Global edit: sorry guys, I got all fired up and wrote a lot of nonsense. Just an old geezer ranting.
I wanted to believe C had been spared, but alas since C11 it has been brought on par with C++. Apparently, knowing what the compiler will do with side effects in expressions requires now to solve a little maths riddle involving a partial ordering of code sequences based on a "is located before the synchronization point of".
I happen to have designed and implemented a few critical real-time embedded systems back in the K&R days (including the controller of an electric car that could send people crashing into the nearest wall if the engine was not kept in check, a 10 tons industrial robot that could squash people to a pulp if not properly commanded, and a system layer that, though harmless, would have a few dozen processors suck their data bus dry with less than 1% system overhead).
I might be too senile or stupid to get the difference between undefined and unspecified, but I think I still have a pretty good idea of what concurrent execution and data access mean. In my arguably informed opinion, this obsession of the C++ and now C guys with their pet languages taking over synchronization issues is a costly pipe dream. Either you know what concurrent execution is, and you don't need any of these gizmos, or you don't, and you would do the world at large a favour not trying to mess with it.
All this truckload of eye-watering memory barrier abstractions is simply due to a temporary set of limitations of the multi-CPU cache systems, all of which can be safely encapsulated in common OS synchronization objects like, for instance, the mutexes and condition variables C++ offers.
The cost of this encapsulation is but a minute drop in performances compared with what a use of fine grained specific CPU instructions could achieve is some cases.
volatile keyword (or a
#pragma dont-mess-with-that-variable for all I, as a system programmer, care) would have been quite enough to tell the compiler to stop reordering memory accesses.
Optimal code can easily be produced with direct asm directives to sprinkle low level driver and OS code with ad hoc CPU specific instructions. Without an intimate knowledge of how the underlying hardware (cache system or bus interface) works, you're bound to write useless, inefficient or faulty code anyway.
A minute adjustment of the
volatile keyword and Bob would have been everybody but the most hardboiled low level programers' uncle.
Instead of that, the usual gang of C++ maths freaks had a field day designing yet another incomprehensible abstraction, yielding to their typical tendency to design solutions looking for non existent problems and mistaking the definition of a programming language with the specs of a compiler.
Only this time the change required to deface a fundamental aspect of C too, since these "barriers" had to be generated even in low level C code to work properly. That, among other things, wrought havoc in the definition of expressions, with no explanation or justification whatsoever.
As a conclusion, the fact that a compiler could produce a consistent machine code from this absurd piece of C is only a distant consequence of the way C++ guys coped with potential inconsistencies of the cache systems of the late 2000s.
It made a terrible mess of one fundamental aspect of C (expression definition), so that the vast majority of C programmers - who don't give a damn about cache systems, and rightly so - is now forced to rely on gurus to explain the difference between
a = b() + c() and
a = b + c.
Trying to guess what will become of this unfortunate array is a net loss of time and efforts anyway. Regardless of what the compiler will make of it, this code is pathologically wrong. The only responsible thing to do with it is send it to the bin.
Conceptually, side effects can always be moved out of expressions, with the trivial effort of explicitly letting the modification occur before or after the evaluation, in a separate statement.
This kind of shitty code might have been justified in the 80's, when you could not expect a compiler to optimize anything. But now that compilers have long become more clever than most programmers, all that remains is a piece of shitty code.
I also fail to understand the importance of this undefined / unspecified debate. Either you can rely on the compiler to generate code with a consistent behaviour or you can't. Whether you call that undefined or unspecified seems like a moot point.
In my arguably informed opinion, C is already dangerous enough in its K&R state. A useful evolution would be to add common sense safety measures. For instance, making use of this advanced code analysis tool the specs force the compiler to implement to at least generate warnings about bonkers code, instead of silently generating a code potentially unreliable to the extreme.
But instead the guys decided, for instance, to define a fixed evaluation order in C++17. Now every software imbecile is actively incited to put side effects in his/her code on purpose, basking in the certainty that the new compilers will eagerly handle the obfuscation in a deterministic way.
K&R was one of the true marvels of the computing world. For twenty bucks you got a comprehensive specification of the language (I've seen single individuals write complete compilers just using this book), an excellent reference manual (the table of contents would usually point you within a couple of pages of the answer to your question), and a textbook that would teach you to use the language in a sensible way. Complete with rationales, examples and wise words of warning about the numerous ways you could abuse the language to do very, very stupid things.
Destroying that heritage for so little gain seems like a cruel waste to me. But again I might very well fail to see the point completely.
Maybe some kind soul could point me in the direction of an example of new C code that takes a significant advantage of these side effects?