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/*
* Copyright (C) 2012 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.
*/
#ifndef ANDROID_DISPSYNC_H
#define ANDROID_DISPSYNC_H
#include <stddef.h>
#include <utils/Mutex.h>
#include <utils/RefBase.h>
#include <utils/Timers.h>
#include <ui/FenceTime.h>
#include <memory>
namespace android {
class String8;
class FenceTime;
class DispSyncThread;
// DispSync maintains a model of the periodic hardware-based vsync events of a
// display and uses that model to execute period callbacks at specific phase
// offsets from the hardware vsync events. The model is constructed by
// feeding consecutive hardware event timestamps to the DispSync object via
// the addResyncSample method.
//
// The model is validated using timestamps from Fence objects that are passed
// to the DispSync object via the addPresentFence method. These fence
// timestamps should correspond to a hardware vsync event, but they need not
// be consecutive hardware vsync times. If this method determines that the
// current model accurately represents the hardware event times it will return
// false to indicate that a resynchronization (via addResyncSample) is not
// needed.
class DispSync {
public:
class Callback {
public:
virtual ~Callback(){};
virtual void onDispSyncEvent(nsecs_t when) = 0;
};
explicit DispSync(const char* name);
~DispSync();
void init(bool hasSyncFramework, int64_t dispSyncPresentTimeOffset);
// reset clears the resync samples and error value.
void reset();
// addPresentFence adds a fence for use in validating the current vsync
// event model. The fence need not be signaled at the time
// addPresentFence is called. When the fence does signal, its timestamp
// should correspond to a hardware vsync event. Unlike the
// addResyncSample method, the timestamps of consecutive fences need not
// correspond to consecutive hardware vsync events.
//
// This method should be called with the retire fence from each HWComposer
// set call that affects the display.
bool addPresentFence(const std::shared_ptr<FenceTime>& fenceTime);
// The beginResync, addResyncSample, and endResync methods are used to re-
// synchronize the DispSync's model to the hardware vsync events. The re-
// synchronization process involves first calling beginResync, then
// calling addResyncSample with a sequence of consecutive hardware vsync
// event timestamps, and finally calling endResync when addResyncSample
// indicates that no more samples are needed by returning false.
//
// This resynchronization process should be performed whenever the display
// is turned on (i.e. once immediately after it's turned on) and whenever
// addPresentFence returns true indicating that the model has drifted away
// from the hardware vsync events.
void beginResync();
bool addResyncSample(nsecs_t timestamp);
void endResync();
// The setPeriod method sets the vsync event model's period to a specific
// value. This should be used to prime the model when a display is first
// turned on. It should NOT be used after that.
void setPeriod(nsecs_t period);
// The getPeriod method returns the current vsync period.
nsecs_t getPeriod();
// setRefreshSkipCount specifies an additional number of refresh
// cycles to skip. For example, on a 60Hz display, a skip count of 1
// will result in events happening at 30Hz. Default is zero. The idea
// is to sacrifice smoothness for battery life.
void setRefreshSkipCount(int count);
// addEventListener registers a callback to be called repeatedly at the
// given phase offset from the hardware vsync events. The callback is
// called from a separate thread and it should return reasonably quickly
// (i.e. within a few hundred microseconds).
status_t addEventListener(const char* name, nsecs_t phase, Callback* callback);
// removeEventListener removes an already-registered event callback. Once
// this method returns that callback will no longer be called by the
// DispSync object.
status_t removeEventListener(Callback* callback);
// changePhaseOffset changes the phase offset of an already-registered event callback. The
// method will make sure that there is no skipping or double-firing on the listener per frame,
// even when changing the offsets multiple times.
status_t changePhaseOffset(Callback* callback, nsecs_t phase);
// computeNextRefresh computes when the next refresh is expected to begin.
// The periodOffset value can be used to move forward or backward; an
// offset of zero is the next refresh, -1 is the previous refresh, 1 is
// the refresh after next. etc.
nsecs_t computeNextRefresh(int periodOffset) const;
// dump appends human-readable debug info to the result string.
void dump(String8& result) const;
private:
void updateModelLocked();
void updateErrorLocked();
void resetErrorLocked();
enum { MAX_RESYNC_SAMPLES = 32 };
enum { MIN_RESYNC_SAMPLES_FOR_UPDATE = 6 };
enum { NUM_PRESENT_SAMPLES = 8 };
enum { MAX_RESYNC_SAMPLES_WITHOUT_PRESENT = 4 };
enum { ACCEPTABLE_ZERO_ERR_SAMPLES_COUNT = 64 };
const char* const mName;
// mPeriod is the computed period of the modeled vsync events in
// nanoseconds.
nsecs_t mPeriod;
// mPhase is the phase offset of the modeled vsync events. It is the
// number of nanoseconds from time 0 to the first vsync event.
nsecs_t mPhase;
// mReferenceTime is the reference time of the modeled vsync events.
// It is the nanosecond timestamp of the first vsync event after a resync.
nsecs_t mReferenceTime;
// mError is the computed model error. It is based on the difference
// between the estimated vsync event times and those observed in the
// mPresentFences array.
nsecs_t mError;
// mZeroErrSamplesCount keeps track of how many times in a row there were
// zero timestamps available in the mPresentFences array.
// Used to sanity check that we are able to calculate the model error.
size_t mZeroErrSamplesCount;
// Whether we have updated the vsync event model since the last resync.
bool mModelUpdated;
// These member variables are the state used during the resynchronization
// process to store information about the hardware vsync event times used
// to compute the model.
nsecs_t mResyncSamples[MAX_RESYNC_SAMPLES];
size_t mFirstResyncSample;
size_t mNumResyncSamples;
int mNumResyncSamplesSincePresent;
// These member variables store information about the present fences used
// to validate the currently computed model.
std::shared_ptr<FenceTime> mPresentFences[NUM_PRESENT_SAMPLES]{FenceTime::NO_FENCE};
size_t mPresentSampleOffset;
int mRefreshSkipCount;
// mThread is the thread from which all the callbacks are called.
sp<DispSyncThread> mThread;
// mMutex is used to protect access to all member variables.
mutable Mutex mMutex;
// This is the offset from the present fence timestamps to the corresponding
// vsync event.
int64_t mPresentTimeOffset;
// Ignore present (retire) fences if the device doesn't have support for the
// sync framework
bool mIgnorePresentFences;
std::unique_ptr<Callback> mZeroPhaseTracer;
};
} // namespace android
#endif // ANDROID_DISPSYNC_H