> By definition, C and C++ are memory safe as long as you follow the rules.
This statement doesn't make sense to me.
Memory safety is a property of language implementations, which is all about what happens when the programmer does not follow the rules.
> The problem is that the rules cannot be automatically checked and in practice are the source of unenumerable issues from straight up bugs to subtle standards violations that trigger the optimizer to rewrite your code into what you didn’t intend.
They can be automatically checked and Fil-C proves this. The prior art had already proved it before Fil-C existed.
> But yes, fil-c is a huge improvement (afaik though it doesn’t solve the UB problem - it just guarantees you can’t have a memory safety issue as a result)
Fil-C doesn't have UB. If you find anything that looks like UB to you, please file a GH issue.
Let's also be clear that you're referring to nasal demons specifically, not UB generally. In some contexts, like CPU ISAs, UB means a trap, rather than nasal demons. So let's use the term "nasal demons".
C and C++ only have nasal demons because:
- Policy decisions. For example, making signed integer addition have nasal demons is because someone wanted to cook a benchmark.
- Lack of memory safety in most implementations, combined with a refusal to acknowledge what happens when the wrong kind of memory access occurs. (Note that CPU ISAs like x86 and ARM are not memory safe, but have no nasal demons, because they do define what happens when any kind of memory access occurs.)
So anyway, Fil-C has no nasal demons, because:
- I turned off all of those silly policy decisions for cooking benchmarks.
- The memory safety means that I define what happens when the wrong kind of memory access occurs: the program gets killed with a panic.
First, let me say that I really respect the work you’re doing in fil-c. Nothing I say is intended as a knock and you’re doing fantastic engineering work moving the field forward and I hope you find success.
That’s good to know about nasal demons. Are you saying you somehow inhibit the optimizer from injecting a security vulnerability due to UB ala https://www.cve.org/CVERecord?id=CVE-2009-1897 ? I’m kinda curious how you trick LLVM into not optimizing through UB since it’s UB model is so tuned to the C/C++ standard.
Anyway, Fil-C is only currently working on (a lot of, but not all yet I think right?) Linux userspace while C and C++ as a standard language definition span a lot more environments. I agree the website should call out Fil-C as memory safe but I think it’s also fair to say that Fil-C is more an independent dialect of C/C++ (eg you do have to patch some existing software) - IMHO it’s too confusing for communicating out to say that C/C++ is memory safe and I’d rather it say something like Fil-C is memory safe or C/C++ code running under Fil-C is memory safe.
> Memory safety is a property of language implementations, which is all about what happens when the programmer does not follow the rules.
By this argument no language is memory safe because every language has bugs that can result in memory safety issues. Certainly rustc definitely has soundness issues that haven’t been fixed and I believe this is also true of Python, JavaScript, etc but I think it’s an unhelpful bar or framing of the problem. The language itself is memory safe and any safety issues within the language spec or implementation are a bug to be fixed. That isn’t true of C/C++ where there’s going to always exist environments where it’s impossible to even have a memory safe implementation (eg microcontrollers) let alone mandate one in the spec. And also fil-C does have a performance impact so some software may not ever be a good fit for it (eg video encoders/decoders). For example, a non memory safe conforming implementation of JavaScript is not possible. Same goes for safe rust, Python or Java. By comparison that isn’t true for c/c++.
At a certain point, it's a trade-off. A systems language will offer facilities that can be used to break encapsulation and abstractions, and access memory as a sequences of bytes. (Anything capable of file I/O on stock Linux can write to /proc/self/mem, for example.) The difference to (typical) C and C++ is that these facilities are less likely to be invoked by accident.
Reasonable people will disagree about what memory safety (and type safety) mean to them. Personally, bounds checking for arrays and strings, some solution for safe deallocation of memory, and an obviously correct way to write manual bounds checks is more interesting than (for example) no access to machine addresses and no FFI.
Regarding bounds checking, GNAT offers some interesting (non-standard) options: https://gcc.gnu.org/onlinedocs/gnat_ugn/Management-of-Overfl...
Basically, you can write a bounds check in the most natural way, and the compiler will evaluate the check with infinite precision (or almost, to improve performance). In standard, you might end up with an exception in some corner cases where the check should pass. I wish more languages would offer something like this. Among widely used languages, only Python offers this capability because it uses infinite-precision integers.
> Are you saying you somehow inhibit the optimizer from injecting a security vulnerability due to UB ala https://www.cve.org/CVERecord?id=CVE-2009-1897 ? I’m kinda curious how you trick LLVM into not optimizing through UB since it’s UB model is so tuned to the C/C++ standard.
Yes that is inhibited. There’s no trick. LLVM (and other compilers) choose to do those stupid things by policy, and the policy can be turned off. It’s not even hard to do it.
> Fil-C is more an independent dialect of C/C++ (eg you do have to patch some existing software)
Fil-C is not a dialect. The patches are similar to what you’d have to do if you were porting a C program to a new CPU architecture or a different compiler.
> By this argument no language is memory safe because every language has bugs that can result in memory safety issues.
You rebutted this argument for me:
> any safety issues within the language spec or implementation are a bug to be fixed
Exactly this. A memory safe language implementation treats outstanding memory safety issues as a bug to be fixed.
This is what makes almost all JS implementations, and Fil-C, memory safe.
This statement doesn't make sense to me.
Memory safety is a property of language implementations, which is all about what happens when the programmer does not follow the rules.
> The problem is that the rules cannot be automatically checked and in practice are the source of unenumerable issues from straight up bugs to subtle standards violations that trigger the optimizer to rewrite your code into what you didn’t intend.
They can be automatically checked and Fil-C proves this. The prior art had already proved it before Fil-C existed.
> But yes, fil-c is a huge improvement (afaik though it doesn’t solve the UB problem - it just guarantees you can’t have a memory safety issue as a result)
Fil-C doesn't have UB. If you find anything that looks like UB to you, please file a GH issue.
Let's also be clear that you're referring to nasal demons specifically, not UB generally. In some contexts, like CPU ISAs, UB means a trap, rather than nasal demons. So let's use the term "nasal demons".
C and C++ only have nasal demons because:
- Policy decisions. For example, making signed integer addition have nasal demons is because someone wanted to cook a benchmark.
- Lack of memory safety in most implementations, combined with a refusal to acknowledge what happens when the wrong kind of memory access occurs. (Note that CPU ISAs like x86 and ARM are not memory safe, but have no nasal demons, because they do define what happens when any kind of memory access occurs.)
So anyway, Fil-C has no nasal demons, because:
- I turned off all of those silly policy decisions for cooking benchmarks.
- The memory safety means that I define what happens when the wrong kind of memory access occurs: the program gets killed with a panic.