Partition List
Source
- leetcode: Partition List | LeetCode OJ
- lintcode: (96) Partition List
Problem
Given a linked list and a value x, partition it such that all nodes less than x come before nodes greater than or equal to x.
You should preserve the original relative order of the nodes in each of the two partitions.
For example,
Given 1->4->3->2->5->2
and x = 3,
return 1->2->2->4->3->5
.
题解
此题出自 CTCI 题 2.4,依据题意,是要根据值x对链表进行分割操作,具体是指将所有小于x的节点放到不小于x的节点之前,咋一看和快速排序的分割有些类似,但是这个题的不同之处在于只要求将小于x的节点放到前面,而并不要求对元素进行排序。
这种分割的题使用两路指针即可轻松解决。左边指针指向小于x的节点,右边指针指向不小于x的节点。由于左右头节点不确定,我们可以使用两个dummy节点。
Python
"""
Definition of ListNode
class ListNode(object):
def __init__(self, val, next=None):
self.val = val
self.next = next
"""
class Solution:
"""
@param head: The first node of linked list.
@param x: an integer
@return: a ListNode
"""
def partition(self, head, x):
if head is None:
return None
leftDummy = ListNode(0)
left = leftDummy
rightDummy = ListNode(0)
right = rightDummy
node = head
while node is not None:
if node.val < x:
left.next = node
left = left.next
else:
right.next = node
right = right.next
node = node.next
# post-processing
right.next = None
left.next = rightDummy.next
return leftDummy.next
C++
/**
* Definition for singly-linked list.
* struct ListNode {
* int val;
* ListNode *next;
* ListNode(int x) : val(x), next(NULL) {}
* };
*/
class Solution {
public:
ListNode* partition(ListNode* head, int x) {
if (head == NULL) return NULL;
ListNode *leftDummy = new ListNode(0);
ListNode *left = leftDummy;
ListNode *rightDummy = new ListNode(0);
ListNode *right = rightDummy;
ListNode *node = head;
while (node != NULL) {
if (node->val < x) {
left->next = node;
left = left->next;
} else {
right->next = node;
right = right->next;
}
node = node->next;
}
// post-processing
right->next = NULL;
left->next = rightDummy->next;
return leftDummy->next;
}
};
Java
/**
* Definition for singly-linked list.
* public class ListNode {
* int val;
* ListNode next;
* ListNode(int x) { val = x; }
* }
*/
public class Solution {
public ListNode partition(ListNode head, int x) {
ListNode leftDummy = new ListNode(0);
ListNode leftCurr = leftDummy;
ListNode rightDummy = new ListNode(0);
ListNode rightCurr = rightDummy;
ListNode runner = head;
while (runner != null) {
if (runner.val < x) {
leftCurr.next = runner;
leftCurr = leftCurr.next;
} else {
rightCurr.next = runner;
rightCurr = rightCurr.next;
}
runner = runner.next;
}
// cut off ListNode after rightCurr to avoid cylic
rightCurr.next = null;
leftCurr.next = rightDummy.next;
return leftDummy.next;
}
}
源码分析
- 异常处理
- 引入左右两个dummy节点及left和right左右尾指针
- 遍历原链表
- 处理右链表,置
right->next
为空(否则如果不为尾节点则会报错,处理链表时 以 null 为判断),将右链表的头部链接到左链表尾指针的next,返回左链表的头部
复杂度分析
遍历链表一次,时间复杂度近似为 , 使用了两个 dummy 节点及中间变量,空间复杂度近似为 .