/* 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 . */ /** MPC106 (Grackle) emulation. */ #include #include #include #include #include #include #include #include #include MPC106::MPC106() : MemCtrlBase(), PCIDevice("Grackle PCI host bridge"), PCIHost() { this->name = "Grackle"; supports_types(HWCompType::MEM_CTRL | HWCompType::MMIO_DEV | HWCompType::PCI_HOST | HWCompType::PCI_DEV); /* add PCI/ISA I/O space, 64K for now */ add_mmio_region(0xFE000000, 0x10000, this); /* add memory mapped I/O region for MPC106 registers */ add_mmio_region(0xFEC00000, 0x300000, this); } uint32_t MPC106::read(uint32_t reg_start, uint32_t offset, int size) { uint32_t result; if (reg_start == 0xFE000000) { /* broadcast I/O request to devices that support I/O space until a device returns true that means "request accepted" */ for (auto& dev : this->io_space_devs) { if (dev->pci_io_read(offset, size, &result)) { return result; } } LOG_F(ERROR, "Attempt to read from unmapped PCI I/O space, offset=0x%X", offset); } else { if (offset >= 0x200000) { if (this->config_addr & 0x80) // process only if bit E (enable) is set return pci_read(size); } } /* FIXME: reading from CONFIG_ADDR is ignored for now */ return 0; } void MPC106::write(uint32_t reg_start, uint32_t offset, uint32_t value, int size) { if (reg_start == 0xFE000000) { /* broadcast I/O request to devices that support I/O space until a device returns true that means "request accepted" */ for (auto& dev : this->io_space_devs) { if (dev->pci_io_write(offset, value, size)) { return; } } LOG_F(ERROR, "Attempt to write to unmapped PCI I/O space, offset=0x%X", offset); } else { if (offset < 0x200000) { this->config_addr = value; } else { if (this->config_addr & 0x80) // process only if bit E (enable) is set return pci_write(value, size); } } } uint32_t MPC106::pci_read(uint32_t size) { int bus_num, dev_num, fun_num, reg_offs; bus_num = (this->config_addr >> 8) & 0xFF; if (bus_num) { LOG_F( ERROR, "%s err: read attempt from non-local PCI bus, config_addr = %x \n", this->name.c_str(), this->config_addr); return 0; } dev_num = (this->config_addr >> 19) & 0x1F; fun_num = (this->config_addr >> 16) & 0x07; reg_offs = (this->config_addr >> 24) & 0xFC; if (dev_num == 0 && fun_num == 0) { // dev_num 0 is assigned to myself return this->pci_cfg_read(reg_offs, size); } else { if (this->dev_map.count(dev_num)) { return this->dev_map[dev_num]->pci_cfg_read(reg_offs, size); } else { LOG_F( ERROR, "%s err: read attempt from non-existing PCI device %d \n", this->name.c_str(), dev_num); return 0; } } return 0; } void MPC106::pci_write(uint32_t value, uint32_t size) { int bus_num, dev_num, fun_num, reg_offs; bus_num = (this->config_addr >> 8) & 0xFF; if (bus_num) { LOG_F( ERROR, "%s err: write attempt to non-local PCI bus, config_addr = %x \n", this->name.c_str(), this->config_addr); return; } dev_num = (this->config_addr >> 19) & 0x1F; fun_num = (this->config_addr >> 16) & 0x07; reg_offs = (this->config_addr >> 24) & 0xFC; if (dev_num == 0 && fun_num == 0) { // dev_num 0 is assigned to myself this->pci_cfg_write(reg_offs, value, size); } else { if (this->dev_map.count(dev_num)) { this->dev_map[dev_num]->pci_cfg_write(reg_offs, value, size); } else { LOG_F( ERROR, "%s err: write attempt to non-existing PCI device %d \n", this->name.c_str(), dev_num); } } } uint32_t MPC106::pci_cfg_read(uint32_t reg_offs, uint32_t size) { #ifdef MPC106_DEBUG LOG_F(9, "read from Grackle register %08X\n", reg_offs); #endif return read_mem(&this->my_pci_cfg_hdr[reg_offs], size); } void MPC106::pci_cfg_write(uint32_t reg_offs, uint32_t value, uint32_t size) { #ifdef MPC106_DEBUG LOG_F(9, "write %08X to Grackle register %08X\n", value, reg_offs); #endif // FIXME: implement write-protection for read-only registers write_mem(&this->my_pci_cfg_hdr[reg_offs], value, size); if (this->my_pci_cfg_hdr[0xF2] & 8) { #ifdef MPC106_DEBUG LOG_F(9, "MPC106: MCCR1[MEMGO] was set! \n"); #endif setup_ram(); } } void MPC106::setup_ram() { uint32_t mem_start, mem_end, ext_mem_start, ext_mem_end, bank_start, bank_end; uint32_t ram_size = 0; uint8_t bank_en = this->my_pci_cfg_hdr[0xA0]; for (int bank = 0; bank < 8; bank++) { if (bank_en & (1 << bank)) { if (bank < 4) { mem_start = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x80]); ext_mem_start = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x88]); mem_end = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x90]); ext_mem_end = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x98]); } else { mem_start = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x84]); ext_mem_start = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x8C]); mem_end = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x94]); ext_mem_end = READ_DWORD_LE_A(&this->my_pci_cfg_hdr[0x9C]); } bank_start = (((ext_mem_start >> bank * 8) & 3) << 30) | (((mem_start >> bank * 8) & 0xFF) << 20); bank_end = (((ext_mem_end >> bank * 8) & 3) << 30) | (((mem_end >> bank * 8) & 0xFF) << 20) | 0xFFFFFUL; if (bank && bank_start != ram_size) LOG_F(WARNING, "MPC106: RAM not contiguous! \n"); ram_size += bank_end - bank_start + 1; } } if (!this->add_ram_region(0, ram_size)) { LOG_F(ERROR, "MPC106 RAM allocation failed! \n"); } }