Modified source engine (2017) developed by valve and leaked in 2020. Not for commercial purporses
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//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
// $NoKeywords: $
//=============================================================================//
#include "audio_pch.h"
#include <assert.h>
#include "voice.h"
#include "ivoicecodec.h"
#if defined( _X360 )
#include "xauddefs.h"
#endif
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
// ------------------------------------------------------------------------- //
// CAudioSourceVoice.
// This feeds the data from an incoming voice channel (a guy on the server
// who is speaking) into the sound engine.
// ------------------------------------------------------------------------- //
class CAudioSourceVoice : public CAudioSourceWave
{
public:
CAudioSourceVoice(CSfxTable *pSfx, int iEntity);
virtual ~CAudioSourceVoice();
virtual int GetType( void )
{
return AUDIO_SOURCE_VOICE;
}
virtual void GetCacheData( CAudioSourceCachedInfo *info )
{
Assert( 0 );
}
virtual CAudioMixer *CreateMixer( int initialStreamPosition = 0 );
virtual int GetOutputData( void **pData, int samplePosition, int sampleCount, char copyBuf[AUDIOSOURCE_COPYBUF_SIZE] );
virtual int SampleRate( void );
// Sample size is in bytes. It will not be accurate for compressed audio. This is a best estimate.
// The compressed audio mixers understand this, but in general do not assume that SampleSize() * SampleCount() = filesize
// or even that SampleSize() is 100% accurate due to compression.
virtual int SampleSize( void );
// Total number of samples in this source. NOTE: Some sources are infinite (mic input), they should return
// a count equal to one second of audio at their current rate.
virtual int SampleCount( void );
virtual bool IsVoiceSource() {return true;}
virtual bool IsLooped() {return false;}
virtual bool IsStreaming() {return true;}
virtual bool IsStereoWav() {return false;}
virtual int GetCacheStatus() {return AUDIO_IS_LOADED;}
virtual void CacheLoad() {}
virtual void CacheUnload() {}
virtual CSentence *GetSentence() {return NULL;}
virtual int ZeroCrossingBefore( int sample ) {return sample;}
virtual int ZeroCrossingAfter( int sample ) {return sample;}
// mixer's references
virtual void ReferenceAdd( CAudioMixer *pMixer );
virtual void ReferenceRemove( CAudioMixer *pMixer );
// check reference count, return true if nothing is referencing this
virtual bool CanDelete();
virtual void Prefetch() {}
// Nothing, not a cache object...
virtual void CheckAudioSourceCache() {}
private:
class CWaveDataVoice : public IWaveData
{
public:
CWaveDataVoice( CAudioSourceWave &source ) : m_source(source) {}
~CWaveDataVoice( void ) {}
virtual CAudioSource &Source( void )
{
return m_source;
}
// this file is in memory, simply pass along the data request to the source
virtual int ReadSourceData( void **pData, int sampleIndex, int sampleCount, char copyBuf[AUDIOSOURCE_COPYBUF_SIZE] )
{
return m_source.GetOutputData( pData, sampleIndex, sampleCount, copyBuf );
}
virtual bool IsReadyToMix()
{
return true;
}
private:
CAudioSourceWave &m_source; // pointer to source
};
private:
CAudioSourceVoice( const CAudioSourceVoice & );
// Which entity's voice this is for.
int m_iChannel;
// How many mixers are referencing us.
int m_refCount;
};
// ----------------------------------------------------------------------------- //
// Globals.
// ----------------------------------------------------------------------------- //
// The format we sample voice in.
extern WAVEFORMATEX g_VoiceSampleFormat;
class CVoiceSfx : public CSfxTable
{
public:
virtual const char *getname()
{
return "?VoiceSfx";
}
};
static CVoiceSfx g_CVoiceSfx[VOICE_NUM_CHANNELS];
static float g_VoiceOverdriveDuration = 0;
static bool g_bVoiceOverdriveOn = false;
// When voice is on, all other sounds are decreased by this factor.
static ConVar voice_overdrive( "voice_overdrive", "2" );
static ConVar voice_overdrivefadetime( "voice_overdrivefadetime", "0.4" ); // How long it takes to fade in and out of the voice overdrive.
// The sound engine uses this to lower all sound volumes.
// All non-voice sounds are multiplied by this and divided by 256.
int g_SND_VoiceOverdriveInt = 256;
extern int Voice_SamplesPerSec();
extern int Voice_AvgBytesPerSec();
// ----------------------------------------------------------------------------- //
// CAudioSourceVoice implementation.
// ----------------------------------------------------------------------------- //
CAudioSourceVoice::CAudioSourceVoice( CSfxTable *pSfx, int iChannel )
: CAudioSourceWave( pSfx )
{
m_iChannel = iChannel;
m_refCount = 0;
WAVEFORMATEX tmp = g_VoiceSampleFormat;
tmp.nSamplesPerSec = Voice_SamplesPerSec();
tmp.nAvgBytesPerSec = Voice_AvgBytesPerSec();
Init((char*)&tmp, sizeof(tmp));
m_sampleCount = tmp.nSamplesPerSec;
}
CAudioSourceVoice::~CAudioSourceVoice()
{
Voice_OnAudioSourceShutdown( m_iChannel );
}
CAudioMixer *CAudioSourceVoice::CreateMixer( int initialStreamPosition )
{
CWaveDataVoice *pVoice = new CWaveDataVoice(*this);
if(!pVoice)
return NULL;
CAudioMixer *pMixer = CreateWaveMixer( pVoice, WAVE_FORMAT_PCM, 1, BYTES_PER_SAMPLE*8, 0 );
if(!pMixer)
{
delete pVoice;
return NULL;
}
return pMixer;
}
int CAudioSourceVoice::GetOutputData( void **pData, int samplePosition, int sampleCount, char copyBuf[AUDIOSOURCE_COPYBUF_SIZE] )
{
int nSamplesGotten = Voice_GetOutputData(
m_iChannel,
copyBuf,
AUDIOSOURCE_COPYBUF_SIZE,
samplePosition,
sampleCount );
// If there weren't enough bytes in the received data channel, pad it with zeros.
if( nSamplesGotten < sampleCount )
{
memset( &copyBuf[nSamplesGotten], 0, (sampleCount - nSamplesGotten) * BYTES_PER_SAMPLE );
nSamplesGotten = sampleCount;
}
*pData = copyBuf;
return nSamplesGotten;
}
int CAudioSourceVoice::SampleRate()
{
return Voice_SamplesPerSec();
}
int CAudioSourceVoice::SampleSize()
{
return BYTES_PER_SAMPLE;
}
int CAudioSourceVoice::SampleCount()
{
return Voice_SamplesPerSec();
}
void CAudioSourceVoice::ReferenceAdd(CAudioMixer *pMixer)
{
m_refCount++;
}
void CAudioSourceVoice::ReferenceRemove(CAudioMixer *pMixer)
{
m_refCount--;
if ( m_refCount <= 0 )
delete this;
}
bool CAudioSourceVoice::CanDelete()
{
return m_refCount == 0;
}
// ----------------------------------------------------------------------------- //
// Interface implementation.
// ----------------------------------------------------------------------------- //
bool VoiceSE_Init()
{
if( !snd_initialized )
return false;
g_SND_VoiceOverdriveInt = 256;
return true;
}
void VoiceSE_Term()
{
// Disable voice ducking.
g_SND_VoiceOverdriveInt = 256;
}
void VoiceSE_Idle(float frametime)
{
g_SND_VoiceOverdriveInt = 256;
if( g_bVoiceOverdriveOn )
{
g_VoiceOverdriveDuration = min( g_VoiceOverdriveDuration+frametime, voice_overdrivefadetime.GetFloat() );
}
else
{
if(g_VoiceOverdriveDuration == 0)
return;
g_VoiceOverdriveDuration = max(g_VoiceOverdriveDuration-frametime, 0.f);
}
float percent = g_VoiceOverdriveDuration / voice_overdrivefadetime.GetFloat();
percent = (float)(-cos(percent * 3.1415926535) * 0.5 + 0.5); // Smooth it out..
float voiceOverdrive = 1 + (voice_overdrive.GetFloat() - 1) * percent;
g_SND_VoiceOverdriveInt = (int)(256 / voiceOverdrive);
}
int VoiceSE_StartChannel(
int iChannel, //! Which channel to start.
int iEntity,
bool bProximity,
int nViewEntityIndex )
{
Assert( iChannel >= 0 && iChannel < VOICE_NUM_CHANNELS );
// Start the sound.
CSfxTable *sfx = &g_CVoiceSfx[iChannel];
sfx->pSource = NULL;
Vector vOrigin(0,0,0);
StartSoundParams_t params;
params.staticsound = false;
params.entchannel = (CHAN_VOICE_BASE+iChannel);
params.pSfx = sfx;
params.origin = vOrigin;
params.fvol = 1.0f;
params.flags = 0;
params.pitch = PITCH_NORM;
if ( bProximity == true )
{
params.bUpdatePositions = true;
params.soundlevel = SNDLVL_TALKING;
params.soundsource = iEntity;
}
else
{
params.soundlevel = SNDLVL_IDLE;
params.soundsource = nViewEntityIndex;
}
return S_StartSound( params );
}
void VoiceSE_EndChannel(
int iChannel, //! Which channel to stop.
int iEntity
)
{
Assert( iChannel >= 0 && iChannel < VOICE_NUM_CHANNELS );
S_StopSound( iEntity, CHAN_VOICE_BASE+iChannel );
// Start the sound.
CSfxTable *sfx = &g_CVoiceSfx[iChannel];
sfx->pSource = NULL;
}
void VoiceSE_StartOverdrive()
{
g_bVoiceOverdriveOn = true;
}
void VoiceSE_EndOverdrive()
{
g_bVoiceOverdriveOn = false;
}
void VoiceSE_InitMouth(int entnum)
{
}
void VoiceSE_CloseMouth(int entnum)
{
}
void VoiceSE_MoveMouth(int entnum, short *pSamples, int nSamples)
{
}
CAudioSource* Voice_SetupAudioSource( int soundsource, int entchannel )
{
int iChannel = entchannel - CHAN_VOICE_BASE;
if( iChannel >= 0 && iChannel < VOICE_NUM_CHANNELS )
{
CSfxTable *sfx = &g_CVoiceSfx[iChannel];
return new CAudioSourceVoice( sfx, iChannel );
}
else
return NULL;
}