/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* A class holding a pair of objects that tries to conserve storage space. */ #ifndef mozilla_CompactPair_h #define mozilla_CompactPair_h #include #include #include #include "mozilla/Attributes.h" namespace mozilla { namespace detail { enum StorageType { AsBase, AsMember }; // Optimize storage using the Empty Base Optimization -- that empty base classes // don't take up space -- to optimize size when one or the other class is // stateless and can be used as a base class. // // The extra conditions on storage for B are necessary so that CompactPairHelper // won't ambiguously inherit from either A or B, such that one or the other base // class would be inaccessible. template ? detail::AsBase : detail::AsMember, detail::StorageType = std::is_empty_v && !std::is_base_of::value && !std::is_base_of::value ? detail::AsBase : detail::AsMember> struct CompactPairHelper; template struct CompactPairHelper { protected: template CompactPairHelper(std::tuple& aATuple, std::tuple& aBTuple, std::index_sequence, std::index_sequence) : mFirstA(std::forward(std::get(aATuple))...), mSecondB(std::forward(std::get(aBTuple))...) {} public: template CompactPairHelper(AArg&& aA, BArg&& aB) : mFirstA(std::forward(aA)), mSecondB(std::forward(aB)) {} A& first() { return mFirstA; } const A& first() const { return mFirstA; } B& second() { return mSecondB; } const B& second() const { return mSecondB; } void swap(CompactPairHelper& aOther) { std::swap(mFirstA, aOther.mFirstA); std::swap(mSecondB, aOther.mSecondB); } private: A mFirstA; B mSecondB; }; template struct CompactPairHelper : private B { protected: template CompactPairHelper(std::tuple& aATuple, std::tuple& aBTuple, std::index_sequence, std::index_sequence) : B(std::forward(std::get(aBTuple))...), mFirstA(std::forward(std::get(aATuple))...) {} public: template CompactPairHelper(AArg&& aA, BArg&& aB) : B(std::forward(aB)), mFirstA(std::forward(aA)) {} A& first() { return mFirstA; } const A& first() const { return mFirstA; } B& second() { return *this; } const B& second() const { return *this; } void swap(CompactPairHelper& aOther) { std::swap(mFirstA, aOther.mFirstA); std::swap(static_cast(*this), static_cast(aOther)); } private: A mFirstA; }; template struct CompactPairHelper : private A { protected: template CompactPairHelper(std::tuple& aATuple, std::tuple& aBTuple, std::index_sequence, std::index_sequence) : A(std::forward(std::get(aATuple))...), mSecondB(std::forward(std::get(aBTuple))...) {} public: template CompactPairHelper(AArg&& aA, BArg&& aB) : A(std::forward(aA)), mSecondB(std::forward(aB)) {} A& first() { return *this; } const A& first() const { return *this; } B& second() { return mSecondB; } const B& second() const { return mSecondB; } void swap(CompactPairHelper& aOther) { std::swap(static_cast(*this), static_cast(aOther)); std::swap(mSecondB, aOther.mSecondB); } private: B mSecondB; }; template struct CompactPairHelper : private A, private B { protected: template CompactPairHelper(std::tuple& aATuple, std::tuple& aBTuple, std::index_sequence, std::index_sequence) : A(std::forward(std::get(aATuple))...), B(std::forward(std::get(aBTuple))...) {} public: template CompactPairHelper(AArg&& aA, BArg&& aB) : A(std::forward(aA)), B(std::forward(aB)) {} A& first() { return static_cast(*this); } const A& first() const { return static_cast(*this); } B& second() { return static_cast(*this); } const B& second() const { return static_cast(*this); } void swap(CompactPairHelper& aOther) { std::swap(static_cast(*this), static_cast(aOther)); std::swap(static_cast(*this), static_cast(aOther)); } }; } // namespace detail /** * CompactPair is the logical concatenation of an instance of A with an instance * B. Space is conserved when possible. Neither A nor B may be a final class. * * In general if space conservation is not critical is preferred to use * std::pair. * * It's typically clearer to have individual A and B member fields. Except if * you want the space-conserving qualities of CompactPair, you're probably * better off not using this! * * No guarantees are provided about the memory layout of A and B, the order of * initialization or destruction of A and B, and so on. (This is approximately * required to optimize space usage.) The first/second names are merely * conceptual! */ template struct CompactPair : private detail::CompactPairHelper { typedef typename detail::CompactPairHelper Base; using Base::Base; template CompactPair(std::piecewise_construct_t, std::tuple aFirst, std::tuple aSecond) : Base(aFirst, aSecond, std::index_sequence_for(), std::index_sequence_for()) {} CompactPair(CompactPair&& aOther) = default; CompactPair(const CompactPair& aOther) = default; CompactPair& operator=(CompactPair&& aOther) = default; CompactPair& operator=(const CompactPair& aOther) = default; /** The A instance. */ using Base::first; /** The B instance. */ using Base::second; /** Swap this pair with another pair. */ void swap(CompactPair& aOther) { Base::swap(aOther); } }; /** * MakeCompactPair allows you to construct a CompactPair instance using type * inference. A call like this: * * MakeCompactPair(Foo(), Bar()) * * will return a CompactPair. */ template CompactPair>, std::remove_cv_t>> MakeCompactPair(A&& aA, B&& aB) { return CompactPair>, std::remove_cv_t>>( std::forward(aA), std::forward(aB)); } /** * CompactPair equality comparison */ template bool operator==(const CompactPair& aLhs, const CompactPair& aRhs) { return aLhs.first() == aRhs.first() && aLhs.second() == aRhs.second(); } } // namespace mozilla namespace std { template void swap(mozilla::CompactPair& aX, mozilla::CompactPair& aY) { aX.swap(aY); } } // namespace std #endif /* mozilla_CompactPair_h */