--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/src/HOL/Data_Structures/Balance.thy Fri Sep 09 14:15:16 2016 +0200
@@ -0,0 +1,151 @@
+(* Author: Tobias Nipkow *)
+
+section \<open>Creating Balanced Trees\<close>
+
+theory Balance
+imports
+ "~~/src/HOL/Library/Tree"
+ "~~/src/HOL/Library/Log_Nat"
+begin
+
+fun bal :: "'a list \<Rightarrow> nat \<Rightarrow> 'a tree * 'a list" where
+"bal xs n = (if n=0 then (Leaf,xs) else
+ (let m = n div 2;
+ (l, ys) = bal xs m;
+ (r, zs) = bal (tl ys) (n-1-m)
+ in (Node l (hd ys) r, zs)))"
+
+declare bal.simps[simp del]
+
+definition balance_list :: "'a list \<Rightarrow> 'a tree" where
+"balance_list xs = fst (bal xs (length xs))"
+
+definition balance_tree :: "'a tree \<Rightarrow> 'a tree" where
+"balance_tree = balance_list o inorder"
+
+
+lemma bal_inorder:
+ "\<lbrakk> bal xs n = (t,ys); n \<le> length xs \<rbrakk>
+ \<Longrightarrow> inorder t = take n xs \<and> ys = drop n xs"
+proof(induction xs n arbitrary: t ys rule: bal.induct)
+ case (1 xs n) show ?case
+ proof cases
+ assume "n = 0" thus ?thesis using 1 by (simp add: bal.simps)
+ next
+ assume [arith]: "n \<noteq> 0"
+ let ?n1 = "n div 2" let ?n2 = "n - 1 - ?n1"
+ from "1.prems" obtain l r xs' where
+ b1: "bal xs ?n1 = (l,xs')" and
+ b2: "bal (tl xs') ?n2 = (r,ys)" and
+ t: "t = \<langle>l, hd xs', r\<rangle>"
+ using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
+ have IH1: "inorder l = take ?n1 xs \<and> xs' = drop ?n1 xs"
+ using b1 "1.prems" by(intro "1.IH"(1)) auto
+ have IH2: "inorder r = take ?n2 (tl xs') \<and> ys = drop ?n2 (tl xs')"
+ using b1 b2 IH1 "1.prems" by(intro "1.IH"(2)) auto
+ have "drop (n div 2) xs \<noteq> []" using "1.prems"(2) by simp
+ hence "hd (drop ?n1 xs) # take ?n2 (tl (drop ?n1 xs)) = take (?n2 + 1) (drop ?n1 xs)"
+ by (metis Suc_eq_plus1 take_Suc)
+ hence *: "inorder t = take n xs" using t IH1 IH2
+ using take_add[of ?n1 "?n2+1" xs] by(simp)
+ have "n - n div 2 + n div 2 = n" by simp
+ hence "ys = drop n xs" using IH1 IH2 by (simp add: drop_Suc[symmetric])
+ thus ?thesis using * by blast
+ qed
+qed
+
+corollary inorder_balance_list: "inorder(balance_list xs) = xs"
+using bal_inorder[of xs "length xs"]
+by (metis balance_list_def order_refl prod.collapse take_all)
+
+lemma bal_height: "bal xs n = (t,ys) \<Longrightarrow> height t = floorlog 2 n"
+proof(induction xs n arbitrary: t ys rule: bal.induct)
+ case (1 xs n) show ?case
+ proof cases
+ assume "n = 0" thus ?thesis
+ using "1.prems" by (simp add: floorlog_def bal.simps)
+ next
+ assume [arith]: "n \<noteq> 0"
+ from "1.prems" obtain l r xs' where
+ b1: "bal xs (n div 2) = (l,xs')" and
+ b2: "bal (tl xs') (n - 1 - n div 2) = (r,ys)" and
+ t: "t = \<langle>l, hd xs', r\<rangle>"
+ using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
+ let ?log1 = "floorlog 2 (n div 2)"
+ let ?log2 = "floorlog 2 (n - 1 - n div 2)"
+ have IH1: "height l = ?log1" using "1.IH"(1) b1 by simp
+ have IH2: "height r = ?log2" using "1.IH"(2) b1 b2 by simp
+ have "n div 2 \<ge> n - 1 - n div 2" by arith
+ hence le: "?log2 \<le> ?log1" by(simp add:floorlog_mono)
+ have "height t = max ?log1 ?log2 + 1" by (simp add: t IH1 IH2)
+ also have "\<dots> = ?log1 + 1" using le by (simp add: max_absorb1)
+ also have "\<dots> = floorlog 2 n" by (simp add: compute_floorlog)
+ finally show ?thesis .
+ qed
+qed
+
+lemma bal_min_height:
+ "bal xs n = (t,ys) \<Longrightarrow> min_height t = floorlog 2 (n + 1) - 1"
+proof(induction xs n arbitrary: t ys rule: bal.induct)
+ case (1 xs n) show ?case
+ proof cases
+ assume "n = 0" thus ?thesis
+ using "1.prems" by (simp add: floorlog_def bal.simps)
+ next
+ assume [arith]: "n \<noteq> 0"
+ from "1.prems" obtain l r xs' where
+ b1: "bal xs (n div 2) = (l,xs')" and
+ b2: "bal (tl xs') (n - 1 - n div 2) = (r,ys)" and
+ t: "t = \<langle>l, hd xs', r\<rangle>"
+ using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
+ let ?log1 = "floorlog 2 (n div 2 + 1) - 1"
+ let ?log2 = "floorlog 2 (n - 1 - n div 2 + 1) - 1"
+ let ?log2' = "floorlog 2 (n - n div 2) - 1"
+ have "n - 1 - n div 2 + 1 = n - n div 2" by arith
+ hence IH2: "min_height r = ?log2'" using "1.IH"(2) b1 b2 by simp
+ have IH1: "min_height l = ?log1" using "1.IH"(1) b1 by simp
+ have *: "floorlog 2 (n - n div 2) \<ge> 1" by (simp add: floorlog_def)
+ have "n div 2 + 1 \<ge> n - n div 2" by arith
+ with * have le: "?log2' \<le> ?log1" by(simp add: floorlog_mono diff_le_mono)
+ have "min_height t = min ?log1 ?log2' + 1" by (simp add: t IH1 IH2)
+ also have "\<dots> = ?log2' + 1" using le by (simp add: min_absorb2)
+ also have "\<dots> = floorlog 2 (n - n div 2)" by(simp add: floorlog_def)
+ also have "n - n div 2 = (n+1) div 2" by arith
+ also have "floorlog 2 \<dots> = floorlog 2 (n+1) - 1"
+ by (simp add: compute_floorlog)
+ finally show ?thesis .
+ qed
+qed
+
+lemma balanced_bal:
+ assumes "bal xs n = (t,ys)" shows "balanced t"
+proof -
+ have "floorlog 2 n \<le> floorlog 2 (n+1)" by (rule floorlog_mono) auto
+ thus ?thesis unfolding balanced_def
+ using bal_height[OF assms] bal_min_height[OF assms] by linarith
+qed
+
+corollary size_balance_list[simp]: "size(balance_list xs) = length xs"
+by (metis inorder_balance_list length_inorder)
+
+corollary balanced_balance_list[simp]: "balanced (balance_list xs)"
+by (metis balance_list_def balanced_bal prod.collapse)
+
+lemma height_balance_list: "height(balance_list xs) = floorlog 2 (length xs)"
+by (metis bal_height balance_list_def prod.collapse)
+
+lemma inorder_balance_tree[simp]: "inorder(balance_tree t) = inorder t"
+by(simp add: balance_tree_def inorder_balance_list)
+
+lemma size_balance_tree[simp]: "size(balance_tree t) = size t"
+by(simp add: balance_tree_def inorder_balance_list)
+
+corollary balanced_balance_tree[simp]: "balanced (balance_tree t)"
+by (simp add: balance_tree_def)
+
+lemma height_balance_tree: "height(balance_tree t) = floorlog 2 (size t)"
+by(simp add: balance_tree_def height_balance_list)
+
+hide_const (open) bal
+
+end
--- a/src/HOL/Data_Structures/Balance_List.thy Fri Sep 09 13:39:21 2016 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,126 +0,0 @@
-(* Tobias Nipkow *)
-
-section \<open>Creating a Balanced Tree from a List\<close>
-
-theory Balance_List
-imports
- "~~/src/HOL/Library/Tree"
- "~~/src/HOL/Library/Log_Nat"
-begin
-
-fun bal :: "'a list \<Rightarrow> nat \<Rightarrow> 'a tree * 'a list" where
-"bal xs n = (if n=0 then (Leaf,xs) else
- (let m = n div 2;
- (l, ys) = bal xs m;
- (r, zs) = bal (tl ys) (n-1-m)
- in (Node l (hd ys) r, zs)))"
-
-declare bal.simps[simp del]
-
-definition "balance xs = fst (bal xs (length xs))"
-
-lemma bal_inorder:
- "\<lbrakk> bal xs n = (t,ys); n \<le> length xs \<rbrakk>
- \<Longrightarrow> inorder t = take n xs \<and> ys = drop n xs"
-proof(induction xs n arbitrary: t ys rule: bal.induct)
- case (1 xs n) show ?case
- proof cases
- assume "n = 0" thus ?thesis using 1 by (simp add: bal.simps)
- next
- assume [arith]: "n \<noteq> 0"
- let ?n1 = "n div 2" let ?n2 = "n - 1 - ?n1"
- from "1.prems" obtain l r xs' where
- b1: "bal xs ?n1 = (l,xs')" and
- b2: "bal (tl xs') ?n2 = (r,ys)" and
- t: "t = \<langle>l, hd xs', r\<rangle>"
- using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
- have IH1: "inorder l = take ?n1 xs \<and> xs' = drop ?n1 xs"
- using b1 "1.prems" by(intro "1.IH"(1)) auto
- have IH2: "inorder r = take ?n2 (tl xs') \<and> ys = drop ?n2 (tl xs')"
- using b1 b2 IH1 "1.prems" by(intro "1.IH"(2)) auto
- have "drop (n div 2) xs \<noteq> []" using "1.prems"(2) by simp
- hence "hd (drop ?n1 xs) # take ?n2 (tl (drop ?n1 xs)) = take (?n2 + 1) (drop ?n1 xs)"
- by (metis Suc_eq_plus1 take_Suc)
- hence *: "inorder t = take n xs" using t IH1 IH2
- using take_add[of ?n1 "?n2+1" xs] by(simp)
- have "n - n div 2 + n div 2 = n" by simp
- hence "ys = drop n xs" using IH1 IH2 by (simp add: drop_Suc[symmetric])
- thus ?thesis using * by blast
- qed
-qed
-
-corollary balance_inorder: "inorder(balance xs) = xs"
-using bal_inorder[of xs "length xs"]
-by (metis balance_def order_refl prod.collapse take_all)
-
-lemma bal_height: "bal xs n = (t,ys) \<Longrightarrow> height t = floorlog 2 n"
-proof(induction xs n arbitrary: t ys rule: bal.induct)
- case (1 xs n) show ?case
- proof cases
- assume "n = 0" thus ?thesis
- using "1.prems" by (simp add: floorlog_def bal.simps)
- next
- assume [arith]: "n \<noteq> 0"
- from "1.prems" obtain l r xs' where
- b1: "bal xs (n div 2) = (l,xs')" and
- b2: "bal (tl xs') (n - 1 - n div 2) = (r,ys)" and
- t: "t = \<langle>l, hd xs', r\<rangle>"
- using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
- let ?log1 = "floorlog 2 (n div 2)"
- let ?log2 = "floorlog 2 (n - 1 - n div 2)"
- have IH1: "height l = ?log1" using "1.IH"(1) b1 by simp
- have IH2: "height r = ?log2" using "1.IH"(2) b1 b2 by simp
- have "n div 2 \<ge> n - 1 - n div 2" by arith
- hence le: "?log2 \<le> ?log1" by(simp add:floorlog_mono)
- have "height t = max ?log1 ?log2 + 1" by (simp add: t IH1 IH2)
- also have "\<dots> = ?log1 + 1" using le by (simp add: max_absorb1)
- also have "\<dots> = floorlog 2 n" by (simp add: compute_floorlog)
- finally show ?thesis .
- qed
-qed
-
-lemma bal_min_height:
- "bal xs n = (t,ys) \<Longrightarrow> min_height t = floorlog 2 (n + 1) - 1"
-proof(induction xs n arbitrary: t ys rule: bal.induct)
- case (1 xs n) show ?case
- proof cases
- assume "n = 0" thus ?thesis
- using "1.prems" by (simp add: floorlog_def bal.simps)
- next
- assume [arith]: "n \<noteq> 0"
- from "1.prems" obtain l r xs' where
- b1: "bal xs (n div 2) = (l,xs')" and
- b2: "bal (tl xs') (n - 1 - n div 2) = (r,ys)" and
- t: "t = \<langle>l, hd xs', r\<rangle>"
- using bal.simps[of xs n] by(auto simp: Let_def split: prod.splits)
- let ?log1 = "floorlog 2 (n div 2 + 1) - 1"
- let ?log2 = "floorlog 2 (n - 1 - n div 2 + 1) - 1"
- let ?log2' = "floorlog 2 (n - n div 2) - 1"
- have "n - 1 - n div 2 + 1 = n - n div 2" by arith
- hence IH2: "min_height r = ?log2'" using "1.IH"(2) b1 b2 by simp
- have IH1: "min_height l = ?log1" using "1.IH"(1) b1 by simp
- have *: "floorlog 2 (n - n div 2) \<ge> 1" by (simp add: floorlog_def)
- have "n div 2 + 1 \<ge> n - n div 2" by arith
- with * have le: "?log2' \<le> ?log1" by(simp add: floorlog_mono diff_le_mono)
- have "min_height t = min ?log1 ?log2' + 1" by (simp add: t IH1 IH2)
- also have "\<dots> = ?log2' + 1" using le by (simp add: min_absorb2)
- also have "\<dots> = floorlog 2 (n - n div 2)" by(simp add: floorlog_def)
- also have "n - n div 2 = (n+1) div 2" by arith
- also have "floorlog 2 \<dots> = floorlog 2 (n+1) - 1"
- by (simp add: compute_floorlog)
- finally show ?thesis .
- qed
-qed
-
-lemma balanced_bal:
- assumes "bal xs n = (t,ys)" shows "balanced t"
-proof -
- have "floorlog 2 n \<le> floorlog 2 (n+1)" by (rule floorlog_mono) auto
- thus ?thesis
- using bal_height[OF assms] bal_min_height[OF assms] by arith
-qed
-
-corollary balanced_balance: "balanced (balance xs)"
-by (metis balance_def balanced_bal prod.collapse)
-
-end
--- a/src/HOL/Library/Tree.thy Fri Sep 09 13:39:21 2016 +0200
+++ b/src/HOL/Library/Tree.thy Fri Sep 09 14:15:16 2016 +0200
@@ -230,7 +230,8 @@
subsection \<open>Balanced\<close>
-abbreviation "balanced t \<equiv> (height t - min_height t \<le> 1)"
+definition balanced :: "'a tree \<Rightarrow> bool" where
+"balanced t = (height t - min_height t \<le> 1)"
text\<open>Balanced trees have optimal height:\<close>
@@ -262,7 +263,7 @@
hence *: "min_height t < height t'" by simp
have "min_height t + 1 = height t"
using min_hight_le_height[of t] assms(1) False
- by (simp add: complete_iff_height)
+ by (simp add: complete_iff_height balanced_def)
with * show ?thesis by arith
qed
--- a/src/HOL/ROOT Fri Sep 09 13:39:21 2016 +0200
+++ b/src/HOL/ROOT Fri Sep 09 14:15:16 2016 +0200
@@ -183,7 +183,7 @@
"~~/src/HOL/Library/Multiset"
"~~/src/HOL/Library/Float"
theories
- Balance_List
+ Balance
Tree_Map
AVL_Map
RBT_Map