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b050b744be
I think that `using` is easier to read than `typedef`, and it's the modern C++ thing anyway. Change-Id: Iccb62dc3869cddfb6a684ef3023dcd5b799f3ab2
486 lines
16 KiB
C++
486 lines
16 KiB
C++
/* Copyright (C) 2015-2024 Free Software Foundation, Inc.
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This file is part of GDB.
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>. */
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#ifndef COMMON_ENUM_FLAGS_H
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#define COMMON_ENUM_FLAGS_H
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#include "traits.h"
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/* Type-safe wrapper for enum flags. enum flags are enums where the
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values are bits that are meant to be ORed together.
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This allows writing code like the below, while with raw enums this
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would fail to compile without casts to enum type at the assignments
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to 'f':
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enum some_flag
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{
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flag_val1 = 1 << 1,
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flag_val2 = 1 << 2,
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flag_val3 = 1 << 3,
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flag_val4 = 1 << 4,
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};
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DEF_ENUM_FLAGS_TYPE(enum some_flag, some_flags);
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some_flags f = flag_val1 | flag_val2;
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f |= flag_val3;
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It's also possible to assign literal zero to an enum flags variable
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(meaning, no flags), dispensing adding an awkward explicit "no
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value" value to the enumeration. For example:
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some_flags f = 0;
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f |= flag_val3 | flag_val4;
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Note that literal integers other than zero fail to compile:
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some_flags f = 1; // error
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*/
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/* Use this to mark an enum as flags enum. It defines FLAGS_TYPE as
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enum_flags wrapper class for ENUM, and enables the global operator
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overloads for ENUM. */
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#define DEF_ENUM_FLAGS_TYPE(enum_type, flags_type) \
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using flags_type = enum_flags<enum_type>; \
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void is_enum_flags_enum_type (enum_type *)
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/* To enable the global enum_flags operators for enum, declare an
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"is_enum_flags_enum_type" overload that has exactly one parameter,
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of type a pointer to that enum class. E.g.,:
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void is_enum_flags_enum_type (enum some_flag *);
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The function does not need to be defined, only declared.
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DEF_ENUM_FLAGS_TYPE declares this.
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A function declaration is preferred over a traits type, because the
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former allows calling the DEF_ENUM_FLAGS_TYPE macro inside a
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namespace to define the corresponding enum flags type in that
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namespace. The compiler finds the corresponding
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is_enum_flags_enum_type function via ADL. */
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/* Note that std::underlying_type<enum_type> is not what we want here,
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since that returns unsigned int even when the enum decays to signed
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int. */
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template<int size, bool sign> class integer_for_size { using type = void; };
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template<> struct integer_for_size<1, 0> { using type = uint8_t; };
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template<> struct integer_for_size<2, 0> { using type = uint16_t; };
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template<> struct integer_for_size<4, 0> { using type = uint32_t; };
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template<> struct integer_for_size<8, 0> { using type = uint64_t; };
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template<> struct integer_for_size<1, 1> { using type = int8_t; };
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template<> struct integer_for_size<2, 1> { using type = int16_t; };
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template<> struct integer_for_size<4, 1> { using type = int32_t; };
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template<> struct integer_for_size<8, 1> { using type = int64_t; };
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template<typename T>
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struct enum_underlying_type
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{
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DIAGNOSTIC_PUSH
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DIAGNOSTIC_IGNORE_ENUM_CONSTEXPR_CONVERSION
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using type
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= typename integer_for_size<sizeof (T),
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static_cast<bool>(T (-1) < T (0))>::type;
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DIAGNOSTIC_POP
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};
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namespace enum_flags_detail
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{
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/* Private type used to support initializing flag types with zero:
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foo_flags f = 0;
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but not other integers:
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foo_flags f = 1;
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The way this works is that we define an implicit constructor that
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takes a pointer to this private type. Since nothing can
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instantiate an object of this type, the only possible pointer to
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pass to the constructor is the NULL pointer, or, zero. */
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struct zero_type;
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/* gdb::Requires trait helpers. */
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template <typename enum_type>
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using EnumIsUnsigned
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= std::is_unsigned<typename enum_underlying_type<enum_type>::type>;
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template <typename enum_type>
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using EnumIsSigned
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= std::is_signed<typename enum_underlying_type<enum_type>::type>;
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}
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template <typename E>
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class enum_flags
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{
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public:
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using enum_type = E;
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using underlying_type = typename enum_underlying_type<enum_type>::type;
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/* For to_string. Maps one enumerator of E to a string. */
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struct string_mapping
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{
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E flag;
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const char *str;
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};
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/* Convenience for to_string implementations, to build a
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string_mapping array. */
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#define MAP_ENUM_FLAG(ENUM_FLAG) { ENUM_FLAG, #ENUM_FLAG }
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public:
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/* Allow default construction. */
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constexpr enum_flags ()
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: m_enum_value ((enum_type) 0)
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{}
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/* The default move/copy ctor/assignment do the right thing. */
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/* If you get an error saying these two overloads are ambiguous,
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then you tried to mix values of different enum types. */
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constexpr enum_flags (enum_type e)
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: m_enum_value (e)
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{}
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constexpr enum_flags (enum_flags_detail::zero_type *zero)
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: m_enum_value ((enum_type) 0)
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{}
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enum_flags &operator&= (enum_flags e) &
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{
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m_enum_value = (enum_type) (m_enum_value & e.m_enum_value);
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return *this;
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}
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enum_flags &operator|= (enum_flags e) &
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{
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m_enum_value = (enum_type) (m_enum_value | e.m_enum_value);
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return *this;
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}
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enum_flags &operator^= (enum_flags e) &
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{
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m_enum_value = (enum_type) (m_enum_value ^ e.m_enum_value);
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return *this;
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}
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/* Delete rval versions. */
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void operator&= (enum_flags e) && = delete;
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void operator|= (enum_flags e) && = delete;
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void operator^= (enum_flags e) && = delete;
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/* Like raw enums, allow conversion to the underlying type. */
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constexpr operator underlying_type () const
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{
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return m_enum_value;
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}
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/* Get the underlying value as a raw enum. */
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constexpr enum_type raw () const
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{
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return m_enum_value;
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}
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/* Binary operations involving some unrelated type (which would be a
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bug) are implemented as non-members, and deleted. */
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/* Convert this object to a std::string, using MAPPING as
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enumerator-to-string mapping array. This is not meant to be
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called directly. Instead, enum_flags specializations should have
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their own to_string function wrapping this one, thus hiding the
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mapping array from callers.
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Note: this is defined outside the template class so it can use
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the global operators for enum_type, which are only defined after
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the template class. */
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template<size_t N>
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std::string to_string (const string_mapping (&mapping)[N]) const;
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private:
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/* Stored as enum_type because GDB knows to print the bit flags
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neatly if the enum values look like bit flags. */
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enum_type m_enum_value;
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};
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template <typename E>
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using is_enum_flags_enum_type_t
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= decltype (is_enum_flags_enum_type (std::declval<E *> ()));
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/* Global operator overloads. */
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/* Generate binary operators. */
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#define ENUM_FLAGS_GEN_BINOP(OPERATOR_OP, OP) \
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\
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/* Raw enum on both LHS/RHS. Returns raw enum type. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_type \
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OPERATOR_OP (enum_type e1, enum_type e2) \
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{ \
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using underlying = typename enum_flags<enum_type>::underlying_type; \
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return (enum_type) (underlying (e1) OP underlying (e2)); \
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} \
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\
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/* enum_flags on the LHS. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (enum_flags<enum_type> e1, enum_type e2) \
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{ return e1.raw () OP e2; } \
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\
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/* enum_flags on the RHS. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (enum_type e1, enum_flags<enum_type> e2) \
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{ return e1 OP e2.raw (); } \
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\
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/* enum_flags on both LHS/RHS. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (enum_flags<enum_type> e1, enum_flags<enum_type> e2) \
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{ return e1.raw () OP e2.raw (); } \
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\
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/* Delete cases involving unrelated types. */ \
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\
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template <typename enum_type, typename unrelated_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (enum_type e1, unrelated_type e2) = delete; \
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\
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template <typename enum_type, typename unrelated_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (unrelated_type e1, enum_type e2) = delete; \
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\
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template <typename enum_type, typename unrelated_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (enum_flags<enum_type> e1, unrelated_type e2) = delete; \
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\
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template <typename enum_type, typename unrelated_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_flags<enum_type> \
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OPERATOR_OP (unrelated_type e1, enum_flags<enum_type> e2) = delete;
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/* Generate non-member compound assignment operators. Only the raw
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enum versions are defined here. The enum_flags versions are
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defined as member functions, simply because it's less code that
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way.
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Note we delete operators that would allow e.g.,
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"enum_type | 1" or "enum_type1 | enum_type2"
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because that would allow a mistake like :
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enum flags1 { F1_FLAGS1 = 1 };
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enum flags2 { F2_FLAGS2 = 2 };
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enum flags1 val;
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switch (val) {
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case F1_FLAGS1 | F2_FLAGS2:
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...
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If you really need to 'or' enumerators of different flag types,
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cast to integer first.
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*/
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#define ENUM_FLAGS_GEN_COMPOUND_ASSIGN(OPERATOR_OP, OP) \
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/* lval reference version. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_type & \
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OPERATOR_OP (enum_type &e1, enum_type e2) \
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{ return e1 = e1 OP e2; } \
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\
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/* rval reference version. */ \
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template <typename enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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void \
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OPERATOR_OP (enum_type &&e1, enum_type e2) = delete; \
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\
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/* Delete compound assignment from unrelated types. */ \
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\
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template <typename enum_type, typename other_enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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constexpr enum_type & \
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OPERATOR_OP (enum_type &e1, other_enum_type e2) = delete; \
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\
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template <typename enum_type, typename other_enum_type, \
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typename = is_enum_flags_enum_type_t<enum_type>> \
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void \
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OPERATOR_OP (enum_type &&e1, other_enum_type e2) = delete;
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ENUM_FLAGS_GEN_BINOP (operator|, |)
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ENUM_FLAGS_GEN_BINOP (operator&, &)
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ENUM_FLAGS_GEN_BINOP (operator^, ^)
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ENUM_FLAGS_GEN_COMPOUND_ASSIGN (operator|=, |)
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ENUM_FLAGS_GEN_COMPOUND_ASSIGN (operator&=, &)
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ENUM_FLAGS_GEN_COMPOUND_ASSIGN (operator^=, ^)
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/* Allow comparison with enum_flags, raw enum, and integers, only.
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The latter case allows "== 0". As side effect, it allows comparing
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with integer variables too, but that's not a common mistake to
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make. It's important to disable comparison with unrelated types to
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prevent accidentally comparing with unrelated enum values, which
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are convertible to integer, and thus coupled with enum_flags
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conversion to underlying type too, would trigger the built-in 'bool
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operator==(unsigned, int)' operator. */
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#define ENUM_FLAGS_GEN_COMP(OPERATOR_OP, OP) \
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\
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/* enum_flags OP enum_flags */ \
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\
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template <typename enum_type> \
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constexpr bool \
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OPERATOR_OP (enum_flags<enum_type> lhs, enum_flags<enum_type> rhs) \
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{ return lhs.raw () OP rhs.raw (); } \
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\
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/* enum_flags OP other */ \
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\
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template <typename enum_type> \
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constexpr bool \
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OPERATOR_OP (enum_flags<enum_type> lhs, enum_type rhs) \
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{ return lhs.raw () OP rhs; } \
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\
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template <typename enum_type> \
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constexpr bool \
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OPERATOR_OP (enum_flags<enum_type> lhs, int rhs) \
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{ return lhs.raw () OP rhs; } \
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\
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template <typename enum_type, typename U> \
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constexpr bool \
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OPERATOR_OP (enum_flags<enum_type> lhs, U rhs) = delete; \
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\
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/* other OP enum_flags */ \
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\
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template <typename enum_type> \
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constexpr bool \
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OPERATOR_OP (enum_type lhs, enum_flags<enum_type> rhs) \
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{ return lhs OP rhs.raw (); } \
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\
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template <typename enum_type> \
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constexpr bool \
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OPERATOR_OP (int lhs, enum_flags<enum_type> rhs) \
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{ return lhs OP rhs.raw (); } \
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\
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template <typename enum_type, typename U> \
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constexpr bool \
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OPERATOR_OP (U lhs, enum_flags<enum_type> rhs) = delete;
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ENUM_FLAGS_GEN_COMP (operator==, ==)
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ENUM_FLAGS_GEN_COMP (operator!=, !=)
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/* Unary operators for the raw flags enum. */
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/* We require underlying type to be unsigned when using operator~ --
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if it were not unsigned, undefined behavior could result. However,
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asserting this in the class itself would require too many
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unnecessary changes to usages of otherwise OK enum types. */
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template <typename enum_type,
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typename = is_enum_flags_enum_type_t<enum_type>,
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typename
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= gdb::Requires<enum_flags_detail::EnumIsUnsigned<enum_type>>>
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constexpr enum_type
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operator~ (enum_type e)
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{
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using underlying = typename enum_flags<enum_type>::underlying_type;
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return (enum_type) ~underlying (e);
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}
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template <typename enum_type,
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typename = is_enum_flags_enum_type_t<enum_type>,
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typename = gdb::Requires<enum_flags_detail::EnumIsSigned<enum_type>>>
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constexpr void operator~ (enum_type e) = delete;
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template <typename enum_type,
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typename = is_enum_flags_enum_type_t<enum_type>,
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typename
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= gdb::Requires<enum_flags_detail::EnumIsUnsigned<enum_type>>>
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constexpr enum_flags<enum_type>
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operator~ (enum_flags<enum_type> e)
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{
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using underlying = typename enum_flags<enum_type>::underlying_type;
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return (enum_type) ~underlying (e);
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}
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template <typename enum_type,
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typename = is_enum_flags_enum_type_t<enum_type>,
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typename = gdb::Requires<enum_flags_detail::EnumIsSigned<enum_type>>>
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constexpr void operator~ (enum_flags<enum_type> e) = delete;
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/* Delete operator<< and operator>>. */
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template <typename enum_type, typename any_type,
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typename = is_enum_flags_enum_type_t<enum_type>>
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void operator<< (const enum_type &, const any_type &) = delete;
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template <typename enum_type, typename any_type,
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typename = is_enum_flags_enum_type_t<enum_type>>
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void operator<< (const enum_flags<enum_type> &, const any_type &) = delete;
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template <typename enum_type, typename any_type,
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typename = is_enum_flags_enum_type_t<enum_type>>
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void operator>> (const enum_type &, const any_type &) = delete;
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template <typename enum_type, typename any_type,
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typename = is_enum_flags_enum_type_t<enum_type>>
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void operator>> (const enum_flags<enum_type> &, const any_type &) = delete;
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template<typename E>
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template<size_t N>
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std::string
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enum_flags<E>::to_string (const string_mapping (&mapping)[N]) const
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{
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enum_type flags = raw ();
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std::string res = hex_string (flags);
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res += " [";
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bool need_space = false;
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for (const auto &entry : mapping)
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{
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if ((flags & entry.flag) != 0)
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{
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/* Work with an unsigned version of the underlying type,
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because if enum_type's underlying type is signed, op~
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won't be defined for it, and, bitwise operations on
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signed types are implementation defined. */
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using uns = typename std::make_unsigned<underlying_type>::type;
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flags &= (enum_type) ~(uns) entry.flag;
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if (need_space)
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res += " ";
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res += entry.str;
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need_space = true;
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}
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}
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/* If there were flags not included in the mapping, print them as
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a hex number. */
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if (flags != 0)
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{
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if (need_space)
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res += " ";
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res += hex_string (flags);
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}
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res += "]";
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return res;
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}
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#endif /* COMMON_ENUM_FLAGS_H */
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