libs/vr/libvrflinger/vsync_service.cpp - third_party/android/platform/frameworks/native - Git at Google

 #include "vsync_service.h"

 #include <hardware/hwcomposer.h>
 #include <log/log.h>
 #include <poll.h>
 #include <sys/prctl.h>
 #include <time.h>
 #include <utils/Trace.h>

 #include <dvr/dvr_display_types.h>
 #include <pdx/default_transport/service_endpoint.h>
 #include <private/dvr/clock_ns.h>
 #include <private/dvr/display_protocol.h>

 using android::dvr::display::VSyncProtocol;
 using android::dvr::display::VSyncSchedInfo;
 using android::pdx::Channel;
 using android::pdx::Message;
 using android::pdx::MessageInfo;
 using android::pdx::default_transport::Endpoint;
 using android::pdx::rpc::DispatchRemoteMethod;

 namespace android {
 namespace dvr {

 VSyncService::VSyncService()
     : BASE("VSyncService", Endpoint::Create(VSyncProtocol::kClientPath)),
       last_vsync_(0),
       current_vsync_(0),
       compositor_time_ns_(0),
       current_vsync_count_(0) {}

 VSyncService::~VSyncService() {}

 void VSyncService::VSyncEvent(int display, int64_t timestamp_ns,
                               int64_t compositor_time_ns,
                               uint32_t vsync_count) {
   ATRACE_NAME("VSyncService::VSyncEvent");
   std::lock_guard<std::mutex> autolock(mutex_);

   if (display == HWC_DISPLAY_PRIMARY) {
     last_vsync_ = current_vsync_;
     current_vsync_ = timestamp_ns;
     compositor_time_ns_ = compositor_time_ns;
     current_vsync_count_ = vsync_count;

     NotifyWaiters();
     UpdateClients();
   }
 }

 std::shared_ptr<Channel> VSyncService::OnChannelOpen(pdx::Message& message) {
   const MessageInfo& info = message.GetInfo();

   auto client = std::make_shared<VSyncChannel>(*this, info.pid, info.cid);
   AddClient(client);

   return client;
 }

 void VSyncService::OnChannelClose(pdx::Message& /*message*/,
                                   const std::shared_ptr<Channel>& channel) {
   auto client = std::static_pointer_cast<VSyncChannel>(channel);
   if (!client) {
     ALOGW("WARNING: VSyncChannel was NULL!!!\n");
     return;
   }

   RemoveClient(client);
 }

 void VSyncService::AddWaiter(pdx::Message& message) {
   std::lock_guard<std::mutex> autolock(mutex_);
   std::unique_ptr<VSyncWaiter> waiter(new VSyncWaiter(message));
   waiters_.push_back(std::move(waiter));
 }

 void VSyncService::AddClient(const std::shared_ptr<VSyncChannel>& client) {
   std::lock_guard<std::mutex> autolock(mutex_);
   clients_.push_back(client);
 }

 void VSyncService::RemoveClient(const std::shared_ptr<VSyncChannel>& client) {
   std::lock_guard<std::mutex> autolock(mutex_);
   clients_.remove(client);
 }

 // Private. Assumes mutex is held.
 void VSyncService::NotifyWaiters() {
   ATRACE_NAME("VSyncService::NotifyWaiters");
   auto first = waiters_.begin();
   auto last = waiters_.end();

   while (first != last) {
     (*first)->Notify(current_vsync_);
     waiters_.erase(first++);
   }
 }

 // Private. Assumes mutex is held.
 void VSyncService::UpdateClients() {
   ATRACE_NAME("VSyncService::UpdateClients");
   auto first = clients_.begin();
   auto last = clients_.end();

   while (first != last) {
     (*first)->Signal();
     first++;
   }
 }

 pdx::Status<void> VSyncService::HandleMessage(pdx::Message& message) {
   ATRACE_NAME("VSyncService::HandleMessage");
   switch (message.GetOp()) {
     case VSyncProtocol::Wait::Opcode:
       AddWaiter(message);
       return {};

     case VSyncProtocol::GetLastTimestamp::Opcode:
       DispatchRemoteMethod<VSyncProtocol::GetLastTimestamp>(
           *this, &VSyncService::OnGetLastTimestamp, message);
       return {};

     case VSyncProtocol::GetSchedInfo::Opcode:
       DispatchRemoteMethod<VSyncProtocol::GetSchedInfo>(
           *this, &VSyncService::OnGetSchedInfo, message);
       return {};

     case VSyncProtocol::Acknowledge::Opcode:
       DispatchRemoteMethod<VSyncProtocol::Acknowledge>(
           *this, &VSyncService::OnAcknowledge, message);
       return {};

     default:
       return Service::HandleMessage(message);
   }
 }

 pdx::Status<int64_t> VSyncService::OnGetLastTimestamp(pdx::Message& message) {
   auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
   std::lock_guard<std::mutex> autolock(mutex_);

   // Getting the timestamp has the side effect of ACKing.
   client->Ack();
   return {current_vsync_};
 }

 pdx::Status<VSyncSchedInfo> VSyncService::OnGetSchedInfo(
     pdx::Message& message) {
   auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
   std::lock_guard<std::mutex> autolock(mutex_);

   // Getting the timestamp has the side effect of ACKing.
   client->Ack();

   uint32_t next_vsync_count = current_vsync_count_ + 1;
   int64_t current_time = GetSystemClockNs();
   int64_t vsync_period_ns = 0;
   int64_t next_warp;
   if (current_vsync_ == 0 || last_vsync_ == 0) {
     // Handle startup when current_vsync_ or last_vsync_ are 0.
     // Normally should not happen because vsync_service is running before
     // applications, but in case it does a sane time prevents applications
     // from malfunctioning.
     vsync_period_ns = 20000000;
     next_warp = current_time;
   } else {
     // TODO(jbates) When we have an accurate reading of the true vsync
     // period, use that instead of this estimated value.
     vsync_period_ns = current_vsync_ - last_vsync_;
     // Clamp the period, because when there are no surfaces the last_vsync_
     // value will get stale. Note this is temporary and goes away as soon
     // as we have an accurate vsync period reported by the system.
     vsync_period_ns = std::min(vsync_period_ns, INT64_C(20000000));
     next_warp = current_vsync_ + vsync_period_ns - compositor_time_ns_;
     // If the request missed the present window, move up to the next vsync.
     if (current_time > next_warp) {
       next_warp += vsync_period_ns;
       ++next_vsync_count;
     }
   }

   return {{vsync_period_ns, next_warp, next_vsync_count}};
 }

 pdx::Status<void> VSyncService::OnAcknowledge(pdx::Message& message) {
   auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
   std::lock_guard<std::mutex> autolock(mutex_);
   client->Ack();
   return {};
 }

 void VSyncWaiter::Notify(int64_t timestamp) {
   timestamp_ = timestamp;
   DispatchRemoteMethod<VSyncProtocol::Wait>(*this, &VSyncWaiter::OnWait,
                                             message_);
 }

 pdx::Status<int64_t> VSyncWaiter::OnWait(pdx::Message& /*message*/) {
   return {timestamp_};
 }

 void VSyncChannel::Ack() {
   ALOGD_IF(TRACE > 1, "VSyncChannel::Ack: pid=%d cid=%d\n", pid_, cid_);
   service_.ModifyChannelEvents(cid_, POLLPRI, 0);
 }

 void VSyncChannel::Signal() {
   ALOGD_IF(TRACE > 1, "VSyncChannel::Signal: pid=%d cid=%d\n", pid_, cid_);
   service_.ModifyChannelEvents(cid_, 0, POLLPRI);
 }

 }  // namespace dvr
 }  // namespace android
	#include "vsync_service.h"

	#include <hardware/hwcomposer.h>
	#include <log/log.h>
	#include <poll.h>
	#include <sys/prctl.h>
	#include <time.h>
	#include <utils/Trace.h>

	#include <dvr/dvr_display_types.h>
	#include <pdx/default_transport/service_endpoint.h>
	#include <private/dvr/clock_ns.h>
	#include <private/dvr/display_protocol.h>

	using android::dvr::display::VSyncProtocol;
	using android::dvr::display::VSyncSchedInfo;
	using android::pdx::Channel;
	using android::pdx::Message;
	using android::pdx::MessageInfo;
	using android::pdx::default_transport::Endpoint;
	using android::pdx::rpc::DispatchRemoteMethod;

	namespace android {
	namespace dvr {

	VSyncService::VSyncService()
	: BASE("VSyncService", Endpoint::Create(VSyncProtocol::kClientPath)),
	last_vsync_(0),
	current_vsync_(0),
	compositor_time_ns_(0),
	current_vsync_count_(0) {}

	VSyncService::~VSyncService() {}

	void VSyncService::VSyncEvent(int display, int64_t timestamp_ns,
	int64_t compositor_time_ns,
	uint32_t vsync_count) {
	ATRACE_NAME("VSyncService::VSyncEvent");
	std::lock_guard<std::mutex> autolock(mutex_);

	if (display == HWC_DISPLAY_PRIMARY) {
	last_vsync_ = current_vsync_;
	current_vsync_ = timestamp_ns;
	compositor_time_ns_ = compositor_time_ns;
	current_vsync_count_ = vsync_count;

	NotifyWaiters();
	UpdateClients();
	}
	}

	std::shared_ptr<Channel> VSyncService::OnChannelOpen(pdx::Message& message) {
	const MessageInfo& info = message.GetInfo();

	auto client = std::make_shared<VSyncChannel>(*this, info.pid, info.cid);
	AddClient(client);

	return client;
	}

	void VSyncService::OnChannelClose(pdx::Message& /message/,
	const std::shared_ptr<Channel>& channel) {
	auto client = std::static_pointer_cast<VSyncChannel>(channel);
	if (!client) {
	ALOGW("WARNING: VSyncChannel was NULL!!!\n");
	return;
	}

	RemoveClient(client);
	}

	void VSyncService::AddWaiter(pdx::Message& message) {
	std::lock_guard<std::mutex> autolock(mutex_);
	std::unique_ptr<VSyncWaiter> waiter(new VSyncWaiter(message));
	waiters_.push_back(std::move(waiter));
	}

	void VSyncService::AddClient(const std::shared_ptr<VSyncChannel>& client) {
	std::lock_guard<std::mutex> autolock(mutex_);
	clients_.push_back(client);
	}

	void VSyncService::RemoveClient(const std::shared_ptr<VSyncChannel>& client) {
	std::lock_guard<std::mutex> autolock(mutex_);
	clients_.remove(client);
	}

	// Private. Assumes mutex is held.
	void VSyncService::NotifyWaiters() {
	ATRACE_NAME("VSyncService::NotifyWaiters");
	auto first = waiters_.begin();
	auto last = waiters_.end();

	while (first != last) {
	(*first)->Notify(current_vsync_);
	waiters_.erase(first++);
	}
	}

	// Private. Assumes mutex is held.
	void VSyncService::UpdateClients() {
	ATRACE_NAME("VSyncService::UpdateClients");
	auto first = clients_.begin();
	auto last = clients_.end();

	while (first != last) {
	(*first)->Signal();
	first++;
	}
	}

	pdx::Status<void> VSyncService::HandleMessage(pdx::Message& message) {
	ATRACE_NAME("VSyncService::HandleMessage");
	switch (message.GetOp()) {
	case VSyncProtocol::Wait::Opcode:
	AddWaiter(message);
	return {};

	case VSyncProtocol::GetLastTimestamp::Opcode:
	DispatchRemoteMethod<VSyncProtocol::GetLastTimestamp>(
	*this, &VSyncService::OnGetLastTimestamp, message);
	return {};

	case VSyncProtocol::GetSchedInfo::Opcode:
	DispatchRemoteMethod<VSyncProtocol::GetSchedInfo>(
	*this, &VSyncService::OnGetSchedInfo, message);
	return {};

	case VSyncProtocol::Acknowledge::Opcode:
	DispatchRemoteMethod<VSyncProtocol::Acknowledge>(
	*this, &VSyncService::OnAcknowledge, message);
	return {};

	default:
	return Service::HandleMessage(message);
	}
	}

	pdx::Status<int64_t> VSyncService::OnGetLastTimestamp(pdx::Message& message) {
	auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
	std::lock_guard<std::mutex> autolock(mutex_);

	// Getting the timestamp has the side effect of ACKing.
	client->Ack();
	return {current_vsync_};
	}

	pdx::Status<VSyncSchedInfo> VSyncService::OnGetSchedInfo(
	pdx::Message& message) {
	auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
	std::lock_guard<std::mutex> autolock(mutex_);

	// Getting the timestamp has the side effect of ACKing.
	client->Ack();

	uint32_t next_vsync_count = current_vsync_count_ + 1;
	int64_t current_time = GetSystemClockNs();
	int64_t vsync_period_ns = 0;
	int64_t next_warp;
	if (current_vsync_ == 0 \|\| last_vsync_ == 0) {
	// Handle startup when current_vsync_ or last_vsync_ are 0.
	// Normally should not happen because vsync_service is running before
	// applications, but in case it does a sane time prevents applications
	// from malfunctioning.
	vsync_period_ns = 20000000;
	next_warp = current_time;
	} else {
	// TODO(jbates) When we have an accurate reading of the true vsync
	// period, use that instead of this estimated value.
	vsync_period_ns = current_vsync_ - last_vsync_;
	// Clamp the period, because when there are no surfaces the last_vsync_
	// value will get stale. Note this is temporary and goes away as soon
	// as we have an accurate vsync period reported by the system.
	vsync_period_ns = std::min(vsync_period_ns, INT64_C(20000000));
	next_warp = current_vsync_ + vsync_period_ns - compositor_time_ns_;
	// If the request missed the present window, move up to the next vsync.
	if (current_time > next_warp) {
	next_warp += vsync_period_ns;
	++next_vsync_count;
	}
	}

	return {{vsync_period_ns, next_warp, next_vsync_count}};
	}

	pdx::Status<void> VSyncService::OnAcknowledge(pdx::Message& message) {
	auto client = std::static_pointer_cast<VSyncChannel>(message.GetChannel());
	std::lock_guard<std::mutex> autolock(mutex_);
	client->Ack();
	return {};
	}

	void VSyncWaiter::Notify(int64_t timestamp) {
	timestamp_ = timestamp;
	DispatchRemoteMethod<VSyncProtocol::Wait>(*this, &VSyncWaiter::OnWait,
	message_);
	}

	pdx::Status<int64_t> VSyncWaiter::OnWait(pdx::Message& /message/) {
	return {timestamp_};
	}

	void VSyncChannel::Ack() {
	ALOGD_IF(TRACE > 1, "VSyncChannel::Ack: pid=%d cid=%d\n", pid_, cid_);
	service_.ModifyChannelEvents(cid_, POLLPRI, 0);
	}

	void VSyncChannel::Signal() {
	ALOGD_IF(TRACE > 1, "VSyncChannel::Signal: pid=%d cid=%d\n", pid_, cid_);
	service_.ModifyChannelEvents(cid_, 0, POLLPRI);
	}

	} // namespace dvr
	} // namespace android