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212 lines
5.3 KiB
C++
212 lines
5.3 KiB
C++
//
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// Audio.hpp
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// Clock Signal
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//
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// Created by Thomas Harte on 20/03/2024.
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// Copyright © 2024 Thomas Harte. All rights reserved.
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//
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#pragma once
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#include "../../../Concurrency/AsyncTaskQueue.hpp"
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#include "../../../Outputs/Speaker/Implementation/LowpassSpeaker.hpp"
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#include <array>
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#include <cstdint>
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namespace Archimedes {
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// Generate lookup table for sound output levels, and hold it only once regardless
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// of how many template instantiations there are of @c Sound.
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static constexpr std::array<int16_t, 256> generate_levels() {
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std::array<int16_t, 256> result{};
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// There are 8 segments of 16 steps; each segment is a linear
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// interpolation from its start level to its end level and
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// each level is double the previous.
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//
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// Bit 7 provides a sign.
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for(size_t c = 0; c < 256; c++) {
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// This is the VIDC1 rule.
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// const bool is_negative = c & 128;
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// const auto point = static_cast<int>(c & 0xf);
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// const auto chord = static_cast<int>((c >> 4) & 7);
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// VIDC2 rule, which seems to be effective. I've yet to spot the rule by which
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// VIDC1/2 is detected.
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const bool is_negative = c & 1;
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const auto point = static_cast<int>((c >> 1) & 0xf);
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const auto chord = static_cast<int>((c >> 5) & 7);
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const int start = (1 << chord) - 1;
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const int end = (chord == 7) ? 247 : ((start << 1) + 1);
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const int level = start * (16 - point) + end * point;
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result[c] = static_cast<int16_t>((level * 32767) / 3832);
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if(is_negative) result[c] = -result[c];
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}
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return result;
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}
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struct SoundLevels {
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static constexpr auto levels = generate_levels();
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};
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/// Models the Archimedes sound output; in a real machine this is a joint efort between the VIDC and the MEMC.
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template <typename InterruptObserverT>
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struct Sound: private SoundLevels {
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Sound(InterruptObserverT &observer, const uint8_t *ram) : ram_(ram), observer_(observer) {
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speaker_.set_input_rate(1'000'000);
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speaker_.set_high_frequency_cutoff(2'200.0f);
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}
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void set_next_end(uint32_t value) {
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next_.end = value;
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}
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void set_next_start(uint32_t value) {
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next_.start = value;
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set_buffer_valid(true); // My guess: this is triggered on next buffer start write.
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// Definitely wrong; testing.
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// set_halted(false);
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}
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bool interrupt() const {
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return !next_buffer_valid_;
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}
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void swap() {
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current_.start = next_.start;
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std::swap(current_.end, next_.end);
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set_buffer_valid(false);
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set_halted(false);
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}
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void set_frequency(uint8_t frequency) {
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divider_ = reload_ = frequency;
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}
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void set_stereo_image(uint8_t channel, uint8_t value) {
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if(!value) {
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positions_[channel].left =
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positions_[channel].right = 0;
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return;
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}
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positions_[channel].right = value - 1;
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positions_[channel].left = 6 - positions_[channel].right;
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}
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void set_dma_enabled(bool enabled) {
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dma_enabled_ = enabled;
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}
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void tick() {
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// Write silence if not currently outputting.
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if(halted_ || !dma_enabled_) {
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post_sample(Outputs::Speaker::StereoSample());
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return;
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}
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// Apply user-programmed clock divider.
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--divider_;
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if(!divider_) {
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divider_ = reload_ + 2;
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// Grab a single byte from the FIFO.
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const uint8_t raw = ram_[static_cast<std::size_t>(current_.start) + static_cast<std::size_t>(byte_)];
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sample_ = Outputs::Speaker::StereoSample( // TODO: pan, volume.
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static_cast<int16_t>((levels[raw] * positions_[byte_ & 7].left) / 6),
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static_cast<int16_t>((levels[raw] * positions_[byte_ & 7].right) / 6)
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);
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++byte_;
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// If the FIFO is exhausted, consider triggering a DMA request.
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if(byte_ == 16) {
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byte_ = 0;
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current_.start += 16;
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if(current_.start == current_.end) {
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if(next_buffer_valid_) {
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swap();
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} else {
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set_halted(true);
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}
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}
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}
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}
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post_sample(sample_);
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}
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Outputs::Speaker::Speaker *speaker() {
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return &speaker_;
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}
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~Sound() {
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while(is_posting_.test_and_set());
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}
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private:
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const uint8_t *ram_ = nullptr;
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uint8_t divider_ = 0, reload_ = 0;
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int byte_ = 0;
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void set_buffer_valid(bool valid) {
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next_buffer_valid_ = valid;
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observer_.update_interrupts();
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}
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void set_halted(bool halted) {
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if(halted_ != halted && !halted) {
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byte_ = 0;
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divider_ = reload_;
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}
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halted_ = halted;
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}
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bool next_buffer_valid_ = false;
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bool halted_ = true; // This is a bit of a guess.
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bool dma_enabled_ = false;
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struct Buffer {
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uint32_t start = 0, end = 0;
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};
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Buffer current_, next_;
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struct StereoPosition {
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// These are maintained as sixths, i.e. a value of 6 means 100%.
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int left, right;
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} positions_[8];
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InterruptObserverT &observer_;
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Outputs::Speaker::PushLowpass<true> speaker_;
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Concurrency::AsyncTaskQueue<true> queue_;
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void post_sample(Outputs::Speaker::StereoSample sample) {
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samples_[sample_target_][sample_pointer_++] = sample;
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if(sample_pointer_ == samples_[0].size()) {
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while(is_posting_.test_and_set());
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const auto post_source = sample_target_;
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sample_target_ ^= 1;
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sample_pointer_ = 0;
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queue_.enqueue([this, post_source]() {
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speaker_.push(reinterpret_cast<int16_t *>(samples_[post_source].data()), samples_[post_source].size());
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is_posting_.clear();
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});
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}
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}
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std::size_t sample_pointer_ = 0;
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std::size_t sample_target_ = 0;
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Outputs::Speaker::StereoSample sample_;
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using SampleBuffer = std::array<Outputs::Speaker::StereoSample, 4096>;
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std::array<SampleBuffer, 2> samples_;
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std::atomic_flag is_posting_ = ATOMIC_FLAG_INIT;
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};
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}
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