1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-23 03:32:32 +00:00
CLK/Machines/Apple/Macintosh/Macintosh.cpp
2021-04-04 15:37:07 -04:00

869 lines
28 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.

//
// Macintosh.cpp
// Clock Signal
//
// Created by Thomas Harte on 03/05/2019.
// Copyright © 2019 Thomas Harte. All rights reserved.
//
#include "Macintosh.hpp"
#include <array>
#include "DeferredAudio.hpp"
#include "DriveSpeedAccumulator.hpp"
#include "Keyboard.hpp"
#include "Video.hpp"
#include "../../MachineTypes.hpp"
#include "../../../Activity/Source.hpp"
#include "../../../Configurable/Configurable.hpp"
#include "../../../Inputs/QuadratureMouse/QuadratureMouse.hpp"
#include "../../../Outputs/Log.hpp"
#include "../../../ClockReceiver/JustInTime.hpp"
#include "../../../ClockReceiver/ClockingHintSource.hpp"
#include "../../../Configurable/StandardOptions.hpp"
//#define LOG_TRACE
#include "../../../Components/5380/ncr5380.hpp"
#include "../../../Components/6522/6522.hpp"
#include "../../../Components/8530/z8530.hpp"
#include "../../../Components/AppleClock/AppleClock.hpp"
#include "../../../Components/DiskII/IWM.hpp"
#include "../../../Components/DiskII/MacintoshDoubleDensityDrive.hpp"
#include "../../../Processors/68000/68000.hpp"
#include "../../../Storage/MassStorage/SCSI/SCSI.hpp"
#include "../../../Storage/MassStorage/SCSI/DirectAccessDevice.hpp"
#include "../../../Storage/MassStorage/Encodings/MacintoshVolume.hpp"
#include "../../../Analyser/Static/Macintosh/Target.hpp"
#include "../../Utility/MemoryPacker.hpp"
#include "../../Utility/MemoryFuzzer.hpp"
namespace {
constexpr int CLOCK_RATE = 7833600;
}
namespace Apple {
namespace Macintosh {
template <Analyser::Static::Macintosh::Target::Model model> class ConcreteMachine:
public Machine,
public MachineTypes::TimedMachine,
public MachineTypes::ScanProducer,
public MachineTypes::AudioProducer,
public MachineTypes::MediaTarget,
public MachineTypes::MouseMachine,
public MachineTypes::MappedKeyboardMachine,
public CPU::MC68000::BusHandler,
public Zilog::SCC::z8530::Delegate,
public Activity::Source,
public Configurable::Device,
public DriveSpeedAccumulator::Delegate,
public ClockingHint::Observer {
public:
using Target = Analyser::Static::Macintosh::Target;
ConcreteMachine(const Target &target, const ROMMachine::ROMFetcher &rom_fetcher) :
MachineTypes::MappedKeyboardMachine({
Inputs::Keyboard::Key::LeftShift, Inputs::Keyboard::Key::RightShift,
Inputs::Keyboard::Key::LeftOption, Inputs::Keyboard::Key::RightOption,
Inputs::Keyboard::Key::LeftMeta, Inputs::Keyboard::Key::RightMeta,
}),
mc68000_(*this),
iwm_(CLOCK_RATE),
video_(audio_, drive_speed_accumulator_),
via_(via_port_handler_),
via_port_handler_(*this, clock_, keyboard_, audio_, iwm_, mouse_),
scsi_bus_(CLOCK_RATE * 2),
scsi_(scsi_bus_, CLOCK_RATE * 2),
hard_drive_(scsi_bus_, 6 /* SCSI ID */),
drives_{
{CLOCK_RATE, model >= Analyser::Static::Macintosh::Target::Model::Mac512ke},
{CLOCK_RATE, model >= Analyser::Static::Macintosh::Target::Model::Mac512ke}
},
mouse_(1) {
// Select a ROM name and determine the proper ROM and RAM sizes
// based on the machine model.
using Model = Analyser::Static::Macintosh::Target::Model;
const std::string machine_name = "Macintosh";
uint32_t ram_size, rom_size;
std::vector<ROMMachine::ROM> rom_descriptions;
switch(model) {
default:
case Model::Mac128k:
ram_size = 128*1024;
rom_size = 64*1024;
rom_descriptions.emplace_back(machine_name, "the Macintosh 128k ROM", "mac128k.rom", 64*1024, 0x6d0c8a28);
break;
case Model::Mac512k:
ram_size = 512*1024;
rom_size = 64*1024;
rom_descriptions.emplace_back(machine_name, "the Macintosh 512k ROM", "mac512k.rom", 64*1024, 0xcf759e0d);
break;
case Model::Mac512ke:
case Model::MacPlus: {
ram_size = ((model == Model::MacPlus) ? 4096 : 512)*1024;
rom_size = 128*1024;
const std::initializer_list<uint32_t> crc32s = { 0x4fa5b399, 0x7cacd18f, 0xb2102e8e };
rom_descriptions.emplace_back(machine_name, "the Macintosh Plus ROM", "macplus.rom", 128*1024, crc32s);
} break;
}
ram_mask_ = ram_size - 1;
rom_mask_ = rom_size - 1;
ram_.resize(ram_size);
video_.set_ram(reinterpret_cast<uint16_t *>(ram_.data()), ram_mask_ >> 1);
// Grab a copy of the ROM and convert it into big-endian data.
const auto roms = rom_fetcher(rom_descriptions);
if(!roms[0]) {
throw ROMMachine::Error::MissingROMs;
}
roms[0]->resize(rom_size);
Memory::PackBigEndian16(*roms[0], rom_);
// Randomise memory contents.
Memory::Fuzz(ram_);
// Attach the drives to the IWM.
iwm_->set_drive(0, &drives_[0]);
iwm_->set_drive(1, &drives_[1]);
// If they are 400kb drives, also attach them to the drive-speed accumulator.
if(!drives_[0].is_800k() || !drives_[1].is_800k()) {
drive_speed_accumulator_.set_delegate(this);
}
// Make sure interrupt changes from the SCC are observed.
scc_.set_delegate(this);
// Also watch for changes in clocking requirement from the SCSI chip.
if constexpr (model == Analyser::Static::Macintosh::Target::Model::MacPlus) {
scsi_bus_.set_clocking_hint_observer(this);
}
// The Mac runs at 7.8336mHz.
set_clock_rate(double(CLOCK_RATE));
audio_.speaker.set_input_rate(float(CLOCK_RATE) / 2.0f);
// Insert any supplied media.
insert_media(target.media);
// Set the immutables of the memory map.
setup_memory_map();
}
~ConcreteMachine() {
audio_.queue.flush();
}
void set_scan_target(Outputs::Display::ScanTarget *scan_target) final {
video_.set_scan_target(scan_target);
}
Outputs::Display::ScanStatus get_scaled_scan_status() const final {
return video_.get_scaled_scan_status();
}
Outputs::Speaker::Speaker *get_speaker() final {
return &audio_.speaker;
}
void run_for(const Cycles cycles) final {
mc68000_.run_for(cycles);
}
using Microcycle = CPU::MC68000::Microcycle;
forceinline HalfCycles perform_bus_operation(const Microcycle &cycle, int) {
// Advance time.
advance_time(cycle.length);
// A null cycle leaves nothing else to do.
if(!(cycle.operation & (Microcycle::NewAddress | Microcycle::SameAddress))) return HalfCycles(0);
// Grab the address.
auto address = cycle.host_endian_byte_address();
// Everything above E0 0000 is signalled as being on the peripheral bus.
mc68000_.set_is_peripheral_address(address >= 0xe0'0000);
// All code below deals only with reads and writes — cycles in which a
// data select is active. So quit now if this is not the active part of
// a read or write.
//
// The 68000 uses 6800-style autovectored interrupts, so the mere act of
// having set VPA above deals with those given that the generated address
// for interrupt acknowledge cycles always has all bits set except the
// lowest explicit address lines.
if(!cycle.data_select_active() || (cycle.operation & Microcycle::InterruptAcknowledge)) return HalfCycles(0);
// Grab the word-precision address being accessed.
uint8_t *memory_base = nullptr;
HalfCycles delay;
switch(memory_map_[address >> 17]) {
default: assert(false);
case BusDevice::Unassigned:
fill_unmapped(cycle);
return delay;
case BusDevice::VIA: {
if(*cycle.address & 1) {
fill_unmapped(cycle);
} else {
const int register_address = address >> 9;
// VIA accesses are via address 0xefe1fe + register*512,
// which at word precision is 0x77f0ff + register*256.
if(cycle.operation & Microcycle::Read) {
cycle.value->halves.low = via_.read(register_address);
} else {
via_.write(register_address, cycle.value->halves.low);
}
if(cycle.operation & Microcycle::SelectWord) cycle.value->halves.high = 0xff;
}
} return delay;
case BusDevice::PhaseRead: {
if(cycle.operation & Microcycle::Read) {
cycle.value->halves.low = phase_ & 7;
}
if(cycle.operation & Microcycle::SelectWord) cycle.value->halves.high = 0xff;
} return delay;
case BusDevice::IWM: {
if(*cycle.address & 1) {
const int register_address = address >> 9;
// The IWM; this is a purely polled device, so can be run on demand.
if(cycle.operation & Microcycle::Read) {
cycle.value->halves.low = iwm_->read(register_address);
} else {
iwm_->write(register_address, cycle.value->halves.low);
}
if(cycle.operation & Microcycle::SelectWord) cycle.value->halves.high = 0xff;
} else {
fill_unmapped(cycle);
}
} return delay;
case BusDevice::SCSI: {
const int register_address = address >> 4;
const bool dma_acknowledge = address & 0x200;
// Even accesses = read; odd = write.
if(*cycle.address & 1) {
// Odd access => this is a write. Data will be in the upper byte.
if(cycle.operation & Microcycle::Read) {
scsi_.write(register_address, 0xff, dma_acknowledge);
} else {
if(cycle.operation & Microcycle::SelectWord) {
scsi_.write(register_address, cycle.value->halves.high, dma_acknowledge);
} else {
scsi_.write(register_address, cycle.value->halves.low, dma_acknowledge);
}
}
} else {
// Even access => this is a read.
if(cycle.operation & Microcycle::Read) {
const auto result = scsi_.read(register_address, dma_acknowledge);
if(cycle.operation & Microcycle::SelectWord) {
// Data is loaded on the top part of the bus only.
cycle.value->full = uint16_t((result << 8) | 0xff);
} else {
cycle.value->halves.low = result;
}
}
}
} return delay;
case BusDevice::SCCReadResetPhase: {
// Any word access here adjusts phase.
if(cycle.operation & Microcycle::SelectWord) {
adjust_phase();
} else {
// A0 = 1 => reset; A0 = 0 => read.
if(*cycle.address & 1) {
scc_.reset();
if(cycle.operation & Microcycle::Read) {
cycle.value->halves.low = 0xff;
}
} else {
const auto read = scc_.read(int(address >> 1));
if(cycle.operation & Microcycle::Read) {
cycle.value->halves.low = read;
}
}
}
} return delay;
case BusDevice::SCCWrite: {
// Any word access here adjusts phase.
if(cycle.operation & Microcycle::SelectWord) {
adjust_phase();
} else {
if(*cycle.address & 1) {
if(cycle.operation & Microcycle::Read) {
scc_.write(int(address >> 1), 0xff);
cycle.value->halves.low = 0xff;
} else {
scc_.write(int(address >> 1), cycle.value->halves.low);
}
} else {
fill_unmapped(cycle);
}
}
} return delay;
case BusDevice::RAM: {
// This is coupled with the Macintosh implementation of video; the magic
// constant should probably be factored into the Video class.
// It embodies knowledge of the fact that video (and audio) will always
// be fetched from the final $d900 bytes of memory.
// (And that ram_mask_ = ram size - 1).
if(address > ram_mask_ - 0xd900)
update_video();
memory_base = ram_.data();
address &= ram_mask_;
// Apply a delay due to video contention if applicable; scheme applied:
// only every other access slot is available during the period of video
// output. I believe this to be correct for the 128k, 512k and Plus.
// More research to do on other models.
if(video_is_outputting() && ram_subcycle_ < 8) {
delay = HalfCycles(8 - ram_subcycle_);
advance_time(delay);
}
} break;
case BusDevice::ROM: {
if(!(cycle.operation & Microcycle::Read)) return delay;
memory_base = rom_;
address &= rom_mask_;
} break;
}
// If control has fallen through to here, the access is either a read from ROM, or a read or write to RAM.
switch(cycle.operation & (Microcycle::SelectWord | Microcycle::SelectByte | Microcycle::Read)) {
default:
break;
case Microcycle::SelectWord | Microcycle::Read:
cycle.value->full = *reinterpret_cast<uint16_t *>(&memory_base[address]);
break;
case Microcycle::SelectByte | Microcycle::Read:
cycle.value->halves.low = memory_base[address];
break;
case Microcycle::SelectWord:
*reinterpret_cast<uint16_t *>(&memory_base[address]) = cycle.value->full;
break;
case Microcycle::SelectByte:
memory_base[address] = cycle.value->halves.low;
break;
}
return delay;
}
void flush() {
// Flush the video before the audio queue; in a Mac the
// video is responsible for providing part of the
// audio signal, so the two aren't as distinct as in
// most machines.
update_video();
// As above: flush audio after video.
via_.flush();
audio_.queue.perform();
// This avoids deferring IWM costs indefinitely, until
// they become artbitrarily large.
iwm_.flush();
}
void set_rom_is_overlay(bool rom_is_overlay) {
ROM_is_overlay_ = rom_is_overlay;
using Model = Analyser::Static::Macintosh::Target::Model;
switch(model) {
case Model::Mac128k:
case Model::Mac512k:
case Model::Mac512ke:
populate_memory_map(0, [rom_is_overlay] (std::function<void(int target, BusDevice device)> map_to) {
// Addresses up to $80 0000 aren't affected by this bit.
if(rom_is_overlay) {
// Up to $60 0000 mirrors of the ROM alternate with unassigned areas every $10 0000 byes.
for(int c = 0; c < 0x600000; c += 0x100000) {
map_to(c + 0x100000, (c & 0x100000) ? BusDevice::Unassigned : BusDevice::ROM);
}
map_to(0x800000, BusDevice::RAM);
} else {
map_to(0x400000, BusDevice::RAM);
map_to(0x500000, BusDevice::ROM);
map_to(0x800000, BusDevice::Unassigned);
}
});
break;
case Model::MacPlus:
populate_memory_map(0, [rom_is_overlay] (std::function<void(int target, BusDevice device)> map_to) {
// Addresses up to $80 0000 aren't affected by this bit.
if(rom_is_overlay) {
for(int c = 0; c < 0x580000; c += 0x20000) {
map_to(c + 0x20000, ((c & 0x100000) || (c & 0x20000)) ? BusDevice::Unassigned : BusDevice::ROM);
}
map_to(0x600000, BusDevice::SCSI);
map_to(0x800000, BusDevice::RAM);
} else {
map_to(0x400000, BusDevice::RAM);
for(int c = 0x400000; c < 0x580000; c += 0x20000) {
map_to(c + 0x20000, ((c & 0x100000) || (c & 0x20000)) ? BusDevice::Unassigned : BusDevice::ROM);
}
map_to(0x600000, BusDevice::SCSI);
map_to(0x800000, BusDevice::Unassigned);
}
});
break;
}
}
bool video_is_outputting() {
return video_.is_outputting(time_since_video_update_);
}
void set_use_alternate_buffers(bool use_alternate_screen_buffer, bool use_alternate_audio_buffer) {
update_video();
video_.set_use_alternate_buffers(use_alternate_screen_buffer, use_alternate_audio_buffer);
}
bool insert_media(const Analyser::Static::Media &media) final {
if(media.disks.empty() && media.mass_storage_devices.empty())
return false;
// TODO: shouldn't allow disks to be replaced like this, as the Mac
// uses software eject. Will need to expand messaging ability of
// insert_media.
if(!media.disks.empty()) {
if(drives_[0].has_disk())
drives_[1].set_disk(media.disks[0]);
else
drives_[0].set_disk(media.disks[0]);
}
// TODO: allow this only at machine startup?
if(!media.mass_storage_devices.empty()) {
const auto volume = dynamic_cast<Storage::MassStorage::Encodings::Macintosh::Volume *>(media.mass_storage_devices.front().get());
if(volume) {
volume->set_drive_type(Storage::MassStorage::Encodings::Macintosh::DriveType::SCSI);
}
hard_drive_->set_storage(media.mass_storage_devices.front());
}
return true;
}
// MARK: Keyboard input.
KeyboardMapper *get_keyboard_mapper() final {
return &keyboard_mapper_;
}
void set_key_state(uint16_t key, bool is_pressed) final {
keyboard_.enqueue_key_state(key, is_pressed);
}
// TODO: clear all keys.
// MARK: Interrupt updates.
void did_change_interrupt_status(Zilog::SCC::z8530 *, bool) final {
update_interrupt_input();
}
void update_interrupt_input() {
// Update interrupt input.
// TODO: does this really cascade like this?
if(scc_.get_interrupt_line()) {
mc68000_.set_interrupt_level(2);
} else if(via_.get_interrupt_line()) {
mc68000_.set_interrupt_level(1);
} else {
mc68000_.set_interrupt_level(0);
}
}
// MARK: - Activity Source
void set_activity_observer(Activity::Observer *observer) final {
iwm_->set_activity_observer(observer);
if constexpr (model == Analyser::Static::Macintosh::Target::Model::MacPlus) {
scsi_bus_.set_activity_observer(observer);
}
}
// MARK: - Configuration options.
std::unique_ptr<Reflection::Struct> get_options() final {
auto options = std::make_unique<Options>(Configurable::OptionsType::UserFriendly);
options->quickboot = quickboot_;
return options;
}
void set_options(const std::unique_ptr<Reflection::Struct> &str) final {
// TODO: should this really be a runtime option?
// It should probably be a construction option.
const auto options = dynamic_cast<Options *>(str.get());
quickboot_ = options->quickboot;
using Model = Analyser::Static::Macintosh::Target::Model;
const bool is_plus_rom = model == Model::Mac512ke || model == Model::MacPlus;
if(quickboot_ && is_plus_rom) {
// Cf. Big Mess o' Wires' disassembly of the Mac Plus ROM, and the
// test at $E00. TODO: adapt as(/if?) necessary for other Macs.
ram_[0x02ae] = 0x40;
ram_[0x02af] = 0x00;
ram_[0x02b0] = 0x00;
ram_[0x02b1] = 0x00;
}
}
private:
bool quickboot_ = false;
void set_component_prefers_clocking(ClockingHint::Source *, ClockingHint::Preference) final {
scsi_bus_is_clocked_ = scsi_bus_.preferred_clocking() != ClockingHint::Preference::None;
}
void drive_speed_accumulator_set_drive_speed(DriveSpeedAccumulator *, float speed) final {
iwm_.flush();
drives_[0].set_rotation_speed(speed);
drives_[1].set_rotation_speed(speed);
}
forceinline void adjust_phase() {
++phase_;
}
forceinline void fill_unmapped(const Microcycle &cycle) {
if(!(cycle.operation & Microcycle::Read)) return;
cycle.set_value16(0xffff);
}
/// Advances all non-CPU components by @c duration half cycles.
forceinline void advance_time(HalfCycles duration) {
time_since_video_update_ += duration;
iwm_ += duration;
ram_subcycle_ = (ram_subcycle_ + duration.as_integral()) & 15;
// The VIA runs at one-tenth of the 68000's clock speed, in sync with the E clock.
// See: Guide to the Macintosh Hardware Family p149 (PDF p188). Some extra division
// may occur here in order to provide VSYNC at a proper moment.
// Possibly route vsync.
if(time_since_video_update_ < time_until_video_event_) {
via_clock_ += duration;
via_.run_for(via_clock_.divide(HalfCycles(10)));
} else {
auto via_time_base = time_since_video_update_ - duration;
auto via_cycles_outstanding = duration;
while(time_until_video_event_ < time_since_video_update_) {
const auto via_cycles = time_until_video_event_ - via_time_base;
via_time_base = HalfCycles(0);
via_cycles_outstanding -= via_cycles;
via_clock_ += via_cycles;
via_.run_for(via_clock_.divide(HalfCycles(10)));
video_.run_for(time_until_video_event_);
time_since_video_update_ -= time_until_video_event_;
time_until_video_event_ = video_.get_next_sequence_point();
via_.set_control_line_input(MOS::MOS6522::Port::A, MOS::MOS6522::Line::One, !video_.vsync());
}
via_clock_ += via_cycles_outstanding;
via_.run_for(via_clock_.divide(HalfCycles(10)));
}
// The keyboard also has a clock, albeit a very slow one — 100,000 cycles/second.
// Its clock and data lines are connected to the VIA.
keyboard_clock_ += duration;
const auto keyboard_ticks = keyboard_clock_.divide(HalfCycles(CLOCK_RATE / 100000));
if(keyboard_ticks > HalfCycles(0)) {
keyboard_.run_for(keyboard_ticks);
via_.set_control_line_input(MOS::MOS6522::Port::B, MOS::MOS6522::Line::Two, keyboard_.get_data());
via_.set_control_line_input(MOS::MOS6522::Port::B, MOS::MOS6522::Line::One, keyboard_.get_clock());
}
// Feed mouse inputs within at most 1250 cycles of each other.
if(mouse_.has_steps()) {
time_since_mouse_update_ += duration;
const auto mouse_ticks = time_since_mouse_update_.divide(HalfCycles(2500));
if(mouse_ticks > HalfCycles(0)) {
mouse_.prepare_step();
scc_.set_dcd(0, mouse_.get_channel(1) & 1);
scc_.set_dcd(1, mouse_.get_channel(0) & 1);
}
}
// TODO: SCC should be clocked at a divide-by-two, if and when it actually has
// anything connected.
// Consider updating the real-time clock.
real_time_clock_ += duration;
auto ticks = real_time_clock_.divide_cycles(Cycles(CLOCK_RATE)).as_integral();
while(ticks--) {
clock_.update();
// TODO: leave a delay between toggling the input rather than using this coupled hack.
via_.set_control_line_input(MOS::MOS6522::Port::A, MOS::MOS6522::Line::Two, true);
via_.set_control_line_input(MOS::MOS6522::Port::A, MOS::MOS6522::Line::Two, false);
}
// Update the SCSI if currently active.
if constexpr (model == Analyser::Static::Macintosh::Target::Model::MacPlus) {
if(scsi_bus_is_clocked_) scsi_bus_.run_for(duration);
}
}
forceinline void update_video() {
video_.run_for(time_since_video_update_.flush<HalfCycles>());
time_until_video_event_ = video_.get_next_sequence_point();
}
Inputs::Mouse &get_mouse() final {
return mouse_;
}
using IWMActor = JustInTimeActor<IWM>;
class VIAPortHandler: public MOS::MOS6522::PortHandler {
public:
VIAPortHandler(ConcreteMachine &machine, Apple::Clock::SerialClock &clock, Keyboard &keyboard, DeferredAudio &audio, IWMActor &iwm, Inputs::QuadratureMouse &mouse) :
machine_(machine), clock_(clock), keyboard_(keyboard), audio_(audio), iwm_(iwm), mouse_(mouse) {}
using Port = MOS::MOS6522::Port;
using Line = MOS::MOS6522::Line;
void set_port_output(Port port, uint8_t value, uint8_t) {
/*
Peripheral lines: keyboard data, interrupt configuration.
(See p176 [/215])
*/
switch(port) {
case Port::A:
/*
Port A:
b7: [input] SCC wait/request (/W/REQA and /W/REQB wired together for a logical OR)
b6: 0 = alternate screen buffer, 1 = main screen buffer
b5: floppy disk SEL state control (upper/lower head "among other things")
b4: 1 = use ROM overlay memory map, 0 = use ordinary memory map
b3: 0 = use alternate sound buffer, 1 = use ordinary sound buffer
b2b0: audio output volume
*/
iwm_->set_select(!!(value & 0x20));
machine_.set_use_alternate_buffers(!(value & 0x40), !(value&0x08));
machine_.set_rom_is_overlay(!!(value & 0x10));
audio_.flush();
audio_.audio.set_volume(value & 7);
break;
case Port::B:
/*
Port B:
b7: 0 = sound enabled, 1 = sound disabled
b6: [input] 0 = video beam in visible portion of line, 1 = outside
b5: [input] mouse y2
b4: [input] mouse x2
b3: [input] 0 = mouse button down, 1 = up
b2: 0 = real-time clock enabled, 1 = disabled
b1: clock's data-clock line
b0: clock's serial data line
*/
if(value & 0x4) clock_.abort();
else clock_.set_input(!!(value & 0x2), !!(value & 0x1));
audio_.flush();
audio_.audio.set_enabled(!(value & 0x80));
break;
}
}
uint8_t get_port_input(Port port) {
switch(port) {
case Port::A:
// printf("6522 r A\n");
return 0x00; // TODO: b7 = SCC wait/request
case Port::B:
return uint8_t(
((mouse_.get_button_mask() & 1) ? 0x00 : 0x08) |
((mouse_.get_channel(0) & 2) << 3) |
((mouse_.get_channel(1) & 2) << 4) |
(clock_.get_data() ? 0x02 : 0x00) |
(machine_.video_is_outputting() ? 0x00 : 0x40)
);
}
// Should be unreachable.
return 0xff;
}
void set_control_line_output(Port port, Line line, bool value) {
/*
Keyboard wiring (I believe):
CB2 = data (input/output)
CB1 = clock (input)
CA2 is used for receiving RTC interrupts.
CA1 is used for receiving vsync.
*/
if(port == Port::B && line == Line::Two) {
keyboard_.set_input(value);
}
else LOG("Unhandled control line output: " << (port ? 'B' : 'A') << int(line));
}
void run_for(HalfCycles duration) {
// The 6522 enjoys a divide-by-ten, so multiply back up here to make the
// divided-by-two clock the audio works on.
audio_.time_since_update += HalfCycles(duration.as_integral() * 5);
}
void flush() {
audio_.flush();
}
void set_interrupt_status(bool) {
machine_.update_interrupt_input();
}
private:
ConcreteMachine &machine_;
Apple::Clock::SerialClock &clock_;
Keyboard &keyboard_;
DeferredAudio &audio_;
IWMActor &iwm_;
Inputs::QuadratureMouse &mouse_;
};
CPU::MC68000::Processor<ConcreteMachine, true> mc68000_;
DriveSpeedAccumulator drive_speed_accumulator_;
IWMActor iwm_;
DeferredAudio audio_;
Video video_;
Apple::Clock::SerialClock clock_;
Keyboard keyboard_;
MOS::MOS6522::MOS6522<VIAPortHandler> via_;
VIAPortHandler via_port_handler_;
Zilog::SCC::z8530 scc_;
SCSI::Bus scsi_bus_;
NCR::NCR5380::NCR5380 scsi_;
SCSI::Target::Target<SCSI::DirectAccessDevice> hard_drive_;
bool scsi_bus_is_clocked_ = false;
HalfCycles via_clock_;
HalfCycles real_time_clock_;
HalfCycles keyboard_clock_;
HalfCycles time_since_video_update_;
HalfCycles time_until_video_event_;
HalfCycles time_since_mouse_update_;
bool ROM_is_overlay_ = true;
int phase_ = 1;
int ram_subcycle_ = 0;
DoubleDensityDrive drives_[2];
Inputs::QuadratureMouse mouse_;
Apple::Macintosh::KeyboardMapper keyboard_mapper_;
enum class BusDevice {
RAM, ROM, VIA, IWM, SCCWrite, SCCReadResetPhase, SCSI, PhaseRead, Unassigned
};
/// Divides the 24-bit address space up into $20000 (i.e. 128kb) segments, recording
/// which device is current mapped in each area. Keeping it in a table is a bit faster
/// than the multi-level address inspection that is otherwise required, as well as
/// simplifying slightly the handling of different models.
///
/// So: index with the top 7 bits of the 24-bit address.
BusDevice memory_map_[128];
void setup_memory_map() {
// Apply the power-up memory map, i.e. assume that ROM_is_overlay_ = true;
// start by calling into set_rom_is_overlay to seed everything up to $800000.
set_rom_is_overlay(true);
populate_memory_map(0x800000, [] (std::function<void(int target, BusDevice device)> map_to) {
map_to(0x900000, BusDevice::Unassigned);
map_to(0xa00000, BusDevice::SCCReadResetPhase);
map_to(0xb00000, BusDevice::Unassigned);
map_to(0xc00000, BusDevice::SCCWrite);
map_to(0xd00000, BusDevice::Unassigned);
map_to(0xe00000, BusDevice::IWM);
map_to(0xe80000, BusDevice::Unassigned);
map_to(0xf00000, BusDevice::VIA);
map_to(0xf80000, BusDevice::PhaseRead);
map_to(0x1000000, BusDevice::Unassigned);
});
}
void populate_memory_map(int start_address, std::function<void(std::function<void(int, BusDevice)>)> populator) {
// Define semantics for below; map_to will write from the current cursor position
// to the supplied 24-bit address, setting a particular mapped device.
int segment = start_address >> 17;
auto map_to = [&segment, this](int address, BusDevice device) {
for(; segment < address >> 17; ++segment) {
this->memory_map_[segment] = device;
}
};
populator(map_to);
}
uint32_t ram_mask_ = 0;
uint32_t rom_mask_ = 0;
uint8_t rom_[128*1024];
std::vector<uint8_t> ram_;
};
}
}
using namespace Apple::Macintosh;
Machine *Machine::Macintosh(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) {
auto *const mac_target = dynamic_cast<const Analyser::Static::Macintosh::Target *>(target);
using Model = Analyser::Static::Macintosh::Target::Model;
switch(mac_target->model) {
default:
case Model::Mac128k: return new ConcreteMachine<Model::Mac128k>(*mac_target, rom_fetcher);
case Model::Mac512k: return new ConcreteMachine<Model::Mac512k>(*mac_target, rom_fetcher);
case Model::Mac512ke: return new ConcreteMachine<Model::Mac512ke>(*mac_target, rom_fetcher);
case Model::MacPlus: return new ConcreteMachine<Model::MacPlus>(*mac_target, rom_fetcher);
}
}
Machine::~Machine() {}