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CLK/Machines/Amiga/Amiga.cpp
Thomas Harte 3544746934 Modifies interface, starts on scheduler. 
Probably corrects the pixel clock, which I think was scaled up by a factor of 4.
2021-07-27 16:41:18 -04:00

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//
// Amiga.cpp
// Clock Signal
//
// Created by Thomas Harte on 16/07/2021.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#include "Amiga.hpp"
#include "../../Activity/Source.hpp"
#include "../MachineTypes.hpp"
#include "../../Processors/68000/68000.hpp"
#include "../../Components/6526/6526.hpp"
#include "../../Analyser/Static/Amiga/Target.hpp"
#include "../Utility/MemoryPacker.hpp"
#include "../Utility/MemoryFuzzer.hpp"
//#define NDEBUG
#define LOG_PREFIX "[Amiga] "
#include "../../Outputs/Log.hpp"
#include "Chipset.hpp"
namespace Amiga {
class ConcreteMachine:
public Activity::Source,
public CPU::MC68000::BusHandler,
public MachineTypes::ScanProducer,
public MachineTypes::TimedMachine,
public Machine {
public:
ConcreteMachine(const Analyser::Static::Amiga::Target &target, const ROMMachine::ROMFetcher &rom_fetcher) :
mc68000_(*this),
chipset_(reinterpret_cast<uint16_t *>(memory_.chip_ram.data()), memory_.chip_ram.size()),
cia_a_handler_(memory_),
cia_a_(cia_a_handler_),
cia_b_(cia_b_handler_)
{
(void)target;
// Temporary: use a hard-coded Kickstart selection.
constexpr ROM::Name rom_name = ROM::Name::AmigaA500Kickstart13;
ROM::Request request(rom_name);
auto roms = rom_fetcher(request);
if(!request.validate(roms)) {
throw ROMMachine::Error::MissingROMs;
}
Memory::PackBigEndian16(roms.find(rom_name)->second, memory_.kickstart.data());
// NTSC clock rate: 2*3.579545 = 7.15909Mhz.
// PAL clock rate: 7.09379Mhz; 227 cycles/line.
set_clock_rate(7'093'790.0);
}
// MARK: - MC68000::BusHandler.
using Microcycle = CPU::MC68000::Microcycle;
HalfCycles perform_bus_operation(const CPU::MC68000::Microcycle &cycle, int) {
// Intended 1-2 step here is:
//
// (1) determine when this CPU access will be scheduled;
// (2) do all the other actions prior to this CPU access being scheduled.
//
// (or at least enqueue them, JIT-wise).
// Advance time.
// The CIAs are on the E clock.
// TODO: so they probably should be behind VPA?
cia_divider_ += cycle.length;
const HalfCycles e_clocks = cia_divider_.divide(HalfCycles(20));
if(e_clocks > HalfCycles(0)) {
cia_a_.run_for(e_clocks);
cia_b_.run_for(e_clocks);
}
const auto changes = chipset_.run_for(cycle.length);
cia_a_.advance_tod(changes.vsyncs);
cia_b_.advance_tod(changes.hsyncs);
mc68000_.set_interrupt_level(changes.interrupt_level);
// Check for assertion of reset.
if(cycle.operation & Microcycle::Reset) {
memory_.reset();
LOG("Reset; PC is around " << PADHEX(8) << mc68000_.get_state().program_counter);
}
// Autovector interrupts.
if(cycle.operation & Microcycle::InterruptAcknowledge) {
mc68000_.set_is_peripheral_address(true);
} else {
mc68000_.set_is_peripheral_address(false);
}
// Do nothing if no address is exposed.
if(!(cycle.operation & (Microcycle::NewAddress | Microcycle::SameAddress))) return HalfCycles(0);
// TODO: interrupt acknowledgement.
// Grab the target address to pick a memory source.
const uint32_t address = cycle.host_endian_byte_address();
// if((cycle.operation & (Microcycle::SelectByte | Microcycle::SelectWord)) && !(cycle.operation & Microcycle::IsProgram)) {
// printf("%06x\n", *cycle.address);
// }
if(!memory_.regions[address >> 18].read_write_mask) {
if((cycle.operation & (Microcycle::SelectByte | Microcycle::SelectWord))) {
// Check for various potential chip accesses.
// Per the manual:
//
// CIA A is: 101x xxxx xx01 rrrr xxxx xxx0 (i.e. loaded into high byte)
// CIA B is: 101x xxxx xx10 rrrr xxxx xxx1 (i.e. loaded into low byte)
//
// but in order to map 0xbfexxx to CIA A and 0xbfdxxx to CIA B, I think
// these might be listed the wrong way around.
//
// Additional assumption: the relevant CIA select lines are connected
// directly to the chip enables.
if((address & 0xe0'0000) == 0xa0'0000) {
const int reg = address >> 8;
LOG("CIA " << (cycle.operation & Microcycle::Read ? "read " : "write ") << PADHEX(4) << *cycle.address);
if(cycle.operation & Microcycle::Read) {
uint16_t result = 0xffff;
if(!(address & 0x1000)) result &= 0xff00 | (cia_a_.read(reg) << 0);
if(!(address & 0x2000)) result &= 0x00ff | (cia_b_.read(reg) << 8);
cycle.set_value16(result);
} else {
if(!(address & 0x1000)) cia_a_.write(reg, cycle.value8_low());
if(!(address & 0x2000)) cia_b_.write(reg, cycle.value8_high());
}
} else if(address >= 0xdf'f000 && address <= 0xdf'f1be) {
chipset_.perform(cycle);
} else {
// This'll do for open bus, for now.
if(cycle.operation & Microcycle::Read) {
cycle.set_value16(0xffff);
}
// Don't log for the region that is definitely just ROM this machine doesn't have.
if(address < 0xf0'0000) {
LOG("Unmapped " << (cycle.operation & Microcycle::Read ? "read from " : "write to ") << PADHEX(4) << *cycle.address << " of " << cycle.value16());
}
}
}
} else {
// A regular memory access.
cycle.apply(
&memory_.regions[address >> 18].contents[address],
memory_.regions[address >> 18].read_write_mask
);
}
return HalfCycles(0);
}
private:
CPU::MC68000::Processor<ConcreteMachine, true> mc68000_;
// MARK: - Memory map.
struct MemoryMap {
public:
std::array<uint8_t, 512*1024> chip_ram{};
std::array<uint8_t, 512*1024> kickstart{0xff};
struct MemoryRegion {
uint8_t *contents = nullptr;
unsigned int read_write_mask = 0;
} regions[64]; // i.e. top six bits are used as an index.
MemoryMap() {
// Address spaces that matter:
//
// 00'0000 08'0000: chip RAM. [or overlayed KickStart]
// 10'0000: extended chip ram for ECS.
// 20'0000: auto-config space (/fast RAM).
// ...
// bf'd000 c0'0000: 8250s.
// c0'0000 d8'0000: pseudo-fast RAM.
// ...
// dc'0000 dd'0000: optional real-time clock.
// df'f000 - e0'0000: custom chip registers.
// ...
// f0'0000 — : 512kb Kickstart (or possibly just an extra 512kb reserved for hypothetical 1mb Kickstart?).
// f8'0000 — : 256kb Kickstart if 2.04 or higher.
// fc'0000 : 256kb Kickstart otherwise.
set_region(0xfc'0000, 0x1'00'0000, kickstart.data(), CPU::MC68000::Microcycle::PermitRead);
reset();
}
void reset() {
set_overlay(true);
}
void set_overlay(bool enabled) {
if(overlay_ == enabled) {
return;
}
overlay_ = enabled;
if(enabled) {
set_region(0x00'0000, 0x08'0000, kickstart.data(), CPU::MC68000::Microcycle::PermitRead);
} else {
// Mirror RAM to fill out the address range up to $20'0000 (?)
set_region(0x00'0000, 0x08'0000, chip_ram.data(), CPU::MC68000::Microcycle::PermitRead | CPU::MC68000::Microcycle::PermitWrite);
}
}
private:
bool overlay_ = false;
void set_region(int start, int end, uint8_t *base, unsigned int read_write_mask) {
assert(!(start & ~0xfc'0000));
assert(!((end - (1 << 18)) & ~0xfc'0000));
base -= start;
for(int c = start >> 18; c < end >> 18; c++) {
regions[c].contents = base;
regions[c].read_write_mask = read_write_mask;
}
}
} memory_;
// MARK: - Chipset.
Chipset chipset_;
// MARK: - CIAs.
class CIAAHandler: public MOS::MOS6526::PortHandler {
public:
CIAAHandler(MemoryMap &map) : map_(map) {}
void set_port_output(MOS::MOS6526::Port port, uint8_t value) {
if(port) {
// Parallel port output.
LOG("TODO: parallel output " << PADHEX(2) << +value);
} else {
// b7: /FIR1
// b6: /FIR0
// b5: /RDY
// b4: /TRK0
// b3: /WPRO
// b2: /CHNG
// b1: /LED [output]
// b0: OVL [output]
LOG("LED & memory map: " << PADHEX(2) << +value);
if(observer_) {
observer_->set_led_status(led_name, !(value & 2));
}
map_.set_overlay(value & 1);
}
}
uint8_t get_port_input(MOS::MOS6526::Port port) {
if(port) {
LOG("TODO: parallel input?");
} else {
LOG("TODO: CIA A, port A input — FIR, RDY, TRK0, etc");
// Announce that TRK0 is upon us.
return 0xef;
}
return 0xff;
}
void set_activity_observer(Activity::Observer *observer) {
observer_ = observer;
if(observer) {
observer->register_led(led_name, Activity::Observer::LEDPresentation::Persistent);
}
}
private:
MemoryMap &map_;
Activity::Observer *observer_ = nullptr;
inline static const std::string led_name = "Power";
} cia_a_handler_;
struct CIABHandler: public MOS::MOS6526::PortHandler {
void set_port_output(MOS::MOS6526::Port port, uint8_t value) {
if(port) {
// Serial port control.
//
// b7: /DTR
// b6: /RTS
// b5: /CD
// b4: /CTS
// b3: /DSR
// b2: SEL
// b1: POUT
// b0: BUSY
LOG("TODO: Serial control: " << PADHEX(2) << +value);
} else {
// Disk motor control, drive and head selection,
// and stepper control:
//
// b7: /MTR
// b6: /SEL3
// b5: /SEL2
// b4: /SEL1
// b3: /SEL0
// b2: /SIDE
// b1: DIR
// b0: /STEP
LOG("TODO: Stepping, etc; " << PADHEX(2) << +value);
}
}
} cia_b_handler_;
HalfCycles cia_divider_;
MOS::MOS6526::MOS6526<CIAAHandler, MOS::MOS6526::Personality::P8250> cia_a_;
MOS::MOS6526::MOS6526<CIABHandler, MOS::MOS6526::Personality::P8250> cia_b_;
// MARK: - Activity Source
void set_activity_observer(Activity::Observer *observer) final {
cia_a_handler_.set_activity_observer(observer);
}
// MARK: - MachineTypes::ScanProducer.
void set_scan_target(Outputs::Display::ScanTarget *scan_target) final {
chipset_.set_scan_target(scan_target);
}
Outputs::Display::ScanStatus get_scaled_scan_status() const {
return chipset_.get_scaled_scan_status();
}
// MARK: - MachineTypes::TimedMachine.
void run_for(const Cycles cycles) {
mc68000_.run_for(cycles);
}
};
}
using namespace Amiga;
Machine *Machine::Amiga(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) {
using Target = Analyser::Static::Amiga::Target;
const Target *const amiga_target = dynamic_cast<const Target *>(target);
return new Amiga::ConcreteMachine(*amiga_target, rom_fetcher);
}
Machine::~Machine() {}
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