I am trying to write out a large partitioned dataset to disk with Spark and the partitionBy algorithm is struggling with both of the approaches I've tried.

The partitions are heavily skewed - some of the partitions are massive and others are tiny.

Problem #1:

When I use repartition before repartitionBy, Spark writes all partitions as a single file, even the huge ones

val df = spark.read.parquet("some_data_lake")

This takes forever to execute because Spark isn't writing the big partitions in parallel. If one of the partitions has 1TB of data, Spark will try to write the entire 1TB of data as a single file.

Problem #2:

When I don't use repartition, Spark writes out way too many files.

This code will write out an insane number of files.


I ran this on a tiny 8 GB data subset and Spark wrote out 85,000+ files!

When I tried running this on a production data set, one partition that has 1.3 GB of data was written out as 3,100 files.

What I'd like

I'd like for each partition to get written out as 1 GB files. So a partition that has 7 GB of data will get written out as 7 files and a partition that has 0.3 GB of data will get written out as a single file.

What is my best path forward?


The simplest solution is to add one or more columns to repartition and explicitly set the number of partitions.

val numPartitions = ???

df.repartition(numPartitions, $"some_col", $"some_other_col")


  • numPartitions - should be an upper bound (actual number can be lower) of the desired number of files written to a partition directory.
  • $"some_other_col" (and optional additional columns) should have high cardinality and be independent of the $"some_column (there should be functional dependency between these two, and shouldn't be highly correlated).

    If data doesn't contain such column you can use o.a.s.sql.functions.rand.

    import org.apache.spark.sql.functions.rand
    df.repartition(numPartitions, $"some_col", rand)
  • I have exact same situation, so I went with salting and I want to have not more than 5 files per partition. But what confuses me that I see 5 tasks at saving Stage, and that what I don't quite understand I thought that data should be balanced but also it should be organized in the way that it utilize cluster resources the best – jk1 Apr 18 '19 at 16:31

I'd like for each partition to get written out as 1 GB files. So a partition that has 7 GB of data will get written out as 7 files and a partition that has 0.3 GB of data will get written out as a single file.

The currently accepted answer is probably good enough most of the time, but doesn't quite deliver on the request that the 0.3 GB partition get written out to a single file. Instead, it will write out numPartitions files for every output partition directory, including the 0.3 GB partition.

What you're looking for is a way to dynamically scale the number of output files by the size of the data partition. To do that, we'll build on 10465355's approach of using rand() to control the behavior of repartition(), and scale the range of rand() based on the number of files we want for that partition.

It's difficult to control partitioning behavior by output file size, so instead we'll control it using the approximate number of rows we want per output file.

I'll provide a demonstration in Python, but the approach is basically the same in Scala.

from pyspark.sql import SparkSession
from pyspark.sql.functions import rand

spark = SparkSession.builder.getOrCreate()
skewed_data = (
        [(1,)] * 100 + [(2,)] * 10 + [(3,), (4,), (5,)],
partition_by_columns = ['id']
desired_rows_per_output_file = 10

partition_count = skewed_data.groupBy(partition_by_columns).count()

partition_balanced_data = (
    .join(partition_count, on=partition_by_columns)
            rand() * partition_count['count'] / desired_rows_per_output_file
    .repartition(*partition_by_columns, 'repartition_seed')

This approach will balance the size of the output files, no matter how skewed the partition sizes are. Every data partition will get the number of files it needs so that each output file has roughly the requested number of rows.

A prerequisite of this approach is calculating the size of each partition, which you can see in partition_count. It's unavoidable if you really want to dynamically scale the number of output files per partition.

To demonstrate this is doing the right thing, let's inspect the partition contents:

from pyspark.sql.functions import spark_partition_id


    .groupBy(*partition_by_columns, 'partition_id')
    .orderBy(*partition_by_columns, 'partition_id')

Here's what the output looks like:

| id|count|
|  1|  100|
|  2|   10|
|  3|    1|
|  4|    1|
|  5|    1|

| id|partition_id|count|
|  1|           7|    9|
|  1|          49|    6|
|  1|          53|   14|
|  1|         117|   12|
|  1|         126|   10|
|  1|         136|   11|
|  1|         147|   15|
|  1|         161|    7|
|  1|         177|    7|
|  1|         181|    9|
|  2|          85|   10|
|  3|          76|    1|
|  4|         197|    1|
|  5|          10|    1|

As desired, each output file has roughly 10 rows. id=1 gets 10 partitions, id=2 gets 1 partition, and id={3,4,5} each get 1 partition.

This solution balances the output file sizes, regardless of data skew, and without limiting parallelism by relying on maxRecordsPerFile.

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