#pragma once /* * Copyright (C) 2024 Brett Terpstra * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #ifndef BLT_ITERATOR_ITER_COMMON #define BLT_ITERATOR_ITER_COMMON #include #include #include #include #include #include namespace blt::iterator { template struct base_wrapper { base_wrapper operator++(int) { auto tmp = *this; ++*this; return tmp; } base_wrapper operator--(int) { static_assert(meta::is_bidirectional_or_better_category_v, "Iterator must allow random access"); auto tmp = *this; --*this; return tmp; } auto operator[](blt::ptrdiff_t n) const { static_assert(meta::is_random_access_iterator_category_v, "Iterator must allow random access"); return *(*this + n); } friend base_wrapper operator+(blt::ptrdiff_t n, const base_wrapper& a) { return a + n; } friend bool operator<(const base_wrapper& a, const base_wrapper& b) { static_assert(meta::is_random_access_iterator_category_v, "Iterator must allow random access"); return b - a > 0; } friend bool operator>(const base_wrapper& a, const base_wrapper& b) { static_assert(meta::is_random_access_iterator_category_v, "Iterator must allow random access"); return b < a; } friend bool operator>=(const base_wrapper& a, base_wrapper& b) { static_assert(meta::is_random_access_iterator_category_v, "Iterator must allow random access"); return !(a < b); // NOLINT } friend bool operator<=(const base_wrapper& a, const base_wrapper& b) { static_assert(meta::is_random_access_iterator_category_v, "Iterator must allow random access"); return !(a > b); // NOLINT } friend bool operator==(const base_wrapper& a, const base_wrapper& b) { return static_cast(a).base() == static_cast(b).base(); } friend bool operator!=(const base_wrapper& a, const base_wrapper& b) { return !(static_cast(a).base() == static_cast(b).base()); // NOLINT } }; template struct passthrough_wrapper : public base_wrapper { public: explicit passthrough_wrapper(Iter iter): iter(std::move(iter)) {} auto base() const { return iter; } friend blt::ptrdiff_t operator-(const passthrough_wrapper& a, const passthrough_wrapper& b) { return a.base() - b.base(); } protected: Iter iter; }; template struct passthrough_wrapper : public passthrough_wrapper { using passthrough_wrapper::passthrough_wrapper; meta::deref_return_t operator*() const { return *this->iter; } // your_class& operator++() // { // return *this; // } // // your_class& operator--() // { // return *this; // } // // friend your_class operator+(const your_class& a, blt::ptrdiff_t n) // { // static_assert(std::is_same_v, // "Iterator must allow random access"); // } // // friend your_class operator-(const your_class& a, blt::ptrdiff_t n) // { // static_assert(std::is_same_v, // "Iterator must allow random access"); // } }; template class map_wrapper : public passthrough_wrapper> { public: using iterator_category = typename std::iterator_traits::iterator_category; using value_type = std::invoke_result_t>; using difference_type = blt::ptrdiff_t; using pointer = value_type; using reference = value_type; map_wrapper(Iter iter, Func func): passthrough_wrapper>(std::move(iter)), func(std::move(func)) {} reference operator*() const { return func(*this->iter); } map_wrapper& operator++() { ++this->iter; return *this; } map_wrapper& operator--() { --this->iter; return *this; } friend map_wrapper operator+(const map_wrapper& a, blt::ptrdiff_t n) { static_assert(meta::is_random_access_iterator_v, "Iterator must allow random access"); return {a.iter + n, a.func}; } friend map_wrapper operator-(const map_wrapper& a, blt::ptrdiff_t n) { static_assert(meta::is_random_access_iterator_v, "Iterator must allow random access"); return {a.iter - n, a.func}; } private: Func func; }; namespace impl { template class skip_t { private: template auto skip_base(blt::size_t n) { auto* d = static_cast(this); auto begin = d->begin(); auto end = d->end(); if constexpr (meta::is_random_access_iterator_category_v) { // random access iterators can have math directly applied to them. if constexpr (check) { return Derived{begin + std::min(static_cast(n), std::distance(begin, end)), end}; } else { return Derived{begin + n, end}; } } else { for (blt::size_t i = 0; i < n; i++) { if constexpr (check) { if (begin == end) break; } ++begin; } return Derived{std::move(begin), std::move(end)}; } } public: auto skip(blt::size_t n) { return skip_base(n); } auto skip_or(blt::size_t n) { return skip_base(n); } }; template class take_t { private: template auto take_base(blt::size_t n) { static_assert(!meta::is_input_iterator_category_v, "Cannot .take() on an input iterator!"); auto* d = static_cast(this); auto begin = d->begin(); auto end = d->end(); // take variant for forward and bidirectional iterators if constexpr (meta::is_forward_iterator_category_v || meta::is_bidirectional_iterator_category_v) { // with these guys we have to loop forward to move the iterators. an unfortunate inefficiency auto new_end = begin; for (blt::size_t i = 0; i < n; i++) { if constexpr (check) { if (new_end == end) break; } ++new_end; } return Derived{std::move(begin), std::move(new_end)}; } else if constexpr (meta::is_random_access_iterator_category_v) { // random access iterators can have math directly applied to them. if constexpr (check) { return Derived{begin, begin + std::min(static_cast(n), std::distance(begin, end))}; } else { return Derived{begin, begin + n}; } } } public: auto take(blt::size_t n) { return take_base(n); } auto take_or(blt::size_t n) { return take_base(n); } }; } template class iterator_container : public impl::take_t>, public impl::skip_t> { public: using iterator_category = typename std::iterator_traits::iterator_category; using iterator = IterBase; iterator_container(IterBase begin, IterBase end): m_begin(std::move(begin)), m_end(std::move(end)) {} template iterator_container(Iter&& begin, Iter&& end): m_begin(std::forward(begin)), m_end(std::forward(end)) {} auto rev() const { static_assert(meta::is_bidirectional_or_better_category_v, ".rev() must be used with bidirectional (or better) iterators!"); return iterator_container>{std::reverse_iterator{end()}, std::reverse_iterator{begin()}}; } template auto zip(iterator_pair... iterator_pairs) const { return zip_iterator_container(iterator_pair{begin(), end()}, iterator_pairs...); } template auto zip(Container& ... containers) const { return zip_iterator_container(iterator_pair{begin(), end()}, iterator_pair{containers.begin(), containers.end()}...); } template auto zip(const Container& ... containers) const { return zip_iterator_container(iterator_pair{begin(), end()}, iterator_pair{containers.begin(), containers.end()}...); } auto enumerate() const { return enumerate_iterator_container{begin(), end(), static_cast(std::distance(begin(), end()))}; } template auto map(Func func) { return iterator_container>{ blt::iterator::map_wrapper{m_begin, func}, blt::iterator::map_wrapper{m_end, func}}; } auto begin() const { return m_begin; } auto end() const { return m_end; } protected: IterBase m_begin; IterBase m_end; }; } #endif //BLT_ITERATOR_ITER_COMMON