base.hpp source code [boost/boost/multi_array/base.hpp]

1	// Copyright 2002 The Trustees of Indiana University.
2
3	// Use, modification and distribution is subject to the Boost Software
4	// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
5	// http://www.boost.org/LICENSE_1_0.txt)
6
7	// Boost.MultiArray Library
8	// Authors: Ronald Garcia
9	// Jeremy Siek
10	// Andrew Lumsdaine
11	// See http://www.boost.org/libs/multi_array for documentation.
12
13	#ifndef BASE_RG071801_HPP
14	#define BASE_RG071801_HPP
15
16	//
17	// base.hpp - some implementation base classes for from which
18	// functionality is acquired
19	//
20
21	#include "boost/multi_array/extent_range.hpp"
22	#include "boost/multi_array/extent_gen.hpp"
23	#include "boost/multi_array/index_range.hpp"
24	#include "boost/multi_array/index_gen.hpp"
25	#include "boost/multi_array/storage_order.hpp"
26	#include "boost/multi_array/types.hpp"
27	#include "boost/config.hpp"
28	#include "boost/multi_array/concept_checks.hpp" //for ignore_unused_...
29	#include "boost/mpl/eval_if.hpp"
30	#include "boost/mpl/if.hpp"
31	#include "boost/mpl/size_t.hpp"
32	#include "boost/iterator/reverse_iterator.hpp"
33	#include "boost/static_assert.hpp"
34	#include "boost/type.hpp"
35	#include "boost/assert.hpp"
36	#include <cstddef>
37	#include <memory>
38
39	namespace boost {
40
41	/////////////////////////////////////////////////////////////////////////
42	// class declarations
43	/////////////////////////////////////////////////////////////////////////
44
45	template<typename T, std::size_t NumDims,
46	typename Allocator = std::allocator<T> >
47	class multi_array;
48
49	// This is a public interface for use by end users!
50	namespace multi_array_types {
51	typedef boost::detail::multi_array::size_type size_type;
52	typedef std::ptrdiff_t difference_type;
53	typedef boost::detail::multi_array::index index;
54	typedef detail::multi_array::index_range<index,size_type> index_range;
55	typedef detail::multi_array::extent_range<index,size_type> extent_range;
56	typedef detail::multi_array::index_gen<`0`,`0`> index_gen;
57	typedef detail::multi_array::extent_gen<`0`> extent_gen;
58	}
59
60
61	// boost::extents and boost::indices are now a part of the public
62	// interface. That way users don't necessarily have to create their
63	// own objects. On the other hand, one may not want the overhead of
64	// object creation in small-memory environments. Thus, the objects
65	// can be left undefined by defining BOOST_MULTI_ARRAY_NO_GENERATORS
66	// before loading multi_array.hpp.
67	#ifndef BOOST_MULTI_ARRAY_NO_GENERATORS
68	namespace {
69	multi_array_types::extent_gen extents;
70	multi_array_types::index_gen indices;
71	}
72	#endif // BOOST_MULTI_ARRAY_NO_GENERATORS
73
74	namespace detail {
75	namespace multi_array {
76
77	template <typename T, std::size_t NumDims>
78	class sub_array;
79
80	template <typename T, std::size_t NumDims, typename TPtr = const T*>
81	class const_sub_array;
82
83	template <typename T, typename TPtr, typename NumDims, typename Reference,
84	typename IteratorCategory>
85	class array_iterator;
86
87	template <typename T, std::size_t NumDims, typename TPtr = const T*>
88	class const_multi_array_view;
89
90	template <typename T, std::size_t NumDims>
91	class multi_array_view;
92
93	/////////////////////////////////////////////////////////////////////////
94	// class interfaces
95	/////////////////////////////////////////////////////////////////////////
96
97	class multi_array_base {
98	public:
99	typedef multi_array_types::size_type size_type;
100	typedef multi_array_types::difference_type difference_type;
101	typedef multi_array_types::index index;
102	typedef multi_array_types::index_range index_range;
103	typedef multi_array_types::extent_range extent_range;
104	typedef multi_array_types::index_gen index_gen;
105	typedef multi_array_types::extent_gen extent_gen;
106	};
107
108	//
109	// value_accessor_n
110	// contains the routines for accessing elements from
111	// N-dimensional views.
112	//
113	template<typename T, std::size_t NumDims>
114	class value_accessor_n : public multi_array_base {
115	typedef multi_array_base super_type;
116	public:
117	typedef typename super_type::index index;
118
119	//
120	// public typedefs used by classes that inherit from this base
121	//
122	typedef T element;
123	typedef boost::multi_array<T,NumDims-`1`> value_type;
124	typedef sub_array<T,NumDims-`1`> reference;
125	typedef const_sub_array<T,NumDims-`1`> const_reference;
126
127	protected:
128	// used by array operator[] and iterators to get reference types.
129	template <typename Reference, typename TPtr>
130	Reference access(boost::type<Reference>,index idx,TPtr base,
131	const size_type* extents,
132	const index* strides,
133	const index* index_bases) const {
134
135	BOOST_ASSERT(idx - index_bases[`0`] >= `0`);
136	BOOST_ASSERT(size_type(idx - index_bases[`0`]) < extents[`0`]);
137	// return a sub_array<T,NDims-1> proxy object
138	TPtr newbase = base + idx * strides[`0`];
139	return Reference(newbase,extents+`1`,strides+`1`,index_bases+`1`);
140
141	}
142
143	value_accessor_n() { }
144	~value_accessor_n() { }
145	};
146
147
148
149	//
150	// value_accessor_one
151	// contains the routines for accessing reference elements from
152	// 1-dimensional views.
153	//
154	template<typename T>
155	class value_accessor_one : public multi_array_base {
156	typedef multi_array_base super_type;
157	public:
158	typedef typename super_type::index index;
159	//
160	// public typedefs for use by classes that inherit it.
161	//
162	typedef T element;
163	typedef T value_type;
164	typedef T& reference;
165	typedef T const& const_reference;
166
167	protected:
168	// used by array operator[] and iterators to get reference types.
169	template <typename Reference, typename TPtr>
170	Reference access(boost::type<Reference>,index idx,TPtr base,
171	const size_type* extents,
172	const index* strides,
173	const index* index_bases) const {
174
175	ignore_unused_variable_warning(index_bases);
176	ignore_unused_variable_warning(extents);
177	BOOST_ASSERT(idx - index_bases[`0`] >= `0`);
178	BOOST_ASSERT(size_type(idx - index_bases[`0`]) < extents[`0`]);
179	return (base + idx strides[`0`]);
180	}
181
182	value_accessor_one() { }
183	~value_accessor_one() { }
184	};
185
186
187	/////////////////////////////////////////////////////////////////////////
188	// choose value accessor begins
189	//
190
191	template <typename T, std::size_t NumDims>
192	struct choose_value_accessor_n {
193	typedef value_accessor_n<T,NumDims> type;
194	};
195
196	template <typename T>
197	struct choose_value_accessor_one {
198	typedef value_accessor_one<T> type;
199	};
200
201	template <typename T, typename NumDims>
202	struct value_accessor_generator {
203	BOOST_STATIC_CONSTANT(std::size_t, dimensionality = NumDims::value);
204
205	typedef typename
206	mpl::eval_if_c<(dimensionality == `1`),
207	choose_value_accessor_one<T>,
208	choose_value_accessor_n<T,dimensionality>
209	>::type type;
210	};
211
212	template <class T, class NumDims>
213	struct associated_types
214	: value_accessor_generator<T,NumDims>::type
215	{};
216
217	//
218	// choose value accessor ends
219	/////////////////////////////////////////////////////////////////////////
220
221	// Due to some imprecision in the C++ Standard,
222	// MSVC 2010 is broken in debug mode: it requires
223	// that an Output Iterator have output_iterator_tag in its iterator_category if
224	// that iterator is not bidirectional_iterator or random_access_iterator.
225	#if BOOST_WORKAROUND(BOOST_MSVC, >= 1600)
226	struct mutable_iterator_tag
227	: boost::random_access_traversal_tag, std::input_iterator_tag
228	{
229	operator std::output_iterator_tag() const {
230	return std::output_iterator_tag();
231	}
232	};
233	#endif
234
235	////////////////////////////////////////////////////////////////////////
236	// multi_array_base
237	////////////////////////////////////////////////////////////////////////
238	template <typename T, std::size_t NumDims>
239	class multi_array_impl_base
240	:
241	public value_accessor_generator<T,mpl::size_t<NumDims> >::type
242	{
243	typedef associated_types<T,mpl::size_t<NumDims> > types;
244	public:
245	typedef typename types::index index;
246	typedef typename types::size_type size_type;
247	typedef typename types::element element;
248	typedef typename types::index_range index_range;
249	typedef typename types::value_type value_type;
250	typedef typename types::reference reference;
251	typedef typename types::const_reference const_reference;
252
253	template <std::size_t NDims>
254	struct subarray {
255	typedef boost::detail::multi_array::sub_array<T,NDims> type;
256	};
257
258	template <std::size_t NDims>
259	struct const_subarray {
260	typedef boost::detail::multi_array::const_sub_array<T,NDims> type;
261	};
262
263	template <std::size_t NDims>
264	struct array_view {
265	typedef boost::detail::multi_array::multi_array_view<T,NDims> type;
266	};
267
268	template <std::size_t NDims>
269	struct const_array_view {
270	public:
271	typedef boost::detail::multi_array::const_multi_array_view<T,NDims> type;
272	};
273
274	//
275	// iterator support
276	//
277	#if BOOST_WORKAROUND(BOOST_MSVC, >= 1600)
278	// Deal with VC 2010 output_iterator_tag requirement
279	typedef array_iterator<T,T*,mpl::size_t<NumDims>,reference,
280	mutable_iterator_tag> iterator;
281	#else
282	typedef array_iterator<T,T*,mpl::size_t<NumDims>,reference,
283	boost::random_access_traversal_tag> iterator;
284	#endif
285	typedef array_iterator<T,T const*,mpl::size_t<NumDims>,const_reference,
286	boost::random_access_traversal_tag> const_iterator;
287
288	typedef ::boost::reverse_iterator<iterator> reverse_iterator;
289	typedef ::boost::reverse_iterator<const_iterator> const_reverse_iterator;
290
291	BOOST_STATIC_CONSTANT(std::size_t, dimensionality = NumDims);
292	protected:
293
294	multi_array_impl_base() { }
295	~multi_array_impl_base() { }
296
297	// Used by operator() in our array classes
298	template <typename Reference, typename IndexList, typename TPtr>
299	Reference access_element(boost::type<Reference>,
300	const IndexList& indices,
301	TPtr base,
302	const size_type* extents,
303	const index* strides,
304	const index* index_bases) const {
305	boost::function_requires<
306	CollectionConcept<IndexList> >();
307	ignore_unused_variable_warning(index_bases);
308	ignore_unused_variable_warning(extents);
309	#if !defined(NDEBUG) && !defined(BOOST_DISABLE_ASSERTS)
310	for (size_type i = `0`; i != NumDims; ++i) {
311	BOOST_ASSERT(indices[i] - index_bases[i] >= `0`);
312	BOOST_ASSERT(size_type(indices[i] - index_bases[i]) < extents[i]);
313	}
314	#endif
315
316	index offset = `0`;
317	{
318	typename IndexList::const_iterator i = indices.begin();
319	size_type n = `0`;
320	while (n != NumDims) {
321	offset += (i) strides[n];
322	++n;
323	++i;
324	}
325	}
326	return base[offset];
327	}
328
329	template <typename StrideList, typename ExtentList>
330	void compute_strides(StrideList& stride_list, ExtentList& extent_list,
331	const general_storage_order<NumDims>& storage)
332	{
333	// invariant: stride = the stride for dimension n
334	index stride = `1`;
335	for (size_type n = `0`; n != NumDims; ++n) {
336	index stride_sign = +`1`;
337
338	if (!storage.ascending(storage.ordering(n)))
339	stride_sign = -`1`;
340
341	// The stride for this dimension is the product of the
342	// lengths of the ranks minor to it.
343	stride_list[storage.ordering(n)] = stride * stride_sign;
344
345	stride *= extent_list[storage.ordering(n)];
346	}
347	}
348
349	// This calculates the offset to the array base pointer due to:
350	// 1. dimensions stored in descending order
351	// 2. non-zero dimension index bases
352	template <typename StrideList, typename ExtentList, typename BaseList>
353	index
354	calculate_origin_offset(const StrideList& stride_list,
355	const ExtentList& extent_list,
356	const general_storage_order<NumDims>& storage,
357	const BaseList& index_base_list)
358	{
359	return
360	calculate_descending_dimension_offset(stride_list,extent_list,
361	storage) +
362	calculate_indexing_offset(stride_list,index_base_list);
363	}
364
365	// This calculates the offset added to the base pointer that are
366	// caused by descending dimensions
367	template <typename StrideList, typename ExtentList>
368	index
369	calculate_descending_dimension_offset(const StrideList& stride_list,
370	const ExtentList& extent_list,
371	const general_storage_order<NumDims>& storage)
372	{
373	index offset = `0`;
374	if (!storage.all_dims_ascending())
375	for (size_type n = `0`; n != NumDims; ++n)
376	if (!storage.ascending(n))
377	offset -= (extent_list[n] - `1`) * stride_list[n];
378
379	return offset;
380	}
381
382	// This is used to reindex array_views, which are no longer
383	// concerned about storage order (specifically, whether dimensions
384	// are ascending or descending) since the viewed array handled it.
385
386	template <typename StrideList, typename BaseList>
387	index
388	calculate_indexing_offset(const StrideList& stride_list,
389	const BaseList& index_base_list)
390	{
391	index offset = `0`;
392	for (size_type n = `0`; n != NumDims; ++n)
393	offset -= stride_list[n] * index_base_list[n];
394	return offset;
395	}
396
397	// Slicing using an index_gen.
398	// Note that populating an index_gen creates a type that encodes
399	// both the number of dimensions in the current Array (NumDims), and
400	// the Number of dimensions for the resulting view. This allows the
401	// compiler to fail if the dimensions aren't completely accounted
402	// for. For reasons unbeknownst to me, a BOOST_STATIC_ASSERT
403	// within the member function template does not work. I should add a
404	// note to the documentation specifying that you get a damn ugly
405	// error message if you screw up in your slicing code.
406	template <typename ArrayRef, int NDims, typename TPtr>
407	ArrayRef
408	generate_array_view(boost::type<ArrayRef>,
409	const boost::detail::multi_array::
410	index_gen<NumDims,NDims>& indices,
411	const size_type* extents,
412	const index* strides,
413	const index* index_bases,
414	TPtr base) const {
415
416	boost::array<index,NDims> new_strides;
417	boost::array<index,NDims> new_extents;
418
419	index offset = `0`;
420	size_type dim = `0`;
421	for (size_type n = `0`; n != NumDims; ++n) {
422
423	// Use array specs and input specs to produce real specs.
424	const index default_start = index_bases[n];
425	const index default_finish = default_start+extents[n];
426	const index_range& current_range = indices.ranges_[n];
427	index start = current_range.get_start(default_start);
428	index finish = current_range.get_finish(default_finish);
429	index stride = current_range.stride();
430	BOOST_ASSERT(stride != `0`);
431
432	// An index range indicates a half-open strided interval
433	// [start,finish) (with stride) which faces upward when stride
434	// is positive and downward when stride is negative,
435
436	// RG: The following code for calculating length suffers from
437	// some representation issues: if finish-start cannot be represented as
438	// by type index, then overflow may result.
439
440	index len;
441	if ((finish - start) / stride < `0`) {
442	// [start,finish) is empty according to the direction imposed by
443	// the stride.
444	len = `0`;
445	} else {
446	// integral trick for ceiling((finish-start) / stride)
447	// taking into account signs.
448	index shrinkage = stride > `0` ? `1` : -`1`;
449	len = (finish - start + (stride - shrinkage)) / stride;
450	}
451
452	// start marks the closed side of the range, so it must lie
453	// exactly in the set of legal indices
454	// with a special case for empty arrays
455	BOOST_ASSERT(index_bases[n] <= start &&
456	((start <= index_bases[n]+index(extents[n])) \|\|
457	(start == index_bases[n] && extents[n] == `0`)));
458
459	#ifndef BOOST_DISABLE_ASSERTS
460	// finish marks the open side of the range, so it can go one past
461	// the "far side" of the range (the top if stride is positive, the bottom
462	// if stride is negative).
463	index bound_adjustment = stride < `0` ? `1` : `0`;
464	BOOST_ASSERT(((index_bases[n] - bound_adjustment) <= finish) &&
465	(finish <= (index_bases[n] + index(extents[n]) - bound_adjustment)));
466	#endif // BOOST_DISABLE_ASSERTS
467
468
469	// the array data pointer is modified to account for non-zero
470	// bases during slicing (see [Garcia] for the math involved)
471	offset += start * strides[n];
472
473	if (!current_range.is_degenerate()) {
474
475	// The stride for each dimension is included into the
476	// strides for the array_view (see [Garcia] for the math involved).
477	new_strides[dim] = stride * strides[n];
478
479	// calculate new extents
480	new_extents[dim] = len;
481	++dim;
482	}
483	}
484	BOOST_ASSERT(dim == NDims);
485
486	return
487	ArrayRef(base+offset,
488	new_extents,
489	new_strides);
490	}
491
492
493	};
494
495	} // namespace multi_array
496	} // namespace detail
497
498	} // namespace boost
499
500	#endif // BASE_RG071801_HPP
501

source code of boost/boost/multi_array/base.hpp