modernized translations;
formal markup of @{syntax_const} and @{const_syntax};
minor tuning;
(* Title: HOLCF/Sprod.thy
Author: Franz Regensburger and Brian Huffman
*)
header {* The type of strict products *}
theory Sprod
imports Bifinite
begin
defaultsort pcpo
subsection {* Definition of strict product type *}
pcpodef (Sprod) ('a, 'b) "**" (infixr "**" 20) =
"{p::'a \<times> 'b. p = \<bottom> \<or> (fst p \<noteq> \<bottom> \<and> snd p \<noteq> \<bottom>)}"
by simp_all
instance "**" :: ("{finite_po,pcpo}", "{finite_po,pcpo}") finite_po
by (rule typedef_finite_po [OF type_definition_Sprod])
instance "**" :: ("{chfin,pcpo}", "{chfin,pcpo}") chfin
by (rule typedef_chfin [OF type_definition_Sprod below_Sprod_def])
syntax (xsymbols)
"**" :: "[type, type] => type" ("(_ \<otimes>/ _)" [21,20] 20)
syntax (HTML output)
"**" :: "[type, type] => type" ("(_ \<otimes>/ _)" [21,20] 20)
lemma spair_lemma:
"(strictify\<cdot>(\<Lambda> b. a)\<cdot>b, strictify\<cdot>(\<Lambda> a. b)\<cdot>a) \<in> Sprod"
by (simp add: Sprod_def strictify_conv_if)
subsection {* Definitions of constants *}
definition
sfst :: "('a ** 'b) \<rightarrow> 'a" where
"sfst = (\<Lambda> p. fst (Rep_Sprod p))"
definition
ssnd :: "('a ** 'b) \<rightarrow> 'b" where
"ssnd = (\<Lambda> p. snd (Rep_Sprod p))"
definition
spair :: "'a \<rightarrow> 'b \<rightarrow> ('a ** 'b)" where
"spair = (\<Lambda> a b. Abs_Sprod
(strictify\<cdot>(\<Lambda> b. a)\<cdot>b, strictify\<cdot>(\<Lambda> a. b)\<cdot>a))"
definition
ssplit :: "('a \<rightarrow> 'b \<rightarrow> 'c) \<rightarrow> ('a ** 'b) \<rightarrow> 'c" where
"ssplit = (\<Lambda> f. strictify\<cdot>(\<Lambda> p. f\<cdot>(sfst\<cdot>p)\<cdot>(ssnd\<cdot>p)))"
syntax
"_stuple" :: "['a, args] => 'a ** 'b" ("(1'(:_,/ _:'))")
translations
"(:x, y, z:)" == "(:x, (:y, z:):)"
"(:x, y:)" == "CONST spair\<cdot>x\<cdot>y"
translations
"\<Lambda>(CONST spair\<cdot>x\<cdot>y). t" == "CONST ssplit\<cdot>(\<Lambda> x y. t)"
subsection {* Case analysis *}
lemma Rep_Sprod_spair:
"Rep_Sprod (:a, b:) = (strictify\<cdot>(\<Lambda> b. a)\<cdot>b, strictify\<cdot>(\<Lambda> a. b)\<cdot>a)"
unfolding spair_def
by (simp add: cont_Abs_Sprod Abs_Sprod_inverse spair_lemma)
lemmas Rep_Sprod_simps =
Rep_Sprod_inject [symmetric] below_Sprod_def
Rep_Sprod_strict Rep_Sprod_spair
lemma Exh_Sprod:
"z = \<bottom> \<or> (\<exists>a b. z = (:a, b:) \<and> a \<noteq> \<bottom> \<and> b \<noteq> \<bottom>)"
apply (insert Rep_Sprod [of z])
apply (simp add: Rep_Sprod_simps Pair_fst_snd_eq)
apply (simp add: Sprod_def)
apply (erule disjE, simp)
apply (simp add: strictify_conv_if)
apply fast
done
lemma sprodE [cases type: **]:
"\<lbrakk>p = \<bottom> \<Longrightarrow> Q; \<And>x y. \<lbrakk>p = (:x, y:); x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> Q\<rbrakk> \<Longrightarrow> Q"
by (cut_tac z=p in Exh_Sprod, auto)
lemma sprod_induct [induct type: **]:
"\<lbrakk>P \<bottom>; \<And>x y. \<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> P (:x, y:)\<rbrakk> \<Longrightarrow> P x"
by (cases x, simp_all)
subsection {* Properties of @{term spair} *}
lemma spair_strict1 [simp]: "(:\<bottom>, y:) = \<bottom>"
by (simp add: Rep_Sprod_simps strictify_conv_if)
lemma spair_strict2 [simp]: "(:x, \<bottom>:) = \<bottom>"
by (simp add: Rep_Sprod_simps strictify_conv_if)
lemma spair_strict_iff [simp]: "((:x, y:) = \<bottom>) = (x = \<bottom> \<or> y = \<bottom>)"
by (simp add: Rep_Sprod_simps strictify_conv_if)
lemma spair_below_iff:
"((:a, b:) \<sqsubseteq> (:c, d:)) = (a = \<bottom> \<or> b = \<bottom> \<or> (a \<sqsubseteq> c \<and> b \<sqsubseteq> d))"
by (simp add: Rep_Sprod_simps strictify_conv_if)
lemma spair_eq_iff:
"((:a, b:) = (:c, d:)) =
(a = c \<and> b = d \<or> (a = \<bottom> \<or> b = \<bottom>) \<and> (c = \<bottom> \<or> d = \<bottom>))"
by (simp add: Rep_Sprod_simps strictify_conv_if)
lemma spair_strict: "x = \<bottom> \<or> y = \<bottom> \<Longrightarrow> (:x, y:) = \<bottom>"
by simp
lemma spair_strict_rev: "(:x, y:) \<noteq> \<bottom> \<Longrightarrow> x \<noteq> \<bottom> \<and> y \<noteq> \<bottom>"
by simp
lemma spair_defined: "\<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> (:x, y:) \<noteq> \<bottom>"
by simp
lemma spair_defined_rev: "(:x, y:) = \<bottom> \<Longrightarrow> x = \<bottom> \<or> y = \<bottom>"
by simp
lemma spair_eq:
"\<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> ((:x, y:) = (:a, b:)) = (x = a \<and> y = b)"
by (simp add: spair_eq_iff)
lemma spair_inject:
"\<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>; (:x, y:) = (:a, b:)\<rbrakk> \<Longrightarrow> x = a \<and> y = b"
by (rule spair_eq [THEN iffD1])
lemma inst_sprod_pcpo2: "UU = (:UU,UU:)"
by simp
lemma sprodE2: "(\<And>x y. p = (:x, y:) \<Longrightarrow> Q) \<Longrightarrow> Q"
by (cases p, simp only: inst_sprod_pcpo2, simp)
subsection {* Properties of @{term sfst} and @{term ssnd} *}
lemma sfst_strict [simp]: "sfst\<cdot>\<bottom> = \<bottom>"
by (simp add: sfst_def cont_Rep_Sprod Rep_Sprod_strict)
lemma ssnd_strict [simp]: "ssnd\<cdot>\<bottom> = \<bottom>"
by (simp add: ssnd_def cont_Rep_Sprod Rep_Sprod_strict)
lemma sfst_spair [simp]: "y \<noteq> \<bottom> \<Longrightarrow> sfst\<cdot>(:x, y:) = x"
by (simp add: sfst_def cont_Rep_Sprod Rep_Sprod_spair)
lemma ssnd_spair [simp]: "x \<noteq> \<bottom> \<Longrightarrow> ssnd\<cdot>(:x, y:) = y"
by (simp add: ssnd_def cont_Rep_Sprod Rep_Sprod_spair)
lemma sfst_defined_iff [simp]: "(sfst\<cdot>p = \<bottom>) = (p = \<bottom>)"
by (cases p, simp_all)
lemma ssnd_defined_iff [simp]: "(ssnd\<cdot>p = \<bottom>) = (p = \<bottom>)"
by (cases p, simp_all)
lemma sfst_defined: "p \<noteq> \<bottom> \<Longrightarrow> sfst\<cdot>p \<noteq> \<bottom>"
by simp
lemma ssnd_defined: "p \<noteq> \<bottom> \<Longrightarrow> ssnd\<cdot>p \<noteq> \<bottom>"
by simp
lemma surjective_pairing_Sprod2: "(:sfst\<cdot>p, ssnd\<cdot>p:) = p"
by (cases p, simp_all)
lemma below_sprod: "x \<sqsubseteq> y = (sfst\<cdot>x \<sqsubseteq> sfst\<cdot>y \<and> ssnd\<cdot>x \<sqsubseteq> ssnd\<cdot>y)"
apply (simp add: below_Sprod_def sfst_def ssnd_def cont_Rep_Sprod)
apply (simp only: below_prod_def)
done
lemma eq_sprod: "(x = y) = (sfst\<cdot>x = sfst\<cdot>y \<and> ssnd\<cdot>x = ssnd\<cdot>y)"
by (auto simp add: po_eq_conv below_sprod)
lemma spair_below:
"\<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> (:x, y:) \<sqsubseteq> (:a, b:) = (x \<sqsubseteq> a \<and> y \<sqsubseteq> b)"
apply (cases "a = \<bottom>", simp)
apply (cases "b = \<bottom>", simp)
apply (simp add: below_sprod)
done
lemma sfst_below_iff: "sfst\<cdot>x \<sqsubseteq> y = x \<sqsubseteq> (:y, ssnd\<cdot>x:)"
apply (cases "x = \<bottom>", simp, cases "y = \<bottom>", simp)
apply (simp add: below_sprod)
done
lemma ssnd_below_iff: "ssnd\<cdot>x \<sqsubseteq> y = x \<sqsubseteq> (:sfst\<cdot>x, y:)"
apply (cases "x = \<bottom>", simp, cases "y = \<bottom>", simp)
apply (simp add: below_sprod)
done
subsection {* Compactness *}
lemma compact_sfst: "compact x \<Longrightarrow> compact (sfst\<cdot>x)"
by (rule compactI, simp add: sfst_below_iff)
lemma compact_ssnd: "compact x \<Longrightarrow> compact (ssnd\<cdot>x)"
by (rule compactI, simp add: ssnd_below_iff)
lemma compact_spair: "\<lbrakk>compact x; compact y\<rbrakk> \<Longrightarrow> compact (:x, y:)"
by (rule compact_Sprod, simp add: Rep_Sprod_spair strictify_conv_if)
lemma compact_spair_iff:
"compact (:x, y:) = (x = \<bottom> \<or> y = \<bottom> \<or> (compact x \<and> compact y))"
apply (safe elim!: compact_spair)
apply (drule compact_sfst, simp)
apply (drule compact_ssnd, simp)
apply simp
apply simp
done
subsection {* Properties of @{term ssplit} *}
lemma ssplit1 [simp]: "ssplit\<cdot>f\<cdot>\<bottom> = \<bottom>"
by (simp add: ssplit_def)
lemma ssplit2 [simp]: "\<lbrakk>x \<noteq> \<bottom>; y \<noteq> \<bottom>\<rbrakk> \<Longrightarrow> ssplit\<cdot>f\<cdot>(:x, y:) = f\<cdot>x\<cdot>y"
by (simp add: ssplit_def)
lemma ssplit3 [simp]: "ssplit\<cdot>spair\<cdot>z = z"
by (cases z, simp_all)
subsection {* Strict product preserves flatness *}
instance "**" :: (flat, flat) flat
proof
fix x y :: "'a \<otimes> 'b"
assume "x \<sqsubseteq> y" thus "x = \<bottom> \<or> x = y"
apply (induct x, simp)
apply (induct y, simp)
apply (simp add: spair_below_iff flat_below_iff)
done
qed
subsection {* Map function for strict products *}
definition
sprod_map :: "('a \<rightarrow> 'b) \<rightarrow> ('c \<rightarrow> 'd) \<rightarrow> 'a \<otimes> 'c \<rightarrow> 'b \<otimes> 'd"
where
"sprod_map = (\<Lambda> f g. ssplit\<cdot>(\<Lambda> x y. (:f\<cdot>x, g\<cdot>y:)))"
lemma sprod_map_strict [simp]: "sprod_map\<cdot>a\<cdot>b\<cdot>\<bottom> = \<bottom>"
unfolding sprod_map_def by simp
lemma sprod_map_spair [simp]:
"x \<noteq> \<bottom> \<Longrightarrow> y \<noteq> \<bottom> \<Longrightarrow> sprod_map\<cdot>f\<cdot>g\<cdot>(:x, y:) = (:f\<cdot>x, g\<cdot>y:)"
by (simp add: sprod_map_def)
lemma sprod_map_ID: "sprod_map\<cdot>ID\<cdot>ID = ID"
unfolding sprod_map_def by (simp add: expand_cfun_eq eta_cfun)
lemma sprod_map_map:
"\<lbrakk>f1\<cdot>\<bottom> = \<bottom>; g1\<cdot>\<bottom> = \<bottom>\<rbrakk> \<Longrightarrow>
sprod_map\<cdot>f1\<cdot>g1\<cdot>(sprod_map\<cdot>f2\<cdot>g2\<cdot>p) =
sprod_map\<cdot>(\<Lambda> x. f1\<cdot>(f2\<cdot>x))\<cdot>(\<Lambda> x. g1\<cdot>(g2\<cdot>x))\<cdot>p"
apply (induct p, simp)
apply (case_tac "f2\<cdot>x = \<bottom>", simp)
apply (case_tac "g2\<cdot>y = \<bottom>", simp)
apply simp
done
lemma ep_pair_sprod_map:
assumes "ep_pair e1 p1" and "ep_pair e2 p2"
shows "ep_pair (sprod_map\<cdot>e1\<cdot>e2) (sprod_map\<cdot>p1\<cdot>p2)"
proof
interpret e1p1: pcpo_ep_pair e1 p1 unfolding pcpo_ep_pair_def by fact
interpret e2p2: pcpo_ep_pair e2 p2 unfolding pcpo_ep_pair_def by fact
fix x show "sprod_map\<cdot>p1\<cdot>p2\<cdot>(sprod_map\<cdot>e1\<cdot>e2\<cdot>x) = x"
by (induct x) simp_all
fix y show "sprod_map\<cdot>e1\<cdot>e2\<cdot>(sprod_map\<cdot>p1\<cdot>p2\<cdot>y) \<sqsubseteq> y"
apply (induct y, simp)
apply (case_tac "p1\<cdot>x = \<bottom>", simp, case_tac "p2\<cdot>y = \<bottom>", simp)
apply (simp add: monofun_cfun e1p1.e_p_below e2p2.e_p_below)
done
qed
lemma deflation_sprod_map:
assumes "deflation d1" and "deflation d2"
shows "deflation (sprod_map\<cdot>d1\<cdot>d2)"
proof
interpret d1: deflation d1 by fact
interpret d2: deflation d2 by fact
fix x
show "sprod_map\<cdot>d1\<cdot>d2\<cdot>(sprod_map\<cdot>d1\<cdot>d2\<cdot>x) = sprod_map\<cdot>d1\<cdot>d2\<cdot>x"
apply (induct x, simp)
apply (case_tac "d1\<cdot>x = \<bottom>", simp, case_tac "d2\<cdot>y = \<bottom>", simp)
apply (simp add: d1.idem d2.idem)
done
show "sprod_map\<cdot>d1\<cdot>d2\<cdot>x \<sqsubseteq> x"
apply (induct x, simp)
apply (simp add: monofun_cfun d1.below d2.below)
done
qed
lemma finite_deflation_sprod_map:
assumes "finite_deflation d1" and "finite_deflation d2"
shows "finite_deflation (sprod_map\<cdot>d1\<cdot>d2)"
proof (intro finite_deflation.intro finite_deflation_axioms.intro)
interpret d1: finite_deflation d1 by fact
interpret d2: finite_deflation d2 by fact
have "deflation d1" and "deflation d2" by fact+
thus "deflation (sprod_map\<cdot>d1\<cdot>d2)" by (rule deflation_sprod_map)
have "{x. sprod_map\<cdot>d1\<cdot>d2\<cdot>x = x} \<subseteq> insert \<bottom>
((\<lambda>(x, y). (:x, y:)) ` ({x. d1\<cdot>x = x} \<times> {y. d2\<cdot>y = y}))"
by (rule subsetI, case_tac x, auto simp add: spair_eq_iff)
thus "finite {x. sprod_map\<cdot>d1\<cdot>d2\<cdot>x = x}"
by (rule finite_subset, simp add: d1.finite_fixes d2.finite_fixes)
qed
subsection {* Strict product is a bifinite domain *}
instantiation "**" :: (bifinite, bifinite) bifinite
begin
definition
approx_sprod_def:
"approx = (\<lambda>n. sprod_map\<cdot>(approx n)\<cdot>(approx n))"
instance proof
fix i :: nat and x :: "'a \<otimes> 'b"
show "chain (approx :: nat \<Rightarrow> 'a \<otimes> 'b \<rightarrow> 'a \<otimes> 'b)"
unfolding approx_sprod_def by simp
show "(\<Squnion>i. approx i\<cdot>x) = x"
unfolding approx_sprod_def sprod_map_def
by (simp add: lub_distribs eta_cfun)
show "approx i\<cdot>(approx i\<cdot>x) = approx i\<cdot>x"
unfolding approx_sprod_def sprod_map_def
by (simp add: ssplit_def strictify_conv_if)
show "finite {x::'a \<otimes> 'b. approx i\<cdot>x = x}"
unfolding approx_sprod_def
by (intro finite_deflation.finite_fixes
finite_deflation_sprod_map
finite_deflation_approx)
qed
end
lemma approx_spair [simp]:
"approx i\<cdot>(:x, y:) = (:approx i\<cdot>x, approx i\<cdot>y:)"
unfolding approx_sprod_def sprod_map_def
by (simp add: ssplit_def strictify_conv_if)
end