#include "tmachine.h"
#include "tsio_wav.h"
#include "tsystem.h"
#include "tfilepath_io.h"

using namespace std;

#if !defined(TNZ_LITTLE_ENDIAN)
TNZ_LITTLE_ENDIAN undefined !!
#endif

	//------------------------------------------------------------------------------

	void
	swapAndCopySamples(short *srcBuffer, short *dstBuffer, TINT32 sampleCount);

//==============================================================================

// TWAVChunk: classe base per i vari chunk WAV

class TWAVChunk
{

public:
	static TINT32 HDR_LENGTH;

	string m_name;
	TINT32 m_length; // lunghezza del chunk in byte

	TWAVChunk(string name, TINT32 length)
		: m_name(name), m_length(length) {}

	virtual ~TWAVChunk() {}

	virtual bool read(Tifstream &is)
	{
		skip(is);
		return true;
	}

	void skip(Tifstream &is)
	{
		is.seekg(m_length, ios::cur);
	}

	static bool readHeader(Tifstream &is, string &name, TINT32 &length)
	{

		char cName[5];
		TINT32 len = 0;
		memset(cName, 0, sizeof(cName));

		is.read(cName, 4);
		if (is.fail())
			return false;
		cName[4] = '\0';

		is.read((char *)&len, sizeof(len));
		if (is.fail())
			return false;

		// il formato WAV memorizza i dati come little-endian
		// se la piattaforma non e' little-endian bisogna scambiare i byte
		if (!TNZ_LITTLE_ENDIAN)
			len = swapTINT32(len);

		name = string(cName);
		length = len;
		return true;
	}
};

TINT32 TWAVChunk::HDR_LENGTH = 8;

//====================================================================

//  FMT Chunk: Chunk contenente le informazioni sulla traccia

class TFMTChunk : public TWAVChunk
{

public:
	static TINT32 LENGTH;

	USHORT m_encodingType; // PCM, ...
	USHORT m_chans;		   // numero di canali
	TUINT32 m_sampleRate;
	TUINT32 m_avgBytesPerSecond;
	USHORT m_bytesPerSample;
	USHORT m_bitPerSample;

	TFMTChunk(TINT32 length)
		: TWAVChunk("fmt ", length) {}

	virtual bool read(Tifstream &is)
	{

		is.read((char *)&m_encodingType, sizeof(m_encodingType));
		is.read((char *)&m_chans, sizeof(m_chans));
		is.read((char *)&m_sampleRate, sizeof(m_sampleRate));
		is.read((char *)&m_avgBytesPerSecond, sizeof(m_avgBytesPerSecond));
		is.read((char *)&m_bytesPerSample, sizeof(m_bytesPerSample));
		is.read((char *)&m_bitPerSample, sizeof(m_bitPerSample));

		if (!TNZ_LITTLE_ENDIAN) {
			m_encodingType = swapUshort(m_encodingType);
			m_chans = swapUshort(m_chans);
			m_sampleRate = swapTINT32(m_sampleRate);
			m_avgBytesPerSecond = swapTINT32(m_avgBytesPerSecond);
			m_bytesPerSample = swapUshort(m_bytesPerSample);
			m_bitPerSample = swapUshort(m_bitPerSample);
		}

		assert(m_length >= 16);
		if (m_length > 16)
			is.seekg((long)is.tellg() + m_length - 16);
		return true;
	}

	bool write(ofstream &os)
	{

		TUINT32 length = m_length;
		USHORT type = m_encodingType;
		USHORT chans = m_chans;
		TUINT32 sampleRate = m_sampleRate;
		TUINT32 bytesPerSecond = m_avgBytesPerSecond;
		USHORT bytesPerSample = m_bytesPerSample;
		USHORT bitPerSample = m_bitPerSample;

		if (!TNZ_LITTLE_ENDIAN) {
			length = swapTINT32(length);
			type = swapUshort(type);
			chans = swapUshort(chans);
			sampleRate = swapTINT32(sampleRate);
			bytesPerSecond = swapTINT32(bytesPerSecond);
			bytesPerSample = swapUshort(bytesPerSample);
			bitPerSample = swapUshort(bitPerSample);
		}

		os.write((char *)"fmt ", 4);
		os.write((char *)&length, sizeof(length));
		os.write((char *)&type, sizeof(type));
		os.write((char *)&chans, sizeof(chans));
		os.write((char *)&sampleRate, sizeof(sampleRate));
		os.write((char *)&bytesPerSecond, sizeof(bytesPerSecond));
		os.write((char *)&bytesPerSample, sizeof(bytesPerSample));
		os.write((char *)&bitPerSample, sizeof(bitPerSample));

		return true;
	}
};

TINT32 TFMTChunk::LENGTH = TWAVChunk::HDR_LENGTH + 16;

//====================================================================

//  DATA Chunk: Chunk contenente i campioni

class TDATAChunk : public TWAVChunk
{

public:
	UCHAR *m_samples;

	TDATAChunk(TINT32 length)
		: TWAVChunk("data", length) {}

	~TDATAChunk()
	{
		if (m_samples)
			delete[] m_samples;
	}

	bool read(Tifstream &is)
	{

		// alloca il buffer dei campioni
		m_samples = new UCHAR[m_length];
		if (!m_samples)
			return false;
		is.read((char *)m_samples, m_length);
		return true;
	}

	bool write(ofstream &os)
	{

		TINT32 length = m_length;

		if (!TNZ_LITTLE_ENDIAN) {
			length = swapTINT32(length);
		}

		os.write((char *)"data", 4);
		os.write((char *)&length, sizeof(length));
		os.write((char *)m_samples, m_length);
		return true;
	}
};

//==============================================================================

TSoundTrackReaderWav::TSoundTrackReaderWav(const TFilePath &fp)
	: TSoundTrackReader(fp)
{
}

//------------------------------------------------------------------------------

TSoundTrackP TSoundTrackReaderWav::load()
{
	char chunkName[5];
	char RIFFType[5];
	TINT32 chunkLength;

	Tifstream is(m_path);

	if (!is)
		throw TException(m_path.getWideString() + L" : File doesn't exist");

	// legge il nome del chunk
	is.read((char *)&chunkName, sizeof(chunkName) - 1);
	chunkName[4] = '\0';

	// legge la lunghezza del chunk
	is.read((char *)&chunkLength, sizeof(chunkLength));

	if (!TNZ_LITTLE_ENDIAN)
		chunkLength = swapTINT32(chunkLength);

	// legge il RIFFType
	is.read((char *)&RIFFType, sizeof(RIFFType) - 1);
	RIFFType[4] = '\0';

	// per i .wav il RIFFType DEVE essere uguale a "WAVE"
	if ((string(RIFFType, 4) != "WAVE"))
		throw TException("The WAV file doesn't contain the WAVE form");

	TFMTChunk *fmtChunk = 0;
	TDATAChunk *dataChunk = 0;

	while (!is.eof()) {
		string name = "";
		TINT32 length = 0;

		bool ret = TWAVChunk::readHeader(is, name, length);

		if (!ret)
			break;

		// legge solo i chunk che ci interessano, ossia FMT e DATA

		if (name == "fmt ") {
			// legge i dati del chunk FMT
			fmtChunk = new TFMTChunk(length);
			fmtChunk->read(is);

			// considera il byte di pad alla fine del chunk nel caso
			// in cui la lunghezza di questi e' dispari
			if (length & 1) {
				is.seekg((long)is.tellg() + 1);
			}
		} else if (name == "data") {
			// legge i dati del chunk DATA
			dataChunk = new TDATAChunk(length);

			dataChunk->read(is);

			// considera il byte di pad alla fine del chunk nel caso
			// in cui la lunghezza di questi e' dispari
			if (length & 1) {
				is.seekg((long)is.tellg() + 1);
			}
		} else {
			// spostati nello stream di un numero di byte pari a length
			if (length & 1)
				is.seekg((long)is.tellg() + (long)length + 1);
			else
				is.seekg((long)is.tellg() + (long)length);
		}
	}

	TSoundTrackP track = 0;

	if (fmtChunk && dataChunk) {
		TINT32 sampleCount = dataChunk->m_length / fmtChunk->m_bytesPerSample;
		bool signedSample = (fmtChunk->m_bitPerSample != 8);

		track = TSoundTrack::create(
			(int)fmtChunk->m_sampleRate,
			fmtChunk->m_bitPerSample,
			fmtChunk->m_chans,
			sampleCount, signedSample);

		if (track) {
			switch (fmtChunk->m_bitPerSample) {
			case 8:
				memcpy(
					(void *)track->getRawData(),
					(void *)(dataChunk->m_samples),
					sampleCount * fmtChunk->m_bytesPerSample);
				break;
			case 16:
				if (!TNZ_LITTLE_ENDIAN)
					swapAndCopySamples(
						(short *)dataChunk->m_samples,
						(short *)track->getRawData(),
						sampleCount * fmtChunk->m_chans);
				else
					memcpy(
						(void *)track->getRawData(),
						(void *)(dataChunk->m_samples),
						sampleCount * fmtChunk->m_bytesPerSample);
				//#endif
				break;
			case 24:
				if (!TNZ_LITTLE_ENDIAN) {
					UCHAR *begin = (UCHAR *)track->getRawData();
					for (int i = 0; i < (int)(sampleCount * fmtChunk->m_chans); ++i) {
						*(begin + 4 * i) = 0;
						*(begin + 4 * i + 1) =
							*(dataChunk->m_samples + 3 * i + 2);
						*(begin + 4 * i + 2) =
							*(dataChunk->m_samples + 3 * i + 1);
						*(begin + 4 * i + 3) =
							*(dataChunk->m_samples + 3 * i);
					}
				} else {
					UCHAR *begin = (UCHAR *)track->getRawData();
					for (int i = 0; i < (int)(sampleCount * fmtChunk->m_chans); ++i) {
						memcpy(
							(void *)(begin + 4 * i),
							(void *)(dataChunk->m_samples + 3 * i), 3);
						*(begin + 4 * i + 3) = 0;
					}
				}
				//#endif
				break;
			}
		}

		/*if (!TNZ_LITTLE_ENDIAN)
    {
      if (fmtChunk->m_bitPerSample > 8)
      {
        assert(fmtChunk->m_bitPerSample <= 16);
        swapAndCopySamples(
          (short*)dataChunk->m_samples, 
          (short*)track->getRawData(), 
          sampleCount*fmtChunk->m_chans);
      }
      else
        memcpy(
	        (void*)track->getRawData(), 
          (void*)(dataChunk->m_samples), 
          sampleCount*fmtChunk->m_bytesPerSample);
    }
    else
      memcpy(
        (void*)track->getRawData(), 
        (void*)(dataChunk->m_samples), 
        sampleCount*fmtChunk->m_bytesPerSample);*/
	}

	if (fmtChunk)
		delete fmtChunk;
	if (dataChunk)
		delete dataChunk;

	return track;
}

//==============================================================================

TSoundTrackWriterWav::TSoundTrackWriterWav(const TFilePath &fp)
	: TSoundTrackWriter(fp)
{
}

//------------------------------------------------------------------------------

bool TSoundTrackWriterWav::save(const TSoundTrackP &sndtrack)
{
	if (!sndtrack)
		throw TException(L"Unable to save the soundtrack: " + m_path.getWideString());

	if (sndtrack->getBitPerSample() == 8 && sndtrack->isSampleSigned())
		throw TException("The format (8 bit signed) is incompatible with WAV file");

	TINT32 soundDataLenght = (TINT32)(sndtrack->getSampleCount() * (sndtrack->getBitPerSample() / 8) * sndtrack->getChannelCount() /*sndtrack->getSampleSize()*/);

	TINT32 RIFFChunkLength = TFMTChunk::LENGTH + TWAVChunk::HDR_LENGTH + soundDataLenght;

	TFileStatus fs(m_path);
	if (fs.doesExist() && !fs.isWritable())
		throw TException(L"Unable to save the soundtrack: " +
						 m_path.getWideString() + L" is read-only");

	Tofstream os(m_path);

	TFMTChunk fmtChunk(16);

	fmtChunk.m_encodingType = 1; // PCM
	fmtChunk.m_chans = sndtrack->getChannelCount();
	fmtChunk.m_sampleRate = sndtrack->getSampleRate();
	fmtChunk.m_avgBytesPerSecond = (sndtrack->getBitPerSample() / 8) * fmtChunk.m_chans * sndtrack->getSampleRate();
	//sndtrack->getSampleSize()*sndtrack->getSampleRate();
	fmtChunk.m_bytesPerSample = (sndtrack->getBitPerSample() / 8) * fmtChunk.m_chans; //sndtrack->getSampleSize();
	fmtChunk.m_bitPerSample = sndtrack->getBitPerSample();

	TDATAChunk dataChunk(soundDataLenght);

	UCHAR *waveData = new UCHAR[soundDataLenght];

	if (!TNZ_LITTLE_ENDIAN)
		RIFFChunkLength = swapTINT32(RIFFChunkLength);

// era if defined(MACOSX)
#if (!TNZ_LITTLE_ENDIAN)
	{
		if (fmtChunk.m_bitPerSample == 8)
			memcpy(
				(void *)waveData,
				(void *)sndtrack->getRawData(),
				soundDataLenght);
		else if (fmtChunk.m_bitPerSample == 16) {
			swapAndCopySamples(
				(short *)sndtrack->getRawData(),
				(short *)waveData,
				sndtrack->getSampleCount() * fmtChunk.m_chans);
		} else if (fmtChunk.m_bitPerSample == 24) { //swap e togliere quarto byte
			UCHAR *begin = (UCHAR *)sndtrack->getRawData();
			for (int i = 0; i < (int)sndtrack->getSampleCount() * fmtChunk.m_chans; ++i) {
				*(waveData + 3 * i) = *(begin + 4 * i + 3);
				*(waveData + 3 * i + 1) = *(begin + 4 * i + 2);
				*(waveData + 3 * i + 2) = *(begin + 4 * i + 1);
			}
		}
	}
#else
	{
		if (fmtChunk.m_bitPerSample != 24)
			memcpy(
				(void *)waveData,
				(void *)sndtrack->getRawData(),
				soundDataLenght);
		else { //togliere quarto byte
			UCHAR *begin = (UCHAR *)sndtrack->getRawData();
			for (int i = 0; i < (int)sndtrack->getSampleCount() * fmtChunk.m_chans; ++i) {
				*(waveData + 3 * i) = *(begin + 4 * i);
				*(waveData + 3 * i + 1) = *(begin + 4 * i + 1);
				*(waveData + 3 * i + 2) = *(begin + 4 * i + 2);
			}
		}
	}
#endif
	dataChunk.m_samples = waveData;

	os.write("RIFF", 4);
	os.write((char *)&RIFFChunkLength, sizeof(TINT32));
	os.write("WAVE", 4);
	fmtChunk.write(os);
	dataChunk.write(os);

	return true;
}