
dispy: Distributed and Parallel Computing with/for Python
*********************************************************

dispy is a comprehensive, yet easy to use framework for creating and
using compute clusters to execute computations in parallel across
multiple processors in a single machine (SMP), among many machines in
a cluster, grid or cloud.  dispy is well suited for data parallel
(SIMD) paradigm where a computation (Python function or standalone
program) is evaluated with different (large) datasets independently
with no communication among computation tasks (except for computation
tasks sending Provisional/Intermediate Results or Transferring Files
to the client). If communication/cooperation among tasks is needed,
asyncoro framework could be used.

Some of the features of dispy:

* dispy is implemented with asyncoro, an independent framework for
  asynchronous, concurrent, distributed, network programming with
  coroutines (without threads). asyncoro uses non-blocking sockets
  with I/O notification mechanisms epoll, kqueue and poll, and Windows
  I/O Completion Ports (IOCP) for high performance and scalability, so
  dispy works efficiently with a single node or large cluster(s) of
  nodes. asyncoro itself has support for distributed/parallel
  computing, including transferring computations, files etc., and
  message passing (for communicating with client and other computation
  tasks).  While dispy can be used to schedule jobs of a computation
  to get the results, asyncoro can be used to create distributed
  communicating processes, for broad range of use cases.

* Computations (Python functions or standalone programs) and their
  dependencies (files, Python functions, classes, modules) are
  distributed to nodes automatically. Computations, if they are Python
  functions, can also transfer files on the nodes to the client.

* Computation nodes can be anywhere on the network (local or
  remote). For security, either simple hash based authentication or
  SSL encryption can be used.

* After each execution is finished, the results of execution,
  output, errors and exception trace are made available for further
  processing.

* In-memory processing is supported (with some limitations under
  Windows); i.e., computations can work on data in memory instead of
  loading data each time.

* Nodes may become available dynamically: dispy will schedule jobs
  whenever a node is available and computations can use that node.

* If callback function is provided, dispy executes that function
  when a job is finished; this can be used for processing job results
  as they become available.

* Client-side and server-side fault recovery are supported:

  If user program (client) terminates unexpectedly (e.g., due to
  uncaught exception), the nodes continue to execute scheduled jobs.
  The results of the scheduled (but unfinished at the time of crash)
  jobs for that cluster can be retrieved easily with (Fault) Recover
  Jobs.

  If a computation is marked reentrant when a cluster is created and a
  node (server) executing jobs for that computation fails, dispy
  automatically resubmits those jobs to other available nodes.

* dispy can be used in a single process to use all the nodes
  exclusively (with JobCluster) or in multiple processes
  simultaneously sharing the nodes (with SharedJobCluster and
  *dispyscheduler (Shared Execution)* program).

* Cloud computing platform, such as Amazon EC2, can be used as
  compute nodes, either exclusively or in addition to any local
  compute nodes. See Cloud Computing (with Amazon EC2) for details.

* *Monitor and Manage Cluster* with a web browser, including in iOS
  or Android devices.

dispy works with Python versions 2.7+ and 3.1+ and tested on Linux, OS
X and Windows; it may work on other platforms too. dispy works with
JIT interpretter PyPy as well.


Dependencies
============

dispy requires asyncoro for concurrent, asynchronous network
programming with coroutines. If dispy is installed with pip (see
below), asyncoro is also installed automatically.

Under Windows asyncoro uses efficient polling notifier I/O Completion
Ports (IOCP) only if pywin32 is installed; otherwise, inefficient
*select* notifier is used.


Download / Installation
=======================

dispy is availble through Python Package Index (PyPI) so it can be
easily installed for Python 2.7+ with:

   pip install dispy

and/or for Python 3.1+ with:

   pip3 install dispy

dispy can also be downloaded from Sourceforge Files.  Files in 'py2'
directory in the downloaded package are to be used with Python 2.7+
and files in 'py3' directory are to be used with Python 3.1+. If
asyncoro package is not installed (with 'pip'), then it can also be
downloaded and unpacked under where dispy is unpacked, so that
asyncoro's directory is copied in dispy's directory; i.e., files in
'dispy' directory are: "dispy/__init__.py", "dispy/httpd.py",
"dispy/asyncoro/__init__.py", "dispy/asyncoro/asyncfile.py" etc. Then
dispy can be used from the parent directory of "dispy".

Docker Container describes how to build Docker image and run dispy in
container.


Quick Guide
===========

Below is a quick guide on how to use dispy. More details are available
in *dispy (Client)*.

dispy framework consists of 4 components:

* A client program can use *dispy (Client)* module to create
  clusters in two different ways: JobCluster when only one instance of
  dispy may run and SharedJobCluster when multiple instances may run
  (in separate programs). If JobCluster is used, the job scheduler
  included in it will distribute jobs on the server nodes; if
  SharedJobCluster is used, *dispyscheduler (Shared Execution)*
  program must also be running.

* *dispynode (Server)* program executes jobs on behalf of a dispy
  client. dispynode must be running on each of the (server) nodes that
  form clusters.

* *dispyscheduler (Shared Execution)* program is needed only when
  SharedJobCluster is used; this provides a job scheduler that can be
  shared by multiple dispy clients simultaneously.

* *dispynetrelay (Using Remote Servers)* program can be used when
  nodes are located across different networks. If all nodes are on
  local network or if all remote nodes can be listed in 'nodes'
  parameter when creating cluster, there is no need for dispynetrelay
  - the scheduler can discover such nodes automatically. However, if
  there are many nodes on remote network(s), dispynetrelay can be used
  to relay information about the nodes on that network to scheduler,
  without having to list all nodes in 'nodes' parameter.

As an example, consider the following program, in which function
*compute* is distributed to nodes on a local network for parallel
execution. First, run dispynode program (**dispynode.py**) on each of
the nodes on the network. Now run the program below, which creates a
cluster with function *compute*; this cluster is then used to create
jobs to execute *compute* with a random number 10 times.:

   # 'compute' is distributed to each node running 'dispynode'
   def compute(n):
       import time, socket
       time.sleep(n)
       host = socket.gethostname()
       return (host, n)

   if __name__ == '__main__':
       import dispy, random
       cluster = dispy.JobCluster(compute)
       jobs = []
       for i in range(10):
           # schedule execution of 'compute' on a node (running 'dispynode')
           # with a parameter (random number in this case)
           job = cluster.submit(random.randint(5,20))
           job.id = i # optionally associate an ID to job (if needed later)
           jobs.append(job)
       # cluster.wait() # waits for all scheduled jobs to finish
       for job in jobs:
           host, n = job() # waits for job to finish and returns results
           print('%s executed job %s at %s with %s' % (host, job.id, job.start_time, n))
           # other fields of 'job' that may be useful:
           # print(job.stdout, job.stderr, job.exception, job.ip_addr, job.start_time, job.end_time)
       cluster.stats()

dispy's scheduler runs the jobs on the processors in the nodes running
dispynode. The nodes execute each job with the job's arguments in
isolation - computations shouldn't depend on global state, such as
modules imported outside of computations, global variables etc.
(except if 'setup' parameter is used, as explained in *dispy (Client)*
and *Examples*). In this case, *compute* needs modules *time* and
*socket*, so it must import them. The program then gets results of
execution for each job with **job()**.


Contents
========

* dispy (Client)

  * JobCluster

  * SharedJobCluster

  * Cluster

  * DispyJob

  * NodeAllocate

  * Provisional/Intermediate Results

  * Transferring Files

  * (Fault) Recover Jobs

  * NAT/Firewall Forwarding

  * SSH Port Forwarding

  * Cloud Computing (with Amazon EC2)

* dispynode (Server)

  * NAT/Firewall Forwarding

  * Docker Container

* dispyscheduler (Shared Execution)

  * NAT/Firewall Forwarding

* dispynetrelay (Using Remote Servers)

* Monitor and Manage Cluster

  * HTTP Server

  * Example

  * Client (Browser) Interface

* Examples

* Contribute to / Recommend / Share dispy


Indices and tables
==================

* Index

* Module Index

* Search Page
