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Difference between revisions of "Unsafe function call from a signal handler"

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[[ASDR Table of Contents]]
 
  
 
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See ''Race condition in signal handler'', for an example usage of free() in a signal handler which is exploitable.
 
See ''Race condition in signal handler'', for an example usage of free() in a signal handler which is exploitable.
 
 
==Related [[Attacks]]==
 
 
* [[Attack 1]]
 
* [[Attack 2]]
 
 
 
==Related [[Vulnerabilities]]==
 
 
* [[Race conditions]]
 
* [[Write-what-where condition]]
 
  
 
==Related [[Controls]]==
 
==Related [[Controls]]==
  
* Requirements specification: A language might be chosen, which is not subject to this flaw, through a guarantee of reentrant code.
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* Requirements specification: A language might be chosen which is not subject to this flaw, through a guarantee of reentrant code.
 
* Design: Design signal handlers to only set flags rather than perform complex functionality.
 
* Design: Design signal handlers to only set flags rather than perform complex functionality.
* Implementation: Ensure that non-reentrant functions are not found in signal handlers. Also, use sanity checks to ensure that state is consistently performing asynchronous actions which effect the state of execution.  
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* Implementation: Ensure that non-reentrant functions are not found in signal handlers. Also, use sanity checks to ensure that state is consistently performing asynchronous actions which effect the state of execution.
 
 
 
 
==Related [[Technical Impacts]]==
 
 
 
* [[Technical Impact 1]]
 
* [[Technical Impact 2]]
 
 
 
 
 
==References==
 
 
 
TBD
 
[[Category:FIXME|add links
 
 
 
In addition, one should classify vulnerability based on the following subcategories: Ex:<nowiki>[[Category:Error Handling Vulnerability]]</nowiki>
 
 
 
Availability Vulnerability
 
 
 
Authorization Vulnerability
 
 
 
Authentication Vulnerability
 
 
 
Concurrency Vulnerability
 
 
 
Configuration Vulnerability
 
 
 
Cryptographic Vulnerability
 
 
 
Encoding Vulnerability
 
 
 
Error Handling Vulnerability
 
 
 
Input Validation Vulnerability
 
 
 
Logging and Auditing Vulnerability
 
 
 
Session Management Vulnerability]]
 
  
 
__NOTOC__
 
__NOTOC__
  
 
[[Category:OWASP ASDR Project]]
 
[[Category:Use of Dangerous API]]
 
[[Category:Synchronization and Timing Vulnerability]]
 
[[Category:OWASP_CLASP_Project]]
 
 
[[Category:Vulnerability]]
 
[[Category:Vulnerability]]

Latest revision as of 21:39, 28 July 2016

This is a Vulnerability. To view all vulnerabilities, please see the Vulnerability Category page.


Last revision (mm/dd/yy): 07/28/2016

Description

There are several functions which - under certain circumstances, if used in a signal handler - may result in the corruption of memory, allowing for exploitation of the process.

Consequences

  • Access control: It may be possible to execute arbitrary code through the use of a write-what-where condition.
  • Integrity: Signal race conditions often result in data corruption.

Exposure period

  • Requirements specification: A language might be chosen which is not subject to this flaw.
  • Design: Signal handlers with complicated functionality may result in this issue.
  • Implementation: The use of any number of non-reentrant functions will result in this issue.

Platform

  • Languages: C, C++, Assembly
  • Platforms: All

Required resources

Any

Severity

High

Likelihood of exploit

Low

This flaw is a subset of race conditions occurring in signal handler calls which is concerned primarily with memory corruption caused by calls to non-reentrant functions in signal handlers.

Non-reentrant functions are functions that cannot safely be called, interrupted, and then recalled before the first call has finished without resulting in memory corruption. The function call syslog() is an example of this. In order to perform its functionality, it allocates a small amount of memory as "scratch space." If syslog() is suspended by a signal call and the signal handler calls syslog(), the memory used by both of these functions enters an undefined, and possibly, exploitable state.


Risk Factors

  • Talk about the factors that make this vulnerability likely or unlikely to actually happen
  • Discuss the technical impact of a successful exploit of this vulnerability
  • Consider the likely [business impacts] of a successful attack


Examples

See Race condition in signal handler, for an example usage of free() in a signal handler which is exploitable.

Related Controls

  • Requirements specification: A language might be chosen which is not subject to this flaw, through a guarantee of reentrant code.
  • Design: Design signal handlers to only set flags rather than perform complex functionality.
  • Implementation: Ensure that non-reentrant functions are not found in signal handlers. Also, use sanity checks to ensure that state is consistently performing asynchronous actions which effect the state of execution.