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gix-transport indirect code execution via malicious username

Moderate severity GitHub Reviewed Published Apr 13, 2024 in GitoxideLabs/gitoxide • Updated Apr 26, 2024

Package

cargo gitoxide (Rust)

Affected versions

< 0.35

Patched versions

0.35
cargo gix (Rust)
< 0.62
0.62
cargo gix-transport (Rust)
< 0.42.0
0.42.0

Description

Summary

gix-transport does not check the username part of a URL for text that the external ssh program would interpret as an option. A specially crafted clone URL can smuggle options to SSH. The possibilities are syntactically limited, but if a malicious clone URL is used by an application whose current working directory contains a malicious file, arbitrary code execution occurs.

Details

This is related to the patched vulnerability GHSA-rrjw-j4m2-mf34, but appears less severe due to a greater attack complexity. Since GitoxideLabs/gitoxide#1032, gix-transport checks the host and path portions of a URL for text that has a - in a position that will cause ssh to interpret part of all of the URL as an option argument. But it does not check the non-mandatory username portion of the URL.

As in Git, when an address is a URL of the form ssh://username@hostname/path, or when it takes the special form username@hostname:dirs/repo, this is treated as an SSH URL. gix-transport will replace some characters in username with their %-based URL encodings, but otherwise passes username@hostname as an argument to the external ssh command. This happens even if username begins with a hyphen. In that case, ssh treats that argument as an option argument, and attempts to interpret and honor it as a sequence of one or more options possibly followed by an operand for the last option.

This is harder to exploit than GHSA-rrjw-j4m2-mf34, because the possibilities are constrained by:

  • The difficulty of forming an option argument ssh accepts, given that characters such as =, /, and \, are URL-encoded, : is removed, and the argument passed to ssh contains the @ sign and subsequent host identifier, which in an effective attack must be parseable as a suffix of the operand passed to the last option.

    The inability to include a literal = prevents the use of -oNAME=VALUE (e.g., -oProxyCommand=payload). The inability to include a literal / or \ prevents smuggling in a path operand residing outside the current working directory, incuding on Windows. (Although a ~ character may be smuggled in, ssh does not perform its own tilde expansion, so it does not form an absolute path.)

  • The difficulty, or perhaps impossibility, of completing a connection (other than when arbitrary code execution has been achieved). This complicates or altogether prevents the use of options such as -A and -X together with a connection to a real but malicious server. The reason a connection cannot generally be completed when exploiting this vulnerability is that, because the argument gix-transport intends as a URL is treated as an option argument, ssh treats the subsequent non-option argument git-upload-pack as the host instead of the command, but it is not a valid host name.

    Although ssh supports aliases for hosts, even if git-upload-pack could be made an alias, that is made difficult by the URL-encoding transformation.

However, an attacker who is able to cause a specially named ssh configuration file to be placed in the current working directory can smuggle in an -F option referencing the file, and this allows arbitrary command execution.

This scenario is especially plausible because programs that operate on git repositories are often run in untrusted git repositories, sometimes even to operate on another repository. Situations where this is likely, such that an attacker could predict or arrange it, may for some applications include a malicious repository with a malicious submodule configuration.

Other avenues of exploitation exist, but appear to be less severe. For example, the -E option can be smuggled to create or append to a file in the current directory (or its target, if it is a symlink). There may also be other significant ways to exploit this that have not yet been discovered, or that would arise with new options in future versions of ssh.

PoC

To reproduce the known case that facilitates arbitrary code execution, first create a file in the current directory named [email protected], of the form

ProxyCommand payload

where payload is a command with an observable side effect. On Unix-like systems, this could be date | tee vulnerable or an xdg-open, open, or other command command to launch a graphical application. On Windows, this could be the name of a graphical application already in the search path, such as calc.exe.

(Although the syntax permitted in the value of ProxyCommand may vary by platform, this is not limited to running commands in the current directory. That limitation only applies to paths directly smuggled in the username, not to the contents of a separate malicious configuration file. Arbitrary other settings may be specified in [email protected] as well.)

Then run:

gix clone 'ssh://[email protected]/abc'

Or:

gix clone -- '[email protected]:abc/def'

(The -- is required to ensure that gix is really passing the argument as a URL for use in gix-transport, rather than interpreting it as an option itself, which would not necessarily be a vulnerability.)

In either case, the payload specified in [email protected] runs, and its side effect can be observed.

Other cases may likewise be produced, in either of the above two forms of SSH addresses. For example, to create or append to the file [email protected], or to create or append to its target if it is a symlink:

gix clone 'ssh://[email protected]/abc'
gix clone -- '[email protected]:abc/def'

Impact

As in GHSA-rrjw-j4m2-mf34, this would typically require user interaction to trigger an attempt to clone or otherwise connect using the malicious URL. Furthermore, known means of exploiting this vulnerability to execute arbitrary commands require further preparatory steps to establish a specially named file in the current directory. The impact is therefore expected to be lesser, though it is difficult to predict it with certainty because it is not known exactly what scenarios will arise when using the gix-transport library.

Users who use applications that make use of gix-transport are potentially vulnerable, especially:

  • On repositories with submodules that are automatically added, depending how the application manages submodules.
  • When operating on other repositories from inside an untrusted repository.
  • When reviewing contributions from untrusted developers by checking out a branch from an untrusted fork and performing clones from that location.

References

@Byron Byron published to GitoxideLabs/gitoxide Apr 13, 2024
Published to the GitHub Advisory Database Apr 15, 2024
Reviewed Apr 15, 2024
Published by the National Vulnerability Database Apr 26, 2024
Last updated Apr 26, 2024

Severity

Moderate

CVSS overall score

This score calculates overall vulnerability severity from 0 to 10 and is based on the Common Vulnerability Scoring System (CVSS).
/ 10

CVSS v3 base metrics

Attack vector
Network
Attack complexity
High
Privileges required
Low
User interaction
None
Scope
Unchanged
Confidentiality
High
Integrity
Low
Availability
Low

CVSS v3 base metrics

Attack vector: More severe the more the remote (logically and physically) an attacker can be in order to exploit the vulnerability.
Attack complexity: More severe for the least complex attacks.
Privileges required: More severe if no privileges are required.
User interaction: More severe when no user interaction is required.
Scope: More severe when a scope change occurs, e.g. one vulnerable component impacts resources in components beyond its security scope.
Confidentiality: More severe when loss of data confidentiality is highest, measuring the level of data access available to an unauthorized user.
Integrity: More severe when loss of data integrity is the highest, measuring the consequence of data modification possible by an unauthorized user.
Availability: More severe when the loss of impacted component availability is highest.
CVSS:3.1/AV:N/AC:H/PR:L/UI:N/S:U/C:H/I:L/A:L

EPSS score

0.043%
(10th percentile)

CVE ID

CVE-2024-32884

GHSA ID

GHSA-98p4-xjmm-8mfh

Source code

Credits

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