How the indexer stores indexes
As the indexer indexes your data, it creates a bunch of files. These files contain two types of data:
- The raw data in compressed form (rawdata)
- Indexes that point to the raw data, plus some metadata files (index files)
Together, these files constitute the Splunk Enterprise index. The files reside in sets of directories organized by age. Some directories contain newly indexed data; others contain previously indexed data. The number of such directories can grow quite large, depending on how much data you're indexing.
Why you might care
You might not care, actually. The indexer handles indexed data by default in a way that gracefully ages the data through several stages. After a long period of time, typically several years, the indexer removes old data from your system. You might well be fine with the default scheme it uses.
However, if you're indexing large amounts of data, have specific data retention requirements, or otherwise need to carefully plan your aging policy, you've got to read this topic. Also, to back up your data, it helps to know where to find it. So, read on....
How data ages
Each of the index directories is known as a bucket. To summarize so far:
- An "index" contains compressed raw data and associated index files.
- An index resides across many age-designated index directories.
- An index directory is a bucket.
A bucket moves through several stages as it ages:
As buckets age, they "roll" from one stage to the next. Newly indexed data goes into a hot bucket, which is a bucket that's both searchable and actively being written to. After the hot bucket reaches a certain size, it becomes a warm bucket ("rolls to warm"), and a new hot bucket is created. Warm buckets are searchable, but are not actively written to. There are many warm buckets.
Once the indexer has created some maximum number of warm buckets, it begins to roll the warm buckets to cold based on their age. Always, the oldest warm bucket rolls to cold. Buckets continue to roll to cold as they age in this manner. After a set period of time, cold buckets roll to frozen, at which point they are either archived or deleted. By editing attributes in indexes.conf, you can specify the bucket aging policy, which determines when a bucket moves from one stage to the next.
Here are the stages that buckets age through:
|Hot||Contains newly indexed data. Open for writing. One or more hot buckets for each index.||Yes|
|Warm||Data rolled from hot. There are many warm buckets.||Yes|
|Cold||Data rolled from warm. There are many cold buckets.||Yes|
|Frozen||Data rolled from cold. The indexer deletes frozen data by default, but you can also archive it. Archived data can later be thawed.||No|
The collection of buckets in a particular stage is sometimes referred to as a database or "db": the "hot db", the "warm db", the "cold db", etc.
Note: Hot buckets always roll when
splunkd gets restarted.
What the index directories look like
Each index occupies its own directory under
$SPLUNK_HOME/var/lib/splunk. The name of the directory is the same as the index name. Under the index directory are a series of subdirectories that categorize the buckets by status (hot/warm, cold, or thawed).
The buckets themselves are subdirectories within those directories. The bucket directory names are based on the age of the data.
Here is the directory structure for the default index (
|Bucket type||Default location||Notes|
||There can be multiple hot subdirectories. Each hot bucket occupies its own subdirectory, which uses this naming convention:
||There are separate subdirectories for each warm bucket. These are named as described below in "Warm/cold bucket naming convention".|
||There are multiple cold subdirectories. When warm buckets roll to cold, they get moved into this directory, but are not renamed.|
|Frozen||N/A: Frozen data gets deleted or archived into a directory location you specify.||Deletion is the default; see "Archive indexed data" for information on how to archive the data instead.|
||Location for data that has been archived and later thawed. See "Restore archived data" for information on restoring archived data to a thawed state.|
The paths for the hot/warm, cold, and thawed directories are configurable, so, for example, you can store cold buckets in a separate location from hot/warm buckets. See "Configure index storage" and "Use multiple partitions for index data".
Important: All index locations must be writable.
Note: In pre-6.0 versions of Splunk Enterprise, replicated copies of cluster buckets always resided in the
colddb directory, even if they were hot or warm buckets. Starting with 6.0, hot and warm replicated copies reside in the
db directory, the same as for non-replicated copies.
Warm/cold bucket naming convention
Bucket names identify the time range for the data they contain. The naming convention varies slightly, depending on whether the bucket rolled to warm while its indexer was functioning as a cluster peer:
- For non-clustered buckets:
- For clustered original bucket copies:
- For clustered replicated bucket copies:
<oldest_time>are timestamps indicating the age of the data within. The timestamps are expressed in UTC epoch time (in seconds). For example:
db_1223658000_1223654401_2835is a warm, non-clustered bucket containing data from October 10, 2008, covering the exact period of 9am-10am.
<localid>is an ID for the bucket, generated on the indexer on which the bucket originated.
guidof the peer node (indexer) on which the bucket originated. The
guidis located in the peer's
In an indexer cluster, the original buckets and its replicated copies have identical names, except for the prefix (
db for the original bucket;
rb for the copies).
Note: In an indexer cluster, when data is streaming from the originating peer to a target peer, the data first goes into a temporary directory on the target peer, which is identified by the originating peer's
<guid>, like this:
<localid>_<guid>. This is true, independent of the type of bucket the data is being streamed from. When the replication has completed, the directory is rolled into a warm bucket, identified by the
rb_ prefix, as described above. For an introduction to indexer cluster architecture and replicated data streaming, read "Basic indexer cluster architecture".
Important: The bucket naming convention is subject to change.
Buckets and Splunk Enterprise administration
When you're administering Splunk Enterprise, it helps to understand how the indexer stores indexes across buckets. In particular, several admin activities require a good understanding of buckets:
For information on setting a retirement and archiving policy, see "Set a retirement and archiving policy". You can base the retirement policy on either size or age of data.
For information on how to archive your indexed data, see "Archive indexed data". For information on archive signing, see "Configure archive signing" in the Security Manual. To learn how to restore data from archive, read "Restore archived data".
To learn how to back up your data, read "Back up indexed data". That topic also discusses how to manually roll hot buckets to warm (so that you can then back them up). Also, see "Best practices for backing up" on the Community Wiki.
For information on setting limits on disk usage, see "Set limits on disk usage".
For a list of configurable bucket settings, see "Configure index storage".
Troubleshoot your buckets
This section tells you how to deal with an assortment of bucket problems.
Recover after a crash
The indexer usually handles crash recovery without your intervention. If an indexer goes down unexpectedly, some recently received data might not be searchable. When you restart the indexer, it will automatically run the
fsck command in the background. This command diagnoses the health of your buckets and rebuilds search data as necessary.
It is highly unlikely that you will need to run
fsck manually. This is a good thing, because to run it manually, you must stop the indexer, and the command can take several hours to complete if your indexes are large. During that time your data will be inaccessible. However, if Splunk Support directs you to run it, the rest of this section tells you how to do so. (Also, you will need to run
fsck manually to perform recovery for any 4.2.x indexers. Only indexers at version 4.3 or above run it automatically.)
fsck manually, you'll need to first stop the indexer. Then run
fsck against any affected buckets. To run
fsck against buckets in all indexes, use this command:
splunk fsck repair --all-buckets-all-indexes
This will rebuild all types of buckets (hot/warm/cold) in all indexes.
fsck command only rebuilds buckets created by version 4.2 or later of Splunk Enterprise.
To learn more about the
fsck command, including a list of all options available, enter:
splunk fsck --help
fsck repair command can take as long as several hours to run, depending on the size of your indexes. That's why you want to let the indexer run it in the background automatically, if possible. Also, if you can determine that you only need to rebuild a few buckets, you can run the
rebuild command on just those buckets, as described in the next section, "Rebuild a bucket."
If you just want to diagnose the state of your indexes (without taking any immediate remedial action), run:
splunk fsck scan --all-buckets-all-indexes
Note: You cannot use
splunk fsck to repair a single bucket. Instead, use the
splunk rebuild command.
Rebuild a bucket
If the index and metadata files in a bucket (version 4.2 and later) somehow get corrupted, you can rebuild the bucket from the raw data file alone. Use this command:
splunk rebuild <bucket directory>
The indexer automatically deletes the old index and metadata files and rebuilds them. You don't need to delete any files yourself.
Important: You must stop the indexer before running the
A few notes:
- Rebuilding a bucket does not count against your license.
- The time required to rebuild a bucket can be significant. Depending on various system considerations, such as your hardware specifications, it can take anywhere from half an hour to a few hours to rebuild a 10 GB bucket.
Recover invalid pre-4.2 hot buckets
A hot bucket becomes an invalid hot (
invalid_hot_<ID>) bucket when the indexer detects that the metadata files (
Sources.data, Hosts.data, SourceTypes.data) are corrupt or incorrect. Incorrect data usually signifies incorrect time ranges; it can also mean that event counts are incorrect.
The indexer ignores invalid hot buckets. Data does not get added to such buckets, and they cannot be searched. Invalid buckets also do not count when determining bucket limit values such as
maxTotalDataSizeMB. This means that invalid buckets do not negatively affect the flow of data through the system, but it also means that they can result in disk storage that exceeds the configured maximum value.
To recover an invalid hot bucket, use the
1. Make backup copies of the metadata files,
Sources.data, Hosts.data, SourceTypes.data.
2. Rebuild the metadata from the raw data information:
splunk cmd recover-metadata path_to_your_hot_buckets/invalid_hot_<ID>
3. If successful, rename the bucket as it would normally be named.
Rebuild index-level bucket manifests
The index-level bucket manifest file is
.bucketManifest. It contains a list of all buckets in the index.
It is unusual to need to rebuild the manifest. One situation where you might need to do so is if you manually copy a bucket into an index.
Only rebuild the manifest if Splunk Support directs you to. Do not rebuild it on your own.
This command rebuilds the
.bucketManifest file for the main index only:
splunk _internal call /data/indexes/main/rebuild-bucket-manifest
To rebuild the manifests for all indexes, use the asterisk (*) wildcard:
splunk _internal call /data/indexes/*/rebuild-bucket-manifest
For more information
For more information on index storage and buckets, read these topics:
- "Configure index storage"
- "Use multiple partitions for index data"
- "Configure index storage size"
- "Buckets and indexer clusters".
Configure index storage
This documentation applies to the following versions of Splunk® Enterprise: 6.0, 6.0.1, 6.0.2, 6.0.3, 6.0.4, 6.0.5, 6.0.6, 6.0.7, 6.0.8, 6.0.9, 6.0.10, 6.0.11, 6.0.12, 6.0.13, 6.0.14, 6.0.15, 6.1, 6.1.1, 6.1.2, 6.1.3, 6.1.4, 6.1.5, 6.1.6, 6.1.7, 6.1.8, 6.1.9, 6.1.10, 6.1.11, 6.1.12, 6.1.13, 6.1.14