# How to write the Fibonacci Sequence?

I had originally coded the program wrongly. Instead of returning the Fibonacci numbers between a range (ie. startNumber 1, endNumber 20 should = only those numbers between 1 & 20), I have written for the program to display all Fibonacci numbers between a range (ie. startNumber 1, endNumber 20 displays = First 20 Fibonacci numbers). I thought I had a sure-fire code. I also do not see why this is happening.

``````startNumber = int(raw_input("Enter the start number here "))
endNumber = int(raw_input("Enter the end number here "))

def fib(n):
if n < 2:
return n
return fib(n-2) + fib(n-1)

print map(fib, range(startNumber, endNumber))
``````

Someone pointed out in my Part II (which was closed for being a duplicate - https://stackoverflow.com/questions/504193/how-to-write-the-fibonacci-sequence-in-python-part-ii) that I need to pass the startNumber and endNumber through a generator using a while loop. Can someone please point me in the direction on how to do this? Any help is welcome.

I'm a learning programmer and I've run into a bit of a jumble. I am asked to write a program that will compute and display Fibonacci's Sequence by a user inputted start number and end number (ie. startNumber = 20 endNumber = 100 and it will display only the numbers between that range). The trick is to use it inclusively (which I do not know how to do in Python? - I'm assuming this means to use an inclusive range?).

What I have so far is no actual coding but rather:

• Write Fib sequence formula to infinite
• Display startNumber to endNumber only from Fib sequence.

I have no idea where to start and I am asking for ideas or insight into how to write this. I also have tried to write the Fib sequence forumla but I get lost on that as well.

There is lots of information about the Fibonacci Sequence on wikipedia and on wolfram. A lot more than you may need. Anyway it is a good thing to learn how to use these resources to find (quickly if possible) what you need.

## Write Fib sequence formula to infinite

In math, it's given in a recursive form: In programming, infinite doesn't exist. You can use a recursive form translating the math form directly in your language, for example in Python it becomes:

``````def F(n):
if n == 0: return 0
elif n == 1: return 1
else: return F(n-1)+F(n-2)
``````

Try it in your favourite language and see that this form requires a lot of time as n gets bigger. In fact, this is O(2n) in time.

Go on on the sites I linked to you and will see this (on wolfram): This one is pretty easy to implement and very, very fast to compute, in Python:

``````from math import sqrt
def F(n):
return ((1+sqrt(5))**n-(1-sqrt(5))**n)/(2**n*sqrt(5))
``````

An other way to do it is following the definition (from wikipedia):

The first number of the sequence is 0, the second number is 1, and each subsequent number is equal to the sum of the previous two numbers of the sequence itself, yielding the sequence 0, 1, 1, 2, 3, 5, 8, etc.

If your language supports iterators you may do something like:

``````def F():
a,b = 0,1
while True:
yield a
a, b = b, a + b
``````

## Display startNumber to endNumber only from Fib sequence.

Once you know how to generate Fibonacci Numbers you just have to cycle trough the numbers and check if they verify the given conditions.

Suppose now you wrote a f(n) that returns the n-th term of the Fibonacci Sequence (like the one with sqrt(5) )

In most languages you can do something like:

``````def SubFib(startNumber, endNumber):
n = 0
cur = f(n)
while cur <= endNumber:
if startNumber <= cur:
print cur
n += 1
cur = f(n)
``````

In python I'd use the iterator form and go for:

``````def SubFib(startNumber, endNumber):
for cur in F():
if cur > endNumber: return
if cur >= startNumber:
yield cur

for i in SubFib(10, 200):
print i
``````

My hint is to learn to read what you need. Project Euler (google for it) will train you to do so :P Good luck and have fun!

• You need to use a while loop, not map. Try to figure it out on your own, then come back with the code if you can't do it. I'm not lazy (the code is shorter than this comment). I'm doing that for you, try it out with the "while" hint ;) If you have problem with that come back again ;) – Andrea Ambu Feb 3 '09 at 11:56
• I'm back, lol. I got rid of the map(range) function and am using only a range(startNumber, endNumber) function. Now the problem I have is where to use the while statement. I try at the beginning of the function but of course there is a billin an done lines of error. Where should I be putting it? Thx – SD. Feb 3 '09 at 21:12
• Try to do, by hand, an example of input-output of your program (with a short range). Try then to figure out where your program is wrong. Try to convert the "by-hand method" in code. This is for exercise, to learn. I could put down two lines of code but I don't think you'll learn anything from them. – Andrea Ambu Feb 3 '09 at 23:11
• We should use `int(((1+sqrt(5))**n-(1-sqrt(5))**n)/(2**n*sqrt(5)))`, any ideas? @AndreaAmbu – lord63. j May 26 '15 at 13:41
• @lord63.j, you should only use that formula if you're aware that it starts deviating from the actual value when `n` is above 70 and blows up with an `OverflowError `when `n` is slightly above 600. Other approaches can handle an `n` of 1000 or more without blowing up or losing precision. – cdlane Sep 4 '17 at 20:54

# Efficient Pythonic generator of the Fibonacci sequence

I found this question while trying to get the shortest Pythonic generation of this sequence (later realizing I had seen a similar one in a Python Enhancement Proposal), and I haven't noticed anyone else coming up with my specific solution (although the top answer gets close, but still less elegant), so here it is, with comments describing the first iteration, because I think that may help readers understand:

``````def fib():
a, b = 0, 1
while True:            # First iteration:
a, b = b, a + b    # a will now be 1, and b will also be 1, (0 + 1)
``````

and usage:

``````for index, fibonacci_number in zip(range(10), fib()):
print('{i:3}: {f:3}'.format(i=index, f=fibonacci_number))
``````

prints:

``````  0:   0
1:   1
2:   1
3:   2
4:   3
5:   5
6:   8
7:  13
8:  21
9:  34
10:  55
``````

(For attribution purposes, I recently noticed a similar implementation in the Python documentation on modules, even using the variables `a` and `b`, which I now recall having seen before writing this answer. But I think this answer demonstrates better usage of the language.)

# Recursively defined implementation

The Online Encyclopedia of Integer Sequences defines the Fibonacci Sequence recursively as

F(n) = F(n-1) + F(n-2) with F(0) = 0 and F(1) = 1

Succinctly defining this recursively in Python can be done as follows:

``````def rec_fib(n):
'''inefficient recursive function as defined, returns Fibonacci number'''
if n > 1:
return rec_fib(n-1) + rec_fib(n-2)
return n
``````

But this exact representation of the mathematical definition is incredibly inefficient for numbers much greater than 30, because each number being calculated must also calculate for every number below it. You can demonstrate how slow it is by using the following:

``````for i in range(40):
print(i, rec_fib(i))
``````

# Memoized recursion for efficiency

It can be memoized to improve speed (this example takes advantage of the fact that a default keyword argument is the same object every time the function is called, but normally you wouldn't use a mutable default argument for exactly this reason):

``````def mem_fib(n, _cache={}):
'''efficiently memoized recursive function, returns a Fibonacci number'''
if n in _cache:
return _cache[n]
elif n > 1:
return _cache.setdefault(n, mem_fib(n-1) + mem_fib(n-2))
return n
``````

You'll find the memoized version is much faster, and will quickly exceed your maximum recursion depth before you can even think to get up for coffee. You can see how much faster it is visually by doing this:

``````for i in range(40):
print(i, mem_fib(i))
``````

(It may seem like we can just do the below, but it actually doesn't let us take advantage of the cache, because it calls itself before setdefault is called.)

``````def mem_fib(n, _cache={}):
'''don't do this'''
if n > 1:
return _cache.setdefault(n, mem_fib(n-1) + mem_fib(n-2))
return n
``````

## Recursively defined generator:

As I have been learning Haskell, I came across this implementation in Haskell:

``````fib@(0:tfib) = 0:1: zipWith (+) fib tfib
``````

The closest I think I can get to this in Python at the moment is:

``````from itertools import tee

def fib():
yield 0
yield 1
# tee required, else with two fib()'s algorithm becomes quadratic
f, tf = tee(fib())
next(tf)
for a, b in zip(f, tf):
yield a + b
``````

This demonstrates it:

``````[f for _, f in zip(range(999), fib())]
``````

It can only go up to the recursion limit, though. Usually, 1000, whereas the Haskell version can go up to the 100s of millions, although it uses all 8 GB of my laptop's memory to do so:

``````> length \$ take 100000000 fib
100000000
``````

### Consuming the iterator to get the nth fibonacci number

Question for the Fib() function which is based on iterator: what if you want to get the nth, for instance 10th fib number?

The itertools documentation has a recipe for this:

``````from itertools import islice

def nth(iterable, n, default=None):
"Returns the nth item or a default value"
return next(islice(iterable, n, None), default)
``````

and now:

``````>>> nth(fib(), 10)
55
``````
• About the last '''don't do this''' option, I don't understand why it would call itself before setdefault. Isn't setdefault supposed to return the value if n is a valid key ? Doc says "If key is in the dictionary, return its value. If not, insert key with a value of default and return default. default defaults to None." What am I missing ? – binithb May 21 '17 at 21:47
• @binithb the expression inside the `setdefault` call is evaluated before `setdefault` is. – Aaron Hall May 22 '17 at 0:04

Why not simply do the following?

``````x = [1,1]
for i in range(2, 10):
x.append(x[-1] + x[-2])
print(', '.join(str(y) for y in x))
``````

The idea behind the Fibonacci sequence is shown in the following Python code:

``````def fib(n):
if n == 1:
return 1
elif n == 0:
return 0
else:
return fib(n-1) + fib(n-2)
``````

This means that fib is a function that can do one of three things. It defines fib(1) == 1, fib(0) == 0, and fib(n) to be:

fib(n-1) + fib(n-2)

Where n is an arbitrary integer. This means that fib(2) for example, expands out to the following arithmetic:

``````fib(2) = fib(1) + fib(0)
fib(1) = 1
fib(0) = 0
# Therefore by substitution:
fib(2) = 1 + 0
fib(2) = 1
``````

We can calculate fib(3) the same way with the arithmetic shown below:

``````fib(3) = fib(2) + fib(1)
fib(2) = fib(1) + fib(0)
fib(2) = 1
fib(1) = 1
fib(0) = 0
# Therefore by substitution:
fib(3) = 1 + 1 + 0
``````

The important thing to realize here is that fib(3) can't be calculated without calculating fib(2), which is calculated by knowing the definitions of fib(1) and fib(0). Having a function call itself like the fibonacci function does is called recursion, and it's an important topic in programming.

This sounds like a homework assignment so I'm not going to do the start/end part for you. Python is a wonderfully expressive language for this though, so this should make sense if you understand math, and will hopefully teach you about recursion. Good luck!

Edit: One potential criticism of my code is that it doesn't use the super-handy Python function yield, which makes the fib(n) function a lot shorter. My example is a little bit more generic though, since not a lot of languages outside Python actually have yield.

• This is not a homework problem but wow thank you for the answer! I understand what I need to do but starting it and implementing is what I am stuck on now (especially with implementing user input values). Can you provide some insight into this? I keep getting a <function fib at 0x0141FAF0> error. – SD. Jan 30 '09 at 6:22
• I understand that you're trying very hard to implement a program that may be beyond your current ability. Having me write more code will not help you. You should try to hack around with my code until it works, and read more Python tutorials. Whitespace may be a problem, but I don't know that error. – James Thompson Jan 30 '09 at 6:39
• I understand. Is there any other idea that you think I may be missing? I understand if you cannot help however. I thank you for your time. – SD. Jan 30 '09 at 6:42
• Your <function fib at 0x0141FAF0> error may be the result of saying "fib" (which refers to the function itself) instead of "fib()" which will call the function. Best of luck. – Kiv Jan 30 '09 at 14:02
• Bear in mind that this naive recursive method of calculating Fibonacci numbers can get into stack overflow (not the site) real fast. For practical purposes, generate iteratively or use some sort of memoization or something. – David Thornley Jan 30 '09 at 15:33

Time complexity :

The caching feature reduces the normal way of calculating Fibonacci series from O(2^n) to O(n) by eliminating the repeats in the recursive tree of Fibonacci series : Code :

``````import sys

table = *1000

def FastFib(n):
if n<=1:
return n
else:
if(table[n-1]==0):
table[n-1] = FastFib(n-1)
if(table[n-2]==0):
table[n-2] = FastFib(n-2)
table[n] = table[n-1] + table[n-2]
return table[n]

def main():
print('Enter a number : ')
print(FastFib(num))

if __name__=='__main__':
main()
``````

This is quite efficient, using O(log n) basic arithmetic operations.

``````def fib(n):
return pow(2 << n, n + 1, (4 << 2*n) - (2 << n) - 1) % (2 << n)
``````

This one uses O(1) basic arithmetic operations, but the size of the intermediate results is large and so is not at all efficient.

``````def fib(n):
return (4 << n*(3+n)) // ((4 << 2*n) - (2 << n) - 1) & ((2 << n) - 1)
``````

This one computes X^n in the polynomial ring Z[X] / (X^2 - X - 1) using exponentiation by squaring. The result of that calculation is the polynomial Fib(n)X + Fib(n-1), from which the nth Fibonacci number can be read.

Again, this uses O(log n) arithmetic operations and is very efficient.

``````def mul(a, b):
return a*b+a*b+a*b, a*b+a*b

def fib(n):
x, r = (1, 0), (0, 1)
while n:
if n & 1: r = mul(r, x)
x = mul(x, x)
n >>= 1
return r
``````
• The first and third techniques are good. The second technique is off by 1; it effectively needs `n -= 1` to work correctly, and it also doesn't work with `n = 0`. In any case, it would really help me if a lot of context was added to explain how these are working, especially the first technique. I see you have a post at paulhankin.github.io/Fibonacci – Acumenus Dec 4 '16 at 9:09

Canonical Python code to print Fibonacci sequence:

``````a,b=1,1
while True:
print a,
a,b=b,a+b       # Could also use b=a+b;a=b-a
``````

For the problem "Print the first Fibonacci number greater than 1000 digits long":

``````a,b=1,1
i=1
while len(str(a))<=1000:
i=i+1
a,b=b,a+b

print i,len(str(a)),a
``````

We know that And that The n-th power of that matrix gives us: So we can implement a function that simply computes the power of that matrix to the n-th -1 power.

as all we know the power a^n is equal to So at the end the fibonacci function would be O( n )... nothing really different than an easier implementation if it wasn't for the fact that we also know that `x^n * x^n = x^2n` and the evaluation of `x^n` can therefore be done with complexity O( log n )

Here is my fibonacci implementation using swift programming language:

``````struct Mat {
var m00: Int
var m01: Int
var m10: Int
var m11: Int
}

func pow(m: Mat, n: Int) -> Mat {
guard n > 1 else { return m }
let temp = pow(m: m, n: n/2)

var result = matMultiply(a: temp, b: temp)
if n%2 != 0 {
result = matMultiply(a: result, b: Mat(m00: 1, m01: 1, m10: 1, m11: 0))
}
return result
}

func matMultiply(a: Mat, b: Mat) -> Mat {
let m00 = a.m00 * b.m00 + a.m01 * b.m10
let m01 = a.m00 * b.m01 + a.m01 * b.m11
let m10 = a.m10 * b.m00 + a.m11 * b.m10
let m11 = a.m10 * b.m01 + a.m11 * b.m11

return Mat(m00: m00, m01: m01, m10: m10, m11: m11)
}

func fibonacciFast(n: Int) -> Int {

guard n > 0 else { return 0 }
let m = Mat(m00: 1, m01: 1, m10: 1, m11: 0)

return pow(m: m, n: n-1).m00
}
``````

This has complexity O( log n ). We compute the oìpower of Q with exponent n-1 and then we take the element m00 which is Fn+1 that at the power exponent n-1 is exactly the n-th Fibonacci number we wanted.

Once you have the fast fibonacci function you can iterate from start number and end number to get the part of the Fibonacci sequence you are interested in.

``````let sequence = (start...end).map(fibonacciFast)
``````

of course first perform some check on start and end to make sure they can form a valid range.

I know the question is 8 years old, but I had fun answering anyway. :)

Fibonacci sequence is: `1, 1, 2, 3, 5, 8, ...`.

That is `f(1) = 1`, `f(2) = 1`, `f(3) = 2`, `...`, `f(n) = f(n-1) + f(n-2)`.

My favorite implementation (simplest and yet achieves a light speed in compare to other implementations) is this:

``````def fibonacci(n):
a, b = 0, 1
for _ in range(1, n):
a, b = b, a + b
return b
``````

Test

``````>>> [fibonacci(i) for i in range(1, 10)]
[1, 1, 2, 3, 5, 8, 13, 21, 34]
``````

Timing

``````>>> %%time
>>> fibonacci(100**3)
CPU times: user 9.65 s, sys: 9.44 ms, total: 9.66 s
Wall time: 9.66 s
``````

Edit: an example visualization for this implementations.

use recursion:

``````def fib(n):
if n == 0:
return 0
elif n == 1:
return 1
else:
return fib(n-1) + fib(n-2)
x=input('which fibonnaci do you want?')
print fib(x)
``````

Another way of doing it:

``````a,n=[0,1],10
map(lambda i: reduce(lambda x,y: a.append(x+y),a[-2:]),range(n-2))
``````

Assigning list to 'a', assigning integer to 'n' Map and reduce are 2 of three most powerful functions in python. Here map is used just to iterate 'n-2' times. a[-2:] will get the last two elements of an array. a.append(x+y) will add the last two elements and will append to the array

this is an improvement to mathew henry's answer:

``````def fib(n):
a = 0
b = 1
for i in range(1,n+1):
c = a + b
print b
a = b
b = c
``````

the code should print b instead of printing c

output: 1,1,2,3,5 ....

Using for loop and print just the result

``````def fib(n:'upto n number')->int:
if n==0:
return 0
elif n==1:
return 1
a=0
b=1
for i in range(0,n-1):
b=a+b
a=b-a
return b
``````

Result

``````>>>fib(50)
12586269025
>>>>
>>> fib(100)
354224848179261915075
>>>
``````

Print the `list` containing all the numbers

``````def fib(n:'upto n number')->int:
l=[0,1]
if n==0:
return l
elif n==1:
return l
a=0
b=1
for i in range(0,n-1):
b=a+b
a=b-a
l.append(b)
return l
``````

Result

``````>>> fib(10)
[0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55]
``````

These all look a bit more complicated than they need to be. My code is very simple and fast:

``````def fibonacci(x):

List = []
f = 1
List.append(f)
List.append(f) #because the fibonacci sequence has two 1's at first
while f<=x:
f = List[-1] + List[-2]   #says that f = the sum of the last two f's in the series
List.append(f)
else:
List.remove(List[-1])  #because the code lists the fibonacci number one past x. Not necessary, but defines the code better
for i in range(0, len(List)):
print List[i]  #prints it in series form instead of list form. Also not necessary
``````
• Dynamic programming FTW! fibonacci(100000000000000000000000000000000000000000000000000000000000000000000000000000) responds almost instantly – Hans Sep 24 '14 at 20:08
• Somehow I doubt it. – Lanaru Mar 18 '15 at 20:09
• What about starting the list as [0, 1] (i.e. List.append(0); List.append(1)) to avoid the remove command after the else? ... and the fibonacci number should be better indexed as fibonacci(10) returns the fibonacci numbers below 10, not the 10-th one. – SeF Apr 15 '18 at 14:19

OK.. after being tired of referring all lengthy answers, now find the below sort & sweet, pretty straight forward way for implementing Fibonacci in python. You can enhance it it the way you want by getting an argument or getting user input…or change the limits from 10000. As you need……

``````def fibonacci():
start = 0
i = 1
lt = []
lt.append(start)
while start < 10000:
start += i
lt.append(start)
i = sum(lt[-2:])
lt.append(i)
print "The Fibonaccii series: ", lt
``````

This approach also performs good. Find the run analytics below

``````In : %timeit fibonacci
10000000 loops, best of 3: 26.3 ns per loop
``````
``````import time
start_time = time.time()

#recursive solution
def fib(x, y, upperLimit):
return [x] + fib(y, (x+y), upperLimit) if x < upperLimit else [x]

#To test :

print(fib(0,1,40000000000000))
print("run time: " + str(time.time() - start_time))
``````

Results

[0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584, 4181, 6765, 10946, 17711, 28657, 46368, 75025, 121393, 196418, 317811, 514229, 832040, 1346269, 2178309, 3524578, 5702887, 9227465, 14930352, 24157817, 39088169, 63245986, 102334155, 165580141, 267914296, 433494437, 701408733, 1134903170, 1836311903, 2971215073, 4807526976, 7778742049, 12586269025, 20365011074, 32951280099, 53316291173, 86267571272, 139583862445, 225851433717, 365435296162, 591286729879, 956722026041, 1548008755920, 2504730781961, 4052739537881, 6557470319842, 10610209857723, 17167680177565, 27777890035288, 44945570212853]

run time: 0.04298138618469238

there is a very easy method to realize that!

you can run this code online freely by using http://www.learnpython.org/

``````# Set the variable brian on line 3!

def fib(n):
"""This is documentation string for function. It'll be available by fib.__doc__()
Return a list containing the Fibonacci series up to n."""
result = []
a = 0
b = 1
while a < n:
result.append(a)  # 0 1 1 2 3 5  8  (13) break
tmp_var = b       # 1 1 2 3 5 8  13
b = a + b         # 1 2 3 5 8 13 21
a = tmp_var       # 1 1 2 3 5 8  13
# print(a)
return result

print(fib(10))
# result should be this: [0, 1, 1, 2, 3, 5, 8]
``````
• a easy way to realize Fibonacci series just using iterator, without any complex Recursion data structure! – xgqfrms Sep 21 '16 at 9:53

Just for fun, in Python 3.8+ you can use an assignment expression (aka the walrus operator) in a list comprehension, e.g.:

``````>>> a, b = 0, 1
>>> [a, b] + [b := a + (a := b) for _ in range(8)]  # first 10 Fibonacci numbers
[0, 1, 1, 2, 3, 5, 8, 13, 21, 34]
``````

An assignment expression allows you to assign a value to a variable and return it in the same expression. Therefore, the expression

``````b := a + (a := b)
``````

is equivalent to executing

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

and returning the value of `b`.

15 minutes into a tutorial I used when learning Python, it asked the reader to write a program that would calculate a Fibonacci sequence from 3 input numbers (first Fibonacci number, second number, and number at which to stop the sequence). The tutorial had only covered variables, if/thens, and loops up to that point. No functions yet. I came up with the following code:

``````sum = 0
endingnumber = 1

print "\n.:Fibonacci sequence:.\n"

firstnumber = input("Enter the first number: ")
secondnumber = input("Enter the second number: ")
endingnumber = input("Enter the number to stop at: ")

if secondnumber < firstnumber:

print "\nSecond number must be bigger than the first number!!!\n"

else:

while sum <= endingnumber:

print firstnumber

if secondnumber > endingnumber:

break

else:

print secondnumber
sum = firstnumber + secondnumber
firstnumber = sum
secondnumber = secondnumber + sum
``````

As you can see, it's really inefficient, but it DOES work.

``````def fib():
a,b = 1,1
num=eval(input("Please input what Fib number you want to be calculated: "))
num_int=int(num-2)
for i in range (num_int):
a,b=b,a+b
print(b)
``````
• `eval(input())` isn't needed here; I think `int(input())` in the case is better. – GingerPlusPlus Oct 26 '14 at 14:51

Just going through http://projecteuler.net/problem=2 this was my take on it

``````# Even Fibonacci numbers
# Problem 2

def get_fibonacci(size):
numbers = [1,2]
while size > len(numbers):
next_fibonacci = numbers[-1]+numbers[-2]
numbers.append(next_fibonacci)

print numbers

get_fibonacci(20)
``````
``````def fib(x, y, n):
if n < 1:
return x, y, n
else:
return fib(y, x + y, n - 1)

print fib(0, 1, 4)
(3, 5, 0)

#
def fib(x, y, n):
if n > 1:
for item in fib(y, x + y, n - 1):
yield item
yield x, y, n

f = fib(0, 1, 12)
f.next()
(89, 144, 1)
f.next()
55
``````

Maybe this will help

``````def fibo(n):
result = []
a, b = 0, 1
while b < n:
result.append(b)
a, b = b, b + a
return result
``````

based on classic fibonacci sequence and just for the sake of the one-liners

if you just need the number of the index, you can use the reduce (even if reduce it's not best suited for this it can be a good exercise)

``````def fibonacci(index):
return reduce(lambda r,v: r.append(r[-1]+r[-2]) or (r.pop(0) and 0) or r , xrange(index), [0, 1])
``````

and to get the complete array just remove the or (r.pop(0) and 0)

``````reduce(lambda r,v: r.append(r[-1]+r[-2]) or r , xrange(last_index), [0, 1])
``````

How about this one? I guess it's not as fancy as the other suggestions because it demands the initial specification of the previous result to produce the expected output, but I feel is a very readable option, i.e., all it does is to provide the result and the previous result to the recursion.

``````#count the number of recursions
num_rec = 0

def fibonacci(num, prev, num_rec, cycles):

num_rec = num_rec + 1

if num == 0 and prev == 0:
result  = 0;
num = 1;
else:
result = num + prev

print(result)

if num_rec == cycles:
print("done")
else:
fibonacci(result, num, num_rec, cycles)

#Run the fibonacci function 10 times
fibonacci(0, 0, num_rec, 10)
``````

Here's the output:

``````0
1
1
2
3
5
8
13
21
34
done
``````

Basically translated from Ruby:

``````def fib(n):
a = 0
b = 1
for i in range(1,n+1):
c = a + b
print c
a = b
b = c
``````

...

``````def fib(lowerbound, upperbound):
x = 0
y = 1
while x <= upperbound:
if (x >= lowerbound):
yield x
x, y = y, x + y

startNumber = 10
endNumber = 100
for fib_sequence in fib(startNumber, endNumber):
print "And the next number is... %d!" % fib_sequence
``````

A more detailed explanation of how Memoization works for Fibonacci sequence.

``````# Fibonacci sequence Memoization

fib_cache = {0:0, 1:1}

def fibonacci(n):
if n < 0:
return -1
if fib_cache.has_key(n):
print "Fibonacci sequence for %d = %d cached" % (n, fib_cache[n])
return fib_cache[n]
else:
fib_cache[n] = fibonacci(n - 1) + fibonacci(n - 2)
return fib_cache[n]

if __name__ == "__main__":
print fibonacci(6)
print fib_cache
# fibonacci(7) reuses fibonacci(6) and fibonacci(5)
print fibonacci(7)
print fib_cache
``````

I was trying to avoid a recursive function to solve this problem, so I took an iterative approach. I was originally doing a memoized recursive function but kept hitting max recursive depth. I also had strict memory goals so you will see me keeping the array as small as I can during the looping process only keeping 2-3 values in the array at any time.

``````def fib(n):
fibs = [1, 1] # my starting array
for f in range(2, n):
fibs.append(fibs[-1] + fibs[-2]) # appending the new fib number
del fibs # removing the oldest number
return fibs[-1] # returning the newest fib

print(fib(6000000))
``````

Getting the 6 millionth fibonacci number takes about 282 seconds on my machine while the 600k fibonacci takes only 2.8 seconds. I was unable to obtain such large fibonacci numbers with a recursive function, even a memoized one.

Recursion adds time. To eliminate loops, first `import math`. Then use `math.sqrt` and golden ratio in a function:

``````#!/usr/bin/env python3

import math

def fib(n):
gr = (1 + math.sqrt(5)) / 2
fib_first = (gr**n - (1 - gr)**n) / math.sqrt(5)
return int(round(fib_first))

fib_final = fib(100)

print(fib_final)
``````
• Once a recursive script (looping) exceeds maximum recursion depth, the script will crash with a `RuntimeError` due to Python's finite stack size. The dreaded stack overflow. – noobninja Aug 29 '16 at 23:22
• It should be noted (in the documention string?) that this solution starts to lose precision starting around `fib(70)` and above since Python's `math.sqrt(5)` is only approximate. – cdlane Sep 4 '17 at 21:06
• Python: Internal Integer Object Array Python's internal integer object array runs out at 256. – noobninja Sep 5 '17 at 12:40