axmol/cocos/audio/android/AudioMixerOps.h

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[big refactoring] Audio latency fix for Android. Support to preload effects on Android now. (#15875) * Audio latency fix for Android. Support preload effects on Android now. Squashed commits: [b6d80fe] log fix [a0a918e] Fixes assetFd didn't be released while PcmData is returned from cache. [4b956ba] Potential crash fix for PcmAudioPlayer while pause / resume. [398ab8c] Updates LOG_TAG position in AudioEngine-inl.cpp [e3634e7] include stdlib.h for posix_memalign [9004074] fixes setVolume logical error. [c96df46] Don't use another thread for mixing, enqueue is in a seperated thread, therefore doing mixing in another thread will waste more time. [0a4c1a8] Adds setLoop, setVolume, setPostion support for Track [c35fb20] Fixed include. [cdd9d32] Do mixing by ourself. (TO BE POLISHED) [6447025] µ -> u since µ could not be shown on some android devices. [97be0c6] Don't send a silence clip. [c1607ed] Make linter.py happy. [0898b54] Puts enqueue & SetPlayState in PcmAudioPlayer::play to thread pool. [b79fc01] Adds getDuration, getPosition support for PcmAudioPlayer [80fa2ab] minor fix of the code position of resetting state to State::INITIALIZED [d9c62f1] underrun fix for PcmAudioPlayer. [9c2212a] UrlAudioPlayer, playOverMutex should be static, and should be used in update method. [1519d2e] static variables [19da936] _pcmAudioPlayer Null pointer check in AudioPlayerProvider. [e6b0d14] Updates audio performance test. [fc01dd4] Registers foreground & background event in AudioEngine-inl.cpp(android), the callback should invoke `provider`'s pause & resume method. [e00a886] TBD: Pause & resume support for PcmAudioPlayerPool. Since OpenSLES audio resources are expensive and device shared, we should delete all unused PcmAudioPlayers in pool while pause and re-create them while resume. But this commit isn't finished yet, I don't find a better way to register pause&resume event in AudioEngine module. [9e42ea3] Interleave mono audio to stereo audio. PcmAudioPlayerPool only contains PcmAudioPlayers with 2 channels. [3f18d05] Adds a strategy for checking small size of different file formats. [753ff49] Adds performance test for AudioEngine. [09d3045] Releases an extra PcmAudioPlayer for UrlAudioPlayer while allocating PcmAudioPlayer fails. [9dd4477] Using std::move for PcmData move constructor & move assignment. [6ca3bcb] some fixes: 1) new -> new (std::nothrow) 2) break if allocate PcmAudioPlayer fails 3) renames 'initForPlayPcmData' to 'init' 4) PcmAudioPlayer destructor deadlock if 'init' failed [54675b6] include path fix. [a1903ca] More refactorings. [19b9498] Makes linter.py happy. :) [923c530] Fixes: 1) Avoid getFileInfo to be invoked twice 2) A critical bug fix for UrlAudioPlayer and adds detailed comments 3) __clang__ compiler option fix for AudioResamplerSinc.cpp. [5ec4faf] minor fix. [faaa0f3] output a log in the destructor of UrlAudioPlayer. [9c20355] NewAudioEngineTest,TestControll crash fix. [f114464] fixes an unused import. [1dc5dab] Better algorithm for allocating PcmAudioPlayer. [331a213] minor fix. [e54084a] null -> nullptr [f9a0389] Support uncache. [89a364f] Removes unused update, and TODO uncache functionality. [1732bf9] Supports AudioEngineImpl::setFinishCallback for android. [43d1596] UrlAudioPlayer::stop fix. [e2ee941] Test case fix in NewAudioEngineTest/AudioIssue11143Test [5c5ba01] More fixes for making cpp-tests/New Audio Engine Test happy. [8b554a3] Adds log while remove player from map. [ed71322] If original file is larger than 30k bytes, consider it's a large audio file. [fb1845a] Updates project.properties [6f3839f] minor log output fix in AudioEngine-inl.cpp [c68bc6c] Don't resample if the sample rate of the decoded pcm data matchs the device's. [43ca45f] PcmAudioPlayers also need to be removed while they play over, but should not be deleted since their lifecycle is managed by PcmAudioPlayerPool. [f5e63c9] Audio latency fix for Android. Support preload effects on Android now. * Supports to loading audio files asynchronously. * Crash fix for stop audio right after play2d. * Minor fix for logic in AudioMixerController.cpp * Adds missing files (CCThreadPool.h/.cpp). * Minor fix for including. * Minor fix for missing include <functional> in Track.h * update license information in audio.h * Don't use std::future/std::promise anymore since ndk counldn't support it well in armeabi arch. * isSmallFile postion updated, fixes large audio file goto the checking logic of cache. * std::atomic<int> isn't supported by ndk-r10e while compiling with `armeabi` arch, using a int with a mutex instead. * fixes __isnanf & posix_memalign doesn't exist on low api (<=16) devices. * namespace updated: cocos2d -> cocos2d::experimental * Removes commented code in AudioMixerController.h/.cpp * Removes unused code again, and fixes a memory leak of `Track` instance. * Oops, namespace changed. * Only outputs log in debug mode. * Uses ALOGV for outputing logs in AudioEngine-inl.cpp * const PcmData& -> PcmData for Track * Fixes a protential crash in NewAudioEngineTest * Adds `COCOS` prefix in header #ifndef COCOS_BALABALA #define COCOS_BALABALA * Uses _ prefix for cocos code style instead of `m` prefix. * Deletes AudioResamplerSinc related files. * Bug fix from @minggo's reply on github. * Don't need to invoke pause after in UrlAudioPlayer::prepare. * Updates ThreadPool class, uses enum class and adds const keyword.
2016-07-18 10:22:40 +08:00
/*
* Copyright (C) 2014 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.
*/
#pragma once
#include "audio/android/cutils/log.h"
namespace cocos2d { namespace experimental {
/* Behavior of is_same<>::value is true if the types are identical,
* false otherwise. Identical to the STL std::is_same.
*/
template<typename T, typename U>
struct is_same
{
static const bool value = false;
};
template<typename T>
struct is_same<T, T> // partial specialization
{
static const bool value = true;
};
/* MixMul is a multiplication operator to scale an audio input signal
* by a volume gain, with the formula:
*
* O(utput) = I(nput) * V(olume)
*
* The output, input, and volume may have different types.
* There are 27 variants, of which 14 are actually defined in an
* explicitly templated class.
*
* The following type variables and the underlying meaning:
*
* Output type TO: int32_t (Q4.27) or int16_t (Q.15) or float [-1,1]
* Input signal type TI: int32_t (Q4.27) or int16_t (Q.15) or float [-1,1]
* Volume type TV: int32_t (U4.28) or int16_t (U4.12) or float [-1,1]
*
* For high precision audio, only the <TO, TI, TV> = <float, float, float>
* needs to be accelerated. This is perhaps the easiest form to do quickly as well.
*
* A generic version is NOT defined to catch any mistake of using it.
*/
template <typename TO, typename TI, typename TV>
TO MixMul(TI value, TV volume);
template <>
inline int32_t MixMul<int32_t, int16_t, int16_t>(int16_t value, int16_t volume) {
return value * volume;
}
template <>
inline int32_t MixMul<int32_t, int32_t, int16_t>(int32_t value, int16_t volume) {
return (value >> 12) * volume;
}
template <>
inline int32_t MixMul<int32_t, int16_t, int32_t>(int16_t value, int32_t volume) {
return value * (volume >> 16);
}
template <>
inline int32_t MixMul<int32_t, int32_t, int32_t>(int32_t value, int32_t volume) {
return (value >> 12) * (volume >> 16);
}
template <>
inline float MixMul<float, float, int16_t>(float value, int16_t volume) {
static const float norm = 1. / (1 << 12);
return value * volume * norm;
}
template <>
inline float MixMul<float, float, int32_t>(float value, int32_t volume) {
static const float norm = 1. / (1 << 28);
return value * volume * norm;
}
template <>
inline int16_t MixMul<int16_t, float, int16_t>(float value, int16_t volume) {
return clamp16_from_float(MixMul<float, float, int16_t>(value, volume));
}
template <>
inline int16_t MixMul<int16_t, float, int32_t>(float value, int32_t volume) {
return clamp16_from_float(MixMul<float, float, int32_t>(value, volume));
}
template <>
inline float MixMul<float, int16_t, int16_t>(int16_t value, int16_t volume) {
static const float norm = 1. / (1 << (15 + 12));
return static_cast<float>(value) * static_cast<float>(volume) * norm;
}
template <>
inline float MixMul<float, int16_t, int32_t>(int16_t value, int32_t volume) {
static const float norm = 1. / (1ULL << (15 + 28));
return static_cast<float>(value) * static_cast<float>(volume) * norm;
}
template <>
inline int16_t MixMul<int16_t, int16_t, int16_t>(int16_t value, int16_t volume) {
return clamp16(MixMul<int32_t, int16_t, int16_t>(value, volume) >> 12);
}
template <>
inline int16_t MixMul<int16_t, int32_t, int16_t>(int32_t value, int16_t volume) {
return clamp16(MixMul<int32_t, int32_t, int16_t>(value, volume) >> 12);
}
template <>
inline int16_t MixMul<int16_t, int16_t, int32_t>(int16_t value, int32_t volume) {
return clamp16(MixMul<int32_t, int16_t, int32_t>(value, volume) >> 12);
}
template <>
inline int16_t MixMul<int16_t, int32_t, int32_t>(int32_t value, int32_t volume) {
return clamp16(MixMul<int32_t, int32_t, int32_t>(value, volume) >> 12);
}
/* Required for floating point volume. Some are needed for compilation but
* are not needed in execution and should be removed from the final build by
* an optimizing compiler.
*/
template <>
inline float MixMul<float, float, float>(float value, float volume) {
return value * volume;
}
template <>
inline float MixMul<float, int16_t, float>(int16_t value, float volume) {
static const float float_from_q_15 = 1. / (1 << 15);
return value * volume * float_from_q_15;
}
template <>
inline int32_t MixMul<int32_t, int32_t, float>(int32_t value, float volume) {
LOG_ALWAYS_FATAL("MixMul<int32_t, int32_t, float> Runtime Should not be here");
return value * volume;
}
template <>
inline int32_t MixMul<int32_t, int16_t, float>(int16_t value, float volume) {
LOG_ALWAYS_FATAL("MixMul<int32_t, int16_t, float> Runtime Should not be here");
static const float u4_12_from_float = (1 << 12);
return value * volume * u4_12_from_float;
}
template <>
inline int16_t MixMul<int16_t, int16_t, float>(int16_t value, float volume) {
LOG_ALWAYS_FATAL("MixMul<int16_t, int16_t, float> Runtime Should not be here");
return clamp16_from_float(MixMul<float, int16_t, float>(value, volume));
}
template <>
inline int16_t MixMul<int16_t, float, float>(float value, float volume) {
return clamp16_from_float(value * volume);
}
/*
* MixAccum is used to add into an accumulator register of a possibly different
* type. The TO and TI types are the same as MixMul.
*/
template <typename TO, typename TI>
inline void MixAccum(TO *auxaccum, TI value) {
if (!is_same<TO, TI>::value) {
LOG_ALWAYS_FATAL("MixAccum type not properly specialized: %zu %zu\n",
sizeof(TO), sizeof(TI));
}
*auxaccum += value;
}
template<>
inline void MixAccum<float, int16_t>(float *auxaccum, int16_t value) {
static const float norm = 1. / (1 << 15);
*auxaccum += norm * value;
}
template<>
inline void MixAccum<float, int32_t>(float *auxaccum, int32_t value) {
static const float norm = 1. / (1 << 27);
*auxaccum += norm * value;
}
template<>
inline void MixAccum<int32_t, int16_t>(int32_t *auxaccum, int16_t value) {
*auxaccum += value << 12;
}
template<>
inline void MixAccum<int32_t, float>(int32_t *auxaccum, float value) {
*auxaccum += clampq4_27_from_float(value);
}
/* MixMulAux is just like MixMul except it combines with
* an accumulator operation MixAccum.
*/
template <typename TO, typename TI, typename TV, typename TA>
inline TO MixMulAux(TI value, TV volume, TA *auxaccum) {
MixAccum<TA, TI>(auxaccum, value);
return MixMul<TO, TI, TV>(value, volume);
}
/* MIXTYPE is used to determine how the samples in the input frame
* are mixed with volume gain into the output frame.
* See the volumeRampMulti functions below for more details.
*/
enum {
MIXTYPE_MULTI,
MIXTYPE_MONOEXPAND,
MIXTYPE_MULTI_SAVEONLY,
MIXTYPE_MULTI_MONOVOL,
MIXTYPE_MULTI_SAVEONLY_MONOVOL,
};
/*
* The volumeRampMulti and volumeRamp functions take a MIXTYPE
* which indicates the per-frame mixing and accumulation strategy.
*
* MIXTYPE_MULTI:
* NCHAN represents number of input and output channels.
* TO: int32_t (Q4.27) or float
* TI: int32_t (Q4.27) or int16_t (Q0.15) or float
* TV: int32_t (U4.28) or int16_t (U4.12) or float
* vol: represents a volume array.
*
* This accumulates into the out pointer.
*
* MIXTYPE_MONOEXPAND:
* Single input channel. NCHAN represents number of output channels.
* TO: int32_t (Q4.27) or float
* TI: int32_t (Q4.27) or int16_t (Q0.15) or float
* TV: int32_t (U4.28) or int16_t (U4.12) or float
* Input channel count is 1.
* vol: represents volume array.
*
* This accumulates into the out pointer.
*
* MIXTYPE_MULTI_SAVEONLY:
* NCHAN represents number of input and output channels.
* TO: int16_t (Q.15) or float
* TI: int32_t (Q4.27) or int16_t (Q0.15) or float
* TV: int32_t (U4.28) or int16_t (U4.12) or float
* vol: represents a volume array.
*
* MIXTYPE_MULTI_SAVEONLY does not accumulate into the out pointer.
*
* MIXTYPE_MULTI_MONOVOL:
* Same as MIXTYPE_MULTI, but uses only volume[0].
*
* MIXTYPE_MULTI_SAVEONLY_MONOVOL:
* Same as MIXTYPE_MULTI_SAVEONLY, but uses only volume[0].
*
*/
template <int MIXTYPE, int NCHAN,
typename TO, typename TI, typename TV, typename TA, typename TAV>
inline void volumeRampMulti(TO* out, size_t frameCount,
const TI* in, TA* aux, TV *vol, const TV *volinc, TAV *vola, TAV volainc)
{
#ifdef ALOGVV
ALOGVV("volumeRampMulti, MIXTYPE:%d\n", MIXTYPE);
#endif
if (aux != NULL) {
do {
TA auxaccum = 0;
switch (MIXTYPE) {
case MIXTYPE_MULTI:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in++, vol[i], &auxaccum);
vol[i] += volinc[i];
}
break;
case MIXTYPE_MONOEXPAND:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in, vol[i], &auxaccum);
vol[i] += volinc[i];
}
in++;
break;
case MIXTYPE_MULTI_SAVEONLY:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMulAux<TO, TI, TV, TA>(*in++, vol[i], &auxaccum);
vol[i] += volinc[i];
}
break;
case MIXTYPE_MULTI_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in++, vol[0], &auxaccum);
}
vol[0] += volinc[0];
break;
case MIXTYPE_MULTI_SAVEONLY_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMulAux<TO, TI, TV, TA>(*in++, vol[0], &auxaccum);
}
vol[0] += volinc[0];
break;
default:
LOG_ALWAYS_FATAL("invalid mixtype %d", MIXTYPE);
break;
}
auxaccum /= NCHAN;
*aux++ += MixMul<TA, TA, TAV>(auxaccum, *vola);
vola[0] += volainc;
} while (--frameCount);
} else {
do {
switch (MIXTYPE) {
case MIXTYPE_MULTI:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in++, vol[i]);
vol[i] += volinc[i];
}
break;
case MIXTYPE_MONOEXPAND:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in, vol[i]);
vol[i] += volinc[i];
}
in++;
break;
case MIXTYPE_MULTI_SAVEONLY:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMul<TO, TI, TV>(*in++, vol[i]);
vol[i] += volinc[i];
}
break;
case MIXTYPE_MULTI_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in++, vol[0]);
}
vol[0] += volinc[0];
break;
case MIXTYPE_MULTI_SAVEONLY_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMul<TO, TI, TV>(*in++, vol[0]);
}
vol[0] += volinc[0];
break;
default:
LOG_ALWAYS_FATAL("invalid mixtype %d", MIXTYPE);
break;
}
} while (--frameCount);
}
}
template <int MIXTYPE, int NCHAN,
typename TO, typename TI, typename TV, typename TA, typename TAV>
inline void volumeMulti(TO* out, size_t frameCount,
const TI* in, TA* aux, const TV *vol, TAV vola)
{
#ifdef ALOGVV
ALOGVV("volumeMulti MIXTYPE:%d\n", MIXTYPE);
#endif
if (aux != NULL) {
do {
TA auxaccum = 0;
switch (MIXTYPE) {
case MIXTYPE_MULTI:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in++, vol[i], &auxaccum);
}
break;
case MIXTYPE_MONOEXPAND:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in, vol[i], &auxaccum);
}
in++;
break;
case MIXTYPE_MULTI_SAVEONLY:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMulAux<TO, TI, TV, TA>(*in++, vol[i], &auxaccum);
}
break;
case MIXTYPE_MULTI_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMulAux<TO, TI, TV, TA>(*in++, vol[0], &auxaccum);
}
break;
case MIXTYPE_MULTI_SAVEONLY_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMulAux<TO, TI, TV, TA>(*in++, vol[0], &auxaccum);
}
break;
default:
LOG_ALWAYS_FATAL("invalid mixtype %d", MIXTYPE);
break;
}
auxaccum /= NCHAN;
*aux++ += MixMul<TA, TA, TAV>(auxaccum, vola);
} while (--frameCount);
} else {
do {
switch (MIXTYPE) {
case MIXTYPE_MULTI:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in++, vol[i]);
}
break;
case MIXTYPE_MONOEXPAND:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in, vol[i]);
}
in++;
break;
case MIXTYPE_MULTI_SAVEONLY:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMul<TO, TI, TV>(*in++, vol[i]);
}
break;
case MIXTYPE_MULTI_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ += MixMul<TO, TI, TV>(*in++, vol[0]);
}
break;
case MIXTYPE_MULTI_SAVEONLY_MONOVOL:
for (int i = 0; i < NCHAN; ++i) {
*out++ = MixMul<TO, TI, TV>(*in++, vol[0]);
}
break;
default:
LOG_ALWAYS_FATAL("invalid mixtype %d", MIXTYPE);
break;
}
} while (--frameCount);
}
}
}} // namespace cocos2d { namespace experimental {