nginx源码剖析数据结构篇(二) 双向链表ngx_queue_t
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Author:Echo Chen(陈斌)
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Email:chenb19870707@gmail.com
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Date:October 20h, 2014
1.ngx_queue优势和特点
ngx_queue作为顺序容器链表,它优势在于其可以高效地执行插入、删除、合并操作,在插入删除的过程中,只需要修改指针指向,而不需要拷贝数据,因此,对于频繁修改的容器很适合。此外,相对于STL list,它还具有以下特点:
- 自身实现了排序功能
- 轻量级,不负责内存的分配
- 自身支持两个链表的合并
2.源代码位置
头文件:http://trac.nginx.org/nginx/browser/nginx/src/core/ngx_queue.h
源文件:http://trac.nginx.org/nginx/browser/nginx/src/core/ngx_queue.c
3.数据结构定义
1: typedef struct ngx_queue_s ngx_queue_t;2:3: struct ngx_queue_s {4: ngx_queue_t *prev;5: ngx_queue_t *next;6: };可以看到,它的结构非常简单,仅有两个成员:prev、next,这样对于链表中元素来说,空间上只增加了两个指针的消耗。
4.初始化ngx_queue_init
1: //q 为链表容器结构体ngx_queue_t的指针,将头尾指针指向自己2: #define ngx_queue_init(q)3: (q)->prev = q;4: (q)->next = q初始状态的链表如图所示:
5.判断链表容器是否为空ngx_queue_empty
判断方法非常简单,即判断链表的prev指针是否指向自己,如上图所示
1: #define ngx_queue_empty(h)2: (h == (h)->prev)6.头部插入ngx_queue_insert_head
1: //h为链表指针,x为要插入的元素2: #define ngx_queue_insert_head(h, x)3: (x)->next = (h)->next;4: (x)->next->prev = x;5: (x)->prev = h;6: (h)->next = x标准的双链表插入四步操作,如图所示:
7.尾部插入ngx_queue_insert_tail
与头部插入类似,只是第一步给的h->prev ,即为最后一个结点:
1: #define ngx_queue_insert_tail(h, x)2: (x)->prev = (h)->prev;3: (x)->prev->next = x;4: (x)->next = h;5: (h)->prev = x8.链表删除ngx_queue_remove
x为要删除的结点,将x的下一个的结点的prev指针指向x的上一个结点,再将x的前一个结点的next指针指向x的下一个结点,常规链表双链表结点删除操作,不处理内存释放
1: #define ngx_queue_remove(x)2: (x)->next->prev = (x)->prev;3: (x)->prev->next = (x)->next4:9.链表拆分ngx_queue_split
1: #define ngx_queue_split(h, q, n)2: (n)->prev = (h)->prev;3: (n)->prev->next = n;4: (n)->next = q;5: (h)->prev = (q)->prev;6: (h)->prev->next = h;7: (q)->prev = n;h为链表容器,q为链表h中的一个元素,这个方法可以将链表h以元素q为界拆分为两个链表h和n,其中h由原链表的前半部分组成(不包含q),而n由后半部分组成,q为首元素,操作也很简单,如图所示:
10.链表合并ngx_queue_add
1: #define ngx_queue_add(h, n)2: (h)->prev->next = (n)->next;3: (n)->next->prev = (h)->prev;4: (h)->prev = (n)->prev;5: (h)->prev->next = h;将链表n 合并到链表h的尾部,如图所示:
11. 链表中心元素ngx_queue_middle
1: ngx_queue_t *ngx_queue_middle(ngx_queue_t *queue)2: {3: ngx_queue_t *middle, *next;4:5: middle = ngx_queue_head(queue);6:7: //头尾相等,空链表,返回头即可8: if (middle == ngx_queue_last(queue)) {9: return middle;10: }11:12: next = ngx_queue_head(queue);13:14: for ( ;; ) {15: middle = ngx_queue_next(middle);16: next = ngx_queue_next(next);17:18: if (next == ngx_queue_last(queue)) {19: return middle;20: }21:22: next = ngx_queue_next(next);23:24: if (next == ngx_queue_last(queue)) {25: return middle;26: }27: }28: }这里用到的技巧是每次middle向后移动一步,next向后移动两步,这样next指到队尾的时候,middle就指到了中间,时间复杂度就是O(N),这是一道经典的面试题,今天在这里看到了源码,似成相识啊,果然经典面试题目都不是凭空而来。
12.链表排序ngx_queue_sort
可以看到,这里采用的是插入排序算法,时间复杂度为O(n),整个代码非常简洁。
1: void ngx_queue_sort(ngx_queue_t *queue, ngx_int_t (*cmp)(const ngx_queue_t *, const ngx_queue_t *))2: {3: ngx_queue_t *q, *prev, *next;4:5: q = ngx_queue_head(queue);6:7: //如果是空链表,直接返回8: if (q == ngx_queue_last(queue)) {9: return;10: }11:12: for (q = ngx_queue_next(q); q != ngx_queue_sentinel(queue); q = next) {13:14: prev = ngx_queue_prev(q);15: next = ngx_queue_next(q);16:17: ngx_queue_remove(q);18:19: //找到插入位置20: do {21: if (cmp(prev, q) <= 0) {22: break;23: }24:25: prev = ngx_queue_prev(prev);26:27: } while (prev != ngx_queue_sentinel(queue));28:29: //插入30: ngx_queue_insert_after(prev, q);31: }32: }13.根据ngx_queue_t 找到链表元素
1: #define ngx_queue_data(q, type, link)2: (type *) ((u_char *) q - offsetof(type, link))其中q为ngx_queue_t* 类型,函数作用为根据q算出,算出链表元素的地址,其中linux接口offsetof是算出link在type中的偏移。
14.其它方法
1: #define ngx_queue_head(h)2: (h)->next3:4:5: #define ngx_queue_last(h)6: (h)->prev7:8:9: #define ngx_queue_sentinel(h)10: (h)11:12:13: #define ngx_queue_next(q)14: (q)->next15:16:17: #define ngx_queue_prev(q)18: (q)->prev15.实战
1: #include <iostream>2: #include <algorithm>3: #include <pthread.h>4: #include <time.h>5: #include <stdio.h>6: #include <errno.h>7: #include <string.h>8: #include "ngx_queue.h"9:10: struct student_info11: {12: long stu_id;13: unsigned int age;14: unsigned int score;15: ngx_queue_t qEle;16: };17:18: ngx_int_t compareStudent(const ngx_queue_t *a, const ngx_queue_t *b)19: {20: //分别取得a b 对象指针21: student_info *ainfo = ngx_queue_data(a,student_info,qEle);22: student_info *binfo = ngx_queue_data(b,student_info,qEle);23:24: return ainfo->score >binfo->score;25: }26:27: void print_ngx_queue(ngx_queue_t *queue)28: {29: //遍历输出30: for(ngx_queue_t *q = ngx_queue_head(queue);q != ngx_queue_sentinel(queue);q = ngx_queue_next(q))31: {32: student_info *info = ngx_queue_data(q,student_info,qEle);33: if(info != NULL)34: {35: std::cout <<info->score << " ";36: }37: }38:39: std::cout << std::endl;40: }41:42: int main()43: {44:45: ngx_queue_t queue;46: ngx_queue_init(&queue);47:48: student_info info[5];49: for(int i = 0;i < 5;i++)50: {51: info[i].stu_id = i;52: info[i].age = i;53: info[i].score = i;54:55: if(i%2)56: {57: ngx_queue_insert_tail(&queue,&info[i].qEle);58: }59: else60: {61: ngx_queue_insert_head(&queue,&info[i].qEle);62: }63: }64:65: print_ngx_queue(&queue);66:67: ngx_queue_sort(&queue,compareStudent);68:69: print_ngx_queue(&queue);70:71: return 0;72: }输出结果:
16.总结
ngx_queue设计非常精巧,基本涵盖了双链表的所有操作,建议需要面试的童鞋看一看,很多链表的题目都迎刃而解。此外,ngx_queue与其它nginx 代码耦合度低,有需要这种双向链表的实现时不妨直接拿过来使用。
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