一.介绍
存储引擎决定了表的类型,而表内存放的数据也要有不同的类型,每种数据类型都有自己的高度,但宽度是可选的。
mysql数据类型概览
#1.数字:(默认都是有符号,宽度指的是显示宽度,与存储无关)
整型:tinyinit int bigint :个数,id, qq号,手机号 小数:float:在位数比较短的情况下不精准 :价格,身高,体重,余额 double:在位数比较长的情况下不精准 #2.字符(宽度指的是字符个数):姓名,性别,职业,地址,职称,介绍 char:简单粗暴,不够则凑够固定长度存起来,浪费空间,存取速度快
varchar:精准,计算出待存放的数据长度,节省空间,存取速度慢
sql优化:创建表时, 定长的类型往前放, 变长的往后放
比如性别 比如地址或者是描述信息 #3.时间类型
#注册时间
最常用:datetime 2017-09-06 10:40:20 #出生年月,开学时间
date:2017-09-06 #聊天记录,上课时间
time:10:40:00 #出生年
year:2017
二.数值类型
整数类型:tinyint smallint mediumint int bigint
作用:存储年龄,等级,id,各种号码等
========================================
tinyint[(m)] [unsigned] [zerofill] 小整数,数据类型用于保存一些范围的整数数值范围:
有符号:
-128 ~ 127
无符号:
~ 255 PS: MySQL中无布尔值,使用tinyint(1)构造。 ========================================
int[(m)][unsigned][zerofill] 整数,数据类型用于保存一些范围的整数数值范围:
有符号:
-2147483648 ~ 2147483647
无符号:
~ 4294967295 ========================================
bigint[(m)][unsigned][zerofill]
大整数,数据类型用于保存一些范围的整数数值范围:
有符号:
-9223372036854775808 ~ 9223372036854775807
无符号:
~ 18446744073709551615
=========有符号和无符号tinyint==========
#tinyint默认为有符号
MariaDB [db1]> create table t1(x tinyint); #默认为有符号,即数字前有正负号
MariaDB [db1]> desc t1;
MariaDB [db1]> insert into t1 values
-> (-129),
-> (-128),
-> (127),
-> (128);
MariaDB [db1]> select * from t1;
+------+
| x |
+------+
| -128 | #-129存成了-128
| -128 | #有符号,最小值为-128
| 127 | #有符号,最大值127
| 127 | #128存成了127
+------+ #设置无符号tinyint
MariaDB [db1]> create table t2(x tinyint unsigned);
MariaDB [db1]> insert into t2 values
-> (-1),
-> (0),
-> (255),
-> (256);
MariaDB [db1]> select * from t2;
+------+
| x |
+------+
| 0 | -1存成了0
| 0 | #无符号,最小值为0
| 255 | #无符号,最大值为255
| 255 | #256存成了255
+------+ ============有符号和无符号int=============
#int默认为有符号
MariaDB [db1]> create table t3(x int); #默认为有符号整数
MariaDB [db1]> insert into t3 values
-> (-2147483649),
-> (-2147483648),
-> (2147483647),
-> (2147483648);
MariaDB [db1]> select * from t3;
+-------------+
| x |
+-------------+
| -2147483648 | #-2147483649存成了-2147483648
| -2147483648 | #有符号,最小值为-2147483648
| 2147483647 | #有符号,最大值为2147483647
| 2147483647 | #2147483648存成了2147483647
+-------------+ #设置无符号int
MariaDB [db1]> create table t4(x int unsigned);
MariaDB [db1]> insert into t4 values
-> (-1),
-> (0),
-> (4294967295),
-> (4294967296);
MariaDB [db1]> select * from t4;
+------------+
| x |
+------------+
| 0 | #-1存成了0
| 0 | #无符号,最小值为0
| 4294967295 | #无符号,最大值为4294967295
| 4294967295 | #4294967296存成了4294967295
+------------+ ==============有符号和无符号bigint=============
MariaDB [db1]> create table t6(x bigint);
MariaDB [db1]> insert into t5 values
-> (-9223372036854775809),
-> (-9223372036854775808),
-> (9223372036854775807),
-> (9223372036854775808); MariaDB [db1]> select * from t5;
+----------------------+
| x |
+----------------------+
| -9223372036854775808 |
| -9223372036854775808 |
| 9223372036854775807 |
| 9223372036854775807 |
+----------------------+ MariaDB [db1]> create table t6(x bigint unsigned);
MariaDB [db1]> insert into t6 values
-> (-1),
-> (0),
-> (18446744073709551615),
-> (18446744073709551616); MariaDB [db1]> select * from t6;
+----------------------+
| x |
+----------------------+
| 0 |
| 0 |
| 18446744073709551615 |
| 18446744073709551615 |
+----------------------+ ======用zerofill测试整数类型的显示宽度=============
MariaDB [db1]> create table t7(x int(3) zerofill);
MariaDB [db1]> insert into t7 values
-> (1),
-> (11),
-> (111),
-> (1111);
MariaDB [db1]> select * from t7;
+------+
| x |
+------+
| 001 |
| 011 |
| 111 |
| 1111 | #超过宽度限制仍然可以存
+------+ 验证
验证
!!!注意:为该类型指定宽度时,仅仅只是指定查询结果的显示宽度,与存储范围无关,存储范围如下
其实我们完全没必要为整数类型指定显示宽度,使用默认的就可以了
默认的显示宽度,都是在最大值的基础上加1
int的存储宽度是4个Bytes,即32个bit,即2**32
无符号最大值为:4294967296-1
有符号最大值:2147483648-1
有符号和无符号的最大数字需要的显示宽度均为10,而针对有符号的最小值则需要11位才能显示完全,所以int类型默认的显示宽度为11是非常合理的
最后:整形类型,其实没有必要指定显示宽度,使用默认的就ok
定点数类型 DEC等同于DECIMAL
浮点类型:FLOAT DOUBLE
作用:存储薪资、身高、体重、体质参数等
int的存储宽度是4个Bytes,即32个bit,即2**32 无符号最大值为:4294967296-1 有符号最大值:2147483648-1 有符号和无符号的最大数字需要的显示宽度均为10,而针对有符号的最小值则需要11位才能显示完全,所以int类型默认的显示宽度为11是非常合理的 最后:整形类型,其实没有必要指定显示宽度,使用默认的就ok 定点数类型 DEC等同于DECIMAL 浮点类型:FLOAT DOUBLE 作用:存储薪资、身高、体重、体质参数等
MariaDB [db1]> create table t8(salary float(5,2)); #总共5位,小数部分占2位,因而整数部分最多3位
MariaDB [db1]> insert into t8 values
-> (3.3),
-> (7.33),
-> (9.335),
-> (1000.1);
MariaDB [db1]> select * from t8;
+--------+
| salary |
+--------+
| 3.30 |
| 7.33 |
| 9.34 | #4舍5入
| 999.99 | #小数最多2位,整数最多3位
+--------+
验证
位类型:BIT
BIT(M)可以用来存放多位二进制数,M范围从1~64,如果不写默认为1位。
注意:对于位字段需要使用函数读取
bin()显示为二进制
hex()显示为十六进制
MariaDB [db1]> create table t9(id bit);
MariaDB [db1]> desc t9; #bit默认宽度为1
+-------+--------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+-------+--------+------+-----+---------+-------+
| id | bit(1) | YES | | NULL | |
+-------+--------+------+-----+---------+-------+ MariaDB [db1]> insert into t9 values(8);
MariaDB [db1]> select * from t9; #直接查看是无法显示二进制位的
+------+
| id |
+------+
| |
+------+
MariaDB [db1]> select bin(id),hex(id) from t9; #需要转换才能看到
+---------+---------+
| bin(id) | hex(id) |
+---------+---------+
| 1 | 1 |
+---------+---------+ MariaDB [db1]> alter table t9 modify id bit(5);
MariaDB [db1]> insert into t9 values(8);
MariaDB [db1]> select bin(id),hex(id) from t9;
+---------+---------+
| bin(id) | hex(id) |
+---------+---------+
| 1 | 1 |
| 1000 | 8 |
+---------+---------+
验证
三.日期类型
date time ,datetime , timestamp ,year
作用:存储用户注册时间,文章发布时间,员工入职时间,出生时间,过期时间等
YEAR
YYYY(1901/2155) DATE
YYYY-MM-DD(1000-01-01/9999-12-31) TIME
HH:MM:SS('-838:59:59'/'838:59:59') DATETIME YYYY-MM-DD HH:MM:SS(1000-01-01 00:00:00/9999-12-31 23:59:59 Y) TIMESTAMP YYYYMMDD HHMMSS(1970-01-01 00:00:00/2037 年某时)
============year===========
MariaDB [db1]> create table t10(born_year year); #无论year指定何种宽度,最后都默认是year(4)
MariaDB [db1]> insert into t10 values
-> (1900),
-> (1901),
-> (2155),
-> (2156);
MariaDB [db1]> select * from t10;
+-----------+
| born_year |
+-----------+
| 0000 |
| 1901 |
| 2155 |
| 0000 |
+-----------+ ============date,time,datetime===========
MariaDB [db1]> create table t11(d date,t time,dt datetime);
MariaDB [db1]> desc t11;
+-------+----------+------+-----+---------+-------+
| Field | Type | Null | Key | Default | Extra |
+-------+----------+------+-----+---------+-------+
| d | date | YES | | NULL | |
| t | time | YES | | NULL | |
| dt | datetime | YES | | NULL | |
+-------+----------+------+-----+---------+-------+ MariaDB [db1]> insert into t11 values(now(),now(),now());
MariaDB [db1]> select * from t11;
+------------+----------+---------------------+
| d | t | dt |
+------------+----------+---------------------+
| 2017-07-25 | 16:26:54 | 2017-07-25 16:26:54 |
+------------+----------+---------------------+ ============timestamp===========
MariaDB [db1]> create table t12(time timestamp);
MariaDB [db1]> insert into t12 values();
MariaDB [db1]> insert into t12 values(null);
MariaDB [db1]> select * from t12;
+---------------------+
| time |
+---------------------+
| 2017-07-25 16:29:17 |
| 2017-07-25 16:30:01 |
+---------------------+ ============注意啦,注意啦,注意啦===========
1. 单独插入时间时,需要以字符串的形式,按照对应的格式插入
2. 插入年份时,尽量使用4位值
3. 插入两位年份时,<=69,以20开头,比如50, 结果2050
>=70,以19开头,比如71,结果1971
MariaDB [db1]> create table t12(y year);
MariaDB [db1]> insert into t12 values
-> (50),
-> (71);
MariaDB [db1]> select * from t12;
+------+
| y |
+------+
| 2050 |
| 1971 |
+------+ ============综合练习===========
MariaDB [db1]> create table student(
-> id int,
-> name varchar(20),
-> born_year year,
-> birth date,
-> class_time time,
-> reg_time datetime); MariaDB [db1]> insert into student values
-> (1,'alex',"","1995-11-11","11:11:11","2017-11-11 11:11:11"),
-> (2,'egon',"","1997-12-12","12:12:12","2017-12-12 12:12:12"),
-> (3,'wsb',"","1998-01-01","13:13:13","2017-01-01 13:13:13"); MariaDB [db1]> select * from student;
+------+------+-----------+------------+------------+---------------------+
| id | name | born_year | birth | class_time | reg_time |
+------+------+-----------+------------+------------+---------------------+
| 1 | alex | 1995 | 1995-11-11 | 11:11:11 | 2017-11-11 11:11:11 |
| 2 | egon | 1997 | 1997-12-12 | 12:12:12 | 2017-12-12 12:12:12 |
| 3 | wsb | 1998 | 1998-01-01 | 13:13:13 | 2017-01-01 13:13:13 |
+------+------+-----------+------------+------------+---------------------+
验证
在实际应用的很多场景中,MySQL的这两种日期类型都能够满足我们的需要,存储精度都为秒,但在某些情况下,会展现出他们各自的优劣。下面就来总结一下两种日期类型的区别。 1.DATETIME的日期范围是1001——9999年,TIMESTAMP的时间范围是1970——2038年。 2.DATETIME存储时间与时区无关,TIMESTAMP存储时间与时区有关,显示的值也依赖于时区。在mysql服务器,操作系统以及客户端连接都有时区的设置。 3.DATETIME使用8字节的存储空间,TIMESTAMP的存储空间为4字节。因此,TIMESTAMP比DATETIME的空间利用率更高。 4.DATETIME的默认值为null;TIMESTAMP的字段默认不为空(not null),默认值为当前时间(CURRENT_TIMESTAMP),如果不做特殊处理,并且update语句中没有指定该列的更新值,则默认更新为当前时间。
datetime与timestamp的区别
四.字符串类型
1. char填充空格来满足固定长度,但是在查询时却会很不要脸地删除尾部的空格(装作自己好像没有浪费过空间一样),然后修改sql_mode让其现出原形
mysql> create table t1(x char(5),y varchar(5));
Query OK, 0 rows affected (0.26 sec) #char存5个字符,而varchar存4个字符
mysql> insert into t1 values('你瞅啥 ','你瞅啥 ');
Query OK, 1 row affected (0.05 sec) mysql> SET sql_mode='';
Query OK, 0 rows affected, 1 warning (0.00 sec) #在检索时char很不要脸地将自己浪费的2个字符给删掉了,装的好像自己没浪费过空间一样,而varchar很老实,存了多少,就显示多少
mysql> select x,char_length(x),y,char_length(y) from t1;
+-----------+----------------+------------+----------------+
| x | char_length(x) | y | char_length(y) |
+-----------+----------------+------------+----------------+
| 你瞅啥 | 3 | 你瞅啥 | 4 |
+-----------+----------------+------------+----------------+
row in set (0.00 sec) #略施小计,让char现出原形
mysql> SET sql_mode = 'PAD_CHAR_TO_FULL_LENGTH';
Query OK, 0 rows affected (0.00 sec) #这下子char原形毕露了......
mysql> select x,char_length(x),y,char_length(y) from t1;
+-------------+----------------+------------+----------------+
| x | char_length(x) | y | char_length(y) |
+-------------+----------------+------------+----------------+
| 你瞅啥 | 5 | 你瞅啥 | 4 |
+-------------+----------------+------------+----------------+
row in set (0.00 sec) #char类型:3个中文字符+2个空格=11Bytes
#varchar类型:3个中文字符+1个空格=10Bytes
mysql> select x,length(x),y,length(y) from t1;
+-------------+-----------+------------+-----------+
| x | length(x) | y | length(y) |
+-------------+-----------+------------+-----------+
| 你瞅啥 | 11 | 你瞅啥 | 10 |
+-------------+-----------+------------+-----------+
row in set (0.00 sec)
2. 虽然 char 和 varchar 的存储方式不太相同,但是对于两个字符串的比较,都只比 较其值,忽略 char值存在的右填充,即使将 sql_mode设置为 pad_char_to_full_ length 也一样,,但这不适用于like
Values in CHAR and VARCHAR columns are sorted and compared according to the character set collation assigned to the column. All MySQL collations are of type PAD SPACE. This means that all CHAR, VARCHAR, and TEXT values are compared without regard to any trailing spaces. “Comparison” in this context does not include the LIKE pattern-matching operator, for which trailing spaces are significant. For example: mysql> CREATE TABLE names (myname CHAR(10));
Query OK, 0 rows affected (0.03 sec) mysql> INSERT INTO names VALUES ('Monty');
Query OK, 1 row affected (0.00 sec) mysql> SELECT myname = 'Monty', myname = 'Monty ' FROM names;
+------------------+--------------------+
| myname = 'Monty' | myname = 'Monty ' |
+------------------+--------------------+
| 1 | 1 |
+------------------+--------------------+
row in set (0.00 sec) mysql> SELECT myname LIKE 'Monty', myname LIKE 'Monty ' FROM names;
+---------------------+-----------------------+
| myname LIKE 'Monty' | myname LIKE 'Monty ' |
+---------------------+-----------------------+
| 1 | 0 |
+---------------------+-----------------------+
row in set (0.00 sec)
3.总结
#常用字符串系列:char与varchar
注:虽然varchar使用起来较为灵活,但是从整个系统的性能角度来说,char数据类型的处理速度更快,有时甚至可以超出varchar处理速度的50%。因此,用户在设计数据库时应当综合考虑各方面的因素,以求达到最佳的平衡 #其他字符串系列(效率:char>varchar>text)
TEXT系列 TINYTEXT TEXT MEDIUMTEXT LONGTEXT
BLOB 系列 TINYBLOB BLOB MEDIUMBLOB LONGBLOB
BINARY系列 BINARY VARBINARY text:text数据类型用于保存变长的大字符串,可以组多到65535 (2**16 − 1)个字符。
mediumtext:A TEXT column with a maximum length of 16,777,215 (2**24 − 1) characters.
longtext:A TEXT column with a maximum length of 4,294,967,295 or 4GB (2**32 − 1) characters.