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Apache Spark SQL connector for Google Bigtable

This connector allows writing Spark SQL DataFrames into Google Bigtable and reading tables from Bigtable. It uses the Spark SQL Data Source API V1 to connect to Bigtable.

Unreleased Changes

This Readme may include documentation for changes that haven't been released yet. The latest release's documentation and source code are found here.

https://github.com/GoogleCloudDataproc/spark-bigtable-connector/blob/main/README.md

Quickstart

You can access the connector in two different ways:

  1. From our Maven Central repository.
  2. Through a public GCS bucket, located at gs://spark-lib/bigtable/spark-bigtable_2.12-<version>.jar.

In Java and Scala applications, you can use different dependency management tools (e.g., Maven, sbt, or Gradle) to access the connector com.google.cloud.spark.bigtable:spark-bigtable_2.12:<version>( current <version> is ${next-release-tag}) and package it inside your application JAR using libraries such as Maven Shade Plugin. For PySpark applications, you can use the --jars flag to pass the GCS address of the connector when submitting it.

For Maven, you can add the following snippet to your pom.xml file:

<dependency>
  <groupId>com.google.cloud.spark.bigtable</groupId>
  <artifactId>spark-bigtable_2.12</artifactId>
  <version>${next-release-tag}</version>
</dependency>

For sbt, you can add the following to your build.sbt file:

libraryDependencies += "com.google.cloud.spark.bigtable" % "spark-bigtable_2.12" % "${next-release-tag}"

Finally, you can add the following to your build.gradle file when using Gradle:

dependencies {
implementation group: 'com.google.cloud.bigtable', name: 'spark-bigtable_2.12', version: '${next-release-tag}'
}

Note that you need plugins such as Maven Shade Plugin, sbt-assembly, or Shadow Plugin to package the connector inside your JAR in Maven, sbt, and Gradle, respectively.

Getting started

About Bigtable

Bigtable is Google's NoSQL Big Data database service. It's the same service powering many of Google's internal applications, e.g., Search, Maps, etc. You can refer to Bigtable documentations to learn more about key concepts, including instances, clusters, nodes, and tablets.

About Apache Spark and Spark SQL

Apache Spark is a distributed computing framework designed for fast and large-scale data processing, where resilient distributed dataset (RDD) is the main data model. Spark SQL is a module built on top of Spark that provides a SQL-like interface for querying and manipulating data. This is done through DataFrame and DataSet, Spark SQL's data model, built on top of RDDs.

Supported Spark runtime environments and requirements

You can use the connector with Spark locally with the Bigtable emulator, as well as in managed environments such as Dataproc cluster or serverless. You need the following depending on the environments you choose to use:

Runtime environment Bigtable Dataproc Cloud Storage
Local Spark w/ Bigtable emulator Optional Optional Optional
Local Spark Required Optional Optional
Dataproc Cluster Required Required Optional
Dataproc Serverless Required Required Required

Supported Spark versions

The connector supports the following Spark versions with Scala 2.12:

Scala version Spark versions Spark Application Languages
2.12 2.4.8, 3.1.x, 3.2.x, 3.4.x, 3.5.x Java, Scala, PySpark (.py files or Jupyter notebooks)

Main features

For a detailed list of features and how to use them, you can refer the official documentation here. A list of main features is as follows:

Catalog definition

You can define a catalog as a JSON-formatted string, to convert from the DataFrame's schema to a format compatible with Bigtable. This is an example of a catalog JSON:

{
  "table": {"name": "t1"},
  "rowkey": "id_rowkey",
  "columns": {
    "id": {"cf": "rowkey", "col": "id_rowkey", "type": "string"},
    "name": {"cf": "info", "col": "name", "type": "string"},
    "birthYear": {"cf": "info", "col": "birth_year", "type": "long"},
    "address": {"cf": "location", "col": "address", "type": "string"}
  }
}

Here, the columns name, birthYear, and address from the DataFrame are converted into Bigtable columns and the id column is used as the row key. Note that you could also specify compound row keys, which are created by concatenating multiple DataFrame columns together.

Writing to Bigtable

You can use the bigtable format along with specifying the Bigtable project and instance id to write to Bigtable. The catalog definition specifies the table destination. This is a sample snippet of writing to Bigtable using Java:

Dataset<Row> dataFrame;
// Adding some values to dataFrame.
dataFrame
  .write()
  .format("bigtable")
  .option("catalog", catalog)
  .option("spark.bigtable.project.id", projectId)
  .option("spark.bigtable.instance.id", instanceId);

Reading from Bigtable

You can use the bigtable format and catalog, along with the Bigtable project and instance id to read from Bigtable. This is a sample snippet of reading from Bigtable using Java:

Dataset<Row> dataFrame = spark
    .read()
    .format("bigtable")
    .option("catalog", catalog)
    .option("spark.bigtable.project.id", projectId)
    .option("spark.bigtable.instance.id", instanceId)
    .load();

Runtime configurations

You can use .option(<config_name>, <config_value>) in Spark to pass different runtime configurations to the connector. For example, Bigtable project and instance ID or settings for timestamp and timeout configurations. For a full list of configurations, refer to BigtableSparkConf.scala, where these configs are defined.

Bigtable emulator support

When using the connector locally, you can start a Bigtable emulator server and set the environment variable export BIGTABLE_EMULATOR_HOST=localhost:<emulator_port> in the same environment where Spark is launched. The connector will use the emulator instead of a real Bigtable instance. You can refer to the Bigtable emulator documentations for more details on using it.

Simple data type serialization

This connector supports encoding a number of Spark's simple data types as byte array for storage in Bigtable, with the following table summarizing the Spark type names, the corresponding GoogleSQL data types, the names you need to use in the catalog string, and the encoding description:

Spark SQL data type GoogleSQL type Catalog type Encoding description
BooleanType BOOL boolean True -> 1 byte corresponding to -1 in two's-complement
False -> 1 byte corresponding to 0 in two's-complement
ByteType N/A byte 1-byte signed two's-complement number
ShortType N/A short 2-byte signed two's-complement number, using big-endian
IntegerType N/A int 4-byte signed two's-complement number, using big-endian
LongType INT64 long 8-byte signed two's-complement number, using big-endian
FloatType FLOAT32 float 4-byte single-precision using IEEE 754 standard
DoubleType FLOAT64 double 64-bit double-precision using IEEE 754 standard
StringType STRING string UTF-8 encoded string
BinaryType BYTES binary The corresponding array of bytes

You can refer to this link for more information on Spark SQL types. If you want to use a specific encoding schema for your DataFrame values, you can manually convert these types to byte arrays and then store them on Bigtable. The examples in the examples folder contain samples for converting a column to BinaryType inside your application, in different languages.

Complex data type serialization using Apache Avro

You can specify an Avro schema for columns with a complex Spark SQL type such as ArrayType, MapType, or StructType, to serialize and store them in Bigtable.

Row key filter push down

This connector supports pushing down some of the filters on the row key column in the DataFrame to Bigtable and performing them on the server-side. The list of supported or non-supported filters is as follows:

NOTE: The supported row key filters are only pushed to Bigtable when the value used in the filter has a type Long, String, or Byte array (e.g., rowKey < "some-value"). Support for other types (e.g., Integer, Float, etc.) will be added in the future.

Filter Push down filter supported
EqualTo Yes
LessThan Yes
GreaterThan Yes
LessThanOrEqual Yes
GreaterThanOrEqual Yes
StringStartsWith Yes
Or Yes
And Yes
Not No
Compound Row Key No

When using compound row keys, filter on those columns are not pushed to Bigtable and are performed on the client-side (resulting in a full-table scan). If filtering is required, a workaround is to concatenate the intended columns into a single DataFrame column of a supported type (e.g., string) and use that column as the row key with one of the supported filters above. One option is using the concat function, with a sample snippet in Scala as follows:

df
  .withColumn(
    "new_row_key",
    org.apache.spark.sql.functions.concat(
      df.col("first_col"),
      df.col("second_col")
    )
  )
  .drop("first_col")
  .drop("second_col")

Client-side metrics

Since the Bigtable Spark connector is based on the Bigtable Client for Java, client-side metrics are enabled inside the connector by default. You can refer to the client-side metrics documentation to find more details on accessing and interpreting these metrics.

Use with Data Boost (Preview)

For read-only jobs, you can use Data Boost (Preview) serverless compute, a new compute option for Bigtable that is specially optimized for high-throughput pipeline job performance and production app serving traffic isolation requirements. To use Data Boost, you must create a Data Boost app profile and then provide the app profile ID for the spark.bigtable.app_profile.id Spark option when you add your Bigtable configuration to your Spark application. You can also convert an existing app profile to a Data Boost app profile or specify a standard app profile to use your instance's cluster nodes. You can refer to documentations on Data Boost and App profiles for more information.

Use low-level RDD functions with Bigtable

You can use the Bigtable Spark connector to write and read low-level RDDs to and from Bigtable. The connector manages steps such as connection creation and caching to simplify the usage, while giving you freedom for how exactly to convert between your RDD and Bigtable table (e.g., type conversion, custom timestamps for each row, number of columns in each row, etc.). You can create a new BigtableRDD object and call these functions for read and write operations (note that this functionality is only supported in Java and Scala, not PySpark):

Writing an RDD

For writing, you need to pass in an RDD of RowMutationEntry objects to the following function (note the use of Java vs. Scala Map in the two languages):

In Java:

BigtableRDD.writeRDD(
    RDD<RowMutationEntry> rdd, 
    String tableId,
    java.util.Map<String, String> parameters);

In Scala:

BigtableRDD.writeRDD(
   rdd: RDD[RowMutationEntry], 
   tableId: String,
   parameters: Map[String, String]
)

Reading an RDD

When reading an RDD, you receive an RDD of Bigtable Row objects after calling the following function (note the use of Java vs. Scala Map in the two languages):

In Java:

BigtableRDD.readRDD(String tableId, java.util.Map<String, String> parameters);

In Scala:

BigtableRDD.readRDD(tableId: String, parameters: Map[String, String])

Note that in both cases, you can pass in a Map of the following runtime parameters:

  1. spark.bigtable.project.id
  2. spark.bigtable.instance.id
  3. spark.bigtable.app_profile.id
  4. spark.bigtable.read.rows.attempt.timeout.milliseconds
  5. spark.bigtable.read.rows.total.timeout.milliseconds
  6. spark.bigtable.mutate.rows.attempt.timeout.milliseconds
  7. spark.bigtable.mutate.rows.total.timeout.milliseconds
  8. spark.bigtable.batch.mutate.size
  9. spark.bigtable.enable.batch_mutate.flow_control

You can refer to the official documentation for more details about each of these options.

Accessing Bigtable Java Client methods

Since the Bigtable Spark connector is based on the Bigtable client for Java, you can directly use the client in your Spark applications, if you want to have even more control over how you interact with Bigtable.

To use the Bigtable client for Java classes, append the com.google.cloud.spark.bigtable.repackaged prefix to the package names. For example, instead of using the class name as com.google.cloud.bigtable.data.v2.BigtableDataClient, use com.google.cloud.spark.bigtable.repackaged.com.google.cloud.bigtable.data.v2.BigtableDataClient.

Examples

You can access examples for Java, Scala, and Python inside the examples directory. Each directory contains a README.md file with instruction on running the example inside.