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llvm-mirror/include/llvm/Support/ErrorOr.h
Kevin Enderby 8994e20f69 Reapply r250906 with many suggested updates from Rafael Espindola. 
The needed lld matching changes to be submitted immediately next,
but this revision will cause lld failures with this alone which is expected.

This removes the eating of the error in Archive::Child::getSize() when the characters
in the size field in the archive header for the member is not a number.  To do this we
have all of the needed methods return ErrorOr to push them up until we get out of lib.
Then the tools and can handle the error in whatever way is appropriate for that tool.

So the solution is to plumb all the ErrorOr stuff through everything that touches archives.
This include its iterators as one can create an Archive object but the first or any other
Child object may fail to be created due to a bad size field in its header.

Thanks to Lang Hames on the changes making child_iterator contain an
ErrorOr<Child> instead of a Child and the needed changes to ErrorOr.h to add
operator overloading for * and -> .

We don’t want to use llvm_unreachable() as it calls abort() and is produces a “crash”
and using report_fatal_error() to move the error checking will cause the program to
stop, neither of which are really correct in library code. There are still some uses of
these that should be cleaned up in this library code for other than the size field.

The test cases use archives with text files so one can see the non-digit character,
in this case a ‘%’, in the size field.

These changes will require corresponding changes to the lld project.  That will be
committed immediately after this change.  But this revision will cause lld failures
with this alone which is expected.

llvm-svn: 252192
2015-11-05 19:24:56 +00:00

299 lines
8.2 KiB
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//===- llvm/Support/ErrorOr.h - Error Smart Pointer -------------*- C++ -*-===//
//
// 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;
typedef const typename std::remove_reference<T>::type *const_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());
}
const_pointer operator->() const { return toPointer(getStorage()); }
reference operator *() {
return *getStorage();
}
const_reference operator*() const { 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;
}
const_pointer toPointer(const_pointer Val) const { return Val; }
pointer toPointer(wrap *Val) {
return &Val->get();
}
const_pointer toPointer(const wrap *Val) const { 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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