upstream/ipython Files · docs/examples/kernel/plotting_backend.py

Fix bug where 'if 1:' was being added to comment-only code....

Fix bug where 'if 1:' was being added to comment-only code. Found by trying to paste and run this example: http://matplotlib.sourceforge.net/examples/api/collections_demo.html that happened to have indented, comment-only lines of the type: code() # comment code() In these cases, we should *not* try to prepend 'if 1:' to the user's code since that comment by itself isn't executable, and it will cause a compiler IndentationError.

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      """An example of how to use IPython1 for plotting remote parallel data

      The two files plotting_frontend.ipy and plotting_backend.py go together.

      This file (plotting_backend.py) performs the actual computation.  For this 

      example, the computation just generates a set of random numbers that

      look like a distribution of particles with 2D position (x,y) and 

      momentum (px,py).  In a real situation, this file would do some time

      consuming and complicated calculation, and could possibly make calls

      to MPI.

      One important feature is that this script can also be run standalone without

      IPython.  This is nice as it allows it to be run in more traditional 

      settings where IPython isn't being used.

      When used with IPython1, this code is run on the engines.  Because this

      code doesn't make any plots, the engines don't have to have any plotting

      packages installed.

      """

      # Imports

      import numpy as N

      import time

      import random

      # Functions

      def compute_particles(number):

          x = N.random.standard_normal(number)

          y = N.random.standard_normal(number)

          px = N.random.standard_normal(number)

          py = N.random.standard_normal(number)

          return x, y, px, py

      def downsample(array, k):

          """Choose k random elements of array."""

          length = array.shape[0]

          indices = random.sample(xrange(length), k)

          return array[indices]

      # Parameters of the run

      number = 100000

      d_number = 1000

      # The actual run

      time.sleep(0) # Pretend it took a while

      x, y, px, py = compute_particles(number)

      # Now downsample the data

      downx = downsample(x, d_number)

      downy = downsample(x, d_number)

      downpx = downsample(px, d_number)

      downpy = downsample(py, d_number)

      print "downx: ", downx[:10]

      print "downy: ", downy[:10]

      print "downpx: ", downpx[:10]

      print "downpy: ", downpy[:10]

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				"""An example of how to use IPython1 for plotting remote parallel data

				The two files plotting_frontend.ipy and plotting_backend.py go together.

				This file (plotting_backend.py) performs the actual computation. For this
				example, the computation just generates a set of random numbers that
				look like a distribution of particles with 2D position (x,y) and
				momentum (px,py). In a real situation, this file would do some time
				consuming and complicated calculation, and could possibly make calls
				to MPI.

				One important feature is that this script can also be run standalone without
				IPython. This is nice as it allows it to be run in more traditional
				settings where IPython isn't being used.

				When used with IPython1, this code is run on the engines. Because this
				code doesn't make any plots, the engines don't have to have any plotting
				packages installed.
				"""

				# Imports
				import numpy as N
				import time
				import random

				# Functions
				def compute_particles(number):
				x = N.random.standard_normal(number)
				y = N.random.standard_normal(number)
				px = N.random.standard_normal(number)
				py = N.random.standard_normal(number)
				return x, y, px, py

				def downsample(array, k):
				"""Choose k random elements of array."""
				length = array.shape[0]
				indices = random.sample(xrange(length), k)
				return array[indices]

				# Parameters of the run
				number = 100000
				d_number = 1000

				# The actual run

				time.sleep(0) # Pretend it took a while
				x, y, px, py = compute_particles(number)
				# Now downsample the data
				downx = downsample(x, d_number)
				downy = downsample(x, d_number)
				downpx = downsample(px, d_number)
				downpy = downsample(py, d_number)

				print "downx: ", downx[:10]
				print "downy: ", downy[:10]
				print "downpx: ", downpx[:10]
				print "downpy: ", downpy[:10]