Edit: The answer helps, but I described my solution in: memoryOverhead issue in Spark.

I have an RDD with 202092 partitions, which reads a dataset created by others. I can manually see that the data is not balanced across the partitions, for example some of them have 0 images and other have 4k, while the mean lies at 432. When processing the data, I got this error:

Container killed by YARN for exceeding memory limits. 16.9 GB of 16 GB physical memory used. Consider boosting spark.yarn.executor.memoryOverhead.

while memoryOverhead is already boosted. I feel that some spikes are happening which make Yarn kill my container, because that spike overflows the specified borders.

So what should I do make sure that my data are (roughly) balanced across partitions?

My idea was that repartition() would work, it invokes shuffling:

dataset = dataset.repartition(202092)

but I just got the very same error, despite the programming-guide's instructions:


Reshuffle the data in the RDD randomly to create either more or fewer partitions and balance it across them. This always shuffles all data over the network.

Check my toy example though:

data = sc.parallelize([0,1,2], 3).mapPartitions(lambda x: range((x.next() + 1) * 1000))
d = data.glom().collect()
len(d[0])     # 1000
len(d[1])     # 2000
len(d[2])     # 3000
repartitioned_data = data.repartition(3)
re_d = repartitioned_data.glom().collect()
len(re_d[0])  # 1854
len(re_d[1])  # 1754
len(re_d[2])  # 2392
repartitioned_data = data.repartition(6)
re_d = repartitioned_data.glom().collect()
len(re_d[0])  # 422
len(re_d[1])  # 845
len(re_d[2])  # 1643
len(re_d[3])  # 1332
len(re_d[4])  # 1547
len(re_d[5])  # 211
repartitioned_data = data.repartition(12)
re_d = repartitioned_data.glom().collect()
len(re_d[0])  # 132
len(re_d[1])  # 265
len(re_d[2])  # 530
len(re_d[3])  # 1060
len(re_d[4])  # 1025
len(re_d[5])  # 145
len(re_d[6])  # 290
len(re_d[7])  # 580
len(re_d[8])  # 1113
len(re_d[9])  # 272
len(re_d[10]) # 522
len(re_d[11]) # 66

1 Answer 1


The memory overhead limit exceeding issue I think is due to DirectMemory buffers used during fetch. I think it's fixed in 2.0.0. (We had the same issue, but stopped digging much deeper when we found that upgrading to 2.0.0 resolved it. Unfortunately I don't have Spark issue numbers to back me up.)

The uneven partitions after repartition are surprising. Contrast with https://github.com/apache/spark/blob/v2.0.0/core/src/main/scala/org/apache/spark/rdd/RDD.scala#L443. Spark even generates random keys in repartition, so it is not done with a hash that could be biased.

I tried your example and get the exact same results with Spark 1.6.2 and Spark 2.0.0. But not from Scala spark-shell:

scala> val data = sc.parallelize(1 to 3, 3).mapPartitions { it => (1 to it.next * 1000).iterator }
data: org.apache.spark.rdd.RDD[Int] = MapPartitionsRDD[6] at mapPartitions at <console>:24

scala> data.mapPartitions { it => Iterator(it.toSeq.size) }.collect.toSeq
res1: Seq[Int] = WrappedArray(1000, 2000, 3000)

scala> data.repartition(3).mapPartitions { it => Iterator(it.toSeq.size) }.collect.toSeq
res2: Seq[Int] = WrappedArray(1999, 2001, 2000)

scala> data.repartition(6).mapPartitions { it => Iterator(it.toSeq.size) }.collect.toSeq
res3: Seq[Int] = WrappedArray(999, 1000, 1000, 1000, 1001, 1000)

scala> data.repartition(12).mapPartitions { it => Iterator(it.toSeq.size) }.collect.toSeq
res4: Seq[Int] = WrappedArray(500, 501, 501, 501, 501, 500, 499, 499, 499, 499, 500, 500)

Such beautiful partitions!

(Sorry this is not a full answer. I just wanted to share my findings so far.)

  • Since I could not upgrade, here is what I did: memoryoverhead issue in Spark (any inputs on that are welcomed). I don't know what's a DirectMemory buffer, nor in which particular fetch you are referring to, bare with me but I am newbie.We use Spark1.6.2,but I haven't control to that. I am trying to launch spark-shell, but I get an error: a secret key must be .., so I cannot confirm. BTW, thanks for the good answers,helped me a lot before!
    – gsamaras
    Aug 10, 2016 at 16:38
  • 2
    Direct memory buffers are memory allocated by the JVM but outside of the heap. Normally a Spark executor is limited by the heap size so will not get killed by YARN. Allocating direct buffers allows it to use more memory than the heap size, and get killed by YARN. (docs.oracle.com/javase/7/docs/api/java/nio/ByteBuffer.html) Large direct buffers are allocated during shuffles, when the reducer tasks fetch data from the mappers. Aug 10, 2016 at 19:08
  • What would this code look like in Python?
    – martin_wun
    Oct 5, 2021 at 14:23
  • This is the Scala version of the Python code from the question. So if you scroll up, I think that's what it looks like in Python. (Sorry if I misunderstoood.) Oct 6, 2021 at 15:56

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