1 | /*
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2 | * zAVLTree.c: Source code for zAVLTrees.
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3 | * Copyright (C) 1998,2001 Michael H. Buselli
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4 | * This is version 0.1.3 (alpha).
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5 | * Generated from $Id: xAVLTree.c.sh,v 1.5 2001/06/07 06:58:28 cosine Exp $
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6 | *
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7 | * This library is free software; you can redistribute it and/or
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8 | * modify it under the terms of the GNU Library General Public
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9 | * License as published by the Free Software Foundation; either
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10 | * version 2 of the License, or (at your option) any later version.
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11 | *
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12 | * This library is distributed in the hope that it will be useful,
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13 | * but WITHOUT ANY WARRANTY; without even the implied warranty of
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14 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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15 | * Library General Public License for more details.
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16 | *
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17 | * You should have received a copy of the GNU Library General Public
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18 | * License along with this library; if not, write to the Free
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19 | * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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20 | *
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21 | * The author of this library can be reached at the following address:
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22 | * Michael H. Buselli
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23 | * 30051 N. Waukegan Rd. Apt. 103
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24 | * Lake Bluff, IL 60044-5412
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25 | *
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26 | * Or you can send email to <cosine@cosine.org>.
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27 | * The official web page for this product is:
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28 | * http://www.cosine.org/project/AVLTree/
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29 | */
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30 |
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31 | #include <stdlib.h>
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32 | #include <string.h>
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33 | #include "zAVLTree.h"
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34 |
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35 | /* Interface for handling "string only" items rw 2014-06-26
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36 | */
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37 | static zAVLKey zstring_key (void const * arg)
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38 | {
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39 | return (zAVLKey) arg;
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40 | }
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41 |
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42 | char * dummy_zfree_string;
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43 | #ifdef __clang__
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44 | char * dummy_zfree_str;
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45 | #endif
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46 |
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47 | static void zfree_string (void * inptr)
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48 | {
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49 | #ifdef __clang__
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50 | dummy_zfree_str = (char *) inptr;
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51 | #else
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52 | char * str = (char *) inptr;
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53 | #endif
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54 |
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55 | /* Take the address to circumvent gcc 4.9 optimizer bug */
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56 | dummy_zfree_string = (char *) &inptr;
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57 |
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58 | #ifdef __clang__
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59 | dummy_zfree_str[0] = '\0';
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60 | free (dummy_zfree_str);
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61 | #else
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62 | str[0] = '\0';
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63 | free (inptr);
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64 | #endif
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65 | return;
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66 | }
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67 | void zAVL_string_reset (zAVLTree * tree)
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68 | {
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69 | if (tree)
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70 | zAVLFreeTree (tree, zfree_string);
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71 | return;
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72 | }
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73 | int zAVL_string_set (zAVLTree ** tree, const char * key)
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74 | {
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75 | if (tree && key)
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76 | {
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77 | zAVLTree * itree = (*tree);
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78 | if (!itree)
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79 | {
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80 | itree = zAVLAllocTree (zstring_key, zAVL_KEY_STRING);
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81 | if (!itree)
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82 | {
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83 | return -1;
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84 | }
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85 | }
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86 | *tree = itree;
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87 | return zAVLInsert (itree, strdup(key));
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88 | }
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89 | return -1;
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90 | }
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91 | char * zAVL_string_get (zAVLTree * tree, const char * key)
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92 | {
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93 | /* zAVLSearch() checks for NULL tree
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94 | */
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95 | if (key)
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96 | {
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97 | return ((char *) zAVLSearch (tree, key));
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98 | }
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99 | return NULL;
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100 | }
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101 | void zAVL_string_del (zAVLTree * tree, const char * key)
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102 | {
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103 | /* zAVLSearch() checks for NULL tree
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104 | */
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105 | if (key)
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106 | {
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107 | char * item = ((char *) zAVLSearch (tree, key));
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108 | if (item)
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109 | {
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110 | zAVLDelete(tree, key);
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111 | zfree_string(item);
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112 | }
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113 | }
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114 | return;
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115 | }
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116 |
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117 |
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118 |
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119 | /* Wed Nov 23 17:57:42 CET 2005 rw: introduce third argument in
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120 | * zAVLCloseSearchNode() to avoid redundant strcmp
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121 | */
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122 | static zAVLNode *zAVLCloseSearchNode (zAVLTree const *avltree, zAVLKey key,
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123 | int * ok);
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124 | static void zAVLRebalanceNode (zAVLTree *avltree, zAVLNode *avlnode);
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125 | static void zAVLFreeBranch (zAVLNode *avlnode, void (freeitem)(void *item));
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126 | static void zAVLFillVacancy (zAVLTree *avltree,
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127 | zAVLNode *origparent, zAVLNode **superparent,
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128 | zAVLNode *left, zAVLNode *right);
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129 |
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130 | #define MAX(x, y) ((x) > (y) ? (x) : (y))
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131 | #define MIN(x, y) ((x) < (y) ? (x) : (y))
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132 | #define L_DEPTH(n) ((n)->left ? (n)->left->depth : 0)
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133 | #define R_DEPTH(n) ((n)->right ? (n)->right->depth : 0)
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134 | #define CALC_DEPTH(n) (MAX(L_DEPTH(n), R_DEPTH(n)) + 1)
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135 |
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136 | #define ZAVL_OK 1
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137 | #define ZAVL_NO 0
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138 |
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139 | /* The comparison function. Was a macro, but this allows for more
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140 | * flexibility (non-string keys). The key is a (void *) now, and
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141 | * the type is stored in the zAVLTree struct. Oct 21, 2011, rw
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142 | */
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143 | static int zAVLKey_cmp(const zAVLTree * tree, zAVLKey a, zAVLKey b)
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144 | {
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145 | if (tree->keytype == zAVL_KEY_STRING)
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146 | {
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147 | return (strcmp((const char*)a, (const char *)b));
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148 | }
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149 | else /* zAVL_KEY_INT */
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150 | {
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151 | const int x = *((const int *)a);
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152 | const int y = *((const int *)b);
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153 |
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154 | if (x > y) return 1;
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155 | else if (x < y) return -1;
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156 | else return 0;
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157 | }
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158 | }
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159 |
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160 | /*
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161 | * AVLAllocTree:
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162 | * Allocate memory for a new AVL tree and set the getkey function for
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163 | * that tree. The getkey function should take an item and return an
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164 | * AVLKey that is to be used for indexing this object in the AVL tree.
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165 | * On success, a pointer to the malloced AVLTree is returned. If there
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166 | * was a malloc failure, then NULL is returned.
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167 | */
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168 | zAVLTree *zAVLAllocTree (zAVLKey (*getkey)(void const *item), int keytype)
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169 | {
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170 | zAVLTree *rc;
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171 |
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172 | rc = calloc(1, sizeof(zAVLTree));
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173 | if (rc == NULL)
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174 | return NULL;
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175 |
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176 | rc->top = NULL;
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177 | rc->count = 0;
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178 | rc->getkey = getkey;
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179 | rc->keytype = keytype;
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180 | return rc;
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181 | }
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182 |
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183 |
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184 | /*
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185 | * AVLFreeTree:
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186 | * Free all memory used by this AVL tree. If freeitem is not NULL, then
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187 | * it is assumed to be a destructor for the items reference in the AVL
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188 | * tree, and they are deleted as well.
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189 | */
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190 | void zAVLFreeTree (zAVLTree *avltree, void (freeitem)(void *item))
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191 | {
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192 | if (NULL == avltree) /* R.W. Mon Nov 19 21:15:44 CET 2001 */
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193 | return;
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194 | if (avltree->top)
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195 | zAVLFreeBranch(avltree->top, freeitem);
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196 | free(avltree);
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197 | }
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198 |
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199 |
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200 | /*
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201 | * AVLInsert:
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202 | * Create a new node and insert an item there.
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203 | *
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204 | * Returns 0 on success,
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205 | * -1 on malloc failure,
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206 | * 3 if duplicate key.
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207 | */
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208 | int zAVLInsert (zAVLTree *avltree, void *item)
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209 | {
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210 | zAVLNode *newnode;
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211 | zAVLNode *node;
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212 | zAVLNode *balnode;
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213 | zAVLNode *nextbalnode;
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214 | int ok;
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215 |
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216 | newnode = calloc(1, sizeof(zAVLNode));
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217 | if (newnode == NULL)
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218 | return -1;
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219 |
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220 | newnode->key = avltree->getkey(item);
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221 | newnode->item = item;
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222 | newnode->depth = 1;
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223 | newnode->left = NULL;
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224 | newnode->right = NULL;
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225 | newnode->parent = NULL;
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226 |
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227 | if (avltree->top != NULL) {
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228 | node = zAVLCloseSearchNode(avltree, newnode->key, &ok);
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229 |
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230 | if (ok == ZAVL_OK) { /* exists already */
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231 | free(newnode);
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232 | return 3;
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233 | }
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234 |
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235 | newnode->parent = node;
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236 |
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237 | if (zAVLKey_cmp(avltree, newnode->key, node->key) < 0) {
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238 | node->left = newnode;
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239 | node->depth = CALC_DEPTH(node);
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240 | }
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241 |
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242 | else {
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243 | node->right = newnode;
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244 | node->depth = CALC_DEPTH(node);
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245 | }
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246 |
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247 | for (balnode = node->parent; balnode; balnode = nextbalnode) {
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248 | nextbalnode = balnode->parent;
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249 | zAVLRebalanceNode(avltree, balnode);
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250 | }
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251 | }
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252 |
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253 | else {
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254 | avltree->top = newnode;
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255 | }
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256 |
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257 | avltree->count++;
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258 | return 0;
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259 | }
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260 |
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261 |
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262 | /*
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263 | * zAVLSearch:
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264 | * Return a pointer to the item with the given key in the AVL tree. If
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265 | * no such item is in the tree, then NULL is returned.
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266 | */
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267 | void *zAVLSearch (zAVLTree const *avltree, zAVLKey key)
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268 | {
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269 | zAVLNode *node;
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270 | int ok;
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271 |
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272 | if (NULL == avltree) /* R.W. Mon Nov 19 21:15:44 CET 2001 */
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273 | return NULL;
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274 |
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275 | node = zAVLCloseSearchNode(avltree, key, &ok);
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276 |
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277 | if (node && ok == ZAVL_OK)
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278 | return node->item;
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279 |
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280 | return NULL;
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281 | }
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282 |
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283 |
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284 | /*
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285 | * zAVLDelete:
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286 | * Deletes the node with the given key. Does not delete the item at
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287 | * that key. Returns 0 on success and -1 if a node with the given key
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288 | * does not exist.
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289 | */
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290 | int zAVLDelete (zAVLTree *avltree, zAVLKey key)
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291 | {
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292 | zAVLNode *avlnode;
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293 | zAVLNode *origparent;
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294 | zAVLNode **superparent;
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295 | int ok;
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296 |
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297 | avlnode = zAVLCloseSearchNode(avltree, key, &ok);
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298 | if (avlnode == NULL || ok == ZAVL_NO) /* does not exist */
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299 | return -1;
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300 |
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301 | origparent = avlnode->parent;
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302 |
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303 | if (origparent) {
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304 | if (zAVLKey_cmp(avltree, avlnode->key, avlnode->parent->key) < 0)
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305 | superparent = &(avlnode->parent->left);
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306 | else
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307 | superparent = &(avlnode->parent->right);
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308 | }
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309 | else
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310 | superparent = &(avltree->top);
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311 |
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312 | zAVLFillVacancy(avltree, origparent, superparent,
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313 | avlnode->left, avlnode->right);
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314 | free(avlnode);
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315 | avltree->count--;
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316 | return 0;
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317 | }
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318 |
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319 |
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320 | /*
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321 | * zAVLFirst:
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322 | * Initializes an zAVLCursor object and returns the item with the lowest
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323 | * key in the zAVLTree.
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324 | */
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325 | void *zAVLFirst (zAVLCursor *avlcursor, zAVLTree const *avltree)
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326 | {
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327 | const zAVLNode *avlnode;
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328 |
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329 | if (NULL == avltree) /* R.W. Mon Nov 19 21:15:44 CET 2001 */
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330 | return NULL;
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331 |
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332 | avlcursor->avltree = avltree;
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333 |
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334 | if (avltree->top == NULL) {
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335 | avlcursor->curnode = NULL;
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336 | return NULL;
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337 | }
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338 |
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339 | for (avlnode = avltree->top;
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340 | avlnode->left != NULL;
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341 | avlnode = avlnode->left);
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342 | avlcursor->curnode = avlnode;
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343 | return avlnode->item;
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344 | }
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345 |
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346 |
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347 | /*
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348 | * zAVLNext:
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349 | * Called after an zAVLFirst() call, this returns the item with the least
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350 | * key that is greater than the last item returned either by zAVLFirst()
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351 | * or a previous invokation of this function.
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352 | */
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353 | void *zAVLNext (zAVLCursor *avlcursor)
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354 | {
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355 | const zAVLNode *avlnode;
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356 |
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357 | avlnode = avlcursor->curnode;
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358 |
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359 | if (avlnode->right != NULL) {
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360 | for (avlnode = avlnode->right;
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361 | avlnode->left != NULL;
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362 | avlnode = avlnode->left);
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363 | avlcursor->curnode = avlnode;
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364 | return avlnode->item;
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365 | }
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366 |
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367 | while (avlnode->parent && avlnode->parent->left != avlnode) {
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368 | avlnode = avlnode->parent;
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369 | }
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370 |
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371 | if (avlnode->parent == NULL) {
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372 | avlcursor->curnode = NULL;
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373 | return NULL;
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374 | }
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375 |
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376 | avlcursor->curnode = avlnode->parent;
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377 | return avlnode->parent->item;
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378 | }
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379 |
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380 |
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381 | /*
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382 | * zAVLCloseSearchNode:
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383 | * Return a pointer to the node closest to the given key.
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384 | * Returns NULL if the AVL tree is empty.
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385 | */
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386 | static zAVLNode *zAVLCloseSearchNode (zAVLTree const *avltree, zAVLKey key,
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387 | int * ok)
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388 | {
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389 | zAVLNode *node;
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390 |
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391 | *ok = ZAVL_NO;
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392 |
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393 | node = avltree->top;
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394 |
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395 | if (!node)
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396 | return NULL;
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397 |
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398 | for (;;) {
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399 | if (!zAVLKey_cmp(avltree, node->key, key))
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400 | {
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401 | *ok = ZAVL_OK;
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402 | return node;
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403 | }
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404 |
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405 | if (zAVLKey_cmp(avltree, node->key, key) < 0) {
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406 | if (node->right)
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407 | node = node->right;
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408 | else
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409 | return node;
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410 | }
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411 |
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412 | else {
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413 | if (node->left)
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414 | node = node->left;
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415 | else
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416 | return node;
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417 | }
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418 | }
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419 | }
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420 |
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421 |
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422 | /*
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423 | * zAVLRebalanceNode:
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424 | * Rebalances the AVL tree if one side becomes too heavy. This function
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425 | * assumes that both subtrees are AVL trees with consistant data. This
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426 | * function has the additional side effect of recalculating the depth of
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427 | * the tree at this node. It should be noted that at the return of this
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428 | * function, if a rebalance takes place, the top of this subtree is no
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429 | * longer going to be the same node.
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430 | */
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431 | static void zAVLRebalanceNode (zAVLTree *avltree, zAVLNode *avlnode)
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432 | {
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433 | long depthdiff;
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434 | zAVLNode *child;
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435 | zAVLNode *gchild;
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436 | zAVLNode *origparent;
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437 | zAVLNode **superparent;
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438 |
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439 | origparent = avlnode->parent;
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440 |
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441 | if (origparent) {
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442 | if (zAVLKey_cmp(avltree, avlnode->key, avlnode->parent->key) < 0)
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443 | superparent = &(avlnode->parent->left);
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444 | else
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445 | superparent = &(avlnode->parent->right);
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446 | }
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447 | else
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448 | superparent = &(avltree->top);
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449 |
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450 | depthdiff = R_DEPTH(avlnode) - L_DEPTH(avlnode);
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451 |
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452 | if (depthdiff <= -2 && avlnode->left) {
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453 | child = avlnode->left;
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454 |
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455 | if (L_DEPTH(child) >= R_DEPTH(child)) {
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456 | avlnode->left = child->right;
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457 | if (avlnode->left != NULL)
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458 | avlnode->left->parent = avlnode;
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459 | avlnode->depth = CALC_DEPTH(avlnode);
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460 | child->right = avlnode;
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461 | if (child->right != NULL)
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462 | child->right->parent = child;
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463 | child->depth = CALC_DEPTH(child);
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464 | *superparent = child;
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465 | child->parent = origparent;
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466 | }
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467 |
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468 | else {
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469 | gchild = child->right;
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470 | if (gchild)
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471 | {
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472 | avlnode->left = gchild->right;
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473 | if (avlnode->left != NULL)
|
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474 | avlnode->left->parent = avlnode;
|
---|
475 | avlnode->depth = CALC_DEPTH(avlnode);
|
---|
476 | child->right = gchild->left;
|
---|
477 | if (child->right != NULL)
|
---|
478 | child->right->parent = child;
|
---|
479 | child->depth = CALC_DEPTH(child);
|
---|
480 | gchild->right = avlnode;
|
---|
481 | if (gchild->right != NULL)
|
---|
482 | gchild->right->parent = gchild;
|
---|
483 | gchild->left = child;
|
---|
484 | if (gchild->left != NULL)
|
---|
485 | gchild->left->parent = gchild;
|
---|
486 | gchild->depth = CALC_DEPTH(gchild);
|
---|
487 | *superparent = gchild;
|
---|
488 | gchild->parent = origparent;
|
---|
489 | }
|
---|
490 | }
|
---|
491 | }
|
---|
492 |
|
---|
493 | else if (depthdiff >= 2 && avlnode->right) {
|
---|
494 | child = avlnode->right;
|
---|
495 |
|
---|
496 | if (R_DEPTH(child) >= L_DEPTH(child)) {
|
---|
497 | avlnode->right = child->left;
|
---|
498 | if (avlnode->right != NULL)
|
---|
499 | avlnode->right->parent = avlnode;
|
---|
500 | avlnode->depth = CALC_DEPTH(avlnode);
|
---|
501 | child->left = avlnode;
|
---|
502 | if (child->left != NULL)
|
---|
503 | child->left->parent = child;
|
---|
504 | child->depth = CALC_DEPTH(child);
|
---|
505 | *superparent = child;
|
---|
506 | child->parent = origparent;
|
---|
507 | }
|
---|
508 |
|
---|
509 | else {
|
---|
510 | gchild = child->left;
|
---|
511 | if (gchild)
|
---|
512 | {
|
---|
513 | avlnode->right = gchild->left;
|
---|
514 | if (avlnode->right != NULL)
|
---|
515 | avlnode->right->parent = avlnode;
|
---|
516 | avlnode->depth = CALC_DEPTH(avlnode);
|
---|
517 | child->left = gchild->right;
|
---|
518 | if (child->left != NULL)
|
---|
519 | child->left->parent = child;
|
---|
520 | child->depth = CALC_DEPTH(child);
|
---|
521 | gchild->left = avlnode;
|
---|
522 | if (gchild->left != NULL)
|
---|
523 | gchild->left->parent = gchild;
|
---|
524 | gchild->right = child;
|
---|
525 | if (gchild->right != NULL)
|
---|
526 | gchild->right->parent = gchild;
|
---|
527 | gchild->depth = CALC_DEPTH(gchild);
|
---|
528 | *superparent = gchild;
|
---|
529 | gchild->parent = origparent;
|
---|
530 | }
|
---|
531 | }
|
---|
532 | }
|
---|
533 |
|
---|
534 | else {
|
---|
535 | avlnode->depth = CALC_DEPTH(avlnode);
|
---|
536 | }
|
---|
537 | }
|
---|
538 |
|
---|
539 |
|
---|
540 | /*
|
---|
541 | * zAVLFreeBranch:
|
---|
542 | * Free memory used by this node and its item. If the freeitem argument
|
---|
543 | * is not NULL, then that function is called on the items to free their
|
---|
544 | * memory as well. In other words, the freeitem function is a
|
---|
545 | * destructor for the items in the tree.
|
---|
546 | */
|
---|
547 | static void zAVLFreeBranch (zAVLNode *avlnode, void (freeitem)(void *item))
|
---|
548 | {
|
---|
549 | if (avlnode->left)
|
---|
550 | zAVLFreeBranch(avlnode->left, freeitem);
|
---|
551 | if (avlnode->right)
|
---|
552 | zAVLFreeBranch(avlnode->right, freeitem);
|
---|
553 | if (freeitem) {
|
---|
554 | freeitem(avlnode->item);
|
---|
555 | avlnode->item = NULL;
|
---|
556 | }
|
---|
557 | free(avlnode);
|
---|
558 | }
|
---|
559 |
|
---|
560 |
|
---|
561 | /*
|
---|
562 | * zAVLFillVacancy:
|
---|
563 | * Given a vacancy in the AVL tree by it's parent, children, and parent
|
---|
564 | * component pointer, fill that vacancy.
|
---|
565 | */
|
---|
566 | static void zAVLFillVacancy (zAVLTree *avltree,
|
---|
567 | zAVLNode *origparent, zAVLNode **superparent,
|
---|
568 | zAVLNode *left, zAVLNode *right)
|
---|
569 | {
|
---|
570 | zAVLNode *avlnode;
|
---|
571 | zAVLNode *balnode;
|
---|
572 | zAVLNode *nextbalnode;
|
---|
573 |
|
---|
574 | if (left == NULL) {
|
---|
575 | if (right)
|
---|
576 | right->parent = origparent;
|
---|
577 |
|
---|
578 | *superparent = right;
|
---|
579 | balnode = origparent;
|
---|
580 | }
|
---|
581 |
|
---|
582 | else {
|
---|
583 | for (avlnode = left; avlnode->right != NULL; avlnode = avlnode->right);
|
---|
584 |
|
---|
585 | if (avlnode == left) {
|
---|
586 | balnode = avlnode;
|
---|
587 | }
|
---|
588 | else {
|
---|
589 | balnode = avlnode->parent;
|
---|
590 | balnode->right = avlnode->left;
|
---|
591 | if (balnode->right != NULL)
|
---|
592 | balnode->right->parent = balnode;
|
---|
593 | avlnode->left = left;
|
---|
594 | left->parent = avlnode;
|
---|
595 | }
|
---|
596 |
|
---|
597 | avlnode->right = right;
|
---|
598 | if (right != NULL)
|
---|
599 | right->parent = avlnode;
|
---|
600 | *superparent = avlnode;
|
---|
601 | avlnode->parent = origparent;
|
---|
602 | }
|
---|
603 |
|
---|
604 | for (; balnode; balnode = nextbalnode) {
|
---|
605 | nextbalnode = balnode->parent;
|
---|
606 | zAVLRebalanceNode(avltree, balnode);
|
---|
607 | }
|
---|
608 | }
|
---|