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I have a dataset with ~5M rows x 20 columns, containing a groupID and a rowID. My goal is to check whether (some) columns contain more than a fixed fraction (say, 50%) of missing (null) values within a group. If this is found, the entire column is set to missing (null), for that group.

df = spark.read.parquet('path/to/parquet/')
check_columns = {'col1': ..., 'col2': ..., ...}  # currently len(check_columns) = 8

for col, _ in check_columns.items():
    total = (df
             .groupBy('groupID').count()
             .toDF('groupID', 'n_total')
             )

    missing = (df
               .where(F.col(col).isNull())
               .groupBy('groupID').count()
               .toDF('groupID', 'n_missing')
               )
    # count_missing = count_missing.persist()  # PERSIST TRY 1
    # print('col {} found {} missing'.format(col, missing.count()))  # missing.count() is b/w 1k-5k

    poor_df = (total
               .join(missing, 'groupID')
               .withColumn('freq', F.col('n_missing') / F.col('n_total'))
               .where(F.col('freq') > 0.5)
               .select('groupID')
               .toDF('poor_groupID')
               )

    df = (df
          .join(poor_df, df['groupID'] == poor_df['poor_groupID'], 'left_outer')
          .withColumn(col, (F.when(F.col('poor_groupID').isNotNull(), None)
                            .otherwise(df[col])
                            )
                    )
        .select(df.columns)
        )

    stats = (missing
             .withColumnRenamed('n_missing', 'cnt')
             .collect()  # FAIL 1
             )

    # df = df.persist()  # PERSIST TRY 2

print(df.count())  # FAIL 2

I initially assigned 1G of spark.driver.memory and 4G of spark.executor.memory, eventually increasing the spark.driver.memory up to 10G.

Problem(s): The loop runs like a charm during the first iterations, but towards the end, around the 6th or 7th iteration I see my CPU utilization dropping (using 1 instead of 6 cores). Along with that, execution time for one iteration increases significantly. At some point, I get an OutOfMemory Error:

  • spark.driver.memory < 4G: at collect() (FAIL 1)
  • 4G <= spark.driver.memory < 10G: at the count() step (FAIL 2)

Stack Trace for FAIL 1 case (relevant part):

[...]
py4j.protocol.Py4JJavaError: An error occurred while calling o1061.collectToPython.
: java.lang.OutOfMemoryError: Java heap space
[...]

The executor UI does not reflect excessive memory usage (it shows a <50k used memory for the driver and <1G for the executor). The Spark metrics system (app-XXX.driver.BlockManager.memory.memUsed_MB) does not either: it shows 600M to 1200M of used memory, but always >300M remaining memory. (This would suggest that 2G driver memory should do it, but it doesn't.)

It also does not matter which column is processed first (as it is a loop over a dict(), it can be in arbitrary order).

My questions thus:

  • What causes the OutOfMemory Error and why are not all available CPU cores used towards the end?
  • And why do I need 10G spark.driver.memory when I am transferring only a few kB from the executors to the driver?

A few (general) questions to make sure I understand things properly:

  • If I get an OOM error, the right place to look at is almost always the driver (b/c the executor spills to disk)?
  • Why would count() cause an OOM error - I thought this action would only consume resources on the exector(s) (delivering a few bytes to the driver)?
  • Are the memory metrics (metrics system, UI) mentioned above the correct places to look at?

BTW: I run Spark 2.1.0 in standalone mode.

UPDATE 2017-04-28

To drill down further, I enabled a heap dump for the driver:

cfg = SparkConfig()
cfg.set('spark.driver.extraJavaOptions', '-XX:+HeapDumpOnOutOfMemoryError')

I ran it with 8G of spark.driver.memory and I analyzed the heap dump with Eclipse MAT. It turns out there are two classes of considerable size (~4G each):

java.lang.Thread
    - char (2G)
    - scala.collection.IndexedSeqLike
        - scala.collection.mutable.WrappedArray (1G)
    - java.lang.String (1G)

org.apache.spark.sql.execution.ui.SQLListener
    - org.apache.spark.sql.execution.ui.SQLExecutionUIData 
      (various of up to 1G in size)
        - java.lang.String
    - ...

I tried to turn off the UI, using

cfg.set('spark.ui.enabled', 'false')

which made the UI unavailable, but didn't help on the OOM error. Also, I tried to have the UI to keep less history, using

cfg.set('spark.ui.retainedJobs', '1')
cfg.set('spark.ui.retainedStages', '1')
cfg.set('spark.ui.retainedTasks', '1')
cfg.set('spark.sql.ui.retainedExecutions', '1')
cfg.set('spark.ui.retainedDeadExecutors', '1')

This also did not help.

UPDATE 2017-05-18

I found out about Spark's pyspark.sql.DataFrame.checkpoint method. This is like persist but gets rid of the dataframe's lineage. Thus it helps to circumvent the above mentioned issues.

  • Is path/to/parquet/ on a local filesystem or HDFS for example? – ImDarrenG Apr 26 '17 at 15:54
  • it is a path on the local filesystem – Tw UxTLi51Nus Apr 26 '17 at 15:57
  • Briefly, please can you explain what lines 18 to 33 are doing? – ImDarrenG Apr 26 '17 at 16:01
  • Scratch that, I can follow the logic now. – ImDarrenG Apr 26 '17 at 16:11

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