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* **Vulnerable Web**: The target website from which information is intended to be extracted.
* **Attacker's Web**: The malicious website created by the attacker, which the victim visits, hosting the exploit.
* **Inclusion Method**: The technique employed to incorporate the Vulnerable Web into the Attacker's Web (e.g., window.open, iframe, fetch, HTML tag with href, etc.).
* **Leak Technique**: Techniques used to discern differences in the state of the Vulnerable Web based on information gathered through the inclusion method.
* **States**: The two potential conditions of the Vulnerable Web, which the attacker aims to distinguish.
* **Detectable Differences**: Observable variations that the attacker relies on to infer the state of the Vulnerable Web.
* **Status Code**: Distinguishing between **various HTTP response status codes** cross-origin, like server errors, client errors, or authentication errors.
* **API Usage**: Identifying **usage of Web APIs** across pages, revealing whether a cross-origin page employs a specific JavaScript Web API.
* **Redirects**: Detecting navigations to different pages, not just HTTP redirects but also those triggered by JavaScript or HTML.
* **Page Content**: Observing **variations in the HTTP response body** or in page sub-resources, such as the **number of embedded frames** or size disparities in images.
* **HTTP Header**: Noting the presence or possibly the value of a **specific HTTP response header**, including headers like X-Frame-Options, Content-Disposition, and Cross-Origin-Resource-Policy.
* **Timing**: Noticing consistent time disparities between the two states.
* **HTML Elements**: HTML offers various elements for **cross-origin resource inclusion**, like stylesheets, images, or scripts, compelling the browser to request a non-HTML resource. A compilation of potential HTML elements for this purpose can be found at [https://github.com/cure53/HTTPLeaks](https://github.com/cure53/HTTPLeaks).
* **Frames**: Elements such as **iframe**, **object**, and **embed** can embed HTML resources directly into the attacker's page. If the page **lacks framing protection**, JavaScript can access the framed resource’s window object via the contentWindow property.
* **Pop-ups**: The **`window.open`** method opens a resource in a new tab or window, providing a **window handle** for JavaScript to interact with methods and properties following the SOP. Pop-ups, often used in single sign-on, circumvent framing and cookie restrictions of a target resource. However, modern browsers restrict pop-up creation to certain user actions.
* **JavaScript Requests**: JavaScript permits direct requests to target resources using **XMLHttpRequests** or the **Fetch API**. These methods offer precise control over the request, like opting to follow HTTP redirects.
* **Event Handler**: A classical leak technique in XS-Leaks, where event handlers like **onload** and **onerror** provide insights about resource loading success or failure.
* **Error Messages**: JavaScript exceptions or special error pages can provide leak information either directly from the error message or by differentiating between its presence and absence.
* **Global Limits**: Physical limitations of a browser, like memory capacity or other enforced browser limits, can signal when a threshold is reached, serving as a leak technique.
* **Global State**: Detectable interactions with browsers' **global states** (e.g., the History interface) can be exploited. For instance, the **number of entries** in a browser's history can offer clues about cross-origin pages.
* **Performance API**: This API provides **performance details of the current page**, including network timing for the document and loaded resources, enabling inferences about requested resources.
* **Readable Attributes**: Some HTML attributes are **readable cross-origin** and can be used as a leak technique. For instance, the `window.frame.length` property allows JavaScript to count the frames included in a webpage cross-origin.
XSinator is an automatic tool to **check browsers against several know XS-Leaks** explained in its paper: [**https://xsinator.com/paper.pdf**](https://xsinator.com/paper.pdf)
**Excluded XS-Leaks**: We had to exclude XS-Leaks that rely on **service workers** as they would interfere with other leaks in XSinator. Furthermore, we chose to **exclude XS-Leaks that rely on misconfiguration and bugs in a specific web application**. For example, CrossOrigin Resource Sharing (CORS) misconfigurations, postMessage leakage or Cross-Site Scripting. Additionally, we excluded timebased XS-Leaks since they often suffer from being slow, noisy and inaccurate.
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Some of the following techniques are going to use timing to as part of the process to detect differences in the possible states of the web pages. There are different ways to measure time in a web browser.
**Clocks**: The [performance.now()](https://developer.mozilla.org/en-US/docs/Web/API/Performance/now) API allows developers to get high-resolution timing measurements.\
There are a considerable number of APIs attackers can abuse to create implicit clocks: [Broadcast Channel API](https://developer.mozilla.org/en-US/docs/Web/API/Broadcast\_Channel\_API), [Message Channel API](https://developer.mozilla.org/en-US/docs/Web/API/MessageChannel), [requestAnimationFrame](https://developer.mozilla.org/en-US/docs/Web/API/window/requestAnimationFrame), [setTimeout](https://developer.mozilla.org/en-US/docs/Web/API/WindowOrWorkerGlobalScope/setTimeout), CSS animations, and others.\
For more info: [https://xsleaks.dev/docs/attacks/timing-attacks/clocks](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/).
* **Summary**: if trying to load a resource onerror/onload events are triggered with the resource is loaded successfully/unsuccessfully it's possible to figure out the status code.
The code example try lo **load scripts objects from JS**, but **other tags** such as objects, stylesheets, images, audios could be also used. Moreover, it's also possible to inject the **tag directly** and declare the `onload` and `onerror` events inside the tag (instead of injecting it from JS).
* **Summary:** The [**performance.now()**](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/#performancenow) **API** can be used to measure how much time it takes to perform a request. However, other clocks could be used, such as [**PerformanceLongTaskTiming API**](https://developer.mozilla.org/en-US/docs/Web/API/PerformanceLongTaskTiming) which can identify tasks running for more than 50ms.
* **Code Example**: [https://xsleaks.dev/docs/attacks/timing-attacks/network-timing/#onload-events](https://xsleaks.dev/docs/attacks/timing-attacks/network-timing/#onload-events) another example in:
This technique is just like the previous one, but the **attacker** will also **force** some action to take a **relevant amount time** when the **answer is positive or negative** and measure that time.
* **Summary:** The [SharedArrayBuffer clock](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/#sharedarraybuffer-and-web-workers) can be used to measure how much time it takes to perform a request. Other clocks could be used.
The time taken to fetch a resource can be measured by utilizing the [`unload`](https://developer.mozilla.org/en-US/docs/Web/API/Window/unload\_event) and [`beforeunload`](https://developer.mozilla.org/en-US/docs/Web/API/Window/beforeunload\_event) events. The **`beforeunload`** event is fired when the browser is about to navigate to a new page, while the **`unload`** event occurs when the navigation is actually taking place. The time difference between these two events can be calculated to determine the **duration the browser spent fetching the resource**.
* **Summary:** The [performance.now()](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/#performancenow) API can be used to measure how much time it takes to perform a request. Other clocks could be used.
It has been observed that in the absence of [Framing Protections](https://xsleaks.dev/docs/defenses/opt-in/xfo/), the time required for a page and its subresources to load over the network can be measured by an attacker. This measurement is typically possible because the `onload` handler of an iframe is triggered only after the completion of resource loading and JavaScript execution. To bypass the variability introduced by script execution, an attacker might employ the [`sandbox`](https://developer.mozilla.org/en-US/docs/Web/HTML/Element/iframe) attribute within the `<iframe>`. The inclusion of this attribute restricts numerous functionalities, notably the execution of JavaScript, thereby facilitating a measurement that is predominantly influenced by network performance.
```javascript
// Example of an iframe with the sandbox attribute
* **Summary**: If you can make the page error when the correct content is accessed and make it load correctly when any content is accessed, then you can make a loop to extract all the information without measuring the time.
Suppose that you can **insert** the **page** that has the **secret** content **inside an Iframe**.
You can **make the victim search** for the file that contains "_**flag**_" using an **Iframe** (exploiting a CSRF for example). Inside the Iframe you know that the _**onload event**_ will be **executed always at least once**. Then, you can **change** the **URL** of the **iframe** but changing only the **content** of the **hash** inside the URL.
For example:
1.**URL1**: www.attacker.com/xssearch#try1
2.**URL2**: www.attacker.com/xssearch#try2
If the first URL was **successfully loaded**, then, when **changing** the **hash** part of the URL the **onload** event **won't be triggered** again. But **if** the page had some kind of **error** when **loading**, then, the **onload** event will be **triggered again**.
Then, you can **distinguish between** a **correctly** loaded page or page that has an **error** when is accessed.
* **Summary:** If the **page** is **returning** the **sensitive** content, **or** a **content** that can be **controlled** by the user. The user could set **valid JS code in the negative case**, an **load** each try inside **`<script>`** tags, so in **negative** cases attackers **code** is **executed,** and in **affirmative** cases **nothing** will be executed.
* **Summary**: **Cross-Origin Read Blocking (CORB)** is a security measure that prevents web pages from loading certain sensitive cross-origin resources to protect against attacks like **Spectre**. However, attackers can exploit its protective behavior. When a response subject to **CORB** returns a _**CORB protected**_`Content-Type` with `nosniff` and a `2xx` status code, **CORB** strips the response's body and headers. Attackers observing this can infer the combination of the **status code** (indicating success or error) and the `Content-Type` (denoting whether it's protected by **CORB**), leading to potential information leakage.
It's possible to **load a page** inside an **iframe** and use the **`#id_value`** to make the page **focus on the element** of the iframe with indicated if, then if an **`onblur`** signal is triggered, the ID element exists.\
You can perform the same attack with **`portal`** tags.
* **Summary**: Gather sensitive information from a postMessage or use the presence of postMessages as an oracle to know the status of the user in the page
Applications frequently utilize [`postMessage` broadcasts](https://developer.mozilla.org/en-US/docs/Web/API/Window/postMessage) to communicate across different origins. However, this method can inadvertently expose **sensitive information** if the `targetOrigin` parameter is not properly specified, allowing any window to receive the messages. Furthermore, the mere act of receiving a message can act as an **oracle**; for instance, certain messages might only be sent to users who are logged in. Therefore, the presence or absence of these messages can reveal information about the user's state or identity, such as whether they are authenticated or not.
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It is possible to identify if, and how many, **WebSocket connections a target page uses**. It allows an attacker to detect application states and leak information tied to the number of WebSocket connections.
If one **origin** uses the **maximum amount of WebSocket** connection objects, regardless of their connections state, the creation of **new objects will result in JavaScript exceptions**. To execute this attack, the attacker website opens the target website in a pop-up or iframe and then, after the target web has been loaded, attempts to create the maximum number of WebSockets connections possible. The **number of thrown exceptions** is the **number of WebSocket connections used by the target website** window.
This XS-Leak enables an attacker to **detect when a cross-origin page initiates a payment request**.
Because **only one request payment can be active** at the same time, if the target website is using the Payment Request API, any f**urther attempts to show use this API will fail**, and cause a **JavaScript exception**. The attacker can exploit this by **periodically attempting to show the Payment API UI**. If one attempt causes an exception, the target website is currently using it. The attacker can hide these periodical attempts by immediately closing the UI after creation.
JavaScript operates on a [single-threaded event loop](https://developer.mozilla.org/en-US/docs/Web/JavaScript/EventLoop) concurrency model, signifying that **it can only execute one task at a time**. This characteristic can be exploited to gauge **how long code from a different origin takes to execute**. An attacker can measure the execution time of their own code in the event loop by continuously dispatching events with fixed properties. These events will be processed when the event pool is empty. If other origins are also dispatching events to the same pool, an **attacker can infer the time it takes for these external events to execute by observing delays in the execution of their own tasks**. This method of monitoring the event loop for delays can reveal the execution time of code from different origins, potentially exposing sensitive information.
In an execution timing it's possible to **eliminate****network factors** to obtain **more precise measurements**. For example, by loading the resources used by the page before loading it.
* **Summary:** One method to measure the execution time of a web operation involves intentionally blocking the event loop of a thread and then timing **how long it takes for the event loop to become available again**. By inserting a blocking operation (such as a long computation or a synchronous API call) into the event loop, and monitoring the time it takes for subsequent code to begin execution, one can infer the duration of the tasks that were executing in the event loop during the blocking period. This technique leverages the single-threaded nature of JavaScript's event loop, where tasks are executed sequentially, and can provide insights into the performance or behavior of other operations sharing the same thread.
A significant advantage of the technique of measuring execution time by locking the event loop is its potential to circumvent **Site Isolation**. **Site Isolation** is a security feature that separates different websites into separate processes, aiming to prevent malicious sites from directly accessing sensitive data from other sites. However, by influencing the execution timing of another origin through the shared event loop, an attacker can indirectly extract information about that origin's activities. This method does not rely on direct access to the other origin's data but rather observes the impact of that origin's activities on the shared event loop, thus evading the protective barriers established by **Site Isolation**.
In an execution timing it's possible to **eliminate****network factors** to obtain **more precise measurements**. For example, by loading the resources used by the page before loading it.
* **Summary:** An attacker could lock all the sockets except 1, load the target web and at the same time load another page, the time until the last page is starting to load is the time the target page took to load.
Browsers utilize sockets for server communication, but due to the limited resources of the operating system and hardware, **browsers are compelled to impose a limit** on the number of concurrent sockets. Attackers can exploit this limitation through the following steps:
1. Ascertain the browser's socket limit, for instance, 256 global sockets.
2. Occupy 255 sockets for an extended duration by initiating 255 requests to various hosts, designed to keep the connections open without completing.
3. Employ the 256th socket to send a request to the target page.
4. Attempt a 257th request to a different host. Given that all sockets are in use (as per steps 2 and 3), this request will be queued until a socket becomes available. The delay before this request proceeds provides the attacker with timing information about the network activity related to the 256th socket (the target page's socket). This inference is possible because the 255 sockets from step 2 are still engaged, implying that any newly available socket must be the one released from step 3. The time taken for the 256th socket to become available is thus directly linked to the time required for the request to the target page to complete.
* **Summary:** It's like the previous technique but instead of using all the sockets, Google **Chrome** puts a limit of **6 concurrent request to the same origin**. If we **block 5** and then **launch a 6th** request we can **time** it and if we managed to make the **victim page send** more **requests** to the same endpoint to detect a **status** of the **page**, the **6th request** will take **longer** and we can detect it.
The [`Performance API`](https://developer.mozilla.org/en-US/docs/Web/API/Performance) offers insights into the performance metrics of web applications, further enriched by the [`Resource Timing API`](https://developer.mozilla.org/en-US/docs/Web/API/Resource\_Timing\_API). The Resource Timing API enables the monitoring of detailed network request timings, such as the duration of the requests. Notably, when servers include the `Timing-Allow-Origin: *` header in their responses, additional data like the transfer size and domain lookup time becomes available.
This wealth of data can be retrieved via methods like [`performance.getEntries`](https://developer.mozilla.org/en-US/docs/Web/API/Performance/getEntries) or [`performance.getEntriesByName`](https://developer.mozilla.org/en-US/docs/Web/API/Performance/getEntriesByName), providing a comprehensive view of performance-related information. Additionally, the API facilitates the measurement of execution times by calculating the difference between timestamps obtained from [`performance.now()`](https://developer.mozilla.org/en-US/docs/Web/API/Performance/now). However, it's worth noting that for certain operations in browsers like Chrome, the precision of `performance.now()` may be limited to milliseconds, which could affect the granularity of timing measurements.
Beyond timing measurements, the Performance API can be leveraged for security-related insights. For instance, the presence or absence of pages in the `performance` object in Chrome can indicate the application of `X-Frame-Options`. Specifically, if a page is blocked from rendering in a frame due to `X-Frame-Options`, it will not be recorded in the `performance` object, providing a subtle clue about the page's framing policies.
It is possible to **differentiate between HTTP response status codes** because requests that lead to an **error** do **not create a performance entry**.
In the previous technique it was also identified two cases where browser bugs in GC lead to **resources being loaded twice when they fail to load**. This will result in multiple entries in the Performance API and can thus be detected.
The technique was found in a table in the mentioned paper but no description of the technique was found on it. However, you can find the source code checking for it in [https://xsinator.com/testing.html#Request%20Merging%20Error%20Leak](https://xsinator.com/testing.html#Request%20Merging%20Error%20Leak)
An attacker can detect if a request resulted in an empty HTTP response body because e**mpty pages do not create a performance entry in some browsers**.
* **Summary:** Using the XSS Auditor in Security Assertions, attackers can detect specific webpage elements by observing alterations in responses when crafted payloads trigger the auditor's filtering mechanism.
In Security Assertions (SA), the XSS Auditor, originally intended to prevent Cross-Site Scripting (XSS) attacks, can paradoxically be exploited to leak sensitive information. Although this built-in feature was removed from Google Chrome (GC), it's still present in SA. In 2013, Braun and Heiderich demonstrated that the XSS Auditor could inadvertently block legitimate scripts, leading to false positives. Building on this, researchers developed techniques to extract information and detect specific content on cross-origin pages, a concept known as XS-Leaks, initially reported by Terada and elaborated by Heyes in a blog post. Although these techniques were specific to the XSS Auditor in GC, it was discovered that in SA, pages blocked by the XSS Auditor do not generate entries in the Performance API, revealing a method through which sensitive information might still be leaked.
If a page is **not allowed** to be **rendered** in an **iframe** it does **not create a performance entry**. As a result, an attacker can detect the response header **`X-Frame-Options`**.\
Similar, to the XS-Leak described, a **resource that is downloaded** because of the ContentDisposition header, also does **not create a performance entry**. This technique works in all major browsers.
We found one XS-Leak instance that abuses the behavior of some browsers which log too much information for cross-origin requests. The standard defines a subset of attributes that should be set to zero for cross-origin resources. However, in **SA** it is possible to detect if the user is **redirected** by the target page, by querying the **Performance API** and checking for the **redirectStart timing data**.
In GC, the **duration** for requests that result in a **redirect** is **negative** and can thus be **distinguished** from requests that do not result in a redirect.
In some cases, the **nextHopProtocol entry** can be used as a leak technique. In GC, when the **CORP header** is set, the nextHopProtocol will be **empty**. Note that SA will not create a performance entry at all for CORP-enabled resources.
Service workers are event-driven script contexts that run at an origin. They run in the background of a web page and can intercept, modify, and **cache resources** to create offline web application.\
If a **resource cached** by a **service worker** is accessed via **iframe**, the resource will be **loaded from the service worker cache**.\
To detect if the resource was **loaded from the service worker** cache the **Performance API** can be used.\
The `MediaError` interface's message property uniquely identifies resources that load successfully with a distinct string. An attacker can exploit this feature by observing the message content, thereby deducing the response status of a cross-origin resource.
This technique enables an attacker to **extract the destination of a cross-origin site's redirect** by exploiting how Webkit-based browsers handle CORS requests. Specifically, when a **CORS-enabled request** is sent to a target site that issues a redirect based on user state and the browser subsequently denies the request, the **full URL of the redirect's target** is disclosed within the error message. This vulnerability not only reveals the fact of the redirect but also exposes the redirect's endpoint and any **sensitive query parameters** it may contain.
An attacker can exploit **verbose error messages** to deduce the size of cross-origin responses. This is possible due to the mechanism of Subresource Integrity (SRI), which uses the integrity attribute to validate that resources fetched, often from CDNs, haven't been tampered with. For SRI to work on cross-origin resources, these must be **CORS-enabled**; otherwise, they're not subject to integrity checks. In Security Assertions (SA), much like the CORS error XS-Leak, an error message can be captured after a fetch request with an integrity attribute fails. Attackers can deliberately **trigger this error** by assigning a **bogus hash value** to the integrity attribute of any request. In SA, the resulting error message inadvertently reveals the content length of the requested resource. This information leakage allows an attacker to discern variations in response size, paving the way for sophisticated XS-Leak attacks.
* **Summary:** Allowing only the victims website in the CSP if we accessed it tries to redirect to a different domain the CSP will trigger a detectable error.
A XS-Leak can use the CSP to detect if a cross-origin site was redirected to a different origin. This leak can detect the redirect, but additionally, the domain of the redirect target leaks. The basic idea of this attack is to **allow the target domain on the attacker site**. Once a request is issued to the target domain, it **redirects** to a cross-origin domain. **CSP blocks** the access to it and creates a **violation report used as a leak technique**. Depending on the browser, **this report may leak the target location of the redirect**.\
Browsers might use one shared cache for all websites. Regardless of their origin, it is possible to deduct whether a target page has **requested a specific file**.
If a page loads an image only if the user is logged in, you can **invalidate** the **resource** (so it's no longer cached if it was, see more info links), **perform a request** that could load that resource and try to load the resource **with a bad request** (e.g. using an overlong referer header). If the resource load **didn't trigger any error**, it's because it was **cached**.
A novel feature in Google Chrome (GC) allows web pages to **propose a Content Security Policy (CSP)** by setting an attribute on an iframe element, with policy directives transmitted along with the HTTP request. Normally, the embedded content must **authorize this via an HTTP header**, or an **error page is displayed**. However, if the iframe is already governed by a CSP and the newly proposed policy isn't more restrictive, the page will load normally. This mechanism opens a pathway for an attacker to **detect specific CSP directives** of a cross-origin page by identifying the error page. Although this vulnerability was marked as fixed, our findings reveal a **new leak technique** capable of detecting the error page, suggesting that the underlying problem was never fully addressed.
The CORP header is a relatively new web platform security feature that when set b**locks no-cors cross-origin requests to the given resource**. The presence of the header can be detected, because a resource protected with CORP will **throw an error when fetched**.
### CORS error on Origin Reflection misconfiguration <a href="#cors-error-on-origin-reflection-misconfiguration" id="cors-error-on-origin-reflection-misconfiguration"></a>
* **Summary**: If the Origin header is reflected in the header `Access-Control-Allow-Origin` it's possible to check if a resource is in the cache already.
In case the **Origin header** is being **reflected** in the header `Access-Control-Allow-Origin` an attacker can abuse this behaviour to try to **fetch** the **resource** in **CORS** mode. If an **error****isn't** triggered, it means that it was **correctly retrieved form the web**, if an error is **triggered**, it's because it was **accessed from the cache** (the error appears because the cache saves a response with a CORS header allowing the original domain and not the attackers domain)**.**\
Submitting a request using the Fetch API with `redirect: "manual"` and other params, it's possible to read the `response.type` attribute and if it's equals to `opaqueredirect` then the response was a redirect.
An attacker is capable of deducing the presence of the Cross-Origin Opener Policy (COOP) header in a cross-origin HTTP response. COOP is utilized by web applications to hinder external sites from obtaining arbitrary window references. The visibility of this header can be discerned by attempting to access the **`contentWindow` reference**. In scenarios where COOP is applied conditionally, the **`opener` property** becomes a telltale indicator: it's **undefined** when COOP is active, and **defined** in its absence.
* **Summary:** Detect differences in responses because of the redirect response length migt be too large that the server replays with an error and an alert is generated.
If a server-side redirect uses **user input inside the redirection** and **extra data**. It's possible to detect this behaviour because usually **servers** has a **limit request length**. If the **user data** is that **length - 1**, because the **redirect** is using **that data** and **adding** something **extra**, it will trigger an **error detectable via Error Events**.
If you can somehow set cookies to a user, you can also perform this attack by **setting enough cookies** ([**cookie bomb**](hacking-with-cookies/cookie-bomb.md)) so with the **response increased size** of the **correct response** an **error** is triggered. In this case, remember that is you trigger this request from a same site, `<script>` will automatically send the cookies (so you can check for errors).\
An example of the **cookie bomb + XS-Search** can be found in the Intended solution of this writeup: [https://blog.huli.tw/2022/05/05/en/angstrom-ctf-2022-writeup-en/#intended](https://blog.huli.tw/2022/05/05/en/angstrom-ctf-2022-writeup-en/#intended)
According to [Chromium documentation](https://chromium.googlesource.com/chromium/src/+/main/docs/security/url\_display\_guidelines/url\_display\_guidelines.md#URL-Length), Chrome's maximum URL length is 2MB.
> In general, the _web platform_ does not have limits on the length of URLs (although 2^31 is a common limit). _Chrome_ limits URLs to a maximum length of **2MB** for practical reasons and to avoid causing denial-of-service problems in inter-process communication.
Therefore if the **redirect URL responded is larger in one of the cases**, it's possible to make it redirect with a **URL larger than 2MB** to hit the **length limit**. When this happens, Chrome shows an **`about:blank#blocked`** page.
The **noticeable difference**, is that if the **redirect** was **completed**, `window.origin` throws an **error** because a cross origin cannot access that info. However, if the **limit** was \*\*\*\* hit and the loaded page was **`about:blank#blocked`** the window's **`origin`** remains that of the **parent**, which is an **accessible information.**
If the **max** number of **redirects** to follow of a browser is **20**, an attacker could try to load his page with **19 redirects** and finally **send the victim** to the tested page. If an **error** is triggered, then the page was trying to **redirect the victim**.
The **History API** allows JavaScript code to manipulate the browser history, which **saves the pages visited by a user**. An attacker can use the length property as an inclusion method: to detect JavaScript and HTML navigation.\
**Checking `history.length`**, making a user **navigate** to a page, **change** it **back** to the same-origin and **checking** the new value of **`history.length`**.
* **Detectable Difference**: If URL is the same as the guessed one
* **Summary:** It's possible to guess if the location of a frame/popup is in an specific URL abusing the history length.
* **Code Example**: Below
An attacker could use JavaScript code to **manipulate the frame/pop-up location to a guessed one** and **immediately****change it to `about:blank`**. If the history length increased it means the URL was correct and it had time to **increase because the URL isn't reloaded if it's the same**. If it didn't increased it means it **tried to load the guessed URL** but because we **immediately after** loaded **`about:blank`**, the **history length did never increase** when loading the guessed url.
Counting the **number of frames in a web** opened via `iframe` or `window.open` might help to identify the **status of the user over that page**.\
Moreover, if the page has always the same number of frames, checking **continuously** the number of frames might help to identify a **pattern** that might leak info.
An example of this technique is that in chrome, a **PDF** can be **detected** with **frame counting** because an `embed` is used internally. There are [Open URL Parameters](https://bugs.chromium.org/p/chromium/issues/detail?id=64309#c113) that allow some control over the content such as `zoom`, `view`, `page`, `toolbar` where this technique could be interesting.
Information leakage through HTML elements is a concern in web security, particularly when dynamic media files are generated based on user information, or when watermarks are added, altering the media size. This can be exploited by attackers to differentiate between possible states by analyzing the information exposed by certain HTML elements.
* **HTMLMediaElement**: This element reveals the media's `duration` and `buffered` times, which can be accessed via its API. [Read more about HTMLMediaElement](https://developer.mozilla.org/en-US/docs/Web/API/HTMLMediaElement)
* **HTMLVideoElement**: It exposes `videoHeight` and `videoWidth`. In some browsers, additional properties like `webkitVideoDecodedByteCount`, `webkitAudioDecodedByteCount`, and `webkitDecodedFrameCount` are available, offering more in-depth information about the media content. [Read more about HTMLVideoElement](https://developer.mozilla.org/en-US/docs/Web/API/HTMLVideoElement)
* **getVideoPlaybackQuality()**: This function provides details about video playback quality, including `totalVideoFrames`, which can indicate the amount of video data processed. [Read more about getVideoPlaybackQuality()](https://developer.mozilla.org/en-US/docs/Web/API/VideoPlaybackQuality)
* **HTMLImageElement**: This element leaks the `height` and `width` of an image. However, if an image is invalid, these properties will return 0, and the `image.decode()` function will be rejected, indicating the failure to load the image properly. [Read more about HTMLImageElement](https://developer.mozilla.org/en-US/docs/Web/API/HTMLImageElement)
Web applications may change w**ebsite styling depending on the status of the use**. Cross-origin CSS files can be embedded on the attacker page with the **HTML link element**, and the **rules** will be **applied** to the attacker page. If a page dynamically changes these rules, an attacker can **detect** these **differences** depending on the user state.\
As a leak technique, the attacker can use the `window.getComputedStyle` method to **read CSS** properties of a specific HTML element. As a result, an attacker can read arbitrary CSS properties if the affected element and property name is known.
The CSS `:visited` selector is utilized to style URLs differently if they have been previously visited by the user. In the past, the `getComputedStyle()` method could be employed to identify these style differences. However, modern browsers have implemented security measures to prevent this method from revealing the state of a link. These measures include always returning the computed style as if the link were visited and restricting the styles that can be applied with the `:visited` selector.
Despite these restrictions, it's possible to discern the visited state of a link indirectly. One technique involves tricking the user into interacting with an area affected by CSS, specifically utilizing the `mix-blend-mode` property. This property allows the blending of elements with their background, potentially revealing the visited state based on user interaction.
Furthermore, detection can be achieved without user interaction by exploiting the rendering timings of links. Since browsers may render visited and unvisited links differently, this can introduce a measurable time difference in rendering. A proof of concept (PoC) was mentioned in a Chromium bug report, demonstrating this technique using multiple links to amplify the timing difference, thereby making the visited state detectable through timing analysis.
For further details on these properties and methods, visit their documentation pages:
* **Summary:** In Google Chrome, a dedicated error page is displayed when a page is blocked from being embedded on a cross-origin site due to X-Frame-Options restrictions.
In Chrome, if a page with the `X-Frame-Options` header set to "deny" or "same-origin" is embedded as an object, an error page appears. Chrome uniquely returns an empty document object (instead of `null`) for the `contentDocument` property of this object, unlike in iframes or other browsers. Attackers could exploit this by detecting the empty document, potentially revealing information about the user's state, especially if developers inconsistently set the X-Frame-Options header, often overlooking error pages. Awareness and consistent application of security headers are crucial for preventing such leaks.
The `Content-Disposition` header, specifically `Content-Disposition: attachment`, instructs the browser to download content rather than display it inline. This behavior can be exploited to detect whether a user has access to a page that triggers a file download. In Chromium-based browsers, there are a few techniques to detect this download behavior:
* When a page triggers a file download using the `Content-Disposition: attachment` header, it does not cause a navigation event.
* By loading the content in an iframe and monitoring for navigation events, it's possible to check if the content disposition causes a file download (no navigation) or not.
* Similar to the iframe technique, this method involves using `window.open` instead of an iframe.
* Monitoring navigation events in the newly opened window can reveal whether a file download was triggered (no navigation) or if the content is displayed inline (navigation occurs).
In scenarios where only logged-in users can trigger such downloads, these techniques can be used to indirectly infer the user's authentication state based on the browser's response to the download request.
This is why this technique is interesting: Chrome now has **cache partitioning**, and the cache key of the newly opened page is: `(https://actf.co, https://actf.co, https://sustenance.web.actf.co/?m =xxx)`, but if I open an ngrok page and use fetch in it, the cache key will be: `(https://myip.ngrok.io, https://myip.ngrok.io, https://sustenance.web.actf.co/?m=xxx)`, the **cache key is different**, so the cache cannot be shared. You can find more detail here: [Gaining security and privacy by partitioning the cache](https://developer.chrome.com/blog/http-cache-partitioning/)\
(Comment from [**here**](https://blog.huli.tw/2022/05/05/en/angstrom-ctf-2022-writeup-en/))
If a site `example.com` includes a resource from `*.example.com/resource` then that resource will have the **same caching key** as if the resource was directly **requested through top-level navigation**. That is because the caching key is consisted of top-level _eTLD+1_ and frame _eTLD+1_.
Because accessing the cache is faster than loading a resource, it's possible to try to change the location of a page and cancel it 20ms (for example) after. If the origin was changed after the stop, it means that the resource was cached.\
Or could just **send some fetch to the pontentially cached page and measure the time it takes**.
* **Summary:** It's possible to try to load a resource and about before it's loaded the loading is interrupted. Depending on if an error is triggered, the resource was or wasn't cached.
Use _**fetch**_ and _**setTimeout**_ with an **AbortController** to both detect whether the **resource is cached** and to evict a specific resource from the browser cache. Moreover, the process occurs without caching new content.
* **Summary:** It's possible to **overwrite built-in functions** and read their arguments which even from **cross-origin script** (which cannot be read directly), this might **leak valuable information**.
In the given scenario, the attacker takes the initiative to register a **service worker** within one of their domains, specifically "attacker.com". Next, the attacker opens a new window in the target website from the main document and instructs the **service worker** to commence a timer. As the new window begins to load, the attacker navigates the reference obtained in the previous step to a page managed by the **service worker**.
Upon arrival of the request initiated in the preceding step, the **service worker** responds with a **204 (No Content)** status code, effectively terminating the navigation process. At this point, the **service worker** captures a measurement from the timer initiated earlier in step two. This measurement is influenced by the duration of JavaScript causing delays in the navigation process.
In an execution timing it's possible to **eliminate****network factors** to obtain **more precise measurements**. For example, by loading the resources used by the page before loading it.
* **Summary:** Use [performance.now()](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/#performancenow) to measure the time it takes to perform a request. Other clocks could be used.
* **Summary:** se [performance.now()](https://xsleaks.dev/docs/attacks/timing-attacks/clocks/#performancenow) to measure the time it takes to perform a request using `window.open`. Other clocks could be used.
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Here you can find techniques to exfiltrate information from a cross-origin HTML **injecting HTML content**. These techniques are interesting in cases where for any reason you can **inject HTML but you cannot inject JS code**.
**Images** in HTML has a "**loading**" attribute whose value can be "**lazy**". In that case, the image will be loaded when it's viewed and not while the page is loading:
Therefore, what you can do is to **add a lot of junk chars** (For example **thousands of "W"s**) to **fill the web page before the secret or add something like**`<br><canvas height="1850px"></canvas><br>.`\
Then if for example our **injection appear before the flag**, the **image** would be **loaded**, but if appears **after** the **flag**, the flag + the junk will **prevent it from being loaded** (you will need to play with how much junk to place). This is what happened in [**this writeup**](https://blog.huli.tw/2022/10/08/en/sekaictf2022-safelist-and-connection/).
Another option would be to use the **scroll-to-text-fragment** if allowed:
What this text will do is to make the bot access any text in the page that contains the text `SECR`. As that text is the secret and it's just **below the image**, the **image will only load if the guessed secret is correct**. So there you have your oracle to **exfiltrate the secret char by char**.
Some code example to exploit this: [https://gist.github.com/jorgectf/993d02bdadb5313f48cf1dc92a7af87e](https://gist.github.com/jorgectf/993d02bdadb5313f48cf1dc92a7af87e)
If it's **not possible to load an external image** that could indicate the attacker that the image was loaded, another option would be to try to **guess the char several times and measure that**. If the image is loaded all the requests would take longer that if the image isn't loaded. This is what was used in the [**solution of this writeup**](https://blog.huli.tw/2022/10/08/en/sekaictf2022-safelist-and-connection/) **sumarized here:**
If `jQuery(location.hash)` is used, it's possible to find out via timing i**f some HTML content exists**, this is because if the selector `main[id='site-main']` doesn't match it doesn't need to check the rest of the **selectors**:
There are mitigations recommended in [https://xsinator.com/paper.pdf](https://xsinator.com/paper.pdf) also in each section of the wiki [https://xsleaks.dev/](https://xsleaks.dev/). Take a look there for more information about how to protect against these techniques.
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