Mercurial > hg > vamp-build-and-test

annotate DEPENDENCIES/generic/include/boost/heap/pairing_heap.hpp @ 133:4acb5d8d80b6 tip

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
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 // boost heap: pairing heap
Chris@16 2 //
Chris@16 3 // Copyright (C) 2010 Tim Blechmann
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 #ifndef BOOST_HEAP_PAIRING_HEAP_HPP
Chris@16 10 #define BOOST_HEAP_PAIRING_HEAP_HPP
Chris@16 11
Chris@16 12 #include <algorithm>
Chris@16 13 #include <utility>
Chris@16 14 #include <vector>
Chris@16 15
Chris@16 16 #include <boost/assert.hpp>
Chris@16 17
Chris@16 18 #include <boost/heap/detail/heap_comparison.hpp>
Chris@16 19 #include <boost/heap/detail/heap_node.hpp>
Chris@16 20 #include <boost/heap/policies.hpp>
Chris@16 21 #include <boost/heap/detail/stable_heap.hpp>
Chris@16 22 #include <boost/heap/detail/tree_iterator.hpp>
Chris@16 23
Chris@101 24 #ifdef BOOST_HAS_PRAGMA_ONCE
Chris@101 25 #pragma once
Chris@101 26 #endif
Chris@101 27
Chris@101 28
Chris@16 29 #ifndef BOOST_DOXYGEN_INVOKED
Chris@16 30 #ifdef BOOST_HEAP_SANITYCHECKS
Chris@16 31 #define BOOST_HEAP_ASSERT BOOST_ASSERT
Chris@16 32 #else
Chris@16 33 #define BOOST_HEAP_ASSERT(expression)
Chris@16 34 #endif
Chris@16 35 #endif
Chris@16 36
Chris@16 37 namespace boost {
Chris@16 38 namespace heap {
Chris@16 39 namespace detail {
Chris@16 40
Chris@16 41 typedef parameter::parameters<boost::parameter::optional<tag::allocator>,
Chris@16 42 boost::parameter::optional<tag::compare>,
Chris@16 43 boost::parameter::optional<tag::stable>,
Chris@16 44 boost::parameter::optional<tag::constant_time_size>,
Chris@16 45 boost::parameter::optional<tag::stability_counter_type>
Chris@16 46 > pairing_heap_signature;
Chris@16 47
Chris@16 48 template <typename T, typename Parspec>
Chris@16 49 struct make_pairing_heap_base
Chris@16 50 {
Chris@16 51 static const bool constant_time_size = parameter::binding<Parspec,
Chris@16 52 tag::constant_time_size,
Chris@16 53 boost::mpl::true_
Chris@16 54 >::type::value;
Chris@16 55 typedef typename detail::make_heap_base<T, Parspec, constant_time_size>::type base_type;
Chris@16 56 typedef typename detail::make_heap_base<T, Parspec, constant_time_size>::allocator_argument allocator_argument;
Chris@16 57 typedef typename detail::make_heap_base<T, Parspec, constant_time_size>::compare_argument compare_argument;
Chris@16 58
Chris@16 59 typedef heap_node<typename base_type::internal_type, false> node_type;
Chris@16 60
Chris@16 61 typedef typename allocator_argument::template rebind<node_type>::other allocator_type;
Chris@16 62
Chris@16 63 struct type:
Chris@16 64 base_type,
Chris@16 65 allocator_type
Chris@16 66 {
Chris@16 67 type(compare_argument const & arg):
Chris@16 68 base_type(arg)
Chris@16 69 {}
Chris@16 70
Chris@16 71 #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES
Chris@16 72 type(type const & rhs):
Chris@16 73 base_type(rhs), allocator_type(rhs)
Chris@16 74 {}
Chris@16 75
Chris@16 76 type(type && rhs):
Chris@16 77 base_type(std::move(static_cast<base_type&>(rhs))),
Chris@16 78 allocator_type(std::move(static_cast<allocator_type&>(rhs)))
Chris@16 79 {}
Chris@16 80
Chris@16 81 type & operator=(type && rhs)
Chris@16 82 {
Chris@16 83 base_type::operator=(std::move(static_cast<base_type&>(rhs)));
Chris@16 84 allocator_type::operator=(std::move(static_cast<allocator_type&>(rhs)));
Chris@16 85 return *this;
Chris@16 86 }
Chris@16 87
Chris@16 88 type & operator=(type const & rhs)
Chris@16 89 {
Chris@16 90 base_type::operator=(static_cast<base_type const &>(rhs));
Chris@16 91 allocator_type::operator=(static_cast<const allocator_type&>(rhs));
Chris@16 92 return *this;
Chris@16 93 }
Chris@16 94 #endif
Chris@16 95 };
Chris@16 96 };
Chris@16 97
Chris@16 98 }
Chris@16 99
Chris@16 100 /**
Chris@16 101 * \class pairing_heap
Chris@16 102 * \brief pairing heap
Chris@16 103 *
Chris@16 104 * Pairing heaps are self-adjusting binary heaps. Although design and implementation are rather simple,
Chris@16 105 * the complexity analysis is yet unsolved. For details, consult:
Chris@16 106 *
Chris@16 107 * Pettie, Seth (2005), "Towards a final analysis of pairing heaps",
Chris@16 108 * Proc. 46th Annual IEEE Symposium on Foundations of Computer Science, pp. 174-183
Chris@16 109 *
Chris@16 110 * The template parameter T is the type to be managed by the container.
Chris@16 111 * The user can specify additional options and if no options are provided default options are used.
Chris@16 112 *
Chris@16 113 * The container supports the following options:
Chris@16 114 * - \c boost::heap::compare<>, defaults to \c compare<std::less<T> >
Chris@16 115 * - \c boost::heap::stable<>, defaults to \c stable<false>
Chris@16 116 * - \c boost::heap::stability_counter_type<>, defaults to \c stability_counter_type<boost::uintmax_t>
Chris@16 117 * - \c boost::heap::allocator<>, defaults to \c allocator<std::allocator<T> >
Chris@16 118 * - \c boost::heap::constant_time_size<>, defaults to \c constant_time_size<true>
Chris@16 119 *
Chris@16 120 *
Chris@16 121 */
Chris@16 122 #ifdef BOOST_DOXYGEN_INVOKED
Chris@16 123 template<class T, class ...Options>
Chris@16 124 #else
Chris@16 125 template <typename T,
Chris@16 126 class A0 = boost::parameter::void_,
Chris@16 127 class A1 = boost::parameter::void_,
Chris@16 128 class A2 = boost::parameter::void_,
Chris@16 129 class A3 = boost::parameter::void_,
Chris@16 130 class A4 = boost::parameter::void_
Chris@16 131 >
Chris@16 132 #endif
Chris@16 133 class pairing_heap:
Chris@16 134 private detail::make_pairing_heap_base<T,
Chris@16 135 typename detail::pairing_heap_signature::bind<A0, A1, A2, A3, A4>::type
Chris@16 136 >::type
Chris@16 137 {
Chris@16 138 typedef typename detail::pairing_heap_signature::bind<A0, A1, A2, A3, A4>::type bound_args;
Chris@16 139 typedef detail::make_pairing_heap_base<T, bound_args> base_maker;
Chris@16 140 typedef typename base_maker::type super_t;
Chris@16 141
Chris@16 142 typedef typename super_t::internal_type internal_type;
Chris@16 143 typedef typename super_t::size_holder_type size_holder;
Chris@16 144 typedef typename base_maker::allocator_argument allocator_argument;
Chris@16 145
Chris@16 146 private:
Chris@16 147 template <typename Heap1, typename Heap2>
Chris@16 148 friend struct heap_merge_emulate;
Chris@16 149
Chris@16 150 #ifndef BOOST_DOXYGEN_INVOKED
Chris@16 151 struct implementation_defined:
Chris@16 152 detail::extract_allocator_types<typename base_maker::allocator_argument>
Chris@16 153 {
Chris@16 154 typedef T value_type;
Chris@16 155 typedef typename detail::extract_allocator_types<typename base_maker::allocator_argument>::size_type size_type;
Chris@16 156 typedef typename detail::extract_allocator_types<typename base_maker::allocator_argument>::reference reference;
Chris@16 157
Chris@16 158 typedef typename base_maker::compare_argument value_compare;
Chris@16 159 typedef typename base_maker::allocator_type allocator_type;
Chris@16 160
Chris@16 161 typedef typename allocator_type::pointer node_pointer;
Chris@16 162 typedef typename allocator_type::const_pointer const_node_pointer;
Chris@16 163
Chris@16 164 typedef detail::heap_node_list node_list_type;
Chris@16 165 typedef typename node_list_type::iterator node_list_iterator;
Chris@16 166 typedef typename node_list_type::const_iterator node_list_const_iterator;
Chris@16 167
Chris@16 168 typedef typename base_maker::node_type node;
Chris@16 169
Chris@16 170 typedef detail::value_extractor<value_type, internal_type, super_t> value_extractor;
Chris@16 171 typedef typename super_t::internal_compare internal_compare;
Chris@16 172 typedef detail::node_handle<node_pointer, super_t, reference> handle_type;
Chris@16 173
Chris@16 174 typedef detail::tree_iterator<node,
Chris@16 175 const value_type,
Chris@16 176 allocator_type,
Chris@16 177 value_extractor,
Chris@16 178 detail::pointer_to_reference<node>,
Chris@16 179 false,
Chris@16 180 false,
Chris@16 181 value_compare
Chris@16 182 > iterator;
Chris@16 183
Chris@16 184 typedef iterator const_iterator;
Chris@16 185
Chris@16 186 typedef detail::tree_iterator<node,
Chris@16 187 const value_type,
Chris@16 188 allocator_type,
Chris@16 189 value_extractor,
Chris@16 190 detail::pointer_to_reference<node>,
Chris@16 191 false,
Chris@16 192 true,
Chris@16 193 value_compare
Chris@16 194 > ordered_iterator;
Chris@16 195 };
Chris@16 196
Chris@16 197 typedef typename implementation_defined::node node;
Chris@16 198 typedef typename implementation_defined::node_pointer node_pointer;
Chris@16 199 typedef typename implementation_defined::node_list_type node_list_type;
Chris@16 200 typedef typename implementation_defined::node_list_iterator node_list_iterator;
Chris@16 201 typedef typename implementation_defined::node_list_const_iterator node_list_const_iterator;
Chris@16 202 typedef typename implementation_defined::internal_compare internal_compare;
Chris@16 203
Chris@16 204 typedef boost::intrusive::list<detail::heap_node_base<true>,
Chris@16 205 boost::intrusive::constant_time_size<false>
Chris@16 206 > node_child_list;
Chris@16 207 #endif
Chris@16 208
Chris@16 209 public:
Chris@16 210 typedef T value_type;
Chris@16 211
Chris@16 212 typedef typename implementation_defined::size_type size_type;
Chris@16 213 typedef typename implementation_defined::difference_type difference_type;
Chris@16 214 typedef typename implementation_defined::value_compare value_compare;
Chris@16 215 typedef typename implementation_defined::allocator_type allocator_type;
Chris@16 216 typedef typename implementation_defined::reference reference;
Chris@16 217 typedef typename implementation_defined::const_reference const_reference;
Chris@16 218 typedef typename implementation_defined::pointer pointer;
Chris@16 219 typedef typename implementation_defined::const_pointer const_pointer;
Chris@16 220 /// \copydoc boost::heap::priority_queue::iterator
Chris@16 221 typedef typename implementation_defined::iterator iterator;
Chris@16 222 typedef typename implementation_defined::const_iterator const_iterator;
Chris@16 223 typedef typename implementation_defined::ordered_iterator ordered_iterator;
Chris@16 224
Chris@16 225 typedef typename implementation_defined::handle_type handle_type;
Chris@16 226
Chris@16 227 static const bool constant_time_size = super_t::constant_time_size;
Chris@16 228 static const bool has_ordered_iterators = true;
Chris@16 229 static const bool is_mergable = true;
Chris@16 230 static const bool is_stable = detail::extract_stable<bound_args>::value;
Chris@16 231 static const bool has_reserve = false;
Chris@16 232
Chris@16 233 /// \copydoc boost::heap::priority_queue::priority_queue(value_compare const &)
Chris@16 234 explicit pairing_heap(value_compare const & cmp = value_compare()):
Chris@16 235 super_t(cmp), root(NULL)
Chris@16 236 {}
Chris@16 237
Chris@16 238 /// \copydoc boost::heap::priority_queue::priority_queue(priority_queue const &)
Chris@16 239 pairing_heap(pairing_heap const & rhs):
Chris@16 240 super_t(rhs), root(NULL)
Chris@16 241 {
Chris@16 242 if (rhs.empty())
Chris@16 243 return;
Chris@16 244
Chris@16 245 clone_tree(rhs);
Chris@16 246 size_holder::set_size(rhs.get_size());
Chris@16 247 }
Chris@16 248
Chris@16 249 #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES
Chris@16 250 /// \copydoc boost::heap::priority_queue::priority_queue(priority_queue &&)
Chris@16 251 pairing_heap(pairing_heap && rhs):
Chris@16 252 super_t(std::move(rhs)), root(rhs.root)
Chris@16 253 {
Chris@16 254 rhs.root = NULL;
Chris@16 255 }
Chris@16 256
Chris@16 257 /// \copydoc boost::heap::priority_queue::operator=(priority_queue &&)
Chris@16 258 pairing_heap & operator=(pairing_heap && rhs)
Chris@16 259 {
Chris@16 260 super_t::operator=(std::move(rhs));
Chris@16 261 root = rhs.root;
Chris@16 262 rhs.root = NULL;
Chris@16 263 return *this;
Chris@16 264 }
Chris@16 265 #endif
Chris@16 266
Chris@16 267 /// \copydoc boost::heap::priority_queue::operator=(priority_queue const & rhs)
Chris@16 268 pairing_heap & operator=(pairing_heap const & rhs)
Chris@16 269 {
Chris@16 270 clear();
Chris@16 271 size_holder::set_size(rhs.get_size());
Chris@16 272 static_cast<super_t&>(*this) = rhs;
Chris@16 273
Chris@16 274 clone_tree(rhs);
Chris@16 275 return *this;
Chris@16 276 }
Chris@16 277
Chris@16 278 ~pairing_heap(void)
Chris@16 279 {
Chris@16 280 while (!empty())
Chris@16 281 pop();
Chris@16 282 }
Chris@16 283
Chris@16 284 /// \copydoc boost::heap::priority_queue::empty
Chris@16 285 bool empty(void) const
Chris@16 286 {
Chris@16 287 return root == NULL;
Chris@16 288 }
Chris@16 289
Chris@16 290 /// \copydoc boost::heap::binomial_heap::size
Chris@16 291 size_type size(void) const
Chris@16 292 {
Chris@16 293 if (constant_time_size)
Chris@16 294 return size_holder::get_size();
Chris@16 295
Chris@16 296 if (root == NULL)
Chris@16 297 return 0;
Chris@16 298 else
Chris@16 299 return detail::count_nodes(root);
Chris@16 300 }
Chris@16 301
Chris@16 302 /// \copydoc boost::heap::priority_queue::max_size
Chris@16 303 size_type max_size(void) const
Chris@16 304 {
Chris@16 305 return allocator_type::max_size();
Chris@16 306 }
Chris@16 307
Chris@16 308 /// \copydoc boost::heap::priority_queue::clear
Chris@16 309 void clear(void)
Chris@16 310 {
Chris@16 311 if (empty())
Chris@16 312 return;
Chris@16 313
Chris@16 314 root->template clear_subtree<allocator_type>(*this);
Chris@16 315 root->~node();
Chris@16 316 allocator_type::deallocate(root, 1);
Chris@16 317 root = NULL;
Chris@16 318 size_holder::set_size(0);
Chris@16 319 }
Chris@16 320
Chris@16 321 /// \copydoc boost::heap::priority_queue::get_allocator
Chris@16 322 allocator_type get_allocator(void) const
Chris@16 323 {
Chris@16 324 return *this;
Chris@16 325 }
Chris@16 326
Chris@16 327 /// \copydoc boost::heap::priority_queue::swap
Chris@16 328 void swap(pairing_heap & rhs)
Chris@16 329 {
Chris@16 330 super_t::swap(rhs);
Chris@16 331 std::swap(root, rhs.root);
Chris@16 332 }
Chris@16 333
Chris@16 334
Chris@16 335 /// \copydoc boost::heap::priority_queue::top
Chris@16 336 const_reference top(void) const
Chris@16 337 {
Chris@16 338 BOOST_ASSERT(!empty());
Chris@16 339
Chris@16 340 return super_t::get_value(root->value);
Chris@16 341 }
Chris@16 342
Chris@16 343 /**
Chris@16 344 * \b Effects: Adds a new element to the priority queue. Returns handle to element
Chris@16 345 *
Chris@16 346 * \cond
Chris@16 347 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 348 * \endcond
Chris@16 349 *
Chris@16 350 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 351 *
Chris@16 352 * */
Chris@16 353 handle_type push(value_type const & v)
Chris@16 354 {
Chris@16 355 size_holder::increment();
Chris@16 356
Chris@16 357 node_pointer n = allocator_type::allocate(1);
Chris@16 358
Chris@16 359 new(n) node(super_t::make_node(v));
Chris@16 360
Chris@16 361 merge_node(n);
Chris@16 362 return handle_type(n);
Chris@16 363 }
Chris@16 364
Chris@16 365 #if !defined(BOOST_NO_CXX11_RVALUE_REFERENCES) && !defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES)
Chris@16 366 /**
Chris@16 367 * \b Effects: Adds a new element to the priority queue. The element is directly constructed in-place. Returns handle to element.
Chris@16 368 *
Chris@16 369 * \cond
Chris@16 370 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 371 * \endcond
Chris@16 372 *
Chris@16 373 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 374 *
Chris@16 375 * */
Chris@16 376 template <class... Args>
Chris@16 377 handle_type emplace(Args&&... args)
Chris@16 378 {
Chris@16 379 size_holder::increment();
Chris@16 380
Chris@16 381 node_pointer n = allocator_type::allocate(1);
Chris@16 382
Chris@16 383 new(n) node(super_t::make_node(std::forward<Args>(args)...));
Chris@16 384
Chris@16 385 merge_node(n);
Chris@16 386 return handle_type(n);
Chris@16 387 }
Chris@16 388 #endif
Chris@16 389
Chris@16 390 /**
Chris@16 391 * \b Effects: Removes the top element from the priority queue.
Chris@16 392 *
Chris@16 393 * \b Complexity: Logarithmic (amortized).
Chris@16 394 *
Chris@16 395 * */
Chris@16 396 void pop(void)
Chris@16 397 {
Chris@16 398 BOOST_ASSERT(!empty());
Chris@16 399
Chris@16 400 erase(handle_type(root));
Chris@16 401 }
Chris@16 402
Chris@16 403 /**
Chris@16 404 * \b Effects: Assigns \c v to the element handled by \c handle & updates the priority queue.
Chris@16 405 *
Chris@16 406 * \cond
Chris@16 407 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 408 * \endcond
Chris@16 409 *
Chris@16 410 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 411 *
Chris@16 412 * */
Chris@16 413 void update (handle_type handle, const_reference v)
Chris@16 414 {
Chris@16 415 handle.node_->value = super_t::make_node(v);
Chris@16 416 update(handle);
Chris@16 417 }
Chris@16 418
Chris@16 419 /**
Chris@16 420 * \b Effects: Updates the heap after the element handled by \c handle has been changed.
Chris@16 421 *
Chris@16 422 * \cond
Chris@16 423 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 424 * \endcond
Chris@16 425 *
Chris@16 426 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 427 *
Chris@16 428 * \b Note: If this is not called, after a handle has been updated, the behavior of the data structure is undefined!
Chris@16 429 * */
Chris@16 430 void update (handle_type handle)
Chris@16 431 {
Chris@16 432 node_pointer n = handle.node_;
Chris@16 433
Chris@16 434 n->unlink();
Chris@16 435 if (!n->children.empty())
Chris@16 436 n = merge_nodes(n, merge_node_list(n->children));
Chris@16 437
Chris@16 438 if (n != root)
Chris@16 439 merge_node(n);
Chris@16 440 }
Chris@16 441
Chris@16 442 /**
Chris@16 443 * \b Effects: Assigns \c v to the element handled by \c handle & updates the priority queue.
Chris@16 444 *
Chris@16 445 * \cond
Chris@16 446 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 447 * \endcond
Chris@16 448 *
Chris@16 449 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 450 *
Chris@16 451 * \b Note: The new value is expected to be greater than the current one
Chris@16 452 * */
Chris@16 453 void increase (handle_type handle, const_reference v)
Chris@16 454 {
Chris@16 455 update(handle, v);
Chris@16 456 }
Chris@16 457
Chris@16 458 /**
Chris@16 459 * \b Effects: Updates the heap after the element handled by \c handle has been changed.
Chris@16 460 *
Chris@16 461 * \cond
Chris@16 462 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 463 * \endcond
Chris@16 464 *
Chris@16 465 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 466 *
Chris@16 467 * \b Note: If this is not called, after a handle has been updated, the behavior of the data structure is undefined!
Chris@16 468 * */
Chris@16 469 void increase (handle_type handle)
Chris@16 470 {
Chris@16 471 update(handle);
Chris@16 472 }
Chris@16 473
Chris@16 474 /**
Chris@16 475 * \b Effects: Assigns \c v to the element handled by \c handle & updates the priority queue.
Chris@16 476 *
Chris@16 477 * \cond
Chris@16 478 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 479 * \endcond
Chris@16 480 *
Chris@16 481 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 482 *
Chris@16 483 * \b Note: The new value is expected to be less than the current one
Chris@16 484 * */
Chris@16 485 void decrease (handle_type handle, const_reference v)
Chris@16 486 {
Chris@16 487 update(handle, v);
Chris@16 488 }
Chris@16 489
Chris@16 490 /**
Chris@16 491 * \b Effects: Updates the heap after the element handled by \c handle has been changed.
Chris@16 492 *
Chris@16 493 * \cond
Chris@16 494 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 495 * \endcond
Chris@16 496 *
Chris@16 497 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 498 *
Chris@16 499 * \b Note: The new value is expected to be less than the current one. If this is not called, after a handle has been updated, the behavior of the data structure is undefined!
Chris@16 500 * */
Chris@16 501 void decrease (handle_type handle)
Chris@16 502 {
Chris@16 503 update(handle);
Chris@16 504 }
Chris@16 505
Chris@16 506 /**
Chris@16 507 * \b Effects: Removes the element handled by \c handle from the priority_queue.
Chris@16 508 *
Chris@16 509 * \cond
Chris@16 510 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 511 * \endcond
Chris@16 512 *
Chris@16 513 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 514 * */
Chris@16 515 void erase(handle_type handle)
Chris@16 516 {
Chris@16 517 node_pointer n = handle.node_;
Chris@16 518 if (n != root) {
Chris@16 519 n->unlink();
Chris@16 520 if (!n->children.empty())
Chris@16 521 merge_node(merge_node_list(n->children));
Chris@16 522 } else {
Chris@16 523 if (!n->children.empty())
Chris@16 524 root = merge_node_list(n->children);
Chris@16 525 else
Chris@16 526 root = NULL;
Chris@16 527 }
Chris@16 528
Chris@16 529 size_holder::decrement();
Chris@16 530 n->~node();
Chris@16 531 allocator_type::deallocate(n, 1);
Chris@16 532 }
Chris@16 533
Chris@16 534 /// \copydoc boost::heap::priority_queue::begin
Chris@16 535 iterator begin(void) const
Chris@16 536 {
Chris@16 537 return iterator(root, super_t::value_comp());
Chris@16 538 }
Chris@16 539
Chris@16 540 /// \copydoc boost::heap::priority_queue::end
Chris@16 541 iterator end(void) const
Chris@16 542 {
Chris@16 543 return iterator();
Chris@16 544 }
Chris@16 545
Chris@16 546 /// \copydoc boost::heap::fibonacci_heap::ordered_begin
Chris@16 547 ordered_iterator ordered_begin(void) const
Chris@16 548 {
Chris@16 549 return ordered_iterator(root, super_t::value_comp());
Chris@16 550 }
Chris@16 551
Chris@16 552 /// \copydoc boost::heap::fibonacci_heap::ordered_begin
Chris@16 553 ordered_iterator ordered_end(void) const
Chris@16 554 {
Chris@16 555 return ordered_iterator(NULL, super_t::value_comp());
Chris@16 556 }
Chris@16 557
Chris@16 558
Chris@16 559 /// \copydoc boost::heap::d_ary_heap_mutable::s_handle_from_iterator
Chris@16 560 static handle_type s_handle_from_iterator(iterator const & it)
Chris@16 561 {
Chris@16 562 node * ptr = const_cast<node *>(it.get_node());
Chris@16 563 return handle_type(ptr);
Chris@16 564 }
Chris@16 565
Chris@16 566 /**
Chris@16 567 * \b Effects: Merge all elements from rhs into this
Chris@16 568 *
Chris@16 569 * \cond
Chris@16 570 * \b Complexity: \f$2^2log(log(N))\f$ (amortized).
Chris@16 571 * \endcond
Chris@16 572 *
Chris@16 573 * \b Complexity: 2**2*log(log(N)) (amortized).
Chris@16 574 *
Chris@16 575 * */
Chris@16 576 void merge(pairing_heap & rhs)
Chris@16 577 {
Chris@16 578 if (rhs.empty())
Chris@16 579 return;
Chris@16 580
Chris@16 581 merge_node(rhs.root);
Chris@16 582
Chris@16 583 size_holder::add(rhs.get_size());
Chris@16 584 rhs.set_size(0);
Chris@16 585 rhs.root = NULL;
Chris@16 586
Chris@16 587 super_t::set_stability_count((std::max)(super_t::get_stability_count(),
Chris@16 588 rhs.get_stability_count()));
Chris@16 589 rhs.set_stability_count(0);
Chris@16 590 }
Chris@16 591
Chris@16 592 /// \copydoc boost::heap::priority_queue::value_comp
Chris@16 593 value_compare const & value_comp(void) const
Chris@16 594 {
Chris@16 595 return super_t::value_comp();
Chris@16 596 }
Chris@16 597
Chris@16 598 /// \copydoc boost::heap::priority_queue::operator<(HeapType const & rhs) const
Chris@16 599 template <typename HeapType>
Chris@16 600 bool operator<(HeapType const & rhs) const
Chris@16 601 {
Chris@16 602 return detail::heap_compare(*this, rhs);
Chris@16 603 }
Chris@16 604
Chris@16 605 /// \copydoc boost::heap::priority_queue::operator>(HeapType const & rhs) const
Chris@16 606 template <typename HeapType>
Chris@16 607 bool operator>(HeapType const & rhs) const
Chris@16 608 {
Chris@16 609 return detail::heap_compare(rhs, *this);
Chris@16 610 }
Chris@16 611
Chris@16 612 /// \copydoc boost::heap::priority_queue::operator>=(HeapType const & rhs) const
Chris@16 613 template <typename HeapType>
Chris@16 614 bool operator>=(HeapType const & rhs) const
Chris@16 615 {
Chris@16 616 return !operator<(rhs);
Chris@16 617 }
Chris@16 618
Chris@16 619 /// \copydoc boost::heap::priority_queue::operator<=(HeapType const & rhs) const
Chris@16 620 template <typename HeapType>
Chris@16 621 bool operator<=(HeapType const & rhs) const
Chris@16 622 {
Chris@16 623 return !operator>(rhs);
Chris@16 624 }
Chris@16 625
Chris@16 626 /// \copydoc boost::heap::priority_queue::operator==(HeapType const & rhs) const
Chris@16 627 template <typename HeapType>
Chris@16 628 bool operator==(HeapType const & rhs) const
Chris@16 629 {
Chris@16 630 return detail::heap_equality(*this, rhs);
Chris@16 631 }
Chris@16 632
Chris@16 633 /// \copydoc boost::heap::priority_queue::operator!=(HeapType const & rhs) const
Chris@16 634 template <typename HeapType>
Chris@16 635 bool operator!=(HeapType const & rhs) const
Chris@16 636 {
Chris@16 637 return !(*this == rhs);
Chris@16 638 }
Chris@16 639
Chris@16 640 private:
Chris@16 641 #if !defined(BOOST_DOXYGEN_INVOKED)
Chris@16 642 void clone_tree(pairing_heap const & rhs)
Chris@16 643 {
Chris@16 644 BOOST_HEAP_ASSERT(root == NULL);
Chris@16 645 if (rhs.empty())
Chris@16 646 return;
Chris@16 647
Chris@16 648 root = allocator_type::allocate(1);
Chris@16 649
Chris@16 650 new(root) node(static_cast<node const &>(*rhs.root), static_cast<allocator_type&>(*this));
Chris@16 651 }
Chris@16 652
Chris@16 653 void merge_node(node_pointer other)
Chris@16 654 {
Chris@16 655 BOOST_HEAP_ASSERT(other);
Chris@16 656 if (root != NULL)
Chris@16 657 root = merge_nodes(root, other);
Chris@16 658 else
Chris@16 659 root = other;
Chris@16 660 }
Chris@16 661
Chris@16 662 node_pointer merge_node_list(node_child_list & children)
Chris@16 663 {
Chris@16 664 BOOST_HEAP_ASSERT(!children.empty());
Chris@16 665 node_pointer merged = merge_first_pair(children);
Chris@16 666 if (children.empty())
Chris@16 667 return merged;
Chris@16 668
Chris@16 669 node_child_list node_list;
Chris@16 670 node_list.push_back(*merged);
Chris@16 671
Chris@16 672 do {
Chris@16 673 node_pointer next_merged = merge_first_pair(children);
Chris@16 674 node_list.push_back(*next_merged);
Chris@16 675 } while (!children.empty());
Chris@16 676
Chris@16 677 return merge_node_list(node_list);
Chris@16 678 }
Chris@16 679
Chris@16 680 node_pointer merge_first_pair(node_child_list & children)
Chris@16 681 {
Chris@16 682 BOOST_HEAP_ASSERT(!children.empty());
Chris@16 683 node_pointer first_child = static_cast<node_pointer>(&children.front());
Chris@16 684 children.pop_front();
Chris@16 685 if (children.empty())
Chris@16 686 return first_child;
Chris@16 687
Chris@16 688 node_pointer second_child = static_cast<node_pointer>(&children.front());
Chris@16 689 children.pop_front();
Chris@16 690
Chris@16 691 return merge_nodes(first_child, second_child);
Chris@16 692 }
Chris@16 693
Chris@16 694 node_pointer merge_nodes(node_pointer node1, node_pointer node2)
Chris@16 695 {
Chris@16 696 if (super_t::operator()(node1->value, node2->value))
Chris@16 697 std::swap(node1, node2);
Chris@16 698
Chris@16 699 node2->unlink();
Chris@16 700 node1->children.push_front(*node2);
Chris@16 701 return node1;
Chris@16 702 }
Chris@16 703
Chris@16 704 node_pointer root;
Chris@16 705 #endif
Chris@16 706 };
Chris@16 707
Chris@16 708
Chris@16 709 } /* namespace heap */
Chris@16 710 } /* namespace boost */
Chris@16 711
Chris@16 712 #undef BOOST_HEAP_ASSERT
Chris@16 713 #endif /* BOOST_HEAP_PAIRING_HEAP_HPP */