2-3树和2-3-4树的区不大,2-3树在插入时先找到叶子节点(没有子节点),然后插入,过程中如果已经是3Node(2 key)就分裂,向上冒泡,一直可能冒泡到顶上。
2-3-4树则在向下找叶子节点时就做调整,把4Node(3 key)提前分裂掉,为下级节点腾出空间,所以叶子节点插入后不会不停向上冒泡。
2-3-4树冗余更大,如果不提前分裂就是2-3树
红黑树是2-3-4树的2节点表示,采用左倾和旋转来简化和冒泡,Rober Segwick的ppt很经典
B+树感觉都是数据库中数据和索引的关系。索引可以没有,有了是用来加速某种查找。
在数据增删时索引维护时个问题。
顺便提下skip list, 对排序好的数据提取N个做索引,再对N个做同样采样索引,重复向上。对于大量数据很好理解,也很容易实现。索引和数据分开。
2-3树删除算法比较复杂,这里没实现。仅仅实现了插入和搜索,测试结果:
E A R C H X M P L A C E H L M P R X (A C) (E) (H L) (M) (P) (R) (X) 16 7 15 15 18 3 6 15 5 11 9 12 7 10 19 18 12 14 2 12 2 3 5 6 7 9 10 11 12 14 15 16 18 19 (2) (3 (5) 6) (7) (9 (10) (11) (12 14) 15) (16) (18) (19)
#include <stdio.h>
#include <stdlib.h>
#include <errno.h>
#include <assert.h>
#include <string.h>
typedef int T;
typedef struct TreeNodeT {
T v; //value left
T v2; //value right
int twins;
struct TreeNodeT *up;
struct TreeNodeT *left;
struct TreeNodeT *center; //center if twins node
struct TreeNodeT *right;
} TreeNode;
typedef int Callback(TreeNode *node, int n, int level, void *ctx); //return stop or not
TreeNode *tree_del(TreeNode *node, T v); //TODO
TreeNode *tree_top(TreeNode *e) {
TreeNode *top = NULL;
while (e && e->up)
top = e->up;
return top;
}
int tree_callback_locate(TreeNode *node, int n, int level, void *ctx) {
T v = n == 0 ? node->v : node->v2;
T t = (T) ctx;
return v == t;
}
int tree_callback_verify(TreeNode *node, int n, int level, void *ctx) {
assert(ctx);
T v = n == 0 ? node->v : node->v2;
T *last = (T *) ctx;
assert(v > *last);
*last = v;
return 0;
}
int tree_callback_print_h(TreeNode *node, int n, int level, void *ctx) {
printf("%d ", n == 0 ? node->v : node->v2);
return 0;
}
int tree_callback_print_hc(TreeNode *node, int n, int level, void *ctx) {
printf("%c ", n == 0 ? node->v : node->v2);
return 0;
}
int tree_callback_print_v(TreeNode *node, int n, int level, void *ctx) {
int i;
for (i = 0; i < level; ++i) {
printf("\t");
}
if (n == 0)
printf("(");
printf("%d", n == 0 ? node->v : node->v2);
if ((node->twins && n == 1) || !node->twins)
printf(")");
printf("\n");
return 0;
}
int tree_callback_print_vc(TreeNode *node, int n, int level, void *ctx) {
int i;
for (i = 0; i < level; ++i) {
printf("\t");
}
if (n == 0)
printf("(");
printf("%c", n == 0 ? node->v : node->v2);
if ((node->twins && n == 1) || !node->twins)
printf(")");
printf("\n");
return 0;
}
/* return stop or not */
int tree_walk(TreeNode *node, int level, Callback cb, void *ctx) {
if (node->left && tree_walk(node->left, level + 1, cb, ctx))
return 1;
if (cb(node, 0, level, ctx))
return 1;
if (node->twins) {
if (node->center && tree_walk(node->center, level + 1, cb, ctx))
return 1;
if (cb(node, 1, level, ctx))
return 1;
}
if (node->right && tree_walk(node->right, level + 1, cb, ctx))
return 1;
return 0;
}
static void tree_node_init_single(TreeNode* node, T v, TreeNode* left,
TreeNode* right) {
//shrink left to Single Node
node->v = v;
node->twins = 0;
node->v2 = 0;
node->left = left;
if (left)
left->up = node;
node->center = NULL;
node->right = right;
if (right)
right->up = node;
}
static TreeNode* tree_node_alloc(TreeNode* up, T v, TreeNode* left,
TreeNode* right) {
// new upper Single Node
TreeNode* node = (TreeNode*) calloc(sizeof(TreeNode), 1);
tree_node_init_single(node, v, left, right);
node->up = up;
return node;
}
static TreeNode *tree_node_insert(TreeNode *node, T v, TreeNode *left,
TreeNode *right);
static TreeNode *tree_node_split(TreeNode *node, T v1, T v2, T v3, //
TreeNode *n1, TreeNode *n2, TreeNode *n3, TreeNode *n4) {
TreeNode *left = node; //reuse node
//shrink left to Single Node
tree_node_init_single(left, v1, n1, n2);
//Create new right Single Node
TreeNode *right = tree_node_alloc(node->up, v3, n3, n4);
TreeNode *up = node->up;
if (up == NULL) { // new upper Single Node
up = tree_node_alloc(NULL, v2, left, right);
return up;
} else { //upper node exist, escalate
return tree_node_insert(up, v2, left, right);
}
}
/* insert v to up:
* if up is single, make it twins
* if up is twins, split
* return NULL if no new top tree node created;
*/
static TreeNode *tree_node_insert(TreeNode *node, T v, TreeNode *left,
TreeNode *right) {
if (!node->twins) { //Single node -> Twins
node->twins = 1;
if (v < node->v) {
node->v2 = node->v;
node->v = v;
node->left = left;
node->center = right;
} else {
node->v2 = v;
node->center = left;
node->right = right;
}
return NULL;
} else { //twins, must have 3 child, split and escalate the middle one
if (v < node->v) {
node = tree_node_split(node, v, node->v, node->v2, left, right,
node->center, node->right);
} else if (v < node->v2) {
node = tree_node_split(node, node->v, v, node->v2, node->left, left,
right, node->right);
} else {
node = tree_node_split(node, node->v, node->v2, v, node->left,
node->center, left, right);
}
return node;
}
}
static void tree_node_check(TreeNode* node) {
assert(node);
assert(
(node->left && node->right) || (node->left == NULL && node->right == NULL));
if (node->left)
assert(node->left->up == node);
if (node->center)
assert(node->center->up == node);
if (node->right)
assert(node->right->up == node);
}
/* NULL: v exists, no action */
static TreeNode *tree_search_leaf_add(TreeNode *node, T v) {
tree_node_check(node);
if (v == node->v || (node->twins && node->v2 == v))
return NULL;
if (node->left) { // has children, 2 or 3
if (v < node->v) //less than v
return tree_search_leaf_add(node->left, v);
if (node->twins && v < node->v2) //twins node
return tree_search_leaf_add(node->center, v);
else
return tree_search_leaf_add(node->right, v);
}
return node;
}
/* TreeNode grow strategy:
* 1. Grow up from leaf!
* 2. Single -> Twins, so each twins node must have 3 children
* 3. Twins -> 3 Single, so each new parent must have 2 children
* 4. left and right must exist!
* 5. if twins, center must exist!
*/
TreeNode *tree_add(TreeNode *tree, T v) {
if (tree == NULL)
return tree_node_alloc(NULL, v, NULL, NULL);
tree_node_check(tree);
TreeNode *leaf = tree_search_leaf_add(tree, v);
if (!leaf) //already exits on tree
return tree;
TreeNode *node = tree_node_insert(leaf, v, NULL, NULL);
return node ? node : tree;
}
void tree_test_number(int n, int random) {
TreeNode* t;
int i;
T last = 0;
T v;
for (i = 1; i <= n; ++i) {
v = random ? ((double) rand() * n) / RAND_MAX : i;
printf("%d ", v);
t = tree_add(t, v);
// tree_walk(t, 0, tree_callback_print_v, 0);
// printf("===================\n");
}
printf("\n");
tree_walk(t, 0, tree_callback_verify, &last);
tree_walk(t, 0, tree_callback_print_h, NULL);
printf("\n");
tree_walk(t, 0, tree_callback_print_v, 0);
}
void tree_test_chars() {
TreeNode *t = NULL;
int i;
T last = 0;
char c;
// http://blog.csdn.net/yang_yulei/article/details/26066409
char* str = "EARCHXMPL";
for (i = 0; i < strlen(str); ++i) {
c = str[i]; //random();
printf("%c ", c);
t = tree_add(t, c);
}
printf("\n");
tree_walk(t, 0, tree_callback_verify, &last);
tree_walk(t, 0, tree_callback_print_hc, NULL);
printf("\n");
tree_walk(t, 0, tree_callback_print_vc, NULL);
}
int main(int argc, char **argv) {
tree_test_chars();
tree_test_number(20, 1);
return EXIT_SUCCESS;
}