Personal blog of Yzmir Ramirez

Prometheus 2 time series database (TSDB) is an amazing piece of engineering, offering a dramatic improvement compared to “v2” storage in Prometheus 1 in terms of ingest performance, query performance and resource use efficiency. As we’ve been adopting Prometheus 2 in Percona Monitoring and Management (PMM), I had a chance to look into the performance of Prometheus 2 TSDB. This blog post details my observations.

Understanding the typical Prometheus workload

For someone who has spent their career working with general purpose databases, the typical workload of Prometheus is quite interesting. The ingest rate tends to remain very stable: typically, devices you monitor will send approximately the same amount of metrics all the time, and infrastructure tends to change relatively slowly.

Queries to the data can come from multiple sources. Some of them, such as alerting, tend to be very stable and predictable too. Others, such as users exploring data, can be spiky, though it is not common for this to be largest part of the load.

The Benchmark

In my assessment, I focused on handling an ingest workload. I had deployed Prometheus 2.3.2 compiled with Go 1.10.1 (as part of PMM 1.14)  on Linode using this StackScript.  For a maximally realistic load generation, I spin up multiple MySQL nodes running some real workloads (Sysbench TPC-C Test) , with each emulating 10 Nodes running MySQL and Linux using this StackScript

The observations below are based on a Linode instance with eight virtual cores and 32GB of memory, running  20 load driving simulating the monitoring of 200 MySQL instances. Or, in Prometheus Terms, some 800 targets; 440 scrapes/sec 380K samples ingested per second and 1.7M of active time series.

Design Observations

The conventional approach of traditional databases, and the approach that Prometheus 1.x used, is to limit amount of memory. If this amount of memory is not enough to handle the load, you will have high latency and some queries (or scrapes) will fail. Prometheus 2 memory usage instead is configured by

storage.tsdb.min-block-duration

   which determines how long samples will be stored in memory before they are flushed (the default being 2h). How much memory it requires will depend on the number of time series, the number of labels you have, and your scrape frequency in addition to the raw ingest rate. On disk, Prometheus tends to use about three bytes per sample. Memory requirements, though, will be significantly higher.

While the configuration knob exists to change the head block size, tuning this by users is discouraged. So you’re limited to providing Prometheus 2 with as much memory as it needs for your workload.

If there is not enough memory for Prometheus to handle your ingest rate, then it will crash with out of memory error message or will be killed by OOM killer.

Adding more swap space as a “backup” in case Prometheus runs out of RAM does not seem to work as using swap space causes a dramatic memory usage explosion. I suspect swapping does not play well with Go garbage collection.

Another interesting design choice is aligning block flushes to specific times, rather than to time since start:

As you can see from this graph, flushes happen every two hours, on the clock. If you change min-block-duration  to 1h, these flushes will happen every hour at 30 minutes past the hour.

(If you want to see this and other graphs for your Prometheus Installation you can use this Dashboard. It has been designed for PMM but can work for any Prometheus installation with little adjustments.)

While the active block—called head block— is kept in memory, blocks containing older blocks are accessed through

mmap()

  This eliminates the need to configure cache separately, but also means you need to allocate plenty of memory for OS Cache if you want to query data older than fits in the head block.

It also means the virtual memory you will see Prometheus 2 using will get very high: do not let it worry you.

Another interesting design choice is WAL configuration. As you can see in the storage documentation, Prometheus protects from data loss during a crash by having WAL log. The exact durability guarantees, though, are not clearly described. As of Prometheus 2.3.2, Prometheus flushes the WAL log every 10 seconds, and this value is not user configurable.

Compactions

Prometheus TSDB is designed somewhat similar to the LSM storage engines – the head block is flushed to disk periodically, while at the same time, compactions to merge a few blocks together are performed to avoid need to scan too many blocks for queries

Here is the number of data blocks I observed on my system after a 24h workload:

If you want more details about storage, you can check out the meta.json file which has additional information about the blocks you have, and how they came about.

{
       "ulid": "01CPZDPD1D9R019JS87TPV5MPE",
       "minTime": 1536472800000,
       "maxTime": 1536494400000,
       "stats": {
               "numSamples": 8292128378,
               "numSeries": 1673622,
               "numChunks": 69528220
       },
       "compaction": {
               "level": 2,
               "sources": [
                       "01CPYRY9MS465Y5ETM3SXFBV7X",
                       "01CPYZT0WRJ1JB1P0DP80VY5KJ",
                       "01CPZ6NR4Q3PDP3E57HEH760XS"
               ],
               "parents": [
                       {
                               "ulid": "01CPYRY9MS465Y5ETM3SXFBV7X",
                               "minTime": 1536472800000,
                               "maxTime": 1536480000000
                       },
                       {
                               "ulid": "01CPYZT0WRJ1JB1P0DP80VY5KJ",
                               "minTime": 1536480000000,
                               "maxTime": 1536487200000
                       },
                       {
                               "ulid": "01CPZ6NR4Q3PDP3E57HEH760XS",
                               "minTime": 1536487200000,
                               "maxTime": 1536494400000
                       }
               ]
       },
       "version": 1
}

Compactions in Prometheus are triggered at the time the head block is flushed, and several compactions may be performed at these intervals:

Compactions do not seem to be throttled in any way, causing huge spikes of disk IO usage when they run:

And a spike in CPU usage:

This, of course, can cause negative impact to the system performance. This is also why it is one of the greatest questions in LSM engines: how to run compactions to maintain great query performance, but not cause too much overhead.

Memory utilization as it relates to the compaction process is also interesting:

We can see after compaction a lot of memory changes from “Cached”  to “Free”, meaning potentially valuable data is washed out from memory. I wonder if

fadvice()

 or other techniques to minimize data washout from cache are in use, or if this is caused by the fact that the blocks which were cached are destroyed by the compaction process

Crash Recovery

Crash recovery from the log file takes time, though it is reasonable. For an ingest rate of about 1 mil samples/sec, I observed some 25 minutes recovery time on SSD storage:

level=info ts=2018-09-13T13:38:14.09650965Z caller=main.go:222 msg="Starting Prometheus" version="(version=2.3.2, branch=v2.3.2, revision=71af5e29e815795e9dd14742ee7725682fa14b7b)"
level=info ts=2018-09-13T13:38:14.096599879Z caller=main.go:223 build_context="(go=go1.10.1, user=Jenkins, date=20180725-08:58:13OURCE)"
level=info ts=2018-09-13T13:38:14.096624109Z caller=main.go:224 host_details="(Linux 4.15.0-32-generic #35-Ubuntu SMP Fri Aug 10 17:58:07 UTC 2018 x86_64 1bee9e9b78cf (none))"
level=info ts=2018-09-13T13:38:14.096641396Z caller=main.go:225 fd_limits="(soft=1048576, hard=1048576)"
level=info ts=2018-09-13T13:38:14.097715256Z caller=web.go:415 component=web msg="Start listening for connections" address=:9090
level=info ts=2018-09-13T13:38:14.097400393Z caller=main.go:533 msg="Starting TSDB ..."
level=info ts=2018-09-13T13:38:14.098718401Z caller=repair.go:39 component=tsdb msg="found healthy block" mint=1536530400000 maxt=1536537600000 ulid=01CQ0FW3ME8Q5W2AN5F9CB7R0R
level=info ts=2018-09-13T13:38:14.100315658Z caller=web.go:467 component=web msg="router prefix" prefix=/prometheus
level=info ts=2018-09-13T13:38:14.101793727Z caller=repair.go:39 component=tsdb msg="found healthy block" mint=1536732000000 maxt=1536753600000 ulid=01CQ78486TNX5QZTBF049PQHSM
level=info ts=2018-09-13T13:38:14.102267346Z caller=repair.go:39 component=tsdb msg="found healthy block" mint=1536537600000 maxt=1536732000000 ulid=01CQ78DE7HSQK0C0F5AZ46YGF0
level=info ts=2018-09-13T13:38:14.102660295Z caller=repair.go:39 component=tsdb msg="found healthy block" mint=1536775200000 maxt=1536782400000 ulid=01CQ7SAT4RM21Y0PT5GNSS146Q
level=info ts=2018-09-13T13:38:14.103075885Z caller=repair.go:39 component=tsdb msg="found healthy block" mint=1536753600000 maxt=1536775200000 ulid=01CQ7SV8WJ3C2W5S3RTAHC2GHB
level=error ts=2018-09-13T14:05:18.208469169Z caller=wal.go:275 component=tsdb msg="WAL corruption detected; truncating" err="unexpected CRC32 checksum d0465484, want 0" file=/opt/prometheus/data/.prom2-data/wal/007357 pos=15504363
level=info ts=2018-09-13T14:05:19.471459777Z caller=main.go:543 msg="TSDB started"
level=info ts=2018-09-13T14:05:19.471604598Z caller=main.go:603 msg="Loading configuration file" filename=/etc/prometheus.yml
level=info ts=2018-09-13T14:05:19.499156711Z caller=main.go:629 msg="Completed loading of configuration file" filename=/etc/prometheus.yml
level=info ts=2018-09-13T14:05:19.499228186Z caller=main.go:502 msg="Server is ready to receive web requests."

The problem I observed with recovery is that it is very memory intensive. While the server may be capable of handling the normal load with memory to spare if it crashes, it may not be able to ever recover due to running out of memory.  The only solution I found for this is to disable scraping, let it perform crash recovery, and then restarting the server with scraping enabled

Warmup

Another behavior to keep in mind is the need for warmup – a lower performance/higher resource usage ratio immediately after start. In some—but not all—starts I can observe significantly higher initial CPU and memory usage

The gaps in the memory utilization graph show that Prometheus is not initially able to perform all the scrapes configured, and as such some data is lost.

I have not profiled what exactly causes this extensive CPU and memory consumption. I suspect these might be happening when new time series entries are created, at head block, and at high rate.

CPU Usage Spikes

Besides compaction—which is quite heavy on the Disk IO—I also can observe significant CPU spikes about every 2 minutes. These are longer with a higher ingest ratio. These seem to be caused by Go Garbage Collection during these spikes: at least some CPU cores are completely saturated

These spikes are not just cosmetic. It looks like when these spikes happen, the Prometheus internal /metrics endpoint becomes unresponsive, thus producing data gaps during the exact time that the spikes occur:

We can also see the Prometheus Exporter hitting a one second timeout:

We can observe this correlates with garbage collection:

Conclusion

Prometheus 2 TSDB offers impressive performance, being able to handle a cardinality of millions of time series, and also to handle hundreds of thousands of samples ingested per second on rather modest hardware. CPU and disk IO usage are both very impressive. I got up to 200K/metrics/sec per used CPU core!

For capacity planning purposes you need to ensure that you have plenty of memory available, and it needs to be real RAM. The actual amount of memory I observed was about 5GB per 100K/samples/sec ingest rate, which with additional space for OS cache, makes it 8GB or so.

There is work that remains to be done to avoid CPU and IO usage spikes, though this is not unexpected considering how young Prometheus 2 TSDB is – if we look at InnoDB, TokuDB, RocksDB, WiredTiger all of them had similar problem in their initial releases.

The post Prometheus 2 Times Series Storage Performance Analyses appeared first on Percona Database Performance Blog.

Percona has revealed the line-up of in-depth tutorials for the Percona Live Europe 2018 Open Source Database Conference, taking place November 5–7, 2018 at the Radisson Blu Hotel in Frankfurt, Germany. Secure your spot now with Advanced Registration prices. Be sure to buy your tickets soon as tickets prices will only head up, not down! Sponsorship opportunities for the conference are still available.

Percona Live Europe 2018 Open Source Database Conference is the premier open source database event. Our theme this year is “Connect. Accelerate. Innovate.”  Percona Live is the place to learn about how open source database technology can power your applications, improve your websites and solve your critical database issues.

Monday, November 5: Tutorial Day

Tutorials take place throughout the day on Monday, November 5. Tutorials are three hours and provide practical, in-depth knowledge exchange on critical open source database issues. The line up includes:

• Query Optimization with MySQL 8.0 and MariaDB 10.3: The Basics with Jaime Crespo – Wikimedia Foundation
• Hands on ProxySQL with René Cannaò – ProxySQL
• ElasticSearch 101 with Antonios Giannopoulos – ObjectRocket
• MySQL Performance Schema in Action: the Complete Tutorial with Sveta Smirnova and Alexander Rubin – Percona
• MySQL InnoDB Cluster in a Nutshell : The Saga Continues with 8.0 with Frédéric Descamps – Oracle
• Introduction to PostgreSQL for MySQL and Oracle DBAs with Avinash Vallarapu – Percona
• InnoDB Architecture and Optimization with Peter Zaitsev – Percona
• MongoDB: Replica Sets and Sharded Clusters with Adamo Tonete – Percona
• High Availability PostgreSQL and Kubernetes with Google Cloud presented by Alexis Guajardo – Google
• Open Source Database Performance Optimization and Monitoring with PMM with Michael Coburn, Vinicius Grippa, and Avinash Vallarapu – Percona
• Percona XtraDB Cluster Tutorial presented by Tibor Köröcz – Percona
• Mastering PostgreSQL Administration with Bruce Momjian – EnterpriseDB

… and a sneak peak at some of the sessions…

Of course, we have a stellar line up of talks, too! Here’s a tantalising glimpse of just some of the talks you could MISS if you don’t head to Frankfurt in November…

Tuesday 6th November

• Percona Server 8.0 – Laurynas Biveinis – Percona
• MySQL 8.0 Performance: Scalability & Benchmarks – Dimitri Kravtchuk – Oracle
• MySQL Group Replication : the magic explained – Frédéric Descamps – Oracle
• Explaining the Postgres Query Optimizer – Bruce Momjian – EnterpriseDB
• TLS for MySQL at large scale – Jaime Crespo – Wikimedia Foundation
• BlaBlaCar – 100% Containers Powered Carpooling – Maxime Fouilleul – BlaBlaCar
• A Year in Google Cloud – Carmen Mason, Alan Mason – VitalSource Technologies
• Demystifying MySQL Replication Crash Safety – Jean-François Gagné
• MongoDB Shard 101 – Adamo Tonete, Vinodh Krishnaswamy – Percona
• Highway to Hell or Stairway to Cloud? – Alexander Kukushkin – Zalando
• MongoDB administration cool tips – Gabriel Ciciliani – Pythian

Wednesday 7th November

• PostgreSQL Enterprise Features – Michael Banck – credativ GmbH
• Open Source Databases and Non-Volatile Memory – Frank Ober – Intel Memory Group
• MariaDB 10.3 Optimizer and beyond – Vicentiu Ciorbaru – MariaDB Foundation
• MariaDB system-versioned tables – Federico Razzoli – PayProp

A shout out to our fantastic Conference Committee who have been working hard to review the tutorial and talk submissions: we had over 200! Thank you!

The Radisson Blu Hotel, Frankfurt

Percona Live 2018 Open Source Database Conference will be held at the Radisson Blu Hotel, Frankfurt Franklinstraße 65, 60486 Frankfurt am Main, Germany

The Radisson Blu enjoys an enviable location in the Bockenheim District, just off the A66 motorway – only one kilometer from Messe Frankfurt, one of the world’s largest exhibition complexes. They’re also just 10 minutes from the city center, and Frankfurt International Airport (FRA) is a quick 15-minute drive away.

Book your hotel using Percona’s special room block rate, available only until September 20.

Sponsorships

Sponsorship opportunities for Percona Live Europe 2018 Open Source Database Conference are available and offer the opportunity to interact with the DBAs, sysadmins, developers, CTOs, CEOs, business managers, technology evangelists, solution vendors, and entrepreneurs who typically attend the event. Contact events@percona.com for sponsorship details.

The post Tutorial Schedule for Percona Live Europe 2018 Is Live appeared first on Percona Database Performance Blog.

A few months ago I wrote a blog post on How to Capture Per Process Metrics in PMM. Since that time, Nick Cabatoff has made a lot of improvements to Process Exporter and I’ve improved the Grafana Dashboard to match.

I will not go through installation instructions, they are well covered in original blog post.  This post covers features available in release 0.4.0 Here are a few new features you might find of interest:

Used Memory

Memory usage in Linux is complicated.  You can look at resident memory, which shows how much space is used in RAM. However, if you have a substantial part of process swapped out because of memory pressure, you would not see it. You can also look at virtual memory–but it will include a lot of address space which was allocated and never mapped either to RAM or to swap space.   Especially for processes written in Go, the difference can be extreme. Let’s look at the process exporter itself: it uses 20MB of resident memory but over 2GB of virtual memory.

Meet the Used Memory dashboard, which shows the sum of resident memory used by the process and swap space used:

There is dashboard to see process by swap space used as well, so you can see if some processes that you expect to be resident are swapped out.

Processes by Disk IO

Processes by Disk IO is another graph which I often find very helpful. It is the most useful for catching the unusual suspects, when the process causing the IO is not totally obvious.

Context Switches

Context switches, as shown by VMSTAT, are often seen as an indication of contention. With contention stats per process you can see which of the process are having those context switches.

Note: while large number of context switches can be a cause of high contention, some applications and workloads are just designed in such a way. You are better off looking at the change in the number of context switches, rather than at the raw number.

CPU and Disk IO Saturation

As Brendan Gregg tells us, utilization and saturation are not the same. While CPU usage and Disk IO usage graphs show us resource utilization by different processes, they do not show saturation.

For example, if you have four CPU cores then you can’t get more than four CPU cores used by any process, whether there are four or four hundred concurrent threads trying to run.

While being rather volatile as gauge metrics, top running processes and top processes waiting on IO are good metrics to understand which processes are prone to saturation.

These graphs roughly provide a breakdown of “r” and “b”  VMSTAT columns per process

Kernel Waits

Finally, you can see which kernel function (WCHAN) the process is sleeping on, which can be very helpful to access processes which are not using a lot of CPU, but are not making much progress either.

I find this graph most useful if you pick the single process in the dashboard picker:

In this graph we can see sysbench has most threads sleeping in

unix_stream_read_generic

  which corresponds to reading the response from MySQL from UNIX socket – exactly what you would expect!

Summary

If you ever need to understand what different processes are doing in your system, then Nick’s Process Exporter is a fantastic tool to have. It just takes few minutes to get it added into your PMM installation.

If you enjoyed this post…

You might also like my pre-recorded webinar MySQL troubleshooting and performance optimization with PMM.

The post Monitoring Processes with Percona Monitoring and Management appeared first on Percona Database Performance Blog.

Please join Percona’s Senior Support Engineer, Adamo Tonete, as he presents Percona Server for MongoDB vs MongoDB Enterprise on Wednesday, September 19th, 2018, at 12:30 PM PDT (UTC-7) / 3:30 PM EDT (UTC-4).

In this webinar we will evaluate MongoDB Community, MongoDB Enterprise Advanced, and Percona Server for MongoDB side-by-side to better inform the decision making process. Percona Server for MongoDB features enterprise-grade functionalities and runs on tools like Percona Monitoring and Management to monitor MongoDB. Even more, it is 100% free and open source. It is also worth mentioning that MongoDB Enterprise Advanced comes with encryption and LDAP authorization. Accordingly, we will walk through those features and much more.

Register for this webinar to learn more about Percona Server for MongoDB vs MongoDB Enterprise.

The post Upcoming Webinar Wed 9/19: Percona Server for MongoDB vs MongoDB Enterprise appeared first on Percona Database Performance Blog.

In my previous blog post, I showed how to deploy Percona Monitoring and Management (PMM) on Linode manually. It is pretty simple, but with a little coding it can be done even more easily using StackScripts

Here’s how:

1. Click on the “Add a Linode” and pick a Linode type you want to deploy.

2. Click on the deployed Linode and then click on the “Rebuild” Link

3. Click on Deploy Using StackScripts

4. On the resulting page search for “PMM” and pick PMMServer from PerconaLab.

5. Provide the host name for new Linode, pick the root password and click on “Rebuild”

6. Boot the server.

7.  You’re done. Wait for about 5 minutes for the installation to complete, then you can see PMM interface by going to this Linode IP

If you think that a manual deployment with StackScripts is not much less hassle than doing it manually, you’re right. The real benefit comes with using Linode API for deployment.

There are multiple way to access this API, though for basic scripting I prefer the linode-cli tool for using the Linode API from the command line.

With linode-cli  you can deploy your PMM Server on Linode using this one liner:

linode-cli linodes create --label pmm-test  --root_pass MyRootPassword123 --stackscript_id 338458  --stackscript_data '{"hostname": "pmm-test"}'

Summary

As you can see, with Linode StackScripts you can get going with Percona Monitoring and Management on Linode in no time, especially if you chose to use the Linode API.

You might also like:

Here’s an overview from the Percona Monitoring and Management manual on deploying PMM. If you are new to PMM and would like to know more, you will find lots of resources on this site including my webinar MySQL Troubleshooting and Performance Optimization with PMM.

The post How To Deploy PMM on Linode With StackScripts appeared first on Percona Database Performance Blog.

Percona Monitoring and Management (PMM) is a free and open-source platform for managing and monitoring MySQL® and MongoDB® performance. You can run PMM in your own environment for maximum security and reliability. It provides thorough time-based analysis for MySQL® and MongoDB® servers to ensure that your data works as efficiently as possible.

We’re releasing hotfix 1.14.1 to address three issues found post-release of 1.14.0:

• PMM-2963: Upgrading to PMM 1.14.0 fails due to attempting to create already existing Dashboard
  • Our upgrade script incorrectly tried to create dashboards that already existed, and generating failure message:

    A folder or dashboard in the general folder with the same name already exists

• PMM-2958: Grafana did not update to 5.1 when upgrading from versions older than 1.11
  • We identified a niche case where PMM installations that were upgraded from < 1.11 would fail to upgrade Grafana to correct release 5.1 (Users were left on Grafana 5.0)

The post Percona Monitoring and Management (PMM) 1.14.1 Is Now Available appeared first on Percona Database Performance Blog.

Percona Monitoring and Management (PMM) is a free and open-source platform for managing and monitoring MySQL® and MongoDB® performance. You can run PMM in your own environment for maximum security and reliability. It provides thorough time-based analysis for MySQL® and MongoDB® servers to ensure that your data works as efficiently as possible.

We’ve included a plethora of visual improvements in this release, including:

• PostgreSQL Metrics Collection – Visualize PostgreSQL performance!
• Identify New Queries in Query Analytics
• New Dashboard: Compare System Parameters
• New Dashboard: PERFORMANCE_SCHEMA Wait Events Analysis
• Dashboard Updates – Advanced Data Exploration, MyRocks, TokuDB, InnoDB Metrics
• Disable SSL between Prometheus and Exporters
• Dashboards grouped by Folder – We’ve organized the Dashboard drop-down to present a cleaner interface

We addressed 16 new features and improvements, and fixed 20 bugs.

pmm-admin add mysql --disable-ssl ...

The post Percona Monitoring and Management (PMM) 1.14.0 Is Now Available appeared first on Percona Database Performance Blog.

Do you need to modify the metrics collected from Linux by Percona Monitoring and Management (PMM)? In this blog post we will see how to enable, disable, and update collected metrics on PMM’s linux:metrics exporter. 

We will assume that the PMM client packages are installed, and they are configured already.

Using a custom list of metrics

Let’s now suppose we are not yet collecting any metrics on our desired client server, and we want to enable only the following: diskstats, meminfo, netdev and vmstat. We can use the following command:

pmm-admin add linux:metrics -- -collectors.enabled=diskstats,meminfo,netdev,vmstat

So, in order to enable or disable the functionality we want, we need to modify the collectors.enabled list accordingly. In the following online documentation page, we are able to find all collectors supported:

https://www.percona.com/doc/percona-monitoring-and-management/section.exporter.node.html

In this way, by adding or removing items from the collectors.enabled list, we can choose which functionality will be set in our PMM linux:metrics collectors.

Checking list of metrics used

We can use the ps aux command to check the collectors list that applies at any given time. Let’s see this in practical terms. After running the previous command, we should expect to see the following:

shell> ps aux | grep node_exporter
...
root     20450 3.2  0.0 1660248 15924 ?       Sl 13:48 0:13 /usr/local/percona/pmm-client/node_exporter -collectors.enabled=diskstats,filefd,filesystem,loadavg,meminfo,netdev,netstat,stat,time,uname,vmstat,meminfo_numa -web.listen-address=10.10.8.141:42000 -web.auth-file=/usr/local/percona/pmm-client/pmm.yml -web.ssl-cert-file=/usr/local/percona/pmm-client/server.crt -web.ssl-key-file=/usr/local/percona/pmm-client/server.key -collectors.enabled=diskstats,meminfo,netdev,vmstat

Note: there is currently a bug where you will see duplicate entries when using custom collectors. We are tracking this under issue PMM-2857. For now, if you see two different lists on ps aux outputs, the one that applies is the last one (as seen above).

Updating the list of metrics

There is currently no way to enable (or disable) metrics dynamically (however, we are working on it). We will need to stop the collector, manually get and edit the metrics list, and re-add it with the updated collectors in place. For this, we will need to know the current list of metrics used from the ps aux outputs.

Continuing with the same example, suppose we are not happy with what netdev metrics offer, and we wish to disable them to avoid unnecessary overhead. Knowing the metrics list was:

-collectors.enabled=diskstats,meminfo,netdev,vmstat

We will need to run the following commands to have it removed from the collectors list:

pmm-admin stop linux:metrics
pmm-admin rm linux:metrics
pmm-admin add linux:metrics -- -collectors.enabled=diskstats,meminfo,vmstat

Links for reference

• Passing options to exporter: here and here
• Collector options for linux:metrics exporter: here

Did you find this post useful?

You might also enjoy some of our other resources. Check out some of these recent technical webinars on using PMM, presented by my colleagues from Percona:

• Migrating to AWS Aurora, Monitoring AWS Aurora with PMM a joint webinar with the team from Autodesk
• MySQL Troubleshooting and Performance Optimization with PMM presented by our CEO, Peter Zaitsev

The post Modifying List of Collected Metrics on PMM Linux Exporter appeared first on Percona Database Performance Blog.

In his excellent blog post, Pavel Trukhanov showed the value of S.M.A.R.T. metric collections, so I wondered how hard would it be to enable their collection in Percona Monitoring and Management (PMM)

A quick search led me to the  text_collector plugin SmartMon, which can be easily integrated with any Prometheus Installation

For PMM, Vadim Yalovets recently showed how to do custom integrations based on text_collector

Let’s put those together:

1. Ensure you have the smartctl tool installed. It is available in repositories for most Linux distributions
2. Get  smartmon.sh and place it in /usr/local/bin or other location
3. Install the cron job

   echo  "*/5 * * * * root bash  /usr/local/bin/smartmon.sh > /tmp/smart_metrics.prom  " > /etc/cron.d/smartmon

4. Enable textfile_collector as described in this blog post

That’s it! You should get your data flowing. Now you can use Prometheus to query device information:

Or if you want to get a specific S.M.A.R.T value, such as media_wearout indicator:

If you would like to see a nicer visualization in Grafana, you can install the appropriate dashboard from the Grafana web site.

The number and kind of metrics you’re going to get depends on the storage device vendor and model. Here is an example list from one of my test systems:

# HELP smartmon_smartctl_version SMART metric smartctl_version
# TYPE smartmon_smartctl_version gauge
smartmon_smartctl_version{version="6.5"} 1
# HELP smartmon_current_pending_sector_raw_value SMART metric current_pending_sector_raw_value
# TYPE smartmon_current_pending_sector_raw_value gauge
smartmon_current_pending_sector_raw_value{disk="/dev/sda",type="sat",smart_id="197"} 0.000000e+00
# HELP smartmon_current_pending_sector_threshold SMART metric current_pending_sector_threshold
# TYPE smartmon_current_pending_sector_threshold gauge
smartmon_current_pending_sector_threshold{disk="/dev/sda",type="sat",smart_id="197"} 0
# HELP smartmon_current_pending_sector_value SMART metric current_pending_sector_value
# TYPE smartmon_current_pending_sector_value gauge
smartmon_current_pending_sector_value{disk="/dev/sda",type="sat",smart_id="197"} 100
# HELP smartmon_current_pending_sector_worst SMART metric current_pending_sector_worst
# TYPE smartmon_current_pending_sector_worst gauge
smartmon_current_pending_sector_worst{disk="/dev/sda",type="sat",smart_id="197"} 100
# HELP smartmon_device_info SMART metric device_info
# TYPE smartmon_device_info gauge
smartmon_device_info{disk="/dev/sda",type="sat",vendor="",product="",revision="",lun_id="",model_family="",device_model="Crucial_CT275MX300SSD1",serial_number="16431465B53F",firmware_version="M0CR031"} 1
# HELP smartmon_device_smart_available SMART metric device_smart_available
# TYPE smartmon_device_smart_available gauge
smartmon_device_smart_available{disk="/dev/sda",type="sat"} 1
# HELP smartmon_device_smart_enabled SMART metric device_smart_enabled
# TYPE smartmon_device_smart_enabled gauge
smartmon_device_smart_enabled{disk="/dev/sda",type="sat"} 1
# HELP smartmon_device_smart_healthy SMART metric device_smart_healthy
# TYPE smartmon_device_smart_healthy gauge
smartmon_device_smart_healthy{disk="/dev/sda",type="sat"} 1
# HELP smartmon_end_to_end_error_raw_value SMART metric end_to_end_error_raw_value
# TYPE smartmon_end_to_end_error_raw_value gauge
smartmon_end_to_end_error_raw_value{disk="/dev/sda",type="sat",smart_id="184"} 0.000000e+00
# HELP smartmon_end_to_end_error_threshold SMART metric end_to_end_error_threshold
# TYPE smartmon_end_to_end_error_threshold gauge
smartmon_end_to_end_error_threshold{disk="/dev/sda",type="sat",smart_id="184"} 0
# HELP smartmon_end_to_end_error_value SMART metric end_to_end_error_value
# TYPE smartmon_end_to_end_error_value gauge
smartmon_end_to_end_error_value{disk="/dev/sda",type="sat",smart_id="184"} 100
# HELP smartmon_end_to_end_error_worst SMART metric end_to_end_error_worst
# TYPE smartmon_end_to_end_error_worst gauge
smartmon_end_to_end_error_worst{disk="/dev/sda",type="sat",smart_id="184"} 100
# HELP smartmon_offline_uncorrectable_raw_value SMART metric offline_uncorrectable_raw_value
# TYPE smartmon_offline_uncorrectable_raw_value gauge
smartmon_offline_uncorrectable_raw_value{disk="/dev/sda",type="sat",smart_id="198"} 0.000000e+00
# HELP smartmon_offline_uncorrectable_threshold SMART metric offline_uncorrectable_threshold
# TYPE smartmon_offline_uncorrectable_threshold gauge
smartmon_offline_uncorrectable_threshold{disk="/dev/sda",type="sat",smart_id="198"} 0
# HELP smartmon_offline_uncorrectable_value SMART metric offline_uncorrectable_value
# TYPE smartmon_offline_uncorrectable_value gauge
smartmon_offline_uncorrectable_value{disk="/dev/sda",type="sat",smart_id="198"} 100
# HELP smartmon_offline_uncorrectable_worst SMART metric offline_uncorrectable_worst
# TYPE smartmon_offline_uncorrectable_worst gauge
smartmon_offline_uncorrectable_worst{disk="/dev/sda",type="sat",smart_id="198"} 100
# HELP smartmon_power_cycle_count_raw_value SMART metric power_cycle_count_raw_value
# TYPE smartmon_power_cycle_count_raw_value gauge
smartmon_power_cycle_count_raw_value{disk="/dev/sda",type="sat",smart_id="12"} 2.000000e+01
# HELP smartmon_power_cycle_count_threshold SMART metric power_cycle_count_threshold
# TYPE smartmon_power_cycle_count_threshold gauge
smartmon_power_cycle_count_threshold{disk="/dev/sda",type="sat",smart_id="12"} 0
# HELP smartmon_power_cycle_count_value SMART metric power_cycle_count_value
# TYPE smartmon_power_cycle_count_value gauge
smartmon_power_cycle_count_value{disk="/dev/sda",type="sat",smart_id="12"} 100
# HELP smartmon_power_cycle_count_worst SMART metric power_cycle_count_worst
# TYPE smartmon_power_cycle_count_worst gauge
smartmon_power_cycle_count_worst{disk="/dev/sda",type="sat",smart_id="12"} 100
# HELP smartmon_power_on_hours_raw_value SMART metric power_on_hours_raw_value
# TYPE smartmon_power_on_hours_raw_value gauge
smartmon_power_on_hours_raw_value{disk="/dev/sda",type="sat",smart_id="9"} 1.313300e+04
# HELP smartmon_power_on_hours_threshold SMART metric power_on_hours_threshold
# TYPE smartmon_power_on_hours_threshold gauge
smartmon_power_on_hours_threshold{disk="/dev/sda",type="sat",smart_id="9"} 0
# HELP smartmon_power_on_hours_value SMART metric power_on_hours_value
# TYPE smartmon_power_on_hours_value gauge
smartmon_power_on_hours_value{disk="/dev/sda",type="sat",smart_id="9"} 100
# HELP smartmon_power_on_hours_worst SMART metric power_on_hours_worst
# TYPE smartmon_power_on_hours_worst gauge
smartmon_power_on_hours_worst{disk="/dev/sda",type="sat",smart_id="9"} 100
# HELP smartmon_raw_read_error_rate_raw_value SMART metric raw_read_error_rate_raw_value
# TYPE smartmon_raw_read_error_rate_raw_value gauge
smartmon_raw_read_error_rate_raw_value{disk="/dev/sda",type="sat",smart_id="1"} 0.000000e+00
# HELP smartmon_raw_read_error_rate_threshold SMART metric raw_read_error_rate_threshold
# TYPE smartmon_raw_read_error_rate_threshold gauge
smartmon_raw_read_error_rate_threshold{disk="/dev/sda",type="sat",smart_id="1"} 0
# HELP smartmon_raw_read_error_rate_value SMART metric raw_read_error_rate_value
# TYPE smartmon_raw_read_error_rate_value gauge
smartmon_raw_read_error_rate_value{disk="/dev/sda",type="sat",smart_id="1"} 100
# HELP smartmon_raw_read_error_rate_worst SMART metric raw_read_error_rate_worst
# TYPE smartmon_raw_read_error_rate_worst gauge
smartmon_raw_read_error_rate_worst{disk="/dev/sda",type="sat",smart_id="1"} 100
# HELP smartmon_reallocated_sector_ct_raw_value SMART metric reallocated_sector_ct_raw_value
# TYPE smartmon_reallocated_sector_ct_raw_value gauge
smartmon_reallocated_sector_ct_raw_value{disk="/dev/sda",type="sat",smart_id="5"} 0.000000e+00
# HELP smartmon_reallocated_sector_ct_threshold SMART metric reallocated_sector_ct_threshold
# TYPE smartmon_reallocated_sector_ct_threshold gauge
smartmon_reallocated_sector_ct_threshold{disk="/dev/sda",type="sat",smart_id="5"} 10
# HELP smartmon_reallocated_sector_ct_value SMART metric reallocated_sector_ct_value
# TYPE smartmon_reallocated_sector_ct_value gauge
smartmon_reallocated_sector_ct_value{disk="/dev/sda",type="sat",smart_id="5"} 100
# HELP smartmon_reallocated_sector_ct_worst SMART metric reallocated_sector_ct_worst
# TYPE smartmon_reallocated_sector_ct_worst gauge
smartmon_reallocated_sector_ct_worst{disk="/dev/sda",type="sat",smart_id="5"} 100
# HELP smartmon_reported_uncorrect_raw_value SMART metric reported_uncorrect_raw_value
# TYPE smartmon_reported_uncorrect_raw_value gauge
smartmon_reported_uncorrect_raw_value{disk="/dev/sda",type="sat",smart_id="187"} 0.000000e+00
# HELP smartmon_reported_uncorrect_threshold SMART metric reported_uncorrect_threshold
# TYPE smartmon_reported_uncorrect_threshold gauge
smartmon_reported_uncorrect_threshold{disk="/dev/sda",type="sat",smart_id="187"} 0
# HELP smartmon_reported_uncorrect_value SMART metric reported_uncorrect_value
# TYPE smartmon_reported_uncorrect_value gauge
smartmon_reported_uncorrect_value{disk="/dev/sda",type="sat",smart_id="187"} 100
# HELP smartmon_reported_uncorrect_worst SMART metric reported_uncorrect_worst
# TYPE smartmon_reported_uncorrect_worst gauge
smartmon_reported_uncorrect_worst{disk="/dev/sda",type="sat",smart_id="187"} 100
# HELP smartmon_smartctl_run SMART metric smartctl_run
# TYPE smartmon_smartctl_run gauge
smartmon_smartctl_run{disk="/dev/sda",type="sat"} 1535666337
# HELP smartmon_temperature_celsius_raw_value SMART metric temperature_celsius_raw_value
# TYPE smartmon_temperature_celsius_raw_value gauge
smartmon_temperature_celsius_raw_value{disk="/dev/sda",type="sat",smart_id="194"} 3.100000e+01
# HELP smartmon_temperature_celsius_threshold SMART metric temperature_celsius_threshold
# TYPE smartmon_temperature_celsius_threshold gauge
smartmon_temperature_celsius_threshold{disk="/dev/sda",type="sat",smart_id="194"} 0
# HELP smartmon_temperature_celsius_value SMART metric temperature_celsius_value
# TYPE smartmon_temperature_celsius_value gauge
smartmon_temperature_celsius_value{disk="/dev/sda",type="sat",smart_id="194"} 69
# HELP smartmon_temperature_celsius_worst SMART metric temperature_celsius_worst
# TYPE smartmon_temperature_celsius_worst gauge
smartmon_temperature_celsius_worst{disk="/dev/sda",type="sat",smart_id="194"} 59
# HELP smartmon_udma_crc_error_count_raw_value SMART metric udma_crc_error_count_raw_value
# TYPE smartmon_udma_crc_error_count_raw_value gauge
smartmon_udma_crc_error_count_raw_value{disk="/dev/sda",type="sat",smart_id="199"} 0.000000e+00
# HELP smartmon_udma_crc_error_count_threshold SMART metric udma_crc_error_count_threshold
# TYPE smartmon_udma_crc_error_count_threshold gauge
smartmon_udma_crc_error_count_threshold{disk="/dev/sda",type="sat",smart_id="199"} 0
# HELP smartmon_udma_crc_error_count_value SMART metric udma_crc_error_count_value
# TYPE smartmon_udma_crc_error_count_value gauge
smartmon_udma_crc_error_count_value{disk="/dev/sda",type="sat",smart_id="199"} 100
# HELP smartmon_udma_crc_error_count_worst SMART metric udma_crc_error_count_worst
# TYPE smartmon_udma_crc_error_count_worst gauge
smartmon_udma_crc_error_count_worst{disk="/dev/sda",type="sat",smart_id="199"} 100

The post Monitoring S.M.A.R.T. Metrics with Prometheus and PMM appeared first on Percona Database Performance Blog.

One of the common ways to classify database workloads is whether it is  “read intensive” or “write intensive”. In other words, whether the workload is dominated by reads or writes.

Why should you care? Because recognizing if the workload is read intensive or write intensive will impact your hardware choices, database configuration as well as what techniques you can apply for performance optimization and scalability.

This question looks trivial on the surface, but as you go deeper—complexity emerges. There are different “levels” of reads and writes for you to consider. You can also choose to look at event counts or at the time it takes to do operations. These can provide very different responses, especially as the cost difference between a single read and a single write can be an order of magnitude.

Let’s examine the TPC-C Benchmark from this point of view, or more specifically its implementation in Sysbench. The illustrations below are taken from Percona Monitoring and Management (PMM) while running this benchmark.

Analyzing read/write workload by counts

At the highest level, you can think about queries that are sent to the database. In this case we can see about 30K of SELECT queries versus 20K of UPDATE+INSERT queries, making this benchmark slightly more read intensive by this measure.

Another way to look at the load is through actual operations at the row level – a single query may touch just one row or may touch millions. In this benchmark the difference between looking at workload from a SQL commands standpoint vs a row operation standpoint yields the same results, but it is not going to always be the case.

Let’s now look at the operating system level. We can see the amount of data written to the disk is 2x more than the amount of data being read from the disk. This workload is write intensive by this measure.

Yet another way to take a look at your workload is to take a look at it from the aspect of tables. This view shows us that tables are being mostly accessed for reads and writes. This in turn allows us to see whether a given table is getting more reads or writes. This is helpful, for example, if you are considering to move some of the tables to a different server and want to clearly understand how your workload will be impacted.

Analyzing Read/Write Workload by Response Time

As I mentioned already, the counts often do not reflect the time to respond, which is typically more representative of the real work being done. To look at timing information from query point of view, we want to look at query analytics.

The “Load” column here is a measure of such a combined response time, versus count which is reflective of query counts. Looking at this list we can see that three out of top five queries are SELECT queries. Looking at the numbers overall, we can see we have a read intensive application from this perspective.

In terms of row level operations, there is currently no easy way to see if reads or writes are dominating overall but  you can get an idea from the table operations dashboard:

This shows the load on a per table basis. It labels reads “Fetch” and breaks down writes in more detail—“Update”, “Delete”, “Inserts”—which is helpful. Not all writes are equal either.

If we want to look at a response time based view of read vs write on an operating system, we can check out this disk IO Load graph. You can see in this case it happens to match the IO activity graph, with storage taking more time to serve write requests versus read requests

Summary

As you can see, the question about whether a workload is read intensive or write intensive, while simple on the surface, can have many different answers. You might ask me “OK, so what should I use?” Well… it really depends.

Looking at query counts is a great way to understand the application’s demands on the database—you can’t really do anything to change the database size.  However by changing the database configuration and schema you may drastically alter the impact of these queries, both from the standpoint of the number of rows they crunch and in terms of the disk IO they require.

The response time based statistics, gathered from the impact your queries cause on the system or disk IO, provide a better representation of the load these queries currently generate.

Another thing to keep in mind—reads and writes are not created equal. My rule of thumb for InnoDB is that a single row write is about 10x more expensive than a single row read.

More resources that you might enjoy

If you found this post useful, you might also like to see some of Percona’s other resources.

For an introduction to PMM, our free and open source management and monitoring software, you might find value in my recorded webinar, MySQL Troubleshooting and Performance Optimization with PMM

While our white paper Performance at Scale could provide useful insight if you are at the planning or review stage.

The post Is It a Read Intensive or a Write Intensive Workload? appeared first on Percona Database Performance Blog.