1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-20 15:31:10 +00:00
CLK/Analyser/Static/MSX/StaticAnalyser.cpp

303 lines
11 KiB
C++

//
// StaticAnalyser.cpp
// Clock Signal
//
// Created by Thomas Harte on 25/11/2017.
// Copyright 2017 Thomas Harte. All rights reserved.
//
#include "StaticAnalyser.hpp"
#include "Cartridge.hpp"
#include "Tape.hpp"
#include "Target.hpp"
#include "../Disassembler/Z80.hpp"
#include "../Disassembler/AddressMapper.hpp"
#include <algorithm>
static std::unique_ptr<Analyser::Static::Target> CartridgeTarget(
const Storage::Cartridge::Cartridge::Segment &segment,
uint16_t start_address,
Analyser::Static::MSX::Cartridge::Type type,
float confidence) {
// Size down to a multiple of 8kb in size and apply the start address.
std::vector<Storage::Cartridge::Cartridge::Segment> output_segments;
if(segment.data.size() & 0x1fff) {
std::vector<uint8_t> truncated_data;
std::vector<uint8_t>::difference_type truncated_size = std::vector<uint8_t>::difference_type(segment.data.size()) & ~0x1fff;
truncated_data.insert(truncated_data.begin(), segment.data.begin(), segment.data.begin() + truncated_size);
output_segments.emplace_back(start_address, truncated_data);
} else {
output_segments.emplace_back(start_address, segment.data);
}
auto target = std::make_unique<Analyser::Static::MSX::Target>();
target->confidence = confidence;
if(type == Analyser::Static::MSX::Cartridge::Type::None) {
target->media.cartridges.emplace_back(new Storage::Cartridge::Cartridge(output_segments));
} else {
target->media.cartridges.emplace_back(new Analyser::Static::MSX::Cartridge(output_segments, type));
}
return target;
}
/*
Expected standard cartridge format:
DEFB "AB" ; expansion ROM header
DEFW initcode ; start of the init code, 0 if no initcode
DEFW callstat; pointer to CALL statement handler, 0 if no such handler
DEFW device; pointer to expansion device handler, 0 if no such handler
DEFW basic ; pointer to the start of a tokenized basicprogram, 0 if no basicprogram
DEFS 6,0 ; room reserved for future extensions
MSX cartridges often include banking hardware; those games were marketed as MegaROMs. The file
format that the MSX community has decided upon doesn't retain the type of hardware included, so
this analyser has to guess.
(additional audio hardware is also sometimes included, but it's implied by the banking hardware)
*/
static Analyser::Static::TargetList CartridgeTargetsFrom(
const std::vector<std::shared_ptr<Storage::Cartridge::Cartridge>> &cartridges) {
// No cartridges implies no targets.
if(cartridges.empty()) {
return {};
}
Analyser::Static::TargetList targets;
for(const auto &cartridge : cartridges) {
const auto &segments = cartridge->get_segments();
// Only one mapped item is allowed.
if(segments.size() != 1) continue;
// Which must be no more than 63 bytes larger than a multiple of 8 kb in size.
Storage::Cartridge::Cartridge::Segment segment = segments.front();
const size_t data_size = segment.data.size();
if(data_size < 0x2000 || (data_size & 0x1fff) > 64) continue;
// Check for a ROM header at address 0; if it's not found then try 0x4000
// and adjust the start address;
uint16_t start_address = 0;
bool found_start = false;
if(segment.data[0] == 0x41 && segment.data[1] == 0x42) {
start_address = 0x4000;
found_start = true;
} else if(segment.data.size() >= 0x8000 && segment.data[0x4000] == 0x41 && segment.data[0x4001] == 0x42) {
start_address = 0;
found_start = true;
}
// Reject cartridge if the ROM header wasn't found.
if(!found_start) continue;
uint16_t init_address = uint16_t(segment.data[2] | (segment.data[3] << 8));
// TODO: check for a rational init address?
// If this ROM is less than 48kb in size then it's an ordinary ROM. Just emplace it and move on.
if(data_size <= 0xc000) {
targets.emplace_back(CartridgeTarget(segment, start_address, Analyser::Static::MSX::Cartridge::Type::None, 1.0));
continue;
}
// If this ROM is greater than 48kb in size then some sort of MegaROM scheme must
// be at play; disassemble to try to figure it out.
std::vector<uint8_t> first_8k;
first_8k.insert(first_8k.begin(), segment.data.begin(), segment.data.begin() + 8192);
Analyser::Static::Z80::Disassembly disassembly =
Analyser::Static::Z80::Disassemble(
first_8k,
Analyser::Static::Disassembler::OffsetMapper(start_address),
{ init_address }
);
// // Look for a indirect store followed by an unconditional JP or CALL into another
// // segment, that's a fairly explicit sign where found.
using Instruction = Analyser::Static::Z80::Instruction;
std::map<uint16_t, Instruction> &instructions = disassembly.instructions_by_address;
bool is_ascii = false;
// auto iterator = instructions.begin();
// while(iterator != instructions.end()) {
// auto next_iterator = iterator;
// next_iterator++;
// if(next_iterator == instructions.end()) break;
//
// if( iterator->second.operation == Instruction::Operation::LD &&
// iterator->second.destination == Instruction::Location::Operand_Indirect &&
// (
// iterator->second.operand == 0x5000 ||
// iterator->second.operand == 0x6000 ||
// iterator->second.operand == 0x6800 ||
// iterator->second.operand == 0x7000 ||
// iterator->second.operand == 0x77ff ||
// iterator->second.operand == 0x7800 ||
// iterator->second.operand == 0x8000 ||
// iterator->second.operand == 0x9000 ||
// iterator->second.operand == 0xa000
// ) &&
// (
// next_iterator->second.operation == Instruction::Operation::CALL ||
// next_iterator->second.operation == Instruction::Operation::JP
// ) &&
// ((next_iterator->second.operand >> 13) != (0x4000 >> 13))
// ) {
// const uint16_t address = uint16_t(next_iterator->second.operand);
// switch(iterator->second.operand) {
// case 0x6000:
// if(address >= 0x6000 && address < 0x8000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::KonamiWithSCC;
// }
// break;
// case 0x6800:
// if(address >= 0x6000 && address < 0x6800) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::ASCII8kb;
// }
// break;
// case 0x7000:
// if(address >= 0x6000 && address < 0x8000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::KonamiWithSCC;
// }
// if(address >= 0x7000 && address < 0x7800) {
// is_ascii = true;
// }
// break;
// case 0x77ff:
// if(address >= 0x7000 && address < 0x7800) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::ASCII16kb;
// }
// break;
// case 0x7800:
// if(address >= 0xa000 && address < 0xc000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::ASCII8kb;
// }
// break;
// case 0x8000:
// if(address >= 0x8000 && address < 0xa000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::KonamiWithSCC;
// }
// break;
// case 0x9000:
// if(address >= 0x8000 && address < 0xa000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::KonamiWithSCC;
// }
// break;
// case 0xa000:
// if(address >= 0xa000 && address < 0xc000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::Konami;
// }
// break;
// case 0xb000:
// if(address >= 0xa000 && address < 0xc000) {
// target.msx.cartridge_type = Analyser::Static::MSXCartridgeType::KonamiWithSCC;
// }
// break;
// }
// }
//
// iterator = next_iterator;
// Look for LD (nnnn), A instructions, and collate those addresses.
std::map<uint16_t, int> address_counts;
for(const auto &instruction_pair : instructions) {
if( instruction_pair.second.operation == Instruction::Operation::LD &&
instruction_pair.second.destination == Instruction::Location::Operand_Indirect &&
instruction_pair.second.source == Instruction::Location::A) {
address_counts[uint16_t(instruction_pair.second.operand)]++;
}
}
// Weight confidences by number of observed hits.
float total_hits =
float(
address_counts[0x6000] + address_counts[0x6800] +
address_counts[0x7000] + address_counts[0x7800] +
address_counts[0x77ff] + address_counts[0x8000] +
address_counts[0xa000] + address_counts[0x5000] +
address_counts[0x9000] + address_counts[0xb000]
);
targets.push_back(CartridgeTarget(
segment,
start_address,
Analyser::Static::MSX::Cartridge::ASCII8kb,
float( address_counts[0x6000] +
address_counts[0x6800] +
address_counts[0x7000] +
address_counts[0x7800]) / total_hits));
targets.push_back(CartridgeTarget(
segment,
start_address,
Analyser::Static::MSX::Cartridge::ASCII16kb,
float( address_counts[0x6000] +
address_counts[0x7000] +
address_counts[0x77ff]) / total_hits));
if(!is_ascii) {
targets.push_back(CartridgeTarget(
segment,
start_address,
Analyser::Static::MSX::Cartridge::Konami,
float( address_counts[0x6000] +
address_counts[0x8000] +
address_counts[0xa000]) / total_hits));
}
if(!is_ascii) {
targets.push_back(CartridgeTarget(
segment,
start_address,
Analyser::Static::MSX::Cartridge::KonamiWithSCC,
float( address_counts[0x5000] +
address_counts[0x7000] +
address_counts[0x9000] +
address_counts[0xb000]) / total_hits));
}
}
return targets;
}
Analyser::Static::TargetList Analyser::Static::MSX::GetTargets(const Media &media, const std::string &, TargetPlatform::IntType) {
TargetList destination;
// Append targets for any cartridges that look correct.
auto cartridge_targets = CartridgeTargetsFrom(media.cartridges);
std::move(cartridge_targets.begin(), cartridge_targets.end(), std::back_inserter(destination));
// Consider building a target for disks and/or tapes.
auto target = std::make_unique<Target>();
// Check tapes for loadable files.
for(auto &tape : media.tapes) {
std::vector<File> files_on_tape = GetFiles(tape);
if(!files_on_tape.empty()) {
switch(files_on_tape.front().type) {
case File::Type::ASCII: target->loading_command = "RUN\"CAS:\r"; break;
case File::Type::TokenisedBASIC: target->loading_command = "CLOAD\rRUN\r"; break;
case File::Type::Binary: target->loading_command = "BLOAD\"CAS:\",R\r"; break;
default: break;
}
target->media.tapes.push_back(tape);
}
}
// Region selection: for now, this as simple as:
// "If a tape is involved, be European. Otherwise be American (i.e. English, but 60Hz)".
target->region = target->media.tapes.empty() ? Target::Region::USA : Target::Region::Europe;
// Blindly accept disks for now.
// TODO: how to spot an MSX disk?
target->media.disks = media.disks;
target->has_disk_drive = !media.disks.empty();
if(!target->media.empty()) {
target->confidence = 0.5;
destination.push_back(std::move(target));
}
return destination;
}