![[DPI][suricata] suricata 配置使用](https://image.shishitao.com:8440/aHR0cHM6Ly9ia3FzaW1nLmlrYWZhbi5jb20vdXBsb2FkL2NoYXRncHQtcy5wbmc%2FIQ%3D%3D.png?!?w=700 "[DPI][suricata] suricata 配置使用")
至此, 我们已经拥有了suricata可以运行的环境了.
接下来,我们来研究一下它的功能, 首先,分析一下配置文件:
/suricata/etc/suricata/suricata.yaml
可以结合着默认配置文件的内容,同时读它的描述文档: http://suricata.readthedocs.io/en/latest/configuration/suricata-yaml.html
这样更好理解.
快速浏览一遍配置之后, 基本上也就了解了suricata的主要功能. 配置项很丰富, 能力也很强大, 最简单快速的可以提供一个主管感受的方法,就是先打开http记录功能.
![[DPI][suricata] suricata 配置使用](https://image.shishitao.com:8440/aHR0cHM6Ly9pbWFnZXMyMDE3LmNuYmxvZ3MuY29tL2Jsb2cvMTAyODU0MC8yMDE4MDIvMTAyODU0MC0yMDE4MDIwODEwMjE0MDEzOC00MjA3MDY1MjUucG5n.png?w=700 "[DPI][suricata] suricata 配置使用")
然后重启,会发现, 多个一个日志文件 /suricata/var/log/suricata/http.log
然后试着访问一个网页,
[root@suricata ~]# wget -q www.baidu.com
[root@suricata ~]#
该日志中,便记录下了这条http访问日志:
[root@suricata suricata]# cat /suricata/var/log/suricata/http.log
//-::02.035401 www.baidu.com[**]/[**]Wget/1.14 (linux-gnu)[**]192.168.7.8: -> 61.135.169.125:
//-::05.893547 www.baidu.com[**]/[**]Wget/1.14 (linux-gnu)[**]192.168.7.8: -> 61.135.169.121:
[root@suricata suricata]#
其他高级用法,可以结合文档, 尝试着进行修改测试, 慢慢熟悉.
另外, suricata有非常多的运行模式, 详见文档, 不做赘述
[root@suricata ~]# /suricata/usr/bin/suricata --list-runmodes
------------------------------------- Runmodes ------------------------------------------
| RunMode Type | Custom Mode | Description
|----------------------------------------------------------------------------------------
| PCAP_DEV | single | Single threaded pcap live mode
| ---------------------------------------------------------------------
| | autofp | Multi threaded pcap live mode. Packets from each flow are assigned to a single detect thread, unlike "pcap_live_auto" where packets from the same flow can be processed by any detect thread
| ---------------------------------------------------------------------
| | workers | Workers pcap live mode, each thread does all tasks from acquisition to logging
|----------------------------------------------------------------------------------------
| PCAP_FILE | single | Single threaded pcap file mode
| ---------------------------------------------------------------------
| | autofp | Multi threaded pcap file mode. Packets from each flow are assigned to a single detect thread, unlike "pcap-file-auto" where packets from the same flow can be processed by any detect thread
|----------------------------------------------------------------------------------------
| PFRING(DISABLED) | autofp | Multi threaded pfring mode. Packets from each flow are assigned to a single detect thread, unlike "pfring_auto" where packets from the same flow can be processed by any detect thread
| ---------------------------------------------------------------------
| | single | Single threaded pfring mode
| ---------------------------------------------------------------------
| | workers | Workers pfring mode, each thread does all tasks from acquisition to logging
|----------------------------------------------------------------------------------------
| NFQ | autofp | Multi threaded NFQ IPS mode with respect to flow
| ---------------------------------------------------------------------
| | workers | Multi queue NFQ IPS mode with one thread per queue
|----------------------------------------------------------------------------------------
| NFLOG | autofp | Multi threaded nflog mode
| ---------------------------------------------------------------------
| | single | Single threaded nflog mode
| ---------------------------------------------------------------------
| | workers | Workers nflog mode
|----------------------------------------------------------------------------------------
| IPFW | autofp | Multi threaded IPFW IPS mode with respect to flow
| ---------------------------------------------------------------------
| | workers | Multi queue IPFW IPS mode with one thread per queue
|----------------------------------------------------------------------------------------
| ERF_FILE | single | Single threaded ERF file mode
| ---------------------------------------------------------------------
| | autofp | Multi threaded ERF file mode. Packets from each flow are assigned to a single detect thread
|----------------------------------------------------------------------------------------
| ERF_DAG | autofp | Multi threaded DAG mode. Packets from each flow are assigned to a single detect thread, unlike "dag_auto" where packets from the same flow can be processed by any detect thread
| ---------------------------------------------------------------------
| | single | Singled threaded DAG mode
| ---------------------------------------------------------------------
| | workers | Workers DAG mode, each thread does all tasks from acquisition to logging
|----------------------------------------------------------------------------------------
| AF_PACKET_DEV | single | Single threaded af-packet mode
| ---------------------------------------------------------------------
| | workers | Workers af-packet mode, each thread does all tasks from acquisition to logging
| ---------------------------------------------------------------------
| | autofp | Multi socket AF_PACKET mode. Packets from each flow are assigned to a single detect thread.
|----------------------------------------------------------------------------------------
| NETMAP(DISABLED) | single | Single threaded netmap mode
| ---------------------------------------------------------------------
| | workers | Workers netmap mode, each thread does all tasks from acquisition to logging
| ---------------------------------------------------------------------
| | autofp | Multi threaded netmap mode. Packets from each flow are assigned to a single detect thread.
|----------------------------------------------------------------------------------------
[root@suricata ~]#
Detection-engine部分对规则引擎相关部分的讲解,值得详细的读一下, 可以帮助理解规则组织结构的内部实现.
http://suricata.readthedocs.io/en/latest/configuration/suricata-yaml.html#detection-engine
做一个自定义规则的配置测试:
修改配置文件,增加一个规则文件 my.rules
[root@suricata suricata]# grep -A rule-files suricata.yaml
rule-files:
- my.rules
[root@suricata suricata]# cat rules/my.rules
alert tcp any any -> any 80 (msg: "http test";)
[root@suricata suricata]#
重启suricata之后,做一条http访问, 将能在fast.log中,看见这条规则被命中.
[root@suricata suricata]# tailf /suricata/var/log/suricata/fast.log
//-::48.265375 [**] [::] http test [**] [Classification: (null)] [Priority: ] {TCP} 192.168.7.8: -> 66.102.251.33:
至此,基本前期准备已经完成, 接下来就是去读源码了.....
题外: 装个splunk看一下, 结合suricata做分析,看一下.
安装手册: http://docs.splunk.com/Documentation/SplunkLight/7.0.2/Installation/InstallonLinux
说起了很简单,只有三步
To follow these installation instructions, replace splunk_package_name.tgz with the name of the installer package you downloaded. . Move the .tgz file to the directory you want to install Splunk Light. For example, to install it into /opt/splunk, use: mv splunk_package_name.tgz /opt/splunk
. In the installation directory, use the tar command to expand the file. tar xvzf splunk_package_name.tgz
. Start Splunk Light. splunk start --accept-license
登录: http://suricata:8000
配置也很简单,都是图像化操作, data input设置成 fast.log就好了.
然后,就是酱紫:
![[DPI][suricata] suricata 配置使用](https://image.shishitao.com:8440/aHR0cHM6Ly9pbWFnZXMyMDE3LmNuYmxvZ3MuY29tL2Jsb2cvMTAyODU0MC8yMDE4MDIvMTAyODU0MC0yMDE4MDIwODE2NDkyODk5OC03NTQyMzM1MzMucG5n.png?w=700 "[DPI][suricata] suricata 配置使用")
我想说, 这不就是个日志分析工具么?
我更喜欢,grep+sed+bash+awk --!!!!