// // AY-3-8910.cpp // Clock Signal // // Created by Thomas Harte on 14/10/2016. // Copyright © 2016 Thomas Harte. All rights reserved. // #include "AY38910.hpp" using namespace GI; AY38910::AY38910() : _selected_register(0), _tone_counters{0, 0, 0}, _tone_periods{0, 0, 0}, _tone_outputs{0, 0, 0}, _noise_shift_register(0xffff), _noise_period(0), _noise_counter(0), _noise_output(0), _envelope_divider(0), _envelope_period(0), _envelope_position(0), _output_registers{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} { _output_registers[8] = _output_registers[9] = _output_registers[10] = 0; // set up envelope lookup tables for(int c = 0; c < 16; c++) { for(int p = 0; p < 32; p++) { switch(c) { case 0: case 1: case 2: case 3: case 9: _envelope_shapes[c][p] = (p < 16) ? (p^0xf) : 0; _envelope_overflow_masks[c] = 0x1f; break; case 4: case 5: case 6: case 7: case 15: _envelope_shapes[c][p] = (p < 16) ? p : 0; _envelope_overflow_masks[c] = 0x1f; break; case 8: _envelope_shapes[c][p] = (p & 0xf) ^ 0xf; _envelope_overflow_masks[c] = 0x00; break; case 12: _envelope_shapes[c][p] = (p & 0xf); _envelope_overflow_masks[c] = 0x00; break; case 10: _envelope_shapes[c][p] = (p & 0xf) ^ ((p < 16) ? 0xf : 0x0); _envelope_overflow_masks[c] = 0x00; break; case 14: _envelope_shapes[c][p] = (p & 0xf) ^ ((p < 16) ? 0x0 : 0xf); _envelope_overflow_masks[c] = 0x00; break; case 11: _envelope_shapes[c][p] = (p < 16) ? (p^0xf) : 0xf; _envelope_overflow_masks[c] = 0x1f; break; case 13: _envelope_shapes[c][p] = (p < 16) ? p : 0xf; _envelope_overflow_masks[c] = 0x1f; break; } } } // set up volume lookup table float max_volume = 8192; float root_two = sqrtf(2.0f); for(int v = 0; v < 16; v++) { _volumes[v] = (int)(max_volume / powf(root_two, (float)(v ^ 0xf))); } _volumes[0] = 0; } void AY38910::set_clock_rate(double clock_rate) { set_input_rate((float)clock_rate); } void AY38910::get_samples(unsigned int number_of_samples, int16_t *target) { int c = 0; while((_master_divider&15) && c < number_of_samples) { target[c] = _output_volume; _master_divider++; c++; } while(c < number_of_samples) { #define step_channel(c) \ if(_tone_counters[c]) _tone_counters[c]--;\ else\ {\ _tone_outputs[c] ^= 1;\ _tone_counters[c] = _tone_periods[c];\ } // update the tone channels step_channel(0); step_channel(1); step_channel(2); #undef step_channel // ... the noise generator. This recomputes the new bit repeatedly but harmlessly, only shifting // it into the official 17 upon divider underflow. if(_noise_counter) _noise_counter--; else { _noise_counter = _noise_period; _noise_output ^= _noise_shift_register&1; _noise_shift_register |= ((_noise_shift_register ^ (_noise_shift_register >> 3))&1) << 17; _noise_shift_register >>= 1; } // ... and the envelope generator. Table based for pattern lookup, with a 'refill' step — a way of // implementing non-repeating patterns by locking them to table position 0x1f. if(_envelope_divider) _envelope_divider--; else { _envelope_divider = _envelope_period; _envelope_position ++; if(_envelope_position == 32) _envelope_position = _envelope_overflow_masks[_output_registers[13]]; } evaluate_output_volume(); for(int ic = 0; ic < 16 && c < number_of_samples; ic++) { target[c] = _output_volume; c++; _master_divider++; } } } void AY38910::evaluate_output_volume() { int envelope_volume = _envelope_shapes[_output_registers[13]][_envelope_position]; // The output level for a channel is: // 1 if neither tone nor noise is enabled; // 0 if either tone or noise is enabled and its value is low. // (which is implemented here with reverse logic, assuming _channel_output and _noise_output are already inverted) #define level(c, tb, nb) \ (((((_output_registers[7] >> tb)&1)^1) & _tone_outputs[c]) | ((((_output_registers[7] >> nb)&1)^1) & _noise_output)) ^ 1 int channel_levels[3] = { level(0, 0, 3), level(1, 1, 4), level(2, 2, 5), }; #undef level // Channel volume is a simple selection: if the bit at 0x10 is set, use the envelope volume; otherwise use the lower four bits #define channel_volume(c) \ ((_output_registers[c] >> 4)&1) * envelope_volume + (((_output_registers[c] >> 4)&1)^1) * (_output_registers[c]&0xf) int volumes[3] = { channel_volume(8), channel_volume(9), channel_volume(10) }; #undef channel_volume // Mix additively. _output_volume = (int16_t)( _volumes[volumes[0]] * channel_levels[0] + _volumes[volumes[1]] * channel_levels[1] + _volumes[volumes[2]] * channel_levels[2] ); } void AY38910::select_register(uint8_t r) { _selected_register = r & 0xf; } void AY38910::set_register_value(uint8_t value) { _registers[_selected_register] = value; if(_selected_register < 14) { int selected_register = _selected_register; enqueue([=] () { uint8_t masked_value = value; switch(selected_register) { case 0: case 2: case 4: case 1: case 3: case 5: { int channel = selected_register >> 1; if(selected_register & 1) _tone_periods[channel] = (_tone_periods[channel] & 0xff) | (uint16_t)((value&0xf) << 8); else _tone_periods[channel] = (_tone_periods[channel] & ~0xff) | value; _tone_counters[channel] = _tone_periods[channel]; } break; case 6: _noise_period = value & 0x1f; _noise_counter = _noise_period; break; case 11: _envelope_period = (_envelope_period & ~0xff) | value; _envelope_divider = _envelope_period; break; case 12: _envelope_period = (_envelope_period & 0xff) | (int)(value << 8); _envelope_divider = _envelope_period; break; case 13: masked_value &= 0xf; _envelope_position = 0; break; } _output_registers[selected_register] = masked_value; evaluate_output_volume(); }); } } uint8_t AY38910::get_register_value() { return _registers[_selected_register]; } uint8_t AY38910::get_port_output(bool port_b) { return _registers[port_b ? 15 : 14]; } void AY38910::set_data_input(uint8_t r) { _data_input = r; } uint8_t AY38910::get_data_output() { return _data_output; } void AY38910::set_control_lines(ControlLines control_lines) { ControlState new_state; switch((int)control_lines) { default: new_state = Inactive; break; case (int)(BCDIR | BC2 | BC1): case BCDIR: case BC1: new_state = LatchAddress; break; case (int)(BC2 | BC1): new_state = Read; break; case (int)(BCDIR | BC2): new_state = Write; break; } if(new_state != _control_state) { _control_state = new_state; switch(new_state) { default: break; case LatchAddress: select_register(_data_input); break; case Write: set_register_value(_data_input); break; case Read: _data_output = get_register_value(); break; } } }