# Single Statement Fibonacci [duplicate]

Possible Duplicate:
Fibonacci numbers, with an one-liner in Python 3?

It may be very easy thing, but I am very new to Python. I came up with this single statement Fibonacci.

``````[fibs.append(fibs[-2]+fibs[-1]) for i in xrange(1000)]
``````

Not really single statement, though. I need to initialise the list, `fibs`, before firing this statement i.e. `fibs = [0, 1]`.

Now, I have 2 questions,

1. How can we get rid of this list initialisation statement, `fibs = [0, 1]`, in order to make it really single statement?

2. Original statement prints `None` n times; where n is the number passed in `xrange()`. Is there any way to avoid that altogether? Or better if the statement can print the series, instead. Then we don't need to print `fibs` explicitly.

[Edited]

Or do we have any alternative to `list.append()` which returns the `list` it appends to?

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## marked as duplicate by Adeel Ansari, Roddy, Cédric Julien, Ken White, Cody GrayJun 28 '11 at 11:12

Why does it have to be a single statement? A generator would be much more suitable in this situation. –  Felix Kling Jun 28 '11 at 9:27
@Felix: Just playing, it doesn't have to be. –  Adeel Ansari Jun 28 '11 at 9:30
@utdemir: Thanks buddy. –  Adeel Ansari Jun 28 '11 at 9:43

Well, this is not idiomatic at all. What you are doing here is using a list comprehension as a shortcut for a `for` loop. Though Python's comprehensions can have side effects, Python is not designed for this. I can't think of no way to get this to work and it is probably a good thing.

For your 2), consider that you are actually creating a list which items are return values of the call `fibs.append(fibs[-2]+fibs[-1])` which is a side effect method and thus return `None`. See the doc for details.

Nice try but this is not what Python is for :)

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Suppose if it were implemented as, where `append()` returns the `list`. Then it would have been possible to do something like this, `list.append().append().append()`. I don't see any problem with this. –  Adeel Ansari Jun 28 '11 at 9:56
@Adeel Ansari It's just that it is not idiomatic, that's all. Python is as much a coding style as a language. As for why side effects return `None`, see stackoverflow.com/questions/4567409/…. To do chained append, consider docs.python.org/dev/py3k/library/… sequence `+` operator. –  Evpok Jun 28 '11 at 10:08
Evpok: Thanks, I do agree with the first. For 2nd I came up with a dirty work-around, as dirty as I got 2 negative votes :). Folks doesn't understand that it was just for fun. Anyways, +1 for your inputs. –  Adeel Ansari Jun 29 '11 at 2:28
Dirty Python code is evil, but fun is excuse enough. Thanks :) –  Evpok Jun 29 '11 at 7:14
``````def fib(n):
return (n in (0,1) and [n] or [fib(n-1) + fib(n-2)])[0]
``````

try this out

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if you want you can also use a lambda expression like this one: lambda n: (n in (0,1) and [n] or [fib(n-1) + fib(n-2)])[0] but you better understand how it works :) –  Samuele Mattiuzzo Jun 28 '11 at 9:32
Firstly, its very slow, as you can see. Secondly, I know we can come up with a function/method and then keep calling that as a single statement. That is not what I want. Thirdly, your solution is just giving me the last value, not the complete series. –  Adeel Ansari Jun 28 '11 at 9:34
@Adeel: I know its not what you are looking for but speaking performance...you should try this: return ((1+math.sqrt(5))**n-(1-math.sqrt(5))**n)/(2nmath.sqrt(5))* –  maozet Jun 28 '11 at 9:59
@Adeel, maozet This is known as Binet's Formula and it is what I implemented in another answer. –  Zéychin Jun 28 '11 at 10:12

This works:

``````for n in range(1000):
print(0.4472135954999579392818347337462552470881236719223051448541*(pow(1.6180339887498948482045868343656381177203091798057628621354,n) - pow(-0.618033988749894848204586834365638117720309179805762862135,n)))
``````

This is an implementation of Binet's Formula. http://en.wikipedia.org/wiki/Fibonacci_number#Relation_to_the_golden_ratio

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It should work for Python's `int` numbers, but it is still precision-dependant and I wouldn't rely on it. Nice thought, though :) –  Evpok Jun 28 '11 at 9:47
If Python supported(supports?) symbolic Mathematics, this would be solvable exactly for all n >=1 within limitations of the largest available variable size. (I'm not a Python developer, here. :P.) –  Zéychin Jun 28 '11 at 9:52
In O(1) time, mind you. –  Zéychin Jun 28 '11 at 9:57
O(1)?! `pow` is O(log n)! –  Evpok Jun 28 '11 at 10:01
Although +1 for the implimentation –  Jakob Bowyer Jun 28 '11 at 10:07