Version v3.0 of the documentation is no longer actively maintained. The site that you are currently viewing is an archived snapshot. For up-to-date documentation, see the latest version.
クエリの式
概要
本ページは以下の節から成ります。
宣言
Query DSLでは、例えばwhere
関数に検索条件を表すラムダ式を渡せます。
QueryDsl.from(a).where { a.addressId eq 1 }
KomapperではこのようなSQLの句に対応するようなラムダ式のことを宣言と呼びます。
宣言は全てtypealiasとしてorg.komapper.core.dsl.expression
パッケージに定義されています。
- Assignment宣言
- VALUES句に相当する
values
関数やSET句に相当するset
関数が受け取るラムダ式。typealiasはAssignmentDeclaration
。 - Having宣言
- HAVING句に対応する
having
関数が受け取るラムダ式。typealiasはHavingDeclaration
。 - On宣言
- ON句に対応する
on
関数が受け取るラムダ式。typealiasはOnDeclaration
。 - When宣言
- WHEN句に対応する
When
関数が受け取るラムダ式。typealiasはWhenDeclaration
。 - Where宣言
- WHERE句に対応する
where
関数が受け取るラムダ式。typealiasはWhereDeclaration
。
これらの宣言は下記に示すように合成が可能です。
plus
+
演算子を使うと、被演算子の宣言内部に持つ式を順番に実行するような新たな宣言を構築できます。
val w1: WhereDeclaration = {
a.addressId eq 1
}
val w2: WhereDeclaration = {
a.version eq 1
}
val w3: WhereDeclaration = w1 + w2 // +演算子の利用
val query: Query<List<Address>> = QueryDsl.from(a).where(w3)
val list: List<Address> = db.runQuery { query }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID = ? and t0_.VERSION = ?
*/
+
演算子はすべての宣言で利用できます。
and
and
関数を使うと、宣言をand
演算子で連結する新たな宣言を構築できます。
val w1: WhereDeclaration = {
a.addressId eq 1
}
val w2: WhereDeclaration = {
a.version eq 1
or { a.version eq 2 }
}
val w3: WhereDeclaration = w1.and(w2) // and関数の利用
val query: Query<List<Address>> = QueryDsl.from(a).where(w3)
val list: List<Address> = db.runQuery { query }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID = ? and (t0_.VERSION = ? or (t0_.VERSION = ?))
*/
and
関数は、Having、When、Whereの宣言に対して適用できます。
or
or
関数を使うと、宣言をor
演算子で連結する新たな宣言を構築できます。
val w1: WhereDeclaration = {
a.addressId eq 1
}
val w2: WhereDeclaration = {
a.version eq 1
a.street eq "STREET 1"
}
val w3: WhereDeclaration = w1.or(w2) // or関数の利用
val query: Query<List<Address>> = QueryDsl.from(a).where(w3)
val list: List<Address> = db.runQuery { query }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID = ? or (t0_.VERSION = ? and t0_.STREET = ?)
*/
or
関数は、Having、When、Whereの宣言に対して適用できます。
比較演算子
Having、On、When、Whereの 宣言 の中で利用できます。
演算子の引数にnull
を渡した場合その演算子は評価されません。つまりSQLに変換されません。
val nullable: Int? = null
val query = QueryDsl.from(a).where { a.addressId eq nullable }
したがって、上記のquery
が実行された場合は次のSQLが発行されます。
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_
eq
QueryDsl.from(a).where { a.addressId eq 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID = ?
*/
notEq
QueryDsl.from(a).where { a.addressId notEq 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID <> ?
*/
less
QueryDsl.from(a).where { a.addressId less 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID < ?
*/
lessEq
QueryDsl.from(a).where { a.addressId lessEq 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID <= ?
*/
greater
QueryDsl.from(a).where { a.addressId greater 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID > ?
*/
greaterEq
QueryDsl.from(a).where { a.addressId greaterEq 1 }
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID >= ?
*/
isNull
QueryDsl.from(e).where { e.managerId.isNull() }
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where t0_.MANAGER_ID is null
*/
isNotNull
QueryDsl.from(e).where { e.managerId.isNotNull() }
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where t0_.MANAGER_ID is not null
*/
like
QueryDsl.from(a).where { a.street like "STREET 1_" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET like ? escape ? order by t0_.ADDRESS_ID asc
*/
notLike
QueryDsl.from(a).where { a.street notLike "STREET 1_" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET not like ? escape ? order by t0_.ADDRESS_ID asc
*/
startsWith
QueryDsl.from(a).where { a.street startsWith "STREET 1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET like ? escape ? order by t0_.ADDRESS_ID asc
*/
notStartsWith
QueryDsl.from(a).where { a.street notStartsWith "STREET 1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET not like ? escape ? order by t0_.ADDRESS_ID asc
*/
contains
QueryDsl.from(a).where { a.street contains "T 1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET like ? escape ? order by t0_.ADDRESS_ID asc
*/
notContains
QueryDsl.from(a).where { a.street notContains "T 1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET not like ? escape ? order by t0_.ADDRESS_ID asc
*/
endsWith
QueryDsl.from(a).where { a.street endsWith "1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET like ? escape ? order by t0_.ADDRESS_ID asc
*/
notEndsWith
QueryDsl.from(a).where { a.street notEndsWith "1" }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.STREET not like ? escape ? order by t0_.ADDRESS_ID asc
*/
between
QueryDsl.from(a).where { a.addressId between 5..10 }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID between ? and ? order by t0_.ADDRESS_ID asc
*/
notBetween
QueryDsl.from(a).where { a.addressId notBetween 5..10 }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID not between ? and ? order by t0_.ADDRESS_ID asc
*/
inList
QueryDsl.from(a).where { a.addressId inList listOf(9, 10) }.orderBy(a.addressId.desc())
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID in (?, ?) order by t0_.ADDRESS_ID desc
*/
サブクエリも使えます。
QueryDsl.from(e).where {
e.addressId inList {
QueryDsl.from(a)
.where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}.select(a.addressId)
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where t0_.ADDRESS_ID in (select t1_.ADDRESS_ID from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
notInList
QueryDsl.from(a).where { a.addressId notInList (1..9).toList() }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID not in (?, ?, ?, ?, ?, ?, ?, ?, ?) order by t0_.ADDRESS_ID asc
*/
サブクエリも使えます。
QueryDsl.from(e).where {
e.addressId notInList {
QueryDsl.from(a).where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}.select(a.addressId)
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where t0_.ADDRESS_ID not in (select t1_.ADDRESS_ID from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
inList2
QueryDsl.from(a).where { a.addressId to a.version inList2 listOf(9 to 1, 10 to 1) }.orderBy(a.addressId.desc())
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where (t0_.ADDRESS_ID, t0_.VERSION) in ((?, ?), (?, ?)) order by t0_.ADDRESS_ID desc
*/
サブクエリも使えます。
QueryDsl.from(e).where {
e.addressId to e.version inList2 {
QueryDsl.from(a)
.where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}.select(a.addressId, a.version)
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where (t0_.ADDRESS_ID, t0_.VERSION) in (select t1_.ADDRESS_ID, t1_.VERSION from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
notInList2
QueryDsl.from(a).where { a.addressId to a.version notInList2 listOf(9 to 1, 10 to 1) }.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where (t0_.ADDRESS_ID, t0_.VERSION) not in ((?, ?), (?, ?)) order by t0_.ADDRESS_ID asc
*/
サブクエリも使えます。
QueryDsl.from(e).where {
e.addressId to e.version notInList2 {
QueryDsl.from(a).where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}.select(a.addressId, a.version)
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where (t0_.ADDRESS_ID, t0_.VERSION) not in (select t1_.ADDRESS_ID, t1_.VERSION from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
exists
QueryDsl.from(e).where {
exists {
QueryDsl.from(a).where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where exists (select t1_.ADDRESS_ID, t1_.STREET, t1_.VERSION from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
notExists
QueryDsl.from(e).where {
notExists {
QueryDsl.from(a).where {
e.addressId eq a.addressId
e.employeeName like "%S%"
}
}
}
/*
select t0_.EMPLOYEE_ID, t0_.EMPLOYEE_NO, t0_.EMPLOYEE_NAME, t0_.MANAGER_ID, t0_.HIREDATE, t0_.SALARY, t0_.DEPARTMENT_ID, t0_.ADDRESS_ID, t0_.VERSION from EMPLOYEE as t0_ where not exists (select t1_.ADDRESS_ID, t1_.STREET, t1_.VERSION from ADDRESS as t1_ where t0_.ADDRESS_ID = t1_.ADDRESS_ID and t0_.EMPLOYEE_NAME like ? escape ?)
*/
論理演算子
Having、On、When、Whereの 宣言 の中で利用できます。
and
宣言の中で式を並べるとAND演算子で連結されます。
QueryDsl.from(a).where {
a.addressId greater 1
a.street startsWith "S"
a.version less 100
}
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID > ? and t0_.STREET like ? escape ? and t0_.VERSION < ?
*/
明示的にAND演算子を使いたい場合はand
関数にラムダ式を渡します。
QueryDsl.from(a).where {
a.addressId greater 1
and {
a.street startsWith "S"
a.version less 100
}
}
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID > ? and (t0_.STREET like ? escape ? and t0_.VERSION < ?)
*/
or
OR演算子で連結したい場合はor
関数にラムダ式を渡します。
QueryDsl.from(a).where {
a.addressId greater 1
or {
a.street startsWith "S"
a.version less 100
}
}
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID > ? or (t0_.STREET like ? escape ? and t0_.VERSION < ?)
*/
not
NOT演算子を使うにはnot
関数にラムダ式を渡します。
QueryDsl.from(a).where {
a.addressId greater 5
not {
a.addressId greaterEq 10
}
}.orderBy(a.addressId)
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ where t0_.ADDRESS_ID > ? and not (t0_.ADDRESS_ID >= ?) order by t0_.ADDRESS_ID asc
*/
算術演算子
以下の演算子が使えます。
+
-
*
/
%
これらの演算子はorg.komapper.core.dsl.operator
に定義されています。
+
演算子を使った例を次に示します。
QueryDsl.update(a).set {
a.version eq (a.version + 10)
}.where {
a.addressId eq 1
}
/*
update ADDRESS as t0_ set VERSION = (t0_.VERSION + ?) where t0_.ADDRESS_ID = ?
*/
数学関数
次の関数が使えます。
- random
この関数はorg.komapper.core.dsl.operator
に定義されています。
random
関数を使った例を次に示します。
QueryDsl.from(a).orderBy(random())
/*
select t0_.ADDRESS_ID, t0_.STREET, t0_.VERSION from ADDRESS as t0_ order by random() asc
*/
文字列関数
次の関数が使えます。
- concat
- substring
- locate
- lower
- upper
- trim
- ltrim
- rtrim
これらの関数はorg.komapper.core.dsl.operator
に定義されています。
concat
関数を使った例を次に示します。
QueryDsl.update(a).set {
a.street eq (concat(concat("[", a.street), "]"))
}.where {
a.addressId eq 1
}
/*
update ADDRESS as t0_ set STREET = (concat((concat(?, t0_.STREET)), ?)) where t0_.ADDRESS_ID = ?
*/
集約関数
次の関数が使えます。
- avg
- count
- sum
- max
- min
これらの関数はorg.komapper.core.dsl.operator
に定義されています。
呼び出して得られる式はhaving
やselect
で使われることを想定しています。
QueryDsl.from(e)
.groupBy(e.departmentId)
.having {
count(e.employeeId) greaterEq 4L
}
.orderBy(e.departmentId)
.select(e.departmentId, count(e.employeeId))
/*
select t0_.DEPARTMENT_ID, count(t0_.EMPLOYEE_ID) from EMPLOYEE as t0_ group by t0_.DEPARTMENT_ID having count(t0_.EMPLOYEE_ID) >= ? order by t0_.DEPARTMENT_ID asc
*/
avg
QueryDsl.from(a).select(avg(a.addressId))
/*
select avg(t0_.ADDRESS_ID) from ADDRESS as t0_
*/
count
SQLのcount(*)
に変換するにはcount
関数を引数なしで呼び出します。
QueryDsl.from(a).select(count())
/*
select count(*) from ADDRESS as t0_
*/
count
関数をカラムを指定して呼び出すこともできます。
QueryDsl.from(a).select(count(a.street))
/*
select count(t0_.STREET) from ADDRESS as t0_
*/
count distinct はcountDistinct
関数で表現できます。
QueryDsl.from(a).select(countDistinct(a.street))
/*
select count(distinct t0_.STREET) from ADDRESS as t0_
*/
sum
QueryDsl.from(a).select(sum(a.addressId))
/*
select sum(t0_.ADDRESS_ID) from ADDRESS as t0_
*/
max
QueryDsl.from(a).select(max(a.addressId))
/*
select max(t0_.ADDRESS_ID) from ADDRESS as t0_
*/
min
QueryDsl.from(a).select(min(a.addressId))
/*
select min(t0_.ADDRESS_ID) from ADDRESS as t0_
*/
ウィンドウ関数
次の関数が使えます。
- rowNumber
- rank
- denseRank
- percentRank
- cumeDist
- ntile
- lag
- lead
- firstValue
- lastValue
- nthValue
これらの関数はorg.komapper.core.dsl.operator
に定義されています。
rowRumber
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, rowNumber().over { orderBy(e.departmentId) })
/*
select t0_.department_id, row_number() over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
rank
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, rank().over { orderBy(e.departmentId) })
/*
select t0_.department_id, rank() over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
denseRank
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, denseRank().over { orderBy(e.departmentId) })
/*
select t0_.department_id, dense_rank() over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
percentRank
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, percentRank().over { orderBy(e.departmentId) })
/*
select t0_.department_id, percent_rank() over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
cumeDist
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, cumeDist().over { orderBy(e.departmentId) })
/*
select t0_.department_id, cume_dist() over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
ntile
QueryDsl.from(e)
.orderBy(e.departmentId)
.selectNotNull(e.departmentId, ntile(5).over { orderBy(e.departmentId) })
/*
select t0_.department_id, ntile(5) over( order by t0_.department_id asc) from employee as t0_ order by t0_.department_id asc
*/
lag
val c1 = d.departmentId
val c2 = lag(d.departmentId).over { orderBy(d.departmentId) }
val c3 = lag(d.departmentId, 2).over { orderBy(d.departmentId) }
val c4 = lag(d.departmentId, 2, literal(-1)).over { orderBy(d.departmentId) }
QueryDsl.from(d)
.orderBy(d.departmentId)
.select(c1, c2, c3, c4)
/*
select t0_.department_id, lag(t0_.department_id) over( order by t0_.department_id asc), lag(t0_.department_id, 2) over( order by t0_.department_id asc), lag(t0_.department_id, 2, -1) over( order by t0_.department_id asc) from department as t0_ order by t0_.department_id asc
*/
lead
val d = Meta.department
val c1 = d.departmentId
val c2 = lead(d.departmentId).over { orderBy(d.departmentId) }
val c3 = lead(d.departmentId, 2).over { orderBy(d.departmentId) }
val c4 = lead(d.departmentId, 2, literal(-1)).over { orderBy(d.departmentId) }
QueryDsl.from(d)
.orderBy(d.departmentId)
.select(c1, c2, c3, c4)
/*
select t0_.department_id, lead(t0_.department_id) over( order by t0_.department_id asc), lead(t0_.department_id, 2) over( order by t0_.department_id asc), lead(t0_.department_id, 2, -1) over( order by t0_.department_id asc) from department as t0_ order by t0_.department_id asc
*/
firstValue
val d = Meta.department
val c1 = d.departmentId
val c2 = firstValue(d.departmentId).over { orderBy(d.departmentId) }
val c3 = firstValue(d.departmentId).over {
orderBy(d.departmentId)
rows(preceding(1))
}
QueryDsl.from(d)
.orderBy(d.departmentId)
.select(c1, c2, c3)
/*
select t0_.department_id, first_value(t0_.department_id) over( order by t0_.department_id asc), first_value(t0_.department_id) over( order by t0_.department_id asc rows 1 preceding) from department as t0_ order by t0_.department_id asc
*/
lastValue
val d = Meta.department
val c1 = d.departmentId
val c2 = lastValue(d.departmentId).over {
orderBy(d.departmentId)
rows(unboundedPreceding, unboundedFollowing)
}
val c3 = lastValue(d.departmentId).over {
orderBy(d.departmentId)
rows(currentRow, following(1))
}
QueryDsl.from(d)
.orderBy(d.departmentId)
.select(c1, c2, c3)
/*
select t0_.department_id, last_value(t0_.department_id) over( order by t0_.department_id asc rows between unbounded preceding and unbounded following), last_value(t0_.department_id) over( order by t0_.department_id asc rows between current row and 1 following) from department as t0_ order by t0_.department_id asc
*/
nthValue
val d = Meta.department
val c1 = d.departmentId
val c2 = nthValue(d.departmentId, 2).over {
orderBy(d.departmentId)
}
val c3 = nthValue(d.departmentId, 2).over {
orderBy(d.departmentId)
rows(preceding(2))
}
QueryDsl.from(d)
.orderBy(d.departmentId)
.select(c1, c2, c3)
/*
select t0_.department_id, nth_value(t0_.department_id, 2) over( order by t0_.department_id asc), nth_value(t0_.department_id, 2) over( order by t0_.department_id asc rows 2 preceding) from department as t0_ order by t0_.department_id asc
*/
条件式
次の関数や式が使えます。
- coalesce
- case
これらはorg.komapper.core.dsl.operator
に定義されています。
coalesce
coalesce
関数を使う例です。
QueryDsl.from(a).select(a.addressId, coalesce(a.street, literal("default")))
/*
select t0_.ADDRESS_ID, coalesce(t0_.STREET, 'default') from ADDRESS as t0_
*/
CASE式
CASE式を使うにはcase
を呼び出します。
val caseExpression = case(
When(
{
a.street eq "STREET 2"
a.addressId greater 1
},
literal("HIT")
)
) { literal("NO HIT") }
val list: List<Pair<String?, String?>> = db.runQuery {
QueryDsl.from(a).where { a.addressId inList listOf(1, 2, 3) }
.orderBy(a.addressId)
.select(a.street, caseExpression)
}
/*
select t0_.street, case when t0_.street = ? and t0_.address_id > ? then 'HIT' else 'NO HIT' end from address as t0_ where t0_.address_id in (?, ?, ?) order by t0_.address_id asc
*/
スカラサブクエリ
集約関数を使ってスカラを返すクエリはサブクエリとして他のクエリのselect
関数に渡せます。
val subquery = QueryDsl.from(e).where { d.departmentId eq e.departmentId }.select(count())
val query = QueryDsl.from(d)
.orderBy(d.departmentId)
.select(d.departmentName, subquery)
/*
select t0_.department_name, (select count(*) from employee as t1_ where t0_.department_id = t1_.department_id) from department as t0_ order by t0_.department_id asc
*/
リテラル
バインド変数を介さず直接値をリテラルとしてSQLに埋め込みたい場合はliteral
またはnullLiteral
を呼び出します。
literal
関数とnullLiteral
関数はorg.komapper.core.dsl.operator
に定義されています。
literal
関数がサポートする引数の型は以下のものです。
- Boolean
- Int
- Long
- String
使用例です。
QueryDsl.insert(a).values {
a.addressId eq 100
a.street eq literal("STREET 100")
a.version eq literal(100)
}
/*
insert into ADDRESS (ADDRESS_ID, STREET, VERSION) values (?, 'STREET 100', 100)
*/
nullリテラルを使うにはnullLiteral
関数を呼び出します。
QueryDsl.insert(a).values {
a.addressId eq 100
a.street eq nullLiteral(String::class)
a.version eq nullLiteral(Long::class)
}
/*
insert into ADDRESS (ADDRESS_ID, STREET, VERSION) values (?, null, null)
*/
ユーザー定義の式
独自の比較演算子
独自の比較演算子は、org.komapper.core.dsl.operator.CriteriaContext
をコンストラクタの引数に持つクラス内で定義してください。
演算子に対応するSQLを生成する処理は、ラムダ関数としてCriteriaContext
にadd
します。
以下の例では、~
演算子と!~
演算子を定義します。
class MyExtension(private val context: CriteriaContext) {
infix fun <T : Any> ColumnExpression<T, String>.`~`(pattern: T?) {
if (pattern == null) return
val o1 = Operand.Column(this)
val o2 = Operand.Argument(this, pattern)
context.add {
visit(o1)
append(" ~ ")
visit(o2)
}
}
infix fun <T : Any> ColumnExpression<T, String>.`!~`(pattern: T?) {
if (pattern == null) return
val o1 = Operand.Column(this)
val o2 = Operand.Argument(this, pattern)
context.add {
visit(o1)
append(" !~ ")
visit(o2)
}
}
}
演算子を利用するには、WhereやHavingの宣言の中でextension
関数を呼び出します。
extension
関数の引数には上述のコンストラクタと演算子を呼び出すラムダ式を指定してください。
QueryDsl.from(e).where {
e.salary greaterEq BigDecimal(1000)
extension(::MyExtension) {
e.employeeName `~` "S"
e.employeeName `!~` "T"
}
}.orderBy(e.employeeName)
/*
select
t0_.EMPLOYEE_ID,
t0_.EMPLOYEE_NO,
t0_.EMPLOYEE_NAME,
t0_.MANAGER_ID,
t0_.HIREDATE,
t0_.SALARY,
t0_.DEPARTMENT_ID,
t0_.ADDRESS_ID,
t0_.VERSION
from
EMPLOYEE as t0_
where
t0_.SALARY >= ?
t0_.EMPLOYEE_NAME ~ ?
t0_.EMPLOYEE_NAME !~ ?
order by
t0_.EMPLOYEE_NAME
*/
独自のカラム式
独自のカラム式(例えば文字列関数など)は、org.komapper.core.dsl.expression.ColumnExpression
を返す関数として定義します。
ColumnExpression
は、org.komapper.core.dsl.operator.columnExpression
を呼び出すことで生成できます。
columnExpression
には、カラム式の型、カラム式を一意に特定するための情報、SQLを生成するラムダ式を渡します。
以下の例では、replace
関数を定義します。
private inline fun <reified T : Any> replace(
expression: ColumnExpression<T, String>,
from: T,
to: T,
): ColumnExpression<T, String> {
val name = "replace"
val o1 = Operand.Column(expression)
val o2 = Operand.Argument(expression, from)
val o3 = Operand.Argument(expression, to)
return columnExpression(expression, name, listOf(o1, o2, o3)) {
append("$name(")
visit(o1)
append(", ")
visit(o2)
append(", ")
visit(o3)
append(")")
}
}
以下は、定義したreplace
関数をクエリに組み込む例です。
QueryDsl.from(a)
.where { a.addressId eq 1 }
.select(replace(a.street, "STREET", "St.")).first()
/*
select replace(t0_.STREET, ?, ?) from ADDRESS as t0_ where t0_.ADDRESS_ID = ?
*/