src/v8/test/mjsunit/es6/math-expm1.js - cobalt - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Flags: --no-fast-math

 assertTrue(isNaN(Math.expm1(NaN)));
 assertTrue(isNaN(Math.expm1(function() {})));
 assertTrue(isNaN(Math.expm1({ toString: function() { return NaN; } })));
 assertTrue(isNaN(Math.expm1({ valueOf: function() { return "abc"; } })));
 assertEquals(Infinity, 1/Math.expm1(0));
 assertEquals(-Infinity, 1/Math.expm1(-0));
 assertEquals(Infinity, Math.expm1(Infinity));
 assertEquals(-1, Math.expm1(-Infinity));


 // Sanity check:
 // Math.expm1(x) stays reasonably close to Math.exp(x) - 1 for large values.
 for (var x = 1; x < 700; x += 0.25) {
   var expected = Math.exp(x) - 1;
   assertEqualsDelta(expected, Math.expm1(x), expected * 1E-15);
   expected = Math.exp(-x) - 1;
   assertEqualsDelta(expected, Math.expm1(-x), -expected * 1E-15);
 }

 // Approximation for values close to 0:
 // Use six terms of Taylor expansion at 0 for exp(x) as test expectation:
 // exp(x) - 1 == exp(0) + exp(0) * x + x * x / 2 + ... - 1
 //            == x + x * x / 2 + x * x * x / 6 + ...
 function expm1(x) {
   return x * (1 + x * (1/2 + x * (
               1/6 + x * (1/24 + x * (
               1/120 + x * (1/720 + x * (
               1/5040 + x * (1/40320 + x*(
               1/362880 + x * (1/3628800))))))))));
 }

 // Sanity check:
 // Math.expm1(x) stays reasonabliy close to the Taylor series for small values.
 for (var x = 1E-1; x > 1E-300; x *= 0.8) {
   var expected = expm1(x);
   assertEqualsDelta(expected, Math.expm1(x), expected * 1E-15);
 }


 // Tests related to the fdlibm implementation.
 // Test overflow.
 assertEquals(Infinity, Math.expm1(709.8));
 // Test largest double value.
 assertEquals(Infinity, Math.exp(1.7976931348623157e308));
 // Cover various code paths.
 assertEquals(-1, Math.expm1(-56 * Math.LN2));
 assertEquals(-1, Math.expm1(-50));
 // Test most negative double value.
 assertEquals(-1, Math.expm1(-1.7976931348623157e308));
 // Test argument reduction.
 // Cases for 0.5*log(2) < |x| < 1.5*log(2).
 assertEquals(Math.E - 1, Math.expm1(1));
 assertEquals(1/Math.E - 1, Math.expm1(-1));
 // Cases for 1.5*log(2) < |x|.
 assertEquals(6.38905609893065, Math.expm1(2));
 assertEquals(-0.8646647167633873, Math.expm1(-2));
 // Cases where Math.expm1(x) = x.
 assertEquals(0, Math.expm1(0));
 assertEquals(Math.pow(2,-55), Math.expm1(Math.pow(2,-55)));
 // Tests for the case where argument reduction has x in the primary range.
 // Test branch for k = 0.
 assertEquals(0.18920711500272105, Math.expm1(0.25 * Math.LN2));
 // Test branch for k = -1.
 assertEquals(-0.5, Math.expm1(-Math.LN2));
 // Test branch for k = 1.
 assertEquals(1, Math.expm1(Math.LN2));
 // Test branch for k <= -2 || k > 56. k = -3.
 assertEquals(1.4411518807585582e17, Math.expm1(57 * Math.LN2));
 // Test last branch for k < 20, k = 19.
 assertEquals(524286.99999999994, Math.expm1(19 * Math.LN2));
 // Test the else branch, k = 20.
 assertEquals(1048575, Math.expm1(20 * Math.LN2));
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Flags: --no-fast-math

	assertTrue(isNaN(Math.expm1(NaN)));
	assertTrue(isNaN(Math.expm1(function() {})));
	assertTrue(isNaN(Math.expm1({ toString: function() { return NaN; } })));
	assertTrue(isNaN(Math.expm1({ valueOf: function() { return "abc"; } })));
	assertEquals(Infinity, 1/Math.expm1(0));
	assertEquals(-Infinity, 1/Math.expm1(-0));
	assertEquals(Infinity, Math.expm1(Infinity));
	assertEquals(-1, Math.expm1(-Infinity));


	// Sanity check:
	// Math.expm1(x) stays reasonably close to Math.exp(x) - 1 for large values.
	for (var x = 1; x < 700; x += 0.25) {
	var expected = Math.exp(x) - 1;
	assertEqualsDelta(expected, Math.expm1(x), expected * 1E-15);
	expected = Math.exp(-x) - 1;
	assertEqualsDelta(expected, Math.expm1(-x), -expected * 1E-15);
	}

	// Approximation for values close to 0:
	// Use six terms of Taylor expansion at 0 for exp(x) as test expectation:
	// exp(x) - 1 == exp(0) + exp(0) * x + x * x / 2 + ... - 1
	// == x + x * x / 2 + x * x * x / 6 + ...
	function expm1(x) {
	return x * (1 + x * (1/2 + x * (
	1/6 + x * (1/24 + x * (
	1/120 + x * (1/720 + x * (
	1/5040 + x * (1/40320 + x*(
	1/362880 + x * (1/3628800))))))))));
	}

	// Sanity check:
	// Math.expm1(x) stays reasonabliy close to the Taylor series for small values.
	for (var x = 1E-1; x > 1E-300; x *= 0.8) {
	var expected = expm1(x);
	assertEqualsDelta(expected, Math.expm1(x), expected * 1E-15);
	}


	// Tests related to the fdlibm implementation.
	// Test overflow.
	assertEquals(Infinity, Math.expm1(709.8));
	// Test largest double value.
	assertEquals(Infinity, Math.exp(1.7976931348623157e308));
	// Cover various code paths.
	assertEquals(-1, Math.expm1(-56 * Math.LN2));
	assertEquals(-1, Math.expm1(-50));
	// Test most negative double value.
	assertEquals(-1, Math.expm1(-1.7976931348623157e308));
	// Test argument reduction.
	// Cases for 0.5log(2) < \|x\| < 1.5log(2).
	assertEquals(Math.E - 1, Math.expm1(1));
	assertEquals(1/Math.E - 1, Math.expm1(-1));
	// Cases for 1.5*log(2) < \|x\|.
	assertEquals(6.38905609893065, Math.expm1(2));
	assertEquals(-0.8646647167633873, Math.expm1(-2));
	// Cases where Math.expm1(x) = x.
	assertEquals(0, Math.expm1(0));
	assertEquals(Math.pow(2,-55), Math.expm1(Math.pow(2,-55)));
	// Tests for the case where argument reduction has x in the primary range.
	// Test branch for k = 0.
	assertEquals(0.18920711500272105, Math.expm1(0.25 * Math.LN2));
	// Test branch for k = -1.
	assertEquals(-0.5, Math.expm1(-Math.LN2));
	// Test branch for k = 1.
	assertEquals(1, Math.expm1(Math.LN2));
	// Test branch for k <= -2 \|\| k > 56. k = -3.
	assertEquals(1.4411518807585582e17, Math.expm1(57 * Math.LN2));
	// Test last branch for k < 20, k = 19.
	assertEquals(524286.99999999994, Math.expm1(19 * Math.LN2));
	// Test the else branch, k = 20.
	assertEquals(1048575, Math.expm1(20 * Math.LN2));