#ifndef NALL_SERIALIZER_HPP #define NALL_SERIALIZER_HPP //serializer: a class designed to save and restore the state of classes. // //benefits: //- data() will be portable in size (it is not necessary to specify type sizes.) //- data() will be portable in endianness (always stored internally as little-endian.) //- one serialize function can both save and restore class states. // //caveats: //- only plain-old-data can be stored. complex classes must provide serialize(serializer&); //- floating-point usage is not portable across different implementations #include #include #include namespace nall { struct serializer; template struct has_serialize { template static auto test(decltype(std::declval().serialize(std::declval()))*) -> char; template static auto test(...) -> long; static const bool value = sizeof(test(0)) == sizeof(char); }; struct serializer { enum Mode : uint { Load, Save, Size }; auto mode() const -> Mode { return _mode; } auto data() const -> const uint8* { return _data; } auto size() const -> uint { return _size; } auto capacity() const -> uint { return _capacity; } template auto floatingpoint(T& value) -> serializer& { enum { size = sizeof(T) }; //this is rather dangerous, and not cross-platform safe; //but there is no standardized way to export FP-values auto p = (uint8*)&value; if(_mode == Save) { for(uint n = 0; n < size; n++) _data[_size++] = p[n]; } else if(_mode == Load) { for(uint n = 0; n < size; n++) p[n] = _data[_size++]; } else { _size += size; } return *this; } template auto integer(T& value) -> serializer& { enum { size = std::is_same::value ? 1 : sizeof(T) }; if(_mode == Save) { for(uint n = 0; n < size; n++) _data[_size++] = (uintmax)value >> (n << 3); } else if(_mode == Load) { value = 0; for(uint n = 0; n < size; n++) value |= (uintmax)_data[_size++] << (n << 3); } else if(_mode == Size) { _size += size; } return *this; } template auto array(T (&array)[N]) -> serializer& { for(uint n = 0; n < N; n++) operator()(array[n]); return *this; } template auto array(T array, uint size) -> serializer& { for(uint n = 0; n < size; n++) operator()(array[n]); return *this; } template auto operator()(T& value, typename std::enable_if::value>::type* = 0) -> serializer& { value.serialize(*this); return *this; } template auto operator()(T& value, typename std::enable_if::value>::type* = 0) -> serializer& { return integer(value); } template auto operator()(T& value, typename std::enable_if::value>::type* = 0) -> serializer& { return floatingpoint(value); } template auto operator()(T& value, typename std::enable_if::value>::type* = 0) -> serializer& { return array(value); } template auto operator()(T& value, uint size, typename std::enable_if::value>::type* = 0) -> serializer& { return array(value, size); } auto operator=(const serializer& s) -> serializer& { if(_data) delete[] _data; _mode = s._mode; _data = new uint8[s._capacity]; _size = s._size; _capacity = s._capacity; memcpy(_data, s._data, s._capacity); return *this; } auto operator=(serializer&& s) -> serializer& { if(_data) delete[] _data; _mode = s._mode; _data = s._data; _size = s._size; _capacity = s._capacity; s._data = nullptr; return *this; } serializer() = default; serializer(const serializer& s) { operator=(s); } serializer(serializer&& s) { operator=(move(s)); } serializer(uint capacity) { _mode = Save; _data = new uint8[capacity](); _size = 0; _capacity = capacity; } serializer(const uint8* data, uint capacity) { _mode = Load; _data = new uint8[capacity]; _size = 0; _capacity = capacity; memcpy(_data, data, capacity); } ~serializer() { if(_data) delete[] _data; } private: Mode _mode = Size; uint8* _data = nullptr; uint _size = 0; uint _capacity = 0; }; }; #endif