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CLK/Components/DiskII/IWM.cpp
2021-03-07 12:52:54 -05:00

431 lines
13 KiB
C++

//
// IWM.cpp
// Clock Signal
//
// Created by Thomas Harte on 05/05/2019.
// Copyright © 2019 Thomas Harte. All rights reserved.
//
#include "IWM.hpp"
#ifndef NDEBUG
#define NDEBUG
#endif
#define LOG_PREFIX "[IWM] "
#include "../../Outputs/Log.hpp"
using namespace Apple;
namespace {
constexpr int CA0 = 1 << 0;
constexpr int CA1 = 1 << 1;
constexpr int CA2 = 1 << 2;
constexpr int LSTRB = 1 << 3;
constexpr int ENABLE = 1 << 4;
constexpr int DRIVESEL = 1 << 5; /* This means drive select, like on the original Disk II. */
constexpr int Q6 = 1 << 6;
constexpr int Q7 = 1 << 7;
constexpr int SEL = 1 << 8; /* This is an additional input, not available on a Disk II, with a confusingly-similar name to SELECT but a distinct purpose. */
}
IWM::IWM(int clock_rate) :
clock_rate_(clock_rate) {}
// MARK: - Bus accessors
uint8_t IWM::read(int address) {
access(address);
// Per Inside Macintosh:
//
// "Before you can read from any of the disk registers you must set up the state of the IWM so that it
// can pass the data through to the MC68000's address space where you'll be able to read it. To do that,
// you must first turn off Q7 by reading or writing dBase+q7L. Then turn on Q6 by accessing dBase+q6H.
// After that, the IWM will be able to pass data from the disk's RD/SENSE line through to you."
//
// My understanding:
//
// Q6 = 1, Q7 = 0 reads the status register. The meaning of the top 'SENSE' bit is then determined by
// the CA0,1,2 and SEL switches as described in Inside Macintosh, summarised above as RD/SENSE.
if(address&1) {
return 0xff;
}
switch(state_ & (Q6 | Q7 | ENABLE)) {
default:
LOG("Invalid read\n");
return 0xff;
// "Read all 1s".
// printf("Reading all 1s\n");
// return 0xff;
case 0:
case ENABLE: { /* Read data register. Zeroing afterwards is a guess. */
const auto result = data_register_;
if(data_register_ & 0x80) {
data_register_ = 0;
// LOG("Reading data: " << PADHEX(2) << int(result));
}
// LOG("Reading data register: " << PADHEX(2) << int(result));
return result;
}
case Q6: case Q6|ENABLE: {
/*
[If A = 0], Read status register:
bits 0-4: same as mode register.
bit 5: 1 = either /ENBL1 or /ENBL2 is currently low.
bit 6: 1 = MZ (reserved for future compatibility; should always be read as 0).
bit 7: 1 = SENSE input high; 0 = SENSE input low.
(/ENBL1 is low when the first drive's motor is on; /ENBL2 is low when the second drive's motor is on.
If the 1-second timer is enabled, motors remain on for one second after being programmatically disabled.)
*/
return uint8_t(
(mode_&0x1f) |
((state_ & ENABLE) ? 0x20 : 0x00) |
(sense() & 0x80)
);
} break;
case Q7: case Q7|ENABLE:
/*
Read write-handshake register:
bits 0-5: reserved for future use (currently read as 1).
bit 6: 1 = write state (0 = underrun has occurred; 1 = no underrun so far).
bit 7: 1 = write data buffer ready for data (1 = ready; 0 = busy).
*/
// LOG("Reading write handshake: " << PADHEX(2) << int(0x3f | write_handshake_));
return 0x3f | write_handshake_;
}
return 0xff;
}
void IWM::write(int address, uint8_t input) {
access(address);
switch(state_ & (Q6 | Q7 | ENABLE)) {
default: break;
case Q7|Q6:
/*
Write mode register:
bit 0: 1 = latch mode (should be set in asynchronous mode).
bit 1: 0 = synchronous handshake protocol; 1 = asynchronous.
bit 2: 0 = 1-second on-board timer enable; 1 = timer disable.
bit 3: 0 = slow mode; 1 = fast mode.
bit 4: 0 = 7Mhz; 1 = 8Mhz (7 or 8 mHz clock descriptor).
bit 5: 1 = test mode; 0 = normal operation.
bit 6: 1 = MZ-reset.
bit 7: reserved for future expansion.
*/
mode_ = input;
// TEMPORARY. To test for the unimplemented mode.
if(input&0x2) {
LOG("Switched to asynchronous mode");
} else {
LOG("Switched to synchronous mode");
}
switch(mode_ & 0x18) {
case 0x00: bit_length_ = Cycles(28); break; // slow mode, 7Mhz
case 0x08: bit_length_ = Cycles(14); break; // fast mode, 7Mhz
case 0x10: bit_length_ = Cycles(32); break; // slow mode, 8Mhz
case 0x18: bit_length_ = Cycles(16); break; // fast mode, 8Mhz
}
LOG("Mode is now " << PADHEX(2) << int(mode_));
LOG("New bit length is " << std::dec << bit_length_.as_integral());
break;
case Q7|Q6|ENABLE: // Write data register.
next_output_ = input;
write_handshake_ &= ~0x80;
break;
}
}
// MARK: - Switch access
void IWM::access(int address) {
// Keep a record of switch state; bits in state_
// should correlate with the anonymous namespace constants
// defined at the top of this file — CA0, CA1, etc.
address &= 0xf;
const auto mask = 1 << (address >> 1);
const auto old_state = state_;
if(address & 1) {
state_ |= mask;
} else {
state_ &= ~mask;
}
// React appropriately to ENABLE and DRIVESEL changes, and changes into/out of write mode.
if(old_state != state_) {
push_drive_state();
switch(mask) {
default: break;
case ENABLE:
if(address & 1) {
if(drives_[active_drive_]) drives_[active_drive_]->set_enabled(true);
} else {
// If the 1-second delay is enabled, set up a timer for that.
if(!(mode_ & 4)) {
cycles_until_disable_ = Cycles(clock_rate_);
} else {
if(drives_[active_drive_]) drives_[active_drive_]->set_enabled(false);
}
}
break;
case DRIVESEL: {
const int new_drive = address & 1;
if(new_drive != active_drive_) {
if(drives_[active_drive_]) drives_[active_drive_]->set_enabled(false);
active_drive_ = new_drive;
if(drives_[active_drive_]) {
drives_[active_drive_]->set_enabled(state_ & ENABLE || (cycles_until_disable_ > Cycles(0)));
push_drive_state();
}
}
} break;
case Q6:
case Q7:
select_shift_mode();
break;
}
}
}
void IWM::set_select(bool enabled) {
// Store SEL as an extra state bit.
if(enabled) state_ |= SEL;
else state_ &= ~SEL;
push_drive_state();
}
void IWM::push_drive_state() {
if(drives_[active_drive_]) {
const uint8_t drive_control_lines =
((state_ & CA0) ? IWMDrive::CA0 : 0) |
((state_ & CA1) ? IWMDrive::CA1 : 0) |
((state_ & CA2) ? IWMDrive::CA2 : 0) |
((state_ & SEL) ? IWMDrive::SEL : 0) |
((state_ & LSTRB) ? IWMDrive::LSTRB : 0);
drives_[active_drive_]->set_control_lines(drive_control_lines);
}
}
// MARK: - Active logic
void IWM::run_for(const Cycles cycles) {
// Check for a timeout of the motor-off timer.
if(cycles_until_disable_ > Cycles(0)) {
cycles_until_disable_ -= cycles;
if(cycles_until_disable_ <= Cycles(0)) {
cycles_until_disable_ = Cycles(0);
if(drives_[active_drive_])
drives_[active_drive_]->set_enabled(false);
}
}
// Activity otherwise depends on mode and motor state.
auto integer_cycles = cycles.as_integral();
switch(shift_mode_) {
case ShiftMode::Reading: {
// Per the IWM patent, column 7, around line 35 onwards: "The expected time
// is widened by approximately one-half an interval before and after the
// expected time since the data is not precisely spaced when read due to
// variations in drive speed and other external factors". The error_margin
// here implements the 'after' part of that contract.
const auto error_margin = Cycles(bit_length_.as_integral() >> 1);
if(drive_is_rotating_[active_drive_]) {
while(integer_cycles--) {
drives_[active_drive_]->run_for(Cycles(1));
++cycles_since_shift_;
if(cycles_since_shift_ == bit_length_ + error_margin) {
// LOG("Shifting 0 at " << std::dec << cycles_since_shift_.as_integral());
propose_shift(0);
}
}
} else {
while(cycles_since_shift_ + integer_cycles >= bit_length_ + error_margin) {
const auto run_length = bit_length_ + error_margin - cycles_since_shift_;
integer_cycles -= run_length.as_integral();
cycles_since_shift_ += run_length;
propose_shift(0);
}
cycles_since_shift_ += Cycles(integer_cycles);
}
} break;
case ShiftMode::Writing:
while(cycles_since_shift_ + integer_cycles >= bit_length_) {
const auto cycles_until_write = bit_length_ - cycles_since_shift_;
if(drives_[active_drive_]) {
drives_[active_drive_]->run_for(cycles_until_write);
// Output a flux transition if the top bit is set.
drives_[active_drive_]->write_bit(shift_register_ & 0x80);
}
shift_register_ <<= 1;
integer_cycles -= cycles_until_write.as_integral();
cycles_since_shift_ = Cycles(0);
--output_bits_remaining_;
if(!output_bits_remaining_) {
if(!(write_handshake_ & 0x80)) {
shift_register_ = next_output_;
output_bits_remaining_ = 8;
// LOG("Next byte: " << PADHEX(2) << int(shift_register_));
} else {
write_handshake_ &= ~0x40;
if(drives_[active_drive_]) drives_[active_drive_]->end_writing();
LOG("Overrun; done.");
output_bits_remaining_ = 1;
}
// Either way, the IWM is ready for more data.
write_handshake_ |= 0x80;
}
}
// Either some bits were output, in which case cycles_since_shift_ is no 0 and
// integer_cycles is some number less than bit_length_, or none were and
// cycles_since_shift_ + integer_cycles is less than bit_length, and the new
// part should be accumulated.
cycles_since_shift_ += integer_cycles;
if(drives_[active_drive_] && integer_cycles) {
drives_[active_drive_]->run_for(cycles_since_shift_);
}
break;
case ShiftMode::CheckingWriteProtect:
if(integer_cycles < 8) {
shift_register_ = (shift_register_ >> integer_cycles) | (sense() & (0xff << (8 - integer_cycles)));
} else {
shift_register_ = sense();
}
[[fallthrough]];
default:
if(drive_is_rotating_[active_drive_]) drives_[active_drive_]->run_for(cycles);
break;
}
}
void IWM::select_shift_mode() {
// Don't allow an ongoing write to be interrupted.
if(shift_mode_ == ShiftMode::Writing && drives_[active_drive_] && drives_[active_drive_]->is_writing()) return;
const auto old_shift_mode = shift_mode_;
switch(state_ & (Q6|Q7)) {
default: shift_mode_ = ShiftMode::CheckingWriteProtect; break;
case 0: shift_mode_ = ShiftMode::Reading; break;
case Q7:
// "The IWM is put into the write state by a transition from the write protect sense state to the
// write load state".
if(shift_mode_ == ShiftMode::CheckingWriteProtect) shift_mode_ = ShiftMode::Writing;
break;
}
// If writing mode just began, set the drive into write mode and cue up the first output byte.
if(old_shift_mode != ShiftMode::Writing && shift_mode_ == ShiftMode::Writing) {
if(drives_[active_drive_]) drives_[active_drive_]->begin_writing(Storage::Time(1, clock_rate_ / bit_length_.as_integral()), false);
shift_register_ = next_output_;
write_handshake_ |= 0x80 | 0x40;
output_bits_remaining_ = 8;
LOG("Seeding output with " << PADHEX(2) << int(shift_register_));
}
}
uint8_t IWM::sense() {
return drives_[active_drive_] ? (drives_[active_drive_]->read() ? 0xff : 0x00) : 0xff;
}
void IWM::process_event(const Storage::Disk::Drive::Event &event) {
if(shift_mode_ != ShiftMode::Reading) return;
switch(event.type) {
case Storage::Disk::Track::Event::IndexHole: return;
case Storage::Disk::Track::Event::FluxTransition:
// LOG("Shifting 1 at " << std::dec << cycles_since_shift_.as_integral());
propose_shift(1);
break;
}
}
void IWM::propose_shift(uint8_t bit) {
// TODO: synchronous mode.
// LOG("Shifting at " << std::dec << cycles_since_shift_.as_integral());
// LOG("Shifting input");
// See above for text from the IWM patent, column 7, around line 35 onwards.
// The error_margin here implements the 'before' part of that contract.
//
// Basic effective logic: if at least 1 is found in the bit_length_ cycles centred
// on the current expected bit delivery time as implied by cycles_since_shift_,
// shift in a 1 and start a new window wherever the first found 1 was.
//
// If no 1s are found, shift in a 0 and don't alter expectations as to window placement.
const auto error_margin = Cycles(bit_length_.as_integral() >> 1);
if(bit && cycles_since_shift_ < error_margin) return;
shift_register_ = uint8_t((shift_register_ << 1) | bit);
if(shift_register_ & 0x80) {
// if(data_register_ & 0x80) LOG("Byte missed");
data_register_ = shift_register_;
shift_register_ = 0;
}
if(bit)
cycles_since_shift_ = Cycles(0);
else
cycles_since_shift_ -= bit_length_;
}
void IWM::set_drive(int slot, IWMDrive *drive) {
drives_[slot] = drive;
if(drive) {
drive->set_event_delegate(this);
drive->set_clocking_hint_observer(this);
} else {
drive_is_rotating_[slot] = false;
}
}
void IWM::set_component_prefers_clocking(ClockingHint::Source *component, ClockingHint::Preference clocking) {
const bool is_rotating = clocking != ClockingHint::Preference::None;
if(drives_[0] && component == static_cast<ClockingHint::Source *>(drives_[0])) {
drive_is_rotating_[0] = is_rotating;
} else if(drives_[1] && component == static_cast<ClockingHint::Source *>(drives_[1])) {
drive_is_rotating_[1] = is_rotating;
}
}
void IWM::set_activity_observer(Activity::Observer *observer) {
if(drives_[0]) drives_[0]->set_activity_observer(observer, "Internal Floppy", true);
if(drives_[1]) drives_[1]->set_activity_observer(observer, "External Floppy", true);
}