The public API of the next generation java.jdbc library.
The basic building blocks are the java.sql
/javax.sql
classes:
DataSource
-- something to get connections from,Connection
-- an active connection to the database,PreparedStatement
-- SQL and parameters combined, from a connection,and the following functions and a macro:
get-datasource
-- given a hash map describing a database or a JDBC
connection string, construct a javax.sql.DataSource
and return it,get-connection
-- given a connectable, obtain a new java.sql.Connection
from it and return that,plan
-- given a connectable and SQL + parameters or a statement,
return a reducible that, when reduced will execute the SQL and consume
the ResultSet
produced,execute!
-- given a connectable and SQL + parameters or a statement,
execute the SQL, consume the ResultSet
produced, and return a vector
of hash maps representing the rows (@1); this can be datafied to allow
navigation of foreign keys into other tables (either by convention or
via a schema definition),execute-one!
-- given a connectable and SQL + parameters or a statement,
execute the SQL, consume the first row of the ResultSet
produced, and
return a hash map representing that row; this can be datafied to allow
navigation of foreign keys into other tables (either by convention or
via a schema definition),execute-batch!
-- given a PreparedStatement
and groups of parameters,
execute the statement in batch mode (via .executeBatch
); given a
connectable, a SQL string, and groups of parameters, create a new
PreparedStatement
from the SQL and execute it in batch mode.prepare
-- given a Connection
and SQL + parameters, construct a new
PreparedStatement
; in general this should be used with with-open
,transact
-- the functional implementation of with-transaction
,with-transaction
-- execute a series of SQL operations within a transaction.@1 result sets are built, by default, as vectors of hash maps, containing qualified keywords as column names, but the row builder and result set builder machinery is open and alternatives are provided to produce unqualified keywords as column names, and to produce a vector the column names followed by vectors of column values for each row, and lower-case variants of each.
The following options are supported wherever a Connection
is created:
:auto-commit
-- either true
or false
,:read-only
-- either true
or false
,:connection
-- a hash map of camelCase properties to set, via reflection,
on the Connection
object after it is created.The following options are supported wherever a Statement
or
PreparedStatement
is created:
:concurrency
-- :read-only
, :updatable
,:cursors
-- :close
, :hold
:fetch-size
-- the fetch size value,:max-rows
-- the maximum number of rows to return,:result-type
-- :forward-only
, :scroll-insensitive
, :scroll-sensitive
,:timeout
-- the query timeout,:statement
-- a hash map of camelCase properties to set, via reflection,
on the Statement
or PreparedStatement
object after it is created.In addition, wherever a PreparedStatement
is created, you may specify:
:return-keys
-- either true
or a vector of key names to return.The public API of the next generation java.jdbc library. The basic building blocks are the `java.sql`/`javax.sql` classes: * `DataSource` -- something to get connections from, * `Connection` -- an active connection to the database, * `PreparedStatement` -- SQL and parameters combined, from a connection, and the following functions and a macro: * `get-datasource` -- given a hash map describing a database or a JDBC connection string, construct a `javax.sql.DataSource` and return it, * `get-connection` -- given a connectable, obtain a new `java.sql.Connection` from it and return that, * `plan` -- given a connectable and SQL + parameters or a statement, return a reducible that, when reduced will execute the SQL and consume the `ResultSet` produced, * `execute!` -- given a connectable and SQL + parameters or a statement, execute the SQL, consume the `ResultSet` produced, and return a vector of hash maps representing the rows (@1); this can be datafied to allow navigation of foreign keys into other tables (either by convention or via a schema definition), * `execute-one!` -- given a connectable and SQL + parameters or a statement, execute the SQL, consume the first row of the `ResultSet` produced, and return a hash map representing that row; this can be datafied to allow navigation of foreign keys into other tables (either by convention or via a schema definition), * `execute-batch!` -- given a `PreparedStatement` and groups of parameters, execute the statement in batch mode (via `.executeBatch`); given a connectable, a SQL string, and groups of parameters, create a new `PreparedStatement` from the SQL and execute it in batch mode. * `prepare` -- given a `Connection` and SQL + parameters, construct a new `PreparedStatement`; in general this should be used with `with-open`, * `transact` -- the functional implementation of `with-transaction`, * `with-transaction` -- execute a series of SQL operations within a transaction. @1 result sets are built, by default, as vectors of hash maps, containing qualified keywords as column names, but the row builder and result set builder machinery is open and alternatives are provided to produce unqualified keywords as column names, and to produce a vector the column names followed by vectors of column values for each row, and lower-case variants of each. The following options are supported wherever a `Connection` is created: * `:auto-commit` -- either `true` or `false`, * `:read-only` -- either `true` or `false`, * `:connection` -- a hash map of camelCase properties to set, via reflection, on the `Connection` object after it is created. The following options are supported wherever a `Statement` or `PreparedStatement` is created: * `:concurrency` -- `:read-only`, `:updatable`, * `:cursors` -- `:close`, `:hold` * `:fetch-size` -- the fetch size value, * `:max-rows` -- the maximum number of rows to return, * `:result-type` -- `:forward-only`, `:scroll-insensitive`, `:scroll-sensitive`, * `:timeout` -- the query timeout, * `:statement` -- a hash map of camelCase properties to set, via reflection, on the `Statement` or `PreparedStatement` object after it is created. In addition, wherever a `PreparedStatement` is created, you may specify: * `:return-keys` -- either `true` or a vector of key names to return.
Standard implementations of get-datasource
and get-connection
.
Also provides dbtypes
as a map of all known database types, and
the ->pool
and component
functions for creating pooled datasource
objects.
Standard implementations of `get-datasource` and `get-connection`. Also provides `dbtypes` as a map of all known database types, and the `->pool` and `component` functions for creating pooled datasource objects.
This namespace provides datafication of several JDBC object types,
all within the java.sql
package:
Connection
-- datafies as a bean.DatabaseMetaData
-- datafies as a bean; six properties
are navigable to produce fully-realized datafiable result sets.ParameterMetaData
-- datafies as a vector of parameter descriptions.ResultSet
-- datafies as a bean; if the ResultSet
has an associated
Statement
and that in turn has an associated Connection
then an
additional key of :rows
is provided which is a datafied result set,
from next.jdbc.result-set/datafiable-result-set
with default options.
This is provided as a convenience, purely for datafication of other
JDBC data types -- in normal next.jdbc
usage, result sets are
datafied under full user control.ResultSetMetaData
-- datafies as a vector of column descriptions.Statement
-- datafies as a bean.Because different database drivers may throw SQLException
for various
unimplemented or unavailable properties on objects in various states,
the default behavior is to return those exceptions using the :qualify
option for clojure.java.data/from-java-shallow
, so for a property
:foo
, if its corresponding getter throws an exception, it would instead
be returned as :foo/exception
. This behavior can be overridden by
binding
next.jdbc.datafy/*datafy-failure*
to any of the other options
supported: :group
, :omit
, or :return
. See the clojure.java.data
documentation for more details.
This namespace provides datafication of several JDBC object types, all within the `java.sql` package: * `Connection` -- datafies as a bean. * `DatabaseMetaData` -- datafies as a bean; six properties are navigable to produce fully-realized datafiable result sets. * `ParameterMetaData` -- datafies as a vector of parameter descriptions. * `ResultSet` -- datafies as a bean; if the `ResultSet` has an associated `Statement` and that in turn has an associated `Connection` then an additional key of `:rows` is provided which is a datafied result set, from `next.jdbc.result-set/datafiable-result-set` with default options. This is provided as a convenience, purely for datafication of other JDBC data types -- in normal `next.jdbc` usage, result sets are datafied under full user control. * `ResultSetMetaData` -- datafies as a vector of column descriptions. * `Statement` -- datafies as a bean. Because different database drivers may throw `SQLException` for various unimplemented or unavailable properties on objects in various states, the default behavior is to return those exceptions using the `:qualify` option for `clojure.java.data/from-java-shallow`, so for a property `:foo`, if its corresponding getter throws an exception, it would instead be returned as `:foo/exception`. This behavior can be overridden by `binding` `next.jdbc.datafy/*datafy-failure*` to any of the other options supported: `:group`, `:omit`, or `:return`. See the `clojure.java.data` documentation for more details.
Optional namespace that extends next.jdbc.prepare/SettableParameter
to various date/time types so that they will all be treated as SQL
timestamps (which also supports date and time column types) and has
functions to extend next.jdbc.result-set/ReadableColumn
.
Simply requiring this namespace will extend the SettableParameter
protocol
to the four types listed below.
In addition, there are several read-as-*
functions here that will
extend next.jdbc.result-set/ReadableColumn
to allow java.sql.Date
and java.sql.Timestamp
columns to be read as (converted to) various
Java Time types automatically. The expectation is that you will call at
most one of these, at application startup, to enable the behavior you want.
Database support for Java Time:
Instant
, LocalDate
,
LocalDateTime
) out of the box,java.util.Date
out of
the box -- except PostgreSQL apparently!Types supported by this namespace:
java.time.Instant
java.time.LocalDate
java.time.LocalDateTime
java.util.Date
-- mainly for PostgreSQLPostgreSQL does not seem able to convert java.util.Date
to a SQL
timestamp by default (every other database can!) so you'll probably
need to require this namespace, even if you don't use Java Time, when
working with PostgreSQL.
Optional namespace that extends `next.jdbc.prepare/SettableParameter` to various date/time types so that they will all be treated as SQL timestamps (which also supports date and time column types) and has functions to extend `next.jdbc.result-set/ReadableColumn`. Simply requiring this namespace will extend the `SettableParameter` protocol to the four types listed below. In addition, there are several `read-as-*` functions here that will extend `next.jdbc.result-set/ReadableColumn` to allow `java.sql.Date` and `java.sql.Timestamp` columns to be read as (converted to) various Java Time types automatically. The expectation is that you will call at most one of these, at application startup, to enable the behavior you want. Database support for Java Time: * H2 and SQLite support conversion of Java Time (`Instant`, `LocalDate`, `LocalDateTime`) out of the box, * Nearly all databases support conversion of `java.util.Date` out of the box -- except PostgreSQL apparently! Types supported by this namespace: * `java.time.Instant` * `java.time.LocalDate` * `java.time.LocalDateTime` * `java.util.Date` -- mainly for PostgreSQL PostgreSQL does not seem able to convert `java.util.Date` to a SQL timestamp by default (every other database can!) so you'll probably need to require this namespace, even if you don't use Java Time, when working with PostgreSQL.
Builders that treat NULL SQL values as 'optional' and omit the corresponding keys from the Clojure hash maps for the rows.
Builders that treat NULL SQL values as 'optional' and omit the corresponding keys from the Clojure hash maps for the rows.
Some helper functions that make common operations with next.jdbc/plan
much easier.
Some helper functions that make common operations with `next.jdbc/plan` much easier.
Mostly an implementation namespace for how PreparedStatement
objects are
created by the next generation java.jdbc library.
set-parameters
is public and may be useful if you have a PreparedStatement
that you wish to reuse and (re)set the parameters on it.
Defines the SettableParameter
protocol for converting Clojure values
to database-specific values.
See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.date-time
for implementations of SettableParameter
that provide automatic
conversion of Java Time objects to SQL data types.
See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.types
for as-xxx
functions that provide per-instance implementations of
SettableParameter
for each of the standard java.sql.Types
values.
Mostly an implementation namespace for how `PreparedStatement` objects are created by the next generation java.jdbc library. `set-parameters` is public and may be useful if you have a `PreparedStatement` that you wish to reuse and (re)set the parameters on it. Defines the `SettableParameter` protocol for converting Clojure values to database-specific values. See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.date-time for implementations of `SettableParameter` that provide automatic conversion of Java Time objects to SQL data types. See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.types for `as-xxx` functions that provide per-instance implementations of `SettableParameter` for each of the standard `java.sql.Types` values.
This is the extensible core of the next generation java.jdbc library.
Sourceable
-- for producing javax.sql.DataSource
objects,Connectable
-- for producing new java.sql.Connection
objects,Executable
-- for executing SQL operations,Preparable
-- for producing new java.sql.PreparedStatement
objects,Transactable
-- for executing SQL operations transactionally.This is the extensible core of the next generation java.jdbc library. * `Sourceable` -- for producing `javax.sql.DataSource` objects, * `Connectable` -- for producing new `java.sql.Connection` objects, * `Executable` -- for executing SQL operations, * `Preparable` -- for producing new `java.sql.PreparedStatement` objects, * `Transactable` -- for executing SQL operations transactionally.
Provides functions for use with the :table-fn
and :column-fn
options
that define how SQL entities should be quoted in strings constructed
from Clojure data.
Provides functions for use with the `:table-fn` and `:column-fn` options that define how SQL entities should be quoted in strings constructed from Clojure data.
An implementation of ResultSet
handling functions.
Defines the following protocols:
DatafiableRow
-- for turning a row into something datafiableReadableColumn
-- to read column values by label or indexRowBuilder
-- for materializing a rowResultSetBuilder
-- for materializing a result setA broad range of result set builder implementation functions are provided.
Also provides the default implementations for Executable
and
the default datafy
/nav
behavior for rows from a result set.
See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.date-time
for implementations of ReadableColumn
that provide automatic
conversion of some SQL data types to Java Time objects.
An implementation of `ResultSet` handling functions. Defines the following protocols: * `DatafiableRow` -- for turning a row into something datafiable * `ReadableColumn` -- to read column values by label or index * `RowBuilder` -- for materializing a row * `ResultSetBuilder` -- for materializing a result set A broad range of result set builder implementation functions are provided. Also provides the default implementations for `Executable` and the default `datafy`/`nav` behavior for rows from a result set. See also https://cljdoc.org/d/com.github.seancorfield/next.jdbc/CURRENT/api/next.jdbc.date-time for implementations of `ReadableColumn` that provide automatic conversion of some SQL data types to Java Time objects.
Specs for the core API of next.jdbc.
The functions from next.jdbc
, next.jdbc.sql
, and next.jdbc.prepare
have specs here.
Just :args
are spec'd. These specs are intended to aid development
with next.jdbc
by catching simple errors in calling the library.
The connectable
argument is currently just any?
but both
get-datasource
and get-connection
have stricter specs.
In addition, there is an instrument
function that provides a simple
way to instrument all of the next.jdbc
functions, and unstrument
to undo that.
Specs for the core API of next.jdbc. The functions from `next.jdbc`, `next.jdbc.sql`, and `next.jdbc.prepare` have specs here. Just `:args` are spec'd. These specs are intended to aid development with `next.jdbc` by catching simple errors in calling the library. The `connectable` argument is currently just `any?` but both `get-datasource` and `get-connection` have stricter specs. In addition, there is an `instrument` function that provides a simple way to instrument all of the `next.jdbc` functions, and `unstrument` to undo that.
Some utility functions that make common operations easier by
providing some syntactic sugar over execute!
/execute-one!
.
This is intended to provide a minimal level of parity with
clojure.java.jdbc
(insert!
, insert-multi!
, query
, find-by-keys
,
get-by-id
, update!
, and delete!
).
For anything more complex, use a library like HoneySQL https://github.com/seancorfield/honeysql to generate SQL + parameters.
The following options are supported:
:table-fn
-- specify a function used to convert table names (strings)
to SQL entity names -- see the next.jdbc.quoted
namespace for the
most common quoting strategy functions,:column-fn
-- specify a function used to convert column names (strings)
to SQL entity names -- see the next.jdbc.quoted
namespace for the
most common quoting strategy functions.In addition, find-by-keys
supports :order-by
to add an ORDER BY
clause to the generated SQL.
Some utility functions that make common operations easier by providing some syntactic sugar over `execute!`/`execute-one!`. This is intended to provide a minimal level of parity with `clojure.java.jdbc` (`insert!`, `insert-multi!`, `query`, `find-by-keys`, `get-by-id`, `update!`, and `delete!`). For anything more complex, use a library like HoneySQL https://github.com/seancorfield/honeysql to generate SQL + parameters. The following options are supported: * `:table-fn` -- specify a function used to convert table names (strings) to SQL entity names -- see the `next.jdbc.quoted` namespace for the most common quoting strategy functions, * `:column-fn` -- specify a function used to convert column names (strings) to SQL entity names -- see the `next.jdbc.quoted` namespace for the most common quoting strategy functions. In addition, `find-by-keys` supports `:order-by` to add an `ORDER BY` clause to the generated SQL.
Some utility functions for building SQL strings.
These were originally private functions in next.jdbc.sql
but
they may proof useful to developers who want to write their own
'SQL sugar' functions, such as a database-specific upsert!
etc.
Some utility functions for building SQL strings. These were originally private functions in `next.jdbc.sql` but they may proof useful to developers who want to write their own 'SQL sugar' functions, such as a database-specific `upsert!` etc.
Implementation of SQL transaction logic.
In general, you cannot nest transactions. clojure.java.jdbc
would
ignore any attempt to create a nested transaction, even tho' some
databases do support it. next.jdbc
allows you to call with-transaction
even while you are inside an active transaction, but the behavior may
vary across databases and the commit or rollback boundaries may not be
what you expect. In order to avoid two transactions constructed on the
same connection from interfering with each other, next.jdbc
locks on
the Connection
object (this prevents concurrent transactions on separate
threads from interfering but will cause deadlock on a single thread --
so beware).
Consequently, this namespace exposes a dynamic variable, *nested-tx*
,
which can be used to vary the behavior when an attempt is made to start
a transaction when you are already inside a transaction.
Implementation of SQL transaction logic. In general, you cannot nest transactions. `clojure.java.jdbc` would ignore any attempt to create a nested transaction, even tho' some databases do support it. `next.jdbc` allows you to call `with-transaction` even while you are inside an active transaction, but the behavior may vary across databases and the commit or rollback boundaries may not be what you expect. In order to avoid two transactions constructed on the same connection from interfering with each other, `next.jdbc` locks on the `Connection` object (this prevents concurrent transactions on separate threads from interfering but will cause deadlock on a single thread -- so beware). Consequently, this namespace exposes a dynamic variable, `*nested-tx*`, which can be used to vary the behavior when an attempt is made to start a transaction when you are already inside a transaction.
Provides convenience functions for wrapping values you pass into SQL
operations that have per-instance implementations of SettableParameter
so that .setObject()
is called with the appropriate java.sql.Types
value.
Provides convenience functions for wrapping values you pass into SQL operations that have per-instance implementations of `SettableParameter` so that `.setObject()` is called with the appropriate `java.sql.Types` value.
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