Google Online Security Blog

How Hash-Based Safe Browsing Works in Google Chrome

August 8, 2022

There are various threats a user faces when browsing the web. Users may be tricked into sharing sensitive information like their passwords with a misleading or fake website, also called phishing. They may also be led into installing malicious software on their machines, called malware, which can collect personal data and also hold it for ransom. Google Chrome, henceforth called Chrome, enables its users to protect themselves from such threats on the internet. When Chrome users browse the web with Safe Browsing protections, Chrome uses the Safe Browsing service from Google to identify and ward off various threats. Safe Browsing works in different ways depending on the user's preferences. In the most common case, Chrome uses the privacy-conscious Update API (Application Programming Interface) from the Safe Browsing service. This API was developed with user privacy in mind and ensures Google gets as little information about the user's browsing history as possible. If the user has opted-in to "Enhanced Protection" (covered in an earlier post) or "Make Searches and Browsing Better", Chrome shares limited additional data with Safe Browsing only to further improve user protection. This post describes how Chrome implements the Update API, with appropriate pointers to the technical implementation and details about the privacy-conscious aspects of the Update API. This should be useful for users to understand how Safe Browsing protects them, and for interested developers to browse through and understand the implementation. We will cover the APIs used for Enhanced Protection users in a future post. Threats on the Internet When a user navigates to a webpage on the internet, their browser fetches objects hosted on the internet. These objects include the structure of the webpage (HTML), the styling (CSS), dynamic behavior in the browser (Javascript), images, downloads initiated by the navigation, and other webpages embedded in the main webpage. These objects, also called resources, have a web address which is called their URL (Uniform Resource Locator). Further, URLs may redirect to other URLs when being loaded. Each of these URLs can potentially host threats such as phishing websites, malware, unwanted downloads, malicious software, unfair billing practices, and more. Chrome with Safe Browsing checks all URLs, redirects or included resources, to identify such threats and protect users. Safe Browsing Lists Safe Browsing provides a list for each threat it protects users against on the internet. A full catalog of lists that are used in Chrome can be found by visiting chrome://safe-browsing/#tab-db-manager on desktop platforms. A list does not contain unsafe web addresses, also referred to as URLs, in entirety; it would be prohibitively expensive to keep all of them in a device’s limited memory. Instead it maps a URL, which can be very long, through a cryptographic hash function (SHA-256), to a unique fixed size string. This distinct fixed size string, called a hash, allows a list to be stored efficiently in limited memory. The Update API handles URLs only in the form of hashes and is also called hash-based API in this post. Further, a list does not store hashes in entirety either, as even that would be too memory intensive. Instead, barring a case where data is not shared with Google and the list is small, it contains prefixes of the hashes. We refer to the original hash as a full hash, and a hash prefix as a partial hash.

A list is updated following the Update API’s request frequency section. Chrome also follows a back-off mode in case of an unsuccessful response. These updates happen roughly every 30 minutes, following the minimum wait duration set by the server in the list update response. For those interested in browsing relevant source code, here’s where to look: Source Code

GetListInfos() contains all the lists, along with their associated threat types, the platforms they are used on, and their file names on disk.

HashPrefixMap shows how the lists are stored and maintained. They are grouped by the size of prefixes, and appended together to allow quick binary search based lookups.

How is hash-based URL lookup done As an example of a Safe Browsing list, let's say that we have one for malware, containing partial hashes of URLs known to host malware. These partial hashes are generally 4 bytes long, but for illustrative purposes, we show only 2 bytes. ['036b', '1a02', 'bac8', 'bb90'] Whenever Chrome needs to check the reputation of a resource with the Update API, for example when navigating to a URL, it does not share the raw URL (or any piece of it) with Safe Browsing to perform the lookup. Instead, Chrome uses full hashes of the URL (and some combinations) to look up the partial hashes in the locally maintained Safe Browsing list. Chrome sends only these matched partial hashes to the Safe Browsing service. This ensures that Chrome provides these protections while respecting the user’s privacy. This hash-based lookup happens in three steps in Chrome: Step 1: Generate URL Combinations and Full Hashes When Google blocks URLs that host potentially unsafe resources by placing them on a Safe Browsing list, the malicious actor can host the resource on a different URL. A malicious actor can cycle through various subdomains to generate new URLs. Safe Browsing uses host suffixes to identify malicious domains that host malware in their subdomains. Similarly, malicious actors can also cycle through various subpaths to generate new URLs. So Safe Browsing also uses path prefixes to identify websites that host malware at various subpaths. This prevents malicious actors from cycling through subdomains or paths for new malicious URLs, allowing robust and efficient identification of threats.

To incorporate these host suffixes and path prefixes, Chrome first computes the full hashes of the URL and some patterns derived from the URL. Following Safe Browsing API's URLs and Hashing specification, Chrome computes the full hashes of URL combinations by following these steps:

First, Chrome converts the URL into a canonical format, as defined in the specification.

Then, Chrome generates up to 5 host suffixes/variants for the URL.

Then, Chrome generates up to 6 path prefixes/variants for the URL.

Then, for the combined 30 host suffixes and path prefixes combinations, Chrome generates the full hash for each combination.

Source Code

V4LocalDatabaseManager::CheckBrowseURL is an example which performs a hash-based lookup.

V4ProtocolManagerUtil::UrlToFullHashes creates the various URL combinations for a URL, and computes their full hashes.

Example For instance, let's say that a user is trying to visit https://evil.example.com/blah#frag. The canonical url is https://evil.example.com/blah. The host suffixes to be tried are evil.example.com, and example.com. The path prefixes are / and /blah. The four combined URL combinations are evil.example.com/, evil.example.com/blah, example.com/, and example.com/blah. url_combinations = ["evil.example.com/", "evil.example.com/blah","example.com/", "example.com/blah"] full_hashes = ['1a02…28', 'bb90…9f', '7a9e…67', 'bac8…fa'] Step 2: Search Partial Hashes in Local Lists Chrome then checks the full hashes of the URL combinations against the locally maintained Safe Browsing lists. These lists, which contain partial hashes, do not provide a decisive malicious verdict, but can quickly identify if the URL is considered not malicious. If the full hash of the URL does not match any of the partial hashes from the local lists, the URL is considered safe and Chrome proceeds to load it. This happens for more than 99% of the URLs checked. Source Code

V4LocalDatabaseManager::GetPrefixMatches gets the matching partial hashes for the full hashes of the URL and its combinations.

Example Chrome finds that three full hashes 1a02…28, bb90…9f, and bac8…fa match local partial hashes. We note that this is for demonstration purposes, and a match here is rare.

Step 3: Fetch Matching Full Hashes Next, Chrome sends only the matching partial hash (not the full URL or any particular part of the URL, or even their full hashes), to the Safe Browsing service's fullHashes.find method. In response, it receives the full hashes of all malicious URLs for which the full hash begins with one of the partial hashes sent by Chrome. Chrome checks the fetched full hashes with the generated full hashes of the URL combinations. If any match is found, it identifies the URL with various threats and their severities inferred from the matched full hashes. Source Code

V4GetHashProtocolManager::GetFullHashes performs the lookup for the full hashes for the matched partial hashes.

Example Chrome sends the matched partial hashes 1a02, bb90, and bac8 to fetch the full hashes. The server returns full hashes that match these partial hashes, 1a02…28, bb90…ce, and bac8…01. Chrome finds that one of the full hashes matches with the full hash of the URL combination being checked, and identifies the malicious URL as hosting malware. Conclusion Safe Browsing protects Chrome users from various malicious threats on the internet. While providing these protections, Chrome faces challenges such as constraints in memory capacity, network bandwidth usage, and a dynamic threat landscape. Chrome is also mindful of the users’ privacy choices, and shares little data with Google. In a follow up post, we will cover the more advanced protections Chrome provides to its users who have opted in to “Enhanced Protection”.

DNS-over-HTTP/3 in Android

July 19, 2022

Posted by Matthew Maurer and Mike Yu, Android team To help keep Android users’ DNS queries private, Android supports encrypted DNS. In addition to existing support for DNS-over-TLS, Android now supports DNS-over-HTTP/3 which has a number of improvements over DNS-over-TLS. Most network connections begin with a DNS lookup. While transport security may be applied to the connection itself, that DNS lookup has traditionally not been private by default: the base DNS protocol is raw UDP with no encryption. While the internet has migrated to TLS over time, DNS has a bootstrapping problem. Certificate verification relies on the domain of the other party, which requires either DNS itself, or moves the problem to DHCP (which may be maliciously controlled). This issue is mitigated by central resolvers like Google, Cloudflare, OpenDNS and Quad9, which allow devices to configure a single DNS resolver locally for every network, overriding what is offered through DHCP. In Android 9.0, we announced the Private DNS feature, which uses DNS-over-TLS (DoT) to protect DNS queries when enabled and supported by the server. Unfortunately, DoT incurs overhead for every DNS request. An alternative encrypted DNS protocol, DNS-over-HTTPS (DoH), is rapidly gaining traction within the industry as DoH has already been deployed by most public DNS operators, including the Cloudflare Resolver and Google Public DNS. While using HTTPS alone will not reduce the overhead significantly, HTTP/3 uses QUIC, a transport that efficiently multiplexes multiple streams over UDP using a single TLS session with session resumption. All of these features are crucial to efficient operation on mobile devices. DNS-over-HTTP/3 (DoH3) support was released as part of a Google Play system update, so by the time you’re reading this, Android devices from Android 11 onwards¹ will use DoH3 instead of DoT for well-known² DNS servers which support it. Which DNS service you are using is unaffected by this change; only the transport will be upgraded. In the future, we aim to support DDR which will allow us to dynamically select the correct configuration for any server. This feature should decrease the performance impact of encrypted DNS. Performance DNS-over-HTTP/3 avoids several problems that can occur with DNS-over-TLS operation:

As DoT operates on a single stream of requests and responses, many server implementations suffer from head-of-line blocking³. This means that if the request at the front of the line takes a while to resolve (possibly because a recursive resolution is necessary), responses for subsequent requests that would have otherwise been resolved quickly are blocked waiting on that first request. DoH3 by comparison runs each request over a separate logical stream, which means implementations will resolve requests out-of-order by default.

Mobile devices change networks frequently as the user moves around. With DoT, these events require a full renegotiation of the connection. By contrast, the QUIC transport HTTP/3 is based on can resume a suspended connection in a single RTT.

DoT intends for many queries to use the same connection to amortize the cost of TCP and TLS handshakes at the start. Unfortunately, in practice several factors (such as network disconnects or server TCP connection management) make these connections less long-lived than we might like. Once a connection is closed, establishing the connection again requires at least 1 RTT.

In unreliable networks, DoH3 may even outperform traditional DNS. While unintuitive, this is because the flow control mechanisms in QUIC can alert either party that packets weren’t received. In traditional DNS, the timeout for a query needs to be based on expected time for the entire query, not just for the resolver to receive the packet.

Field measurements during the initial limited rollout of this feature show that DoH3 significantly improves on DoT’s performance. For successful queries, our studies showed that replacing DoT with DoH3 reduces median query time by 24%, and 95th percentile query time by 44%. While it might seem suspect that the reported data is conditioned on successful queries, both DoT and DoH3 resolve 97% of queries successfully, so their metrics are directly comparable. UDP resolves only 83% of queries successfully. As a result, UDP latency is not directly comparable to TLS/HTTP3 latency because non-connection-oriented protocols have a different notion of what a "query" is. We have still included it for rough comparison. Memory Safety The DNS resolver processes input that could potentially be controlled by an attacker, both from the network and from apps on the device. To reduce the risk of security vulnerabilities, we chose to use a memory safe language for the implementation. Fortunately, we’ve been adding Rust support to the Android platform. This effort is intended exactly for cases like this — system level features which need to be performant or low level (both in this case) and which would carry risk to implement in C++. While we’ve previously launched Keystore 2.0, this represents our first foray into Rust in Mainline Modules. Cloudflare maintains an HTTP/3 library called quiche, which fits our use case well, as it has a memory-safe implementation, few dependencies, and a small code size. Quiche also supports use directly from C++. We considered this, but even the request dispatching service had sufficient complexity that we chose to implement that portion in Rust as well. We built the query engine using the Tokio async framework to simultaneously handle new requests, incoming packet events, control signals, and timers. In C++, this would likely have required multiple threads or a carefully crafted event loop. By leveraging asynchronous in Rust, this occurs on a single thread with minimal locking⁴. The DoH3 implementation is 1,640 lines and uses a single runtime thread. By comparison, DoT takes 1,680 lines while managing less and using up to 4 threads per DoT server in use. Safety and Performance — Together at Last With the introduction of Rust, we are able to improve both security and the performance at the same time. Likewise, QUIC allows us to improve network performance and privacy simultaneously. Finally, Mainline ensures that such improvements are able to make their way to more Android users sooner. Acknowledgements Special thanks to Luke Huang who greatly contributed to the development of this feature, and Lorenzo Colitti for his in-depth review of the technical aspects of this post.

Some Android 10 devices which adopted Google Play system updates early will also receive this feature. ↩
Google DNS and Cloudflare DNS at launch, others may be added in the future. ↩
DoT can be implemented in a way that avoids this problem, as the client must accept server responses out of order. However, in practice most servers do not implement this reordering. ↩
There is a lock used for the SSL context which is accessed once per DNS server, and another on the FFI when issuing a request. The FFI lock could be removed with changes to the C++ side, but has remained because it is low contention. ↩

Game on! The 2022 Google CTF is here.

June 21, 2022

Posted by Jan Keller, Technical Entertainment Manager, Bug Hunters

Are you ready to put your hacking skills to the test? It’s Google CTF time!

The competition kicks off on July 1 2022 6:00 PM UTC and runs through July 3 2022 6:00 PM UTC. Registration is now open at http://goo.gle/ctf.

In true old Google CTF fashion, the top 8 teams will qualify for our Hackceler8 speedrunning meets CTFs competition. The prize pool stands similar to previous years at more than $40,000.

We can’t wait to see whether PPP will be able to defend their crown. For those of you looking to satisfy your late-night hacking hunger: past year's challenges, including Hackceler8 2021 matches, are open-sourced here. On top of that there are hours of Hackceler8 2020 videos to watch!

If you are just starting out in this space, last year’s Beginner’s Quest is a great resource to get started. For later in the year, we have something mysterious planned - stay tuned to find out more!

Whether you’re a seasoned CTF player or just curious about cyber security and ethical hacking, we want you to join us. Sign up to expand your skill set, meet new friends in the security community, and even watch the pros in action. For the latest announcements, see g.co/ctf, subscribe to our mailing list, or follow us on @GoogleVRP. Interested in bug hunting for Google? Check out bughunters.google.com. See you there!

SBOM in Action: finding vulnerabilities with a Software Bill of Materials

June 14, 2022

Posted by Brandon Lum and Oliver Chang, Google Open Source Security Team

SBOMs2021 Executive Order on CybersecuritySecure Software Development Frameworkmaking progress on methodscriticalOSV: Connecting SBOMs to vulnerabilitiesbomOpen Source Vulnerabilities (OSV) databaseGithub Advisory Database (GHSA)Global Security Database (GSD)spdx-to-osvpublicly available

# Download the Kubernetes SPDX source document

$ curl -L https://sbom.k8s.io/v1.21.3/source > k8s-1.21.3-source.spdx

spdx-to-osv

# Run the spdx-to-osv tool, taking the information from the SPDX SBOM and mapping it to OSV vulnerabilities

$ java -jar ./target/spdx-to-osv-0.0.4-SNAPSHOT-jar-with-dependencies.jar -I k8s-1.21.3-source.spdx -O out-k8s.1.21.3.json

# Show the output OSV vulnerabilities of the spdx-to-osv tool

$ cat out-k8s.1.21.3.json

…

{

"id": "GHSA-w73w-5m7g-f7qc",

"published": "2021-05-18T21:08:21Z",

"modified": "2021-06-28T21:32:34Z",

"aliases": [

"CVE-2020-26160"

"summary": "Authorization bypass in github.com/dgrijalva/jwt-go",

"details": "jwt-go allows attackers to bypass intended access restrictions in situations with []string{} for m[\"aud\"] (which is allowed by the specification). Because the type assertion fails, \"\" is the value of aud. This is a security problem if the JWT token is presented to a service that lacks its own audience check. There is no patch available and users of jwt-go are advised to migrate to [golang-jwt](https://github.com/golang-jwt/jwt) at version 3.2.1",

"affected": [

{

"package": {

"name": "github.com/dgrijalva/jwt-go",

"ecosystem": "Go",

"purl": "pkg:golang/github.com/dgrijalva/jwt-go"

…

CVE-2020-26160
Suggestions for SBOM tooling improvements

To get the spdx-to-osv tool to work we had to make some minor changes to disambiguate the information provided in the SBOM:

In the current implementation of the bom tool, the version was included as part of the package name (gopkg.in/square/go-jose.v2@v2.2.2). We needed to trim the suffix to match the SPDX format, which has a different field for version number.

The SBOM created by the bom tool does not specify an ecosystem. Without an ecosystem, it's impossible to reliably disambiguate which library or package is affected in an automated way. Vulnerability scanners could return false positives if one ecosystem was affected but not others. It would be more helpful if the SBOM differentiated between different library and package versions.

These are relatively minor hurdles, though, and we were able to successfully run the tool with only small manual adjustments. To make the process easier in the future, we have the following recommendation for improving SBOM generation tooling:

SBOM tooling creators should add a reference using an identification scheme such as Purl for all packages included in the software. This type of identification scheme both specifies the ecosystem and also makes package identification easier, since the scheme is more resilient to small deviations in package descriptors like the suffix example above. SPDX supports this via external references to Purl and other package identification schemas.

SBOM in the future

It’s clear that we’re getting very close to achieving the original goal of SBOMs: using them to help manage the risk of vulnerabilities in software. Our example queried the OSV database, but we will soon see the same success in mapping SBOM data to other vulnerability databases and even using them with new standards like VEX, which provides additional context around whether vulnerabilities in software have been mitigated.

Continuing on this path of widespread SBOM adoption and tooling refinement, we will hopefully soon be able to not only request and download SBOMs for every piece of software, but also use them to understand the vulnerabilities affecting any software we consume. This example is a peek into a possible future of what SBOMs can offer when we bridge the gap to connect them with vulnerability databases: a new normal of worrying less about the risks in the software we use.

A special thanks to Gary O’Neall of Source Auditor for creating the spdx-to-osv tool and contributing to this blog post.

Announcing the winners of the 2021 GCP VRP Prize

June 3, 2022

Posted by Harshvardhan Sharma, Information Security Engineer, Google
record-breaking yearGoogle Cloud Platform (GCP)announcedFirst PrizeBypassing Identity-Aware ProxySecond PrizeGCE VM takeover via DHCP floodThird PrizeRemote Code Execution in Google Cloud DataflowFourth PrizeThe Speckle Umbrella story — part 2(Remember, you can make multiple submissions for the GCP VRP Prize and be eligible for more than one prize!)Fifth PrizeRemote code execution in Managed Anthos Service Mesh control planeSixth PrizeCommand Injection in Google Cloud Shell

New Details About 2022 GCP VRP

We will pay out a total of $313,337 to the top seven submissions in the 2022 edition of the GCP VRP Prize. Individual prize amounts will be as follows:

1st prize: $133,337
2nd prize: $73,331
3rd prize: $31,337
4th prize: $31,311
5th prize: $17,311
6th prize: $13,373
7th prize: $13,337

If you are a security researcher, here's how you can enter the competition for the GCP VRP Prize 2022:

Make sure to submit your VRP reports and write-ups before January 15, 2023 at 23:59 PT. VRP reports which were submitted in preceding years but fixed only in 2022 are also eligible. You can check out the official rules for the prize here. Good luck!

Retrofitting Temporal Memory Safety on C++

May 26, 2022

Posted by Anton Bikineev, Michael Lippautz and Hannes Payer, Chrome security team

Memory safety in Chrome is an ever-ongoing effort to protect our users. We are constantly experimenting with different technologies to stay ahead of malicious actors. In this spirit, this post is about our journey of using heap scanning technologies to improve memory safety of C++.

Let’s start at the beginning though. Throughout the lifetime of an application its state is generally represented in memory. Temporal memory safety refers to the problem of guaranteeing that memory is always accessed with the most up to date information of its structure, its type. C++ unfortunately does not provide such guarantees. While there is appetite for different languages than C++ with stronger memory safety guarantees, large codebases such as Chromium will use C++ for the foreseeable future.

auto* foo = new Foo();

delete foo;

// The memory location pointed to by foo is not representing

// a Foo object anymore, as the object has been deleted (freed).

foo->Process();

In the example above, foo is used after its memory has been returned to the underlying system. The out-of-date pointer is called a dangling pointer and any access through it results in a use-after-free (UAF) access. In the best case such errors result in well-defined crashes, in the worst case they cause subtle breakage that can be exploited by malicious actors.

UAFs are often hard to spot in larger codebases where ownership of objects is transferred between various components. The general problem is so widespread that to this date both industry and academia regularly come up with mitigation strategies. The examples are endless: C++ smart pointers of all kinds are used to better define and manage ownership on application level; static analysis in compilers is used to avoid compiling problematic code in the first place; where static analysis fails, dynamic tools such as C++ sanitizers can intercept accesses and catch problems on specific executions.

Chrome’s use of C++ is sadly no different here and the majority of high-severity security bugs are UAF issues. In order to catch issues before they reach production, all of the aforementioned techniques are used. In addition to regular tests, fuzzers ensure that there’s always new input to work with for dynamic tools. Chrome even goes further and employs a C++ garbage collector called Oilpan which deviates from regular C++ semantics but provides temporal memory safety where used. Where such deviation is unreasonable, a new kind of smart pointer called MiraclePtr was introduced recently to deterministically crash on accesses to dangling pointers when used. Oilpan, MiraclePtr, and smart-pointer-based solutions require significant adoptions of the application code.

Over the last decade, another approach has seen some success: memory quarantine. The basic idea is to put explicitly freed memory into quarantine and only make it available when a certain safety condition is reached. Microsoft has shipped versions of this mitigation in its browsers: MemoryProtector in Internet Explorer in 2014 and its successor MemGC in (pre-Chromium) Edge in 2015. In the Linux kernel a probabilistic approach was used where memory was eventually just recycled. And this approach has seen attention in academia in recent years with the MarkUs paper. The rest of this article summarizes our journey of experimenting with quarantines and heap scanning in Chrome.

(At this point, one may ask where pointer authentication fits into this picture – keep on reading!)

Quarantining and Heap Scanning, the Basics

The main idea behind assuring temporal safety with quarantining and heap scanning is to avoid reusing memory until it has been proven that there are no more (dangling) pointers referring to it. To avoid changing C++ user code or its semantics, the memory allocator providing new and delete is intercepted.

Upon invoking delete, the memory is actually put in a quarantine, where it is unavailable for being reused for subsequent new calls by the application. At some point a heap scan is triggered which scans the whole heap, much like a garbage collector, to find references to quarantined memory blocks. Blocks that have no incoming references from the regular application memory are transferred back to the allocator where they can be reused for subsequent allocations.

There are various hardening options which come with a performance cost:

Overwrite the quarantined memory with special values (e.g. zero);
Stop all application threads when the scan is running or scan the heap concurrently;
Intercept memory writes (e.g. by page protection) to catch pointer updates;
Scan memory word by word for possible pointers (conservative handling) or provide descriptors for objects (precise handling);
Segregation of application memory in safe and unsafe partitions to opt-out certain objects which are either performance sensitive or can be statically proven as being safe to skip;
Scan the execution stack in addition to just scanning heap memory;

We call the collection of different versions of these algorithms StarScan [stɑː skæn], or *Scan for short.

Reality Check

We apply *Scan to the unmanaged parts of the renderer process and use Speedometer2 to evaluate the performance impact.

We have experimented with different versions of *Scan. To minimize performance overhead as much as possible though, we evaluate a configuration that uses a separate thread to scan the heap and avoids clearing of quarantined memory eagerly on delete but rather clears quarantined memory when running *Scan. We opt in all memory allocated with new and don’t discriminate between allocation sites and types for simplicity in the first implementation.

Note that the proposed version of *Scan is not complete. Concretely, a malicious actor may exploit a race condition with the scanning thread by moving a dangling pointer from an unscanned to an already scanned memory region. Fixing this race condition requires keeping track of writes into blocks of already scanned memory, by e.g. using memory protection mechanisms to intercept those accesses, or stopping all application threads in safepoints from mutating the object graph altogether. Either way, solving this issue comes at a performance cost and exhibits an interesting performance and security trade-off. Note that this kind of attack is not generic and does not work for all UAF. Problems such as depicted in the introduction would not be prone to such attacks as the dangling pointer is not copied around.

Since the security benefits really depend on the granularity of such safepoints and we want to experiment with the fastest possible version, we disabled safepoints altogether.

Running our basic version on Speedometer2 regresses the total score by 8%. Bummer…

Where does all this overhead come from? Unsurprisingly, heap scanning is memory bound and quite expensive as the entire user memory must be walked and examined for references by the scanning thread.

To reduce the regression we implemented various optimizations that improve the raw scanning speed. Naturally, the fastest way to scan memory is to not scan it at all and so we partitioned the heap into two classes: memory that can contain pointers and memory that we can statically prove to not contain pointers, e.g. strings. We avoid scanning memory that cannot contain any pointers. Note that such memory is still part of the quarantine, it is just not scanned.

We extended this mechanism to also cover allocations that serve as backing memory for other allocators, e.g., zone memory that is managed by V8 for the optimizing JavaScript compiler. Such zones are always discarded at once (c.f. region-based memory management) and temporal safety is established through other means in V8.

On top, we applied several micro optimizations to speed up and eliminate computations: we use helper tables for pointer filtering; rely on SIMD for the memory-bound scanning loop; and minimize the number of fetches and lock-prefixed instructions.

We also improve upon the initial scheduling algorithm that just starts a heap scan when reaching a certain limit by adjusting how much time we spent in scanning compared to actually executing the application code (c.f. mutator utilization in garbage collection literature).

In the end, the algorithm is still memory bound and scanning remains a noticeably expensive procedure. The optimizations helped to reduce the Speedometer2 regression from 8% down to 2%.

While we improved raw scanning time, the fact that memory sits in a quarantine increases the overall working set of a process. To further quantify this overhead, we use a selected set of Chrome’s real-world browsing benchmarks to measure memory consumption. *Scan in the renderer process regresses memory consumption by about 12%. It’s this increase of the working set that leads to more memory being paged in which is noticeable on application fast paths.

Hardware Memory Tagging to the Rescue

MTE (Memory Tagging Extension) is a new extension on the ARM v8.5A architecture that helps with detecting errors in software memory use. These errors can be spatial errors (e.g. out-of-bounds accesses) or temporal errors (use-after-free). The extension works as follows. Every 16 bytes of memory are assigned a 4-bit tag. Pointers are also assigned a 4-bit tag. The allocator is responsible for returning a pointer with the same tag as the allocated memory. The load and store instructions verify that the pointer and memory tags match. In case the tags of the memory location and the pointer do not match a hardware exception is raised.

MTE doesn't offer a deterministic protection against use-after-free. Since the number of tag bits is finite there is a chance that the tag of the memory and the pointer match due to overflow. With 4 bits, only 16 reallocations are enough to have the tags match. A malicious actor may exploit the tag bit overflow to get a use-after-free by just waiting until the tag of a dangling pointer matches (again) the memory it is pointing to.

*Scan can be used to fix this problematic corner case. On each delete call the tag for the underlying memory block gets incremented by the MTE mechanism. Most of the time the block will be available for reallocation as the tag can be incremented within the 4-bit range. Stale pointers would refer to the old tag and thus reliably crash on dereference. Upon overflowing the tag, the object is then put into quarantine and processed by *Scan. Once the scan verifies that there are no more dangling pointers to this block of memory, it is returned back to the allocator. This reduces the number of scans and their accompanying cost by ~16x.

The following picture depicts this mechanism. The pointer to foo initially has a tag of 0x0E which allows it to be incremented once again for allocating bar. Upon invoking delete for bar the tag overflows and the memory is actually put into quarantine of *Scan.

We got our hands on some actual hardware supporting MTE and redid the experiments in the renderer process. The results are promising as the regression on Speedometer was within noise and we only regressed memory footprint by around 1% on Chrome’s real-world browsing stories.

Is this some actual free lunch? Turns out that MTE comes with some cost which has already been paid for. Specifically, PartitionAlloc, which is Chrome’s underlying allocator, already performs the tag management operations for all MTE-enabled devices by default. Also, for security reasons, memory should really be zeroed eagerly. To quantify these costs, we ran experiments on an early hardware prototype that supports MTE in several configurations:

MTE disabled and without zeroing memory;
MTE disabled but with zeroing memory;
MTE enabled without *Scan;
MTE enabled with *Scan;

(We are also aware that there’s synchronous and asynchronous MTE which also affects determinism and performance. For the sake of this experiment we kept using the asynchronous mode.)

The results show that MTE and memory zeroing come with some cost which is around 2% on Speedometer2. Note that neither PartitionAlloc, nor hardware has been optimized for these scenarios yet. The experiment also shows that adding *Scan on top of MTE comes without measurable cost.

Conclusions

C++ allows for writing high-performance applications but this comes at a price, security. Hardware memory tagging may fix some security pitfalls of C++, while still allowing high performance. We are looking forward to see a more broad adoption of hardware memory tagging in the future and suggest using *Scan on top of hardware memory tagging to fix temporary memory safety for C++. Both the used MTE hardware and the implementation of *Scan are prototypes and we expect that there is still room for performance optimizations.