src/work/deba/array_map_factory.h
author alpar
Thu, 07 Apr 2005 11:30:12 +0000
changeset 1317 83f80464f111
parent 703 32f280a5ed7d
permissions -rw-r--r--
- XMap and YMap added
- Spell checking
     1 // -*- c++ -*-
     2 #ifndef ARRAY_MAP_H
     3 #define ARRAY_MAP_H
     4 
     5 #include <memory>
     6 
     7 #include "extended_pair.h"
     8 
     9 namespace lemon {
    10 	
    11   template <typename MapRegistry> class ArrayMapFactory {
    12 		
    13   public:
    14 		
    15     typedef typename MapRegistry::Graph Graph;
    16     typedef typename MapRegistry::Key Key;
    17     typedef typename MapRegistry::KeyIt KeyIt;
    18 
    19     typedef typename MapRegistry::MapBase MapBase;
    20 		
    21     template <typename V, typename A = std::allocator<V> > 
    22     class Map : public MapBase {
    23     
    24       public:
    25 
    26       typedef V Value;
    27       typedef A Allocator;
    28 
    29 	
    30       Map() : values(0), capacity(0) {}
    31 			
    32       Map(const Graph& g, MapRegistry& r) : MapBase(g, r) {
    33 	allocate_memory();
    34 	for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    35 	  int id = getGraph()->id(it);
    36 	  allocator.construct(&(values[id]), Value());
    37 	}								
    38       }
    39 
    40       Map(const Graph& g, MapRegistry& r, const Value& v) : MapBase(g, r) {
    41 	allocate_memory();
    42 	for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    43 	  int id = getGraph()->id(it);
    44 	  allocator.construct(&(values[id]), v);
    45 	}								
    46       }
    47 
    48       Map(const Map& copy) : MapBase(*copy.graph, *copy.registry) {
    49 	capacity = copy.capacity;
    50 	if (capacity == 0) return;
    51 	values = allocator.allocate(capacity);
    52 	for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    53 	  int id = getGraph()->id(it);
    54 	  allocator.construct(&(values[id]), copy.values[id]);
    55 	}
    56       }
    57 
    58       template <typename CMap> Map(const CMap& copy) 
    59 	: capacity(0), values(0), MapBase(copy) {
    60 	if (getGraph()) {
    61 	  allocate_memory();
    62 	  for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    63 	    set(it, copy[it]);
    64 	  }
    65 	}
    66       }
    67 
    68       Map& operator=(const Map& copy) {
    69 	if (&copy == this) return;
    70 	if (capacity != 0) {
    71 	  destroy();
    72 	  allocator.deallocate(values, capacity);
    73 	}
    74 	capacity = copy.capacity;
    75 	if (capacity == 0) return;
    76 	values = allocator.allocate(capacity);
    77 	for (KeyIt it(getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    78 	  int id = getGraph()->id(it);
    79 	  allocator.construct(&(values[id]), copy.values[id]);
    80 	}
    81       }
    82 
    83       template <typename CMap> Map& operator=(const CMap& copy) {
    84 	if (getGraph()) {
    85 	  destroy();
    86 	} 
    87 	this->MapBase::operator=(copy);
    88 	if (getGraph()) {
    89 	  allocate_memory();
    90 	  for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
    91 	    set(it, copy[it]);
    92 	  }
    93 	}
    94       }
    95 				
    96       virtual ~Map() {
    97 	if (capacity != 0) {
    98 	  destroy();
    99 	  allocator.deallocate(values, capacity);
   100 	}
   101       }
   102 	
   103 	
   104       Value& operator[](const Key& key) {
   105 	int id = getGraph()->id(key);
   106 	return values[id];
   107       } 
   108 		
   109       const Value& operator[](const Key& key) const {
   110 	int id = getGraph()->id(key);
   111 	return values[id];
   112       }
   113 	
   114       const Value& get(const Key& key) const {
   115 	int id = getGraph()->id(key);
   116 	return values[id];
   117       } 
   118 		
   119       void set(const Key& key, const Value& val) {
   120 	int id = getGraph()->id(key);
   121 	values[id] = val;
   122       }
   123 		
   124       void add(const Key& key) {
   125 	int id = getGraph()->id(key);
   126 	if (id >= capacity) {
   127 	  int new_capacity = (capacity == 0 ? 1 : capacity);
   128 	  while (new_capacity <= id) {
   129 	    new_capacity <<= 1;
   130 	  }
   131 	  Value* new_values = allocator.allocate(new_capacity);;
   132 	  for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
   133 	    int jd = getGraph()->id(it);
   134 	    if (id != jd) {
   135 	      allocator.construct(&(new_values[jd]), values[jd]);
   136 	      allocator.destroy(&(values[jd]));
   137 	    }
   138 	  }
   139 	  if (capacity != 0) allocator.deallocate(values, capacity);
   140 	  values = new_values;
   141 	  capacity = new_capacity;
   142 	}
   143 	allocator.construct(&(values[id]), Value());
   144       }
   145 		
   146       void erase(const Key& key) {
   147 	int id = getGraph()->id(key);
   148 	allocator.destroy(&(values[id]));
   149       }
   150 	
   151       class iterator {
   152 	friend class Map;
   153 	friend class const_iterator;
   154       private:
   155 
   156 	/** Private constructor to initalize the the iterators returned
   157 	 *  by the begin() and end().
   158 	 */
   159 	iterator (Map& pmap, const KeyIt& pit) : map(&pmap), it(pit) {}
   160 
   161       public:
   162 
   163 	/** Default constructor. 
   164 	 */
   165 	iterator() {}
   166 
   167 	typedef extended_pair<const Key&, const Key&, 
   168 			      Value&, Value&> Reference;
   169 
   170 	/** Dereference operator for map.
   171 	 */	 
   172 	Reference operator*() {
   173 	  return Reference(it, (*map)[it]);
   174 	}
   175 
   176 	class Pointer {
   177 	  friend class iterator;
   178 	private:
   179 	  Reference data;
   180 	  Pointer(const Key& key, Value& val) : data(key, val) {}
   181 	public:
   182 	  Reference* operator->() {return &data;}
   183 	};
   184 
   185 	/** Arrow operator for map.
   186 	 */	 
   187 	Pointer operator->() {
   188 	  return Pointer(it, ((*map)[it])); 
   189 	}
   190 
   191 	/** The pre increment operator of the map.
   192 	 */
   193 	iterator& operator++() { 
   194 	  map->getGraph()->next(it); 
   195 	  return *this; 
   196 	}
   197 
   198 	/** The post increment operator of the map.
   199 	 */
   200 	iterator operator++(int) { 
   201 	  iterator tmp(it); 
   202 	  map.getGraph()->next(it); 
   203 	  return tmp; 
   204 	}
   205 
   206 	/** The equality operator of the map.
   207 	 */
   208 	bool operator==(const_iterator p_it) {
   209 	  return p_it.it == it;
   210 	}
   211 	
   212 	/** The not-equality operator of the map.
   213 	 */
   214 	bool operator!=(const_iterator p_it) {
   215 	  return !(*this == p_it);
   216 	}
   217 
   218 	
   219       private:
   220 	Map* map;
   221 	KeyIt it;
   222       };
   223 
   224       /** Returns the begin iterator of the map.
   225        */
   226       iterator begin() {
   227 	return iterator(*this, KeyIt(*getGraph()));
   228       }
   229 
   230       /** Returns the end iterator of the map.
   231        */
   232       iterator end() {
   233 	return iterator(*this, INVALID);
   234       }
   235 
   236       class const_iterator {
   237 	friend class Map;
   238 	friend class iterator;
   239       private:
   240 
   241 	/** Private constructor to initalize the the iterators returned
   242 	 *  by the begin() and end().
   243 	 */
   244 	const_iterator (const Map& pmap, const KeyIt& pit) 
   245 	  : map(&pmap), it(pit) {}
   246 
   247       public:
   248 
   249 	/** Default constructor. 
   250 	 */
   251 	const_iterator() {}
   252 
   253 	/** Constructor to convert iterator to const_iterator.
   254 	 */
   255 	const_iterator(iterator p_it) : map(p_it.map), it(p_it.it) {}
   256       
   257 	typedef extended_pair<const Key&, const Key&, 
   258 	  const Value&, const Value&> Reference;
   259 
   260 	/** Dereference operator for map.
   261 	 */	 
   262 	Reference operator*() {
   263 	  return Reference(it, (*map)[it]);
   264 	}
   265 
   266 
   267 	class Pointer {
   268 	  friend class const_iterator;
   269 	private:
   270 	  Reference data;
   271 	  Pointer(const Key& key, const Value& val) : data(key, val) {}
   272 	public:
   273 	  Reference* operator->() {return &data;}
   274 	};
   275 
   276 	/** Arrow operator for map.
   277 	 */	 
   278 	Pointer operator->() {
   279 	  return Pointer(it, ((*map)[it])); 
   280 	}
   281 
   282 	/** The pre increment operator of the map.
   283 	 */
   284 	const_iterator& operator++() { 
   285 	  map->getGraph()->next(it); 
   286 	  return *this; 
   287 	}
   288 
   289 	/** The post increment operator of the map.
   290 	 */
   291 	const_iterator operator++(int) { 
   292 	  const_iterator tmp(it); 
   293 	  map->getGraph()->next(it); 
   294 	  return tmp; 
   295 	}
   296 
   297 	/** The equality operator of the map.
   298 	 */
   299 	bool operator==(const_iterator p_it) {
   300 	  return p_it.it == it;
   301 	}
   302 	
   303 	/** The not-equality operator of the map.
   304 	 */
   305 	bool operator!=(const_iterator p_it) {
   306 	  return !(*this == p_it);
   307 	}
   308 	
   309 
   310       private:
   311 	const Map* map;
   312 	KeyIt it;
   313       };
   314 
   315       /** Returns the begin const_iterator of the map.
   316        */
   317       const_iterator begin() const {
   318 	return const_iterator(*this, KeyIt(*getGraph()));
   319       }
   320 
   321       /** Returns the end const_iterator of the map.
   322        */
   323       const_iterator end() const {
   324 	return const_iterator(*this, INVALID);
   325       }
   326 
   327     private:
   328       
   329       void allocate_memory() {
   330 	int max_id = -1;
   331 	for (KeyIt it(*getGraph()); getGraph()->valid(it); getGraph()->next(it)) {
   332 	  int id = getGraph()->id(it);
   333 	  if (id > max_id) {
   334 	    max_id = id;
   335 	  }			
   336 	}
   337 	if (max_id == -1) {
   338 	  capacity = 0;
   339 	  values = 0;
   340 	  return;
   341 	}
   342 	capacity = 1;
   343 	while (capacity <= max_id) {
   344 	  capacity <<= 1;
   345 	}
   346 	values = allocator.allocate(capacity);	
   347       }      
   348       int capacity;
   349       Value* values;
   350       Allocator allocator;
   351     };		
   352   };
   353 }
   354 
   355 #endif