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      #!/usr/bin/env python

      """

      A simple python program of solving a 2D wave equation in parallel.

      Domain partitioning and inter-processor communication

      are done by an object of class ZMQRectPartitioner2D

      (which is a subclass of RectPartitioner2D and uses 0MQ via pyzmq)

      An example of running the program is (8 processors, 4x2 partition,

      200x200 grid cells)::

         $ ipcluster start -n 8 # start 8 engines

         $ python parallelwave.py --grid 200 200 --partition 4 2

      See also parallelwave-mpi, which runs the same program, but uses MPI

      (via mpi4py) for the inter-engine communication.

      Authors

      -------

       * Xing Cai

       * Min Ragan-Kelley

      """

      #

      import sys

      import time

      from numpy import exp, zeros, newaxis, sqrt

      from IPython.external import argparse

      from IPython.parallel import Client, Reference

      def setup_partitioner(comm, addrs, index, num_procs, gnum_cells, parts):

          """create a partitioner in the engine namespace"""

          global partitioner

          p = ZMQRectPartitioner2D(comm, addrs, my_id=index, num_procs=num_procs)

          p.redim(global_num_cells=gnum_cells, num_parts=parts)

          p.prepare_communication()

          # put the partitioner into the global namespace:

          partitioner=p

      def setup_solver(*args, **kwargs):

          """create a WaveSolver in the engine namespace."""

          global solver

          solver = WaveSolver(*args, **kwargs)

      def wave_saver(u, x, y, t):

          """save the wave state for each timestep."""

          global u_hist

          global t_hist

          t_hist.append(t)

          u_hist.append(1.0*u)

      # main program:

      if __name__ == '__main__':

          parser = argparse.ArgumentParser()

          paa = parser.add_argument

          paa('--grid', '-g',

              type=int, nargs=2, default=[100,100], dest='grid',

              help="Cells in the grid, e.g. --grid 100 200")

          paa('--partition', '-p',

              type=int, nargs=2, default=None,

              help="Process partition grid, e.g. --partition 4 2 for 4x2")

          paa('-c',

              type=float, default=1.,

              help="Wave speed (I think)")

          paa('-Ly',

              type=float, default=1.,

              help="system size (in y)")

          paa('-Lx',

              type=float, default=1.,

              help="system size (in x)")

          paa('-t', '--tstop',

              type=float, default=1.,

              help="Time units to run")

          paa('--profile',

              type=unicode, default=u'default',

              help="Specify the ipcluster profile for the client to connect to.")

          paa('--save',

              action='store_true',

              help="Add this flag to save the time/wave history during the run.")

          paa('--scalar',

              action='store_true',

              help="Also run with scalar interior implementation, to see vector speedup.")

          ns = parser.parse_args()

          # set up arguments

          grid = ns.grid

          partition = ns.partition

          Lx = ns.Lx

          Ly = ns.Ly

          c = ns.c

          tstop = ns.tstop

          if ns.save:

              user_action = wave_saver

          else:

              user_action = None

          num_cells = 1.0*(grid[0]-1)*(grid[1]-1)

          final_test = True

          # create the Client

          rc = Client(profile=ns.profile)

          num_procs = len(rc.ids)

          if partition is None:

              partition = [num_procs,1]

          else:

              num_procs = min(num_procs, partition[0]*partition[1])

          assert partition[0]*partition[1] == num_procs, "can't map partition %s to %i engines"%(partition, num_procs)

          # construct the View:

          view = rc[:num_procs]

          print("Running %s system on %s processes until %f"%(grid, partition, tstop))

          # functions defining initial/boundary/source conditions

          def I(x,y):

              from numpy import exp

              return 1.5*exp(-100*((x-0.5)**2+(y-0.5)**2))

          def f(x,y,t):

              return 0.0

              # from numpy import exp,sin

              # return 10*exp(-(x - sin(100*t))**2)

          def bc(x,y,t):

              return 0.0

          # initialize t_hist/u_hist for saving the state at each step (optional)

          view['t_hist'] = []

          view['u_hist'] = []

          # set vector/scalar implementation details

          impl = {}

          impl['ic'] = 'vectorized'

          impl['inner'] = 'scalar'

          impl['bc'] = 'vectorized'

          # execute some files so that the classes we need will be defined on the engines:

          view.execute('import numpy')

          view.run('communicator.py')

          view.run('RectPartitioner.py')

          view.run('wavesolver.py')

          # scatter engine IDs

          view.scatter('my_id', range(num_procs), flatten=True)

          # create the engine connectors

          view.execute('com = EngineCommunicator()')

          # gather the connection information into a single dict

          ar = view.apply_async(lambda : com.info)

          peers = ar.get_dict()

          # print peers

          # this is a dict, keyed by engine ID, of the connection info for the EngineCommunicators

          # setup remote partitioner

          # note that Reference means that the argument passed to setup_partitioner will be the

          # object named 'com' in the engine's namespace

          view.apply_sync(setup_partitioner, Reference('com'), peers, Reference('my_id'), num_procs, grid, partition)

          time.sleep(1)

          # convenience lambda to call solver.solve:

          _solve = lambda *args, **kwargs: solver.solve(*args, **kwargs)

          if ns.scalar:

              impl['inner'] = 'scalar'

              # setup remote solvers

              view.apply_sync(setup_solver, I,f,c,bc,Lx,Ly, partitioner=Reference('partitioner'), dt=0,implementation=impl)

              # run first with element-wise Python operations for each cell

              t0 = time.time()

              ar = view.apply_async(_solve, tstop, dt=0, verbose=True, final_test=final_test, user_action=user_action)

              if final_test:

                  # this sum is performed element-wise as results finish

                  s = sum(ar)

                  # the L2 norm (RMS) of the result:

                  norm = sqrt(s/num_cells)

              else:

                  norm = -1

              t1 = time.time()

              print('scalar inner-version, Wtime=%g, norm=%g'%(t1-t0, norm))

          # run again with faster numpy-vectorized inner implementation:

          impl['inner'] = 'vectorized'

          # setup remote solvers

          view.apply_sync(setup_solver, I,f,c,bc,Lx,Ly,partitioner=Reference('partitioner'), dt=0,implementation=impl)

          t0 = time.time()

          ar = view.apply_async(_solve, tstop, dt=0, verbose=True, final_test=final_test, user_action=user_action)

          if final_test:

              # this sum is performed element-wise as results finish

              s = sum(ar)

              # the L2 norm (RMS) of the result:

              norm = sqrt(s/num_cells)

          else:

              norm = -1

          t1 = time.time()

          print('vector inner-version, Wtime=%g, norm=%g'%(t1-t0, norm))

          # if ns.save is True, then u_hist stores the history of u as a list

          # If the partion scheme is Nx1, then u can be reconstructed via 'gather':

          if ns.save and partition[-1] == 1:

              import matplotlib.pyplot as plt

              view.execute('u_last=u_hist[-1]')

              u_last = view.gather('u_last', block=True)

              plt.pcolor(u_last)

              plt.show()

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				#!/usr/bin/env python
				"""
				A simple python program of solving a 2D wave equation in parallel.
				Domain partitioning and inter-processor communication
				are done by an object of class ZMQRectPartitioner2D
				(which is a subclass of RectPartitioner2D and uses 0MQ via pyzmq)

				An example of running the program is (8 processors, 4x2 partition,
				200x200 grid cells)::

				$ ipcluster start -n 8 # start 8 engines
				$ python parallelwave.py --grid 200 200 --partition 4 2

				See also parallelwave-mpi, which runs the same program, but uses MPI
				(via mpi4py) for the inter-engine communication.

				Authors
				-------

				* Xing Cai
				* Min Ragan-Kelley

				"""
				#
				import sys
				import time

				from numpy import exp, zeros, newaxis, sqrt

				from IPython.external import argparse
				from IPython.parallel import Client, Reference

				def setup_partitioner(comm, addrs, index, num_procs, gnum_cells, parts):
				"""create a partitioner in the engine namespace"""
				global partitioner
				p = ZMQRectPartitioner2D(comm, addrs, my_id=index, num_procs=num_procs)
				p.redim(global_num_cells=gnum_cells, num_parts=parts)
				p.prepare_communication()
				# put the partitioner into the global namespace:
				partitioner=p

				def setup_solver(args, *kwargs):
				"""create a WaveSolver in the engine namespace."""
				global solver
				solver = WaveSolver(args, *kwargs)

				def wave_saver(u, x, y, t):
				"""save the wave state for each timestep."""
				global u_hist
				global t_hist
				t_hist.append(t)
				u_hist.append(1.0*u)


				# main program:
				if __name__ == '__main__':

				parser = argparse.ArgumentParser()
				paa = parser.add_argument
				paa('--grid', '-g',
				type=int, nargs=2, default=[100,100], dest='grid',
				help="Cells in the grid, e.g. --grid 100 200")
				paa('--partition', '-p',
				type=int, nargs=2, default=None,
				help="Process partition grid, e.g. --partition 4 2 for 4x2")
				paa('-c',
				type=float, default=1.,
				help="Wave speed (I think)")
				paa('-Ly',
				type=float, default=1.,
				help="system size (in y)")
				paa('-Lx',
				type=float, default=1.,
				help="system size (in x)")
				paa('-t', '--tstop',
				type=float, default=1.,
				help="Time units to run")
				paa('--profile',
				type=unicode, default=u'default',
				help="Specify the ipcluster profile for the client to connect to.")
				paa('--save',
				action='store_true',
				help="Add this flag to save the time/wave history during the run.")
				paa('--scalar',
				action='store_true',
				help="Also run with scalar interior implementation, to see vector speedup.")

				ns = parser.parse_args()
				# set up arguments
				grid = ns.grid
				partition = ns.partition
				Lx = ns.Lx
				Ly = ns.Ly
				c = ns.c
				tstop = ns.tstop
				if ns.save:
				user_action = wave_saver
				else:
				user_action = None

				num_cells = 1.0(grid[0]-1)(grid[1]-1)
				final_test = True

				# create the Client
				rc = Client(profile=ns.profile)
				num_procs = len(rc.ids)

				if partition is None:
				partition = [num_procs,1]
				else:
				num_procs = min(num_procs, partition[0]*partition[1])

				assert partition[0]*partition[1] == num_procs, "can't map partition %s to %i engines"%(partition, num_procs)

				# construct the View:
				view = rc[:num_procs]
				print("Running %s system on %s processes until %f"%(grid, partition, tstop))

				# functions defining initial/boundary/source conditions
				def I(x,y):
				from numpy import exp
				return 1.5exp(-100((x-0.5)2+(y-0.5)2))
				def f(x,y,t):
				return 0.0
				# from numpy import exp,sin
				# return 10exp(-(x - sin(100t))**2)
				def bc(x,y,t):
				return 0.0

				# initialize t_hist/u_hist for saving the state at each step (optional)
				view['t_hist'] = []
				view['u_hist'] = []

				# set vector/scalar implementation details
				impl = {}
				impl['ic'] = 'vectorized'
				impl['inner'] = 'scalar'
				impl['bc'] = 'vectorized'

				# execute some files so that the classes we need will be defined on the engines:
				view.execute('import numpy')
				view.run('communicator.py')
				view.run('RectPartitioner.py')
				view.run('wavesolver.py')

				# scatter engine IDs
				view.scatter('my_id', range(num_procs), flatten=True)

				# create the engine connectors
				view.execute('com = EngineCommunicator()')

				# gather the connection information into a single dict
				ar = view.apply_async(lambda : com.info)
				peers = ar.get_dict()
				# print peers
				# this is a dict, keyed by engine ID, of the connection info for the EngineCommunicators

				# setup remote partitioner
				# note that Reference means that the argument passed to setup_partitioner will be the
				# object named 'com' in the engine's namespace
				view.apply_sync(setup_partitioner, Reference('com'), peers, Reference('my_id'), num_procs, grid, partition)
				time.sleep(1)
				# convenience lambda to call solver.solve:
				_solve = lambda args, kwargs: solver.solve(args, **kwargs)

				if ns.scalar:
				impl['inner'] = 'scalar'
				# setup remote solvers
				view.apply_sync(setup_solver, I,f,c,bc,Lx,Ly, partitioner=Reference('partitioner'), dt=0,implementation=impl)

				# run first with element-wise Python operations for each cell
				t0 = time.time()
				ar = view.apply_async(_solve, tstop, dt=0, verbose=True, final_test=final_test, user_action=user_action)
				if final_test:
				# this sum is performed element-wise as results finish
				s = sum(ar)
				# the L2 norm (RMS) of the result:
				norm = sqrt(s/num_cells)
				else:
				norm = -1
				t1 = time.time()
				print('scalar inner-version, Wtime=%g, norm=%g'%(t1-t0, norm))

				# run again with faster numpy-vectorized inner implementation:
				impl['inner'] = 'vectorized'
				# setup remote solvers
				view.apply_sync(setup_solver, I,f,c,bc,Lx,Ly,partitioner=Reference('partitioner'), dt=0,implementation=impl)

				t0 = time.time()

				ar = view.apply_async(_solve, tstop, dt=0, verbose=True, final_test=final_test, user_action=user_action)
				if final_test:
				# this sum is performed element-wise as results finish
				s = sum(ar)
				# the L2 norm (RMS) of the result:
				norm = sqrt(s/num_cells)
				else:
				norm = -1
				t1 = time.time()
				print('vector inner-version, Wtime=%g, norm=%g'%(t1-t0, norm))

				# if ns.save is True, then u_hist stores the history of u as a list
				# If the partion scheme is Nx1, then u can be reconstructed via 'gather':
				if ns.save and partition[-1] == 1:
				import matplotlib.pyplot as plt
				view.execute('u_last=u_hist[-1]')
				u_last = view.gather('u_last', block=True)
				plt.pcolor(u_last)
				plt.show()