Version: 2.0.0-SNAPSHOT

Lifecycle of a Storm Topology

(NOTE: this page is based on the 0.7.1 code; many things have changed since then, including a split between tasks and executors, and a reorganization of the code under storm-client/src rather than src/.)

This page explains in detail the lifecycle of a topology from running the "storm jar" command to uploading the topology to Nimbus to the supervisors starting/stopping workers to workers and tasks setting themselves up. It also explains how Nimbus monitors topologies and how topologies are shutdown when they are killed.

First a couple of important notes about topologies:

  1. The actual topology that runs is different than the topology the user specifies. The actual topology has implicit streams and an implicit "acker" bolt added to manage the acking framework (used to guarantee data processing). The implicit topology is created via the system-topology! function.
  2. system-topology! is used in two places:
    • when Nimbus is creating tasks for the topology code
    • in the worker so it knows where it needs to route messages to code

Starting a topology

  • "storm jar" command executes your class with the specified arguments. The only special thing that "storm jar" does is set the "storm.jar" environment variable for use by StormSubmitter later. code
  • When your code uses StormSubmitter.submitTopology, StormSubmitter takes the following actions:

    • First, StormSubmitter uploads the jar if it hasn't been uploaded before. code
    • Jar uploading is done via Nimbus's Thrift interface code
    • beginFileUpload returns a path in Nimbus's inbox
    • 15 kilobytes are uploaded at a time through uploadChunk
    • finishFileUpload is called when it's finished uploading
    • Here is Nimbus's implementation of those Thrift methods: code
    • Second, StormSubmitter calls submitTopology on the Nimbus thrift interface code
    • The topology config is serialized using JSON (JSON is used so that writing DSL's in any language is as easy as possible)
    • Notice that the Thrift submitTopology call takes in the Nimbus inbox path where the jar was uploaded
  • Nimbus receives the topology submission. code

  • Nimbus normalizes the topology configuration. The main purpose of normalization is to ensure that every single task will have the same serialization registrations, which is critical for getting serialization working correctly. code

  • Nimbus sets up the static state for the topology code

    • Jars and configs are kept on local filesystem because they're too big for Zookeeper. The jar and configs are copied into the path {nimbus local dir}/stormdist/{topology id}
    • setup-storm-static writes task -> component mapping into ZK
    • setup-heartbeats creates a ZK "directory" in which tasks can heartbeat
  • Nimbus calls mk-assignment to assign tasks to machines code

    • Assignment record definition is here: code
    • Assignment contains:
      • master-code-dir: used by supervisors to download the correct jars/configs for the topology from Nimbus
      • task->node+port: Map from a task id to the worker that task should be running on. (A worker is identified by a node/port pair)
      • node->host: A map from node id to hostname. This is used so workers know which machines to connect to to communicate with other workers. Node ids are used to identify supervisors so that multiple supervisors can be run on one machine. One place this is done is with Mesos integration.
      • task->start-time-secs: Contains a map from task id to the timestamp at which Nimbus launched that task. This is used by Nimbus when monitoring topologies, as tasks are given a longer timeout to heartbeat when they're first launched (the launch timeout is configured by "nimbus.task.launch.secs" config)
  • Once topologies are assigned, they're initially in a deactivated mode. start-storm writes data into Zookeeper so that the cluster knows the topology is active and can start emitting tuples from spouts. code

  • TODO cluster state diagram (show all nodes and what's kept everywhere)

  • Supervisor runs two functions in the background:

    • synchronize-supervisor: This is called whenever assignments in Zookeeper change and also every 10 seconds. code
      • Downloads code from Nimbus for topologies assigned to this machine for which it doesn't have the code yet. code
      • Writes into local filesystem what this node is supposed to be running. It writes a map from port -> LocalAssignment. LocalAssignment contains a topology id as well as the list of task ids for that worker. code
    • sync-processes: Reads from the LFS what synchronize-supervisor wrote and compares that to what's actually running on the machine. It then starts/stops worker processes as necessary to synchronize. code
  • Worker processes start up through the mk-worker function code

    • Worker connects to other workers and starts a thread to monitor for changes. So if a worker gets reassigned, the worker will automatically reconnect to the other worker's new location. code
    • Monitors whether a topology is active or not and stores that state in the storm-active-atom variable. This variable is used by tasks to determine whether or not to call nextTuple on the spouts. code
    • The worker launches the actual tasks as threads within it code
  • Tasks are set up through the mk-task function code

    • Tasks set up routing function which takes in a stream and an output tuple and returns a list of task ids to send the tuple to code (there's also a 3-arity version used for direct streams)
    • Tasks set up the spout-specific or bolt-specific code with code

Topology Monitoring

  • Nimbus monitors the topology during its lifetime
    • Schedules recurring task on the timer thread to check the topologies code
    • Nimbus's behavior is represented as a finite state machine code
    • The "monitor" event is called on a topology every "nimbus.monitor.freq.secs", which calls reassign-topology through reassign-transition code
    • reassign-topology calls mk-assignments, the same function used to assign the topology the first time. mk-assignments is also capable of incrementally updating a topology
      • mk-assignments checks heartbeats and reassigns workers as necessary
      • Any reassignments change the state in ZK, which will trigger supervisors to synchronize and start/stop workers

Killing a topology

  • "storm kill" command runs this code which just calls the Nimbus Thrift interface to kill the topology: code
  • Nimbus receives the kill command code
  • Nimbus applies the "kill" transition to the topology code
  • The kill transition function changes the status of the topology to "killed" and schedules the "remove" event to run "wait time seconds" in the future. code
    • The wait time defaults to the topology message timeout but can be overridden with the -w flag in the "storm kill" command
    • This causes the topology to be deactivated for the wait time before its actually shut down. This gives the topology a chance to finish processing what it's currently processing before shutting down the workers
    • Changing the status during the kill transition ensures that the kill protocol is fault-tolerant to Nimbus crashing. On startup, if the status of the topology is "killed", Nimbus schedules the remove event to run "wait time seconds" in the future code
  • Removing a topology cleans out the assignment and static information from ZK code
  • A separate cleanup thread runs the do-cleanup function which will clean up the heartbeat dir and the jars/configs stored locally. code