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Performance Monitoring Tools for Linux

Mr. Gavin provides tools for systems data collection and display and discusses what information is needed and why.

by David Gavin

For the last few years, I have been supporting users on various flavors of UNIX systems and have found the System Accounting Reports data invaluable for performance analysis. When I began using Linux for my personal workstation, the lack of a similar performance data collection and reporting tool set was a real problem. It's hard to get management to upgrade your system when you have no data to back up your claims of ``I need more POWER!''. Thus, I started looking for a package to get the information I needed, and found out there wasn't any. I fell back on the last resort--I wrote my own, using as many existing tools as possible. I came up with scripts that collect data and display it graphically in an X11 window or hard copy.

What Do We Want to Know?

To get a good idea of how a system is performing, watch key system resources over a period of time to see how their usage and availability changes depending upon what's running on the system. The following categories of system resources are ones I wished to track.

CPU Utilization: The central processing unit, as viewed from Linux, is always in one of the following states:

By noting the percentage of time spent in each state, we can discover overloading of one state or another. Too much idle means nothing is being done; too much system time indicates a need for faster I/O or additional devices to spread the load. Each system will have its own profile when running its workload, and by watching these numbers over time, we can determine what's normal for that system. Once a baseline is established, we can easily detect changes in the profile.

Interrupts: Most I/O devices use interrupts to signal the CPU when there is work for it to do. For example, SCSI controllers will raise an interrupt to signal that a requested disk block has been read and is available in memory. A serial port with a mouse on it will generate an interrupt each time a button is pressed/released or when the mouse is moved. Watching the count of each interrupt can give you a rough idea of how much load the associated device is handling.

Context Switching: Time slicing is the term often used to describe how computers can appear to be doing multiple jobs at once. Each task is given control of the system for a certain ``slice'' of time, and when that time is up, the system saves the state of the running process and gives control of the system to another process, making sure that the necessary resources are available. This administrative process is called context switching. In some operating systems, the cost of this switching can be fairly expensive, sometimes using more resources than the processes it is switching. Linux is very good in this respect, but by watching the amount of this activity, you will learn to recognize when a system has a lot of tasks actively consuming resources.

Memory: When many processes are running and using up available memory, the system will slow down as processes get paged or swapped out to make room for other processes to run. When the time slice is exhausted, that task may have to be written out to the paging device to make way for the next process. Memory-utilization graphs help point out memory problems.

Paging: As mentioned above, when available memory begins to get scarce, the virtual memory system will start writing pages of real memory out to the swap device, freeing up space for active processes. Disk drives are fast, but when paging gets beyond a certain point, the system can spend all of its time shuttling pages in and out. Paging on a Linux system can also be increased by the loading of programs, as Linux ``demand pages'' each portion of an executable as needed.

Swapping: Swapping is much like paging. However, it migrates entire process images, consisting of many pages of memory, from real memory to the swap devices rather than the usual page-by-page mechanism normally used for paging.

Disk I/O: Linux keeps statistics on the first four disks; total I/O, reads, writes, block reads and block writes. These numbers can show uneven loading of multiple disks and show the balance of reads versus writes.

Network I/O: Network I/O can be used to diagnose problems and examine loading of the network interface(s). The statistics show traffic in and out, collisions, and errors encountered in both directions.

These charts can also help in the following instances:

This sort of information will often show up as a spike in the charts at times when the system should have been idle. Sudden increases in activity can also be due to jobs run by crontab.

Collecting the Data

The file /proc/stat contains current counters for most of the data I wanted, and it is in a readable format. In order to keep the collector script as quick and simple as possible, I saved the data in a readable format rather than as binary data.

Breaking down and reorganizing the data for storage was a good job for awk, writing the data out to different files depending on the type of data. The /proc files are formatted nicely for this; each record has an identifying name in the first field. Here's a sample of /proc/stat from my 486 system:

cpu 1228835 394 629667 23922418
disk 43056 111530 0 0
disk_rio 18701 20505 0 0
disk_wio 24355 91025 0 0
disk_rblk 37408 40690 0 0
disk_wblk 48710 182050 0 0
page 94533 204827
swap 1 0
intr 27433973 25781314 58961 0 1059544 368102 1 2\
0 0 0 11133 154916 0 0 0 0
ctxt 18176677
btime 863065361
processes 18180
I dug into the kernel source for the /proc file system to figure out what the various fields were, as the man pages seem to date back to 1.x.

Network activity counters are found in the /proc/net/dev file; an example of this file is shown in Table 1.

The lines we want here are the ethx and pppx records. In the collector script, the data is written out to a file using the full interface name. This way, the script is generalized for most any configuration.

Memory utilization can be tracked in the /proc/meminfo file as shown in Table 2.

The memory counters are expressed twice in this file, so we need to save only the Mem: and Swap: records to get the whole picture. The script matches the keywords at the start of the line and writes the data out to individual files rather than to one large database to allow more flexibility as new fields or data types are added. This makes for a cluttered directory but simpler script writing.

The script that collects the data is shown in Listing 1. Here are some things that are going on in a few key parts, plus comments:

The following line in my crontab file runs the collection script every five minutes every hour of every day:

0,5,10,15,20,25,30,35,40,45,50,55 * * * *\
/var/log/sar/sa 0 0 * * * exec /usr/bin/find\
/var/log/sar/data/ -mtime +14
-exec /bin/rm -f {} \;
The data accumulates over the course of the day to provide the data points for analysis. A cleanup script invoked by the second line removes each file after two weeks to keep the disk space requirements down. A possible enhancement might be to compress each file after it is complete, but space hasn't been much of an issue yet.

What Do We Do with the Data?

I now had the data, but since columns of figures are boring, I needed a way to look at the data and make sense of it. I had used gnuplot for similar tools on other systems, so it seemed to be a good choice. I started with a script to display CPU utilization, charting the percentages of time spent in idle, user, system and nice states.

The cpu data file has five columns that look like this:

0000 4690259 69915 661038 7937582
0005 4690408 69964 661286 7966975
Column 1: seconds in idle state since last booted
Column 2: seconds in system state since last booted
Column 3: seconds in nice state since last booted
Column 4: seconds in user state since last booted
Column 5: time-stamp of observation (HHMM)

My reporting scheme was to get the amount of seconds spent in each state since the last observation, add up the different states and express each one as a percentage of the total. I ran into an interesting issue right away--what about a reboot? Booting the system zeroes out the counters and subtracting the old from the new generates negative values, so I had to handle it properly to provide useful information. I decided to watch for a counter value that was lower than the last observation's value and, if found, reset the prior values to zero. To make the chart more informative, a data point was set to 100 for a reboot and -1 for a normal record. The -1 value causes the data point to be outside the chart and thus not displayed.

Sometimes a hard copy is preferred when presentations or reports are needed. The gnuplot authors provide for a variety of output formats, and the script will switch between X11 display and PostScript output depending upon which option switches are set.

Figure 1. Sample Chart

Figure 1 is a sample chart produced by the graphing script shown in Listing 2. A breakdown of the major parts of this script is included in the archive file on SSC's FTP site, ftp://ftp.ssc.com/pub/lj/listings/issue56/2396.tgz. Also included are the collection script, graphing scripts, a sample crontab entry for running the collector script and the following charting scripts:

I'm currently converting this toolkit to Perl and building a web interface to allow these charts to be viewed as HTML pages with the charts as GIF files.

David Gavin has worked in various support environments since 1977, when after COBOL training, he had the good fortune to be assigned to the TSO (Time Sharing Option) support group. From there he moved to MVS technical support, to VM and to UNIX. He has worked with UNIX from mainframes to desktops, baby-sitting Microsoft systems only when he couldn't avoid it. He started using Linux back when it meant downloading twenty-five disks over a 2400 BAUD dial-up line. He can be reached at dgavin@unifi.com.

All listings referred to in this article are available by anonymous download in the file ftp://ftp.ssc.com/pub/lj/listings/issue56/2396.tgz.