1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-29 12:50:28 +00:00
CLK/Components/6845/CRTC6845.hpp
2024-01-16 23:34:46 -05:00

416 lines
13 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.

//
// CRTC6845.hpp
// Clock Signal
//
// Created by Thomas Harte on 31/07/2017.
// Copyright 2017 Thomas Harte. All rights reserved.
//
#pragma once
#include "../../ClockReceiver/ClockReceiver.hpp"
#include <cstdint>
#include <cstdio>
namespace Motorola::CRTC {
struct BusState {
bool display_enable = false;
bool hsync = false;
bool vsync = false;
bool cursor = false;
uint16_t refresh_address = 0;
uint16_t row_address = 0;
// Not strictly part of the bus state; provided because the partition between 6845 and bus handler
// doesn't quite hold up in some emulated systems where the two are integrated and share more state.
int field_count = 0;
};
class BusHandler {
public:
/*!
Performs the first phase of a 6845 bus cycle; this is the phase in which it is intended that
systems using the 6845 respect the bus state and produce pixels, sync or whatever they require.
*/
void perform_bus_cycle_phase1(const BusState &) {}
/*!
Performs the second phase of a 6845 bus cycle. Some bus state, including sync, is updated
directly after phase 1 and hence is visible to an observer during phase 2. Handlers may therefore
implement @c perform_bus_cycle_phase2 to be notified of the availability of that state without
having to wait until the next cycle has begun.
*/
void perform_bus_cycle_phase2(const BusState &) {}
};
enum class Personality {
HD6845S, // Type 0 in CPC parlance. Zero-width HSYNC available, no status, programmable VSYNC length.
// Considered exactly identical to the UM6845, so this enum covers both.
UM6845R, // Type 1 in CPC parlance. Status register, fixed-length VSYNC.
MC6845, // Type 2. No status register, fixed-length VSYNC, no zero-length HSYNC.
AMS40226, // Type 3. Status is get register, fixed-length VSYNC, no zero-length HSYNC.
EGA, // Extended EGA-style CRTC; uses 16-bit addressing throughout.
};
constexpr bool is_egavga(Personality p) {
return p >= Personality::EGA;
}
// https://www.pcjs.org/blog/2018/03/20/ advises that "the behavior of bits 5 and 6 [of register 10, the cursor start
// register is really card specific".
//
// This enum captures those specifics.
enum class CursorType {
/// No cursor signal is generated.
None,
/// MDA style: 00 => symmetric blinking; 01 or 10 => no blinking; 11 => short on, long off.
MDA,
/// EGA style: ignore the bits completely.
EGA,
};
// TODO UM6845R and R12/R13; see http://www.cpcwiki.eu/index.php/CRTC#CRTC_Differences
template <class BusHandlerT, Personality personality, CursorType cursor_type> class CRTC6845 {
public:
CRTC6845(BusHandlerT &bus_handler) noexcept :
bus_handler_(bus_handler), status_(0) {}
void select_register(uint8_t r) {
selected_register_ = r;
}
uint8_t get_status() {
switch(personality) {
case Personality::UM6845R: return status_ | (bus_state_.vsync ? 0x20 : 0x00);
case Personality::AMS40226: return get_register();
default: return 0xff;
}
return 0xff;
}
uint8_t get_register() {
if(selected_register_ == 31) status_ &= ~0x80;
if(selected_register_ == 16 || selected_register_ == 17) status_ &= ~0x40;
if(personality == Personality::UM6845R && selected_register_ == 31) return dummy_register_;
if(selected_register_ < 12 || selected_register_ > 17) return 0xff;
return registers_[selected_register_];
}
void set_register(uint8_t value) {
static constexpr bool is_ega = is_egavga(personality);
auto load_low = [value](uint16_t &target) {
target = (target & 0xff00) | value;
};
auto load_high = [value](uint16_t &target) {
constexpr uint8_t mask = RefreshMask >> 8;
target = uint16_t((target & 0x00ff) | ((value & mask) << 8));
};
switch(selected_register_) {
case 0: layout_.horizontal.total = value; break;
case 1: layout_.horizontal.displayed = value; break;
case 2: layout_.horizontal.start_sync = value; break;
case 3:
layout_.horizontal.sync_width = value & 0xf;
layout_.vertical.sync_lines = value >> 4;
// TODO: vertical sync lines:
// "(0 means 16 on some CRTC. Not present on all CRTCs, fixed to 16 lines on these)"
break;
case 4: layout_.vertical.total = value & 0x7f; break;
case 5: layout_.vertical.adjust = value & 0x1f; break;
case 6: layout_.vertical.displayed = value & 0x7f; break;
case 7: layout_.vertical.start_sync = value & 0x7f; break;
case 8:
switch(value & 3) {
default: layout_.interlace_mode_ = InterlaceMode::Off; break;
case 0b01: layout_.interlace_mode_ = InterlaceMode::InterlaceSync; break;
case 0b11: layout_.interlace_mode_ = InterlaceMode::InterlaceSyncAndVideo; break;
}
// Per CPC documentation, skew doesn't work on a "type 1 or 2", i.e. an MC6845 or a UM6845R.
if(personality != Personality::UM6845R && personality != Personality::MC6845) {
switch((value >> 4)&3) {
default: display_skew_mask_ = 1; break;
case 1: display_skew_mask_ = 2; break;
case 2: display_skew_mask_ = 4; break;
}
}
break;
case 9: layout_.vertical.end_row = value & 0x1f; break;
case 10:
layout_.vertical.start_cursor = value & 0x1f;
layout_.cursor_flags = (value >> 5) & 3;
break;
case 11:
layout_.vertical.end_cursor = value & 0x1f;
break;
case 12: load_high(layout_.start_address); break;
case 13: load_low(layout_.start_address); break;
case 14: load_high(layout_.cursor_address); break;
case 15: load_low(layout_.cursor_address); break;
}
static constexpr uint8_t masks[] = {
0xff, // Horizontal total.
0xff, // Horizontal display end.
0xff, // Start horizontal blank.
0xff, //
// EGA: b0b4: end of horizontal blank;
// b5b6: "Number of character clocks to delay start of display after Horizontal Total has been reached."
is_ega ? 0xff : 0x7f, // Start horizontal retrace.
0x1f, 0x7f, 0x7f,
0xff, 0x1f, 0x7f, 0x1f,
uint8_t(RefreshMask >> 8), uint8_t(RefreshMask),
uint8_t(RefreshMask >> 8), uint8_t(RefreshMask),
};
if(selected_register_ < 16) {
registers_[selected_register_] = value & masks[selected_register_];
}
if(selected_register_ == 31 && personality == Personality::UM6845R) {
dummy_register_ = value;
}
}
void trigger_light_pen() {
registers_[17] = bus_state_.refresh_address & 0xff;
registers_[16] = bus_state_.refresh_address >> 8;
status_ |= 0x40;
}
void run_for(Cycles cycles) {
auto cyles_remaining = cycles.as_integral();
while(cyles_remaining--) {
// Check for end of visible characters.
if(character_counter_ == layout_.horizontal.displayed) {
// TODO: consider skew in character_is_visible_. Or maybe defer until perform_bus_cycle?
character_is_visible_ = false;
end_of_line_address_ = bus_state_.refresh_address;
}
perform_bus_cycle_phase1();
bus_state_.refresh_address = (bus_state_.refresh_address + 1) & RefreshMask;
bus_state_.cursor = is_cursor_line_ &&
bus_state_.refresh_address == layout_.cursor_address;
// Check for end-of-line.
if(character_counter_ == layout_.horizontal.total) {
character_counter_ = 0;
do_end_of_line();
character_is_visible_ = true;
} else {
// Increment counter.
character_counter_++;
}
// Check for start of horizontal sync.
if(character_counter_ == layout_.horizontal.start_sync) {
hsync_counter_ = 0;
bus_state_.hsync = true;
}
// Check for end of horizontal sync; note that a sync time of zero will result in an immediate
// cancellation of the plan to perform sync if this is an HD6845S or UM6845R; otherwise zero
// will end up counting as 16 as it won't be checked until after overflow.
if(bus_state_.hsync) {
switch(personality) {
case Personality::HD6845S:
case Personality::UM6845R:
bus_state_.hsync = hsync_counter_ != layout_.horizontal.sync_width;
hsync_counter_ = (hsync_counter_ + 1) & 15;
break;
default:
hsync_counter_ = (hsync_counter_ + 1) & 15;
bus_state_.hsync = hsync_counter_ != layout_.horizontal.sync_width;
break;
}
}
perform_bus_cycle_phase2();
}
}
const BusState &get_bus_state() const {
return bus_state_;
}
private:
static constexpr uint16_t RefreshMask = (personality >= Personality::EGA) ? 0xffff : 0x3fff;
inline void perform_bus_cycle_phase1() {
// Skew theory of operation: keep a history of the last three states, and apply whichever is selected.
character_is_visible_shifter_ = (character_is_visible_shifter_ << 1) | unsigned(character_is_visible_);
bus_state_.display_enable = (int(character_is_visible_shifter_) & display_skew_mask_) && line_is_visible_;
bus_handler_.perform_bus_cycle_phase1(bus_state_);
}
inline void perform_bus_cycle_phase2() {
bus_handler_.perform_bus_cycle_phase2(bus_state_);
}
inline void do_end_of_line() {
if constexpr (cursor_type != CursorType::None) {
// Check for cursor disable.
// TODO: this is handled differently on the EGA, should I ever implement that.
is_cursor_line_ &= bus_state_.row_address != layout_.vertical.end_cursor;
}
// Check for end of vertical sync.
if(bus_state_.vsync) {
vsync_counter_ = (vsync_counter_ + 1) & 15;
// On the UM6845R and AMS40226, honour the programmed vertical sync time; on the other CRTCs
// always use a vertical sync count of 16.
switch(personality) {
case Personality::HD6845S:
case Personality::AMS40226:
bus_state_.vsync = vsync_counter_ != layout_.vertical.sync_lines;
break;
default:
bus_state_.vsync = vsync_counter_ != 0;
break;
}
}
if(is_in_adjustment_period_) {
line_counter_++;
if(line_counter_ == layout_.vertical.adjust) {
is_in_adjustment_period_ = false;
do_end_of_frame();
}
} else {
// Advance vertical counter.
if(bus_state_.row_address == layout_.vertical.end_row) {
bus_state_.row_address = 0;
line_address_ = end_of_line_address_;
// Check for entry into the overflow area.
if(line_counter_ == layout_.vertical.total) {
if(layout_.vertical.adjust) {
line_counter_ = 0;
is_in_adjustment_period_ = true;
} else {
do_end_of_frame();
}
} else {
line_counter_ = (line_counter_ + 1) & 0x7f;
// Check for start of vertical sync.
if(line_counter_ == layout_.vertical.start_sync) {
bus_state_.vsync = true;
vsync_counter_ = 0;
}
// Check for end of visible lines.
if(line_counter_ == layout_.vertical.displayed) {
line_is_visible_ = false;
}
}
} else {
bus_state_.row_address = (bus_state_.row_address + 1) & 0x1f;
}
}
bus_state_.refresh_address = line_address_;
character_counter_ = 0;
character_is_visible_ = (layout_.horizontal.displayed != 0);
if constexpr (cursor_type != CursorType::None) {
// Check for cursor enable.
is_cursor_line_ |= bus_state_.row_address == layout_.vertical.start_cursor;
switch(cursor_type) {
// MDA-style blinking.
// https://retrocomputing.stackexchange.com/questions/27803/what-are-the-blinking-rates-of-the-caret-and-of-blinking-text-on-pc-graphics-car
// gives an 8/8 pattern for regular blinking though mode 11 is then just a guess.
case CursorType::MDA:
switch(layout_.cursor_flags) {
case 0b11: is_cursor_line_ &= (bus_state_.field_count & 8) < 3; break;
case 0b00: is_cursor_line_ &= bool(bus_state_.field_count & 8); break;
case 0b01: is_cursor_line_ = false; break;
case 0b10: is_cursor_line_ = true; break;
default: break;
}
break;
}
}
}
inline void do_end_of_frame() {
line_counter_ = 0;
line_is_visible_ = true;
line_address_ = layout_.start_address;
bus_state_.refresh_address = line_address_;
++bus_state_.field_count;
}
BusHandlerT &bus_handler_;
BusState bus_state_;
enum class InterlaceMode {
Off,
InterlaceSync,
InterlaceSyncAndVideo,
};
enum class BlinkMode {
// TODO.
};
struct {
struct {
uint8_t total;
uint8_t displayed;
uint8_t start_sync;
uint8_t sync_width;
} horizontal;
struct {
uint8_t total;
uint8_t displayed;
uint8_t start_sync;
uint8_t sync_lines;
uint8_t adjust;
uint8_t end_row;
uint8_t start_cursor;
uint8_t end_cursor;
} vertical;
InterlaceMode interlace_mode_ = InterlaceMode::Off;
uint16_t start_address;
uint16_t cursor_address;
uint16_t light_pen_address;
uint8_t cursor_flags;
} layout_;
uint8_t registers_[18]{};
uint8_t dummy_register_ = 0;
int selected_register_ = 0;
uint8_t character_counter_ = 0;
uint8_t line_counter_ = 0;
bool character_is_visible_ = false, line_is_visible_ = false;
int hsync_counter_ = 0;
int vsync_counter_ = 0;
bool is_in_adjustment_period_ = false;
uint16_t line_address_ = 0;
uint16_t end_of_line_address_ = 0;
uint8_t status_ = 0;
int display_skew_mask_ = 1;
unsigned int character_is_visible_shifter_ = 0;
bool is_cursor_line_ = false;
};
}