boost/multi_array/base.hpp
// Copyright 2002 The Trustees of Indiana University. // 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) // Boost.MultiArray Library // Authors: Ronald Garcia // Jeremy Siek // Andrew Lumsdaine // See http://www.boost.org/libs/multi_array for documentation. #ifndef BASE_RG071801_HPP #define BASE_RG071801_HPP // // base.hpp - some implementation base classes for from which // functionality is acquired // #include "boost/multi_array/extent_range.hpp" #include "boost/multi_array/extent_gen.hpp" #include "boost/multi_array/index_range.hpp" #include "boost/multi_array/index_gen.hpp" #include "boost/multi_array/storage_order.hpp" #include "boost/multi_array/types.hpp" #include "boost/config.hpp" #include "boost/multi_array/concept_checks.hpp" //for ignore_unused_... #include "boost/mpl/eval_if.hpp" #include "boost/mpl/if.hpp" #include "boost/mpl/size_t.hpp" #include "boost/iterator/reverse_iterator.hpp" #include "boost/static_assert.hpp" #include "boost/type.hpp" #include "boost/assert.hpp" #include <cstddef> #include <memory> namespace boost { ///////////////////////////////////////////////////////////////////////// // class declarations ///////////////////////////////////////////////////////////////////////// template<typename T, std::size_t NumDims, typename Allocator = std::allocator<T> > class multi_array; // This is a public interface for use by end users! namespace multi_array_types { typedef boost::detail::multi_array::size_type size_type; typedef std::ptrdiff_t difference_type; typedef boost::detail::multi_array::index index; typedef detail::multi_array::index_range<index,size_type> index_range; typedef detail::multi_array::extent_range<index,size_type> extent_range; typedef detail::multi_array::index_gen<0,0> index_gen; typedef detail::multi_array::extent_gen<0> extent_gen; } // boost::extents and boost::indices are now a part of the public // interface. That way users don't necessarily have to create their // own objects. On the other hand, one may not want the overhead of // object creation in small-memory environments. Thus, the objects // can be left undefined by defining BOOST_MULTI_ARRAY_NO_GENERATORS // before loading multi_array.hpp. #ifndef BOOST_MULTI_ARRAY_NO_GENERATORS namespace { multi_array_types::extent_gen extents; multi_array_types::index_gen indices; } #endif // BOOST_MULTI_ARRAY_NO_GENERATORS namespace detail { namespace multi_array { template <typename T, std::size_t NumDims> class sub_array; template <typename T, std::size_t NumDims, typename TPtr = const T*> class const_sub_array; template <typename T, typename TPtr, typename NumDims, typename Reference, typename IteratorCategory> class array_iterator; template <typename T, std::size_t NumDims, typename TPtr = const T*> class const_multi_array_view; template <typename T, std::size_t NumDims> class multi_array_view; ///////////////////////////////////////////////////////////////////////// // class interfaces ///////////////////////////////////////////////////////////////////////// class multi_array_base { public: typedef multi_array_types::size_type size_type; typedef multi_array_types::difference_type difference_type; typedef multi_array_types::index index; typedef multi_array_types::index_range index_range; typedef multi_array_types::extent_range extent_range; typedef multi_array_types::index_gen index_gen; typedef multi_array_types::extent_gen extent_gen; }; // // value_accessor_n // contains the routines for accessing elements from // N-dimensional views. // template<typename T, std::size_t NumDims> class value_accessor_n : public multi_array_base { typedef multi_array_base super_type; public: typedef typename super_type::index index; // // public typedefs used by classes that inherit from this base // typedef T element; typedef boost::multi_array<T,NumDims-1> value_type; typedef sub_array<T,NumDims-1> reference; typedef const_sub_array<T,NumDims-1> const_reference; protected: // used by array operator[] and iterators to get reference types. template <typename Reference, typename TPtr> Reference access(boost::type<Reference>,index idx,TPtr base, const size_type* extents, const index* strides, const index* index_bases) const { BOOST_ASSERT(idx - index_bases[0] >= 0); BOOST_ASSERT(size_type(idx - index_bases[0]) < extents[0]); // return a sub_array<T,NDims-1> proxy object TPtr newbase = base + idx * strides[0]; return Reference(newbase,extents+1,strides+1,index_bases+1); } value_accessor_n() { } ~value_accessor_n() { } }; // // value_accessor_one // contains the routines for accessing reference elements from // 1-dimensional views. // template<typename T> class value_accessor_one : public multi_array_base { typedef multi_array_base super_type; public: typedef typename super_type::index index; // // public typedefs for use by classes that inherit it. // typedef T element; typedef T value_type; typedef T& reference; typedef T const& const_reference; protected: // used by array operator[] and iterators to get reference types. template <typename Reference, typename TPtr> Reference access(boost::type<Reference>,index idx,TPtr base, const size_type* extents, const index* strides, const index* index_bases) const { ignore_unused_variable_warning(index_bases); ignore_unused_variable_warning(extents); BOOST_ASSERT(idx - index_bases[0] >= 0); BOOST_ASSERT(size_type(idx - index_bases[0]) < extents[0]); return *(base + idx * strides[0]); } value_accessor_one() { } ~value_accessor_one() { } }; ///////////////////////////////////////////////////////////////////////// // choose value accessor begins // template <typename T, std::size_t NumDims> struct choose_value_accessor_n { typedef value_accessor_n<T,NumDims> type; }; template <typename T> struct choose_value_accessor_one { typedef value_accessor_one<T> type; }; template <typename T, typename NumDims> struct value_accessor_generator { BOOST_STATIC_CONSTANT(std::size_t, dimensionality = NumDims::value); typedef typename mpl::eval_if_c<(dimensionality == 1), choose_value_accessor_one<T>, choose_value_accessor_n<T,dimensionality> >::type type; }; template <class T, class NumDims> struct associated_types : value_accessor_generator<T,NumDims>::type {}; // // choose value accessor ends ///////////////////////////////////////////////////////////////////////// // Due to some imprecision in the C++ Standard, // MSVC 2010 is broken in debug mode: it requires // that an Output Iterator have output_iterator_tag in its iterator_category if // that iterator is not bidirectional_iterator or random_access_iterator. #if BOOST_WORKAROUND(BOOST_MSVC, >= 1600) struct mutable_iterator_tag : boost::random_access_traversal_tag, std::input_iterator_tag { operator std::output_iterator_tag() const { return std::output_iterator_tag(); } }; #endif //////////////////////////////////////////////////////////////////////// // multi_array_base //////////////////////////////////////////////////////////////////////// template <typename T, std::size_t NumDims> class multi_array_impl_base : public value_accessor_generator<T,mpl::size_t<NumDims> >::type { typedef associated_types<T,mpl::size_t<NumDims> > types; public: typedef typename types::index index; typedef typename types::size_type size_type; typedef typename types::element element; typedef typename types::index_range index_range; typedef typename types::value_type value_type; typedef typename types::reference reference; typedef typename types::const_reference const_reference; template <std::size_t NDims> struct subarray { typedef boost::detail::multi_array::sub_array<T,NDims> type; }; template <std::size_t NDims> struct const_subarray { typedef boost::detail::multi_array::const_sub_array<T,NDims> type; }; template <std::size_t NDims> struct array_view { typedef boost::detail::multi_array::multi_array_view<T,NDims> type; }; template <std::size_t NDims> struct const_array_view { public: typedef boost::detail::multi_array::const_multi_array_view<T,NDims> type; }; // // iterator support // #if BOOST_WORKAROUND(BOOST_MSVC, >= 1600) // Deal with VC 2010 output_iterator_tag requirement typedef array_iterator<T,T*,mpl::size_t<NumDims>,reference, mutable_iterator_tag> iterator; #else typedef array_iterator<T,T*,mpl::size_t<NumDims>,reference, boost::random_access_traversal_tag> iterator; #endif typedef array_iterator<T,T const*,mpl::size_t<NumDims>,const_reference, boost::random_access_traversal_tag> const_iterator; typedef ::boost::reverse_iterator<iterator> reverse_iterator; typedef ::boost::reverse_iterator<const_iterator> const_reverse_iterator; BOOST_STATIC_CONSTANT(std::size_t, dimensionality = NumDims); protected: multi_array_impl_base() { } ~multi_array_impl_base() { } // Used by operator() in our array classes template <typename Reference, typename IndexList, typename TPtr> Reference access_element(boost::type<Reference>, const IndexList& indices, TPtr base, const size_type* extents, const index* strides, const index* index_bases) const { boost::function_requires< CollectionConcept<IndexList> >(); ignore_unused_variable_warning(index_bases); ignore_unused_variable_warning(extents); #if !defined(NDEBUG) && !defined(BOOST_DISABLE_ASSERTS) for (size_type i = 0; i != NumDims; ++i) { BOOST_ASSERT(indices[i] - index_bases[i] >= 0); BOOST_ASSERT(size_type(indices[i] - index_bases[i]) < extents[i]); } #endif index offset = 0; { typename IndexList::const_iterator i = indices.begin(); size_type n = 0; while (n != NumDims) { offset += (*i) * strides[n]; ++n; ++i; } } return base[offset]; } template <typename StrideList, typename ExtentList> void compute_strides(StrideList& stride_list, ExtentList& extent_list, const general_storage_order<NumDims>& storage) { // invariant: stride = the stride for dimension n index stride = 1; for (size_type n = 0; n != NumDims; ++n) { index stride_sign = +1; if (!storage.ascending(storage.ordering(n))) stride_sign = -1; // The stride for this dimension is the product of the // lengths of the ranks minor to it. stride_list[storage.ordering(n)] = stride * stride_sign; stride *= extent_list[storage.ordering(n)]; } } // This calculates the offset to the array base pointer due to: // 1. dimensions stored in descending order // 2. non-zero dimension index bases template <typename StrideList, typename ExtentList, typename BaseList> index calculate_origin_offset(const StrideList& stride_list, const ExtentList& extent_list, const general_storage_order<NumDims>& storage, const BaseList& index_base_list) { return calculate_descending_dimension_offset(stride_list,extent_list, storage) + calculate_indexing_offset(stride_list,index_base_list); } // This calculates the offset added to the base pointer that are // caused by descending dimensions template <typename StrideList, typename ExtentList> index calculate_descending_dimension_offset(const StrideList& stride_list, const ExtentList& extent_list, const general_storage_order<NumDims>& storage) { index offset = 0; if (!storage.all_dims_ascending()) for (size_type n = 0; n != NumDims; ++n) if (!storage.ascending(n)) offset -= (extent_list[n] - 1) * stride_list[n]; return offset; } // This is used to reindex array_views, which are no longer // concerned about storage order (specifically, whether dimensions // are ascending or descending) since the viewed array handled it. template <typename StrideList, typename BaseList> index calculate_indexing_offset(const StrideList& stride_list, const BaseList& index_base_list) { index offset = 0; for (size_type n = 0; n != NumDims; ++n) offset -= stride_list[n] * index_base_list[n]; return offset; } // Slicing using an index_gen. // Note that populating an index_gen creates a type that encodes // both the number of dimensions in the current Array (NumDims), and // the Number of dimensions for the resulting view. This allows the // compiler to fail if the dimensions aren't completely accounted // for. For reasons unbeknownst to me, a BOOST_STATIC_ASSERT // within the member function template does not work. I should add a // note to the documentation specifying that you get a damn ugly // error message if you screw up in your slicing code. template <typename ArrayRef, int NDims, typename TPtr> ArrayRef generate_array_view(boost::type<ArrayRef>, const boost::detail::multi_array:: index_gen<NumDims,NDims>& indices, const size_type* extents, const index* strides, const index* index_bases, TPtr base) const { boost::array<index,NDims> new_strides; boost::array<index,NDims> new_extents; index offset = 0; size_type dim = 0; for (size_type n = 0; n != NumDims; ++n) { // Use array specs and input specs to produce real specs. const index default_start = index_bases[n]; const index default_finish = default_start+extents[n]; const index_range& current_range = indices.ranges_[n]; index start = current_range.get_start(default_start); index finish = current_range.get_finish(default_finish); index stride = current_range.stride(); BOOST_ASSERT(stride != 0); // An index range indicates a half-open strided interval // [start,finish) (with stride) which faces upward when stride // is positive and downward when stride is negative, // RG: The following code for calculating length suffers from // some representation issues: if finish-start cannot be represented as // by type index, then overflow may result. index len; if ((finish - start) / stride < 0) { // [start,finish) is empty according to the direction imposed by // the stride. len = 0; } else { // integral trick for ceiling((finish-start) / stride) // taking into account signs. index shrinkage = stride > 0 ? 1 : -1; len = (finish - start + (stride - shrinkage)) / stride; } // start marks the closed side of the range, so it must lie // exactly in the set of legal indices // with a special case for empty arrays BOOST_ASSERT(index_bases[n] <= start && ((start <= index_bases[n]+index(extents[n])) || (start == index_bases[n] && extents[n] == 0))); #ifndef BOOST_DISABLE_ASSERTS // finish marks the open side of the range, so it can go one past // the "far side" of the range (the top if stride is positive, the bottom // if stride is negative). index bound_adjustment = stride < 0 ? 1 : 0; BOOST_ASSERT(((index_bases[n] - bound_adjustment) <= finish) && (finish <= (index_bases[n] + index(extents[n]) - bound_adjustment))); #endif // BOOST_DISABLE_ASSERTS // the array data pointer is modified to account for non-zero // bases during slicing (see [Garcia] for the math involved) offset += start * strides[n]; if (!current_range.is_degenerate()) { // The stride for each dimension is included into the // strides for the array_view (see [Garcia] for the math involved). new_strides[dim] = stride * strides[n]; // calculate new extents new_extents[dim] = len; ++dim; } } BOOST_ASSERT(dim == NDims); return ArrayRef(base+offset, new_extents, new_strides); } }; } // namespace multi_array } // namespace detail } // namespace boost #endif // BASE_RG071801_HPP