【学习资料】第13期快速入门PostgreSQL应用开发与管理 - 3 访问数据

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简介: 大家好,这里是快速入门PostgreSQL应用开发与管理 - 3 访问数据

背景


在线SQL平台

http://www.sqlfiddle.com/

 

本章大纲

 

1. 使用PSQL

 

2. 使用Select语句

 

3. 使用游标

 

4. 行表达式

 

5. with和递归查询

 

6. 执行DML\DDL\DCL

 

7. 选择行

 

8. 使用序列

 

9. 使用默认值

 

10. 生成数据

 

11. 检查空值(NULL

 

12. 时间和日期

 

13. 多个表协同工作

 

第一章: 访问数据

 

1. 使用PSQL

psql PostgreSQL软件包中的命令行工具,可以连接数据库,执行SQL

psql 详细用法参考

psql --help  

 

or  

 

man psql  

psql的选项

psql --help  

psql is the PostgreSQL interactive terminal.  

 

Usage:  

 psql [OPTION]... [DBNAME [USERNAME]]  

 

General options:  

 -c, --command=COMMAND    run only single command (SQL or internal) and exit  

 -d, --dbname=DBNAME      database name to connect to (default: "postgres")  

 -f, --file=FILENAME      execute commands from file, then exit  

 -l, --list               list available databases, then exit  

 -v, --set=, --variable=NAME=VALUE  

                          set psql variable NAME to VALUE  

                          (e.g., -v ON_ERROR_STOP=1)  

 -V, --version            output version information, then exit  

 -X, --no-psqlrc          do not read startup file (~/.psqlrc)  

 -1 ("one"), --single-transaction  

                          execute as a single transaction (if non-interactive)  

 -?, --help[=options]     show this help, then exit  

     --help=commands      list backslash commands, then exit  

     --help=variables     list special variables, then exit  

 

Input and output options:  

 -a, --echo-all           echo all input from script  

 -b, --echo-errors        echo failed commands  

 -e, --echo-queries       echo commands sent to server  

 -E, --echo-hidden        display queries that internal commands generate  

 -L, --log-file=FILENAME  send session log to file  

 -n, --no-readline        disable enhanced command line editing (readline)  

 -o, --output=FILENAME    send query results to file (or |pipe)  

 -q, --quiet              run quietly (no messages, only query output)  

 -s, --single-step        single-step mode (confirm each query)  

 -S, --single-line        single-line mode (end of line terminates SQL command)  

 

Output format options:  

 -A, --no-align           unaligned table output mode  

 -F, --field-separator=STRING  

                          field separator for unaligned output (default: "|")

 -H, --html               HTML table output mode  

 -P, --pset=VAR[=ARG]     set printing option VAR to ARG (see \pset command)  

 -R, --record-separator=STRING  

                          record separator for unaligned output (default: newline)  

 -t, --tuples-only        print rows only  

 -T, --table-attr=TEXT    set HTML table tag attributes (e.g., width, border)  

 -x, --expanded           turn on expanded table output  

 -z, --field-separator-zero  

                          set field separator for unaligned output to zero byte  

 -0, --record-separator-zero  

                          set record separator for unaligned output to zero byte  

 

Connection options:  

 -h, --host=HOSTNAME      database server host or socket directory (default: "127.0.0.1")  

 -p, --port=PORT          database server port (default: "1921")  

 -U, --username=USERNAME  database user name (default: "postgres")  

 -w, --no-password        never prompt for password  

 -W, --password           force password prompt (should happen automatically)  

 

For more information, type "\?" (for internal commands) or "\help" (for SQL  

commands) from within psql, or consult the psql section in the PostgreSQL  

documentation.  

 

Report bugs to <pgsql-bugs@postgresql.org>.

使用psql连接数据库例子

psql -h 127.0.0.1 -p 1921 -U postgres -d postgres

psql (9.6.1)  

Type "help" for help.  

 

postgres=#  

2. 使用Select语句

psql 支持输出帮助文档,例如select 子句的语法

postgres=# \h select  

Command:     SELECT

Description: retrieve rows from a table or view  

Syntax:  

[ WITH [ RECURSIVE ] with_query [, ...] ]  

SELECT [ ALL | DISTINCT [ ON ( expression [, ...] ) ] ]  

   [ * | expression [ [ AS ] output_name ] [, ...] ]  

   [ FROM from_item [, ...] ]  

   [ WHERE condition ]  

   [ GROUP BY grouping_element [, ...] ]  

   [ HAVING condition [, ...] ]  

   [ WINDOW window_name AS ( window_definition ) [, ...] ]  

   [ { UNION | INTERSECT | EXCEPT } [ ALL | DISTINCT ] select ]  

   [ ORDER BY expression [ ASC | DESC | USING operator ] [ NULLS { FIRST | LAST } ] [, ...] ]

   [ LIMIT { count | ALL } ]  

   [ OFFSET start [ ROW | ROWS ] ]  

   [ FETCH { FIRST | NEXT } [ count ] { ROW | ROWS } ONLY ]  

   [ FOR { UPDATE | NO KEY UPDATE | SHARE | KEY SHARE } [ OF table_name [, ...] ] [ NOWAIT | SKIP LOCKED ] [...] ]  

 

where from_item can be one of:  

 

   [ ONLY ] table_name [ * ] [ [ AS ] alias [ ( column_alias [, ...] ) ] ]  

               [ TABLESAMPLE sampling_method ( argument [, ...] ) [ REPEATABLE ( seed ) ] ]

   [ LATERAL ] ( select ) [ AS ] alias [ ( column_alias [, ...] ) ]  

   with_query_name [ [ AS ] alias [ ( column_alias [, ...] ) ] ]  

   [ LATERAL ] function_name ( [ argument [, ...] ] )  

               [ WITH ORDINALITY ] [ [ AS ] alias [ ( column_alias [, ...] ) ] ]  

   [ LATERAL ] function_name ( [ argument [, ...] ] ) [ AS ] alias ( column_definition [, ...] )  

   [ LATERAL ] function_name ( [ argument [, ...] ] ) AS ( column_definition [, ...] )

   [ LATERAL ] ROWS FROM( function_name ( [ argument [, ...] ] ) [ AS ( column_definition [, ...] ) ] [, ...] )  

               [ WITH ORDINALITY ] [ [ AS ] alias [ ( column_alias [, ...] ) ] ]  

   from_item [ NATURAL ] join_type from_item [ ON join_condition | USING ( join_column [, ...] ) ]  

 

and grouping_element can be one of:  

 

   ( )  

   expression

   ( expression [, ...] )  

   ROLLUP ( { expression | ( expression [, ...] ) } [, ...] )  

   CUBE ( { expression | ( expression [, ...] ) } [, ...] )  

   GROUPING SETS ( grouping_element [, ...] )  

 

and with_query is:  

 

   with_query_name [ ( column_name [, ...] ) ] AS ( select | values | insert | update | delete )  

 

TABLE [ ONLY ] table_name [ * ]  

目标、源别名

postgres=# select 'nihao' as col_alias -- 列别名  

          from pg_class as t 源别名  

          limit 1;  

col_alias  

-----------  

nihao  

(1 row)  

select 目标

字段、函数、表达式、子查询

postgres=# select relname, -- 列名  

                 now(), -- 函数  

                upper(relname)||'__digoal',   -- 表达式  

                 (select 1+2+3)  -- 子查询  

                 from pg_class limit 2;  

    relname    |              now              |        ?column?         | ?column?  

-----------------+-------------------------------+-------------------------+----------  

pg_type        | 2017-04-11 15:09:45.440779+08 | PG_TYPE__digoal         |        6

pg_toast_187550 | 2017-04-11 15:09:45.440779+08 | PG_TOAST_187550__digoal |        6

(2 rows)  

select

表、视图、物化视图、函数、表达式、子查询

select * from pg_class;  

 

select * from 视图;  

 

select * from 物化视图;  

 

select * from 函数(参数);  -- 如果函数返回的是record,需要格式化  

 

select * from 函数(参数) as t(1 类型1, ... ,n 类型n);  -- 如果函数返回的是record,需要格式化  

 

select函数(参数);  

 

select函数(参数) as t(1 类型1, ... ,n 类型n);  

 

select表达式;  

 

select (子查询) as t;  

select where条件

postgres=# select relname,reltuples from pg_class where relname='pg_class';  

relname | reltuples  

----------+-----------  

pg_class |       360

(1 row)  

select 排序

postgres=# select oid,relname from pg_class order by oid limit 1;  

oid |              relname                

-----+-----------------------------------  

112 | pg_foreign_data_wrapper_oid_index  

(1 row)  

select 随机排序

postgres=# select oid,relname from pg_class order by random() limit 1;  

 oid |  relname    

-------+-----------  

13124 | sql_parts  

(1 row)  

select 分组

postgres=# select relkind,count(*) from pg_class group by relkind;  

relkind | count  

---------+-------  

f      |     1  

c      |     2  

t      |    28  

S      |     3  

i      |   149  

r      |    80  

v      |   115  

(7 rows)  

select 限制输出条数

postgres=# select relkind,count(*) from pg_class group by relkind limit 1;  

relkind | count  

---------+-------  

f      |     1  

(1 row)  

select 位移

postgres=# select relkind,count(*) from pg_class group by relkind order by relkind offset 1 limit 1;  

relkind | count  

---------+-------  

c      |     2  

(1 row)  

select 当前表以及所有继承表

postgres=# create table p(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# create table c1(id int, info text, crt_time timestamp) inherits(p);  

NOTICE:  merging column "id" with inherited definition  

NOTICE:  merging column "info" with inherited definition  

NOTICE:  merging column "crt_time" with inherited definition  

CREATE TABLE  

postgres=# create table c2(id int, info text, crt_time timestamp) inherits(p);  

NOTICE:  merging column "id" with inherited definition  

NOTICE:  merging column "info" with inherited definition  

NOTICE:  merging column "crt_time" with inherited definition  

CREATE TABLE  

postgres=# create table cc1(id int, info text, crt_time timestamp) inherits(c1);  

NOTICE:  merging column "id" with inherited definition  

NOTICE:  merging column "info" with inherited definition  

NOTICE:  merging column "crt_time" with inherited definition  

CREATE TABLE  

postgres=# insert into p values (1,'p',now());  

INSERT 0 1  

postgres=# insert into c1 values (1,'c1',now());  

INSERT 0 1  

postgres=# insert into c2 values (1,'c2',now());  

INSERT 0 1  

postgres=# insert into cc1 values (1,'cc1',now());  

INSERT 0 1  

postgres=# select * from p;  

id | info |          crt_time            

----+------+----------------------------  

 1 | p   | 2017-04-11 15:37:01.157824  

 1 | c1  | 2017-04-11 15:37:05.635794  

 1 | c2  | 2017-04-11 15:37:11.271823  

 1 | cc1 | 2017-04-11 15:37:16.177828  

(4 rows)  

 

postgres=# select tableoid::regclass,* from p;  

tableoid | id | info |          crt_time            

----------+----+------+----------------------------  

p       |  1 | p    | 2017-04-11 15:37:01.157824  

c1      |  1 | c1   | 2017-04-11 15:37:05.635794  

c2      |  1 | c2   | 2017-04-11 15:37:11.271823  

cc1     |  1 | cc1  | 2017-04-11 15:37:16.177828  

(4 rows)  

select 当前表

postgres=# select tableoid::regclass,* from  only p;  

tableoid | id | info |          crt_time            

----------+----+------+----------------------------  

p       |  1 | p    | 2017-04-11 15:37:01.157824  

(1 row)  

 

postgres=# select tableoid::regclass,* from  only c1;  

tableoid | id | info |          crt_time            

----------+----+------+----------------------------  

c1      |  1 | c1   | 2017-04-11 15:37:05.635794  

(1 row)  

 

3. 使用游标

创建游标

postgres=# begin;  

BEGIN  

postgres=# \h declare  

Command:     DECLARE

Description: define a cursor  

Syntax:  

DECLARE name [ BINARY ] [ INSENSITIVE ] [ [ NO ] SCROLL ]  

   CURSOR [ { WITH | WITHOUT } HOLD ] FOR query  

 

postgres=# declare cur1 cursor for select oid,relname,relkind from pg_class;  

DECLARE CURSOR  

fetch 游标

postgres=# \h fetch  

Command:     FETCH

Description: retrieve rows from a query using a cursor

Syntax:  

FETCH [ direction [ FROM | IN ] ] cursor_name  

 

where direction can be empty or one of:  

 

   NEXT

   PRIOR

   FIRST

   LAST

   ABSOLUTE count  

   RELATIVE count  

   count

   ALL  

   FORWARD

   FORWARD count  

   FORWARD ALL

   BACKWARD

   BACKWARD count  

   BACKWARD ALL

 

postgres=# fetch 2 from cur1;  

 oid  |     relname     | relkind  

--------+-----------------+---------  

  1247 | pg_type         | r

187553 | pg_toast_187550 | t  

(2 rows)  

关闭游标

postgres=# \h close  

Command:     CLOSE

Description: close a cursor  

Syntax:  

CLOSE { name | ALL }  

 

postgres=# close cur1;  

CLOSE CURSOR  

 

4. 行表达式

行表达式

postgres=# select * from (values(1,'test1'),(2,'test2'),(3,'test3')) as t(id, info);  

id | info  

----+-------  

 1 | test1

 2 | test2

 3 | test3

(3 rows)  

 

5. with和递归查询

with语句

postgres=# with  

a as (select * from (values(1,'test1'),(2,'test2'),(3,'test3')) as t(id, info)),  

b as (select oid,relname,relkind from pg_class)  

select a.*,b.* from a,b where a.id=mod(b.oid::int,3)+1;  

 

id | info |  oid   |                    relname                    | relkind  

----+-------+--------+-----------------------------------------------+---------  

 3 | test3 |  1247 | pg_type                                       | r  

 3 | test3 | 187553 | pg_toast_187550                               | t  

 3 | test3 | 186725 | new_type                                      | c  

 2 | test2 | 187555 | pg_toast_187550_index                         | i

 3 | test3 | 187550 | test                                          | r  

 3 | test3 | 187559 | pg_toast_187556                               | t  

 2 | test2 | 187561 | pg_toast_187556_index                        | i  

递归语句

 

 

例子

 

postgres=# with recursive a as (select * from (values (1,2),(2,3),(3,4),(4,100),(2,101),(101,104),(3,102),(4,103),(103,105)) as t(id1,id2)),  

tmp as (  

select * from a where id2=105  

union all  

select a.* from a join tmp on (a.id2=tmp.id1)  

)  

select * from tmp;  

id1 | id2  

-----+-----  

103 | 105

  4 | 103

  3 |  4  

  2 |  3  

  1 |  2  

(5 rows)  

 6. 执行DML\DDL\DCL

插入

postgres=# create table tbl1(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# insert into tbl1 (id,info,crt_time) values (1,'test',now());  

INSERT 0 1  

postgres=# select * from tbl1;  

id | info |          crt_time            

----+------+----------------------------  

 1 | test | 2017-04-11 15:30:38.810826  

(1 row)  

批量插入1

postgres=# insert into tbl1 (id, info ,crt_time) select generate_series(1,10000),'test',now();  

INSERT 0 10000  

postgres=# select count(*) from tbl1;  

count  

-------  

10001  

(1 row)  

批量插入2

postgres=# insert into tbl1 (id,info,crt_time) values (1,'test',now()), (2,'test2',now()), (3,'test3',now());  

INSERT 0 3  

批量插入3

postgres=# begin;  

BEGIN  

postgres=# insert into tbl1 (id,info,crt_time) values (1,'test',now());  

INSERT 0 1  

postgres=# insert into tbl1 (id,info,crt_time) values (2,'test2',now());  

INSERT 0 1  

postgres=# insert into tbl1 (id,info,crt_time) values (3,'test3',now());  

INSERT 0 1  

postgres=# end;  

COMMIT  

更新

postgres=# update tbl1 set info='new value' where id=1;

UPDATE 4  

有则更新、无则插入

postgres=# create table tbl2(id int primary key, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# insert into tbl2 select generate_series(1,1000),'test',now() on conflict  (id) do update set info=excluded.info, crt_time=excluded.crt_time;  

INSERT 0 1000  

postgres=# insert into tbl2 select generate_series(1,1000),'test',now() on conflict  (id) do update set info=excluded.info, crt_time=excluded.crt_time;  

INSERT 0 1000  

postgres=# insert into tbl2 select generate_series(1,1000),'test',now() on conflict  (id) do nothing;  

INSERT 0 0  

删除数据

postgres=# delete from tbl1 where id=1;  

DELETE 4  

批量更新

update target_table set c2 = t.c2 from (values(1,1),(2,2),(3,3)...(2000,2000)) as t(c1,c2) where target_table.c1=t.c1;

批量删除

delete from target_table using (values(1,1),(2,2),(3,3)...(2000,2000)) as t(c1,c2) where target_table.c1 = t.c1;

truncate(如果要清除全表,建议使用truncate)

注意,请使用DDL锁超时,如果有继承表,并且只想清理当前表,使用ONLY.

建议所有的DDL操作前,都设置锁超时,避免堵塞其他操作。

postgres=# \h truncate  

Command:     TRUNCATE

Description: empty a table or set of tables  

Syntax:  

TRUNCATE [ TABLE ] [ ONLY ] name [ * ] [, ... ]  

   [ RESTART IDENTITY | CONTINUE IDENTITY ] [ CASCADE | RESTRICT ]  

 

postgres=# set lock_timeout = '1s';  -- 设置锁超时  

SET  

postgres=# truncate only tbl1;  -- 清理当前表(不清理继承表)  

TRUNCATE TABLE  

drop

drop表时,如果有依赖对象,想一同删除,可以使用cascade关键字

postgres=# drop table p;  

ERROR:  cannot drop table p because other objects depend on it  

DETAIL:  table c1 depends on table p  

table cc1 depends on table c1  

table c2 depends on table p  

HINT:  Use DROP ... CASCADE to drop the dependent objects too.  

postgres=# drop table p cascade;  

NOTICE:  drop cascades to 3 other objects  

DETAIL:  drop cascades to table c1  

drop cascades to table cc1  

drop cascades to table c2  

DROP TABLE  

alter table修改表

例如添加字段

postgres=# alter table tbl1 add column c1 int;  

ALTER TABLE  

添加字段,并添加默认值(会rewrite table, 不建议对大表这么操作,会很久。大表增加字段和默认值,建议先增加自动,默认值可以异步小批量的UPDATE

postgres=# alter table tbl1 add column c2 int default 100;

ALTER TABLE  

转换兼容类型

postgres=# alter table tbl1 alter column c2 type int2;

ALTER TABLE  

转换不兼容类型

postgres=# create table tbl2(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# insert into tbl2 values (1,'1', now());  

INSERT 0 1  

postgres=# insert into tbl2 values (2,'2a', now());

INSERT 0 1  

 

postgres=# select to_number(info,'9999999999999999999') from tbl2;  

to_number  

-----------  

        1

        2

(2 rows)  

 

postgres=# alter table tbl2 alter column info type int using to_number(info,'9999999999999999999');  

ALTER TABLE  

psql服务端COPY(文件读写在数据库所在服务器)

postgres=# \h copy  

Command:     COPY

Description: copy data between a file and a table  

Syntax:  

COPY table_name [ ( column_name [, ...] ) ]  

   FROM { 'filename' | PROGRAM 'command' | STDIN }  

   [ [ WITH ] ( option [, ...] ) ]  

 

COPY { table_name [ ( column_name [, ...] ) ] | ( query ) }  

   TO { 'filename' | PROGRAM 'command' | STDOUT }  

   [ [ WITH ] ( option [, ...] ) ]  

 

where option can be one of:  

 

   FORMAT format_name  

   OIDS [ boolean ]  

   FREEZE [ boolean ]  

   DELIMITER 'delimiter_character'  

   NULL 'null_string'  

   HEADER [ boolean ]  

   QUOTE 'quote_character'  

   ESCAPE 'escape_character'  

   FORCE_QUOTE { ( column_name [, ...] ) | * }  

   FORCE_NOT_NULL ( column_name [, ...] )  

   FORCE_NULL ( column_name [, ...] )  

   ENCODING 'encoding_name'  

COPY out

postgres=# copy tbl2 to '/tmp/test.csv';  

COPY 2  

COPY in

postgres=# copy tbl2 from '/tmp/test.csv';  

COPY 2  

psql客户端COPY(文件读写在客户端)

COPY in

cat /tmp/test.csv | psql -h 127.0.0.1 -p 1921 -U postgres -d postgres -c "copy tbl2 from stdin"  

COPY 2  

COPY out

psql -h 127.0.0.1 -p 1921 -U postgres -d postgres -c "copy tbl2 to stdout" > /tmp/test.csv  

 

cat /tmp/test.csv  

1       1      2017-04-11 15:48:39.728835  

2       2      2017-04-11 15:48:44.370834  

1       1      2017-04-11 15:48:39.728835  

2       2      2017-04-11 15:48:44.370834  

1       1      2017-04-11 15:48:39.728835  

2       2      2017-04-11 15:48:44.370834  

软件开发时请使用程序语言对应的驱动接口。

 

7. 选择行

where子句过滤条件

postgres=# select tableoid::regclass,xmin,xmax,cmin,cmax,ctid,relname from pg_class where relname='pg_type';  

tableoid |  xmin   | xmax | cmin | cmax | ctid  | relname  

----------+----------+------+------+------+-------+---------  

pg_class | 94858157 |    0 |   1 |    1 | (0,3) | pg_type  

(1 row)  

隐藏字段(oid, 插入事务号, 删除事务号, 事务命令偏移值, 行号)

postgres=# select tableoid::regclass,xmin,xmax,cmin,cmax,ctid,relname from pg_class limit 10;  

tableoid |  xmin   | xmax | cmin | cmax |  ctid  |       relname          

----------+----------+------+------+------+--------+-----------------------  

pg_class | 94858157 |    0 |   1 |    1 | (0,3)  | pg_type

pg_class | 94858326 |    0 |   1 |    1 | (0,4)  | pg_toast_187550  

pg_class | 94858205 |    0 | 232 |  232 | (0,5)  | new_type

pg_class | 94858326 |    0 |   2 |    2 | (0,6)  | pg_toast_187550_index  

pg_class | 94858326 |    0 |   4 |    4 | (0,7)  | test

pg_class | 95516401 |    0 |   1 |    1 | (0,9)  | pg_toast_187556  

pg_class | 95516401 |    0 |   2 |    2 | (0,10) | pg_toast_187556_index  

pg_class | 95516401 |    0 |   4 |    4 | (0,11) | tblaccount4  

pg_class |    1726 |    0 |    2 |   2 | (0,20) | hints_id_seq  

pg_class |    1726 |    0 |    5 |   5 | (0,22) | pg_toast_17134  

(10 rows)  

 

8. 使用序列

PostgreSQL允许创建多个序列,每个序列独立自主,有自己的取值空间。

序列一旦消耗掉,就无法回退,除非设置它。

序列通常用来表示唯一自增值。

创建序列

postgres=# \h create sequence  

Command:     CREATE SEQUENCE  

Description: define a new sequence generator  

Syntax:  

CREATE [ TEMPORARY | TEMP ] SEQUENCE [ IF NOT EXISTS ] name [ INCREMENT [ BY ] increment ]  

   [ MINVALUE minvalue | NO MINVALUE ] [ MAXVALUE maxvalue | NO MAXVALUE ]  

   [ START [ WITH ] start ] [ CACHE cache ] [ [ NO ] CYCLE ]  

   [ OWNED BY { table_name.column_name | NONE } ]  

 

postgres=# create sequence seq;  

CREATE SEQUENCE  

获取序列值

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

      1

(1 row)  

 

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

      2

(1 row)  

读取序列当前状态

postgres=# select * from seq;  

sequence_name | last_value | start_value | increment_by |      max_value      | min_value | cache_value | log_cnt | is_cycled | is_called  

---------------+------------+-------------+--------------+---------------------+-----------+-------------+---------+-----------+-----------  

seq          |          2 |           1 |            1 | 9223372036854775807 |         1 |           1 |      31 | f         | t

(1 row)  

读取当前会话,上一次获取的序列值

postgres=# select * from currval('seq'::regclass);  

currval  

---------  

      2

(1 row)  

设置序列起始值

postgres=# \h alter sequence  

Command:     ALTER SEQUENCE  

Description: change the definition of a sequence generator

Syntax:  

ALTER SEQUENCE [ IF EXISTS ] name [ INCREMENT [ BY ] increment ]  

   [ MINVALUE minvalue | NO MINVALUE ] [ MAXVALUE maxvalue | NO MAXVALUE ]  

   [ START [ WITH ] start ]  

   [ RESTART [ [ WITH ] restart ] ]  

   [ CACHE cache ] [ [ NO ] CYCLE ]  

   [ OWNED BY { table_name.column_name | NONE } ]

 

postgres=# alter sequence seq restart with 1;  

ALTER SEQUENCE  

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

      1

(1 row)  

设置序列是否轮回

postgres=# alter sequence seq cycle;  

ALTER SEQUENCE  

设置序列的cache值,提升性能,每个会话,一次会获取一个CACHEVALUE

postgres=# alter sequence seq cache 10000;  

ALTER SEQUENCE  

设置序列的步调

postgres=# alter sequence seq increment by 99;  

ALTER SEQUENCE  

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

    100

(1 row)  

 

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

    199

(1 row)  

修改序列的nextval(restart效果一样)

postgres=# select setval('seq'::regclass, 1);  

setval  

--------  

     1  

(1 row)  

 

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

    100

(1 row)  

 

postgres=# select nextval('seq'::regclass);  

nextval  

---------  

    199

(1 row)  

serial2,serial4,serial8类型

这三个类型,对应int2,int4,int8,同时会自动创建序列,并将默认值设置为序列值。

postgres=# create table tbl3(id serial2);  

CREATE TABLE  

postgres=# \d+ tbl3  

                                           Table "public.tbl3"  

Column |  Type   |                     Modifiers                     | Storage | Stats target | Description  

--------+----------+---------------------------------------------------+---------+--------------+-------------  

id     | smallint | not null default nextval('tbl3_id_seq'::regclass) | plain   |              |  

 

9. 使用默认值

postgres=# create table tbl4(id int, info text, crt_time timestamp default now());  

CREATE TABLE  

 

postgres=# insert into tbl4 (id, info) values (1,'test');

INSERT 0 1  

postgres=# select * from tbl4;  

id | info |          crt_time            

----+------+----------------------------  

 1 | test | 2017-04-11 16:08:12.232796  

(1 row)  

 

10. 生成数据

PostgreSQL 的函数支持返回多条记录,使用这种方法可以很方便的生成测试数据。

postgres=# \df generate_series  

                                                             List of functions  

  Schema  |      Name       |        Result data type          |                        Argument data types                         |  Type  

------------+-----------------+-----------------------------------+--------------------------------------------------------------------+--------  

pg_catalog | generate_series | SETOF bigint                      | bigint, bigint                                                    | normal  

pg_catalog | generate_series | SETOF bigint                      | bigint, bigint, bigint                                             | normal  

pg_catalog | generate_series | SETOF integer                     | integer, integer                                                  | normal  

pg_catalog | generate_series | SETOF integer                     | integer, integer, integer                                          | normal  

pg_catalog | generate_series | SETOF numeric                     | numeric, numeric                                                  | normal  

pg_catalog | generate_series | SETOF numeric                     | numeric, numeric, numeric                                          | normal  

pg_catalog | generate_series | SETOF timestamp with time zone    | timestamp with time zone, timestamp with time zone, interval      | normal  

pg_catalog | generate_series | SETOF timestamp without time zone | timestamp without time zone, timestamp without time zone, interval | normal  

(8 rows)  

插入1万条测试数据

postgres=# create table tbl5(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# insert into tbl5 select id, md5(random()::text), clock_timestamp() from generate_series(1,10000) t(id);  

INSERT 0 10000  

postgres=# select * from tbl5 limit 10;  

id |               info               |          crt_time            

----+----------------------------------+----------------------------  

 1 | 1b9e90de0b1236339503a9a79b13dd55 | 2017-04-11 16:11:07.106191  

 2 | c43a151d1a7df9d587488ca5ac4df7c3 | 2017-04-11 16:11:07.106326  

 3 | 789ec7d6feb1cdac55f252cc17ef8bf1 | 2017-04-11 16:11:07.106335  

 4 | 1c229df1e6b2aa344bee239b91b9c1af | 2017-04-11 16:11:07.10634  

 5 | 88d95fc422a28361292201dc7f648a54 | 2017-04-11 16:11:07.106345  

 6 | 3f8f88d9a69fdd92062a8bd9e49e5a6a | 2017-04-11 16:11:07.10635  

 7 | b66c5c9b46eef16e28e9d909442cb675 | 2017-04-11 16:11:07.106355  

 8 | 2a28d6a7b760821d826d6fc4891fa167 | 2017-04-11 16:11:07.106361  

 9 | 3fd0ec10c7068b83646b1920e4f97319 | 2017-04-11 16:11:07.106366  

10 | d0544855ee8f926c5e5ee821e3932344 | 2017-04-11 16:11:07.106371  

(10 rows)  

其他生产数据的方法

pgbench 压测生成tpc-B测试数据

pgbench -i -s 10  

NOTICE:  table "pgbench_history" does not exist, skipping  

NOTICE:  table "pgbench_tellers" does not exist, skipping  

NOTICE:  table "pgbench_accounts" does not exist, skipping  

NOTICE:  table "pgbench_branches" does not exist, skipping  

creating tables...  

100000 of 1000000 tuples (10%) done (elapsed 0.08 s, remaining 0.74 s)  

200000 of 1000000 tuples (20%) done (elapsed 0.19 s, remaining 0.75 s)  

300000 of 1000000 tuples (30%) done (elapsed 0.30 s, remaining 0.69 s)  

400000 of 1000000 tuples (40%) done (elapsed 0.41 s, remaining 0.61 s)  

500000 of 1000000 tuples (50%) done (elapsed 0.51 s, remaining 0.51 s)  

600000 of 1000000 tuples (60%) done (elapsed 0.62 s, remaining 0.41 s)  

700000 of 1000000 tuples (70%) done (elapsed 0.72 s, remaining 0.31 s)  

800000 of 1000000 tuples (80%) done (elapsed 0.84 s, remaining 0.21 s)  

900000 of 1000000 tuples (90%) done (elapsed 0.95 s, remaining 0.11 s)  

1000000 of 1000000 tuples (100%) done (elapsed 1.06 s, remaining 0.00 s)  

vacuum...  

set primary keys...  

done.  

pgbench 压测, 使用脚本生成测试数据

postgres=# create table tbl6(id int ,info text, crt_time timestamp);  

CREATE TABLE  

 

vi test.sql  

\set id random(1,10000000)  

insert into tbl6 values (:id, md5(random()::text), now());  

 

pgbench -M prepared -n -r -f ./test.sql -P 1 -c 32 -j 32 -t 1000  

transaction type: ./test.sql  

scaling factor: 1  

query mode: prepared  

number of clients: 32  

number of threads: 32  

number of transactions per client: 1000  

number of transactions actually processed: 32000/32000

latency average = 0.111 ms  

latency stddev = 0.355 ms  

tps = 257806.709420 (including connections establishing)  

tps = 265264.082829 (excluding connections establishing)  

script statistics:  

- statement latencies in milliseconds:  

        0.001 \set id random(1,10000000)  

        0.111 insert into tbl6 values (:id, md5(random()::text), now());  

do 编程

postgres=# do language plpgsql $$  

declare  

begin  

 for i in 1..100 loop  

   insert into tbl6 select mod(id,i), md5(random()::text), clock_timestamp() from generate_series(1,1000) t(id);  

 end loop;

end;  

$$;  

DO  

plpgsql 编程

create or replace function func_test() returns void as $$  

declare  

begin  

...  

end;  

$$ language plpgsql strict;  

 

11. 检查空值(NULL

判断空值

is null

postgres=# select 1 where null is null;  

?column?  

----------  

       1

(1 row)  

is not null

postgres=# select 1 where null is not null;  

?column?  

----------  

(0 rows)  

 

postgres=# select 1 where 'a' is not null;  

?column?  

----------  

       1

(1 row)  

is distinct from null

postgres=# select 1 where 'a' is distinct from null;

?column?  

----------  

       1

(1 row)  

 

postgres=# select 1 where null is distinct from null;

?column?  

----------  

(0 rows)  

 

postgres=# select 1 where null is not distinct from null;

?column?  

----------  

       1

(1 row)  

is distinct from is not distinct from 可以用于两张表的JOIN,如果希望NULLNULL相连,可以使用is not distinct from

postgres=# select 1 where 'a'='a';  

?column?  

----------  

       1

(1 row)  

postgres=# select 1 where 'a' is not distinct from 'a';

?column?  

----------  

       1

(1 row)  

 

 

postgres=# select 1 where null=null;  -- 无法关联  

?column?  

----------  

(0 rows)  

 

postgres=# select 1 where null is not distinct from null; -- 可以关联  

?column?  

----------  

       1

(1 row)  

修正空值

postgres=# select coalesce(null,'a');  

coalesce  

----------  

a  

(1 row)  

 

postgres=# select coalesce(null,'a','b');  

coalesce  

----------  

a  

(1 row)  

 

postgres=# select coalesce(null,null,'b');  

coalesce  

----------  

b  

(1 row)  

 

12. 时间和日期

当前日期

postgres=# select current_date;  

   date    

------------  

2017-04-11

(1 row)  

事务时间

postgres=# select current_time;  

      timetz        

--------------------  

16:25:53.179793+08  

(1 row)  

事务timestamp

postgres=# select now();  

             now                

-------------------------------  

2017-04-11 16:25:53.179793+08  

(1 row)  

语句时间

postgres=# select clock_timestamp()::time;  

clock_timestamp  

-----------------  

16:26:57.251972  

(1 row)  

 

postgres=# select statement_timestamp()::time;  

statement_timestamp  

---------------------  

16:27:02.886793  

(1 row)  

 

postgres=# select statement_timestamp()::timetz;  

statement_timestamp  

---------------------  

16:27:06.975794+08  

(1 row)  

 

postgres=# select clock_timestamp()::timetz;  

 clock_timestamp    

--------------------  

16:27:10.199891+08  

(1 row)  

 

语句timestamp

postgres=# select statement_timestamp();  

     statement_timestamp        

-------------------------------

2017-04-11 16:26:42.905786+08  

(1 row)  

 

postgres=# select clock_timestamp();  

       clock_timestamp          

-------------------------------  

2017-04-11 16:26:47.695877+08  

(1 row)  

提取时间中的信息

https://www.postgresql.org/docs/9.6/static/functions-datetime.html

unix epoch time

postgres=# select extract(epoch from now());  

   date_part      

------------------  

1491899255.64279  

(1 row)  

postgres=# SELECT EXTRACT(YEAR from now());  

date_part  

-----------  

     2017

(1 row)  

postgres=# SELECT EXTRACT(month from now());  

date_part  

-----------  

        4

(1 row)  

一年中的第几日

postgres=# SELECT EXTRACT(doy from now());  

date_part  

-----------  

      101

(1 row)  

一年中的第几周

postgres=# SELECT EXTRACT(week from now());  

date_part  

-----------  

       15

(1 row)  

一月中的第几日

postgres=# SELECT EXTRACT(day from now());  

date_part  

-----------  

       11

(1 row)  

一周中的第几日

postgres=# SELECT EXTRACT(dow from now());  

date_part  

-----------  

        2

(1 row)  

 

13. 多个表协同工作

子查询

只能返回一列  

postgres=# select (select * from (values (1,2),(2,3)) as t(c1,c2)) , relname, relkind from pg_class;  

ERROR:  subquery must return only one column  

LINE 1: select (select * from (values (1,2),(2,3)) as t(c1,c2)) , re...  

              ^  

只能返回一条记录  

postgres=# select (select * from (values (1),(2)) as t(c1)) , relname, relkind from pg_class;  

ERROR:  more than one row returned by a subquery used as an expression  

 

postgres=# select (select * from (values (1),(2)) as t(c1) limit 1) , relname, relkind from pg_class;  

c1 |                    relname                    | relkind  

----+-----------------------------------------------+---------  

 1 | pg_type                                       | r  

 1 | pg_toast_187550                               | t  

 1 | new_type                                      | c  

 1 | pg_toast_187550_index                         | i  

 1 | test                                          | r  

 1 | pg_toast_187556                               | t  

 

postgres=# select t.relname from (select * from pg_class limit 1) t , pg_class where t.relname=pg_class.relname;  

relname  

---------  

pg_type

(1 row)  

JOIN

postgres=# select t1.relname,t2.rolname from pg_class t1, pg_authid t2 where t1.relowner=t2.oid limit 10;  

       relname        | rolname    

-----------------------+----------  

pg_type               | postgres  

pg_toast_187550       | postgres  

new_type              | postgres  

pg_toast_187550_index | postgres  

test                  | postgres  

pg_toast_187556       | postgres  

pg_toast_187556_index | postgres  

tblaccount4           | postgres  

hints_id_seq          | postgres  

pg_toast_17134        | postgres  

(10 rows)  

update from

postgres=# create table tbl7(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# create table tbl8(id int, info text, crt_time timestamp);  

CREATE TABLE  

postgres=# insert into tbl7 select generate_series(1,100), 'test', now();  

INSERT 0 100  

postgres=# insert into tbl8 select generate_series(1,100), md5(random()::text), now();  

INSERT 0 100  

postgres=# update tbl7 set info=tbl8.info from tbl8 where tbl7.id=tbl8.id;  

UPDATE 100  

postgres=# select info from tbl7 limit 10;  

              info                

----------------------------------  

4c86016ec0236be89de3ef4f6044b201  

b7a9c835cac248ef0de3003f4f41e57e  

60173e7d7bd328826f48cdf32b74ae96  

dec7041c58dcb367a0ab59c272032d80  

775017af1ec532808e24be24ed9e1593  

67b7326219629ea22d88bdb47e1f4b54  

0da20f68c459518081f4f3c3a58fc088  

21b20b667563a7d67f0a92aae2c64b09  

4074650815e08ddb6f2af8d4b05fd992  

a2cf8866d99361a545b7a96cbb718a9c  

(10 rows)  

相关实践学习
使用PolarDB和ECS搭建门户网站
本场景主要介绍基于PolarDB和ECS实现搭建门户网站。
阿里云数据库产品家族及特性
阿里云智能数据库产品团队一直致力于不断健全产品体系,提升产品性能,打磨产品功能,从而帮助客户实现更加极致的弹性能力、具备更强的扩展能力、并利用云设施进一步降低企业成本。以云原生+分布式为核心技术抓手,打造以自研的在线事务型(OLTP)数据库Polar DB和在线分析型(OLAP)数据库Analytic DB为代表的新一代企业级云原生数据库产品体系, 结合NoSQL数据库、数据库生态工具、云原生智能化数据库管控平台,为阿里巴巴经济体以及各个行业的企业客户和开发者提供从公共云到混合云再到私有云的完整解决方案,提供基于云基础设施进行数据从处理、到存储、再到计算与分析的一体化解决方案。本节课带你了解阿里云数据库产品家族及特性。
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