In the context of argument reduction for trigonometric functions, what you are looking at is Cody-Waite argument reduction, a technique introduced in the book: William J. Cody and William Waite, *Software Manual for the Elementary Functions*, Prentice-Hall, 1980. The goal is to achieve, for arguments up to a certain magnitude, an accurate reduced argument, despite subtractive cancellation in intermediate computation. For this purpose, the relevant constant is represented with *more than native precision*, by using a sum of multiple numbers of decreasing magnitude (here: `DP1`

, `DP2`

, `DP3`

), such that all of the intermediate products except the least significant one can be computed without rounding error.

Consider as an example the computation of sin (113) in IEEE-754 `binary32`

(single precision). The typical argument reduction would conceptually compute `i=rintf(x/(π/2)); reduced_x = x-i*(π/2)`

. The `binary32`

number closest to π/2 is `0x1.921fb6p+0`

. We compute `i=72`

, the product rounds to `0x1.c463acp+6`

, which is close to the argument `x=0x1.c40000p+6`

. During subtraction, some leading bits cancel, and we wind up with `reduced_x = -0x1.8eb000p-4`

. Note the trailing zeros introduced by renormalization. These zero bits carry no useful information. Applying an accurate approximation to the reduced argument, `sin(x) = -0x1.8e0eeap-4`

, whereas the true result is `-0x1.8e0e9d39...p-4`

. We wind up with large relative error and large ulp error.

We can remedy this by using a two-step Cody-Waite argument reduction. For example, we could use `pio2_hi = 0x1.921f00p+0`

, and `pio2_lo = 0x1.6a8886p-17`

. Note the eight trailing zero bits in single-precision representation of`pio2_hi`

, which allow us to multiply with any 8-bit integer `i`

and still have the product `i * pio2_hi`

representable *exactly* as a single-precision number. When we compute `((x - i * pio2_hi) - i * pio2_lo)`

, we get `reduced_x = -0x1.8eafb4p-4`

, and therefore `sin(x) = -0x1.8e0e9ep-4`

, a quite accurate result.

The best way to split the constant into a sum will depend on the magnitude of `i`

we need to handle, on the maximum number of bits subject to subtractive cancellation for a given argument range (based on how close integer multiples of π/2 can get to integers), and performance considerations. Typical real-life use cases involve two- to four-stage Cody-Waite reduction schemes. The availability of fused multiple-add (FMA) allows the use of constituent constants with fewer trailing zero bits. See this paper: Sylvie Boldo, Marc Daumas, and Ren-Cang Li, "Formally verified argument reduction with a fused multiply-add." *IEEE Transactions on Computers*, 58 :1139–1145, 2009. For a worked example using `fmaf()`

you might want to look at the code in one of my previous answers.

Software Manual for the Elementary Functions, Prentice-Hall, 1980 – njuffa Mar 1 '17 at 3:34