upstream/ipython Files · examples/Parallel Computing/interengine/bintree.py

Backport PR : Changed right arrow key movement function to mirror left arrow key...

Backport PR : Changed right arrow key movement function to mirror left arrow key Seems to solve Issue on this machine, and passing the test file locally. Changed from `cursor.movePosition` to `self._control.moveCursor`, the latter is what the left-arrow key uses. Also removed line 1373 which seems unnecessary and which prevents the cursor from moving at all. I'm not certain how to further test this to make sure nothing was broken.

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      """

      BinaryTree inter-engine communication class

      use from bintree_script.py

      Provides parallel [all]reduce functionality

      """

      from __future__ import print_function

      import cPickle as pickle

      import re

      import socket

      import uuid

      import zmq

      from IPython.parallel.util import disambiguate_url

      #----------------------------------------------------------------------------

      # bintree-related construction/printing helpers

      #----------------------------------------------------------------------------

      def bintree(ids, parent=None):

          """construct {child:parent} dict representation of a binary tree

          keys are the nodes in the tree, and values are the parent of each node.

          The root node has parent `parent`, default: None.

          >>> tree = bintree(range(7))

          >>> tree

          {0: None, 1: 0, 2: 1, 3: 1, 4: 0, 5: 4, 6: 4}

          >>> print_bintree(tree)

          0

            1

              2

              3

            4

              5

              6

          """

          parents = {}

          n = len(ids)

          if n == 0:

              return parents

          root = ids[0]

          parents[root] = parent

          if len(ids) == 1:

              return parents

          else:

              ids = ids[1:]

              n = len(ids)

              left = bintree(ids[:n/2], parent=root)

              right = bintree(ids[n/2:], parent=root)

              parents.update(left)

              parents.update(right)

          return parents

      def reverse_bintree(parents):

          """construct {parent:[children]} dict from {child:parent}

          keys are the nodes in the tree, and values are the lists of children

          of that node in the tree.

          reverse_tree[None] is the root node

          >>> tree = bintree(range(7))

          >>> reverse_bintree(tree)

          {None: 0, 0: [1, 4], 4: [5, 6], 1: [2, 3]}

          """

          children = {}

          for child,parent in parents.iteritems():

              if parent is None:

                  children[None] = child

                  continue

              elif parent not in children:

                  children[parent] = []

              children[parent].append(child)

          return children

      def depth(n, tree):

          """get depth of an element in the tree"""

          d = 0

          parent = tree[n]

          while parent is not None:

              d += 1

              parent = tree[parent]

          return d

      def print_bintree(tree, indent='  '):

          """print a binary tree"""

          for n in sorted(tree.keys()):

              print("%s%s" % (indent * depth(n,tree), n))

      #----------------------------------------------------------------------------

      # Communicator class for a binary-tree map

      #----------------------------------------------------------------------------

      ip_pat = re.compile(r'^\d+\.\d+\.\d+\.\d+$')

      def disambiguate_dns_url(url, location):

          """accept either IP address or dns name, and return IP"""

          if not ip_pat.match(location):

              location = socket.gethostbyname(location)

          return disambiguate_url(url, location)

      class BinaryTreeCommunicator(object):

          id          = None

          pub         = None

          sub         = None

          downstream  = None

          upstream    = None

          pub_url     = None

          tree_url    = None

          def __init__(self, id, interface='tcp://*', root=False):

              self.id = id

              self.root = root

              # create context and sockets

              self._ctx = zmq.Context()

              if root:

                  self.pub = self._ctx.socket(zmq.PUB)

              else:

                  self.sub = self._ctx.socket(zmq.SUB)

                  self.sub.setsockopt(zmq.SUBSCRIBE, b'')

              self.downstream = self._ctx.socket(zmq.PULL)

              self.upstream = self._ctx.socket(zmq.PUSH)

              # bind to ports

              interface_f = interface + ":%i"

              if self.root:

                  pub_port = self.pub.bind_to_random_port(interface)

                  self.pub_url = interface_f % pub_port

              tree_port = self.downstream.bind_to_random_port(interface)

              self.tree_url = interface_f % tree_port

              self.downstream_poller = zmq.Poller()

              self.downstream_poller.register(self.downstream, zmq.POLLIN)

              # guess first public IP from socket

              self.location = socket.gethostbyname_ex(socket.gethostname())[-1][0]

          def __del__(self):

              self.downstream.close()

              self.upstream.close()

              if self.root:

                  self.pub.close()

              else:

                  self.sub.close()

              self._ctx.term()

          @property

          def info(self):

              """return the connection info for this object's sockets."""

              return (self.tree_url, self.location)

          def connect(self, peers, btree, pub_url, root_id=0):

              """connect to peers.  `peers` will be a dict of 4-tuples, keyed by name.

              {peer : (ident, addr, pub_addr, location)}

              where peer is the name, ident is the XREP identity, addr,pub_addr are the

              """

              # count the number of children we have

              self.nchildren = btree.values().count(self.id)

              if self.root:

                  return # root only binds

              root_location = peers[root_id][-1]

              self.sub.connect(disambiguate_dns_url(pub_url, root_location))

              parent = btree[self.id]

              tree_url, location = peers[parent]

              self.upstream.connect(disambiguate_dns_url(tree_url, location))

          def serialize(self, obj):

              """serialize objects.

              Must return list of sendable buffers.

              Can be extended for more efficient/noncopying serialization of numpy arrays, etc.

              """

              return [pickle.dumps(obj)]

          def unserialize(self, msg):

              """inverse of serialize"""

              return pickle.loads(msg[0])

          def publish(self, value):

              assert self.root

              self.pub.send_multipart(self.serialize(value))

          def consume(self):

              assert not self.root

              return self.unserialize(self.sub.recv_multipart())

          def send_upstream(self, value, flags=0):

              assert not self.root

              self.upstream.send_multipart(self.serialize(value), flags=flags|zmq.NOBLOCK)

          def recv_downstream(self, flags=0, timeout=2000.):

              # wait for a message, so we won't block if there was a bug

              self.downstream_poller.poll(timeout)

              msg = self.downstream.recv_multipart(zmq.NOBLOCK|flags)

              return self.unserialize(msg)

          def reduce(self, f, value, flat=True, all=False):

              """parallel reduce on binary tree

              if flat:

                  value is an entry in the sequence

              else:

                  value is a list of entries in the sequence

              if all:

                  broadcast final result to all nodes

              else:

                  only root gets final result

              """

              if not flat:

                  value = reduce(f, value)

              for i in range(self.nchildren):

                  value = f(value, self.recv_downstream())

              if not self.root:

                  self.send_upstream(value)

              if all:

                  if self.root:

                      self.publish(value)

                  else:

                      value = self.consume()

              return value

          def allreduce(self, f, value, flat=True):

              """parallel reduce followed by broadcast of the result"""

              return self.reduce(f, value, flat=flat, all=True)

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				"""
				BinaryTree inter-engine communication class

				use from bintree_script.py

				Provides parallel [all]reduce functionality

				"""
				from __future__ import print_function

				import cPickle as pickle
				import re
				import socket
				import uuid

				import zmq

				from IPython.parallel.util import disambiguate_url


				#----------------------------------------------------------------------------
				# bintree-related construction/printing helpers
				#----------------------------------------------------------------------------

				def bintree(ids, parent=None):
				"""construct {child:parent} dict representation of a binary tree

				keys are the nodes in the tree, and values are the parent of each node.

				The root node has parent `parent`, default: None.

				>>> tree = bintree(range(7))
				>>> tree
				{0: None, 1: 0, 2: 1, 3: 1, 4: 0, 5: 4, 6: 4}
				>>> print_bintree(tree)
				0
				1
				2
				3
				4
				5
				6
				"""
				parents = {}
				n = len(ids)
				if n == 0:
				return parents
				root = ids[0]
				parents[root] = parent
				if len(ids) == 1:
				return parents
				else:
				ids = ids[1:]
				n = len(ids)
				left = bintree(ids[:n/2], parent=root)
				right = bintree(ids[n/2:], parent=root)
				parents.update(left)
				parents.update(right)
				return parents

				def reverse_bintree(parents):
				"""construct {parent:[children]} dict from {child:parent}

				keys are the nodes in the tree, and values are the lists of children
				of that node in the tree.

				reverse_tree[None] is the root node

				>>> tree = bintree(range(7))
				>>> reverse_bintree(tree)
				{None: 0, 0: [1, 4], 4: [5, 6], 1: [2, 3]}
				"""
				children = {}
				for child,parent in parents.iteritems():
				if parent is None:
				children[None] = child
				continue
				elif parent not in children:
				children[parent] = []
				children[parent].append(child)

				return children

				def depth(n, tree):
				"""get depth of an element in the tree"""
				d = 0
				parent = tree[n]
				while parent is not None:
				d += 1
				parent = tree[parent]
				return d

				def print_bintree(tree, indent=' '):
				"""print a binary tree"""
				for n in sorted(tree.keys()):
				print("%s%s" % (indent * depth(n,tree), n))

				#----------------------------------------------------------------------------
				# Communicator class for a binary-tree map
				#----------------------------------------------------------------------------

				ip_pat = re.compile(r'^\d+\.\d+\.\d+\.\d+$')

				def disambiguate_dns_url(url, location):
				"""accept either IP address or dns name, and return IP"""
				if not ip_pat.match(location):
				location = socket.gethostbyname(location)
				return disambiguate_url(url, location)

				class BinaryTreeCommunicator(object):

				id = None
				pub = None
				sub = None
				downstream = None
				upstream = None
				pub_url = None
				tree_url = None

				def __init__(self, id, interface='tcp://*', root=False):
				self.id = id
				self.root = root

				# create context and sockets
				self._ctx = zmq.Context()
				if root:
				self.pub = self._ctx.socket(zmq.PUB)
				else:
				self.sub = self._ctx.socket(zmq.SUB)
				self.sub.setsockopt(zmq.SUBSCRIBE, b'')
				self.downstream = self._ctx.socket(zmq.PULL)
				self.upstream = self._ctx.socket(zmq.PUSH)

				# bind to ports
				interface_f = interface + ":%i"
				if self.root:
				pub_port = self.pub.bind_to_random_port(interface)
				self.pub_url = interface_f % pub_port

				tree_port = self.downstream.bind_to_random_port(interface)
				self.tree_url = interface_f % tree_port
				self.downstream_poller = zmq.Poller()
				self.downstream_poller.register(self.downstream, zmq.POLLIN)

				# guess first public IP from socket
				self.location = socket.gethostbyname_ex(socket.gethostname())[-1][0]

				def __del__(self):
				self.downstream.close()
				self.upstream.close()
				if self.root:
				self.pub.close()
				else:
				self.sub.close()
				self._ctx.term()

				@property
				def info(self):
				"""return the connection info for this object's sockets."""
				return (self.tree_url, self.location)

				def connect(self, peers, btree, pub_url, root_id=0):
				"""connect to peers. `peers` will be a dict of 4-tuples, keyed by name.
				{peer : (ident, addr, pub_addr, location)}
				where peer is the name, ident is the XREP identity, addr,pub_addr are the
				"""

				# count the number of children we have
				self.nchildren = btree.values().count(self.id)

				if self.root:
				return # root only binds

				root_location = peers[root_id][-1]
				self.sub.connect(disambiguate_dns_url(pub_url, root_location))

				parent = btree[self.id]

				tree_url, location = peers[parent]
				self.upstream.connect(disambiguate_dns_url(tree_url, location))

				def serialize(self, obj):
				"""serialize objects.

				Must return list of sendable buffers.

				Can be extended for more efficient/noncopying serialization of numpy arrays, etc.
				"""
				return [pickle.dumps(obj)]

				def unserialize(self, msg):
				"""inverse of serialize"""
				return pickle.loads(msg[0])

				def publish(self, value):
				assert self.root
				self.pub.send_multipart(self.serialize(value))

				def consume(self):
				assert not self.root
				return self.unserialize(self.sub.recv_multipart())

				def send_upstream(self, value, flags=0):
				assert not self.root
				self.upstream.send_multipart(self.serialize(value), flags=flags\|zmq.NOBLOCK)

				def recv_downstream(self, flags=0, timeout=2000.):
				# wait for a message, so we won't block if there was a bug
				self.downstream_poller.poll(timeout)

				msg = self.downstream.recv_multipart(zmq.NOBLOCK\|flags)
				return self.unserialize(msg)

				def reduce(self, f, value, flat=True, all=False):
				"""parallel reduce on binary tree

				if flat:
				value is an entry in the sequence
				else:
				value is a list of entries in the sequence

				if all:
				broadcast final result to all nodes
				else:
				only root gets final result
				"""
				if not flat:
				value = reduce(f, value)

				for i in range(self.nchildren):
				value = f(value, self.recv_downstream())

				if not self.root:
				self.send_upstream(value)

				if all:
				if self.root:
				self.publish(value)
				else:
				value = self.consume()
				return value

				def allreduce(self, f, value, flat=True):
				"""parallel reduce followed by broadcast of the result"""
				return self.reduce(f, value, flat=flat, all=True)