fully meets polkadot specification.
It allows encoding and decoding following data types:
- Built-in integer types specified by size:
uint8_t
,int8_t
uint16_t
,int16_t
uint32_t
,int32_t
uint64_t
,int64_t
- bool values
- pairs of types represented by
std::pair<T1, T2>
- compact integers represented by CompactInteger type
- optional values represented by
boost::optional<T>
- as special case of optional values
boost::optional<bool>
is encoded using one byte following specification.
- as special case of optional values
- collections of items represented by
std::vector<T>
- variants represented by
boost::variant<T...>
class ScaleEncoderStream is in charge of encoding data
ScaleEncoderStream s;
uint32_t ui32 = 123u;
uint8_t ui8 = 234u;
std::string str = "asdasdasd";
auto * raw_str = "zxczxczx";
bool b = true;
CompactInteger ci = 123456789;
boost::variant<uint8_t, uint32_t, CompactInteger> vint = CompactInteger(12345);
boost::optional<std::string> opt_str = "asdfghjkl";
boost::optional<bool> opt_bool = false;
std::pair<uint8_t, uint32_t> pair{1u, 2u};
std::vector<uint32_t> coll_ui32 = {1u, 2u, 3u, 4u};
std::vector<std::string> coll_str = {"asd", "fgh", "jkl"};
std::vector<std::vector<int32_t>> coll_coll_i32 = {{1, 2, 3}, {4, 5, 6, 7}};
try {
s << ui32 << ui8 << str << raw_str << b << ci << vint;
s << opt_str << opt_bool << pair << coll_ui32 << coll_str << coll_coll_i32;
} catch (std::runtime_error &e) {
// handle error
// for example make and return outcome::result
return outcome::failure(e.code());
}
You can now get encoded data:
ByteArray data = s.data();
class ScaleEncoderStream is in charge of encoding data
ByteArray bytes = {...};
ScaleEncoderStream s(bytes);
uint32_t ui32 = 0u;
uint8_t ui8 = 0u;
std::string str;
bool b = true;
CompactInteger ci;
boost::variant<uint8_t, uint32_t, CompactInteger> vint;
boost::optional<std::string> opt_str;
boost::optional<bool> opt_bool;
std::pair<uint8_t, uint32_t> pair{};
std::vector<uint32_t> coll_ui32;
std::vector<std::string> coll_str;
std::vector<std::vector<int32_t>> coll_coll_i32;
try {
s >> ui32 >> ui8 >> str >> b >> ci >> vint;
s >> opt_str >> opt_bool >> pair >> coll_ui32 >> coll_str >> coll_coll_i32;
} catch (std::system_error &e) {
// handle error
}
You may need to encode or decode custom data types, you have to define custom << and >> operators. Please note, that your custom data types must be default-constructible.
struct MyType {
int a = 0;
std::string b;
};
ScaleEncoderStream &operator<<(ScaleEncoderStream &s, const MyType &v) {
return s << v.a << v.b;
}
ScaleDecoderStream &operator>>(ScaleDecoderStream &s, MyType &v) {
return s >> v.a >> v.b;
}
Now you can use them in collections, optionals and variants
std::vector<MyType> v = {{1, "asd"}, {2, "qwe"}};
ScaleEncoderStream s;
try {
s << v;
} catch (...) {
// handle error
}
The same for ScaleDecoderStream
ByteArray data = {...};
std::vector<MyType> v;
ScaleDecoderStream s{data};
try {
s >> v;
} catch (...) {
// handle error
}
Convenience functions
template<class T>
outcome::result<std::vector<uint8_t>> encode(T &&t);
template <class T>
outcome::result<T> decode(gsl::span<const uint8_t> span)
template <class T>
outcome::result<T> decode(ScaleDecoderStream &s)
are wrappers over <<
and >>
operators described above.
Encoding data using encode
convenience function looks as follows:
std::vector<uint32_t> v = {1u, 2u, 3u, 4u};
auto &&result = encode(v);
if (!res) {
// handle error
}
Decoding data using decode
convenience function looks as follows:
ByteArray bytes = {...};
outcome::result<MyType> result = decode<MyType>(bytes);
if (!result) {
// handle error
}
or
ByteArray bytes = {...};
ScaleDecoderStream s(bytes);
outcome::result<MyType> result = decode<MyType>(s);
if (!result) {
// handle error
}