#include "content/providers/intel_hex_provider.hpp" #include #include #include #include #include #include #include namespace hex::plugin::builtin::prv { namespace intel_hex { u8 parseHexDigit(char c) { if (c >= '0' && c <= '9') return c - '0'; else if (c >= 'A' && c <= 'F') return c - 'A' + 10; else if (c >= 'a' && c <= 'f') return c - 'a' + 10; else throw std::runtime_error("Failed to parse hex digit"); } std::map> parseIntelHex(const std::string &string) { std::map> result; u8 checksum = 0x00; u64 offset = 0x00; u8 byteCount = 0x00; u32 segmentAddress = 0x0000'0000; u32 extendedLinearAddress = 0x0000'0000; u16 address = 0x0000; std::vector data; enum class RecordType { Data = 0x00, EndOfFile = 0x01, ExtendedSegmentAddress = 0x02, StartSegmentAddress = 0x03, ExtendedLinearAddress = 0x04, StartLinearAddress = 0x05 } recordType; auto c = [&]() { while (std::isspace(string[offset]) && offset < string.length()) offset++; if (offset >= string.length()) throw std::runtime_error("Unexpected end of file"); return string[offset++]; }; auto parseValue = [&](u8 byteCount) { u64 value = 0x00; for (u8 i = 0; i < byteCount; i++) { u8 byte = (parseHexDigit(c()) << 4) | parseHexDigit(c()); value <<= 8; value |= byte; checksum += byte; } return value; }; bool endOfFile = false; try { while (offset < string.length()) { // Parse start code if (c() != ':') return { }; checksum = 0x00; if (endOfFile) throw std::runtime_error("Unexpected end of file"); // Parse byte count byteCount = parseValue(1); // Parse address address = parseValue(2); // Parse record type recordType = static_cast(parseValue(1)); data.clear(); for (u32 i = 0; i < byteCount; i++) { data.push_back(parseValue(1)); } parseValue(1); if (!data.empty() && checksum != 0x00) throw std::runtime_error("Checksum mismatch"); while (std::isspace(string[offset]) && offset < string.length()) offset++; // Construct region switch (recordType) { case RecordType::Data: { result[extendedLinearAddress | (segmentAddress + address)] = data; break; } case RecordType::EndOfFile: { endOfFile = true; break; } case RecordType::ExtendedSegmentAddress: { if (byteCount != 2) throw std::runtime_error("Unexpected byte count"); segmentAddress = (data[0] << 8 | data[1]) * 16; break; } case RecordType::StartSegmentAddress: { if (byteCount != 4) throw std::runtime_error("Unexpected byte count"); // Can be safely ignored break; } case RecordType::ExtendedLinearAddress: { if (byteCount != 2) throw std::runtime_error("Unexpected byte count"); extendedLinearAddress = (data[0] << 8 | data[1]) << 16; break; } case RecordType::StartLinearAddress: { if (byteCount != 4) throw std::runtime_error("Unexpected byte count"); // Can be safely ignored break; } } } } catch (const std::runtime_error &e) { return { }; } return result; } } void IntelHexProvider::setBaseAddress(u64 address) { auto oldBase = this->getBaseAddress(); auto intervals = this->m_data.findOverlapping(oldBase, oldBase + this->getActualSize()); for (auto &interval : intervals) { interval.start = (interval.start - oldBase) + address; interval.stop = (interval.stop - oldBase) + address; } this->m_data = std::move(intervals); Provider::setBaseAddress(address); } void IntelHexProvider::readRaw(u64 offset, void *buffer, size_t size) { auto intervals = this->m_data.findOverlapping(offset, (offset + size) - 1); std::memset(buffer, 0x00, size); auto bytes = reinterpret_cast(buffer); for (const auto &interval : intervals) { for (u32 i = std::max(interval.start, offset); i <= interval.stop && (i - offset) < size; i++) { bytes[i - offset] = interval.value[i - interval.start]; } } } void IntelHexProvider::writeRaw(u64 offset, const void *buffer, size_t size) { hex::unused(offset, buffer, size); } size_t IntelHexProvider::getActualSize() const { return this->m_dataSize; } bool IntelHexProvider::open() { auto file = fs::File(this->m_sourceFilePath, fs::File::Mode::Read); if (!file.isValid()) return false; auto data = intel_hex::parseIntelHex(file.readString()); if (data.empty()) return false; u64 maxAddress = 0x00; decltype(this->m_data)::interval_vector intervals; for (auto &[address, bytes] : data) { auto endAddress = (address + bytes.size()) - 1; intervals.emplace_back(address, endAddress, std::move(bytes)); if (endAddress > maxAddress) maxAddress = endAddress; } this->m_data = std::move(intervals); this->m_dataSize = maxAddress + 1; this->m_dataValid = true; return true; } void IntelHexProvider::close() { } [[nodiscard]] std::string IntelHexProvider::getName() const { return hex::format("hex.builtin.provider.intel_hex.name"_lang, this->m_sourceFilePath.filename().string()); } bool IntelHexProvider::handleFilePicker() { auto picked = fs::openFileBrowser(fs::DialogMode::Open, { { "Intel Hex File", "*" } }, [this](const std::fs::path &path) { this->m_sourceFilePath = path; }); if (!picked) return false; if (!fs::isRegularFile(this->m_sourceFilePath)) return false; return true; } std::pair IntelHexProvider::getRegionValidity(u64 address) const { auto intervals = this->m_data.findOverlapping(address, address); if (intervals.empty()) { return Provider::getRegionValidity(address); } auto closestInterval = intervals.front(); for (const auto &interval : intervals) { if (interval.start < closestInterval.start) closestInterval = interval; } return { Region { closestInterval.start, (closestInterval.stop - closestInterval.start) + 1}, true }; } void IntelHexProvider::loadSettings(const nlohmann::json &settings) { Provider::loadSettings(settings); this->m_sourceFilePath = settings["path"].get(); } nlohmann::json IntelHexProvider::storeSettings(nlohmann::json settings) const { settings["path"] = this->m_sourceFilePath.string(); return Provider::storeSettings(settings); } }