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TestingSbsConnection.py
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178 lines (122 loc) · 5.68 KB
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import AlgorithmOne as algoOne
import AlgorithmTwo as algoTwo
import AlgorithmThree as algoThree
from graph_tool.all import *
import random
import TotalNetwork as tn
import matplotlib.pyplot as plt
# ---------------------------------------------------------------------------------------------------
# (1) No. of Connections Sbs vs No. of Succesfull Mapings
def testSuccMappings(algoType, connectivitySbs = tn.sbsDegree, intervalFactor = tn.intervalFactor, iterations = tn.iterCount):
connectivity = tn.sbsDegree
xOne = []
yOne = []
ranSlices = tn.createRANSlice(tn.numRnSlices, tn.numVnfFunctions, tn.resList, tn.resCtPerVnf, connectivity=tn.vnfDegree, random_range=0)
for ctrVar in range(iterations):
# One
substrateNetwork = tn.createSbsNetwork(tn.numSubsNodes, tn.resCapList, tn.resCtPerSbs, connectivity, random_range=tn.randUpBound)
totalNetwork = tn.createTotalNetwork(substrateNetwork, ranSlices)
if algoType == 1:
numMappings = tn.algoOneTest(totalNetwork)
elif algoType == 2:
numMappings = tn.algoTwoTest(totalNetwork)
elif algoType == 3:
numMappings = tn.algoThreeTest(totalNetwork)
else:
numMappings = tn.algoFourTest(totalNetwork)
xOne.append(connectivity)
yOne.append(numMappings)
substrateNetwork.clear()
totalNetwork.clear()
tn.resCapList.clear()
tn.vnfCncList.clear()
tn.vnfTotalAccList.clear()
connectivity+= intervalFactor
returnData = [xOne, yOne]
return returnData;
# (2) No. of Connections Sbs vs No. of UnSuccesfull Mapings
def testUnsuccMappings(algoType, connectivitySbs = tn.sbsDegree, intervalFactor = tn.intervalFactor, iterations = tn.iterCount):
connectivity = tn.sbsDegree
xOne = []
yOne = []
ranSlices = tn.createRANSlice(tn.numRnSlices, tn.numVnfFunctions, tn.resList, tn.resCtPerVnf, connectivity = tn.vnfDegree, random_range=0)
for ctrVar in range(iterations):
# One
substrateNetwork = tn.createSbsNetwork(tn.numSubsNodes, tn.resCapList, tn.resCtPerSbs, connectivity, random_range=tn.randUpBound)
totalNetwork = tn.createTotalNetwork(substrateNetwork, ranSlices)
if algoType == 1:
numMappings = tn.algoOneTest(totalNetwork)
elif algoType == 2:
numMappings = tn.algoTwoTest(totalNetwork)
elif algoType == 3:
numMappings = tn.algoThreeTest(totalNetwork)
else:
numMappings = tn.algoFourTest(totalNetwork)
xOne.append(connectivity)
yOne.append(tn.numVnfFunctions - numMappings)
substrateNetwork.clear()
totalNetwork.clear()
tn.resCapList.clear()
tn.vnfCncList.clear()
tn.vnfTotalAccList.clear()
connectivity+=intervalFactor
returnData = [xOne, yOne]
return returnData;
# (3) No. of Connections Sbs vs Amount of Sbs. Resouces Unused.
def testAvailRes(algoType, connectivitySbs = tn.sbsDegree, intervalFactor = tn.intervalFactor, iterations = tn.iterCount):
connectivity = tn.sbsDegree
xOne = []
yOne = []
ranSlices = tn.createRANSlice(tn.numRnSlices, tn.numVnfFunctions, tn.resList, tn.resCtPerVnf, connectivity = tn.vnfDegree, random_range=0)
for ctrVar in range(iterations):
# One
substrateNetwork = tn.createSbsNetwork(tn.numSubsNodes, tn.resCapList, tn.resCtPerSbs, connectivity, random_range=tn.randUpBound)
totalNetwork = tn.createTotalNetwork(substrateNetwork, ranSlices)
if algoType == 1:
numMappings = tn.algoOneTest(totalNetwork)
elif algoType == 2:
numMappings = tn.algoTwoTest(totalNetwork)
elif algoType == 3:
numMappings = tn.algoThreeTest(totalNetwork)
else:
numMappings = tn.algoFourTest(totalNetwork)
avRes = tn.sbsAvailableRes(totalNetwork)
xOne.append(connectivity)
yOne.append(avRes)
substrateNetwork.clear()
totalNetwork.clear()
tn.resCapList.clear()
tn.vnfCncList.clear()
tn.vnfTotalAccList.clear()
connectivity+= intervalFactor
returnData = [xOne, yOne]
return returnData;
# (4) No. of Connections Sbs vs Amount of Sbs. Resouces Exhausted
def testExhaustRes(algoType, connectivitySbs = tn.sbsDegree, intervalFactor = tn.intervalFactor, iterations = tn.iterCount):
connectivity = tn.sbsDegree
xOne = []
yOne = []
ranSlices = tn.createRANSlice(tn.numRnSlices, tn.numVnfFunctions, tn.resList, tn.resCtPerVnf, connectivity =tn.vnfDegree, random_range=0)
for ctrVar in range(iterations):
# One
substrateNetwork = tn.createSbsNetwork(tn.numSubsNodes, tn.resCapList, tn.resCtPerSbs, connectivity, random_range=tn.randUpBound)
totalNetwork = tn.createTotalNetwork(substrateNetwork, ranSlices)
if algoType == 1:
numMappings = tn.algoOneTest(totalNetwork)
elif algoType == 2:
numMappings = tn.algoTwoTest(totalNetwork)
elif algoType == 3:
numMappings = tn.algoThreeTest(totalNetwork)
else:
numMappings = tn.algoFourTest(totalNetwork)
avRes = tn.sbsAvailableRes(totalNetwork)
xOne.append(connectivity)
yOne.append(tn.numSubsNodes*tn.resCtPerSbs - avRes)
substrateNetwork.clear()
totalNetwork.clear()
tn.resCapList.clear()
tn.vnfCncList.clear()
tn.vnfTotalAccList.clear()
connectivity+= intervalFactor
returnData = [xOne, yOne]
return returnData;