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SELECT
SELECT statement is used to retrieve records from one or more tables in PostgreSQL.
More about SELECT statement can be found at:
PostgreSQL - https://www.postgresql.org/docs/11/sql-select.html
MySQL - https://dev.mysql.com/doc/refman/8.0/en/select.html
MariaDB - https://mariadb.com/kb/en/library/select/
-
SELECT(expressions...)
- expressions to form output rows of the SELECT statement. -
OPTIMIZER_HINTS(hints...)
- provides a way to optimize query execution per-statement basis (MySQL only) -
DISTINCT()
- remove all duplicate rows from result set -
FROM(tableSource...)
- specifies one or more source tables for the SELECT. -
WHERE(condition)
- only rows for which condition returns true will be selected. -
GROUP BY(groupingElement, ...)
- will condense into a single row all selected rows that share the same values for the grouped expressions. -
HAVING(condition)
- eliminates group rows that do not satisfy the condition -
WINDOW(name)
- starts composing name window definition -
ORDER BY(orderBy, ...)
- causes the result rows to be sorted according to the specified expression(s) -
LIMIT(count)
- specifies the maximum number of rows to return -
OFFSET(start)
- specifies the number of rows to skip before starting to return rows -
FOR(lockMode)
- how SELECT will lock rows as they are obtained from the table
PostgreSQL lock mode can be:UPDATE()
,NO_KEY_UPDATE()
,SHARE()
andKEY_SHARE()
, with optional clauses:NOWAIT()
andSKIP_LOCKED()
.
MySQL lock modes can be:UPDATE()
andSHARE()
, with optional clauses:NOWAIT()
andSKIP_LOCKED()
. -
UNION(select)
/UNION_ALL(select)
- computes the set union of the rows returned by the involved SELECT statements -
INTERSECT(select)
/INTERSECT_ALL(select)
- computes the set intersection of the rows returned by the involved SELECT statements -
EXCEPT(select)
/EXCEPT_ALL(select)
- computes the set of rows that are in the result of the left SELECT statement but not in the result of the right one
This list might be extended with feature Jet releases.
Sample SELECT clause written in Go:
// dot "." import implied
SELECT(
Int(1).ADD(Int(12)).SUB(Int(21)), // arbitrary expression
Film.Name, // column
Customer.FirstName.CONCAT(Customer.LastName).AS("FullName") // alias
)
Above SQL clause in go will produce following raw SQL:
SELECT 1 + 12 - 21,
film.name AS "film.name",
customer.first_name || customer.last_name AS "FullName"
film.name AS "film.name"
- column names are aliased by default. Alias is used during execution to map row result to
appropriate model
structure.
SELECT(Actor.ActorID).
OPTIMIZER_HINTS(MAX_EXECUTION_TIME(1), QB_NAME("mainQueryBlock"), "NO_ICP(actor)")
SELECT /*+ MAX_EXECUTION_TIME(1) QB_NAME(mainQueryBlock) NO_ICP(actor) */ actor.actor_id AS "actor.actor_id"
// Go:
SELECT(Film.Name).
DISTINCT().
// PostgreSQL only
SELECT(Film.Duration, Film.Rating, Film.Name).
DISTINCT(Film.Duration, Film.Rating)
-- SQL:
SELECT DISTINCT film.name AS "film.name"
// PostgreSQL only
SELECT DISTINCT ON (film.duration, film.rating)
film.duration AS "film.duration"
film.rating AS "film.rating"
film.name AS "film.name"
The FROM clause specifies one or more source tables for the SELECT.
Go:
1) .FROM(Film)
2) .FROM(
Film.
INNER_JOIN(Language, Langauge.LanguageID.EQ(Film.FilmID))
)
3) .FROM(Film, Language, Artist) // implicit CROSS JOIN
SQL:
1) FROM dvds.film
2) FROM Film
INNER JOIN Language ON (Language.LanguageID = Film.FilmID)
3) FROM Film, Language, Artists
Go:
.WHERE(Film.Length.GT(Int(150)))
SQL:
WHERE film.length > 150
Go:
1) .GROUP_BY(Film.Length)
// postgres
2) .GROUP_BY(
GROUPING_SETS(
WRAP(Inventory.FilmID, Inventory.StoreID),
WRAP(Inventory.FilmID),
WRAP(),
),
)
3) .GROUP_BY(
CUBE(Country.Country, City.City),
)
4) .GROUP_BY(
ROLLUP(Country.Country, City.City),
)
// mysql
5) .GROUP_BY(
WITH_ROLLUP(Inventory.FilmID, Inventory.StoreID),
)
SQL:
1) GROUP BY film.length
-- postgres
2) GROUP BY GROUPING SETS((inventory.film_id, inventory.store_id), (inventory.film_id), ())
3) GROUP BY CUBE(country.country, city.city)
4) GROUP BY ROLLUP(country.country, city.city)
-- mysql
5) GROUP BY inventory.film_id, inventory.store_id WITH ROLLUP
SELECT(
AVG(Payment.Amount).OVER(),
MINf(Payment.Amount).OVER(PARTITION_BY(Payment.CustomerID).ORDER_BY(Payment.PaymentDate.DESC())),
ROW_NUMBER().OVER(Window("w1")),
RANK().OVER(
Window("w2").
ORDER_BY(Payment.CustomerID).
RANGE(PRECEDING(UNBOUNDED), FOLLOWING(UNBOUNDED)),
),
AVG(Payment.Amount).OVER(Window("w3").ROWS(PRECEDING(1), FOLLOWING(2))),
).
FROM(Payment).
WINDOW("w1").AS(PARTITION_BY(Payment.PaymentDate)).
WINDOW("w2").AS(Window("w1")).
WINDOW("w3").AS(Window("w2").ORDER_BY(Payment.CustomerID)).
SELECT AVG(payment.amount) OVER (),
MIN(payment.amount) OVER (PARTITION BY payment.customer_id ORDER BY payment.payment_date DESC),
ROW_NUMBER() OVER (w1),
RANK() OVER (w2 ORDER BY payment.customer_id RANGE BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING),
AVG(payment.amount) OVER (w3 ROWS BETWEEN 1 PRECEDING AND 2 FOLLOWING)
FROM dvds.payment
WINDOW w1 AS (PARTITION BY payment.payment_date), w2 AS (w1), w3 AS (w2 ORDER BY payment.customer_id);
Go:
.HAVING(SUMi(Film.Length).GT(Int(150))
SQL:
HAVING SUM(film.length) > 150
Go:
.ORDER_BY(Film.Length)
SQL:
ORDER BY film.length
Go:
.LIMIT(11)
SQL:
LIMIT 11
Go:
.OFFSET(11)
SQL:
OFFSET 11
Go:
.FOR(NO_KEY_UPDATE().SKIP_LOCKED())
SQL:
FOR NO KEY UPDATE SKIP LOCKED
Go:
SELECT(Payment.Amount).FROM(Payment)
UNION_ALL(SELECT(Payment.Amount).FROM(Payment))
Sql:
(
SELECT payment.amount AS "payment.amount"
FROM dvds.payment
)
UNION
(
SELECT payment.amount AS "payment.amount"
FROM dvds.payment
);
Columns selected are before table sources(FROM
clause)
SELECT(
Payment.AllColumns,
Customer.AllColumns,
).
FROM(
Payment.
INNER_JOIN(Customer, Payment.CustomerID.EQ(Customer.CustomerID)),
).
ORDER_BY(Payment.PaymentID.ASC()).
LIMIT(30)
Table sources are before columns selected. There is no FROM
clause.
Payment.
INNER_JOIN(Customer, Payment.CustomerID.EQ(Customer.CustomerID))
SELECT(
Payment.AllColumns,
Customer.AllColumns,
).
ORDER_BY(Payment.PaymentID.ASC()).
LIMIT(30)
Note
Jet form is added, because sometimes feels more natural to first think about the tables
of interest, and then about the columns. Although the second form feels more natural, the first
form is preferred because it looks and feels more like a native SQL.
Both forms produce exactly the same raw SQL.
// alias first
manager := Employee.AS("Manager")
// then aliased table can be used in a statement
stmt := SELECT(
manager.AllColumns,
).FROM(
manager,
)
SELECT "Manager"."EmployeeId" AS "Manager.EmployeeId",
"Manager"."LastName" AS "Manager.LastName",
"Manager"."FirstName" AS "Manager.FirstName",
"Manager"."Title" AS "Manager.Title",
FROM chinook."Employee" AS "Manager";
Note that model.Employee
can not be used as a destination for this query. Expected destination type name is now Manager
.
To use generated model types with aliased tables there are two options:
- Define new type
type Manager model.Employee
var dest Manager
err := stmt.Query(db, &dest)
- Field aliasing
var dest struct {
Manager model.Employee `alias:"Manager.*"`
}
err := stmt.Query(db, &dest)
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FAQ
- How to execute jet statement in SQL transaction?
- How to construct dynamic projection list?
- How to construct dynamic condition?
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