3 /* ========================================================================== **
6 * Copyright (C) 1991-1998 by Christopher R. Hertel
8 * Email: crh@ubiqx.mn.org
9 * -------------------------------------------------------------------------- **
11 * This module implements a simple binary tree.
13 * -------------------------------------------------------------------------- **
15 * This library is free software; you can redistribute it and/or
16 * modify it under the terms of the GNU Library General Public
17 * License as published by the Free Software Foundation; either
18 * version 2 of the License, or (at your option) any later version.
20 * This library is distributed in the hope that it will be useful,
21 * but WITHOUT ANY WARRANTY; without even the implied warranty of
22 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
23 * Library General Public License for more details.
25 * You should have received a copy of the GNU Library General Public
26 * License along with this library; if not, write to the Free
27 * Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
29 * -------------------------------------------------------------------------- **
31 * Log: ubi_BinTree.h,v
32 * Revision 4.10 2000/06/06 20:38:40 crh
33 * In the ReplaceNode() function, the old node header was being copied
34 * to the new node header using a byte-by-byte copy. This was causing
35 * the 'insure' software testing program to report a memory leak. The
36 * fix was to do a simple assignement: *newnode = *oldnode;
37 * This quieted the (errant) memory leak reports and is probably a bit
38 * faster than the bytewise copy.
40 * Revision 4.9 2000/01/08 23:24:30 crh
41 * Clarified a variety of if( pointer ) lines, replacing them with
42 * if( NULL != pointer ). This is more correct, and I have heard
43 * of at least one (obscure?) system out there that uses a non-zero
45 * Also, speed improvement in Neighbor(). It was comparing pointers
46 * when it could have compared two gender values. The pointer
47 * comparison was somewhat indirect (does pointer equal the pointer
48 * of the parent of the node pointed to by pointer). Urq.
50 * Revision 4.8 1999/09/22 03:40:30 crh
51 * Modified ubi_btTraverse() and ubi_btKillTree(). They now return an
52 * unsigned long indicating the number of nodes processed. The change
53 * is subtle. An empty tree formerly returned False, and now returns
56 * Revision 4.7 1998/10/21 06:15:07 crh
57 * Fixed bugs in FirstOf() and LastOf() reported by Massimo Campostrini.
58 * See function comments.
60 * Revision 4.6 1998/07/25 17:02:10 crh
61 * Added the ubi_trNewTree() macro.
63 * Revision 4.5 1998/06/04 21:29:27 crh
64 * Upper-cased defined constants (eg UBI_BINTREE_H) in some header files.
65 * This is more "standard", and is what people expect. Weird, eh?
67 * Revision 4.4 1998/06/03 17:42:46 crh
68 * Further fiddling with sys_include.h. It's now in ubi_BinTree.h which is
69 * included by all of the binary tree files.
71 * Reminder: Some of the ubi_tr* macros in ubi_BinTree.h are redefined in
72 * ubi_AVLtree.h and ubi_SplayTree.h. This allows easy swapping
73 * of tree types by simply changing a header. Unfortunately, the
74 * macro redefinitions in ubi_AVLtree.h and ubi_SplayTree.h will
75 * conflict if used together. You must either choose a single tree
76 * type, or use the underlying function calls directly. Compare
77 * the two header files for more information.
79 * Revision 4.3 1998/06/02 01:28:43 crh
80 * Changed ubi_null.h to sys_include.h to make it more generic.
82 * Revision 4.2 1998/05/20 04:32:36 crh
83 * The C file now includes ubi_null.h. See ubi_null.h for more info.
84 * Also, the balance and gender fields of the node were declared as
85 * signed char. As I understand it, at least one SunOS or Solaris
86 * compiler doesn't like "signed char". The declarations were
87 * wrong anyway, so I changed them to simple "char".
89 * Revision 4.1 1998/03/31 06:13:47 crh
90 * Thomas Aglassinger sent E'mail pointing out errors in the
91 * dereferencing of function pointers, and a missing typecast.
94 * Revision 4.0 1998/03/10 03:16:04 crh
95 * Added the AVL field 'balance' to the ubi_btNode structure. This means
96 * that all BinTree modules now use the same basic node structure, which
97 * greatly simplifies the AVL module.
98 * Decided that this was a big enough change to justify a new major revision
99 * number. 3.0 was an error, so we're at 4.0.
101 * Revision 2.6 1998/01/24 06:27:30 crh
102 * Added ubi_trCount() macro.
104 * Revision 2.5 1997/12/23 03:59:21 crh
105 * In this version, all constants & macros defined in the header file have
106 * the ubi_tr prefix. Also cleaned up anything that gcc complained about
107 * when run with '-pedantic -fsyntax-only -Wall'.
109 * Revision 2.4 1997/07/26 04:11:14 crh
110 * + Just to be annoying I changed ubi_TRUE and ubi_FALSE to ubi_trTRUE
112 * + There is now a type ubi_trBool to go with ubi_trTRUE and ubi_trFALSE.
113 * + There used to be something called "ubi_TypeDefs.h". I got rid of it.
114 * + Added function ubi_btLeafNode().
116 * Revision 2.3 1997/06/03 05:15:27 crh
117 * Changed TRUE and FALSE to ubi_TRUE and ubi_FALSE to avoid conflicts.
118 * Also changed the interface to function InitTree(). See the comments
119 * for this function for more information.
121 * Revision 2.2 1995/10/03 22:00:40 CRH
124 * Revision 2.1 95/03/09 23:43:46 CRH
125 * Added the ModuleID static string and function. These modules are now
128 * Revision 2.0 95/02/27 22:00:33 CRH
129 * Revision 2.0 of this program includes the following changes:
131 * 1) A fix to a major typo in the RepaceNode() function.
132 * 2) The addition of the static function Border().
133 * 3) The addition of the public functions FirstOf() and LastOf(), which
134 * use Border(). These functions are used with trees that allow
136 * 4) A complete rewrite of the Locate() function. Locate() now accepts
137 * a "comparison" operator.
138 * 5) Overall enhancements to both code and comments.
140 * I decided to give this a new major rev number because the interface has
141 * changed. In particular, there are two new functions, and changes to the
144 * Revision 1.0 93/10/15 22:55:04 CRH
145 * With this revision, I have added a set of #define's that provide a single,
146 * standard API to all existing tree modules. Until now, each of the three
147 * existing modules had a different function and typedef prefix, as follows:
151 * ubi_AVLtree ubi_avl
152 * ubi_SplayTree ubi_spt
154 * To further complicate matters, only those portions of the base module
155 * (ubi_BinTree) that were superceeded in the new module had the new names.
156 * For example, if you were using ubi_SplayTree, the locate function was
157 * called "ubi_sptLocate", but the next and previous functions remained
158 * "ubi_btNext" and "ubi_btPrev".
160 * This was not too terrible if you were familiar with the modules and knew
161 * exactly which tree model you wanted to use. If you wanted to be able to
162 * change modules (for speed comparisons, etc), things could get messy very
165 * So, I have added a set of defined names that get redefined in any of the
166 * descendant modules. To use this standardized interface in your code,
167 * simply replace all occurances of "ubi_bt", "ubi_avl", and "ubi_spt" with
168 * "ubi_tr". The "ubi_tr" names will resolve to the correct function or
169 * datatype names for the module that you are using. Just remember to
170 * include the header for that module in your program file. Because these
171 * names are handled by the preprocessor, there is no added run-time
174 * Note that the original names do still exist, and can be used if you wish
175 * to write code directly to a specific module. This should probably only be
176 * done if you are planning to implement a new descendant type, such as
177 * red/black trees. CRH
179 * V0.0 - June, 1991 - Written by Christopher R. Hertel (CRH).
181 * ========================================================================== **
184 #include "sys_include.h" /* Global include file, used to adapt the ubiqx
185 * modules to the host environment and the project
186 * with which the modules will be used. See
187 * sys_include.h for more info.
190 /* -------------------------------------------------------------------------- **
191 * Macros and constants.
194 * ubi_trTRUE - Boolean TRUE.
195 * ubi_trFALSE - Boolean FALSE.
197 * Flags used in the tree header:
198 * ubi_trOVERWRITE - This flag indicates that an existing node may be
199 * overwritten by a new node with a matching key.
200 * ubi_trDUPKEY - This flag indicates that the tree allows duplicate
201 * keys. If the tree does allow duplicates, the
202 * overwrite flag is ignored.
204 * Node link array index constants: (Each node has an array of three
205 * pointers. One to the left, one to the right, and one back to the
207 * ubi_trLEFT - Left child pointer.
208 * ubi_trPARENT - Parent pointer.
209 * ubi_trRIGHT - Right child pointer.
210 * ubi_trEQUAL - Synonym for PARENT.
212 * ubi_trCompOps: These values are used in the ubi_trLocate() function.
213 * ubi_trLT - request the first instance of the greatest key less than
215 * ubi_trLE - request the first instance of the greatest key that is less
216 * than or equal to the search key.
217 * ubi_trEQ - request the first instance of key that is equal to the
219 * ubi_trGE - request the first instance of a key that is greater than
220 * or equal to the search key.
221 * ubi_trGT - request the first instance of the first key that is greater
222 * than the search key.
223 * -------------------------------------------------------------------------- **
226 #define ubi_trTRUE 0xFF
227 #define ubi_trFALSE 0x00
229 #define ubi_trOVERWRITE 0x01 /* Turn on allow overwrite */
230 #define ubi_trDUPKEY 0x02 /* Turn on allow duplicate keys */
232 /* Pointer array index constants... */
233 #define ubi_trLEFT 0x00
234 #define ubi_trPARENT 0x01
235 #define ubi_trRIGHT 0x02
236 #define ubi_trEQUAL ubi_trPARENT
246 /* -------------------------------------------------------------------------- **
247 * These three macros allow simple manipulation of pointer index values (LEFT,
248 * RIGHT, and PARENT).
250 * Normalize() - converts {LEFT, PARENT, RIGHT} into {-1, 0 ,1}. C
251 * uses {negative, zero, positive} values to indicate
252 * {less than, equal to, greater than}.
253 * AbNormal() - converts {negative, zero, positive} to {LEFT, PARENT,
254 * RIGHT} (opposite of Normalize()). Note: C comparison
255 * functions, such as strcmp(), return {negative, zero,
256 * positive} values, which are not necessarily {-1, 0,
257 * 1}. This macro uses the the ubi_btSgn() function to
259 * RevWay() - converts LEFT to RIGHT and RIGHT to LEFT. PARENT (EQUAL)
261 * -------------------------------------------------------------------------- **
263 #define ubi_trNormalize(W) ((char)( (W) - ubi_trEQUAL ))
264 #define ubi_trAbNormal(W) ((char)( ((char)ubi_btSgn( (long)(W) )) \
266 #define ubi_trRevWay(W) ((char)( ubi_trEQUAL - ((W) - ubi_trEQUAL) ))
268 /* -------------------------------------------------------------------------- **
269 * These macros allow us to quickly read the values of the OVERWRITE and
270 * DUPlicate KEY bits of the tree root flags field.
271 * -------------------------------------------------------------------------- **
273 #define ubi_trDups_OK(A) \
274 ((ubi_trDUPKEY & ((A)->flags))?(ubi_trTRUE):(ubi_trFALSE))
275 #define ubi_trOvwt_OK(A) \
276 ((ubi_trOVERWRITE & ((A)->flags))?(ubi_trTRUE):(ubi_trFALSE))
278 /* -------------------------------------------------------------------------- **
279 * Additional Macros...
281 * ubi_trCount() - Given a pointer to a tree root, this macro returns the
282 * number of nodes currently in the tree.
284 * ubi_trNewTree() - This macro makes it easy to declare and initialize a
285 * tree header in one step. The line
287 * static ubi_trNewTree( MyTree, cmpfn, ubi_trDUPKEY );
291 * static ubi_trRoot MyTree[1]
292 * = {{ NULL, cmpfn, 0, ubi_trDUPKEY }};
294 * -------------------------------------------------------------------------- **
297 #define ubi_trCount( R ) (((ubi_trRootPtr)(R))->count)
299 #define ubi_trNewTree( N, C, F ) ubi_trRoot (N)[1] = {{ NULL, (C), 0, (F) }}
301 /* -------------------------------------------------------------------------- **
304 * ubi_trBool - Your typcial true or false...
306 * Item Pointer: The ubi_btItemPtr is a generic pointer. It is used to
307 * indicate a key that is being searched for within the tree.
308 * Searching occurs whenever the ubi_trFind(), ubi_trLocate(),
309 * or ubi_trInsert() functions are called.
310 * -------------------------------------------------------------------------- **
313 typedef unsigned char ubi_trBool
;
315 typedef void *ubi_btItemPtr
; /* A pointer to key data within a node. */
317 /* ------------------------------------------------------------------------- **
318 * Binary Tree Node Structure: This structure defines the basic elements of
319 * the tree nodes. In general you *SHOULD NOT PLAY WITH THESE FIELDS*!
320 * But, of course, I have to put the structure into this header so that
321 * you can use it as a building block.
323 * The fields are as follows:
324 * Link - an array of pointers. These pointers are manipulated by
325 * the BT routines. The pointers indicate the left and right
326 * child nodes and the parent node. By keeping track of the
327 * parent pointer, we avoid the need for recursive routines or
328 * hand-tooled stacks to keep track of our path back to the
329 * root. The use of these pointers is subject to change without
331 * gender - a one-byte field indicating whether the node is the RIGHT or
332 * LEFT child of its parent. If the node is the root of the
333 * tree, gender will be PARENT.
334 * balance - only used by the AVL tree module. This field indicates
335 * the height balance at a given node. See ubi_AVLtree for
338 * ------------------------------------------------------------------------- **
340 typedef struct ubi_btNodeStruct
{
341 struct ubi_btNodeStruct
*Link
[ 3 ];
346 typedef ubi_btNode
*ubi_btNodePtr
; /* Pointer to an ubi_btNode structure. */
348 /* ------------------------------------------------------------------------- **
349 * The next three typedefs define standard function types used by the binary
350 * tree management routines. In particular:
352 * ubi_btCompFunc is a pointer to a comparison function. Comparison
353 * functions are passed an ubi_btItemPtr and an
354 * ubi_btNodePtr. They return a value that is (<0), 0,
355 * or (>0) to indicate that the Item is (respectively)
356 * "less than", "equal to", or "greater than" the Item
357 * contained within the node. (See ubi_btInitTree()).
358 * ubi_btActionRtn is a pointer to a function that may be called for each
359 * node visited when performing a tree traversal (see
360 * ubi_btTraverse()). The function will be passed two
361 * parameters: the first is a pointer to a node in the
362 * tree, the second is a generic pointer that may point to
363 * anything that you like.
364 * ubi_btKillNodeRtn is a pointer to a function that will deallocate the
365 * memory used by a node (see ubi_btKillTree()). Since
366 * memory management is left up to you, deallocation may
367 * mean anything that you want it to mean. Just remember
368 * that the tree *will* be destroyed and that none of the
369 * node pointers will be valid any more.
370 * ------------------------------------------------------------------------- **
373 typedef int (*ubi_btCompFunc
)( ubi_btItemPtr
, ubi_btNodePtr
);
375 typedef void (*ubi_btActionRtn
)( ubi_btNodePtr
, void * );
377 typedef void (*ubi_btKillNodeRtn
)( ubi_btNodePtr
);
379 /* -------------------------------------------------------------------------- **
380 * Tree Root Structure: This structure gives us a convenient handle for
381 * accessing whole binary trees. The fields are:
382 * root - A pointer to the root node of the tree.
383 * count - A count of the number of nodes stored in the tree.
384 * cmp - A pointer to the comparison routine to be used when building or
385 * searching the tree.
386 * flags - A set of bit flags. Two flags are currently defined:
388 * ubi_trOVERWRITE - If set, this flag indicates that a new node should
389 * (bit 0x01) overwrite an old node if the two have identical
390 * keys (ie., the keys are equal).
391 * ubi_trDUPKEY - If set, this flag indicates that the tree is
392 * (bit 0x02) allowed to contain nodes with duplicate keys.
394 * NOTE: ubi_trInsert() tests ubi_trDUPKEY before ubi_trOVERWRITE.
396 * All of these values are set when you initialize the root structure by
397 * calling ubi_trInitTree().
398 * -------------------------------------------------------------------------- **
402 ubi_btNodePtr root
; /* A pointer to the root node of the tree */
403 ubi_btCompFunc cmp
; /* A pointer to the tree's comparison function */
404 unsigned long count
; /* A count of the number of nodes in the tree */
405 char flags
; /* Overwrite Y|N, Duplicate keys Y|N... */
408 typedef ubi_btRoot
*ubi_btRootPtr
; /* Pointer to an ubi_btRoot structure. */
411 /* -------------------------------------------------------------------------- **
412 * Function Prototypes.
415 long ubi_btSgn( long x
);
416 /* ------------------------------------------------------------------------ **
417 * Return the sign of x; {negative,zero,positive} ==> {-1, 0, 1}.
419 * Input: x - a signed long integer value.
421 * Output: the "sign" of x, represented as follows:
423 * 0 == zero (no sign)
426 * Note: This utility is provided in order to facilitate the conversion
427 * of C comparison function return values into BinTree direction
428 * values: {LEFT, PARENT, EQUAL}. It is INCORPORATED into the
429 * AbNormal() conversion macro!
431 * ------------------------------------------------------------------------ **
434 ubi_btNodePtr
ubi_btInitNode( ubi_btNodePtr NodePtr
);
435 /* ------------------------------------------------------------------------ **
436 * Initialize a tree node.
438 * Input: a pointer to a ubi_btNode structure to be initialized.
439 * Output: a pointer to the initialized ubi_btNode structure (ie. the
440 * same as the input pointer).
441 * ------------------------------------------------------------------------ **
444 ubi_btRootPtr
ubi_btInitTree( ubi_btRootPtr RootPtr
,
445 ubi_btCompFunc CompFunc
,
447 /* ------------------------------------------------------------------------ **
448 * Initialize the fields of a Tree Root header structure.
450 * Input: RootPtr - a pointer to an ubi_btRoot structure to be
452 * CompFunc - a pointer to a comparison function that will be used
453 * whenever nodes in the tree must be compared against
455 * Flags - One bytes worth of flags. Flags include
456 * ubi_trOVERWRITE and ubi_trDUPKEY. See the header
457 * file for more info.
459 * Output: a pointer to the initialized ubi_btRoot structure (ie. the
460 * same value as RootPtr).
462 * Note: The interface to this function has changed from that of
463 * previous versions. The <Flags> parameter replaces two
464 * boolean parameters that had the same basic effect.
465 * ------------------------------------------------------------------------ **
468 ubi_trBool
ubi_btInsert( ubi_btRootPtr RootPtr
,
469 ubi_btNodePtr NewNode
,
470 ubi_btItemPtr ItemPtr
,
471 ubi_btNodePtr
*OldNode
);
472 /* ------------------------------------------------------------------------ **
473 * This function uses a non-recursive algorithm to add a new element to the
476 * Input: RootPtr - a pointer to the ubi_btRoot structure that indicates
477 * the root of the tree to which NewNode is to be added.
478 * NewNode - a pointer to an ubi_btNode structure that is NOT
480 * ItemPtr - A pointer to the sort key that is stored within
481 * *NewNode. ItemPtr MUST point to information stored
482 * in *NewNode or an EXACT DUPLICATE. The key data
483 * indicated by ItemPtr is used to place the new node
485 * OldNode - a pointer to an ubi_btNodePtr. When searching
486 * the tree, a duplicate node may be found. If
487 * duplicates are allowed, then the new node will
488 * be simply placed into the tree. If duplicates
489 * are not allowed, however, then one of two things
491 * 1) if overwritting *is not* allowed, this
492 * function will return FALSE (indicating that
493 * the new node could not be inserted), and
494 * *OldNode will point to the duplicate that is
496 * 2) if overwritting *is* allowed, then this
497 * function will swap **OldNode for *NewNode.
498 * In this case, *OldNode will point to the node
499 * that was removed (thus allowing you to free
501 * ** If you are using overwrite mode, ALWAYS **
502 * ** check the return value of this parameter! **
503 * Note: You may pass NULL in this parameter, the
504 * function knows how to cope. If you do this,
505 * however, there will be no way to return a
506 * pointer to an old (ie. replaced) node (which is
507 * a problem if you are using overwrite mode).
509 * Output: a boolean value indicating success or failure. The function
510 * will return FALSE if the node could not be added to the tree.
511 * Such failure will only occur if duplicates are not allowed,
512 * nodes cannot be overwritten, AND a duplicate key was found
514 * ------------------------------------------------------------------------ **
517 ubi_btNodePtr
ubi_btRemove( ubi_btRootPtr RootPtr
,
518 ubi_btNodePtr DeadNode
);
519 /* ------------------------------------------------------------------------ **
520 * This function removes the indicated node from the tree.
522 * Input: RootPtr - A pointer to the header of the tree that contains
523 * the node to be removed.
524 * DeadNode - A pointer to the node that will be removed.
526 * Output: This function returns a pointer to the node that was removed
527 * from the tree (ie. the same as DeadNode).
529 * Note: The node MUST be in the tree indicated by RootPtr. If not,
530 * strange and evil things will happen to your trees.
531 * ------------------------------------------------------------------------ **
534 ubi_btNodePtr
ubi_btLocate( ubi_btRootPtr RootPtr
,
535 ubi_btItemPtr FindMe
,
536 ubi_trCompOps CompOp
);
537 /* ------------------------------------------------------------------------ **
538 * The purpose of ubi_btLocate() is to find a node or set of nodes given
539 * a target value and a "comparison operator". The Locate() function is
540 * more flexible and (in the case of trees that may contain dupicate keys)
541 * more precise than the ubi_btFind() function. The latter is faster,
542 * but it only searches for exact matches and, if the tree contains
543 * duplicates, Find() may return a pointer to any one of the duplicate-
547 * RootPtr - A pointer to the header of the tree to be searched.
548 * FindMe - An ubi_btItemPtr that indicates the key for which to
550 * CompOp - One of the following:
551 * CompOp Return a pointer to the node with
552 * ------ ---------------------------------
553 * ubi_trLT - the last key value that is less
555 * ubi_trLE - the first key matching FindMe, or
556 * the last key that is less than
558 * ubi_trEQ - the first key matching FindMe.
559 * ubi_trGE - the first key matching FindMe, or the
560 * first key greater than FindMe.
561 * ubi_trGT - the first key greater than FindMe.
563 * A pointer to the node matching the criteria listed above under
564 * CompOp, or NULL if no node matched the criteria.
567 * In the case of trees with duplicate keys, Locate() will behave as
571 * Keys: 1 2 2 2 3 3 3 3 3 4 4 Keys: 1 1 2 2 2 4 4 5 5 5 6
575 * That is, when returning a pointer to a node with a key that is LESS
576 * THAN the target key (FindMe), Locate() will return a pointer to the
577 * LAST matching node.
578 * When returning a pointer to a node with a key that is GREATER
579 * THAN the target key (FindMe), Locate() will return a pointer to the
580 * FIRST matching node.
582 * See Also: ubi_btFind(), ubi_btFirstOf(), ubi_btLastOf().
583 * ------------------------------------------------------------------------ **
586 ubi_btNodePtr
ubi_btFind( ubi_btRootPtr RootPtr
,
587 ubi_btItemPtr FindMe
);
588 /* ------------------------------------------------------------------------ **
589 * This function performs a non-recursive search of a tree for any node
590 * matching a specific key.
593 * RootPtr - a pointer to the header of the tree to be searched.
594 * FindMe - a pointer to the key value for which to search.
597 * A pointer to a node with a key that matches the key indicated by
598 * FindMe, or NULL if no such node was found.
600 * Note: In a tree that allows duplicates, the pointer returned *might
601 * not* point to the (sequentially) first occurance of the
602 * desired key. In such a tree, it may be more useful to use
604 * ------------------------------------------------------------------------ **
607 ubi_btNodePtr
ubi_btNext( ubi_btNodePtr P
);
608 /* ------------------------------------------------------------------------ **
609 * Given the node indicated by P, find the (sorted order) Next node in the
611 * Input: P - a pointer to a node that exists in a binary tree.
612 * Output: A pointer to the "next" node in the tree, or NULL if P pointed
613 * to the "last" node in the tree or was NULL.
614 * ------------------------------------------------------------------------ **
617 ubi_btNodePtr
ubi_btPrev( ubi_btNodePtr P
);
618 /* ------------------------------------------------------------------------ **
619 * Given the node indicated by P, find the (sorted order) Previous node in
621 * Input: P - a pointer to a node that exists in a binary tree.
622 * Output: A pointer to the "previous" node in the tree, or NULL if P
623 * pointed to the "first" node in the tree or was NULL.
624 * ------------------------------------------------------------------------ **
627 ubi_btNodePtr
ubi_btFirst( ubi_btNodePtr P
);
628 /* ------------------------------------------------------------------------ **
629 * Given the node indicated by P, find the (sorted order) First node in the
630 * subtree of which *P is the root.
631 * Input: P - a pointer to a node that exists in a binary tree.
632 * Output: A pointer to the "first" node in a subtree that has *P as its
633 * root. This function will return NULL only if P is NULL.
634 * Note: In general, you will be passing in the value of the root field
635 * of an ubi_btRoot structure.
636 * ------------------------------------------------------------------------ **
639 ubi_btNodePtr
ubi_btLast( ubi_btNodePtr P
);
640 /* ------------------------------------------------------------------------ **
641 * Given the node indicated by P, find the (sorted order) Last node in the
642 * subtree of which *P is the root.
643 * Input: P - a pointer to a node that exists in a binary tree.
644 * Output: A pointer to the "last" node in a subtree that has *P as its
645 * root. This function will return NULL only if P is NULL.
646 * Note: In general, you will be passing in the value of the root field
647 * of an ubi_btRoot structure.
648 * ------------------------------------------------------------------------ **
651 ubi_btNodePtr
ubi_btFirstOf( ubi_btRootPtr RootPtr
,
652 ubi_btItemPtr MatchMe
,
654 /* ------------------------------------------------------------------------ **
655 * Given a tree that a allows duplicate keys, and a pointer to a node in
656 * the tree, this function will return a pointer to the first (traversal
657 * order) node with the same key value.
659 * Input: RootPtr - A pointer to the root of the tree.
660 * MatchMe - A pointer to the key value. This should probably
661 * point to the key within node *p.
662 * p - A pointer to a node in the tree.
663 * Output: A pointer to the first node in the set of nodes with keys
665 * Notes: Node *p MUST be in the set of nodes with keys matching
666 * <FindMe>. If not, this function will return NULL.
668 * 4.7: Bug found & fixed by Massimo Campostrini,
669 * Istituto Nazionale di Fisica Nucleare, Sezione di Pisa.
671 * ------------------------------------------------------------------------ **
674 ubi_btNodePtr
ubi_btLastOf( ubi_btRootPtr RootPtr
,
675 ubi_btItemPtr MatchMe
,
677 /* ------------------------------------------------------------------------ **
678 * Given a tree that a allows duplicate keys, and a pointer to a node in
679 * the tree, this function will return a pointer to the last (traversal
680 * order) node with the same key value.
682 * Input: RootPtr - A pointer to the root of the tree.
683 * MatchMe - A pointer to the key value. This should probably
684 * point to the key within node *p.
685 * p - A pointer to a node in the tree.
686 * Output: A pointer to the last node in the set of nodes with keys
688 * Notes: Node *p MUST be in the set of nodes with keys matching
689 * <FindMe>. If not, this function will return NULL.
691 * 4.7: Bug found & fixed by Massimo Campostrini,
692 * Istituto Nazionale di Fisica Nucleare, Sezione di Pisa.
694 * ------------------------------------------------------------------------ **
697 unsigned long ubi_btTraverse( ubi_btRootPtr RootPtr
,
698 ubi_btActionRtn EachNode
,
700 /* ------------------------------------------------------------------------ **
701 * Traverse a tree in sorted order (non-recursively). At each node, call
702 * (*EachNode)(), passing a pointer to the current node, and UserData as the
705 * Input: RootPtr - a pointer to an ubi_btRoot structure that indicates
706 * the tree to be traversed.
707 * EachNode - a pointer to a function to be called at each node
708 * as the node is visited.
709 * UserData - a generic pointer that may point to anything that
712 * Output: A count of the number of nodes visited. This will be zero
713 * if the tree is empty.
715 * ------------------------------------------------------------------------ **
719 unsigned long ubi_btKillTree( ubi_btRootPtr RootPtr
,
720 ubi_btKillNodeRtn FreeNode
);
721 /* ------------------------------------------------------------------------ **
722 * Delete an entire tree (non-recursively) and reinitialize the ubi_btRoot
723 * structure. Return a count of the number of nodes deleted.
725 * Input: RootPtr - a pointer to an ubi_btRoot structure that indicates
726 * the root of the tree to delete.
727 * FreeNode - a function that will be called for each node in the
728 * tree to deallocate the memory used by the node.
730 * Output: The number of nodes removed from the tree.
731 * A value of 0 will be returned if:
732 * - The tree actually contains 0 entries.
733 * - the value of <RootPtr> is NULL, in which case the tree is
734 * assumed to be empty
735 * - the value of <FreeNode> is NULL, in which case entries
736 * cannot be removed, so 0 is returned. *Make sure that you
737 * provide a valid value for <FreeNode>*.
738 * In all other cases, you should get a positive value equal to
739 * the value of RootPtr->count upon entry.
741 * ------------------------------------------------------------------------ **
744 ubi_btNodePtr
ubi_btLeafNode( ubi_btNodePtr leader
);
745 /* ------------------------------------------------------------------------ **
746 * Returns a pointer to a leaf node.
748 * Input: leader - Pointer to a node at which to start the descent.
750 * Output: A pointer to a leaf node selected in a somewhat arbitrary
753 * Notes: I wrote this function because I was using splay trees as a
754 * database cache. The cache had a maximum size on it, and I
755 * needed a way of choosing a node to sacrifice if the cache
756 * became full. In a splay tree, less recently accessed nodes
757 * tend toward the bottom of the tree, meaning that leaf nodes
758 * are good candidates for removal. (I really can't think of
759 * any other reason to use this function.)
760 * + In a simple binary tree or an AVL tree, the most recently
761 * added nodes tend to be nearer the bottom, making this a *bad*
762 * way to choose which node to remove from the cache.
763 * + Randomizing the traversal order is probably a good idea. You
764 * can improve the randomization of leaf node selection by passing
765 * in pointers to nodes other than the root node each time. A
766 * pointer to any node in the tree will do. Of course, if you
767 * pass a pointer to a leaf node you'll get the same thing back.
769 * ------------------------------------------------------------------------ **
773 int ubi_btModuleID( int size
, char *list
[] );
774 /* ------------------------------------------------------------------------ **
775 * Returns a set of strings that identify the module.
777 * Input: size - The number of elements in the array <list>.
778 * list - An array of pointers of type (char *). This array
779 * should, initially, be empty. This function will fill
780 * in the array with pointers to strings.
781 * Output: The number of elements of <list> that were used. If this value
782 * is less than <size>, the values of the remaining elements are
785 * Notes: Please keep in mind that the pointers returned indicate strings
786 * stored in static memory. Don't free() them, don't write over
787 * them, etc. Just read them.
788 * ------------------------------------------------------------------------ **
791 /* -------------------------------------------------------------------------- **
794 * This set of defines allows you to write programs that will use any of the
795 * implemented binary tree modules (currently BinTree, AVLtree, and SplayTree).
796 * Instead of using ubi_bt..., use ubi_tr..., and select the tree type by
797 * including the appropriate module header.
800 #define ubi_trItemPtr ubi_btItemPtr
802 #define ubi_trNode ubi_btNode
803 #define ubi_trNodePtr ubi_btNodePtr
805 #define ubi_trRoot ubi_btRoot
806 #define ubi_trRootPtr ubi_btRootPtr
808 #define ubi_trCompFunc ubi_btCompFunc
809 #define ubi_trActionRtn ubi_btActionRtn
810 #define ubi_trKillNodeRtn ubi_btKillNodeRtn
812 #define ubi_trSgn( x ) ubi_btSgn( x )
814 #define ubi_trInitNode( Np ) ubi_btInitNode( (ubi_btNodePtr)(Np) )
816 #define ubi_trInitTree( Rp, Cf, Fl ) \
817 ubi_btInitTree( (ubi_btRootPtr)(Rp), (ubi_btCompFunc)(Cf), (Fl) )
819 #define ubi_trInsert( Rp, Nn, Ip, On ) \
820 ubi_btInsert( (ubi_btRootPtr)(Rp), (ubi_btNodePtr)(Nn), \
821 (ubi_btItemPtr)(Ip), (ubi_btNodePtr *)(On) )
823 #define ubi_trRemove( Rp, Dn ) \
824 ubi_btRemove( (ubi_btRootPtr)(Rp), (ubi_btNodePtr)(Dn) )
826 #define ubi_trLocate( Rp, Ip, Op ) \
827 ubi_btLocate( (ubi_btRootPtr)(Rp), \
828 (ubi_btItemPtr)(Ip), \
829 (ubi_trCompOps)(Op) )
831 #define ubi_trFind( Rp, Ip ) \
832 ubi_btFind( (ubi_btRootPtr)(Rp), (ubi_btItemPtr)(Ip) )
834 #define ubi_trNext( P ) ubi_btNext( (ubi_btNodePtr)(P) )
836 #define ubi_trPrev( P ) ubi_btPrev( (ubi_btNodePtr)(P) )
838 #define ubi_trFirst( P ) ubi_btFirst( (ubi_btNodePtr)(P) )
840 #define ubi_trLast( P ) ubi_btLast( (ubi_btNodePtr)(P) )
842 #define ubi_trFirstOf( Rp, Ip, P ) \
843 ubi_btFirstOf( (ubi_btRootPtr)(Rp), \
844 (ubi_btItemPtr)(Ip), \
847 #define ubi_trLastOf( Rp, Ip, P ) \
848 ubi_btLastOf( (ubi_btRootPtr)(Rp), \
849 (ubi_btItemPtr)(Ip), \
852 #define ubi_trTraverse( Rp, En, Ud ) \
853 ubi_btTraverse((ubi_btRootPtr)(Rp), (ubi_btActionRtn)(En), (void *)(Ud))
855 #define ubi_trKillTree( Rp, Fn ) \
856 ubi_btKillTree( (ubi_btRootPtr)(Rp), (ubi_btKillNodeRtn)(Fn) )
858 #define ubi_trLeafNode( Nd ) \
859 ubi_btLeafNode( (ubi_btNodePtr)(Nd) )
861 #define ubi_trModuleID( s, l ) ubi_btModuleID( s, l )
863 /* ========================================================================== */
864 #endif /* UBI_BINTREE_H */