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CLK/InstructionSets/Disassembler.hpp

92 lines
2.6 KiB
C++

//
// Disassembler.hpp
// Clock Signal
//
// Created by Thomas Harte on 26/01/2021.
// Copyright © 2021 Thomas Harte. All rights reserved.
//
#pragma once
#include "../Numeric/Sizes.hpp"
#include <list>
#include <map>
#include <set>
namespace InstructionSet {
template <
/// Indicates the Parser for this platform.
template<typename, bool> class ParserType,
/// Indicates the greatest value the program counter might take.
uint64_t max_address,
/// Provides the type of Instruction to expect.
typename InstructionType,
/// Provides the storage size used for memory.
typename MemoryWord,
/// Provides the addressing range of memory.
typename AddressType
> class Disassembler {
public:
using ProgramCounterType = typename MinIntTypeValue<max_address>::type;
/*!
Adds the result of disassembling @c memory which is @c length @c MemoryWords long from @c start_address
to the current net total of instructions and recorded memory accesses.
*/
void disassemble(
const MemoryWord *const memory,
const ProgramCounterType location,
const ProgramCounterType length,
const ProgramCounterType start_address
) {
// TODO: possibly, move some of this stuff to instruction-set specific disassemblers, analogous to
// the Executor's ownership of the Parser. That would allow handling of stateful parsing.
ParserType<decltype(*this), true> parser;
pending_entry_points_.push_back(start_address);
entry_points_.insert(start_address);
while(!pending_entry_points_.empty()) {
const auto next_entry_point = pending_entry_points_.front();
pending_entry_points_.pop_front();
if(next_entry_point >= location) {
parser.parse(*this, memory - location, next_entry_point & max_address, length + location);
}
}
}
const std::map<ProgramCounterType, InstructionType> &instructions() const {
return instructions_;
}
const std::set<ProgramCounterType> &entry_points() const {
return entry_points_;
}
void announce_overflow(ProgramCounterType) {}
void announce_instruction(const ProgramCounterType address, const InstructionType instruction) {
instructions_[address] = instruction;
}
void add_entry(const ProgramCounterType address) {
if(entry_points_.find(address) == entry_points_.end()) {
pending_entry_points_.push_back(address);
entry_points_.insert(address);
}
}
void add_access(const AddressType address, const AccessType access_type) {
// TODO.
(void)address;
(void)access_type;
}
private:
std::map<ProgramCounterType, InstructionType> instructions_;
std::set<ProgramCounterType> entry_points_;
std::list<ProgramCounterType> pending_entry_points_;
};
}