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.. _parallelsecurity:
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===========================
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Security details of IPython
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===========================
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.. note::
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This section is not thorough, and IPython.zmq needs a thorough security
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audit.
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IPython's :mod:`IPython.zmq` package exposes the full power of the
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Python interpreter over a TCP/IP network for the purposes of parallel
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computing. This feature brings up the important question of IPython's security
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model. This document gives details about this model and how it is implemented
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in IPython's architecture.
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Processs and network topology
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=============================
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To enable parallel computing, IPython has a number of different processes that
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run. These processes are discussed at length in the IPython documentation and
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are summarized here:
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* The IPython *engine*. This process is a full blown Python
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interpreter in which user code is executed. Multiple
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engines are started to make parallel computing possible.
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* The IPython *hub*. This process monitors a set of
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engines and schedulers, and keeps track of the state of the processes. It listens
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for registration connections from engines and clients, and monitor connections
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from schedulers.
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* The IPython *schedulers*. This is a set of processes that relay commands and results
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between clients and engines. They are typically on the same machine as the controller,
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and listen for connections from engines and clients, but connect to the Hub.
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* The IPython *client*. This process is typically an
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interactive Python process that is used to coordinate the
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engines to get a parallel computation done.
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Collectively, these processes are called the IPython *kernel*, and the hub and schedulers
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together are referred to as the *controller*.
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.. note::
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Are these really still referred to as the Kernel? It doesn't seem so to me. 'cluster'
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seems more accurate.
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-MinRK
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These processes communicate over any transport supported by ZeroMQ (tcp,pgm,infiniband,ipc)
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with a well defined topology. The IPython hub and schedulers listen on sockets. Upon
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starting, an engine connects to a hub and registers itself, which then informs the engine
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of the connection information for the schedulers, and the engine then connects to the
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schedulers. These engine/hub and engine/scheduler connections persist for the
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lifetime of each engine.
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The IPython client also connects to the controller processes using a number of socket
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connections. As of writing, this is one socket per scheduler (4), and 3 connections to the
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hub for a total of 7. These connections persist for the lifetime of the client only.
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A given IPython controller and set of engines engines typically has a relatively
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short lifetime. Typically this lifetime corresponds to the duration of a single parallel
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simulation performed by a single user. Finally, the hub, schedulers, engines, and client
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processes typically execute with the permissions of that same user. More specifically, the
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controller and engines are *not* executed as root or with any other superuser permissions.
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Application logic
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=================
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When running the IPython kernel to perform a parallel computation, a user
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utilizes the IPython client to send Python commands and data through the
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IPython schedulers to the IPython engines, where those commands are executed
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and the data processed. The design of IPython ensures that the client is the
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only access point for the capabilities of the engines. That is, the only way
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of addressing the engines is through a client.
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A user can utilize the client to instruct the IPython engines to execute
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arbitrary Python commands. These Python commands can include calls to the
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system shell, access the filesystem, etc., as required by the user's
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application code. From this perspective, when a user runs an IPython engine on
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a host, that engine has the same capabilities and permissions as the user
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themselves (as if they were logged onto the engine's host with a terminal).
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Secure network connections
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==========================
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Overview
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--------
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ZeroMQ provides exactly no security. For this reason, users of IPython must be very
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careful in managing connections, because an open TCP/IP socket presents access to
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arbitrary execution as the user on the engine machines. As a result, the default behavior
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of controller processes is to only listen for clients on the loopback interface, and the
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client must establish SSH tunnels to connect to the controller processes.
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.. warning::
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If the controller's loopback interface is untrusted, then IPython should be considered
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vulnerable, and this extends to the loopback of all connected clients, which have
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opened a loopback port that is redirected to the controller's loopback port.
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SSH
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---
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Since ZeroMQ provides no security, SSH tunnels are the primary source of secure
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connections. A connector file, such as `ipcontroller-client.json`, will contain
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information for connecting to the controller, possibly including the address of an
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ssh-server through with the client is to tunnel. The Client object then creates tunnels
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using either [OpenSSH]_ or [Paramiko]_, depending on the platform. If users do not wish to
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use OpenSSH or Paramiko, or the tunneling utilities are insufficient, then they may
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construct the tunnels themselves, and simply connect clients and engines as if the
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controller were on loopback on the connecting machine.
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.. note::
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There is not currently tunneling available for engines.
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Authentication
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--------------
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To protect users of shared machines, an execution key is used to authenticate all messages.
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The Session object that handles the message protocol uses a unique key to verify valid
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messages. This can be any value specified by the user, but the default behavior is a
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pseudo-random 128-bit number, as generated by `uuid.uuid4()`. This key is checked on every
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message everywhere it is unpacked (Controller, Engine, and Client) to ensure that it came
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from an authentic user, and no messages that do not contain this key are acted upon in any
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way.
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There is exactly one key per cluster - it must be the same everywhere. Typically, the
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controller creates this key, and stores it in the private connection files
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`ipython-{engine|client}.json`. These files are typically stored in the
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`~/.ipython/cluster_<profile>/security` directory, and are maintained as readable only by
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the owner, just as is common practice with a user's keys in their `.ssh` directory.
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.. warning::
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It is important to note that the key authentication, as emphasized by the use of
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a uuid rather than generating a key with a cryptographic library, provides a
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defense against *accidental* messages more than it does against malicious attacks.
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If loopback is compromised, it would be trivial for an attacker to intercept messages
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and deduce the key, as there is no encryption.
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Specific security vulnerabilities
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=================================
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There are a number of potential security vulnerabilities present in IPython's
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architecture. In this section we discuss those vulnerabilities and detail how
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the security architecture described above prevents them from being exploited.
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Unauthorized clients
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--------------------
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The IPython client can instruct the IPython engines to execute arbitrary
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Python code with the permissions of the user who started the engines. If an
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attacker were able to connect their own hostile IPython client to the IPython
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controller, they could instruct the engines to execute code.
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On the first level, this attack is prevented by requiring access to the controller's
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ports, which are recommended to only be open on loopback if the controller is on an
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untrusted local network. If the attacker does have access to the Controller's ports, then
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the attack is prevented by the capabilities based client authentication of the execution
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key. The relevant authentication information is encoded into the JSON file that clients
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must present to gain access to the IPython controller. By limiting the distribution of
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those keys, a user can grant access to only authorized persons, just as with SSH keys.
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It is highly unlikely that an execution key could be guessed by an attacker
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in a brute force guessing attack. A given instance of the IPython controller
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only runs for a relatively short amount of time (on the order of hours). Thus
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an attacker would have only a limited amount of time to test a search space of
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size 2**128.
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.. warning::
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If the attacker has gained enough access to intercept loopback connections on
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*either* the controller or client, then the key is easily deduced from network
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traffic.
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Unauthorized engines
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--------------------
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If an attacker were able to connect a hostile engine to a user's controller,
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the user might unknowingly send sensitive code or data to the hostile engine.
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This attacker's engine would then have full access to that code and data.
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This type of attack is prevented in the same way as the unauthorized client
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attack, through the usage of the capabilities based authentication scheme.
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Unauthorized controllers
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------------------------
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It is also possible that an attacker could try to convince a user's IPython
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client or engine to connect to a hostile IPython controller. That controller
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would then have full access to the code and data sent between the IPython
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client and the IPython engines.
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Again, this attack is prevented through the capabilities in a connection file, which
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ensure that a client or engine connects to the correct controller. It is also important to
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note that the connection files also encode the IP address and port that the controller is
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listening on, so there is little chance of mistakenly connecting to a controller running
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on a different IP address and port.
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When starting an engine or client, a user must specify the key to use
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for that connection. Thus, in order to introduce a hostile controller, the
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attacker must convince the user to use the key associated with the
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hostile controller. As long as a user is diligent in only using keys from
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trusted sources, this attack is not possible.
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.. note::
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I may be wrong, the unauthorized controller may be easier to fake than this.
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Other security measures
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=======================
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A number of other measures are taken to further limit the security risks
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involved in running the IPython kernel.
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First, by default, the IPython controller listens on random port numbers.
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While this can be overridden by the user, in the default configuration, an
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attacker would have to do a port scan to even find a controller to attack.
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When coupled with the relatively short running time of a typical controller
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(on the order of hours), an attacker would have to work extremely hard and
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extremely *fast* to even find a running controller to attack.
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Second, much of the time, especially when run on supercomputers or clusters,
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the controller is running behind a firewall. Thus, for engines or client to
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connect to the controller:
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* The different processes have to all be behind the firewall.
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or:
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* The user has to use SSH port forwarding to tunnel the
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connections through the firewall.
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In either case, an attacker is presented with additional barriers that prevent
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attacking or even probing the system.
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Summary
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=======
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IPython's architecture has been carefully designed with security in mind. The
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capabilities based authentication model, in conjunction with SSH tunneled
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TCP/IP channels, address the core potential vulnerabilities in the system,
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while still enabling user's to use the system in open networks.
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Other questions
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===============
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.. note::
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this does not apply to ZMQ, but I am sure there will be questions.
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About keys
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----------
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Can you clarify the roles of the certificate and its keys versus the FURL,
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which is also called a key?
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The certificate created by IPython processes is a standard public key x509
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certificate, that is used by the SSL handshake protocol to setup encrypted
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channel between the controller and the IPython engine or client. This public
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and private key associated with this certificate are used only by the SSL
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handshake protocol in setting up this encrypted channel.
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The FURL serves a completely different and independent purpose from the
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key pair associated with the certificate. When we refer to a FURL as a
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key, we are using the word "key" in the capabilities based security model
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sense. This has nothing to do with "key" in the public/private key sense used
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in the SSL protocol.
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With that said the FURL is used as an cryptographic key, to grant
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IPython engines and clients access to particular capabilities that the
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controller offers.
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Self signed certificates
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------------------------
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Is the controller creating a self-signed certificate? Is this created for per
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instance/session, one-time-setup or each-time the controller is started?
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The Foolscap network protocol, which handles the SSL protocol details, creates
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a self-signed x509 certificate using OpenSSL for each IPython process. The
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lifetime of the certificate is handled differently for the IPython controller
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and the engines/client.
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For the IPython engines and client, the certificate is only held in memory for
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the lifetime of its process. It is never written to disk.
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For the controller, the certificate can be created anew each time the
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controller starts or it can be created once and reused each time the
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controller starts. If at any point, the certificate is deleted, a new one is
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created the next time the controller starts.
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SSL private key
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---------------
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How the private key (associated with the certificate) is distributed?
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In the usual implementation of the SSL protocol, the private key is never
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distributed. We follow this standard always.
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SSL versus Foolscap authentication
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----------------------------------
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Many SSL connections only perform one sided authentication (the server to the
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client). How is the client authentication in IPython's system related to SSL
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authentication?
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We perform a two way SSL handshake in which both parties request and verify
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the certificate of their peer. This mutual authentication is handled by the
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SSL handshake and is separate and independent from the additional
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authentication steps that the CLIENT and SERVER perform after an encrypted
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channel is established.
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.. [RFC5246] <http://tools.ietf.org/html/rfc5246>
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.. [OpenSSH] <http://www.openssh.com/>
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.. [Paramiko] <http://www.lag.net/paramiko/>
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