/* * Copyright (C) 2010 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 LOG_NDEBUG 0 #undef LOG_TAG #define LOG_TAG "HWComposer" #define ATRACE_TAG ATRACE_TAG_GRAPHICS #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "HWComposer.h" #include "HWC2.h" #include "ComposerHal.h" #include "../Layer.h" // needed only for debugging #include "../SurfaceFlinger.h" #define LOG_DISPLAY_ERROR(displayId, msg) \ ALOGE("%s failed for display %d: %s", __FUNCTION__, displayId, msg) #define LOG_HWC_ERROR(what, error, displayId) \ ALOGE("%s: %s failed for display %d: %s (%d)", __FUNCTION__, what, displayId, \ to_string(error).c_str(), static_cast(error)) #define RETURN_IF_INVALID_DISPLAY(displayId, ...) \ do { \ if (!isValidDisplay(displayId)) { \ LOG_DISPLAY_ERROR(displayId, "Invalid display"); \ return __VA_ARGS__; \ } \ } while (false) #define RETURN_IF_HWC_ERROR_FOR(what, error, displayId, ...) \ do { \ if (error != HWC2::Error::None) { \ LOG_HWC_ERROR(what, error, displayId); \ return __VA_ARGS__; \ } \ } while (false) #define RETURN_IF_HWC_ERROR(error, displayId, ...) \ RETURN_IF_HWC_ERROR_FOR(__FUNCTION__, error, displayId, __VA_ARGS__) namespace android { #define MIN_HWC_HEADER_VERSION HWC_HEADER_VERSION // --------------------------------------------------------------------------- HWComposer::HWComposer(std::unique_ptr composer) : mHwcDevice(std::make_unique(std::move(composer))) {} HWComposer::~HWComposer() = default; void HWComposer::registerCallback(HWC2::ComposerCallback* callback, int32_t sequenceId) { mHwcDevice->registerCallback(callback, sequenceId); } bool HWComposer::hasCapability(HWC2::Capability capability) const { return mHwcDevice->getCapabilities().count(capability) > 0; } bool HWComposer::isValidDisplay(int32_t displayId) const { return static_cast(displayId) < mDisplayData.size() && mDisplayData[displayId].hwcDisplay; } void HWComposer::validateChange(HWC2::Composition from, HWC2::Composition to) { bool valid = true; switch (from) { case HWC2::Composition::Client: valid = false; break; case HWC2::Composition::Device: case HWC2::Composition::SolidColor: valid = (to == HWC2::Composition::Client); break; case HWC2::Composition::Cursor: case HWC2::Composition::Sideband: valid = (to == HWC2::Composition::Client || to == HWC2::Composition::Device); break; default: break; } if (!valid) { ALOGE("Invalid layer type change: %s --> %s", to_string(from).c_str(), to_string(to).c_str()); } } void HWComposer::onHotplug(hwc2_display_t displayId, int32_t displayType, HWC2::Connection connection) { if (displayType >= HWC_NUM_PHYSICAL_DISPLAY_TYPES) { ALOGE("Invalid display type of %d", displayType); return; } ALOGV("hotplug: %" PRIu64 ", %s %s", displayId, displayType == DisplayDevice::DISPLAY_PRIMARY ? "primary" : "external", to_string(connection).c_str()); mHwcDevice->onHotplug(displayId, connection); // Disconnect is handled through HWComposer::disconnectDisplay via // SurfaceFlinger's onHotplugReceived callback handling if (connection == HWC2::Connection::Connected) { mDisplayData[displayType].hwcDisplay = mHwcDevice->getDisplayById(displayId); mHwcDisplaySlots[displayId] = displayType; } } bool HWComposer::onVsync(hwc2_display_t displayId, int64_t timestamp, int32_t* outDisplay) { auto display = mHwcDevice->getDisplayById(displayId); if (!display) { ALOGE("onVsync Failed to find display %" PRIu64, displayId); return false; } auto displayType = HWC2::DisplayType::Invalid; auto error = display->getType(&displayType); if (error != HWC2::Error::None) { ALOGE("onVsync: Failed to determine type of display %" PRIu64, display->getId()); return false; } if (displayType == HWC2::DisplayType::Virtual) { ALOGE("Virtual display %" PRIu64 " passed to vsync callback", display->getId()); return false; } if (mHwcDisplaySlots.count(display->getId()) == 0) { ALOGE("Unknown physical display %" PRIu64 " passed to vsync callback", display->getId()); return false; } int32_t disp = mHwcDisplaySlots[display->getId()]; { Mutex::Autolock _l(mLock); // There have been reports of HWCs that signal several vsync events // with the same timestamp when turning the display off and on. This // is a bug in the HWC implementation, but filter the extra events // out here so they don't cause havoc downstream. if (timestamp == mLastHwVSync[disp]) { ALOGW("Ignoring duplicate VSYNC event from HWC (t=%" PRId64 ")", timestamp); return false; } mLastHwVSync[disp] = timestamp; } if (outDisplay) { *outDisplay = disp; } char tag[16]; snprintf(tag, sizeof(tag), "HW_VSYNC_%1u", disp); ATRACE_INT(tag, ++mVSyncCounts[disp] & 1); return true; } status_t HWComposer::allocateVirtualDisplay(uint32_t width, uint32_t height, ui::PixelFormat* format, int32_t *outId) { if (mRemainingHwcVirtualDisplays == 0) { ALOGE("allocateVirtualDisplay: No remaining virtual displays"); return NO_MEMORY; } if (SurfaceFlinger::maxVirtualDisplaySize != 0 && (width > SurfaceFlinger::maxVirtualDisplaySize || height > SurfaceFlinger::maxVirtualDisplaySize)) { ALOGE("createVirtualDisplay: Can't create a virtual display with" " a dimension > %" PRIu64 " (tried %u x %u)", SurfaceFlinger::maxVirtualDisplaySize, width, height); return INVALID_OPERATION; } HWC2::Display* display; auto error = mHwcDevice->createVirtualDisplay(width, height, format, &display); if (error != HWC2::Error::None) { ALOGE("allocateVirtualDisplay: Failed to create HWC virtual display"); return NO_MEMORY; } size_t displaySlot = 0; if (!mFreeDisplaySlots.empty()) { displaySlot = *mFreeDisplaySlots.begin(); mFreeDisplaySlots.erase(displaySlot); } else if (mDisplayData.size() < INT32_MAX) { // Don't bother allocating a slot larger than we can return displaySlot = mDisplayData.size(); mDisplayData.resize(displaySlot + 1); } else { ALOGE("allocateVirtualDisplay: Unable to allocate a display slot"); return NO_MEMORY; } mDisplayData[displaySlot].hwcDisplay = display; --mRemainingHwcVirtualDisplays; *outId = static_cast(displaySlot); return NO_ERROR; } HWC2::Layer* HWComposer::createLayer(int32_t displayId) { RETURN_IF_INVALID_DISPLAY(displayId, nullptr); auto display = mDisplayData[displayId].hwcDisplay; HWC2::Layer* layer; auto error = display->createLayer(&layer); RETURN_IF_HWC_ERROR(error, displayId, nullptr); return layer; } void HWComposer::destroyLayer(int32_t displayId, HWC2::Layer* layer) { RETURN_IF_INVALID_DISPLAY(displayId); auto display = mDisplayData[displayId].hwcDisplay; auto error = display->destroyLayer(layer); RETURN_IF_HWC_ERROR(error, displayId); } nsecs_t HWComposer::getRefreshTimestamp(int32_t displayId) const { // this returns the last refresh timestamp. // if the last one is not available, we estimate it based on // the refresh period and whatever closest timestamp we have. Mutex::Autolock _l(mLock); nsecs_t now = systemTime(CLOCK_MONOTONIC); auto vsyncPeriod = getActiveConfig(displayId)->getVsyncPeriod(); return now - ((now - mLastHwVSync[displayId]) % vsyncPeriod); } bool HWComposer::isConnected(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, false); return mDisplayData[displayId].hwcDisplay->isConnected(); } std::vector> HWComposer::getConfigs(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, {}); auto& displayData = mDisplayData[displayId]; auto configs = mDisplayData[displayId].hwcDisplay->getConfigs(); if (displayData.configMap.empty()) { for (size_t i = 0; i < configs.size(); ++i) { displayData.configMap[i] = configs[i]; } } return configs; } std::shared_ptr HWComposer::getActiveConfig(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, nullptr); std::shared_ptr config; auto error = mDisplayData[displayId].hwcDisplay->getActiveConfig(&config); if (error == HWC2::Error::BadConfig) { LOG_DISPLAY_ERROR(displayId, "No active config"); return nullptr; } RETURN_IF_HWC_ERROR(error, displayId, nullptr); if (!config) { LOG_DISPLAY_ERROR(displayId, "Unknown config"); return nullptr; } return config; } int HWComposer::getActiveConfigIndex(int32_t displayId) const { if (!isValidDisplay(displayId)) { ALOGV("getActiveConfigIndex: Attempted to access invalid display %d", displayId); return -1; } int index; auto error = mDisplayData[displayId].hwcDisplay->getActiveConfigIndex(&index); if (error == HWC2::Error::BadConfig) { ALOGE("getActiveConfigIndex: No config active, returning -1"); return -1; } else if (error != HWC2::Error::None) { ALOGE("getActiveConfigIndex failed for display %d: %s (%d)", displayId, to_string(error).c_str(), static_cast(error)); return -1; } else if (index < 0) { ALOGE("getActiveConfigIndex returned an unknown config for display %d", displayId); return -1; } return index; } std::vector HWComposer::getColorModes(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, {}); std::vector modes; auto error = mDisplayData[displayId].hwcDisplay->getColorModes(&modes); RETURN_IF_HWC_ERROR(error, displayId, {}); return modes; } status_t HWComposer::setActiveColorMode(int32_t displayId, ui::ColorMode mode, ui::RenderIntent renderIntent) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& displayData = mDisplayData[displayId]; auto error = displayData.hwcDisplay->setColorMode(mode, renderIntent); RETURN_IF_HWC_ERROR_FOR(("setColorMode(" + decodeColorMode(mode) + ", " + decodeRenderIntent(renderIntent) + ")") .c_str(), error, displayId, UNKNOWN_ERROR); return NO_ERROR; } void HWComposer::setVsyncEnabled(int32_t displayId, HWC2::Vsync enabled) { if (displayId < 0 || displayId >= HWC_DISPLAY_VIRTUAL) { ALOGD("setVsyncEnabled: Ignoring for virtual display %d", displayId); return; } RETURN_IF_INVALID_DISPLAY(displayId); // NOTE: we use our own internal lock here because we have to call // into the HWC with the lock held, and we want to make sure // that even if HWC blocks (which it shouldn't), it won't // affect other threads. Mutex::Autolock _l(mVsyncLock); auto& displayData = mDisplayData[displayId]; if (enabled != displayData.vsyncEnabled) { ATRACE_CALL(); auto error = displayData.hwcDisplay->setVsyncEnabled(enabled); RETURN_IF_HWC_ERROR(error, displayId); displayData.vsyncEnabled = enabled; char tag[16]; snprintf(tag, sizeof(tag), "HW_VSYNC_ON_%1u", displayId); ATRACE_INT(tag, enabled == HWC2::Vsync::Enable ? 1 : 0); } } status_t HWComposer::setClientTarget(int32_t displayId, uint32_t slot, const sp& acquireFence, const sp& target, ui::Dataspace dataspace) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); ALOGV("setClientTarget for display %d", displayId); auto& hwcDisplay = mDisplayData[displayId].hwcDisplay; auto error = hwcDisplay->setClientTarget(slot, target, acquireFence, dataspace); RETURN_IF_HWC_ERROR(error, displayId, BAD_VALUE); return NO_ERROR; } status_t HWComposer::prepare(DisplayDevice& displayDevice) { ATRACE_CALL(); Mutex::Autolock _l(mDisplayLock); auto displayId = displayDevice.getHwcDisplayId(); if (displayId == DisplayDevice::DISPLAY_ID_INVALID) { ALOGV("Skipping HWComposer prepare for non-HWC display"); return NO_ERROR; } RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& displayData = mDisplayData[displayId]; auto& hwcDisplay = displayData.hwcDisplay; if (!hwcDisplay->isConnected()) { return NO_ERROR; } uint32_t numTypes = 0; uint32_t numRequests = 0; HWC2::Error error = HWC2::Error::None; // First try to skip validate altogether when there is no client // composition. When there is client composition, since we haven't // rendered to the client target yet, we should not attempt to skip // validate. // // displayData.hasClientComposition hasn't been updated for this frame. // The check below is incorrect. We actually rely on HWC here to fall // back to validate when there is any client layer. displayData.validateWasSkipped = false; if (!displayData.hasClientComposition) { sp outPresentFence; uint32_t state = UINT32_MAX; error = hwcDisplay->presentOrValidate(&numTypes, &numRequests, &outPresentFence , &state); if (error != HWC2::Error::HasChanges) { RETURN_IF_HWC_ERROR_FOR("presentOrValidate", error, displayId, UNKNOWN_ERROR); } if (state == 1) { //Present Succeeded. std::unordered_map> releaseFences; error = hwcDisplay->getReleaseFences(&releaseFences); displayData.releaseFences = std::move(releaseFences); displayData.lastPresentFence = outPresentFence; displayData.validateWasSkipped = true; displayData.presentError = error; return NO_ERROR; } // Present failed but Validate ran. } else { error = hwcDisplay->validate(&numTypes, &numRequests); } ALOGV("SkipValidate failed, Falling back to SLOW validate/present"); if (error != HWC2::Error::HasChanges) { RETURN_IF_HWC_ERROR_FOR("validate", error, displayId, BAD_INDEX); } std::unordered_map changedTypes; changedTypes.reserve(numTypes); error = hwcDisplay->getChangedCompositionTypes(&changedTypes); RETURN_IF_HWC_ERROR_FOR("getChangedCompositionTypes", error, displayId, BAD_INDEX); displayData.displayRequests = static_cast(0); std::unordered_map layerRequests; layerRequests.reserve(numRequests); error = hwcDisplay->getRequests(&displayData.displayRequests, &layerRequests); RETURN_IF_HWC_ERROR_FOR("getRequests", error, displayId, BAD_INDEX); displayData.hasClientComposition = false; displayData.hasDeviceComposition = false; for (auto& layer : displayDevice.getVisibleLayersSortedByZ()) { auto hwcLayer = layer->getHwcLayer(displayId); if (changedTypes.count(hwcLayer) != 0) { // We pass false so we only update our state and don't call back // into the HWC device validateChange(layer->getCompositionType(displayId), changedTypes[hwcLayer]); layer->setCompositionType(displayId, changedTypes[hwcLayer], false); } switch (layer->getCompositionType(displayId)) { case HWC2::Composition::Client: displayData.hasClientComposition = true; break; case HWC2::Composition::Device: case HWC2::Composition::SolidColor: case HWC2::Composition::Cursor: case HWC2::Composition::Sideband: displayData.hasDeviceComposition = true; break; default: break; } if (layerRequests.count(hwcLayer) != 0 && layerRequests[hwcLayer] == HWC2::LayerRequest::ClearClientTarget) { layer->setClearClientTarget(displayId, true); } else { if (layerRequests.count(hwcLayer) != 0) { LOG_DISPLAY_ERROR(displayId, ("Unknown layer request " + to_string(layerRequests[hwcLayer])) .c_str()); } layer->setClearClientTarget(displayId, false); } } error = hwcDisplay->acceptChanges(); RETURN_IF_HWC_ERROR_FOR("acceptChanges", error, displayId, BAD_INDEX); return NO_ERROR; } bool HWComposer::hasDeviceComposition(int32_t displayId) const { if (displayId == DisplayDevice::DISPLAY_ID_INVALID) { // Displays without a corresponding HWC display are never composed by // the device return false; } RETURN_IF_INVALID_DISPLAY(displayId, false); return mDisplayData[displayId].hasDeviceComposition; } bool HWComposer::hasFlipClientTargetRequest(int32_t displayId) const { if (displayId == DisplayDevice::DISPLAY_ID_INVALID) { // Displays without a corresponding HWC display are never composed by // the device return false; } RETURN_IF_INVALID_DISPLAY(displayId, false); return ((static_cast(mDisplayData[displayId].displayRequests) & static_cast(HWC2::DisplayRequest::FlipClientTarget)) != 0); } bool HWComposer::hasClientComposition(int32_t displayId) const { if (displayId == DisplayDevice::DISPLAY_ID_INVALID) { // Displays without a corresponding HWC display are always composed by // the client return true; } RETURN_IF_INVALID_DISPLAY(displayId, true); return mDisplayData[displayId].hasClientComposition; } sp HWComposer::getPresentFence(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, Fence::NO_FENCE); return mDisplayData[displayId].lastPresentFence; } sp HWComposer::getLayerReleaseFence(int32_t displayId, HWC2::Layer* layer) const { RETURN_IF_INVALID_DISPLAY(displayId, Fence::NO_FENCE); auto displayFences = mDisplayData[displayId].releaseFences; if (displayFences.count(layer) == 0) { ALOGV("getLayerReleaseFence: Release fence not found"); return Fence::NO_FENCE; } return displayFences[layer]; } status_t HWComposer::presentAndGetReleaseFences(int32_t displayId) { ATRACE_CALL(); RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& displayData = mDisplayData[displayId]; auto& hwcDisplay = displayData.hwcDisplay; if (displayData.validateWasSkipped) { // explicitly flush all pending commands auto error = mHwcDevice->flushCommands(); RETURN_IF_HWC_ERROR_FOR("flushCommands", error, displayId, UNKNOWN_ERROR); RETURN_IF_HWC_ERROR_FOR("present", displayData.presentError, displayId, UNKNOWN_ERROR); return NO_ERROR; } auto error = hwcDisplay->present(&displayData.lastPresentFence); RETURN_IF_HWC_ERROR_FOR("present", error, displayId, UNKNOWN_ERROR); std::unordered_map> releaseFences; error = hwcDisplay->getReleaseFences(&releaseFences); RETURN_IF_HWC_ERROR_FOR("getReleaseFences", error, displayId, UNKNOWN_ERROR); displayData.releaseFences = std::move(releaseFences); return NO_ERROR; } status_t HWComposer::setPowerMode(int32_t displayId, int32_t intMode) { ALOGV("setPowerMode(%d, %d)", displayId, intMode); RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); if (displayId >= VIRTUAL_DISPLAY_ID_BASE) { LOG_DISPLAY_ERROR(displayId, "Invalid operation on virtual display"); return INVALID_OPERATION; } auto mode = static_cast(intMode); if (mode == HWC2::PowerMode::Off) { setVsyncEnabled(displayId, HWC2::Vsync::Disable); } auto& hwcDisplay = mDisplayData[displayId].hwcDisplay; switch (mode) { case HWC2::PowerMode::Off: case HWC2::PowerMode::On: ALOGV("setPowerMode: Calling HWC %s", to_string(mode).c_str()); { auto error = hwcDisplay->setPowerMode(mode); if (error != HWC2::Error::None) { LOG_HWC_ERROR(("setPowerMode(" + to_string(mode) + ")").c_str(), error, displayId); } } break; case HWC2::PowerMode::Doze: case HWC2::PowerMode::DozeSuspend: ALOGV("setPowerMode: Calling HWC %s", to_string(mode).c_str()); { bool supportsDoze = false; auto error = hwcDisplay->supportsDoze(&supportsDoze); if (error != HWC2::Error::None) { LOG_HWC_ERROR("supportsDoze", error, displayId); } if (!supportsDoze) { mode = HWC2::PowerMode::On; } error = hwcDisplay->setPowerMode(mode); if (error != HWC2::Error::None) { LOG_HWC_ERROR(("setPowerMode(" + to_string(mode) + ")").c_str(), error, displayId); } } break; default: ALOGV("setPowerMode: Not calling HWC"); break; } return NO_ERROR; } status_t HWComposer::setActiveConfig(int32_t displayId, size_t configId) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& displayData = mDisplayData[displayId]; if (displayData.configMap.count(configId) == 0) { LOG_DISPLAY_ERROR(displayId, ("Invalid config " + std::to_string(configId)).c_str()); return BAD_INDEX; } auto error = displayData.hwcDisplay->setActiveConfig(displayData.configMap[configId]); RETURN_IF_HWC_ERROR(error, displayId, UNKNOWN_ERROR); return NO_ERROR; } status_t HWComposer::setColorTransform(int32_t displayId, const mat4& transform) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& displayData = mDisplayData[displayId]; bool isIdentity = transform == mat4(); auto error = displayData.hwcDisplay->setColorTransform(transform, isIdentity ? HAL_COLOR_TRANSFORM_IDENTITY : HAL_COLOR_TRANSFORM_ARBITRARY_MATRIX); RETURN_IF_HWC_ERROR(error, displayId, UNKNOWN_ERROR); return NO_ERROR; } void HWComposer::disconnectDisplay(int displayId) { LOG_ALWAYS_FATAL_IF(displayId < 0); auto& displayData = mDisplayData[displayId]; auto displayType = HWC2::DisplayType::Invalid; auto error = displayData.hwcDisplay->getType(&displayType); RETURN_IF_HWC_ERROR_FOR("getType", error, displayId); // If this was a virtual display, add its slot back for reuse by future // virtual displays if (displayType == HWC2::DisplayType::Virtual) { mFreeDisplaySlots.insert(displayId); ++mRemainingHwcVirtualDisplays; } auto hwcId = displayData.hwcDisplay->getId(); mHwcDisplaySlots.erase(hwcId); displayData.reset(); mHwcDevice->destroyDisplay(hwcId); } status_t HWComposer::setOutputBuffer(int32_t displayId, const sp& acquireFence, const sp& buffer) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& hwcDisplay = mDisplayData[displayId].hwcDisplay; auto displayType = HWC2::DisplayType::Invalid; auto error = hwcDisplay->getType(&displayType); RETURN_IF_HWC_ERROR_FOR("getType", error, displayId, NAME_NOT_FOUND); if (displayType != HWC2::DisplayType::Virtual) { LOG_DISPLAY_ERROR(displayId, "Invalid operation on physical display"); return INVALID_OPERATION; } error = hwcDisplay->setOutputBuffer(buffer, acquireFence); RETURN_IF_HWC_ERROR(error, displayId, UNKNOWN_ERROR); return NO_ERROR; } void HWComposer::clearReleaseFences(int32_t displayId) { RETURN_IF_INVALID_DISPLAY(displayId); mDisplayData[displayId].releaseFences.clear(); } status_t HWComposer::getHdrCapabilities( int32_t displayId, HdrCapabilities* outCapabilities) { RETURN_IF_INVALID_DISPLAY(displayId, BAD_INDEX); auto& hwcDisplay = mDisplayData[displayId].hwcDisplay; auto error = hwcDisplay->getHdrCapabilities(outCapabilities); RETURN_IF_HWC_ERROR(error, displayId, UNKNOWN_ERROR); return NO_ERROR; } int32_t HWComposer::getSupportedPerFrameMetadata(int32_t displayId) const { RETURN_IF_INVALID_DISPLAY(displayId, 0); int32_t supportedMetadata; auto error = mDisplayData[displayId].hwcDisplay->getSupportedPerFrameMetadata( &supportedMetadata); RETURN_IF_HWC_ERROR(error, displayId, 0); return supportedMetadata; } std::vector HWComposer::getRenderIntents(int32_t displayId, ui::ColorMode colorMode) const { RETURN_IF_INVALID_DISPLAY(displayId, {}); std::vector renderIntents; auto error = mDisplayData[displayId].hwcDisplay->getRenderIntents(colorMode, &renderIntents); RETURN_IF_HWC_ERROR(error, displayId, {}); return renderIntents; } mat4 HWComposer::getDataspaceSaturationMatrix(int32_t displayId, ui::Dataspace dataspace) { RETURN_IF_INVALID_DISPLAY(displayId, {}); mat4 matrix; auto error = mDisplayData[displayId].hwcDisplay->getDataspaceSaturationMatrix(dataspace, &matrix); RETURN_IF_HWC_ERROR(error, displayId, {}); return matrix; } // Converts a PixelFormat to a human-readable string. Max 11 chars. // (Could use a table of prefab String8 objects.) /* static String8 getFormatStr(PixelFormat format) { switch (format) { case PIXEL_FORMAT_RGBA_8888: return String8("RGBA_8888"); case PIXEL_FORMAT_RGBX_8888: return String8("RGBx_8888"); case PIXEL_FORMAT_RGB_888: return String8("RGB_888"); case PIXEL_FORMAT_RGB_565: return String8("RGB_565"); case PIXEL_FORMAT_BGRA_8888: return String8("BGRA_8888"); case HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED: return String8("ImplDef"); default: String8 result; result.appendFormat("? %08x", format); return result; } } */ bool HWComposer::isUsingVrComposer() const { return getComposer()->isUsingVrComposer(); } void HWComposer::dump(String8& result) const { // TODO: In order to provide a dump equivalent to HWC1, we need to shadow // all the state going into the layers. This is probably better done in // Layer itself, but it's going to take a bit of work to get there. result.append(mHwcDevice->dump().c_str()); } std::optional HWComposer::getHwcDisplayId(int32_t displayId) const { if (!isValidDisplay(displayId)) { return {}; } return mDisplayData[displayId].hwcDisplay->getId(); } // --------------------------------------------------------------------------- HWComposer::DisplayData::DisplayData() : hasClientComposition(false), hasDeviceComposition(false), hwcDisplay(nullptr), lastPresentFence(Fence::NO_FENCE), outbufHandle(nullptr), outbufAcquireFence(Fence::NO_FENCE), vsyncEnabled(HWC2::Vsync::Disable) { ALOGV("Created new DisplayData"); } HWComposer::DisplayData::~DisplayData() { } void HWComposer::DisplayData::reset() { ALOGV("DisplayData reset"); *this = DisplayData(); } // --------------------------------------------------------------------------- }; // namespace android