Documentation for repoze.tm2 ( fork)


repoze.tm2 is WSGI middleware which uses the ZODB package’s transaction manager to wrap a call to its pipeline children inside a transaction.


repoze.tm2 is equivalent to the package (it was forked from, except it has a dependency only on the transaction package rather than a dependency on the entire ZODB3 package (ZODB3 3.8 ships with the transaction package right now). It is an error to install both and repoze.tm2 into the same environment, as they provide the same entry points and import points.


When this middleware is present in the WSGI pipeline, a new transaction will be started once a WSGI request makes it to the middleware. If any downstream application raises an exception, the transaction will be aborted, otherwise the transaction will be committed. Any “data managers” participating in the transaction will be aborted or committed respectively. A ZODB “connection” is an example of a data manager.

Since this is a tiny wrapper around the ZODB transaction module, and the ZODB transaction module is “thread-safe” (in the sense that its default policy is to create a new transaction for each thread), it should be fine to use in either multiprocess or multithread environments.

Purpose and Usage

The ZODB transaction manager is a completely generic transaction manager. It can be used independently of the actual “object database” part of ZODB. One of the purposes of creating was to allow for systems other than Zope to make use of two-phase commit transactions in a WSGI context.

Let’s pretend we have an existing system that places data into a relational database when someone submits a form. The system has been running for a while, and our code handles the database commit and rollback for us explicitly; if the form processing succeeds, our code commits the database transaction. If it fails, our code rolls back the database transaction. Everything works fine.

Now our customer asks us if we can also place data into another separate relational database when the form is submitted as well as continuing to place data in the original database. We need to put data in both databases, and if we want to ensure that no records exist in one that don’t exist in the other as a result of a form submission, we’re going to need to do a pretty complicated commit and rollback dance in each place in our code which needs to write to both data stores. We can’t just blindly commit one, then commit the other, because the second commit may fail and we’ll be left with “orphan” data in the first, and we’ll either need to clean it up manually or leave it there to trip over later.

A transaction manager helps us ensure that no data is committed to either database unless both participating data stores can commit. Once the transaction manager determines that both data stores are willing to commit, it will commit them both in very quick succession, so that there is only a minimal chance that the second data store will fail to commit. If it does, the system will raise an error that makes it impossible to begin another transaction until the system restarts, so the damage is minimized. In practice, this error almost never occurs unless the code that interfaces the database to the transaction manager has a bug.

Adding repoze.tm2 To Your WSGI Pipeline

Via PasteDeploy .INI configuration:

 pipeline =

Via Python:

from otherplace import mywsgiapp

from import TM
new_wsgiapp = TM(mywsgiapp)

Using A Commit Veto

If you’d like to veto commits based on the status code returned by the downstream application, use a commit veto callback.

First, define the callback somewhere in your application:

def commit_veto(environ, status, headers):
    for header_name, header_value in headers:
        if header_name.lower() == 'x-tm':
            if header_value.lower() == 'commit':
                return False
            return True
    for bad in ('4', '5'):
        if status.startswith(bad):
            return True
    return False

Then configure it into your middleware.

Via Python:

from otherplace import mywsgiapp
from my.package import commit_veto

from import TM
new_wsgiapp = TM(mywsgiapp, commit_veto=commit_veto)

Via PasteDeploy:

commit_veto = my.package:commit_veto

In the PasteDeploy example, the path is a Python dotted name, where the dots separate module and package names, and the colon separates a module from its contents. In the above example, the code would be implemented as a “commit_veto” function which lives in the “package” submodule of the “my” package.

A variant of the commit veto implementation shown above as an example is actually present in the repoze.tm2 package as It’s fairly general, so you needn’t implement one yourself. Instead just use it.

Via Python:

from otherplace import mywsgiapp
from import default_commit_veto

from import TM
new_wsgiapp = TM(mywsgiapp, commit_veto=default_commit_veto)

Via PasteDeploy:

commit_veto =

API documentation for default_commit_veto exists at

Mocking Up A Data Manager

The piece of code you need to write in order to participate in ZODB transactions is called a ‘data manager’. It is typically a class. Here’s the interface that you need to implement in the code for a data manager:

class IDataManager(zope.interface.Interface):
    """Objects that manage transactional storage.

    These objects may manage data for other objects, or they
    may manage non-object storages, such as relational
    databases.  For example, a ZODB.Connection.

    Note that when some data is modified, that data's data
    manager should join a transaction so that data can be
    committed when the user commits the transaction.  """

    transaction_manager = zope.interface.Attribute(
        """The transaction manager (TM) used by this data

        This is a public attribute, intended for read-only
        use.  The value is an instance of ITransactionManager,
        typically set by the data manager's constructor.  """

    def abort(transaction):
        """Abort a transaction and forget all changes.

        Abort must be called outside of a two-phase commit.

        Abort is called by the transaction manager to abort transactions
        that are not yet in a two-phase commit.

    # Two-phase commit protocol.  These methods are called by
    # the ITransaction object associated with the transaction
    # being committed.  The sequence of calls normally follows
    # this regular expression: tpc_begin commit tpc_vote
    # (tpc_finish | tpc_abort)

    def tpc_begin(transaction):

        """Begin commit of a transaction, starting the
        two-phase commit.

        transaction is the ITransaction instance associated with the
        transaction being committed.

    def commit(transaction):

        """Commit modifications to registered objects.

        Save changes to be made persistent if the transaction
        commits (if tpc_finish is called later).  If tpc_abort
        is called later, changes must not persist.

        This includes conflict detection and handling.  If no
        conflicts or errors occur, the data manager should be
        prepared to make the changes persist when tpc_finish
        is called.  """

    def tpc_vote(transaction):
        """Verify that a data manager can commit the transaction.

        This is the last chance for a data manager to vote 'no'.  A
        data manager votes 'no' by raising an exception.

        transaction is the ITransaction instance associated with the
        transaction being committed.

    def tpc_finish(transaction):

        """Indicate confirmation that the transaction is done.

        Make all changes to objects modified by this
        transaction persist.

        transaction is the ITransaction instance associated
        with the transaction being committed.

        This should never fail.  If this raises an exception,
        the database is not expected to maintain consistency;
        it's a serious error.  """

    def tpc_abort(transaction):

        """Abort a transaction.

        This is called by a transaction manager to end a
        two-phase commit on the data manager.  Abandon all
        changes to objects modified by this transaction.

        transaction is the ITransaction instance associated
        with the transaction being committed.

        This should never fail.

    def sortKey():

        """Return a key to use for ordering registered

        ZODB uses a global sort order to prevent deadlock when
        it commits transactions involving multiple resource
        managers.  The resource manager must define a
        sortKey() method that provides a global ordering for
        resource managers.  """
        # Alternate version:
        #"""Return a consistent sort key for this connection.
        # #This allows ordering multiple connections that use
        the same storage in #a consistent manner. This is
        unique for the lifetime of a connection, #which is
        good enough to avoid ZEO deadlocks.  #"""

Let’s implement a mock data manager. Our mock data manager will write data to a file if the transaction commits. It will not write data to a file if the transaction aborts:

class MockDataManager:

    transaction_manager = None

    def __init__(self, data, path): = data
        self.path = path

    def abort(self, transaction):

    def tpc_begin(self, transaction):

    def commit(self, transaction):
        import tempfile
        self.tempfn = tempfile.mktemp()
        temp = open(self.tempfn, 'wb')

    def tpc_vote(self, transaction):
        import os
        if not os.path.exists(self.tempfn):
            raise ValueError('%s doesnt exist' % self.tempfn)
        if os.path.exists(self.path):
            raise ValueError('file already exists')

    def tpc_finish(self, transaction):
        import os
        os.rename(self.tempfn, self.path)

    def tpc_abort(self, transaction):
        import os
        except OSError:

We can create a datamanager and join it into the currently running transaction:

dm = MockDataManager('heres the data',  '/tmp/file')
import transaction
t = transaction.get()

When the transaction commits, a file will be placed in ‘/tmp/file’ containing ‘heres the data’. If the transaction aborts, no file will be created.

If more than one data manager is joined to the transaction, all of them must be willing to commit or the entire transaction is aborted and none of them commit. If you can imagine creating two of the mock data managers we’ve made within application code, if one has a problem during “tpc_vote”, neither will actually write a file to the ultimate location, and thus your application consistency is maintained.

Integrating Your Data Manager With repoze.tm2

The repoze.tm2 transaction management machinery has an implicit policy. When it is in the WSGI pipeline, a transaction is started when the middleware is invoked. Thus, in your application code, calling “import transaction; transaction.get()” will return the transaction object created by the repoze.tm2 middleware. You needn’t call t.commit() or t.abort() within your application code. You only need to call t.join, to register your data manager with the transaction. repoze.tm2 will abort the transaction if an exception is raised by your application code or lower middleware before it returns a WSGI response. If your application or lower middleware raises an exception, the transaction is aborted.


When the repoze.tm2 middleware is in the WSGI pipeline, a boolean key is present in the environment ( A utility function named can be imported and passed the WSGI environment to check for activation:

from import isActive
tm_active = isActive(wsgi_environment)

If an application needs to perform an action after a transaction ends, the registry may be used to register a callback. This object is an instance fo the class. The method accepts a callback (accepting no arguments) and a transaction instance:

from import after_end
import transaction
t = transaction.get() # the current transaction
def func():
    pass # close a connection, etc
after_end.register(func, t)

“after_end” callbacks should only be registered when the transaction manager is active, or a memory leak will result (registration cleanup happens only on transaction commit or abort, which is managed by repoze.tm2 while in the pipeline).

Further Documentation

Many database adapters written for Zope (e.g. for Postgres, MySQL, etc) use this transaction manager, so it should be possible to take a look in these places to see how to implement a more real-world transaction-aware database connector that uses this module in non-Zope applications:


The repoze-dev maillist should be used for communications about this software.

Report bugs on Github:

Fork it on Github:

API Docs

Indices and tables