But why Python
// choose to round towards negative infinity?
I'm not sure if the reason why this choice was originally made is documented anywhere (although, for all I know, it could be explained in great length in some PEP somewhere), but we can certainly come up with various reasons why it makes sense.
One reason is simply that rounding towards negative (or positive!) infinity means that all numbers get rounded the same way, whereas rounding towards zero makes zero special. The mathematical way of saying this is that rounding down towards −∞ is translation invariant, i.e. it satisfies the equation:
round_down(x + k) == round_down(x) + k
for all real numbers
x and all integers
k. Rounding towards zero does not, since, for example:
round_to_zero(0.5 - 1) != round_to_zero(0.5) - 1
Of course, other arguments exist too, such as the argument you quote based on compatibility with (how we would like) the
% operator (to behave) — more on that below.
Indeed, I would say the real question here is why Python's
int() function is not defined to round floating point arguments towards negative infinity, so that
m // n would equal
int(m / n). (I suspect "historical reasons".) Then again, it's not that big of a deal, since Python does at least have
math.floor() that does satisfy
m // n == math.floor(m / n).
But I don't see C++ 's
/ not being compatible with the modulo function. In C++,
(m/n)*n + m%n == m also applies.
True, but retaining that identity while having
/ round towards zero requires defining
% in an awkward way for negative numbers. In particular, we lose both of the following useful mathematical properties of Python's
0 <= m % n < n for all
m and all positive
(m + k * n) % n == m % n for all integers
These properties are useful because one of the main uses of
% is "wrapping around" a number
m to a limited range of length
For example, let's say we're trying to calculate directions: let's say
heading is our current compass heading in degrees (counted clockwise from due north, with
0 <= heading < 360) and that we want to calculate our new heading after turning
angle degrees (where
angle > 0 if we turn clockwise, or
angle < 0 if we turn counterclockwise). Using Python's
% operator, we can calculate our new heading simply as:
heading = (heading + angle) % 360
and this will simply work in all cases.
However, if we try to to use this formula in C++, with its different rounding rules and correspondingly different
% operator, we'll find that the wrap-around doesn't always work as expected! For example, if we start facing northwest (
heading = 315) and turn 90° clockwise (
angle = 90), we'll indeed end up facing northeast (
heading = 45). But if then try to turn back 90° counterclockwise (
angle = -90), with C++'s
% operator we won't end up back at
heading = 315 as expected, but instead at
heading = -45!
To get the correct wrap-around behavior using the C++
% operator, we'll instead need to write the formula as something like:
heading = (heading + angle) % 360;
if (heading < 0) heading += 360;
heading = ((heading + angle) % 360) + 360) % 360;
(The simpler formula
heading = (heading + angle + 360) % 360 will only work if we can always guarantee that
heading + angle >= -360.)
This is the price you pay for having a non-translation-invariant rounding rule for division, and consequently a non-translation-invariant
%operator is not quite the same in C++ and Python: in C++, it is a remainder operator but, in Python, it is a modulus operator. Nice answer explaining the difference.
(m/n)*n + m%n == mapplies, the possible outputs of
[-n+1,n-1]and it is twice as big as it should be
[0,n-1]. And it is very inconvenient for multiple purposes. Instead they chose the sign invariance... it has its perks too. In general, the problem is that people would want several properties from the rounded division but not all are achievable at the same time - so they pick what they prefer.