218

I found out about the // operator in Python which in Python 3 does division with floor.

Is there an operator which divides with ceil instead? (I know about the / operator which in Python 3 does floating point division.)

3
  • 1
    Important: do you want an int or float result?
    – smci
    Jun 25, 2015 at 6:36
  • 14
    You should change accepted answer to dlitz's. math.ceil is for floats, it does not work with Python's arbitrary-precision long ints.
    – endolith
    May 1, 2016 at 17:50
  • 3
    @milllimoose The question is valid, because 1) "ceil division" is also based on "division with modulus", 2) math doesn't really say what's common and what isn't, 3) you need this operation for "continuous bin packing problem", i.e. how many boxes of size $k$ are neeeded to pack $n$ items. Nov 21, 2019 at 4:57

9 Answers 9

443

No, but you can use upside-down floor division:¹

def ceildiv(a, b):
    return -(a // -b)

This works because Python's division operator does floor division (unlike in C, where integer division truncates the fractional part).

Here's a demonstration:

>>> from __future__ import division     # for Python 2.x compatibility
>>> import math
>>> def ceildiv(a, b):
...     return -(a // -b)
...
>>> b = 3
>>> for a in range(-7, 8):
...     q1 = math.ceil(a / b)   # a/b is float division
...     q2 = ceildiv(a, b)
...     print("%2d/%d %2d %2d" % (a, b, q1, q2))
...
-7/3 -2 -2
-6/3 -2 -2
-5/3 -1 -1
-4/3 -1 -1
-3/3 -1 -1
-2/3  0  0
-1/3  0  0
 0/3  0  0
 1/3  1  1
 2/3  1  1
 3/3  1  1
 4/3  2  2
 5/3  2  2
 6/3  2  2
 7/3  3  3

Why this instead of math.ceil?

math.ceil(a / b) can quietly produce incorrect results, because it introduces floating-point error. For example:

>>> from __future__ import division     # Python 2.x compat
>>> import math
>>> def ceildiv(a, b):
...     return -(a // -b)
...
>>> x = 2**64
>>> y = 2**48
>>> ceildiv(x, y)
65536
>>> ceildiv(x + 1, y)
65537                       # Correct
>>> math.ceil(x / y)
65536
>>> math.ceil((x + 1) / y)
65536                       # Incorrect!

In general, it's considered good practice to avoid floating-point arithmetic altogether unless you specifically need it. Floating-point math has several tricky edge cases, which tends to introduce bugs if you're not paying close attention. It can also be computationally expensive on small/low-power devices that do not have a hardware FPU.


¹In a previous version of this answer, ceildiv was implemented as return -(-a // b) but it was changed to return -(a // -b) after commenters reported that the latter performs slightly better in benchmarks. That makes sense, because the dividend (a) is typically larger than the divisor (b). Since Python uses arbitrary-precision arithmetic to perform these calculations, computing the unary negation -a would almost always involve equal-or-more work than computing -b.

10
  • 2
    @apadana I agree this is very smart, but not very readable and hard to maintain! I have decided to import ceil from math so that when one of my colleagues reads my line of code he will understand what it does!
    – tomcheney
    Mar 21, 2018 at 11:28
  • 4
    @apadana I disagree. The question asked whether there "is" an operator for this "in" Python. Based on the responses, the answer appears to be "no." I'm upvoting dlitz's answer for its usefulness, though.
    – Ana Nimbus
    Jul 25, 2018 at 22:49
  • 17
    @SlimCheney Toss this method into a documented function and you're good to go. Performance + readability in one sweeping motion.
    – Samie Bee
    Dec 10, 2018 at 10:45
  • 5
    @SamyBencherif: Not just performance + readability, but also correctness for large inputs; floating point has representation limitations, while Python's int does not (well, no meaningful ones; on 64 bit Python you're limited to 30 * (2**63 - 1) bit numbers), and even temporarily converting to float can lose information. Compare math.ceil((1 << 128) / 10) to -(-(1 << 128) // 10). Jan 3, 2020 at 14:36
  • 3
    This should just be included in standard library
    – endolith
    Feb 4, 2020 at 4:11
71

There is no operator which divides with ceil. You need to import math and use math.ceil

4
  • so foobar = math.ceil(foo / bar)? Hmm, I can live with that, don't know of anywhere I wanted to use that, was just curious, thanks
    – Cradam
    Feb 11, 2013 at 22:51
  • 64
    –1 do not use, this will begin to fail for very large integers. Either use a multiple-precision arithmetic library or stay in the integer domain with this approach.
    – wim
    May 30, 2017 at 20:21
  • 6
    definitely stay in the integer domain. that's almost guaranteed to be more performant and less of a headache.
    – Samie Bee
    Dec 10, 2018 at 10:44
  • 2
    Note that math.ceil is limited to 53 bits of precision. If you are working with large integers, you may not get exact results.
    – techkuz
    Jul 8, 2019 at 8:39
69

Solution 1: Convert floor to ceiling with negation

def ceiling_division(n, d):
    return -(n // -d)

Reminiscent of the Penn & Teller levitation trick, this "turns the world upside down (with negation), uses plain floor division (where the ceiling and floor have been swapped), and then turns the world right-side up (with negation again)"

Solution 2: Let divmod() do the work

def ceiling_division(n, d):
    q, r = divmod(n, d)
    return q + bool(r)

The divmod() function gives (a // b, a % b) for integers (this may be less reliable with floats due to round-off error). The step with bool(r) adds one to the quotient whenever there is a non-zero remainder.

Solution 3: Adjust the numerator before the division

def ceiling_division(n, d):
    return (n + d - 1) // d

Translate the numerator upwards so that floor division rounds down to the intended ceiling. Note, this only works for integers.

Solution 4: Convert to floats to use math.ceil()

def ceiling_division(n, d):
    return math.ceil(n / d)

The math.ceil() code is easy to understand, but it converts from ints to floats and back. This isn't very fast and it may have rounding issues. Also, it relies on Python 3 semantics where "true division" produces a float and where the ceil() function returns an integer.

4
  • 3
    In quick tests, #1 is the fastest here, even compared to -(-a // b) o_O
    – endolith
    Feb 4, 2020 at 5:00
  • Confirming here that -(a // -b) is faster than -(-a // b), at least when timing toy examples with python -m timeit ...
    – Jasha
    Jul 31, 2020 at 22:40
  • @Jasha, any idea how one could be faster than the other? Are your tests symmetric, in that for every case of the form a=x, b=y there is a case of the form a=y, b=x (excluding of course, b=0)?
    – Joe
    Aug 9, 2021 at 13:37
  • @Joe Sorry, I don't remember :)
    – Jasha
    Aug 12, 2021 at 21:57
33

You could do (x + (d-1)) // d when dividing x by d, e.g. (x + 4) // 5.

3
  • 4
    This is the classic method I've used forever. Doesn't work for negative divisors though. Jul 8, 2013 at 16:20
  • It produces the same result as math.ceil().
    – Abhijeet
    Jan 30, 2017 at 5:54
  • 5
    @Abhijeet Yes, that's what the question asks. Except it works better for big integers above sys.float_info.max, and it doesn't require an import.
    – Artyer
    May 10, 2017 at 19:01
24

You can always just do it inline as well

((foo - 1) // bar) + 1

In python3, this is just shy of an order of magnitude faster than forcing the float division and calling ceil(), provided you care about the speed. Which you shouldn't, unless you've proven through usage that you need to.

>>> timeit.timeit("((5 - 1) // 4) + 1", number = 100000000)
1.7249219375662506
>>> timeit.timeit("ceil(5/4)", setup="from math import ceil", number = 100000000)
12.096064013894647
7
  • just ran those tests myself I get about 12.5 seconds, ehrm, why wouldn't I care about speed when it is such a huge speed difference?
    – Cradam
    Feb 11, 2013 at 23:17
  • 4
    @Cradam Note that he's using doing 100 million calls (number=100000000). Per single call, the difference is pretty insignificant. Feb 11, 2013 at 23:19
  • 4
    Because code clarity trumps all. Clarity is objective in this case probably. But you should always make readable/maintainable first. When, and only when, you've discovered a performance checkpoint, do you get to break the rules. Modern machines are so fast, and so often all of the other stuff your program is doing renders this kind of difference lost in the noise. Feb 11, 2013 at 23:26
  • 6
    @TravisGriggs using integer math instead of floating point math isn't just for speed. For large enough integers float math gives the wrong answer
    – endolith
    Mar 23, 2016 at 1:47
  • 1
    If foo = -8 and bar = -4, for example, the answer should be 2, not 3, just like -8 // -4. Python floor division is defined as "that of mathematical division with the ‘floor’ function applied to the result" and ceiling division is the same thing but with ceil() instead of floor().
    – endolith
    Feb 5, 2020 at 2:07
8

Note that math.ceil is limited to 53 bits of precision. If you are working with large integers, you may not get exact results.

The gmpy2 libary provides a c_div function which uses ceiling rounding.

Disclaimer: I maintain gmpy2.

2
  • 3
    This package would be useful if I was doing something heavily mathematics or science orientated, I prefer the answer which uses core libraries though. I am giving an upvote though as it is a useful answer
    – Cradam
    Feb 12, 2013 at 13:38
  • Wow, can confirm. python2 -c 'from math import ceil;assert ceil(11520000000000000102.9)==11520000000000000000' (as well as substituting python3) BOTH are True Jul 19, 2018 at 14:39
1

You can use -(-a//b) or math.ceil(a/b) from math for ceiling division.

1
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    Jul 5, 2022 at 6:19
-1

If you want to celling upto multiple off a number. it works like we have Math.celling in excel.

def excel_celling(number=None, multiple_off=None):
    quotient = number // multiple_off
    reminder = number % multiple_off
    celling_value = quotient * multiple_off + (multiple_off, 0)[reminder==0]
    return int(celling_value)


assert excel_celling(99.99, 100) == 100, "True"
print(excel_celling(99.99, 100) , 100)
assert excel_celling(1, 100) == 100, "True"
print(excel_celling(1, 100),100)
assert excel_celling(99, 100) == 100, "True"
print(excel_celling(99, 100),100)
assert excel_celling(90, 100) == 100, "True"
print(excel_celling(90, 100),100)
assert excel_celling(101, 100) == 200, "True"
print(excel_celling(101, 100),200)
assert excel_celling(199, 100) == 200, "True"
print(excel_celling(199, 100),200)
assert excel_celling(199.99, 100) == 200, "True"
print(excel_celling(199.99, 100),200)
assert excel_celling(200, 100) == 200, "True"
print(excel_celling(200, 100),200)

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-12

Simple solution: a // b + 1

1
  • 12
    This is wrong for anything that divides evenly. a=4, b=2, etc.
    – endolith
    Feb 4, 2020 at 4:16

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