Why is Project Euler say I am getting No. 20 wrong?

Here is the problem I am trying to solve: Euler 20.

`n!` means `n ⨉ (n - 1) ⨉ ... ⨉ 3 ⨉ 2 ⨉ 1`

For example, `10! = 10 ⨉ 9 ⨉ ... ⨉ 3 ⨉ 2 ⨉ 1 = 3628800`, and the sum of the digits in the number `10!` is `3 + 6 + 2 + 8 + 8 + 0 + 0 = 27`.

Find the sum of the digits in the number `100!`

I have tried this:

``````y = 1  #The actual number
sum = 0 #The sum of its digits.

def factorial(x): #Calculates the number using a recursive factorial algorithm
global y
y = y*x
if x > 1:
factorial(x-1)
else:
return 0

factorial(100) #Calculate 100! and the function will put it in y.

def count(): #Calculates the sum.
global y, sum
while y > 0:
currentDigit = int(y) % 10 #Find the remainder of the number gives the very last digit
sum = sum + currentDigit #Add that to the total sum.
y = int(y) / 10 #Divide y by 10 knocking of the 1s-digit place and putting the 10s digit in its place.
return sum #return the sum.

print(count()) #print the count.
``````

If I do `factorial(10)` instead of 100 I get 27 which is what the problem says I should get, but I get 675 for `factorial(100)` which the program says is wrong. What did I do wrong? I am not that familiar with Python, sorry if I made a stupid error.

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why are you using a global variable? – tekknolagi Nov 24 '11 at 5:13
@tekknolagi: Because I had trouble finding a replacement in Python for the keyword `static` in C++, so I decided just to make it global... Plus, I was more concerned with just getting the problem done. – Dair Nov 24 '11 at 5:14
For your own good, I would strongly encourage you not to take that attitude ("concerned with just getting the problem done"). The point of Project Euler is to learn to program, and using global variables the way you're doing it here is a terrible practice. Your `factorial` function should return its answer, not store it in a variable. – David Z Nov 24 '11 at 5:16
@outis: even that is overly complicated – sarnold Nov 24 '11 at 5:19
@outis: having explained tail recursion to more than a handful of people, I'm prepared to stand behind "it's complicated" -- beginners almost never grasp it on the first try. Or second. Plain recursion alone is enough trouble for most beginners. :) (Though I do agree that it is an important concept to grasp. +1 there. :) – sarnold Nov 24 '11 at 5:41

The problem lies in your implementation of `count`, specifically the line:

``````    y = int(y) / 10
``````

Since Python 3, `/` is true division. In Python 2.2 and later, you can get Python 3's division behavior with `from __future__ import division`. After executing the above line, `y` is a float. Python floats on most systems only have about 15 significant decimal digits (`sys.float_info.dig` will give you the precision for your system; note that there are actually 53 bits of precision, which is equal to 53 / log2(10) ≈ 15.955). Any decimal digit that `count` extracts after those significant ones is the result of rounding error and is a consequence of converting a base-2 float into base 10. Over a certain length, the middle digits won't contribute to the sum calculated by `count`.

``````[count(int('8' * 17 + str(k) + '0')) for k in range(1, 10)]
# [130, 130, 130, 130, 130, 130, 130, 130, 130]
import random
[count(int('8' * 17 + ('%05d' % random.randint(1,99999)) + '0')) for k in range(1, 10)]
# [146, 146, 146, 146, 146, 146, 146, 146, 146]
``````

The solution is to use `//` for integer division, at which point you can also remove the `int` conversions. While you're at it, you might as well make `y` a parameter to `count`, and make `sum` local. Otherwise, your global `sum` variable will hide the built-in `sum` function.

As for doing away with the global `y` in `factorial`, it's quite easy to pass an extra argument:

``````def factorial(x, p=1):
p *= x
if x > 1:
return factorial(x-1, p)
else:
return p
``````

This has the advantage of being tail-recursive. The standard python interpreter doesn't implement the tail call optimization, but it can be done with a decorator. Apply such a decorator to `factorial` and the result is a function that won't cause a stack overflow. This technique of passing an accumulation can be used for many other functions to create a tail-recursive function.

Alternatively, write an iterative version, which is a little more pythonic.

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Thank you so much it works now! – Dair Nov 24 '11 at 5:48

Here's an easy way to re-write your `factorial()` function so that it no longer relies on global variables:

``````>>> def fac(x):
...   if x > 1:
...     return x * fac(x-1)
...   else:
...     return 1
...
>>> fac(10)
3628800
>>> fac(100)
93326215443944152681699238856266700490715968264381621468592963895217599993229915608941463976156518286253697920827223758251185210916864000000000000000000000000L
``````

It relies upon returning a value and calling itself recursively to perform the calculation. Granted, to calculate 100! means the call-chain will be 100 levels deep, but for the clarity in this function, I think the tradeoff is well worth it. (There might be more robust ways to write this function -- handle negatives or non-integers better, for example.)

There's a few ways you can find the sum of the digits -- consider approaches that look at either the large number as a single string, iterate through all characters, and sum up the integer values of the digits and approaches that treat the number as a number, find the value of the lowest digit in its decimal representation, and removes that lowest digit once you've accounted for it. Both approaches work.

As for the actual error in your summer, I hope this is educational:

``````\$ python3.2 -c "print (755 / 10)"
75.5
\$ python2.7 -c "print (755 / 10)"
75
``````
-

Find the sum of the digits in the number 100!

``````def sumFactorial(n):
factorial=str(reduce(lambda x,y:x*y, range(n,0,-1)))
return sum(int(x) for x in factorial)

>>> sumFactorial(10)
27
>>> sumFactorial(100)
648
>>>
``````
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``````//In c++
#include<cstdio>
#include<cstring>
#include<iostream>
using namespace std;
int main()
{
int a[200];
int carry=0,temp,m=1,k=0;
int n;
cin>>n;
a[0]=1;
for(int i=1;i<=n;i++)
{
k=0;
for(int j=0;j<m;j++)
{
temp=a[j]*i+carry;
a[j]=temp%10;
carry=temp/10;

}
while(carry!=0)
a[m++]=carry%10,carry/=10;

}
long long ans=0;
for(int i=m-1;i>=0;i--)
{
ans+=a[i];
}
cout<<endl;
cout<<ans<<endl;
}
1.Array a[200] is used to store the digits of factorial.
2.Outer loop run from 1..100
3.varible m indicates no of digits in array or factorial
4.now lets take a example
take a simple multiplication
25 x 12
-------------
5 0
2 5
-------------
3 0 0
300- value stores in temp;
by taking modulo 10 we can get the last digit it is placed array
300/10 becomes carry.
``````
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Could you add an explanation of how this solves the problem? – Kmeixner Jun 2 at 17:14