def __init__(self, price, quantity, inventory, category, name, safety_info,
age_group):
Toy.__init__(self)
Product.__init__(self, price, quantity, inventory, category)
self.name = name
self.safety_info = safety_info
self.age_group = age_group
def series_solver(strip_lengths):
"""
The basic solver.
Just run a depth first search, no tricks.
"""
toy = Toy(strip_lengths)
toy.run()
return toy.rel_solutions()
def main():
while True:
choice = get_user_choice(main_menu)
if choice == 1:
pet_name = input("What would you like to name your pet?\n")
print("Please choose the type of pet:")
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
pets.append(Pet(pet_name))
print("You now hae %s pets" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
if choice == 3:
for pet in pets:
pet.eat_food()
if choice == 4:
for pet in pets:
print(pet)
if choice == 5:
for pet in pets:
pet.get_toy(Toy())
if choice == 6:
for pet in pets:
pet.be_alive()
if choice == 7:
print("Thanks for playing!!!")
break
def main():
while True:
choice = get_user_choice(main_menu)
if choice == 1:
print("Please choose the type of pet:")
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
print("You now have %d pets" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
if choice == 3:
for pet in pets:
pet.eat_food()
if choice == 4:
for pet in pets:
print(pet)
if choice == 5:
for pet in pets:
pet.get_toy(Toy())
if choice == 6:
# Pet levels naturally lower.
for pet in pets:
pet.be_alive()
def powerAvailableEstimation(big_jobs, boosters, hrs):
'''
Assume a rating of 0.25, total gain in ratings that can be obtained for different jobs
'''
total_gain = 0.0;
ratio_big_jobs_boosters = len(big_jobs) / float( len(big_jobs) + len(boosters) );
#Dummy Elf
dummy_elf = Elf(0);
dummy_elf.rating = 0.25;
work_start_time = 540; #All boosters are played with maximum sanctioned time
shuffle(boosters);
for job in boosters:
#Assume the work starts at 9:00 on start of the day
next_available_time, work_duration = \
assign_elf_to_toy(work_start_time, dummy_elf, job[1], hrs);
dummy_elf.update_elf(hrs, Toy(0, '2014 01 01 01 01' ,job[1]), work_start_time, work_duration); #Every toy has default arrival time(irrelevant)
#Flip a coin and play a big job based on above probability
if random.random() < ratio_big_jobs_boosters:
#Big Job Played - Measure the gain
if dummy_elf.rating > 0.25:
total_gain += (dummy_elf.rating - 0.25);
#Reinitialize the dummy_elf
dummy_elf = Elf(0);
dummy_elf.rating = 0.25;
return total_gain;
def get_toy(self):
"""Get all the actual toy in clearance."""
self.Logger.debug("Start to get the toys")
temp = {}
extract = BadDragonApi(self.Logger)
self.actualise_toy_name()
self.Logger.debug("Start to parse the toys")
for i in range(0, extract.number_of_toy()):
toy = extract.get_toy(i)
if toy['sku'].lower() in self.Options.ProductName:
temp[toy['id']] = Toy(
self.option_from_type(toy['sku'], self.Options.ProductName),
self.Options.ProductType[toy['sku'].lower()],
self.option_from_type(toy['size'], self.Options.SizeOptions),
self.option_from_type(toy['colorTheme']['name'] if toy['colorTheme'] else None,
self.Options.ColorOptions),
self.option_from_type(toy['firmness'], self.Options.FirmnessOptions),
self.option_from_type(toy['cumtube'], self.Options.CumTubValues),
self.option_from_type(toy['suction_cup'], self.Options.SuctionCupValues),
self.option_from_type(toy['is_flop'], self.Options.FlopOption),
toy['external_flop_reason'], toy['id'])
else:
self.Logger.warning("Error {} is not in the dictionary".format(toy['sku']))
self.Logger.info("Get {} toy in stock".format(len(temp)))
return temp
def main():
while True:
clear()
choice = get_user_choice(main_menu)
if choice == 1:
pet_name = input("What would you like to name your pet? ")
print("Please choose the type of pet:")
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
print("You now have %d pets" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
if choice == 3:
for pet in pets:
pet.eat_food()
if choice == 4:
for pet in pets:
pet.get_toy(Toy())
if choice == 5:
for pet in pets:
print(pet)
input("")
if choice == 6:
for pet in pets:
pet.be_alive()
if choice == 7:
clear()
print("Thanks for adopting and taking care of your pet.")
return False
def show_toys():
if request.method == "POST":
new_toy = Toy(request.form['toyname'], request.form['image_url'])
toys.append(new_toy)
return redirect(url_for('show_toys'))
else:
return render_template('index.html', toys = toys)
def play_elf(self, output, elf_object, toy_id, toy_duration, work_start_time=None):
"""
:param elf_id: Elf id
:param toy_id: Toy_Id
:param work_start_time: Minute since Jan, 2014
:return:
"""
hrs = Hours();
ref_time = datetime.datetime(2014, 1, 1, 0, 0);
if work_start_time == None:
work_start_time = elf_object.next_available_time;
elf_object.next_available_time, work_duration = \
self.assign_elf_to_toy(work_start_time, elf_object, toy_duration, hrs);
elf_object.update_elf(hrs, Toy(toy_id, '2014 01 01 01 01' ,toy_duration), work_start_time, work_duration); #Every toy has default arrival time(irrelevant)
tt = ref_time + datetime.timedelta(seconds=60*work_start_time)
time_string = " ".join([str(tt.year), str(tt.month), str(tt.day), str(tt.hour), str(tt.minute)])
if elf_object.id in output:
output[elf_object.id].append((toy_id, time_string, work_duration, work_start_time)); #work_start_time will be used to print in sorted order
else:
output[elf_object.id] = [(toy_id, time_string, work_duration, work_start_time)];
return tt.year;
def main():
while True:
choice = get_user_choice(main_menu)
#allowing user to adopt a pet
if choice == 1:
pet_name = input("What would you like to name your pet? ")
print("Please choose the type of pet:")
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
print("You now have %d pets" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
if choice == 3:
for pet in pets:
pet.eat_food()
#View pet status
if choice == 4:
for pet in pets:
print(pet)
if choice == 5:
for pet in pets:
pet.get_toy(Toy())
if choice == 6:
# Pet levels naturally lower.
for pet in pets:
pet.be_alive()
def __init__(self, name, globalP):
self.env = Toy()
self.name = name
self.policy = Policy(env=self.env,
state_shape=N_F,
n_actions=N_A,
globalP=globalP,
scope=name + '/Policy')
def index():
if request.method == "POST":
# gather the value of an input with a name attribute of "name"
toys.append(Toy(request.form['name']))
# respond with a redirect to the route which has a function called "index" (in this case that is '/toys')
return redirect(url_for('index'))
# if the method is GET, just return index.html
return render_template('index.html', toys=toys)
def solution_firstAvailableElf(toy_file, soln_file, myelves):
""" Creates a simple solution where the next available elf is assigned a toy. Elves do not start
work outside of sanctioned hours.
:param toy_file: filename for toys file (input)
:param soln_file: filename for solution file (output)
:param myelves: list of elves in a priority queue ordered by next available time
:return:
"""
hrs = Hours()
ref_time = datetime.datetime(2014, 1, 1, 0, 0)
row_count = 0
with open(toy_file, 'rb') as f:
toysfile = csv.reader(f)
toysfile.next() # header row
with open(soln_file, 'wb') as w:
wcsv = csv.writer(w)
wcsv.writerow(['ToyId', 'ElfId', 'StartTime', 'Duration'])
for row in toysfile:
current_toy = Toy(row[0], row[1], row[2])
# get next available elf
elf_available_time, current_elf = heapq.heappop(myelves)
work_start_time = elf_available_time
if current_toy.arrival_minute > elf_available_time:
work_start_time = current_toy.arrival_minute
# work_start_time cannot be before toy's arrival
if work_start_time < current_toy.arrival_minute:
print 'Work_start_time before arrival minute: {0}, {1}'.\
format(work_start_time, current_toy.arrival_minute)
exit(-1)
current_elf.next_available_time, work_duration = \
assign_elf_to_toy(work_start_time, current_elf, current_toy, hrs)
current_elf.update_elf(hrs, current_toy, work_start_time,
work_duration)
# put elf back in heap
heapq.heappush(myelves,
(current_elf.next_available_time, current_elf))
# write to file in correct format
tt = ref_time + datetime.timedelta(seconds=60 *
work_start_time)
time_string = " ".join([
str(tt.year),
str(tt.month),
str(tt.day),
str(tt.hour),
str(tt.minute)
])
wcsv.writerow([
current_toy.id, current_elf.id, time_string, work_duration
])
def subprocess(strip_lengths, start, end):
"""
Subprocess for embarrassinly parallel
"""
toy = Toy(strip_lengths)
toy.start(start)
toy.run(finish_state=end)
# print(start, toy.rel_solutions())
return toy.rel_solutions()
async def asyncio_subprocess(strip_lengths, start, end):
"""
Subprocess for concurrent_asyncio
"""
toy = Toy(strip_lengths)
toy.start(start)
toy.run(finish_state=end)
# print(start, toy.rel_solutions())
return toy.rel_solutions()
def __init__(self, name, globalP):
self.env = Toy()
self.name = name
self.policy = Policy(name + '/Policy',
env=self.env,
state_shape=self.env.observation_shape,
n_actions=16)
self.policy.build()
self.pull_global_op = get_pull_global(globalP, self.policy)
self.update_global_op = get_update_global(globalP, self.policy)
def main():
while True:
choice = get_user_choice(main_menu)
if choice == 1:
pet_name = input(
u"\n\u001b[32;1m Please enter the name of your new pet: \u001b[0m\n"
)
print(
u"\u001b[35;1m\n What type of pet would you like to adopt? \u001b[0m\n"
)
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(PlayfulPet(pet_name))
print(u"\n\u001b[35;1m Extra playful!! \u001b[0m\n")
print("You now have %d new pet(s) \n" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
print(u"\u001b[32;1m This is fun! Let's play all day\u001b[0m")
if choice == 3:
print(
u"\n\u001b[32;1m What kind of treat would you like to give your pet? \u001b[0m\n"
)
for pet in pets:
type_treat = get_pet_treat(treat_list)
my_treat = treat_list[type_treat]
print(my_treat.message)
results = my_treat.give_treat()
pet.happiness += results[1]
pet.hunger -= results[0]
if choice == 4:
for pet in pets:
pet.eat_food()
print(u"\u001b[32;1m YUM! That hit the spot! \u001b[0m")
if choice == 5:
for pet in pets:
pet.nap_time()
print(u"\u001b[32;1m Nap time!...I'm sleepy. \u001b[0m")
if choice == 6:
for pet in pets:
print(pet)
if choice == 7:
for pet in pets:
pet.get_toy(Toy())
if choice == 8:
for pet in pets:
pet.life()
if choice == 9:
exit(print(u"\u001b[42m Please, come back soon! \u001b[0m\n"))
def toy_from_database(self):
"""Sync the toy list with the toy in the database."""
data = self.Database.get_toys()
self.Logger.debug('Toy in database : {}'.format(data))
dic = {}
for toy in data:
dic[toy[0]] = Toy(
self.option_from_type(toy[1], self.Options.ProductName),
self.option_from_type(toy[3], self.Options.ProductType),
self.option_from_type(toy[2], self.Options.SizeOptions),
toy[4],
self.option_from_type(toy[5], self.Options.FirmnessOptions),
self.option_from_type(toy[6], self.Options.CumTubValues),
self.option_from_type(toy[7], self.Options.SuctionCupValues),
self.option_from_type(toy[8], self.Options.FlopOption),
toy[9], toy[0])
self.ToyInShop = dic
def main():
main = Menu("Please choose an option:", main_menu)
type = Menu("Please choose the type of pet:", adoption_menu)
treat = Menu("Please choose the type of treat:", treat_menu)
while True:
choice = main.get_choice()
if choice == 1:
pet_name = input("What would you like to name your pet? ")
type_choice = type.get_user_choice()
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
print("You now have %d pets" % len(pets))
if choice == 2:
for pet in pets:
pet.get_love()
print("Pets have been loved!")
if choice == 3:
for pet in pets:
pet.eat_food()
print("Pets have been fed!")
if choice == 4:
for pet in pets:
print(pet)
if choice == 5:
for pet in pets:
pet.get_toy(Toy())
print("Pets got a toy!")
if choice == 6:
treat_choice = treat.get_user_choice()
if treat_choice == 1:
treat_type = ColdPizza()
if treat_choice == 2:
treat_type = Bacon()
if treat_choice == 3:
treat_type = VeganSnack
for pet in pets:
pet.get_treat(treat_type)
print("Pets got a treat!")
if choice == 7:
for pet in pets:
pet.be_alive()
print("Pets did nothing!")
def read_toys(toy_file):
""" Reads the toy file and returns a dictionary of Toys.
Toy file format: ToyId, Arrival_time, Duration
ToyId: toy id
Arrival_time: time toy arrives. Format is: YYYY MM DD HH MM (space-separated)
Duration: duration in minutes to build toy
:param toy_file: toys input file
:param hrs: hours object
:param num_toys: total number of toys to build
:return: Dictionary of toys
"""
toy_dict = {}
with open(toy_file, 'rb') as f:
fcsv = csv.reader(f)
fcsv.next() # header row
for row in fcsv:
new_toy = Toy(row[0], row[1], row[2])
toy_dict[new_toy.id] = new_toy
return toy_dict
def main():
app = Menu("Please choose an option", main_menu)
types = Menu("Please choose a type of pet", adoption_menu)
treats = Menu("please choose a type of treat", treat_menu)
while True:
choice = app.get_user_choice()
if choice == 1:
pet_name = input("What would you like the pet name to be?")
type_choice = types.get_user_choice()
if type_choice == 1:
pets.append(Pet(pet_name))
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
num_pets = len(pets)
print(f"You now have {num_pets} pets")
elif choice == 2:
for pet in pets:
pet.get_love()
elif choice == 3:
for pet in pets:
pet.eat_food()
elif choice == 4:
for pet in pets:
print(pet)
elif choice == 5:
for pet in pets:
pet.get_toy(Toy())
elif choice == 6:
for pet in pets:
pet.be_alive()
elif choice == 7:
print("Please choose your type of treat:")
treat_choice = treats.get_user_choice
if treat_choice == 1:
for pet in pets:
pet.eat_treat(ColdPizza())
elif treat_choice == 2:
for pet in pets:
pet.eat_treat(Bacon())
elif treat_choice == 3:
for pet in pets:
pet.eat_treat(VeganSnack())
def main():
app = Menu('Please choose an Option: ', main_menu)
types = Menu('Please choose a Pet Option: ', adoption_menu)
treats = Menu('Please choose a Treat Option: ', menu_menu)
while True:
choice = app.get_choice()
if choice == 1:
pet_name = input('What do you want to name your pet?')
type_choice = types.get_choice()
if (type_choice == 1):
pets.append(Pet(pet_name))
elif (type_choice == 2):
pets.append(CuddlyPet(pet_name))
print(f'\n\nYou now have {len(pets)} pets')
elif choice == 2:
for pet in pets: pet.get_love()
elif choice == 3:
treat_choice = treats.get_choice()
food_to_feed = 0
if(treat_choice == 1):
food_to_feed = ColdPizza()
elif(treat_choice == 2):
food_to_feed = Bacon()
elif(treat_choice == 3):
food_to_feed = VeganSnack()
for pet in pets: pet.eat_food(food_to_feed)
elif choice == 4:
for pet in pets:
print(pet)
elif choice == 5:
for pet in pets:
pet.get_toy(Toy())
elif choice == 6:
for pet in pets:
pet.be_alive()
print(pet)
def solution_noovertime(toy_file, soln_file, myelves):
""" Creates a simple solution where the next available elf is assigned a toy. Elves do not start
work outside of sanctioned hours.
:param toy_file: filename for toys file (input)
:param soln_file: filename for solution file (output)
:param myelves: list of elves in a priority queue ordered by next available time
:return:
"""
hrs = Hours()
ref_time = datetime.datetime(2014, 1, 1, 0, 0)
row_count = 0
with open(toy_file, 'rb') as f:
toysfile = csv.reader(f)
toysfile.next() # header row
available_toys = OrderedDict([])
for row in toysfile:
available_toys[row[0]] = Toy(row[0], row[1], row[2])
with open(soln_file, 'wb') as w:
wcsv = csv.writer(w)
wcsv.writerow(['ToyId', 'ElfId', 'StartTime', 'Duration'])
toys_assigned = [
9999,
]
start_times = np.array([a.next_available_time for a in myelves])
while len(available_toys.keys()) > 0:
print 'available_toys ', len(available_toys.keys())
tot_ass = 0
to_pop = []
for toycount, currtoy in available_toys.items():
best_times2 = np.where(currtoy.arrival_minute >= start_times,
np.nan, start_times)
best_times = np.argsort(best_times2)
for elfpos in best_times:
try:
work_start_time = int(best_times2[elfpos])
except ValueError:
break
current_elf = myelves[elfpos]
# work_start_time cannot be before toy's arrival
#if work_start_time < current_toy.arrival_minute:
# print 'Work_start_time before arrival minute: {0}, {1}'.\
# format(work_start_time, current_toy.arrival_minute)
# exit(-1)
next_available_time, work_duration, unsanctioned = \
assign_elf_to_toy(work_start_time, current_elf, currtoy, hrs)
if (unsanctioned == 0 or toys_assigned[-1] == 0
or current_elf.rating > 3.5):
current_elf.next_available_time = next_available_time
current_elf.update_elf(hrs, currtoy, work_start_time,
work_duration)
start_times[elfpos] = current_elf.next_available_time
# write to file in correct format
tt = ref_time + datetime.timedelta(seconds=60 *
work_start_time)
time_string = " ".join([
str(tt.year),
str(tt.month),
str(tt.day),
str(tt.hour),
str(tt.minute)
])
wcsv.writerow([
currtoy.id, current_elf.id, time_string,
work_duration
])
tot_ass += 1
del available_toys[toycount]
break
toys_assigned.append(tot_ass)
print 'productivities'
print[a.rating for a in myelves]
print toys_assigned
return
def _adjustColor(self, color):
return (int(c * self.brightness) for c in color)
def color(self, x, y, color):
self.trellis.color(x, y, self._adjustColor(color))
def width(self):
return 8
def height(self):
return 8
trellisWrapper = TrellisWrapper(trellis, 0.5)
toy = Toy(trellisWrapper)
def buttonEvent(x, y, edge):
toy.onEvent(x, y, edge == NeoTrellis.EDGE_RISING)
for y in range(8):
for x in range(8):
trellis.activate_key(x, y, NeoTrellis.EDGE_RISING)
trellis.activate_key(x, y, NeoTrellis.EDGE_FALLING)
trellis.set_callback(x, y, buttonEvent)
def tick(cmd=None):
toy.tick(cmd)
def index():
if request.method == "POST":
toys.append(Toy(request.form['name']))
return redirect(url_for('index'))
return render_template('index.html', toys=toys)
def index():
if request.method == "POST":
toys.append(Toy(request.form["name"]))
return redirect(url_for("index"))
return render_template("index.html", toys=toys)
def main():
while True:
choice = get_user_choice(main_menu)
if choice == 1:
pet_name = input("What would you like to name your pet? ")
print("Please choose the type of pet:")
type_choice = get_user_choice(adoption_menu)
if type_choice == 1:
pets.append(Pet(pet_name))
print(
"Good choice, these pets are great to start your journey as pet owner.\n"
)
elif type_choice == 2:
pets.append(CuddlyPet(pet_name))
print(
"Great choice, these pets are great for one's mental health and great anxiety reducers. But they do require lots of attention.\n"
)
print("You now have %d pets.\n" % len(pets))
### first part of the main menu
#### when a choice is made it starts the loop of choices
elif choice == 2:
for pet in pets:
pet.get_love()
if pet.happiness >= 8 and pet.happiness < 10:
print(
f"{pet_name}, is very happy, may want rest a bit. \n")
elif pet.happiness >= 10:
print(f"{pet_name} is very tired and needs to rest. \n")
elif choice == 3:
for pet in pets:
pet.eat_food()
if pet.fullness >= 8 and pet.fullness < 10:
print(
f"{pet_name}, is statisfied, you can stop feeding it. \n"
)
elif pet.fullness >= 10:
print(
f"{pet_name} has over eatten, and now needs to sleep. \n"
)
elif choice == 4:
for pet in pets:
print(pet)
elif choice == 5:
for pet in pets:
pet.get_toy(Toy())
elif choice == 6:
# Pet levels naturally lower.
for pet in pets:
pet.be_alive()
if pet.happiness <= 3 and pet.happiness > 0:
print(
f"{pet_name} is sad, you may want to play with your pet.\n"
)
elif pet.fullness <= 3 and pet.fullness > 0:
print(
f"{pet_name} is hungry, you may want to feed your pet.\n"
)
elif pet.fullness <= 0:
print(
f"{pet_name}, has died of hunger. Expect a call from the authorities!!!\n"
)
break
elif pet.happiness <= 0:
print(
f"{pet_name}, has run away, you may want to reflect of your life choices!\n"
)
break
### when this choice is made, depending on the level pet is already, parameter is set to notify the user of pets health and happiness.
elif choice == 7:
print("Thanks for playing, tell your friends! \n")
break
def global_optimizer(sub_file, myToys, hrs, NUM_ELVES, output):
""" Score the submission file, performing constraint checking. Returns the time (in minutes) when
final present is complete.
:param sub_file: submission file name. Headers: ToyId, ElfId, Start_Time, Duration
:param myToys: toys dictionary
:param hrs: hours object
:return: time (in minutes) when final present is complete
"""
file_handler = open(output, "wb")
hrs = Hours()
ref_time = datetime.datetime(2014, 1, 1, 0, 0)
threshold_minute = hrs.convert_to_minute('2450 1 1 0 0')
basket_toys_above_th = []
basket_toys_below_th = []
#Unchanged
elf_availability = {}
#Maintains the earliest time when elves finish their last jobs
for i in range(1, NUM_ELVES + 1):
elf_availability[i] = [0, 0]
row_count = 0
with open(sub_file, 'rb') as f:
fcsv = csv.reader(f)
fcsv.next() # header
for row in fcsv:
row_count += 1
if row_count % 50000 == 0:
print 'Starting toy: {0}'.format(row_count)
current_toy = int(row[0])
current_elf = int(row[1])
start_minute = hrs.convert_to_minute(row[2])
duration = int(row[3])
if start_minute > threshold_minute:
basket_toys_above_th.append(current_toy)
else:
basket_toys_below_th.append((row[0], row[1], row[2], row[3]))
if elf_availability[current_elf][0] < start_minute:
elf_availability[current_elf][0] = start_minute
elf_availability[current_elf][1] = duration
myelves = []
for i in elf_availability.keys():
elf = Elf(i)
elf.rating = 0.25
elf.next_available_time = elf_availability[current_elf][0] + int(
math.ceil(elf_availability[current_elf][1] / elf.rating))
heapq.heappush(myelves, (elf.next_available_time, elf))
while len(basket_toys_above_th) > 0:
#Retrive the toy object
current_toy_duration = myToys[basket_toys_above_th[0]]
#Pick the next available elf and execute it
elf_available_time, current_elf = heapq.heappop(myelves)
work_start_time = elf_available_time
current_elf.next_available_time, work_duration = \
assign_elf_to_toy(work_start_time, current_elf, current_toy_duration, hrs)
current_elf.update_elf(hrs, Toy(basket_toys_above_th[0], '2014 01 01 01 01' ,current_toy_duration), \
work_start_time, work_duration)
# put elf back in heap
heapq.heappush(myelves, (current_elf.next_available_time, current_elf))
tt = ref_time + datetime.timedelta(seconds=60 * work_start_time)
time_string = " ".join([
str(tt.year),
str(tt.month),
str(tt.day),
str(tt.hour),
str(tt.minute)
])
#Add it to the basket below the threshold
basket_toys_below_th.append((basket_toys_above_th[0], current_elf.id,
time_string, work_duration))
del basket_toys_above_th[0]
basket_toys_below_th = sorted(
basket_toys_below_th,
key=lambda element: hrs.convert_to_minute(element[2]))
file_handler.write("ToyId,ElfId,StartTime,Duration\n")
for obj in basket_toys_below_th:
file_handler.write(
str(obj[0]) + "," + str(obj[1]) + "," + str(obj[2]) + "," +
str(obj[3]) + "\n")
file_handler.close()
from toy import Toy
import tensorflow_tools as tf_tool
from policy import Policy
import imageio
from collections import namedtuple
tc = tf.nn.rnn_cell
Batch = namedtuple("Batch", [
"states", "actions", "last_actions", "states_", "rewards", "conditions",
"values", "reward_total"
])
LR = 2e-5
OPT = tf.train.AdamOptimizer(LR)
N_WORKERS = multiprocessing.cpu_count()
GLOBAL_POLICY_NET_SCOPE = 'Global_Policy'
env = Toy()
N_F = env.observation_shape
N_A = 16
MAX_EPISODE = 3000000
MAX_EP_STEPS = 20
def get_data(policy, batch_size, train=True, chooce_max=False, fixed=False):
batch_states = []
batch_actions = []
batch_last_actions = []
batch_states_ = []
batch_rewards = []
batch_conditions = []
batch_values = []
reward_total = 0
toy_heap = []
# Elf Heap
elf_heap = []
for i in xrange(NUM_ELVES):
heapq.heappush(elf_heap, (0, Elf(i+1)))
# Lecture du fichier des jouets
i = 0
all_toys_filename = os.path.join("..", "DATA", "toys_rev2.csv")
f = open(all_toys_filename, "rb")
fcsv = csv.reader(f)
fcsv.next()
for row in fcsv:
i += 1
new_toy = Toy(row[0], row[1], row[2])
t = new_toy.get_arrival_minute()
if t % 1440 <= (9*60):
t = ((t/1440)*1440)+(9*60)
elif t % 1440 >= (19*60):
t = (((t/1440)+1)*1440)+(9*60)
toy_arrival_minute = t
toy_arrival_day = toy_arrival_minute / 1440
toy_duration = new_toy.get_duration()
heapq.heappush(toy_heap, (-(toy_duration), new_toy))
if i % 1000 == 0:
print i
#if i == 1000000:
#!/usr/bin/python
from flask import Flask, render_template, redirect, url_for, request
from flask_modus import Modus
from toy import Toy
app = Flask(__name__)
modus = Modus(app)
duplo = Toy(name='duplo')
lego = Toy(name='lego')
knex = Toy(name='knex')
toys = [duplo, lego, knex]
@app.route('/toys/new')
def new():
return render_template('new.html')
@app.route('/toys', methods=["GET", "POST"])
def index():
if request.method == "POST":
# gather the value of an input with a name attribute of "name"
toys.append(Toy(request.form['name']))
# respond with a redirect to the route which has a function called "index" (in this case that is '/toys')
return redirect(url_for('index'))
# if the method is GET, just return index.html
return render_template('index.html', toys=toys)
