- Location of Mobile Number Code -
import phonenumbers
from phonenumbers import timezone
from phonenumbers import geocoder
from phonenumbers import carrier
number = input("Enter the phone number with country code : ")
# Parsing String to the Phone number
phoneNumber = phonenumbers.parse(number)
# printing the timezone using the timezone module
timeZone = timezone.time_zones_for_number(phoneNumber)
print("timezone : "+str(timeZone))
# printing the geolocation of the given number using the geocoder module
geolocation = geocoder.description_for_number(phoneNumber,"en")
print("location : "+geolocation)
# printing the service provider name using the carrier module
service = carrier.name_for_number(phoneNumber,"en")
print("service provider : "+service)
import phonenumbers
from phonenumbers import timezone
from phonenumbers import geocoder
from phonenumbers import carrier
number = input("Enter the phone number with country code : ")
# Parsing String to the Phone number
phoneNumber = phonenumbers.parse(number)
# printing the timezone using the timezone module
timeZone = timezone.time_zones_for_number(phoneNumber)
print("timezone : "+str(timeZone))
# printing the geolocation of the given number using the geocoder module
geolocation = geocoder.description_for_number(phoneNumber,"en")
print("location : "+geolocation)
# printing the service provider name using the carrier module
service = carrier.name_for_number(phoneNumber,"en")
print("service provider : "+service)
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--- Python Logo Source Code ---
import turtle
t = turtle.Turtle()
s = turtle.Screen()
s.bgcolor("black")
t.speed(10)
t.pensize(2)
t.pencolor("white")
def s_curve():
for i in range(90):
t.left(1)
t.forward(1)
def r_curve():
for i in range(90):
t.right(1)
t.forward(1)
def l_curve():
s_curve()
t.forward(80)
s_curve()
def l_curve1():
s_curve()
t.forward(90)
s_curve()
def half():
t.forward(50)
s_curve()
t.forward(90)
l_curve()
t.forward(40)
t.left(90)
t.forward(80)
t.right(90)
t.forward(10)
t.right(90)
t.forward(120) #on test
l_curve1()
t.forward(30)
t.left(90)
t.forward(50)
r_curve()
t.forward(40)
t.end_fill()
def get_pos():
t.penup()
t.forward(20)
t.right(90)
t.forward(10)
t.right(90)
t.pendown()
def eye():
t.penup()
t.right(90)
t.forward(160)
t.left(90)
t.forward(70)
t.pencolor("black")
t.dot(35)
def sec_dot():
t.left(90)
t.penup()
t.forward(310)
t.left(90)
t.forward(120)
t.pendown()
t.dot(35)
t.fillcolor("#306998")
t.begin_fill()
half()
t.end_fill()
get_pos()
t.fillcolor("#FFD43B")
t.begin_fill()
half()
t.end_fill()
eye()
sec_dot()
def pause():
t.speed(2)
for i in range(100):
t.left(90)
pause()
import turtle
t = turtle.Turtle()
s = turtle.Screen()
s.bgcolor("black")
t.speed(10)
t.pensize(2)
t.pencolor("white")
def s_curve():
for i in range(90):
t.left(1)
t.forward(1)
def r_curve():
for i in range(90):
t.right(1)
t.forward(1)
def l_curve():
s_curve()
t.forward(80)
s_curve()
def l_curve1():
s_curve()
t.forward(90)
s_curve()
def half():
t.forward(50)
s_curve()
t.forward(90)
l_curve()
t.forward(40)
t.left(90)
t.forward(80)
t.right(90)
t.forward(10)
t.right(90)
t.forward(120) #on test
l_curve1()
t.forward(30)
t.left(90)
t.forward(50)
r_curve()
t.forward(40)
t.end_fill()
def get_pos():
t.penup()
t.forward(20)
t.right(90)
t.forward(10)
t.right(90)
t.pendown()
def eye():
t.penup()
t.right(90)
t.forward(160)
t.left(90)
t.forward(70)
t.pencolor("black")
t.dot(35)
def sec_dot():
t.left(90)
t.penup()
t.forward(310)
t.left(90)
t.forward(120)
t.pendown()
t.dot(35)
t.fillcolor("#306998")
t.begin_fill()
half()
t.end_fill()
get_pos()
t.fillcolor("#FFD43B")
t.begin_fill()
half()
t.end_fill()
eye()
sec_dot()
def pause():
t.speed(2)
for i in range(100):
t.left(90)
pause()
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