800

How does one round a number UP in Python?

I tried round(number) but it rounds the number down. Here is an example:

round(2.3) = 2.0 

and not 3, as I would like.

Then I tried int(number + .5) but it round the number down again! Example:

int(2.3 + .5) = 2
1
  • 13
    round(number + .5) doesn't work if the number is integer. round(3+.5) == 4, when you actually want 3.
    – Nearoo
    Jan 27, 2019 at 16:47

31 Answers 31

1302

The math.ceil (ceiling) function returns the smallest integer higher or equal to x.

For Python 3:

import math
print(math.ceil(4.2))

For Python 2:

import math
print(int(math.ceil(4.2)))
6
  • 44
    Elaboration: math.ceil returns the smallest integer which is greater than or equal to the input value. This function treats the input as a float (Python does not have strongly-typed variables) and the function returns a float. If you want an int, you can construct an int from the return value, i.e., int(math.ceil(363)) Aug 26, 2015 at 23:37
  • 14
    @Sinnet: Actually one could say that python is strongly typed stackoverflow.com/a/11328980/5069869
    – Bernhard
    Jan 8, 2016 at 12:54
  • 3
    @TheEspinosa: Yes, python is definitely strongly typed, its just that many functions ask questions about the type of some parameters and execute different code depending on the answer.
    – quamrana
    Dec 17, 2017 at 12:27
  • 30
    @R.W.Sinnet In Python 3, math.ceil returns an actual integer object, not just floating object with integer value. May 2, 2018 at 15:50
  • 6
    Take care of float precision, due to 10000000 * 0.00136 = 13600.000000000002 ceil can increase a lot math.ceil(10000000 * 0.00136) = 13601.0 Sep 10, 2019 at 8:23
329

I know this answer is for a question from a while back, but if you don't want to import math and you just want to round up, this works for me.

>>> int(21 / 5)
4
>>> int(21 / 5) + (21 % 5 > 0)
5

The first part becomes 4 and the second part evaluates to "True" if there is a remainder, which in addition True = 1; False = 0. So if there is no remainder, then it stays the same integer, but if there is a remainder it adds 1.

4
  • 87
    Nice. You can also use // for integer division, so this becomes 21 // 5 + (21 % 5 > 0).
    – naught101
    Aug 19, 2015 at 13:04
  • 4
    ...and to have it as a nice function: def round_up(number): return int(number) + (number % 1 > 0)
    – Bitstream
    Oct 13, 2021 at 8:39
  • but you would have to do a bit much of calculation for that, right? I know, you don't care, neither do I unless I really do.
    – france1
    Jan 12, 2023 at 15:08
  • Also the integrated divmod function can be used for this: d, m = divmod(number) return int(d) + m > 0
    – VMAtm
    Aug 1, 2023 at 10:52
201

If working with integers, one way of rounding up is to take advantage of the fact that // rounds down: Just do the division on the negative number, then negate the answer. No import, floating point, or conditional needed.

rounded_up = -(-numerator // denominator)

For example:

>>> print(-(-101 // 5))
21
4
  • 2
    What about when you don't need to perform any math operation? I.e. you just have one number.
    – Klik
    Sep 8, 2016 at 6:33
  • 5
    @Klik: then you can just divide by 1 ==> -( -num // 1) and you are getting your answer :-) Have a nice day! David Bau: very nice proposal!
    – Marco smdm
    Apr 4, 2017 at 8:57
  • 2
    Nice! I've always used (num + den - 1) // den, which is fine for int inputs with positive denominators, but fails if even a single non-integral float is involved (either numerator or denominator); this is more magical looking, but works for both ints and floats. For small numerators, it's also faster (on CPython 3.7.2), though oddly, when only the numerator is large enough that array based math is needed, your approach is slower; not clear why this is, since the division work should be similar and two unary negations should be cheaper than addition + subtraction. Aug 7, 2019 at 16:17
  • 2
    The fact that it doesn't need any import and is fast makes it exactly what i was looking for. Apr 14, 2020 at 13:59
179

Interesting Python 2.x issue to keep in mind:

>>> import math
>>> math.ceil(4500/1000)
4.0
>>> math.ceil(4500/1000.0)
5.0

The problem is that dividing two ints in python produces another int and that's truncated before the ceiling call. You have to make one value a float (or cast) to get a correct result.

In javascript, the exact same code produces a different result:

console.log(Math.ceil(4500/1000));
5
2
  • 49
    In Python 2.x : int/int --> int and int/float --> float In Python 3.x : int/int can result in a float
    – gecco
    Oct 31, 2011 at 6:46
  • 8
    you can get the Python 3.x on behavior on certain versions of Python 2.x by enabling "true division" as shown here
    – Rob Dennis
    Oct 22, 2013 at 17:54
88

You might also like numpy:

>>> import numpy as np
>>> np.ceil(2.3)
3.0

I'm not saying it's better than math, but if you were already using numpy for other purposes, you can keep your code consistent.

Anyway, just a detail I came across. I use numpy a lot and was surprised it didn't get mentioned, but of course the accepted answer works perfectly fine.

2
  • 5
    Using numpy is nice too. The easiest would be with math since it is already part of python built in libraries. It makes more sense. Instead as you mentioned if you use a lot numpy for other issues, then it makes sense and consistent to use numpy.ceil :-) Good hint!
    – Marco smdm
    Apr 4, 2017 at 8:52
  • If you are using pandas and imported the whole module as pd, then just use pd.np.ceil(2.3). No need for a separate numpy import. Dec 11, 2021 at 12:37
40

Use math.ceil to round up:

>>> import math
>>> math.ceil(5.4)
6.0

NOTE: The input should be float.

If you need an integer, call int to convert it:

>>> int(math.ceil(5.4))
6

BTW, use math.floor to round down and round to round to nearest integer.

>>> math.floor(4.4), math.floor(4.5), math.floor(5.4), math.floor(5.5)
(4.0, 4.0, 5.0, 5.0)
>>> round(4.4), round(4.5), round(5.4), round(5.5)
(4.0, 5.0, 5.0, 6.0)
>>> math.ceil(4.4), math.ceil(4.5), math.ceil(5.4), math.ceil(5.5)
(5.0, 5.0, 6.0, 6.0)
2
  • 2
    The input does not necessarily need to be a float if using python 3: ceil() will take care of it internally Feb 24, 2017 at 10:33
  • Note that in python 3, round() will actually round half to even as described in the docs so the second line will return (4, 4, 5, 6)
    – hummusw
    Jun 14, 2021 at 15:01
29

I am surprised nobody suggested

(numerator + denominator - 1) // denominator

for integer division with rounding up. Used to be the common way for C/C++/CUDA (cf. divup)

3
  • 4
    Relevant only for statically typed languages. If the denominator is a float you're dead.
    – Bharel
    Jul 6, 2017 at 12:31
  • 2
    This also only works consistently if the denominator is positive; if the denominator is negative, you need to add 1 instead of subtracting it, or flip the signs of both numerator and denominator before performing the math. Aug 7, 2019 at 16:28
  • 3
    @Bharel obviously not true. Python has types and you may even check it for a value. This code will work fine for int. This is also worth noting that this code will work even for integers greater than 2^53 in which case floating point arithmetic might fail to produce correct result.
    – Nolan
    Jan 23, 2021 at 10:48
18

Here is a way using modulo and bool

n = 2.3
int(n) + bool(n%1)

Output:

3
1
  • 4
    upvoted for not needing an import
    – irene
    Mar 30, 2022 at 6:59
14

For those who want to round up a / b and get integer:

Another variant using integer division is

def int_ceil(a, b):
    return (a - 1) // b + 1

>>> int_ceil(19, 5)
4
>>> int_ceil(20, 5)
4
>>> int_ceil(21, 5)
5

Note: a and b must be non-negative integers

5
  • Gives wrong answer for int_ceil(-0.1, 1). Should be 0.0 when it's -1.0
    – wlad
    Aug 24, 2021 at 16:55
  • @ogogmad it makes sense only if a and b are integers. If you have float, use math.ceil as the top answer suggests
    – Pavel
    Aug 24, 2021 at 18:00
  • int_ceil(2,-1) gives 0 for me. So the integers have to be non-negative
    – wlad
    Aug 25, 2021 at 20:42
  • @ogogmad I agree, added note to the answer, thank you
    – Pavel
    Aug 26, 2021 at 7:14
  • @Pavel Isn't it enough that b is positive?
    – user313032
    Dec 7, 2021 at 0:36
14

The syntax may not be as pythonic as one might like, but it is a powerful library.

https://docs.python.org/2/library/decimal.html

>>> from decimal import Decimal, ROUND_UP
>>> Decimal(1.2).quantize(Decimal("1"), ROUND_UP)
Decimal('2')
>>> int(Decimal(2.3).quantize(Decimal('1.'), rounding=ROUND_UP))
3
11

Try this:

a = 211.0
print(int(a) + ((int(a) - a) != 0))
2
  • 2
    Clever. The ((int(a) - a) != 0) expression returns 1 whenever a needs to be rounded up. You may want to expand your answer and explain how this work.
    – Tom Aranda
    Dec 4, 2017 at 23:01
  • @TomAranda Can anyone explain how a boolean expression evaluates to a value please?
    – Bowen Liu
    Dec 18, 2018 at 20:51
9

In case anyone is looking to round up to a specific decimal place:

import math
def round_up(n, decimals=0):
    multiplier = 10 ** decimals
    return math.ceil(n * multiplier) / multiplier
7

Be shure rounded value should be float

a = 8 
b = 21
print math.ceil(a / b)
>>> 0

but

print math.ceil(float(a) / b)
>>> 1.0
7

The above answers are correct, however, importing the math module just for this one function usually feels like a bit of an overkill for me. Luckily, there is another way to do it:

g = 7/5
g = int(g) + (not g.is_integer())

True and False are interpreted as 1 and 0 in a statement involving numbers in python. g.is_interger() basically translates to g.has_no_decimal() or g == int(g). So the last statement in English reads round g down and add one if g has decimal.

3
  • 2
    And if you feel fancy, you can use int(g) + (g % 1 > 0) instead ;-)
    – Nearoo
    May 5, 2017 at 3:23
  • from math import ceil seems to fix importing the entire math module :)
    – SH7890
    Jan 25, 2019 at 21:50
  • 1
    @SH7890 I'm afraid that line isn't much different to import math in terms of what happens behind the scenes. It just drops all symbols except ceil.
    – Nearoo
    Jan 27, 2019 at 16:52
6

Without importing math // using basic envionment:

a) method / class method

def ceil(fl): 
  return int(fl) + (1 if fl-int(fl) else 0)

def ceil(self, fl): 
  return int(fl) + (1 if fl-int(fl) else 0)

b) lambda:

ceil = lambda fl:int(fl)+(1 if fl-int(fl) else 0)
6

x * -1 // 1 * -1

Confusing but it works: For x=7.1, you get 8.0. For x = -1.1, you get -1.0

No need to import a module.

2
  • Nice, but what's the logic behind it? Feb 5, 2022 at 23:35
  • 2
    x * -1 // 1 * -1 = -(-x // 1). The // operator always rounds down, so x // 1 = floor(x). Therefore, the logic here to round the negated number down, then negate again, which results in rounding up the original number.
    – Alexander
    Feb 7, 2023 at 15:44
5
>>> def roundup(number):
...     return round(number+.5)
>>> roundup(2.3)
3
>>> roundup(19.00000000001)
20

This function requires no modules.

1
  • 7
    What if your number is 3, then it would round up to 4 which may or may not be what someone wants
    – buydadip
    Oct 20, 2018 at 23:01
2

For those who doesn't want to use import.

For a given list or any number:

x = [2, 2.1, 2.5, 3, 3.1, 3.5, 2.499,2.4999999999, 3.4999999,3.99999999999]

You must first evaluate if the number is equal to its integer, which always rounds down. If the result is True, you return the number, if is not, return the integer(number) + 1.

w = lambda x: x if x == int(x) else int(x)+1
[w(i) for i in z]
>>> [2, 3, 3, 3, 4, 4, 3, 3, 4, 4]

Math logic:

  • If the number has decimal part: round_up - round_down == 1, always.
  • If the number doens't have decimal part: round_up - round_down == 0.

So:

  • round_up == x + round_down

With:

  • x == 1 if number != round_down
  • x == 0 if number == round_down

You are cutting the number in 2 parts, the integer and decimal. If decimal isn't 0, you add 1.

PS:I explained this in details since some comments above asked for that and I'm still noob here, so I can't comment.

0
1

If you don't want to import anything, you can always write your own simple function as:

def RoundUP(num):
    if num== int(num):
        return num
    return int(num + 1)
1
  • 4
    This does not work if num is 2.05. You have to have at least as many digits with a 9 as your input, leaving you with a 0.999... which is 1. But then your corner case 2 is rounded up again. -- Well, I guess there is a reason why math.ceil is there. Mar 28, 2017 at 0:01
0

To do it without any import:

>>> round_up = lambda num: int(num + 1) if int(num) != num else int(num)
>>> round_up(2.0)
2
>>> round_up(2.1)
3
0
0

I know this is from quite a while back, but I found a quite interesting answer, so here goes:

-round(-x-0.5)

This fixes the edges cases and works for both positive and negative numbers, and doesn't require any function import

Cheers

2
  • 2
    This will still rounds down -round(-x-0.3) = x
    – Diblo Dk
    Jun 19, 2015 at 20:44
  • Also incorrectly increments exact numbers. Eg, -round(-3-0.5) returns 4 rather than 3, as it should.
    – Jonah
    Sep 17, 2021 at 17:43
0

I'm surprised I haven't seen this answer yet round(x + 0.4999), so I'm going to put it down. Note that this works with any Python version. Changes made to the Python rounding scheme has made things difficult. See this post.

Without importing, I use:

def roundUp(num):
    return round(num + 0.49)

testCases = list(x*0.1 for x in range(0, 50))

print(testCases)
for test in testCases:
    print("{:5.2f}  -> {:5.2f}".format(test, roundUp(test)))

Why this works

From the docs

For the built-in types supporting round(), values are rounded to the closest multiple of 10 to the power minus n; if two multiples are equally close, rounding is done toward the even choice

Therefore 2.5 gets rounded to 2 and 3.5 gets rounded to 4. If this was not the case then rounding up could be done by adding 0.5, but we want to avoid getting to the halfway point. So, if you add 0.4999 you will get close, but with enough margin to be rounded to what you would normally expect. Of course, this will fail if the x + 0.4999 is equal to [n].5000, but that is unlikely.

3
  • 3
    Using 0.4999, it will fail to give a correct result for any input in between ???.0000 and ???.0001 (open interval), not just exactly ???.0001. For instance, if you try it with 3.00005, you will get a result of 3 instead of the expected 4. Of course you can decrease the likelihood of this happening by adding more and more digits up to the maximum precision of floats, but what's the point to that if there are more robust and intuitive solutions at hand, like using math.ceil()? Nov 14, 2016 at 9:08
  • @blubberdiblub In my answer I state Without importing I use:. I've also mentioned that it will fail if the x + 0.4999 is equal to [n].5000.
    – Klik
    Nov 14, 2016 at 22:23
  • 4
    Yes, you state in your answer that your solution is without importing, but I don't see the value of it. The math module and math.ceil() is in the standard library, so available everywhere for all practical purposes without installing extra stuff. And regarding your mention of when it fails, this is incomplete in your answer, as it fails for a whole interval, not just for a single point. Technically, you could argue you are correct, as you say if and not iff, but it will make the impression on the casual reader that it is less likely than it really is. Nov 17, 2016 at 5:59
0

You could use round like this:

cost_per_person = round(150 / 2, 2)

  
1
  • This should work when the second argument of round() is zero. That is round(x/y,0) Dec 6, 2021 at 23:15
0

Here is pretty straightforward answer, based on use of default round()

def round_up(arg):
    if arg > round(arg):
        return round(arg) + 1
    else:
        return round(arg)

It does

1 to 1     -1 to -1     1.0 to 1    1.00000001 to 2    -1.00000001 to -1
0

Incase you don't want to use math, use the floor division operator //. Floor division will always take the floor or the lower number.

Problem Example:

x = 5.5
x //= 1
print(x)

Output: 5.0

Solution: Add 1

x //= 1 + 1
print(x)

Output: 6.0

You can then typecast it to int or round() it if needed.

-1

You can use floor devision and add 1 to it. 2.3 // 2 + 1

2
  • 2
    or use ceil() instead of weirdly doing the opposite and then compensating Feb 24, 2017 at 10:34
  • 2
    This won't work. For example: from math import ceil; assert 4 // 2 + 1 == ceil(4 / 2) Jul 26, 2017 at 15:36
-1

when you operate 4500/1000 in python, result will be 4, because for default python asume as integer the result, logically: 4500/1000 = 4.5 --> int(4.5) = 4 and ceil of 4 obviouslly is 4

using 4500/1000.0 the result will be 4.5 and ceil of 4.5 --> 5

Using javascript you will recieve 4.5 as result of 4500/1000, because javascript asume only the result as "numeric type" and return a result directly as float

Good Luck!!

1
  • 1
    That's only true in Python 2.x. In Python 3, division with a single / always results in a float, so 4500/1000 is always 4.5.
    – Nearoo
    Jun 19, 2018 at 12:41
-2

This should work.

a=16
b= int(input("Please enter a number greater than 0 \n"))

if b==0:
    print ( "Wrong input")

elif a%b != 0:
    c=a/b
    d= int(c)+1
    print (c)
    print (d)
else:
    c=a/b
    d=c        
print (c)
print (d)
1
  • This question is over 13 years old and has dozens of existing answers. Are you entirely sure that your answer brings something new? If so, great! But please explain that to us.
    – Chris
    Apr 5, 2023 at 22:17
-3

I think you are confusing the working mechanisms between int() and round().

int() always truncates the decimal numbers if a floating number is given; whereas round(), in case of 2.5 where 2 and 3 are both within equal distance from 2.5, Python returns whichever that is more away from the 0 point.

round(2.5) = 3
int(2.5) = 2
1
  • "rounding up" means that e.g. 2.3 gets turned into 3, which happens in neither of your examples.
    – Nearoo
    Jun 19, 2018 at 12:43
-3

My share

I have tested print(-(-101 // 5)) = 21 given example above.

Now for rounding up:

101 * 19% = 19.19

I can not use ** so I spread the multiply to division:

(-(-101 //(1/0.19))) = 20
1
  • 1
    Please explain what you are trying to do? Jul 15, 2021 at 12:44

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