树

一.树

1.树是有n个结点的集合，仅有一个根结点，有若干子结点

2.结点拥有的子树数称为结点的度；树的度是树内各结点的度的最大值

3.叶节点（终端节点）：度为0的结点；树中还有双亲结点，孩子结点，兄弟结点，子孙结点，祖先结点

4.结点的层数从根开始定义，根为第一层；树中结点的最大层次称为树的深度（高度）

5.森林是互不相交的树的结合

6.树中：结点总数=所有节点度数+1

二.二叉树

1.二叉树：每个结点至多只有两颗子树（即二叉树中不存在度大于2的结点），子树有左右之分，次序不能颠倒

2.性质：

（1）树的结点编号一般是按先序遍历（先根遍历）（一层一层编号）

（2）在二叉树的第 i 层至多有 2^i-1 个结点（i>=1）

（3）高度为 k 的二叉树至多有 2^k-1 个结点

（4）若叶子结点有 n₀ 个，度为 2 的结点有 n₂ 个，则  n₀ = n₂ +1

（5）一般来说，对于第 i 个结点，它的父亲结点为第 [i/2] 个结点，它左孩子为第 2i 个结点，它的右孩子为第 2i+1 个结点

3.满二叉树：树中每层必须满，共有 2^k-1 个结点

4.完全二叉树：（满二叉树砍掉一些树）每个结点都有与其对应的满二叉树中编号为1...n的结点一一对应

（1）具有 n 个结点的完全二叉树的高度为 [log₂n]+1

（2）度为1的结点至多为1

5.平衡二叉树（AVL）：树中任一结点的左子树和右子树深度之差不超过1

三.二叉搜索树(二叉排序树)（和快速排序非常相似的算法）

1.二叉搜索树：对于任何结点，它的左子树所有结点关键字 <= 该结点关键字 <= 它的右子树所有结点关键字

2.对于一棵二叉搜索树，通过中序遍历（子树根结点关键字位于左子树关键字和右子树关键字之间），可以按序输出所有关键字

class Node:
    def __init__(self, key, right, left, p):
        '''节点（关键字，左孩子，右孩子，父节点）'''
        self.key = key
        self.right = right
        self.left = left
        self.p = p

class Binary_search_tree:
    '''二叉搜索树'''
    def __init__(self, root):
        '''以根节点初始化一棵树'''
        self.root = root
    def tree_insert(self, z):
        '''在树中插入节点'''
        y = None
        x = self.root
        while x != None:
            y = x
            if z.key < x.key:
                x = x.left
            else:
                x = x.right
        z.p = y
        if y == None:
            self.root = z
        elif z.key < y.key:
            y.left = z
        else:
            y.right = z

    def inorder_tree_walk(self, x):
        '''中序遍历'''
        if x != None:
            self.inorder_tree_walk(x.left)
            print(x.key)
            self.inorder_tree_walk(x.right)

root=Node(6,None,None,None)
tree=Binary_search_tree(root)
List=[5,2,5,7,8]
for i in List:
    node=Node(i,None,None,None)
    tree.tree_insert(node)
print(tree)
print(tree.inorder_tree_walk(tree.root))
-------------------------------------------------------
<__main__.Binary_search_tree object at 0x032B7890>
2
5
5
6
7
8
None

3.查询二叉搜索树

def tree_search(tree, x, k):
    '''查找一个具有给定关键字的节点，x表示指向树根的指针'''
    if x == None or k == x.key:
        return x
    if k < x.key:
        return tree_search(tree,x.left, k)
    else:
        return tree_search(tree,x.right, k)

def iterative_tree_search(tree, x, k):
    '''迭代的树的搜索'''
    while x != None and k != x.key:
        if k < x.key:
            x = x.left
        else:
            x = x.right
    return x

def tree_minimum(tree, x):
    '''最小关键字元素，最左边的节点'''
    while x.left != None:
        x = x.left
    return x

def tree_maximum(tree, x):
    '''最大关键字元素，最右边的节点'''
    while x.right != None:
        x = x.right
    return x

def tree_successor(tree, x):
    '''树的前继'''
    if x.right != None:
        return tree_minimum(tree,x.right)
    y = x.p
    while y != None and x == y.right:
        x = y
        y = y.p
    return y

root=Node(15,None,None,None)
tree=Binary_search_tree(root)
List=[6,18,3,7,17,20,2,4,13,9]
for i in List:
    node=Node(i,None,None,None)
    tree.tree_insert(node)
print(tree)
print(tree_search(tree, root, 13).key)
print(tree_maximum(tree,root).key)
print(tree_minimum(tree,root).key)
print(tree_successor(tree,tree_search(tree, root, 13)).key)
---------------------------------------------------------------------
<__main__.Binary_search_tree object at 0x0391B530>
13
20
2
15

4.插入和删除节点

def tree_delete(tree, z):
    '''树的删除节点，分情况讨论'''
    if z.left == None:
        #1.z没有左孩子节点，用右孩子来替代他
        transplant(tree,z, z.right)
    elif z.right == None:
        #2.若z没有右孩子，用他的左孩子来替代他
        transplant(tree,z, z.left)
    else:
        #如果有两个孩子，在z的右子树中找他的后继（最小关键字），并让y替代z的位置
        y = tree_minimum(tree,z.right)
        if y.p != z:
            #若y不是z的左孩子，用y右孩子替换y并成为y的双亲的一个孩子，再将z的右孩子转换为y的右孩子
            transplant(tree,y, y.right)
            y.right = z.right
            y.right.p = y
        #用y替换z并成为z的双亲的一个孩子，再用z的左孩子替换为y的左孩子
        transplant(tree,z, y)
        y.left = z.left
        y.left.p = y

def transplant(tree, u, v):
    '''删除u后，树的替代，以一棵v为根的子树来替换一棵u为根的子树
    结果：u的双亲变为v的双亲，v成为u的双亲的相应孩子'''
    if u.p == None:
        #1.若u是根节点，直接初始化一个v为根节点的树
        tree.root = v
    elif u == u.p.left:
        #2.若u是他父节点的左孩子，更新他父节点的左孩子为v
        u.p.left = v
    else:
        #3.若u是他父节点的右孩子，更新他父节点的右孩子为v
        u.p.right = v
    if v != None:
        #如果v不为空，u的父节点变为v的父节点
        v.p = u.p

root=Node(15,None,None,None)
tree=Binary_search_tree(root)
List=[6,18,3,7,17,20,2,4,13,9]
for i in List:
    node=Node(i,None,None,None)
    tree.tree_insert(node)

print(tree.inorder_tree_walk(tree.root))
print('#'*30)
tree_delete(tree,tree_search(tree, root, 13))
print(tree.inorder_tree_walk(tree.root))
------------------------------------------------------------------------
2
3
4
6
7
9
13
15
17
18
20
None
##############################
2
3
4
6
7
9
15
17
18
20
None

5.随机构建二叉搜索树（参考随机化快速排序）

六.红黑树

1.红黑树是一种确保拥有对数阶O（lg n）高度的二叉搜索树

2.红黑树任何路径只能是红黑红的间隔或连续的黑色，不可能是连续红红

3.黑高：从某个结点出发（不含该结点）到达一个叶结点的的任意一条简单路径上的黑色结点个数，称为该结点的黑高

 4.

5.旋转

 

class Node:
    def __init__(self, key, right, left, p, color):
        self.key = key
        self.right = right
        self.left = left
        self.p = p
        self.color = color

class RB_tree:
    '''红黑树'''
    def __init__(self, root, nil):
        self.root = root
        self.nil = nil

    def tree_insert(self, z):
        '''树的插入'''
        y = self.nil
        x = self.root
        while x != self.nil:
            y = x
            if z.key < x.key:
                x = x.left
            else:
                x = x.right
        z.p = y
        if y == self.nil:
            self.root = z
        elif z.key < y.key:
            y.left = z
        else:
            y.right = z
        z.left = self.nil
        z.right = self.nil
        z.color = "RED"
        self.rb_insert_fixup(z)

    def left_rotate(self, x):
        '''左旋：y是x的右孩子，y变为x和y原来右子树的父节点，x变为x原来左子树和y左子树的父节点'''
        y = x.right
        x.right = y.left
        if y.left != self.nil:
            y.left.p = x
        y.p = x.p
        if x.p == self.nil:
            self.root = y
        elif x == x.p.left:
            x.p.left = y
        else:
            x.p.right = y
        y.left = x
        x.p = y

    def right_rotate(self, y):
        '''右旋：x是y的左孩子，x为x原左孩子和y的父节点，y为x原右孩子和y右孩子的父节点'''
        x = y.left
        y.left = x.right
        if x.right != self.nil:
            x.right.p = y
        x.p = y.p
        if y.p == self.nil:
            self.root = x
        elif y == y.p.left:
            y.p.left = x
        else:
            y.p.right = x
        x.right = y
        y.p = x

    def rb_insert_fixup(self, z):
        while z.p.color == "RED":
            if z.p == z.p.p.left:
                y = z.p.p.right
                if y.color == "RED":
                    z.p.color = "BLACK"
                    y.color = "BLACK"
                    z.p.p.color = "RED"
                    z = z.p.p
                else:
                    if z == z.p.right:
                        z = z.p
                        self.left_rotate(z)
                    z.p.color = "BLACK"
                    z.p.p.color = "RED"
                    self.right_rotate(z.p.p)
            else:
                y = z.p.p.left
                if y.color == "RED":
                    z.p.color = "BLACK"
                    y.color = "BLACK"
                    z.p.p.color = "RED"
                    z = z.p.p
                else:
                    if z == z.p.left:
                        z = z.p
                        self.right_rotate(z)
                    z.p.color = "BLACK"
                    z.p.p.color = "RED"
                    self.left_rotate(z.p.p)
        self.root.color = "BLACK"

    def inorder_tree_walk(self, x):
        if x != self.nil:
            self.inorder_tree_walk(x.left)
            print(x.key)
            self.inorder_tree_walk(x.right)

    def tree_search(self, x, k):
        if x == self.nil or k == x.key:
            return x
        if k < x.key:
            return self.tree_search(x.left, k)
        else:
            return self.tree_search(x.right, k)


nil=Node(0,None,None,None,"BLACK")#哨兵节点，黑色
root=Node(7,nil,nil,nil,"BLACK")#根节点，黑色
t=RB_tree(root,nil)
T=[4,18,3,6,11,19,2,9,14,22,12,17,20]
for i in T:
    z=Node(i,None,None,None,"RED")
    t.tree_insert(z)
TT=[7,4,18,3,6,11,19,2,9,14,22,12,17,20]
for i in TT:
    zz=t.tree_search(t.root,i)
    print(i,' ',zz.color)
-------------------------------------------
7   BLACK
4   BLACK
18   BLACK
3   BLACK
6   BLACK
11   RED
19   RED
2   RED
9   BLACK
14   BLACK
22   RED
12   RED
17   RED
20   BLACK

删除

 

    def rb_transplant(self, u, v):
        if u.p == self.nil:
            self.root = v
        elif u == u.p.left:
            u.p.left = v
        else:
            u.p.right = v
        v.p = u.p

    def tree_minimum(self, x):
        while x.left != self.nil:
            x = x.left
        return x

    def rb_delete(self, z):
        y = z
        y_original_color = y.color
        if z.left == self.nil:
            x = z.right
            self.rb_transplant(z, z.right)
        elif z.right == self.nil:
            x = z.left
            self.rb_transplant(z, z.left)
        else:
            y = self.tree_minimum(z.right)
            y_original_color = y.color
            x = y.right
            if y.p == z:
                x.p = y
            else:
                self.rb_transplant(y, y.right)
                y.right = z.right
                y.right.p = y
            self.rb_transplant(z, y)
            y.left = z.left
            y.left.p = y
            y.color = z.color
            if y_original_color == "BLACK":
                self.rb_delete_fixup(x)

    def rb_delete_fixup(self, x):
        while x != self.root and x.color == "BLACK":
            if x == x.p.left:
                w = x.p.right
                if w.color == "RED":
                    w.color = "BLACK"
                    x.p.color = "RED"
                    self.left_rotate(x.p)
                    w = x.p.right
                if w.left.color == "BLACK" and w.right.color == "BLACK":
                    w.color = "RED"
                    x = x.p
                else:
                    if w.right.color == "BLACK":
                        w.left.color == "BLACK"
                        w.color = "RED"
                        self.right_rotate(w)
                        w = x.p.right
                    w.color = x.p.color
                    x.p.color = "BLACK"
                    w.right.color = "BLACK"
                    self.left_rotate(x.p)
                    x = self.root
            else:
                w = x.p.left
                if w.color == "RED":
                    w.color = "BLACK"
                    x.p.color = "RED"
                    self.right_rotate(x.p)
                    w = x.p.left
                if w.right.color == "BLACK" and w.left.color == "BLACK":
                    w.color = "RED"
                    x = x.p
                else:
                    if w.left.color == "BLACK":
                        w.right.color == "BLACK"
                        w.color = "RED"
                        self.left_rotate(w)
                        w = x.p.left
                    w.color = x.p.color
                    x.p.color = "BLACK"
                    w.left.color = "BLACK"
                    self.right_rotate(x.p)
                    x = self.root
        x.color = "BLACK"