/**************************************************************************** ** ** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). ** Contact: Qt Software Information (qt-info@nokia.com) ** ** This file is part of the test suite of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the either Technology Preview License Agreement or the ** Beta Release License Agreement. ** ** GNU Lesser General Public License Usage ** Alternatively, 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 1.0, 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. ** ** If you are unsure which license is appropriate for your use, please ** contact the sales department at qt-sales@nokia.com. ** $QT_END_LICENSE$ ** ****************************************************************************/ #include #include //TESTED_FILES= class tst_QTransform : public QObject { Q_OBJECT public: tst_QTransform(); virtual ~tst_QTransform(); public slots: void init(); void cleanup(); private slots: void construct(); void translate_data(); void translate(); void scale_data(); void scale(); void shear_data(); void shear(); void rotate_data(); void rotate(); void rotateXYZ_data(); void rotateXYZ(); void operatorAssign_data(); void operatorAssign(); void operatorEqual_data(); void operatorEqual(); void operatorNotEqual_data(); void operatorNotEqual(); void operatorMultiply_data(); void operatorMultiply(); void operatorPlusEqualScalar_data(); void operatorPlusEqualScalar(); void operatorMinusEqualScalar_data(); void operatorMinusEqualScalar(); void operatorMultiplyEqual_data(); void operatorMultiplyEqual(); void operatorMultiplyEqualScalar_data(); void operatorMultiplyEqualScalar(); void operatorDivideEqualScalar_data(); void operatorDivideEqualScalar(); void mapQPoint_data(); void mapQPoint(); void mapQPointF_data(); void mapQPointF(); void mapRect_data(); void mapRect(); void mapRectF_data(); void mapRectF(); void mapQPolygon_data(); void mapQPolygon(); void mapQPolygonF_data(); void mapQPolygonF(); void mapQRegion_data(); void mapQRegion(); void mapToPolygon_data(); void mapToPolygon(); void mapQPainterPath_data(); void mapQPainterPath(); void isIdentity_data(); void isIdentity(); void isAffine_data(); void isAffine(); void isInvertible_data(); void isInvertible(); void isRotating_data(); void isRotating(); void isScaling_data(); void isScaling(); void isTranslating_data(); void isTranslating(); void type_data(); void type(); void determinant_data(); void determinant(); void adjoint_data(); void adjoint(); void transposed_data(); void transposed(); void inverted_data(); void inverted(); private: QMap generateTransforms() const; }; tst_QTransform::tst_QTransform() { } tst_QTransform::~tst_QTransform() { } void tst_QTransform::init() { } void tst_QTransform::cleanup() { } QMap tst_QTransform::generateTransforms() const { QMap x; x["0: identity"] = QTransform(); x["1: translate"] = QTransform().translate(10, 10); x["2: translate"] = QTransform().translate(-10, -10); x["3: rotate45"] = QTransform().rotate(45); x["4: rotate90"] = QTransform().rotate(90); x["5: rotate180"] = QTransform().rotate(180); x["6: shear2,2"] = QTransform().shear(2, 2); x["7: shear-2,-2"] = QTransform().shear(-2, -2); x["8: scaleUp2,2"] = QTransform().scale(2, 2); x["9: scaleUp2,3"] = QTransform().scale(2, 3); x["10: scaleDown0.5,0.5"] = QTransform().scale(0.5, 0.5); x["11: scaleDown0.5,0.25"] = QTransform().scale(0.5, 0.25); x["12: rotateX"] = QTransform().rotate(45, Qt::XAxis); x["13: rotateY"] = QTransform().rotate(45, Qt::YAxis); x["14: rotateXY"] = QTransform().rotate(45, Qt::XAxis).rotate(45, Qt::YAxis); x["15: rotateYZ"] = QTransform().rotate(45, Qt::YAxis).rotate(45, Qt::ZAxis); x["16: full"] = QTransform().translate(10, 10).rotate(45).shear(2, 2).scale(2, 2).rotate(45, Qt::YAxis).rotate(45, Qt::XAxis).rotate(45, Qt::ZAxis); return x; } void tst_QTransform::construct() { QBENCHMARK { QTransform x; } } #define SINGLE_DATA_IMPLEMENTATION(func) \ void tst_QTransform::func##_data() \ { \ QTest::addColumn("transform"); \ QMap x = generateTransforms(); \ QMapIterator it(x); \ while (it.hasNext()) { \ it.next(); \ QTest::newRow(it.key()) << it.value(); \ } \ } #define DOUBLE_DATA_IMPLEMENTATION(func) \ void tst_QTransform::func##_data() \ { \ QTest::addColumn("x1"); \ QTest::addColumn("x2"); \ QMap x = generateTransforms(); \ QMapIterator it(x); \ while (it.hasNext()) { \ it.next(); \ const char *key1 = it.key(); \ QTransform x1 = it.value(); \ QMapIterator it2(x); \ while (it2.hasNext()) { \ it2.next(); \ QTest::newRow(QString("%1 + %2").arg(key1).arg(it2.key()).toLatin1().constData()) \ << x1 << it2.value(); \ } \ } \ } SINGLE_DATA_IMPLEMENTATION(translate) void tst_QTransform::translate() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.translate(10, 10); } } SINGLE_DATA_IMPLEMENTATION(scale) void tst_QTransform::scale() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.scale(2, 2); } } SINGLE_DATA_IMPLEMENTATION(shear) void tst_QTransform::shear() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.shear(2, 2); } } SINGLE_DATA_IMPLEMENTATION(rotate) void tst_QTransform::rotate() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.rotate(45); } } SINGLE_DATA_IMPLEMENTATION(rotateXYZ) void tst_QTransform::rotateXYZ() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.rotate(45, Qt::XAxis); x.rotate(45, Qt::YAxis); x.rotate(45, Qt::ZAxis); } } DOUBLE_DATA_IMPLEMENTATION(operatorAssign) void tst_QTransform::operatorAssign() { QFETCH(QTransform, x1); QFETCH(QTransform, x2); QTransform x = x1; QBENCHMARK { x = x2; } } DOUBLE_DATA_IMPLEMENTATION(operatorEqual) void tst_QTransform::operatorEqual() { QFETCH(QTransform, x1); QFETCH(QTransform, x2); QTransform x = x1; QBENCHMARK { x == x2; } } DOUBLE_DATA_IMPLEMENTATION(operatorNotEqual) void tst_QTransform::operatorNotEqual() { QFETCH(QTransform, x1); QFETCH(QTransform, x2); QTransform x = x1; QBENCHMARK { x != x2; } } DOUBLE_DATA_IMPLEMENTATION(operatorMultiply) void tst_QTransform::operatorMultiply() { QFETCH(QTransform, x1); QFETCH(QTransform, x2); QTransform x = x1; QBENCHMARK { x * x2; } } SINGLE_DATA_IMPLEMENTATION(operatorPlusEqualScalar) void tst_QTransform::operatorPlusEqualScalar() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x += 3.14; } } SINGLE_DATA_IMPLEMENTATION(operatorMinusEqualScalar) void tst_QTransform::operatorMinusEqualScalar() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x -= 3.14; } } DOUBLE_DATA_IMPLEMENTATION(operatorMultiplyEqual) void tst_QTransform::operatorMultiplyEqual() { QFETCH(QTransform, x1); QFETCH(QTransform, x2); QTransform x = x1; QBENCHMARK { x *= x2; } } SINGLE_DATA_IMPLEMENTATION(operatorMultiplyEqualScalar) void tst_QTransform::operatorMultiplyEqualScalar() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x * 3; } } SINGLE_DATA_IMPLEMENTATION(operatorDivideEqualScalar) void tst_QTransform::operatorDivideEqualScalar() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x /= 3; } } SINGLE_DATA_IMPLEMENTATION(mapQPoint) void tst_QTransform::mapQPoint() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.map(QPoint(3, 3)); } } SINGLE_DATA_IMPLEMENTATION(mapQPointF) void tst_QTransform::mapQPointF() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.map(QPointF(3, 3)); } } SINGLE_DATA_IMPLEMENTATION(mapRect) void tst_QTransform::mapRect() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.mapRect(QRect(0, 0, 100, 100)); } } SINGLE_DATA_IMPLEMENTATION(mapRectF) void tst_QTransform::mapRectF() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.mapRect(QRectF(0, 0, 100, 100)); } } SINGLE_DATA_IMPLEMENTATION(mapQPolygon) void tst_QTransform::mapQPolygon() { QFETCH(QTransform, transform); QTransform x = transform; QPolygon poly = QPolygon(QRect(0, 0, 100, 100)); QBENCHMARK { x.map(poly); } } SINGLE_DATA_IMPLEMENTATION(mapQPolygonF) void tst_QTransform::mapQPolygonF() { QFETCH(QTransform, transform); QTransform x = transform; QPolygonF poly = QPolygonF(QRectF(0, 0, 100, 100)); QBENCHMARK { x.map(poly); } } SINGLE_DATA_IMPLEMENTATION(mapQRegion) void tst_QTransform::mapQRegion() { QFETCH(QTransform, transform); QTransform x = transform; QRegion region; for (int i = 0; i < 10; ++i) region += QRect(i * 10, i * 10, 100, 100); QBENCHMARK { x.map(region); } } SINGLE_DATA_IMPLEMENTATION(mapToPolygon) void tst_QTransform::mapToPolygon() { QFETCH(QTransform, transform); QTransform x = transform; QBENCHMARK { x.mapToPolygon(QRect(0, 0, 100, 100)); } } SINGLE_DATA_IMPLEMENTATION(mapQPainterPath) void tst_QTransform::mapQPainterPath() { QFETCH(QTransform, transform); QTransform x = transform; QPainterPath path; for (int i = 0; i < 10; ++i) path.addEllipse(i * 10, i * 10, 100, 100); QBENCHMARK { x.map(path); } } SINGLE_DATA_IMPLEMENTATION(isIdentity) void tst_QTransform::isIdentity() { QFETCH(QTransform, transform); QBENCHMARK { transform.isIdentity(); } } SINGLE_DATA_IMPLEMENTATION(isAffine) void tst_QTransform::isAffine() { QFETCH(QTransform, transform); QBENCHMARK { transform.isAffine(); } } SINGLE_DATA_IMPLEMENTATION(isInvertible) void tst_QTransform::isInvertible() { QFETCH(QTransform, transform); QBENCHMARK { transform.isInvertible(); } } SINGLE_DATA_IMPLEMENTATION(isRotating) void tst_QTransform::isRotating() { QFETCH(QTransform, transform); QBENCHMARK { transform.isRotating(); } } SINGLE_DATA_IMPLEMENTATION(isScaling) void tst_QTransform::isScaling() { QFETCH(QTransform, transform); QBENCHMARK { transform.isScaling(); } } SINGLE_DATA_IMPLEMENTATION(isTranslating) void tst_QTransform::isTranslating() { QFETCH(QTransform, transform); QBENCHMARK { transform.isTranslating(); } } SINGLE_DATA_IMPLEMENTATION(type) void tst_QTransform::type() { QFETCH(QTransform, transform); QBENCHMARK { transform.type(); } } SINGLE_DATA_IMPLEMENTATION(determinant) void tst_QTransform::determinant() { QFETCH(QTransform, transform); QBENCHMARK { transform.determinant(); } } SINGLE_DATA_IMPLEMENTATION(adjoint) void tst_QTransform::adjoint() { QFETCH(QTransform, transform); QBENCHMARK { transform.adjoint(); } } SINGLE_DATA_IMPLEMENTATION(transposed) void tst_QTransform::transposed() { QFETCH(QTransform, transform); QBENCHMARK { transform.transposed(); } } SINGLE_DATA_IMPLEMENTATION(inverted) void tst_QTransform::inverted() { QFETCH(QTransform, transform); QBENCHMARK { transform.inverted(); } } QTEST_MAIN(tst_QTransform) #include "tst_qtransform.moc"