If both Map-Reduce and Spark writes the data to the local disk then how spark shuffle process is different from Hadoop MapReduce?
When you execute a Spark application, the very first thing is starting the
SparkContext first that becomes the home of multiple interconnected services with
SchedulerBackend being among the most important ones.
DAGScheduler is the main orchestrator and is responsible for transforming a RDD lineage graph (i.e. a directed acyclic graph of RDDs) into stages. While doing it,
DAGScheduler traverses the parent dependencies of the final RDD and creates a
ResultStage with parent
ResultStage is (mostly) the last stage with
ShuffleMapStages being its parents. I said mostly because I think I may have seen that you can "schedule" a
This is the very early and first optimization Spark applies to your Spark jobs (that together create a Spark application) - execution pipelining where multiple transformations are wired together to create a single stage (because their inter-dependencies are narrow). That's what makes Spark faster than Hadoop MapReduce since two or more transformations can get executed one by one with no data shuffling possibly all in memory.
A single stage is as wide until it hits
ShuffleDependency (aka wide dependency).
There are RDD transformations that will cause shuffling (due to creating a
ShuffleDependency). That's the moment where Spark is very much like Hadoop's MapReduce since it will save partial shuffle outputs to...local disks on executors.
When a Spark application starts it requests executors from a cluster manager (there are three supported: Spark Standalone, Apache Mesos and Hadoop YARN). This is what
SchedulerBackend is for -- to manage communication between your Spark application and cluster resources.
(Let's assume you are not using External Shuffle Manager)
Executors host their own local
BlockManagers that are responsible for managing RDD blocks that are kept on local hard drive (possibly in memory and replicated too). You can control RDD block persistence using
persist operators and StorageLevels. You can use
Executors tabs in web UI to track blocks with their location and size.
The difference between Spark storing data locally (on executors) and Hadoop MapReduce is that:
The partial results (after computing
ShuffleMapStages) are saved on local hard drives not HDFS which is a distributed file system with a very expensive saves.
Only some files are saved to local hard drive (after operations being pipelined) which does not happen in Hadoop MapReduce that saves all maps to HDFS.
Let me answer the following item:
If there are lot of small intermediate files as output how spark handles the network and I/O bottleneck?
That's the trickest part in the Spark execution plan and heavily depends on how wide the shuffling is. If you work only with local data (multiple executors on a single machine) you will see no data traffic since the data is in place already.
If the data shuffle is required, executors will send data between each other and that will increase the traffic.
Data Exchange Between Nodes in Spark Application
Just to elaborate on the traffic between nodes in a Spark application.
Broadcast variables are the means of sending data from the driver to executors.
Accumulators are the means of sending data from executors to the driver.
Operators like collect will pull all the remote blocks from executors to the driver.
p.s. Yeah, figures and diagrams would have helped...working on some. Upvote to get me inspired :)