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annotate DEPENDENCIES/generic/include/boost/numeric/ublas/traits.hpp @ 133:4acb5d8d80b6 tip

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Don't fail environmental check if README.md exists (but .txt and no-suffix don't)
author Chris Cannam
date Tue, 30 Jul 2019 12:25:44 +0100
parents c530137014c0
children
rev   line source
Chris@16 1 //
Chris@16 2 // Copyright (c) 2000-2002
Chris@16 3 // Joerg Walter, Mathias Koch
Chris@16 4 //
Chris@16 5 // Distributed under the Boost Software License, Version 1.0. (See
Chris@16 6 // accompanying file LICENSE_1_0.txt or copy at
Chris@16 7 // http://www.boost.org/LICENSE_1_0.txt)
Chris@16 8 //
Chris@16 9 // The authors gratefully acknowledge the support of
Chris@16 10 // GeNeSys mbH & Co. KG in producing this work.
Chris@16 11 //
Chris@16 12
Chris@16 13 #ifndef _BOOST_UBLAS_TRAITS_
Chris@16 14 #define _BOOST_UBLAS_TRAITS_
Chris@16 15
Chris@16 16 #include <iterator>
Chris@16 17 #include <complex>
Chris@16 18 #include <boost/config/no_tr1/cmath.hpp>
Chris@16 19
Chris@16 20 #include <boost/numeric/ublas/detail/config.hpp>
Chris@16 21 #include <boost/numeric/ublas/detail/iterator.hpp>
Chris@16 22 #include <boost/numeric/ublas/detail/returntype_deduction.hpp>
Chris@101 23 #ifdef BOOST_UBLAS_USE_INTERVAL
Chris@101 24 #include <boost/numeric/interval.hpp>
Chris@101 25 #endif
Chris@16 26
Chris@16 27 #include <boost/type_traits.hpp>
Chris@16 28 #include <complex>
Chris@16 29 #include <boost/typeof/typeof.hpp>
Chris@16 30 #include <boost/utility/enable_if.hpp>
Chris@16 31 #include <boost/type_traits/is_float.hpp>
Chris@16 32 #include <boost/type_traits/is_integral.hpp>
Chris@101 33 #include <boost/type_traits/is_unsigned.hpp>
Chris@16 34 #include <boost/mpl/and.hpp>
Chris@16 35
Chris@16 36 // anonymous namespace to avoid ADL issues
Chris@16 37 namespace {
Chris@16 38 template<class T> T boost_numeric_ublas_sqrt (const T& t) {
Chris@16 39 using namespace std;
Chris@16 40 // we'll find either std::sqrt or else another version via ADL:
Chris@16 41 return sqrt (t);
Chris@16 42 }
Chris@101 43
Chris@101 44 template<typename T>
Chris@101 45 inline typename boost::disable_if<
Chris@101 46 boost::is_unsigned<T>, T >::type
Chris@101 47 boost_numeric_ublas_abs (const T &t ) {
Chris@101 48 using namespace std;
Chris@101 49 return abs( t );
Chris@101 50 }
Chris@101 51
Chris@101 52 template<typename T>
Chris@101 53 inline typename boost::enable_if<
Chris@101 54 boost::is_unsigned<T>, T >::type
Chris@101 55 boost_numeric_ublas_abs (const T &t ) {
Chris@101 56 return t;
Chris@101 57 }
Chris@16 58 }
Chris@16 59
Chris@16 60 namespace boost { namespace numeric { namespace ublas {
Chris@16 61
Chris@101 62
Chris@101 63 template<typename R, typename I>
Chris@101 64 typename boost::enable_if<
Chris@101 65 mpl::and_<
Chris@101 66 boost::is_float<R>,
Chris@101 67 boost::is_integral<I>
Chris@101 68 >,
Chris@101 69 std::complex<R> >::type inline operator+ (I in1, std::complex<R> const& in2 ) {
Chris@101 70 return R (in1) + in2;
Chris@101 71 }
Chris@101 72
Chris@101 73 template<typename R, typename I>
Chris@101 74 typename boost::enable_if<
Chris@101 75 mpl::and_<
Chris@101 76 boost::is_float<R>,
Chris@101 77 boost::is_integral<I>
Chris@101 78 >,
Chris@101 79 std::complex<R> >::type inline operator+ (std::complex<R> const& in1, I in2) {
Chris@101 80 return in1 + R (in2);
Chris@101 81 }
Chris@101 82
Chris@101 83 template<typename R, typename I>
Chris@101 84 typename boost::enable_if<
Chris@101 85 mpl::and_<
Chris@101 86 boost::is_float<R>,
Chris@101 87 boost::is_integral<I>
Chris@101 88 >,
Chris@101 89 std::complex<R> >::type inline operator- (I in1, std::complex<R> const& in2) {
Chris@101 90 return R (in1) - in2;
Chris@101 91 }
Chris@101 92
Chris@101 93 template<typename R, typename I>
Chris@101 94 typename boost::enable_if<
Chris@101 95 mpl::and_<
Chris@101 96 boost::is_float<R>,
Chris@101 97 boost::is_integral<I>
Chris@101 98 >,
Chris@101 99 std::complex<R> >::type inline operator- (std::complex<R> const& in1, I in2) {
Chris@101 100 return in1 - R (in2);
Chris@101 101 }
Chris@101 102
Chris@101 103 template<typename R, typename I>
Chris@101 104 typename boost::enable_if<
Chris@101 105 mpl::and_<
Chris@101 106 boost::is_float<R>,
Chris@101 107 boost::is_integral<I>
Chris@101 108 >,
Chris@101 109 std::complex<R> >::type inline operator* (I in1, std::complex<R> const& in2) {
Chris@101 110 return R (in1) * in2;
Chris@101 111 }
Chris@101 112
Chris@101 113 template<typename R, typename I>
Chris@101 114 typename boost::enable_if<
Chris@101 115 mpl::and_<
Chris@101 116 boost::is_float<R>,
Chris@101 117 boost::is_integral<I>
Chris@101 118 >,
Chris@101 119 std::complex<R> >::type inline operator* (std::complex<R> const& in1, I in2) {
Chris@101 120 return in1 * R(in2);
Chris@101 121 }
Chris@101 122
Chris@101 123 template<typename R, typename I>
Chris@101 124 typename boost::enable_if<
Chris@101 125 mpl::and_<
Chris@101 126 boost::is_float<R>,
Chris@101 127 boost::is_integral<I>
Chris@101 128 >,
Chris@101 129 std::complex<R> >::type inline operator/ (I in1, std::complex<R> const& in2) {
Chris@101 130 return R(in1) / in2;
Chris@101 131 }
Chris@101 132
Chris@101 133 template<typename R, typename I>
Chris@101 134 typename boost::enable_if<
Chris@101 135 mpl::and_<
Chris@101 136 boost::is_float<R>,
Chris@101 137 boost::is_integral<I>
Chris@101 138 >,
Chris@101 139 std::complex<R> >::type inline operator/ (std::complex<R> const& in1, I in2) {
Chris@101 140 return in1 / R (in2);
Chris@101 141 }
Chris@101 142
Chris@16 143 // Use Joel de Guzman's return type deduction
Chris@16 144 // uBLAS assumes a common return type for all binary arithmetic operators
Chris@16 145 template<class X, class Y>
Chris@16 146 struct promote_traits {
Chris@16 147 typedef type_deduction_detail::base_result_of<X, Y> base_type;
Chris@16 148 static typename base_type::x_type x;
Chris@16 149 static typename base_type::y_type y;
Chris@16 150 static const std::size_t size = sizeof (
Chris@16 151 type_deduction_detail::test<
Chris@16 152 typename base_type::x_type
Chris@16 153 , typename base_type::y_type
Chris@16 154 >(x + y) // Use x+y to stand of all the arithmetic actions
Chris@16 155 );
Chris@16 156
Chris@16 157 static const std::size_t index = (size / sizeof (char)) - 1;
Chris@16 158 typedef typename mpl::at_c<
Chris@16 159 typename base_type::types, index>::type id;
Chris@16 160 typedef typename id::type promote_type;
Chris@16 161 };
Chris@16 162
Chris@16 163
Chris@16 164
Chris@16 165 // Type traits - generic numeric properties and functions
Chris@16 166 template<class T>
Chris@16 167 struct type_traits;
Chris@16 168
Chris@16 169 // Define properties for a generic scalar type
Chris@16 170 template<class T>
Chris@16 171 struct scalar_traits {
Chris@16 172 typedef scalar_traits<T> self_type;
Chris@16 173 typedef T value_type;
Chris@16 174 typedef const T &const_reference;
Chris@16 175 typedef T &reference;
Chris@16 176
Chris@16 177 typedef T real_type;
Chris@16 178 typedef real_type precision_type; // we do not know what type has more precision then the real_type
Chris@16 179
Chris@16 180 static const unsigned plus_complexity = 1;
Chris@16 181 static const unsigned multiplies_complexity = 1;
Chris@16 182
Chris@16 183 static
Chris@16 184 BOOST_UBLAS_INLINE
Chris@16 185 real_type real (const_reference t) {
Chris@16 186 return t;
Chris@16 187 }
Chris@16 188 static
Chris@16 189 BOOST_UBLAS_INLINE
Chris@16 190 real_type imag (const_reference /*t*/) {
Chris@16 191 return 0;
Chris@16 192 }
Chris@16 193 static
Chris@16 194 BOOST_UBLAS_INLINE
Chris@16 195 value_type conj (const_reference t) {
Chris@16 196 return t;
Chris@16 197 }
Chris@16 198
Chris@16 199 static
Chris@16 200 BOOST_UBLAS_INLINE
Chris@16 201 real_type type_abs (const_reference t) {
Chris@16 202 return boost_numeric_ublas_abs (t);
Chris@16 203 }
Chris@16 204 static
Chris@16 205 BOOST_UBLAS_INLINE
Chris@16 206 value_type type_sqrt (const_reference t) {
Chris@16 207 // force a type conversion back to value_type for intgral types
Chris@16 208 return value_type (boost_numeric_ublas_sqrt (t));
Chris@16 209 }
Chris@16 210
Chris@16 211 static
Chris@16 212 BOOST_UBLAS_INLINE
Chris@16 213 real_type norm_1 (const_reference t) {
Chris@16 214 return self_type::type_abs (t);
Chris@16 215 }
Chris@16 216 static
Chris@16 217 BOOST_UBLAS_INLINE
Chris@16 218 real_type norm_2 (const_reference t) {
Chris@16 219 return self_type::type_abs (t);
Chris@16 220 }
Chris@16 221 static
Chris@16 222 BOOST_UBLAS_INLINE
Chris@16 223 real_type norm_inf (const_reference t) {
Chris@16 224 return self_type::type_abs (t);
Chris@16 225 }
Chris@16 226
Chris@16 227 static
Chris@16 228 BOOST_UBLAS_INLINE
Chris@16 229 bool equals (const_reference t1, const_reference t2) {
Chris@16 230 return self_type::norm_inf (t1 - t2) < BOOST_UBLAS_TYPE_CHECK_EPSILON *
Chris@16 231 (std::max) ((std::max) (self_type::norm_inf (t1),
Chris@16 232 self_type::norm_inf (t2)),
Chris@16 233 BOOST_UBLAS_TYPE_CHECK_MIN);
Chris@16 234 }
Chris@16 235 };
Chris@16 236
Chris@16 237 // Define default type traits, assume T is a scalar type
Chris@16 238 template<class T>
Chris@16 239 struct type_traits : scalar_traits <T> {
Chris@16 240 typedef type_traits<T> self_type;
Chris@16 241 typedef T value_type;
Chris@16 242 typedef const T &const_reference;
Chris@16 243 typedef T &reference;
Chris@16 244
Chris@16 245 typedef T real_type;
Chris@16 246 typedef real_type precision_type;
Chris@16 247 static const unsigned multiplies_complexity = 1;
Chris@16 248
Chris@16 249 };
Chris@16 250
Chris@16 251 // Define real type traits
Chris@16 252 template<>
Chris@16 253 struct type_traits<float> : scalar_traits<float> {
Chris@16 254 typedef type_traits<float> self_type;
Chris@16 255 typedef float value_type;
Chris@16 256 typedef const value_type &const_reference;
Chris@16 257 typedef value_type &reference;
Chris@16 258 typedef value_type real_type;
Chris@16 259 typedef double precision_type;
Chris@16 260 };
Chris@16 261 template<>
Chris@16 262 struct type_traits<double> : scalar_traits<double> {
Chris@16 263 typedef type_traits<double> self_type;
Chris@16 264 typedef double value_type;
Chris@16 265 typedef const value_type &const_reference;
Chris@16 266 typedef value_type &reference;
Chris@16 267 typedef value_type real_type;
Chris@16 268 typedef long double precision_type;
Chris@16 269 };
Chris@16 270 template<>
Chris@16 271 struct type_traits<long double> : scalar_traits<long double> {
Chris@16 272 typedef type_traits<long double> self_type;
Chris@16 273 typedef long double value_type;
Chris@16 274 typedef const value_type &const_reference;
Chris@16 275 typedef value_type &reference;
Chris@16 276 typedef value_type real_type;
Chris@16 277 typedef value_type precision_type;
Chris@16 278 };
Chris@16 279
Chris@16 280 // Define properties for a generic complex type
Chris@16 281 template<class T>
Chris@16 282 struct complex_traits {
Chris@16 283 typedef complex_traits<T> self_type;
Chris@16 284 typedef T value_type;
Chris@16 285 typedef const T &const_reference;
Chris@16 286 typedef T &reference;
Chris@16 287
Chris@16 288 typedef typename T::value_type real_type;
Chris@16 289 typedef real_type precision_type; // we do not know what type has more precision then the real_type
Chris@16 290
Chris@16 291 static const unsigned plus_complexity = 2;
Chris@16 292 static const unsigned multiplies_complexity = 6;
Chris@16 293
Chris@16 294 static
Chris@16 295 BOOST_UBLAS_INLINE
Chris@16 296 real_type real (const_reference t) {
Chris@16 297 return std::real (t);
Chris@16 298 }
Chris@16 299 static
Chris@16 300 BOOST_UBLAS_INLINE
Chris@16 301 real_type imag (const_reference t) {
Chris@16 302 return std::imag (t);
Chris@16 303 }
Chris@16 304 static
Chris@16 305 BOOST_UBLAS_INLINE
Chris@16 306 value_type conj (const_reference t) {
Chris@16 307 return std::conj (t);
Chris@16 308 }
Chris@16 309
Chris@16 310 static
Chris@16 311 BOOST_UBLAS_INLINE
Chris@16 312 real_type type_abs (const_reference t) {
Chris@16 313 return abs (t);
Chris@16 314 }
Chris@16 315 static
Chris@16 316 BOOST_UBLAS_INLINE
Chris@16 317 value_type type_sqrt (const_reference t) {
Chris@16 318 return sqrt (t);
Chris@16 319 }
Chris@16 320
Chris@16 321 static
Chris@16 322 BOOST_UBLAS_INLINE
Chris@16 323 real_type norm_1 (const_reference t) {
Chris@16 324 return self_type::type_abs (t);
Chris@16 325 // original computation has been replaced because a complex number should behave like a scalar type
Chris@16 326 // return type_traits<real_type>::type_abs (self_type::real (t)) +
Chris@16 327 // type_traits<real_type>::type_abs (self_type::imag (t));
Chris@16 328 }
Chris@16 329 static
Chris@16 330 BOOST_UBLAS_INLINE
Chris@16 331 real_type norm_2 (const_reference t) {
Chris@16 332 return self_type::type_abs (t);
Chris@16 333 }
Chris@16 334 static
Chris@16 335 BOOST_UBLAS_INLINE
Chris@16 336 real_type norm_inf (const_reference t) {
Chris@16 337 return self_type::type_abs (t);
Chris@16 338 // original computation has been replaced because a complex number should behave like a scalar type
Chris@16 339 // return (std::max) (type_traits<real_type>::type_abs (self_type::real (t)),
Chris@16 340 // type_traits<real_type>::type_abs (self_type::imag (t)));
Chris@16 341 }
Chris@16 342
Chris@16 343 static
Chris@16 344 BOOST_UBLAS_INLINE
Chris@16 345 bool equals (const_reference t1, const_reference t2) {
Chris@16 346 return self_type::norm_inf (t1 - t2) < BOOST_UBLAS_TYPE_CHECK_EPSILON *
Chris@16 347 (std::max) ((std::max) (self_type::norm_inf (t1),
Chris@16 348 self_type::norm_inf (t2)),
Chris@16 349 BOOST_UBLAS_TYPE_CHECK_MIN);
Chris@16 350 }
Chris@16 351 };
Chris@16 352
Chris@16 353 // Define complex type traits
Chris@16 354 template<>
Chris@16 355 struct type_traits<std::complex<float> > : complex_traits<std::complex<float> >{
Chris@16 356 typedef type_traits<std::complex<float> > self_type;
Chris@16 357 typedef std::complex<float> value_type;
Chris@16 358 typedef const value_type &const_reference;
Chris@16 359 typedef value_type &reference;
Chris@16 360 typedef float real_type;
Chris@16 361 typedef std::complex<double> precision_type;
Chris@16 362
Chris@16 363 };
Chris@16 364 template<>
Chris@16 365 struct type_traits<std::complex<double> > : complex_traits<std::complex<double> >{
Chris@16 366 typedef type_traits<std::complex<double> > self_type;
Chris@16 367 typedef std::complex<double> value_type;
Chris@16 368 typedef const value_type &const_reference;
Chris@16 369 typedef value_type &reference;
Chris@16 370 typedef double real_type;
Chris@16 371 typedef std::complex<long double> precision_type;
Chris@16 372 };
Chris@16 373 template<>
Chris@16 374 struct type_traits<std::complex<long double> > : complex_traits<std::complex<long double> > {
Chris@16 375 typedef type_traits<std::complex<long double> > self_type;
Chris@16 376 typedef std::complex<long double> value_type;
Chris@16 377 typedef const value_type &const_reference;
Chris@16 378 typedef value_type &reference;
Chris@16 379 typedef long double real_type;
Chris@16 380 typedef value_type precision_type;
Chris@16 381 };
Chris@16 382
Chris@16 383 #ifdef BOOST_UBLAS_USE_INTERVAL
Chris@16 384 // Define scalar interval type traits
Chris@16 385 template<>
Chris@16 386 struct type_traits<boost::numeric::interval<float> > : scalar_traits<boost::numeric::interval<float> > {
Chris@16 387 typedef type_traits<boost::numeric::interval<float> > self_type;
Chris@16 388 typedef boost::numeric::interval<float> value_type;
Chris@16 389 typedef const value_type &const_reference;
Chris@16 390 typedef value_type &reference;
Chris@16 391 typedef value_type real_type;
Chris@16 392 typedef boost::numeric::interval<double> precision_type;
Chris@16 393
Chris@16 394 };
Chris@16 395 template<>
Chris@16 396 struct type_traits<boost::numeric::interval<double> > : scalar_traits<boost::numeric::interval<double> > {
Chris@16 397 typedef type_traits<boost::numeric::interval<double> > self_type;
Chris@16 398 typedef boost::numeric::interval<double> value_type;
Chris@16 399 typedef const value_type &const_reference;
Chris@16 400 typedef value_type &reference;
Chris@16 401 typedef value_type real_type;
Chris@16 402 typedef boost::numeric::interval<long double> precision_type;
Chris@16 403 };
Chris@16 404 template<>
Chris@16 405 struct type_traits<boost::numeric::interval<long double> > : scalar_traits<boost::numeric::interval<long double> > {
Chris@16 406 typedef type_traits<boost::numeric::interval<long double> > self_type;
Chris@16 407 typedef boost::numeric::interval<long double> value_type;
Chris@16 408 typedef const value_type &const_reference;
Chris@16 409 typedef value_type &reference;
Chris@16 410 typedef value_type real_type;
Chris@16 411 typedef value_type precision_type;
Chris@16 412 };
Chris@16 413 #endif
Chris@16 414
Chris@16 415
Chris@16 416 // Storage tags -- hierarchical definition of storage characteristics
Chris@16 417
Chris@16 418 struct unknown_storage_tag {};
Chris@16 419 struct sparse_proxy_tag: public unknown_storage_tag {};
Chris@16 420 struct sparse_tag: public sparse_proxy_tag {};
Chris@16 421 struct packed_proxy_tag: public sparse_proxy_tag {};
Chris@16 422 struct packed_tag: public packed_proxy_tag {};
Chris@16 423 struct dense_proxy_tag: public packed_proxy_tag {};
Chris@16 424 struct dense_tag: public dense_proxy_tag {};
Chris@16 425
Chris@16 426 template<class S1, class S2>
Chris@16 427 struct storage_restrict_traits {
Chris@16 428 typedef S1 storage_category;
Chris@16 429 };
Chris@16 430
Chris@16 431 template<>
Chris@16 432 struct storage_restrict_traits<sparse_tag, dense_proxy_tag> {
Chris@16 433 typedef sparse_proxy_tag storage_category;
Chris@16 434 };
Chris@16 435 template<>
Chris@16 436 struct storage_restrict_traits<sparse_tag, packed_proxy_tag> {
Chris@16 437 typedef sparse_proxy_tag storage_category;
Chris@16 438 };
Chris@16 439 template<>
Chris@16 440 struct storage_restrict_traits<sparse_tag, sparse_proxy_tag> {
Chris@16 441 typedef sparse_proxy_tag storage_category;
Chris@16 442 };
Chris@16 443
Chris@16 444 template<>
Chris@16 445 struct storage_restrict_traits<packed_tag, dense_proxy_tag> {
Chris@16 446 typedef packed_proxy_tag storage_category;
Chris@16 447 };
Chris@16 448 template<>
Chris@16 449 struct storage_restrict_traits<packed_tag, packed_proxy_tag> {
Chris@16 450 typedef packed_proxy_tag storage_category;
Chris@16 451 };
Chris@16 452 template<>
Chris@16 453 struct storage_restrict_traits<packed_tag, sparse_proxy_tag> {
Chris@16 454 typedef sparse_proxy_tag storage_category;
Chris@16 455 };
Chris@16 456
Chris@16 457 template<>
Chris@16 458 struct storage_restrict_traits<packed_proxy_tag, sparse_proxy_tag> {
Chris@16 459 typedef sparse_proxy_tag storage_category;
Chris@16 460 };
Chris@16 461
Chris@16 462 template<>
Chris@16 463 struct storage_restrict_traits<dense_tag, dense_proxy_tag> {
Chris@16 464 typedef dense_proxy_tag storage_category;
Chris@16 465 };
Chris@16 466 template<>
Chris@16 467 struct storage_restrict_traits<dense_tag, packed_proxy_tag> {
Chris@16 468 typedef packed_proxy_tag storage_category;
Chris@16 469 };
Chris@16 470 template<>
Chris@16 471 struct storage_restrict_traits<dense_tag, sparse_proxy_tag> {
Chris@16 472 typedef sparse_proxy_tag storage_category;
Chris@16 473 };
Chris@16 474
Chris@16 475 template<>
Chris@16 476 struct storage_restrict_traits<dense_proxy_tag, packed_proxy_tag> {
Chris@16 477 typedef packed_proxy_tag storage_category;
Chris@16 478 };
Chris@16 479 template<>
Chris@16 480 struct storage_restrict_traits<dense_proxy_tag, sparse_proxy_tag> {
Chris@16 481 typedef sparse_proxy_tag storage_category;
Chris@16 482 };
Chris@16 483
Chris@16 484
Chris@16 485 // Iterator tags -- hierarchical definition of storage characteristics
Chris@16 486
Chris@16 487 struct sparse_bidirectional_iterator_tag : public std::bidirectional_iterator_tag {};
Chris@16 488 struct packed_random_access_iterator_tag : public std::random_access_iterator_tag {};
Chris@16 489 struct dense_random_access_iterator_tag : public packed_random_access_iterator_tag {};
Chris@16 490
Chris@16 491 // Thanks to Kresimir Fresl for convincing Comeau with iterator_base_traits ;-)
Chris@16 492 template<class IC>
Chris@16 493 struct iterator_base_traits {};
Chris@16 494
Chris@16 495 template<>
Chris@16 496 struct iterator_base_traits<std::forward_iterator_tag> {
Chris@16 497 template<class I, class T>
Chris@16 498 struct iterator_base {
Chris@16 499 typedef forward_iterator_base<std::forward_iterator_tag, I, T> type;
Chris@16 500 };
Chris@16 501 };
Chris@16 502
Chris@16 503 template<>
Chris@16 504 struct iterator_base_traits<std::bidirectional_iterator_tag> {
Chris@16 505 template<class I, class T>
Chris@16 506 struct iterator_base {
Chris@16 507 typedef bidirectional_iterator_base<std::bidirectional_iterator_tag, I, T> type;
Chris@16 508 };
Chris@16 509 };
Chris@16 510 template<>
Chris@16 511 struct iterator_base_traits<sparse_bidirectional_iterator_tag> {
Chris@16 512 template<class I, class T>
Chris@16 513 struct iterator_base {
Chris@16 514 typedef bidirectional_iterator_base<sparse_bidirectional_iterator_tag, I, T> type;
Chris@16 515 };
Chris@16 516 };
Chris@16 517
Chris@16 518 template<>
Chris@16 519 struct iterator_base_traits<std::random_access_iterator_tag> {
Chris@16 520 template<class I, class T>
Chris@16 521 struct iterator_base {
Chris@16 522 typedef random_access_iterator_base<std::random_access_iterator_tag, I, T> type;
Chris@16 523 };
Chris@16 524 };
Chris@16 525 template<>
Chris@16 526 struct iterator_base_traits<packed_random_access_iterator_tag> {
Chris@16 527 template<class I, class T>
Chris@16 528 struct iterator_base {
Chris@16 529 typedef random_access_iterator_base<packed_random_access_iterator_tag, I, T> type;
Chris@16 530 };
Chris@16 531 };
Chris@16 532 template<>
Chris@16 533 struct iterator_base_traits<dense_random_access_iterator_tag> {
Chris@16 534 template<class I, class T>
Chris@16 535 struct iterator_base {
Chris@16 536 typedef random_access_iterator_base<dense_random_access_iterator_tag, I, T> type;
Chris@16 537 };
Chris@16 538 };
Chris@16 539
Chris@16 540 template<class I1, class I2>
Chris@16 541 struct iterator_restrict_traits {
Chris@16 542 typedef I1 iterator_category;
Chris@16 543 };
Chris@16 544
Chris@16 545 template<>
Chris@16 546 struct iterator_restrict_traits<packed_random_access_iterator_tag, sparse_bidirectional_iterator_tag> {
Chris@16 547 typedef sparse_bidirectional_iterator_tag iterator_category;
Chris@16 548 };
Chris@16 549 template<>
Chris@16 550 struct iterator_restrict_traits<sparse_bidirectional_iterator_tag, packed_random_access_iterator_tag> {
Chris@16 551 typedef sparse_bidirectional_iterator_tag iterator_category;
Chris@16 552 };
Chris@16 553
Chris@16 554 template<>
Chris@16 555 struct iterator_restrict_traits<dense_random_access_iterator_tag, sparse_bidirectional_iterator_tag> {
Chris@16 556 typedef sparse_bidirectional_iterator_tag iterator_category;
Chris@16 557 };
Chris@16 558 template<>
Chris@16 559 struct iterator_restrict_traits<sparse_bidirectional_iterator_tag, dense_random_access_iterator_tag> {
Chris@16 560 typedef sparse_bidirectional_iterator_tag iterator_category;
Chris@16 561 };
Chris@16 562
Chris@16 563 template<>
Chris@16 564 struct iterator_restrict_traits<dense_random_access_iterator_tag, packed_random_access_iterator_tag> {
Chris@16 565 typedef packed_random_access_iterator_tag iterator_category;
Chris@16 566 };
Chris@16 567 template<>
Chris@16 568 struct iterator_restrict_traits<packed_random_access_iterator_tag, dense_random_access_iterator_tag> {
Chris@16 569 typedef packed_random_access_iterator_tag iterator_category;
Chris@16 570 };
Chris@16 571
Chris@16 572 template<class I>
Chris@16 573 BOOST_UBLAS_INLINE
Chris@16 574 void increment (I &it, const I &it_end, typename I::difference_type compare, packed_random_access_iterator_tag) {
Chris@16 575 it += (std::min) (compare, it_end - it);
Chris@16 576 }
Chris@16 577 template<class I>
Chris@16 578 BOOST_UBLAS_INLINE
Chris@16 579 void increment (I &it, const I &/* it_end */, typename I::difference_type /* compare */, sparse_bidirectional_iterator_tag) {
Chris@16 580 ++ it;
Chris@16 581 }
Chris@16 582 template<class I>
Chris@16 583 BOOST_UBLAS_INLINE
Chris@16 584 void increment (I &it, const I &it_end, typename I::difference_type compare) {
Chris@16 585 increment (it, it_end, compare, typename I::iterator_category ());
Chris@16 586 }
Chris@16 587
Chris@16 588 template<class I>
Chris@16 589 BOOST_UBLAS_INLINE
Chris@16 590 void increment (I &it, const I &it_end) {
Chris@16 591 #if BOOST_UBLAS_TYPE_CHECK
Chris@16 592 I cit (it);
Chris@16 593 while (cit != it_end) {
Chris@16 594 BOOST_UBLAS_CHECK (*cit == typename I::value_type/*zero*/(), internal_logic ());
Chris@16 595 ++ cit;
Chris@16 596 }
Chris@16 597 #endif
Chris@16 598 it = it_end;
Chris@16 599 }
Chris@16 600
Chris@16 601 namespace detail {
Chris@16 602
Chris@16 603 // specialisation which define whether a type has a trivial constructor
Chris@16 604 // or not. This is used by array types.
Chris@16 605 template<typename T>
Chris@16 606 struct has_trivial_constructor : public boost::has_trivial_constructor<T> {};
Chris@16 607
Chris@16 608 template<typename T>
Chris@16 609 struct has_trivial_destructor : public boost::has_trivial_destructor<T> {};
Chris@16 610
Chris@16 611 template<typename FLT>
Chris@16 612 struct has_trivial_constructor<std::complex<FLT> > : public has_trivial_constructor<FLT> {};
Chris@16 613
Chris@16 614 template<typename FLT>
Chris@16 615 struct has_trivial_destructor<std::complex<FLT> > : public has_trivial_destructor<FLT> {};
Chris@16 616
Chris@16 617 }
Chris@16 618
Chris@16 619
Chris@16 620 /** \brief Traits class to extract type information from a constant matrix or vector CONTAINER.
Chris@16 621 *
Chris@16 622 */
Chris@16 623 template < class E >
Chris@16 624 struct container_view_traits {
Chris@16 625 /// type of indices
Chris@16 626 typedef typename E::size_type size_type;
Chris@16 627 /// type of differences of indices
Chris@16 628 typedef typename E::difference_type difference_type;
Chris@16 629
Chris@16 630 /// storage category: \c unknown_storage_tag, \c dense_tag, \c packed_tag, ...
Chris@16 631 typedef typename E::storage_category storage_category;
Chris@16 632
Chris@16 633 /// type of elements
Chris@16 634 typedef typename E::value_type value_type;
Chris@16 635 /// const reference to an element
Chris@16 636 typedef typename E::const_reference const_reference;
Chris@16 637
Chris@16 638 /// type used in expressions to mark a reference to this class (usually a const container_reference<const E> or the class itself)
Chris@16 639 typedef typename E::const_closure_type const_closure_type;
Chris@16 640 };
Chris@16 641
Chris@16 642 /** \brief Traits class to extract additional type information from a mutable matrix or vector CONTAINER.
Chris@16 643 *
Chris@16 644 */
Chris@16 645 template < class E >
Chris@16 646 struct mutable_container_traits {
Chris@16 647 /// reference to an element
Chris@16 648 typedef typename E::reference reference;
Chris@16 649
Chris@16 650 /// type used in expressions to mark a reference to this class (usually a container_reference<E> or the class itself)
Chris@16 651 typedef typename E::closure_type closure_type;
Chris@16 652 };
Chris@16 653
Chris@16 654 /** \brief Traits class to extract type information from a matrix or vector CONTAINER.
Chris@16 655 *
Chris@16 656 */
Chris@16 657 template < class E >
Chris@16 658 struct container_traits
Chris@16 659 : container_view_traits<E>, mutable_container_traits<E> {
Chris@16 660
Chris@16 661 };
Chris@16 662
Chris@16 663
Chris@16 664 /** \brief Traits class to extract type information from a constant MATRIX.
Chris@16 665 *
Chris@16 666 */
Chris@16 667 template < class MATRIX >
Chris@16 668 struct matrix_view_traits : container_view_traits <MATRIX> {
Chris@16 669
Chris@16 670 /// orientation of the matrix, either \c row_major_tag, \c column_major_tag or \c unknown_orientation_tag
Chris@16 671 typedef typename MATRIX::orientation_category orientation_category;
Chris@16 672
Chris@16 673 /// row iterator for the matrix
Chris@16 674 typedef typename MATRIX::const_iterator1 const_iterator1;
Chris@16 675
Chris@16 676 /// column iterator for the matrix
Chris@16 677 typedef typename MATRIX::const_iterator2 const_iterator2;
Chris@16 678 };
Chris@16 679
Chris@16 680 /** \brief Traits class to extract additional type information from a mutable MATRIX.
Chris@16 681 *
Chris@16 682 */
Chris@16 683 template < class MATRIX >
Chris@16 684 struct mutable_matrix_traits
Chris@16 685 : mutable_container_traits <MATRIX> {
Chris@16 686
Chris@16 687 /// row iterator for the matrix
Chris@16 688 typedef typename MATRIX::iterator1 iterator1;
Chris@16 689
Chris@16 690 /// column iterator for the matrix
Chris@16 691 typedef typename MATRIX::iterator2 iterator2;
Chris@16 692 };
Chris@16 693
Chris@16 694
Chris@16 695 /** \brief Traits class to extract type information from a MATRIX.
Chris@16 696 *
Chris@16 697 */
Chris@16 698 template < class MATRIX >
Chris@16 699 struct matrix_traits
Chris@16 700 : matrix_view_traits <MATRIX>, mutable_matrix_traits <MATRIX> {
Chris@16 701 };
Chris@16 702
Chris@16 703 /** \brief Traits class to extract type information from a VECTOR.
Chris@16 704 *
Chris@16 705 */
Chris@16 706 template < class VECTOR >
Chris@16 707 struct vector_view_traits : container_view_traits <VECTOR> {
Chris@16 708
Chris@16 709 /// iterator for the VECTOR
Chris@16 710 typedef typename VECTOR::const_iterator const_iterator;
Chris@16 711
Chris@16 712 /// iterator pointing to the first element
Chris@16 713 static
Chris@16 714 const_iterator begin(const VECTOR & v) {
Chris@16 715 return v.begin();
Chris@16 716 }
Chris@16 717 /// iterator pointing behind the last element
Chris@16 718 static
Chris@16 719 const_iterator end(const VECTOR & v) {
Chris@16 720 return v.end();
Chris@16 721 }
Chris@16 722
Chris@16 723 };
Chris@16 724
Chris@16 725 /** \brief Traits class to extract type information from a VECTOR.
Chris@16 726 *
Chris@16 727 */
Chris@16 728 template < class VECTOR >
Chris@16 729 struct mutable_vector_traits : mutable_container_traits <VECTOR> {
Chris@16 730 /// iterator for the VECTOR
Chris@16 731 typedef typename VECTOR::iterator iterator;
Chris@16 732
Chris@16 733 /// iterator pointing to the first element
Chris@16 734 static
Chris@16 735 iterator begin(VECTOR & v) {
Chris@16 736 return v.begin();
Chris@16 737 }
Chris@16 738
Chris@16 739 /// iterator pointing behind the last element
Chris@16 740 static
Chris@16 741 iterator end(VECTOR & v) {
Chris@16 742 return v.end();
Chris@16 743 }
Chris@16 744 };
Chris@16 745
Chris@16 746 /** \brief Traits class to extract type information from a VECTOR.
Chris@16 747 *
Chris@16 748 */
Chris@16 749 template < class VECTOR >
Chris@16 750 struct vector_traits
Chris@16 751 : vector_view_traits <VECTOR>, mutable_vector_traits <VECTOR> {
Chris@16 752 };
Chris@16 753
Chris@16 754
Chris@16 755 // Note: specializations for T[N] and T[M][N] have been moved to traits/c_array.hpp
Chris@16 756
Chris@16 757 }}}
Chris@16 758
Chris@16 759 #endif