Spark SQL allows relational queries expressed in SQL, HiveQL, or Scala to be executed using Spark. At the core of this component is a new type of RDD, SchemaRDD. SchemaRDDs are composed of Row objects, along with a schema that describes the data types of each column in the row. A SchemaRDD is similar to a table in a traditional relational database. A SchemaRDD can be created from an existing RDD, a Parquet file, a JSON dataset, or by running HiveQL against data stored in Apache Hive.
All of the examples on this page use sample data included in the Spark distribution and can be run in the spark-shell
.
Spark SQL allows relational queries expressed in SQL or HiveQL to be executed using Spark. At the core of this component is a new type of RDD, SchemaRDD. SchemaRDDs are composed of Row objects, along with a schema that describes the data types of each column in the row. A SchemaRDD is similar to a table in a traditional relational database. A SchemaRDD can be created from an existing RDD, a Parquet file, a JSON dataset, or by running HiveQL against data stored in Apache Hive.
All of the examples on this page use sample data included in the Spark distribution and can be run in the pyspark
shell.
Spark SQL is currently an alpha component. While we will minimize API changes, some APIs may change in future releases.
The entry point into all relational functionality in Spark is the SQLContext class, or one of its descendants. To create a basic SQLContext, all you need is a SparkContext.
{% highlight scala %} val sc: SparkContext // An existing SparkContext. val sqlContext = new org.apache.spark.sql.SQLContext(sc)
// createSchemaRDD is used to implicitly convert an RDD to a SchemaRDD. import sqlContext.createSchemaRDD {% endhighlight %}
In addition to the basic SQLContext, you can also create a HiveContext, which provides a superset of the functionality provided by the basic SQLContext. Additional features include the ability to write queries using the more complete HiveQL parser, access to HiveUDFs, and the ability to read data from Hive tables. To use a HiveContext, you do not need to have an existing Hive setup, and all of the data sources available to a SQLContext are still available. HiveContext is only packaged separately to avoid including all of Hive's dependencies in the default Spark build. If these dependencies are not a problem for your application then using HiveContext is recommended for the 1.2 release of Spark. Future releases will focus on bringing SQLContext up to feature parity with a HiveContext.
The entry point into all relational functionality in Spark is the JavaSQLContext class, or one of its descendants. To create a basic JavaSQLContext, all you need is a JavaSparkContext.
{% highlight java %} JavaSparkContext sc = ...; // An existing JavaSparkContext. JavaSQLContext sqlContext = new org.apache.spark.sql.api.java.JavaSQLContext(sc); {% endhighlight %}
In addition to the basic SQLContext, you can also create a HiveContext, which provides a strict super set of the functionality provided by the basic SQLContext. Additional features include the ability to write queries using the more complete HiveQL parser, access to HiveUDFs, and the ability to read data from Hive tables. To use a HiveContext, you do not need to have an existing Hive setup, and all of the data sources available to a SQLContext are still available. HiveContext is only packaged separately to avoid including all of Hive's dependencies in the default Spark build. If these dependencies are not a problem for your application then using HiveContext is recommended for the 1.2 release of Spark. Future releases will focus on bringing SQLContext up to feature parity with a HiveContext.
The entry point into all relational functionality in Spark is the SQLContext class, or one of its decedents. To create a basic SQLContext, all you need is a SparkContext.
{% highlight python %} from pyspark.sql import SQLContext sqlContext = SQLContext(sc) {% endhighlight %}
In addition to the basic SQLContext, you can also create a HiveContext, which provides a strict super set of the functionality provided by the basic SQLContext. Additional features include the ability to write queries using the more complete HiveQL parser, access to HiveUDFs, and the ability to read data from Hive tables. To use a HiveContext, you do not need to have an existing Hive setup, and all of the data sources available to a SQLContext are still available. HiveContext is only packaged separately to avoid including all of Hive's dependencies in the default Spark build. If these dependencies are not a problem for your application then using HiveContext is recommended for the 1.2 release of Spark. Future releases will focus on bringing SQLContext up to feature parity with a HiveContext.
The specific variant of SQL that is used to parse queries can also be selected using the spark.sql.dialect
option. This parameter can be changed using either the setConf
method on a SQLContext or by using a SET key=value
command in SQL. For a SQLContext, the only dialect available is “sql” which uses a simple SQL parser provided by Spark SQL. In a HiveContext, the default is “hiveql”, though “sql” is also available. Since the HiveQL parser is much more complete, this is recommended for most use cases.
Spark SQL supports operating on a variety of data sources through the SchemaRDD
interface. A SchemaRDD can be operated on as normal RDDs and can also be registered as a temporary table. Registering a SchemaRDD as a table allows you to run SQL queries over its data. This section describes the various methods for loading data into a SchemaRDD.
Spark SQL supports two different methods for converting existing RDDs into SchemaRDDs. The first method uses reflection to infer the schema of an RDD that contains specific types of objects. This reflection based approach leads to more concise code and works well when you already know the schema while writing your Spark application.
The second method for creating SchemaRDDs is through a programmatic interface that allows you to construct a schema and then apply it to an existing RDD. While this method is more verbose, it allows you to construct SchemaRDDs when the columns and their types are not known until runtime.
The Scala interaface for Spark SQL supports automatically converting an RDD containing case classes to a SchemaRDD. The case class defines the schema of the table. The names of the arguments to the case class are read using reflection and become the names of the columns. Case classes can also be nested or contain complex types such as Sequences or Arrays. This RDD can be implicitly converted to a SchemaRDD and then be registered as a table. Tables can be used in subsequent SQL statements.
{% highlight scala %} // sc is an existing SparkContext. val sqlContext = new org.apache.spark.sql.SQLContext(sc) // createSchemaRDD is used to implicitly convert an RDD to a SchemaRDD. import sqlContext.createSchemaRDD
// Define the schema using a case class. // Note: Case classes in Scala 2.10 can support only up to 22 fields. To work around this limit, // you can use custom classes that implement the Product interface. case class Person(name: String, age: Int)
// Create an RDD of Person objects and register it as a table. val people = sc.textFile(“examples/src/main/resources/people.txt”).map(_.split(“,”)).map(p => Person(p(0), p(1).trim.toInt)) people.registerTempTable(“people”)
// SQL statements can be run by using the sql methods provided by sqlContext. val teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”)
// The results of SQL queries are SchemaRDDs and support all the normal RDD operations. // The columns of a row in the result can be accessed by ordinal. teenagers.map(t => "Name: " + t(0)).collect().foreach(println) {% endhighlight %}
Spark SQL supports automatically converting an RDD of JavaBeans into a Schema RDD. The BeanInfo, obtained using reflection, defines the schema of the table. Currently, Spark SQL does not support JavaBeans that contain nested or contain complex types such as Lists or Arrays. You can create a JavaBean by creating a class that implements Serializable and has getters and setters for all of its fields.
{% highlight java %}
public static class Person implements Serializable { private String name; private int age;
public String getName() { return name; }
public void setName(String name) { this.name = name; }
public int getAge() { return age; }
public void setAge(int age) { this.age = age; } }
{% endhighlight %}
A schema can be applied to an existing RDD by calling applySchema
and providing the Class object for the JavaBean.
{% highlight java %} // sc is an existing JavaSparkContext. JavaSQLContext sqlContext = new org.apache.spark.sql.api.java.JavaSQLContext(sc);
// Load a text file and convert each line to a JavaBean. JavaRDD people = sc.textFile(“examples/src/main/resources/people.txt”).map( new Function<String, Person>() { public Person call(String line) throws Exception { String[] parts = line.split(“,”);
Person person = new Person(); person.setName(parts[0]); person.setAge(Integer.parseInt(parts[1].trim())); return person; }
});
// Apply a schema to an RDD of JavaBeans and register it as a table. JavaSchemaRDD schemaPeople = sqlContext.applySchema(people, Person.class); schemaPeople.registerTempTable(“people”);
// SQL can be run over RDDs that have been registered as tables. JavaSchemaRDD teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”)
// The results of SQL queries are SchemaRDDs and support all the normal RDD operations. // The columns of a row in the result can be accessed by ordinal. List teenagerNames = teenagers.map(new Function<Row, String>() { public String call(Row row) { return "Name: " + row.getString(0); } }).collect();
{% endhighlight %}
Spark SQL can convert an RDD of Row objects to a SchemaRDD, inferring the datatypes. Rows are constructed by passing a list of key/value pairs as kwargs to the Row class. The keys of this list define the column names of the table, and the types are inferred by looking at the first row. Since we currently only look at the first row, it is important that there is no missing data in the first row of the RDD. In future versions we plan to more completely infer the schema by looking at more data, similar to the inference that is performed on JSON files.
{% highlight python %}
from pyspark.sql import SQLContext, Row sqlContext = SQLContext(sc)
lines = sc.textFile(“examples/src/main/resources/people.txt”) parts = lines.map(lambda l: l.split(“,”)) people = parts.map(lambda p: Row(name=p[0], age=int(p[1])))
schemaPeople = sqlContext.inferSchema(people) schemaPeople.registerTempTable(“people”)
teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”)
teenNames = teenagers.map(lambda p: "Name: " + p.name) for teenName in teenNames.collect(): print teenName {% endhighlight %}
When case classes cannot be defined ahead of time (for example, the structure of records is encoded in a string, or a text dataset will be parsed and fields will be projected differently for different users), a SchemaRDD
can be created programmatically with three steps.
Row
s from the original RDD;StructType
matching the structure of Row
s in the RDD created in Step 1.Row
s via applySchema
method provided by SQLContext
.For example: {% highlight scala %} // sc is an existing SparkContext. val sqlContext = new org.apache.spark.sql.SQLContext(sc)
// Create an RDD val people = sc.textFile(“examples/src/main/resources/people.txt”)
// The schema is encoded in a string val schemaString = “name age”
// Import Spark SQL data types and Row. import org.apache.spark.sql._
// Generate the schema based on the string of schema val schema = StructType( schemaString.split(" ").map(fieldName => StructField(fieldName, StringType, true)))
// Convert records of the RDD (people) to Rows. val rowRDD = people.map(_.split(“,”)).map(p => Row(p(0), p(1).trim))
// Apply the schema to the RDD. val peopleSchemaRDD = sqlContext.applySchema(rowRDD, schema)
// Register the SchemaRDD as a table. peopleSchemaRDD.registerTempTable(“people”)
// SQL statements can be run by using the sql methods provided by sqlContext. val results = sqlContext.sql(“SELECT name FROM people”)
// The results of SQL queries are SchemaRDDs and support all the normal RDD operations. // The columns of a row in the result can be accessed by ordinal. results.map(t => "Name: " + t(0)).collect().foreach(println) {% endhighlight %}
When JavaBean classes cannot be defined ahead of time (for example, the structure of records is encoded in a string, or a text dataset will be parsed and fields will be projected differently for different users), a SchemaRDD
can be created programmatically with three steps.
Row
s from the original RDD;StructType
matching the structure of Row
s in the RDD created in Step 1.Row
s via applySchema
method provided by JavaSQLContext
.For example: {% highlight java %} // Import factory methods provided by DataType. import org.apache.spark.sql.api.java.DataType // Import StructType and StructField import org.apache.spark.sql.api.java.StructType import org.apache.spark.sql.api.java.StructField // Import Row. import org.apache.spark.sql.api.java.Row
// sc is an existing JavaSparkContext. JavaSQLContext sqlContext = new org.apache.spark.sql.api.java.JavaSQLContext(sc);
// Load a text file and convert each line to a JavaBean. JavaRDD people = sc.textFile(“examples/src/main/resources/people.txt”);
// The schema is encoded in a string String schemaString = “name age”;
// Generate the schema based on the string of schema List fields = new ArrayList(); for (String fieldName: schemaString.split(" ")) { fields.add(DataType.createStructField(fieldName, DataType.StringType, true)); } StructType schema = DataType.createStructType(fields);
// Convert records of the RDD (people) to Rows. JavaRDD rowRDD = people.map( new Function<String, Row>() { public Row call(String record) throws Exception { String[] fields = record.split(“,”); return Row.create(fields[0], fields[1].trim()); } });
// Apply the schema to the RDD. JavaSchemaRDD peopleSchemaRDD = sqlContext.applySchema(rowRDD, schema);
// Register the SchemaRDD as a table. peopleSchemaRDD.registerTempTable(“people”);
// SQL can be run over RDDs that have been registered as tables. JavaSchemaRDD results = sqlContext.sql(“SELECT name FROM people”);
// The results of SQL queries are SchemaRDDs and support all the normal RDD operations. // The columns of a row in the result can be accessed by ordinal. List names = results.map(new Function<Row, String>() { public String call(Row row) { return "Name: " + row.getString(0); } }).collect();
{% endhighlight %}
When a dictionary of kwargs cannot be defined ahead of time (for example, the structure of records is encoded in a string, or a text dataset will be parsed and fields will be projected differently for different users), a SchemaRDD
can be created programmatically with three steps.
StructType
matching the structure of tuples or lists in the RDD created in the step 1.applySchema
method provided by SQLContext
.For example: {% highlight python %}
from pyspark.sql import *
sqlContext = SQLContext(sc)
lines = sc.textFile(“examples/src/main/resources/people.txt”) parts = lines.map(lambda l: l.split(“,”)) people = parts.map(lambda p: (p[0], p[1].strip()))
schemaString = “name age”
fields = [StructField(field_name, StringType(), True) for field_name in schemaString.split()] schema = StructType(fields)
schemaPeople = sqlContext.applySchema(people, schema)
schemaPeople.registerTempTable(“people”)
results = sqlContext.sql(“SELECT name FROM people”)
names = results.map(lambda p: "Name: " + p.name) for name in names.collect(): print name {% endhighlight %}
Parquet is a columnar format that is supported by many other data processing systems. Spark SQL provides support for both reading and writing Parquet files that automatically preserves the schema of the original data.
Using the data from the above example:
{% highlight scala %} // sqlContext from the previous example is used in this example. // createSchemaRDD is used to implicitly convert an RDD to a SchemaRDD. import sqlContext.createSchemaRDD
val people: RDD[Person] = ... // An RDD of case class objects, from the previous example.
// The RDD is implicitly converted to a SchemaRDD by createSchemaRDD, allowing it to be stored using Parquet. people.saveAsParquetFile(“people.parquet”)
// Read in the parquet file created above. Parquet files are self-describing so the schema is preserved. // The result of loading a Parquet file is also a SchemaRDD. val parquetFile = sqlContext.parquetFile(“people.parquet”)
//Parquet files can also be registered as tables and then used in SQL statements. parquetFile.registerTempTable(“parquetFile”) val teenagers = sqlContext.sql(“SELECT name FROM parquetFile WHERE age >= 13 AND age <= 19”) teenagers.map(t => "Name: " + t(0)).collect().foreach(println) {% endhighlight %}
{% highlight java %} // sqlContext from the previous example is used in this example.
JavaSchemaRDD schemaPeople = ... // The JavaSchemaRDD from the previous example.
// JavaSchemaRDDs can be saved as Parquet files, maintaining the schema information. schemaPeople.saveAsParquetFile(“people.parquet”);
// Read in the Parquet file created above. Parquet files are self-describing so the schema is preserved. // The result of loading a parquet file is also a JavaSchemaRDD. JavaSchemaRDD parquetFile = sqlContext.parquetFile(“people.parquet”);
//Parquet files can also be registered as tables and then used in SQL statements. parquetFile.registerTempTable(“parquetFile”); JavaSchemaRDD teenagers = sqlContext.sql(“SELECT name FROM parquetFile WHERE age >= 13 AND age <= 19”); List teenagerNames = teenagers.map(new Function<Row, String>() { public String call(Row row) { return "Name: " + row.getString(0); } }).collect(); {% endhighlight %}
{% highlight python %}
schemaPeople # The SchemaRDD from the previous example.
schemaPeople.saveAsParquetFile(“people.parquet”)
parquetFile = sqlContext.parquetFile(“people.parquet”)
parquetFile.registerTempTable(“parquetFile”); teenagers = sqlContext.sql(“SELECT name FROM parquetFile WHERE age >= 13 AND age <= 19”) teenNames = teenagers.map(lambda p: "Name: " + p.name) for teenName in teenNames.collect(): print teenName {% endhighlight %}
Configuration of Parquet can be done using the setConf
method on SQLContext or by running SET key=value
commands using SQL.
jsonFile
- loads data from a directory of JSON files where each line of the files is a JSON object.jsonRDD
- loads data from an existing RDD where each element of the RDD is a string containing a JSON object.{% highlight scala %} // sc is an existing SparkContext. val sqlContext = new org.apache.spark.sql.SQLContext(sc)
// A JSON dataset is pointed to by path. // The path can be either a single text file or a directory storing text files. val path = “examples/src/main/resources/people.json” // Create a SchemaRDD from the file(s) pointed to by path val people = sqlContext.jsonFile(path)
// The inferred schema can be visualized using the printSchema() method. people.printSchema() // root // |-- age: integer (nullable = true) // |-- name: string (nullable = true)
// Register this SchemaRDD as a table. people.registerTempTable(“people”)
// SQL statements can be run by using the sql methods provided by sqlContext. val teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”)
// Alternatively, a SchemaRDD can be created for a JSON dataset represented by // an RDD[String] storing one JSON object per string. val anotherPeopleRDD = sc.parallelize( “““{“name”:“Yin”,“address”:{“city”:“Columbus”,“state”:“Ohio”}}””” :: Nil) val anotherPeople = sqlContext.jsonRDD(anotherPeopleRDD) {% endhighlight %}
jsonFile
- loads data from a directory of JSON files where each line of the files is a JSON object.jsonRDD
- loads data from an existing RDD where each element of the RDD is a string containing a JSON object.{% highlight java %} // sc is an existing JavaSparkContext. JavaSQLContext sqlContext = new org.apache.spark.sql.api.java.JavaSQLContext(sc);
// A JSON dataset is pointed to by path. // The path can be either a single text file or a directory storing text files. String path = “examples/src/main/resources/people.json”; // Create a JavaSchemaRDD from the file(s) pointed to by path JavaSchemaRDD people = sqlContext.jsonFile(path);
// The inferred schema can be visualized using the printSchema() method. people.printSchema(); // root // |-- age: integer (nullable = true) // |-- name: string (nullable = true)
// Register this JavaSchemaRDD as a table. people.registerTempTable(“people”);
// SQL statements can be run by using the sql methods provided by sqlContext. JavaSchemaRDD teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”);
// Alternatively, a JavaSchemaRDD can be created for a JSON dataset represented by // an RDD[String] storing one JSON object per string. List jsonData = Arrays.asList( “{"name":"Yin","address":{"city":"Columbus","state":"Ohio"}}”); JavaRDD anotherPeopleRDD = sc.parallelize(jsonData); JavaSchemaRDD anotherPeople = sqlContext.jsonRDD(anotherPeopleRDD); {% endhighlight %}
jsonFile
- loads data from a directory of JSON files where each line of the files is a JSON object.jsonRDD
- loads data from an existing RDD where each element of the RDD is a string containing a JSON object.{% highlight python %}
from pyspark.sql import SQLContext sqlContext = SQLContext(sc)
path = “examples/src/main/resources/people.json”
people = sqlContext.jsonFile(path)
people.printSchema()
people.registerTempTable(“people”)
teenagers = sqlContext.sql(“SELECT name FROM people WHERE age >= 13 AND age <= 19”)
anotherPeopleRDD = sc.parallelize([ ‘{“name”:“Yin”,“address”:{“city”:“Columbus”,“state”:“Ohio”}}’]) anotherPeople = sqlContext.jsonRDD(anotherPeopleRDD) {% endhighlight %}
Spark SQL also supports reading and writing data stored in Apache Hive. However, since Hive has a large number of dependencies, it is not included in the default Spark assembly. In order to use Hive you must first run “sbt/sbt -Phive assembly/assembly
” (or use -Phive
for maven). This command builds a new assembly jar that includes Hive. Note that this Hive assembly jar must also be present on all of the worker nodes, as they will need access to the Hive serialization and deserialization libraries (SerDes) in order to access data stored in Hive.
Configuration of Hive is done by placing your hive-site.xml
file in conf/
.
When working with Hive one must construct a HiveContext
, which inherits from SQLContext
, and adds support for finding tables in the MetaStore and writing queries using HiveQL. Users who do not have an existing Hive deployment can still create a HiveContext. When not configured by the hive-site.xml, the context automatically creates metastore_db
and warehouse
in the current directory.
{% highlight scala %} // sc is an existing SparkContext. val sqlContext = new org.apache.spark.sql.hive.HiveContext(sc)
sqlContext.sql(“CREATE TABLE IF NOT EXISTS src (key INT, value STRING)”) sqlContext.sql(“LOAD DATA LOCAL INPATH ‘examples/src/main/resources/kv1.txt’ INTO TABLE src”)
// Queries are expressed in HiveQL sqlContext.sql(“FROM src SELECT key, value”).collect().foreach(println) {% endhighlight %}
When working with Hive one must construct a JavaHiveContext
, which inherits from JavaSQLContext
, and adds support for finding tables in the MetaStore and writing queries using HiveQL. In addition to the sql
method a JavaHiveContext
also provides an hql
methods, which allows queries to be expressed in HiveQL.
{% highlight java %} // sc is an existing JavaSparkContext. JavaHiveContext sqlContext = new org.apache.spark.sql.hive.api.java.HiveContext(sc);
sqlContext.sql(“CREATE TABLE IF NOT EXISTS src (key INT, value STRING)”); sqlContext.sql(“LOAD DATA LOCAL INPATH ‘examples/src/main/resources/kv1.txt’ INTO TABLE src”);
// Queries are expressed in HiveQL. Row[] results = sqlContext.sql(“FROM src SELECT key, value”).collect();
{% endhighlight %}
When working with Hive one must construct a HiveContext
, which inherits from SQLContext
, and adds support for finding tables in the MetaStore and writing queries using HiveQL. In addition to the sql
method a HiveContext
also provides an hql
methods, which allows queries to be expressed in HiveQL.
{% highlight python %}
from pyspark.sql import HiveContext sqlContext = HiveContext(sc)
sqlContext.sql(“CREATE TABLE IF NOT EXISTS src (key INT, value STRING)”) sqlContext.sql(“LOAD DATA LOCAL INPATH ‘examples/src/main/resources/kv1.txt’ INTO TABLE src”)
results = sqlContext.sql(“FROM src SELECT key, value”).collect()
{% endhighlight %}
For some workloads it is possible to improve performance by either caching data in memory, or by turning on some experimental options.
Spark SQL can cache tables using an in-memory columnar format by calling sqlContext.cacheTable("tableName")
. Then Spark SQL will scan only required columns and will automatically tune compression to minimize memory usage and GC pressure. You can call sqlContext.uncacheTable("tableName")
to remove the table from memory.
Note that if you call schemaRDD.cache()
rather than sqlContext.cacheTable(...)
, tables will not be cached using the in-memory columnar format, and therefore sqlContext.cacheTable(...)
is strongly recommended for this use case.
Configuration of in-memory caching can be done using the setConf
method on SQLContext or by running SET key=value
commands using SQL.
The following options can also be used to tune the performance of query execution. It is possible that these options will be deprecated in future release as more optimizations are performed automatically.
Spark SQL also supports interfaces for running SQL queries directly without the need to write any code.
The Thrift JDBC server implemented here corresponds to the HiveServer2
in Hive 0.12. You can test the JDBC server with the beeline script that comes with either Spark or Hive 0.12.
To start the JDBC server, run the following in the Spark directory:
./sbin/start-thriftserver.sh
This script accepts all bin/spark-submit
command line options, plus a --hiveconf
option to specify Hive properties. You may run ./sbin/start-thriftserver.sh --help
for a complete list of all available options. By default, the server listens on localhost:10000. You may override this bahaviour via either environment variables, i.e.:
{% highlight bash %} export HIVE_SERVER2_THRIFT_PORT= export HIVE_SERVER2_THRIFT_BIND_HOST= ./sbin/start-thriftserver.sh
--master
... {% endhighlight %}
or system properties:
{% highlight bash %} ./sbin/start-thriftserver.sh
--hiveconf hive.server2.thrift.port=
--hiveconf hive.server2.thrift.bind.host=
--master ... {% endhighlight %}
Now you can use beeline to test the Thrift JDBC server:
./bin/beeline
Connect to the JDBC server in beeline with:
beeline> !connect jdbc:hive2://localhost:10000
Beeline will ask you for a username and password. In non-secure mode, simply enter the username on your machine and a blank password. For secure mode, please follow the instructions given in the beeline documentation.
Configuration of Hive is done by placing your hive-site.xml
file in conf/
.
You may also use the beeline script that comes with Hive.
The Spark SQL CLI is a convenient tool to run the Hive metastore service in local mode and execute queries input from the command line. Note that the Spark SQL CLI cannot talk to the Thrift JDBC server.
To start the Spark SQL CLI, run the following in the Spark directory:
./bin/spark-sql
Configuration of Hive is done by placing your hive-site.xml
file in conf/
. You may run ./bin/spark-sql --help
for a complete list of all available options.
To set a Fair Scheduler pool for a JDBC client session, users can set the spark.sql.thriftserver.scheduler.pool
variable:
SET spark.sql.thriftserver.scheduler.pool=accounting;
In Shark, default reducer number is 1 and is controlled by the property mapred.reduce.tasks
. Spark SQL deprecates this property in favor of spark.sql.shuffle.partitions
, whose default value is 200. Users may customize this property via SET
:
SET spark.sql.shuffle.partitions=10; SELECT page, count(*) c FROM logs_last_month_cached GROUP BY page ORDER BY c DESC LIMIT 10;
You may also put this property in hive-site.xml
to override the default value.
For now, the mapred.reduce.tasks
property is still recognized, and is converted to spark.sql.shuffle.partitions
automatically.
The shark.cache
table property no longer exists, and tables whose name end with _cached
are no longer automatically cached. Instead, we provide CACHE TABLE
and UNCACHE TABLE
statements to let user control table caching explicitly:
CACHE TABLE logs_last_month; UNCACHE TABLE logs_last_month;
NOTE: CACHE TABLE tbl
is lazy, similar to .cache
on an RDD. This command only marks tbl
to ensure that partitions are cached when calculated but doesn't actually cache it until a query that touches tbl
is executed. To force the table to be cached, you may simply count the table immediately after executing CACHE TABLE
:
CACHE TABLE logs_last_month; SELECT COUNT(1) FROM logs_last_month;
Several caching related features are not supported yet:
Spark SQL is designed to be compatible with the Hive Metastore, SerDes and UDFs. Currently Spark SQL is based on Hive 0.12.0.
The Spark SQL Thrift JDBC server is designed to be “out of the box” compatible with existing Hive installations. You do not need to modify your existing Hive Metastore or change the data placement or partitioning of your tables.
Spark SQL supports the vast majority of Hive features, such as:
SELECT
GROUP BY
ORDER BY
CLUSTER BY
SORT BY
=
, ⇔
, ==
, <>
, <
, >
, >=
, <=
, etc)+
, -
, *
, /
, %
, etc)AND
, &&
, OR
, ||
, etc)sign
, ln
, cos
, etc)instr
, length
, printf
, etc)JOIN
{LEFT|RIGHT|FULL} OUTER JOIN
LEFT SEMI JOIN
CROSS JOIN
SELECT col FROM ( SELECT a + b AS col from t1) t2
CREATE TABLE
CREATE TABLE AS SELECT
ALTER TABLE
TINYINT
SMALLINT
INT
BIGINT
BOOLEAN
FLOAT
DOUBLE
STRING
BINARY
TIMESTAMP
ARRAY<>
MAP<>
STRUCT<>
Below is a list of Hive features that we don't support yet. Most of these features are rarely used in Hive deployments.
Major Hive Features
Esoteric Hive Features
key < 10
”), Spark SQL will output wrong result for the NULL
tuple.UNION
type and DATE
typeHive Input/Output Formats
Hive Optimizations
A handful of Hive optimizations are not yet included in Spark. Some of these (such as indexes) are less important due to Spark SQL's in-memory computational model. Others are slotted for future releases of Spark SQL.
SET spark.sql.shuffle.partitions=[num_tasks];
”.STREAMTABLE
hint in join: Spark SQL does not follow the STREAMTABLE
hint.Language-Integrated queries are experimental and currently only supported in Scala.
Spark SQL also supports a domain specific language for writing queries. Once again, using the data from the above examples:
{% highlight scala %} // sc is an existing SparkContext. val sqlContext = new org.apache.spark.sql.SQLContext(sc) // Importing the SQL context gives access to all the public SQL functions and implicit conversions. import sqlContext._ val people: RDD[Person] = ... // An RDD of case class objects, from the first example.
// The following is the same as ‘SELECT name FROM people WHERE age >= 10 AND age <= 19’ val teenagers = people.where('age >= 10).where('age <= 19).select('name) teenagers.map(t => "Name: " + t(0)).collect().foreach(println) {% endhighlight %}
The DSL uses Scala symbols to represent columns in the underlying table, which are identifiers prefixed with a tick ('
). Implicit conversions turn these symbols into expressions that are evaluated by the SQL execution engine. A full list of the functions supported can be found in the ScalaDoc.
ByteType
: Represents 1-byte signed integer numbers. The range of numbers is from -128
to 127
.ShortType
: Represents 2-byte signed integer numbers. The range of numbers is from -32768
to 32767
.IntegerType
: Represents 4-byte signed integer numbers. The range of numbers is from -2147483648
to 2147483647
.LongType
: Represents 8-byte signed integer numbers. The range of numbers is from -9223372036854775808
to 9223372036854775807
.FloatType
: Represents 4-byte single-precision floating point numbers.DoubleType
: Represents 8-byte double-precision floating point numbers.DecimalType
: Represents arbitrary-precision signed decimal numbers. Backed internally by java.math.BigDecimal
. A BigDecimal
consists of an arbitrary precision integer unscaled value and a 32-bit integer scale.StringType
: Represents character string values.BinaryType
: Represents byte sequence values.BooleanType
: Represents boolean values.TimestampType
: Represents values comprising values of fields year, month, day, hour, minute, and second.ArrayType(elementType, containsNull)
: Represents values comprising a sequence of elements with the type of elementType
. containsNull
is used to indicate if elements in a ArrayType
value can have null
values.MapType(keyType, valueType, valueContainsNull)
: Represents values comprising a set of key-value pairs. The data type of keys are described by keyType
and the data type of values are described by valueType
. For a MapType
value, keys are not allowed to have null
values. valueContainsNull
is used to indicate if values of a MapType
value can have null
values.StructType(fields)
: Represents values with the structure described by a sequence of StructField
s (fields
).StructField(name, dataType, nullable)
: Represents a field in a StructType
. The name of a field is indicated by name
. The data type of a field is indicated by dataType
. nullable
is used to indicate if values of this fields can have null
values.All data types of Spark SQL are located in the package org.apache.spark.sql
. You can access them by doing {% highlight scala %} import org.apache.spark.sql._ {% endhighlight %}
All data types of Spark SQL are located in the package of org.apache.spark.sql.api.java
. To access or create a data type, please use factory methods provided in org.apache.spark.sql.api.java.DataType
.
All data types of Spark SQL are located in the package of pyspark.sql
. You can access them by doing {% highlight python %} from pyspark.sql import * {% endhighlight %}