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-rw-r--r--libm/float/sinf.c283
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diff --git a/libm/float/sinf.c b/libm/float/sinf.c
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-/* sinf.c
- *
- * Circular sine
- *
- *
- *
- * SYNOPSIS:
- *
- * float x, y, sinf();
- *
- * y = sinf( x );
- *
- *
- *
- * DESCRIPTION:
- *
- * Range reduction is into intervals of pi/4. The reduction
- * error is nearly eliminated by contriving an extended precision
- * modular arithmetic.
- *
- * Two polynomial approximating functions are employed.
- * Between 0 and pi/4 the sine is approximated by
- * x + x**3 P(x**2).
- * Between pi/4 and pi/2 the cosine is represented as
- * 1 - x**2 Q(x**2).
- *
- *
- * ACCURACY:
- *
- * Relative error:
- * arithmetic domain # trials peak rms
- * IEEE -4096,+4096 100,000 1.2e-7 3.0e-8
- * IEEE -8192,+8192 100,000 3.0e-7 3.0e-8
- *
- * ERROR MESSAGES:
- *
- * message condition value returned
- * sin total loss x > 2^24 0.0
- *
- * Partial loss of accuracy begins to occur at x = 2^13
- * = 8192. Results may be meaningless for x >= 2^24
- * The routine as implemented flags a TLOSS error
- * for x >= 2^24 and returns 0.0.
- */
-
-/* cosf.c
- *
- * Circular cosine
- *
- *
- *
- * SYNOPSIS:
- *
- * float x, y, cosf();
- *
- * y = cosf( x );
- *
- *
- *
- * DESCRIPTION:
- *
- * Range reduction is into intervals of pi/4. The reduction
- * error is nearly eliminated by contriving an extended precision
- * modular arithmetic.
- *
- * Two polynomial approximating functions are employed.
- * Between 0 and pi/4 the cosine is approximated by
- * 1 - x**2 Q(x**2).
- * Between pi/4 and pi/2 the sine is represented as
- * x + x**3 P(x**2).
- *
- *
- * ACCURACY:
- *
- * Relative error:
- * arithmetic domain # trials peak rms
- * IEEE -8192,+8192 100,000 3.0e-7 3.0e-8
- */
-
-/*
-Cephes Math Library Release 2.2: June, 1992
-Copyright 1985, 1987, 1988, 1992 by Stephen L. Moshier
-Direct inquiries to 30 Frost Street, Cambridge, MA 02140
-*/
-
-
-/* Single precision circular sine
- * test interval: [-pi/4, +pi/4]
- * trials: 10000
- * peak relative error: 6.8e-8
- * rms relative error: 2.6e-8
- */
-#include <math.h>
-
-
-static float FOPI = 1.27323954473516;
-
-extern float PIO4F;
-/* Note, these constants are for a 32-bit significand: */
-/*
-static float DP1 = 0.7853851318359375;
-static float DP2 = 1.30315311253070831298828125e-5;
-static float DP3 = 3.03855025325309630e-11;
-static float lossth = 65536.;
-*/
-
-/* These are for a 24-bit significand: */
-static float DP1 = 0.78515625;
-static float DP2 = 2.4187564849853515625e-4;
-static float DP3 = 3.77489497744594108e-8;
-static float lossth = 8192.;
-static float T24M1 = 16777215.;
-
-static float sincof[] = {
--1.9515295891E-4,
- 8.3321608736E-3,
--1.6666654611E-1
-};
-static float coscof[] = {
- 2.443315711809948E-005,
--1.388731625493765E-003,
- 4.166664568298827E-002
-};
-
-float sinf( float xx )
-{
-float *p;
-float x, y, z;
-register unsigned long j;
-register int sign;
-
-sign = 1;
-x = xx;
-if( xx < 0 )
- {
- sign = -1;
- x = -xx;
- }
-if( x > T24M1 )
- {
- mtherr( "sinf", TLOSS );
- return(0.0);
- }
-j = FOPI * x; /* integer part of x/(PI/4) */
-y = j;
-/* map zeros to origin */
-if( j & 1 )
- {
- j += 1;
- y += 1.0;
- }
-j &= 7; /* octant modulo 360 degrees */
-/* reflect in x axis */
-if( j > 3)
- {
- sign = -sign;
- j -= 4;
- }
-
-if( x > lossth )
- {
- mtherr( "sinf", PLOSS );
- x = x - y * PIO4F;
- }
-else
- {
-/* Extended precision modular arithmetic */
- x = ((x - y * DP1) - y * DP2) - y * DP3;
- }
-/*einits();*/
-z = x * x;
-if( (j==1) || (j==2) )
- {
-/* measured relative error in +/- pi/4 is 7.8e-8 */
-/*
- y = (( 2.443315711809948E-005 * z
- - 1.388731625493765E-003) * z
- + 4.166664568298827E-002) * z * z;
-*/
- p = coscof;
- y = *p++;
- y = y * z + *p++;
- y = y * z + *p++;
- y *= z * z;
- y -= 0.5 * z;
- y += 1.0;
- }
-else
- {
-/* Theoretical relative error = 3.8e-9 in [-pi/4, +pi/4] */
-/*
- y = ((-1.9515295891E-4 * z
- + 8.3321608736E-3) * z
- - 1.6666654611E-1) * z * x;
- y += x;
-*/
- p = sincof;
- y = *p++;
- y = y * z + *p++;
- y = y * z + *p++;
- y *= z * x;
- y += x;
- }
-/*einitd();*/
-if(sign < 0)
- y = -y;
-return( y);
-}
-
-
-/* Single precision circular cosine
- * test interval: [-pi/4, +pi/4]
- * trials: 10000
- * peak relative error: 8.3e-8
- * rms relative error: 2.2e-8
- */
-
-float cosf( float xx )
-{
-float x, y, z;
-int j, sign;
-
-/* make argument positive */
-sign = 1;
-x = xx;
-if( x < 0 )
- x = -x;
-
-if( x > T24M1 )
- {
- mtherr( "cosf", TLOSS );
- return(0.0);
- }
-
-j = FOPI * x; /* integer part of x/PIO4 */
-y = j;
-/* integer and fractional part modulo one octant */
-if( j & 1 ) /* map zeros to origin */
- {
- j += 1;
- y += 1.0;
- }
-j &= 7;
-if( j > 3)
- {
- j -=4;
- sign = -sign;
- }
-
-if( j > 1 )
- sign = -sign;
-
-if( x > lossth )
- {
- mtherr( "cosf", PLOSS );
- x = x - y * PIO4F;
- }
-else
-/* Extended precision modular arithmetic */
- x = ((x - y * DP1) - y * DP2) - y * DP3;
-
-z = x * x;
-
-if( (j==1) || (j==2) )
- {
- y = (((-1.9515295891E-4 * z
- + 8.3321608736E-3) * z
- - 1.6666654611E-1) * z * x)
- + x;
- }
-else
- {
- y = (( 2.443315711809948E-005 * z
- - 1.388731625493765E-003) * z
- + 4.166664568298827E-002) * z * z;
- y -= 0.5 * z;
- y += 1.0;
- }
-if(sign < 0)
- y = -y;
-return( y );
-}
-