dingusppc/devices/video/control.cpp

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/*
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 <https://www.gnu.org/licenses/>.
*/
/** @file TNT on-board video output emulation. */
/** TNT on-board video comprises several components:
- Chaos ASIC that provides data bus buffering between the video subsystem
and the processor bus
- Control ASIC that provides addressing and control for the video subsystem
- RaDACal RAMDAC ASIC for generating video stream to the monitor
- Athens clock generator for generating pixel clock
Kudos to joevt#3510 for his precious technical help and HW hacking.
*/
#include <devices/common/i2c/athens.h>
#include <devices/common/i2c/i2c.h>
#include <devices/deviceregistry.h>
#include <devices/video/control.h>
#include <endianswap.h>
#include <loguru.hpp>
#include <machines/machinebase.h>
#include <machines/machineproperties.h>
#include <memaccess.h>
#include <cinttypes>
ControlVideo::ControlVideo()
: PCIDevice("Control-Video"), VideoCtrlBase(640, 480)
{
supports_types(HWCompType::PCI_HOST | HWCompType::PCI_DEV);
// get VRAM size in MBs and convert it to bytes
this->vram_size = GET_INT_PROP("gfxmem_size") << 20;
// allocate VRAM
this->vram_ptr = std::unique_ptr<uint8_t[]> (new uint8_t[this->vram_size]);
// set up PCI configuration space header
this->vendor_id = PCI_VENDOR_APPLE;
this->device_id = 3;
this->class_rev = 0;
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this->setup_bars({
{0, 0xFFFFFFFFUL}, // I/O region (4 bytes but it's weird because bit 1 is set)
{1, 0xFFFFF000UL}, // base address for the HW registers (4KB)
{2, 0xFC000000UL} // base address for the VRAM (64MB)
});
this->pci_notify_bar_change = [this](int bar_num) {
this->notify_bar_change(bar_num);
};
// initialize the video clock generator
this->clk_gen = std::unique_ptr<AthensClocks> (new AthensClocks(0x28));
// register the video clock generator with the I2C host
I2CBus* i2c_bus = dynamic_cast<I2CBus*>(gMachineObj->get_comp_by_type(HWCompType::I2C_HOST));
i2c_bus->register_device(0x28, this->clk_gen.get());
// register RaDACal with the I/O controller
GrandCentral* gc_obj = dynamic_cast<GrandCentral*>(gMachineObj->get_comp_by_name("GrandCentral"));
gc_obj->attach_iodevice(1, this);
// initialize display identification
this->display_id = std::unique_ptr<DisplayID> (new DisplayID());
}
void ControlVideo::notify_bar_change(int bar_num)
{
switch (bar_num) {
case 0:
this->io_base = this->bars[bar_num] & ~3;
LOG_F(INFO, "Control: I/O space address set to 0x%08X", this->io_base);
break;
case 1:
if (this->regs_base != (this->bars[bar_num] & 0xFFFFFFF0UL)) {
this->regs_base = this->bars[bar_num] & 0xFFFFFFF0UL;
this->host_instance->pci_register_mmio_region(this->regs_base,
0x1000, this);
LOG_F(INFO, "Control: register aperture set to 0x%08X", this->regs_base);
}
break;
case 2:
if (this->vram_base != (this->bars[bar_num] & 0xFFFFFFF0UL)) {
this->vram_base = this->bars[bar_num] & 0xFFFFFFF0UL;
this->host_instance->pci_register_mmio_region(this->vram_base,
0x04000000, this);
LOG_F(INFO, "Control: VRAM aperture set to 0x%08X", this->vram_base);
}
break;
}
}
uint32_t ControlVideo::read(uint32_t rgn_start, uint32_t offset, int size)
{
uint32_t result = 0;
if (rgn_start == this->vram_base) {
if (offset >= 0x800000) {
return read_mem_rev(&this->vram_ptr[offset - 0x800000], size);
} else {
LOG_F(INFO, "Control: little-endian access to VRAM not supported yet");
return 0;
}
}
if (rgn_start == this->regs_base) {
switch (offset >> 4) {
case ControlRegs::TEST:
result = this->test;
break;
case ControlRegs::MON_SENSE:
result = this->cur_mon_id << 6;
break;
default:
LOG_F(INFO, "read from 0x%08X:0x%08X", rgn_start, offset);
}
return BYTESWAP_32(result);
}
return 0;
}
void ControlVideo::write(uint32_t rgn_start, uint32_t offset, uint32_t value, int size)
{
if (rgn_start == this->vram_base) {
if (offset >= 0x800000) {
write_mem_rev(&this->vram_ptr[offset - 0x800000], value, size);
} else {
LOG_F(INFO, "Control: little-endian access to VRAM not supported yet");
}
return;
}
if (rgn_start == this->regs_base) {
value = BYTESWAP_32(value);
switch (offset >> 4) {
case ControlRegs::VFPEQ:
case ControlRegs::VFP:
case ControlRegs::VAL:
case ControlRegs::VBP:
case ControlRegs::VBPEQ:
case ControlRegs::VSYNC:
case ControlRegs::VHLINE:
case ControlRegs::PIPED:
case ControlRegs::HPIX:
case ControlRegs::HFP:
case ControlRegs::HAL:
case ControlRegs::HBWAY:
case ControlRegs::HSP:
case ControlRegs::HEQ:
case ControlRegs::HLFLN:
case ControlRegs::HSERR:
this->swatch_params[(offset >> 4) - 1] = value;
break;
case ControlRegs::TEST:
if (this->test != value) {
if ((this->test & ~TEST_STROBE) != (value & ~TEST_STROBE)) {
this->test = value;
this->test_shift = 0;
LOG_F(9, "New TEST value: 0x%08X", this->test);
} else {
LOG_F(9, "TEST strobe bit flipped, new value: 0x%08X", value);
this->test = value;
if (++this->test_shift >= 3) {
LOG_F(9, "Received TEST reg value: 0x%08X", this->test & ~TEST_STROBE);
if ((this->test ^ this->prev_test) & 0x400) {
if (this->test & 0x400) {
this->disable_display();
} else {
this->enable_display();
}
this->prev_test = this->test;
}
}
}
}
break;
case ControlRegs::GBASE:
this->fb_base = value;
break;
case ControlRegs::ROW_WORDS:
this->row_words = value;
break;
case ControlRegs::MON_SENSE:
LOG_F(9, "Control: monitor sense written with 0x%X", value);
value = (value >> 3) & 7;
this->cur_mon_id = this->display_id->read_monitor_sense(value & 7, value ^ 7);
break;
case ControlRegs::ENABLE:
this->flags = value;
break;
case ControlRegs::GSC_DIVIDE:
this->clock_divider = value;
break;
case ControlRegs::REFRESH_COUNT:
LOG_F(INFO, "Control: refresh count set to 0x%08X", value);
break;
case ControlRegs::INT_ENABLE:
this->int_enable = value;
break;
default:
LOG_F(INFO, "write 0x%08X to 0x%08X:0x%08X", value, rgn_start, offset);
}
}
}
void ControlVideo::enable_display()
{
int new_width, new_height, hori_blank, vert_blank, clk_divisor;
// get pixel frequency from Athens
this->pixel_clock = this->clk_gen->get_dot_freq();
// get RaDACal clock divisor
clk_divisor = 1 << ((rad_cr >> 6) + 1);
// calculate active_width and active_height from video timing parameters
new_width = swatch_params[ControlRegs::HFP-1] - swatch_params[ControlRegs::HAL-1];
new_height = swatch_params[ControlRegs::VFP-1] - swatch_params[ControlRegs::VAL-1];
new_width *= clk_divisor;
new_height >>= 1; // FIXME: assume non-interlaced mode for now
if (new_width != this->active_width || new_height != this->active_height) {
LOG_F(WARNING, "Display window resizing not implemented yet!");
}
this->active_width = new_width;
this->active_height = new_height;
// get pixel depth from RaDACal
switch ((this->rad_cr >> 2) & 3) {
case 0:
this->pixel_depth = 8;
break;
case 1:
this->pixel_depth = 16;
break;
case 2:
this->pixel_depth = 32;
break;
default:
ABORT_F("Invalid RaDACal pixel depth code!");
}
if (pixel_depth == 8) {
this->convert_fb_cb = [this](uint8_t *dst_buf, int dst_pitch) {
this->convert_frame_8bpp(dst_buf, dst_pitch);
};
} else {
ABORT_F("Control: 16bpp and 32bpp formats not supported yet!");
}
// set framebuffer parameters
this->fb_ptr = &this->vram_ptr[this->fb_base];
this->fb_pitch = this->row_words;
// calculate display refresh rate
hori_blank = swatch_params[ControlRegs::HAL-1] +
(swatch_params[ControlRegs::HSP-1] - swatch_params[ControlRegs::HFP-1]);
hori_blank *= clk_divisor;
vert_blank = swatch_params[ControlRegs::VAL-1] +
(swatch_params[ControlRegs::VSYNC-1] - swatch_params[ControlRegs::VFP-1]);
vert_blank >>= 1;
this->refresh_rate = (double)(this->pixel_clock) / (new_width + hori_blank)
/ (new_height + vert_blank);
LOG_F(INFO, "Control: refresh rate set to %f Hz", this->refresh_rate);
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this->stop_refresh_task();
// set up periodic timer for display updates
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this->start_refresh_task();
this->blank_on = false;
LOG_F(INFO, "Control: display enabled");
this->crtc_on = true;
}
void ControlVideo::disable_display()
{
this->crtc_on = false;
LOG_F(INFO, "Control: display disabled");
}
// ========================== RaDACal related stuff ==========================
uint16_t ControlVideo::iodev_read(uint32_t address)
{
LOG_F(INFO, "RaDACal: read from 0x%08X", address);
return 0;
}
void ControlVideo::iodev_write(uint32_t address, uint16_t value)
{
switch (address) {
case RadacalRegs::ADDRESS:
this->rad_addr = value;
this->comp_index = 0;
break;
case RadacalRegs::CURSOR_DATA:
break;
case RadacalRegs::MULTI:
switch (this->rad_addr) {
case RadacalRegs::CURSOR_POS_HI:
this->rad_cur_pos_hi = value;
break;
case RadacalRegs::CURSOR_POS_LO:
this->rad_cur_pos_lo = value;
break;
case RadacalRegs::MISC_CTRL:
this->rad_cr = value;
break;
case RadacalRegs::DBL_BUF_CTRL:
this->rad_dbl_buf_cr = value;
break;
default:
LOG_F(ERROR, "Unsupported RaDACal register %d", this->rad_addr);
}
break;
case RadacalRegs::CLUT_DATA:
this->clut_color[this->comp_index++] = value;
if (this->comp_index >= 3) {
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this->set_palette_color(this->rad_addr, clut_color[0],
clut_color[1], clut_color[2], 0xFF);
this->rad_addr++; // auto-increment CLUT address
this->comp_index = 0;
}
break;
default:
LOG_F(INFO, "RaDACal: write to non-existent register at 0x%08X", address);
}
}
// ========================== Device registry stuff ==========================
static const PropMap Control_Properties = {
{"gfxmem_size",
new IntProperty( 2, vector<uint32_t>({2, 4}))},
{"mon_id",
new StrProperty("AppleVision1710")},
};
static const DeviceDescription Control_Descriptor = {
ControlVideo::create, {}, Control_Properties
};
REGISTER_DEVICE(ControlVideo, Control_Descriptor);