AOR_v20.02/math/tools/log2.sollya - llvm-project/libc - Git at Google

 // polynomial for approximating log2(1+x)
 //
 // 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

 deg = 11; // poly degree
 // |log2(1+x)| > 0x1p-4 outside the interval
 a = -0x1.5b51p-5;
 b =  0x1.6ab2p-5;

 ln2 = evaluate(log(2),0);
 invln2hi = double(1/ln2 + 0x1p21) - 0x1p21; // round away last 21 bits
 invln2lo = double(1/ln2 - invln2hi);

 // find log2(1+x)/x polynomial with minimal relative error
 // (minimal relative error polynomial for log2(1+x) is the same * x)
 deg = deg-1; // because of /x

 // f = log(1+x)/x; using taylor series
 f = 0;
 for i from 0 to 60 do { f = f + (-x)^i/(i+1); };
 f = f/ln2;

 // return p that minimizes |f(x) - poly(x) - x^d*p(x)|/|f(x)|
 approx = proc(poly,d) {
   return remez(1 - poly(x)/f(x), deg-d, [a;b], x^d/f(x), 1e-10);
 };

 // first coeff is fixed, iteratively find optimal double prec coeffs
 poly = invln2hi + invln2lo;
 for i from 1 to deg do {
   p = roundcoefficients(approx(poly,i), [|D ...|]);
   poly = poly + x^i*coeff(p,0);
 };

 display = hexadecimal;
 print("invln2hi:", invln2hi);
 print("invln2lo:", invln2lo);
 print("rel error:", accurateinfnorm(1-poly(x)/f(x), [a;b], 30));
 print("in [",a,b,"]");
 print("coeffs:");
 for i from 0 to deg do coeff(poly,i);
	// polynomial for approximating log2(1+x)
	//
	// 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

	deg = 11; // poly degree
	// \|log2(1+x)\| > 0x1p-4 outside the interval
	a = -0x1.5b51p-5;
	b = 0x1.6ab2p-5;

	ln2 = evaluate(log(2),0);
	invln2hi = double(1/ln2 + 0x1p21) - 0x1p21; // round away last 21 bits
	invln2lo = double(1/ln2 - invln2hi);

	// find log2(1+x)/x polynomial with minimal relative error
	// (minimal relative error polynomial for log2(1+x) is the same * x)
	deg = deg-1; // because of /x

	// f = log(1+x)/x; using taylor series
	f = 0;
	for i from 0 to 60 do { f = f + (-x)^i/(i+1); };
	f = f/ln2;

	// return p that minimizes \|f(x) - poly(x) - x^d*p(x)\|/\|f(x)\|
	approx = proc(poly,d) {
	return remez(1 - poly(x)/f(x), deg-d, [a;b], x^d/f(x), 1e-10);
	};

	// first coeff is fixed, iteratively find optimal double prec coeffs
	poly = invln2hi + invln2lo;
	for i from 1 to deg do {
	p = roundcoefficients(approx(poly,i), [\|D ...\|]);
	poly = poly + x^i*coeff(p,0);
	};

	display = hexadecimal;
	print("invln2hi:", invln2hi);
	print("invln2lo:", invln2lo);
	print("rel error:", accurateinfnorm(1-poly(x)/f(x), [a;b], 30));
	print("in [",a,b,"]");
	print("coeffs:");
	for i from 0 to deg do coeff(poly,i);