1
0
mirror of https://github.com/NekoX-Dev/NekoX.git synced 2024-12-15 11:59:41 +01:00
NekoX/TMessagesProj/jni/libtgvoip/MediaStreamItf.cpp
2019-06-04 13:14:50 +03:00

210 lines
5.1 KiB
C++

//
// libtgvoip is free and unencumbered public domain software.
// For more information, see http://unlicense.org or the UNLICENSE file
// you should have received with this source code distribution.
//
#include "logging.h"
#include "MediaStreamItf.h"
#include "EchoCanceller.h"
#include <stdint.h>
#include <algorithm>
#include <math.h>
#include <assert.h>
using namespace tgvoip;
void MediaStreamItf::SetCallback(size_t (*f)(unsigned char *, size_t, void*), void* param){
callback=f;
callbackParam=param;
}
size_t MediaStreamItf::InvokeCallback(unsigned char *data, size_t length){
if(callback)
return (*callback)(data, length, callbackParam);
return 0;
}
AudioMixer::AudioMixer() : bufferPool(960*2, 16), processedQueue(16), semaphore(16, 0){
running=false;
}
AudioMixer::~AudioMixer(){
}
void AudioMixer::SetOutput(MediaStreamItf* output){
output->SetCallback(OutputCallback, this);
}
void AudioMixer::Start(){
assert(!running);
running=true;
thread=new Thread(std::bind(&AudioMixer::RunThread, this));
thread->SetName("AudioMixer");
thread->Start();
}
void AudioMixer::Stop(){
if(!running){
LOGE("Tried to stop AudioMixer that wasn't started");
return;
}
running=false;
semaphore.Release();
thread->Join();
delete thread;
thread=NULL;
}
void AudioMixer::DoCallback(unsigned char *data, size_t length){
//memset(data, 0, 960*2);
//LOGD("audio mixer callback, %d inputs", inputs.size());
if(processedQueue.Size()==0)
semaphore.Release(2);
else
semaphore.Release();
unsigned char* buf=processedQueue.GetBlocking();
memcpy(data, buf, 960*2);
bufferPool.Reuse(buf);
}
size_t AudioMixer::OutputCallback(unsigned char *data, size_t length, void *arg){
((AudioMixer*)arg)->DoCallback(data, length);
return 960*2;
}
void AudioMixer::AddInput(std::shared_ptr<MediaStreamItf> input){
MutexGuard m(inputsMutex);
MixerInput in;
in.multiplier=1;
in.source=input;
inputs.push_back(in);
}
void AudioMixer::RemoveInput(std::shared_ptr<MediaStreamItf> input){
MutexGuard m(inputsMutex);
for(std::vector<MixerInput>::iterator i=inputs.begin();i!=inputs.end();++i){
if(i->source==input){
inputs.erase(i);
return;
}
}
}
void AudioMixer::SetInputVolume(std::shared_ptr<MediaStreamItf> input, float volumeDB){
MutexGuard m(inputsMutex);
for(std::vector<MixerInput>::iterator i=inputs.begin();i!=inputs.end();++i){
if(i->source==input){
if(volumeDB==-INFINITY)
i->multiplier=0;
else
i->multiplier=expf(volumeDB/20.0f * logf(10.0f));
return;
}
}
}
void AudioMixer::RunThread(){
LOGV("AudioMixer thread started");
while(running){
semaphore.Acquire();
if(!running)
break;
unsigned char* data=bufferPool.Get();
//LOGV("Audio mixer processing a frame");
if(!data){
LOGE("AudioMixer: no buffers left");
continue;
}
MutexGuard m(inputsMutex);
int16_t* buf=reinterpret_cast<int16_t*>(data);
int16_t input[960];
float out[960];
memset(out, 0, 960*4);
int usedInputs=0;
for(std::vector<MixerInput>::iterator in=inputs.begin();in!=inputs.end();++in){
size_t res=in->source->InvokeCallback(reinterpret_cast<unsigned char*>(input), 960*2);
if(!res || in->multiplier==0){
//LOGV("AudioMixer: skipping silent packet");
continue;
}
usedInputs++;
float k=in->multiplier;
if(k!=1){
for(size_t i=0; i<960; i++){
out[i]+=(float)input[i]*k;
}
}else{
for(size_t i=0;i<960;i++){
out[i]+=(float)input[i];
}
}
}
if(usedInputs>0){
for(size_t i=0; i<960; i++){
if(out[i]>32767.0f)
buf[i]=INT16_MAX;
else if(out[i]<-32768.0f)
buf[i]=INT16_MIN;
else
buf[i]=(int16_t)out[i];
}
}else{
memset(data, 0, 960*2);
}
if(echoCanceller)
echoCanceller->SpeakerOutCallback(data, 960*2);
processedQueue.Put(data);
}
LOGI("======== audio mixer thread exiting =========");
}
void AudioMixer::SetEchoCanceller(EchoCanceller *aec){
echoCanceller=aec;
}
AudioLevelMeter::AudioLevelMeter(){
absMax=0;
count=0;
currentLevel=0;
currentLevelFullRange=0;
}
float AudioLevelMeter::GetLevel(){
return currentLevel/9.0f;
}
void AudioLevelMeter::Update(int16_t *samples, size_t count){
// Number of bars on the indicator.
// Note that the number of elements is specified because we are indexing it
// in the range of 0-32
const int8_t permutation[33]={0,1,2,3,4,4,5,5,5,5,6,6,6,6,6,7,7,7,7,8,8,8,9,9,9,9,9,9,9,9,9,9,9};
int16_t absValue=0;
for(unsigned int k=0;k<count;k++){
int16_t absolute=(int16_t)abs(samples[k]);
if (absolute>absValue)
absValue=absolute;
}
if(absValue>absMax)
absMax = absValue;
// Update level approximately 10 times per second
if (this->count++==10){
currentLevelFullRange=absMax;
this->count=0;
// Highest value for a int16_t is 0x7fff = 32767
// Divide with 1000 to get in the range of 0-32 which is the range of
// the permutation vector
int32_t position=absMax/1000;
// Make it less likely that the bar stays at position 0. I.e. only if
// its in the range 0-250 (instead of 0-1000)
/*if ((position==0) && (absMax>250)){
position=1;
}*/
currentLevel=permutation[position];
// Decay the absolute maximum (divide by 4)
absMax >>= 2;
}
}