qt5base-lts/tests/auto/qvectornd/tst_qvectornd.cpp
Jyri Tahtela f9f395c28b Update licenseheader text in source files for qtbase Qt module
Updated version of LGPL and FDL licenseheaders.
Apply release phase licenseheaders for all source files.

Reviewed-by: Trust Me
2011-05-24 12:34:08 +03:00

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58 KiB
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/****************************************************************************
**
** Copyright (C) 2011 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the test suite of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:LGPL$
** GNU Lesser General Public License Usage
** This file may be used under the terms of the GNU Lesser General Public
** License version 2.1 as published by the Free Software Foundation and
** appearing in the file LICENSE.LGPL included in the packaging of this
** file. Please review the following information to ensure the GNU Lesser
** General Public License version 2.1 requirements will be met:
** http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, Nokia gives you certain additional
** rights. These rights are described in the Nokia Qt LGPL Exception
** version 1.1, included in the file LGPL_EXCEPTION.txt in this package.
**
** GNU General Public License Usage
** Alternatively, this file may be used under the terms of the GNU General
** Public License version 3.0 as published by the Free Software Foundation
** and appearing in the file LICENSE.GPL included in the packaging of this
** file. Please review the following information to ensure the GNU General
** Public License version 3.0 requirements will be met:
** http://www.gnu.org/copyleft/gpl.html.
**
** Other Usage
** Alternatively, this file may be used in accordance with the terms and
** conditions contained in a signed written agreement between you and Nokia.
**
**
**
**
**
** $QT_END_LICENSE$
**
****************************************************************************/
#include <QtTest/QtTest>
#include <QtCore/qmath.h>
#include <QtGui/qvector2d.h>
#include <QtGui/qvector3d.h>
#include <QtGui/qvector4d.h>
class tst_QVectorND : public QObject
{
Q_OBJECT
public:
tst_QVectorND() {}
~tst_QVectorND() {}
private slots:
void create2();
void create3();
void create4();
void length2_data();
void length2();
void length3_data();
void length3();
void length4_data();
void length4();
void normalized2_data();
void normalized2();
void normalized3_data();
void normalized3();
void normalized4_data();
void normalized4();
void normalize2_data();
void normalize2();
void normalize3_data();
void normalize3();
void normalize4_data();
void normalize4();
void compare2();
void compare3();
void compare4();
void add2_data();
void add2();
void add3_data();
void add3();
void add4_data();
void add4();
void subtract2_data();
void subtract2();
void subtract3_data();
void subtract3();
void subtract4_data();
void subtract4();
void multiply2_data();
void multiply2();
void multiply3_data();
void multiply3();
void multiply4_data();
void multiply4();
void multiplyFactor2_data();
void multiplyFactor2();
void multiplyFactor3_data();
void multiplyFactor3();
void multiplyFactor4_data();
void multiplyFactor4();
void divide2_data();
void divide2();
void divide3_data();
void divide3();
void divide4_data();
void divide4();
void negate2_data();
void negate2();
void negate3_data();
void negate3();
void negate4_data();
void negate4();
void crossProduct_data();
void crossProduct();
void normal_data();
void normal();
void distanceToPlane_data();
void distanceToPlane();
void distanceToLine_data();
void distanceToLine();
void dotProduct2_data();
void dotProduct2();
void dotProduct3_data();
void dotProduct3();
void dotProduct4_data();
void dotProduct4();
void properties();
void metaTypes();
};
// QVector2/3/4D use float internally, which can sometimes lead
// to precision issues when converting to and from qreal.
// This fuzzy compare is slightly "fuzzier" than the default
// qFuzzyCompare for qreal to compensate.
static bool fuzzyCompare(qreal x, qreal y)
{
return qFuzzyIsNull((float)(x - y));
}
// Test the creation of QVector2D objects in various ways:
// construct, copy, and modify.
void tst_QVectorND::create2()
{
QVector2D null;
QCOMPARE(null.x(), (qreal)0.0f);
QCOMPARE(null.y(), (qreal)0.0f);
QVERIFY(null.isNull());
QVector2D v1(1.0f, 2.5f);
QCOMPARE(v1.x(), (qreal)1.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QVERIFY(!v1.isNull());
QVector2D v1i(1, 2);
QCOMPARE(v1i.x(), (qreal)1.0f);
QCOMPARE(v1i.y(), (qreal)2.0f);
QVERIFY(!v1i.isNull());
QVector2D v2(v1);
QCOMPARE(v2.x(), (qreal)1.0f);
QCOMPARE(v2.y(), (qreal)2.5f);
QVERIFY(!v2.isNull());
QVector2D v4;
QCOMPARE(v4.x(), (qreal)0.0f);
QCOMPARE(v4.y(), (qreal)0.0f);
QVERIFY(v4.isNull());
v4 = v1;
QCOMPARE(v4.x(), (qreal)1.0f);
QCOMPARE(v4.y(), (qreal)2.5f);
QVERIFY(!v4.isNull());
QVector2D v5(QPoint(1, 2));
QCOMPARE(v5.x(), (qreal)1.0f);
QCOMPARE(v5.y(), (qreal)2.0f);
QVERIFY(!v5.isNull());
QVector2D v6(QPointF(1, 2.5));
QCOMPARE(v6.x(), (qreal)1.0f);
QCOMPARE(v6.y(), (qreal)2.5f);
QVERIFY(!v6.isNull());
QVector2D v7(QVector3D(1.0f, 2.5f, 54.25f));
QCOMPARE(v7.x(), (qreal)1.0f);
QCOMPARE(v7.y(), (qreal)2.5f);
QVERIFY(!v6.isNull());
QVector2D v8(QVector4D(1.0f, 2.5f, 54.25f, 34.0f));
QCOMPARE(v8.x(), (qreal)1.0f);
QCOMPARE(v8.y(), (qreal)2.5f);
QVERIFY(!v6.isNull());
v1.setX(3.0f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QVERIFY(!v1.isNull());
v1.setY(10.5f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QVERIFY(!v1.isNull());
v1.setX(0.0f);
v1.setY(0.0f);
QCOMPARE(v1.x(), (qreal)0.0f);
QCOMPARE(v1.y(), (qreal)0.0f);
QVERIFY(v1.isNull());
QPoint p1 = v8.toPoint();
QCOMPARE(p1.x(), 1);
QCOMPARE(p1.y(), 3);
QPointF p2 = v8.toPointF();
QCOMPARE((qreal)p2.x(), (qreal)1.0f);
QCOMPARE((qreal)p2.y(), (qreal)2.5f);
QVector3D v9 = v8.toVector3D();
QCOMPARE(v9.x(), (qreal)1.0f);
QCOMPARE(v9.y(), (qreal)2.5f);
QCOMPARE(v9.z(), (qreal)0.0f);
QVector4D v10 = v8.toVector4D();
QCOMPARE(v10.x(), (qreal)1.0f);
QCOMPARE(v10.y(), (qreal)2.5f);
QCOMPARE(v10.z(), (qreal)0.0f);
QCOMPARE(v10.w(), (qreal)0.0f);
}
// Test the creation of QVector3D objects in various ways:
// construct, copy, and modify.
void tst_QVectorND::create3()
{
QVector3D null;
QCOMPARE(null.x(), (qreal)0.0f);
QCOMPARE(null.y(), (qreal)0.0f);
QCOMPARE(null.z(), (qreal)0.0f);
QVERIFY(null.isNull());
QVector3D v1(1.0f, 2.5f, -89.25f);
QCOMPARE(v1.x(), (qreal)1.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QVERIFY(!v1.isNull());
QVector3D v1i(1, 2, -89);
QCOMPARE(v1i.x(), (qreal)1.0f);
QCOMPARE(v1i.y(), (qreal)2.0f);
QCOMPARE(v1i.z(), (qreal)-89.0f);
QVERIFY(!v1i.isNull());
QVector3D v2(v1);
QCOMPARE(v2.x(), (qreal)1.0f);
QCOMPARE(v2.y(), (qreal)2.5f);
QCOMPARE(v2.z(), (qreal)-89.25f);
QVERIFY(!v2.isNull());
QVector3D v3(1.0f, 2.5f, 0.0f);
QCOMPARE(v3.x(), (qreal)1.0f);
QCOMPARE(v3.y(), (qreal)2.5f);
QCOMPARE(v3.z(), (qreal)0.0f);
QVERIFY(!v3.isNull());
QVector3D v3i(1, 2, 0);
QCOMPARE(v3i.x(), (qreal)1.0f);
QCOMPARE(v3i.y(), (qreal)2.0f);
QCOMPARE(v3i.z(), (qreal)0.0f);
QVERIFY(!v3i.isNull());
QVector3D v4;
QCOMPARE(v4.x(), (qreal)0.0f);
QCOMPARE(v4.y(), (qreal)0.0f);
QCOMPARE(v4.z(), (qreal)0.0f);
QVERIFY(v4.isNull());
v4 = v1;
QCOMPARE(v4.x(), (qreal)1.0f);
QCOMPARE(v4.y(), (qreal)2.5f);
QCOMPARE(v4.z(), (qreal)-89.25f);
QVERIFY(!v4.isNull());
QVector3D v5(QPoint(1, 2));
QCOMPARE(v5.x(), (qreal)1.0f);
QCOMPARE(v5.y(), (qreal)2.0f);
QCOMPARE(v5.z(), (qreal)0.0f);
QVERIFY(!v5.isNull());
QVector3D v6(QPointF(1, 2.5));
QCOMPARE(v6.x(), (qreal)1.0f);
QCOMPARE(v6.y(), (qreal)2.5f);
QCOMPARE(v6.z(), (qreal)0.0f);
QVERIFY(!v6.isNull());
QVector3D v7(QVector2D(1.0f, 2.5f));
QCOMPARE(v7.x(), (qreal)1.0f);
QCOMPARE(v7.y(), (qreal)2.5f);
QCOMPARE(v7.z(), (qreal)0.0f);
QVERIFY(!v7.isNull());
QVector3D v8(QVector2D(1.0f, 2.5f), 54.25f);
QCOMPARE(v8.x(), (qreal)1.0f);
QCOMPARE(v8.y(), (qreal)2.5f);
QCOMPARE(v8.z(), (qreal)54.25f);
QVERIFY(!v8.isNull());
QVector3D v9(QVector4D(1.0f, 2.5f, 54.25f, 34.0f));
QCOMPARE(v9.x(), (qreal)1.0f);
QCOMPARE(v9.y(), (qreal)2.5f);
QCOMPARE(v9.z(), (qreal)54.25f);
QVERIFY(!v9.isNull());
v1.setX(3.0f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QVERIFY(!v1.isNull());
v1.setY(10.5f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QVERIFY(!v1.isNull());
v1.setZ(15.5f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QCOMPARE(v1.z(), (qreal)15.5f);
QVERIFY(!v1.isNull());
v1.setX(0.0f);
v1.setY(0.0f);
v1.setZ(0.0f);
QCOMPARE(v1.x(), (qreal)0.0f);
QCOMPARE(v1.y(), (qreal)0.0f);
QCOMPARE(v1.z(), (qreal)0.0f);
QVERIFY(v1.isNull());
QPoint p1 = v8.toPoint();
QCOMPARE(p1.x(), 1);
QCOMPARE(p1.y(), 3);
QPointF p2 = v8.toPointF();
QCOMPARE((qreal)p2.x(), (qreal)1.0f);
QCOMPARE((qreal)p2.y(), (qreal)2.5f);
QVector2D v10 = v8.toVector2D();
QCOMPARE(v10.x(), (qreal)1.0f);
QCOMPARE(v10.y(), (qreal)2.5f);
QVector4D v11 = v8.toVector4D();
QCOMPARE(v11.x(), (qreal)1.0f);
QCOMPARE(v11.y(), (qreal)2.5f);
QCOMPARE(v11.z(), (qreal)54.25f);
QCOMPARE(v11.w(), (qreal)0.0f);
}
// Test the creation of QVector4D objects in various ways:
// construct, copy, and modify.
void tst_QVectorND::create4()
{
QVector4D null;
QCOMPARE(null.x(), (qreal)0.0f);
QCOMPARE(null.y(), (qreal)0.0f);
QCOMPARE(null.z(), (qreal)0.0f);
QCOMPARE(null.w(), (qreal)0.0f);
QVERIFY(null.isNull());
QVector4D v1(1.0f, 2.5f, -89.25f, 34.0f);
QCOMPARE(v1.x(), (qreal)1.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QCOMPARE(v1.w(), (qreal)34.0f);
QVERIFY(!v1.isNull());
QVector4D v1i(1, 2, -89, 34);
QCOMPARE(v1i.x(), (qreal)1.0f);
QCOMPARE(v1i.y(), (qreal)2.0f);
QCOMPARE(v1i.z(), (qreal)-89.0f);
QCOMPARE(v1i.w(), (qreal)34.0f);
QVERIFY(!v1i.isNull());
QVector4D v2(v1);
QCOMPARE(v2.x(), (qreal)1.0f);
QCOMPARE(v2.y(), (qreal)2.5f);
QCOMPARE(v2.z(), (qreal)-89.25f);
QCOMPARE(v2.w(), (qreal)34.0f);
QVERIFY(!v2.isNull());
QVector4D v3(1.0f, 2.5f, 0.0f, 0.0f);
QCOMPARE(v3.x(), (qreal)1.0f);
QCOMPARE(v3.y(), (qreal)2.5f);
QCOMPARE(v3.z(), (qreal)0.0f);
QCOMPARE(v3.w(), (qreal)0.0f);
QVERIFY(!v3.isNull());
QVector4D v3i(1, 2, 0, 0);
QCOMPARE(v3i.x(), (qreal)1.0f);
QCOMPARE(v3i.y(), (qreal)2.0f);
QCOMPARE(v3i.z(), (qreal)0.0f);
QCOMPARE(v3i.w(), (qreal)0.0f);
QVERIFY(!v3i.isNull());
QVector4D v3b(1.0f, 2.5f, -89.25f, 0.0f);
QCOMPARE(v3b.x(), (qreal)1.0f);
QCOMPARE(v3b.y(), (qreal)2.5f);
QCOMPARE(v3b.z(), (qreal)-89.25f);
QCOMPARE(v3b.w(), (qreal)0.0f);
QVERIFY(!v3b.isNull());
QVector4D v3bi(1, 2, -89, 0);
QCOMPARE(v3bi.x(), (qreal)1.0f);
QCOMPARE(v3bi.y(), (qreal)2.0f);
QCOMPARE(v3bi.z(), (qreal)-89.0f);
QCOMPARE(v3bi.w(), (qreal)0.0f);
QVERIFY(!v3bi.isNull());
QVector4D v4;
QCOMPARE(v4.x(), (qreal)0.0f);
QCOMPARE(v4.y(), (qreal)0.0f);
QCOMPARE(v4.z(), (qreal)0.0f);
QCOMPARE(v4.w(), (qreal)0.0f);
QVERIFY(v4.isNull());
v4 = v1;
QCOMPARE(v4.x(), (qreal)1.0f);
QCOMPARE(v4.y(), (qreal)2.5f);
QCOMPARE(v4.z(), (qreal)-89.25f);
QCOMPARE(v4.w(), (qreal)34.0f);
QVERIFY(!v4.isNull());
QVector4D v5(QPoint(1, 2));
QCOMPARE(v5.x(), (qreal)1.0f);
QCOMPARE(v5.y(), (qreal)2.0f);
QCOMPARE(v5.z(), (qreal)0.0f);
QCOMPARE(v5.w(), (qreal)0.0f);
QVERIFY(!v5.isNull());
QVector4D v6(QPointF(1, 2.5));
QCOMPARE(v6.x(), (qreal)1.0f);
QCOMPARE(v6.y(), (qreal)2.5f);
QCOMPARE(v6.z(), (qreal)0.0f);
QCOMPARE(v6.w(), (qreal)0.0f);
QVERIFY(!v6.isNull());
QVector4D v7(QVector2D(1.0f, 2.5f));
QCOMPARE(v7.x(), (qreal)1.0f);
QCOMPARE(v7.y(), (qreal)2.5f);
QCOMPARE(v7.z(), (qreal)0.0f);
QCOMPARE(v7.w(), (qreal)0.0f);
QVERIFY(!v7.isNull());
QVector4D v8(QVector3D(1.0f, 2.5f, -89.25f));
QCOMPARE(v8.x(), (qreal)1.0f);
QCOMPARE(v8.y(), (qreal)2.5f);
QCOMPARE(v8.z(), (qreal)-89.25f);
QCOMPARE(v8.w(), (qreal)0.0f);
QVERIFY(!v8.isNull());
QVector4D v9(QVector3D(1.0f, 2.5f, -89.25f), 34);
QCOMPARE(v9.x(), (qreal)1.0f);
QCOMPARE(v9.y(), (qreal)2.5f);
QCOMPARE(v9.z(), (qreal)-89.25f);
QCOMPARE(v9.w(), (qreal)34.0f);
QVERIFY(!v9.isNull());
QVector4D v10(QVector2D(1.0f, 2.5f), 23.5f, -8);
QCOMPARE(v10.x(), (qreal)1.0f);
QCOMPARE(v10.y(), (qreal)2.5f);
QCOMPARE(v10.z(), (qreal)23.5f);
QCOMPARE(v10.w(), (qreal)-8.0f);
QVERIFY(!v10.isNull());
v1.setX(3.0f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)2.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QCOMPARE(v1.w(), (qreal)34.0f);
QVERIFY(!v1.isNull());
v1.setY(10.5f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QCOMPARE(v1.z(), (qreal)-89.25f);
QCOMPARE(v1.w(), (qreal)34.0f);
QVERIFY(!v1.isNull());
v1.setZ(15.5f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QCOMPARE(v1.z(), (qreal)15.5f);
QCOMPARE(v1.w(), (qreal)34.0f);
QVERIFY(!v1.isNull());
v1.setW(6.0f);
QCOMPARE(v1.x(), (qreal)3.0f);
QCOMPARE(v1.y(), (qreal)10.5f);
QCOMPARE(v1.z(), (qreal)15.5f);
QCOMPARE(v1.w(), (qreal)6.0f);
QVERIFY(!v1.isNull());
v1.setX(0.0f);
v1.setY(0.0f);
v1.setZ(0.0f);
v1.setW(0.0f);
QCOMPARE(v1.x(), (qreal)0.0f);
QCOMPARE(v1.y(), (qreal)0.0f);
QCOMPARE(v1.z(), (qreal)0.0f);
QCOMPARE(v1.w(), (qreal)0.0f);
QVERIFY(v1.isNull());
QPoint p1 = v8.toPoint();
QCOMPARE(p1.x(), 1);
QCOMPARE(p1.y(), 3);
QPointF p2 = v8.toPointF();
QCOMPARE((qreal)p2.x(), (qreal)1.0f);
QCOMPARE((qreal)p2.y(), (qreal)2.5f);
QVector2D v11 = v8.toVector2D();
QCOMPARE(v11.x(), (qreal)1.0f);
QCOMPARE(v11.y(), (qreal)2.5f);
QVector3D v12 = v8.toVector3D();
QCOMPARE(v12.x(), (qreal)1.0f);
QCOMPARE(v12.y(), (qreal)2.5f);
QCOMPARE(v12.z(), (qreal)-89.25f);
QVector2D v13 = v9.toVector2DAffine();
QVERIFY(fuzzyCompare(v13.x(), (qreal)(1.0f / 34.0f)));
QVERIFY(fuzzyCompare(v13.y(), (qreal)(2.5f / 34.0f)));
QVector4D zerow(1.0f, 2.0f, 3.0f, 0.0f);
v13 = zerow.toVector2DAffine();
QVERIFY(v13.isNull());
QVector3D v14 = v9.toVector3DAffine();
QVERIFY(fuzzyCompare(v14.x(), (qreal)(1.0f / 34.0f)));
QVERIFY(fuzzyCompare(v14.y(), (qreal)(2.5f / 34.0f)));
QVERIFY(fuzzyCompare(v14.z(), (qreal)(-89.25f / 34.0f)));
v14 = zerow.toVector3DAffine();
QVERIFY(v14.isNull());
}
// Test vector length computation for 2D vectors.
void tst_QVectorND::length2_data()
{
QTest::addColumn<qreal>("x");
QTest::addColumn<qreal>("y");
QTest::addColumn<qreal>("len");
QTest::newRow("null") << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("1x") << (qreal)1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1y") << (qreal)0.0f << (qreal)1.0f << (qreal)1.0f;
QTest::newRow("-1x") << (qreal)-1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1y") << (qreal)0.0f << (qreal)-1.0f << (qreal)1.0f;
QTest::newRow("two") << (qreal)2.0f << (qreal)-2.0f << (qreal)qSqrt(8.0f);
}
void tst_QVectorND::length2()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, len);
QVector2D v(x, y);
QCOMPARE(v.length(), len);
QCOMPARE(v.lengthSquared(), x * x + y * y);
}
// Test vector length computation for 3D vectors.
void tst_QVectorND::length3_data()
{
QTest::addColumn<qreal>("x");
QTest::addColumn<qreal>("y");
QTest::addColumn<qreal>("z");
QTest::addColumn<qreal>("len");
QTest::newRow("null") << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("1x") << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1y") << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1z") << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)1.0f;
QTest::newRow("-1x") << (qreal)-1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1y") << (qreal)0.0f << (qreal)-1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1z") << (qreal)0.0f << (qreal)0.0f << (qreal)-1.0f << (qreal)1.0f;
QTest::newRow("two") << (qreal)2.0f << (qreal)-2.0f << (qreal)2.0f << (qreal)qSqrt(12.0f);
}
void tst_QVectorND::length3()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QFETCH(qreal, len);
QVector3D v(x, y, z);
QCOMPARE(v.length(), len);
QCOMPARE(v.lengthSquared(), x * x + y * y + z * z);
}
// Test vector length computation for 4D vectors.
void tst_QVectorND::length4_data()
{
QTest::addColumn<qreal>("x");
QTest::addColumn<qreal>("y");
QTest::addColumn<qreal>("z");
QTest::addColumn<qreal>("w");
QTest::addColumn<qreal>("len");
QTest::newRow("null") << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("1x") << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1y") << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1z") << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("1w") << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)1.0f;
QTest::newRow("-1x") << (qreal)-1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1y") << (qreal)0.0f << (qreal)-1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1z") << (qreal)0.0f << (qreal)0.0f << (qreal)-1.0f << (qreal)0.0f << (qreal)1.0f;
QTest::newRow("-1w") << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)-1.0f << (qreal)1.0f;
QTest::newRow("two") << (qreal)2.0f << (qreal)-2.0f << (qreal)2.0f << (qreal)2.0f << (qreal)qSqrt(16.0f);
}
void tst_QVectorND::length4()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QFETCH(qreal, w);
QFETCH(qreal, len);
QVector4D v(x, y, z, w);
QCOMPARE(v.length(), len);
QCOMPARE(v.lengthSquared(), x * x + y * y + z * z + w * w);
}
// Test the unit vector conversion for 2D vectors.
void tst_QVectorND::normalized2_data()
{
// Use the same test data as the length test.
length2_data();
}
void tst_QVectorND::normalized2()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, len);
QVector2D v(x, y);
QVector2D u = v.normalized();
if (v.isNull())
QVERIFY(u.isNull());
else
QVERIFY(fuzzyCompare(u.length(), qreal(1.0f)));
QVERIFY(fuzzyCompare(u.x() * len, v.x()));
QVERIFY(fuzzyCompare(u.y() * len, v.y()));
}
// Test the unit vector conversion for 3D vectors.
void tst_QVectorND::normalized3_data()
{
// Use the same test data as the length test.
length3_data();
}
void tst_QVectorND::normalized3()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QFETCH(qreal, len);
QVector3D v(x, y, z);
QVector3D u = v.normalized();
if (v.isNull())
QVERIFY(u.isNull());
else
QVERIFY(fuzzyCompare(u.length(), qreal(1.0f)));
QVERIFY(fuzzyCompare(u.x() * len, v.x()));
QVERIFY(fuzzyCompare(u.y() * len, v.y()));
QVERIFY(fuzzyCompare(u.z() * len, v.z()));
}
// Test the unit vector conversion for 4D vectors.
void tst_QVectorND::normalized4_data()
{
// Use the same test data as the length test.
length4_data();
}
void tst_QVectorND::normalized4()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QFETCH(qreal, w);
QFETCH(qreal, len);
QVector4D v(x, y, z, w);
QVector4D u = v.normalized();
if (v.isNull())
QVERIFY(u.isNull());
else
QVERIFY(fuzzyCompare(u.length(), qreal(1.0f)));
QVERIFY(fuzzyCompare(u.x() * len, v.x()));
QVERIFY(fuzzyCompare(u.y() * len, v.y()));
QVERIFY(fuzzyCompare(u.z() * len, v.z()));
QVERIFY(fuzzyCompare(u.w() * len, v.w()));
}
// Test the unit vector conversion for 2D vectors.
void tst_QVectorND::normalize2_data()
{
// Use the same test data as the length test.
length2_data();
}
void tst_QVectorND::normalize2()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QVector2D v(x, y);
bool isNull = v.isNull();
v.normalize();
if (isNull)
QVERIFY(v.isNull());
else
QVERIFY(fuzzyCompare(v.length(), qreal(1.0f)));
}
// Test the unit vector conversion for 3D vectors.
void tst_QVectorND::normalize3_data()
{
// Use the same test data as the length test.
length3_data();
}
void tst_QVectorND::normalize3()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QVector3D v(x, y, z);
bool isNull = v.isNull();
v.normalize();
if (isNull)
QVERIFY(v.isNull());
else
QVERIFY(fuzzyCompare(v.length(), qreal(1.0f)));
}
// Test the unit vector conversion for 4D vectors.
void tst_QVectorND::normalize4_data()
{
// Use the same test data as the length test.
length4_data();
}
void tst_QVectorND::normalize4()
{
QFETCH(qreal, x);
QFETCH(qreal, y);
QFETCH(qreal, z);
QFETCH(qreal, w);
QVector4D v(x, y, z, w);
bool isNull = v.isNull();
v.normalize();
if (isNull)
QVERIFY(v.isNull());
else
QVERIFY(fuzzyCompare(v.length(), qreal(1.0f)));
}
// Test the comparison operators for 2D vectors.
void tst_QVectorND::compare2()
{
QVector2D v1(1, 2);
QVector2D v2(1, 2);
QVector2D v3(3, 2);
QVector2D v4(1, 3);
QVERIFY(v1 == v2);
QVERIFY(v1 != v3);
QVERIFY(v1 != v4);
}
// Test the comparison operators for 3D vectors.
void tst_QVectorND::compare3()
{
QVector3D v1(1, 2, 4);
QVector3D v2(1, 2, 4);
QVector3D v3(3, 2, 4);
QVector3D v4(1, 3, 4);
QVector3D v5(1, 2, 3);
QVERIFY(v1 == v2);
QVERIFY(v1 != v3);
QVERIFY(v1 != v4);
QVERIFY(v1 != v5);
}
// Test the comparison operators for 4D vectors.
void tst_QVectorND::compare4()
{
QVector4D v1(1, 2, 4, 8);
QVector4D v2(1, 2, 4, 8);
QVector4D v3(3, 2, 4, 8);
QVector4D v4(1, 3, 4, 8);
QVector4D v5(1, 2, 3, 8);
QVector4D v6(1, 2, 4, 3);
QVERIFY(v1 == v2);
QVERIFY(v1 != v3);
QVERIFY(v1 != v4);
QVERIFY(v1 != v5);
QVERIFY(v1 != v6);
}
// Test vector addition for 2D vectors.
void tst_QVectorND::add2_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f
<< (qreal)3.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)3.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f
<< (qreal)4.0f << (qreal)5.0f
<< (qreal)5.0f << (qreal)7.0f;
}
void tst_QVectorND::add2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
QVector2D v3(x3, y3);
QVERIFY((v1 + v2) == v3);
QVector2D v4(v1);
v4 += v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() + v2.x());
QCOMPARE(v4.y(), v1.y() + v2.y());
}
// Test vector addition for 3D vectors.
void tst_QVectorND::add3_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)3.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)3.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)3.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)-6.0f
<< (qreal)5.0f << (qreal)7.0f << (qreal)-3.0f;
}
void tst_QVectorND::add3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVERIFY((v1 + v2) == v3);
QVector3D v4(v1);
v4 += v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() + v2.x());
QCOMPARE(v4.y(), v1.y() + v2.y());
QCOMPARE(v4.z(), v1.z() + v2.z());
}
// Test vector addition for 4D vectors.
void tst_QVectorND::add4_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("w1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("w2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::addColumn<qreal>("w3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)3.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)3.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)3.0f << (qreal)0.0f;
QTest::newRow("wonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)3.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f << (qreal)8.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)-6.0f << (qreal)9.0f
<< (qreal)5.0f << (qreal)7.0f << (qreal)-3.0f << (qreal)17.0f;
}
void tst_QVectorND::add4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, w3);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
QVector4D v3(x3, y3, z3, w3);
QVERIFY((v1 + v2) == v3);
QVector4D v4(v1);
v4 += v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() + v2.x());
QCOMPARE(v4.y(), v1.y() + v2.y());
QCOMPARE(v4.z(), v1.z() + v2.z());
QCOMPARE(v4.w(), v1.w() + v2.w());
}
// Test vector subtraction for 2D vectors.
void tst_QVectorND::subtract2_data()
{
// Use the same test data as the add test.
add2_data();
}
void tst_QVectorND::subtract2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
QVector2D v3(x3, y3);
QVERIFY((v3 - v1) == v2);
QVERIFY((v3 - v2) == v1);
QVector2D v4(v3);
v4 -= v1;
QVERIFY(v4 == v2);
QCOMPARE(v4.x(), v3.x() - v1.x());
QCOMPARE(v4.y(), v3.y() - v1.y());
QVector2D v5(v3);
v5 -= v2;
QVERIFY(v5 == v1);
QCOMPARE(v5.x(), v3.x() - v2.x());
QCOMPARE(v5.y(), v3.y() - v2.y());
}
// Test vector subtraction for 3D vectors.
void tst_QVectorND::subtract3_data()
{
// Use the same test data as the add test.
add3_data();
}
void tst_QVectorND::subtract3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVERIFY((v3 - v1) == v2);
QVERIFY((v3 - v2) == v1);
QVector3D v4(v3);
v4 -= v1;
QVERIFY(v4 == v2);
QCOMPARE(v4.x(), v3.x() - v1.x());
QCOMPARE(v4.y(), v3.y() - v1.y());
QCOMPARE(v4.z(), v3.z() - v1.z());
QVector3D v5(v3);
v5 -= v2;
QVERIFY(v5 == v1);
QCOMPARE(v5.x(), v3.x() - v2.x());
QCOMPARE(v5.y(), v3.y() - v2.y());
QCOMPARE(v5.z(), v3.z() - v2.z());
}
// Test vector subtraction for 4D vectors.
void tst_QVectorND::subtract4_data()
{
// Use the same test data as the add test.
add4_data();
}
void tst_QVectorND::subtract4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, w3);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
QVector4D v3(x3, y3, z3, w3);
QVERIFY((v3 - v1) == v2);
QVERIFY((v3 - v2) == v1);
QVector4D v4(v3);
v4 -= v1;
QVERIFY(v4 == v2);
QCOMPARE(v4.x(), v3.x() - v1.x());
QCOMPARE(v4.y(), v3.y() - v1.y());
QCOMPARE(v4.z(), v3.z() - v1.z());
QCOMPARE(v4.w(), v3.w() - v1.w());
QVector4D v5(v3);
v5 -= v2;
QVERIFY(v5 == v1);
QCOMPARE(v5.x(), v3.x() - v2.x());
QCOMPARE(v5.y(), v3.y() - v2.y());
QCOMPARE(v5.z(), v3.z() - v2.z());
QCOMPARE(v5.w(), v3.w() - v2.w());
}
// Test component-wise vector multiplication for 2D vectors.
void tst_QVectorND::multiply2_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f
<< (qreal)4.0f << (qreal)5.0f
<< (qreal)4.0f << (qreal)10.0f;
}
void tst_QVectorND::multiply2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
QVector2D v3(x3, y3);
QVERIFY((v1 * v2) == v3);
QVector2D v4(v1);
v4 *= v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() * v2.x());
QCOMPARE(v4.y(), v1.y() * v2.y());
}
// Test component-wise vector multiplication for 3D vectors.
void tst_QVectorND::multiply3_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)-6.0f
<< (qreal)4.0f << (qreal)10.0f << (qreal)-18.0f;
}
void tst_QVectorND::multiply3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVERIFY((v1 * v2) == v3);
QVector3D v4(v1);
v4 *= v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() * v2.x());
QCOMPARE(v4.y(), v1.y() * v2.y());
QCOMPARE(v4.z(), v1.z() * v2.z());
}
// Test component-wise vector multiplication for 4D vectors.
void tst_QVectorND::multiply4_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("w1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("w2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::addColumn<qreal>("w3");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f << (qreal)0.0f;
QTest::newRow("wonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f << (qreal)8.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)-6.0f << (qreal)9.0f
<< (qreal)4.0f << (qreal)10.0f << (qreal)-18.0f << (qreal)72.0f;
}
void tst_QVectorND::multiply4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, w3);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
QVector4D v3(x3, y3, z3, w3);
QVERIFY((v1 * v2) == v3);
QVector4D v4(v1);
v4 *= v2;
QVERIFY(v4 == v3);
QCOMPARE(v4.x(), v1.x() * v2.x());
QCOMPARE(v4.y(), v1.y() * v2.y());
QCOMPARE(v4.z(), v1.z() * v2.z());
QCOMPARE(v4.w(), v1.w() * v2.w());
}
// Test vector multiplication by a factor for 2D vectors.
void tst_QVectorND::multiplyFactor2_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("factor");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)100.0f
<< (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)4.0f;
QTest::newRow("allzero")
<< (qreal)1.0f << (qreal)2.0f
<< (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f;
}
void tst_QVectorND::multiplyFactor2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
QVERIFY((v1 * factor) == v2);
QVERIFY((factor * v1) == v2);
QVector2D v3(v1);
v3 *= factor;
QVERIFY(v3 == v2);
QCOMPARE(v3.x(), v1.x() * factor);
QCOMPARE(v3.y(), v1.y() * factor);
}
// Test vector multiplication by a factor for 3D vectors.
void tst_QVectorND::multiplyFactor3_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("factor");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)100.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)-3.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)4.0f << (qreal)-6.0f;
QTest::newRow("allzero")
<< (qreal)1.0f << (qreal)2.0f << (qreal)-3.0f
<< (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
}
void tst_QVectorND::multiplyFactor3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVERIFY((v1 * factor) == v2);
QVERIFY((factor * v1) == v2);
QVector3D v3(v1);
v3 *= factor;
QVERIFY(v3 == v2);
QCOMPARE(v3.x(), v1.x() * factor);
QCOMPARE(v3.y(), v1.y() * factor);
QCOMPARE(v3.z(), v1.z() * factor);
}
// Test vector multiplication by a factor for 4D vectors.
void tst_QVectorND::multiplyFactor4_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("w1");
QTest::addColumn<qreal>("factor");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("w2");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)100.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("xonly")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("yonly")
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f << (qreal)0.0f;
QTest::newRow("zonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f << (qreal)0.0f;
QTest::newRow("wonly")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)2.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)2.0f;
QTest::newRow("all")
<< (qreal)1.0f << (qreal)2.0f << (qreal)-3.0f << (qreal)4.0f
<< (qreal)2.0f
<< (qreal)2.0f << (qreal)4.0f << (qreal)-6.0f << (qreal)8.0f;
QTest::newRow("allzero")
<< (qreal)1.0f << (qreal)2.0f << (qreal)-3.0f << (qreal)4.0f
<< (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f;
}
void tst_QVectorND::multiplyFactor4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
QVERIFY((v1 * factor) == v2);
QVERIFY((factor * v1) == v2);
QVector4D v3(v1);
v3 *= factor;
QVERIFY(v3 == v2);
QCOMPARE(v3.x(), v1.x() * factor);
QCOMPARE(v3.y(), v1.y() * factor);
QCOMPARE(v3.z(), v1.z() * factor);
QCOMPARE(v3.w(), v1.w() * factor);
}
// Test vector division by a factor for 2D vectors.
void tst_QVectorND::divide2_data()
{
// Use the same test data as the multiply test.
multiplyFactor2_data();
}
void tst_QVectorND::divide2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
if (factor == (qreal)0.0f)
return;
QVERIFY((v2 / factor) == v1);
QVector2D v3(v2);
v3 /= factor;
QVERIFY(v3 == v1);
QCOMPARE(v3.x(), v2.x() / factor);
QCOMPARE(v3.y(), v2.y() / factor);
}
// Test vector division by a factor for 3D vectors.
void tst_QVectorND::divide3_data()
{
// Use the same test data as the multiply test.
multiplyFactor3_data();
}
void tst_QVectorND::divide3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
if (factor == (qreal)0.0f)
return;
QVERIFY((v2 / factor) == v1);
QVector3D v3(v2);
v3 /= factor;
QVERIFY(v3 == v1);
QCOMPARE(v3.x(), v2.x() / factor);
QCOMPARE(v3.y(), v2.y() / factor);
QCOMPARE(v3.z(), v2.z() / factor);
}
// Test vector division by a factor for 4D vectors.
void tst_QVectorND::divide4_data()
{
// Use the same test data as the multiply test.
multiplyFactor4_data();
}
void tst_QVectorND::divide4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, factor);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
if (factor == (qreal)0.0f)
return;
QVERIFY((v2 / factor) == v1);
QVector4D v3(v2);
v3 /= factor;
QVERIFY(v3 == v1);
QCOMPARE(v3.x(), v2.x() / factor);
QCOMPARE(v3.y(), v2.y() / factor);
QCOMPARE(v3.z(), v2.z() / factor);
QCOMPARE(v3.w(), v2.w() / factor);
}
// Test vector negation for 2D vectors.
void tst_QVectorND::negate2_data()
{
// Use the same test data as the add test.
add2_data();
}
void tst_QVectorND::negate2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QVector2D v1(x1, y1);
QVector2D v2(-x1, -y1);
QVERIFY(-v1 == v2);
}
// Test vector negation for 3D vectors.
void tst_QVectorND::negate3_data()
{
// Use the same test data as the add test.
add3_data();
}
void tst_QVectorND::negate3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QVector3D v1(x1, y1, z1);
QVector3D v2(-x1, -y1, -z1);
QVERIFY(-v1 == v2);
}
// Test vector negation for 4D vectors.
void tst_QVectorND::negate4_data()
{
// Use the same test data as the add test.
add4_data();
}
void tst_QVectorND::negate4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(-x1, -y1, -z1, -w1);
QVERIFY(-v1 == v2);
}
// Test the computation of vector cross-products.
void tst_QVectorND::crossProduct_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("x3");
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::addColumn<qreal>("dot");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("unitvec")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f;
QTest::newRow("complex")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)6.0f
<< (qreal)-3.0f << (qreal)6.0f << (qreal)-3.0f
<< (qreal)32.0f;
}
void tst_QVectorND::crossProduct()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVector3D v4 = QVector3D::crossProduct(v1, v2);
QVERIFY(v4 == v3);
// Compute the cross-product long-hand and check again.
qreal xres = y1 * z2 - z1 * y2;
qreal yres = z1 * x2 - x1 * z2;
qreal zres = x1 * y2 - y1 * x2;
QCOMPARE(v4.x(), xres);
QCOMPARE(v4.y(), yres);
QCOMPARE(v4.z(), zres);
}
// Test the computation of normals.
void tst_QVectorND::normal_data()
{
// Use the same test data as the crossProduct test.
crossProduct_data();
}
void tst_QVectorND::normal()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVERIFY(QVector3D::normal(v1, v2) == v3.normalized());
QVERIFY(QVector3D::normal(QVector3D(), v1, v2) == v3.normalized());
QVector3D point(1.0f, 2.0f, 3.0f);
QVERIFY(QVector3D::normal(point, v1 + point, v2 + point) == v3.normalized());
}
// Test distance to plane calculations.
void tst_QVectorND::distanceToPlane_data()
{
QTest::addColumn<qreal>("x1"); // Point on plane
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("x2"); // Normal to plane
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("x3"); // Point to test for distance
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::addColumn<qreal>("x4"); // Second point on plane
QTest::addColumn<qreal>("y4");
QTest::addColumn<qreal>("z4");
QTest::addColumn<qreal>("x5"); // Third point on plane
QTest::addColumn<qreal>("y5");
QTest::addColumn<qreal>("z5");
QTest::addColumn<qreal>("distance");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("above")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)2.0f
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)2.0f;
QTest::newRow("below")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)-1.0f << (qreal)1.0f << (qreal)-2.0f
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)2.0f << (qreal)0.0f
<< (qreal)-2.0f;
}
void tst_QVectorND::distanceToPlane()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, x4);
QFETCH(qreal, y4);
QFETCH(qreal, z4);
QFETCH(qreal, x5);
QFETCH(qreal, y5);
QFETCH(qreal, z5);
QFETCH(qreal, distance);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QVector3D v4(x4, y4, z4);
QVector3D v5(x5, y5, z5);
QCOMPARE(v3.distanceToPlane(v1, v2), distance);
QCOMPARE(v3.distanceToPlane(v1, v4, v5), distance);
}
// Test distance to line calculations.
void tst_QVectorND::distanceToLine_data()
{
QTest::addColumn<qreal>("x1"); // Point on line
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("x2"); // Direction of the line
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("x3"); // Point to test for distance
QTest::addColumn<qreal>("y3");
QTest::addColumn<qreal>("z3");
QTest::addColumn<qreal>("distance");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("on line")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)5.0f
<< (qreal)0.0f;
QTest::newRow("off line")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)1.0f;
QTest::newRow("off line 2")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f << (qreal)-2.0f << (qreal)0.0f
<< (qreal)2.0f;
QTest::newRow("points")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)5.0f << (qreal)0.0f
<< (qreal)5.0f;
}
void tst_QVectorND::distanceToLine()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, distance);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVector3D v3(x3, y3, z3);
QCOMPARE(v3.distanceToLine(v1, v2), distance);
}
// Test the computation of dot products for 2D vectors.
void tst_QVectorND::dotProduct2_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("dot");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("unitvec")
<< (qreal)1.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)1.0f
<< (qreal)0.0f;
QTest::newRow("complex")
<< (qreal)1.0f << (qreal)2.0f
<< (qreal)4.0f << (qreal)5.0f
<< (qreal)14.0f;
}
void tst_QVectorND::dotProduct2()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, dot);
QVector2D v1(x1, y1);
QVector2D v2(x2, y2);
QVERIFY(QVector2D::dotProduct(v1, v2) == dot);
// Compute the dot-product long-hand and check again.
qreal d = x1 * x2 + y1 * y2;
QCOMPARE(QVector2D::dotProduct(v1, v2), d);
}
// Test the computation of dot products for 3D vectors.
void tst_QVectorND::dotProduct3_data()
{
// Use the same test data as the crossProduct test.
crossProduct_data();
}
void tst_QVectorND::dotProduct3()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, x3);
QFETCH(qreal, y3);
QFETCH(qreal, z3);
QFETCH(qreal, dot);
Q_UNUSED(x3);
Q_UNUSED(y3);
Q_UNUSED(z3);
QVector3D v1(x1, y1, z1);
QVector3D v2(x2, y2, z2);
QVERIFY(QVector3D::dotProduct(v1, v2) == dot);
// Compute the dot-product long-hand and check again.
qreal d = x1 * x2 + y1 * y2 + z1 * z2;
QCOMPARE(QVector3D::dotProduct(v1, v2), d);
}
// Test the computation of dot products for 4D vectors.
void tst_QVectorND::dotProduct4_data()
{
QTest::addColumn<qreal>("x1");
QTest::addColumn<qreal>("y1");
QTest::addColumn<qreal>("z1");
QTest::addColumn<qreal>("w1");
QTest::addColumn<qreal>("x2");
QTest::addColumn<qreal>("y2");
QTest::addColumn<qreal>("z2");
QTest::addColumn<qreal>("w2");
QTest::addColumn<qreal>("dot");
QTest::newRow("null")
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("unitvec")
<< (qreal)1.0f << (qreal)0.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f << (qreal)1.0f << (qreal)0.0f << (qreal)0.0f
<< (qreal)0.0f;
QTest::newRow("complex")
<< (qreal)1.0f << (qreal)2.0f << (qreal)3.0f << (qreal)4.0f
<< (qreal)4.0f << (qreal)5.0f << (qreal)6.0f << (qreal)7.0f
<< (qreal)60.0f;
}
void tst_QVectorND::dotProduct4()
{
QFETCH(qreal, x1);
QFETCH(qreal, y1);
QFETCH(qreal, z1);
QFETCH(qreal, w1);
QFETCH(qreal, x2);
QFETCH(qreal, y2);
QFETCH(qreal, z2);
QFETCH(qreal, w2);
QFETCH(qreal, dot);
QVector4D v1(x1, y1, z1, w1);
QVector4D v2(x2, y2, z2, w2);
QVERIFY(QVector4D::dotProduct(v1, v2) == dot);
// Compute the dot-product long-hand and check again.
qreal d = x1 * x2 + y1 * y2 + z1 * z2 + w1 * w2;
QCOMPARE(QVector4D::dotProduct(v1, v2), d);
}
class tst_QVectorNDProperties : public QObject
{
Q_OBJECT
Q_PROPERTY(QVector2D vector2D READ vector2D WRITE setVector2D)
Q_PROPERTY(QVector3D vector3D READ vector3D WRITE setVector3D)
Q_PROPERTY(QVector4D vector4D READ vector4D WRITE setVector4D)
public:
tst_QVectorNDProperties(QObject *parent = 0) : QObject(parent) {}
QVector2D vector2D() const { return v2; }
void setVector2D(const QVector2D& value) { v2 = value; }
QVector3D vector3D() const { return v3; }
void setVector3D(const QVector3D& value) { v3 = value; }
QVector4D vector4D() const { return v4; }
void setVector4D(const QVector4D& value) { v4 = value; }
private:
QVector2D v2;
QVector3D v3;
QVector4D v4;
};
// Test getting and setting vector properties via the metaobject system.
void tst_QVectorND::properties()
{
tst_QVectorNDProperties obj;
obj.setVector2D(QVector2D(1.0f, 2.0f));
obj.setVector3D(QVector3D(3.0f, 4.0f, 5.0f));
obj.setVector4D(QVector4D(6.0f, 7.0f, 8.0f, 9.0f));
QVector2D v2 = qVariantValue<QVector2D>(obj.property("vector2D"));
QCOMPARE(v2.x(), (qreal)1.0f);
QCOMPARE(v2.y(), (qreal)2.0f);
QVector3D v3 = qVariantValue<QVector3D>(obj.property("vector3D"));
QCOMPARE(v3.x(), (qreal)3.0f);
QCOMPARE(v3.y(), (qreal)4.0f);
QCOMPARE(v3.z(), (qreal)5.0f);
QVector4D v4 = qVariantValue<QVector4D>(obj.property("vector4D"));
QCOMPARE(v4.x(), (qreal)6.0f);
QCOMPARE(v4.y(), (qreal)7.0f);
QCOMPARE(v4.z(), (qreal)8.0f);
QCOMPARE(v4.w(), (qreal)9.0f);
obj.setProperty("vector2D",
qVariantFromValue(QVector2D(-1.0f, -2.0f)));
obj.setProperty("vector3D",
qVariantFromValue(QVector3D(-3.0f, -4.0f, -5.0f)));
obj.setProperty("vector4D",
qVariantFromValue(QVector4D(-6.0f, -7.0f, -8.0f, -9.0f)));
v2 = qVariantValue<QVector2D>(obj.property("vector2D"));
QCOMPARE(v2.x(), (qreal)-1.0f);
QCOMPARE(v2.y(), (qreal)-2.0f);
v3 = qVariantValue<QVector3D>(obj.property("vector3D"));
QCOMPARE(v3.x(), (qreal)-3.0f);
QCOMPARE(v3.y(), (qreal)-4.0f);
QCOMPARE(v3.z(), (qreal)-5.0f);
v4 = qVariantValue<QVector4D>(obj.property("vector4D"));
QCOMPARE(v4.x(), (qreal)-6.0f);
QCOMPARE(v4.y(), (qreal)-7.0f);
QCOMPARE(v4.z(), (qreal)-8.0f);
QCOMPARE(v4.w(), (qreal)-9.0f);
}
void tst_QVectorND::metaTypes()
{
QVERIFY(QMetaType::type("QVector2D") == QMetaType::QVector2D);
QVERIFY(QMetaType::type("QVector3D") == QMetaType::QVector3D);
QVERIFY(QMetaType::type("QVector4D") == QMetaType::QVector4D);
QCOMPARE(QByteArray(QMetaType::typeName(QMetaType::QVector2D)),
QByteArray("QVector2D"));
QCOMPARE(QByteArray(QMetaType::typeName(QMetaType::QVector3D)),
QByteArray("QVector3D"));
QCOMPARE(QByteArray(QMetaType::typeName(QMetaType::QVector4D)),
QByteArray("QVector4D"));
QVERIFY(QMetaType::isRegistered(QMetaType::QVector2D));
QVERIFY(QMetaType::isRegistered(QMetaType::QVector3D));
QVERIFY(QMetaType::isRegistered(QMetaType::QVector4D));
QVERIFY(qMetaTypeId<QVector2D>() == QMetaType::QVector2D);
QVERIFY(qMetaTypeId<QVector3D>() == QMetaType::QVector3D);
QVERIFY(qMetaTypeId<QVector4D>() == QMetaType::QVector4D);
}
QTEST_APPLESS_MAIN(tst_QVectorND)
#include "tst_qvectornd.moc"