libclc/generic/lib/math/expm1.cl - llvm-project - Git at Google

 #include <clc/clc.h>

 #include "math.h"
 #include "tables.h"
 #include "../clcmacro.h"

 /* Refer to the exp routine for the underlying algorithm */

 _CLC_OVERLOAD _CLC_DEF float expm1(float x) {
     const float X_MAX = 0x1.62e42ep+6f; // 128*log2 : 88.722839111673
     const float X_MIN = -0x1.9d1da0p+6f; // -149*log2 : -103.27892990343184

     const float R_64_BY_LOG2 = 0x1.715476p+6f;     // 64/log2 : 92.332482616893657
     const float R_LOG2_BY_64_LD = 0x1.620000p-7f;  // log2/64 lead: 0.0108032227
     const float R_LOG2_BY_64_TL = 0x1.c85fdep-16f; // log2/64 tail: 0.0000272020388

     uint xi = as_uint(x);
     int n = (int)(x * R_64_BY_LOG2);
     float fn = (float)n;

     int j = n & 0x3f;
     int m = n >> 6;

     float r = mad(fn, -R_LOG2_BY_64_TL, mad(fn, -R_LOG2_BY_64_LD, x));

     // Truncated Taylor series
     float z2 = mad(r*r, mad(r, mad(r, 0x1.555556p-5f,  0x1.555556p-3f), 0.5f), r);

     float m2 = as_float((m + EXPBIAS_SP32) << EXPSHIFTBITS_SP32);
     float2 tv = USE_TABLE(exp_tbl_ep, j);

     float two_to_jby64_h = tv.s0 * m2;
     float two_to_jby64_t = tv.s1 * m2;
     float two_to_jby64 = two_to_jby64_h + two_to_jby64_t;

     z2 = mad(z2, two_to_jby64, two_to_jby64_t) + (two_to_jby64_h - 1.0f);
 	//Make subnormals work
     z2 = x == 0.f ? x : z2;
     z2 = x < X_MIN | m < -24 ? -1.0f : z2;
     z2 = x > X_MAX ? as_float(PINFBITPATT_SP32) : z2;
     z2 = isnan(x) ? x : z2;

     return z2;
 }

 _CLC_UNARY_VECTORIZE(_CLC_OVERLOAD _CLC_DEF, float, expm1, float)

 #ifdef cl_khr_fp64

 #include "exp_helper.h"

 #pragma OPENCL EXTENSION cl_khr_fp64 : enable

 _CLC_OVERLOAD _CLC_DEF double expm1(double x) {
     const double max_expm1_arg = 709.8;
     const double min_expm1_arg = -37.42994775023704;
     const double log_OnePlus_OneByFour = 0.22314355131420976;   //0x3FCC8FF7C79A9A22 = log(1+1/4)
     const double log_OneMinus_OneByFour = -0.28768207245178096; //0xBFD269621134DB93 = log(1-1/4)
     const double sixtyfour_by_lnof2 = 92.33248261689366;        //0x40571547652b82fe
     const double lnof2_by_64_head = 0.010830424696223417;       //0x3f862e42fefa0000
     const double lnof2_by_64_tail = 2.5728046223276688e-14;     //0x3d1cf79abc9e3b39

     // First, assume log(1-1/4) < x < log(1+1/4) i.e  -0.28768 < x < 0.22314
     double u = as_double(as_ulong(x) & 0xffffffffff000000UL);
     double v = x - u;
     double y = u * u * 0.5;
     double z = v * (x + u) * 0.5;

     double q = fma(x,
 	           fma(x,
 		       fma(x,
 			   fma(x,
 			       fma(x,
 				   fma(x,
 				       fma(x,
 					   fma(x,2.4360682937111612e-8, 2.7582184028154370e-7),
 					   2.7558212415361945e-6),
 				       2.4801576918453420e-5),
 				   1.9841269447671544e-4),
 			       1.3888888890687830e-3),
 			   8.3333333334012270e-3),
 		       4.1666666666665560e-2),
 		   1.6666666666666632e-1);
     q *= x * x * x;

     double z1g = (u + y) + (q + (v + z));
     double z1 = x + (y + (q + z));
     z1 = y >= 0x1.0p-7 ? z1g : z1;

     // Now assume outside interval around 0
     int n = (int)(x * sixtyfour_by_lnof2);
     int j = n & 0x3f;
     int m = n >> 6;

     double2 tv = USE_TABLE(two_to_jby64_ep_tbl, j);
     double f1 = tv.s0;
     double f2 = tv.s1;
     double f = f1 + f2;

     double dn = -n;
     double r = fma(dn, lnof2_by_64_tail, fma(dn, lnof2_by_64_head, x));

     q = fma(r,
 	    fma(r,
 		fma(r,
 		    fma(r, 1.38889490863777199667e-03, 8.33336798434219616221e-03),
 		    4.16666666662260795726e-02),
 		1.66666666665260878863e-01),
 	     5.00000000000000008883e-01);
     q = fma(r*r, q, r);

     double twopm = as_double((long)(m + EXPBIAS_DP64) << EXPSHIFTBITS_DP64);
     double twopmm = as_double((long)(EXPBIAS_DP64 - m) << EXPSHIFTBITS_DP64);

     // Computations for m > 52, including where result is close to Inf
     ulong uval = as_ulong(0x1.0p+1023 * (f1 + (f * q + (f2))));
     int e = (int)(uval >> EXPSHIFTBITS_DP64) + 1;

     double zme1024 = as_double(((long)e << EXPSHIFTBITS_DP64) | (uval & MANTBITS_DP64));
     zme1024 = e == 2047 ? as_double(PINFBITPATT_DP64) : zme1024;

     double zmg52 = twopm * (f1 + fma(f, q, f2 - twopmm));
     zmg52 = m == 1024 ? zme1024 : zmg52;

     // For m < 53
     double zml53 = twopm * ((f1 - twopmm) + fma(f1, q, f2*(1.0 + q)));

     // For m < -7
     double zmln7 = fma(twopm,  f1 + fma(f, q, f2), -1.0);

     z = m < 53 ? zml53 : zmg52;
     z = m < -7 ? zmln7 : z;
     z = x > log_OneMinus_OneByFour & x < log_OnePlus_OneByFour ? z1 : z;
     z = x > max_expm1_arg ? as_double(PINFBITPATT_DP64) : z;
     z = x < min_expm1_arg ? -1.0 : z;

     return z;
 }

 _CLC_UNARY_VECTORIZE(_CLC_OVERLOAD _CLC_DEF, double, expm1, double)

 #endif
	#include <clc/clc.h>

	#include "math.h"
	#include "tables.h"
	#include "../clcmacro.h"

	/* Refer to the exp routine for the underlying algorithm */

	_CLC_OVERLOAD _CLC_DEF float expm1(float x) {
	const float X_MAX = 0x1.62e42ep+6f; // 128*log2 : 88.722839111673
	const float X_MIN = -0x1.9d1da0p+6f; // -149*log2 : -103.27892990343184

	const float R_64_BY_LOG2 = 0x1.715476p+6f; // 64/log2 : 92.332482616893657
	const float R_LOG2_BY_64_LD = 0x1.620000p-7f; // log2/64 lead: 0.0108032227
	const float R_LOG2_BY_64_TL = 0x1.c85fdep-16f; // log2/64 tail: 0.0000272020388

	uint xi = as_uint(x);
	int n = (int)(x * R_64_BY_LOG2);
	float fn = (float)n;

	int j = n & 0x3f;
	int m = n >> 6;

	float r = mad(fn, -R_LOG2_BY_64_TL, mad(fn, -R_LOG2_BY_64_LD, x));

	// Truncated Taylor series
	float z2 = mad(r*r, mad(r, mad(r, 0x1.555556p-5f, 0x1.555556p-3f), 0.5f), r);

	float m2 = as_float((m + EXPBIAS_SP32) << EXPSHIFTBITS_SP32);
	float2 tv = USE_TABLE(exp_tbl_ep, j);

	float two_to_jby64_h = tv.s0 * m2;
	float two_to_jby64_t = tv.s1 * m2;
	float two_to_jby64 = two_to_jby64_h + two_to_jby64_t;

	z2 = mad(z2, two_to_jby64, two_to_jby64_t) + (two_to_jby64_h - 1.0f);
	//Make subnormals work
	z2 = x == 0.f ? x : z2;
	z2 = x < X_MIN \| m < -24 ? -1.0f : z2;
	z2 = x > X_MAX ? as_float(PINFBITPATT_SP32) : z2;
	z2 = isnan(x) ? x : z2;

	return z2;
	}

	_CLC_UNARY_VECTORIZE(_CLC_OVERLOAD _CLC_DEF, float, expm1, float)

	#ifdef cl_khr_fp64

	#include "exp_helper.h"

	#pragma OPENCL EXTENSION cl_khr_fp64 : enable

	_CLC_OVERLOAD _CLC_DEF double expm1(double x) {
	const double max_expm1_arg = 709.8;
	const double min_expm1_arg = -37.42994775023704;
	const double log_OnePlus_OneByFour = 0.22314355131420976; //0x3FCC8FF7C79A9A22 = log(1+1/4)
	const double log_OneMinus_OneByFour = -0.28768207245178096; //0xBFD269621134DB93 = log(1-1/4)
	const double sixtyfour_by_lnof2 = 92.33248261689366; //0x40571547652b82fe
	const double lnof2_by_64_head = 0.010830424696223417; //0x3f862e42fefa0000
	const double lnof2_by_64_tail = 2.5728046223276688e-14; //0x3d1cf79abc9e3b39

	// First, assume log(1-1/4) < x < log(1+1/4) i.e -0.28768 < x < 0.22314
	double u = as_double(as_ulong(x) & 0xffffffffff000000UL);
	double v = x - u;
	double y = u * u * 0.5;
	double z = v * (x + u) * 0.5;

	double q = fma(x,
	fma(x,
	fma(x,
	fma(x,
	fma(x,
	fma(x,
	fma(x,
	fma(x,2.4360682937111612e-8, 2.7582184028154370e-7),
	2.7558212415361945e-6),
	2.4801576918453420e-5),
	1.9841269447671544e-4),
	1.3888888890687830e-3),
	8.3333333334012270e-3),
	4.1666666666665560e-2),
	1.6666666666666632e-1);
	q = x x * x;

	double z1g = (u + y) + (q + (v + z));
	double z1 = x + (y + (q + z));
	z1 = y >= 0x1.0p-7 ? z1g : z1;

	// Now assume outside interval around 0
	int n = (int)(x * sixtyfour_by_lnof2);
	int j = n & 0x3f;
	int m = n >> 6;

	double2 tv = USE_TABLE(two_to_jby64_ep_tbl, j);
	double f1 = tv.s0;
	double f2 = tv.s1;
	double f = f1 + f2;

	double dn = -n;
	double r = fma(dn, lnof2_by_64_tail, fma(dn, lnof2_by_64_head, x));

	q = fma(r,
	fma(r,
	fma(r,
	fma(r, 1.38889490863777199667e-03, 8.33336798434219616221e-03),
	4.16666666662260795726e-02),
	1.66666666665260878863e-01),
	5.00000000000000008883e-01);
	q = fma(r*r, q, r);

	double twopm = as_double((long)(m + EXPBIAS_DP64) << EXPSHIFTBITS_DP64);
	double twopmm = as_double((long)(EXPBIAS_DP64 - m) << EXPSHIFTBITS_DP64);

	// Computations for m > 52, including where result is close to Inf
	ulong uval = as_ulong(0x1.0p+1023 * (f1 + (f * q + (f2))));
	int e = (int)(uval >> EXPSHIFTBITS_DP64) + 1;

	double zme1024 = as_double(((long)e << EXPSHIFTBITS_DP64) \| (uval & MANTBITS_DP64));
	zme1024 = e == 2047 ? as_double(PINFBITPATT_DP64) : zme1024;

	double zmg52 = twopm * (f1 + fma(f, q, f2 - twopmm));
	zmg52 = m == 1024 ? zme1024 : zmg52;

	// For m < 53
	double zml53 = twopm * ((f1 - twopmm) + fma(f1, q, f2*(1.0 + q)));

	// For m < -7
	double zmln7 = fma(twopm, f1 + fma(f, q, f2), -1.0);

	z = m < 53 ? zml53 : zmg52;
	z = m < -7 ? zmln7 : z;
	z = x > log_OneMinus_OneByFour & x < log_OnePlus_OneByFour ? z1 : z;
	z = x > max_expm1_arg ? as_double(PINFBITPATT_DP64) : z;
	z = x < min_expm1_arg ? -1.0 : z;

	return z;
	}

	_CLC_UNARY_VECTORIZE(_CLC_OVERLOAD _CLC_DEF, double, expm1, double)

	#endif