By definition, any collection of source text which is accepted by at least one Conforming C Implementation somewhere in the universe is a Conforming C Program. I think you might have the term "Conforming C Program" confused with "Strictly Conforming C Program" Also, the fact that the return value given to the host environment is undefined does not mean that the behavior of the C program would not be defined. The question of what a host environment does after main() returns is outside the C Standard's jurisdiction.

@supercat "A conforming implementation may have extensions (including additional library functions), provided they do not alter the behavior of any strictly conforming program." /--/ "A conforming program is one that is acceptable to a conforming implementation". The behavior of a strictly conforming program will naturally have its behavior altered in case there is undefined behavior.

I updated the answer with an explanation about the meaning of a conforming program. These are all formal terms and easy to look up, with informative foot notes and everything.

@supercat As for whether the host environment "uses" the return value, this was always true in any version of Unix, Linux, Windows and so on. A programming language designed for the purpose of being the official one for the Unix OS ought to be aware of this by design.

Hence the exit status is undefined but the behavior of the program is defined, and the code is conforming.

@chqrlie Either way it is still UB as per the quoted C90 6.6.6.4.

@Lundin: C90 6.6.6.4 specifies and the value of the function call is used by the caller. But the initial caller of main not necessarily C code, hence not covered by this statement. C90 has 5.1.2.2.3 to cover the initial call to main() that does not use the term undefined behavior, just the termination status returned to the host environment is undefined. It might be more consistent to have write indeterminate in this particular case.

@chqrlie Undefined means undefined behavior. Not indeterminate, not unspecified. So the program might for example crash the host environment upon termination, as far as C is concerned.

I don't think it was the intent of the committee. As a matter of fact, more recent versions of 5.1.2.2.3 use unspecified: C23 5.1.2.2.3 Program termination If the return type of the main function is a type compatible with int, a return from the initial call to the main function is equivalent to calling the exit function with the value returned by the main function as its argument; reaching the } that terminates the main function returns a value of 0. If the return type is not compatible with int, the termination status returned to the host environment is unspecified.

@chqrlie That's just further proof that the behavior is explicitly undefined between C90 to C17.

@Lundin: The normal paradigm in C prior to C89, and which C89 had no intention of changing, was that it was only necessary for a function to return a value if calling code would do something with the value returned, and if function foo() ended with "return bar();", the return value of bar() would only be "used" in cases where foo's caller used the return value from foo. The intention was never to make programmers write extra source code to make compilers generate machine code that would serve no useful purpose.

@Lundin: On some platforms, if control reached the end of function unsigned char foo() when it was invoked via register unsigned char x = foo();, operations with x may behave in a manner not consistent with it holding any value in the range 0 to 255, causing weird things to happen if code tries to do much of anything with the value. The authors of the Standard would have seen no reason to imagine compiler writers generating code that would behave gratuitously weirdly even in cases the value is ultimately ignored, however, and thus would have seen no need to waste ink forbidding that.

@Lundin: In MS-DOS, if a program is invoked from the command line, the return value will be ignored. If invoked from a batch file, it will be ignored unless the batch file explicitly tests ERRORLEVEL. If invoked by soime other program, the return value may be used or ignored at that other program's leisure. Failure to set a return value in main() would make a program unsuitable for purposes where the return value would matter, but the Standard was agnostic as to whether the return value would matter sometimes, always, or never.

There's only 2 versions of C that matter - K&R C (used by the original edition of the book) and ANSI C (used by 2nd edition of the book). There is no 3rd edition of the book. C90 and everything after (and everything mentioned in this answer) is irrelevant.

@supercat What happened before C89 isn't of relevance here since the question is if K&R ever contained a conforming program. Conforming program being a term introduced with C89. It's also of note that K&R explicitly claim that the book was updated to follow C89.

The authors of the Standard did use ink to print the parts quoted in this answer, specifically C90 6.6.6.4 and C90 5.1.2.2.3, so you need not imagine what they printed or not, you could just read the answer posted.

@Brendan Some raised concerns about int main() without return being valid standard C, which is correct in the current version of the language, but not in C90. Therefore I had to cover the changes introduced in C99.

@Lundin: You are, like many people, confusing the definitions of "Strictly Conforming C Program" and "Conforming C Program". Also, anything that happens after execution returns from main() is outside the jurisdiction of the C Standard. The Standard does not say that behavior is undefined; it says the value is undefined. Do you think they wrote "value" rather than "behavior" because they wanted to use three less letters, or what?

@Brendan: What about K&R2 C, which includes some behavioral specifications beyond those mandated in the C Standard?

@Lundin: Nothing would forbid a C implementation from doing something like if (main(argc, argv) > 1) melt_cpu();, but then again nothing would forbid a C implementation from if (main(argc, argv == 0); melt_cpu(); [because the code which invokes the C program's main knows that once the program's task is done the CPU wouldn't be needed for anything else]. The Standard is completely agnostic as to how anything main() might do would influence the likelihood of the CPU turning into a blob of goo once it returns. A program that falls through the end of main() would waive any control...

...it might otherwise have had over what happens later, but from the point of view of the Standard everything that happens once a program returns from main() is "Undefined Behavior" since there is nothing an otherwise-conforming implementation could ever do in such cases that would render it non-conforming.

@supercat These arguments are starting to sound like a broken record. Quoted parts from my answer "C90 6.6.6.4 If a return statement without an expression is executed and the value of the function call is used by the caller, the behavior is undefined. Reaching the } that terminates a function is equivalent to executing a return statement without an expression. " "A conforming program is one that is acceptable to a conforming implementation. A conforming implementation may have extensions, provided they do not alter the behavior of any strictly conforming program."

@Lundin It's not that we're not hearing the arguments you keep repeating over and over: it's that we don't agree with them. But at the same time, I don't expect that any of us will succeed in convincing you that you're wrong, so we're sort of at a stalemate here.

In C99 (ISO 9899:1999) and beyond, the code won't compile This is clearly wrong, as most compilers continued to support implicit int for quite some time after 1999.

@SteveSummit: Many people seen unable to recognize that there was never a consensus among the Committee to "forbid" within non-portable programs many of the program constructs that are forbidden in Strictly Conforming C Program. The compromise between "implementations must squawk if a programmer does X" with "implementations must be allowed to let programmers do X" was "Implementations that want to let programmers do X may do so if they output a diagnostic with the intention that programmers wanting to do X will ignore it".

@supercat I see your point, but I've been wondering: if something like that is true, what do such people think the distinction between "conforming" and "strictly conforming" actually is?

@SteveSummit: A related question would be what level of normative authority the Standard is supposed to exercise over freestanding implementations or non-trivial programs therefor, essentially all of which rely upon constructs upon which the Standard imposes no requirements.

In C99 (ISO 9899:1999) and beyond, the code won't compile because of the implicit int. That's false. Many post-1999 compilers will accept this code.

A correct statement would be, "In ISO 9899:1999 and beyond, the code is not strictly conforming, because of the implicit int."

@SteveSummit What must a C compiler do when it finds an error?

Yes, you linked to that before. Are you asserting that the presence of a diagnostic indicates "lack of acceptance" or nonconformance? Would you then say that the code int main(void) { int x = 0; return 0; } is not strictly conforming, if a compiler issues a diagnostic about the unused variable?

@SteveSummit You seem to confuse mandatory diagnostic messages with optional ones. To give a diagnostic message upon spotting the syntax error main(){ } is not optional in standard C, it's required or the compiler is non-conforming. To warn about unused variables is just an optional quality of implementation thing not required by any standard.

@Lundin: The Standard was a compromise between people who thought certain constructs should be forbidden, and those who thought the constructs were useful. If the Standard had regarded all programs for which it demands a diagnostic as non-conforming, it would have been soundly rejected. There's a reason gcc's -pedantic flag is so named. Many of the conditions diagnosed thereby are useful constructs that some people on the Committee happened not to like, and the diagnostics were added purely to appease those people.

@Lundin It's not that I "confuse mandatory diagnostic messages with optional ones", it's that I reject the notion that the Standard defines any such distinction in the first place. I reject also that such a distinction has any bearing on conformance, let alone strict conformance. I am saying that the fact that certain erroneous constructs require a diagnostic does not imply that presence of a diagnostic implies an erroneous program.

IOW, I believe that a program can be conforming even if it suffers diagnostics.

@supercat The point is that 5.1.1.3 is the very definition of the behavior of a conforming implementation. The question was tagged "language lawyer" for a reason, it's about what the standard says, not about what you think it should say.

@SteveSummit Again, the very definition of conformance is that a diagnostic message must be generated in case of constraint and syntax violations. If following language constraints and syntax does not make a program conforming to the C standard, then what does? I might as well type the source in Java then, and call it conforming C.

@Lundin It is a well-known if not well-liked fact that if there were an otherwise conforming C compiler that had extensions to also accept Java syntax, then yes, Java code could on that basis be considered conforming C code. If you don't like that, it's immaterial: As you pointed out, we don't base these conclusions on what we like or don't like, but on what the Standard says.

@Lundin: One of the reasons many earlier language standards faltered is that their definitions of "conforming programs" limited the range of tasks that such programs could accomplish to a small fraction of the range of tasks for which the languages were already being used. The C Standard sought to avoid this by ensuring that almost anything that people were already doing with C programs could be done by "conforming C programs", but conforming implementations would only be required to meaningfully process "Strictly conforming C Programs".

@Lundin: If the authors of the Standard had been willing to "invent" new constructs, they could usefully have specified that e.g. a conforming program which declares a zero-sized array must include #pragma _STDC_ARRAY_MINIMUM 0, and a conforming implementation must reject any program that contains #pragma _STDC_ARRAY_MINIMUM 1 and attempts to define a zero-sized array. Conforming programs that rely upon any kind of type punning would be required to include a pragma specifying that, and implementations would be required to refrain from making optimizations blocked by such pragmas.

@SteveSummit: And lest anyone think people like us are interpreting the Standard unreasonably loosely, the published Rationale makes clear that the authors of the Standard did not intend to require that implementations actually be useful, and acknowledge that one could contrive a "Conforming C Implementation" that "succeeds at being useless". It further states that the authors thought the potential existence of compiler bugs would make it impractical to require that conforming implementations process a non-trivial subset of programs correctly.

@supercat I don't have my copy of the Standard in front of me, but my memory is that the interpretation of all this was intended to be a happy medium, not collapsing to either slippery-slope extreme. It wasn't intended that the only conforming programs be strictly-conforming programs; as you said, that'd be useless. But it wasn't intended that conforming implementations would go nuts with their extensions such that, in the reductio ad absurdum case, Java code could be considered as "conforming C code", either.

(cont'd) No, it was assumed that conforming implementations would tend to limit their extensions to things consonant with the "Spirit of C". And I haven't gotten the impression that the spirit has been routinely violated. Certainly (and returning to the original question here) an otherwise modern compiler that still doggedly accepts implicit int and other pre-C99 or pre-C90 constructs is absolutely maintaining the Spirit of C.

@SteveSummit: The intention of the Standard was fundamentally to view compiler's treatment of many situations as a "quality of implementation" issue. Consider a construct like int a[5][5]; ... a[0][x] = 3;. The authors of the Standard recognized that there were were programs that relied upon the ability to access all 25 elements of the array, but that if a program wasn't intending to perform any cross-row access, it might be useful to trap if x wasn't in the range 0..4, or perform optimizations that assume the operation won't disturb rows other than row 0.

@SteveSummit: The authors of the Standard recognize that each approach would make implementations more suitable for some tasks and less suitable for others. Code which relied upon the first approach should be viewed as "non-portable", but that doesn't imply any judgment that such code was "erroneous". I think the intention was that in places where the Standard characterized an action as UB, compilers would process it as they would have done if the Standard didn't exist at all.