Published: 04 November 2016 at 10:00 UTC
Updated: 16 August 2022 at 09:25 UTC
Existing web scanners search for server-side injection vulnerabilities by throwing a canned list of technology-specific payloads at a target and looking for signatures - almost like an anti-virus. In this document, I'll share the conception and development of an alternative approach, capable of finding and confirming both known and unknown classes of injection vulnerabilities. Evolved from classic manual techniques, this approach reaps many of the benefits of manual testing including casual WAF evasion, a tiny network footprint, and flexibility in the face of input filtering.
True to its heritage, this approach also manages to harness some pitfalls that will be all too familiar to experienced manual testers. I'll share some of the more entertaining findings and lessons learned from unleashing this prototype on a few thousand sites, and release a purpose-built stealthy-scanning toolkit. Finally, I'll show how it can be taken far beyond injection hunting, leaving you with numerous leads for future research.
Outside marketing brochures, web application scanners are widely regarded as only being fit for identifying 'low-hanging fruit' - vulnerabilities that are obvious and easily found by just about anyone. This is often a fair judgement; in comparison with manual testers, automated scanners' reliance on canned technology-specific payloads and innate lack of adaptability means even the most advanced scanners can fail to identify vulnerabilities obvious to a human. In some cases it's unfair - scanners are increasingly good at detecting client-side issues like Cross-Site Scripting, even identifying DOM-based XSS using both static and dynamic analysis. However, black-box scanners lack insight into what's happening server-side, so they typically have a harder time with detection of server-side injection vulnerabilities like SQL injection, Code Injection, and OS Command Injection.
In this paper, I'll break down the three core blind spots in scanners' detection of server-side injection vulnerabilities, then show that by implementing an approach to scanning evolved from classic manual techniques, I was able to develop an open-source scanner capable of detecting research-grade vulnerabilities far above low-hanging fruit. In particular, I will show that this scanner could have found Server-Side Template Injection (SSTI) vulnerabilities prior to the vulnerability class being discovered.
This scanner can be installed as a Burp Suite extension via the BApp store, and the source is available on Github: Backslash Powered Scanner, Distribute Damage.
Security through obscurity works against scanners. As an illustration, I'll look at SSTI, a vulnerability that arises when an application unsafely embeds user input into a template. Depending on the template engine in use, it may be possible to exploit this to gain arbitrary code execution and complete control of the server. In order for a scanner to detect this vulnerability, it needs to be hard coded with a payload for each template engine. If your application is using a popular template engine like FreeMarker or Jinja, that's fine. But how many of the following template engines does your scanner support?
Amber, Apache Velocity, action4JAVA, ASP.NET (Microsoft), ASP.NET (Mono), AutoGen, Beard, Blade, Blitz, Casper, CheetahTemplate, Chip Template Engine, Chunk Templates, CL-EMB, CodeCharge Studio, ColdFusion, Cottle, csharptemplates, CTPP, dbPager, Dermis, Django, DTL::Fast (port of Django templates), Djolt-objc, Dwoo, Dylan Server Pages, ECT, eRuby, FigDice, FreeMarker, Genshi (templating language), Go templates, Google-ctemplate, Grantlee Template System, GvTags, H2o, HAH, Haml, Hamlets, Handlebars, Hyperkit PHP/XML Template Engine, Histone template Engine, HTML-TEMPLATE, HTTL, Jade, JavaServer Pages, jin-template, Jinja, Jinja2, JScore, Kalahari, Kid (templating language), Liquid, Lofn, Lucee, Mako, Mars-Templater, MiniTemplator, mTemplate, Mustache, nTPL, Open Power Template, Obyx, Pebble, Outline, pHAML, PHP, PURE Unobtrusive Rendering Engine, pyratemp, QueryTemplates, RainTPL, Razor, Rythm, Scalate, Scurvy, Simphple, Smarty, StampTE, StringTemplate, SUIT Framework, Template Attribute Language, Twital, Template Blocks, Template Toolkit, Thymeleaf, TinyButStrong, Tonic, Toupl, Twig, Twirl, uBook Template, vlibTemplate, WebMacro, ZeniTPL, BabaJS, Rage, PlannerFw, Fenom
This list only includes the template engines well known enough to be recorded on Wikipedia. Michael Stepankin recently found a remote code execution vulnerability in Paypal stemming from SSTI in Dust.js, a templating engine by LinkedIn conspicuously missing from the above list. Lack of scanner coverage applies equally to anyone using the myriad obscure database languages out there, not to mention frameworks that distort code injection beyond comprehension.
Furthermore, scanners are forced to make assumptions about backend technology stacks, which means changes to one server-side component can break the detection of unrelated vulnerabilities. For example, running a webapp under SELinux can prevent detection of Local File Include and External Entity Include vulnerabilities, since these are typically detected by reading the contents of /etc/passwd, an action SELinux may block.
If this wasn't the case, scanner vendors would be regularly releasing juicy vulnerabilities like SSTI, rather than them going unnoticed for years. Applications with obscure vulnerabilities are absolutely being scanned - during the early stages of my SSTI research when the issue was unpublished, a client of ours informed us that Burp Suite was reporting a false-positive XSS vulnerability on their site. When I investigated the site myself it quickly became apparent the 'false positive' was caused by a significantly more serious SSTI vulnerability.
Ultimately, scanners have seriously degraded performance on applications using the long tail of obscure technologies.
Consider a classic vulnerability in a well known language: blind code injection in PHP, inside a double-quoted string. A scanner can easily detect this by sending a payload to induce a time-delay:
".sleep(10)."
So far so good. But if the application happens to filter out parenthesis, we'll get a false negative although the application could still be exploited using
".`sleep 10`."
And if there's a Web Application Firewall (WAF) looking for payloads containing the word 'sleep', we'll almost certainly get a false negative again. Provided the application is normalising input, we can probably still exploit it by using the Cyrillic 'ะต' character in the hope that it gets normalised into 'e':
".sl%D0%B5ep(10)."
And if the application is filtering double-quotes? Once again, we'll get a false negative, when the application is still easily exploitable:
{${sleep(10)}}
Of these three examples, I've encountered two personally during pentests and seen the third in a writeup by someone else.
The design of scanners makes them easily thwarted by unexpected filters and variations. Scanners could of course send the variant payloads shown above, but those only cover three of numerous possible variations of a single vulnerability. Sending sufficient payloads to cover every variation of every vulnerability is fundamentally implausible at today's network speeds - the Million Payload Problem. Scanners are limited to sending 'best-effort' payloads, which means even something as basic as using double quotes instead of single quotes to encapsulate SQL statements can annihilate a scanner's detection capabilities.
Given the following HTTP request to an endpoint on Ebay that used to be vulnerable to PHP injection, where should a scanner try injecting its payloads?
GET /search/?q=david HTTP/1.1
Host: sea.ebay.com.sg
User-Agent: Mozilla/5.0 etc Firefox/49.0
Accept: text/html
Accept-Language: en-US,en;q=0.5
Accept-Encoding: gzip, deflate
Referer: http://sea.ebay.com.sg/
Cookie: session=pZGFjciI6IjAkLCJlx2V4cCI6MTA4
Connection: close
The obvious place to inject is the 'q' parameter, but that doesn't work. Neither does the Referer, User-Agent, or session cookie. An experienced pentester might think to try injecting in some headers that aren't present, like Origin, X-Forwarded-For, or X-Forwarded Host. In this case, none of these would work either. By the time a scanner reaches this point, it's sent an awful lot of payloads without success. David Vieira-Kurz found it was possible to exploit this endpoint by passing a second q parameter, creating a malicious array server-side:
GET /search/?q=david&q[1]=sec{${phpinfo()}}
He tried this attack because the q parameter causes a search that has a spellchecker, and also filters out certain keywords, which provided a clue that something interesting was happening server-side. Here we once again have a vulnerability that a scanner could detect only if it had no constraints on the number of payloads it could send to each endpoint (or, arguably, detected spellcheckers). This example is an extreme case, but vulnerabilities in other rarely-useful inputs like the Accept-Language header are also likely to be missed.
At this point you know how to make an application more or less scanner-proof; just code it with an obscure web language, store data with a niche NoSQL variant with non-standard syntax, and layer a couple of WAFs on top for good measure. How is it that manual testers avoid these blind spots? The fundamental difference is their concept of boring inputs, and interesting, suspicious or promising inputs. David Vieira-Kurz's observation that an input had a spellchecker directly lead to him subjecting it to extensive auditing that would be a waste of time on your typical input.
We can learn from this. Rather than scanning for vulnerabilities, we need to scan for interesting behaviour. Then, having identified the tiny fraction of inputs that yield interesting behaviour, we can investigate further. This iterative approach to identifying vulnerabilities is both extremely flexible in what it can identify, and highly efficient. An input that doesn't yield any interesting results can be quickly discounted, saving time for sustained investigation of inputs that look more promising. The development of a scanner that uses this technique can also be approached in successive stages, as expressed in the following positive feedback cycle:
The initial probe used to identify suspicious behaviour should be as simple and generic as possible. Take the following payload which exploits FreeMarker SSTI:
<#assign ex="freemarker.template.utility.Execute"?new()> ${ex("id")}
We can easily roll this back to a more generic payload that will identify most template engines using a specific popular statement syntax:
${7*7} (expect 49)
Can we expand the coverage of this to detect generic code evaluation? We could try something like:
7*7 (expect 49)
but that will only work on numeric inputs. To detect injection into strings, we need something like:
\x41 (expect A)
However many languages, notably including SQL, don't support hex escapes. This probe can be made one step more generic, to support almost every language:
\\ (expect \)
At this point we have our very first probe for detecting suspicious input transformations. We can now move to the 'Scan' stage of the development process, trying out this payload on a range of applications and seeing what it throws up. Provided the probe is good and the testbed is large enough (more on that later), we'll get a suitably sized set of results which we can manually investigate to find out what's interesting.
In this case, the first step to understanding the behaviour is to look for other input transformations like \x41=>A. By comparing the application's handling of a known-bad escape sequence with other characters, we can gain subtle clues to which characters has special significance server-side. For example, using the baseline of \zz we can easily spot the anomaly:
\zz => \zz
\" => \"
\$ => \$
\{ => {
\x41 => \x41
This tells us that the { character has special significance. Having repeated and refined this manual investigation process a few times, we can loop back around to the 'Implement' stage and automate it. Here's a screenshot of the scanner's output on a page that is vulnerable to Markdown injection:
And a page that isn't vulnerable to anything, but merely calls stripslashes() on the input:
This automated followup means that we can tell how exploitable the endpoint is at a glance. A potential further refinement would be to recognise and classify specific transformation fingerprints.
Note that even though this technique is capable of detecting a huge range of vulnerabilities, on most inputs it only sends a single request. This combination of flexibility and efficiency is at the heart of iterative scanning.
If you're aware of (or able to construct) targets that are definitely vulnerable, you can verify the scanner's susceptibility to false negatives. I found the scanner failed to identify vulnerabilities in JSON responses, since although the server would decode \\ to \, it would then escape the \ back to \\ when embedding it in a JSON string. This was easily fixed by JSON decoding responses where appropriate.
Unfortunately, there's a more serious weakness. This approach relies on user input being reflected after it's been processed. For example, if an application places user input into a SQL SELECT statement, but never displays that query, the vulnerability will be missed entirely. This is a fundamental flaw with relying on suspicious input transformations to detect vulnerabilities.
We can avoid relying on input reflection by analysing the entire response and inferring whether our input caused a significant change. At its most basic, this is quite similar to a classic webapp fuzzer (throw input at the application and see if it crashes), and something many pentesters will be familiar with partially automating using Burp Intruder and fuzzlists. We aren't limited to naively looking at status codes and grepping for error messages - using automation, we can recognise changes as subtle as a single word or empty line disappearing.
Just like a manual tester, we can gather further information using pairs of probes. First, we identify the normal response of the application by sending a probe containing random alphanumeric characters. This will be referred to as the 'base' response. If a probe containing ' consistently gets a response that's different from the base, we can infer that the ' character has a special significance to the application. This may not indicate a vulnerability - the application might just be rejecting inputs containing '. Once again, we can use backslashes to escape our predicament. If the application responds to probes containing \' in the same way as random alphanumeric probes, we can infer that the anomalous response to ' is a caused by a failure to escape the character. This might make more sense in a diagram. The smiley and sad faces represent classification as 'interesting' and 'boring' respectively:
This technique isn't limited to identifying injection into strings. We can also identify injections into various other contexts by using alternative probe-pairs. Each additional probe pair only requires a few lines of code, so we're already using quite a few:
' vs \' // single-quoted string
' vs '' // single-quoted string (alternative escaping)
" vs \" // double-quoted string
7/0 vs 7/1 // number
${{ vs $}} // interpolation
/**/ vs /*/ // raw code
,99 vs ,1 // order-by
sprintz vs sprintf // function name
We can also string sequences of probe-pairs together to iteratively gather more information on a potential vulnerability. When faced with injection into a string, Backslash Powered Scanner will first identify the type of quote in use, then the concatenation sequence, then identify whether function calls are possible, and finally send a list of language-specific functions to try and identify the backend language. The following screenshot shows the scanner's output when pointed at an application vulnerable to Server-Side JavaScript Injection. Note that the information obtained in each stage is used by the following stage.
The scanner will still report a vulnerability even if it doesn't manage to identify the exact vulnerability: it simply displays all the successful probe-pairs. This means it effectively puts every input into one of three categories: 'boring' (no issue reported), 'vulnerable' (clearly suffers from a specific vulnerability in a known language), and 'interesting' (some probe-pairs were successful, application may be vulnerable to an unknown issue).
Applications handle modified inputs in one of two distinct ways. Most inputs vulnerable to server-side injection issues, especially those where the input originates from a free-form text field like a comment, only display a distinct response when you trigger a syntax error server-side:
/post_comment?text=baseComment 200 OK
/post_comment?text=randomtext 200 OK
/post_comment?text=random'text 500 Oops
/post_comment?text=random\'text 200 OK
On other inputs, any deviation from the expected input triggers an error:
/profile?user=bob 200 OK
/profile?user=randomtext 500 Oops
/profile?user=random'text 500 Oops
/profile?user=random\'text 500 Oops
/profile?user=bo'||'b 200 OK
/profile?user=bo'|z'b 500 Oops
The latter case is significantly harder to handle. To find such vulnerabilities we need to skip the quote-identification stage and guess the concatenation character to find evidence of a vulnerability, making the scanner less efficient. As we can't put random text in probes, we're constrained to a limited number of unique probes which makes reliably fingerprinting responses harder. At the time of writing the scanner doesn't handle such cases, although an early prototype has confirmed it's definitely possible.
This limitation doesn't apply to detecting injections into numeric inputs - given a base number, there is an infinite number of ways to express the same number using simple arithmetic. I've opted for x/1 and x/0, since dividing by zero has the added bonus of throwing an exception in some circumstances.
The technical challenge at the heart of this technique is recognising when an application's response to two distinct probes is consistently different. A simple string comparison is utterly useless on real world applications, which are notoriously dynamic. Responses are full of dynamic one-time tokens, timestamps, cache-busters, and reflections of the supplied input.
When I approached this challenge three years ago, I used the intuition that responses are composed of static content with dynamic 'fuzzy points'. I therefore tried to use a set of responses to generate a regular expression by stitching together blocks of static content (identified using the longest-common-subsequence algorithm) with wildcards. For reasons of brevity, I'll only mention a small sample of the crippling issues with this approach. For a start, it's computationally intensive - the longest common subsequence implementation I used was O(n2); the time it took to process a response was proportional to the length of the response squared. The regular expressions were often so complex that scanning the wrong application caused a denial of service on the scanner itself. It also fails to account for applications giving drastically different responses which are difficult to regex together, and shuffling the order of response content. Even timestamps in responses raise difficulties, because parts of them by definition only change every 10, 60, or 100 seconds. Finally, it's extremely difficult to debug, as identifying why a particular response doesn't match a 500-line regular expression can be tricky. Each of these problems may sound solvable, but my attempting to solve them is why this code wasn't released two years ago.
Instead, Backslash Powered Scanner uses the simpler approach of calculating a number of attributes for each response, and noting which ones are consistent across responses. Attributes include the status code, content type, HTML structure, line count, word count, input reflection count, and the frequency of various keywords.
The selection and delivery of probes is also crucial in minimising diffing problems. To differentiate between response differences due to non-determinism and differences caused by our probes, it's necessary to send each pair of probes multiple times. A scanner that simply alternates between two payloads will fail and report false positives when confronted with an application that happens to alternate between two distinct responses, so it's important to mix up the probe order. Some particularly pernicious applications reflect deterministic transformations of user input, or even use user input to seed the choice of testimonial quote. To remedy this, rather than probe-pairs we use pairs of sets of slightly different probes. Finally, caches can make 'random' content appear permanent, but this can easily be fixed using a cache buster.
Seeking to evaluate the scanner on real word systems and having a relatively limited supply of pentests, I decided to run it on every website within scope of a bug bounty program that doesn't disallow automated testing. This is a couple of thousand domains by my calculation. To display courtesy (and avoid being IP-banned), I needed to throttle the scanner to ensure it only sent one request per three seconds to each application. Burp Suite only supports per-thread throttling, so I've coded and released an extension which will implement a per-host throttle. This extension also enables interleaving scan items on different hosts to ensure the overall scanner speed is still decent, and generating host-interleaved lists of unfetched pages for efficient throttled crawling. It also makes some other minor optimisations to improve scan speed without significantly reducing coverage, such as only scanning unpromising parameters like cookies once per host per response type.
To illustrate the types of findings the scanner provides and how to interpret them, I'll take a look at selected results from this experiment. It may help to think of Backslash Powered Scanner as less like a vulnerability scanner, and more like an eager assistant with limited technical understanding.
The following result came from a site that was vulnerable to SQL injection via the User-Agent header:
Basic fuzz (\z`z'z"\ vs \`z\'z\"\\)
Content: 5357 vs 5263
String - apostrophe (\zz'z vs z\\\'z)
Content: 5357 vs 5263
Concatenation: '|| (z||'z(z'z vs z(z'||'z)
Content: 5357 vs 5263
Basic function injection ('||abf(1)||' vs '||abs(1)||')
Content: 5281 vs 5263
MySQL injection ('||power(unix_timestanp(),0)||' vs '||power(unix_timestamp(),0)||')
Content: 5281 vs 5263
The scanner identified that the input was interesting, and correctly identified the exact vulnerability by injecting a function that only exists in MySQL. The 'Content: 5357 vs 5263' line is indicating the attribute the scanner used to distinguish the two results. In this case, the word count on the two responses is different. When this amount of evidence is displayed, the issue is extremely unlikely to be a false positive.
The following finding comes from a pentest of a site that had already been tested numerous times, and clearly shows the power of this scanner:
String - doublequoted (\zz" vs \")
error: 1 vs 0
Content: 9 vs 1
Tags: 3 vs 0
Concatenation: ". (z."z(z"z vs z(z"."z)
error: 1 vs 0
Content: 9 vs 1
Tags: 3 vs 0
Interpolation - dollar (z${{z vs }}$z)
error: 1 vs 0
Content: 9 vs 1
Tags: 3 vs 0
This was vulnerable to PHP code injection, but parenthesis were being filtered out by the application - it's the second of the three blind spots of classic scanners mentioned earlier. Because parenthesis are being filtered, the scanner has failed to inject a function, but we can execute arbitrary shell commands manually with a little effort.
I think the reason this vulnerability was missed by previous pentesters is that the injection was in the file path, which perhaps isn't somewhere a time-pressured tester would bother to manually check for code injection vulnerabilities. Why the application was calling eval() on the path remains a mystery. It's the kind of behaviour you expect from an internet of things device, not a household name website.
The following finding shows the current status of the input on sea.ebay.com that was previously vulnerable to PHP code injection (blind spot #3). We can clearly see that the application responds differently to any input containing the { character.
Note that the responses demonstrate a behaviour opposite to what a naive fuzzer might expect - the string intended to break the application ${{z causes a 200 OK response, whereas the harmless string causes a 500 Internal Server Error. Even though the search function is broken, the scanner has identified a clue of a vulnerability that used to be. Since the scanner is so efficient, it's perfectly plausible to try the PHP array-bypass attack on every input.
The scanner reported quite a few regex injection vulnerabilities, using both the input-transformation and diffing techniques. This is typically a low severity issue - it can be used to interfere with application logic and perhaps cause a denial of service (ReDoS) but little else. An exception is on servers running PHP<5.4.7, where regex injection can be escalated to arbitrary code execution by using a null byte to specify the 'e' flag. This technique was recently used to exploit phpMyAdmin, and I've verified that the scanner finds it. Regex injection is typically reported with the following fingerprint:
Diffing scanner:
Backslash (\ vs \\)
Transformation Scanner:
\0 => Truncated
\1 => Truncated
\$ => $
$ => $
Backreferences like \0 offer a simple way to recognise regex injection. Applications may treat \99 differently from \100, and expand lower groups like \0 or \1 to other strings:
GET /folder?q=foo\0bar HTTP/1.1
HTTP/1.1 301 Moved Permanently
Location: https://redacted.com/folder/?q=foohttp://redacted.com/folder/bar
The scanner noticed a cute but useless flaw in the way a popular web framework escapes values to be put into cookies:
foo"z: Set-Cookie: bci=1234; domain="foo\"z";
foo\: Set-Cookie: bci=1234; domain="foo\";
foo"z\: 500 Internal Server Error
This framework proved so popular that I added a followup probe to automatically classify this issue and prevent anyone wasting time on it:
Basic fuzz (\z`z'z"\ vs \`z\'z\"\\)
exception: 1 vs 0
Doublequote plus slash (z"z\ vs z\z)
exception: 1 vs 0
The function injection detection code raised a single false positive:
Function hijacking (sprintg vs sprintf)
<div: 13 vs 14
The root problem is evident from the URL: https://code.google.com/hosting/search?q=sprintg. The q input is being used to search a large codebase, where 'sprintf' is naturally a far more common term than 'sprintg'. Search functions are frequently ranked as interesting by the scanner, particularly those that support advanced syntax as they can appear deceptively similar to code injection vulnerabilities.
Web Application Firewalls provide another source of 'interesting' behaviour. The scanner noticed that inline comments were being ignored on an otherwise value-sensitive input:
0/**z'*/ vs 0/*/*/z'*/
Manual investigation revealed that even HTML comments were being ignored... and also iframes.
0<!--foo--> vs 0<!--foo->
0<iframe> vs 0<zframe>
It looks like a Web Application Firewall (WAF) is rewriting input to remove comments and potentially harmful HTML. This is good to know - input rewriting effectively disables browsers' XSS filters. As ever, we can automate the HTML-comment followup to prevent this WAF from being a reoccurring distraction.
The scanner flagged some interesting behaviour exhibited by a search function:
Basic fuzz (\z`z'z"\ vs \`z\'z\"\\)
Content: 1578 vs 1575
Backslash (\ vs \\)
Content: 1576 vs 1575
String - doublequoted (\zz" vs \")
Content: 1578 vs 1575
Manual testing revealed that the application was decoding unicode-escaped input too - searching for \u006d\u0069\u0072\u0072\u006f\u0072 returned the same results as searching for 'mirror'. It appeared that user input was being embedded into a JSON string without escaping, enabling us to break out of the search string and alter the query structure.
These examples clearly show that the probe iteration process is crucial - it means that at a glance, we can distinguish a clearly critical issue from something that may take untold hours of investigation to classify. At present, search functions, WAFs and regex injections are a persistent source of promising looking behaviour that doesn't normally lead anywhere useful. Due to the flexibility of the probe-pair approach, almost every dud lead we encounter can be automatically classified in future with a followup probe.
We've also seen that the scanner can identify information that is useful even though it doesn't directly cause a vulnerability.
Many of these vulnerabilities were found on applications protected by WAFs - it appears that the simplicity of the payloads used makes them slip past WAFs unnoticed. However, I found that per-host rate limiting won't keep you off the radar of certain distributed firewall solutions that share IP-reputation scores; I managed to get the office IP banned from oracle.net without sending a single packet to it.
The techniques and code used in the scanner can be adapted to detect far more than server-side injection vulnerabilities. We've already seen that followup probe pairs can be used to identify both WAFs and search functions.
Applications frequently suffer from access control bypasses where attackers can perform unauthorised operations simply by incrementing a number, for example on a URL like /edit_profile?id=734
We can automate detection of inputs where it's possible to obtain additional data by incrementing a number. First, confirm that id=734, id=735, and id=736 return distinct responses. Fetching three distinct responses shows that the id input is being used, and that we're getting more than an 'invalid id' message. However, the application might just be performing a fixed transformation on the input or using it to seed an RNG. By requesting id=100734 and id=100735, and confirming they match, we can verify that we're retrieving data from a finite set.
Pentesters are often in a situation where they want to bruteforce a value, but don't know what the success condition looks like. I made the earliest version of this scanner on a pentest where an ill-prepared client had failed to provide me with a single valid username, let alone a password. In order to stand a chance of guessing a valid password I had to bruteforce a username first, but the response to a valid username might be only subtly different, and I couldn't manually review thousands of login attempts. Using the response attribute diffing technique, this attack can be reliably automated. This approach can even bypass anti-bruteforce measures; when testing this tool I found that addons.mozilla.org gave a slightly distinct response to login attempts with a valid password, even when the account was locked due to excessive login attempts.
Bruteforcing file and folder names on servers that don't provide helpful 404 codes raises a similar challenge. With a few modifications, we could also use this technique to bruteforce hidden parameters to find mass-assignment vulnerabilities, and perhaps even bruteforce valid objects for deserialization exploits.
Classic scanners have several serious blind spots when it comes to identifying server-side injection vulnerabilities. By modelling the approach of an experienced manual tester, I have created a scanner that avoids these blind spots and is extremely efficient. It currently classifies inputs as either boring, interesting, or vulnerable to a specific issue. Issues classified as interesting require manual investigation by security experts, so at present this tool is primarily useful only to security experts. However, the scanner can be adapted to classify individual issues, so over time the proportion of issues classified as 'interesting' instead of 'vulnerable' should drop, making it suitable for a broader range of users.