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///\file
/******************************************************************************
The MIT License(MIT)
Embedded Template Library.
https://github.com/ETLCPP/etl
https://www.etlcpp.com
Documentation: https://www.etlcpp.com/algorithm.html
Copyright(c) 2014 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_ALGORITHM_INCLUDED
#define ETL_ALGORITHM_INCLUDED
///\defgroup algorithm algorithm
/// Including reverse engineered algorithms from C++ 0x11, 0x14, 0x17
/// Additional new variants of certain algorithms.
///\ingroup utilities
#include "platform.h"
#include "type_traits.h"
#include "iterator.h"
#include "functional.h"
#include "utility.h"
#include "gcd.h"
#include <stdint.h>
#include <string.h>
#include "private/minmax_push.h"
#if ETL_USING_STL
#include <algorithm>
#include <utility>
#include <iterator>
#include <functional>
#include <numeric>
#endif
namespace etl
{
// Declare prototypes of the ETL's sort functions
template <typename TIterator>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
void shell_sort(TIterator first, TIterator last);
template <typename TIterator, typename TCompare>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
void shell_sort(TIterator first, TIterator last, TCompare compare);
template <typename TIterator>
ETL_CONSTEXPR14 void insertion_sort(TIterator first, TIterator last);
template <typename TIterator, typename TCompare>
ETL_CONSTEXPR14 void insertion_sort(TIterator first, TIterator last, TCompare compare);
}
//*****************************************************************************
// Algorithms defined by the ETL
//*****************************************************************************
namespace etl
{
namespace private_algorithm
{
template <bool use_swap>
struct swap_impl;
// Generic swap
template <>
struct swap_impl<false>
{
template <typename TIterator1, typename TIterator2>
static void do_swap(TIterator1 a, TIterator2 b)
{
typename etl::iterator_traits<TIterator1>::value_type tmp = *a;
*a = *b;
*b = tmp;
}
};
// Specialised swap
template <>
struct swap_impl<true>
{
template <typename TIterator1, typename TIterator2>
static void do_swap(TIterator1 a, TIterator2 b)
{
using ETL_OR_STD::swap; // Allow ADL
swap(*a, *b);
}
};
}
//***************************************************************************
// iter_swap
//***************************************************************************
template <typename TIterator1, typename TIterator2>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
void iter_swap(TIterator1 a, TIterator2 b)
{
typedef etl::iterator_traits<TIterator1> traits1;
typedef etl::iterator_traits<TIterator2> traits2;
typedef typename traits1::value_type v1;
typedef typename traits2::value_type v2;
typedef typename traits1::reference r1;
typedef typename traits2::reference r2;
const bool use_swap = etl::is_same<v1, v2>::value &&
etl::is_reference<r1>::value &&
etl::is_reference<r2>::value;
private_algorithm::swap_impl<use_swap>::do_swap(a, b);
}
//***************************************************************************
// swap_ranges
//***************************************************************************
template <typename TIterator1, typename TIterator2>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
TIterator2 swap_ranges(TIterator1 first1,
TIterator1 last1,
TIterator2 first2)
{
while (first1 != last1)
{
iter_swap(first1, first2);
++first1;
++first2;
}
return first2;
}
//***************************************************************************
// generate
template <typename TIterator, typename TFunction>
ETL_CONSTEXPR14
void generate(TIterator db, TIterator de, TFunction funct)
{
while (db != de)
{
*db++ = funct();
}
}
//***************************************************************************
// copy
#if ETL_USING_STL && ETL_USING_CPP20
// Use the STL constexpr implementation.
template <typename TIterator1, typename TIterator2>
constexpr TIterator2 copy(TIterator1 sb, TIterator1 se, TIterator2 db)
{
return std::copy(sb, se, db);
}
#else
// Non-pointer or not trivially copyable or not using builtin memcpy.
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 copy(TIterator1 sb, TIterator1 se, TIterator2 db)
{
while (sb != se)
{
*db = *sb;
++db;
++sb;
}
return db;
}
#endif
//***************************************************************************
// reverse_copy
#if ETL_USING_STL && ETL_USING_CPP20
template <typename TIterator1, typename TIterator2>
constexpr TIterator2 reverse_copy(TIterator1 sb, TIterator1 se, TIterator2 db)
{
return std::reverse_copy(sb, se, db);
}
#else
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14
TIterator2 reverse_copy(TIterator1 sb, TIterator1 se, TIterator2 db)
{
while (sb != se)
{
*db = *--se;
++db;
}
return db;
}
#endif
//***************************************************************************
// copy_n
#if ETL_USING_STL && ETL_USING_CPP20
// Use the STL implementation
template <typename TIterator1, typename TSize, typename TIterator2>
constexpr TIterator2 copy_n(TIterator1 sb, TSize count, TIterator2 db)
{
return std::copy_n(sb, count, db);
}
#else
// Non-pointer or not trivially copyable or not using builtin memcpy.
template <typename TIterator1, typename TSize, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 copy_n(TIterator1 sb, TSize count, TIterator2 db)
{
while (count != 0)
{
*db = *sb;
++db;
++sb;
--count;
}
return db;
}
#endif
//***************************************************************************
// copy_backward
#if ETL_USING_STL && ETL_USING_CPP20
template <typename TIterator1, typename TIterator2>
constexpr TIterator2 copy_backward(TIterator1 sb, TIterator1 se, TIterator2 de)
{
return std::copy_backward(sb, se, de);
}
#else
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 copy_backward(TIterator1 sb, TIterator1 se, TIterator2 de)
{
while (se != sb)
{
*(--de) = *(--se);
}
return de;
}
#endif
//***************************************************************************
// move
#if ETL_USING_STL && ETL_USING_CPP20
template <typename TIterator1, typename TIterator2>
constexpr TIterator2 move(TIterator1 sb, TIterator1 se, TIterator2 db)
{
return std::move(sb, se, db);
}
#elif ETL_USING_CPP11
// For C++11
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 move(TIterator1 sb, TIterator1 se, TIterator2 db)
{
while (sb != se)
{
*db = etl::move(*sb);
++db;
++sb;
}
return db;
}
#else
// For C++03
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 move(TIterator1 sb, TIterator1 se, TIterator2 db)
{
return copy(sb, se, db);
}
#endif
//***************************************************************************
// move_backward
#if ETL_USING_STL && ETL_USING_CPP20
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR20 TIterator2 move_backward(TIterator1 sb, TIterator1 se, TIterator2 de)
{
return std::move_backward(sb, se, de);
}
#elif ETL_USING_CPP11
// For C++11
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 move_backward(TIterator1 sb, TIterator1 se, TIterator2 de)
{
while (sb != se)
{
*(--de) = etl::move(*(--se));
}
return de;
}
#else
// For C++03
template <typename TIterator1, typename TIterator2>
ETL_CONSTEXPR14 TIterator2 move_backward(TIterator1 sb, TIterator1 se, TIterator2 de)
{
return etl::copy_backward(sb, se, de);
}
#endif
//***************************************************************************
// reverse
//***************************************************************************
// Pointers
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_pointer<TIterator>::value, void>::type
reverse(TIterator b, TIterator e)
{
if (b != e)
{
while (b < --e)
{
etl::iter_swap(b, e);
++b;
}
}
}
// Non-pointers
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<!etl::is_pointer<TIterator>::value, void>::type
reverse(TIterator b, TIterator e)
{
while ((b != e) && (b != --e))
{
etl::iter_swap(b++, e);
}
}
//***************************************************************************
// lower_bound
//***************************************************************************
template<typename TIterator, typename TValue, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator lower_bound(TIterator first, TIterator last, const TValue& value, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::difference_type difference_t;
difference_t count = etl::distance(first, last);
while (count > 0)
{
TIterator itr = first;
difference_t step = count / 2;
etl::advance(itr, step);
if (compare(*itr, value))
{
first = ++itr;
count -= step + 1;
}
else
{
count = step;
}
}
return first;
}
template<typename TIterator, typename TValue>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator lower_bound(TIterator first, TIterator last, const TValue& value)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
return etl::lower_bound(first, last, value, compare());
}
//***************************************************************************
// upper_bound
//***************************************************************************
template<typename TIterator, typename TValue, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator upper_bound(TIterator first, TIterator last, const TValue& value, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::difference_type difference_t;
difference_t count = etl::distance(first, last);
while (count > 0)
{
TIterator itr = first;
difference_t step = count / 2;
etl::advance(itr, step);
if (!compare(value, *itr))
{
first = ++itr;
count -= step + 1;
}
else
{
count = step;
}
}
return first;
}
template<typename TIterator, typename TValue>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator upper_bound(TIterator first, TIterator last, const TValue& value)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
return etl::upper_bound(first, last, value, compare());
}
//***************************************************************************
// equal_range
//***************************************************************************
template<typename TIterator, typename TValue, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
ETL_OR_STD::pair<TIterator, TIterator> equal_range(TIterator first, TIterator last, const TValue& value, TCompare compare)
{
return ETL_OR_STD::make_pair(etl::lower_bound(first, last, value, compare),
etl::upper_bound(first, last, value, compare));
}
template<typename TIterator, typename TValue>
ETL_NODISCARD
ETL_OR_STD::pair<TIterator, TIterator> equal_range(TIterator first, TIterator last, const TValue& value)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
return ETL_OR_STD::make_pair(etl::lower_bound(first, last, value, compare()),
etl::upper_bound(first, last, value, compare()));
}
//***************************************************************************
// binary_search
//***************************************************************************
template <typename TIterator, typename T, typename Compare>
ETL_NODISCARD
bool binary_search(TIterator first, TIterator last, const T& value, Compare compare)
{
first = etl::lower_bound(first, last, value, compare);
return (!(first == last) && !(compare(value, *first)));
}
template <typename TIterator, typename T>
ETL_NODISCARD
bool binary_search(TIterator first, TIterator last, const T& value)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
return binary_search(first, last, value, compare());
}
//***************************************************************************
// find_if
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator find_if(TIterator first, TIterator last, TUnaryPredicate predicate)
{
while (first != last)
{
if (predicate(*first))
{
return first;
}
++first;
}
return last;
}
//***************************************************************************
// find
//***************************************************************************
template <typename TIterator, typename T>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator find(TIterator first, TIterator last, const T& value)
{
while (first != last)
{
if (*first == value)
{
return first;
}
++first;
}
return last;
}
//***************************************************************************
// fill
#if ETL_USING_STL && ETL_USING_CPP20
template<typename TIterator, typename TValue>
constexpr void fill(TIterator first, TIterator last, const TValue& value)
{
std::fill(first, last, value);
}
#else
template<typename TIterator, typename TValue>
ETL_CONSTEXPR14 void fill(TIterator first, TIterator last, const TValue& value)
{
while (first != last)
{
*first = value;
++first;
}
}
#endif
//***************************************************************************
// fill_n
#if ETL_USING_STL && ETL_USING_CPP20
template<typename TIterator, typename TSize, typename TValue>
constexpr TIterator fill_n(TIterator first, TSize count, const TValue& value)
{
return std::fill_n(first, count, value);
}
#else
template<typename TIterator, typename TSize, typename TValue>
ETL_CONSTEXPR14 TIterator fill_n(TIterator first, TSize count, const TValue& value)
{
while (count != 0)
{
*first++ = value;
--count;
}
return first;
}
#endif
//***************************************************************************
// count
//***************************************************************************
template <typename TIterator, typename T>
ETL_NODISCARD
ETL_CONSTEXPR14
typename etl::iterator_traits<TIterator>::difference_type count(TIterator first, TIterator last, const T& value)
{
typename iterator_traits<TIterator>::difference_type n = 0;
while (first != last)
{
if (*first == value)
{
++n;
}
++first;
}
return n;
}
//***************************************************************************
// count_if
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
typename etl::iterator_traits<TIterator>::difference_type
count_if(TIterator first, TIterator last, TUnaryPredicate predicate)
{
typename iterator_traits<TIterator>::difference_type n = 0;
while (first != last)
{
if (predicate(*first))
{
++n;
}
++first;
}
return n;
}
//***************************************************************************
// equal
#if ETL_USING_STL && ETL_USING_CPP20
// Three parameter
template <typename TIterator1, typename TIterator2>
[[nodiscard]]
constexpr
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2)
{
return std::equal(first1, last1, first2);
}
// Three parameter + predicate
template <typename TIterator1, typename TIterator2, typename TPredicate>
[[nodiscard]]
constexpr
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TPredicate predicate)
{
return std::equal(first1, last1, first2, predicate);
}
// Four parameter
template <typename TIterator1, typename TIterator2>
[[nodiscard]]
constexpr
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TIterator2 last2)
{
return std::equal(first1, last1, first2, last2);
}
// Four parameter + Predicate
template <typename TIterator1, typename TIterator2, typename TPredicate>
[[nodiscard]]
constexpr
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TIterator2 last2, TPredicate predicate)
{
return std::equal(first1, last1, first2, last2, predicate);
}
#else
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2)
{
while (first1 != last1)
{
if (*first1 != *first2)
{
return false;
}
++first1;
++first2;
}
return true;
}
// Predicate
template <typename TIterator1, typename TIterator2, typename TPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TPredicate predicate)
{
while (first1 != last1)
{
if (!predicate(*first1, *first2))
{
return false;
}
++first1;
++first2;
}
return true;
}
// Four parameter
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TIterator2 last2)
{
while ((first1 != last1) && (first2 != last2))
{
if (*first1 != *first2)
{
return false;
}
++first1;
++first2;
}
return (first1 == last1) && (first2 == last2);
}
// Four parameter, Predicate
template <typename TIterator1, typename TIterator2, typename TPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool equal(TIterator1 first1, TIterator1 last1, TIterator2 first2, TIterator2 last2, TPredicate predicate)
{
while ((first1 != last1) && (first2 != last2))
{
if (!predicate(*first1 , *first2))
{
return false;
}
++first1;
++first2;
}
return (first1 == last1) && (first2 == last2);
}
#endif
//***************************************************************************
// lexicographical_compare
//***************************************************************************
template <typename TIterator1, typename TIterator2, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
bool lexicographical_compare(TIterator1 first1, TIterator1 last1,
TIterator2 first2, TIterator2 last2,
TCompare compare)
{
while ((first1 != last1) && (first2 != last2))
{
if (compare(*first1, *first2))
{
return true;
}
if (compare(*first2, *first1))
{
return false;
}
++first1;
++first2;
}
return (first1 == last1) && (first2 != last2);
}
// lexicographical_compare
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
bool lexicographical_compare(TIterator1 first1, TIterator1 last1,
TIterator2 first2, TIterator2 last2)
{
typedef etl::less<typename etl::iterator_traits<TIterator1>::value_type> compare;
return etl::lexicographical_compare(first1, last1, first2, last2, compare());
}
//***************************************************************************
// min
//***************************************************************************
template <typename T, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR
const T& min(const T& a, const T& b, TCompare compare)
{
return (compare(a, b)) ? a : b;
}
template <typename T>
ETL_NODISCARD
ETL_CONSTEXPR
const T& min(const T& a, const T& b)
{
typedef etl::less<T> compare;
return etl::min(a, b, compare());
}
//***************************************************************************
// max
//***************************************************************************
template <typename T, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR
const T& max(const T& a, const T& b, TCompare compare)
{
return (compare(a, b)) ? b : a;
}
template <typename T>
ETL_NODISCARD
ETL_CONSTEXPR
const T& max(const T& a, const T& b)
{
typedef etl::less<T> compare;
return etl::max(a, b, compare());
}
//***************************************************************************
// for_each
//***************************************************************************
template <typename TIterator, typename TUnaryOperation>
ETL_CONSTEXPR14
TUnaryOperation for_each(TIterator first, TIterator last, TUnaryOperation unary_operation)
{
while (first != last)
{
unary_operation(*first);
++first;
}
return unary_operation;
}
//***************************************************************************
// transform
//***************************************************************************
template <typename TIteratorIn, typename TIteratorOut, typename TUnaryOperation>
ETL_CONSTEXPR14
TIteratorOut transform(TIteratorIn first1, TIteratorIn last1, TIteratorOut d_first, TUnaryOperation unary_operation)
{
while (first1 != last1)
{
*d_first = unary_operation(*first1);
++d_first;
++first1;
}
return d_first;
}
template <typename TIteratorIn1, typename TIteratorIn2, typename TIteratorOut, typename TBinaryOperation>
ETL_CONSTEXPR14
TIteratorOut transform(TIteratorIn1 first1, TIteratorIn1 last1, TIteratorIn2 first2, TIteratorOut d_first, TBinaryOperation binary_operation)
{
while (first1 != last1)
{
*d_first = binary_operation(*first1, *first2);
++d_first;
++first1;
++first2;
}
return d_first;
}
//***************************************************************************
// replace
//***************************************************************************
template <typename TIterator, typename T>
ETL_CONSTEXPR14 void replace(TIterator first, TIterator last, const T& old_value, const T& new_value)
{
while (first != last)
{
if (*first == old_value)
{
*first = new_value;
}
++first;
}
}
//***************************************************************************
// replace_if
//***************************************************************************
template <typename TIterator, typename TPredicate, typename T>
ETL_CONSTEXPR14 void replace_if(TIterator first, TIterator last, TPredicate predicate, const T& new_value)
{
while (first != last)
{
if (predicate(*first))
{
*first = new_value;
}
++first;
}
}
//***************************************************************************
// Heap
//***************************************************************************
namespace private_heap
{
// Push Heap Helper
template <typename TIterator, typename TDistance, typename TValue, typename TCompare>
void push_heap(TIterator first, TDistance value_index, TDistance top_index, TValue value, TCompare compare)
{
TDistance parent = (value_index - 1) / 2;
while ((value_index > top_index) && compare(first[parent], value))
{
first[value_index] = etl::move(first[parent]);
value_index = parent;
parent = (value_index - 1) / 2;
}
first[value_index] = etl::move(value);
}
// Adjust Heap Helper
template <typename TIterator, typename TDistance, typename TValue, typename TCompare>
void adjust_heap(TIterator first, TDistance value_index, TDistance length, TValue value, TCompare compare)
{
TDistance top_index = value_index;
TDistance child2nd = (2 * value_index) + 2;
while (child2nd < length)
{
if (compare(first[child2nd], first[child2nd - 1]))
{
--child2nd;
}
first[value_index] = etl::move(first[child2nd]);
value_index = child2nd;
child2nd = 2 * (child2nd + 1);
}
if (child2nd == length)
{
first[value_index] = etl::move(first[child2nd - 1]);
value_index = child2nd - 1;
}
push_heap(first, value_index, top_index, etl::move(value), compare);
}
// Is Heap Helper
template <typename TIterator, typename TDistance, typename TCompare>
bool is_heap(const TIterator first, const TDistance n, TCompare compare)
{
TDistance parent = 0;
for (TDistance child = 1; child < n; ++child)
{
if (compare(first[parent], first[child]))
{
return false;
}
if ((child & 1) == 0)
{
++parent;
}
}
return true;
}
}
// Pop Heap
template <typename TIterator, typename TCompare>
void pop_heap(TIterator first, TIterator last, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_t;
typedef typename etl::iterator_traits<TIterator>::difference_type distance_t;
value_t value = etl::move(last[-1]);
last[-1] = etl::move(first[0]);
private_heap::adjust_heap(first, distance_t(0), distance_t(last - first - 1), etl::move(value), compare);
}
// Pop Heap
template <typename TIterator>
void pop_heap(TIterator first, TIterator last)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
etl::pop_heap(first, last, compare());
}
// Push Heap
template <typename TIterator, typename TCompare>
void push_heap(TIterator first, TIterator last, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::difference_type difference_t;
typedef typename etl::iterator_traits<TIterator>::value_type value_t;
private_heap::push_heap(first, difference_t(last - first - 1), difference_t(0), value_t(etl::move(*(last - 1))), compare);
}
// Push Heap
template <typename TIterator>
void push_heap(TIterator first, TIterator last)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
etl::push_heap(first, last, compare());
}
// Make Heap
template <typename TIterator, typename TCompare>
void make_heap(TIterator first, TIterator last, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::difference_type difference_t;
if ((last - first) < 2)
{
return;
}
difference_t length = last - first;
difference_t parent = (length - 2) / 2;
while (true)
{
private_heap::adjust_heap(first, parent, length, etl::move(*(first + parent)), compare);
if (parent == 0)
{
return;
}
--parent;
}
}
// Make Heap
template <typename TIterator>
void make_heap(TIterator first, TIterator last)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
etl::make_heap(first, last, compare());
}
// Is Heap
template <typename TIterator>
ETL_NODISCARD
bool is_heap(TIterator first, TIterator last)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare;
return private_heap::is_heap(first, last - first, compare());
}
// Is Heap
template <typename TIterator, typename TCompare>
ETL_NODISCARD
bool is_heap(TIterator first, TIterator last, TCompare compare)
{
return private_heap::is_heap(first, last - first, compare);
}
// Sort Heap
template <typename TIterator>
void sort_heap(TIterator first, TIterator last)
{
while (first != last)
{
etl::pop_heap(first, last);
--last;
}
}
// Sort Heap
template <typename TIterator, typename TCompare>
void sort_heap(TIterator first, TIterator last, TCompare compare)
{
while (first != last)
{
etl::pop_heap(first, last, compare);
--last;
}
}
//***************************************************************************
// Search
//***************************************************************************
template<typename TIterator1, typename TIterator2, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator1 search(TIterator1 first, TIterator1 last, TIterator2 search_first, TIterator2 search_last, TCompare compare)
{
while (true)
{
TIterator1 itr = first;
TIterator2 search_itr = search_first;
while (true)
{
if (search_itr == search_last)
{
return first;
}
if (itr == last)
{
return last;
}
if (!compare(*itr, *search_itr))
{
break;
}
++itr;
++search_itr;
}
++first;
}
}
// Search
template<typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator1 search(TIterator1 first, TIterator1 last, TIterator2 search_first, TIterator2 search_last)
{
typedef etl::equal_to<typename etl::iterator_traits<TIterator1>::value_type> compare;
return etl::search(first, last, search_first, search_last, compare());
}
//***************************************************************************
// Rotate
//***************************************************************************
namespace private_algorithm
{
#if ETL_USING_CPP11
//*********************************
// For random access iterators
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_random_access_iterator<TIterator>::value, TIterator>::type
rotate_general(TIterator first, TIterator middle, TIterator last)
{
if (first == middle || middle == last)
{
return first;
}
typedef typename etl::iterator_traits<TIterator>::value_type value_type;
int n = last - first;
int m = middle - first;
int gcd_nm = (n == 0 || m == 0) ? n + m : etl::gcd(n, m);
TIterator result = first + (last - middle);
for (int i = 0; i < gcd_nm; i++)
{
value_type temp = etl::move(*(first + i));
int j = i;
while (true)
{
int k = j + m;
if (k >= n)
{
k = k - n;
}
if (k == i)
{
break;
}
*(first + j) = etl::move(*(first + k));
j = k;
}
*(first + j) = etl::move(temp);
}
return result;
}
#else
//*********************************
// For random access iterators
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_random_access_iterator<TIterator>::value, TIterator>::type
rotate_general(TIterator first, TIterator middle, TIterator last)
{
if (first == middle || middle == last)
{
return first;
}
typedef typename etl::iterator_traits<TIterator>::value_type value_type;
int n = last - first;
int m = middle - first;
int gcd_nm = (n == 0 || m == 0) ? n + m : etl::gcd(n, m);
TIterator result = first + (last - middle);
for (int i = 0; i < gcd_nm; i++)
{
value_type temp = *(first + i);
int j = i;
while (true)
{
int k = j + m;
if (k >= n)
{
k = k - n;
}
if (k == i)
{
break;
}
*(first + j) = *(first + k);
j = k;
}
*(first + j) = temp;
}
return result;
}
#endif
//*********************************
// For bidirectional iterators
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_bidirectional_iterator<TIterator>::value, TIterator>::type
rotate_general(TIterator first, TIterator middle, TIterator last)
{
if (first == middle || middle == last)
{
return first;
}
TIterator result = first;
etl::advance(result, etl::distance(middle, last));
reverse(first, middle);
reverse(middle, last);
reverse(first, last);
return result;
}
//*********************************
// For forward iterators
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_forward_iterator<TIterator>::value, TIterator>::type
rotate_general(TIterator first, TIterator middle, TIterator last)
{
if (first == middle || middle == last)
{
return first;
}
TIterator next = middle;
TIterator result = first;
etl::advance(result, etl::distance(middle, last));
while (first != next)
{
using ETL_OR_STD::swap;
swap(*first++, *next++);
if (next == last)
{
next = middle;
}
else if (first == middle)
{
middle = next;
}
}
return result;
}
//*********************************
// Simplified algorithm for rotate left by one
template <typename TIterator>
ETL_CONSTEXPR14
TIterator rotate_left_by_one(TIterator first, TIterator last)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_type;
// Save the first item.
value_type temp(etl::move(*first));
// Move the rest.
TIterator result = etl::move(etl::next(first), last, first);
// Restore the first item in its rotated position.
*result = etl::move(temp);
// The new position of the first item.
return result;
}
//*********************************
// Simplified for algorithm rotate right by one
template <typename TIterator>
ETL_CONSTEXPR14
TIterator rotate_right_by_one(TIterator first, TIterator last)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_type;
// Save the last item.
TIterator previous = etl::prev(last);
value_type temp(etl::move(*previous));
// Move the rest.
TIterator result = etl::move_backward(first, previous, last);
// Restore the last item in its rotated position.
*first = etl::move(temp);
// The new position of the first item.
return result;
}
}
//*********************************
template<typename TIterator>
ETL_CONSTEXPR14
TIterator rotate(TIterator first, TIterator middle, TIterator last)
{
if (etl::next(first) == middle)
{
return private_algorithm::rotate_left_by_one(first, last);
}
if (etl::next(middle) == last)
{
#if ETL_USING_CPP20
if ETL_IF_CONSTEXPR(etl::is_forward_iterator<TIterator>::value)
{
return private_algorithm::rotate_general(first, middle, last);
}
else
{
return private_algorithm::rotate_right_by_one(first, last);
}
#else
return private_algorithm::rotate_general(first, middle, last);
#endif
}
return private_algorithm::rotate_general(first, middle, last);
}
//***************************************************************************
// find_end
//***************************************************************************
// Predicate
template <typename TIterator1, typename TIterator2, typename TPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator1 find_end(TIterator1 b, TIterator1 e,
TIterator2 sb, TIterator2 se,
TPredicate predicate)
{
if (sb == se)
{
return e;
}
TIterator1 result = e;
while (true)
{
TIterator1 new_result = etl::search(b, e, sb, se, predicate);
if (new_result == e)
{
break;
}
else
{
result = new_result;
b = result;
++b;
}
}
return result;
}
// Default
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator1 find_end(TIterator1 b, TIterator1 e,
TIterator2 sb, TIterator2 se)
{
typedef etl::equal_to<typename etl::iterator_traits<TIterator1>::value_type> predicate;
return find_end(b, e, sb, se, predicate());
}
//***************************************************************************
/// Finds the iterator to the smallest element in the range (begin, end).<br>
///<a href="http://en.cppreference.com/w/cpp/algorithm/min_element"></a>
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator min_element(TIterator begin,
TIterator end,
TCompare compare)
{
TIterator minimum = begin;
++begin;
while (begin != end)
{
if (compare(*begin, *minimum))
{
minimum = begin;
}
++begin;
}
return minimum;
}
//***************************************************************************
/// min_element
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/min_element"></a>
//***************************************************************************
template <typename TIterator>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator min_element(TIterator begin,
TIterator end)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_t;
return etl::min_element(begin, end, etl::less<value_t>());
}
//***************************************************************************
/// Finds the iterator to the largest element in the range (begin, end).<br>
///<a href="http://en.cppreference.com/w/cpp/algorithm/max_element"></a>
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator max_element(TIterator begin,
TIterator end,
TCompare compare)
{
TIterator maximum = begin;
++begin;
while (begin != end)
{
if (!compare(*begin, *maximum))
{
maximum = begin;
}
++begin;
}
return maximum;
}
//***************************************************************************
/// max_element
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/max_element"></a>
//***************************************************************************
template <typename TIterator>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator max_element(TIterator begin,
TIterator end)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_t;
return etl::max_element(begin, end, etl::less<value_t>());
}
//***************************************************************************
/// Finds the greatest and the smallest element in the range (begin, end).<br>
///<a href="http://en.cppreference.com/w/cpp/algorithm/minmax_element"></a>
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
ETL_OR_STD::pair<TIterator, TIterator> minmax_element(TIterator begin,
TIterator end,
TCompare compare)
{
TIterator minimum = begin;
TIterator maximum = begin;
++begin;
while (begin != end)
{
if (compare(*begin, *minimum))
{
minimum = begin;
}
if (compare(*maximum, *begin))
{
maximum = begin;
}
++begin;
}
return ETL_OR_STD::pair<TIterator, TIterator>(minimum, maximum);
}
//***************************************************************************
/// minmax_element
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/minmax_element"></a>
//***************************************************************************
template <typename TIterator>
ETL_NODISCARD
ETL_CONSTEXPR14
ETL_OR_STD::pair<TIterator, TIterator> minmax_element(TIterator begin,
TIterator end)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_t;
return etl::minmax_element(begin, end, etl::less<value_t>());
}
//***************************************************************************
/// minmax
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/minmax"></a>
//***************************************************************************
template <typename T>
ETL_NODISCARD
ETL_CONSTEXPR14
ETL_OR_STD::pair<const T&, const T&> minmax(const T& a,
const T& b)
{
return (b < a) ? ETL_OR_STD::pair<const T&, const T&>(b, a) : ETL_OR_STD::pair<const T&, const T&>(a, b);
}
//***************************************************************************
/// minmax
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/minmax"></a>
//***************************************************************************
template <typename T, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
ETL_OR_STD::pair<const T&, const T&> minmax(const T& a,
const T& b,
TCompare compare)
{
return compare(b, a) ? ETL_OR_STD::pair<const T&, const T&>(b, a) : ETL_OR_STD::pair<const T&, const T&>(a, b);
}
//***************************************************************************
/// is_sorted_until
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_sorted_until"></a>
//***************************************************************************
template <typename TIterator>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator is_sorted_until(TIterator begin,
TIterator end)
{
if (begin != end)
{
TIterator next = begin;
while (++next != end)
{
if (*next < *begin)
{
return next;
}
++begin;
}
}
return end;
}
//***************************************************************************
/// is_sorted_until
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_sorted_until"></a>
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator is_sorted_until(TIterator begin,
TIterator end,
TCompare compare)
{
if (begin != end)
{
TIterator next = begin;
while (++next != end)
{
if (compare(*next, *begin))
{
return next;
}
++begin;
}
}
return end;
}
//***************************************************************************
/// is_sorted
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_sorted"></a>
//***************************************************************************
template<typename TIterator>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_sorted(TIterator begin,
TIterator end)
{
return etl::is_sorted_until(begin, end) == end;
}
//***************************************************************************
/// is_sorted
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_sorted"></a>
//***************************************************************************
template<typename TIterator, typename TCompare>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_sorted(TIterator begin,
TIterator end,
TCompare compare)
{
return etl::is_sorted_until(begin, end, compare) == end;
}
//***************************************************************************
/// find_if_not
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/find"></a>
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator find_if_not(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (!predicate(*begin))
{
return begin;
}
++begin;
}
return end;
}
//***************************************************************************
/// is_permutation
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_permutation"></a>
//***************************************************************************
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_permutation(TIterator1 begin1,
TIterator1 end1,
TIterator2 begin2)
{
if (begin1 != end1)
{
TIterator2 end2 = begin2;
etl::advance(end2, etl::distance(begin1, end1));
for (TIterator1 i = begin1; i != end1; ++i)
{
if (i == etl::find(begin1, i, *i))
{
size_t n = etl::count(begin2, end2, *i);
if (n == 0 || size_t(etl::count(i, end1, *i)) != n)
{
return false;
}
}
}
}
return true;
}
//***************************************************************************
/// is_permutation
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_permutation"></a>
//***************************************************************************
template <typename TIterator1, typename TIterator2, typename TBinaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_permutation(TIterator1 begin1,
TIterator1 end1,
TIterator2 begin2,
TBinaryPredicate predicate)
{
if (begin1 != end1)
{
TIterator2 end2 = begin2;
etl::advance(end2, etl::distance(begin1, end1));
for (TIterator1 i = begin1; i != end1; ++i)
{
if (i == etl::find_if(begin1, i, etl::bind1st(predicate, *i)))
{
size_t n = etl::count(begin2, end2, *i);
if (n == 0 || size_t(etl::count(i, end1, *i)) != n)
{
return false;
}
}
}
}
return true;
}
//***************************************************************************
/// is_permutation
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_permutation"></a>
//***************************************************************************
template <typename TIterator1, typename TIterator2>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_permutation(TIterator1 begin1,
TIterator1 end1,
TIterator2 begin2,
TIterator2 end2)
{
if (begin1 != end1)
{
for (TIterator1 i = begin1; i != end1; ++i)
{
if (i == etl::find(begin1, i, *i))
{
size_t n = etl::count(begin2, end2, *i);
if (n == 0 || size_t(etl::count(i, end1, *i)) != n)
{
return false;
}
}
}
}
return true;
}
//***************************************************************************
/// is_permutation
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_permutation"></a>
//***************************************************************************
template <typename TIterator1, typename TIterator2, typename TBinaryPredicate>
ETL_NODISCARD
bool is_permutation(TIterator1 begin1,
TIterator1 end1,
TIterator2 begin2,
TIterator2 end2,
TBinaryPredicate predicate)
{
if (begin1 != end1)
{
for (TIterator1 i = begin1; i != end1; ++i)
{
if (i == etl::find_if(begin1, i, etl::bind1st(predicate, *i)))
{
size_t n = etl::count(begin2, end2, *i);
if (n == 0 || size_t(etl::count(i, end1, *i)) != n)
{
return false;
}
}
}
}
return true;
}
//***************************************************************************
/// is_partitioned
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/is_partitioned"></a>
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool is_partitioned(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (!predicate(*begin))
{
break;
}
++begin;
}
while (begin != end)
{
if (predicate(*begin))
{
return false;
}
++begin;
}
return true;
}
//***************************************************************************
/// partition_point
///<a href="http://en.cppreference.com/w/cpp/algorithm/partition_point"></a>
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator partition_point(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (!predicate(*begin))
{
return begin;
}
++begin;
}
return begin;
}
//***************************************************************************
/// Copies the elements from the range (begin, end) to two different ranges
/// depending on the value returned by the predicate.<br>
///<a href="http://en.cppreference.com/w/cpp/algorithm/partition_copy"></a>
///\ingroup algorithm
//***************************************************************************
template <typename TSource, typename TDestinationTrue, typename TDestinationFalse, typename TUnaryPredicate>
ETL_CONSTEXPR14
ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse> partition_copy(TSource begin,
TSource end,
TDestinationTrue destination_true,
TDestinationFalse destination_false,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (predicate(*begin))
{
*destination_true = *begin;
++destination_true;
}
else
{
*destination_false = *begin;
++destination_false;
}
++begin;
}
return ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse>(destination_true, destination_false);
}
//***************************************************************************
/// copy_if
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/copy"></a>
//***************************************************************************
template <typename TIterator, typename TOutputIterator, typename TUnaryPredicate>
ETL_CONSTEXPR14
TOutputIterator copy_if(TIterator begin,
TIterator end,
TOutputIterator out,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (predicate(*begin))
{
*out = *begin;
++out;
}
++begin;
}
return out;
}
//***************************************************************************
/// all_of
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/all_any_none_of"></a>
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool all_of(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
return etl::find_if_not(begin, end, predicate) == end;
}
//***************************************************************************
/// any_of
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/all_any_none_of"></a>
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool any_of(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
return etl::find_if(begin, end, predicate) != end;
}
//***************************************************************************
/// none_of
///\ingroup algorithm
///<a href="http://en.cppreference.com/w/cpp/algorithm/all_any_none_of"></a>
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_NODISCARD
ETL_CONSTEXPR14
bool none_of(TIterator begin,
TIterator end,
TUnaryPredicate predicate)
{
return etl::find_if(begin, end, predicate) == end;
}
#if ETL_NOT_USING_STL
//***************************************************************************
/// Sorts the elements.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
void sort(TIterator first, TIterator last, TCompare compare)
{
etl::shell_sort(first, last, compare);
}
//***************************************************************************
/// Sorts the elements.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
void sort(TIterator first, TIterator last)
{
etl::shell_sort(first, last, etl::less<typename etl::iterator_traits<TIterator>::value_type>());
}
//***************************************************************************
/// Sorts the elements.
/// Stable.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
void stable_sort(TIterator first, TIterator last, TCompare compare)
{
etl::insertion_sort(first, last, compare);
}
//***************************************************************************
/// Sorts the elements.
/// Stable.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
void stable_sort(TIterator first, TIterator last)
{
etl::insertion_sort(first, last, etl::less<typename etl::iterator_traits<TIterator>::value_type>());
}
#else
//***************************************************************************
/// Sorts the elements.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
void sort(TIterator first, TIterator last, TCompare compare)
{
std::sort(first, last, compare);
}
//***************************************************************************
/// Sorts the elements.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
void sort(TIterator first, TIterator last)
{
std::sort(first, last);
}
//***************************************************************************
/// Sorts the elements.
/// Stable.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
void stable_sort(TIterator first, TIterator last, TCompare compare)
{
std::stable_sort(first, last, compare);
}
//***************************************************************************
/// Sorts the elements.
/// Stable.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
void stable_sort(TIterator first, TIterator last)
{
std::stable_sort(first, last);
}
#endif
//***************************************************************************
/// Accumulates values.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename T>
ETL_CONSTEXPR14
T accumulate(TIterator first, TIterator last, T sum)
{
while (first != last)
{
sum = etl::move(sum) + *first;
++first;
}
return sum;
}
//***************************************************************************
/// Accumulates values.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename T, typename TBinaryOperation>
ETL_CONSTEXPR14
T accumulate(TIterator first, TIterator last, T sum, TBinaryOperation operation)
{
while (first != last)
{
sum = operation(etl::move(sum), *first);
++first;
}
return sum;
}
//***************************************************************************
/// Clamp values.
///\ingroup algorithm
//***************************************************************************
template<typename T, typename TCompare>
ETL_CONSTEXPR
T clamp(const T& value, const T& low, const T& high, TCompare compare)
{
return compare(value, low) ? low : compare(high, value) ? high : value;
}
template <typename T>
ETL_CONSTEXPR
T clamp(const T& value, const T& low, const T& high)
{
return clamp(value, low, high, etl::less<T>());
}
template<typename T, T Low, T High, typename TCompare>
ETL_CONSTEXPR
T clamp(const T& value, TCompare compare)
{
return compare(value, Low) ? Low : compare(High, value) ? High : value;
}
template <typename T, T Low, T High>
ETL_CONSTEXPR
T clamp(const T& value)
{
return clamp<T, Low, High>(value, etl::less<T>());
}
//***************************************************************************
/// Remove
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename T>
ETL_CONSTEXPR14
TIterator remove(TIterator first, TIterator last, const T& value)
{
first = etl::find(first, last, value);
if (first != last)
{
TIterator itr = first;
while (++itr != last)
{
if (!(*itr == value))
{
*first++ = etl::move(*itr);
}
}
}
return first;
}
//***************************************************************************
/// Remove If
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TUnaryPredicate>
ETL_CONSTEXPR14
TIterator remove_if(TIterator first, TIterator last, TUnaryPredicate predicate)
{
first = etl::find_if(first, last, predicate);
if (first != last)
{
TIterator itr = first;
while (++itr != last)
{
if (!predicate(*itr))
{
*first++ = etl::move(*itr);
}
}
}
return first;
}
}
//*****************************************************************************
// ETL extensions to the STL algorithms.
//*****************************************************************************
namespace etl
{
//***************************************************************************
/// copy_s
/// A safer form of copy where the smallest of the two ranges is used.
/// There is currently no STL equivalent.
/// Specialisation for random access iterators.
///\param i_begin Beginning of the input range.
///\param i_end End of the input range.
///\param o_begin Beginning of the output range.
///\param o_end End of the output range.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TOutputIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_random_iterator<TInputIterator>::value &&
etl::is_random_iterator<TOutputIterator>::value, TOutputIterator>::type
copy_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end)
{
size_t s_size = etl::distance(i_begin, i_end);
size_t d_size = etl::distance(o_begin, o_end);
size_t size = (s_size < d_size) ? s_size : d_size;
return etl::copy(i_begin, i_begin + size, o_begin);
}
//***************************************************************************
/// copy
/// A safer form of copy where the smallest of the two ranges is used.
/// There is currently no STL equivalent.
/// Specialisation for non random access iterators.
///\param i_begin Beginning of the input range.
///\param i_end End of the input range.
///\param o_begin Beginning of the output range.
///\param o_end End of the output range.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TOutputIterator>
ETL_CONSTEXPR14
typename etl::enable_if<!etl::is_random_iterator<TInputIterator>::value ||
!etl::is_random_iterator<TOutputIterator>::value, TOutputIterator>::type
copy_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end)
{
while ((i_begin != i_end) && (o_begin != o_end))
{
*o_begin = *i_begin;
++o_begin;
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// copy_n
/// A safer form of copy_n where the smallest of the two ranges is used.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TSize,
typename TOutputIterator>
ETL_CONSTEXPR14
TOutputIterator copy_n_s(TInputIterator i_begin,
TSize n,
TOutputIterator o_begin,
TOutputIterator o_end)
{
while ((n-- > 0) && (o_begin != o_end))
{
*o_begin = *i_begin;
++o_begin;
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// copy_n
/// A safer form of copy_n where the smallest of the two ranges is used.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TSize1,
typename TOutputIterator,
typename TSize2>
ETL_CONSTEXPR14
TOutputIterator copy_n_s(TInputIterator i_begin,
TSize1 n1,
TOutputIterator o_begin,
TSize2 n2)
{
while ((n1-- > 0) && (n2-- > 0))
{
*o_begin = *i_begin;
++o_begin;
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// copy_if
/// A safer form of copy_if where it terminates when the first end iterator is reached.
/// There is currently no STL equivalent.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TOutputIterator,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TOutputIterator copy_if_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end,
TUnaryPredicate predicate)
{
while ((i_begin != i_end) && (o_begin != o_end))
{
if (predicate(*i_begin))
{
*o_begin = *i_begin;
++o_begin;
}
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// copy_n_if
/// Combination of copy_n and copy_if.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TSize,
typename TOutputIterator,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TOutputIterator copy_n_if(TInputIterator i_begin,
TSize n,
TOutputIterator o_begin,
TUnaryPredicate predicate)
{
while (n-- > 0)
{
if (predicate(*i_begin))
{
*o_begin = *i_begin;
++o_begin;
}
++i_begin;
}
return o_begin;
}
#if ETL_USING_CPP11
//***************************************************************************
/// move_s
/// A safer form of move where the smallest of the two ranges is used.
/// There is currently no STL equivalent.
/// Specialisation for random access iterators.
///\param i_begin Beginning of the input range.
///\param i_end End of the input range.
///\param o_begin Beginning of the output range.
///\param o_end End of the output range.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator, typename TOutputIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_random_iterator<TInputIterator>::value &&
etl::is_random_iterator<TOutputIterator>::value, TOutputIterator>::type
move_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end)
{
size_t s_size = etl::distance(i_begin, i_end);
size_t d_size = etl::distance(o_begin, o_end);
size_t size = (s_size < d_size) ? s_size : d_size;
return etl::move(i_begin, i_begin + size, o_begin);
}
//***************************************************************************
/// move_s
/// A safer form of move where the smallest of the two ranges is used.
/// There is currently no STL equivalent.
/// Specialisation for non random access iterators.
///\param i_begin Beginning of the input range.
///\param i_end End of the input range.
///\param o_begin Beginning of the output range.
///\param o_end End of the output range.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator, typename TOutputIterator>
ETL_CONSTEXPR14
typename etl::enable_if<!etl::is_random_iterator<TInputIterator>::value ||
!etl::is_random_iterator<TOutputIterator>::value, TOutputIterator>::type
move_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end)
{
while ((i_begin != i_end) && (o_begin != o_end))
{
*o_begin = etl::move(*i_begin);
++i_begin;
++o_begin;
}
return o_begin;
}
#else
//***************************************************************************
/// move_s
/// C++03
/// A safer form of move where the smallest of the two ranges is used.
/// There is currently no STL equivalent.
/// Specialisation for non random access iterators.
///\param i_begin Beginning of the input range.
///\param i_end End of the input range.
///\param o_begin Beginning of the output range.
///\param o_end End of the output range.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator, typename TOutputIterator>
TOutputIterator move_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end)
{
// Move not supported. Defer to copy.
return etl::copy_s(i_begin, i_end, o_begin, o_end);
}
#endif
//***************************************************************************
/// binary_find
///\ingroup algorithm
/// Does a binary search and returns an iterator to the value or end if not found.
//***************************************************************************
template <typename TIterator, typename TValue>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator binary_find(TIterator begin,
TIterator end,
const TValue& value)
{
TIterator it = etl::lower_bound(begin, end, value);
if ((it == end) || (*it != value))
{
it = end;
}
return it;
}
//***************************************************************************
/// binary_find
///\ingroup algorithm
/// Does a binary search and returns an iterator to the value or end if not found.
//***************************************************************************
template <typename TIterator,
typename TValue,
typename TBinaryPredicate,
typename TBinaryEquality>
ETL_NODISCARD
ETL_CONSTEXPR14
TIterator binary_find(TIterator begin,
TIterator end,
const TValue& value,
TBinaryPredicate predicate,
TBinaryEquality equality)
{
TIterator it = etl::lower_bound(begin, end, value, predicate);
if ((it == end) || !equality(*it, value))
{
it = end;
}
return it;
}
//***************************************************************************
/// Like std::for_each but applies a predicate before calling the function.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator,
typename TUnaryFunction,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TUnaryFunction for_each_if(TIterator begin,
const TIterator end,
TUnaryFunction function,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (predicate(*begin))
{
function(*begin);
}
++begin;
}
return function;
}
//***************************************************************************
/// Like std::for_each but for 'n' iterations.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator,
typename TSize,
typename TUnaryFunction>
ETL_CONSTEXPR14
TIterator for_each_n(TIterator begin,
TSize n,
TUnaryFunction function)
{
while (n-- > 0)
{
function(*begin);
++begin;
}
return begin;
}
//***************************************************************************
/// Like std::for_each but applies a predicate before calling the function, for 'n' iterations
///\ingroup algorithm
//***************************************************************************
template <typename TIterator,
typename TSize,
typename TUnaryFunction,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TIterator for_each_n_if(TIterator begin,
TSize n,
TUnaryFunction function,
TUnaryPredicate predicate)
{
while (n-- > 0)
{
if (predicate(*begin))
{
function(*begin);
}
++begin;
}
return begin;
}
//***************************************************************************
/// A safer form of std::transform where the transform returns when the first
/// range end is reached.
/// There is currently no STL equivalent.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator, typename TOutputIterator, typename TUnaryFunction>
ETL_CONSTEXPR14
TOutputIterator transform_s(TInputIterator i_begin,
TInputIterator i_end,
TOutputIterator o_begin,
TOutputIterator o_end,
TUnaryFunction function)
{
while ((i_begin != i_end) && (o_begin != o_end))
{
*o_begin = function(*i_begin);
++i_begin;
++o_begin;
}
return o_begin;
}
//***************************************************************************
/// Transform 'n' items.
/// Random iterators.
/// There is currently no STL equivalent.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TSize,
typename TOutputIterator,
typename TUnaryFunction>
ETL_CONSTEXPR14
void transform_n(TInputIterator i_begin,
TSize n,
TOutputIterator o_begin,
TUnaryFunction function)
{
TInputIterator i_end(i_begin);
etl::advance(i_end, n);
etl::transform(i_begin, i_end, o_begin, function);
}
//***************************************************************************
/// Transform 'n' items from two ranges.
/// Random iterators.
/// There is currently no STL equivalent.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator1,
typename TInputIterator2,
typename TSize,
typename TOutputIterator,
typename TBinaryFunction>
ETL_CONSTEXPR14
void transform_n(TInputIterator1 i_begin1,
TInputIterator2 i_begin2,
TSize n,
TOutputIterator o_begin,
TBinaryFunction function)
{
TInputIterator1 i_end1(i_begin1);
etl::advance(i_end1, n);
etl::transform(i_begin1, i_end1, i_begin2, o_begin, function);
}
//***************************************************************************
/// Like std::transform but applies a predicate before calling the function.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TOutputIterator,
typename TUnaryFunction,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TOutputIterator transform_if(TInputIterator i_begin,
const TInputIterator i_end,
TOutputIterator o_begin,
TUnaryFunction function,
TUnaryPredicate predicate)
{
while (i_begin != i_end)
{
if (predicate(*i_begin))
{
*o_begin = function(*i_begin);
++o_begin;
}
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// Like etl::transform_if but inputs from two ranges.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator1,
typename TInputIterator2,
typename TOutputIterator,
typename TBinaryFunction,
typename TBinaryPredicate>
ETL_CONSTEXPR14
TOutputIterator transform_if(TInputIterator1 i_begin1,
const TInputIterator1 i_end1,
TInputIterator2 i_begin2,
TOutputIterator o_begin,
TBinaryFunction function,
TBinaryPredicate predicate)
{
while (i_begin1 != i_end1)
{
if (predicate(*i_begin1, *i_begin2))
{
*o_begin = function(*i_begin1, *i_begin2);
++o_begin;
}
++i_begin1;
++i_begin2;
}
return o_begin;
}
//***************************************************************************
/// Like std::transform_if, for 'n' items.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator,
typename TSize,
typename TOutputIterator,
typename TUnaryFunction,
typename TUnaryPredicate>
ETL_CONSTEXPR14
TOutputIterator transform_n_if(TInputIterator i_begin,
TSize n,
TOutputIterator o_begin,
TUnaryFunction function,
TUnaryPredicate predicate)
{
while (n-- > 0)
{
if (predicate(*i_begin))
{
*o_begin = function(*i_begin);
++o_begin;
}
++i_begin;
}
return o_begin;
}
//***************************************************************************
/// Like etl::transform_if but inputs from two ranges for 'n' items.
///\ingroup algorithm
//***************************************************************************
template <typename TInputIterator1,
typename TInputIterator2,
typename TSize,
typename TOutputIterator,
typename TBinaryFunction,
typename TBinaryPredicate>
ETL_CONSTEXPR14
TOutputIterator transform_n_if(TInputIterator1 i_begin1,
TInputIterator2 i_begin2,
TSize n,
TOutputIterator o_begin,
TBinaryFunction function,
TBinaryPredicate predicate)
{
while (n-- > 0)
{
if (predicate(*i_begin1, *i_begin2))
{
*o_begin++ = function(*i_begin1, *i_begin2);
}
++i_begin1;
++i_begin2;
}
return o_begin;
}
//***************************************************************************
/// Transforms the elements from the range (begin, end) to two different ranges
/// depending on the value returned by the predicate.<br>
///\ingroup algorithm
//***************************************************************************
template <typename TSource, typename TDestinationTrue, typename TDestinationFalse,
typename TUnaryFunctionTrue, typename TUnaryFunctionFalse,
typename TUnaryPredicate>
ETL_CONSTEXPR14
ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse> partition_transform(TSource begin,
TSource end,
TDestinationTrue destination_true,
TDestinationFalse destination_false,
TUnaryFunctionTrue function_true,
TUnaryFunctionFalse function_false,
TUnaryPredicate predicate)
{
while (begin != end)
{
if (predicate(*begin))
{
*destination_true = function_true(*begin);
++destination_true;
}
else
{
*destination_false = function_false(*begin);
++destination_false;
}
++begin;
}
return ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse>(destination_true, destination_false);
}
//***************************************************************************
/// Transforms the elements from the ranges (begin1, end1) & (begin2)
/// to two different ranges depending on the value returned by the predicate.
///\ingroup algorithm
//***************************************************************************
template <typename TSource1,
typename TSource2,
typename TDestinationTrue,
typename TDestinationFalse,
typename TBinaryFunctionTrue,
typename TBinaryFunctionFalse,
typename TBinaryPredicate>
ETL_CONSTEXPR14
ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse> partition_transform(TSource1 begin1,
TSource1 end1,
TSource2 begin2,
TDestinationTrue destination_true,
TDestinationFalse destination_false,
TBinaryFunctionTrue function_true,
TBinaryFunctionFalse function_false,
TBinaryPredicate predicate)
{
while (begin1 != end1)
{
if (predicate(*begin1, *begin2))
{
*destination_true = function_true(*begin1, *begin2);
++destination_true;
}
else
{
*destination_false = function_false(*begin1, *begin2);
++destination_false;
}
++begin1;
++begin2;
}
return ETL_OR_STD::pair<TDestinationTrue, TDestinationFalse>(destination_true, destination_false);
}
//***************************************************************************
/// Sorts the elements using shell sort.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
void shell_sort(TIterator first, TIterator last, TCompare compare)
{
if (first == last)
{
return;
}
typedef typename etl::iterator_traits<TIterator>::difference_type difference_t;
difference_t n = etl::distance(first, last);
for (difference_t i = n / 2; i > 0; i /= 2)
{
for (difference_t j = i; j < n; ++j)
{
for (difference_t k = j - i; k >= 0; k -= i)
{
TIterator itr1 = first;
TIterator itr2 = first;
etl::advance(itr1, k);
etl::advance(itr2, k + i);
if (compare(*itr2, *itr1))
{
etl::iter_swap(itr1, itr2);
}
}
}
}
}
//***************************************************************************
/// Sorts the elements using shell sort.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
#if ETL_USING_STD_NAMESPACE
ETL_CONSTEXPR20
#else
ETL_CONSTEXPR14
#endif
void shell_sort(TIterator first, TIterator last)
{
etl::shell_sort(first, last, etl::less<typename etl::iterator_traits<TIterator>::value_type>());
}
//***************************************************************************
/// Sorts the elements using insertion sort.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_CONSTEXPR14
void insertion_sort(TIterator first, TIterator last, TCompare compare)
{
for (TIterator itr = first; itr != last; ++itr)
{
etl::rotate(etl::upper_bound(first, itr, *itr, compare), itr, etl::next(itr));
}
}
//***************************************************************************
/// Sorts the elements using insertion sort.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
ETL_CONSTEXPR14
void insertion_sort(TIterator first, TIterator last)
{
etl::insertion_sort(first, last, etl::less<typename etl::iterator_traits<TIterator>::value_type>());
}
//***************************************************************************
namespace private_algorithm
{
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_forward_iterator<TIterator>::value, TIterator>::type
get_before_last(TIterator first_, TIterator last_)
{
TIterator last = first_;
TIterator lastplus1 = first_;
++lastplus1;
while (lastplus1 != last_)
{
++last;
++lastplus1;
}
return last;
}
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_bidirectional_iterator<TIterator>::value, TIterator>::type
get_before_last(TIterator /*first_*/, TIterator last_)
{
TIterator last = last_;
--last;
return last;
}
template <typename TIterator>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_random_access_iterator<TIterator>::value, TIterator>::type
get_before_last(TIterator /*first_*/, TIterator last_)
{
return last_ - 1;
}
}
//***************************************************************************
/// Sorts the elements using selection sort.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_CONSTEXPR20
void selection_sort(TIterator first, TIterator last, TCompare compare)
{
TIterator min;
const TIterator ilast = private_algorithm::get_before_last(first, last);
const TIterator jlast = last;
for (TIterator i = first; i != ilast; ++i)
{
min = i;
TIterator j = i;
++j;
for (; j != jlast; ++j)
{
if (compare(*j, *min))
{
min = j;
}
}
using ETL_OR_STD::swap; // Allow ADL
swap(*i, *min);
}
}
//***************************************************************************
/// Sorts the elements using selection sort.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
ETL_CONSTEXPR20
void selection_sort(TIterator first, TIterator last)
{
selection_sort(first, last, etl::less<typename etl::iterator_traits<TIterator>::value_type>());
}
//***************************************************************************
/// Sorts the elements using heap sort.
/// Uses user defined comparison.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator, typename TCompare>
ETL_CONSTEXPR14
void heap_sort(TIterator first, TIterator last, TCompare compare)
{
if (!etl::is_heap(first, last, compare))
{
etl::make_heap(first, last, compare);
}
etl::sort_heap(first, last, compare);
}
//***************************************************************************
/// Sorts the elements using heap sort.
///\ingroup algorithm
//***************************************************************************
template <typename TIterator>
ETL_CONSTEXPR14
void heap_sort(TIterator first, TIterator last)
{
if (!etl::is_heap(first, last))
{
etl::make_heap(first, last);
}
etl::sort_heap(first, last);
}
//***************************************************************************
/// Returns the maximum value.
//***************************************************************************
#if ETL_USING_CPP11
template <typename T>
ETL_NODISCARD
constexpr const T& multimax(const T& a, const T& b)
{
return a < b ? b : a;
}
template <typename T, typename... Tx>
ETL_NODISCARD
constexpr const T& multimax(const T& t, const Tx&... tx)
{
return multimax(t, multimax(tx...));
}
#endif
//***************************************************************************
/// Returns the maximum value.
/// User supplied compare function.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TCompare, typename T>
ETL_NODISCARD
constexpr const T& multimax_compare(TCompare compare, const T& a, const T& b)
{
return compare(a, b) ? b : a;
}
template <typename TCompare, typename T, typename... Tx>
ETL_NODISCARD
constexpr const T& multimax_compare(TCompare compare, const T& t, const Tx&... tx)
{
return multimax_compare(compare, t, multimax_compare(compare, tx...));
}
#endif
//***************************************************************************
/// Returns the maximum value.
//***************************************************************************
#if ETL_USING_CPP11
template <typename T>
ETL_NODISCARD
constexpr const T& multimin(const T& a, const T& b)
{
return a < b ? a : b;
}
template <typename T, typename... Tx>
ETL_NODISCARD
constexpr const T& multimin(const T& t, const Tx&... tx)
{
return multimin(t, multimin(tx...));
}
#endif
//***************************************************************************
/// Returns the minimum value.
/// User supplied compare function.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TCompare, typename T>
ETL_NODISCARD
constexpr const T& multimin_compare(TCompare compare, const T& a, const T& b)
{
return compare(a, b) ? a : b;
}
template <typename TCompare, typename T, typename... Tx>
ETL_NODISCARD
constexpr const T& multimin_compare(TCompare compare, const T& t, const Tx&... tx)
{
return multimin_compare(compare, t, multimin_compare(compare, tx...));
}
#endif
//***************************************************************************
/// Returns the iterator to the maximum value.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TIterator>
ETL_NODISCARD
constexpr const TIterator& multimax_iter(const TIterator& a, const TIterator& b)
{
return *a < *b ? b : a;
}
template <typename TIterator, typename... TIteratorx>
ETL_NODISCARD
constexpr const TIterator& multimax_iter(const TIterator& t, const TIteratorx&... tx)
{
return multimax_iter(t, multimax_iter(tx...));
}
#endif
//***************************************************************************
/// Returns the iterator to the maximum value.
/// User supplied compare function.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TCompare, typename TIterator>
ETL_NODISCARD
constexpr const TIterator& multimax_iter_compare(TCompare compare, const TIterator& a, const TIterator& b)
{
return compare(*a, *b) ? b : a;
}
template <typename TCompare, typename TIterator, typename... TIteratorx>
ETL_NODISCARD
constexpr const TIterator& multimax_iter_compare(TCompare compare, const TIterator& t, const TIteratorx&... tx)
{
return multimax_iter_compare(compare, t, multimax_iter_compare(compare, tx...));
}
#endif
//***************************************************************************
/// Returns the iterator to the minimum value.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TIterator>
ETL_NODISCARD
constexpr const TIterator& multimin_iter(const TIterator& a, const TIterator& b)
{
return *a < *b ? a : b;
}
template <typename TIterator, typename... Tx>
ETL_NODISCARD
constexpr const TIterator& multimin_iter(const TIterator& t, const Tx&... tx)
{
return multimin_iter(t, multimin_iter(tx...));
}
#endif
//***************************************************************************
/// Returns the iterator to the minimum value.
/// User supplied compare function.
//***************************************************************************
#if ETL_USING_CPP11
template <typename TCompare, typename TIterator>
ETL_NODISCARD
constexpr const TIterator& multimin_iter_compare(TCompare compare, const TIterator& a, const TIterator& b)
{
return compare(*a, *b) ? a : b;
}
template <typename TCompare, typename TIterator, typename... Tx>
ETL_NODISCARD
constexpr const TIterator& multimin_iter_compare(TCompare compare, const TIterator& t, const Tx&... tx)
{
return multimin_iter_compare(compare, t, multimin_iter_compare(compare, tx...));
}
#endif
//***************************************************************************
/// partition
/// For forward iterators only
/// Does at most etl::distance(first, last) swaps.
//***************************************************************************
template <typename TIterator, typename TPredicate>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_forward_iterator<TIterator>::value, TIterator>::type
partition(TIterator first, TIterator last, TPredicate predicate)
{
first = etl::find_if_not(first, last, predicate);
if (first == last)
{
return first;
}
for (TIterator i = etl::next(first); i != last; ++i)
{
if (predicate(*i))
{
using ETL_OR_STD::swap;
swap(*i, *first);
++first;
}
}
return first;
}
//***************************************************************************
/// partition
/// For iterators that support bidirectional iteration.
/// Does at most (etl::distance(first, last) / 2) swaps.
//***************************************************************************
template <typename TIterator, typename TPredicate>
ETL_CONSTEXPR14
typename etl::enable_if<etl::is_bidirectional_iterator_concept<TIterator>::value, TIterator>::type
partition(TIterator first, TIterator last, TPredicate predicate)
{
while (first != last)
{
first = etl::find_if_not(first, last, predicate);
if (first == last)
{
break;
}
last = etl::find_if(etl::reverse_iterator<TIterator>(last),
etl::reverse_iterator<TIterator>(first),
predicate).base();
if (first == last)
{
break;
}
--last;
using ETL_OR_STD::swap;
swap(*first, *last);
++first;
}
return first;
}
//*********************************************************
namespace private_algorithm
{
using ETL_OR_STD::swap;
template <typename TIterator, typename TCompare>
#if (ETL_USING_CPP20 && ETL_USING_STL) || (ETL_USING_CPP14 && ETL_NOT_USING_STL && !defined(ETL_IN_UNIT_TEST))
constexpr
#endif
TIterator nth_partition(TIterator first, TIterator last, TCompare compare)
{
typedef typename etl::iterator_traits<TIterator>::value_type value_type;
TIterator pivot = last; // Maybe find a better pivot choice?
value_type pivot_value = *pivot;
// Swap the pivot with the last, if necessary.
if (pivot != last)
{
swap(*pivot, *last);
}
TIterator i = first;
for (TIterator j = first; j < last; ++j)
{
if (!compare(pivot_value, *j)) // Hack to get '*j <= pivot_value' in terms of 'pivot_value < *j'
{
swap(*i, *j);
++i;
}
}
swap(*i, *last);
return i;
}
}
//*********************************************************
/// nth_element
/// see https://en.cppreference.com/w/cpp/algorithm/nth_element
//*********************************************************
#if ETL_USING_CPP11
template <typename TIterator, typename TCompare = etl::less<typename etl::iterator_traits<TIterator>::value_type>>
#if (ETL_USING_CPP20 && ETL_USING_STL) || (ETL_USING_CPP14 && ETL_NOT_USING_STL && !defined(ETL_IN_UNIT_TEST))
constexpr
#endif
typename etl::enable_if<etl::is_random_access_iterator_concept<TIterator>::value, void>::type
nth_element(TIterator first, TIterator nth, TIterator last, TCompare compare = TCompare())
{
if (first == last)
{
return;
}
// 'last' must point to the actual last value.
--last;
while (first <= last)
{
TIterator p = private_algorithm::nth_partition(first, last, compare);
if (p == nth)
{
return;
}
else if (p > nth)
{
last = p - 1;
}
else
{
first = p + 1;
}
}
}
#else
//*********************************************************
template <typename TIterator, typename TCompare>
typename etl::enable_if<etl::is_random_access_iterator_concept<TIterator>::value, void>::type
nth_element(TIterator first, TIterator nth, TIterator last, TCompare compare)
{
if (first == last)
{
return;
}
// 'last' must point to the actual last value.
--last;
while (first <= last)
{
TIterator p = private_algorithm::nth_partition(first, last, compare);
if (p == nth)
{
return;
}
else if (p > nth)
{
last = p - 1;
}
else
{
first = p + 1;
}
}
}
//*********************************************************
template <typename TIterator>
typename etl::enable_if<etl::is_random_access_iterator_concept<TIterator>::value, void>::type
nth_element(TIterator first, TIterator nth, TIterator last)
{
typedef etl::less<typename etl::iterator_traits<TIterator>::value_type> compare_t;
nth_element(first, last, compare_t());
}
#endif
}
#include "private/minmax_pop.h"
#endif
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