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TEMPLATE Queries
Overview
TEMPLATE queries are constructed using SQL templates.
The TEMPLATE query is an optional feature not included in the core module. To use it, the following dependency declaration must be included in your Gradle build script:
val komapperVersion: String by project
dependencies {
implementation("org.komapper:komapper-template:$komapperVersion")
}
Note
The above dependency declaration is not necessary when using Starters.Note
Thekomapper-template
module uses reflection internally.
fromTemplate
To issue a SELECT statement, call the fromTemplate
, bind
, and select
functions as follows:
val sql = "select * from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.bind("street", "STREET 10")
.select { row: Row ->
Address(
row.getNotNull("address_id"),
row.getNotNull("street"),
row.getNotNull("version")
)
}
The fromTemplate
function accepts a string of SQL template.
The bind
function binds a value to a bind variable directive.
The select
function converts a Row
to any type using the given lambda expression.
Row
is a thin wrapper around java.sql.ResultSet
and io.r2dbc.spi.Row
.
It has functions to retrieve values by column label or index.
Note that the index starts from 0.
selectAsEntity
If you want to receive the result as a specific entity, call selectAsEntity
.
For the first argument, specify the entity’s metamodel.
The SELECT clause in the SQL template must include columns corresponding to all properties of the entity.
In the following example, the result is received as an Address
entity.
val sql = "select address_id, street, version from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.bind("street", "STREET 10")
.selectAsEntity(a)
By default, entities are mapped based on the order of columns in the SELECT list.
However, by passing ProjectionType.NAME
as the second argument to selectAsEntity
, you can map based on the column names.
val sql = "select street, version, address_id from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.bind("street", "STREET 10")
.selectAsEntity(a, ProjectionType.NAME)
When you annotate the entity class you want to receive as a result with @KomapperProjection
,
you can use a dedicated extension function to write your code more concisely as follows:
val sql = "select address_id, street, version from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.bind("street", "STREET 10")
.selectAsAddress()
val sql = "select street, version, address_id from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.bind("street", "STREET 10")
.selectAsAddress(ProjectionType.NAME)
options
To customize the behavior of the query, call the options
function.
The options
function accept a lambda expression whose parameter represents default options.
Call the copy
function on the parameter to change its properties:
val sql = "select * from ADDRESS where street = /*street*/'test'"
val query: Query<List<Address>> = QueryDsl.fromTemplate(sql)
.options {
it.copy(
fetchSize = 100,
queryTimeoutSeconds = 5
)
}
.bind("street", "STREET 10")
.select { row: Row ->
Address(
row.getNotNull("address_id"),
row.getNotNull("street"),
row.getNotNull("version")
)
}
The options that can be specified are as follows:
- escapeSequence
- Escape sequence specified for the LIKE predicate. The default is
null
to indicate the use of Dialect values. - fetchSize
- Default is
null
to indicate that the driver value should be used. - maxRows
- Default is
null
to indicate use of the driver’s value. - queryTimeoutSeconds
- Query timeout in seconds. Default is
null
to indicate that the driver value should be used. - suppressLogging
- Whether to suppress SQL log output. Default is
false
.
Properties explicitly set here will be used in preference to properties with the same name that exist in executionOptions.
executeTemplate
To issue a DML(Data Manipulation Language) statement, call the executeTemplate
and bind
functions as follows:
val sql = "update ADDRESS set street = /*street*/'' where address_id = /*id*/0"
val query: Query<Long> = QueryDsl.executeTemplate(sql)
.bind("id", 15)
.bind("street", "NY street")
The executeTemplate
function accepts a string of SQL template.
The bind
function binds a value to a bind variable directive.
If a duplicate key is detected during query execution,
the org.komapper.core.UniqueConstraintException
is thrown.
returning
By using the returning
function, you can execute an update DML and also retrieve the results. After executing the returning
function, you can use the select
and selectAsEntity
functions mentioned in fromTemplate.
val sql = """
insert into address
(address_id, street, version)
values
(/*id*/0, /*street*/'', /*version*/0)
returning address_id, street, version
""".trimIndent()
val query: Query<Address> = QueryDsl.executeTemplate(sql)
.returning()
.bind("id", 16)
.bind("street", "NY street")
.bind("version", 1)
.select { row: Row ->
Address(
row.getNotNull("address_id"),
row.getNotNull("street"),
row.getNotNull("version")
)
}
.single()
Note
The above SQL template uses the RETURNING clause, which is supported by PostgreSQL and other databases. Please note that the SQL for returning results from update DML varies depending on the DBMS.options
To customize the behavior of the query, call the options
function.
The options
function accept a lambda expression whose parameter represents default options.
Call the copy
function on the parameter to change its properties:
val sql = "update ADDRESS set street = /*street*/'' where address_id = /*id*/0"
val query: Query<Long> = QueryDsl.executeTemplate(sql)
.bind("id", 15)
.bind("street", "NY street")
.options {
it.copy(
queryTimeoutSeconds = 5
)
}
The options that can be specified are as follows:
- escapeSequence
- Escape sequence specified for the LIKE predicate. The default is
null
to indicate the use of Dialect values. - queryTimeoutSeconds
- Query timeout in seconds. Default is
null
to indicate that the driver value should be used. - suppressLogging
- Whether to suppress SQL log output. Default is
false
.
Properties explicitly set here will be used in preference to properties with the same name that exist in executionOptions.
SQL templates
In SQL template, directives such as bind variables and conditional branches are expressed as SQL comments. Therefore, you can paste a string from the SQL template into a tool such as pgAdmin to execute it.
For example, an SQL template containing a conditional branch and a bind variable is written as follows:
select name, age from person where
/*% if name != null */
name = /* name */'test'
/*% end */
order by name
In the above SQL template, if name != null
is true, the following SQL is generated:
select name, age from person where name = ? order by name
Conversely, if name != null
is false, the following SQL is generated:
select name, age from person order by name
Note
In the example above, did you notice that if name != null
is false,
the generated SQL does not contain a WHERE clause?
The SQL template does not output WHERE, HAVING, GROUP BY, or ORDER BY clauses if they do not have any SQL identifiers or keywords.
Thus, there is no need to always include 1 = 1
in the WHERE clause
to prevent incorrect SQL from being generated:
select name, age from person where 1 = 1 // unnecessary
/*% if name != null */
and name = /* name */'test'
/*% end */
order by name
Bind variable directives
To represent bind variables, use bind variable directives.
Bind variable directives are simple SQL comments enclosed in /*
and */
.
They require test data immediately after the directive.
In the following example, /* name */
is the bind variable directive,
and the following 'test'
is the test data:
where name = /* name */'test'
Test data exists only to preserve correct SQL syntax. It is not used by the application. In the process of parsing the template, test data is removed and bind variables are resolved. Finally, the above template is converted to SQL as follows:
where name = ?
To bind a value to an IN clause, the bound value must be kotlin.collections.Iterable
.
In the following example, names
is Iterable<String>
, and the following ('a', 'b')
is the test data:
where name in /* names */('a', 'b')
To bind a Pair
value to an IN clause, the bound value must be kotlin.collections.Iterable<Pair>
In the following example, pairs
is Iterable<Pair<String, String>>
,
and the following (('a', 'b'), ('c', 'd'))
is the test data:
where (name, age) in /* pairs */(('a', 'b'), ('c', 'd'))
Literal variable directives
To represent literals, use literal variable directives.
Literal variable directives are SQL comments enclosed in /*^
and */
.
They require test data immediately after the directive.
In the following example, /*^ myLiteral */
is the literal variable directive,
and the following 'test'
is the test data:
where name = /*^ myLiteral */'test'
Test data exists only to preserve correct SQL syntax. It is not used by the application. In the process of parsing the template, test data is removed and literal variables are resolved. Finally, the above template is converted to SQL as follows:
where name = 'abc'
Embedded variable directives
To embed sql fragments, use embedded variable directives.
Embedded variable directives are SQL comments enclosed in /*#
and */
.
Unlike other variable directives, they do not require test data immediately after the directive.
In the following example, /*# orderBy */
is the embedded variable directive:
select name, age from person where age > 1 /*# orderBy */
In the example above, if the orderBy
expression evaluates to order by name
,
the template is converted to the following SQL:
select name, age from person where age > 1 order by name
if directives
To start conditional branching, use if directives.
If directives are SQL comments enclosed in /*% if
and */
.
A conditional branch must begin with an if directive and end with an end directive.
In the following example, /*% if name != null */
is the if directive:
/*% if name != null */
name = /* name */'test'
/*% end */
You can also put an else directive between an if directive and an end directive:
/*% if name != null */
name = /* name */'test'
/*% else */
name is null
/*% end */
for directives
To start loop processing, use for directives.
For directives are SQL comments enclosed in /*% for
and */
.
A loop process must begin with a for directive and end with an end directive.
In the following example, /*% for name in names */
is the for directive:
/*% for name in names */
employee_name like /* name */'hoge'
/*% if name_has_next */
/*# "or" */
/*% end */
/*% end */
In the /*% for name in names */
directive, the names
express an Iterable
object
and the name
is an identifier for each element of the Iterable
object.
Between the for and end directives, the following special variables are available.
- identifier_has_next: Returns a boolean value indicating whether the next iteration should be executed.
- identifier_next_comma: Returns
,
if the next iteration will be executed; otherwise, returns an empty string. - identifier_next_or: Returns
or
if the next iteration should be executed; otherwise, returns an empty string. - identifier_next_and: Returns
and
if the next iteration should be executed; otherwise, returns an empty string.
In the above example, name_has_next
is a special variable.
The above example can be rewritten as follows using name_next_or
:
/*% for name in names */
employee_name like /* name */'hoge'
/*# name_next_or */
/*% end */
end directives
To end conditional branching and loop processing, use end directives.
End directives are SQL comments expressed as /*% end */
.
Parser-level comment directives
Using a parser-level comment directive allows you to include comments in an SQL template that will be removed after the template is parsed.
To express parser-level comments, you can use the syntax /*%! comment */
.
Suppose you have the following SQL template:
select
name
from
employee
where /*%! This comment will be removed */
employee_id = /* employeeId */99
The above SQL template is parsed into the following SQL:
select
name
from
employee
where
employee_id = ?
Expressions
Expressions in the directives can perform the following:
- Execution of operators
- Property access
- Function call
- Class reference
- Use of extension properties and functions
Operators
The following operators are supported. Semantics are the same as for operators in Kotlin:
==
!=
>=
<=
>
<
!
&&
||
These can be used as follows:
/*% if name != null && name.length > 0 */
name = /* name */'test'
/*% else */
name is null
/*% end */
Property accesses
To access properties, use .
or ?.
as follows:
/*% if person?.name != null */
name = /* person?.name */'test'
/*% else */
name is null
/*% end */
?.
is equivalent to the safe call operator of Kotlin.
Function calls
Functions can be called as follows:
/*% if isValid(name) */
name = /*name*/'test'
/*% else */
name is null
/*% end */
Class references
You can refer to a class by using the notation @fully qualified name of the class@
.
For example, if the example.Direction
enum class has an element named WEST
,
it can be referenced as follows:
/*% if direction == @example.Direction@.WEST */
direction = 'west'
/*% end */
Extension properties and functions
The following extension properties and functions provided by Kotlin are available by default:
val CharSequence.lastIndex: Int
fun CharSequence.isBlank(): Boolean
fun CharSequence.isNotBlank(): Boolean
fun CharSequence.isNullOrBlank(): Boolean
fun CharSequence.isEmpty(): Boolean
fun CharSequence.isNotEmpty(): Boolean
fun CharSequence.isNullOrEmpty(): Boolean
fun CharSequence.any(): Boolean
fun CharSequence.none(): Boolean
/*% if name.isNotBlank() */
name = /* name */'test'
/*% else */
name is null
/*% end */
The following extension functions defined by Komapper are also available:
fun String?.asPrefix(): String?
fun String?.asInfix(): String?
fun String?.asSuffix(): String?
fun String?.escape(): String?
For example, if you call the asPrefix
function,
the string "hello"
becomes "hello%"
and can be used in a prefix search:
where name like /* name.asPrefix() */
Similarly, calling the asInfix
function converts it to a string for an infix search,
and calling the asSuffix
function converts it to a string for a suffix search.
The escape
function escapes special characters.
For example, it converts a string "he%llo_"
into a string like "he\%llo\_"
.
Note
TheasPrefix
, asInfix
, and asSuffix
functions perform escaping internally,
so there is no need to call the escape
function in addition.