1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-26 23:52:26 +00:00
CLK/Machines/Atari/ST/DMAController.cpp
Thomas Harte 05bcd73f82 Attempts to pull drive ownership into DiskController.
For the sake of being more intelligent as to drive clocking, hopefully. And, eventually, to support multiple drive selection.
2020-02-11 21:59:13 -05:00

261 lines
7.4 KiB
C++

//
// DMAController.cpp
// Clock Signal
//
// Created by Thomas Harte on 26/10/2019.
// Copyright © 2019 Thomas Harte. All rights reserved.
//
#include "DMAController.hpp"
#define LOG_PREFIX "[DMA] "
#include "../../../Outputs/Log.hpp"
#include <cstdio>
using namespace Atari::ST;
namespace {
enum Control: uint16_t {
Direction = 0x100,
DRQSource = 0x80,
SectorCountSelect = 0x10,
CPUTarget = 0x08
};
}
DMAController::DMAController() {
fdc_.set_delegate(this);
fdc_.set_clocking_hint_observer(this);
}
uint16_t DMAController::read(int address) {
switch(address & 7) {
// Reserved.
default: break;
// Disk controller or sector count.
case 2:
if(control_ & Control::SectorCountSelect) {
return uint16_t((byte_count_ + 511) >> 9); // Assumed here: the count is of sectors remaining, i.e. it decrements
// only when a sector is complete.
} else {
if(control_ & Control::CPUTarget) {
return 0xffff;
} else {
return 0xff00 | fdc_.read(control_ >> 1);
}
}
break;
// DMA status.
case 3:
// TODO: should DRQ come from the HDC if that mode is selected?
return 0xfff8 | (error_ ? 0 : 1) | (byte_count_ ? 2 : 0) | (fdc_.get_data_request_line() ? 4 : 0);
// DMA addressing.
case 4: return uint16_t(0xff00 | ((address_ >> 16) & 0xff));
case 5: return uint16_t(0xff00 | ((address_ >> 8) & 0xff));
case 6: return uint16_t(0xff00 | ((address_ >> 0) & 0xff));
}
return 0xffff;
}
void DMAController::write(int address, uint16_t value) {
switch(address & 7) {
// Reserved.
default: break;
// Disk controller or sector count.
case 2:
if(control_ & Control::SectorCountSelect) {
byte_count_ = (value & 0xff) << 9; // The computer provides a sector count; that times 512 is a byte count.
// TODO: if this is a write-mode DMA operation, try to fill both buffers, ASAP.
} else {
if(control_ & Control::CPUTarget) {
// TODO: HDC.
} else {
fdc_.write(control_ >> 1, uint8_t(value));
}
}
break;
// DMA control; meaning is:
//
// b0: unused
// b1, b2 = address lines for FDC access.
// b3 = 1 => CPU HDC access; 0 => CPU FDC access.
// b4 = 1 => sector count access; 0 => [F/H]DC access.
// b5: unused.
// b6 = officially, 1 => DMA off; 0 => DMA on. Ignored in real hardware.
// b7 = 1 => FDC DRQs being observed; 0 => HDC access DRQs being observed.
// b8 = 1 => DMA is writing to [F/H]DC; 0 => DMA is reading. Changing value resets DMA state.
//
// All other bits: undefined.
case 3:
// Check for a DMA state reset.
if((control_^value) & Control::Direction) {
bytes_received_ = active_buffer_ = 0;
error_ = false;
byte_count_ = 0;
}
control_ = value;
break;
// DMA addressing; cf. http://www.atari-forum.com/viewtopic.php?t=30289 on a hardware
// feature emulated here: 'carry' will ripple upwards if a write resets the top bit
// of the byte it is adjusting.
case 4: address_ = int((address_ & 0x00ffff) | ((value & 0xff) << 16)); break;
case 5:
if(((value << 8) ^ address_) & ~(value << 8) & 0x8000) address_ += 0x10000;
address_ = int((address_ & 0xff00ff) | ((value & 0xff) << 8));
break;
case 6:
if((value ^ address_) & ~value & 0x80) address_ += 0x100;
address_ = int((address_ & 0xffff00) | ((value & 0xfe) << 0));
break; // Lowest bit: discarded.
}
}
void DMAController::set_floppy_drive_selection(bool drive1, bool drive2, bool side2) {
// LOG("Selected: " << (drive1 ? "1" : "-") << (drive2 ? "2" : "-") << (side2 ? "s" : "-"));
fdc_.set_floppy_drive_selection(drive1, drive2, side2);
}
void DMAController::set_floppy_disk(std::shared_ptr<Storage::Disk::Disk> disk, size_t drive) {
fdc_.set_disk(disk, drive);
}
void DMAController::run_for(HalfCycles duration) {
running_time_ += duration;
fdc_.run_for(duration.flush<Cycles>());
}
void DMAController::wd1770_did_change_output(WD::WD1770 *) {
// Check for a change in interrupt state.
const bool old_interrupt_line = interrupt_line_;
interrupt_line_ = fdc_.get_interrupt_request_line();
if(delegate_ && interrupt_line_ != old_interrupt_line) {
delegate_->dma_controller_did_change_output(this);
}
// Check for a change in DRQ state, if it's the FDC that is currently being watched.
if(byte_count_ && fdc_.get_data_request_line() && (control_ & Control::DRQSource)) {
--byte_count_;
if(control_ & Control::Direction) {
// TODO: DMA is supposed to be helping with a write.
} else {
// DMA is enabling a read.
// Read from the data register into the active buffer.
if(bytes_received_ < 16) {
buffer_[active_buffer_].contents[bytes_received_] = fdc_.read(3);
++bytes_received_;
}
if(bytes_received_ == 16) {
// Mark buffer as full.
buffer_[active_buffer_].is_full = true;
// Move to the next if it is empty; if it isn't, note a DMA error.
const auto next_buffer = active_buffer_ ^ 1;
error_ |= buffer_[next_buffer].is_full;
if(!buffer_[next_buffer].is_full) {
bytes_received_ = 0;
active_buffer_ = next_buffer;
}
// Set bus request.
if(!bus_request_line_) {
bus_request_line_ = true;
if(delegate_) delegate_->dma_controller_did_change_output(this);
}
}
}
}
}
int DMAController::bus_grant(uint16_t *ram, size_t size) {
// Being granted the bus negates the request.
bus_request_line_ = false;
if(delegate_) delegate_->dma_controller_did_change_output(this);
size <<= 1; // Convert to bytes.
if(control_ & Control::Direction) {
// TODO: writes.
return 0;
} else {
// Check that the older buffer is full; stop if not.
if(!buffer_[active_buffer_ ^ 1].is_full) return 0;
#define b(i, n) " " << PADHEX(2) << int(buffer_[i].contents[n])
#define b2(i, n) b(i, n) << b(i, n+1)
#define b4(i, n) b2(i, n) << b2(i, n+2)
#define b16(i) b4(i, 0) << b4(i, 4) << b4(i, 8) << b4(i, 12)
// LOG("[1] to " << PADHEX(6) << address_ << b16(active_buffer_ ^ 1));
for(int c = 0; c < 8; ++c) {
if(size_t(address_) < size) {
ram[address_ >> 1] = uint16_t(
(buffer_[active_buffer_ ^ 1].contents[(c << 1) + 0] << 8) |
(buffer_[active_buffer_ ^ 1].contents[(c << 1) + 1] << 0)
);
}
address_ += 2;
}
buffer_[active_buffer_ ^ 1].is_full = false;
// Check that the newer buffer is full; stop if not.
if(!buffer_[active_buffer_ ].is_full) return 8;
// LOG("[2] to " << PADHEX(6) << address_ << b16(active_buffer_));
#undef b16
#undef b4
#undef b2
#undef b
for(int c = 0; c < 8; ++c) {
if(size_t(address_) < size) {
ram[address_ >> 1] = uint16_t(
(buffer_[active_buffer_].contents[(c << 1) + 0] << 8) |
(buffer_[active_buffer_].contents[(c << 1) + 1] << 0)
);
}
address_ += 2;
}
buffer_[active_buffer_].is_full = false;
// Both buffers were full, so unblock reading.
bytes_received_ = 0;
return 16;
}
}
void DMAController::set_delegate(Delegate *delegate) {
delegate_ = delegate;
}
bool DMAController::get_interrupt_line() {
return interrupt_line_;
}
bool DMAController::get_bus_request_line() {
return bus_request_line_;
}
void DMAController::set_component_prefers_clocking(ClockingHint::Source *, ClockingHint::Preference) {
update_clocking_observer();
}
ClockingHint::Preference DMAController::preferred_clocking() {
return (fdc_.preferred_clocking() == ClockingHint::Preference::None) ? ClockingHint::Preference::None : ClockingHint::Preference::RealTime;
}
void DMAController::set_activity_observer(Activity::Observer *observer) {
fdc_.set_activity_observer(observer);
}