/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the QtQuick 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 #include #include #if QT_CONFIG(opengl) #include #endif #include QT_BEGIN_NAMESPACE /*! \qmltype ShaderEffect \instantiates QQuickShaderEffect \inqmlmodule QtQuick \inherits Item \ingroup qtquick-effects \brief Applies custom shaders to a rectangle. The ShaderEffect type applies a custom \l{vertexShader}{vertex} and \l{fragmentShader}{fragment (pixel)} shader to a rectangle. It allows you to write effects such as drop shadow, blur, colorize and page curl directly in QML. \note Depending on the Qt Quick scenegraph backend in use, the ShaderEffect type may not be supported (for example, with the software backend), or may use a different shading language with rules and expectations different from OpenGL and GLSL. \section1 OpenGL and GLSL There are two types of input to the \l vertexShader: uniform variables and attributes. Some are predefined: \list \li uniform mat4 qt_Matrix - combined transformation matrix, the product of the matrices from the root item to this ShaderEffect, and an orthogonal projection. \li uniform float qt_Opacity - combined opacity, the product of the opacities from the root item to this ShaderEffect. \li attribute vec4 qt_Vertex - vertex position, the top-left vertex has position (0, 0), the bottom-right (\l{Item::width}{width}, \l{Item::height}{height}). \li attribute vec2 qt_MultiTexCoord0 - texture coordinate, the top-left coordinate is (0, 0), the bottom-right (1, 1). If \l supportsAtlasTextures is true, coordinates will be based on position in the atlas instead. \endlist In addition, any property that can be mapped to an OpenGL Shading Language (GLSL) type is available as a uniform variable. The following list shows how properties are mapped to GLSL uniform variables: \list \li bool, int, qreal -> bool, int, float - If the type in the shader is not the same as in QML, the value is converted automatically. \li QColor -> vec4 - When colors are passed to the shader, they are first premultiplied. Thus Qt.rgba(0.2, 0.6, 1.0, 0.5) becomes vec4(0.1, 0.3, 0.5, 0.5) in the shader, for example. \li QRect, QRectF -> vec4 - Qt.rect(x, y, w, h) becomes vec4(x, y, w, h) in the shader. \li QPoint, QPointF, QSize, QSizeF -> vec2 \li QVector3D -> vec3 \li QVector4D -> vec4 \li QTransform -> mat3 \li QMatrix4x4 -> mat4 \li QQuaternion -> vec4, scalar value is \c w. \li \l Image -> sampler2D - Origin is in the top-left corner, and the color values are premultiplied. The texture is provided as is, excluding the Image item's fillMode. To include fillMode, use a ShaderEffectSource or Image::layer::enabled. \li \l ShaderEffectSource -> sampler2D - Origin is in the top-left corner, and the color values are premultiplied. \endlist The QML scene graph back-end may choose to allocate textures in texture atlases. If a texture allocated in an atlas is passed to a ShaderEffect, it is by default copied from the texture atlas into a stand-alone texture so that the texture coordinates span from 0 to 1, and you get the expected wrap modes. However, this will increase the memory usage. To avoid the texture copy, set \l supportsAtlasTextures for simple shaders using qt_MultiTexCoord0, or for each "uniform sampler2D " declare a "uniform vec4 qt_SubRect_" which will be assigned the texture's normalized source rectangle. For stand-alone textures, the source rectangle is [0, 1]x[0, 1]. For textures in an atlas, the source rectangle corresponds to the part of the texture atlas where the texture is stored. The correct way to calculate the texture coordinate for a texture called "source" within a texture atlas is "qt_SubRect_source.xy + qt_SubRect_source.zw * qt_MultiTexCoord0". The output from the \l fragmentShader should be premultiplied. If \l blending is enabled, source-over blending is used. However, additive blending can be achieved by outputting zero in the alpha channel. \table 70% \row \li \image declarative-shadereffectitem.png \li \qml import QtQuick 2.0 Rectangle { width: 200; height: 100 Row { Image { id: img; sourceSize { width: 100; height: 100 } source: "qt-logo.png" } ShaderEffect { width: 100; height: 100 property variant src: img vertexShader: " uniform highp mat4 qt_Matrix; attribute highp vec4 qt_Vertex; attribute highp vec2 qt_MultiTexCoord0; varying highp vec2 coord; void main() { coord = qt_MultiTexCoord0; gl_Position = qt_Matrix * qt_Vertex; }" fragmentShader: " varying highp vec2 coord; uniform sampler2D src; uniform lowp float qt_Opacity; void main() { lowp vec4 tex = texture2D(src, coord); gl_FragColor = vec4(vec3(dot(tex.rgb, vec3(0.344, 0.5, 0.156))), tex.a) * qt_Opacity; }" } } } \endqml \endtable \note Scene Graph textures have origin in the top-left corner rather than bottom-left which is common in OpenGL. For information about the GLSL version being used, see \l QtQuick::GraphicsInfo. Starting from Qt 5.8 ShaderEffect also supports reading the GLSL source code from files. Whenever the fragmentShader or vertexShader property value is a URL with the \c file or \c qrc schema, it is treated as a file reference and the source code is read from the specified file. \section1 Direct3D and HLSL Direct3D backends provide ShaderEffect support with HLSL. The Direct3D 12 backend requires using at least Shader Model 5.0 both for vertex and pixel shaders. When necessary, GraphicsInfo.shaderType can be used to decide at runtime what kind of value to assign to \l fragmentShader or \l vertexShader. All concepts described above for OpenGL and GLSL apply to Direct3D and HLSL as well. There are however a number of notable practical differences, which are the following: Instead of uniforms, HLSL shaders are expected to use a single constant buffer, assigned to register \c b0. The special names \c qt_Matrix, \c qt_Opacity, and \c qt_SubRect_ function the same way as with GLSL. All other members of the buffer are expected to map to properties in the ShaderEffect item. \note The buffer layout must be compatible for both shaders. This means that application-provided shaders must make sure \c qt_Matrix and \c qt_Opacity are included in the buffer, starting at offset 0, when custom code is provided for one type of shader only, leading to ShaderEffect providing the other shader. This is due to ShaderEffect's built-in shader code declaring a constant buffer containing \c{float4x4 qt_Matrix; float qt_Opacity;}. Unlike GLSL's attributes, no names are used for vertex input elements. Therefore qt_Vertex and qt_MultiTexCoord0 are not relevant. Instead, the standard Direct3D semantics, \c POSITION and \c TEXCOORD (or \c TEXCOORD0) are used for identifying the correct input layout. Unlike GLSL's samplers, texture and sampler objects are separate in HLSL. Shaders are expected to expect 2D, non-array, non-multisample textures. Both the texture and sampler binding points are expected to be sequential and start from 0 (meaning registers \c{t0, t1, ...}, and \c{s0, s1, ...}, respectively). Unlike with OpenGL, samplers are not mapped to Qt Quick item properties and therefore the name of the sampler is not relevant. Instead, it is the textures that map to properties referencing \l Image or \l ShaderEffectSource items. Unlike OpenGL, backends for modern APIs will typically prefer offline compilation and shipping pre-compiled bytecode with applications instead of inlined shader source strings. In this case the string properties for vertex and fragment shaders are treated as URLs referring to local files or files shipped via the Qt resource system. To check at runtime what is supported, use the GraphicsInfo.shaderSourceType and GraphicsInfo.shaderCompilationType properties. Note that these are bitmasks, because some backends may support multiple approaches. In case of Direct3D 12, all combinations are supported. If the vertexShader and fragmentShader properties form a valid URL with the \c file or \c qrc schema, the bytecode or HLSL source code is read from the specified file. The type of the file contents is detected automatically. Otherwise, the string is treated as HLSL source code and is compiled at runtime, assuming Shader Model 5.0 and an entry point of \c{"main"}. This allows dynamically constructing shader strings. However, whenever the shader source code is static, it is strongly recommended to pre-compile to bytecode using the \c fxc tool and refer to these files from QML. This will be a lot more efficient at runtime and allows catching syntax errors in the shaders at compile time. Unlike OpenGL, the Direct3D backend is able to perform runtime shader compilation on dedicated threads. This is managed transparently to the applications, and means that ShaderEffect items that contain HLSL source strings do not block the rendering or other parts of the application until the bytecode is ready. Using files with bytecode is more flexible also when it comes to the entry point name (it can be anything, not limited to \c main) and the shader model (it can be something newer than 5.0, for instance 5.1). \table 70% \row \li \qml import QtQuick 2.0 Rectangle { width: 200; height: 100 Row { Image { id: img; sourceSize { width: 100; height: 100 } source: "qt-logo.png" } ShaderEffect { width: 100; height: 100 property variant src: img fragmentShader: "qrc:/effect_ps.cso" } } } \endqml \row \li where \c effect_ps.cso is the compiled bytecode for the following HLSL shader: \code cbuffer ConstantBuffer : register(b0) { float4x4 qt_Matrix; float qt_Opacity; }; Texture2D src : register(t0); SamplerState srcSampler : register(s0); float4 ExamplePixelShader(float4 position : SV_POSITION, float2 coord : TEXCOORD0) : SV_TARGET { float4 tex = src.Sample(srcSampler, coord); float3 col = dot(tex.rgb, float3(0.344, 0.5, 0.156)); return float4(col, tex.a) * qt_Opacity; } \endcode \endtable The above is equivalent to the OpenGL example presented earlier. The vertex shader is provided implicitly by ShaderEffect. Note that the output of the pixel shader is using premultiplied alpha and that \c qt_Matrix is present in the constant buffer at offset 0, even though the pixel shader does not use the value. If desired, the HLSL source code can be placed directly into the QML source, similarly to how its done with GLSL. The only difference in this case is the entry point name, which must be \c main when using inline source strings. Alternatively, we could also have referred to a file containing the source of the effect instead of the compiled bytecode version. Some effects will want to provide a vertex shader as well. Below is a similar effect with both the vertex and fragment shader provided by the application. This time the colorization factor is provided by the QML item instead of hardcoding it in the shader. This can allow, among others, animating the value using QML's and Qt Quick's standard facilities. \table 70% \row \li \qml import QtQuick 2.0 Rectangle { width: 200; height: 100 Row { Image { id: img; sourceSize { width: 100; height: 100 } source: "qt-logo.png" } ShaderEffect { width: 100; height: 100 property variant src: img property variant color: Qt.vector3d(0.344, 0.5, 0.156) vertexShader: "qrc:/effect_vs.cso" fragmentShader: "qrc:/effect_ps.cso" } } } \endqml \row \li where \c effect_vs.cso and \c effect_ps.cso are the compiled bytecode for \c ExampleVertexShader and \c ExamplePixelShader. The source code is presented as one snippet here, the shaders can however be placed in separate source files as well. \code cbuffer ConstantBuffer : register(b0) { float4x4 qt_Matrix; float qt_Opacity; float3 color; }; Texture2D src : register(t0); SamplerState srcSampler : register(s0); struct PSInput { float4 position : SV_POSITION; float2 coord : TEXCOORD0; }; PSInput ExampleVertexShader(float4 position : POSITION, float2 coord : TEXCOORD0) { PSInput result; result.position = mul(qt_Matrix, position); result.coord = coord; return result; } float4 ExamplePixelShader(PSInput input) : SV_TARGET { float4 tex = src.Sample(srcSampler, coord); float3 col = dot(tex.rgb, color); return float4(col, tex.a) * qt_Opacity; } \endcode \endtable \note With OpenGL the \c y coordinate runs from bottom to top whereas with Direct 3D it goes top to bottom. For shader effect sources Qt Quick hides the difference by treating QtQuick::ShaderEffectSource::textureMirroring as appropriate, meaning texture coordinates in HLSL version of the shaders will not need any adjustments compared to the equivalent GLSL code. \section1 Cross-platform, Cross-API ShaderEffect Items Some applications will want to be functional with multiple accelerated graphics backends. This has consequences for ShaderEffect items because the supported shading languages may vary from backend to backend. There are two approaches to handle this: either write conditional property values based on GraphicsInfo.shaderType, or use file selectors. In practice the latter is strongly recommended as it leads to more concise and cleaner application code. The only case it is not suitable is when the source strings are constructed dynamically. \table 70% \row \li \qml import QtQuick 2.8 // for GraphicsInfo Rectangle { width: 200; height: 100 Row { Image { id: img; sourceSize { width: 100; height: 100 } source: "qt-logo.png" } ShaderEffect { width: 100; height: 100 property variant src: img property variant color: Qt.vector3d(0.344, 0.5, 0.156) fragmentShader: GraphicsInfo.shaderType === GraphicsInfo.GLSL ? "varying highp vec2 coord; uniform sampler2D src; uniform lowp float qt_Opacity; void main() { lowp vec4 tex = texture2D(src, coord); gl_FragColor = vec4(vec3(dot(tex.rgb, vec3(0.344, 0.5, 0.156))), tex.a) * qt_Opacity;" : GraphicsInfo.shaderType === GraphicsInfo.HLSL ? "cbuffer ConstantBuffer : register(b0) { float4x4 qt_Matrix; float qt_Opacity; }; Texture2D src : register(t0); SamplerState srcSampler : register(s0); float4 ExamplePixelShader(float4 position : SV_POSITION, float2 coord : TEXCOORD0) : SV_TARGET { float4 tex = src.Sample(srcSampler, coord); float3 col = dot(tex.rgb, float3(0.344, 0.5, 0.156)); return float4(col, tex.a) * qt_Opacity; }" : "" } } } \endqml \row \li This is the first approach based on GraphicsInfo. Note that the value reported by GraphicsInfo is not up-to-date until the ShaderEffect item gets associated with a QQuickWindow. Before that, the reported value is GraphicsInfo.UnknownShadingLanguage. The alternative is to place the GLSL source code and the compiled D3D bytecode into the files \c{shaders/effect.frag} and \c{shaders/+hlsl/effect.frag}, include them in the Qt resource system, and let the ShaderEffect's internal QFileSelector do its job. The selector-less version is the GLSL source, while the \c hlsl selector is used when running on the D3D12 backend. The file under \c{+hlsl} can then contain either HLSL source code or compiled bytecode from the \c fxc tool. Additionally, when using a version 3.2 or newer core profile context with OpenGL, GLSL sources with a core profile compatible syntax can be placed under \c{+glslcore}. \qml import QtQuick 2.8 // for GraphicsInfo Rectangle { width: 200; height: 100 Row { Image { id: img; sourceSize { width: 100; height: 100 } source: "qt-logo.png" } ShaderEffect { width: 100; height: 100 property variant src: img property variant color: Qt.vector3d(0.344, 0.5, 0.156) fragmentShader: "qrc:shaders/effect.frag" // selects the correct variant automatically } } } \endqml \endtable \section1 ShaderEffect and Item Layers The ShaderEffect type can be combined with \l {Item Layers} {layered items}. \table \row \li \b {Layer with effect disabled} \inlineimage qml-shadereffect-nolayereffect.png \li \b {Layer with effect enabled} \inlineimage qml-shadereffect-layereffect.png \row \li \snippet qml/layerwitheffect.qml 1 \endtable It is also possible to combine multiple layered items: \table \row \li \inlineimage qml-shadereffect-opacitymask.png \row \li \snippet qml/opacitymask.qml 1 \endtable \section1 Other Notes By default, the ShaderEffect consists of four vertices, one for each corner. For non-linear vertex transformations, like page curl, you can specify a fine grid of vertices by specifying a \l mesh resolution. The \l {Qt Graphical Effects} module contains several ready-made effects for using with Qt Quick applications. \sa {Item Layers} */ class QQuickShaderEffectPrivate : public QQuickItemPrivate { Q_DECLARE_PUBLIC(QQuickShaderEffect) public: void updatePolish() override; }; QSGContextFactoryInterface::Flags qsg_backend_flags(); QQuickShaderEffect::QQuickShaderEffect(QQuickItem *parent) : QQuickItem(*new QQuickShaderEffectPrivate, parent), #if QT_CONFIG(opengl) m_glImpl(nullptr), #endif m_impl(nullptr) { setFlag(QQuickItem::ItemHasContents); #if QT_CONFIG(opengl) if (!qsg_backend_flags().testFlag(QSGContextFactoryInterface::SupportsShaderEffectNode)) m_glImpl = new QQuickOpenGLShaderEffect(this, this); if (!m_glImpl) #endif m_impl = new QQuickGenericShaderEffect(this, this); } /*! \qmlproperty string QtQuick::ShaderEffect::fragmentShader This property holds the fragment (pixel) shader's source code or a reference to the pre-compiled bytecode. Some APIs, like OpenGL, always support runtime compilation and therefore the traditional Qt Quick way of inlining shader source strings is functional. Qt Quick backends for other APIs may however limit support to pre-compiled bytecode like SPIR-V or D3D shader bytecode. There the string is simply a filename, which may be a file in the filesystem or bundled with the executable via Qt's resource system. With GLSL the default shader expects the texture coordinate to be passed from the vertex shader as \c{varying highp vec2 qt_TexCoord0}, and it samples from a sampler2D named \c source. With HLSL the texture is named \c source, while the vertex shader is expected to provide \c{float2 coord : TEXCOORD0} in its output in addition to \c{float4 position : SV_POSITION} (names can differ since linking is done based on the semantics). \sa vertexShader, GraphicsInfo */ QByteArray QQuickShaderEffect::fragmentShader() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->fragmentShader(); #endif return m_impl->fragmentShader(); } void QQuickShaderEffect::setFragmentShader(const QByteArray &code) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setFragmentShader(code); return; } #endif m_impl->setFragmentShader(code); } /*! \qmlproperty string QtQuick::ShaderEffect::vertexShader This property holds the vertex shader's source code or a reference to the pre-compiled bytecode. Some APIs, like OpenGL, always support runtime compilation and therefore the traditional Qt Quick way of inlining shader source strings is functional. Qt Quick backends for other APIs may however limit support to pre-compiled bytecode like SPIR-V or D3D shader bytecode. There the string is simply a filename, which may be a file in the filesystem or bundled with the executable via Qt's resource system. With GLSL the default shader passes the texture coordinate along to the fragment shader as \c{varying highp vec2 qt_TexCoord0}. With HLSL it is enough to use the standard \c TEXCOORD0 semantic, for example \c{float2 coord : TEXCOORD0}. \sa fragmentShader, GraphicsInfo */ QByteArray QQuickShaderEffect::vertexShader() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->vertexShader(); #endif return m_impl->vertexShader(); } void QQuickShaderEffect::setVertexShader(const QByteArray &code) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setVertexShader(code); return; } #endif m_impl->setVertexShader(code); } /*! \qmlproperty bool QtQuick::ShaderEffect::blending If this property is true, the output from the \l fragmentShader is blended with the background using source-over blend mode. If false, the background is disregarded. Blending decreases the performance, so you should set this property to false when blending is not needed. The default value is true. */ bool QQuickShaderEffect::blending() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->blending(); #endif return m_impl->blending(); } void QQuickShaderEffect::setBlending(bool enable) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setBlending(enable); return; } #endif m_impl->setBlending(enable); } /*! \qmlproperty variant QtQuick::ShaderEffect::mesh This property defines the mesh used to draw the ShaderEffect. It can hold any \l GridMesh object. If a size value is assigned to this property, the ShaderEffect implicitly uses a \l GridMesh with the value as \l{GridMesh::resolution}{mesh resolution}. By default, this property is the size 1x1. \sa GridMesh */ QVariant QQuickShaderEffect::mesh() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->mesh(); #endif return m_impl->mesh(); } void QQuickShaderEffect::setMesh(const QVariant &mesh) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setMesh(mesh); return; } #endif m_impl->setMesh(mesh); } /*! \qmlproperty enumeration QtQuick::ShaderEffect::cullMode This property defines which sides of the item should be visible. \list \li ShaderEffect.NoCulling - Both sides are visible \li ShaderEffect.BackFaceCulling - only front side is visible \li ShaderEffect.FrontFaceCulling - only back side is visible \endlist The default is NoCulling. */ QQuickShaderEffect::CullMode QQuickShaderEffect::cullMode() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->cullMode(); #endif return m_impl->cullMode(); } void QQuickShaderEffect::setCullMode(CullMode face) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setCullMode(face); return; } #endif return m_impl->setCullMode(face); } /*! \qmlproperty bool QtQuick::ShaderEffect::supportsAtlasTextures Set this property true to confirm that your shader code doesn't rely on qt_MultiTexCoord0 ranging from (0,0) to (1,1) relative to the mesh. In this case the range of qt_MultiTexCoord0 will rather be based on the position of the texture within the atlas. This property currently has no effect if there is less, or more, than one sampler uniform used as input to your shader. This differs from providing qt_SubRect_ uniforms in that the latter allows drawing one or more textures from the atlas in a single ShaderEffect item, while supportsAtlasTextures allows multiple instances of a ShaderEffect component using a different source image from the atlas to be batched in a single draw. Both prevent a texture from being copied out of the atlas when referenced by a ShaderEffect. The default value is false. \since 5.4 \since QtQuick 2.4 */ bool QQuickShaderEffect::supportsAtlasTextures() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->supportsAtlasTextures(); #endif return m_impl->supportsAtlasTextures(); } void QQuickShaderEffect::setSupportsAtlasTextures(bool supports) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->setSupportsAtlasTextures(supports); return; } #endif m_impl->setSupportsAtlasTextures(supports); } /*! \qmlproperty enumeration QtQuick::ShaderEffect::status This property tells the current status of the OpenGL shader program. \list \li ShaderEffect.Compiled - the shader program was successfully compiled and linked. \li ShaderEffect.Uncompiled - the shader program has not yet been compiled. \li ShaderEffect.Error - the shader program failed to compile or link. \endlist When setting the fragment or vertex shader source code, the status will become Uncompiled. The first time the ShaderEffect is rendered with new shader source code, the shaders are compiled and linked, and the status is updated to Compiled or Error. When runtime compilation is not in use and the shader properties refer to files with bytecode, the status is always Compiled. The contents of the shader is not examined (apart from basic reflection to discover vertex input elements and constant buffer data) until later in the rendering pipeline so potential errors (like layout or root signature mismatches) will only be detected at a later point. \sa log */ /*! \qmlproperty string QtQuick::ShaderEffect::log This property holds a log of warnings and errors from the latest attempt at compiling and linking the OpenGL shader program. It is updated at the same time \l status is set to Compiled or Error. \sa status */ QString QQuickShaderEffect::log() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->log(); #endif return m_impl->log(); } QQuickShaderEffect::Status QQuickShaderEffect::status() const { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->status(); #endif return m_impl->status(); } bool QQuickShaderEffect::event(QEvent *e) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->handleEvent(e); return QQuickItem::event(e); } #endif if (m_impl) m_impl->handleEvent(e); return QQuickItem::event(e); } void QQuickShaderEffect::geometryChanged(const QRectF &newGeometry, const QRectF &oldGeometry) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->handleGeometryChanged(newGeometry, oldGeometry); QQuickItem::geometryChanged(newGeometry, oldGeometry); return; } #endif m_impl->handleGeometryChanged(newGeometry, oldGeometry); QQuickItem::geometryChanged(newGeometry, oldGeometry); } QSGNode *QQuickShaderEffect::updatePaintNode(QSGNode *oldNode, UpdatePaintNodeData *updatePaintNodeData) { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->handleUpdatePaintNode(oldNode, updatePaintNodeData); #endif return m_impl->handleUpdatePaintNode(oldNode, updatePaintNodeData); } void QQuickShaderEffect::componentComplete() { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->maybeUpdateShaders(); QQuickItem::componentComplete(); return; } #endif m_impl->maybeUpdateShaders(); QQuickItem::componentComplete(); } void QQuickShaderEffect::itemChange(ItemChange change, const ItemChangeData &value) { #if QT_CONFIG(opengl) if (m_glImpl) { m_glImpl->handleItemChange(change, value); QQuickItem::itemChange(change, value); return; } #endif m_impl->handleItemChange(change, value); QQuickItem::itemChange(change, value); } bool QQuickShaderEffect::isComponentComplete() const { return QQuickItem::isComponentComplete(); } QString QQuickShaderEffect::parseLog() // for OpenGL-based autotests { #if QT_CONFIG(opengl) if (m_glImpl) return m_glImpl->parseLog(); #endif return m_impl->parseLog(); } void QQuickShaderEffectPrivate::updatePolish() { Q_Q(QQuickShaderEffect); #if QT_CONFIG(opengl) if (q->m_glImpl) { q->m_glImpl->maybeUpdateShaders(); return; } #endif q->m_impl->maybeUpdateShaders(); } #if QT_CONFIG(opengl) bool QQuickShaderEffect::isOpenGLShaderEffect() const { return m_glImpl != nullptr; } #endif QT_END_NAMESPACE #include "moc_qquickshadereffect_p.cpp"