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llvm / llvm-project / 746e632dafbec2277c62164b3e63da4bee1d8553 / . / compiler-rt / lib / orc / wrapper_function_utils.h
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//===-- wrapper_function_utils.h - Utilities for wrapper funcs --*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file is a part of the ORC runtime support library.
//
//===----------------------------------------------------------------------===//
#ifndef ORC_RT_WRAPPER_FUNCTION_UTILS_H
#define ORC_RT_WRAPPER_FUNCTION_UTILS_H
#include "c_api.h"
#include "common.h"
#include "error.h"
#include "executor_address.h"
#include "simple_packed_serialization.h"
#include <type_traits>
namespace __orc_rt {
/// C++ wrapper function result: Same as CWrapperFunctionResult but
/// auto-releases memory.
class WrapperFunctionResult {
public:
/// Create a default WrapperFunctionResult.
WrapperFunctionResult() { __orc_rt_CWrapperFunctionResultInit(&R); }
/// Create a WrapperFunctionResult from a CWrapperFunctionResult. This
/// instance takes ownership of the result object and will automatically
/// call dispose on the result upon destruction.
WrapperFunctionResult(__orc_rt_CWrapperFunctionResult R) : R(R) {}
WrapperFunctionResult(const WrapperFunctionResult &) = delete;
WrapperFunctionResult &operator=(const WrapperFunctionResult &) = delete;
WrapperFunctionResult(WrapperFunctionResult &&Other) {
__orc_rt_CWrapperFunctionResultInit(&R);
std::swap(R, Other.R);
}
WrapperFunctionResult &operator=(WrapperFunctionResult &&Other) {
__orc_rt_CWrapperFunctionResult Tmp;
__orc_rt_CWrapperFunctionResultInit(&Tmp);
std::swap(Tmp, Other.R);
std::swap(R, Tmp);
return *this;
}
~WrapperFunctionResult() { __orc_rt_DisposeCWrapperFunctionResult(&R); }
/// Relinquish ownership of and return the
/// __orc_rt_CWrapperFunctionResult.
__orc_rt_CWrapperFunctionResult release() {
__orc_rt_CWrapperFunctionResult Tmp;
__orc_rt_CWrapperFunctionResultInit(&Tmp);
std::swap(R, Tmp);
return Tmp;
}
/// Get a pointer to the data contained in this instance.
char *data() { return __orc_rt_CWrapperFunctionResultData(&R); }
/// Returns the size of the data contained in this instance.
size_t size() const { return __orc_rt_CWrapperFunctionResultSize(&R); }
/// Returns true if this value is equivalent to a default-constructed
/// WrapperFunctionResult.
bool empty() const { return __orc_rt_CWrapperFunctionResultEmpty(&R); }
/// Create a WrapperFunctionResult with the given size and return a pointer
/// to the underlying memory.
static WrapperFunctionResult allocate(size_t Size) {
WrapperFunctionResult R;
R.R = __orc_rt_CWrapperFunctionResultAllocate(Size);
return R;
}
/// Copy from the given char range.
static WrapperFunctionResult copyFrom(const char *Source, size_t Size) {
return __orc_rt_CreateCWrapperFunctionResultFromRange(Source, Size);
}
/// Copy from the given null-terminated string (includes the null-terminator).
static WrapperFunctionResult copyFrom(const char *Source) {
return __orc_rt_CreateCWrapperFunctionResultFromString(Source);
}
/// Copy from the given std::string (includes the null terminator).
static WrapperFunctionResult copyFrom(const std::string &Source) {
return copyFrom(Source.c_str());
}
/// Create an out-of-band error by copying the given string.
static WrapperFunctionResult createOutOfBandError(const char *Msg) {
return __orc_rt_CreateCWrapperFunctionResultFromOutOfBandError(Msg);
}
/// Create an out-of-band error by copying the given string.
static WrapperFunctionResult createOutOfBandError(const std::string &Msg) {
return createOutOfBandError(Msg.c_str());
}
template <typename SPSArgListT, typename... ArgTs>
static WrapperFunctionResult fromSPSArgs(const ArgTs &...Args) {
auto Result = allocate(SPSArgListT::size(Args...));
SPSOutputBuffer OB(Result.data(), Result.size());
if (!SPSArgListT::serialize(OB, Args...))
return createOutOfBandError(
"Error serializing arguments to blob in call");
return Result;
}
/// If this value is an out-of-band error then this returns the error message,
/// otherwise returns nullptr.
const char *getOutOfBandError() const {
return __orc_rt_CWrapperFunctionResultGetOutOfBandError(&R);
}
private:
__orc_rt_CWrapperFunctionResult R;
};
namespace detail {
template <typename RetT> class WrapperFunctionHandlerCaller {
public:
template <typename HandlerT, typename ArgTupleT, std::size_t... I>
static decltype(auto) call(HandlerT &&H, ArgTupleT &Args,
std::index_sequence<I...>) {
return std::forward<HandlerT>(H)(std::get<I>(Args)...);
}
};
template <> class WrapperFunctionHandlerCaller<void> {
public:
template <typename HandlerT, typename ArgTupleT, std::size_t... I>
static SPSEmpty call(HandlerT &&H, ArgTupleT &Args,
std::index_sequence<I...>) {
std::forward<HandlerT>(H)(std::get<I>(Args)...);
return SPSEmpty();
}
};
template <typename WrapperFunctionImplT,
template <typename> class ResultSerializer, typename... SPSTagTs>
class WrapperFunctionHandlerHelper
: public WrapperFunctionHandlerHelper<
decltype(&std::remove_reference_t<WrapperFunctionImplT>::operator()),
ResultSerializer, SPSTagTs...> {};
template <typename RetT, typename... ArgTs,
template <typename> class ResultSerializer, typename... SPSTagTs>
class WrapperFunctionHandlerHelper<RetT(ArgTs...), ResultSerializer,
SPSTagTs...> {
public:
using ArgTuple = std::tuple<std::decay_t<ArgTs>...>;
using ArgIndices = std::make_index_sequence<std::tuple_size<ArgTuple>::value>;
template <typename HandlerT>
static WrapperFunctionResult apply(HandlerT &&H, const char *ArgData,
size_t ArgSize) {
ArgTuple Args;
if (!deserialize(ArgData, ArgSize, Args, ArgIndices{}))
return WrapperFunctionResult::createOutOfBandError(
"Could not deserialize arguments for wrapper function call");
auto HandlerResult = WrapperFunctionHandlerCaller<RetT>::call(
std::forward<HandlerT>(H), Args, ArgIndices{});
return ResultSerializer<decltype(HandlerResult)>::serialize(
std::move(HandlerResult));
}
private:
template <std::size_t... I>
static bool deserialize(const char *ArgData, size_t ArgSize, ArgTuple &Args,
std::index_sequence<I...>) {
SPSInputBuffer IB(ArgData, ArgSize);
return SPSArgList<SPSTagTs...>::deserialize(IB, std::get<I>(Args)...);
}
};
// Map function pointers to function types.
template <typename RetT, typename... ArgTs,
template <typename> class ResultSerializer, typename... SPSTagTs>
class WrapperFunctionHandlerHelper<RetT (*)(ArgTs...), ResultSerializer,
SPSTagTs...>
: public WrapperFunctionHandlerHelper<RetT(ArgTs...), ResultSerializer,
SPSTagTs...> {};
// Map non-const member function types to function types.
template <typename ClassT, typename RetT, typename... ArgTs,
template <typename> class ResultSerializer, typename... SPSTagTs>
class WrapperFunctionHandlerHelper<RetT (ClassT::*)(ArgTs...), ResultSerializer,
SPSTagTs...>
: public WrapperFunctionHandlerHelper<RetT(ArgTs...), ResultSerializer,
SPSTagTs...> {};
// Map const member function types to function types.
template <typename ClassT, typename RetT, typename... ArgTs,
template <typename> class ResultSerializer, typename... SPSTagTs>
class WrapperFunctionHandlerHelper<RetT (ClassT::*)(ArgTs...) const,
ResultSerializer, SPSTagTs...>
: public WrapperFunctionHandlerHelper<RetT(ArgTs...), ResultSerializer,
SPSTagTs...> {};
template <typename SPSRetTagT, typename RetT> class ResultSerializer {
public:
static WrapperFunctionResult serialize(RetT Result) {
return WrapperFunctionResult::fromSPSArgs<SPSArgList<SPSRetTagT>>(Result);
}
};
template <typename SPSRetTagT> class ResultSerializer<SPSRetTagT, Error> {
public:
static WrapperFunctionResult serialize(Error Err) {
return WrapperFunctionResult::fromSPSArgs<SPSArgList<SPSRetTagT>>(
toSPSSerializable(std::move(Err)));
}
};
template <typename SPSRetTagT, typename T>
class ResultSerializer<SPSRetTagT, Expected<T>> {
public:
static WrapperFunctionResult serialize(Expected<T> E) {
return WrapperFunctionResult::fromSPSArgs<SPSArgList<SPSRetTagT>>(
toSPSSerializable(std::move(E)));
}
};
template <typename SPSRetTagT, typename RetT> class ResultDeserializer {
public:
static void makeSafe(RetT &Result) {}
static Error deserialize(RetT &Result, const char *ArgData, size_t ArgSize) {
SPSInputBuffer IB(ArgData, ArgSize);
if (!SPSArgList<SPSRetTagT>::deserialize(IB, Result))
return make_error<StringError>(
"Error deserializing return value from blob in call");
return Error::success();
}
};
template <> class ResultDeserializer<SPSError, Error> {
public:
static void makeSafe(Error &Err) { cantFail(std::move(Err)); }
static Error deserialize(Error &Err, const char *ArgData, size_t ArgSize) {
SPSInputBuffer IB(ArgData, ArgSize);
SPSSerializableError BSE;
if (!SPSArgList<SPSError>::deserialize(IB, BSE))
return make_error<StringError>(
"Error deserializing return value from blob in call");
Err = fromSPSSerializable(std::move(BSE));
return Error::success();
}
};
template <typename SPSTagT, typename T>
class ResultDeserializer<SPSExpected<SPSTagT>, Expected<T>> {
public:
static void makeSafe(Expected<T> &E) { cantFail(E.takeError()); }
static Error deserialize(Expected<T> &E, const char *ArgData,
size_t ArgSize) {
SPSInputBuffer IB(ArgData, ArgSize);
SPSSerializableExpected<T> BSE;
if (!SPSArgList<SPSExpected<SPSTagT>>::deserialize(IB, BSE))
return make_error<StringError>(
"Error deserializing return value from blob in call");
E = fromSPSSerializable(std::move(BSE));
return Error::success();
}
};
} // end namespace detail
template <typename SPSSignature> class WrapperFunction;
template <typename SPSRetTagT, typename... SPSTagTs>
class WrapperFunction<SPSRetTagT(SPSTagTs...)> {
private:
template <typename RetT>
using ResultSerializer = detail::ResultSerializer<SPSRetTagT, RetT>;
public:
template <typename RetT, typename... ArgTs>
static Error call(const void *FnTag, RetT &Result, const ArgTs &...Args) {
// RetT might be an Error or Expected value. Set the checked flag now:
// we don't want the user to have to check the unused result if this
// operation fails.
detail::ResultDeserializer<SPSRetTagT, RetT>::makeSafe(Result);
if (ORC_RT_UNLIKELY(!&__orc_rt_jit_dispatch_ctx))
return make_error<StringError>("__orc_rt_jit_dispatch_ctx not set");
if (ORC_RT_UNLIKELY(!&__orc_rt_jit_dispatch))
return make_error<StringError>("__orc_rt_jit_dispatch not set");
auto ArgBuffer =
WrapperFunctionResult::fromSPSArgs<SPSArgList<SPSTagTs...>>(Args...);
if (const char *ErrMsg = ArgBuffer.getOutOfBandError())
return make_error<StringError>(ErrMsg);
WrapperFunctionResult ResultBuffer = __orc_rt_jit_dispatch(
&__orc_rt_jit_dispatch_ctx, FnTag, ArgBuffer.data(), ArgBuffer.size());
if (auto ErrMsg = ResultBuffer.getOutOfBandError())
return make_error<StringError>(ErrMsg);
return detail::ResultDeserializer<SPSRetTagT, RetT>::deserialize(
Result, ResultBuffer.data(), ResultBuffer.size());
}
template <typename HandlerT>
static WrapperFunctionResult handle(const char *ArgData, size_t ArgSize,
HandlerT &&Handler) {
using WFHH =
detail::WrapperFunctionHandlerHelper<std::remove_reference_t<HandlerT>,
ResultSerializer, SPSTagTs...>;
return WFHH::apply(std::forward<HandlerT>(Handler), ArgData, ArgSize);
}
private:
template <typename T> static const T &makeSerializable(const T &Value) {
return Value;
}
static detail::SPSSerializableError makeSerializable(Error Err) {
return detail::toSPSSerializable(std::move(Err));
}
template <typename T>
static detail::SPSSerializableExpected<T> makeSerializable(Expected<T> E) {
return detail::toSPSSerializable(std::move(E));
}
};
template <typename... SPSTagTs>
class WrapperFunction<void(SPSTagTs...)>
: private WrapperFunction<SPSEmpty(SPSTagTs...)> {
public:
template <typename... ArgTs>
static Error call(const void *FnTag, const ArgTs &...Args) {
SPSEmpty BE;
return WrapperFunction<SPSEmpty(SPSTagTs...)>::call(FnTag, BE, Args...);
}
using WrapperFunction<SPSEmpty(SPSTagTs...)>::handle;
};
/// A function object that takes an ExecutorAddr as its first argument,
/// casts that address to a ClassT*, then calls the given method on that
/// pointer passing in the remaining function arguments. This utility
/// removes some of the boilerplate from writing wrappers for method calls.
///
/// @code{.cpp}
/// class MyClass {
/// public:
/// void myMethod(uint32_t, bool) { ... }
/// };
///
/// // SPS Method signature -- note MyClass object address as first argument.
/// using SPSMyMethodWrapperSignature =
/// SPSTuple<SPSExecutorAddr, uint32_t, bool>;
///
/// WrapperFunctionResult
/// myMethodCallWrapper(const char *ArgData, size_t ArgSize) {
/// return WrapperFunction<SPSMyMethodWrapperSignature>::handle(
/// ArgData, ArgSize, makeMethodWrapperHandler(&MyClass::myMethod));
/// }
/// @endcode
///
template <typename RetT, typename ClassT, typename... ArgTs>
class MethodWrapperHandler {
public:
using MethodT = RetT (ClassT::*)(ArgTs...);
MethodWrapperHandler(MethodT M) : M(M) {}
RetT operator()(ExecutorAddr ObjAddr, ArgTs &...Args) {
return (ObjAddr.toPtr<ClassT *>()->*M)(std::forward<ArgTs>(Args)...);
}
private:
MethodT M;
};
/// Create a MethodWrapperHandler object from the given method pointer.
template <typename RetT, typename ClassT, typename... ArgTs>
MethodWrapperHandler<RetT, ClassT, ArgTs...>
makeMethodWrapperHandler(RetT (ClassT::*Method)(ArgTs...)) {
return MethodWrapperHandler<RetT, ClassT, ArgTs...>(Method);
}
/// Represents a call to a wrapper function.
struct WrapperFunctionCall {
ExecutorAddr Func;
ExecutorAddrRange ArgData;
WrapperFunctionCall() = default;
WrapperFunctionCall(ExecutorAddr Func, ExecutorAddrRange ArgData)
: Func(Func), ArgData(ArgData) {}
/// Run and return result as WrapperFunctionResult.
WrapperFunctionResult run() {
WrapperFunctionResult WFR(
Func.toPtr<__orc_rt_CWrapperFunctionResult (*)(const char *, size_t)>()(
ArgData.Start.toPtr<const char *>(),
static_cast<size_t>(ArgData.size().getValue())));
return WFR;
}
/// Run call and deserialize result using SPS.
template <typename SPSRetT, typename RetT> Error runWithSPSRet(RetT &RetVal) {
auto WFR = run();
if (const char *ErrMsg = WFR.getOutOfBandError())
return make_error<StringError>(ErrMsg);
SPSInputBuffer IB(WFR.data(), WFR.size());
if (!SPSSerializationTraits<SPSRetT, RetT>::deserialize(IB, RetVal))
return make_error<StringError>("Could not deserialize result from "
"serialized wrapper function call");
return Error::success();
}
/// Overload for SPS functions returning void.
Error runWithSPSRet() {
SPSEmpty E;
return runWithSPSRet<SPSEmpty>(E);
}
};
class SPSWrapperFunctionCall {};
template <>
class SPSSerializationTraits<SPSWrapperFunctionCall, WrapperFunctionCall> {
public:
static size_t size(const WrapperFunctionCall &WFC) {
return SPSArgList<SPSExecutorAddr, SPSExecutorAddrRange>::size(WFC.Func,
WFC.ArgData);
}
static bool serialize(SPSOutputBuffer &OB, const WrapperFunctionCall &WFC) {
return SPSArgList<SPSExecutorAddr, SPSExecutorAddrRange>::serialize(
OB, WFC.Func, WFC.ArgData);
}
static bool deserialize(SPSInputBuffer &IB, WrapperFunctionCall &WFC) {
return SPSArgList<SPSExecutorAddr, SPSExecutorAddrRange>::deserialize(
IB, WFC.Func, WFC.ArgData);
}
};
} // end namespace __orc_rt
#endif // ORC_RT_WRAPPER_FUNCTION_UTILS_H