Today, we’re announcing Sec-Gemini v1, a new experimental AI model focused on advancing cybersecurity AI frontiers. 

As outlined a year ago, defenders face the daunting task of securing against all cyber threats, while attackers need to successfully find and exploit only a single vulnerability. This fundamental asymmetry has made securing systems extremely difficult, time consuming and error prone. AI-powered cybersecurity workflows have the potential to help shift the balance back to the defenders by force multiplying cybersecurity professionals like never before.

Effectively powering SecOps workflows requires state-of-the-art reasoning capabilities and extensive current cybersecurity knowledge. Sec-Gemini v1 achieves this by combining Gemini’s advanced capabilities with near real-time cybersecurity knowledge and tooling. This combination allows it to achieve superior performance on key cybersecurity workflows, including incident root cause analysis, threat analysis, and vulnerability impact understanding.

We firmly believe that successfully pushing AI cybersecurity frontiers to decisively tilt the balance in favor of the defenders requires a strong collaboration across the cybersecurity community. This is why we are making Sec-Gemini v1 freely available to select organizations, institutions, professionals, and NGOs for research purposes.

Sec-Gemini v1 outperforms other models on key cybersecurity benchmarks as a result of its advanced integration of Google Threat Intelligence (GTI), OSV, and other key data sources. Sec-Gemini v1 outperforms other models on CTI-MCQ, a leading threat intelligence benchmark, by at least 11% (See Figure 1). It also outperforms other models by at least 10.5% on the CTI-Root Cause Mapping benchmark (See Figure 2):

Figure 1: Sec-Gemini v1 outperforms other models on the CTI-MCQ Cybersecurity Threat Intelligence benchmark.

Figure 2: Sec-Gemini v1 has outperformed other models in a Cybersecurity Threat Intelligence-Root Cause Mapping (CTI-RCM) benchmark that evaluates an LLM's ability to understand the nuances of vulnerability descriptions, identify vulnerabilities underlying root causes, and accurately classify them according to the CWE taxonomy.

Below is an example of the comprehensiveness of Sec-Gemini v1’s answers in response to key cybersecurity questions. First, Sec-Gemini v1 is able to determine that Salt Typhoon is a threat actor (not all models do) and provides a comprehensive description of that threat actor, thanks to its deep integration with Mandiant Threat intelligence data.

Next, in response to a question about the vulnerabilities in the Salt Typhoon description, Sec-Gemini v1 outputs not only vulnerability details (thanks to its integration with OSV data, the open-source vulnerabilities database operated by Google), but also contextualizes the vulnerabilities with respect to threat actors (using Mandiant data). With Sec-Gemini v1, analysts can understand the risk and threat profile associated with specific vulnerabilities faster.

In partnership with NVIDIA and HiddenLayer, as part of the Open Source Security Foundation, we are now launching the first stable version of our model signing library. Using digital signatures like those from Sigstore, we allow users to verify that the model used by the application is exactly the model that was created by the developers. In this blog post we will illustrate why this release is important from Google’s point of view.

With the advent of LLMs, the ML field has entered an era of rapid evolution. We have seen remarkable progress leading to weekly launches of various applications which incorporate ML models to perform tasks ranging from customer support, software development, and even performing security critical tasks.

However, this has also opened the door to a new wave of security threats. Model and data poisoning, prompt injection, prompt leaking and prompt evasion are just a few of the risks that have recently been in the news. Garnering less attention are the risks around the ML supply chain process: since models are an uninspectable collection of weights (sometimes also with arbitrary code), an attacker can tamper with them and achieve significant impact to those using the models. Users, developers, and practitioners need to examine an important question during their risk assessment process: “can I trust this model?”

Since its launch, Google’s Secure AI Framework (SAIF) has created guidance and technical solutions for creating AI applications that users can trust. A first step in achieving trust in the model is to permit users to verify its integrity and provenance, to prevent tampering across all processes from training to usage, via cryptographic signing. 

The ML supply chain

To understand the need for the model signing project, let’s look at the way ML powered applications are developed, with an eye to where malicious tampering can occur.

Applications that use advanced AI models are typically developed in at least three different stages. First, a large foundation model is trained on large datasets. Next, a separate ML team finetunes the model to make it achieve good performance on application specific tasks. Finally,  this fine-tuned model is embedded into an application.

The three steps involved in building an application that uses large language models.

These three stages are usually handled by different teams, and potentially even different companies, since each stage requires specialized expertise. To make models available from one stage to the next, practitioners leverage model hubs, which are repositories for storing models. Kaggle and HuggingFace are popular open source options, although internal model hubs could also be used.

This separation into stages creates multiple opportunities where a malicious user (or external threat actor who has compromised the internal infrastructure) could tamper with the model. This could range from just a slight alteration of the model weights that control model behavior, to injecting architectural backdoors — completely new model behaviors and capabilities that could be triggered only on specific inputs. It is also possible to exploit the serialization format and inject arbitrary code execution in the model as saved on disk — our whitepaper on AI supply chain integrity goes into more details on how popular model serialization libraries could be exploited. The following diagram summarizes the risks across the ML supply chain for developing a single model, as discussed in the whitepaper.

The supply chain diagram for building a single model, illustrating some supply chain risks (oval labels) and where model signing can defend against them (check marks)

The diagram shows several places where the model could be compromised. Most of these could be prevented by signing the model during training and verifying integrity before any usage, in every step: the signature would have to be verified when the model gets uploaded to a model hub, when the model gets selected to be deployed into an application (embedded or via remote APIs) and when the model is used as an intermediary during another training run. Assuming the training infrastructure is trustworthy and not compromised, this approach guarantees that each model user can trust the model.

Sigstore for ML models

Signing models is inspired by code signing, a critical step in traditional software development. A signed binary artifact helps users identify its producer and prevents tampering after publication. The average developer, however, would not want to manage keys and rotate them on compromise.

These challenges are addressed by using Sigstore, a collection of tools and services that make code signing secure and easy. By binding an OpenID Connect token to a workload or developer identity, Sigstore alleviates the need to manage or rotate long-lived secrets. Furthermore, signing is made transparent so signatures over malicious artifacts could be audited in a public transparency log, by anyone. This ensures that split-view attacks are not possible, so any user would get the exact same model. These features are why we recommend Sigstore’s signing mechanism as the default approach for signing ML models.

Today the OSS community is releasing the v1.0 stable version of our model signing library as a Python package supporting Sigstore and traditional signing methods. This model signing library is specialized to handle the sheer scale of ML models (which are usually much larger than traditional software components), and handles signing models represented as a directory tree. The package provides CLI utilities so that users can sign and verify model signatures for individual models. The package can also be used as a library which we plan to incorporate directly into model hub upload flows as well as into ML frameworks.

Future goals

We can view model signing as establishing the foundation of trust in the ML ecosystem. We envision extending this approach to also include datasets and other ML-related artifacts. Then, we plan to build on top of signatures, towards fully tamper-proof metadata records, that can be read by both humans and machines. This has the potential to automate a significant fraction of the work needed to perform incident response in case of a compromise in the ML world. In an ideal world, an ML developer would not need to perform any code changes to the training code, while the framework itself would handle model signing and verification in a transparent manner.

We’re excited to announce that starting today, Titan Security Keys are available for purchase in more than 10 new countries:

• Ireland

• Portugal

• The Netherlands

• Denmark

• Norway

• Sweden

• Finland

• Australia

• New Zealand

• Singapore

• Puerto Rico

This expansion means Titan Security Keys are now available in 22 markets, including previously announced countries like Austria, Belgium, Canada, France, Germany, Italy, Japan, Spain, Switzerland, the UK, and the US.

What is a Titan Security Key?

A Titan Security Key is a small, physical device that you can use to verify your identity when you sign in to your Google Account. It’s like a second password that’s much harder for cybercriminals to steal.

Titan Security Keys allow you to store your passkeys on a strong, purpose-built device that can help protect you against phishing and other online attacks. They’re easy to use and work with a wide range of devices and services as they’re compatible with the FIDO2 standard.

How do I use a Titan Security Key?

To use a Titan Security Key, you simply plug it into your computer’s USB port or tap it to your device using NFC. When you’re asked to verify your identity, you’ll just need to tap the button on the key.

Where can I buy a Titan Security Key?

You can buy Titan Security Keys on the Google Store.

We’re committed to making our products available to as many people as possible and we hope this expansion will help more people stay safe online.

In December 2022, we released the open source OSV-Scanner tool, and earlier this year, we open sourced OSV-SCALIBR. OSV-Scanner and OSV-SCALIBR, together with OSV.dev are components of an open platform for managing vulnerability metadata and enabling simple and accurate matching and remediation of known vulnerabilities. Our goal is to simplify and streamline vulnerability management for developers and security teams alike.

Today, we're thrilled to announce the launch of OSV-Scanner V2.0.0, following the announcement of the beta version. This V2 release builds upon the foundation we laid with OSV-SCALIBR and adds significant new capabilities to OSV-Scanner, making it a comprehensive vulnerability scanner and remediation tool with broad support for formats and ecosystems. 

What’s new

Enhanced Dependency Extraction with OSV-SCALIBR

This release represents the first major integration of OSV-SCALIBR features into OSV-Scanner, which is now the official command-line code and container scanning tool for the OSV-SCALIBR library. This integration also expanded our support for the kinds of dependencies we can extract from projects and containers:

Source manifests and lockfiles:

• .NET: deps.json

• Python: uv.lock

• JavaScript: bun.lock

• Haskell: cabal.project.freeze, stack.yaml.lock

Artifacts:

• Node modules

• Python wheels

• Java uber jars

• Go binaries

Layer and base image-aware container scanning

Previously, OSV-Scanner focused on scanning of source repositories and language package manifests and lockfiles. OSV-Scanner V2 adds support for comprehensive, layer-aware scanning for Debian, Ubuntu, and Alpine container images. OSV-Scanner can now analyze container images to provide:

• Layers where a package was first introduced

• Layer history and commands

• Base images the image is based on (leveraging a new experimental API provided by deps.dev).

• OS/Distro the container is running on

• Filtering of vulnerabilities that are unlikely to impact your container image

This layer analysis currently supports the following OSes and languages:

Distro Support:

• Alpine OS

• Debian

• Ubuntu

Language Artifacts Support:

• Go

• Java

• Node

• Python

Interactive HTML output

Presenting vulnerability scan information in a clear and actionable way is difficult, particularly in the context of container scanning. To address this, we built a new interactive local HTML output format. This provides more interactivity and information compared to terminal only outputs, including:

• Severity breakdown

• Package and ID filtering

• Vulnerability importance filtering

• Full vulnerability advisory entries

And additionally for container image scanning:

• Layer filtering

• Image layer information

• Base image identification

Illustration of HTML output for container image scanning

Guided remediation for Maven pom.xml

Last year we released a feature called guided remediation for npm, which streamlines vulnerability management by intelligently suggesting prioritized, targeted upgrades and offering flexible strategies. This ultimately maximizes security improvements while minimizing disruption. We have now expanded this feature to Java through support for Maven pom.xml.

With guided remediation support for Maven, you can remediate vulnerabilities in both direct and transitive dependencies through direct version updates or overriding versions through dependency management.

We’ve introduced a few new things for our Maven support:

• A new remediation strategy override.

• Support for reading and writing pom.xml files, including writing changes to local parent pom files. We leverage OSV-Scalibr for Maven transitive dependency extraction.

• A private registry can be specified to fetch Maven metadata.

• A new experimental subcommend to update all your dependencies in pom.xml to the latest version.

We also introduced machine readable output for guided remediation that makes it easier to integrate guided remediation into your workflow.

What’s next?

We have exciting plans for the remainder of the year, including:

• Continued OSV-SCALIBR Convergence: We will continue to converge OSV-Scanner and OSV-SCALIBR to bring OSV-SCALIBR’s functionality to OSV-Scanner’s CLI interface.

• Expanded Ecosystem Support: We'll expand the number of ecosystems we support across all the features currently in OSV-Scanner, including more languages for guided remediation, OS advisories for container scanning, and more general lockfile support for source code scanning.

• Full Filesystem Accountability for Containers: Another goal of osv-scanner is to give you the ability to know and account for every single file on your container image, including sideloaded binaries downloaded from the internet.

• Reachability Analysis: We're working on integrating reachability analysis to provide deeper insights into the potential impact of vulnerabilities.

• VEX Support: We're planning to add support for Vulnerability Exchange (VEX) to facilitate better communication and collaboration around vulnerability information.

Try OSV-Scanner V2

You can try V2.0.0 and contribute to its ongoing development by checking out OSV-Scanner or the OSV-SCALIBR repository. We welcome your feedback and contributions as we continue to improve the platform and make vulnerability management easier for everyone.

In 2024, our Vulnerability Reward Program confirmed the ongoing value of engaging with the security research community to make Google and its products safer. This was evident as we awarded just shy of $12 million to over 600 researchers based in countries around the globe across all of our programs.

Vulnerability Reward Program 2024 in Numbers

You can learn about who’s reporting to the Vulnerability Reward Program via our Leaderboard – and find out more about our youngest security researchers who’ve recently joined the ranks of Google bug hunters.

VRP Highlights in 2024

In 2024 we made a series of changes and improvements coming to our vulnerability reward programs and related initiatives:

• The Google VRP revamped its reward structure, bumping rewards up to a maximum of $151,515, the Mobile VRP is now offering up to $300,000 for critical vulnerabilities in top-tier apps, Cloud VRP has a top-tier award of up $151,515, and Chrome awards now peak at $250,000 (see the below section on Chrome for details).

• We rolled out InternetCTF – to get rewarded, discover novel code execution vulnerabilities in open source and provide Tsunami plugin patches for them.

• The Abuse VRP saw a 40% YoY increase in payouts – we received over 250 valid bugs targeting abuse and misuse issues in Google products, resulting in over $290,000 in rewards.

• To improve the payment process for rewards going to bug hunters, we introduced Bugcrowd as an additional payment option on bughunters.google.com alongside the existing standard Google payment option. 

• We hosted two editions of bugSWAT for training, skill sharing, and, of course, some live hacking – in August, we had 16 bug hunters in attendance in Las Vegas, and in October, as part of our annual security conference ESCAL8 in Malaga, Spain, we welcomed 40 of our top researchers. Between these two events, our bug hunters were rewarded $370,000 (and plenty of swag).

• We doubled down on our commitment to support the next generation of security engineers by hosting four init.g workshops (Las Vegas, São Paulo, Paris, and Malaga). Follow the Google VRP channel on X to stay tuned on future events.

More detailed updates on selected programs are shared in the following sections.

Android and Google Devices

In 2024, the Android and Google Devices Security Reward Program and the Google Mobile Vulnerability Reward Program, both part of the broader Google Bug Hunters program, continued their mission to fortify the Android ecosystem, achieving new heights in both impact and severity. We awarded over $3.3 million in rewards to researchers who demonstrated exceptional skill in uncovering critical vulnerabilities within Android and Google mobile applications. 

The above numbers mark a significant change compared to previous years. Although we saw an 8% decrease in the total number of submissions, there was a 2% increase in the number of critical and high vulnerabilities. In other words, fewer researchers are submitting fewer, but more impactful bugs, and are citing the improved security posture of the Android operating system as the central challenge. This showcases the program's sustained success in hardening Android.

This year, we had a heightened focus on Android Automotive OS and WearOS, bringing actual automotive devices to multiple live hacking events and conferences. At ESCAL8, we hosted a live-hacking challenge focused on Pixel devices, resulting in over $75,000 in rewards in one weekend, and the discovery of several memory safety vulnerabilities. To facilitate learning, we launched a new Android hacking course in collaboration with external security researchers, focused on mobile app security, designed for newcomers and veterans alike. Stay tuned for more.

We extend our deepest gratitude to the dedicated researchers who make the Android ecosystem safer. We're proud to work with you! Special thanks to Zinuo Han (@ele7enxxh) for their expertise in Bluetooth security, blunt (@blunt_qian) for holding the record for the most valid reports submitted to the Google Play Security Reward Program, and WANG,YONG (@ThomasKing2014) for groundbreaking research on rooting Android devices with kernel MTE enabled. We also appreciate all researchers who participated in last year's bugSWAT event in Málaga. Your contributions are invaluable! 

Chrome

Chrome did some remodeling in 2024 as we updated our reward amounts and structure to incentivize deeper research. For example, we increased our maximum reward for a single issue to $250,000 for demonstrating RCE in the browser or other non-sandboxed process, and more if done directly without requiring a renderer compromise. 

In 2024, UAF mitigation MiraclePtr was fully launched across all platforms, and a year after the initial launch, MiraclePtr-protected bugs are no longer being considered exploitable security bugs. In tandem, we increased the MiraclePtr Bypass Reward to $250,128. Between April and November, we also launched the first and second iterations of the V8 Sandbox Bypass Rewards as part of the progression towards the V8 sandbox, eventually becoming a security boundary in Chrome. 

We received 337 reports of unique, valid security bugs in Chrome during 2024, and awarded 137 Chrome VRP researchers $3.4 million in total. The highest single reward of 2024 was $100,115 and was awarded to Mickey for their report of a MiraclePtr Bypass after MiraclePtr was initially enabled across most platforms in Chrome M115 in 2023. We rounded out the year by announcing the top 20 Chrome VRP researchers for 2024, all of whom were gifted new Chrome VRP swag, featuring our new Chrome VRP mascot, Bug.

Cloud VRP

The Cloud VRP launched in October as a Cloud-focused vulnerability reward program dedicated to Google Cloud products and services. As part of the launch, we also updated our product tiering and improved our reward structure to better align our reports with their impact on Google Cloud. This resulted in over 150 Google Cloud products coming under the top two reward tiers, enabling better rewards for our Cloud researchers and a more secure cloud.

Since its launch, Google Cloud VRP triaged over 400 reports and filed over 200 unique security vulnerabilities for Google Cloud products and services leading to over $500,000 in researcher rewards. 

Our highlight last year was launching at the bugSWAT event in Málaga where we got to meet many of our amazing researchers who make our program so successful! The overwhelming positive feedback from the researcher community continues to propel us to mature Google Cloud VRP further this year. Stay tuned for some exciting announcements!

Generative AI

We’re celebrating an exciting first year of AI bug bounties.  We received over 150 bug reports – over $55,000 in rewards so far – with one-in-six leading to key improvements. 

We also ran a bugSWAT live-hacking event targeting LLM products and received 35 reports, totaling more than $87,000 – including issues like “Hacking Google Bard - From Prompt Injection to Data Exfiltration” and “We Hacked Google A.I. for $50,000”.

Keep an eye on Gen AI in 2025 as we focus on expanding scope and sharing additional ways for our researcher community to contribute. 

Looking Forward to 2025

In 2025, we will be celebrating 15 years of VRP at Google, during which we have remained fully committed to fostering collaboration, innovation, and transparency with the security community, and will continue to do so in the future. Our goal remains to stay ahead of emerging threats, adapt to evolving technologies, and continue to strengthen the security posture of Google’s products and services. 

We want to send a huge thank you to our bug hunter community for helping us make Google products and platforms more safe and secure for our users around the world – and invite researchers not yet engaged with the Vulnerability Reward Program to join us in our mission to keep Google safe! 

Thank you to Dirk Göhmann, Amy Ressler, Eduardo Vela, Jan Keller, Krzysztof Kotowicz, Martin Straka, Michael Cote, Mike Antares, Sri Tulasiram, and Tony Mendez.

For decades, memory safety vulnerabilities have been at the center of various security incidents across the industry, eroding trust in technology and costing billions. Traditional approaches, like code auditing, fuzzing, and exploit mitigations – while helpful – haven't been enough to stem the tide, while incurring an increasingly high cost.

In this blog post, we are calling for a fundamental shift: a collective commitment to finally eliminate this class of vulnerabilities, anchored on secure-by-design practices – not just for ourselves but for the generations that follow.

The shift we are calling for is reinforced by a recent ACM article calling to standardize memory safety we took part in releasing with academic and industry partners. It's a recognition that the lack of memory safety is no longer a niche technical problem but a societal one, impacting everything from national security to personal privacy.

The standardization opportunity

Over the past decade, a confluence of secure-by-design advancements has matured to the point of practical, widespread deployment. This includes memory-safe languages, now including high-performance ones such as Rust, as well as safer language subsets like Safe Buffers for C++. 

These tools are already proving effective. In Android for example, the increasing adoption of memory-safe languages like Kotlin and Rust in new code has driven a significant reduction in vulnerabilities.

Looking forward, we're also seeing exciting and promising developments in hardware. Technologies like ARM's Memory Tagging Extension (MTE) and the Capability Hardware Enhanced RISC Instructions (CHERI) architecture offer a complementary defense, particularly for existing code.

While these advancements are encouraging, achieving comprehensive memory safety across the entire software industry requires more than just individual technological progress:  we need to create the right environment and accountability for their widespread adoption. Standardization is key to this. 

To facilitate standardization, we suggest establishing a common framework for specifying and objectively assessing memory safety assurances; doing so will lay the foundation for creating a market in which vendors are incentivized to invest in memory safety. Customers will be empowered to recognize, demand, and reward safety. This framework will provide governments and businesses with the clarity to specify memory safety requirements, driving the procurement of more secure systems. 

The framework we are proposing would complement existing efforts by defining specific, measurable criteria for achieving different levels of memory safety assurance across the industry. In this way, policymakers will gain the technical foundation to craft effective policy initiatives and incentives promoting memory safety.

A blueprint for a memory-safe future

We know there's more than one way of solving this problem, and we are ourselves investing in several. Importantly, our vision for achieving memory safety through standardization focuses on defining the desired outcomes rather than locking ourselves into specific technologies.

To translate this vision into an effective standard, we need a framework that will:

Foster innovation and support diverse approaches: The standard should focus on the security properties we want to achieve (e.g., freedom from spatial and temporal safety violations) rather than mandating specific implementation details. The framework should therefore be technology-neutral, allowing vendors to choose the best approach for their products and requirements. This encourages innovation and allows software and hardware manufacturers to adopt the best solutions as they emerge.

Tailor memory safety requirements based on need: The framework should establish different levels of safety assurance, akin to SLSA levels, recognizing that different applications have different security needs and cost constraints. Similarly, we likely need distinct guidance for developing new systems and improving existing codebases. For instance, we probably do not need every single piece of code to be formally proven. This allows for tailored security, ensuring appropriate levels of memory safety for various contexts. 

Enable objective assessment: The framework should define clear criteria and potentially metrics for assessing memory safety and compliance with a given level of assurance. The goal would be to objectively compare the memory safety assurance of different software components or systems, much like we assess energy efficiency today. This will move us beyond subjective claims and towards objective and comparable security properties across products.

Be practical and actionable: Alongside the technology-neutral framework, we need best practices for existing technologies. The framework should provide guidance on how to effectively leverage specific technologies to meet the standards. This includes answering questions such as when and to what extent unsafe code is acceptable within larger software systems, and guidelines on structuring such unsafe dependencies to support compositional reasoning about safety.

Google's commitment

At Google, we're not just advocating for standardization and a memory-safe future, we're actively working to build it.

We are collaborating with industry and academic partners to develop potential standards, and our joint authorship of the recent CACM call-to-action marks an important first step in this process. In addition, as outlined in our Secure by Design whitepaper and in our memory safety strategy, we are deeply committed to building security into the foundation of our products and services.

This commitment is also reflected in our internal efforts. We are prioritizing memory-safe languages, and have already seen significant reductions in vulnerabilities by adopting languages like Rust in combination with existing, wide-spread usage of Java, Kotlin, and Go where performance constraints permit. We recognize that a complete transition to those languages will take time. That's why we're also investing in techniques to improve the safety of our existing C++ codebase by design, such as deploying hardened libc++.

Let's build a memory-safe future together

This effort isn't about picking winners or dictating solutions. It's about creating a level playing field, empowering informed decision-making, and driving a virtuous cycle of security improvement. It's about enabling a future where:

• Developers and vendors can confidently build more secure systems, knowing their efforts can be objectively assessed.

• Businesses can procure memory-safe products with assurance, reducing their risk and protecting their customers.

• Governments can effectively protect critical infrastructure and incentivize the adoption of secure-by-design practices.

• Consumers are empowered to make decisions about the services they rely on and the devices they use with confidence – knowing the security of each option was assessed against a common framework. 

The journey towards memory safety requires a collective commitment to standardization. We need to build a future where memory safety is not an afterthought but a foundational principle, a future where the next generation inherits a digital world that is secure by design.

Acknowledgments

We'd like to thank our CACM article co-authors for their invaluable contributions: Robert N. M. Watson, John Baldwin, Tony Chen, David Chisnall, Jessica Clarke, Brooks Davis, Nathaniel Wesley Filardo, Brett Gutstein, Graeme Jenkinson, Christoph Kern, Alfredo Mazzinghi, Simon W. Moore, Peter G. Neumann, Hamed Okhravi, Peter Sewell, Laurence Tratt, Hugo Vincent, and Konrad Witaszczyk, as well as many others.