> 9 of the 10 senior developers didn't know how many bits were in basic elemetary types
That's likely thanks to C which goes to great pains to not specify the size of the basic types. For example, for 64 bit architectures, "long" is 32 bits on the Mac and 64 bits everywhere else.
The net result of that is I never use C "long", instead using "int" and "long long".
This mess is why D has 32 bit ints and 64 bit longs, whether it's a 32 bit machine or a 64 bit machine. The result was we haven't had porting problems with integer sizes.
It's substantially worse on the JVM. One's intuition from C just fails when you have to think about references vs primitives, and the overhead of those (with or without compressed OOPs).
I've met very few folks who understand the overheads involved, and how extreme the benefits can be from avoiding those.
Conversely I've met many folks who come into managed environments and piss away time trying to wrangle the managed system into how they think it should work, instead of accepting that clever people wrote it and guidelines when followed result in acceptable outcomes.
The sort of insane stuff I've seen on the dotnet repo where people are trying to tear apart the entire type system just because they think they've cracked some secret performance code.
>on the dotnet repo
You mean the .net compiler/runtime itself? I haven't looked at it, but isn't that the one place you'd expect to see weirdly low-level C# code?
In what way is it worse? The range of values they can contain is well-specified.
And you have a frame with an operands stack where you should be able to store at least a 32-bit value. `double` would just fill 2 adjacent slots.
And references are just pointers (possibly not using the whole of the value as an address, but as flags for e.g. the GC) pointing to objects, whose internal structure is implementation detail, but usually having a header and the fields (that can again be reference types).
Pretty standard stuff, heap allocating stuff is pretty common in C as well.
And unlike C, it will run the exact same way on every platform.
My favourite JVM trivia, although I openly admit I don't know if it's still true, is the fact that the size of a boolean is not defined.
If you ask a typical grad the size of a bool they will inevitably say one bit, but, CPUs and RAM, etc don't work like that, typically they expect WORD sized chunks of memory - meaning that the boolean size of one but becomes a WORD sized chunk, assuming that it hasn't been packed
". While it represents one bit of information, it is typically implemented as 1 byte in arrays, and often 4 bytes (an int) or more as a standalone variable on the stack "
That's a reasonable answer. But, I meant they seemed to have little understanding or interest. I don't interview much, and I'm probably a poor interviewer. But, I guess I was expecting some discussion.
I ran into some comp sci graduates in the early 80's who did not know what a "register" was.
To be fair, though, I come up short on a lot of things comp sci graduates know.
It's why Andrei Alexandrescu and I made a good team. I was the engineer, and he the scientist. The yin and the yang, so to speak.
Oooh, saw Andrei's name pop up and remember his books on C++ back in the day .. ran into a systems engineer a while ago that asked why during a tech review asked why some data size wasn't 1000 instead of 1024.. like err ??
Even more fun is pointers, especially when windows / macos were switching from 32-bits to 64-bits (in different ways).
Microsoft tried valiantly to make Win16 code portable to Win32, and Win32 to Win64. But it failed miserably, apparently because the programmers had never ported 16 bit C to 32 bit C, etc., and picked all the wrong abstractions.
> Even more fun is pointers, especially when windows / macos were switching from 32-bits to 64-bits (in different ways).
And yet even more of a fun time with porting pointer code was going from the various x86 memory models[0] to 32-bit. Depending on the program, the pain was either near, far, or huge... :-D
0 - https://en.wikipedia.org/wiki/X86_memory_models
Why did they design it like that? It must have seemed like a good idea at the time.
In ancient computing times, which is when C was birthed, the size of integers at the hardware level and their representation was much more diverse than it is today. The register bit-width was almost arbitrary, not the tidy powers of 2 that everyone is accustomed to today.
The integer representation wasn't always two's complement in the early days of computing, so you couldn't even assume that. C++ only required integer representations to be two's complement as of C++20, since the last architectures that don't work this way had effectively been dead for decades.
In that context, an 'int' was supposed to be the native word size of an integer on a given architecture. A long time ago, 'int' was an abstraction over the dozen different bit-widths used in real hardware. In that context, it was an aid to portability.
Was it possible to write a program taking into account this diversity, and have it work properly?
C is a portable language, in that programs will likely compile successfully on a different architecture. Unfortunately, that doesn't mean they will run properly, as the semantics are not portable.
So what’s the point of having portable syntax, but not portable semantics?
C certainly gives the illusion of portability. I recall a fellow who worked on DSP programming, where chars and shorts and ints and longs were all 32 bits. He said C was great because that would compile.
I suggested to him that he'd have a hard time finding any existing C code that ran correctly on it. After all, how are you going to write a byte to memory if you've only got 32 bit operations?
Anyhow, after 20 years of programming C, I took what I learned and applied it to D. The integral types are specified sizes, and 2's complement.
One might ask, what about 16 bit machines? Instead of trying to define how this would work in official D, I suggested a variant of D where the language rules were adapted to 16 bits. This is not objectively worse than what C does, and it works fine, and the advantage is there is no false pretense of portability.