freebsd-dev/lib/msun/src/s_sin.c

/* @(#)s_sin.c 5.1 93/09/24 */
/*
 * ====================================================
 * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved.
 *
 * Developed at SunPro, a Sun Microsystems, Inc. business.
 * Permission to use, copy, modify, and distribute this
 * software is freely granted, provided that this notice
 * is preserved.
 * ====================================================
 */

#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");

/* sin(x)
 * Return sine function of x.
 *
 * kernel function:
 *	__kernel_sin		... sine function on [-pi/4,pi/4]
 *	__kernel_cos		... cose function on [-pi/4,pi/4]
 *	__ieee754_rem_pio2	... argument reduction routine
 *
 * Method.
 *      Let S,C and T denote the sin, cos and tan respectively on
 *	[-PI/4, +PI/4]. Reduce the argument x to y1+y2 = x-k*pi/2
 *	in [-pi/4 , +pi/4], and let n = k mod 4.
 *	We have
 *
 *          n        sin(x)      cos(x)        tan(x)
 *     ----------------------------------------------------------
 *	    0	       S	   C		 T
 *	    1	       C	  -S		-1/T
 *	    2	      -S	  -C		 T
 *	    3	      -C	   S		-1/T
 *     ----------------------------------------------------------
 *
 * Special cases:
 *      Let trig be any of sin, cos, or tan.
 *      trig(+-INF)  is NaN, with signals;
 *      trig(NaN)    is that NaN;
 *
 * Accuracy:
 *	TRIG(x) returns trig(x) nearly rounded
 */

#include <float.h>

#include "math.h"
#define INLINE_REM_PIO2
#include "math_private.h"
#include "e_rem_pio2.c"

double
sin(double x)
{
	double y[2],z=0.0;
	int32_t n, ix;

    /* High word of x. */
	GET_HIGH_WORD(ix,x);

    /* |x| ~< pi/4 */
	ix &= 0x7fffffff;
	if(ix <= 0x3fe921fb) {
	    if(ix<0x3e500000)			/* |x| < 2**-26 */
	       {if((int)x==0) return x;}	/* generate inexact */
	    return __kernel_sin(x,z,0);
	}

    /* sin(Inf or NaN) is NaN */
	else if (ix>=0x7ff00000) return x-x;

    /* argument reduction needed */
	else {
	    n = __ieee754_rem_pio2(x,y);
	    switch(n&3) {
		case 0: return  __kernel_sin(y[0],y[1],1);
		case 1: return  __kernel_cos(y[0],y[1]);
		case 2: return -__kernel_sin(y[0],y[1],1);
		default:
			return -__kernel_cos(y[0],y[1]);
	    }
	}
}

#if (LDBL_MANT_DIG == 53)
__weak_reference(sin, sinl);
#endif
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`/* @(#)s_sin.c 5.1 93/09/24 */`
			`/*`
			`* ====================================================`
			`* Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved.`
			`*`
			`* Developed at SunPro, a Sun Microsystems, Inc. business.`
			`* Permission to use, copy, modify, and distribute this`
Remove trailing whitespace. 1995-05-30 05:51:47 +00:00			`* software is freely granted, provided that this notice`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`* is preserved.`
			`* ====================================================`
			`*/`

Inline __ieee754__rem_pio2(). With gcc4-2, this gives an average optimization of about 10% for cos(x), sin(x) and tan(x) on \|x\| < 2*19pi/2. We didn't do this before because __ieee754__rem_pio2() is too large and complicated for gcc-3.3 to inline very well. We don't do this for float precision because it interferes with optimization of the usual (?) case (\|x\| < 9pi/4) which is manually inlined for float precision only. This has some rough edges: - some static data is duplicated unnecessarily. There isn't much after the recent move of large tables to k_rem_pio2.c, and some static data is duplicated to good affect (all the data static const, so that the compiler can evaluate expressions like 2*pio2 at compile time and generate even more static data for the constant for this). - extern inline is used (for the same reason as in previous inlining of k_cosf.c etc.), but C99 apparently doesn't allow extern inline functions with static data, and gcc will eventually warn about this. Convert to __FBSDID(). Indent __ieee754_rem_pio2()'s declaration consistently (its style was made inconsistent with fdlibm a while ago, so complete this). Fix __ieee754_rem_pio2()'s return type to match its prototype. Someone changed too many ints to int32_t's when fixing the assumption that all ints are int32_t's. 2008-02-18 14:02:12 +00:00			`#include <sys/cdefs.h>`
			`__FBSDID("$FreeBSD$");`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00
			`/* sin(x)`
			`* Return sine function of x.`
			`*`
			`* kernel function:`
			`* __kernel_sin ... sine function on [-pi/4,pi/4]`
			`* __kernel_cos ... cose function on [-pi/4,pi/4]`
			`* __ieee754_rem_pio2 ... argument reduction routine`
			`*`
			`* Method.`
Remove trailing whitespace. 1995-05-30 05:51:47 +00:00			`* Let S,C and T denote the sin, cos and tan respectively on`
			`* [-PI/4, +PI/4]. Reduce the argument x to y1+y2 = x-k*pi/2`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`* in [-pi/4 , +pi/4], and let n = k mod 4.`
			`* We have`
			`*`
			`* n sin(x) cos(x) tan(x)`
			`* ----------------------------------------------------------`
			`* 0 S C T`
			`* 1 C -S -1/T`
			`* 2 -S -C T`
			`* 3 -C S -1/T`
			`* ----------------------------------------------------------`
			`*`
			`* Special cases:`
			`* Let trig be any of sin, cos, or tan.`
			`* trig(+-INF) is NaN, with signals;`
			`* trig(NaN) is that NaN;`
			`*`
			`* Accuracy:`
Remove trailing whitespace. 1995-05-30 05:51:47 +00:00			`* TRIG(x) returns trig(x) nearly rounded`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`*/`

Add implementations of sinl(), cosl(), and tanl(). Submitted by: Steve Kargl <sgk@apl.washington.edu> 2008-02-17 07:33:12 +00:00			`#include <float.h>`

J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`#include "math.h"`
Inline __ieee754__rem_pio2(). With gcc4-2, this gives an average optimization of about 10% for cos(x), sin(x) and tan(x) on \|x\| < 2*19pi/2. We didn't do this before because __ieee754__rem_pio2() is too large and complicated for gcc-3.3 to inline very well. We don't do this for float precision because it interferes with optimization of the usual (?) case (\|x\| < 9pi/4) which is manually inlined for float precision only. This has some rough edges: - some static data is duplicated unnecessarily. There isn't much after the recent move of large tables to k_rem_pio2.c, and some static data is duplicated to good affect (all the data static const, so that the compiler can evaluate expressions like 2*pio2 at compile time and generate even more static data for the constant for this). - extern inline is used (for the same reason as in previous inlining of k_cosf.c etc.), but C99 apparently doesn't allow extern inline functions with static data, and gcc will eventually warn about this. Convert to __FBSDID(). Indent __ieee754_rem_pio2()'s declaration consistently (its style was made inconsistent with fdlibm a while ago, so complete this). Fix __ieee754_rem_pio2()'s return type to match its prototype. Someone changed too many ints to int32_t's when fixing the assumption that all ints are int32_t's. 2008-02-18 14:02:12 +00:00			`#define INLINE_REM_PIO2`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`#include "math_private.h"`
Inline __ieee754__rem_pio2(). With gcc4-2, this gives an average optimization of about 10% for cos(x), sin(x) and tan(x) on \|x\| < 2*19pi/2. We didn't do this before because __ieee754__rem_pio2() is too large and complicated for gcc-3.3 to inline very well. We don't do this for float precision because it interferes with optimization of the usual (?) case (\|x\| < 9pi/4) which is manually inlined for float precision only. This has some rough edges: - some static data is duplicated unnecessarily. There isn't much after the recent move of large tables to k_rem_pio2.c, and some static data is duplicated to good affect (all the data static const, so that the compiler can evaluate expressions like 2*pio2 at compile time and generate even more static data for the constant for this). - extern inline is used (for the same reason as in previous inlining of k_cosf.c etc.), but C99 apparently doesn't allow extern inline functions with static data, and gcc will eventually warn about this. Convert to __FBSDID(). Indent __ieee754_rem_pio2()'s declaration consistently (its style was made inconsistent with fdlibm a while ago, so complete this). Fix __ieee754_rem_pio2()'s return type to match its prototype. Someone changed too many ints to int32_t's when fixing the assumption that all ints are int32_t's. 2008-02-18 14:02:12 +00:00			`#include "e_rem_pio2.c"`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00
Fix formatting, this is hard to explain, so I'll show one example. - float ynf(int n, float x) /* wrapper ynf / +float +ynf(int n, float x) / wrapper ynf */ This is because the __STDC__ stuff was indented. Reviewed by: md5 2002-05-28 18:15:04 +00:00			`double`
Only provide one copy of the math functions. If we provide a MD function, do not also provide a __generic_XXX version as well. This is how we used to runtime select the generic vs i387 versions on the i386 platform. This saves a pile of #defines in the src/math_private.h file to undo the __generic_XXX renames in some of the *.c files. 2003-07-23 04:53:47 +00:00			`sin(double x)`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00			`{`
			`double y[2],z=0.0;`
			`int32_t n, ix;`

			`/* High word of x. */`
			`GET_HIGH_WORD(ix,x);`

			`/* \|x\| ~< pi/4 */`
			`ix &= 0x7fffffff;`
Moved the optimization for tiny x from __kernel_{cos,sin}[f](x) to {cos_sin}[f](x) so that x doesn't need to be reclassified in the "kernel" functions to determine if it is tiny (it still needs to be reclassified in the cosine case for other reasons that will go away). This optimization is quite large for exponentially distributed x, since x is tiny for almost half of the domain, but it is a pessimization for uniformally distributed x since it takes a little time for all cases but rarely applies. Arg reduction on exponentially distributed x rarely gives a tiny x unless the reduction is null, so it is best to only do the optimization if the initial x is tiny, which is what this commit arranges. The imediate result is an average optimization of 1.4% relative to the previous version in a case that doesn't favour the optimization (double cos(x) on all float x) and a large pessimization for the relatively unimportant cases of lgamma[f][_r](x) on tiny, negative, exponentially distributed x. The optimization should be recovered for lgamma() as part of fixing lgamma()'s low-quality arg reduction. Fixed various wrong constants for the cutoff for "tiny". For cosine, the cutoff is when x2/2! == {FLT or DBL}_EPSILON/2. We round down to an integral power of 2 (and for cos() reduce the power by another 1) because the exact cutoff doesn't matter and would take more work to determine. For sine, the exact cutoff is larger due to the ration of terms being x2/3! instead of x2/2!, but we use the same cutoff as for cosine. We now use a cutoff of 2-27 for double precision and 2-12 for single precision. 2-27 was used in all cases but was misspelled 2**27 in comments. Wrong and sloppy cutoffs just cause missed optimizations (provided the rounding mode is to nearest -- other modes just aren't supported). 2005-10-24 14:08:36 +00:00			`if(ix <= 0x3fe921fb) {`
For small arguments, these functions use simple approximations, e.g. cos(small) = 1, sin(small) = small. This commit tightens the thresholds at which the simple approximations are used. Reviewed by: bde 2011-02-10 07:37:50 +00:00			`if(ix<0x3e500000) /* \|x\| < 2*-26 /`
Moved the optimization for tiny x from __kernel_{cos,sin}[f](x) to {cos_sin}[f](x) so that x doesn't need to be reclassified in the "kernel" functions to determine if it is tiny (it still needs to be reclassified in the cosine case for other reasons that will go away). This optimization is quite large for exponentially distributed x, since x is tiny for almost half of the domain, but it is a pessimization for uniformally distributed x since it takes a little time for all cases but rarely applies. Arg reduction on exponentially distributed x rarely gives a tiny x unless the reduction is null, so it is best to only do the optimization if the initial x is tiny, which is what this commit arranges. The imediate result is an average optimization of 1.4% relative to the previous version in a case that doesn't favour the optimization (double cos(x) on all float x) and a large pessimization for the relatively unimportant cases of lgamma[f][_r](x) on tiny, negative, exponentially distributed x. The optimization should be recovered for lgamma() as part of fixing lgamma()'s low-quality arg reduction. Fixed various wrong constants for the cutoff for "tiny". For cosine, the cutoff is when x2/2! == {FLT or DBL}_EPSILON/2. We round down to an integral power of 2 (and for cos() reduce the power by another 1) because the exact cutoff doesn't matter and would take more work to determine. For sine, the exact cutoff is larger due to the ration of terms being x2/3! instead of x2/2!, but we use the same cutoff as for cosine. We now use a cutoff of 2-27 for double precision and 2-12 for single precision. 2-27 was used in all cases but was misspelled 2**27 in comments. Wrong and sloppy cutoffs just cause missed optimizations (provided the rounding mode is to nearest -- other modes just aren't supported). 2005-10-24 14:08:36 +00:00			`{if((int)x==0) return x;} /* generate inexact */`
			`return __kernel_sin(x,z,0);`
			`}`
J.T. Conklin's latest version of the Sun math library. -- Begin comments from J.T. Conklin: The most significant improvement is the addition of "float" versions of the math functions that take float arguments, return floats, and do all operations in floating point. This doesn't help (performance) much on the i386, but they are still nice to have. The float versions were orginally done by Cygnus' Ian Taylor when fdlibm was integrated into the libm we support for embedded systems. I gave Ian a copy of my libm as a starting point since I had already fixed a lot of bugs & problems in Sun's original code. After he was done, I cleaned it up a bit and integrated the changes back into my libm. -- End comments Reviewed by: jkh Submitted by: jtc 1994-08-19 09:40:01 +00:00
			`/* sin(Inf or NaN) is NaN */`
			`else if (ix>=0x7ff00000) return x-x;`

			`/* argument reduction needed */`
			`else {`
			`n = __ieee754_rem_pio2(x,y);`
			`switch(n&3) {`
			`case 0: return __kernel_sin(y[0],y[1],1);`
			`case 1: return __kernel_cos(y[0],y[1]);`
			`case 2: return -__kernel_sin(y[0],y[1],1);`
			`default:`
			`return -__kernel_cos(y[0],y[1]);`
			`}`
			`}`
			`}`
Add implementations of sinl(), cosl(), and tanl(). Submitted by: Steve Kargl <sgk@apl.washington.edu> 2008-02-17 07:33:12 +00:00
			`#if (LDBL_MANT_DIG == 53)`
			`__weak_reference(sin, sinl);`
			`#endif`