def check(): # Code for checking the results
ans_check = input('Do you want to print the result in dorder they were played or sorted? \n \
[Enter "o" for in order and "s" for sorted]\n')
if ans_check == 'o':
f = open('result.txt','r') # Another way to operate file I/O
result = Queue()
for line in open('result.txt'):
line = line.strip() # To make the output more clear
result.enqueue(line)
while result.size()>1:
print(result.dequeue())
f.close()
if ans_check == 's':
f = open('result.txt','r')
result = [] # Read lines and store it as a list
for line in open('result.txt'):
line = line.strip()
result.append(line)
result.sort() # Sorted
for item in result:
print(item)
f.close()
def send_flowers(name_list, num):
simqueue = Queue()
for name in name_list:
simqueue.enqueue(name)
while simqueue.size() > 1:
for i in range(num):
simqueue.enqueue(simqueue.dequeue())
print(simqueue.dequeue())
return simqueue.dequeue()
def send_flower(name_list, num):
q = Queue()
for name in name_list:
q.enqueue(name)
while q.size() > 1:
for i in range(num):
q.enqueue(q.dequeue())
print(q.dequeue())
return q.dequeue()
def safe_postion(num_soldiers):
queue_sol = Queue() # Declare an Empty Queue
# Adding the list-num_soldiers to Queue using push
for name in num_soldiers:
queue_sol.enqueue(name)
# looping through the soldires and killing the next to it
# list_a =[]
print("Original Circle:%s " % (queue_sol.items))
while queue_sol.size() > 1:
for i in range(1):
k = queue_sol.enqueue(queue_sol.dequeue())
print('-' * 30)
#s = s.join(queue_sol.items)
print("Remaining Soldier:", "".join(queue_sol.items))
#print("Remaining Soldier:%s" % (queue_sol.items))
print('-' * 30)
#print('%s Kills: '%(queue_sol.items[0]))
n = queue_sol.dequeue()
print(queue_sol.items[0] + ' Kills: ' + n)
time.sleep(1)
return queue_sol.dequeue()
def HotPotato(namelist,num):
simqueue=Queue()
for name in namelist:
simqueue.enqueue(name)
while simqueue.size()>1:
for i in range(num):
simqueue.enqueue(simqueue.dequeue())
simqueue.dequeue()
return simqueue.dequeue
def hotPotato(namelist, num):
q = Queue()
for name in namelist:
q.enqueue(name)
while q.size() > 1:
for i in range(num):
q.enqueue(q.dequeue())
q.dequeue()
return q.dequeue()
def hotPotato(namelist, num):
simqueue = Queue()
for name in namelist:
simqueue.enqueue(name)
while simqueue.size() > 1:
for i in range(num):
simqueue.enqueue(simqueue.dequeue())
simqueue.dequeue()
return simqueue.dequeue()
def hotPotato(namelist, num):
simqueue = Queue()
for name in namelist:
simqueue.enqueue(name)
while simqueue.size() > 1:
for i in range(1, num):
simqueue.enqueue(simqueue.dequeue())
temp = simqueue.dequeue()
print(temp + "*" * 10)
return simqueue.dequeue()
def __init__(self):
# 创建一个队列用来保存进程获取到的数据
self.q = Queue()
self.headers = {
'Cookie':
'll="118282"; bid=ctyiEarSLfw; ps=y; __yadk_uid=0Sr85yZ9d4bEeLKhv4w3695OFOPoedzC; dbcl2="155150959:OEu4dds1G1o"; as="https://sec.douban.com/b?r=https%3A%2F%2Fbook.douban.com%2F"; ck=fTrQ; _pk_id.100001.4cf6=c86baf05e448fb8d.1506160776.3.1507290432.1507283501.; _pk_ses.100001.4cf6=*; __utma=30149280.1633528206.1506160772.1507283346.1507290433.3; __utmb=30149280.0.10.1507290433; __utmc=30149280; __utmz=30149280.1506160772.1.1.utmcsr=(direct)|utmccn=(direct)|utmcmd=(none); __utma=223695111.1475767059.1506160772.1507283346.1507290433.3; __utmb=223695111.0.10.1507290433; __utmc=223695111; __utmz=223695111.1506160772.1.1.utmcsr=(direct)|utmccn=(direct)|utmcmd=(none); push_noty_num=0; push_doumail_num=0',
'Host':
'movie.douban.com',
'Referer':
'https://movie.douban.com/top250?start=225&filter=',
'User-Agent':
'Mozilla/5.0 (Windows NT 10.0; WOW64) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/59.0.3071.104 Safari/537.36',
}
def hotpotato(namelist, num):
simqueue = Queue()
for name in namelist:
simqueue.enqueue(name)
while simqueue.size() > 1:
for i in range(num):
simqueue.enqueue(simqueue.dequeue())
aa = simqueue.dequeue()
print(aa)
return simqueue.dequeue()
def hotpotato(nameList, num):
q = Queue()
for i in nameList:
q.enqueue(i)
while q.size() > 1:
for _ in range(num):
v = q.dequeue()
q.enqueue(v)
print(q.dequeue())
print(f"the last one is: {q.dequeue()}")
def hot_pot(names, num):
# create a Queue
q = Queue()
_ = [q.enqueue(i) for i in names]
count = 0
while q.size()!=1:
while count !=num:
q.enqueue(q.dequeue())
count +=1
q.dequeue()
return q.dequeue()
def hotPotato(namelist,num): s = Queue() for one in namelist: s.enqueue(one) while s.size() > 1: for i in range(num): tmp = s.dequeue() s.enqueue(tmp) tmp = s.dequeue() return s.dequeue()
def HotPotato(namelist: List[str], repetitions: int) -> List[str]:
queue = Queue()
for name in namelist:
queue.enqueue(name)
for rep in range(repetitions):
person = queue.dequeue()
queue.enqueue(person)
return queue.dequeue()
def simulation(numSeconds, pagesPerMinute):
# create a new printer object
labprinter = Printer(pagesPerMinute)
# create a queue object
printQueue = Queue()
# create a list type of object, for storing all waiting times for each task
waitingtimes = []
# unit is based on second, and numSeconds is the total time
# for simulation, create a loop for simulation
for currentSecond in range(numSeconds):
# newprinttaask decides whether we want to create a new task
# see detail in newPrintTask function defined later
if newPrintTask():
task = Task(currentSecond)
# if there is a new task, put that new task to
# the end of the queue
printQueue.enqueue(task)
if (not labprinter.busy()) and (not printQueue.isEmpty()):
# when printer is not busy or queue is empty
# start to process next task from the top of the task queue
nexttask = printQueue.dequeue()
# meanwhile add the waiting time to the end of the time lise
waitingtimes.append(nexttask.waitTime(currentSecond))
# then start the next task pop out from the queue
labprinter.startNext(nexttask)
# keep counting the time till the end of the task
labprinter.tick()
averageWait = sum(waitingtimes) / len(waitingtimes)
print("Average Wait %6.2f secs %3d tasks remaining." %
(averageWait, printQueue.size()))
def murderPossibility(band, enemy, enemyX, enemyY, enemyId, enemyDirection,
me, meId, distance):
searchGrid = {
0: [(1, 0, 0), (0, -1, 3), (0, 1, 1)],
1: [(0, 1, 1), (1, 0, 0), (-1, 0, 2)],
2: [(-1, 0, 2), (0, 1, 1), (0, -1, 3)],
3: [(0, -1, 3), (1, 0, 0), (-1, 0, 2)]
}
searchList = [(enemyX, enemyY)]
searchQueue = Queue()
searchQueue.enqueue((enemyX, enemyY, 0, enemyDirection))
while True:
currentPosition = searchQueue.dequeue()
currentX = currentPosition[0]
currentY = currentPosition[1]
currentStep = currentPosition[2]
currentDirection = currentPosition[3]
if currentStep >= distance + 5:
return False
step = currentStep + 1
for coordinate in searchGrid[currentDirection]:
horizon = currentX + coordinate[0]
vertical = currentY + coordinate[1]
newDirection = coordinate[2]
if horizon >= 0 and horizon <= 100 and vertical >= 0 and vertical <= 101:
if band[horizon][vertical] == meId and step < distance + 5:
return True
elif band[horizon][vertical] != enemyId and (
(horizon, vertical) not in searchList):
searchQueue.enqueue(
(horizon, vertical, step, newDirection))
searchList.append((horizon, vertical))
def simulation(numSeconds, pagesPerMinute):
"""
Simulate the printing tasks managed by the shared printer in a computer
science lab.
:param numSeconds: the total time for the printer to run
:param pagesPerMinute: the printing speed of the printer
"""
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 pig_latin_converter(word):
if type(word) != str:
raise TypeError('Argument should be a string')
my_simulation = Queue()
to_lower = word.lower()
modified = list(to_lower)
pos = 0
found = True
if modified[0] in ['a', 'e', 'i', 'o', 'u']:
return word + 'way'
else:
while pos <= len(word) and found:
if modified[pos] in ['a', 'e', 'i', 'o', 'u']:
found = False
else:
my_simulation.enqueue(modified[pos])
pos += 1
rounds = my_simulation.size()
simulator_stack = Stack()
for i in modified:
simulator_stack.push(i)
diff = len(word) - rounds
fixed = []
for j in range(diff):
fixed.append(simulator_stack.pop())
fixed.reverse()
final_word = ''
to_fix_with = []
while not my_simulation.isEmpty():
to_fix_with.append(my_simulation.dequeue())
final_word = ''.join(fixed) + ''.join(to_fix_with) + 'ay'
return final_word
class Printer():
def __init__(self):
self.printQueue = Queue()
self.currentTask = None
def isBusy(self):
return self.currentTask == None
def addTask(self, task):
self.printQueue.enqueue(task)
def removeTask(self):
self.currentTask = None
def getNextTask(self):
if self.printQueue.isEmpty():
self.currentTask = None
else:
self.currentTask = self.printQueue.dequeue()
def printTask(self):
if self.currentTask != None:
self.currentTask.removePage()
if self.currentTask.isDone():
self.currentTask = None
if self.currentTask == None and not self.printQueue.isEmpty():
self.currentTask = self.printQueue.dequeue()
waitTimes.append(time - self.currentTask.startTime)
def bfs(g, start):
start.setDistance(0)
start.setPred(None)
vertQueue = Queue()
vertQueue.enqueue(start)
while (vertQueue.size() > 0):
currentVert = vertQueue.dequeue()
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 hotPotato(namelist, num):
simqueue = Queue() #create a new queue
for name in namelist:
simqueue.enqueue(name)
while simqueue.size() > 1 :
for i in range(num):
simqueue.enqueue(simqueue.dequeue()) #the first in queue leaves the queue and enters again.
#simqueue.dequeue()
break
return simqueue.dequeue()
def bfs(g, start):
start.setDistance(0)
start.setPred(None)
vertQueue = Queue()
vertQueue.enqueue(start)
while (vertQueue.size() > 0):
currentVert = vertQueue.dequeue()
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 BFS(g,start): # 给定一幅图g和一个起始节点start,在广度优先搜索过程中遍历图中所有结点,并标记它们的距离,前驱和颜色
start.setDistance(0)#设置start结点的距离为0
start.setPred(None)#设置start结点的前驱为None
VertQueue=Queue()#创建一个队列用于按保存待搜索结点
VertQueue.enqueue(start)#将start结点入队
#循环遍历所有入队的结点
while (VertQueue.size()>0):
CurrentVert=VertQueue.dequeue()
# 遍历当前搜索结点的所有邻居
for nbr in CurrentVert.getConnections(): #.getConnections方法返回CurrentVert的所有邻居结点
#若该邻居的颜色为白色,则其从未被搜索,对其执行入队,染色,设定距离和前驱的操作
if (nbr.getColor()=='white'):
nbr.setColor('grey')
nbr.setDistance(CurrentVert.getDistance()+1)
nbr.setPred(CurrentVert)
VertQueue.enqueue(nbr)
#直至CurrentVert的结点被遍历完毕,代表其邻居结点已被完全搜索,将其颜色设为黑色
CurrentVert.setColor('black')
def simulation(numSeconds, ppm):
labprinter = Printer(ppm)
printq = Queue()
waitingtime = []
for i in range(numSeconds):
if newtask():
task = Task(i)
printq.enqueue(task)
if (not labprinter.busy()) and (not printq.isEmpty()):
nextprint = printq.dequeue()
waitingtime.append(nextprint.waittime(i))
labprinter.startnew(nextprint)
labprinter.tick()
averagewaittime = sum(waitingtime) / len(waitingtime)
print('Average wait time %6.2f secs and %3d tasks remaining.' %
(averagewaittime, printq.size()))
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.setStart(nexttask)
labprinter.tick()
averageWait = sum(waitingtimes) / len(waitingtimes)
print("Average Wait %6.2f secs %3d tasks remaining." %
(averageWait, printQueue.size()))
def simulation(num_seconds, ppm):
lab_printer = Printer(ppm)
print_queue = Queue()
waiting_times = []
for current_second in range(num_seconds):
if new_print_task():
task = Task(current_second)
print_queue.enqueue(task)
if (not lab_printer.busy()) and (not print_queue.isEmpty()):
next_task = print_queue.dequeue()
waiting_times.append(next_task.wait_time(current_second))
lab_printer.start_next(next_task)
lab_printer.tick()
average_wait = sum(waiting_times) / len(waiting_times)
print('Average wait %6.2f secs %3d tasks remaining.' %
(average_wait, print_queue.size()))
def main(numSeconds,pagesPerMinute):
labPrinter = Printer(pagesPerMinute)
printQueue = Queue()
watingtimes = []
for currentSeconds in range(numSeconds):
if newPrintTask():
task = Task(currentSeconds)
printQueue.enqueue(task)
if(not labPrinter.is_busy()) and (not printQueue.isEmpty()):
nexttask = printQueue.dequeue()
watingtimes.append(nexttask.waitTime(currentSeconds))
labPrinter.startNew(nexttask)
labPrinter.tick()
averageWait = sum(watingtimes)/len(watingtimes)
print('平均等待%6.2f秒 还剩%3d任务'%(averageWait,printQueue.size()))
def simulation(timeSpanSeconds, pagerate, studentnum, pages_per_task):
labprinter = Printer(pagerate)
waitQueue = Queue()
waitTimes = []
for nth_second in range(timeSpanSeconds):
if nextTask(studentnum):
task = Task(nth_second, pages_per_task)
waitQueue.enqueue(task)
if (not labprinter.busy()) and (not waitQueue.isEmpty()):
newtask = waitQueue.dequeue()
waitTimes.append(newtask.waitTime(nth_second))
labprinter.setNextTask(newtask)
labprinter.tick()
average_wait_time = sum(waitTimes) / len(waitTimes)
print("Average wait time = {:.4f}, tasks remaining = {:d}".format(
average_wait_time, waitQueue.size()))
return average_wait_time
def simulation(number_second, pages_per_minute):
lab_printer = Printer(pages_per_minute)
print_queue = Queue()
wait_times = []
for current_second in range(number_second):
if new_print_task():
task = Task(current_second)
print_queue.enqueue(task)
if (not lab_printer.busy()) and (not print_queue.isEmpty()):
next_task = print_queue.dequeue()
wait_times.append(next_task.wait_time(current_second))
lab_printer.start_next(next_task)
lab_printer.tick()
average_wait = sum(wait_times) / len(wait_times)
print("Average Wait %6.2f secs %3d task remaining." % (average_wait, print_queue.size()))
def printer_simulator(num_sec, pages_per_min):
printer = Printer(pages_per_min)
wait_time_list = []
print_queue = Queue()
for sec in range(num_sec):
if new_task():
task = Task(sec)
print_queue.enqueue(task)
if (not printer.is_busy()) and (not print_queue.isEmpty()):
next_task = print_queue.dequeue()
wait_time_list.append(sec - next_task.get_timestamp())
printer.next_task(next_task)
printer.tick()
average_wait_time = sum(wait_time_list) / len(wait_time_list)
print('average: {aver}; waiting task: {tasks}'.format(
aver=average_wait_time, tasks=print_queue.size()))
def simulation(speed, totaltime):
l = Line(speed)
cartQueue = Queue()
waitTimes = []
for i in range(totaltime):
if newCart():
c = Cart(i)
cartQueue.enqueue(c)
if (not l.busy()) and (not cartQueue.isEmpty()):
cart = cartQueue.dequeue()
waitTimes.append(cart.waitTime(i))
l.startNext(cart)
l.tick()
avgWait = sum(waitTimes) / len(waitTimes)
print(
"Average wait time for each cart is %6.2f secs, %3d tasks remaining" %
(avgWait, cartQueue.size()))
def simulation(numberSeconds, ppm):
printer = Printer(ppm=ppm)
tasks = Queue()
waitingList = []
for currentTime in range(numberSeconds):
if printer.isBusy():
printer.tick()
else:
if not tasks.isEmpty():
newTask = tasks.dequeue()
printer.startNext(newTask)
waitingList.append(newTask.waitTime(currentTime))
if random.randint(1, 180) == 180:
task = Task(currentTime)
tasks.enqueue(task)
print(sum(waitingList) * 1.0 / len(waitingList))
def simulation(numSeconds, pagesPerMinute):
labprinter = Printer(pagesPerMinute) #初始化打印机
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("平均等待时间为:%6.2f" % averageWait)
def simulateOneServer(file):
"""function to handle requests using one server"""
global averageWait
content = urllib.request.urlopen(file).read().decode(
"ascii", "ignore") # fetch contents
data = StringIO(content)
# read csv file
csv_reader = csv.reader(data, delimiter=',')
dataList = [] # store data from csv
for line in csv_reader:
# Use list to store data
dataList.append(line)
requestQueue = Queue() # queue tor requests
waitingtimes = [
] # list to store's that are waiting before a request is processed
server = Server() # instantiate server class
# listlength=len(dataList)-1
for i in dataList:
# iterated the requests
request = Request(i) # pass data to request class
requestQueue.enqueue(request) # enqueue the request object
if (not requestQueue.isEmpty()) and (not server.busy(
)): # if server is not busy and queue is not empty
nexttask = requestQueue.dequeue() # dequeue first item in queue
waitingtimes.append(nexttask.waitTime(int(
i[0]))) # append to waiting time to list
server.startNext(
nexttask) # if server is free move to the next task
server.tick() # server timer
averageWait = sum(waitingtimes) / len(
waitingtimes) # calculate average wait time
print("Average Wait %6.2f secs %3d tasks remaining." %
(averageWait,
requestQueue.size())) # similar to pritning example in notes
print("Average latency is {} seconds".format(averageWait))
return averageWait # return latency
def simulation(num_seconds, page_rate):
labPrinter = Printer(page_rate)
printerQueue = Queue()
waitingTime = []
pages_number = 20
students_number = 10
for second in range(num_seconds):
if newPrintTask(students_number):
task = Task(second, pages_number)
printerQueue.enqueue(task)
if (not labPrinter.busy()) and (not printerQueue.isEmpty()):
nextTask = printerQueue.dequeue()
waitingTime.append(nextTask.waitingTime(second))
labPrinter.startNext(nextTask)
labPrinter.tick()
averageWait = sum(waitingTime) / len(waitingTime)
print("Average Wait %6.2f secs %3d tasks remaining." % (averageWait, printerQueue.size()))
def simulation(numSeconds, pagesPerMinute, stud):
labprinter = Printer(pagesPerMinute)
printQueue = Queue()
waitingtimes = []
for currentSecond in range(numSeconds):
if newPrintTask(stud):
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 %2.2f secs %2d tasks remaining.' % (averageWait, printQueue.size()))
f=open('url_queue.txt','r')
start_url = f.readlines()
f.close()
#start_url = 'https://www.zomato.com/users/rajdeep-biswas-4638621'
#Path to the Directory for the data to be dumped
path = 'C:\Users\shoaib khan\Desktop\Tomato\Maps.Google.Com\Trajectory Mining\TryingNew\dust_bin'
'''#Declaring Driver
driver = webdriver.Chrome(chromedriver)
#Defining Wait time over driver
wait = WebDriverWait(driver,30)'''
#Declaring the URL Queue
url_q = Queue()
users_crawled = []
def define_driver():
#Declaring Driver
driver = webdriver.Chrome(chromedriver)
#Defining Wait time over driver
wait = WebDriverWait(driver,30)
return driver,wait
def driver_get(driver,url):
try:
driver.get(url)
