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CLK/Machines/Amiga/Chipset.cpp
2021-09-23 20:29:39 -04:00

896 lines
29 KiB
C++

//
// Chipset.cpp
// Clock Signal
//
// Created by Thomas Harte on 22/07/2021.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#include "Chipset.hpp"
//#define NDEBUG
#define LOG_PREFIX "[Amiga chipset] "
#include "../../Outputs/Log.hpp"
#include <algorithm>
#include <cassert>
using namespace Amiga;
namespace {
template <typename EnumT, EnumT... T> struct Mask {
static constexpr uint16_t value = 0;
};
template <typename EnumT, EnumT F, EnumT... T> struct Mask<EnumT, F, T...> {
static constexpr uint16_t value = uint16_t(F) | Mask<EnumT, T...>::value;
};
template <InterruptFlag... Flags> struct InterruptMask: Mask<InterruptFlag, Flags...> {};
template <DMAFlag... Flags> struct DMAMask: Mask<DMAFlag, Flags...> {};
}
Chipset::Chipset(uint16_t *ram, size_t word_size) :
blitter_(*this, ram, word_size),
bitplanes_(*this, ram, word_size),
copper_(*this, ram, word_size),
disk_(*this, ram, word_size),
crt_(908, 4, Outputs::Display::Type::PAL50, Outputs::Display::InputDataType::Red4Green4Blue4) {
}
Chipset::Changes Chipset::run_for(HalfCycles length) {
return run<false>(length);
}
Chipset::Changes Chipset::run_until_cpu_slot() {
return run<true>();
}
void Chipset::set_cia_interrupts(bool cia_a, bool cia_b) {
// TODO: are these really latched, or are they active live?
interrupt_requests_ &= ~InterruptMask<InterruptFlag::IOPortsAndTimers, InterruptFlag::External>::value;
interrupt_requests_ |=
(cia_a ? InterruptMask<InterruptFlag::IOPortsAndTimers>::value : 0) |
(cia_b ? InterruptMask<InterruptFlag::External>::value : 0);
update_interrupts();
}
void Chipset::posit_interrupt(InterruptFlag flag) {
interrupt_requests_ |= uint16_t(flag);
update_interrupts();
}
template <int cycle> void Chipset::output() {
// Notes to self on guesses below:
//
// Hardware stop is at 0x18;
// 12/64 * 227 = 42.5625
//
// "However, horizontal blanking actually limits the displayable
// video to 368 low resolution pixel"
//
// => 184 windows out of 227 are visible, which concurs.
//
// A complete from-thin-air guess:
//
// 7 cycles blank;
// 17 cycles sync;
// 3 cycles blank;
// 9 cycles colour burst;
// 7 cycles blank.
constexpr int blank1 = 7;
constexpr int sync = 17 + blank1;
constexpr int blank2 = 3 + sync;
constexpr int burst = 9 + blank2;
constexpr int blank3 = 7 + burst;
static_assert(blank3 == 43);
#define LINK(location, action, length) \
if(cycle == (location)) { \
crt_.action((length) * 4); \
}
if(y_ < vertical_blank_height_) {
// Put three lines of sync at the centre of the vertical blank period.
// Offset by half a line if interlaced and on an odd frame.
const int midline = vertical_blank_height_ >> 1;
if(frame_height_ & 1) {
if(y_ < midline - 1 || y_ > midline + 2) {
LINK(blank1, output_blank, blank1);
LINK(sync, output_sync, sync - blank1);
LINK(line_length_ - 1, output_blank, line_length_ - 1 - sync);
} else if(y_ == midline - 1) {
LINK(113, output_blank, 113);
LINK(line_length_ - 1, output_sync, line_length_ - 1 - 113);
} else if(y_ == midline + 2) {
LINK(113, output_sync, 113);
LINK(line_length_ - 1, output_blank, line_length_ - 1 - 113);
} else {
LINK(blank1, output_sync, blank1);
LINK(sync, output_blank, sync - blank1);
LINK(line_length_ - 1, output_sync, line_length_ - 1 - sync);
}
} else {
if(y_ < midline - 1 || y_ > midline + 1) {
LINK(blank1, output_blank, blank1);
LINK(sync, output_sync, sync - blank1);
LINK(line_length_ - 1, output_blank, line_length_ - 1 - sync);
} else {
LINK(blank1, output_sync, blank1);
LINK(sync, output_blank, sync - blank1);
LINK(line_length_ - 1, output_sync, line_length_ - 1 - sync);
}
}
} else {
// Output the correct sequence of blanks, syncs and burst atomically.
LINK(blank1, output_blank, blank1);
LINK(sync, output_sync, sync - blank1);
LINK(blank2, output_blank, blank2 - sync);
LINK(burst, output_default_colour_burst, burst - blank2); // TODO: only if colour enabled.
LINK(blank3, output_blank, blank3 - burst);
// TODO: these shouldn't be functions of the fetch window,
// but of the display window.
display_horizontal_ |= (cycle << 1) == fetch_window_[0];
display_horizontal_ &= (cycle << 1) != fetch_window_[1];
if constexpr (cycle > blank3) {
const bool is_pixel_display = display_horizontal_ && fetch_vertical_;
if(
(is_pixel_display == is_border_) ||
(is_border_ && border_colour_ != palette_[0])) {
flush_output();
is_border_ = !is_pixel_display;
border_colour_ = palette_[0];
}
if(is_pixel_display) {
if(!pixels_) {
uint16_t *const new_pixels = reinterpret_cast<uint16_t *>(crt_.begin_data(4 * size_t(line_length_ - cycle)));
if(new_pixels) {
flush_output();
}
pixels_ = new_pixels;
}
if(pixels_) {
// TODO: this is obviously nonsense. Probably do a table-based
// planar-to-chunky up front into 8-bit pockets, and just shift that.
pixels_[0] = palette_[
((current_bitplanes_[0]&1) << 0) |
((current_bitplanes_[1]&1) << 1) |
((current_bitplanes_[2]&1) << 2) |
((current_bitplanes_[3]&1) << 3) |
((current_bitplanes_[4]&1) << 4)
];
current_bitplanes_ >>= is_high_res_;
pixels_[1] = palette_[
((current_bitplanes_[0]&1) << 0) |
((current_bitplanes_[1]&1) << 1) |
((current_bitplanes_[2]&1) << 2) |
((current_bitplanes_[3]&1) << 3) |
((current_bitplanes_[4]&1) << 4)
];
current_bitplanes_ >>= 1;
pixels_[2] = palette_[
((current_bitplanes_[0]&1) << 0) |
((current_bitplanes_[1]&1) << 1) |
((current_bitplanes_[2]&1) << 2) |
((current_bitplanes_[3]&1) << 3) |
((current_bitplanes_[4]&1) << 4)
];
current_bitplanes_ >>= is_high_res_;
pixels_[3] = palette_[
((current_bitplanes_[0]&1) << 0) |
((current_bitplanes_[1]&1) << 1) |
((current_bitplanes_[2]&1) << 2) |
((current_bitplanes_[3]&1) << 3) |
((current_bitplanes_[4]&1) << 4)
];
current_bitplanes_ >>= 1;
pixels_ += 4;
}
}
++zone_duration_;
// Output the rest of the line. TODO: optimise border area.
if(cycle == line_length_ - 1) {
flush_output();
}
}
}
#undef LINK
}
void Chipset::flush_output() {
if(!zone_duration_) return;
if(is_border_) {
uint16_t *const pixels = reinterpret_cast<uint16_t *>(crt_.begin_data(1));
if(pixels) {
*pixels = border_colour_;
}
crt_.output_data(zone_duration_ * 4, 1);
} else {
crt_.output_data(zone_duration_ * 4);
}
zone_duration_ = 0;
pixels_ = nullptr;
}
/// @returns @c true if this was a CPU slot; @c false otherwise.
template <int cycle, bool stop_if_cpu> bool Chipset::perform_cycle() {
constexpr auto BlitterFlag = DMAMask<DMAFlag::Blitter, DMAFlag::AllBelow>::value;
constexpr auto BitplaneFlag = DMAMask<DMAFlag::Bitplane, DMAFlag::AllBelow>::value;
constexpr auto CopperFlag = DMAMask<DMAFlag::Copper, DMAFlag::AllBelow>::value;
constexpr auto DiskFlag = DMAMask<DMAFlag::Disk, DMAFlag::AllBelow>::value;
// Update state as to whether bitplane fetching should happen now.
//
// TODO: figure out how the hard stops factor into this.
fetch_horizontal_ |= (cycle << 1) == fetch_window_[0];
fetch_horizontal_ &= (cycle << 1) != fetch_window_[1];
// Top priority: bitplane collection.
if((dma_control_ & BitplaneFlag) == BitplaneFlag) {
// TODO: offer a cycle for bitplane collection.
// Probably need to indicate odd or even?
if(fetch_horizontal_ && fetch_vertical_ && bitplanes_.advance(cycle)) { // TODO: cycle should be relative to start of collection.
did_fetch_ = true;
return false;
}
}
if constexpr (cycle & 1) {
// Odd slot use/priority:
//
// 1. Bitplane fetches [dealt with above].
// 2. Refresh, disk, audio, or sprites. Depending on region.
//
// Blitter and CPU priority is dealt with below.
if constexpr (cycle >= 4 && cycle <= 6) {
if((dma_control_ & DiskFlag) == DiskFlag) {
if(disk_.advance()) {
return false;
}
}
}
} else {
// Bitplanes being dealt with, specific odd-cycle responsibility
// is just possibly to pass to the Copper.
//
// The Blitter and CPU are dealt with outside of the odd/even test.
if((dma_control_ & CopperFlag) == CopperFlag) {
if(copper_.advance(uint16_t(((y_ & 0xff) << 8) | (cycle & 0xfe)))) {
return false;
}
} else {
copper_.stop();
}
}
// Down here: give first refusal to the Blitter, otherwise
// pass on to the CPU.
return (dma_control_ & BlitterFlag) != BlitterFlag || !blitter_.advance();
}
/// Performs all slots starting with @c first_slot and ending just before @c last_slot.
/// If @c stop_on_cpu is true, stops upon discovery of a CPU slot.
///
/// @returns the number of slots completed if @c stop_on_cpu was true and a CPU slot was found.
/// @c -1 otherwise.
template <bool stop_on_cpu> int Chipset::advance_slots(int first_slot, int last_slot) {
if(first_slot == last_slot) {
return -1;
}
#define C(x) \
case x: \
if constexpr(stop_on_cpu) {\
if(perform_cycle<x, stop_on_cpu>()) {\
return x - first_slot;\
}\
} else {\
perform_cycle<x, stop_on_cpu>(); \
} \
output<x>(); \
if((x + 1) == last_slot) break; \
[[fallthrough]]
#define C10(x) C(x); C(x+1); C(x+2); C(x+3); C(x+4); C(x+5); C(x+6); C(x+7); C(x+8); C(x+9);
switch(first_slot) {
C10(0); C10(10); C10(20); C10(30); C10(40);
C10(50); C10(60); C10(70); C10(80); C10(90);
C10(100); C10(110); C10(120); C10(130); C10(140);
C10(150); C10(160); C10(170); C10(180); C10(190);
C10(200); C10(210);
C(220); C(221); C(222); C(223); C(224);
C(225); C(226); C(227); C(228);
// break;
default: assert(false);
}
#undef C
return -1;
}
template <bool stop_on_cpu> Chipset::Changes Chipset::run(HalfCycles length) {
Changes changes;
// This code uses 'pixels' as a measure, which is equivalent to one pixel clock time,
// or half a cycle.
auto pixels_remaining = length.as<int>();
// Update raster position, spooling out graphics.
while(pixels_remaining) {
// Determine number of pixels left on this line.
const int line_pixels = std::min(pixels_remaining, (line_length_ * 4) - line_cycle_);
const int start_slot = line_cycle_ >> 2;
const int end_slot = (line_cycle_ + line_pixels) >> 2;
const int actual_slots = advance_slots<stop_on_cpu>(start_slot, end_slot);
if(stop_on_cpu && actual_slots >= 0) {
// Run until the end of the named slot.
if(actual_slots) {
const int actual_line_pixels =
(4 - (line_cycle_ & 3)) + ((actual_slots - 1) << 2);
line_cycle_ += actual_line_pixels;
changes.duration += HalfCycles(actual_line_pixels);
}
// Just ensure an exit.
pixels_remaining = 0;
} else {
line_cycle_ += line_pixels;
changes.duration += HalfCycles(line_pixels);
pixels_remaining -= line_pixels;
}
// Advance intraline counter and pcoossibly ripple upwards into
// lines and fields.
if(line_cycle_ == (line_length_ * 4)) {
++changes.hsyncs;
line_cycle_ = 0;
++y_;
fetch_vertical_ |= y_ == display_window_start_[1];
fetch_vertical_ &= y_ != display_window_stop_[1];
if(did_fetch_) {
// TODO: find out when modulos are actually applied, since
// they're dynamically programmable.
bitplanes_.do_end_of_line();
did_fetch_ = false;
}
if(y_ == frame_height_) {
++changes.vsyncs;
interrupt_requests_ |= InterruptMask<InterruptFlag::VerticalBlank>::value;
update_interrupts();
y_ = 0;
// TODO: the manual is vague on when this happens. Try to find out.
copper_.reload<0>();
}
}
assert(line_cycle_ < line_length_ * 4);
}
changes.interrupt_level = interrupt_level_;
return changes;
}
void Chipset::post_bitplanes(const BitplaneData &data) {
// TODO: should probably store for potential delay?
current_bitplanes_ = data;
// current_bitplanes_[0] = 0xaaaa;
// current_bitplanes_[1] = 0x3333;
// current_bitplanes_[2] = 0x4444;
// current_bitplanes_[3] = 0x1111;
// Convert to future pixels.
// const int odd_offset = line_cycle_ + odd_delay_;
// const int even_offset = line_cycle_ + odd_delay_;
// for(int x = 0; x < 16; x++) {
// const uint16_t mask = uint16_t(1 << x);
// even_playfield_[x + even_offset] = uint8_t(
// ((data[0] & mask) | ((data[2] & mask) << 1) | ((data[4] & mask) << 2)) >> x
// );
// odd_playfield_[x + odd_offset] = uint8_t(
// ((data[1] & mask) | ((data[3] & mask) << 1) | ((data[5] & mask) << 2)) >> x
// );
// }
}
void Chipset::update_interrupts() {
interrupt_level_ = 0;
const uint16_t enabled_requests = interrupt_enable_ & interrupt_requests_ & 0x3fff;
if(enabled_requests && (interrupt_enable_ & 0x4000)) {
if(enabled_requests & InterruptMask<InterruptFlag::External>::value) {
interrupt_level_ = 6;
} else if(enabled_requests & InterruptMask<InterruptFlag::SerialPortReceive, InterruptFlag::DiskSyncMatch>::value) {
interrupt_level_ = 5;
} else if(enabled_requests & InterruptMask<InterruptFlag::AudioChannel0, InterruptFlag::AudioChannel1, InterruptFlag::AudioChannel2, InterruptFlag::AudioChannel3>::value) {
interrupt_level_ = 4;
} else if(enabled_requests & InterruptMask<InterruptFlag::Copper, InterruptFlag::VerticalBlank, InterruptFlag::Blitter>::value) {
interrupt_level_ = 3;
} else if(enabled_requests & InterruptMask<InterruptFlag::IOPortsAndTimers>::value) {
interrupt_level_ = 2;
} else if(enabled_requests & InterruptMask<InterruptFlag::SerialPortTransmit, InterruptFlag::DiskBlock, InterruptFlag::Software>::value) {
interrupt_level_ = 1;
}
}
}
void Chipset::perform(const CPU::MC68000::Microcycle &cycle) {
using Microcycle = CPU::MC68000::Microcycle;
#define RW(address) address | ((cycle.operation & Microcycle::Read) << 12)
#define Read(address) address | (Microcycle::Read << 12)
#define Write(address) address
#define ApplySetClear(target) { \
const uint16_t value = cycle.value16(); \
if(value & 0x8000) { \
target |= (value & 0x7fff); \
} else { \
target &= ~(value & 0x7fff); \
} \
}
const uint32_t register_address = *cycle.address & 0x1fe;
switch(RW(register_address)) {
default:
LOG("Unimplemented chipset " << (cycle.operation & Microcycle::Read ? "read" : "write") << " " << PADHEX(6) << *cycle.address);
assert(false);
break;
// Raster position.
case Read(0x004): {
const uint16_t position = uint16_t(y_ >> 8);
LOG("Read vertical position high " << PADHEX(4) << position);
cycle.set_value16(position);
} break;
case Read(0x006): {
// const uint16_t position = uint16_t(((line_cycle_ << 6) & 0xff00) | (y_ & 0x00ff));
const uint16_t position = 0xd1ef; // TODO: !!!
LOG("Read position low " << PADHEX(4) << position);
cycle.set_value16(position);
} break;
case Write(0x02a):
LOG("TODO: write vertical position high " << PADHEX(4) << cycle.value16());
break;
case Write(0x02c):
LOG("TODO: write vertical position low " << PADHEX(4) << cycle.value16());
break;
// Joystick/mouse input.
case Read(0x00a):
case Read(0x00c):
LOG("TODO: Joystick/mouse position " << PADHEX(4) << *cycle.address);
cycle.set_value16(0x8080);
break;
case Write(0x034):
LOG("TODO: pot port start");
break;
case Read(0x016):
LOG("TODO: pot port read");
cycle.set_value16(0xff00);
break;
// Disk DMA.
case Write(0x020): disk_.set_pointer<0, 16>(cycle.value16()); break;
case Write(0x022): disk_.set_pointer<0, 0>(cycle.value16()); break;
case Write(0x024): disk_.set_length(cycle.value16()); break;
case Write(0x026):
LOG("TODO: disk DMA; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
break;
// Refresh.
case Write(0x028):
LOG("TODO (maybe): refresh; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
break;
// Serial port.
case Read(0x018):
LOG("TODO: serial data and status");
cycle.set_value16(0x3000); // i.e. transmit buffer empty.
break;
case Write(0x030):
LOG("TODO: serial data: " << PADHEX(4) << cycle.value16());
break;
case Write(0x032):
LOG("TODO: serial control: " << PADHEX(4) << cycle.value16());
serial_.set_control(cycle.value16());
break;
// DMA management.
case Read(0x002):
LOG("DMA control and status read");
cycle.set_value16(dma_control_ | blitter_.get_status());
break;
case Write(0x096):
ApplySetClear(dma_control_);
LOG("DMA control modified by " << PADHEX(4) << cycle.value16() << "; is now " << std::bitset<16>{dma_control_});
break;
// Interrupts.
case Write(0x09a):
ApplySetClear(interrupt_enable_);
update_interrupts();
LOG("Interrupt enable mask modified by " << PADHEX(4) << cycle.value16() << "; is now " << std::bitset<16>{interrupt_enable_});
break;
case Read(0x01c):
cycle.set_value16(interrupt_enable_);
LOG("Interrupt enable mask read: " << PADHEX(4) << interrupt_enable_);
break;
case Write(0x09c):
ApplySetClear(interrupt_requests_);
update_interrupts();
LOG("Interrupt request modified by " << PADHEX(4) << cycle.value16() << "; is now " << std::bitset<16>{interrupt_requests_});
break;
case Read(0x01e):
cycle.set_value16(interrupt_requests_);
LOG("Interrupt requests read: " << PADHEX(4) << interrupt_requests_);
break;
// Display management.
case Write(0x08e): {
const uint16_t value = cycle.value16();
display_window_start_[0] = value & 0xff;
display_window_start_[1] = value >> 8;
LOG("Display window start set to " << std::dec << display_window_start_[0] << ", " << display_window_start_[1]);
} break;
case Write(0x090): {
const uint16_t value = cycle.value16();
display_window_stop_[0] = 0x100 | (value & 0xff);
display_window_stop_[1] = value >> 8;
display_window_stop_[1] |= ((value >> 7) & 0x100) ^ 0x100;
LOG("Display window stop set to " << std::dec << display_window_stop_[0] << ", " << display_window_stop_[1]);
} break;
case Write(0x092):
fetch_window_[0] = uint16_t((cycle.value16() & 0xfc) << 1);
LOG("Fetch window start set to " << std::dec << fetch_window_[0]);
break;
case Write(0x094):
fetch_window_[1] = uint16_t((cycle.value16() & 0xfc) << 1);
LOG("Fetch window stop set to " << std::dec << fetch_window_[1]);
break;
// Bitplanes.
case Write(0x0e0): bitplanes_.set_pointer<0, 16>(cycle.value16()); break;
case Write(0x0e2): bitplanes_.set_pointer<0, 0>(cycle.value16()); break;
case Write(0x0e4): bitplanes_.set_pointer<1, 16>(cycle.value16()); break;
case Write(0x0e6): bitplanes_.set_pointer<1, 0>(cycle.value16()); break;
case Write(0x0e8): bitplanes_.set_pointer<2, 16>(cycle.value16()); break;
case Write(0x0ea): bitplanes_.set_pointer<2, 0>(cycle.value16()); break;
case Write(0x0ec): bitplanes_.set_pointer<3, 16>(cycle.value16()); break;
case Write(0x0ee): bitplanes_.set_pointer<3, 0>(cycle.value16()); break;
case Write(0x0f0): bitplanes_.set_pointer<4, 16>(cycle.value16()); break;
case Write(0x0f2): bitplanes_.set_pointer<4, 0>(cycle.value16()); break;
case Write(0x0f4): bitplanes_.set_pointer<5, 16>(cycle.value16()); break;
case Write(0x0f6): bitplanes_.set_pointer<5, 0>(cycle.value16()); break;
case Write(0x102): {
const uint8_t delay = cycle.value8_low();
odd_delay_ = delay & 0x0f;
even_delay_ = delay >> 4;
} break;
case Write(0x100):
bitplanes_.set_control(cycle.value16());
is_high_res_ = cycle.value16() & 0x8000;
break;
case Write(0x104):
case Write(0x106):
LOG("TODO: Bitplane control; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
break;
case Write(0x108):
case Write(0x10a):
LOG("TODO: Bitplane modulo; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
break;
case Write(0x110):
case Write(0x112):
case Write(0x114):
case Write(0x116):
case Write(0x118):
case Write(0x11a):
LOG("TODO: Bitplane data; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
break;
case Read(0x110): case Read(0x112): case Read(0x114): case Read(0x116):
case Read(0x118): case Read(0x11a):
cycle.set_value16(0xffff);
LOG("Invalid read at " << PADHEX(6) << *cycle.address);
break;
// Blitter.
case Write(0x040): blitter_.set_control(0, cycle.value16()); break;
case Write(0x042): blitter_.set_control(1, cycle.value16()); break;
case Write(0x044): blitter_.set_first_word_mask(cycle.value16()); break;
case Write(0x046): blitter_.set_last_word_mask(cycle.value16()); break;
case Write(0x048): blitter_.set_pointer<2, 16>(cycle.value16()); break;
case Write(0x04a): blitter_.set_pointer<2, 0>(cycle.value16()); break;
case Write(0x04c): blitter_.set_pointer<1, 16>(cycle.value16()); break;
case Write(0x04e): blitter_.set_pointer<1, 0>(cycle.value16()); break;
case Write(0x050): blitter_.set_pointer<0, 16>(cycle.value16()); break;
case Write(0x052): blitter_.set_pointer<0, 0>(cycle.value16()); break;
case Write(0x054): blitter_.set_pointer<3, 16>(cycle.value16()); break;
case Write(0x056): blitter_.set_pointer<3, 0>(cycle.value16()); break;
case Write(0x058): blitter_.set_size(cycle.value16()); break;
case Write(0x05a): blitter_.set_minterms(cycle.value16()); break;
case Write(0x05c): blitter_.set_vertical_size(cycle.value16()); break;
case Write(0x05e): blitter_.set_horizontal_size(cycle.value16()); break;
case Write(0x060): blitter_.set_modulo(2, cycle.value16()); break;
case Write(0x062): blitter_.set_modulo(1, cycle.value16()); break;
case Write(0x064): blitter_.set_modulo(0, cycle.value16()); break;
case Write(0x066): blitter_.set_modulo(3, cycle.value16()); break;
case Write(0x070): blitter_.set_data(2, cycle.value16()); break;
case Write(0x072): blitter_.set_data(1, cycle.value16()); break;
case Write(0x074): blitter_.set_data(0, cycle.value16()); break;
// Paula.
case Write(0x09e):
case Write(0x0a0): case Write(0x0a2): case Write(0x0a4): case Write(0x0a6):
case Write(0x0a8): case Write(0x0aa):
case Write(0x0b0): case Write(0x0b2): case Write(0x0b4): case Write(0x0b6):
case Write(0x0b8): case Write(0x0ba):
case Write(0x0c0): case Write(0x0c2): case Write(0x0c4): case Write(0x0c6):
case Write(0x0c8): case Write(0x0ca):
case Write(0x0d0): case Write(0x0d2): case Write(0x0d4): case Write(0x0d6):
case Write(0x0d8): case Write(0x0da):
LOG("TODO: Paula write " << PADHEX(2) << (*cycle.address & 0xff) << " " << PADHEX(4) << cycle.value16());
break;
// Copper.
case Write(0x02e):
LOG("Coprocessor control " << PADHEX(4) << cycle.value16());
copper_.set_control(cycle.value16());
break;
case Write(0x080):
LOG("Coprocessor first location register high " << PADHEX(4) << cycle.value16());
copper_.set_pointer<0, 16>(cycle.value16());
break;
case Write(0x082):
LOG("Coprocessor first location register low " << PADHEX(4) << cycle.value16());
copper_.set_pointer<0, 0>(cycle.value16());
break;
case Write(0x084):
LOG("Coprocessor second location register high " << PADHEX(4) << cycle.value16());
copper_.set_pointer<1, 16>(cycle.value16());
break;
case Write(0x086):
LOG("Coprocessor second location register low " << PADHEX(4) << cycle.value16());
copper_.set_pointer<1, 0>(cycle.value16());
break;
case Write(0x088): case Read(0x088):
LOG("Coprocessor restart at first location");
copper_.reload<0>();
break;
case Write(0x08a): case Read(0x08a):
LOG("Coprocessor restart at second location");
copper_.reload<1>();
break;
case Write(0x08c):
LOG("TODO: coprocessor instruction fetch identity " << PADHEX(4) << cycle.value16());
break;
// Sprites.
#define Sprite(index, pointer, position) \
case Write(pointer + 0): sprites_[index].set_pointer(16, cycle.value16()); break; \
case Write(pointer + 2): sprites_[index].set_pointer(0, cycle.value16()); break; \
case Write(position + 0): sprites_[index].set_start_position(cycle.value16()); break; \
case Write(position + 2): sprites_[index].set_stop_and_control(cycle.value16()); break; \
case Write(position + 4): sprites_[index].set_image_data(0, cycle.value16()); break; \
case Write(position + 6): sprites_[index].set_image_data(1, cycle.value16()); break;
Sprite(0, 0x120, 0x140);
Sprite(1, 0x124, 0x148);
Sprite(2, 0x128, 0x150);
Sprite(3, 0x12c, 0x158);
Sprite(4, 0x130, 0x160);
Sprite(5, 0x134, 0x168);
Sprite(6, 0x138, 0x170);
Sprite(7, 0x13c, 0x178);
#undef Sprite
// Colour palette.
case Write(0x180): case Write(0x182): case Write(0x184): case Write(0x186):
case Write(0x188): case Write(0x18a): case Write(0x18c): case Write(0x18e):
case Write(0x190): case Write(0x192): case Write(0x194): case Write(0x196):
case Write(0x198): case Write(0x19a): case Write(0x19c): case Write(0x19e):
case Write(0x1a0): case Write(0x1a2): case Write(0x1a4): case Write(0x1a6):
case Write(0x1a8): case Write(0x1aa): case Write(0x1ac): case Write(0x1ae):
case Write(0x1b0): case Write(0x1b2): case Write(0x1b4): case Write(0x1b6):
case Write(0x1b8): case Write(0x1ba): case Write(0x1bc): case Write(0x1be): {
LOG("Colour palette; " << PADHEX(4) << cycle.value16() << " to " << *cycle.address);
// Store once in regular, linear order.
const auto entry_address = (register_address - 0x180) >> 1;
uint8_t *const entry = reinterpret_cast<uint8_t *>(&palette_[entry_address]);
entry[0] = cycle.value8_high();
entry[1] = cycle.value8_low();
// Also store in bit-swizzled order. In this array,
// instead of being indexed as [b4 b3 b2 b1 b0], index
// as [b3 b1 b4 b2 b0]. This is related to the dual/single-playfield
// decision being made relatively late in the planar -> chunky
// conversion performed by this implementation.
const auto swizzled_address =
(entry_address&0x01) |
((entry_address&0x02) << 2) |
((entry_address&0x04) >> 1) |
((entry_address&0x08) << 1) |
((entry_address&0x10) >> 2);
uint8_t *const swizzled_entry = reinterpret_cast<uint8_t *>(&swizzled_palette_[swizzled_address]);
swizzled_entry[0] = cycle.value8_high();
swizzled_entry[1] = cycle.value8_low();
} break;
}
#undef ApplySetClear
#undef Write
#undef Read
#undef RW
}
// MARK: - Bitplanes.
bool Chipset::Bitplanes::advance(int cycle) {
// TODO: possibly dispatch a BitplaneData.
// The chipset has responsibility for applying a delay,
// and the pixel-level start/stop boundaries.
#define BIND_CYCLE(offset, plane) \
case offset: \
if(plane_count_ > plane) { \
next[plane] = ram_[pointer_[plane] & ram_mask_]; \
++pointer_[plane]; \
if constexpr (!plane) { \
chipset_.post_bitplanes(next); \
} \
return true; \
} \
return false;
if(is_high_res_) {
// TODO: I'm unclear whether this is correct, or merely
// an artefact of the way the Hardware Reference Manual
// depicts per-line DMA responsibilities.
if(cycle < 4) {
return false;
}
switch(cycle&7) {
default: return false;
BIND_CYCLE(0, 3);
BIND_CYCLE(1, 1);
BIND_CYCLE(2, 2);
BIND_CYCLE(3, 0);
BIND_CYCLE(4, 3);
BIND_CYCLE(5, 1);
BIND_CYCLE(6, 2);
BIND_CYCLE(7, 0);
}
} else {
switch(cycle&7) {
default: return false;
BIND_CYCLE(1, 3);
BIND_CYCLE(2, 5);
BIND_CYCLE(3, 1);
BIND_CYCLE(5, 2);
BIND_CYCLE(6, 4);
BIND_CYCLE(7, 0);
}
}
return false;
}
void Chipset::Bitplanes::do_end_of_line() {
// TODO: apply modulos.
}
void Chipset::Bitplanes::set_control(uint16_t control) {
is_high_res_ = control & 0x8000;
plane_count_ = (control >> 12) & 7;
// TODO: who really has responsibility for clearing the other
// bit plane fields?
std::fill(next.begin() + plane_count_, next.end(), 0);
if(plane_count_ == 7) {
plane_count_ = 4;
}
}
// MARK: - Sprites.
void Chipset::Sprite::set_pointer(int shift, uint16_t value) {
LOG("Sprite pointer with shift " << std::dec << shift << " to " << PADHEX(4) << value);
}
void Chipset::Sprite::set_start_position(uint16_t value) {
LOG("Sprite start position " << PADHEX(4) << value);
}
void Chipset::Sprite::set_stop_and_control(uint16_t value) {
LOG("Sprite stop and control " << PADHEX(4) << value);
}
void Chipset::Sprite::set_image_data(int slot, uint16_t value) {
LOG("Sprite image data " << slot << " to " << PADHEX(4) << value);
}
// MARK: - Disk.
bool Chipset::DiskDMA::advance() {
if(!dma_enable_) return false;
if(!write_) {
// TODO: run an actual PLL, collect actual disk data.
if(length_) {
ram_[pointer_[0] & ram_mask_] = 0xffff;
++pointer_[0];
--length_;
if(!length_) {
chipset_.posit_interrupt(InterruptFlag::DiskBlock);
}
return true;
}
}
return false;
}
// MARK: - CRT connection.
void Chipset::set_scan_target(Outputs::Display::ScanTarget *scan_target) {
crt_.set_scan_target(scan_target);
}
Outputs::Display::ScanStatus Chipset::get_scaled_scan_status() const {
return crt_.get_scaled_scan_status();
}
void Chipset::set_display_type(Outputs::Display::DisplayType type) {
crt_.set_display_type(type);
}
Outputs::Display::DisplayType Chipset::get_display_type() const {
return crt_.get_display_type();
}