dingusppc/devices/common/pci/bandit.cpp
2024-03-20 07:38:39 -07:00

348 lines
11 KiB
C++

/*
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 <https://www.gnu.org/licenses/>.
*/
/** Bandit/Chaos ARBus-to-PCI Bridge emulation. */
#include <devices/common/pci/bandit.h>
#include <devices/deviceregistry.h>
#include <devices/memctrl/memctrlbase.h>
#include <endianswap.h>
#include <loguru.hpp>
#include <machines/machinebase.h>
#include <cinttypes>
const int MultiplyDeBruijnBitPosition2[] =
{
0, 1, 28, 2, 29, 14, 24, 3, 30, 22, 20, 15, 25, 17, 4, 8,
31, 27, 13, 23, 21, 19, 16, 7, 26, 12, 18, 6, 11, 5, 10, 9
};
/** finds the position of the bit that is set */
#define WHAT_BIT_SET(val) (MultiplyDeBruijnBitPosition2[(uint32_t)(val * 0x077CB531U) >> 27])
BanditPciDevice::BanditPciDevice(int bridge_num, std::string name, int dev_id, int rev)
: PCIDevice(name)
{
supports_types(HWCompType::PCI_DEV);
// prepare the PCI config header
this->vendor_id = PCI_VENDOR_APPLE;
this->device_id = dev_id;
this->class_rev = 0x06000000 | (rev & 0xFFU);
this->cache_ln_sz = 8;
this->command = 0x16;
// make several PCI config space registers read-only
this->pci_wr_cmd = [](uint16_t cmd) {}; // command register
this->pci_wr_cache_lnsz = [](uint8_t val) {}; // cache line size register
// set the bits in the fine address space field of the address mask register
// that correspond to the 32MB assigned PCI address space of this Bandit.
// This initialization is implied by the device functionality.
this->addr_mask = 3 << ((bridge_num & 3) * 2);
// initial PCI number + chip mode: big endian, interrupts & VGA space disabled
this->mode_ctrl = ((bridge_num & 3) << 2) | 3;
this->rd_hold_off_cnt = 8;
}
uint32_t BanditPciDevice::pci_cfg_read(uint32_t reg_offs, AccessDetails &details)
{
if (reg_offs < 64) {
return PCIDevice::pci_cfg_read(reg_offs, details);
}
switch (reg_offs) {
case BANDIT_ADDR_MASK:
return this->addr_mask;
case BANDIT_MODE_SELECT:
return this->mode_ctrl;
case BANDIT_ARBUS_RD_HOLD_OFF:
return this->rd_hold_off_cnt;
default:
LOG_READ_UNIMPLEMENTED_CONFIG_REGISTER();
}
return 0;
}
void BanditPciDevice::pci_cfg_write(uint32_t reg_offs, uint32_t value, AccessDetails &details)
{
if (reg_offs < 64) {
PCIDevice::pci_cfg_write(reg_offs, value, details);
return;
}
switch (reg_offs) {
case BANDIT_ADDR_MASK:
this->addr_mask = value;
this->verbose_address_space();
return;
case BANDIT_MODE_SELECT:
this->mode_ctrl = value;
return;
case BANDIT_ARBUS_RD_HOLD_OFF:
this->rd_hold_off_cnt = value & 0x1F;
return;
default:
LOG_WRITE_UNIMPLEMENTED_CONFIG_REGISTER();
}
}
void BanditPciDevice::verbose_address_space()
{
uint32_t mask;
int bit_pos;
if (!this->addr_mask) {
return;
}
LOG_F(INFO, "%s address spaces:", this->pci_name.c_str());
// verbose coarse aka 256MB memory regions
for (mask = 0x10000, bit_pos = 0; mask != 0x80000000UL; mask <<= 1, bit_pos++) {
if (this->addr_mask & mask) {
uint32_t start_addr = bit_pos << 28;
LOG_F(INFO, "- 0x%X ... 0x%X", start_addr, start_addr + 0x0FFFFFFFU);
}
}
// verbose fine aka 16MB memory regions
for (mask = 0x1, bit_pos = 0; mask != 0x10000UL; mask <<= 1, bit_pos++) {
if (this->addr_mask & mask) {
uint32_t start_addr = (bit_pos << 24) + 0xF0000000UL;
LOG_F(INFO, "- 0x%X ... 0x%X", start_addr, start_addr + 0x00FFFFFFU);
}
}
}
uint32_t BanditHost::read(uint32_t rgn_start, uint32_t offset, int size)
{
switch (offset >> 22) {
case 3: // CONFIG_DATA
int bus_num, dev_num, fun_num;
uint8_t reg_offs;
AccessDetails details;
PCIBase *device;
cfg_setup(offset, size, bus_num, dev_num, fun_num, reg_offs, details, device);
details.flags |= PCI_CONFIG_READ;
if (device) {
uint32_t value = device->pci_cfg_read(reg_offs, details);
// bytes 4 to 7 are random on bandit but
// we choose to repeat bytes 0 to 3 like grackle
return pci_conv_rd_data(value, value, details);
}
LOG_READ_NON_EXISTENT_PCI_DEVICE();
return 0xFFFFFFFFUL; // PCI spec §6.1
case 2: // CONFIG_ADDR
return BYTESWAP_32(this->config_addr);
default: // I/O space
return pci_io_read_broadcast(offset, size);
}
}
void BanditHost::write(uint32_t rgn_start, uint32_t offset, uint32_t value, int size)
{
switch (offset >> 22) {
case 3: // CONFIG_DATA
int bus_num, dev_num, fun_num;
uint8_t reg_offs;
AccessDetails details;
PCIBase *device;
cfg_setup(offset, size, bus_num, dev_num, fun_num, reg_offs, details, device);
details.flags |= PCI_CONFIG_WRITE;
if (device) {
if (size == 4 && !details.offset) { // aligned DWORD writes -> fast path
device->pci_cfg_write(reg_offs, BYTESWAP_32(value), details);
return;
}
// otherwise perform necessary data transformations -> slow path
uint32_t old_val = details.size == 4 ? 0 : device->pci_cfg_read(reg_offs, details);
uint32_t new_val = pci_conv_wr_data(old_val, value, details);
device->pci_cfg_write(reg_offs, new_val, details);
return;
}
LOG_WRITE_NON_EXISTENT_PCI_DEVICE();
break;
case 2: // CONFIG_ADDR
this->config_addr = BYTESWAP_32(value);
break;
default: // I/O space
pci_io_write_broadcast(offset, size, value);
}
}
inline void BanditHost::cfg_setup(uint32_t offset, int size, int &bus_num,
int &dev_num, int &fun_num, uint8_t &reg_offs,
AccessDetails &details, PCIBase *&device)
{
details.size = size;
details.offset = offset & 3;
fun_num = FUN_NUM();
reg_offs = REG_NUM();
if (this->config_addr & BANDIT_CAR_TYPE) { // type 1 configuration command
details.flags = PCI_CONFIG_TYPE_1;
bus_num = BUS_NUM();
dev_num = DEV_NUM();
device = pci_find_device(bus_num, dev_num, fun_num);
return;
}
details.flags = PCI_CONFIG_TYPE_0;
bus_num = 0; // use dummy value for bus number
uint32_t idsel = this->config_addr & 0xFFFFF800U;
if (!SINGLE_BIT_SET(idsel)) {
for (dev_num = -1, idsel = this->config_addr; idsel; idsel >>= 1, dev_num++) {}
LOG_F(ERROR, "%s: config_addr 0x%08x does not contain valid IDSEL",
this->name.c_str(), (uint32_t)this->config_addr);
device = NULL;
return;
}
dev_num = WHAT_BIT_SET(idsel);
device = pci_find_device(dev_num, fun_num);
}
int BanditHost::device_postinit()
{
std::string pci_dev_name;
static const std::map<std::string, int> pci_slots1 = {
{"pci_A1", DEV_FUN(0xD,0)}, {"pci_B1", DEV_FUN(0xE,0)}, {"pci_C1", DEV_FUN(0xF,0)}
};
static const std::map<std::string, int> pci_slots2 = {
{"pci_D2", DEV_FUN(0xD,0)}, {"pci_E2", DEV_FUN(0xE,0)}, {"pci_F2", DEV_FUN(0xF,0)}
};
static const std::map<std::string, int> vci_slots = {
{"vci_D", DEV_FUN(0xD,0)}, {"vci_E", DEV_FUN(0xE,0)}, {"vci_F", DEV_FUN(0xF,0)}
};
for (auto& slot :
this->bridge_num == 0 ? vci_slots :
this->bridge_num == 1 ? pci_slots1 :
this->bridge_num == 2 ? pci_slots2 :
pci_slots1
) {
pci_dev_name = GET_STR_PROP(slot.first);
if (!pci_dev_name.empty()) {
this->attach_pci_device(pci_dev_name, slot.second);
}
}
return 0;
}
Bandit::Bandit(int bridge_num, std::string name, int dev_id, int rev)
: BanditHost(bridge_num)
{
this->name = name;
supports_types(HWCompType::PCI_HOST);
this->base_addr = 0xF0000000 + ((bridge_num & 3) << 25);
MemCtrlBase *mem_ctrl = dynamic_cast<MemCtrlBase *>
(gMachineObj->get_comp_by_type(HWCompType::MEM_CTRL));
// add memory mapped I/O region for Bandit control registers
// This region has the following layout:
// base_addr + 0x000000 --> I/O space
// base_addr + 0x800000 --> CONFIG_ADDR
// base_addr + 0xC00000 --> CONFIG_DATA
// base_addr + 0x1000000 --> pass-through memory space (not included below)
mem_ctrl->add_mmio_region(base_addr, 0x01000000, this);
// connnect Bandit PCI device
this->my_pci_device = unique_ptr<BanditPciDevice>(
new BanditPciDevice(bridge_num, name, dev_id, rev)
);
this->pci_register_device(DEV_FUN(BANDIT_DEV,0), this->my_pci_device.get());
}
Chaos::Chaos(std::string name) : BanditHost(0)
{
this->name = name;
supports_types(HWCompType::PCI_HOST);
MemCtrlBase *mem_ctrl = dynamic_cast<MemCtrlBase *>
(gMachineObj->get_comp_by_type(HWCompType::MEM_CTRL));
// add memory mapped I/O region for Chaos control registers
// This region has the following layout:
// base_addr + 0x800000 --> CONFIG_ADDR
// base_addr + 0xC00000 --> CONFIG_DATA
mem_ctrl->add_mmio_region(0xF0000000UL, 0x01000000, this);
}
static const PropMap Bandit1_Properties = {
{"pci_A1",
new StrProperty("")},
{"pci_B1",
new StrProperty("")},
{"pci_C1",
new StrProperty("")},
};
static const PropMap Bandit2_Properties = {
{"pci_D2",
new StrProperty("")},
{"pci_E2",
new StrProperty("")},
{"pci_F2",
new StrProperty("")},
};
static const PropMap Chaos_Properties = {
{"vci_D",
new StrProperty("")},
{"vci_E",
new StrProperty("")},
{"vci_F",
new StrProperty("")},
};
static const DeviceDescription Bandit1_Descriptor = {
Bandit::create_first, {}, Bandit1_Properties
};
static const DeviceDescription Bandit2_Descriptor = {
Bandit::create_second, {}, Bandit2_Properties
};
static const DeviceDescription PsxPci1_Descriptor = {
Bandit::create_psx_first, {}, Bandit1_Properties
};
static const DeviceDescription Chaos_Descriptor = {
Chaos::create, {}, Chaos_Properties
};
REGISTER_DEVICE(Bandit1, Bandit1_Descriptor);
REGISTER_DEVICE(Bandit2, Bandit2_Descriptor);
REGISTER_DEVICE(PsxPci1, PsxPci1_Descriptor);
REGISTER_DEVICE(Chaos, Chaos_Descriptor);