def test_queues(self):
q = Queue()
for i in range(1,100):
q.push(i)
self.assertEqual(99,q.size())
self.assertEqual(1,q.peek())
self.assertEqual(1,q.pop())
def Algorithm1(G, basesore, sourceList):
n = 0
SG = nx.MultiGraph()
simqueue = Queue()
for i in range(len(sourceList)):
simqueue.enqueue(sourceList[i])
# while(not(simqueue.empty())):
while (n < 100 and simqueue.size() < 98):
# print ("这次感染队列列表有个感染点")
# print (simqueue.size())
sourceItem_ = simqueue.dequeue()
SG.add_node(sourceItem_)
for sourceNeightor in list(G.neighbors(sourceItem_)):
if G.node[sourceNeightor]['Cn'] == 0:
G.node[sourceNeightor]['Scn'] += G.nodes[sourceItem_]['Scn']
G.add_node(sourceNeightor, Cn=1)
SG.add_node(sourceNeightor)
SG.add_edge(sourceItem_, sourceNeightor)
simqueue.enqueue(sourceNeightor)
n += 1
#对所有n<V(就是分数达到阕值的节点感染)算是谣言的不同之处吧。更新。
for index in range(1, 35):
if G.node[index]['Scn'] > basesore:
G.add_node(index, Cn=1)
return G, SG
class TestQueues(unittest.TestCase):
def setUp(self):
self.Q = Queue(N=5)
def test_setup(self):
"Test for Empty Queue"
self.assertEqual(self.Q.size(), 0)
self.assertTrue(self.Q.isEmpty())
self.assertFalse(self.Q.isFull())
with self.assertRaises(EmptyQueueException) as cm:
self.Q.dequeue()
expected_msg = "Queue is empty"
self.assertEquals(cm.exception.message, expected_msg)
with self.assertRaises(EmptyQueueException) as cm:
self.Q.front()
expected_msg = "Queue is empty"
self.assertEquals(cm.exception.message, expected_msg)
def test_enqueue_dequeue(self):
self.Q.enqueue('A')
self.Q.enqueue('B')
self.assertEqual(self.Q.size(), 2)
self.assertFalse(self.Q.isEmpty())
self.assertFalse(self.Q.isFull())
self.Q.enqueue('C')
self.Q.enqueue('D')
self.Q.enqueue('E')
self.assertFalse(self.Q.isEmpty())
self.assertTrue(self.Q.isFull())
self.assertEqual(self.Q.front(), 'A')
with self.assertRaises(FullQueueException) as cm:
self.Q.enqueue('F')
expected_msg = "Queue is full"
self.assertEquals(cm.exception.message, expected_msg)
self.assertEqual(self.Q.size(), 5)
self.Q.dequeue()
self.assertEqual(self.Q.size(), 4)
self.assertFalse(self.Q.isEmpty())
self.assertFalse(self.Q.isFull())
self.Q.enqueue('G')
self.assertEqual(self.Q.front(), 'B')
self.assertEqual(self.Q.size(), 5)
self.Q.dequeue()
self.Q.dequeue()
self.Q.dequeue()
self.Q.dequeue()
self.assertEqual(self.Q.size(), 1)
self.assertEqual(self.Q.front(), 'G')
self.assertFalse(self.Q.isEmpty())
self.assertFalse(self.Q.isFull())
self.Q.dequeue()
self.assertEqual(self.Q.size(), 0)
with self.assertRaises(EmptyQueueException) as cm:
self.Q.dequeue()
expected_msg = "Queue is empty"
self.assertEquals(cm.exception.message, expected_msg)
self.assertTrue(self.Q.isEmpty())
self.assertFalse(self.Q.isFull())
def josephus(nameList, count):
q = Queue()
for name in nameList:
q.enqueue(name)
while q.size() > 1:
for j in range(count + 1):
out = q.dequeue()
if j != count:
q.enqueue(out)
return q.dequeue()
def breadth_first_search(self, starting_vert):
to_visit = Queue()
visited = set()
to_visit.enqueue(starting_vert)
visited.add(starting_vert)
while to_visit.size() > 0:
current_vert = to_visit.dequeue()
for next_vert in current_vert.get_connections():
if next_vert not in visited:
visited.add(next_vert)
to_visit.enqueue(next_vert)
def bfs(g,start):
"""Breadth First Search from start vertex"""
start.setDistance(0)
start.setPred(None)
# start at the front of the queue
vertQueue = Queue()
vertQueue.enqueue(start)
while (vertQueue.size() > 0):
# explore vertices at the front of the queue
currentVert = vertQueue.dequeue()
# all adjacent vertices of currentVert
for nbr in currentVert.getConnections():
if (nbr.getColor() == 'white'):
nbr.setColor('gray')
nbr.setDistance(currentVert.getDistance() + 1)
nbr.setPred(currentVert)
vertQueue.enqueue(nbr)
currentVert.setColor('black')
def _findPathInResidualNetwork(self, s, t, path=[]):
"""find a path as list from s to t in residual network based on Breadth First Search"""
self._initializeColorDistanceParent(s)
queue = Queue()
queue.enqueue(s)
while (queue.size() > 0):
u = queue.dequeue()
for edge in self.adj[u]:
v = edge.getDestination()
if self.color[v] == WHITE:
residualCapacity = edge.getCapacity() - self.flow[edge.getEndPoints()]
if residualCapacity > 0:
self.color[v] = GREY
self.distance[v] = self.distance[u] + 1
self.parentEdge[v] = (edge, residualCapacity)
queue.enqueue(v)
self.color[u] = BLACK
# build improving path
return self._buildImprovingPath(s,t)
def simulation(numSeconds, pagesPerMinute):
labprinter = Printer(pagesPerMinute)
printQueue = Queue()
waitingtimes = []
for currentSecond in range(numSeconds):
if newPrintTask():
task = Task(currentSecond)
printQueue.enQueue(task)
if (not labprinter.busy()) and (not printQueue.isEmpty()):
nexttask = printQueue.deQueue()
waitingtimes.append( nexttask.waitTime(currentSecond))
labprinter.startNext(nexttask)
labprinter.tick()
averageWait=sum(waitingtimes)/len(waitingtimes)
print("Average Wait %6.2f secs %3d tasks remaining."%(averageWait,printQueue.size()))
def waitTime(numStudents=10, pagePerMin=10):
from random import randint
from queues import Queue
numOfPrints = 0
#each student prints 1-2 times
for student in range(numStudents):
numOfPrints += randint(0,2)
## print(numOfPrints)
pageList = []
#1-20 pages per print
for i in range(numOfPrints):
pageList.append(randint(1, 20))
## print(pageList)
timePerPage = 1 * 60 / pagePerMin
enterTimeList = []
#3600 seconds in an hour, make a random list of time each print enters
for i in range(numOfPrints):
enterTimeList.append(randint(0,3599))
enterTimeList.sort()
## print(enterTimeList)
listToQueue = zip(enterTimeList, pageList)
printQueue = Queue()
for item in listToQueue:
printQueue.enqueue(item)
lastEndTime = 0
totalWaitTime = 0
while printQueue.size():
aPrint = printQueue.dequeue()
thisEnterTime = aPrint[0]
thisPrintDur = aPrint[1] * timePerPage
endStartDiff = lastEndTime - thisEnterTime
endStartDiff = endStartDiff if endStartDiff > 0 else 0
thisStartTime = thisEnterTime + endStartDiff
thisEndTime = thisStartTime + thisPrintDur
totalWaitTime += (thisEndTime - thisEnterTime)
lastEndTime = thisEndTime
## print('thisEnterTime: {}, thisPrintDur: {}, endStartDiff: {}, thisStartTime: {}, thisEndTime: {}, totalWaitTime: {}'.format(thisEnterTime, thisPrintDur, endStartDiff, thisStartTime, thisEndTime, totalWaitTime))
return totalWaitTime / numOfPrints
def test_size(self):
q = Queue()
assert q.size() == 0
q.enqueue('Python')
q.enqueue('Java')
assert q.size() == 2