boost/multi_array/multi_array_ref.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 BOOST_MULTI_ARRAY_MULTI_ARRAY_REF_HPP
#define BOOST_MULTI_ARRAY_MULTI_ARRAY_REF_HPP
//
// multi_array_ref.hpp - code for creating "views" of array data.
//
#include "boost/multi_array/base.hpp"
#include "boost/multi_array/collection_concept.hpp"
#include "boost/multi_array/concept_checks.hpp"
#include "boost/multi_array/iterator.hpp"
#include "boost/multi_array/storage_order.hpp"
#include "boost/multi_array/subarray.hpp"
#include "boost/multi_array/view.hpp"
#include "boost/multi_array/algorithm.hpp"
#include "boost/type_traits/is_integral.hpp"
#include "boost/utility/enable_if.hpp"
#include "boost/array.hpp"
#include "boost/concept_check.hpp"
#include "boost/functional.hpp"
#include "boost/limits.hpp"
#include <algorithm>
#include <cstddef>
#include <functional>
#include <numeric>
namespace boost {
template <typename T, std::size_t NumDims,
typename TPtr = const T*
>
class const_multi_array_ref :
public detail::multi_array::multi_array_impl_base<T,NumDims>
{
typedef detail::multi_array::multi_array_impl_base<T,NumDims> super_type;
public:
typedef typename super_type::value_type value_type;
typedef typename super_type::const_reference const_reference;
typedef typename super_type::const_iterator const_iterator;
typedef typename super_type::const_reverse_iterator const_reverse_iterator;
typedef typename super_type::element element;
typedef typename super_type::size_type size_type;
typedef typename super_type::difference_type difference_type;
typedef typename super_type::index index;
typedef typename super_type::extent_range extent_range;
typedef general_storage_order<NumDims> storage_order_type;
// template typedefs
template <std::size_t NDims>
struct const_array_view {
typedef boost::detail::multi_array::const_multi_array_view<T,NDims> type;
};
template <std::size_t NDims>
struct array_view {
typedef boost::detail::multi_array::multi_array_view<T,NDims> type;
};
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
// make const_multi_array_ref a friend of itself
template <typename,std::size_t,typename>
friend class const_multi_array_ref;
#endif
// This ensures that const_multi_array_ref types with different TPtr
// types can convert to each other
template <typename OPtr>
const_multi_array_ref(const const_multi_array_ref<T,NumDims,OPtr>& other)
: base_(other.base_), storage_(other.storage_),
extent_list_(other.extent_list_),
stride_list_(other.stride_list_),
index_base_list_(other.index_base_list_),
origin_offset_(other.origin_offset_),
directional_offset_(other.directional_offset_),
num_elements_(other.num_elements_) { }
template <typename ExtentList>
explicit const_multi_array_ref(TPtr base, const ExtentList& extents) :
base_(base), storage_(c_storage_order()) {
boost::function_requires<
CollectionConcept<ExtentList> >();
index_base_list_.assign(0);
init_multi_array_ref(extents.begin());
}
template <typename ExtentList>
explicit const_multi_array_ref(TPtr base, const ExtentList& extents,
const general_storage_order<NumDims>& so) :
base_(base), storage_(so) {
boost::function_requires<
CollectionConcept<ExtentList> >();
index_base_list_.assign(0);
init_multi_array_ref(extents.begin());
}
explicit const_multi_array_ref(TPtr base,
const detail::multi_array::
extent_gen<NumDims>& ranges) :
base_(base), storage_(c_storage_order()) {
init_from_extent_gen(ranges);
}
explicit const_multi_array_ref(TPtr base,
const detail::multi_array::
extent_gen<NumDims>& ranges,
const general_storage_order<NumDims>& so) :
base_(base), storage_(so) {
init_from_extent_gen(ranges);
}
template <class InputIterator>
void assign(InputIterator begin, InputIterator end) {
boost::function_requires<InputIteratorConcept<InputIterator> >();
InputIterator in_iter = begin;
T* out_iter = base_;
std::size_t copy_count=0;
while (in_iter != end && copy_count < num_elements_) {
*out_iter++ = *in_iter++;
copy_count++;
}
}
template <class BaseList>
#ifdef BOOST_NO_SFINAE
void
#else
typename
disable_if<typename boost::is_integral<BaseList>::type,void >::type
#endif // BOOST_NO_SFINAE
reindex(const BaseList& values) {
boost::function_requires<
CollectionConcept<BaseList> >();
boost::detail::multi_array::
copy_n(values.begin(),num_dimensions(),index_base_list_.begin());
origin_offset_ =
this->calculate_origin_offset(stride_list_,extent_list_,
storage_,index_base_list_);
}
void reindex(index value) {
index_base_list_.assign(value);
origin_offset_ =
this->calculate_origin_offset(stride_list_,extent_list_,
storage_,index_base_list_);
}
template <typename SizeList>
void reshape(const SizeList& extents) {
boost::function_requires<
CollectionConcept<SizeList> >();
BOOST_ASSERT(num_elements_ ==
std::accumulate(extents.begin(),extents.end(),
size_type(1),std::multiplies<size_type>()));
std::copy(extents.begin(),extents.end(),extent_list_.begin());
this->compute_strides(stride_list_,extent_list_,storage_);
origin_offset_ =
this->calculate_origin_offset(stride_list_,extent_list_,
storage_,index_base_list_);
}
size_type num_dimensions() const { return NumDims; }
size_type size() const { return extent_list_.front(); }
// given reshaping functionality, this is the max possible size.
size_type max_size() const { return num_elements(); }
bool empty() const { return size() == 0; }
const size_type* shape() const {
return extent_list_.data();
}
const index* strides() const {
return stride_list_.data();
}
const element* origin() const { return base_+origin_offset_; }
const element* data() const { return base_; }
size_type num_elements() const { return num_elements_; }
const index* index_bases() const {
return index_base_list_.data();
}
const storage_order_type& storage_order() const {
return storage_;
}
template <typename IndexList>
const element& operator()(IndexList indices) const {
boost::function_requires<
CollectionConcept<IndexList> >();
return super_type::access_element(boost::type<const element&>(),
indices,origin(),
shape(),strides(),index_bases());
}
// Only allow const element access
const_reference operator[](index idx) const {
return super_type::access(boost::type<const_reference>(),
idx,origin(),
shape(),strides(),index_bases());
}
// see generate_array_view in base.hpp
template <int NDims>
typename const_array_view<NDims>::type
operator[](const detail::multi_array::
index_gen<NumDims,NDims>& indices)
const {
typedef typename const_array_view<NDims>::type return_type;
return
super_type::generate_array_view(boost::type<return_type>(),
indices,
shape(),
strides(),
index_bases(),
origin());
}
const_iterator begin() const {
return const_iterator(*index_bases(),origin(),
shape(),strides(),index_bases());
}
const_iterator end() const {
return const_iterator(*index_bases()+(index)*shape(),origin(),
shape(),strides(),index_bases());
}
const_reverse_iterator rbegin() const {
return const_reverse_iterator(end());
}
const_reverse_iterator rend() const {
return const_reverse_iterator(begin());
}
template <typename OPtr>
bool operator==(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
if(std::equal(extent_list_.begin(),
extent_list_.end(),
rhs.extent_list_.begin()))
return std::equal(begin(),end(),rhs.begin());
else return false;
}
template <typename OPtr>
bool operator<(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
return std::lexicographical_compare(begin(),end(),rhs.begin(),rhs.end());
}
template <typename OPtr>
bool operator!=(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
return !(*this == rhs);
}
template <typename OPtr>
bool operator>(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
return rhs < *this;
}
template <typename OPtr>
bool operator<=(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
return !(*this > rhs);
}
template <typename OPtr>
bool operator>=(const
const_multi_array_ref<T,NumDims,OPtr>& rhs)
const {
return !(*this < rhs);
}
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
protected:
#else
public:
#endif
typedef boost::array<size_type,NumDims> size_list;
typedef boost::array<index,NumDims> index_list;
// This is used by multi_array, which is a subclass of this
void set_base_ptr(TPtr new_base) { base_ = new_base; }
// This constructor supports multi_array's default constructor
// and constructors from multi_array_ref, subarray, and array_view
explicit
const_multi_array_ref(TPtr base,
const storage_order_type& so,
const index * index_bases,
const size_type* extents) :
base_(base), storage_(so), origin_offset_(0), directional_offset_(0)
{
// If index_bases or extents is null, then initialize the corresponding
// private data to zeroed lists.
if(index_bases) {
boost::detail::multi_array::
copy_n(index_bases,NumDims,index_base_list_.begin());
} else {
std::fill_n(index_base_list_.begin(),NumDims,0);
}
if(extents) {
init_multi_array_ref(extents);
} else {
boost::array<index,NumDims> extent_list;
extent_list.assign(0);
init_multi_array_ref(extent_list.begin());
}
}
TPtr base_;
storage_order_type storage_;
size_list extent_list_;
index_list stride_list_;
index_list index_base_list_;
index origin_offset_;
index directional_offset_;
size_type num_elements_;
private:
// const_multi_array_ref cannot be assigned to (no deep copies!)
const_multi_array_ref& operator=(const const_multi_array_ref& other);
void init_from_extent_gen(const
detail::multi_array::
extent_gen<NumDims>& ranges) {
typedef boost::array<index,NumDims> extent_list;
// get the index_base values
std::transform(ranges.ranges_.begin(),ranges.ranges_.end(),
index_base_list_.begin(),
boost::mem_fun_ref(&extent_range::start));
// calculate the extents
extent_list extents;
std::transform(ranges.ranges_.begin(),ranges.ranges_.end(),
extents.begin(),
boost::mem_fun_ref(&extent_range::size));
init_multi_array_ref(extents.begin());
}
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
protected:
#else
public:
#endif
// RG - move me!
template <class InputIterator>
void init_multi_array_ref(InputIterator extents_iter) {
boost::function_requires<InputIteratorConcept<InputIterator> >();
boost::detail::multi_array::
copy_n(extents_iter,num_dimensions(),extent_list_.begin());
// Calculate the array size
num_elements_ = std::accumulate(extent_list_.begin(),extent_list_.end(),
size_type(1),std::multiplies<size_type>());
this->compute_strides(stride_list_,extent_list_,storage_);
origin_offset_ =
this->calculate_origin_offset(stride_list_,extent_list_,
storage_,index_base_list_);
directional_offset_ =
this->calculate_descending_dimension_offset(stride_list_,extent_list_,
storage_);
}
};
template <typename T, std::size_t NumDims>
class multi_array_ref :
public const_multi_array_ref<T,NumDims,T*>
{
typedef const_multi_array_ref<T,NumDims,T*> super_type;
public:
typedef typename super_type::value_type value_type;
typedef typename super_type::reference reference;
typedef typename super_type::iterator iterator;
typedef typename super_type::reverse_iterator reverse_iterator;
typedef typename super_type::const_reference const_reference;
typedef typename super_type::const_iterator const_iterator;
typedef typename super_type::const_reverse_iterator const_reverse_iterator;
typedef typename super_type::element element;
typedef typename super_type::size_type size_type;
typedef typename super_type::difference_type difference_type;
typedef typename super_type::index index;
typedef typename super_type::extent_range extent_range;
typedef typename super_type::storage_order_type storage_order_type;
typedef typename super_type::index_list index_list;
typedef typename super_type::size_list size_list;
template <std::size_t NDims>
struct const_array_view {
typedef boost::detail::multi_array::const_multi_array_view<T,NDims> type;
};
template <std::size_t NDims>
struct array_view {
typedef boost::detail::multi_array::multi_array_view<T,NDims> type;
};
template <class ExtentList>
explicit multi_array_ref(T* base, const ExtentList& extents) :
super_type(base,extents) {
boost::function_requires<
CollectionConcept<ExtentList> >();
}
template <class ExtentList>
explicit multi_array_ref(T* base, const ExtentList& extents,
const general_storage_order<NumDims>& so) :
super_type(base,extents,so) {
boost::function_requires<
CollectionConcept<ExtentList> >();
}
explicit multi_array_ref(T* base,
const detail::multi_array::
extent_gen<NumDims>& ranges) :
super_type(base,ranges) { }
explicit multi_array_ref(T* base,
const detail::multi_array::
extent_gen<NumDims>&
ranges,
const general_storage_order<NumDims>& so) :
super_type(base,ranges,so) { }
// Assignment from other ConstMultiArray types.
template <typename ConstMultiArray>
multi_array_ref& operator=(const ConstMultiArray& other) {
function_requires<
multi_array_concepts::
ConstMultiArrayConcept<ConstMultiArray,NumDims> >();
// make sure the dimensions agree
BOOST_ASSERT(other.num_dimensions() == this->num_dimensions());
BOOST_ASSERT(std::equal(other.shape(),other.shape()+this->num_dimensions(),
this->shape()));
// iterator-based copy
std::copy(other.begin(),other.end(),this->begin());
return *this;
}
multi_array_ref& operator=(const multi_array_ref& other) {
if (&other != this) {
// make sure the dimensions agree
BOOST_ASSERT(other.num_dimensions() == this->num_dimensions());
BOOST_ASSERT(std::equal(other.shape(),
other.shape()+this->num_dimensions(),
this->shape()));
// iterator-based copy
std::copy(other.begin(),other.end(),this->begin());
}
return *this;
}
element* origin() { return super_type::base_+super_type::origin_offset_; }
element* data() { return super_type::base_; }
template <class IndexList>
element& operator()(const IndexList& indices) {
boost::function_requires<
CollectionConcept<IndexList> >();
return super_type::access_element(boost::type<element&>(),
indices,origin(),
this->shape(),this->strides(),
this->index_bases());
}
reference operator[](index idx) {
return super_type::access(boost::type<reference>(),
idx,origin(),
this->shape(),this->strides(),
this->index_bases());
}
// See note attached to generate_array_view in base.hpp
template <int NDims>
typename array_view<NDims>::type
operator[](const detail::multi_array::
index_gen<NumDims,NDims>& indices) {
typedef typename array_view<NDims>::type return_type;
return
super_type::generate_array_view(boost::type<return_type>(),
indices,
this->shape(),
this->strides(),
this->index_bases(),
origin());
}
iterator begin() {
return iterator(*this->index_bases(),origin(),this->shape(),
this->strides(),this->index_bases());
}
iterator end() {
return iterator(*this->index_bases()+(index)*this->shape(),origin(),
this->shape(),this->strides(),
this->index_bases());
}
// rbegin() and rend() written naively to thwart MSVC ICE.
reverse_iterator rbegin() {
reverse_iterator ri(end());
return ri;
}
reverse_iterator rend() {
reverse_iterator ri(begin());
return ri;
}
// Using declarations don't seem to work for g++
// These are the proxies to work around this.
const element* origin() const { return super_type::origin(); }
const element* data() const { return super_type::data(); }
template <class IndexList>
const element& operator()(const IndexList& indices) const {
boost::function_requires<
CollectionConcept<IndexList> >();
return super_type::operator()(indices);
}
const_reference operator[](index idx) const {
return super_type::access(boost::type<const_reference>(),
idx,origin(),
this->shape(),this->strides(),
this->index_bases());
}
// See note attached to generate_array_view in base.hpp
template <int NDims>
typename const_array_view<NDims>::type
operator[](const detail::multi_array::
index_gen<NumDims,NDims>& indices)
const {
return super_type::operator[](indices);
}
const_iterator begin() const {
return super_type::begin();
}
const_iterator end() const {
return super_type::end();
}
const_reverse_iterator rbegin() const {
return super_type::rbegin();
}
const_reverse_iterator rend() const {
return super_type::rend();
}
protected:
// This is only supplied to support multi_array's default constructor
explicit multi_array_ref(T* base,
const storage_order_type& so,
const index* index_bases,
const size_type* extents) :
super_type(base,so,index_bases,extents) { }
};
} // namespace boost
#endif