4.4.4 Lab – Locating Log Files Answers
Lab – Locating Log Files (Answers Version)
Answers Note: Red font color or gray highlights indicate text that appears in the instructor copy only.
Objectives
In this lab, you will get familiar with locating and manipulating Linux log files.
Part 1: Log File Overview
Part 2: Locating Log Files in Unknown Systems
Part 3: Monitoring Log Files in Real Time
Required Resources
Instructions
Part 1: Log File Overview
Log files (also spelled logfiles), are files used by computers to log events. Software programs, background processes, services, or transactions between services, including the operating system itself, may generate such events. Log files are dependent on the application that generates them. It is up to the application developer to conform to log file convention. Software documentation should include information on its log files.
Step 1: Web server log file example
Because log files are essentially a way to track specific events, the type of information stored varies depending of the application or services generating the events.
- Consider the single log entry below. It was generated by Apache, a popular web server.
[Wed Mar 22 11:23:12.207022 2017] [core:error] [pid 3548:tid 4682351596] [client 209.165.200.230] File does not exist: /var/www/apache/htdocs/favicon.ico
The single log entry above represents a web event recorded by Apache. A few pieces of information are important in web transactions, including client IP address, time and details of the transaction. The entry above can be broken down into five main parts:
Timestamp: This part records when the event took place. It is very important that the server clock is correctly synchronized as it allows for accurately cross-referencing and tracing back events.
Type: This is the type of event. In this case, it was an error.
PID: This contains information about the process ID used by Apache at the moment.
Client: This records the IP address of the requesting client.
Description: This contains a description of the event.
Question:
Based on the log entry above, describe what happened.
Type your answers here.
On Wednesday, March 22nd, 11:23:12.207022 am of 2017, a client with IP address of 209.165.200.230 requested a non-existent file named favicon.ico. The file should have been located in the following path /var/www/apache/htdocs/favicon.ico, but because it could not be found, it triggered an error.
Use the cat command below to list a web server sample log file. The sample file is located at /var/log:
[analyst@secOps ~]$ cat /var/log/logstash-tutorial.log
83.149.9.216 – – [04/Jan/2015:05:13:42 +0000] “GET /presentations/logstash-monitorama-2013/images/kibana-search.png HTTP/1.1” 200 203023 “http://semicomplete.com/presentations/logstash-monitorama-2013/” “Mozilla/5.0 (Macintosh; Intel Mac OS X 10_9_1) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/32.0.1700.77 Safari/537.36″
83.149.9.216 – – [04/Jan/2015:05:13:42 +0000] “GET /presentations/logstash-monitorama-2013/images/kibana-dashboard3.png HTTP/1.1” 200 171717 “http://semicomplete.com/presentations/logstash-monitorama-2013/” “Mozilla/5.0 (Macintosh; Intel Mac OS X 10_9_1) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/32.0.1700.77 Safari/537.36″
83.149.9.216 – – [04/Jan/2015:05:13:44 +0000] “GET /presentations/logstash-monitorama-2013/plugin/highlight/highlight.js HTTP/1.1” 200 26185 “http://semicomplete.com/presentations/logstash-monitorama-2013/” “Mozilla/5.0 (Macintosh; Intel Mac OS X 10_9_1) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/32.0.1700.77 Safari/537.36”
<some output omitted>
Question:
Is the output above still considered a web transaction? Explain why the output of the cat command is in a different format than the single entry shown in item (a).
Type your answers here.
Yes, it is a web event. The fields are in a different order, but the GET message, the presence of client IP addresses, references to various web browsers and the HTTPv1.1, confirms this is a web server log file. The format is different because the service was configured to record different fields in a different order.
Step 2: Operating system log file example
Any software can keep log files, including the operating system itself. Conventionally, Linux uses the /var/log directory to stores various log files, including operating system logs. Modern operating systems are complex pieces of software and therefore use several different files to log events. This section takes a quick look at the /var/log/messages file.
- Stored under /var/log, the messages file stores various system events. The connection of new USB drive, a network card becoming available, and too many missed root login attempts, are a few examples of events logged to the /var/log/messages file. Use the more command to display the contents of the /var/log/messages file. Unlike the cat command, more allows for a paced navigation through the file. Press ENTER to advance line-by-line or SPACE to advance an entire page. Press q or CTRL + C to abort and exit more.
Note: the sudo command is required because the messages file belongs to the root user.
[analyst@secOps ~]$ sudo more /var/log/messages
[sudo] password for analyst:
Mar 20 08:34:38 secOps kernel: [6.149910] random: crng init done
Mar 20 08:34:40 secOps kernel: [8.280667] floppy0: no floppy controllers found
Mar 20 08:34:40 secOps kernel: [8.280724] work still pending
Mar 20 08:35:16 secOps kernel: [ 44.414695] hrtimer: interrupt took 5346452 ns
Mar 20 14:28:29 secOps kernel: [21239.566409] pcnet32 0000:00:03.0 enp0s3: link down
Mar 20 14:28:33 secOps kernel: [21243.404646] pcnet32 0000:00:03.0 enp0s3: link up, 100Mbps, full-duplex
Mar 20 14:28:35 secOps kernel: [21245.536961] pcnet32 0000:00:03.0 enp0s3: link down
Mar 20 14:28:43 secOps kernel: [21253.427459] pcnet32 0000:00:03.0 enp0s3: link up, 100Mbps, full-duplex
Mar 20 14:28:53 secOps kernel: [21263.449480] pcnet32 0000:00:03.0 enp0s3: link down
Mar 20 14:28:57 secOps kernel: [21267.500152] pcnet32 0000:00:03.0 enp0s3: link up, 100Mbps, full-duplex
Mar 20 14:29:01 secOps kernel: [21271.551499] pcnet32 0000:00:03.0 enp0s3: link down
Mar 20 14:29:05 secOps kernel: [21275.389707] pcnet32 0000:00:03.0 enp0s3: link up, 100Mbps, full-duplex
Mar 22 06:01:40 secOps kernel: [0.000000] Linux version 4.8.12-2-ARCH (builduser@andyrtr) (gcc version 6.2.1 20160830 (GCC) ) #1 SMP PREEMPT Fri Dec 2 20:41:47 CET 2016
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: Supporting XSAVE feature 0x001: ‘x87 floating point registers’
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: Supporting XSAVE feature 0x002: ‘SSE registers’
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: Supporting XSAVE feature 0x004: ‘AVX registers’
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: xstate_offset[2]: 576, xstate_sizes[2]: 256
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: Enabled xstate features 0x7, context size is 832 bytes, using ‘standard’ format.
Mar 22 06:01:40 secOps kernel: [0.000000] x86/fpu: Using ‘eager’ FPU context switches.
<some output omitted>
Notice that the events listed above are very different from the web server events. Because the operating system itself is generating this log, all recorded events are in relation to the OS itself.
- If necessary, enter Ctrl + C to exit out of the previous command.
- Log files are very important for troubleshooting. Assume that a user of that specific system reported that all network operations were slow around 4:20 am on May 19.
Question:
Can you find evidence of that in the log entries shown above? If so, in what lines? Explain.
Type your answers here.
On May 19, 04:19:53 through 04:21:27, the network card was flapping (switching from up to down quickly). The log entries clearly confirm the user report.
Part 2: Locating Log Files in Unknown Systems
The CyberOps Workstation VM includes nginx, a lightweight web server. This section will show how to find and display nginx logs using the CyberOps Workstation VM.
Note: nginx was installed on the CyberOps Workstation VM with its default settings. With default settings, its global configuration file is located under /etc/nginx/nginx.conf, its access log file is at /var/log/nginx/access.log, and errors are redirected to the terminal window. However, it is common for a security analyst to work on computers in which the installation details for tool and services are unknown. This section describes the process of locating such files described for nginx but is by no means complete. Nevertheless, it should be a good exercise about locating and displaying log files on unfamiliar systems.
- When working with new software, the first step is to look at the documentation. It provides important information about the software, including information about its log files. Use the man command to display the nginx manual page:
[analyst@secOps ~]$ man nginx
NGINX(8) BSD System Manager’s Manual NGINX(8)
NAME
nginx — HTTP and reverse proxy server, mail proxy server
SYNOPSIS
nginx [-?hqTtVv] [-c file] [-g directives] [-p prefix] [-s signal]
DESCRIPTION
nginx (pronounced “engine x”) is an HTTP and reverse proxy server, as well as a mail proxy
server. It is known for its high performance, stability, rich feature set, simple configura‐
tion, and low resource consumption.
<some output omitted>
- Scroll down the page to locate the nginx logging section. The documentation makes it clear that nginx supports logging, with the location of its log files defined at compilation time.
[PARTIAL OUTPUT EXTRACTED FROM NGINX MANUAL PAGE]
DEBUGGING LOG
To enable a debugging log, reconfigure nginx to build with debugging:
./configure –with-debug …
and then set the debug level of the error_log:
error_log /path/to/log debug;
It is also possible to enable the debugging for a particular IP address:
events {
debug_connection 127.0.0.1;
}
- The manual page also contains information on the files used by nginx. Scroll down further to display the nginx operating files under the Files section:
FILES
%%PID_PATH%%
Contains the process ID of nginx. The contents of this file are
not sensitive, so it can be world-readable.
%%CONF_PATH%%
The main configuration file.
%%ERROR_LOG_PATH%%
Error log file.
The outputs above help you to conclude that nginx supports logging and that it can save to log files. The output also hints at the existence of a configuration file for nginx.
- Before looking for nginx files, use the ps and the grep commands to ensure nginx is running in the VM.
Note: Use man to learn more about ps and grep commands.
[analyst@secOps ~]$ ps ax | grep nginx
415 ? Ss 0:00 nginx: master process /usr/bin/nginx -g pid /run/nginx.pid; error_log stderr;
416 ? S 0:00 nginx: worker process
1207 pts/0 S+ 0:00 grep nginx
The output above confirms that nginx is running. In addition, the output also displays the parameters used when nginx was started. nginx process ID is being stored in /run/nginx.pid and error messages are being redirected to the terminal.
Note: If nginx is not running, enter the sudo /usr/sbin/nginx at the prompt to start the service using the default configuration.
Note: If you need to restart nginx, you can kill the service by using the sudo pkill nginx command. To start nginx with the custom configuration from a previous lab, run the following command: sudo nginx -c custom_server.conf, and test the server by opening a web browser and going to URL: 127.0.0.1:8080. If you wish to start nginx with a default configuration you can start it with the command: sudo /usr/sbin/nginx, and open a web browser and go to URL: 127.0.0.1.
Because the location to the log files was not specified, the global nginx configuration file should be checked for the location of the log files.
- By design, the CyberOps Workstation VM utilizes default locations and definitions as much as possible. Conventionally, the /var/log directory holds various log files for various applications and services while configuration files are stored under the /etc directory. While the nginx manual page did not provide an exact location for its log files, it not only confirmed that nginx supports logging but also hinted at the location of a configuration file. Because the log file locations can often be customized in configuration files, a logical next step is to use the ls command to look under /etc and look for a nginx configuration file:
[analyst@secOps ~]$ ls /etc/
adjtime host.conf mke2fs.conf rc_maps.cfg
apache-ant hostname mkinitcpio.conf request-key.conf
apparmor.d hosts mkinitcpio.d request-key.d
arch-release ifplugd modprobe.d resolv.conf
avahi initcpio modules-load.d resolvconf.conf
bash.bash_logout inputrc motd rpc
bash.bashrc iproute2 mtab rsyslog.conf
binfmt.d iptables nanorc securetty
ca-certificates issue netconfig security
crypttab java-7-openjdk netctl services
dbus-1 java-8-openjdk netsniff-ng shadow
default kernel nginx shadow-
depmod.d krb5.conf nscd.conf shells
dhcpcd.conf ld.so.cache nsswitch.conf skel
dhcpcd.duid ld.so.conf ntp.conf ssh
dkms ld.so.conf.d openldap ssl
drirc libnl openvswitch sudoers
elasticsearch libpaper.d os-release sudoers.d
environment lightdm pacman.conf sudoers.pacnew
ethertypes locale.conf pacman.conf.pacnew sysctl.d
<output omitted>
- Notice the nginx folder under /etc in the output above. Using ls again, we find a number of files, including one named nginx.conf.
[analyst@secOps ~]$ ls -l /etc/nginx/
total 48
-rw-r–r– 1 root root 2730 Mar 21 16:02 custom_server.conf
-rw-r–r– 1 root root 1077 Nov 18 15:14 fastcgi.conf
-rw-r–r– 1 root root 1007 Nov 18 15:14 fastcgi_params
–rw-r–r– 1 root root 2837 Nov 18 15:14 koi-utf
–rw-r–r– 1 root root 2223 Nov 18 15:14 koi-win
–rw-r–r– 1 root root 2743 Jan 6 15:41 mal_server.conf
–rw-r–r– 1 root root 3957 Nov 18 15:14 mime.types
–rw-r–r– 1 root root 3264 Mar 22 13:34 nginx.conf
–rw-r–r– 1 root root 3261 Oct 19 16:42 nginx.conf.working
–rw-r–r– 1 root root 636 Nov 18 15:14 scgi_params
–rw-r–r– 1 root root 664 Nov 18 15:14 uwsgi_params
–rw-r–r– 1 root root 3610 Nov 18 15:14 win-utf
- Use the cat command to list the contents of /etc/nginx/nginx.conf. You can also use more or less to view the file and nano or SciTE to edit it. These tools make it easier to navigate through long text files (only the output of cat is displayed below).
[analyst@secOps ~]$ cat /etc/nginx/nginx.conf
#user html;
worker_processes 1;
#error_log logs/error.log;
#error_log logs/error.log notice;
#error_log logs/error.log info;
#pid logs/nginx.pid;
events {
worker_connections 1024;
}
<some output omitted>
Note: Lines that start with ‘#’ are comments and are ignored by nginx.
- A quick look at the configuration file reveals that it is an nginx configuration file. Because there is no direct mention to the location of nginx log files, it is very likely that nginx is using default values for it. Following the convention of storing log files under /var/log, use the ls command to list its contents:
[analyst@secOps ~]$ ls -l /var/log/
total 5708
–rw-r—– 1 root log 188962 Apr 19 10:35 auth.log
–rw-rw—- 1 root utmp 384 Apr 19 10:05 btmp
–rw-rw—- 1 root utmp 1536 Mar 22 08:50 btmp.1
–rw-r—– 1 root log 849038 Apr 19 10:05 daemon.log
–rw-r—– 1 root log 4416 Apr 19 09:45 errors.log
–rw-r—– 1 root log 1819814 Apr 19 10:05 everything.log
–rw——- 1 root root 32032 Apr 19 10:05 faillog
drwxr–sr-x+ 4 root systemd-journal 4096 Mar 20 15:28 journal
–rw-r—– 1 root log 927701 Apr 19 09:45 kernel.log
–rw–rw-r— 1 root utmp 292292 Mar 26 11:03 lastlog
drwx–x–x 2 root lightdm 4096 Apr 19 09:45 lightdm
–rw-r–r— 1 analyst analyst 24464 Apr 19 10:05 logstash-tutorial.log
–rw-r—– 1 root log 1673153 Apr 19 10:05 messages
drwxr–xr-x 2 root root 4096 Apr 19 10:28 nginx
-rw-r–r– 1 http root 989 Apr 19 10:05 nginx-logstash.log
drwxr–xr-x 2 root root 4096 Jan 5 14:17 old
–rw-r–r— 1 root root 97655 Apr 17 12:52 pacman.log
drwxr–xr-x 2 snort snort 4096 Mar 26 11:03 snort
–rw-r—– 1 root log 563 Apr 19 09:45 syslog.log
–rw——- 1 root root 64064 Mar 26 11:03 tallylog
–rw-r—– 1 root log 216 Apr 17 13:04 user.log
–rw–rw-r— 1 root utmp 70272 Apr 19 09:45 wtmp
–rw-r–r— 1 root root 24756 Apr 19 09:45 Xorg.0.log
–rw-r–r— 1 root root 25585 Apr 17 14:43 Xorg.0.log.old
- As shown above, the /var/log directory has a subdirectory named nginx. Use the ls command again to list the contents of /var/log/nginx.
Note: Because the /var/log/nginx belongs to the http user, you must execute ls as root by preceding it with the sudo command.
[analyst@secOps ~]$ sudo ls -l /var/log/nginx
[sudo] password for analyst:
total 16
–rw-r—– 1 http log 0 May 18 17:53 access.log
–rw-r—– 1 http log 175 May 6 09:42 access.log.1.gz
–rw-r—– 1 http log 593 May 5 16:58 access.log.2.gz
–rw-r—– 1 http log 193 Jul 19 2018 access.log.3.gz
–rw-r—– 1 http log 425 Apr 19 2018 access.log.4.gz
These are very likely to be the log files in use by nginx. Move on to the next section to monitor these files and get confirmation that they are indeed nginx log files.
Note: Your output may be different. The .GZ log files above were generated by a log rotation service. Linux systems often implement a service to rotate logs, ensuring that individual log files do not become too large. The log rotate service takes the latest log file, compresses it and saves it under a different name (access.log.1.gz, access.log.2.gz, etc). A new empty main log file is then created and used to store the latest log entries.
Part 3: Monitoring Log Files in Real Time
As seen in the previous sections, log files can be displayed with many text-presentation tools. While cat, more, less, and nano can be used to work with log files, they are not suitable for log file real-time monitoring. Developers designed various tools that allow for log file real-time monitoring. Some tools are text-based while others have a graphical interface. This lab focuses on tail, a simple but efficient tool, available in practically every Unix-based system.
The CyberOps Workstation VM uses a log rotating system to ensure that older logs are archived. By the time this lab gets used in class, some time will have passed and the log files will likely have been rotated. The result is that some log files, including the access.log file, could appear empty. To work around this problem and create some entries in access.log, simply open Firefox in the VM, point it to 127.0.0.1 and reload the page a few times.
Step 1: Using the tail command
The tail command displays the end of a text file. By default, tail will display the last ten (10) lines of a text file.
Note: If you do not see any log entries, navigate to 127.0.0.1 in a web browser and refresh the page a few time.
- Use the tail command to display the end of the /var/log/nginx/access.log.
[analyst@secOps ~]$ sudo tail /var/log/nginx/access.log
[sudo] password for analyst:
127.0.0.1 – – [21/May/2017:15:32:32 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/May/2017:15:32:34 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/May/2017:15:32:41 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/May/2017:15:32:41 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/May/2017:15:32:44 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:11:20:27 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:26 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:50 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:53 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:13:01:55 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
[analyst@secOps ~]$
Note: If you do not see any log entries, navigate to 127.0.0.1 in a web browser and refresh the page a few time.
- Use the –n option to specify how many lines from the end of a file, tail should display.
[analyst@secOps ~]$ sudo tail -n 5 /var/log/nginx/access.log
127.0.0.1 – – [22/May/2017:11:20:27 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:26 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:50 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:12:49:53 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/May/2017:13:01:55 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
[analyst@secOps ~]$
- You can use the tail command with the -f option to monitor the nginx access.log in real-time. Short for follow, -f tells tail to continuously display the end of a given text file. In a terminal window, issue tail with the –f option:
[analyst@secOps log]$ sudo tail -f /var/log/nginx/access.log
[sudo] password for analyst:
127.0.0.1 – – [21/Mar/2017:15:32:32 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/Mar/2017:15:32:34 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/Mar/2017:15:32:41 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/Mar/2017:15:32:41 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [21/Mar/2017:15:32:44 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/Mar/2017:11:20:27 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/Mar/2017:12:49:26 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/Mar/2017:12:49:50 -0400] “GET / HTTP/1.1” 304 0 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/Mar/2017:12:49:53 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
127.0.0.1 – – [22/Mar/2017:13:01:55 -0400] “GET /favicon.ico HTTP/1.1” 404 169 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
As before, tail displays the last 10 lines of the file. However, notice that tail does not exit after displaying the lines; the command prompt is not visible, indicating that tail is still running.
Note: Your /var/log/access.log file may be empty due to log rotation. Continue following the lab as an empty /var/log/access.log file will not impact the lab.
- With tail still running on the terminal window, click the web browser icon on the Dock to open a web browser window. Re-size the web browser window in a way that it allows you to see the bottom of the terminal window where tail is still running.
Note: In the screenshot below, the Enter key was pressed a few times in the terminal window running tail. This is for visualization only as tail does not process any input while running with –f. The extra empty lines make it easier to detect new entries, as they are displayed at the bottom of the terminal window.
- In the web browser address bar, enter 127.0.0.1 and press Enter. This is the address of the VM itself, which tells the browser to connect to a web server running on the local computer. A new entry should be recorded in the /var/log/nginx/access.log file. Refresh the webpage to see new entries added to the log.
127.0.0.1 – – [23/Mar/2017:09:48:36 -0400] “GET / HTTP/1.1” 200 612 “-” “Mozilla/5.0 (X11; Linux i686; rv:50.0) Gecko/20100101 Firefox/50.0”
Because tail is still running, it should display the new entry at the bottom of the terminal window. Aside from the timestamp, your entry should look like the one above.
Note: Firefox stores pages in cache for future use. If a page is already in cache, force Firefox to ignore the cache and place web requests, reload the page by pressing <CTRL+SHIFT+R>.
- Because the log file is being updated by nginx, we can state with certainty that /var/log/acess.log is in fact the log file in use by nginx.
- Enter Ctrl + C to end the tail monitoring session.
Step 2: BONUS TOOL: Journalctl
The CyberOps Workstation VM is based on Arch Linux. Categorized as a Linux distribution, Arch Linux is designed to be lightweight, minimalist and simple. As part of this design philosophy, Arch Linux uses systemd as its init system. In Linux, the init process is the first process loaded when the computer boots. Init is directly or indirectly, the parent of all processes running on the system. It is started by the kernel at boot time and continues to run until the computer shuts down. Typically, init has the process ID 1.
An init system is a set of rules and conventions governing the way the user space in a given Linux system is created and made available to the user. Init systems also specify system-wide parameters such as global configuration files, logging structure and service management.
Systemd is a modern init system designed to unify Linux configuration and service behavior across all Linux distributions and has been increasingly adopted by major Linux distributions. Arch Linux relies on systemd for init functionality. The CyberOps Workstation VM also uses systemd.
system-journald (or simply journald) is systemd’s event logging service and uses append-only binary files serving as its log files. Notice that journald does not impede the use of other logging systems, such as syslog and rsyslog.
This section provides a brief overview of journalctl, a journald utility used for log viewing and real-time monitoring.
- In a terminal window in the CyberOps Workstation VM, issue the journalctl command with no options to display all journal log entries (it can be quite long):
[analyst@secOps ~]$ journalctl
Hint: You are currently not seeing messages from other users and the system.
Users in groups ‘adm‘, ‘systemd-journal’, ‘wheel’ can see all messages.
Pass -q to turn off this notice.
— Logs begin at Fri 2014-09-26 14:13:12 EDT, end at Fri 2017-03-31 09:54:58 EDT
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Starting Paths.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Reached target Paths.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Starting Timers.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Reached target Timers.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Starting Sockets.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Reached target Sockets.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Starting Basic System.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Reached target Basic System.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Starting Default.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Reached target Default.
Sep 26 14:13:12 dataAnalyzer systemd[1087]: Startup finished in 18ms.
Sep 26 14:14:24 dataAnalyzer systemd[1087]: Stopping Default.
<some output omitted>
The output begins with a line similar to the one below, marking the timestamp where the system started logging. Notice that the timestamps will vary from system to system.
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:12:19 EDT. –-
journalctl includes a number of functionalities such as page scrolling, color-coded messages and more. Use the keyboard up/down arrow keys to scroll up/down the output, one line at a time. Use the left/right keyboard arrow keys to scroll sideways and display log entries that span beyond the boundaries of the terminal window. The <ENTER> key displays the next line while the space bar displays the next page in the output. Press the q key to exit journalctl.
Notice the hint message provided by journalctl:
Hint: You are currently not seeing messages from other users and the system.
Users in groups ‘adm‘, ‘systemd-journal’, ‘wheel’ can see all messages.
Pass -q to turn off this notice.
This message reminds you that, because analyst is a regular user and not a member of either the adm, systemd-journal or wheel groups, not all log entries will be displayed by journalctl. It also states that running journalctl with the –q option suppresses the hint message.
Question:
How can you run journalctl and see all log entries?
Type your answers here.
Running journalctl as the root user will display all entries. To run journalctl as root, prepend the sudo command to journalctl: sudo journalctl.
- journalctl includes options to help in filtering the output. Use the –b option to display boot-related log entries:
[analyst@secOps ~]$ sudo journalctl -b
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:18:04 EDT. —
Mar 31 05:54:43 secOps systemd-journald[169]: Time spent on flushing to /var is 849us for 0 entries.
Mar 31 05:54:43 secOps kernel: Linux version 4.8.12-2-ARCH (builduser@andyrtr) (gcc version 6.2.1 20160830 (GCC) ) #1 SMP PREEM
Mar 31 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x001: ‘x87 floating point registers’
Mar 31 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x002: ‘SSE registers’
Mar 31 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x004: ‘AVX registers’
Mar 31 05:54:43 secOps kernel: x86/fpu: xstate_offset[2]: 576, xstate_sizes[2]: 256
Mar 31 05:54:43 secOps kernel: x86/fpu: Enabled xstate features 0x7, context size is 832 bytes, using ‘standard’ format.
Mar 31 05:54:43 secOps kernel: x86/fpu: Using ‘eager’ FPU context switches.
Mar 31 05:54:43 secOps kernel: e820: BIOS-provided physical RAM map:
Mar 31 05:54:43 secOps kernel: BIOS-e820: [mem 0x0000000000000000-0x000000000009fbff] usable
Mar 31 05:54:43 secOps kernel: BIOS-e820: [mem 0x000000000009fc00-0x000000000009ffff] reserved
Mar 31 05:54:43 secOps kernel: BIOS-e820: [mem 0x00000000000f0000-0x00000000000fffff] reserved
Mar 31 05:54:43 secOps kernel: BIOS-e820: [mem 0x0000000000100000-0x000000007ffeffff] usable
<some output omitted>
- To see entries related to the last boot, add the -1 to the command above. To see entries related to the two last boots, add the -2 option.
[analyst@secOps ~]$ sudo journalctl –b -2
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:21:03 EDT. —
Mar 22 09:35:11 secOps systemd-journald[181]: Time spent on flushing to /var is 4.204ms for 0 entries.
Mar 22 09:35:11 secOps kernel: Linux version 4.8.12-2-ARCH (builduser@andyrtr) (gcc version 6.2.1 20160830 (GCC) ) #1 SMP PREEM
Mar 22 09:35:11 secOps kernel: x86/fpu: Supporting XSAVE feature 0x001: ‘x87 floating point registers’
Mar 22 09:35:11 secOps kernel: x86/fpu: Supporting XSAVE feature 0x002: ‘SSE registers’
Mar 22 09:35:11 secOps kernel: x86/fpu: Supporting XSAVE feature 0x004: ‘AVX registers’
Mar 22 09:35:11 secOps kernel: x86/fpu: xstate_offset[2]: 576, xstate_sizes[2]: 256
Mar 22 09:35:11 secOps kernel: x86/fpu: Enabled xstate features 0x7, context size is 832 bytes, using ‘standard’ format.
Mar 22 09:35:11 secOps kernel: x86/fpu: Using ‘eager’ FPU context switches.
Mar 22 09:35:11 secOps kernel: e820: BIOS-provided physical RAM map:
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x0000000000000000-0x000000000009fbff] usable
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x000000000009fc00-0x000000000009ffff] reserved
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x00000000000f0000-0x00000000000fffff] reserved
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x0000000000100000-0x000000007ffeffff] usable
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x000000007fff0000-0x000000007fffffff] ACPI data
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x00000000fec00000-0x00000000fec00fff] reserved
Mar 22 09:35:11 secOps kernel: BIOS-e820: [mem 0x00000000fee00000-0x00000000fee00fff] reserved
<some output omitted>
- Use the —list-boots option to list previous boots:
[analyst@secOps ~]$ sudo journalctl –-list-boots
-144 fbef03a1b59c40429f3e083613ab775a Fri 2014-09-26 13:22:51 EDT—Fri 2014-09-26 14:05:00 EDT
-143 69ebae646d6b41f0b3de9401cb3aa591 Fri 2014-09-26 14:05:07 EDT—Fri 2014-09-26 20:35:29 EDT
-142 73a305f65dea41e787b164411dfc6750 Fri 2014-09-26 20:35:34 EDT—Fri 2014-09-26 20:52:22 EDT
-141 48a113d5d2f44979a849c9c0d9ecdfa2 Fri 2014-09-26 20:52:33 EDT—Fri 2014-09-26 21:08:35 EDT
-140 002af74c3fc44008a882384f546c438d Fri 2014-09-26 21:08:45 EDT—Fri 2014-09-26 21:16:39 EDT
-139 f3ca1d06495c4e26b367e6867f03374c Fri 2014-09-26 21:16:47 EDT—Fri 2014-09-26 21:50:19 EDT
-138 bd232f288e544a79aa3bc444e02185a8 Fri 2014-09-26 21:50:28 EDT—Fri 2014-09-26 22:33:13 EDT
-137 2097c11f249c431aa8ad8da31a5b26d1 Fri 2014-09-26 22:40:39 EDT—Fri 2014-09-26 23:55:46 EDT
-136 b24d5e718a724b18b352e9b2daed3db6 Sat 2014-09-27 10:57:32 EDT—Sat 2014-09-27 14:26:43 EDT
-135 5a189fc68352484a8b40cd719ff7dd41 Sat 2014-09-27 19:44:23 EDT—Sat 2014-09-27 22:50:24 EDT
-134 d0be08c1f26642a1a20bb70bfc7b722c Mon 2014-09-29 09:17:14 EDT—Mon 2014-09-29 12:12:10 EDT
-133 b00b0d4c07464071b0d3cac4eb79dda3 Mon 2014-09-29 12:39:12 EDT—Mon 2014-09-29 13:24:38 EDT
<some output omitted>
- Use the —since “<time range>” to specify the time range of which log entries should be displayed. The two commands below display all log entries generated in the last two hours and in the last day, respectively:
[analyst@secOps ~]$ sudo journalctl –-since “2 hours ago”
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:28:29 EDT. —
Mar 31 09:54:45 secOps kernel: 00:00:00.008577 main 5.1.10 r112026 started. Verbose level = 0
Mar 31 09:54:45 secOps systemd[1]: Time has been changed
Mar 31 09:54:45 secOps systemd[1]: Started Rotate log files.
Mar 31 09:54:45 secOps ovsdb–server[263]: 2017-03-31T13:54:45Z|00001|ovsdb_server|INFO|ovsdb-server (Open vSwitch) 2.6.1
Mar 31 09:54:45 secOps ovsdb–server[263]: ovs|00001|ovsdb_server|INFO|ovsdb-server (Open vSwitch) 2.6.1
Mar 31 09:54:45 secOps kernel: openvswitch: Open vSwitch switching datapath
Mar 31 09:54:45 secOps systemd[1]: Started Open vSwitch Daemon.
Mar 31 09:54:45 secOps dhcpcd[279]: enp0s3: soliciting an IPv6 router
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00001|ovs_numa|INFO|Discovered 1 CPU cores on NUMA node 0
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00002|ovs_numa|INFO|Discovered 1 NUMA nodes and 1 CPU cores
Mar 31 09:54:45 secOps ovs-vswitchd[319]: ovs|00001|ovs_numa|INFO|Discovered 1 CPU cores on NUMA node 0
Mar 31 09:54:45 secOps ovs-vswitchd[319]: ovs|00002|ovs_numa|INFO|Discovered 1 NUMA nodes and 1 CPU cores
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00003|reconnect|INFO|unix:/run/openvswitch/db.sock: connecting..
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00004|reconnect|INFO|unix:/run/openvswitch/db.sock: connected
Mar 31 09:54:45 secOps ovs-vswitchd[319]: ovs|00003|reconnect|INFO|unix:/run/openvswitch/db.sock: connecting…
Mar 31 09:54:45 secOps ovs-vswitchd[319]: ovs|00004|reconnect|INFO|unix:/run/openvswitch/db.sock: connected
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00005|ovsdb_idl|WARN|Interface table in Open_vSwitch database la
Mar 31 09:54:45 secOps ovs-vswitchd[319]: 2017-03-31T13:54:45Z|00006|ovsdb_idl|WARN|Mirror table in Open_vSwitch database lacks
<some output omitted>
[analyst@secOps ~]$ sudo journalctl –-since “1 day ago“
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:26:48 EDT. —
Mar 30 05:54:43 secOps systemd-journald[169]: Time spent on flushing to /var is 849us for 0 entries.
Mar 30 05:54:43 secOps kernel: Linux version 4.8.12-2-ARCH (builduser@andyrtr) (gcc version 6.2.1 20160830 (GCC) ) #1 SMP PREEM
Mar 30 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x001: ‘x87 floating point registers’
Mar 30 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x002: ‘SSE registers’
Mar 30 05:54:43 secOps kernel: x86/fpu: Supporting XSAVE feature 0x004: ‘AVX registers’
Mar 30 05:54:43 secOps kernel: x86/fpu: xstate_offset[2]: 576, xstate_sizes[2]: 256
Mar 31 05:54:43 secOps kernel: x86/fpu: Enabled xstate features 0x7, context size is 832 bytes, using ‘standard’ format.
Mar 30 05:54:43 secOps kernel: x86/fpu: Using ‘eager’ FPU context switches.
Mar 30 05:54:43 secOps kernel: e820: BIOS-provided physical RAM map:
Mar 30 05:54:43 secOps kernel: BIOS-e820: [mem 0x0000000000000000-0x000000000009fbff] usable
Mar 30 05:54:43 secOps kernel: BIOS-e820: [mem 0x000000000009fc00-0x000000000009ffff] reserved
Mar 30 05:54:43 secOps kernel: BIOS-e820: [mem 0x00000000000f0000-0x00000000000fffff] reserved
<some output omitted>
- journalctl also allows for displaying log entries related to a specific service with the –u option. The command below displays logs entries related to nginx:
[analyst@secOps ~]$ sudo journalctl –u nginx.service
— Logs begin at Fri 2014-09-26 13:22:51 EDT, end at Fri 2017-03-31 10:30:39 EDT. —
Oct 19 16:47:57 secOps systemd[1]: Starting A high performance web server and a reverse proxy server…
Oct 19 16:47:57 secOps nginx[21058]: 2016/10/19 16:47:57 [warn] 21058#21058: conflicting server name “localhost” on 0.0.0.0:80,
Oct 19 16:47:57 secOps systemd[1]: nginx.service: PID file /run/nginx.pid not readable (yet?) after start: No such file or dire
Oct 19 16:47:57 secOps systemd[1]: Started A high performance web server and a reverse proxy server.
Oct 19 17:40:09 secOps nginx[21058]: 2016/10/19 17:40:09 [error] 21060#21060: *1 open() “/usr/share/nginx/html/favicon.ico” fai
Oct 19 17:40:09 secOps nginx[21058]: 2016/10/19 17:40:09 [error] 21060#21060: *1 open() “/usr/share/nginx/html/favicon.ico” fai
Oct 19 17:41:21 secOps nginx[21058]: 2016/10/19 17:41:21 [error] 21060#21060: *2 open() “/usr/share/nginx/html/favicon.ico” fai
Oct 19 17:41:21 secOps nginx[21058]: 2016/10/19 17:41:21 [error] 21060#21060: *2 open() “/usr/share/nginx/html/favicon.ico” fai
Oct 19 18:36:33 secOps systemd[1]: Stopping A high performance web server and a reverse proxy server…
Oct 19 18:36:33 secOps systemd[1]: Stopped A high performance web server and a reverse proxy server.
— Reboot —
Oct 19 18:36:49 secOps systemd[1]: Starting A high performance web server and a reverse proxy server…
Oct 19 18:36:49 secOps nginx[399]: 2016/10/19 18:36:49 [warn] 399#399: conflicting server name “localhost” on 0.0.0.0:80, ignor
Oct 19 18:36:49 secOps systemd[1]: nginx.service: PID file /run/nginx.pid not readable (yet?) after start: No such file or dire
Oct 19 18:36:49 secOps systemd[1]: Started A high performance web server and a reverse proxy server.
<some output omitted>
Note: As part of systemd, services are described as units. Most service installation packages create units and enable units during the installation process.
- Similar to tail –f, journalctl also supports real-time monitoring. Use the –f option to instruct journalctl to follow a specific log. Press Ctrl + C to exit.
[analyst@secOps ~]$ sudo journalctl -f
[sudo] password for analyst:
— Logs begin at Fri 2014-09-26 13:22:51 EDT. —
Mar 31 10:34:15 secOps filebeat[222]: 2017/03/31 14:34:15.077058 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:34:40 secOps sudo[821]: pam_unix(sudo:session): session closed for user root
Mar 31 10:34:45 secOps filebeat[222]: 2017/03/31 14:34:45.076057 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:35:15 secOps filebeat[222]: 2017/03/31 14:35:15.076118 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:35:45 secOps filebeat[222]: 2017/03/31 14:35:45.076924 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:36:15 secOps filebeat[222]: 2017/03/31 14:36:15.076060 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:36:45 secOps filebeat[222]: 2017/03/31 14:36:45.076122 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:37:15 secOps filebeat[222]: 2017/03/31 14:37:15.076801 logp.go:232: INFO No non-zero metrics in the last 30s
Mar 31 10:37:30 secOps sudo[842]: analyst : TTY=pts/0 ; PWD=/home/analyst ; USER=root ; COMMAND=/usr/bin/journalctl -f
Mar 31 10:37:31 secOps sudo[842]: pam_unix(sudo:session): session opened for user root by (uid=0)
<some output omitted>
- journalctl also supports mixing options to achieve the desired filter set. The command below monitors nginx system events in real time.
[analyst@secOps ~]$ sudo journalctl -u nginx.service -f
— Logs begin at Fri 2014-09-26 13:22:51 EDT. —
Mar 23 10:08:41 secOps systemd[1]: Stopping A high performance web server and a reverse proxy server…
Mar 23 10:08:41 secOps systemd[1]: Stopped A high performance web server and a reverse proxy server.
— Reboot —
Mar 29 11:28:06 secOps systemd[1]: Starting A high performance web server and a reverse proxy server…
Mar 29 11:28:06 secOps systemd[1]: nginx.service: PID file /run/nginx.pid not readable (yet?) after start: No such file or directory
Mar 29 11:28:06 secOps systemd[1]: Started A high performance web server and a reverse proxy server.
Mar 29 11:31:45 secOps systemd[1]: Stopping A high performance web server and a reverse proxy server…
Mar 29 11:31:45 secOps systemd[1]: Stopped A high performance web server and a reverse proxy server.
— Reboot —
Mar 31 09:54:51 secOps systemd[1]: Starting A high performance web server and a reverse proxy server…
Mar 31 09:54:51 secOps systemd[1]: nginx.service: PID file /run/nginx.pid not readable (yet?) after start: No such file or directory
Mar 31 09:54:51 secOps systemd[1]: Started A high performance web server and a reverse proxy server.
- Keep the command above running, open a new web browser window and type 127.0.0.1 (default configuration) or 127.0.0.1:8080 (custom_server.conf) in the address bar. journalctl should display an error related to a missing favicon.ico file in real-time. Use Ctrl+C to quit journalctl.
Reflection
Log files are extremely important for troubleshooting.
Log file location follows convention but ultimately, it is a choice of the developer.
More often than not, log file information (location, file names, etc.) is included in the documentation. If the documentation does not provide useful information on log files, a combination of web research, and system investigation should be used.
Clocks should always be synchronized to ensure all systems have the correct time. If clocks are not correctly set, it is very difficult to trace back events.
It is important to understand when specific events took place. In addition to that, events from different sources are often analyzed at the same time.