ddnet/src/engine/client/sound.cpp

/* (c) Magnus Auvinen. See licence.txt in the root of the distribution for more information. */
/* If you are missing that file, acquire a complete release at teeworlds.com.                */
#include <atomic>
#include <base/math.h>
#include <base/system.h>

#include <engine/graphics.h>
#include <engine/storage.h>

#include <engine/shared/config.h>
#include <mutex>

#include "SDL.h"

#include "sound.h"

extern "C" {
#if defined(CONF_VIDEORECORDER)
#include <engine/shared/video.h>
#endif
#include <opusfile.h>
#include <wavpack.h>
}
#include <cmath>

enum
{
	NUM_SAMPLES = 512,
	NUM_VOICES = 256,
	NUM_CHANNELS = 16,
};

struct CSample
{
	short *m_pData;
	int m_NumFrames;
	int m_Rate;
	int m_Channels;
	int m_LoopStart;
	int m_LoopEnd;
	int m_PausedAt;
};

struct CChannel
{
	int m_Vol;
	int m_Pan;
};

struct CVoice
{
	CSample *m_pSample;
	CChannel *m_pChannel;
	int m_Age; // increases when reused
	int m_Tick;
	int m_Vol; // 0 - 255
	int m_Flags;
	int m_X, m_Y;
	float m_Falloff; // [0.0, 1.0]

	int m_Shape;
	union
	{
		ISound::CVoiceShapeCircle m_Circle;
		ISound::CVoiceShapeRectangle m_Rectangle;
	};
};

static CSample m_aSamples[NUM_SAMPLES] = {{0}};
static CVoice m_aVoices[NUM_VOICES] = {{0}};
static CChannel m_aChannels[NUM_CHANNELS] = {{255, 0}};

static std::mutex m_SoundLock;

static std::atomic<int> m_CenterX{0};
static std::atomic<int> m_CenterY{0};

static int m_MixingRate = 48000;
static std::atomic<int> m_SoundVolume{100};

static int m_NextVoice = 0;
static int *m_pMixBuffer = 0; // buffer only used by the thread callback function
static unsigned m_MaxFrames = 0;

static const void *s_pWVBuffer = 0x0;
static int s_WVBufferPosition = 0;
static int s_WVBufferSize = 0;

const int DefaultDistance = 1500;
int m_LastBreak = 0;

// TODO: there should be a faster way todo this
static short Int2Short(int i)
{
	if(i > 0x7fff)
		return 0x7fff;
	else if(i < -0x7fff)
		return -0x7fff;
	return i;
}

static int IntAbs(int i)
{
	if(i < 0)
		return -i;
	return i;
}

static void Mix(short *pFinalOut, unsigned Frames)
{
	int MasterVol;
	mem_zero(m_pMixBuffer, m_MaxFrames * 2 * sizeof(int));
	Frames = minimum(Frames, m_MaxFrames);

	// acquire lock while we are mixing
	m_SoundLock.lock();

	MasterVol = m_SoundVolume;

	for(auto &Voice : m_aVoices)
	{
		if(Voice.m_pSample)
		{
			// mix voice
			int *pOut = m_pMixBuffer;

			int Step = Voice.m_pSample->m_Channels; // setup input sources
			short *pInL = &Voice.m_pSample->m_pData[Voice.m_Tick * Step];
			short *pInR = &Voice.m_pSample->m_pData[Voice.m_Tick * Step + 1];

			unsigned End = Voice.m_pSample->m_NumFrames - Voice.m_Tick;

			int Rvol = (int)(Voice.m_pChannel->m_Vol * (Voice.m_Vol / 255.0f));
			int Lvol = (int)(Voice.m_pChannel->m_Vol * (Voice.m_Vol / 255.0f));

			// make sure that we don't go outside the sound data
			if(Frames < End)
				End = Frames;

			// check if we have a mono sound
			if(Voice.m_pSample->m_Channels == 1)
				pInR = pInL;

			// volume calculation
			if(Voice.m_Flags & ISound::FLAG_POS && Voice.m_pChannel->m_Pan)
			{
				// TODO: we should respect the channel panning value
				int dx = Voice.m_X - m_CenterX.load(std::memory_order_relaxed);
				int dy = Voice.m_Y - m_CenterY.load(std::memory_order_relaxed);
				//
				int p = IntAbs(dx);
				float FalloffX = 0.0f;
				float FalloffY = 0.0f;

				int RangeX = 0; // for panning
				bool InVoiceField = false;

				switch(Voice.m_Shape)
				{
				case ISound::SHAPE_CIRCLE:
				{
					float r = Voice.m_Circle.m_Radius;
					RangeX = r;

					int Dist = (int)sqrtf((float)dx * dx + dy * dy); // nasty float
					if(Dist < r)
					{
						InVoiceField = true;

						// falloff
						int FalloffDistance = r * Voice.m_Falloff;
						if(Dist > FalloffDistance)
							FalloffX = FalloffY = (r - Dist) / (r - FalloffDistance);
						else
							FalloffX = FalloffY = 1.0f;
					}
					else
						InVoiceField = false;

					break;
				}

				case ISound::SHAPE_RECTANGLE:
				{
					RangeX = Voice.m_Rectangle.m_Width / 2.0f;

					int abs_dx = abs(dx);
					int abs_dy = abs(dy);

					int w = Voice.m_Rectangle.m_Width / 2.0f;
					int h = Voice.m_Rectangle.m_Height / 2.0f;

					if(abs_dx < w && abs_dy < h)
					{
						InVoiceField = true;

						// falloff
						int fx = Voice.m_Falloff * w;
						int fy = Voice.m_Falloff * h;

						FalloffX = abs_dx > fx ? (float)(w - abs_dx) / (w - fx) : 1.0f;
						FalloffY = abs_dy > fy ? (float)(h - abs_dy) / (h - fy) : 1.0f;
					}
					else
						InVoiceField = false;

					break;
				}
				};

				if(InVoiceField)
				{
					// panning
					if(!(Voice.m_Flags & ISound::FLAG_NO_PANNING))
					{
						if(dx > 0)
							Lvol = ((RangeX - p) * Lvol) / RangeX;
						else
							Rvol = ((RangeX - p) * Rvol) / RangeX;
					}

					{
						Lvol *= FalloffX * FalloffY;
						Rvol *= FalloffX * FalloffY;
					}
				}
				else
				{
					Lvol = 0;
					Rvol = 0;
				}
			}

			// process all frames
			for(unsigned s = 0; s < End; s++)
			{
				*pOut++ += (*pInL) * Lvol;
				*pOut++ += (*pInR) * Rvol;
				pInL += Step;
				pInR += Step;
				Voice.m_Tick++;
			}

			// free voice if not used any more
			if(Voice.m_Tick == Voice.m_pSample->m_NumFrames)
			{
				if(Voice.m_Flags & ISound::FLAG_LOOP)
					Voice.m_Tick = 0;
				else
				{
					Voice.m_pSample = 0;
					Voice.m_Age++;
				}
			}
		}
	}

	// release the lock
	m_SoundLock.unlock();

	{
		// clamp accumulated values
		// TODO: this seams slow
		for(unsigned i = 0; i < Frames; i++)
		{
			int j = i << 1;
			int vl = ((m_pMixBuffer[j] * MasterVol) / 101) >> 8;
			int vr = ((m_pMixBuffer[j + 1] * MasterVol) / 101) >> 8;

			pFinalOut[j] = Int2Short(vl);
			pFinalOut[j + 1] = Int2Short(vr);

			// dbg_msg("sound", "the real shit: %d %d", pFinalOut[j], pFinalOut[j+1]);
		}
	}

#if defined(CONF_ARCH_ENDIAN_BIG)
	swap_endian(pFinalOut, sizeof(short), Frames * 2);
#endif
}

static void SdlCallback(void *pUnused, Uint8 *pStream, int Len)
{
	(void)pUnused;
#if defined(CONF_VIDEORECORDER)
	if(!(IVideo::Current() && g_Config.m_ClVideoSndEnable))
		Mix((short *)pStream, Len / 2 / 2);
	else
		IVideo::Current()->NextAudioFrame(Mix);
#else
	Mix((short *)pStream, Len / 2 / 2);
#endif
}

int CSound::Init()
{
	m_SoundEnabled = 0;
	m_pGraphics = Kernel()->RequestInterface<IEngineGraphics>();
	m_pStorage = Kernel()->RequestInterface<IStorage>();

	SDL_AudioSpec Format, FormatOut;

	if(!g_Config.m_SndEnable)
		return 0;

	if(SDL_InitSubSystem(SDL_INIT_AUDIO) < 0)
	{
		dbg_msg("gfx", "unable to init SDL audio: %s", SDL_GetError());
		return -1;
	}

	m_MixingRate = g_Config.m_SndRate;

	// Set 16-bit stereo audio at 22Khz
	Format.freq = g_Config.m_SndRate; // ignore_convention
	Format.format = AUDIO_S16; // ignore_convention
	Format.channels = 2; // ignore_convention
	Format.samples = g_Config.m_SndBufferSize; // ignore_convention
	Format.callback = SdlCallback; // ignore_convention
	Format.userdata = NULL; // ignore_convention

	// Open the audio device and start playing sound!
	m_Device = SDL_OpenAudioDevice(NULL, 0, &Format, &FormatOut, 0);

	if(m_Device == 0)
	{
		dbg_msg("client/sound", "unable to open audio: %s", SDL_GetError());
		return -1;
	}
	else
		dbg_msg("client/sound", "sound init successful using audio driver '%s'", SDL_GetCurrentAudioDriver());

	m_MaxFrames = FormatOut.samples * 2;
	m_pMixBuffer = (int *)calloc(m_MaxFrames * 2, sizeof(int));

	SDL_PauseAudioDevice(m_Device, 0);

	m_SoundEnabled = 1;
	Update(); // update the volume
	return 0;
}

int CSound::Update()
{
	// update volume
	int WantedVolume = g_Config.m_SndVolume;

	if(!m_pGraphics->WindowActive() && g_Config.m_SndNonactiveMute)
		WantedVolume = 0;

	if(WantedVolume != m_SoundVolume)
	{
		std::unique_lock<std::mutex> Lock(m_SoundLock);
		m_SoundVolume = WantedVolume;
	}
	//#if defined(CONF_VIDEORECORDER)
	//	if(IVideo::Current() && g_Config.m_ClVideoSndEnable)
	//		IVideo::Current()->NextAudioFrame(Mix);
	//#endif
	return 0;
}

int CSound::Shutdown()
{
	for(unsigned SampleID = 0; SampleID < NUM_SAMPLES; SampleID++)
	{
		UnloadSample(SampleID);
	}

	SDL_CloseAudioDevice(m_Device);
	SDL_QuitSubSystem(SDL_INIT_AUDIO);
	free(m_pMixBuffer);
	m_pMixBuffer = 0;
	return 0;
}

int CSound::AllocID()
{
	// TODO: linear search, get rid of it
	for(unsigned SampleID = 0; SampleID < NUM_SAMPLES; SampleID++)
	{
		if(m_aSamples[SampleID].m_pData == 0x0)
			return SampleID;
	}

	return -1;
}

void CSound::RateConvert(int SampleID)
{
	CSample *pSample = &m_aSamples[SampleID];
	int NumFrames = 0;
	short *pNewData = 0;

	// make sure that we need to convert this sound
	if(!pSample->m_pData || pSample->m_Rate == m_MixingRate)
		return;

	// allocate new data
	NumFrames = (int)((pSample->m_NumFrames / (float)pSample->m_Rate) * m_MixingRate);
	pNewData = (short *)calloc((size_t)NumFrames * pSample->m_Channels, sizeof(short));

	for(int i = 0; i < NumFrames; i++)
	{
		// resample TODO: this should be done better, like linear at least
		float a = i / (float)NumFrames;
		int f = (int)(a * pSample->m_NumFrames);
		if(f >= pSample->m_NumFrames)
			f = pSample->m_NumFrames - 1;

		// set new data
		if(pSample->m_Channels == 1)
			pNewData[i] = pSample->m_pData[f];
		else if(pSample->m_Channels == 2)
		{
			pNewData[i * 2] = pSample->m_pData[f * 2];
			pNewData[i * 2 + 1] = pSample->m_pData[f * 2 + 1];
		}
	}

	// free old data and apply new
	free(pSample->m_pData);
	pSample->m_pData = pNewData;
	pSample->m_NumFrames = NumFrames;
	pSample->m_Rate = m_MixingRate;
}

int CSound::DecodeOpus(int SampleID, const void *pData, unsigned DataSize)
{
	if(SampleID == -1 || SampleID >= NUM_SAMPLES)
		return -1;

	CSample *pSample = &m_aSamples[SampleID];

	OggOpusFile *OpusFile = op_open_memory((const unsigned char *)pData, DataSize, NULL);
	if(OpusFile)
	{
		int NumChannels = op_channel_count(OpusFile, -1);
		int NumSamples = op_pcm_total(OpusFile, -1); // per channel!

		pSample->m_Channels = NumChannels;

		if(pSample->m_Channels > 2)
		{
			dbg_msg("sound/opus", "file is not mono or stereo.");
			return -1;
		}

		pSample->m_pData = (short *)calloc((size_t)NumSamples * NumChannels, sizeof(short));

		int Read;
		int Pos = 0;
		while(Pos < NumSamples)
		{
			Read = op_read(OpusFile, pSample->m_pData + Pos * NumChannels, NumSamples * NumChannels, NULL);
			Pos += Read;
		}

		pSample->m_NumFrames = NumSamples; // ?
		pSample->m_Rate = 48000;
		pSample->m_LoopStart = -1;
		pSample->m_LoopEnd = -1;
		pSample->m_PausedAt = 0;
	}
	else
	{
		dbg_msg("sound/opus", "failed to decode sample");
		return -1;
	}

	return SampleID;
}

static int ReadDataOld(void *pBuffer, int Size)
{
	int ChunkSize = minimum(Size, s_WVBufferSize - s_WVBufferPosition);
	mem_copy(pBuffer, (const char *)s_pWVBuffer + s_WVBufferPosition, ChunkSize);
	s_WVBufferPosition += ChunkSize;
	return ChunkSize;
}

#if defined(CONF_WAVPACK_OPEN_FILE_INPUT_EX)
static int ReadData(void *pId, void *pBuffer, int Size)
{
	(void)pId;
	return ReadDataOld(pBuffer, Size);
}

static int ReturnFalse(void *pId)
{
	(void)pId;
	return 0;
}

static unsigned int GetPos(void *pId)
{
	(void)pId;
	return s_WVBufferPosition;
}

static unsigned int GetLength(void *pId)
{
	(void)pId;
	return s_WVBufferSize;
}

static int PushBackByte(void *pId, int Char)
{
	s_WVBufferPosition -= 1;
	return 0;
}
#endif

int CSound::DecodeWV(int SampleID, const void *pData, unsigned DataSize)
{
	if(SampleID == -1 || SampleID >= NUM_SAMPLES)
		return -1;

	CSample *pSample = &m_aSamples[SampleID];
	char aError[100];
	WavpackContext *pContext;

	s_pWVBuffer = pData;
	s_WVBufferSize = DataSize;
	s_WVBufferPosition = 0;

#if defined(CONF_WAVPACK_OPEN_FILE_INPUT_EX)
	WavpackStreamReader Callback = {0};
	Callback.can_seek = ReturnFalse;
	Callback.get_length = GetLength;
	Callback.get_pos = GetPos;
	Callback.push_back_byte = PushBackByte;
	Callback.read_bytes = ReadData;
	pContext = WavpackOpenFileInputEx(&Callback, (void *)1, 0, aError, 0, 0);
#else
	pContext = WavpackOpenFileInput(ReadDataOld, aError);
#endif
	if(pContext)
	{
		int NumSamples = WavpackGetNumSamples(pContext);
		int BitsPerSample = WavpackGetBitsPerSample(pContext);
		unsigned int SampleRate = WavpackGetSampleRate(pContext);
		int NumChannels = WavpackGetNumChannels(pContext);
		int *pSrc;
		short *pDst;
		int i;

		pSample->m_Channels = NumChannels;
		pSample->m_Rate = SampleRate;

		if(pSample->m_Channels > 2)
		{
			dbg_msg("sound/wv", "file is not mono or stereo.");
			return -1;
		}

		if(BitsPerSample != 16)
		{
			dbg_msg("sound/wv", "bps is %d, not 16", BitsPerSample);
			return -1;
		}

		int *pBuffer = (int *)calloc((size_t)NumSamples * NumChannels, sizeof(int));
		WavpackUnpackSamples(pContext, pBuffer, NumSamples); // TODO: check return value
		pSrc = pBuffer;

		pSample->m_pData = (short *)calloc((size_t)NumSamples * NumChannels, sizeof(short));
		pDst = pSample->m_pData;

		for(i = 0; i < NumSamples * NumChannels; i++)
			*pDst++ = (short)*pSrc++;

		free(pBuffer);
#ifdef CONF_WAVPACK_CLOSE_FILE
		WavpackCloseFile(pContext);
#endif

		pSample->m_NumFrames = NumSamples;
		pSample->m_LoopStart = -1;
		pSample->m_LoopEnd = -1;
		pSample->m_PausedAt = 0;
	}
	else
	{
		dbg_msg("sound/wv", "failed to decode sample (%s)", aError);
		return -1;
	}

	return SampleID;
}

int CSound::LoadOpus(const char *pFilename)
{
	// don't waste memory on sound when we are stress testing
#ifdef CONF_DEBUG
	if(g_Config.m_DbgStress)
		return -1;
#endif

	// no need to load sound when we are running with no sound
	if(!m_SoundEnabled)
		return -1;

	if(!m_pStorage)
		return -1;

	IOHANDLE File = m_pStorage->OpenFile(pFilename, IOFLAG_READ, IStorage::TYPE_ALL);
	if(!File)
	{
		dbg_msg("sound/opus", "failed to open file. filename='%s'", pFilename);
		return -1;
	}

	int SampleID = AllocID();
	int DataSize = io_length(File);
	if(SampleID < 0 || DataSize <= 0)
	{
		io_close(File);
		File = NULL;
		dbg_msg("sound/opus", "failed to open file. filename='%s'", pFilename);
		return -1;
	}

	// read the whole file into memory
	char *pData = new char[DataSize];
	io_read(File, pData, DataSize);

	SampleID = DecodeOpus(SampleID, pData, DataSize);

	delete[] pData;
	io_close(File);
	File = NULL;

	if(g_Config.m_Debug)
		dbg_msg("sound/opus", "loaded %s", pFilename);

	RateConvert(SampleID);
	return SampleID;
}

int CSound::LoadWV(const char *pFilename)
{
	// don't waste memory on sound when we are stress testing
#ifdef CONF_DEBUG
	if(g_Config.m_DbgStress)
		return -1;
#endif

	// no need to load sound when we are running with no sound
	if(!m_SoundEnabled)
		return -1;

	if(!m_pStorage)
		return -1;

	IOHANDLE File = m_pStorage->OpenFile(pFilename, IOFLAG_READ, IStorage::TYPE_ALL);
	if(!File)
	{
		dbg_msg("sound/wv", "failed to open file. filename='%s'", pFilename);
		return -1;
	}

	int SampleID = AllocID();
	int DataSize = io_length(File);
	if(SampleID < 0 || DataSize <= 0)
	{
		io_close(File);
		File = NULL;
		dbg_msg("sound/wv", "failed to open file. filename='%s'", pFilename);
		return -1;
	}

	// read the whole file into memory
	char *pData = new char[DataSize];
	io_read(File, pData, DataSize);

	SampleID = DecodeWV(SampleID, pData, DataSize);

	delete[] pData;
	io_close(File);
	File = NULL;

	if(g_Config.m_Debug)
		dbg_msg("sound/wv", "loaded %s", pFilename);

	RateConvert(SampleID);
	return SampleID;
}

int CSound::LoadOpusFromMem(const void *pData, unsigned DataSize, bool FromEditor = false)
{
	// don't waste memory on sound when we are stress testing
#ifdef CONF_DEBUG
	if(g_Config.m_DbgStress)
		return -1;
#endif

	// no need to load sound when we are running with no sound
	if(!m_SoundEnabled && !FromEditor)
		return -1;

	if(!pData)
		return -1;

	int SampleID = AllocID();
	if(SampleID < 0)
		return -1;

	SampleID = DecodeOpus(SampleID, pData, DataSize);

	RateConvert(SampleID);
	return SampleID;
}

int CSound::LoadWVFromMem(const void *pData, unsigned DataSize, bool FromEditor = false)
{
	// don't waste memory on sound when we are stress testing
#ifdef CONF_DEBUG
	if(g_Config.m_DbgStress)
		return -1;
#endif

	// no need to load sound when we are running with no sound
	if(!m_SoundEnabled && !FromEditor)
		return -1;

	if(!pData)
		return -1;

	int SampleID = AllocID();
	if(SampleID < 0)
		return -1;

	SampleID = DecodeWV(SampleID, pData, DataSize);

	RateConvert(SampleID);
	return SampleID;
}

void CSound::UnloadSample(int SampleID)
{
	if(SampleID == -1 || SampleID >= NUM_SAMPLES)
		return;

	Stop(SampleID);
	free(m_aSamples[SampleID].m_pData);

	m_aSamples[SampleID].m_pData = 0x0;
}

float CSound::GetSampleDuration(int SampleID)
{
	if(SampleID == -1 || SampleID >= NUM_SAMPLES)
		return 0.0f;

	return (m_aSamples[SampleID].m_NumFrames / m_aSamples[SampleID].m_Rate);
}

void CSound::SetListenerPos(float x, float y)
{
	m_CenterX.store((int)x, std::memory_order_relaxed);
	m_CenterY.store((int)y, std::memory_order_relaxed);
}

void CSound::SetVoiceVolume(CVoiceHandle Voice, float Volume)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	Volume = clamp(Volume, 0.0f, 1.0f);
	m_aVoices[VoiceID].m_Vol = (int)(Volume * 255.0f);
}

void CSound::SetVoiceFalloff(CVoiceHandle Voice, float Falloff)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	Falloff = clamp(Falloff, 0.0f, 1.0f);
	m_aVoices[VoiceID].m_Falloff = Falloff;
}

void CSound::SetVoiceLocation(CVoiceHandle Voice, float x, float y)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	m_aVoices[VoiceID].m_X = x;
	m_aVoices[VoiceID].m_Y = y;
}

void CSound::SetVoiceTimeOffset(CVoiceHandle Voice, float offset)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	{
		if(m_aVoices[VoiceID].m_pSample)
		{
			int Tick = 0;
			bool IsLooping = m_aVoices[VoiceID].m_Flags & ISound::FLAG_LOOP;
			uint64_t TickOffset = m_aVoices[VoiceID].m_pSample->m_Rate * offset;
			if(m_aVoices[VoiceID].m_pSample->m_NumFrames > 0 && IsLooping)
				Tick = TickOffset % m_aVoices[VoiceID].m_pSample->m_NumFrames;
			else
				Tick = clamp(TickOffset, (uint64_t)0, (uint64_t)m_aVoices[VoiceID].m_pSample->m_NumFrames);

			// at least 200msec off, else depend on buffer size
			float Threshold = maximum(0.2f * m_aVoices[VoiceID].m_pSample->m_Rate, (float)m_MaxFrames);
			if(abs(m_aVoices[VoiceID].m_Tick - Tick) > Threshold)
			{
				// take care of looping (modulo!)
				if(!(IsLooping && (minimum(m_aVoices[VoiceID].m_Tick, Tick) + m_aVoices[VoiceID].m_pSample->m_NumFrames - maximum(m_aVoices[VoiceID].m_Tick, Tick)) <= Threshold))
				{
					m_aVoices[VoiceID].m_Tick = Tick;
				}
			}
		}
	}
}

void CSound::SetVoiceCircle(CVoiceHandle Voice, float Radius)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	m_aVoices[VoiceID].m_Shape = ISound::SHAPE_CIRCLE;
	m_aVoices[VoiceID].m_Circle.m_Radius = maximum(0.0f, Radius);
}

void CSound::SetVoiceRectangle(CVoiceHandle Voice, float Width, float Height)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	m_aVoices[VoiceID].m_Shape = ISound::SHAPE_RECTANGLE;
	m_aVoices[VoiceID].m_Rectangle.m_Width = maximum(0.0f, Width);
	m_aVoices[VoiceID].m_Rectangle.m_Height = maximum(0.0f, Height);
}

void CSound::SetChannel(int ChannelID, float Vol, float Pan)
{
	m_aChannels[ChannelID].m_Vol = (int)(Vol * 255.0f);
	m_aChannels[ChannelID].m_Pan = (int)(Pan * 255.0f); // TODO: this is only on and off right now
}

ISound::CVoiceHandle CSound::Play(int ChannelID, int SampleID, int Flags, float x, float y)
{
	int VoiceID = -1;
	int Age = -1;
	int i;

	m_SoundLock.lock();

	// search for voice
	for(i = 0; i < NUM_VOICES; i++)
	{
		int id = (m_NextVoice + i) % NUM_VOICES;
		if(!m_aVoices[id].m_pSample)
		{
			VoiceID = id;
			m_NextVoice = id + 1;
			break;
		}
	}

	// voice found, use it
	if(VoiceID != -1)
	{
		m_aVoices[VoiceID].m_pSample = &m_aSamples[SampleID];
		m_aVoices[VoiceID].m_pChannel = &m_aChannels[ChannelID];
		if(Flags & FLAG_LOOP)
			m_aVoices[VoiceID].m_Tick = m_aSamples[SampleID].m_PausedAt;
		else
			m_aVoices[VoiceID].m_Tick = 0;
		m_aVoices[VoiceID].m_Vol = 255;
		m_aVoices[VoiceID].m_Flags = Flags;
		m_aVoices[VoiceID].m_X = (int)x;
		m_aVoices[VoiceID].m_Y = (int)y;
		m_aVoices[VoiceID].m_Falloff = 0.0f;
		m_aVoices[VoiceID].m_Shape = ISound::SHAPE_CIRCLE;
		m_aVoices[VoiceID].m_Circle.m_Radius = DefaultDistance;
		Age = m_aVoices[VoiceID].m_Age;
	}

	m_SoundLock.unlock();
	return CreateVoiceHandle(VoiceID, Age);
}

ISound::CVoiceHandle CSound::PlayAt(int ChannelID, int SampleID, int Flags, float x, float y)
{
	return Play(ChannelID, SampleID, Flags | ISound::FLAG_POS, x, y);
}

ISound::CVoiceHandle CSound::Play(int ChannelID, int SampleID, int Flags)
{
	return Play(ChannelID, SampleID, Flags, 0, 0);
}

void CSound::Stop(int SampleID)
{
	// TODO: a nice fade out
	std::unique_lock<std::mutex> Lock(m_SoundLock);
	CSample *pSample = &m_aSamples[SampleID];
	for(auto &Voice : m_aVoices)
	{
		if(Voice.m_pSample == pSample)
		{
			if(Voice.m_Flags & FLAG_LOOP)
				Voice.m_pSample->m_PausedAt = Voice.m_Tick;
			else
				Voice.m_pSample->m_PausedAt = 0;
			Voice.m_pSample = 0;
		}
	}
}

void CSound::StopAll()
{
	// TODO: a nice fade out
	std::unique_lock<std::mutex> Lock(m_SoundLock);
	for(auto &Voice : m_aVoices)
	{
		if(Voice.m_pSample)
		{
			if(Voice.m_Flags & FLAG_LOOP)
				Voice.m_pSample->m_PausedAt = Voice.m_Tick;
			else
				Voice.m_pSample->m_PausedAt = 0;
		}
		Voice.m_pSample = 0;
	}
}

void CSound::StopVoice(CVoiceHandle Voice)
{
	if(!Voice.IsValid())
		return;

	int VoiceID = Voice.Id();

	std::unique_lock<std::mutex> Lock(m_SoundLock);
	if(m_aVoices[VoiceID].m_Age != Voice.Age())
		return;

	{
		m_aVoices[VoiceID].m_pSample = 0;
		m_aVoices[VoiceID].m_Age++;
	}
}

IEngineSound *CreateEngineSound() { return new CSound; }