2 // STL-like templated tree class.
4 // Copyright (C) 2001-2009 Kasper Peeters <kasper.peeters@aei.mpg.de>
5 // Distributed under the GNU General Public License version 3,
6 // (eventually to be changed to the Boost Software License).
12 \see http://www.aei.mpg.de/~peekas/tree/
13 \see http://www.aei.mpg.de/~peekas/tree/ChangeLog
15 The tree.hh library for C++ provides an STL-like container class
16 for n-ary trees, templated over the data stored at the
17 nodes. Various types of iterators are provided (post-order,
18 pre-order, and others). Where possible the access methods are
19 compatible with the STL or alternative algorithms are
35 // HP-style construct/destroy have gone from the standard,
40 template <class T1, class T2>
41 void constructor(T1* p, T2& val)
43 new ((void *) p) T1(val);
47 void constructor(T1* p)
53 void destructor(T1* p)
60 /// A node in the tree, combining links to other nodes as well as the actual data.
62 class tree_node_ { // size: 5*4=20 bytes (on 32 bit arch), can be reduced by 8.
64 tree_node_<T> *parent;
65 tree_node_<T> *first_child, *last_child;
66 tree_node_<T> *prev_sibling, *next_sibling;
68 }; // __attribute__((packed));
70 template <class T, class tree_node_allocator = std::allocator<tree_node_<T> > >
73 typedef tree_node_<T> tree_node;
75 /// Value of the data stored at a node.
79 class pre_order_iterator;
80 class post_order_iterator;
81 class sibling_iterator;
86 tree(const iterator_base&);
87 tree(const tree<T, tree_node_allocator>&);
89 void operator=(const tree<T, tree_node_allocator>&);
91 /// Base class for iterators, only pointers stored, no traversal logic.
93 class iterator_base : public stlport::bidirectional_iterator<T, std::ptrdiff_t> {
100 typedef T& reference;
101 typedef size_t size_type;
102 typedef std::ptrdiff_t difference_type;
103 typedef std::bidirectional_iterator_tag iterator_category;
106 iterator_base(tree_node *);
108 T& operator*() const;
109 T* operator->() const;
111 /// When called, the next increment/decrement skips children of this node.
112 void skip_children();
113 void skip_children(bool skip);
114 /// Number of children of the node pointed to by the iterator.
115 unsigned int number_of_children() const;
117 sibling_iterator begin() const;
118 sibling_iterator end() const;
122 bool skip_current_children_;
125 /// Depth-first iterator, first accessing the node, then its children.
126 class pre_order_iterator : public iterator_base {
128 pre_order_iterator();
129 pre_order_iterator(tree_node *);
130 pre_order_iterator(const iterator_base&);
131 pre_order_iterator(const sibling_iterator&);
133 bool operator==(const pre_order_iterator&) const;
134 bool operator!=(const pre_order_iterator&) const;
135 pre_order_iterator& operator++();
136 pre_order_iterator& operator--();
137 pre_order_iterator operator++(int);
138 pre_order_iterator operator--(int);
139 pre_order_iterator& operator+=(unsigned int);
140 pre_order_iterator& operator-=(unsigned int);
143 /// Depth-first iterator, first accessing the children, then the node itself.
144 class post_order_iterator : public iterator_base {
146 post_order_iterator();
147 post_order_iterator(tree_node *);
148 post_order_iterator(const iterator_base&);
149 post_order_iterator(const sibling_iterator&);
151 bool operator==(const post_order_iterator&) const;
152 bool operator!=(const post_order_iterator&) const;
153 post_order_iterator& operator++();
154 post_order_iterator& operator--();
155 post_order_iterator operator++(int);
156 post_order_iterator operator--(int);
157 post_order_iterator& operator+=(unsigned int);
158 post_order_iterator& operator-=(unsigned int);
160 /// Set iterator to the first child as deep as possible down the tree.
164 /// Breadth-first iterator, using a queue
165 class breadth_first_queued_iterator : public iterator_base {
167 breadth_first_queued_iterator();
168 breadth_first_queued_iterator(tree_node *);
169 breadth_first_queued_iterator(const iterator_base&);
171 bool operator==(const breadth_first_queued_iterator&) const;
172 bool operator!=(const breadth_first_queued_iterator&) const;
173 breadth_first_queued_iterator& operator++();
174 breadth_first_queued_iterator operator++(int);
175 breadth_first_queued_iterator& operator+=(unsigned int);
178 std::queue<tree_node *> traversal_queue;
181 /// The default iterator types throughout the tree class.
182 typedef pre_order_iterator iterator;
183 typedef breadth_first_queued_iterator breadth_first_iterator;
185 /// Iterator which traverses only the nodes at a given depth from the root.
186 class fixed_depth_iterator : public iterator_base {
188 fixed_depth_iterator();
189 fixed_depth_iterator(tree_node *);
190 fixed_depth_iterator(const iterator_base&);
191 fixed_depth_iterator(const sibling_iterator&);
192 fixed_depth_iterator(const fixed_depth_iterator&);
194 bool operator==(const fixed_depth_iterator&) const;
195 bool operator!=(const fixed_depth_iterator&) const;
196 fixed_depth_iterator& operator++();
197 fixed_depth_iterator& operator--();
198 fixed_depth_iterator operator++(int);
199 fixed_depth_iterator operator--(int);
200 fixed_depth_iterator& operator+=(unsigned int);
201 fixed_depth_iterator& operator-=(unsigned int);
206 /// Iterator which traverses only the nodes which are siblings of each other.
207 class sibling_iterator : public iterator_base {
210 sibling_iterator(tree_node *);
211 sibling_iterator(const sibling_iterator&);
212 sibling_iterator(const iterator_base&);
214 bool operator==(const sibling_iterator&) const;
215 bool operator!=(const sibling_iterator&) const;
216 sibling_iterator& operator++();
217 sibling_iterator& operator--();
218 sibling_iterator operator++(int);
219 sibling_iterator operator--(int);
220 sibling_iterator& operator+=(unsigned int);
221 sibling_iterator& operator-=(unsigned int);
223 tree_node *range_first() const;
224 tree_node *range_last() const;
230 /// Iterator which traverses only the leaves.
231 class leaf_iterator : public iterator_base {
234 leaf_iterator(tree_node *, tree_node *top=0);
235 leaf_iterator(const sibling_iterator&);
236 leaf_iterator(const iterator_base&);
238 bool operator==(const leaf_iterator&) const;
239 bool operator!=(const leaf_iterator&) const;
240 leaf_iterator& operator++();
241 leaf_iterator& operator--();
242 leaf_iterator operator++(int);
243 leaf_iterator operator--(int);
244 leaf_iterator& operator+=(unsigned int);
245 leaf_iterator& operator-=(unsigned int);
250 /// Return iterator to the beginning of the tree.
251 inline pre_order_iterator begin() const;
252 /// Return iterator to the end of the tree.
253 inline pre_order_iterator end() const;
254 /// Return post-order iterator to the beginning of the tree.
255 post_order_iterator begin_post() const;
256 /// Return post-order end iterator of the tree.
257 post_order_iterator end_post() const;
258 /// Return fixed-depth iterator to the first node at a given depth from the given iterator.
259 fixed_depth_iterator begin_fixed(const iterator_base&, unsigned int) const;
260 /// Return fixed-depth end iterator.
261 fixed_depth_iterator end_fixed(const iterator_base&, unsigned int) const;
262 /// Return breadth-first iterator to the first node at a given depth.
263 breadth_first_queued_iterator begin_breadth_first() const;
264 /// Return breadth-first end iterator.
265 breadth_first_queued_iterator end_breadth_first() const;
266 /// Return sibling iterator to the first child of given node.
267 sibling_iterator begin(const iterator_base&) const;
268 /// Return sibling end iterator for children of given node.
269 sibling_iterator end(const iterator_base&) const;
270 /// Return leaf iterator to the first leaf of the tree.
271 leaf_iterator begin_leaf() const;
272 /// Return leaf end iterator for entire tree.
273 leaf_iterator end_leaf() const;
274 /// Return leaf iterator to the first leaf of the subtree at the given node.
275 leaf_iterator begin_leaf(const iterator_base& top) const;
276 /// Return leaf end iterator for the subtree at the given node.
277 leaf_iterator end_leaf(const iterator_base& top) const;
279 /// Return iterator to the parent of a node.
280 template<typename iter> static iter parent(iter);
281 /// Return iterator to the previous sibling of a node.
282 template<typename iter> iter previous_sibling(iter) const;
283 /// Return iterator to the next sibling of a node.
284 template<typename iter> iter next_sibling(iter) const;
285 /// Return iterator to the next node at a given depth.
286 template<typename iter> iter next_at_same_depth(iter) const;
288 /// Erase all nodes of the tree.
290 /// Erase element at position pointed to by iterator, return incremented iterator.
291 template<typename iter> iter erase(iter);
292 /// Erase all children of the node pointed to by iterator.
293 void erase_children(const iterator_base&);
295 /// Insert empty node as last/first child of node pointed to by position.
296 template<typename iter> iter append_child(iter position);
297 template<typename iter> iter prepend_child(iter position);
298 /// Insert node as last/first child of node pointed to by position.
299 template<typename iter> iter append_child(iter position, const T& x);
300 template<typename iter> iter prepend_child(iter position, const T& x);
301 /// Append the node (plus its children) at other_position as last/first child of position.
302 template<typename iter> iter append_child(iter position, iter other_position);
303 template<typename iter> iter prepend_child(iter position, iter other_position);
304 /// Append the nodes in the from-to range (plus their children) as last/first children of position.
305 template<typename iter> iter append_children(iter position, sibling_iterator from, sibling_iterator to);
306 template<typename iter> iter prepend_children(iter position, sibling_iterator from, sibling_iterator to);
308 /// Short-hand to insert topmost node in otherwise empty tree.
309 pre_order_iterator set_head(const T& x);
310 /// Insert node as previous sibling of node pointed to by position.
311 template<typename iter> iter insert(iter position, const T& x);
312 /// Specialisation of previous member.
313 sibling_iterator insert(sibling_iterator position, const T& x);
314 /// Insert node (with children) pointed to by subtree as previous sibling of node pointed to by position.
315 template<typename iter> iter insert_subtree(iter position, const iterator_base& subtree);
316 /// Insert node as next sibling of node pointed to by position.
317 template<typename iter> iter insert_after(iter position, const T& x);
318 /// Insert node (with children) pointed to by subtree as next sibling of node pointed to by position.
319 template<typename iter> iter insert_subtree_after(iter position, const iterator_base& subtree);
321 /// Replace node at 'position' with other node (keeping same children); 'position' becomes invalid.
322 template<typename iter> iter replace(iter position, const T& x);
323 /// Replace node at 'position' with subtree starting at 'from' (do not erase subtree at 'from'); see above.
324 template<typename iter> iter replace(iter position, const iterator_base& from);
325 /// Replace string of siblings (plus their children) with copy of a new string (with children); see above
326 sibling_iterator replace(sibling_iterator orig_begin, sibling_iterator orig_end,
327 sibling_iterator new_begin, sibling_iterator new_end);
329 /// Move all children of node at 'position' to be siblings, returns position.
330 template<typename iter> iter flatten(iter position);
331 /// Move nodes in range to be children of 'position'.
332 template<typename iter> iter reparent(iter position, sibling_iterator begin, sibling_iterator end);
333 /// Move all child nodes of 'from' to be children of 'position'.
334 template<typename iter> iter reparent(iter position, iter from);
336 /// Replace node with a new node, making the old node a child of the new node.
337 template<typename iter> iter wrap(iter position, const T& x);
339 /// Move 'source' node (plus its children) to become the next sibling of 'target'.
340 template<typename iter> iter move_after(iter target, iter source);
341 /// Move 'source' node (plus its children) to become the previous sibling of 'target'.
342 template<typename iter> iter move_before(iter target, iter source);
343 sibling_iterator move_before(sibling_iterator target, sibling_iterator source);
344 /// Move 'source' node (plus its children) to become the node at 'target' (erasing the node at 'target').
345 template<typename iter> iter move_ontop(iter target, iter source);
347 /// Merge with other tree, creating new branches and leaves only if they are not already present.
348 void merge(sibling_iterator, sibling_iterator, sibling_iterator, sibling_iterator,
349 bool duplicate_leaves=false);
350 /// Sort (std::sort only moves values of nodes, this one moves children as well).
351 void sort(sibling_iterator from, sibling_iterator to, bool deep=false);
352 template<class StrictWeakOrdering>
353 void sort(sibling_iterator from, sibling_iterator to, StrictWeakOrdering comp, bool deep=false);
354 /// Compare two ranges of nodes (compares nodes as well as tree structure).
355 template<typename iter>
356 bool equal(const iter& one, const iter& two, const iter& three) const;
357 template<typename iter, class BinaryPredicate>
358 bool equal(const iter& one, const iter& two, const iter& three, BinaryPredicate) const;
359 template<typename iter>
360 bool equal_subtree(const iter& one, const iter& two) const;
361 template<typename iter, class BinaryPredicate>
362 bool equal_subtree(const iter& one, const iter& two, BinaryPredicate) const;
363 /// Extract a new tree formed by the range of siblings plus all their children.
364 tree subtree(sibling_iterator from, sibling_iterator to) const;
365 void subtree(tree&, sibling_iterator from, sibling_iterator to) const;
366 /// Exchange the node (plus subtree) with its sibling node (do nothing if no sibling present).
367 void swap(sibling_iterator it);
368 /// Exchange two nodes (plus subtrees)
369 void swap(iterator, iterator);
371 /// Count the total number of nodes.
373 /// Count the total number of nodes below the indicated node (plus one).
374 size_t size(const iterator_base&) const;
375 /// Check if tree is empty.
377 /// Compute the depth to the root or to a fixed other iterator.
378 static int depth(const iterator_base&);
379 static int depth(const iterator_base&, const iterator_base&);
380 /// Determine the maximal depth of the tree. An empty tree has max_depth=-1.
381 int max_depth() const;
382 /// Determine the maximal depth of the tree with top node at the given position.
383 int max_depth(const iterator_base&) const;
384 /// Count the number of children of node at position.
385 static unsigned int number_of_children(const iterator_base&);
386 /// Count the number of siblings (left and right) of node at iterator. Total nodes at this level is +1.
387 unsigned int number_of_siblings(const iterator_base&) const;
388 /// Determine whether node at position is in the subtrees with root in the range.
389 bool is_in_subtree(const iterator_base& position, const iterator_base& begin,
390 const iterator_base& end) const;
391 /// Determine whether the iterator is an 'end' iterator and thus not actually pointing to a node.
392 bool is_valid(const iterator_base&) const;
394 /// Determine the index of a node in the range of siblings to which it belongs.
395 unsigned int index(sibling_iterator it) const;
396 /// Inverse of 'index': return the n-th child of the node at position.
397 static sibling_iterator child(const iterator_base& position, unsigned int);
398 /// Return iterator to the sibling indicated by index
399 sibling_iterator sibling(const iterator_base& position, unsigned int);
401 /// Comparator class for iterators (compares pointer values; why doesn't this work automatically?)
402 class iterator_base_less {
404 bool operator()(const typename tree<T, tree_node_allocator>::iterator_base& one,
405 const typename tree<T, tree_node_allocator>::iterator_base& two) const
407 return one.node < two.node;
410 tree_node *head, *feet; // head/feet are always dummy; if an iterator points to them it is invalid
412 tree_node_allocator alloc_;
413 void head_initialise_();
414 void copy_(const tree<T, tree_node_allocator>& other);
416 /// Comparator class for two nodes of a tree (used for sorting and searching).
417 template<class StrictWeakOrdering>
418 class compare_nodes {
420 compare_nodes(StrictWeakOrdering comp) : comp_(comp) {};
422 bool operator()(const tree_node *a, const tree_node *b)
424 return comp_(a->data, b->data);
427 StrictWeakOrdering comp_;
431 //template <class T, class tree_node_allocator>
432 //class iterator_base_less {
434 // bool operator()(const typename tree<T, tree_node_allocator>::iterator_base& one,
435 // const typename tree<T, tree_node_allocator>::iterator_base& two) const
437 // txtout << "operatorclass<" << one.node < two.node << std::endl;
438 // return one.node < two.node;
442 // template <class T, class tree_node_allocator>
443 // bool operator<(const typename tree<T, tree_node_allocator>::iterator& one,
444 // const typename tree<T, tree_node_allocator>::iterator& two)
446 // txtout << "operator< " << one.node < two.node << std::endl;
447 // if(one.node < two.node) return true;
451 // template <class T, class tree_node_allocator>
452 // bool operator==(const typename tree<T, tree_node_allocator>::iterator& one,
453 // const typename tree<T, tree_node_allocator>::iterator& two)
455 // txtout << "operator== " << one.node == two.node << std::endl;
456 // if(one.node == two.node) return true;
460 // template <class T, class tree_node_allocator>
461 // bool operator>(const typename tree<T, tree_node_allocator>::iterator_base& one,
462 // const typename tree<T, tree_node_allocator>::iterator_base& two)
464 // txtout << "operator> " << one.node < two.node << std::endl;
465 // if(one.node > two.node) return true;
473 template <class T, class tree_node_allocator>
474 tree<T, tree_node_allocator>::tree()
479 template <class T, class tree_node_allocator>
480 tree<T, tree_node_allocator>::tree(const T& x)
486 template <class T, class tree_node_allocator>
487 tree<T, tree_node_allocator>::tree(const iterator_base& other)
491 replace(begin(), other);
494 template <class T, class tree_node_allocator>
495 tree<T, tree_node_allocator>::~tree()
498 alloc_.deallocate(head,1);
499 alloc_.deallocate(feet,1);
502 template <class T, class tree_node_allocator>
503 void tree<T, tree_node_allocator>::head_initialise_()
505 head = alloc_.allocate(1,0); // MSVC does not have default second argument
506 feet = alloc_.allocate(1,0);
511 head->prev_sibling=0; //head;
512 head->next_sibling=feet; //head;
517 feet->prev_sibling=head;
518 feet->next_sibling=0;
521 template <class T, class tree_node_allocator>
522 void tree<T, tree_node_allocator>::operator=(const tree<T, tree_node_allocator>& other)
527 template <class T, class tree_node_allocator>
528 tree<T, tree_node_allocator>::tree(const tree<T, tree_node_allocator>& other)
534 template <class T, class tree_node_allocator>
535 void tree<T, tree_node_allocator>::copy_(const tree<T, tree_node_allocator>& other)
538 pre_order_iterator it=other.begin(), to=begin();
539 while(it!=other.end()) {
540 to=insert(to, (*it));
546 while(it!=other.end()) {
555 template <class T, class tree_node_allocator>
556 void tree<T, tree_node_allocator>::clear()
559 while(head->next_sibling!=feet)
560 erase(pre_order_iterator(head->next_sibling));
563 template<class T, class tree_node_allocator>
564 void tree<T, tree_node_allocator>::erase_children(const iterator_base& it)
566 // std::cout << "erase_children " << it.node << std::endl;
567 if(it.node==0) return;
569 tree_node *cur=it.node->first_child;
574 cur=cur->next_sibling;
575 erase_children(pre_order_iterator(prev));
576 kp::destructor(&prev->data);
577 alloc_.deallocate(prev,1);
579 it.node->first_child=0;
580 it.node->last_child=0;
581 // std::cout << "exit" << std::endl;
584 template<class T, class tree_node_allocator>
586 iter tree<T, tree_node_allocator>::erase(iter it)
588 tree_node *cur=it.node;
594 if(cur->prev_sibling==0) {
595 cur->parent->first_child=cur->next_sibling;
598 cur->prev_sibling->next_sibling=cur->next_sibling;
600 if(cur->next_sibling==0) {
601 cur->parent->last_child=cur->prev_sibling;
604 cur->next_sibling->prev_sibling=cur->prev_sibling;
607 kp::destructor(&cur->data);
608 alloc_.deallocate(cur,1);
612 template <class T, class tree_node_allocator>
613 typename tree<T, tree_node_allocator>::pre_order_iterator tree<T, tree_node_allocator>::begin() const
615 return pre_order_iterator(head->next_sibling);
618 template <class T, class tree_node_allocator>
619 typename tree<T, tree_node_allocator>::pre_order_iterator tree<T, tree_node_allocator>::end() const
621 return pre_order_iterator(feet);
624 template <class T, class tree_node_allocator>
625 typename tree<T, tree_node_allocator>::breadth_first_queued_iterator tree<T, tree_node_allocator>::begin_breadth_first() const
627 return breadth_first_queued_iterator(head->next_sibling);
630 template <class T, class tree_node_allocator>
631 typename tree<T, tree_node_allocator>::breadth_first_queued_iterator tree<T, tree_node_allocator>::end_breadth_first() const
633 return breadth_first_queued_iterator();
636 template <class T, class tree_node_allocator>
637 typename tree<T, tree_node_allocator>::post_order_iterator tree<T, tree_node_allocator>::begin_post() const
639 tree_node *tmp=head->next_sibling;
641 while(tmp->first_child)
642 tmp=tmp->first_child;
644 return post_order_iterator(tmp);
647 template <class T, class tree_node_allocator>
648 typename tree<T, tree_node_allocator>::post_order_iterator tree<T, tree_node_allocator>::end_post() const
650 return post_order_iterator(feet);
653 template <class T, class tree_node_allocator>
654 typename tree<T, tree_node_allocator>::fixed_depth_iterator tree<T, tree_node_allocator>::begin_fixed(const iterator_base& pos, unsigned int dp) const
656 typename tree<T, tree_node_allocator>::fixed_depth_iterator ret;
657 ret.top_node=pos.node;
659 tree_node *tmp=pos.node;
660 unsigned int curdepth=0;
661 while(curdepth<dp) { // go down one level
662 while(tmp->first_child==0) {
663 if(tmp->next_sibling==0) {
664 // try to walk up and then right again
666 if(tmp==ret.top_node)
667 throw std::range_error("tree: begin_fixed out of range");
670 throw std::range_error("tree: begin_fixed out of range");
672 } while(tmp->next_sibling==0);
674 tmp=tmp->next_sibling;
676 tmp=tmp->first_child;
684 template <class T, class tree_node_allocator>
685 typename tree<T, tree_node_allocator>::fixed_depth_iterator tree<T, tree_node_allocator>::end_fixed(const iterator_base& pos, unsigned int dp) const
687 assert(1==0); // FIXME: not correct yet: use is_valid() as a temporary workaround
688 tree_node *tmp=pos.node;
689 unsigned int curdepth=1;
690 while(curdepth<dp) { // go down one level
691 while(tmp->first_child==0) {
692 tmp=tmp->next_sibling;
694 throw std::range_error("tree: end_fixed out of range");
696 tmp=tmp->first_child;
702 template <class T, class tree_node_allocator>
703 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::begin(const iterator_base& pos) const
706 if(pos.node->first_child==0) {
709 return pos.node->first_child;
712 template <class T, class tree_node_allocator>
713 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::end(const iterator_base& pos) const
715 sibling_iterator ret(0);
716 ret.parent_=pos.node;
720 template <class T, class tree_node_allocator>
721 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::begin_leaf() const
723 tree_node *tmp=head->next_sibling;
725 while(tmp->first_child)
726 tmp=tmp->first_child;
728 return leaf_iterator(tmp);
731 template <class T, class tree_node_allocator>
732 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::end_leaf() const
734 return leaf_iterator(feet);
737 template <class T, class tree_node_allocator>
738 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::begin_leaf(const iterator_base& top) const
740 tree_node *tmp=top.node;
741 while(tmp->first_child)
742 tmp=tmp->first_child;
743 return leaf_iterator(tmp, top.node);
746 template <class T, class tree_node_allocator>
747 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::end_leaf(const iterator_base& top) const
749 return leaf_iterator(top.node, top.node);
752 template <class T, class tree_node_allocator>
753 template <typename iter>
754 iter tree<T, tree_node_allocator>::parent(iter position)
756 assert(position.node!=0);
757 return iter(position.node->parent);
760 template <class T, class tree_node_allocator>
761 template <typename iter>
762 iter tree<T, tree_node_allocator>::previous_sibling(iter position) const
764 assert(position.node!=0);
766 ret.node=position.node->prev_sibling;
770 template <class T, class tree_node_allocator>
771 template <typename iter>
772 iter tree<T, tree_node_allocator>::next_sibling(iter position) const
774 assert(position.node!=0);
776 ret.node=position.node->next_sibling;
780 template <class T, class tree_node_allocator>
781 template <typename iter>
782 iter tree<T, tree_node_allocator>::next_at_same_depth(iter position) const
784 // We make use of a temporary fixed_depth iterator to implement this.
786 typename tree<T, tree_node_allocator>::fixed_depth_iterator tmp(position.node);
791 // assert(position.node!=0);
792 // iter ret(position);
794 // if(position.node->next_sibling) {
795 // ret.node=position.node->next_sibling;
798 // int relative_depth=0;
801 // ret.node=ret.node->parent;
802 // if(ret.node==0) return ret;
804 // } while(ret.node->next_sibling==0);
806 // ret.node=ret.node->next_sibling;
807 // while(ret.node->first_child==0) {
808 // if(ret.node->next_sibling==0)
810 // ret.node=ret.node->next_sibling;
811 // if(ret.node==0) return ret;
813 // while(relative_depth<0 && ret.node->first_child!=0) {
814 // ret.node=ret.node->first_child;
817 // if(relative_depth<0) {
818 // if(ret.node->next_sibling==0) goto upper;
825 template <class T, class tree_node_allocator>
826 template <typename iter>
827 iter tree<T, tree_node_allocator>::append_child(iter position)
829 assert(position.node!=head);
830 assert(position.node);
832 tree_node *tmp=alloc_.allocate(1,0);
833 kp::constructor(&tmp->data);
837 tmp->parent=position.node;
838 if(position.node->last_child!=0) {
839 position.node->last_child->next_sibling=tmp;
842 position.node->first_child=tmp;
844 tmp->prev_sibling=position.node->last_child;
845 position.node->last_child=tmp;
850 template <class T, class tree_node_allocator>
851 template <typename iter>
852 iter tree<T, tree_node_allocator>::prepend_child(iter position)
854 assert(position.node!=head);
855 assert(position.node);
857 tree_node *tmp=alloc_.allocate(1,0);
858 kp::constructor(&tmp->data);
862 tmp->parent=position.node;
863 if(position.node->first_child!=0) {
864 position.node->first_child->prev_sibling=tmp;
867 position.node->last_child=tmp;
869 tmp->next_sibling=position.node->first_child;
870 position.node->prev_child=tmp;
875 template <class T, class tree_node_allocator>
876 template <class iter>
877 iter tree<T, tree_node_allocator>::append_child(iter position, const T& x)
879 // If your program fails here you probably used 'append_child' to add the top
880 // node to an empty tree. From version 1.45 the top element should be added
881 // using 'insert'. See the documentation for further information, and sorry about
883 assert(position.node!=head);
884 assert(position.node);
886 tree_node* tmp = alloc_.allocate(1,0);
887 kp::constructor(&tmp->data, x);
891 tmp->parent=position.node;
892 if(position.node->last_child!=0) {
893 position.node->last_child->next_sibling=tmp;
896 position.node->first_child=tmp;
898 tmp->prev_sibling=position.node->last_child;
899 position.node->last_child=tmp;
904 template <class T, class tree_node_allocator>
905 template <class iter>
906 iter tree<T, tree_node_allocator>::prepend_child(iter position, const T& x)
908 assert(position.node!=head);
909 assert(position.node);
911 tree_node* tmp = alloc_.allocate(1,0);
912 kp::constructor(&tmp->data, x);
916 tmp->parent=position.node;
917 if(position.node->first_child!=0) {
918 position.node->first_child->prev_sibling=tmp;
921 position.node->last_child=tmp;
923 tmp->next_sibling=position.node->first_child;
924 position.node->first_child=tmp;
929 template <class T, class tree_node_allocator>
930 template <class iter>
931 iter tree<T, tree_node_allocator>::append_child(iter position, iter other)
933 assert(position.node!=head);
934 assert(position.node);
936 sibling_iterator aargh=append_child(position, value_type());
937 return replace(aargh, other);
940 template <class T, class tree_node_allocator>
941 template <class iter>
942 iter tree<T, tree_node_allocator>::prepend_child(iter position, iter other)
944 assert(position.node!=head);
945 assert(position.node);
947 sibling_iterator aargh=prepend_child(position, value_type());
948 return replace(aargh, other);
951 template <class T, class tree_node_allocator>
952 template <class iter>
953 iter tree<T, tree_node_allocator>::append_children(iter position, sibling_iterator from, sibling_iterator to)
955 assert(position.node!=head);
956 assert(position.node);
961 insert_subtree(position.end(), from);
967 template <class T, class tree_node_allocator>
968 template <class iter>
969 iter tree<T, tree_node_allocator>::prepend_children(iter position, sibling_iterator from, sibling_iterator to)
971 assert(position.node!=head);
972 assert(position.node);
977 insert_subtree(position.begin(), from);
983 template <class T, class tree_node_allocator>
984 typename tree<T, tree_node_allocator>::pre_order_iterator tree<T, tree_node_allocator>::set_head(const T& x)
986 assert(head->next_sibling==feet);
987 return insert(iterator(feet), x);
990 template <class T, class tree_node_allocator>
991 template <class iter>
992 iter tree<T, tree_node_allocator>::insert(iter position, const T& x)
994 if(position.node==0) {
995 position.node=feet; // Backward compatibility: when calling insert on a null node,
996 // insert before the feet.
998 tree_node* tmp = alloc_.allocate(1,0);
999 kp::constructor(&tmp->data, x);
1003 tmp->parent=position.node->parent;
1004 tmp->next_sibling=position.node;
1005 tmp->prev_sibling=position.node->prev_sibling;
1006 position.node->prev_sibling=tmp;
1008 if(tmp->prev_sibling==0) {
1009 if(tmp->parent) // when inserting nodes at the head, there is no parent
1010 tmp->parent->first_child=tmp;
1013 tmp->prev_sibling->next_sibling=tmp;
1017 template <class T, class tree_node_allocator>
1018 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::insert(sibling_iterator position, const T& x)
1020 tree_node* tmp = alloc_.allocate(1,0);
1021 kp::constructor(&tmp->data, x);
1025 tmp->next_sibling=position.node;
1026 if(position.node==0) { // iterator points to end of a subtree
1027 tmp->parent=position.parent_;
1028 tmp->prev_sibling=position.range_last();
1029 tmp->parent->last_child=tmp;
1032 tmp->parent=position.node->parent;
1033 tmp->prev_sibling=position.node->prev_sibling;
1034 position.node->prev_sibling=tmp;
1037 if(tmp->prev_sibling==0) {
1038 if(tmp->parent) // when inserting nodes at the head, there is no parent
1039 tmp->parent->first_child=tmp;
1042 tmp->prev_sibling->next_sibling=tmp;
1046 template <class T, class tree_node_allocator>
1047 template <class iter>
1048 iter tree<T, tree_node_allocator>::insert_after(iter position, const T& x)
1050 tree_node* tmp = alloc_.allocate(1,0);
1051 kp::constructor(&tmp->data, x);
1055 tmp->parent=position.node->parent;
1056 tmp->prev_sibling=position.node;
1057 tmp->next_sibling=position.node->next_sibling;
1058 position.node->next_sibling=tmp;
1060 if(tmp->next_sibling==0) {
1061 if(tmp->parent) // when inserting nodes at the head, there is no parent
1062 tmp->parent->last_child=tmp;
1065 tmp->next_sibling->prev_sibling=tmp;
1070 template <class T, class tree_node_allocator>
1071 template <class iter>
1072 iter tree<T, tree_node_allocator>::insert_subtree(iter position, const iterator_base& subtree)
1075 iter it=insert(position, value_type());
1076 // replace dummy with subtree
1077 return replace(it, subtree);
1080 template <class T, class tree_node_allocator>
1081 template <class iter>
1082 iter tree<T, tree_node_allocator>::insert_subtree_after(iter position, const iterator_base& subtree)
1085 iter it=insert_after(position, value_type());
1086 // replace dummy with subtree
1087 return replace(it, subtree);
1090 // template <class T, class tree_node_allocator>
1091 // template <class iter>
1092 // iter tree<T, tree_node_allocator>::insert_subtree(sibling_iterator position, iter subtree)
1095 // iter it(insert(position, value_type()));
1096 // // replace dummy with subtree
1097 // return replace(it, subtree);
1100 template <class T, class tree_node_allocator>
1101 template <class iter>
1102 iter tree<T, tree_node_allocator>::replace(iter position, const T& x)
1104 kp::destructor(&position.node->data);
1105 kp::constructor(&position.node->data, x);
1109 template <class T, class tree_node_allocator>
1110 template <class iter>
1111 iter tree<T, tree_node_allocator>::replace(iter position, const iterator_base& from)
1113 assert(position.node!=head);
1114 tree_node *current_from=from.node;
1115 tree_node *start_from=from.node;
1116 tree_node *current_to =position.node;
1118 // replace the node at position with head of the replacement tree at from
1119 // std::cout << "warning!" << position.node << std::endl;
1120 erase_children(position);
1121 // std::cout << "no warning!" << std::endl;
1122 tree_node* tmp = alloc_.allocate(1,0);
1123 kp::constructor(&tmp->data, (*from));
1126 if(current_to->prev_sibling==0) {
1127 if(current_to->parent!=0)
1128 current_to->parent->first_child=tmp;
1131 current_to->prev_sibling->next_sibling=tmp;
1133 tmp->prev_sibling=current_to->prev_sibling;
1134 if(current_to->next_sibling==0) {
1135 if(current_to->parent!=0)
1136 current_to->parent->last_child=tmp;
1139 current_to->next_sibling->prev_sibling=tmp;
1141 tmp->next_sibling=current_to->next_sibling;
1142 tmp->parent=current_to->parent;
1143 kp::destructor(¤t_to->data);
1144 alloc_.deallocate(current_to,1);
1147 // only at this stage can we fix 'last'
1148 tree_node *last=from.node->next_sibling;
1150 pre_order_iterator toit=tmp;
1151 // copy all children
1153 assert(current_from!=0);
1154 if(current_from->first_child != 0) {
1155 current_from=current_from->first_child;
1156 toit=append_child(toit, current_from->data);
1159 while(current_from->next_sibling==0 && current_from!=start_from) {
1160 current_from=current_from->parent;
1162 assert(current_from!=0);
1164 current_from=current_from->next_sibling;
1165 if(current_from!=last) {
1166 toit=append_child(parent(toit), current_from->data);
1169 } while(current_from!=last);
1174 template <class T, class tree_node_allocator>
1175 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::replace(
1176 sibling_iterator orig_begin,
1177 sibling_iterator orig_end,
1178 sibling_iterator new_begin,
1179 sibling_iterator new_end)
1181 tree_node *orig_first=orig_begin.node;
1182 tree_node *new_first=new_begin.node;
1183 tree_node *orig_last=orig_first;
1184 while((++orig_begin)!=orig_end)
1185 orig_last=orig_last->next_sibling;
1186 tree_node *new_last=new_first;
1187 while((++new_begin)!=new_end)
1188 new_last=new_last->next_sibling;
1190 // insert all siblings in new_first..new_last before orig_first
1192 pre_order_iterator ret;
1194 pre_order_iterator tt=insert_subtree(pre_order_iterator(orig_first), pre_order_iterator(new_first));
1199 if(new_first==new_last)
1201 new_first=new_first->next_sibling;
1204 // erase old range of siblings
1206 tree_node *next=orig_first;
1210 next=next->next_sibling;
1211 erase((pre_order_iterator)orig_first);
1219 template <class T, class tree_node_allocator>
1220 template <typename iter>
1221 iter tree<T, tree_node_allocator>::flatten(iter position)
1223 if(position.node->first_child==0)
1226 tree_node *tmp=position.node->first_child;
1228 tmp->parent=position.node->parent;
1229 tmp=tmp->next_sibling;
1231 if(position.node->next_sibling) {
1232 position.node->last_child->next_sibling=position.node->next_sibling;
1233 position.node->next_sibling->prev_sibling=position.node->last_child;
1236 position.node->parent->last_child=position.node->last_child;
1238 position.node->next_sibling=position.node->first_child;
1239 position.node->next_sibling->prev_sibling=position.node;
1240 position.node->first_child=0;
1241 position.node->last_child=0;
1247 template <class T, class tree_node_allocator>
1248 template <typename iter>
1249 iter tree<T, tree_node_allocator>::reparent(iter position, sibling_iterator begin, sibling_iterator end)
1251 tree_node *first=begin.node;
1252 tree_node *last=first;
1254 assert(first!=position.node);
1256 if(begin==end) return begin;
1257 // determine last node
1258 while((++begin)!=end) {
1259 last=last->next_sibling;
1262 if(first->prev_sibling==0) {
1263 first->parent->first_child=last->next_sibling;
1266 first->prev_sibling->next_sibling=last->next_sibling;
1268 if(last->next_sibling==0) {
1269 last->parent->last_child=first->prev_sibling;
1272 last->next_sibling->prev_sibling=first->prev_sibling;
1274 if(position.node->first_child==0) {
1275 position.node->first_child=first;
1276 position.node->last_child=last;
1277 first->prev_sibling=0;
1280 position.node->last_child->next_sibling=first;
1281 first->prev_sibling=position.node->last_child;
1282 position.node->last_child=last;
1284 last->next_sibling=0;
1286 tree_node *pos=first;
1288 pos->parent=position.node;
1289 if(pos==last) break;
1290 pos=pos->next_sibling;
1296 template <class T, class tree_node_allocator>
1297 template <typename iter> iter tree<T, tree_node_allocator>::reparent(iter position, iter from)
1299 if(from.node->first_child==0) return position;
1300 return reparent(position, from.node->first_child, end(from));
1303 template <class T, class tree_node_allocator>
1304 template <typename iter> iter tree<T, tree_node_allocator>::wrap(iter position, const T& x)
1306 assert(position.node!=0);
1307 sibling_iterator fr=position, to=position;
1309 iter ret = insert(position, x);
1310 reparent(ret, fr, to);
1314 template <class T, class tree_node_allocator>
1315 template <typename iter> iter tree<T, tree_node_allocator>::move_after(iter target, iter source)
1317 tree_node *dst=target.node;
1318 tree_node *src=source.node;
1322 if(dst==src) return source;
1323 if(dst->next_sibling)
1324 if(dst->next_sibling==src) // already in the right spot
1327 // take src out of the tree
1328 if(src->prev_sibling!=0) src->prev_sibling->next_sibling=src->next_sibling;
1329 else src->parent->first_child=src->next_sibling;
1330 if(src->next_sibling!=0) src->next_sibling->prev_sibling=src->prev_sibling;
1331 else src->parent->last_child=src->prev_sibling;
1333 // connect it to the new point
1334 if(dst->next_sibling!=0) dst->next_sibling->prev_sibling=src;
1335 else dst->parent->last_child=src;
1336 src->next_sibling=dst->next_sibling;
1337 dst->next_sibling=src;
1338 src->prev_sibling=dst;
1339 src->parent=dst->parent;
1343 template <class T, class tree_node_allocator>
1344 template <typename iter> iter tree<T, tree_node_allocator>::move_before(iter target, iter source)
1346 tree_node *dst=target.node;
1347 tree_node *src=source.node;
1351 if(dst==src) return source;
1352 if(dst->prev_sibling)
1353 if(dst->prev_sibling==src) // already in the right spot
1356 // take src out of the tree
1357 if(src->prev_sibling!=0) src->prev_sibling->next_sibling=src->next_sibling;
1358 else src->parent->first_child=src->next_sibling;
1359 if(src->next_sibling!=0) src->next_sibling->prev_sibling=src->prev_sibling;
1360 else src->parent->last_child=src->prev_sibling;
1362 // connect it to the new point
1363 if(dst->prev_sibling!=0) dst->prev_sibling->next_sibling=src;
1364 else dst->parent->first_child=src;
1365 src->prev_sibling=dst->prev_sibling;
1366 dst->prev_sibling=src;
1367 src->next_sibling=dst;
1368 src->parent=dst->parent;
1372 // specialisation for sibling_iterators
1373 template <class T, class tree_node_allocator>
1374 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::move_before(sibling_iterator target,
1375 sibling_iterator source)
1377 tree_node *dst=target.node;
1378 tree_node *src=source.node;
1379 tree_node *dst_prev_sibling;
1380 if(dst==0) { // must then be an end iterator
1381 dst_prev_sibling=target.parent_->last_child;
1382 assert(dst_prev_sibling);
1384 else dst_prev_sibling=dst->prev_sibling;
1387 if(dst==src) return source;
1388 if(dst_prev_sibling)
1389 if(dst_prev_sibling==src) // already in the right spot
1392 // take src out of the tree
1393 if(src->prev_sibling!=0) src->prev_sibling->next_sibling=src->next_sibling;
1394 else src->parent->first_child=src->next_sibling;
1395 if(src->next_sibling!=0) src->next_sibling->prev_sibling=src->prev_sibling;
1396 else src->parent->last_child=src->prev_sibling;
1398 // connect it to the new point
1399 if(dst_prev_sibling!=0) dst_prev_sibling->next_sibling=src;
1400 else target.parent_->first_child=src;
1401 src->prev_sibling=dst_prev_sibling;
1403 dst->prev_sibling=src;
1404 src->parent=dst->parent;
1406 src->next_sibling=dst;
1410 template <class T, class tree_node_allocator>
1411 template <typename iter> iter tree<T, tree_node_allocator>::move_ontop(iter target, iter source)
1413 tree_node *dst=target.node;
1414 tree_node *src=source.node;
1418 if(dst==src) return source;
1420 // remember connection points
1421 tree_node *b_prev_sibling=dst->prev_sibling;
1422 tree_node *b_next_sibling=dst->next_sibling;
1423 tree_node *b_parent=dst->parent;
1428 // take src out of the tree
1429 if(src->prev_sibling!=0) src->prev_sibling->next_sibling=src->next_sibling;
1430 else src->parent->first_child=src->next_sibling;
1431 if(src->next_sibling!=0) src->next_sibling->prev_sibling=src->prev_sibling;
1432 else src->parent->last_child=src->prev_sibling;
1434 // connect it to the new point
1435 if(b_prev_sibling!=0) b_prev_sibling->next_sibling=src;
1436 else b_parent->first_child=src;
1437 if(b_next_sibling!=0) b_next_sibling->prev_sibling=src;
1438 else b_parent->last_child=src;
1439 src->prev_sibling=b_prev_sibling;
1440 src->next_sibling=b_next_sibling;
1441 src->parent=b_parent;
1445 template <class T, class tree_node_allocator>
1446 void tree<T, tree_node_allocator>::merge(sibling_iterator to1, sibling_iterator to2,
1447 sibling_iterator from1, sibling_iterator from2,
1448 bool duplicate_leaves)
1450 sibling_iterator fnd;
1451 while(from1!=from2) {
1452 if((fnd=std::find(to1, to2, (*from1))) != to2) { // element found
1453 if(from1.begin()==from1.end()) { // full depth reached
1454 if(duplicate_leaves)
1455 append_child(parent(to1), (*from1));
1457 else { // descend further
1458 merge(fnd.begin(), fnd.end(), from1.begin(), from1.end(), duplicate_leaves);
1461 else { // element missing
1462 insert_subtree(to2, from1);
1469 template <class T, class tree_node_allocator>
1470 void tree<T, tree_node_allocator>::sort(sibling_iterator from, sibling_iterator to, bool deep)
1473 sort(from, to, comp, deep);
1476 template <class T, class tree_node_allocator>
1477 template <class StrictWeakOrdering>
1478 void tree<T, tree_node_allocator>::sort(sibling_iterator from, sibling_iterator to,
1479 StrictWeakOrdering comp, bool deep)
1481 if(from==to) return;
1482 // make list of sorted nodes
1483 // CHECK: if multiset stores equivalent nodes in the order in which they
1484 // are inserted, then this routine should be called 'stable_sort'.
1485 std::multiset<tree_node *, compare_nodes<StrictWeakOrdering> > nodes(comp);
1486 sibling_iterator it=from, it2=to;
1488 nodes.insert(it.node);
1494 // prev and next are the nodes before and after the sorted range
1495 tree_node *prev=from.node->prev_sibling;
1496 tree_node *next=it2.node->next_sibling;
1497 typename std::multiset<tree_node *, compare_nodes<StrictWeakOrdering> >::iterator nit=nodes.begin(), eit=nodes.end();
1499 if((*nit)->parent!=0) // to catch "sorting the head" situations, when there is no parent
1500 (*nit)->parent->first_child=(*nit);
1502 else prev->next_sibling=(*nit);
1506 (*nit)->prev_sibling=prev;
1508 prev->next_sibling=(*nit);
1512 // prev now points to the last-but-one node in the sorted range
1514 prev->next_sibling=(*eit);
1516 // eit points to the last node in the sorted range.
1517 (*eit)->next_sibling=next;
1518 (*eit)->prev_sibling=prev; // missed in the loop above
1520 if((*eit)->parent!=0) // to catch "sorting the head" situations, when there is no parent
1521 (*eit)->parent->last_child=(*eit);
1523 else next->prev_sibling=(*eit);
1525 if(deep) { // sort the children of each node too
1526 sibling_iterator bcs(*nodes.begin());
1527 sibling_iterator ecs(*eit);
1530 sort(begin(bcs), end(bcs), comp, deep);
1536 template <class T, class tree_node_allocator>
1537 template <typename iter>
1538 bool tree<T, tree_node_allocator>::equal(const iter& one_, const iter& two, const iter& three_) const
1540 std::equal_to<T> comp;
1541 return equal(one_, two, three_, comp);
1544 template <class T, class tree_node_allocator>
1545 template <typename iter>
1546 bool tree<T, tree_node_allocator>::equal_subtree(const iter& one_, const iter& two_) const
1548 std::equal_to<T> comp;
1549 return equal_subtree(one_, two_, comp);
1552 template <class T, class tree_node_allocator>
1553 template <typename iter, class BinaryPredicate>
1554 bool tree<T, tree_node_allocator>::equal(const iter& one_, const iter& two, const iter& three_, BinaryPredicate fun) const
1556 pre_order_iterator one(one_), three(three_);
1558 // if(one==two && is_valid(three) && three.number_of_children()!=0)
1560 while(one!=two && is_valid(three)) {
1561 if(!fun(*one,*three))
1563 if(one.number_of_children()!=three.number_of_children())
1571 template <class T, class tree_node_allocator>
1572 template <typename iter, class BinaryPredicate>
1573 bool tree<T, tree_node_allocator>::equal_subtree(const iter& one_, const iter& two_, BinaryPredicate fun) const
1575 pre_order_iterator one(one_), two(two_);
1577 if(!fun(*one,*two)) return false;
1578 if(number_of_children(one)!=number_of_children(two)) return false;
1579 return equal(begin(one),end(one),begin(two),fun);
1582 template <class T, class tree_node_allocator>
1583 tree<T, tree_node_allocator> tree<T, tree_node_allocator>::subtree(sibling_iterator from, sibling_iterator to) const
1586 tmp.set_head(value_type());
1587 tmp.replace(tmp.begin(), tmp.end(), from, to);
1591 template <class T, class tree_node_allocator>
1592 void tree<T, tree_node_allocator>::subtree(tree& tmp, sibling_iterator from, sibling_iterator to) const
1594 tmp.set_head(value_type());
1595 tmp.replace(tmp.begin(), tmp.end(), from, to);
1598 template <class T, class tree_node_allocator>
1599 size_t tree<T, tree_node_allocator>::size() const
1602 pre_order_iterator it=begin(), eit=end();
1610 template <class T, class tree_node_allocator>
1611 size_t tree<T, tree_node_allocator>::size(const iterator_base& top) const
1614 pre_order_iterator it=top, eit=top;
1615 eit.skip_children();
1624 template <class T, class tree_node_allocator>
1625 bool tree<T, tree_node_allocator>::empty() const
1627 pre_order_iterator it=begin(), eit=end();
1631 template <class T, class tree_node_allocator>
1632 int tree<T, tree_node_allocator>::depth(const iterator_base& it)
1634 tree_node* pos=it.node;
1637 while(pos->parent!=0) {
1644 template <class T, class tree_node_allocator>
1645 int tree<T, tree_node_allocator>::depth(const iterator_base& it, const iterator_base& root)
1647 tree_node* pos=it.node;
1650 while(pos->parent!=0 && pos!=root.node) {
1657 template <class T, class tree_node_allocator>
1658 int tree<T, tree_node_allocator>::max_depth() const
1661 for(tree_node *it = head->next_sibling; it!=feet; it=it->next_sibling)
1662 maxd=std::max(maxd, max_depth(it));
1668 template <class T, class tree_node_allocator>
1669 int tree<T, tree_node_allocator>::max_depth(const iterator_base& pos) const
1671 tree_node *tmp=pos.node;
1673 if(tmp==0 || tmp==head || tmp==feet) return -1;
1675 int curdepth=0, maxdepth=0;
1676 while(true) { // try to walk the bottom of the tree
1677 while(tmp->first_child==0) {
1678 if(tmp==pos.node) return maxdepth;
1679 if(tmp->next_sibling==0) {
1680 // try to walk up and then right again
1683 if(tmp==0) return maxdepth;
1685 } while(tmp->next_sibling==0);
1687 if(tmp==pos.node) return maxdepth;
1688 tmp=tmp->next_sibling;
1690 tmp=tmp->first_child;
1692 maxdepth=std::max(curdepth, maxdepth);
1696 template <class T, class tree_node_allocator>
1697 unsigned int tree<T, tree_node_allocator>::number_of_children(const iterator_base& it)
1699 tree_node *pos=it.node->first_child;
1700 if(pos==0) return 0;
1703 // while(pos!=it.node->last_child) {
1705 // pos=pos->next_sibling;
1707 while((pos=pos->next_sibling))
1712 template <class T, class tree_node_allocator>
1713 unsigned int tree<T, tree_node_allocator>::number_of_siblings(const iterator_base& it) const
1715 tree_node *pos=it.node;
1718 while(pos->next_sibling &&
1719 pos->next_sibling!=head &&
1720 pos->next_sibling!=feet) {
1722 pos=pos->next_sibling;
1726 while(pos->prev_sibling &&
1727 pos->prev_sibling!=head &&
1728 pos->prev_sibling!=feet) {
1730 pos=pos->prev_sibling;
1736 template <class T, class tree_node_allocator>
1737 void tree<T, tree_node_allocator>::swap(sibling_iterator it)
1739 tree_node *nxt=it.node->next_sibling;
1741 if(it.node->prev_sibling)
1742 it.node->prev_sibling->next_sibling=nxt;
1744 it.node->parent->first_child=nxt;
1745 nxt->prev_sibling=it.node->prev_sibling;
1746 tree_node *nxtnxt=nxt->next_sibling;
1748 nxtnxt->prev_sibling=it.node;
1750 it.node->parent->last_child=it.node;
1751 nxt->next_sibling=it.node;
1752 it.node->prev_sibling=nxt;
1753 it.node->next_sibling=nxtnxt;
1757 template <class T, class tree_node_allocator>
1758 void tree<T, tree_node_allocator>::swap(iterator one, iterator two)
1760 // if one and two are adjacent siblings, use the sibling swap
1761 if(one.node->next_sibling==two.node) swap(one);
1762 else if(two.node->next_sibling==one.node) swap(two);
1764 tree_node *nxt1=one.node->next_sibling;
1765 tree_node *nxt2=two.node->next_sibling;
1766 tree_node *pre1=one.node->prev_sibling;
1767 tree_node *pre2=two.node->prev_sibling;
1768 tree_node *par1=one.node->parent;
1769 tree_node *par2=two.node->parent;
1772 one.node->parent=par2;
1773 one.node->next_sibling=nxt2;
1774 if(nxt2) nxt2->prev_sibling=one.node;
1775 else par2->last_child=one.node;
1776 one.node->prev_sibling=pre2;
1777 if(pre2) pre2->next_sibling=one.node;
1778 else par2->first_child=one.node;
1780 two.node->parent=par1;
1781 two.node->next_sibling=nxt1;
1782 if(nxt1) nxt1->prev_sibling=two.node;
1783 else par1->last_child=two.node;
1784 two.node->prev_sibling=pre1;
1785 if(pre1) pre1->next_sibling=two.node;
1786 else par1->first_child=two.node;
1790 // template <class BinaryPredicate>
1791 // tree<T, tree_node_allocator>::iterator tree<T, tree_node_allocator>::find_subtree(
1792 // sibling_iterator subfrom, sibling_iterator subto, iterator from, iterator to,
1793 // BinaryPredicate fun) const
1795 // assert(1==0); // this routine is not finished yet.
1796 // while(from!=to) {
1797 // if(fun(*subfrom, *from)) {
1804 template <class T, class tree_node_allocator>
1805 bool tree<T, tree_node_allocator>::is_in_subtree(const iterator_base& it, const iterator_base& begin,
1806 const iterator_base& end) const
1808 // FIXME: this should be optimised.
1809 pre_order_iterator tmp=begin;
1811 if(tmp==it) return true;
1817 template <class T, class tree_node_allocator>
1818 bool tree<T, tree_node_allocator>::is_valid(const iterator_base& it) const
1820 if(it.node==0 || it.node==feet || it.node==head) return false;
1824 template <class T, class tree_node_allocator>
1825 unsigned int tree<T, tree_node_allocator>::index(sibling_iterator it) const
1828 if(it.node->parent==0) {
1829 while(it.node->prev_sibling!=head) {
1830 it.node=it.node->prev_sibling;
1835 while(it.node->prev_sibling!=0) {
1836 it.node=it.node->prev_sibling;
1843 template <class T, class tree_node_allocator>
1844 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::sibling(const iterator_base& it, unsigned int num)
1847 if(it.node->parent==0) {
1848 tmp=head->next_sibling;
1850 tmp = tmp->next_sibling;
1855 tmp=it.node->parent->first_child;
1858 tmp = tmp->next_sibling;
1866 template <class T, class tree_node_allocator>
1867 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::child(const iterator_base& it, unsigned int num)
1869 tree_node *tmp=it.node->first_child;
1872 tmp=tmp->next_sibling;
1882 template <class T, class tree_node_allocator>
1883 tree<T, tree_node_allocator>::iterator_base::iterator_base()
1884 : node(0), skip_current_children_(false)
1888 template <class T, class tree_node_allocator>
1889 tree<T, tree_node_allocator>::iterator_base::iterator_base(tree_node *tn)
1890 : node(tn), skip_current_children_(false)
1894 template <class T, class tree_node_allocator>
1895 T& tree<T, tree_node_allocator>::iterator_base::operator*() const
1900 template <class T, class tree_node_allocator>
1901 T* tree<T, tree_node_allocator>::iterator_base::operator->() const
1903 return &(node->data);
1906 template <class T, class tree_node_allocator>
1907 bool tree<T, tree_node_allocator>::post_order_iterator::operator!=(const post_order_iterator& other) const
1909 if(other.node!=this->node) return true;
1913 template <class T, class tree_node_allocator>
1914 bool tree<T, tree_node_allocator>::post_order_iterator::operator==(const post_order_iterator& other) const
1916 if(other.node==this->node) return true;
1920 template <class T, class tree_node_allocator>
1921 bool tree<T, tree_node_allocator>::pre_order_iterator::operator!=(const pre_order_iterator& other) const
1923 if(other.node!=this->node) return true;
1927 template <class T, class tree_node_allocator>
1928 bool tree<T, tree_node_allocator>::pre_order_iterator::operator==(const pre_order_iterator& other) const
1930 if(other.node==this->node) return true;
1934 template <class T, class tree_node_allocator>
1935 bool tree<T, tree_node_allocator>::sibling_iterator::operator!=(const sibling_iterator& other) const
1937 if(other.node!=this->node) return true;
1941 template <class T, class tree_node_allocator>
1942 bool tree<T, tree_node_allocator>::sibling_iterator::operator==(const sibling_iterator& other) const
1944 if(other.node==this->node) return true;
1948 template <class T, class tree_node_allocator>
1949 bool tree<T, tree_node_allocator>::leaf_iterator::operator!=(const leaf_iterator& other) const
1951 if(other.node!=this->node) return true;
1955 template <class T, class tree_node_allocator>
1956 bool tree<T, tree_node_allocator>::leaf_iterator::operator==(const leaf_iterator& other) const
1958 if(other.node==this->node && other.top_node==this->top_node) return true;
1962 template <class T, class tree_node_allocator>
1963 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::iterator_base::begin() const
1965 if(node->first_child==0)
1968 sibling_iterator ret(node->first_child);
1969 ret.parent_=this->node;
1973 template <class T, class tree_node_allocator>
1974 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::iterator_base::end() const
1976 sibling_iterator ret(0);
1981 template <class T, class tree_node_allocator>
1982 void tree<T, tree_node_allocator>::iterator_base::skip_children()
1984 skip_current_children_=true;
1987 template <class T, class tree_node_allocator>
1988 void tree<T, tree_node_allocator>::iterator_base::skip_children(bool skip)
1990 skip_current_children_=skip;
1993 template <class T, class tree_node_allocator>
1994 unsigned int tree<T, tree_node_allocator>::iterator_base::number_of_children() const
1996 tree_node *pos=node->first_child;
1997 if(pos==0) return 0;
2000 while(pos!=node->last_child) {
2002 pos=pos->next_sibling;
2009 // Pre-order iterator
2011 template <class T, class tree_node_allocator>
2012 tree<T, tree_node_allocator>::pre_order_iterator::pre_order_iterator()
2017 template <class T, class tree_node_allocator>
2018 tree<T, tree_node_allocator>::pre_order_iterator::pre_order_iterator(tree_node *tn)
2023 template <class T, class tree_node_allocator>
2024 tree<T, tree_node_allocator>::pre_order_iterator::pre_order_iterator(const iterator_base &other)
2025 : iterator_base(other.node)
2029 template <class T, class tree_node_allocator>
2030 tree<T, tree_node_allocator>::pre_order_iterator::pre_order_iterator(const sibling_iterator& other)
2031 : iterator_base(other.node)
2034 if(other.range_last()!=0)
2035 this->node=other.range_last();
2037 this->node=other.parent_;
2038 this->skip_children();
2043 template <class T, class tree_node_allocator>
2044 typename tree<T, tree_node_allocator>::pre_order_iterator& tree<T, tree_node_allocator>::pre_order_iterator::operator++()
2046 assert(this->node!=0);
2047 if(!this->skip_current_children_ && this->node->first_child != 0) {
2048 this->node=this->node->first_child;
2051 this->skip_current_children_=false;
2052 while(this->node->next_sibling==0) {
2053 this->node=this->node->parent;
2057 this->node=this->node->next_sibling;
2062 template <class T, class tree_node_allocator>
2063 typename tree<T, tree_node_allocator>::pre_order_iterator& tree<T, tree_node_allocator>::pre_order_iterator::operator--()
2065 assert(this->node!=0);
2066 if(this->node->prev_sibling) {
2067 this->node=this->node->prev_sibling;
2068 while(this->node->last_child)
2069 this->node=this->node->last_child;
2072 this->node=this->node->parent;
2079 template <class T, class tree_node_allocator>
2080 typename tree<T, tree_node_allocator>::pre_order_iterator tree<T, tree_node_allocator>::pre_order_iterator::operator++(int)
2082 pre_order_iterator copy = *this;
2087 template <class T, class tree_node_allocator>
2088 typename tree<T, tree_node_allocator>::pre_order_iterator tree<T, tree_node_allocator>::pre_order_iterator::operator--(int)
2090 pre_order_iterator copy = *this;
2095 template <class T, class tree_node_allocator>
2096 typename tree<T, tree_node_allocator>::pre_order_iterator& tree<T, tree_node_allocator>::pre_order_iterator::operator+=(unsigned int num)
2105 template <class T, class tree_node_allocator>
2106 typename tree<T, tree_node_allocator>::pre_order_iterator& tree<T, tree_node_allocator>::pre_order_iterator::operator-=(unsigned int num)
2117 // Post-order iterator
2119 template <class T, class tree_node_allocator>
2120 tree<T, tree_node_allocator>::post_order_iterator::post_order_iterator()
2125 template <class T, class tree_node_allocator>
2126 tree<T, tree_node_allocator>::post_order_iterator::post_order_iterator(tree_node *tn)
2131 template <class T, class tree_node_allocator>
2132 tree<T, tree_node_allocator>::post_order_iterator::post_order_iterator(const iterator_base &other)
2133 : iterator_base(other.node)
2137 template <class T, class tree_node_allocator>
2138 tree<T, tree_node_allocator>::post_order_iterator::post_order_iterator(const sibling_iterator& other)
2139 : iterator_base(other.node)
2142 if(other.range_last()!=0)
2143 this->node=other.range_last();
2145 this->node=other.parent_;
2146 this->skip_children();
2151 template <class T, class tree_node_allocator>
2152 typename tree<T, tree_node_allocator>::post_order_iterator& tree<T, tree_node_allocator>::post_order_iterator::operator++()
2154 assert(this->node!=0);
2155 if(this->node->next_sibling==0) {
2156 this->node=this->node->parent;
2157 this->skip_current_children_=false;
2160 this->node=this->node->next_sibling;
2161 if(this->skip_current_children_) {
2162 this->skip_current_children_=false;
2165 while(this->node->first_child)
2166 this->node=this->node->first_child;
2172 template <class T, class tree_node_allocator>
2173 typename tree<T, tree_node_allocator>::post_order_iterator& tree<T, tree_node_allocator>::post_order_iterator::operator--()
2175 assert(this->node!=0);
2176 if(this->skip_current_children_ || this->node->last_child==0) {
2177 this->skip_current_children_=false;
2178 while(this->node->prev_sibling==0)
2179 this->node=this->node->parent;
2180 this->node=this->node->prev_sibling;
2183 this->node=this->node->last_child;
2188 template <class T, class tree_node_allocator>
2189 typename tree<T, tree_node_allocator>::post_order_iterator tree<T, tree_node_allocator>::post_order_iterator::operator++(int)
2191 post_order_iterator copy = *this;
2196 template <class T, class tree_node_allocator>
2197 typename tree<T, tree_node_allocator>::post_order_iterator tree<T, tree_node_allocator>::post_order_iterator::operator--(int)
2199 post_order_iterator copy = *this;
2205 template <class T, class tree_node_allocator>
2206 typename tree<T, tree_node_allocator>::post_order_iterator& tree<T, tree_node_allocator>::post_order_iterator::operator+=(unsigned int num)
2215 template <class T, class tree_node_allocator>
2216 typename tree<T, tree_node_allocator>::post_order_iterator& tree<T, tree_node_allocator>::post_order_iterator::operator-=(unsigned int num)
2225 template <class T, class tree_node_allocator>
2226 void tree<T, tree_node_allocator>::post_order_iterator::descend_all()
2228 assert(this->node!=0);
2229 while(this->node->first_child)
2230 this->node=this->node->first_child;
2234 // Breadth-first iterator
2236 template <class T, class tree_node_allocator>
2237 tree<T, tree_node_allocator>::breadth_first_queued_iterator::breadth_first_queued_iterator()
2242 template <class T, class tree_node_allocator>
2243 tree<T, tree_node_allocator>::breadth_first_queued_iterator::breadth_first_queued_iterator(tree_node *tn)
2246 traversal_queue.push(tn);
2249 template <class T, class tree_node_allocator>
2250 tree<T, tree_node_allocator>::breadth_first_queued_iterator::breadth_first_queued_iterator(const iterator_base& other)
2251 : iterator_base(other.node)
2253 traversal_queue.push(other.node);
2256 template <class T, class tree_node_allocator>
2257 bool tree<T, tree_node_allocator>::breadth_first_queued_iterator::operator!=(const breadth_first_queued_iterator& other) const
2259 if(other.node!=this->node) return true;
2263 template <class T, class tree_node_allocator>
2264 bool tree<T, tree_node_allocator>::breadth_first_queued_iterator::operator==(const breadth_first_queued_iterator& other) const
2266 if(other.node==this->node) return true;
2270 template <class T, class tree_node_allocator>
2271 typename tree<T, tree_node_allocator>::breadth_first_queued_iterator& tree<T, tree_node_allocator>::breadth_first_queued_iterator::operator++()
2273 assert(this->node!=0);
2275 // Add child nodes and pop current node
2276 sibling_iterator sib=this->begin();
2277 while(sib!=this->end()) {
2278 traversal_queue.push(sib.node);
2281 traversal_queue.pop();
2282 if(traversal_queue.size()>0)
2283 this->node=traversal_queue.front();
2289 template <class T, class tree_node_allocator>
2290 typename tree<T, tree_node_allocator>::breadth_first_queued_iterator tree<T, tree_node_allocator>::breadth_first_queued_iterator::operator++(int)
2292 breadth_first_queued_iterator copy = *this;
2297 template <class T, class tree_node_allocator>
2298 typename tree<T, tree_node_allocator>::breadth_first_queued_iterator& tree<T, tree_node_allocator>::breadth_first_queued_iterator::operator+=(unsigned int num)
2309 // Fixed depth iterator
2311 template <class T, class tree_node_allocator>
2312 tree<T, tree_node_allocator>::fixed_depth_iterator::fixed_depth_iterator()
2317 template <class T, class tree_node_allocator>
2318 tree<T, tree_node_allocator>::fixed_depth_iterator::fixed_depth_iterator(tree_node *tn)
2319 : iterator_base(tn), top_node(0)
2323 template <class T, class tree_node_allocator>
2324 tree<T, tree_node_allocator>::fixed_depth_iterator::fixed_depth_iterator(const iterator_base& other)
2325 : iterator_base(other.node), top_node(0)
2329 template <class T, class tree_node_allocator>
2330 tree<T, tree_node_allocator>::fixed_depth_iterator::fixed_depth_iterator(const sibling_iterator& other)
2331 : iterator_base(other.node), top_node(0)
2335 template <class T, class tree_node_allocator>
2336 tree<T, tree_node_allocator>::fixed_depth_iterator::fixed_depth_iterator(const fixed_depth_iterator& other)
2337 : iterator_base(other.node), top_node(other.top_node)
2341 template <class T, class tree_node_allocator>
2342 bool tree<T, tree_node_allocator>::fixed_depth_iterator::operator==(const fixed_depth_iterator& other) const
2344 if(other.node==this->node && other.top_node==top_node) return true;
2348 template <class T, class tree_node_allocator>
2349 bool tree<T, tree_node_allocator>::fixed_depth_iterator::operator!=(const fixed_depth_iterator& other) const
2351 if(other.node!=this->node || other.top_node!=top_node) return true;
2355 template <class T, class tree_node_allocator>
2356 typename tree<T, tree_node_allocator>::fixed_depth_iterator& tree<T, tree_node_allocator>::fixed_depth_iterator::operator++()
2358 assert(this->node!=0);
2360 if(this->node->next_sibling) {
2361 this->node=this->node->next_sibling;
2364 int relative_depth=0;
2367 if(this->node==this->top_node) {
2368 this->node=0; // FIXME: return a proper fixed_depth end iterator once implemented
2371 this->node=this->node->parent;
2372 if(this->node==0) return *this;
2374 } while(this->node->next_sibling==0);
2376 this->node=this->node->next_sibling;
2377 while(this->node->first_child==0) {
2378 if(this->node->next_sibling==0)
2380 this->node=this->node->next_sibling;
2381 if(this->node==0) return *this;
2383 while(relative_depth<0 && this->node->first_child!=0) {
2384 this->node=this->node->first_child;
2387 if(relative_depth<0) {
2388 if(this->node->next_sibling==0) goto upper;
2395 template <class T, class tree_node_allocator>
2396 typename tree<T, tree_node_allocator>::fixed_depth_iterator& tree<T, tree_node_allocator>::fixed_depth_iterator::operator--()
2398 assert(this->node!=0);
2400 if(this->node->prev_sibling) {
2401 this->node=this->node->prev_sibling;
2404 int relative_depth=0;
2407 if(this->node==this->top_node) {
2411 this->node=this->node->parent;
2412 if(this->node==0) return *this;
2414 } while(this->node->prev_sibling==0);
2416 this->node=this->node->prev_sibling;
2417 while(this->node->last_child==0) {
2418 if(this->node->prev_sibling==0)
2420 this->node=this->node->prev_sibling;
2421 if(this->node==0) return *this;
2423 while(relative_depth<0 && this->node->last_child!=0) {
2424 this->node=this->node->last_child;
2427 if(relative_depth<0) {
2428 if(this->node->prev_sibling==0) goto upper;
2436 // assert(this->node!=0);
2437 // if(this->node->prev_sibling!=0) {
2438 // this->node=this->node->prev_sibling;
2439 // assert(this->node!=0);
2440 // if(this->node->parent==0 && this->node->prev_sibling==0) // head element
2444 // tree_node *par=this->node->parent;
2446 // par=par->prev_sibling;
2447 // if(par==0) { // FIXME: need to keep track of this!
2451 // } while(par->last_child==0);
2452 // this->node=par->last_child;
2457 template <class T, class tree_node_allocator>
2458 typename tree<T, tree_node_allocator>::fixed_depth_iterator tree<T, tree_node_allocator>::fixed_depth_iterator::operator++(int)
2460 fixed_depth_iterator copy = *this;
2465 template <class T, class tree_node_allocator>
2466 typename tree<T, tree_node_allocator>::fixed_depth_iterator tree<T, tree_node_allocator>::fixed_depth_iterator::operator--(int)
2468 fixed_depth_iterator copy = *this;
2473 template <class T, class tree_node_allocator>
2474 typename tree<T, tree_node_allocator>::fixed_depth_iterator& tree<T, tree_node_allocator>::fixed_depth_iterator::operator-=(unsigned int num)
2483 template <class T, class tree_node_allocator>
2484 typename tree<T, tree_node_allocator>::fixed_depth_iterator& tree<T, tree_node_allocator>::fixed_depth_iterator::operator+=(unsigned int num)
2496 template <class T, class tree_node_allocator>
2497 tree<T, tree_node_allocator>::sibling_iterator::sibling_iterator()
2503 template <class T, class tree_node_allocator>
2504 tree<T, tree_node_allocator>::sibling_iterator::sibling_iterator(tree_node *tn)
2510 template <class T, class tree_node_allocator>
2511 tree<T, tree_node_allocator>::sibling_iterator::sibling_iterator(const iterator_base& other)
2512 : iterator_base(other.node)
2517 template <class T, class tree_node_allocator>
2518 tree<T, tree_node_allocator>::sibling_iterator::sibling_iterator(const sibling_iterator& other)
2519 : iterator_base(other), parent_(other.parent_)
2523 template <class T, class tree_node_allocator>
2524 void tree<T, tree_node_allocator>::sibling_iterator::set_parent_()
2527 if(this->node==0) return;
2528 if(this->node->parent!=0)
2529 parent_=this->node->parent;
2532 template <class T, class tree_node_allocator>
2533 typename tree<T, tree_node_allocator>::sibling_iterator& tree<T, tree_node_allocator>::sibling_iterator::operator++()
2536 this->node=this->node->next_sibling;
2540 template <class T, class tree_node_allocator>
2541 typename tree<T, tree_node_allocator>::sibling_iterator& tree<T, tree_node_allocator>::sibling_iterator::operator--()
2543 if(this->node) this->node=this->node->prev_sibling;
2546 this->node=parent_->last_child;
2551 template <class T, class tree_node_allocator>
2552 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::sibling_iterator::operator++(int)
2554 sibling_iterator copy = *this;
2559 template <class T, class tree_node_allocator>
2560 typename tree<T, tree_node_allocator>::sibling_iterator tree<T, tree_node_allocator>::sibling_iterator::operator--(int)
2562 sibling_iterator copy = *this;
2567 template <class T, class tree_node_allocator>
2568 typename tree<T, tree_node_allocator>::sibling_iterator& tree<T, tree_node_allocator>::sibling_iterator::operator+=(unsigned int num)
2577 template <class T, class tree_node_allocator>
2578 typename tree<T, tree_node_allocator>::sibling_iterator& tree<T, tree_node_allocator>::sibling_iterator::operator-=(unsigned int num)
2587 template <class T, class tree_node_allocator>
2588 typename tree<T, tree_node_allocator>::tree_node *tree<T, tree_node_allocator>::sibling_iterator::range_first() const
2590 tree_node *tmp=parent_->first_child;
2594 template <class T, class tree_node_allocator>
2595 typename tree<T, tree_node_allocator>::tree_node *tree<T, tree_node_allocator>::sibling_iterator::range_last() const
2597 return parent_->last_child;
2602 template <class T, class tree_node_allocator>
2603 tree<T, tree_node_allocator>::leaf_iterator::leaf_iterator()
2604 : iterator_base(0), top_node(0)
2608 template <class T, class tree_node_allocator>
2609 tree<T, tree_node_allocator>::leaf_iterator::leaf_iterator(tree_node *tn, tree_node *top)
2610 : iterator_base(tn), top_node(top)
2614 template <class T, class tree_node_allocator>
2615 tree<T, tree_node_allocator>::leaf_iterator::leaf_iterator(const iterator_base &other)
2616 : iterator_base(other.node), top_node(0)
2620 template <class T, class tree_node_allocator>
2621 tree<T, tree_node_allocator>::leaf_iterator::leaf_iterator(const sibling_iterator& other)
2622 : iterator_base(other.node), top_node(0)
2625 if(other.range_last()!=0)
2626 this->node=other.range_last();
2628 this->node=other.parent_;
2633 template <class T, class tree_node_allocator>
2634 typename tree<T, tree_node_allocator>::leaf_iterator& tree<T, tree_node_allocator>::leaf_iterator::operator++()
2636 assert(this->node!=0);
2637 if(this->node->first_child!=0) { // current node is no longer leaf (children got added)
2638 while(this->node->first_child)
2639 this->node=this->node->first_child;
2642 while(this->node->next_sibling==0) {
2643 if (this->node->parent==0) return *this;
2644 this->node=this->node->parent;
2645 if (top_node != 0 && this->node==top_node) return *this;
2647 this->node=this->node->next_sibling;
2648 while(this->node->first_child)
2649 this->node=this->node->first_child;
2654 template <class T, class tree_node_allocator>
2655 typename tree<T, tree_node_allocator>::leaf_iterator& tree<T, tree_node_allocator>::leaf_iterator::operator--()
2657 assert(this->node!=0);
2658 while (this->node->prev_sibling==0) {
2659 if (this->node->parent==0) return *this;
2660 this->node=this->node->parent;
2661 if (top_node !=0 && this->node==top_node) return *this;
2663 this->node=this->node->prev_sibling;
2664 while(this->node->last_child)
2665 this->node=this->node->last_child;
2669 template <class T, class tree_node_allocator>
2670 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::leaf_iterator::operator++(int)
2672 leaf_iterator copy = *this;
2677 template <class T, class tree_node_allocator>
2678 typename tree<T, tree_node_allocator>::leaf_iterator tree<T, tree_node_allocator>::leaf_iterator::operator--(int)
2680 leaf_iterator copy = *this;
2686 template <class T, class tree_node_allocator>
2687 typename tree<T, tree_node_allocator>::leaf_iterator& tree<T, tree_node_allocator>::leaf_iterator::operator+=(unsigned int num)
2696 template <class T, class tree_node_allocator>
2697 typename tree<T, tree_node_allocator>::leaf_iterator& tree<T, tree_node_allocator>::leaf_iterator::operator-=(unsigned int num)
2709 // default-tab-width: 3