z80/ay-3-8912.cpp

#include "ay-3-8912.h"
#include "z80.h"
#include <SDL2/SDL.h>
#include "zx_ula.h"

#define MIXER_REG_A_TONE    0x01
#define MIXER_REG_B_TONE    0x02
#define MIXER_REG_C_TONE    0x04
#define MIXER_REG_A_NOISE   0x08
#define MIXER_REG_B_NOISE   0x10
#define MIXER_REG_C_NOISE   0x20
#define MIXER_REG_PORT_A    0x40
#define MIXER_REG_PORT_B    0x80

#define ENVELOPE_HOLD       0x01
#define ENVELOPE_ALTERNATE  0x02
#define ENVELOPE_ATTACK     0x04
#define ENVELOPE_CONTINUE   0x08

namespace audio
{
    #define SAMPLING_FREQ 44100
    #define AUDIO_BUFFER_SIZE 2048
    float cycles_per_sample;

    uint8_t volume_table[16] {0,2,3,4,6,8,11,16,23,32,45,64,90,128,180,255};
    SDL_AudioDeviceID sdlAudioDevice;

    uint8_t selected_register {0};
    uint8_t registers[16];

    uint16_t channel_a_tone_freq;
    uint16_t channel_a_tone_freq_counter;
    uint16_t channel_a_tone_level;
    uint16_t channel_a_level;
    uint16_t channel_b_tone_freq;
    uint16_t channel_b_tone_freq_counter;
    uint16_t channel_b_tone_level;
    uint16_t channel_b_level;
    uint16_t channel_c_tone_freq;
    uint16_t channel_c_tone_freq_counter;
    uint16_t channel_c_tone_level;
    uint16_t channel_c_level;

    uint8_t noise_freq;
    uint8_t noise_freq_counter;
    uint8_t noise_level;
    uint32_t shiftreg;

    uint16_t envelope_freq;
    uint16_t envelope_freq_counter;
    int8_t envelope_volume;
    int8_t envelope_direction;

    void select_register(int port, int val)
    {
        selected_register = val & 0xf;
    }

    int read_register(int port)
    {
        return registers[selected_register];
    }

    void write_register(int port, int val)
    {
        registers[selected_register] = val;
        uint32_t clock = (z80::getClock() >> 5);

        switch (selected_register) {
            case 0:
            case 1: {
                uint16_t freq = registers[0] | ((registers[1] & 0xf) << 8);
                channel_a_tone_freq = clock / freq==0?1:freq;
                channel_a_tone_freq_counter = 0;
                break;
            }
            case 2:
            case 3: {
                uint16_t freq = registers[2] | ((registers[3] & 0xf) << 8);
                channel_b_tone_freq = clock / freq==0?1:freq;
                channel_b_tone_freq_counter = 0;
                break;
            }
            case 4:
            case 5: {
                uint16_t freq = registers[4] | ((registers[5] & 0xf) << 8);
                channel_c_tone_freq = clock / freq==0?1:freq;
                channel_c_tone_freq_counter = 0;
                break;
            }
            case 6: {
                uint8_t freq = (registers[6] & 0x1f);
                noise_freq = clock / freq==0?1:freq;
                noise_freq_counter = 0;
                break;
            }
            case 11:
            case 12: {
                uint16_t freq = registers[11] | (registers[12] << 8);
                envelope_freq = clock / freq==0?1:freq;
                break;
            }
            case 13:
                if (registers[13]&ENVELOPE_ATTACK) {
                    envelope_volume = 0;
                    envelope_direction = 1;
                } else {
                    envelope_volume = 15;
                    envelope_direction = -1;
                }
        }
    }

    void init()
    {
        reset();
        z80::connect_port(0xfffd, 0xffff, audio::read_register, audio::select_register);
        z80::connect_port(0xbffd, 0xffff, nullptr, audio::write_register);
    }

    void reset()
    {
        selected_register = 0;
        for (int i=0; i<16;++i) registers[i]=0;
    }

    void update(uint32_t dt)
    {
        dt = dt >> 1;

        // Oscillate (0-1) channel A tone level given its frequency
        channel_a_tone_freq_counter+=dt;
        if (channel_a_tone_freq_counter >= channel_a_tone_freq) {
            channel_a_tone_freq_counter -= channel_a_tone_freq;
            channel_a_tone_level = channel_a_tone_level ^ 1;
        }

        // Oscillate (0-1) channel B tone level given its frequency
        channel_b_tone_freq_counter+=dt;
        if (channel_b_tone_freq_counter >= channel_b_tone_freq) {
            channel_b_tone_freq_counter -= channel_b_tone_freq;
            channel_b_tone_level = channel_b_tone_level ^ 1;
        }

        // Oscillate (0-1) channel C tone level given its frequency
        channel_c_tone_freq_counter+=dt;
        if (channel_c_tone_freq_counter >= channel_c_tone_freq) {
            channel_c_tone_freq_counter -= channel_c_tone_freq;
            channel_c_tone_level = channel_c_tone_level ^ 1;
        }

        // Oscillate (0-1) noise level given its frequency and shift register
        noise_freq_counter+=dt;
        if (noise_freq_counter >= noise_freq) {
            noise_freq_counter -= noise_freq;
            noise_level = noise_level ^ shiftreg;
            uint32_t newbit = shiftreg ^ (shiftreg >> 3);
            shiftreg = ((shiftreg >> 1) & 0xff) | ((newbit << 16) & 0x100);
        }

        // Develop (0-15) envelope volume given its frequency and shape
        envelope_freq_counter+=dt;
        if (envelope_freq_counter >= envelope_freq) {
            envelope_freq_counter -= envelope_freq;
            
            envelope_volume += envelope_direction;
            if ( (envelope_volume > 15) || (envelope_volume < 0) ) {
                switch(registers[13]&0xf) {
                    case 8:
                    case 12:
                        envelope_volume &= 0x0f;
                        break;
                    case 10:
                    case 14:
                        envelope_direction = -envelope_direction;
                        envelope_volume += envelope_direction;
                    case 11:
                    case 13:
                        envelope_direction = 0;
                        envelope_volume = 15;
                    default:
                        envelope_direction = 0;
                        envelope_volume = 0;
                }
            }
        }
    }

    uint8_t get_sample()
    {
        // Mix tone and noise on channel A given register 7 values
        channel_a_level = 1;
        if (registers[7] & MIXER_REG_A_TONE) channel_a_level &= channel_a_tone_level;
        if (registers[7] & MIXER_REG_A_NOISE) channel_a_level &= noise_level;

        // Mix tone and noise on channel B given register 7 values
        channel_b_level = 1;
        if (registers[7] & MIXER_REG_B_TONE) channel_b_level &= channel_b_tone_level;
        if (registers[7] & MIXER_REG_B_NOISE) channel_b_level &= noise_level;

        // Mix tone and noise on channel C given register 7 values
        channel_c_level = 1;
        if (registers[7] & MIXER_REG_C_TONE) channel_c_level &= channel_c_tone_level;
        if (registers[7] & MIXER_REG_C_NOISE) channel_c_level &= noise_level;

        const uint8_t channel_a_volume = (registers[8]&0x10) ? envelope_volume : registers[8]&0xf;
        const uint8_t channel_b_volume = (registers[9]&0x10) ? envelope_volume : registers[9]&0xf;
        const uint8_t channel_c_volume = (registers[10]&0x10) ? envelope_volume : registers[10]&0xf;

        const uint8_t channel_a_sample = volume_table[(channel_a_level&1) * channel_a_volume] >> 1;
        const uint8_t channel_b_sample = volume_table[(channel_b_level&1) * channel_b_volume] >> 1;
        const uint8_t channel_c_sample = volume_table[(channel_c_level&1) * channel_c_volume] >> 1;

        uint8_t sample = (channel_a_sample+channel_b_sample+channel_c_sample)&0xff;
        zx_ula::set_border_color(sample&0xf);
        return sample;
    }

}