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# mysql/base.py # Copyright (C) 2005-2019 the SQLAlchemy authors and contributors # <see AUTHORS file> # # This module is part of SQLAlchemy and is released under # the MIT License: http://www.opensource.org/licenses/mit-license.php r""" .. dialect:: mysql :name: MySQL Supported Versions and Features ------------------------------- SQLAlchemy supports MySQL starting with version 4.1 through modern releases. However, no heroic measures are taken to work around major missing SQL features - if your server version does not support sub-selects, for example, they won't work in SQLAlchemy either. See the official MySQL documentation for detailed information about features supported in any given server release. .. _mysql_connection_timeouts: Connection Timeouts and Disconnects ----------------------------------- MySQL features an automatic connection close behavior, for connections that have been idle for a fixed period of time, defaulting to eight hours. To circumvent having this issue, use the :paramref:`.create_engine.pool_recycle` option which ensures that a connection will be discarded and replaced with a new one if it has been present in the pool for a fixed number of seconds:: engine = create_engine('mysql+mysqldb://...', pool_recycle=3600) For more comprehensive disconnect detection of pooled connections, including accommodation of server restarts and network issues, a pre-ping approach may be employed. See :ref:`pool_disconnects` for current approaches. .. seealso:: :ref:`pool_disconnects` - Background on several techniques for dealing with timed out connections as well as database restarts. .. _mysql_storage_engines: CREATE TABLE arguments including Storage Engines ------------------------------------------------ MySQL's CREATE TABLE syntax includes a wide array of special options, including ``ENGINE``, ``CHARSET``, ``MAX_ROWS``, ``ROW_FORMAT``, ``INSERT_METHOD``, and many more. To accommodate the rendering of these arguments, specify the form ``mysql_argument_name="value"``. For example, to specify a table with ``ENGINE`` of ``InnoDB``, ``CHARSET`` of ``utf8mb4``, and ``KEY_BLOCK_SIZE`` of ``1024``:: Table('mytable', metadata, Column('data', String(32)), mysql_engine='InnoDB', mysql_charset='utf8mb4', mysql_key_block_size="1024" ) The MySQL dialect will normally transfer any keyword specified as ``mysql_keyword_name`` to be rendered as ``KEYWORD_NAME`` in the ``CREATE TABLE`` statement. A handful of these names will render with a space instead of an underscore; to support this, the MySQL dialect has awareness of these particular names, which include ``DATA DIRECTORY`` (e.g. ``mysql_data_directory``), ``CHARACTER SET`` (e.g. ``mysql_character_set``) and ``INDEX DIRECTORY`` (e.g. ``mysql_index_directory``). The most common argument is ``mysql_engine``, which refers to the storage engine for the table. Historically, MySQL server installations would default to ``MyISAM`` for this value, although newer versions may be defaulting to ``InnoDB``. The ``InnoDB`` engine is typically preferred for its support of transactions and foreign keys. A :class:`.Table` that is created in a MySQL database with a storage engine of ``MyISAM`` will be essentially non-transactional, meaning any INSERT/UPDATE/DELETE statement referring to this table will be invoked as autocommit. It also will have no support for foreign key constraints; while the ``CREATE TABLE`` statement accepts foreign key options, when using the ``MyISAM`` storage engine these arguments are discarded. Reflecting such a table will also produce no foreign key constraint information. For fully atomic transactions as well as support for foreign key constraints, all participating ``CREATE TABLE`` statements must specify a transactional engine, which in the vast majority of cases is ``InnoDB``. .. seealso:: `The InnoDB Storage Engine <http://dev.mysql.com/doc/refman/5.0/en/innodb-storage-engine.html>`_ - on the MySQL website. Case Sensitivity and Table Reflection ------------------------------------- MySQL has inconsistent support for case-sensitive identifier names, basing support on specific details of the underlying operating system. However, it has been observed that no matter what case sensitivity behavior is present, the names of tables in foreign key declarations are *always* received from the database as all-lower case, making it impossible to accurately reflect a schema where inter-related tables use mixed-case identifier names. Therefore it is strongly advised that table names be declared as all lower case both within SQLAlchemy as well as on the MySQL database itself, especially if database reflection features are to be used. .. _mysql_isolation_level: Transaction Isolation Level --------------------------- All MySQL 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 SESSION TRANSACTION ISOLATION LEVEL <level>`` for each new connection. For the special AUTOCOMMIT isolation level, DBAPI-specific techniques are used. To set isolation level using :func:`.create_engine`:: engine = create_engine( "mysql://scott:tiger@localhost/test", isolation_level="READ UNCOMMITTED" ) To set using per-connection execution options:: connection = engine.connect() connection = connection.execution_options( isolation_level="READ COMMITTED" ) Valid values for ``isolation_level`` include: * ``READ COMMITTED`` * ``READ UNCOMMITTED`` * ``REPEATABLE READ`` * ``SERIALIZABLE`` * ``AUTOCOMMIT`` The special ``AUTOCOMMIT`` value makes use of the various "autocommit" attributes provided by specific DBAPIs, and is currently supported by MySQLdb, MySQL-Client, MySQL-Connector Python, and PyMySQL. Using it, the MySQL connection will return true for the value of ``SELECT @@autocommit;``. .. versionadded:: 1.1 - added support for the AUTOCOMMIT isolation level. AUTO_INCREMENT Behavior ----------------------- When creating tables, SQLAlchemy will automatically set ``AUTO_INCREMENT`` on the first :class:`.Integer` primary key column which is not marked as a foreign key:: >>> t = Table('mytable', metadata, ... Column('mytable_id', Integer, primary_key=True) ... ) >>> t.create() CREATE TABLE mytable ( id INTEGER NOT NULL AUTO_INCREMENT, PRIMARY KEY (id) ) You can disable this behavior by passing ``False`` to the :paramref:`~.Column.autoincrement` argument of :class:`.Column`. This flag can also be used to enable auto-increment on a secondary column in a multi-column key for some storage engines:: Table('mytable', metadata, Column('gid', Integer, primary_key=True, autoincrement=False), Column('id', Integer, primary_key=True) ) .. _mysql_ss_cursors: Server Side Cursors ------------------- Server-side cursor support is available for the MySQLdb and PyMySQL dialects. From a MySQL point of view this means that the ``MySQLdb.cursors.SSCursor`` or ``pymysql.cursors.SSCursor`` class is used when building up the cursor which will receive results. The most typical way of invoking this feature is via the :paramref:`.Connection.execution_options.stream_results` connection execution option. Server side cursors can also be enabled for all SELECT statements unconditionally by passing ``server_side_cursors=True`` to :func:`.create_engine`. .. versionadded:: 1.1.4 - added server-side cursor support. .. _mysql_unicode: Unicode ------- Charset Selection ~~~~~~~~~~~~~~~~~ Most MySQL DBAPIs offer the option to set the client character set for a connection. This is typically delivered using the ``charset`` parameter in the URL, such as:: e = create_engine( "mysql+pymysql://scott:tiger@localhost/test?charset=utf8mb4") This charset is the **client character set** for the connection. Some MySQL DBAPIs will default this to a value such as ``latin1``, and some will make use of the ``default-character-set`` setting in the ``my.cnf`` file as well. Documentation for the DBAPI in use should be consulted for specific behavior. The encoding used for Unicode has traditionally been ``'utf8'``. However, for MySQL versions 5.5.3 on forward, a new MySQL-specific encoding ``'utf8mb4'`` has been introduced, and as of MySQL 8.0 a warning is emitted by the server if plain ``utf8`` is specified within any server-side directives, replaced with ``utf8mb3``. The rationale for this new encoding is due to the fact that MySQL's legacy utf-8 encoding only supports codepoints up to three bytes instead of four. Therefore, when communicating with a MySQL database that includes codepoints more than three bytes in size, this new charset is preferred, if supported by both the database as well as the client DBAPI, as in:: e = create_engine( "mysql+pymysql://scott:tiger@localhost/test?charset=utf8mb4") All modern DBAPIs should support the ``utf8mb4`` charset. In order to use ``utf8mb4`` encoding for a schema that was created with legacy ``utf8``, changes to the MySQL schema and/or server configuration may be required. .. seealso:: `The utf8mb4 Character Set \ <http://dev.mysql.com/doc/refman/5.5/en/charset-unicode-utf8mb4.html>`_ - \ in the MySQL documentation .. _mysql_binary_introducer: Dealing with Binary Data Warnings and Unicode ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ MySQL versions 5.6, 5.7 and later (not MariaDB at the time of this writing) now emit a warning when attempting to pass binary data to the database, while a character set encoding is also in place, when the binary data itself is not valid for that encoding:: default.py:509: Warning: (1300, "Invalid utf8mb4 character string: 'F9876A'") cursor.execute(statement, parameters) This warning is due to the fact that the MySQL client library is attempting to interpret the binary string as a unicode object even if a datatype such as :class:`.LargeBinary` is in use. To resolve this, the SQL statement requires a binary "character set introducer" be present before any non-NULL value that renders like this:: INSERT INTO table (data) VALUES (_binary %s) These character set introducers are provided by the DBAPI driver, assuming the use of mysqlclient or PyMySQL (both of which are recommended). Add the query string parameter ``binary_prefix=true`` to the URL to repair this warning:: # mysqlclient engine = create_engine( "mysql+mysqldb://scott:tiger@localhost/test?charset=utf8mb4&binary_prefix=true") # PyMySQL engine = create_engine( "mysql+pymysql://scott:tiger@localhost/test?charset=utf8mb4&binary_prefix=true") The ``binary_prefix`` flag may or may not be supported by other MySQL drivers. SQLAlchemy itself cannot render this ``_binary`` prefix reliably, as it does not work with the NULL value, which is valid to be sent as a bound parameter. As the MySQL driver renders parameters directly into the SQL string, it's the most efficient place for this additional keyword to be passed. .. seealso:: `Character set introducers <https://dev.mysql.com/doc/refman/5.7/en/charset-introducer.html>`_ - on the MySQL website ANSI Quoting Style ------------------ MySQL features two varieties of identifier "quoting style", one using backticks and the other using quotes, e.g. ```some_identifier``` vs. ``"some_identifier"``. All MySQL dialects detect which version is in use by checking the value of ``sql_mode`` when a connection is first established with a particular :class:`.Engine`. This quoting style comes into play when rendering table and column names as well as when reflecting existing database structures. The detection is entirely automatic and no special configuration is needed to use either quoting style. MySQL SQL Extensions -------------------- Many of the MySQL SQL extensions are handled through SQLAlchemy's generic function and operator support:: table.select(table.c.password==func.md5('plaintext')) table.select(table.c.username.op('regexp')('^[a-d]')) And of course any valid MySQL statement can be executed as a string as well. Some limited direct support for MySQL extensions to SQL is currently available. * INSERT..ON DUPLICATE KEY UPDATE: See :ref:`mysql_insert_on_duplicate_key_update` * SELECT pragma, use :meth:`.Select.prefix_with` and :meth:`.Query.prefix_with`:: select(...).prefix_with(['HIGH_PRIORITY', 'SQL_SMALL_RESULT']) * UPDATE with LIMIT:: update(..., mysql_limit=10) * optimizer hints, use :meth:`.Select.prefix_with` and :meth:`.Query.prefix_with`:: select(...).prefix_with("/*+ NO_RANGE_OPTIMIZATION(t4 PRIMARY) */") * index hints, use :meth:`.Select.with_hint` and :meth:`.Query.with_hint`:: select(...).with_hint(some_table, "USE INDEX xyz") .. _mysql_insert_on_duplicate_key_update: INSERT...ON DUPLICATE KEY UPDATE (Upsert) ------------------------------------------ MySQL allows "upserts" (update or insert) of rows into a table via the ``ON DUPLICATE KEY UPDATE`` clause of the ``INSERT`` statement. A candidate row will only be inserted if that row does not match an existing primary or unique key in the table; otherwise, an UPDATE will be performed. The statement allows for separate specification of the values to INSERT versus the values for UPDATE. SQLAlchemy provides ``ON DUPLICATE KEY UPDATE`` support via the MySQL-specific :func:`.mysql.dml.insert()` function, which provides the generative method :meth:`~.mysql.dml.Insert.on_duplicate_key_update`:: from sqlalchemy.dialects.mysql import insert insert_stmt = insert(my_table).values( id='some_existing_id', data='inserted value') on_duplicate_key_stmt = insert_stmt.on_duplicate_key_update( data=insert_stmt.inserted.data, status='U' ) conn.execute(on_duplicate_key_stmt) Unlike PostgreSQL's "ON CONFLICT" phrase, the "ON DUPLICATE KEY UPDATE" phrase will always match on any primary key or unique key, and will always perform an UPDATE if there's a match; there are no options for it to raise an error or to skip performing an UPDATE. ``ON DUPLICATE KEY UPDATE`` is used to perform an update of the already existing row, using any combination of new values as well as values from the proposed insertion. These values are normally specified using keyword arguments passed to the :meth:`~.mysql.dml.Insert.on_duplicate_key_update` given column key values (usually the name of the column, unless it specifies :paramref:`.Column.key`) as keys and literal or SQL expressions as values:: on_duplicate_key_stmt = insert_stmt.on_duplicate_key_update( data="some data", updated_at=func.current_timestamp(), ) In a manner similar to that of :meth:`.UpdateBase.values`, other parameter forms are accepted, including a single dictionary:: on_duplicate_key_stmt = insert_stmt.on_duplicate_key_update( {"data": "some data", "updated_at": func.current_timestamp()}, ) as well as a list of 2-tuples, which will automatically provide a parameter-ordered UPDATE statement in a manner similar to that described at :ref:`updates_order_parameters`. Unlike the :class:`.Update` object, no special flag is needed to specify the intent since the argument form is this context is unambiguous:: on_duplicate_key_stmt = insert_stmt.on_duplicate_key_update( [ ("data", "some data"), ("updated_at", func.current_timestamp()), ], ) .. versionchanged:: 1.3 support for parameter-ordered UPDATE clause within MySQL ON DUPLICATE KEY UPDATE .. warning:: The :meth:`.Insert.on_duplicate_key_update` method does **not** take into account Python-side default UPDATE values or generation functions, e.g. e.g. those specified using :paramref:`.Column.onupdate`. These values will not be exercised for an ON DUPLICATE KEY style of UPDATE, unless they are manually specified explicitly in the parameters. In order to refer to the proposed insertion row, the special alias :attr:`~.mysql.dml.Insert.inserted` is available as an attribute on the :class:`.mysql.dml.Insert` object; this object is a :class:`.ColumnCollection` which contains all columns of the target table:: from sqlalchemy.dialects.mysql import insert stmt = insert(my_table).values( id='some_id', data='inserted value', author='jlh') do_update_stmt = stmt.on_duplicate_key_update( data="updated value", author=stmt.inserted.author ) conn.execute(do_update_stmt) When rendered, the "inserted" namespace will produce the expression ``VALUES(<columnname>)``. .. versionadded:: 1.2 Added support for MySQL ON DUPLICATE KEY UPDATE clause rowcount Support ---------------- SQLAlchemy standardizes the DBAPI ``cursor.rowcount`` attribute to be the usual definition of "number of rows matched by an UPDATE or DELETE" statement. This is in contradiction to the default setting on most MySQL DBAPI drivers, which is "number of rows actually modified/deleted". For this reason, the SQLAlchemy MySQL dialects always add the ``constants.CLIENT.FOUND_ROWS`` flag, or whatever is equivalent for the target dialect, upon connection. This setting is currently hardcoded. .. seealso:: :attr:`.ResultProxy.rowcount` CAST Support ------------ MySQL documents the CAST operator as available in version 4.0.2. When using the SQLAlchemy :func:`.cast` function, SQLAlchemy will not render the CAST token on MySQL before this version, based on server version detection, instead rendering the internal expression directly. CAST may still not be desirable on an early MySQL version post-4.0.2, as it didn't add all datatype support until 4.1.1. If your application falls into this narrow area, the behavior of CAST can be controlled using the :ref:`sqlalchemy.ext.compiler_toplevel` system, as per the recipe below:: from sqlalchemy.sql.expression import Cast from sqlalchemy.ext.compiler import compiles @compiles(Cast, 'mysql') def _check_mysql_version(element, compiler, **kw): if compiler.dialect.server_version_info < (4, 1, 0): return compiler.process(element.clause, **kw) else: return compiler.visit_cast(element, **kw) The above function, which only needs to be declared once within an application, overrides the compilation of the :func:`.cast` construct to check for version 4.1.0 before fully rendering CAST; else the internal element of the construct is rendered directly. .. _mysql_indexes: MySQL Specific Index Options ---------------------------- MySQL-specific extensions to the :class:`.Index` construct are available. Index Length ~~~~~~~~~~~~~ MySQL provides an option to create index entries with a certain length, where "length" refers to the number of characters or bytes in each value which will become part of the index. SQLAlchemy provides this feature via the ``mysql_length`` parameter:: Index('my_index', my_table.c.data, mysql_length=10) Index('a_b_idx', my_table.c.a, my_table.c.b, mysql_length={'a': 4, 'b': 9}) Prefix lengths are given in characters for nonbinary string types and in bytes for binary string types. The value passed to the keyword argument *must* be either an integer (and, thus, specify the same prefix length value for all columns of the index) or a dict in which keys are column names and values are prefix length values for corresponding columns. MySQL only allows a length for a column of an index if it is for a CHAR, VARCHAR, TEXT, BINARY, VARBINARY and BLOB. Index Prefixes ~~~~~~~~~~~~~~ MySQL storage engines permit you to specify an index prefix when creating an index. SQLAlchemy provides this feature via the ``mysql_prefix`` parameter on :class:`.Index`:: Index('my_index', my_table.c.data, mysql_prefix='FULLTEXT') The value passed to the keyword argument will be simply passed through to the underlying CREATE INDEX, so it *must* be a valid index prefix for your MySQL storage engine. .. versionadded:: 1.1.5 .. seealso:: `CREATE INDEX <http://dev.mysql.com/doc/refman/5.0/en/create-index.html>`_ - MySQL documentation Index Types ~~~~~~~~~~~~~ Some MySQL storage engines permit you to specify an index type when creating an index or primary key constraint. SQLAlchemy provides this feature via the ``mysql_using`` parameter on :class:`.Index`:: Index('my_index', my_table.c.data, mysql_using='hash') As well as the ``mysql_using`` parameter on :class:`.PrimaryKeyConstraint`:: PrimaryKeyConstraint("data", mysql_using='hash') The value passed to the keyword argument will be simply passed through to the underlying CREATE INDEX or PRIMARY KEY clause, so it *must* be a valid index type for your MySQL storage engine. More information can be found at: http://dev.mysql.com/doc/refman/5.0/en/create-index.html http://dev.mysql.com/doc/refman/5.0/en/create-table.html Index Parsers ~~~~~~~~~~~~~ CREATE FULLTEXT INDEX in MySQL also supports a "WITH PARSER" option. This is available using the keyword argument ``mysql_with_parser``:: Index( 'my_index', my_table.c.data, mysql_prefix='FULLTEXT', mysql_with_parser="ngram") .. versionadded:: 1.3 .. _mysql_foreign_keys: MySQL Foreign Keys ------------------ MySQL's behavior regarding foreign keys has some important caveats. Foreign Key Arguments to Avoid ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ MySQL does not support the foreign key arguments "DEFERRABLE", "INITIALLY", or "MATCH". Using the ``deferrable`` or ``initially`` keyword argument with :class:`.ForeignKeyConstraint` or :class:`.ForeignKey` will have the effect of these keywords being rendered in a DDL expression, which will then raise an error on MySQL. In order to use these keywords on a foreign key while having them ignored on a MySQL backend, use a custom compile rule:: from sqlalchemy.ext.compiler import compiles from sqlalchemy.schema import ForeignKeyConstraint @compiles(ForeignKeyConstraint, "mysql") def process(element, compiler, **kw): element.deferrable = element.initially = None return compiler.visit_foreign_key_constraint(element, **kw) .. versionchanged:: 0.9.0 - the MySQL backend no longer silently ignores the ``deferrable`` or ``initially`` keyword arguments of :class:`.ForeignKeyConstraint` and :class:`.ForeignKey`. The "MATCH" keyword is in fact more insidious, and is explicitly disallowed by SQLAlchemy in conjunction with the MySQL backend. This argument is silently ignored by MySQL, but in addition has the effect of ON UPDATE and ON DELETE options also being ignored by the backend. Therefore MATCH should never be used with the MySQL backend; as is the case with DEFERRABLE and INITIALLY, custom compilation rules can be used to correct a MySQL ForeignKeyConstraint at DDL definition time. .. versionadded:: 0.9.0 - the MySQL backend will raise a :class:`.CompileError` when the ``match`` keyword is used with :class:`.ForeignKeyConstraint` or :class:`.ForeignKey`. Reflection of Foreign Key Constraints ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Not all MySQL storage engines support foreign keys. When using the very common ``MyISAM`` MySQL storage engine, the information loaded by table reflection will not include foreign keys. For these tables, you may supply a :class:`~sqlalchemy.ForeignKeyConstraint` at reflection time:: Table('mytable', metadata, ForeignKeyConstraint(['other_id'], ['othertable.other_id']), autoload=True ) .. seealso:: :ref:`mysql_storage_engines` .. _mysql_unique_constraints: MySQL Unique Constraints and Reflection --------------------------------------- SQLAlchemy supports both the :class:`.Index` construct with the flag ``unique=True``, indicating a UNIQUE index, as well as the :class:`.UniqueConstraint` construct, representing a UNIQUE constraint. Both objects/syntaxes are supported by MySQL when emitting DDL to create these constraints. However, MySQL does not have a unique constraint construct that is separate from a unique index; that is, the "UNIQUE" constraint on MySQL is equivalent to creating a "UNIQUE INDEX". When reflecting these constructs, the :meth:`.Inspector.get_indexes` and the :meth:`.Inspector.get_unique_constraints` methods will **both** return an entry for a UNIQUE index in MySQL. However, when performing full table reflection using ``Table(..., autoload=True)``, the :class:`.UniqueConstraint` construct is **not** part of the fully reflected :class:`.Table` construct under any circumstances; this construct is always represented by a :class:`.Index` with the ``unique=True`` setting present in the :attr:`.Table.indexes` collection. .. _mysql_timestamp_null: TIMESTAMP Columns and NULL -------------------------- MySQL historically enforces that a column which specifies the TIMESTAMP datatype implicitly includes a default value of CURRENT_TIMESTAMP, even though this is not stated, and additionally sets the column as NOT NULL, the opposite behavior vs. that of all other datatypes:: mysql> CREATE TABLE ts_test ( -> a INTEGER, -> b INTEGER NOT NULL, -> c TIMESTAMP, -> d TIMESTAMP DEFAULT CURRENT_TIMESTAMP, -> e TIMESTAMP NULL); Query OK, 0 rows affected (0.03 sec) mysql> SHOW CREATE TABLE ts_test; +---------+----------------------------------------------------- | Table | Create Table +---------+----------------------------------------------------- | ts_test | CREATE TABLE `ts_test` ( `a` int(11) DEFAULT NULL, `b` int(11) NOT NULL, `c` timestamp NOT NULL DEFAULT CURRENT_TIMESTAMP ON UPDATE CURRENT_TIMESTAMP, `d` timestamp NOT NULL DEFAULT CURRENT_TIMESTAMP, `e` timestamp NULL DEFAULT NULL ) ENGINE=MyISAM DEFAULT CHARSET=latin1 Above, we see that an INTEGER column defaults to NULL, unless it is specified with NOT NULL. But when the column is of type TIMESTAMP, an implicit default of CURRENT_TIMESTAMP is generated which also coerces the column to be a NOT NULL, even though we did not specify it as such. This behavior of MySQL can be changed on the MySQL side using the `explicit_defaults_for_timestamp <http://dev.mysql.com/doc/refman/5.6/en/server-system-variables.html #sysvar_explicit_defaults_for_timestamp>`_ configuration flag introduced in MySQL 5.6. With this server setting enabled, TIMESTAMP columns behave like any other datatype on the MySQL side with regards to defaults and nullability. However, to accommodate the vast majority of MySQL databases that do not specify this new flag, SQLAlchemy emits the "NULL" specifier explicitly with any TIMESTAMP column that does not specify ``nullable=False``. In order to accommodate newer databases that specify ``explicit_defaults_for_timestamp``, SQLAlchemy also emits NOT NULL for TIMESTAMP columns that do specify ``nullable=False``. The following example illustrates:: from sqlalchemy import MetaData, Integer, Table, Column, text from sqlalchemy.dialects.mysql import TIMESTAMP m = MetaData() t = Table('ts_test', m, Column('a', Integer), Column('b', Integer, nullable=False), Column('c', TIMESTAMP), Column('d', TIMESTAMP, nullable=False) ) from sqlalchemy import create_engine e = create_engine("mysql://scott:tiger@localhost/test", echo=True) m.create_all(e) output:: CREATE TABLE ts_test ( a INTEGER, b INTEGER NOT NULL, c TIMESTAMP NULL, d TIMESTAMP NOT NULL ) .. versionchanged:: 1.0.0 - SQLAlchemy now renders NULL or NOT NULL in all cases for TIMESTAMP columns, to accommodate ``explicit_defaults_for_timestamp``. Prior to this version, it will not render "NOT NULL" for a TIMESTAMP column that is ``nullable=False``. """ # noqa from array import array as _array from collections import defaultdict import re import sys from . import reflection as _reflection from .enumerated import ENUM from .enumerated import SET from .json import JSON from .json import JSONIndexType from .json import JSONPathType from .types import _FloatType from .types import _IntegerType from .types import _MatchType from .types import _NumericType from .types import _StringType from .types import BIGINT from .types import BIT from .types import CHAR from .types import DATETIME from .types import DECIMAL from .types import DOUBLE from .types import FLOAT from .types import INTEGER from .types import LONGBLOB from .types import LONGTEXT from .types import MEDIUMBLOB from .types import MEDIUMINT from .types import MEDIUMTEXT from .types import NCHAR from .types import NUMERIC from .types import NVARCHAR from .types import REAL from .types import SMALLINT from .types import TEXT from .types import TIME from .types import TIMESTAMP from .types import TINYBLOB from .types import TINYINT from .types import TINYTEXT from .types import VARCHAR from .types import YEAR from ... import exc from ... import log from ... import schema as sa_schema from ... import sql from ... import types as sqltypes from ... import util from ...engine import default from ...engine import reflection from ...sql import compiler from ...sql import elements from ...types import BINARY from ...types import BLOB from ...types import BOOLEAN from ...types import DATE from ...types import VARBINARY from ...util import topological RESERVED_WORDS = set( [ "accessible", "add", "all", "alter", "analyze", "and", "as", "asc", "asensitive", "before", "between", "bigint", "binary", "blob", "both", "by", "call", "cascade", "case", "change", "char", "character", "check", "collate", "column", "condition", "constraint", "continue", "convert", "create", "cross", "current_date", "current_time", "current_timestamp", "current_user", "cursor", "database", "databases", "day_hour", "day_microsecond", "day_minute", "day_second", "dec", "decimal", "declare", "default", "delayed", "delete", "desc", "describe", "deterministic", "distinct", "distinctrow", "div", "double", "drop", "dual", "each", "else", "elseif", "enclosed", "escaped", "exists", "exit", "explain", "false", "fetch", "float", "float4", "float8", "for", "force", "foreign", "from", "fulltext", "grant", "group", "having", "high_priority", "hour_microsecond", "hour_minute", "hour_second", "if", "ignore", "in", "index", "infile", "inner", "inout", "insensitive", "insert", "int", "int1", "int2", "int3", "int4", "int8", "integer", "interval", "into", "is", "iterate", "join", "key", "keys", "kill", "leading", "leave", "left", "like", "limit", "linear", "lines", "load", "localtime", "localtimestamp", "lock", "long", "longblob", "longtext", "loop", "low_priority", "master_ssl_verify_server_cert", "match", "mediumblob", "mediumint", "mediumtext", "middleint", "minute_microsecond", "minute_second", "mod", "modifies", "natural", "not", "no_write_to_binlog", "null", "numeric", "on", "optimize", "option", "optionally", "or", "order", "out", "outer", "outfile", "precision", "primary", "procedure", "purge", "range", "read", "reads", "read_only", "read_write", "real", "references", "regexp", "release", "rename", "repeat", "replace", "require", "restrict", "return", "revoke", "right", "rlike", "schema", "schemas", "second_microsecond", "select", "sensitive", "separator", "set", "show", "smallint", "spatial", "specific", "sql", "sqlexception", "sqlstate", "sqlwarning", "sql_big_result", "sql_calc_found_rows", "sql_small_result", "ssl", "starting", "straight_join", "table", "terminated", "then", "tinyblob", "tinyint", "tinytext", "to", "trailing", "trigger", "true", "undo", "union", "unique", "unlock", "unsigned", "update", "usage", "use", "using", "utc_date", "utc_time", "utc_timestamp", "values", "varbinary", "varchar", "varcharacter", "varying", "when", "where", "while", "with", "write", "x509", "xor", "year_month", "zerofill", # 5.0 "columns", "fields", "privileges", "soname", "tables", # 4.1 "accessible", "linear", "master_ssl_verify_server_cert", "range", "read_only", "read_write", # 5.1 "general", "ignore_server_ids", "master_heartbeat_period", "maxvalue", "resignal", "signal", "slow", # 5.5 "get", "io_after_gtids", "io_before_gtids", "master_bind", "one_shot", "partition", "sql_after_gtids", "sql_before_gtids", # 5.6 "generated", "optimizer_costs", "stored", "virtual", # 5.7 "admin", "cume_dist", "empty", "except", "first_value", "grouping", "function", "groups", "json_table", "last_value", "nth_value", "ntile", "of", "over", "percent_rank", "persist", "persist_only", "rank", "recursive", "role", "row", "rows", "row_number", "system", "window", # 8.0 ] ) AUTOCOMMIT_RE = re.compile( r"\s*(?:UPDATE|INSERT|CREATE|DELETE|DROP|ALTER|LOAD +DATA|REPLACE)", re.I | re.UNICODE, ) SET_RE = re.compile( r"\s*SET\s+(?:(?:GLOBAL|SESSION)\s+)?\w", re.I | re.UNICODE ) # old names MSTime = TIME MSSet = SET MSEnum = ENUM MSLongBlob = LONGBLOB MSMediumBlob = MEDIUMBLOB MSTinyBlob = TINYBLOB MSBlob = BLOB MSBinary = BINARY MSVarBinary = VARBINARY MSNChar = NCHAR MSNVarChar = NVARCHAR MSChar = CHAR MSString = VARCHAR MSLongText = LONGTEXT MSMediumText = MEDIUMTEXT MSTinyText = TINYTEXT MSText = TEXT MSYear = YEAR MSTimeStamp = TIMESTAMP MSBit = BIT MSSmallInteger = SMALLINT MSTinyInteger = TINYINT MSMediumInteger = MEDIUMINT MSBigInteger = BIGINT MSNumeric = NUMERIC MSDecimal = DECIMAL MSDouble = DOUBLE MSReal = REAL MSFloat = FLOAT MSInteger = INTEGER colspecs = { _IntegerType: _IntegerType, _NumericType: _NumericType, _FloatType: _FloatType, sqltypes.Numeric: NUMERIC, sqltypes.Float: FLOAT, sqltypes.Time: TIME, sqltypes.Enum: ENUM, sqltypes.MatchType: _MatchType, sqltypes.JSON: JSON, sqltypes.JSON.JSONIndexType: JSONIndexType, sqltypes.JSON.JSONPathType: JSONPathType, } # Everything 3.23 through 5.1 excepting OpenGIS types. ischema_names = { "bigint": BIGINT, "binary": BINARY, "bit": BIT, "blob": BLOB, "boolean": BOOLEAN, "char": CHAR, "date": DATE, "datetime": DATETIME, "decimal": DECIMAL, "double": DOUBLE, "enum": ENUM, "fixed": DECIMAL, "float": FLOAT, "int": INTEGER, "integer": INTEGER, "json": JSON, "longblob": LONGBLOB, "longtext": LONGTEXT, "mediumblob": MEDIUMBLOB, "mediumint": MEDIUMINT, "mediumtext": MEDIUMTEXT, "nchar": NCHAR, "nvarchar": NVARCHAR, "numeric": NUMERIC, "set": SET, "smallint": SMALLINT, "text": TEXT, "time": TIME, "timestamp": TIMESTAMP, "tinyblob": TINYBLOB, "tinyint": TINYINT, "tinytext": TINYTEXT, "varbinary": VARBINARY, "varchar": VARCHAR, "year": YEAR, } class MySQLExecutionContext(default.DefaultExecutionContext): def should_autocommit_text(self, statement): return AUTOCOMMIT_RE.match(statement) def create_server_side_cursor(self): if self.dialect.supports_server_side_cursors: return self._dbapi_connection.cursor(self.dialect._sscursor) else: raise NotImplementedError() class MySQLCompiler(compiler.SQLCompiler): render_table_with_column_in_update_from = True """Overridden from base SQLCompiler value""" extract_map = compiler.SQLCompiler.extract_map.copy() extract_map.update({"milliseconds": "millisecond"}) def visit_random_func(self, fn, **kw): return "rand%s" % self.function_argspec(fn) def visit_sysdate_func(self, fn, **kw): return "SYSDATE()" def visit_json_getitem_op_binary(self, binary, operator, **kw): return "JSON_EXTRACT(%s, %s)" % ( self.process(binary.left, **kw), self.process(binary.right, **kw), ) def visit_json_path_getitem_op_binary(self, binary, operator, **kw): return "JSON_EXTRACT(%s, %s)" % ( self.process(binary.left, **kw), self.process(binary.right, **kw), ) def visit_on_duplicate_key_update(self, on_duplicate, **kw): if on_duplicate._parameter_ordering: parameter_ordering = [ elements._column_as_key(key) for key in on_duplicate._parameter_ordering ] ordered_keys = set(parameter_ordering) cols = [ self.statement.table.c[key] for key in parameter_ordering if key in self.statement.table.c ] + [ c for c in self.statement.table.c if c.key not in ordered_keys ] else: cols = self.statement.table.c clauses = [] # traverses through all table columns to preserve table column order for column in (col for col in cols if col.key in on_duplicate.update): val = on_duplicate.update[column.key] if elements._is_literal(val): val = elements.BindParameter(None, val, type_=column.type) value_text = self.process(val.self_group(), use_schema=False) elif isinstance(val, elements.BindParameter) and val.type._isnull: val = val._clone() val.type = column.type value_text = self.process(val.self_group(), use_schema=False) elif ( isinstance(val, elements.ColumnClause) and val.table is on_duplicate.inserted_alias ): value_text = "VALUES(" + self.preparer.quote(column.name) + ")" else: value_text = self.process(val.self_group(), use_schema=False) name_text = self.preparer.quote(column.name) clauses.append("%s = %s" % (name_text, value_text)) non_matching = set(on_duplicate.update) - set(c.key for c in cols) if non_matching: util.warn( "Additional column names not matching " "any column keys in table '%s': %s" % ( self.statement.table.name, (", ".join("'%s'" % c for c in non_matching)), ) ) return "ON DUPLICATE KEY UPDATE " + ", ".join(clauses) def visit_concat_op_binary(self, binary, operator, **kw): return "concat(%s, %s)" % ( self.process(binary.left, **kw), self.process(binary.right, **kw), ) def visit_match_op_binary(self, binary, operator, **kw): return "MATCH (%s) AGAINST (%s IN BOOLEAN MODE)" % ( self.process(binary.left, **kw), self.process(binary.right, **kw), ) def get_from_hint_text(self, table, text): return text def visit_typeclause(self, typeclause, type_=None, **kw): if type_ is None: type_ = typeclause.type.dialect_impl(self.dialect) if isinstance(type_, sqltypes.TypeDecorator): return self.visit_typeclause(typeclause, type_.impl, **kw) elif isinstance(type_, sqltypes.Integer): if getattr(type_, "unsigned", False): return "UNSIGNED INTEGER" else: return "SIGNED INTEGER" elif isinstance(type_, sqltypes.TIMESTAMP): return "DATETIME" elif isinstance( type_, ( sqltypes.DECIMAL, sqltypes.DateTime, sqltypes.Date, sqltypes.Time, ), ): return self.dialect.type_compiler.process(type_) elif isinstance(type_, sqltypes.String) and not isinstance( type_, (ENUM, SET) ): adapted = CHAR._adapt_string_for_cast(type_) return self.dialect.type_compiler.process(adapted) elif isinstance(type_, sqltypes._Binary): return "BINARY" elif isinstance(type_, sqltypes.JSON): return "JSON" elif isinstance(type_, sqltypes.NUMERIC): return self.dialect.type_compiler.process(type_).replace( "NUMERIC", "DECIMAL" ) else: return None def visit_cast(self, cast, **kw): # No cast until 4, no decimals until 5. if not self.dialect._supports_cast: util.warn( "Current MySQL version does not support " "CAST; the CAST will be skipped." ) return self.process(cast.clause.self_group(), **kw) type_ = self.process(cast.typeclause) if type_ is None: util.warn( "Datatype %s does not support CAST on MySQL; " "the CAST will be skipped." % self.dialect.type_compiler.process(cast.typeclause.type) ) return self.process(cast.clause.self_group(), **kw) return "CAST(%s AS %s)" % (self.process(cast.clause, **kw), type_) def render_literal_value(self, value, type_): value = super(MySQLCompiler, self).render_literal_value(value, type_) if self.dialect._backslash_escapes: value = value.replace("\\", "\\\\") return value # override native_boolean=False behavior here, as # MySQL still supports native boolean def visit_true(self, element, **kw): return "true" def visit_false(self, element, **kw): return "false" def get_select_precolumns(self, select, **kw): """Add special MySQL keywords in place of DISTINCT. .. note:: this usage is deprecated. :meth:`.Select.prefix_with` should be used for special keywords at the start of a SELECT. """ if isinstance(select._distinct, util.string_types): return select._distinct.upper() + " " elif select._distinct: return "DISTINCT " else: return "" def visit_join(self, join, asfrom=False, **kwargs): if join.full: join_type = " FULL OUTER JOIN " elif join.isouter: join_type = " LEFT OUTER JOIN " else: join_type = " INNER JOIN " return "".join( ( self.process(join.left, asfrom=True, **kwargs), join_type, self.process(join.right, asfrom=True, **kwargs), " ON ", self.process(join.onclause, **kwargs), ) ) def for_update_clause(self, select, **kw): if select._for_update_arg.read: return " LOCK IN SHARE MODE" else: return " FOR UPDATE" def limit_clause(self, select, **kw): # MySQL supports: # LIMIT <limit> # LIMIT <offset>, <limit> # and in server versions > 3.3: # LIMIT <limit> OFFSET <offset> # The latter is more readable for offsets but we're stuck with the # former until we can refine dialects by server revision. limit_clause, offset_clause = ( select._limit_clause, select._offset_clause, ) if limit_clause is None and offset_clause is None: return "" elif offset_clause is not None: # As suggested by the MySQL docs, need to apply an # artificial limit if one wasn't provided # http://dev.mysql.com/doc/refman/5.0/en/select.html if limit_clause is None: # hardwire the upper limit. Currently # needed by OurSQL with Python 3 # (https://bugs.launchpad.net/oursql/+bug/686232), # but also is consistent with the usage of the upper # bound as part of MySQL's "syntax" for OFFSET with # no LIMIT return " \n LIMIT %s, %s" % ( self.process(offset_clause, **kw), "18446744073709551615", ) else: return " \n LIMIT %s, %s" % ( self.process(offset_clause, **kw), self.process(limit_clause, **kw), ) else: # No offset provided, so just use the limit return " \n LIMIT %s" % (self.process(limit_clause, **kw),) def update_limit_clause(self, update_stmt): limit = update_stmt.kwargs.get("%s_limit" % self.dialect.name, None) if limit: return "LIMIT %s" % limit else: return None def update_tables_clause(self, update_stmt, from_table, extra_froms, **kw): return ", ".join( t._compiler_dispatch(self, asfrom=True, **kw) for t in [from_table] + list(extra_froms) ) def update_from_clause( self, update_stmt, from_table, extra_froms, from_hints, **kw ): return None 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 .. USING clause specific to MySQL.""" return "USING " + ", ".join( t._compiler_dispatch(self, asfrom=True, fromhints=from_hints, **kw) for t in [from_table] + extra_froms ) def visit_empty_set_expr(self, element_types): return ( "SELECT %(outer)s FROM (SELECT %(inner)s) " "as _empty_set WHERE 1!=1" % { "inner": ", ".join( "1 AS _in_%s" % idx for idx, type_ in enumerate(element_types) ), "outer": ", ".join( "_in_%s" % idx for idx, type_ in enumerate(element_types) ), } ) class MySQLDDLCompiler(compiler.DDLCompiler): def get_column_specification(self, column, **kw): """Builds column DDL.""" colspec = [ self.preparer.format_column(column), self.dialect.type_compiler.process( column.type, type_expression=column ), ] is_timestamp = isinstance( column.type._unwrapped_dialect_impl(self.dialect), sqltypes.TIMESTAMP, ) if not column.nullable: colspec.append("NOT NULL") # see: http://docs.sqlalchemy.org/en/latest/dialects/ # mysql.html#mysql_timestamp_null elif column.nullable and is_timestamp: colspec.append("NULL") default = self.get_column_default_string(column) if default is not None: colspec.append("DEFAULT " + default) comment = column.comment if comment is not None: literal = self.sql_compiler.render_literal_value( comment, sqltypes.String() ) colspec.append("COMMENT " + literal) if ( column.table is not None and column is column.table._autoincrement_column and column.server_default is None ): colspec.append("AUTO_INCREMENT") return " ".join(colspec) def post_create_table(self, table): """Build table-level CREATE options like ENGINE and COLLATE.""" table_opts = [] opts = dict( (k[len(self.dialect.name) + 1 :].upper(), v) for k, v in table.kwargs.items() if k.startswith("%s_" % self.dialect.name) ) if table.comment is not None: opts["COMMENT"] = table.comment partition_options = [ "PARTITION_BY", "PARTITIONS", "SUBPARTITIONS", "SUBPARTITION_BY", ] nonpart_options = set(opts).difference(partition_options) part_options = set(opts).intersection(partition_options) for opt in topological.sort( [ ("DEFAULT_CHARSET", "COLLATE"), ("DEFAULT_CHARACTER_SET", "COLLATE"), ], nonpart_options, ): arg = opts[opt] if opt in _reflection._options_of_type_string: arg = self.sql_compiler.render_literal_value( arg, sqltypes.String() ) if opt in ( "DATA_DIRECTORY", "INDEX_DIRECTORY", "DEFAULT_CHARACTER_SET", "CHARACTER_SET", "DEFAULT_CHARSET", "DEFAULT_COLLATE", ): opt = opt.replace("_", " ") joiner = "=" if opt in ( "TABLESPACE", "DEFAULT CHARACTER SET", "CHARACTER SET", "COLLATE", ): joiner = " " table_opts.append(joiner.join((opt, arg))) for opt in topological.sort( [ ("PARTITION_BY", "PARTITIONS"), ("PARTITION_BY", "SUBPARTITION_BY"), ("PARTITION_BY", "SUBPARTITIONS"), ("PARTITIONS", "SUBPARTITIONS"), ("PARTITIONS", "SUBPARTITION_BY"), ("SUBPARTITION_BY", "SUBPARTITIONS"), ], part_options, ): arg = opts[opt] if opt in _reflection._options_of_type_string: arg = self.sql_compiler.render_literal_value( arg, sqltypes.String() ) opt = opt.replace("_", " ") joiner = " " table_opts.append(joiner.join((opt, arg))) return " ".join(table_opts) def visit_create_index(self, create, **kw): index = create.element self._verify_index_table(index) preparer = self.preparer table = preparer.format_table(index.table) columns = [ self.sql_compiler.process( expr, include_table=False, literal_binds=True ) for expr in index.expressions ] name = self._prepared_index_name(index) text = "CREATE " if index.unique: text += "UNIQUE " index_prefix = index.kwargs.get("mysql_prefix", None) if index_prefix: text += index_prefix + " " text += "INDEX %s ON %s " % (name, table) length = index.dialect_options["mysql"]["length"] if length is not None: if isinstance(length, dict): # length value can be a (column_name --> integer value) # mapping specifying the prefix length for each column of the # index columns = ", ".join( "%s(%d)" % (expr, length[col.name]) if col.name in length else ( "%s(%d)" % (expr, length[expr]) if expr in length else "%s" % expr ) for col, expr in zip(index.expressions, columns) ) else: # or can be an integer value specifying the same # prefix length for all columns of the index columns = ", ".join( "%s(%d)" % (col, length) for col in columns ) else: columns = ", ".join(columns) text += "(%s)" % columns parser = index.dialect_options["mysql"]["with_parser"] if parser is not None: text += " WITH PARSER %s" % (parser,) using = index.dialect_options["mysql"]["using"] if using is not None: text += " USING %s" % (preparer.quote(using)) return text def visit_primary_key_constraint(self, constraint): text = super(MySQLDDLCompiler, self).visit_primary_key_constraint( constraint ) using = constraint.dialect_options["mysql"]["using"] if using: text += " USING %s" % (self.preparer.quote(using)) return text def visit_drop_index(self, drop): index = drop.element return "\nDROP INDEX %s ON %s" % ( self._prepared_index_name(index, include_schema=False), self.preparer.format_table(index.table), ) def visit_drop_constraint(self, drop): constraint = drop.element if isinstance(constraint, sa_schema.ForeignKeyConstraint): qual = "FOREIGN KEY " const = self.preparer.format_constraint(constraint) elif isinstance(constraint, sa_schema.PrimaryKeyConstraint): qual = "PRIMARY KEY " const = "" elif isinstance(constraint, sa_schema.UniqueConstraint): qual = "INDEX " const = self.preparer.format_constraint(constraint) elif isinstance(constraint, sa_schema.CheckConstraint): if self.dialect._is_mariadb: qual = "CONSTRAINT " else: qual = "CHECK " const = self.preparer.format_constraint(constraint) else: qual = "" const = self.preparer.format_constraint(constraint) return "ALTER TABLE %s DROP %s%s" % ( self.preparer.format_table(constraint.table), qual, const, ) def define_constraint_match(self, constraint): if constraint.match is not None: raise exc.CompileError( "MySQL ignores the 'MATCH' keyword while at the same time " "causes ON UPDATE/ON DELETE clauses to be ignored." ) return "" def visit_set_table_comment(self, create): return "ALTER TABLE %s COMMENT %s" % ( self.preparer.format_table(create.element), self.sql_compiler.render_literal_value( create.element.comment, sqltypes.String() ), ) def visit_drop_table_comment(self, create): return "ALTER TABLE %s COMMENT ''" % ( self.preparer.format_table(create.element) ) def visit_set_column_comment(self, create): return "ALTER TABLE %s CHANGE %s %s" % ( self.preparer.format_table(create.element.table), self.preparer.format_column(create.element), self.get_column_specification(create.element), ) class MySQLTypeCompiler(compiler.GenericTypeCompiler): def _extend_numeric(self, type_, spec): "Extend a numeric-type declaration with MySQL specific extensions." if not self._mysql_type(type_): return spec if type_.unsigned: spec += " UNSIGNED" if type_.zerofill: spec += " ZEROFILL" return spec def _extend_string(self, type_, defaults, spec): """Extend a string-type declaration with standard SQL CHARACTER SET / COLLATE annotations and MySQL specific extensions. """ def attr(name): return getattr(type_, name, defaults.get(name)) if attr("charset"): charset = "CHARACTER SET %s" % attr("charset") elif attr("ascii"): charset = "ASCII" elif attr("unicode"): charset = "UNICODE" else: charset = None if attr("collation"): collation = "COLLATE %s" % type_.collation elif attr("binary"): collation = "BINARY" else: collation = None if attr("national"): # NATIONAL (aka NCHAR/NVARCHAR) trumps charsets. return " ".join( [c for c in ("NATIONAL", spec, collation) if c is not None] ) return " ".join( [c for c in (spec, charset, collation) if c is not None] ) def _mysql_type(self, type_): return isinstance(type_, (_StringType, _NumericType)) def visit_NUMERIC(self, type_, **kw): if type_.precision is None: return self._extend_numeric(type_, "NUMERIC") elif type_.scale is None: return self._extend_numeric( type_, "NUMERIC(%(precision)s)" % {"precision": type_.precision}, ) else: return self._extend_numeric( type_, "NUMERIC(%(precision)s, %(scale)s)" % {"precision": type_.precision, "scale": type_.scale}, ) def visit_DECIMAL(self, type_, **kw): if type_.precision is None: return self._extend_numeric(type_, "DECIMAL") elif type_.scale is None: return self._extend_numeric( type_, "DECIMAL(%(precision)s)" % {"precision": type_.precision}, ) else: return self._extend_numeric( type_, "DECIMAL(%(precision)s, %(scale)s)" % {"precision": type_.precision, "scale": type_.scale}, ) def visit_DOUBLE(self, type_, **kw): if type_.precision is not None and type_.scale is not None: return self._extend_numeric( type_, "DOUBLE(%(precision)s, %(scale)s)" % {"precision": type_.precision, "scale": type_.scale}, ) else: return self._extend_numeric(type_, "DOUBLE") def visit_REAL(self, type_, **kw): if type_.precision is not None and type_.scale is not None: return self._extend_numeric( type_, "REAL(%(precision)s, %(scale)s)" % {"precision": type_.precision, "scale": type_.scale}, ) else: return self._extend_numeric(type_, "REAL") def visit_FLOAT(self, type_, **kw): if ( self._mysql_type(type_) and type_.scale is not None and type_.precision is not None ): return self._extend_numeric( type_, "FLOAT(%s, %s)" % (type_.precision, type_.scale) ) elif type_.precision is not None: return self._extend_numeric( type_, "FLOAT(%s)" % (type_.precision,) ) else: return self._extend_numeric(type_, "FLOAT") def visit_INTEGER(self, type_, **kw): if self._mysql_type(type_) and type_.display_width is not None: return self._extend_numeric( type_, "INTEGER(%(display_width)s)" % {"display_width": type_.display_width}, ) else: return self._extend_numeric(type_, "INTEGER") def visit_BIGINT(self, type_, **kw): if self._mysql_type(type_) and type_.display_width is not None: return self._extend_numeric( type_, "BIGINT(%(display_width)s)" % {"display_width": type_.display_width}, ) else: return self._extend_numeric(type_, "BIGINT") def visit_MEDIUMINT(self, type_, **kw): if self._mysql_type(type_) and type_.display_width is not None: return self._extend_numeric( type_, "MEDIUMINT(%(display_width)s)" % {"display_width": type_.display_width}, ) else: return self._extend_numeric(type_, "MEDIUMINT") def visit_TINYINT(self, type_, **kw): if self._mysql_type(type_) and type_.display_width is not None: return self._extend_numeric( type_, "TINYINT(%s)" % type_.display_width ) else: return self._extend_numeric(type_, "TINYINT") def visit_SMALLINT(self, type_, **kw): if self._mysql_type(type_) and type_.display_width is not None: return self._extend_numeric( type_, "SMALLINT(%(display_width)s)" % {"display_width": type_.display_width}, ) else: return self._extend_numeric(type_, "SMALLINT") def visit_BIT(self, type_, **kw): if type_.length is not None: return "BIT(%s)" % type_.length else: return "BIT" def visit_DATETIME(self, type_, **kw): if getattr(type_, "fsp", None): return "DATETIME(%d)" % type_.fsp else: return "DATETIME" def visit_DATE(self, type_, **kw): return "DATE" def visit_TIME(self, type_, **kw): if getattr(type_, "fsp", None): return "TIME(%d)" % type_.fsp else: return "TIME" def visit_TIMESTAMP(self, type_, **kw): if getattr(type_, "fsp", None): return "TIMESTAMP(%d)" % type_.fsp else: return "TIMESTAMP" def visit_YEAR(self, type_, **kw): if type_.display_width is None: return "YEAR" else: return "YEAR(%s)" % type_.display_width def visit_TEXT(self, type_, **kw): if type_.length: return self._extend_string(type_, {}, "TEXT(%d)" % type_.length) else: return self._extend_string(type_, {}, "TEXT") def visit_TINYTEXT(self, type_, **kw): return self._extend_string(type_, {}, "TINYTEXT") def visit_MEDIUMTEXT(self, type_, **kw): return self._extend_string(type_, {}, "MEDIUMTEXT") def visit_LONGTEXT(self, type_, **kw): return self._extend_string(type_, {}, "LONGTEXT") def visit_VARCHAR(self, type_, **kw): if type_.length: return self._extend_string(type_, {}, "VARCHAR(%d)" % type_.length) else: raise exc.CompileError( "VARCHAR requires a length on dialect %s" % self.dialect.name ) def visit_CHAR(self, type_, **kw): if type_.length: return self._extend_string( type_, {}, "CHAR(%(length)s)" % {"length": type_.length} ) else: return self._extend_string(type_, {}, "CHAR") def visit_NVARCHAR(self, type_, **kw): # We'll actually generate the equiv. "NATIONAL VARCHAR" instead # of "NVARCHAR". if type_.length: return self._extend_string( type_, {"national": True}, "VARCHAR(%(length)s)" % {"length": type_.length}, ) else: raise exc.CompileError( "NVARCHAR requires a length on dialect %s" % self.dialect.name ) def visit_NCHAR(self, type_, **kw): # We'll actually generate the equiv. # "NATIONAL CHAR" instead of "NCHAR". if type_.length: return self._extend_string( type_, {"national": True}, "CHAR(%(length)s)" % {"length": type_.length}, ) else: return self._extend_string(type_, {"national": True}, "CHAR") def visit_VARBINARY(self, type_, **kw): return "VARBINARY(%d)" % type_.length def visit_JSON(self, type_, **kw): return "JSON" def visit_large_binary(self, type_, **kw): return self.visit_BLOB(type_) def visit_enum(self, type_, **kw): if not type_.native_enum: return super(MySQLTypeCompiler, self).visit_enum(type_) else: return self._visit_enumerated_values("ENUM", type_, type_.enums) def visit_BLOB(self, type_, **kw): if type_.length: return "BLOB(%d)" % type_.length else: return "BLOB" def visit_TINYBLOB(self, type_, **kw): return "TINYBLOB" def visit_MEDIUMBLOB(self, type_, **kw): return "MEDIUMBLOB" def visit_LONGBLOB(self, type_, **kw): return "LONGBLOB" def _visit_enumerated_values(self, name, type_, enumerated_values): quoted_enums = [] for e in enumerated_values: quoted_enums.append("'%s'" % e.replace("'", "''")) return self._extend_string( type_, {}, "%s(%s)" % (name, ",".join(quoted_enums)) ) def visit_ENUM(self, type_, **kw): return self._visit_enumerated_values( "ENUM", type_, type_._enumerated_values ) def visit_SET(self, type_, **kw): return self._visit_enumerated_values( "SET", type_, type_._enumerated_values ) def visit_BOOLEAN(self, type_, **kw): return "BOOL" class MySQLIdentifierPreparer(compiler.IdentifierPreparer): reserved_words = RESERVED_WORDS def __init__(self, dialect, server_ansiquotes=False, **kw): if not server_ansiquotes: quote = "`" else: quote = '"' super(MySQLIdentifierPreparer, self).__init__( dialect, initial_quote=quote, escape_quote=quote ) def _quote_free_identifiers(self, *ids): """Unilaterally identifier-quote any number of strings.""" return tuple([self.quote_identifier(i) for i in ids if i is not None]) @log.class_logger class MySQLDialect(default.DefaultDialect): """Details of the MySQL dialect. Not used directly in application code. """ name = "mysql" supports_alter = True # MySQL has no true "boolean" type; we # allow for the "true" and "false" keywords, however supports_native_boolean = False # identifiers are 64, however aliases can be 255... max_identifier_length = 255 max_index_name_length = 64 supports_native_enum = True supports_sane_rowcount = True supports_sane_multi_rowcount = False supports_multivalues_insert = True supports_comments = True inline_comments = True default_paramstyle = "format" colspecs = colspecs cte_follows_insert = True statement_compiler = MySQLCompiler ddl_compiler = MySQLDDLCompiler type_compiler = MySQLTypeCompiler ischema_names = ischema_names preparer = MySQLIdentifierPreparer # default SQL compilation settings - # these are modified upon initialize(), # i.e. first connect _backslash_escapes = True _server_ansiquotes = False construct_arguments = [ (sa_schema.Table, {"*": None}), (sql.Update, {"limit": None}), (sa_schema.PrimaryKeyConstraint, {"using": None}), ( sa_schema.Index, { "using": None, "length": None, "prefix": None, "with_parser": None, }, ), ] def __init__( self, isolation_level=None, json_serializer=None, json_deserializer=None, **kwargs ): kwargs.pop("use_ansiquotes", None) # legacy default.DefaultDialect.__init__(self, **kwargs) self.isolation_level = isolation_level self._json_serializer = json_serializer self._json_deserializer = json_deserializer 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 _isolation_lookup = set( [ "SERIALIZABLE", "READ UNCOMMITTED", "READ COMMITTED", "REPEATABLE READ", ] ) def set_isolation_level(self, connection, level): level = level.replace("_", " ") # adjust for ConnectionFairy being present # allows attribute set e.g. "connection.autocommit = True" # to work properly if hasattr(connection, "connection"): connection = connection.connection self._set_isolation_level(connection, level) def _set_isolation_level(self, connection, level): 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 SESSION TRANSACTION ISOLATION LEVEL %s" % level) cursor.execute("COMMIT") cursor.close() def get_isolation_level(self, connection): cursor = connection.cursor() if self._is_mysql and self.server_version_info >= (5, 7, 20): cursor.execute("SELECT @@transaction_isolation") else: cursor.execute("SELECT @@tx_isolation") val = cursor.fetchone()[0] cursor.close() if util.py3k and isinstance(val, bytes): val = val.decode() return val.upper().replace("-", " ") def _get_server_version_info(self, connection): # get database server version info explicitly over the wire # to avoid proxy servers like MaxScale getting in the # way with their own values, see #4205 dbapi_con = connection.connection cursor = dbapi_con.cursor() cursor.execute("SELECT VERSION()") val = cursor.fetchone()[0] cursor.close() if util.py3k and isinstance(val, bytes): val = val.decode() return self._parse_server_version(val) def _parse_server_version(self, val): version = [] r = re.compile(r"[.\-]") for n in r.split(val): try: version.append(int(n)) except ValueError: mariadb = re.match(r"(.*)(MariaDB)(.*)", n) if mariadb: version.extend(g for g in mariadb.groups() if g) else: version.append(n) return tuple(version) def do_commit(self, dbapi_connection): """Execute a COMMIT.""" # COMMIT/ROLLBACK were introduced in 3.23.15. # Yes, we have at least one user who has to talk to these old # versions! # # Ignore commit/rollback if support isn't present, otherwise even # basic operations via autocommit fail. try: dbapi_connection.commit() except Exception: if self.server_version_info < (3, 23, 15): args = sys.exc_info()[1].args if args and args[0] == 1064: return raise def do_rollback(self, dbapi_connection): """Execute a ROLLBACK.""" try: dbapi_connection.rollback() except Exception: if self.server_version_info < (3, 23, 15): args = sys.exc_info()[1].args if args and args[0] == 1064: return raise def do_begin_twophase(self, connection, xid): connection.execute(sql.text("XA BEGIN :xid"), xid=xid) def do_prepare_twophase(self, connection, xid): connection.execute(sql.text("XA END :xid"), xid=xid) connection.execute(sql.text("XA PREPARE :xid"), xid=xid) def do_rollback_twophase( self, connection, xid, is_prepared=True, recover=False ): if not is_prepared: connection.execute(sql.text("XA END :xid"), xid=xid) connection.execute(sql.text("XA ROLLBACK :xid"), xid=xid) def do_commit_twophase( self, connection, xid, is_prepared=True, recover=False ): if not is_prepared: self.do_prepare_twophase(connection, xid) connection.execute(sql.text("XA COMMIT :xid"), xid=xid) def do_recover_twophase(self, connection): resultset = connection.execute("XA RECOVER") return [row["data"][0 : row["gtrid_length"]] for row in resultset] def is_disconnect(self, e, connection, cursor): if isinstance( e, (self.dbapi.OperationalError, self.dbapi.ProgrammingError) ): return self._extract_error_code(e) in ( 2006, 2013, 2014, 2045, 2055, ) elif isinstance( e, (self.dbapi.InterfaceError, self.dbapi.InternalError) ): # if underlying connection is closed, # this is the error you get return "(0, '')" in str(e) else: return False def _compat_fetchall(self, rp, charset=None): """Proxy result rows to smooth over MySQL-Python driver inconsistencies.""" return [_DecodingRowProxy(row, charset) for row in rp.fetchall()] def _compat_fetchone(self, rp, charset=None): """Proxy a result row to smooth over MySQL-Python driver inconsistencies.""" row = rp.fetchone() if row: return _DecodingRowProxy(row, charset) else: return None def _compat_first(self, rp, charset=None): """Proxy a result row to smooth over MySQL-Python driver inconsistencies.""" row = rp.first() if row: return _DecodingRowProxy(row, charset) else: return None def _extract_error_code(self, exception): raise NotImplementedError() def _get_default_schema_name(self, connection): return connection.execute("SELECT DATABASE()").scalar() def has_table(self, connection, table_name, schema=None): # SHOW TABLE STATUS LIKE and SHOW TABLES LIKE do not function properly # on macosx (and maybe win?) with multibyte table names. # # TODO: if this is not a problem on win, make the strategy swappable # based on platform. DESCRIBE is slower. # [ticket:726] # full_name = self.identifier_preparer.format_table(table, # use_schema=True) full_name = ".".join( self.identifier_preparer._quote_free_identifiers( schema, table_name ) ) st = "DESCRIBE %s" % full_name rs = None try: try: rs = connection.execution_options( skip_user_error_events=True ).execute(st) have = rs.fetchone() is not None rs.close() return have except exc.DBAPIError as e: if self._extract_error_code(e.orig) == 1146: return False raise finally: if rs: rs.close() def initialize(self, connection): self._connection_charset = self._detect_charset(connection) self._detect_sql_mode(connection) self._detect_ansiquotes(connection) self._detect_casing(connection) if self._server_ansiquotes: # if ansiquotes == True, build a new IdentifierPreparer # with the new setting self.identifier_preparer = self.preparer( self, server_ansiquotes=self._server_ansiquotes ) default.DefaultDialect.initialize(self, connection) self._needs_correct_for_88718 = ( not self._is_mariadb and self.server_version_info >= (8,) ) self._warn_for_known_db_issues() def _warn_for_known_db_issues(self): if self._is_mariadb: mdb_version = self._mariadb_normalized_version_info if mdb_version > (10, 2) and mdb_version < (10, 2, 9): util.warn( "MariaDB %r before 10.2.9 has known issues regarding " "CHECK constraints, which impact handling of NULL values " "with SQLAlchemy's boolean datatype (MDEV-13596). An " "additional issue prevents proper migrations of columns " "with CHECK constraints (MDEV-11114). Please upgrade to " "MariaDB 10.2.9 or greater, or use the MariaDB 10.1 " "series, to avoid these issues." % (mdb_version,) ) @property def _is_mariadb(self): return ( self.server_version_info and "MariaDB" in self.server_version_info ) @property def _is_mysql(self): return not self._is_mariadb @property def _is_mariadb_102(self): return self._is_mariadb and self._mariadb_normalized_version_info > ( 10, 2, ) @property def _mariadb_normalized_version_info(self): # MariaDB's wire-protocol prepends the server_version with # the string "5.5"; now that we use @@version we no longer see this. if self._is_mariadb: idx = self.server_version_info.index("MariaDB") return self.server_version_info[idx - 3 : idx] else: return self.server_version_info @property def _supports_cast(self): return ( self.server_version_info is None or self.server_version_info >= (4, 0, 2) ) @reflection.cache def get_schema_names(self, connection, **kw): rp = connection.execute("SHOW schemas") return [r[0] for r in rp] @reflection.cache def get_table_names(self, connection, schema=None, **kw): """Return a Unicode SHOW TABLES from a given schema.""" if schema is not None: current_schema = schema else: current_schema = self.default_schema_name charset = self._connection_charset if self.server_version_info < (5, 0, 2): rp = connection.execute( "SHOW TABLES FROM %s" % self.identifier_preparer.quote_identifier(current_schema) ) return [ row[0] for row in self._compat_fetchall(rp, charset=charset) ] else: rp = connection.execute( "SHOW FULL TABLES FROM %s" % self.identifier_preparer.quote_identifier(current_schema) ) return [ row[0] for row in self._compat_fetchall(rp, charset=charset) if row[1] == "BASE TABLE" ] @reflection.cache def get_view_names(self, connection, schema=None, **kw): if self.server_version_info < (5, 0, 2): raise NotImplementedError if schema is None: schema = self.default_schema_name if self.server_version_info < (5, 0, 2): return self.get_table_names(connection, schema) charset = self._connection_charset rp = connection.execute( "SHOW FULL TABLES FROM %s" % self.identifier_preparer.quote_identifier(schema) ) return [ row[0] for row in self._compat_fetchall(rp, charset=charset) if row[1] in ("VIEW", "SYSTEM VIEW") ] @reflection.cache def get_table_options(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) return parsed_state.table_options @reflection.cache def get_columns(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) return parsed_state.columns @reflection.cache def get_pk_constraint(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) for key in parsed_state.keys: if key["type"] == "PRIMARY": # There can be only one. cols = [s[0] for s in key["columns"]] return {"constrained_columns": cols, "name": None} return {"constrained_columns": [], "name": None} @reflection.cache def get_foreign_keys(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) default_schema = None fkeys = [] for spec in parsed_state.fk_constraints: ref_name = spec["table"][-1] ref_schema = len(spec["table"]) > 1 and spec["table"][-2] or schema if not ref_schema: if default_schema is None: default_schema = connection.dialect.default_schema_name if schema == default_schema: ref_schema = schema loc_names = spec["local"] ref_names = spec["foreign"] con_kw = {} for opt in ("onupdate", "ondelete"): if spec.get(opt, False): con_kw[opt] = spec[opt] fkey_d = { "name": spec["name"], "constrained_columns": loc_names, "referred_schema": ref_schema, "referred_table": ref_name, "referred_columns": ref_names, "options": con_kw, } fkeys.append(fkey_d) if self._needs_correct_for_88718: self._correct_for_mysql_bug_88718(fkeys, connection) return fkeys def _correct_for_mysql_bug_88718(self, fkeys, connection): # Foreign key is always in lower case (MySQL 8.0) # https://bugs.mysql.com/bug.php?id=88718 # issue #4344 for SQLAlchemy # for lower_case_table_names=2, information_schema.columns # preserves the original table/schema casing, but SHOW CREATE # TABLE does not. this problem is not in lower_case_table_names=1, # but use case-insensitive matching for these two modes in any case. if self._casing in (1, 2): def lower(s): return s.lower() else: # if on case sensitive, there can be two tables referenced # with the same name different casing, so we need to use # case-sensitive matching. def lower(s): return s default_schema_name = connection.dialect.default_schema_name col_tuples = [ ( lower(rec["referred_schema"] or default_schema_name), lower(rec["referred_table"]), col_name, ) for rec in fkeys for col_name in rec["referred_columns"] ] if col_tuples: correct_for_wrong_fk_case = connection.execute( sql.text( """ select table_schema, table_name, column_name from information_schema.columns where (table_schema, table_name, lower(column_name)) in :table_data; """ ).bindparams(sql.bindparam("table_data", expanding=True)), table_data=col_tuples, ) # in casing=0, table name and schema name come back in their # exact case. # in casing=1, table name and schema name come back in lower # case. # in casing=2, table name and schema name come back from the # information_schema.columns view in the case # that was used in CREATE DATABASE and CREATE TABLE, but # SHOW CREATE TABLE converts them to *lower case*, therefore # not matching. So for this case, case-insensitive lookup # is necessary d = defaultdict(dict) for schema, tname, cname in correct_for_wrong_fk_case: d[(lower(schema), lower(tname))][cname.lower()] = cname for fkey in fkeys: fkey["referred_columns"] = [ d[ ( lower( fkey["referred_schema"] or default_schema_name ), lower(fkey["referred_table"]), ) ][col.lower()] for col in fkey["referred_columns"] ] @reflection.cache def get_check_constraints(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) return [ {"name": spec["name"], "sqltext": spec["sqltext"]} for spec in parsed_state.ck_constraints ] @reflection.cache def get_table_comment(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) return {"text": parsed_state.table_options.get("mysql_comment", None)} @reflection.cache def get_indexes(self, connection, table_name, schema=None, **kw): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) indexes = [] for spec in parsed_state.keys: dialect_options = {} unique = False flavor = spec["type"] if flavor == "PRIMARY": continue if flavor == "UNIQUE": unique = True elif flavor in ("FULLTEXT", "SPATIAL"): dialect_options["mysql_prefix"] = flavor elif flavor is None: pass else: self.logger.info( "Converting unknown KEY type %s to a plain KEY", flavor ) pass if spec["parser"]: dialect_options["mysql_with_parser"] = spec["parser"] index_d = {} if dialect_options: index_d["dialect_options"] = dialect_options index_d["name"] = spec["name"] index_d["column_names"] = [s[0] for s in spec["columns"]] index_d["unique"] = unique if flavor: index_d["type"] = flavor indexes.append(index_d) return indexes @reflection.cache def get_unique_constraints( self, connection, table_name, schema=None, **kw ): parsed_state = self._parsed_state_or_create( connection, table_name, schema, **kw ) return [ { "name": key["name"], "column_names": [col[0] for col in key["columns"]], "duplicates_index": key["name"], } for key in parsed_state.keys if key["type"] == "UNIQUE" ] @reflection.cache def get_view_definition(self, connection, view_name, schema=None, **kw): charset = self._connection_charset full_name = ".".join( self.identifier_preparer._quote_free_identifiers(schema, view_name) ) sql = self._show_create_table( connection, None, charset, full_name=full_name ) return sql def _parsed_state_or_create( self, connection, table_name, schema=None, **kw ): return self._setup_parser( connection, table_name, schema, info_cache=kw.get("info_cache", None), ) @util.memoized_property def _tabledef_parser(self): """return the MySQLTableDefinitionParser, generate if needed. The deferred creation ensures that the dialect has retrieved server version information first. """ if self.server_version_info < (4, 1) and self._server_ansiquotes: # ANSI_QUOTES doesn't affect SHOW CREATE TABLE on < 4.1 preparer = self.preparer(self, server_ansiquotes=False) else: preparer = self.identifier_preparer return _reflection.MySQLTableDefinitionParser(self, preparer) @reflection.cache def _setup_parser(self, connection, table_name, schema=None, **kw): charset = self._connection_charset parser = self._tabledef_parser full_name = ".".join( self.identifier_preparer._quote_free_identifiers( schema, table_name ) ) sql = self._show_create_table( connection, None, charset, full_name=full_name ) if re.match(r"^CREATE (?:ALGORITHM)?.* VIEW", sql): # Adapt views to something table-like. columns = self._describe_table( connection, None, charset, full_name=full_name ) sql = parser._describe_to_create(table_name, columns) return parser.parse(sql, charset) def _detect_charset(self, connection): raise NotImplementedError() def _detect_casing(self, connection): """Sniff out identifier case sensitivity. Cached per-connection. This value can not change without a server restart. """ # http://dev.mysql.com/doc/refman/5.0/en/name-case-sensitivity.html charset = self._connection_charset row = self._compat_first( connection.execute("SHOW VARIABLES LIKE 'lower_case_table_names'"), charset=charset, ) if not row: cs = 0 else: # 4.0.15 returns OFF or ON according to [ticket:489] # 3.23 doesn't, 4.0.27 doesn't.. if row[1] == "OFF": cs = 0 elif row[1] == "ON": cs = 1 else: cs = int(row[1]) self._casing = cs return cs def _detect_collations(self, connection): """Pull the active COLLATIONS list from the server. Cached per-connection. """ collations = {} if self.server_version_info < (4, 1, 0): pass else: charset = self._connection_charset rs = connection.execute("SHOW COLLATION") for row in self._compat_fetchall(rs, charset): collations[row[0]] = row[1] return collations def _detect_sql_mode(self, connection): row = self._compat_first( connection.execute("SHOW VARIABLES LIKE 'sql_mode'"), charset=self._connection_charset, ) if not row: util.warn( "Could not retrieve SQL_MODE; please ensure the " "MySQL user has permissions to SHOW VARIABLES" ) self._sql_mode = "" else: self._sql_mode = row[1] or "" def _detect_ansiquotes(self, connection): """Detect and adjust for the ANSI_QUOTES sql mode.""" mode = self._sql_mode if not mode: mode = "" elif mode.isdigit(): mode_no = int(mode) mode = (mode_no | 4 == mode_no) and "ANSI_QUOTES" or "" self._server_ansiquotes = "ANSI_QUOTES" in mode # as of MySQL 5.0.1 self._backslash_escapes = "NO_BACKSLASH_ESCAPES" not in mode def _show_create_table( self, connection, table, charset=None, full_name=None ): """Run SHOW CREATE TABLE for a ``Table``.""" if full_name is None: full_name = self.identifier_preparer.format_table(table) st = "SHOW CREATE TABLE %s" % full_name rp = None try: rp = connection.execution_options( skip_user_error_events=True ).execute(st) except exc.DBAPIError as e: if self._extract_error_code(e.orig) == 1146: raise exc.NoSuchTableError(full_name) else: raise row = self._compat_first(rp, charset=charset) if not row: raise exc.NoSuchTableError(full_name) return row[1].strip() return sql def _describe_table(self, connection, table, charset=None, full_name=None): """Run DESCRIBE for a ``Table`` and return processed rows.""" if full_name is None: full_name = self.identifier_preparer.format_table(table) st = "DESCRIBE %s" % full_name rp, rows = None, None try: try: rp = connection.execution_options( skip_user_error_events=True ).execute(st) except exc.DBAPIError as e: code = self._extract_error_code(e.orig) if code == 1146: raise exc.NoSuchTableError(full_name) elif code == 1356: raise exc.UnreflectableTableError( "Table or view named %s could not be " "reflected: %s" % (full_name, e) ) else: raise rows = self._compat_fetchall(rp, charset=charset) finally: if rp: rp.close() return rows class _DecodingRowProxy(object): """Return unicode-decoded values based on type inspection. Smooth over data type issues (esp. with alpha driver versions) and normalize strings as Unicode regardless of user-configured driver encoding settings. """ # Some MySQL-python versions can return some columns as # sets.Set(['value']) (seriously) but thankfully that doesn't # seem to come up in DDL queries. _encoding_compat = { "koi8r": "koi8_r", "koi8u": "koi8_u", "utf16": "utf-16-be", # MySQL's uft16 is always bigendian "utf8mb4": "utf8", # real utf8 "eucjpms": "ujis", } def __init__(self, rowproxy, charset): self.rowproxy = rowproxy self.charset = self._encoding_compat.get(charset, charset) def __getitem__(self, index): item = self.rowproxy[index] if isinstance(item, _array): item = item.tostring() if self.charset and isinstance(item, util.binary_type): return item.decode(self.charset) else: return item def __getattr__(self, attr): item = getattr(self.rowproxy, attr) if isinstance(item, _array): item = item.tostring() if self.charset and isinstance(item, util.binary_type): return item.decode(self.charset) else: return item