def get_coordinate_free(self):
while True:
x = int(int(quantumrandom.randint(0, self.size)))
y = int(int(quantumrandom.randint(0, self.size)))
print("{} - {}; {} - {}".format(x, type(x), y, type(y)))
if self.get_value((x, y)) == 0:
return (x, y)
def main():
usage = "Usage: %s [--binary|--hex|--int --min MIN --max MAX]" % \
sys.argv[0]
generator = None
# TODO -- use argparse here
if '--binary' in sys.argv or '-b' in sys.argv:
generator = quantumrandom.binary
if '--hex' in sys.argv or '-h' in sys.argv:
generator = quantumrandom.hex
if '--int' in sys.argv or '-i' in sys.argv:
# Special case. Just print one.
try:
min = int(sys.argv[sys.argv.index('--min') + 1])
max = int(sys.argv[sys.argv.index('--max') + 1])
except ValueError:
print usage
sys.exit(1)
print quantumrandom.randint(min=min, max=max)
sys.exit(0)
if not generator:
print usage
sys.exit(1)
try:
while True:
print generator(),
except:
pass
def setdDefault(self):
self.P1Strat = 0
self.P2Strat = 0
self.Min = 0;
self.Max = 0;
self.Weight = quantumrandom.randint(0, 6)
self.Probability = float(quantumrandom.randint(0, 10) / 10)
def main():
usage = "Usage: %s [--binary|--hex|--int --min MIN --max MAX]" % \
sys.argv[0]
generator = None
# TODO -- use argparse here
if '--binary' in sys.argv or '-b' in sys.argv:
generator = quantumrandom.binary
if '--hex' in sys.argv or '-h' in sys.argv:
generator = quantumrandom.hex
if '--int' in sys.argv or '-i' in sys.argv:
# Special case. Just print one.
try:
min = int(sys.argv[sys.argv.index('--min')+1])
max = int(sys.argv[sys.argv.index('--max')+1])
except ValueError:
print usage
sys.exit(1)
print quantumrandom.randint(min=min, max=max)
sys.exit(0)
if not generator:
print usage
sys.exit(1)
try:
while True:
print generator(),
except:
pass
async def random(ctx, nb1=None, nb2=None):
if nb1 is None:
random_number = round(quantumrandom.randint(0, 100))
await ctx.send("```" + str(random_number) + "```")
else:
if nb1.isdecimal() & nb2.isdecimal():
random_number = round(quantumrandom.randint(int(nb1), int(nb2)))
await ctx.send("```" + str(random_number) + "```")
else:
await ctx.send("```Those are not numbers```")
def quantum_d10(number_of_dice: int):
'''
Uses quantum number generation to produce a series of truly random numbers between 1-10.
Based off the quantumrandom module, this is true RNG, not pseudo-RNG.
'''
remove_decimal = [x for x in str(quantumrandom.randint()) if x != '.']
while len(remove_decimal) < number_of_dice:
for y in range(round(number_of_dice / 10)):
remove_decimal = remove_decimal + [
x for x in str(quantumrandom.randint()) if x != '.'
]
list_of_numbers = [int(y) if y != '0' else 10 for y in remove_decimal]
return [list_of_numbers[y] for y in range(number_of_dice)]
def get_sample(dist_type):
""" 퀀텀 난수를 가지는 2차원 배열을 반환한다 """
if dist_type == 'poisson' or dist_type == 'expon':
random_number = np.zeros((const.EXPERIMENTS, const.SAMPLES))
cached_generator = qt.cached_generator(
) # chached_generator를 생성하면 서버 딜레이를 회피할 수 있다
for i in range(const.EXPERIMENTS):
for j in range(const.SAMPLES):
random_number[i][j] = qt.randfloat(
0, 1,
cached_generator) # cached_generator로 0에서 1사이의 값을 생성한다
elif dist_type == 'binomial':
random_number = np.zeros((const.EXPERIMENTS, const.SAMPLES))
cached_generator = qt.cached_generator(
) # chached_generator를 생성하면 서버 딜레이를 회피할 수 있다
for i in range(const.EXPERIMENTS):
for j in range(const.SAMPLES):
random_number[i][j] = math.floor(
qt.randint(0, 10, cached_generator)
) # 홀수인 경우는 1, 3, 5, 7, 9, 짝수인 경우는 0, 2, 4, 6, 8이 된다
else:
raise Exception(
"Invalid distribution type. Allowed types are 'poisson', 'expon', 'binomial'."
)
return random_number
def bok(bot, update):
gwa = int(quantumrandom.randint(1, 64))
print('new command from:', update.message.from_user.username)
# url_prefix = 'http://www.eee-learning.com/eeeApp/'
# full_url = url_prefix + str(gwa) + '.html'
# print(full_url)
gwa_img = 'gwa_img/' + str(gwa) + '.gif'
gwa_illustrate = 'gwa_illustrate/' + str(gwa) + '.jpg'
gwa_index = gwa - 1
gwa_title = all_gwas[gwa_index]['title']
gwa_digest = all_gwas[gwa_index]['digest']
gwa_article = all_gwas[gwa_index]['article']
print(gwa_illustrate)
print(gwa_img)
print(gwa_title)
print(gwa_digest)
print(gwa_article)
bot.send_chat_action(chat_id=update.message.chat_id, action='typing')
update.message.reply_photo(photo=open(gwa_img, 'rb'), caption=gwa_title)
bot.send_chat_action(chat_id=update.message.chat_id, action='typing')
update.message.reply_photo(photo=open(gwa_illustrate, 'rb'),
caption=gwa_digest)
bot.send_chat_action(chat_id=update.message.chat_id, action='typing')
update.message.reply_text(gwa_article)
def selection_from_collection(Card_Set, Card_Subset):
Cardinality = Card_Set
Cardinality_Subset = Card_Subset
universe = []
sample = []
#dice = 0
#element = 0
# New Universe.
for i in range(1, Cardinality + 1):
universe.append(i)
for i in range(1, Cardinality_Subset + 1):
Cardinality = len(universe)
print("Universum (Cardinality = ", Cardinality, "):")
#print(universe)
#print("Card of Universum = ", Cardinality)
dice = round(quantumrandom.randint(1, Cardinality))
element = universe[dice - 1]
sample.append(element)
print("====|||| Dice = ", dice, " |||| Element selected {", element,
"}")
#print("Element selected {", element, "}")
del universe[dice - 1]
print("Universe after {", element, "} selected:")
print(universe)
sample.sort()
#print("Sample:")
return sample
def loc(c: Client, m: Message):
m.reply_chat_action('find_location')
user = m.from_user
u = get_user(user)
loc: Location = m.location
p = Point(loc.latitude, loc.longitude)
try:
d = qr.randint(500, u.distance) / 1000
angle = qr.randint(0, 360)
np = distance.distance(d).destination(p, angle)
m.reply_location(np.latitude, np.longitude)
c.send_message(m.from_user.id, 'В добрый путь!')
update_points_count(user)
except Exception as e:
m.reply('Error =(\n%s' % e)
async def gostosa(self, ctx):
role = discord.utils.get(ctx.guild.roles, name="webnamorada")
gostosas = list()
for m in role.members:
if m.id != 552595247809429546 and m.id != 525447699579797505 and m.id != 238803776507478017 and m.id != 523626016145539073 and m.id != 304873309164535808 and m.id != 323236550555074562 and m.id != 361181769380397058:
gostosas.append(m)
random.shuffle(gostosas)
gostosa = gostosas[self.random]
membro = busca_gostosa(gostosa.id)
if (membro):
update_gostosa(gostosa.id, membro[1] + 1)
else:
insert_gostosa(gostosa.id)
role_burro = discord.utils.get(ctx.guild.roles, name="Burro")
if (role_burro in gostosa.roles):
response = requests.get(
'https://media.discordapp.net/attachments/223594824681521152/707385777037901944/EQH1UEyWoAEW1jn.png'
)
img = BytesIO(response.content)
file = discord.File(img, filename='burra_e_gostosa.png')
await ctx.send(content='<@{}> gostosa'.format(gostosa.id),
file=file)
self.random = int(quantumrandom.randint(0, len(gostosas) - 1))
else:
await ctx.send('<@{}> gostosa'.format(gostosa.id))
def true_random_roll(num_dice: int, num_sides=10):
'''Uses quantum number generation to produce a series of truly random numbers, not pseudo-RNG. \n\nBe warned: this function is EXTREMELY slow.'''
num_dice = int(num_dice)
num_sides = int(num_sides)
return [
int(quantumrandom.randint(1, num_sides + 1)) for r in range(num_dice)
]
async def get_random(self):
guild = self.bot.get_guild(223594824681521152)
role = discord.utils.get(guild.roles, name="webnamorada")
gostosas = list()
for m in role.members:
if m.id != 552595247809429546 and m.id != 525447699579797505 and m.id != 238803776507478017 and m.id != 523626016145539073 and m.id != 304873309164535808 and m.id != 323236550555074562 and m.id != 361181769380397058:
gostosas.append(m)
self.random = int(quantumrandom.randint(0, len(gostosas)))
def setIterationNumber():
text = pmt.getMaxGamesText()
for x in text:
print(x)
n_max = validateInput()
n = int(quantumrandom.randint(1, n_max))
print("\nLooks like you're playing " + str(n) + " games.\n")
return n
def go(ev=None):
# time.sleep(20)
# try:
global status
status = not status
file = open("numbers.txt", "r")
#print(file.read())
num = int(float(file.read()))
file.close()
# print(num)
num = num * 2
file = open("numbers.txt", "w")
file.write('%d' % num)
file.close()
x = int(quantumrandom.randint(0, 2))
# print(x)
if (x == 0):
print('Red ')
#Turn on LED
GPIO.output(LedPin, GPIO.LOW)
time.sleep(2)
GPIO.output(LedPin, GPIO.HIGH)
else:
GPIO.output(LedPinGreen, GPIO.LOW)
print('Green')
time.sleep(2)
GPIO.output(LedPinGreen, GPIO.HIGH)
#lighting up counter
timeout = time.time() + 15
while (True):
clearDisplay()
pickDigit(0)
hc595_shift(number[num % 10])
clearDisplay()
pickDigit(1)
hc595_shift(number[num % 100 // 10])
clearDisplay()
pickDigit(2)
hc595_shift(number[num % 1000 // 100])
clearDisplay()
pickDigit(3)
hc595_shift(number[num % 10000 // 1000])
if time.time() > timeout:
break
print('LED OFF....')
time.sleep(0.5)
def main():
usage = ("Usage: %s [--binary|--hex|--int --min MIN --max MAX]" + \
" [--count BLOCKS]") % sys.argv[0]
generator = None
# TODO -- use argparse here
if '--binary' in sys.argv or '-b' in sys.argv:
generator = quantumrandom.binary
if '--hex' in sys.argv or '-h' in sys.argv:
generator = quantumrandom.hex
if '--int' in sys.argv or '-i' in sys.argv:
# Special case. Just print one.
try:
min = int(sys.argv[sys.argv.index('--min')+1])
max = int(sys.argv[sys.argv.index('--max')+1])
except ValueError:
print usage
sys.exit(1)
print quantumrandom.randint(min=min, max=max)
sys.exit(0)
if not generator:
print usage
sys.exit(1)
try:
#Decided not use argpase to maintain 2.6 compatibility
maxblocks = 0
blocks = -1
if '--count' in sys.argv:
maxblocks = int(sys.argv[sys.argv.index('--count')+1])
blocks = 0
while True:
if maxblocks and blocks >= maxblocks:
break
print generator(),
blocks+=1
except:
pass
def calculatePi(pValue):
for k in range(pValue):
j = 0
count = 0
while (j < circlePoints):
x = (quantumrandom.randint(0, 10) * (0.05)) + (
0.5
) # taking a random point in the upper right quadrant of circle
circleEq = (0.5) + math.sqrt(
0.25 - ((x - (0.5))**2)
) # the circle equation for a circle of center (0.5, 0.5) and radius 1
y = (quantumrandom.randint(0, 10) * (0.05)) + (0.5)
if (y <= circleEq):
count += 1
j += 1
frac = (count) / float(circlePoints)
pi = frac * 4
datac.append(pi)
return datac
def shuffle_gen():
for q, r in enumerate(shuffled_deck):
try:
if shuffled_deck[q] == shuffled_deck[
q + 1] and quantumrandom.randint() <= 0.701:
tmpnum = random.randrange(0, 52)
index = tmpnum if tmpnum != q else random.randrange(0, q)
shuffled_deck.insert(index, shuffled_deck[q])
del shuffled_deck[q]
else:
pass
except Exception:
pass
return shuffled_deck
def form_valid(self, form):
decohered = form.data['state1']
if randint(0, 2) > 0:
decohered = form.data['state2']
decoherence = Decoherence(
state1=form.data['state1'],
state2=form.data['state2'],
decohered=decohered,
)
decoherence.save()
return render_to_response(
'decoherence.html',
{'decohered': decohered}
)
def merge_datasets(pickle_files, train_size, valid_size=0):
num_classes = len(pickle_files)
valid_dataset, valid_labels = make_arrays(valid_size, image_size)
train_dataset, train_labels = make_arrays(train_size, image_size)
vsize_per_class = valid_size // num_classes
tsize_per_class = train_size // num_classes
start_v, start_t = 0, 0
end_v, end_t = vsize_per_class, tsize_per_class
end_l = vsize_per_class+tsize_per_class
pbar = tqdm(total = len(pickle_files))
for label, pickle_file in enumerate(pickle_files):
try:
with open(pickle_file, 'rb') as f:
letter_set = pickle.load(f)
# let's shuffle the letters to have random validation and training set
Nshuf = quantumrandom.randint(0,10)
for i in range(0,Nshuf):
np.random.shuffle(letter_set)
if valid_dataset is not None:
valid_letter = letter_set[:vsize_per_class, :, :]
valid_dataset[start_v:end_v, :, :] = valid_letter
valid_labels[start_v:end_v] = label
start_v += vsize_per_class
end_v += vsize_per_class
train_letter = letter_set[vsize_per_class:end_l, :, :]
train_dataset[start_t:end_t, :, :] = train_letter
train_labels[start_t:end_t] = label
start_t += tsize_per_class
end_t += tsize_per_class
except Exception as e:
print('Unable to process data from', pickle_file, ':', e)
raise
pbar.update(1)
return valid_dataset, valid_labels, train_dataset, train_labels
def on_data(self, data):
print('Incoming: {0}'.format(data))
tweet = json.loads(data)
screen_name = tweet['user']['screen_name']
me = screen_name == bot.SCREEN_NAME
retweet = 'retweeted_status' in tweet
if not me and not retweet:
#declare TRNG lines 42-47
flip = int(quantumrandom.randint(0, 100))
if flip >= 50:
flip = 1
else:
flip = 0
side = bot.SIDES[flip]
hashtag = random.choice(bot.HASHTAGS)
e = random.choice(emoji.EMOJI.values())
# I swear that the next line of code isn't Ruby.
reply = u'@{0} {1}. #{2} {3}'.format(screen_name, side, hashtag, e)
try:
log = u'Outgoing: {0}'.format(reply)
print(log)
except UnicodeEncodeError:
log = bot.unicode_to_ascii(reply)
log = u'Outgoing: {0}'.format(log)
print(log)
if bot.ENV == 'production':
try:
bot.api.update_status(reply, tweet['id'])
except tweepy.TweepError:
pass
# Return True to keep the stream listener listening.
return True
def secure_key(self,length):
self.check_modules()
keygen = lambda y:''.join([self.characters[int(Random.randint(0,len(self.characters)))] for i in range(0,int(y))])
return keygen(length)
def randint(min, max):
if trulyRandom:
return int(quantumrandom.randint(min, max))
else:
return int(random.randint(min, max))
import math
import numpy as np
import matplotlib.pyplot as plt
datax = []
datay = []
count = 0 # this will keep track of the number of points found in that quarter circle
datac = [] # this will hold the number of calculated Pi values
piValues = 500 # how many pi values we will calculate
totalPoints = 1000 # how many points we set to be found in that quarter of the square
dataPi = []
# this simulates points for square (x,y) between 0 and 1
for i in range(1000):
datax.append(quantumrandom.randint(0, 10) / 10)
datay.append(quantumrandom.randint(0, 10) / 10)
# circle function
# This function finds if point is in circle by using a quarter of a circle (upper right quadrant) and takes in a
def calculatePi(pValue):
for k in range(pValue):
j = 0
count = 0
while (j < circlePoints):
x = (quantumrandom.randint(0, 10) * (0.05)) + (
0.5
) # taking a random point in the upper right quadrant of circle
circleEq = (0.5) + math.sqrt(
def all(args):
"""
run all sequence modification changes
"""
import random as rand
import quantumrandom as qrand
import platform
if (args.seed):
RANDOM_SEED=args.seed
logging.info("User supplied random seed")
else:
RANDOM_SEED= int(qrand.randint(0, 20000000000000))
logging.info("Random seed is: %s",RANDOM_SEED)
rand.seed(RANDOM_SEED)
logging.info("==Python Details==")
logging.info("Version: %s",platform.python_version())
logging.info("Implementation: %s",platform.python_implementation())
logging.info("Platform: %s",platform.platform())
import os
morph_dir=args.output+"/morph"
if not os.path.exists(morph_dir):
os.makedirs(morph_dir)
import skbio
bootstrap = args.bootstraps
for f in args.files:
exp_sequences = []
# since SecretomeP will remove duplciates in input, implement a ful maping from original header to an incrementing ID
morph_id=1
logging.info("Morph_ID initialised at: %d", morph_id)
sk_seqs = skbio.io.read(f, format='fasta')
for s in sk_seqs:
print(s.metadata)
exp_sequences.append(MorphedSequence(s.metadata['id'],s.metadata['description'],str(s),bootstrap,call_signalP))
output_stub = morph_dir + "/" + os.path.basename(f.name)
exclude_less_than=41
with open(output_stub+"_original.fasta", 'w') as original, open(output_stub+"_rev.fasta", 'w') as reverse,open(output_stub+"_spremove.fasta", 'w') as sp_remove,open(output_stub+"_spcterm.fasta", 'w') as sp_cterm,open(output_stub+"_sprandom.fasta", 'w') as sp_random,open(output_stub+"_random.fasta", 'w') as random:
for m in exp_sequences:
if (len(m.seq) < exclude_less_than):
continue
# use annotations for headers
# O)riginal with description intact
# R)everse
# r(A)ndom with iteration
# S)p_remove
# sp_ra(N)dom with iteration
# sp_(C)term
# i.e O1, R2, A3
#
skbio.sequence.Protein(sequence = m.seq , metadata= {'id': "O"+str(morph_id), 'description': m.header +":"+m.description } ).write(original)
morph_id = morph_id+1
skbio.sequence.Protein(sequence = m.rev , metadata= {'id': "R"+str(morph_id), 'description':m.header +":" + 'sequence reversed'} ).write(reverse)
morph_id = morph_id+1
if (m.positive_data):
skbio.sequence.Protein(sequence = m.sp_remove , metadata= {'id': "S"+str(morph_id),
'description': m.header+": "+'SP at positions' + m.drange + ' removed using '+str(m.signal_function.__name__)} ).write(sp_remove)
morph_id = morph_id+1
skbio.sequence.Protein(sequence = m.sp_cterm , metadata= {'id': "C"+str(morph_id),
'description': m.header +": "+'SP at positions' + m.drange + ' placed at C-terminus using '+ str(m.signal_function.__name__)} ).write(sp_cterm)
morph_id = morph_id+1
else:
skbio.sequence.Protein(sequence = m.sp_remove , metadata= {'id': "S"+str(morph_id),
'description': m.header+": "+ 'False SP at positions' + m.drange + ' removed (negative data)'} ).write(sp_remove)
morph_id = morph_id+1
skbio.sequence.Protein(sequence = m.sp_cterm , metadata= {'id': "C"+str(morph_id),
'description': m.header +": "+'False SP at positions' + m.drange + ' placed at C-terminus (negativa data)'} ).write(sp_cterm)
morph_id = morph_id+1
randoms = m.random
iteration=1
for r in randoms:
skbio.sequence.Protein(sequence = r , metadata= {'id': "A"+str(morph_id), 'description': m.header+":"+ ' randomised iteration '+str(iteration)} ).write(random)
iteration = iteration +1
morph_id = morph_id+1
sp_randoms = m.sp_random
iteration=1
for spr in sp_randoms:
skbio.sequence.Protein(sequence = spr , metadata= {'id': "N"+str(morph_id), 'description': m.header+": "+' SP randomised' +' using '+ str(m.signal_function.__name__) + 'iteration '+str(iteration)} ).write(sp_random)
iteration = iteration +1
morph_id = morph_id+1
logging.info("Morph_ID finished at: %d", morph_id)
import re
try:
import quantumrandom
generator = quantumrandom.cached_generator()
get_int = lambda n: quantumrandom.randint(1, n, generator)
except ImportError:
import random
get_int = lambda n: random.randint(1, n)
def roll(n, sides, bonus=0):
return sum([get_int(sides) for i in xrange(n)], bonus)
pattern = re.compile(r'^([0-9]*)d([0-9]+)(?:\+([0-9]+))?')
def rollstr(s):
match = pattern.match(s)
if not match:
raise ValueError("Badly formatted roll string: %s" % s)
n, sides, bonus = match.groups
if not n: n = 0
if not bonus: bonus = 0
return roll(int(n), int(sides), int(bonus))
def check(dc, bonus=0, tie_win=False, extremes=True):
raw_result = roll(1, 20, 0)
if extremes and raw_result in (1, 20): return raw_result == 20
import quantumrandom
def few_numbers():
return quantumrandom.get_data(data_type='uint16', array_length=5)
print('число от 0 до 9 = ', quantumrandom.randint(0, 9))
print('целое число от 0 до 9 = ', int(quantumrandom.randint(0, 9)))
random_list = few_numbers()
print(
'лист из нескольких чисел = ',
random_list,
)
async def quantumroll(client, message):
i = math.floor(quantumrandom.randint(1, 7))
response = "You rolled a " + str(i) + " {0.author.mention}."
await message.channel.send(response.format(message))
return
def MakeAndSendMemeMail():
import quantumrandom as Qran #quantumrandom is like random, but it uses a newer method to get better random
import smtplib #number. It's called quantumrandom because it uses newer quantum computer
from email.mime.text import MIMEText #technology.
from email.mime.multipart import MIMEMultipart
from email.mime.base import MIMEBase
from email import encoders
import os.path
import time as T
from NamesAndImagesLists import image_list
from NamesAndImagesLists import email_list
start_time = T.time() #The timer starts here
#the program picks the meme with this
ran_meme = round(Qran.randint(1, 9))
meme = image_list[ran_meme]
print(meme, '\n')
#this program picks the email to send to
ran_email = round(Qran.randint(1, 6))
email = email_list[ran_email]
#for the two parts that randomly get the meme and email, be sure to set the number after Qran.randint. The second number
#should be the amount you have. I.e., if I have 3 memes and 2 emails it should look like this:
# ran_meme = round(Qran.randint(1,3))
# ran_email = round(Qran.randint(1, 2))
print('Starting\n')
#This is for setting up the email in the code. Look at the readme for the guide on what settings you have to change
#in the email
sender = '*****@*****.**'
password = '******'
send_to_email = email
#This is where you set the subject and text of the email
subject = "You've got MemeMail"
message = ""
#This is the program taking the parameters we've set previously in the script and formatting them to be an email
msg = MIMEMultipart()
msg['From'] = sender
msg['To'] = send_to_email
msg['Subject'] = subject
#This is converting the image into something that can be sent via email
msg.attach(MIMEText(message, 'plain'))
attachment = open(meme, "rb")
part = MIMEBase('application', 'octet-stream')
part.set_payload((attachment).read())
encoders.encode_base64(part)
part.add_header('Content-Disposition', "attachment; filename= %s" % meme)
msg.attach(part)
print('Email Fully Built\n')
print('Email is being sent to ', send_to_email, ' ')
try:
server = smtplib.SMTP(
'smtp.gmail.com',
587) #This part is the program connecting to the server and
server.starttls() #attempting to send the email
server.login(sender, password)
text = msg.as_string()
server.sendmail(sender, send_to_email, text)
server.quit()
print('Success...?')
except:
print('Failed to either connect to server or to send the email')
end_time = T.time() #The end of the timer
print("Ending Program\n", "Finished in", end_time - start_time,
"seconds.\n") #Final message stating completion
def __init__(self, e, n):
self.gameLength = int(quantumrandom.randint(1, n))
self.currentGame = 0
self.p1_moves = []
self.p2_moves = []
self.entropy = e
import re
try:
import quantumrandom
generator = quantumrandom.cached_generator()
get_int = lambda n: quantumrandom.randint(1, n, generator)
except ImportError:
import random
get_int = lambda n: random.randint(1, n)
def roll(n, sides, bonus=0):
return sum([get_int(sides) for i in xrange(n)], bonus)
pattern = re.compile(r'^([0-9]*)d([0-9]+)(?:\+([0-9]+))?')
def rollstr(s):
match = pattern.match(s)
if not match:
raise ValueError("Badly formatted roll string: %s" % s)
n, sides, bonus = match.groups
if not n: n = 0
if not bonus: bonus = 0
return roll(int(n), int(sides), int(bonus))
def check(dc, bonus=0, tie_win=False, extremes=True):
raw_result = roll(1, 20, 0)
if extremes and raw_result in (1, 20): return raw_result == 20
result += bonus
return result > dc or (tie_win and result == dc)
"Ok {}! What is the smartest insect?".format(student),
"Alright {}! What did the spider make online?".format(student),
"R U ready {}? Why do magicians always do so well at school?".format(
student),
"Your turn {}! Which side of the turkey has the most feathers? left side? Right side?"
.format(student)
]
as_joke = [
"Your computer has a byte ^O^", "Bison..... Get it?",
"They are full of problem T-T",
"Because the kid wanted to go to HIGH school >O<", "Spelling Bee",
"A Website! hehe", "They can handle trick question!",
"is the OUTSIDE! hahahaha"
]
rand = quantumrandom.randint(0, 7)
print("\n")
for char in qs_joke[int(rand)]:
print(char, end='')
sys.stdout.flush()
time.sleep(0.15)
time.sleep(5)
print("\n")
for char in as_joke[int(rand)]:
print(char, end='')
sys.stdout.flush()
time.sleep(0.1)
def die(sides): return quantumrandom.randint(1, sides, generator) class Room(object):
from lxml import html
import random
import re
#Get string from user
question = input('Question: ')
lucky_number = sum([x for x in map(ord, question)])
#print('Lucky number:', lucky_number) #DEBUG
#Get a random interger
try:
print('Connecting to quantum random number generator...')
ran = int(quantumrandom.randint(0, 78))
except:
print('Failed, falling back to pseudo-random number generator...')
ran = int(random.randint(0, 77))
#print('Random integer:', ran) #DEBUG
#Combine two numners to get card index
i = (ran + lucky_number) % 78
#print('Card index:', i) #DEBUG
## Major Arcana
if i < 22:
def main():
end = False
while (end == False):
print("1: generate a new master password")
print("2: login")
print("3: quit")
mainMenu = input("enter prefered number to proceed.")
if mainMenu == str(2):
passDetails = {}
options = ["site", "login", "rules", "exclude", "length"]
index = 0
while index <= 4:
details = input(f"Enter {options[index]} details")
if index == 3 and details == "none":
passDetails[options[index]] = ""
index += 1
continue
if details == 'quit':
break
passDetails[options[index]] = details
index += 1
print(passDetails)
masterPassword = input("enter master password")
print(makePassword(masterPassword, passDetails))
elif mainMenu == str(3):
print("exiting....")
break
elif mainMenu == str(1):
print("PASSWORD")
len = input("specify length of password")
#length of string is 94 characters long
SYMBOLS = CHARACTER_SUBSETS["lowercase"] + CHARACTER_SUBSETS[
"uppercase"] + CHARACTER_SUBSETS["digits"] + CHARACTER_SUBSETS[
"symbols"]
masterPassword = ""
for character in range(int(len)):
num = int(quantumrandom.randint(0, 94))
masterPassword += SYMBOLS[num]
passDetails = {
"site": "37L>,5k*R?y`unyS",
"login": "******",
#lowercase, uppercase, digits, symbols
"rules": ["lowercase", "uppercase", "digits", "symbols"],
"exclude": "",
"length": len
}
print(
"write this password down somewhere safe and cozy, we do not reccoment you storing this anywhere but in real life!"
)
print(makePassword(masterPassword, passDetails))
print("generated password", " ",
makePassword("j^%pC*3UKDgzBr%lXMHqC", passDetails))
import quantumrandom
import ssl
ssl._create_default_https_context = ssl._create_unverified_context
Cardinality = 4
Cardinality_Subset = 2
universe = []
sample = []
dice = 0
element = 0
# New Universe.
for i in range(1,Cardinality+1):
universe.append(i)
for i in range(1,Cardinality_Subset + 1):
print("Universum:")
print(universe)
Cardinality = len(universe)
print("Card of Universum = ", Cardinality)
dice = round(quantumrandom.randint(1, Cardinality))
print("====|||| Dice = ", dice)
element = universe[dice - 1]
sample.append(element)
print("Element selected {", element, "}")
del universe[dice - 1]
print("Universe after {", element, "} selected.")
print(universe)
sample.sort()
print("Sample:")
print(sample)
def test_randint(self):
for i in range(5):
for j in range(i + 1, 5):
for k in range(3):
val = quantumrandom.randint(i, j)
assert(val >= i and val < j)
