trophy-case
go
trophy-case | go | |
---|---|---|
14 | 2,075 | |
394 | 119,718 | |
1.0% | 0.7% | |
2.8 | 10.0 | |
26 days ago | 3 days ago | |
Go | ||
Creative Commons Zero v1.0 Universal | BSD 3-clause "New" or "Revised" License |
Stars - the number of stars that a project has on GitHub. Growth - month over month growth in stars.
Activity is a relative number indicating how actively a project is being developed. Recent commits have higher weight than older ones.
For example, an activity of 9.0 indicates that a project is amongst the top 10% of the most actively developed projects that we are tracking.
trophy-case
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Rust from a security perspective, where is it vulnerable?
You could check cargo-fuzz trophy case, which is a list of issues that have been found via fuzzing.
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capnproto-rust: out-of-bound memory access bug
I've added it to the trophy case.
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[LWN] A pair of Rust kernel modules
That said, what's present in what quantities under what circumstances in the Rust fuzzing trophy case does a pretty good job of illustrating how effective the Rust compiler is at ruling out entire classes of bugs.
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Looking for simple rust programs to crash
The same fuzzing techniques applied to Rust yielded a lot of bugs as well. But in Rust's case only 7 out of 340 fuzzer-discovered bugs, or 2%, were memory corruption issues. Naturally, all of the memory corruption bugs were in unsafe code.
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Everything Is Broken: Shipping rust-minidump at Mozilla, Part 1
https://github.com/rust-fuzz/trophy-case has like 70 of my issues in it, including the nine minidump bugs
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Fuzzcheck (a structure-aware Rust fuzzer)
If you have found any bugs with this tool, perhaps add them to the Rust fuzz trophy case?
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Rust is more portable than C for pngquant/libimagequant
Source: https://github.com/rust-fuzz/trophy-case (over 40 of those are just from me).
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Rust takes a major step forward as Linux's second official language
But to bring some data, check out the fuzz trophy case. It shows that failures in Rust are most often assertions/panics (equivalent to C++ exception) with memory corruption being relatively rare (it's not never—Rust isn't promising magic—but it's a significant change).
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Shouldn't have happened: A vulnerability postmortem
You need to read the list more carefully.
• The list is not for Rust itself, but every program every written in Rust. By itself it doesn't mean much, unless you compare prevalence of issues among Rust programs to prevalence of issues among C programs. For some context, see how memory unsafety is rare compared to assertions and uncaught exceptions: https://github.com/rust-fuzz/trophy-case
• Many of the memory-unsafety issues are on the C FFI boundary, which is unsafe due to C lacking expressiveness about memory ownership of its APIs (i.e. it shows how dangerous is to program where you don't have the Rust borrow checker checking your code).
• Many bugs about missing Send/Sync or evil trait implementations are about type-system loopholes that prevented compiler from catching code that was already buggy. C doesn't have these guarantees in the first place, so lack of them is not a CVE for C, but just how C is designed.
- Safer usage of C++ in Chrome
go
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Go: the future encoding/json/v2 module
A Discussion about including this package in Go as encoding/json/v2 has been started on the Go Github project on 2023-10-05. Please provide your feedback there.
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Evolving the Go Standard Library with math/rand/v2
I like the Principles section. Very measured and practical approach to releasing new stdlib packages. https://go.dev/blog/randv2#principles
The end of the post they mention that an encoding/json/v2 package is in the works: https://github.com/golang/go/discussions/63397
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Microsoft Maintains Go Fork for FIPS 140-2 Support
There used to be the GO FIPS branch :
https://github.com/golang/go/tree/dev.boringcrypto/misc/bori...
But it looks dead.
And it looks like https://github.com/golang-fips/go as well.
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Borgo is a statically typed language that compiles to Go
I'm not sure what exactly you mean by acknowledgement, but here are some counterexamples:
- A proposal for sum types by a Go team member: https://github.com/golang/go/issues/57644
- The community proposal with some comments from the Go team: https://github.com/golang/go/issues/19412
Here are some excerpts from the latest Go survey [1]:
- "The top responses in the closed-form were learning how to write Go effectively (15%) and the verbosity of error handling (13%)."
- "The most common response mentioned Go’s type system, and often asked specifically for enums, option types, or sum types in Go."
I think the problem is not the lack of will on the part of the Go team, but rather that these issues are not easy to fix in a way that fits the language and doesn't cause too many issues with backwards compatibility.
[1]: https://go.dev/blog/survey2024-h1-results
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AWS Serverless Diversity: Multi-Language Strategies for Optimal Solutions
Now, I’m not going to use C++ again; I left that chapter years ago, and it’s not going to happen. C++ isn’t memory safe and easy to use and would require extended time for developers to adapt. Rust is the new kid on the block, but I’ve heard mixed opinions about its developer experience, and there aren’t many libraries around it yet. LLRD is too new for my taste, but **Go** caught my attention.
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How to use Retrieval Augmented Generation (RAG) for Go applications
Generative AI development has been democratised, thanks to powerful Machine Learning models (specifically Large Language Models such as Claude, Meta's LLama 2, etc.) being exposed by managed platforms/services as API calls. This frees developers from the infrastructure concerns and lets them focus on the core business problems. This also means that developers are free to use the programming language best suited for their solution. Python has typically been the go-to language when it comes to AI/ML solutions, but there is more flexibility in this area. In this post you will see how to leverage the Go programming language to use Vector Databases and techniques such as Retrieval Augmented Generation (RAG) with langchaingo. If you are a Go developer who wants to how to build learn generative AI applications, you are in the right place!
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From Homemade HTTP Router to New ServeMux
net/http: add methods and path variables to ServeMux patterns Discussion about ServeMux enhancements
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Building a Playful File Locker with GoFr
Make sure you have Go installed https://go.dev/.
- Fastest way to get IPv4 address from string
- We now have crypto/rand back ends that ~never fail
What are some alternatives?
diem - Diem’s mission is to build a trusted and innovative financial network that empowers people and businesses around the world.
v - Simple, fast, safe, compiled language for developing maintainable software. Compiles itself in <1s with zero library dependencies. Supports automatic C => V translation. https://vlang.io
go-fuzz - Randomized testing for Go
TinyGo - Go compiler for small places. Microcontrollers, WebAssembly (WASM/WASI), and command-line tools. Based on LLVM.
gccrs - GCC Front-End for Rust
zig - General-purpose programming language and toolchain for maintaining robust, optimal, and reusable software.
BLAKE3 - the official Rust and C implementations of the BLAKE3 cryptographic hash function
Nim - Nim is a statically typed compiled systems programming language. It combines successful concepts from mature languages like Python, Ada and Modula. Its design focuses on efficiency, expressiveness, and elegance (in that order of priority).
bitwarden_rs - Unofficial Bitwarden compatible server written in Rust, formerly known as bitwarden_rs [Moved to: https://github.com/dani-garcia/vaultwarden]
Angular - Deliver web apps with confidence 🚀
rustc_codegen_gcc - libgccjit AOT codegen for rustc
golang-developer-roadmap - Roadmap to becoming a Go developer in 2020