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//===- llvm/Support/ErrorOr.h - Error Smart Pointer -----------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file
///
/// Provides ErrorOr<T> smart pointer.
///
//===----------------------------------------------------------------------===//
#ifndef LLVM_SUPPORT_ERROROR_H
#define LLVM_SUPPORT_ERROROR_H
#include "llvm/ADT/PointerIntPair.h"
#include "llvm/Support/AlignOf.h"
#include <cassert>
#include <system_error>
#include <type_traits>
namespace llvm {
template<class T, class V>
typename std::enable_if< std::is_constructible<T, V>::value
, typename std::remove_reference<V>::type>::type &&
moveIfMoveConstructible(V &Val) {
return std::move(Val);
}
template<class T, class V>
typename std::enable_if< !std::is_constructible<T, V>::value
, typename std::remove_reference<V>::type>::type &
moveIfMoveConstructible(V &Val) {
return Val;
}
/// \brief Stores a reference that can be changed.
template <typename T>
class ReferenceStorage {
T *Storage;
public:
ReferenceStorage(T &Ref) : Storage(&Ref) {}
operator T &() const { return *Storage; }
T &get() const { return *Storage; }
};
/// \brief Represents either an error or a value T.
///
/// ErrorOr<T> is a pointer-like class that represents the result of an
/// operation. The result is either an error, or a value of type T. This is
/// designed to emulate the usage of returning a pointer where nullptr indicates
/// failure. However instead of just knowing that the operation failed, we also
/// have an error_code and optional user data that describes why it failed.
///
/// It is used like the following.
/// \code
/// ErrorOr<Buffer> getBuffer();
///
/// auto buffer = getBuffer();
/// if (error_code ec = buffer.getError())
/// return ec;
/// buffer->write("adena");
/// \endcode
///
///
/// Implicit conversion to bool returns true if there is a usable value. The
/// unary * and -> operators provide pointer like access to the value. Accessing
/// the value when there is an error has undefined behavior.
///
/// When T is a reference type the behaivor is slightly different. The reference
/// is held in a std::reference_wrapper<std::remove_reference<T>::type>, and
/// there is special handling to make operator -> work as if T was not a
/// reference.
///
/// T cannot be a rvalue reference.
template<class T>
class ErrorOr {
template <class OtherT> friend class ErrorOr;
static const bool isRef = std::is_reference<T>::value;
typedef ReferenceStorage<typename std::remove_reference<T>::type> wrap;
public:
typedef typename std::conditional<isRef, wrap, T>::type storage_type;
private:
typedef typename std::remove_reference<T>::type &reference;
typedef const typename std::remove_reference<T>::type &const_reference;
typedef typename std::remove_reference<T>::type *pointer;
public:
template <class E>
ErrorOr(E ErrorCode,
typename std::enable_if<std::is_error_code_enum<E>::value ||
std::is_error_condition_enum<E>::value,
void *>::type = 0)
: HasError(true) {
new (getErrorStorage()) std::error_code(make_error_code(ErrorCode));
}
ErrorOr(std::error_code EC) : HasError(true) {
new (getErrorStorage()) std::error_code(EC);
}
ErrorOr(T Val) : HasError(false) {
new (getStorage()) storage_type(moveIfMoveConstructible<storage_type>(Val));
}
ErrorOr(const ErrorOr &Other) {
copyConstruct(Other);
}
template <class OtherT>
ErrorOr(
const ErrorOr<OtherT> &Other,
typename std::enable_if<std::is_convertible<OtherT, T>::value>::type * =
nullptr) {
copyConstruct(Other);
}
template <class OtherT>
explicit ErrorOr(
const ErrorOr<OtherT> &Other,
typename std::enable_if<
!std::is_convertible<OtherT, const T &>::value>::type * = nullptr) {
copyConstruct(Other);
}
ErrorOr(ErrorOr &&Other) {
moveConstruct(std::move(Other));
}
template <class OtherT>
ErrorOr(
ErrorOr<OtherT> &&Other,
typename std::enable_if<std::is_convertible<OtherT, T>::value>::type * =
nullptr) {
moveConstruct(std::move(Other));
}
// This might eventually need SFINAE but it's more complex than is_convertible
// & I'm too lazy to write it right now.
template <class OtherT>
explicit ErrorOr(
ErrorOr<OtherT> &&Other,
typename std::enable_if<!std::is_convertible<OtherT, T>::value>::type * =
nullptr) {
moveConstruct(std::move(Other));
}
ErrorOr &operator=(const ErrorOr &Other) {
copyAssign(Other);
return *this;
}
ErrorOr &operator=(ErrorOr &&Other) {
moveAssign(std::move(Other));
return *this;
}
~ErrorOr() {
if (!HasError)
getStorage()->~storage_type();
}
/// \brief Return false if there is an error.
explicit operator bool() const {
return !HasError;
}
reference get() { return *getStorage(); }
const_reference get() const { return const_cast<ErrorOr<T> *>(this)->get(); }
std::error_code getError() const {
return HasError ? *getErrorStorage() : std::error_code();
}
pointer operator ->() {
return toPointer(getStorage());
}
reference operator *() {
return *getStorage();
}
private:
template <class OtherT>
void copyConstruct(const ErrorOr<OtherT> &Other) {
if (!Other.HasError) {
// Get the other value.
HasError = false;
new (getStorage()) storage_type(*Other.getStorage());
} else {
// Get other's error.
HasError = true;
new (getErrorStorage()) std::error_code(Other.getError());
}
}
template <class T1>
static bool compareThisIfSameType(const T1 &a, const T1 &b) {
return &a == &b;
}
template <class T1, class T2>
static bool compareThisIfSameType(const T1 &a, const T2 &b) {
return false;
}
template <class OtherT>
void copyAssign(const ErrorOr<OtherT> &Other) {
if (compareThisIfSameType(*this, Other))
return;
this->~ErrorOr();
new (this) ErrorOr(Other);
}
template <class OtherT>
void moveConstruct(ErrorOr<OtherT> &&Other) {
if (!Other.HasError) {
// Get the other value.
HasError = false;
new (getStorage()) storage_type(std::move(*Other.getStorage()));
} else {
// Get other's error.
HasError = true;
new (getErrorStorage()) std::error_code(Other.getError());
}
}
template <class OtherT>
void moveAssign(ErrorOr<OtherT> &&Other) {
if (compareThisIfSameType(*this, Other))
return;
this->~ErrorOr();
new (this) ErrorOr(std::move(Other));
}
pointer toPointer(pointer Val) {
return Val;
}
pointer toPointer(wrap *Val) {
return &Val->get();
}
storage_type *getStorage() {
assert(!HasError && "Cannot get value when an error exists!");
return reinterpret_cast<storage_type*>(TStorage.buffer);
}
const storage_type *getStorage() const {
assert(!HasError && "Cannot get value when an error exists!");
return reinterpret_cast<const storage_type*>(TStorage.buffer);
}
std::error_code *getErrorStorage() {
assert(HasError && "Cannot get error when a value exists!");
return reinterpret_cast<std::error_code *>(ErrorStorage.buffer);
}
const std::error_code *getErrorStorage() const {
return const_cast<ErrorOr<T> *>(this)->getErrorStorage();
}
union {
AlignedCharArrayUnion<storage_type> TStorage;
AlignedCharArrayUnion<std::error_code> ErrorStorage;
};
bool HasError : 1;
};
template <class T, class E>
typename std::enable_if<std::is_error_code_enum<E>::value ||
std::is_error_condition_enum<E>::value,
bool>::type
operator==(const ErrorOr<T> &Err, E Code) {
return Err.getError() == Code;
}
} // end namespace llvm
#endif
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