#include "LtRtProcessing.hpp"
#include <cmath>
#include <algorithm>

#undef min
#undef max

namespace boo {

template <typename T>
inline T ClampFull(float in) {
  if (std::is_floating_point<T>()) {
    return std::min<T>(std::max<T>(in, -1.f), 1.f);
  } else {
    constexpr T MAX = std::numeric_limits<T>::max();
    constexpr T MIN = std::numeric_limits<T>::min();

    if (in < MIN)
      return MIN;
    else if (in > MAX)
      return MAX;
    else
      return in;
  }
}

#if INTEL_IPP

#ifndef M_PI
#define M_PI 3.14159265358979323846 /* pi */
#endif

#if USE_LPF
constexpr int FirTaps = 27;

FIRFilter12k::FIRFilter12k(int windowFrames, double sampleRate) {
  Ipp64f* taps = ippsMalloc_64f(FirTaps);
  Ipp32f* taps32 = ippsMalloc_32f(FirTaps);
  int sizeSpec, sizeBuf;

  ippsFIRGenGetBufferSize(FirTaps, &sizeBuf);
  m_firBuffer = ippsMalloc_8u(sizeBuf);
  ippsFIRGenLowpass_64f(12000.0 / sampleRate, taps, FirTaps, ippWinBartlett, ippTrue, m_firBuffer);
  ippsConvert_64f32f(taps, taps32, FirTaps);
  ippsFree(taps);
  ippsFree(m_firBuffer);

  m_dlySrc = ippsMalloc_32f(FirTaps);

  ippsFIRSRGetSize(FirTaps, ipp32f, &sizeSpec, &sizeBuf);
  m_firSpec = (IppsFIRSpec_32f*)ippsMalloc_8u(sizeSpec);
  m_firBuffer = ippsMalloc_8u(sizeBuf);
  ippsFIRSRInit_32f(taps32, FirTaps, ippAlgDirect, m_firSpec);
  ippsFree(taps32);

  m_inBuf = ippsMalloc_32f(windowFrames);
}

FIRFilter12k::~FIRFilter12k() {
  ippsFree(m_firSpec);
  ippsFree(m_firBuffer);
  ippsFree(m_dlySrc);
  ippsFree(m_inBuf);
}

void FIRFilter12k::Process(Ipp32f* buf, int windowFrames) {
  ippsZero_32f(m_dlySrc, FirTaps);
  ippsMove_32f(buf, m_inBuf, windowFrames);
  ippsFIRSR_32f(m_inBuf, buf, windowFrames, m_firSpec, m_dlySrc, nullptr, m_firBuffer);
}
#endif

WindowedHilbert::WindowedHilbert(int windowFrames, double sampleRate)
:
#if USE_LPF
    m_fir(windowFrames, sampleRate)
,
#endif
    m_windowFrames(windowFrames)
, m_halfFrames(windowFrames / 2)
, m_inputBuf(ippsMalloc_32f(m_windowFrames * 2 + m_halfFrames))
, m_outputBuf(ippsMalloc_32fc(m_windowFrames * 4))
, m_hammingTable(ippsMalloc_32f(m_halfFrames)) {
  ippsZero_32f(m_inputBuf, m_windowFrames * 2 + m_halfFrames);
  ippsZero_32fc(m_outputBuf, m_windowFrames * 4);
  m_output[0] = m_outputBuf;
  m_output[1] = m_output[0] + m_windowFrames;
  m_output[2] = m_output[1] + m_windowFrames;
  m_output[3] = m_output[2] + m_windowFrames;
  int sizeSpec, sizeBuf;
  ippsHilbertGetSize_32f32fc(m_windowFrames, ippAlgHintFast, &sizeSpec, &sizeBuf);
  m_spec = (IppsHilbertSpec*)ippMalloc(sizeSpec);
  m_buffer = (Ipp8u*)ippMalloc(sizeBuf);
  ippsHilbertInit_32f32fc(m_windowFrames, ippAlgHintFast, m_spec, m_buffer);

  for (int i = 0; i < m_halfFrames; ++i)
    m_hammingTable[i] = Ipp32f(std::cos(M_PI * (i / double(m_halfFrames) + 1.0)) * 0.5 + 0.5);
}

WindowedHilbert::~WindowedHilbert() {
  ippFree(m_spec);
  ippFree(m_buffer);
  ippsFree(m_inputBuf);
  ippsFree(m_outputBuf);
  ippsFree(m_hammingTable);
}

void WindowedHilbert::_AddWindow() {
#if USE_LPF
  Ipp32f* inBufBase = &m_inputBuf[m_windowFrames * m_bufIdx + m_halfFrames];
  m_fir.Process(inBufBase, m_windowFrames);
#endif

  if (m_bufIdx) {
    /* Mirror last half of samples to start of input buffer */
    Ipp32f* bufBase = &m_inputBuf[m_windowFrames * 2];
    ippsCopy_32f(bufBase, m_inputBuf, m_halfFrames);
    ippsHilbert_32f32fc(&m_inputBuf[m_windowFrames], m_output[2], m_spec, m_buffer);
    ippsHilbert_32f32fc(&m_inputBuf[m_windowFrames + m_halfFrames], m_output[3], m_spec, m_buffer);
  } else {
    ippsHilbert_32f32fc(&m_inputBuf[0], m_output[0], m_spec, m_buffer);
    ippsHilbert_32f32fc(&m_inputBuf[m_halfFrames], m_output[1], m_spec, m_buffer);
  }
  m_bufIdx ^= 1;
}

void WindowedHilbert::AddWindow(const float* input, int stride) {
  Ipp32f* bufBase = &m_inputBuf[m_windowFrames * m_bufIdx + m_halfFrames];
  for (int i = 0; i < m_windowFrames; ++i)
    bufBase[i] = input[i * stride];
  _AddWindow();
}

void WindowedHilbert::AddWindow(const int32_t* input, int stride) {
  Ipp32f* bufBase = &m_inputBuf[m_windowFrames * m_bufIdx + m_halfFrames];
  for (int i = 0; i < m_windowFrames; ++i)
    bufBase[i] = input[i * stride] / (float(INT32_MAX) + 1.f);
  _AddWindow();
}

void WindowedHilbert::AddWindow(const int16_t* input, int stride) {
  Ipp32f* bufBase = &m_inputBuf[m_windowFrames * m_bufIdx + m_halfFrames];
  for (int i = 0; i < m_windowFrames; ++i)
    bufBase[i] = input[i * stride] / (float(INT16_MAX) + 1.f);
  _AddWindow();
}

template <typename T>
void WindowedHilbert::Output(T* output, float lCoef, float rCoef) const {
  int first, middle, last;
  if (m_bufIdx) {
    first = 3;
    middle = 0;
    last = 1;
  } else {
    first = 1;
    middle = 2;
    last = 3;
  }

#if 0
    for (int i=0 ; i<m_windowFrames ; ++i)
    {
        float tmp = m_output[middle][i].im;
        output[i*2] = ClampFull<T>(output[i*2] + tmp * lCoef);
        output[i*2+1] = ClampFull<T>(output[i*2+1] + tmp * rCoef);
    }
    return;
#endif

  int i, t;
  for (i = 0, t = 0; i < m_halfFrames; ++i, ++t) {
    float tmp =
        m_output[first][m_halfFrames + i].im * (1.f - m_hammingTable[t]) + m_output[middle][i].im * m_hammingTable[t];
    output[i * 2] = ClampFull<T>(output[i * 2] + tmp * lCoef);
    output[i * 2 + 1] = ClampFull<T>(output[i * 2 + 1] + tmp * rCoef);
  }
  for (; i < m_windowFrames - m_halfFrames; ++i) {
    float tmp = m_output[middle][i].im;
    output[i * 2] = ClampFull<T>(output[i * 2] + tmp * lCoef);
    output[i * 2 + 1] = ClampFull<T>(output[i * 2 + 1] + tmp * rCoef);
  }
  for (t = 0; i < m_windowFrames; ++i, ++t) {
    float tmp = m_output[middle][i].im * (1.f - m_hammingTable[t]) + m_output[last][t].im * m_hammingTable[t];
    output[i * 2] = ClampFull<T>(output[i * 2] + tmp * lCoef);
    output[i * 2 + 1] = ClampFull<T>(output[i * 2 + 1] + tmp * rCoef);
  }
}

template void WindowedHilbert::Output<int16_t>(int16_t* output, float lCoef, float rCoef) const;
template void WindowedHilbert::Output<int32_t>(int32_t* output, float lCoef, float rCoef) const;
template void WindowedHilbert::Output<float>(float* output, float lCoef, float rCoef) const;

#endif

template <>
int16_t* LtRtProcessing::_getInBuf<int16_t>() {
  return m_16Buffer.get();
}
template <>
int32_t* LtRtProcessing::_getInBuf<int32_t>() {
  return m_32Buffer.get();
}
template <>
float* LtRtProcessing::_getInBuf<float>() {
  return m_fltBuffer.get();
}

template <>
int16_t* LtRtProcessing::_getOutBuf<int16_t>() {
  return m_16Buffer.get() + m_outputOffset;
}
template <>
int32_t* LtRtProcessing::_getOutBuf<int32_t>() {
  return m_32Buffer.get() + m_outputOffset;
}
template <>
float* LtRtProcessing::_getOutBuf<float>() {
  return m_fltBuffer.get() + m_outputOffset;
}

LtRtProcessing::LtRtProcessing(int _5msFrames, const AudioVoiceEngineMixInfo& mixInfo)
: m_inMixInfo(mixInfo)
, m_windowFrames(_5msFrames * 4)
, m_halfFrames(m_windowFrames / 2)
, m_outputOffset(m_windowFrames * 5 * 2)
#if INTEL_IPP
, m_hilbertSL(m_windowFrames, mixInfo.m_sampleRate)
, m_hilbertSR(m_windowFrames, mixInfo.m_sampleRate)
#endif
{
  m_inMixInfo.m_channels = AudioChannelSet::Surround51;
  m_inMixInfo.m_channelMap.m_channelCount = 5;
  m_inMixInfo.m_channelMap.m_channels[0] = AudioChannel::FrontLeft;
  m_inMixInfo.m_channelMap.m_channels[1] = AudioChannel::FrontRight;
  m_inMixInfo.m_channelMap.m_channels[2] = AudioChannel::FrontCenter;
  m_inMixInfo.m_channelMap.m_channels[3] = AudioChannel::RearLeft;
  m_inMixInfo.m_channelMap.m_channels[4] = AudioChannel::RearRight;

  int samples = m_windowFrames * (5 * 2 + 2 * 2);
  switch (mixInfo.m_sampleFormat) {
  case SOXR_INT16_I:
    m_16Buffer.reset(new int16_t[samples]);
    memset(m_16Buffer.get(), 0, sizeof(int16_t) * samples);
    break;
  case SOXR_INT32_I:
    m_32Buffer.reset(new int32_t[samples]);
    memset(m_32Buffer.get(), 0, sizeof(int32_t) * samples);
    break;
  case SOXR_FLOAT32_I:
    m_fltBuffer.reset(new float[samples]);
    memset(m_fltBuffer.get(), 0, sizeof(float) * samples);
    break;
  default:
    break;
  }
}

template <typename T>
void LtRtProcessing::Process(const T* input, T* output, int frameCount) {
#if 0
  for (int i=0 ; i<frameCount ; ++i)
  {
    output[i * 2] = input[i * 5 + 3];
    output[i * 2 + 1] = input[i * 5 + 4];
  }
  return;
#endif

  int outFramesRem = frameCount;
  T* inBuf = _getInBuf<T>();
  T* outBuf = _getOutBuf<T>();
  int tail = std::min(m_windowFrames * 2, m_bufferTail + frameCount);
  int samples = (tail - m_bufferTail) * 5;
  memmove(&inBuf[m_bufferTail * 5], input, samples * sizeof(T));
  // fmt::print("input {} to {}\n", tail - m_bufferTail, m_bufferTail);
  input += samples;
  frameCount -= tail - m_bufferTail;

  int head = std::min(m_windowFrames * 2, m_bufferHead + outFramesRem);
  samples = (head - m_bufferHead) * 2;
  memmove(output, outBuf + m_bufferHead * 2, samples * sizeof(T));
  // fmt::print("output {} from {}\n", head - m_bufferHead, m_bufferHead);
  output += samples;
  outFramesRem -= head - m_bufferHead;

  int bufIdx = m_bufferTail / m_windowFrames;
  if (tail / m_windowFrames > bufIdx) {
    T* in = &inBuf[bufIdx * m_windowFrames * 5];
    T* out = &outBuf[bufIdx * m_windowFrames * 2];
#if INTEL_IPP
    m_hilbertSL.AddWindow(in + 3, 5);
    m_hilbertSR.AddWindow(in + 4, 5);
#endif

    // x(:,1) + sqrt(.5)*x(:,3) + sqrt(19/25)*x(:,4) + sqrt(6/25)*x(:,5)
    // x(:,2) + sqrt(.5)*x(:,3) - sqrt(6/25)*x(:,4) - sqrt(19/25)*x(:,5)
    if (bufIdx) {
      int delayI = -m_halfFrames;
      for (int i = 0; i < m_windowFrames; ++i, ++delayI) {
        out[i * 2] = ClampFull<T>(in[delayI * 5] + 0.7071068f * in[delayI * 5 + 2]);
        out[i * 2 + 1] = ClampFull<T>(in[delayI * 5 + 1] + 0.7071068f * in[delayI * 5 + 2]);
        // fmt::print("in {} out {}\n", bufIdx * m_5msFrames + delayI, bufIdx * m_5msFrames + i);
      }
    } else {
      int delayI = m_windowFrames * 2 - m_halfFrames;
      int i;
      for (i = 0; i < m_halfFrames; ++i, ++delayI) {
        out[i * 2] = ClampFull<T>(in[delayI * 5] + 0.7071068f * in[delayI * 5 + 2]);
        out[i * 2 + 1] = ClampFull<T>(in[delayI * 5 + 1] + 0.7071068f * in[delayI * 5 + 2]);
        // fmt::print("in {} out {}\n", bufIdx * m_5msFrames + delayI, bufIdx * m_5msFrames + i);
      }
      delayI = 0;
      for (; i < m_windowFrames; ++i, ++delayI) {
        out[i * 2] = ClampFull<T>(in[delayI * 5] + 0.7071068f * in[delayI * 5 + 2]);
        out[i * 2 + 1] = ClampFull<T>(in[delayI * 5 + 1] + 0.7071068f * in[delayI * 5 + 2]);
        // fmt::print("in {} out {}\n", bufIdx * m_5msFrames + delayI, bufIdx * m_5msFrames + i);
      }
    }
#if INTEL_IPP
    m_hilbertSL.Output(out, 0.8717798f, 0.4898979f);
    m_hilbertSR.Output(out, -0.4898979f, -0.8717798f);
#endif
  }
  m_bufferTail = (tail == m_windowFrames * 2) ? 0 : tail;
  m_bufferHead = (head == m_windowFrames * 2) ? 0 : head;

  if (frameCount) {
    samples = frameCount * 5;
    memmove(inBuf, input, samples * sizeof(T));
    // fmt::print("input {} to {}\n", frameCount, 0);
    m_bufferTail = frameCount;
  }

  if (outFramesRem) {
    samples = outFramesRem * 2;
    memmove(output, outBuf, samples * sizeof(T));
    // fmt::print("output {} from {}\n", outFramesRem, 0);
    m_bufferHead = outFramesRem;
  }
}

template void LtRtProcessing::Process<int16_t>(const int16_t* input, int16_t* output, int frameCount);
template void LtRtProcessing::Process<int32_t>(const int32_t* input, int32_t* output, int frameCount);
template void LtRtProcessing::Process<float>(const float* input, float* output, int frameCount);

} // namespace boo