* Copyright (c) 1985 Regents of the University of California.
* Use and reproduction of this software are granted in accordance with
* the terms and conditions specified in the Berkeley Software License
* Agreement (in particular, this entails acknowledgement of the programs'
* source, and inclusion of this notice) with the additional understanding
* that all recipients should regard themselves as participants in an
* ongoing research project and hence should feel obligated to report
* their experiences (good or bad) with these elementary function codes,
* using "sendbug 4bsd-bugs@BERKELEY", to the authors.
"@(#)trig.c 1.2 (Berkeley) 8/22/85; 1.7 (ucb.elefunt) %G%";
/* SIN(X), COS(X), TAN(X)
* RETURN THE SINE, COSINE, AND TANGENT OF X RESPECTIVELY
* DOUBLE PRECISION (VAX D format 56 bits, IEEE DOUBLE 53 BITS)
* CODED IN C BY K.C. NG, 1/8/85;
* REVISED BY W. Kahan and K.C. NG, 8/17/85.
* Required system supported functions:
* Static kernel functions:
* sin__S(z) ....sin__S(x*x) return (sin(x)-x)/x
* cos__C(z) ....cos__C(x*x) return cos(x)-1-x*x/2
* Let S and C denote the polynomial approximations to sin and cos
* respectively on [-PI/4, +PI/4].
* 1. Reduce the argument into [-PI , +PI] by the remainder function.
* 2. For x in (-PI,+PI), there are three cases:
* case 2: PI/4 <= |x| < 3PI/4
* SIN and COS of x are computed by:
* ----------------------------------------------------------
* case 2 sign(x)*C(y) S(y) y=PI/2-|x|
* case 3 S(y) -C(y) y=sign(x)*(PI-|x|)
* ----------------------------------------------------------
* 1. Reduce the argument into [-PI/2 , +PI/2] by the remainder function.
* 2. For x in (-PI/2,+PI/2), there are two cases:
* case 2: PI/4 <= |x| < PI/2
* TAN of x is computed by:
* ----------------------------------------------------------
* case 2 C(y)/S(y) y=sign(x)*(PI/2-|x|)
* ----------------------------------------------------------
* 1. S(y) and C(y) were computed by:
* C(y) = 1-(y*y/2-cos__C(x*x)) ... if y*y/2 < thresh,
* = 0.5-((y*y/2-0.5)-cos__C(x*x)) ... if y*y/2 >= thresh.
* thresh = 0.5*(acos(3/4)**2)
* 2. For better accuracy, we use the following formula for S/C for tan
* (k=0): let ss=sin__S(y*y), and cc=cos__C(y*y), then
* S(y)/C(y) = -------- = y + y * ---------------.
* Let trig be any of sin, cos, or tan.
* trig(+-INF) is NaN, with signals;
* trig(n*PI/2) is exact for any integer n, provided n*PI is
* representable; otherwise, trig(x) is inexact.
* trig(x) returns the exact trig(x*pi/PI) nearly rounded, where
* pi = 3.141592653589793 23846264338327 .....
* 53 bits PI = 3.141592653589793 115997963 ..... ,
* 56 bits PI = 3.141592653589793 227020265 ..... ,
* pi = 3.243F6A8885A308D313198A2E....
* 53 bits PI = 3.243F6A8885A30 = 2 * 1.921FB54442D18 error=.276ulps
* 56 bits PI = 3.243F6A8885A308 = 4 * .C90FDAA22168C2 error=.206ulps
* In a test run with 1,024,000 random arguments on a VAX, the maximum
* observed errors (compared with the exact trig(x*pi/PI)) were
* tan(x) : 2.09 ulps (around 4.716340404662354)
* The hexadecimal values are the intended ones for the following constants.
* The decimal values may be used, provided that the compiler will convert
* from decimal to binary accurately enough to produce the hexadecimal values
#if defined(vax)||defined(tahoe)
#define _0x(A,B) 0x/**/A/**/B
#define _0x(A,B) 0x/**/B/**/A
/*thresh = 2.6117239648121182150E-1 , Hex 2^ -1 * .85B8636B026EA0 */
/*PIo4 = 7.8539816339744830676E-1 , Hex 2^ 0 * .C90FDAA22168C2 */
/*PIo2 = 1.5707963267948966135E0 , Hex 2^ 1 * .C90FDAA22168C2 */
/*PI3o4 = 2.3561944901923449203E0 , Hex 2^ 2 * .96CBE3F9990E92 */
/*PI = 3.1415926535897932270E0 , Hex 2^ 2 * .C90FDAA22168C2 */
/*PI2 = 6.2831853071795864540E0 ; Hex 2^ 3 * .C90FDAA22168C2 */
static long threshx
[] = { _0x(b863
,3f85
), _0x(6ea0
,6b02
)};
#define thresh (*(double*)threshx)
static long PIo4x
[] = { _0x(0fda
,4049), _0x(68c2
,a221
)};
#define PIo4 (*(double*)PIo4x)
static long PIo2x
[] = { _0x(0fda
,40c9
), _0x(68c2
,a221
)};
#define PIo2 (*(double*)PIo2x)
static long PI3o4x
[] = { _0x(cbe3
,4116), _0x(0e92
,f999
)};
#define PI3o4 (*(double*)PI3o4x)
static long PIx
[] = { _0x(0fda
,4149), _0x(68c2
,a221
)};
#define PI (*(double*)PIx)
static long PI2x
[] = { _0x(0fda
,41c9
), _0x(68c2
,a221
)};
#define PI2 (*(double*)PI2x)
#else /* defined(vax)||defined(tahoe) */
thresh
= 2.6117239648121182150E-1 , /*Hex 2^ -2 * 1.0B70C6D604DD4 */
PIo4
= 7.8539816339744827900E-1 , /*Hex 2^ -1 * 1.921FB54442D18 */
PIo2
= 1.5707963267948965580E0
, /*Hex 2^ 0 * 1.921FB54442D18 */
PI3o4
= 2.3561944901923448370E0
, /*Hex 2^ 1 * 1.2D97C7F3321D2 */
PI
= 3.1415926535897931160E0
, /*Hex 2^ 1 * 1.921FB54442D18 */
PI2
= 6.2831853071795862320E0
; /*Hex 2^ 2 * 1.921FB54442D18 */
static long fmaxx
[] = { 0xffffffff, 0x7fefffff};
#define fmax (*(double*)fmaxx)
#endif /* defined(vax)||defined(tahoe) */
static double zero
=0, one
=1, negone
= -1, half
=1.0/2.0,
small
=1E-10, /* 1+small**2==1; better values for small:
= 2.8E-10 for IEEE Extended */
big
=1E20
; /* big = 1/(small**2) */
double copysign(),drem(),cos__C(),sin__S(),a
,z
,ss
,cc
,c
;
/* tan(NaN) and tan(INF) must be NaN */
if(!finite(x
)) return(x
-x
);
x
=drem(x
,PI
); /* reduce x into [-PI/2, PI/2] */
a
=copysign(x
,one
); /* ... = abs(x) */
if ( a
>= PIo4
) {k
=1; x
= copysign( PIo2
- a
, x
); }
else { k
=0; if(a
< small
) { big
+ a
; return(x
); }}
z
= z
*half
; /* Next get c = cos(x) accurately */
c
= (z
>= thresh
)? half
-((z
-half
)-cc
) : one
-(z
-cc
);
if (k
==0) return ( x
+ (x
*(z
-(cc
-ss
)))/c
); /* sin/cos */
else if(x
==0.0) return copysign(fmax
,x
); /* no inf on 32k */
else return( c
/(x
+x
*ss
) ); /* ... cos/sin */
double copysign(),drem(),sin__S(),cos__C(),a
,c
,z
;
/* sin(NaN) and sin(INF) must be NaN */
if(!finite(x
)) return(x
-x
);
x
=drem(x
,PI2
); /* reduce x into [-PI, PI] */
if( a
>= PI3o4
) /* .. in [3PI/4, PI ] */
else { /* .. in [PI/4, 3PI/4] */
a
=PIo2
-a
; /* return sign(x)*C(PI/2-|x|) */
a
=(z
>=thresh
)?half
-((z
-half
)-c
):one
-(z
-c
);
if( a
< small
) { big
+ a
; return(x
);}
double copysign(),drem(),sin__S(),cos__C(),a
,c
,z
,s
=1.0;
/* cos(NaN) and cos(INF) must be NaN */
if(!finite(x
)) return(x
-x
);
x
=drem(x
,PI2
); /* reduce x into [-PI, PI] */
if ( a
>= PI3o4
) /* .. in [3PI/4, PI ] */
else /* .. in [PI/4, 3PI/4] */
{ a
=PIo2
-a
; return(a
+a
*sin__S(a
*a
));}
if( a
< small
) { big
+ a
; return(s
);}
a
=(z
>=thresh
)?half
-((z
-half
)-c
):one
-(z
-c
);
* DOUBLE PRECISION (VAX D format 56 bits, IEEE DOUBLE 53 BITS)
* STATIC KERNEL FUNCTION OF SIN(X), COS(X), AND TAN(X)
* CODED IN C BY K.C. NG, 1/21/85;
* REVISED BY K.C. NG on 8/13/85.
* RETURN --------------- on [-PI/4,PI/4] , where k=pi/PI, PI is the rounded
* value of pi in machine precision:
* pi = 3.141592653589793 23846264338327 .....
* 53 bits PI = 3.141592653589793 115997963 ..... ,
* 56 bits PI = 3.141592653589793 227020265 ..... ,
* pi = 3.243F6A8885A308D313198A2E....
* 53 bits PI = 3.243F6A8885A30 = 2 * 1.921FB54442D18
* 56 bits PI = 3.243F6A8885A308 = 4 * .C90FDAA22168C2
* 1. Let z=x*x. Create a polynomial approximation to
* (sin(k*x)-x)/x = z*(S0 + S1*z^1 + ... + S5*z^5).
* sin__S(x*x) = z*(S0 + S1*z^1 + ... + S5*z^5)
* The coefficient S's are obtained by a special Remez algorithm.
* In the absence of rounding error, the approximation has absolute error
* less than 2**(-61.11) for VAX D FORMAT, 2**(-57.45) for IEEE DOUBLE.
* The hexadecimal values are the intended ones for the following constants.
* The decimal values may be used, provided that the compiler will convert
* from decimal to binary accurately enough to produce the hexadecimal values
#if defined(vax)||defined(tahoe)
/*S0 = -1.6666666666666646660E-1 , Hex 2^ -2 * -.AAAAAAAAAAAA71 */
/*S1 = 8.3333333333297230413E-3 , Hex 2^ -6 * .8888888888477F */
/*S2 = -1.9841269838362403710E-4 , Hex 2^-12 * -.D00D00CF8A1057 */
/*S3 = 2.7557318019967078930E-6 , Hex 2^-18 * .B8EF1CA326BEDC */
/*S4 = -2.5051841873876551398E-8 , Hex 2^-25 * -.D73195374CE1D3 */
/*S5 = 1.6028995389845827653E-10 , Hex 2^-32 * .B03D9C6D26CCCC */
/*S6 = -6.2723499671769283121E-13 ; Hex 2^-40 * -.B08D0B7561EA82 */
static long S0x
[] = { _0x(aaaa
,bf2a
), _0x(aa71
,aaaa
)};
#define S0 (*(double*)S0x)
static long S1x
[] = { _0x(8888,3d08
), _0x(477f
,8888)};
#define S1 (*(double*)S1x)
static long S2x
[] = { _0x(0d00
,ba50
), _0x(1057,cf8a
)};
#define S2 (*(double*)S2x)
static long S3x
[] = { _0x(ef1c
,3738), _0x(bedc
,a326
)};
#define S3 (*(double*)S3x)
static long S4x
[] = { _0x(3195,b3d7
), _0x(e1d3
,374c
)};
#define S4 (*(double*)S4x)
static long S5x
[] = { _0x(3d9c
,3030), _0x(cccc
,6d26
)};
#define S5 (*(double*)S5x)
static long S6x
[] = { _0x(8d0b
,ac30
), _0x(ea82
,7561)};
#define S6 (*(double*)S6x)
S0
= -1.6666666666666463126E-1 , /*Hex 2^ -3 * -1.555555555550C */
S1
= 8.3333333332992771264E-3 , /*Hex 2^ -7 * 1.111111110C461 */
S2
= -1.9841269816180999116E-4 , /*Hex 2^-13 * -1.A01A019746345 */
S3
= 2.7557309793219876880E-6 , /*Hex 2^-19 * 1.71DE3209CDCD9 */
S4
= -2.5050225177523807003E-8 , /*Hex 2^-26 * -1.AE5C0E319A4EF */
S5
= 1.5868926979889205164E-10 ; /*Hex 2^-33 * 1.5CF61DF672B13 */
#if defined(vax)||defined(tahoe)
return(z
*(S0
+z
*(S1
+z
*(S2
+z
*(S3
+z
*(S4
+z
*(S5
+z
*S6
)))))));
#else /* defined(vax)||defined(tahoe) */
return(z
*(S0
+z
*(S1
+z
*(S2
+z
*(S3
+z
*(S4
+z
*S5
))))));
#endif /* defined(vax)||defined(tahoe) */
* DOUBLE PRECISION (VAX D FORMAT 56 BITS, IEEE DOUBLE 53 BITS)
* STATIC KERNEL FUNCTION OF SIN(X), COS(X), AND TAN(X)
* CODED IN C BY K.C. NG, 1/21/85;
* REVISED BY K.C. NG on 8/13/85.
* RETURN cos(k*x) - 1 + ----- on [-PI/4,PI/4], where k = pi/PI,
* PI is the rounded value of pi in machine precision :
* pi = 3.141592653589793 23846264338327 .....
* 53 bits PI = 3.141592653589793 115997963 ..... ,
* 56 bits PI = 3.141592653589793 227020265 ..... ,
* pi = 3.243F6A8885A308D313198A2E....
* 53 bits PI = 3.243F6A8885A30 = 2 * 1.921FB54442D18
* 56 bits PI = 3.243F6A8885A308 = 4 * .C90FDAA22168C2
* 1. Let z=x*x. Create a polynomial approximation to
* cos(k*x)-1+z/2 = z*z*(C0 + C1*z^1 + ... + C5*z^5)
* cos__C(z) = z*z*(C0 + C1*z^1 + ... + C5*z^5)
* The coefficient C's are obtained by a special Remez algorithm.
* In the absence of rounding error, the approximation has absolute error
* less than 2**(-64) for VAX D FORMAT, 2**(-58.3) for IEEE DOUBLE.
* The hexadecimal values are the intended ones for the following constants.
* The decimal values may be used, provided that the compiler will convert
* from decimal to binary accurately enough to produce the hexadecimal values
#if defined(vax)||defined(tahoe)
/*C0 = 4.1666666666666504759E-2 , Hex 2^ -4 * .AAAAAAAAAAA9F0 */
/*C1 = -1.3888888888865302059E-3 , Hex 2^ -9 * -.B60B60B60A0CCA */
/*C2 = 2.4801587285601038265E-5 , Hex 2^-15 * .D00D00CDCD098F */
/*C3 = -2.7557313470902390219E-7 , Hex 2^-21 * -.93F27BB593E805 */
/*C4 = 2.0875623401082232009E-9 , Hex 2^-28 * .8F74C8FA1E3FF0 */
/*C5 = -1.1355178117642986178E-11 ; Hex 2^-36 * -.C7C32D0A5C5A63 */
static long C0x
[] = { _0x(aaaa
,3e2a
), _0x(a9f0
,aaaa
)};
#define C0 (*(double*)C0x)
static long C1x
[] = { _0x(0b60,bbb6
), _0x(0cca
,b60a
)};
#define C1 (*(double*)C1x)
static long C2x
[] = { _0x(0d00
,38d0
), _0x(098f
,cdcd
)};
#define C2 (*(double*)C2x)
static long C3x
[] = { _0x(f27b
,b593
), _0x(e805
,b593
)};
#define C3 (*(double*)C3x)
static long C4x
[] = { _0x(74c8
,320f
), _0x(3ff0
,fa1e
)};
#define C4 (*(double*)C4x)
static long C5x
[] = { _0x(c32d
,ae47
), _0x(5a63
,0a5c
)};
#define C5 (*(double*)C5x)
#else /* defined(vax)||defined(tahoe) */
C0
= 4.1666666666666504759E-2 , /*Hex 2^ -5 * 1.555555555553E */
C1
= -1.3888888888865301516E-3 , /*Hex 2^-10 * -1.6C16C16C14199 */
C2
= 2.4801587269650015769E-5 , /*Hex 2^-16 * 1.A01A01971CAEB */
C3
= -2.7557304623183959811E-7 , /*Hex 2^-22 * -1.27E4F1314AD1A */
C4
= 2.0873958177697780076E-9 , /*Hex 2^-29 * 1.1EE3B60DDDC8C */
C5
= -1.1250289076471311557E-11 ; /*Hex 2^-37 * -1.8BD5986B2A52E */
#endif /* defined(vax)||defined(tahoe) */
return(z
*z
*(C0
+z
*(C1
+z
*(C2
+z
*(C3
+z
*(C4
+z
*C5
))))));