# mssql/base.py # Copyright (C) 2005-2018 the SQLAlchemy authors and contributors # # # This module is part of SQLAlchemy and is released under # the MIT License: http://www.opensource.org/licenses/mit-license.php """ .. dialect:: mssql :name: Microsoft SQL Server Auto Increment Behavior ----------------------- SQL Server provides so-called "auto incrementing" behavior using the ``IDENTITY`` construct, which can be placed on an integer primary key. SQLAlchemy considers ``IDENTITY`` within its default "autoincrement" behavior, described at :paramref:`.Column.autoincrement`; this means that by default, the first integer primary key column in a :class:`.Table` will be considered to be the identity column and will generate DDL as such:: from sqlalchemy import Table, MetaData, Column, Integer m = MetaData() t = Table('t', m, Column('id', Integer, primary_key=True), Column('x', Integer)) m.create_all(engine) The above example will generate DDL as: .. sourcecode:: sql CREATE TABLE t ( id INTEGER NOT NULL IDENTITY(1,1), x INTEGER NULL, PRIMARY KEY (id) ) For the case where this default generation of ``IDENTITY`` is not desired, specify ``autoincrement=False`` on all integer primary key columns:: m = MetaData() t = Table('t', m, Column('id', Integer, primary_key=True, autoincrement=False), Column('x', Integer)) m.create_all(engine) .. note:: An INSERT statement which refers to an explicit value for such a column is prohibited by SQL Server, however SQLAlchemy will detect this and modify the ``IDENTITY_INSERT`` flag accordingly at statement execution time. As this is not a high performing process, care should be taken to set the ``autoincrement`` flag appropriately for columns that will not actually require IDENTITY behavior. Controlling "Start" and "Increment" ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Specific control over the parameters of the ``IDENTITY`` value is supported using the :class:`.schema.Sequence` object. While this object normally represents an explicit "sequence" for supporting backends, on SQL Server it is re-purposed to specify behavior regarding the identity column, including support of the "start" and "increment" values:: from sqlalchemy import Table, Integer, Sequence, Column Table('test', metadata, Column('id', Integer, Sequence('blah', start=100, increment=10), primary_key=True), Column('name', String(20)) ).create(some_engine) would yield: .. sourcecode:: sql CREATE TABLE test ( id INTEGER NOT NULL IDENTITY(100,10) PRIMARY KEY, name VARCHAR(20) NULL, ) Note that the ``start`` and ``increment`` values for sequences are optional and will default to 1,1. INSERT behavior ^^^^^^^^^^^^^^^^ Handling of the ``IDENTITY`` column at INSERT time involves two key techniques. The most common is being able to fetch the "last inserted value" for a given ``IDENTITY`` column, a process which SQLAlchemy performs implicitly in many cases, most importantly within the ORM. The process for fetching this value has several variants: * In the vast majority of cases, RETURNING is used in conjunction with INSERT statements on SQL Server in order to get newly generated primary key values: .. sourcecode:: sql INSERT INTO t (x) OUTPUT inserted.id VALUES (?) * When RETURNING is not available or has been disabled via ``implicit_returning=False``, either the ``scope_identity()`` function or the ``@@identity`` variable is used; behavior varies by backend: * when using PyODBC, the phrase ``; select scope_identity()`` will be appended to the end of the INSERT statement; a second result set will be fetched in order to receive the value. Given a table as:: t = Table('t', m, Column('id', Integer, primary_key=True), Column('x', Integer), implicit_returning=False) an INSERT will look like: .. sourcecode:: sql INSERT INTO t (x) VALUES (?); select scope_identity() * Other dialects such as pymssql will call upon ``SELECT scope_identity() AS lastrowid`` subsequent to an INSERT statement. If the flag ``use_scope_identity=False`` is passed to :func:`.create_engine`, the statement ``SELECT @@identity AS lastrowid`` is used instead. A table that contains an ``IDENTITY`` column will prohibit an INSERT statement that refers to the identity column explicitly. The SQLAlchemy dialect will detect when an INSERT construct, created using a core :func:`.insert` construct (not a plain string SQL), refers to the identity column, and in this case will emit ``SET IDENTITY_INSERT ON`` prior to the insert statement proceeding, and ``SET IDENTITY_INSERT OFF`` subsequent to the execution. Given this example:: m = MetaData() t = Table('t', m, Column('id', Integer, primary_key=True), Column('x', Integer)) m.create_all(engine) engine.execute(t.insert(), {'id': 1, 'x':1}, {'id':2, 'x':2}) The above column will be created with IDENTITY, however the INSERT statement we emit is specifying explicit values. In the echo output we can see how SQLAlchemy handles this: .. sourcecode:: sql CREATE TABLE t ( id INTEGER NOT NULL IDENTITY(1,1), x INTEGER NULL, PRIMARY KEY (id) ) COMMIT SET IDENTITY_INSERT t ON INSERT INTO t (id, x) VALUES (?, ?) ((1, 1), (2, 2)) SET IDENTITY_INSERT t OFF COMMIT This is an auxiliary use case suitable for testing and bulk insert scenarios. MAX on VARCHAR / NVARCHAR ------------------------- SQL Server supports the special string "MAX" within the :class:`.sqltypes.VARCHAR` and :class:`.sqltypes.NVARCHAR` datatypes, to indicate "maximum length possible". The dialect currently handles this as a length of "None" in the base type, rather than supplying a dialect-specific version of these types, so that a base type specified such as ``VARCHAR(None)`` can assume "unlengthed" behavior on more than one backend without using dialect-specific types. To build a SQL Server VARCHAR or NVARCHAR with MAX length, use None:: my_table = Table( 'my_table', metadata, Column('my_data', VARCHAR(None)), Column('my_n_data', NVARCHAR(None)) ) Collation Support ----------------- Character collations are supported by the base string types, specified by the string argument "collation":: from sqlalchemy import VARCHAR Column('login', VARCHAR(32, collation='Latin1_General_CI_AS')) When such a column is associated with a :class:`.Table`, the CREATE TABLE statement for this column will yield:: login VARCHAR(32) COLLATE Latin1_General_CI_AS NULL .. versionadded:: 0.8 Character collations are now part of the base string types. LIMIT/OFFSET Support -------------------- MSSQL has no support for the LIMIT or OFFSET keywords. LIMIT is supported directly through the ``TOP`` Transact SQL keyword:: select.limit will yield:: SELECT TOP n If using SQL Server 2005 or above, LIMIT with OFFSET support is available through the ``ROW_NUMBER OVER`` construct. For versions below 2005, LIMIT with OFFSET usage will fail. .. _mssql_isolation_level: Transaction Isolation Level --------------------------- All SQL Server dialects support setting of transaction isolation level both via a dialect-specific parameter :paramref:`.create_engine.isolation_level` accepted by :func:`.create_engine`, as well as the :paramref:`.Connection.execution_options.isolation_level` argument as passed to :meth:`.Connection.execution_options`. This feature works by issuing the command ``SET TRANSACTION ISOLATION LEVEL `` for each new connection. To set isolation level using :func:`.create_engine`:: engine = create_engine( "mssql+pyodbc://scott:tiger@ms_2008", isolation_level="REPEATABLE READ" ) To set using per-connection execution options:: connection = engine.connect() connection = connection.execution_options( isolation_level="READ COMMITTED" ) Valid values for ``isolation_level`` include: * ``AUTOCOMMIT`` - pyodbc / pymssql-specific * ``READ COMMITTED`` * ``READ UNCOMMITTED`` * ``REPEATABLE READ`` * ``SERIALIZABLE`` * ``SNAPSHOT`` - specific to SQL Server .. versionadded:: 1.1 support for isolation level setting on Microsoft SQL Server. .. versionadded:: 1.2 added AUTOCOMMIT isolation level setting Nullability ----------- MSSQL has support for three levels of column nullability. The default nullability allows nulls and is explicit in the CREATE TABLE construct:: name VARCHAR(20) NULL If ``nullable=None`` is specified then no specification is made. In other words the database's configured default is used. This will render:: name VARCHAR(20) If ``nullable`` is ``True`` or ``False`` then the column will be ``NULL`` or ``NOT NULL`` respectively. Date / Time Handling -------------------- DATE and TIME are supported. Bind parameters are converted to datetime.datetime() objects as required by most MSSQL drivers, and results are processed from strings if needed. The DATE and TIME types are not available for MSSQL 2005 and previous - if a server version below 2008 is detected, DDL for these types will be issued as DATETIME. .. _mssql_large_type_deprecation: Large Text/Binary Type Deprecation ---------------------------------- Per `SQL Server 2012/2014 Documentation `_, the ``NTEXT``, ``TEXT`` and ``IMAGE`` datatypes are to be removed from SQL Server in a future release. SQLAlchemy normally relates these types to the :class:`.UnicodeText`, :class:`.Text` and :class:`.LargeBinary` datatypes. In order to accommodate this change, a new flag ``deprecate_large_types`` is added to the dialect, which will be automatically set based on detection of the server version in use, if not otherwise set by the user. The behavior of this flag is as follows: * When this flag is ``True``, the :class:`.UnicodeText`, :class:`.Text` and :class:`.LargeBinary` datatypes, when used to render DDL, will render the types ``NVARCHAR(max)``, ``VARCHAR(max)``, and ``VARBINARY(max)``, respectively. This is a new behavior as of the addition of this flag. * When this flag is ``False``, the :class:`.UnicodeText`, :class:`.Text` and :class:`.LargeBinary` datatypes, when used to render DDL, will render the types ``NTEXT``, ``TEXT``, and ``IMAGE``, respectively. This is the long-standing behavior of these types. * The flag begins with the value ``None``, before a database connection is established. If the dialect is used to render DDL without the flag being set, it is interpreted the same as ``False``. * On first connection, the dialect detects if SQL Server version 2012 or greater is in use; if the flag is still at ``None``, it sets it to ``True`` or ``False`` based on whether 2012 or greater is detected. * The flag can be set to either ``True`` or ``False`` when the dialect is created, typically via :func:`.create_engine`:: eng = create_engine("mssql+pymssql://user:pass@host/db", deprecate_large_types=True) * Complete control over whether the "old" or "new" types are rendered is available in all SQLAlchemy versions by using the UPPERCASE type objects instead: :class:`.NVARCHAR`, :class:`.VARCHAR`, :class:`.types.VARBINARY`, :class:`.TEXT`, :class:`.mssql.NTEXT`, :class:`.mssql.IMAGE` will always remain fixed and always output exactly that type. .. versionadded:: 1.0.0 .. _multipart_schema_names: Multipart Schema Names ---------------------- SQL Server schemas sometimes require multiple parts to their "schema" qualifier, that is, including the database name and owner name as separate tokens, such as ``mydatabase.dbo.some_table``. These multipart names can be set at once using the :paramref:`.Table.schema` argument of :class:`.Table`:: Table( "some_table", metadata, Column("q", String(50)), schema="mydatabase.dbo" ) When performing operations such as table or component reflection, a schema argument that contains a dot will be split into separate "database" and "owner" components in order to correctly query the SQL Server information schema tables, as these two values are stored separately. Additionally, when rendering the schema name for DDL or SQL, the two components will be quoted separately for case sensitive names and other special characters. Given an argument as below:: Table( "some_table", metadata, Column("q", String(50)), schema="MyDataBase.dbo" ) The above schema would be rendered as ``[MyDataBase].dbo``, and also in reflection, would be reflected using "dbo" as the owner and "MyDataBase" as the database name. To control how the schema name is broken into database / owner, specify brackets (which in SQL Server are quoting characters) in the name. Below, the "owner" will be considered as ``MyDataBase.dbo`` and the "database" will be None:: Table( "some_table", metadata, Column("q", String(50)), schema="[MyDataBase.dbo]" ) To individually specify both database and owner name with special characters or embedded dots, use two sets of brackets:: Table( "some_table", metadata, Column("q", String(50)), schema="[MyDataBase.Period].[MyOwner.Dot]" ) .. versionchanged:: 1.2 the SQL Server dialect now treats brackets as identifier delimeters splitting the schema into separate database and owner tokens, to allow dots within either name itself. .. _legacy_schema_rendering: Legacy Schema Mode ------------------ Very old versions of the MSSQL dialect introduced the behavior such that a schema-qualified table would be auto-aliased when used in a SELECT statement; given a table:: account_table = Table( 'account', metadata, Column('id', Integer, primary_key=True), Column('info', String(100)), schema="customer_schema" ) this legacy mode of rendering would assume that "customer_schema.account" would not be accepted by all parts of the SQL statement, as illustrated below:: >>> eng = create_engine("mssql+pymssql://mydsn", legacy_schema_aliasing=True) >>> print(account_table.select().compile(eng)) SELECT account_1.id, account_1.info FROM customer_schema.account AS account_1 This mode of behavior is now off by default, as it appears to have served no purpose; however in the case that legacy applications rely upon it, it is available using the ``legacy_schema_aliasing`` argument to :func:`.create_engine` as illustrated above. .. versionchanged:: 1.1 the ``legacy_schema_aliasing`` flag introduced in version 1.0.5 to allow disabling of legacy mode for schemas now defaults to False. .. _mssql_indexes: Clustered Index Support ----------------------- The MSSQL dialect supports clustered indexes (and primary keys) via the ``mssql_clustered`` option. This option is available to :class:`.Index`, :class:`.UniqueConstraint`. and :class:`.PrimaryKeyConstraint`. To generate a clustered index:: Index("my_index", table.c.x, mssql_clustered=True) which renders the index as ``CREATE CLUSTERED INDEX my_index ON table (x)``. To generate a clustered primary key use:: Table('my_table', metadata, Column('x', ...), Column('y', ...), PrimaryKeyConstraint("x", "y", mssql_clustered=True)) which will render the table, for example, as:: CREATE TABLE my_table (x INTEGER NOT NULL, y INTEGER NOT NULL, PRIMARY KEY CLUSTERED (x, y)) Similarly, we can generate a clustered unique constraint using:: Table('my_table', metadata, Column('x', ...), Column('y', ...), PrimaryKeyConstraint("x"), UniqueConstraint("y", mssql_clustered=True), ) To explicitly request a non-clustered primary key (for example, when a separate clustered index is desired), use:: Table('my_table', metadata, Column('x', ...), Column('y', ...), PrimaryKeyConstraint("x", "y", mssql_clustered=False)) which will render the table, for example, as:: CREATE TABLE my_table (x INTEGER NOT NULL, y INTEGER NOT NULL, PRIMARY KEY NONCLUSTERED (x, y)) .. versionchanged:: 1.1 the ``mssql_clustered`` option now defaults to None, rather than False. ``mssql_clustered=False`` now explicitly renders the NONCLUSTERED clause, whereas None omits the CLUSTERED clause entirely, allowing SQL Server defaults to take effect. MSSQL-Specific Index Options ----------------------------- In addition to clustering, the MSSQL dialect supports other special options for :class:`.Index`. INCLUDE ^^^^^^^ The ``mssql_include`` option renders INCLUDE(colname) for the given string names:: Index("my_index", table.c.x, mssql_include=['y']) would render the index as ``CREATE INDEX my_index ON table (x) INCLUDE (y)`` .. versionadded:: 0.8 Index ordering ^^^^^^^^^^^^^^ Index ordering is available via functional expressions, such as:: Index("my_index", table.c.x.desc()) would render the index as ``CREATE INDEX my_index ON table (x DESC)`` .. versionadded:: 0.8 .. seealso:: :ref:`schema_indexes_functional` Compatibility Levels -------------------- MSSQL supports the notion of setting compatibility levels at the database level. This allows, for instance, to run a database that is compatible with SQL2000 while running on a SQL2005 database server. ``server_version_info`` will always return the database server version information (in this case SQL2005) and not the compatibility level information. Because of this, if running under a backwards compatibility mode SQAlchemy may attempt to use T-SQL statements that are unable to be parsed by the database server. Triggers -------- SQLAlchemy by default uses OUTPUT INSERTED to get at newly generated primary key values via IDENTITY columns or other server side defaults. MS-SQL does not allow the usage of OUTPUT INSERTED on tables that have triggers. To disable the usage of OUTPUT INSERTED on a per-table basis, specify ``implicit_returning=False`` for each :class:`.Table` which has triggers:: Table('mytable', metadata, Column('id', Integer, primary_key=True), # ..., implicit_returning=False ) Declarative form:: class MyClass(Base): # ... __table_args__ = {'implicit_returning':False} This option can also be specified engine-wide using the ``implicit_returning=False`` argument on :func:`.create_engine`. .. _mssql_rowcount_versioning: Rowcount Support / ORM Versioning --------------------------------- The SQL Server drivers may have limited ability to return the number of rows updated from an UPDATE or DELETE statement. As of this writing, the PyODBC driver is not able to return a rowcount when OUTPUT INSERTED is used. This impacts the SQLAlchemy ORM's versioning feature in many cases where server-side value generators are in use in that while the versioning operations can succeed, the ORM cannot always check that an UPDATE or DELETE statement matched the number of rows expected, which is how it verifies that the version identifier matched. When this condition occurs, a warning will be emitted but the operation will proceed. The use of OUTPUT INSERTED can be disabled by setting the :paramref:`.Table.implicit_returning` flag to ``False`` on a particular :class:`.Table`, which in declarative looks like:: class MyTable(Base): __tablename__ = 'mytable' id = Column(Integer, primary_key=True) stuff = Column(String(10)) timestamp = Column(TIMESTAMP(), default=text('DEFAULT')) __mapper_args__ = { 'version_id_col': timestamp, 'version_id_generator': False, } __table_args__ = { 'implicit_returning': False } Enabling Snapshot Isolation --------------------------- SQL Server has a default transaction isolation mode that locks entire tables, and causes even mildly concurrent applications to have long held locks and frequent deadlocks. Enabling snapshot isolation for the database as a whole is recommended for modern levels of concurrency support. This is accomplished via the following ALTER DATABASE commands executed at the SQL prompt:: ALTER DATABASE MyDatabase SET ALLOW_SNAPSHOT_ISOLATION ON ALTER DATABASE MyDatabase SET READ_COMMITTED_SNAPSHOT ON Background on SQL Server snapshot isolation is available at http://msdn.microsoft.com/en-us/library/ms175095.aspx. """ import codecs import datetime import operator import re from ... import sql, schema as sa_schema, exc, util from ...sql import compiler, expression, util as sql_util, quoted_name from ... import engine from ...engine import reflection, default from ... import types as sqltypes from ...types import INTEGER, BIGINT, SMALLINT, DECIMAL, NUMERIC, \ FLOAT, DATETIME, DATE, BINARY, \ TEXT, VARCHAR, NVARCHAR, CHAR, NCHAR from ...util import update_wrapper from . import information_schema as ischema # http://sqlserverbuilds.blogspot.com/ MS_2016_VERSION = (13,) MS_2014_VERSION = (12,) MS_2012_VERSION = (11,) MS_2008_VERSION = (10,) MS_2005_VERSION = (9,) MS_2000_VERSION = (8,) RESERVED_WORDS = set( ['add', 'all', 'alter', 'and', 'any', 'as', 'asc', 'authorization', 'backup', 'begin', 'between', 'break', 'browse', 'bulk', 'by', 'cascade', 'case', 'check', 'checkpoint', 'close', 'clustered', 'coalesce', 'collate', 'column', 'commit', 'compute', 'constraint', 'contains', 'containstable', 'continue', 'convert', 'create', 'cross', 'current', 'current_date', 'current_time', 'current_timestamp', 'current_user', 'cursor', 'database', 'dbcc', 'deallocate', 'declare', 'default', 'delete', 'deny', 'desc', 'disk', 'distinct', 'distributed', 'double', 'drop', 'dump', 'else', 'end', 'errlvl', 'escape', 'except', 'exec', 'execute', 'exists', 'exit', 'external', 'fetch', 'file', 'fillfactor', 'for', 'foreign', 'freetext', 'freetexttable', 'from', 'full', 'function', 'goto', 'grant', 'group', 'having', 'holdlock', 'identity', 'identity_insert', 'identitycol', 'if', 'in', 'index', 'inner', 'insert', 'intersect', 'into', 'is', 'join', 'key', 'kill', 'left', 'like', 'lineno', 'load', 'merge', 'national', 'nocheck', 'nonclustered', 'not', 'null', 'nullif', 'of', 'off', 'offsets', 'on', 'open', 'opendatasource', 'openquery', 'openrowset', 'openxml', 'option', 'or', 'order', 'outer', 'over', 'percent', 'pivot', 'plan', 'precision', 'primary', 'print', 'proc', 'procedure', 'public', 'raiserror', 'read', 'readtext', 'reconfigure', 'references', 'replication', 'restore', 'restrict', 'return', 'revert', 'revoke', 'right', 'rollback', 'rowcount', 'rowguidcol', 'rule', 'save', 'schema', 'securityaudit', 'select', 'session_user', 'set', 'setuser', 'shutdown', 'some', 'statistics', 'system_user', 'table', 'tablesample', 'textsize', 'then', 'to', 'top', 'tran', 'transaction', 'trigger', 'truncate', 'tsequal', 'union', 'unique', 'unpivot', 'update', 'updatetext', 'use', 'user', 'values', 'varying', 'view', 'waitfor', 'when', 'where', 'while', 'with', 'writetext', ]) class REAL(sqltypes.REAL): __visit_name__ = 'REAL' def __init__(self, **kw): # REAL is a synonym for FLOAT(24) on SQL server kw['precision'] = 24 super(REAL, self).__init__(**kw) class TINYINT(sqltypes.Integer): __visit_name__ = 'TINYINT' # MSSQL DATE/TIME types have varied behavior, sometimes returning # strings. MSDate/TIME check for everything, and always # filter bind parameters into datetime objects (required by pyodbc, # not sure about other dialects). class _MSDate(sqltypes.Date): def bind_processor(self, dialect): def process(value): if type(value) == datetime.date: return datetime.datetime(value.year, value.month, value.day) else: return value return process _reg = re.compile(r"(\d+)-(\d+)-(\d+)") def result_processor(self, dialect, coltype): def process(value): if isinstance(value, datetime.datetime): return value.date() elif isinstance(value, util.string_types): m = self._reg.match(value) if not m: raise ValueError( "could not parse %r as a date value" % (value, )) return datetime.date(*[ int(x or 0) for x in m.groups() ]) else: return value return process class TIME(sqltypes.TIME): def __init__(self, precision=None, **kwargs): self.precision = precision super(TIME, self).__init__() __zero_date = datetime.date(1900, 1, 1) def bind_processor(self, dialect): def process(value): if isinstance(value, datetime.datetime): value = datetime.datetime.combine( self.__zero_date, value.time()) elif isinstance(value, datetime.time): value = datetime.datetime.combine(self.__zero_date, value) return value return process _reg = re.compile(r"(\d+):(\d+):(\d+)(?:\.(\d{0,6}))?") def result_processor(self, dialect, coltype): def process(value): if isinstance(value, datetime.datetime): return value.time() elif isinstance(value, util.string_types): m = self._reg.match(value) if not m: raise ValueError( "could not parse %r as a time value" % (value, )) return datetime.time(*[ int(x or 0) for x in m.groups()]) else: return value return process _MSTime = TIME class _DateTimeBase(object): def bind_processor(self, dialect): def process(value): if type(value) == datetime.date: return datetime.datetime(value.year, value.month, value.day) else: return value return process class _MSDateTime(_DateTimeBase, sqltypes.DateTime): pass class SMALLDATETIME(_DateTimeBase, sqltypes.DateTime): __visit_name__ = 'SMALLDATETIME' class DATETIME2(_DateTimeBase, sqltypes.DateTime): __visit_name__ = 'DATETIME2' def __init__(self, precision=None, **kw): super(DATETIME2, self).__init__(**kw) self.precision = precision # TODO: is this not an Interval ? class DATETIMEOFFSET(sqltypes.TypeEngine): __visit_name__ = 'DATETIMEOFFSET' def __init__(self, precision=None, **kwargs): self.precision = precision class _StringType(object): """Base for MSSQL string types.""" def __init__(self, collation=None): super(_StringType, self).__init__(collation=collation) class TIMESTAMP(sqltypes._Binary): """Implement the SQL Server TIMESTAMP type. Note this is **completely different** than the SQL Standard TIMESTAMP type, which is not supported by SQL Server. It is a read-only datatype that does not support INSERT of values. .. versionadded:: 1.2 .. seealso:: :class:`.mssql.ROWVERSION` """ __visit_name__ = 'TIMESTAMP' # expected by _Binary to be present length = None def __init__(self, convert_int=False): """Construct a TIMESTAMP or ROWVERSION type. :param convert_int: if True, binary integer values will be converted to integers on read. .. versionadded:: 1.2 """ self.convert_int = convert_int def result_processor(self, dialect, coltype): super_ = super(TIMESTAMP, self).result_processor(dialect, coltype) if self.convert_int: def process(value): value = super_(value) if value is not None: # https://stackoverflow.com/a/30403242/34549 value = int(codecs.encode(value, 'hex'), 16) return value return process else: return super_ class ROWVERSION(TIMESTAMP): """Implement the SQL Server ROWVERSION type. The ROWVERSION datatype is a SQL Server synonym for the TIMESTAMP datatype, however current SQL Server documentation suggests using ROWVERSION for new datatypes going forward. The ROWVERSION datatype does **not** reflect (e.g. introspect) from the database as itself; the returned datatype will be :class:`.mssql.TIMESTAMP`. This is a read-only datatype that does not support INSERT of values. .. versionadded:: 1.2 .. seealso:: :class:`.mssql.TIMESTAMP` """ __visit_name__ = 'ROWVERSION' class NTEXT(sqltypes.UnicodeText): """MSSQL NTEXT type, for variable-length unicode text up to 2^30 characters.""" __visit_name__ = 'NTEXT' class VARBINARY(sqltypes.VARBINARY, sqltypes.LargeBinary): """The MSSQL VARBINARY type. This type is present to support "deprecate_large_types" mode where either ``VARBINARY(max)`` or IMAGE is rendered. Otherwise, this type object is redundant vs. :class:`.types.VARBINARY`. .. versionadded:: 1.0.0 .. seealso:: :ref:`mssql_large_type_deprecation` """ __visit_name__ = 'VARBINARY' class IMAGE(sqltypes.LargeBinary): __visit_name__ = 'IMAGE' class XML(sqltypes.Text): """MSSQL XML type. This is a placeholder type for reflection purposes that does not include any Python-side datatype support. It also does not currently support additional arguments, such as "CONTENT", "DOCUMENT", "xml_schema_collection". .. versionadded:: 1.1.11 """ __visit_name__ = 'XML' class BIT(sqltypes.TypeEngine): __visit_name__ = 'BIT' class MONEY(sqltypes.TypeEngine): __visit_name__ = 'MONEY' class SMALLMONEY(sqltypes.TypeEngine): __visit_name__ = 'SMALLMONEY' class UNIQUEIDENTIFIER(sqltypes.TypeEngine): __visit_name__ = "UNIQUEIDENTIFIER" class SQL_VARIANT(sqltypes.TypeEngine): __visit_name__ = 'SQL_VARIANT' # old names. MSDateTime = _MSDateTime MSDate = _MSDate MSReal = REAL MSTinyInteger = TINYINT MSTime = TIME MSSmallDateTime = SMALLDATETIME MSDateTime2 = DATETIME2 MSDateTimeOffset = DATETIMEOFFSET MSText = TEXT MSNText = NTEXT MSString = VARCHAR MSNVarchar = NVARCHAR MSChar = CHAR MSNChar = NCHAR MSBinary = BINARY MSVarBinary = VARBINARY MSImage = IMAGE MSBit = BIT MSMoney = MONEY MSSmallMoney = SMALLMONEY MSUniqueIdentifier = UNIQUEIDENTIFIER MSVariant = SQL_VARIANT ischema_names = { 'int': INTEGER, 'bigint': BIGINT, 'smallint': SMALLINT, 'tinyint': TINYINT, 'varchar': VARCHAR, 'nvarchar': NVARCHAR, 'char': CHAR, 'nchar': NCHAR, 'text': TEXT, 'ntext': NTEXT, 'decimal': DECIMAL, 'numeric': NUMERIC, 'float': FLOAT, 'datetime': DATETIME, 'datetime2': DATETIME2, 'datetimeoffset': DATETIMEOFFSET, 'date': DATE, 'time': TIME, 'smalldatetime': SMALLDATETIME, 'binary': BINARY, 'varbinary': VARBINARY, 'bit': BIT, 'real': REAL, 'image': IMAGE, 'xml': XML, 'timestamp': TIMESTAMP, 'money': MONEY, 'smallmoney': SMALLMONEY, 'uniqueidentifier': UNIQUEIDENTIFIER, 'sql_variant': SQL_VARIANT, } class MSTypeCompiler(compiler.GenericTypeCompiler): def _extend(self, spec, type_, length=None): """Extend a string-type declaration with standard SQL COLLATE annotations. """ if getattr(type_, 'collation', None): collation = 'COLLATE %s' % type_.collation else: collation = None if not length: length = type_.length if length: spec = spec + "(%s)" % length return ' '.join([c for c in (spec, collation) if c is not None]) def visit_FLOAT(self, type_, **kw): precision = getattr(type_, 'precision', None) if precision is None: return "FLOAT" else: return "FLOAT(%(precision)s)" % {'precision': precision} def visit_TINYINT(self, type_, **kw): return "TINYINT" def visit_DATETIMEOFFSET(self, type_, **kw): if type_.precision is not None: return "DATETIMEOFFSET(%s)" % type_.precision else: return "DATETIMEOFFSET" def visit_TIME(self, type_, **kw): precision = getattr(type_, 'precision', None) if precision is not None: return "TIME(%s)" % precision else: return "TIME" def visit_TIMESTAMP(self, type_, **kw): return "TIMESTAMP" def visit_ROWVERSION(self, type_, **kw): return "ROWVERSION" def visit_DATETIME2(self, type_, **kw): precision = getattr(type_, 'precision', None) if precision is not None: return "DATETIME2(%s)" % precision else: return "DATETIME2" def visit_SMALLDATETIME(self, type_, **kw): return "SMALLDATETIME" def visit_unicode(self, type_, **kw): return self.visit_NVARCHAR(type_, **kw) def visit_text(self, type_, **kw): if self.dialect.deprecate_large_types: return self.visit_VARCHAR(type_, **kw) else: return self.visit_TEXT(type_, **kw) def visit_unicode_text(self, type_, **kw): if self.dialect.deprecate_large_types: return self.visit_NVARCHAR(type_, **kw) else: return self.visit_NTEXT(type_, **kw) def visit_NTEXT(self, type_, **kw): return self._extend("NTEXT", type_) def visit_TEXT(self, type_, **kw): return self._extend("TEXT", type_) def visit_VARCHAR(self, type_, **kw): return self._extend("VARCHAR", type_, length=type_.length or 'max') def visit_CHAR(self, type_, **kw): return self._extend("CHAR", type_) def visit_NCHAR(self, type_, **kw): return self._extend("NCHAR", type_) def visit_NVARCHAR(self, type_, **kw): return self._extend("NVARCHAR", type_, length=type_.length or 'max') def visit_date(self, type_, **kw): if self.dialect.server_version_info < MS_2008_VERSION: return self.visit_DATETIME(type_, **kw) else: return self.visit_DATE(type_, **kw) def visit_time(self, type_, **kw): if self.dialect.server_version_info < MS_2008_VERSION: return self.visit_DATETIME(type_, **kw) else: return self.visit_TIME(type_, **kw) def visit_large_binary(self, type_, **kw): if self.dialect.deprecate_large_types: return self.visit_VARBINARY(type_, **kw) else: return self.visit_IMAGE(type_, **kw) def visit_IMAGE(self, type_, **kw): return "IMAGE" def visit_XML(self, type_, **kw): return "XML" def visit_VARBINARY(self, type_, **kw): return self._extend( "VARBINARY", type_, length=type_.length or 'max') def visit_boolean(self, type_, **kw): return self.visit_BIT(type_) def visit_BIT(self, type_, **kw): return "BIT" def visit_MONEY(self, type_, **kw): return "MONEY" def visit_SMALLMONEY(self, type_, **kw): return 'SMALLMONEY' def visit_UNIQUEIDENTIFIER(self, type_, **kw): return "UNIQUEIDENTIFIER" def visit_SQL_VARIANT(self, type_, **kw): return 'SQL_VARIANT' class MSExecutionContext(default.DefaultExecutionContext): _enable_identity_insert = False _select_lastrowid = False _result_proxy = None _lastrowid = None def _opt_encode(self, statement): if not self.dialect.supports_unicode_statements: return self.dialect._encoder(statement)[0] else: return statement def pre_exec(self): """Activate IDENTITY_INSERT if needed.""" if self.isinsert: tbl = self.compiled.statement.table seq_column = tbl._autoincrement_column insert_has_sequence = seq_column is not None if insert_has_sequence: self._enable_identity_insert = \ seq_column.key in self.compiled_parameters[0] or \ ( self.compiled.statement.parameters and ( ( self.compiled.statement._has_multi_parameters and seq_column.key in self.compiled.statement.parameters[0] ) or ( not self.compiled.statement._has_multi_parameters and seq_column.key in self.compiled.statement.parameters ) ) ) else: self._enable_identity_insert = False self._select_lastrowid = not self.compiled.inline and \ insert_has_sequence and \ not self.compiled.returning and \ not self._enable_identity_insert and \ not self.executemany if self._enable_identity_insert: self.root_connection._cursor_execute( self.cursor, self._opt_encode( "SET IDENTITY_INSERT %s ON" % self.dialect.identifier_preparer.format_table(tbl)), (), self) def post_exec(self): """Disable IDENTITY_INSERT if enabled.""" conn = self.root_connection if self._select_lastrowid: if self.dialect.use_scope_identity: conn._cursor_execute( self.cursor, "SELECT scope_identity() AS lastrowid", (), self) else: conn._cursor_execute(self.cursor, "SELECT @@identity AS lastrowid", (), self) # fetchall() ensures the cursor is consumed without closing it row = self.cursor.fetchall()[0] self._lastrowid = int(row[0]) if (self.isinsert or self.isupdate or self.isdelete) and \ self.compiled.returning: self._result_proxy = engine.FullyBufferedResultProxy(self) if self._enable_identity_insert: conn._cursor_execute( self.cursor, self._opt_encode( "SET IDENTITY_INSERT %s OFF" % self.dialect.identifier_preparer. format_table( self.compiled.statement.table)), (), self) def get_lastrowid(self): return self._lastrowid def handle_dbapi_exception(self, e): if self._enable_identity_insert: try: self.cursor.execute( self._opt_encode( "SET IDENTITY_INSERT %s OFF" % self.dialect.identifier_preparer. format_table( self.compiled.statement.table))) except Exception: pass def get_result_proxy(self): if self._result_proxy: return self._result_proxy else: return engine.ResultProxy(self) class MSSQLCompiler(compiler.SQLCompiler): returning_precedes_values = True extract_map = util.update_copy( compiler.SQLCompiler.extract_map, { 'doy': 'dayofyear', 'dow': 'weekday', 'milliseconds': 'millisecond', 'microseconds': 'microsecond' }) def __init__(self, *args, **kwargs): self.tablealiases = {} super(MSSQLCompiler, self).__init__(*args, **kwargs) def _with_legacy_schema_aliasing(fn): def decorate(self, *arg, **kw): if self.dialect.legacy_schema_aliasing: return fn(self, *arg, **kw) else: super_ = getattr(super(MSSQLCompiler, self), fn.__name__) return super_(*arg, **kw) return decorate def visit_now_func(self, fn, **kw): return "CURRENT_TIMESTAMP" def visit_current_date_func(self, fn, **kw): return "GETDATE()" def visit_length_func(self, fn, **kw): return "LEN%s" % self.function_argspec(fn, **kw) def visit_char_length_func(self, fn, **kw): return "LEN%s" % self.function_argspec(fn, **kw) def visit_concat_op_binary(self, binary, operator, **kw): return "%s + %s" % \ (self.process(binary.left, **kw), self.process(binary.right, **kw)) def visit_true(self, expr, **kw): return '1' def visit_false(self, expr, **kw): return '0' def visit_match_op_binary(self, binary, operator, **kw): return "CONTAINS (%s, %s)" % ( self.process(binary.left, **kw), self.process(binary.right, **kw)) def get_select_precolumns(self, select, **kw): """ MS-SQL puts TOP, it's version of LIMIT here """ s = "" if select._distinct: s += "DISTINCT " if select._simple_int_limit and not select._offset: # ODBC drivers and possibly others # don't support bind params in the SELECT clause on SQL Server. # so have to use literal here. s += "TOP %d " % select._limit if s: return s else: return compiler.SQLCompiler.get_select_precolumns( self, select, **kw) def get_from_hint_text(self, table, text): return text def get_crud_hint_text(self, table, text): return text def limit_clause(self, select, **kw): # Limit in mssql is after the select keyword return "" def visit_select(self, select, **kwargs): """Look for ``LIMIT`` and OFFSET in a select statement, and if so tries to wrap it in a subquery with ``row_number()`` criterion. """ if ( ( not select._simple_int_limit and select._limit_clause is not None ) or ( select._offset_clause is not None and not select._simple_int_offset or select._offset ) ) and not getattr(select, '_mssql_visit', None): # to use ROW_NUMBER(), an ORDER BY is required. if not select._order_by_clause.clauses: raise exc.CompileError('MSSQL requires an order_by when ' 'using an OFFSET or a non-simple ' 'LIMIT clause') _order_by_clauses = [ sql_util.unwrap_label_reference(elem) for elem in select._order_by_clause.clauses ] limit_clause = select._limit_clause offset_clause = select._offset_clause kwargs['select_wraps_for'] = select select = select._generate() select._mssql_visit = True select = select.column( sql.func.ROW_NUMBER().over(order_by=_order_by_clauses) .label("mssql_rn")).order_by(None).alias() mssql_rn = sql.column('mssql_rn') limitselect = sql.select([c for c in select.c if c.key != 'mssql_rn']) if offset_clause is not None: limitselect.append_whereclause(mssql_rn > offset_clause) if limit_clause is not None: limitselect.append_whereclause( mssql_rn <= (limit_clause + offset_clause)) else: limitselect.append_whereclause( mssql_rn <= (limit_clause)) return self.process(limitselect, **kwargs) else: return compiler.SQLCompiler.visit_select(self, select, **kwargs) @_with_legacy_schema_aliasing def visit_table(self, table, mssql_aliased=False, iscrud=False, **kwargs): if mssql_aliased is table or iscrud: return super(MSSQLCompiler, self).visit_table(table, **kwargs) # alias schema-qualified tables alias = self._schema_aliased_table(table) if alias is not None: return self.process(alias, mssql_aliased=table, **kwargs) else: return super(MSSQLCompiler, self).visit_table(table, **kwargs) @_with_legacy_schema_aliasing def visit_alias(self, alias, **kw): # translate for schema-qualified table aliases kw['mssql_aliased'] = alias.original return super(MSSQLCompiler, self).visit_alias(alias, **kw) @_with_legacy_schema_aliasing def visit_column(self, column, add_to_result_map=None, **kw): if column.table is not None and \ (not self.isupdate and not self.isdelete) or \ self.is_subquery(): # translate for schema-qualified table aliases t = self._schema_aliased_table(column.table) if t is not None: converted = expression._corresponding_column_or_error( t, column) if add_to_result_map is not None: add_to_result_map( column.name, column.name, (column, column.name, column.key), column.type ) return super(MSSQLCompiler, self).\ visit_column(converted, **kw) return super(MSSQLCompiler, self).visit_column( column, add_to_result_map=add_to_result_map, **kw) def _schema_aliased_table(self, table): if getattr(table, 'schema', None) is not None: if table not in self.tablealiases: self.tablealiases[table] = table.alias() return self.tablealiases[table] else: return None def visit_extract(self, extract, **kw): field = self.extract_map.get(extract.field, extract.field) return 'DATEPART(%s, %s)' % \ (field, self.process(extract.expr, **kw)) def visit_savepoint(self, savepoint_stmt): return "SAVE TRANSACTION %s" % \ self.preparer.format_savepoint(savepoint_stmt) def visit_rollback_to_savepoint(self, savepoint_stmt): return ("ROLLBACK TRANSACTION %s" % self.preparer.format_savepoint(savepoint_stmt)) def visit_binary(self, binary, **kwargs): """Move bind parameters to the right-hand side of an operator, where possible. """ if ( isinstance(binary.left, expression.BindParameter) and binary.operator == operator.eq and not isinstance(binary.right, expression.BindParameter) ): return self.process( expression.BinaryExpression(binary.right, binary.left, binary.operator), **kwargs) return super(MSSQLCompiler, self).visit_binary(binary, **kwargs) def returning_clause(self, stmt, returning_cols): if self.isinsert or self.isupdate: target = stmt.table.alias("inserted") else: target = stmt.table.alias("deleted") adapter = sql_util.ClauseAdapter(target) columns = [ self._label_select_column(None, adapter.traverse(c), True, False, {}) for c in expression._select_iterables(returning_cols) ] return 'OUTPUT ' + ', '.join(columns) def get_cte_preamble(self, recursive): # SQL Server finds it too inconvenient to accept # an entirely optional, SQL standard specified, # "RECURSIVE" word with their "WITH", # so here we go return "WITH" def label_select_column(self, select, column, asfrom): if isinstance(column, expression.Function): return column.label(None) else: return super(MSSQLCompiler, self).\ label_select_column(select, column, asfrom) def for_update_clause(self, select): # "FOR UPDATE" is only allowed on "DECLARE CURSOR" which # SQLAlchemy doesn't use return '' def order_by_clause(self, select, **kw): order_by = self.process(select._order_by_clause, **kw) # MSSQL only allows ORDER BY in subqueries if there is a LIMIT if order_by and (not self.is_subquery() or select._limit): return " ORDER BY " + order_by else: return "" def update_from_clause(self, update_stmt, from_table, extra_froms, from_hints, **kw): """Render the UPDATE..FROM clause specific to MSSQL. In MSSQL, if the UPDATE statement involves an alias of the table to be updated, then the table itself must be added to the FROM list as well. Otherwise, it is optional. Here, we add it regardless. """ return "FROM " + ', '.join( t._compiler_dispatch(self, asfrom=True, fromhints=from_hints, **kw) for t in [from_table] + extra_froms) def delete_table_clause(self, delete_stmt, from_table, extra_froms): """If we have extra froms make sure we render any alias as hint.""" ashint = False if extra_froms: ashint = True return from_table._compiler_dispatch( self, asfrom=True, iscrud=True, ashint=ashint ) def delete_extra_from_clause(self, delete_stmt, from_table, extra_froms, from_hints, **kw): """Render the DELETE .. FROM clause specific to MSSQL. Yes, it has the FROM keyword twice. """ return "FROM " + ', '.join( t._compiler_dispatch(self, asfrom=True, fromhints=from_hints, **kw) for t in [from_table] + extra_froms) class MSSQLStrictCompiler(MSSQLCompiler): """A subclass of MSSQLCompiler which disables the usage of bind parameters where not allowed natively by MS-SQL. A dialect may use this compiler on a platform where native binds are used. """ ansi_bind_rules = True def visit_in_op_binary(self, binary, operator, **kw): kw['literal_binds'] = True return "%s IN %s" % ( self.process(binary.left, **kw), self.process(binary.right, **kw) ) def visit_notin_op_binary(self, binary, operator, **kw): kw['literal_binds'] = True return "%s NOT IN %s" % ( self.process(binary.left, **kw), self.process(binary.right, **kw) ) def render_literal_value(self, value, type_): """ For date and datetime values, convert to a string format acceptable to MSSQL. That seems to be the so-called ODBC canonical date format which looks like this: yyyy-mm-dd hh:mi:ss.mmm(24h) For other data types, call the base class implementation. """ # datetime and date are both subclasses of datetime.date if issubclass(type(value), datetime.date): # SQL Server wants single quotes around the date string. return "'" + str(value) + "'" else: return super(MSSQLStrictCompiler, self).\ render_literal_value(value, type_) class MSDDLCompiler(compiler.DDLCompiler): def get_column_specification(self, column, **kwargs): colspec = ( self.preparer.format_column(column) + " " + self.dialect.type_compiler.process( column.type, type_expression=column) ) if column.nullable is not None: if not column.nullable or column.primary_key or \ isinstance(column.default, sa_schema.Sequence): colspec += " NOT NULL" else: colspec += " NULL" if column.table is None: raise exc.CompileError( "mssql requires Table-bound columns " "in order to generate DDL") # install an IDENTITY Sequence if we either a sequence or an implicit # IDENTITY column if isinstance(column.default, sa_schema.Sequence): if column.default.start == 0: start = 0 else: start = column.default.start or 1 colspec += " IDENTITY(%s,%s)" % (start, column.default.increment or 1) elif column is column.table._autoincrement_column: colspec += " IDENTITY(1,1)" else: default = self.get_column_default_string(column) if default is not None: colspec += " DEFAULT " + default return colspec def visit_create_index(self, create, include_schema=False): index = create.element self._verify_index_table(index) preparer = self.preparer text = "CREATE " if index.unique: text += "UNIQUE " # handle clustering option clustered = index.dialect_options['mssql']['clustered'] if clustered is not None: if clustered: text += "CLUSTERED " else: text += "NONCLUSTERED " text += "INDEX %s ON %s (%s)" \ % ( self._prepared_index_name(index, include_schema=include_schema), preparer.format_table(index.table), ', '.join( self.sql_compiler.process(expr, include_table=False, literal_binds=True) for expr in index.expressions) ) # handle other included columns if index.dialect_options['mssql']['include']: inclusions = [index.table.c[col] if isinstance(col, util.string_types) else col for col in index.dialect_options['mssql']['include'] ] text += " INCLUDE (%s)" \ % ', '.join([preparer.quote(c.name) for c in inclusions]) return text def visit_drop_index(self, drop): return "\nDROP INDEX %s ON %s" % ( self._prepared_index_name(drop.element, include_schema=False), self.preparer.format_table(drop.element.table) ) def visit_primary_key_constraint(self, constraint): if len(constraint) == 0: return '' text = "" if constraint.name is not None: text += "CONSTRAINT %s " % \ self.preparer.format_constraint(constraint) text += "PRIMARY KEY " clustered = constraint.dialect_options['mssql']['clustered'] if clustered is not None: if clustered: text += "CLUSTERED " else: text += "NONCLUSTERED " text += "(%s)" % ', '.join(self.preparer.quote(c.name) for c in constraint) text += self.define_constraint_deferrability(constraint) return text def visit_unique_constraint(self, constraint): if len(constraint) == 0: return '' text = "" if constraint.name is not None: text += "CONSTRAINT %s " % \ self.preparer.format_constraint(constraint) text += "UNIQUE " clustered = constraint.dialect_options['mssql']['clustered'] if clustered is not None: if clustered: text += "CLUSTERED " else: text += "NONCLUSTERED " text += "(%s)" % ', '.join(self.preparer.quote(c.name) for c in constraint) text += self.define_constraint_deferrability(constraint) return text class MSIdentifierPreparer(compiler.IdentifierPreparer): reserved_words = RESERVED_WORDS def __init__(self, dialect): super(MSIdentifierPreparer, self).__init__( dialect, initial_quote='[', final_quote=']', quote_case_sensitive_collations=False) def _escape_identifier(self, value): return value def quote_schema(self, schema, force=None): """Prepare a quoted table and schema name.""" dbname, owner = _schema_elements(schema) if dbname: result = "%s.%s" % ( self.quote(dbname, force), self.quote(owner, force)) elif owner: result = self.quote(owner, force) else: result = "" return result def _db_plus_owner_listing(fn): def wrap(dialect, connection, schema=None, **kw): dbname, owner = _owner_plus_db(dialect, schema) return _switch_db(dbname, connection, fn, dialect, connection, dbname, owner, schema, **kw) return update_wrapper(wrap, fn) def _db_plus_owner(fn): def wrap(dialect, connection, tablename, schema=None, **kw): dbname, owner = _owner_plus_db(dialect, schema) return _switch_db(dbname, connection, fn, dialect, connection, tablename, dbname, owner, schema, **kw) return update_wrapper(wrap, fn) def _switch_db(dbname, connection, fn, *arg, **kw): if dbname: current_db = connection.scalar("select db_name()") connection.execute("use %s" % dbname) try: return fn(*arg, **kw) finally: if dbname: connection.execute("use %s" % current_db) def _owner_plus_db(dialect, schema): if not schema: return None, dialect.default_schema_name elif "." in schema: return _schema_elements(schema) else: return None, schema def _schema_elements(schema): if isinstance(schema, quoted_name) and schema.quote: return None, schema push = [] symbol = "" bracket = False for token in re.split(r"(\[|\]|\.)", schema): if not token: continue if token == '[': bracket = True elif token == ']': bracket = False elif not bracket and token == ".": push.append(symbol) symbol = "" else: symbol += token if symbol: push.append(symbol) if len(push) > 1: return push[0], "".join(push[1:]) elif len(push): return None, push[0] else: return None, None class MSDialect(default.DefaultDialect): name = 'mssql' supports_default_values = True supports_empty_insert = False execution_ctx_cls = MSExecutionContext use_scope_identity = True max_identifier_length = 128 schema_name = "dbo" colspecs = { sqltypes.DateTime: _MSDateTime, sqltypes.Date: _MSDate, sqltypes.Time: TIME, } engine_config_types = default.DefaultDialect.engine_config_types.union([ ('legacy_schema_aliasing', util.asbool), ]) ischema_names = ischema_names supports_native_boolean = True supports_unicode_binds = True postfetch_lastrowid = True server_version_info = () statement_compiler = MSSQLCompiler ddl_compiler = MSDDLCompiler type_compiler = MSTypeCompiler preparer = MSIdentifierPreparer construct_arguments = [ (sa_schema.PrimaryKeyConstraint, { "clustered": None }), (sa_schema.UniqueConstraint, { "clustered": None }), (sa_schema.Index, { "clustered": None, "include": None }) ] def __init__(self, query_timeout=None, use_scope_identity=True, max_identifier_length=None, schema_name="dbo", isolation_level=None, deprecate_large_types=None, legacy_schema_aliasing=False, **opts): self.query_timeout = int(query_timeout or 0) self.schema_name = schema_name self.use_scope_identity = use_scope_identity self.max_identifier_length = int(max_identifier_length or 0) or \ self.max_identifier_length self.deprecate_large_types = deprecate_large_types self.legacy_schema_aliasing = legacy_schema_aliasing super(MSDialect, self).__init__(**opts) self.isolation_level = isolation_level def do_savepoint(self, connection, name): # give the DBAPI a push connection.execute("IF @@TRANCOUNT = 0 BEGIN TRANSACTION") super(MSDialect, self).do_savepoint(connection, name) def do_release_savepoint(self, connection, name): # SQL Server does not support RELEASE SAVEPOINT pass _isolation_lookup = set(['SERIALIZABLE', 'READ UNCOMMITTED', 'READ COMMITTED', 'REPEATABLE READ', 'SNAPSHOT']) def set_isolation_level(self, connection, level): level = level.replace('_', ' ') if level not in self._isolation_lookup: raise exc.ArgumentError( "Invalid value '%s' for isolation_level. " "Valid isolation levels for %s are %s" % (level, self.name, ", ".join(self._isolation_lookup)) ) cursor = connection.cursor() cursor.execute( "SET TRANSACTION ISOLATION LEVEL %s" % level) cursor.close() def get_isolation_level(self, connection): if self.server_version_info < MS_2005_VERSION: raise NotImplementedError( "Can't fetch isolation level prior to SQL Server 2005") views = ("sys.dm_exec_sessions", "sys.dm_pdw_nodes_exec_sessions") for view in views: cursor = connection.cursor() try: cursor.execute(""" SELECT CASE transaction_isolation_level WHEN 0 THEN NULL WHEN 1 THEN 'READ UNCOMMITTED' WHEN 2 THEN 'READ COMMITTED' WHEN 3 THEN 'REPEATABLE READ' WHEN 4 THEN 'SERIALIZABLE' WHEN 5 THEN 'SNAPSHOT' END AS TRANSACTION_ISOLATION_LEVEL FROM %s where session_id = @@SPID """ % view) val = cursor.fetchone()[0] except self.dbapi.Error as err: continue else: return val.upper() finally: cursor.close() util.warn( "Could not fetch transaction isolation level, " "tried views: %s; final error was: %s" % (views, err)) raise NotImplementedError( "Can't fetch isolation level on this particular " "SQL Server version" ) def initialize(self, connection): super(MSDialect, self).initialize(connection) self._setup_version_attributes() def on_connect(self): if self.isolation_level is not None: def connect(conn): self.set_isolation_level(conn, self.isolation_level) return connect else: return None def _setup_version_attributes(self): if self.server_version_info[0] not in list(range(8, 17)): util.warn( "Unrecognized server version info '%s'. Some SQL Server " "features may not function properly." % ".".join(str(x) for x in self.server_version_info)) if self.server_version_info >= MS_2005_VERSION and \ 'implicit_returning' not in self.__dict__: self.implicit_returning = True if self.server_version_info >= MS_2008_VERSION: self.supports_multivalues_insert = True if self.deprecate_large_types is None: self.deprecate_large_types = \ self.server_version_info >= MS_2012_VERSION def _get_default_schema_name(self, connection): if self.server_version_info < MS_2005_VERSION: return self.schema_name else: query = sql.text("SELECT schema_name()") default_schema_name = connection.scalar(query) if default_schema_name is not None: return util.text_type(default_schema_name) else: return self.schema_name @_db_plus_owner def has_table(self, connection, tablename, dbname, owner, schema): columns = ischema.columns whereclause = columns.c.table_name == tablename if owner: whereclause = sql.and_(whereclause, columns.c.table_schema == owner) s = sql.select([columns], whereclause) c = connection.execute(s) return c.first() is not None @reflection.cache def get_schema_names(self, connection, **kw): s = sql.select([ischema.schemata.c.schema_name], order_by=[ischema.schemata.c.schema_name] ) schema_names = [r[0] for r in connection.execute(s)] return schema_names @reflection.cache @_db_plus_owner_listing def get_table_names(self, connection, dbname, owner, schema, **kw): tables = ischema.tables s = sql.select([tables.c.table_name], sql.and_( tables.c.table_schema == owner, tables.c.table_type == 'BASE TABLE' ), order_by=[tables.c.table_name] ) table_names = [r[0] for r in connection.execute(s)] return table_names @reflection.cache @_db_plus_owner_listing def get_view_names(self, connection, dbname, owner, schema, **kw): tables = ischema.tables s = sql.select([tables.c.table_name], sql.and_( tables.c.table_schema == owner, tables.c.table_type == 'VIEW' ), order_by=[tables.c.table_name] ) view_names = [r[0] for r in connection.execute(s)] return view_names @reflection.cache @_db_plus_owner def get_indexes(self, connection, tablename, dbname, owner, schema, **kw): # using system catalogs, don't support index reflection # below MS 2005 if self.server_version_info < MS_2005_VERSION: return [] rp = connection.execute( sql.text("select ind.index_id, ind.is_unique, ind.name " "from sys.indexes as ind join sys.tables as tab on " "ind.object_id=tab.object_id " "join sys.schemas as sch on sch.schema_id=tab.schema_id " "where tab.name = :tabname " "and sch.name=:schname " "and ind.is_primary_key=0 and ind.type != 0", bindparams=[ sql.bindparam('tabname', tablename, sqltypes.String(convert_unicode=True)), sql.bindparam('schname', owner, sqltypes.String(convert_unicode=True)) ], typemap={ 'name': sqltypes.Unicode() } ) ) indexes = {} for row in rp: indexes[row['index_id']] = { 'name': row['name'], 'unique': row['is_unique'] == 1, 'column_names': [] } rp = connection.execute( sql.text( "select ind_col.index_id, ind_col.object_id, col.name " "from sys.columns as col " "join sys.tables as tab on tab.object_id=col.object_id " "join sys.index_columns as ind_col on " "(ind_col.column_id=col.column_id and " "ind_col.object_id=tab.object_id) " "join sys.schemas as sch on sch.schema_id=tab.schema_id " "where tab.name=:tabname " "and sch.name=:schname", bindparams=[ sql.bindparam('tabname', tablename, sqltypes.String(convert_unicode=True)), sql.bindparam('schname', owner, sqltypes.String(convert_unicode=True)) ], typemap={'name': sqltypes.Unicode()} ), ) for row in rp: if row['index_id'] in indexes: indexes[row['index_id']]['column_names'].append(row['name']) return list(indexes.values()) @reflection.cache @_db_plus_owner def get_view_definition(self, connection, viewname, dbname, owner, schema, **kw): rp = connection.execute( sql.text( "select definition from sys.sql_modules as mod, " "sys.views as views, " "sys.schemas as sch" " where " "mod.object_id=views.object_id and " "views.schema_id=sch.schema_id and " "views.name=:viewname and sch.name=:schname", bindparams=[ sql.bindparam('viewname', viewname, sqltypes.String(convert_unicode=True)), sql.bindparam('schname', owner, sqltypes.String(convert_unicode=True)) ] ) ) if rp: view_def = rp.scalar() return view_def @reflection.cache @_db_plus_owner def get_columns(self, connection, tablename, dbname, owner, schema, **kw): # Get base columns columns = ischema.columns if owner: whereclause = sql.and_(columns.c.table_name == tablename, columns.c.table_schema == owner) else: whereclause = columns.c.table_name == tablename s = sql.select([columns], whereclause, order_by=[columns.c.ordinal_position]) c = connection.execute(s) cols = [] while True: row = c.fetchone() if row is None: break (name, type, nullable, charlen, numericprec, numericscale, default, collation) = ( row[columns.c.column_name], row[columns.c.data_type], row[columns.c.is_nullable] == 'YES', row[columns.c.character_maximum_length], row[columns.c.numeric_precision], row[columns.c.numeric_scale], row[columns.c.column_default], row[columns.c.collation_name] ) coltype = self.ischema_names.get(type, None) kwargs = {} if coltype in (MSString, MSChar, MSNVarchar, MSNChar, MSText, MSNText, MSBinary, MSVarBinary, sqltypes.LargeBinary): if charlen == -1: charlen = None kwargs['length'] = charlen if collation: kwargs['collation'] = collation if coltype is None: util.warn( "Did not recognize type '%s' of column '%s'" % (type, name)) coltype = sqltypes.NULLTYPE else: if issubclass(coltype, sqltypes.Numeric) and \ coltype is not MSReal: kwargs['scale'] = numericscale kwargs['precision'] = numericprec coltype = coltype(**kwargs) cdict = { 'name': name, 'type': coltype, 'nullable': nullable, 'default': default, 'autoincrement': False, } cols.append(cdict) # autoincrement and identity colmap = {} for col in cols: colmap[col['name']] = col # We also run an sp_columns to check for identity columns: cursor = connection.execute("sp_columns @table_name = '%s', " "@table_owner = '%s'" % (tablename, owner)) ic = None while True: row = cursor.fetchone() if row is None: break (col_name, type_name) = row[3], row[5] if type_name.endswith("identity") and col_name in colmap: ic = col_name colmap[col_name]['autoincrement'] = True colmap[col_name]['sequence'] = dict( name='%s_identity' % col_name) break cursor.close() if ic is not None and self.server_version_info >= MS_2005_VERSION: table_fullname = "%s.%s" % (owner, tablename) cursor = connection.execute( "select ident_seed('%s'), ident_incr('%s')" % (table_fullname, table_fullname) ) row = cursor.first() if row is not None and row[0] is not None: colmap[ic]['sequence'].update({ 'start': int(row[0]), 'increment': int(row[1]) }) return cols @reflection.cache @_db_plus_owner def get_pk_constraint(self, connection, tablename, dbname, owner, schema, **kw): pkeys = [] TC = ischema.constraints C = ischema.key_constraints.alias('C') # Primary key constraints s = sql.select([C.c.column_name, TC.c.constraint_type, C.c.constraint_name], sql.and_(TC.c.constraint_name == C.c.constraint_name, TC.c.table_schema == C.c.table_schema, C.c.table_name == tablename, C.c.table_schema == owner) ) c = connection.execute(s) constraint_name = None for row in c: if 'PRIMARY' in row[TC.c.constraint_type.name]: pkeys.append(row[0]) if constraint_name is None: constraint_name = row[C.c.constraint_name.name] return {'constrained_columns': pkeys, 'name': constraint_name} @reflection.cache @_db_plus_owner def get_foreign_keys(self, connection, tablename, dbname, owner, schema, **kw): RR = ischema.ref_constraints C = ischema.key_constraints.alias('C') R = ischema.key_constraints.alias('R') # Foreign key constraints s = sql.select([C.c.column_name, R.c.table_schema, R.c.table_name, R.c.column_name, RR.c.constraint_name, RR.c.match_option, RR.c.update_rule, RR.c.delete_rule], sql.and_(C.c.table_name == tablename, C.c.table_schema == owner, RR.c.constraint_schema == C.c.table_schema, C.c.constraint_name == RR.c.constraint_name, R.c.constraint_name == RR.c.unique_constraint_name, C.c.ordinal_position == R.c.ordinal_position ), order_by=[RR.c.constraint_name, R.c.ordinal_position] ) # group rows by constraint ID, to handle multi-column FKs fkeys = [] fknm, scols, rcols = (None, [], []) def fkey_rec(): return { 'name': None, 'constrained_columns': [], 'referred_schema': None, 'referred_table': None, 'referred_columns': [] } fkeys = util.defaultdict(fkey_rec) for r in connection.execute(s).fetchall(): scol, rschema, rtbl, rcol, rfknm, fkmatch, fkuprule, fkdelrule = r rec = fkeys[rfknm] rec['name'] = rfknm if not rec['referred_table']: rec['referred_table'] = rtbl if schema is not None or owner != rschema: if dbname: rschema = dbname + "." + rschema rec['referred_schema'] = rschema local_cols, remote_cols = \ rec['constrained_columns'],\ rec['referred_columns'] local_cols.append(scol) remote_cols.append(rcol) return list(fkeys.values())