Commit c94bdc63 authored by Georgios Dagkakis's avatar Georgios Dagkakis

code for experiments

parent 50a4e123
CACHE MANIFEST
# This manifest was generated by grunt-manifest HTML5 Cache Manifest Generator
# Time: Wed Sep 16 2015 18:23:50 GMT+0200 (CEST)
# Time: Wed Nov 28 2018 10:09:45 GMT+0000 (GMT)
CACHE:
daff/index.html
......
......@@ -41,6 +41,7 @@ class ACO(plugin.ExecutionPlugin):
def run(self, data):
"""Preprocess the data.
"""
self.logger.info("ACO")
distributor_url = data['general'].get('distributorURL')
distributor = None
if distributor_url:
......@@ -108,7 +109,12 @@ class ACO(plugin.ExecutionPlugin):
else:
# synchronous
for ant in scenario_list:
self.logger.info("%s running" % ant['key'])
try:
ant['result'] = self.runOneScenario(ant['input'])['result']
except:
self.logger.info("%s failed" % ant['key'])
ant['result'] = {'result_list': ['fail']}
else: # asynchronous
self.logger.info("Registering a job for %s scenarios" % len(scenario_list))
......
......@@ -18,6 +18,8 @@ class BatchesACO(ACO):
"""Calculate the score of this ant.
"""
result, = ant['result']['result_list'] #read the result as JSON
if result == 'fail':
return 0
#loop through the elements
for element in result['elementList']:
element_family = element.get('family', None)
......
......@@ -39,6 +39,8 @@ class BatchesStochasticACO(BatchesACO):
"""Calculate the score of this ant.
"""
result, = ant['result']['result_list'] #read the result as JSON
if result == 'fail':
return 0
#loop through the elements
for element in result['elementList']:
element_family = element.get('family', None)
......@@ -68,6 +70,7 @@ class BatchesStochasticACO(BatchesACO):
def run(self, data):
"""Preprocess the data.
"""
self.logger.info("Stoch ACO")
self.outputFile = xlwt.Workbook()
self.outputSheet = self.outputFile.add_sheet('ACO Results', cell_overwrite_ok=True)
self.rowIndex=0
......@@ -141,6 +144,7 @@ class BatchesStochasticACO(BatchesACO):
for i in range(int(data["general"]["numberOfGenerations"])):
self.outputSheet.write(self.rowIndex,0,'Generation '+str(i+1))
self.rowIndex+=1
self.logger.info("Generation %s" % self.rowIndex)
antsInCurrentGeneration=[]
scenario_list = [] # for the distributor
# number of ants created per generation
......@@ -190,8 +194,13 @@ class BatchesStochasticACO(BatchesACO):
self.outputSheet.write(self.rowIndex,1,'running deterministic')
self.outputSheet.write(self.rowIndex,2,ant['key'])
self.rowIndex+=1
try:
ant['result'] = self.runOneScenario(ant['input'])['result']
ant['score'] = self._calculateAntScore(ant)
except:
self.logger.info("%s failed" % ant['key'])
ant['result'] = {'result_list': ['fail']}
ant['score'] = 0
ant['evaluationType']='deterministic'
self.outputSheet.write(self.rowIndex,2,'Units Throughput')
self.outputSheet.write(self.rowIndex,3,-ant['score'])
......@@ -220,9 +229,14 @@ class BatchesStochasticACO(BatchesACO):
self.outputSheet.write(self.rowIndex,1,'running stochastic for '+str(numberOfReplicationsInGeneration)+' replications')
self.outputSheet.write(self.rowIndex,2,ant['key'])
self.rowIndex+=1
try:
ant['result'] = self.runOneScenario(ant['input'])['result']
ant['evaluationType']='stochastic'
ant['score'] = self.calculateStochasticAntScore(ant)
except:
self.logger.info("%s failed" % ant['key'])
ant['result'] = {'result_list': ['fail']}
ant['score'] = 0
ant['evaluationType']='stochastic'
self.outputSheet.write(self.rowIndex,2,'Average Units Throughput')
self.outputSheet.write(self.rowIndex,3,-ant['score'])
self.rowIndex+=1
......@@ -281,8 +295,15 @@ class BatchesStochasticACO(BatchesACO):
self.outputSheet.write(self.rowIndex,1,'running stochastic for '+str(numberOfReplicationsInTheEnd)+' replications')
self.outputSheet.write(self.rowIndex,2,ant['key'])
self.rowIndex+=1
try:
ant['result'] = self.runOneScenario(ant['input'])['result']
ant['score'] = self.calculateStochasticAntScore(ant)
except:
self.logger.info("%s failed" % ant['key'])
ant['result'] = {'result_list': ['fail']}
ant['score'] = 0
# ant['result'] = self.runOneScenario(ant['input'])['result']
# ant['score'] = self.calculateStochasticAntScore(ant)
self.outputSheet.write(self.rowIndex,2,'Average Units Throughput')
self.outputSheet.write(self.rowIndex,3,-ant['score'])
self.rowIndex+=1
......
......@@ -347,6 +347,11 @@ class CoreObject(ManPyObject):
# gets an entity from the giver
# =======================================================================
def getEntity(self):
import logging
self.logger = logging.getLogger("dream.platform")
self.logger.info(self.env.now, self.id, 'GETTING!')
# raise ValueError('FOO')
# get active object and its queue, as well as the active (to be) entity
#(after the sorting of the entities in the queue of the giver object)
# activeObject=self.getActiveObject()
......
from dream.simulation.Source import Source
from dream.simulation.Queue import Queue
from dream.simulation.Machine import Machine
from dream.simulation.Exit import Exit
from dream.simulation.Part import Part
from dream.simulation.Globals import runSimulation
from dream.simulation.Globals import G
import random
#the custom machine
class Inspection(Machine):
def selectReceiver(self, possibleReceivers=[]):
# 80% continue, 20% go back to Q1
# XXX Custom implementation hard-coding objects
if random.uniform(0, 1) < 0.8:
return Q2
else:
return Q1
#define the objects of the model
S=Source('S','Source', interArrivalTime={'Fixed':{'mean':0.5}}, entity='Dream.Part')
Q1=Queue('Q','Queue', capacity=float("inf"))
M1=Machine('M1','Milling1', processingTime={'Fixed':{'mean':1}})
QI=Queue('Q','Queue', capacity=float("inf"))
I=Inspection('I','Inspection', processingTime={'Fixed':{'mean':0.2}})
Q2=Queue('Q','Queue', capacity=float("inf"))
M2=Machine('M2','Milling2', processingTime={'Fixed':{'mean':1}})
E=Exit('E1','Exit')
#create the global counter variables
G.NumM1=0
G.NumM2=0
#define predecessors and successors for the objects
S.defineRouting([Q1])
Q1.defineRouting([S, I],[M1])
M1.defineRouting([Q1],[QI])
QI.defineRouting([M1],[I])
I.defineRouting([QI],[Q1, Q2])
Q2.defineRouting([I],[M2])
M2.defineRouting([Q2],[E])
E.defineRouting([M2])
def main(test=0):
# add all the objects in a list
objectList=[S,Q1,M1,QI,I,Q2,M2,E]
# set the length of the experiment
maxSimTime=1440.0
# call the runSimulation giving the objects and the length of the experiment
runSimulation(objectList, maxSimTime)
# calculate metrics
working_ratio_M1=(M1.totalWorkingTime/maxSimTime)*100
working_ratio_M2=(M2.totalWorkingTime/maxSimTime)*100
# return results for the test
if test:
return {"parts": E.numOfExits,
"working_ratio_M1": working_ratio_M1,
"working_ratio_M2": working_ratio_M2,
"NumM1":G.NumM1,
"NumM2":G.NumM2}
#print the results
print "the system produced", E.numOfExits, "parts"
print "the working ratio of", M1.objName, "is", working_ratio_M1, "%"
print "the working ratio of", M2.objName, "is", working_ratio_M2, "%"
if __name__ == '__main__':
main()
......@@ -105,6 +105,10 @@ class Exit(CoreObject):
# gets an entity from the predecessor
# =======================================================================
def getEntity(self):
import logging
self.logger = logging.getLogger("dream.platform")
self.logger.info("!--- %s ----!" % self.env.now)
activeEntity = CoreObject.getEntity(self) #run the default method
# if the entity is in the G.pendingEntities list then remove it from there
from Globals import G
......
......@@ -30,6 +30,7 @@ Models an Interruption that handles the operating of a Station by an ObjectResou
import simpy
from ObjectInterruption import ObjectInterruption
# from SimPy.Simulation import waituntil, now, hold, request, release, waitevent
import logging
# ===========================================================================
# Class that handles the Operator Behavior
......@@ -52,6 +53,7 @@ class Broker(ObjectInterruption):
# flag that shows if broker was called to request or release operator.
# Machine updates this before calling the broker
self.invokeType='request'
self.logger = logging.getLogger("dream.platform")
#===========================================================================
# the initialize method
......@@ -77,8 +79,9 @@ class Broker(ObjectInterruption):
# TODO: add new broker event - brokerIsCalled
self.expectedSignals['isCalled']=1
self.logger.info("!--- %s %s Waiting isCalled1 ----!" % (self.env.now, self.id))
yield self.isCalled
self.logger.info("!--- %s %s Got isCalled1 ----!" % (self.env.now, self.id))
transmitter, eventTime=self.isCalled.value
assert eventTime==self.env.now, 'the broker should be granted control instantly'
self.isCalled=self.env.event()
......@@ -106,8 +109,9 @@ class Broker(ObjectInterruption):
self.victim.printTrace(self.victim.id, waitEvent='(resourceIsAvailable broker)')
self.expectedSignals['resourceAvailable']=1
self.logger.info("!--- %s %s Waiting resourceAvailable ----!" % (self.env.now, self.id))
yield self.resourceAvailable
self.logger.info("!--- %s %s Got resourceAvailable ----!" % (self.env.now, self.id))
transmitter, eventTime=self.resourceAvailable.value
self.resourceAvailable=self.env.event()
......@@ -132,7 +136,10 @@ class Broker(ObjectInterruption):
with self.victim.operatorPool.getResource(self.victim.currentOperator).request() as request:
self.logger.info("!--- %s %s Waiting request ----!" % (self.env.now, self.id))
yield request
self.logger.info("!--- %s %s Got request ----!" % (self.env.now, self.id))
# update the operator workingStation
self.victim.currentOperator.workingStation=self.victim
self.victim.printTrace(self.victim.currentOperator.objName, startWork=self.victim.id)
......@@ -165,7 +172,9 @@ class Broker(ObjectInterruption):
# wait till the processing is over
self.expectedSignals['isCalled']=1
self.logger.info("!--- %s %s Waiting isCalled2 ----!" % (self.env.now, self.id))
yield self.isCalled
self.logger.info("!--- %s %s Got isCalled2 ----!" % (self.env.now, self.id))
transmitter, eventTime=self.isCalled.value
assert eventTime==self.env.now, 'the broker should be granted control instantly'
......
......@@ -87,8 +87,9 @@ class SkilledRouter(Router):
# wait until the router is called
self.expectedSignals['isCalled']=1
self.logger.info("!--- %s %s WAITING isCalled ----!" % (self.env.now, self.id))
yield self.isCalled
self.logger.info("!--- %s %s GOT isCalled ----!" % (self.env.now, self.id))
transmitter, eventTime=self.isCalled.value
self.isCalled=self.env.event()
......@@ -223,8 +224,11 @@ class SkilledRouter(Router):
import time
startLP=time.time()
if LPFlag:
if self.whereToMaxWIP and self.previousSolution:
self.logger.info('---> ' + str(self.env.now))
self.logger.info(self.previousSolution)
self.logger.info(self.availableOperatorList)
if self.whereToMaxWIP and self.previousSolution:
# self.logger.info('---> ' + str(self.env.now))
solution={}
maxWIP=-1
minWIP=float('inf')
......@@ -239,7 +243,7 @@ class SkilledRouter(Router):
# first, find the machine with max wip
for stationId in sorted_station_id_list:
stationDict = self.availableStationsDict.get(stationId, None)
self.logger.info(stationDict)
# self.logger.info(stationDict)
if not stationDict:
continue
wip = stationDict['WIP']
......@@ -250,11 +254,12 @@ class SkilledRouter(Router):
]
assert len(assignedOperatorList) in (0, 1), assignedOperatorList
if not assignedOperatorList:
self.logger.info('%s has no operator' % stationId)
pass
# self.logger.info('%s has no operator' % stationId)
if wip > maxWIP and not assignedOperatorList:
machineWithMaxWIP=stationId
maxWIP = wip
self.logger.info(machineWithMaxWIP)
# self.logger.info(machineWithMaxWIP)
solution={}
# First, search for an operator that was not
# previously assigned, and can handle the maxWIP station
......@@ -398,7 +403,7 @@ class SkilledRouter(Router):
if operatorID in self.previousSolution:
# if the solution returned the operator that is already in the station
# then no signal is needed
if not self.previousSolution[operatorID] == solution[operatorID]:
if not (self.previousSolution[operatorID] == solution[operatorID] and operator == station.currentOperator):
self.toBeSignalled.append(station)
else:
self.toBeSignalled.append(station)
......@@ -413,12 +418,15 @@ class SkilledRouter(Router):
# remove the operator id from availableOperatorList
self.availableOperatorList.remove(operatorID)
#===================================================================
# # XXX signal the stations that the assignment is complete
#===================================================================
# if the operator is free the station can be signalled right away
stationsProcessingLast=[]
toBeSignalled=list(self.toBeSignalled)
self.logger.info("!--- %s toBeSignalled: %s ----!" % (self.env.now, len(toBeSignalled)))
for station in toBeSignalled:
# check if the operator that the station waits for is free
operator=station.operatorToGet
......@@ -438,7 +446,10 @@ class SkilledRouter(Router):
self.expectedFinishSignalsDict[station.id]=signal
self.expectedFinishSignals.append(signal)
while self.expectedFinishSignals:
self.logger.info("!--- %s %s WAITING expectedFinishSignals ----!" % (self.env.now, self.id))
receivedEvent = yield self.env.any_of(self.expectedFinishSignals)
self.logger.info("!--- %s %s GOT expectedFinishSignals ----!" % (self.env.now, self.id))
for signal in self.expectedFinishSignals:
if signal in receivedEvent:
transmitter, eventTime=signal.value
......@@ -488,6 +499,8 @@ class SkilledRouter(Router):
# =======================================================================
def signalStation(self, station, operator):
# signal this station's broker that the resource is available
self.logger.info("!--- %s %s signalStation ----!" % (self.env.now, self.id))
if station.broker.waitForOperator:
if station.broker.expectedSignals['resourceAvailable']:
self.sendSignal(receiver=station.broker, signal=station.broker.resourceAvailable)
......
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