Isar "default" step needs to fail for solved problems, for clear distinction of '.' and '..' for example -- amending lapse introduced in 9de4d64eee3b (April 2004);
(* Title: HOLCF/ex/Powerdomain_ex.thy
Author: Brian Huffman
*)
header {* Powerdomain examples *}
theory Powerdomain_ex
imports HOLCF
begin
default_sort bifinite
subsection {* Monadic sorting example *}
domain ordering = LT | EQ | GT
definition
compare :: "int lift \<rightarrow> int lift \<rightarrow> ordering" where
"compare = (FLIFT x y. if x < y then LT else if x = y then EQ else GT)"
definition
is_le :: "int lift \<rightarrow> int lift \<rightarrow> tr" where
"is_le = (\<Lambda> x y. case compare\<cdot>x\<cdot>y of LT \<Rightarrow> TT | EQ \<Rightarrow> TT | GT \<Rightarrow> FF)"
definition
is_less :: "int lift \<rightarrow> int lift \<rightarrow> tr" where
"is_less = (\<Lambda> x y. case compare\<cdot>x\<cdot>y of LT \<Rightarrow> TT | EQ \<Rightarrow> FF | GT \<Rightarrow> FF)"
definition
r1 :: "(int lift \<times> 'a) \<rightarrow> (int lift \<times> 'a) \<rightarrow> tr convex_pd" where
"r1 = (\<Lambda> (x,_) (y,_). case compare\<cdot>x\<cdot>y of
LT \<Rightarrow> {TT}\<natural> |
EQ \<Rightarrow> {TT, FF}\<natural> |
GT \<Rightarrow> {FF}\<natural>)"
definition
r2 :: "(int lift \<times> 'a) \<rightarrow> (int lift \<times> 'a) \<rightarrow> tr convex_pd" where
"r2 = (\<Lambda> (x,_) (y,_). {is_le\<cdot>x\<cdot>y, is_less\<cdot>x\<cdot>y}\<natural>)"
lemma r1_r2: "r1\<cdot>(x,a)\<cdot>(y,b) = (r2\<cdot>(x,a)\<cdot>(y,b) :: tr convex_pd)"
apply (simp add: r1_def r2_def)
apply (simp add: is_le_def is_less_def)
apply (cases "compare\<cdot>x\<cdot>y")
apply simp_all
done
subsection {* Picking a leaf from a tree *}
domain 'a tree =
Node (lazy "'a tree") (lazy "'a tree") |
Leaf (lazy "'a")
fixrec
mirror :: "'a tree \<rightarrow> 'a tree"
where
mirror_Leaf: "mirror\<cdot>(Leaf\<cdot>a) = Leaf\<cdot>a"
| mirror_Node: "mirror\<cdot>(Node\<cdot>l\<cdot>r) = Node\<cdot>(mirror\<cdot>r)\<cdot>(mirror\<cdot>l)"
lemma mirror_strict [simp]: "mirror\<cdot>\<bottom> = \<bottom>"
by fixrec_simp
fixrec
pick :: "'a tree \<rightarrow> 'a convex_pd"
where
pick_Leaf: "pick\<cdot>(Leaf\<cdot>a) = {a}\<natural>"
| pick_Node: "pick\<cdot>(Node\<cdot>l\<cdot>r) = pick\<cdot>l +\<natural> pick\<cdot>r"
lemma pick_strict [simp]: "pick\<cdot>\<bottom> = \<bottom>"
by fixrec_simp
lemma pick_mirror: "pick\<cdot>(mirror\<cdot>t) = pick\<cdot>t"
by (induct t) (simp_all add: convex_plus_ac)
fixrec tree1 :: "int lift tree"
where "tree1 = Node\<cdot>(Node\<cdot>(Leaf\<cdot>(Def 1))\<cdot>(Leaf\<cdot>(Def 2)))
\<cdot>(Node\<cdot>(Leaf\<cdot>(Def 3))\<cdot>(Leaf\<cdot>(Def 4)))"
fixrec tree2 :: "int lift tree"
where "tree2 = Node\<cdot>(Node\<cdot>(Leaf\<cdot>(Def 1))\<cdot>(Leaf\<cdot>(Def 2)))
\<cdot>(Node\<cdot>\<bottom>\<cdot>(Leaf\<cdot>(Def 4)))"
fixrec tree3 :: "int lift tree"
where "tree3 = Node\<cdot>(Node\<cdot>(Leaf\<cdot>(Def 1))\<cdot>tree3)
\<cdot>(Node\<cdot>(Leaf\<cdot>(Def 3))\<cdot>(Leaf\<cdot>(Def 4)))"
declare tree1.simps tree2.simps tree3.simps [simp del]
lemma pick_tree1:
"pick\<cdot>tree1 = {Def 1, Def 2, Def 3, Def 4}\<natural>"
apply (subst tree1.simps)
apply simp
apply (simp add: convex_plus_ac)
done
lemma pick_tree2:
"pick\<cdot>tree2 = {Def 1, Def 2, \<bottom>, Def 4}\<natural>"
apply (subst tree2.simps)
apply simp
apply (simp add: convex_plus_ac)
done
lemma pick_tree3:
"pick\<cdot>tree3 = {Def 1, \<bottom>, Def 3, Def 4}\<natural>"
apply (subst tree3.simps)
apply simp
apply (induct rule: tree3.induct)
apply simp
apply simp
apply (simp add: convex_plus_ac)
apply simp
apply (simp add: convex_plus_ac)
done
end