1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-17 10:06:21 +00:00
CLK/Components/AY38910/AY38910.cpp

423 lines
14 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//
// AY-3-8910.cpp
// Clock Signal
//
// Created by Thomas Harte on 14/10/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include <cmath>
#include "AY38910.hpp"
using namespace GI::AY38910;
// Note on dividers: the real AY has a built-in divider of 8
// prior to applying its tone and noise dividers. But the YM fills the
// same total periods for noise and tone with double-precision envelopes.
// Therefore this class implements a divider of 4 and doubles the tone
// and noise periods. The envelope ticks along at the divide-by-four rate,
// but if this is an AY rather than a YM then its lowest bit is forced to 1,
// matching the YM datasheet's depiction of envelope level 31 as equal to
// programmatic volume 15, envelope level 29 as equal to programmatic 14, etc.
template <bool is_stereo>
AY38910SampleSource<is_stereo>::AY38910SampleSource(Personality personality, Concurrency::AsyncTaskQueue<false> &task_queue) : task_queue_(task_queue) {
// Don't use the low bit of the envelope position if this is an AY.
envelope_position_mask_ |= personality == Personality::AY38910;
// Set up envelope lookup tables; these are based on 32 volume levels as used by the YM2149F.
// The AY38910 will just use only even table entries, and therefore only even volumes.
for(int c = 0; c < 16; c++) {
for(int p = 0; p < 64; p++) {
switch(c) {
case 0: case 1: case 2: case 3: case 9:
/* Envelope: \____ */
envelope_shapes_[c][p] = (p < 32) ? (p^0x1f) : 0;
envelope_overflow_masks_[c] = 0x3f;
break;
case 4: case 5: case 6: case 7: case 15:
/* Envelope: /____ */
envelope_shapes_[c][p] = (p < 32) ? p : 0;
envelope_overflow_masks_[c] = 0x3f;
break;
case 8:
/* Envelope: \\\\\\\\ */
envelope_shapes_[c][p] = (p & 0x1f) ^ 0x1f;
envelope_overflow_masks_[c] = 0x00;
break;
case 12:
/* Envelope: //////// */
envelope_shapes_[c][p] = (p & 0x1f);
envelope_overflow_masks_[c] = 0x00;
break;
case 10:
/* Envelope: \/\/\/\/ */
envelope_shapes_[c][p] = (p & 0x1f) ^ ((p < 32) ? 0x1f : 0x0);
envelope_overflow_masks_[c] = 0x00;
break;
case 14:
/* Envelope: /\/\/\/\ */
envelope_shapes_[c][p] = (p & 0x1f) ^ ((p < 32) ? 0x0 : 0x1f);
envelope_overflow_masks_[c] = 0x00;
break;
case 11:
/* Envelope: \------ (if - is high) */
envelope_shapes_[c][p] = (p < 32) ? (p^0x1f) : 0x1f;
envelope_overflow_masks_[c] = 0x3f;
break;
case 13:
/* Envelope: /------- */
envelope_shapes_[c][p] = (p < 32) ? p : 0x1f;
envelope_overflow_masks_[c] = 0x3f;
break;
}
}
}
set_sample_volume_range(0);
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_sample_volume_range(std::int16_t range) {
// Set up volume lookup table; the function below is based on a combination of the graph
// from the YM's datasheet, showing a clear power curve, and fitting that to observed
// values reported elsewhere.
const float max_volume = float(range) / 3.0f; // As there are three channels.
constexpr float root_two = 1.414213562373095f;
for(int v = 0; v < 32; v++) {
volumes_[v] = int(max_volume / powf(root_two, float(v ^ 0x1f) / 3.18f));
}
// Tie level 0 to silence.
for(int v = 31; v >= 0; --v) {
volumes_[v] -= volumes_[0];
}
evaluate_output_volume();
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_output_mixing(float a_left, float b_left, float c_left, float a_right, float b_right, float c_right) {
a_left_ = uint8_t(a_left * 255.0f);
b_left_ = uint8_t(b_left * 255.0f);
c_left_ = uint8_t(c_left * 255.0f);
a_right_ = uint8_t(a_right * 255.0f);
b_right_ = uint8_t(b_right * 255.0f);
c_right_ = uint8_t(c_right * 255.0f);
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::advance() {
const auto step_channel = [&](int c) {
if(tone_counters_[c]) --tone_counters_[c];
else {
tone_outputs_[c] ^= 1;
tone_counters_[c] = tone_periods_[c] << 1;
}
};
// Update the tone channels.
step_channel(0);
step_channel(1);
step_channel(2);
// Update 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_ << 1; // To cover the double resolution of envelopes.
noise_output_ ^= noise_shift_register_&1;
noise_shift_register_ |= ((noise_shift_register_ ^ (noise_shift_register_ >> 3))&1) << 17;
noise_shift_register_ >>= 1;
}
// Update the envelope generator. Table based for pattern lookup, with a 'refill' step: a way of
// implementing non-repeating patterns by locking them to the final table position.
if(envelope_divider_) --envelope_divider_;
else {
envelope_divider_ = envelope_period_ << 1;
++envelope_position_;
if(envelope_position_ == 64) envelope_position_ = envelope_overflow_masks_[output_registers_[13]];
}
evaluate_output_volume();
}
template <bool is_stereo>
typename Outputs::Speaker::SampleT<is_stereo>::type AY38910SampleSource<is_stereo>::level() const {
return output_volume_;
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::evaluate_output_volume() {
int envelope_volume = envelope_shapes_[output_registers_[13]][envelope_position_ | envelope_position_mask_];
// 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.
// The tone/noise enable bits use inverse logic; 0 = on, 1 = off; permitting the OR logic below.
#define tone_level(c, tone_bit) (tone_outputs_[c] | (output_registers_[7] >> tone_bit))
#define noise_level(c, noise_bit) (noise_output_ | (output_registers_[7] >> noise_bit))
#define level(c, tone_bit, noise_bit) tone_level(c, tone_bit) & noise_level(c, noise_bit) & 1
const int channel_levels[3] = {
level(0, 0, 3),
level(1, 1, 4),
level(2, 2, 5),
};
#undef level
// This remapping table seeks to map 'channel volumes', i.e. the levels produced from the
// 16-step progammatic volumes set per channel to 'envelope volumes', i.e. the 32-step
// volumes that are produced by the envelope generators (on a YM at least). My reading of
// the data sheet is that '0' is still off, but 15 should be as loud as peak envelope. So
// I've thrown in the discontinuity at the low end, where it'll be very quiet.
const int channel_volumes[] = {
0, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, 31
};
static_assert(sizeof(channel_volumes) == 16*sizeof(int));
// Channel volume is a simple selection: if the bit at 0x10 is set, use the envelope volume; otherwise use the lower four bits,
// mapped to the range 131 in case this is a YM.
#define channel_volume(c) \
((output_registers_[c] >> 4)&1) * envelope_volume + (((output_registers_[c] >> 4)&1)^1) * channel_volumes[output_registers_[c]&0xf]
const int volumes[3] = {
channel_volume(8),
channel_volume(9),
channel_volume(10)
};
#undef channel_volume
// Mix additively, weighting if in stereo.
if constexpr (is_stereo) {
output_volume_.left = int16_t((
volumes_[volumes[0]] * channel_levels[0] * a_left_ +
volumes_[volumes[1]] * channel_levels[1] * b_left_ +
volumes_[volumes[2]] * channel_levels[2] * c_left_
) >> 8);
output_volume_.right = int16_t((
volumes_[volumes[0]] * channel_levels[0] * a_right_ +
volumes_[volumes[1]] * channel_levels[1] * b_right_ +
volumes_[volumes[2]] * channel_levels[2] * c_right_
) >> 8);
} else {
output_volume_ = int16_t(
volumes_[volumes[0]] * channel_levels[0] +
volumes_[volumes[1]] * channel_levels[1] +
volumes_[volumes[2]] * channel_levels[2]
);
}
}
template <bool is_stereo>
bool AY38910SampleSource<is_stereo>::is_zero_level() const {
// Confirm that the AY is trivially at the zero level if all three volume controls are set to fixed zero.
return output_registers_[0x8] == 0 && output_registers_[0x9] == 0 && output_registers_[0xa] == 0;
}
// MARK: - Register manipulation
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::select_register(uint8_t r) {
selected_register_ = r;
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_register_value(uint8_t value) {
// There are only 16 registers.
if(selected_register_ > 15) return;
// If this is a register that affects audio output, enqueue a mutation onto the
// audio generation thread.
if(selected_register_ < 14) {
task_queue_.enqueue([this, selected_register = selected_register_, value] () {
// Perform any register-specific mutation to output generation.
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;
}
break;
case 6:
noise_period_ = value & 0x1f;
break;
case 11:
envelope_period_ = (envelope_period_ & ~0xff) | value;
break;
case 12:
envelope_period_ = (envelope_period_ & 0xff) | int(value << 8);
break;
case 13:
masked_value &= 0xf;
envelope_position_ = 0;
break;
}
// Store a copy of the current register within the storage used by the audio generation
// thread, and apply any changes to output volume.
output_registers_[selected_register] = masked_value;
evaluate_output_volume();
});
}
// Decide which outputs are going to need updating (if any).
bool update_port_a = false;
bool update_port_b = true;
if(port_handler_) {
if(selected_register_ == 7) {
const uint8_t io_change = registers_[7] ^ value;
update_port_b = !!(io_change&0x80);
update_port_a = !!(io_change&0x40);
} else {
update_port_b = selected_register_ == 15;
update_port_a = selected_register_ != 15;
}
}
// Keep a copy of the new value that is usable from the emulation thread.
registers_[selected_register_] = value;
// Update ports as required.
if(update_port_b) set_port_output(true);
if(update_port_a) set_port_output(false);
}
template <bool is_stereo>
uint8_t AY38910SampleSource<is_stereo>::get_register_value() {
// This table ensures that bits that aren't defined within the AY are returned as 0s
// when read, conforming to CPC-sourced unit tests.
const uint8_t register_masks[16] = {
0xff, 0x0f, 0xff, 0x0f, 0xff, 0x0f, 0x1f, 0xff,
0x1f, 0x1f, 0x1f, 0xff, 0xff, 0x0f, 0xff, 0xff
};
if(selected_register_ > 15) return 0xff;
return registers_[selected_register_] & register_masks[selected_register_];
}
// MARK: - Port querying
template <bool is_stereo>
uint8_t AY38910SampleSource<is_stereo>::get_port_output(bool port_b) {
return registers_[port_b ? 15 : 14];
}
// MARK: - Bus handling
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_port_handler(PortHandler *handler) {
port_handler_ = handler;
set_port_output(true);
set_port_output(false);
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_data_input(uint8_t r) {
data_input_ = r;
update_bus();
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_port_output(bool port_b) {
// Per the data sheet: "each [IO] pin is provided with an on-chip pull-up resistor,
// so that when in the "input" mode, all pins will read normally high". Therefore,
// report programmer selection of input mode as creating an output of 0xff.
if(port_handler_) {
const bool is_output = !!(registers_[7] & (port_b ? 0x80 : 0x40));
port_handler_->set_port_output(port_b, is_output ? registers_[port_b ? 15 : 14] : 0xff);
}
}
template <bool is_stereo>
uint8_t AY38910SampleSource<is_stereo>::get_data_output() {
if(control_state_ == Read && selected_register_ >= 14 && selected_register_ < 16) {
// Per http://cpctech.cpc-live.com/docs/psgnotes.htm if a port is defined as output then the
// value returned to the CPU when reading it is the and of the output value and any input.
// If it's defined as input then you just get the input.
const uint8_t mask = port_handler_ ? port_handler_->get_port_input(selected_register_ == 15) : 0xff;
switch(selected_register_) {
default: break;
case 14: return mask & ((registers_[0x7] & 0x40) ? registers_[14] : 0xff);
case 15: return mask & ((registers_[0x7] & 0x80) ? registers_[15] : 0xff);
}
}
return data_output_;
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_control_lines(ControlLines control_lines) {
switch(int(control_lines)) {
default: control_state_ = Inactive; break;
case int(BDIR | BC2 | BC1):
case BDIR:
case BC1: control_state_ = LatchAddress; break;
case int(BC2 | BC1): control_state_ = Read; break;
case int(BDIR | BC2): control_state_ = Write; break;
}
update_bus();
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::set_reset(bool active) {
if(active == reset_) return;
reset_ = active;
// Reset upon the leading edge; TODO: is this right?
if(reset_) {
reset();
}
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::reset() {
// TODO: the below is a guess. Look up real answers.
selected_register_ = 0;
std::fill(registers_, registers_ + 16, 0);
task_queue_.enqueue([&] {
std::fill(output_registers_, output_registers_ + 16, 0);
evaluate_output_volume();
});
}
template <bool is_stereo>
void AY38910SampleSource<is_stereo>::update_bus() {
// Assume no output, unless this turns out to be a read.
data_output_ = 0xff;
switch(control_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;
}
}
// Ensure both mono and stereo versions of the AY are built.
template class GI::AY38910::AY38910SampleSource<true>;
template class GI::AY38910::AY38910SampleSource<false>;
// Perform an explicit instantiation of the BufferSource to hope for
// appropriate inlining of advance() and level().
template struct GI::AY38910::AY38910<true>;
template struct GI::AY38910::AY38910<false>;