/* SPDX-FileCopyrightText: 2010 Fredrik Höglund SPDX-FileCopyrightText: 2011 Philipp Knechtges SPDX-FileCopyrightText: 2018 Alex Nemeth SPDX-License-Identifier: GPL-2.0-or-later */ #include "blur.h" #include "blurshader.h" // KConfigSkeleton #include "blurconfig.h" #include #include #include // for QGuiApplication #include #include #include // for ceil() #include #include #include #include #include #include namespace KWin { static const QByteArray s_blurAtomName = QByteArrayLiteral("_KDE_NET_WM_BLUR_BEHIND_REGION"); BlurEffect::BlurEffect() { initConfig(); m_shader = new BlurShader(this); initBlurStrengthValues(); reconfigure(ReconfigureAll); // ### Hackish way to announce support. // Should be included in _NET_SUPPORTED instead. if (m_shader && m_shader->isValid() && m_renderTargetsValid) { net_wm_blur_region = effects->announceSupportProperty(s_blurAtomName, this); KWaylandServer::Display *display = effects->waylandDisplay(); if (display) { m_blurManager = display->createBlurManager(this); } } else { net_wm_blur_region = 0; } connect(effects, &EffectsHandler::windowAdded, this, &BlurEffect::slotWindowAdded); connect(effects, &EffectsHandler::windowDeleted, this, &BlurEffect::slotWindowDeleted); connect(effects, &EffectsHandler::propertyNotify, this, &BlurEffect::slotPropertyNotify); connect(effects, &EffectsHandler::screenGeometryChanged, this, &BlurEffect::slotScreenGeometryChanged); connect(effects, &EffectsHandler::xcbConnectionChanged, this, [this] { if (m_shader && m_shader->isValid() && m_renderTargetsValid) { net_wm_blur_region = effects->announceSupportProperty(s_blurAtomName, this); } } ); // Fetch the blur regions for all windows foreach (EffectWindow *window, effects->stackingOrder()) updateBlurRegion(window); } BlurEffect::~BlurEffect() { deleteFBOs(); } void BlurEffect::slotScreenGeometryChanged() { effects->makeOpenGLContextCurrent(); updateTexture(); // Fetch the blur regions for all windows foreach (EffectWindow *window, effects->stackingOrder()) updateBlurRegion(window); effects->doneOpenGLContextCurrent(); } bool BlurEffect::renderTargetsValid() const { return !m_renderTargets.isEmpty() && std::find_if(m_renderTargets.cbegin(), m_renderTargets.cend(), [](const GLRenderTarget *target) { return !target->valid(); }) == m_renderTargets.cend(); } void BlurEffect::deleteFBOs() { qDeleteAll(m_renderTargets); m_renderTargets.clear(); m_renderTextures.clear(); } void BlurEffect::updateTexture() { deleteFBOs(); /* Reserve memory for: * - The original sized texture (1) * - The downsized textures (m_downSampleIterations) * - The helper texture (1) */ m_renderTargets.reserve(m_downSampleIterations + 2); m_renderTextures.reserve(m_downSampleIterations + 2); GLenum textureFormat = GL_RGBA8; // Check the color encoding of the default framebuffer if (!GLPlatform::instance()->isGLES()) { GLuint prevFbo = 0; glGetIntegerv(GL_DRAW_FRAMEBUFFER_BINDING, reinterpret_cast(&prevFbo)); if (prevFbo != 0) { glBindFramebuffer(GL_DRAW_FRAMEBUFFER, 0); } GLenum colorEncoding = GL_LINEAR; glGetFramebufferAttachmentParameteriv(GL_DRAW_FRAMEBUFFER, GL_BACK_LEFT, GL_FRAMEBUFFER_ATTACHMENT_COLOR_ENCODING, reinterpret_cast(&colorEncoding)); if (prevFbo != 0) { glBindFramebuffer(GL_DRAW_FRAMEBUFFER, prevFbo); } if (colorEncoding == GL_SRGB) { textureFormat = GL_SRGB8_ALPHA8; } } for (int i = 0; i <= m_downSampleIterations; i++) { m_renderTextures.append(GLTexture(textureFormat, effects->virtualScreenSize() / (1 << i))); m_renderTextures.last().setFilter(GL_LINEAR); m_renderTextures.last().setWrapMode(GL_CLAMP_TO_EDGE); m_renderTargets.append(new GLRenderTarget(m_renderTextures.last())); } // This last set is used as a temporary helper texture m_renderTextures.append(GLTexture(textureFormat, effects->virtualScreenSize())); m_renderTextures.last().setFilter(GL_LINEAR); m_renderTextures.last().setWrapMode(GL_CLAMP_TO_EDGE); m_renderTargets.append(new GLRenderTarget(m_renderTextures.last())); m_renderTargetsValid = renderTargetsValid(); // Prepare the stack for the rendering m_renderTargetStack.clear(); m_renderTargetStack.reserve(m_downSampleIterations * 2); // Upsample for (int i = 1; i < m_downSampleIterations; i++) { m_renderTargetStack.push(m_renderTargets[i]); } // Downsample for (int i = m_downSampleIterations; i > 0; i--) { m_renderTargetStack.push(m_renderTargets[i]); } // Copysample m_renderTargetStack.push(m_renderTargets[0]); // Generate the noise helper texture generateNoiseTexture(); } void BlurEffect::initBlurStrengthValues() { // This function creates an array of blur strength values that are evenly distributed // The range of the slider on the blur settings UI int numOfBlurSteps = 15; int remainingSteps = numOfBlurSteps; /* * Explanation for these numbers: * * The texture blur amount depends on the downsampling iterations and the offset value. * By changing the offset we can alter the blur amount without relying on further downsampling. * But there is a minimum and maximum value of offset per downsample iteration before we * get artifacts. * * The minOffset variable is the minimum offset value for an iteration before we * get blocky artifacts because of the downsampling. * * The maxOffset value is the maximum offset value for an iteration before we * get diagonal line artifacts because of the nature of the dual kawase blur algorithm. * * The expandSize value is the minimum value for an iteration before we reach the end * of a texture in the shader and sample outside of the area that was copied into the * texture from the screen. */ // {minOffset, maxOffset, expandSize} blurOffsets.append({1.0, 2.0, 10}); // Down sample size / 2 blurOffsets.append({2.0, 3.0, 20}); // Down sample size / 4 blurOffsets.append({2.0, 5.0, 50}); // Down sample size / 8 blurOffsets.append({3.0, 8.0, 150}); // Down sample size / 16 //blurOffsets.append({5.0, 10.0, 400}); // Down sample size / 32 //blurOffsets.append({7.0, ?.0}); // Down sample size / 64 float offsetSum = 0; for (int i = 0; i < blurOffsets.size(); i++) { offsetSum += blurOffsets[i].maxOffset - blurOffsets[i].minOffset; } for (int i = 0; i < blurOffsets.size(); i++) { int iterationNumber = std::ceil((blurOffsets[i].maxOffset - blurOffsets[i].minOffset) / offsetSum * numOfBlurSteps); remainingSteps -= iterationNumber; if (remainingSteps < 0) { iterationNumber += remainingSteps; } float offsetDifference = blurOffsets[i].maxOffset - blurOffsets[i].minOffset; for (int j = 1; j <= iterationNumber; j++) { // {iteration, offset} blurStrengthValues.append({i + 1, blurOffsets[i].minOffset + (offsetDifference / iterationNumber) * j}); } } } void BlurEffect::reconfigure(ReconfigureFlags flags) { Q_UNUSED(flags) BlurConfig::self()->read(); int blurStrength = BlurConfig::blurStrength() - 1; m_downSampleIterations = blurStrengthValues[blurStrength].iteration; m_offset = blurStrengthValues[blurStrength].offset; m_expandSize = blurOffsets[m_downSampleIterations - 1].expandSize; m_noiseStrength = BlurConfig::noiseStrength(); m_scalingFactor = qMax(1.0, QGuiApplication::primaryScreen()->logicalDotsPerInch() / 96.0); updateTexture(); if (!m_shader || !m_shader->isValid()) { effects->removeSupportProperty(s_blurAtomName, this); delete m_blurManager; m_blurManager = nullptr; } // Update all windows for the blur to take effect effects->addRepaintFull(); } void BlurEffect::updateBlurRegion(EffectWindow *w) const { QRegion region; QByteArray value; if (net_wm_blur_region != XCB_ATOM_NONE) { value = w->readProperty(net_wm_blur_region, XCB_ATOM_CARDINAL, 32); if (value.size() > 0 && !(value.size() % (4 * sizeof(uint32_t)))) { const uint32_t *cardinals = reinterpret_cast(value.constData()); for (unsigned int i = 0; i < value.size() / sizeof(uint32_t);) { int x = cardinals[i++]; int y = cardinals[i++]; int w = cardinals[i++]; int h = cardinals[i++]; region += QRect(x, y, w, h); } } } KWaylandServer::SurfaceInterface *surf = w->surface(); if (surf && surf->blur()) { region = surf->blur()->region(); } if (auto internal = w->internalWindow()) { const auto property = internal->property("kwin_blur"); if (property.isValid()) { region = property.value(); } } //!value.isNull() full window in X11 case, surf->blur() //valid, full window in wayland case if (region.isEmpty() && (!value.isNull() || (surf && surf->blur()))) { // Set the data to a dummy value. // This is needed to be able to distinguish between the value not // being set, and being set to an empty region. w->setData(WindowBlurBehindRole, 1); } else w->setData(WindowBlurBehindRole, region); } void BlurEffect::slotWindowAdded(EffectWindow *w) { KWaylandServer::SurfaceInterface *surf = w->surface(); if (surf) { windowBlurChangedConnections[w] = connect(surf, &KWaylandServer::SurfaceInterface::blurChanged, this, [this, w] () { if (w) { updateBlurRegion(w); } }); } if (auto internal = w->internalWindow()) { internal->installEventFilter(this); } updateBlurRegion(w); } void BlurEffect::slotWindowDeleted(EffectWindow *w) { auto it = windowBlurChangedConnections.find(w); if (it == windowBlurChangedConnections.end()) { return; } disconnect(*it); windowBlurChangedConnections.erase(it); } void BlurEffect::slotPropertyNotify(EffectWindow *w, long atom) { if (w && atom == net_wm_blur_region && net_wm_blur_region != XCB_ATOM_NONE) { updateBlurRegion(w); } } bool BlurEffect::eventFilter(QObject *watched, QEvent *event) { auto internal = qobject_cast(watched); if (internal && event->type() == QEvent::DynamicPropertyChange) { QDynamicPropertyChangeEvent *pe = static_cast(event); if (pe->propertyName() == "kwin_blur") { if (auto w = effects->findWindow(internal)) { updateBlurRegion(w); } } } return false; } bool BlurEffect::enabledByDefault() { GLPlatform *gl = GLPlatform::instance(); if (gl->isIntel() && gl->chipClass() < SandyBridge) return false; if (gl->isSoftwareEmulation()) { return false; } return true; } bool BlurEffect::supported() { bool supported = effects->isOpenGLCompositing() && GLRenderTarget::supported() && GLRenderTarget::blitSupported(); if (supported) { int maxTexSize; glGetIntegerv(GL_MAX_TEXTURE_SIZE, &maxTexSize); const QSize screenSize = effects->virtualScreenSize(); if (screenSize.width() > maxTexSize || screenSize.height() > maxTexSize) supported = false; } return supported; } QRect BlurEffect::expand(const QRect &rect) const { return rect.adjusted(-m_expandSize, -m_expandSize, m_expandSize, m_expandSize); } QRegion BlurEffect::expand(const QRegion ®ion) const { QRegion expanded; for (const QRect &rect : region) { expanded += expand(rect); } return expanded; } QRegion BlurEffect::blurRegion(const EffectWindow *w) const { QRegion region; const QVariant value = w->data(WindowBlurBehindRole); if (value.isValid()) { const QRegion appRegion = qvariant_cast(value); if (!appRegion.isEmpty()) { if (w->decorationHasAlpha() && effects->decorationSupportsBlurBehind()) { region = w->shape() & w->rect(); region -= w->decorationInnerRect(); } region |= appRegion.translated(w->contentsRect().topLeft()) & w->decorationInnerRect(); } else { // An empty region means that the blur effect should be enabled // for the whole window. region = w->shape() & w->rect(); } } else if (w->decorationHasAlpha() && effects->decorationSupportsBlurBehind()) { // If the client hasn't specified a blur region, we'll only enable // the effect behind the decoration. region = w->shape() & w->rect(); region -= w->decorationInnerRect(); } return region; } void BlurEffect::uploadRegion(QVector2D *&map, const QRegion ®ion, const int downSampleIterations) { for (int i = 0; i <= downSampleIterations; i++) { const int divisionRatio = (1 << i); for (const QRect &r : region) { const QVector2D topLeft( r.x() / divisionRatio, r.y() / divisionRatio); const QVector2D topRight( (r.x() + r.width()) / divisionRatio, r.y() / divisionRatio); const QVector2D bottomLeft( r.x() / divisionRatio, (r.y() + r.height()) / divisionRatio); const QVector2D bottomRight((r.x() + r.width()) / divisionRatio, (r.y() + r.height()) / divisionRatio); // First triangle *(map++) = topRight; *(map++) = topLeft; *(map++) = bottomLeft; // Second triangle *(map++) = bottomLeft; *(map++) = bottomRight; *(map++) = topRight; } } } void BlurEffect::uploadGeometry(GLVertexBuffer *vbo, const QRegion &blurRegion, const QRegion &windowRegion) { const int vertexCount = ((blurRegion.rectCount() * (m_downSampleIterations + 1)) + windowRegion.rectCount()) * 6; if (!vertexCount) return; QVector2D *map = (QVector2D *) vbo->map(vertexCount * sizeof(QVector2D)); uploadRegion(map, blurRegion, m_downSampleIterations); uploadRegion(map, windowRegion, 0); vbo->unmap(); const GLVertexAttrib layout[] = { { VA_Position, 2, GL_FLOAT, 0 }, { VA_TexCoord, 2, GL_FLOAT, 0 } }; vbo->setAttribLayout(layout, 2, sizeof(QVector2D)); } void BlurEffect::prePaintScreen(ScreenPrePaintData &data, std::chrono::milliseconds presentTime) { m_paintedArea = QRegion(); m_currentBlur = QRegion(); effects->prePaintScreen(data, presentTime); } void BlurEffect::prePaintWindow(EffectWindow* w, WindowPrePaintData& data, std::chrono::milliseconds presentTime) { // this effect relies on prePaintWindow being called in the bottom to top order effects->prePaintWindow(w, data, presentTime); if (!w->isPaintingEnabled()) { return; } if (!m_shader || !m_shader->isValid()) { return; } // to blur an area partially we have to shrink the opaque area of a window QRegion newClip; const QRegion oldClip = data.clip; for (const QRect &rect : data.clip) { newClip |= rect.adjusted(m_expandSize, m_expandSize, -m_expandSize, -m_expandSize); } data.clip = newClip; // we don't have to blur a region we don't see m_currentBlur -= newClip; // if we have to paint a non-opaque part of this window that intersects with the // currently blurred region we have to redraw the whole region if ((data.paint - oldClip).intersects(m_currentBlur)) { data.paint |= m_currentBlur; } // in case this window has regions to be blurred const QRect screen = effects->virtualScreenGeometry(); const QRegion blurArea = blurRegion(w).translated(w->pos()) & screen; const QRegion expandedBlur = (w->isDock() ? blurArea : expand(blurArea)) & screen; // if this window or a window underneath the blurred area is painted again we have to // blur everything if (m_paintedArea.intersects(expandedBlur) || data.paint.intersects(blurArea)) { data.paint |= expandedBlur; // we have to check again whether we do not damage a blurred area // of a window if (expandedBlur.intersects(m_currentBlur)) { data.paint |= m_currentBlur; } } m_currentBlur |= expandedBlur; m_paintedArea -= data.clip; m_paintedArea |= data.paint; } bool BlurEffect::shouldBlur(const EffectWindow *w, int mask, const WindowPaintData &data) const { if (!m_renderTargetsValid || !m_shader || !m_shader->isValid()) return false; if (effects->activeFullScreenEffect() && !w->data(WindowForceBlurRole).toBool()) return false; if (w->isDesktop()) return false; bool scaled = !qFuzzyCompare(data.xScale(), 1.0) && !qFuzzyCompare(data.yScale(), 1.0); bool translated = data.xTranslation() || data.yTranslation(); if ((scaled || (translated || (mask & PAINT_WINDOW_TRANSFORMED))) && !w->data(WindowForceBlurRole).toBool()) return false; bool blurBehindDecos = effects->decorationsHaveAlpha() && effects->decorationSupportsBlurBehind(); if (!w->hasAlpha() && w->opacity() >= 1.0 && !(blurBehindDecos && w->hasDecoration())) return false; return true; } void BlurEffect::drawWindow(EffectWindow *w, int mask, const QRegion ®ion, WindowPaintData &data) { const QRect screen = GLRenderTarget::virtualScreenGeometry(); if (shouldBlur(w, mask, data)) { QRegion shape = region & blurRegion(w).translated(w->pos()) & screen; // let's do the evil parts - someone wants to blur behind a transformed window const bool translated = data.xTranslation() || data.yTranslation(); const bool scaled = data.xScale() != 1 || data.yScale() != 1; if (scaled) { QPoint pt = shape.boundingRect().topLeft(); QRegion scaledShape; for (QRect r : shape) { r.moveTo(pt.x() + (r.x() - pt.x()) * data.xScale() + data.xTranslation(), pt.y() + (r.y() - pt.y()) * data.yScale() + data.yTranslation()); r.setWidth(r.width() * data.xScale()); r.setHeight(r.height() * data.yScale()); scaledShape |= r; } shape = scaledShape & region; //Only translated, not scaled } else if (translated) { shape = shape.translated(data.xTranslation(), data.yTranslation()); shape = shape & region; } EffectWindow* modal = w->transientFor(); const bool transientForIsDock = (modal ? modal->isDock() : false); if (!shape.isEmpty()) { doBlur(shape, screen, data.opacity(), data.screenProjectionMatrix(), w->isDock() || transientForIsDock, w->geometry()); } } // Draw the window over the blurred area effects->drawWindow(w, mask, region, data); } void BlurEffect::paintEffectFrame(EffectFrame *frame, const QRegion ®ion, double opacity, double frameOpacity) { const QRect screen = effects->virtualScreenGeometry(); bool valid = m_renderTargetsValid && m_shader && m_shader->isValid(); QRegion shape = frame->geometry().adjusted(-borderSize, -borderSize, borderSize, borderSize) & screen; if (valid && !shape.isEmpty() && region.intersects(shape.boundingRect()) && frame->style() != EffectFrameNone) { doBlur(shape, screen, opacity * frameOpacity, frame->screenProjectionMatrix(), false, frame->geometry()); } effects->paintEffectFrame(frame, region, opacity, frameOpacity); } void BlurEffect::generateNoiseTexture() { if (m_noiseStrength == 0) { return; } // Init randomness based on time qsrand((uint)QTime::currentTime().msec()); QImage noiseImage(QSize(256, 256), QImage::Format_Grayscale8); for (int y = 0; y < noiseImage.height(); y++) { uint8_t *noiseImageLine = (uint8_t *) noiseImage.scanLine(y); for (int x = 0; x < noiseImage.width(); x++) { noiseImageLine[x] = qrand() % m_noiseStrength + (128 - m_noiseStrength / 2); } } // The noise texture looks distorted when not scaled with integer noiseImage = noiseImage.scaled(noiseImage.size() * m_scalingFactor); m_noiseTexture = GLTexture(noiseImage); m_noiseTexture.setFilter(GL_NEAREST); m_noiseTexture.setWrapMode(GL_REPEAT); } void BlurEffect::doBlur(const QRegion& shape, const QRect& screen, const float opacity, const QMatrix4x4 &screenProjection, bool isDock, QRect windowRect) { // Blur would not render correctly on a secondary monitor because of wrong coordinates // BUG: 393723 const int xTranslate = -screen.x(); const int yTranslate = effects->virtualScreenSize().height() - screen.height() - screen.y(); const QRegion expandedBlurRegion = expand(shape) & expand(screen); const bool useSRGB = m_renderTextures.first().internalFormat() == GL_SRGB8_ALPHA8; // Upload geometry for the down and upsample iterations GLVertexBuffer *vbo = GLVertexBuffer::streamingBuffer(); vbo->reset(); uploadGeometry(vbo, expandedBlurRegion.translated(xTranslate, yTranslate), shape); vbo->bindArrays(); const QRect sourceRect = expandedBlurRegion.boundingRect() & screen; const QRect destRect = sourceRect.translated(xTranslate, yTranslate); GLRenderTarget::pushRenderTargets(m_renderTargetStack); int blurRectCount = expandedBlurRegion.rectCount() * 6; /* * If the window is a dock or panel we avoid the "extended blur" effect. * Extended blur is when windows that are not under the blurred area affect * the final blur result. * We want to avoid this on panels, because it looks really weird and ugly * when maximized windows or windows near the panel affect the dock blur. */ if (isDock) { m_renderTargets.last()->blitFromFramebuffer(sourceRect, destRect); if (useSRGB) { glEnable(GL_FRAMEBUFFER_SRGB); } copyScreenSampleTexture(vbo, blurRectCount, shape.translated(xTranslate, yTranslate), screenProjection); } else { m_renderTargets.first()->blitFromFramebuffer(sourceRect, destRect); if (useSRGB) { glEnable(GL_FRAMEBUFFER_SRGB); } // Remove the m_renderTargets[0] from the top of the stack that we will not use GLRenderTarget::popRenderTarget(); } downSampleTexture(vbo, blurRectCount); upSampleTexture(vbo, blurRectCount); // Modulate the blurred texture with the window opacity if the window isn't opaque if (opacity < 1.0) { glEnable(GL_BLEND); #if 1 // bow shape, always above y = x float o = 1.0f-opacity; o = 1.0f - o*o; #else // sigmoid shape, above y = x for x > 0.5, below y = x for x < 0.5 float o = 2.0f*opacity - 1.0f; o = 0.5f + o / (1.0f + qAbs(o)); #endif glBlendColor(0, 0, 0, o); glBlendFunc(GL_CONSTANT_ALPHA, GL_ONE_MINUS_CONSTANT_ALPHA); } upscaleRenderToScreen(vbo, blurRectCount * (m_downSampleIterations + 1), shape.rectCount() * 6, screenProjection, windowRect.topLeft()); if (useSRGB) { glDisable(GL_FRAMEBUFFER_SRGB); } if (opacity < 1.0) { glDisable(GL_BLEND); } vbo->unbindArrays(); } void BlurEffect::upscaleRenderToScreen(GLVertexBuffer *vbo, int vboStart, int blurRectCount, QMatrix4x4 screenProjection, QPoint windowPosition) { glActiveTexture(GL_TEXTURE0); m_renderTextures[1].bind(); if (m_noiseStrength > 0) { m_shader->bind(BlurShader::NoiseSampleType); m_shader->setTargetTextureSize(m_renderTextures[0].size() * GLRenderTarget::virtualScreenScale()); m_shader->setNoiseTextureSize(m_noiseTexture.size() * GLRenderTarget::virtualScreenScale()); m_shader->setTexturePosition(windowPosition * GLRenderTarget::virtualScreenScale()); glActiveTexture(GL_TEXTURE1); m_noiseTexture.bind(); } else { m_shader->bind(BlurShader::UpSampleType); m_shader->setTargetTextureSize(m_renderTextures[0].size() * GLRenderTarget::virtualScreenScale()); } m_shader->setOffset(m_offset); m_shader->setModelViewProjectionMatrix(screenProjection); //Render to the screen vbo->draw(GL_TRIANGLES, vboStart, blurRectCount); glActiveTexture(GL_TEXTURE0); m_shader->unbind(); } void BlurEffect::downSampleTexture(GLVertexBuffer *vbo, int blurRectCount) { QMatrix4x4 modelViewProjectionMatrix; m_shader->bind(BlurShader::DownSampleType); m_shader->setOffset(m_offset); for (int i = 1; i <= m_downSampleIterations; i++) { modelViewProjectionMatrix.setToIdentity(); modelViewProjectionMatrix.ortho(0, m_renderTextures[i].width(), m_renderTextures[i].height(), 0 , 0, 65535); m_shader->setModelViewProjectionMatrix(modelViewProjectionMatrix); m_shader->setTargetTextureSize(m_renderTextures[i].size()); //Copy the image from this texture m_renderTextures[i - 1].bind(); vbo->draw(GL_TRIANGLES, blurRectCount * i, blurRectCount); GLRenderTarget::popRenderTarget(); } m_shader->unbind(); } void BlurEffect::upSampleTexture(GLVertexBuffer *vbo, int blurRectCount) { QMatrix4x4 modelViewProjectionMatrix; m_shader->bind(BlurShader::UpSampleType); m_shader->setOffset(m_offset); for (int i = m_downSampleIterations - 1; i >= 1; i--) { modelViewProjectionMatrix.setToIdentity(); modelViewProjectionMatrix.ortho(0, m_renderTextures[i].width(), m_renderTextures[i].height(), 0 , 0, 65535); m_shader->setModelViewProjectionMatrix(modelViewProjectionMatrix); m_shader->setTargetTextureSize(m_renderTextures[i].size()); //Copy the image from this texture m_renderTextures[i + 1].bind(); vbo->draw(GL_TRIANGLES, blurRectCount * i, blurRectCount); GLRenderTarget::popRenderTarget(); } m_shader->unbind(); } void BlurEffect::copyScreenSampleTexture(GLVertexBuffer *vbo, int blurRectCount, QRegion blurShape, QMatrix4x4 screenProjection) { m_shader->bind(BlurShader::CopySampleType); m_shader->setModelViewProjectionMatrix(screenProjection); m_shader->setTargetTextureSize(effects->virtualScreenSize()); /* * This '1' sized adjustment is necessary do avoid windows affecting the blur that are * right next to this window. */ m_shader->setBlurRect(blurShape.boundingRect().adjusted(1, 1, -1, -1), effects->virtualScreenSize()); m_renderTextures.last().bind(); vbo->draw(GL_TRIANGLES, 0, blurRectCount); GLRenderTarget::popRenderTarget(); m_shader->unbind(); } bool BlurEffect::isActive() const { return !effects->isScreenLocked(); } } // namespace KWin