[pjmlp]

Any user of compiled languages cares about Assembly, which is why regardless of the compiled language, an Assembler was always shipped alongside.

Also it isn't a C invention to have the compiler dump the Assembly output instead of object code.

Now the culture that C language constructs in 2026 are still 1:1 to Assembly instructions, that pretty much prevails, despite easy proof that isn't the case at various compiler optimization levels.

Proficient devs, well many still don't know to distinguish what is their compiler, and what ISO says.

[jstimpfle]

It is the case that you can more easily know what happens when you don't use the wrong abstractions but stay in control. Highly-abstracted C++ code basically makes allocations and syscalls in the whitespace between the source code tokens. You can't do systems software like that, you have to roll back the abstractions and roll back the use of pre-canned containers and libraries that you don't understand.

So it's all about understanding and control, not about some idea that C was defined in terms of assembly instructions, which it obviously is not. That's a total strawman.

[pjmlp]

Except modern C also has plenty of abstractions, devs wrongly assume it doesn't.

Then get surprised when it doesn't map to the SIMD/SIMT NUMA machine their code actually executes on.

[uecker]

There is not much real evidence for "devs wrongly assume" and as someone writing numerical code (clusters, NUMA, SIMD, etc.) I think C is still the ideal tool for this.

[pjmlp]

Why should it be, the language doesn't expose any of it.

[uecker]

Assuming you mean the standard does not provide features for numa and simd? It doesn't necessarily have to. I think it is not surprising that you seem always bewildered that people still use C (as per your comments), as it seems you fundamentally do understand neither standardization nor systems programming.

[pjmlp]

I do certainly understand it, by the eyes of C++, Rust, Ada, Object Pascal, Modula-2, D.

[jstimpfle]

such a strawman again... You don't want to be writing explicit platform specific SIMD most of the time. You just want to write a dumb function that doesn't do any non-obvious calls, doesn't cause thread contention, doesn't hide complexity, isn't going to be a nightmare to change later, no surprises.

I am talking about self-inflicted complexity that is entirely within the C(++) machine model. Avoid that complexity and you're pretty good already. Only drop down to concrete hardware arch level where it makes sense. But largely, the C machine model is still very much suited as a model for actual hardware. Writing straightforward obvious code allows you to stay in control of memory layout and the data transformation paths. It easily gets you within <<2x of what you could achieve with hand coded assembler for the >90% of the code that are pretty boring and straightforward. And obviously you couldn't get the work done in time when coding everything in assembler.

[pjmlp]

So abstractions are desired then?

I have seen plenty of self inflicted complexity in C, starting in the golden age of Yourdon Structured Method, and all those libraries that replicate C++ basic features with preprocessor macros.

[jstimpfle]

Most of these methods and ideas turned out to not work, neither in messy C libraries, nor in C++ or other languages.