Python* API Reference for Intel® Data Analytics Acceleration Library 2019 Update 5

low_order_moms_csr_distr.py

Deprecation Notice: With the introduction of daal4py, a package that supersedes PyDAAL, Intel is deprecating PyDAAL and will discontinue support starting with Intel® DAAL 2021 and Intel® Distribution for Python 2021. Until then Intel will continue to provide compatible pyDAAL pip and conda packages for newer releases of Intel DAAL and make it available in open source. However, Intel will not add the new features of Intel DAAL to pyDAAL. Intel recommends developers switch to and use daal4py.

Note: To find daal4py examples, refer to daal4py documentation or browse github repository.

1 # file: low_order_moms_csr_distr.py
2 #===============================================================================
3 # Copyright 2014-2019 Intel Corporation.
4 #
5 # This software and the related documents are Intel copyrighted materials, and
6 # your use of them is governed by the express license under which they were
7 # provided to you (License). Unless the License provides otherwise, you may not
8 # use, modify, copy, publish, distribute, disclose or transmit this software or
9 # the related documents without Intel's prior written permission.
10 #
11 # This software and the related documents are provided as is, with no express
12 # or implied warranties, other than those that are expressly stated in the
13 # License.
14 #===============================================================================
15 
16 ## <a name="DAAL-EXAMPLE-PY-LOW_ORDER_MOMENTS_CSR_DISTRIBUTED"></a>
17 ## \example low_order_moms_csr_distr.py
18 
19 import os
20 import sys
21 
22 from daal import step1Local, step2Master
23 from daal.algorithms import low_order_moments
24 
25 utils_folder = os.path.realpath(os.path.abspath(os.path.dirname(os.path.dirname(__file__))))
26 if utils_folder not in sys.path:
27  sys.path.insert(0, utils_folder)
28 from utils import printNumericTable, createSparseTable
29 
30 DAAL_PREFIX = os.path.join('..', 'data')
31 
32 # Input data set parameters
33 nBlocks = 4
34 
35 datasetFileNames = [
36  os.path.join(DAAL_PREFIX, 'distributed', 'covcormoments_csr_1.csv'),
37  os.path.join(DAAL_PREFIX, 'distributed', 'covcormoments_csr_2.csv'),
38  os.path.join(DAAL_PREFIX, 'distributed', 'covcormoments_csr_3.csv'),
39  os.path.join(DAAL_PREFIX, 'distributed', 'covcormoments_csr_4.csv')
40 ]
41 
42 partialResult = [0] * nBlocks
43 result = None
44 
45 
46 def computestep1Local(block):
47 
48  dataTable = createSparseTable(datasetFileNames[block])
49 
50  # Create algorithm objects to compute low order moments in the distributed processing mode using the default method
51  algorithm = low_order_moments.Distributed(step1Local, method=low_order_moments.fastCSR)
52 
53  # Set input objects for the algorithm
54  algorithm.input.set(low_order_moments.data, dataTable)
55 
56  # Compute partial low order moments estimates on nodes
57  partialResult[block] = algorithm.compute() # Get the computed partial estimates
58 
59 
60 def computeOnMasterNode():
61  global result
62 
63  # Create algorithm objects to compute low order moments in the distributed processing mode using the default method
64  algorithm = low_order_moments.Distributed(step2Master, method=low_order_moments.fastCSR)
65 
66  # Set input objects for the algorithm
67  for i in range(nBlocks):
68  algorithm.input.add(low_order_moments.partialResults, partialResult[i])
69 
70  # Compute a partial low order moments estimate on the master node from the partial estimates on local nodes
71  algorithm.compute()
72 
73  # Finalize the result in the distributed processing mode and get the computed low order moments
74  result = algorithm.finalizeCompute()
75 
76 
77 def printResults(res):
78 
79  printNumericTable(res.get(low_order_moments.minimum), "Minimum:")
80  printNumericTable(res.get(low_order_moments.maximum), "Maximum:")
81  printNumericTable(res.get(low_order_moments.sum), "Sum:")
82  printNumericTable(res.get(low_order_moments.sumSquares), "Sum of squares:")
83  printNumericTable(res.get(low_order_moments.sumSquaresCentered), "Sum of squared difference from the means:")
84  printNumericTable(res.get(low_order_moments.mean), "Mean:")
85  printNumericTable(res.get(low_order_moments.secondOrderRawMoment), "Second order raw moment:")
86  printNumericTable(res.get(low_order_moments.variance), "Variance:")
87  printNumericTable(res.get(low_order_moments.standardDeviation), "Standard deviation:")
88  printNumericTable(res.get(low_order_moments.variation), "Variation:")
89 
90 if __name__ == "__main__":
91  for block in range(nBlocks):
92  computestep1Local(block)
93 
94  computeOnMasterNode()
95  printResults(result)

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