average c++ dev
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I don't think that casting a range of bits as some other arbitrary type "is a bug nobody sees coming".
C++ compilers also warn you that this is likely an issue and will fail to compile if configured to do so. But it will let you do it if you really want to.
That's why I love C++
"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
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Not only that, but everyone who sees that code later is going to waste so much time trying to understand it. That includes future you.
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But it will let you do it if you really want to.
Now, I've seen this a couple of times in this post. The idea that the compiler will let you do anything is so bizarre to me. It's not a matter of being allowed by the software to do anything. The software will do what you goddamn tell it to do, or it gets replaced.
WE'RE the humans, we're not asking some silicon diodes for permission. What the actual fuck?!? We created the fucking thing to do our bidding, and now we're all oh pwueez mr computer sir, may I have another ADC EAX, R13? FUCK THAT! Either the computer performs like the tool it is, or it goes the way of broken hammers and lawnmowers!
wrote on last edited by [email protected]This comment makes me want to reformat every fucking thing i use and bend it to -my- will like some sort of technomancer
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"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
You shouldn't have any warnings. They can be totally benign, but when you get used to seeing warnings, you will not see the one that does matter.
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I don't think that casting a range of bits as some other arbitrary type "is a bug nobody sees coming".
C++ compilers also warn you that this is likely an issue and will fail to compile if configured to do so. But it will let you do it if you really want to.
That's why I love C++
As it should be. Airbags should go off when you crash, not when you drive near the edge of a cliff.
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"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
Ignoring warnings is really not a good way to deal with it. If a compiler is bitching about something there is a reason to.
A lot of times the devs are too overworked or a little underloaded in the supply of fucks to give, so they ignore them.
In some really high quality codebases, they turn on "treat warnings as errors" to ensure better code.
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"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
wrote on last edited by [email protected]Depends on the age of the codebase, the age of the compiler and the culture of the team.
I’ve arrived into a team with 1000+ warnings, no const correctness (code had been ported from a C codebase) and nothing but C style casts. Within 6 months, we had it all cleaned up but my least favourite memory from that time was “I’ll just make this const correct; ah, right, and then this; and now I have to do this” etc etc. A right pain.
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Safe in what regards? You're being cagey on purpose. In terms of memory there is a guarantee that Rust is automatically safer than c++, period. Im business Logic? Sure you're right
wrote on last edited by [email protected]No there is not. Borrow checking and RAII existed in C++ too and there is no formal axiomatic proof of their safety in a general sense. Only to a very clearly defined degree.
In fact, someone found memory bugs in Rust, again, because it is NOT soundly memory safe.
Dart is soundly Null-safe. Meaning it can never mathematically compile null unsafe code unless you explicitly say you're OK with it. Kotlin is simply Null safe, meaning it can run into bullshit null conditions.
The same thing with Rust: don't let it lull you into a sense of security that doesn't exist.
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My issue is C++ will "let me do it", and by that I mean "you didn't cast here (which is UB), so I will optimize out a null check later, and then segfault in a random location"
wrote on last edited by [email protected]Always check your programs on -O0 or pay the price
Shit gets really fun when you find out your code is a edge case for compiler optimization and should never be optimized away (although this is very very rare for -O2)
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But does it have cargo-mommy
TIL there's more than one kind of "vibe" coding.
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But does it have cargo-mommy
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I actually do like that C/C++ let you do this stuff.
Sometimes it's nice to acknowledge that I'm writing software for a computer and it's all just bytes. Sometimes I don't really want to wrestle with the ivory tower of abstract type theory mixed with vague compiler errors, I just want to allocate a block of memory and apply a minimal set rules on top.
wrote on last edited by [email protected]100%. In my opinion, the whole "build your program around your model of the world" mantra has caused more harm than good. Lots of "best practices" seem to be accepted without any quantitative measurement to prove it's actually better. I want to think it's just the growing pains of a young field.
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You shouldn't have any warnings. They can be totally benign, but when you get used to seeing warnings, you will not see the one that does matter.
I know, that's why it bothered me that it seemed to be "policy" to just ignore them.
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Ignoring warnings is really not a good way to deal with it. If a compiler is bitching about something there is a reason to.
A lot of times the devs are too overworked or a little underloaded in the supply of fucks to give, so they ignore them.
In some really high quality codebases, they turn on "treat warnings as errors" to ensure better code.
I know that should be the philosophy, but is it? In my experience it seems to be normal to ignore warnings.
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Depends on the age of the codebase, the age of the compiler and the culture of the team.
I’ve arrived into a team with 1000+ warnings, no const correctness (code had been ported from a C codebase) and nothing but C style casts. Within 6 months, we had it all cleaned up but my least favourite memory from that time was “I’ll just make this const correct; ah, right, and then this; and now I have to do this” etc etc. A right pain.
So, did you get it down to 0 warnings and manage to keep it there? Or did it eventually start creeping up again?
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"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
None. We treat warnings as compiler errors with a compiler flag
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"C++ compilers also warn you..."
Ok, quick question here for people who work in C++ with other people (not personal projects). How many warnings does the code produce when it's compiled?
I've written a little bit of C++ decades ago, and since then I've worked alongside devs who worked on C++ projects. I've never seen a codebase that didn't produce hundreds if not thousands of lines of warnings when compiling.
I mostly see warnings when compiling source code of other projects. If you get a warning as a dev, it's your responsibility to deal with it. But also your risk, if you don't. I made it a habit to fix every warning in my own projects. For prototyping I might ignore them temporarily. Some types of warnings are unavoidable sometimes.
If you want to make yourself not ignore warnings, you can compile with
-Werrorif using GCC/G++ to make the compiler a pedantic asshole that doesn't compile until you fix every fucking warning. Not advisable for drafting code, but definitely if you want to ship it. -
I used to love C++ until I learned Rust. Now I think it is obnoxious, because even if you write modern C++, without raw pointers, casting and the like, you will be constantly questioning whether you do stuff right. The spec is just way too complicated at this point and it can only get worse, unless they choose to break backwards compatibility and throw out the pre C++11 bullshit
I suppose it's a matter of experience and practise. The more you wotk with it the better you get. As usual with all things one can learn.
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Not only that, but everyone who sees that code later is going to waste so much time trying to understand it. That includes future you.
That what comments and documentation are for.
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No there is not. Borrow checking and RAII existed in C++ too and there is no formal axiomatic proof of their safety in a general sense. Only to a very clearly defined degree.
In fact, someone found memory bugs in Rust, again, because it is NOT soundly memory safe.
Dart is soundly Null-safe. Meaning it can never mathematically compile null unsafe code unless you explicitly say you're OK with it. Kotlin is simply Null safe, meaning it can run into bullshit null conditions.
The same thing with Rust: don't let it lull you into a sense of security that doesn't exist.
Borrow checking...existed in C++ too
Wat? That's absolutely not true; even today lifetime-tracking in C++ tools is still basically a research topic.
...someone found memory bugs in Rust, again, because it is NOT soundly memory safe.
It's not clear what you're talking about here. In general, there are two ways that a language promising soundness can be unsound: a bug in the compiler, or a problem in the language definition itself permitting unsound code. (
unsafechanges the prerequisites for unsoundness, placing more burden on the user to ensure that certain invariants are upheld; if the code upholds these invariants, but there's still unsoundness, then that falls into the "bug in Rust" category, but unsoundness of incorrectunsafecode is not a bug in Rust.)Rust has had both types of bugs. Compiler bugs can be (and are) fixed without breaking (correct) user code. Bugs in the language definition are, fortunately, fixable at edition boundaries (or in rare cases by making a small breaking change, as when the behavior of
extern "C"changed).
