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CLK/Machines/Apple/Macintosh/RealTimeClock.hpp
2019-06-13 13:35:16 -04:00

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//
// RealTimeClock.hpp
// Clock Signal
//
// Created by Thomas Harte on 07/05/2019.
// Copyright © 2019 Thomas Harte. All rights reserved.
//
#ifndef RealTimeClock_hpp
#define RealTimeClock_hpp
#include "../../Utility/MemoryFuzzer.hpp"
namespace Apple {
namespace Macintosh {
/*!
Models the storage component of Apple's real-time clock.
Since tracking of time is pushed to this class, it is assumed
that whomever is translating real time into emulated time
will notify the VIA of a potential interrupt.
*/
class RealTimeClock {
public:
RealTimeClock() {
// TODO: this should persist, if possible, rather than
// being randomly initialised.
Memory::Fuzz(data_, sizeof(data_));
}
/*!
Advances the clock by 1 second.
The caller should also notify the VIA.
*/
void update() {
for(int c = 0; c < 4; ++c) {
++seconds_[c];
if(seconds_[c]) break;
}
}
/*!
Sets the current clock and data inputs to the clock.
*/
void set_input(bool clock, bool data) {
/*
Documented commands:
z0000001 Seconds register 0 (lowest order byte)
z0000101 Seconds register 1
z0001001 Seconds register 2
z0001101 Seconds register 3
00110001 Test register (write only)
00110101 Write-protect register (write only)
z010aa01 RAM addresses 0x10 - 0x13
z1aaaa01 RAM addresses 0x00 0x0f
z = 1 => a read; z = 0 => a write.
The top bit of the write-protect register enables (0) or disables (1)
writes to other locations.
All the documentation says about the test register is to set the top
two bits to 0 for normal operation. Abnormal operation is undefined.
The data line is valid when the clock transitions to level 0.
*/
if(clock && !previous_clock_) {
// Shift into the command_ register, no matter what.
command_ = uint16_t((command_ << 1) | (data ? 1 : 0));
result_ <<= 1;
// Increment phase.
++phase_;
// When phase hits 8, inspect the command.
// If it's a read, prepare a result.
if(phase_ == 8) {
if(command_ & 0x80) {
// A read.
const auto address = (command_ >> 2) & 0x1f;
// Begin pessimistically.
result_ = 0xff;
if(address < 4) {
result_ = seconds_[address];
} else if(address >= 0x10) {
result_ = data_[address & 0xf];
} else if(address >= 0x8 && address <= 0xb) {
result_ = data_[0x10 + (address & 0x3)];
}
}
}
// If phase hits 16 and this was a read command,
// just stop. If it was a write command, do the
// actual write.
if(phase_ == 16) {
if(!(command_ & 0x8000)) {
// A write.
const auto address = (command_ >> 10) & 0x1f;
const uint8_t value = uint8_t(command_ & 0xff);
// First test: is this to the write-protect register?
if(address == 0xd) {
write_protect_ = value;
}
// No other writing is permitted if the write protect
// register won't allow it.
if(!(write_protect_ & 0x80)) {
if(address < 4) {
seconds_[address] = value;
} else if(address >= 0x10) {
data_[address & 0xf] = value;
} else if(address >= 0x8 && address <= 0xb) {
data_[0x10 + (address & 0x3)] = value;
}
}
}
// A phase of 16 always ends the command, so reset here.
abort();
}
}
previous_clock_ = clock;
}
/*!
Reads the current data output level from the clock.
*/
bool get_data() {
return !!(result_ & 0x80);
}
/*!
Announces that a serial command has been aborted.
*/
void abort() {
result_ = 0;
phase_ = 0;
command_ = 0;
}
private:
uint8_t data_[0x14];
uint8_t seconds_[4];
uint8_t write_protect_;
int phase_ = 0;
uint16_t command_;
uint8_t result_ = 0;
bool previous_clock_ = false;
};
}
}
#endif /* RealTimeClock_hpp */