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CLK/Machines/Apple/AppleII/AppleII.cpp

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//
// AppleII.cpp
// Clock Signal
//
// Created by Thomas Harte on 14/04/2018.
// Copyright 2018 Thomas Harte. All rights reserved.
//
#include "AppleII.hpp"
#include "../../../Activity/Source.hpp"
#include "../../MachineTypes.hpp"
#include "../../Utility/MemoryFuzzer.hpp"
#include "../../Utility/StringSerialiser.hpp"
#include "../../../Processors/6502/6502.hpp"
#include "../../../Components/AudioToggle/AudioToggle.hpp"
#include "../../../Components/AY38910/AY38910.hpp"
#include "../../../Outputs/Speaker/Implementation/CompoundSource.hpp"
#include "../../../Outputs/Speaker/Implementation/LowpassSpeaker.hpp"
#include "../../../Outputs/Log.hpp"
#include "AuxiliaryMemorySwitches.hpp"
#include "Card.hpp"
#include "DiskIICard.hpp"
#include "Joystick.hpp"
#include "LanguageCardSwitches.hpp"
#include "Mockingboard.hpp"
#include "SCSICard.hpp"
#include "Video.hpp"
#include "../../../Analyser/Static/AppleII/Target.hpp"
#include "../../../ClockReceiver/ForceInline.hpp"
#include "../../../Configurable/StandardOptions.hpp"
#include "../../../Storage/MassStorage/SCSI/SCSI.hpp"
#include "../../../Storage/MassStorage/SCSI/DirectAccessDevice.hpp"
#include "../../../Storage/MassStorage/Encodings/MacintoshVolume.hpp"
#include <algorithm>
#include <array>
#include <memory>
namespace {
constexpr int DiskIISlot = 6; // Apple recommended slot 6 for the (first) Disk II.
constexpr int SCSISlot = 7; // Install the SCSI card in slot 7, to one-up any connected Disk II.
constexpr int MockingboardSlot = 4; // Conventional Mockingboard slot.
// The system's master clock rate.
//
// Quick note on this:
//
// * 64 out of 65 CPU cycles last for 14 cycles of the master clock;
// * every 65th cycle lasts for 16 cycles of the master clock;
// * that keeps CPU cycles in-phase with the colour subcarrier: each line of output is 64*14 + 16 = 912 master cycles long;
// * ... and since hsync is placed to make each line 228 colour clocks long that means 4 master clocks per colour clock;
// * ... which is why all Apple II video modes are expressible as four binary outputs per colour clock;
// * ... and hence seven pixels per memory access window clock in high-res mode, 14 in double high-res, etc.
constexpr float master_clock = 14318180.0;
/// Provides an AY that runs at the CPU rate divided by 4 given an input of the master clock divided by 2,
/// allowing for stretched CPU clock cycles.
struct StretchedAYPair:
Apple::II::AYPair,
public Outputs::Speaker::BufferSource<StretchedAYPair, true> {
using AYPair::AYPair;
template <Outputs::Speaker::Action action>
void apply_samples(std::size_t number_of_samples, Outputs::Speaker::StereoSample *target) {
// (1) take 64 windows of 7 input cycles followed by one window of 8 input cycles;
// (2) after each four windows, advance the underlying AY.
//
// i.e. advance after:
//
// * 28 cycles, {16 times, then 15 times, then 15 times, then 15 times};
// * 29 cycles, once.
//
// so:
// 16, 1; 15, 1; 15, 1; 15, 1
//
// i.e. add an extra one on the 17th, 33rd, 49th and 65th ticks in a 65-tick loop.
for(std::size_t c = 0; c < number_of_samples; c++) {
++subdivider_;
if(subdivider_ == 28) {
++phase_;
subdivider_ = (phase_ & 15) ? 0 : -1;
if(phase_ == 65) phase_ = 0;
advance();
}
target[c] = level();
}
}
private:
int phase_ = 0;
int subdivider_ = 0;
};
}
namespace Apple {
namespace II {
template <Analyser::Static::AppleII::Target::Model model, bool has_mockingboard> class ConcreteMachine:
public Apple::II::Machine,
public MachineTypes::TimedMachine,
public MachineTypes::ScanProducer,
public MachineTypes::AudioProducer,
public MachineTypes::MediaTarget,
public MachineTypes::MappedKeyboardMachine,
public MachineTypes::JoystickMachine,
public CPU::MOS6502::BusHandler,
public Configurable::Device,
public Activity::Source,
public Apple::II::Card::Delegate {
private:
struct VideoBusHandler : public Apple::II::Video::BusHandler {
public:
VideoBusHandler(uint8_t *ram, uint8_t *aux_ram) : ram_(ram), aux_ram_(aux_ram) {}
void perform_read(uint16_t address, size_t count, uint8_t *base_target, uint8_t *auxiliary_target) {
memcpy(base_target, &ram_[address], count);
memcpy(auxiliary_target, &aux_ram_[address], count);
}
private:
uint8_t *ram_, *aux_ram_;
};
using Processor = CPU::MOS6502::Processor<
(model == Analyser::Static::AppleII::Target::Model::EnhancedIIe) ? CPU::MOS6502::Personality::PSynertek65C02 : CPU::MOS6502::Personality::P6502,
ConcreteMachine,
false>;
Processor m6502_;
VideoBusHandler video_bus_handler_;
Apple::II::Video::Video<VideoBusHandler, is_iie(model)> video_;
int cycles_into_current_line_ = 0;
Cycles cycles_since_video_update_;
void update_video() {
video_.run_for(cycles_since_video_update_.flush<Cycles>());
}
static constexpr int audio_divider = has_mockingboard ? 1 : 8;
void update_audio() {
speaker_.run_for(audio_queue_, cycles_since_audio_update_.divide(Cycles(audio_divider)));
}
void update_just_in_time_cards() {
if(cycles_since_card_update_ > Cycles(0)) {
for(const auto &card : just_in_time_cards_) {
card->run_for(cycles_since_card_update_, stretched_cycles_since_card_update_);
}
}
cycles_since_card_update_ = 0;
stretched_cycles_since_card_update_ = 0;
}
uint8_t ram_[65536], aux_ram_[65536];
std::vector<uint8_t> rom_;
Concurrency::AsyncTaskQueue<false> audio_queue_;
Audio::Toggle audio_toggle_;
StretchedAYPair ays_;
using SourceT =
std::conditional_t<has_mockingboard, Outputs::Speaker::CompoundSource<StretchedAYPair, Audio::Toggle>, Audio::Toggle>;
using LowpassT = Outputs::Speaker::PullLowpass<SourceT>;
Outputs::Speaker::CompoundSource<StretchedAYPair, Audio::Toggle> mixer_;
Outputs::Speaker::PullLowpass<SourceT> speaker_;
Cycles cycles_since_audio_update_;
constexpr SourceT &lowpass_source() {
if constexpr (has_mockingboard) {
return mixer_;
} else {
return audio_toggle_;
}
}
// MARK: - Cards
static constexpr size_t NoActiveCard = 7; // There is no 'card 0' in internal numbering.
size_t active_card_ = NoActiveCard;
std::array<std::unique_ptr<Apple::II::Card>, 8> cards_; // The final slot is a sentinel for 'no active card'.
Cycles cycles_since_card_update_;
std::vector<Apple::II::Card *> every_cycle_cards_;
std::vector<Apple::II::Card *> just_in_time_cards_;
int stretched_cycles_since_card_update_ = 0;
void install_card(std::size_t slot, Apple::II::Card *card) {
assert(slot >= 1 && slot < 8);
cards_[slot - 1].reset(card);
card->set_delegate(this);
pick_card_messaging_group(card);
}
bool is_every_cycle_card(const Apple::II::Card *card) {
return !card->get_select_constraints();
}
bool card_lists_are_dirty_ = true;
bool card_became_just_in_time_ = false;
void pick_card_messaging_group(Apple::II::Card *card) {
// Simplify to a card being either just-in-time or realtime.
// Don't worry about exactly what it's watching,
const bool is_every_cycle = is_every_cycle_card(card);
std::vector<Apple::II::Card *> &intended = is_every_cycle ? every_cycle_cards_ : just_in_time_cards_;
// If the card is already in the proper group, stop.
if(std::find(intended.begin(), intended.end(), card) != intended.end()) return;
// Otherwise, mark the sets as dirty. It isn't safe to transition the card here,
// as the main loop may be part way through iterating the two lists.
card_lists_are_dirty_ = true;
card_became_just_in_time_ |= !is_every_cycle;
}
void card_did_change_select_constraints(Apple::II::Card *card) final {
pick_card_messaging_group(card);
}
void card_did_change_interrupt_flags(Apple::II::Card *) final {
bool nmi = false;
bool irq = false;
for(const auto &card: cards_) {
if(card) {
nmi |= card->nmi();
irq |= card->irq();
}
}
m6502_.set_nmi_line(nmi);
m6502_.set_irq_line(irq);
}
Apple::II::Mockingboard *mockingboard() {
return dynamic_cast<Apple::II::Mockingboard *>(cards_[MockingboardSlot - 1].get());
}
Apple::II::DiskIICard *diskii_card() {
return dynamic_cast<Apple::II::DiskIICard *>(cards_[DiskIISlot - 1].get());
}
Apple::II::SCSICard *scsi_card() {
return dynamic_cast<Apple::II::SCSICard *>(cards_[SCSISlot - 1].get());
}
// MARK: - Memory Map.
/*
The Apple II's paging mechanisms are byzantine to say the least. Painful is
another appropriate adjective.
On a II and II+ there are five distinct zones of memory:
0000 to c000 : the main block of RAM
c000 to d000 : the IO area, including card ROMs
d000 to e000 : the low ROM area, which can alternatively contain either one of two 4kb blocks of RAM with a language card
e000 onward : the rest of ROM, also potentially replaced with RAM by a language card
On a IIe with auxiliary memory the following orthogonal changes also need to be factored in:
0000 to 0200 : can be paged independently of the rest of RAM, other than part of the language card area which pages with it
0400 to 0800 : the text screen, can be configured to write to auxiliary RAM
2000 to 4000 : the graphics screen, which can be configured to write to auxiliary RAM
c100 to d000 : can be used to page an additional 3.75kb of ROM, replacing the IO area
c300 to c400 : can contain the same 256-byte segment of the ROM as if the whole IO area were switched, but while leaving cards visible in the rest
c800 to d000 : can contain ROM separately from the region below c800
If dealt with as individual blocks in the inner loop, that would therefore imply mapping
an address to one of 13 potential pageable zones. So I've gone reductive and surrendered
to paging every 6502 page of memory independently. It makes the paging events more expensive,
but hopefully more clear.
*/
const uint8_t *read_pages_[256]; // each is a pointer to the 256-block of memory the CPU should read when accessing that page of memory
uint8_t *write_pages_[256]; // as per read_pages_, but this is where the CPU should write. If a pointer is nullptr, don't write.
void page(int start, int end, uint8_t *read, uint8_t *write) {
for(int position = start; position < end; ++position) {
read_pages_[position] = read;
if(read) read += 256;
write_pages_[position] = write;
if(write) write += 256;
}
}
// MARK: - The language card, auxiliary memory, and IIe-specific improvements.
LanguageCardSwitches<ConcreteMachine> language_card_;
AuxiliaryMemorySwitches<ConcreteMachine> auxiliary_switches_;
friend LanguageCardSwitches<ConcreteMachine>;
friend AuxiliaryMemorySwitches<ConcreteMachine>;
template <int type> void set_paging() {
if constexpr (bool(type & PagingType::ZeroPage)) {
if(auxiliary_switches_.zero_state()) {
write_pages_[0] = aux_ram_;
} else {
write_pages_[0] = ram_;
}
write_pages_[1] = write_pages_[0] + 256;
read_pages_[0] = write_pages_[0];
read_pages_[1] = write_pages_[1];
}
if constexpr (bool(type & (PagingType::LanguageCard | PagingType::ZeroPage))) {
const auto language_state = language_card_.state();
const auto zero_state = auxiliary_switches_.zero_state();
uint8_t *const ram = zero_state ? aux_ram_ : ram_;
uint8_t *const rom = is_iie(model) ? &rom_[3840] : rom_.data();
// Which way the region here is mapped to be banks 1 and 2 is
// arbitrary.
page(0xd0, 0xe0,
language_state.read ? &ram[language_state.bank2 ? 0xd000 : 0xc000] : rom,
language_state.write ? nullptr : &ram[language_state.bank2 ? 0xd000 : 0xc000]);
page(0xe0, 0x100,
language_state.read ? &ram[0xe000] : &rom[0x1000],
language_state.write ? nullptr : &ram[0xe000]);
}
if constexpr (bool(type & PagingType::CardArea)) {
const auto state = auxiliary_switches_.card_state();
page(0xc1, 0xc4, state.region_C1_C3 ? &rom_[0xc100 - 0xc100] : nullptr, nullptr);
read_pages_[0xc3] = state.region_C3 ? &rom_[0xc300 - 0xc100] : nullptr;
page(0xc4, 0xc8, state.region_C4_C8 ? &rom_[0xc400 - 0xc100] : nullptr, nullptr);
page(0xc8, 0xd0, state.region_C8_D0 ? &rom_[0xc800 - 0xc100] : nullptr, nullptr);
}
if constexpr (bool(type & PagingType::Main)) {
const auto state = auxiliary_switches_.main_state();
page(0x02, 0x04,
state.base.read ? &aux_ram_[0x0200] : &ram_[0x0200],
state.base.write ? &aux_ram_[0x0200] : &ram_[0x0200]);
page(0x08, 0x20,
state.base.read ? &aux_ram_[0x0800] : &ram_[0x0800],
state.base.write ? &aux_ram_[0x0800] : &ram_[0x0800]);
page(0x40, 0xc0,
state.base.read ? &aux_ram_[0x4000] : &ram_[0x4000],
state.base.write ? &aux_ram_[0x4000] : &ram_[0x4000]);
page(0x04, 0x08,
state.region_04_08.read ? &aux_ram_[0x0400] : &ram_[0x0400],
state.region_04_08.write ? &aux_ram_[0x0400] : &ram_[0x0400]);
page(0x20, 0x40,
state.region_20_40.read ? &aux_ram_[0x2000] : &ram_[0x2000],
state.region_20_40.write ? &aux_ram_[0x2000] : &ram_[0x2000]);
}
}
// MARK: - Keyboard and typing.
struct Keyboard: public Inputs::Keyboard {
Keyboard(Processor *m6502) : m6502_(m6502) {}
void reset_all_keys() final {
open_apple_is_pressed =
closed_apple_is_pressed =
control_is_pressed_ =
shift_is_pressed_ =
repeat_is_pressed_ =
key_is_down_ =
character_is_pressed_ = false;
}
bool set_key_pressed(Key key, char value, bool is_pressed, bool is_repeat) final {
if constexpr (!is_iie(model)) {
if(is_repeat && !repeat_is_pressed_) return true;
}
// If no ASCII value is supplied, look for a few special cases.
switch(key) {
case Key::Left: value = 0x08; break;
case Key::Right: value = 0x15; break;
case Key::Down: value = 0x0a; break;
case Key::Up: value = 0x0b; break;
case Key::Backspace:
if(is_iie(model)) {
value = 0x7f;
break;
} else {
return false;
}
case Key::Enter: value = 0x0d; break;
case Key::Tab:
if (is_iie(model)) {
value = '\t';
break;
} else {
return false;
}
case Key::Escape: value = 0x1b; break;
case Key::Space: value = 0x20; break;
case Key::LeftOption:
case Key::RightMeta:
if (is_iie(model)) {
open_apple_is_pressed = is_pressed;
return true;
} else {
return false;
}
case Key::RightOption:
case Key::LeftMeta:
if (is_iie(model)) {
closed_apple_is_pressed = is_pressed;
return true;
} else {
return false;
}
case Key::LeftControl:
control_is_pressed_ = is_pressed;
return true;
case Key::LeftShift:
case Key::RightShift:
shift_is_pressed_ = is_pressed;
return true;
case Key::F1: case Key::F2: case Key::F3: case Key::F4:
case Key::F5: case Key::F6: case Key::F7: case Key::F8:
case Key::F9: case Key::F10: case Key::F11:
repeat_is_pressed_ = is_pressed;
if constexpr (!is_iie(model)) {
if(is_pressed && (!is_repeat || character_is_pressed_)) {
keyboard_input_ = uint8_t(last_pressed_character_ | 0x80);
}
}
return true;
case Key::F12:
case Key::PrintScreen:
case Key::ScrollLock:
case Key::Pause:
case Key::Insert:
case Key::Home:
case Key::PageUp:
case Key::PageDown:
case Key::End:
// Accept a bunch non-symbolic other keys, as
// reset, in the hope that the user can find
// at least one usable key.
m6502_->set_reset_line(is_pressed);
return true;
default:
if(!value) {
return false;
}
// Prior to the IIe, the keyboard could produce uppercase only.
if(!is_iie(model)) value = char(toupper(value));
if(control_is_pressed_ && isalpha(value)) value &= 0xbf;
// TODO: properly map IIe keys
if(!is_iie(model) && shift_is_pressed_) {
switch(value) {
case 0x27: value = 0x22; break; // ' -> "
case 0x2c: value = 0x3c; break; // , -> <
case 0x2e: value = 0x3e; break; // . -> >
case 0x2f: value = 0x3f; break; // / -> ?
case 0x30: value = 0x29; break; // 0 -> )
case 0x31: value = 0x21; break; // 1 -> !
case 0x32: value = 0x40; break; // 2 -> @
case 0x33: value = 0x23; break; // 3 -> #
case 0x34: value = 0x24; break; // 4 -> $
case 0x35: value = 0x25; break; // 5 -> %
case 0x36: value = 0x5e; break; // 6 -> ^
case 0x37: value = 0x26; break; // 7 -> &
case 0x38: value = 0x2a; break; // 8 -> *
case 0x39: value = 0x28; break; // 9 -> (
case 0x3b: value = 0x3a; break; // ; -> :
case 0x3d: value = 0x2b; break; // = -> +
}
}
break;
}
if(is_pressed) {
last_pressed_character_ = value;
character_is_pressed_ = true;
keyboard_input_ = uint8_t(value | 0x80);
key_is_down_ = true;
} else {
if(value == last_pressed_character_) {
character_is_pressed_ = false;
}
if((keyboard_input_ & 0x3f) == value) {
key_is_down_ = false;
}
}
return true;
}
uint8_t get_keyboard_input() {
if(string_serialiser_) {
return string_serialiser_->head() | 0x80;
} else {
return keyboard_input_;
}
}
void clear_keyboard_input() {
keyboard_input_ &= 0x7f;
if(string_serialiser_ && !string_serialiser_->advance()) {
string_serialiser_.reset();
}
}
bool get_key_is_down() {
return key_is_down_;
}
void set_string_serialiser(std::unique_ptr<Utility::StringSerialiser> &&serialiser) {
string_serialiser_ = std::move(serialiser);
}
// The IIe has three keys that are wired directly to the same input as the joystick buttons.
bool open_apple_is_pressed = false;
bool closed_apple_is_pressed = false;
private:
// Current keyboard input register, as exposed to the programmer; on the IIe the programmer
// can also poll for whether any key is currently down.
uint8_t keyboard_input_ = 0x00;
bool key_is_down_ = false;
// ASCII input state, referenced by the REPT key on models before the IIe.
char last_pressed_character_ = 0;
bool character_is_pressed_ = false;
// The repeat key itself.
bool repeat_is_pressed_ = false;
// Modifier states.
bool shift_is_pressed_ = false;
bool control_is_pressed_ = false;
// A string serialiser for receiving copy and paste.
std::unique_ptr<Utility::StringSerialiser> string_serialiser_;
// 6502 connection, for applying the reset button.
Processor *const m6502_;
};
Keyboard keyboard_;
// MARK: - Joysticks.
JoystickPair joysticks_;
public:
ConcreteMachine(const Analyser::Static::AppleII::Target &target, const ROMMachine::ROMFetcher &rom_fetcher):
m6502_(*this),
video_bus_handler_(ram_, aux_ram_),
video_(video_bus_handler_),
audio_toggle_(audio_queue_),
ays_(audio_queue_),
mixer_(ays_, audio_toggle_),
speaker_(lowpass_source()),
language_card_(*this),
auxiliary_switches_(*this),
keyboard_(&m6502_) {
// This is where things get slightly convoluted: establish the machine as having a clock rate
// equal to the number of cycles of work the 6502 will actually achieve. Which is less than
// the master clock rate divided by 14 because every 65th cycle is extended by one seventh.
set_clock_rate((master_clock / 14.0) * 65.0 / (65.0 + 1.0 / 7.0));
// The speaker, however, should think it is clocked at half the master clock, per a general
// decision to sample it at seven times the CPU clock (plus stretches).
speaker_.set_input_rate(float(master_clock / (2.0 * float(audio_divider))));
// Apply a 6Khz low-pass filter. This was picked by ear and by an attempt to understand the
// Apple II schematic but, well, I don't claim much insight on the latter. This is definitely
// something to review in the future.
speaker_.set_high_frequency_cutoff(6000);
// Also, start with randomised memory contents.
Memory::Fuzz(ram_, sizeof(ram_));
Memory::Fuzz(aux_ram_, sizeof(aux_ram_));
// Pick the required ROMs.
using Target = Analyser::Static::AppleII::Target;
ROM::Name character, system;
switch(target.model) {
default:
character = ROM::Name::AppleIICharacter;
system = ROM::Name::AppleIIOriginal;
break;
case Target::Model::IIplus:
character = ROM::Name::AppleIICharacter;
system = ROM::Name::AppleIIPlus;
break;
case Target::Model::IIe:
character = ROM::Name::AppleIIeCharacter;
system = ROM::Name::AppleIIe;
break;
case Target::Model::EnhancedIIe:
character = ROM::Name::AppleIIEnhancedECharacter;
system = ROM::Name::AppleIIEnhancedE;
break;
}
ROM::Request request = ROM::Request(character) && ROM::Request(system);
// Add the necessary Disk II requests if appropriate.
const bool has_disk_controller = target.disk_controller != Target::DiskController::None;
const bool is_sixteen_sector = target.disk_controller == Target::DiskController::SixteenSector;
if(has_disk_controller) {
request = request && DiskIICard::rom_request(is_sixteen_sector);
}
// Add a SCSI card if requested.
const bool has_scsi_card = target.scsi_controller == Target::SCSIController::AppleSCSI;
if(has_scsi_card) {
request = request && SCSICard::rom_request();
}
// Request, validate and install ROMs.
auto roms = rom_fetcher(request);
if(!request.validate(roms)) {
throw ROMMachine::Error::MissingROMs;
}
if(has_disk_controller) {
install_card(DiskIISlot, new Apple::II::DiskIICard(roms, is_sixteen_sector));
}
if(has_scsi_card) {
// Rounding the clock rate slightly shouldn't matter, but:
// TODO: be [slightly] more honest about clock rate.
install_card(SCSISlot, new Apple::II::SCSICard(roms, int(master_clock / 14.0f)));
}
if(target.has_mockingboard) {
// The Mockingboard has a parasitic relationship with this class due to the way
// that audio outputs are implemented in this emulator.
install_card(MockingboardSlot, new Apple::II::Mockingboard(ays_));
}
rom_ = std::move(roms.find(system)->second);
// The IIe and Enhanced IIe ROMs often distributed are oversized; trim if necessary.
if(system == ROM::Name::AppleIIe || system == ROM::Name::AppleIIEnhancedE) {
if(rom_.size() > 16128) {
rom_.erase(rom_.begin(), rom_.end() - 16128);
}
}
video_.set_character_rom(roms.find(character)->second);
// Set up the default memory blocks. On a II or II+ these values will never change.
// On a IIe they'll be affected by selection of auxiliary RAM.
set_paging<PagingType::Main | PagingType::ZeroPage>();
// Set the whole card area to initially backed by nothing.
page(0xc0, 0xd0, nullptr, nullptr);
insert_media(target.media);
}
~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();
}
/// Sets the type of display.
void set_display_type(Outputs::Display::DisplayType display_type) final {
video_.set_display_type(display_type);
}
Outputs::Display::DisplayType get_display_type() const final {
return video_.get_display_type();
}
Outputs::Speaker::Speaker *get_speaker() final {
return &speaker_;
}
forceinline Cycles perform_bus_operation(const CPU::MOS6502::BusOperation operation, const uint16_t address, uint8_t *const value) {
++ cycles_since_video_update_;
++ cycles_since_card_update_;
cycles_since_audio_update_ += Cycles(7);
// The Apple II has a slightly weird timing pattern: every 65th CPU cycle is stretched
// by an extra 1/7th. That's because one cycle lasts 3.5 NTSC colour clocks, so after
// 65 cycles a full line of 227.5 colour clocks have passed. But the high-rate binary
// signal approximation that produces colour needs to be in phase, so a stretch of exactly
// 0.5 further colour cycles is added. The video class handles that implicitly, but it
// needs to be accumulated here for the audio.
cycles_into_current_line_ = (cycles_into_current_line_ + 1) % 65;
const bool is_stretched_cycle = !cycles_into_current_line_;
if(is_stretched_cycle) {
++ cycles_since_audio_update_;
++ stretched_cycles_since_card_update_;
}
bool has_updated_cards = false;
if(read_pages_[address >> 8]) {
if(isReadOperation(operation)) *value = read_pages_[address >> 8][address & 0xff];
else {
if(address >= 0x200 && address < 0x6000) update_video();
if(write_pages_[address >> 8]) write_pages_[address >> 8][address & 0xff] = *value;
}
if(is_iie(model)) {
auxiliary_switches_.access(address, isReadOperation(operation));
}
} else {
// Assume a vapour read unless it turns out otherwise; this is a little
// wasteful but works for now.
//
// Longer version: like many other machines, when the Apple II reads from
// an address at which no hardware loads the data bus, through a process of
// practical analogue effects it'll end up receiving whatever was last on
// the bus. Which will always be whatever the video circuit fetched because
// that fetches in between every instruction.
//
// So this code assumes that'll happen unless it later determines that it
// doesn't. The call into the video isn't free because it's a just-in-time
// actor, but this will actually be the result most of the time so it's not
// too terrible.
if(isReadOperation(operation) && address != 0xc000) {
if(video_.has_deferred_actions()) {
update_video();
}
*value = video_.get_last_read_value(cycles_since_video_update_);
}
switch(address) {
default:
if(isReadOperation(operation)) {
// Read-only switches.
switch(address) {
default: break;
case 0xc000:
*value = keyboard_.get_keyboard_input();
break;
case 0xc001: case 0xc002: case 0xc003: case 0xc004: case 0xc005: case 0xc006: case 0xc007:
case 0xc008: case 0xc009: case 0xc00a: case 0xc00b: case 0xc00c: case 0xc00d: case 0xc00e: case 0xc00f:
*value = (*value & 0x80) | (keyboard_.get_keyboard_input() & 0x7f);
break;
case 0xc061: // Switch input 0.
*value &= 0x7f;
if(
joysticks_.button(0) ||
(is_iie(model) && keyboard_.open_apple_is_pressed)
)
*value |= 0x80;
break;
case 0xc062: // Switch input 1.
*value &= 0x7f;
if(
joysticks_.button(1) ||
(is_iie(model) && keyboard_.closed_apple_is_pressed)
)
*value |= 0x80;
break;
case 0xc063: // Switch input 2.
*value &= 0x7f;
if(joysticks_.button(2))
*value |= 0x80;
break;
case 0xc064: // Analogue input 0.
case 0xc065: // Analogue input 1.
case 0xc066: // Analogue input 2.
case 0xc067: { // Analogue input 3.
const size_t input = address - 0xc064;
*value &= 0x7f;
if(!joysticks_.analogue_channel_is_discharged(input)) {
*value |= 0x80;
}
} break;
// The IIe-only state reads follow...
#define IIeSwitchRead(s) *value = keyboard_.get_keyboard_input(); if(is_iie(model)) *value = (*value & 0x7f) | (s ? 0x80 : 0x00);
case 0xc011: IIeSwitchRead(language_card_.state().bank2); break;
case 0xc012: IIeSwitchRead(language_card_.state().read); break;
case 0xc013: IIeSwitchRead(auxiliary_switches_.switches().read_auxiliary_memory); break;
case 0xc014: IIeSwitchRead(auxiliary_switches_.switches().write_auxiliary_memory); break;
case 0xc015: IIeSwitchRead(auxiliary_switches_.switches().internal_CX_rom); break;
case 0xc016: IIeSwitchRead(auxiliary_switches_.switches().alternative_zero_page); break;
case 0xc017: IIeSwitchRead(auxiliary_switches_.switches().slot_C3_rom); break;
case 0xc018: IIeSwitchRead(video_.get_80_store()); break;
case 0xc019: IIeSwitchRead(video_.get_is_vertical_blank(cycles_since_video_update_)); break;
case 0xc01a: IIeSwitchRead(video_.get_text()); break;
case 0xc01b: IIeSwitchRead(video_.get_mixed()); break;
case 0xc01c: IIeSwitchRead(video_.get_page2()); break;
case 0xc01d: IIeSwitchRead(video_.get_high_resolution()); break;
case 0xc01e: IIeSwitchRead(video_.get_alternative_character_set()); break;
case 0xc01f: IIeSwitchRead(video_.get_80_columns()); break;
#undef IIeSwitchRead
case 0xc07f:
if(is_iie(model)) *value = (*value & 0x7f) | (video_.get_annunciator_3() ? 0x80 : 0x00);
break;
}
} else {
// Write-only switches. All IIe as currently implemented.
if(is_iie(model)) {
auxiliary_switches_.access(address, false);
switch(address) {
default: break;
case 0xc000:
case 0xc001:
update_video();
video_.set_80_store(!!(address&1));
break;
case 0xc00c:
case 0xc00d:
update_video();
video_.set_80_columns(!!(address&1));
break;
case 0xc00e:
case 0xc00f:
update_video();
video_.set_alternative_character_set(!!(address&1));
break;
}
}
}
break;
case 0xc070: joysticks_.access_c070(); break;
/* Switches triggered by reading or writing. */
case 0xc050:
case 0xc051:
update_video();
video_.set_text(address&1);
break;
case 0xc052: update_video(); video_.set_mixed(false); break;
case 0xc053: update_video(); video_.set_mixed(true); break;
case 0xc054:
case 0xc055:
update_video();
video_.set_page2(address&1);
auxiliary_switches_.access(address, isReadOperation(operation));
break;
case 0xc056:
case 0xc057:
update_video();
video_.set_high_resolution(address&1);
auxiliary_switches_.access(address, isReadOperation(operation));
break;
case 0xc05e:
case 0xc05f:
if(is_iie(model)) {
update_video();
video_.set_annunciator_3(!(address&1));
}
break;
case 0xc010:
keyboard_.clear_keyboard_input();
// On the IIe, reading C010 returns additional key info.
if(is_iie(model) && isReadOperation(operation)) {
*value = (keyboard_.get_key_is_down() ? 0x80 : 0x00) | (keyboard_.get_keyboard_input() & 0x7f);
}
break;
case 0xc030: case 0xc031: case 0xc032: case 0xc033: case 0xc034: case 0xc035: case 0xc036: case 0xc037:
case 0xc038: case 0xc039: case 0xc03a: case 0xc03b: case 0xc03c: case 0xc03d: case 0xc03e: case 0xc03f:
update_audio();
audio_toggle_.set_output(!audio_toggle_.get_output());
break;
case 0xc080: case 0xc084: case 0xc088: case 0xc08c:
case 0xc081: case 0xc085: case 0xc089: case 0xc08d:
case 0xc082: case 0xc086: case 0xc08a: case 0xc08e:
case 0xc083: case 0xc087: case 0xc08b: case 0xc08f:
language_card_.access(address, isReadOperation(operation));
break;
}
/*
Communication with cards follows.
*/
if(!read_pages_[address >> 8] && address >= 0xc090 && address < 0xd000) {
// If this is a card access, figure out which card is at play before determining
// the totality of who needs messaging.
size_t card_number = 0;
Apple::II::Card::Select select = Apple::II::Card::None;
if(address >= 0xc800) {
/*
Decode the 2kb area used for additional ROMs.
This is shared by all cards.
*/
card_number = active_card_;
select = Apple::II::Card::C8Region;
// An access to $cfff will disable the active card.
if(address == 0xcfff) {
active_card_ = NoActiveCard;
}
} else if(address >= 0xc100) {
/*
Decode the area conventionally used by cards for ROMs:
0xCn00 to 0xCnff: card n.
This also sets the active card for the C8 region.
*/
active_card_ = card_number = (address - 0xc100) >> 8;
select = Apple::II::Card::IO;
} else {
/*
Decode the area conventionally used by cards for registers:
C0n0 to C0nF: card n - 8.
*/
card_number = (address - 0xc090) >> 4;
select = Apple::II::Card::Device;
}
// If the selected card is a just-in-time card, update the just-in-time cards,
// and then message it specifically.
const bool is_read = isReadOperation(operation);
Apple::II::Card *const target = cards_[size_t(card_number)].get();
if(target && !is_every_cycle_card(target)) {
update_just_in_time_cards();
target->perform_bus_operation(select, is_read, address, value);
}
// Update all the every-cycle cards regardless, but send them a ::None select if they're
// not the one actually selected.
for(const auto &card: every_cycle_cards_) {
card->run_for(Cycles(1), is_stretched_cycle);
card->perform_bus_operation(
(card == target) ? select : Apple::II::Card::None,
is_read, address, value);
}
has_updated_cards = true;
}
}
if(!has_updated_cards && !every_cycle_cards_.empty()) {
// Update all every-cycle cards and give them the cycle.
const bool is_read = isReadOperation(operation);
for(const auto &card: every_cycle_cards_) {
card->run_for(Cycles(1), is_stretched_cycle);
card->perform_bus_operation(Apple::II::Card::None, is_read, address, value);
}
}
// Update the card lists if any mutations are due.
if(card_lists_are_dirty_) {
card_lists_are_dirty_ = false;
// There's only one counter of time since update
// for just-in-time cards. If something new is
// transitioning, that needs to be zeroed.
if(card_became_just_in_time_) {
card_became_just_in_time_ = false;
update_just_in_time_cards();
}
// Clear the two lists and repopulate.
every_cycle_cards_.clear();
just_in_time_cards_.clear();
for(const auto &card: cards_) {
if(!card) continue;
if(is_every_cycle_card(card.get())) {
every_cycle_cards_.push_back(card.get());
} else {
just_in_time_cards_.push_back(card.get());
}
}
}
// Update analogue charge level.
joysticks_.update_charge();
return Cycles(1);
}
void flush_output(int outputs) final {
update_just_in_time_cards();
if(outputs & Output::Video) {
update_video();
}
if(outputs & Output::Audio) {
update_audio();
audio_queue_.perform();
}
}
void run_for(const Cycles cycles) final {
m6502_.run_for(cycles);
}
bool prefers_logical_input() final {
return is_iie(model);
}
Inputs::Keyboard &get_keyboard() final {
return keyboard_;
}
void type_string(const std::string &string) final {
keyboard_.set_string_serialiser(std::make_unique<Utility::StringSerialiser>(string, true));
}
bool can_type(char c) const final {
// Make an effort to type the entire printable ASCII range.
return c >= 32 && c < 127;
}
// MARK:: Configuration options.
std::unique_ptr<Reflection::Struct> get_options() final {
auto options = std::make_unique<Options>(Configurable::OptionsType::UserFriendly);
options->output = get_video_signal_configurable();
options->use_square_pixels = video_.get_use_square_pixels();
return options;
}
void set_options(const std::unique_ptr<Reflection::Struct> &str) {
const auto options = dynamic_cast<Options *>(str.get());
set_video_signal_configurable(options->output);
video_.set_use_square_pixels(options->use_square_pixels);
}
// MARK: MediaTarget
bool insert_media(const Analyser::Static::Media &media) final {
if(!media.disks.empty()) {
auto diskii = diskii_card();
if(diskii) diskii->set_disk(media.disks[0], 0);
}
if(!media.mass_storage_devices.empty()) {
auto scsi = scsi_card();
if(scsi) scsi->set_storage_device(media.mass_storage_devices[0]);
}
return true;
}
// MARK: Activity::Source
void set_activity_observer(Activity::Observer *observer) final {
for(const auto &card: cards_) {
if(card) card->set_activity_observer(observer);
}
}
// MARK: JoystickMachine
const std::vector<std::unique_ptr<Inputs::Joystick>> &get_joysticks() final {
return joysticks_.get_joysticks();
}
};
}
}
using namespace Apple::II;
std::unique_ptr<Machine> Machine::AppleII(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) {
using Target = Analyser::Static::AppleII::Target;
const Target *const appleii_target = dynamic_cast<const Target *>(target);
if(appleii_target->has_mockingboard) {
switch(appleii_target->model) {
default: return nullptr;
case Target::Model::II: return std::make_unique<ConcreteMachine<Target::Model::II, true>>(*appleii_target, rom_fetcher);
case Target::Model::IIplus: return std::make_unique<ConcreteMachine<Target::Model::IIplus, true>>(*appleii_target, rom_fetcher);
case Target::Model::IIe: return std::make_unique<ConcreteMachine<Target::Model::IIe, true>>(*appleii_target, rom_fetcher);
case Target::Model::EnhancedIIe: return std::make_unique<ConcreteMachine<Target::Model::EnhancedIIe, true>>(*appleii_target, rom_fetcher);
}
} else {
switch(appleii_target->model) {
default: return nullptr;
case Target::Model::II: return std::make_unique<ConcreteMachine<Target::Model::II, false>>(*appleii_target, rom_fetcher);
case Target::Model::IIplus: return std::make_unique<ConcreteMachine<Target::Model::IIplus, false>>(*appleii_target, rom_fetcher);
case Target::Model::IIe: return std::make_unique<ConcreteMachine<Target::Model::IIe, false>>(*appleii_target, rom_fetcher);
case Target::Model::EnhancedIIe: return std::make_unique<ConcreteMachine<Target::Model::EnhancedIIe, false>>(*appleii_target, rom_fetcher);
}
}
}
Machine::~Machine() {}
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