Echo chambers suck, I’m sorry. It’s assbackwards when people dismiss real, lived experiences that don’t align with what they optimistically imagine those experiences would be like.
Echo chambers suck, I’m sorry. It’s assbackwards when people dismiss real, lived experiences that don’t align with what they optimistically imagine those experiences would be like.
Something can be objectively correct yet still presented in an opinionated manner.
Oh, don’t worry. The guy who answered vmlinuz
beat me to the joke in general :)
There’s always BSD, Hurd, Darwin… or NT 🤮
The kernel. I can take or leave most things, but I’m not going back to the days of writing directly into memory-mapped registers.
That’s not the point, though. The point is to use a nominal type that asserts an invariant and make it impossible to create an instance of said type which violates the invariant.
Both validation functions and refinement types put the onus on the caller to ensure they’re not passing invalid data around, but only refinement types can guarantee it. Humans are fallible, and it’s easy to accidentally forget to put a check_if_valid()
function somewhere or assume that some function earlier in the call stack did it for you.
With smart constructors and refinement types, the developer literally can’t pass an unvalidated type downstream by accident.
You’re going to need to cite that.
I’m not familiar with C23 or many of the compiler-specific extensions, but in all the previous versions I worked with, there is no type visibility other than “fully exposed” or opaque and dangerous (void*
).
You could try wrapping your Foo
in
typedef struct {
Foo validated
} ValidFoo;
But nothing stops someone from being an idiot about it and constructing it by hand:
ValidFoo trustMeBro;
trustMeBro.validated = someFoo;
otherFunction(trustMeBro);
Or even just casting it.
Foo* someFoo;
otherFunction((ValidFoo*) someFoo);
If it were poorly designed and used exceptions, yes. The correct way to design smart constructors is to not actually use a constructor directly but instead use a static method that forces the caller to handle both cases (or explicitly ignore the failure case). The static method would have a return type that either indicates “success and here’s the refined type” or “error and this is why.”
In Rust terminology, that would be a Result<T, Error>
.
For Go, it would be (*RefinedType, error)
(where dereferencing the first value without checking it would be at your own peril).
C++ would look similar to Rust, but it doesn’t come as part of the standard library last I checked.
C doesn’t have the language-level features to be able to do this. You can’t make a refined type that’s accessible as a type while also making it impossible to construct arbitrarily.
Unless you’re a functional programming purist or coming from a systems programming background, it takes a lot longer than a few days to get used to the borrow checker. If you’re coming as someone who most often uses garbage-collected languages, it’s even worse.
The problem isn’t so much understanding what the compiler is bitching about, as it is understanding why the paradigm you used isn’t safe and learning how to structure your code differently. That part takes the longest and only really starts to become easier when you learn to stop fighting the language.
Of course. Rust isn’t immune to logic errors, off-by-one mistakes, and other such issues. Nor is it memory safe in unsafe
blocks.
Just by virtue of how memory safety issues account for 50%+ of vulnerabilities, it’s worth genuinely considering as long as the bindings don’t cause maintainability issues.
Let me know when you find one?
The first directory block is a hole. But type == DIRENT, so no error is reported. After that, we get a directory block without ‘.’ and ‘…’ but with a valid dentry. This may cause some code that relies on dot or dotdot (such as make_indexed_dir()) to crash
The problem isn’t that the block is a hole. It’s that the downstream function expects the directory block to contain .
and ..
, and it gets given one without because of incorrect error handling.
You can encode the invariant of “has dot and dot dot” using a refinement type and smart constructor. The refined type would be a directory block with a guarantee it meets that invariant, and an instance of it could only be created through a function that validates the invariant. If the invariant is met, you get the refined type. If it isn’t, you only get an error.
This doesn’t work in C, but in languages with stricter type systems, refinement types are a huge advantage.
Arrogant hypocrites are a pet peeve of mine. If someone is going to act like progressive technology changes are beneath them and unnecessary, they should be able to put their money where their mouth is.
Wait, yeah. I was thinking of ad hominem when i wrote that, sorry. Correct, that is a strawman.
I understand his experience is hard to match, we all have something in our lives we’re that good at
At some point, that mix of experience and ego becomes a significant liability. He’s directly hurting the adoption of Rust in the kernel, while the C code he’s responsible for is full of problems that would have been impossible if written in safe Rust.
CVE-2024-42304 — crash from undocumented function parameter invariants
CVE-2024-40955 — out of bounds read
CVE-2024-0775 — use-after-free
CVE-2023-2513 — use-after-free
CVE-2023-1252 — use-after-free
CVE-2022-1184 — use-after-free
CVE-2020-14314 — out of bounds read
CVE-2019-19447 — use-after-free
CVE-2018-10879 — use-after-free
CVE-2018-10878 — out of bounds write
CVE-2018-10881 — out of bounds read
CVE-2015-8324 — null pointer dereference
CVE-2014-8086 — race condition
CVE-2011-2493 — call function pointer in uninitialized struct
CVE-2009-0748 — null pointer dereference
There’s really only one valid response to Ted Ts’o:
If you think you can do better with C, prove it.
CVE-2024-42304 — crash from undocumented function parameter invariants
CVE-2024-40955 — out of bounds read
CVE-2024-0775 — use-after-free
CVE-2023-2513 — use-after-free
CVE-2023-1252 — use-after-free
CVE-2022-1184 — use-after-free
CVE-2020-14314 — out of bounds read
CVE-2019-19447 — use-after-free
CVE-2018-10879 — use-after-free
CVE-2018-10878 — out of bounds write
CVE-2018-10881 — out of bounds read
CVE-2015-8324 — null pointer dereference
CVE-2014-8086 — race condition
CVE-2011-2493 — call function pointer in uninitialized struct
CVE-2009-0748 — null pointer dereference
Part of the hostility was the other maintainer misunderstanding the presenter, going on a diatribe about how the kernel Rust maintainers are going to force the C code to become unrefactorable and stagnate, and rudely interrupting the presenter with another tangent whenever he (the presenter) tried to clarify anything.
An unpleasant mix of DM railroading and gish galloping, essentially.
I wouldn’t quite call it a strawman, but the guy was clearly not engaging in good faith. He made up hypothetical scenarios that nobody asked about, and then denigrated Rust by attacking the scenarios he came up with.
Edit: I was thinking of the wrong fallacy. It is a strawman, yes.
I was only going for explaining why AMD still continues to have the license to the x86 instruction set in modern times, but I appreciate the added historical context to explain to others how they originally had the rights to use it.
TL;DR: While Intel had their heads shoved up their ass making the Itanium architecture, AMD made a 64-bit variant of x86 that was backward compatible with the older x86 ISA. Technology moved on, and amd64 was adopted while Intel kept trying and failing to push their binary-incompatible architecture.
Eventually, Intel had to give up and adopt AMD’s amd64 ISA. In exchange for letting them use it, Intel lets AMD use the older x86 ISA.
In late-stage capitalism, they are.