继上次的redis源码分析(一)之后,本人开始订制着一份非常伟大的计划-啃完redis源代码,也对他进行了切块划分,鉴于本人目前对他的整个运行流畅还不特别清楚的情况下,所以决定第一个要解决的就是与逻辑无关的代码,也就是一些基本模块,因为是相互独立的,所以不会影响整体的阅读,所以第一个开刀的就是结构体模块了。结构体模块我划分了差不多10个文件的样子,今天看的主要是adlist.c的文件,收获有如下
**1.真心的帮我把数据结构的链表操作复习了一遍**
**2.还有给人感觉最深的就是函数编程的思想无处不在,并没有明确的数据类型,结构体里的各种函数指针的调用,函数作为参数存在的频率非常高**
**3.让我见识到了C语言中迭代器还能这么写,像用过高级语言的java,C#语言的同学肯定感觉迭代器Iterator嘛,不很简单嘛,一句话的事呗,但是C语言中没有现成的方法,怎么实现,adlist.c给我们提供了一种很简洁的写法.**
**下面给出我分析的2个文件,一个是.h头文件,一个是.c的具体文件(我上面提到的3点可以着重看看出现的地方):**
~~~
/* adlist.h - A generic doubly linked list implementation
*
* Copyright (c) 2006-2012, Salvatore Sanfilippo <antirez at gmail dot com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Redis nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef __ADLIST_H__
#define __ADLIST_H__
/* Node, List, and Iterator are the only data structures used currently. */
/* listNode结点 */
typedef struct listNode {
//结点的前一结点
struct listNode *prev;
//结点的下一结点
struct listNode *next;
//Node的函数指针
void *value;
} listNode;
/* list迭代器,只能为单向 */
typedef struct listIter {
//当前迭代位置的下一结点
listNode *next;
//迭代器的方向
int direction;
} listIter;
/* listNode 列表 */
typedef struct list {
//列表头结点
listNode *head;
//列表尾结点
listNode *tail;
/* 下面3个方法为所有结点公用的方法,分别在相应情况下回调用 */
//复制函数指针
void *(*dup)(void *ptr);
//释放函数指针
void (*free)(void *ptr);
//匹配函数指针
int (*match)(void *ptr, void *key);
//列表长度
unsigned long len;
} list;
/* Functions implemented as macros */
/* 宏定义了一些基本操作 */
#define listLength(l) ((l)->len) //获取list长度
#define listFirst(l) ((l)->head) //获取列表首部
#define listLast(l) ((l)->tail) //获取列表尾部
#define listPrevNode(n) ((n)->prev) //给定结点的上一结点
#define listNextNode(n) ((n)->next) //给定结点的下一节点
#define listNodeValue(n) ((n)->value) //给点的结点的值,这个value不是一个数值类型,而是一个函数指针
#define listSetDupMethod(l,m) ((l)->dup = (m)) //列表的复制方法的设置
#define listSetFreeMethod(l,m) ((l)->free = (m)) //列表的释放方法的设置
#define listSetMatchMethod(l,m) ((l)->match = (m)) //列表的匹配方法的设置
#define listGetDupMethod(l) ((l)->dup) //列表的复制方法的获取
#define listGetFree(l) ((l)->free) //列表的释放方法的获取
#define listGetMatchMethod(l) ((l)->match) //列表的匹配方法的获取
/* Prototypes */
/* 定义了方法的原型 */
list *listCreate(void); //创建list列表
void listRelease(list *list); //列表的释放
list *listAddNodeHead(list *list, void *value); //添加列表头结点
list *listAddNodeTail(list *list, void *value); //添加列表尾结点
list *listInsertNode(list *list, listNode *old_node, void *value, int after); //某位置上插入及结点
void listDelNode(list *list, listNode *node); //列表上删除给定的结点
listIter *listGetIterator(list *list, int direction); //获取列表给定方向上的迭代器
listNode *listNext(listIter *iter); //获取迭代器内的下一结点
void listReleaseIterator(listIter *iter); //释放列表迭代器
list *listDup(list *orig); //列表的复制
listNode *listSearchKey(list *list, void *key); //关键字搜索具体结点
listNode *listIndex(list *list, long index); //下标索引具体的结点
void listRewind(list *list, listIter *li); // 重置迭代器为方向从头开始
void listRewindTail(list *list, listIter *li); //重置迭代器为方向从尾部开始
void listRotate(list *list); //列表旋转操作,方法名说的很玄乎,具体只能到实现里去看了
/* Directions for iterators */
/* 定义2个迭代方向,从头部开始往尾部,第二个从尾部开始向头部 */
#define AL_START_HEAD 0
#define AL_START_TAIL 1
#endif /* __ADLIST_H__ */
~~~
adlist.c:
~~~
/* adlist.c - A generic doubly linked list implementation
*
* Copyright (c) 2006-2010, Salvatore Sanfilippo <antirez at gmail dot com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Redis nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include <stdlib.h>
#include "adlist.h"
#include "zmalloc.h"
/* Create a new list. The created list can be freed with
* AlFreeList(), but private value of every node need to be freed
* by the user before to call AlFreeList().
*
* On error, NULL is returned. Otherwise the pointer to the new list. */
/* 创建结点列表 */
list *listCreate(void)
{
struct list *list;
//申请空间,如果失败了就直接返回NULL
if ((list = zmalloc(sizeof(*list))) == NULL)
return NULL;
//初始化操作,头尾结点,,3个公共的函数指针全部赋值为NULL
list->head = list->tail = NULL;
list->len = 0;
list->dup = NULL;
list->free = NULL;
list->match = NULL;
return list;
}
/* Free the whole list.
*
* This function can't fail. */
/* 释放整个列表 */
void listRelease(list *list)
{
unsigned long len;
listNode *current, *next;
//找到当前结点,也就是头结点
current = list->head;
len = list->len;
while(len--) {
//while循环依次释放结点
next = current->next;
//如果列表有free释放方法定义,每个结点都必须调用自己内部的value方法
if (list->free) list->free(current->value);
//采用redis新定义的在zfree方式释放结点,与zmalloc对应,不是free!!
zfree(current);
current = next;
}
//最后再次释放list同样是zfree
zfree(list);
}
/* Add a new node to the list, to head, contaning the specified 'value'
* pointer as value.
*
* On error, NULL is returned and no operation is performed (i.e. the
* list remains unaltered).
* On success the 'list' pointer you pass to the function is returned. */
/* 列表添加头结点 */
list *listAddNodeHead(list *list, void *value)
{
listNode *node;
//定义新的listNode,并赋值函数指针
if ((node = zmalloc(sizeof(*node))) == NULL)
return NULL;
node->value = value;
if (list->len == 0) {
//当此时没有任何结点时,头尾结点是同一个结点,前后指针为NULL
list->head = list->tail = node;
node->prev = node->next = NULL;
} else {
//设置此结点next与前头结点的位置关系
node->prev = NULL;
node->next = list->head;
list->head->prev = node;
list->head = node;
}
//结点计数递增并返回
list->len++;
return list;
}
/* Add a new node to the list, to tail, containing the specified 'value'
* pointer as value.
*
* On error, NULL is returned and no operation is performed (i.e. the
* list remains unaltered).
* On success the 'list' pointer you pass to the function is returned. */
/* 列表添加尾结点,操作大体上与增加头结点一样,不加以描述了 */
list *listAddNodeTail(list *list, void *value)
{
listNode *node;
if ((node = zmalloc(sizeof(*node))) == NULL)
return NULL;
node->value = value;
if (list->len == 0) {
list->head = list->tail = node;
node->prev = node->next = NULL;
} else {
node->prev = list->tail;
node->next = NULL;
list->tail->next = node;
list->tail = node;
}
list->len++;
return list;
}
/* 在old_node结点的前面或后面插入新结点 */
list *listInsertNode(list *list, listNode *old_node, void *value, int after) {
listNode *node;
//新申请结点,并赋值好函数指针
if ((node = zmalloc(sizeof(*node))) == NULL)
return NULL;
node->value = value;
if (after) {
//如果是在目标结点的后面插入的情况,将新结点的next指针指向老结点的next
node->prev = old_node;
node->next = old_node->next;
if (list->tail == old_node) {
//如果老结点已经是最后一个结点了,则新的结点直接成为尾部结点
list->tail = node;
}
} else {
//如果是在目标结点的前面插入的情况,将新结点的preview指针指向老结点的preview
node->next = old_node;
node->prev = old_node->prev;
if (list->head == old_node) {
//如果老结点已经是头结点了,则新的结点直接成为头部结点
list->head = node;
}
}
//检查Node的前后结点还有没有未连接的操作
if (node->prev != NULL) {
node->prev->next = node;
}
if (node->next != NULL) {
node->next->prev = node;
}
list->len++;
return list;
}
/* Remove the specified node from the specified list.
* It's up to the caller to free the private value of the node.
*
* This function can't fail. */
/* 列表删除某结点 */
void listDelNode(list *list, listNode *node)
{
if (node->prev)
//如果结点prev结点存在,prev的结点的下一及诶单指向Node的next结点
node->prev->next = node->next;
else
//如果不存在说明是被删除的是头结点,则重新赋值Node的next为新头结点
list->head = node->next;
//后半操作类似
if (node->next)
node->next->prev = node->prev;
else
list->tail = node->prev;
//同样要调用list的free函数
if (list->free) list->free(node->value);
zfree(node);
list->len--;
}
/* Returns a list iterator 'iter'. After the initialization every
* call to listNext() will return the next element of the list.
*
* This function can't fail. */
/* 获取列表呢迭代器 */
listIter *listGetIterator(list *list, int direction)
{
listIter *iter;
//申请空间,失败了就直接返回NULL
if ((iter = zmalloc(sizeof(*iter))) == NULL) return NULL;
if (direction == AL_START_HEAD)
//如果方向定义的是从头开始,则迭代器的next指针指向列表头结点
iter->next = list->head;
else
//如果方向定义的是从尾开始,则迭代器的next指针指向列表尾结点
iter->next = list->tail;
//赋值好迭代器方向并返回
iter->direction = direction;
return iter;
}
/* Release the iterator memory */
/* 释放迭代器内存 */
void listReleaseIterator(listIter *iter) {
zfree(iter);
}
/* Create an iterator in the list private iterator structure */
/* 相当于重置迭代器为方向从头开始 */
void listRewind(list *list, listIter *li) {
li->next = list->head;
li->direction = AL_START_HEAD;
}
/* 重置迭代器为方向从尾部开始 */
void listRewindTail(list *list, listIter *li) {
li->next = list->tail;
li->direction = AL_START_TAIL;
}
/* Return the next element of an iterator.
* It's valid to remove the currently returned element using
* listDelNode(), but not to remove other elements.
*
* The function returns a pointer to the next element of the list,
* or NULL if there are no more elements, so the classical usage patter
* is:
*
* iter = listGetIterator(list,<direction>);
* while ((node = listNext(iter)) != NULL) {
* doSomethingWith(listNodeValue(node));
* }
*
* */
/* 根据迭代器获取下一结点 */
listNode *listNext(listIter *iter)
{
//获取当前迭代器的当前结点
listNode *current = iter->next;
if (current != NULL) {
if (iter->direction == AL_START_HEAD)
//如果方向为从头部开始,则当前结点等于当前的结点的下一结点
iter->next = current->next;
else
//如果方向为从尾部开始,则当前结点等于当前的结点的上一结点
iter->next = current->prev;
}
return current;
}
/* Duplicate the whole list. On out of memory NULL is returned.
* On success a copy of the original list is returned.
*
* The 'Dup' method set with listSetDupMethod() function is used
* to copy the node value. Otherwise the same pointer value of
* the original node is used as value of the copied node.
*
* The original list both on success or error is never modified. */
/* 列表赋值方法,传入的参数为原始列表 */
list *listDup(list *orig)
{
list *copy;
listIter *iter;
listNode *node;
//如果创建列表失败则直接返回
if ((copy = listCreate()) == NULL)
return NULL;
//为新列表赋值好3个函数指针
copy->dup = orig->dup;
copy->free = orig->free;
copy->match = orig->match;
//获得从头方向开始的迭代器
iter = listGetIterator(orig, AL_START_HEAD);
while((node = listNext(iter)) != NULL) {
//从前往后遍历结点
void *value;
if (copy->dup) {
//如果定义了列表复制方法,则调用dup方法
value = copy->dup(node->value);
if (value == NULL) {
//如果发生OOM内存溢出问题,直接释放所有空间
listRelease(copy);
listReleaseIterator(iter);
return NULL;
}
} else
//没定义直接复制函数指针
value = node->value;
if (listAddNodeTail(copy, value) == NULL) {
//后面的结点都是从尾部逐一添加结点,如果内存溢出,同上操作
listRelease(copy);
listReleaseIterator(iter);
return NULL;
}
}
//最后释放迭代器
listReleaseIterator(iter);
return copy;
}
/* Search the list for a node matching a given key.
* The match is performed using the 'match' method
* set with listSetMatchMethod(). If no 'match' method
* is set, the 'value' pointer of every node is directly
* compared with the 'key' pointer.
*
* On success the first matching node pointer is returned
* (search starts from head). If no matching node exists
* NULL is returned. */
/* 关键字搜索Node结点此时用到了list的match方法了 */
listNode *listSearchKey(list *list, void *key)
{
listIter *iter;
listNode *node;
//获取迭代器
iter = listGetIterator(list, AL_START_HEAD);
while((node = listNext(iter)) != NULL) {
//遍历循环
if (list->match) {
//如果定义了list的match方法,则调用match方法
if (list->match(node->value, key)) {
//如果方法返回true,则代表找到结点,释放迭代器
listReleaseIterator(iter);
return node;
}
} else {
//如果没有定义list 的match方法,则直接比较函数指针
if (key == node->value) {
//如果相等,则代表找到结点,释放迭代器
listReleaseIterator(iter);
return node;
}
}
}
listReleaseIterator(iter);
return NULL;
}
/* Return the element at the specified zero-based index
* where 0 is the head, 1 is the element next to head
* and so on. Negative integers are used in order to count
* from the tail, -1 is the last element, -2 the penultimate
* and so on. If the index is out of range NULL is returned. */
/* 根据下标值返回相应的结点*/
/*下标有2种表示形式,从头往后一次0, 1, 2,...从后往前是 ...-3, -2, -1.-1为最后一个结点*/
listNode *listIndex(list *list, long index) {
listNode *n;
if (index < 0) {
//如果index为负数,则从后往前数
index = (-index)-1;
n = list->tail;
while(index-- && n) n = n->prev;
} else {
//如果index为正数,则从前往后数
n = list->head;
while(index-- && n) n = n->next;
}
return n;
}
/* Rotate the list removing the tail node and inserting it to the head. */
/* rotate操作其实就是把尾部结点挪到头部,原本倒数第二个结点变为尾部结点 */
void listRotate(list *list) {
listNode *tail = list->tail;
//如果长度为不足,直接返回,之前宏定义的方法
if (listLength(list) <= 1) return;
/* Detach current tail */
//替换新的尾部结点,原结点后挪一个位置
list->tail = tail->prev;
list->tail->next = NULL;
/* Move it as head */
//设置新结点
list->head->prev = tail;
tail->prev = NULL;
tail->next = list->head;
list->head = tail;
}
~~~
其实目前网上的各种的解析都有吧,每个人阅读带给自己的感受是不一样的,只有自己亲手体验过才叫真的体会过,阅读代码的确会给人很多启发,非常严谨吧,每行代码,抱着一种学习,欣赏的心态看待代码。不错,良好的开始,继续坚持。
- 前言
- (一)--Redis结构解析
- (二)--结构体分析(1)
- (三)---dict哈希结构
- (四)-- sds字符串
- (五)--- sparkline微线图
- (六)--- ziplist压缩列表
- (七)--- zipmap压缩图
- (八)--- t_hash哈希转换
- (九)--- t_list,t_string的分析
- (十)--- testhelp.h小型测试框架和redis-check-aof.c日志检测
- (十一)--- memtest内存检测
- (十二)--- redis-check-dump本地数据库检测
- (十三)--- redis-benchmark性能测试
- (十四)--- rdb.c本地数据库操作
- (十五)--- aof-append only file解析
- (十六)--- config配置文件
- (十七)--- multi事务操作
- (十八)--- db.c内存数据库操作
- (十九)--- replication主从数据复制的实现
- (二十)--- ae事件驱动
- (二十一)--- anet网络通信的封装
- (二十二)--- networking网络协议传输
- (二十三)--- CRC循环冗余算法和RAND随机数算法
- (二十四)--- tool工具类(2)
- (二十五)--- zmalloc内存分配实现
- (二十六)--- slowLog和hyperloglog
- (二十七)--- rio系统I/O的封装
- (二十八)--- object创建和释放redisObject对象
- (二十九)--- bio后台I/O服务的实现
- (三十)--- pubsub发布订阅模式
- (三十一)--- latency延迟分析处理
- (三十二)--- redis-cli.c客户端命令行接口的实现(1)
- (三十三)--- redis-cli.c客户端命令行接口的实现(2)
- (三十四)--- redis.h服务端的实现分析(1)
- (三十五)--- redis.c服务端的实现分析(2)
- (三十六)--- Redis中的11大优秀设计