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review.evervolv.com / android_frameworks_av / 21e8c50bd13ebe44f3088e26c9c6df0e163c469c / . / services / audioflinger / FastMixer.cpp
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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.
*/
#define LOG_TAG "FastMixer"
//#define LOG_NDEBUG 0
#include <sys/atomics.h>
#include <time.h>
#include <utils/Log.h>
#include <system/audio.h>
#ifdef FAST_MIXER_STATISTICS
#include <cpustats/CentralTendencyStatistics.h>
#endif
#include "AudioMixer.h"
#include "FastMixer.h"
#define FAST_HOT_IDLE_NS 1000000L // 1 ms: time to sleep while hot idling
#define FAST_DEFAULT_NS 999999999L // ~1 sec: default time to sleep
namespace android {
// Fast mixer thread
bool FastMixer::threadLoop()
{
static const FastMixerState initial;
const FastMixerState *previous = &initial, *current = &initial;
FastMixerState preIdle; // copy of state before we went into idle
struct timespec oldTs = {0, 0};
bool oldTsValid = false;
long slopNs = 0; // accumulated time we've woken up too early (> 0) or too late (< 0)
long sleepNs = -1; // -1: busy wait, 0: sched_yield, > 0: nanosleep
int fastTrackNames[FastMixerState::kMaxFastTracks]; // handles used by mixer to identify tracks
int generations[FastMixerState::kMaxFastTracks]; // last observed mFastTracks[i].mGeneration
unsigned i;
for (i = 0; i < FastMixerState::kMaxFastTracks; ++i) {
fastTrackNames[i] = -1;
generations[i] = 0;
}
NBAIO_Sink *outputSink = NULL;
int outputSinkGen = 0;
AudioMixer* mixer = NULL;
short *mixBuffer = NULL;
enum {UNDEFINED, MIXED, ZEROED} mixBufferState = UNDEFINED;
NBAIO_Format format = Format_Invalid;
unsigned sampleRate = 0;
int fastTracksGen = 0;
long periodNs = 0; // expected period; the time required to render one mix buffer
long underrunNs = 0; // an underrun is likely if an actual cycle is greater than this value
long overrunNs = 0; // an overrun is likely if an actual cycle if less than this value
FastMixerDumpState dummyDumpState, *dumpState = &dummyDumpState;
bool ignoreNextOverrun = true; // used to ignore initial overrun and first after an underrun
#ifdef FAST_MIXER_STATISTICS
CentralTendencyStatistics cts; // cycle times in seconds
static const unsigned kMaxSamples = 1000;
#endif
unsigned coldGen = 0; // last observed mColdGen
for (;;) {
// either nanosleep, sched_yield, or busy wait
if (sleepNs >= 0) {
if (sleepNs > 0) {
ALOG_ASSERT(sleepNs < 1000000000);
const struct timespec req = {0, sleepNs};
nanosleep(&req, NULL);
} else {
sched_yield();
}
}
// default to long sleep for next cycle
sleepNs = FAST_DEFAULT_NS;
// poll for state change
const FastMixerState *next = mSQ.poll();
if (next == NULL) {
// continue to use the default initial state until a real state is available
ALOG_ASSERT(current == &initial && previous == &initial);
next = current;
}
FastMixerState::Command command = next->mCommand;
if (next != current) {
// As soon as possible of learning of a new dump area, start using it
dumpState = next->mDumpState != NULL ? next->mDumpState : &dummyDumpState;
// We want to always have a valid reference to the previous (non-idle) state.
// However, the state queue only guarantees access to current and previous states.
// So when there is a transition from a non-idle state into an idle state, we make a
// copy of the last known non-idle state so it is still available on return from idle.
// The possible transitions are:
// non-idle -> non-idle update previous from current in-place
// non-idle -> idle update previous from copy of current
// idle -> idle don't update previous
// idle -> non-idle don't update previous
if (!(current->mCommand & FastMixerState::IDLE)) {
if (command & FastMixerState::IDLE) {
preIdle = *current;
current = &preIdle;
oldTsValid = false;
ignoreNextOverrun = true;
}
previous = current;
}
current = next;
}
#if !LOG_NDEBUG
next = NULL; // not referenced again
#endif
dumpState->mCommand = command;
switch (command) {
case FastMixerState::INITIAL:
case FastMixerState::HOT_IDLE:
sleepNs = FAST_HOT_IDLE_NS;
continue;
case FastMixerState::COLD_IDLE:
// only perform a cold idle command once
// FIXME consider checking previous state and only perform if previous != COLD_IDLE
if (current->mColdGen != coldGen) {
int32_t *coldFutexAddr = current->mColdFutexAddr;
ALOG_ASSERT(coldFutexAddr != NULL);
int32_t old = android_atomic_dec(coldFutexAddr);
if (old <= 0) {
__futex_syscall4(coldFutexAddr, FUTEX_WAIT_PRIVATE, old - 1, NULL);
}
sleepNs = -1;
coldGen = current->mColdGen;
} else {
sleepNs = FAST_HOT_IDLE_NS;
}
continue;
case FastMixerState::EXIT:
delete mixer;
delete[] mixBuffer;
return false;
case FastMixerState::MIX:
case FastMixerState::WRITE:
case FastMixerState::MIX_WRITE:
break;
default:
LOG_FATAL("bad command %d", command);
}
// there is a non-idle state available to us; did the state change?
size_t frameCount = current->mFrameCount;
if (current != previous) {
// handle state change here, but since we want to diff the state,
// we're prepared for previous == &initial the first time through
unsigned previousTrackMask;
// check for change in output HAL configuration
NBAIO_Format previousFormat = format;
if (current->mOutputSinkGen != outputSinkGen) {
outputSink = current->mOutputSink;
outputSinkGen = current->mOutputSinkGen;
if (outputSink == NULL) {
format = Format_Invalid;
sampleRate = 0;
} else {
format = outputSink->format();
sampleRate = Format_sampleRate(format);
ALOG_ASSERT(Format_channelCount(format) == 2);
}
dumpState->mSampleRate = sampleRate;
}
if ((format != previousFormat) || (frameCount != previous->mFrameCount)) {
// FIXME to avoid priority inversion, don't delete here
delete mixer;
mixer = NULL;
delete[] mixBuffer;
mixBuffer = NULL;
if (frameCount > 0 && sampleRate > 0) {
// FIXME new may block for unbounded time at internal mutex of the heap
// implementation; it would be better to have normal mixer allocate for us
// to avoid blocking here and to prevent possible priority inversion
mixer = new AudioMixer(frameCount, sampleRate, FastMixerState::kMaxFastTracks);
mixBuffer = new short[frameCount * 2];
periodNs = (frameCount * 1000000000LL) / sampleRate; // 1.00
underrunNs = (frameCount * 1750000000LL) / sampleRate; // 1.75
overrunNs = (frameCount * 250000000LL) / sampleRate; // 0.25
} else {
periodNs = 0;
underrunNs = 0;
overrunNs = 0;
}
mixBufferState = UNDEFINED;
#if !LOG_NDEBUG
for (i = 0; i < FastMixerState::kMaxFastTracks; ++i) {
fastTrackNames[i] = -1;
}
#endif
// we need to reconfigure all active tracks
previousTrackMask = 0;
fastTracksGen = current->mFastTracksGen - 1;
dumpState->mFrameCount = frameCount;
} else {
previousTrackMask = previous->mTrackMask;
}
// check for change in active track set
unsigned currentTrackMask = current->mTrackMask;
if (current->mFastTracksGen != fastTracksGen) {
ALOG_ASSERT(mixBuffer != NULL);
int name;
// process removed tracks first to avoid running out of track names
unsigned removedTracks = previousTrackMask & ~currentTrackMask;
while (removedTracks != 0) {
i = __builtin_ctz(removedTracks);
removedTracks &= ~(1 << i);
const FastTrack* fastTrack = &current->mFastTracks[i];
if (mixer != NULL) {
name = fastTrackNames[i];
ALOG_ASSERT(name >= 0);
mixer->deleteTrackName(name);
}
#if !LOG_NDEBUG
fastTrackNames[i] = -1;
#endif
generations[i] = fastTrack->mGeneration;
}
// now process added tracks
unsigned addedTracks = currentTrackMask & ~previousTrackMask;
while (addedTracks != 0) {
i = __builtin_ctz(addedTracks);
addedTracks &= ~(1 << i);
const FastTrack* fastTrack = &current->mFastTracks[i];
AudioBufferProvider *bufferProvider = fastTrack->mBufferProvider;
ALOG_ASSERT(bufferProvider != NULL && fastTrackNames[i] == -1);
if (mixer != NULL) {
// calling getTrackName with default channel mask
name = mixer->getTrackName(AUDIO_CHANNEL_OUT_STEREO);
ALOG_ASSERT(name >= 0);
fastTrackNames[i] = name;
mixer->setBufferProvider(name, bufferProvider);
mixer->setParameter(name, AudioMixer::TRACK, AudioMixer::MAIN_BUFFER,
(void *) mixBuffer);
// newly allocated track names default to full scale volume
if (fastTrack->mSampleRate != 0 && fastTrack->mSampleRate != sampleRate) {
mixer->setParameter(name, AudioMixer::RESAMPLE,
AudioMixer::SAMPLE_RATE, (void*) fastTrack->mSampleRate);
}
mixer->setParameter(name, AudioMixer::TRACK, AudioMixer::CHANNEL_MASK,
(void *) fastTrack->mChannelMask);
mixer->enable(name);
}
generations[i] = fastTrack->mGeneration;
}
// finally process modified tracks; these use the same slot
// but may have a different buffer provider or volume provider
unsigned modifiedTracks = currentTrackMask & previousTrackMask;
while (modifiedTracks != 0) {
i = __builtin_ctz(modifiedTracks);
modifiedTracks &= ~(1 << i);
const FastTrack* fastTrack = &current->mFastTracks[i];
if (fastTrack->mGeneration != generations[i]) {
AudioBufferProvider *bufferProvider = fastTrack->mBufferProvider;
ALOG_ASSERT(bufferProvider != NULL);
if (mixer != NULL) {
name = fastTrackNames[i];
ALOG_ASSERT(name >= 0);
mixer->setBufferProvider(name, bufferProvider);
if (fastTrack->mVolumeProvider == NULL) {
mixer->setParameter(name, AudioMixer::VOLUME, AudioMixer::VOLUME0,
(void *)0x1000);
mixer->setParameter(name, AudioMixer::VOLUME, AudioMixer::VOLUME1,
(void *)0x1000);
}
if (fastTrack->mSampleRate != 0 &&
fastTrack->mSampleRate != sampleRate) {
mixer->setParameter(name, AudioMixer::RESAMPLE,
AudioMixer::SAMPLE_RATE, (void*) fastTrack->mSampleRate);
} else {
mixer->setParameter(name, AudioMixer::RESAMPLE,
AudioMixer::REMOVE, NULL);
}
mixer->setParameter(name, AudioMixer::TRACK, AudioMixer::CHANNEL_MASK,
(void *) fastTrack->mChannelMask);
// already enabled
}
generations[i] = fastTrack->mGeneration;
}
}
fastTracksGen = current->mFastTracksGen;
dumpState->mNumTracks = popcount(currentTrackMask);
}
#if 1 // FIXME shouldn't need this
// only process state change once
previous = current;
#endif
}
// do work using current state here
if ((command & FastMixerState::MIX) && (mixer != NULL)) {
ALOG_ASSERT(mixBuffer != NULL);
// update volumes
unsigned volumeTracks = current->mTrackMask;
while (volumeTracks != 0) {
i = __builtin_ctz(volumeTracks);
volumeTracks &= ~(1 << i);
const FastTrack* fastTrack = &current->mFastTracks[i];
int name = fastTrackNames[i];
ALOG_ASSERT(name >= 0);
if (fastTrack->mVolumeProvider != NULL) {
uint32_t vlr = fastTrack->mVolumeProvider->getVolumeLR();
mixer->setParameter(name, AudioMixer::VOLUME, AudioMixer::VOLUME0,
(void *)(vlr & 0xFFFF));
mixer->setParameter(name, AudioMixer::VOLUME, AudioMixer::VOLUME1,
(void *)(vlr >> 16));
}
}
// process() is CPU-bound
mixer->process(AudioBufferProvider::kInvalidPTS);
mixBufferState = MIXED;
} else if (mixBufferState == MIXED) {
mixBufferState = UNDEFINED;
}
if ((command & FastMixerState::WRITE) && (outputSink != NULL) && (mixBuffer != NULL)) {
if (mixBufferState == UNDEFINED) {
memset(mixBuffer, 0, frameCount * 2 * sizeof(short));
mixBufferState = ZEROED;
}
// FIXME write() is non-blocking and lock-free for a properly implemented NBAIO sink,
// but this code should be modified to handle both non-blocking and blocking sinks
dumpState->mWriteSequence++;
ssize_t framesWritten = outputSink->write(mixBuffer, frameCount);
dumpState->mWriteSequence++;
if (framesWritten >= 0) {
dumpState->mFramesWritten += framesWritten;
} else {
dumpState->mWriteErrors++;
}
// FIXME count # of writes blocked excessively, CPU usage, etc. for dump
}
// To be exactly periodic, compute the next sleep time based on current time.
// This code doesn't have long-term stability when the sink is non-blocking.
// FIXME To avoid drift, use the local audio clock or watch the sink's fill status.
struct timespec newTs;
int rc = clock_gettime(CLOCK_MONOTONIC, &newTs);
if (rc == 0) {
if (oldTsValid) {
time_t sec = newTs.tv_sec - oldTs.tv_sec;
long nsec = newTs.tv_nsec - oldTs.tv_nsec;
if (nsec < 0) {
--sec;
nsec += 1000000000;
}
if (sec > 0 || nsec > underrunNs) {
// FIXME only log occasionally
ALOGV("underrun: time since last cycle %d.%03ld sec",
(int) sec, nsec / 1000000L);
dumpState->mUnderruns++;
sleepNs = -1;
ignoreNextOverrun = true;
} else if (nsec < overrunNs) {
if (ignoreNextOverrun) {
ignoreNextOverrun = false;
} else {
// FIXME only log occasionally
ALOGV("overrun: time since last cycle %d.%03ld sec",
(int) sec, nsec / 1000000L);
dumpState->mOverruns++;
}
sleepNs = periodNs - overrunNs;
} else {
sleepNs = -1;
ignoreNextOverrun = false;
}
#ifdef FAST_MIXER_STATISTICS
// long-term statistics
cts.sample(sec + nsec * 1e-9);
if (cts.n() >= kMaxSamples) {
dumpState->mMean = cts.mean();
dumpState->mMinimum = cts.minimum();
dumpState->mMaximum = cts.maximum();
dumpState->mStddev = cts.stddev();
cts.reset();
}
#endif
} else {
// first time through the loop
oldTsValid = true;
sleepNs = periodNs;
ignoreNextOverrun = true;
}
oldTs = newTs;
} else {
// monotonic clock is broken
oldTsValid = false;
sleepNs = periodNs;
}
} // for (;;)
// never return 'true'; Thread::_threadLoop() locks mutex which can result in priority inversion
}
FastMixerDumpState::FastMixerDumpState() :
mCommand(FastMixerState::INITIAL), mWriteSequence(0), mFramesWritten(0),
mNumTracks(0), mWriteErrors(0), mUnderruns(0), mOverruns(0),
mSampleRate(0), mFrameCount(0)
#ifdef FAST_MIXER_STATISTICS
, mMean(0.0), mMinimum(0.0), mMaximum(0.0), mStddev(0.0)
#endif
{
}
FastMixerDumpState::~FastMixerDumpState()
{
}
void FastMixerDumpState::dump(int fd)
{
#define COMMAND_MAX 32
char string[COMMAND_MAX];
switch (mCommand) {
case FastMixerState::INITIAL:
strcpy(string, "INITIAL");
break;
case FastMixerState::HOT_IDLE:
strcpy(string, "HOT_IDLE");
break;
case FastMixerState::COLD_IDLE:
strcpy(string, "COLD_IDLE");
break;
case FastMixerState::EXIT:
strcpy(string, "EXIT");
break;
case FastMixerState::MIX:
strcpy(string, "MIX");
break;
case FastMixerState::WRITE:
strcpy(string, "WRITE");
break;
case FastMixerState::MIX_WRITE:
strcpy(string, "MIX_WRITE");
break;
default:
snprintf(string, COMMAND_MAX, "%d", mCommand);
break;
}
fdprintf(fd, "FastMixer command=%s writeSequence=%u framesWritten=%u\n"
" numTracks=%u writeErrors=%u underruns=%u overruns=%u\n"
" sampleRate=%u frameCount=%u\n",
string, mWriteSequence, mFramesWritten,
mNumTracks, mWriteErrors, mUnderruns, mOverruns,
mSampleRate, mFrameCount);
#ifdef FAST_MIXER_STATISTICS
fdprintf(fd, " cycle time in ms: mean=%.1f min=%.1f max=%.1f stddev=%.1f\n",
mMean*1e3, mMinimum*1e3, mMaximum*1e3, mStddev*1e3);
#endif
}
} // namespace android