370

I have this tail recursive function here:

def recursive_function(n, sum):
    if n < 1:
        return sum
    else:
        return recursive_function(n-1, sum+n)

c = 998
print(recursive_function(c, 0))

It works up to n=997, then it just breaks and spits out a RecursionError: maximum recursion depth exceeded in comparison. Is this just a stack overflow? Is there a way to get around it?

  • 3
    See also stackoverflow.com/questions/5061582/… – Thomas Ahle Apr 28 '14 at 19:09
  • 6
    memoization could speed up your function and increase its effective recursive depth by making previously calculated values terminate instead of increasing the stack size. – Cyoce Jan 11 '16 at 18:47
  • 2
    The recursion limit is usually 1000. – Boris Apr 24 '19 at 7:29
  • 1
    @tonix the interpreter adds a stack frame (the line <n>, in <module> in stack traces) and this code takes 2 stack frames for n=1 (because the base case is n < 1, so for n=1 it still recurses). And I guess the recursion limit is not inclusive, as in it's "error when you hit 1000" not "error if you exceed 1000 (1001)". 997 + 2 is less than 1000 so it works 998 + 2 doesn't because it hits the limit. – Boris Dec 15 '19 at 19:00
  • 1
    @tonix no. recursive_function(997) works, it breaks at 998. When you call recursive_function(998) it uses 999 stack frames and 1 frame is added by the interpreter (because your code is always run as if it's part of top level module), which makes it hit the 1000 limit. – Boris Dec 15 '19 at 19:49

17 Answers 17

417

It is a guard against a stack overflow, yes. Python (or rather, the CPython implementation) doesn't optimize tail recursion, and unbridled recursion causes stack overflows. You can check the recursion limit with sys.getrecursionlimit and change the recursion limit with sys.setrecursionlimit, but doing so is dangerous -- the standard limit is a little conservative, but Python stackframes can be quite big.

Python isn't a functional language and tail recursion is not a particularly efficient technique. Rewriting the algorithm iteratively, if possible, is generally a better idea.

115

Looks like you just need to set a higher recursion depth:

import sys
sys.setrecursionlimit(1500)
  • In my case i forgot the return statement in the base case and it went on to exceed 1000. Python started throwing this exception and i was amazed, because i was sure about the no. of stacks its going to create to run it. – vijayraj34 May 19 '19 at 8:07
51

It's to avoid a stack overflow. The Python interpreter limits the depths of recursion to help you avoid infinite recursions, resulting in stack overflows. Try increasing the recursion limit (sys.setrecursionlimit) or re-writing your code without recursion.

From the Python documentation:

sys.getrecursionlimit()

Return the current value of the recursion limit, the maximum depth of the Python interpreter stack. This limit prevents infinite recursion from causing an overflow of the C stack and crashing Python. It can be set by setrecursionlimit().

  • On my Anaconda x64, 3.5 Python on Windows, the default limit is 1000. – Guillaume Chevalier Dec 4 '15 at 21:48
25

If you often need to change the recursion limit (e.g. while solving programming puzzles) you can define a simple context manager like this:

import sys

class recursionlimit:
    def __init__(self, limit):
        self.limit = limit
        self.old_limit = sys.getrecursionlimit()

    def __enter__(self):
        sys.setrecursionlimit(self.limit)

    def __exit__(self, type, value, tb):
        sys.setrecursionlimit(self.old_limit)

Then to call a function with a custom limit you can do:

with recursionlimit(1500):
    print(fib(1000, 0))

On exit from the body of the with statement the recursion limit will be restored to the default value.

  • You also want to up the process' recursion limit with resource. Without it, you'll get a Segmentation Fault and the whole Python process will crash if you setrecursionlimit too high and try to use the new limit (about 8 megabytes of stack frames, which translates to ~30,000 stack frames with the simple function above, on my laptop). – Boris Dec 28 '19 at 19:35
16

Use a language that guarantees tail-call optimisation. Or use iteration. Alternatively, get cute with decorators.

  • 31
    That's rather throwing the baby out with the bathwater. – Russell Borogove Jul 24 '10 at 0:09
  • 3
    @Russell: Only one of the options I offered advises this. – Marcelo Cantos Jul 24 '10 at 3:22
  • "Get cute with decorators" isn't exactly an option. – Mr. B Dec 16 '19 at 19:56
  • @Mr.B unless you need more than ulimit -s of stack frames, yes it is stackoverflow.com/a/50120316 – Boris Dec 28 '19 at 19:22
13

resource.setrlimit must also be used to increase the stack size and prevent segfault

The Linux kernel limits the stack of processes.

Python stores local variables on the stack of the interpreter, and so recursion takes up stack space of the interpreter.

If the Python interpreter tries to go over the stack limit, the Linux kernel makes it segmentation fault.

The stack limit size is controlled with the getrlimit and setrlimit system calls.

Python offers access to those system calls through the resource module.

import resource
import sys

print resource.getrlimit(resource.RLIMIT_STACK)
print sys.getrecursionlimit()
print

# Will segfault without this line.
resource.setrlimit(resource.RLIMIT_STACK, [0x10000000, resource.RLIM_INFINITY])
sys.setrecursionlimit(0x100000)

def f(i):
    print i
    sys.stdout.flush()
    f(i + 1)
f(0)

Of course, if you keep increasing ulimit, your RAM will run out, which will either slow your computer to a halt due to swap madness, or kill Python via the OOM Killer.

From bash, you can see and set the stack limit (in kb) with:

ulimit -s
ulimit -s 10000

The default value for me is 8Mb.

See also:

Tested on Ubuntu 16.10, Python 2.7.12.

  • 1
    Attempting to set rlimit_stack after Stack Clash remediations may result in failure or related problems. Also see Red Hat Issue 1463241 – jww Jun 21 '17 at 16:35
  • I used this (the Python resource part) to help my implementation of Kosaraju's algorithm on professor Tim Roughgarden's mean (huge) dataset. My implementation worked on small sets, certainly the issue with a large dataset was the recursion/stack limit... Or was it? Well, yes it was! Thanks! – nilo Jan 28 '19 at 8:04
9

I realize this is an old question but for those reading, I would recommend against using recursion for problems such as this - lists are much faster and avoid recursion entirely. I would implement this as:

def fibonacci(n):
    f = [0,1,1]
    for i in xrange(3,n):
        f.append(f[i-1] + f[i-2])
    return 'The %.0fth fibonacci number is: %.0f' % (n,f[-1])

(Use n+1 in xrange if you start counting your fibonacci sequence from 0 instead of 1.)

  • 13
    why use O(n) space when you can use O(1)? – Janus Troelsen Mar 12 '14 at 9:11
  • 11
    Just in case the O(n) space comment was confusing: don't use a list. List will keep all the values when all you need is the nth value. A simple algorithm would be to keep the last two fibonacci numbers and add them until you get to the one you need. There are better algorithms too. – Milimetric Jul 14 '14 at 19:12
  • 3
    @Mathime: xrange is called simply range, in Python 3. – Eric O Lebigot Aug 3 '16 at 9:50
  • 1
    @EOL I'm aware of this – Mathime Aug 3 '16 at 9:51
  • 6
    @Mathime I was making things explicit for those reading these comments. – Eric O Lebigot Aug 3 '16 at 9:54
9

Of course Fibonacci numbers can be computed in O(n) by applying the Binet formula:

from math import floor, sqrt

def fib(n):                                                     
    return int(floor(((1+sqrt(5))**n-(1-sqrt(5))**n)/(2**n*sqrt(5))+0.5))

As the commenters note it's not O(1) but O(n) because of 2**n. Also a difference is that you only get one value, while with recursion you get all values of Fibonacci(n) up to that value.

  • 8
    There is no maximum size of a long in python. – pppery Nov 21 '15 at 18:14
  • 8
    It's worth noting that this fails for larger n because of floating point imprecision - the difference between (1+sqrt(5))**n and (1+sqrt(5))**(n+1) becomes less than 1 ulp, so you start getting incorrect results. – user2508324 Jul 7 '16 at 14:02
  • 2
    There are actually no big integers in NumPy… – Eric O Lebigot Aug 3 '16 at 9:52
  • @Mego What? It's the difference between (1+sqrt(5))**n and ((1+sqrt(5))**n)+1 that becomes less than 1 ulp! (small typo) Also, {@}rwst That's not O(1)! Calculating 2**n takes at least O(n) time. – user202729 Jan 5 '18 at 1:43
  • 3
    @user202729 That's not true, calculating 2**n is effectively O(log(n)) using Exponentiattion by squaring. – Sam Feb 18 '18 at 18:02
6

I had a similar issue with the error "Max recursion depth exceeded". I discovered the error was being triggered by a corrupt file in the directory I was looping over with os.walk. If you have trouble solving this issue and you are working with file paths, be sure to narrow it down, as it might be a corrupt file.

  • 2
    The OP does give his code, and his experiment is reproducible at will. It does not involve corrupt files. – T. Verron Mar 1 '15 at 19:25
  • 5
    You're right, but my answer isn't geared towards the OP, since this was over four years ago. My answer is aimed to help those with MRD errors indirectly caused by corrupt files - since this is one of the first search results. It helped someone, since it was up voted. Thanks for the down vote. – Tyler Mar 2 '15 at 20:36
  • 2
    This was the only thing I found anywhere when searching for my issue that connected a "max recursion depth" traceback to a corrupted file. Thanks! – Jeff Jul 18 '17 at 17:23
4

Use generators?

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

fibs = fib() #seems to be the only way to get the following line to work is to
             #assign the infinite generator to a variable

f = [fibs.next() for x in xrange(1001)]

for num in f:
        print num

above fib() function adapted from: http://intermediatepythonista.com/python-generators

  • 1
    the reason for having to assign a generator to a variable is because [fibs().next() for ...] would make a new generator each time. – tox123 Aug 10 '16 at 19:02
4

If you want to get only few Fibonacci numbers, you can use matrix method.

from numpy import matrix

def fib(n):
    return (matrix('0 1; 1 1', dtype='object') ** n).item(1)

It's fast as numpy uses fast exponentiation algorithm. You get answer in O(log n). And it's better than Binet's formula because it uses only integers. But if you want all Fibonacci numbers up to n, then it's better to do it by memorisation.

  • Sadly you can't use numpy in most competitive programming judges. But yes sir, your solution is my favorite. I've used the matrix soluction for some problems. It is the best solution when you need a very large fibonacci number and you can't use a modulus. If you are allowed to use a modulus, the pisano period the better way to do it. – mentatkgs Jun 9 '18 at 1:49
2

Many recommend that increasing recursion limit is a good solution however it is not because there will be always limit. Instead use an iterative solution.

def fib(n):
    a,b = 1,1
    for i in range(n-1):
        a,b = b,a+b
    return a
print fib(5)
2

As @alex suggested, you could use a generator function to do this sequentially instead of recursively.

Here's the equivalent of the code in your question:

def fib(n):
    def fibseq(n):
        """ Iteratively return the first n Fibonacci numbers, starting from 0. """
        a, b = 0, 1
        for _ in xrange(n):
            yield a
            a, b = b, a + b

    return sum(v for v in fibseq(n))

print format(fib(100000), ',d')  # -> no recursion depth error
1

I wanted to give you an example for using memoization to compute Fibonacci as this will allow you to compute significantly larger numbers using recursion:

cache = {}
def fib_dp(n):
    if n in cache:
        return cache[n]
    if n == 0: return 0
    elif n == 1: return 1
    else:
        value = fib_dp(n-1) + fib_dp(n-2)
    cache[n] = value
    return value

print(fib_dp(998))

This is still recursive, but uses a simple hashtable that allows the reuse of previously calculated Fibonacci numbers instead of doing them again.

1
import sys
sys.setrecursionlimit(1500)

def fib(n, sum):
    if n < 1:
        return sum
    else:
        return fib(n-1, sum+n)

c = 998
print(fib(c, 0))
  • 1
    This same answer has been given many times. Please remove it. – ZF007 Jun 19 '19 at 23:08
0

We can do that using @lru_cache decorator and setrecursionlimit() method:

import sys
from functools import lru_cache

sys.setrecursionlimit(15000)


@lru_cache(128)
def fib(n: int) -> int:
    if n == 0:
        return 0
    if n == 1:
        return 1

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


print(fib(14000))

Output

3002468761178461090995494179715025648692747937490792943468375429502230242942284835863402333575216217865811638730389352239181342307756720414619391217798542575996541081060501905302157019002614964717310808809478675602711440361241500732699145834377856326394037071666274321657305320804055307021019793251762830816701587386994888032362232198219843549865275880699612359275125243457132496772854886508703396643365042454333009802006384286859581649296390803003232654898464561589234445139863242606285711591746222880807391057211912655818499798720987302540712067959840802106849776547522247429904618357394771725653253559346195282601285019169360207355179223814857106405285007997547692546378757062999581657867188420995770650565521377874333085963123444258953052751461206977615079511435862879678439081175536265576977106865074099512897235100538241196445815568291377846656352979228098911566675956525644182645608178603837172227838896725425605719942300037650526231486881066037397866942013838296769284745527778439272995067231492069369130289154753132313883294398593507873555667211005422003204156154859031529462152953119957597195735953686798871131148255050140450845034240095305094449911578598539658855704158240221809528010179414493499583473568873253067921639513996596738275817909624857593693291980841303291145613566466575233283651420134915764961372875933822262953420444548349180436583183291944875599477240814774580187144637965487250578134990402443365677985388481961492444981994523034245619781853365476552719460960795929666883665704293897310201276011658074359194189359660792496027472226428571547971602259808697441435358578480589837766911684200275636889192254762678512597000452676191374475932796663842865744658264924913771676415404179920096074751516422872997665425047457428327276230059296132722787915300105002019006293320082955378715908263653377755031155794063450515731009402407584683132870206376994025920790298591144213659942668622062191441346200098342943955169522532574271644954360217472458521489671859465232568419404182043966092211744372699797375966048010775453444600153524772238401414789562651410289808994960533132759532092895779406940925252906166612153699850759933762897947175972147868784008320247586210378556711332739463277940255289047962323306946068381887446046387745247925675240182981190836264964640612069909458682443392729946084099312047752966806439331403663934969942958022237945205992581178803606156982034385347182766573351768749665172549908638337611953199808161937885366709285043276595726484068138091188914698151703122773726725261370542355162118164302728812259192476428938730724109825922331973256105091200551566581350508061922762910078528219869913214146575557249199263634241165352226570749618907050553115468306669184485910269806225894530809823102279231750061652042560772530576713148647858705369649642907780603247428680176236527220826640665659902650188140474762163503557640566711903907798932853656216227739411210513756695569391593763704981001125

Source

functools lru_cache

0

We could also use a variation of dynamic programming bottom up approach

def fib_bottom_up(n):

    bottom_up = [None] * (n+1)
    bottom_up[0] = 1
    bottom_up[1] = 1

    for i in range(2, n+1):
        bottom_up[i] = bottom_up[i-1] + bottom_up[i-2]

    return bottom_up[n]

print(fib_bottom_up(20000))

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