/* * Copyright (C) 2007 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #define ATRACE_TAG ATRACE_TAG_GRAPHICS #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "clz.h" #include "DisplayDevice.h" #include "GLExtensions.h" #include "Layer.h" #include "SurfaceFlinger.h" #include "SurfaceTextureLayer.h" #include "DisplayHardware/HWComposer.h" #define DEBUG_RESIZE 0 namespace android { // --------------------------------------------------------------------------- Layer::Layer(SurfaceFlinger* flinger, const sp& client) : LayerBaseClient(flinger, client), mTextureName(-1U), mQueuedFrames(0), mCurrentTransform(0), mCurrentScalingMode(NATIVE_WINDOW_SCALING_MODE_FREEZE), mCurrentOpacity(true), mRefreshPending(false), mFrameLatencyNeeded(false), mFormat(PIXEL_FORMAT_NONE), mGLExtensions(GLExtensions::getInstance()), mOpaqueLayer(true), mSecure(false), mProtectedByApp(false) { mCurrentCrop.makeInvalid(); glGenTextures(1, &mTextureName); } void Layer::onLayerDisplayed(const sp& hw, HWComposer::HWCLayerInterface* layer) { LayerBaseClient::onLayerDisplayed(hw, layer); if (layer) { mSurfaceFlingerConsumer->setReleaseFence(layer->getAndResetReleaseFenceFd()); } } void Layer::onFirstRef() { LayerBaseClient::onFirstRef(); // Creates a custom BufferQueue for SurfaceFlingerConsumer to use sp bq = new SurfaceTextureLayer(); mSurfaceFlingerConsumer = new SurfaceFlingerConsumer(mTextureName, true, GL_TEXTURE_EXTERNAL_OES, false, bq); mSurfaceFlingerConsumer->setConsumerUsageBits(getEffectiveUsage(0)); mSurfaceFlingerConsumer->setFrameAvailableListener(this); mSurfaceFlingerConsumer->setSynchronousMode(true); #ifdef TARGET_DISABLE_TRIPLE_BUFFERING #warning "disabling triple buffering" mSurfaceFlingerConsumer->setDefaultMaxBufferCount(2); #else mSurfaceFlingerConsumer->setDefaultMaxBufferCount(3); #endif const sp hw(mFlinger->getDefaultDisplayDevice()); updateTransformHint(hw); } Layer::~Layer() { mFlinger->deleteTextureAsync(mTextureName); } void Layer::onFrameAvailable() { android_atomic_inc(&mQueuedFrames); mFlinger->signalLayerUpdate(); } // called with SurfaceFlinger::mStateLock as soon as the layer is entered // in the purgatory list void Layer::onRemoved() { mSurfaceFlingerConsumer->abandon(); } void Layer::setName(const String8& name) { LayerBase::setName(name); mSurfaceFlingerConsumer->setName(name); } sp Layer::createSurface() { class BSurface : public BnSurface, public LayerCleaner { wp mOwner; virtual sp getSurfaceTexture() const { sp res; sp that( mOwner.promote() ); if (that != NULL) { res = that->mSurfaceFlingerConsumer->getBufferQueue(); } return res; } public: BSurface(const sp& flinger, const sp& layer) : LayerCleaner(flinger, layer), mOwner(layer) { } }; sp sur(new BSurface(mFlinger, this)); return sur; } wp Layer::getSurfaceTextureBinder() const { return mSurfaceFlingerConsumer->getBufferQueue()->asBinder(); } status_t Layer::setBuffers( uint32_t w, uint32_t h, PixelFormat format, uint32_t flags) { // this surfaces pixel format PixelFormatInfo info; status_t err = getPixelFormatInfo(format, &info); if (err) { ALOGE("unsupported pixelformat %d", format); return err; } uint32_t const maxSurfaceDims = min( mFlinger->getMaxTextureSize(), mFlinger->getMaxViewportDims()); // never allow a surface larger than what our underlying GL implementation // can handle. if ((uint32_t(w)>maxSurfaceDims) || (uint32_t(h)>maxSurfaceDims)) { ALOGE("dimensions too large %u x %u", uint32_t(w), uint32_t(h)); return BAD_VALUE; } mFormat = format; mSecure = (flags & ISurfaceComposerClient::eSecure) ? true : false; mProtectedByApp = (flags & ISurfaceComposerClient::eProtectedByApp) ? true : false; mOpaqueLayer = (flags & ISurfaceComposerClient::eOpaque); mCurrentOpacity = getOpacityForFormat(format); mSurfaceFlingerConsumer->setDefaultBufferSize(w, h); mSurfaceFlingerConsumer->setDefaultBufferFormat(format); mSurfaceFlingerConsumer->setConsumerUsageBits(getEffectiveUsage(0)); return NO_ERROR; } Rect Layer::computeBufferCrop() const { // Start with the SurfaceFlingerConsumer's buffer crop... Rect crop; if (!mCurrentCrop.isEmpty()) { crop = mCurrentCrop; } else if (mActiveBuffer != NULL){ crop = Rect(mActiveBuffer->getWidth(), mActiveBuffer->getHeight()); } else { crop.makeInvalid(); return crop; } // ... then reduce that in the same proportions as the window crop reduces // the window size. const State& s(drawingState()); if (!s.active.crop.isEmpty()) { // Transform the window crop to match the buffer coordinate system, // which means using the inverse of the current transform set on the // SurfaceFlingerConsumer. uint32_t invTransform = mCurrentTransform; int winWidth = s.active.w; int winHeight = s.active.h; if (invTransform & NATIVE_WINDOW_TRANSFORM_ROT_90) { invTransform ^= NATIVE_WINDOW_TRANSFORM_FLIP_V | NATIVE_WINDOW_TRANSFORM_FLIP_H; winWidth = s.active.h; winHeight = s.active.w; } Rect winCrop = s.active.crop.transform(invTransform, s.active.w, s.active.h); float xScale = float(crop.width()) / float(winWidth); float yScale = float(crop.height()) / float(winHeight); crop.left += int(ceilf(float(winCrop.left) * xScale)); crop.top += int(ceilf(float(winCrop.top) * yScale)); crop.right -= int(ceilf(float(winWidth - winCrop.right) * xScale)); crop.bottom -= int(ceilf(float(winHeight - winCrop.bottom) * yScale)); } return crop; } void Layer::setGeometry( const sp& hw, HWComposer::HWCLayerInterface& layer) { LayerBaseClient::setGeometry(hw, layer); // enable this layer layer.setSkip(false); // we can't do alpha-fade with the hwc HAL const State& s(drawingState()); if (s.alpha < 0xFF) { layer.setSkip(true); } if (isSecure() && !hw->isSecure()) { layer.setSkip(true); } /* * Transformations are applied in this order: * 1) buffer orientation/flip/mirror * 2) state transformation (window manager) * 3) layer orientation (screen orientation) * (NOTE: the matrices are multiplied in reverse order) */ const Transform bufferOrientation(mCurrentTransform); const Transform tr(hw->getTransform() * s.transform * bufferOrientation); // this gives us only the "orientation" component of the transform const uint32_t finalTransform = tr.getOrientation(); // we can only handle simple transformation if (finalTransform & Transform::ROT_INVALID) { layer.setSkip(true); } else { layer.setTransform(finalTransform); } layer.setCrop(computeBufferCrop()); } void Layer::setPerFrameData(const sp& hw, HWComposer::HWCLayerInterface& layer) { LayerBaseClient::setPerFrameData(hw, layer); // NOTE: buffer can be NULL if the client never drew into this // layer yet, or if we ran out of memory layer.setBuffer(mActiveBuffer); } void Layer::setAcquireFence(const sp& hw, HWComposer::HWCLayerInterface& layer) { int fenceFd = -1; // TODO: there is a possible optimization here: we only need to set the // acquire fence the first time a new buffer is acquired on EACH display. if (layer.getCompositionType() == HWC_OVERLAY) { sp fence = mSurfaceFlingerConsumer->getCurrentFence(); if (fence.get()) { fenceFd = fence->dup(); if (fenceFd == -1) { ALOGW("failed to dup layer fence, skipping sync: %d", errno); } } } layer.setAcquireFenceFd(fenceFd); } void Layer::onDraw(const sp& hw, const Region& clip) const { ATRACE_CALL(); if (CC_UNLIKELY(mActiveBuffer == 0)) { // the texture has not been created yet, this Layer has // in fact never been drawn into. This happens frequently with // SurfaceView because the WindowManager can't know when the client // has drawn the first time. // If there is nothing under us, we paint the screen in black, otherwise // we just skip this update. // figure out if there is something below us Region under; const SurfaceFlinger::LayerVector& drawingLayers( mFlinger->mDrawingState.layersSortedByZ); const size_t count = drawingLayers.size(); for (size_t i=0 ; i& layer(drawingLayers[i]); if (layer.get() == static_cast(this)) break; under.orSelf( hw->getTransform().transform(layer->visibleRegion) ); } // if not everything below us is covered, we plug the holes! Region holes(clip.subtract(under)); if (!holes.isEmpty()) { clearWithOpenGL(hw, holes, 0, 0, 0, 1); } return; } // Bind the current buffer to the GL texture, and wait for it to be // ready for us to draw into. status_t err = mSurfaceFlingerConsumer->bindTextureImage(); if (err != NO_ERROR) { ALOGW("onDraw: bindTextureImage failed (err=%d)", err); // Go ahead and draw the buffer anyway; no matter what we do the screen // is probably going to have something visibly wrong. } bool blackOutLayer = isProtected() || (isSecure() && !hw->isSecure()); if (!blackOutLayer) { // TODO: we could be more subtle with isFixedSize() const bool useFiltering = getFiltering() || needsFiltering(hw) || isFixedSize(); // Query the texture matrix given our current filtering mode. float textureMatrix[16]; mSurfaceFlingerConsumer->setFilteringEnabled(useFiltering); mSurfaceFlingerConsumer->getTransformMatrix(textureMatrix); // Set things up for texturing. glBindTexture(GL_TEXTURE_EXTERNAL_OES, mTextureName); GLenum filter = GL_NEAREST; if (useFiltering) { filter = GL_LINEAR; } glTexParameterx(GL_TEXTURE_EXTERNAL_OES, GL_TEXTURE_MAG_FILTER, filter); glTexParameterx(GL_TEXTURE_EXTERNAL_OES, GL_TEXTURE_MIN_FILTER, filter); glMatrixMode(GL_TEXTURE); glLoadMatrixf(textureMatrix); glMatrixMode(GL_MODELVIEW); glDisable(GL_TEXTURE_2D); glEnable(GL_TEXTURE_EXTERNAL_OES); } else { glBindTexture(GL_TEXTURE_2D, mFlinger->getProtectedTexName()); glMatrixMode(GL_TEXTURE); glLoadIdentity(); glMatrixMode(GL_MODELVIEW); glDisable(GL_TEXTURE_EXTERNAL_OES); glEnable(GL_TEXTURE_2D); } drawWithOpenGL(hw, clip); glDisable(GL_TEXTURE_EXTERNAL_OES); glDisable(GL_TEXTURE_2D); } // As documented in libhardware header, formats in the range // 0x100 - 0x1FF are specific to the HAL implementation, and // are known to have no alpha channel // TODO: move definition for device-specific range into // hardware.h, instead of using hard-coded values here. #define HARDWARE_IS_DEVICE_FORMAT(f) ((f) >= 0x100 && (f) <= 0x1FF) bool Layer::getOpacityForFormat(uint32_t format) { if (HARDWARE_IS_DEVICE_FORMAT(format)) { return true; } PixelFormatInfo info; status_t err = getPixelFormatInfo(PixelFormat(format), &info); // in case of error (unknown format), we assume no blending return (err || info.h_alpha <= info.l_alpha); } bool Layer::isOpaque() const { // if we don't have a buffer yet, we're translucent regardless of the // layer's opaque flag. if (mActiveBuffer == 0) { return false; } // if the layer has the opaque flag, then we're always opaque, // otherwise we use the current buffer's format. return mOpaqueLayer || mCurrentOpacity; } bool Layer::isProtected() const { const sp& activeBuffer(mActiveBuffer); return (activeBuffer != 0) && (activeBuffer->getUsage() & GRALLOC_USAGE_PROTECTED); } uint32_t Layer::doTransaction(uint32_t flags) { ATRACE_CALL(); const Layer::State& front(drawingState()); const Layer::State& temp(currentState()); const bool sizeChanged = (temp.requested.w != front.requested.w) || (temp.requested.h != front.requested.h); if (sizeChanged) { // the size changed, we need to ask our client to request a new buffer ALOGD_IF(DEBUG_RESIZE, "doTransaction: geometry (layer=%p '%s'), tr=%02x, scalingMode=%d\n" " current={ active ={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }\n" " requested={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }}\n" " drawing={ active ={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }\n" " requested={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }}\n", this, (const char*) getName(), mCurrentTransform, mCurrentScalingMode, temp.active.w, temp.active.h, temp.active.crop.left, temp.active.crop.top, temp.active.crop.right, temp.active.crop.bottom, temp.active.crop.getWidth(), temp.active.crop.getHeight(), temp.requested.w, temp.requested.h, temp.requested.crop.left, temp.requested.crop.top, temp.requested.crop.right, temp.requested.crop.bottom, temp.requested.crop.getWidth(), temp.requested.crop.getHeight(), front.active.w, front.active.h, front.active.crop.left, front.active.crop.top, front.active.crop.right, front.active.crop.bottom, front.active.crop.getWidth(), front.active.crop.getHeight(), front.requested.w, front.requested.h, front.requested.crop.left, front.requested.crop.top, front.requested.crop.right, front.requested.crop.bottom, front.requested.crop.getWidth(), front.requested.crop.getHeight()); // record the new size, form this point on, when the client request // a buffer, it'll get the new size. mSurfaceFlingerConsumer->setDefaultBufferSize( temp.requested.w, temp.requested.h); } if (!isFixedSize()) { const bool resizePending = (temp.requested.w != temp.active.w) || (temp.requested.h != temp.active.h); if (resizePending) { // don't let LayerBase::doTransaction update the drawing state // if we have a pending resize, unless we are in fixed-size mode. // the drawing state will be updated only once we receive a buffer // with the correct size. // // in particular, we want to make sure the clip (which is part // of the geometry state) is latched together with the size but is // latched immediately when no resizing is involved. flags |= eDontUpdateGeometryState; } } return LayerBase::doTransaction(flags); } bool Layer::isFixedSize() const { return mCurrentScalingMode != NATIVE_WINDOW_SCALING_MODE_FREEZE; } bool Layer::isCropped() const { return !mCurrentCrop.isEmpty(); } // ---------------------------------------------------------------------------- // pageflip handling... // ---------------------------------------------------------------------------- bool Layer::onPreComposition() { mRefreshPending = false; return mQueuedFrames > 0; } void Layer::onPostComposition() { if (mFrameLatencyNeeded) { nsecs_t desiredPresentTime = mSurfaceFlingerConsumer->getTimestamp(); mFrameTracker.setDesiredPresentTime(desiredPresentTime); sp frameReadyFence = mSurfaceFlingerConsumer->getCurrentFence(); if (frameReadyFence != NULL) { mFrameTracker.setFrameReadyFence(frameReadyFence); } else { // There was no fence for this frame, so assume that it was ready // to be presented at the desired present time. mFrameTracker.setFrameReadyTime(desiredPresentTime); } const HWComposer& hwc = mFlinger->getHwComposer(); sp presentFence = hwc.getDisplayFence(HWC_DISPLAY_PRIMARY); // XXX: Temporarily don't use the present fence from HWC to work // around a driver bug. presentFence.clear(); if (presentFence != NULL) { mFrameTracker.setActualPresentFence(presentFence); } else { // The HWC doesn't support present fences, so use the refresh // timestamp instead. nsecs_t presentTime = hwc.getRefreshTimestamp(HWC_DISPLAY_PRIMARY); mFrameTracker.setActualPresentTime(presentTime); } mFrameTracker.advanceFrame(); mFrameLatencyNeeded = false; } } bool Layer::isVisible() const { return LayerBaseClient::isVisible() && (mActiveBuffer != NULL); } Region Layer::latchBuffer(bool& recomputeVisibleRegions) { ATRACE_CALL(); Region outDirtyRegion; if (mQueuedFrames > 0) { // if we've already called updateTexImage() without going through // a composition step, we have to skip this layer at this point // because we cannot call updateTeximage() without a corresponding // compositionComplete() call. // we'll trigger an update in onPreComposition(). if (mRefreshPending) { return outDirtyRegion; } // Capture the old state of the layer for comparisons later const bool oldOpacity = isOpaque(); sp oldActiveBuffer = mActiveBuffer; // signal another event if we have more frames pending if (android_atomic_dec(&mQueuedFrames) > 1) { mFlinger->signalLayerUpdate(); } struct Reject : public SurfaceFlingerConsumer::BufferRejecter { Layer::State& front; Layer::State& current; bool& recomputeVisibleRegions; Reject(Layer::State& front, Layer::State& current, bool& recomputeVisibleRegions) : front(front), current(current), recomputeVisibleRegions(recomputeVisibleRegions) { } virtual bool reject(const sp& buf, const BufferQueue::BufferItem& item) { if (buf == NULL) { return false; } uint32_t bufWidth = buf->getWidth(); uint32_t bufHeight = buf->getHeight(); // check that we received a buffer of the right size // (Take the buffer's orientation into account) if (item.mTransform & Transform::ROT_90) { swap(bufWidth, bufHeight); } bool isFixedSize = item.mScalingMode != NATIVE_WINDOW_SCALING_MODE_FREEZE; if (front.active != front.requested) { if (isFixedSize || (bufWidth == front.requested.w && bufHeight == front.requested.h)) { // Here we pretend the transaction happened by updating the // current and drawing states. Drawing state is only accessed // in this thread, no need to have it locked front.active = front.requested; // We also need to update the current state so that // we don't end-up overwriting the drawing state with // this stale current state during the next transaction // // NOTE: We don't need to hold the transaction lock here // because State::active is only accessed from this thread. current.active = front.active; // recompute visible region recomputeVisibleRegions = true; } ALOGD_IF(DEBUG_RESIZE, "latchBuffer/reject: buffer (%ux%u, tr=%02x), scalingMode=%d\n" " drawing={ active ={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }\n" " requested={ wh={%4u,%4u} crop={%4d,%4d,%4d,%4d} (%4d,%4d) }}\n", bufWidth, bufHeight, item.mTransform, item.mScalingMode, front.active.w, front.active.h, front.active.crop.left, front.active.crop.top, front.active.crop.right, front.active.crop.bottom, front.active.crop.getWidth(), front.active.crop.getHeight(), front.requested.w, front.requested.h, front.requested.crop.left, front.requested.crop.top, front.requested.crop.right, front.requested.crop.bottom, front.requested.crop.getWidth(), front.requested.crop.getHeight()); } if (!isFixedSize) { if (front.active.w != bufWidth || front.active.h != bufHeight) { // reject this buffer return true; } } return false; } }; Reject r(mDrawingState, currentState(), recomputeVisibleRegions); if (mSurfaceFlingerConsumer->updateTexImage(&r) != NO_ERROR) { // something happened! recomputeVisibleRegions = true; return outDirtyRegion; } // update the active buffer mActiveBuffer = mSurfaceFlingerConsumer->getCurrentBuffer(); if (mActiveBuffer == NULL) { // this can only happen if the very first buffer was rejected. return outDirtyRegion; } mRefreshPending = true; mFrameLatencyNeeded = true; if (oldActiveBuffer == NULL) { // the first time we receive a buffer, we need to trigger a // geometry invalidation. recomputeVisibleRegions = true; } Rect crop(mSurfaceFlingerConsumer->getCurrentCrop()); const uint32_t transform(mSurfaceFlingerConsumer->getCurrentTransform()); const uint32_t scalingMode(mSurfaceFlingerConsumer->getCurrentScalingMode()); if ((crop != mCurrentCrop) || (transform != mCurrentTransform) || (scalingMode != mCurrentScalingMode)) { mCurrentCrop = crop; mCurrentTransform = transform; mCurrentScalingMode = scalingMode; recomputeVisibleRegions = true; } if (oldActiveBuffer != NULL) { uint32_t bufWidth = mActiveBuffer->getWidth(); uint32_t bufHeight = mActiveBuffer->getHeight(); if (bufWidth != uint32_t(oldActiveBuffer->width) || bufHeight != uint32_t(oldActiveBuffer->height)) { recomputeVisibleRegions = true; } } mCurrentOpacity = getOpacityForFormat(mActiveBuffer->format); if (oldOpacity != isOpaque()) { recomputeVisibleRegions = true; } glTexParameterx(GL_TEXTURE_EXTERNAL_OES, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE); glTexParameterx(GL_TEXTURE_EXTERNAL_OES, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE); // FIXME: postedRegion should be dirty & bounds const Layer::State& front(drawingState()); Region dirtyRegion(Rect(front.active.w, front.active.h)); // transform the dirty region to window-manager space outDirtyRegion = (front.transform.transform(dirtyRegion)); } return outDirtyRegion; } void Layer::dump(String8& result, char* buffer, size_t SIZE) const { LayerBaseClient::dump(result, buffer, SIZE); sp buf0(mActiveBuffer); uint32_t w0=0, h0=0, s0=0, f0=0; if (buf0 != 0) { w0 = buf0->getWidth(); h0 = buf0->getHeight(); s0 = buf0->getStride(); f0 = buf0->format; } snprintf(buffer, SIZE, " " "format=%2d, activeBuffer=[%4ux%4u:%4u,%3X]," " queued-frames=%d, mRefreshPending=%d\n", mFormat, w0, h0, s0,f0, mQueuedFrames, mRefreshPending); result.append(buffer); if (mSurfaceFlingerConsumer != 0) { mSurfaceFlingerConsumer->dump(result, " ", buffer, SIZE); } } void Layer::dumpStats(String8& result, char* buffer, size_t SIZE) const { LayerBaseClient::dumpStats(result, buffer, SIZE); const nsecs_t period = mFlinger->getHwComposer().getRefreshPeriod(HWC_DISPLAY_PRIMARY); result.appendFormat("%lld\n", period); mFrameTracker.dump(result); } void Layer::clearStats() { LayerBaseClient::clearStats(); mFrameTracker.clear(); } uint32_t Layer::getEffectiveUsage(uint32_t usage) const { // TODO: should we do something special if mSecure is set? if (mProtectedByApp) { // need a hardware-protected path to external video sink usage |= GraphicBuffer::USAGE_PROTECTED; } usage |= GraphicBuffer::USAGE_HW_COMPOSER; return usage; } void Layer::updateTransformHint(const sp& hw) const { uint32_t orientation = 0; if (!mFlinger->mDebugDisableTransformHint) { // The transform hint is used to improve performance, but we can // only have a single transform hint, it cannot // apply to all displays. const Transform& planeTransform(hw->getTransform()); orientation = planeTransform.getOrientation(); if (orientation & Transform::ROT_INVALID) { orientation = 0; } } mSurfaceFlingerConsumer->setTransformHint(orientation); } // --------------------------------------------------------------------------- }; // namespace android