DButils for python3
python setup.py install
++++++++++++++++++++
:Version: 1.1 :Released: 08/14/11 :Translations: English German_
.. _German: UsersGuide.de.html
.. contents:: Contents
DBUtils_ is a suite of Python modules allowing to connect in a safe and
efficient way between a threaded Python_ application and a database. DBUtils
has been written in view of Webware for Python
_ as the application and
PyGreSQL_ as the adapter to a PostgreSQL_ database, but it can be used
for any other Python application and DB-API 2
_ conformant database adapter.
The DBUtils suite is realized as a Python package containing two subsets of modules, one for use with arbitrary DB-API 2 modules, the other one for use with the classic PyGreSQL module.
+-------------------+------------------------------------------+ | Universal DB-API 2 variant | +===================+==========================================+ | SteadyDB.py | Hardened DB-API 2 connections | +-------------------+------------------------------------------+ | PooledDB.py | Pooling for DB-API 2 connections | +-------------------+------------------------------------------+ | PersistentDB.py | Persistent DB-API 2 connections | +-------------------+------------------------------------------+ | SimplePooledDB.py | Simple pooling for DB-API 2 | +-------------------+------------------------------------------+
+-------------------+------------------------------------------+ | Classic PyGreSQL variant | +===================+==========================================+ | SteadyPg.py | Hardened classic PyGreSQL connections | +-------------------+------------------------------------------+ | PooledPg.py | Pooling for classic PyGreSQL connections | +-------------------+------------------------------------------+ | PersistentPg.py | Persistent classic PyGreSQL connections | +-------------------+------------------------------------------+ | SimplePooledPg.py | Simple pooling for classic PyGreSQL | +-------------------+------------------------------------------+
The dependencies of the modules in the universal DB-API 2 variant are as indicated in the following diagram:
.. image:: dbdep.gif
The dependencies of the modules in the classic PyGreSQL variant are similar:
.. image:: pgdep.gif
You can download the actual version of DBUtils from the Webware for Python homepage at:
http://www.webwareforpython.org/downloads/DBUtils/
You can also download it from the Python Package Index (also known as the "Cheese Shop") at:
http://www.python.org/pypi/DBUtils/
If you intend to use DBUtils from other applications than Webware for Python, it is recommended to install the package in the usual way::
python setup.py install
If you want to use DBUtils as a supplement for the Webware for Python framework only, you should install it as a Webware plug-in::
python setup.py install --install-lib=/path/to/Webware
Replace /path/to/Webware
with the path to the root directory of
your Webware for Python installation. You will also need to run the
Webware installer if this has not been done already or if you want to
integrate the DBUtils documentation into the Webware documentation::
cd path/to/Webware python install.py
DBUtils runs with Python_ 2.3 or newer Python 2 versions. The modules in
the classic PyGreSQL variant need PyGreSQL_ version 3.4 or above, while the
modules in the universal DB-API 2 variant run with any Python DB-API 2
_
compliant database interface module.
This section will refer to the names in the DB-API 2 variant only, but the same applies to the classic PyGreSQL variant.
DBUtils.SimplePooledDB
is a very basic reference implementation of
a pooled database connection. It is much less sophisticated than the
regular PooledDB
module and is particularly lacking the failover
functionality. DBUtils.SimplePooledDB
is essentially the same as
the MiscUtils.DBPool
module that is part of Webware for Python.
You should consider it a demonstration of concept rather than something
that should go into production.
DBUtils.SteadyDB
is a module implementing "hardened" connections
to a database, based on ordinary connections made by any DB-API 2
database module. A "hardened" connection will transparently reopen upon
access when it has been closed or the database connection has been lost
or when it is used more often than an optional usage limit.
A typical example where this is needed is when the database has been restarted while your application is still running and has open connections to the database, or when your application accesses a remote database in a network that is separated by a firewall and the firewall has been restarted and lost its state.
Usually, you will not use the SteadyDB
module directly; it merely serves
as a basis for the next two modules, PersistentDB
and PooledDB
.
DBUtils.PersistentDB
implements steady, thread-affine, persistent
connections to a database, using any DB-API 2 database module.
The following diagram shows the connection layers involved when you
are using PersistentDB
connections:
.. image:: persist.gif
Whenever a thread opens a database connection for the first time, a new connection to the database will be opened that will be used from now on for this specific thread. When the thread closes the database connection, it will still be kept open so that the next time when a connection is requested by the same thread, this already opened connection can be used. The connecton will be closed automatically when the thread dies.
In short: PersistentDB
tries to recycle database connections to
increase the overall database access performance of your threaded application,
but it makes sure that connections are never shared between threads.
Therefore, PersistentDB
will work perfectly even if the underlying
DB-API module is not thread-safe at the connection level, and it will
avoid problems when other threads change the database session or perform
transactions spreading over more than one SQL command.
DBUtils.PooledDB
implements a pool of steady, thread-safe cached
connections to a database which are transparently reused, using any
DB-API 2 database module.
The following diagram shows the connection layers involved when you
are using PooledDB
connections:
.. image:: pool.gif
As the diagram indicates, PooledDB
can share opened database connections
between different threads. This will happen by default if you set up the
connection pool with a positive value of maxshared
and the underlying
DB-API 2 is thread-safe at the connection level, but you can also request
dedicated database connections that will not be shared between threads.
Besides the pool of shared connections, you can also set up a pool of
at least mincached
and at the most maxcached
idle connections that
will be used whenever a thread is requesting a dedicated database connection
or the pool of shared connections is not yet full. When a thread closes a
connection that is not shared any more, it is returned back to the pool of
idle connections so that it can be recycled again.
If the underlying DB-API module is not thread-safe, thread locks will be
used to ensure that the PooledDB
connections are thread-safe. So you
don't need to worry about that, but you should be careful to use dedicated
connections whenever you change the database session or perform transactions
spreading over more than one SQL command.
Both PersistentDB
and PooledDB
serve the same purpose to improve
the database access performance by recycling database connections, while
preserving stability even if database connection will be disrupted.
So which of these two modules should you use? From the above explanations
it is clear that PersistentDB
will make more sense if your application
keeps a constant number of threads which frequently use the database. In
this case, you will always have the same amount of open database connections.
However, if your application frequently starts and ends threads, then it
will be better to use PooledDB
. The latter will also allow more
fine-tuning, particularly if you are using a thread-safe DB-API 2 module.
Since the interface of both modules is similar, you can easily switch from one to the other and check which one will suit better.
The usage of all the modules is similar, but there are also some differences in the initialization between the "Pooled" and "Persistent" variants and also between the universal DB-API 2 and the classic PyGreSQL variants.
We will cover here only the PersistentDB
module and the more complex
PooledDB
module. For the details of the other modules, have a look
at their module docstrings. Using the Python interpreter console, you can
display the documentation of the PooledDB
module as follows (this
works analogously for the other modules)::
help(PooledDB)
In order to make use of the PersistentDB
module, you first need to set
up a generator for your kind of database connections by creating an instance
of PersistentDB
, passing the following parameters:
-
creator
: either an arbitrary function returning new DB-API 2 connection objects or a DB-API 2 compliant database module -
maxusage
: the maximum number of reuses of a single connection (the default of0
orNone
means unlimited reuse)Whenever the limit is reached, the connection will be reset.
-
setsession
: an optional list of SQL commands that may serve to prepare the session, e.g.["set datestyle to german", ...]
-
failures
: an optional exception class or a tuple of exception classes for which the connection failover mechanism shall be applied, if the default (OperationalError, InternalError) is not adequate -
ping
: an optional flag controlling when connections are checked with theping()
method if such a method is available (0
=None
= never,1
= default = whenever it is requested,2
= when a cursor is created,4
= when a query is executed,7
= always, and all other bit combinations of these values) -
closeable
: if this is set to true, then closing connections will be allowed, but by default this will be silently ignored -
threadlocal
: an optional class for representing thread-local data that will be used instead of our Python implementation (threading.local is faster, but cannot be used in all cases) -
The creator function or the connect function of the DB-API 2 compliant database module specified as the creator will receive any additional parameters such as the host, database, user, password etc. You may choose some or all of these parameters in your own creator function, allowing for sophisticated failover and load-balancing mechanisms.
For instance, if you are using pgdb
as your DB-API 2 database module and
want every connection to your local database mydb
to be reused 1000 times::
import pgdb # import used DB-API 2 module from DBUtils.PersistentDB import PersistentDB persist = PersistentDB(pgdb, 1000, database='mydb')
Once you have set up the generator with these parameters, you can request database connections of that kind::
db = persist.connection()
You can use these connections just as if they were ordinary DB-API 2
connections. Actually what you get is the hardened SteadyDB
version of
the underlying DB-API 2 connection.
Closing a persistent connection with db.close()
will be silently
ignored since it would be reopened at the next usage anyway and
contrary to the intent of having persistent connections. Instead,
the connection will be automatically closed when the thread dies.
You can change this behavior be setting the closeable
parameter.
Note that you need to explicitly start transactions by calling the
begin()
method. This ensures that the transparent reopening will be
suspended until the end of the transaction, and that the connection
will be rolled back before being reused by the same thread.
By setting the threadlocal
parameter to threading.local
, getting
connections may become a bit faster, but this may not work in all
environments (for instance, mod_wsgi
is known to cause problems
since it clears the threading.local
data between requests).
In order to make use of the PooledDB
module, you first need to set up the
database connection pool by creating an instance of PooledDB
, passing the
following parameters:
-
creator
: either an arbitrary function returning new DB-API 2 connection objects or a DB-API 2 compliant database module -
mincached
: the initial number of idle connections in the pool (the default of0
means no connections are made at startup) -
maxcached
: the maximum number of idle connections in the pool (the default value of0
orNone
means unlimited pool size) -
maxshared
: maximum number of shared connections allowed (the default value of0
orNone
means all connections are dedicated)When this maximum number is reached, connections are shared if they have been requested as shareable.
-
maxconnections
: maximum number of connections generally allowed (the default value of0
orNone
means any number of connections) -
blocking
: determines behavior when exceeding the maximumIf this is set to true, block and wait until the number of connections decreases, but by default an error will be reported.
-
maxusage
: maximum number of reuses of a single connection (the default of0
orNone
means unlimited reuse)When this maximum usage number of the connection is reached, the connection is automatically reset (closed and reopened).
-
setsession
: an optional list of SQL commands that may serve to prepare the session, e.g.["set datestyle to german", ...]
-
reset
: how connections should be reset when returned to the pool (False
orNone
to rollback transcations started withbegin()
, the default valueTrue
always issues a rollback for safety's sake) -
failures
: an optional exception class or a tuple of exception classes for which the connection failover mechanism shall be applied, if the default (OperationalError, InternalError) is not adequate -
ping
: an optional flag controlling when connections are checked with theping()
method if such a method is available (0
=None
= never,1
= default = whenever fetched from the pool,2
= when a cursor is created,4
= when a query is executed,7
= always, and all other bit combinations of these values) -
The creator function or the connect function of the DB-API 2 compliant database module specified as the creator will receive any additional parameters such as the host, database, user, password etc. You may choose some or all of these parameters in your own creator function, allowing for sophisticated failover and load-balancing mechanisms.
For instance, if you are using pgdb
as your DB-API 2 database module and
want a pool of at least five connections to your local database mydb
::
import pgdb # import used DB-API 2 module from DBUtils.PooledDB import PooledDB pool = PooledDB(pgdb, 5, database='mydb')
Once you have set up the connection pool you can request database connections from that pool::
db = pool.connection()
You can use these connections just as if they were ordinary DB-API 2
connections. Actually what you get is the hardened SteadyDB
version of
the underlying DB-API 2 connection.
Please note that the connection may be shared with other threads by default
if you set a non-zero maxshared
parameter and the DB-API 2 module allows
this. If you want to have a dedicated connection, use::
db = pool.connection(shareable=False)
Instead of this, you can also get a dedicated connection as follows::
db = pool.dedicated_connection()
If you don't need it any more, you should immediately return it to the
pool with db.close()
. You can get another connection in the same way.
Warning: In a threaded environment, never do the following::
pool.connection().cursor().execute(...)
This would release the connection too early for reuse which may be fatal if the connections are not thread-safe. Make sure that the connection object stays alive as long as you are using it, like that::
db = pool.connection() cur = db.cursor() cur.execute(...) res = cur.fetchone() cur.close() # or del cur db.close() # or del db
Note that you need to explicitly start transactions by calling the
begin()
method. This ensures that the connection will not be shared
with other threads, that the transparent reopening will be suspended
until the end of the transaction, and that the connection will be rolled
back before being given back to the connection pool.
If you are using DBUtils in order to access a database from Webware for Python
_ servlets, you need to make sure that you set up your
database connection generators only once when the application starts,
and not every time a servlet instance is created. For this purpose,
you can add the necessary code to the module or class initialization
code of your base servlet class, or you can use the contextInitialize()
function in the __init__.py
script of your application context.
The directory Examples
that is part of the DButils distribution
contains an example context for Webware for Python that uses a small
demo database designed to track the attendees for a series of seminars
(the idea for this example has been taken from the article
"The Python DB-API
_" by Andrew Kuchling).
The example context can be configured by either creating a config file
Configs/Database.config
or by directly changing the default parameters
in the example servlet Examples/DBUtilsExample.py
. This way you can
set an appropriate database user and password, and you can choose the
underlying database module (PyGreSQL classic or any DB-API 2 module).
If the setting maxcached
is present, then the example servlet will use
the "Pooled" variant, otherwise it will use the "Persistent" variant.
If you are using one of the popular object-relational mappers SQLObject_
or SQLAlchemy_, you won't need DBUtils, since they come with their own
connection pools. SQLObject 2
_ (SQL-API_) is actually borrowing some code
from DBUtils to split the pooling out into a separate layer.
Also note that when you are using a solution like the Apache webserver
with mod_python_ or mod_wsgi_, then your Python code will be usually run
in the context of the webserver's child processes. So if you are using
the PooledDB
module, and several of these child processes are running,
you will have as much database connection pools. If these processes are
running many threads, this may still be a reasonable approach, but if these
processes don't spawn more than one worker thread, as in the case of Apache's
"prefork" multi-processing module, this approach does not make sense.
If you're running such a configuration, you should resort to a middleware
for connection pooling that supports multi-processing, such as pgpool_
or pgbouncer_ for the PostgreSQL database.
Some ideas for future improvements:
- Alternatively to the maximum number of uses of a connection, implement a maximum time to live for connections.
- Create modules
MonitorDB
andMonitorPg
that will run in a separate thread, monitoring the pool of the idle connections and maybe also the shared connections respectively the thread-affine connections. If a disrupted connection is detected, then it will be reestablished automatically by the monitoring thread. This will be useful in a scenario where a database powering a website is restarted during the night. Without the monitoring thread, the users would experience a slight delay in the next morning, because only then, the disrupted database connections will be detected and the pool will be rebuilt. With the monitoring thread, this will already happen during the night, shortly after the disruption. The monitoring thread could also be configured to generally recreate the connection pool every day shortly before the users arrive. - Optionally log usage, bad connections and exceeding of limits.
Please send bug reports, patches and feedback directly to the author (using the email address given below).
If there are Webware related problems, these can also be discussed in
the Webware for Python mailing list
_.
Some links to related and alternative software:
- DBUtils_
- Python_
Webware for Python
_ framework- Python
DB-API 2
_ - PostgreSQL_ database
- PyGreSQL_ Python adapter for PostgreSQL
- pgpool_ middleware for PostgreSQL connection pooling
- pgbouncer_ lightweight PostgreSQL connection pooling
- SQLObject_ object-relational mapper
- SQLAlchemy_ object-relational mapper
.. _DBUtils: http://www.webwareforpython.org/DBUtils .. _Python: http://www.python.org .. _Webware for Python: http://www.webwareforpython.org .. _Webware for Python mailing list: https://lists.sourceforge.net/lists/listinfo/webware-discuss .. _DB-API 2: http://www.python.org/dev/peps/pep-0249/ .. _The Python DB-API: http://www.linuxjournal.com/article/2605 .. _PostgresQL: http://www.postgresql.org .. _PyGreSQL: http://www.pygresql.org .. _SQLObject: http://www.sqlobject.org .. _SQLObject 2: http://www.sqlobject.org/2/ .. _SQL-API: http://www.sqlobject.org/sqlapi/ .. _SQLAlchemy: http://www.sqlalchemy.org .. _Apache: http://httpd.apache.org .. _mod_python: http://www.modpython.org .. _mod_wsgi: http://code.google.com/p/modwsgi/ .. _pgpool: http://pgpool.projects.postgresql.org .. _pgbouncer: http://pgbouncer.projects.postgresql.org/
:Author: Christoph Zwerschke [email protected]
:Contributions: DBUtils uses code, input and suggestions made by Ian Bicking, Chuck Esterbrook (Webware for Python), Dan Green (DBTools), Jay Love, Michael Palmer, Tom Schwaller, Geoffrey Talvola, Warren Smith (DbConnectionPool), Ezio Vernacotola, Jehiah Czebotar, Matthew Harriger, Gregory Piñero and Josef van Eenbergen.
Copyright © 2005-2011 by Christoph Zwerschke. All Rights Reserved.
DBUtils is free and open source software,
licensed under the Open Software License version 2.1
__.