mirror of
https://code.semirocket.science/wrapsix
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b6a9de321b
Fixed mistake in field type in pseudo-IPv6 header Bundled a library for red-black trees (storage mechanism is based on it)
583 lines
15 KiB
C
583 lines
15 KiB
C
/*
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Red Black balanced tree library
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> Created (Julienne Walker): August 23, 2003
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> Modified (Julienne Walker): March 14, 2008
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*/
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#include "jsw_rbtree.h"
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#ifdef __cplusplus
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#include <cstdlib>
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using std::malloc;
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using std::free;
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using std::size_t;
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#else
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#include <stdlib.h>
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#endif
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#ifndef HEIGHT_LIMIT
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#define HEIGHT_LIMIT 64 /* Tallest allowable tree */
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#endif
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typedef struct jsw_rbnode {
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int red; /* Color (1=red, 0=black) */
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void *data; /* User-defined content */
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struct jsw_rbnode *link[2]; /* Left (0) and right (1) links */
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} jsw_rbnode_t;
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struct jsw_rbtree {
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jsw_rbnode_t *root; /* Top of the tree */
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cmp_f cmp; /* Compare two items */
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dup_f dup; /* Clone an item (user-defined) */
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rel_f rel; /* Destroy an item (user-defined) */
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size_t size; /* Number of items (user-defined) */
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};
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struct jsw_rbtrav {
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jsw_rbtree_t *tree; /* Paired tree */
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jsw_rbnode_t *it; /* Current node */
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jsw_rbnode_t *path[HEIGHT_LIMIT]; /* Traversal path */
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size_t top; /* Top of stack */
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};
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/**
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<summary>
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Checks the color of a red black node
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<summary>
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<param name="root">The node to check</param>
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<returns>1 for a red node, 0 for a black node</returns>
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<remarks>For jsw_rbtree.c internal use only</remarks>
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*/
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static int is_red ( jsw_rbnode_t *root )
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{
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return root != NULL && root->red == 1;
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}
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/**
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<summary>
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Performs a single red black rotation in the specified direction
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This function assumes that all nodes are valid for a rotation
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<summary>
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<param name="root">The original root to rotate around</param>
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<param name="dir">The direction to rotate (0 = left, 1 = right)</param>
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<returns>The new root ater rotation</returns>
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<remarks>For jsw_rbtree.c internal use only</remarks>
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*/
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static jsw_rbnode_t *jsw_single ( jsw_rbnode_t *root, int dir )
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{
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jsw_rbnode_t *save = root->link[!dir];
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root->link[!dir] = save->link[dir];
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save->link[dir] = root;
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root->red = 1;
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save->red = 0;
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return save;
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}
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/**
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<summary>
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Performs a double red black rotation in the specified direction
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This function assumes that all nodes are valid for a rotation
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<summary>
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<param name="root">The original root to rotate around</param>
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<param name="dir">The direction to rotate (0 = left, 1 = right)</param>
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<returns>The new root after rotation</returns>
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<remarks>For jsw_rbtree.c internal use only</remarks>
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*/
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static jsw_rbnode_t *jsw_double ( jsw_rbnode_t *root, int dir )
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{
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root->link[!dir] = jsw_single ( root->link[!dir], !dir );
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return jsw_single ( root, dir );
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}
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/**
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<summary>
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Creates an initializes a new red black node with a copy of
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the data. This function does not insert the new node into a tree
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<summary>
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<param name="tree">The red black tree this node is being created for</param>
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<param name="data">The data value that will be stored in this node</param>
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<returns>A pointer to the new node</returns>
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<remarks>
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For jsw_rbtree.c internal use only. The data for this node must
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be freed using the same tree's rel function. The returned pointer
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must be freed using C's free function
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</remarks>
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*/
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static jsw_rbnode_t *new_node ( jsw_rbtree_t *tree, void *data )
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{
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jsw_rbnode_t *rn = (jsw_rbnode_t *)malloc ( sizeof *rn );
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if ( rn == NULL )
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return NULL;
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rn->red = 1;
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rn->data = tree->dup ( data );
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rn->link[0] = rn->link[1] = NULL;
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return rn;
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}
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/**
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<summary>
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Creates and initializes an empty red black tree with
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user-defined comparison, data copy, and data release operations
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<summary>
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<param name="cmp">User-defined data comparison function</param>
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<param name="dup">User-defined data copy function</param>
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<param name="rel">User-defined data release function</param>
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<returns>A pointer to the new tree</returns>
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<remarks>
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The returned pointer must be released with jsw_rbdelete
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</remarks>
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*/
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jsw_rbtree_t *jsw_rbnew ( cmp_f cmp, dup_f dup, rel_f rel )
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{
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jsw_rbtree_t *rt = (jsw_rbtree_t *)malloc ( sizeof *rt );
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if ( rt == NULL )
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return NULL;
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rt->root = NULL;
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rt->cmp = cmp;
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rt->dup = dup;
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rt->rel = rel;
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rt->size = 0;
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return rt;
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}
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/**
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<summary>
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Releases a valid red black tree
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<summary>
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<param name="tree">The tree to release</param>
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<remarks>
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The tree must have been created using jsw_rbnew
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</remarks>
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*/
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void jsw_rbdelete ( jsw_rbtree_t *tree )
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{
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jsw_rbnode_t *it = tree->root;
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jsw_rbnode_t *save;
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/*
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Rotate away the left links so that
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we can treat this like the destruction
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of a linked list
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*/
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while ( it != NULL ) {
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if ( it->link[0] == NULL ) {
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/* No left links, just kill the node and move on */
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save = it->link[1];
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tree->rel ( it->data );
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free ( it );
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}
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else {
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/* Rotate away the left link and check again */
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save = it->link[0];
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it->link[0] = save->link[1];
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save->link[1] = it;
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}
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it = save;
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}
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free ( tree );
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}
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/**
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<summary>
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Search for a copy of the specified
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node data in a red black tree
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<summary>
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<param name="tree">The tree to search</param>
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<param name="data">The data value to search for</param>
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<returns>
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A pointer to the data value stored in the tree,
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or a null pointer if no data could be found
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</returns>
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*/
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void *jsw_rbfind ( jsw_rbtree_t *tree, void *data )
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{
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jsw_rbnode_t *it = tree->root;
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while ( it != NULL ) {
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int cmp = tree->cmp ( it->data, data );
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if ( cmp == 0 )
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break;
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/*
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If the tree supports duplicates, they should be
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chained to the right subtree for this to work
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*/
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it = it->link[cmp < 0];
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}
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return it == NULL ? NULL : it->data;
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}
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/**
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<summary>
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Insert a copy of the user-specified
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data into a red black tree
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<summary>
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<param name="tree">The tree to insert into</param>
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<param name="data">The data value to insert</param>
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<returns>
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1 if the value was inserted successfully,
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0 if the insertion failed for any reason
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</returns>
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*/
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int jsw_rbinsert ( jsw_rbtree_t *tree, void *data )
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{
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if ( tree->root == NULL ) {
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/*
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We have an empty tree; attach the
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new node directly to the root
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*/
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tree->root = new_node ( tree, data );
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if ( tree->root == NULL )
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return 0;
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}
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else {
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jsw_rbnode_t head = {0}; /* False tree root */
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jsw_rbnode_t *g, *t; /* Grandparent & parent */
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jsw_rbnode_t *p, *q; /* Iterator & parent */
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int dir = 0, last = 0;
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/* Set up our helpers */
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t = &head;
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g = p = NULL;
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q = t->link[1] = tree->root;
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/* Search down the tree for a place to insert */
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for ( ; ; ) {
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if ( q == NULL ) {
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/* Insert a new node at the first null link */
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p->link[dir] = q = new_node ( tree, data );
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if ( q == NULL )
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return 0;
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}
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else if ( is_red ( q->link[0] ) && is_red ( q->link[1] ) ) {
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/* Simple red violation: color flip */
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q->red = 1;
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q->link[0]->red = 0;
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q->link[1]->red = 0;
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}
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if ( is_red ( q ) && is_red ( p ) ) {
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/* Hard red violation: rotations necessary */
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int dir2 = t->link[1] == g;
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if ( q == p->link[last] )
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t->link[dir2] = jsw_single ( g, !last );
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else
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t->link[dir2] = jsw_double ( g, !last );
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}
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/*
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Stop working if we inserted a node. This
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check also disallows duplicates in the tree
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*/
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if ( tree->cmp ( q->data, data ) == 0 )
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break;
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last = dir;
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dir = tree->cmp ( q->data, data ) < 0;
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/* Move the helpers down */
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if ( g != NULL )
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t = g;
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g = p, p = q;
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q = q->link[dir];
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}
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/* Update the root (it may be different) */
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tree->root = head.link[1];
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}
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/* Make the root black for simplified logic */
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tree->root->red = 0;
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++tree->size;
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return 1;
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}
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/**
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<summary>
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Remove a node from a red black tree
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that matches the user-specified data
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<summary>
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<param name="tree">The tree to remove from</param>
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<param name="data">The data value to search for</param>
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<returns>
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1 if the value was removed successfully,
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0 if the removal failed for any reason
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</returns>
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<remarks>
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The most common failure reason should be
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that the data was not found in the tree
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</remarks>
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*/
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int jsw_rberase ( jsw_rbtree_t *tree, void *data )
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{
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if ( tree->root != NULL ) {
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jsw_rbnode_t head = {0}; /* False tree root */
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jsw_rbnode_t *q, *p, *g; /* Helpers */
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jsw_rbnode_t *f = NULL; /* Found item */
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int dir = 1;
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/* Set up our helpers */
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q = &head;
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g = p = NULL;
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q->link[1] = tree->root;
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/*
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Search and push a red node down
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to fix red violations as we go
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*/
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while ( q->link[dir] != NULL ) {
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int last = dir;
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/* Move the helpers down */
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g = p, p = q;
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q = q->link[dir];
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dir = tree->cmp ( q->data, data ) < 0;
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/*
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Save the node with matching data and keep
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going; we'll do removal tasks at the end
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*/
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if ( tree->cmp ( q->data, data ) == 0 )
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f = q;
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/* Push the red node down with rotations and color flips */
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if ( !is_red ( q ) && !is_red ( q->link[dir] ) ) {
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if ( is_red ( q->link[!dir] ) )
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p = p->link[last] = jsw_single ( q, dir );
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else if ( !is_red ( q->link[!dir] ) ) {
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jsw_rbnode_t *s = p->link[!last];
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if ( s != NULL ) {
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if ( !is_red ( s->link[!last] ) && !is_red ( s->link[last] ) ) {
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/* Color flip */
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p->red = 0;
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s->red = 1;
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q->red = 1;
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}
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else {
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int dir2 = g->link[1] == p;
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if ( is_red ( s->link[last] ) )
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g->link[dir2] = jsw_double ( p, last );
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else if ( is_red ( s->link[!last] ) )
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g->link[dir2] = jsw_single ( p, last );
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/* Ensure correct coloring */
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q->red = g->link[dir2]->red = 1;
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g->link[dir2]->link[0]->red = 0;
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g->link[dir2]->link[1]->red = 0;
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}
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}
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}
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}
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}
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/* Replace and remove the saved node */
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if ( f != NULL ) {
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tree->rel ( f->data );
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f->data = q->data;
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p->link[p->link[1] == q] =
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q->link[q->link[0] == NULL];
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free ( q );
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}
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/* Update the root (it may be different) */
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tree->root = head.link[1];
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/* Make the root black for simplified logic */
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if ( tree->root != NULL )
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tree->root->red = 0;
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--tree->size;
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}
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return 1;
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}
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/**
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<summary>
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Gets the number of nodes in a red black tree
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<summary>
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<param name="tree">The tree to calculate a size for</param>
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<returns>The number of nodes in the tree</returns>
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*/
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size_t jsw_rbsize ( jsw_rbtree_t *tree )
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{
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return tree->size;
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}
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/**
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<summary>
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Create a new traversal object
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<summary>
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<returns>A pointer to the new object</returns>
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<remarks>
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The traversal object is not initialized until
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jsw_rbtfirst or jsw_rbtlast are called.
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The pointer must be released with jsw_rbtdelete
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</remarks>
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*/
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jsw_rbtrav_t *jsw_rbtnew ( void )
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{
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return (jsw_rbtrav_t*)malloc ( sizeof ( jsw_rbtrav_t ) );
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}
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/**
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<summary>
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Release a traversal object
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<summary>
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<param name="trav">The object to release</param>
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<remarks>
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The object must have been created with jsw_rbtnew
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</remarks>
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*/
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void jsw_rbtdelete ( jsw_rbtrav_t *trav )
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{
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free ( trav );
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}
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/**
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<summary>
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Initialize a traversal object. The user-specified
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direction determines whether to begin traversal at the
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smallest or largest valued node
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<summary>
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<param name="trav">The traversal object to initialize</param>
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<param name="tree">The tree that the object will be attached to</param>
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<param name="dir">
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The direction to traverse (0 = ascending, 1 = descending)
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</param>
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<returns>A pointer to the smallest or largest data value</returns>
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<remarks>For jsw_rbtree.c internal use only</remarks>
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*/
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static void *start ( jsw_rbtrav_t *trav, jsw_rbtree_t *tree, int dir )
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{
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trav->tree = tree;
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trav->it = tree->root;
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trav->top = 0;
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/* Save the path for later traversal */
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if ( trav->it != NULL ) {
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while ( trav->it->link[dir] != NULL ) {
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trav->path[trav->top++] = trav->it;
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trav->it = trav->it->link[dir];
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}
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}
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return trav->it == NULL ? NULL : trav->it->data;
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}
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/**
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<summary>
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Traverse a red black tree in the user-specified direction
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<summary>
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<param name="trav">The initialized traversal object</param>
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<param name="dir">
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The direction to traverse (0 = ascending, 1 = descending)
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</param>
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<returns>
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A pointer to the next data value in the specified direction
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</returns>
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<remarks>For jsw_rbtree.c internal use only</remarks>
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*/
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static void *move ( jsw_rbtrav_t *trav, int dir )
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{
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if ( trav->it->link[dir] != NULL ) {
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/* Continue down this branch */
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trav->path[trav->top++] = trav->it;
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trav->it = trav->it->link[dir];
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while ( trav->it->link[!dir] != NULL ) {
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trav->path[trav->top++] = trav->it;
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trav->it = trav->it->link[!dir];
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}
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}
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else {
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/* Move to the next branch */
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jsw_rbnode_t *last;
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do {
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if ( trav->top == 0 ) {
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trav->it = NULL;
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break;
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}
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last = trav->it;
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trav->it = trav->path[--trav->top];
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} while ( last == trav->it->link[dir] );
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}
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return trav->it == NULL ? NULL : trav->it->data;
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}
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/**
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<summary>
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Initialize a traversal object to the smallest valued node
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<summary>
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<param name="trav">The traversal object to initialize</param>
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<param name="tree">The tree that the object will be attached to</param>
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<returns>A pointer to the smallest data value</returns>
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*/
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void *jsw_rbtfirst ( jsw_rbtrav_t *trav, jsw_rbtree_t *tree )
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{
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return start ( trav, tree, 0 ); /* Min value */
|
|
}
|
|
|
|
/**
|
|
<summary>
|
|
Initialize a traversal object to the largest valued node
|
|
<summary>
|
|
<param name="trav">The traversal object to initialize</param>
|
|
<param name="tree">The tree that the object will be attached to</param>
|
|
<returns>A pointer to the largest data value</returns>
|
|
*/
|
|
void *jsw_rbtlast ( jsw_rbtrav_t *trav, jsw_rbtree_t *tree )
|
|
{
|
|
return start ( trav, tree, 1 ); /* Max value */
|
|
}
|
|
|
|
/**
|
|
<summary>
|
|
Traverse to the next value in ascending order
|
|
<summary>
|
|
<param name="trav">The initialized traversal object</param>
|
|
<returns>A pointer to the next value in ascending order</returns>
|
|
*/
|
|
void *jsw_rbtnext ( jsw_rbtrav_t *trav )
|
|
{
|
|
return move ( trav, 1 ); /* Toward larger items */
|
|
}
|
|
|
|
/**
|
|
<summary>
|
|
Traverse to the next value in descending order
|
|
<summary>
|
|
<param name="trav">The initialized traversal object</param>
|
|
<returns>A pointer to the next value in descending order</returns>
|
|
*/
|
|
void *jsw_rbtprev ( jsw_rbtrav_t *trav )
|
|
{
|
|
return move ( trav, 0 ); /* Toward smaller items */
|
|
}
|
|
|