furnace/extern/NSFplay/nes_apu.cpp

//
// NES 2A03
//
#include <assert.h>
#include "nes_apu.h"

namespace xgm
{
  void NES_APU::sweep_sqr (int i)
  {
      int shifted = freq[i] >> sweep_amount[i];
      if (i == 0 && sweep_mode[i]) shifted += 1;
      sfreq[i] = freq[i] + (sweep_mode[i] ? -shifted : shifted);
      //DEBUG_OUT("shifted[%d] = %d (%d >> %d)\n",i,shifted,freq[i],sweep_amount[i]);
  }

  void NES_APU::FrameSequence(int s)
  {
    //DEBUG_OUT("FrameSequence(%d)\n",s);

    if (s > 3) return; // no operation in step 4

    // 240hz clock
    for (int i=0; i < 2; ++i)
    {
        bool divider = false;
        if (envelope_write[i])
        {
            envelope_write[i] = false;
            envelope_counter[i] = 15;
            envelope_div[i] = 0;
        }
        else
        {
            ++envelope_div[i];
            if (envelope_div[i] > envelope_div_period[i])
            {
                divider = true;
                envelope_div[i] = 0;
            }
        }
        if (divider)
        {
            if (envelope_loop[i] && envelope_counter[i] == 0)
                envelope_counter[i] = 15;
            else if (envelope_counter[i] > 0)
                --envelope_counter[i];
        }
    }

    // 120hz clock
    if ((s&1) == 0)
    for (int i=0; i < 2; ++i)
    {
        if (!envelope_loop[i] && (length_counter[i] > 0))
            --length_counter[i];

        if (sweep_enable[i])
        {
            //DEBUG_OUT("Clock sweep: %d\n", i);

            --sweep_div[i];
            if (sweep_div[i] <= 0)
            {
                sweep_sqr(i); // calculate new sweep target

                //DEBUG_OUT("sweep_div[%d] (0/%d)\n",i,sweep_div_period[i]);
                //DEBUG_OUT("freq[%d]=%d > sfreq[%d]=%d\n",i,freq[i],i,sfreq[i]);

                if (freq[i] >= 8 && sfreq[i] < 0x800 && sweep_amount[i] > 0) // update frequency if appropriate
                {
                    freq[i] = sfreq[i] < 0 ? 0 : sfreq[i];
                }
                sweep_div[i] = sweep_div_period[i] + 1;

                //DEBUG_OUT("freq[%d]=%d\n",i,freq[i]);
            }

            if (sweep_write[i])
            {
                sweep_div[i] = sweep_div_period[i] + 1;
                sweep_write[i] = false;
            }
        }
    }

  }

  INT32 NES_APU::calc_sqr (int i, UINT32 clocks)
  {
    static const INT16 sqrtbl[4][16] = {
      {0, 0, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0},
      {0, 0, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0},
      {0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0},
      {1, 1, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1}
    };

    scounter[i] -= clocks;
    while (scounter[i] < 0)
    {
        sphase[i] = (sphase[i] + 1) & 15;
        scounter[i] += freq[i] + 1;
    }

    INT32 ret = 0;
    if (length_counter[i] > 0 &&
        freq[i] >= 8 &&
        sfreq[i] < 0x800
        )
    {
        int v = envelope_disable[i] ? volume[i] : envelope_counter[i];
        ret = sqrtbl[duty[i]][sphase[i]] ? v : 0;
    }
    
    return ret;
  }

  bool NES_APU::Read (UINT32 adr, UINT32 & val, UINT32 id)
  {
    if (0x4000 <= adr && adr < 0x4008)
    {
      val |= reg[adr&0x7];
      return true;
    }
    else if(adr==0x4015)
    {
      val |= (length_counter[1]?2:0)|(length_counter[0]?1:0);
      return true;
    }
    else
      return false;
  }

  void NES_APU::Tick (UINT32 clocks)
  {
    out[0] = calc_sqr(0, clocks);
    out[1] = calc_sqr(1, clocks);
  }

  // <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>g<EFBFBD>`<60>̐U<CC90><55><EFBFBD><EFBFBD>0-8191
  UINT32 NES_APU::Render (INT32 b[2])
  {
    out[0] = (mask & 1) ? 0 : out[0];
    out[1] = (mask & 2) ? 0 : out[1];

    INT32 m[2];

    if(option[OPT_NONLINEAR_MIXER])
    {
        INT32 voltage = square_table[out[0] + out[1]];
        m[0] = out[0] << 6;
        m[1] = out[1] << 6;
        INT32 ref = m[0] + m[1];
        if (ref > 0)
        {
            m[0] = (m[0] * voltage) / ref;
            m[1] = (m[1] * voltage) / ref;
        }
        else
        {
            m[0] = voltage;
            m[1] = voltage;
        }
    }
    else
    {
        m[0] = (out[0] * square_linear) / 15;
        m[1] = (out[1] * square_linear) / 15;
    }

    b[0]  = m[0] * sm[0][0];
    b[0] += m[1] * sm[0][1];
    b[0] >>= 7;

    b[1]  = m[0] * sm[1][0];
    b[1] += m[1] * sm[1][1];
    b[1] >>= 7;

    return 2;
  }

  NES_APU::NES_APU ()
  {
    SetClock (DEFAULT_CLOCK);
    SetRate (DEFAULT_RATE);
    option[OPT_UNMUTE_ON_RESET] = true;
    option[OPT_PHASE_REFRESH] = true;
    option[OPT_NONLINEAR_MIXER] = true;
    option[OPT_DUTY_SWAP] = false;
    option[OPT_NEGATE_SWEEP_INIT] = false;

    square_table[0] = 0;
    for(int i=1;i<32;i++) 
        square_table[i]=(INT32)((8192.0*95.88)/(8128.0/i+100));

    square_linear = square_table[15]; // match linear scale to one full volume square of nonlinear

    for(int c=0;c<2;++c)
        for(int t=0;t<2;++t)
            sm[c][t] = 128;
  }

  NES_APU::~NES_APU ()
  {
  }

  void NES_APU::Reset ()
  {
    int i;
    gclock = 0;
    mask = 0;

    for (int i=0; i<2; ++i)
    {
        scounter[i] = 0;
        sphase[i] = 0;
        duty[i] = 0;
        volume[i] = 0;
        freq[i] = 0;
        sfreq[i] = 0;
        sweep_enable[i] = 0;
        sweep_mode[i] = 0;
        sweep_write[i] = 0;
        sweep_div_period[i] = 0;
        sweep_div[i] = 1;
        sweep_amount[i] = 0;
        envelope_disable[i] = 0;
        envelope_loop[i] = 0;
        envelope_write[i] = 0;
        envelope_div_period[i] = 0;
        envelope_div[0] = 0;
        envelope_counter[i] = 0;
        length_counter[i] = 0;
        enable[i] = 0;
    }

    for (i = 0x4000; i < 0x4008; i++)
      Write (i, 0);

    Write (0x4015, 0);
    if (option[OPT_UNMUTE_ON_RESET])
      Write (0x4015, 0x0f);
    if (option[OPT_NEGATE_SWEEP_INIT])
    {
      Write (0x4001, 0x08);
      Write (0x4005, 0x08);
    }

    for (i = 0; i < 2; i++)
      out[i] = 0;

    SetRate(rate);
  }

  void NES_APU::SetOption (int id, int val)
  {
    if(id<OPT_END) option[id] = val;
  }

  void NES_APU::SetClock (double c)
  {
    clock = c;
  }

  void NES_APU::SetRate (double r)
  {
    rate = r ? r : DEFAULT_RATE;
  }

  void NES_APU::SetStereoMix(int trk, xgm::INT16 mixl, xgm::INT16 mixr)
  {
      if (trk < 0) return;
      if (trk > 1) return;
      sm[0][trk] = mixl;
      sm[1][trk] = mixr;
  }

  ITrackInfo *NES_APU::GetTrackInfo(int trk)
  {
    trkinfo[trk]._freq = freq[trk];
    if(freq[trk])
      trkinfo[trk].freq = clock/16/(freq[trk] + 1);
    else
      trkinfo[trk].freq = 0;

    trkinfo[trk].output = out[trk];
    trkinfo[trk].volume = volume[trk]+(envelope_disable[trk]?0:0x10)+(envelope_loop[trk]?0x20:0);
    trkinfo[trk].key =
        enable[trk] &&
        length_counter[trk] > 0 &&
        freq[trk] >= 8 &&
        sfreq[trk] < 0x800 &&
        (envelope_disable[trk] ? volume[trk] : (envelope_counter[trk] > 0));
    trkinfo[trk].tone = duty[trk];
    trkinfo[trk].max_volume = 15;
    return &trkinfo[trk];
  }

  bool NES_APU::Write (UINT32 adr, UINT32 val, UINT32 id)
  {
    int ch;

    static const UINT8 length_table[32] = {
        0x0A, 0xFE,
        0x14, 0x02,
        0x28, 0x04,
        0x50, 0x06,
        0xA0, 0x08,
        0x3C, 0x0A,
        0x0E, 0x0C,
        0x1A, 0x0E,
        0x0C, 0x10,
        0x18, 0x12,
        0x30, 0x14,
        0x60, 0x16,
        0xC0, 0x18,
        0x48, 0x1A,
        0x10, 0x1C,
        0x20, 0x1E
    };

    if (0x4000 <= adr && adr < 0x4008)
    {
      //DEBUG_OUT("$%04X = %02X\n",adr,val);

      adr &= 0xf;
      ch = adr >> 2;
      switch (adr)
      {
      case 0x0:
      case 0x4:
        volume[ch] = val & 15;
        envelope_disable[ch] = (val >> 4) & 1;
        envelope_loop[ch] = (val >> 5) & 1;
        envelope_div_period[ch] = (val & 15);
        duty[ch] = (val >> 6) & 3;
        if (option[OPT_DUTY_SWAP])
        {
            if      (duty[ch] == 1) duty[ch] = 2;
            else if (duty[ch] == 2) duty[ch] = 1;
        }
        break;

      case 0x1:
      case 0x5:
        sweep_enable[ch] = (val >> 7) & 1;
        sweep_div_period[ch] = (((val >> 4) & 7));
        sweep_mode[ch] = (val >> 3) & 1;
        sweep_amount[ch] = val & 7;
        sweep_write[ch] = true;
        sweep_sqr(ch);
        break;

      case 0x2:
      case 0x6:
        freq[ch] = val | (freq[ch] & 0x700) ;
        sweep_sqr(ch);
        break;

      case 0x3: 
      case 0x7:
        freq[ch] = (freq[ch] & 0xFF) | ((val & 0x7) << 8) ;
        if (option[OPT_PHASE_REFRESH])
          sphase[ch] = 0;
        envelope_write[ch] = true;
        if (enable[ch])
        {
          length_counter[ch] = length_table[(val >> 3) & 0x1f];
        }
        sweep_sqr(ch);
        break;

      default:
        return false;
      }
      reg[adr] = val;
      return true;
    }
    else if (adr == 0x4015)
    {
      enable[0] = (val & 1) ? true : false;
      enable[1] = (val & 2) ? true : false;

      if (!enable[0])
          length_counter[0] = 0;
      if (!enable[1])
          length_counter[1] = 0;

      reg[adr-0x4000] = val;
      return true;
    }

    // 4017 is handled in nes_dmc.cpp
    //else if (adr == 0x4017)
    //{
    //}

    return false;
  }
} // namespace xgm;