CMake/Source/cm_auto_ptr.hxx

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Simplify CMake per-source license notices Per-source copyright/license notice headers that spell out copyright holder names and years are hard to maintain and often out-of-date or plain wrong. Precise contributor information is already maintained automatically by the version control tool. Ultimately it is the receiver of a file who is responsible for determining its licensing status, and per-source notices are merely a convenience. Therefore it is simpler and more accurate for each source to have a generic notice of the license name and references to more detailed information on copyright holders and full license terms. Our `Copyright.txt` file now contains a list of Contributors whose names appeared source-level copyright notices. It also references version control history for more precise information. Therefore we no longer need to spell out the list of Contributors in each source file notice. Replace CMake per-source copyright/license notice headers with a short description of the license and links to `Copyright.txt` and online information available from "https://cmake.org/licensing". The online URL also handles cases of modules being copied out of our source into other projects, so we can drop our notices about replacing links with full license text. Run the `Utilities/Scripts/filter-notices.bash` script to perform the majority of the replacements mechanically. Manually fix up shebang lines and trailing newlines in a few files. Manually update the notices in a few files that the script does not handle.
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/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
file Copyright.txt or https://cmake.org/licensing for details. */
#ifndef CM_AUTO_PTR_HXX
#define CM_AUTO_PTR_HXX
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#include <cmConfigure.h>
#ifdef CMake_HAVE_CXX_AUTO_PTR
#include <memory>
#define CM_AUTO_PTR std::auto_ptr
#else
#define CM_AUTO_PTR cm::auto_ptr
// The HP compiler cannot handle the conversions necessary to use
// auto_ptr_ref to pass an auto_ptr returned from one function
// directly to another function as in use_auto_ptr(get_auto_ptr()).
// We instead use const_cast to achieve the syntax on those platforms.
// We do not use const_cast on other platforms to maintain the C++
// standard design and guarantee that if an auto_ptr is bound
// to a reference-to-const then ownership will be maintained.
#if defined(__HP_aCC)
#define cm_AUTO_PTR_REF 0
#define cm_AUTO_PTR_CONST const
#define cm_AUTO_PTR_CAST(a) cast(a)
#else
#define cm_AUTO_PTR_REF 1
#define cm_AUTO_PTR_CONST
#define cm_AUTO_PTR_CAST(a) a
#endif
// In C++11, clang will warn about using dynamic exception specifications
// as they are deprecated. But as this class is trying to faithfully
// mimic std::auto_ptr, we want to keep the 'throw()' decorations below.
// So we suppress the warning.
#if defined(__clang__) && defined(__has_warning)
#if __has_warning("-Wdeprecated")
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wdeprecated"
#endif
#endif
namespace cm {
template <class X>
class auto_ptr;
#if cm_AUTO_PTR_REF
namespace detail {
// The auto_ptr_ref template is supposed to be a private member of
// auto_ptr but Borland 5.8 cannot handle it. Instead put it in
// a private namespace.
template <class Y>
struct auto_ptr_ref
{
Y* p_;
// The extra constructor argument prevents implicit conversion to
// auto_ptr_ref from auto_ptr through the constructor. Normally
// this should be done with the explicit keyword but Borland 5.x
// generates code in the conversion operator to call itself
// infinately.
auto_ptr_ref(Y* p, int)
: p_(p)
{
}
};
}
#endif
/** C++98 Standard Section 20.4.5 - Template class auto_ptr. */
template <class X>
class auto_ptr
{
#if !cm_AUTO_PTR_REF
template <typename Y>
static inline auto_ptr<Y>& cast(auto_ptr<Y> const& a)
{
return const_cast<auto_ptr<Y>&>(a);
}
#endif
/** The pointer to the object held. */
X* x_;
public:
/** The type of object held by the auto_ptr. */
typedef X element_type;
/** Construct from an auto_ptr holding a compatible object. This
transfers ownership to the newly constructed auto_ptr. */
template <class Y>
auto_ptr(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw()
: x_(cm_AUTO_PTR_CAST(a).release())
{
}
/** Assign from an auto_ptr holding a compatible object. This
transfers ownership to the left-hand-side of the assignment. */
template <class Y>
auto_ptr& operator=(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw()
{
this->reset(cm_AUTO_PTR_CAST(a).release());
return *this;
}
/**
* Explicitly construct from a raw pointer. This is typically
* called with the result of operator new. For example:
*
* auto_ptr<X> ptr(new X());
*/
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explicit auto_ptr(X* p = CM_NULLPTR) throw()
: x_(p)
{
}
/** Construct from another auto_ptr holding an object of the same
type. This transfers ownership to the newly constructed
auto_ptr. */
auto_ptr(auto_ptr cm_AUTO_PTR_CONST& a) throw()
: x_(cm_AUTO_PTR_CAST(a).release())
{
}
/** Assign from another auto_ptr holding an object of the same type.
This transfers ownership to the newly constructed auto_ptr. */
auto_ptr& operator=(auto_ptr cm_AUTO_PTR_CONST& a) throw()
{
this->reset(cm_AUTO_PTR_CAST(a).release());
return *this;
}
/** Destruct and delete the object held. */
~auto_ptr() throw()
{
// Assume object destructor is nothrow.
delete this->x_;
}
/** Dereference and return a reference to the object held. */
X& operator*() const throw() { return *this->x_; }
/** Return a pointer to the object held. */
X* operator->() const throw() { return this->x_; }
/** Return a pointer to the object held. */
X* get() const throw() { return this->x_; }
/** Return a pointer to the object held and reset to hold no object.
This transfers ownership to the caller. */
X* release() throw()
{
X* x = this->x_;
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this->x_ = CM_NULLPTR;
return x;
}
/** Assume ownership of the given object. The object previously
held is deleted. */
void reset(X* p = 0) throw()
{
if (this->x_ != p) {
// Assume object destructor is nothrow.
delete this->x_;
this->x_ = p;
}
}
/** Convert to an auto_ptr holding an object of a compatible type.
This transfers ownership to the returned auto_ptr. */
template <class Y>
operator auto_ptr<Y>() throw()
{
return auto_ptr<Y>(this->release());
}
#if cm_AUTO_PTR_REF
/** Construct from an auto_ptr_ref. This is used when the
constructor argument is a call to a function returning an
auto_ptr. */
auto_ptr(detail::auto_ptr_ref<X> r) throw()
: x_(r.p_)
{
}
/** Assign from an auto_ptr_ref. This is used when a function
returning an auto_ptr is passed on the right-hand-side of an
assignment. */
auto_ptr& operator=(detail::auto_ptr_ref<X> r) throw()
{
this->reset(r.p_);
return *this;
}
/** Convert to an auto_ptr_ref. This is used when a function
returning an auto_ptr is the argument to the constructor of
another auto_ptr. */
template <class Y>
operator detail::auto_ptr_ref<Y>() throw()
{
return detail::auto_ptr_ref<Y>(this->release(), 1);
}
#endif
};
} // namespace cm
// Undo warning suppression.
#if defined(__clang__) && defined(__has_warning)
#if __has_warning("-Wdeprecated")
#pragma clang diagnostic pop
#endif
#endif
#endif
#endif