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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2019-05-21 18:56:05 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2019-05-21 18:56:05 +0000 |
commit | 54deae27eed83a162ee438ef6bad4a23767757dd (patch) | |
tree | da5333377dfacf22177375aef822a8e696f007eb /database/engine/README.md | |
parent | Releasing debian version 1.14.0-1. (diff) | |
download | netdata-54deae27eed83a162ee438ef6bad4a23767757dd.tar.xz netdata-54deae27eed83a162ee438ef6bad4a23767757dd.zip |
Merging upstream version 1.15.0.
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r-- | database/engine/README.md | 109 |
1 files changed, 109 insertions, 0 deletions
diff --git a/database/engine/README.md b/database/engine/README.md new file mode 100644 index 000000000..28a2528cb --- /dev/null +++ b/database/engine/README.md @@ -0,0 +1,109 @@ +# Database engine + +The Database Engine works like a traditional +database. There is some amount of RAM dedicated to data caching and indexing and the rest of +the data reside compressed on disk. The number of history entries is not fixed in this case, +but depends on the configured disk space and the effective compression ratio of the data stored. + +## Files + +With the DB engine memory mode the metric data are stored in database files. These files are +organized in pairs, the datafiles and their corresponding journalfiles, e.g.: + +``` +datafile-1-0000000001.ndf +journalfile-1-0000000001.njf +datafile-1-0000000002.ndf +journalfile-1-0000000002.njf +datafile-1-0000000003.ndf +journalfile-1-0000000003.njf +... +``` + +They are located under their host's cache directory in the directory `./dbengine` +(e.g. for localhost the default location is `/var/cache/netdata/dbengine/*`). The higher +numbered filenames contain more recent metric data. The user can safely delete some pairs +of files when netdata is stopped to manually free up some space. + +*Users should* **back up** *their `./dbengine` folders if they consider this data to be important.* + +## Configuration + +There is one DB engine instance per netdata host/node. That is, there is one `./dbengine` folder +per node, and all charts of `dbengine` memory mode in such a host share the same storage space +and DB engine instance memory state. You can select the memory mode for localhost by editing +netdata.conf and setting: + +``` +[global] + memory mode = dbengine +``` + +For setting the memory mode for the rest of the nodes you should look at +[streaming](../../streaming/). + +The `history` configuration option is meaningless for `memory mode = dbengine` and is ignored +for any metrics being stored in the DB engine. + +All DB engine instances, for localhost and all other streaming recipient nodes inherit their +configuration from `netdata.conf`: + +``` +[global] + page cache size = 32 + dbengine disk space = 256 +``` + +The above values are the default and minimum values for Page Cache size and DB engine disk space +quota. Both numbers are in **MiB**. All DB engine instances will allocate the configured resources +separately. + +The `page cache size` option determines the amount of RAM in **MiB** that is dedicated to caching +netdata metric values themselves. + +The `dbengine disk space` option determines the amount of disk space in **MiB** that is dedicated +to storing netdata metric values and all related metadata describing them. + +## Operation + +The DB engine stores chart metric values in 4096-byte pages in memory. Each chart dimension gets +its own page to store consecutive values generated from the data collectors. Those pages comprise +the **Page Cache**. + +When those pages fill up they are slowly compressed and flushed to disk. +It can take `4096 / 4 = 1024 seconds = 17 minutes`, for a chart dimension that is being collected +every 1 second, to fill a page. Pages can be cut short when we stop netdata or the DB engine +instance so as to not lose the data. When we query the DB engine for data we trigger disk read +I/O requests that fill the Page Cache with the requested pages and potentially evict cold +(not recently used) pages. + +When the disk quota is exceeded the oldest values are removed from the DB engine at real time, by +automatically deleting the oldest datafile and journalfile pair. Any corresponding pages residing +in the Page Cache will also be invalidated and removed. The DB engine logic will try to maintain +between 10 and 20 file pairs at any point in time. + +The Database Engine uses direct I/O to avoid polluting the OS filesystem caches and does not +generate excessive I/O traffic so as to create the minimum possible interference with other +applications. + +## Memory requirements + +Using memory mode `dbengine` we can overcome most memory restrictions and store a dataset that +is much larger than the available memory. + +There are explicit memory requirements **per** DB engine **instance**, meaning **per** netdata +**node** (e.g. localhost and streaming recipient nodes): + +- `page cache size` must be at least `#dimensions-being-collected x 4096 x 2` bytes. + +- an additional `#pages-on-disk x 4096 x 0.06` bytes of RAM are allocated for metadata. + + - roughly speaking this is 6% of the uncompressed disk space taken by the DB files. + + - for very highly compressible data (compression ratio > 90%) this RAM overhead + is comparable to the disk space footprint. + +An important observation is that RAM usage depends on both the `page cache size` and the +`dbengine disk space` options. + +[![analytics](https://www.google-analytics.com/collect?v=1&aip=1&t=pageview&_s=1&ds=github&dr=https%3A%2F%2Fgithub.com%2Fnetdata%2Fnetdata&dl=https%3A%2F%2Fmy-netdata.io%2Fgithub%2Fdatabase%2Fengine%2FREADME&_u=MAC~&cid=5792dfd7-8dc4-476b-af31-da2fdb9f93d2&tid=UA-64295674-3)]() |