (simp add: below_prod_def)
instance prod :: (pcpo, pcpo) pcpo
by intro_classes (fast intro: minimal_prod)
lemma inst_prod_pcpo: "⊥ = (⊥, ⊥)"
by (rule minimal_prod [THEN bottomI, symmetric])
lemma Pair_bottom_iff [simp]: "(x, y) = ⊥ <-> x = ⊥ ∧ y = ⊥"
unfolding inst_prod_pcpo by simp
lemma fst_strict [simp]: "fst ⊥ = ⊥"
unfolding inst_prod_pcpo by (rule fst_conv)
lemma snd_strict [simp]: "snd ⊥ = ⊥"
unfolding inst_prod_pcpo by (rule snd_conv)
lemma Pair_strict [simp]: "(⊥, ⊥) = ⊥"
by simp
lemma split_strict [simp]: "split f ⊥ = f ⊥ ⊥"
unfolding split_def by simp
subsection {* Continuity of \emph{Pair}, \emph{fst}, \emph{snd} *}
lemma cont_pair1: "cont (λx. (x, y))"
apply (rule contI)
apply (rule is_lub_Pair)
apply (erule cpo_lubI)
apply (rule is_lub_const)
done
lemma cont_pair2: "cont (λy. (x, y))"
apply (rule contI)
apply (rule is_lub_Pair)
apply (rule is_lub_const)
apply (erule cpo_lubI)
done
lemma cont_fst: "cont fst"
apply (rule contI)
apply (simp add: lub_prod)
apply (erule cpo_lubI [OF ch2ch_fst])
done
lemma cont_snd: "cont snd"
apply (rule contI)
apply (simp add: lub_prod)
apply (erule cpo_lubI [OF ch2ch_snd])
done
lemma cont2cont_Pair [simp, cont2cont]:
assumes f: "cont (λx. f x)"
assumes g: "cont (λx. g x)"
shows "cont (λx. (f x, g x))"
apply (rule cont_apply [OF f cont_pair1])
apply (rule cont_apply [OF g cont_pair2])
apply (rule cont_const)
done
lemmas cont2cont_fst [simp, cont2cont] = cont_compose [OF cont_fst]
lemmas cont2cont_snd [simp, cont2cont] = cont_compose [OF cont_snd]
lemma cont2cont_case_prod:
assumes f1: "!!a b. cont (λx. f x a b)"
assumes f2: "!!x b. cont (λa. f x a b)"
assumes f3: "!!x a. cont (λb. f x a b)"
assumes g: "cont (λx. g x)"
shows "cont (λx. case g x of (a, b) => f x a b)"
unfolding split_def
apply (rule cont_apply [OF g])
apply (rule cont_apply [OF cont_fst f2])
apply (rule cont_apply [OF cont_snd f3])
apply (rule cont_const)
apply (rule f1)
done
lemma prod_contI:
assumes f1: "!!y. cont (λx. f (x, y))"
assumes f2: "!!x. cont (λy. f (x, y))"
shows "cont f"
proof -
have "cont (λ(x, y). f (x, y))"
by (intro cont2cont_case_prod f1 f2 cont2cont)
thus "cont f"
by (simp only: split_eta)
qed
lemma prod_cont_iff:
"cont f <-> (∀y. cont (λx. f (x, y))) ∧ (∀x. cont (λy. f (x, y)))"
apply safe
apply (erule cont_compose [OF _ cont_pair1])
apply (erule cont_compose [OF _ cont_pair2])
apply (simp only: prod_contI)
done
lemma cont2cont_case_prod' [simp, cont2cont]:
assumes f: "cont (λp. f (fst p) (fst (snd p)) (snd (snd p)))"
assumes g: "cont (λx. g x)"
shows "cont (λx. case_prod (f x) (g x))"
using assms by (simp add: cont2cont_case_prod prod_cont_iff)
text {* The simple version (due to Joachim Breitner) is needed if
either element type of the pair is not a cpo. *}
lemma cont2cont_split_simple [simp, cont2cont]:
assumes "!!a b. cont (λx. f x a b)"
shows "cont (λx. case p of (a, b) => f x a b)"
using assms by (cases p) auto
text {* Admissibility of predicates on product types. *}
lemma adm_case_prod [simp]:
assumes "adm (λx. P x (fst (f x)) (snd (f x)))"
shows "adm (λx. case f x of (a, b) => P x a b)"
unfolding case_prod_beta using assms .
subsection {* Compactness and chain-finiteness *}
lemma fst_below_iff: "fst (x::'a × 'b) \<sqsubseteq> y <-> x \<sqsubseteq> (y, snd x)"
unfolding below_prod_def by simp
lemma snd_below_iff: "snd (x::'a × 'b) \<sqsubseteq> y <-> x \<sqsubseteq> (fst x, y)"
unfolding below_prod_def by simp
lemma compact_fst: "compact x ==> compact (fst x)"
by (rule compactI, simp add: fst_below_iff)
lemma compact_snd: "compact x ==> compact (snd x)"
by (rule compactI, simp add: snd_below_iff)
lemma compact_Pair: "[|compact x; compact y|] ==> compact (x, y)"
by (rule compactI, simp add: below_prod_def)
lemma compact_Pair_iff [simp]: "compact (x, y) <-> compact x ∧ compact y"
apply (safe intro!: compact_Pair)
apply (drule compact_fst, simp)
apply (drule compact_snd, simp)
done
instance prod :: (chfin, chfin) chfin
apply intro_classes
apply (erule compact_imp_max_in_chain)
apply (case_tac "\<Squnion>i. Y i", simp)
done
end