标签:循环链表 class 链表是否有环 append data 数据结构与算法 连续 false 依次
循环链表
当要处理的数据具有环形结构的时候, 适合循环链表. 如约瑟夫环问题
双向循环链表
数组的缺点是大小固定, 一旦声明长度就要占用连续的内存空间, 当空间不够用时更换更大的空间, 此时就需要将原数组的所有数据迁移过去, 比较费时. 链表则可以动态扩容.
数组在查询上可以更快, 链表在插入和删除上更快, 为了结合数组和链表的优点, 有同时使用的情况, 比如一个网站的用户注册, 可以以A-Z
为数组, 在每个字母后面加入链表, 这样可以在添加新用户的时候能快速找到要添加的链表并进行插入, 同时在查询用户的时候也能缩短查询时间
"""
单链表
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
class SingleLinkedList(object):
def __init__(self):
self.head = None
def is_empty(self):
return self.head == None
def size(self):
current = self.head
num = 0
while current != None:
current = current.next_
num += 1
return num
def prepend(self, value):
"""
在头部添加节点
:param value:
:return:
"""
self.head = Node(value, self.head)
def append(self, value):
"""
在尾部追加节点
:param value:
:return:
"""
node = Node(value)
if self.is_empty():
self.head = node
else:
current = self.head
while current.next_ != None:
current = current.next_
current.next_ = node
def insert(self, position, value):
"""
指定位置插入节点, 从1开始计数
:param position:
:param value:
:return:
"""
if position <= 1:
self.prepend(value)
elif position > self.size():
self.append(value)
else:
node = Node(value)
tmp_pos = 1
pre_node = None
current = self.head
while tmp_pos < position:
pre_node = current
current = current.next_
tmp_pos += 1
node.next_ = current
pre_node.next_ = node
def delete(self, value):
if self.is_empty():
raise Exception("empty")
pre_node = None
current = self.head
while current != None:
if current.data == value:
# 判断删除的元素是不是第一个
if not pre_node:
self.head = current.next_
else:
pre_node.next_ = current.next_
break
else:
pre_node = current
current = current.next_
def pop_first(self):
if self.is_empty():
raise Exception("empty")
data = self.head.data
self.head = self.head.next_
return data
def pop_last(self):
if self.is_empty():
raise Exception("empty")
pre_node = None
current = self.head
while current.next_ != None:
pre_node = current
current = current.next_
data = current.data
if pre_node == None:
self.head = None
else:
pre_node.next = None
return data
def find(self, value):
status = False
current = self.head
while current != None and not status:
if current.data == value:
status = True
else:
current = current.next_
return status
# coding:utf-8
"""
单链表反转
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
def reverse(linked_list):
head = linked_list
pre = None
while head != None:
current = head
head = current.next_
current.next_ = pre
pre = current
return pre
def output(linked_list):
current = linked_list
res = []
while current != None:
res.append(current.data)
current = current.next_
print(res)
if __name__ == '__main__':
link = Node(1, Node(2, Node(3, Node(4, Node(5, Node(6, Node(7, Node(8, Node(9)))))))))
output(link)
root = reverse(link)
output(root)
"""
[1, 2, 3, 4, 5, 6, 7, 8, 9]
[9, 8, 7, 6, 5, 4, 3, 2, 1]
"""
# coding:utf-8
"""
链表成对调换
1 -> 2 -> 3 -> 4
调换后为
2 -> 1 -> 4 -> 3
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
def swap(head):
if head != None and head.next_ != None:
after = head.next_
head.next_ = swap(after.next_)
after.next_ = head
return after
return head
def output(linked_list):
current = linked_list
res = []
while current != None:
res.append(current.data)
current = current.next_
print(res)
if __name__ == '__main__':
link = Node(1, Node(2, Node(3, Node(4))))
output(link)
print('----')
link1 = swap(link)
output(link1)
"""
[1, 2, 3, 4]
----
[2, 1, 4, 3]
"""
sub_size
sub_size
步定义两个游标first和later, first步长是1, later步长是2. 同时向前走, 如果有环一定会遇到. 复杂度O(n)
# -*- coding:utf-8 -*-
"""
判断链表是否有环
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
def check(head):
current1 = current2 = head
while True:
current1 = current1.next_ # 指向第一个节点
current2 = current2.next_.next_ # 指向第二个节点
if (not current1) or (not current2):
break
if current1.data == current2.data:
return True
return False
if __name__ == '__main__':
node1 = Node(6)
node2 = Node(2)
node3 = Node(3)
node4 = Node(4)
node5 = Node(5)
node6 = Node(6)
node1.next_ = node2
node2.next_ = node3
node3.next_ = node4
node4.next_ = node5
node5.next_ = node6
node6.next_ = node3 # 环交点
assert check(node1) == True
定义两个指针first, later都初始化指向头节点, 然后first先走k步, 再同时走, 当first到尾节点的时候, 读出later节点的值. 复杂度是O(n)
# -*- coding:utf-8 -*-
"""
找到链表的倒数第K个元素
定义两个游标, 第二个游标先走k-1步, 之后再同时走, 此时第一个游标停留位置就是倒数第K个元素
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
def find_reverse_k(head, k):
c1 = head
current = head
for _ in range(k - 1):
current = current.next_
c2 = current
while c2.next_ != None:
c2 = c2.next_
c1 = c1.next_
return c1.data
if __name__ == '__main__':
link = Node(1, Node(2, Node(3, Node(4, Node(5, Node(6, Node(7, Node(8, Node(9)))))))))
assert find_reverse_k(link, 3) == 7
assert find_reverse_k(link, 1) == 9
assert find_reverse_k(link, 2) == 8
# coding:utf-8
"""
合并两个有序单链表
输入:1->2->4, 1->3->4
输出:1->1->2->3->4->4
"""
class Node(object):
def __init__(self, data, next_=None):
self.data = data
self.next_ = next_
def merge2linkedlist(l1, l2):
"""
合并两个有序链表
:param l1:
:param l2:
:return:
"""
if l1 == None and l2 == None:
raise Exception("None!!!")
if l1 == None:
return l2
if l2 == None:
return l1
# 使用head为辅助节点
head = Node(0)
current = head
while l1 and l2:
if l1.data <= l2.data:
current.next_ = l1
l1 = l1.next_
elif l1.data > l2.data:
current.next_ = l2
l2 = l2.next_
current = current.next_
if l1:
current.next_ = l1
if l2:
current.next_ = l2
return head.next_
if __name__ == "__main__":
l1 = Node(1, Node(2, Node(4)))
l2 = Node(1, Node(3, Node(4)))
tmp = merge2linkedlist(l1, l2)
res = []
while tmp:
res.append(tmp.data)
tmp = tmp.next_
print(res)
"""
[1, 1, 2, 3, 4, 4]
"""
我们说空间复杂度的时候, 是指除了原本的数据存储空间外, 算法还需要的额外的存储空间, 即不管原来所占空间是多少
标签:循环链表 class 链表是否有环 append data 数据结构与算法 连续 false 依次
原文地址:https://www.cnblogs.com/zlone/p/10993902.html