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@ -1,64 +1,57 @@
Ansible Extension
=================
.. image:: images/ansible/cell_division.png
:align: right
An extension to `Ansible`_ is included that implements host connections over
Mitogen, replacing embedded shell invocations with pure-Python equivalents
invoked via highly efficient remote procedure calls tunnelled over SSH. No
changes are required to the target hosts.
Mitogen for Ansible
===================
The extension is approaching a generally dependable state, and works well for
many real-world playbooks. `Bug reports`_ in this area are very welcome
Ansible is a huge beast, and only significant testing will prove the
extension's soundness.
Divergence from Ansible's normal behaviour is considered a bug, so please
report anything you notice, regardless of how inconsequential it may seem.
An extension to `Ansible`_ is included that implements connections over
Mitogen, replacing embedded shell invocations with pure-Python equivalents
invoked via highly efficient remote procedure calls to persistent interpreters
tunnelled over SSH. No changes are required to target hosts.
The extension is approaching stability and real-world testing is now
encouraged. `Bug reports`_ are welcome: Ansible is huge, and only wide testing
will ensure soundness.
.. _Ansible: https://www.ansible.com/
.. _Bug reports: https://goo.gl/yLKZiJ
Overview
--------
You should **expect a 1.25x - 7x speedup** and a **CPU usage reduction of at
least 2x**, depending on network conditions, the specific modules executed, and
time spent by the target host already doing useful work. Mitogen cannot speed
up a module once it is executing, it can only ensure the module executes as
quickly as possible.
* **A single SSH connection is used for each target host**, in addition to one
sudo invocation per distinct user account. Subsequent playbook steps always
reuse the same connection. This is much better than SSH multiplexing combined
with pipelining, as significant state can be maintained in RAM between steps,
and the system logs aren't filled with spam from repeat SSH and sudo
invocations.
* **A single Python interpreter is used** per host and sudo account combination
for the duration of the run, avoiding the repeat cost of invoking multiple
interpreters and recompiling imports, saving 300-800 ms for every playbook
step.
* Remote interpreters reuse Mitogen's module import mechanism, caching uploaded
dependencies between steps at the host and user account level. As a
consequence, **bandwidth usage is consistently an order of magnitude lower**
compared to SSH pipelining, and around 5x fewer frames are required to
traverse the wire for a run to complete successfully.
* **No writes to the target host's filesystem occur**, unless explicitly
triggered by a playbook step. In all typical configurations, Ansible
repeatedly rewrites and extracts ZIP files to multiple temporary directories
on the target host. Since no temporary files are used, security issues
relating to those files in cross-account scenarios are entirely avoided.
**Expect a 1.25x - 7x speedup** and a **CPU usage reduction of at least 2x**,
depending on network conditions, modules executed, and time already spent by
targets on useful work. Mitogen cannot improve a module once it is executing,
it can only ensure the module executes as quickly as possible.
* **One connection is used per target**, in addition to one sudo invocation per
user account. This is much better than SSH multiplexing combined with
pipelining, as significant state can be maintained in RAM between steps, and
system logs aren't spammed with repeat authentication events.
* **A single network roundtrip is used** to execute a step whose code already
exists in RAM on the target. Eliminating multiplexed SSH channel creation
saves 5 ms runtime per 1 ms of network latency for every playbook step.
* **Processes are aggressively reused**, avoiding the cost of invoking Python
and recompiling imports, saving 300-800 ms for every playbook step.
* Code is ephemerally cached in RAM, **reducing bandwidth usage by an order
of magnitude** compared to SSH pipelining, with around 5x fewer frames
traversing the network in a typical run.
* **No writes to the target's filesystem occur**, unless explicitly triggered
by a playbook step. In all typical configurations, Ansible repeatedly
rewrites and extracts ZIP files to multiple temporary directories on the
target. Since no temporary files are used, security issues relating to those
files in cross-account scenarios are entirely avoided.
Demo
----
~~~~
This demonstrates Ansible running a subset of the Mitogen integration tests
concurrent to an equivalent run using the extension.
@ -71,7 +64,7 @@ concurrent to an equivalent run using the extension.
Testimonials
------------
~~~~~~~~~~~~
* "With mitogen **my playbook runtime went from 45 minutes to just under 3
minutes**. Awesome work!"
@ -96,14 +89,11 @@ Testimonials
Installation
------------
.. caution::
Please review the behavioural differences documented below prior to use.
1. Verify Ansible 2.4 and Python 2.7 are listed in the output of ``ansible
--version``
2. Download and extract https://github.com/dw/mitogen/archive/master.zip
3. Modify ``ansible.cfg``:
1. Thoroughly review the documented behavioural differences.
2. Verify Ansible 2.4/2.5 and Python 2.7 are listed in ``ansible --version``
output.
3. Download and extract https://github.com/dw/mitogen/archive/master.zip
4. Modify ``ansible.cfg``:
.. code-block:: dosini
@ -111,70 +101,256 @@ Installation
strategy_plugins = /path/to/mitogen-master/ansible_mitogen/plugins/strategy
strategy = mitogen_linear
The ``strategy`` key is optional. If omitted, you can set the
``ANSIBLE_STRATEGY=mitogen_linear`` environment variable on a per-run basis.
Like ``mitogen_linear``, the ``mitogen_free`` strategy also exists to mimic
the built-in ``free`` strategy.
The ``strategy`` key is optional. If omitted, the
``ANSIBLE_STRATEGY=mitogen_linear`` environment variable can be set on a
per-run basis. Like ``mitogen_linear``, the ``mitogen_free`` strategy exists
to mimic the ``free`` strategy.
Noteworthy Differences
----------------------
* Ansible 2.4 and 2.5 are supported. File bugs to register interest in older
releases.
4. Cross your fingers and try it.
* The ``sudo`` become method is available and ``su`` is planned. File bugs to
register interest in additional methods.
* The ``ssh``, ``local`` and ``docker`` connection types are available, with
more planned. File bugs to register interest.
Limitations
-----------
* Local commands execute in a reuseable interpreter created identically to
interpreters on targets. Presently one interpreter per ``become_user``
exists, and so only one local action may execute simultaneously.
* Only Ansible 2.4 is being used for development, with occasional tests under
2.5, 2.3 and 2.2. It should be more than possible to fully support at least
2.3, if not also 2.2.
Ansible usually permits up to ``forks`` simultaneous local actions. Any
long-running local actions that execute for every target will experience
artificial serialization, causing slowdown equivalent to `task_duration *
num_targets`. This will be fixed soon.
* Only the ``sudo`` become method is available, however adding new methods is
straightforward, and eventually at least ``su`` will be included.
* Asynchronous jobs presently exist only for the duration of a run, and time
limits are not implemented.
* The extension's performance benefits do not scale perfectly linearly with the
number of targets. This is a subject of ongoing investigation and
improvements will appear in time.
* Due to use of :func:`select.select` the IO multiplexer breaks down around 100
targets, expect performance degradation as this number is approached and
errant behaviour as it is exceeded. A replacement will appear soon.
* "Module Replacer" style modules are not yet supported. These rarely appear in
practice, and light Github code searches failed to reveal many examples of
them.
* The undocumented ability to extend :mod:`ansible.module_utils` by supplying a
``module_utils`` directory alongside a custom new-style module is not yet
supported.
* "Module Replacer" style modules are not supported. These rarely appear in
practice, and light web searches failed to reveal many examples of them.
Behavioural Differences
-----------------------
* Ansible permits up to ``forks`` connections to be setup in parallel, whereas
in Mitogen this is handled by a fixed-size thread pool. Up to 16 connections
may be established in parallel by default, this can be modified by setting
the ``MITOGEN_POOL_SIZE`` environment variable.
* Ansible permits up to ``forks`` SSH connections to be setup simultaneously,
whereas in Mitogen this is handled by a thread pool. Eventually this pool
will become per-CPU, but meanwhile, a maximum of 16 SSH connections may be
established simultaneously by default. This can be increased or decreased
setting the ``MITOGEN_POOL_SIZE`` environment variable.
* Performance does not scale perfectly linearly with target count. This will
improve over time.
* Mitogen treats connection timeouts for the SSH and become steps of a task
invocation separately, meaning that in some circumstances the configured
timeout may appear to be doubled. This is since Mitogen internally treats the
creation of an SSH account context separately to the creation of a sudo
account context proxied via that SSH account.
* Timeouts normally apply to the combined runtime of the SSH and become steps
of a task. As Mitogen treats SSH and sudo distincly, during a failure the
effective timeout may appear to double.
A future revision may detect a sudo account context created immediately
following its parent SSH account, and try to emulate Ansible's existing
timeout semantics.
* Local commands are executed in a reuseable Python interpreter created
identically to interpreters used on remote hosts. At present only one such
interpreter per ``become_user`` exists, and so only one local action may be
executed simultaneously per local user account.
New Features & Notes
--------------------
Connection Delegation
~~~~~~~~~~~~~~~~~~~~~
.. image:: images/jumpbox.png
:align: right
Included is a preview of **Connection Delegation**, a Mitogen-specific
implementation of `stackable connection plug-ins`_. This enables multi-hop
connections via a bastion, or Docker connections delegated via their host
machine, where reaching the host may itself entail recursive delegation.
.. _Stackable connection plug-ins: https://github.com/ansible/proposals/issues/25
Unlike with SSH forwarding Ansible has complete visibility of the final
topology, declarative configuration via static/dynamic inventory is possible,
and data can be cached and re-served, and code executed on every intermediary.
For example when targeting Docker containers on a remote machine, each module
need only be uploaded once for the first task and container that requires it,
then cached and served from the SSH account for every future task in any
container.
.. raw:: html
<div style="clear: both;"></div>
.. caution::
Connection delegation is a work in progress, bug reports are welcome.
Ansible usually permits up to ``ansible.cfg:forks`` simultaneous local
actions. Any long-running local actions that execute for every target will
experience artificial serialization, causing slowdown equivalent to
`task_duration * num_targets`. This will be fixed soon.
* While imports are cached on intermediaries, module scripts are needlessly
reuploaded for each target. Fixing this is equivalent to implementing
**Topology-Aware File Synchronization**, so it may remain unfixed until
that feature is started.
* Delegated connection setup is single-threaded; only one connection can be
constructed in parallel per intermediary.
* Unbounded queue RAM growth may occur in an intermediary during large file
transfers if the link between any two hops is slower than the link
between the controller and the first hop.
* Inferring the configuration of intermediaries may be buggy, manifesting
as duplicate connections between hops, due to not perfectly replicating
the configuration Ansible would normally use for the intermediary.
* The extension does not understand the difference between a delegated
connection and a ``become_user``. If interpreter recycling kicks in, a
delegated connection could be prematurely recycled.
To enable connection delegation, set ``mitogen_via=<inventory name>`` on the
command line, or as host and group variables.
.. code-block:: ini
# Docker container on web1.dc1 is reachable via web1.dc1.
[app-containers.web1.dc1]
app1.web1.dc1 ansible_host=app1 ansible_connection=docker mitogen_via=web1.dc1
# Web servers in DC1 are reachable via bastion.dc1
[dc1]
web1.dc1
web2.dc1
web3.dc1
[dc1:vars]
mitogen_via = bastion.dc1
# Web servers in DC2 are reachable via bastion.dc2
[dc2]
web1.dc2
web2.dc2
web3.dc2
[dc2:vars]
mitogen_via = bastion.dc2
# Prod bastions are reachable via a corporate network gateway.
[bastions]
bastion.dc1 mitogen_via=corp-gateway.internal
bastion.dc2 mitogen_via=corp-gateway.internal
[corp-gateway]
corp-gateway.internal
File Transfer
~~~~~~~~~~~~~
Normally a tool like ``scp`` is used to copy a file with the ``copy`` or
``template`` actions, or when uploading modules with pipelining disabled. With
Mitogen copies are implemented natively using the same interpreters, connection
tree, and routed message bus that carries RPCs.
This permits streaming directly between endpoints regardless of execution
environment, without necessitating temporary copies in intermediary accounts or
machines, for example when ``become`` is active, or in the presence of
connection delegation. It also neatly avoids the problem of securely sharing
temporary files between accounts and machines.
One roundtrip is required to initiate a transfer. For any tool that operates
via SSH multiplexing, 5 are required to configure the associated IO channel, in
addition to the time needed to start the local and remote processes. A complete
localhost invocation of ``scp`` requires around 15 ms.
As the implementation is self-contained, it is simple to make future
improvements like prioritizing transfers, supporting resume, or displaying
progress bars.
Interpreter Reuse
~~~~~~~~~~~~~~~~~
Python interpreters are aggressively reused to execute modules. While this
works well, it violates an unwritten assumption, and so it is possible an
earlier module execution could cause a subsequent module to fail, or for
unrelated modules to interact poorly due to bad hygiene, such as
monkey-patching that becomes stacked over repeat invocations.
Before reporting a bug relating to a misbehaving module, please re-run with
``-e mitogen_task_isolation=fork`` to see if the problem abates. This may be
set per-task, paying attention to the possibility an earlier task may be the
true cause of a failure.
.. code-block:: yaml
- name: My task.
broken_module:
some_option: true
vars:
mitogen_task_isolation: fork
* Asynchronous jobs exist only for the duration of a run, and cannot be
queried by subsequent ansible-playbook invocations. Since the ability to
query job IDs across runs relied on an implementation detail, it is not
expected this will break any real-world playbooks.
If forking solves your problem, **please report a bug regardless**, as an
internal list can be updated to prevent others bumping into the same problem.
Interpreter Recycling
~~~~~~~~~~~~~~~~~~~~~
There is a per-target limit on the number of interpreters. Once 20 exist, the
youngest is terminated before starting any new interpreter, preventing
situations like below from triggering memory exhaustion.
.. code-block:: yaml
- hosts: corp_boxes
vars:
user_directory: [
# 10,000 corporate user accounts
]
tasks:
- name: Create user bashrc
become: true
vars:
ansible_become_user: "{{item}}"
copy:
src: bashrc
dest: "~{{item}}/.bashrc"
with_items: "{{user_directory}}"
The youngest is chosen to preserve useful accounts like ``root`` and
``postgresql`` that often appear early in a run, however it is simple to
construct a playbook that defeats this strategy. A future version will key
interpreters on the identity of their creating task, avoiding useful account
recycling in every scenario.
To modify the limit, set the ``MITOGEN_MAX_INTERPRETERS`` environment variable.
Standard IO
~~~~~~~~~~~
Ansible uses pseudo TTYs for most invocations to allow it to type interactive
passwords, however pseudo TTYs are disabled where standard input is required or
``sudo`` is not in use. Additionally when SSH multiplexing is enabled, a string
like ``Shared connection to localhost closed\r\n`` appears in ``stderr`` of
every invocation.
Mitogen does not naturally require either of these, as command output is always
embedded within framed messages, and it can simply call :py:func:`pty.openpty`
in any location an interactive password must be typed.
A major downside to Ansible's behaviour is that ``stdout`` and ``stderr`` are
merged together into a single ``stdout`` variable, with carriage returns
inserted in the output by the TTY layer. However ugly, the extension emulates
this precisely, to avoid breaking playbooks that expect text to appear in
specific variables with a particular linefeed style.
How Modules Execute
-------------------
~~~~~~~~~~~~~~~~~~~
Ansible usually modifies, recompresses and reuploads modules every time they
run on a target, work that must be repeated by the controller for every
@ -218,47 +394,51 @@ cached in RAM for the remainder of the run.
key2=repr(value2)[ ..]] "``.
Sample Profiles
---------------
Local VM connection
~~~~~~~~~~~~~~~~~~~
Runtime Patches
~~~~~~~~~~~~~~~
This demonstrates Mitogen vs. connection pipelining to a local VM, executing
the 100 simple repeated steps of ``run_hostname_100_times.yml`` from the
examples directory. Mitogen requires **43x less bandwidth and 4.25x less
time**.
Three small runtime patches are employed in ``strategy.py`` to hook into
desirable locations, in order to override uses of shell, the module executor,
and the mechanism for selecting a connection plug-in. While it is hoped the
patches can be avoided in future, for interesting versions of Ansible deployed
today this simply is not possible, and so they continue to be required.
.. image:: images/ansible/run_hostname_100_times.png
The patches are concise and behave conservatively, including by disabling
themselves when non-Mitogen connections are in use. Additional third party
plug-ins are unlikely to attempt similar patches, so the risk to an established
configuration should be minimal.
Kathmandu to Paris
~~~~~~~~~~~~~~~~~~
Flag Emulation
~~~~~~~~~~~~~~
This is a full Django application playbook over a ~180ms link between Kathmandu
and Paris. Aside from large pauses where the host performs useful work, the
high latency of this link means Mitogen only manages a 1.7x speedup.
Mitogen re-parses ``sudo_flags``, ``become_flags``, and ``ssh_flags`` using
option parsers extracted from `sudo(1)` and `ssh(1)` in order to emulate their
equivalent semantics. This allows:
Many early roundtrips are due to inefficiencies in Mitogen's importer that will
be fixed over time, however the majority, comprising at least 10 seconds, are
due to idling while the host's previous result and next command are in-flight
on the network.
* robust support for common ``ansible.cfg`` tricks without reconfiguration,
such as forwarding SSH agents across ``sudo`` invocations,
* reporting on conflicting flag combinations,
* reporting on unsupported flag combinations,
* internally special-casing certain behaviour (like recursive agent forwarding)
without boring the user with the details,
* avoiding opening the extension up to untestable scenarios where users can
insert arbitrary garbage between Mitogen and the components it integrates
with,
* precise emulation by an alternative implementation, for example if Mitogen
grew support for Paramiko.
The initial extension lays groundwork for exciting structural changes to the
execution model: a future version will tackle latency head-on by delegating
some control flow to the target host, melding the performance and scalability
benefits of pull-based operation with the management simplicity of push-based
operation.
.. image:: images/ansible/costapp.png
Supported Variables
-------------------
Matching Ansible's model, variables are treated on a per-task basis, causing
establishment of additional reuseable interpreters as necessary to match the
configuration of each task.
SSH Variables
-------------
Matching Ansible's existing model, these variables are treated on a per-task
basis, causing establishment of additional reuseable interpreters as necessary
to match the configuration of each task.
SSH
~~~
This list will grow as more missing pieces are discovered.
@ -272,8 +452,8 @@ This list will grow as more missing pieces are discovered.
* ``ssh_args``, ``ssh_common_args``, ``ssh_extra_args``
Sudo Variables
--------------
Sudo
~~~~
* ``ansible_python_interpreter``
* ``ansible_sudo_exe``, ``ansible_become_exe``
@ -283,31 +463,23 @@ Sudo Variables
* ansible.cfg: ``timeout``
Docker Variables
----------------
Note: Docker support is only intended for developer testing, it might disappear
entirely prior to a stable release.
Docker
~~~~~~
* ansible_host
Docker support has received relatively little testing, expect increased
probability of surprises for the time being.
Chat on IRC
-----------
Some users and developers hang out on the
`#mitogen <https://webchat.freenode.net/?channels=mitogen>`_ channel on the
FreeNode IRC network.
* ``ansible_host``
Debugging
---------
Normally with Ansible, diagnostics and use of the :py:mod:`logging` package
output on the target machine are discarded. With Mitogen, all of this is
captured and returned to the host machine, where it can be viewed as desired
with ``-vvv``. Basic high level logs are produced with ``-vvv``, with logging
of all IO on the controller with ``-vvvv`` or higher.
Diagnostics and use of the :py:mod:`logging` package output on the target
machine are usually discarded. With Mitogen, all of this is captured and
returned to the controller, where it can be viewed as desired with ``-vvv``.
Basic high level logs are produced with ``-vvv``, with logging of all IO on the
controller with ``-vvvv`` or higher.
Although use of standard IO and the logging package on the target is forwarded
to the controller, it is not possible to receive IO activity logs, as the
@ -320,129 +492,45 @@ When file-based logging is enabled, one file per context will be created on the
local machine and every target machine, as ``/tmp/mitogen.<pid>.log``.
Implementation Notes
--------------------
Interpreter Reuse
~~~~~~~~~~~~~~~~~
The extension aggressively reuses the single target Python interpreter to
execute every module. While this generally works well, it violates an unwritten
assumption regarding Ansible modules, and so it is possible a buggy module
could cause a run to fail, or for unrelated modules to interact with each other
due to bad hygiene.
Before reporting a bug relating to a module behaving incorrectly, please re-run
your playbook with ``-e mitogen_task_isolation=fork`` to see if the problem
abates. This may also be set on a per-task basis:
::
- name: My task.
broken_module:
some_option: true
vars:
mitogen_task_isolation: fork
If forking fixes your problem, **please report a bug regardless**, as an
internal list can be updated to prevent users bumping into the same problem in
future.
Interpreter Recycling
~~~~~~~~~~~~~~~~~~~~~
The extension limits the number of persistent interpreters in use. When the
limit is reached, the youngest interpreter is terminated before starting a new
interpreter, preventing situations like below from triggering memory
exhaustion.
.. code-block:: yaml
- hosts: corp_boxes
vars:
user_directory: [
# 10,000 corporate user accounts
]
tasks:
- name: Create user bashrc
become: true
vars:
ansible_become_user: "{{item}}"
copy:
src: bashrc
dest: "~{{item}}/.bashrc"
with_items: "{{user_directory}}"
This recycling does not occur for direct connections from the controller, and
it is keyed on a per-target basis, i.e. up to 20 interpreters may exist for
each directly connected target.
The youngest interpreter is chosen to preserve useful accounts, like "root" or
"postgresql" that tend to appear early in a run, however it is simple to
construct a playbook that defeats this strategy. A future version will key
interpreters on the identity of their creating task, file and/or playbook,
avoiding useful account recycling in every scenario.
To raise or lower the limit from 20, set the ``MITOGEN_MAX_INTERPRETERS``
environment variable to a new value.
Runtime Patches
~~~~~~~~~~~~~~~
Getting Help
~~~~~~~~~~~~
Some users and developers hang out on the
`#mitogen <https://webchat.freenode.net/?channels=mitogen>`_ channel on the
FreeNode IRC network.
Three small runtime patches are employed in ``strategy.py`` to hook into
desirable locations, in order to override uses of shell, the module executor,
and the mechanism for selecting a connection plug-in. While it is hoped the
patches can be avoided in future, for interesting versions of Ansible deployed
today this simply is not possible, and so they continue to be required.
The patches are concise and behave conservatively, including by disabling
themselves when non-Mitogen connections are in use. Additional third party
plug-ins are unlikely to attempt similar patches, so the risk to an established
configuration should be minimal.
Sample Profiles
---------------
Standard IO
~~~~~~~~~~~
Local VM connection
~~~~~~~~~~~~~~~~~~~
Ansible uses pseudo TTYs for most invocations, to allow it to handle typing
passwords interactively, however it disables pseudo TTYs for certain commands
where standard input is required or ``sudo`` is not in use. Additionally when
SSH multiplexing is enabled, a string like ``Shared connection to localhost
closed\r\n`` appears in ``stderr`` of every invocation.
This demonstrates Mitogen vs. connection pipelining to a local VM, executing
the 100 simple repeated steps of ``run_hostname_100_times.yml`` from the
examples directory. Mitogen requires **43x less bandwidth and 4.25x less
time**.
Mitogen does not naturally require either of these, as command output is
embedded within the SSH stream, and it can simply call :py:func:`pty.openpty`
in every location an interactive password must be typed.
.. image:: images/ansible/run_hostname_100_times.png
A major downside to Ansible's behaviour is that ``stdout`` and ``stderr`` are
merged together into a single ``stdout`` variable, with carriage returns
inserted in the output by the TTY layer. However ugly, the extension emulates
all of this behaviour precisely, to avoid breaking playbooks that expect
certain text to appear in certain variables with certain linefeed characters.
See `Ansible#14377`_ for related discussion.
Kathmandu to Paris
~~~~~~~~~~~~~~~~~~
.. _Ansible#14377: https://github.com/ansible/ansible/issues/14377
This is a full Django application playbook over a ~180ms link between Kathmandu
and Paris. Aside from large pauses where the host performs useful work, the
high latency of this link means Mitogen only manages a 1.7x speedup.
Many early roundtrips are due to inefficiencies in Mitogen's importer that will
be fixed over time, however the majority, comprising at least 10 seconds, are
due to idling while the host's previous result and next command are in-flight
on the network.
Flag Emulation
~~~~~~~~~~~~~~
The initial extension lays groundwork for exciting structural changes to the
execution model: a future version will tackle latency head-on by delegating
some control flow to the target host, melding the performance and scalability
benefits of pull-based operation with the management simplicity of push-based
operation.
Mitogen re-parses ``sudo_flags``, ``become_flags``, and ``ssh_flags`` using
option parsers extracted from `sudo(1)` and `ssh(1)` in order to emulate their
equivalent semantics. This allows:
.. image:: images/ansible/costapp.png
* robust support for common ``ansible.cfg`` tricks without reconfiguration,
such as forwarding SSH agents across ``sudo`` invocations,
* reporting on conflicting flag combinations,
* reporting on unsupported flag combinations,
* internally special-casing certain behaviour (like recursive agent forwarding)
without boring the user with the details,
* avoiding opening the extension up to untestable scenarios where users can
insert arbitrary garbage between Mitogen and the components it integrates
with,
* precise emulation by an alternative implementation, for example if Mitogen
grew support for Paramiko.

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