1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-19 08:31:11 +00:00
CLK/Machines/Apple/AppleIIgs/ADB.cpp
2023-05-12 14:14:45 -04:00

291 lines
8.5 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.

//
// ADB.cpp
// Clock Signal
//
// Created by Thomas Harte on 31/10/2020.
// Copyright © 2020 Thomas Harte. All rights reserved.
//
#include "ADB.hpp"
#include <cassert>
#include <cstdio>
#include <iostream>
// TEST.
#include "../../../InstructionSets/M50740/Parser.hpp"
#include "../../../InstructionSets/Disassembler.hpp"
#define LOG_PREFIX "[ADB GLU] "
#include "../../../Outputs/Log.hpp"
using namespace Apple::IIgs::ADB;
namespace {
// Flags affecting the CPU-visible status register.
enum class CPUFlags: uint8_t {
MouseDataFull = 0x80,
MouseInterruptEnabled = 0x40,
CommandDataIsValid = 0x20,
CommandDataInterruptEnabled = 0x10,
KeyboardDataFull = 0x08,
KeyboardDataInterruptEnabled = 0x04,
MouseXIsAvailable = 0x02,
CommandRegisterFull = 0x01,
};
// Flags affecting the microcontroller-visible register.
enum class MicrocontrollerFlags: uint8_t {
CommandRegisterFull = 0x40,
};
}
GLU::GLU() :
executor_(*this),
bus_(HalfCycles(1'789'772)),
controller_id_(bus_.add_device()),
mouse_(bus_),
keyboard_(bus_) {}
// MARK: - External interface.
uint8_t GLU::get_keyboard_data() {
// The classic Apple II serial keyboard register:
// b7: key strobe.
// b6b0: ASCII code.
return (registers_[0] & 0x7f) | ((status_ & uint8_t(CPUFlags::KeyboardDataFull)) ? 0x80 : 0x00);
}
void GLU::clear_key_strobe() {
// Clears the key strobe of the classic Apple II serial keyboard register.
status_ &= ~uint8_t(CPUFlags::KeyboardDataFull);
}
uint8_t GLU::get_any_key_down() {
// The Apple IIe check-for-any-key-down bit.
return registers_[5];
}
uint8_t GLU::get_mouse_data() {
// Alternates between returning x and y values.
//
// b7: 1 = button is up; 0 = button is down.
// b6: delta sign bit; 1 = negative.
// b5b0: mouse delta.
const uint8_t result = registers_[visible_mouse_register_];
if(visible_mouse_register_ == 2) {
++visible_mouse_register_;
} else {
status_ &= ~uint8_t(CPUFlags::MouseDataFull);
}
return result;
}
uint8_t GLU::get_modifier_status() {
// b7: 1 = command key pressed; 0 = not.
// b6: option key.
// b5: 1 = modifier key latch has been updated, no key has been pressed; 0 = not.
// b4: any numeric keypad key.
// b3: a key is down.
// b2: caps lock is pressed.
// b1: control key.
// b0: shift key.
return registers_[6];
}
uint8_t GLU::get_data() {
// b02: number of data bytes to be returned.
// b3: 1 = a valid service request is pending; 0 = no request pending.
// b4: 1 = control, command and delete keys have been pressed simultaneously; 0 = they haven't.
// b5: 1 = control, command and reset have all been pressed together; 0 = they haven't.
// b6: 1 = ADB controller encountered an error and reset itself; 0 = no error.
// b7: 1 = ADB has received a response from the addressed ADB device; 0 = no respone.
status_ &= ~uint8_t(CPUFlags::CommandDataIsValid);
return registers_[7];
}
uint8_t GLU::get_status() {
// b7: 1 = mouse data register is full; 0 = empty.
// b6: 1 = mouse interrupt is enabled.
// b5: 1 = command/data has valid data.
// b4: 1 = command/data interrupt is enabled.
// b3: 1 = keyboard data is full.
// b2: 1 = keyboard data interrupt is enabled.
// b1: 1 = mouse x-data is available; 0 = y.
// b0: 1 = command register is full (set when command is written); 0 = empty (cleared when data is read).
return status_ | ((visible_mouse_register_ == 2) ? uint8_t(CPUFlags::MouseXIsAvailable) : 0);
}
void GLU::set_status(uint8_t status) {
// This permits only the interrupt flags to be set.
constexpr uint8_t interrupt_flags =
uint8_t(CPUFlags::MouseInterruptEnabled) |
uint8_t(CPUFlags::CommandDataInterruptEnabled) |
uint8_t(CPUFlags::KeyboardDataInterruptEnabled);
status_ = (status_ & ~interrupt_flags) | (status & interrupt_flags);
}
void GLU::set_command(uint8_t command) {
registers_[1] = command;
registers_[4] |= uint8_t(MicrocontrollerFlags::CommandRegisterFull);
status_ |= uint8_t(CPUFlags::CommandRegisterFull);
}
// MARK: - Setup and run.
void GLU::set_microcontroller_rom(const std::vector<uint8_t> &rom) {
executor_.set_rom(rom);
// TEST invocation.
/* InstructionSet::Disassembler<InstructionSet::M50740::Parser, 0x1fff, InstructionSet::M50740::Instruction, uint8_t, uint16_t> disassembler;
disassembler.disassemble(rom.data(), 0x1000, uint16_t(rom.size()), 0x1000);
const auto instructions = disassembler.instructions();
const auto entry_points = disassembler.entry_points();
for(const auto &pair : instructions) {
std::cout << std::hex << pair.first << "\t\t";
if(entry_points.find(pair.first) != entry_points.end()) {
std::cout << "L" << pair.first << "\t";
} else {
std::cout << "\t\t";
}
std::cout << operation_name(pair.second.operation) << " ";
std::cout << address(pair.second.addressing_mode, &rom[pair.first - 0x1000], pair.first);
std::cout << std::endl;
}*/
}
void GLU::run_for(Cycles cycles) {
executor_.run_for(cycles);
}
// MARK: - M50470 port handler
void GLU::set_port_output(int port, uint8_t value) {
switch(port) {
case 0:
register_latch_ = value;
break;
case 1:
// printf("Keyboard write: %02x???\n", value);
break;
case 2: {
// printf("ADB data line input: %d???\n", value >> 7);
// printf("IIe keyboard reset line: %d\n", (value >> 6)&1);
// printf("IIgs reset line: %d\n", (value >> 5)&1);
// printf("GLU strobe: %d\n", (value >> 4)&1);
// printf("Select GLU register: %d [%02x]\n", value & 0xf, value);
register_address_ = value & 0xf;
// This is an ugly hack, I think. Per Neil Parker's Inside the Apple IIGS ADB Controller
// http://nparker.llx.com/a2/adb.html#external:
//
// The protocol for reading an ADB GLU register is as follows:
//
// 1. Put the register number of the ADB GLU register in port P2 bits 0-3.
// 2. Clear bit 4 of port P2, read the data from P0, and set bit 4 of P0.
//
// The protocol for writing a GLU register is similar:
//
// 1. Write the register number to port P2 bits 0-3.
// 2. Write the data to port P0.
// 3. Configure port P0 for output by writing $FF to $E1.
// 4. Clear bit 4 of P2, and immediately set it again.
// 5. Configure port P0 for input by writing 0 to $E1.
//
// ---
//
// I tried: linking a read or write to rising or falling edges of the strobe.
// Including with hysteresis as per the "immediately" (which, in practice, seems
// to mean "in the very next instruction", i.e. 5 cycles later). That didn't seem
// properly to differentiate.
//
// So I'm focussing on the "configure port P0 for output" bit. Which I don't see
// would be visible here unless it is actually an exposed signal, which is unlikely.
//
// Ergo: ugly. HACK.
const bool strobe = value & 0x10;
if(strobe != register_strobe_) {
register_strobe_ = strobe;
if(!register_strobe_) {
if(executor_.get_output_mask(0)) {
registers_[register_address_] = register_latch_;
switch(register_address_) {
default: break;
case 0: status_ |= uint8_t(CPUFlags::KeyboardDataFull); break;
case 2:
case 3:
status_ |= uint8_t(CPUFlags::MouseDataFull);
visible_mouse_register_ = 2;
printf("Mouse: %d <- %02x\n", register_address_, register_latch_);
break;
case 7: status_ |= uint8_t(CPUFlags::CommandDataIsValid); break;
}
} else {
register_latch_ = registers_[register_address_];
switch(register_address_) {
default: break;
case 1:
registers_[4] &= ~uint8_t(MicrocontrollerFlags::CommandRegisterFull);
status_ &= ~uint8_t(CPUFlags::CommandRegisterFull);
break;
}
}
}
}
} break;
case 3:
if(modifier_state_ != (value & 0x30)) {
modifier_state_ = value & 0x30;
LOG("Modifier state: " << int(value & 0x30));
}
// Output is inverted respective to input; the microcontroller
// sets a value of '1' in order to pull the ADB bus low.
bus_.set_device_output(controller_id_, !(value & 0x08));
break;
default: assert(false);
}
}
bool GLU::get_command_button() const {
return modifier_state_ & 0x20;
}
bool GLU::get_option_button() const {
return modifier_state_ & 0x10;
}
uint8_t GLU::get_port_input(int port) {
switch(port) {
case 0: return register_latch_;
case 1:
// printf("IIe keyboard read\n");
return 0x06;
case 2:
// printf("ADB data line input, etc\n");
return bus_.get_state() ? 0x80 : 0x00;
case 3:
// printf("ADB data line output, etc\n");
return 0x00;
default: assert(false);
}
return 0xff;
}
void GLU::run_ports_for(Cycles cycles) {
bus_.run_for(cycles);
}
void GLU::set_vertical_blank(bool is_blank) {
executor_.set_interrupt_line(is_blank);
}