Here's a new answer to an old question, based on this Microsoft Research paper and references therein.

Note that from C11 and C++11 onwards, the semantics of `div`

has become **truncation towards zero** (see `[expr.mul]/4`

). Furthermore, for `D`

divided by `d`

, C++11 guarantees the following about the quotient `qT`

and remainder `rT`

```
auto const qT = D / d;
auto const rT = D % d;
assert(D == d * qT + rT);
assert(abs(rT) < abs(d));
assert(signum(rT) == signum(D) || rT == 0);
```

where `signum`

maps to -1, 0, +1, depending on whether its argument is <, ==, > than 0 (see this Q&A for source code).

With truncated division, **the sign of the remainder is equal to the sign of the dividend **`D`

, i.e. `-1 % 8 == -1`

. C++11 also provides a `std::div`

function that returns a struct with members `quot`

and `rem`

according to truncated division.

There are other definitions possible, e.g. so-called **floored division** can be defined in terms of the builtin truncated division

```
auto const I = signum(rT) == -signum(d) ? 1 : 0;
auto const qF = qT - I;
auto const rF = rT + I * d;
assert(D == d * qF + rF);
assert(abs(rF) < abs(d));
assert(signum(rF) == signum(d));
```

With floored division, **the sign of the remainder is equal to the sign of the divisor **`d`

. In languages such as Haskell and Oberon, there are builtin operators for floored division. In C++, you'd need to write a function using the above definitions.

Yet another way is **Euclidean division**, which can also be defined in terms of the builtin truncated division

```
auto const I = rT >= 0 ? 0 : (d > 0 ? 1 : -1);
auto const qE = qT - I;
auto const rE = rT + I * d;
assert(D == d * qE + rE);
assert(abs(rE) < abs(d));
assert(signum(rE) >= 0);
```

With Euclidean division, **the sign of the remainder is always non-negative**.

`%`

said to be themodulo... it's theremainder.`%`

problem.`(-1) & 8 == 7`

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