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/*
* 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 LOG_TAG "SurfaceComposerClient"
#include <semaphore.h>
#include <stdint.h>
#include <sys/types.h>
#include <android/gui/BnWindowInfosReportedListener.h>
#include <android/gui/DisplayState.h>
#include <android/gui/ISurfaceComposerClient.h>
#include <android/gui/IWindowInfosListener.h>
#include <android/gui/TrustedPresentationThresholds.h>
#include <android/os/IInputConstants.h>
#include <gui/FrameRateUtils.h>
#include <gui/TraceUtils.h>
#include <utils/Errors.h>
#include <utils/Log.h>
#include <utils/SortedVector.h>
#include <utils/String8.h>
#include <utils/threads.h>
#include <binder/IPCThreadState.h>
#include <binder/IServiceManager.h>
#include <binder/ProcessState.h>
#include <system/graphics.h>
#include <gui/AidlStatusUtil.h>
#include <gui/BufferItemConsumer.h>
#include <gui/CpuConsumer.h>
#include <gui/IGraphicBufferProducer.h>
#include <gui/ISurfaceComposer.h>
#include <gui/LayerState.h>
#include <gui/Surface.h>
#include <gui/SurfaceComposerClient.h>
#include <gui/WindowInfo.h>
#include <private/gui/ParcelUtils.h>
#include <ui/DisplayMode.h>
#include <ui/DisplayState.h>
#include <ui/DynamicDisplayInfo.h>
#include <android-base/thread_annotations.h>
#include <gui/LayerStatePermissions.h>
#include <private/gui/ComposerService.h>
#include <private/gui/ComposerServiceAIDL.h>
// This server size should always be smaller than the server cache size
#define BUFFER_CACHE_MAX_SIZE 4096
namespace android {
using aidl::android::hardware::graphics::common::DisplayDecorationSupport;
using gui::FocusRequest;
using gui::IRegionSamplingListener;
using gui::TrustedPresentationThresholds;
using gui::WindowInfo;
using gui::WindowInfoHandle;
using gui::WindowInfosListener;
using gui::aidl_utils::statusTFromBinderStatus;
using ui::ColorMode;
// ---------------------------------------------------------------------------
ANDROID_SINGLETON_STATIC_INSTANCE(ComposerService);
ANDROID_SINGLETON_STATIC_INSTANCE(ComposerServiceAIDL);
namespace {
// Initialize transaction id counter used to generate transaction ids
std::atomic<uint32_t> idCounter = 0;
int64_t generateId() {
return (((int64_t)getpid()) << 32) | ++idCounter;
}
void emptyCallback(nsecs_t, const sp<Fence>&, const std::vector<SurfaceControlStats>&) {}
} // namespace
ComposerService::ComposerService()
: Singleton<ComposerService>() {
Mutex::Autolock _l(mLock);
connectLocked();
}
bool ComposerService::connectLocked() {
const String16 name("SurfaceFlinger");
mComposerService = waitForService<ISurfaceComposer>(name);
if (mComposerService == nullptr) {
return false; // fatal error or permission problem
}
// Create the death listener.
class DeathObserver : public IBinder::DeathRecipient {
ComposerService& mComposerService;
virtual void binderDied(const wp<IBinder>& who) {
ALOGW("ComposerService remote (surfaceflinger) died [%p]",
who.unsafe_get());
mComposerService.composerServiceDied();
}
public:
explicit DeathObserver(ComposerService& mgr) : mComposerService(mgr) { }
};
mDeathObserver = new DeathObserver(*const_cast<ComposerService*>(this));
IInterface::asBinder(mComposerService)->linkToDeath(mDeathObserver);
return true;
}
/*static*/ sp<ISurfaceComposer> ComposerService::getComposerService() {
ComposerService& instance = ComposerService::getInstance();
Mutex::Autolock _l(instance.mLock);
if (instance.mComposerService == nullptr) {
if (ComposerService::getInstance().connectLocked()) {
ALOGD("ComposerService reconnected");
}
}
return instance.mComposerService;
}
void ComposerService::composerServiceDied()
{
Mutex::Autolock _l(mLock);
mComposerService = nullptr;
mDeathObserver = nullptr;
}
ComposerServiceAIDL::ComposerServiceAIDL() : Singleton<ComposerServiceAIDL>() {
std::scoped_lock lock(mMutex);
connectLocked();
}
bool ComposerServiceAIDL::connectLocked() {
const String16 name("SurfaceFlingerAIDL");
mComposerService = waitForService<gui::ISurfaceComposer>(name);
if (mComposerService == nullptr) {
return false; // fatal error or permission problem
}
// Create the death listener.
class DeathObserver : public IBinder::DeathRecipient {
ComposerServiceAIDL& mComposerService;
virtual void binderDied(const wp<IBinder>& who) {
ALOGW("ComposerService aidl remote (surfaceflinger) died [%p]", who.unsafe_get());
mComposerService.composerServiceDied();
}
public:
explicit DeathObserver(ComposerServiceAIDL& mgr) : mComposerService(mgr) {}
};
mDeathObserver = new DeathObserver(*const_cast<ComposerServiceAIDL*>(this));
IInterface::asBinder(mComposerService)->linkToDeath(mDeathObserver);
return true;
}
/*static*/ sp<gui::ISurfaceComposer> ComposerServiceAIDL::getComposerService() {
ComposerServiceAIDL& instance = ComposerServiceAIDL::getInstance();
std::scoped_lock lock(instance.mMutex);
if (instance.mComposerService == nullptr) {
if (ComposerServiceAIDL::getInstance().connectLocked()) {
ALOGD("ComposerServiceAIDL reconnected");
WindowInfosListenerReporter::getInstance()->reconnect(instance.mComposerService);
}
}
return instance.mComposerService;
}
void ComposerServiceAIDL::composerServiceDied() {
std::scoped_lock lock(mMutex);
mComposerService = nullptr;
mDeathObserver = nullptr;
}
class DefaultComposerClient: public Singleton<DefaultComposerClient> {
Mutex mLock;
sp<SurfaceComposerClient> mClient;
friend class Singleton<ComposerService>;
public:
static sp<SurfaceComposerClient> getComposerClient() {
DefaultComposerClient& dc = DefaultComposerClient::getInstance();
Mutex::Autolock _l(dc.mLock);
if (dc.mClient == nullptr) {
dc.mClient = new SurfaceComposerClient;
}
return dc.mClient;
}
};
ANDROID_SINGLETON_STATIC_INSTANCE(DefaultComposerClient);
sp<SurfaceComposerClient> SurfaceComposerClient::getDefault() {
return DefaultComposerClient::getComposerClient();
}
JankDataListener::~JankDataListener() {
}
// ---------------------------------------------------------------------------
// TransactionCompletedListener does not use ANDROID_SINGLETON_STATIC_INSTANCE because it needs
// to be able to return a sp<> to its instance to pass to SurfaceFlinger.
// ANDROID_SINGLETON_STATIC_INSTANCE only allows a reference to an instance.
// 0 is an invalid callback id
TransactionCompletedListener::TransactionCompletedListener() : mCallbackIdCounter(1) {}
int64_t TransactionCompletedListener::getNextIdLocked() {
return mCallbackIdCounter++;
}
sp<TransactionCompletedListener> TransactionCompletedListener::sInstance = nullptr;
static std::mutex sListenerInstanceMutex;
void TransactionCompletedListener::setInstance(const sp<TransactionCompletedListener>& listener) {
sInstance = listener;
}
sp<TransactionCompletedListener> TransactionCompletedListener::getInstance() {
std::lock_guard<std::mutex> lock(sListenerInstanceMutex);
if (sInstance == nullptr) {
sInstance = new TransactionCompletedListener;
}
return sInstance;
}
sp<ITransactionCompletedListener> TransactionCompletedListener::getIInstance() {
return static_cast<sp<ITransactionCompletedListener>>(getInstance());
}
void TransactionCompletedListener::startListeningLocked() {
if (mListening) {
return;
}
ProcessState::self()->startThreadPool();
mListening = true;
}
CallbackId TransactionCompletedListener::addCallbackFunction(
const TransactionCompletedCallback& callbackFunction,
const std::unordered_set<sp<SurfaceControl>, SurfaceComposerClient::SCHash>&
surfaceControls,
CallbackId::Type callbackType) {
std::lock_guard<std::mutex> lock(mMutex);
return addCallbackFunctionLocked(callbackFunction, surfaceControls, callbackType);
}
CallbackId TransactionCompletedListener::addCallbackFunctionLocked(
const TransactionCompletedCallback& callbackFunction,
const std::unordered_set<sp<SurfaceControl>, SurfaceComposerClient::SCHash>&
surfaceControls,
CallbackId::Type callbackType) {
startListeningLocked();
CallbackId callbackId(getNextIdLocked(), callbackType);
mCallbacks[callbackId].callbackFunction = callbackFunction;
auto& callbackSurfaceControls = mCallbacks[callbackId].surfaceControls;
for (const auto& surfaceControl : surfaceControls) {
callbackSurfaceControls[surfaceControl->getHandle()] = surfaceControl;
if (callbackType == CallbackId::Type::ON_COMPLETE &&
mJankListeners.count(surfaceControl->getLayerId()) != 0) {
callbackId.includeJankData = true;
}
}
return callbackId;
}
void TransactionCompletedListener::addJankListener(const sp<JankDataListener>& listener,
sp<SurfaceControl> surfaceControl) {
std::lock_guard<std::mutex> lock(mMutex);
mJankListeners.insert({surfaceControl->getLayerId(), listener});
}
void TransactionCompletedListener::removeJankListener(const sp<JankDataListener>& listener) {
std::lock_guard<std::mutex> lock(mMutex);
for (auto it = mJankListeners.begin(); it != mJankListeners.end();) {
if (it->second == listener) {
it = mJankListeners.erase(it);
} else {
it++;
}
}
}
void TransactionCompletedListener::setReleaseBufferCallback(const ReleaseCallbackId& callbackId,
ReleaseBufferCallback listener) {
std::scoped_lock<std::mutex> lock(mMutex);
mReleaseBufferCallbacks[callbackId] = listener;
}
void TransactionCompletedListener::addSurfaceStatsListener(void* context, void* cookie,
sp<SurfaceControl> surfaceControl, SurfaceStatsCallback listener) {
std::scoped_lock<std::recursive_mutex> lock(mSurfaceStatsListenerMutex);
mSurfaceStatsListeners.insert(
{surfaceControl->getLayerId(), SurfaceStatsCallbackEntry(context, cookie, listener)});
}
void TransactionCompletedListener::removeSurfaceStatsListener(void* context, void* cookie) {
std::scoped_lock<std::recursive_mutex> lock(mSurfaceStatsListenerMutex);
for (auto it = mSurfaceStatsListeners.begin(); it != mSurfaceStatsListeners.end();) {
auto [itContext, itCookie, itListener] = it->second;
if (itContext == context && itCookie == cookie) {
it = mSurfaceStatsListeners.erase(it);
} else {
it++;
}
}
}
void TransactionCompletedListener::addSurfaceControlToCallbacks(
SurfaceComposerClient::CallbackInfo& callbackInfo,
const sp<SurfaceControl>& surfaceControl) {
std::lock_guard<std::mutex> lock(mMutex);
bool includingJankData = false;
for (auto callbackId : callbackInfo.callbackIds) {
mCallbacks[callbackId].surfaceControls.emplace(std::piecewise_construct,
std::forward_as_tuple(
surfaceControl->getHandle()),
std::forward_as_tuple(surfaceControl));
includingJankData = includingJankData || callbackId.includeJankData;
}
// If no registered callback is requesting jank data, but there is a jank listener registered
// on the new surface control, add a synthetic callback that requests the jank data.
if (!includingJankData && mJankListeners.count(surfaceControl->getLayerId()) != 0) {
CallbackId callbackId =
addCallbackFunctionLocked(&emptyCallback, callbackInfo.surfaceControls,
CallbackId::Type::ON_COMPLETE);
callbackInfo.callbackIds.emplace(callbackId);
}
}
void TransactionCompletedListener::onTransactionCompleted(ListenerStats listenerStats) {
std::unordered_map<CallbackId, CallbackTranslation, CallbackIdHash> callbacksMap;
std::multimap<int32_t, sp<JankDataListener>> jankListenersMap;
{
std::lock_guard<std::mutex> lock(mMutex);
/* This listener knows all the sp<IBinder> to sp<SurfaceControl> for all its registered
* callbackIds, except for when Transactions are merged together. This probably cannot be
* solved before this point because the Transactions could be merged together and applied in
* a different process.
*
* Fortunately, we get all the callbacks for this listener for the same frame together at
* the same time. This means if any Transactions were merged together, we will get their
* callbacks at the same time. We can combine all the sp<IBinder> to sp<SurfaceControl> maps
* for all the callbackIds to generate one super map that contains all the sp<IBinder> to
* sp<SurfaceControl> that could possibly exist for the callbacks.
*/
callbacksMap = mCallbacks;
jankListenersMap = mJankListeners;
for (const auto& transactionStats : listenerStats.transactionStats) {
for (auto& callbackId : transactionStats.callbackIds) {
mCallbacks.erase(callbackId);
}
}
}
for (const auto& transactionStats : listenerStats.transactionStats) {
// handle on commit callbacks
for (auto callbackId : transactionStats.callbackIds) {
if (callbackId.type != CallbackId::Type::ON_COMMIT) {
continue;
}
auto& [callbackFunction, callbackSurfaceControls] = callbacksMap[callbackId];
if (!callbackFunction) {
continue;
}
std::vector<SurfaceControlStats> surfaceControlStats;
for (const auto& surfaceStats : transactionStats.surfaceStats) {
surfaceControlStats
.emplace_back(callbacksMap[callbackId]
.surfaceControls[surfaceStats.surfaceControl],
transactionStats.latchTime, surfaceStats.acquireTimeOrFence,
transactionStats.presentFence,
surfaceStats.previousReleaseFence, surfaceStats.transformHint,
surfaceStats.eventStats,
surfaceStats.currentMaxAcquiredBufferCount);
}
callbackFunction(transactionStats.latchTime, transactionStats.presentFence,
surfaceControlStats);
// More than one transaction may contain the same callback id. Erase the callback from
// the map to ensure that it is only called once. This can happen if transactions are
// parcelled out of process and applied in both processes.
callbacksMap.erase(callbackId);
}
// handle on complete callbacks
for (auto callbackId : transactionStats.callbackIds) {
if (callbackId.type != CallbackId::Type::ON_COMPLETE) {
continue;
}
auto& [callbackFunction, callbackSurfaceControls] = callbacksMap[callbackId];
if (!callbackFunction) {
ALOGE("cannot call null callback function, skipping");
continue;
}
std::vector<SurfaceControlStats> surfaceControlStats;
for (const auto& surfaceStats : transactionStats.surfaceStats) {
surfaceControlStats
.emplace_back(callbacksMap[callbackId]
.surfaceControls[surfaceStats.surfaceControl],
transactionStats.latchTime, surfaceStats.acquireTimeOrFence,
transactionStats.presentFence,
surfaceStats.previousReleaseFence, surfaceStats.transformHint,
surfaceStats.eventStats,
surfaceStats.currentMaxAcquiredBufferCount);
if (callbacksMap[callbackId].surfaceControls[surfaceStats.surfaceControl] &&
surfaceStats.transformHint.has_value()) {
callbacksMap[callbackId]
.surfaceControls[surfaceStats.surfaceControl]
->setTransformHint(*surfaceStats.transformHint);
}
// If there is buffer id set, we look up any pending client release buffer callbacks
// and call them. This is a performance optimization when we have a transaction
// callback and a release buffer callback happening at the same time to avoid an
// additional ipc call from the server.
if (surfaceStats.previousReleaseCallbackId != ReleaseCallbackId::INVALID_ID) {
ReleaseBufferCallback callback;
{
std::scoped_lock<std::mutex> lock(mMutex);
callback = popReleaseBufferCallbackLocked(
surfaceStats.previousReleaseCallbackId);
}
if (callback) {
callback(surfaceStats.previousReleaseCallbackId,
surfaceStats.previousReleaseFence
? surfaceStats.previousReleaseFence
: Fence::NO_FENCE,
surfaceStats.currentMaxAcquiredBufferCount);
}
}
}
callbackFunction(transactionStats.latchTime, transactionStats.presentFence,
surfaceControlStats);
}
}
for (const auto& transactionStats : listenerStats.transactionStats) {
for (const auto& surfaceStats : transactionStats.surfaceStats) {
// The callbackMap contains the SurfaceControl object, which we need to look up the
// layerId. Since we don't know which callback contains the SurfaceControl, iterate
// through all until the SC is found.
int32_t layerId = -1;
for (auto callbackId : transactionStats.callbackIds) {
if (callbackId.type != CallbackId::Type::ON_COMPLETE) {
// We only want to run the stats callback for ON_COMPLETE
continue;
}
sp<SurfaceControl> sc =
callbacksMap[callbackId].surfaceControls[surfaceStats.surfaceControl];
if (sc != nullptr) {
layerId = sc->getLayerId();
break;
}
}
if (layerId != -1) {
// Acquire surface stats listener lock such that we guarantee that after calling
// unregister, there won't be any further callback.
std::scoped_lock<std::recursive_mutex> lock(mSurfaceStatsListenerMutex);
auto listenerRange = mSurfaceStatsListeners.equal_range(layerId);
for (auto it = listenerRange.first; it != listenerRange.second; it++) {
auto entry = it->second;
entry.callback(entry.context, transactionStats.latchTime,
transactionStats.presentFence, surfaceStats);
}
}
if (surfaceStats.jankData.empty()) continue;
auto jankRange = jankListenersMap.equal_range(layerId);
for (auto it = jankRange.first; it != jankRange.second; it++) {
it->second->onJankDataAvailable(surfaceStats.jankData);
}
}
}
}
void TransactionCompletedListener::onTransactionQueueStalled(const String8& reason) {
std::unordered_map<void*, std::function<void(const std::string&)>> callbackCopy;
{
std::scoped_lock<std::mutex> lock(mMutex);
callbackCopy = mQueueStallListeners;
}
for (auto const& it : callbackCopy) {
it.second(reason.c_str());
}
}
void TransactionCompletedListener::addQueueStallListener(
std::function<void(const std::string&)> stallListener, void* id) {
std::scoped_lock<std::mutex> lock(mMutex);
mQueueStallListeners[id] = stallListener;
}
void TransactionCompletedListener::removeQueueStallListener(void* id) {
std::scoped_lock<std::mutex> lock(mMutex);
mQueueStallListeners.erase(id);
}
void TransactionCompletedListener::onReleaseBuffer(ReleaseCallbackId callbackId,
sp<Fence> releaseFence,
uint32_t currentMaxAcquiredBufferCount) {
ReleaseBufferCallback callback;
{
std::scoped_lock<std::mutex> lock(mMutex);
callback = popReleaseBufferCallbackLocked(callbackId);
}
if (!callback) {
ALOGE("Could not call release buffer callback, buffer not found %s",
callbackId.to_string().c_str());
return;
}
std::optional<uint32_t> optionalMaxAcquiredBufferCount =
currentMaxAcquiredBufferCount == UINT_MAX
? std::nullopt
: std::make_optional<uint32_t>(currentMaxAcquiredBufferCount);
callback(callbackId, releaseFence, optionalMaxAcquiredBufferCount);
}
ReleaseBufferCallback TransactionCompletedListener::popReleaseBufferCallbackLocked(
const ReleaseCallbackId& callbackId) {
ReleaseBufferCallback callback;
auto itr = mReleaseBufferCallbacks.find(callbackId);
if (itr == mReleaseBufferCallbacks.end()) {
return nullptr;
}
callback = itr->second;
mReleaseBufferCallbacks.erase(itr);
return callback;
}
void TransactionCompletedListener::removeReleaseBufferCallback(
const ReleaseCallbackId& callbackId) {
{
std::scoped_lock<std::mutex> lock(mMutex);
popReleaseBufferCallbackLocked(callbackId);
}
}
SurfaceComposerClient::PresentationCallbackRAII::PresentationCallbackRAII(
TransactionCompletedListener* tcl, int id) {
mTcl = tcl;
mId = id;
}
SurfaceComposerClient::PresentationCallbackRAII::~PresentationCallbackRAII() {
mTcl->clearTrustedPresentationCallback(mId);
}
sp<SurfaceComposerClient::PresentationCallbackRAII>
TransactionCompletedListener::addTrustedPresentationCallback(TrustedPresentationCallback tpc,
int id, void* context) {
std::scoped_lock<std::mutex> lock(mMutex);
mTrustedPresentationCallbacks[id] =
std::tuple<TrustedPresentationCallback, void*>(tpc, context);
return new SurfaceComposerClient::PresentationCallbackRAII(this, id);
}
void TransactionCompletedListener::clearTrustedPresentationCallback(int id) {
std::scoped_lock<std::mutex> lock(mMutex);
mTrustedPresentationCallbacks.erase(id);
}
void TransactionCompletedListener::onTrustedPresentationChanged(int id,
bool presentedWithinThresholds) {
TrustedPresentationCallback tpc;
void* context;
{
std::scoped_lock<std::mutex> lock(mMutex);
auto it = mTrustedPresentationCallbacks.find(id);
if (it == mTrustedPresentationCallbacks.end()) {
return;
}
std::tie(tpc, context) = it->second;
}
tpc(context, presentedWithinThresholds);
}
// ---------------------------------------------------------------------------
void removeDeadBufferCallback(void* /*context*/, uint64_t graphicBufferId);
/**
* We use the BufferCache to reduce the overhead of exchanging GraphicBuffers with
* the server. If we were to simply parcel the GraphicBuffer we would pay two overheads
* 1. Cost of sending the FD
* 2. Cost of importing the GraphicBuffer with the mapper in the receiving process.
* To ease this cost we implement the following scheme of caching buffers to integers,
* or said-otherwise, naming them with integers. This is the scheme known as slots in
* the legacy BufferQueue system.
* 1. When sending Buffers to SurfaceFlinger we look up the Buffer in the cache.
* 2. If there is a cache-hit we remove the Buffer from the Transaction and instead
* send the cached integer.
* 3. If there is a cache miss, we cache the new buffer and send the integer
* along with the Buffer, SurfaceFlinger on it's side creates a new cache
* entry, and we use the integer for further communication.
* A few details about lifetime:
* 1. The cache evicts by LRU. The server side cache is keyed by BufferCache::getToken
* which is per process Unique. The server side cache is larger than the client side
* cache so that the server will never evict entries before the client.
* 2. When the client evicts an entry it notifies the server via an uncacheBuffer
* transaction.
* 3. The client only references the Buffers by ID, and uses buffer->addDeathCallback
* to auto-evict destroyed buffers.
*/
class BufferCache : public Singleton<BufferCache> {
public:
BufferCache() : token(new BBinder()) {}
sp<IBinder> getToken() {
return IInterface::asBinder(TransactionCompletedListener::getIInstance());
}
status_t getCacheId(const sp<GraphicBuffer>& buffer, uint64_t* cacheId) {
std::lock_guard<std::mutex> lock(mMutex);
auto itr = mBuffers.find(buffer->getId());
if (itr == mBuffers.end()) {
return BAD_VALUE;
}
itr->second = getCounter();
*cacheId = buffer->getId();
return NO_ERROR;
}
uint64_t cache(const sp<GraphicBuffer>& buffer,
std::optional<client_cache_t>& outUncacheBuffer) {
std::lock_guard<std::mutex> lock(mMutex);
if (mBuffers.size() >= BUFFER_CACHE_MAX_SIZE) {
outUncacheBuffer = findLeastRecentlyUsedBuffer();
mBuffers.erase(outUncacheBuffer->id);
}
buffer->addDeathCallback(removeDeadBufferCallback, nullptr);
mBuffers[buffer->getId()] = getCounter();
return buffer->getId();
}
void uncache(uint64_t cacheId) {
std::lock_guard<std::mutex> lock(mMutex);
if (mBuffers.erase(cacheId)) {
SurfaceComposerClient::doUncacheBufferTransaction(cacheId);
}
}
private:
client_cache_t findLeastRecentlyUsedBuffer() REQUIRES(mMutex) {
auto itr = mBuffers.begin();
uint64_t minCounter = itr->second;
auto minBuffer = itr;
itr++;
while (itr != mBuffers.end()) {
uint64_t counter = itr->second;
if (counter < minCounter) {
minCounter = counter;
minBuffer = itr;
}
itr++;
}
return {.token = getToken(), .id = minBuffer->first};
}
uint64_t getCounter() REQUIRES(mMutex) {
static uint64_t counter = 0;
return counter++;
}
std::mutex mMutex;
std::map<uint64_t /*Cache id*/, uint64_t /*counter*/> mBuffers GUARDED_BY(mMutex);
// Used by ISurfaceComposer to identify which process is sending the cached buffer.
sp<IBinder> token;
};
ANDROID_SINGLETON_STATIC_INSTANCE(BufferCache);
void removeDeadBufferCallback(void* /*context*/, uint64_t graphicBufferId) {
// GraphicBuffer id's are used as the cache ids.
BufferCache::getInstance().uncache(graphicBufferId);
}
// ---------------------------------------------------------------------------
SurfaceComposerClient::Transaction::Transaction() {
mId = generateId();
}
SurfaceComposerClient::Transaction::Transaction(const Transaction& other)
: mId(other.mId),
mTransactionNestCount(other.mTransactionNestCount),
mAnimation(other.mAnimation),
mEarlyWakeupStart(other.mEarlyWakeupStart),
mEarlyWakeupEnd(other.mEarlyWakeupEnd),
mMayContainBuffer(other.mMayContainBuffer),
mDesiredPresentTime(other.mDesiredPresentTime),
mIsAutoTimestamp(other.mIsAutoTimestamp),
mFrameTimelineInfo(other.mFrameTimelineInfo),
mApplyToken(other.mApplyToken) {
mDisplayStates = other.mDisplayStates;
mComposerStates = other.mComposerStates;
mInputWindowCommands = other.mInputWindowCommands;
mListenerCallbacks = other.mListenerCallbacks;
}
void SurfaceComposerClient::Transaction::sanitize(int pid, int uid) {
uint32_t permissions = LayerStatePermissions::getTransactionPermissions(pid, uid);
for (auto & [handle, composerState] : mComposerStates) {
composerState.state.sanitize(permissions);
}
if (!mInputWindowCommands.empty() &&
(permissions & layer_state_t::Permission::ACCESS_SURFACE_FLINGER) == 0) {
ALOGE("Only privileged callers are allowed to send input commands.");
mInputWindowCommands.clear();
}
}
std::unique_ptr<SurfaceComposerClient::Transaction>
SurfaceComposerClient::Transaction::createFromParcel(const Parcel* parcel) {
auto transaction = std::make_unique<Transaction>();
if (transaction->readFromParcel(parcel) == NO_ERROR) {
return transaction;
}
return nullptr;
}
status_t SurfaceComposerClient::Transaction::readFromParcel(const Parcel* parcel) {
const uint64_t transactionId = parcel->readUint64();
const uint32_t transactionNestCount = parcel->readUint32();
const bool animation = parcel->readBool();
const bool earlyWakeupStart = parcel->readBool();
const bool earlyWakeupEnd = parcel->readBool();
const int64_t desiredPresentTime = parcel->readInt64();
const bool isAutoTimestamp = parcel->readBool();
FrameTimelineInfo frameTimelineInfo;
frameTimelineInfo.readFromParcel(parcel);
sp<IBinder> applyToken;
parcel->readNullableStrongBinder(&applyToken);
size_t count = static_cast<size_t>(parcel->readUint32());
if (count > parcel->dataSize()) {
return BAD_VALUE;
}
SortedVector<DisplayState> displayStates;
displayStates.setCapacity(count);
for (size_t i = 0; i < count; i++) {
DisplayState displayState;
if (displayState.read(*parcel) == BAD_VALUE) {
return BAD_VALUE;
}
displayStates.add(displayState);
}
count = static_cast<size_t>(parcel->readUint32());
if (count > parcel->dataSize()) {
return BAD_VALUE;
}
std::unordered_map<sp<ITransactionCompletedListener>, CallbackInfo, TCLHash> listenerCallbacks;
listenerCallbacks.reserve(count);
for (size_t i = 0; i < count; i++) {
sp<ITransactionCompletedListener> listener =
interface_cast<ITransactionCompletedListener>(parcel->readStrongBinder());
size_t numCallbackIds = parcel->readUint32();
if (numCallbackIds > parcel->dataSize()) {
return BAD_VALUE;
}
for (size_t j = 0; j < numCallbackIds; j++) {
CallbackId id;
parcel->readParcelable(&id);
listenerCallbacks[listener].callbackIds.insert(id);
}
size_t numSurfaces = parcel->readUint32();
if (numSurfaces > parcel->dataSize()) {
return BAD_VALUE;
}
for (size_t j = 0; j < numSurfaces; j++) {
sp<SurfaceControl> surface;
SAFE_PARCEL(SurfaceControl::readFromParcel, *parcel, &surface);
listenerCallbacks[listener].surfaceControls.insert(surface);
}
}
count = static_cast<size_t>(parcel->readUint32());
if (count > parcel->dataSize()) {
return BAD_VALUE;
}
std::unordered_map<sp<IBinder>, ComposerState, IBinderHash> composerStates;
composerStates.reserve(count);
for (size_t i = 0; i < count; i++) {
sp<IBinder> surfaceControlHandle;
SAFE_PARCEL(parcel->readStrongBinder, &surfaceControlHandle);
ComposerState composerState;
if (composerState.read(*parcel) == BAD_VALUE) {
return BAD_VALUE;
}
composerStates[surfaceControlHandle] = composerState;
}
InputWindowCommands inputWindowCommands;
inputWindowCommands.read(*parcel);
count = static_cast<size_t>(parcel->readUint32());
if (count > parcel->dataSize()) {
return BAD_VALUE;
}
std::vector<client_cache_t> uncacheBuffers(count);
for (size_t i = 0; i < count; i++) {
sp<IBinder> tmpBinder;
SAFE_PARCEL(parcel->readStrongBinder, &tmpBinder);
uncacheBuffers[i].token = tmpBinder;
SAFE_PARCEL(parcel->readUint64, &uncacheBuffers[i].id);
}
count = static_cast<size_t>(parcel->readUint32());
if (count > parcel->dataSize()) {
return BAD_VALUE;
}
std::vector<uint64_t> mergedTransactionIds(count);
for (size_t i = 0; i < count; i++) {
SAFE_PARCEL(parcel->readUint64, &mergedTransactionIds[i]);
}
// Parsing was successful. Update the object.
mId = transactionId;
mTransactionNestCount = transactionNestCount;
mAnimation = animation;
mEarlyWakeupStart = earlyWakeupStart;
mEarlyWakeupEnd = earlyWakeupEnd;
mDesiredPresentTime = desiredPresentTime;
mIsAutoTimestamp = isAutoTimestamp;
mFrameTimelineInfo = frameTimelineInfo;
mDisplayStates = displayStates;
mListenerCallbacks = listenerCallbacks;
mComposerStates = composerStates;
mInputWindowCommands = inputWindowCommands;
mApplyToken = applyToken;
mUncacheBuffers = std::move(uncacheBuffers);
mMergedTransactionIds = std::move(mergedTransactionIds);
return NO_ERROR;
}
status_t SurfaceComposerClient::Transaction::writeToParcel(Parcel* parcel) const {
// If we write the Transaction to a parcel, we want to ensure the Buffers are cached
// before crossing the IPC boundary. Otherwise the receiving party will cache the buffers
// but is unlikely to use them again as they are owned by the other process.
// You may be asking yourself, is this const cast safe? Const cast is safe up
// until the point where you try and write to an object that was originally const at which
// point we enter undefined behavior. In this case we are safe though, because there are
// two possibilities:
// 1. The SurfaceComposerClient::Transaction was originally non-const. Safe.
// 2. It was originall const! In this case not only was it useless, but it by definition
// contains no composer states and so cacheBuffers will not perform any writes.
const_cast<SurfaceComposerClient::Transaction*>(this)->cacheBuffers();
parcel->writeUint64(mId);
parcel->writeUint32(mTransactionNestCount);
parcel->writeBool(mAnimation);
parcel->writeBool(mEarlyWakeupStart);
parcel->writeBool(mEarlyWakeupEnd);
parcel->writeInt64(mDesiredPresentTime);
parcel->writeBool(mIsAutoTimestamp);
mFrameTimelineInfo.writeToParcel(parcel);
parcel->writeStrongBinder(mApplyToken);
parcel->writeUint32(static_cast<uint32_t>(mDisplayStates.size()));
for (auto const& displayState : mDisplayStates) {
displayState.write(*parcel);
}
parcel->writeUint32(static_cast<uint32_t>(mListenerCallbacks.size()));
for (auto const& [listener, callbackInfo] : mListenerCallbacks) {
parcel->writeStrongBinder(ITransactionCompletedListener::asBinder(listener));
parcel->writeUint32(static_cast<uint32_t>(callbackInfo.callbackIds.size()));
for (auto callbackId : callbackInfo.callbackIds) {
parcel->writeParcelable(callbackId);
}
parcel->writeUint32(static_cast<uint32_t>(callbackInfo.surfaceControls.size()));
for (auto surfaceControl : callbackInfo.surfaceControls) {
SAFE_PARCEL(surfaceControl->writeToParcel, *parcel);
}
}
parcel->writeUint32(static_cast<uint32_t>(mComposerStates.size()));
for (auto const& [handle, composerState] : mComposerStates) {
SAFE_PARCEL(parcel->writeStrongBinder, handle);
composerState.write(*parcel);
}
mInputWindowCommands.write(*parcel);
SAFE_PARCEL(parcel->writeUint32, static_cast<uint32_t>(mUncacheBuffers.size()));
for (const client_cache_t& uncacheBuffer : mUncacheBuffers) {
SAFE_PARCEL(parcel->writeStrongBinder, uncacheBuffer.token.promote());
SAFE_PARCEL(parcel->writeUint64, uncacheBuffer.id);
}
SAFE_PARCEL(parcel->writeUint32, static_cast<uint32_t>(mMergedTransactionIds.size()));
for (auto mergedTransactionId : mMergedTransactionIds) {
SAFE_PARCEL(parcel->writeUint64, mergedTransactionId);
}
return NO_ERROR;
}
void SurfaceComposerClient::Transaction::releaseBufferIfOverwriting(const layer_state_t& state) {
if (!(state.what & layer_state_t::eBufferChanged) || !state.bufferData->hasBuffer()) {
return;
}
auto listener = state.bufferData->releaseBufferListener;
sp<Fence> fence =
state.bufferData->acquireFence ? state.bufferData->acquireFence : Fence::NO_FENCE;
if (state.bufferData->releaseBufferEndpoint ==
IInterface::asBinder(TransactionCompletedListener::getIInstance())) {
// if the callback is in process, run on a different thread to avoid any lock contigency
// issues in the client.
SurfaceComposerClient::getDefault()
->mReleaseCallbackThread
.addReleaseCallback(state.bufferData->generateReleaseCallbackId(), fence);
} else {
listener->onReleaseBuffer(state.bufferData->generateReleaseCallbackId(), fence, UINT_MAX);
}
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::merge(Transaction&& other) {
while (mMergedTransactionIds.size() + other.mMergedTransactionIds.size() >
MAX_MERGE_HISTORY_LENGTH - 1 &&
mMergedTransactionIds.size() > 0) {
mMergedTransactionIds.pop_back();
}
if (other.mMergedTransactionIds.size() == MAX_MERGE_HISTORY_LENGTH) {
mMergedTransactionIds.insert(mMergedTransactionIds.begin(),
other.mMergedTransactionIds.begin(),
other.mMergedTransactionIds.end() - 1);
} else if (other.mMergedTransactionIds.size() > 0u) {
mMergedTransactionIds.insert(mMergedTransactionIds.begin(),
other.mMergedTransactionIds.begin(),
other.mMergedTransactionIds.end());
}
mMergedTransactionIds.insert(mMergedTransactionIds.begin(), other.mId);
for (auto const& [handle, composerState] : other.mComposerStates) {
if (mComposerStates.count(handle) == 0) {
mComposerStates[handle] = composerState;
} else {
if (composerState.state.what & layer_state_t::eBufferChanged) {
releaseBufferIfOverwriting(mComposerStates[handle].state);
}
mComposerStates[handle].state.merge(composerState.state);
}
}
for (auto const& state : other.mDisplayStates) {
ssize_t index = mDisplayStates.indexOf(state);
if (index < 0) {
mDisplayStates.add(state);
} else {
mDisplayStates.editItemAt(static_cast<size_t>(index)).merge(state);
}
}
for (const auto& [listener, callbackInfo] : other.mListenerCallbacks) {
auto& [callbackIds, surfaceControls] = callbackInfo;
mListenerCallbacks[listener].callbackIds.insert(std::make_move_iterator(
callbackIds.begin()),
std::make_move_iterator(callbackIds.end()));
mListenerCallbacks[listener].surfaceControls.insert(surfaceControls.begin(),
surfaceControls.end());
auto& currentProcessCallbackInfo =
mListenerCallbacks[TransactionCompletedListener::getIInstance()];
currentProcessCallbackInfo.surfaceControls
.insert(std::make_move_iterator(surfaceControls.begin()),
std::make_move_iterator(surfaceControls.end()));
// register all surface controls for all callbackIds for this listener that is merging
for (const auto& surfaceControl : currentProcessCallbackInfo.surfaceControls) {
TransactionCompletedListener::getInstance()
->addSurfaceControlToCallbacks(currentProcessCallbackInfo, surfaceControl);
}
}
for (const auto& cacheId : other.mUncacheBuffers) {
mUncacheBuffers.push_back(cacheId);
}
mInputWindowCommands.merge(other.mInputWindowCommands);
mMayContainBuffer |= other.mMayContainBuffer;
mEarlyWakeupStart = mEarlyWakeupStart || other.mEarlyWakeupStart;
mEarlyWakeupEnd = mEarlyWakeupEnd || other.mEarlyWakeupEnd;
mApplyToken = other.mApplyToken;
mergeFrameTimelineInfo(mFrameTimelineInfo, other.mFrameTimelineInfo);
other.clear();
return *this;
}
void SurfaceComposerClient::Transaction::clear() {
mComposerStates.clear();
mDisplayStates.clear();
mListenerCallbacks.clear();
mInputWindowCommands.clear();
mUncacheBuffers.clear();
mMayContainBuffer = false;
mTransactionNestCount = 0;
mAnimation = false;
mEarlyWakeupStart = false;
mEarlyWakeupEnd = false;
mDesiredPresentTime = 0;
mIsAutoTimestamp = true;
mFrameTimelineInfo = {};
mApplyToken = nullptr;
mMergedTransactionIds.clear();
}
uint64_t SurfaceComposerClient::Transaction::getId() {
return mId;
}
std::vector<uint64_t> SurfaceComposerClient::Transaction::getMergedTransactionIds() {
return mMergedTransactionIds;
}
void SurfaceComposerClient::doUncacheBufferTransaction(uint64_t cacheId) {
sp<ISurfaceComposer> sf(ComposerService::getComposerService());
client_cache_t uncacheBuffer;
uncacheBuffer.token = BufferCache::getInstance().getToken();
uncacheBuffer.id = cacheId;
Vector<ComposerState> composerStates;
status_t status = sf->setTransactionState(FrameTimelineInfo{}, composerStates, {},
ISurfaceComposer::eOneWay,
Transaction::getDefaultApplyToken(), {}, systemTime(),
true, {uncacheBuffer}, false, {}, generateId(), {});
if (status != NO_ERROR) {
ALOGE_AND_TRACE("SurfaceComposerClient::doUncacheBufferTransaction - %s",
strerror(-status));
}
}
void SurfaceComposerClient::Transaction::cacheBuffers() {
if (!mMayContainBuffer) {
return;
}
size_t count = 0;
for (auto& [handle, cs] : mComposerStates) {
layer_state_t* s = &(mComposerStates[handle].state);
if (!(s->what & layer_state_t::eBufferChanged)) {
continue;
} else if (s->bufferData &&
s->bufferData->flags.test(BufferData::BufferDataChange::cachedBufferChanged)) {
// If eBufferChanged and eCachedBufferChanged are both trued then that means
// we already cached the buffer in a previous call to cacheBuffers, perhaps
// from writeToParcel on a Transaction that was merged in to this one.
continue;
}
// Don't try to cache a null buffer. Sending null buffers is cheap so we shouldn't waste
// time trying to cache them.
if (!s->bufferData || !s->bufferData->buffer) {
continue;
}
uint64_t cacheId = 0;
status_t ret = BufferCache::getInstance().getCacheId(s->bufferData->buffer, &cacheId);
if (ret == NO_ERROR) {
// Cache-hit. Strip the buffer and send only the id.
s->bufferData->buffer = nullptr;
} else {
// Cache-miss. Include the buffer and send the new cacheId.
std::optional<client_cache_t> uncacheBuffer;
cacheId = BufferCache::getInstance().cache(s->bufferData->buffer, uncacheBuffer);
if (uncacheBuffer) {
mUncacheBuffers.push_back(*uncacheBuffer);
}
}
s->bufferData->flags |= BufferData::BufferDataChange::cachedBufferChanged;
s->bufferData->cachedBuffer.token = BufferCache::getInstance().getToken();
s->bufferData->cachedBuffer.id = cacheId;
// If we have more buffers than the size of the cache, we should stop caching so we don't
// evict other buffers in this transaction
count++;
if (count >= BUFFER_CACHE_MAX_SIZE) {
break;
}
}
}
class SyncCallback {
public:
static auto getCallback(std::shared_ptr<SyncCallback>& callbackContext) {
return [callbackContext](void* /* unused context */, nsecs_t /* latchTime */,
const sp<Fence>& /* presentFence */,
const std::vector<SurfaceControlStats>& /* stats */) {
if (!callbackContext) {
ALOGE("failed to get callback context for SyncCallback");
return;
}
LOG_ALWAYS_FATAL_IF(sem_post(&callbackContext->mSemaphore), "sem_post failed");
};
}
~SyncCallback() {
if (mInitialized) {
LOG_ALWAYS_FATAL_IF(sem_destroy(&mSemaphore), "sem_destroy failed");
}
}
void init() {
LOG_ALWAYS_FATAL_IF(clock_gettime(CLOCK_MONOTONIC, &mTimeoutTimespec) == -1,
"clock_gettime() fail! in SyncCallback::init");
mTimeoutTimespec.tv_sec += 4;
LOG_ALWAYS_FATAL_IF(sem_init(&mSemaphore, 0, 0), "sem_init failed");
mInitialized = true;
}
void wait() {
int result = sem_clockwait(&mSemaphore, CLOCK_MONOTONIC, &mTimeoutTimespec);
if (result && errno != ETIMEDOUT && errno != EINTR) {
LOG_ALWAYS_FATAL("sem_clockwait failed(%d)", errno);
} else if (errno == ETIMEDOUT) {
ALOGW("Sync transaction timed out waiting for commit callback.");
}
}
void* getContext() { return static_cast<void*>(this); }
private:
sem_t mSemaphore;
bool mInitialized = false;
timespec mTimeoutTimespec;
};
status_t SurfaceComposerClient::Transaction::apply(bool synchronous, bool oneWay) {
if (mStatus != NO_ERROR) {
return mStatus;
}
std::shared_ptr<SyncCallback> syncCallback = std::make_shared<SyncCallback>();
if (synchronous) {
syncCallback->init();
addTransactionCommittedCallback(SyncCallback::getCallback(syncCallback),
/*callbackContext=*/nullptr);
}
bool hasListenerCallbacks = !mListenerCallbacks.empty();
std::vector<ListenerCallbacks> listenerCallbacks;
// For every listener with registered callbacks
for (const auto& [listener, callbackInfo] : mListenerCallbacks) {
auto& [callbackIds, surfaceControls] = callbackInfo;
if (callbackIds.empty()) {
continue;
}
if (surfaceControls.empty()) {
listenerCallbacks.emplace_back(IInterface::asBinder(listener), std::move(callbackIds));
} else {
// If the listener has any SurfaceControls set on this Transaction update the surface
// state
for (const auto& surfaceControl : surfaceControls) {
layer_state_t* s = getLayerState(surfaceControl);
if (!s) {
ALOGE("failed to get layer state");
continue;
}
std::vector<CallbackId> callbacks(callbackIds.begin(), callbackIds.end());
s->what |= layer_state_t::eHasListenerCallbacksChanged;
s->listeners.emplace_back(IInterface::asBinder(listener), callbacks);
}
}
}
cacheBuffers();
Vector<ComposerState> composerStates;
Vector<DisplayState> displayStates;
uint32_t flags = 0;
for (auto const& kv : mComposerStates) {
composerStates.add(kv.second);
}
displayStates = std::move(mDisplayStates);
if (mAnimation) {
flags |= ISurfaceComposer::eAnimation;
}
if (oneWay) {
if (synchronous) {
ALOGE("Transaction attempted to set synchronous and one way at the same time"
" this is an invalid request. Synchronous will win for safety");
} else {
flags |= ISurfaceComposer::eOneWay;
}
}
// If both mEarlyWakeupStart and mEarlyWakeupEnd are set
// it is equivalent for none
if (mEarlyWakeupStart && !mEarlyWakeupEnd) {
flags |= ISurfaceComposer::eEarlyWakeupStart;
}
if (mEarlyWakeupEnd && !mEarlyWakeupStart) {
flags |= ISurfaceComposer::eEarlyWakeupEnd;
}
sp<IBinder> applyToken = mApplyToken ? mApplyToken : getDefaultApplyToken();
sp<ISurfaceComposer> sf(ComposerService::getComposerService());
sf->setTransactionState(mFrameTimelineInfo, composerStates, displayStates, flags, applyToken,
mInputWindowCommands, mDesiredPresentTime, mIsAutoTimestamp,
mUncacheBuffers, hasListenerCallbacks, listenerCallbacks, mId,
mMergedTransactionIds);
mId = generateId();
// Clear the current states and flags
clear();
if (synchronous) {
syncCallback->wait();
}
mStatus = NO_ERROR;
return NO_ERROR;
}
sp<IBinder> SurfaceComposerClient::Transaction::sApplyToken = new BBinder();
std::mutex SurfaceComposerClient::Transaction::sApplyTokenMutex;
sp<IBinder> SurfaceComposerClient::Transaction::getDefaultApplyToken() {
std::scoped_lock lock{sApplyTokenMutex};
return sApplyToken;
}
void SurfaceComposerClient::Transaction::setDefaultApplyToken(sp<IBinder> applyToken) {
std::scoped_lock lock{sApplyTokenMutex};
sApplyToken = applyToken;
}
status_t SurfaceComposerClient::Transaction::sendSurfaceFlushJankDataTransaction(
const sp<SurfaceControl>& sc) {
Transaction t;
layer_state_t* s = t.getLayerState(sc);
if (!s) {
return BAD_INDEX;
}
s->what |= layer_state_t::eFlushJankData;
t.registerSurfaceControlForCallback(sc);
return t.apply(/*sync=*/false, /* oneWay=*/true);
}
// ---------------------------------------------------------------------------
sp<IBinder> SurfaceComposerClient::createDisplay(const String8& displayName, bool secure,
float requestedRefereshRate) {
sp<IBinder> display = nullptr;
binder::Status status =
ComposerServiceAIDL::getComposerService()->createDisplay(std::string(
displayName.c_str()),
secure, requestedRefereshRate,
&display);
return status.isOk() ? display : nullptr;
}
void SurfaceComposerClient::destroyDisplay(const sp<IBinder>& display) {
ComposerServiceAIDL::getComposerService()->destroyDisplay(display);
}
std::vector<PhysicalDisplayId> SurfaceComposerClient::getPhysicalDisplayIds() {
std::vector<int64_t> displayIds;
std::vector<PhysicalDisplayId> physicalDisplayIds;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getPhysicalDisplayIds(&displayIds);
if (status.isOk()) {
physicalDisplayIds.reserve(displayIds.size());
for (auto item : displayIds) {
auto id = DisplayId::fromValue<PhysicalDisplayId>(static_cast<uint64_t>(item));
physicalDisplayIds.push_back(*id);
}
}
return physicalDisplayIds;
}
sp<IBinder> SurfaceComposerClient::getPhysicalDisplayToken(PhysicalDisplayId displayId) {
sp<IBinder> display = nullptr;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getPhysicalDisplayToken(displayId.value,
&display);
return status.isOk() ? display : nullptr;
}
std::optional<gui::StalledTransactionInfo> SurfaceComposerClient::getStalledTransactionInfo(
pid_t pid) {
std::optional<gui::StalledTransactionInfo> result;
ComposerServiceAIDL::getComposerService()->getStalledTransactionInfo(pid, &result);
return result;
}
void SurfaceComposerClient::Transaction::setAnimationTransaction() {
mAnimation = true;
}
void SurfaceComposerClient::Transaction::setEarlyWakeupStart() {
mEarlyWakeupStart = true;
}
void SurfaceComposerClient::Transaction::setEarlyWakeupEnd() {
mEarlyWakeupEnd = true;
}
layer_state_t* SurfaceComposerClient::Transaction::getLayerState(const sp<SurfaceControl>& sc) {
auto handle = sc->getLayerStateHandle();
if (mComposerStates.count(handle) == 0) {
// we don't have it, add an initialized layer_state to our list
ComposerState s;
s.state.surface = handle;
s.state.layerId = sc->getLayerId();
mComposerStates[handle] = s;
}
return &(mComposerStates[handle].state);
}
void SurfaceComposerClient::Transaction::registerSurfaceControlForCallback(
const sp<SurfaceControl>& sc) {
auto& callbackInfo = mListenerCallbacks[TransactionCompletedListener::getIInstance()];
callbackInfo.surfaceControls.insert(sc);
TransactionCompletedListener::getInstance()->addSurfaceControlToCallbacks(callbackInfo, sc);
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setPosition(
const sp<SurfaceControl>& sc, float x, float y) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::ePositionChanged;
s->x = x;
s->y = y;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::show(
const sp<SurfaceControl>& sc) {
return setFlags(sc, 0, layer_state_t::eLayerHidden);
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::hide(
const sp<SurfaceControl>& sc) {
return setFlags(sc, layer_state_t::eLayerHidden, layer_state_t::eLayerHidden);
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setLayer(
const sp<SurfaceControl>& sc, int32_t z) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eLayerChanged;
s->what &= ~layer_state_t::eRelativeLayerChanged;
s->z = z;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setRelativeLayer(
const sp<SurfaceControl>& sc, const sp<SurfaceControl>& relativeTo, int32_t z) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eRelativeLayerChanged;
s->what &= ~layer_state_t::eLayerChanged;
s->relativeLayerSurfaceControl = relativeTo;
s->z = z;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFlags(
const sp<SurfaceControl>& sc, uint32_t flags,
uint32_t mask) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
if ((mask & layer_state_t::eLayerOpaque) || (mask & layer_state_t::eLayerHidden) ||
(mask & layer_state_t::eLayerSecure) || (mask & layer_state_t::eLayerSkipScreenshot) ||
(mask & layer_state_t::eEnableBackpressure) ||
(mask & layer_state_t::eIgnoreDestinationFrame) ||
(mask & layer_state_t::eLayerIsDisplayDecoration) ||
(mask & layer_state_t::eLayerIsRefreshRateIndicator)) {
s->what |= layer_state_t::eFlagsChanged;
}
s->flags &= ~mask;
s->flags |= (flags & mask);
s->mask |= mask;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setTransparentRegionHint(
const sp<SurfaceControl>& sc,
const Region& transparentRegion) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eTransparentRegionChanged;
s->transparentRegion = transparentRegion;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setDimmingEnabled(
const sp<SurfaceControl>& sc, bool dimmingEnabled) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eDimmingEnabledChanged;
s->dimmingEnabled = dimmingEnabled;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setAlpha(
const sp<SurfaceControl>& sc, float alpha) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
if (alpha < 0.0f || alpha > 1.0f) {
ALOGE("SurfaceComposerClient::Transaction::setAlpha: invalid alpha %f, clamping", alpha);
}
s->what |= layer_state_t::eAlphaChanged;
s->color.a = std::clamp(alpha, 0.f, 1.f);
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setLayerStack(
const sp<SurfaceControl>& sc, ui::LayerStack layerStack) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eLayerStackChanged;
s->layerStack = layerStack;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setMetadata(
const sp<SurfaceControl>& sc, uint32_t key, const Parcel& p) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eMetadataChanged;
s->metadata.mMap[key] = {p.data(), p.data() + p.dataSize()};
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setMatrix(
const sp<SurfaceControl>& sc, float dsdx, float dtdx,
float dtdy, float dsdy) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eMatrixChanged;
layer_state_t::matrix22_t matrix;
matrix.dsdx = dsdx;
matrix.dtdx = dtdx;
matrix.dsdy = dsdy;
matrix.dtdy = dtdy;
s->matrix = matrix;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setCrop(
const sp<SurfaceControl>& sc, const Rect& crop) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eCropChanged;
s->crop = crop;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setCornerRadius(
const sp<SurfaceControl>& sc, float cornerRadius) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eCornerRadiusChanged;
s->cornerRadius = cornerRadius;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBackgroundBlurRadius(
const sp<SurfaceControl>& sc, int backgroundBlurRadius) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eBackgroundBlurRadiusChanged;
s->backgroundBlurRadius = backgroundBlurRadius;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBlurRegions(
const sp<SurfaceControl>& sc, const std::vector<BlurRegion>& blurRegions) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eBlurRegionsChanged;
s->blurRegions = blurRegions;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::reparent(
const sp<SurfaceControl>& sc, const sp<SurfaceControl>& newParent) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
if (SurfaceControl::isSameSurface(sc, newParent)) {
return *this;
}
s->what |= layer_state_t::eReparent;
s->parentSurfaceControlForChild = newParent ? newParent->getParentingLayer() : nullptr;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setColor(
const sp<SurfaceControl>& sc,
const half3& color) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eColorChanged;
s->color.rgb = color;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBackgroundColor(
const sp<SurfaceControl>& sc, const half3& color, float alpha, ui::Dataspace dataspace) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eBackgroundColorChanged;
s->bgColor.rgb = color;
s->bgColor.a = alpha;
s->bgColorDataspace = dataspace;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setTransform(
const sp<SurfaceControl>& sc, uint32_t transform) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eBufferTransformChanged;
s->bufferTransform = transform;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::setTransformToDisplayInverse(const sp<SurfaceControl>& sc,
bool transformToDisplayInverse) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eTransformToDisplayInverseChanged;
s->transformToDisplayInverse = transformToDisplayInverse;
registerSurfaceControlForCallback(sc);
return *this;
}
std::shared_ptr<BufferData> SurfaceComposerClient::Transaction::getAndClearBuffer(
const sp<SurfaceControl>& sc) {
layer_state_t* s = getLayerState(sc);
if (!s) {
return nullptr;
}
if (!(s->what & layer_state_t::eBufferChanged)) {
return nullptr;
}
std::shared_ptr<BufferData> bufferData = std::move(s->bufferData);
TransactionCompletedListener::getInstance()->removeReleaseBufferCallback(
bufferData->generateReleaseCallbackId());
s->what &= ~layer_state_t::eBufferChanged;
s->bufferData = nullptr;
return bufferData;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBufferHasBarrier(
const sp<SurfaceControl>& sc, uint64_t barrierFrameNumber) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->bufferData->hasBarrier = true;
s->bufferData->barrierFrameNumber = barrierFrameNumber;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBuffer(
const sp<SurfaceControl>& sc, const sp<GraphicBuffer>& buffer,
const std::optional<sp<Fence>>& fence, const std::optional<uint64_t>& optFrameNumber,
uint32_t producerId, ReleaseBufferCallback callback) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
releaseBufferIfOverwriting(*s);
std::shared_ptr<BufferData> bufferData = std::make_shared<BufferData>();
bufferData->buffer = buffer;
if (buffer) {
uint64_t frameNumber = sc->resolveFrameNumber(optFrameNumber);
bufferData->frameNumber = frameNumber;
bufferData->producerId = producerId;
bufferData->flags |= BufferData::BufferDataChange::frameNumberChanged;
if (fence) {
bufferData->acquireFence = *fence;
bufferData->flags |= BufferData::BufferDataChange::fenceChanged;
}
bufferData->releaseBufferEndpoint =
IInterface::asBinder(TransactionCompletedListener::getIInstance());
setReleaseBufferCallback(bufferData.get(), callback);
}
if (mIsAutoTimestamp) {
mDesiredPresentTime = systemTime();
}
s->what |= layer_state_t::eBufferChanged;
s->bufferData = std::move(bufferData);
registerSurfaceControlForCallback(sc);
// With the current infrastructure, a release callback will not be invoked if there's no
// transaction callback in the case when a buffer is latched and not released early. This is
// because the legacy implementation didn't have a release callback and sent releases in the
// transaction callback. Because of this, we need to make sure to have a transaction callback
// set up when a buffer is sent in a transaction to ensure the caller gets the release
// callback, regardless if they set up a transaction callback.
//
// TODO (b/230380821): Remove when release callbacks are separated from transaction callbacks
addTransactionCompletedCallback([](void*, nsecs_t, const sp<Fence>&,
const std::vector<SurfaceControlStats>&) {},
nullptr);
mMayContainBuffer = true;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::unsetBuffer(
const sp<SurfaceControl>& sc) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
if (!(s->what & layer_state_t::eBufferChanged)) {
return *this;
}
releaseBufferIfOverwriting(*s);
s->what &= ~layer_state_t::eBufferChanged;
s->bufferData = nullptr;
return *this;
}
void SurfaceComposerClient::Transaction::setReleaseBufferCallback(BufferData* bufferData,
ReleaseBufferCallback callback) {
if (!callback) {
return;
}
if (!bufferData->buffer) {
ALOGW("Transaction::setReleaseBufferCallback"
"ignored trying to set a callback on a null buffer.");
return;
}
bufferData->releaseBufferListener = TransactionCompletedListener::getIInstance();
auto listener = TransactionCompletedListener::getInstance();
listener->setReleaseBufferCallback(bufferData->generateReleaseCallbackId(), callback);
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setDataspace(
const sp<SurfaceControl>& sc, ui::Dataspace dataspace) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eDataspaceChanged;
s->dataspace = dataspace;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setExtendedRangeBrightness(
const sp<SurfaceControl>& sc, float currentBufferRatio, float desiredRatio) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eExtendedRangeBrightnessChanged;
s->currentHdrSdrRatio = currentBufferRatio;
s->desiredHdrSdrRatio = desiredRatio;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setCachingHint(
const sp<SurfaceControl>& sc, gui::CachingHint cachingHint) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eCachingHintChanged;
s->cachingHint = cachingHint;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setHdrMetadata(
const sp<SurfaceControl>& sc, const HdrMetadata& hdrMetadata) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eHdrMetadataChanged;
s->hdrMetadata = hdrMetadata;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setSurfaceDamageRegion(
const sp<SurfaceControl>& sc, const Region& surfaceDamageRegion) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eSurfaceDamageRegionChanged;
s->surfaceDamageRegion = surfaceDamageRegion;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setApi(
const sp<SurfaceControl>& sc, int32_t api) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eApiChanged;
s->api = api;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setSidebandStream(
const sp<SurfaceControl>& sc, const sp<NativeHandle>& sidebandStream) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eSidebandStreamChanged;
s->sidebandStream = sidebandStream;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setDesiredPresentTime(
nsecs_t desiredPresentTime) {
mDesiredPresentTime = desiredPresentTime;
mIsAutoTimestamp = false;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setColorSpaceAgnostic(
const sp<SurfaceControl>& sc, const bool agnostic) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eColorSpaceAgnosticChanged;
s->colorSpaceAgnostic = agnostic;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::setFrameRateSelectionPriority(const sp<SurfaceControl>& sc,
int32_t priority) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eFrameRateSelectionPriority;
s->frameRateSelectionPriority = priority;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::addTransactionCallback(
TransactionCompletedCallbackTakesContext callback, void* callbackContext,
CallbackId::Type callbackType) {
auto listener = TransactionCompletedListener::getInstance();
auto callbackWithContext = std::bind(callback, callbackContext, std::placeholders::_1,
std::placeholders::_2, std::placeholders::_3);
const auto& surfaceControls =
mListenerCallbacks[TransactionCompletedListener::getIInstance()].surfaceControls;
CallbackId callbackId =
listener->addCallbackFunction(callbackWithContext, surfaceControls, callbackType);
mListenerCallbacks[TransactionCompletedListener::getIInstance()].callbackIds.emplace(
callbackId);
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::addTransactionCompletedCallback(
TransactionCompletedCallbackTakesContext callback, void* callbackContext) {
return addTransactionCallback(callback, callbackContext, CallbackId::Type::ON_COMPLETE);
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::addTransactionCommittedCallback(
TransactionCompletedCallbackTakesContext callback, void* callbackContext) {
return addTransactionCallback(callback, callbackContext, CallbackId::Type::ON_COMMIT);
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::notifyProducerDisconnect(
const sp<SurfaceControl>& sc) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eProducerDisconnect;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setInputWindowInfo(
const sp<SurfaceControl>& sc, const WindowInfo& info) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->windowInfoHandle = new WindowInfoHandle(info);
s->what |= layer_state_t::eInputInfoChanged;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFocusedWindow(
const FocusRequest& request) {
mInputWindowCommands.focusRequests.push_back(request);
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::addWindowInfosReportedListener(
sp<gui::IWindowInfosReportedListener> windowInfosReportedListener) {
mInputWindowCommands.windowInfosReportedListeners.insert(windowInfosReportedListener);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setColorTransform(
const sp<SurfaceControl>& sc, const mat3& matrix, const vec3& translation) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eColorTransformChanged;
s->colorTransform = mat4(matrix, translation);
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setGeometry(
const sp<SurfaceControl>& sc, const Rect& source, const Rect& dst, int transform) {
setCrop(sc, source);
int x = dst.left;
int y = dst.top;
float sourceWidth = source.getWidth();
float sourceHeight = source.getHeight();
float xScale = sourceWidth < 0 ? 1.0f : dst.getWidth() / sourceWidth;
float yScale = sourceHeight < 0 ? 1.0f : dst.getHeight() / sourceHeight;
float matrix[4] = {1, 0, 0, 1};
switch (transform) {
case NATIVE_WINDOW_TRANSFORM_FLIP_H:
matrix[0] = -xScale; matrix[1] = 0;
matrix[2] = 0; matrix[3] = yScale;
x += source.getWidth();
break;
case NATIVE_WINDOW_TRANSFORM_FLIP_V:
matrix[0] = xScale; matrix[1] = 0;
matrix[2] = 0; matrix[3] = -yScale;
y += source.getHeight();
break;
case NATIVE_WINDOW_TRANSFORM_ROT_90:
matrix[0] = 0; matrix[1] = -yScale;
matrix[2] = xScale; matrix[3] = 0;
x += source.getHeight();
break;
case NATIVE_WINDOW_TRANSFORM_ROT_180:
matrix[0] = -xScale; matrix[1] = 0;
matrix[2] = 0; matrix[3] = -yScale;
x += source.getWidth();
y += source.getHeight();
break;
case NATIVE_WINDOW_TRANSFORM_ROT_270:
matrix[0] = 0; matrix[1] = yScale;
matrix[2] = -xScale; matrix[3] = 0;
y += source.getWidth();
break;
default:
matrix[0] = xScale; matrix[1] = 0;
matrix[2] = 0; matrix[3] = yScale;
break;
}
setMatrix(sc, matrix[0], matrix[1], matrix[2], matrix[3]);
float offsetX = xScale * source.left;
float offsetY = yScale * source.top;
setPosition(sc, x - offsetX, y - offsetY);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setShadowRadius(
const sp<SurfaceControl>& sc, float shadowRadius) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eShadowRadiusChanged;
s->shadowRadius = shadowRadius;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFrameRate(
const sp<SurfaceControl>& sc, float frameRate, int8_t compatibility,
int8_t changeFrameRateStrategy) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
// Allow privileged values as well here, those will be ignored by SF if
// the caller is not privileged
if (!ValidateFrameRate(frameRate, compatibility, changeFrameRateStrategy,
"Transaction::setFrameRate",
/*privileged=*/true)) {
mStatus = BAD_VALUE;
return *this;
}
s->what |= layer_state_t::eFrameRateChanged;
s->frameRate = frameRate;
s->frameRateCompatibility = compatibility;
s->changeFrameRateStrategy = changeFrameRateStrategy;
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::setDefaultFrameRateCompatibility(const sp<SurfaceControl>& sc,
int8_t compatibility) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eDefaultFrameRateCompatibilityChanged;
s->defaultFrameRateCompatibility = compatibility;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFrameRateCategory(
const sp<SurfaceControl>& sc, int8_t category, bool smoothSwitchOnly) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eFrameRateCategoryChanged;
s->frameRateCategory = category;
s->frameRateCategorySmoothSwitchOnly = smoothSwitchOnly;
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::setFrameRateSelectionStrategy(const sp<SurfaceControl>& sc,
int8_t strategy) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eFrameRateSelectionStrategyChanged;
s->frameRateSelectionStrategy = strategy;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFixedTransformHint(
const sp<SurfaceControl>& sc, int32_t fixedTransformHint) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
const ui::Transform::RotationFlags transform = fixedTransformHint == -1
? ui::Transform::ROT_INVALID
: ui::Transform::toRotationFlags(static_cast<ui::Rotation>(fixedTransformHint));
s->what |= layer_state_t::eFixedTransformHintChanged;
s->fixedTransformHint = transform;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setFrameTimelineInfo(
const FrameTimelineInfo& frameTimelineInfo) {
mergeFrameTimelineInfo(mFrameTimelineInfo, frameTimelineInfo);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setAutoRefresh(
const sp<SurfaceControl>& sc, bool autoRefresh) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eAutoRefreshChanged;
s->autoRefresh = autoRefresh;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setTrustedOverlay(
const sp<SurfaceControl>& sc, bool isTrustedOverlay) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eTrustedOverlayChanged;
s->isTrustedOverlay = isTrustedOverlay;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setApplyToken(
const sp<IBinder>& applyToken) {
mApplyToken = applyToken;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setStretchEffect(
const sp<SurfaceControl>& sc, const StretchEffect& stretchEffect) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eStretchChanged;
s->stretchEffect = stretchEffect;
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setBufferCrop(
const sp<SurfaceControl>& sc, const Rect& bufferCrop) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eBufferCropChanged;
s->bufferCrop = bufferCrop;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setDestinationFrame(
const sp<SurfaceControl>& sc, const Rect& destinationFrame) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eDestinationFrameChanged;
s->destinationFrame = destinationFrame;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::setDropInputMode(
const sp<SurfaceControl>& sc, gui::DropInputMode mode) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eDropInputModeChanged;
s->dropInputMode = mode;
registerSurfaceControlForCallback(sc);
return *this;
}
SurfaceComposerClient::Transaction& SurfaceComposerClient::Transaction::enableBorder(
const sp<SurfaceControl>& sc, bool shouldEnable, float width, const half4& color) {
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eRenderBorderChanged;
s->borderEnabled = shouldEnable;
s->borderWidth = width;
s->borderColor = color;
registerSurfaceControlForCallback(sc);
return *this;
}
// ---------------------------------------------------------------------------
DisplayState& SurfaceComposerClient::Transaction::getDisplayState(const sp<IBinder>& token) {
DisplayState s;
s.token = token;
ssize_t index = mDisplayStates.indexOf(s);
if (index < 0) {
// we don't have it, add an initialized layer_state to our list
s.what = 0;
index = mDisplayStates.add(s);
}
return mDisplayStates.editItemAt(static_cast<size_t>(index));
}
status_t SurfaceComposerClient::Transaction::setDisplaySurface(const sp<IBinder>& token,
const sp<IGraphicBufferProducer>& bufferProducer) {
if (bufferProducer.get() != nullptr) {
// Make sure that composition can never be stalled by a virtual display
// consumer that isn't processing buffers fast enough.
status_t err = bufferProducer->setAsyncMode(true);
if (err != NO_ERROR) {
ALOGE("Composer::setDisplaySurface Failed to enable async mode on the "
"BufferQueue. This BufferQueue cannot be used for virtual "
"display. (%d)", err);
return err;
}
}
DisplayState& s(getDisplayState(token));
s.surface = bufferProducer;
s.what |= DisplayState::eSurfaceChanged;
return NO_ERROR;
}
void SurfaceComposerClient::Transaction::setDisplayLayerStack(const sp<IBinder>& token,
ui::LayerStack layerStack) {
DisplayState& s(getDisplayState(token));
s.layerStack = layerStack;
s.what |= DisplayState::eLayerStackChanged;
}
void SurfaceComposerClient::Transaction::setDisplayFlags(const sp<IBinder>& token, uint32_t flags) {
DisplayState& s(getDisplayState(token));
s.flags = flags;
s.what |= DisplayState::eFlagsChanged;
}
void SurfaceComposerClient::Transaction::setDisplayProjection(const sp<IBinder>& token,
ui::Rotation orientation,
const Rect& layerStackRect,
const Rect& displayRect) {
DisplayState& s(getDisplayState(token));
s.orientation = orientation;
s.layerStackSpaceRect = layerStackRect;
s.orientedDisplaySpaceRect = displayRect;
s.what |= DisplayState::eDisplayProjectionChanged;
}
void SurfaceComposerClient::Transaction::setDisplaySize(const sp<IBinder>& token, uint32_t width, uint32_t height) {
DisplayState& s(getDisplayState(token));
s.width = width;
s.height = height;
s.what |= DisplayState::eDisplaySizeChanged;
}
// copied from FrameTimelineInfo::merge()
void SurfaceComposerClient::Transaction::mergeFrameTimelineInfo(FrameTimelineInfo& t,
const FrameTimelineInfo& other) {
// When merging vsync Ids we take the oldest valid one
if (t.vsyncId != FrameTimelineInfo::INVALID_VSYNC_ID &&
other.vsyncId != FrameTimelineInfo::INVALID_VSYNC_ID) {
if (other.vsyncId > t.vsyncId) {
t = other;
}
} else if (t.vsyncId == FrameTimelineInfo::INVALID_VSYNC_ID) {
t = other;
}
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::setTrustedPresentationCallback(
const sp<SurfaceControl>& sc, TrustedPresentationCallback cb,
const TrustedPresentationThresholds& thresholds, void* context,
sp<SurfaceComposerClient::PresentationCallbackRAII>& outCallbackRef) {
auto listener = TransactionCompletedListener::getInstance();
outCallbackRef = listener->addTrustedPresentationCallback(cb, sc->getLayerId(), context);
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eTrustedPresentationInfoChanged;
s->trustedPresentationThresholds = thresholds;
s->trustedPresentationListener.callbackInterface = TransactionCompletedListener::getIInstance();
s->trustedPresentationListener.callbackId = sc->getLayerId();
return *this;
}
SurfaceComposerClient::Transaction&
SurfaceComposerClient::Transaction::clearTrustedPresentationCallback(const sp<SurfaceControl>& sc) {
auto listener = TransactionCompletedListener::getInstance();
listener->clearTrustedPresentationCallback(sc->getLayerId());
layer_state_t* s = getLayerState(sc);
if (!s) {
mStatus = BAD_INDEX;
return *this;
}
s->what |= layer_state_t::eTrustedPresentationInfoChanged;
s->trustedPresentationThresholds = TrustedPresentationThresholds();
s->trustedPresentationListener.callbackInterface = nullptr;
s->trustedPresentationListener.callbackId = -1;
return *this;
}
// ---------------------------------------------------------------------------
SurfaceComposerClient::SurfaceComposerClient() : mStatus(NO_INIT) {}
SurfaceComposerClient::SurfaceComposerClient(const sp<ISurfaceComposerClient>& client)
: mStatus(NO_ERROR), mClient(client) {}
void SurfaceComposerClient::onFirstRef() {
sp<gui::ISurfaceComposer> sf(ComposerServiceAIDL::getComposerService());
if (sf != nullptr && mStatus == NO_INIT) {
sp<ISurfaceComposerClient> conn;
binder::Status status = sf->createConnection(&conn);
if (status.isOk() && conn != nullptr) {
mClient = conn;
mStatus = NO_ERROR;
}
}
}
SurfaceComposerClient::~SurfaceComposerClient() {
dispose();
}
status_t SurfaceComposerClient::initCheck() const {
return mStatus;
}
sp<IBinder> SurfaceComposerClient::connection() const {
return IInterface::asBinder(mClient);
}
status_t SurfaceComposerClient::linkToComposerDeath(
const sp<IBinder::DeathRecipient>& recipient,
void* cookie, uint32_t flags) {
sp<ISurfaceComposer> sf(ComposerService::getComposerService());
return IInterface::asBinder(sf)->linkToDeath(recipient, cookie, flags);
}
void SurfaceComposerClient::dispose() {
// this can be called more than once.
sp<ISurfaceComposerClient> client;
Mutex::Autolock _lm(mLock);
if (mClient != nullptr) {
client = mClient; // hold ref while lock is held
mClient.clear();
}
mStatus = NO_INIT;
}
status_t SurfaceComposerClient::bootFinished() {
sp<gui::ISurfaceComposer> sf(ComposerServiceAIDL::getComposerService());
binder::Status status = sf->bootFinished();
return statusTFromBinderStatus(status);
}
sp<SurfaceControl> SurfaceComposerClient::createSurface(const String8& name, uint32_t w, uint32_t h,
PixelFormat format, int32_t flags,
const sp<IBinder>& parentHandle,
LayerMetadata metadata,
uint32_t* outTransformHint) {
sp<SurfaceControl> s;
createSurfaceChecked(name, w, h, format, &s, flags, parentHandle, std::move(metadata),
outTransformHint);
return s;
}
static std::string toString(const String16& string) {
return std::string(String8(string).c_str());
}
status_t SurfaceComposerClient::createSurfaceChecked(const String8& name, uint32_t w, uint32_t h,
PixelFormat format,
sp<SurfaceControl>* outSurface, int32_t flags,
const sp<IBinder>& parentHandle,
LayerMetadata metadata,
uint32_t* outTransformHint) {
sp<SurfaceControl> sur;
status_t err = mStatus;
if (mStatus == NO_ERROR) {
gui::CreateSurfaceResult result;
binder::Status status = mClient->createSurface(std::string(name.c_str()), flags,
parentHandle, std::move(metadata), &result);
err = statusTFromBinderStatus(status);
if (outTransformHint) {
*outTransformHint = result.transformHint;
}
ALOGE_IF(err, "SurfaceComposerClient::createSurface error %s", strerror(-err));
if (err == NO_ERROR) {
*outSurface = new SurfaceControl(this, result.handle, result.layerId,
toString(result.layerName), w, h, format,
result.transformHint, flags);
}
}
return err;
}
sp<SurfaceControl> SurfaceComposerClient::mirrorSurface(SurfaceControl* mirrorFromSurface) {
if (mirrorFromSurface == nullptr) {
return nullptr;
}
sp<IBinder> mirrorFromHandle = mirrorFromSurface->getHandle();
gui::CreateSurfaceResult result;
const binder::Status status = mClient->mirrorSurface(mirrorFromHandle, &result);
const status_t err = statusTFromBinderStatus(status);
if (err == NO_ERROR) {
return new SurfaceControl(this, result.handle, result.layerId, toString(result.layerName));
}
return nullptr;
}
sp<SurfaceControl> SurfaceComposerClient::mirrorDisplay(DisplayId displayId) {
gui::CreateSurfaceResult result;
const binder::Status status = mClient->mirrorDisplay(displayId.value, &result);
const status_t err = statusTFromBinderStatus(status);
if (err == NO_ERROR) {
return new SurfaceControl(this, result.handle, result.layerId, toString(result.layerName));
}
return nullptr;
}
status_t SurfaceComposerClient::clearLayerFrameStats(const sp<IBinder>& token) const {
if (mStatus != NO_ERROR) {
return mStatus;
}
const binder::Status status = mClient->clearLayerFrameStats(token);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getLayerFrameStats(const sp<IBinder>& token,
FrameStats* outStats) const {
if (mStatus != NO_ERROR) {
return mStatus;
}
gui::FrameStats stats;
const binder::Status status = mClient->getLayerFrameStats(token, &stats);
if (status.isOk()) {
outStats->refreshPeriodNano = stats.refreshPeriodNano;
outStats->desiredPresentTimesNano.setCapacity(stats.desiredPresentTimesNano.size());
for (const auto& t : stats.desiredPresentTimesNano) {
outStats->desiredPresentTimesNano.add(t);
}
outStats->actualPresentTimesNano.setCapacity(stats.actualPresentTimesNano.size());
for (const auto& t : stats.actualPresentTimesNano) {
outStats->actualPresentTimesNano.add(t);
}
outStats->frameReadyTimesNano.setCapacity(stats.frameReadyTimesNano.size());
for (const auto& t : stats.frameReadyTimesNano) {
outStats->frameReadyTimesNano.add(t);
}
}
return statusTFromBinderStatus(status);
}
// ----------------------------------------------------------------------------
status_t SurfaceComposerClient::getDisplayState(const sp<IBinder>& display,
ui::DisplayState* state) {
gui::DisplayState ds;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDisplayState(display, &ds);
if (status.isOk()) {
state->layerStack = ui::LayerStack::fromValue(ds.layerStack);
state->orientation = static_cast<ui::Rotation>(ds.orientation);
state->layerStackSpaceRect =
ui::Size(ds.layerStackSpaceRect.width, ds.layerStackSpaceRect.height);
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getStaticDisplayInfo(int64_t displayId,
ui::StaticDisplayInfo* outInfo) {
using Tag = android::gui::DeviceProductInfo::ManufactureOrModelDate::Tag;
gui::StaticDisplayInfo ginfo;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getStaticDisplayInfo(displayId, &ginfo);
if (status.isOk()) {
// convert gui::StaticDisplayInfo to ui::StaticDisplayInfo
outInfo->connectionType = static_cast<ui::DisplayConnectionType>(ginfo.connectionType);
outInfo->density = ginfo.density;
outInfo->secure = ginfo.secure;
outInfo->installOrientation = static_cast<ui::Rotation>(ginfo.installOrientation);
if (const std::optional<gui::DeviceProductInfo> dpi = ginfo.deviceProductInfo) {
DeviceProductInfo info;
info.name = dpi->name;
if (dpi->manufacturerPnpId.size() > 0) {
// copid from PnpId = std::array<char, 4> in ui/DeviceProductInfo.h
constexpr int kMaxPnpIdSize = 4;
size_t count = std::max<size_t>(kMaxPnpIdSize, dpi->manufacturerPnpId.size());
std::copy_n(dpi->manufacturerPnpId.begin(), count, info.manufacturerPnpId.begin());
}
if (dpi->relativeAddress.size() > 0) {
std::copy(dpi->relativeAddress.begin(), dpi->relativeAddress.end(),
std::back_inserter(info.relativeAddress));
}
info.productId = dpi->productId;
const gui::DeviceProductInfo::ManufactureOrModelDate& date =
dpi->manufactureOrModelDate;
if (date.getTag() == Tag::modelYear) {
DeviceProductInfo::ModelYear modelYear;
modelYear.year = static_cast<uint32_t>(date.get<Tag::modelYear>().year);
info.manufactureOrModelDate = modelYear;
} else if (date.getTag() == Tag::manufactureYear) {
DeviceProductInfo::ManufactureYear manufactureYear;
manufactureYear.year = date.get<Tag::manufactureYear>().modelYear.year;
info.manufactureOrModelDate = manufactureYear;
} else if (date.getTag() == Tag::manufactureWeekAndYear) {
DeviceProductInfo::ManufactureWeekAndYear weekAndYear;
weekAndYear.year =
date.get<Tag::manufactureWeekAndYear>().manufactureYear.modelYear.year;
weekAndYear.week = date.get<Tag::manufactureWeekAndYear>().week;
info.manufactureOrModelDate = weekAndYear;
}
outInfo->deviceProductInfo = info;
}
}
return statusTFromBinderStatus(status);
}
void SurfaceComposerClient::getDynamicDisplayInfoInternal(gui::DynamicDisplayInfo& ginfo,
ui::DynamicDisplayInfo*& outInfo) {
// convert gui::DynamicDisplayInfo to ui::DynamicDisplayInfo
outInfo->supportedDisplayModes.clear();
outInfo->supportedDisplayModes.reserve(ginfo.supportedDisplayModes.size());
for (const auto& mode : ginfo.supportedDisplayModes) {
ui::DisplayMode outMode;
outMode.id = mode.id;
outMode.resolution.width = mode.resolution.width;
outMode.resolution.height = mode.resolution.height;
outMode.xDpi = mode.xDpi;
outMode.yDpi = mode.yDpi;
outMode.peakRefreshRate = mode.peakRefreshRate;
outMode.vsyncRate = mode.vsyncRate;
outMode.appVsyncOffset = mode.appVsyncOffset;
outMode.sfVsyncOffset = mode.sfVsyncOffset;
outMode.presentationDeadline = mode.presentationDeadline;
outMode.group = mode.group;
std::transform(mode.supportedHdrTypes.begin(), mode.supportedHdrTypes.end(),
std::back_inserter(outMode.supportedHdrTypes),
[](const int32_t& value) { return static_cast<ui::Hdr>(value); });
outInfo->supportedDisplayModes.push_back(outMode);
}
outInfo->activeDisplayModeId = ginfo.activeDisplayModeId;
outInfo->renderFrameRate = ginfo.renderFrameRate;
outInfo->supportedColorModes.clear();
outInfo->supportedColorModes.reserve(ginfo.supportedColorModes.size());
for (const auto& cmode : ginfo.supportedColorModes) {
outInfo->supportedColorModes.push_back(static_cast<ui::ColorMode>(cmode));
}
outInfo->activeColorMode = static_cast<ui::ColorMode>(ginfo.activeColorMode);
std::vector<ui::Hdr> types;
types.reserve(ginfo.hdrCapabilities.supportedHdrTypes.size());
for (const auto& hdr : ginfo.hdrCapabilities.supportedHdrTypes) {
types.push_back(static_cast<ui::Hdr>(hdr));
}
outInfo->hdrCapabilities = HdrCapabilities(types, ginfo.hdrCapabilities.maxLuminance,
ginfo.hdrCapabilities.maxAverageLuminance,
ginfo.hdrCapabilities.minLuminance);
outInfo->autoLowLatencyModeSupported = ginfo.autoLowLatencyModeSupported;
outInfo->gameContentTypeSupported = ginfo.gameContentTypeSupported;
outInfo->preferredBootDisplayMode = ginfo.preferredBootDisplayMode;
}
status_t SurfaceComposerClient::getDynamicDisplayInfoFromId(int64_t displayId,
ui::DynamicDisplayInfo* outInfo) {
gui::DynamicDisplayInfo ginfo;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDynamicDisplayInfoFromId(displayId,
&ginfo);
if (status.isOk()) {
getDynamicDisplayInfoInternal(ginfo, outInfo);
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getDynamicDisplayInfoFromToken(const sp<IBinder>& display,
ui::DynamicDisplayInfo* outInfo) {
gui::DynamicDisplayInfo ginfo;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDynamicDisplayInfoFromToken(display,
&ginfo);
if (status.isOk()) {
getDynamicDisplayInfoInternal(ginfo, outInfo);
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getActiveDisplayMode(const sp<IBinder>& display,
ui::DisplayMode* mode) {
ui::DynamicDisplayInfo info;
status_t result = getDynamicDisplayInfoFromToken(display, &info);
if (result != NO_ERROR) {
return result;
}
if (const auto activeMode = info.getActiveDisplayMode()) {
*mode = *activeMode;
return NO_ERROR;
}
ALOGE("Active display mode not found.");
return NAME_NOT_FOUND;
}
status_t SurfaceComposerClient::setDesiredDisplayModeSpecs(const sp<IBinder>& displayToken,
const gui::DisplayModeSpecs& specs) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->setDesiredDisplayModeSpecs(displayToken,
specs);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getDesiredDisplayModeSpecs(const sp<IBinder>& displayToken,
gui::DisplayModeSpecs* outSpecs) {
if (!outSpecs) {
return BAD_VALUE;
}
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDesiredDisplayModeSpecs(displayToken,
outSpecs);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getDisplayNativePrimaries(const sp<IBinder>& display,
ui::DisplayPrimaries& outPrimaries) {
gui::DisplayPrimaries primaries;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDisplayNativePrimaries(display,
&primaries);
if (status.isOk()) {
outPrimaries.red.X = primaries.red.X;
outPrimaries.red.Y = primaries.red.Y;
outPrimaries.red.Z = primaries.red.Z;
outPrimaries.green.X = primaries.green.X;
outPrimaries.green.Y = primaries.green.Y;
outPrimaries.green.Z = primaries.green.Z;
outPrimaries.blue.X = primaries.blue.X;
outPrimaries.blue.Y = primaries.blue.Y;
outPrimaries.blue.Z = primaries.blue.Z;
outPrimaries.white.X = primaries.white.X;
outPrimaries.white.Y = primaries.white.Y;
outPrimaries.white.Z = primaries.white.Z;
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setActiveColorMode(const sp<IBinder>& display,
ColorMode colorMode) {
binder::Status status = ComposerServiceAIDL::getComposerService()
->setActiveColorMode(display, static_cast<int>(colorMode));
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getBootDisplayModeSupport(bool* support) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->getBootDisplayModeSupport(support);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getOverlaySupport(gui::OverlayProperties* outProperties) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->getOverlaySupport(outProperties);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setBootDisplayMode(const sp<IBinder>& display,
ui::DisplayModeId displayModeId) {
binder::Status status = ComposerServiceAIDL::getComposerService()
->setBootDisplayMode(display, static_cast<int>(displayModeId));
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::clearBootDisplayMode(const sp<IBinder>& display) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->clearBootDisplayMode(display);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getHdrConversionCapabilities(
std::vector<gui::HdrConversionCapability>* hdrConversionCapabilities) {
binder::Status status = ComposerServiceAIDL::getComposerService()->getHdrConversionCapabilities(
hdrConversionCapabilities);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setHdrConversionStrategy(
gui::HdrConversionStrategy hdrConversionStrategy, ui::Hdr* outPreferredHdrOutputType) {
int hdrType;
binder::Status status = ComposerServiceAIDL::getComposerService()
->setHdrConversionStrategy(hdrConversionStrategy, &hdrType);
*outPreferredHdrOutputType = static_cast<ui::Hdr>(hdrType);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getHdrOutputConversionSupport(bool* isSupported) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->getHdrOutputConversionSupport(isSupported);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setGameModeFrameRateOverride(uid_t uid, float frameRate) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->setGameModeFrameRateOverride(uid, frameRate);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setGameDefaultFrameRateOverride(uid_t uid, float frameRate) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->setGameDefaultFrameRateOverride(uid,
frameRate);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::updateSmallAreaDetection(std::vector<int32_t>& appIds,
std::vector<float>& thresholds) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->updateSmallAreaDetection(appIds, thresholds);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setSmallAreaDetectionThreshold(int32_t appId, float threshold) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->setSmallAreaDetectionThreshold(appId,
threshold);
return statusTFromBinderStatus(status);
}
void SurfaceComposerClient::setAutoLowLatencyMode(const sp<IBinder>& display, bool on) {
ComposerServiceAIDL::getComposerService()->setAutoLowLatencyMode(display, on);
}
void SurfaceComposerClient::setGameContentType(const sp<IBinder>& display, bool on) {
ComposerServiceAIDL::getComposerService()->setGameContentType(display, on);
}
void SurfaceComposerClient::setDisplayPowerMode(const sp<IBinder>& token,
int mode) {
ComposerServiceAIDL::getComposerService()->setPowerMode(token, mode);
}
status_t SurfaceComposerClient::getCompositionPreference(
ui::Dataspace* defaultDataspace, ui::PixelFormat* defaultPixelFormat,
ui::Dataspace* wideColorGamutDataspace, ui::PixelFormat* wideColorGamutPixelFormat) {
gui::CompositionPreference pref;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getCompositionPreference(&pref);
if (status.isOk()) {
*defaultDataspace = static_cast<ui::Dataspace>(pref.defaultDataspace);
*defaultPixelFormat = static_cast<ui::PixelFormat>(pref.defaultPixelFormat);
*wideColorGamutDataspace = static_cast<ui::Dataspace>(pref.wideColorGamutDataspace);
*wideColorGamutPixelFormat = static_cast<ui::PixelFormat>(pref.wideColorGamutPixelFormat);
}
return statusTFromBinderStatus(status);
}
bool SurfaceComposerClient::getProtectedContentSupport() {
bool supported = false;
ComposerServiceAIDL::getComposerService()->getProtectedContentSupport(&supported);
return supported;
}
status_t SurfaceComposerClient::clearAnimationFrameStats() {
binder::Status status = ComposerServiceAIDL::getComposerService()->clearAnimationFrameStats();
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getAnimationFrameStats(FrameStats* outStats) {
gui::FrameStats stats;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getAnimationFrameStats(&stats);
if (status.isOk()) {
outStats->refreshPeriodNano = stats.refreshPeriodNano;
outStats->desiredPresentTimesNano.setCapacity(stats.desiredPresentTimesNano.size());
for (const auto& t : stats.desiredPresentTimesNano) {
outStats->desiredPresentTimesNano.add(t);
}
outStats->actualPresentTimesNano.setCapacity(stats.actualPresentTimesNano.size());
for (const auto& t : stats.actualPresentTimesNano) {
outStats->actualPresentTimesNano.add(t);
}
outStats->frameReadyTimesNano.setCapacity(stats.frameReadyTimesNano.size());
for (const auto& t : stats.frameReadyTimesNano) {
outStats->frameReadyTimesNano.add(t);
}
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::overrideHdrTypes(const sp<IBinder>& display,
const std::vector<ui::Hdr>& hdrTypes) {
std::vector<int32_t> hdrTypesVector;
hdrTypesVector.reserve(hdrTypes.size());
for (auto t : hdrTypes) {
hdrTypesVector.push_back(static_cast<int32_t>(t));
}
binder::Status status =
ComposerServiceAIDL::getComposerService()->overrideHdrTypes(display, hdrTypesVector);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::onPullAtom(const int32_t atomId, std::string* outData,
bool* success) {
gui::PullAtomData pad;
binder::Status status = ComposerServiceAIDL::getComposerService()->onPullAtom(atomId, &pad);
if (status.isOk()) {
outData->assign(pad.data.begin(), pad.data.end());
*success = pad.success;
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getDisplayedContentSamplingAttributes(const sp<IBinder>& display,
ui::PixelFormat* outFormat,
ui::Dataspace* outDataspace,
uint8_t* outComponentMask) {
if (!outFormat || !outDataspace || !outComponentMask) {
return BAD_VALUE;
}
gui::ContentSamplingAttributes attrs;
binder::Status status = ComposerServiceAIDL::getComposerService()
->getDisplayedContentSamplingAttributes(display, &attrs);
if (status.isOk()) {
*outFormat = static_cast<ui::PixelFormat>(attrs.format);
*outDataspace = static_cast<ui::Dataspace>(attrs.dataspace);
*outComponentMask = static_cast<uint8_t>(attrs.componentMask);
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setDisplayContentSamplingEnabled(const sp<IBinder>& display,
bool enable, uint8_t componentMask,
uint64_t maxFrames) {
binder::Status status =
ComposerServiceAIDL::getComposerService()
->setDisplayContentSamplingEnabled(display, enable,
static_cast<int8_t>(componentMask),
static_cast<int64_t>(maxFrames));
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::getDisplayedContentSample(const sp<IBinder>& display,
uint64_t maxFrames, uint64_t timestamp,
DisplayedFrameStats* outStats) {
if (!outStats) {
return BAD_VALUE;
}
gui::DisplayedFrameStats stats;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDisplayedContentSample(display, maxFrames,
timestamp, &stats);
if (status.isOk()) {
// convert gui::DisplayedFrameStats to ui::DisplayedFrameStats
outStats->numFrames = static_cast<uint64_t>(stats.numFrames);
outStats->component_0_sample.reserve(stats.component_0_sample.size());
for (const auto& s : stats.component_0_sample) {
outStats->component_0_sample.push_back(static_cast<uint64_t>(s));
}
outStats->component_1_sample.reserve(stats.component_1_sample.size());
for (const auto& s : stats.component_1_sample) {
outStats->component_1_sample.push_back(static_cast<uint64_t>(s));
}
outStats->component_2_sample.reserve(stats.component_2_sample.size());
for (const auto& s : stats.component_2_sample) {
outStats->component_2_sample.push_back(static_cast<uint64_t>(s));
}
outStats->component_3_sample.reserve(stats.component_3_sample.size());
for (const auto& s : stats.component_3_sample) {
outStats->component_3_sample.push_back(static_cast<uint64_t>(s));
}
}
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::isWideColorDisplay(const sp<IBinder>& display,
bool* outIsWideColorDisplay) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->isWideColorDisplay(display,
outIsWideColorDisplay);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::addRegionSamplingListener(
const Rect& samplingArea, const sp<IBinder>& stopLayerHandle,
const sp<IRegionSamplingListener>& listener) {
gui::ARect rect;
rect.left = samplingArea.left;
rect.top = samplingArea.top;
rect.right = samplingArea.right;
rect.bottom = samplingArea.bottom;
binder::Status status =
ComposerServiceAIDL::getComposerService()->addRegionSamplingListener(rect,
stopLayerHandle,
listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::removeRegionSamplingListener(
const sp<IRegionSamplingListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->removeRegionSamplingListener(listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::addFpsListener(int32_t taskId,
const sp<gui::IFpsListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->addFpsListener(taskId, listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::removeFpsListener(const sp<gui::IFpsListener>& listener) {
binder::Status status = ComposerServiceAIDL::getComposerService()->removeFpsListener(listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::addTunnelModeEnabledListener(
const sp<gui::ITunnelModeEnabledListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->addTunnelModeEnabledListener(listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::removeTunnelModeEnabledListener(
const sp<gui::ITunnelModeEnabledListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->removeTunnelModeEnabledListener(listener);
return statusTFromBinderStatus(status);
}
bool SurfaceComposerClient::getDisplayBrightnessSupport(const sp<IBinder>& displayToken) {
bool support = false;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDisplayBrightnessSupport(displayToken,
&support);
return status.isOk() ? support : false;
}
status_t SurfaceComposerClient::setDisplayBrightness(const sp<IBinder>& displayToken,
const gui::DisplayBrightness& brightness) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->setDisplayBrightness(displayToken,
brightness);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::addHdrLayerInfoListener(
const sp<IBinder>& displayToken, const sp<gui::IHdrLayerInfoListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->addHdrLayerInfoListener(displayToken,
listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::removeHdrLayerInfoListener(
const sp<IBinder>& displayToken, const sp<gui::IHdrLayerInfoListener>& listener) {
binder::Status status =
ComposerServiceAIDL::getComposerService()->removeHdrLayerInfoListener(displayToken,
listener);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::notifyPowerBoost(int32_t boostId) {
binder::Status status = ComposerServiceAIDL::getComposerService()->notifyPowerBoost(boostId);
return statusTFromBinderStatus(status);
}
status_t SurfaceComposerClient::setGlobalShadowSettings(const half4& ambientColor,
const half4& spotColor, float lightPosY,
float lightPosZ, float lightRadius) {
gui::Color ambientColorG, spotColorG;
ambientColorG.r = ambientColor.r;
ambientColorG.g = ambientColor.g;
ambientColorG.b = ambientColor.b;
ambientColorG.a = ambientColor.a;
spotColorG.r = spotColor.r;
spotColorG.g = spotColor.g;
spotColorG.b = spotColor.b;
spotColorG.a = spotColor.a;
binder::Status status =
ComposerServiceAIDL::getComposerService()->setGlobalShadowSettings(ambientColorG,
spotColorG,
lightPosY, lightPosZ,
lightRadius);
return statusTFromBinderStatus(status);
}
std::optional<DisplayDecorationSupport> SurfaceComposerClient::getDisplayDecorationSupport(
const sp<IBinder>& displayToken) {
std::optional<gui::DisplayDecorationSupport> gsupport;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getDisplayDecorationSupport(displayToken,
&gsupport);
std::optional<DisplayDecorationSupport> support;
if (status.isOk() && gsupport.has_value()) {
support.emplace(DisplayDecorationSupport{
.format =
static_cast<aidl::android::hardware::graphics::common::PixelFormat>(
gsupport->format),
.alphaInterpretation =
static_cast<aidl::android::hardware::graphics::common::AlphaInterpretation>(
gsupport->alphaInterpretation)
});
}
return support;
}
int SurfaceComposerClient::getGpuContextPriority() {
int priority;
binder::Status status =
ComposerServiceAIDL::getComposerService()->getGpuContextPriority(&priority);
if (!status.isOk()) {
status_t err = statusTFromBinderStatus(status);
ALOGE("getGpuContextPriority failed to read data: %s (%d)", strerror(-err), err);
return 0;
}
return priority;
}
status_t SurfaceComposerClient::addWindowInfosListener(
const sp<WindowInfosListener>& windowInfosListener,
std::pair<std::vector<gui::WindowInfo>, std::vector<gui::DisplayInfo>>* outInitialInfo) {
return WindowInfosListenerReporter::getInstance()
->addWindowInfosListener(windowInfosListener, ComposerServiceAIDL::getComposerService(),
outInitialInfo);
}
status_t SurfaceComposerClient::removeWindowInfosListener(
const sp<WindowInfosListener>& windowInfosListener) {
return WindowInfosListenerReporter::getInstance()
->removeWindowInfosListener(windowInfosListener,
ComposerServiceAIDL::getComposerService());
}
// ----------------------------------------------------------------------------
status_t ScreenshotClient::captureDisplay(const DisplayCaptureArgs& captureArgs,
const sp<IScreenCaptureListener>& captureListener) {
sp<gui::ISurfaceComposer> s(ComposerServiceAIDL::getComposerService());
if (s == nullptr) return NO_INIT;
binder::Status status = s->captureDisplay(captureArgs, captureListener);
return statusTFromBinderStatus(status);
}
status_t ScreenshotClient::captureDisplay(DisplayId displayId, const gui::CaptureArgs& captureArgs,
const sp<IScreenCaptureListener>& captureListener) {
sp<gui::ISurfaceComposer> s(ComposerServiceAIDL::getComposerService());
if (s == nullptr) return NO_INIT;
binder::Status status = s->captureDisplayById(displayId.value, captureArgs, captureListener);
return statusTFromBinderStatus(status);
}
status_t ScreenshotClient::captureLayers(const LayerCaptureArgs& captureArgs,
const sp<IScreenCaptureListener>& captureListener) {
sp<gui::ISurfaceComposer> s(ComposerServiceAIDL::getComposerService());
if (s == nullptr) return NO_INIT;
binder::Status status = s->captureLayers(captureArgs, captureListener);
return statusTFromBinderStatus(status);
}
// ---------------------------------------------------------------------------------
void ReleaseCallbackThread::addReleaseCallback(const ReleaseCallbackId callbackId,
sp<Fence> releaseFence) {
std::scoped_lock<std::mutex> lock(mMutex);
if (!mStarted) {
mThread = std::thread(&ReleaseCallbackThread::threadMain, this);
mStarted = true;
}
mCallbackInfos.emplace(callbackId, std::move(releaseFence));
mReleaseCallbackPending.notify_one();
}
void ReleaseCallbackThread::threadMain() {
const auto listener = TransactionCompletedListener::getInstance();
std::queue<std::tuple<const ReleaseCallbackId, const sp<Fence>>> callbackInfos;
while (true) {
{
std::unique_lock<std::mutex> lock(mMutex);
base::ScopedLockAssertion assumeLocked(mMutex);
callbackInfos = std::move(mCallbackInfos);
mCallbackInfos = {};
}
while (!callbackInfos.empty()) {
auto [callbackId, releaseFence] = callbackInfos.front();
listener->onReleaseBuffer(callbackId, std::move(releaseFence), UINT_MAX);
callbackInfos.pop();
}
{
std::unique_lock<std::mutex> lock(mMutex);
base::ScopedLockAssertion assumeLocked(mMutex);
if (mCallbackInfos.size() == 0) {
mReleaseCallbackPending.wait(lock);
}
}
}
}
} // namespace android