#1、首先明确一点:分组发生在where之后,即分组是基于where之后得到的记录而进行的 #2、分组指的是:将所有记录按照某个相同字段进行归类,比如针对员工信息表的职位分组,或者按照性别进行分组等 #3、为何要分组呢? 取每个部门的最高工资 取每个部门的员工数 取男人数和女人数 小窍门:‘每’这个字后面的字段,就是我们分组的依据 #4、大前提: 可以按照任意字段分组,但是分组完毕后,比如group by post,只能查看post字段,如果想查看组内信息,需要借助于聚合函数
单独使用GROUP BY关键字分组 SELECT post FROM employee GROUP BY post; 注意:我们按照post字段分组,那么select查询的字段只能是post,想要获取组内的其他相关信息,需要借助函数 GROUP BY关键字和GROUP_CONCAT()函数一起使用 SELECT post,GROUP_CONCAT(name) FROM employee GROUP BY post;#按照岗位分组,并查看组内成员名 SELECT post,GROUP_CONCAT(name) as emp_members FROM employee GROUP BY post; GROUP BY与聚合函数一起使用 select post,count(id) as count from employee group by post;#按照岗位分组,并查看每个组有多少人
聚合函数
#强调:聚合函数聚合的是组的内容,若是没有分组,则默认一组 示例: SELECT COUNT(*) FROM employee; SELECT COUNT(*) FROM employee WHERE depart_id=1; SELECT MAX(salary) FROM employee; SELECT MIN(salary) FROM employee; SELECT AVG(salary) FROM employee; SELECT SUM(salary) FROM employee; SELECT SUM(salary) FROM employee WHERE depart_id=3;
HAVING过滤
having用于分组之后的条件查询
限制查询的记录数:LIMIT
示例: SELECT * FROM employee ORDER BY salary DESC LIMIT 3; #默认初始位置为0 SELECT * FROM employee ORDER BY salary DESC LIMIT 0,5; #从第0开始,即先查询出第一条,然后包含这一条在内往后查5条 SELECT * FROM employee ORDER BY salary DESC LIMIT 5,5; #从第5开始,即先查询出第6条,然后包含这一条在内往后查5条
使用正则表达式查询
SELECT * FROM employee WHERE name REGEXP ‘^ale‘; SELECT * FROM employee WHERE name REGEXP ‘on$‘; SELECT * FROM employee WHERE name REGEXP ‘m{2}‘; 小结:对字符串匹配的方式 WHERE name = ‘egon‘; WHERE name LIKE ‘yua%‘; WHERE name REGEXP ‘on$‘
多表查询
多表连接查询
#重点:外链接语法 SELECT 字段列表 FROM 表1 INNER|LEFT|RIGHT JOIN 表2 ON 表1.字段 = 表2.字段;
交叉连接:不适用任何匹配条件。生成笛卡尔积
mysql> select * from employee,department;
+----+------------+--------+------+--------+------+--------------+
| id | name | sex | age | dep_id | id | name |
+----+------------+--------+------+--------+------+--------------+
| 1 | egon | male | 18 | 200 | 200 | 技术 |
| 1 | egon | male | 18 | 200 | 201 | 人力资源 |
| 1 | egon | male | 18 | 200 | 202 | 销售 |
| 1 | egon | male | 18 | 200 | 203 | 运营 |
| 2 | alex | female | 48 | 201 | 200 | 技术 |
| 2 | alex | female | 48 | 201 | 201 | 人力资源 |
| 2 | alex | female | 48 | 201 | 202 | 销售 |
| 2 | alex | female | 48 | 201 | 203 | 运营 |
| 3 | wupeiqi | male | 38 | 201 | 200 | 技术 |
| 3 | wupeiqi | male | 38 | 201 | 201 | 人力资源 |
| 3 | wupeiqi | male | 38 | 201 | 202 | 销售 |
| 3 | wupeiqi | male | 38 | 201 | 203 | 运营 |
| 4 | yuanhao | female | 28 | 202 | 200 | 技术 |
| 4 | yuanhao | female | 28 | 202 | 201 | 人力资源 |
| 4 | yuanhao | female | 28 | 202 | 202 | 销售 |
| 4 | yuanhao | female | 28 | 202 | 203 | 运营 |
| 5 | liwenzhou | male | 18 | 200 | 200 | 技术 |
| 5 | liwenzhou | male | 18 | 200 | 201 | 人力资源 |
| 5 | liwenzhou | male | 18 | 200 | 202 | 销售 |
| 5 | liwenzhou | male | 18 | 200 | 203 | 运营 |
| 6 | jingliyang | female | 18 | 204 | 200 | 技术 |
| 6 | jingliyang | female | 18 | 204 | 201 | 人力资源 |
| 6 | jingliyang | female | 18 | 204 | 202 | 销售 |
| 6 | jingliyang | female | 18 | 204 | 203 | 运营 |
+----+------------+--------+------+--------+------+--------------+
内连接:只连接匹配的行
#找两张表共有的部分,相当于利用条件从笛卡尔积结果中筛选出了正确的结果 #department没有204这个部门,因而employee表中关于204这条员工信息没有匹配出来 mysql> select employee.id,employee.name,employee.age,employee.sex,department.name from employee inner join department on employee.dep_id=department.id; +----+-----------+------+--------+--------------+ | id | name | age | sex | name | +----+-----------+------+--------+--------------+ | 1 | egon | 18 | male | 技术 | | 2 | alex | 48 | female | 人力资源 | | 3 | wupeiqi | 38 | male | 人力资源 | | 4 | yuanhao | 28 | female | 销售 | | 5 | liwenzhou | 18 | male | 技术 | +----+-----------+------+--------+--------------+ #上述sql等同于 mysql> select employee.id,employee.name,employee.age,employee.sex,department.name from employee,department where employee.dep_id=department.id;
外链接之左连接:优先显示左表全部记录
#以左表为准,即找出所有员工信息,当然包括没有部门的员工 #本质就是:在内连接的基础上增加左边有右边没有的结果 mysql> select employee.id,employee.name,department.name as depart_name from employee left join department on employee.dep_id=department.id; +----+------------+--------------+ | id | name | depart_name | +----+------------+--------------+ | 1 | egon | 技术 | | 5 | liwenzhou | 技术 | | 2 | alex | 人力资源 | | 3 | wupeiqi | 人力资源 | | 4 | yuanhao | 销售 | | 6 | jingliyang | NULL | +----+------------+--------------+
外链接之右连接:优先显示右表全部记录
#以右表为准,即找出所有部门信息,包括没有员工的部门 #本质就是:在内连接的基础上增加右边有左边没有的结果 mysql> select employee.id,employee.name,department.name as depart_name from employee right join department on employee.dep_id=department.id; +------+-----------+--------------+ | id | name | depart_name | +------+-----------+--------------+ | 1 | egon | 技术 | | 2 | alex | 人力资源 | | 3 | wupeiqi | 人力资源 | | 4 | yuanhao | 销售 | | 5 | liwenzhou | 技术 | | NULL | NULL | 运营 | +------+-----------+--------------+
全外连接:显示左右两个表全部记录
全外连接:在内连接的基础上增加左边有右边没有的和右边有左边没有的结果 #注意:mysql不支持全外连接 full JOIN #强调:mysql可以使用此种方式间接实现全外连接 select * from employee left join department on employee.dep_id = department.id union select * from employee right join department on employee.dep_id = department.id ; #查看结果 +------+------------+--------+------+--------+------+--------------+ | id | name | sex | age | dep_id | id | name | +------+------------+--------+------+--------+------+--------------+ | 1 | egon | male | 18 | 200 | 200 | 技术 | | 5 | liwenzhou | male | 18 | 200 | 200 | 技术 | | 2 | alex | female | 48 | 201 | 201 | 人力资源 | | 3 | wupeiqi | male | 38 | 201 | 201 | 人力资源 | | 4 | yuanhao | female | 28 | 202 | 202 | 销售 | | 6 | jingliyang | female | 18 | 204 | NULL | NULL | | NULL | NULL | NULL | NULL | NULL | 203 | 运营 | +------+------------+--------+------+--------+------+--------------+ #注意 union与union all的区别:union会去掉相同的纪录
符合条件连接查询
#示例1:以内连接的方式查询employee和department表,并且employee表中的age字段值必须大于25,即找出年龄大于25岁的员工以及员工所在的部门 select employee.name,department.name from employee inner join department on employee.dep_id = department.id where age > 25; #示例2:以内连接的方式查询employee和department表,并且以age字段的升序方式显示 select employee.id,employee.name,employee.age,department.name from employee,department where employee.dep_id = department.id and age > 25 order by age asc;
子查询
#1:子查询是将一个查询语句嵌套在另一个查询语句中。 #2:内层查询语句的查询结果,可以为外层查询语句提供查询条件。 #3:子查询中可以包含:IN、NOT IN、ANY、ALL、EXISTS 和 NOT EXISTS等关键字 #4:还可以包含比较运算符:= 、 !=、> 、<等
带IN关键字的子查询
#查询平均年龄在25岁以上的部门名 select id,name from department where id in (select dep_id from employee group by dep_id having avg(age) > 25); #查看技术部员工姓名 select name from employee where dep_id in (select id from department where name=‘技术‘); #查看不足1人的部门名 select name from department where id in (select dep_id from employee group by dep_id having count(id) <=1);
带比较运算符的子查询
#比较运算符:=、!=、>、>=、<、<=、<> #查询大于所有人平均年龄的员工名与年龄 mysql> select name,age from emp where age > (select avg(age) from emp); +---------+------+ | name | age | +---------+------+ | alex | 48 | | wupeiqi | 38 | +---------+------+ 2 rows in set (0.00 sec) #查询大于部门内平均年龄的员工名、年龄 select t1.name,t1.age from emp t1 inner join (select dep_id,avg(age) avg_age from emp group by dep_id) t2 on t1.dep_id = t2.dep_id where t1.age > t2.avg_age;
带EXISTS关键字的子查询
EXISTS关字键字表示存在。在使用EXISTS关键字时,内层查询语句不返回查询的记录。
而是返回一个真假值。True或False
当返回True时,外层查询语句将进行查询;当返回值为False时,外层查询语句不进行查询
#department表中存在dept_id=203,Ture mysql> select * from employee -> where exists -> (select id from department where id=200); +----+------------+--------+------+--------+ | id | name | sex | age | dep_id | +----+------------+--------+------+--------+ | 1 | egon | male | 18 | 200 | | 2 | alex | female | 48 | 201 | | 3 | wupeiqi | male | 38 | 201 | | 4 | yuanhao | female | 28 | 202 | | 5 | liwenzhou | male | 18 | 200 | | 6 | jingliyang | female | 18 | 204 | +----+------------+--------+------+--------+ #department表中存在dept_id=205,False mysql> select * from employee -> where exists -> (select id from department where id=204); Empty set (0.00 sec)
约束条件
约束条件与数据类型的宽度一样,都是可选参数
作用:用于保证数据的完整性和一致性
主要分为:
PRIMARY KEY (PK) 标识该字段为该表的主键,可以唯一的标识记录 FOREIGN KEY (FK) 标识该字段为该表的外键 NOT NULL 标识该字段不能为空 UNIQUE KEY (UK) 标识该字段的值是唯一的 AUTO_INCREMENT 标识该字段的值自动增长(整数类型,而且为主键) DEFAULT 为该字段设置默认值 UNSIGNED 无符号 ZEROFILL 使用0填充
not null与default
是否可空,null表示空,非字符串
not null - 不可空
null - 可空
默认值,创建列时可以指定默认值,当插入数据时如果未主动设置,则自动添加默认值
create table tb1(
nid int not null defalut 2,
num int not null
)
==================not null====================
mysql> create table t1(id int); #id字段默认可以插入空
mysql> desc t1;
+-------+---------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+-------+---------+------+-----+---------+-------+
| id | int(11) | YES | | NULL | |
+-------+---------+------+-----+---------+-------+
mysql> insert into t1 values(); #可以插入空
mysql> create table t2(id int not null); #设置字段id不为空
mysql> desc t2;
+-------+---------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+-------+---------+------+-----+---------+-------+
| id | int(11) | NO | | NULL | |
+-------+---------+------+-----+---------+-------+
mysql> insert into t2 values(); #不能插入空
ERROR 1364 (HY000): Field ‘id‘ doesn‘t have a default value
==================default====================
#设置id字段有默认值后,则无论id字段是null还是not null,都可以插入空,插入空默认填入default指定的默认值
mysql> create table t3(id int default 1);
mysql> alter table t3 modify id int not null default 1;
unique
============设置唯一约束 UNIQUE=============== 方法一: create table department1( id int, name varchar(20) unique, comment varchar(100) ); 方法二: create table department2( id int, name varchar(20), comment varchar(100), constraint uk_name unique(name) ); mysql> insert into department1 values(1,‘IT‘,‘技术‘); Query OK, 1 row affected (0.00 sec) mysql> insert into department1 values(1,‘IT‘,‘技术‘); ERROR 1062 (23000): Duplicate entry ‘IT‘ for key ‘name‘
create table service(
id int primary key auto_increment,
name varchar(20),
host varchar(15) not null,
port int not null,
unique(host,port) #联合唯一
);
mysql> insert into service values
-> (1,‘nginx‘,‘192.168.0.10‘,80),
-> (2,‘haproxy‘,‘192.168.0.20‘,80),
-> (3,‘mysql‘,‘192.168.0.30‘,3306)
-> ;
Query OK, 3 rows affected (0.01 sec)
Records: 3 Duplicates: 0 Warnings: 0
mysql> insert into service(name,host,port) values(‘nginx‘,‘192.168.0.10‘,80);
ERROR 1062 (23000): Duplicate entry ‘192.168.0.10-80‘ for key ‘host‘
当一个字段被设置为not null和unique时,默认为主键
primary key
primary key字段的值不为空且唯一
一个表中可以:
单列做主键
多列做主键(复合主键)
但一个表内只能有一个主键primary key
============单列做主键===============
#方法一:not null+unique
create table department1(
id int not null unique, #主键
name varchar(20) not null unique,
comment varchar(100)
);
mysql> desc department1;
+---------+--------------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+---------+--------------+------+-----+---------+-------+
| id | int(11) | NO | PRI | NULL | |
| name | varchar(20) | NO | UNI | NULL | |
| comment | varchar(100) | YES | | NULL | |
+---------+--------------+------+-----+---------+-------+
rows in set (0.01 sec)
#方法二:在某一个字段后用primary key
create table department2(
id int primary key, #主键
name varchar(20),
comment varchar(100)
);
mysql> desc department2;
+---------+--------------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+---------+--------------+------+-----+---------+-------+
| id | int(11) | NO | PRI | NULL | |
| name | varchar(20) | YES | | NULL | |
| comment | varchar(100) | YES | | NULL | |
+---------+--------------+------+-----+---------+-------+
rows in set (0.00 sec)
#方法三:在所有字段后单独定义primary key
create table department3(
id int,
name varchar(20),
comment varchar(100),
constraint pk_name primary key(id); #创建主键并为其命名pk_name
mysql> desc department3;
+---------+--------------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+---------+--------------+------+-----+---------+-------+
| id | int(11) | NO | PRI | NULL | |
| name | varchar(20) | YES | | NULL | |
| comment | varchar(100) | YES | | NULL | |
+---------+--------------+------+-----+---------+-------+
rows in set (0.01 sec)
==================多列做主键================
create table service(
ip varchar(15),
port char(5),
service_name varchar(10) not null,
primary key(ip,port)
);
mysql> desc service;
+--------------+-------------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+--------------+-------------+------+-----+---------+-------+
| ip | varchar(15) | NO | PRI | NULL | |
| port | char(5) | NO | PRI | NULL | |
| service_name | varchar(10) | NO | | NULL | |
+--------------+-------------+------+-----+---------+-------+
3 rows in set (0.00 sec)
mysql> insert into service values
-> (‘172.16.45.10‘,‘3306‘,‘mysqld‘),
-> (‘172.16.45.11‘,‘3306‘,‘mariadb‘)
-> ;
Query OK, 2 rows affected (0.00 sec)
Records: 2 Duplicates: 0 Warnings: 0
mysql> insert into service values (‘172.16.45.10‘,‘3306‘,‘nginx‘);
ERROR 1062 (23000): Duplicate entry ‘172.16.45.10-3306‘ for key ‘PRIMARY‘
//alter删除主键约束 alter table t3 drop primary key; //alter添加主键约束 alter table t3 add primary key(name, pwd); //alter 修改列为主键 alter table t3 modify id int primary key;
auto_increment
约束字段为自动增长,被约束的字段必须同时被key约束
#不指定id,则自动增长
create table student(
id int primary key auto_increment,
name varchar(20),
sex enum(‘male‘,‘female‘) default ‘male‘
);
mysql> desc student;
+-------+-----------------------+------+-----+---------+----------------+
| Field | Type | Null | Key | Default | Extra |
+-------+-----------------------+------+-----+---------+----------------+
| id | int(11) | NO | PRI | NULL | auto_increment |
| name | varchar(20) | YES | | NULL | |
| sex | enum(‘male‘,‘female‘) | YES | | male | |
+-------+-----------------------+------+-----+---------+----------------+
mysql> insert into student(name) values
-> (‘egon‘),
-> (‘alex‘)
-> ;
mysql> select * from student;
+----+------+------+
| id | name | sex |
+----+------+------+
| 1 | egon | male |
| 2 | alex | male |
+----+------+------+
#也可以指定id
mysql> insert into student values(4,‘asb‘,‘female‘);
Query OK, 1 row affected (0.00 sec)
mysql> insert into student values(7,‘wsb‘,‘female‘);
Query OK, 1 row affected (0.00 sec)
mysql> select * from student;
+----+------+--------+
| id | name | sex |
+----+------+--------+
| 1 | egon | male |
| 2 | alex | male |
| 4 | asb | female |
| 7 | wsb | female |
+----+------+--------+
#对于自增的字段,在用delete删除后,再插入值,该字段仍按照删除前的位置继续增长
mysql> delete from student;
Query OK, 4 rows affected (0.00 sec)
mysql> select * from student;
Empty set (0.00 sec)
mysql> insert into student(name) values(‘ysb‘);
mysql> select * from student;
+----+------+------+
| id | name | sex |
+----+------+------+
| 8 | ysb | male |
+----+------+------+
#应该用truncate清空表,比起delete一条一条地删除记录,truncate是直接清空表,在删除大表时用它
mysql> truncate student;
Query OK, 0 rows affected (0.01 sec)
mysql> insert into student(name) values(‘egon‘);
Query OK, 1 row affected (0.01 sec)
mysql> select * from student;
+----+------+------+
| id | name | sex |
+----+------+------+
| 1 | egon | male |
+----+------+------+
1 row in set (0.00 sec)
foreign key
员工信息表有三个字段:工号 姓名 部门
公司有3个部门,但是有1个亿的员工,那意味着部门这个字段需要重复存储,部门名字越长,越浪费
解决方法:
我们完全可以定义一个部门表
然后让员工信息表关联该表,如何关联,即foreign key
#表类型必须是innodb存储引擎,且被关联的字段,即references指定的另外一个表的字段,必须保证唯一
create table department(
id int primary key,
name varchar(20) not null
)engine=innodb;
#dpt_id外键,关联父表(department主键id),同步更新,同步删除
create table employee(
id int primary key,
name varchar(20) not null,
dpt_id int,
constraint fk_name foreign key(dpt_id)
references department(id)
on delete cascade
on update cascade
)engine=innodb;
#先往父表department中插入记录
insert into department values
(1,‘欧德博爱技术有限事业部‘),
(2,‘艾利克斯人力资源部‘),
(3,‘销售部‘);
#再往子表employee中插入记录
insert into employee values
(1,‘egon‘,1),
(2,‘alex1‘,2),
(3,‘alex2‘,2),
(4,‘alex3‘,2),
(5,‘李坦克‘,3),
(6,‘刘飞机‘,3),
(7,‘张火箭‘,3),
(8,‘林子弹‘,3),
(9,‘加特林‘,3)
;
#删父表department,子表employee中对应的记录跟着删
mysql> delete from department where id=3;
mysql> select * from employee;
+----+-------+--------+
| id | name | dpt_id |
+----+-------+--------+
| 1 | egon | 1 |
| 2 | alex1 | 2 |
| 3 | alex2 | 2 |
| 4 | alex3 | 2 |
+----+-------+--------+
#更新父表department,子表employee中对应的记录跟着改
mysql> update department set id=22222 where id=2;
mysql> select * from employee;
+----+-------+--------+
| id | name | dpt_id |
+----+-------+--------+
| 1 | egon | 1 |
| 3 | alex2 | 22222 |
| 4 | alex3 | 22222 |
| 5 | alex1 | 22222 |
+----+-------+--------+
两张表之间的关系
分析步骤: #1、先站在左表的角度去找 是否左表的多条记录可以对应右表的一条记录,如果是,则证明左表的一个字段foreign key 右表一个字段(通常是id) #2、再站在右表的角度去找 是否右表的多条记录可以对应左表的一条记录,如果是,则证明右表的一个字段foreign key 左表一个字段(通常是id) #3、总结: #多对一: 如果只有步骤1成立,则是左表多对一右表 如果只有步骤2成立,则是右表多对一左表 #多对多 如果步骤1和2同时成立,则证明这两张表时一个双向的多对一,即多对多,需要定义一个这两张表的关系表来专门存放二者的关系 #一对一: 如果1和2都不成立,而是左表的一条记录唯一对应右表的一条记录,反之亦然。这种情况很简单,就是在左表foreign key右表的基础上,将左表的外键字段设置成unique即可
数据库设计
1.概念
1.有效存储数据
2.满足用户的多种需求
2.关系
1-1 :最少需要1张表
1-n :最少需要2张表
n-n :最少需要3张表
3.数据库三范式
1.保证每列的原子性
2.保证每列都与主键相关
3.保证每列都和主键直接相关,而不能是间接相关
三范式的详解:http://www.cnblogs.com/wangfengming/p/7929118.html
索引
1.概念:相当于书的目录,快速找到数据
好处:可以帮助你提高查询效率,数据量越大越明显
缺点: 新增和删除数据时,效率较低
2.索引方法:
1.hash 是以key-value 的形式进行索引存储
2.BTree 是以二叉树方式进行索引存储。(默认存储索引类型)
3.索引分类
1. 普通索引 create INDEX name_index on person(name);
2. 唯一索引 create unique INDEX name_age on person(name,age);
3. 主键索引 alter table person MODIFY id int PRIMARY key;
4. 组合索引 create unique INDEX name_age on person(name,age);
5. 全文索引 full text :原理是分词查找
创建 普通索引
CREATE index aaa on ren(p_name) 添加普通索引 注意:index :表示索引 aaa:表示索引的别名, on:表示给哪个表添加索引 ren:表名称,(添加索引的字段,多个字段以","间隔) alter table ren add index aaa(p_name)
创建 唯一索引
CREATE UNIQUE index age on ren(p_age) 添加唯一索引 注意:unique index :表示唯一索引 aaa:表示索引的别名, on:表示给哪个表添加索引 ren:表名称,(添加索引的字段,多个字段以","间隔)
创建 主键索引
alter table 表名 add primary key(id); 添加之间索引 注意:主键索引只能有一个
创建 组合索引
create index id_name on ren (id,name) 添加组合索引 注意: 如上创建组合索引之后,查询: id and name-- 使用索引 id -- 使用索引 name -- 不使用索引