Why is the following true?
print(-7 % 6 == 5);
This means that -7 % 6
yields 5
, but I would expect to see -1
(in JavaScript this is the case).
Why is the following true?
print(-7 % 6 == 5);
This means that -7 % 6
yields 5
, but I would expect to see -1
(in JavaScript this is the case).
The modulo behavior in Dart is different from the behavior in JavaScript, C, C++, and others. It shares its behavior with Python and about this topic there is a question with great answers here.
Adding a bit to the superb answer by @kennytm, the intuitive explanation for this is that it works analogous to positive factorisation (at least in Dart):
17 % 6 == 5 <=> -7 % 6 == 5
(2 * 6 + 5) % 6 == 5 <=> (-2 * 6 + 5) % 6 == 5
However, it could have easily been implemented differently, reasonably, but this is how it works in Dart.
A benefit of this is the following (quote from the answer mentioned earlier):
It is chosen over the C behavior because a nonnegative result is often more useful. An example is to compute week days. If today is Tuesday (day #2), what is the week day N days before? In Python we can compute with
return (2 - N) % 7
The %
is actually a remainder
operator in Java. So it would return -1.
But a true modulo operator can have many remainders. This is because
a modulo operator means.
if b mod(m) == c
Then there exists some integer k
where km = (b - c)
which means that
(1) c = b - km
for any integer k
is a valid answer.
so in your example, -7 % 6 = 5
works because k6 = (-7 -5) = -12 so k = -2
.
by (1) above, c = -7 - k6
are all valid answers.
So for -3 <= k <= 3
11, 5, -1, -7, -13, -19, -25
are all valid
`
To get the expected answer from your perspective, simply subtract
the modulus from the actual answer. So 5 - 6 = -1