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bintree.py
246 lines | 7.0 KiB | text/x-python | PythonLexer
"""
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)