14

Is it possible to add extra meta data to DataFrames?

Reason

I have Spark DataFrames for which I need to keep extra information. Example: A DataFrame, for which I want to "remember" the highest used index in an Integer id column.

Current solution

I use a separate DataFrame to store this information. Of course, keeping this information separately is tedious and error-prone.

Is there a better solution to store such extra information on DataFrames?

  • Would it be possible to add an additional column to the target dataframe? – Till Rohrmann Sep 17 '15 at 11:27
  • In total I'm interested in storing roughly 1-10 additional values per DataFrame. Even though it would be possible to store that information in additional columns, I'm still concerned about memory usage. (Not sure, how Column(...).lit(....) behaves in such case.) – Martin Senne Sep 17 '15 at 11:44
  • 1
    Is there a need to persist the metadata or can it be easily recomputed? – Ryan Sep 17 '15 at 13:48
  • 1
    Persistence of metadata is wanted. – Martin Senne Sep 17 '15 at 14:04
  • Aha - it seems that Spark has had some support for metadata for columns since 1.2, which seems to persist when copied at least. See my answer. – nealmcb Dec 15 '15 at 20:59
14

To expand and Scala-fy nealmcb's answer (the question was tagged scala, not python, so I don't think this answer will be off-topic or redundant), suppose you have a DataFrame:

import org.apache.spark.sql
val df = sc.parallelize(Seq.fill(100) { scala.util.Random.nextInt() }).toDF("randInt")

And some way to get the max or whatever you want to memoize on the DataFrame:

val randIntMax = df.rdd.map { case sql.Row(randInt: Int) => randInt }.reduce(math.max)

sql.types.Metadata can only hold strings, booleans, some types of numbers, and other metadata structures. So we have to use a Long:

val metadata = new sql.types.MetadataBuilder().putLong("columnMax", randIntMax).build()

DataFrame.withColumn() actually has an overload that permits supplying a metadata argument at the end, but it's inexplicably marked [private], so we just do what it does — use Column.as(alias, metadata):

val newColumn = df.col("randInt").as("randInt_withMax", metadata)
val dfWithMax = df.withColumn("randInt_withMax", newColumn)

dfWithMax now has (a column with) the metadata you want!

dfWithMax.schema.foreach(field => println(s"${field.name}: metadata=${field.metadata}"))
> randInt: metadata={}
> randInt_withMax: metadata={"columnMax":2094414111}

Or programmatically and type-safely (sort of; Metadata.getLong() and others do not return Option and may throw a "key not found" exception):

dfWithMax.schema("randInt_withMax").metadata.getLong("columnMax")
> res29: Long = 209341992

Attaching the max to a column makes sense in your case, but in the general case of attaching metadata to a DataFrame and not a column in particular, it appears you'd have to take the wrapper route described by the other answers.

10

As of Spark 1.2, StructType schemas have a metadata attribute which can hold an arbitrary mapping / dictionary of information for each Column in a Dataframe. E.g. (when used with the separate spark-csv library):

customSchema = StructType([
  StructField("cat_id", IntegerType(), True,
    {'description': "Unique id, primary key"}),
  StructField("cat_title", StringType(), True,
    {'description': "Name of the category, with underscores"}) ])

categoryDumpDF = (sqlContext.read.format('com.databricks.spark.csv')
 .options(header='false')
 .load(csvFilename, schema = customSchema) )

f = categoryDumpDF.schema.fields
["%s (%s): %s" % (t.name, t.dataType, t.metadata) for t in f]

["cat_id (IntegerType): {u'description': u'Unique id, primary key'}",
 "cat_title (StringType): {u'description': u'Name of the category, with underscores.'}"]

This was added in [SPARK-3569] Add metadata field to StructField - ASF JIRA, and designed for use in Machine Learning pipelines to track information about the features stored in columns, like categorical/continuous, number categories, category-to-index map. See the SPARK-3569: Add metadata field to StructField design document.

I'd like to see this used more widely, e.g. for descriptions and documentation of columns, the unit of measurement used in the column, coordinate axis information, etc.

Issues include how to appropriately preserve or manipulate the metadata information when the column is transformed, how to handle multiple sorts of metadata, how to make it all extensible, etc.

For the benefit of those thinking of expanding this functionality in Spark dataframes, I reference some analogous discussions around Pandas.

For example, see xray - bring the labeled data power of pandas to the physical sciences which supports metadata for labeled arrays.

And see the discussion of metadata for Pandas at Allow custom metadata to be attached to panel/df/series? · Issue #2485 · pydata/pandas.

See also discussion related to units: ENH: unit of measurement / physical quantities · Issue #10349 · pydata/pandas

3

If you want to have less tedious work, I think you can add an implicit conversion between DataFrame and your custom wrapper (haven't tested it yet though).

   implicit class WrappedDataFrame(val df: DataFrame) {
        var metadata = scala.collection.mutable.Map[String, Long]()

        def addToMetaData(key: String, value: Long) {
           metadata += key -> value
        }
     ...[other methods you consider useful, getters, setters, whatever]...
      }

If the implicit wrapper is in DataFrame's scope, you can just use normal DataFrame as if it was your wrapper, ie.:

df.addtoMetaData("size", 100)

This way also makes your metadata mutable, so you should not be forced to compute it only once and carry it around.

  • Two potential flaws (IMHO): First, metadata is mutable (while DataFrame is not). Second, there is no "syncing" between DataFrame and meta data: A high risk that both run out of sync. Last, where is meta data stored / persisted? – Martin Senne Sep 18 '15 at 8:05
  • 2
    Well it's a tradeoff - you can choose to pass an immutable map of metadata and bind it in a similar implicit way with a DataFrame. You have to remember to recreate the immutable metadata map every time you obtain a new instance of DataFrame. If you really want an automated syncing, I guess you have to specifically override some DataFrame methods and enrich them with updating metadata or use an Observer pattern. – TheMP Sep 18 '15 at 8:30
  • I like the idea - and am going to use it in my project. – StephenBoesch Aug 16 '17 at 23:22
1

I would store a wrapper around your dataframe. For example:

case class MyDFWrapper(dataFrame: DataFrame, metadata: Map[String, Long])
val maxIndex = df1.agg("index" ->"MAX").head.getLong(0)
MyDFWrapper(df1, Map("maxIndex" -> maxIndex))
  • 1
    Sorry, but not really acceptable, as this requires to work on wrapped objects all the time. Second, I can easily mix up a dataFrame with wrong meta data. As mentioned in my question, I do not want to (re-) compute the meta data, but carry them along. Third, what is your idea to store the meta information at? – Martin Senne Sep 17 '15 at 15:44
  • 2
    This was going to be my suggestion. Simply define an implicit conversion from the wrapper to the DataFrame and implement a loader function that loads both the metadata and the data frame in tandem. – Ryan Sep 17 '15 at 16:02
  • Using a wrapper means you only compute the metadata once, then you just carry the wrapper afterwards. DataFrames don't have the ability to store custom values except by adding extra columns. – Al M Sep 18 '15 at 7:11
0

A lot of people saw the word "metadata" and went straight to "column metadata". This does not seem to be what you wanted, and was not what I wanted when I had a similar problem. Ultimately, the problem here is that a DataFrame is an immutable data structure that, whenever an operation is performed on it, the data passes on but the rest of the DataFrame does not. This means that you can't simply put a wrapper on it, because as soon as you perform an operation you've got a whole new DataFrame (potentially of a completely new type, especially with Scala/Spark's tendencies toward implicit conversions). Finally, if the DataFrame ever escapes its wrapper, there's no way to reconstruct the metadata from the DataFrame.

I had this problem in Spark Streaming, which focuses on RDDs (the underlying datastructure of the DataFrame as well) and came to one simple conclusion: the only place to store the metadata is in the name of the RDD. An RDD name is never used by the core Spark system except for reporting, so it's safe to repurpose it. Then, you can create your wrapper based on the RDD name, with an explicit conversion between any DataFrame and your wrapper, complete with metadata.

Unfortunately, this does still leave you with the problem of immutability and new RDDs being created with every operation. The RDD name (our metadata field) is lost with each new RDD. That means you need a way to re-add the name to your new RDD. This can be solved by providing a method that takes a function as an argument. It can extract the metadata before the function, call the function and get the new RDD/DataFrame, then name it with the metadata:

def withMetadata(fn: (df: DataFrame) => DataFrame): MetaDataFrame = {
  val meta = df.rdd.name
  val result = fn(wrappedFrame)
  result.rdd.setName(meta)
  MetaDataFrame(result)
}

Your wrapping class (MetaDataFrame) can provide convenience methods for parsing and setting metadata values, as well as implicit conversions back and forth between Spark DataFrame and MetaDataFrame. As long as you run all your mutations through the withMetadata method, your metadata will carry along though your entire transformation pipeline. Using this method for every call is a bit of a hassle, yes, but the simple reality is that there is not a first-class metadata concept in Spark.

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