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/*
* Copyright 2019 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.
*/
#include <android-base/stringprintf.h>
#include <compositionengine/CompositionEngine.h>
#include <compositionengine/CompositionRefreshArgs.h>
#include <compositionengine/DisplayCreationArgs.h>
#include <compositionengine/DisplaySurface.h>
#include <compositionengine/LayerFE.h>
#include <compositionengine/impl/Display.h>
#include <compositionengine/impl/DisplayColorProfile.h>
#include <compositionengine/impl/DumpHelpers.h>
#include <compositionengine/impl/OutputLayer.h>
#include <compositionengine/impl/RenderSurface.h>
#include <gui/TraceUtils.h>
#include <utils/Trace.h>
// TODO(b/129481165): remove the #pragma below and fix conversion issues
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wconversion"
#include "DisplayHardware/HWComposer.h"
// TODO(b/129481165): remove the #pragma below and fix conversion issues
#pragma clang diagnostic pop // ignored "-Wconversion"
#include "DisplayHardware/PowerAdvisor.h"
using aidl::android::hardware::graphics::composer3::Capability;
using aidl::android::hardware::graphics::composer3::DisplayCapability;
namespace android::compositionengine::impl {
std::shared_ptr<Display> createDisplay(
const compositionengine::CompositionEngine& compositionEngine,
const compositionengine::DisplayCreationArgs& args) {
return createDisplayTemplated<Display>(compositionEngine, args);
}
Display::~Display() = default;
void Display::setConfiguration(const compositionengine::DisplayCreationArgs& args) {
mId = args.id;
mPowerAdvisor = args.powerAdvisor;
editState().isSecure = args.isSecure;
editState().isProtected = args.isProtected;
editState().displaySpace.setBounds(args.pixels);
setName(args.name);
}
bool Display::isValid() const {
return Output::isValid() && mPowerAdvisor;
}
DisplayId Display::getId() const {
return mId;
}
bool Display::isSecure() const {
return getState().isSecure;
}
bool Display::isVirtual() const {
return VirtualDisplayId::tryCast(mId).has_value();
}
std::optional<DisplayId> Display::getDisplayId() const {
return mId;
}
void Display::disconnect() {
if (mIsDisconnected) {
return;
}
mIsDisconnected = true;
if (const auto id = HalDisplayId::tryCast(mId)) {
getCompositionEngine().getHwComposer().disconnectDisplay(*id);
}
}
void Display::setColorTransform(const compositionengine::CompositionRefreshArgs& args) {
Output::setColorTransform(args);
const auto halDisplayId = HalDisplayId::tryCast(mId);
if (mIsDisconnected || !halDisplayId || CC_LIKELY(!args.colorTransformMatrix)) {
return;
}
auto& hwc = getCompositionEngine().getHwComposer();
status_t result = hwc.setColorTransform(*halDisplayId, *args.colorTransformMatrix);
ALOGE_IF(result != NO_ERROR, "Failed to set color transform on display \"%s\": %d",
to_string(mId).c_str(), result);
}
void Display::setColorProfile(const ColorProfile& colorProfile) {
if (colorProfile.mode == getState().colorMode &&
colorProfile.dataspace == getState().dataspace &&
colorProfile.renderIntent == getState().renderIntent) {
return;
}
if (isVirtual()) {
ALOGW("%s: Invalid operation on virtual display", __func__);
return;
}
Output::setColorProfile(colorProfile);
const auto physicalId = PhysicalDisplayId::tryCast(mId);
LOG_FATAL_IF(!physicalId);
getCompositionEngine().getHwComposer().setActiveColorMode(*physicalId, colorProfile.mode,
colorProfile.renderIntent);
}
void Display::dump(std::string& out) const {
const char* const type = isVirtual() ? "virtual" : "physical";
base::StringAppendF(&out, "Display %s (%s, \"%s\")", to_string(mId).c_str(), type,
getName().c_str());
out.append("\n Composition Display State:\n");
Output::dumpBase(out);
}
void Display::createDisplayColorProfile(const DisplayColorProfileCreationArgs& args) {
setDisplayColorProfile(compositionengine::impl::createDisplayColorProfile(args));
}
void Display::createRenderSurface(const RenderSurfaceCreationArgs& args) {
setRenderSurface(
compositionengine::impl::createRenderSurface(getCompositionEngine(), *this, args));
}
void Display::createClientCompositionCache(uint32_t cacheSize) {
cacheClientCompositionRequests(cacheSize);
}
std::unique_ptr<compositionengine::OutputLayer> Display::createOutputLayer(
const sp<compositionengine::LayerFE>& layerFE) const {
auto outputLayer = impl::createOutputLayer(*this, layerFE);
if (const auto halDisplayId = HalDisplayId::tryCast(mId);
outputLayer && !mIsDisconnected && halDisplayId) {
auto& hwc = getCompositionEngine().getHwComposer();
auto hwcLayer = hwc.createLayer(*halDisplayId);
ALOGE_IF(!hwcLayer, "Failed to create a HWC layer for a HWC supported display %s",
getName().c_str());
outputLayer->setHwcLayer(std::move(hwcLayer));
}
return outputLayer;
}
void Display::setReleasedLayers(const compositionengine::CompositionRefreshArgs& refreshArgs) {
Output::setReleasedLayers(refreshArgs);
if (mIsDisconnected || GpuVirtualDisplayId::tryCast(mId) ||
refreshArgs.layersWithQueuedFrames.empty()) {
return;
}
// For layers that are being removed from a HWC display, and that have
// queued frames, add them to a a list of released layers so we can properly
// set a fence.
compositionengine::Output::ReleasedLayers releasedLayers;
// Any non-null entries in the current list of layers are layers that are no
// longer going to be visible
for (auto* outputLayer : getOutputLayersOrderedByZ()) {
if (!outputLayer) {
continue;
}
compositionengine::LayerFE* layerFE = &outputLayer->getLayerFE();
const bool hasQueuedFrames =
std::any_of(refreshArgs.layersWithQueuedFrames.cbegin(),
refreshArgs.layersWithQueuedFrames.cend(),
[layerFE](sp<compositionengine::LayerFE> layerWithQueuedFrames) {
return layerFE == layerWithQueuedFrames.get();
});
if (hasQueuedFrames) {
releasedLayers.emplace_back(wp<LayerFE>::fromExisting(layerFE));
}
}
setReleasedLayers(std::move(releasedLayers));
}
void Display::applyDisplayBrightness(const bool applyImmediately) {
auto& hwc = getCompositionEngine().getHwComposer();
const auto halDisplayId = HalDisplayId::tryCast(*getDisplayId());
if (const auto physicalDisplayId = PhysicalDisplayId::tryCast(*halDisplayId);
physicalDisplayId && getState().displayBrightness) {
const status_t result =
hwc.setDisplayBrightness(*physicalDisplayId, *getState().displayBrightness,
getState().displayBrightnessNits,
Hwc2::Composer::DisplayBrightnessOptions{
.applyImmediately = applyImmediately})
.get();
ALOGE_IF(result != NO_ERROR, "setDisplayBrightness failed for %s: %d, (%s)",
getName().c_str(), result, strerror(-result));
}
// Clear out the display brightness now that it's been communicated to composer.
editState().displayBrightness.reset();
}
void Display::beginFrame() {
Output::beginFrame();
// If we don't have a HWC display, then we are done.
const auto halDisplayId = HalDisplayId::tryCast(mId);
if (!halDisplayId) {
return;
}
applyDisplayBrightness(false);
}
bool Display::chooseCompositionStrategy(
std::optional<android::HWComposer::DeviceRequestedChanges>* outChanges) {
ATRACE_FORMAT("%s for %s", __func__, getNamePlusId().c_str());
ALOGV(__FUNCTION__);
if (mIsDisconnected) {
return false;
}
// If we don't have a HWC display, then we are done.
const auto halDisplayId = HalDisplayId::tryCast(mId);
if (!halDisplayId) {
return false;
}
// Get any composition changes requested by the HWC device, and apply them.
std::optional<android::HWComposer::DeviceRequestedChanges> changes;
auto& hwc = getCompositionEngine().getHwComposer();
const bool requiresClientComposition = anyLayersRequireClientComposition();
if (isPowerHintSessionEnabled()) {
mPowerAdvisor->setRequiresClientComposition(mId, requiresClientComposition);
}
const TimePoint hwcValidateStartTime = TimePoint::now();
if (status_t result = hwc.getDeviceCompositionChanges(*halDisplayId, requiresClientComposition,
getState().earliestPresentTime,
getState().expectedPresentTime,
getState().frameInterval, outChanges);
result != NO_ERROR) {
ALOGE("chooseCompositionStrategy failed for %s: %d (%s)", getName().c_str(), result,
strerror(-result));
return false;
}
if (isPowerHintSessionEnabled()) {
mPowerAdvisor->setHwcValidateTiming(mId, hwcValidateStartTime, TimePoint::now());
if (auto halDisplayId = HalDisplayId::tryCast(mId)) {
mPowerAdvisor->setSkippedValidate(mId, hwc.getValidateSkipped(*halDisplayId));
}
}
return true;
}
void Display::applyCompositionStrategy(const std::optional<DeviceRequestedChanges>& changes) {
if (changes) {
applyChangedTypesToLayers(changes->changedTypes);
applyDisplayRequests(changes->displayRequests);
applyLayerRequestsToLayers(changes->layerRequests);
applyClientTargetRequests(changes->clientTargetProperty);
}
// Determine what type of composition we are doing from the final state
auto& state = editState();
state.usesClientComposition = anyLayersRequireClientComposition();
state.usesDeviceComposition = !allLayersRequireClientComposition();
}
bool Display::getSkipColorTransform() const {
const auto& hwc = getCompositionEngine().getHwComposer();
if (const auto halDisplayId = HalDisplayId::tryCast(mId)) {
return hwc.hasDisplayCapability(*halDisplayId,
DisplayCapability::SKIP_CLIENT_COLOR_TRANSFORM);
}
return hwc.hasCapability(Capability::SKIP_CLIENT_COLOR_TRANSFORM);
}
bool Display::allLayersRequireClientComposition() const {
const auto layers = getOutputLayersOrderedByZ();
return std::all_of(layers.begin(), layers.end(),
[](const auto& layer) { return layer->requiresClientComposition(); });
}
void Display::applyChangedTypesToLayers(const ChangedTypes& changedTypes) {
if (changedTypes.empty()) {
return;
}
for (auto* layer : getOutputLayersOrderedByZ()) {
auto hwcLayer = layer->getHwcLayer();
if (!hwcLayer) {
continue;
}
if (auto it = changedTypes.find(hwcLayer); it != changedTypes.end()) {
layer->applyDeviceCompositionTypeChange(
static_cast<aidl::android::hardware::graphics::composer3::Composition>(
it->second));
}
}
}
void Display::applyDisplayRequests(const DisplayRequests& displayRequests) {
auto& state = editState();
state.flipClientTarget = (static_cast<uint32_t>(displayRequests) &
static_cast<uint32_t>(hal::DisplayRequest::FLIP_CLIENT_TARGET)) != 0;
// Note: HWC2::DisplayRequest::WriteClientTargetToOutput is currently ignored.
}
void Display::applyLayerRequestsToLayers(const LayerRequests& layerRequests) {
for (auto* layer : getOutputLayersOrderedByZ()) {
layer->prepareForDeviceLayerRequests();
auto hwcLayer = layer->getHwcLayer();
if (!hwcLayer) {
continue;
}
if (auto it = layerRequests.find(hwcLayer); it != layerRequests.end()) {
layer->applyDeviceLayerRequest(
static_cast<Hwc2::IComposerClient::LayerRequest>(it->second));
}
}
}
void Display::applyClientTargetRequests(const ClientTargetProperty& clientTargetProperty) {
if (static_cast<ui::Dataspace>(clientTargetProperty.clientTargetProperty.dataspace) ==
ui::Dataspace::UNKNOWN) {
return;
}
editState().dataspace =
static_cast<ui::Dataspace>(clientTargetProperty.clientTargetProperty.dataspace);
editState().clientTargetBrightness = clientTargetProperty.brightness;
editState().clientTargetDimmingStage = clientTargetProperty.dimmingStage;
getRenderSurface()->setBufferDataspace(editState().dataspace);
getRenderSurface()->setBufferPixelFormat(
static_cast<ui::PixelFormat>(clientTargetProperty.clientTargetProperty.pixelFormat));
}
compositionengine::Output::FrameFences Display::presentFrame() {
auto fences = impl::Output::presentFrame();
const auto halDisplayIdOpt = HalDisplayId::tryCast(mId);
if (mIsDisconnected || !halDisplayIdOpt) {
return fences;
}
auto& hwc = getCompositionEngine().getHwComposer();
const TimePoint startTime = TimePoint::now();
if (isPowerHintSessionEnabled() && getState().earliestPresentTime) {
mPowerAdvisor->setHwcPresentDelayedTime(mId, *getState().earliestPresentTime);
}
hwc.presentAndGetReleaseFences(*halDisplayIdOpt, getState().earliestPresentTime);
if (isPowerHintSessionEnabled()) {
mPowerAdvisor->setHwcPresentTiming(mId, startTime, TimePoint::now());
}
fences.presentFence = hwc.getPresentFence(*halDisplayIdOpt);
// TODO(b/121291683): Change HWComposer call to return entire map
for (const auto* layer : getOutputLayersOrderedByZ()) {
auto hwcLayer = layer->getHwcLayer();
if (!hwcLayer) {
continue;
}
fences.layerFences.emplace(hwcLayer, hwc.getLayerReleaseFence(*halDisplayIdOpt, hwcLayer));
}
hwc.clearReleaseFences(*halDisplayIdOpt);
return fences;
}
void Display::setExpensiveRenderingExpected(bool enabled) {
Output::setExpensiveRenderingExpected(enabled);
if (mPowerAdvisor && !GpuVirtualDisplayId::tryCast(mId)) {
mPowerAdvisor->setExpensiveRenderingExpected(mId, enabled);
}
}
bool Display::isPowerHintSessionEnabled() {
return mPowerAdvisor != nullptr && mPowerAdvisor->usePowerHintSession();
}
void Display::setHintSessionGpuFence(std::unique_ptr<FenceTime>&& gpuFence) {
mPowerAdvisor->setGpuFenceTime(mId, std::move(gpuFence));
}
void Display::finishFrame(GpuCompositionResult&& result) {
// We only need to actually compose the display if:
// 1) It is being handled by hardware composer, which may need this to
// keep its virtual display state machine in sync, or
// 2) There is work to be done (the dirty region isn't empty)
if (GpuVirtualDisplayId::tryCast(mId) && !mustRecompose()) {
ALOGV("Skipping display composition");
return;
}
impl::Output::finishFrame(std::move(result));
}
bool Display::supportsOffloadPresent() const {
if (const auto halDisplayId = HalDisplayId::tryCast(mId)) {
const auto& hwc = getCompositionEngine().getHwComposer();
return hwc.hasDisplayCapability(*halDisplayId, DisplayCapability::MULTI_THREADED_PRESENT);
}
return false;
}
} // namespace android::compositionengine::impl