41 KiB
id | title |
---|---|
index | Ingestion |
Overview
All data in Druid is organized into segments, which are data files that generally have up to a few million rows each. Loading data in Druid is called ingestion or indexing and consists of reading data from a source system and creating segments based on that data.
In most ingestion methods, the work of loading data is done by Druid MiddleManager processes (or the Indexer processes). One exception is Hadoop-based ingestion, where this work is instead done using a Hadoop MapReduce job on YARN (although MiddleManager or Indexer processes are still involved in starting and monitoring the Hadoop jobs). Once segments have been generated and stored in deep storage, they will be loaded by Historical processes. For more details on how this works under the hood, see the Storage design section of Druid's design documentation.
How to use this documentation
This page you are currently reading provides information about universal Druid ingestion concepts, and about configurations that are common to all ingestion methods.
The individual pages for each ingestion method provide additional information about concepts and configurations that are unique to each ingestion method.
We recommend reading (or at least skimming) this universal page first, and then referring to the page for the ingestion method or methods that you have chosen.
Ingestion methods
The table below lists Druid's most common data ingestion methods, along with comparisons to help you choose the best one for your situation. Each ingestion method supports its own set of source systems to pull from. For details about how each method works, as well as configuration properties specific to that method, check out its documentation page.
Streaming
The most recommended, and most popular, method of streaming ingestion is the Kafka indexing service that reads directly from Kafka. The Kinesis indexing service also works well if you prefer Kinesis.
This table compares the major available options:
Method | Kafka | Kinesis | Tranquility |
---|---|---|---|
Supervisor type | kafka |
kinesis |
N/A |
How it works | Druid reads directly from Apache Kafka. | Druid reads directly from Amazon Kinesis. | Tranquility, a library that ships separately from Druid, is used to push data into Druid. |
Can ingest late data? | Yes | Yes | No (late data is dropped based on the windowPeriod config) |
Exactly-once guarantees? | Yes | Yes | No |
Batch
When doing batch loads from files, you should use one-time tasks, and you have three options: index_parallel
(native batch; parallel), index_hadoop
(Hadoop-based),
or index
(native batch; single-task).
In general, we recommend native batch whenever it meets your needs, since the setup is simpler (it does not depend on an external Hadoop cluster). However, there are still scenarios where Hadoop-based batch ingestion might be a better choice, for example when you already have a running Hadoop cluster and want to use the cluster resource of the existing cluster for batch ingestion.
This table compares the three available options:
Method | Native batch (parallel) | Hadoop-based | Native batch (simple) |
---|---|---|---|
Task type | index_parallel |
index_hadoop |
index |
Parallel? | Yes, if inputFormat is splittable and maxNumConcurrentSubTasks > 1 in tuningConfig . See data format documentation for details. |
Yes, always. | No. Each task is single-threaded. |
Can append or overwrite? | Yes, both. | Overwrite only. | Yes, both. |
External dependencies | None. | Hadoop cluster (Druid submits Map/Reduce jobs). | None. |
Input locations | Any inputSource . |
Any Hadoop FileSystem or Druid datasource. | Any inputSource . |
File formats | Any inputFormat . |
Any Hadoop InputFormat. | Any inputFormat . |
Rollup modes | Perfect if forceGuaranteedRollup = true in the tuningConfig . |
Always perfect. | Perfect if forceGuaranteedRollup = true in the tuningConfig . |
Partitioning options | Dynamic, hash-based, and range-based partitioning methods are available. See Partitions Spec for details. | Hash-based or range-based partitioning via partitionsSpec . |
Dynamic and hash-based partitioning methods are available. See Partitions Spec for details. |
Druid's data model
Datasources
Druid data is stored in datasources, which are similar to tables in a traditional RDBMS. Druid offers a unique data modeling system that bears similarity to both relational and timeseries models.
Primary timestamp
Druid schemas must always include a primary timestamp. The primary timestamp is used for partitioning and sorting your data. Druid queries are able to rapidly identify and retrieve data corresponding to time ranges of the primary timestamp column. Druid is also able to use the primary timestamp column for time-based data management operations such as dropping time chunks, overwriting time chunks, and time-based retention rules.
The primary timestamp is parsed based on the timestampSpec
. In addition, the
granularitySpec
controls other important operations that are based on the primary timestamp.
Regardless of which input field the primary timestamp is read from, it will always be stored as a column named __time
in your Druid datasource.
If you have more than one timestamp column, you can store the others as secondary timestamps.
Dimensions
Dimensions are columns that are stored as-is and can be used for any purpose. You can group, filter, or apply aggregators to dimensions at query time in an ad-hoc manner. If you run with rollup disabled, then the set of dimensions is simply treated like a set of columns to ingest, and behaves exactly as you would expect from a typical database that does not support a rollup feature.
Dimensions are configured through the dimensionsSpec
.
Metrics
Metrics are columns that are stored in an aggregated form. They are most useful when rollup is enabled. Specifying a metric allows you to choose an aggregation function for Druid to apply to each row during ingestion. This has two benefits:
- If rollup is enabled, multiple rows can be collapsed into one row even while retaining summary
information. In the rollup tutorial, this is used to collapse netflow data to a
single row per
(minute, srcIP, dstIP)
tuple, while retaining aggregate information about total packet and byte counts. - Some aggregators, especially approximate ones, can be computed faster at query time even on non-rolled-up data if they are partially computed at ingestion time.
Metrics are configured through the metricsSpec
.
Rollup
What is rollup?
Druid can roll up data as it is ingested to minimize the amount of raw data that needs to be stored. Rollup is a form of summarization or pre-aggregation. In practice, rolling up data can dramatically reduce the size of data that needs to be stored, reducing row counts by potentially orders of magnitude. This storage reduction does come at a cost: as we roll up data, we lose the ability to query individual events.
When rollup is disabled, Druid loads each row as-is without doing any form of pre-aggregation. This mode is similar to what you would expect from a typical database that does not support a rollup feature.
When rollup is enabled, then any rows that have identical dimensions and timestamp
to each other (after queryGranularity
-based truncation) can be collapsed, or rolled up, into a
single row in Druid.
By default, rollup is enabled.
Enabling or disabling rollup
Rollup is controlled by the rollup
setting in the granularitySpec
. By default, it is true
(enabled). Set this to false
if you want Druid to store each record as-is, without any rollup summarization.
Example of rollup
For an example of how to configure rollup, and of how the feature will modify your data, check out the rollup tutorial.
Maximizing rollup ratio
You can measure the rollup ratio of a datasource by comparing the number of rows in Druid with the number of ingested events. The higher this number, the more benefit you are gaining from rollup. One way to do this is with a Druid SQL query like:
SELECT SUM("cnt") / COUNT(*) * 1.0 FROM datasource
In this query, cnt
should refer to a "count" type metric specified at ingestion time. See
Counting the number of ingested events on the "Schema design" page for more details about
how counting works when rollup is enabled.
Tips for maximizing rollup:
- Generally, the fewer dimensions you have, and the lower the cardinality of your dimensions, the better rollup ratios you will achieve.
- Use sketches to avoid storing high cardinality dimensions, which harm rollup ratios.
- Adjusting
queryGranularity
at ingestion time (for example, usingPT5M
instead ofPT1M
) increases the likelihood of two rows in Druid having matching timestamps, and can improve your rollup ratios. - It can be beneficial to load the same data into more than one Druid datasource. Some users choose to create a "full" datasource that has rollup disabled (or enabled, but with a minimal rollup ratio) and an "abbreviated" datasource that has fewer dimensions and a higher rollup ratio. When queries only involve dimensions in the "abbreviated" set, using that datasource leads to much faster query times. This can often be done with just a small increase in storage footprint, since abbreviated datasources tend to be substantially smaller.
- If you are using a best-effort rollup ingestion configuration that does not guarantee perfect rollup, you can potentially improve your rollup ratio by switching to a guaranteed perfect rollup option, or by reindexing your data in the background after initial ingestion.
Perfect rollup vs Best-effort rollup
Some Druid ingestion methods guarantee perfect rollup, meaning that input data are perfectly aggregated at ingestion time. Others offer best-effort rollup, meaning that input data might not be perfectly aggregated and thus there could be multiple segments holding rows with the same timestamp and dimension values.
In general, ingestion methods that offer best-effort rollup do this because they are either parallelizing ingestion without a shuffling step (which would be required for perfect rollup), or because they are finalizing and publishing segments before all data for a time chunk has been received, which we call incremental publishing. In both of these cases, records that could theoretically be rolled up may end up in different segments. All types of streaming ingestion run in this mode.
Ingestion methods that guarantee perfect rollup do it with an additional preprocessing step to determine intervals and partitioning before the actual data ingestion stage. This preprocessing step scans the entire input dataset, which generally increases the time required for ingestion, but provides information necessary for perfect rollup.
The following table shows how each method handles rollup:
Method | How it works |
---|---|
Native batch | index_parallel and index type may be either perfect or best-effort, based on configuration. |
Hadoop | Always perfect. |
Kafka indexing service | Always best-effort. |
Kinesis indexing service | Always best-effort. |
Partitioning
Why partition?
Optimal partitioning and sorting of segments within your datasources can have substantial impact on footprint and performance.
Druid datasources are always partitioned by time into time chunks, and each time chunk contains one or more segments.
This partitioning happens for all ingestion methods, and is based on the segmentGranularity
parameter of your
ingestion spec's dataSchema
.
The segments within a particular time chunk may also be partitioned further, using options that vary based on the ingestion type you have chosen. In general, doing this secondary partitioning using a particular dimension will improve locality, meaning that rows with the same value for that dimension are stored together and can be accessed quickly.
You will usually get the best performance and smallest overall footprint by partitioning your data on some "natural" dimension that you often filter by, if one exists. This will often improve compression - users have reported threefold storage size decreases - and it also tends to improve query performance as well.
Partitioning and sorting are best friends! If you do have a "natural" partitioning dimension, you should also consider placing it first in the
dimensions
list of yourdimensionsSpec
, which tells Druid to sort rows within each segment by that column. This will often improve compression even more, beyond the improvement gained by partitioning alone.However, note that currently, Druid always sorts rows within a segment by timestamp first, even before the first dimension listed in your
dimensionsSpec
. This can prevent dimension sorting from being maximally effective. If necessary, you can work around this limitation by settingqueryGranularity
equal tosegmentGranularity
in yourgranularitySpec
, which will set all timestamps within the segment to the same value, and by saving your "real" timestamp as a secondary timestamp. This limitation may be removed in a future version of Druid.
How to set up partitioning
Not all ingestion methods support an explicit partitioning configuration, and not all have equivalent levels of flexibility. As of current Druid versions, If you are doing initial ingestion through a less-flexible method (like Kafka) then you can use reindexing techniques to repartition your data after it is initially ingested. This is a powerful technique: you can use it to ensure that any data older than a certain threshold is optimally partitioned, even as you continuously add new data from a stream.
The following table shows how each ingestion method handles partitioning:
Method | How it works |
---|---|
Native batch | Configured using partitionsSpec inside the tuningConfig . |
Hadoop | Configured using partitionsSpec inside the tuningConfig . |
Kafka indexing service | Partitioning in Druid is guided by how your Kafka topic is partitioned. You can also reindex to repartition after initial ingestion. |
Kinesis indexing service | Partitioning in Druid is guided by how your Kinesis stream is sharded. You can also reindex to repartition after initial ingestion. |
Note that, of course, one way to partition data is to load it into separate datasources. This is a perfectly viable approach and works very well when the number of datasources does not lead to excessive per-datasource overheads. If you go with this approach, then you can ignore this section, since it is describing how to set up partitioning within a single datasource.
For more details on splitting data up into separate datasources, and potential operational considerations, refer to the Multitenancy considerations page.
Ingestion specs
No matter what ingestion method you use, data is loaded into Druid using either one-time tasks or ongoing "supervisors" (which run and supervised a set of tasks over time). In any case, part of the task or supervisor definition is an ingestion spec.
Ingestion specs consists of three main components:
dataSchema
, which configures the datasource name, primary timestamp, dimensions, metrics, and transforms and filters (if needed).ioConfig
, which tells Druid how to connect to the source system and how to parse data. For more information, see the documentation for each ingestion method.tuningConfig
, which controls various tuning parameters specific to each ingestion method.
Example ingestion spec for task type index_parallel
(native batch):
{
"type": "index_parallel",
"spec": {
"dataSchema": {
"dataSource": "wikipedia",
"timestampSpec": {
"column": "timestamp",
"format": "auto"
},
"dimensionsSpec": {
"dimensions": [
{ "type": "string", "page" },
{ "type": "string", "language" },
{ "type": "long", "name": "userId" }
]
},
"metricsSpec": [
{ "type": "count", "name": "count" },
{ "type": "doubleSum", "name": "bytes_added_sum", "fieldName": "bytes_added" },
{ "type": "doubleSum", "name": "bytes_deleted_sum", "fieldName": "bytes_deleted" }
],
"granularitySpec": {
"segmentGranularity": "day",
"queryGranularity": "none",
"intervals": [
"2013-08-31/2013-09-01"
]
}
},
"ioConfig": {
"type": "index_parallel",
"inputSource": {
"type": "local",
"baseDir": "examples/indexing/",
"filter": "wikipedia_data.json"
},
"inputFormat": {
"type": "json",
"flattenSpec": {
"useFieldDiscovery": true,
"fields": [
{ "type": "path", "name": "userId", "expr": "$.user.id" }
]
}
}
},
"tuningConfig": {
"type": "index_parallel"
}
}
}
The specific options supported by these sections will depend on the ingestion method you have chosen. For more examples, refer to the documentation for each ingestion method.
You can also load data visually, without the need to write an ingestion spec, using the "Load data" functionality available in Druid's web console. Druid's visual data loader supports Kafka, Kinesis, and native batch mode.
dataSchema
The
dataSchema
spec has been changed in 0.17.0. The new spec is supported by all ingestion methods except for Hadoop ingestion. See the LegacydataSchema
spec for the old spec.
The dataSchema
is a holder for the following components:
- datasource name, primary timestamp, dimensions, metrics, and transforms and filters (if needed).
An example dataSchema
is:
"dataSchema": {
"dataSource": "wikipedia",
"timestampSpec": {
"column": "timestamp",
"format": "auto"
},
"dimensionsSpec": {
"dimensions": [
{ "type": "string", "page" },
{ "type": "string", "language" },
{ "type": "long", "name": "userId" }
]
},
"metricsSpec": [
{ "type": "count", "name": "count" },
{ "type": "doubleSum", "name": "bytes_added_sum", "fieldName": "bytes_added" },
{ "type": "doubleSum", "name": "bytes_deleted_sum", "fieldName": "bytes_deleted" }
],
"granularitySpec": {
"segmentGranularity": "day",
"queryGranularity": "none",
"intervals": [
"2013-08-31/2013-09-01"
]
}
}
dataSource
The dataSource
is located in dataSchema
→ dataSource
and is simply the name of the
datasource that data will be written to. An example
dataSource
is:
"dataSource": "my-first-datasource"
timestampSpec
The timestampSpec
is located in dataSchema
→ timestampSpec
and is responsible for
configuring the primary timestamp. An example timestampSpec
is:
"timestampSpec": {
"column": "timestamp",
"format": "auto"
}
Conceptually, after input data records are read, Druid applies ingestion spec components in a particular order: first
flattenSpec
(if any), thentimestampSpec
, thentransformSpec
, and finallydimensionsSpec
andmetricsSpec
. Keep this in mind when writing your ingestion spec.
A timestampSpec
can have the following components:
Field | Description | Default |
---|---|---|
column | Input row field to read the primary timestamp from. Regardless of the name of this input field, the primary timestamp will always be stored as a column named __time in your Druid datasource. |
timestamp |
format | Timestamp format. Options are:
|
auto |
missingValue | Timestamp to use for input records that have a null or missing timestamp column . Should be in ISO8601 format, like "2000-01-01T01:02:03.456" , even if you have specified something else for format . Since Druid requires a primary timestamp, this setting can be useful for ingesting datasets that do not have any per-record timestamps at all. |
none |
dimensionsSpec
The dimensionsSpec
is located in dataSchema
→ dimensionsSpec
and is responsible for
configuring dimensions. An example dimensionsSpec
is:
"dimensionsSpec" : {
"dimensions": [
"page",
"language",
{ "type": "long", "name": "userId" }
],
"dimensionExclusions" : [],
"spatialDimensions" : []
}
Conceptually, after input data records are read, Druid applies ingestion spec components in a particular order: first
flattenSpec
(if any), thentimestampSpec
, thentransformSpec
, and finallydimensionsSpec
andmetricsSpec
. Keep this in mind when writing your ingestion spec.
A dimensionsSpec
can have the following components:
Field | Description | Default |
---|---|---|
dimensions | A list of dimension names or objects. Cannot have the same column in both dimensions and dimensionExclusions .If this is an empty array, Druid will treat all non-timestamp, non-metric columns that do not appear in dimensionExclusions as String-typed dimension columns (see inclusions and exclusions below). |
[] |
dimensionExclusions | The names of dimensions to exclude from ingestion. Only names are supported here, not objects. Cannot have the same column in both dimensions and dimensionExclusions . |
[] |
spatialDimensions | An array of spatial dimensions. | [] |
Dimension objects
Each dimension in the dimensions
list can either be a name or an object. Providing a name is equivalent to providing
a string
type dimension object with the given name, e.g. "page"
is equivalent to {"name": "page", "type": "string"}
.
Dimension objects can have the following components:
Field | Description | Default |
---|---|---|
type | Either string , long , float , or double . |
string |
name | The name of the dimension. This will be used as the field name to read from input records, as well as the column name stored in generated segments. Note that you can use a transformSpec if you want to rename columns during ingestion time. |
none (required) |
createBitmapIndex | For string typed dimensions, whether or not bitmap indexes should be created for the column in generated segments. Creating a bitmap index requires more storage, but speeds up certain kinds of filtering (especially equality and prefix filtering). Only supported for string typed dimensions. |
true |
Inclusions and exclusions
Druid will interpret a dimensionsSpec
in two possible ways: normal or schemaless.
Normal interpretation occurs when either dimensions
or spatialDimensions
is non-empty. In this case, the combination of the two lists will be taken as the set of dimensions to be ingested.
Schemaless interpretation occurs when both dimensions
and spatialDimensions
are empty or null. In this case, the set of dimensions is determined in the following way:
- First, start from the set of all input fields from the
inputFormat
(or theflattenSpec
, if one is being used). - Any field listed in
dimensionExclusions
is excluded. - The field listed as
column
in thetimestampSpec
is excluded. - Any field used as an input to an aggregator from the metricsSpec is excluded.
- Any field with the same name as an aggregator from the metricsSpec is excluded.
- All other fields are ingested as
string
typed dimensions with the default settings.
Note: Fields generated by a
transformSpec
are not currently considered candidates for schemaless dimension interpretation.
metricsSpec
The metricsSpec
is located in dataSchema
→ metricsSpec
and is a list of aggregators
to apply at ingestion time. This is most useful when rollup is enabled, since it's how you configure
ingestion-time aggregation.
An example metricsSpec
is:
"metricsSpec": [
{ "type": "count", "name": "count" },
{ "type": "doubleSum", "name": "bytes_added_sum", "fieldName": "bytes_added" },
{ "type": "doubleSum", "name": "bytes_deleted_sum", "fieldName": "bytes_deleted" }
]
Generally, when rollup is disabled, you should have an empty
metricsSpec
(because without rollup, Druid does not do any ingestion-time aggregation, so there is little reason to include an ingestion-time aggregator). However, in some cases, it can still make sense to define metrics: for example, if you want to create a complex column as a way of pre-computing part of an approximate aggregation, this can only be done by defining a metric in ametricsSpec
.
granularitySpec
The granularitySpec
is located in dataSchema
→ granularitySpec
and is responsible for configuring
the following operations:
- Partitioning a datasource into time chunks (via
segmentGranularity
). - Truncating the timestamp, if desired (via
queryGranularity
). - Specifying which time chunks of segments should be created, for batch ingestion (via
intervals
). - Specifying whether ingestion-time rollup should be used or not (via
rollup
).
Other than rollup
, these operations are all based on the primary timestamp.
An example granularitySpec
is:
"granularitySpec": {
"segmentGranularity": "day",
"queryGranularity": "none",
"intervals": [
"2013-08-31/2013-09-01"
],
"rollup": true
}
A granularitySpec
can have the following components:
Field | Description | Default |
---|---|---|
type | Either uniform or arbitrary . In most cases you want to use uniform . |
uniform |
segmentGranularity | Time chunking granularity for this datasource. Multiple segments can be created per time chunk. For example, when set to day , the events of the same day fall into the same time chunk which can be optionally further partitioned into multiple segments based on other configurations and input size. Any granularity can be provided here. Note that all segments in the same time chunk should have the same segment granularity.Ignored if type is set to arbitrary . |
day |
queryGranularity | The resolution of timestamp storage within each segment. This must be equal to, or finer, than segmentGranularity . This will be the finest granularity that you can query at and still receive sensible results, but note that you can still query at anything coarser than this granularity. E.g., a value of minute will mean that records will be stored at minutely granularity, and can be sensibly queried at any multiple of minutes (including minutely, 5-minutely, hourly, etc).Any granularity can be provided here. Use none to store timestamps as-is, without any truncation. Note that rollup will be applied if it is set even when the queryGranularity is set to none . |
none |
rollup | Whether to use ingestion-time rollup or not. Note that rollup is still effective even when queryGranularity is set to none . Your data will be rolled up if they have the exactly same timestamp. |
true |
intervals | A list of intervals describing what time chunks of segments should be created. If type is set to uniform , this list will be broken up and rounded-off based on the segmentGranularity . If type is set to arbitrary , this list will be used as-is.If null or not provided, batch ingestion tasks will generally determine which time chunks to output based on what timestamps are found in the input data.If specified, batch ingestion tasks may be able to skip a determining-partitions phase, which can result in faster ingestion. Batch ingestion tasks may also be able to request all their locks up-front instead of one by one. Batch ingestion tasks will throw away any records with timestamps outside of the specified intervals. Ignored for any form of streaming ingestion. |
null |
transformSpec
The transformSpec
is located in dataSchema
→ transformSpec
and is responsible for transforming and filtering
records during ingestion time. It is optional. An example transformSpec
is:
"transformSpec": {
"transforms": [
{ "type": "expression", "name": "countryUpper", "expression": "upper(country)" }
],
"filter": {
"type": "selector",
"dimension": "country",
"value": "San Serriffe"
}
}
Conceptually, after input data records are read, Druid applies ingestion spec components in a particular order: first
flattenSpec
(if any), thentimestampSpec
, thentransformSpec
, and finallydimensionsSpec
andmetricsSpec
. Keep this in mind when writing your ingestion spec.
Transforms
The transforms
list allows you to specify a set of expressions to evaluate on top of input data. Each transform has a
"name" which can be referred to by your dimensionsSpec
, metricsSpec
, etc.
If a transform has the same name as a field in an input row, then it will shadow the original field. Transforms that shadow fields may still refer to the fields they shadow. This can be used to transform a field "in-place".
Transforms do have some limitations. They can only refer to fields present in the actual input rows; in particular, they cannot refer to other transforms. And they cannot remove fields, only add them. However, they can shadow a field with another field containing all nulls, which will act similarly to removing the field.
Transforms can refer to the timestamp of an input row by referring to __time
as part of the expression.
They can also replace the timestamp if you set their "name" to __time
. In both cases, __time
should be treated as
a millisecond timestamp (number of milliseconds since Jan 1, 1970 at midnight UTC). Transforms are applied after the
timestampSpec
.
Druid currently includes one kind of built-in transform, the expression transform. It has the following syntax:
{
"type": "expression",
"name": "<output name>",
"expression": "<expr>"
}
The expression
is a Druid query expression.
Conceptually, after input data records are read, Druid applies ingestion spec components in a particular order: first
flattenSpec
(if any), thentimestampSpec
, thentransformSpec
, and finallydimensionsSpec
andmetricsSpec
. Keep this in mind when writing your ingestion spec.
Filter
The filter
conditionally filters input rows during ingestion. Only rows that pass the filter will be
ingested. Any of Druid's standard query filters can be used. Note that within a
transformSpec
, the transforms
are applied before the filter
, so the filter can refer to a transform.
Legacy dataSchema
spec
The
dataSchema
spec has been changed in 0.17.0. The new spec is supported by all ingestion methods except for Hadoop ingestion. SeedataSchema
for the new spec.
The legacy dataSchema
spec has below two more components in addition to the ones listed in the dataSchema
section above.
- input row parser, flattening of nested data (if needed)
parser
(Deprecated)
In legacy dataSchema
, the parser
is located in the dataSchema
→ parser
and is responsible for configuring a wide variety of
items related to parsing input records. The parser
is deprecated and it is highly recommended to use inputFormat
instead.
For details about inputFormat
and supported parser
types, see the "Data formats" page.
For details about major components of the parseSpec
, refer to their subsections:
timestampSpec
, responsible for configuring the primary timestamp.dimensionsSpec
, responsible for configuring dimensions.flattenSpec
, responsible for flattening nested data formats.
An example parser
is:
"parser": {
"type": "string",
"parseSpec": {
"format": "json",
"flattenSpec": {
"useFieldDiscovery": true,
"fields": [
{ "type": "path", "name": "userId", "expr": "$.user.id" }
]
},
"timestampSpec": {
"column": "timestamp",
"format": "auto"
},
"dimensionsSpec": {
"dimensions": [
{ "type": "string", "page" },
{ "type": "string", "language" },
{ "type": "long", "name": "userId" }
]
}
}
}
flattenSpec
In the legacy dataSchema
, the flattenSpec
is located in dataSchema
→ parser
→ parseSpec
→ flattenSpec
and is responsible for
bridging the gap between potentially nested input data (such as JSON, Avro, etc) and Druid's flat data model.
See Flatten spec for more details.
ioConfig
The ioConfig
influences how data is read from a source system, such as Apache Kafka, Amazon S3, a mounted
filesystem, or any other supported source system. The inputFormat
property applies to all
ingestion method except for Hadoop ingestion. The Hadoop ingestion still
uses the parser
in the legacy dataSchema
.
The rest of ioConfig
is specific to each individual ingestion method.
An example ioConfig
to read JSON data is:
"ioConfig": {
"type": "<ingestion-method-specific type code>",
"inputFormat": {
"type": "json"
},
...
}
For more details, see the documentation provided by each ingestion method.
tuningConfig
Tuning properties are specified in a tuningConfig
, which goes at the top level of an ingestion spec. Some
properties apply to all ingestion methods, but most are specific to each individual
ingestion method. An example tuningConfig
that sets all of the shared, common properties to their defaults
is:
"tuningConfig": {
"type": "<ingestion-method-specific type code>",
"maxRowsInMemory": 1000000,
"maxBytesInMemory": <one-sixth of JVM memory>,
"indexSpec": {
"bitmap": { "type": "concise" },
"dimensionCompression": "lz4",
"metricCompression": "lz4",
"longEncoding": "longs"
},
<other ingestion-method-specific properties>
}
Field | Description | Default |
---|---|---|
type | Each ingestion method has its own tuning type code. You must specify the type code that matches your ingestion method. Common options are index , hadoop , kafka , and kinesis . |
|
maxRowsInMemory | The maximum number of records to store in memory before persisting to disk. Note that this is the number of rows post-rollup, and so it may not be equal to the number of input records. Ingested records will be persisted to disk when either maxRowsInMemory or maxBytesInMemory are reached (whichever happens first). |
1000000 |
maxBytesInMemory | The maximum aggregate size of records, in bytes, to store in the JVM heap before persisting. This is based on a rough estimate of memory usage. Ingested records will be persisted to disk when either maxRowsInMemory or maxBytesInMemory are reached (whichever happens first).Setting maxBytesInMemory to -1 disables this check, meaning Druid will rely entirely on maxRowsInMemory to control memory usage. Setting it to zero means the default value will be used (one-sixth of JVM heap size). Note that the estimate of memory usage is designed to be an overestimate, and can be especially high when using complex ingest-time aggregators, including sketches. If this causes your indexing workloads to persist to disk too often, you can set maxBytesInMemory to -1 and rely on maxRowsInMemory instead. |
One-sixth of max JVM heap size |
indexSpec | Tune how data is indexed. See below for more information. | See table below |
Other properties | Each ingestion method has its own list of additional tuning properties. See the documentation for each method for a full list: Kafka indexing service, Kinesis indexing service, Native batch, and Hadoop-based. |
indexSpec
The indexSpec
object can include the following properties:
Field | Description | Default |
---|---|---|
bitmap | Compression format for bitmap indexes. Should be a JSON object with type set to concise or roaring . For type roaring , the boolean property compressRunOnSerialization (defaults to true) controls whether or not run-length encoding will be used when it is determined to be more space-efficient. |
{"type": "concise"} |
dimensionCompression | Compression format for dimension columns. Options are lz4 , lzf , or uncompressed . |
lz4 |
metricCompression | Compression format for metric columns. Options are lz4 , lzf , uncompressed , or none (which is more efficient than uncompressed , but not supported by older versions of Druid). |
lz4 |
longEncoding | Encoding format for long-typed columns. Applies regardless of whether they are dimensions or metrics. Options are auto or longs . auto encodes the values using offset or lookup table depending on column cardinality, and store them with variable size. longs stores the value as-is with 8 bytes each. |
longs |
Beyond these properties, each ingestion method has its own specific tuning properties. See the documentation for each ingestion method for details.