All,

Is there an elegant and accepted way to flatten a Spark SQL table (Parquet) with columns that are of nested StructType

For example

If my schema is:

foo
 |_bar
 |_baz
x
y
z

How do I select it into a flattened tabular form without resorting to manually running

df.select("foo.bar","foo.baz","x","y","z")

In other words, how do I obtain the result of the above code programmatically given just a StructType and a DataFrame

  • Have you tried using the explode DataFrame method? – Daniel de Paula May 26 '16 at 22:37
  • 1
    Don't think explode is going to do it. explode creates new rows -- he wants to add columns. I think you need to work with Column objects. – David Griffin May 27 '16 at 2:42
  • Sorry, my mistake. – Daniel de Paula May 27 '16 at 13:55
  • I mean, I'm sure I could do it with explode -- explode actually does let you create new columns. I just don't think it would be very elegant -- you would probably have to do the schema reflection for every record, instead of front-loading the schema reflection to only do it once to create the select(...) – David Griffin May 27 '16 at 15:57
up vote 39 down vote accepted

The short answer is, there's no "accepted" way to do this, but you can do it very elegantly with a recursive function that generates your select(...) statement by walking through the DataFrame.schema.

The recursive function should return an Array[Column]. Every time the function hits a StructType, it would call itself and append the returned Array[Column] to its own Array[Column].

Something like:

def flattenSchema(schema: StructType, prefix: String = null) : Array[Column] = {
  schema.fields.flatMap(f => {
    val colName = if (prefix == null) f.name else (prefix + "." + f.name)

    f.dataType match {
      case st: StructType => flattenSchema(st, colName)
      case _ => Array(col(colName))
    }
  })
}

You would then use it like this:

df.select(flattenSchema(df.schema):_*)
  • Thank you, this seems like a very reasonable solution. – echen May 28 '16 at 12:34
  • 1
    Using this solution, how can I handle lowest level child nodes which have identical names? For example parent element Foo has child Bar and parent element Foz also has a separate child named Bar. When selecting Foo.Bar and Foz.Bar from initial dataframe (with the Array returned by flattenSchema), I get 2 columns both named Bar. But I would like column headers as Foo.Bar or Foo_Bar or something like that. So every one of them would be unique and unambiguous. – V. Samma Jul 15 '16 at 12:08
  • IM having trouble with the col(colName) part, what import statement do I need for col/ – TheM00s3 Oct 20 '16 at 20:39
  • In what version of Spark is the above solution applicable? In Spark 2.1.0 (Java API) it doesn't look like StructField's type can ever be a StructType. – dmux Jan 30 '17 at 19:10
  • 3
    Just in case someone else stumbled on this: if you want the new column names to reflect the nested structure of the original schema: f1.nested1.nested2 ... you should alias the columns at this line: case _ => Array(col(colName)) should become case _ => Array(col(colName).alias(colName)) – ylabidi Mar 6 at 17:08

I am improving my previous answer and offering a solution to my own problem stated in the comments of the accepted answer.

This accepted solution creates an array of Column objects and uses it to select these columns. In Spark, if you have a nested DataFrame, you can select the child column like this: df.select("Parent.Child") and this returns a DataFrame with the values of the child column and is named Child. But if you have identical names for attributes of different parent structures, you lose the info about the parent and may end up with identical column names and cannot access them by name anymore as they are unambiguous.

This was my problem.

I found a solution to my problem, maybe it can help someone else as well. I called the flattenSchema separately:

val flattenedSchema = flattenSchema(df.schema)

and this returned an Array of Column objects. Instead of using this in the select(), which would return a DataFrame with columns named by the child of the last level, I mapped the original column names to themselves as strings, then after selecting Parent.Child column, it renames it as Parent.Child instead of Child (I also replaced dots with underscores for my convenience):

val renamedCols = flattenedSchema.map(name => col(name.toString()).as(name.toString().replace(".","_")))

And then you can use the select function as shown in the original answer:

var newDf = df.select(renamedCols:_*)
  • Hi @V. Samma, This solution is great. However, what will the code be in case of child attributes with the same name and from a single parent attr. ? e.g. { "batter": [ { "id": "1001", "type": "Regular" }, { "id": "1002", "type": "Chocolate" }, { "id": "1003", "type": "Blueberry" }, { "id": "1004", "type": "Devil's Food" } ] } – vsdaking Jul 17 '17 at 16:16
  • @vsdaking Hi, thanks. I'm sure I have tackled a problem where you want data from a JSON array. Unfortunately, some time has passed and I don't have access to Spark currently to test as well. The child attributes with the same name is not a problem because they would need to be the column names for your final DF I presume. You just have to search for how to read JSON Arrays in Spark. Maybe the explode command will help you with that. – V. Samma Jul 17 '17 at 20:47
  • thanks for this @V.Samma I've used this for my problem, however it creates a very wide dataframe, I actually need my nested Struct Types as new Rows in my Dataframe. Any advise on this would be appreciated – ukbaz Sep 28 '17 at 8:23
  • @ukbaz Of course, it takes all nested child properties and flattens them schema-wise, which actually means that they are now a separate column for the dataframe. That was the goal of my solution. I am struggling to understand what do you need exactly. If you have columns ID, Person, Address but schema is like: "ID", "Person.Name", "Person.Age", "Address.City", "Address.Street", "Address.Country", then by flattening, the initial 3 columns create 6 columns. What's the result you would want based on my example? – V. Samma Sep 28 '17 at 8:35
  • Thanks for your reply @V.Samma. Based on your example I get the following; "ID", "Person.Name", "Person.Age", "Address.City", "Address.Street", "Address.Country", "ID1", "Person.Name1", "Person.Age1", "Address.City1", "Address.Street1", "Address.Country1","ID2", "Person.Name2", "Person.Age2", "Address.City2", "Address.Street2", "Address.Country2" ... etc this goes on. What I would like is those new columns to be Rows in my dataframe, so the data in "ID1" and "ID2" would be under the ID column. Thanks – ukbaz Sep 28 '17 at 9:21

Just wanted to share my solution for Pyspark - it's more or less a translation of @David Griffin's solution, so it supports any level of nested objects.

from pyspark.sql.types import StructType, ArrayType  

def flatten(schema, prefix=None):
    fields = []
    for field in schema.fields:
        name = prefix + '.' + field.name if prefix else field.name
        dtype = field.dataType
        if isinstance(dtype, ArrayType):
            dtype = dtype.elementType

        if isinstance(dtype, StructType):
            fields += flatten(dtype, prefix=name)
        else:
            fields.append(name)

    return fields


df.select(flattenSchema(df.schema)).show()

You could also use SQL to select columns as flat.

  1. Get original data-frame schema
  2. Generate SQL string, by browsing schema
  3. Query your original data-frame

I did an implementation in Java: https://gist.github.com/ebuildy/3de0e2855498e5358e4eed1a4f72ea48

(use recursive method as well, I prefer SQL way, so you can test it easily via Spark-shell).

I have been using one liners which result in a flattened schema with 5 columns of bar, baz, x, y, z:

df.select("foo.*", "x", "y", "z")

As for explode: I typically reserve explode for flattening a list. For example if you have a column idList that is a list of Strings, you could do:

df.withColumn("flattenedId", functions.explode(col("idList")))
  .drop("idList")

That will result in a new Dataframe with a column named flattenedId (no longer a list)

Here is a function that is doing what you want and that can deal with multiple nested columns containing columns with same name, with a prefix:

from pyspark.sql import functions as F

def flatten_df(nested_df):
    flat_cols = [c[0] for c in nested_df.dtypes if c[1][:6] != 'struct']
    nested_cols = [c[0] for c in nested_df.dtypes if c[1][:6] == 'struct']

    flat_df = nested_df.select(flat_cols +
                               [F.col(nc+'.'+c).alias(nc+'_'+c)
                                for nc in nested_cols
                                for c in nested_df.select(nc+'.*').columns])
    return flat_df

Before:

root
 |-- x: string (nullable = true)
 |-- y: string (nullable = true)
 |-- foo: struct (nullable = true)
 |    |-- a: float (nullable = true)
 |    |-- b: float (nullable = true)
 |    |-- c: integer (nullable = true)
 |-- bar: struct (nullable = true)
 |    |-- a: float (nullable = true)
 |    |-- b: float (nullable = true)
 |    |-- c: integer (nullable = true)

After:

root
 |-- x: string (nullable = true)
 |-- y: string (nullable = true)
 |-- foo_a: float (nullable = true)
 |-- foo_b: float (nullable = true)
 |-- foo_c: integer (nullable = true)
 |-- bar_a: float (nullable = true)
 |-- bar_b: float (nullable = true)
 |-- bar_c: integer (nullable = true)

I added a DataFrame#flattenSchema method to the open source spark-daria project.

Here's how you can use the function with your code.

import com.github.mrpowers.spark.daria.sql.DataFrameExt._
df.flattenSchema().show()

+-------+-------+---------+----+---+
|foo.bar|foo.baz|        x|   y|  z|
+-------+-------+---------+----+---+
|   this|     is|something|cool| ;)|
+-------+-------+---------+----+---+

You can also specify different column name delimiters with the flattenSchema() method.

df.flattenSchema(delimiter = "_").show()
+-------+-------+---------+----+---+
|foo_bar|foo_baz|        x|   y|  z|
+-------+-------+---------+----+---+
|   this|     is|something|cool| ;)|
+-------+-------+---------+----+---+

This delimiter parameter is surprisingly important. If you're flattening your schema to load the table in Redshift, you won't be able to use periods as the delimiter.

Here's the full code snippet to generate this output.

val data = Seq(
  Row(Row("this", "is"), "something", "cool", ";)")
)

val schema = StructType(
  Seq(
    StructField(
      "foo",
      StructType(
        Seq(
          StructField("bar", StringType, true),
          StructField("baz", StringType, true)
        )
      ),
      true
    ),
    StructField("x", StringType, true),
    StructField("y", StringType, true),
    StructField("z", StringType, true)
  )
)

val df = spark.createDataFrame(
  spark.sparkContext.parallelize(data),
  StructType(schema)
)

df.flattenSchema().show()

The underlying code is similar to David Griffin's code (in case you don't want to add the spark-daria dependency to your project).

object StructTypeHelpers {

  def flattenSchema(schema: StructType, delimiter: String = ".", prefix: String = null): Array[Column] = {
    schema.fields.flatMap(structField => {
      val codeColName = if (prefix == null) structField.name else prefix + "." + structField.name
      val colName = if (prefix == null) structField.name else prefix + delimiter + structField.name

      structField.dataType match {
        case st: StructType => flattenSchema(schema = st, delimiter = delimiter, prefix = colName)
        case _ => Array(col(codeColName).alias(colName))
      }
    })
  }

}

object DataFrameExt {

  implicit class DataFrameMethods(df: DataFrame) {

    def flattenSchema(delimiter: String = ".", prefix: String = null): DataFrame = {
      df.select(
        StructTypeHelpers.flattenSchema(df.schema, delimiter, prefix): _*
      )
    }

  }

}

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