Justin's answer is awesome and this response goes into more depth.
repartition algorithm does a full shuffle and creates new partitions with data that's distributed evenly. Let's create a DataFrame with the numbers from 1 to 12.
val x = (1 to 12).toList
val numbersDf = x.toDF("number")
numbersDf contains 4 partitions on my machine.
numbersDf.rdd.partitions.size // => 4
Here is how the data is divided on the partitions:
Partition 00000: 1, 2, 3
Partition 00001: 4, 5, 6
Partition 00002: 7, 8, 9
Partition 00003: 10, 11, 12
Let's do a full-shuffle with the
repartition method and get this data on two nodes.
val numbersDfR = numbersDf.repartition(2)
Here is how the
numbersDfR data is partitioned on my machine:
Partition A: 1, 3, 4, 6, 7, 9, 10, 12
Partition B: 2, 5, 8, 11
repartition method makes new partitions and evenly distributes the data in the new partitions (the data distribution is more even for larger data sets).
coalesce uses existing partitions to minimize the amount of data that's shuffled.
repartition creates new partitions and does a full shuffle.
coalesce results in partitions with different amounts of data (sometimes partitions that have much different sizes) and
repartition results in roughly equal sized partitions.
coalesce may run faster than
repartition, but unequal sized partitions are generally slower to work with than equal sized partitions. You'll usually need to repartition datasets after filtering a large data set. I've found
repartition to be faster overall because Spark is built to work with equal sized partitions.
N.B. I've curiously observed that repartition can increase the size of data on disk. Make sure to run tests when you're using repartition / coalesce on large datasets.
Read this blog post if you'd like even more details.
When you'll use coalesce & repartition in practice