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paddlepaddle--paddle/paddle/utils/optional.h
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2026-07-13 12:40:42 +08:00

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// This file copy from boost/optional/optional.hpp and boost version: 1.41.0
// Modified the following points:
// 1. modify namespace from boost::optional to paddle::optional
// 2. remove the depending boost header files
// 3. remove/modify some macro
// 4. copy some necessary data structures which are the depended by optional
// 5. replace type_with_alignment with std::aligned_storage
// Copyright (C) 2003, Fernando Luis Cacciola Carballal.
//
// Use, modification, and distribution is subject to the Boost Software
// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
// http://www.boost.org/LICENSE_1_0.txt)
//
// See http://www.boost.org/lib/optional for documentation.
//
// You are welcome to contact the author at:
// fernando_cacciola@hotmail.com
//
#pragma once
#include <algorithm>
#include <cassert>
#include <functional>
#include <new>
#include <type_traits>
#include "paddle/utils/none.h"
namespace paddle {
// Daniel Wallin discovered that bind/apply.hpp badly interacts with the apply<>
// member template of a factory as used in the optional<> implementation.
// He proposed this simple fix which is to move the call to apply<> outside
// namespace boost.
namespace paddle_optional_detail {
template <class T, class Factory>
void construct(Factory const& factory, void* address) {
factory.template apply<T>(address);
}
} // namespace paddle_optional_detail
template <typename T>
class optional;
class in_place_factory_base {};
class typed_in_place_factory_base {};
// template<class OP> bool equal_pointees(OP const& x, OP const& y);
// template<class OP> struct equal_pointees_t;
//
// Being OP a model of OptionalPointee (either a pointer or an optional):
//
// If both x and y have valid pointees, returns the result of (*x == *y)
// If only one has a valid pointee, returns false.
// If none have valid pointees, returns true.
// No-throw
template <class OptionalPointee>
inline bool equal_pointees(OptionalPointee const& x, OptionalPointee const& y) {
return (!x) != (!y) ? false : (!x ? true : (*x) == (*y));
}
template <class OptionalPointee>
struct equal_pointees_t {
using first_argument_type = OptionalPointee;
using second_argument_type = OptionalPointee;
using result_type = bool;
bool operator()(OptionalPointee const& x, OptionalPointee const& y) const {
return equal_pointees(x, y);
}
};
// template<class OP> bool less_pointees(OP const& x, OP const& y);
// template<class OP> struct less_pointees_t;
//
// Being OP a model of OptionalPointee (either a pointer or an optional):
//
// If y has not a valid pointee, returns false.
// ElseIf x has not a valid pointee, returns true.
// ElseIf both x and y have valid pointees, returns the result of (*x < *y)
// No-throw
template <class OptionalPointee>
inline bool less_pointees(OptionalPointee const& x, OptionalPointee const& y) {
return !y ? false : (!x ? true : (*x) < (*y));
}
template <class OptionalPointee>
struct less_pointees_t {
using first_argument_type = OptionalPointee;
using second_argument_type = OptionalPointee;
using result_type = bool;
bool operator()(OptionalPointee const& x, OptionalPointee const& y) const {
return less_pointees(x, y);
}
};
namespace detail {
template <typename RefT>
class reference_content {
private: // representation
RefT content_;
public: // structors
~reference_content() {}
reference_content(RefT r) : content_(r) {} // NOLINT
reference_content(const reference_content& operand)
: content_(operand.content_) {}
private: // non-Assignable
reference_content& operator=(const reference_content&);
public: // queries
RefT get() const { return content_; }
};
template <typename T>
struct make_reference_content {
typedef T type;
};
template <typename T>
struct make_reference_content<T&> {
typedef reference_content<T&> type;
};
} // namespace detail
namespace optional_detail {
// This local class is used instead of that in "aligned_storage.hpp"
// because I've found the 'official' class to ICE BCB5.5
// when some types are used with optional<>
// (due to sizeof() passed down as a non-type template parameter)
template <class T>
class aligned_storage {
// Borland ICEs if unnamed unions are used for this!
union dummy_u {
char data[sizeof(T)];
typename std::aligned_storage<::std::alignment_of<T>::value>::type aligner_;
} dummy_;
public:
void const* address() const { return &dummy_.data[0]; }
void* address() { return &dummy_.data[0]; }
};
template <class T>
struct types_when_isnt_ref {
typedef T const& reference_const_type;
typedef T& reference_type;
typedef T const* pointer_const_type;
typedef T* pointer_type;
typedef T const& argument_type;
};
template <class T>
struct types_when_is_ref {
typedef typename std::remove_reference<T>::type raw_type;
typedef raw_type& reference_const_type;
typedef raw_type& reference_type;
typedef raw_type* pointer_const_type;
typedef raw_type* pointer_type;
typedef raw_type& argument_type;
};
struct optional_tag {};
template <class T>
class optional_base : public optional_tag {
private:
typedef
typename ::paddle::detail::make_reference_content<T>::type internal_type;
typedef aligned_storage<internal_type> storage_type;
typedef types_when_isnt_ref<T> types_when_not_ref;
typedef types_when_is_ref<T> types_when_ref;
typedef optional_base<T> this_type;
protected:
typedef T value_type;
typedef std::true_type is_reference_tag;
typedef std::false_type is_not_reference_tag;
typedef typename std::is_reference<T>::type is_reference_predicate;
typedef typename std::conditional<is_reference_predicate::value,
types_when_ref,
types_when_not_ref>::type types;
typedef bool (this_type::*unspecified_bool_type)() const;
typedef typename types::reference_type reference_type;
typedef typename types::reference_const_type reference_const_type;
typedef typename types::pointer_type pointer_type;
typedef typename types::pointer_const_type pointer_const_type;
typedef typename types::argument_type argument_type;
// Creates an optional<T> uninitialized.
// No-throw
optional_base() : m_initialized(false) {}
// Creates an optional<T> uninitialized.
// No-throw
optional_base(none_t) : m_initialized(false) {} // NOLINT
// Creates an optional<T> initialized with 'val'.
// Can throw if T::T(T const&) does
optional_base(argument_type val) : m_initialized(false) { // NOLINT
construct(val);
}
// Creates an optional<T> initialized with 'val' IFF cond is true, otherwise
// creates an uninitialized optional<T>.
// Can throw if T::T(T const&) does
optional_base(bool cond, argument_type val) : m_initialized(false) {
if (cond) construct(val);
}
// Creates a deep copy of another optional<T>
// Can throw if T::T(T const&) does
optional_base(optional_base const& rhs) : m_initialized(false) {
if (rhs.is_initialized()) construct(rhs.get_impl());
}
// This is used for both converting and in-place constructions.
// Derived classes use the 'tag' to select the appropriate
// implementation (the correct 'construct()' overload)
template <class Expr>
explicit optional_base(Expr const& expr, Expr const* tag)
: m_initialized(false) {
construct(expr, tag);
}
// No-throw (assuming T::~T() doesn't)
~optional_base() { destroy(); }
// Assigns from another optional<T> (deep-copies the rhs value)
void assign(optional_base const& rhs) {
if (is_initialized()) {
if (rhs.is_initialized())
assign_value(rhs.get_impl(), is_reference_predicate());
else
destroy();
} else {
if (rhs.is_initialized()) construct(rhs.get_impl());
}
}
// Assigns from another _convertible_ optional<U> (deep-copies the rhs value)
template <class U>
void assign(optional<U> const& rhs) {
if (is_initialized()) {
if (rhs.is_initialized())
assign_value(static_cast<value_type>(rhs.get()),
is_reference_predicate());
else
destroy();
} else {
if (rhs.is_initialized()) construct(static_cast<value_type>(rhs.get()));
}
}
// Assigns from a T (deep-copies the rhs value)
void assign(argument_type val) {
if (is_initialized())
assign_value(val, is_reference_predicate());
else
construct(val);
}
// Assigns from "none", destroying the current value, if any, leaving this
// UNINITIALIZED
// No-throw (assuming T::~T() doesn't)
void assign(none_t) { destroy(); }
template <class Expr>
void assign_expr(Expr const& expr, Expr const* tag) {
if (is_initialized())
assign_expr_to_initialized(expr, tag);
else
construct(expr, tag);
}
public:
// Destroys the current value, if any, leaving this UNINITIALIZED
// No-throw (assuming T::~T() doesn't)
void reset() { destroy(); }
// Replaces the current value -if any- with 'val'
void reset(argument_type val) { assign(val); }
// Returns a pointer to the value if this is initialized, otherwise,
// returns NULL.
// No-throw
pointer_const_type get_ptr() const {
return m_initialized ? get_ptr_impl() : 0;
}
pointer_type get_ptr() { return m_initialized ? get_ptr_impl() : 0; }
bool is_initialized() const { return m_initialized; }
protected:
void construct(argument_type val) {
new (m_storage.address()) internal_type(val);
m_initialized = true;
}
// Constructs in-place using the given factory
template <class Expr>
void construct(Expr const& factory, in_place_factory_base const*) {
static_assert(!is_reference_predicate::value,
"!is_reference_predicate::value");
paddle_optional_detail::construct<value_type>(factory, m_storage.address());
m_initialized = true;
}
// Constructs in-place using the given typed factory
template <class Expr>
void construct(Expr const& factory, typed_in_place_factory_base const*) {
static_assert(!is_reference_predicate::value,
"!is_reference_predicate::value");
factory.apply(m_storage.address());
m_initialized = true;
}
template <class Expr>
void assign_expr_to_initialized(Expr const& factory,
in_place_factory_base const* tag) {
destroy();
construct(factory, tag);
}
// Constructs in-place using the given typed factory
template <class Expr>
void assign_expr_to_initialized(Expr const& factory,
typed_in_place_factory_base const* tag) {
destroy();
construct(factory, tag);
}
// Constructs using any expression implicitly convertible to the single
// argument
// of a one-argument T constructor.
// Converting constructions of optional<T> from optional<U> uses this function
// with
// 'Expr' being of type 'U' and relying on a converting constructor of T from
// U.
template <class Expr>
void construct(Expr const& expr, void const*) {
new (m_storage.address()) internal_type(expr);
m_initialized = true;
}
// Assigns using a form any expression implicitly convertible to the single
// argument
// of a T's assignment operator.
// Converting assignments of optional<T> from optional<U> uses this function
// with
// 'Expr' being of type 'U' and relying on a converting assignment of T from
// U.
template <class Expr>
void assign_expr_to_initialized(Expr const& expr, void const*) {
assign_value(expr, is_reference_predicate());
}
void assign_value(argument_type val, is_not_reference_tag) {
get_impl() = val;
}
void assign_value(argument_type val, is_reference_tag) { construct(val); }
void destroy() {
if (m_initialized) destroy_impl(is_reference_predicate());
}
unspecified_bool_type safe_bool() const {
return m_initialized ? &this_type::is_initialized : 0;
}
reference_const_type get_impl() const {
return dereference(get_object(), is_reference_predicate());
}
reference_type get_impl() {
return dereference(get_object(), is_reference_predicate());
}
pointer_const_type get_ptr_impl() const {
return cast_ptr(get_object(), is_reference_predicate());
}
pointer_type get_ptr_impl() {
return cast_ptr(get_object(), is_reference_predicate());
}
private:
// internal_type can be either T or reference_content<T>
internal_type const* get_object() const {
return static_cast<internal_type const*>(m_storage.address());
}
internal_type* get_object() {
return static_cast<internal_type*>(m_storage.address());
}
// reference_content<T> lacks an implicit conversion to T&, so the following
// is needed to obtain a proper reference.
reference_const_type dereference(internal_type const* p,
is_not_reference_tag) const {
return *p;
}
reference_type dereference(internal_type* p, is_not_reference_tag) {
return *p;
}
reference_const_type dereference(internal_type const* p,
is_reference_tag) const {
return p->get();
}
reference_type dereference(internal_type* p, is_reference_tag) {
return p->get();
}
void destroy_impl(is_not_reference_tag) {
get_ptr_impl()->T::~T();
m_initialized = false;
}
void destroy_impl(is_reference_tag) { m_initialized = false; }
// If T is of reference type, trying to get a pointer to the held value must
// result in a compile-time error.
// Decent compilers should disallow conversions from reference_content<T>* to
// T*, but just in case,
// the following olverloads are used to filter out the case and guarantee an
// error in case of T being a reference.
pointer_const_type cast_ptr(internal_type const* p,
is_not_reference_tag) const {
return p;
}
pointer_type cast_ptr(internal_type* p, is_not_reference_tag) { return p; }
pointer_const_type cast_ptr(internal_type const* p, is_reference_tag) const {
return &p->get();
}
pointer_type cast_ptr(internal_type* p, is_reference_tag) {
return &p->get();
}
bool m_initialized;
storage_type m_storage;
};
} // namespace optional_detail
template <class T>
class optional : public optional_detail::optional_base<T> {
typedef optional_detail::optional_base<T> base;
typedef typename base::unspecified_bool_type unspecified_bool_type;
public:
typedef optional<T> this_type;
typedef typename base::value_type value_type;
typedef typename base::reference_type reference_type;
typedef typename base::reference_const_type reference_const_type;
typedef typename base::pointer_type pointer_type;
typedef typename base::pointer_const_type pointer_const_type;
typedef typename base::argument_type argument_type;
// Creates an optional<T> uninitialized.
// No-throw
optional() : base() {}
// Creates an optional<T> uninitialized.
// No-throw
optional(none_t none_) : base(none_) {} // NOLINT
// Creates an optional<T> initialized with 'val'.
// Can throw if T::T(T const&) does
optional(argument_type val) : base(val) {} // NOLINT
// Creates an optional<T> initialized with 'val' IFF cond is true, otherwise
// creates an uninitialized optional.
// Can throw if T::T(T const&) does
optional(bool cond, argument_type val) : base(cond, val) {}
// Creates a deep copy of another convertible optional<U>
// Requires a valid conversion from U to T.
// Can throw if T::T(U const&) does
template <class U>
explicit optional(optional<U> const& rhs) : base() {
if (rhs.is_initialized()) this->construct(rhs.get());
}
// Creates an optional<T> with an expression which can be either
// (a) An instance of InPlaceFactory (i.e. in_place(a,b,...,n);
// (b) An instance of TypedInPlaceFactory ( i.e. in_place<T>(a,b,...,n);
// (c) Any expression implicitly convertible to the single type
// of a one-argument T's constructor.
// (d*) Weak compilers (BCB) might also resolved Expr as optional<T> and
// optional<U>
// even though explicit overloads are present for these.
// Depending on the above some T ctor is called.
// Can throw is the resolved T ctor throws.
template <class Expr>
explicit optional(Expr const& expr) : base(expr, &expr) {}
// Creates a deep copy of another optional<T>
// Can throw if T::T(T const&) does
optional(optional const& rhs) : base(rhs) {}
// No-throw (assuming T::~T() doesn't)
~optional() {}
// Assigns from an expression. See corresponding constructor.
// Basic Guarantee: If the resolved T ctor throws, this is left UNINITIALIZED
template <class Expr>
optional& operator=(Expr expr) {
this->assign_expr(expr, &expr);
return *this;
}
// Assigns from another convertible optional<U> (converts && deep-copies the
// rhs value)
// Requires a valid conversion from U to T.
// Basic Guarantee: If T::T( U const& ) throws, this is left UNINITIALIZED
template <class U>
optional& operator=(optional<U> const& rhs) {
this->assign(rhs);
return *this;
}
// Assigns from another optional<T> (deep-copies the rhs value)
// Basic Guarantee: If T::T( T const& ) throws, this is left UNINITIALIZED
// (NOTE: On BCB, this operator is not actually called and left is left
// UNMODIFIED in case of a throw)
optional& operator=(optional const& rhs) {
this->assign(rhs);
return *this;
}
// Assigns from a T (deep-copies the rhs value)
// Basic Guarantee: If T::( T const& ) throws, this is left UNINITIALIZED
optional& operator=(argument_type val) {
this->assign(val);
return *this;
}
// Assigns from a "none"
// Which destroys the current value, if any, leaving this UNINITIALIZED
// No-throw (assuming T::~T() doesn't)
optional& operator=(none_t none_) {
this->assign(none_);
return *this;
}
// Returns a reference to the value if this is initialized, otherwise,
// the behaviour is UNDEFINED
// No-throw
reference_const_type get() const {
assert(this->is_initialized());
return this->get_impl();
}
reference_type get() {
assert(this->is_initialized());
return this->get_impl();
}
// Returns a copy of the value if this is initialized, 'v' otherwise
reference_const_type get_value_or(reference_const_type v) const {
return this->is_initialized() ? get() : v;
}
reference_type get_value_or(reference_type v) {
return this->is_initialized() ? get() : v;
}
// Returns a pointer to the value if this is initialized, otherwise,
// the behaviour is UNDEFINED
// No-throw
pointer_const_type operator->() const {
assert(this->is_initialized());
return this->get_ptr_impl();
}
pointer_type operator->() {
assert(this->is_initialized());
return this->get_ptr_impl();
}
// Returns a reference to the value if this is initialized, otherwise,
// the behaviour is UNDEFINED
// No-throw
reference_const_type operator*() const { return this->get(); }
reference_type operator*() { return this->get(); }
// implicit conversion to "bool"
// No-throw
operator unspecified_bool_type() const { return this->safe_bool(); }
// This is provided for those compilers which don't like the conversion to
// bool
// on some contexts.
bool operator!() const { return !this->is_initialized(); }
};
// Returns optional<T>(v)
template <class T>
inline optional<T> make_optional(T const& v) {
return optional<T>(v);
}
// Returns optional<T>(cond,v)
template <class T>
inline optional<T> make_optional(bool cond, T const& v) {
return optional<T>(cond, v);
}
// Returns a reference to the value if this is initialized, otherwise, the
// behaviour is UNDEFINED.
// No-throw
template <class T>
inline typename optional<T>::reference_const_type get(optional<T> const& opt) {
return opt.get();
}
template <class T>
inline typename optional<T>::reference_type get(optional<T>& opt) { // NOLINT
return opt.get();
}
// Returns a pointer to the value if this is initialized, otherwise, returns
// NULL.
// No-throw
template <class T>
inline typename optional<T>::pointer_const_type get(optional<T> const* opt) {
return opt->get_ptr();
}
template <class T>
inline typename optional<T>::pointer_type get(optional<T>* opt) {
return opt->get_ptr();
}
// Returns a reference to the value if this is initialized, otherwise, the
// behaviour is UNDEFINED.
// No-throw
template <class T>
inline typename optional<T>::reference_const_type get_optional_value_or(
optional<T> const& opt, typename optional<T>::reference_const_type v) {
return opt.get_value_or(v);
}
template <class T>
inline typename optional<T>::reference_type get_optional_value_or(
optional<T>& opt, typename optional<T>::reference_type v) { // NOLINT
return opt.get_value_or(v);
}
// Returns a pointer to the value if this is initialized, otherwise, returns
// NULL.
// No-throw
template <class T>
inline typename optional<T>::pointer_const_type get_pointer(
optional<T> const& opt) {
return opt.get_ptr();
}
template <class T>
inline typename optional<T>::pointer_type get_pointer(
optional<T>& opt) { // NOLINT
return opt.get_ptr();
}
// optional's relational operators ( ==, !=, <, >, <=, >= ) have deep-semantics
// (compare values).
// WARNING: This is UNLIKE pointers. Use equal_pointees()/less_pointess() in
// generic code instead.
//
// optional<T> vs optional<T> cases
//
template <class T>
inline bool operator==(optional<T> const& x, optional<T> const& y) {
return equal_pointees(x, y);
}
template <class T>
inline bool operator<(optional<T> const& x, optional<T> const& y) {
return less_pointees(x, y);
}
template <class T>
inline bool operator!=(optional<T> const& x, optional<T> const& y) {
return !(x == y);
}
template <class T>
inline bool operator>(optional<T> const& x, optional<T> const& y) {
return y < x;
}
template <class T>
inline bool operator<=(optional<T> const& x, optional<T> const& y) {
return !(y < x);
}
template <class T>
inline bool operator>=(optional<T> const& x, optional<T> const& y) {
return !(x < y);
}
//
// optional<T> vs T cases
//
template <class T>
inline bool operator==(optional<T> const& x, T const& y) {
return equal_pointees(x, optional<T>(y));
}
template <class T>
inline bool operator<(optional<T> const& x, T const& y) {
return less_pointees(x, optional<T>(y));
}
template <class T>
inline bool operator!=(optional<T> const& x, T const& y) {
return !(x == y);
}
template <class T>
inline bool operator>(optional<T> const& x, T const& y) {
return y < x;
}
template <class T>
inline bool operator<=(optional<T> const& x, T const& y) {
return !(y < x);
}
template <class T>
inline bool operator>=(optional<T> const& x, T const& y) {
return !(x < y);
}
//
// T vs optional<T> cases
//
template <class T>
inline bool operator==(T const& x, optional<T> const& y) {
return equal_pointees(optional<T>(x), y);
}
template <class T>
inline bool operator<(T const& x, optional<T> const& y) {
return less_pointees(optional<T>(x), y);
}
template <class T>
inline bool operator!=(T const& x, optional<T> const& y) {
return !(x == y);
}
template <class T>
inline bool operator>(T const& x, optional<T> const& y) {
return y < x;
}
template <class T>
inline bool operator<=(T const& x, optional<T> const& y) {
return !(y < x);
}
template <class T>
inline bool operator>=(T const& x, optional<T> const& y) {
return !(x < y);
}
//
// optional<T> vs none cases
//
template <class T>
inline bool operator==(optional<T> const& x, none_t) {
return equal_pointees(x, optional<T>());
}
template <class T>
inline bool operator<(optional<T> const& x, none_t) {
return less_pointees(x, optional<T>());
}
template <class T>
inline bool operator!=(optional<T> const& x, none_t y) {
return !(x == y);
}
template <class T>
inline bool operator>(optional<T> const& x, none_t y) {
return y < x;
}
template <class T>
inline bool operator<=(optional<T> const& x, none_t y) {
return !(y < x);
}
template <class T>
inline bool operator>=(optional<T> const& x, none_t y) {
return !(x < y);
}
//
// none vs optional<T> cases
//
template <class T>
inline bool operator==(none_t x, optional<T> const& y) {
return equal_pointees(optional<T>(), y);
}
template <class T>
inline bool operator<(none_t x, optional<T> const& y) {
return less_pointees(optional<T>(), y);
}
template <class T>
inline bool operator!=(none_t x, optional<T> const& y) {
return !(x == y);
}
template <class T>
inline bool operator>(none_t x, optional<T> const& y) {
return y < x;
}
template <class T>
inline bool operator<=(none_t x, optional<T> const& y) {
return !(y < x);
}
template <class T>
inline bool operator>=(none_t x, optional<T> const& y) {
return !(x < y);
}
namespace optional_detail {
// optional's swap:
// If both are initialized, calls swap(T&, T&). If this swap throws, both will
// remain initialized but their values are now unspecified.
// If only one is initialized, calls U.reset(*I), THEN I.reset().
// If U.reset(*I) throws, both are left UNCHANGED (U is kept uinitialized and I
// is never reset)
// If both are uninitialized, do nothing (no-throw)
template <class T>
inline void optional_swap(optional<T>& x, optional<T>& y) {
if (!x && !!y) {
x.reset(*y);
y.reset();
} else if (!!x && !y) {
y.reset(*x);
x.reset();
} else if (!!x && !!y) {
// allow for Koenig lookup
using std::swap;
swap(*x, *y);
}
}
} // namespace optional_detail
} // namespace paddle
namespace phi {
template <class T>
using optional = paddle::optional<T>;
}