This site is the archived OWASP Foundation Wiki and is no longer accepting Account Requests.
To view the new OWASP Foundation website, please visit https://owasp.org

Difference between revisions of "Testing for IMAP/SMTP Injection (OTG-INPVAL-011)"

From OWASP
Jump to: navigation, search
(References)
 
(17 intermediate revisions by 7 users not shown)
Line 1: Line 1:
[[http://www.owasp.org/index.php/Web_Application_Penetration_Testing_AoC Up]]<br>
+
{{Template:OWASP Testing Guide v4}}
{{Template:OWASP Testing Guide v2}}
+
 
 +
== Summary ==
 +
This threat affects all applications that communicate with mail servers (IMAP/SMTP), generally webmail applications. The aim of this test is to verify the capacity to inject arbitrary IMAP/SMTP commands into the mail servers, due to input data not being properly sanitized.
 +
 
 +
 
 +
The IMAP/SMTP Injection technique is more effective if the mail server is not directly accessible from Internet. Where full communication with the backend mail server is possible, it is recommended to conduct direct testing.
  
== Brief Summary ==
 
This threat affects all those applications that communicate with mail servers (IMAP/SMTP), generally webmail applications. The aim of this test is to verify the capacity to inject arbitrary IMAP/SMTP commands into the mail servers, due to input data not properly sanitized.
 
<br>
 
  
==Description of the Issue==
+
An IMAP/SMTP Injection makes it possible to access a mail server which otherwise would not be directly accessible from the Internet. In some cases, these internal systems do not have the same level of infrastructure security and hardening that is applied to the front-end web servers. Therefore, mail server results may be more vulnerable to attacks by end users (see the scheme presented in Figure 1).
The IMAP/SMTP Injection technique is more effective if the mail server is not directly accessible from Internet. Where full communication with the backend mail server is possible, it is recommended to make a direct testing.
 
  
An IMAP/SMTP Injection makes possible to access a mail server which previously did not have direct access from the Internet. In some cases, these internal systems do not have the same level of infrastructure security hardening applied to the front-end web servers: so the mail server results more exposed to successful attacks by end users (see the scheme presented in Figure 1).
+
<center>[[Image:imap-smtp-injection.png]]<br>
 +
Figure 1 - Communication with the mail servers using the IMAP/SMTP Injection technique.</center><br>
  
<center>[[Image:imap-smtp-injection.png]]
 
  
Figure 1 - Communication with the mail servers using the IMAP/SMTP Injection technique.</center>
+
Figure 1 depicts the flow of traffic generally seen when using webmail technologies. Step 1 and 2 is the user interacting with the webmail client, whereas step 2 is the tester bypassing the webmail client and interacting with the back-end mail servers directly.  
  
Figure 1 depicts the flow control of traffic generally seen when using webmail technologies. Step 1 and 2 is the user interacting with the webmail client, whereas step 2' is the tester bypassing the webmail client and interacting with the back-end mail servers directly.
 
  
 
This technique allows a wide variety of actions and attacks. The possibilities depend on the type and scope of injection and the mail server technology being tested.  
 
This technique allows a wide variety of actions and attacks. The possibilities depend on the type and scope of injection and the mail server technology being tested.  
 +
  
 
Some examples of attacks using the IMAP/SMTP Injection technique are:
 
Some examples of attacks using the IMAP/SMTP Injection technique are:
Line 26: Line 27:
 
* Relay/SPAM
 
* Relay/SPAM
  
== Black Box testing and example ==
+
 
The standard attacks pattern are:
+
== How to Test ==
 +
The standard attack patterns are:
 
* Identifying vulnerable parameters
 
* Identifying vulnerable parameters
 
* Understanding the data flow and deployment structure of the client
 
* Understanding the data flow and deployment structure of the client
 
* IMAP/SMTP command injection
 
* IMAP/SMTP command injection
<br>
 
'''Identifying vulnerable parameters'''
 
----
 
In order to detect vulnerable parameters requires the tester has to analyse the applications ability in handling input. Input validation testing requires the tester to send bogus, or malicious, requests to the server and analyse the response. In a secure developed application, the response should be an error with some corresponding action telling the client something has gone wrong. In a not secure application the malicious request may be processed by the back-end application that will answer with a "HTTP 200 OK" response message.
 
  
It is important to notice that the requests being sent should match the technology being tested. Sending SQL injection strings for Microsoft SQL server when a MySQL server is being used will result in false positive responses. In this case, sending malicious IMAP commands is modus operandi since IMAP is the underlying protocol being tested.   
+
 
 +
===Identifying vulnerable parameters===
 +
In order to detect vulnerable parameters, the tester has to analyze the application's ability in handling input. Input validation testing requires the tester to send bogus, or malicious, requests to the server and analyse the response. In a secure application, the response should be an error with some corresponding action telling the client that something has gone wrong. In a vulnerable application, the malicious request may be processed by the back-end application that will answer with a "HTTP 200 OK" response message.
 +
 
 +
 
 +
It is important to note that the requests being sent should match the technology being tested. Sending SQL injection strings for Microsoft SQL server when a MySQL server is being used will result in false positive responses. In this case, sending malicious IMAP commands is modus operandi since IMAP is the underlying protocol being tested.   
 +
 
  
 
IMAP special parameters that should be used are:
 
IMAP special parameters that should be used are:
Line 57: Line 61:
  
 
   
 
   
In this testing example, the "mailbox" parameter is being tested by manipulating all requests with the parameter in:
+
In this example, the "mailbox" parameter is being tested by manipulating all requests with the parameter in:
 
<pre>
 
<pre>
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46106&startMessage=1
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46106&startMessage=1
 
</pre>
 
</pre>
 +
 +
 
The following examples can be used.
 
The following examples can be used.
* Left the parameter with a null value:<br>
+
* Assign a null value to the parameter:<br>
 
<pre>
 
<pre>
 
http://<webmail>/src/read_body.php?mailbox=&passed_id=46106&startMessage=1
 
http://<webmail>/src/read_body.php?mailbox=&passed_id=46106&startMessage=1
Line 82: Line 88:
 
http://<webmail>/src/read_body.php?passed_id=46106&startMessage=1
 
http://<webmail>/src/read_body.php?passed_id=46106&startMessage=1
 
</pre>
 
</pre>
 +
  
 
The final result of the above testing gives the tester three possible situations: <br>
 
The final result of the above testing gives the tester three possible situations: <br>
Line 88: Line 95:
 
S3 - The application does not return an error code/message and realizes the operation requested normally <br>
 
S3 - The application does not return an error code/message and realizes the operation requested normally <br>
  
Situations S1 and S2 represent sucessful IMAP/SMTP injection.
 
  
An attacker's aim is receiving the S1 response as its an indicator that the application is vulnerable to injection and further manipulation.
+
Situations S1 and S2 represent successful IMAP/SMTP injection.
 +
 
 +
An attacker's aim is receiving the S1 response, as it is an indicator that the application is vulnerable to injection and further manipulation.
  
Let's suppose that a user visualizes the email headers across the following HTTP request:
+
Let's suppose that a user retrieves the email headers using the following HTTP request:
 
<pre>
 
<pre>
 
http://<webmail>/src/view_header.php?mailbox=INBOX&passed_id=46105&passed_ent_id=0
 
http://<webmail>/src/view_header.php?mailbox=INBOX&passed_id=46105&passed_ent_id=0
 
</pre>
 
</pre>
 +
  
 
An attacker might modify the value of the parameter INBOX by injecting the character " (%22 using URL encoding):
 
An attacker might modify the value of the parameter INBOX by injecting the character " (%22 using URL encoding):
Line 102: Line 111:
 
</pre>
 
</pre>
  
In this case the application answer will be:
+
 
 +
In this case, the application answer may be:
 
<pre>
 
<pre>
 
ERROR: Bad or malformed request.
 
ERROR: Bad or malformed request.
Line 109: Line 119:
 
</pre>
 
</pre>
  
S2 is a harder testing technique to sucessfully execute. The tester needs to use blind command injection in order to determine if the server is vulnerable.
 
  
On the other hand, the last scene (S3) does not have relevancy in this paragraph.
+
The situation S2 is harder to test successfully. The tester needs to use blind command injection in order to determine if the server is vulnerable.
 +
 
 +
 
 +
On the other hand, the last situation (S3) is not revelant in this paragraph.
 
<br><br>
 
<br><br>
 
'''Result Expected:'''<br>
 
'''Result Expected:'''<br>
Line 118: Line 130:
 
* Type of possible injection (IMAP/SMTP)  
 
* Type of possible injection (IMAP/SMTP)  
 
<br>
 
<br>
'''Understanding the data flow and deployment structure of the client'''
 
----
 
After having identifying all vulnerable parameters (for example, "passed_id"), the tester needs to determine what level of injection is possible and then draw up a testing plan to further exploit the application.
 
  
 +
===Understanding the data flow and deployment structure of the client===
  
In this test case, we have detected that the application's "passed_id" is vulnerable and used in the following request:
+
After identifying all vulnerable parameters (for example, "passed_id"), the tester needs to determine what level of injection is possible and then design a testing plan to further exploit the application.
 +
 
 +
 
 +
In this test case, we have detected that the application's "passed_id" parameter is vulnerable and is used in the following request:
 
<pre>
 
<pre>
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46225&startMessage=1
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46225&startMessage=1
 
</pre>
 
</pre>
  
Using the following test case (to use an alphabetical value when a numerical value is required):
+
 
 +
Using the following test case (providing an alphabetical value when a numerical value is required):
 
<pre>
 
<pre>
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=test&startMessage=1
 
http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=test&startMessage=1
Line 140: Line 154:
 
</pre>
 
</pre>
  
In the previous example, the other error message returned the name of the executed command and the associate parameters.
 
  
In other situations, the error message ("not controlled" by the application) contains the name of the executed command, but reading the suitable RFC (see "Reference" paragraph) allows the tester understand what other possible commands can be executed.
+
In this example, the error message returned the name of the executed command and the corresponding parameters.
 +
 
 +
 
 +
In other situations, the error message ("not controlled" by the application) contains the name of the executed command, but reading the suitable RFC (see "Reference" paragraph) allows the tester to understand what other possible commands can be executed.
 +
 
  
If the application does not return descriptive error messages, the tester needs to analyze the affected functionality to understand possible deduce all possible commands (and parameters) associated with the above mentioned functionality. For example, if the detection of the vulnerable parameter has been realized trying to create a mailbox, it turns out logical to think that the IMAP command affected will be "CREATE" and, according to the RFC, it contains a only parameter which value corresponds to the mailbox name that is expected to create.
+
If the application does not return descriptive error messages, the tester needs to analyze the affected functionality to deduce all the possible commands (and parameters) associated with the above mentioned functionality. For example, if a vulnerable parameter has been detected in the create mailbox functionality, it is logical to assume that the affected IMAP command is "CREATE". According to the RFC, the CREATE command accepts one parameter which specifies the name of the mailbox to create.
 
<br><br>
 
<br><br>
 
'''Result Expected:'''<br>
 
'''Result Expected:'''<br>
 
* List of IMAP/SMTP commands affected  
 
* List of IMAP/SMTP commands affected  
* Type, value and number of parameters waited by the affected IMAP/SMTP commands
+
* Type, value, and number of parameters expected by the affected IMAP/SMTP commands
 
<br>
 
<br>
'''IMAP/SMTP command injection'''
+
 
----
+
===IMAP/SMTP command injection===
Once the tester has identified vulnerable parameters and has analyzed the context in which it is executed, the next stage is exploiting the functionality.
+
 
 +
Once the tester has identified vulnerable parameters and has analyzed the context in which they are executed, the next stage is exploiting the functionality.
 +
 
  
 
This stage has two possible outcomes:<br>
 
This stage has two possible outcomes:<br>
1. The injection is possible in an unauthenticated state: the affected functionality does not require the user to be authenticated. The injected (IMAP) commands available are limited to: CAPABILITY, NOOP, AUTHENTICATE, LOGIN and LOGOUT.<br>  
+
1. The injection is possible in an unauthenticated state: the affected functionality does not require the user to be authenticated. The injected (IMAP) commands available are limited to: CAPABILITY, NOOP, AUTHENTICATE, LOGIN, and LOGOUT.<br>  
2. The injection is only possible in an authenticated state: the sucessful exploitation requires the user to be fully authentication before testing can continue
+
2. The injection is only possible in an authenticated state: the successful exploitation requires the user to be fully authenticated before testing can continue.
 +
 
  
 
In any case, the typical structure of an IMAP/SMTP Injection is as follows:
 
In any case, the typical structure of an IMAP/SMTP Injection is as follows:
Line 163: Line 183:
 
* Footer: beginning of the expected command.
 
* Footer: beginning of the expected command.
  
It is important to state that in order to execute the IMAP/SMTP command, the previous one must have finished with the CRLF (%0d%0a) sequence.  
+
 
Let's suppose that in the stage 1 ("Identifying vulnerable parameters"), the attacker detects the parameter "message_id" of the following request as a vulnerable parameter:
+
It is important to remember that, in order to execute an IMAP/SMTP command, the previous command must be terminated with the CRLF (%0d%0a) sequence.  
 +
 
 +
 
 +
Let's suppose that in the stage 1 ("Identifying vulnerable parameters"), the attacker detects that the parameter "message_id" in the following request is vulnerable:
 
<pre>
 
<pre>
 
http://<webmail>/read_email.php?message_id=4791
 
http://<webmail>/read_email.php?message_id=4791
 
</pre>
 
</pre>
  
Let's suppose also that the outcome of the analysis performed in the stage 2 ("Understanding the data flow and deployment structure of the client
+
 
") has identified the command and arguments associated with this parameter:
+
Let's suppose also that the outcome of the analysis performed in the stage 2 ("Understanding the data flow and deployment structure of the client") has identified the command and arguments associated with this parameter as:
 
<pre>
 
<pre>
 
FETCH 4791 BODY[HEADER]
 
FETCH 4791 BODY[HEADER]
 
</pre>
 
</pre>
  
In this scene, the IMAP injection structure would be:
+
 
 +
In this scenario, the IMAP injection structure would be:
 
<pre>
 
<pre>
 
http://<webmail>/read_email.php?message_id=4791 BODY[HEADER]%0d%0aV100 CAPABILITY%0d%0aV101 FETCH 4791
 
http://<webmail>/read_email.php?message_id=4791 BODY[HEADER]%0d%0aV100 CAPABILITY%0d%0aV101 FETCH 4791
 
</pre>
 
</pre>
 +
  
 
Which would generate the following commands:
 
Which would generate the following commands:
Line 194: Line 219:
 
</pre>
 
</pre>
 
<br>
 
<br>
 +
 
'''Result Expected:'''<br>
 
'''Result Expected:'''<br>
 
* Arbitrary IMAP/SMTP command injection
 
* Arbitrary IMAP/SMTP command injection
 
<br>
 
<br>
 
  
 
== References ==
 
== References ==
Line 204: Line 229:
 
* RFC 3501 “Internet Message Access Protocol - Version 4rev1”.
 
* RFC 3501 “Internet Message Access Protocol - Version 4rev1”.
 
* Vicente Aguilera Díaz: “MX Injection: Capturing and Exploiting Hidden Mail Servers" - <u>http://www.webappsec.org/projects/articles/121106.pdf</u>
 
* Vicente Aguilera Díaz: “MX Injection: Capturing and Exploiting Hidden Mail Servers" - <u>http://www.webappsec.org/projects/articles/121106.pdf</u>
 
 
{{Category:OWASP Testing Project AoC}}
 

Latest revision as of 12:04, 8 August 2014

This article is part of the new OWASP Testing Guide v4.
Back to the OWASP Testing Guide v4 ToC: https://www.owasp.org/index.php/OWASP_Testing_Guide_v4_Table_of_Contents Back to the OWASP Testing Guide Project: https://www.owasp.org/index.php/OWASP_Testing_Project

Summary

This threat affects all applications that communicate with mail servers (IMAP/SMTP), generally webmail applications. The aim of this test is to verify the capacity to inject arbitrary IMAP/SMTP commands into the mail servers, due to input data not being properly sanitized.


The IMAP/SMTP Injection technique is more effective if the mail server is not directly accessible from Internet. Where full communication with the backend mail server is possible, it is recommended to conduct direct testing.


An IMAP/SMTP Injection makes it possible to access a mail server which otherwise would not be directly accessible from the Internet. In some cases, these internal systems do not have the same level of infrastructure security and hardening that is applied to the front-end web servers. Therefore, mail server results may be more vulnerable to attacks by end users (see the scheme presented in Figure 1).

Imap-smtp-injection.png
Figure 1 - Communication with the mail servers using the IMAP/SMTP Injection technique.


Figure 1 depicts the flow of traffic generally seen when using webmail technologies. Step 1 and 2 is the user interacting with the webmail client, whereas step 2 is the tester bypassing the webmail client and interacting with the back-end mail servers directly.


This technique allows a wide variety of actions and attacks. The possibilities depend on the type and scope of injection and the mail server technology being tested.


Some examples of attacks using the IMAP/SMTP Injection technique are:

  • Exploitation of vulnerabilities in the IMAP/SMTP protocol
  • Application restrictions evasion
  • Anti-automation process evasion
  • Information leaks
  • Relay/SPAM


How to Test

The standard attack patterns are:

  • Identifying vulnerable parameters
  • Understanding the data flow and deployment structure of the client
  • IMAP/SMTP command injection


Identifying vulnerable parameters

In order to detect vulnerable parameters, the tester has to analyze the application's ability in handling input. Input validation testing requires the tester to send bogus, or malicious, requests to the server and analyse the response. In a secure application, the response should be an error with some corresponding action telling the client that something has gone wrong. In a vulnerable application, the malicious request may be processed by the back-end application that will answer with a "HTTP 200 OK" response message.


It is important to note that the requests being sent should match the technology being tested. Sending SQL injection strings for Microsoft SQL server when a MySQL server is being used will result in false positive responses. In this case, sending malicious IMAP commands is modus operandi since IMAP is the underlying protocol being tested.


IMAP special parameters that should be used are:

On the IMAP server On the SMTP server
Authentication Emissor e-mail
operations with mail boxes (list, read, create, delete, rename) Destination e-mail
operations with messages (read, copy, move, delete) Subject
Disconnection Message body
Attached files


In this example, the "mailbox" parameter is being tested by manipulating all requests with the parameter in:

http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46106&startMessage=1


The following examples can be used.

  • Assign a null value to the parameter:
http://<webmail>/src/read_body.php?mailbox=&passed_id=46106&startMessage=1
  • Substitute the value with a random value:
http://<webmail>/src/read_body.php?mailbox=NOTEXIST&passed_id=46106&startMessage=1
  • Add other values to the parameter:
http://<webmail>/src/read_body.php?mailbox=INBOX PARAMETER2&passed_id=46106&startMessage=1
  • Add non standard special characters (i.e.: \, ', ", @, #, !, |):
http://<webmail>/src/read_body.php?mailbox=INBOX"&passed_id=46106&startMessage=1
  • Eliminate the parameter:
http://<webmail>/src/read_body.php?passed_id=46106&startMessage=1


The final result of the above testing gives the tester three possible situations:
S1 - The application returns a error code/message
S2 - The application does not return an error code/message, but it does not realize the requested operation
S3 - The application does not return an error code/message and realizes the operation requested normally


Situations S1 and S2 represent successful IMAP/SMTP injection.

An attacker's aim is receiving the S1 response, as it is an indicator that the application is vulnerable to injection and further manipulation.

Let's suppose that a user retrieves the email headers using the following HTTP request:

http://<webmail>/src/view_header.php?mailbox=INBOX&passed_id=46105&passed_ent_id=0


An attacker might modify the value of the parameter INBOX by injecting the character " (%22 using URL encoding):

http://<webmail>/src/view_header.php?mailbox=INBOX%22&passed_id=46105&passed_ent_id=0


In this case, the application answer may be:

ERROR: Bad or malformed request.
Query: SELECT "INBOX""
Server responded: Unexpected extra arguments to Select


The situation S2 is harder to test successfully. The tester needs to use blind command injection in order to determine if the server is vulnerable.


On the other hand, the last situation (S3) is not revelant in this paragraph.

Result Expected:

  • List of vulnerable parameters
  • Affected functionality
  • Type of possible injection (IMAP/SMTP)


Understanding the data flow and deployment structure of the client

After identifying all vulnerable parameters (for example, "passed_id"), the tester needs to determine what level of injection is possible and then design a testing plan to further exploit the application.


In this test case, we have detected that the application's "passed_id" parameter is vulnerable and is used in the following request:

http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=46225&startMessage=1


Using the following test case (providing an alphabetical value when a numerical value is required):

http://<webmail>/src/read_body.php?mailbox=INBOX&passed_id=test&startMessage=1

will generate the following error message:

ERROR : Bad or malformed request.
Query: FETCH test:test BODY[HEADER]
Server responded: Error in IMAP command received by server.


In this example, the error message returned the name of the executed command and the corresponding parameters.


In other situations, the error message ("not controlled" by the application) contains the name of the executed command, but reading the suitable RFC (see "Reference" paragraph) allows the tester to understand what other possible commands can be executed.


If the application does not return descriptive error messages, the tester needs to analyze the affected functionality to deduce all the possible commands (and parameters) associated with the above mentioned functionality. For example, if a vulnerable parameter has been detected in the create mailbox functionality, it is logical to assume that the affected IMAP command is "CREATE". According to the RFC, the CREATE command accepts one parameter which specifies the name of the mailbox to create.

Result Expected:

  • List of IMAP/SMTP commands affected
  • Type, value, and number of parameters expected by the affected IMAP/SMTP commands


IMAP/SMTP command injection

Once the tester has identified vulnerable parameters and has analyzed the context in which they are executed, the next stage is exploiting the functionality.


This stage has two possible outcomes:
1. The injection is possible in an unauthenticated state: the affected functionality does not require the user to be authenticated. The injected (IMAP) commands available are limited to: CAPABILITY, NOOP, AUTHENTICATE, LOGIN, and LOGOUT.
2. The injection is only possible in an authenticated state: the successful exploitation requires the user to be fully authenticated before testing can continue.


In any case, the typical structure of an IMAP/SMTP Injection is as follows:

  • Header: ending of the expected command;
  • Body: injection of the new command;
  • Footer: beginning of the expected command.


It is important to remember that, in order to execute an IMAP/SMTP command, the previous command must be terminated with the CRLF (%0d%0a) sequence.


Let's suppose that in the stage 1 ("Identifying vulnerable parameters"), the attacker detects that the parameter "message_id" in the following request is vulnerable:

http://<webmail>/read_email.php?message_id=4791


Let's suppose also that the outcome of the analysis performed in the stage 2 ("Understanding the data flow and deployment structure of the client") has identified the command and arguments associated with this parameter as:

FETCH 4791 BODY[HEADER]


In this scenario, the IMAP injection structure would be:

http://<webmail>/read_email.php?message_id=4791 BODY[HEADER]%0d%0aV100 CAPABILITY%0d%0aV101 FETCH 4791


Which would generate the following commands:

???? FETCH 4791 BODY[HEADER]
V100 CAPABILITY
V101 FETCH 4791 BODY[HEADER]

where:

Header = 4791 BODY[HEADER]
Body   = %0d%0aV100 CAPABILITY%0d%0a
Footer = V101 FETCH 4791 


Result Expected:

  • Arbitrary IMAP/SMTP command injection


References

Whitepapers