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CLK/Analyser/Static/Atari2600/StaticAnalyser.cpp

206 lines
9.0 KiB
C++

//
// StaticAnalyser.cpp
// Clock Signal
//
// Created by Thomas Harte on 15/09/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include "StaticAnalyser.hpp"
#include "Target.hpp"
#include "../Disassembler/6502.hpp"
using namespace Analyser::Static::Atari2600;
using Target = Analyser::Static::Atari2600::Target;
static void DeterminePagingFor2kCartridge(Target &target, const Storage::Cartridge::Cartridge::Segment &segment) {
// if this is a 2kb cartridge then it's definitely either unpaged or a CommaVid
uint16_t entry_address, break_address;
entry_address = (static_cast<uint16_t>(segment.data[0x7fc] | (segment.data[0x7fd] << 8))) & 0x1fff;
break_address = (static_cast<uint16_t>(segment.data[0x7fe] | (segment.data[0x7ff] << 8))) & 0x1fff;
// a CommaVid start address needs to be outside of its RAM
if(entry_address < 0x1800 || break_address < 0x1800) return;
std::function<std::size_t(uint16_t address)> high_location_mapper = [](uint16_t address) {
address &= 0x1fff;
return static_cast<std::size_t>(address - 0x1800);
};
Analyser::Static::MOS6502::Disassembly high_location_disassembly =
Analyser::Static::MOS6502::Disassemble(segment.data, high_location_mapper, {entry_address, break_address});
// assume that any kind of store that looks likely to be intended for large amounts of memory implies
// large amounts of memory
bool has_wide_area_store = false;
for(std::map<uint16_t, Analyser::Static::MOS6502::Instruction>::value_type &entry : high_location_disassembly.instructions_by_address) {
if(entry.second.operation == Analyser::Static::MOS6502::Instruction::STA) {
has_wide_area_store |= entry.second.addressing_mode == Analyser::Static::MOS6502::Instruction::Indirect;
has_wide_area_store |= entry.second.addressing_mode == Analyser::Static::MOS6502::Instruction::IndexedIndirectX;
has_wide_area_store |= entry.second.addressing_mode == Analyser::Static::MOS6502::Instruction::IndirectIndexedY;
if(has_wide_area_store) break;
}
}
// conclude that this is a CommaVid if it attempted to write something to the CommaVid RAM locations;
// caveat: false positives aren't likely to be problematic; a false positive is a 2KB ROM that always addresses
// itself so as to land in ROM even if mapped as a CommaVid and this code is on the fence as to whether it
// attempts to modify itself but it probably doesn't
if(has_wide_area_store) target.paging_model = Target::PagingModel::CommaVid;
}
static void DeterminePagingFor8kCartridge(Target &target, const Storage::Cartridge::Cartridge::Segment &segment, const Analyser::Static::MOS6502::Disassembly &disassembly) {
// Activision stack titles have their vectors at the top of the low 4k, not the top, and
// always list 0xf000 as both vectors; they do not repeat them, and, inexplicably, they all
// issue an SEI as their first instruction (maybe some sort of relic of the development environment?)
if(
segment.data[4095] == 0xf0 && segment.data[4093] == 0xf0 && segment.data[4094] == 0x00 && segment.data[4092] == 0x00 &&
(segment.data[8191] != 0xf0 || segment.data[8189] != 0xf0 || segment.data[8190] != 0x00 || segment.data[8188] != 0x00) &&
segment.data[0] == 0x78
) {
target.paging_model = Target::PagingModel::ActivisionStack;
return;
}
// make an assumption that this is the Atari paging model
target.paging_model = Target::PagingModel::Atari8k;
std::set<uint16_t> internal_accesses;
internal_accesses.insert(disassembly.internal_stores.begin(), disassembly.internal_stores.end());
internal_accesses.insert(disassembly.internal_modifies.begin(), disassembly.internal_modifies.end());
internal_accesses.insert(disassembly.internal_loads.begin(), disassembly.internal_loads.end());
int atari_access_count = 0;
int parker_access_count = 0;
int tigervision_access_count = 0;
for(uint16_t address : internal_accesses) {
uint16_t masked_address = address & 0x1fff;
atari_access_count += masked_address >= 0x1ff8 && masked_address < 0x1ffa;
parker_access_count += masked_address >= 0x1fe0 && masked_address < 0x1ff8;
}
for(uint16_t address: disassembly.external_stores) {
uint16_t masked_address = address & 0x1fff;
tigervision_access_count += masked_address == 0x3f;
}
if(parker_access_count > atari_access_count) target.paging_model = Target::PagingModel::ParkerBros;
else if(tigervision_access_count > atari_access_count) target.paging_model = Target::PagingModel::Tigervision;
}
static void DeterminePagingFor16kCartridge(Target &target, const Storage::Cartridge::Cartridge::Segment &segment, const Analyser::Static::MOS6502::Disassembly &disassembly) {
// make an assumption that this is the Atari paging model
target.paging_model = Target::PagingModel::Atari16k;
std::set<uint16_t> internal_accesses;
internal_accesses.insert(disassembly.internal_stores.begin(), disassembly.internal_stores.end());
internal_accesses.insert(disassembly.internal_modifies.begin(), disassembly.internal_modifies.end());
internal_accesses.insert(disassembly.internal_loads.begin(), disassembly.internal_loads.end());
int atari_access_count = 0;
int mnetwork_access_count = 0;
for(uint16_t address : internal_accesses) {
uint16_t masked_address = address & 0x1fff;
atari_access_count += masked_address >= 0x1ff6 && masked_address < 0x1ffa;
mnetwork_access_count += masked_address >= 0x1fe0 && masked_address < 0x1ffb;
}
if(mnetwork_access_count > atari_access_count) target.paging_model = Target::PagingModel::MNetwork;
}
static void DeterminePagingFor64kCartridge(Target &target, const Storage::Cartridge::Cartridge::Segment &segment, const Analyser::Static::MOS6502::Disassembly &disassembly) {
// make an assumption that this is a Tigervision if there is a write to 3F
target.paging_model =
(disassembly.external_stores.find(0x3f) != disassembly.external_stores.end()) ?
Target::PagingModel::Tigervision : Target::PagingModel::MegaBoy;
}
static void DeterminePagingForCartridge(Target &target, const Storage::Cartridge::Cartridge::Segment &segment) {
if(segment.data.size() == 2048) {
DeterminePagingFor2kCartridge(target, segment);
return;
}
uint16_t entry_address, break_address;
entry_address = static_cast<uint16_t>(segment.data[segment.data.size() - 4] | (segment.data[segment.data.size() - 3] << 8));
break_address = static_cast<uint16_t>(segment.data[segment.data.size() - 2] | (segment.data[segment.data.size() - 1] << 8));
std::function<std::size_t(uint16_t address)> address_mapper = [](uint16_t address) {
if(!(address & 0x1000)) return static_cast<std::size_t>(-1);
return static_cast<std::size_t>(address & 0xfff);
};
std::vector<uint8_t> final_4k(segment.data.end() - 4096, segment.data.end());
Analyser::Static::MOS6502::Disassembly disassembly = Analyser::Static::MOS6502::Disassemble(final_4k, address_mapper, {entry_address, break_address});
switch(segment.data.size()) {
case 8192:
DeterminePagingFor8kCartridge(target, segment, disassembly);
break;
case 10495:
target.paging_model = Target::PagingModel::Pitfall2;
break;
case 12288:
target.paging_model = Target::PagingModel::CBSRamPlus;
break;
case 16384:
DeterminePagingFor16kCartridge(target, segment, disassembly);
break;
case 32768:
target.paging_model = Target::PagingModel::Atari32k;
break;
case 65536:
DeterminePagingFor64kCartridge(target, segment, disassembly);
break;
default:
break;
}
// check for a Super Chip. Atari ROM images [almost] always have the same value stored over RAM
// regions; when they don't they at least seem to have the first 128 bytes be the same as the
// next 128 bytes. So check for that.
if( target.paging_model != Target::PagingModel::CBSRamPlus &&
target.paging_model != Target::PagingModel::MNetwork) {
bool has_superchip = true;
for(std::size_t address = 0; address < 128; address++) {
if(segment.data[address] != segment.data[address+128]) {
has_superchip = false;
break;
}
}
target.uses_superchip = has_superchip;
}
// check for a Tigervision or Tigervision-esque scheme
if(target.paging_model == Target::PagingModel::None && segment.data.size() > 4096) {
bool looks_like_tigervision = disassembly.external_stores.find(0x3f) != disassembly.external_stores.end();
if(looks_like_tigervision) target.paging_model = Target::PagingModel::Tigervision;
}
}
Analyser::Static::TargetList Analyser::Static::Atari2600::GetTargets(const Media &media, const std::string &file_name, TargetPlatform::IntType potential_platforms) {
// TODO: sanity checking; is this image really for an Atari 2600?
std::unique_ptr<Target> target(new Target);
target->machine = Machine::Atari2600;
target->confidence = 0.5;
target->media.cartridges = media.cartridges;
target->paging_model = Target::PagingModel::None;
target->uses_superchip = false;
// try to figure out the paging scheme
if(!media.cartridges.empty()) {
const auto &segments = media.cartridges.front()->get_segments();
if(segments.size() == 1) {
const Storage::Cartridge::Cartridge::Segment &segment = segments.front();
DeterminePagingForCartridge(*target, segment);
}
}
TargetList destinations;
destinations.push_back(std::move(target));
return destinations;
}