I wanna write a WAF which detects attacks with signature-based method. for example, for SQL injection, I collect a blacklist contains words such "select", "drop" and etc. when an attacker inputs these strings to query field, then the attack is detected. Now, my question is how to separate these words from valid inputs that a regular user enters (such his username contains "select" word)? (Note that this is a WAF and I don't know what are the fields in the web app to check the best security and write a specific code for every field. I can just check common security and the rest must check by developers of the web app).
There is no use for WAF in regard of SQL injection. Because
There will be too much false positives that will be driving users mad. If such a silly approach were used on this site of Stack Overflow, you were just unable to post your question.
Like any other black-listing based approach it will be always incomplete and thus will not offer 100% protection
There are specific measures to prevent an SQL injection that offer 100% protection
Related
I'm familiar with using templates in NodeJS like EJS to escape data for an HTML context.
However what would be the recommended way to safely output from an API? Given the intended usage is not known, it couldn't be escaped using HTML encoding.
Since I'm currently basically just doing res.json({}) for the output.
I'm thinking while some fields of incoming data can be validated (like 'email'), other fields that are more vague (like 'description') could contain any of the characters someone might use for XSS. Like < and ;. The options on OWASP seem limited https://cheatsheetseries.owasp.org/cheatsheets/Nodejs_Security_Cheat_Sheet.html Like this, but it was last updated 7 years ago https://github.com/ESAPI/node-esapi
Is it up to the recipient to handle? So if someone sends "alert(0);" as their description, I allow it through, as that is a valid JSON {"description":"alert(0);"}
If someone wants to send <script>tweet(document.cookie)</script> in a description let them do so. They may have perfectly valid and legitimate reasons to do that. Perhaps they're writing an article about security and this is just an example of an XSS attack.
This isn't a threat to your database but to your web pages.
Security is neither a server-only nor a client-only job. It's a bit of both and the way you mitigate threats depends on the context.
When writing to a database, it's not XSS you have to worry about but things like SQL injection for example.
XSS is a threat for web applications and the way to mitigate that threat is to properly encode and/or escape any user-controlled input before it gets into the DOM.
I run a landscaping company and have multiple crews. I want to provide each one with a custom URL (like mysite.com/xxxx-xxxx-xxxx) that shows their daily schedule. Going to the page will list the name, address and phone number of 5-10 customers for the day.
Is it safe/wise to use a UUID in a URL for semi-private data?
Depends on how safe you want it to be.
Are the UUIDs used for anything else? If not, they are fine for creating random URLs.
But, browser history would allow anyone using the same machine to find the URLs. Also, unless using https, a network sniffer could easily see the requested URLs and go to the same page.
Another concern is spider bots. Make sure nothing links to those pages, use a robots.txt to prevent indexing the site, but you still might find that some of the pages show up on search engines. It might be better to have the UUID set in a cookie and check that for determining which employee it is, lest your semi-private pages start showing up on google.
Whether or not that schema would work for you, depends on your threat model (as well as some implementation details). Without a concrete threat model, it is not possible to give a definitive answer to your question.
I can, however, give you some ideas about potential issues with the solution, so you can determine if they are relevant for your application. This is not a complete list.
On the implementation side of things:
Not all UUID generators are created equal. Ideally, you want to use a generator based on a cryptographically secure RNG, providing an UUID where every byte is chosen at random.
Using the UUID for a database lookup or similar operation is not necessarily a constant-time operation (and thus there might be side-channel attacks unless you implement the lookup by yourself)
Make sure your URI does not leak via referrer
Some tools attempt to detect 'secret' URLs to protect them from history synchronization or other automatic features. Your schema will most likely not be detected as 'secret'. It might be better to artificially lengthen your URI and to move your UUID into a query parameter.
You can further reduce attack surface with the usual methods (rate limiting, server hardening, etc.)
On the conceptual side of things:
A single identifier for both identification and authentication is not necessarily a bad thing. However, in most cases there is a need for an identification-only identifier – you must not use the 'secret' UUID in those scenarios
If a 'crew' consists of multiple people: you cannot revoke access for a single crew member
Some software (antivirus, browser, etc.) treats information in URLs as public information, and might upload them without user interaction
I am new to Security of Web apps. I am developing an application in Cakephp and one of my friends told me about the Cross-site request forgery (CSRF) and cross-site scripting (XSS) attacks etc. not sure how many more are there.
I need some help in understanding how to make Cakephp defend my web app against these. we are low budget and we cant hire a security consulant as of now. We are still developing the app and plan to release in by the end of the month. so wanna take care of the initial stuff that can help me stand un hacked ;)
There is not (and cannot be) one tool you can deploy and then never have to think about security again. Deploying ‘anti-XSS’ hacks like CakePHP's Sanitize::clean will get in users' way by blocking valid input, whilst still not necessarily making the app secure. Input filtering hacks are at best an obfuscation measure, not a fix for security holes.
To have a secure web application, you must write a secure web application, from the ground up. That means, primarily, attention to detail when you are putting strings from one context into another. In particular:
any time you write a string to HTML text content or attribute value, HTML-escape it (htmlspecialchars()) to avoid HTML-injection leading to XSS. This isn't just a matter of user input that might contain attacks, it's the correct way to put plain text into HTML.
Where you are using HTML helper methods, they should take care of HTML-escaping of those elements by default (unless you turn off escape); it is very unfortunate that the CakePHP tutorial includes the bad practice of echoing unescaped strings into HTML for text outside of HTML helpers.
any time you create SQL queries with string values, SQL-escape it (with an appropriate function for your database such as mysql_real_escape_string).
If you are using CakePHP's ORM and not writing your own SQL you don't have to worry about this.
avoid using user input (eg file upload names) to name files on the filesystem (generate clean unique IDs instead) or as any part of a system() command.
include the Security component to add a form submission token scheme that will prevent XSRF on forms generated by CakePHP.
Cake can be secured relatively easy (compared to self written php scripts):
http://www.dereuromark.de/2010/10/05/cakephp-security/
Watching SO come online has been quite an education for me. I'd like to make a checklist of various vunerabilities and exploits used against web sites, and what programming techniques can be used to defend against them.
What categories of vunerabilities?
crashing site
breaking into server
breaking into other people's logins
spam
sockpuppeting, meatpuppeting
etc...
What kind of defensive programming techniques?
etc...
From the Open Web Application Security Project:
The OWASP Top Ten vulnerabilities (pdf)
For a more painfully exhaustive list: Category:Vulnerability
The top ten are:
Cross-site scripting (XSS)
Injection flaws (SQL injection, script injection)
Malicious file execution
Insecure direct object reference
Cross-site request forgery (XSRF)
Information leakage and improper error handling
Broken authentication and session management
Insecure cryptographic storage
Insecure communications
Failure to restrict URL access
I second the OWASP info as being a valuable resource. The following may be of interest as well, notably the attack patterns:
CERT Top 10 Secure Coding Practices
Common Attack Pattern Enumeration and Classification
Attack Patterns
Secure Programming for Linux and Unix
A Taxonomy of Coding Errors that Affect Security
Secure Programming with Static Analysis Presentation
Obviously test every field for vulnerabilities:
SQL - escape strings (e.g. mysql_real_escape_string)
XSS
HTML being printed from input fields (a good sign of XSS usually)
Anything else thatis not the specific purpose that field was created for
Search for infinite loops (the only indirect thing (if a lot of people found it accidentally) that could kill a server really).
Some prevention techniques:
XSS
If you take any parameters/input from the user and ever plan on outputting it, whether in a log or a web page, sanitize it (strip/escape anything resembling HTML, quotes, javascript...) If you print the current URI of a page within itself, sanitize! Even printing PHP_SELF, for example, is unsafe. Sanitize! Reflective XSS comes mostly from unsanitized page parameters.
If you take any input from the user and save it or print it, warn them if anything dangerous/invalid is detected and have them re-input. an IDS is good for detection (such as PHPIDS.) Then sanitize before storage/printing. Then when you print something from storage/database, sanitize again!
Input -> IDS/sanitize -> store -> sanitize -> output
use a code scanner during development to help spot potentially vulnerable code.
XSRF
Never use GET request for
destructive functionality, i.e.
deleting a post. Instead, only
accept POST requests. GET makes it extra easy for hackery.
Checking the
referrer to make sure the request
came from your site does not
work. It's not hard to spoof the
referrer.
Use a random hash as a token that must be present and valid in every request, and that will expire after a while. Print the token in a hidden form field and check it on the server side when the form is posted. Bad guys would have to supply the correct token in order to forge a request, and if they managed to get the real token, it would need to be before it expired.
SQL injection
your ORM or db abstraction class should have sanitizing methods - use them, always. If you're not using an ORM or db abstraction class... you should be.
SQL injection
XSS (Cross Site Scripting) Attacks
Easy to oversee and easy to fix: the sanitizing of data received from the client side. Checking for things such as ';' can help in preventing malicious code being injected into your application.
G'day,
A good static analysis tool for security is FlawFinder written by David Wheeler. It does a good job looking for various security exploits,
However, it doesn't replace having a knowledgable someone read through your code. As David says on his web page, "A fool with a tool is still a fool!"
HTH.
cheers,
Rob
You can get good firefox addons to test multiple flaws and vulnerabilities like xss and sql injections from Security Compass. Too bad they doesn't work on firefox 3.0. I hope that those will be updated soon.
Closed. This question needs to be more focused. It is not currently accepting answers.
Want to improve this question? Update the question so it focuses on one problem only by editing this post.
Closed 4 years ago.
Improve this question
I'm pretty green still when it comes to web programming, I've spent most of my time on client applications. So I'm curious about the common exploits I should fear/test for in my site.
I'm posting the OWASP Top 2007 abbreviated list here so people don't have to look through to another link and in case the source goes down.
Cross Site Scripting (XSS)
XSS flaws occur whenever an application takes user supplied data and sends it to a web browser without first validating or encoding that content. XSS allows attackers to execute script in the victim's browser which can hijack user sessions, deface web sites, possibly introduce worms, etc.
Injection Flaws
Injection flaws, particularly SQL injection, are common in web applications. Injection occurs when user-supplied data is sent to an interpreter as part of a command or query. The attacker's hostile data tricks the interpreter into executing unintended commands or changing data.
Malicious File Execution
Code vulnerable to remote file inclusion (RFI) allows attackers to include hostile code and data, resulting in devastating attacks, such as total server compromise. Malicious file execution attacks affect PHP, XML and any framework which accepts filenames or files from users.
Insecure Direct Object Reference
A direct object reference occurs when a developer exposes a reference to an internal implementation object, such as a file, directory, database record, or key, as a URL or form parameter. Attackers can manipulate those references to access other objects without authorization.
Cross Site Request Forgery (CSRF)
A CSRF attack forces a logged-on victim's browser to send a pre-authenticated request to a vulnerable web application, which then forces the victim's browser to perform a hostile action to the benefit of the attacker. CSRF can be as powerful as the web application that it attacks.
Information Leakage and Improper Error Handling
Applications can unintentionally leak information about their configuration, internal workings, or violate privacy through a variety of application problems. Attackers use this weakness to steal sensitive data, or conduct more serious attacks.
Broken Authentication and Session Management
Account credentials and session tokens are often not properly protected. Attackers compromise passwords, keys, or authentication tokens to assume other users' identities.
Insecure Cryptographic Storage
Web applications rarely use cryptographic functions properly to protect data and credentials. Attackers use weakly protected data to conduct identity theft and other crimes, such as credit card fraud.
Insecure Communications
Applications frequently fail to encrypt network traffic when it is necessary to protect sensitive communications.
Failure to Restrict URL Access
Frequently, an application only protects sensitive functionality by preventing the display of links or URLs to unauthorized users. Attackers can use this weakness to access and perform unauthorized operations by accessing those URLs directly.
The Open Web Application Security Project
-Adam
OWASP keeps a list of the Top 10 web attacks to watch our for, in addition to a ton of other useful security information for web development.
These three are the most important:
Cross Site Request Forgery
Cross Site Scripting
SQL injection
Everyone's going to say "SQL Injection", because it's the scariest-sounding vulnerability and the easiest one to get your head around. Cross-Site Scripting (XSS) is going to come in second place, because it's also easy to understand. "Poor input validation" isn't a vulnerability, but rather an evaluation of a security best practice.
Let's try this from a different perspective. Here are features that, when implemented in a web application, are likely to mess you up:
Dynamic SQL (for instance, UI query builders). By now, you probably know that the only reliably safe way to use SQL in a web app is to use parameterized queries, where you explicitly bind each parameter in the query to a variable. The places where I see web apps most frequently break this rule is when the malicious input isn't an obvious parameter (like a name), but rather a query attribute. An obvious example are the iTunes-like "Smart Playlist" query builders you see on search sites, where things like where-clause operators are passed directly to the backend. Another great rock to turn over are table column sorts, where you'll see things like DESC exposed in HTTP parameters.
File upload. File upload messes people up because file pathnames look suspiciously like URL pathnames, and because web servers make it easy to implement the "download" part just by aiming URLs at directories on the filesystem. 7 out of 10 upload handlers we test allow attackers to access arbitrary files on the server, because the app developers assumed the same permissions were applied to the filesystem "open()" call as are applied to queries.
Password storage. If your application can mail me back my raw password when I lose it, you fail. There's a single safe reliable answer for password storage, which is bcrypt; if you're using PHP, you probably want PHPpass.
Random number generation. A classic attack on web apps: reset another user's password, and, because the app is using the system's "rand()" function, which is not crypto-strong, the password is predictable. This also applies anywhere you're doing cryptography. Which, by the way, you shouldn't be doing: if you're relying on crypto anywhere, you're very likely vulnerable.
Dynamic output. People put too much faith in input validation. Your chances of scrubbing user inputs of all possible metacharacters, especially in the real world, where metacharacters are necessary parts of user input, are low. A much better approach is to have a consistent regime of filtering database outputs and transforming them into HTML entities, like quot, gt, and lt. Rails will do this for you automatically.
Email. Plenty of applications implement some sort of outbound mail capability that enable an attacker to either create an anonymous account, or use no account at all, to send attacker-controlled email to arbitrary email addresses.
Beyond these features, the #1 mistake you are likely to make in your application is to expose a database row ID somewhere, so that user X can see data for user Y simply by changing a number from "5" to "6".
bool UserCredentialsOK(User user)
{
if (user.Name == "modesty")
return false;
else
// perform other checks
}
SQL INJECTION ATTACKS. They are easy to avoid but all too common.
NEVER EVER EVER EVER (did I mention "ever"?) trust user information passed to you from form elements. If your data is not vetted before being passed into other logical layers of your application, you might as well give the keys to your site to a stranger on the street.
You do not mention what platform you are on but if on ASP.NET get a start with good ol' Scott Guthrie and his article "Tip/Trick: Guard Against SQL Injection Attacks".
After that you need to consider what type of data you will permit users to submit into and eventually out of your database. If you permit HTML to be inserted and then later presented you are wide-open for Cross Site Scripting attacks (known as XSS).
Those are the two that come to mind for me, but our very own Jeff Atwood had a good article at Coding Horror with a review of the book "19 Deadly Sins of Software Security".
Most people here have mentioned SQL Injection and XSS, which is kind of correct, but don't be fooled - the most important things you need to worry about as a web developer is INPUT VALIDATION, which is where XSS and SQL Injection stem from.
For instance, if you have a form field that will only ever accept integers, make sure you're implementing something at both the client-side AND the server-side to sanitise the data.
Check and double check any input data especially if it's going to end up in an SQL query. I suggest building an escaper function and wrap it around anything going into a query. For instance:
$query = "SELECT field1, field2 FROM table1 WHERE field1 = '" . myescapefunc($userinput) . "'";
Likewise, if you're going to display any user-inputted information onto a webpage, make sure you've stripped any <script> tags or anything else that might result in Javascript execution (such as onLoad= onMouseOver= etc. attributes on tags).
This is also a short little presentation on security by one of wordpress's core developers.
Security in wordpress
it covers all of the basic security problems in web apps.
The most common are probably database injection attacks and cross-site scripting attacks; mainly because those are the easiest to accomplish (that's likely because those are the ones programmers are laziest about).
You can see even on this site that the most damaging things you'll be looking after involve code injection into your application, so XSS (Cross Site Scripting) and SQL injection (#Patrick's suggestions) are your biggest concerns.
Basically you're going to want to make sure that if your application allows for a user to inject any code whatsoever, it's regulated and tested to be sure that only things you're sure you want to allow (an html link, image, etc) are passed, and nothing else is executed.
SQL Injection. Cross Site Scripting.
Using stored procedures and/or parameterized queries will go a long way in protecting you from sql injection. Also do NOT have your web app access the database as sa or dbo - set a up a standard user account and set the permissions.
AS for XSS (cross site scripting) ASP.NET has some built in protections. The best thing is to filter input using validation controls and Regex.
I'm no expert, but from what I learned so far the golden rule is not to trust any user data (GET, POST, COOKIE). Common attack types and how to save yourself:
SQL Injection Attack: Use prepared queries
Cross Site Scripting: Send no user data to browser without filtering/escaping first. This also includes user data stored in database, which originally came from users.