boost/range/irange.hpp
// Boost.Range library // // Copyright Neil Groves 2010. Use, modification and // distribution is subject to the Boost Software License, Version // 1.0. (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // // For more information, see http://www.boost.org/libs/range/ // #ifndef BOOST_RANGE_IRANGE_HPP_INCLUDED #define BOOST_RANGE_IRANGE_HPP_INCLUDED #include <boost/assert.hpp> #include <boost/iterator/iterator_facade.hpp> #include <boost/range/iterator_range.hpp> namespace boost { namespace range_detail { // integer_iterator is an iterator over an integer sequence that // is bounded only by the limits of the underlying integer // representation. // // This is useful for implementing the irange(first, last) // function. // // Note: // This use of this iterator and irange is appreciably less // performant than the corresponding hand-written integer // loop on many compilers. template<typename Integer> class integer_iterator : public boost::iterator_facade< integer_iterator<Integer>, Integer, boost::random_access_traversal_tag, Integer, std::ptrdiff_t > { typedef boost::iterator_facade< integer_iterator<Integer>, Integer, boost::random_access_traversal_tag, Integer, std::ptrdiff_t > base_t; public: typedef typename base_t::value_type value_type; typedef typename base_t::difference_type difference_type; typedef typename base_t::reference reference; typedef std::random_access_iterator_tag iterator_category; integer_iterator() : m_value() {} explicit integer_iterator(value_type x) : m_value(x) {} private: void increment() { ++m_value; } void decrement() { --m_value; } void advance(difference_type offset) { m_value += offset; } difference_type distance_to(const integer_iterator& other) const { return is_signed<value_type>::value ? (other.m_value - m_value) : (other.m_value >= m_value) ? static_cast<difference_type>(other.m_value - m_value) : -static_cast<difference_type>(m_value - other.m_value); } bool equal(const integer_iterator& other) const { return m_value == other.m_value; } reference dereference() const { return m_value; } friend class ::boost::iterator_core_access; value_type m_value; }; // integer_iterator_with_step is similar in nature to the // integer_iterator but provides the ability to 'move' in // a number of steps specified at construction time. // // The three variable implementation provides the best guarantees // of loop termination upon various combinations of input. // // While this design is less performant than some less // safe alternatives, the use of ranges and iterators to // perform counting will never be optimal anyhow, hence // if optimal performance is desired a hand-coded loop // is the solution. template<typename Integer> class integer_iterator_with_step : public boost::iterator_facade< integer_iterator_with_step<Integer>, Integer, boost::random_access_traversal_tag, Integer, std::ptrdiff_t > { typedef boost::iterator_facade< integer_iterator_with_step<Integer>, Integer, boost::random_access_traversal_tag, Integer, std::ptrdiff_t > base_t; public: typedef typename base_t::value_type value_type; typedef typename base_t::difference_type difference_type; typedef typename base_t::reference reference; typedef std::random_access_iterator_tag iterator_category; integer_iterator_with_step(value_type first, difference_type step, value_type step_size) : m_first(first) , m_step(step) , m_step_size(step_size) { } private: void increment() { ++m_step; } void decrement() { --m_step; } void advance(difference_type offset) { m_step += offset; } difference_type distance_to(const integer_iterator_with_step& other) const { return other.m_step - m_step; } bool equal(const integer_iterator_with_step& other) const { return m_step == other.m_step; } reference dereference() const { return m_first + (m_step * m_step_size); } friend class ::boost::iterator_core_access; value_type m_first; difference_type m_step; difference_type m_step_size; }; } // namespace range_detail template<typename Integer> class integer_range : public iterator_range< range_detail::integer_iterator<Integer> > { typedef range_detail::integer_iterator<Integer> iterator_t; typedef iterator_range<iterator_t> base_t; public: integer_range(Integer first, Integer last) : base_t(iterator_t(first), iterator_t(last)) { } }; template<typename Integer> class strided_integer_range : public iterator_range< range_detail::integer_iterator_with_step<Integer> > { typedef range_detail::integer_iterator_with_step<Integer> iterator_t; typedef iterator_range<iterator_t> base_t; public: template<typename Iterator> strided_integer_range(Iterator first, Iterator last) : base_t(first, last) { } }; template<typename Integer> integer_range<Integer> irange(Integer first, Integer last) { BOOST_ASSERT( first <= last ); return integer_range<Integer>(first, last); } template<typename Integer, typename StepSize> strided_integer_range<Integer> irange(Integer first, Integer last, StepSize step_size) { BOOST_ASSERT( step_size != 0 ); BOOST_ASSERT( (step_size > 0) ? (last >= first) : (last <= first) ); typedef typename range_detail::integer_iterator_with_step<Integer> iterator_t; const std::ptrdiff_t sz = static_cast<std::ptrdiff_t>(step_size >= 0 ? step_size : -step_size); const Integer l = step_size >= 0 ? last : first; const Integer f = step_size >= 0 ? first : last; const std::ptrdiff_t num_steps = (l - f) / sz + ((l - f) % sz ? 1 : 0); BOOST_ASSERT(num_steps >= 0); return strided_integer_range<Integer>( iterator_t(first, 0, step_size), iterator_t(first, num_steps, step_size)); } } // namespace boost #endif // include guard