Storing records with dynamic schemas in a table with a fixed schema.
Some domains (e.g., logging) generate records where each record can have a different set of keys, whereas Pinot tables have a relatively static schema. For records with varying keys, it's impractical to store each field in its own table column. However, most (if not all) fields may be important, so fields should not be dropped unnecessarily.
The SchemaConformingTransformer is a RecordTransformer that can transform records with dynamic schemas such that they can be ingested in a table with a static schema. The transformer primarily takes record fields that don't exist in the schema and stores them in a type of catchall field.
For example, consider this record:
Let's say the table's schema contains the following fields:
timestamp
hostname
level
message
tags.platform
tags.service
indexableExtras
unindexableExtras
Without this transformer, the HOSTNAME
field and the entire tags
field would be dropped when storing the record in the table. However, with this transformer, the record would be transformed into the following:
Notice that the transformer does the following:
Flattens nested fields which exist in the schema, like tags.platform
Drops some fields like HOSTNAME
, where HOSTNAME
must be listed as a field in the config option fieldPathsToDrop
Moves fields that don't exist in the schema and have the suffix _noIndex
into the unindexableExtras
field
Moves any remaining fields that don't exist in the schema into the indexableExtras
field
The unindexableExtras
field allows the transformer to separate fields that don't need indexing (because they are only retrieved, not searched) from those that do.
To use the transformer, add the schemaConformingTransformerConfig
option in the ingestionConfig
section of your table configuration, as shown in the following example.
For example:
Available configuration options are listed in SchemaConformingTransformerConfig.
This section contains a collection of guides that will show you how to import data from a Pinot-supported input format.
Pinot offers support for various popular input formats during ingestion. By changing the input format, you can reduce the time spent doing serialization-deserialization and speed up the ingestion.
To change the input format, adjust the recordReaderSpec
config in the ingestion job specification.
The configuration consists of the following keys:
dataFormat
: Name of the data format to consume.
className
: Name of the class that implements the RecordReader
interface. This class is used for parsing the data.
configClassName
: Name of the class that implements the RecordReaderConfig
interface. This class is used the parse the values mentioned in configs
configs
: Key-value pair for format-specific configurations. This field is optional.
Pinot supports multiple input formats out of the box. Specify the corresponding readers and the associated custom configurations to switch between formats.
CSV Record Reader supports the following configs:
fileFormat
: default
, rfc4180
, excel
, tdf
, mysql
header
: Header of the file. The columnNames
should be separated by the delimiter mentioned in the configuration.
delimiter
: The character seperating the columns.
multiValueDelimiter
: The character separating multiple values in a single column. This can be used to split a column into a list.
skipHeader
: Skip header record in the file. Boolean.
ignoreEmptyLines
: Ignore empty lines (instead of filling them with default values). Boolean.
ignoreSurroundingSpaces
: ignore spaces around column names and values. Boolean
quoteCharacter
: Single character used for quotes in CSV files.
recordSeparator
: Character used to separate records in the input file. Default is or \r
depending on the platform.
nullStringValue
: String value that represents null in CSV files. Default is empty string.
skipUnParseableLines
: Skip lines that cannot be parsed. Note that this would result in data loss. Boolean.
Your CSV file may have raw text fields that cannot be reliably delimited using any character. In this case, explicitly set the multiValueDelimeter field to empty in the ingestion config.
multiValueDelimiter: ''
The Avro record reader converts the data in file to a GenericRecord
. A Java class or .avro
file is not required. By default, the Avro record reader only supports primitive types. To enable support for rest of the Avro data types, set enableLogicalTypes
to true
.
We use the following conversion table to translate between Avro and Pinot data types. The conversions are done using the offical Avro methods present in org.apache.avro.Conversions
.
Thrift requires the generated class using .thrift
file to parse the data. The .class
file should be available in the Pinot's classpath
. You can put the files in the lib/
folder of Pinot distribution directory.
Since 0.11.0 release, the Parquet record reader determines whether to use ParquetAvroRecordReader
or ParquetNativeRecordReader
to read records. The reader looks for the parquet.avro.schema
or avro.schema
key in the parquet file footer, and if present, uses the Avro reader.
You can change the record reader manually in case of a misconfiguration.
For the support of DECIMAL and other parquet native data types, always use ParquetNativeRecordReader
.
For ParquetAvroRecordReader
, you can refer to the Avro section above for the type conversions.
ORC record reader supports the following data types -
In LIST and MAP types, the object should only belong to one of the data types supported by Pinot.
The reader requires a descriptor file to deserialize the data present in the files. You can generate the descriptor file (.desc
) from the .proto
file using the command -
Avro Data Type | Pinot Data Type | Comment |
---|---|---|
ORC Data Type | Java Data Type |
---|---|
INT
INT
LONG
LONG
FLOAT
FLOAT
DOUBLE
DOUBLE
BOOLEAN
BOOLEAN
STRING
STRING
ENUM
STRING
BYTES
BYTES
FIXED
BYTES
MAP
JSON
ARRAY
JSON
RECORD
JSON
UNION
JSON
DECIMAL
BYTES
UUID
STRING
DATE
STRING
yyyy-MM-dd
format
TIME_MILLIS
STRING
HH:mm:ss.SSS
format
TIME_MICROS
STRING
HH:mm:ss.SSSSSS
format
TIMESTAMP_MILLIS
TIMESTAMP
TIMESTAMP_MICROS
TIMESTAMP
INT96
LONG
ParquetINT96
type converts nanoseconds
to Pinot INT64
type of milliseconds
INT64
LONG
INT32
INT
FLOAT
FLOAT
DOUBLE
DOUBLE
BINARY
BYTES
FIXED-LEN-BYTE-ARRAY
BYTES
DECIMAL
DOUBLE
ENUM
STRING
UTF8
STRING
REPEATED
MULTIVALUE/MAP (represented as MV
if parquet original type is LIST, then it is converted to MULTIVALUE column otherwise a MAP column.
BOOLEAN
String
SHORT
Integer
INT
Integer
LONG
Integer
FLOAT
Float
DOUBLE
Double
STRING
String
VARCHAR
String
CHAR
String
LIST
Object[]
MAP
Map<Object, Object>
DATE
Long
TIMESTAMP
Long
BINARY
byte[]
BYTE
Integer
Complex type handling in Apache Pinot.
Commonly, ingested data has a complex structure. For example, Avro schemas have records and arrays while JSON supports objects and arrays.
Apache Pinot's data model supports primitive data types (including int, long, float, double, BigDecimal, string, bytes), and limited multi-value types, such as an array of primitive types. Simple data types allow Pinot to build fast indexing structures for good query performance, but does require some handling of the complex structures.
There are two options for complex type handling:
Convert the complex-type data into a JSON string and then build a JSON index.
Use the built-in complex-type handling rules in the ingestion configuration.
On this page, we'll show how to handle these complex-type structures with each of these two approaches. We will process some example data, consisting of the field group
from the Meetup events Quickstart example.
This object has two child fields and the child group
is a nested array with elements of object type.
Apache Pinot provides a powerful JSON index to accelerate the value lookup and filtering for the column. To convert an object group
with complex type to JSON, add the following to your table configuration.
The config transformConfigs
transforms the object group
to a JSON string group_json
, which then creates the JSON indexing with configuration jsonIndexColumns
. To read the full spec, see meetupRsvpJson_realtime_table_config.json.
Also, note that group
is a reserved keyword in SQL and therefore needs to be quoted in transformFunction
.
The columnName
can't use the same name as any of the fields in the source JSON data, for example, if our source data contains the field group
and we want to transform the data in that field before persisting it, the destination column name would need to be something different, like group_json
.
Note that you do not need to worry about the maxLength
of the field group_json
on the schema, because "JSON"
data type does not have a maxLength
and will not be truncated. This is true even though "JSON"
is stored as a string internally.
The schema will look like this:
For the full specification, see json_meetupRsvp_schema.json.
With this, you can start to query the nested fields under group
. For more details about the supported JSON function, see guide).
Though JSON indexing is a handy way to process the complex types, there are some limitations:
It’s not performant to group by or order by a JSON field, because JSON_EXTRACT_SCALAR
is needed to extract the values in the GROUP BY and ORDER BY clauses, which invokes the function evaluation.
It does not work with Pinot's multi-column functions such as DISTINCTCOUNTMV
.
Alternatively, from Pinot 0.8, you can use the complex-type handling in ingestion configurations to flatten and unnest the complex structure and convert them into primitive types. Then you can reduce the complex-type data into a flattened Pinot table, and query it via SQL. With the built-in processing rules, you do not need to write ETL jobs in another compute framework such as Flink or Spark.
To process this complex type, you can add the configuration complexTypeConfig
to the ingestionConfig
. For example:
With the complexTypeConfig
, all the map objects will be flattened to direct fields automatically. And with unnestFields
, a record with the nested collection will unnest into multiple records. For instance, the example at the beginning will transform into two rows with this configuration example.
Note that:
The nested field group_id
under group
is flattened to group.group_id
. The default value of the delimiter is .
You can choose another delimiter by specifying the configuration delimiter
under complexTypeConfig
. This flattening rule also applies to maps in the collections to be unnested.
The nested array group_topics
under group
is unnested into the top-level, and converts the output to a collection of two rows. Note the handling of the nested field within group_topics
, and the eventual top-level field of group.group_topics.urlkey
. All the collections to unnest shall be included in the configuration fieldsToUnnest
.
Collections not specified in fieldsToUnnest
will be serialized into JSON string, except for the array of primitive values, which will be ingested as a multi-value column by default. The behavior is defined by the collectionNotUnnestedToJson
config, which takes the following values:
NON_PRIMITIVE
- Converts the array to a multi-value column. (default)
ALL
- Converts the array of primitive values to JSON string.
NONE
- Does not do any conversion.
You can find the full specifications of the table config here and the table schema here.
You can then query the table with primitive values using the following SQL query:
.
is a reserved character in SQL, so you need to quote the flattened columns in the query.
When there are complex structures, it can be challenging and tedious to figure out the Pinot schema manually. To help with schema inference, Pinot provides utility tools to take the Avro schema or JSON data as input and output the inferred Pinot schema.
To infer the Pinot schema from Avro schema, you can use a command like this:
Note you can input configurations like fieldsToUnnest
similar to the ones in complexTypeConfig
. And this will simulate the complex-type handling rules on the Avro schema and output the Pinot schema in the file specified in outputDir
.
Similarly, you can use the command like the following to infer the Pinot schema from a file of JSON objects.
You can check out an example of this run in this PR.