# Project Euler #2 in “Python”

I am an absolute beginner here. I was giving the questions on Project Euler a try in Python. Can you please point out where does my code go wrong?

Q) Each new term in the Fibonacci sequence is generated by adding the previous two terms. By starting with 1 and 2, the first 10 terms will be:

1, 2, 3, 5, 8, 13, 21, 34, 55, 89, ...

By considering the terms in the Fibonacci sequence whose values do not exceed four million, find the sum of the even-valued terms.

``````def fib(a):
if ((a==0) or (a==1)):
return 1
else:
return((fib(a-1))+(fib(a-2)))
r=0
sum=0
while (fib(r))<4000000:
if(((fib(r))%2)==0):
sum+=fib(r)
print(sum)
``````
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That's an expensive way of creating Fibonacci numbers. –  alex Apr 24 '14 at 2:11
What is the problem with your code? –  Matt Ball Apr 24 '14 at 2:11
First, you don't increment r so your code will never exit the while loop. Second, using recursion is an expensive way to achieve what you want. –  Rod Xavier Apr 24 '14 at 2:13
Oh yes! Stupid me. I'll increment r. And, use something better than recursion. Thanks a lot. @RodXavier –  Ashtrix Apr 24 '14 at 2:15
Moreover, you compute `fib(r)` twice! Store it in a variable, don't compute it twice at least within the same loop. –  devnull Apr 24 '14 at 2:17

Your code isn't wrong, it's just too slow. In order to solve Project Euler problems, not only does your code have to be correct, but your algorithm must be efficient.

Your fibonacci computation is extremely expensive - that is, recursively trying to attain the next fibonacci number runs in O(2^n) time - far too long when you want to sum numbers with a limit of four million.

A more efficient implementation in Python is as follows:

``````x = 1
y = 1
z = 0
result = 0

while z < 4000000:
z = (x+y)
if z%2 == 0:
result = result + z

#next iteration

x = y
y = z

print result
``````
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This code is tagged python for a reason. –  A.J. Apr 24 '14 at 2:15
Thanks a lot. I followed what you meant. I want to give another try. I want to stick to Python though. I'll try and figure out the algorithm that you've used and generate my Python code. –  Ashtrix Apr 24 '14 at 2:17
Actually the code executes in 9 seconds on my laptop with cpython and 1.2 with pypy. It is an inefficient algorithm, but you don't have to worry about that quite yet. –  Peter Micheal Lacey-Bordeaux Apr 24 '14 at 13:56

this definetly is not the only way- but another way of doing it.

``````def fib(number):
series = [1,1]
lastnum = (series[len(series)-1]+series[len(series)-2])
_sum = 0
while lastnum < number:
if lastnum % 2 == 0:
_sum += lastnum
series.append(lastnum)
lastnum = (series[len(series)-1] +series[len(series)-2])
return series,_sum
``````
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You should use generator function, here's the gist:

``````def fib(max):

a, b = 0, 1

while a < max:

yield a

a,b = b, a+b
``````

Now call this function from the shell, or write a function after this calling the fib function, your problem will get resolved.It took me 7 months to solve this problem

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This is probably the the most efficient way to do it.

``````a, b = 1, 1
total = 0
while a <= 4000000:
if a % 2 == 0:
total += a
a, b = b, a+b
print (total)
``````
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A slightly more efficient implementation would use that exactly every third Fibonacci number is even to do a little loop-unrolling and elimation of the if-statement. Even more efficient is to find the recursion formula for the sum of even elements, and its solution 0.5*(F[(n//3)*3+2]-1), (convention F[0]=0, F[1]=1) and use a halving-and-squaring approach to compute the single Fibonacci number in this formula. –  LutzL May 5 '14 at 14:34

Using recursion might work for smaller numbers, but since you're testing every case up to 4000000, you might want to store the values that you've already found into values. You can look for this algorithm in existing answers.

Another way to do this is to use Binet's formula. This formula will always return the nth Fibonacci number. You can read more about this on MathWorld.

Note that even numbered Fibonacci numbers occur every three elements in the sequence. You can use:

``````def binet(n):
""" Gets the nth Fibonacci number using Binet's formula """
return int((1/sqrt(5))*(pow(((1+sqrt(5))/2),n)-pow(((1-sqrt(5))/2),n)));

s = 0; # this is the sum
i = 3;
while binet(i)<=4000000:
s += binet(i);
i += 3; # increment by 3 gives only even-numbered values

print(s);
``````
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You may try this dynamic program too, worked faster for me

``````dict = {}
def fib(x):
if x in dict:
return dict[x]
if x==1:
f = 1
elif x==2:
f = 2
else:
f = fib(x-1) + fib(x-2)
dict[x]=f
return f

i = 1
su = 0
fin = 1

while fin < 4000000:
fin = fib(i)
if fin%2 == 0:
su += fib(i)
i+=1

print (su)
``````
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