gctf2023/pwn/flipper/dist/common/include/ustl/umemory.h

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2023-11-24 18:11:34 +00:00
// This file is part of the uSTL library, an STL implementation.
//
// Copyright (c) 2005 by Mike Sharov <msharov@users.sourceforge.net>
// This file is free software, distributed under the MIT License.
#pragma once
#include "unew.h"
#include "uatomic.h"
#include "uiterator.h"
#include "ulimits.h"
#include "upair.h"
namespace ustl {
//{{{ auto_ptr -------------------------------------------------------
/// \class auto_ptr umemory.h ustl.h
/// \ingroup MemoryManagement
///
/// \brief A smart pointer.
///
/// Calls delete in the destructor; assignment transfers ownership.
/// This class does not work with void pointers due to the absence
/// of the required dereference operator. auto_ptr is deprecated in
/// c++11; use unique_ptr instead.
///
template <typename T>
class auto_ptr {
public:
typedef T value_type;
typedef T* pointer;
typedef T& reference;
public:
/// Takes ownership of \p p.
inline explicit auto_ptr (pointer p = nullptr) : _p (p) {}
/// Takes ownership of pointer in \p p. \p p relinquishes ownership.
inline auto_ptr (auto_ptr<T>& p) : _p (p.release()) {}
/// Deletes the owned pointer.
inline ~auto_ptr (void) { delete _p; }
/// Returns the pointer without relinquishing ownership.
inline pointer get (void) const { return _p; }
/// Returns the pointer and gives up ownership.
inline pointer release (void) { pointer rv (_p); _p = nullptr; return rv; }
/// Deletes the pointer and sets it equal to \p p.
inline void reset (pointer p) { if (p != _p) { delete _p; _p = p; } }
/// Takes ownership of \p p.
inline auto_ptr<T>& operator= (pointer p) { reset (p); return *this; }
/// Takes ownership of pointer in \p p. \p p relinquishes ownership.
inline auto_ptr<T>& operator= (auto_ptr<T>& p) { reset (p.release()); return *this; }
inline reference operator* (void) const { return *_p; }
inline pointer operator-> (void) const { return _p; }
inline bool operator== (const pointer p) const { return _p == p; }
inline bool operator== (const auto_ptr<T>& p) const { return _p == p._p; }
inline bool operator< (const auto_ptr<T>& p) const { return p._p < _p; }
private:
pointer _p;
};
//}}}-------------------------------------------------------------------
//{{{ unique_ptr
#if HAVE_CPP11
/// \class unique_ptr memory.h stl.h
/// \ingroup MemoryManagement
/// \brief A smart pointer.
/// Calls delete in the destructor; assignment transfers ownership.
/// This class does not work with void pointers due to the absence
/// of the required dereference operator.
template <typename T>
class unique_ptr {
public:
using element_type = T;
using pointer = element_type*;
using reference = element_type&;
public:
inline constexpr unique_ptr (void) : _p (nullptr) {}
inline constexpr explicit unique_ptr (pointer p) : _p (p) {}
inline unique_ptr (unique_ptr&& p) : _p (p.release()) {}
unique_ptr (const unique_ptr&) = delete;
inline ~unique_ptr (void) { delete _p; }
inline constexpr pointer get (void) const { return _p; }
inline pointer release (void) { auto rv (_p); _p = nullptr; return rv; }
inline void reset (pointer p = nullptr) { assert (p != _p || !p); auto ov (_p); _p = p; delete ov; }
inline void swap (unique_ptr& v) { ::ustl::swap (_p, v._p); }
inline constexpr explicit operator bool (void) const { return _p != nullptr; }
inline unique_ptr& operator= (pointer p) { reset (p); return *this; }
inline unique_ptr& operator= (unique_ptr&& p) { reset (p.release()); return *this; }
unique_ptr& operator=(const unique_ptr&) = delete;
inline constexpr reference operator* (void) const { return *get(); }
inline constexpr pointer operator-> (void) const { return get(); }
inline constexpr reference operator[] (size_t i) const { return get()[i]; }
inline constexpr bool operator== (const pointer p) const { return _p == p; }
inline constexpr bool operator== (const unique_ptr& p) const { return _p == p._p; }
inline constexpr bool operator< (const unique_ptr& p) const { return _p < p._p; }
private:
pointer _p;
};
// array version
template<typename T>
class unique_ptr<T[]> {
public:
using element_type = T;
using pointer = element_type*;
using reference = element_type&;
public:
inline constexpr unique_ptr (void) : _p (nullptr) {}
inline constexpr explicit unique_ptr (pointer p) : _p (p) {}
inline unique_ptr (unique_ptr&& p) : _p (p.release()) {}
unique_ptr(const unique_ptr&) = delete;
inline ~unique_ptr (void) { delete [] _p; }
inline constexpr pointer get (void) const { return _p; }
inline pointer release (void) { auto rv (_p); _p = nullptr; return rv; }
inline void reset (pointer p) { assert (p != _p); auto ov (_p); _p = p; delete [] ov; }
inline void swap (unique_ptr& v) { ::ustl::swap (_p, v._p); }
inline constexpr explicit operator bool (void) const { return _p != nullptr; }
inline unique_ptr& operator= (pointer p) { reset (p); return *this; }
inline unique_ptr& operator= (unique_ptr&& p) { reset (p.release()); return *this; }
unique_ptr& operator=(const unique_ptr&) = delete;
inline constexpr reference operator* (void) const { return *_p; }
inline constexpr pointer operator-> (void) const { return _p; }
inline constexpr reference operator[] (size_t i) const { return _p[i]; }
inline constexpr bool operator== (const pointer p) const { return _p == p; }
inline constexpr bool operator== (const unique_ptr& p) const { return _p == p._p; }
inline constexpr bool operator< (const unique_ptr& p) const { return _p < p._p; }
private:
pointer _p;
};
#if HAVE_CPP14
template <typename T> struct __make_unique { using __single_object = unique_ptr<T>; };
template <typename T> struct __make_unique<T[]> { using __array = unique_ptr<T[]>; };
template <typename T, size_t N> struct __make_unique<T[N]> { struct __invalid_type {}; };
template <typename T, typename... Args>
inline typename __make_unique<T>::__single_object
make_unique (Args&&... args) { return unique_ptr<T> (new T (forward<Args>(args)...)); }
template <typename T>
inline typename __make_unique<T>::__array
make_unique (size_t n) { return unique_ptr<T> (new remove_extent_t<T>[n]()); }
template <typename T, typename... Args>
inline typename __make_unique<T>::__invalid_type
make_unique (Args&&...) = delete;
#endif // HAVE_CPP14
#endif // HAVE_CPP11
//}}}-------------------------------------------------------------------
//{{{ shared_ptr
#if HAVE_CPP11
/// \class shared_ptr memory.h stl.h
/// \ingroup MemoryManagement
/// \brief A smart pointer.
/// Calls delete in the destructor; assignment shares ownership.
template <typename T>
class shared_ptr {
public:
using element_type = T;
using pointer = element_type*;
using reference = element_type&;
private:
struct container {
pointer p;
atomic<size_t> refs;
inline constexpr explicit container (pointer np) : p(np),refs(1) {}
inline ~container (void) noexcept { assert (!refs); delete p; }
};
public:
inline constexpr shared_ptr (void) : _p (nullptr) {}
inline explicit shared_ptr (pointer p) : _p (new container (p)) {}
inline shared_ptr (shared_ptr&& p) : _p (p._p) { p._p = nullptr; }
inline shared_ptr (const shared_ptr& p): _p (p._p) { if (_p) ++_p->refs; }
inline ~shared_ptr (void) { reset(); }
inline constexpr size_t use_count (void) const { return _p ? _p->refs.load() : 0; }
inline constexpr bool unique (void) const { return use_count() == 1; }
inline constexpr pointer get (void) const { return _p ? _p->p : nullptr; }
void reset (pointer p = nullptr) {
assert (p != get() || !p);
auto ov = _p;
_p = p ? new container(p) : nullptr;
if (ov && !--ov->refs)
delete ov;
}
inline void swap (shared_ptr& v) { ::ustl::swap (_p, v._p); }
inline constexpr explicit operator bool (void) const { return get(); }
inline shared_ptr& operator= (pointer p) { reset (p); return *this; }
inline shared_ptr& operator= (shared_ptr&& p) { swap (p); return *this; }
inline shared_ptr& operator= (const shared_ptr& p) { reset(); _p = p._p; if (_p) ++_p->refs; return *this; }
inline constexpr reference operator* (void) const { return *get(); }
inline constexpr pointer operator-> (void) const { return get(); }
inline constexpr reference operator[] (size_t i) const { return get()[i]; }
inline constexpr bool operator== (const pointer p) const { return get() == p; }
inline constexpr bool operator== (const shared_ptr& p) const { return get() == p.get(); }
inline constexpr bool operator< (const shared_ptr& p) const { return get() < p.get(); }
private:
container* _p;
};
#if HAVE_CPP14
template <typename T, typename... Args>
inline auto make_shared (Args&&... args)
{ return shared_ptr<T> (new T (forward<Args>(args)...)); }
#endif // HAVE_CPP14
//}}}-------------------------------------------------------------------
//{{{ scope_exit
template <typename F>
class scope_exit {
public:
inline explicit scope_exit (F&& f) noexcept : _f(move(f)),_enabled(true) {}
inline scope_exit (scope_exit&& f) noexcept : _f(move(f._f)),_enabled(f._enabled) { f.release(); }
inline void release (void) noexcept { _enabled = false; }
inline ~scope_exit (void) noexcept (noexcept (declval<F>())) { if (_enabled) _f(); }
scope_exit (const scope_exit&) = delete;
scope_exit& operator= (const scope_exit&) = delete;
scope_exit& operator= (scope_exit&&) = delete;
private:
F _f;
bool _enabled;
};
#if HAVE_CPP14
template <typename F>
auto make_scope_exit (F&& f) noexcept
{ return scope_exit<remove_reference_t<F>>(forward<F>(f)); }
#endif // HAVE_CPP14
//}}}-------------------------------------------------------------------
//{{{ unique_resource
template <typename R, typename D>
class unique_resource {
public:
inline explicit unique_resource (R&& resource, D&& deleter, bool enabled = true) noexcept
: _resource(move(resource)), _deleter(move(deleter)),_enabled(enabled) {}
inline unique_resource (unique_resource&& r) noexcept
: _resource(move(r._resource)),_deleter(move(r._deleter)),_enabled(r._enabled) { r.release(); }
unique_resource (const unique_resource&) = delete;
inline ~unique_resource() noexcept(noexcept(declval<unique_resource<R,D>>().reset()))
{ reset(); }
inline const D& get_deleter (void) const noexcept { return _deleter; }
inline R const& get (void) const noexcept { return _resource; }
inline R const& release (void) noexcept { _enabled = false; return get(); }
inline void reset (void) noexcept (noexcept(declval<D>())) {
if (_enabled) {
_enabled = false;
get_deleter()(_resource);
}
}
inline void reset (R&& r) noexcept (noexcept(reset())) {
reset();
_resource = move(r);
_enabled = true;
}
unique_resource& operator= (const unique_resource&) = delete;
unique_resource& operator= (unique_resource &&r) noexcept(noexcept(reset())) {
reset();
_deleter = move(r._deleter);
_resource = move(r._resource);
_enabled = r._enabled;
r.release();
return *this;
}
inline operator R const& (void) const noexcept { return get(); }
inline R operator-> (void) const noexcept { return _resource; }
inline add_lvalue_reference_t<remove_pointer_t<R>>
operator* (void) const { return *_resource; }
private:
R _resource;
D _deleter;
bool _enabled;
};
#if HAVE_CPP14
template <typename R,typename D>
auto make_unique_resource (R&& r, D&& d) noexcept
{ return unique_resource<R,remove_reference_t<D>>(move(r), forward<remove_reference_t<D>>(d), true); }
template <typename R,typename D>
auto make_unique_resource_checked (R r, R invalid, D d) noexcept
{
bool shouldrun = !(r == invalid);
return unique_resource<R,D>(move(r), move(d), shouldrun);
}
#endif // HAVE_CPP14
#endif // HAVE_CPP11
//}}}-------------------------------------------------------------------
//{{{ construct and destroy
/// Calls the placement new on \p p.
/// \ingroup RawStorageAlgorithms
///
template <typename T>
inline void construct_at (T* p)
{ new (p) T; }
/// Calls the placement new on \p p.
/// \ingroup RawStorageAlgorithms
///
template <typename T>
inline void construct_at (T* p, const T& value)
{ new (p) T (value); }
#if HAVE_CPP11
/// Calls the move placement new on \p p.
/// \ingroup RawStorageAlgorithms
///
template <typename T>
inline void construct_at (T* p, T&& value)
{ new (p) T (move<T>(value)); }
#endif
template <typename T>
inline void construct (T* p)
{ construct_at(p); }
/// Calls the placement new on \p p.
/// \ingroup RawStorageAlgorithms
///
template <typename ForwardIterator>
inline void uninitialized_default_construct (ForwardIterator first, ForwardIterator last)
{
typedef typename iterator_traits<ForwardIterator>::value_type value_type;
#if HAVE_CPP11
if (is_pod<value_type>::value)
#else
if (numeric_limits<value_type>::is_integral)
#endif
memset (reinterpret_cast<void*>(first), 0, max(distance(first,last),0)*sizeof(value_type));
else
for (--last; intptr_t(first) <= intptr_t(last); ++first)
construct_at (&*first);
}
template <typename ForwardIterator>
inline void uninitialized_default_construct_n (ForwardIterator first, size_t n)
{ uninitialized_default_construct (first, first+n); }
template <typename ForwardIterator>
inline void construct (ForwardIterator first, ForwardIterator last)
{ uninitialized_default_construct (first, last); }
/// Calls the placement new on \p [first,last) with iterator_traits::value_type()
template <typename ForwardIterator>
inline void uninitialized_value_construct (ForwardIterator first, ForwardIterator last)
{
typedef typename iterator_traits<ForwardIterator>::value_type value_type;
for (--last; intptr_t(first) <= intptr_t(last); ++first)
construct_at (&*first, value_type());
}
template <typename ForwardIterator>
inline void uninitialized_value_construct_n (ForwardIterator first, size_t n)
{ uninitialized_value_construct (first, first+n); }
/// Calls the destructor of \p p without calling delete.
/// \ingroup RawStorageAlgorithms
///
template <typename T>
inline void destroy_at (T* p) noexcept
{ p->~T(); }
template <typename T>
inline void destroy (T* p) noexcept
{ destroy_at(p); }
// Helper templates to not instantiate anything for integral types.
namespace {
template <typename T>
void dtors (T first, T last) noexcept
{ for (--last; intptr_t(first) <= intptr_t(last); ++first) destroy_at (&*first); }
template <typename T, bool bIntegral>
struct Sdtorsr {
inline void operator()(T first, T last) noexcept { dtors (first, last); }
};
template <typename T>
struct Sdtorsr<T,true> {
inline void operator()(T, T) noexcept {}
};
} // namespace
/// Calls the destructor on elements in range [first, last) without calling delete.
/// \ingroup RawStorageAlgorithms
///
template <typename ForwardIterator>
inline void destroy (ForwardIterator first, ForwardIterator last) noexcept
{
typedef typename iterator_traits<ForwardIterator>::value_type value_type;
#if HAVE_CPP11
Sdtorsr<ForwardIterator,is_pod<value_type>::value>()(first, last);
#else
Sdtorsr<ForwardIterator,numeric_limits<value_type>::is_integral>()(first, last);
#endif
}
template <typename ForwardIterator>
inline void destroy_n (ForwardIterator first, size_t n) noexcept
{ destroy (first, first+n); }
//}}}-------------------------------------------------------------------
//{{{ Raw storage algorithms
//}}}-------------------------------------------------------------------
//{{{ Raw storage algorithms
template <typename T> inline T* cast_to_type (void* p, const T*) { return reinterpret_cast<T*>(p); }
/// \brief Creates a temporary buffer pair from \p p and \p n
/// This is intended to be used with alloca to create temporary buffers.
/// The size in the returned pair is set to 0 if the allocation is unsuccessful.
/// \ingroup RawStorageAlgorithms
///
template <typename T>
inline pair<T*, ptrdiff_t> make_temporary_buffer (void* p, size_t n, const T* ptype)
{
return make_pair (cast_to_type(p,ptype), ptrdiff_t(p ? n : 0));
}
#if HAVE_ALLOCA_H
/// \brief Allocates a temporary buffer, if possible.
/// \ingroup RawStorageAlgorithms
#define get_temporary_buffer(size, ptype) make_temporary_buffer (alloca(size_of_elements(size, ptype)), size, ptype)
#define return_temporary_buffer(p)
#else
#define get_temporary_buffer(size, ptype) make_temporary_buffer (malloc(size_of_elements(size, ptype)), size, ptype)
#define return_temporary_buffer(p) if (p) free (p), p = nullptr
#endif
/// Copies [first, last) into result by calling copy constructors in result.
/// \ingroup RawStorageAlgorithms
///
template <typename InputIterator, typename ForwardIterator>
ForwardIterator uninitialized_copy (InputIterator first, InputIterator last, ForwardIterator result)
{
for (; first < last; ++result, ++first)
construct_at (&*result, *first);
return result;
}
/// Copies [first, first + n) into result by calling copy constructors in result.
/// \ingroup RawStorageAlgorithms
///
template <typename InputIterator, typename ForwardIterator>
ForwardIterator uninitialized_copy_n (InputIterator first, size_t n, ForwardIterator result)
{
for (++n; --n; ++result, ++first)
construct_at (&*result, *first);
return result;
}
/// Calls construct on all elements in [first, last) with value \p v.
/// \ingroup RawStorageAlgorithms
///
template <typename ForwardIterator, typename T>
void uninitialized_fill (ForwardIterator first, ForwardIterator last, const T& v)
{
for (; first < last; ++first)
construct_at (&*first, v);
}
/// Calls construct on all elements in [first, first + n) with value \p v.
/// \ingroup RawStorageAlgorithms
///
template <typename ForwardIterator, typename T>
ForwardIterator uninitialized_fill_n (ForwardIterator first, size_t n, const T& v)
{
for (++n; --n; ++first)
construct_at (&*first, v);
return first;
}
#if HAVE_CPP11
/// Moves [first, last) into result by calling move constructors in result.
/// \ingroup RawStorageAlgorithms
///
template <typename InputIterator, typename ForwardIterator>
ForwardIterator uninitialized_move (InputIterator first, InputIterator last, ForwardIterator result)
{
for (; first < last; ++result, ++first)
construct_at (&*result, move(*first));
return result;
}
/// Moves [first, first + n) into result by calling move constructors in result.
/// \ingroup RawStorageAlgorithms
///
template <typename InputIterator, typename ForwardIterator>
ForwardIterator uninitialized_move_n (InputIterator first, size_t n, ForwardIterator result)
{
for (++n; --n; ++result, ++first)
construct_at (&*result, move(*first));
return result;
}
#endif // HAVE_CPP11
} // namespace ustl
//}}}-------------------------------------------------------------------
//{{{ initializer_list
#if HAVE_CPP11 && WITHOUT_LIBSTDCPP
namespace std { // Internal stuff must be in std::
/// Internal class for compiler support of C++11 initializer lists
template <typename T>
class initializer_list {
public:
typedef T value_type;
typedef size_t size_type;
typedef const T& const_reference;
typedef const_reference reference;
typedef const T* const_iterator;
typedef const_iterator iterator;
private:
/// This object is only constructed by the compiler when the {1,2,3}
/// syntax is used, so the constructor must be private
inline constexpr initializer_list (const_iterator p, size_type sz) noexcept : _data(p), _size(sz) {}
public:
inline constexpr initializer_list (void)noexcept : _data(nullptr), _size(0) {}
inline constexpr size_type size (void) const noexcept { return _size; }
inline constexpr const_iterator begin() const noexcept { return _data; }
inline constexpr const_iterator end() const noexcept { return begin()+size(); }
private:
iterator _data;
size_type _size;
};
template <typename T>
inline constexpr const T* begin (initializer_list<T> il) noexcept { return il.begin(); }
template <typename T>
inline constexpr const T* end (initializer_list<T> il) noexcept { return il.end(); }
} // namespace std
#endif // HAVE_CPP11
//}}}-------------------------------------------------------------------