libc/src/__support/math/exp10f_utils.h - llvm-project - Git at Google

 //===-- Common utils for exp10f ---------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H
 #define LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H

 #include "src/__support/FPUtil/FPBits.h"
 #include "src/__support/FPUtil/PolyEval.h"
 #include "src/__support/FPUtil/nearest_integer.h"
 #include "src/__support/macros/config.h"

 namespace LIBC_NAMESPACE_DECL {

 struct ExpBase {
   // Base = e
   static constexpr int MID_BITS = 5;
   static constexpr int MID_MASK = (1 << MID_BITS) - 1;
   // log2(e) * 2^5
   static constexpr double LOG2_B = 0x1.71547652b82fep+0 * (1 << MID_BITS);
   // High and low parts of -log(2) * 2^(-5)
   static constexpr double M_LOGB_2_HI = -0x1.62e42fefa0000p-1 / (1 << MID_BITS);
   static constexpr double M_LOGB_2_LO =
       -0x1.cf79abc9e3b3ap-40 / (1 << MID_BITS);
   // Look up table for bit fields of 2^(i/32) for i = 0..31, generated by Sollya
   // with:
   // > for i from 0 to 31 do printdouble(round(2^(i/32), D, RN));
   static constexpr int64_t EXP_2_MID[1 << MID_BITS] = {
       0x3ff0000000000000, 0x3ff059b0d3158574, 0x3ff0b5586cf9890f,
       0x3ff11301d0125b51, 0x3ff172b83c7d517b, 0x3ff1d4873168b9aa,
       0x3ff2387a6e756238, 0x3ff29e9df51fdee1, 0x3ff306fe0a31b715,
       0x3ff371a7373aa9cb, 0x3ff3dea64c123422, 0x3ff44e086061892d,
       0x3ff4bfdad5362a27, 0x3ff5342b569d4f82, 0x3ff5ab07dd485429,
       0x3ff6247eb03a5585, 0x3ff6a09e667f3bcd, 0x3ff71f75e8ec5f74,
       0x3ff7a11473eb0187, 0x3ff82589994cce13, 0x3ff8ace5422aa0db,
       0x3ff93737b0cdc5e5, 0x3ff9c49182a3f090, 0x3ffa5503b23e255d,
       0x3ffae89f995ad3ad, 0x3ffb7f76f2fb5e47, 0x3ffc199bdd85529c,
       0x3ffcb720dcef9069, 0x3ffd5818dcfba487, 0x3ffdfc97337b9b5f,
       0x3ffea4afa2a490da, 0x3fff50765b6e4540,
   };

   // Approximating e^dx with degree-5 minimax polynomial generated by Sollya:
   // > Q = fpminimax(expm1(x)/x, 4, [|1, D...|], [-log(2)/64, log(2)/64]);
   // Then:
   //   e^dx ~ P(dx) = 1 + dx + COEFFS[0] * dx^2 + ... + COEFFS[3] * dx^5.
   static constexpr double COEFFS[4] = {
       0x1.ffffffffe5bc8p-2, 0x1.555555555cd67p-3, 0x1.5555c2a9b48b4p-5,
       0x1.11112a0e34bdbp-7};

   LIBC_INLINE static double powb_lo(double dx) {
     using fputil::multiply_add;
     double dx2 = dx * dx;
     double c0 = 1.0 + dx;
     // c1 = COEFFS[0] + COEFFS[1] * dx
     double c1 = multiply_add(dx, ExpBase::COEFFS[1], ExpBase::COEFFS[0]);
     // c2 = COEFFS[2] + COEFFS[3] * dx
     double c2 = multiply_add(dx, ExpBase::COEFFS[3], ExpBase::COEFFS[2]);
     // r = c4 + c5 * dx^4
     //   = 1 + dx + COEFFS[0] * dx^2 + ... + COEFFS[5] * dx^7
     return fputil::polyeval(dx2, c0, c1, c2);
   }
 };

 struct Exp10Base : public ExpBase {
   // log2(10) * 2^5
   static constexpr double LOG2_B = 0x1.a934f0979a371p1 * (1 << MID_BITS);
   // High and low parts of -log10(2) * 2^(-5).
   // Notice that since |x * log2(10)| < 150:
   //   |k| = |round(x * log2(10) * 2^5)| < 2^8 * 2^5 = 2^13
   // So when the FMA instructions are not available, in order for the product
   //   k * M_LOGB_2_HI
   // to be exact, we only store the high part of log10(2) up to 38 bits
   // (= 53 - 15) of precision.
   // It is generated by Sollya with:
   // > round(log10(2), 44, RN);
   static constexpr double M_LOGB_2_HI = -0x1.34413509f8p-2 / (1 << MID_BITS);
   // > round(log10(2) - 0x1.34413509f8p-2, D, RN);
   static constexpr double M_LOGB_2_LO = 0x1.80433b83b532ap-44 / (1 << MID_BITS);

   // Approximating 10^dx with degree-5 minimax polynomial generated by Sollya:
   // > Q = fpminimax((10^x - 1)/x, 4, [|D...|], [-log10(2)/2^6, log10(2)/2^6]);
   // Then:
   //   10^dx ~ P(dx) = 1 + COEFFS[0] * dx + ... + COEFFS[4] * dx^5.
   static constexpr double COEFFS[5] = {0x1.26bb1bbb55515p1, 0x1.53524c73bd3eap1,
                                        0x1.0470591dff149p1, 0x1.2bd7c0a9fbc4dp0,
                                        0x1.1429e74a98f43p-1};

   static double powb_lo(double dx) {
     using fputil::multiply_add;
     double dx2 = dx * dx;
     // c0 = 1 + COEFFS[0] * dx
     double c0 = multiply_add(dx, Exp10Base::COEFFS[0], 1.0);
     // c1 = COEFFS[1] + COEFFS[2] * dx
     double c1 = multiply_add(dx, Exp10Base::COEFFS[2], Exp10Base::COEFFS[1]);
     // c2 = COEFFS[3] + COEFFS[4] * dx
     double c2 = multiply_add(dx, Exp10Base::COEFFS[4], Exp10Base::COEFFS[3]);
     // r = c0 + dx^2 * (c1 + c2 * dx^2)
     //   = c0 + c1 * dx^2 + c2 * dx^4
     //   = 1 + COEFFS[0] * dx + ... + COEFFS[4] * dx^5.
     return fputil::polyeval(dx2, c0, c1, c2);
   }
 };

 // Output of range reduction for exp_b: (2^(mid + hi), lo)
 // where:
 //   b^x = 2^(mid + hi) * b^lo
 struct exp_b_reduc_t {
   double mh; // 2^(mid + hi)
   double lo;
 };

 // The function correctly calculates b^x value with at least float precision
 // in a limited range.
 // Range reduction:
 //   b^x = 2^(hi + mid) * b^lo
 // where:
 //   x = (hi + mid) * log_b(2) + lo
 //   hi is an integer,
 //   0 <= mid * 2^MID_BITS < 2^MID_BITS is an integer
 //   -2^(-MID_BITS - 1) <= lo * log2(b) <= 2^(-MID_BITS - 1)
 // Base class needs to provide the following constants:
 //   - MID_BITS    : number of bits after decimal points used for mid
 //   - MID_MASK    : 2^MID_BITS - 1, mask to extract mid bits
 //   - LOG2_B      : log2(b) * 2^MID_BITS for scaling
 //   - M_LOGB_2_HI : high part of -log_b(2) * 2^(-MID_BITS)
 //   - M_LOGB_2_LO : low part of -log_b(2) * 2^(-MID_BITS)
 //   - EXP_2_MID   : look up table for bit fields of 2^mid
 // Return:
 //   { 2^(hi + mid), lo }
 template <class Base>
 LIBC_INLINE static constexpr exp_b_reduc_t exp_b_range_reduc(float x) {
   double xd = static_cast<double>(x);
   // kd = round((hi + mid) * log2(b) * 2^MID_BITS)
   double kd = fputil::nearest_integer(Base::LOG2_B * xd);
   // k = round((hi + mid) * log2(b) * 2^MID_BITS)
   int k = static_cast<int>(kd);
   // hi = floor(kd * 2^(-MID_BITS))
   // exp_hi = shift hi to the exponent field of double precision.
   uint64_t exp_hi = static_cast<uint64_t>(k >> Base::MID_BITS)
                     << fputil::FPBits<double>::FRACTION_LEN;
   // mh = 2^hi * 2^mid
   // mh_bits = bit field of mh
   uint64_t mh_bits = Base::EXP_2_MID[k & Base::MID_MASK] + exp_hi;
   double mh = fputil::FPBits<double>(mh_bits).get_val();
   // dx = lo = x - (hi + mid) * log(2)
   double dx = fputil::multiply_add(
       kd, Base::M_LOGB_2_LO, fputil::multiply_add(kd, Base::M_LOGB_2_HI, xd));
   return {mh, dx};
 }

 } // namespace LIBC_NAMESPACE_DECL

 #endif // LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H
	//===-- Common utils for exp10f ---------------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H
	#define LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H

	#include "src/__support/FPUtil/FPBits.h"
	#include "src/__support/FPUtil/PolyEval.h"
	#include "src/__support/FPUtil/nearest_integer.h"
	#include "src/__support/macros/config.h"

	namespace LIBC_NAMESPACE_DECL {

	struct ExpBase {
	// Base = e
	static constexpr int MID_BITS = 5;
	static constexpr int MID_MASK = (1 << MID_BITS) - 1;
	// log2(e) * 2^5
	static constexpr double LOG2_B = 0x1.71547652b82fep+0 * (1 << MID_BITS);
	// High and low parts of -log(2) * 2^(-5)
	static constexpr double M_LOGB_2_HI = -0x1.62e42fefa0000p-1 / (1 << MID_BITS);
	static constexpr double M_LOGB_2_LO =
	-0x1.cf79abc9e3b3ap-40 / (1 << MID_BITS);
	// Look up table for bit fields of 2^(i/32) for i = 0..31, generated by Sollya
	// with:
	// > for i from 0 to 31 do printdouble(round(2^(i/32), D, RN));
	static constexpr int64_t EXP_2_MID[1 << MID_BITS] = {
	0x3ff0000000000000, 0x3ff059b0d3158574, 0x3ff0b5586cf9890f,
	0x3ff11301d0125b51, 0x3ff172b83c7d517b, 0x3ff1d4873168b9aa,
	0x3ff2387a6e756238, 0x3ff29e9df51fdee1, 0x3ff306fe0a31b715,
	0x3ff371a7373aa9cb, 0x3ff3dea64c123422, 0x3ff44e086061892d,
	0x3ff4bfdad5362a27, 0x3ff5342b569d4f82, 0x3ff5ab07dd485429,
	0x3ff6247eb03a5585, 0x3ff6a09e667f3bcd, 0x3ff71f75e8ec5f74,
	0x3ff7a11473eb0187, 0x3ff82589994cce13, 0x3ff8ace5422aa0db,
	0x3ff93737b0cdc5e5, 0x3ff9c49182a3f090, 0x3ffa5503b23e255d,
	0x3ffae89f995ad3ad, 0x3ffb7f76f2fb5e47, 0x3ffc199bdd85529c,
	0x3ffcb720dcef9069, 0x3ffd5818dcfba487, 0x3ffdfc97337b9b5f,
	0x3ffea4afa2a490da, 0x3fff50765b6e4540,
	};

	// Approximating e^dx with degree-5 minimax polynomial generated by Sollya:
	// > Q = fpminimax(expm1(x)/x, 4, [\|1, D...\|], [-log(2)/64, log(2)/64]);
	// Then:
	// e^dx ~ P(dx) = 1 + dx + COEFFS[0] * dx^2 + ... + COEFFS[3] * dx^5.
	static constexpr double COEFFS[4] = {
	0x1.ffffffffe5bc8p-2, 0x1.555555555cd67p-3, 0x1.5555c2a9b48b4p-5,
	0x1.11112a0e34bdbp-7};

	LIBC_INLINE static double powb_lo(double dx) {
	using fputil::multiply_add;
	double dx2 = dx * dx;
	double c0 = 1.0 + dx;
	// c1 = COEFFS[0] + COEFFS[1] * dx
	double c1 = multiply_add(dx, ExpBase::COEFFS[1], ExpBase::COEFFS[0]);
	// c2 = COEFFS[2] + COEFFS[3] * dx
	double c2 = multiply_add(dx, ExpBase::COEFFS[3], ExpBase::COEFFS[2]);
	// r = c4 + c5 * dx^4
	// = 1 + dx + COEFFS[0] * dx^2 + ... + COEFFS[5] * dx^7
	return fputil::polyeval(dx2, c0, c1, c2);
	}
	};

	struct Exp10Base : public ExpBase {
	// log2(10) * 2^5
	static constexpr double LOG2_B = 0x1.a934f0979a371p1 * (1 << MID_BITS);
	// High and low parts of -log10(2) * 2^(-5).
	// Notice that since \|x * log2(10)\| < 150:
	// \|k\| = \|round(x * log2(10) * 2^5)\| < 2^8 * 2^5 = 2^13
	// So when the FMA instructions are not available, in order for the product
	// k * M_LOGB_2_HI
	// to be exact, we only store the high part of log10(2) up to 38 bits
	// (= 53 - 15) of precision.
	// It is generated by Sollya with:
	// > round(log10(2), 44, RN);
	static constexpr double M_LOGB_2_HI = -0x1.34413509f8p-2 / (1 << MID_BITS);
	// > round(log10(2) - 0x1.34413509f8p-2, D, RN);
	static constexpr double M_LOGB_2_LO = 0x1.80433b83b532ap-44 / (1 << MID_BITS);

	// Approximating 10^dx with degree-5 minimax polynomial generated by Sollya:
	// > Q = fpminimax((10^x - 1)/x, 4, [\|D...\|], [-log10(2)/2^6, log10(2)/2^6]);
	// Then:
	// 10^dx ~ P(dx) = 1 + COEFFS[0] * dx + ... + COEFFS[4] * dx^5.
	static constexpr double COEFFS[5] = {0x1.26bb1bbb55515p1, 0x1.53524c73bd3eap1,
	0x1.0470591dff149p1, 0x1.2bd7c0a9fbc4dp0,
	0x1.1429e74a98f43p-1};

	static double powb_lo(double dx) {
	using fputil::multiply_add;
	double dx2 = dx * dx;
	// c0 = 1 + COEFFS[0] * dx
	double c0 = multiply_add(dx, Exp10Base::COEFFS[0], 1.0);
	// c1 = COEFFS[1] + COEFFS[2] * dx
	double c1 = multiply_add(dx, Exp10Base::COEFFS[2], Exp10Base::COEFFS[1]);
	// c2 = COEFFS[3] + COEFFS[4] * dx
	double c2 = multiply_add(dx, Exp10Base::COEFFS[4], Exp10Base::COEFFS[3]);
	// r = c0 + dx^2 * (c1 + c2 * dx^2)
	// = c0 + c1 * dx^2 + c2 * dx^4
	// = 1 + COEFFS[0] * dx + ... + COEFFS[4] * dx^5.
	return fputil::polyeval(dx2, c0, c1, c2);
	}
	};

	// Output of range reduction for exp_b: (2^(mid + hi), lo)
	// where:
	// b^x = 2^(mid + hi) * b^lo
	struct exp_b_reduc_t {
	double mh; // 2^(mid + hi)
	double lo;
	};

	// The function correctly calculates b^x value with at least float precision
	// in a limited range.
	// Range reduction:
	// b^x = 2^(hi + mid) * b^lo
	// where:
	// x = (hi + mid) * log_b(2) + lo
	// hi is an integer,
	// 0 <= mid * 2^MID_BITS < 2^MID_BITS is an integer
	// -2^(-MID_BITS - 1) <= lo * log2(b) <= 2^(-MID_BITS - 1)
	// Base class needs to provide the following constants:
	// - MID_BITS : number of bits after decimal points used for mid
	// - MID_MASK : 2^MID_BITS - 1, mask to extract mid bits
	// - LOG2_B : log2(b) * 2^MID_BITS for scaling
	// - M_LOGB_2_HI : high part of -log_b(2) * 2^(-MID_BITS)
	// - M_LOGB_2_LO : low part of -log_b(2) * 2^(-MID_BITS)
	// - EXP_2_MID : look up table for bit fields of 2^mid
	// Return:
	// { 2^(hi + mid), lo }
	template <class Base>
	LIBC_INLINE static constexpr exp_b_reduc_t exp_b_range_reduc(float x) {
	double xd = static_cast<double>(x);
	// kd = round((hi + mid) * log2(b) * 2^MID_BITS)
	double kd = fputil::nearest_integer(Base::LOG2_B * xd);
	// k = round((hi + mid) * log2(b) * 2^MID_BITS)
	int k = static_cast<int>(kd);
	// hi = floor(kd * 2^(-MID_BITS))
	// exp_hi = shift hi to the exponent field of double precision.
	uint64_t exp_hi = static_cast<uint64_t>(k >> Base::MID_BITS)
	<< fputil::FPBits<double>::FRACTION_LEN;
	// mh = 2^hi * 2^mid
	// mh_bits = bit field of mh
	uint64_t mh_bits = Base::EXP_2_MID[k & Base::MID_MASK] + exp_hi;
	double mh = fputil::FPBits<double>(mh_bits).get_val();
	// dx = lo = x - (hi + mid) * log(2)
	double dx = fputil::multiply_add(
	kd, Base::M_LOGB_2_LO, fputil::multiply_add(kd, Base::M_LOGB_2_HI, xd));
	return {mh, dx};
	}

	} // namespace LIBC_NAMESPACE_DECL

	#endif // LLVM_LIBC_SRC___SUPPORT_MATH_EXP_FLOAT_CONSTANTS_H