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614 lines
22 KiB
Python
614 lines
22 KiB
Python
3 months ago
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# ext/compiler.py
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# Copyright (C) 2005-2022 the SQLAlchemy authors and contributors
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# <see AUTHORS file>
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#
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# This module is part of SQLAlchemy and is released under
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# the MIT License: https://www.opensource.org/licenses/mit-license.php
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r"""Provides an API for creation of custom ClauseElements and compilers.
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Synopsis
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========
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Usage involves the creation of one or more
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:class:`~sqlalchemy.sql.expression.ClauseElement` subclasses and one or
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more callables defining its compilation::
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from sqlalchemy.ext.compiler import compiles
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from sqlalchemy.sql.expression import ColumnClause
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class MyColumn(ColumnClause):
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inherit_cache = True
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@compiles(MyColumn)
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def compile_mycolumn(element, compiler, **kw):
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return "[%s]" % element.name
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Above, ``MyColumn`` extends :class:`~sqlalchemy.sql.expression.ColumnClause`,
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the base expression element for named column objects. The ``compiles``
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decorator registers itself with the ``MyColumn`` class so that it is invoked
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when the object is compiled to a string::
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from sqlalchemy import select
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s = select(MyColumn('x'), MyColumn('y'))
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print(str(s))
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Produces::
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SELECT [x], [y]
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Dialect-specific compilation rules
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==================================
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Compilers can also be made dialect-specific. The appropriate compiler will be
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invoked for the dialect in use::
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from sqlalchemy.schema import DDLElement
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class AlterColumn(DDLElement):
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inherit_cache = False
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def __init__(self, column, cmd):
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self.column = column
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self.cmd = cmd
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@compiles(AlterColumn)
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def visit_alter_column(element, compiler, **kw):
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return "ALTER COLUMN %s ..." % element.column.name
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@compiles(AlterColumn, 'postgresql')
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def visit_alter_column(element, compiler, **kw):
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return "ALTER TABLE %s ALTER COLUMN %s ..." % (element.table.name,
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element.column.name)
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The second ``visit_alter_table`` will be invoked when any ``postgresql``
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dialect is used.
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.. _compilerext_compiling_subelements:
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Compiling sub-elements of a custom expression construct
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=======================================================
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The ``compiler`` argument is the
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:class:`~sqlalchemy.engine.interfaces.Compiled` object in use. This object
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can be inspected for any information about the in-progress compilation,
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including ``compiler.dialect``, ``compiler.statement`` etc. The
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:class:`~sqlalchemy.sql.compiler.SQLCompiler` and
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:class:`~sqlalchemy.sql.compiler.DDLCompiler` both include a ``process()``
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method which can be used for compilation of embedded attributes::
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from sqlalchemy.sql.expression import Executable, ClauseElement
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class InsertFromSelect(Executable, ClauseElement):
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inherit_cache = False
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def __init__(self, table, select):
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self.table = table
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self.select = select
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@compiles(InsertFromSelect)
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def visit_insert_from_select(element, compiler, **kw):
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return "INSERT INTO %s (%s)" % (
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compiler.process(element.table, asfrom=True, **kw),
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compiler.process(element.select, **kw)
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)
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insert = InsertFromSelect(t1, select(t1).where(t1.c.x>5))
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print(insert)
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Produces::
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"INSERT INTO mytable (SELECT mytable.x, mytable.y, mytable.z
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FROM mytable WHERE mytable.x > :x_1)"
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.. note::
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The above ``InsertFromSelect`` construct is only an example, this actual
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functionality is already available using the
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:meth:`_expression.Insert.from_select` method.
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.. note::
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The above ``InsertFromSelect`` construct probably wants to have "autocommit"
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enabled. See :ref:`enabling_compiled_autocommit` for this step.
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Cross Compiling between SQL and DDL compilers
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---------------------------------------------
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SQL and DDL constructs are each compiled using different base compilers -
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``SQLCompiler`` and ``DDLCompiler``. A common need is to access the
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compilation rules of SQL expressions from within a DDL expression. The
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``DDLCompiler`` includes an accessor ``sql_compiler`` for this reason, such as
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below where we generate a CHECK constraint that embeds a SQL expression::
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@compiles(MyConstraint)
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def compile_my_constraint(constraint, ddlcompiler, **kw):
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kw['literal_binds'] = True
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return "CONSTRAINT %s CHECK (%s)" % (
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constraint.name,
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ddlcompiler.sql_compiler.process(
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constraint.expression, **kw)
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)
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Above, we add an additional flag to the process step as called by
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:meth:`.SQLCompiler.process`, which is the ``literal_binds`` flag. This
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indicates that any SQL expression which refers to a :class:`.BindParameter`
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object or other "literal" object such as those which refer to strings or
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integers should be rendered **in-place**, rather than being referred to as
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a bound parameter; when emitting DDL, bound parameters are typically not
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supported.
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.. _enabling_compiled_autocommit:
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Enabling Autocommit on a Construct
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==================================
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Recall from the section :ref:`autocommit` that the :class:`_engine.Engine`,
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when
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asked to execute a construct in the absence of a user-defined transaction,
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detects if the given construct represents DML or DDL, that is, a data
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modification or data definition statement, which requires (or may require,
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in the case of DDL) that the transaction generated by the DBAPI be committed
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(recall that DBAPI always has a transaction going on regardless of what
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SQLAlchemy does). Checking for this is actually accomplished by checking for
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the "autocommit" execution option on the construct. When building a
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construct like an INSERT derivation, a new DDL type, or perhaps a stored
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procedure that alters data, the "autocommit" option needs to be set in order
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for the statement to function with "connectionless" execution
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(as described in :ref:`dbengine_implicit`).
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Currently a quick way to do this is to subclass :class:`.Executable`, then
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add the "autocommit" flag to the ``_execution_options`` dictionary (note this
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is a "frozen" dictionary which supplies a generative ``union()`` method)::
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from sqlalchemy.sql.expression import Executable, ClauseElement
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class MyInsertThing(Executable, ClauseElement):
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_execution_options = \
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Executable._execution_options.union({'autocommit': True})
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More succinctly, if the construct is truly similar to an INSERT, UPDATE, or
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DELETE, :class:`.UpdateBase` can be used, which already is a subclass
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of :class:`.Executable`, :class:`_expression.ClauseElement` and includes the
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``autocommit`` flag::
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from sqlalchemy.sql.expression import UpdateBase
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class MyInsertThing(UpdateBase):
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def __init__(self, ...):
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...
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DDL elements that subclass :class:`.DDLElement` already have the
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"autocommit" flag turned on.
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Changing the default compilation of existing constructs
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=======================================================
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The compiler extension applies just as well to the existing constructs. When
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overriding the compilation of a built in SQL construct, the @compiles
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decorator is invoked upon the appropriate class (be sure to use the class,
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i.e. ``Insert`` or ``Select``, instead of the creation function such
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as ``insert()`` or ``select()``).
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Within the new compilation function, to get at the "original" compilation
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routine, use the appropriate visit_XXX method - this
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because compiler.process() will call upon the overriding routine and cause
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an endless loop. Such as, to add "prefix" to all insert statements::
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from sqlalchemy.sql.expression import Insert
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@compiles(Insert)
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def prefix_inserts(insert, compiler, **kw):
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return compiler.visit_insert(insert.prefix_with("some prefix"), **kw)
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The above compiler will prefix all INSERT statements with "some prefix" when
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compiled.
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.. _type_compilation_extension:
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Changing Compilation of Types
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=============================
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``compiler`` works for types, too, such as below where we implement the
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MS-SQL specific 'max' keyword for ``String``/``VARCHAR``::
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@compiles(String, 'mssql')
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@compiles(VARCHAR, 'mssql')
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def compile_varchar(element, compiler, **kw):
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if element.length == 'max':
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return "VARCHAR('max')"
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else:
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return compiler.visit_VARCHAR(element, **kw)
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foo = Table('foo', metadata,
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Column('data', VARCHAR('max'))
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)
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Subclassing Guidelines
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======================
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A big part of using the compiler extension is subclassing SQLAlchemy
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expression constructs. To make this easier, the expression and
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schema packages feature a set of "bases" intended for common tasks.
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A synopsis is as follows:
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* :class:`~sqlalchemy.sql.expression.ClauseElement` - This is the root
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expression class. Any SQL expression can be derived from this base, and is
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probably the best choice for longer constructs such as specialized INSERT
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statements.
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* :class:`~sqlalchemy.sql.expression.ColumnElement` - The root of all
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"column-like" elements. Anything that you'd place in the "columns" clause of
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a SELECT statement (as well as order by and group by) can derive from this -
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the object will automatically have Python "comparison" behavior.
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:class:`~sqlalchemy.sql.expression.ColumnElement` classes want to have a
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``type`` member which is expression's return type. This can be established
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at the instance level in the constructor, or at the class level if its
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generally constant::
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class timestamp(ColumnElement):
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type = TIMESTAMP()
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inherit_cache = True
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* :class:`~sqlalchemy.sql.functions.FunctionElement` - This is a hybrid of a
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``ColumnElement`` and a "from clause" like object, and represents a SQL
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function or stored procedure type of call. Since most databases support
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statements along the line of "SELECT FROM <some function>"
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``FunctionElement`` adds in the ability to be used in the FROM clause of a
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``select()`` construct::
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from sqlalchemy.sql.expression import FunctionElement
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class coalesce(FunctionElement):
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name = 'coalesce'
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inherit_cache = True
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@compiles(coalesce)
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def compile(element, compiler, **kw):
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return "coalesce(%s)" % compiler.process(element.clauses, **kw)
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@compiles(coalesce, 'oracle')
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def compile(element, compiler, **kw):
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if len(element.clauses) > 2:
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raise TypeError("coalesce only supports two arguments on Oracle")
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return "nvl(%s)" % compiler.process(element.clauses, **kw)
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* :class:`.DDLElement` - The root of all DDL expressions,
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like CREATE TABLE, ALTER TABLE, etc. Compilation of :class:`.DDLElement`
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subclasses is issued by a :class:`.DDLCompiler` instead of a
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:class:`.SQLCompiler`. :class:`.DDLElement` can also be used as an event hook
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in conjunction with event hooks like :meth:`.DDLEvents.before_create` and
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:meth:`.DDLEvents.after_create`, allowing the construct to be invoked
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automatically during CREATE TABLE and DROP TABLE sequences.
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.. seealso::
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:ref:`metadata_ddl_toplevel` - contains examples of associating
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:class:`.DDL` objects (which are themselves :class:`.DDLElement`
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instances) with :class:`.DDLEvents` event hooks.
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* :class:`~sqlalchemy.sql.expression.Executable` - This is a mixin which
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should be used with any expression class that represents a "standalone"
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SQL statement that can be passed directly to an ``execute()`` method. It
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is already implicit within ``DDLElement`` and ``FunctionElement``.
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Most of the above constructs also respond to SQL statement caching. A
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subclassed construct will want to define the caching behavior for the object,
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which usually means setting the flag ``inherit_cache`` to the value of
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``False`` or ``True``. See the next section :ref:`compilerext_caching`
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for background.
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.. _compilerext_caching:
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Enabling Caching Support for Custom Constructs
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==============================================
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SQLAlchemy as of version 1.4 includes a
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:ref:`SQL compilation caching facility <sql_caching>` which will allow
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equivalent SQL constructs to cache their stringified form, along with other
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structural information used to fetch results from the statement.
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For reasons discussed at :ref:`caching_caveats`, the implementation of this
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caching system takes a conservative approach towards including custom SQL
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constructs and/or subclasses within the caching system. This includes that
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any user-defined SQL constructs, including all the examples for this
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extension, will not participate in caching by default unless they positively
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assert that they are able to do so. The :attr:`.HasCacheKey.inherit_cache`
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attribute when set to ``True`` at the class level of a specific subclass
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will indicate that instances of this class may be safely cached, using the
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cache key generation scheme of the immediate superclass. This applies
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for example to the "synopsis" example indicated previously::
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class MyColumn(ColumnClause):
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inherit_cache = True
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@compiles(MyColumn)
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def compile_mycolumn(element, compiler, **kw):
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return "[%s]" % element.name
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Above, the ``MyColumn`` class does not include any new state that
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affects its SQL compilation; the cache key of ``MyColumn`` instances will
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make use of that of the ``ColumnClause`` superclass, meaning it will take
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into account the class of the object (``MyColumn``), the string name and
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datatype of the object::
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>>> MyColumn("some_name", String())._generate_cache_key()
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CacheKey(
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key=('0', <class '__main__.MyColumn'>,
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'name', 'some_name',
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'type', (<class 'sqlalchemy.sql.sqltypes.String'>,
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('length', None), ('collation', None))
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), bindparams=[])
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For objects that are likely to be **used liberally as components within many
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larger statements**, such as :class:`_schema.Column` subclasses and custom SQL
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datatypes, it's important that **caching be enabled as much as possible**, as
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this may otherwise negatively affect performance.
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An example of an object that **does** contain state which affects its SQL
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compilation is the one illustrated at :ref:`compilerext_compiling_subelements`;
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this is an "INSERT FROM SELECT" construct that combines together a
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:class:`_schema.Table` as well as a :class:`_sql.Select` construct, each of
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which independently affect the SQL string generation of the construct. For
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this class, the example illustrates that it simply does not participate in
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caching::
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class InsertFromSelect(Executable, ClauseElement):
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inherit_cache = False
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def __init__(self, table, select):
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self.table = table
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self.select = select
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@compiles(InsertFromSelect)
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def visit_insert_from_select(element, compiler, **kw):
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return "INSERT INTO %s (%s)" % (
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compiler.process(element.table, asfrom=True, **kw),
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compiler.process(element.select, **kw)
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)
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While it is also possible that the above ``InsertFromSelect`` could be made to
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produce a cache key that is composed of that of the :class:`_schema.Table` and
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:class:`_sql.Select` components together, the API for this is not at the moment
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fully public. However, for an "INSERT FROM SELECT" construct, which is only
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used by itself for specific operations, caching is not as critical as in the
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previous example.
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For objects that are **used in relative isolation and are generally
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standalone**, such as custom :term:`DML` constructs like an "INSERT FROM
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SELECT", **caching is generally less critical** as the lack of caching for such
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a construct will have only localized implications for that specific operation.
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Further Examples
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================
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"UTC timestamp" function
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-------------------------
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A function that works like "CURRENT_TIMESTAMP" except applies the
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appropriate conversions so that the time is in UTC time. Timestamps are best
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stored in relational databases as UTC, without time zones. UTC so that your
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database doesn't think time has gone backwards in the hour when daylight
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savings ends, without timezones because timezones are like character
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encodings - they're best applied only at the endpoints of an application
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(i.e. convert to UTC upon user input, re-apply desired timezone upon display).
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For PostgreSQL and Microsoft SQL Server::
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from sqlalchemy.sql import expression
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from sqlalchemy.ext.compiler import compiles
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from sqlalchemy.types import DateTime
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class utcnow(expression.FunctionElement):
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type = DateTime()
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inherit_cache = True
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@compiles(utcnow, 'postgresql')
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def pg_utcnow(element, compiler, **kw):
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return "TIMEZONE('utc', CURRENT_TIMESTAMP)"
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|
|
||
|
@compiles(utcnow, 'mssql')
|
||
|
def ms_utcnow(element, compiler, **kw):
|
||
|
return "GETUTCDATE()"
|
||
|
|
||
|
Example usage::
|
||
|
|
||
|
from sqlalchemy import (
|
||
|
Table, Column, Integer, String, DateTime, MetaData
|
||
|
)
|
||
|
metadata = MetaData()
|
||
|
event = Table("event", metadata,
|
||
|
Column("id", Integer, primary_key=True),
|
||
|
Column("description", String(50), nullable=False),
|
||
|
Column("timestamp", DateTime, server_default=utcnow())
|
||
|
)
|
||
|
|
||
|
"GREATEST" function
|
||
|
-------------------
|
||
|
|
||
|
The "GREATEST" function is given any number of arguments and returns the one
|
||
|
that is of the highest value - its equivalent to Python's ``max``
|
||
|
function. A SQL standard version versus a CASE based version which only
|
||
|
accommodates two arguments::
|
||
|
|
||
|
from sqlalchemy.sql import expression, case
|
||
|
from sqlalchemy.ext.compiler import compiles
|
||
|
from sqlalchemy.types import Numeric
|
||
|
|
||
|
class greatest(expression.FunctionElement):
|
||
|
type = Numeric()
|
||
|
name = 'greatest'
|
||
|
inherit_cache = True
|
||
|
|
||
|
@compiles(greatest)
|
||
|
def default_greatest(element, compiler, **kw):
|
||
|
return compiler.visit_function(element)
|
||
|
|
||
|
@compiles(greatest, 'sqlite')
|
||
|
@compiles(greatest, 'mssql')
|
||
|
@compiles(greatest, 'oracle')
|
||
|
def case_greatest(element, compiler, **kw):
|
||
|
arg1, arg2 = list(element.clauses)
|
||
|
return compiler.process(case([(arg1 > arg2, arg1)], else_=arg2), **kw)
|
||
|
|
||
|
Example usage::
|
||
|
|
||
|
Session.query(Account).\
|
||
|
filter(
|
||
|
greatest(
|
||
|
Account.checking_balance,
|
||
|
Account.savings_balance) > 10000
|
||
|
)
|
||
|
|
||
|
"false" expression
|
||
|
------------------
|
||
|
|
||
|
Render a "false" constant expression, rendering as "0" on platforms that
|
||
|
don't have a "false" constant::
|
||
|
|
||
|
from sqlalchemy.sql import expression
|
||
|
from sqlalchemy.ext.compiler import compiles
|
||
|
|
||
|
class sql_false(expression.ColumnElement):
|
||
|
inherit_cache = True
|
||
|
|
||
|
@compiles(sql_false)
|
||
|
def default_false(element, compiler, **kw):
|
||
|
return "false"
|
||
|
|
||
|
@compiles(sql_false, 'mssql')
|
||
|
@compiles(sql_false, 'mysql')
|
||
|
@compiles(sql_false, 'oracle')
|
||
|
def int_false(element, compiler, **kw):
|
||
|
return "0"
|
||
|
|
||
|
Example usage::
|
||
|
|
||
|
from sqlalchemy import select, union_all
|
||
|
|
||
|
exp = union_all(
|
||
|
select(users.c.name, sql_false().label("enrolled")),
|
||
|
select(customers.c.name, customers.c.enrolled)
|
||
|
)
|
||
|
|
||
|
"""
|
||
|
from .. import exc
|
||
|
from .. import util
|
||
|
from ..sql import sqltypes
|
||
|
|
||
|
|
||
|
def compiles(class_, *specs):
|
||
|
"""Register a function as a compiler for a
|
||
|
given :class:`_expression.ClauseElement` type."""
|
||
|
|
||
|
def decorate(fn):
|
||
|
# get an existing @compiles handler
|
||
|
existing = class_.__dict__.get("_compiler_dispatcher", None)
|
||
|
|
||
|
# get the original handler. All ClauseElement classes have one
|
||
|
# of these, but some TypeEngine classes will not.
|
||
|
existing_dispatch = getattr(class_, "_compiler_dispatch", None)
|
||
|
|
||
|
if not existing:
|
||
|
existing = _dispatcher()
|
||
|
|
||
|
if existing_dispatch:
|
||
|
|
||
|
def _wrap_existing_dispatch(element, compiler, **kw):
|
||
|
try:
|
||
|
return existing_dispatch(element, compiler, **kw)
|
||
|
except exc.UnsupportedCompilationError as uce:
|
||
|
util.raise_(
|
||
|
exc.UnsupportedCompilationError(
|
||
|
compiler,
|
||
|
type(element),
|
||
|
message="%s construct has no default "
|
||
|
"compilation handler." % type(element),
|
||
|
),
|
||
|
from_=uce,
|
||
|
)
|
||
|
|
||
|
existing.specs["default"] = _wrap_existing_dispatch
|
||
|
|
||
|
# TODO: why is the lambda needed ?
|
||
|
setattr(
|
||
|
class_,
|
||
|
"_compiler_dispatch",
|
||
|
lambda *arg, **kw: existing(*arg, **kw),
|
||
|
)
|
||
|
setattr(class_, "_compiler_dispatcher", existing)
|
||
|
|
||
|
if specs:
|
||
|
for s in specs:
|
||
|
existing.specs[s] = fn
|
||
|
|
||
|
else:
|
||
|
existing.specs["default"] = fn
|
||
|
return fn
|
||
|
|
||
|
return decorate
|
||
|
|
||
|
|
||
|
def deregister(class_):
|
||
|
"""Remove all custom compilers associated with a given
|
||
|
:class:`_expression.ClauseElement` type.
|
||
|
|
||
|
"""
|
||
|
|
||
|
if hasattr(class_, "_compiler_dispatcher"):
|
||
|
class_._compiler_dispatch = class_._original_compiler_dispatch
|
||
|
del class_._compiler_dispatcher
|
||
|
|
||
|
|
||
|
class _dispatcher(object):
|
||
|
def __init__(self):
|
||
|
self.specs = {}
|
||
|
|
||
|
def __call__(self, element, compiler, **kw):
|
||
|
# TODO: yes, this could also switch off of DBAPI in use.
|
||
|
fn = self.specs.get(compiler.dialect.name, None)
|
||
|
if not fn:
|
||
|
try:
|
||
|
fn = self.specs["default"]
|
||
|
except KeyError as ke:
|
||
|
util.raise_(
|
||
|
exc.UnsupportedCompilationError(
|
||
|
compiler,
|
||
|
type(element),
|
||
|
message="%s construct has no default "
|
||
|
"compilation handler." % type(element),
|
||
|
),
|
||
|
replace_context=ke,
|
||
|
)
|
||
|
|
||
|
# if compilation includes add_to_result_map, collect add_to_result_map
|
||
|
# arguments from the user-defined callable, which are probably none
|
||
|
# because this is not public API. if it wasn't called, then call it
|
||
|
# ourselves.
|
||
|
arm = kw.get("add_to_result_map", None)
|
||
|
if arm:
|
||
|
arm_collection = []
|
||
|
kw["add_to_result_map"] = lambda *args: arm_collection.append(args)
|
||
|
|
||
|
expr = fn(element, compiler, **kw)
|
||
|
|
||
|
if arm:
|
||
|
if not arm_collection:
|
||
|
arm_collection.append(
|
||
|
(None, None, (element,), sqltypes.NULLTYPE)
|
||
|
)
|
||
|
for tup in arm_collection:
|
||
|
arm(*tup)
|
||
|
return expr
|