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(* Author: Tobias Nipkow *)


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section \<open>Leftist Heap\<close>


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theory Leftist_Heap


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imports Tree2 "~~/src/HOL/Library/Multiset" Complex_Main


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begin


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fun mset_tree :: "('a,'b) tree \<Rightarrow> 'a multiset" where


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"mset_tree Leaf = {#}" 


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"mset_tree (Node _ l a r) = {#a#} + mset_tree l + mset_tree r"


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type_synonym 'a lheap = "('a,nat)tree"


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fun rank :: "'a lheap \<Rightarrow> nat" where


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"rank Leaf = 0" 


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"rank (Node _ _ _ r) = rank r + 1"


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fun rk :: "'a lheap \<Rightarrow> nat" where


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"rk Leaf = 0" 


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"rk (Node n _ _ _) = n"


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text{* The invariants: *}


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fun (in linorder) heap :: "('a,'b) tree \<Rightarrow> bool" where


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"heap Leaf = True" 


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"heap (Node _ l m r) =


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(heap l \<and> heap r \<and> (\<forall>x \<in> set_mset(mset_tree l + mset_tree r). m \<le> x))"

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fun lheap :: "'a lheap \<Rightarrow> bool" where


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"lheap Leaf = True" 


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"lheap (Node n l a r) =


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(n = rank r + 1 \<and> rank l \<ge> rank r \<and> lheap l & lheap r)"


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definition node :: "'a lheap \<Rightarrow> 'a \<Rightarrow> 'a lheap \<Rightarrow> 'a lheap" where


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"node l a r =


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(let rl = rk l; rr = rk r


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in if rl \<ge> rr then Node (rr+1) l a r else Node (rl+1) r a l)"


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fun get_min :: "'a lheap \<Rightarrow> 'a" where


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"get_min(Node n l a r) = a"


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function meld :: "'a::ord lheap \<Rightarrow> 'a lheap \<Rightarrow> 'a lheap" where


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"meld Leaf t2 = t2" 


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"meld t1 Leaf = t1" 


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"meld (Node n1 l1 a1 r1) (Node n2 l2 a2 r2) =


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(if a1 \<le> a2 then node l1 a1 (meld r1 (Node n2 l2 a2 r2))


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else node l2 a2 (meld r2 (Node n1 l1 a1 r1)))"


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by pat_completeness auto


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termination by (relation "measure (%(t1,t2). rank t1 + rank t2)") auto


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lemma meld_code: "meld t1 t2 = (case (t1,t2) of


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(Leaf, _) \<Rightarrow> t2 


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(_, Leaf) \<Rightarrow> t1 


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(Node n1 l1 a1 r1, Node n2 l2 a2 r2) \<Rightarrow>


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if a1 \<le> a2 then node l1 a1 (meld r1 t2) else node l2 a2 (meld r2 t1))"


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by(induction t1 t2 rule: meld.induct) (simp_all split: tree.split)


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definition insert :: "'a::ord \<Rightarrow> 'a lheap \<Rightarrow> 'a lheap" where


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"insert x t = meld (Node 1 Leaf x Leaf) t"


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fun del_min :: "'a::ord lheap \<Rightarrow> 'a lheap" where


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"del_min Leaf = Leaf" 


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"del_min (Node n l x r) = meld l r"


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subsection "Lemmas"


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declare Let_def [simp]


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lemma rk_eq_rank[simp]: "lheap t \<Longrightarrow> rk t = rank t"


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by(cases t) auto


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lemma lheap_node: "lheap (node l a r) \<longleftrightarrow> lheap l \<and> lheap r"


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by(auto simp add: node_def)


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lemma heap_node: "heap (node l a r) \<longleftrightarrow>


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heap l \<and> heap r \<and> (\<forall>x \<in> set_mset(mset_tree l + mset_tree r). a \<le> x)"


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by(auto simp add: node_def)


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subsection "Functional Correctness"


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locale Priority_Queue =


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fixes empty :: "'pq"

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and insert :: "'a::linorder \<Rightarrow> 'pq \<Rightarrow> 'pq"

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and get_min :: "'pq \<Rightarrow> 'a"


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and del_min :: "'pq \<Rightarrow> 'pq"


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and invar :: "'pq \<Rightarrow> bool"


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and mset :: "'pq \<Rightarrow> 'a multiset"


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assumes mset_empty: "mset empty = {#}"

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and mset_insert: "invar pq \<Longrightarrow> mset (insert x pq) = mset pq + {#x#}"

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and mset_del_min: "invar pq \<Longrightarrow> mset (del_min pq) = mset pq  {#get_min pq#}"

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and get_min: "invar pq \<Longrightarrow> pq \<noteq> empty \<Longrightarrow>


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get_min pq \<in> set_mset(mset pq) \<and> (\<forall>x \<in># mset pq. get_min pq \<le> x)"

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and invar_insert: "invar pq \<Longrightarrow> invar (insert x pq)"


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and invar_del_min: "invar pq \<Longrightarrow> invar (del_min pq)"


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lemma mset_meld: "mset_tree (meld h1 h2) = mset_tree h1 + mset_tree h2"


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by (induction h1 h2 rule: meld.induct) (auto simp add: node_def ac_simps)


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lemma mset_insert: "mset_tree (insert x t) = mset_tree t + {#x#}"

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by (auto simp add: insert_def mset_meld)


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lemma get_min:


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"heap h \<Longrightarrow> h \<noteq> Leaf \<Longrightarrow>


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get_min h \<in> set_mset(mset_tree h) \<and> (\<forall>x \<in># mset_tree h. get_min h \<le> x)"


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by (induction h) (auto)


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lemma mset_del_min: "mset_tree (del_min h) = mset_tree h  {# get_min h #}"

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by (cases h) (auto simp: mset_meld)

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lemma lheap_meld: "\<lbrakk> lheap l; lheap r \<rbrakk> \<Longrightarrow> lheap (meld l r)"


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proof(induction l r rule: meld.induct)


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case (3 n1 l1 a1 r1 n2 l2 a2 r2)


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show ?case (is "lheap(meld ?t1 ?t2)")


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proof cases


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assume "a1 \<le> a2"


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hence "lheap (meld ?t1 ?t2) = lheap (node l1 a1 (meld r1 ?t2))" by simp


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also have "\<dots> = (lheap l1 \<and> lheap(meld r1 ?t2))"


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by(simp add: lheap_node)


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also have "..." using "3.prems" "3.IH"(1)[OF `a1 \<le> a2`] by (simp)


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finally show ?thesis .


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next (* analogous but automatic *)


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assume "\<not> a1 \<le> a2"


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thus ?thesis using 3 by(simp)(auto simp: lheap_node)


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qed


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qed simp_all


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lemma heap_meld: "\<lbrakk> heap l; heap r \<rbrakk> \<Longrightarrow> heap (meld l r)"


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proof(induction l r rule: meld.induct)


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case 3 thus ?case by(auto simp: heap_node mset_meld ball_Un)


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qed simp_all


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lemma lheap_insert: "lheap t \<Longrightarrow> lheap(insert x t)"


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by(simp add: insert_def lheap_meld del: meld.simps split: tree.split)


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lemma heap_insert: "heap t \<Longrightarrow> heap(insert x t)"


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by(simp add: insert_def heap_meld del: meld.simps split: tree.split)


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lemma lheap_del_min: "lheap t \<Longrightarrow> lheap(del_min t)"


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by(cases t)(auto simp add: lheap_meld simp del: meld.simps)


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lemma heap_del_min: "heap t \<Longrightarrow> heap(del_min t)"


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by(cases t)(auto simp add: heap_meld simp del: meld.simps)


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interpretation lheap: Priority_Queue


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where empty = Leaf and insert = insert and del_min = del_min

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and get_min = get_min and invar = "\<lambda>h. heap h \<and> lheap h"


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and mset = mset_tree

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proof(standard, goal_cases)


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case 1 show ?case by simp


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next


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case 2 show ?case by(rule mset_insert)


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next


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case 3 show ?case by(rule mset_del_min)


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next

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case 4 thus ?case by(simp add: get_min)

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next

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case 5 thus ?case by(simp add: heap_insert lheap_insert)


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next


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case 6 thus ?case by(simp add: heap_del_min lheap_del_min)

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qed


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subsection "Complexity"


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lemma pow2_rank_size1: "lheap t \<Longrightarrow> 2 ^ rank t \<le> size1 t"


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proof(induction t)


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case Leaf show ?case by simp


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next


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case (Node n l a r)


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hence "rank r \<le> rank l" by simp


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hence *: "(2::nat) ^ rank r \<le> 2 ^ rank l" by simp


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have "(2::nat) ^ rank \<langle>n, l, a, r\<rangle> = 2 ^ rank r + 2 ^ rank r"


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by(simp add: mult_2)


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also have "\<dots> \<le> size1 l + size1 r"


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using Node * by (simp del: power_increasing_iff)


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also have "\<dots> = size1 \<langle>n, l, a, r\<rangle>" by simp


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finally show ?case .


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qed


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function t_meld :: "'a::ord lheap \<Rightarrow> 'a lheap \<Rightarrow> nat" where


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"t_meld Leaf t2 = 1" 


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"t_meld t2 Leaf = 1" 


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"t_meld (Node n1 l1 a1 r1) (Node n2 l2 a2 r2) =


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(if a1 \<le> a2 then 1 + t_meld r1 (Node n2 l2 a2 r2)


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else 1 + t_meld r2 (Node n1 l1 a1 r1))"


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by pat_completeness auto


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termination by (relation "measure (%(t1,t2). rank t1 + rank t2)") auto


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definition t_insert :: "'a::ord \<Rightarrow> 'a lheap \<Rightarrow> nat" where


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"t_insert x t = t_meld (Node 1 Leaf x Leaf) t"


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fun t_del_min :: "'a::ord lheap \<Rightarrow> nat" where


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"t_del_min Leaf = 1" 


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"t_del_min (Node n l a r) = t_meld l r"


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lemma t_meld_rank: "t_meld l r \<le> rank l + rank r + 1"


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proof(induction l r rule: meld.induct)


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case 3 thus ?case


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by(simp)(fastforce split: tree.splits simp del: t_meld.simps)


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qed simp_all


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corollary t_meld_log: assumes "lheap l" "lheap r"


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shows "t_meld l r \<le> log 2 (size1 l) + log 2 (size1 r) + 1"


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using le_log2_of_power[OF pow2_rank_size1[OF assms(1)]]


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le_log2_of_power[OF pow2_rank_size1[OF assms(2)]] t_meld_rank[of l r]


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by linarith


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corollary t_insert_log: "lheap t \<Longrightarrow> t_insert x t \<le> log 2 (size1 t) + 2"


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using t_meld_log[of "Node 1 Leaf x Leaf" t]


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by(simp add: t_insert_def split: tree.split)


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lemma ld_ld_1_less:


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assumes "x > 0" "y > 0" shows "1 + log 2 x + log 2 y < 2 * log 2 (x+y)"


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proof 


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have 1: "2*x*y < (x+y)^2" using assms


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by(simp add: numeral_eq_Suc algebra_simps add_pos_pos)


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show ?thesis


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apply(rule powr_less_cancel_iff[of 2, THEN iffD1])


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apply simp


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using assms 1 by(simp add: powr_add log_powr[symmetric] powr_numeral)


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qed


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corollary t_del_min_log: assumes "lheap t"


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shows "t_del_min t \<le> 2 * log 2 (size1 t) + 1"


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proof(cases t)


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case Leaf thus ?thesis using assms by simp


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next


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case [simp]: (Node _ t1 _ t2)


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have "t_del_min t = t_meld t1 t2" by simp


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also have "\<dots> \<le> log 2 (size1 t1) + log 2 (size1 t2) + 1"


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using \<open>lheap t\<close> by (auto simp: t_meld_log simp del: t_meld.simps)


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also have "\<dots> \<le> 2 * log 2 (size1 t) + 1"


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using ld_ld_1_less[of "size1 t1" "size1 t2"] by (simp)


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finally show ?thesis .


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qed


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end
