qt-everywhere-src-5.15.1/qtdeclarative/src/qml/jsruntime/qv4mathobject.cpp - orbit - Git at Google

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 #include "qv4mathobject_p.h"
 #include "qv4objectproto_p.h"
 #include "qv4symbol_p.h"

 #include <QtCore/qdatetime.h>
 #include <QtCore/qmath.h>
 #include <QtCore/qrandom.h>
 #include <QtCore/private/qnumeric_p.h>
 #include <QtCore/qthreadstorage.h>

 #include <math.h>
 #include <cmath>

 using namespace QV4;

 DEFINE_OBJECT_VTABLE(MathObject);

 void Heap::MathObject::init()
 {
     Object::init();
     Scope scope(internalClass->engine);
     ScopedObject m(scope, this);

     m->defineReadonlyProperty(QStringLiteral("E"), Value::fromDouble(M_E));
     m->defineReadonlyProperty(QStringLiteral("LN2"), Value::fromDouble(M_LN2));
     m->defineReadonlyProperty(QStringLiteral("LN10"), Value::fromDouble(M_LN10));
     m->defineReadonlyProperty(QStringLiteral("LOG2E"), Value::fromDouble(M_LOG2E));
     m->defineReadonlyProperty(QStringLiteral("LOG10E"), Value::fromDouble(M_LOG10E));
     m->defineReadonlyProperty(QStringLiteral("PI"), Value::fromDouble(M_PI));
     m->defineReadonlyProperty(QStringLiteral("SQRT1_2"), Value::fromDouble(M_SQRT1_2));
     m->defineReadonlyProperty(QStringLiteral("SQRT2"), Value::fromDouble(M_SQRT2));

     m->defineDefaultProperty(QStringLiteral("abs"), QV4::MathObject::method_abs, 1);
     m->defineDefaultProperty(QStringLiteral("acos"), QV4::MathObject::method_acos, 1);
     m->defineDefaultProperty(QStringLiteral("acosh"), QV4::MathObject::method_acosh, 1);
     m->defineDefaultProperty(QStringLiteral("asin"), QV4::MathObject::method_asin, 1);
     m->defineDefaultProperty(QStringLiteral("asinh"), QV4::MathObject::method_asinh, 1);
     m->defineDefaultProperty(QStringLiteral("atan"), QV4::MathObject::method_atan, 1);
     m->defineDefaultProperty(QStringLiteral("atanh"), QV4::MathObject::method_atanh, 1);
     m->defineDefaultProperty(QStringLiteral("atan2"), QV4::MathObject::method_atan2, 2);
     m->defineDefaultProperty(QStringLiteral("cbrt"), QV4::MathObject::method_cbrt, 1);
     m->defineDefaultProperty(QStringLiteral("ceil"), QV4::MathObject::method_ceil, 1);
     m->defineDefaultProperty(QStringLiteral("clz32"), QV4::MathObject::method_clz32, 1);
     m->defineDefaultProperty(QStringLiteral("cos"), QV4::MathObject::method_cos, 1);
     m->defineDefaultProperty(QStringLiteral("cosh"), QV4::MathObject::method_cosh, 1);
     m->defineDefaultProperty(QStringLiteral("exp"), QV4::MathObject::method_exp, 1);
     m->defineDefaultProperty(QStringLiteral("expm1"), QV4::MathObject::method_expm1, 1);
     m->defineDefaultProperty(QStringLiteral("floor"), QV4::MathObject::method_floor, 1);
     m->defineDefaultProperty(QStringLiteral("fround"), QV4::MathObject::method_fround, 1);
     m->defineDefaultProperty(QStringLiteral("hypot"), QV4::MathObject::method_hypot, 2);
     m->defineDefaultProperty(QStringLiteral("imul"), QV4::MathObject::method_imul, 2);
     m->defineDefaultProperty(QStringLiteral("log"), QV4::MathObject::method_log, 1);
     m->defineDefaultProperty(QStringLiteral("log10"), QV4::MathObject::method_log10, 1);
     m->defineDefaultProperty(QStringLiteral("log1p"), QV4::MathObject::method_log1p, 1);
     m->defineDefaultProperty(QStringLiteral("log2"), QV4::MathObject::method_log2, 1);
     m->defineDefaultProperty(QStringLiteral("max"), QV4::MathObject::method_max, 2);
     m->defineDefaultProperty(QStringLiteral("min"), QV4::MathObject::method_min, 2);
     m->defineDefaultProperty(QStringLiteral("pow"), QV4::MathObject::method_pow, 2);
     m->defineDefaultProperty(QStringLiteral("random"), QV4::MathObject::method_random, 0);
     m->defineDefaultProperty(QStringLiteral("round"), QV4::MathObject::method_round, 1);
     m->defineDefaultProperty(QStringLiteral("sign"), QV4::MathObject::method_sign, 1);
     m->defineDefaultProperty(QStringLiteral("sin"), QV4::MathObject::method_sin, 1);
     m->defineDefaultProperty(QStringLiteral("sinh"), QV4::MathObject::method_sinh, 1);
     m->defineDefaultProperty(QStringLiteral("sqrt"), QV4::MathObject::method_sqrt, 1);
     m->defineDefaultProperty(QStringLiteral("tan"), QV4::MathObject::method_tan, 1);
     m->defineDefaultProperty(QStringLiteral("tanh"), QV4::MathObject::method_tanh, 1);
     m->defineDefaultProperty(QStringLiteral("trunc"), QV4::MathObject::method_trunc, 1);

     ScopedString name(scope, scope.engine->newString(QStringLiteral("Math")));
     m->defineReadonlyConfigurableProperty(scope.engine->symbol_toStringTag(), name);
 }

 static Q_ALWAYS_INLINE double copySign(double x, double y)
 {
     return ::copysign(x, y);
 }

 ReturnedValue MathObject::method_abs(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     if (!argc)
         RETURN_RESULT(Encode(qt_qnan()));

     if (argv[0].isInteger()) {
         int i = argv[0].integerValue();
         RETURN_RESULT(Encode(i < 0 ? - i : i));
     }

     double v = argv[0].toNumber();
     if (v == 0) // 0 | -0
         RETURN_RESULT(Encode(0));

     RETURN_RESULT(Encode(v < 0 ? -v : v));
 }

 ReturnedValue MathObject::method_acos(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : 2;
     if (v > 1)
         RETURN_RESULT(Encode(qt_qnan()));

     RETURN_RESULT(Encode(std::acos(v)));
 }

 ReturnedValue MathObject::method_acosh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : 2;
     if (v < 1)
         RETURN_RESULT(Encode(qt_qnan()));

 #ifdef Q_OS_ANDROID // incomplete std :-(
     RETURN_RESULT(Encode(std::log(v +std::sqrt(v + 1) * std::sqrt(v - 1))));
 #else
     RETURN_RESULT(Encode(std::acosh(v)));
 #endif
 }

 ReturnedValue MathObject::method_asin(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : 2;
     if (v > 1)
         RETURN_RESULT(Encode(qt_qnan()));
     else
         RETURN_RESULT(Encode(std::asin(v)));
 }

 ReturnedValue MathObject::method_asinh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : 2;
     if (v == 0.0)
         RETURN_RESULT(Encode(v));

 #ifdef Q_OS_ANDROID // incomplete std :-(
     RETURN_RESULT(Encode(std::log(v +std::sqrt(1 + v * v))));
 #else
     RETURN_RESULT(Encode(std::asinh(v)));
 #endif
 }

 ReturnedValue MathObject::method_atan(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));
     else
         RETURN_RESULT(Encode(std::atan(v)));
 }

 ReturnedValue MathObject::method_atanh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));

 #ifdef Q_OS_ANDROID // incomplete std :-(
     if (-1 < v && v < 1)
         RETURN_RESULT(Encode(0.5 * (std::log(v + 1) - std::log(v - 1))));

     if (v > 1 || v < -1)
         RETURN_RESULT(Encode(qt_qnan()));

     RETURN_RESULT(Encode(copySign(qt_inf(), v)));
 #else
     RETURN_RESULT(Encode(std::atanh(v)));
 #endif
 }

 ReturnedValue MathObject::method_atan2(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v1 = argc ? argv[0].toNumber() : qt_qnan();
     double v2 = argc > 1 ? argv[1].toNumber() : qt_qnan();

     if ((v1 < 0) && qt_is_finite(v1) && qt_is_inf(v2) && (copySign(1.0, v2) == 1.0))
         RETURN_RESULT(Encode(copySign(0, -1.0)));

     if ((v1 == 0.0) && (v2 == 0.0)) {
         if ((copySign(1.0, v1) == 1.0) && (copySign(1.0, v2) == -1.0)) {
             RETURN_RESULT(Encode(M_PI));
         } else if ((copySign(1.0, v1) == -1.0) && (copySign(1.0, v2) == -1.0)) {
             RETURN_RESULT(Encode(-M_PI));
         }
     }
     RETURN_RESULT(Encode(std::atan2(v1, v2)));
 }

 ReturnedValue MathObject::method_cbrt(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
 #ifdef Q_OS_ANDROID // incomplete std :-(
     RETURN_RESULT(Encode(copySign(std::exp(std::log(std::abs(v)) / 3), v)));
 #else
     RETURN_RESULT(Encode(std::cbrt(v))); // cube root
 #endif
 }

 ReturnedValue MathObject::method_ceil(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v < 0.0 && v > -1.0)
         RETURN_RESULT(Encode(copySign(0, -1.0)));
     else
         RETURN_RESULT(Encode(std::ceil(v)));
 }

 ReturnedValue MathObject::method_clz32(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     quint32 v = argc ? argv[0].toUInt32() : 0;
     RETURN_RESULT(Encode(qint32(qCountLeadingZeroBits(v))));
 }

 ReturnedValue MathObject::method_cos(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     RETURN_RESULT(Encode(std::cos(v)));
 }

 ReturnedValue MathObject::method_cosh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     RETURN_RESULT(Encode(std::cosh(v)));
 }

 ReturnedValue MathObject::method_exp(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (qt_is_inf(v)) {
         if (copySign(1.0, v) == -1.0)
             RETURN_RESULT(Encode(0));
         else
             RETURN_RESULT(Encode(qt_inf()));
     } else {
         RETURN_RESULT(Encode(std::exp(v)));
     }
 }

 ReturnedValue MathObject::method_expm1(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (std::isnan(v) || qIsNull(v)) {
         RETURN_RESULT(Encode(v));
     } else if (qt_is_inf(v)) {
         if (copySign(1.0, v) == -1.0)
             RETURN_RESULT(Encode(-1.0));
         else
             RETURN_RESULT(Encode(qt_inf()));
     } else {
 #ifdef Q_OS_ANDROID // incomplete std :-(
         RETURN_RESULT(Encode(std::exp(v) - 1));
 #else
         RETURN_RESULT(Encode(std::expm1(v)));
 #endif
     }
 }

 ReturnedValue MathObject::method_floor(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     Value result = Value::fromDouble(std::floor(v));
     result.isInt32();
     RETURN_RESULT(result);
 }

 ReturnedValue MathObject::method_fround(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (std::isnan(v) || qt_is_inf(v) || qIsNull(v))
         RETURN_RESULT(Encode(v));
     else // convert to 32-bit float using roundTiesToEven, then convert back to 64-bit double
         RETURN_RESULT(Encode(double(float(v))));
 }

 ReturnedValue MathObject::method_hypot(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     // ES6 Math.hypot(v1, ..., vn) -> sqrt(sum(vi**2)) but "should take care to
     // avoid the loss of precision from overflows and underflows" (as std::hypot does).
     double v = argc ? argv[0].toNumber() : 0;
     // Spec mandates +0 on no args; and says nothing about what to do if toNumber() signals ...
 #ifdef Q_OS_ANDROID // incomplete std :-(
     bool big = qt_is_inf(v), bad = std::isnan(v);
     v *= v;
     for (int i = 1; !big && i < argc; i++) {
         double u = argv[i].toNumber();
         if (qt_is_inf(u))
             big = true;
         if (std::isnan(u))
             bad = true;
         v += u * u;
     }
     if (big)
         RETURN_RESULT(Encode(qt_inf()));
     if (bad)
         RETURN_RESULT(Encode(qt_qnan()));
     // Should actually check for {und,ov}erflow, but too fiddly !
     RETURN_RESULT(Value::fromDouble(sqrt(v)));
 #else
     for (int i = 1; i < argc; i++)
         v = std::hypot(v, argv[i].toNumber());
 #endif
     RETURN_RESULT(Value::fromDouble(v));
 }

 ReturnedValue MathObject::method_imul(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     quint32 a = argc ? argv[0].toUInt32() : 0;
     quint32 b = argc > 0 ? argv[1].toUInt32() : 0;
     qint32 product = a * b;
     RETURN_RESULT(Encode(product));
 }

 ReturnedValue MathObject::method_log(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v < 0)
         RETURN_RESULT(Encode(qt_qnan()));
     else
         RETURN_RESULT(Encode(std::log(v)));
 }

 ReturnedValue MathObject::method_log10(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v < 0)
         RETURN_RESULT(Encode(qt_qnan()));
     else
         RETURN_RESULT(Encode(std::log10(v)));
 }

 ReturnedValue MathObject::method_log1p(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
 #if !defined(__ANDROID__)
     using std::log1p;
 #endif
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v < -1)
         RETURN_RESULT(Encode(qt_qnan()));
     else
         RETURN_RESULT(Encode(log1p(v)));
 }

 ReturnedValue MathObject::method_log2(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v < 0) {
         RETURN_RESULT(Encode(qt_qnan()));
     } else {
 #ifdef Q_OS_ANDROID // incomplete std :-(
         // Android ndk r10e doesn't have std::log2, so fall back.
         const double ln2 = std::log(2.0);
         RETURN_RESULT(Encode(std::log(v) / ln2));
 #else
         RETURN_RESULT(Encode(std::log2(v)));
 #endif
     }
 }

 ReturnedValue MathObject::method_max(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double mx = -qt_inf();
     for (int i = 0, ei = argc; i < ei; ++i) {
         double x = argv[i].toNumber();
         if ((x == 0 && mx == x && copySign(1.0, x) == 1.0)
                 || (x > mx) || std::isnan(x)) {
             mx = x;
         }
     }
     RETURN_RESULT(Encode::smallestNumber(mx));
 }

 ReturnedValue MathObject::method_min(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double mx = qt_inf();
     for (int i = 0, ei = argc; i < ei; ++i) {
         double x = argv[i].toNumber();
         if ((x == 0 && mx == x && copySign(1.0, x) == -1.0)
                 || (x < mx) || std::isnan(x)) {
             mx = x;
         }
     }
     RETURN_RESULT(Encode::smallestNumber(mx));
 }

 ReturnedValue MathObject::method_pow(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double x = argc > 0 ? argv[0].toNumber() : qt_qnan();
     double y = argc > 1 ? argv[1].toNumber() : qt_qnan();

     if (std::isnan(y))
         RETURN_RESULT(Encode(qt_qnan()));

     if (y == 0) {
         RETURN_RESULT(Encode(1));
     } else if (((x == 1) || (x == -1)) && std::isinf(y)) {
         RETURN_RESULT(Encode(qt_qnan()));
     } else if (((x == 0) && copySign(1.0, x) == 1.0) && (y < 0)) {
         RETURN_RESULT(Encode(qInf()));
     } else if ((x == 0) && copySign(1.0, x) == -1.0) {
         if (y < 0) {
             if (std::fmod(-y, 2.0) == 1.0)
                 RETURN_RESULT(Encode(-qt_inf()));
             else
                 RETURN_RESULT(Encode(qt_inf()));
         } else if (y > 0) {
             if (std::fmod(y, 2.0) == 1.0)
                 RETURN_RESULT(Encode(copySign(0, -1.0)));
             else
                 RETURN_RESULT(Encode(0));
         }
     }

 #ifdef Q_OS_AIX
     else if (qt_is_inf(x) && copySign(1.0, x) == -1.0) {
         if (y > 0) {
             if (std::fmod(y, 2.0) == 1.0)
                 RETURN_RESULT(Encode(-qt_inf()));
             else
                 RETURN_RESULT(Encode(qt_inf()));
         } else if (y < 0) {
             if (std::fmod(-y, 2.0) == 1.0)
                 RETURN_RESULT(Encode(copySign(0, -1.0)));
             else
                 RETURN_RESULT(Encode(0));
         }
     }
 #endif
     else {
         RETURN_RESULT(Encode(std::pow(x, y)));
     }
     // ###
     RETURN_RESULT(Encode(qt_qnan()));
 }

 ReturnedValue MathObject::method_random(const FunctionObject *, const Value *, const Value *, int)
 {
     RETURN_RESULT(Encode(QRandomGenerator::global()->generateDouble()));
 }

 ReturnedValue MathObject::method_round(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (std::isnan(v) || qt_is_inf(v) || qIsNull(v))
         RETURN_RESULT(Encode(v));

      v = copySign(std::floor(v + 0.5), v);
      RETURN_RESULT(Encode(v));
 }

 ReturnedValue MathObject::method_sign(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();

     if (std::isnan(v))
         RETURN_RESULT(Encode(qt_qnan()));

     if (qIsNull(v))
         RETURN_RESULT(Encode(v));

     RETURN_RESULT(Encode(std::signbit(v) ? -1 : 1));
 }

 ReturnedValue MathObject::method_sin(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));
     else
         RETURN_RESULT(Encode(std::sin(v)));
 }

 ReturnedValue MathObject::method_sinh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));
     else
         RETURN_RESULT(Encode(std::sinh(v)));
 }

 ReturnedValue MathObject::method_sqrt(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     RETURN_RESULT(Encode(std::sqrt(v)));
 }

 ReturnedValue MathObject::method_tan(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));
     else
         RETURN_RESULT(Encode(std::tan(v)));
 }

 ReturnedValue MathObject::method_tanh(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
     if (v == 0.0)
         RETURN_RESULT(Encode(v));
     else
         RETURN_RESULT(Encode(std::tanh(v)));
 }

 ReturnedValue MathObject::method_trunc(const FunctionObject *, const Value *, const Value *argv, int argc)
 {
     double v = argc ? argv[0].toNumber() : qt_qnan();
 #ifdef Q_OS_ANDROID // incomplete std :-(
     if (std::isnan(v) || qt_is_inf(v) || qIsNull(v))
         RETURN_RESULT(Encode(v));
     // Nearest integer not greater in magnitude:
     quint64 whole = std::abs(v);
     RETURN_RESULT(Encode(copySign(whole, v)));
 #else
     RETURN_RESULT(Encode(std::trunc(v)));
 #endif
 }
	/****************************************************************************
	**
	** Copyright (C) 2016 The Qt Company Ltd.
	** Contact: https://www.qt.io/licensing/
	**
	** This file is part of the QtQml module of the Qt Toolkit.
	**
	** $QT_BEGIN_LICENSE:LGPL$
	** Commercial License Usage
	** Licensees holding valid commercial Qt licenses may use this file in
	** accordance with the commercial license agreement provided with the
	** Software or, alternatively, in accordance with the terms contained in
	** a written agreement between you and The Qt Company. For licensing terms
	** and conditions see https://www.qt.io/terms-conditions. For further
	** information use the contact form at https://www.qt.io/contact-us.
	**
	** GNU Lesser General Public License Usage
	** Alternatively, this file may be used under the terms of the GNU Lesser
	** General Public License version 3 as published by the Free Software
	** Foundation and appearing in the file LICENSE.LGPL3 included in the
	** packaging of this file. Please review the following information to
	** ensure the GNU Lesser General Public License version 3 requirements
	** will be met: https://www.gnu.org/licenses/lgpl-3.0.html.
	**
	** GNU General Public License Usage
	** Alternatively, this file may be used under the terms of the GNU
	** General Public License version 2.0 or (at your option) the GNU General
	** Public license version 3 or any later version approved by the KDE Free
	** Qt Foundation. The licenses are as published by the Free Software
	** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3
	** included in the packaging of this file. Please review the following
	** information to ensure the GNU General Public License requirements will
	** be met: https://www.gnu.org/licenses/gpl-2.0.html and
	** https://www.gnu.org/licenses/gpl-3.0.html.
	**
	** $QT_END_LICENSE$
	**
	****************************************************************************/

	#include "qv4mathobject_p.h"
	#include "qv4objectproto_p.h"
	#include "qv4symbol_p.h"

	#include <QtCore/qdatetime.h>
	#include <QtCore/qmath.h>
	#include <QtCore/qrandom.h>
	#include <QtCore/private/qnumeric_p.h>
	#include <QtCore/qthreadstorage.h>

	#include <math.h>
	#include <cmath>

	using namespace QV4;

	DEFINE_OBJECT_VTABLE(MathObject);

	void Heap::MathObject::init()
	{
	Object::init();
	Scope scope(internalClass->engine);
	ScopedObject m(scope, this);

	m->defineReadonlyProperty(QStringLiteral("E"), Value::fromDouble(M_E));
	m->defineReadonlyProperty(QStringLiteral("LN2"), Value::fromDouble(M_LN2));
	m->defineReadonlyProperty(QStringLiteral("LN10"), Value::fromDouble(M_LN10));
	m->defineReadonlyProperty(QStringLiteral("LOG2E"), Value::fromDouble(M_LOG2E));
	m->defineReadonlyProperty(QStringLiteral("LOG10E"), Value::fromDouble(M_LOG10E));
	m->defineReadonlyProperty(QStringLiteral("PI"), Value::fromDouble(M_PI));
	m->defineReadonlyProperty(QStringLiteral("SQRT1_2"), Value::fromDouble(M_SQRT1_2));
	m->defineReadonlyProperty(QStringLiteral("SQRT2"), Value::fromDouble(M_SQRT2));

	m->defineDefaultProperty(QStringLiteral("abs"), QV4::MathObject::method_abs, 1);
	m->defineDefaultProperty(QStringLiteral("acos"), QV4::MathObject::method_acos, 1);
	m->defineDefaultProperty(QStringLiteral("acosh"), QV4::MathObject::method_acosh, 1);
	m->defineDefaultProperty(QStringLiteral("asin"), QV4::MathObject::method_asin, 1);
	m->defineDefaultProperty(QStringLiteral("asinh"), QV4::MathObject::method_asinh, 1);
	m->defineDefaultProperty(QStringLiteral("atan"), QV4::MathObject::method_atan, 1);
	m->defineDefaultProperty(QStringLiteral("atanh"), QV4::MathObject::method_atanh, 1);
	m->defineDefaultProperty(QStringLiteral("atan2"), QV4::MathObject::method_atan2, 2);
	m->defineDefaultProperty(QStringLiteral("cbrt"), QV4::MathObject::method_cbrt, 1);
	m->defineDefaultProperty(QStringLiteral("ceil"), QV4::MathObject::method_ceil, 1);
	m->defineDefaultProperty(QStringLiteral("clz32"), QV4::MathObject::method_clz32, 1);
	m->defineDefaultProperty(QStringLiteral("cos"), QV4::MathObject::method_cos, 1);
	m->defineDefaultProperty(QStringLiteral("cosh"), QV4::MathObject::method_cosh, 1);
	m->defineDefaultProperty(QStringLiteral("exp"), QV4::MathObject::method_exp, 1);
	m->defineDefaultProperty(QStringLiteral("expm1"), QV4::MathObject::method_expm1, 1);
	m->defineDefaultProperty(QStringLiteral("floor"), QV4::MathObject::method_floor, 1);
	m->defineDefaultProperty(QStringLiteral("fround"), QV4::MathObject::method_fround, 1);
	m->defineDefaultProperty(QStringLiteral("hypot"), QV4::MathObject::method_hypot, 2);
	m->defineDefaultProperty(QStringLiteral("imul"), QV4::MathObject::method_imul, 2);
	m->defineDefaultProperty(QStringLiteral("log"), QV4::MathObject::method_log, 1);
	m->defineDefaultProperty(QStringLiteral("log10"), QV4::MathObject::method_log10, 1);
	m->defineDefaultProperty(QStringLiteral("log1p"), QV4::MathObject::method_log1p, 1);
	m->defineDefaultProperty(QStringLiteral("log2"), QV4::MathObject::method_log2, 1);
	m->defineDefaultProperty(QStringLiteral("max"), QV4::MathObject::method_max, 2);
	m->defineDefaultProperty(QStringLiteral("min"), QV4::MathObject::method_min, 2);
	m->defineDefaultProperty(QStringLiteral("pow"), QV4::MathObject::method_pow, 2);
	m->defineDefaultProperty(QStringLiteral("random"), QV4::MathObject::method_random, 0);
	m->defineDefaultProperty(QStringLiteral("round"), QV4::MathObject::method_round, 1);
	m->defineDefaultProperty(QStringLiteral("sign"), QV4::MathObject::method_sign, 1);
	m->defineDefaultProperty(QStringLiteral("sin"), QV4::MathObject::method_sin, 1);
	m->defineDefaultProperty(QStringLiteral("sinh"), QV4::MathObject::method_sinh, 1);
	m->defineDefaultProperty(QStringLiteral("sqrt"), QV4::MathObject::method_sqrt, 1);
	m->defineDefaultProperty(QStringLiteral("tan"), QV4::MathObject::method_tan, 1);
	m->defineDefaultProperty(QStringLiteral("tanh"), QV4::MathObject::method_tanh, 1);
	m->defineDefaultProperty(QStringLiteral("trunc"), QV4::MathObject::method_trunc, 1);

	ScopedString name(scope, scope.engine->newString(QStringLiteral("Math")));
	m->defineReadonlyConfigurableProperty(scope.engine->symbol_toStringTag(), name);
	}

	static Q_ALWAYS_INLINE double copySign(double x, double y)
	{
	return ::copysign(x, y);
	}

	ReturnedValue MathObject::method_abs(const FunctionObject , const Value , const Value *argv, int argc)
	{
	if (!argc)
	RETURN_RESULT(Encode(qt_qnan()));

	if (argv[0].isInteger()) {
	int i = argv[0].integerValue();
	RETURN_RESULT(Encode(i < 0 ? - i : i));
	}

	double v = argv[0].toNumber();
	if (v == 0) // 0 \| -0
	RETURN_RESULT(Encode(0));

	RETURN_RESULT(Encode(v < 0 ? -v : v));
	}

	ReturnedValue MathObject::method_acos(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : 2;
	if (v > 1)
	RETURN_RESULT(Encode(qt_qnan()));

	RETURN_RESULT(Encode(std::acos(v)));
	}

	ReturnedValue MathObject::method_acosh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : 2;
	if (v < 1)
	RETURN_RESULT(Encode(qt_qnan()));

	#ifdef Q_OS_ANDROID // incomplete std :-(
	RETURN_RESULT(Encode(std::log(v +std::sqrt(v + 1) * std::sqrt(v - 1))));
	#else
	RETURN_RESULT(Encode(std::acosh(v)));
	#endif
	}

	ReturnedValue MathObject::method_asin(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : 2;
	if (v > 1)
	RETURN_RESULT(Encode(qt_qnan()));
	else
	RETURN_RESULT(Encode(std::asin(v)));
	}

	ReturnedValue MathObject::method_asinh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : 2;
	if (v == 0.0)
	RETURN_RESULT(Encode(v));

	#ifdef Q_OS_ANDROID // incomplete std :-(
	RETURN_RESULT(Encode(std::log(v +std::sqrt(1 + v * v))));
	#else
	RETURN_RESULT(Encode(std::asinh(v)));
	#endif
	}

	ReturnedValue MathObject::method_atan(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));
	else
	RETURN_RESULT(Encode(std::atan(v)));
	}

	ReturnedValue MathObject::method_atanh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));

	#ifdef Q_OS_ANDROID // incomplete std :-(
	if (-1 < v && v < 1)
	RETURN_RESULT(Encode(0.5 * (std::log(v + 1) - std::log(v - 1))));

	if (v > 1 \|\| v < -1)
	RETURN_RESULT(Encode(qt_qnan()));

	RETURN_RESULT(Encode(copySign(qt_inf(), v)));
	#else
	RETURN_RESULT(Encode(std::atanh(v)));
	#endif
	}

	ReturnedValue MathObject::method_atan2(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v1 = argc ? argv[0].toNumber() : qt_qnan();
	double v2 = argc > 1 ? argv[1].toNumber() : qt_qnan();

	if ((v1 < 0) && qt_is_finite(v1) && qt_is_inf(v2) && (copySign(1.0, v2) == 1.0))
	RETURN_RESULT(Encode(copySign(0, -1.0)));

	if ((v1 == 0.0) && (v2 == 0.0)) {
	if ((copySign(1.0, v1) == 1.0) && (copySign(1.0, v2) == -1.0)) {
	RETURN_RESULT(Encode(M_PI));
	} else if ((copySign(1.0, v1) == -1.0) && (copySign(1.0, v2) == -1.0)) {
	RETURN_RESULT(Encode(-M_PI));
	}
	}
	RETURN_RESULT(Encode(std::atan2(v1, v2)));
	}

	ReturnedValue MathObject::method_cbrt(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	#ifdef Q_OS_ANDROID // incomplete std :-(
	RETURN_RESULT(Encode(copySign(std::exp(std::log(std::abs(v)) / 3), v)));
	#else
	RETURN_RESULT(Encode(std::cbrt(v))); // cube root
	#endif
	}

	ReturnedValue MathObject::method_ceil(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v < 0.0 && v > -1.0)
	RETURN_RESULT(Encode(copySign(0, -1.0)));
	else
	RETURN_RESULT(Encode(std::ceil(v)));
	}

	ReturnedValue MathObject::method_clz32(const FunctionObject , const Value , const Value *argv, int argc)
	{
	quint32 v = argc ? argv[0].toUInt32() : 0;
	RETURN_RESULT(Encode(qint32(qCountLeadingZeroBits(v))));
	}

	ReturnedValue MathObject::method_cos(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	RETURN_RESULT(Encode(std::cos(v)));
	}

	ReturnedValue MathObject::method_cosh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	RETURN_RESULT(Encode(std::cosh(v)));
	}

	ReturnedValue MathObject::method_exp(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (qt_is_inf(v)) {
	if (copySign(1.0, v) == -1.0)
	RETURN_RESULT(Encode(0));
	else
	RETURN_RESULT(Encode(qt_inf()));
	} else {
	RETURN_RESULT(Encode(std::exp(v)));
	}
	}

	ReturnedValue MathObject::method_expm1(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (std::isnan(v) \|\| qIsNull(v)) {
	RETURN_RESULT(Encode(v));
	} else if (qt_is_inf(v)) {
	if (copySign(1.0, v) == -1.0)
	RETURN_RESULT(Encode(-1.0));
	else
	RETURN_RESULT(Encode(qt_inf()));
	} else {
	#ifdef Q_OS_ANDROID // incomplete std :-(
	RETURN_RESULT(Encode(std::exp(v) - 1));
	#else
	RETURN_RESULT(Encode(std::expm1(v)));
	#endif
	}
	}

	ReturnedValue MathObject::method_floor(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	Value result = Value::fromDouble(std::floor(v));
	result.isInt32();
	RETURN_RESULT(result);
	}

	ReturnedValue MathObject::method_fround(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (std::isnan(v) \|\| qt_is_inf(v) \|\| qIsNull(v))
	RETURN_RESULT(Encode(v));
	else // convert to 32-bit float using roundTiesToEven, then convert back to 64-bit double
	RETURN_RESULT(Encode(double(float(v))));
	}

	ReturnedValue MathObject::method_hypot(const FunctionObject , const Value , const Value *argv, int argc)
	{
	// ES6 Math.hypot(v1, ..., vn) -> sqrt(sum(vi**2)) but "should take care to
	// avoid the loss of precision from overflows and underflows" (as std::hypot does).
	double v = argc ? argv[0].toNumber() : 0;
	// Spec mandates +0 on no args; and says nothing about what to do if toNumber() signals ...
	#ifdef Q_OS_ANDROID // incomplete std :-(
	bool big = qt_is_inf(v), bad = std::isnan(v);
	v *= v;
	for (int i = 1; !big && i < argc; i++) {
	double u = argv[i].toNumber();
	if (qt_is_inf(u))
	big = true;
	if (std::isnan(u))
	bad = true;
	v += u * u;
	}
	if (big)
	RETURN_RESULT(Encode(qt_inf()));
	if (bad)
	RETURN_RESULT(Encode(qt_qnan()));
	// Should actually check for {und,ov}erflow, but too fiddly !
	RETURN_RESULT(Value::fromDouble(sqrt(v)));
	#else
	for (int i = 1; i < argc; i++)
	v = std::hypot(v, argv[i].toNumber());
	#endif
	RETURN_RESULT(Value::fromDouble(v));
	}

	ReturnedValue MathObject::method_imul(const FunctionObject , const Value , const Value *argv, int argc)
	{
	quint32 a = argc ? argv[0].toUInt32() : 0;
	quint32 b = argc > 0 ? argv[1].toUInt32() : 0;
	qint32 product = a * b;
	RETURN_RESULT(Encode(product));
	}

	ReturnedValue MathObject::method_log(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v < 0)
	RETURN_RESULT(Encode(qt_qnan()));
	else
	RETURN_RESULT(Encode(std::log(v)));
	}

	ReturnedValue MathObject::method_log10(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v < 0)
	RETURN_RESULT(Encode(qt_qnan()));
	else
	RETURN_RESULT(Encode(std::log10(v)));
	}

	ReturnedValue MathObject::method_log1p(const FunctionObject , const Value , const Value *argv, int argc)
	{
	#if !defined(__ANDROID__)
	using std::log1p;
	#endif
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v < -1)
	RETURN_RESULT(Encode(qt_qnan()));
	else
	RETURN_RESULT(Encode(log1p(v)));
	}

	ReturnedValue MathObject::method_log2(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v < 0) {
	RETURN_RESULT(Encode(qt_qnan()));
	} else {
	#ifdef Q_OS_ANDROID // incomplete std :-(
	// Android ndk r10e doesn't have std::log2, so fall back.
	const double ln2 = std::log(2.0);
	RETURN_RESULT(Encode(std::log(v) / ln2));
	#else
	RETURN_RESULT(Encode(std::log2(v)));
	#endif
	}
	}

	ReturnedValue MathObject::method_max(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double mx = -qt_inf();
	for (int i = 0, ei = argc; i < ei; ++i) {
	double x = argv[i].toNumber();
	if ((x == 0 && mx == x && copySign(1.0, x) == 1.0)
	\|\| (x > mx) \|\| std::isnan(x)) {
	mx = x;
	}
	}
	RETURN_RESULT(Encode::smallestNumber(mx));
	}

	ReturnedValue MathObject::method_min(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double mx = qt_inf();
	for (int i = 0, ei = argc; i < ei; ++i) {
	double x = argv[i].toNumber();
	if ((x == 0 && mx == x && copySign(1.0, x) == -1.0)
	\|\| (x < mx) \|\| std::isnan(x)) {
	mx = x;
	}
	}
	RETURN_RESULT(Encode::smallestNumber(mx));
	}

	ReturnedValue MathObject::method_pow(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double x = argc > 0 ? argv[0].toNumber() : qt_qnan();
	double y = argc > 1 ? argv[1].toNumber() : qt_qnan();

	if (std::isnan(y))
	RETURN_RESULT(Encode(qt_qnan()));

	if (y == 0) {
	RETURN_RESULT(Encode(1));
	} else if (((x == 1) \|\| (x == -1)) && std::isinf(y)) {
	RETURN_RESULT(Encode(qt_qnan()));
	} else if (((x == 0) && copySign(1.0, x) == 1.0) && (y < 0)) {
	RETURN_RESULT(Encode(qInf()));
	} else if ((x == 0) && copySign(1.0, x) == -1.0) {
	if (y < 0) {
	if (std::fmod(-y, 2.0) == 1.0)
	RETURN_RESULT(Encode(-qt_inf()));
	else
	RETURN_RESULT(Encode(qt_inf()));
	} else if (y > 0) {
	if (std::fmod(y, 2.0) == 1.0)
	RETURN_RESULT(Encode(copySign(0, -1.0)));
	else
	RETURN_RESULT(Encode(0));
	}
	}

	#ifdef Q_OS_AIX
	else if (qt_is_inf(x) && copySign(1.0, x) == -1.0) {
	if (y > 0) {
	if (std::fmod(y, 2.0) == 1.0)
	RETURN_RESULT(Encode(-qt_inf()));
	else
	RETURN_RESULT(Encode(qt_inf()));
	} else if (y < 0) {
	if (std::fmod(-y, 2.0) == 1.0)
	RETURN_RESULT(Encode(copySign(0, -1.0)));
	else
	RETURN_RESULT(Encode(0));
	}
	}
	#endif
	else {
	RETURN_RESULT(Encode(std::pow(x, y)));
	}
	// ###
	RETURN_RESULT(Encode(qt_qnan()));
	}

	ReturnedValue MathObject::method_random(const FunctionObject , const Value , const Value *, int)
	{
	RETURN_RESULT(Encode(QRandomGenerator::global()->generateDouble()));
	}

	ReturnedValue MathObject::method_round(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (std::isnan(v) \|\| qt_is_inf(v) \|\| qIsNull(v))
	RETURN_RESULT(Encode(v));

	v = copySign(std::floor(v + 0.5), v);
	RETURN_RESULT(Encode(v));
	}

	ReturnedValue MathObject::method_sign(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();

	if (std::isnan(v))
	RETURN_RESULT(Encode(qt_qnan()));

	if (qIsNull(v))
	RETURN_RESULT(Encode(v));

	RETURN_RESULT(Encode(std::signbit(v) ? -1 : 1));
	}

	ReturnedValue MathObject::method_sin(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));
	else
	RETURN_RESULT(Encode(std::sin(v)));
	}

	ReturnedValue MathObject::method_sinh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));
	else
	RETURN_RESULT(Encode(std::sinh(v)));
	}

	ReturnedValue MathObject::method_sqrt(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	RETURN_RESULT(Encode(std::sqrt(v)));
	}

	ReturnedValue MathObject::method_tan(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));
	else
	RETURN_RESULT(Encode(std::tan(v)));
	}

	ReturnedValue MathObject::method_tanh(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	if (v == 0.0)
	RETURN_RESULT(Encode(v));
	else
	RETURN_RESULT(Encode(std::tanh(v)));
	}

	ReturnedValue MathObject::method_trunc(const FunctionObject , const Value , const Value *argv, int argc)
	{
	double v = argc ? argv[0].toNumber() : qt_qnan();
	#ifdef Q_OS_ANDROID // incomplete std :-(
	if (std::isnan(v) \|\| qt_is_inf(v) \|\| qIsNull(v))
	RETURN_RESULT(Encode(v));
	// Nearest integer not greater in magnitude:
	quint64 whole = std::abs(v);
	RETURN_RESULT(Encode(copySign(whole, v)));
	#else
	RETURN_RESULT(Encode(std::trunc(v)));
	#endif
	}