There seems to be a common confusion between the terms "modulo" and "remainder".
In math, a remainder should always be defined consistent with the quotient, so that if
a / b == c rem d then
(c * b) + d == a. Depending on how you round your quotient, you get different remainders.
However, modulo should always give a result
0 <= r < divisor, which is only consistent with round-to-minus-infinity division if you allow negative integers. If division rounds towards zero (which is common), modulo and remainder are only equivalent for non-negative values.
Some languages (notably C and C++) don't define the required rounding/remainder behaviours and
% is ambiguous. Many define rounding as towards zero, yet use the term modulo where remainder would be more correct. Python is relatively unusual in that it rounds to negative infinity, so modulo and remainder are equivalent.
Ada rounds towards zero IIRC, but has both
The C policy is intended to allow compilers to choose the most efficient implementation for the machine, but IMO is a false optimisation, at least these days. A good compiler will probably be able to use the equivalence for optimisation wherever a negative number cannot occur (and almost certainly if you use unsigned types). On the other hand, where negative numbers can occur, you almost certainly care about the details - for portability reasons you have to use very carefully designed overcomplex algorithms and/or checks to ensure that you get the results you want irrespective of the rounding and remainder behaviour.
In other words, the gain for this "optimisation" is mostly (if not always) an illusion, whereas there are very real costs in some cases - so it's a false optimisation.