U kf\I @sddlmZddlmZddlmZddlmZddlmZddlmZddlmZddlm Z d d l m Z d d l m Z d d l mZd d l mZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZd dlmZerd dl mZd dl m Z d dl m!Z!d dl m"Z"d dl m#Z#d d l m$Z$d d!l m%Z%d d"l m&Z&d d#l m'Z'd d$l m(Z(d d%l m)Z)d d&l m*Z*d d'l m+Z+d d(l m,Z-d d)l.m/Z/d d*lm0Z0d d+lm1Z1d d,lm2Z2d d-lm3Z3ed.ed/Z4dd2d3d4d5d6d7d8Z5dd9d3d4d:d;dd?d@dAdBZ7d>d?d@dCdDZ8ddEdFdGdHdIZ9d>d?d@dJdKZ:d>d?d@dLdMZ;ddNdNdOd4d4dPdQdRdSZed\d]d^d_d`Z?ed\dadbdcddd`Z?ed\dadedfdgdhd`Z?ed\dadedidjdkdld`Z?ed\dadedidmdndodpd`Z?ed\dadedidmdqdrdsdtd`Z?ed\dadedidmdqdudvdwdxd`Z?ed\dadedidmdqdudydzd{ d|d`Z?ed\dadedidmdqdudyd}d~d dd`Z?ed\dadedidmdqdudyd}ddd dd`Z?edddddd`Z?dddddd`Z?dddddddZ@ddNdd3dddddZAd>d?d@ddZBd>d?d@ddZCd0d1ddd3d4ddddZDd0S)) annotations)Any)Optional)overload)Tuple) TYPE_CHECKING)TypeVar)Union) coercions)roles)_ColumnsClauseArgument)_no_kw) ColumnClause)Alias)CompoundSelectExists) FromClauseJoin)Lateral)LateralFromClause)NamedFromClause)Select TableClause) TableSampleValues)_FromClauseArgument)_OnClauseArgument)#_SelectStatementForCompoundArgument)_T0)_T1)_T2)_T3)_T4)_T5)_T6)_T7)_T8)_T9)_TypedColumnClauseArgument)Function)CTE)HasCTE) ScalarSelect) SelectBase_T)boundNFrz Optional[str]boolr) selectablenameflatreturncCstj|||dS)a,Return a named alias of the given :class:`.FromClause`. For :class:`.Table` and :class:`.Join` objects, the return type is the :class:`_expression.Alias` object. Other kinds of :class:`.NamedFromClause` objects may be returned for other kinds of :class:`.FromClause` objects. The named alias represents any :class:`_expression.FromClause` with an alternate name assigned within SQL, typically using the ``AS`` clause when generated, e.g. ``SELECT * FROM table AS aliasname``. Equivalent functionality is available via the :meth:`_expression.FromClause.alias` method available on all :class:`_expression.FromClause` objects. :param selectable: any :class:`_expression.FromClause` subclass, such as a table, select statement, etc. :param name: string name to be assigned as the alias. If ``None``, a name will be deterministically generated at compile time. Deterministic means the name is guaranteed to be unique against other constructs used in the same statement, and will also be the same name for each successive compilation of the same statement object. :param flat: Will be passed through to if the given selectable is an instance of :class:`_expression.Join` - see :meth:`_expression.Join.alias` for details. )r7r8)r_factory)r6r7r8r;W/opt/hc_python/lib64/python3.8/site-packages/sqlalchemy/sql/_selectable_constructors.pyalias=sr=r0r/)r6r7 recursiver9cCsttj|j||dS)zReturn a new :class:`_expression.CTE`, or Common Table Expression instance. Please see :meth:`_expression.HasCTE.cte` for detail on CTE usage. )r7r>)r expectr Z HasCTERolecte)r6r7r>r;r;r<r@_s r@r"r)selectsr9cGs tj|S)zReturn an ``EXCEPT`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. :param \*selects: a list of :class:`_expression.Select` instances. )rZ_create_exceptrAr;r;r<except_ms rCcGs tj|S)zReturn an ``EXCEPT ALL`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. :param \*selects: a list of :class:`_expression.Select` instances. )rZ_create_except_allrBr;r;r< except_all|s rDzKOptional[Union[_ColumnsClauseArgument[Any], SelectBase, ScalarSelect[Any]]]r) __argumentr9cCst|S)aConstruct a new :class:`_expression.Exists` construct. The :func:`_sql.exists` can be invoked by itself to produce an :class:`_sql.Exists` construct, which will accept simple WHERE criteria:: exists_criteria = exists().where(table1.c.col1 == table2.c.col2) However, for greater flexibility in constructing the SELECT, an existing :class:`_sql.Select` construct may be converted to an :class:`_sql.Exists`, most conveniently by making use of the :meth:`_sql.SelectBase.exists` method:: exists_criteria = ( select(table2.c.col2). where(table1.c.col1 == table2.c.col2). exists() ) The EXISTS criteria is then used inside of an enclosing SELECT:: stmt = select(table1.c.col1).where(exists_criteria) The above statement will then be of the form:: SELECT col1 FROM table1 WHERE EXISTS (SELECT table2.col2 FROM table2 WHERE table2.col2 = table1.col1) .. seealso:: :ref:`tutorial_exists` - in the :term:`2.0 style` tutorial. :meth:`_sql.SelectBase.exists` - method to transform a ``SELECT`` to an ``EXISTS`` clause. r)rEr;r;r<existss*rFcGs tj|S)zReturn an ``INTERSECT`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. :param \*selects: a list of :class:`_expression.Select` instances. )rZ_create_intersectrBr;r;r< intersects rGcGs tj|S)zReturn an ``INTERSECT ALL`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. :param \*selects: a list of :class:`_expression.Select` instances. )rZ_create_intersect_allrBr;r;r< intersect_alls rHr zOptional[_OnClauseArgument]r)leftrightonclauseisouterfullr9cCst|||||S)aProduce a :class:`_expression.Join` object, given two :class:`_expression.FromClause` expressions. E.g.:: j = join(user_table, address_table, user_table.c.id == address_table.c.user_id) stmt = select(user_table).select_from(j) would emit SQL along the lines of:: SELECT user.id, user.name FROM user JOIN address ON user.id = address.user_id Similar functionality is available given any :class:`_expression.FromClause` object (e.g. such as a :class:`_schema.Table`) using the :meth:`_expression.FromClause.join` method. :param left: The left side of the join. :param right: the right side of the join; this is any :class:`_expression.FromClause` object such as a :class:`_schema.Table` object, and may also be a selectable-compatible object such as an ORM-mapped class. :param onclause: a SQL expression representing the ON clause of the join. If left at ``None``, :meth:`_expression.FromClause.join` will attempt to join the two tables based on a foreign key relationship. :param isouter: if True, render a LEFT OUTER JOIN, instead of JOIN. :param full: if True, render a FULL OUTER JOIN, instead of JOIN. .. seealso:: :meth:`_expression.FromClause.join` - method form, based on a given left side. :class:`_expression.Join` - the type of object produced. r)rIrJrKrLrMr;r;r<joins5rNz&Union[SelectBase, _FromClauseArgument]r)r6r7r9cCstj||dS)aQReturn a :class:`_expression.Lateral` object. :class:`_expression.Lateral` is an :class:`_expression.Alias` subclass that represents a subquery with the LATERAL keyword applied to it. The special behavior of a LATERAL subquery is that it appears in the FROM clause of an enclosing SELECT, but may correlate to other FROM clauses of that SELECT. It is a special case of subquery only supported by a small number of backends, currently more recent PostgreSQL versions. .. seealso:: :ref:`tutorial_lateral_correlation` - overview of usage. )r7)rr:)r6r7r;r;r<lateralsrO)rIrJrKrMr9cCst|||d|dS)aReturn an ``OUTER JOIN`` clause element. The returned object is an instance of :class:`_expression.Join`. Similar functionality is also available via the :meth:`_expression.FromClause.outerjoin` method on any :class:`_expression.FromClause`. :param left: The left side of the join. :param right: The right side of the join. :param onclause: Optional criterion for the ``ON`` clause, is derived from foreign key relationships established between left and right otherwise. To chain joins together, use the :meth:`_expression.FromClause.join` or :meth:`_expression.FromClause.outerjoin` methods on the resulting :class:`_expression.Join` object. T)rLrMr)rIrJrKrMr;r;r< outerjoin'srPz _TCCA[_T0]zSelect[Tuple[_T0]])__ent0r9cCsdSNr;)rQr;r;r<selectLsrSz _TCCA[_T1]zSelect[Tuple[_T0, _T1]])rQ__ent1r9cCsdSrRr;)rQrTr;r;r<rSPsz _TCCA[_T2]zSelect[Tuple[_T0, _T1, _T2]])rQrT__ent2r9cCsdSrRr;)rQrTrUr;r;r<rSVsz _TCCA[_T3]z!Select[Tuple[_T0, _T1, _T2, _T3]])rQrTrU__ent3r9cCsdSrRr;)rQrTrUrVr;r;r<rS\sz _TCCA[_T4]z&Select[Tuple[_T0, _T1, _T2, _T3, _T4]])rQrTrUrV__ent4r9cCsdSrRr;)rQrTrUrVrWr;r;r<rSesz _TCCA[_T5]z+Select[Tuple[_T0, _T1, _T2, _T3, _T4, _T5]])rQrTrUrVrW__ent5r9cCsdSrRr;)rQrTrUrVrWrXr;r;r<rSosz _TCCA[_T6]z0Select[Tuple[_T0, _T1, _T2, _T3, _T4, _T5, _T6]])rQrTrUrVrWrX__ent6r9cCsdSrRr;)rQrTrUrVrWrXrYr;r;r<rSzs z _TCCA[_T7]z5Select[Tuple[_T0, _T1, _T2, _T3, _T4, _T5, _T6, _T7]]) rQrTrUrVrWrXrY__ent7r9cCsdSrRr;)rQrTrUrVrWrXrYrZr;r;r<rSs z _TCCA[_T8]z:Select[Tuple[_T0, _T1, _T2, _T3, _T4, _T5, _T6, _T7, _T8]]) rQrTrUrVrWrXrYrZ__ent8r9c CsdSrRr;) rQrTrUrVrWrXrYrZr[r;r;r<rSs z _TCCA[_T9]z?Select[Tuple[_T0, _T1, _T2, _T3, _T4, _T5, _T6, _T7, _T8, _T9]]) rQrTrUrVrWrXrYrZr[__ent9r9c CsdSrRr;) rQrTrUrVrWrXrYrZr[r\r;r;r<rSs z_ColumnsClauseArgument[Any]rz Select[Any])entities__kwr9cOsdSrRr;r]r^r;r;r<rSscOs|r tt|S)aoConstruct a new :class:`_expression.Select`. .. versionadded:: 1.4 - The :func:`_sql.select` function now accepts column arguments positionally. The top-level :func:`_sql.select` function will automatically use the 1.x or 2.x style API based on the incoming arguments; using :func:`_sql.select` from the ``sqlalchemy.future`` module will enforce that only the 2.x style constructor is used. Similar functionality is also available via the :meth:`_expression.FromClause.select` method on any :class:`_expression.FromClause`. .. seealso:: :ref:`tutorial_selecting_data` - in the :ref:`unified_tutorial` :param \*entities: Entities to SELECT from. For Core usage, this is typically a series of :class:`_expression.ColumnElement` and / or :class:`_expression.FromClause` objects which will form the columns clause of the resulting statement. For those objects that are instances of :class:`_expression.FromClause` (typically :class:`_schema.Table` or :class:`_expression.Alias` objects), the :attr:`_expression.FromClause.c` collection is extracted to form a collection of :class:`_expression.ColumnElement` objects. This parameter will also accept :class:`_expression.TextClause` constructs as given, as well as ORM-mapped classes. )rrr_r;r;r<rSs'strzColumnClause[Any]r)r7columnskwr9cOst|f||S)a;Produce a new :class:`_expression.TableClause`. The object returned is an instance of :class:`_expression.TableClause`, which represents the "syntactical" portion of the schema-level :class:`_schema.Table` object. It may be used to construct lightweight table constructs. :param name: Name of the table. :param columns: A collection of :func:`_expression.column` constructs. :param schema: The schema name for this table. .. versionadded:: 1.3.18 :func:`_expression.table` can now accept a ``schema`` argument. r)r7rarbr;r;r<tablesrczUnion[float, Function[Any]]z*Optional[roles.ExpressionElementRole[Any]]r)r6samplingr7seedr9cCstj||||dS)aReturn a :class:`_expression.TableSample` object. :class:`_expression.TableSample` is an :class:`_expression.Alias` subclass that represents a table with the TABLESAMPLE clause applied to it. :func:`_expression.tablesample` is also available from the :class:`_expression.FromClause` class via the :meth:`_expression.FromClause.tablesample` method. The TABLESAMPLE clause allows selecting a randomly selected approximate percentage of rows from a table. It supports multiple sampling methods, most commonly BERNOULLI and SYSTEM. e.g.:: from sqlalchemy import func selectable = people.tablesample( func.bernoulli(1), name='alias', seed=func.random()) stmt = select(selectable.c.people_id) Assuming ``people`` with a column ``people_id``, the above statement would render as:: SELECT alias.people_id FROM people AS alias TABLESAMPLE bernoulli(:bernoulli_1) REPEATABLE (random()) :param sampling: a ``float`` percentage between 0 and 100 or :class:`_functions.Function`. :param name: optional alias name :param seed: any real-valued SQL expression. When specified, the REPEATABLE sub-clause is also rendered. )r7re)rr:)r6rdr7rer;r;r< tablesamples.rfcGs tj|S)aReturn a ``UNION`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. A similar :func:`union()` method is available on all :class:`_expression.FromClause` subclasses. :param \*selects: a list of :class:`_expression.Select` instances. :param \**kwargs: available keyword arguments are the same as those of :func:`select`. )rZ _create_unionrBr;r;r<union,srgcGs tj|S)aEReturn a ``UNION ALL`` of multiple selectables. The returned object is an instance of :class:`_expression.CompoundSelect`. A similar :func:`union_all()` method is available on all :class:`_expression.FromClause` subclasses. :param \*selects: a list of :class:`_expression.Select` instances. )rZ_create_union_allrBr;r;r< union_allBsrh)r7 literal_bindsr)rar7rir9cGst|||dS)aConstruct a :class:`_expression.Values` construct. The column expressions and the actual data for :class:`_expression.Values` are given in two separate steps. The constructor receives the column expressions typically as :func:`_expression.column` constructs, and the data is then passed via the :meth:`_expression.Values.data` method as a list, which can be called multiple times to add more data, e.g.:: from sqlalchemy import column from sqlalchemy import values value_expr = values( column('id', Integer), column('name', String), name="my_values" ).data( [(1, 'name1'), (2, 'name2'), (3, 'name3')] ) :param \*columns: column expressions, typically composed using :func:`_expression.column` objects. :param name: the name for this VALUES construct. If omitted, the VALUES construct will be unnamed in a SQL expression. Different backends may have different requirements here. :param literal_binds: Defaults to False. Whether or not to render the data values inline in the SQL output, rather than using bound parameters. )rir7r)r7rirar;r;r<valuesTs'rj)NF)NF)N)NFF)N)NF)NN)E __future__rtypingrrrrrrr r r Z_typingr relementsrr6rrrrrrrrrrrrr r!r"r#r$r%r&r'r(r)r*r+r,r-Z_TCCAZ functionsr.r/r0r1r2r3r=r@rCrDrFrGrHrNrOrPrSrcrfrgrhrjr;r;r;r<s                                             #-:%    " $,1