map.py
165 lines
| 5.1 KiB
| text/x-python
|
PythonLexer
MinRK
|
r3587 | # encoding: utf-8 | ||
"""Classes used in scattering and gathering sequences. | ||||
Scattering consists of partitioning a sequence and sending the various | ||||
pieces to individual nodes in a cluster. | ||||
MinRK
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r4018 | |||
Authors: | ||||
* Brian Granger | ||||
* MinRK | ||||
MinRK
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r3587 | """ | ||
__docformat__ = "restructuredtext en" | ||||
#------------------------------------------------------------------------------- | ||||
MinRK
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r4018 | # Copyright (C) 2008-2011 The IPython Development Team | ||
MinRK
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r3587 | # | ||
# Distributed under the terms of the BSD License. The full license is in | ||||
# the file COPYING, distributed as part of this software. | ||||
#------------------------------------------------------------------------------- | ||||
#------------------------------------------------------------------------------- | ||||
# Imports | ||||
#------------------------------------------------------------------------------- | ||||
import types | ||||
from IPython.utils.data import flatten as utils_flatten | ||||
#------------------------------------------------------------------------------- | ||||
# Figure out which array packages are present and their array types | ||||
#------------------------------------------------------------------------------- | ||||
arrayModules = [] | ||||
try: | ||||
import Numeric | ||||
except ImportError: | ||||
pass | ||||
else: | ||||
arrayModules.append({'module':Numeric, 'type':Numeric.arraytype}) | ||||
try: | ||||
import numpy | ||||
except ImportError: | ||||
pass | ||||
else: | ||||
arrayModules.append({'module':numpy, 'type':numpy.ndarray}) | ||||
try: | ||||
import numarray | ||||
except ImportError: | ||||
pass | ||||
else: | ||||
arrayModules.append({'module':numarray, | ||||
'type':numarray.numarraycore.NumArray}) | ||||
class Map: | ||||
"""A class for partitioning a sequence using a map.""" | ||||
def getPartition(self, seq, p, q): | ||||
"""Returns the pth partition of q partitions of seq.""" | ||||
# Test for error conditions here | ||||
if p<0 or p>=q: | ||||
print "No partition exists." | ||||
return | ||||
remainder = len(seq)%q | ||||
basesize = len(seq)/q | ||||
hi = [] | ||||
lo = [] | ||||
for n in range(q): | ||||
if n < remainder: | ||||
lo.append(n * (basesize + 1)) | ||||
hi.append(lo[-1] + basesize + 1) | ||||
else: | ||||
lo.append(n*basesize + remainder) | ||||
hi.append(lo[-1] + basesize) | ||||
result = seq[lo[p]:hi[p]] | ||||
return result | ||||
def joinPartitions(self, listOfPartitions): | ||||
return self.concatenate(listOfPartitions) | ||||
def concatenate(self, listOfPartitions): | ||||
testObject = listOfPartitions[0] | ||||
# First see if we have a known array type | ||||
for m in arrayModules: | ||||
#print m | ||||
if isinstance(testObject, m['type']): | ||||
return m['module'].concatenate(listOfPartitions) | ||||
# Next try for Python sequence types | ||||
if isinstance(testObject, (types.ListType, types.TupleType)): | ||||
return utils_flatten(listOfPartitions) | ||||
# If we have scalars, just return listOfPartitions | ||||
return listOfPartitions | ||||
class RoundRobinMap(Map): | ||||
"""Partitions a sequence in a roun robin fashion. | ||||
This currently does not work! | ||||
""" | ||||
def getPartition(self, seq, p, q): | ||||
# if not isinstance(seq,(list,tuple)): | ||||
# raise NotImplementedError("cannot RR partition type %s"%type(seq)) | ||||
return seq[p:len(seq):q] | ||||
#result = [] | ||||
#for i in range(p,len(seq),q): | ||||
# result.append(seq[i]) | ||||
#return result | ||||
def joinPartitions(self, listOfPartitions): | ||||
testObject = listOfPartitions[0] | ||||
# First see if we have a known array type | ||||
for m in arrayModules: | ||||
#print m | ||||
if isinstance(testObject, m['type']): | ||||
return self.flatten_array(m['type'], listOfPartitions) | ||||
if isinstance(testObject, (types.ListType, types.TupleType)): | ||||
return self.flatten_list(listOfPartitions) | ||||
return listOfPartitions | ||||
def flatten_array(self, klass, listOfPartitions): | ||||
test = listOfPartitions[0] | ||||
shape = list(test.shape) | ||||
shape[0] = sum([ p.shape[0] for p in listOfPartitions]) | ||||
A = klass(shape) | ||||
N = shape[0] | ||||
q = len(listOfPartitions) | ||||
for p,part in enumerate(listOfPartitions): | ||||
A[p:N:q] = part | ||||
return A | ||||
def flatten_list(self, listOfPartitions): | ||||
flat = [] | ||||
for i in range(len(listOfPartitions[0])): | ||||
flat.extend([ part[i] for part in listOfPartitions if len(part) > i ]) | ||||
return flat | ||||
#lengths = [len(x) for x in listOfPartitions] | ||||
#maxPartitionLength = len(listOfPartitions[0]) | ||||
#numberOfPartitions = len(listOfPartitions) | ||||
#concat = self.concatenate(listOfPartitions) | ||||
#totalLength = len(concat) | ||||
#result = [] | ||||
#for i in range(maxPartitionLength): | ||||
# result.append(concat[i:totalLength:maxPartitionLength]) | ||||
# return self.concatenate(listOfPartitions) | ||||
def mappable(obj): | ||||
"""return whether an object is mappable or not.""" | ||||
if isinstance(obj, (tuple,list)): | ||||
return True | ||||
for m in arrayModules: | ||||
if isinstance(obj,m['type']): | ||||
return True | ||||
return False | ||||
dists = {'b':Map,'r':RoundRobinMap} | ||||