虽然自己没想到是这样的,不过一看还是很自然和谐的,从哪里获取,不断的过滤条件,要选择一样或不一样的,排好序,那才知道要取前几条呢。既然如此了,那就让我们一步步来看看其中的细节吧。准备工作1.创建测试数据库create database testQuery 2.创建测试表 CREATE TABLE table1 ( uid VARCHAR(10) NOT NULL, name VARCHAR(10) NOT NULL, PRIMARY KEY(uid) )ENGINE=INNODB DEFAULT CHARSET=UTF8;
CREATE TABLE table2 ( oid INT NOT NULL auto_increment, uid VARCHAR(10), PRIMARY KEY(oid) )ENGINE=INNODB DEFAULT CHARSET=UTF8;
3.插入数据INSERT INTO table1(uid,name) VALUES('aaa','mike'),('bbb','jack'),('ccc','mike'),('ddd','mike');
INSERT INTO table2(uid) VALUES('aaa'),('aaa'),('bbb'),('bbb'),('bbb'),('ccc'),(NULL); 4.最后想要的结果 SELECT a.uid, count(b.oid) AS total FROM table1 AS a LEFT JOIN table2 AS b ON a.uid = b.uid WHERE a. NAME = 'mike' GROUP BY a.uid HAVING count(b.oid) < 2 ORDER BY total DESC LIMIT 1;
!现在开始SQL解析之旅吧!1. FROM当涉及多个表的时候,左边表的输出会作为右边表的输入,之后会生成一个虚拟表VT1。(1-J1)笛卡尔积计算两个相关联表的笛卡尔积(CROSS JOIN) ,生成虚拟表VT1-J1。 mysql> select * from table1,table2; ----- ------ ----- ------ | uid | name | oid | uid | ----- ------ ----- ------ | aaa | mike | 1 | aaa | | bbb | jack | 1 | aaa | | ccc | mike | 1 | aaa | | ddd | mike | 1 | aaa | | aaa | mike | 2 | aaa | | bbb | jack | 2 | aaa | | ccc | mike | 2 | aaa | | ddd | mike | 2 | aaa | | aaa | mike | 3 | bbb | | bbb | jack | 3 | bbb | | ccc | mike | 3 | bbb | | ddd | mike | 3 | bbb | | aaa | mike | 4 | bbb | | bbb | jack | 4 | bbb | | ccc | mike | 4 | bbb | | ddd | mike | 4 | bbb | | aaa | mike | 5 | bbb | | bbb | jack | 5 | bbb | | ccc | mike | 5 | bbb | | ddd | mike | 5 | bbb | | aaa | mike | 6 | ccc | | bbb | jack | 6 | ccc | | ccc | mike | 6 | ccc | | ddd | mike | 6 | ccc | | aaa | mike | 7 | NULL | | bbb | jack | 7 | NULL | | ccc | mike | 7 | NULL | | ddd | mike | 7 | NULL | ----- ------ ----- ------ 28 rows inset (0.00 sec)
(1-J2)ON过滤基于虚拟表VT1-J1这一个虚拟表进行过滤,过滤出所有满足ON 谓词条件的列,生成虚拟表VT1-J2。注意:这里因为语法限制,使用了'WHERE'代替,从中读者也可以感受到两者之间微妙的关系; mysql> SELECT -> * -> FROM -> table1, -> table2 -> WHERE -> table1.uid = table2.uid -> ; ----- ------ ----- ------ | uid | name | oid | uid | ----- ------ ----- ------ | aaa | mike | 1 | aaa | | aaa | mike | 2 | aaa | | bbb | jack | 3 | bbb | | bbb | jack | 4 | bbb | | bbb | jack | 5 | bbb | | ccc | mike | 6 | ccc | ----- ------ ----- ------ 6 rows inset (0.00 sec)
(1-J3)添加外部列如果使用了外连接(LEFT,RIGHT,FULL),主表(保留表)中的不符合ON条件的列也会被加入到VT1-J2中,作为外部行,生成虚拟表VT1-J3。 mysql> SELECT -> * -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid; ----- ------ ------ ------ | uid | name | oid | uid | ----- ------ ------ ------ | aaa | mike | 1 | aaa | | aaa | mike | 2 | aaa | | bbb | jack | 3 | bbb | | bbb | jack | 4 | bbb | | bbb | jack | 5 | bbb | | ccc | mike | 6 | ccc | | ddd | mike | NULL | NULL | ----- ------ ------ ------ 7 rows inset (0.00 sec)
下面从网上找到一张很形象的关于‘SQL JOINS'的解释图,如若侵犯了你的权益,请劳烦告知删除,谢谢。img2. WHERE对VT1过程中生成的临时表进行过滤,满足WHERE子句的列被插入到VT2表中。注意:此时因为分组,不能使用聚合运算;也不能使用SELECT中创建的别名;与ON的区别:如果有外部列,ON针对过滤的是关联表,主表(保留表)会返回所有的列;如果没有添加外部列,两者的效果是一样的;应用:对主表的过滤应该放在WHERE;对于关联表,先条件查询后连接则用ON,先连接后条件查询则用WHERE; mysql> SELECT -> * -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike'; ----- ------ ------ ------ | uid | name | oid | uid | ----- ------ ------ ------ | aaa | mike | 1 | aaa | | aaa | mike | 2 | aaa | | ccc | mike | 6 | ccc | | ddd | mike | NULL | NULL | ----- ------ ------ ------ 4 rows inset (0.00 sec)
3. GROUP BY这个子句会把VT2中生成的表按照GROUP BY中的列进行分组。生成VT3表。注意:其后处理过程的语句,如SELECT,HAVING,所用到的列必须包含在GROUP BY中,对于没有出现的,得用聚合函数;原因:GROUP BY改变了对表的引用,将其转换为新的引用方式,能够对其进行下一级逻辑操作的列会减少;我的理解是:根据分组字段,将具有相同分组字段的记录归并成一条记录,因为每一个分组只能返回一条记录,除非是被过滤掉了,而不在分组字段里面的字段可能会有多个值,多个值是无法放进一条记录的,所以必须通过聚合函数将这些具有多值的列转换成单值; mysql> SELECT -> * -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike' -> GROUP BY -> a.uid; ----- ------ ------ ------ | uid | name | oid | uid | ----- ------ ------ ------ | aaa | mike | 1 | aaa | | ccc | mike | 6 | ccc | | ddd | mike | NULL | NULL | ----- ------ ------ ------ 3 rows inset (0.00 sec)
4. HAVING这个子句对VT3表中的不同的组进行过滤,只作用于分组后的数据,满足HAVING条件的子句被加入到VT4表中。 mysql> SELECT -> * -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike' -> GROUP BY -> a.uid -> HAVING -> count(b.oid) < 2; ----- ------ ------ ------ | uid | name | oid | uid | ----- ------ ------ ------ | ccc | mike | 6 | ccc | | ddd | mike | NULL | NULL | ----- ------ ------ ------ 2 rows inset (0.00 sec)
5. SELECT这个子句对SELECT子句中的元素进行处理,生成VT5表。(5-J1)计算表达式 计算SELECT 子句中的表达式,生成VT5-J1(5-J2)DISTINCT寻找VT5-1中的重复列,并删掉,生成VT5-J2如果在查询中指定了DISTINCT子句,则会创建一张内存临时表(如果内存放不下,就需要存放在硬盘了)。这张临时表的表结构和上一步产生的虚拟表VT5是一样的,不同的是对进行DISTINCT操作的列增加了一个唯一索引,以此来除重复数据。 mysql> SELECT -> a.uid, -> count(b.oid) AS total -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike' -> GROUP BY -> a.uid -> HAVING -> count(b.oid) < 2; ----- ------- | uid | total | ----- ------- | ccc | 1 | | ddd | 0 | ----- ------- 2 rows inset (0.00 sec)
6.ORDER BY从VT5-J2中的表中,根据ORDER BY 子句的条件对结果进行排序,生成VT6表。注意:唯一可使用SELECT中别名的地方; mysql> SELECT -> a.uid, -> count(b.oid) AS total -> FROM -> table1 AS a -> LEFT OUTER JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike' -> GROUP BY -> a.uid -> HAVING -> count(b.oid) < 2 -> ORDER BY -> total DESC; ----- ------- | uid | total | ----- ------- | ccc | 1 | | ddd | 0 | ----- ------- 2 rows inset (0.00 sec)
7.LIMITLIMIT子句从上一步得到的VT6虚拟表中选出从指定位置开始的指定行数据。注意:offset和rows的正负带来的影响;当偏移量很大时效率是很低的,可以这么做:采用子查询的方式优化,在子查询里先从索引获取到最大id,然后倒序排,再取N行结果集采用INNER JOIN优化,JOIN子句里也优先从索引获取ID列表,然后直接关联查询获得最终结果 mysql> SELECT -> a.uid, -> count(b.oid) AS total -> FROM -> table1 AS a -> LEFT JOIN table2 AS b ON a.uid = b.uid -> WHERE -> a. NAME = 'mike' -> GROUP BY -> a.uid -> HAVING -> count(b.oid) < 2 -> ORDER BY -> total DESC -> LIMIT 1; ----- ------- | uid | total | ----- ------- | ccc | 1 | ----- ------- 1 row inset (0.00 sec)
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