python实现跳表SkipList的示例代码_Python

跳表

跳表，又叫做跳跃表、跳跃列表，在有序链表的基础上增加了“跳跃”的功能，由william pugh于1990年发布，设计的初衷是为了取代平衡树（比如红黑树）。
redis、leveldb 都是著名的 key-value 数据库，而redis中的 sortedset、leveldb 中的 memtable 都用到了跳表。
对比平衡树，跳表的实现和维护会更加简单，跳表的搜索、删除、添加的平均时间复杂度是 o(logn)。
跳表的结构如图所示：

python实现跳表SkipList的示例代码

可以发现，对于一个节点node，其含有多个next指针，不同索引的next分别代表不同层次的下一个节点，下次是节点类node的python定义：

				?

									class node():

									     def __init__(self,key,value,level):

									         '''

									         :param level:每个node对应的nexts层数不同

									         '''

									         self.key=key

									         self.value=value

									         self.nexts=[none]*level#节点类型next指针，初始值为空

									     def __str__(self):

									         #return "[key:"+str(self.key)+", value:"+str(self.value)+" len:"+str(len(self.nexts))+"]"

									         return "["+str(self.key)+","+str(self.value)+","+str(len(self.nexts))+"]"

关于添加、删除、查找见一下完整代码：

				?

									'''

									跳表 skip list ，其初衷是为了替代红黑树

									'''

									import random

									import mkl_random

									import time

									class skiplist():

									    def __init__(self):

									        #头节点不存储任何数据

									        self.max_level = 32  # 最大level层数

									        self.__first=skiplist.node(none, none, self.max_level)#头节点

									        self.__level=0#实际的level层数

									        self.__size=0#jiedian个数

									        self.__p=0.25#用于生成添加节点时的随机level

									        return

									    class node():

									        def __init__(self,key,value,level):

									            '''

									            :param level:每个node对应的nexts层数不同

									            '''

									            self.key=key

									            self.value=value

									            self.nexts=[none]*level

									        def __str__(self):

									            #return "[key:"+str(self.key)+", value:"+str(self.value)+" len:"+str(len(self.nexts))+"]"

									            return "["+str(self.key)+","+str(self.value)+","+str(len(self.nexts))+"]"

									    def get(self,key):

									        '''

									        :param key:

									        :return: key对应的value

									        '''

									        self.keycheck(key)

									        node=self.__first

									        for level in range(self.__level - 1,-1,-1):

									            #在该层查找，key大于节点的key向前查找

									            while node.nexts[level] and node.nexts[level].key<key:

									                node=node.nexts[level]

									            if node.nexts[level] and node.nexts[level].key==key:#相等则找到，否则向下寻找

									                return node.nexts[level].value

									        return none

									    def put(self,key,value):

									        '''

									        return:原来的value，原来不存在key则为空

									        '''

									        self.keycheck(key)

									        prev=[none]*self.__level

									        node=self.__first

									        for i in range(self.__level - 1, -1, -1):

									            while node.nexts[i] and node.nexts[i].key<key:

									                node=node.nexts[i]

									            if node.nexts[i] and node.nexts[i].key==key:

									                oldvalue=node.nexts[i].value

									                node.nexts[i].value=value

									                return oldvalue

									            prev[i]=node#保存当前level小于key的node

									        newlevel=self.randomlevel()

									        newnode=skiplist.node(key,value,newlevel)

									        for i in range(newlevel):

									            if i<self.__level:

									                newnode.nexts[i]=prev[i].nexts[i]

									                prev[i].nexts[i]=newnode

									            else:

									                self.__first.nexts[i]=newnode

									        self.__size+=1

									        self.__level=max(self.__level, newlevel)

									        return none

									    def remove(self,key):

									        '''

									        :return: 节点对应的value值，不存在则返回none

									        '''

									        self.keycheck(key)

									        prev=[none]*self.__level

									        node=self.__first

									        flag=false#该节点是否被查找到

									        for i in range(self.__level - 1, -1, -1):

									            while node.nexts[i] and node.nexts[i].key<key:

									                node=node.nexts[i]

									            if node.nexts[i].key==key:

									                flag=true

									            prev[i]=node

									        if not flag:

									            return none

									        removednode=node.nexts[0]#需要被删除的节点

									        for i in range(len(removednode.nexts)):#该nexts一定小于等于prev的长度

									            prev[i].next[i]=removednode.nexts[i]

									        self.__size-=1

									        newlevel=self.__level

									        while newlevel>0 and not self.__first.nexts[newlevel - 1]:

									            newlevel-=1

									        self.__level=newlevel

									        return removednode.value

									    def keycheck(self, key):

									        '''

									        限制传入key不能为空

									        '''

									        if key!=0 and not key:

									            raise attributeerror("key can not be none")

									    def size(self):

									        return self.__size

									    def isempty(self):

									        return self.__size == 0

									    def randomlevel(self):#生成一个随机的层数

									        level=1

									        while mkl_random.rand()<self.__p and level<self.max_level:

									            level+=1

									        return level

									    def __str__(self):

									        result=""

									        for i in range(self.__level - 1, -1, -1):

									            result+=str(i)

									            node = self.__first

									            while node.nexts[i]:

									                result+=str(node.nexts[i])

									                node=node.nexts[i]

									            result+='\n'

									        print("level:"+str(self.__level))

									        return result

									    def showfirst(self):

									        for item in self.__first.nexts:

									            print(item,end=' ')

									        print()

									def timecalculate(container, size:int):

									    begin=time.time()

									    for i in range(size):

									        if isinstance(container,dict):

									            container[i]= i * 3

									        else:

									            container.put(i, i * 3)

									    error_count = 0

									    for i in range(size):

									        if container.get(i) != i * 3:

									            #print("wrong " + str(i) + ":" + str(skiplist.get(i)))

									            error_count+=1

									    end=time.time()

									    print(type(container))

									    print(f'error rate:{float(error_count) / size:0.5f}')

									    print(f'time cost:{float(end-begin)*1000:0.3f} ms')

									if __name__=='__main__':

									    timecalculate({},1000000)

									    timecalculate(skiplist(),10000)