预排序遍历树算法(非递归无限极分类算法)
多层数据结构估计所有的web开发者估计都不会陌生,各种软件的分类都是基于多层结构来设计的。
下面是一个典型的多层数据结构示意图:
CREATE TABLE category(
category_id INT AUTO_INCREMENT PRIMARY KEY,
name VARCHAR(20) NOT NULL,
parent INT DEFAULT NULL);
INSERT INTO category
VALUES(1,‘ELECTRONICS‘,NULL),(2,‘TELEVISIONS‘,1),(3,‘TUBE‘,2),
(4,‘LCD‘,2),(5,‘PLASMA‘,2),(6,‘PORTABLE ELECTRONICS‘,1),
(7,‘MP3 PLAYERS‘,6),(8,‘FLASH‘,7),
(9,‘CD PLAYERS‘,6),(10,‘2 WAY RADIOS‘,6);
SELECT * FROM category ORDER BY category_id;
在这种数据结构中,各层之间通过字段 parent 来形成邻接表,我们查询某些层级的关系的时候一般都是通过递归的方式,遍历某个层级关系的SQL的查询次数会顺着层级的增加,想想在层级有20的时候,根据某个底层节点取它到顶层节点的查询次数吧。
为了解决这个问题,人们想出了嵌套集模型(The Nested Set Model),请看下图:
上图依然是表现的与图一相同的层级关系,但是却更换了一种表现形式 下面是新的关系表和数据(关系和数据与之前相同,但是表结构不一样):
CREATE TABLE nested_category (
category_id INT AUTO_INCREMENT PRIMARY KEY,
name VARCHAR(20) NOT NULL,
lft INT NOT NULL,
rgt INT NOT NULL
);
INSERT INTO nested_category
VALUES(1,‘ELECTRONICS‘,1,20),(2,‘TELEVISIONS‘,2,9),(3,‘TUBE‘,3,4),
(4,‘LCD‘,5,6),(5,‘PLASMA‘,7,8),(6,‘PORTABLE ELECTRONICS‘,10,19),
(7,‘MP3 PLAYERS‘,11,14),(8,‘FLASH‘,12,13),
(9,‘CD PLAYERS‘,15,16),(10,‘2 WAY RADIOS‘,17,18);
SELECT * FROM nested_category ORDER BY category_id;
这里将 left,right 修改为 lft,rgt因为这两个词在MYSQL中属于关键字 下面我们将插入的数据标识在图上:
怎么样,是不是很明确了
下面使我自己标定一种形式,方便理解
[1
[2
[3 4]
[5 6]
[7 8]
9]
[10
[11
[12 13]
14]
[15 16]
[17 18]
19]
20]
遍历整个树,查询子集 条件:左边 > 父级L, 右边 < 父级R
SELECT node.name
FROM nested_category AS node,
nested_category AS parent
WHERE node.lft BETWEEN parent.lft AND parent.rgt
AND parent.name = ‘ELECTRONICS‘
ORDER BY node.lft;
+----------------------+
| name |
+----------------------+
| ELECTRONICS |
| TELEVISIONS |
| TUBE |
| LCD |
| PLASMA |
| PORTABLE ELECTRONICS |
| MP3 PLAYERS |
| FLASH |
| CD PLAYERS |
| 2 WAY RADIOS |
+----------------------+
- 查询所有无分支的节点 条件:右边 = 左边L + 1
SELECT name
FROM nested_category
WHERE rgt = lft + 1;
- 查询某个字节点到根节点的路径
SELECT parent.name
FROM nested_category AS node,
nested_category AS parent
WHERE node.lft BETWEEN parent.lft AND parent.rgt
AND node.name = ‘FLASH‘
ORDER BY parent.lft;
SELECT node.name, (COUNT(parent.name) - 1) AS depth
FROM nested_category AS node,
nested_category AS parent
WHERE node.lft BETWEEN parent.lft AND parent.rgt
GROUP BY node.name
ORDER BY node.lft;
- 查询子节点的深度
SELECT node.name, (COUNT(parent.name) - (sub_tree.depth + 1)) AS depth
FROM nested_category AS node,
nested_category AS parent,
nested_category AS sub_parent,
(
SELECT node.name, (COUNT(parent.name) - 1) AS depth
FROM nested_category AS node,
nested_category AS parent
WHERE node.lft BETWEEN parent.lft AND parent.rgt
AND node.name = ‘PORTABLE ELECTRONICS‘
GROUP BY node.name
ORDER BY node.lft
)AS sub_tree
WHERE node.lft BETWEEN parent.lft AND parent.rgt
AND node.lft BETWEEN sub_parent.lft AND sub_parent.rgt
AND sub_parent.name = sub_tree.name
GROUP BY node.name
ORDER BY node.lft;
- 插入新节点
算法详解:
1.所有分类 左边和右边的值 > 插入节点的左边节点记录的右值 的全部 + 2
2.插入节点 左值 = 插入位置左边节点记录的右值 + 1, 右值 = 插入位置左边节点记录的右值 + 2
例子:
在 R = 9(L8, R9)与 L = 10(L10,R11) 节点之间插入一个新节点
那么所有 左值 和 右值 > 9 的节点的左值和右值需要 + 2
例如新节点右边的节点(L10,R11)左值右值都需要 + 2 那么插入后的新值为 L12 R13
新节点的左值为 9 + 1 = 10 右值为 9 + 2 = 11
SQL语句实现
LOCK TABLE nested_category WRITE;
SELECT @myRight := rgt FROM nested_category
WHERE name = ‘TELEVISIONS‘;
UPDATE nested_category SET rgt = rgt + 2 WHERE rgt > @myRight;
UPDATE nested_category SET lft = lft + 2 WHERE lft > @myRight;
INSERT INTO nested_category(name, lft, rgt) VALUES(‘GAME CONSOLES‘, @myRight + 1, @myRight +2);
UNLOCK TABLES;
- 删除新节点
删除节点的算法与添加一个节点的算法相反
删除一个没有子节点的节点
LOCK TABLE nested_category WRITE;
SELECT @myLeft := lft, @myRight := rgt, @myWidth := rgt - lft + 1
FROM nested_category
WHERE name = ‘GAME CONSOLES‘;
DELETE FROM nested_category WHERE lft BETWEEN @myLeft AND @myRight;
UPDATE nested_category SET rgt = rgt - @myWidth WHERE rgt > @myRight;
UPDATE nested_category SET lft = lft - @myWidth WHERE lft > @myRight;
UNLOCK TABLES;
删除一个分支节点和它所有的子节点
LOCK TABLE nested_category WRITE;
SELECT @myLeft := lft, @myRight := rgt, @myWidth := rgt - lft + 1
FROM nested_category
WHERE name = ‘MP3 PLAYERS‘;
DELETE FROM nested_category WHERE lft BETWEEN @myLeft AND @myRight;
UPDATE nested_category SET rgt = rgt - @myWidth WHERE rgt > @myRight;
UPDATE nested_category SET lft = lft - @myWidth WHERE lft > @myRight;
UNLOCK TABLES;
删除一个节点后移动其字节点到
LOCK TABLE nested_category WRITE;
SELECT @myLeft := lft, @myRight := rgt, @myWidth := rgt - lft + 1
FROM nested_category
WHERE name = ‘PORTABLE ELECTRONICS‘;
DELETE FROM nested_category WHERE lft = @myLeft;
UPDATE nested_category SET rgt = rgt - 1, lft = lft - 1 WHERE lft BETWEEN @myLeft AND @myRight;
UPDATE nested_category SET rgt = rgt - 2 WHERE rgt > @myRight;
UPDATE nested_category SET lft = lft - 2 WHERE lft > @myRight;
UNLOCK TABLES;
总结:
预排序遍历树算法的核心就是牺牲了写的性能来换取读取的性能
在你的开发的应用遇到此类问题的时(读压力 > 写压力),尝试下使用预排序遍历树算法来提高你的程序的性能吧。
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