boost/compute/iterator/buffer_iterator.hpp
//---------------------------------------------------------------------------// // Copyright (c) 2013 Kyle Lutz <kyle.r.lutz@gmail.com> // // Distributed under 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 // // See http://boostorg.github.com/compute for more information. //---------------------------------------------------------------------------// #ifndef BOOST_COMPUTE_ITERATOR_BUFFER_ITERATOR_HPP #define BOOST_COMPUTE_ITERATOR_BUFFER_ITERATOR_HPP #include <cstddef> #include <iterator> #include <boost/config.hpp> #include <boost/type_traits.hpp> #include <boost/static_assert.hpp> #include <boost/utility/enable_if.hpp> #include <boost/iterator/iterator_facade.hpp> #include <boost/compute/buffer.hpp> #include <boost/compute/detail/buffer_value.hpp> #include <boost/compute/detail/is_buffer_iterator.hpp> #include <boost/compute/detail/meta_kernel.hpp> #include <boost/compute/detail/read_write_single_value.hpp> #include <boost/compute/type_traits/is_device_iterator.hpp> namespace boost { namespace compute { // forward declaration for buffer_iterator<T> template<class T> class buffer_iterator; namespace detail { // helper class which defines the iterator_facade super-class // type for buffer_iterator<T> template<class T> class buffer_iterator_base { public: typedef ::boost::iterator_facade< ::boost::compute::buffer_iterator<T>, T, ::std::random_access_iterator_tag, ::boost::compute::detail::buffer_value<T> > type; }; template<class T, class IndexExpr> struct buffer_iterator_index_expr { typedef T result_type; buffer_iterator_index_expr(const buffer &buffer, size_t index, const memory_object::address_space address_space, const IndexExpr &expr) : m_buffer(buffer.get(), false), m_index(index), m_address_space(address_space), m_expr(expr) { } buffer_iterator_index_expr(const buffer_iterator_index_expr& other) : m_buffer(other.m_buffer.get(), false), m_index(other.m_index), m_address_space(other.m_address_space), m_expr(other.m_expr) { } ~buffer_iterator_index_expr() { // set buffer to null so that its reference count will // not be decremented when its destructor is called m_buffer.get() = 0; } operator T() const { BOOST_STATIC_ASSERT_MSG(boost::is_integral<IndexExpr>::value, "Index expression must be integral"); return buffer_value<T>(m_buffer, size_t(m_expr) * sizeof(T)); } const buffer m_buffer; const size_t m_index; const memory_object::address_space m_address_space; const IndexExpr m_expr; }; template<class T, class IndexExpr> inline meta_kernel& operator<<(meta_kernel &kernel, const buffer_iterator_index_expr<T, IndexExpr> &expr) { if(expr.m_index == 0){ return kernel << kernel.get_buffer_identifier<T>(expr.m_buffer, expr.m_address_space) << '[' << expr.m_expr << ']'; } else { return kernel << kernel.get_buffer_identifier<T>(expr.m_buffer, expr.m_address_space) << '[' << uint_(expr.m_index) << "+(" << expr.m_expr << ")]"; } } } // end detail namespace /// \class buffer_iterator /// \brief An iterator for values in a buffer. /// /// The buffer_iterator class iterates over values in a memory buffer on a /// compute device. It is the most commonly used iterator in Boost.Compute /// and is used by the \ref vector "vector<T>" and \ref array "array<T, N>" /// container classes. /// /// Buffer iterators store a reference to a memory buffer along with an index /// into that memory buffer. /// /// The buffer_iterator class allows for arbitrary OpenCL memory objects /// (including those created outside of Boost.Compute) to be used with the /// Boost.Compute algorithms (such as transform() and sort()). For example, /// to reverse the contents of an OpenCL memory buffer containing a set of /// integers: /// /// \snippet test/test_buffer_iterator.cpp reverse_external_buffer /// /// \see buffer, make_buffer_iterator() template<class T> class buffer_iterator : public detail::buffer_iterator_base<T>::type { public: typedef typename detail::buffer_iterator_base<T>::type super_type; typedef typename super_type::reference reference; typedef typename super_type::difference_type difference_type; buffer_iterator() : m_index(0) { } buffer_iterator(const buffer &buffer, size_t index) : m_buffer(buffer.get(), false), m_index(index) { } buffer_iterator(const buffer_iterator<T> &other) : m_buffer(other.m_buffer.get(), false), m_index(other.m_index) { } buffer_iterator<T>& operator=(const buffer_iterator<T> &other) { if(this != &other){ m_buffer.get() = other.m_buffer.get(); m_index = other.m_index; } return *this; } ~buffer_iterator() { // set buffer to null so that its reference count will // not be decremented when its destructor is called m_buffer.get() = 0; } const buffer& get_buffer() const { return m_buffer; } size_t get_index() const { return m_index; } T read(command_queue &queue) const { BOOST_ASSERT(m_buffer.get()); BOOST_ASSERT(m_index < m_buffer.size() / sizeof(T)); return detail::read_single_value<T>(m_buffer, m_index, queue); } void write(const T &value, command_queue &queue) { BOOST_ASSERT(m_buffer.get()); BOOST_ASSERT(m_index < m_buffer.size() / sizeof(T)); detail::write_single_value<T>(value, m_buffer, m_index, queue); } /// \internal_ template<class Expr> detail::buffer_iterator_index_expr<T, Expr> operator[](const Expr &expr) const { BOOST_ASSERT(m_buffer.get()); return detail::buffer_iterator_index_expr<T, Expr>( m_buffer, m_index, memory_object::global_memory, expr ); } private: friend class ::boost::iterator_core_access; /// \internal_ reference dereference() const { return detail::buffer_value<T>(m_buffer, m_index * sizeof(T)); } /// \internal_ bool equal(const buffer_iterator<T> &other) const { return m_buffer.get() == other.m_buffer.get() && m_index == other.m_index; } /// \internal_ void increment() { m_index++; } /// \internal_ void decrement() { m_index--; } /// \internal_ void advance(difference_type n) { m_index = static_cast<size_t>(static_cast<difference_type>(m_index) + n); } /// \internal_ difference_type distance_to(const buffer_iterator<T> &other) const { return static_cast<difference_type>(other.m_index - m_index); } private: const buffer m_buffer; size_t m_index; }; /// Creates a new \ref buffer_iterator for \p buffer at \p index. /// /// \param buffer the \ref buffer object /// \param index the index in the buffer /// /// \return a \c buffer_iterator for \p buffer at \p index template<class T> inline buffer_iterator<T> make_buffer_iterator(const buffer &buffer, size_t index = 0) { return buffer_iterator<T>(buffer, index); } /// \internal_ (is_device_iterator specialization for buffer_iterator) template<class T> struct is_device_iterator<buffer_iterator<T> > : boost::true_type {}; namespace detail { // is_buffer_iterator specialization for buffer_iterator template<class Iterator> struct is_buffer_iterator< Iterator, typename boost::enable_if< boost::is_same< buffer_iterator<typename Iterator::value_type>, typename boost::remove_const<Iterator>::type > >::type > : public boost::true_type {}; } // end detail namespace } // end compute namespace } // end boost namespace #endif // BOOST_COMPUTE_ITERATOR_BUFFER_ITERATOR_HPP