//===- llvm/ExecutionEngine/Orc/RPCSerialization.h --------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_EXECUTIONENGINE_ORC_RPCSERIALIZATION_H
#define LLVM_EXECUTIONENGINE_ORC_RPCSERIALIZATION_H
#include "OrcError.h"
#include "llvm/Support/thread.h"
#include <map>
#include <mutex>
#include <set>
#include <sstream>
#include <string>
#include <vector>
namespace llvm {
namespace orc {
namespace rpc {
template <typename T>
class RPCTypeName;
/// TypeNameSequence is a utility for rendering sequences of types to a string
/// by rendering each type, separated by ", ".
template <typename... ArgTs> class RPCTypeNameSequence {};
/// Render an empty TypeNameSequence to an ostream.
template <typename OStream>
OStream &operator<<(OStream &OS, const RPCTypeNameSequence<> &V) {
return OS;
}
/// Render a TypeNameSequence of a single type to an ostream.
template <typename OStream, typename ArgT>
OStream &operator<<(OStream &OS, const RPCTypeNameSequence<ArgT> &V) {
OS << RPCTypeName<ArgT>::getName();
return OS;
}
/// Render a TypeNameSequence of more than one type to an ostream.
template <typename OStream, typename ArgT1, typename ArgT2, typename... ArgTs>
OStream&
operator<<(OStream &OS, const RPCTypeNameSequence<ArgT1, ArgT2, ArgTs...> &V) {
OS << RPCTypeName<ArgT1>::getName() << ", "
<< RPCTypeNameSequence<ArgT2, ArgTs...>();
return OS;
}
template <>
class RPCTypeName<void> {
public:
static const char* getName() { return "void"; }
};
template <>
class RPCTypeName<int8_t> {
public:
static const char* getName() { return "int8_t"; }
};
template <>
class RPCTypeName<uint8_t> {
public:
static const char* getName() { return "uint8_t"; }
};
template <>
class RPCTypeName<int16_t> {
public:
static const char* getName() { return "int16_t"; }
};
template <>
class RPCTypeName<uint16_t> {
public:
static const char* getName() { return "uint16_t"; }
};
template <>
class RPCTypeName<int32_t> {
public:
static const char* getName() { return "int32_t"; }
};
template <>
class RPCTypeName<uint32_t> {
public:
static const char* getName() { return "uint32_t"; }
};
template <>
class RPCTypeName<int64_t> {
public:
static const char* getName() { return "int64_t"; }
};
template <>
class RPCTypeName<uint64_t> {
public:
static const char* getName() { return "uint64_t"; }
};
template <>
class RPCTypeName<bool> {
public:
static const char* getName() { return "bool"; }
};
template <>
class RPCTypeName<std::string> {
public:
static const char* getName() { return "std::string"; }
};
template <>
class RPCTypeName<Error> {
public:
static const char* getName() { return "Error"; }
};
template <typename T>
class RPCTypeName<Expected<T>> {
public:
static const char* getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name) << "Expected<"
<< RPCTypeNameSequence<T>()
<< ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename T>
std::mutex RPCTypeName<Expected<T>>::NameMutex;
template <typename T>
std::string RPCTypeName<Expected<T>>::Name;
template <typename T1, typename T2>
class RPCTypeName<std::pair<T1, T2>> {
public:
static const char* getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name) << "std::pair<" << RPCTypeNameSequence<T1, T2>()
<< ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename T1, typename T2>
std::mutex RPCTypeName<std::pair<T1, T2>>::NameMutex;
template <typename T1, typename T2>
std::string RPCTypeName<std::pair<T1, T2>>::Name;
template <typename... ArgTs>
class RPCTypeName<std::tuple<ArgTs...>> {
public:
static const char* getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name) << "std::tuple<"
<< RPCTypeNameSequence<ArgTs...>() << ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename... ArgTs>
std::mutex RPCTypeName<std::tuple<ArgTs...>>::NameMutex;
template <typename... ArgTs>
std::string RPCTypeName<std::tuple<ArgTs...>>::Name;
template <typename T>
class RPCTypeName<std::vector<T>> {
public:
static const char*getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name) << "std::vector<" << RPCTypeName<T>::getName()
<< ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename T>
std::mutex RPCTypeName<std::vector<T>>::NameMutex;
template <typename T>
std::string RPCTypeName<std::vector<T>>::Name;
template <typename T> class RPCTypeName<std::set<T>> {
public:
static const char *getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name)
<< "std::set<" << RPCTypeName<T>::getName() << ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename T> std::mutex RPCTypeName<std::set<T>>::NameMutex;
template <typename T> std::string RPCTypeName<std::set<T>>::Name;
template <typename K, typename V> class RPCTypeName<std::map<K, V>> {
public:
static const char *getName() {
std::lock_guard<std::mutex> Lock(NameMutex);
if (Name.empty())
raw_string_ostream(Name)
<< "std::map<" << RPCTypeNameSequence<K, V>() << ">";
return Name.data();
}
private:
static std::mutex NameMutex;
static std::string Name;
};
template <typename K, typename V>
std::mutex RPCTypeName<std::map<K, V>>::NameMutex;
template <typename K, typename V> std::string RPCTypeName<std::map<K, V>>::Name;
/// The SerializationTraits<ChannelT, T> class describes how to serialize and
/// deserialize an instance of type T to/from an abstract channel of type
/// ChannelT. It also provides a representation of the type's name via the
/// getName method.
///
/// Specializations of this class should provide the following functions:
///
/// @code{.cpp}
///
/// static const char* getName();
/// static Error serialize(ChannelT&, const T&);
/// static Error deserialize(ChannelT&, T&);
///
/// @endcode
///
/// The third argument of SerializationTraits is intended to support SFINAE.
/// E.g.:
///
/// @code{.cpp}
///
/// class MyVirtualChannel { ... };
///
/// template <DerivedChannelT>
/// class SerializationTraits<DerivedChannelT, bool,
/// typename std::enable_if<
/// std::is_base_of<VirtChannel, DerivedChannel>::value
/// >::type> {
/// public:
/// static const char* getName() { ... };
/// }
///
/// @endcode
template <typename ChannelT, typename WireType,
typename ConcreteType = WireType, typename = void>
class SerializationTraits;
template <typename ChannelT>
class SequenceTraits {
public:
static Error emitSeparator(ChannelT &C) { return Error::success(); }
static Error consumeSeparator(ChannelT &C) { return Error::success(); }
};
/// Utility class for serializing sequences of values of varying types.
/// Specializations of this class contain 'serialize' and 'deserialize' methods
/// for the given channel. The ArgTs... list will determine the "over-the-wire"
/// types to be serialized. The serialize and deserialize methods take a list
/// CArgTs... ("caller arg types") which must be the same length as ArgTs...,
/// but may be different types from ArgTs, provided that for each CArgT there
/// is a SerializationTraits specialization
/// SerializeTraits<ChannelT, ArgT, CArgT> with methods that can serialize the
/// caller argument to over-the-wire value.
template <typename ChannelT, typename... ArgTs>
class SequenceSerialization;
template <typename ChannelT>
class SequenceSerialization<ChannelT> {
public:
static Error serialize(ChannelT &C) { return Error::success(); }
static Error deserialize(ChannelT &C) { return Error::success(); }
};
template <typename ChannelT, typename ArgT>
class SequenceSerialization<ChannelT, ArgT> {
public:
template <typename CArgT>
static Error serialize(ChannelT &C, CArgT &&CArg) {
return SerializationTraits<ChannelT, ArgT,
typename std::decay<CArgT>::type>::
serialize(C, std::forward<CArgT>(CArg));
}
template <typename CArgT>
static Error deserialize(ChannelT &C, CArgT &CArg) {
return SerializationTraits<ChannelT, ArgT, CArgT>::deserialize(C, CArg);
}
};
template <typename ChannelT, typename ArgT, typename... ArgTs>
class SequenceSerialization<ChannelT, ArgT, ArgTs...> {
public:
template <typename CArgT, typename... CArgTs>
static Error serialize(ChannelT &C, CArgT &&CArg,
CArgTs &&... CArgs) {
if (auto Err =
SerializationTraits<ChannelT, ArgT, typename std::decay<CArgT>::type>::
serialize(C, std::forward<CArgT>(CArg)))
return Err;
if (auto Err = SequenceTraits<ChannelT>::emitSeparator(C))
return Err;
return SequenceSerialization<ChannelT, ArgTs...>::
serialize(C, std::forward<CArgTs>(CArgs)...);
}
template <typename CArgT, typename... CArgTs>
static Error deserialize(ChannelT &C, CArgT &CArg,
CArgTs &... CArgs) {
if (auto Err =
SerializationTraits<ChannelT, ArgT, CArgT>::deserialize(C, CArg))
return Err;
if (auto Err = SequenceTraits<ChannelT>::consumeSeparator(C))
return Err;
return SequenceSerialization<ChannelT, ArgTs...>::deserialize(C, CArgs...);
}
};
template <typename ChannelT, typename... ArgTs>
Error serializeSeq(ChannelT &C, ArgTs &&... Args) {
return SequenceSerialization<ChannelT, typename std::decay<ArgTs>::type...>::
serialize(C, std::forward<ArgTs>(Args)...);
}
template <typename ChannelT, typename... ArgTs>
Error deserializeSeq(ChannelT &C, ArgTs &... Args) {
return SequenceSerialization<ChannelT, ArgTs...>::deserialize(C, Args...);
}
template <typename ChannelT>
class SerializationTraits<ChannelT, Error> {
public:
using WrappedErrorSerializer =
std::function<Error(ChannelT &C, const ErrorInfoBase&)>;
using WrappedErrorDeserializer =
std::function<Error(ChannelT &C, Error &Err)>;
template <typename ErrorInfoT, typename SerializeFtor,
typename DeserializeFtor>
static void registerErrorType(std::string Name, SerializeFtor Serialize,
DeserializeFtor Deserialize) {
assert(!Name.empty() &&
"The empty string is reserved for the Success value");
const std::string *KeyName = nullptr;
{
// We're abusing the stability of std::map here: We take a reference to the
// key of the deserializers map to save us from duplicating the string in
// the serializer. This should be changed to use a stringpool if we switch
// to a map type that may move keys in memory.
std::lock_guard<std::recursive_mutex> Lock(DeserializersMutex);
auto I =
Deserializers.insert(Deserializers.begin(),
std::make_pair(std::move(Name),
std::move(Deserialize)));
KeyName = &I->first;
}
{
assert(KeyName != nullptr && "No keyname pointer");
std::lock_guard<std::recursive_mutex> Lock(SerializersMutex);
// FIXME: Move capture Serialize once we have C++14.
Serializers[ErrorInfoT::classID()] =
[KeyName, Serialize](ChannelT &C, const ErrorInfoBase &EIB) -> Error {
assert(EIB.dynamicClassID() == ErrorInfoT::classID() &&
"Serializer called for wrong error type");
if (auto Err = serializeSeq(C, *KeyName))
return Err;
return Serialize(C, static_cast<const ErrorInfoT &>(EIB));
};
}
}
static Error serialize(ChannelT &C, Error &&Err) {
std::lock_guard<std::recursive_mutex> Lock(SerializersMutex);
if (!Err)
return serializeSeq(C, std::string());
return handleErrors(std::move(Err),
[&C](const ErrorInfoBase &EIB) {
auto SI = Serializers.find(EIB.dynamicClassID());
if (SI == Serializers.end())
return serializeAsStringError(C, EIB);
return (SI->second)(C, EIB);
});
}
static Error deserialize(ChannelT &C, Error &Err) {
std::lock_guard<std::recursive_mutex> Lock(DeserializersMutex);
std::string Key;
if (auto Err = deserializeSeq(C, Key))
return Err;
if (Key.empty()) {
ErrorAsOutParameter EAO(&Err);
Err = Error::success();
return Error::success();
}
auto DI = Deserializers.find(Key);
assert(DI != Deserializers.end() && "No deserializer for error type");
return (DI->second)(C, Err);
}
private:
static Error serializeAsStringError(ChannelT &C, const ErrorInfoBase &EIB) {
std::string ErrMsg;
{
raw_string_ostream ErrMsgStream(ErrMsg);
EIB.log(ErrMsgStream);
}
return serialize(C, make_error<StringError>(std::move(ErrMsg),
inconvertibleErrorCode()));
}
static std::recursive_mutex SerializersMutex;
static std::recursive_mutex DeserializersMutex;
static std::map<const void*, WrappedErrorSerializer> Serializers;
static std::map<std::string, WrappedErrorDeserializer> Deserializers;
};
template <typename ChannelT>
std::recursive_mutex SerializationTraits<ChannelT, Error>::SerializersMutex;
template <typename ChannelT>
std::recursive_mutex SerializationTraits<ChannelT, Error>::DeserializersMutex;
template <typename ChannelT>
std::map<const void*,
typename SerializationTraits<ChannelT, Error>::WrappedErrorSerializer>
SerializationTraits<ChannelT, Error>::Serializers;
template <typename ChannelT>
std::map<std::string,
typename SerializationTraits<ChannelT, Error>::WrappedErrorDeserializer>
SerializationTraits<ChannelT, Error>::Deserializers;
/// Registers a serializer and deserializer for the given error type on the
/// given channel type.
template <typename ChannelT, typename ErrorInfoT, typename SerializeFtor,
typename DeserializeFtor>
void registerErrorSerialization(std::string Name, SerializeFtor &&Serialize,
DeserializeFtor &&Deserialize) {
SerializationTraits<ChannelT, Error>::template registerErrorType<ErrorInfoT>(
std::move(Name),
std::forward<SerializeFtor>(Serialize),
std::forward<DeserializeFtor>(Deserialize));
}
/// Registers serialization/deserialization for StringError.
template <typename ChannelT>
void registerStringError() {
static bool AlreadyRegistered = false;
if (!AlreadyRegistered) {
registerErrorSerialization<ChannelT, StringError>(
"StringError",
[](ChannelT &C, const StringError &SE) {
return serializeSeq(C, SE.getMessage());
},
[](ChannelT &C, Error &Err) -> Error {
ErrorAsOutParameter EAO(&Err);
std::string Msg;
if (auto E2 = deserializeSeq(C, Msg))
return E2;
Err =
make_error<StringError>(std::move(Msg),
orcError(
OrcErrorCode::UnknownErrorCodeFromRemote));
return Error::success();
});
AlreadyRegistered = true;
}
}
/// SerializationTraits for Expected<T1> from an Expected<T2>.
template <typename ChannelT, typename T1, typename T2>
class SerializationTraits<ChannelT, Expected<T1>, Expected<T2>> {
public:
static Error serialize(ChannelT &C, Expected<T2> &&ValOrErr) {
if (ValOrErr) {
if (auto Err = serializeSeq(C, true))
return Err;
return SerializationTraits<ChannelT, T1, T2>::serialize(C, *ValOrErr);
}
if (auto Err = serializeSeq(C, false))
return Err;
return serializeSeq(C, ValOrErr.takeError());
}
static Error deserialize(ChannelT &C, Expected<T2> &ValOrErr) {
ExpectedAsOutParameter<T2> EAO(&ValOrErr);
bool HasValue;
if (auto Err = deserializeSeq(C, HasValue))
return Err;
if (HasValue)
return SerializationTraits<ChannelT, T1, T2>::deserialize(C, *ValOrErr);
Error Err = Error::success();
if (auto E2 = deserializeSeq(C, Err))
return E2;
ValOrErr = std::move(Err);
return Error::success();
}
};
/// SerializationTraits for Expected<T1> from a T2.
template <typename ChannelT, typename T1, typename T2>
class SerializationTraits<ChannelT, Expected<T1>, T2> {
public:
static Error serialize(ChannelT &C, T2 &&Val) {
return serializeSeq(C, Expected<T2>(std::forward<T2>(Val)));
}
};
/// SerializationTraits for Expected<T1> from an Error.
template <typename ChannelT, typename T>
class SerializationTraits<ChannelT, Expected<T>, Error> {
public:
static Error serialize(ChannelT &C, Error &&Err) {
return serializeSeq(C, Expected<T>(std::move(Err)));
}
};
/// SerializationTraits default specialization for std::pair.
template <typename ChannelT, typename T1, typename T2, typename T3, typename T4>
class SerializationTraits<ChannelT, std::pair<T1, T2>, std::pair<T3, T4>> {
public:
static Error serialize(ChannelT &C, const std::pair<T3, T4> &V) {
if (auto Err = SerializationTraits<ChannelT, T1, T3>::serialize(C, V.first))
return Err;
return SerializationTraits<ChannelT, T2, T4>::serialize(C, V.second);
}
static Error deserialize(ChannelT &C, std::pair<T3, T4> &V) {
if (auto Err =
SerializationTraits<ChannelT, T1, T3>::deserialize(C, V.first))
return Err;
return SerializationTraits<ChannelT, T2, T4>::deserialize(C, V.second);
}
};
/// SerializationTraits default specialization for std::tuple.
template <typename ChannelT, typename... ArgTs>
class SerializationTraits<ChannelT, std::tuple<ArgTs...>> {
public:
/// RPC channel serialization for std::tuple.
static Error serialize(ChannelT &C, const std::tuple<ArgTs...> &V) {
return serializeTupleHelper(C, V, llvm::index_sequence_for<ArgTs...>());
}
/// RPC channel deserialization for std::tuple.
static Error deserialize(ChannelT &C, std::tuple<ArgTs...> &V) {
return deserializeTupleHelper(C, V, llvm::index_sequence_for<ArgTs...>());
}
private:
// Serialization helper for std::tuple.
template <size_t... Is>
static Error serializeTupleHelper(ChannelT &C, const std::tuple<ArgTs...> &V,
llvm::index_sequence<Is...> _) {
return serializeSeq(C, std::get<Is>(V)...);
}
// Serialization helper for std::tuple.
template <size_t... Is>
static Error deserializeTupleHelper(ChannelT &C, std::tuple<ArgTs...> &V,
llvm::index_sequence<Is...> _) {
return deserializeSeq(C, std::get<Is>(V)...);
}
};
/// SerializationTraits default specialization for std::vector.
template <typename ChannelT, typename T>
class SerializationTraits<ChannelT, std::vector<T>> {
public:
/// Serialize a std::vector<T> from std::vector<T>.
static Error serialize(ChannelT &C, const std::vector<T> &V) {
if (auto Err = serializeSeq(C, static_cast<uint64_t>(V.size())))
return Err;
for (const auto &E : V)
if (auto Err = serializeSeq(C, E))
return Err;
return Error::success();
}
/// Deserialize a std::vector<T> to a std::vector<T>.
static Error deserialize(ChannelT &C, std::vector<T> &V) {
assert(V.empty() &&
"Expected default-constructed vector to deserialize into");
uint64_t Count = 0;
if (auto Err = deserializeSeq(C, Count))
return Err;
V.resize(Count);
for (auto &E : V)
if (auto Err = deserializeSeq(C, E))
return Err;
return Error::success();
}
};
template <typename ChannelT, typename T, typename T2>
class SerializationTraits<ChannelT, std::set<T>, std::set<T2>> {
public:
/// Serialize a std::set<T> from std::set<T2>.
static Error serialize(ChannelT &C, const std::set<T2> &S) {
if (auto Err = serializeSeq(C, static_cast<uint64_t>(S.size())))
return Err;
for (const auto &E : S)
if (auto Err = SerializationTraits<ChannelT, T, T2>::serialize(C, E))
return Err;
return Error::success();
}
/// Deserialize a std::set<T> to a std::set<T>.
static Error deserialize(ChannelT &C, std::set<T2> &S) {
assert(S.empty() && "Expected default-constructed set to deserialize into");
uint64_t Count = 0;
if (auto Err = deserializeSeq(C, Count))
return Err;
while (Count-- != 0) {
T2 Val;
if (auto Err = SerializationTraits<ChannelT, T, T2>::deserialize(C, Val))
return Err;
auto Added = S.insert(Val).second;
if (!Added)
return make_error<StringError>("Duplicate element in deserialized set",
orcError(OrcErrorCode::UnknownORCError));
}
return Error::success();
}
};
template <typename ChannelT, typename K, typename V, typename K2, typename V2>
class SerializationTraits<ChannelT, std::map<K, V>, std::map<K2, V2>> {
public:
/// Serialize a std::map<K, V> from std::map<K2, V2>.
static Error serialize(ChannelT &C, const std::map<K2, V2> &M) {
if (auto Err = serializeSeq(C, static_cast<uint64_t>(M.size())))
return Err;
for (const auto &E : M) {
if (auto Err =
SerializationTraits<ChannelT, K, K2>::serialize(C, E.first))
return Err;
if (auto Err =
SerializationTraits<ChannelT, V, V2>::serialize(C, E.second))
return Err;
}
return Error::success();
}
/// Deserialize a std::map<K, V> to a std::map<K, V>.
static Error deserialize(ChannelT &C, std::map<K2, V2> &M) {
assert(M.empty() && "Expected default-constructed map to deserialize into");
uint64_t Count = 0;
if (auto Err = deserializeSeq(C, Count))
return Err;
while (Count-- != 0) {
std::pair<K2, V2> Val;
if (auto Err =
SerializationTraits<ChannelT, K, K2>::deserialize(C, Val.first))
return Err;
if (auto Err =
SerializationTraits<ChannelT, V, V2>::deserialize(C, Val.second))
return Err;
auto Added = M.insert(Val).second;
if (!Added)
return make_error<StringError>("Duplicate element in deserialized map",
orcError(OrcErrorCode::UnknownORCError));
}
return Error::success();
}
};
} // end namespace rpc
} // end namespace orc
} // end namespace llvm
#endif // LLVM_EXECUTIONENGINE_ORC_RPCSERIALIZATION_H