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对于一个能够支撑超高并发的大型分布式系统来说,像Redis这类分布式缓存是必不可少。Redis在单机部署的模式下,QPS几乎不可能超过10万+,除非机器配置特别好且Redis操作不太复杂。

我们知道,对于数据库来说,如果想要提升读写性能,最简单的方式就是做 一主多从+读写分离 。对于分布式缓存也是一样的道理,因为缓存一般都是用来支撑读请求的高并发,写请求相对较少(一般也就每秒一两千写请求),所以非常适合读写分离的架构。

关于Redis的复制原理,我在进阶篇的《分布式框架之高性能:Redis主从同步》已经详细讲解过了,不熟悉的读者可以先去了解下。

一、主从架构搭建

在生产环境下,我们必须要将Master节点的持久化功能打开,否则万一Master宕机后重启,此时Slave连上Master后,会触发一次全量复制,master就会将空的数据集同步到slave上去,导致Slave中的数据也被清空。

我们先来搭建一个一主二从的Redis构架,我首先在ressmix-dsf02这个节点上安装单机版本的Redis。具体的安装步骤不再赘述,读者可以参考我在《Redis持久化实战》中讲解的搭建步骤。

1.1 配置步骤

搭建完Redis节点后,我们按照以下步骤进行读写分离的配置,ressmix-dsf01作为Master,ressmix-dsf02和ressmix-dsf03作为Slave。(我这里只操作ressmix-dsf02,ressmix-dsf03读者可以自行操作)

  1. 修改Slave节点的配置文件,配置replicaof ressmix-dsf01 6379,这样ressmix-dsf01节点就作为了ressmix-dsf02的Master节点;
  2. 强制读写分离:修改Slave节点的配置文件,配置replica-read-only yes,这样Slave节点会拒绝所有的写操作(Redis 2.6以后Slave节点默认就是只读的,所以这个版本以后的Redis默认可以不设置);
  3. 集群安全认证:修改Slave节点的配置文件,配置masterauth ressmix,其中ressmix是我设置的认证密码;
  4. 停止Master节点,然后修改Master节点的配置文件,配置requirepass ressmix
  5. 主从节点均配置appendonly yes,开启AOF持久化;
  6. 绑定节点IP:修改Slave节点的配置文件,配置bind 192.168.0.109,其中192.168.0.109为ressmix-dsf02的IP,同理也把Master节点的这个配置修改下。另外,为了以防外一,每个节点都执行下iptables -A INPUT -ptcp --dport 6379 -j ACCEPT,用于放开6379端口,然后清理下防火墙:sudo iptables -F

上述操作全部配置完成后,我们通过以下命令启动主节点,然后以相同方式启动从节点ressmix-dsf02。

    cd /etc/init.d
    ./redis_6379 start

节点启动后,我们可以先在Master节点中写入一条记录:

    redis-cli -h 192.168.0.107 -a ressmix
    set k1 v1

然后在ressmix-dsf02节点可以查看到同步过来的数据:

我们可以通过执行info replication查看主从复制的状态:

二、性能压测

搭建完Redis的主从架构后,可以对其做一个基准压测,测一下Redis的性能和QPS。Redis自身提供了redis-benchmark压测工具,可以用于一些简单场景下性能测试。

压测工具位于redis安装包的src目录下:

    ./redis-benchmark -h 192.168.0.107

常用参数如下:

    -c <clients>       Number of parallel connections (default 50)
    -n <requests>      Total number of requests (default 100000)
    -d <size>          Data size of SET/GET value in bytes (default 2)

我们可以根据自己系统高峰期的业务量来设置参数,比如在高峰期,瞬时最大用户量会达到10万,总请求数为1000万,每条数据的大小为50字节,则可以像下面这样模拟请求:

    ./redis-benchmark -h 192.168.0.107 -c 100000 -n 10000000 -d 50

压测的结果可能像下面这样,显示了不同操作的每秒请求数:

    ====== PING_INLINE ======
      100000 requests completed in 1.28 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    99.78% <= 1 milliseconds
    99.93% <= 2 milliseconds
    99.97% <= 3 milliseconds
    100.00% <= 3 milliseconds
    78308.54 requests per second
    
    ====== PING_BULK ======
      100000 requests completed in 1.30 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    99.87% <= 1 milliseconds
    100.00% <= 1 milliseconds
    76804.91 requests per second
    
    ====== SET ======
      100000 requests completed in 2.50 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    5.95% <= 1 milliseconds
    99.63% <= 2 milliseconds
    99.93% <= 3 milliseconds
    99.99% <= 4 milliseconds
    100.00% <= 4 milliseconds
    40032.03 requests per second
    
    ====== GET ======
      100000 requests completed in 1.30 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    99.73% <= 1 milliseconds
    100.00% <= 2 milliseconds
    100.00% <= 2 milliseconds
    76628.35 requests per second
    
    ====== INCR ======
      100000 requests completed in 1.90 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    80.92% <= 1 milliseconds
    99.81% <= 2 milliseconds
    99.95% <= 3 milliseconds
    99.96% <= 4 milliseconds
    99.97% <= 5 milliseconds
    100.00% <= 6 milliseconds
    52548.61 requests per second
    
    ====== LPUSH ======
      100000 requests completed in 2.58 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    3.76% <= 1 milliseconds
    99.61% <= 2 milliseconds
    99.93% <= 3 milliseconds
    100.00% <= 3 milliseconds
    38684.72 requests per second
    
    ====== RPUSH ======
      100000 requests completed in 2.47 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    6.87% <= 1 milliseconds
    99.69% <= 2 milliseconds
    99.87% <= 3 milliseconds
    99.99% <= 4 milliseconds
    100.00% <= 4 milliseconds
    40469.45 requests per second
    
    ====== LPOP ======
      100000 requests completed in 2.26 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    28.39% <= 1 milliseconds
    99.83% <= 2 milliseconds
    100.00% <= 2 milliseconds
    44306.60 requests per second
    
    ====== RPOP ======
      100000 requests completed in 2.18 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    36.08% <= 1 milliseconds
    99.75% <= 2 milliseconds
    100.00% <= 2 milliseconds
    45871.56 requests per second
    
    ====== SADD ======
      100000 requests completed in 1.23 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    99.94% <= 1 milliseconds
    100.00% <= 2 milliseconds
    100.00% <= 2 milliseconds
    81168.83 requests per second
    
    ====== SPOP ======
      100000 requests completed in 1.28 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    99.80% <= 1 milliseconds
    99.96% <= 2 milliseconds
    99.96% <= 3 milliseconds
    99.97% <= 5 milliseconds
    100.00% <= 5 milliseconds
    78369.91 requests per second
    
    ====== LPUSH (needed to benchmark LRANGE) ======
      100000 requests completed in 2.47 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    15.29% <= 1 milliseconds
    99.64% <= 2 milliseconds
    99.94% <= 3 milliseconds
    100.00% <= 3 milliseconds
    40420.37 requests per second
    
    ====== LRANGE_100 (first 100 elements) ======
      100000 requests completed in 3.69 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    30.86% <= 1 milliseconds
    96.99% <= 2 milliseconds
    99.94% <= 3 milliseconds
    99.99% <= 4 milliseconds
    100.00% <= 4 milliseconds
    27085.59 requests per second
    
    ====== LRANGE_300 (first 300 elements) ======
      100000 requests completed in 10.22 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    0.03% <= 1 milliseconds
    5.90% <= 2 milliseconds
    90.68% <= 3 milliseconds
    95.46% <= 4 milliseconds
    97.67% <= 5 milliseconds
    99.12% <= 6 milliseconds
    99.98% <= 7 milliseconds
    100.00% <= 7 milliseconds
    9784.74 requests per second
    
    ====== LRANGE_500 (first 450 elements) ======
      100000 requests completed in 14.71 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    0.00% <= 1 milliseconds
    0.07% <= 2 milliseconds
    1.59% <= 3 milliseconds
    89.26% <= 4 milliseconds
    97.90% <= 5 milliseconds
    99.24% <= 6 milliseconds
    99.73% <= 7 milliseconds
    99.89% <= 8 milliseconds
    99.96% <= 9 milliseconds
    99.99% <= 10 milliseconds
    100.00% <= 10 milliseconds
    6799.48 requests per second
    
    ====== LRANGE_600 (first 600 elements) ======
      100000 requests completed in 18.56 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    0.00% <= 2 milliseconds
    0.23% <= 3 milliseconds
    1.75% <= 4 milliseconds
    91.17% <= 5 milliseconds
    98.16% <= 6 milliseconds
    99.04% <= 7 milliseconds
    99.83% <= 8 milliseconds
    99.95% <= 9 milliseconds
    99.98% <= 10 milliseconds
    100.00% <= 10 milliseconds
    5387.35 requests per second
    
    ====== MSET (10 keys) ======
      100000 requests completed in 4.02 seconds
      50 parallel clients
      3 bytes payload
      keep alive: 1
    
    0.01% <= 1 milliseconds
    53.22% <= 2 milliseconds
    99.12% <= 3 milliseconds
    99.55% <= 4 milliseconds
    99.70% <= 5 milliseconds
    99.90% <= 6 milliseconds
    99.95% <= 7 milliseconds
    100.00% <= 8 milliseconds
    24869.44 requests per second

三、总结

本章,我重点讲解了如何进行生产环境的Redis读写分离部署,读者可以自己尝试在虚拟机中动手进行节点部署,以加深印象。

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