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pep-0249.txt
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PEP: 249
Title: Python Database API Specification v2.0
Author: Marc-André Lemburg <[email protected]>
Discussions-To: [email protected]
Status: Final
Type: Informational
Content-Type: text/x-rst
Created: 12-Apr-1999
Post-History:
Replaces: 248
Introduction
============
This API has been defined to encourage similarity between the Python
modules that are used to access databases. By doing this, we hope to
achieve a consistency leading to more easily understood modules, code
that is generally more portable across databases, and a broader reach
of database connectivity from Python.
Comments and questions about this specification may be directed to the
`SIG for Database Interfacing with Python <[email protected]>`__.
For more information on database interfacing with Python and available
packages see the `Database Topic Guide
<http://www.python.org/topics/database/>`__.
This document describes the Python Database API Specification 2.0 and
a set of common optional extensions. The previous version 1.0 version
is still available as reference, in :PEP:`248`. Package writers are
encouraged to use this version of the specification as basis for new
interfaces.
Module Interface
=================
Constructors
------------
Access to the database is made available through connection
objects. The module must provide the following constructor for these:
.. _connect:
`connect`_\ ( *parameters...* )
Constructor for creating a connection to the database.
Returns a Connection_ Object. It takes a number of parameters
which are database dependent. [1]_
Globals
-------
These module globals must be defined:
.. _apilevel:
`apilevel`_
String constant stating the supported DB API level.
Currently only the strings "``1.0``" and "``2.0``" are allowed.
If not given, a DB-API 1.0 level interface should be assumed.
.. _threadsafety:
`threadsafety`_
Integer constant stating the level of thread safety the interface
supports. Possible values are:
============ =======================================================
threadsafety Meaning
============ =======================================================
0 Threads may not share the module.
1 Threads may share the module, but not connections.
2 Threads may share the module and connections.
3 Threads may share the module, connections and cursors.
============ =======================================================
Sharing in the above context means that two threads may use a
resource without wrapping it using a mutex semaphore to implement
resource locking. Note that you cannot always make external
resources thread safe by managing access using a mutex: the
resource may rely on global variables or other external sources
that are beyond your control.
.. _paramstyle:
`paramstyle`_
String constant stating the type of parameter marker formatting
expected by the interface. Possible values are [2]_:
============ ==============================================================
paramstyle Meaning
============ ==============================================================
``qmark`` Question mark style, e.g. ``...WHERE name=?``
``numeric`` Numeric, positional style, e.g. ``...WHERE name=:1``
``named`` Named style, e.g. ``...WHERE name=:name``
``format`` ANSI C printf format codes, e.g. ``...WHERE name=%s``
``pyformat`` Python extended format codes, e.g. ``...WHERE name=%(name)s``
============ ==============================================================
Exceptions
----------
The module should make all error information available through these
exceptions or subclasses thereof:
.. _Warning:
`Warning`_
Exception raised for important warnings like data truncations
while inserting, etc. It must be a subclass of the Python
``Exception`` class [10]_ [11]_.
.. _Error:
`Error`_
Exception that is the base class of all other error
exceptions. You can use this to catch all errors with one single
``except`` statement. Warnings are not considered errors and thus
should not use this class as base. It must be a subclass of the
Python ``Exception`` class [10]_.
.. _InterfaceError:
`InterfaceError`_
Exception raised for errors that are related to the database
interface rather than the database itself. It must be a subclass
of Error_.
.. _DatabaseError:
`DatabaseError`_
Exception raised for errors that are related to the database. It
must be a subclass of Error_.
.. _DataError:
`DataError`_
Exception raised for errors that are due to problems with the
processed data like division by zero, numeric value out of range,
etc. It must be a subclass of DatabaseError_.
.. _OperationalError:
`OperationalError`_
Exception raised for errors that are related to the database's
operation and not necessarily under the control of the programmer,
e.g. an unexpected disconnect occurs, the data source name is not
found, a transaction could not be processed, a memory allocation
error occurred during processing, etc. It must be a subclass of
DatabaseError_.
.. _IntegrityError:
`IntegrityError`_
Exception raised when the relational integrity of the database is
affected, e.g. a foreign key check fails. It must be a subclass
of DatabaseError_.
.. _InternalError:
`InternalError`_
Exception raised when the database encounters an internal error,
e.g. the cursor is not valid anymore, the transaction is out of
sync, etc. It must be a subclass of DatabaseError_.
.. _ProgrammingError:
`ProgrammingError`_
Exception raised for programming errors, e.g. table not found or
already exists, syntax error in the SQL statement, wrong number of
parameters specified, etc. It must be a subclass of
DatabaseError_.
.. _NotSupportedError:
`NotSupportedError`_
Exception raised in case a method or database API was used which
is not supported by the database, e.g. requesting a
`.rollback()`_ on a connection that does not support transaction
or has transactions turned off. It must be a subclass of
DatabaseError_.
This is the exception inheritance layout [10]_ [11]_:
.. code-block:: text
Exception
|__Warning
|__Error
|__InterfaceError
|__DatabaseError
|__DataError
|__OperationalError
|__IntegrityError
|__InternalError
|__ProgrammingError
|__NotSupportedError
.. Note::
The values of these exceptions are not defined. They should give the user
a fairly good idea of what went wrong, though.
.. _Connection:
Connection Objects
==================
Connection objects should respond to the following methods.
Connection methods
------------------
.. .close():
.. _Connection.close:
`.close() <#Connection.close>`_
Close the connection now (rather than whenever ``.__del__()`` is
called).
The connection will be unusable from this point forward; an Error_
(or subclass) exception will be raised if any operation is
attempted with the connection. The same applies to all cursor
objects trying to use the connection. Note that closing a
connection without committing the changes first will cause an
implicit rollback to be performed.
.. _.commit:
.. _.commit():
`.commit`_\ ()
Commit 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.
.. _.rollback:
.. _.rollback():
`.rollback`_\ ()
This method is optional since not all databases provide transaction
support. [3]_
In case a database does provide transactions this method causes 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.
.. _.cursor:
`.cursor`_\ ()
Return a new Cursor_ Object using the connection.
If the database does not provide a direct cursor concept, the module will
have to emulate cursors using other means to the extent needed by this
specification. [4]_
.. _Cursor:
Cursor Objects
==============
These objects represent a database cursor, which is used to manage the
context of a fetch operation. Cursors created from the same connection
are not isolated, *i.e.*, any changes done to the database by a cursor
are immediately visible by the other cursors. Cursors created from
different connections can or can not be isolated, depending on how the
transaction support is implemented (see also the connection's
`.rollback`_\ () and `.commit`_\ () methods).
Cursor Objects should respond to the following methods and attributes.
Cursor attributes
-----------------
.. _.description:
`.description`_
This read-only attribute is a sequence of 7-item sequences.
Each of these sequences contains information describing one result
column:
* ``name``
* ``type_code``
* ``display_size``
* ``internal_size``
* ``precision``
* ``scale``
* ``null_ok``
The first two items (``name`` and ``type_code``) are mandatory,
the other five are optional and are set to ``None`` if no
meaningful values can be provided.
This attribute will be ``None`` for operations that do not return
rows or if the cursor has not had an operation invoked via the
`.execute*()`_ method yet.
The ``type_code`` can be interpreted by comparing it to the `Type
Objects`_ specified in the section below.
.. _.rowcount:
`.rowcount`_
This read-only attribute specifies the number of rows that the last
`.execute*()`_ produced (for DQL statements like ``SELECT``) or affected
(for DML statements like ``UPDATE`` or ``INSERT``). [9]_
The attribute is -1 in case no `.execute*()`_ has been performed
on the cursor or the rowcount of the last operation is cannot be
determined by the interface. [7]_
.. note::
Future versions of the DB API specification could redefine the
latter case to have the object return ``None`` instead of -1.
Cursor methods
--------------
.. _.callproc:
.. _.callproc():
`.callproc`_\ ( *procname* [, *parameters* ] )
(This method is optional since not all databases provide stored
procedures. [3]_)
Call a stored database procedure with the given name. The sequence
of parameters must contain one entry for each argument that the
procedure expects. The result of the call is returned as modified
copy of the input sequence. Input parameters are left untouched,
output and input/output parameters replaced with possibly new
values.
The procedure may also provide a result set as output. This must
then be made available through the standard `.fetch*()`_ methods.
.. .close:
.. _Cursor.close:
.. _Cursor.close():
`.close <#Cursor.close>`_\ ()
Close the cursor now (rather than whenever ``__del__`` is called).
The cursor will be unusable from this point forward; an Error_ (or
subclass) exception will be raised if any operation is attempted
with the cursor.
.. _.execute*:
.. _.execute*():
.. _.execute:
.. _.execute():
`.execute`_\ (*operation* [, *parameters*])
Prepare and execute a database operation (query or command).
Parameters may be provided as sequence or mapping and will be
bound to variables in the operation. Variables are specified in a
database-specific notation (see the module's paramstyle_ attribute
for details). [5]_
A reference to the operation will be retained by the cursor. If
the same operation object is passed in again, then the cursor can
optimize its behavior. This is most effective for algorithms
where the same operation is used, but different parameters are
bound to it (many times).
For maximum efficiency when reusing an operation, it is best to
use the `.setinputsizes()`_ method to specify the parameter types
and sizes ahead of time. It is legal for a parameter to not match
the predefined information; the implementation should compensate,
possibly with a loss of efficiency.
The parameters may also be specified as list of tuples to
e.g. insert multiple rows in a single operation, but this kind of
usage is deprecated: `.executemany()`_ should be used instead.
Return values are not defined.
.. _.executemany:
.. _.executemany():
`.executemany`_\ ( *operation*, *seq_of_parameters* )
Prepare a database operation (query or command) and then execute it
against all parameter sequences or mappings found in the sequence
*seq_of_parameters*.
Modules are free to implement this method using multiple calls to
the `.execute()`_ method or by using array operations to have the
database process the sequence as a whole in one call.
Use of this method for an operation which produces one or more
result sets constitutes undefined behavior, and the implementation
is permitted (but not required) to raise an exception when it
detects that a result set has been created by an invocation of the
operation.
The same comments as for `.execute()`_ also apply accordingly to
this method.
Return values are not defined.
.. _.fetch*:
.. _.fetch*():
.. _.fetchone:
.. _.fetchone():
`.fetchone`_\ ()
Fetch the next row of a query result set, returning a single
sequence, or ``None`` when no more data is available. [6]_
An Error_ (or subclass) exception is raised if the previous call
to `.execute*()`_ did not produce any result set or no call was
issued yet.
.. _.fetchmany:
.. _.fetchmany():
`.fetchmany`_\ ([*size=cursor.arraysize*])
Fetch 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 arraysize determines
the number of rows to be fetched. The method should 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.
An Error_ (or subclass) exception is raised if the previous call
to `.execute*()`_ did not produce any result set or no call was
issued yet.
Note there are performance considerations involved with the *size*
parameter. For optimal performance, it is usually best to use the
`.arraysize`_ attribute. If the size parameter is used, then it
is best for it to retain the same value from one `.fetchmany()`_
call to the next.
.. _.fetchall:
.. _.fetchall():
`.fetchall`_\ ()
Fetch all (remaining) rows of a query result, returning them as a
sequence of sequences (e.g. a list of tuples). Note that the
cursor's arraysize attribute can affect the performance of this
operation.
An Error_ (or subclass) exception is raised if the previous call
to `.execute*()`_ did not produce any result set or no call was
issued yet.
.. _.nextset:
.. _.nextset():
`.nextset`_\ ()
(This method is optional since not all databases support multiple
result sets. [3]_)
This method will make the cursor skip to the next available set,
discarding any remaining rows from the current set.
If there are no more sets, the method returns ``None``. Otherwise,
it returns a true value and subsequent calls to the `.fetch*()`_
methods will return rows from the next result set.
An Error_ (or subclass) exception is raised if the previous call
to `.execute*()`_ did not produce any result set or no call was
issued yet.
.. _.arraysize:
`.arraysize`_
This read/write attribute specifies the number of rows to fetch at
a time with `.fetchmany()`_. It defaults to 1 meaning to fetch a
single row at a time.
Implementations must observe this value with respect to the
`.fetchmany()`_ method, but are free to interact with the database
a single row at a time. It may also be used in the implementation
of `.executemany()`_.
.. _.setinputsizes:
.. _.setinputsizes():
`.setinputsizes`_\ (*sizes*)
This can be used before a call to `.execute*()`_ to predefine
memory areas for the operation's parameters.
*sizes* is specified as a sequence — one item for each input
parameter. The item should be a Type Object that corresponds to
the input that will be used, or it should be an integer specifying
the maximum length of a string parameter. If the item is
``None``, then no predefined memory area will be reserved for that
column (this is useful to avoid predefined areas for large
inputs).
This method would be used before the `.execute*()`_ method is
invoked.
Implementations are free to have this method do nothing and users
are free to not use it.
.. _.setoutputsize:
.. _.setoutputsize():
`.setoutputsize`_\ (*size* [, *column*])
Set a column buffer size for fetches of large columns
(e.g. ``LONG``\s, ``BLOB``\s, etc.). The column is specified as
an index into the result sequence. Not specifying the column will
set the default size for all large columns in the cursor.
This method would be used before the `.execute*()`_ method is
invoked.
Implementations are free to have this method do nothing and users
are free to not use it.
.. _Type Objects:
Type Objects and Constructors
=============================
Many databases need to have the input in a particular format for
binding to an operation's input parameters. For example, if an input
is destined for a ``DATE`` column, then it must be bound to the
database in a particular string format. Similar problems exist for
"Row ID" columns or large binary items (e.g. blobs or ``RAW``
columns). This presents problems for Python since the parameters to
the `.execute*()`_ method are untyped. When the database module sees
a Python string object, it doesn't know if it should be bound as a
simple ``CHAR`` column, as a raw ``BINARY`` item, or as a ``DATE``.
To overcome this problem, a module must provide the constructors
defined below to create objects that can hold special values. When
passed to the cursor methods, the module can then detect the proper
type of the input parameter and bind it accordingly.
A Cursor_ Object's description attribute returns information about
each of the result columns of a query. The ``type_code`` must compare
equal to one of Type Objects defined below. Type Objects may be equal
to more than one type code (e.g. ``DATETIME`` could be equal to the
type codes for date, time and timestamp columns; see the
`Implementation Hints`_ below for details).
The module exports the following constructors and singletons:
.. _Date:
`Date`_\ (*year*, *month*, *day*)
This function constructs an object holding a date value.
.. _Time:
`Time`_\ (*hour*, *minute*, *second*)
This function constructs an object holding a time value.
.. _Timestamp:
`Timestamp`_\ (*year*, *month*, *day*, *hour*, *minute*, *second*)
This function constructs an object holding a time stamp value.
.. _DateFromTicks:
`DateFromTicks`_\ (*ticks*)
This function constructs an object holding a date value from the
given ticks value (number of seconds since the epoch; see the
documentation of `the standard Python time module
<http://docs.python.org/library/time.html>`__ for details).
.. _TimeFromTicks:
`TimeFromTicks`_\ (*ticks*)
This function constructs an object holding a time value from the
given ticks value (number of seconds since the epoch; see the
documentation of the standard Python time module for details).
.. _TimeStampFromTicks:
`TimestampFromTicks`_\ (*ticks*)
This function constructs an object holding a time stamp value from
the given ticks value (number of seconds since the epoch; see the
documentation of the standard Python time module for details).
.. _Binary:
`Binary`_\ (*string*)
This function constructs an object capable of holding a binary
(long) string value.
.. _STRING:
`STRING`_ type
This type object is used to describe columns in a database that
are string-based (e.g. ``CHAR``).
.. _Binary type:
`BINARY`_ type
This type object is used to describe (long) binary columns in a
database (e.g. ``LONG``, ``RAW``, ``BLOB``\s).
.. _NUMBER:
`NUMBER`_ type
This type object is used to describe numeric columns in a
database.
.. _DATETIME:
`DATETIME`_ type
This type object is used to describe date/time columns in a
database.
.. _ROWID:
`ROWID`_ type
This type object is used to describe the "Row ID" column in a
database.
SQL ``NULL`` values are represented by the Python ``None`` singleton
on input and output.
.. Note::
Usage of Unix ticks for database interfacing can cause troubles
because of the limited date range they cover.
.. _Implementation Hints:
Implementation Hints for Module Authors
=======================================
* Date/time objects can be implemented as `Python datetime module
<http://docs.python.org/library/datetime.html>`__ objects (available
since Python 2.3, with a C API since 2.4) or using the `mxDateTime
<http://www.egenix.com/products/python/mxBase/mxDateTime/>`_ package
(available for all Python versions since 1.5.2). They both provide
all necessary constructors and methods at Python and C level.
* Here is a sample implementation of the Unix ticks based constructors
for date/time delegating work to the generic constructors::
import time
def DateFromTicks(ticks):
return Date(*time.localtime(ticks)[:3])
def TimeFromTicks(ticks):
return Time(*time.localtime(ticks)[3:6])
def TimestampFromTicks(ticks):
return Timestamp(*time.localtime(ticks)[:6])
* The preferred object type for Binary objects are the buffer types
available in standard Python starting with version 1.5.2. Please
see the Python documentation for details. For information about the
C interface have a look at ``Include/bufferobject.h`` and
``Objects/bufferobject.c`` in the Python source distribution.
* This Python class allows implementing the above type objects even
though the description type code field yields multiple values for on
type object::
class DBAPITypeObject:
def __init__(self,*values):
self.values = values
def __cmp__(self,other):
if other in self.values:
return 0
if other < self.values:
return 1
else:
return -1
The resulting type object compares equal to all values passed to the
constructor.
* Here is a snippet of Python code that implements the exception
hierarchy defined above [10]_::
class Error(Exception):
pass
class Warning(Exception):
pass
class InterfaceError(Error):
pass
class DatabaseError(Error):
pass
class InternalError(DatabaseError):
pass
class OperationalError(DatabaseError):
pass
class ProgrammingError(DatabaseError):
pass
class IntegrityError(DatabaseError):
pass
class DataError(DatabaseError):
pass
class NotSupportedError(DatabaseError):
pass
In C you can use the ``PyErr_NewException(fullname, base, NULL)``
API to create the exception objects.
Optional DB API Extensions
==========================
During the lifetime of DB API 2.0, module authors have often extended
their implementations beyond what is required by this DB API
specification. To enhance compatibility and to provide a clean upgrade
path to possible future versions of the specification, this section
defines a set of common extensions to the core DB API 2.0
specification.
As with all DB API optional features, the database module authors are
free to not implement these additional attributes and methods (using
them will then result in an ``AttributeError``) or to raise a
NotSupportedError_ in case the availability can only be checked at
run-time.
It has been proposed to make usage of these extensions optionally
visible to the programmer by issuing Python warnings through the
Python warning framework. To make this feature useful, the warning
messages must be standardized in order to be able to mask them. These
standard messages are referred to below as *Warning Message*.
.. _.rownumber:
Cursor\ `.rownumber`_
This read-only attribute should provide the current 0-based index
of the cursor in the result set or ``None`` if the index cannot be
determined.
The index can be seen as index of the cursor in a sequence (the
result set). The next fetch operation will fetch the row indexed
by `.rownumber`_ in that sequence.
*Warning Message:* "DB-API extension cursor.rownumber used"
.. _Connection.Error:
.. _Connection.ProgrammingError:
`Connection.Error`_, `Connection.ProgrammingError`_, etc.
All exception classes defined by the DB API standard should be
exposed on the Connection_ objects as attributes (in addition to
being available at module scope).
These attributes simplify error handling in multi-connection
environments.
*Warning Message:* "DB-API extension connection.<exception> used"
.. _.connection:
Cursor\ `.connection`_
This read-only attribute return a reference to the Connection_
object on which the cursor was created.
The attribute simplifies writing polymorph code in
multi-connection environments.
*Warning Message:* "DB-API extension cursor.connection used"
.. _.scroll:
.. _.scroll():
Cursor\ `.scroll`_\ (*value* [, *mode='relative'* ])
Scroll the cursor in the result set to a new position according to
*mode*.
If mode is ``relative`` (default), value is taken as offset to the
current position in the result set, if set to ``absolute``, value
states an absolute target position.
An ``IndexError`` should be raised in case a scroll operation
would leave the result set. In this case, the cursor position is
left undefined (ideal would be to not move the cursor at all).
.. Note::
This method should use native scrollable cursors, if available,
or revert to an emulation for forward-only scrollable
cursors. The method may raise NotSupportedError_ to signal
that a specific operation is not supported by the database
(e.g. backward scrolling).
*Warning Message:* "DB-API extension cursor.scroll() used"
.. _Cursor.messages:
`Cursor.messages`_
This is a Python list object to which the interface appends tuples
(exception class, exception value) for all messages which the
interfaces receives from the underlying database for this cursor.
The list is cleared by all standard cursor methods calls (prior to
executing the call) except for the `.fetch*()`_ calls
automatically to avoid excessive memory usage and can also be
cleared by executing ``del cursor.messages[:]``.
All error and warning messages generated by the database are
placed into this list, so checking the list allows the user to
verify correct operation of the method calls.
The aim of this attribute is to eliminate the need for a Warning
exception which often causes problems (some warnings really only
have informational character).
*Warning Message:* "DB-API extension cursor.messages used"
.. _Connection.messages:
`Connection.messages`_
Same as Cursor.messages_ except that the messages in the list are
connection oriented.
The list is cleared automatically by all standard connection
methods calls (prior to executing the call) to avoid excessive
memory usage and can also be cleared by executing ``del
connection.messages[:]``.
*Warning Message:* "DB-API extension connection.messages used"
.. _.next:
.. _.next():
Cursor\ `.next`_\ ()
Return the next row from the currently executing SQL statement
using the same semantics as `.fetchone()`_. A ``StopIteration``
exception is raised when the result set is exhausted for Python
versions 2.2 and later. Previous versions don't have the
``StopIteration`` exception and so the method should raise an
``IndexError`` instead.
*Warning Message:* "DB-API extension cursor.next() used"
.. _.__iter__:
.. _.__iter__():
Cursor\ `.__iter__`_\ ()
Return self to make cursors compatible to the iteration protocol
[8]_.
*Warning Message:* "DB-API extension cursor.__iter__() used"
.. _.lastrowid:
Cursor\ `.lastrowid`_
This read-only attribute provides the rowid of the last modified
row (most databases return a rowid only when a single ``INSERT``
operation is performed). If the operation does not set a rowid or
if the database does not support rowids, this attribute should be
set to ``None``.
The semantics of ``.lastrowid`` are undefined in case the last
executed statement modified more than one row, e.g. when using
``INSERT`` with ``.executemany()``.
*Warning Message:* "DB-API extension cursor.lastrowid used"
.. _Connection.autocommit:
.. _.autocommit:
Connection\ `.autocommit`_
Attribute to query and set the autocommit mode of the connection.
Return ``True`` if the connection is operating in autocommit (non-
transactional) mode. Return ``False`` if the connection is
operating in manual commit (transactional) mode.
Setting the attribute to ``True`` or ``False`` adjusts the
connection's mode accordingly.
Changing the setting from ``True`` to ``False`` (disabling
autocommit) will have the database leave autocommit mode and start
a new transaction. Changing from ``False`` to ``True`` (enabling
autocommit) has database dependent semantics with respect to how
pending transactions are handled. [12]_
*Deprecation notice*: Even though several database modules implement
both the read and write nature of this attribute, setting the
autocommit mode by writing to the attribute is deprecated, since
this may result in I/O and related exceptions, making it difficult
to implement in an async context. [13]_
*Warning Message:* "DB-API extension connection.autocommit used"
Optional Error Handling Extensions
==================================
The core DB API specification only introduces a set of exceptions
which can be raised to report errors to the user. In some cases,
exceptions may be too disruptive for the flow of a program or even
render execution impossible.
For these cases and in order to simplify error handling when dealing
with databases, database module authors may choose to implement user
definable error handlers. This section describes a standard way of
defining these error handlers.
.. _Connection.errorhandler:
.. _Cursor.errorhandler:
`Connection.errorhandler`_, `Cursor.errorhandler`_
Read/write attribute which references an error handler to call in
case an error condition is met.
The handler must be a Python callable taking the following arguments:
.. parsed-literal::
errorhandler(*connection*, *cursor*, *errorclass*, *errorvalue*)
where connection is a reference to the connection on which the
cursor operates, cursor a reference to the cursor (or ``None`` in
case the error does not apply to a cursor), *errorclass* is an
error class which to instantiate using *errorvalue* as
construction argument.
The standard error handler should add the error information to the
appropriate ``.messages`` attribute (`Connection.messages`_ or
`Cursor.messages`_) and raise the exception defined by the given
*errorclass* and *errorvalue* parameters.
If no ``.errorhandler`` is set (the attribute is ``None``), the