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proof-pile

	(* Title: Binary Search Trees, Isar-Style
	Author: Viktor Kuncak, MIT CSAIL, November 2003
	Maintainer: Larry Paulson <Larry.Paulson at cl.cam.ac.uk>
	License: LGPL
	*)

	section \<open>Isar-style Reasoning for Binary Tree Operations\<close>
	theory BinaryTree imports Main begin

	text \<open>We prove correctness of operations on
	binary search tree implementing a set.

	This document is LGPL.

	Author: Viktor Kuncak, MIT CSAIL, November 2003\<close>

	(============================================================)
	section \<open>Tree Definition\<close>
	(============================================================)

	datatype 'a Tree = Tip \| T "'a Tree" 'a "'a Tree"

	primrec
	setOf :: "'a Tree => 'a set"
	\<comment> \<open>set abstraction of a tree\<close>
	where
	"setOf Tip = {}"
	\| "setOf (T t1 x t2) = (setOf t1) Un (setOf t2) Un {x}"

	type_synonym
	\<comment> \<open>we require index to have an irreflexive total order <\<close>
	\<comment> \<open>apart from that, we do not rely on index being int\<close>
	index = int

	type_synonym \<comment> \<open>hash function type\<close>
	'a hash = "'a => index"

	definition eqs :: "'a hash => 'a => 'a set" where
	\<comment> \<open>equivalence class of elements with the same hash code\<close>
	"eqs h x == {y. h y = h x}"

	primrec
	sortedTree :: "'a hash => 'a Tree => bool"
	\<comment> \<open>check if a tree is sorted\<close>
	where
	"sortedTree h Tip = True"
	\| "sortedTree h (T t1 x t2) =
	(sortedTree h t1 &
	(\<forall>l \<in> setOf t1. h l < h x) &
	(\<forall>r \<in> setOf t2. h x < h r) &
	sortedTree h t2)"

	lemma sortLemmaL:
	"sortedTree h (T t1 x t2) ==> sortedTree h t1" by simp
	lemma sortLemmaR:
	"sortedTree h (T t1 x t2) ==> sortedTree h t2" by simp

	(============================================================)
	section \<open>Tree Lookup\<close>
	(============================================================)

	primrec
	tlookup :: "'a hash => index => 'a Tree => 'a option"
	where
	"tlookup h k Tip = None"
	\| "tlookup h k (T t1 x t2) =
	(if k < h x then tlookup h k t1
	else if h x < k then tlookup h k t2
	else Some x)"

	lemma tlookup_none:
	"sortedTree h t & (tlookup h k t = None) --> (\<forall>x\<in>setOf t. h x ~= k)"
	by (induct t, auto)

	lemma tlookup_some:
	"sortedTree h t & (tlookup h k t = Some x) --> x:setOf t & h x = k"
	apply (induct t)
	\<comment> \<open>Just auto will do it, but very slowly\<close>
	apply (simp)
	apply (clarify, auto)
	apply (simp_all split: if_split_asm)
	done

	definition sorted_distinct_pred :: "'a hash => 'a => 'a => 'a Tree => bool" where
	\<comment> \<open>No two elements have the same hash code\<close>
	"sorted_distinct_pred h a b t == sortedTree h t &
	a:setOf t & b:setOf t & h a = h b -->
	a = b"

	declare sorted_distinct_pred_def [simp]

	\<comment> \<open>for case analysis on three cases\<close>
	lemma cases3: "[\| C1 ==> G; C2 ==> G; C3 ==> G;
	C1 \| C2 \| C3 \|] ==> G"
	by auto

	text \<open>@{term sorted_distinct_pred} holds for out trees:\<close>

	lemma sorted_distinct: "sorted_distinct_pred h a b t" (is "?P t")
	proof (induct t)
	show "?P Tip" by simp
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof (unfold sorted_distinct_pred_def, safe)
	assume s: "sortedTree h (T t1 x t2)"
	assume adef: "a : setOf (T t1 x t2)"
	assume bdef: "b : setOf (T t1 x t2)"
	assume hahb: "h a = h b"
	from s have s1: "sortedTree h t1" by auto
	from s have s2: "sortedTree h t2" by auto
	show "a = b"
	\<comment> \<open>We consider 9 cases for the position of a and b are in the tree\<close>
	proof -
	\<comment> \<open>three cases for a\<close>
	from adef have "a : setOf t1 \| a = x \| a : setOf t2" by auto
	moreover { assume adef1: "a : setOf t1"
	have ?thesis
	proof -
	\<comment> \<open>three cases for b\<close>
	from bdef have "b : setOf t1 \| b = x \| b : setOf t2" by auto
	moreover { assume bdef1: "b : setOf t1"
	from s1 adef1 bdef1 hahb h1 have ?thesis by simp }
	moreover { assume bdef1: "b = x"
	from adef1 bdef1 s have "h a < h b" by auto
	from this hahb have ?thesis by simp }
	moreover { assume bdef1: "b : setOf t2"
	from adef1 s have o1: "h a < h x" by auto
	from bdef1 s have o2: "h x < h b" by auto
	from o1 o2 have "h a < h b" by simp
	from this hahb have ?thesis by simp } \<comment> \<open>case impossible\<close>
	ultimately show ?thesis by blast
	qed
	}
	moreover { assume adef1: "a = x"
	have ?thesis
	proof -
	\<comment> \<open>three cases for b\<close>
	from bdef have "b : setOf t1 \| b = x \| b : setOf t2" by auto
	moreover { assume bdef1: "b : setOf t1"
	from this s have "h b < h x" by auto
	from this adef1 have "h b < h a" by auto
	from hahb this have ?thesis by simp } \<comment> \<open>case impossible\<close>
	moreover { assume bdef1: "b = x"
	from adef1 bdef1 have ?thesis by simp }
	moreover { assume bdef1: "b : setOf t2"
	from this s have "h x < h b" by auto
	from this adef1 have "h a < h b" by simp
	from hahb this have ?thesis by simp } \<comment> \<open>case impossible\<close>
	ultimately show ?thesis by blast
	qed
	}
	moreover { assume adef1: "a : setOf t2"
	have ?thesis
	proof -
	\<comment> \<open>three cases for b\<close>
	from bdef have "b : setOf t1 \| b = x \| b : setOf t2" by auto
	moreover { assume bdef1: "b : setOf t1"
	from bdef1 s have o1: "h b < h x" by auto
	from adef1 s have o2: "h x < h a" by auto
	from o1 o2 have "h b < h a" by simp
	from this hahb have ?thesis by simp } \<comment> \<open>case impossible\<close>
	moreover { assume bdef1: "b = x"
	from adef1 bdef1 s have "h b < h a" by auto
	from this hahb have ?thesis by simp } \<comment> \<open>case impossible\<close>
	moreover { assume bdef1: "b : setOf t2"
	from s2 adef1 bdef1 hahb h2 have ?thesis by simp }
	ultimately show ?thesis by blast
	qed
	}
	ultimately show ?thesis by blast
	qed
	qed
	qed

	lemma tlookup_finds: \<comment> \<open>if a node is in the tree, lookup finds it\<close>
	"sortedTree h t & y:setOf t -->
	tlookup h (h y) t = Some y"
	proof safe
	assume s: "sortedTree h t"
	assume yint: "y : setOf t"
	show "tlookup h (h y) t = Some y"
	proof (cases "tlookup h (h y) t")
	case None note res = this
	from s res have "sortedTree h t & (tlookup h (h y) t = None)" by simp
	from this have o1: "\<forall>x\<in>setOf t. h x ~= h y" by (simp add: tlookup_none)
	from o1 yint have "h y ~= h y" by fastforce (* auto does not work *)
	from this show ?thesis by simp
	next case (Some z) note res = this
	have ls: "sortedTree h t & (tlookup h (h y) t = Some z) -->
	z:setOf t & h z = h y" by (simp add: tlookup_some)
	have sd: "sorted_distinct_pred h y z t"
	by (insert sorted_distinct [of h y z t], simp)
	(* for some reason simplifier would never guess this substitution *)
	from s res ls have o1: "z:setOf t & h z = h y" by simp
	from s yint o1 sd have "y = z" by auto
	from this res show "tlookup h (h y) t = Some y" by simp
	qed
	qed

	subsection \<open>Tree membership as a special case of lookup\<close>

	definition memb :: "'a hash => 'a => 'a Tree => bool" where
	"memb h x t ==
	(case (tlookup h (h x) t) of
	None => False
	\| Some z => (x=z))"

	lemma assumes s: "sortedTree h t"
	shows memb_spec: "memb h x t = (x : setOf t)"
	proof (cases "tlookup h (h x) t")
	case None note tNone = this
	from tNone have res: "memb h x t = False" by (simp add: memb_def)
	from s tNone tlookup_none have o1: "\<forall>y\<in>setOf t. h y ~= h x" by fastforce
	have notIn: "x ~: setOf t"
	proof
	assume h: "x : setOf t"
	from h o1 have "h x ~= h x" by fastforce
	from this show False by simp
	qed
	from res notIn show ?thesis by simp
	next case (Some z) note tSome = this
	from s tSome tlookup_some have zin: "z : setOf t" by fastforce
	show ?thesis
	proof (cases "x=z")
	case True note xez = this
	from tSome xez have res: "memb h x t" by (simp add: memb_def)
	from res zin xez show ?thesis by simp
	next case False note xnez = this
	from tSome xnez have res: "~ memb h x t" by (simp add: memb_def)
	have "x ~: setOf t"
	proof
	assume xin: "x : setOf t"
	from s tSome tlookup_some have hzhx: "h x = h z" by fastforce
	have o1: "sorted_distinct_pred h x z t"
	by (insert sorted_distinct [of h x z t], simp)
	from s xin zin hzhx o1 have "x = z" by fastforce
	from this xnez show False by simp
	qed
	from this res show ?thesis by simp
	qed
	qed

	declare sorted_distinct_pred_def [simp del]

	(============================================================)
	section \<open>Insertion into a Tree\<close>
	(============================================================)

	primrec
	binsert :: "'a hash => 'a => 'a Tree => 'a Tree"
	where
	"binsert h e Tip = (T Tip e Tip)"
	\| "binsert h e (T t1 x t2) = (if h e < h x then
	(T (binsert h e t1) x t2)
	else
	(if h x < h e then
	(T t1 x (binsert h e t2))
	else (T t1 e t2)))"

	text \<open>A technique for proving disjointness of sets.\<close>
	lemma disjCond: "[\| !! x. [\| x:A; x:B \|] ==> False \|] ==> A Int B = {}"
	by fastforce

	text \<open>The following is a proof that insertion correctly implements
	the set interface.
	Compared to \<open>BinaryTree_TacticStyle\<close>, the claim is more
	difficult, and this time we need to assume as a hypothesis
	that the tree is sorted.\<close>

	lemma binsert_set: "sortedTree h t -->
	setOf (binsert h e t) = (setOf t) - (eqs h e) Un {e}"
	(is "?P t")
	proof (induct t)
	\<comment> \<open>base case\<close>
	show "?P Tip" by (simp add: eqs_def)
	\<comment> \<open>inductition step\<close>
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof
	assume s: "sortedTree h (T t1 x t2)"
	from s have s1: "sortedTree h t1" by (rule sortLemmaL)
	from s1 and h1 have c1: "setOf (binsert h e t1) = setOf t1 - eqs h e Un {e}" by simp
	from s have s2: "sortedTree h t2" by (rule sortLemmaR)
	from s2 and h2 have c2: "setOf (binsert h e t2) = setOf t2 - eqs h e Un {e}" by simp
	show "setOf (binsert h e (T t1 x t2)) =
	setOf (T t1 x t2) - eqs h e Un {e}"
	proof (cases "h e < h x")
	case True note eLess = this
	from eLess have res: "binsert h e (T t1 x t2) = (T (binsert h e t1) x t2)" by simp
	show "setOf (binsert h e (T t1 x t2)) =
	setOf (T t1 x t2) - eqs h e Un {e}"
	proof (simp add: res eLess c1)
	show "insert x (insert e (setOf t1 - eqs h e Un setOf t2)) =
	insert e (insert x (setOf t1 Un setOf t2) - eqs h e)"
	proof -
	have eqsLessX: "\<forall>el \<in> eqs h e. h el < h x" by (simp add: eqs_def eLess)
	from this have eqsDisjX: "\<forall>el \<in> eqs h e. h el ~= h x" by fastforce
	from s have xLessT2: "\<forall>r \<in> setOf t2. h x < h r" by auto
	have eqsLessT2: "\<forall>el \<in> eqs h e. \<forall>r \<in> setOf t2. h el < h r"
	proof safe
	fix el assume hel: "el : eqs h e"
	from hel eqs_def have o1: "h el = h e" by fastforce (* auto fails here! *)
	fix r assume hr: "r : setOf t2"
	from xLessT2 hr o1 eLess show "h el < h r" by auto
	qed
	from eqsLessT2 have eqsDisjT2: "\<forall>el \<in> eqs h e. \<forall>r \<in> setOf t2. h el ~= h r"
	by fastforce (* auto fails here *)
	from eqsDisjX eqsDisjT2 show ?thesis by fastforce
	qed
	qed
	next case False note eNotLess = this
	show "setOf (binsert h e (T t1 x t2)) = setOf (T t1 x t2) - eqs h e Un {e}"
	proof (cases "h x < h e")
	case True note xLess = this
	from xLess have res: "binsert h e (T t1 x t2) = (T t1 x (binsert h e t2))" by simp
	show "setOf (binsert h e (T t1 x t2)) =
	setOf (T t1 x t2) - eqs h e Un {e}"
	proof (simp add: res xLess eNotLess c2)
	show "insert x (insert e (setOf t1 Un (setOf t2 - eqs h e))) =
	insert e (insert x (setOf t1 Un setOf t2) - eqs h e)"
	proof -
	have XLessEqs: "\<forall>el \<in> eqs h e. h x < h el" by (simp add: eqs_def xLess)
	from this have eqsDisjX: "\<forall>el \<in> eqs h e. h el ~= h x" by auto
	from s have t1LessX: "\<forall>l \<in> setOf t1. h l < h x" by auto
	have T1lessEqs: "\<forall>el \<in> eqs h e. \<forall>l \<in> setOf t1. h l < h el"
	proof safe
	fix el assume hel: "el : eqs h e"
	fix l assume hl: "l : setOf t1"
	from hel eqs_def have o1: "h el = h e" by fastforce (* auto fails here! *)
	from t1LessX hl o1 xLess show "h l < h el" by auto
	qed
	from T1lessEqs have T1disjEqs: "\<forall>el \<in> eqs h e. \<forall>l \<in> setOf t1. h el ~= h l"
	by fastforce
	from eqsDisjX T1lessEqs show ?thesis by auto
	qed
	qed
	next case False note xNotLess = this
	from xNotLess eNotLess have xeqe: "h x = h e" by simp
	from xeqe have res: "binsert h e (T t1 x t2) = (T t1 e t2)" by simp
	show "setOf (binsert h e (T t1 x t2)) =
	setOf (T t1 x t2) - eqs h e Un {e}"
	proof (simp add: res eNotLess xeqe)
	show "insert e (setOf t1 Un setOf t2) =
	insert e (insert x (setOf t1 Un setOf t2) - eqs h e)"
	proof -
	have "insert x (setOf t1 Un setOf t2) - eqs h e =
	setOf t1 Un setOf t2"
	proof -
	have (* o1: *) "x : eqs h e" by (simp add: eqs_def xeqe)
	moreover have (* o2: *) "(setOf t1) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix w
	assume whSet: "w : setOf t1"
	assume whEq: "w : eqs h e"
	from whSet s have o1: "h w < h x" by simp
	from whEq eqs_def have o2: "h w = h e" by fastforce
	from o2 xeqe have o3: "~ h w < h x" by simp
	from o1 o3 show False by contradiction
	qed
	moreover have (* o3: *) "(setOf t2) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix w
	assume whSet: "w : setOf t2"
	assume whEq: "w : eqs h e"
	from whSet s have o1: "h x < h w" by simp
	from whEq eqs_def have o2: "h w = h e" by fastforce
	from o2 xeqe have o3: "~ h x < h w" by simp
	from o1 o3 show False by contradiction
	qed
	ultimately show ?thesis by auto
	qed
	from this show ?thesis by simp
	qed
	qed
	qed
	qed
	qed
	qed

	text \<open>Using the correctness of set implementation,
	preserving sortedness is still simple.\<close>
	lemma binsert_sorted: "sortedTree h t --> sortedTree h (binsert h x t)"
	by (induct t) (auto simp add: binsert_set)

	text \<open>We summarize the specification of binsert as follows.\<close>
	corollary binsert_spec: "sortedTree h t -->
	sortedTree h (binsert h x t) &
	setOf (binsert h e t) = (setOf t) - (eqs h e) Un {e}"
	by (simp add: binsert_set binsert_sorted)

	(============================================================)
	section \<open>Removing an element from a tree\<close>
	(============================================================)

	text \<open>These proofs are influenced by those in \<open>BinaryTree_Tactic\<close>\<close>

	primrec
	rm :: "'a hash => 'a Tree => 'a"
	\<comment> \<open>rightmost element of a tree\<close>
	where
	"rm h (T t1 x t2) =
	(if t2=Tip then x else rm h t2)"

	primrec
	wrm :: "'a hash => 'a Tree => 'a Tree"
	\<comment> \<open>tree without the rightmost element\<close>
	where
	"wrm h (T t1 x t2) =
	(if t2=Tip then t1 else (T t1 x (wrm h t2)))"

	primrec
	wrmrm :: "'a hash => 'a Tree => 'a Tree * 'a"
	\<comment> \<open>computing rightmost and removal in one pass\<close>
	where
	"wrmrm h (T t1 x t2) =
	(if t2=Tip then (t1,x)
	else (T t1 x (fst (wrmrm h t2)),
	snd (wrmrm h t2)))"

	primrec
	remove :: "'a hash => 'a => 'a Tree => 'a Tree"
	\<comment> \<open>removal of an element from the tree\<close>
	where
	"remove h e Tip = Tip"
	\| "remove h e (T t1 x t2) =
	(if h e < h x then (T (remove h e t1) x t2)
	else if h x < h e then (T t1 x (remove h e t2))
	else (if t1=Tip then t2
	else let (t1p,r) = wrmrm h t1
	in (T t1p r t2)))"

	theorem wrmrm_decomp: "t ~= Tip --> wrmrm h t = (wrm h t, rm h t)"
	apply (induct_tac t)
	apply simp_all
	done

	lemma rm_set: "t ~= Tip & sortedTree h t --> rm h t : setOf t"
	apply (induct_tac t)
	apply simp_all
	done

	lemma wrm_set: "t ~= Tip & sortedTree h t -->
	setOf (wrm h t) = setOf t - {rm h t}" (is "?P t")
	proof (induct t)
	show "?P Tip" by simp
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof (rule impI, erule conjE)
	assume s: "sortedTree h (T t1 x t2)"
	show "setOf (wrm h (T t1 x t2)) =
	setOf (T t1 x t2) - {rm h (T t1 x t2)}"
	proof (cases "t2 = Tip")
	case True note t2tip = this
	from t2tip have rm_res: "rm h (T t1 x t2) = x" by simp
	from t2tip have wrm_res: "wrm h (T t1 x t2) = t1" by simp
	from s have "x ~: setOf t1" by auto
	from this rm_res wrm_res t2tip show ?thesis by simp
	next case False note t2nTip = this
	from t2nTip have rm_res: "rm h (T t1 x t2) = rm h t2" by simp
	from t2nTip have wrm_res: "wrm h (T t1 x t2) = T t1 x (wrm h t2)" by simp
	from s have s2: "sortedTree h t2" by simp
	from h2 t2nTip s2
	have o1: "setOf (wrm h t2) = setOf t2 - {rm h t2}" by simp
	show ?thesis
	proof (simp add: rm_res wrm_res t2nTip h2 o1)
	show "insert x (setOf t1 Un (setOf t2 - {rm h t2})) =
	insert x (setOf t1 Un setOf t2) - {rm h t2}"
	proof -
	from s rm_set t2nTip have xOk: "h x < h (rm h t2)" by auto
	have t1Ok: "\<forall>l \<in> setOf t1. h l < h (rm h t2)"
	proof safe
	fix l :: 'a assume ldef: "l : setOf t1"
	from ldef s have lx: "h l < h x" by auto
	from lx xOk show "h l < h (rm h t2)" by auto
	qed
	from xOk t1Ok show ?thesis by auto
	qed
	qed
	qed
	qed
	qed

	lemma wrm_set1: "t ~= Tip & sortedTree h t --> setOf (wrm h t) <= setOf t"
	by (auto simp add: wrm_set)

	lemma wrm_sort: "t ~= Tip & sortedTree h t --> sortedTree h (wrm h t)" (is "?P t")
	proof (induct t)
	show "?P Tip" by simp
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof safe
	assume s: "sortedTree h (T t1 x t2)"
	show "sortedTree h (wrm h (T t1 x t2))"
	proof (cases "t2 = Tip")
	case True note t2tip = this
	from t2tip have res: "wrm h (T t1 x t2) = t1" by simp
	from res s show ?thesis by simp
	next case False note t2nTip = this
	from t2nTip have res: "wrm h (T t1 x t2) = T t1 x (wrm h t2)" by simp
	from s have s1: "sortedTree h t1" by simp
	from s have s2: "sortedTree h t2" by simp
	from s2 h2 t2nTip have o1: "sortedTree h (wrm h t2)" by simp
	from s2 t2nTip wrm_set1 have o2: "setOf (wrm h t2) <= setOf t2" by auto
	from s o2 have o3: "\<forall>r \<in> setOf (wrm h t2). h x < h r" by auto
	from s1 o1 o3 res s show "sortedTree h (wrm h (T t1 x t2))" by simp
	qed
	qed
	qed

	lemma wrm_less_rm:
	"t ~= Tip & sortedTree h t -->
	(\<forall>l \<in> setOf (wrm h t). h l < h (rm h t))" (is "?P t")
	proof (induct t)
	show "?P Tip" by simp
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof safe
	fix l :: "'a" assume ldef: "l : setOf (wrm h (T t1 x t2))"
	assume s: "sortedTree h (T t1 x t2)"
	from s have s1: "sortedTree h t1" by simp
	from s have s2: "sortedTree h t2" by simp
	show "h l < h (rm h (T t1 x t2))"
	proof (cases "t2 = Tip")
	case True note t2tip = this
	from t2tip have rm_res: "rm h (T t1 x t2) = x" by simp
	from t2tip have wrm_res: "wrm h (T t1 x t2) = t1" by simp
	from ldef wrm_res have o1: "l : setOf t1" by simp
	from rm_res o1 s show ?thesis by simp
	next case False note t2nTip = this
	from t2nTip have rm_res: "rm h (T t1 x t2) = rm h t2" by simp
	from t2nTip have wrm_res: "wrm h (T t1 x t2) = T t1 x (wrm h t2)" by simp
	from ldef wrm_res
	have l_scope: "l : {x} Un setOf t1 Un setOf (wrm h t2)" by simp
	have hLess: "h l < h (rm h t2)"
	proof (cases "l = x")
	case True note lx = this
	from s t2nTip rm_set s2 have o1: "h x < h (rm h t2)" by auto
	from lx o1 show ?thesis by simp
	next case False note lnx = this
	show ?thesis
	proof (cases "l : setOf t1")
	case True note l_in_t1 = this
	from s t2nTip rm_set s2 have o1: "h x < h (rm h t2)" by auto
	from l_in_t1 s have o2: "h l < h x" by auto
	from o1 o2 show ?thesis by simp
	next case False note l_notin_t1 = this
	from l_scope lnx l_notin_t1
	have l_in_res: "l : setOf (wrm h t2)" by auto
	from l_in_res h2 t2nTip s2 show ?thesis by auto
	qed
	qed
	from rm_res hLess show ?thesis by simp
	qed
	qed
	qed

	lemma remove_set: "sortedTree h t -->
	setOf (remove h e t) = setOf t - eqs h e" (is "?P t")
	proof (induct t)
	show "?P Tip" by auto
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof
	assume s: "sortedTree h (T t1 x t2)"
	show "setOf (remove h e (T t1 x t2)) = setOf (T t1 x t2) - eqs h e"
	proof (cases "h e < h x")
	case True note elx = this
	from elx have res: "remove h e (T t1 x t2) = T (remove h e t1) x t2"
	by simp
	from s have s1: "sortedTree h t1" by simp
	from s1 h1 have o1: "setOf (remove h e t1) = setOf t1 - eqs h e" by simp
	show ?thesis
	proof (simp add: o1 elx)
	show "insert x (setOf t1 - eqs h e Un setOf t2) =
	insert x (setOf t1 Un setOf t2) - eqs h e"
	proof -
	have xOk: "x ~: eqs h e"
	proof
	assume h: "x : eqs h e"
	from h have o1: "~ (h e < h x)" by (simp add: eqs_def)
	from elx o1 show "False" by contradiction
	qed
	have t2Ok: "(setOf t2) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix y :: 'a
	assume y_in_t2: "y : setOf t2"
	assume y_in_eq: "y : eqs h e"
	from y_in_t2 s have xly: "h x < h y" by auto
	from y_in_eq have eey: "h y = h e" by (simp add: eqs_def) (* must "add:" not "from" *)
	from xly eey have nelx: "~ (h e < h x)" by simp
	from nelx elx show False by contradiction
	qed
	from xOk t2Ok show ?thesis by auto
	qed
	qed
	next case False note nelx = this
	show ?thesis
	proof (cases "h x < h e")
	case True note xle = this
	from xle have res: "remove h e (T t1 x t2) = T t1 x (remove h e t2)" by simp
	from s have s2: "sortedTree h t2" by simp
	from s2 h2 have o1: "setOf (remove h e t2) = setOf t2 - eqs h e" by simp
	show ?thesis
	proof (simp add: o1 xle nelx)
	show "insert x (setOf t1 Un (setOf t2 - eqs h e)) =
	insert x (setOf t1 Un setOf t2) - eqs h e"
	proof -
	have xOk: "x ~: eqs h e"
	proof
	assume h: "x : eqs h e"
	from h have o1: "~ (h x < h e)" by (simp add: eqs_def)
	from xle o1 show "False" by contradiction
	qed
	have t1Ok: "(setOf t1) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix y :: 'a
	assume y_in_t1: "y : setOf t1"
	assume y_in_eq: "y : eqs h e"
	from y_in_t1 s have ylx: "h y < h x" by auto
	from y_in_eq have eey: "h y = h e" by (simp add: eqs_def)
	from ylx eey have nxle: "~ (h x < h e)" by simp
	from nxle xle show False by contradiction
	qed
	from xOk t1Ok show ?thesis by auto
	qed
	qed
	next case False note nxle = this
	from nelx nxle have ex: "h e = h x" by simp
	have t2Ok: "(setOf t2) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix y :: 'a
	assume y_in_t2: "y : setOf t2"
	assume y_in_eq: "y : eqs h e"
	from y_in_t2 s have xly: "h x < h y" by auto
	from y_in_eq have eey: "h y = h e" by (simp add: eqs_def)
	from y_in_eq ex eey have nxly: "~ (h x < h y)" by simp
	from nxly xly show False by contradiction
	qed
	show ?thesis
	proof (cases "t1 = Tip")
	case True note t1tip = this
	from ex t1tip have res: "remove h e (T t1 x t2) = t2" by simp
	show ?thesis
	proof (simp add: res t1tip ex)
	show "setOf t2 = insert x (setOf t2) - eqs h e"
	proof -
	from ex have x_in_eqs: "x : eqs h e" by (simp add: eqs_def)
	from x_in_eqs t2Ok show ?thesis by auto
	qed
	qed
	next case False note t1nTip = this
	from nelx nxle ex t1nTip
	have res: "remove h e (T t1 x t2) =
	T (wrm h t1) (rm h t1) t2"
	by (simp add: Let_def wrmrm_decomp)
	from res show ?thesis
	proof simp
	from s have s1: "sortedTree h t1" by simp
	show "insert (rm h t1) (setOf (wrm h t1) Un setOf t2) =
	insert x (setOf t1 Un setOf t2) - eqs h e"
	proof (simp add: t1nTip s1 rm_set wrm_set)
	show "insert (rm h t1) (setOf t1 - {rm h t1} Un setOf t2) =
	insert x (setOf t1 Un setOf t2) - eqs h e"
	proof -
	from t1nTip s1 rm_set
	have o1: "insert (rm h t1) (setOf t1 - {rm h t1} Un setOf t2) =
	setOf t1 Un setOf t2" by auto
	have o2: "insert x (setOf t1 Un setOf t2) - eqs h e =
	setOf t1 Un setOf t2"
	proof -
	from ex have xOk: "x : eqs h e" by (simp add: eqs_def)
	have t1Ok: "(setOf t1) Int (eqs h e) = {}"
	proof (rule disjCond)
	fix y :: 'a
	assume y_in_t1: "y : setOf t1"
	assume y_in_eq: "y : eqs h e"
	from y_in_t1 s ex have o1: "h y < h e" by auto
	from y_in_eq have o2: "~ (h y < h e)" by (simp add: eqs_def)
	from o1 o2 show False by contradiction
	qed
	from xOk t1Ok t2Ok show ?thesis by auto
	qed
	from o1 o2 show ?thesis by simp
	qed
	qed
	qed
	qed
	qed
	qed
	qed
	qed

	lemma remove_sort: "sortedTree h t -->
	sortedTree h (remove h e t)" (is "?P t")
	proof (induct t)
	show "?P Tip" by auto
	fix t1 :: "'a Tree" assume h1: "?P t1"
	fix t2 :: "'a Tree" assume h2: "?P t2"
	fix x :: 'a
	show "?P (T t1 x t2)"
	proof
	assume s: "sortedTree h (T t1 x t2)"
	from s have s1: "sortedTree h t1" by simp
	from s have s2: "sortedTree h t2" by simp
	from h1 s1 have sr1: "sortedTree h (remove h e t1)" by simp
	from h2 s2 have sr2: "sortedTree h (remove h e t2)" by simp
	show "sortedTree h (remove h e (T t1 x t2))"
	proof (cases "h e < h x")
	case True note elx = this
	from elx have res: "remove h e (T t1 x t2) = T (remove h e t1) x t2"
	by simp
	show ?thesis
	proof (simp add: s sr1 s2 elx res)
	let ?C1 = "\<forall>l \<in> setOf (remove h e t1). h l < h x"
	let ?C2 = "\<forall>r \<in> setOf t2. h x < h r"
	have o1: "?C1"
	proof -
	from s1 have "setOf (remove h e t1) = setOf t1 - eqs h e" by (simp add: remove_set)
	from s this show ?thesis by auto
	qed
	from o1 s show "?C1 & ?C2" by auto
	qed
	next case False note nelx = this
	show ?thesis
	proof (cases "h x < h e")
	case True note xle = this
	from xle have res: "remove h e (T t1 x t2) = T t1 x (remove h e t2)" by simp
	show ?thesis
	proof (simp add: s s1 sr2 xle nelx res)
	let ?C1 = "\<forall>l \<in> setOf t1. h l < h x"
	let ?C2 = "\<forall>r \<in> setOf (remove h e t2). h x < h r"
	have o2: "?C2"
	proof -
	from s2 have "setOf (remove h e t2) = setOf t2 - eqs h e" by (simp add: remove_set)
	from s this show ?thesis by auto
	qed
	from o2 s show "?C1 & ?C2" by auto
	qed
	next case False note nxle = this
	from nelx nxle have ex: "h e = h x" by simp
	show ?thesis
	proof (cases "t1 = Tip")
	case True note t1tip = this
	from ex t1tip have res: "remove h e (T t1 x t2) = t2" by simp
	show ?thesis by (simp add: res t1tip ex s2)
	next case False note t1nTip = this
	from nelx nxle ex t1nTip
	have res: "remove h e (T t1 x t2) =
	T (wrm h t1) (rm h t1) t2"
	by (simp add: Let_def wrmrm_decomp)
	from res show ?thesis
	proof simp
	let ?C1 = "sortedTree h (wrm h t1)"
	let ?C2 = "\<forall>l \<in> setOf (wrm h t1). h l < h (rm h t1)"
	let ?C3 = "\<forall>r \<in> setOf t2. h (rm h t1) < h r"
	let ?C4 = "sortedTree h t2"
	from s1 t1nTip have o1: ?C1 by (simp add: wrm_sort)
	from s1 t1nTip have o2: ?C2 by (simp add: wrm_less_rm)
	have o3: ?C3
	proof
	fix r :: 'a
	assume rt2: "r : setOf t2"
	from s rm_set s1 t1nTip have o1: "h (rm h t1) < h x" by auto
	from rt2 s have o2: "h x < h r" by auto
	from o1 o2 show "h (rm h t1) < h r" by simp
	qed
	from o1 o2 o3 s2 show "?C1 & ?C2 & ?C3 & ?C4" by simp
	qed
	qed
	qed
	qed
	qed
	qed

	text \<open>We summarize the specification of remove as follows.\<close>
	corollary remove_spec: "sortedTree h t -->
	sortedTree h (remove h e t) &
	setOf (remove h e t) = setOf t - eqs h e"
	by (simp add: remove_sort remove_set)

	definition "test = tlookup id 4 (remove id 3 (binsert id 4 (binsert id 3 Tip)))"

	export_code test
	in SML module_name BinaryTree_Code file \<open>BinaryTree_Code.ML\<close>

	end