///\file /****************************************************************************** The MIT License(MIT) Embedded Template Library. https://github.com/ETLCPP/etl https://www.etlcpp.com Copyright(c) 2015 John Wellbelove Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files(the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and / or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions : The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ******************************************************************************/ #ifndef ETL_FLAT_SET_INCLUDED #define ETL_FLAT_SET_INCLUDED #include "platform.h" #include "reference_flat_set.h" #include "pool.h" #include "placement_new.h" #include "nth_type.h" #include "type_traits.h" #include "initializer_list.h" #include "private/comparator_is_transparent.h" //***************************************************************************** ///\defgroup flat_set flat_set /// A flat_set with the capacity defined at compile time. /// Has insertion of O(N) and find of O(logN) /// Duplicate entries and not allowed. ///\ingroup containers //***************************************************************************** namespace etl { //*************************************************************************** /// The base class for specifically sized flat_sets. /// Can be used as a reference type for all flat_sets containing a specific type. ///\ingroup flat_set //*************************************************************************** template > class iflat_set : private etl::ireference_flat_set { private: typedef etl::ireference_flat_set refset_t; typedef typename refset_t::lookup_t lookup_t; typedef etl::ipool storage_t; typedef const T& key_parameter_t; public: typedef T key_type; typedef T value_type; typedef TKeyCompare key_compare; typedef value_type& reference; typedef const value_type& const_reference; #if ETL_USING_CPP11 typedef value_type&& rvalue_reference; #endif typedef value_type* pointer; typedef const value_type* const_pointer; typedef size_t size_type; typedef typename refset_t::iterator iterator; typedef typename refset_t::const_iterator const_iterator; typedef ETL_OR_STD::reverse_iterator reverse_iterator; typedef ETL_OR_STD::reverse_iterator const_reverse_iterator; typedef typename etl::iterator_traits::difference_type difference_type; public: //********************************************************************* /// Returns an iterator to the beginning of the flat_set. ///\return An iterator to the beginning of the flat_set. //********************************************************************* iterator begin() { return refset_t::begin(); } //********************************************************************* /// Returns a const_iterator to the beginning of the flat_set. ///\return A const iterator to the beginning of the flat_set. //********************************************************************* const_iterator begin() const { return refset_t::begin(); } //********************************************************************* /// Returns an iterator to the end of the flat_set. ///\return An iterator to the end of the flat_set. //********************************************************************* iterator end() { return refset_t::end(); } //********************************************************************* /// Returns a const_iterator to the end of the flat_set. ///\return A const iterator to the end of the flat_set. //********************************************************************* const_iterator end() const { return refset_t::end(); } //********************************************************************* /// Returns a const_iterator to the beginning of the flat_set. ///\return A const iterator to the beginning of the flat_set. //********************************************************************* const_iterator cbegin() const { return refset_t::cbegin(); } //********************************************************************* /// Returns a const_iterator to the end of the flat_set. ///\return A const iterator to the end of the flat_set. //********************************************************************* const_iterator cend() const { return refset_t::cend(); } //********************************************************************* /// Returns an reverse iterator to the reverse beginning of the flat_set. ///\return Iterator to the reverse beginning of the flat_set. //********************************************************************* reverse_iterator rbegin() { return refset_t::rbegin(); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the flat_set. ///\return Const iterator to the reverse beginning of the flat_set. //********************************************************************* const_reverse_iterator rbegin() const { return refset_t::rbegin(); } //********************************************************************* /// Returns a reverse iterator to the end + 1 of the flat_set. ///\return Reverse iterator to the end + 1 of the flat_set. //********************************************************************* reverse_iterator rend() { return refset_t::rend(); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the flat_set. ///\return Const reverse iterator to the end + 1 of the flat_set. //********************************************************************* const_reverse_iterator rend() const { return refset_t::rend(); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the flat_set. ///\return Const reverse iterator to the reverse beginning of the flat_set. //********************************************************************* const_reverse_iterator crbegin() const { return refset_t::crbegin(); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the flat_set. ///\return Const reverse iterator to the end + 1 of the flat_set. //********************************************************************* const_reverse_iterator crend() const { return refset_t::crend(); } //********************************************************************* /// Assigns values to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set does not have enough free space. /// If asserts or exceptions are enabled, emits flat_set_iterator if the iterators are reversed. ///\param first The iterator to the first element. ///\param last The iterator to the last element + 1. //********************************************************************* template void assign(TIterator first, TIterator last) { #if ETL_IS_DEBUG_BUILD difference_type d = etl::distance(first, last); ETL_ASSERT(d <= difference_type(capacity()), ETL_ERROR(flat_set_full)); #endif clear(); while (first != last) { insert(*first); ++first; } } //********************************************************************* /// Inserts a value to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set is already full. ///\param value The value to insert. //********************************************************************* ETL_OR_STD::pair insert(const_reference value) { iterator i_element = lower_bound(value); ETL_OR_STD::pair result(i_element, false); // Doesn't already exist? if ((i_element == end()) || compare(value, *i_element)) { ETL_ASSERT(!refset_t::full(), ETL_ERROR(flat_set_full)); value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(value); ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } return result; } #if ETL_USING_CPP11 //********************************************************************* /// Inserts a value to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set is already full. ///\param value The value to insert. //********************************************************************* ETL_OR_STD::pair insert(rvalue_reference value) { iterator i_element = lower_bound(value); ETL_OR_STD::pair result(i_element, false); // Doesn't already exist? if ((i_element == end()) || compare(value, *i_element)) { ETL_ASSERT(!refset_t::full(), ETL_ERROR(flat_set_full)); value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(etl::move(value)); ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } return result; } #endif //********************************************************************* /// Inserts a value to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set is already full. ///\param position The position to insert at. ///\param value The value to insert. //********************************************************************* iterator insert(const_iterator /*position*/, const_reference value) { return insert(value).first; } #if ETL_USING_CPP11 //********************************************************************* /// Inserts a value to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set is already full. ///\param position The position to insert at. ///\param value The value to insert. //********************************************************************* iterator insert(const_iterator /*position*/, rvalue_reference value) { return insert(etl::move(value)).first; } #endif //********************************************************************* /// Inserts a range of values to the flat_set. /// If asserts or exceptions are enabled, emits flat_set_full if the flat_set does not have enough free space. ///\param position The position to insert at. ///\param first The first element to add. ///\param last The last + 1 element to add. //********************************************************************* template void insert(TIterator first, TIterator last) { while (first != last) { insert(*first); ++first; } } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* ETL_OR_STD::pair emplace(const_reference value) { return insert(value); } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* #if ETL_USING_CPP11 && ETL_NOT_USING_STLPORT && !defined(ETL_FLAT_SET_FORCE_CPP03_IMPLEMENTATION) template ETL_OR_STD::pair emplace(Args && ... args) { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(etl::forward(args)...); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } #else //************************************************************************* /// Emplaces a value to the set. //************************************************************************* ETL_OR_STD::pair emplace() { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* template ETL_OR_STD::pair emplace(const T1& value1) { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(value1); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* template ETL_OR_STD::pair emplace(const T1& value1, const T2& value2) { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(value1, value2); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* template ETL_OR_STD::pair emplace(const T1& value1, const T2& value2, const T3& value3) { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(value1, value2, value3); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } //************************************************************************* /// Emplaces a value to the set. //************************************************************************* template ETL_OR_STD::pair emplace(const T1& value1, const T2& value2, const T3& value3, const T4& value4) { ETL_ASSERT(!full(), ETL_ERROR(flat_set_full)); ETL_OR_STD::pair result; // Create it. value_type* pvalue = storage.allocate(); ::new (pvalue) value_type(value1, value2, value3, value4); iterator i_element = lower_bound(*pvalue); // Doesn't already exist? if ((i_element == end()) || compare(*pvalue, *i_element)) { ETL_INCREMENT_DEBUG_COUNT; result = refset_t::insert_at(i_element, *pvalue); } else { // Destroy it. pvalue->~value_type(); storage.release(pvalue); result = ETL_OR_STD::pair(end(), false); } return result; } #endif //********************************************************************* /// Erases an element. ///\param key The key to erase. ///\return The number of elements erased. 0 or 1. //********************************************************************* size_t erase(key_parameter_t key) { iterator i_element = find(key); if (i_element == end()) { return 0; } else { etl::destroy_at(etl::addressof(*i_element)); storage.release(etl::addressof(*i_element)); refset_t::erase(i_element); ETL_DECREMENT_DEBUG_COUNT; return 1; } } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> size_t erase(K&& key) { iterator i_element = find(etl::forward(key)); if (i_element == end()) { return 0; } else { etl::destroy_at(etl::addressof(*i_element)); storage.release(etl::addressof(*i_element)); refset_t::erase(i_element); ETL_DECREMENT_DEBUG_COUNT; return 1; } } #endif //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. //********************************************************************* iterator erase(iterator i_element) { etl::destroy_at(etl::addressof(*i_element)); storage.release(etl::addressof(*i_element)); ETL_DECREMENT_DEBUG_COUNT; return refset_t::erase(i_element); } //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. //********************************************************************* iterator erase(const_iterator i_element) { etl::destroy_at(etl::addressof(*i_element)); storage.release(etl::addressof(*i_element)); ETL_DECREMENT_DEBUG_COUNT; return refset_t::erase(i_element); } //********************************************************************* /// Erases a range of elements. /// The range includes all the elements between first and last, including the /// element pointed by first, but not the one pointed by last. ///\param first Iterator to the first element. ///\param last Iterator to the last element. //********************************************************************* iterator erase(const_iterator first, const_iterator last) { const_iterator itr = first; while (itr != last) { etl::destroy_at(etl::addressof(*itr)); storage.release(etl::addressof(*itr)); ++itr; ETL_DECREMENT_DEBUG_COUNT; } return refset_t::erase(first, last); } //************************************************************************* /// Clears the flat_set. //************************************************************************* void clear() { if ETL_IF_CONSTEXPR(etl::is_trivially_destructible::value) { storage.release_all(); } else { iterator itr = begin(); while (itr != end()) { etl::destroy_at(etl::addressof(*itr)); storage.release(etl::addressof(*itr)); ++itr; ETL_DECREMENT_DEBUG_COUNT; } } ETL_RESET_DEBUG_COUNT; refset_t::clear(); } //********************************************************************* /// Finds an element. ///\param key The key to search for. ///\return An iterator pointing to the element or end() if not found. //********************************************************************* iterator find(key_parameter_t key) { return refset_t::find(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> iterator find(const K& key) { return refset_t::find(key); } #endif //********************************************************************* /// Finds an element. ///\param key The key to search for. ///\return An iterator pointing to the element or end() if not found. //********************************************************************* const_iterator find(key_parameter_t key) const { return refset_t::find(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> const_iterator find(const K& key) const { return refset_t::find(key); } #endif //********************************************************************* /// Counts an element. ///\param key The key to search for. ///\return 1 if the key exists, otherwise 0. //********************************************************************* size_t count(key_parameter_t key) const { return refset_t::count(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> size_t count(const K& key) const { return refset_t::count(key); } #endif //********************************************************************* /// Finds the lower bound of a key ///\param key The key to search for. ///\return An iterator. //********************************************************************* iterator lower_bound(key_parameter_t key) { return refset_t::lower_bound(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> iterator lower_bound(const K& key) { return refset_t::lower_bound(key); } #endif //********************************************************************* /// Finds the lower bound of a key ///\param key The key to search for. ///\return An iterator. //********************************************************************* const_iterator lower_bound(key_parameter_t key) const { return refset_t::lower_bound(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> const_iterator lower_bound(const K& key) const { return refset_t::lower_bound(key); } #endif //********************************************************************* /// Finds the upper bound of a key ///\param key The key to search for. ///\return An iterator. //********************************************************************* iterator upper_bound(key_parameter_t key) { return refset_t::upper_bound(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> iterator upper_bound(const K& key) { return refset_t::upper_bound(key); } #endif //********************************************************************* /// Finds the upper bound of a key ///\param key The key to search for. ///\return An iterator. //********************************************************************* const_iterator upper_bound(key_parameter_t key) const { return refset_t::upper_bound(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> const_iterator upper_bound(const K& key) const { return refset_t::upper_bound(key); } #endif //********************************************************************* /// Finds the range of equal elements of a key ///\param key The key to search for. ///\return An iterator pair. //********************************************************************* ETL_OR_STD::pair equal_range(key_parameter_t key) { return refset_t::equal_range(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> ETL_OR_STD::pair equal_range(const K& key) { return refset_t::equal_range(key); } #endif //********************************************************************* /// Finds the range of equal elements of a key ///\param key The key to search for. ///\return An iterator pair. //********************************************************************* ETL_OR_STD::pair equal_range(key_parameter_t key) const { return refset_t::upper_bound(key); } #if ETL_USING_CPP11 //********************************************************************* template ::value, int> = 0> ETL_OR_STD::pair equal_range(const K& key) const { return refset_t::upper_bound(key); } #endif //************************************************************************* /// Check if the map contains the key. //************************************************************************* bool contains(key_parameter_t key) const { return find(key) != end(); } #if ETL_USING_CPP11 //************************************************************************* template ::value, int> = 0> bool contains(const K& k) const { return find(k) != end(); } #endif //************************************************************************* /// Assignment operator. //************************************************************************* iflat_set& operator = (const iflat_set& rhs) { if (&rhs != this) { assign(rhs.cbegin(), rhs.cend()); } return *this; } #if ETL_USING_CPP11 //************************************************************************* /// Move assignment operator. //************************************************************************* iflat_set& operator = (iflat_set&& rhs) { move_container(etl::move(rhs)); return *this; } #endif //************************************************************************* /// Gets the current size of the flat_set. ///\return The current size of the flat_set. //************************************************************************* size_type size() const { return refset_t::size(); } //************************************************************************* /// Checks the 'empty' state of the flat_set. ///\return true if empty. //************************************************************************* bool empty() const { return refset_t::empty(); } //************************************************************************* /// Checks the 'full' state of the flat_set. ///\return true if full. //************************************************************************* bool full() const { return refset_t::full(); } //************************************************************************* /// Returns the capacity of the flat_set. ///\return The capacity of the flat_set. //************************************************************************* size_type capacity() const { return refset_t::capacity(); } //************************************************************************* /// Returns the maximum possible size of the flat_set. ///\return The maximum size of the flat_set. //************************************************************************* size_type max_size() const { return refset_t::max_size(); } //************************************************************************* /// Returns the remaining capacity. ///\return The remaining capacity. //************************************************************************* size_t available() const { return refset_t::available(); } protected: //********************************************************************* /// Constructor. //********************************************************************* iflat_set(lookup_t& lookup_, storage_t& storage_) : refset_t(lookup_), storage(storage_) { } #if ETL_USING_CPP11 //************************************************************************* /// Move a flat_set. /// Assumes the flat_set is initialised and empty. //************************************************************************* void move_container(iflat_set&& rhs) { if (&rhs != this) { this->clear(); etl::iflat_set::iterator first = rhs.begin(); etl::iflat_set::iterator last = rhs.end(); // Move all of the elements. while (first != last) { typename etl::iflat_set::iterator temp = first; ++temp; this->insert(etl::move(*first)); first = temp; } } } #endif private: // Disable copy construction. iflat_set(const iflat_set&); storage_t& storage; TKeyCompare compare; /// Internal debugging. ETL_DECLARE_DEBUG_COUNT; //************************************************************************* /// Destructor. //************************************************************************* #if defined(ETL_POLYMORPHIC_FLAT_SET) || defined(ETL_POLYMORPHIC_CONTAINERS) public: virtual ~iflat_set() { } #else protected: ~iflat_set() { } #endif }; //*************************************************************************** /// Equal operator. ///\param lhs Reference to the first flat_set. ///\param rhs Reference to the second flat_set. ///\return true if the arrays are equal, otherwise false ///\ingroup flat_set //*************************************************************************** template bool operator ==(const etl::iflat_set& lhs, const etl::iflat_set& rhs) { return (lhs.size() == rhs.size()) && etl::equal(lhs.begin(), lhs.end(), rhs.begin()); } //*************************************************************************** /// Not equal operator. ///\param lhs Reference to the first flat_set. ///\param rhs Reference to the second flat_set. ///\return true if the arrays are not equal, otherwise false ///\ingroup flat_set //*************************************************************************** template bool operator !=(const etl::iflat_set& lhs, const etl::iflat_set& rhs) { return !(lhs == rhs); } //*************************************************************************** /// A flat_set implementation that uses a fixed size buffer. ///\tparam T The value type. ///\tparam TCompare The type to compare keys. Default = etl::less ///\tparam MAX_SIZE_ The maximum number of elements that can be stored. ///\ingroup flat_set //*************************************************************************** template > class flat_set : public etl::iflat_set { public: static ETL_CONSTANT size_t MAX_SIZE = MAX_SIZE_; //************************************************************************* /// Constructor. //************************************************************************* flat_set() : etl::iflat_set(lookup, storage) { } //************************************************************************* /// Copy constructor. //************************************************************************* flat_set(const flat_set& other) : etl::iflat_set(lookup, storage) { this->assign(other.cbegin(), other.cend()); } #if ETL_USING_CPP11 //************************************************************************* /// Move constructor. //************************************************************************* flat_set(flat_set&& other) : etl::iflat_set(lookup, storage) { if (&other != this) { this->move_container(etl::move(other)); } } #endif //************************************************************************* /// Constructor, from an iterator range. ///\tparam TIterator The iterator type. ///\param first The iterator to the first element. ///\param last The iterator to the last element + 1. //************************************************************************* template flat_set(TIterator first, TIterator last) : etl::iflat_set(lookup, storage) { this->assign(first, last); } #if ETL_HAS_INITIALIZER_LIST //************************************************************************* /// Construct from initializer_list. //************************************************************************* flat_set(std::initializer_list init) : etl::iflat_set(lookup, storage) { this->assign(init.begin(), init.end()); } #endif //************************************************************************* /// Destructor. //************************************************************************* ~flat_set() { this->clear(); } //************************************************************************* /// Assignment operator. //************************************************************************* flat_set& operator = (const flat_set& rhs) { if (&rhs != this) { this->assign(rhs.cbegin(), rhs.cend()); } return *this; } #if ETL_USING_CPP11 //************************************************************************* /// Move assignment operator. //************************************************************************* flat_set& operator = (flat_set&& rhs) { if (&rhs != this) { this->move_container(etl::move(rhs)); } return *this; } #endif private: typedef typename etl::iflat_set::value_type node_t; // The pool of nodes. etl::pool storage; // The vector that stores pointers to the nodes. etl::vector lookup; }; template ETL_CONSTANT size_t flat_set::MAX_SIZE; //************************************************************************* /// Template deduction guides. //************************************************************************* #if ETL_USING_CPP17 && ETL_HAS_INITIALIZER_LIST template flat_set(T...) -> flat_set, sizeof...(T)>; #endif //************************************************************************* /// Make //************************************************************************* #if ETL_USING_CPP11 && ETL_HAS_INITIALIZER_LIST template , typename... T> constexpr auto make_flat_set(T&&... keys) -> etl::flat_set { return { etl::forward(keys)... }; } #endif } #endif