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CLK/Components/SN76489/SN76489.cpp

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//
// SN76489.cpp
// Clock Signal
//
// Created by Thomas Harte on 26/02/2018.
// Copyright 2018 Thomas Harte. All rights reserved.
//
#include "SN76489.hpp"
#include <cassert>
#include <cmath>
using namespace TI;
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SN76489::SN76489(Personality personality, Concurrency::AsyncTaskQueue<false> &task_queue, int additional_divider) : task_queue_(task_queue) {
set_sample_volume_range(0);
switch(personality) {
case Personality::SN76494:
master_divider_period_ = 2;
shifter_is_16bit_ = false;
break;
case Personality::SN76489:
master_divider_period_ = 16;
shifter_is_16bit_ = false;
break;
case Personality::SMS:
master_divider_period_ = 16;
shifter_is_16bit_ = true;
break;
}
assert((master_divider_period_ % additional_divider) == 0);
assert(additional_divider < master_divider_period_);
master_divider_period_ /= additional_divider;
}
void SN76489::set_sample_volume_range(std::int16_t range) {
// Build a volume table.
double multiplier = pow(10.0, -0.1);
double volume = float(range) / 4.0f; // As there are four channels.
for(int c = 0; c < 16; ++c) {
volumes_[c] = int(round(volume));
volume *= multiplier;
}
volumes_[15] = 0;
evaluate_output_volume();
}
void SN76489::write(uint8_t value) {
task_queue_.enqueue([value, this] () {
if(value & 0x80) {
active_register_ = value;
}
const int channel = (active_register_ >> 5)&3;
if(active_register_ & 0x10) {
// latch for volume
channels_[channel].volume = value & 0xf;
evaluate_output_volume();
} else {
// latch for tone/data
if(channel < 3) {
if(value & 0x80) {
channels_[channel].divider = (channels_[channel].divider & ~0xf) | (value & 0xf);
} else {
channels_[channel].divider = uint16_t((channels_[channel].divider & 0xf) | ((value & 0x3f) << 4));
}
} else {
// writes to the noise register always reset the shifter
noise_shifter_ = shifter_is_16bit_ ? 0x8000 : 0x4000;
if(value & 4) {
noise_mode_ = shifter_is_16bit_ ? Noise16 : Noise15;
} else {
noise_mode_ = shifter_is_16bit_ ? Periodic16 : Periodic15;
}
channels_[3].divider = uint16_t(0x10 << (value & 3));
// Special case: if these bits are both set, the noise channel should track channel 2,
// which is marked with a divider of 0xffff.
if(channels_[3].divider == 0x80) channels_[3].divider = 0xffff;
}
}
});
}
bool SN76489::is_zero_level() const {
return channels_[0].volume == 0xf && channels_[1].volume == 0xf && channels_[2].volume == 0xf && channels_[3].volume == 0xf;
}
void SN76489::evaluate_output_volume() {
output_volume_ = int16_t(
channels_[0].level * volumes_[channels_[0].volume] +
channels_[1].level * volumes_[channels_[1].volume] +
channels_[2].level * volumes_[channels_[2].volume] +
channels_[3].level * volumes_[channels_[3].volume]
);
}
void SN76489::get_samples(std::size_t number_of_samples, std::int16_t *target) {
std::size_t c = 0;
while((master_divider_& (master_divider_period_ - 1)) && c < number_of_samples) {
target[c] = output_volume_;
master_divider_++;
c++;
}
while(c < number_of_samples) {
bool did_flip = false;
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#define step_channel(x, s) \
if(channels_[x].counter) channels_[x].counter--;\
else {\
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channels_[x].level ^= 1;\
channels_[x].counter = channels_[x].divider;\
s;\
}
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step_channel(0, /**/);
step_channel(1, /**/);
step_channel(2, did_flip = true);
#undef step_channel
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if(channels_[3].divider != 0xffff) {
if(channels_[3].counter) channels_[3].counter--;
else {
did_flip = true;
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channels_[3].counter = channels_[3].divider;
}
}
if(did_flip) {
channels_[3].level = noise_shifter_ & 1;
int new_bit = channels_[3].level;
switch(noise_mode_) {
default: break;
case Noise15:
new_bit ^= (noise_shifter_ >> 1);
break;
case Noise16:
new_bit ^= (noise_shifter_ >> 3);
break;
}
noise_shifter_ >>= 1;
noise_shifter_ |= (new_bit & 1) << (shifter_is_16bit_ ? 15 : 14);
}
evaluate_output_volume();
for(int ic = 0; ic < master_divider_period_ && c < number_of_samples; ++ic) {
target[c] = output_volume_;
c++;
master_divider_++;
}
}
master_divider_ &= (master_divider_period_ - 1);
}