/*
DingusPPC - The Experimental PowerPC Macintosh emulator
Copyright (C) 2018-24 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 SCSI bus emulation. */
#include
#include
#include
#include
#include
#include
#include
#include
#include
ScsiBus::ScsiBus(const std::string name)
{
this->set_name(name);
supports_types(HWCompType::SCSI_BUS);
for(int i = 0; i < SCSI_MAX_DEVS; i++) {
this->devices[i] = nullptr;
this->dev_ctrl_lines[i] = 0;
}
this->ctrl_lines = 0; // all control lines released
this->data_lines = 0; // data lines released
this->arb_winner_id = -1;
this->initiator_id = -1;
this->target_id = -1;
}
void ScsiBus::register_device(int id, ScsiDevice* dev_obj)
{
if (this->devices[id] != nullptr) {
ABORT_F("ScsiBus: device with ID %d already registered", id);
}
this->devices[id] = dev_obj;
dev_obj->set_bus_object_ptr(this);
}
void ScsiBus::change_bus_phase(int initiator_id)
{
for (int i = 0; i < SCSI_MAX_DEVS; i++) {
if (i == initiator_id)
continue; // don't notify the initiator
if (this->devices[i] != nullptr) {
this->devices[i]->notify(ScsiMsg::BUS_PHASE_CHANGE, this->cur_phase);
}
}
}
void ScsiBus::assert_ctrl_line(int initiator_id, uint16_t mask)
{
DCHECK_F(initiator_id >= 0 && initiator_id < SCSI_MAX_DEVS, "ScsiBus: invalid initiator ID %d", initiator_id);
uint16_t new_state = 0xFFFFU & mask;
this->dev_ctrl_lines[initiator_id] |= new_state;
if (new_state == this->ctrl_lines) {
return;
}
if (new_state & SCSI_CTRL_RST) {
this->ctrl_lines |= SCSI_CTRL_RST;
this->cur_phase = ScsiPhase::RESET;
change_bus_phase(initiator_id);
}
}
void ScsiBus::release_ctrl_line(int id, uint16_t mask)
{
DCHECK_F(id >= 0 && id < SCSI_MAX_DEVS, "ScsiBus: invalid initiator ID %d", id);
uint16_t new_state = 0;
this->dev_ctrl_lines[id] &= ~mask;
// OR control lines of all devices together
for (int i = 0; i < SCSI_MAX_DEVS; i++) {
new_state |= this->dev_ctrl_lines[i];
}
if (this->ctrl_lines & SCSI_CTRL_RST) {
if (!(new_state & SCSI_CTRL_RST)) {
this->ctrl_lines = new_state;
this->cur_phase = ScsiPhase::BUS_FREE;
change_bus_phase(id);
}
} else {
this->ctrl_lines = new_state;
}
}
void ScsiBus::release_ctrl_lines(int id)
{
this->release_ctrl_line(id, 0xFFFFUL);
}
uint16_t ScsiBus::test_ctrl_lines(uint16_t mask)
{
uint16_t new_state = 0;
// OR control lines of all devices together
for (int i = 0; i < SCSI_MAX_DEVS; i++) {
new_state |= this->dev_ctrl_lines[i];
}
return new_state & mask;
}
int ScsiBus::switch_phase(int id, int new_phase)
{
int old_phase = this->cur_phase;
// leave the current phase (low-level)
switch (old_phase) {
case ScsiPhase::COMMAND:
this->release_ctrl_line(id, SCSI_CTRL_CD);
break;
case ScsiPhase::DATA_IN:
this->release_ctrl_line(id, SCSI_CTRL_IO);
break;
case ScsiPhase::STATUS:
this->release_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_IO);
break;
case ScsiPhase::MESSAGE_OUT:
this->release_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_MSG);
break;
case ScsiPhase::MESSAGE_IN:
this->release_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_MSG | SCSI_CTRL_IO);
break;
}
// enter new phase (low-level)
switch (new_phase) {
case ScsiPhase::COMMAND:
this->assert_ctrl_line(id, SCSI_CTRL_CD);
break;
case ScsiPhase::DATA_IN:
this->assert_ctrl_line(id, SCSI_CTRL_IO);
break;
case ScsiPhase::STATUS:
this->assert_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_IO);
break;
case ScsiPhase::MESSAGE_OUT:
this->assert_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_MSG);
break;
case ScsiPhase::MESSAGE_IN:
this->assert_ctrl_line(id, SCSI_CTRL_CD | SCSI_CTRL_MSG | SCSI_CTRL_IO);
break;
}
// switch the bus to the new phase (high-level)
this->cur_phase = new_phase;
change_bus_phase(id);
return old_phase;
}
bool ScsiBus::begin_arbitration(int initiator_id)
{
if (this->cur_phase == ScsiPhase::BUS_FREE) {
this->data_lines |= 1 << initiator_id;
this->cur_phase = ScsiPhase::ARBITRATION;
change_bus_phase(initiator_id);
return true;
} else {
return false;
}
}
bool ScsiBus::end_arbitration(int initiator_id)
{
int highest_id = -1;
// find the highest ID bit on the data lines
for (int id = 7; id >= 0; id--) {
if (this->data_lines & (1 << id)) {
highest_id = id;
break;
}
}
if (highest_id >= 0) {
this->arb_winner_id = highest_id;
}
return highest_id == initiator_id;
}
bool ScsiBus::begin_selection(int initiator_id, int target_id, bool atn)
{
// perform bus integrity checks
if (this->cur_phase != ScsiPhase::ARBITRATION || this->arb_winner_id != initiator_id)
return false;
this->assert_ctrl_line(initiator_id, SCSI_CTRL_SEL);
this->data_lines = (1 << initiator_id) | (1 << target_id);
if (atn) {
assert_ctrl_line(initiator_id, SCSI_CTRL_ATN);
}
this->initiator_id = initiator_id;
this->cur_phase = ScsiPhase::SELECTION;
change_bus_phase(initiator_id);
return true;
}
void ScsiBus::confirm_selection(int target_id)
{
this->target_id = target_id;
// notify initiator about selection confirmation from target
if (this->initiator_id >= 0) {
this->devices[this->initiator_id]->notify(ScsiMsg::CONFIRM_SEL, target_id);
}
}
bool ScsiBus::end_selection(int initiator_id, int target_id)
{
// check for selection confirmation from target
return this->target_id == target_id;
}
bool ScsiBus::pull_data(const int id, uint8_t* dst_ptr, const int size)
{
if (dst_ptr == nullptr || !size) {
return false;
}
if (!this->devices[id]->send_data(dst_ptr, size)) {
LOG_F(ERROR, "ScsiBus: error while transferring T->I data!");
return false;
}
return true;
}
bool ScsiBus::push_data(const int id, const uint8_t* src_ptr, const int size)
{
if (!this->devices[id]) {
LOG_F(ERROR, "%s: no device %d for push_data %d bytes", this->get_name().c_str(), id, size);
return false;
}
if (!this->devices[id]->rcv_data(src_ptr, size)) {
if (size) {
LOG_F(ERROR, "%s: error while transferring I->T data!", this->get_name().c_str());
return false;
}
}
return true;
}
int ScsiBus::target_xfer_data() {
return this->devices[this->target_id]->xfer_data();
}
void ScsiBus::target_next_step()
{
this->devices[this->target_id]->next_step();
}
bool ScsiBus::negotiate_xfer(int& bytes_in, int& bytes_out)
{
this->devices[this->target_id]->prepare_xfer(this, bytes_in, bytes_out);
return true;
}
void ScsiBus::disconnect(int dev_id)
{
this->release_ctrl_lines(dev_id);
if (!(this->ctrl_lines & SCSI_CTRL_BSY) && !(this->ctrl_lines & SCSI_CTRL_SEL)) {
this->cur_phase = ScsiPhase::BUS_FREE;
change_bus_phase(dev_id);
}
}
void ScsiBus::attach_scsi_devices(const std::string bus_suffix)
{
std::string path;
int scsi_id;
std::string image_path;
image_path = GET_STR_PROP("hdd_img" + bus_suffix);
if (!image_path.empty()) {
std::istringstream image_stream(image_path);
while (std::getline(image_stream, path, ':')) {
// do two passes because we skip ID 3.
for (scsi_id = 0; scsi_id < SCSI_MAX_DEVS * 2 && (scsi_id == 3 || this->devices[scsi_id % SCSI_MAX_DEVS]); scsi_id++) {}
if (scsi_id < SCSI_MAX_DEVS * 2) {
scsi_id = scsi_id % SCSI_MAX_DEVS;
std::string scsi_device_name = "ScsiHD" + bus_suffix + "," + std::to_string(scsi_id);
ScsiHardDisk *scsi_device = new ScsiHardDisk(scsi_device_name, scsi_id);
gMachineObj->add_device(scsi_device_name, std::unique_ptr(scsi_device));
this->register_device(scsi_id, scsi_device);
scsi_device->insert_image(path);
}
else {
LOG_F(ERROR, "%s: Too many devices. HDD \"%s\" was not added.", this->get_name().c_str(), path.c_str());
}
}
}
image_path = GET_STR_PROP("cdr_img" + bus_suffix);
if (!image_path.empty()) {
std::istringstream image_stream(image_path);
while (std::getline(image_stream, path, ':')) {
// do two passes because we start at ID 3.
for (scsi_id = 3; scsi_id < SCSI_MAX_DEVS * 2 && this->devices[scsi_id % SCSI_MAX_DEVS]; scsi_id++) {}
if (scsi_id < SCSI_MAX_DEVS * 2) {
scsi_id = scsi_id % SCSI_MAX_DEVS;
std::string scsi_device_name = "ScsiCdrom" + bus_suffix + "," + std::to_string(scsi_id);
ScsiCdrom *scsi_device = new ScsiCdrom(scsi_device_name, scsi_id);
gMachineObj->add_device(scsi_device_name, std::unique_ptr(scsi_device));
this->register_device(scsi_id, scsi_device);
scsi_device->insert_image(path);
}
else {
LOG_F(ERROR, "%s: Too many devices. CD-ROM \"%s\" was not added.", this->get_name().c_str(), path.c_str());
}
}
}
}
static const DeviceDescription ScsiCurio_Descriptor = {
ScsiBus::create_ScsiCurio, {}, {}
};
static const DeviceDescription ScsiMesh_Descriptor = {
ScsiBus::create_ScsiMesh, {}, {}
};
REGISTER_DEVICE(ScsiCurio, ScsiCurio_Descriptor);
REGISTER_DEVICE(ScsiMesh, ScsiMesh_Descriptor);