A while back, clever snippets of code portraying how different people programming in Python went about solving the same problem, appeared on the internet. Needless to say, it was pretty funny and despite its popularity, not many people seem to know of it when I bring it up. Being as lazy as I am when it comes to these sorts of things, I am blogging about it now. Almost three years later. It has been posted and reposted dozens of times, but full of geek pride, I can proudly say that I helped create it by correcting some of the mistakes in the original. How’s that for major geek cred?
def factorial(x): if x == 0: return 1 else: return x * factorial(x - 1) print factorial(6)
def factorial(x): result = 1 i = 2 while i <= x: result = result * i i = i + 1 return result print factorial(6)
def fact(x): #{ result = i = 1; while (i <= x): #{ result *= i; i += 1; #} return result; #} print(fact(6))
@tailcall def fact(x, acc=1): if (x > 1): return (fact((x - 1), (acc * x))) else: return acc print(fact(6))
def Factorial(x): res = 1 for i in xrange(2, x + 1): res *= i return res print Factorial(6)
def fact(x): return x > 1 and x * fact(x - 1) or 1 print fact(6)
f = lambda x: x and x * f(x - 1) or 1 print f(6)
fact = lambda x: reduce(int.__mul__, xrange(2, x + 1), 1) print fact(6)
import sys @tailcall def fact(x, acc=1): if x: return fact(x.__sub__(1), acc.__mul__(x)) return acc sys.stdout.write(str(fact(6)) + '\n')
from c_math import fact print fact(6)
from c_maths import fact print fact(6)
def factorial(x): #------------------------------------------------- #--- Code snippet from The Math Vault --- #--- Calculate factorial (C) Arthur Smith 1999 --- #------------------------------------------------- result = str(1) i = 1 #Thanks Adam while i <= x: #result = result * i #It's faster to use *= #result = str(result * result + i) #result = int(result *= i) #?????? result = str(int(result) * i) #result = int(str(result) * i) i = i + 1 return result print factorial(6)
import os def fact(x): os.system('factorial ' + str(x)) fact(6)
NULL = None def CalculateAndPrintFactorialEx(dwNumber, hOutputDevice, lpLparam, lpWparam, lpsscSecurity, *dwReserved): if lpsscSecurity != NULL: return NULL #Not implemented dwResult = dwCounter = 1 while dwCounter <= dwNumber: dwResult *= dwCounter dwCounter += 1 hOutputDevice.write(str(dwResult)) hOutputDevice.write('\n') return 1 import sys CalculateAndPrintFactorialEx(6, sys.stdout, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL)
def new(cls, *args, **kwargs): return cls(*args, **kwargs) class Number(object): pass class IntegralNumber(int, Number): def toInt(self): return new (int, self) class InternalBase(object): def __init__(self, base): self.base = base.toInt() def getBase(self): return new (IntegralNumber, self.base) class MathematicsSystem(object): def __init__(self, ibase): Abstract @classmethod def getInstance(cls, ibase): try: cls.__instance except AttributeError: cls.__instance = new (cls, ibase) return cls.__instance class StandardMathematicsSystem(MathematicsSystem): def __init__(self, ibase): if ibase.getBase() != new (IntegralNumber, 2): raise NotImplementedError self.base = ibase.getBase() def calculateFactorial(self, target): result = new (IntegralNumber, 1) i = new (IntegralNumber, 2) while i <= target: result = result * i i = i + new (IntegralNumber, 1) return result print StandardMathematicsSystem.getInstance(new (InternalBase, new (IntegralNumber, 2))).calculateFactorial(new (IntegralNumber, 6))