/*
DingusPPC - The Experimental PowerPC Macintosh emulator
Copyright (C) 2018-22 divingkatae and maximum
(theweirdo) spatium
(Contact divingkatae#1017 or powermax#2286 on Discord for more info)
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
/** @file Sander-Wozniak Machine 3 (SWIM3) emulation. */
#include
#include
#include
#include
#include
#include
#include
#include
using namespace Swim3;
Swim3Ctrl::Swim3Ctrl()
{
this->name = "SWIM3";
this->supported_types = HWCompType::FLOPPY_CTRL;
this->setup_reg = 0;
this->mode_reg = 0;
this->int_reg = 0;
this->int_flags = 0;
this->int_mask = 0;
this->error = 0;
this->xfer_cnt = 0;
this->first_sec = 0xFF;
// Attach virtual Superdrive to the internal drive connector
// TODO: make SWIM3/drive wiring user selectable
this->int_drive = std::unique_ptr
(new MacSuperdrive::MacSuperDrive());
gMachineObj->add_subdevice("Superdrive", this->int_drive.get());
}
int Swim3Ctrl::device_postinit()
{
this->int_ctrl = dynamic_cast(
gMachineObj->get_comp_by_type(HWCompType::INT_CTRL));
this->irq_id = this->int_ctrl->register_dev_int(IntSrc::SWIM3);
return 0;
};
uint8_t Swim3Ctrl::read(uint8_t reg_offset)
{
uint8_t status_addr, old_int_flags, old_error;
switch(reg_offset) {
case Swim3Reg::Error:
old_error = this->error;
this->error = 0;
return old_error;
case Swim3Reg::Phase:
return this->phase_lines;
case Swim3Reg::Setup:
return this->setup_reg;
case Swim3Reg::Handshake_Mode1:
if (this->mode_reg & 2) { // internal drive?
status_addr = ((this->mode_reg & 0x20) >> 2) | (this->phase_lines & 7);
return ((this->int_drive->status(status_addr) & 1) << 2);
}
return 4;
case Swim3Reg::Interrupt_Flags:
old_int_flags = this->int_flags;
this->int_flags = 0; // read from this register clears all flags
update_irq();
return old_int_flags;
case Swim3Reg::Current_Track:
return this->cur_track;
case Swim3Reg::Current_Sector:
return this->cur_sector;
case Swim3Reg::Gap_Format:
return this->format;
case Swim3Reg::First_Sector:
return this->first_sec;
case Swim3Reg::Sectors_To_Xfer:
return this->xfer_cnt;
case Swim3Reg::Interrupt_Mask:
return this->int_mask;
default:
LOG_F(INFO, "SWIM3: reading from 0x%X register", reg_offset);
}
return 0;
}
void Swim3Ctrl::write(uint8_t reg_offset, uint8_t value)
{
uint8_t old_mode_reg;
switch(reg_offset) {
case Swim3Reg::Param_Data:
this->pram = value;
break;
case Swim3Reg::Phase:
this->phase_lines = value & 0xF;
if (value & 8) {
if (this->mode_reg & 2) { // internal drive?
this->int_drive->command(
((this->mode_reg & 0x20) >> 3) | (this->phase_lines & 3),
(value >> 2) & 1
);
}
}
break;
case Swim3Reg::Setup:
this->setup_reg = value;
break;
case Swim3Reg::Status_Mode0:
// ones in value clear the corresponding bits in the mode register
if ((this->mode_reg & value) & (SWIM3_GO | SWIM3_GO_STEP)) {
if (value & SWIM3_GO_STEP) {
stop_stepping();
} else {
stop_disk_access();
}
}
this->mode_reg &= ~value;
break;
case Swim3Reg::Handshake_Mode1:
// ones in value set the corresponding bits in the mode register
if ((this->mode_reg ^ value) & (SWIM3_GO | SWIM3_GO_STEP)) {
if (value & SWIM3_GO_STEP) {
start_stepping();
} else {
start_disk_access();
}
}
this->mode_reg |= value;
break;
case Swim3Reg::Step:
this->step_count = value;
break;
case Swim3Reg::Gap_Format:
this->gap_size = value;
break;
case Swim3Reg::First_Sector:
this->first_sec = value;
break;
case Swim3Reg::Sectors_To_Xfer:
this->xfer_cnt = value;
break;
case Swim3Reg::Interrupt_Mask:
this->int_mask = value;
break;
default:
LOG_F(INFO, "SWIM3: writing 0x%X to register 0x%X", value, reg_offset);
}
}
void Swim3Ctrl::update_irq()
{
if (this->mode_reg & SWIM3_INT_ENA) {
uint8_t new_irq = !!(this->int_flags & this->int_mask);
if (new_irq != this->irq) {
this->irq = new_irq;
this->int_ctrl->ack_int(this->irq_id, new_irq);
}
}
}
void Swim3Ctrl::do_step()
{
if (this->mode_reg & SWIM3_GO_STEP && this->step_count) { // are we still stepping?
// instruct the drive to perform single step in current direction
this->int_drive->command(MacSuperdrive::CommandAddr::Do_Step, 0);
if (--this->step_count == 0) {
if (this->step_timer_id) {
this->stop_stepping();
}
this->int_flags |= INT_STEP_DONE;
update_irq();
}
}
}
void Swim3Ctrl::start_stepping()
{
if (!this->step_count) {
LOG_F(WARNING, "SWIM3: step_count is zero while go_step is active!");
return;
}
if (this->mode_reg & SWIM3_GO_STEP || this->step_timer_id) {
LOG_F(ERROR, "SWIM3: another stepping action is running!");
return;
}
if (this->mode_reg & SWIM3_GO || this->access_timer_id) {
LOG_F(ERROR, "SWIM3: stepping attempt while disk access is in progress!");
return;
}
if ((((this->mode_reg & 0x20) >> 3) | (this->phase_lines & 3))
!= MacSuperdrive::CommandAddr::Do_Step) {
LOG_F(WARNING, "SWIM3: invalid command address on the phase lines!");
return;
}
this->mode_reg |= SWIM3_GO_STEP;
// step count > 1 requires periodic task
if (this->step_count > 1) {
this->step_timer_id = TimerManager::get_instance()->add_cyclic_timer(
USECS_TO_NSECS(80),
[this]() {
this->do_step();
}
);
}
// perform the first step immediately
do_step();
}
void Swim3Ctrl::stop_stepping()
{
// cancel stepping task
if (this->step_timer_id) {
TimerManager::get_instance()->cancel_timer(this->step_timer_id);
}
this->step_timer_id = 0;
this->step_count = 0; // not sure this one is required
}
void Swim3Ctrl::start_disk_access()
{
if (this->mode_reg & SWIM3_GO || this->access_timer_id) {
LOG_F(ERROR, "SWIM3: another disk access is running!");
return;
}
if (this->mode_reg & SWIM3_GO_STEP || this->step_timer_id) {
LOG_F(ERROR, "SWIM3: disk access attempt while stepping is in progress!");
return;
}
if (this->mode_reg & SWIM3_WR_MODE) {
LOG_F(ERROR, "SWIM3: writing not implemented yet");
return;
}
this->mode_reg |= SWIM3_GO;
LOG_F(9, "SWIM3: disk access started!");
if (this->first_sec == 0xFF) {
// $FF means no sector to match ->
// generate ID_read interrups as long as the GO bit is set
this->int_drive->init_track_search(-1); // start at random sector
} else {
this->cur_sector = this->first_sec;
}
// HACK: figure out from bits in int_mask register which kind of disk access is requested
if (this->int_mask & INT_ID_READ) { // read address header
this->access_timer_id = TimerManager::get_instance()->add_cyclic_timer(
static_cast(this->int_drive->get_sector_delay() * NS_PER_SEC + 0.5f),
[this]() {
// get next sector's address field
MacSuperdrive::SectorHdr addr = this->int_drive->next_sector_header();
// set up the corresponding SWIM3 registers
this->cur_track = ((addr.side & 1) << 7) | (addr.track & 0x7F);
this->cur_sector = 0x80 /* CRC/checksum valid */ | (addr.sector & 0x7F);
this->format = addr.format;
// generate ID_read interrupt
this->int_flags |= INT_ID_READ;
update_irq();
}
);
} else { // otherwise, read sector data
this->access_timer_id = TimerManager::get_instance()->add_cyclic_timer(
static_cast(this->int_drive->get_sector_delay() * NS_PER_SEC + 0.5f),
[this]() {
// transfer sector data over DMA
this->dma_ch->push_data(this->int_drive->get_sector_data_ptr(this->cur_sector), 512);
// get next address field
MacSuperdrive::SectorHdr addr = this->int_drive->next_sector_header();
// set up the corresponding SWIM3 registers
this->cur_track = ((addr.side & 1) << 7) | (addr.track & 0x7F);
this->cur_sector = 0x80 /* CRC/checksum valid */ | (addr.sector & 0x7F);
this->format = addr.format;
if (--this->xfer_cnt == 0) {
this->stop_disk_access();
// generate sector_done interrupt
this->int_flags |= INT_SECT_DONE;
update_irq();
}
}
);
}
}
void Swim3Ctrl::stop_disk_access()
{
// cancel disk access timer
if (this->access_timer_id) {
TimerManager::get_instance()->cancel_timer(this->access_timer_id);
}
this->access_timer_id = 0;
}