The vulnerable system is bound to the network stack and the set of possible attackers extends beyond the other options listed below, up to and including the entire Internet. Such a vulnerability is often termed “remotely exploitable” and can be thought of as an attack being exploitable at the protocol level one or more network hops away (e.g., across one or more routers). An example of a network attack is an attacker causing a denial of service by sending a specially crafted TCP packet across a wide area network (e.g., CVE-2004-0230).
Attack Complexity
Low
AC
The attacker must take no measurable action to exploit the vulnerability. The attack requires no target-specific circumvention to exploit the vulnerability. An attacker can expect repeatable success against the vulnerable system.
Privileges Required
Low
PR
The attacker requires privileges that provide basic capabilities that are typically limited to settings and resources owned by a single low-privileged user. Alternatively, an attacker with Low privileges has the ability to access only non-sensitive resources.
User Interaction
None
UI
The vulnerable system can be exploited without interaction from any human user, other than the attacker. Examples include: a remote attacker is able to send packets to a target system a locally authenticated attacker executes code to elevate privileges
Scope
Unchanged
S
An exploited vulnerability can only affect resources managed by the same security authority. In the case of a vulnerability in a virtualized environment, an exploited vulnerability in one guest instance would not affect neighboring guest instances.
Confidentiality
High
C
There is total information disclosure, resulting in all data on the system being revealed to the attacker, or there is a possibility of the attacker gaining control over confidential data.
Integrity
High
I
There is a total compromise of system integrity. There is a complete loss of system protection, resulting in the attacker being able to modify any file on the target system.
Availability
High
A
There is a total shutdown of the affected resource. The attacker can deny access to the system or data, potentially causing significant loss to the organization.
Below is a copy: Coldfusion / JNBridge Remote Code Execution
Advisory ID: SYSS-2019-006
Product: Coldfusion/JNBridge
Manufacturer: Adobe/JNBridge LLC
Affected Version(s): Coldfusion 2016,2018, JNBridge all versions
Tested Version(s): 2018
Vulnerability Type: Remote Code Execution
Risk Level: High
Solution Status: Fixed
Manufacturer Notification: 2019-03-27
Solution Date: 2019-06-11
Public Disclosure: 2019-06-24
CVE Reference: CVE-2019-7839
Author of Advisory: Moritz Bechler, SySS GmbH
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Overview:
JNBridge is a technology for integrating Java and .NET application code.
The manufacturer describes the product as follows (see [1]):
"Access Java classes from .NET as if Java were a .NET language
(C#, VB, etc). Access .NET classes (written in C#, VB, F#, etc.)
from Java as if they were Java classes. Access objects and libraries
across the platform boundary."
"Create objects, call methods, access fields, return objects."
As stated, this technology, more or less by design, allows unrestricted
access to a remote Java Runtime Environment, thereby allowing the execution
of arbitrary code and system commands.
Adobe Coldfusion is a web application development platform.
Coldfusion servers running on Windows publicly expose an JNBridge
network listener on TCP port 6093 or 6095.
An attacker that is able to reach that service can execute arbitrary
Java code or system commands. By default this services is running with
highest privileges (SYSTEM).
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Vulnerability Details:
Analysis of the JNBridge protocol reveals that it directly exposes
basic operations like:
* creating Java objects using arbitrary constructors
* calling methods on these objects
* getting/setting fields of these objects
* calling static methods
Combined, these primitives essentially expose all of the Java runtime
environment's available code/methods. For example the sequence
1. objectStaticCall java.lang.Runtime:getRuntime
-> handle to java.lang.Runtime instance
2. objectVirtualCall handle->exec("command")
-> handle to Process
can be used to invoke arbitrary system commands.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Proof of Concept (PoC):
The necessary parts of the protocol to invoke the Runtime.exec() method
like described above were implemented. That code remains unreleased at
this time.
The PoC also reads and shows the command output. Running it against
a default installation of Coldfusion 2018 on Windows 10:
$ ./jnbridge.py -p 6095 192.168.56.101 'whoami'
nt authority\system
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Solution:
Apply the latest ColdFusion security patches, see [5].
Do not expose JNBridge listeners to untrusted parties.
In general, the JNBridge technology/protocol must not be used across
privilege boundaries. It appears unlikely that this technology can be
made reasonably secure, even with major changes to the protocol.
Securing a JNBridge listener seems non-trivial, there does not seem
to be built-in support for authentication and
"JNBridgePro supports secure cross-platform communications using SSL
(secure sockets library). SSL provides message encryption, server
authentication, and message integrity. Currently, client authentication
is not supported."
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Disclosure Timeline:
2019-03-18: Vulnerability discovered
2019-03-27: Vulnerability reported to manufacturer
2019-06-11: Patch released by manufacturer
2019-06-24: Public disclosure of vulnerability
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
References:
[1] Product website for JNBridge
https://jnbridge.com/
[2] Product website for Adobe Coldfusion
https://www.adobe.com/products/coldfusion-family.html
[3] SySS Security Advisory SYSS-2019-006
https://www.syss.de/fileadmin/dokumente/Publikationen/Advisories/SYSS-2019-006.txt
[4] SySS Responsible Disclosure Policy
https://www.syss.de/en/news/responsible-disclosure-policy/
[5] Adobe Security Bulletin APSB19-27
https://helpx.adobe.com/security/products/coldfusion/apsb19-27.html
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Credits:
This security vulnerability was found by Moritz Bechler of SySS GmbH.
E-Mail: [email protected]
Public Key: ://www.syss.de/fileadmin/dokumente/PGPKeys/Moritz_Bechler.asc
Key ID: 0x768EFE2BB3E53DDA
Key Fingerprint: 2C8F F101 9D77 BDE6 465E CCC2 768E FE2B B3E5 3DDA
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Disclaimer:
The information provided in this security advisory is provided "as is"
and without warranty of any kind. Details of this security advisory may
be updated in order to provide as accurate information as possible. The
latest version of this security advisory is available on the SySS Web
site.
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Copyright:
Creative Commons - Attribution (by) - Version 3.0
URL: http://creativecommons.org/licenses/by/3.0/deed.en
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