I want to write about Cassandra performance tuning, but first I need to cover some basics: how to use vmstat, iostat, and top to understand what part of your system is the bottleneck -- not just for Cassandra but for any system.
procs -----------memory---------- ---swap-- -----io---- -system-- ----cpu---- r b swpd free buff cache si so bi bo in cs us sy id wa 20 0 195540 32772 6952 576752 0 0 11 12 38 43 1 0 99 0 22 2 195536 35988 6680 575132 6 0 2952 14 959 16375 72 21 4 3The first line is your total system average since boot; typically this will not be very useful, since you are interested in what is causing problems NOW. Then you will get one line per sample period; most of the output is self explanatory. The reason to start with vmstat is the "swap" section: si and so are swap in (memory read from disk) and swap out (memory written to disk). Remember that a little swapping is normal, particularly during application startup: by default, Linux will swap infrequently used pages of application memory to disk to free up more room for disk caching, even if there is enough ram to accommodate all applications.
Device: rrqm/s wrqm/s r/s w/s rsec/s wsec/s avgrq-sz avgqu-sz await svctm %util sda 9.80 0.20 36.60 0.40 5326.40 4.80 144.09 0.06 1.62 1.41 5.20There are 3 easy ways to tell if a disk is a probable bottleneck here, and none of them show up without the -x flag, so get in the habit of using that. "avgqu-sz" is the size of the io request queue; if it is large, there are lots of requests waiting in line. "await" is how long (in ms) the average request took to be satisfied (including time enqueued); recall that on non-SSDs, a single seek is between 5 and 10ms. Finally, "%util" is Linux's guess at how fully saturated the device is.
- "P" and "M" toggle between sorting by cpu usage and sorting by memory usage
- "1" toggles breaking down the CPU summary by CPU core
- SHR (shared memory) is included in RES (resident memory)
- Amount of memory belonging to a process that has been swapped out is VIRT - RES
- a state (S column) of D means the process (or thread, see below) is waiting for disk or network i/o
- "steal" is how much CPU the hypervisor is giving to another VM in a virtual environment; as virtual provisioning becomes more common, avoiding noisy neighbors is increasingly important
"top -H" will split out individual threads into their own lines; both per-process and per-thread views are useful. The per-thread view is particularly useful when dealing with Java applications since you can easily correlate them with thread names from the JVM to see which threads are consuming your CPU. Briefly, you take the PID (thread ID) from top, convert it to hex -- e.g., "python -c 'print hex(12345)'" -- and match it with the corresponding thread ID from jstack.
Now you can troubleshoot with a process like: "Am I swapping? If so, what processes are using all the memory? If my application makes a lot of disk read requests, are my reads being cached or are they actually hitting the disk? If I am hitting the disk, is it saturated? How much 'hot data' can I have before I run out of cache room? Are any/all of my cpu cores maxed? Which threads are actually using the CPU? Which threads spend most of their time waiting for i/o?" Then if you go to ask for help tuning something, you can show that you've done your homework.
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Which is spiffy since I had no idea that it would do that till just now : )
Nitpickery: VIRT also includes things like file-backed memory (e. g. code from the executable and shared libraries that hasn't been demand-loaded), so VIRT - RES is not precisely equal to the amount of swap used for the app. Things like the X server also include video memory and register space in their VIRT, and often seem to eat much more memory than they really do.
Recently I just came across a good article on "100 Linux Tips and Tricks"
Here is its link.