/* Offset types for GDB. Copyright (C) 2017-2018 Free Software Foundation, Inc. This file is part of GDB. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* Define an "offset" type. Offset types are distinct integer types that are used to represent an offset into anything that is addressable. For example, an offset into a DWARF debug section. The idea is catch mixing unrelated offset types at compile time, in code that needs to manipulate multiple different kinds of offsets that are easily confused. They're safer to use than native integers, because they have no implicit conversion to anything. And also, since they're implemented as "enum class" strong typedefs, they're still integers ABI-wise, making them a bit more efficient than wrapper structs on some ABIs. Some properties of offset types, loosely modeled on pointers: - You can compare offsets of the same type for equality and order. You can't compare an offset with an unrelated type. - You can add/substract an integer to/from an offset, which gives you back a shifted offset. - You can subtract two offsets of the same type, which gives you back the delta as an integer (of the enum class's underlying type), not as an offset type. - You can't add two offsets of the same type, as that would not make sense. However, unlike pointers, you can't deference offset types. */ #ifndef COMMON_OFFSET_TYPE_H #define COMMON_OFFSET_TYPE_H /* Declare TYPE as being an offset type. This declares the type and enables the operators defined below. */ #define DEFINE_OFFSET_TYPE(TYPE, UNDERLYING) \ enum class TYPE : UNDERLYING {}; \ void is_offset_type (TYPE) /* The macro macro is all you need to know use offset types. The rest below is all implementation detail. */ /* For each enum class type that you want to support relational operators, declare an "is_offset_type" overload that has exactly one parameter, of type that enum class. E.g.,: void is_offset_type (sect_offset); The function does not need to be defined, only declared. DEFINE_OFFSET_TYPE declares this. A function declaration is preferred over a traits type, because the former allows calling the DEFINE_OFFSET_TYPE macro inside a namespace to define the corresponding offset type in that namespace. The compiler finds the corresponding is_offset_type function via ADL. */ #define DEFINE_OFFSET_REL_OP(OP) \ template ()))> \ constexpr bool \ operator OP (E lhs, E rhs) \ { \ using underlying = typename std::underlying_type::type; \ return (static_cast (lhs) \ OP static_cast (lhs)); \ } DEFINE_OFFSET_REL_OP(>) DEFINE_OFFSET_REL_OP(>=) DEFINE_OFFSET_REL_OP(<) DEFINE_OFFSET_REL_OP(<=) /* Adding or subtracting an integer to an offset type shifts the offset. This is like "PTR = PTR + INT" and "PTR += INT". */ #define DEFINE_OFFSET_ARITHM_OP(OP) \ template ()))> \ constexpr E \ operator OP (E lhs, typename std::underlying_type::type rhs) \ { \ using underlying = typename std::underlying_type::type; \ return (E) (static_cast (lhs) OP rhs); \ } \ \ template ()))> \ constexpr E \ operator OP (typename std::underlying_type::type lhs, E rhs) \ { \ using underlying = typename std::underlying_type::type; \ return (E) (lhs OP static_cast (rhs)); \ } \ \ template ()))> \ E & \ operator OP ## = (E &lhs, typename std::underlying_type::type rhs) \ { \ using underlying = typename std::underlying_type::type; \ lhs = (E) (static_cast (lhs) OP rhs); \ return lhs; \ } DEFINE_OFFSET_ARITHM_OP(+) DEFINE_OFFSET_ARITHM_OP(-) /* Adding two offset types doesn't make sense, just like "PTR + PTR" doesn't make sense. This is defined as a deleted function so that a compile error easily brings you to this comment. */ template ()))> constexpr typename std::underlying_type::type operator+ (E lhs, E rhs) = delete; /* Subtracting two offset types, however, gives you back the difference between the offsets, as an underlying type. Similar to how "PTR2 - PTR1" returns a ptrdiff_t. */ template ()))> constexpr typename std::underlying_type::type operator- (E lhs, E rhs) { using underlying = typename std::underlying_type::type; return static_cast (lhs) - static_cast (rhs); } #endif /* COMMON_OFFSET_TYPE_H */