replicant-frameworks_native/services/surfaceflinger/DispSync.cpp
Haixia Shi 179bd77ab6 SF: more DispSync improvements.
Pass the reference time to DispSyncThread. Since the phase offset is calculated
using timestamps relative to the reference time, we must also adjust the phase
offset by the same reference time when computing the next refresh time.

Always reset phase offset to zero when updating the reference time because the
reference time equals the first timestamp.

After beginResync() we need to keep HW vsync enabled until the model is updated.

Bug: 25113115
Change-Id: I8eae227bee91c24a99bf8e57fbebceb98d29c77d
Test: check in systrace that app/sf vsync events have correct phase
2016-07-20 04:16:16 -07:00

582 lines
18 KiB
C++

/*
* Copyright (C) 2013 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 ATRACE_TAG ATRACE_TAG_GRAPHICS
// This is needed for stdint.h to define INT64_MAX in C++
#define __STDC_LIMIT_MACROS
#include <math.h>
#include <cutils/iosched_policy.h>
#include <cutils/log.h>
#include <ui/Fence.h>
#include <utils/String8.h>
#include <utils/Thread.h>
#include <utils/Trace.h>
#include <utils/Vector.h>
#include "DispSync.h"
#include "EventLog/EventLog.h"
namespace android {
// Setting this to true enables verbose tracing that can be used to debug
// vsync event model or phase issues.
static const bool kTraceDetailedInfo = false;
// This is the threshold used to determine when hardware vsync events are
// needed to re-synchronize the software vsync model with the hardware. The
// error metric used is the mean of the squared difference between each
// present time and the nearest software-predicted vsync.
static const nsecs_t kErrorThreshold = 160000000000; // 400 usec squared
// This is the offset from the present fence timestamps to the corresponding
// vsync event.
static const int64_t kPresentTimeOffset = PRESENT_TIME_OFFSET_FROM_VSYNC_NS;
class DispSyncThread: public Thread {
public:
DispSyncThread():
mStop(false),
mPeriod(0),
mPhase(0),
mReferenceTime(0),
mWakeupLatency(0) {
}
virtual ~DispSyncThread() {}
void updateModel(nsecs_t period, nsecs_t phase, nsecs_t referenceTime) {
Mutex::Autolock lock(mMutex);
mPeriod = period;
mPhase = phase;
mReferenceTime = referenceTime;
mCond.signal();
}
void stop() {
Mutex::Autolock lock(mMutex);
mStop = true;
mCond.signal();
}
virtual bool threadLoop() {
status_t err;
nsecs_t now = systemTime(SYSTEM_TIME_MONOTONIC);
nsecs_t nextEventTime = 0;
while (true) {
Vector<CallbackInvocation> callbackInvocations;
nsecs_t targetTime = 0;
{ // Scope for lock
Mutex::Autolock lock(mMutex);
if (mStop) {
return false;
}
if (mPeriod == 0) {
err = mCond.wait(mMutex);
if (err != NO_ERROR) {
ALOGE("error waiting for new events: %s (%d)",
strerror(-err), err);
return false;
}
continue;
}
nextEventTime = computeNextEventTimeLocked(now);
targetTime = nextEventTime;
bool isWakeup = false;
if (now < targetTime) {
err = mCond.waitRelative(mMutex, targetTime - now);
if (err == TIMED_OUT) {
isWakeup = true;
} else if (err != NO_ERROR) {
ALOGE("error waiting for next event: %s (%d)",
strerror(-err), err);
return false;
}
}
now = systemTime(SYSTEM_TIME_MONOTONIC);
if (isWakeup) {
mWakeupLatency = ((mWakeupLatency * 63) +
(now - targetTime)) / 64;
if (mWakeupLatency > 500000) {
// Don't correct by more than 500 us
mWakeupLatency = 500000;
}
if (kTraceDetailedInfo) {
ATRACE_INT64("DispSync:WakeupLat", now - nextEventTime);
ATRACE_INT64("DispSync:AvgWakeupLat", mWakeupLatency);
}
}
callbackInvocations = gatherCallbackInvocationsLocked(now);
}
if (callbackInvocations.size() > 0) {
fireCallbackInvocations(callbackInvocations);
}
}
return false;
}
status_t addEventListener(nsecs_t phase, const sp<DispSync::Callback>& callback) {
Mutex::Autolock lock(mMutex);
for (size_t i = 0; i < mEventListeners.size(); i++) {
if (mEventListeners[i].mCallback == callback) {
return BAD_VALUE;
}
}
EventListener listener;
listener.mPhase = phase;
listener.mCallback = callback;
// We want to allow the firstmost future event to fire without
// allowing any past events to fire. Because
// computeListenerNextEventTimeLocked filters out events within a half
// a period of the last event time, we need to initialize the last
// event time to a half a period in the past.
listener.mLastEventTime = systemTime(SYSTEM_TIME_MONOTONIC) - mPeriod / 2;
mEventListeners.push(listener);
mCond.signal();
return NO_ERROR;
}
status_t removeEventListener(const sp<DispSync::Callback>& callback) {
Mutex::Autolock lock(mMutex);
for (size_t i = 0; i < mEventListeners.size(); i++) {
if (mEventListeners[i].mCallback == callback) {
mEventListeners.removeAt(i);
mCond.signal();
return NO_ERROR;
}
}
return BAD_VALUE;
}
// This method is only here to handle the kIgnorePresentFences case.
bool hasAnyEventListeners() {
Mutex::Autolock lock(mMutex);
return !mEventListeners.empty();
}
private:
struct EventListener {
nsecs_t mPhase;
nsecs_t mLastEventTime;
sp<DispSync::Callback> mCallback;
};
struct CallbackInvocation {
sp<DispSync::Callback> mCallback;
nsecs_t mEventTime;
};
nsecs_t computeNextEventTimeLocked(nsecs_t now) {
nsecs_t nextEventTime = INT64_MAX;
for (size_t i = 0; i < mEventListeners.size(); i++) {
nsecs_t t = computeListenerNextEventTimeLocked(mEventListeners[i],
now);
if (t < nextEventTime) {
nextEventTime = t;
}
}
return nextEventTime;
}
Vector<CallbackInvocation> gatherCallbackInvocationsLocked(nsecs_t now) {
Vector<CallbackInvocation> callbackInvocations;
nsecs_t ref = now - mPeriod;
for (size_t i = 0; i < mEventListeners.size(); i++) {
nsecs_t t = computeListenerNextEventTimeLocked(mEventListeners[i],
ref);
if (t < now) {
CallbackInvocation ci;
ci.mCallback = mEventListeners[i].mCallback;
ci.mEventTime = t;
callbackInvocations.push(ci);
mEventListeners.editItemAt(i).mLastEventTime = t;
}
}
return callbackInvocations;
}
nsecs_t computeListenerNextEventTimeLocked(const EventListener& listener,
nsecs_t ref) {
nsecs_t lastEventTime = listener.mLastEventTime;
if (ref < lastEventTime) {
ref = lastEventTime;
}
nsecs_t phase = mReferenceTime + mPhase + listener.mPhase;
nsecs_t t = (((ref - phase) / mPeriod) + 1) * mPeriod + phase;
if (t - listener.mLastEventTime < mPeriod / 2) {
t += mPeriod;
}
return t;
}
void fireCallbackInvocations(const Vector<CallbackInvocation>& callbacks) {
for (size_t i = 0; i < callbacks.size(); i++) {
callbacks[i].mCallback->onDispSyncEvent(callbacks[i].mEventTime);
}
}
bool mStop;
nsecs_t mPeriod;
nsecs_t mPhase;
nsecs_t mReferenceTime;
nsecs_t mWakeupLatency;
Vector<EventListener> mEventListeners;
Mutex mMutex;
Condition mCond;
};
class ZeroPhaseTracer : public DispSync::Callback {
public:
ZeroPhaseTracer() : mParity(false) {}
virtual void onDispSyncEvent(nsecs_t /*when*/) {
mParity = !mParity;
ATRACE_INT("ZERO_PHASE_VSYNC", mParity ? 1 : 0);
}
private:
bool mParity;
};
DispSync::DispSync() :
mRefreshSkipCount(0),
mThread(new DispSyncThread()) {
mThread->run("DispSync", PRIORITY_URGENT_DISPLAY + PRIORITY_MORE_FAVORABLE);
android_set_rt_ioprio(mThread->getTid(), 1);
reset();
beginResync();
if (kTraceDetailedInfo) {
// If we're not getting present fences then the ZeroPhaseTracer
// would prevent HW vsync event from ever being turned off.
// Even if we're just ignoring the fences, the zero-phase tracing is
// not needed because any time there is an event registered we will
// turn on the HW vsync events.
if (!kIgnorePresentFences) {
addEventListener(0, new ZeroPhaseTracer());
}
}
}
DispSync::~DispSync() {}
void DispSync::reset() {
Mutex::Autolock lock(mMutex);
mPhase = 0;
mReferenceTime = 0;
mModelUpdated = false;
mNumResyncSamples = 0;
mFirstResyncSample = 0;
mNumResyncSamplesSincePresent = 0;
resetErrorLocked();
}
bool DispSync::addPresentFence(const sp<Fence>& fence) {
Mutex::Autolock lock(mMutex);
mPresentFences[mPresentSampleOffset] = fence;
mPresentTimes[mPresentSampleOffset] = 0;
mPresentSampleOffset = (mPresentSampleOffset + 1) % NUM_PRESENT_SAMPLES;
mNumResyncSamplesSincePresent = 0;
for (size_t i = 0; i < NUM_PRESENT_SAMPLES; i++) {
const sp<Fence>& f(mPresentFences[i]);
if (f != NULL) {
nsecs_t t = f->getSignalTime();
if (t < INT64_MAX) {
mPresentFences[i].clear();
mPresentTimes[i] = t + kPresentTimeOffset;
}
}
}
updateErrorLocked();
return !mModelUpdated || mError > kErrorThreshold;
}
void DispSync::beginResync() {
Mutex::Autolock lock(mMutex);
mModelUpdated = false;
mNumResyncSamples = 0;
}
bool DispSync::addResyncSample(nsecs_t timestamp) {
Mutex::Autolock lock(mMutex);
size_t idx = (mFirstResyncSample + mNumResyncSamples) % MAX_RESYNC_SAMPLES;
mResyncSamples[idx] = timestamp;
if (mNumResyncSamples == 0) {
mPhase = 0;
mReferenceTime = timestamp;
}
if (mNumResyncSamples < MAX_RESYNC_SAMPLES) {
mNumResyncSamples++;
} else {
mFirstResyncSample = (mFirstResyncSample + 1) % MAX_RESYNC_SAMPLES;
}
updateModelLocked();
if (mNumResyncSamplesSincePresent++ > MAX_RESYNC_SAMPLES_WITHOUT_PRESENT) {
resetErrorLocked();
}
if (kIgnorePresentFences) {
// If we don't have the sync framework we will never have
// addPresentFence called. This means we have no way to know whether
// or not we're synchronized with the HW vsyncs, so we just request
// that the HW vsync events be turned on whenever we need to generate
// SW vsync events.
return mThread->hasAnyEventListeners();
}
return !mModelUpdated || mError > kErrorThreshold;
}
void DispSync::endResync() {
}
status_t DispSync::addEventListener(nsecs_t phase,
const sp<Callback>& callback) {
Mutex::Autolock lock(mMutex);
return mThread->addEventListener(phase, callback);
}
void DispSync::setRefreshSkipCount(int count) {
Mutex::Autolock lock(mMutex);
ALOGD("setRefreshSkipCount(%d)", count);
mRefreshSkipCount = count;
updateModelLocked();
}
status_t DispSync::removeEventListener(const sp<Callback>& callback) {
Mutex::Autolock lock(mMutex);
return mThread->removeEventListener(callback);
}
void DispSync::setPeriod(nsecs_t period) {
Mutex::Autolock lock(mMutex);
mPeriod = period;
mPhase = 0;
mReferenceTime = 0;
mThread->updateModel(mPeriod, mPhase, mReferenceTime);
}
nsecs_t DispSync::getPeriod() {
// lock mutex as mPeriod changes multiple times in updateModelLocked
Mutex::Autolock lock(mMutex);
return mPeriod;
}
void DispSync::updateModelLocked() {
if (mNumResyncSamples >= MIN_RESYNC_SAMPLES_FOR_UPDATE) {
nsecs_t durationSum = 0;
for (size_t i = 1; i < mNumResyncSamples; i++) {
size_t idx = (mFirstResyncSample + i) % MAX_RESYNC_SAMPLES;
size_t prev = (idx + MAX_RESYNC_SAMPLES - 1) % MAX_RESYNC_SAMPLES;
durationSum += mResyncSamples[idx] - mResyncSamples[prev];
}
mPeriod = durationSum / (mNumResyncSamples - 1);
double sampleAvgX = 0;
double sampleAvgY = 0;
double scale = 2.0 * M_PI / double(mPeriod);
for (size_t i = 0; i < mNumResyncSamples; i++) {
size_t idx = (mFirstResyncSample + i) % MAX_RESYNC_SAMPLES;
nsecs_t sample = mResyncSamples[idx] - mReferenceTime;
double samplePhase = double(sample % mPeriod) * scale;
sampleAvgX += cos(samplePhase);
sampleAvgY += sin(samplePhase);
}
sampleAvgX /= double(mNumResyncSamples);
sampleAvgY /= double(mNumResyncSamples);
mPhase = nsecs_t(atan2(sampleAvgY, sampleAvgX) / scale);
if (mPhase < 0) {
mPhase += mPeriod;
}
if (kTraceDetailedInfo) {
ATRACE_INT64("DispSync:Period", mPeriod);
ATRACE_INT64("DispSync:Phase", mPhase);
}
// Artificially inflate the period if requested.
mPeriod += mPeriod * mRefreshSkipCount;
mThread->updateModel(mPeriod, mPhase, mReferenceTime);
mModelUpdated = true;
}
}
void DispSync::updateErrorLocked() {
if (!mModelUpdated) {
return;
}
// Need to compare present fences against the un-adjusted refresh period,
// since they might arrive between two events.
nsecs_t period = mPeriod / (1 + mRefreshSkipCount);
int numErrSamples = 0;
nsecs_t sqErrSum = 0;
for (size_t i = 0; i < NUM_PRESENT_SAMPLES; i++) {
nsecs_t sample = mPresentTimes[i] - mReferenceTime;
if (sample > mPhase) {
nsecs_t sampleErr = (sample - mPhase) % period;
if (sampleErr > period / 2) {
sampleErr -= period;
}
sqErrSum += sampleErr * sampleErr;
numErrSamples++;
}
}
if (numErrSamples > 0) {
mError = sqErrSum / numErrSamples;
} else {
mError = 0;
}
if (kTraceDetailedInfo) {
ATRACE_INT64("DispSync:Error", mError);
}
}
void DispSync::resetErrorLocked() {
mPresentSampleOffset = 0;
mError = 0;
for (size_t i = 0; i < NUM_PRESENT_SAMPLES; i++) {
mPresentFences[i].clear();
mPresentTimes[i] = 0;
}
}
nsecs_t DispSync::computeNextRefresh(int periodOffset) const {
Mutex::Autolock lock(mMutex);
nsecs_t now = systemTime(SYSTEM_TIME_MONOTONIC);
nsecs_t phase = mReferenceTime + mPhase;
return (((now - phase) / mPeriod) + periodOffset + 1) * mPeriod + phase;
}
void DispSync::dump(String8& result) const {
Mutex::Autolock lock(mMutex);
result.appendFormat("present fences are %s\n",
kIgnorePresentFences ? "ignored" : "used");
result.appendFormat("mPeriod: %" PRId64 " ns (%.3f fps; skipCount=%d)\n",
mPeriod, 1000000000.0 / mPeriod, mRefreshSkipCount);
result.appendFormat("mPhase: %" PRId64 " ns\n", mPhase);
result.appendFormat("mError: %" PRId64 " ns (sqrt=%.1f)\n",
mError, sqrt(mError));
result.appendFormat("mNumResyncSamplesSincePresent: %d (limit %d)\n",
mNumResyncSamplesSincePresent, MAX_RESYNC_SAMPLES_WITHOUT_PRESENT);
result.appendFormat("mNumResyncSamples: %zd (max %d)\n",
mNumResyncSamples, MAX_RESYNC_SAMPLES);
result.appendFormat("mResyncSamples:\n");
nsecs_t previous = -1;
for (size_t i = 0; i < mNumResyncSamples; i++) {
size_t idx = (mFirstResyncSample + i) % MAX_RESYNC_SAMPLES;
nsecs_t sampleTime = mResyncSamples[idx];
if (i == 0) {
result.appendFormat(" %" PRId64 "\n", sampleTime);
} else {
result.appendFormat(" %" PRId64 " (+%" PRId64 ")\n",
sampleTime, sampleTime - previous);
}
previous = sampleTime;
}
result.appendFormat("mPresentFences / mPresentTimes [%d]:\n",
NUM_PRESENT_SAMPLES);
nsecs_t now = systemTime(SYSTEM_TIME_MONOTONIC);
previous = 0;
for (size_t i = 0; i < NUM_PRESENT_SAMPLES; i++) {
size_t idx = (i + mPresentSampleOffset) % NUM_PRESENT_SAMPLES;
bool signaled = mPresentFences[idx] == NULL;
nsecs_t presentTime = mPresentTimes[idx];
if (!signaled) {
result.appendFormat(" [unsignaled fence]\n");
} else if (presentTime == 0) {
result.appendFormat(" 0\n");
} else if (previous == 0) {
result.appendFormat(" %" PRId64 " (%.3f ms ago)\n", presentTime,
(now - presentTime) / 1000000.0);
} else {
result.appendFormat(" %" PRId64 " (+%" PRId64 " / %.3f) (%.3f ms ago)\n",
presentTime, presentTime - previous,
(presentTime - previous) / (double) mPeriod,
(now - presentTime) / 1000000.0);
}
previous = presentTime;
}
result.appendFormat("current monotonic time: %" PRId64 "\n", now);
}
} // namespace android