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CLK/StaticAnalyser/Disassembler/Disassembler6502.cpp

338 lines
12 KiB
C++

//
// Disassembler6502.cpp
// Clock Signal
//
// Created by Thomas Harte on 10/11/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "Disassembler6502.hpp"
#include <map>
using namespace StaticAnalyser::MOS6502;
struct PartialDisassembly {
Disassembly disassembly;
std::vector<uint16_t> remaining_entry_points;
};
static void AddToDisassembly(PartialDisassembly &disassembly, const std::vector<uint8_t> &memory, const std::function<std::size_t(uint16_t)> &address_mapper, uint16_t entry_point) {
disassembly.disassembly.internal_calls.insert(entry_point);
uint16_t address = entry_point;
while(1) {
std::size_t local_address = address_mapper(address);
if(local_address >= memory.size()) return;
struct Instruction instruction;
instruction.address = address;
address++;
// get operation
uint8_t operation = memory[local_address];
// decode addressing mode
switch(operation&0x1f) {
case 0x00:
if(operation >= 0x80) instruction.addressing_mode = Instruction::Immediate;
else if(operation == 0x20) instruction.addressing_mode = Instruction::Absolute;
else instruction.addressing_mode = Instruction::Implied;
break;
case 0x08: case 0x18: case 0x0a: case 0x1a: case 0x12:
instruction.addressing_mode = Instruction::Implied;
break;
case 0x10:
instruction.addressing_mode = Instruction::Relative;
break;
case 0x01: case 0x03:
instruction.addressing_mode = Instruction::IndexedIndirectX;
break;
case 0x02: case 0x09: case 0x0b:
instruction.addressing_mode = Instruction::Immediate;
break;
case 0x04: case 0x05: case 0x06: case 0x07:
instruction.addressing_mode = Instruction::ZeroPage;
break;
case 0x0c: case 0x0d: case 0x0e: case 0x0f:
instruction.addressing_mode = (operation == 0x6c) ? Instruction::Indirect : Instruction::Absolute;
break;
case 0x11: case 0x13:
instruction.addressing_mode = Instruction::IndirectIndexedY;
break;
case 0x14: case 0x15: case 0x16: case 0x17:
instruction.addressing_mode =
(operation == 0x96 || operation == 0xb6 || operation == 0x97 || operation == 0xb7)
? Instruction::ZeroPageY : Instruction::ZeroPageX;
break;
case 0x19: case 0x1b:
instruction.addressing_mode = Instruction::AbsoluteY;
break;
case 0x1c: case 0x1d: case 0x1e: case 0x1f:
instruction.addressing_mode =
(operation == 0x9e || operation == 0xbe || operation == 0x9f || operation == 0xbf)
? Instruction::AbsoluteY : Instruction::AbsoluteX;
break;
}
// decode operation
#define RM_INSTRUCTION(base, op) \
case base+0x09: case base+0x05: case base+0x15: case base+0x01: case base+0x11: case base+0x0d: case base+0x1d: case base+0x19: \
instruction.operation = op; \
break;
#define URM_INSTRUCTION(base, op) \
case base+0x07: case base+0x17: case base+0x03: case base+0x13: case base+0x0f: case base+0x1f: case base+0x1b: \
instruction.operation = op; \
break;
#define M_INSTRUCTION(base, op) \
case base+0x0a: case base+0x06: case base+0x16: case base+0x0e: case base+0x1e: \
instruction.operation = op; \
break;
#define IM_INSTRUCTION(base, op) \
case base: instruction.operation = op; break;
switch(operation) {
default:
instruction.operation = Instruction::KIL;
break;
IM_INSTRUCTION(0x00, Instruction::BRK)
IM_INSTRUCTION(0x20, Instruction::JSR)
IM_INSTRUCTION(0x40, Instruction::RTI)
IM_INSTRUCTION(0x60, Instruction::RTS)
case 0x4c: case 0x6c:
instruction.operation = Instruction::JMP;
break;
IM_INSTRUCTION(0x10, Instruction::BPL)
IM_INSTRUCTION(0x30, Instruction::BMI)
IM_INSTRUCTION(0x50, Instruction::BVC)
IM_INSTRUCTION(0x70, Instruction::BVS)
IM_INSTRUCTION(0x90, Instruction::BCC)
IM_INSTRUCTION(0xb0, Instruction::BCS)
IM_INSTRUCTION(0xd0, Instruction::BNE)
IM_INSTRUCTION(0xf0, Instruction::BEQ)
IM_INSTRUCTION(0xca, Instruction::DEX)
IM_INSTRUCTION(0x88, Instruction::DEY)
IM_INSTRUCTION(0xe8, Instruction::INX)
IM_INSTRUCTION(0xc8, Instruction::INY)
IM_INSTRUCTION(0xaa, Instruction::TAX)
IM_INSTRUCTION(0x8a, Instruction::TXA)
IM_INSTRUCTION(0xa8, Instruction::TAY)
IM_INSTRUCTION(0x98, Instruction::TYA)
IM_INSTRUCTION(0xba, Instruction::TSX)
IM_INSTRUCTION(0x9a, Instruction::TXS)
IM_INSTRUCTION(0x68, Instruction::PLA)
IM_INSTRUCTION(0x48, Instruction::PHA)
IM_INSTRUCTION(0x28, Instruction::PLP)
IM_INSTRUCTION(0x08, Instruction::PHP)
IM_INSTRUCTION(0x18, Instruction::CLC)
IM_INSTRUCTION(0x38, Instruction::SEC)
IM_INSTRUCTION(0xd8, Instruction::CLD)
IM_INSTRUCTION(0xf8, Instruction::SED)
IM_INSTRUCTION(0x58, Instruction::CLI)
IM_INSTRUCTION(0x78, Instruction::SEI)
IM_INSTRUCTION(0xb8, Instruction::CLV)
URM_INSTRUCTION(0x00, Instruction::SLO)
URM_INSTRUCTION(0x20, Instruction::RLA)
URM_INSTRUCTION(0x40, Instruction::SRE)
URM_INSTRUCTION(0x60, Instruction::RRA)
RM_INSTRUCTION(0x00, Instruction::ORA)
RM_INSTRUCTION(0x20, Instruction::AND)
RM_INSTRUCTION(0x40, Instruction::EOR)
case 0x24: case 0x2c:
instruction.operation = Instruction::BIT;
break;
RM_INSTRUCTION(0x60, Instruction::ADC)
RM_INSTRUCTION(0xc0, Instruction::CMP)
RM_INSTRUCTION(0xe0, Instruction::SBC)
M_INSTRUCTION(0x00, Instruction::ASL)
M_INSTRUCTION(0x20, Instruction::ROL)
M_INSTRUCTION(0x40, Instruction::LSR)
M_INSTRUCTION(0x60, Instruction::ROR)
case 0xe0: case 0xe4: case 0xec: instruction.operation = Instruction::CPX; break;
case 0xc0: case 0xc4: case 0xcc: instruction.operation = Instruction::CPY; break;
case 0xc6: case 0xd6: case 0xce: case 0xde: instruction.operation = Instruction::DEC; break;
case 0xe6: case 0xf6: case 0xee: case 0xfe: instruction.operation = Instruction::INC; break;
RM_INSTRUCTION(0xa0, Instruction::LDA)
case 0x85: case 0x95: case 0x81: case 0x91: case 0x8d: case 0x9d: case 0x99:
instruction.operation = Instruction::STA;
break;
case 0xa2: case 0xa6: case 0xb6: case 0xae: case 0xbe:
instruction.operation = Instruction::LDX;
break;
case 0x86: case 0x96: case 0x8e:
instruction.operation = Instruction::STX;
break;
case 0xa0: case 0xa4: case 0xb4: case 0xac: case 0xbc:
instruction.operation = Instruction::LDY;
break;
case 0x84: case 0x94: case 0x8c:
instruction.operation = Instruction::STY;
break;
case 0x04: case 0x0c: case 0x14: case 0x1a: case 0x1c:
case 0x34: case 0x3a: case 0x3c: case 0x44: case 0x54: case 0x5a: case 0x5c:
case 0x64: case 0x74: case 0x7a: case 0x7c:
case 0x80: case 0x82: case 0x89:
case 0xc2: case 0xd4: case 0xda: case 0xdc:
case 0xe2: case 0xea: case 0xf4: case 0xfa: case 0xfc:
instruction.operation = Instruction::NOP;
break;
case 0x87: case 0x97: case 0x83: case 0x8f:
instruction.operation = Instruction::AXS;
break;
case 0xa7: case 0xb7: case 0xa3: case 0xb3: case 0xaf: case 0xbf:
instruction.operation = Instruction::LAX;
break;
URM_INSTRUCTION(0xc0, Instruction::DCP)
URM_INSTRUCTION(0xe0, Instruction::ISC)
case 0x0b: case 0x2b:
instruction.operation = Instruction::ANC;
break;
IM_INSTRUCTION(0x4b, Instruction::ALR)
IM_INSTRUCTION(0x6b, Instruction::ARR)
IM_INSTRUCTION(0x8b, Instruction::XAA)
IM_INSTRUCTION(0xab, Instruction::LAX)
IM_INSTRUCTION(0xcb, Instruction::SAX)
IM_INSTRUCTION(0xeb, Instruction::SBC)
case 0x93: case 0x9f:
instruction.operation = Instruction::AHX;
break;
IM_INSTRUCTION(0x9c, Instruction::SHY)
IM_INSTRUCTION(0x9e, Instruction::SHX)
IM_INSTRUCTION(0x9b, Instruction::TAS)
IM_INSTRUCTION(0xbb, Instruction::LAS)
}
#undef RM_INSTRUCTION
#undef URM_INSTRUCTION
#undef M_INSTRUCTION
#undef IM_INSTRUCTION
// get operand
switch(instruction.addressing_mode) {
// zero-byte operands
case Instruction::Implied:
instruction.operand = 0;
break;
// one-byte operands
case Instruction::Immediate:
case Instruction::ZeroPage: case Instruction::ZeroPageX: case Instruction::ZeroPageY:
case Instruction::IndexedIndirectX: case Instruction::IndirectIndexedY:
case Instruction::Relative: {
std::size_t operand_address = address_mapper(address);
if(operand_address >= memory.size()) return;
address++;
instruction.operand = memory[operand_address];
}
break;
// two-byte operands
case Instruction::Absolute: case Instruction::AbsoluteX: case Instruction::AbsoluteY:
case Instruction::Indirect: {
std::size_t low_operand_address = address_mapper(address);
std::size_t high_operand_address = address_mapper(address + 1);
if(low_operand_address >= memory.size() || high_operand_address >= memory.size()) return;
address += 2;
instruction.operand = memory[low_operand_address] | static_cast<uint16_t>(memory[high_operand_address] << 8);
}
break;
}
// store the instruction away
disassembly.disassembly.instructions_by_address[instruction.address] = instruction;
// TODO: something wider-ranging than this
if(instruction.addressing_mode == Instruction::Absolute || instruction.addressing_mode == Instruction::ZeroPage) {
std::size_t mapped_address = address_mapper(instruction.operand);
bool is_external = mapped_address >= memory.size();
switch(instruction.operation) {
default: break;
case Instruction::LDY: case Instruction::LDX: case Instruction::LDA:
case Instruction::LAX:
case Instruction::AND: case Instruction::EOR: case Instruction::ORA: case Instruction::BIT:
case Instruction::ADC: case Instruction::SBC:
case Instruction::LAS:
case Instruction::CMP: case Instruction::CPX: case Instruction::CPY:
(is_external ? disassembly.disassembly.external_loads : disassembly.disassembly.internal_loads).insert(instruction.operand);
break;
case Instruction::STY: case Instruction::STX: case Instruction::STA:
case Instruction::AXS: case Instruction::AHX: case Instruction::SHX: case Instruction::SHY:
case Instruction::TAS:
(is_external ? disassembly.disassembly.external_stores : disassembly.disassembly.internal_stores).insert(instruction.operand);
break;
case Instruction::SLO: case Instruction::RLA: case Instruction::SRE: case Instruction::RRA:
case Instruction::DCP: case Instruction::ISC:
case Instruction::INC: case Instruction::DEC:
case Instruction::ASL: case Instruction::ROL: case Instruction::LSR: case Instruction::ROR:
(is_external ? disassembly.disassembly.external_modifies : disassembly.disassembly.internal_modifies).insert(instruction.operand);
break;
}
}
// decide on overall flow control
if(instruction.operation == Instruction::RTS || instruction.operation == Instruction::RTI) return;
if(instruction.operation == Instruction::BRK) return; // TODO: check whether IRQ vector is within memory range
if(instruction.operation == Instruction::JSR) {
disassembly.remaining_entry_points.push_back(instruction.operand);
}
if(instruction.operation == Instruction::JMP) {
if(instruction.addressing_mode == Instruction::Absolute)
disassembly.remaining_entry_points.push_back(instruction.operand);
return;
}
if(instruction.addressing_mode == Instruction::Relative) {
uint16_t destination = static_cast<uint16_t>(address + (int8_t)instruction.operand);
disassembly.remaining_entry_points.push_back(destination);
}
}
}
Disassembly StaticAnalyser::MOS6502::Disassemble(const std::vector<uint8_t> &memory, const std::function<std::size_t(uint16_t)> &address_mapper, std::vector<uint16_t> entry_points) {
PartialDisassembly partialDisassembly;
partialDisassembly.remaining_entry_points = entry_points;
while(!partialDisassembly.remaining_entry_points.empty()) {
// pull the next entry point from the back of the vector
uint16_t next_entry_point = partialDisassembly.remaining_entry_points.back();
partialDisassembly.remaining_entry_points.pop_back();
// if that address has already bene visited, forget about it
if(partialDisassembly.disassembly.instructions_by_address.find(next_entry_point) != partialDisassembly.disassembly.instructions_by_address.end()) continue;
// if it's outgoing, log it as such and forget about it; otherwise disassemble
std::size_t mapped_entry_point = address_mapper(next_entry_point);
if(mapped_entry_point >= memory.size())
partialDisassembly.disassembly.outward_calls.insert(next_entry_point);
else
AddToDisassembly(partialDisassembly, memory, address_mapper, next_entry_point);
}
return std::move(partialDisassembly.disassembly);
}
std::function<std::size_t(uint16_t)> StaticAnalyser::MOS6502::OffsetMapper(uint16_t start_address) {
return [start_address](uint16_t argument) {
return static_cast<std::size_t>(argument - start_address);
};
}