/*
DingusPPC - The Experimental PowerPC Macintosh emulator
Copyright (C) 2018-25 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 MacIO 2nd generation I/O controllers emulation. */
#include
#include
#include
#include
MacIoTwo::MacIoTwo(std::string name, uint16_t dev_id) : MacIoBase(name, dev_id) {
// NVRAM connection
this->nvram = dynamic_cast(gMachineObj->get_comp_by_name("NVRAM"));
// connect SCSI controller cell and its DMA channel
this->mesh = dynamic_cast(gMachineObj->get_comp_by_type(HWCompType::SCSI_HOST));
this->mesh_dma = std::unique_ptr (new DMAChannel("mesh"));
this->mesh_dma->register_dma_int(this, this->register_dma_int(IntSrc::DMA_SCSI_MESH));
this->mesh_dma->connect(this->mesh);
this->mesh->connect(this->mesh_dma.get());
// connect IDE HW
this->ide_0 = dynamic_cast(gMachineObj->get_comp_by_name("Ide0"));
this->ide_1 = dynamic_cast(gMachineObj->get_comp_by_name("Ide1"));
this->ide0_dma = std::unique_ptr (new DMAChannel("Ide0-Dma"));
this->ide1_dma = std::unique_ptr (new DMAChannel("Ide1-Dma"));
// connect Ethernet HW (Heathrow and Paddington)
if (this->device_id != MIO_DEV_ID_OHARE) {
this->bmac = dynamic_cast(gMachineObj->get_comp_by_type(HWCompType::ETHER_MAC));
this->enet_xmit_dma = std::unique_ptr (new DMAChannel("BmacTx"));
this->enet_rcv_dma = std::unique_ptr (new DMAChannel("BmacRx"));
}
// set EMMO status (active low)
this->emmo = GET_BIN_PROP("emmo") ^ 1;
}
uint32_t MacIoTwo::read(uint32_t rgn_start, uint32_t offset, int size) {
uint32_t value;
LOG_F(9, "%s: read @%x.%c", this->get_name().c_str(),
offset, SIZE_ARG(size));
unsigned sub_addr = (offset >> 12) & 0x7F;
switch (sub_addr) {
case 0:
value = mio_ctrl_read(offset, size);
break;
case 8:
value = dma_read(offset & 0x7FFF, size);
break;
case 0x10: // SCSI
value = this->mesh->read((offset >> 4) & 0xF);
break;
case 0x11: // Ethernet
value = BYTESWAP_SIZED(this->bmac->read(offset & 0xFFFU), size);
break;
case 0x12: // ESCC compatible addressing
if ((offset & 0xFF) < 0x0C) {
value = this->escc->read(compat_to_macrisc[(offset >> 1) & 0xF]);
break;
}
if ((offset & 0xFF) < 0x60) {
value = 0;
LOG_F(ERROR, "%s: ESCC compatible read @%x.%c", this->name.c_str(),
offset, SIZE_ARG(size));
break;
}
// fallthrough
case 0x13: // ESCC MacRISC addressing
value = this->escc->read((offset >> 4) & 0xF);
break;
case 0x14:
value = this->snd_codec->snd_ctrl_read(offset & 0xFF, size);
break;
case 0x15: // SWIM3
value = this->swim3->read((offset >> 4) & 0xF);
break;
case 0x16: // VIA-CUDA
case 0x17:
value = this->viacuda->read((offset >> 9) & 0xF);
break;
case 0x20: // IDE 0
value = this->ide_0->read((offset >> 4) & 0x1F, size);
break;
case 0x21: // IDE 1
value = this->ide_1->read((offset >> 4) & 0x1F, size);
break;
default:
if (sub_addr >= 0x60) {
value = this->nvram->read_byte((offset >> 4) & 0x1FFF);
} else {
value = 0;
LOG_F(WARNING, "%s: read @%x.%c", this->get_name().c_str(),
offset, SIZE_ARG(size));
}
}
return value;
}
void MacIoTwo::write(uint32_t rgn_start, uint32_t offset, uint32_t value, int size) {
LOG_F(9, "%s: write @%x.%c = %0*x", this->get_name().c_str(),
offset, SIZE_ARG(size), size * 2, value);
unsigned sub_addr = (offset >> 12) & 0x7F;
switch (sub_addr) {
case 0:
this->mio_ctrl_write(offset, value, size);
break;
case 8:
this->dma_write(offset & 0x7FFF, value, size);
break;
case 0x10: // SCSI
this->mesh->write((offset >> 4) & 0xF, value);
break;
case 0x11: // Ethernet
this->bmac->write(offset & 0xFFFU, BYTESWAP_SIZED(value, size));
break;
case 0x12: // ESCC compatible addressing
if ((offset & 0xFF) < 0x0C) {
this->escc->write(compat_to_macrisc[(offset >> 1) & 0xF], value);
break;
}
if ((offset & 0xFF) < 0x60) {
LOG_F(ERROR, "%s: SCC write @%x.%c = %0*x", this->name.c_str(),
offset, SIZE_ARG(size), size * 2, value);
break;
}
// fallthrough
case 0x13: // ESCC MacRISC addressing
this->escc->write((offset >> 4) & 0xF, value);
break;
case 0x14:
this->snd_codec->snd_ctrl_write(offset & 0xFF, value, size);
break;
case 0x15: // SWIM3
this->swim3->write((offset >> 4) & 0xF, value);
break;
case 0x16: // VIA-CUDA
case 0x17:
this->viacuda->write((offset >> 9) & 0xF, value);
break;
case 0x20: // IDE 0
this->ide_0->write((offset >> 4) & 0x1F, value, size);
break;
case 0x21: // IDE 1
this->ide_1->write((offset >> 4) & 0x1F, value, size);
break;
default:
if (sub_addr >= 0x60) {
this->nvram->write_byte((offset - 0x60000) >> 4, value);
} else {
LOG_F(WARNING, "%s: write @%x.%c = %0*x", this->get_name().c_str(),
offset, SIZE_ARG(size), size * 2, value);
}
}
}
static const char *get_name_dma(unsigned dma_channel) {
switch (dma_channel) {
case MIO_OHARE_DMA_MESH : return "DMA_MESH" ;
case MIO_OHARE_DMA_FLOPPY : return "DMA_FLOPPY" ;
case MIO_OHARE_DMA_ETH_XMIT : return "DMA_ETH_XMIT" ;
case MIO_OHARE_DMA_ETH_RCV : return "DMA_ETH_RCV" ;
case MIO_OHARE_DMA_ESCC_A_XMIT : return "DMA_ESCC_A_XMIT";
case MIO_OHARE_DMA_ESCC_A_RCV : return "DMA_ESCC_A_RCV" ;
case MIO_OHARE_DMA_ESCC_B_XMIT : return "DMA_ESCC_B_XMIT";
case MIO_OHARE_DMA_ESCC_B_RCV : return "DMA_ESCC_B_RCV" ;
case MIO_OHARE_DMA_AUDIO_OUT : return "DMA_AUDIO_OUT" ;
case MIO_OHARE_DMA_AUDIO_IN : return "DMA_AUDIO_IN" ;
case MIO_OHARE_DMA_IDE0 : return "DMA_IDE0" ;
case MIO_OHARE_DMA_IDE1 : return "DMA_IDE1" ;
default : return "unknown" ;
}
}
uint32_t MacIoTwo::dma_read(uint32_t offset, int size) {
int dma_channel = offset >> 8;
switch (dma_channel) {
case MIO_OHARE_DMA_MESH:
return this->mesh_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_FLOPPY:
return this->floppy_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_ETH_XMIT:
return this->enet_xmit_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_ETH_RCV:
return this->enet_rcv_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_ESCC_B_RCV:
return 0;
//return this->escc_b_rx_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_AUDIO_OUT:
return this->snd_out_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_IDE0:
return this->ide0_dma->reg_read(offset & 0xFF, size);
case MIO_OHARE_DMA_IDE1:
return this->ide1_dma->reg_read(offset & 0xFF, size);
default:
if (!(unsupported_dma_channel_read & (1 << dma_channel))) {
unsupported_dma_channel_read |= (1 << dma_channel);
LOG_F(WARNING, "%s: Unsupported DMA channel %d %s read @%02x.%c",
this->name.c_str(), dma_channel, get_name_dma(dma_channel),
offset & 0xFF, SIZE_ARG(size));
}
}
return 0;
}
void MacIoTwo::dma_write(uint32_t offset, uint32_t value, int size) {
int dma_channel = offset >> 8;
switch (dma_channel) {
case MIO_OHARE_DMA_MESH:
this->mesh_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_FLOPPY:
this->floppy_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_ETH_XMIT:
this->enet_xmit_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_ETH_RCV:
this->enet_rcv_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_ESCC_B_RCV:
this->escc_b_rx_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_AUDIO_OUT:
this->snd_out_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_IDE0:
this->ide0_dma->reg_write(offset & 0xFF, value, size);
break;
case MIO_OHARE_DMA_IDE1:
this->ide1_dma->reg_write(offset & 0xFF, value, size);
break;
default:
if (!(unsupported_dma_channel_write & (1 << dma_channel))) {
unsupported_dma_channel_write |= (1 << dma_channel);
LOG_F(WARNING, "%s: Unsupported DMA channel %d %s write @%02x.%c = %0*x",
this->name.c_str(), dma_channel, get_name_dma(dma_channel),
offset & 0xFF, SIZE_ARG(size), size * 2, value);
}
}
}
uint32_t MacIoTwo::mio_ctrl_read(uint32_t offset, int size) {
uint32_t value;
switch (offset & 0xFC) {
case MIO_INT_EVENTS2:
value = this->int_events >> 32;
break;
case MIO_INT_MASK2:
value = this->int_mask >> 32;
break;
case MIO_INT_LEVELS2:
value = this->int_levels >> 32;
break;
case MIO_INT_EVENTS1:
value = uint32_t(this->int_events);
break;
case MIO_INT_MASK1:
value = uint32_t(this->int_mask);
break;
case MIO_INT_LEVELS1:
value = uint32_t(int_levels);
break;
case MIO_INT_CLEAR1:
case MIO_INT_CLEAR2:
// some Mac OS drivers read from these write-only registers
// so we return zero here as real HW does
value = 0;
break;
case MIO_OHARE_ID:
value = (this->fp_id << 24) | (this->mon_id << 16) | (this->mb_id << 8) |
(this->cpu_id | (this->emmo << 4));
LOG_F(9, "%s: read OHARE_ID @%02x = %08x",
this->get_name().c_str(), offset, value);
break;
case MIO_OHARE_FEAT_CTRL:
value = this->feat_ctrl;
LOG_F(9, "%s: read FEAT_CTRL @%02x = %08x",
this->get_name().c_str(), offset, value);
break;
default:
value = 0;
LOG_F(WARNING, "%s: read @%02x",
this->get_name().c_str(), offset);
}
return BYTESWAP_32(value);
}
void MacIoTwo::mio_ctrl_write(uint32_t offset, uint32_t value, int size) {
switch (offset & 0xFC) {
case MIO_INT_MASK2:
this->int_mask |= uint64_t(BYTESWAP_32(value) & ~MACIO_INT_MODE) << 32;
this->signal_cpu_int();
break;
case MIO_INT_CLEAR2:
this->int_events &= ~(uint64_t(BYTESWAP_32(value) & 0x7FFFFFFFUL) << 32);
clear_cpu_int();
break;
case MIO_INT_MASK1:
this->int_mask = (this->int_mask & 0x7FFFFFFF00000000ULL) | BYTESWAP_32(value);
// copy IntMode bit to InterruptMask2 register
this->int_mask |= uint64_t(this->int_mask & MACIO_INT_MODE) << 32;
this->signal_cpu_int();
break;
case MIO_INT_CLEAR1:
if ((this->int_mask & MACIO_INT_MODE) && (value & MACIO_INT_CLR)) {
this->int_events = 0;
} else {
this->int_events &= ~uint64_t(BYTESWAP_32(value) & 0x7FFFFFFFUL);
}
clear_cpu_int();
break;
case MIO_OHARE_ID:
LOG_F(ERROR, "%s: write OHARE_ID @%x.%c = %0*x",
this->get_name().c_str(), offset, SIZE_ARG(size), size * 2, value);
break;
case MIO_OHARE_FEAT_CTRL:
LOG_F(WARNING, "%s: write FEAT_CTRL @%x.%c = %0*x",
this->get_name().c_str(), offset, SIZE_ARG(size), size * 2, value);
this->feature_control(BYTESWAP_32(value));
break;
case MIO_AUX_CTRL:
LOG_F(9, "%s: write AUX_CTRL @%x.%c = %0*x",
this->get_name().c_str(), offset, SIZE_ARG(size), size * 2, value);
this->aux_ctrl = value;
break;
default:
LOG_F(WARNING, "%s: write @%x.%c = %0*x",
this->get_name().c_str(), offset, SIZE_ARG(size), size * 2, value);
}
}
void MacIoTwo::feature_control(uint32_t value) {
this->feat_ctrl = value;
if (!(this->feat_ctrl & 1)) {
LOG_F(9, "%s: monitor sense enabled", this->name.c_str());
} else {
LOG_F(9, "%s: monitor sense disabled", this->name.c_str());
}
}
uint64_t MacIoTwo::register_dev_int(IntSrc src_id) {
if (this->device_id == MIO_DEV_ID_OHARE && src_id == ETHERNET) {
ABORT_F("%s: attempt to register non-existing Ethernet device int",
this->name.c_str());
}
switch (src_id) {
case IntSrc::SCSI_MESH : return INT_TO_IRQ_ID(0x0C);
case IntSrc::IDE0 : return INT_TO_IRQ_ID(0x0D); // Beige G3 first IDE controller, or Yosemite ata-3
case IntSrc::IDE1 : return INT_TO_IRQ_ID(0x0E);
case IntSrc::SCCA : return INT_TO_IRQ_ID(0x0F);
case IntSrc::SCCB : return INT_TO_IRQ_ID(0x10);
case IntSrc::DAVBUS : return INT_TO_IRQ_ID(0x11);
case IntSrc::VIA_CUDA : return INT_TO_IRQ_ID(0x12);
case IntSrc::SWIM3 : return INT_TO_IRQ_ID(0x13);
case IntSrc::NMI : return INT_TO_IRQ_ID(0x14); // nmiSource in AppleHeathrow/Heathrow.cpp; programmer-switch in B&W G3
case IntSrc::BANDIT1 : return INT_TO_IRQ_ID(0x16);
case IntSrc::PCI_E : return (this->device_id == MIO_DEV_ID_OHARE)
? INT_TO_IRQ_ID(0x16) // same interrupt as bandit
: INT_TO_IRQ_ID(0x18); // Lombard GPU
case IntSrc::PCI_F : return INT_TO_IRQ_ID(0x18);
case IntSrc::PCI_A : return INT_TO_IRQ_ID(0x17);
case IntSrc::PCI_B : return (this->device_id == MIO_DEV_ID_OHARE)
? INT_TO_IRQ_ID(0x19)
: INT_TO_IRQ_ID(0x18);
// case IntSrc::??? : return INT_TO_IRQ_ID(0x1A);
// case IntSrc::??? : return INT_TO_IRQ_ID(0x1B);
case IntSrc::PCI_C : return (this->device_id == MIO_DEV_ID_OHARE)
? INT_TO_IRQ_ID(0x1C)
: INT_TO_IRQ_ID(0x19);
case IntSrc::PERCH2 : return INT_TO_IRQ_ID(0x15);
case IntSrc::PCI_GPU : return INT_TO_IRQ_ID(0x16);
case IntSrc::PERCH1 : return INT_TO_IRQ_ID(0x1A);
case IntSrc::PCI_PERCH : return INT_TO_IRQ_ID(0x1C);
case IntSrc::FIREWIRE : return INT_TO_IRQ_ID(0x15); // Yosemite built-in PCI FireWire
case IntSrc::PCI_J12 : return INT_TO_IRQ_ID(0x16); // Yosemite 32-bit 66MHz slot for GPU
case IntSrc::PCI_J11 : return INT_TO_IRQ_ID(0x17); // Yosemite 64-bit 33MHz slot
case IntSrc::PCI_J10 : return INT_TO_IRQ_ID(0x18); // Yosemite 64-bit 33MHz slot
case IntSrc::PCI_J9 : return INT_TO_IRQ_ID(0x19); // Yosemite 64-bit 33MHz slot
case IntSrc::ATA : return INT_TO_IRQ_ID(0x1A); // Yosemite PCI pci-ata
case IntSrc::USB : return INT_TO_IRQ_ID(0x1C); // Yosemite PCI USB
case IntSrc::ETHERNET : return INT_TO_IRQ_ID(0x2A);
default:
ABORT_F("%s: unknown interrupt source %d", this->name.c_str(), src_id);
}
return 0;
}
uint64_t MacIoTwo::register_dma_int(IntSrc src_id) {
if (this->device_id == MIO_DEV_ID_OHARE &&
(src_id == IntSrc::DMA_ETHERNET_Tx || src_id == IntSrc::DMA_ETHERNET_Rx)) {
ABORT_F("%s: attempt to register non-existing Ethernet DMA int", this->name.c_str());
}
switch (src_id) {
case IntSrc::DMA_SCSI_MESH : return INT_TO_IRQ_ID(0x00);
case IntSrc::DMA_IDE0 : return INT_TO_IRQ_ID(0x02);
case IntSrc::DMA_IDE1 : return INT_TO_IRQ_ID(0x03);
case IntSrc::DMA_ETHERNET_Tx : return INT_TO_IRQ_ID(0x20);
case IntSrc::DMA_ETHERNET_Rx : return INT_TO_IRQ_ID(0x21);
default:
return MacIoBase::register_dma_int(src_id);
}
return 0;
}
//===========================================================================
static const std::vector OHare_Subdevices = {
"NVRAM", "ViaCuda", "MeshTnt", "Escc", "Swim3", "Ide0", "Ide1"
};
static const std::vector Heathrow_Subdevices = {
"NVRAM", "ViaCuda", "MeshHeathrow", "Escc", "Swim3", "Ide0", "Ide1",
"BigMacHeathrow"
};
static const std::vector Paddington_Subdevices = {
"NVRAM", "ViaCuda", "MeshHeathrow", "Escc", "Swim3", "Ide0", "Ide1",
"BigMacPaddington"
};
static const DeviceDescription OHare_Descriptor = {
MacIoTwo::create_ohare, OHare_Subdevices, {},
HWCompType::MMIO_DEV | HWCompType::PCI_DEV | HWCompType::INT_CTRL
};
static const DeviceDescription Heathrow_Descriptor = {
MacIoTwo::create_heathrow, Heathrow_Subdevices, {},
HWCompType::MMIO_DEV | HWCompType::PCI_DEV | HWCompType::INT_CTRL
};
static const DeviceDescription Paddington_Descriptor = {
MacIoTwo::create_paddington, Paddington_Subdevices, {},
HWCompType::MMIO_DEV | HWCompType::PCI_DEV | HWCompType::INT_CTRL
};
REGISTER_DEVICE(OHare, OHare_Descriptor);
REGISTER_DEVICE(Heathrow, Heathrow_Descriptor);
REGISTER_DEVICE(Paddington, Paddington_Descriptor);