Skip to main content

Launchpad is a library that simplifies writing distributed programs and seamlessly launching them on a range of supported platforms.

Project description

Launchpad

PyPI - Python Version PyPI version

Launchpad is a library that simplifies writing distributed programs by seamlessly launching them on a variety of different platforms. Switching between local and distributed execution requires only a flag change.

Launchpad introduces a programming model that represents a distributed system as a graph data structure (a Program) describing the system’s topology. Each node in the program graph represents a service in the distributed system, i.e. the fundamental unit of computation that we are interested in running. As nodes are added to this graph, Launchpad constructs a handle for each of them. A handle ultimately represents a client to the yet-to-be-constructed service. A directed edge in the program graph, representing communication between two services, is created when the handle associated with one node is given to another at construction time. This edge originates from the receiving node, indicating that the receiving node will be the one initiating communication. This process allows Launchpad to define cross-service communication simply by passing handles to nodes. The open-sourced version of Launchpad currently provides following types of nodes (you can implement your own types as needed):

  • PyNode - a simple node executing provided Python code upon entry. It is similar to a main function, but with the distinction that each node may be running in separate processes and on different machines.
  • CourierNode - it enables cross-node communication. CourierNodes can communicate by calling public methods on each other either synchronously or asynchronously via futures. The underlying remote procedure calls are handled transparently by Launchpad.
  • ReverbNode - it exposes functionality of Reverb, an easy-to-use data storage and transport system primarily used by RL algorithms as an experience replay. You can read more about Reverb here.
  • MultiThreadingColocation - allows to colocate multiple other nodes in a single process.
  • MultiProcessingColocation - allows to colocate multiple other nodes as sub processes.

Using Launchpad involves implementing nodes and defining the topology of your distributed program by passing to each node references of the other nodes that it can communicate with. The core data structure dealing with this is called a Launchpad program, which can then be used for local debugging runs, tests, distributed executions, etc.

Table of Contents

Installation

Please keep in mind that Launchpad is not hardened for production use, and while we do our best to keep things in working order, things may break or segfault.

:warning: Launchpad currently only supports Linux based OSes.

The recommended way to install Launchpad is with pip. We also provide instructions to build from source using the same docker images we use for releases.

TensorFlow can be installed separately or as part of the pip install. Installing TensorFlow as part of the install ensures compatibility.

$ pip install dm-launchpad[tensorflow]

# Without Tensorflow install and version dependency check.
$ pip install dm-launchpad

Nightly builds

PyPI version

$ pip install dm-launchpad-nightly[tensorflow]

# Without Tensorflow install and version dependency check.
$ pip install dm-launchpad-nightly

Similarily, Reverb can be installed ensuring compatibility:

$ pip install dm-launchpad[reverb]

Develop Launchpad inside a docker container

The most convenient way to develop Launchpad is with Docker. This way you can compile and test Launchpad inside a container without having to install anything on your host machine, while you can still use your editor of choice for making code changes. The steps are as follows.

Checkout Launchpad's source code from GitHub.

$ git checkout https://github.com/deepmind/launchpad.git
$ cd launchpad

Build the Docker container to be used for compiling and testing Launchpad. You can specify tensorflow_pip parameter to set the version of Tensorflow to build against. You can also specify which version(s) of Python container should support. The command below enables support for Python 3.7, 3.8 and 3.9.

$ docker build --tag launchpad:devel \
  --build-arg tensorflow_pip=tensorflow==2.3.0 \
  --build-arg python_version="3.7 3.8 3.9" - < docker/build.dockerfile

The next step is to enter the built Docker image, binding checked out Launchpad's sources to /tmp/launchpad within the container.

$ docker run --rm --mount "type=bind,src=$PWD,dst=/tmp/launchpad" \
  -it launchpad:devel bash

At this point you can build and install Launchpad within the container by executing:

$ /tmp/launchpad/oss_build.sh

By default it builds Python 3.8 version, you can change that with --python flag.

$ /tmp/launchpad/oss_build.sh --python 3.8

To make sure installation was successful and Launchpad works as expected, you can run some examples provided:

$ python3.8 -m launchpad.examples.hello_world.launch
$ python3.8 -m launchpad.examples.consumer_producers.launch --lp_launch_type=local_mp

To make changes to Launchpad codebase, edit sources checked out from GitHub directly on your host machine (outside of the Docker container). All changes are visible inside the Docker container. To recompile just run the oss_build.sh script again from the Docker container. In order to reduce compilation time of the consecutive runs, make sure to not exit the Docker container.

Quick Start

The complete implementation can be found here.

Implement example nodes

In this producer-consumer example, we have one consumer and multiple producers. The consumer sends work to the producers, which perform some time-intensive task before returning the result to the consumer. Finally, the consumer summarizes the work done by all of the producers.

consumer-producer-topology

The producer in this example has just one method which performs some work (for you to implement) in a given context provided by the caller. Any method of the class can be exposed for other nodes to call by wrapping a node with a CourierNode. In a typical setup, all nodes live in separate processes or on distinct machines, while the communication between the nodes is taken care of transparently by Launchpad. Some care has to be taken though. For example, the work() method may be called from multiple threads within the same process, so if the producer were to have any shared state then access to it must be made thread-safe. In this case, the producer is stateless so it is not a concern.

class Producer:
  def work(self, context):
    return context

The consumer defines an initializer and a run() method. The initializer takes a list of handles to the producers (CourierNodes).

Any Launchpad PyClassNode with a run() method will have that method called automatically upon program entry. Here the run() method simply calls work() on each producer and collects the results. At the end, it calls launchpad.stop() to terminate all nodes running within a program.

class Consumer:
  def __init__(self, producers):
    self._producers = producers

  def run(self):
    results = [producer.work(context)
               for context, producer in enumerate(self._producers)]
    logging.info('Results: %s', results)
    lp.stop()

In the example above, work() methods are called sequentially, so there is no benefit in running this program distributed. Launchpad, however, allows for asynchronous calls as well through the use of futures. In the example below all producers will perform their work in parallel while consumer waits on all of their results when calling future.result().

class Consumer:
  def __init__(self, producers):
    self._producers = producers

  def run(self):
    futures = [producer.futures.work(context)
               for context, producer in enumerate(self._producers)]
    results = [future.result() for future in futures]
    logging.info('Results: %s', results)
    launchpad.stop()

Define the topology

The next step is to instantiate nodes for the consumer and producers and then connect them so that the consumer can call methods on the producers. The connections between nodes define the topology of the distributed program.

Launchpad uses an lp.Program class to hold all the nodes. There are several different types of nodes but here lp.CourierNode is used since it is the simplest type which supports communication between nodes. The parameters to lp.CourierNode are the name of the class and the parameters of its initializer. Connecting the consumer node to the producer nodes is as simple as passing in handles to all producers in the initializer of the consumer. The handles themselves are returned by lp.Program.add_node().

def make_program(num_producers):
  program = lp.Program('consumer_producers')
  with program.group('producer'):
    producers = [
        program.add_node(lp.CourierNode(Producer)) for _ in range(num_producers)
    ]
  node = lp.CourierNode(
      Consumer,
      producers=producers)
  program.add_node(node, label='consumer')
  return program

With the above function defining the topology all that remains is to implement main() for Launchpad:

def main(_):
  program = make_program(num_producers=FLAGS.num_producers)
  lp.launch(program)

if __name__ == '__main__':
  app.run(main)

Launch the program

To launch the program (assuming it is called launch.py), simply run:

python3 -m launch --lp_launch_type=local_mp

The --lp_launch_type controls how the program is launched. In the above case it is launched locally with each node executed in a separate process. List of supported execution modes can be found here.

Add a test

Here are some points to keep in mind when creating a test for a Launchpad program.

  • The easiest way to add a test for your program is to reuse the same topology for an integration test (i.e. call make_program() from above in this example).
  • Launch a test by calling lp.launch() just like in main() in the above example, but explicitly specify launch_type='test_mt' (multithreaded tests) as a parameter.
  • It is possible to disable automatic execution of a node's run() method before launching. Do so by calling disable_run() on the node in question.
  • In order to call methods to test on a Courier node you will need to explicitly dereference the handle of the node first. Do so by calling create_handle() followed by dereference() on the node in question.

Below is an incomplete example illustrating the above concepts. A complete example can be found here.

import launchpad as lp
from launchpad.examples.consumer_producers import launch
from absl.testing import absltest

class LaunchTest(absltest.TestCase):
  def test_consumer(self):
    program = launch.make_program(num_producers=2)
    (consumer_node,) = program.groups['consumer']
    consumer_node.disable_run()
    lp.launch(program, launch_type='test_mt')
    consumer = consumer_node.create_handle().dereference()
    # Perform actual test here by calling methods on `consumer` ...

Citing Launchpad

If you use Launchpad in your work, please cite the accompanying technical report:

@article{yang2021launchpad,
    title={Launchpad: A Programming Model for Distributed Machine Learning
           Research},
    author={Fan Yang and Gabriel Barth-Maron and Piotr Stańczyk and Matthew
            Hoffman and Siqi Liu and Manuel Kroiss and Aedan Pope and Alban
            Rrustemi},
    year={2021},
    journal={arXiv preprint arXiv:2106.04516},
    url={https://arxiv.org/abs/2106.04516},
}

Acknowledgements

We greatly appreciate all the help from Reverb and TF-Agents teams in setting up building and testing setup for Launchpad.

Project details


Release history Release notifications | RSS feed

Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distributions

No source distribution files available for this release.See tutorial on generating distribution archives.

Built Distributions

dm_launchpad_nightly-0.3.0.dev20211001-cp39-cp39-manylinux2010_x86_64.whl (4.0 MB view details)

Uploaded CPython 3.9 manylinux: glibc 2.12+ x86-64

dm_launchpad_nightly-0.3.0.dev20211001-cp38-cp38-manylinux2010_x86_64.whl (4.0 MB view details)

Uploaded CPython 3.8 manylinux: glibc 2.12+ x86-64

dm_launchpad_nightly-0.3.0.dev20211001-cp37-cp37m-manylinux2010_x86_64.whl (4.0 MB view details)

Uploaded CPython 3.7m manylinux: glibc 2.12+ x86-64

File details

Details for the file dm_launchpad_nightly-0.3.0.dev20211001-cp39-cp39-manylinux2010_x86_64.whl.

File metadata

File hashes

Hashes for dm_launchpad_nightly-0.3.0.dev20211001-cp39-cp39-manylinux2010_x86_64.whl
Algorithm Hash digest
SHA256 473f054f7fc8e0cb63e4fa7dd51e04b814c2f46af99c4f666ed88f3e920849c5
MD5 699d10b2daa46c554df25ac71401e9d0
BLAKE2b-256 471652a30f3cb0b9ea249925b6c728866e45a923b4ec4b22331321a9a8a368a1

See more details on using hashes here.

File details

Details for the file dm_launchpad_nightly-0.3.0.dev20211001-cp38-cp38-manylinux2010_x86_64.whl.

File metadata

File hashes

Hashes for dm_launchpad_nightly-0.3.0.dev20211001-cp38-cp38-manylinux2010_x86_64.whl
Algorithm Hash digest
SHA256 2b791e2648d8f8a6fb7a44efd79b80f3622b4dd40b04970f2fb0ef8476da22ec
MD5 35f6d96b59997fc7691ffa6384517cfd
BLAKE2b-256 1ccebc81c412feb8fefbae554d67c589a1f7c9e1efaacecb2b758aaa42cc5fc1

See more details on using hashes here.

File details

Details for the file dm_launchpad_nightly-0.3.0.dev20211001-cp37-cp37m-manylinux2010_x86_64.whl.

File metadata

File hashes

Hashes for dm_launchpad_nightly-0.3.0.dev20211001-cp37-cp37m-manylinux2010_x86_64.whl
Algorithm Hash digest
SHA256 31e3ea1c42594e0a190f560575c5b3fc9cf241fe4daf3fee98b475072f3eb54a
MD5 59cce477ff3e2a1e389542f4f6739eff
BLAKE2b-256 24c01e83e0a36ed2a27b428a036a9ff3b6f0bef4193120bc2a7ba5e2f3565d4c

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page