///\file /****************************************************************************** The MIT License(MIT) Embedded Template Library. https://github.com/ETLCPP/etl https://www.etlcpp.com Copyright(c) 2016 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_IVECTOR_POINTER_INCLUDED #define ETL_IVECTOR_POINTER_INCLUDED #ifndef ETL_IN_VECTOR_H #error This header is a private element of etl::ivector #endif #include "pvoidvector.h" namespace etl { //*************************************************************************** /// The base class for specifically sized vectors. /// Can be used as a reference type for all vectors containing a specific pointer type. ///\ingroup vector //*************************************************************************** template class ivector : public pvoidvector { public: typedef T* value_type; typedef value_type& reference; typedef const value_type& const_reference; typedef value_type* pointer; typedef const value_type* const_pointer; typedef value_type* iterator; typedef const value_type* const_iterator; typedef ETL_OR_STD::reverse_iterator reverse_iterator; typedef ETL_OR_STD::reverse_iterator const_reverse_iterator; typedef size_t size_type; typedef typename etl::iterator_traits::difference_type difference_type; protected: typedef value_type parameter_t; private: typedef pvoidvector base_t; public: //********************************************************************* /// Returns an iterator to the beginning of the vector. ///\return An iterator to the beginning of the vector. //********************************************************************* iterator begin() { return iterator(base_t::begin()); } //********************************************************************* /// Returns a const_iterator to the beginning of the vector. ///\return A const iterator to the beginning of the vector. //********************************************************************* const_iterator begin() const { return const_iterator(base_t::begin()); } //********************************************************************* /// Returns an iterator to the end of the vector. ///\return An iterator to the end of the vector. //********************************************************************* iterator end() { return iterator(base_t::end()); } //********************************************************************* /// Returns a const_iterator to the end of the vector. ///\return A const iterator to the end of the vector. //********************************************************************* const_iterator end() const { return const_iterator(base_t::end()); } //********************************************************************* /// Returns a const_iterator to the beginning of the vector. ///\return A const iterator to the beginning of the vector. //********************************************************************* const_iterator cbegin() const { return const_iterator(base_t::cbegin()); } //********************************************************************* /// Returns a const_iterator to the end of the vector. ///\return A const iterator to the end of the vector. //********************************************************************* const_iterator cend() const { return const_iterator(base_t::cend()); } //********************************************************************* /// Returns an reverse iterator to the reverse beginning of the vector. ///\return Iterator to the reverse beginning of the vector. //********************************************************************* reverse_iterator rbegin() { return reverse_iterator(iterator(base_t::end())); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the vector. ///\return Const iterator to the reverse beginning of the vector. //********************************************************************* const_reverse_iterator rbegin() const { return const_reverse_iterator(const_iterator(base_t::end())); } //********************************************************************* /// Returns a reverse iterator to the end + 1 of the vector. ///\return Reverse iterator to the end + 1 of the vector. //********************************************************************* reverse_iterator rend() { return reverse_iterator(iterator(base_t::begin())); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the vector. ///\return Const reverse iterator to the end + 1 of the vector. //********************************************************************* const_reverse_iterator rend() const { return const_reverse_iterator(const_iterator(base_t::begin())); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the vector. ///\return Const reverse iterator to the reverse beginning of the vector. //********************************************************************* const_reverse_iterator crbegin() const { return const_reverse_iterator(const_iterator(base_t::cend())); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the vector. ///\return Const reverse iterator to the end + 1 of the vector. //********************************************************************* const_reverse_iterator crend() const { return const_reverse_iterator(const_iterator(base_t::cbegin())); } //********************************************************************* /// Resizes the vector. /// If asserts or exceptions are enabled and the new size is larger than the /// maximum then a vector_full is thrown. ///\param new_size The new size. //********************************************************************* void resize(size_t new_size) { base_t::resize(new_size); } //********************************************************************* /// Resizes the vector. /// If asserts or exceptions are enabled and the new size is larger than the /// maximum then a vector_full is thrown. ///\param new_size The new size. ///\param value The value to fill new elements with. Default = default constructed value. //********************************************************************* void resize(size_t new_size, value_type value) { base_t::resize(new_size, value); } //********************************************************************* /// Resizes the vector, but does not initialise new entries. ///\param new_size The new size. //********************************************************************* void uninitialized_resize(size_t new_size) { base_t::uninitialized_resize(new_size); } //********************************************************************* /// Returns a reference to the value at index 'i' ///\param i The index. ///\return A reference to the value at index 'i' //********************************************************************* reference operator [](size_t i) { return reference(base_t::operator[](i)); } //********************************************************************* /// Returns a const reference to the value at index 'i' ///\param i The index. ///\return A const reference to the value at index 'i' //********************************************************************* const_reference operator [](size_t i) const { return const_reference(base_t::operator[](i)); } //********************************************************************* /// Returns a reference to the value at index 'i' /// If asserts or exceptions are enabled, emits an etl::vector_out_of_bounds if the index is out of range. ///\param i The index. ///\return A reference to the value at index 'i' //********************************************************************* reference at(size_t i) { return reference(base_t::at(i)); } //********************************************************************* /// Returns a const reference to the value at index 'i' /// If asserts or exceptions are enabled, emits an etl::vector_out_of_bounds if the index is out of range. ///\param i The index. ///\return A const reference to the value at index 'i' //********************************************************************* const_reference at(size_t i) const { return const_reference(base_t::at(i)); } //********************************************************************* /// Returns a reference to the first element. ///\return A reference to the first element. //********************************************************************* reference front() { return reference(base_t::front()); } //********************************************************************* /// Returns a const reference to the first element. ///\return A const reference to the first element. //********************************************************************* const_reference front() const { return const_reference(base_t::front()); } //********************************************************************* /// Returns a reference to the last element. ///\return A reference to the last element. //********************************************************************* reference back() { return reference(base_t::back()); } //********************************************************************* /// Returns a const reference to the last element. ///\return A const reference to the last element. //********************************************************************* const_reference back() const { return const_reference(base_t::back()); } //********************************************************************* /// Returns a pointer to the beginning of the vector data. ///\return A pointer to the beginning of the vector data. //********************************************************************* pointer data() { return pointer(base_t::data()); } //********************************************************************* /// Returns a const pointer to the beginning of the vector data. ///\return A const pointer to the beginning of the vector data. //********************************************************************* const_pointer data() const { return const_pointer(base_t::data()); } //********************************************************************* /// Assigns values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. /// If asserts or exceptions are enabled, emits vector_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) { base_t::assign(first, last); } //********************************************************************* /// Assigns values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param n The number of elements to add. ///\param value The value to insert for each element. //********************************************************************* void assign(size_t n, parameter_t value) { base_t::assign(n, value); } //************************************************************************* /// Clears the vector. //************************************************************************* void clear() { base_t::clear(); } //********************************************************************* /// Inserts a value at the end of the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param value The value to add. //********************************************************************* void push_back(parameter_t value) { base_t::push_back(value); } //********************************************************************* /// Constructs a value at the end of the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param value The value to add. //********************************************************************* reference emplace_back() { base_t::emplace_back(ETL_NULLPTR); return back(); } //********************************************************************* /// Constructs a value at the end of the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param value The value to add. //********************************************************************* reference emplace_back(parameter_t value) { base_t::emplace_back(value); return back(); } //************************************************************************* /// Removes an element from the end of the vector. /// Does nothing if the vector is empty. //************************************************************************* void pop_back() { base_t::pop_back(); } //********************************************************************* /// Inserts a value to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param position The position to insert before. ///\param value The value to insert. //********************************************************************* iterator insert(const_iterator position, parameter_t value) { return iterator(base_t::insert(base_t::iterator(position), value)); } //************************************************************************* /// Emplaces a value to the vector at the specified position. //************************************************************************* iterator emplace(const_iterator position) { return iterator(base_t::emplace(base_t::iterator(position), ETL_NULLPTR)); } //************************************************************************* /// Emplaces a value to the vector at the specified position. //************************************************************************* iterator emplace(const_iterator position, parameter_t value) { return iterator(base_t::emplace(base_t::iterator(position), value)); } //********************************************************************* /// Inserts 'n' values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param position The position to insert before. ///\param n The number of elements to add. ///\param value The value to insert. //********************************************************************* void insert(const_iterator position, size_t n, parameter_t value) { base_t::insert(base_t::iterator(position), n, value); } //********************************************************************* /// Inserts a range of values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param position The position to insert before. ///\param first The first element to add. ///\param last The last + 1 element to add. //********************************************************************* template void insert(const_iterator position, TIterator first, TIterator last) { base_t::insert(base_t::iterator(position), first, last); } //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(iterator i_element) { return iterator(base_t::erase(base_t::iterator(i_element))); } //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(const_iterator i_element) { return iterator(base_t::erase(base_t::const_iterator(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. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(const_iterator first, const_iterator last) { return iterator(base_t::erase(base_t::const_iterator(first), base_t::const_iterator(last))); } //************************************************************************* /// Assignment operator. //************************************************************************* ivector& operator = (const ivector& rhs) { base_t::operator = (rhs); return *this; } #if ETL_USING_CPP11 //************************************************************************* /// Move assignment operator. //************************************************************************* ivector& operator = (ivector&& rhs) { (void)base_t::operator = (etl::move(rhs)); return *this; } #endif #ifdef ETL_IVECTOR_REPAIR_ENABLE //************************************************************************* /// Fix the internal pointers after a low level memory copy. //************************************************************************* virtual void repair() = 0; #endif protected: //********************************************************************* /// Constructor. //********************************************************************* ivector(T** p_buffer_, size_t MAX_SIZE_) : pvoidvector(reinterpret_cast(p_buffer_), MAX_SIZE_) { } }; template class ivector : public pvoidvector { public: typedef const T* value_type; typedef value_type& reference; typedef const value_type& const_reference; typedef value_type* pointer; typedef const value_type* const_pointer; typedef value_type* iterator; typedef const value_type* const_iterator; typedef ETL_OR_STD::reverse_iterator reverse_iterator; typedef ETL_OR_STD::reverse_iterator const_reverse_iterator; typedef size_t size_type; typedef typename etl::iterator_traits::difference_type difference_type; protected: typedef value_type parameter_t; private: typedef pvoidvector base_t; public: //********************************************************************* /// Returns an iterator to the beginning of the vector. ///\return An iterator to the beginning of the vector. //********************************************************************* iterator begin() { return iterator(base_t::begin()); } //********************************************************************* /// Returns a const_iterator to the beginning of the vector. ///\return A const iterator to the beginning of the vector. //********************************************************************* const_iterator begin() const { return const_iterator(base_t::begin()); } //********************************************************************* /// Returns an iterator to the end of the vector. ///\return An iterator to the end of the vector. //********************************************************************* iterator end() { return iterator(base_t::end()); } //********************************************************************* /// Returns a const_iterator to the end of the vector. ///\return A const iterator to the end of the vector. //********************************************************************* const_iterator end() const { return const_iterator(base_t::end()); } //********************************************************************* /// Returns a const_iterator to the beginning of the vector. ///\return A const iterator to the beginning of the vector. //********************************************************************* const_iterator cbegin() const { return const_iterator(base_t::cbegin()); } //********************************************************************* /// Returns a const_iterator to the end of the vector. ///\return A const iterator to the end of the vector. //********************************************************************* const_iterator cend() const { return const_iterator(base_t::cend()); } //********************************************************************* /// Returns an reverse iterator to the reverse beginning of the vector. ///\return Iterator to the reverse beginning of the vector. //********************************************************************* reverse_iterator rbegin() { return reverse_iterator(iterator(base_t::end())); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the vector. ///\return Const iterator to the reverse beginning of the vector. //********************************************************************* const_reverse_iterator rbegin() const { return const_reverse_iterator(const_iterator(base_t::end())); } //********************************************************************* /// Returns a reverse iterator to the end + 1 of the vector. ///\return Reverse iterator to the end + 1 of the vector. //********************************************************************* reverse_iterator rend() { return reverse_iterator(iterator(base_t::begin())); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the vector. ///\return Const reverse iterator to the end + 1 of the vector. //********************************************************************* const_reverse_iterator rend() const { return const_reverse_iterator(const_iterator(base_t::begin())); } //********************************************************************* /// Returns a const reverse iterator to the reverse beginning of the vector. ///\return Const reverse iterator to the reverse beginning of the vector. //********************************************************************* const_reverse_iterator crbegin() const { return const_reverse_iterator(const_iterator(base_t::cend())); } //********************************************************************* /// Returns a const reverse iterator to the end + 1 of the vector. ///\return Const reverse iterator to the end + 1 of the vector. //********************************************************************* const_reverse_iterator crend() const { return const_reverse_iterator(const_iterator(base_t::cbegin())); } //********************************************************************* /// Resizes the vector. /// If asserts or exceptions are enabled and the new size is larger than the /// maximum then a vector_full is thrown. ///\param new_size The new size. //********************************************************************* void resize(size_t new_size) { base_t::resize(new_size); } //********************************************************************* /// Resizes the vector. /// If asserts or exceptions are enabled and the new size is larger than the /// maximum then a vector_full is thrown. ///\param new_size The new size. ///\param value The value to fill new elements with. Default = default constructed value. //********************************************************************* void resize(size_t new_size, value_type value) { base_t::resize(new_size, const_cast(value)); } //********************************************************************* /// Resizes the vector, but does not initialise new entries. ///\param new_size The new size. //********************************************************************* void uninitialized_resize(size_t new_size) { base_t::uninitialized_resize(new_size); } //********************************************************************* /// Returns a reference to the value at index 'i' ///\param i The index. ///\return A reference to the value at index 'i' //********************************************************************* reference operator [](size_t i) { return reference(base_t::operator[](i)); } //********************************************************************* /// Returns a const reference to the value at index 'i' ///\param i The index. ///\return A const reference to the value at index 'i' //********************************************************************* const_reference operator [](size_t i) const { return const_reference(base_t::operator[](i)); } //********************************************************************* /// Returns a reference to the value at index 'i' /// If asserts or exceptions are enabled, emits an etl::vector_out_of_bounds if the index is out of range. ///\param i The index. ///\return A reference to the value at index 'i' //********************************************************************* reference at(size_t i) { return reference(base_t::at(i)); } //********************************************************************* /// Returns a const reference to the value at index 'i' /// If asserts or exceptions are enabled, emits an etl::vector_out_of_bounds if the index is out of range. ///\param i The index. ///\return A const reference to the value at index 'i' //********************************************************************* const_reference at(size_t i) const { return const_reference(base_t::at(i)); } //********************************************************************* /// Returns a reference to the first element. ///\return A reference to the first element. //********************************************************************* reference front() { return reference(base_t::front()); } //********************************************************************* /// Returns a const reference to the first element. ///\return A const reference to the first element. //********************************************************************* const_reference front() const { return const_reference(base_t::front()); } //********************************************************************* /// Returns a reference to the last element. ///\return A reference to the last element. //********************************************************************* reference back() { return reference(base_t::back()); } //********************************************************************* /// Returns a const reference to the last element. ///\return A const reference to the last element. //********************************************************************* const_reference back() const { return const_reference(base_t::back()); } //********************************************************************* /// Returns a pointer to the beginning of the vector data. ///\return A pointer to the beginning of the vector data. //********************************************************************* pointer data() { return pointer(base_t::data()); } //********************************************************************* /// Returns a const pointer to the beginning of the vector data. ///\return A const pointer to the beginning of the vector data. //********************************************************************* const_pointer data() const { return const_pointer(base_t::data()); } //********************************************************************* /// Assigns values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. /// If asserts or exceptions are enabled, emits vector_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) { base_t::assign(first, last); } //********************************************************************* /// Assigns values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param n The number of elements to add. ///\param value The value to insert for each element. //********************************************************************* void assign(size_t n, parameter_t value) { base_t::assign(n, const_cast(value)); } //************************************************************************* /// Clears the vector. //************************************************************************* void clear() { base_t::clear(); } //********************************************************************* /// Inserts a value at the end of the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param value The value to add. //********************************************************************* void push_back(parameter_t value) { base_t::push_back(const_cast(value)); } //************************************************************************* /// Removes an element from the end of the vector. /// Does nothing if the vector is empty. //************************************************************************* void pop_back() { base_t::pop_back(); } //********************************************************************* /// Inserts a value to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector is already full. ///\param position The position to insert before. ///\param value The value to insert. //********************************************************************* iterator insert(const_iterator position, parameter_t value) { return iterator(base_t::insert(base_t::iterator(position), const_cast(value))); } //********************************************************************* /// Inserts 'n' values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param position The position to insert before. ///\param n The number of elements to add. ///\param value The value to insert. //********************************************************************* void insert(const_iterator position, size_t n, parameter_t value) { base_t::insert(base_t::iterator(position), n, const_cast(value)); } //********************************************************************* /// Inserts a range of values to the vector. /// If asserts or exceptions are enabled, emits vector_full if the vector does not have enough free space. ///\param position The position to insert before. ///\param first The first element to add. ///\param last The last + 1 element to add. //********************************************************************* template void insert(const_iterator position, TIterator first, TIterator last) { base_t::insert(base_t::iterator(position), first, last); } //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(iterator i_element) { return iterator(base_t::erase(base_t::iterator(i_element))); } //********************************************************************* /// Erases an element. ///\param i_element Iterator to the element. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(const_iterator i_element) { return iterator(base_t::erase(base_t::iterator(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. ///\return An iterator pointing to the element that followed the erased element. //********************************************************************* iterator erase(const_iterator first, const_iterator last) { return iterator(base_t::erase(base_t::iterator(first), base_t::iterator(last))); } //************************************************************************* /// Assignment operator. //************************************************************************* ivector& operator = (const ivector& rhs) { base_t::operator = (rhs); return *this; } #if ETL_USING_CPP11 //************************************************************************* /// Move assignment operator. //************************************************************************* ivector& operator = (ivector&& rhs) { (void)base_t::operator = (etl::move(rhs)); return *this; } #endif #ifdef ETL_IVECTOR_REPAIR_ENABLE //************************************************************************* /// Fix the internal pointers after a low level memory copy. //************************************************************************* virtual void repair() = 0; #endif protected: //********************************************************************* /// Constructor. //********************************************************************* ivector(const T** p_buffer_, size_t MAX_SIZE_) : pvoidvector(reinterpret_cast(const_cast(p_buffer_)), MAX_SIZE_) { } }; //*************************************************************************** /// Equal operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the arrays are equal, otherwise false ///\ingroup vector //*************************************************************************** template bool operator ==(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_equal(lhs, rhs); } //*************************************************************************** /// Not equal operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the arrays are not equal, otherwise false ///\ingroup vector //*************************************************************************** template bool operator !=(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_not_equal(lhs, rhs); } //*************************************************************************** /// Less than operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the first vector is lexicographically less than the second, otherwise false ///\ingroup vector //*************************************************************************** template bool operator <(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_less_than(lhs, rhs); } //*************************************************************************** /// Greater than operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the first vector is lexicographically greater than the second, otherwise false ///\ingroup vector //*************************************************************************** template bool operator >(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_greater_than(lhs, rhs); } //*************************************************************************** /// Less than or equal operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the first vector is lexicographically less than or equal to the second, otherwise false ///\ingroup vector //*************************************************************************** template bool operator <=(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_less_than_equal(lhs, rhs); } //*************************************************************************** /// Greater than or equal operator. ///\param lhs Reference to the first vector. ///\param rhs Reference to the second vector. ///\return true if the first vector is lexicographically greater than or equal to the second, otherwise false ///\ingroup vector //*************************************************************************** template bool operator >=(const etl::ivector& lhs, const etl::ivector& rhs) { return pvoidvector_greater_than_equal(lhs, rhs); } //*************************************************************************** // Helper functions //*************************************************************************** inline bool pvoidvector_equal(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator ==(lhs, rhs); } inline bool pvoidvector_not_equal(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator !=(lhs, rhs); } inline bool pvoidvector_less_than(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator <(lhs, rhs); } inline bool pvoidvector_greater_than(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator >(lhs, rhs); } inline bool pvoidvector_less_than_equal(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator <=(lhs, rhs); } inline bool pvoidvector_greater_than_equal(const etl::pvoidvector& lhs, const etl::pvoidvector& rhs) { return operator >=(lhs, rhs); } } #endif