Parrot Security OS 4.7 Released With New Linux Kernel, Menu Structure, Tools Improvements And Many Changes

In Sep 18 2019, Parrot Security OS 4.7 has released, with many new following changes below.

Latest Linux 5.2.x series
   The new ISO files of Parrot 4.7 are being released only now, but we were the first Debian derivative distribution to introduce Linux 5.1 and 5.2 to all our users, and now ParrotSec team is ready to offer it also with our ISO files rebild cycle to support more devices and integrate all the latest linux features from the beginning.

New sandbox behavior (opt-in rather than opt-out)
   Sandboxing is a great thing, and ParrotSec team was in the first line when they introduced our custom Firejail and AppArmor solution for the first time many years ago. We still want to improve such feature and ParrotSec team has a whole team dedicated to improve sandboxing and hardening of the Parrot Security OS system, but ParrotSec team had to face the many users with issues caused by the restrictions of our sandbox.

   In Parrot Security OS 4.7 the sandbox is disabled by default, and users can decide wether to start an application sandboxed or not. You can easily start the sandboxed version of an installed program from the /sandbox/ folder or from a dedicated menu that ParrotSec team plans to improve in the future (meanwhile the search feature of the bottom menu will fit all your needs), or you can re-enable it by default by using the firecfg tool.

New menu structure and tools improvements
   The pentesting menu structure was refactored and re-designed to make tools easier to access in a more logical hierarchical structure. New tools were also added to the project, and ParrotSec team plans to add even more in the future. Not all of them are going to be pre-installed, but a good set of tools in our repository enables pentesters to build up the perfect pentest system for their specific needs, regardless the default package selection picked by ParrotSec team.

Domain changes
   To reflect the neutrality of a distro that started as a pentest-only system and became more general purpose later with Parro Home, the community voted through a democratic process to switch to parrotlinux.org as the new default domain of the project.

   ParrotSec team will still use ParrotSec.org for other things (included the old email addresses), and they introduced other project domains to handle specific parts of the infrastructure.

Repository changes
   ParrotSec team is preparing to integrate a future LTS branch, so they decided to rename the current repository from stable to rolling. Nothing changes for the end user, and the current Parrot Security OS branch will continue to behave the same as before, but now with a different name to better reflect the rolling release nature of the system, waiting for the LTS edition to join the Parrot Security OS family along side the rolling branch in a similar way OpenSUSE does.

New MATE 1.22 release: Parrot Security OS 4.7 ships with the latest MATE 1.22 desktop environment.

Miscellaneous: New Firefox Browser 69, the latest Radare2 and cutter versions and many other important upgrades are all aboard as expected in a properly developed rolling release distro.

How to upgrade to the lastest Parrot Security OS version
   You can update your existing Parrot Security OS system with this command:
sudo parrot-upgrade

   Or use the raw apt command
sudo apt update
sudo apt full-upgrade

   Don't forget to use this command regularly (at least once a week) to receive the latest security updates and bugfixes from the Parrot Security OS repository.

   Or you can download the latest release from official download page.

From Parrot Project Blog

Related links

1. Un Hacker
2. Elladodelmal
3. What Is Growth Hacking
4. Chema Alonso Wikipedia
5. Hardware Hacking
6. Growth Hacking Que Es
7. Hacking Quotes
8. Hacking Ético Curso
9. Hacking Linkedin
10. Herramientas Hacking
11. Travel Hacking
12. Hacking Con Buscadores Pdf
13. Como Aprender A Ser Hacker
14. Hacking Smart Tv

Save Your Cloud: Gain Root Access To VMs In OpenNebula 4.6.1

In this post, we show a proof-of-concept attack that gives us root access to a victim's VM in the Cloud Management Platform OpenNebula, which means that we can read and write all its data, install software, etc. The interesting thing about the attack is, that it allows an attacker to bridge the gap between the cloud's high-level web interface and the low-level shell-access to a virtual machine.

Like the latest blogpost of this series, this is a post about an old CSRF- and XSS-vulnerability that dates back to 2014. However, the interesting part is not the vulnerability itself but rather the exploit that we were able to develop for it.

An attacker needs the following information for a successful attack.

• ID of the VM to attack
  OpenNebula's VM ID is a simple global integer that is increased whenever a VM is instantiated. The attacker may simply guess the ID. Once the attacker can execute JavaScript code in the scope of Sunstone, it is possible to use OpenNebula's API and data structures to retrieve this ID based on the name of the desired VM or its IP address.
• Operating system & bootloader
  There are various ways to get to know a VMs OS, apart from simply guessing. For example, if the VM runs a publicly accessible web server, the OS of the VM could be leaked in the HTTP-Header Server (see RFC 2616). Another option would be to check the images or the template the VM was created from. Usually, the name and description of an image contains information about the installed OS, especially if the image was imported from a marketplace.
  Since most operating systems are shipped with a default bootloader, making a correct guess about a VMs bootloader is feasible. Even if this is not possible, other approaches can be used (see below).
• Keyboard layout of the VM's operating system
  As with the VMs bootloader, making an educated guess about a VM's keyboard layout is not difficult. For example, it is highly likely that VMs in a company's cloud will use the keyboard layout of the country the company is located in.

Overview of the Attack

The key idea of this attack is that neither Sunstone nor noVNC check whether keyboard related events were caused by human input or if they were generated by a script. This can be exploited so that gaining root access to a VM in OpenNebula requires five steps:

1. Using CSRF, a persistent XSS payload is deployed.
2. The XSS payload controls Sunstone's API.
3. The noVNC window of the VM to attack is loaded into an iFrame.
4. The VM is restarted using Sunstone's API.
5. Keystroke-events are simulated in the iFrame to let the bootloader open a root shell.

Figure 1: OpenNebula's Sunstone Interface displaying the terminal of a VM in a noVNC window.

The following sections give detailed information about each step.

Executing Remote Code in Sunstone

In Sunstone, every account can choose a display language. This choice is stored as an account parameter (e.g. for English LANG=en_US). In Sunstone, the value of the LANG parameter is used to construct a <script> tag that loads the corresponding localization script. For English, this creates the following tag:

<script src="locale/en_US/en_US.js?v=4.6.1" type="text/javascript"></script>

Setting the LANG parameter to a different string directly manipulates the path in the script tag. This poses an XSS vulnerability. By setting the LANG parameter to LANG="onerror=alert(1)//, the resulting script tag looks as follows:

<script src="locale/"onerror=alert(1)///"onerror=alert(1)//.js?v=4.6.1" type="text/javascript"></script>

For the web browser, this is a command to fetch the script locale/ from the server. However, this URL points to a folder, not a script. Therefore, what the server returns is no JavaScript. For the browser, this is an error, so the browser executes the JavaScript in the onerror statement: alert(1). The rest of the line (including the second alert(1)) is treated as comment due to the forward slashes.

When a user updates the language setting, the browser sends an XMLHttpRequest of the form

{ "action" : { "perform" : "update", "params" : { "template_raw" : "LANG=\"en_US\"" } }}

to the server (The original request contains more parameters. Since these parameters are irrelevant for the technique, we omitted them for readability.). Forging a request to Sunstone from some other web page via the victim's browser requires a trick since one cannot use an XMLHttpRequest due to restrictions enforced by the browser's Same-Origin-Policy. Nevertheless, using a self-submitting HTML form, the attacker can let the victim's browser issue a POST request that is similar enough to an XMLHttpRequest so that the server accepts it.

An HTML form field like

<input name='deliver' value='attacker' />

is translated to a request in the form of deliver=attacker. To create a request changing the user's language setting to en_US, the HTML form has to look like

<input name='{"action":{"perform":"update","params":{"template_raw":"LANG' value='\"en_US\""}}}' />

Notice that the equals sign in LANG=\"en_US\" is inserted by the browser because of the name=value format.

Figure 2: OpenNebula's Sunstone Interface displaying a user's attributes with the malicious payload in the LANG attribute.

Using this trick, the attacker sets the LANG parameter for the victim's account to "onerror=[remote code]//, where [remote code] is the attacker's exploit code. The attacker can either insert the complete exploit code into this parameter (there is no length limitation) or include code from a server under the attacker's control. Once the user reloads Sunstone, the server delivers HTML code to the client that executes the attacker's exploit.

Prepare Attack on VM

Due to the overwritten language parameter, the victim's browser does not load the localization script that is required for Sunstone to work. Therefore, the attacker achieved code execution, but Sunstone breaks and does not work anymore. For this reason, the attacker needs to set the language back to a working value (e.g. en_US) and reload the page in an iFrame. This way Sunstone is working again in the iFrame, but the attacker can control the iFrame from the outside. In addition, the attack code needs to disable a watchdog timer outside the iFrame that checks whether Sunstone is correctly initialized.

From this point on, the attacker can use the Sunstone API with the privileges of the victim. This way, the attacker can gather all required information like OpenNebula's internal VM ID and the keyboard layout of the VM's operating system from Sunstone's data-structures based on the name or the IP address of the desired VM.

Compromising a VM

Using the Sunstone API the attacker can issue a command to open a VNC connection. However, this command calls window.open, which opens a new browser window that the attacker cannot control. To circumvent this restriction, the attacker can overwrite window.open with a function that creates an iFrame under the attacker's control.

Once the noVNC-iFrame has loaded, the attacker can send keystrokes to the VM using the dispatchEvent function. Keystrokes on character keys can be simulated using keypress events. Keystrokes on special keys (Enter, Tab, etc.) have to be simulated using pairs of keydown and keyup events since noVNC filters keypress events on special keys.

Getting Root Access to VM

To get root access to a VM the attacker can reboot a victim's VM using the Sunstone API and then control the VM's bootloader by interrupting it with keystrokes. Once the attacker can inject commands into the bootloader, it is possible to use recovery options or the single user mode of Linux based operating systems to get a shell with root privileges. The hardest part with this attack is to get the timing right. Usually, one only has a few seconds to interrupt a bootloader. However, if the attacker uses the hard reboot feature, which instantly resets the VM without shutting it down gracefully, the time between the reboot command and the interrupting keystroke can be roughly estimated.

Even if the bootloader is unknown, it is possible to use a try-and-error approach. Since the variety of bootloaders is small, one can try for one particular bootloader and reset the machine if the attack was unsuccessful. Alternatively, one can capture a screenshot of the noVNC canvas of the VM a few seconds after resetting the VM and determine the bootloader.

A video of the attack can be seen here. The browser on the right hand side shows the victim's actions. A second browser on the left hand side shows what is happening in OpenNebula. The console window on the bottom right shows that there is no user-made keyboard input while the attack is happening.