/**************************************************************************** ** ** Copyright (C) 2015 Klaralvdalens Datakonsult AB (KDAB). ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the Qt3D 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 "qtorusgeometry.h" #include "qtorusgeometry_p.h" #include #include #include #include #include #include QT_BEGIN_NAMESPACE using namespace Qt3DRender; namespace Qt3DExtras { namespace { int vertexCount(int requestedRings, int requestedSlices) { return (requestedRings + 1) * (requestedSlices + 1); } int triangleCount(int requestedRings, int requestedSlices) { return 2 * requestedRings * requestedSlices; } QByteArray createTorusVertexData(double radius, double minorRadius, int rings, int slices) { // The additional side and ring compared to what the user asked // for is because we also need to ensure proper texture coordinate // wrapping at the seams. Without this the last ring and side would // interpolate the texture coordinates from ~0.9x back down to 0 // (the starting value at the first ring). So we insert an extra // ring and side with the same positions as the first ring and side // but with texture coordinates of 1 (compared to 0). const int nVerts = vertexCount(rings, slices); QByteArray bufferBytes; // vec3 pos, vec2 texCoord, vec3 normal, vec4 tangent const quint32 elementSize = 3 + 2 + 3 + 4; const quint32 stride = elementSize * sizeof(float); bufferBytes.resize(stride * nVerts); float* fptr = reinterpret_cast(bufferBytes.data()); const float ringFactor = (M_PI * 2) / static_cast(rings); const float sliceFactor = (M_PI * 2) / static_cast(slices); for (int ring = 0; ring <= rings; ++ring) { const float u = ring * ringFactor; const float cu = qCos(u); const float su = qSin(u); for (int slice = 0; slice <= slices; ++slice) { const float v = slice * sliceFactor; const float cv = qCos(v + M_PI); const float sv = qSin(v); const float r = (radius + minorRadius * cv); *fptr++ = r * cu; *fptr++ = r * su; *fptr++ = minorRadius * sv; *fptr++ = u / (M_PI * 2); *fptr++ = v / (M_PI * 2); QVector3D n(cv * cu, cv * su, sv); n.normalize(); *fptr++ = n.x(); *fptr++ = n.y(); *fptr++ = n.z(); QVector4D t(-su, cu, 0.0f, 1.0f); t.normalize(); *fptr++ = t.x(); *fptr++ = t.y(); *fptr++ = t.z(); *fptr++ = t.w(); } } return bufferBytes; } QByteArray createTorusIndexData(int requestedRings, int requestedSlices) { const int slices = requestedSlices + 1; int triangles = triangleCount(requestedRings, requestedSlices); int indices = triangles * 3; Q_ASSERT(indices < 65536); QByteArray indexBytes; indexBytes.resize(indices * sizeof(quint16)); quint16* indexPtr = reinterpret_cast(indexBytes.data()); for (int ring = 0; ring < requestedRings; ++ring) { const int ringStart = ring * slices; const int nextRingStart = (ring + 1) * slices; for (int slice = 0; slice < requestedSlices; ++slice) { const int nextSlice = (slice + 1) % slices; *indexPtr++ = ringStart + slice; *indexPtr++ = ringStart + nextSlice; *indexPtr++ = nextRingStart + slice; *indexPtr++ = ringStart + nextSlice; *indexPtr++ = nextRingStart + nextSlice; *indexPtr++ = nextRingStart + slice; } } return indexBytes; } } // anonymous class TorusVertexDataFunctor : public QBufferDataGenerator { public: TorusVertexDataFunctor(int rings, int slices, float radius, float minorRadius) : m_rings(rings) , m_slices(slices) , m_radius(radius) , m_minorRadius(minorRadius) { } QByteArray operator ()() Q_DECL_OVERRIDE { return createTorusVertexData(m_radius, m_minorRadius, m_rings, m_slices); } bool operator ==(const QBufferDataGenerator &other) const Q_DECL_OVERRIDE { const TorusVertexDataFunctor *otherFunctor = functor_cast(&other); if (otherFunctor != nullptr) return (otherFunctor->m_rings == m_rings && otherFunctor->m_slices == m_slices && otherFunctor->m_radius == m_radius && otherFunctor->m_minorRadius == m_minorRadius); return false; } QT3D_FUNCTOR(TorusVertexDataFunctor) private: int m_rings; int m_slices; float m_radius; float m_minorRadius; }; class TorusIndexDataFunctor : public QBufferDataGenerator { public: TorusIndexDataFunctor(int rings, int slices) : m_rings(rings) , m_slices(slices) { } QByteArray operator ()() Q_DECL_OVERRIDE { return createTorusIndexData(m_rings, m_slices); } bool operator ==(const QBufferDataGenerator &other) const Q_DECL_OVERRIDE { const TorusIndexDataFunctor *otherFunctor = functor_cast(&other); if (otherFunctor != nullptr) return (otherFunctor->m_rings == m_rings && otherFunctor->m_slices == m_slices); return false; } QT3D_FUNCTOR(TorusIndexDataFunctor) private: int m_rings; int m_slices; }; QTorusGeometryPrivate::QTorusGeometryPrivate() : QGeometryPrivate() , m_rings(16) , m_slices(16) , m_radius(1.0f) , m_minorRadius(1.0f) , m_positionAttribute(nullptr) , m_normalAttribute(nullptr) , m_texCoordAttribute(nullptr) , m_tangentAttribute(nullptr) , m_indexAttribute(nullptr) , m_vertexBuffer(nullptr) , m_indexBuffer(nullptr) { } void QTorusGeometryPrivate::init() { Q_Q(QTorusGeometry); m_positionAttribute = new QAttribute(q); m_normalAttribute = new QAttribute(q); m_texCoordAttribute = new QAttribute(q); m_tangentAttribute = new QAttribute(q); m_indexAttribute = new QAttribute(q); m_vertexBuffer = new Qt3DRender::QBuffer(Qt3DRender::QBuffer::VertexBuffer, q); m_indexBuffer = new Qt3DRender::QBuffer(Qt3DRender::QBuffer::IndexBuffer, q); // vec3 pos, vec2 tex, vec3 normal, vec4 tangent const quint32 elementSize = 3 + 2 + 3 + 4; const quint32 stride = elementSize * sizeof(float); const int nVerts = vertexCount(m_rings, m_slices); const int triangles = triangleCount(m_rings, m_slices); m_positionAttribute->setName(QAttribute::defaultPositionAttributeName()); m_positionAttribute->setVertexBaseType(QAttribute::Float); m_positionAttribute->setVertexSize(3); m_positionAttribute->setAttributeType(QAttribute::VertexAttribute); m_positionAttribute->setBuffer(m_vertexBuffer); m_positionAttribute->setByteStride(stride); m_positionAttribute->setCount(nVerts); m_texCoordAttribute->setName(QAttribute::defaultTextureCoordinateAttributeName()); m_texCoordAttribute->setVertexBaseType(QAttribute::Float); m_texCoordAttribute->setVertexSize(2); m_texCoordAttribute->setAttributeType(QAttribute::VertexAttribute); m_texCoordAttribute->setBuffer(m_vertexBuffer); m_texCoordAttribute->setByteStride(stride); m_texCoordAttribute->setByteOffset(3 * sizeof(float)); m_texCoordAttribute->setCount(nVerts); m_normalAttribute->setName(QAttribute::defaultNormalAttributeName()); m_normalAttribute->setVertexBaseType(QAttribute::Float); m_normalAttribute->setVertexSize(3); m_normalAttribute->setAttributeType(QAttribute::VertexAttribute); m_normalAttribute->setBuffer(m_vertexBuffer); m_normalAttribute->setByteStride(stride); m_normalAttribute->setByteOffset(5 * sizeof(float)); m_normalAttribute->setCount(nVerts); m_tangentAttribute->setName(QAttribute::defaultTangentAttributeName()); m_tangentAttribute->setVertexBaseType(QAttribute::Float); m_tangentAttribute->setVertexSize(4); m_tangentAttribute->setAttributeType(QAttribute::VertexAttribute); m_tangentAttribute->setBuffer(m_vertexBuffer); m_tangentAttribute->setByteStride(stride); m_tangentAttribute->setByteOffset(8 * sizeof(float)); m_tangentAttribute->setCount(nVerts); m_indexAttribute->setAttributeType(QAttribute::IndexAttribute); m_indexAttribute->setVertexBaseType(QAttribute::UnsignedShort); m_indexAttribute->setBuffer(m_indexBuffer); m_indexAttribute->setCount(triangles * 3); m_vertexBuffer->setDataGenerator(QSharedPointer::create(m_rings, m_slices, m_radius, m_minorRadius)); m_indexBuffer->setDataGenerator(QSharedPointer::create(m_rings, m_slices)); q->addAttribute(m_positionAttribute); q->addAttribute(m_texCoordAttribute); q->addAttribute(m_normalAttribute); q->addAttribute(m_tangentAttribute); q->addAttribute(m_indexAttribute); } /*! * \qmltype TorusGeometry * \instantiates Qt3DExtras::QTorusGeometry * \inqmlmodule Qt3D.Extras * \brief TorusGeometry allows creation of a torus in 3D space. * * The TorusGeometry type is most commonly used internally by the TorusMesh type * but can also be used in custom GeometryRenderer types. */ /*! * \qmlproperty int TorusGeometry::rings * * Holds the number of rings in the torus. */ /*! * \qmlproperty int TorusGeometry::slices * * Holds the number of slices in the torus. */ /*! * \qmlproperty real TorusGeometry::radius * * Holds the outer radius of the torus. */ /*! * \qmlproperty real TorusGeometry::minorRadius * * Holds the inner radius of the torus. */ /*! * \qmlproperty Attribute TorusGeometry::positionAttribute * * Holds the geometry position attribute. */ /*! * \qmlproperty Attribute TorusGeometry::normalAttribute * * Holds the geometry normal attribute. */ /*! * \qmlproperty Attribute TorusGeometry::texCoordAttribute * * Holds the geometry texture coordinate attribute. */ /*! * \qmlproperty Attribute TorusGeometry::indexAttribute * * Holds the geometry index attribute. */ /*! * \class Qt3DExtras::QTorusGeometry * \inheaderfile Qt3DExtras/QTorusGeometry * \inmodule Qt3DExtras * \brief The QTorusGeometry class allows creation of a torus in 3D space. * \since 5.7 * \ingroup geometries * \inherits Qt3DRender::QGeometry * * The QTorusGeometry class is most commonly used internally by the QTorusMesh * but can also be used in custom Qt3DRender::QGeometryRenderer subclasses. */ /*! * Constructs a new QTorusGeometry with \a parent. */ QTorusGeometry::QTorusGeometry(QNode *parent) : QGeometry(*new QTorusGeometryPrivate(), parent) { Q_D(QTorusGeometry); d->init(); } /*! * \internal */ QTorusGeometry::QTorusGeometry(QTorusGeometryPrivate &dd, QNode *parent) : QGeometry(dd, parent) { Q_D(QTorusGeometry); d->init(); } /*! * \internal */ QTorusGeometry::~QTorusGeometry() { } /*! * Updates vertices based on rings, slices, and radius properties. */ void QTorusGeometry::updateVertices() { Q_D(QTorusGeometry); const int nVerts = vertexCount(d->m_rings, d->m_slices); d->m_positionAttribute->setCount(nVerts); d->m_texCoordAttribute->setCount(nVerts); d->m_normalAttribute->setCount(nVerts); d->m_vertexBuffer->setDataGenerator(QSharedPointer::create(d->m_rings, d->m_slices, d->m_radius, d->m_minorRadius)); } /*! * Updates indices based on rings and slices properties. */ void QTorusGeometry::updateIndices() { Q_D(QTorusGeometry); const int triangles = triangleCount(d->m_rings, d->m_slices); d->m_indexAttribute->setCount(triangles * 3); d->m_indexBuffer->setDataGenerator(QSharedPointer::create(d->m_rings, d->m_slices)); } void QTorusGeometry::setRings(int rings) { Q_D(QTorusGeometry); if (rings != d->m_rings) { d->m_rings = rings; updateVertices(); updateIndices(); emit ringsChanged(rings); } } void QTorusGeometry::setSlices(int slices) { Q_D(QTorusGeometry); if (slices != d->m_slices) { d->m_slices = slices; updateVertices(); updateIndices(); emit slicesChanged(slices); } } void QTorusGeometry::setRadius(float radius) { Q_D(QTorusGeometry); if (radius != d->m_radius) { d->m_radius = radius; updateVertices(); emit radiusChanged(radius); } } void QTorusGeometry::setMinorRadius(float minorRadius) { Q_D(QTorusGeometry); if (minorRadius != d->m_minorRadius) { d->m_minorRadius = minorRadius; updateVertices(); emit minorRadiusChanged(minorRadius); } } /*! * \property QTorusGeometry::rings * * Holds the number of rings in the torus. */ int QTorusGeometry::rings() const { Q_D(const QTorusGeometry); return d->m_rings; } /*! * \property QTorusGeometry::slices * * Holds the number of slices in the torus. */ int QTorusGeometry::slices() const { Q_D(const QTorusGeometry); return d->m_slices; } /*! * \property QTorusGeometry::radius * * Holds the outer radius of the torus. */ float QTorusGeometry::radius() const { Q_D(const QTorusGeometry); return d->m_radius; } /*! * \property QTorusGeometry::minorRadius * * Holds the inner radius of the torus. */ float QTorusGeometry::minorRadius() const { Q_D(const QTorusGeometry); return d->m_minorRadius; } /*! * \property QTorusGeometry::positionAttribute * * Holds the geometry position attribute. */ QAttribute *QTorusGeometry::positionAttribute() const { Q_D(const QTorusGeometry); return d->m_positionAttribute; } /*! * \property QTorusGeometry::normalAttribute * * Holds the geometry normal attribute. */ QAttribute *QTorusGeometry::normalAttribute() const { Q_D(const QTorusGeometry); return d->m_normalAttribute; } /*! * \property QTorusGeometry::texCoordAttribute * * Holds the geometry texture coordinate attribute. */ QAttribute *QTorusGeometry::texCoordAttribute() const { Q_D(const QTorusGeometry); return d->m_texCoordAttribute; } /*! * \property QTorusGeometry::indexAttribute * * Holds the geometry index attribute. */ QAttribute *QTorusGeometry::indexAttribute() const { Q_D(const QTorusGeometry); return d->m_indexAttribute; } } // Qt3DExtras QT_END_NAMESPACE