=========== Usage Guide =========== .. currentModule:: firebird.driver Driver structure ================ Source code is currently divided into next submodules: * :mod:`~firebird.driver.types` - Data types used by driver. * :mod:`~firebird.driver.interfaces` - Interface wrappers for Firebird new API * :mod:`~firebird.driver.core` - Main driver source code. * :mod:`~firebird.driver.fbapi` - Python `ctypes` interface to Firebird client library. * :mod:`~firebird.driver.config` - Driver configuration. * :mod:`~firebird.driver.hooks` - Drivers hooks. All important data, functions, classes and constants are available directly in `firebird.driver` name space. In normal circumstances is not necessary to import sub-modules directly. However, you may need them to access some not so frequently needed driver functionality like driver hooks, or to implement your own callback interfaces. .. important:: `firebird-driver` is designed to support all Firebird versions starting from version 3.0. Because each Firebird major version adds new functionality, and Firebird OO API could be extended even in maintenance releases, the driver isolates volatile functionality into special class hierarchies. For example information about database (provided via `~.iAttachment_v3.get_info()` API call) is isolated into separate `.DatabaseInfoProvider` class hierarchy. The `.Connection.info` attribute then provides access to instance of appropriate class - `.DatabaseInfoProvider` or its ancestor - for connected database. The `.DatabaseInfoProvider` class **always** provides functionality of most recent Firebird version supported by driver. This layout has several important consequences: 1. The `.DatabaseInfoProvider` class may change in major driver release if new Firebird functionality is introduced. This normally represent no problems for client application as backward compatibility is guaranteed. 2. You should check the class hierarchy for "evolving" classes when you start using the driver, and whenever you upgrade to new **major** driver version. If there are versioned ancestor classes (they always have Firebird version number in their name) for canonical (top level) ones, you should adjust your application to deal with situations when instance of ancestor class is provided by driver instead top-level one, to prevent run-time exceptions caused by access to functionality not provided by currently attached Firebird server. .. note:: The same apply for low-level API (`~firebird.driver.interfaces`) with difference that they may change in minor driver releases (because API could be extended in Firebird maintenance releases). .. seealso:: `.DatabaseInfoProvider`, `.TransactionInfoProvider`, `.ServerInfoProvider`, `.ServerDbServices`, `.ServerUserServices` and `.ServerTraceServices`. .. index:: Configuration Configuration ============= The driver uses configuration built on top of `configuration system ` provided by `firebird-base`_ package. In addition to global settings, the configuration also includes the definition of connection parameters to Firebird servers and databases. The default configuration connects to embedded server using direct/local connection method. To access remote servers and databases (or local ones through remote protocols), it's necessary to adjust default configuration, or `register` them in configuration manager. You can manipulate the configuration objects directly, or load configuration from files or strings (in `.ini-style` `configparser` format). The 'driver_config' object -------------------------- The global `.driver_config` object holds all configurable driver parameters, and access configuration parameters for registered Firebird servers and databases. In initial state, all parameters have default values and there are no registered servers and databases. You can set individual parameter values directly, or you can set multiple parameters (including registered servers and databases) at once by loading them from configuration string, dict or file(s). .. important:: If you want to use specific Firebird client library, you must set the value of `.DriverConfig.fb_client_library` configuration option **before** your application calls any from following functions: `.connect()`, `~firebird.driver.core.create_database()`, `.connect_server()`, `.load_api()` or `.get_api()`. .. seealso:: `.DriverConfig` for list of available methods and parameters. Server and database configuration --------------------------------- Firebird provides ever-increasing list of parameter options for database and server connections. To keep the Python API clean and manageable, the `firebird-driver` uses server and database configuration objects instead function parameters to specify values for almost all such options. Connection functions then provide a name parameter that can refer to particular server / database or configuration, and few keyword parameters to specify / override selected options. .. important:: The configuration objects does not allow specification of next options: - set database encryption callback (for technical reasons) - set db_key scope (for security reasons) - disable garbage collection (for security reasons) - disable database triggers (for security reasons) - allow overwrite of existing database with newly created database (for security reasons) These options could be specified only as keyword arguments in appropriate functions. .. seealso:: `.ServerConfig` and `.DatabaseConfig` for list of available methods and parameters. .. index:: Database pair: Connection; creation Databases ========= Access to the database is made available through `.Connection` objects. Firebird-driver provides two constructors for these: * `.connect` - Returns `.Connection` to database that already exists. * `~firebird.driver.core.create_database` - Returns `.Connection` to newly created database. .. index:: pair: Database; connect Using connect() --------------- This constructor has one positional and several keyword parameters. The value of `database` positional parameter must be one of: * name of registered database configuration * database name / alias .. important:: This value **cannot** be DSN / fully qualified Firebird connection string! Keyword parameters are intended to override selected configuration options, or to specify options that are not configurable. .. note:: If `database` value is not recognized as name of registered database configuration, the driver uses `~.DriverConfig.db_defaults` and `~.DriverConfig.server_defaults` configuration objects. A simple database connection is typically established with code such as this: .. sourcecode:: python from firebird.driver import connect # Attach to 'employee' database/alias using embedded server connection con = connect('employee', user='sysdba', password='masterkey') # Attach to 'employee' database/alias using local server connection from firebird.driver import driver_config driver_config.server_defaults.host.value = 'localhost' con = connect('employee', user='sysdba', password='masterkey') # Set 'user' and 'password' via configuration driver_config.server_defaults.user.value = 'SYSDBA' driver_config.server_defaults.password.value = 'masterkey' con = connect('employee') However, it's recommended to use specific configuration for servers and databases. It's possible to register servers and databases directly in code like this: .. sourcecode:: python from firebird.driver import connect, driver_config # Register Firebird server srv_cfg = """[local] host = localhost user = SYSDBA password = masterkey """ driver_config.register_server('local', srv_cfg) # Register database db_cfg = """[employee] server = local database = employee.fdb protocol = inet charset = utf8 """ driver_config.register_database('employee', db_cfg) # Attach to 'employee' database con = connect('employee') But more convenient approach is using single configuration file:: # file: myapp.cfg [firebird.driver] servers = local databases = employee [local] host = localhost user = SYSDBA password = masterkey [employee] server = local database = employee.fdb protocol = inet charset = utf8 .. sourcecode:: python from firebird.driver import connect, driver_config driver_config.read('myapp.cfg') # Attach to 'employee' database con = connect('employee') .. seealso:: `.connect()` for details. .. index:: pair: Database; create Using create_database() ----------------------- This constructor returns connection to newly created database. It works in the same way as `.connect()`, but utilizes additional database configuration options. It's possible to specify these options in code like this: .. sourcecode:: python from firebird.driver import connect, driver_config # Register Firebird server srv_cfg = """[local] host = localhost user = SYSDBA password = masterkey """ driver_config.register_server('local', srv_cfg) # Register database db_cfg = """[mydb] server = local database = mydb.fdb protocol = inet charset = utf8 # create options page_size = 16384 db_charset = utf8 sweep_interval = 80000 reserve_space = no """ driver_config.register_database('mydb', db_cfg) # create 'mydb' database con = create_database('mydb') But more convenient approach is using single configuration file:: # file: myapp.cfg [firebird.driver] servers = local databases = mydb [local] host = localhost user = SYSDBA password = masterkey [mydb] server = local database = mydb.fdb protocol = inet charset = utf8 # create options page_size = 16384 db_charset = utf8 sweep_interval = 80000 reserve_space = no .. sourcecode:: python from firebird.driver import create_database, driver_config driver_config.read('myapp.cfg') # create 'mydb' database con = create_database('mydb') .. seealso:: `~firebird.driver.core.create_database()` for details. .. index:: pair: Database; delete Deleting databases ------------------ The Firebird engine also supports dropping (deleting) databases dynamically, but dropping is a more complicated operation than creating, for several reasons: an existing database may be in use by users other than the one who requests the deletion, it may have supporting objects such as temporary sort files, and it may even have dependent shadow databases. Although the database engine recognizes a `DROP DATABASE` SQL statement, support for that statement is limited to the `isql` command-line administration utility. However, the engine supports the deletion of databases via an API call, which `firebird-driver` exposes as `~.Connection.drop_database` method in `.Connection` class. So, to drop a database you need to connect to it first. **Example:** .. sourcecode:: python from firebird.driver import connect, driver_config driver_config.read('myapp.cfg') # Attach to 'myapp' database con = connect('myapp') con.drop_database() .. seealso:: `.Connection.drop_database()` for details. .. index:: pair: Connection; usage pair: connection; Database Connection object ----------------- `.Connection` object represents a direct link to database, and works as gateway for next operations with it: * `Executing SQL Statements`_: methods `~.Connection.execute_immediate()` and `~.Connection.cursor()`. * `Dropping database `_: method `~.Connection.drop_database()`. * `Transanction management`_: methods `~.Connection.begin()`, `~.Connection.commit()`, `~.Connection.rollback()`, `~.Connection.savepoint()`, `~.Connection.transaction_manager()`, `~.Connection.is_active()`, and attributes `~.Connection.main_transaction`, `~.Connection.query_transaction`, `~.Connection.transactions` and `~.Connection.default_tpb`. * Work with `Database Events`_: method `~.Connection.event_collector`. * `Getting information about connection`_: methods `~.Connection.is_closed()` and `~.Connection.ping()` and attributes `~.Connection.dsn`, `~.Connection.charset` and `~.Connection.sql_dialect`. * `Getting information about database`_: attribute `~.Connection.info`. * `Closing the connection`_: method `~.Connection.close()` .. index:: pair: Connection; closing Closing the connection ---------------------- There are many local and server resources used by firebird-driver that must be properly managed, and disposed when they are no longer necessary. All objects that require proper finalization provide `close()` method that must be called when object is no longer needed. The `.Connection` (and `.Server`) objects are the most important ones, as other most frequently used objects like cursors, prepared statements and transactions are typically associated with connections. You may call the `close()` method directly, or use the :ref:`with ` statement and context manager support provided by all these objects. **Example:** .. sourcecode:: python from firebird.driver import connect, driver_config driver_config.read('myapp.cfg') with connect('employee') as con: cur = con.cursor() cur.execute('select 1 from rdb$database') print(cur.fetchone()[0]) .. note:: Objects that require proper finalization are: `.Connection`, `.TransactionManager` and `.DistributedTransactionManager`, `.Statement`, `.BlobReader`, `.Cursor` and `.Server`. Although only `.Connection` and `.Server` objects must be closed directly because all other objects are associated with them and thus closed when connection is closed, it's **recommended** to directly close any resource object obtained by your code when it's no longer needed (either directly by calling `close()` or using `with` statement). .. important:: All managed objects have `~object.__del__` method, which ensures that the object in the active state is properly closed before it is destroyed by the Python memory manager. However, **the close operation may fail** as the state of your application could be arbitrary and the sequence in which objects are disposed by memory manager is not deterministic. The `~object.__del__` methods should be thus considered as safe guard of last resort that your code should not rely upon. To indicate that your code is not managing resources properly, the `ResourceWarning` is raises when active object is disposed by memory manager. .. note:: Such warnings may not reach your attention if warnings are disabled or filtered on your system. You should always develop and test your applications with enabled delivery of resource warnings. .. seealso:: `.Connection.close()` for details. .. index:: pair: Connection; information about Getting information about connection ------------------------------------ Only (most useful) part of information associated with `.Connection` object is directly available: * It's possible to check whether Connection object is closed or not with `~.Connection.is_closed()` method. * It's possible to check whether connection to the Firebird server is not broken with `~.Connection.ping()` method. * The DSN (fully qualified Firebird database connection string) is surfaced as `~.Connection.dsn` read-only property. * The character set used by Connection is surfaced as `~.Connection.charset` read-only property. * The SQL dialect used by Connection is surfaced as `~.Connection.sql_dialect` read-only property. .. tip:: Additional connection-specific information is currently held as `bytes` in protected `Connection._dpb` attribute that could be processed using `~firebird.driver.core.DPB` object. .. index:: pair: Database; information about Getting information about database ---------------------------------- .. important:: Because the scope and type of database information depends on the version of the Firebird server and database ODS, this information is made available through a separate class `.DatabaseInfoProvider`. The `.Connection.info` property provides access to instance of `.DatabaseInfoProvider` or it's **ancestor** class according to ODS of attached database and Firebird version. Although you may query the information directly from server using `~firebird.driver.core.DatabaseInfoProvider3.get_info()` method (that wraps the Firebird `.iAttachment.getInfo()` API call), the `.DatabaseInfoProvider` object provides more convenient methods and properties for obtaining specific information directly. .. note:: Some information provided by `.DatabaseInfoProvider` properties (like `~.DatabaseInfoProvider3.cache_hit_ratio`) could not be obtained via `get_info()` method. **Example:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: print(f"Database character set: {con.info.charset}") print(f"Page size (in bytes): {con.info.page_size}") print(f"Attachment ID: {con.info.id}") print(f"SQL dialect used by connected database: {con.info.sql_dialect}") print(f"Database name (filename or alias): {con.info.name}") print(f"Database site name: {con.info.site}") print(f"Implementation (old format): {con.info.implementation!s}") print(f"Database Provider: {con.info.provider!s}") print(f"Database Class: {con.info.db_class!s}") print(f"Date when database was created: {con.info.creation_date}") print(f"Size of page cache used by connection: {con.info.page_cache_size}") print(f"Number of pages allocated for database: {con.info.pages_allocated}") print(f"Number of database pages in active use: {con.info.pages_used}") print(f"Number of free allocated pages in database: {con.info.pages_free}") print(f"Sweep interval: {con.info.sweep_interval}") print(f"Data page space usage (USE_FULL or RESERVE): {con.info.space_reservation!s}") print(f"Database write mode (SYNC or ASYNC): {con.info.write_mode!s}") print(f"Database access mode (READ_ONLY or READ_WRITE): {con.info.access_mode!s}") print(f"Current I/O statistics - Reads from disk to page cache: {con.info.reads}") print(f"Current I/O statistics - Fetches from page cache: {con.info.fetches}") print(f"Cache hit ratio = 1 - (reads / fetches): {con.info.cache_hit_ratio}") print(f"Current I/O statistics - Writes from page cache to disk: {con.info.writes}") print(f"Current I/O statistics - Writes to page in cache: {con.info.marks}") print(f"Total amount of memory curretly used by database engine: {con.info.current_memory}") print(f"Max. total amount of memory so far used by database engine: {con.info.max_memory}") print(f"ID of Oldest Interesting Transaction: {con.info.oit}") print(f"ID of Oldest Active Transaction: {con.info.oat}") print(f"ID of Oldest Snapshot Transaction: {con.info.ost}") print(f"ID for next transaction: {con.info.next_transaction}") **Sample output**:: Database character set: NONE Page size (in bytes): 8192 Attachment ID: 378 SQL dialect used by connected database: 3 Database name (filename or alias): /opt/firebird/examples/empbuild/employee.fdb Database site name: NewAmarisk Implementation (old format): Implementation.RDB_VMS Database Provider: DbProvider.FIREBIRD Database Class: DbClass.SERVER_ACCESS Date when database was created: 2020-05-13 10:13:57.005010 Size of page cache used by connection: 2048 Number of pages allocated for database: 346 Number of database pages in active use: 311 Number of free allocated pages in database: 35 Sweep interval: 20000 Data page space usage (USE_FULL or RESERVE): DbSpaceReservation.RESERVE Database write mode (SYNC or ASYNC): DbWriteMode.SYNC Database access mode (READ_ONLY or READ_WRITE): DbAccessMode.READ_WRITE Current I/O statistics - Reads from disk to page cache: 87 Current I/O statistics - Fetches from page cache: 1525 Cache hit ratio = 1 - (reads / fetches): 0.9429508196721311 Current I/O statistics - Writes from page cache to disk: 2 Current I/O statistics - Writes to page in cache: 5 Total amount of memory curretly used by database engine: 21925248 Max. total amount of memory so far used by database engine: 22033760 ID of Oldest Interesting Transaction: 307 ID of Oldest Active Transaction: 308 ID of Oldest Snapshot Transaction: 308 ID for next transaction: 308 .. seealso:: `.DatabaseInfoProvider` for details. Getting information about Firebird version ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Because functionality and some features depends on actual Firebird version, it could be important for driver users to check it. This (otherwise) simple task could be confusing for new Firebird users, because Firebird uses two different version lineages. This abomination was introduced to Firebird thanks to its InterBase legacy (Firebird 1.0 is a fork of InterBase 6.0), as applications designed to work with InterBase can often work with Firebird without problems (and vice versa). `.DatabaseInfoProvider` provides these version strings as two properties: * `~.DatabaseInfoProvider.server_version` - Legacy InterBase-friendly version string. * `~.DatabaseInfoProvider.firebird_version` - Firebird’s own version string. However, this version string contains more information than version number. For example for Linux Firebird 4.0.0 it’s ‘LI-T4.0.0.1963 Firebird 4.0 Beta 2’. So `.DatabaseInfoProvider` provides two more properties for your convenience: * `~.DatabaseInfoProvider.version` - Only Firebird version number. It’s a string with format: major.minor.subrelease.build * `~.DatabaseInfoProvider.engine_version` - Engine (major.minor) version as (float) number. **Example:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: print(f"server_version: '{con.info.server_version}'") print(f"firebird_version: '{con.info.firebird_version}'") print(f"version: '{con.info.version}'") print(f"engine_version: {con.info.engine_version}") **Sample output**:: server_version: 'LI-T6.3.0.1963 Firebird 4.0 Beta 2' firebird_version: 'LI-T4.0.0.1963 Firebird 4.0 Beta 2' version: '4.0.0.1963' engine_version: 4.0 Database On-Disk Structure ^^^^^^^^^^^^^^^^^^^^^^^^^^ Particular Firebird features may also depend on specific support in database (for example number and structure of monitoring tables). These required structures are present automatically when database is created by particular engine verison that needs them, but Firebird engine may work with databases created by older versions and thus with older structure, so it could be necessary to consult also On-Disk Structure (ODS for short) version. `.DatabaseInfoProvider` provides this number as `~.DatabaseInfoProvider.ods` (float) property. **Example:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: print(f"ods: {con.info.ods}") print(f"ods_version: {con.info.ods_version}") print(f"ods_minor_version: {con.info.ods_minor_version}") **Sample output**:: ods: 13.0 ods_version: 13 ods_minor_version: 0 .. index:: SQL Statement Executing SQL Statements ======================== Firebird-driver implements two ways for execution of SQL commands against connected database: * `~.Connection.execute_immediate` - for execution of SQL commands that don't return any result. * `.Cursor` objects that offer rich interface for execution of SQL commands and fetching their results. .. index:: pair: Cursor; usage Cursor object ------------- Because `.Cursor` objects always operate in context of single `.Connection` (and `.TransactionManager`), `.Cursor` instances are not created directly, but by constructor method. Python DB API 2.0 assumes that if database engine supports transactions, it supports only one transaction per connection, hence it defines constructor method `~.Connection.cursor` (and other transaction-related methods) as part of `.Connection` interface. However, Firebird supports multiple independent transactions per connection. To conform to Python DB API, firebird-driver uses concept of internal `~.Connection.main_transaction` and secondary `~.Connection.transactions`. Cursor constructor is primarily defined by `.TransactionManager`, and Cursor constructor on `.Connection` is therefore a shortcut for `main_transaction.cursor()`. `.Cursor` objects are used for next operations: * Execution of SQL Statemets: methods `~.Cursor.execute()`, `~.Cursor.executemany()`, `~.Cursor.open()` and `~.Cursor.callproc()`. * Creating `.Statement` objects for efficient repeated execution of SQL statements, and to obtain additional information about SQL statements (like execution `~.Statement.plan`): method `~.Cursor.prepare()`. * `Fetching results `_: methods `~.Cursor.fetchone()`, `~.Cursor.fetchmany()`, `~.Cursor.fetchall()`, `~.Cursor.fetch_next()`, `~.Cursor.fetch_prior()`, `~.Cursor.fetch_first()`, `~.Cursor.fetch_last()`, `~.Cursor.fetch_absolute()` and `~.Cursor.fetch_relative()`. .. index:: pair: SQL Statement; execution SQL Execution Basics -------------------- There are five methods how to execute SQL commands: 1. `.Connection.execute_immediate()` or `.TransactionManager.execute_immediate()` for SQL commands that don't return any result, and are not executed frequently. This method also **doesn't** support either `parameterized statements `_ or `prepared statements `_. .. tip:: This method is efficient for `administrative` and `DDL`_ SQL commands, like `DROP`, `CREATE` or `ALTER` commands, `SET STATISTICS` etc. 2. `.Cursor.execute()` for SQL commands that return result sets, i.e. sequence of `rows` of the same structure, and sequence has unknown number of `rows` (including zero). Each row of the sequence can be read only once, and is returned in the order it is read from the server. .. tip:: This method is preferred for all `SELECT` and other `DML`_ statements, or any statement that is executed frequently, either `as is` or in `parameterized` form. 3. `.Cursor.executemany()` for execution of single parameterized SQL command with various set of parameters. .. important:: Because `executemany()` is basically a simple loop that calls `execute()` with different parameters, it's possible to execute any statement acceptable by `execute()`. However, it's possible to access the result set **only** from last executed command, so this method should not be used for SQL commands that return results. 4. `.Cursor.open()` for SQL command that return result sets, i.e. sequence of `rows` of the same structure, and sequence has unknown number of `rows` (including zero). Instead of just fetching rows sequentially in a forward direction like `execute()`, this method allows flexible navigation through an open cursor set both backwards and forwards. Rows next to, prior to and relative to the current cursor row can be targeted. .. seealso:: `Scrollable cursors `_ for details. 5. `.Cursor.callproc()` for execution of `Stored procedures` that always return exactly one set of values. .. note:: This method of SP invocation is equivalent to `"EXECUTE PROCEDURE ..."` SQL statement. .. index:: pair: Cursor; fetching data Fetching data from server ------------------------- Result of SQL statement execution consists from sequence of zero to unknown number of `rows`, where each `row` is a set of exactly the same number of values. `.Cursor` object offer number of different methods for fetching these `rows`, that should satisfy all your specific needs: * `~.Cursor.fetchone()` - Returns the next row of a query result set, or `None` when no more data is available. .. tip:: Cursor supports the :ref:`iterator protocol `, yielding tuples of values like `~.Cursor.fetchone()`. * `~.Cursor.fetchmany()` - Returns the next set of rows of a query result, returning a sequence of sequences (e.g. a list of tuples). An empty sequence is returned when no more rows are available. The number of rows to fetch per call is specified by the parameter. If it is not given, the cursor’s `~.Cursor.arraysize` determines the number of rows to be fetched. The method does try to fetch as many rows as indicated by the size parameter. If this is not possible due to the specified number of rows not being available, fewer rows may be returned. .. note:: The default value of `~.Cursor.arraysize` is `1`, so without paremeter it's equivalent to `~.Cursor.fetchone()`, but returns list of `rows`, instead actual `row` directly. * `~.Cursor.fetchall()` - Returns all (remaining) rows of a query result as list of tuples, where each tuple is one row of returned values. .. tip:: This method can potentially return huge amount of data, that may exhaust available memory. If you need just `iteration` over potentially big result set, use loops with `~.Cursor.fetchone()` or Cursor's built-in support for :ref:`iterator protocol ` instead this method. * Call to `~.Cursor.execute()` returns `self` (Cursor instance) that itself supports the :ref:`iterator protocol `, yielding tuples of values like `~.Cursor.fetchone()`. .. important:: Firebird-driver makes absolutely no guarantees about the `row` return value of the `fetch*()` methods except that it is a sequence indexed by field position. Therefore, client programmers should not rely on the return value being an instance of a particular class or type. **Examples:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() SELECT = "select country, currency from country" # 1. Using built-in support for iteration protocol to iterate over the rows available # from the cursor, unpacking the resulting sequences to yield their elements (country, currency): cur.execute(SELECT) for (country, currency) in cur: print(f"{country} uses {currency} as currency.") # or alternatively you can take an advantage of cur.execute() returning self. for (country, currency) in cur.execute(SELECT): print(f"{country} uses {currency} as currency.") # 2. Equivalently using fetchall(): # This is potentially dangerous if result set is huge, as the whole result set is # first materialized as list and then used for iteration. cur.execute(SELECT) for row in cur.fetchall(): print(f"{row[0]} uses {row[1]} as currency.") .. important:: Method `.Cursor.executemany()` is not intended for operations that return results, so it does **NOT** returns `self` like `.Cursor.execute()`, and you can't use calls to this method as iterator. .. _scrollable-cursors: .. index:: pair: Cursor; scrollable Scrollable cursors ------------------ SQL statements executed by `.Cursor.open()` have scrollable result set that could be navigated using next methods: * `~.Cursor.fetch_next()` - Moves the cursor's current position to the next row and returns it. Returns `None` if the cursor is empty or already positioned at the last row. * `~.Cursor.fetch_prior()` - Moves the cursor's current position to the prior row and returns it. Returns `None` if the cursor is empty or already positioned at the first row. * `~.Cursor.fetch_first()` - Moves the cursor's current position to the first row and returns it. Returns `None` if the cursor is empty. * `~.Cursor.fetch_last()` - Moves the cursor's current position to the last row and returns it. Returns `None` if the cursor is empty. * `~.Cursor.fetch_absolute()` - Moves the cursor's current position to the specified and returns the located row. Returns `None` if is beyond the cursor's boundaries. * `~.Cursor.fetch_relative()` - Moves the cursor's current position backward or forward by the specified and returns the located row. Returns `None` if the calculated position is beyond the cursor's boundaries. .. important:: Please note that scrollable cursors: a) are not supported by all versions of Firebird server. b) are internally materialized as a temporary record set, thus consuming memory/disk resources, so this feature should be used only when really necessary. **Example:** .. sourcecode:: python from firebird.driver import connect def print_row(row): if row: print(f"{row[0]}, {row[1]}, {row[2]}") else: print('NO DATA') with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() cur.open('select row_number() over (order by country), country, currency from country order by country') # You can iterate over scrollable cursors for row in cur: print_row(row) print('-' * 10) # or fetch particular rows directly print_row(cur.fetch_first()) print_row(cur.fetch_last()) print_row(cur.fetch_absolute(10)) print_row(cur.fetch_next()) print_row(cur.fetch_prior()) print_row(cur.fetch_relative(-5)) print_row(cur.fetch_relative(10)) print('-' * 10) cur.fetch_last() print_row(cur.fetch_next()) **Sample output**:: 1, Australia, ADollar 2, Austria, Euro 3, Belgium, Euro 4, Canada, CdnDlr 5, England, Pound 6, Fiji, FDollar 7, France, Euro 8, Germany, Euro 9, Hong Kong, HKDollar 10, Italy, Euro 11, Japan, Yen 12, Netherlands, Euro 13, Romania, RLeu 14, Russia, Ruble 15, Switzerland, SFranc 16, USA, Dollar ---------- 1, Australia, ADollar 16, USA, Dollar 10, Italy, Euro 11, Japan, Yen 10, Italy, Euro 5, England, Pound 15, Switzerland, SFranc ---------- NO DATA .. index:: pair: SQL Statement; parameterized .. _parameterized-statements: Parameterized statements ------------------------ When SQL command you want to execute contains data `values`, you can either: * Embed them `directly` or via `string formatting` into command string, e.g.: .. sourcecode:: python cur.execute("insert into the_table (a,b,c) values ('aardvark', 1, 0.1)") # or cur.execute("select * from the_table where col == 'aardvark'") # or cur.execute("insert into the_table (a,b,c) values ('%s', %i, %f)" % ('aardvark',1,0.1)) # or cur.execute(f"select * from the_table where col == '{value}'") * Use parameter marker (`?`) in command string in the slots where values are expected, then supply those values as Python list or tuple: .. sourcecode:: python cur.execute("insert into the_table (a,b,c) values (?,?,?)", ('aardvark', 1, 0.1)) # or cur.execute("select * from the_table where col == ?",('aardvark',)) While both methods have the same results, the second one (called `parametrized`) has several important advantages: * You don't need to handle conversions from Python data types to strings. * Firebird-driver will handle all data type conversions (if necessary) from Python data types to Firebird ones, including `None/NULL` conversion and conversion from `str` to `bytes` in encoding expected by server. * You may pass BLOB values as open `file-like` objects, and firebird-driver will handle the transfer of BLOB value. Parametrized statemets also have some limitations. Currently: * `DATE`, `TIME` and `DATETIME` values must be relevant `datetime` objects. * `NUMERIC` and `DECIMAL` values must be `decimal` objects. .. index:: pair: SQL Statement; prepared .. _prepared-statements: Prepared Statements ------------------- Execution of any SQL statement has three phases: * *Preparation*: command is analyzed, validated, execution plan is determined by optimizer and all necessary data structures (for example for input and output parameters) are initialized. * *Execution*: input parameters (if any) are passed to server and previously prepared statement is actually executed by database engine. * *Fetching*: result of execution and data (if any) are transferred from server to client, and allocated resources are then released (by closing the statement). The preparation phase consumes some amount of server resources (memory and CPU). Although preparation and release of resources typically takes only small amount of CPU time, it builds up as number of executed statements grows. Firebird (like most database engines) allows to spare this time for subsequent execution if particular statement should be executed repeatedly - by reusing once prepared statement for repeated execution. This may save significant amount of server processing time, and result in better overall performance. Firebird-driver builds on this by encapsulating the Firebird SQL statement data and related code into separate `.Statement` class, and implementing the `.Cursor` class around it. The Cursor uses either an internally managed `.Statement` instance to execute SQL commands provided as `string`, or uses `.Statement` instance provided by your code as SQL command. To get the (prepared) `.Statement` instance for later (repeated) execution, use `~.Cursor.prepare()` method. You can then pass this instance to `~.Cursor.execute()`, `~.Cursor.executemany()` or `~.Cursor.open()` instead `command string`. `.Statement` instances are bound to `.Connection` instance, and can't be used with any other `.Connection`. Beside repeated execution they are also useful to get information about statement (like its execution `~.Statement.plan` or `~.Statement.type`) before its execution. .. note:: The internally managed `.Statement` instance is released when `.Cursor` is closed, or before any new statement is executed. It means that if your code executes the same SQL command (passed as string) repeatedly without closing the cursor between calls, the same `.Statement` instance is (re)used. .. important:: Implementation of Cursor in firebird-driver somewhat violates the Python DB API 2.0, which requires that cursor will be unusable after call to `~.Cursor.close()`; and an Error (or subclass) exception should be raised if any operation is attempted with the cursor. In firebird-driver, the `.Cursor.close()` call only releases resources associated with executed statement like the result set, and you can't fetch data or query information about the SQL statement. However, you can use the cursor instance to execute new SQL commands. .. warning:: If you'll take advantage of this anomaly, your code would be less portable to other Python DB API 2.0 compliant drivers. **Example:** .. sourcecode:: python insertStatement = cur.prepare("insert into the_table (a,b,c) values (?,?,?)") inputRows = [ ('aardvark', 1, 0.1), ('zymurgy', 2147483647, 99999.999), ('foobar', 2000, 9.9) ] for row in inputRows: cur.execute(insertStatement,row) # # or you can use executemany # cur.executemany(insertStatement, inputRows) .. seealso:: `.Statement` for details. .. index:: pair: Cursor; named Named Cursors ------------- To allow the Python programmer to perform scrolling **UPDATE** or **DELETE** via the **“SELECT ... FOR UPDATE”** syntax, the firebird-driver provides the read-only property `.Cursor.name` and method `.Cursor.set_cursor_name()`. **Example Program:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='sysdba', password='masterkey') as con: curScroll = con.cursor() curUpdate = con.cursor() curScroll.execute("select city from customer for update") curScroll.set_cursor_name('city_scroller') update = "update customer set city=? where current of " + curScroll.name for (city,) in curScroll: city = ... # make some changes to city curUpdate.execute( update, (city,) ) con.commit() .. index:: pair: Stored procedure; execution Working with stored procedures ------------------------------ Firebird stored procedures can have input parameters and/or output parameters. Some databases support input/output parameters, where the same parameter is used for both input and output; Firebird does not support this. It is important to distinguish between procedures that **return a result set** and procedures that **populate and return their output parameters** exactly once. Conceptually, the latter “return their output parameters” like a Python function, whereas the former “yield result rows” like a Python generator. Firebird’s **server-side** procedural SQL syntax makes no such distinction, but client-side SQL code (and C API code) must. A result set is retrieved from a stored procedure by **SELECT'ing from the procedure, whereas output parameters are retrieved with an 'EXECUTE PROCEDURE' statement**. To **retrieve a result set** from a stored procedure with firebird-driver, use code such as this: .. sourcecode:: python cur.execute("select output1, output2 from the_proc(?, ?)", (input1, input2)) # Ordinary fetch code here, such as: for row in cur: ... # process row con.commit() # If the procedure had any side effects, commit them. To **execute** a stored procedure and **access its output parameters**, you can choose from two options: 1. Method `.Cursor.callproc()` that **conforms to Python DB API 2.0**. This method does not returns the output parameters directly, and you must call `.Cursor.fetchone()` **exactly once** to retrieve them. 2. Method `.Cursor.call_procedure()` that returns output parameters directly (or `None` if procedure does not have output parameters). **Examples:** .. sourcecode:: python # Python DB API 2.0 compliant method: cur.callproc("the_proc", (input1, input2)) # If there are output parameters, retrieve them as though they were the # first row of a result set... outputParams = cur.fetchone() # alternative method: outputParams = cur.call_procedure("the_proc", (input1, input2)) con.commit() # If the procedure had any side effects, commit them. .. index:: pair: Data; conversion Data handling and conversions ============================= .. index:: pair: parameter; conversion Implicit Conversion of Input Parameters from Strings ---------------------------------------------------- The Firebird database engine treats most SQL data types in a weakly typed fashion: the engine may attempt to convert the raw value to a different type, as appropriate for the current context. For instance, the SQL expressions `123` (integer) and `‘123’` (string) are treated equivalently when the value is to be inserted into an `integer` field; the same applies when `‘123’` and `123` are to be inserted into a `varchar` field. This weak typing model is quite unlike Python’s dynamic yet strong typing. Although weak typing is regarded with suspicion by most experienced Python programmers, the database engine is in certain situations so aggressive about its typing model that firebird-driver must compromise in order to remain an elegant means of programming the database engine. An example is the handling of “magic values” for date and time fields. The database engine interprets certain string values such as `‘yesterday’` and `‘now’` as having special meaning in a date/time context. If firebird-driver did not accept strings as the values of parameters destined for storage in date/time fields, the resulting code would be awkward. Consider the difference between the two Python snippets below, which insert a row containing an integer and a timestamp into a table defined with the following DDL statement: .. sourcecode:: sql create table test_table (i integer, t timestamp) .. sourcecode:: python i = 1 t = 'now' sqlWithMagicValues = f"insert into test_table (i, t) values (?, '{t}')" cur.execute(sqlWithMagicValues, (i,)) .. sourcecode:: python i = 1 t = 'now' cur.execute("insert into test_table (i, t) values (?, ?)", (i, t)) If firebird-driver did not support weak parameter typing, string parameters that the database engine is to interpret as “magic values” would have to be rolled into the SQL statement in a separate operation from the binding of the rest of the parameters, as in the first Python snippet above. Implicit conversion of parameter values from strings allows the consistency evident in the second snippet, which is both more readable and more general. .. note:: It should be noted that firebird-driver does not perform the conversion from string itself. Instead, it passes that responsibility to the database engine by changing the parameter metadata structure dynamically at the last moment, then restoring the original state of the metadata structure after the database engine has performed the conversion. A secondary benefit is that when one uses firebird-driver to import large amounts of data from flat files into the database, the incoming values need not necessarily be converted to their proper Python types before being passed to the database engine. Eliminating this intermediate step may accelerate the import process considerably, although other factors such as the chosen connection protocol and the deactivation of indexes during the import are more consequential. For bulk import tasks, the database engine’s external tables also deserve consideration. External tables can be used to suck semi-structured data from flat files directly into the relational database without the intervention of an ad hoc conversion program. .. index:: pair: unicode; conversion Automatic conversion from/to Unicode ------------------------------------ In Firebird, every `CHAR`, `VARCHAR` or textual `BLOB` field can (or, better: must) have a `character set` assigned. While it's possible to define single character set for whole database, it's also possible to define different character set for each textual field. This information is used to correctly store the bytes that make up the character string, and together with collation information (that defines the sort ordering and uppercase conversions for a string) is vital for correct data manipulation, including automatic transliteration between character sets when necessary. .. important:: Because data also flow between server and client application, it's vital that client will send data encoded only in character set(s) that server expects. While it's possible to leave this responsibility completely on client application, it's better when client and server settle on single character set they would use for communication, especially when database operates with multiple character sets, or uses character set that is not `native` for client application. Character set for communication is specified using `~.DatabaseConfig.charset` configuration option, or parameter in `.connect()` or `~firebird.driver.core.create_database()` call. When `connection charset` is defined, all textual data returned from server are encoded in this charset, and client application must ensure that all textual data sent to server are encoded only in this charset as well. Firebird-driver helps with client side of this character set bargain by automatically converting Python `str` values into `bytes` encoded in connection character set, and vice versa. However, developers are still responsible that `bytes` strings passed to server are in correct encoding (because firebird-driver makes no assumption about encoding of `bytes` strings, so it can't recode them to connection charset). .. important:: In case that `connection charset` is NOT defined at all, or `NONE` charset is specified, firebird-driver uses `locale.getpreferredencoding` to determine encoding for conversions from/to `unicode`. .. important:: There is one exception to automatic conversion: when character set OCTETS is defined for data column. Values assigned to OCTETS columns are always passed `as is`, because they're basically binary streams. This has specific implications. Python 3 native strings are `unicode`, and you would probably want to use `bytes` type instead. However, firebird-driver in this case doesn't check the value type at all, so you'll not be warned if you'll make a mistake and pass `str` to OCTETS column (unless you'll pass more bytes than column may hold, or you intend to store unicode that way). Conversion is fully automatic in both directions for all textual data, i.e. including for string values returned by Firebird Service and `info` calls etc. When `connection charset` is not specified, firebird-driver uses `locale.getpreferredencoding` to determine encoding for conversions from/to `unicode`. .. tip:: Except for legacy databases that doesn't have `character set` defined, **always** define character set for your databases and specify `connection charset`. It will make your life much easier. .. index:: BLOB pair: Data; BLOB pair: BLOB; materialized pair: BLOB; stream .. _working_with_blobs: Working with BLOBs ------------------ Firebird-driver uses two types of BLOB values: * **Materialized** BLOB values are Python `str` or `bytes` values. This is the **default** type. * **Streamed** BLOB values are `file-like` objects. Materialized BLOBs are easy to work with, but are not suitable for: * **deferred loading** of BLOBs. They're called `materialized` because they're always fetched from server as part of row fetch. Fetching BLOB value means separate API calls (and network roundtrips), which may slow down you application considerably. * **large values**, as they are always stored in memory in full size. These drawbacks are addressed by `stream` BLOBs. Using BLOBs in `stream` mode is easy: * For **input** values, simply use :ref:`parameterized statement ` and pass any `file-like` object in place of BLOB parameter. The `file-like` object must implement only the `~file.read` method, as no other method is used. * For **output** values, add column name(s) that should be returned as `file-like` objects to `.Cursor.stream_blobs` list attribute. Firebird-driver then returns `.BlobReader` instance instead string in place of returned BLOB value for these column(s). .. important:: The firebird-driver provides `.Cursor.stream_blob_threshold` attribute that controls the maximum size of materialized blobs (as memory exhaustion safeguard). When particular blob value exceeds this threshold, an instance of `.BlobReader` is returned instead string/bytes value. Zero threshold value effectively forces all blobs to be returned as stream blobs. Negative value means no size limit for materialized blobs (use at your own risk). Please note that positive threshold value means that your application has to be prepared to handle BLOBs in both incarnations. The default threshold is 64K and could be changed using `.DriverConfig.stream_blob_threshold` configuration option. Blob size threshold has effect only on materialized blob columns, i.e. columns not explicitly requested to be returned as streamed ones using `.Cursor.stream_blobs` attribute, that are **always** returned as stream blobs. The `.BlobReader` instance is bound to `.Cursor` instance, and it's automatically closed with cursor. However, it's good practice to use `with` statement or call `.BlobReader.close()` once you're finished reading to release system resources associated with BLOB value. .. important:: When working with BLOB values, always have memory efficiency in mind, especially when you're processing huge quantity of rows with BLOB values at once. Materialized BLOB values may exhaust your memory quickly, but using stream BLOBs may have inpact on performance too, as new `.BlobReader` instance is created for each value fetched. **Example program:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() print("Materialized retrieval (as str):") cur.execute('select proj_id, proj_desc from project') proj_id, proj_desc = cur.fetchone() print(f"{proj_id=}, {proj_desc=}") print("\nStreaming retrieval (via BlobReader):") cur.stream_blobs.append('PROJ_DESC') cur.execute('select proj_id, proj_desc from project') proj_id, proj_desc = cur.fetchone() with proj_desc: print(f"{proj_id=}, {proj_desc=}") print(proj_desc.read()) Output:: Materialized retrieval (as str): proj_id='VBASE', proj_desc='Design a video data base management system for\ncontrolling on-demand video distribution.\n' Streaming retrieval (via BlobReader): proj_id='VBASE', proj_desc=BlobReader[size=89] Design a video data base management system for controlling on-demand video distribution. .. index:: ARRAY pair: Data; ARRAY Firebird ARRAY type ------------------- Firebird-driver supports Firebird ARRAY data type. ARRAY values are represented as Python lists. On input, the Python sequence (list or tuple) must be nested appropriately if the array field is multi-dimensional, and the incoming sequence must not fall short of its maximum possible length (it will not be “padded” implicitly–see below). On output, the lists will be nested if the database array has multiple dimensions. .. note:: Database arrays have no place in a purely relational data model, which requires that data values be atomized (that is, every value stored in the database must be reduced to elementary, non-decomposable parts). The Firebird implementation of database arrays, like that of most relational database engines that support this data type, is fraught with limitations. Database arrays are of fixed size, with a predeclared number of dimensions (max. 16) and number of elements per dimension. Individual array elements cannot be set to NULL / None, so the mapping between Python lists (which have dynamic length and are therefore not normally “padded” with dummy values) and non-trivial database arrays is clumsy. Stored procedures cannot have array parameters. Finally, many interface libraries, GUIs, and even the isql command line utility do not support database arrays. In general, it is preferable to avoid using database arrays unless you have a compelling reason. **Example:** .. sourcecode:: python >>> from firebird.driver import connect >>> con = connect('employee',user='sysdba', password='masterkey') >>> cur = con.cursor() >>> cur.execute("select LANGUAGE_REQ from job where job_code='Eng' and job_grade=3 and job_country='Japan'") >>> cur.fetchone() (['Japanese\n', 'Mandarin\n', 'English\n', '\n', '\n'],) **Example program:** .. sourcecode:: python from firebird.driver import connect arrayIn = [ [1, 2, 3, 4], [5, 6, 7, 8], [9,10,11,12] ] with connect('/temp/test.db', user='sysdba', password='pass') as con: con.execute_immediate("recreate table array_table (a int[3,4])") con.commit() cur = con.cursor() print(f"{arrayIn=}") cur.execute("insert into array_table values (?)", (arrayIn,)) con.commit() cur.execute("select a from array_table") arrayOut = cur.fetchone()[0] print(f"{arrayOut=}) Output:: arrayIn=[[1, 2, 3, 4], [5, 6, 7, 8], [9, 10, 11, 12]] arrayOut=[[1, 2, 3, 4], [5, 6, 7, 8], [9, 10, 11, 12]] .. index:: pair: Transaction; management Transanction management ======================= For the sake of simplicity, firebird-driver lets the Python programmer ignore transaction management to the greatest extent allowed by the Python Database API Specification 2.0. The specification says, “if the database supports an auto-commit feature, this must be initially off”. At a minimum, therefore, it is necessary to call the commit method of the connection in order to persist any changes made to the database. Remember that because of ACID, every data manipulation operation in the Firebird database engine takes place in the context of a transaction, including operations that are conceptually “read-only”, such as a typical SELECT. The client programmer of firebird-driver establishes a transaction implicitly by using any SQL execution method, such as `.Connection.execute_immediate()`, `.Cursor.execute()`, or `.Cursor.callproc()`. Although firebird-driver allows the programmer to pay little attention to transactions, it also exposes the full complement of the database engine’s advanced transaction control features: `transaction parameters`_, `retaining transactions`_, `savepoints`_, and `distributed transactions`_. Basics ------ When it comes to transactions, Python Database API 2.0 specify that `.Connection` object has to respond to the following methods: `.Connection.commit()` Commits any pending transaction to the database. Note that if the database supports an auto-commit feature, this must be initially off. An interface method may be provided to turn it back on. Database modules that do not support transactions should implement this method with void functionality. `.Connection.rollback()` (optional) In case a database does provide transactions this method causes the the database to roll back to the start of any pending transaction. **Closing a connection without committing the changes first will cause an implicit rollback to be performed.** In addition to the implicit transaction initiation required by Python Database API, firebird-driver allows the programmer to start transactions explicitly via the `.Connection.begin()` method. Also `.Connection.savepoint()` method was added to provide support for `Firebird SAVEPOINTs`_. But Python Database API 2.0 was created with assumption that connection can support only one transactions per single connection. However, Firebird can support multiple independent transactions that can run simultaneously within single connection / attachment to the database. This feature is very important, as applications may require multiple transaction opened simultaneously to perform various tasks, which would require to open multiple connections and thus consume more resources than necessary. Firebird-driver surfaces this Firebird feature by separating transaction management out from `.Connection` into separate `.TransactionManager` objects. To comply with Python DB API 2.0 requirements, `.Connection` object uses one `.TransactionManager` instance as :attr:`main transaction <.Connection.main_transaction>`, and delegates `~.Connection.begin()`, `~.Connection.savepoint()`, `~.Connection.commit()`, `~.Connection.rollback()` and `~.Connection.execute_immediate()` calls to it. .. seealso:: More about using multiple transactions with the same connection in separate :ref:`section `. **Example:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() # Most minimalistic transaction management -> implicit start, only commit() and rollback() # ======================================================================================== # # Transaction is started implicitly cur.execute('insert into country values ('Oz','Crowns') con.commit() # commits active transaction # Again, transaction is started implicitly cur.execute('insert into country values ('Barsoom','XXX') con.rollback() # rolls back active transaction cur.execute('insert into country values ('Pellucidar','Shells') # Commit was not performed before connection context was closed # This will roll back the transaction because Python DB API 2.0 # requires that closing connection with pending transaction must # cause an implicit rollback .. seealso:: `.TransactionManager` for details. .. index:: pair: Transaction; auto-commit Auto-commit ----------- Firebird-driver doesn't support `auto-commit` feature directly, but developers may achieve the similar result using `explicit` transaction start, taking advantage of `.TransactionManager.default_action` and its default value (`~.DefaultAction.COMMIT`). **Example:** .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() con.begin() cur.execute('insert into country values ('Oz','Crowns') con.begin() # commits active transaction and starts new one cur.execute('insert into country values ('Barsoom','XXX') con.begin() # commits active transaction and starts new one cur.execute('insert into country values ('Pellucidar','Shells') # However, commit is required before connection is closed, # because Python DB API 2.0 requires that closing connection # with pending transaction must cause an implicit rollback con.commit() .. index:: pair: Transaction; parameters Transaction parameters ---------------------- The database engine offers the client programmer an optional facility called `transaction parameter buffers` (TPBs) for tweaking the operating characteristics of the transactions he initiates. These include characteristics such as whether the transaction has read and write access to tables, or read-only access, and whether or not other simultaneously active transactions can share table access with the transaction. Transaction manager has `~.TransactionManager.default_tpb` attribute that can be changed to set the default TPB to be used for all subsequent transactions started by this manager. Also Connection have a `~.Connection.default_tpb` attribute, but it's used to set the default TPB for all transactions managers subsequently created for the connection (see `.Connection.transaction_manager()`). Alternatively, if the programmer only wants to set the TPB for a single transaction, he can start a transaction explicitly via the `.Connection.begin()` or `.TransactionManager.begin()` method and pass a TPB for that single transaction. The TPB is a `bytes` value constructed from various tags and binary values, as defined by API. While you can construct the TPB manually, the firebird-driver provides several convenient ways for TPB construction: 1. The `.tpb()` function for simple TPBs. 2. The `~firebird.driver.core.TPB` class for complex TPBs (including table reservation etc.). **Examples:** .. sourcecode:: python from firebird.driver import tpb, TPB, Isolation, TraAccessMode, TableShareMode, TableAccessMode # Use tpb() if isolation, timeout and access_mode parameters are enough for you simple_tpb = tpb(Isolation.READ_COMMITTED_READ_CONSISTENCY,100,TraAccessMode.WRITE) # Use TPB if you want additional parameters than isolation, timeout and access_mode my_tpb = TPB(isolation=Isolation.SNAPSHOT, access_mode=TraAccessMode.WRITE, lock_timeout=100, no_auto_undo=True, auto_commit=True, ignore_limbo=True) my_tpb.reserve_table('MY_TABLE', TableShareMode.PROTECTED, TableAccessMode.LOCK_WRITE) complex_tpb = my_tpb.get_buffer() .. index:: pair: Transaction; information about Getting information about transaction ------------------------------------- .. important:: Because the scope and type of transaction information depends on the version of the Firebird server, this information is made available through a separate class `.TransactionInfoProvider`. The `.TransactionManager.info` property provides access to instance of `.TransactionInfoProvider` or it's **ancestor** class according to used Firebird version. Although you may query the information directly from server using `~.TransactionInfoProvider3.get_info()` method (that wraps the Firebird `ITransaction.getInfo()` API call), the `.TransactionInfoProvider` object provides more convenient methods and properties for obtaining specific information directly. **Example:** .. sourcecode:: python from firebird.driver import connect, driver_config driver_config.server_defaults.host.value = 'localhost' with connect('employee', user='SYSDBA', password='masterkey') as con: con.begin() info = con.main_transaction.info print(f"Transaction ID: {info.id}") print(f"Database: {info.database}") print(f"Isolation level: {info.isolation!s}") print(f"Lock timeout: {info.lock_timeout}") print(f"Is Read-Only: {info.is_read_only()}") print(f"ID of Oldest Interesting Transaction: {info.oit}") print(f"ID of Oldest Active Transaction: {info.oat}") print(f"ID of Oldest Snapshot Transaction: {info.ost}") Output:: Transaction ID: 352 Database: localhost:employee Isolation level: Isolation.SNAPSHOT Lock timeout: -1 Is Read-Only: False ID of Oldest Interesting Transaction: 350 ID of Oldest Active Transaction: 352 ID of Oldest Snapshot Transaction: 352 .. index:: pair: Transaction; retaining Retaining transactions ---------------------- The `~.TransactionManager.commit()` and `~.TransactionManager.rollback()` methods accept an optional boolean keyword parameter `retaining` (**default False**) to indicate whether to recycle the transactional context of the transaction being resolved by the method call. If retaining is `True`, the infrastructural support for the transaction active at the time of the method call will be “retained” (efficiently and transparently recycled) after the database server has committed or rolled back the conceptual transaction. .. important:: In code that commits or rolls back frequently in short amount of time (like in loop), “retaining” the transaction may yield better performance. However, retaining transactions must be used cautiously because they can interfere with the server’s ability to garbage collect old record versions. For details about this issue, read the “Garbage” section of `this document `_ by Ann Harrison. It's definitely no recommended to use retaining for all transactions, or retain the transaction context indefinitely (you should eventually commit/rollback the transaction in normal way). For more information about retaining transactions, see `Firebird documentation`. .. index:: SAVEPOINT pair: Transaction; SAVEPOINT Savepoints ---------- Savepoints are named, intermediate control points within an open transaction that can later be rolled back to, without affecting the preceding work. Multiple savepoints can exist within a single unresolved transaction, providing “multi-level undo” functionality. Although Firebird savepoints are fully supported from SQL alone via the `SAVEPOINT ‘name’` and `ROLLBACK TO ‘name’` statements, firebird-driver also exposes savepoints at the Python API level for the sake of convenience. Call to method `.TransactionManager.savepoint()` establishes a savepoint with the specified `name`. To roll back to a specific savepoint, call the `~.TransactionManager.rollback()` method and provide the name of the savepoint for the `savepoint` keyword parameter. If the savepoint parameter of `~.TransactionManager.rollback()` is not specified, the active transaction is cancelled in its entirety, as required by the Python Database API Specification. The following program demonstrates savepoint manipulation via the firebird-driver API, rather than raw SQL. .. sourcecode:: python from firebird.driver import connect with connect('employee', user='SYSDBA', password='masterkey') as con: cur = con.cursor() cur.execute("recreate table test_savepoints (a integer)") con.commit() print('Before the first savepoint, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) cur.execute("insert into test_savepoints values (?)", [1]) con.savepoint('A') print('After savepoint A, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) cur.execute("insert into test_savepoints values (?)", [2]) con.savepoint('B') print('After savepoint B, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) cur.execute("insert into test_savepoints values (?)", [3]) con.savepoint('C') print('After savepoint C, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) con.rollback(savepoint='B') print('After rolling back to savepoint B, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) con.rollback() print('After rolling back entirely, the contents of the table are:') cur.execute("select * from test_savepoints") print(' ', cur.fetchall()) The output of the example program is shown below:: Before the first savepoint, the contents of the table are: [] After savepoint A, the contents of the table are: [(1,)] After savepoint B, the contents of the table are: [(1,), (2,)] After savepoint C, the contents of the table are: [(1,), (2,), (3,)] After rolling back to savepoint B, the contents of the table are: [(1,), (2,)] After rolling back entirely, the contents of the table are: [] .. index:: pair: Transaction; multiple .. _multiple_transactions: Using multiple transactions with the same connection ---------------------------------------------------- To use additional transactions that could run simultaneously with :attr:`main transaction <.Connection.main_transaction>` managed by `.Connection`, create new `.TransactionManager` object calling `.Connection.transaction_manager()` method. If you don't specify the optional `default_tpb` parameter, this new `.TransactionManager` inherits the `~.Connection.default_tpb` from `.Connection`. Physical transaction is not started when `.TransactionManager` instance is created, but implicitly when first SQL statement for cursor created from this manager is executed, or explicitly via `.TransactionManager.begin()` call. To execute statements in context of this additional transaction you have to use `cursors` obtained directly from this `.TransactionManager` instance calling its `~.TransactionManager.cursor()` method, or call `.TransactionManager.execute_immediate()` method. **Example:** .. sourcecode:: python from firebird.driver import connect, tpb, Isolation, TraAccessMode with connect('employee', user='SYSDBA', password='masterkey') as con: # Cursor for main_transaction context cur = con.cursor() # Create new READ ONLY READ COMMITTED transaction ro_transaction = con.transaction_manager(tpb(Isolation.READ_COMMITTED_RECORD_VERSION, access=TraAccessMode.READ)) # and cursor ro_cur = ro_transaction.cursor() cur.execute('insert into country values ('Oz','Crowns') con.commit() # commits main transaction # Read data created by main transaction from second one ro_cur.execute("select * from COUNTRY where COUNTRY = `Oz`") print(ro_cur.fetchall()) # Insert more data, but don't commit cur.execute('insert into country values ('Barsoom','XXX') # Read data created by main transaction from second one ro_cur.execute("select * from COUNTRY where COUNTRY = `Barsoom`") print(ro_cur.fetchall()) .. index:: pair: Transaction; distributed .. _distributed_transactions: Distributed Transactions ------------------------ Distributed transactions are transactions that span multiple databases. Firebird-driver provides this Firebird feature through `.DistributedTransactionManager` class. Instances of this class must be created manually, and managed transactions are fully independent from all other transactions, main or secondary, of member connections. Similarly to `.TransactionManager`, distributed transactions are managed through `~.DistributedTransactionManager.begin()`, `~.DistributedTransactionManager.savepoint()`, `~.DistributedTransactionManager.commit()` and `~.DistributedTransactionManager.rollback()` methods. Additionally, `.DistributedTransactionManager` exposes method `~.DistributedTransactionManager.prepare()` that explicitly initiates the first phase of `Two-Phase Commit Protocol`. Transaction parameters are defined similarly to `.TransactionManager` using `~.DistributedTransactionManager.default_tpb` or as optional parameter to `~.DistributedTransactionManager.begin()` call. SQL statements that should belong to context of distributed transaction are executed via `.Cursor` instances aquired through `.DistributedTransactionManager.cursor()` method, or calling `.DistributedTransactionManager.execute_immediate()` method. .. note:: Because `.Cursor` instances can belong to only one `.Connection`, the `~.DistributedTransactionManager.cursor()` method has mandatory parameter `connection`, to specify to which member connection cursor should belong. The `~.DistributedTransactionManager.execute_immediate()` method operates on **all** databases in *group*. **Example program:** .. sourcecode:: python from firebird.driver import create_database, DistributedTransactionManager # First database con1 = create_database('db1.fdb', user='SYSDBA', password='masterkey') con1.execute_immediate("recreate table T (PK integer, C1 integer)") con1.commit() # Second database con2 = create_database('db2.fdb', user='SYSDBA', password='masterkey') con2.execute_immediate("recreate table T (PK integer, C1 integer)") con2.commit() # Create distributed transaction manager dt = DistributedTransactionManager((con1,con2)) # Prepare cursors for each connection dc1 = dt.cursor(con1) dc2 = dt.cursor(con2) # Connection cursors to check content of databases q = 'select * from T order by pk' cc1 = con1.cursor() p1 = cc1.prep(q) cc2 = con2.cursor() p2 = cc2.prep(q) print("Distributed transaction: COMMIT") # =============================== dc1.execute('insert into t (pk) values (1)') dc2.execute('insert into t (pk) values (1)') dt.commit() # check it con1.commit() cc1.execute(p1) print('db1:', cc1.fetchall()) con2.commit() cc2.execute(p2) print('db2:', cc2.fetchall()) print("Distributed transaction: PREPARE + COMMIT") # ========================================= dc1.execute('insert into t (pk) values (2)') dc2.execute('insert into t (pk) values (2)') dt.prepare() dt.commit() # check it con1.commit() cc1.execute(p1) print('db1:', cc1.fetchall()) con2.commit() cc2.execute(p2) print('db2:', cc2.fetchall()) print("Distributed transaction: SAVEPOINT + ROLLBACK to it") # =================================================== dc1.execute('insert into t (pk) values (3)') dt.savepoint('CG_SAVEPOINT') dc2.execute('insert into t (pk) values (3)') dt.rollback(savepoint='CG_SAVEPOINT') # check it - via group cursors, as transaction is still active dc1.execute(q) print('db1:', dc1.fetchall()) dc2.execute(q) print('db2:', dc2.fetchall()) print("Distributed transaction: ROLLBACK") # ================================= dt.rollback() # check it con1.commit() cc1.execute(p1) print('db1:', cc1.fetchall()) con2.commit() cc2.execute(p2) print('db2:', cc2.fetchall()) print("Distributed transaction: EXECUTE_IMMEDIATE") # ========================================== dt.execute_immediate('insert into t (pk) values (3)') dt.commit() # check it con1.commit() cc1.execute(p1) print('db1:', cc1.fetchall()) con2.commit() cc2.execute(p2) print('db2:', cc2.fetchall()) # Finalize con1.drop_database() con1.close() con2.drop_database() con2.close() Output:: Distributed transaction: COMMIT db1: [(1, None)] db2: [(1, None)] Distributed transaction: PREPARE + COMMIT db1: [(1, None), (2, None)] db2: [(1, None), (2, None)] Distributed transaction: SAVEPOINT + ROLLBACK to it db1: [(1, None), (2, None), (3, None)] db2: [(1, None), (2, None)] Distributed transaction: ROLLBACK db1: [(1, None), (2, None)] db2: [(1, None), (2, None)] Distributed transaction: EXECUTE_IMMEDIATE db1: [(1, None), (2, None), (3, None)] db2: [(1, None), (2, None), (3, None)] .. index:: pair: Transaction; context manager .. _transaction-context-manager: Transaction Context Manager --------------------------- Firebird-driver provides context manager `~firebird.driver.core.transaction` that allows automatic transaction management using :ref:`WITH statement `. It can work with any object that supports `begin()`, `commit()` and `rollback()` methods, i.e. `.Connection`, `.TransactionManager` or `.DistributedTransactionManager`. It starts transaction when WITH block is entered and commits it if no exception occurs within it, or calls `rollback()` otherwise. Exceptions raised in WITH block are never suppressed. Examples: .. sourcecode:: python from firebird.driver import connect, transaction, DistributedTransactionManager with connect('employee', user='SYSDBA', password='masterkey') as con: # Uses default main transaction with transaction(con): cur = con.cursor() cur.execute("insert into T (PK,C1) values (1,'TXT')") # Uses separate transaction with transaction(con.transaction_manager()) as tr: cur = tr.cursor() cur.execute("insert into T (PK,C1) values (2,'AAA')") # Uses distributed transaction with connect('employee2', user='SYSDBA', password='masterkey') as con2, DistributedTransactionManager(con, con2) as dtm: with transaction(dtm): cur1 = cg.cursor(con) cur2 = cg.cursor(con2) cur1.execute("insert into T (PK,C1) values (3,'Local')") cur2.execute("insert into T (PK,C1) values (3,'Remote')") .. index:: pair: Database; events Database Events =============== What they are ------------- The Firebird engine features a distributed, inter-process communication mechanism based on messages called `database events`. A database event is a message passed from a trigger or stored procedure to an application to announce the occurrence of a specified condition or action, usually a database change such as an insertion, modification, or deletion of a record. The Firebird event mechanism enables applications to respond to actions and database changes made by other, concurrently running applications without the need for those applications to communicate directly with one another, and without incurring the expense of CPU time required for periodic polling to determine if an event has occurred. Why use them ------------ Anything that can be accomplished with database events can also be implemented using other techniques, so why bother with events? Since you’ve chosen to write database-centric programs in Python rather than assembly language, you probably already know the answer to this question, but let’s illustrate. A typical application for database events is the handling of administrative messages. Suppose you have an administrative message database with a `message's` table, into which various applications insert timestamped status reports. It may be desirable to react to these messages in diverse ways, depending on the status they indicate: to ignore them, to initiate the update of dependent databases upon their arrival, to forward them by e-mail to a remote administrator, or even to set off an alarm so that on-site administrators will know a problem has occurred. It is undesirable to tightly couple the program whose status is being reported (the `message producer`) to the program that handles the status reports (the `message handler`). There are obvious losses of flexibility in doing so. For example, the message producer may run on a separate machine from the administrative message database and may lack access rights to the downstream reporting facilities (e.g., network access to the SMTP server, in the case of forwarded e-mail notifications). Additionally, the actions required to handle status reports may themselves be time-consuming and error-prone, as in accessing a remote network to transmit e-mail. In the absence of database event support, the message handler would probably be implemented via `polling`. Polling is simply the repetition of a check for a condition at a specified interval. In this case, the message handler would check in an infinite loop to see whether the most recent record in the `messages` table was more recent than the last message it had handled. If so, it would handle the fresh message(s); if not, it would go to sleep for a specified interval, then loop. The `polling-based` implementation of the message handler is fundamentally flawed. Polling is a form of busy-wait_; the check for new messages is performed at the specified interval, regardless of the actual activity level of the message producers. If the polling interval is lengthy, messages might not be handled within a reasonable time period after their arrival; if the polling interval is brief, the message handler program (and there may be many such programs) will waste a large amount of CPU time on unnecessary checks. The database server is necessarily aware of the exact moment when a new message arrives. Why not let the message handler program request that the database server send it a notification when a new message arrives? The message handler can then efficiently sleep until the moment its services are needed. Under this `event-based` scheme, the message handler becomes aware of new messages at the instant they arrive, yet it does not waste CPU time checking in vain for new messages when there are none available. How events are exposed ---------------------- #. Server Process ("An event just occurred!") To notify any interested listeners that a specific event has occurred, issue the `POST_EVENT` statement from Stored Procedure or Trigger. The `POST_EVENT` statement has one parameter: the name of the event to post. In the preceding example of the administrative message database, `POST_EVENT` might be used from an `after insert` trigger on the `messages` table, like this: .. sourcecode:: sql create trigger trig_messages_handle_insert for messages after insert as begin POST_EVENT 'new_message'; end .. note:: The physical notification of the client process does not occur until the transaction in which the `POST_EVENT` took place is actually committed. Therefore, multiple events may *conceptually* occur before the client process is *physically* informed of even one occurrence. Furthermore, the database engine makes no guarantee that clients will be informed of events in the same groupings in which they conceptually occurred. If, within a single transaction, an event named `event_a` is posted once and an event named `event_b` is posted once, the client may receive those posts in separate "batches", despite the fact that they occurred in the same conceptual unit (a single transaction). This also applies to multiple occurrences of *the same* event within a single conceptual unit: the physical notifications may arrive at the client separately. #. Client Process ("Send me a message when an event occurs.") .. note:: If you don't care about the gory details of event notification, skip to the section that describes FDB's Python-level event handling API. The Firebird C client library offers two forms of event notification. The first form is *synchronous* notification, by way of the function :c:func:`isc_wait_for_event()`. This form is admirably simple for a C programmer to use, but is inappropriate as a basis for FDB's event support, chiefly because it's not sophisticated enough to serve as the basis for a comfortable Python-level API. The other form of event notification offered by the database client library is *asynchronous*, by way of the functions :c:func:`isc_que_events()` (note that the name of that function is misspelled), :c:func:`isc_cancel_events()`, and others. The details are as nasty as they are numerous, but the essence of using asynchronous notification from C is as follows: #. Call :c:func:`isc_event_block()` to create a formatted binary buffer that will tell the server which events the client wants to listen for. #. Call :c:func:`isc_que_events()` (passing the buffer created in the previous step) to inform the server that the client is ready to receive event notifications, and provide a callback that will be asynchronously invoked when one or more of the registered events occurs. #. [The thread that called :c:func:`isc_que_events()` to initiate event listening must now do something else.] #. When the callback is invoked (the database client library starts a thread dedicated to this purpose), it can use the :c:func:`isc_event_counts()` function to determine how many times each of the registered events has occurred since the last call to :c:func:`isc_event_counts()` (if any). #. [The callback thread should now "do its thing", which may include communicating with the thread that called :c:func:`isc_que_events()`.] #. When the callback thread is finished handling an event notification, it must call :c:func:`isc_que_events()` again in order to receive future notifications. Future notifications will invoke the callback again, effectively "looping" the callback thread back to Step 4. API for Python developers ------------------------- The Firebird-driver database event API is comprised of the following: the method `.Connection.event_collector()` and the class `.EventCollector`. Use the `.Connection.event_collector()` method (takes a sequence of string event names as parameter) to create `.EventCollector` instance, that collects database event notifications sent from the server for given database. .. important:: To start listening for events it's necessary to call `.EventCollector.begin()` method or use EventCollector's context manager interface. Immediately when `~.EventCollector.begin()` method is called, EventCollector starts to accumulate notifications of any event that occur within the collector’s internal queue until the collector is closed either explicitly (via the `~.EventCollector.close()` method) or implicitly (via garbage collection). Notifications about events are aquired through call to `~.EventCollector.wait()` method, that blocks the calling thread until at least one of the events occurs, or the specified `timeout` (if any) expires, and returns `None` if the wait timed out, or a dictionary that maps `event_name -> event_occurrence_count`. .. important:: `.EventCollector` can act as context manager that ensures execution of `~.EventCollector.begin()` and `~.EventCollector.close()` methods. It's strongly advised to use the `.EventCollector` with the `with` statement. **Example:** .. sourcecode:: python with connection.event_collector(['event_a', 'event_b']) as collector: events = collector.wait() process_events(events) If you want to drop notifications accumulated so far by conduit, call `.EventCollector.flush()` method. **Example program:** .. sourcecode:: python from firebird.driver import create_database, transaction import threading import time # Prepare database con = create_database('event-test', user='SYSDBA', password='masterkey') with transaction(con): con.execute_immediate("CREATE TABLE T (PK Integer, C1 Integer)") con.execute_immediate("""CREATE TRIGGER EVENTS_AU FOR T ACTIVE BEFORE UPDATE POSITION 0 AS BEGIN if (old.C1 <> new.C1) then post_event 'c1_updated' ; END""") con.execute_immediate("""CREATE TRIGGER EVENTS_AI FOR T ACTIVE AFTER INSERT POSITION 0 AS BEGIN if (new.c1 = 1) then post_event 'insert_1' ; else if (new.c1 = 2) then post_event 'insert_2' ; else if (new.c1 = 3) then post_event 'insert_3' ; else post_event 'insert_other' ; END""") cur = con.cursor() # Utility function def send_events(command_list): with transaction(con): for cmd in command_list: cur.execute(cmd) print("One event") # ========= timed_event = threading.Timer(3.0,send_events,args=[["insert into T (PK,C1) values (1,1)",]]) with con.event_collector(['insert_1']) as events: timed_event.start() e = events.wait() print(e) print("Multiple events") # =============== cmds = ["insert into T (PK,C1) values (1,1)", "insert into T (PK,C1) values (1,2)", "insert into T (PK,C1) values (1,3)", "insert into T (PK,C1) values (1,1)", "insert into T (PK,C1) values (1,2)",] timed_event = threading.Timer(3.0,send_events,args=[cmds]) with con.event_collector(['insert_1','insert_3']) as events: timed_event.start() e = events.wait() print(e) print("20 events") # ========= cmds = ["insert into T (PK,C1) values (1,1)", "insert into T (PK,C1) values (1,2)", "insert into T (PK,C1) values (1,3)", "insert into T (PK,C1) values (1,1)", "insert into T (PK,C1) values (1,2)",] timed_event = threading.Timer(1.0,send_events,args=[cmds]) with con.event_collector(['insert_1','A','B','C','D', 'E','F','G','H','I','J','K','L','M', 'N','O','P','Q','R','insert_3']) as events: timed_event.start() time.sleep(3) e = events.wait() print(e) print("Flush events") # ============ timed_event = threading.Timer(3.0,send_events,args=[["insert into T (PK,C1) values (1,1)",]]) with con.event_collector(['insert_1']) as events: send_events(["insert into T (PK,C1) values (1,1)", "insert into T (PK,C1) values (1,1)"]) time.sleep(2) events.flush() timed_event.start() e = events.wait() print(e) # Finalize con.drop_database() con.close() Output:: One event {'insert_1': 1} Multiple events {'insert_3': 1, 'insert_1': 2} 20 events {'A': 0, 'C': 0, 'B': 0, 'E': 0, 'D': 0, 'G': 0, 'insert_1': 2, 'I': 0, 'H': 0, 'K': 0, 'J': 0, 'M': 0, 'L': 0, 'O': 0, 'N': 0, 'Q': 0, 'P': 0, 'R': 0, 'insert_3': 1, 'F': 0} Flush events {'insert_1': 1} .. index:: Services pair: Services; working with .. index:: Server pair: Server; services .. _working_with_services: Working with Services ===================== Database server maintenance tasks such as user management, load monitoring, and database backup have traditionally been automated by scripting the command-line tools :program:`gbak`, :program:`gfix`, :program:`gsec`, and :program:`gstat`. The API presented to the client programmer by these utilities is inelegant because they are, after all, command-line tools rather than native components of the client language. To address this problem, Firebird has a facility called the `Services API`, which exposes a uniform interface to the administrative functionality of the traditional command-line tools. The native Services API, though consistent, is much lower-level than a Pythonic API. If the native version were exposed directly, accomplishing a given task would probably require more Python code than scripting the traditional command-line tools. For this reason, the firebird-driver presents its own abstraction over the native API. .. index:: pair: Services; connection pair: Server; connection Services API Connections ------------------------ All Services API operations are performed in the context of a `connection` to a specific database server, represented by the `.Server` class. Similarly to database connections, firebird-driver provides `.connect_server()` constructor function to create such connections. This constructor has one positional and several keyword parameters. The value of `server` positional parameter must be one of: * name of registered server configuration * server host name or address Keyword parameters are intended to override selected configuration options, or to specify options that are not configurable. A simple server connection is typically established with code such as this: .. sourcecode:: python from firebird.driver import connect_server # Attach to 'embedded' server srv = connect_server('', user='SYSDBA', password='masterkey') # Attach to 'local' server srv = connect_server('localhost', user='SYSDBA', password='masterkey') # Set 'user' and 'password' via configuration from firebird.driver import driver_config driver_config.server_defaults.user.value = 'SYSDBA' driver_config.server_defaults.password.value = 'masterkey' srv = connect_server('localhost') However, it's recommended to use specific configuration for servers. It's possible to register servers directly in code like this: .. sourcecode:: python from firebird.driver import connect_server, driver_config # Register Firebird server srv_cfg = """[main_server] host = 192.168.0.15 user = SYSDBA password = Xyzzy """ driver_config.register_server('main_server', srv_cfg) # Attach to 'main' server con = connect('main_server') But more convenient approach is using single configuration file:: # file: myapp.cfg [firebird.driver] servers = main_server databases = employee [main_server] host = 192.168.0.15 user = SYSDBA password = Xyzzy .. sourcecode:: python from firebird.driver import connect_server, driver_config driver_config.read('myapp.cfg') # Attach to 'main' server con = connect('main_server') .. note:: Like database connections, it's important to properly `~Server.close()` them when you don't need them anymore. `.Server` object provides main infrastructure for communication with Firebird server services, and manages number of objects that provide actual server services: * The `.Server.info` property object provides `Server Configuration and State information`_. * The `.Server.database` property object provides `Database options`_ and `Database maintenance`_. * The `.Server.user` property object provides `User maintenance`_. * The `.Server.trace` property object provides management of `Trace sessions`_. .. seealso:: `.connect_server()` and `.Server` for details. .. index:: pair: Services; output Text output from Services ------------------------- Some services like `.ServerDbServices.backup()` may return significant amount of text. Rather than return the whole text as single string value by methods that provide access to these services, firebird-driver isolated the transfer process to separate methods: * `~.Server.readline()` - Similar to `file.readline`, returns next line of output from Service. * `~.Server.readline_timed()` - Like `~.Server.readline()` but with timeout. * `~.Server.readlines()` - Like `file.readlines`, returns list of output lines. * Iteration over `.Server` object, because `.Server` has built-in support for :ref:`iterator protocol `. * Using `callback` method provided by developer. Each `.Server` method that returns its result asynchronously accepts an optional parameter `callback`, which must be a function that accepts one string parameter. This method is then called with each output line coming from service. * `~.Server.wait()` - Waits for Sevice to finish, ignoring rest of the output it may produce. .. important:: The Firebird server sends text output from services as packets, that could have two forms. The method for packet construction used for text transfer is controlled by `.Server.mode` attribute with next possible values: 1. `.SrvInfoCode.LINE` : A single line of text. 2. `.SrvInfoCode.TO_EOF` : A block of text up to specified (buffer) size. Both methods have specific pros and cons: 1. `~.SrvInfoCode.LINE` means more roundtrips and thus slower transfer of service output, but each line is sent to client immediately when it's available. 2. `~.SrvInfoCode.TO_EOF` means fewer roundtrips so large output is transferred quickly, but service output is not sent until the transfer buffer is not full, or service stops. **The default mode is** `~.SrvInfoCode.TO_EOF` **with 64K buffer.** .. warning:: Until output is not fully fetched from service, any attempt to start another asynchronous service will fail with exception! This constraint is set by Firebird Service API. You may check the status of asynchronous Services using `.Server.is_running()` method. In cases when you're not interested in output produced by Service, call `~.Server.wait()` to wait for service to complete. .. important:: Normally, requesting output with `~.Server.readline()` blocks until any output is available from server. Bacuse this method is used by iteration over `.Server` and `~.Server.readlines()` method, they will block as well. Most services produce output continuously and without (much) delay, so this is usually not a problem. However, some services (eg trace) can produce output at significantly slower intervals (if at all), which complicates the creation of responsive applications. In this case, it is necessary to use the `~.Server.readline_timed()` method, which allows you to limit the waiting time for the output. **Examples:** .. sourcecode:: python from firebird.driver import connect_server with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: print("Fetch materialized") print("==================") print("Start backup") srv.database.backup(database='employee', backup='employee.fbk') print("srv.running is", srv.isrunning()) report = srv.readlines() print(f"{len(report)} lines returned") print("First 5 lines from output:") for i in xrange(5): print(i,report[i]) print("srv.running is", srv.isrunning()) print() print("Iterate over result") print("===================") srv.database.backup(database='employee', backup='employee.fbk') output = [] for line in srv: output.append(line) print(f"{len(output)} lines returned") print("Last 5 lines from output:") for line in output[-5:]: print(line) print() print("Callback") print("========") output = [] # Callback function def fetchline(line): output.append(line) srv.database.backup(database='employee', backup='employee.fbk', callback=fetchline) print(f"{len(output)} lines returned") print("Last 5 lines from output:") for line in output[-5:]: print(line) Output:: Fetch materialized ================== Start backup svc.running is True 558 lines returned First 5 lines from output: 0 gbak:readied database employee for backup 1 gbak:creating file employee.fbk 2 gbak:starting transaction 3 gbak:database employee has a page size of 4096 bytes. 4 gbak:writing domains svc.running is False Iterate over result =================== 558 lines returned Last 5 lines from output: gbak:writing referential constraints gbak:writing check constraints gbak:writing SQL roles gbak:writing names mapping gbak:closing file, committing, and finishing. 74752 bytes written Callback ======== 558 lines returned Last 5 lines from output: gbak:writing referential constraints gbak:writing check constraints gbak:writing SQL roles gbak:writing names mapping gbak:closing file, committing, and finishing. 74752 bytes written .. index:: pair: Services; server information Server Configuration and State information ------------------------------------------ .. important:: Because the scope and type of service information depends on the version of the Firebird server, this information is made available through a separate class `.ServerInfoProvider`. The `.Server.info` property provides access to instance of `.ServerInfoProvider` or it's **ancestor** class according to attached Firebird server version. `.ServerInfoProvider` methods and properties: * `~.ServerInfoProvider.get_log()` - Request the contents of the server’s log file (:file:`firebird.log`). This method is so-called `Async service` that only initiates log transfer. Actual log content could be read by one from many methods for `text output from Services`_ that `.Server` provides . * `~.ServerInfoProvider.version` - Returns Firebird server version as SEMVER string. * `~.ServerInfoProvider.engine_version` - Firebird server version as . float value. * `~.ServerInfoProvider.manager_version` - Firebird service manager version. * `~.ServerInfoProvider.architecture` - Firebird server implementation description. * `~.ServerInfoProvider.home_directory` - Firebird server home directory. * `~.ServerInfoProvider.security_database` - Security database. * `~.ServerInfoProvider.lock_directory` - Directory with lock file(s). * `~.ServerInfoProvider.message_directory` - Directory with message file(s). * `~.ServerInfoProvider.capabilities` - Firebird server capabilities (as `.ServerCapability` flags). * `~.ServerInfoProvider.connection_count` - Current number of database attachments. * `~.ServerInfoProvider.attached_databases` - List of attached databases. **Example:** .. sourcecode:: python from firebird.driver import driver_config, connect, connect_server srv_cfg = """[local] host = localhost user = SYSDBA password = masterkey """ driver_config.register_server('local', srv_cfg) db_cfg = """[employee] server = local database = employee.fdb protocol = inet """ driver_config.register_database('employee', db_cfg) with connect('employee', user='SYSDBA', password='masterkey'), connect_server('local', user='SYSDBA', password='masterkey') as srv: print(f'{srv.info.version=}') print(f'{srv.info.engine_version=}') print(f'{srv.info.manager_version=}') print(f'{srv.info.architecture=}') print(f'{srv.info.home_directory=}') print(f'{srv.info.security_database=}') print(f'{srv.info.lock_directory=}') print(f'{srv.info.message_directory=}') print(f'{srv.info.capabilities=!s}') print(f'{srv.info.connection_count=}') print(f'{srv.info.attached_databases=}') Sample output for 64-bit Linux Firebird 4.0 Beta 2:: srv.info.version='4.0.0.1963' srv.info.engine_version=4.0 srv.info.manager_version=2 srv.info.architecture='Firebird/Linux/AMD/Intel/x64' srv.info.home_directory='/opt/firebird/' srv.info.security_database='/opt/firebird/security4.fdb' srv.info.lock_directory='/tmp/firebird/' srv.info.message_directory='/opt/firebird/' srv.info.capabilities=ServerCapability.REMOTE_HOP|MULTI_CLIENT srv.info.connection_count=1 srv.info.attached_databases=['/opt/firebird/examples/empbuild/employee.fdb'] .. index:: pair: Services; database options Database options ---------------- Database options could be set using `.ServerDbServices` instance accessible via `.Server.database` property. * `~.ServerDbServices.set_default_cache_size()` - Sets individual page cache size for database. .. sourcecode:: python >>> from firebird.driver import connect_server >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_default_cache_size(database='employee.fdb', size=5000) * `~.ServerDbServices.set_sweep_interval()` - Sets database sweep interval. .. sourcecode:: python >>> from firebird.driver import connect_server >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_sweep_interval(database='employee.fdb', interval=100000) * `~.ServerDbServices.set_space_reservation()` - Sets space reservation option for database. .. sourcecode:: python >>> from firebird.driver import connect_server, DbSpaceReservation >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_space_reservation(database='employee.fdb', mode=DbSpaceReservation.USE_FULL) * `~.ServerDbServices.set_write_mode()` - Sets database write mode (SYNC/ASYNC). .. sourcecode:: python >>> from firebird.driver import connect_server, DbWriteMode >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_write_mode(database='employee.fdb', mode=DbWriteMode.ASYNC) * `~.ServerDbServices.set_access_mode()` - Sets database access mode (R/W or R/O). .. sourcecode:: python >>> from firebird.driver import connect_server, DbAccessMode >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_access_mode(database='employee.fdb', mode=DbAccessMode.READ_ONLY) * `~.ServerDbServices.set_sql_dialect()` - Sets database SQL dialect. .. warning:: Changing SQL dialect on existing database is not recommended. Only newly created database objects would respect new dialect setting, while objects created with previous dialect remain unchanged. That may have dire consequences. .. sourcecode:: python >>> from firebird.driver import connect_server >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.set_sql_dialect(database='employee.fdb', dialect=1) * `~.ServerDbServices.no_linger()` - Sets one-off override for database linger. .. sourcecode:: python >>> from firebird.driver import connect_server >>> with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: >>> srv.database.no_linger(database='employee.fdb') .. index:: triple: Services; Database; maintenance Database maintenance -------------------- .. important:: Because available database-related actions depends on the version of the Firebird server, they are made available through a separate class `.ServerDbServices`. The `.Server.database` property provides access to instance of `.ServerDbServices` or it's **ancestor** class according to attached Firebird server version. * `~.ServerDbServices3.get_statistics()` - Returns database statistics produced by gstat utility. This method is so-called `Async service` that only initiates report processing. Actual report content could be read by one from many methods for `text output from Services`_ that `.Server` provides . .. sourcecode:: python from firebird.driver import connect_server, SrvStatFlag with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.get_statistics(database='employee.fdb', flags=SrvStatFlag.DATA_PAGES | SrvStatFlag.RECORD_VERSIONS), tables=['EMPLOYEE','PROJECT']) stats = srv.readlines() * `~.ServerDbServices3.backup()` - Performs logical (GBAK) database backup. This method is so-called `Async service` that only initiates the backup process. Output from gbak could be read by one from many methods for `text output from Services`_ that `.Server` provides . .. sourcecode:: python from firebird.driver import connect_server, SrvBackupFlag with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.backup(database='employee.fdb', backup='/backup/employee.fbk', flags=SrvBackupFlag.IGNORE_CHECKSUMS | SrvBackupFlag.NO_GARBAGE_COLLECT, stats='TD', verbose=True) report = srv.readlines() * `~.ServerDbServices3.local_backup()` - Performs logical (GBAK) database backup into local byte stream. .. sourcecode:: python from firebird.driver import connect_server, SrvBackupFlag f = open('/backup/employee.fbk',mode='wb') with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.local_backup(database='employee.fdb', backup_stream=f, flags=SrvBackupFlag.IGNORE_CHECKSUMS | SrvBackupFlag.NO_GARBAGE_COLLECT) f.close() * `~.ServerDbServices3.restore()` - Performs database restore from logical (GBAK) backup. This method is so-called `Async service` that only initiates the restore process. Output from gbak could be read by one from many methods for `text output from Services`_ that `.Server` provides . .. sourcecode:: python from firebird.driver import connect_server, SrvRestoreFlag with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.restore(backup='/backup/employee.fbk', database='/data/employee.fdb', flags=SrvRestoreFlag.REPLACE, stats='TD', verbose=True, page_size=8192) report = srv.readlines() * `~.ServerDbServices3.local_restore()` - Performs database restore from logical (GBAK) backup stored in local byte stream. .. sourcecode:: python from firebird.driver import connect_server, SrvRestoreFlag f = open('/backup/employee.fbk',mode='rb') with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.local_restore(backup_stream=f, database='/data/employee.fdb', flags=SrvRestoreFlag.REPLACE, page_size=8192) f.close() * `~.ServerDbServices3.nbackup()` - Performs physical (NBACKUP) database backup. .. sourcecode:: python from firebird.driver import connect_server with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.nbackup(database='employee.fdb', backup='/backup/employee.bkp1', level=1) * `~.ServerDbServices3.nrestore()` - Performs restore from physical (NBACKUP) database backup. .. sourcecode:: python from firebird.driver import connect_server with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.nrestore(backups=['/backup/employee.bkp0', '/backup/employee.bkp1'], database='/data/employee.fdb') * `~.ServerDbServices3.shutdown()` - Database shutdown. .. sourcecode:: python from firebird.driver import connect_server, ShutdownMode, ShutdownMethod with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.shutdown(database='employee.fdb', mode=ShutdownMode.SINGLE, method=ShutdownMethod.FORCED, timeout=10) * `~.ServerDbServices3.bring_online()` - Bring previously shut down database back online. .. sourcecode:: python from firebird.driver import connect_server, OnlineMode with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.bring_online(database='employee.fdb', mode=OnlineMode.MULTI) * `~.ServerDbServices3.sweep()` - Performs database sweep operation. .. sourcecode:: python from firebird.driver import connect_server with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.sweep(database='employee.fdb') * `~.ServerDbServices3.validate()` - Performs database validation. This method is so-called `Async service` that only initiates the validation process. Output from validation could be read by one from many methods for `text output from Services`_ that `.Server` provides . .. sourcecode:: python from firebird.driver import connect_server with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.validate(database='employee.fdb') report = srv.readlines() * `~.ServerDbServices3.repair()` - Performs database repair operation. .. sourcecode:: python from firebird.driver import connect_server, SrvRepairFlag with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: srv.database.repair(database='employee.fdb', flags=SrvRepairFlag.REPAIR | SrvRepairFlag.KILL_SHADOWS) * `~.ServerDbServices3.get_limbo_transaction_ids()` - Returns list of transactions in limbo. * `~.ServerDbServices3.commit_limbo_transaction()` - Resolves limbo transaction with commit. * `~.ServerDbServices3.rollback_limbo_transaction()` - Resolves limbo transaction with rollback. * `~.ServerDbServices.nfix_database` - Fixup database after filesystem copy. * `~.ServerDbServices.set_replica_mode` - Manage replica database. .. index:: triple: Services; Database; users User maintenance ---------------- .. important:: Because user maintenance functionality may depend on the version of the Firebird server, this functionality is made available through a separate class `.ServerUserServices`. The `.Server.user` property provides access to instance of `.ServerUserServices` or it's **ancestor** class according to attached Firebird server version. .. tip:: Since Firebird 2.5 you can use SQL commands (CREATE/ALTER/DROP USER) to manage users in a security database from a regular database attachment. The SQL set of DDL commands for managing user accounts has been further enhanced in Firebird 3, thus improving the DDL capabilities in a way that exceeds capabilities of user management services. * `~.ServerUserServices.get_all()` - Returns information about all users. * `~.ServerUserServices.get()` - Returns information about specified users. * `~.ServerUserServices.add()` - Add new user. * `~.ServerUserServices.update()` - Update user information. * `~.ServerUserServices.delete()` - Delete user. * `~.ServerUserServices.exists()` - Returns True if user exists. .. index:: pair: Services; trace Trace sessions -------------- .. important:: Because trace functionality may depend on the version of the Firebird server, this functionality is made available through a separate class `.ServerTraceServices`. The `.Server.trace` property provides access to instance of `.ServerTraceServices` or its **ancestor** class according to attached Firebird server version. * `.ServerTraceServices.start()` - Start new trace session. Requires trace `configuration` and returns `Session ID`. This method is so-called `Async service` that only starts the trace session. Output from trace session could be read by one from many methods for `text output from Services`_ that `.Server` provides . .. sourcecode:: python from firebird.driver import connect_server trace_config = """database = %[\\/]employee.fdb { enabled = true log_statement_finish = true print_plan = true include_filter = %%SELECT%% exclude_filter = %%RDB$%% time_threshold = 0 max_sql_length = 2048 } """ with connect_server('localhost', user='SYSDBA', password='masterkey') as srv: trace_id = srv.trace.start(trace_config,'test_trace_1') trace_log = [] # Get first 10 lines of trace output for i in range(10): trace_log.append(srv.readline()) # Stop trace session # Because trace session blocks the connection, we need another one to stop trace session! with connect_server('localhost', user='SYSDBA', password='masterkey') as srv_aux: srv_aux.trace.stop(trace_id) * `.ServerTraceServices.stop()` - Stop trace session. * `.ServerTraceServices.suspend()` - Suspend trace session. * `.ServerTraceServices.resume()` - Resume trace session. * `.ServerTraceServices.sessions` - Dictionary with active trace sessions. The key is session ID, value is `.TraceSession` instance. .. index:: Logging pair: driver; logging Logging driver activities ========================= The firebird-driver supports `context-based logging system ` provided by `firebird-base`_ package through use of `~firebird.base.logging.LoggingIdMixin`. Classes that use `~firebird.base.logging.LoggingIdMixin`: * `.Connection` - Internally used objects have `_logging_id_` set to 'Transaction.Main', 'Transaction.Query' and 'Cursor.internal'. The log context is not defined. * `.TransactionManager` - The `_logging_id_` is set to 'Transaction'. The `~.TransactionManager.log_context()` is the `.Connection`. * `.DistributedTransactionManager` - The `_logging_id_` is set to 'DTransaction'. The `~.DistributedTransactionManager.log_context()` is `~firebird.base.types.UNDEFINED`. * `.Statement` - The `~.Statement.log_context()` is `.Connection`. * `.BlobReader` - The `~.Statement.log_context()` is the owning object or `~firebird.base.types.UNDEFINED`. * `.Cursor` - The `~.Cursor.log_context()` is `.Connection`. * `.Server` - The log context is not defined. **Example:** .. sourcecode:: python import logging from firebird.base.logging import get_logger, LogLevel from firebird.driver import connect, driver_config # Helper function def execute(cur: Cursor, cmd: str) -> None: get_logger(cur).debug(f"Execute [{cmd=}]") cur.execute(cmd) # Basic Python logging configuration sh = logging.StreamHandler() sh.setFormatter(logging.Formatter('%(levelname)-10s: [%(agent)s][%(context)s] %(message)s')) logger = logging.getLogger() logger.addHandler(sh) logger.setLevel(LogLevel.DEBUG) # Firebird driver configuration srv_cfg = """[local] host = localhost user = SYSDBA password = masterkey """ driver_config.register_server('local', srv_cfg) db_cfg = """[employee] server = local database = employee.fdb protocol = inet """ driver_config.register_database('employee', db_cfg) print("Default logging ids") with connect('employee') as con: con_log = get_logger(con) con_log.info('Start') cur1 = con.cursor() cur2 = con.cursor() execute(cur1, 'select * from country') execute(cur2, 'select * from project') con_log.info('Stop') print("Custom logging ids") with connect('employee') as con: con._logging_id_ = 'employee-1' con_log = get_logger(con) con_log.info('Start') cur1 = con.cursor() cur1._logging_id_ = 'cursor-1' cur2 = con.cursor() cur2._logging_id_ = 'cursor-2' execute(cur1, 'select * from country') execute(cur2, 'select * from project') con_log.info('Stop') Output:: Default logging ids INFO : [Connection][UNDEFINED] Start DEBUG : [Cursor][Connection] Execute [cmd='select * from country'] DEBUG : [Cursor][Connection] Execute [cmd='select * from project'] INFO : [Connection][UNDEFINED] Stop Custom logging ids INFO : [employee-1][UNDEFINED] Start DEBUG : [cursor-1][employee-1] Execute [cmd='select * from country'] DEBUG : [cursor-2][employee-1] Execute [cmd='select * from project'] INFO : [employee-1][UNDEFINED] Stop You can also trace the driver activities using `trace/audit for class instances ` provided by `firebird-base`_ package. **Example:** .. sourcecode:: python import logging from firebird.base.logging import get_logger, LogLevel from firebird.base.trace import trace_manager, add_trace, trace_object, traced, TraceFlag from firebird.driver import connect, driver_config from firebird.driver.core import TransactionManager # Helper function def execute(cur: Cursor, cmd: str) -> None: cur.execute(cmd) # Basic Python logging configuration sh = logging.StreamHandler() sh.setFormatter(logging.Formatter('%(levelname)-10s: [%(agent)s][%(context)s] %(message)s')) logger = logging.getLogger() logger.addHandler(sh) logger.setLevel(LogLevel.DEBUG) # Firebird driver configuration srv_cfg = """[local] host = localhost user = SYSDBA password = masterkey """ driver_config.register_server('local', srv_cfg) db_cfg = """[employee] server = local database = employee.fdb protocol = inet """ driver_config.register_database('employee', db_cfg) # Trace configuration # First: register classes and methods that could be traced trace_manager.register(Connection) add_trace(Connection, 'close', traced) trace_manager.register(TransactionManager) add_trace(TransactionManager, 'begin', traced) add_trace(TransactionManager, 'commit', traced) add_trace(TransactionManager, 'rollback', traced) trace_manager.register(Cursor) add_trace(Cursor, 'execute', traced) add_trace(Cursor, 'close', traced) # Activate trace/audit trace_manager.trace |= (TraceFlag.ACTIVE | TraceFlag.BEFORE | TraceFlag.AFTER | TraceFlag.FAIL) # Traced code with connect('employee') as con: trace_object(con) trace_object(con.main_transaction) con._logging_id_ = 'employee-1' cur1 = con.cursor() trace_object(cur1) cur1._logging_id_ = 'cursor-1' cur2 = con.cursor() trace_object(cur2) cur2._logging_id_ = 'cursor-2' execute(cur1, 'select * from country') execute(cur2, 'select * from project') con.commit() Sample output:: DEBUG : [cursor-1][employee-1] >>> execute(operation='select * from country', parameters=None) DEBUG : [Transaction.Main][employee-1] >>> begin(tpb=None) DEBUG : [Transaction.Main][employee-1] <<< begin[0.00672] DEBUG : [cursor-1][employee-1] >>> close() DEBUG : [cursor-1][employee-1] <<< close[0.00004] DEBUG : [cursor-1][employee-1] <<< execute[0.01119] Result: cursor-1 DEBUG : [cursor-2][employee-1] >>> execute(operation='select * from project', parameters=None) DEBUG : [cursor-2][employee-1] >>> close() DEBUG : [cursor-2][employee-1] <<< close[0.00002] DEBUG : [cursor-2][employee-1] <<< execute[0.00352] Result: cursor-2 DEBUG : [Transaction.Main][employee-1] >>> commit(retaining=False) DEBUG : [cursor-1][employee-1] >>> close() DEBUG : [cursor-1][employee-1] <<< close[0.00017] DEBUG : [cursor-2][employee-1] >>> close() DEBUG : [cursor-2][employee-1] <<< close[0.00012] DEBUG : [Transaction.Main][employee-1] <<< commit[0.00225] DEBUG : [employee-1][UNDEFINED] >>> close() DEBUG : [employee-1][UNDEFINED] <<< close[0.00764] If you will remove the `con.commit()` from the example above, the output will change to:: DEBUG : [cursor-1][employee-1] >>> execute(operation='select * from country', parameters=None) DEBUG : [Transaction.Main][employee-1] >>> begin(tpb=None) DEBUG : [Transaction.Main][employee-1] <<< begin[0.00338] DEBUG : [cursor-1][employee-1] >>> close() DEBUG : [cursor-1][employee-1] <<< close[0.00003] DEBUG : [cursor-1][employee-1] <<< execute[0.00730] Result: cursor-1 DEBUG : [cursor-2][employee-1] >>> execute(operation='select * from project', parameters=None) DEBUG : [cursor-2][employee-1] >>> close() DEBUG : [cursor-2][employee-1] <<< close[0.00003] DEBUG : [cursor-2][employee-1] <<< execute[0.00345] Result: cursor-2 DEBUG : [employee-1][UNDEFINED] >>> close() DEBUG : [Transaction.Main][employee-1] >>> rollback(retaining=False, savepoint=None) DEBUG : [cursor-1][employee-1] >>> close() DEBUG : [cursor-1][employee-1] <<< close[0.00016] DEBUG : [cursor-2][employee-1] >>> close() DEBUG : [cursor-2][employee-1] <<< close[0.00014] DEBUG : [Transaction.Main][employee-1] <<< rollback[0.00171] DEBUG : [employee-1][UNDEFINED] <<< close[0.01001] .. _driver-hooks: .. index:: pair: driver; hooks pair: hooks; usage Driver hooks ============ The firebird-driver uses `hook manager ` from `firebird-base`_ package to provide internal notification mechanism that allows installation of custom hooks into certain driver tasks. Driver hooks are divided into several types exposed as enums in `firebird.driver.hooks` module. APIHook ------- `.APIHook.LOADED` - This hook is invoked once when instance of `.FirebirdAPI` is created. It could be used for additional initialization tasks that require Firebird API, or to manipulate the FirebirdAPI instance itself before its use. Hook routine must have signature: `hook_func(api: FirebirdAPI) -> None`. Any value returned by hook is ignored. ConnectionHook -------------- * `.ConnectionHook.ATTACH_REQUEST` This hook is invoked after all parameters are preprocessed and before `.Connection` is created. Hook routine must have signature: `hook_func(dsn: str, dpb: bytes) -> Optional[Connection]` where `dpb` is Database Parameter Buffer that would be used to create the attachment to the database defined by `dsn`. It may return `.Connection` (or subclass) instance or `None`. First instance returned by any hook of this type will become the return value of caller function and other hooks of the same type are not invoked. * `.ConnectionHook.ATTACHED` This hook is invoked just before `.Connection` (or subclass) instance is returned to the client application. Hook routine must have signature: `hook_func(con: Connection) -> None`. * `.ConnectionHook.DETACH_REQUEST` This hook is invoked before connection is closed. Hook must have signature: `hook_func(con: Connection) -> None`. If any hook function returns True, connection is not closed. * `.ConnectionHook.CLOSED` This hook is invoked after connection is closed. Hook routine must have signature: `hook_func(con: Connection) -> None`. * `.ConnectionHook.DROPPED` This hook is invoked after database is dropped (and connection is closed). Hook routine must have signature: `hook_func(con: Connection) -> None`. ServerHook ---------- * `.ServerHook.ATTACHED` This hook is invoked before `.Server` instance is returned. Hook routine must have signature: `hook_func(srv: Server) -> None`. .. index:: pair: hooks; invocation .. _DDL: http://en.wikipedia.org/wiki/Data_Definition_Language .. _DML: http://en.wikipedia.org/wiki/Data_Manipulation_Language .. _Firebird SAVEPOINTs: http://www.firebirdsql.org/refdocs/langrefupd15-savepoint.html .. _Firebird Book: https://www.ibphoenix.com/products/books/firebird_book .. _busy-wait: http://www.catb.org/jargon/html/B/busy-wait.html .. _Visitor Pattern: http://en.wikipedia.org/wiki/Visitor_pattern .. _setuptools: https://pypi.org/project/setuptools/ .. _PYPI: https://pypi.org/ .. _ctypes: http://docs.python.org/library/ctypes.html .. _pip: https://pypi.org/project/pip/ .. _firebird-base: https://firebird-base.rtfd.io