/* * Copyright 2015 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. */ // TODO(b/129481165): remove the #pragma below and fix conversion issues #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wconversion" // #define LOG_NDEBUG 0 #undef LOG_TAG #define LOG_TAG "HWC2" #define ATRACE_TAG ATRACE_TAG_GRAPHICS #include "HWC2.h" #include #include #include #include #include #include #include #include #include using aidl::android::hardware::graphics::composer3::Color; using aidl::android::hardware::graphics::composer3::Composition; using AidlCapability = aidl::android::hardware::graphics::composer3::Capability; using aidl::android::hardware::graphics::composer3::DisplayCapability; using aidl::android::hardware::graphics::composer3::OverlayProperties; namespace android { using android::Fence; using android::FloatRect; using android::GraphicBuffer; using android::HdrCapabilities; using android::HdrMetadata; using android::Rect; using android::Region; using android::sp; namespace HWC2 { using namespace android::hardware::graphics::composer::hal; namespace Hwc2 = android::Hwc2; namespace { inline bool hasMetadataKey(const std::set& keys, const Hwc2::PerFrameMetadataKey& key) { return keys.find(key) != keys.end(); } } // namespace anonymous // Display methods Display::~Display() = default; namespace impl { Display::Display(android::Hwc2::Composer& composer, const std::unordered_set& capabilities, HWDisplayId id, DisplayType type) : mComposer(composer), mCapabilities(capabilities), mId(id), mType(type) { ALOGV("Created display %" PRIu64, id); if (mType == hal::DisplayType::VIRTUAL) { loadDisplayCapabilities(); } } Display::~Display() { // Note: The calls to onOwningDisplayDestroyed() are allowed (and expected) // to call Display::onLayerDestroyed(). As that call removes entries from // mLayers, we do not want to have a for loop directly over it here. Since // the end goal is an empty mLayers anyway, we just go ahead and swap an // initially empty local container with mLayers, and then enumerate // the contents of the local container. Layers destroyingLayers; std::swap(mLayers, destroyingLayers); for (const auto& [_, weakLayer] : destroyingLayers) { if (std::shared_ptr layer = weakLayer.lock()) { layer->onOwningDisplayDestroyed(); } } Error error = Error::NONE; const char* msg; switch (mType) { case DisplayType::PHYSICAL: error = setVsyncEnabled(HWC2::Vsync::DISABLE); msg = "disable VSYNC for"; break; case DisplayType::VIRTUAL: error = static_cast(mComposer.destroyVirtualDisplay(mId)); msg = "destroy virtual"; break; case DisplayType::INVALID: // Used in unit tests. break; } ALOGE_IF(error != Error::NONE, "%s: Failed to %s display %" PRIu64 ": %d", __FUNCTION__, msg, mId, static_cast(error)); ALOGV("Destroyed display %" PRIu64, mId); } // Required by HWC2 display Error Display::acceptChanges() { auto intError = mComposer.acceptDisplayChanges(mId); return static_cast(intError); } base::expected, hal::Error> Display::createLayer() { HWLayerId layerId = 0; auto intError = mComposer.createLayer(mId, &layerId); auto error = static_cast(intError); if (error != Error::NONE) { return base::unexpected(error); } auto layer = std::make_shared(mComposer, mCapabilities, *this, layerId); mLayers.emplace(layerId, layer); return layer; } void Display::onLayerDestroyed(hal::HWLayerId layerId) { mLayers.erase(layerId); } bool Display::isVsyncPeriodSwitchSupported() const { ALOGV("[%" PRIu64 "] isVsyncPeriodSwitchSupported()", mId); return mComposer.isSupported(android::Hwc2::Composer::OptionalFeature::RefreshRateSwitching); } bool Display::hasDisplayIdleTimerCapability() const { bool isCapabilitySupported = false; return mComposer.hasDisplayIdleTimerCapability(mId, &isCapabilitySupported) == Error::NONE && isCapabilitySupported; } Error Display::getPhysicalDisplayOrientation(Hwc2::AidlTransform* outTransform) const { auto error = mComposer.getPhysicalDisplayOrientation(mId, outTransform); return static_cast(error); } Error Display::getChangedCompositionTypes(std::unordered_map* outTypes) { std::vector layerIds; std::vector types; auto intError = mComposer.getChangedCompositionTypes( mId, &layerIds, &types); uint32_t numElements = layerIds.size(); const auto error = static_cast(intError); if (error != Error::NONE) { return error; } outTypes->clear(); outTypes->reserve(numElements); for (uint32_t element = 0; element < numElements; ++element) { auto layer = getLayerById(layerIds[element]); if (layer) { auto type = types[element]; ALOGV("getChangedCompositionTypes: adding %" PRIu64 " %s", layer->getId(), to_string(type).c_str()); outTypes->emplace(layer.get(), type); } else { ALOGE("getChangedCompositionTypes: invalid layer %" PRIu64 " found" " on display %" PRIu64, layerIds[element], mId); } } return Error::NONE; } Error Display::getColorModes(std::vector* outModes) const { auto intError = mComposer.getColorModes(mId, outModes); return static_cast(intError); } int32_t Display::getSupportedPerFrameMetadata() const { int32_t supportedPerFrameMetadata = 0; std::vector tmpKeys = mComposer.getPerFrameMetadataKeys(mId); std::set keys(tmpKeys.begin(), tmpKeys.end()); // Check whether a specific metadata type is supported. A metadata type is considered // supported if and only if all required fields are supported. // SMPTE2086 if (hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_RED_PRIMARY_X) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_RED_PRIMARY_Y) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_X) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_Y) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_X) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_Y) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::WHITE_POINT_X) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::WHITE_POINT_Y) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::MAX_LUMINANCE) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::MIN_LUMINANCE)) { supportedPerFrameMetadata |= HdrMetadata::Type::SMPTE2086; } // CTA861_3 if (hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::MAX_CONTENT_LIGHT_LEVEL) && hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::MAX_FRAME_AVERAGE_LIGHT_LEVEL)) { supportedPerFrameMetadata |= HdrMetadata::Type::CTA861_3; } // HDR10PLUS if (hasMetadataKey(keys, Hwc2::PerFrameMetadataKey::HDR10_PLUS_SEI)) { supportedPerFrameMetadata |= HdrMetadata::Type::HDR10PLUS; } return supportedPerFrameMetadata; } Error Display::getRenderIntents(ColorMode colorMode, std::vector* outRenderIntents) const { auto intError = mComposer.getRenderIntents(mId, colorMode, outRenderIntents); return static_cast(intError); } Error Display::getDataspaceSaturationMatrix(Dataspace dataspace, android::mat4* outMatrix) { auto intError = mComposer.getDataspaceSaturationMatrix(dataspace, outMatrix); return static_cast(intError); } Error Display::getName(std::string* outName) const { auto intError = mComposer.getDisplayName(mId, outName); return static_cast(intError); } Error Display::getRequests(HWC2::DisplayRequest* outDisplayRequests, std::unordered_map* outLayerRequests) { uint32_t intDisplayRequests = 0; std::vector layerIds; std::vector layerRequests; auto intError = mComposer.getDisplayRequests( mId, &intDisplayRequests, &layerIds, &layerRequests); uint32_t numElements = layerIds.size(); auto error = static_cast(intError); if (error != Error::NONE) { return error; } *outDisplayRequests = static_cast(intDisplayRequests); outLayerRequests->clear(); outLayerRequests->reserve(numElements); for (uint32_t element = 0; element < numElements; ++element) { auto layer = getLayerById(layerIds[element]); if (layer) { auto layerRequest = static_cast(layerRequests[element]); outLayerRequests->emplace(layer.get(), layerRequest); } else { ALOGE("getRequests: invalid layer %" PRIu64 " found on display %" PRIu64, layerIds[element], mId); } } return Error::NONE; } ftl::Expected Display::getConnectionType() const { if (!mConnectionType) { mConnectionType = [this]() -> decltype(mConnectionType) { if (mType != DisplayType::PHYSICAL) { return ftl::Unexpected(Error::BAD_DISPLAY); } using ConnectionType = Hwc2::IComposerClient::DisplayConnectionType; ConnectionType connectionType; if (const auto error = static_cast( mComposer.getDisplayConnectionType(mId, &connectionType)); error != Error::NONE) { return ftl::Unexpected(error); } return connectionType == ConnectionType::INTERNAL ? ui::DisplayConnectionType::Internal : ui::DisplayConnectionType::External; }(); } return *mConnectionType; } bool Display::hasCapability(DisplayCapability capability) const { std::scoped_lock lock(mDisplayCapabilitiesMutex); if (mDisplayCapabilities) { return mDisplayCapabilities->count(capability) > 0; } ALOGW("Can't query capability %s." " Display Capabilities were not queried from HWC yet", to_string(capability).c_str()); return false; } Error Display::supportsDoze(bool* outSupport) const { { std::scoped_lock lock(mDisplayCapabilitiesMutex); if (!mDisplayCapabilities) { // The display has not turned on since boot, so DOZE support is unknown. ALOGW("%s: haven't queried capabilities yet!", __func__); return Error::NO_RESOURCES; } } *outSupport = hasCapability(DisplayCapability::DOZE); return Error::NONE; } Error Display::getHdrCapabilities(HdrCapabilities* outCapabilities) const { float maxLuminance = -1.0f; float maxAverageLuminance = -1.0f; float minLuminance = -1.0f; std::vector hdrTypes; auto intError = mComposer.getHdrCapabilities(mId, &hdrTypes, &maxLuminance, &maxAverageLuminance, &minLuminance); auto error = static_cast(intError); if (error != Error::NONE) { return error; } *outCapabilities = HdrCapabilities(std::move(hdrTypes), maxLuminance, maxAverageLuminance, minLuminance); return Error::NONE; } Error Display::getOverlaySupport(OverlayProperties* outProperties) const { auto intError = mComposer.getOverlaySupport(outProperties); return static_cast(intError); } Error Display::getDisplayedContentSamplingAttributes(hal::PixelFormat* outFormat, Dataspace* outDataspace, uint8_t* outComponentMask) const { auto intError = mComposer.getDisplayedContentSamplingAttributes(mId, outFormat, outDataspace, outComponentMask); return static_cast(intError); } Error Display::setDisplayContentSamplingEnabled(bool enabled, uint8_t componentMask, uint64_t maxFrames) const { auto intError = mComposer.setDisplayContentSamplingEnabled(mId, enabled, componentMask, maxFrames); return static_cast(intError); } Error Display::getDisplayedContentSample(uint64_t maxFrames, uint64_t timestamp, android::DisplayedFrameStats* outStats) const { auto intError = mComposer.getDisplayedContentSample(mId, maxFrames, timestamp, outStats); return static_cast(intError); } Error Display::getReleaseFences(std::unordered_map>* outFences) const { std::vector layerIds; std::vector fenceFds; auto intError = mComposer.getReleaseFences(mId, &layerIds, &fenceFds); auto error = static_cast(intError); uint32_t numElements = layerIds.size(); if (error != Error::NONE) { return error; } std::unordered_map> releaseFences; releaseFences.reserve(numElements); for (uint32_t element = 0; element < numElements; ++element) { auto layer = getLayerById(layerIds[element]); if (layer) { sp fence(sp::make(fenceFds[element])); releaseFences.emplace(layer.get(), fence); } else { ALOGE("getReleaseFences: invalid layer %" PRIu64 " found on display %" PRIu64, layerIds[element], mId); for (; element < numElements; ++element) { close(fenceFds[element]); } return Error::BAD_LAYER; } } *outFences = std::move(releaseFences); return Error::NONE; } Error Display::present(sp* outPresentFence) { int32_t presentFenceFd = -1; auto intError = mComposer.presentDisplay(mId, &presentFenceFd); auto error = static_cast(intError); if (error != Error::NONE) { return error; } *outPresentFence = sp::make(presentFenceFd); return Error::NONE; } Error Display::setActiveConfigWithConstraints(hal::HWConfigId configId, const VsyncPeriodChangeConstraints& constraints, VsyncPeriodChangeTimeline* outTimeline) { ALOGV("[%" PRIu64 "] setActiveConfigWithConstraints", mId); // FIXME (b/319505580): At least the first config set on an external display must be // `setActiveConfig`, so skip over the block that calls `setActiveConfigWithConstraints` // for simplicity. const bool connected_display = FlagManager::getInstance().connected_display(); if (isVsyncPeriodSwitchSupported() && (!connected_display || getConnectionType().value_opt() != ui::DisplayConnectionType::External)) { Hwc2::IComposerClient::VsyncPeriodChangeConstraints hwc2Constraints; hwc2Constraints.desiredTimeNanos = constraints.desiredTimeNanos; hwc2Constraints.seamlessRequired = constraints.seamlessRequired; Hwc2::VsyncPeriodChangeTimeline vsyncPeriodChangeTimeline = {}; auto intError = mComposer.setActiveConfigWithConstraints(mId, configId, hwc2Constraints, &vsyncPeriodChangeTimeline); outTimeline->newVsyncAppliedTimeNanos = vsyncPeriodChangeTimeline.newVsyncAppliedTimeNanos; outTimeline->refreshRequired = vsyncPeriodChangeTimeline.refreshRequired; outTimeline->refreshTimeNanos = vsyncPeriodChangeTimeline.refreshTimeNanos; return static_cast(intError); } // Use legacy setActiveConfig instead ALOGV("fallback to legacy setActiveConfig"); const auto now = systemTime(); if (constraints.desiredTimeNanos > now || constraints.seamlessRequired) { ALOGE("setActiveConfigWithConstraints received constraints that can't be satisfied"); } auto intError_2_4 = mComposer.setActiveConfig(mId, configId); outTimeline->newVsyncAppliedTimeNanos = std::max(now, constraints.desiredTimeNanos); outTimeline->refreshRequired = true; outTimeline->refreshTimeNanos = now; return static_cast(intError_2_4); } Error Display::setClientTarget(uint32_t slot, const sp& target, const sp& acquireFence, Dataspace dataspace, float hdrSdrRatio) { // TODO: Properly encode client target surface damage int32_t fenceFd = acquireFence->dup(); auto intError = mComposer.setClientTarget(mId, slot, target, fenceFd, dataspace, std::vector(), hdrSdrRatio); return static_cast(intError); } Error Display::setColorMode(ColorMode mode, RenderIntent renderIntent) { auto intError = mComposer.setColorMode(mId, mode, renderIntent); return static_cast(intError); } Error Display::setColorTransform(const android::mat4& matrix) { auto intError = mComposer.setColorTransform(mId, matrix.asArray()); return static_cast(intError); } Error Display::setOutputBuffer(const sp& buffer, const sp& releaseFence) { int32_t fenceFd = releaseFence->dup(); auto handle = buffer->getNativeBuffer()->handle; auto intError = mComposer.setOutputBuffer(mId, handle, fenceFd); close(fenceFd); return static_cast(intError); } Error Display::setPowerMode(PowerMode mode) { auto intMode = static_cast(mode); auto intError = mComposer.setPowerMode(mId, intMode); if (mode == PowerMode::ON) { loadDisplayCapabilities(); } return static_cast(intError); } Error Display::setVsyncEnabled(Vsync enabled) { auto intEnabled = static_cast(enabled); auto intError = mComposer.setVsyncEnabled(mId, intEnabled); return static_cast(intError); } Error Display::validate(nsecs_t expectedPresentTime, int32_t frameIntervalNs, uint32_t* outNumTypes, uint32_t* outNumRequests) { uint32_t numTypes = 0; uint32_t numRequests = 0; auto intError = mComposer.validateDisplay(mId, expectedPresentTime, frameIntervalNs, &numTypes, &numRequests); auto error = static_cast(intError); if (error != Error::NONE && !hasChangesError(error)) { return error; } *outNumTypes = numTypes; *outNumRequests = numRequests; return error; } Error Display::presentOrValidate(nsecs_t expectedPresentTime, int32_t frameIntervalNs, uint32_t* outNumTypes, uint32_t* outNumRequests, sp* outPresentFence, uint32_t* state) { uint32_t numTypes = 0; uint32_t numRequests = 0; int32_t presentFenceFd = -1; auto intError = mComposer.presentOrValidateDisplay(mId, expectedPresentTime, frameIntervalNs, &numTypes, &numRequests, &presentFenceFd, state); auto error = static_cast(intError); if (error != Error::NONE && !hasChangesError(error)) { return error; } if (*state == 1) { *outPresentFence = sp::make(presentFenceFd); } if (*state == 0) { *outNumTypes = numTypes; *outNumRequests = numRequests; } return error; } ftl::Future Display::setDisplayBrightness( float brightness, float brightnessNits, const Hwc2::Composer::DisplayBrightnessOptions& options) { return ftl::defer([composer = &mComposer, id = mId, brightness, brightnessNits, options] { const auto intError = composer->setDisplayBrightness(id, brightness, brightnessNits, options); return static_cast(intError); }); } Error Display::setBootDisplayConfig(hal::HWConfigId configId) { auto intError = mComposer.setBootDisplayConfig(mId, configId); return static_cast(intError); } Error Display::clearBootDisplayConfig() { auto intError = mComposer.clearBootDisplayConfig(mId); return static_cast(intError); } Error Display::getPreferredBootDisplayConfig(hal::HWConfigId* configId) const { auto intError = mComposer.getPreferredBootDisplayConfig(mId, configId); return static_cast(intError); } Error Display::setAutoLowLatencyMode(bool on) { auto intError = mComposer.setAutoLowLatencyMode(mId, on); return static_cast(intError); } Error Display::getSupportedContentTypes(std::vector* outSupportedContentTypes) const { std::vector tmpSupportedContentTypes; auto intError = mComposer.getSupportedContentTypes(mId, &tmpSupportedContentTypes); for (Hwc2::IComposerClient::ContentType contentType : tmpSupportedContentTypes) { outSupportedContentTypes->push_back(static_cast(contentType)); } return static_cast(intError); } Error Display::setContentType(ContentType contentType) { auto intError = mComposer.setContentType(mId, contentType); return static_cast(intError); } Error Display::getClientTargetProperty( aidl::android::hardware::graphics::composer3::ClientTargetPropertyWithBrightness* outClientTargetProperty) { const auto error = mComposer.getClientTargetProperty(mId, outClientTargetProperty); return static_cast(error); } Error Display::getDisplayDecorationSupport( std::optional* support) { const auto error = mComposer.getDisplayDecorationSupport(mId, support); return static_cast(error); } Error Display::setIdleTimerEnabled(std::chrono::milliseconds timeout) { const auto error = mComposer.setIdleTimerEnabled(mId, timeout); return static_cast(error); } // For use by Device void Display::setConnected(bool connected) { if (!mIsConnected && connected) { mComposer.setClientTargetSlotCount(mId); } mIsConnected = connected; } // Other Display methods std::shared_ptr Display::getLayerById(HWLayerId id) const { auto it = mLayers.find(id); return it != mLayers.end() ? it->second.lock() : nullptr; } void Display::loadDisplayCapabilities() { std::call_once(mDisplayCapabilityQueryFlag, [this]() { std::vector tmpCapabilities; auto error = static_cast(mComposer.getDisplayCapabilities(mId, &tmpCapabilities)); if (error == Error::NONE) { std::scoped_lock lock(mDisplayCapabilitiesMutex); mDisplayCapabilities.emplace(); for (auto capability : tmpCapabilities) { mDisplayCapabilities->emplace(capability); } } else if (error == Error::UNSUPPORTED) { std::scoped_lock lock(mDisplayCapabilitiesMutex); mDisplayCapabilities.emplace(); if (mCapabilities.count(AidlCapability::SKIP_CLIENT_COLOR_TRANSFORM)) { mDisplayCapabilities->emplace(DisplayCapability::SKIP_CLIENT_COLOR_TRANSFORM); } bool dozeSupport = false; error = static_cast(mComposer.getDozeSupport(mId, &dozeSupport)); if (error == Error::NONE && dozeSupport) { mDisplayCapabilities->emplace(DisplayCapability::DOZE); } } }); } } // namespace impl // Layer methods namespace { std::vector convertRegionToHwcRects(const Region& region) { size_t rectCount = 0; Rect const* rectArray = region.getArray(&rectCount); std::vector hwcRects; hwcRects.reserve(rectCount); for (size_t rect = 0; rect < rectCount; ++rect) { hwcRects.push_back({rectArray[rect].left, rectArray[rect].top, rectArray[rect].right, rectArray[rect].bottom}); } return hwcRects; } } // namespace Layer::~Layer() = default; namespace impl { Layer::Layer(android::Hwc2::Composer& composer, const std::unordered_set& capabilities, HWC2::Display& display, HWLayerId layerId) : mComposer(composer), mCapabilities(capabilities), mDisplay(&display), mId(layerId), mColorMatrix(android::mat4()) { ALOGV("Created layer %" PRIu64 " on display %" PRIu64, layerId, display.getId()); } Layer::~Layer() { onOwningDisplayDestroyed(); } void Layer::onOwningDisplayDestroyed() { // Note: onOwningDisplayDestroyed() may be called to perform cleanup by // either the Layer dtor or by the Display dtor and must be safe to call // from either path. In particular, the call to Display::onLayerDestroyed() // is expected to be safe to do, if (CC_UNLIKELY(!mDisplay)) { return; } mDisplay->onLayerDestroyed(mId); // Note: If the HWC display was actually disconnected, these calls are will // return an error. We always make them as there may be other reasons for // the HWC2::Display to be destroyed. auto intError = mComposer.destroyLayer(mDisplay->getId(), mId); auto error = static_cast(intError); ALOGE_IF(error != Error::NONE, "destroyLayer(%" PRIu64 ", %" PRIu64 ")" " failed: %s (%d)", mDisplay->getId(), mId, to_string(error).c_str(), intError); mDisplay = nullptr; } Error Layer::setCursorPosition(int32_t x, int32_t y) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setCursorPosition(mDisplay->getId(), mId, x, y); return static_cast(intError); } Error Layer::setBuffer(uint32_t slot, const sp& buffer, const sp& acquireFence) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (buffer == nullptr && mBufferSlot == slot) { return Error::NONE; } mBufferSlot = slot; int32_t fenceFd = acquireFence->dup(); auto intError = mComposer.setLayerBuffer(mDisplay->getId(), mId, slot, buffer, fenceFd); return static_cast(intError); } Error Layer::setBufferSlotsToClear(const std::vector& slotsToClear, uint32_t activeBufferSlot) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerBufferSlotsToClear(mDisplay->getId(), mId, slotsToClear, activeBufferSlot); return static_cast(intError); } Error Layer::setSurfaceDamage(const Region& damage) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (damage.isRect() && mDamageRegion.isRect() && (damage.getBounds() == mDamageRegion.getBounds())) { return Error::NONE; } mDamageRegion = damage; // We encode default full-screen damage as INVALID_RECT upstream, but as 0 // rects for HWC Hwc2::Error intError = Hwc2::Error::NONE; if (damage.isRect() && damage.getBounds() == Rect::INVALID_RECT) { intError = mComposer.setLayerSurfaceDamage(mDisplay->getId(), mId, std::vector()); } else { const auto hwcRects = convertRegionToHwcRects(damage); intError = mComposer.setLayerSurfaceDamage(mDisplay->getId(), mId, hwcRects); } return static_cast(intError); } Error Layer::setBlendMode(BlendMode mode) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerBlendMode(mDisplay->getId(), mId, mode); return static_cast(intError); } Error Layer::setColor(Color color) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerColor(mDisplay->getId(), mId, color); return static_cast(intError); } Error Layer::setCompositionType(Composition type) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerCompositionType(mDisplay->getId(), mId, type); return static_cast(intError); } Error Layer::setDataspace(Dataspace dataspace) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (dataspace == mDataSpace) { return Error::NONE; } mDataSpace = dataspace; auto intError = mComposer.setLayerDataspace(mDisplay->getId(), mId, mDataSpace); return static_cast(intError); } Error Layer::setPerFrameMetadata(const int32_t supportedPerFrameMetadata, const android::HdrMetadata& metadata) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (metadata == mHdrMetadata) { return Error::NONE; } mHdrMetadata = metadata; int validTypes = mHdrMetadata.validTypes & supportedPerFrameMetadata; std::vector perFrameMetadatas; if (validTypes & HdrMetadata::SMPTE2086) { perFrameMetadatas.insert(perFrameMetadatas.end(), {{Hwc2::PerFrameMetadataKey::DISPLAY_RED_PRIMARY_X, mHdrMetadata.smpte2086.displayPrimaryRed.x}, {Hwc2::PerFrameMetadataKey::DISPLAY_RED_PRIMARY_Y, mHdrMetadata.smpte2086.displayPrimaryRed.y}, {Hwc2::PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_X, mHdrMetadata.smpte2086.displayPrimaryGreen.x}, {Hwc2::PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_Y, mHdrMetadata.smpte2086.displayPrimaryGreen.y}, {Hwc2::PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_X, mHdrMetadata.smpte2086.displayPrimaryBlue.x}, {Hwc2::PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_Y, mHdrMetadata.smpte2086.displayPrimaryBlue.y}, {Hwc2::PerFrameMetadataKey::WHITE_POINT_X, mHdrMetadata.smpte2086.whitePoint.x}, {Hwc2::PerFrameMetadataKey::WHITE_POINT_Y, mHdrMetadata.smpte2086.whitePoint.y}, {Hwc2::PerFrameMetadataKey::MAX_LUMINANCE, mHdrMetadata.smpte2086.maxLuminance}, {Hwc2::PerFrameMetadataKey::MIN_LUMINANCE, mHdrMetadata.smpte2086.minLuminance}}); } if (validTypes & HdrMetadata::CTA861_3) { perFrameMetadatas.insert(perFrameMetadatas.end(), {{Hwc2::PerFrameMetadataKey::MAX_CONTENT_LIGHT_LEVEL, mHdrMetadata.cta8613.maxContentLightLevel}, {Hwc2::PerFrameMetadataKey::MAX_FRAME_AVERAGE_LIGHT_LEVEL, mHdrMetadata.cta8613.maxFrameAverageLightLevel}}); } const Error error = static_cast( mComposer.setLayerPerFrameMetadata(mDisplay->getId(), mId, perFrameMetadatas)); if (error != Error::NONE) { return error; } std::vector perFrameMetadataBlobs; if (validTypes & HdrMetadata::HDR10PLUS) { if (CC_UNLIKELY(mHdrMetadata.hdr10plus.size() == 0)) { return Error::BAD_PARAMETER; } perFrameMetadataBlobs.push_back( {Hwc2::PerFrameMetadataKey::HDR10_PLUS_SEI, mHdrMetadata.hdr10plus}); } return static_cast( mComposer.setLayerPerFrameMetadataBlobs(mDisplay->getId(), mId, perFrameMetadataBlobs)); } Error Layer::setDisplayFrame(const Rect& frame) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } Hwc2::IComposerClient::Rect hwcRect{frame.left, frame.top, frame.right, frame.bottom}; auto intError = mComposer.setLayerDisplayFrame(mDisplay->getId(), mId, hwcRect); return static_cast(intError); } Error Layer::setPlaneAlpha(float alpha) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerPlaneAlpha(mDisplay->getId(), mId, alpha); return static_cast(intError); } Error Layer::setSidebandStream(const native_handle_t* stream) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (mCapabilities.count(AidlCapability::SIDEBAND_STREAM) == 0) { ALOGE("Attempted to call setSidebandStream without checking that the " "device supports sideband streams"); return Error::UNSUPPORTED; } auto intError = mComposer.setLayerSidebandStream(mDisplay->getId(), mId, stream); return static_cast(intError); } Error Layer::setSourceCrop(const FloatRect& crop) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } Hwc2::IComposerClient::FRect hwcRect{ crop.left, crop.top, crop.right, crop.bottom}; auto intError = mComposer.setLayerSourceCrop(mDisplay->getId(), mId, hwcRect); return static_cast(intError); } Error Layer::setTransform(Transform transform) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intTransform = static_cast(transform); auto intError = mComposer.setLayerTransform(mDisplay->getId(), mId, intTransform); return static_cast(intError); } Error Layer::setVisibleRegion(const Region& region) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (region.isRect() && mVisibleRegion.isRect() && (region.getBounds() == mVisibleRegion.getBounds())) { return Error::NONE; } mVisibleRegion = region; const auto hwcRects = convertRegionToHwcRects(region); auto intError = mComposer.setLayerVisibleRegion(mDisplay->getId(), mId, hwcRects); return static_cast(intError); } Error Layer::setZOrder(uint32_t z) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerZOrder(mDisplay->getId(), mId, z); return static_cast(intError); } // Composer HAL 2.3 Error Layer::setColorTransform(const android::mat4& matrix) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (matrix == mColorMatrix) { return Error::NONE; } auto intError = mComposer.setLayerColorTransform(mDisplay->getId(), mId, matrix.asArray()); Error error = static_cast(intError); if (error != Error::NONE) { return error; } mColorMatrix = matrix; return error; } // Composer HAL 2.4 Error Layer::setLayerGenericMetadata(const std::string& name, bool mandatory, const std::vector& value) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerGenericMetadata(mDisplay->getId(), mId, name, mandatory, value); return static_cast(intError); } // AIDL HAL Error Layer::setBrightness(float brightness) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } auto intError = mComposer.setLayerBrightness(mDisplay->getId(), mId, brightness); return static_cast(intError); } Error Layer::setBlockingRegion(const Region& region) { if (CC_UNLIKELY(!mDisplay)) { return Error::BAD_DISPLAY; } if (region.isRect() && mBlockingRegion.isRect() && (region.getBounds() == mBlockingRegion.getBounds())) { return Error::NONE; } mBlockingRegion = region; const auto hwcRects = convertRegionToHwcRects(region); const auto intError = mComposer.setLayerBlockingRegion(mDisplay->getId(), mId, hwcRects); return static_cast(intError); } } // namespace impl } // namespace HWC2 } // namespace android // TODO(b/129481165): remove the #pragma below and fix conversion issues #pragma clang diagnostic pop // ignored "-Wconversion"