Is there a built-in function that can round like the following?
10 -> 10
12 -> 10
13 -> 15
14 -> 15
16 -> 15
18 -> 20
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23 Answers
I don't know of a standard function in Python, but this works for me:
Python 3
def myround(x, base=5):
return base * round(x/base)
It is easy to see why the above works. You want to make sure that your number divided by 5 is an integer, correctly rounded. So, we first do exactly that (round(x/5)), and then since we divided by 5, we multiply by 5 as well.
I made the function more generic by giving it a base parameter, defaulting to 5.
Python 2
In Python 2, float(x) would be needed to ensure that / does floating-point division, and a final conversion to int is needed because round() returns a floating-point value in Python 2.
def myround(x, base=5):
return int(base * round(float(x)/base))
8 Comments
Tjorriemorrie
If only integers and rounding down, then you can also just do
x // base * base
user666412
this is me being paranoid but I prefer to use
floor() and ceil() rather than casting: base * floor(x/base)
Asclepius
@user666412
math.floor and math.ceil don't allow use with a custom base, so the preference is irrelevant.
bnlucas
In case others stumble upon this, the suggested Python 3 way produces false results.
m = 2312**9; n = 3; m * round(n / m) == 1887515243828655024291056713728 where as using the Python 2 way in Py3, casting x or base as a float you get m = 2312**9; n = 3; m * round(float(n) / m) == 1887515243828654813184824180736
Alok Singhal
@bnlucas wow, thank you! It seems like in Python 3,
/ converts both operands to float and loses precision. Even in Python 2, due to the size of numbers involved, the result isn't actually correct. For example, using float() explicitly in Python 3: m - m * round(float(n) / m) gives a large residual instead of <= 3. |
For rounding to non-integer values, such as 0.05:
def myround(x, prec=2, base=.05):
return round(base * round(float(x)/base),prec)
I found this useful since I could just do a search and replace in my code to change "round(" to "myround(", without having to change the parameter values.
3 Comments
saubhik
You can use:
def my_round(x, prec=2, base=0.05): return (base * (np.array(x) / base).round()).round(prec) which accepts numpy arrays as well.
Ramesh Patel
print(myround(10.205)) generate 10.24 print(myround(10.135)) generate 10.16
kappa101
float typecasting no loger req if using >=py3.5 . find more detailed description at PEP 238: Changing the Division Operator.
It's just a matter of scaling
>>> a=[10,11,12,13,14,15,16,17,18,19,20]
>>> for b in a:
... int(round(b/5.0)*5.0)
...
10
10
10
15
15
15
15
15
20
20
20
Comments
Removing the 'rest' would work:
rounded = int(val) - int(val) % 5
If the value is aready an integer:
rounded = val - val % 5
As a function:
def roundint(value, base=5):
return int(value) - int(value) % int(base)
1 Comment
jersey bean
I like this answer for rounding to the nearest fractional value. i.e. If i only want increments of 0.25.
def round_to_next5(n):
return n + (5 - n) % 5
Comments
def round_up_to_base(x, base=10):
return x + (-x % base)
def round_down_to_base(x, base=10):
return x - (x % base)
which gives
for base=5:
>>> [i for i in range(20)]
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19]
>>> [round_down_to_base(x=i, base=5) for i in range(20)]
[0, 0, 0, 0, 0, 5, 5, 5, 5, 5, 10, 10, 10, 10, 10, 15, 15, 15, 15, 15]
>>> [round_up_to_base(x=i, base=5) for i in range(20)]
[0, 5, 5, 5, 5, 5, 10, 10, 10, 10, 10, 15, 15, 15, 15, 15, 20, 20, 20, 20]
for base=10:
>>> [i for i in range(20)]
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19]
>>> [round_down_to_base(x=i, base=10) for i in range(20)]
[0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10]
>>> [round_up_to_base(x=i, base=10) for i in range(20)]
[0, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 20, 20, 20, 20, 20, 20, 20, 20, 20]
tested in Python >= 3.7.9
1 Comment
Donovan Baarda
Note round_up_to_base() can be simplified to;
def round_up_to_base(x, base=10): return x + (-x % base) round(x[, n]): values are rounded to the closest multiple of 10 to the power minus n. So if n is negative...
def round5(x):
return int(round(x*2, -1)) / 2
Since 10 = 5 * 2, you can use integer division and multiplication with 2, rather than float division and multiplication with 5.0. Not that that matters much, unless you like bit shifting
def round5(x):
return int(round(x << 1, -1)) >> 1
2 Comments
Peter Hansen
+1 for showing us that round() can handle rounding to multiples other than 1.0, including higher values. (Note, however, that the bit-shifting approach won't work with floats, not to mention it's much less readable to most programmers.)
pwdyson
@Peter Hansen thanks for the +1. Need to have an int(x) for the bit shifting to work with floats. Agreed not the most readable and I wouldn't use it myself, but I did like the "purity" of it only involving 1's and not 2's or 5's.
Sorry, I wanted to comment on Alok Singhai's answer, but it won't let me due to a lack of reputation =/
Anyway, we can generalize one more step and go:
def myround(x, base=5):
return base * round(float(x) / base)
This allows us to use non-integer bases, like .25 or any other fractional base.
1 Comment
jason-hernandez-73
This works as an answer in itself, though. I used it, without defining it as a function: y = base * round(float(x) / base). It works as long as you have already defined x and base. Note that this answer got seven upvotes.
Use:
>>> def round_to_nearest(n, m):
r = n % m
return n + m - r if r + r >= m else n - r
It does not use multiplication and will not convert from/to floats.
Rounding to the nearest multiple of 10:
>>> for n in range(-21, 30, 3): print('{:3d} => {:3d}'.format(n, round_to_nearest(n, 10)))
-21 => -20
-18 => -20
-15 => -10
-12 => -10
-9 => -10
-6 => -10
-3 => 0
0 => 0
3 => 0
6 => 10
9 => 10
12 => 10
15 => 20
18 => 20
21 => 20
24 => 20
27 => 30
As you can see, it works for both negative and positive numbers. Ties (e.g. -15 and 15) will always be rounded upwards.
A similar example that rounds to the nearest multiple of 5, demonstrating that it also behaves as expected for a different "base":
>>> for n in range(-21, 30, 3): print('{:3d} => {:3d}'.format(n, round_to_nearest(n, 5)))
-21 => -20
-18 => -20
-15 => -15
-12 => -10
-9 => -10
-6 => -5
-3 => -5
0 => 0
3 => 5
6 => 5
9 => 10
12 => 10
15 => 15
18 => 20
21 => 20
24 => 25
27 => 25
Comments
Modified version of divround :-)
def divround(value, step, barrage):
result, rest = divmod(value, step)
return result*step if rest < barrage else (result+1)*step
2 Comments
pwdyson
so in this case you use divround(value, 5, 3)? or maybe divround(value, 5, 2.5)?
Christian Hausknecht
divround(value, 5, 3), exactly.
Another way to do this (without explicit multiplication or division operators):
def rnd(x, b=5):
return round(x + min(-(x % b), b - (x % b), key=abs))
Comments
In case someone needs "financial rounding" (0.5 rounds always up):
from decimal import ROUND_HALF_UP, Decimal, localcontext
def myround(x, base: int = 5):
# starting with Python 3.11:
# with localcontext(rounding=decimal.ROUND_HALF_UP):
with localcontext() as ctx:
ctx.rounding = ROUND_HALF_UP
return base * int(decimal.Decimal(x / base).quantize(Decimal('0')))
As per documentation the rounding options are:
ROUND_CEILING(towards Infinity)ROUND_DOWN(towards zero)ROUND_FLOOR(towards -Infinity)ROUND_HALF_DOWN(to nearest with ties going towards zero)ROUND_HALF_EVEN(to nearest with ties going to nearest even integer)ROUND_HALF_UP(to nearest with ties going away from zero)ROUND_UP(away from zero)ROUND_05UP(away from zero if last digit after rounding towards zero would have been 0 or 5; otherwise towards zero)
By default Python uses ROUND_HALF_EVEN as it has some statistical advantages (the rounded results are not biased).
1 Comment
Cristian Ciupitu
Instead of setting the decimal context permanently as a side effect when the function is called, you should probably set it explicitly beforehand or even better use a local context temporarily.
For integers and with Python 3:
def divround_down(value, step):
return value//step*step
def divround_up(value, step):
return (value+step-1)//step*step
Producing:
>>> [divround_down(x,5) for x in range(20)]
[0, 0, 0, 0, 0, 5, 5, 5, 5, 5, 10, 10, 10, 10, 10, 15, 15, 15, 15, 15]
>>> [divround_up(x,5) for x in range(20)]
[0, 5, 5, 5, 5, 5, 10, 10, 10, 10, 10, 15, 15, 15, 15, 15, 20, 20, 20, 20]
2 Comments
KiriSakow
Hi, what do you think of my algorithm? Which is like yours but looks simpler stackoverflow.com/a/65725123/4883320
Sylvain Leroux
Hi @KiriSakow -- your solution looks good to me. To be honest, I don't know why I posted an answer for that question myself -- especially why I posted that answer, which far from being excellent :/
No one actually wrote this yet I guess but you can do:
round(12, -1) --> 10
round(18, -1) --> 20
Comments
Next multiple of 5
Consider 51 needs to be converted to 55:
code here
mark = 51;
r = 100 - mark;
a = r%5;
new_mark = mark + a;
Comments
What about this:
def divround(value, step):
return divmod(value, step)[0] * step
1 Comment
duhaime
Docs on divmod: docs.python.org/2/library/functions.html#divmod
I needed to round down to the preceding 5.
Example 16 rounds down to 15 or 19 rounds down to 15
Here's the code used
def myround(x,segment):
preRound = x / segment
roundNum = int(preRound)
segVal = segment * roundNum
return segVal
Comments
Here is my C code. If I understand it correctly, it should supposed to be something like this;
#include <stdio.h>
int main(){
int number;
printf("Enter number: \n");
scanf("%d" , &number);
if(number%5 == 0)
printf("It is multiple of 5\n");
else{
while(number%5 != 0)
number++;
printf("%d\n",number);
}
}
and this also rounds to nearest multiple of 5 instead of just rounding up;
#include <stdio.h>
int main(){
int number;
printf("Enter number: \n");
scanf("%d" , &number);
if(number%5 == 0)
printf("It is multiple of 5\n");
else{
while(number%5 != 0)
if (number%5 < 3)
number--;
else
number++;
printf("nearest multiple of 5 is: %d\n",number);
}
}
Comments
An addition to accepted answer, to specify rounding up or down to nearest 5-or-whatever
import math
def my_round(x, base, down = True):
return base * math.floor(x/base) + (not down) * base
Comments
A solution that works only with ints (it accepts floats, but the rounding behaves as if the decimal component doesn't exist), but unlike any solution relying on temporary conversion to float (all the math.floor/math.ceil-based solutions, all the solutions using /, most solutions using round), it works for arbitrarily huge int inputs, never losing precision, never raising exceptions or resulting in infinity values.
It's an adaptation of the simplest solution for rounding down to the next lower multiple of a number:
def round_to_nearest(num, base=5):
num += base // 2
return num - (num % base)
The round down recipe it's based on is just:
def round_down(num, base=5):
return num - (num % base)
the only change is that you add half the base to the number ahead of time so it rounds to nearest. With exact midpoint values, only possible with even bases, rounding up, so round_to_nearest(3, 6) will round to 6 rather than 0, while round_to_nearest(-3, 6) will round to 0 rather than -6. If you prefer midpoint values round down, you can change the first line to num += (base - 1) // 2.
Comments
from math import isclose
def myPrice (p1,p2):
return isclose(p1, p2, rel_tol=0.05)
print(myPrice(50.10,50.20))
To set a tolerance of 5%, pass rel_tol=0.05. The default tolerance is 1e-09
Comments
I find this one to be negligibly slower than the answer by @mkrieger1 and @Alok Singhal but it is more explicit about the rounding behavior and easier to modify or extend.
def round_up_to_5(num):
rounded_num = math.ceil(num / 5) * 5
return int(rounded_num)
Comments
You can “trick” int() into rounding off instead of rounding down by adding 0.5 to the
number you pass to int().
1 Comment
Uri Agassi
This does not actually answer the question