/* * Copyright (c) 2020, Ben Wiederhake * Copyright (c) 2021, Andreas Kling * Copyright (c) 2022, Sam Atkins * * SPDX-License-Identifier: BSD-2-Clause */ #pragma once #include #include #include namespace AK { /** * This implements a "distinct" numeric type that is intentionally incompatible * to other incantations. The intention is that each "distinct" type that you * want simply gets different values for `fn_length` and `line`. The macros * `TYPEDEF_DISTINCT_NUMERIC_*()` at the bottom of `DistinctNumeric.h`. * * The tags in `DistinctNumericFeature` simply split up the space of operators into 6 simple categories: * - No matter the values of these, `DistinctNumeric` always implements `==` and `!=`. * - If `Arithmetic` is present, then `a+b`, `a-b`, `+a`, `-a`, `a*b`, `a/b`, `a%b`, and the respective `a_=b` versions are implemented. * - If `CastToBool` is present, then `!a`, `a&&b`, and `a||b` are implemented (but not `operator bool()`, because of overzealous integer promotion rules). * - If `Comparison` is present, then `a>b`, `a=b`, and `a<=b` are implemented. * - If `Flags` is present, then `~a`, `a&b`, `a|b`, `a^b`, `a&=b`, `a|=b`, and `a^=b` are implemented. * - If `Increment` is present, then `++a`, `a++`, `--a`, and `a--` are implemented. * - If `Shift` is present, then `a<>b`, `a<<=b`, `a>>=b` are implemented. * The semantics are always those of the underlying basic type `T`. * * These can be combined arbitrarily. Want a numeric type that supports `++a` * and `a >> b` but not `a > b`? Sure thing, just set * `Increment, Comparison, Shift` and you're done! * Furthermore, some of these overloads make more sense with specific types, like `a&&b` which should be able to operate * * I intentionally decided against overloading `&a` because these shall remain * numeric types. * * The C++20 `operator<=>` would require, among other things `std::weak_equality`. * Since we do not have that, it cannot be implemented. * * The are many operators that do not work on `int`, so I left them out: * `a[b]`, `*a`, `a->b`, `a.b`, `a->*b`, `a.*b`. * * There are many more operators that do not make sense for numerical types, * or cannot be overloaded in the first place. Naturally, they are not implemented. */ namespace DistinctNumericFeature { enum Arithmetic {}; enum CastToBool {}; enum Comparison {}; enum Flags {}; enum Increment {}; enum Shift {}; }; template class DistinctNumeric { using Self = DistinctNumeric; struct Option { template consteval Option(K option, Os... other_options) : Option(other_options...) { set(option); } consteval Option() { } constexpr void set(DistinctNumericFeature::Arithmetic const&) { arithmetic = true; } constexpr void set(DistinctNumericFeature::CastToBool const&) { cast_to_bool = true; } constexpr void set(DistinctNumericFeature::Comparison const&) { comparisons = true; } constexpr void set(DistinctNumericFeature::Flags const&) { flags = true; } constexpr void set(DistinctNumericFeature::Increment const&) { increment = true; } constexpr void set(DistinctNumericFeature::Shift const&) { shift = true; } bool arithmetic { false }; bool cast_to_bool { false }; bool comparisons { false }; bool flags { false }; bool increment { false }; bool shift { false }; }; constexpr static Option options { Opts()... }; public: constexpr DistinctNumeric() = default; constexpr DistinctNumeric(T value) : m_value { value } { } constexpr T const& value() const { return m_value; } constexpr T& value() { return m_value; } // Always implemented: identity. constexpr bool operator==(Self const& other) const { return this->m_value == other.m_value; } // Only implemented when `Increment` is true: constexpr Self& operator++() { static_assert(options.increment, "'++a' is only available for DistinctNumeric types with 'Increment'."); this->m_value += 1; return *this; } constexpr Self operator++(int) { static_assert(options.increment, "'a++' is only available for DistinctNumeric types with 'Increment'."); Self ret = this->m_value; this->m_value += 1; return ret; } constexpr Self& operator--() { static_assert(options.increment, "'--a' is only available for DistinctNumeric types with 'Increment'."); this->m_value -= 1; return *this; } constexpr Self operator--(int) { static_assert(options.increment, "'a--' is only available for DistinctNumeric types with 'Increment'."); Self ret = this->m_value; this->m_value -= 1; return ret; } // Only implemented when `Comparison` is true: constexpr bool operator>(Self const& other) const { static_assert(options.comparisons, "'a>b' is only available for DistinctNumeric types with 'Comparison'."); return this->m_value > other.m_value; } constexpr bool operator<(Self const& other) const { static_assert(options.comparisons, "'am_value < other.m_value; } constexpr bool operator>=(Self const& other) const { static_assert(options.comparisons, "'a>=b' is only available for DistinctNumeric types with 'Comparison'."); return this->m_value >= other.m_value; } constexpr bool operator<=(Self const& other) const { static_assert(options.comparisons, "'a<=b' is only available for DistinctNumeric types with 'Comparison'."); return this->m_value <= other.m_value; } // 'operator<=>' cannot be implemented. See class comment. // Only implemented when `CastToBool` is true: constexpr bool operator!() const { static_assert(options.cast_to_bool, "'!a' is only available for DistinctNumeric types with 'CastToBool'."); return !this->m_value; } // Intentionally don't define `operator bool() const` here. C++ is a bit // overzealous, and whenever there would be a type error, C++ instead tries // to convert to a common int-ish type first. `bool` is int-ish, so // `operator bool() const` would defy the entire point of this class. // Only implemented when `Flags` is true: constexpr Self operator~() const { static_assert(options.flags, "'~a' is only available for DistinctNumeric types with 'Flags'."); return ~this->m_value; } constexpr Self operator&(Self const& other) const { static_assert(options.flags, "'a&b' is only available for DistinctNumeric types with 'Flags'."); return this->m_value & other.m_value; } constexpr Self operator|(Self const& other) const { static_assert(options.flags, "'a|b' is only available for DistinctNumeric types with 'Flags'."); return this->m_value | other.m_value; } constexpr Self operator^(Self const& other) const { static_assert(options.flags, "'a^b' is only available for DistinctNumeric types with 'Flags'."); return this->m_value ^ other.m_value; } constexpr Self& operator&=(Self const& other) { static_assert(options.flags, "'a&=b' is only available for DistinctNumeric types with 'Flags'."); this->m_value &= other.m_value; return *this; } constexpr Self& operator|=(Self const& other) { static_assert(options.flags, "'a|=b' is only available for DistinctNumeric types with 'Flags'."); this->m_value |= other.m_value; return *this; } constexpr Self& operator^=(Self const& other) { static_assert(options.flags, "'a^=b' is only available for DistinctNumeric types with 'Flags'."); this->m_value ^= other.m_value; return *this; } // Only implemented when `Shift` is true: // TODO: Should this take `int` instead? constexpr Self operator<<(Self const& other) const { static_assert(options.shift, "'a<m_value << other.m_value; } constexpr Self operator>>(Self const& other) const { static_assert(options.shift, "'a>>b' is only available for DistinctNumeric types with 'Shift'."); return this->m_value >> other.m_value; } constexpr Self& operator<<=(Self const& other) { static_assert(options.shift, "'a<<=b' is only available for DistinctNumeric types with 'Shift'."); this->m_value <<= other.m_value; return *this; } constexpr Self& operator>>=(Self const& other) { static_assert(options.shift, "'a>>=b' is only available for DistinctNumeric types with 'Shift'."); this->m_value >>= other.m_value; return *this; } // Only implemented when `Arithmetic` is true: constexpr Self operator+(Self const& other) const { static_assert(options.arithmetic, "'a+b' is only available for DistinctNumeric types with 'Arithmetic'."); return this->m_value + other.m_value; } constexpr Self operator-(Self const& other) const { static_assert(options.arithmetic, "'a-b' is only available for DistinctNumeric types with 'Arithmetic'."); return this->m_value - other.m_value; } constexpr Self operator+() const { static_assert(options.arithmetic, "'+a' is only available for DistinctNumeric types with 'Arithmetic'."); return +this->m_value; } constexpr Self operator-() const { static_assert(options.arithmetic, "'-a' is only available for DistinctNumeric types with 'Arithmetic'."); return -this->m_value; } constexpr Self operator*(Self const& other) const { static_assert(options.arithmetic, "'a*b' is only available for DistinctNumeric types with 'Arithmetic'."); return this->m_value * other.m_value; } constexpr Self operator/(Self const& other) const { static_assert(options.arithmetic, "'a/b' is only available for DistinctNumeric types with 'Arithmetic'."); return this->m_value / other.m_value; } constexpr Self operator%(Self const& other) const { static_assert(options.arithmetic, "'a%b' is only available for DistinctNumeric types with 'Arithmetic'."); return this->m_value % other.m_value; } constexpr Self& operator+=(Self const& other) { static_assert(options.arithmetic, "'a+=b' is only available for DistinctNumeric types with 'Arithmetic'."); this->m_value += other.m_value; return *this; } constexpr Self& operator-=(Self const& other) { static_assert(options.arithmetic, "'a+=b' is only available for DistinctNumeric types with 'Arithmetic'."); this->m_value += other.m_value; return *this; } constexpr Self& operator*=(Self const& other) { static_assert(options.arithmetic, "'a*=b' is only available for DistinctNumeric types with 'Arithmetic'."); this->m_value *= other.m_value; return *this; } constexpr Self& operator/=(Self const& other) { static_assert(options.arithmetic, "'a/=b' is only available for DistinctNumeric types with 'Arithmetic'."); this->m_value /= other.m_value; return *this; } constexpr Self& operator%=(Self const& other) { static_assert(options.arithmetic, "'a%=b' is only available for DistinctNumeric types with 'Arithmetic'."); this->m_value %= other.m_value; return *this; } private: T m_value {}; }; template struct Formatter> : Formatter { ErrorOr format(FormatBuilder& builder, DistinctNumeric value) { return Formatter::format(builder, value.value()); } }; } #define AK_TYPEDEF_DISTINCT_NUMERIC_GENERAL(T, NAME, ...) \ struct NAME##_decl { \ using Arithmetic [[maybe_unused]] = AK::DistinctNumericFeature::Arithmetic; \ using CastToBool [[maybe_unused]] = AK::DistinctNumericFeature::CastToBool; \ using Comparison [[maybe_unused]] = AK::DistinctNumericFeature::Comparison; \ using Flags [[maybe_unused]] = AK::DistinctNumericFeature::Flags; \ using Increment [[maybe_unused]] = AK::DistinctNumericFeature::Increment; \ using Shift [[maybe_unused]] = AK::DistinctNumericFeature::Shift; \ using NAME [[maybe_unused]] = DistinctNumeric; \ }; \ using NAME = typename NAME##_decl::NAME; #define AK_TYPEDEF_DISTINCT_ORDERED_ID(T, NAME) AK_TYPEDEF_DISTINCT_NUMERIC_GENERAL(T, NAME, Comparison, CastToBool) // TODO: Further type aliases? template struct Traits> : public GenericTraits> { static constexpr bool is_trivial() { return true; } static constexpr auto hash(DistinctNumeric const& d) { return Traits::hash(d.value()); } }; using AK::DistinctNumeric;