1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-12-11 15:49:38 +00:00
CLK/Machines/PCCompatible/CGA.hpp
2024-10-09 11:59:27 -04:00

448 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.

//
// CGA.hpp
// Clock Signal
//
// Created by Thomas Harte on 05/12/2023.
// Copyright © 2023 Thomas Harte. All rights reserved.
//
#pragma once
#include "../../Components/6845/CRTC6845.hpp"
#include "../../Outputs/CRT/CRT.hpp"
#include "../../Machines/Utility/ROMCatalogue.hpp"
namespace PCCompatible {
class CGA {
public:
CGA() : crtc_(outputter_) {}
static constexpr uint32_t BaseAddress = 0xb'8000;
static constexpr auto FontROM = ROM::Name::PCCompatibleCGAFont;
void set_source(const uint8_t *ram, std::vector<uint8_t> font) {
outputter_.ram = ram;
outputter_.font = font;
}
void run_for(Cycles cycles) {
// Input rate is the PIT rate of 1,193,182 Hz.
// CGA is clocked at the real oscillator rate of 12 times that.
// But there's also an internal divide by 8 to align to the 80-cfetch clock.
// ... and 12/8 = 3/2.
full_clock_ += 3 * cycles.as<int>();
const int modulo = 2 * outputter_.clock_divider;
crtc_.run_for(Cycles(full_clock_ / modulo));
full_clock_ %= modulo;
}
template <int address>
void write(uint8_t value) {
switch(address) {
case 0: case 2: case 4: case 6:
crtc_.select_register(value);
break;
case 1: case 3: case 5: case 7:
crtc_.set_register(value);
break;
case 0x8: outputter_.set_mode(value); break;
case 0x9: outputter_.set_colours(value); break;
}
}
template <int address>
uint8_t read() {
switch(address) {
case 1: case 3: case 5: case 7:
return crtc_.get_register();
case 0xa:
return
// b3: 1 => in vsync; 0 => not;
// b2: 1 => light pen switch is off;
// b1: 1 => positive edge from light pen has set trigger;
// b0: 1 => safe to write to VRAM now without causing snow.
(crtc_.get_bus_state().vsync ? 0b1001 : 0b0000) |
(crtc_.get_bus_state().display_enable ? 0b0000 : 0b0001) |
0b0100;
default: return 0xff;
}
}
// MARK: - Display type configuration.
void set_display_type(Outputs::Display::DisplayType display_type) {
outputter_.crt.set_display_type(display_type);
outputter_.set_is_composite(Outputs::Display::is_composite(display_type));
}
Outputs::Display::DisplayType get_display_type() const {
return outputter_.crt.get_display_type();
}
// MARK: - Call-ins for ScanProducer.
void set_scan_target(Outputs::Display::ScanTarget *scan_target) {
outputter_.crt.set_scan_target(scan_target);
}
Outputs::Display::ScanStatus get_scaled_scan_status() const {
// The CRT is always handed data at the full CGA pixel clock rate, so just
// divide by 12 to get back to the rate that run_for is being called at.
return outputter_.crt.get_scaled_scan_status() / 12.0f;
}
private:
struct CRTCOutputter {
enum class OutputState {
Sync, Pixels, Border, ColourBurst
};
CRTCOutputter() :
crt(910, 8, Outputs::Display::Type::NTSC60, Outputs::Display::InputDataType::Red2Green2Blue2)
{
crt.set_visible_area(Outputs::Display::Rect(0.097f, 0.095f, 0.82f, 0.82f));
crt.set_display_type(Outputs::Display::DisplayType::RGB);
}
void set_mode(uint8_t control) {
// b5: enable blink
// b4: 1 => 640x200 graphics
// b3: video enable
// b2: 1 => monochrome
// b1: 1 => 320x200 graphics; 0 => text
// b0: 1 => 80-column text; 0 => 40
control_ = control; // To capture blink, monochrome and video enable bits.
if(control & 0x2) {
mode_ = (control & 0x10) ? Mode::Pixels640 : Mode::Pixels320;
pixels_per_tick = (mode_ == Mode::Pixels640) ? 16 : 8;
} else {
mode_ = Mode::Text;
pixels_per_tick = 8;
}
clock_divider = 1 + !(control & 0x01);
// Both graphics mode and monochrome/colour may have changed, so update the palette.
update_palette();
}
void set_is_composite(bool is_composite) {
is_composite_ = is_composite;
update_palette();
}
void set_colours(uint8_t value) {
colours_ = value;
update_palette();
}
uint8_t control() {
return control_;
}
void update_hsync(bool new_hsync) {
if(new_hsync == previous_hsync) {
cycles_since_hsync += clock_divider;
} else {
cycles_since_hsync = 0;
previous_hsync = new_hsync;
}
}
OutputState implied_state(const Motorola::CRTC::BusState &state) const {
OutputState new_state;
if(state.hsync || state.vsync) {
new_state = OutputState::Sync;
} else if(!state.display_enable || !(control_&0x08)) {
new_state = OutputState::Border;
// TODO: this isn't correct for colour burst positioning, though
// it happens to fool the particular CRT I've implemented.
if(!(control_&4) && cycles_since_hsync <= 6) {
new_state = OutputState::ColourBurst;
}
} else {
new_state = OutputState::Pixels;
}
return new_state;
}
void perform_bus_cycle(const Motorola::CRTC::BusState &state) {
// Determine new output state.
update_hsync(state.hsync);
const OutputState new_state = implied_state(state);
static constexpr uint8_t colour_phase = 200;
// Upon either a state change or just having accumulated too much local time...
if(
new_state != output_state ||
active_pixels_per_tick != pixels_per_tick ||
active_clock_divider != clock_divider ||
active_border_colour != border_colour ||
count > 912
) {
// (1) flush preexisting state.
if(count) {
switch(output_state) {
case OutputState::Sync: crt.output_sync(count * active_clock_divider); break;
case OutputState::Border:
if(active_border_colour) {
crt.output_blank(count * active_clock_divider);
} else {
crt.output_level<uint8_t>(count * active_clock_divider, active_border_colour);
}
break;
case OutputState::ColourBurst: crt.output_colour_burst(count * active_clock_divider, colour_phase); break;
case OutputState::Pixels: flush_pixels(); break;
}
}
// (2) adopt new state.
output_state = new_state;
active_pixels_per_tick = pixels_per_tick;
active_clock_divider = clock_divider;
active_border_colour = border_colour;
count = 0;
}
// Collect pixels if applicable.
if(output_state == OutputState::Pixels) {
if(!pixels) {
pixel_pointer = pixels = crt.begin_data(DefaultAllocationSize);
// Flush any period where pixels weren't recorded due to back pressure.
if(pixels && count) {
crt.output_blank(count * active_clock_divider);
count = 0;
}
}
if(pixels) {
if(state.cursor) {
std::fill(pixel_pointer, pixel_pointer + pixels_per_tick, 0x3f); // i.e. white.
} else {
if(mode_ == Mode::Text) {
serialise_text(state);
} else {
serialise_pixels(state);
}
}
pixel_pointer += active_pixels_per_tick;
}
}
// Advance.
count += 8;
// Output pixel row prematurely if storage is exhausted.
if(output_state == OutputState::Pixels && pixel_pointer == pixels + DefaultAllocationSize) {
flush_pixels();
count = 0;
}
}
void flush_pixels() {
crt.output_data(count * active_clock_divider, size_t((count * active_pixels_per_tick) / 8));
pixels = pixel_pointer = nullptr;
}
void serialise_pixels(const Motorola::CRTC::BusState &state) {
// Refresh address is shifted left and two bytes are fetched, just as if the fetch were for
// character code + attributes, but producing two bytes worth of graphics.
//
// Meanwhile, row address is used as a substitute 14th address line.
const auto base_address =
((state.refresh_address & 0xfff) << 1) +
((state.row_address & 1) << 13);
const uint8_t bitmap[] = {
ram[base_address],
ram[base_address + 1],
};
if(mode_ == Mode::Pixels320) {
pixel_pointer[0] = palette320[(bitmap[0] & 0xc0) >> 6];
pixel_pointer[1] = palette320[(bitmap[0] & 0x30) >> 4];
pixel_pointer[2] = palette320[(bitmap[0] & 0x0c) >> 2];
pixel_pointer[3] = palette320[(bitmap[0] & 0x03) >> 0];
pixel_pointer[4] = palette320[(bitmap[1] & 0xc0) >> 6];
pixel_pointer[5] = palette320[(bitmap[1] & 0x30) >> 4];
pixel_pointer[6] = palette320[(bitmap[1] & 0x0c) >> 2];
pixel_pointer[7] = palette320[(bitmap[1] & 0x03) >> 0];
} else {
pixel_pointer[0x0] = palette640[(bitmap[0] & 0x80) >> 7];
pixel_pointer[0x1] = palette640[(bitmap[0] & 0x40) >> 6];
pixel_pointer[0x2] = palette640[(bitmap[0] & 0x20) >> 5];
pixel_pointer[0x3] = palette640[(bitmap[0] & 0x10) >> 4];
pixel_pointer[0x4] = palette640[(bitmap[0] & 0x08) >> 3];
pixel_pointer[0x5] = palette640[(bitmap[0] & 0x04) >> 2];
pixel_pointer[0x6] = palette640[(bitmap[0] & 0x02) >> 1];
pixel_pointer[0x7] = palette640[(bitmap[0] & 0x01) >> 0];
pixel_pointer[0x8] = palette640[(bitmap[1] & 0x80) >> 7];
pixel_pointer[0x9] = palette640[(bitmap[1] & 0x40) >> 6];
pixel_pointer[0xa] = palette640[(bitmap[1] & 0x20) >> 5];
pixel_pointer[0xb] = palette640[(bitmap[1] & 0x10) >> 4];
pixel_pointer[0xc] = palette640[(bitmap[1] & 0x08) >> 3];
pixel_pointer[0xd] = palette640[(bitmap[1] & 0x04) >> 2];
pixel_pointer[0xe] = palette640[(bitmap[1] & 0x02) >> 1];
pixel_pointer[0xf] = palette640[(bitmap[1] & 0x01) >> 0];
}
}
void serialise_text(const Motorola::CRTC::BusState &state) {
const uint8_t attributes = ram[((state.refresh_address << 1) + 1) & 0x3fff];
const uint8_t glyph = ram[((state.refresh_address << 1) + 0) & 0x3fff];
const uint8_t row = font[(glyph * 8) + state.row_address];
uint8_t colours[2] = { rgb(attributes >> 4), rgbi(attributes) };
// Apply blink or background intensity.
if(control_ & 0x20) {
// Set both colours to black if within a blink; otherwise consider a yellow-to-brown conversion.
if((attributes & 0x80) && (state.field_count & 16)) {
colours[0] = colours[1] = 0;
} else {
colours[0] = yellow_to_brown(colours[0]);
}
} else {
if(attributes & 0x80) {
colours[0] = bright(colours[0]);
} else {
// Yellow to brown definitely doesn't apply if the colour has been brightened.
colours[0] = yellow_to_brown(colours[0]);
}
}
// Draw according to ROM contents.
pixel_pointer[0] = (row & 0x80) ? colours[1] : colours[0];
pixel_pointer[1] = (row & 0x40) ? colours[1] : colours[0];
pixel_pointer[2] = (row & 0x20) ? colours[1] : colours[0];
pixel_pointer[3] = (row & 0x10) ? colours[1] : colours[0];
pixel_pointer[4] = (row & 0x08) ? colours[1] : colours[0];
pixel_pointer[5] = (row & 0x04) ? colours[1] : colours[0];
pixel_pointer[6] = (row & 0x02) ? colours[1] : colours[0];
pixel_pointer[7] = (row & 0x01) ? colours[1] : colours[0];
}
Outputs::CRT::CRT crt;
static constexpr size_t DefaultAllocationSize = 320;
// Current output stream.
uint8_t *pixels = nullptr;
uint8_t *pixel_pointer = nullptr;
int active_pixels_per_tick = 8;
int active_clock_divider = 1;
uint8_t active_border_colour = 0;
// Source data.
const uint8_t *ram = nullptr;
std::vector<uint8_t> font;
// CRTC state tracking, for CRT serialisation.
OutputState output_state = OutputState::Sync;
int count = 0;
bool previous_hsync = false;
int cycles_since_hsync = 0;
// Current Programmer-set parameters.
int clock_divider = 1;
int pixels_per_tick = 8;
uint8_t colours_ = 0;
uint8_t control_ = 0;
bool is_composite_ = false;
enum class Mode {
Pixels640, Pixels320, Text,
} mode_ = Mode::Text;
uint8_t palette320[4]{};
uint8_t palette640[2]{};
uint8_t border_colour;
void update_palette() {
// b5: 320x200 palette, unless in monochrome mode.
if(control_ & 0x04) {
palette320[1] = DarkCyan;
palette320[2] = DarkRed;
palette320[3] = DarkGrey;
} else {
if(colours_ & 0x20) {
palette320[1] = DarkCyan;
palette320[2] = DarkMagenta;
palette320[3] = DarkGrey;
} else {
palette320[1] = DarkGreen;
palette320[2] = DarkRed;
palette320[3] = DarkYellow;
}
}
// b4: set 320x200 palette into high intensity.
if(colours_ & 0x10) {
palette320[1] = bright(palette320[1]);
palette320[2] = bright(palette320[2]);
palette320[3] = bright(palette320[3]);
} else {
// Remap dark yellow to brown if applicable.
palette320[3] = yellow_to_brown(palette320[3]);
}
// b3b0: set background, border, monochrome colour.
palette640[1] = palette320[0] = rgbi(colours_);
border_colour = (mode_ != Mode::Pixels640) ? palette320[0] : 0;
}
//
// Named colours and mapping logic.
//
static constexpr uint8_t DarkCyan = 0b00'10'10;
static constexpr uint8_t DarkMagenta = 0b10'00'10;
static constexpr uint8_t DarkGrey = 0b10'10'10;
static constexpr uint8_t DarkGreen = 0b00'10'00;
static constexpr uint8_t DarkRed = 0b10'00'00;
static constexpr uint8_t DarkYellow = 0b10'10'00;
static constexpr uint8_t Brown = 0b10'01'00;
/// @returns @c Brown if @c source is @c DarkYellow and composite output is not enabled; @c source otherwise.
constexpr uint8_t yellow_to_brown(uint8_t source) {
return (source == DarkYellow && !is_composite_) ? Brown : source;
}
/// @returns The brightened (i.e. high intensity) version of @c source.
constexpr uint8_t bright(uint8_t source) {
return source | (source >> 1);
}
/// Maps the RGB TTL triplet @c source to an appropriate output colour.
constexpr uint8_t rgb(uint8_t source) {
return uint8_t(
((source & 0x01) << 1) |
((source & 0x02) << 2) |
((source & 0x04) << 3)
);
}
/// Maps the RGBI value in @c source to an appropriate output colour, including potential yellow-to-brown conversion.
constexpr uint8_t rgbi(uint8_t source) {
const uint8_t result = rgb(source);
return (source & 0x10) ? bright(result) : yellow_to_brown(result);
}
} outputter_;
Motorola::CRTC::CRTC6845<
CRTCOutputter,
Motorola::CRTC::Personality::HD6845S,
Motorola::CRTC::CursorType::MDA> crtc_;
int full_clock_ = 0;
};
}