What is the purpose of the std::remquo
function? What is an example of when you would use it instead of the regular std::remainder
function?

1When you also want the quotient?– Oliver CharlesworthCommented Jun 17, 2012 at 21:22

1@Oli: Except it doesn't provide the quotient in full, only atleast the last three bits. :) en.cppreference.com/w/cpp/numeric/math/remquo– XeoCommented Jun 17, 2012 at 21:23
2 Answers
Suppose I am implementing a sine function. A typical way to implement sine is to design some polynomial s such that s(x) approximates sine of x, but the polynomial is only good for π/4 <= x <= π/4. Outside of that interval, the polynomial deviates from sine(x) and is a bad approximation. (Making the polynomial good over a larger interval requires a polynomial with more terms, and, at some point, the polynomial becomes larger than is useful.) Commonly, we would also design a polynomial c such that c(x) approximates the cosine of x, in a similar interval.
The remquo function helps us use these polynomials to implement sine. We can use “r = remquo(x, pi/2, &q)” and use q to determine which portion of the circle x is in. (Note that sine is periodic with period 2π, so we only need to know the low few bits of the quotient. The higher bits just indicate x has wrapped around the circle and is repeating sine values.) Depending on which part of the circle x is in, the routine will return s(r), s(r), c(r), or c(r) for the sine of x.
There are embellishments, of course, but that is the basic idea. It only works for values of x that are small, not more than a few multiples of 2π. That is because each time x doubles, another bit of the divisor moves into the calculation of the exact result. However, we cannot pass π/2 exactly to remquo, because the precision of the double type is limited. So, as x grows, the error grows.
remquo
first appeared in C99 before being in C++ and here is what the C99 rationale says about it:
The remquo functions are intended for implementing argument reductions which can exploit a few loworder bits of the quotient. Note that x may be so large in magnitude relative to y that an exact representation of the quotient is not practical.