# Payne Hanek algorithm implementation in C

I'm struggling to understand how TO IMPLEMENT the range reduction algorithm published by Payne and Hanek (range reduction for trigonometric functions)

I've seen there's this library: http://www.netlib.org/fdlibm/

But it looks to me so twisted, and all the theoretical explanation i've founded are too simple to provide an implementation.

Is there some good... good... good explanation of it?

• It seems to me like you are expecting us to do your implementation for you? – the_OTHER_DJMethaneMan May 26 '15 at 16:06
• Nono, but if you know some phd thesis or i don't know whatever useful to understand better how to implement it. – user8469759 May 26 '15 at 16:10

## 2 Answers

Performing argument reduction for trigonometric functions via the Payne-Hanek algorithm is actually pretty straightforward. As with other argument reduction schemes, compute `n = round_nearest (x / (π/2))`, then compute remainder via `x - n * π/2`. Better efficiency is achieved by computing `n = round_nearest (x * (2/π))`.

The key observation in Payne-Hanek is that when computing the remainder of `x - n * π/2` using the full unrounded product the leading bits cancel during subtraction, so we do not need to compute those. We are left with the problem of finding the right starting point (non-zero bits) based on the magnitude of `x`. If `x` is close to a multiple of `π/2`, there may be additional cancellation, which is limited. One can consult the literature for an upper bound on the number of additional bits that cancel in such cases. Due to relatively high computational cost, Payne-Hanek is usually only used for arguments large in magnitude, which has the additional benefit that during subtraction the bits of the original argument `x` are zero in the relevant bit positions.

Below I show exhaustively tested C99 code for single-precision `sinf()` that I wrote recently that incorporates Payne-Hanek reduction in the slow path of the reduction, see `trig_red_slowpath_f()`. Note that in order to achieve a faithfully rounded `sinf()` one would have to augment the argument reduction to return the reduced argument as two `float` operands in head/tail fashion.

Various design choices are possible, below I opted for largely integer-based computation in order to minimize the storage for the required bits of `2/π`. Implementations using floating-point computation and overlapped pairs or triples of floating-point numbers to store the bits of `2/π` are also common.

``````/* 190 bits of 2/pi for Payne-Hanek style argument reduction. */
static const unsigned int two_over_pi_f [] =
{
0x00000000,
0x28be60db,
0x9391054a,
0x7f09d5f4,
0x7d4d3770,
0x36d8a566,
0x4f10e410
};

float trig_red_slowpath_f (float a, int *quadrant)
{
unsigned long long int p;
unsigned int ia, hi, mid, lo, tmp, i;
int e, q;
float r;

ia = (unsigned int)(fabsf (frexpf (a, &e)) * 0x1.0p32f);

/* extract 96 relevant bits of 2/pi based on magnitude of argument */
i = (unsigned int)e >> 5;
e = (unsigned int)e & 31;

hi  = two_over_pi_f [i+0];
mid = two_over_pi_f [i+1];
lo  = two_over_pi_f [i+2];
tmp = two_over_pi_f [i+3];

if (e) {
hi  = (hi  << e) | (mid >> (32 - e));
mid = (mid << e) | (lo  >> (32 - e));
lo  = (lo  << e) | (tmp >> (32 - e));
}

/* compute product x * 2/pi in 2.62 fixed-point format */
p = (unsigned long long int)ia * lo;
p = (unsigned long long int)ia * mid + (p >> 32);
p = ((unsigned long long int)(ia * hi) << 32) + p;

/* round quotient to nearest */
q = (int)(p >> 62);                // integral portion = quadrant<1:0>
p = p & 0x3fffffffffffffffULL;     // fraction
if (p & 0x2000000000000000ULL) {   // fraction >= 0.5
p = p - 0x4000000000000000ULL; // fraction - 1.0
q = q + 1;
}

/* compute remainder of x / (pi/2) */
double d;

d = (double)(long long int)p;
d = d * 0x1.921fb54442d18p-62; // 1.5707963267948966 * 0x1.0p-62
r = (float)d;
if (a < 0.0f) {
r = -r;
q = -q;
}

*quadrant = q;
return r;
}

/* Like rintf(), but -0.0f -> +0.0f, and |a| must be <= 0x1.0p+22 */
float quick_and_dirty_rintf (float a)
{
float cvt_magic = 0x1.800000p+23f;
return (a + cvt_magic) - cvt_magic;
}

/* Argument reduction for trigonometric functions that reduces the argument
to the interval [-PI/4, +PI/4] and also returns the quadrant. It returns
-0.0f for an input of -0.0f
*/
float trig_red_f (float a, float switch_over, int *q)
{
float j, r;

if (fabsf (a) > switch_over) {
/* Payne-Hanek style reduction. M. Payne and R. Hanek, Radian reduction
for trigonometric functions. SIGNUM Newsletter, 18:19-24, 1983
*/
r = trig_red_slowpath_f (a, q);
} else {
/* FMA-enhanced Cody-Waite style reduction. W. J. Cody and W. Waite,
"Software Manual for the Elementary Functions", Prentice-Hall 1980
*/
j = 0x1.45f306p-1f * a;             // 2/pi
j = quick_and_dirty_rintf (j);
r = fmaf (j, -0x1.921fb0p+00f, a);  // pio2_high
r = fmaf (j, -0x1.5110b4p-22f, r);  // pio2_mid
r = fmaf (j, -0x1.846988p-48f, r);  // pio2_low
*q = (int)j;
}
return r;
}

/* Approximate sine on [-PI/4,+PI/4]. Maximum ulp error = 0.64721
Returns -0.0f for an argument of -0.0f
Polynomial approximation based on unpublished work by T. Myklebust
*/
float sinf_poly (float a, float s)
{
float r;

r =              0x1.7d3bbcp-19f;
r = fmaf (r, s, -0x1.a06bbap-13f);
r = fmaf (r, s,  0x1.11119ap-07f);
r = fmaf (r, s, -0x1.555556p-03f);
r = r * s + 0.0f; // ensure -0 is passed trough
r = fmaf (r, a, a);
return r;
}

/* Approximate cosine on [-PI/4,+PI/4]. Maximum ulp error = 0.87531 */
float cosf_poly (float s)
{
float r;

r =              0x1.98e616p-16f;
r = fmaf (r, s, -0x1.6c06dcp-10f);
r = fmaf (r, s,  0x1.55553cp-05f);
r = fmaf (r, s, -0x1.000000p-01f);
r = fmaf (r, s,  0x1.000000p+00f);
return r;
}

/* Map sine or cosine value based on quadrant */
float sinf_cosf_core (float a, int i)
{
float r, s;

s = a * a;
r = (i & 1) ? cosf_poly (s) : sinf_poly (a, s);
if (i & 2) {
r = 0.0f - r; // don't change "sign" of NaNs
}
return r;
}

/* maximum ulp error = 1.49241 */
float my_sinf (float a)
{
float r;
int i;

a = a * 0.0f + a; // inf -> NaN
r = trig_red_f (a, 117435.992f, &i);
r = sinf_cosf_core (r, i);
return r;
}

/* maximum ulp error = 1.49510 */
float my_cosf (float a)
{
float r;
int i;

a = a * 0.0f + a; // inf -> NaN
r = trig_red_f (a, 71476.0625f, &i);
r = sinf_cosf_core (r, i + 1);
return r;
}
``````
• Why choose π/2 instead of π/4? (i can't find the original paper of the payne-hanek algorithm). – user8469759 May 27 '15 at 8:17
• Note that the rounding of the quotient here is to-nearest, causing the magnitude of the arguments passed to the core approximations to be <= π/4. So only two core approximations are required, and they can be used for both `cosf()` and `sinf()`. I tried to keep the code as simple as possible in hopes of making it easy to read and easy to understand the mechanics of the algorithm. For the same reason I did not target a faithfully rounded function, which would require a double-float output from the reduction process. – njuffa May 27 '15 at 8:38
• I'm studying your code. By the way... for core approximation i guess you mean approximation of sin and cos using the poly approximation isn't? – user8469759 May 27 '15 at 8:47
• By "core approximations" I meant the the two polynomial minimax approximations on the primary approximation interval [- π/4, + π/4], correct. I have now added the `cosf()` implementation to demonstrate that it simply re-uses the code and approximations used for `sinf()`. – njuffa May 27 '15 at 8:52
• I'm trying to follow your code using the original paper i've just found, if you have the same paper is that a problem if i comment your code following that paper? So you can confirm i understood well or not. – user8469759 May 27 '15 at 9:04

As someone who once tried to implement it, I feel your pain (no pun intended).

Before attempting it, make sure you have a good understanding of when floating point operations are exact, and know how double-double arithmetic works.

Other than that, my best advice is to look at what other smart people have done:

• NETLIB: you mentioned it in the question, but this is the file you're interested in. It's a bit confusing, as it tries to do 80-bit long doubles as well.
• OS X (from 10.7.5: Apple no longer makes their libm source available): look for `ReduceFull`
• glibc
• About the theoretic part i've been looking up the Muller books (2 specifically, one is an handbook of floating point arithmetic and another which is specifically focused on function approximation). Apparently the algorithm is very simple, but i need to understand how an actual implementation should be done. I've also tried yesterday to understand the code of Netlib but it is a pain... so i guess it will take some time for the reverse engineering of the code written by "smart people". – user8469759 May 27 '15 at 8:14
• Hi there, i'm sorry... but i'm still struggling with this painful algorithm... i've tried to have a look to the glibc and netlib and try to follow the implementation using the original just to understand the meaning of the several variables used especially in the k_rem_pio function... you said you tried to implement it, did you understand well the code you posted? do you mind if i make you some question about that code? – user8469759 Jun 25 '15 at 15:23
• I never finished it, and don't have the code available. That said, I think the OS X code is the easiest, and Muller's 2005 book (Elementary Functions) seems to have the best explanation. – Simon Byrne Jun 25 '15 at 16:57
• I did get around to finishing my implementation gist.github.com/simonbyrne/d640ac1c1db3e1774cf2d405049beef3. It's written in Julia, but it shouldn't be too hard to translate to C if you can take advantage of the checked arithmetic operations (available in gcc or clang) – Simon Byrne Feb 9 '17 at 20:56
• Thank you! I'll have a look as soon as I can. – user8469759 Feb 9 '17 at 22:28