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I'm not too deeply rooted in the very formal side of static code analysis, hence this question.

A couple of years ago I read that distinguishing code from data using static code analysis is equivalent to the Halting Problem. (Citation needed, but I don't have it anymore. stackoverflow has threads on this here or here.) At least for common computer architectures based on the Von Neumann architecture where code and data share the same memory this seemed to make sense.

Now I'm looking at the static analysis of C/C++ code and pointer analysis; the program does not execute. Somehow I have a feeling that tracking all creations and uses of pointer values statically is similar to the Halting Problem because I can not determine if a given value in memory is a pointer value, i.e. I can not track the value-flow of pointer values through memory. Alias analysis may narrow down the problem, but it seems to become less useful in the face of multi-threaded code.

(One might even consider tracking arbitrary values, not just pointers: constructing a complete value-flow for any given "interesting" value seems equivalent to the Halting Problem.)

As this is just a hunch, my question is: are the more formal findings on this that I can refer to? Am I mistaken?

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@Dukeling: Well, static analysis seems to imply that the program is not running. I think that the OP is trying to analyze the program looking at the C/C++ source code. Or maybe the generated assembler? –  rodrigo Dec 30 '13 at 22:59
How to ask about the 'halting problem' on StackOverflow, regarding the title filter - no useful answers there though :( –  Digital Trauma Dec 30 '13 at 23:08
The premise of this question is trumped by the intent. You use static analysis to discover problems in code, undefined behavior in particular. So your starting point is assuming that you have a mal-formed program and you cannot make any assumptions that language rules apply. You cannot formulate a theory on a foundation without rules. –  Hans Passant Dec 30 '13 at 23:41
@HansPassant: not sure I grok what you mean? –  Cheers and hth. - Alf Dec 31 '13 at 0:00
@HansPassant Your remark containing the word “assuming” is easily circumvented by limiting oneself to static analyzers that discover the first Undefined Behavior in an execution of the C program on the “abstract machine” that is supposed to be defined by the C standard. You are right that predicting anything after the first UB is unreasonable. There are two articles that cover this in some detail in the proceedings of compare2012.verifythis.org . You should recognize them easily if interested (or just look for the article of which I am a co-author). –  Pascal Cuoq Dec 31 '13 at 2:58

4 Answers 4

You can always code up this:

extern bool some_program_halts();
extern int* invalid_pointer();

#include <iostream>
int main()
    using namespace std;
    if( some_program_halts() ) { cout << *invalid_pointer() << endl; }

Checking whether this program dereferences the invalid pointer is equivalent to finding out whether the call to some_program_halts(), uh, halts.

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It's that simple. :) –  Cheers and hth. - Alf Dec 30 '13 at 23:14
Oh, by the way, just because!, a link to my "Ironclad proof that you are smarter than Roger Penrose". He he. :) –  Cheers and hth. - Alf Dec 30 '13 at 23:27
Agreed. Now let's assume a closed world (where we do have access to all code, and no code is added at runtime. :) –  Jens Dec 31 '13 at 2:31
The above example calls out to two extern functions, i.e. functions whose behavior can not be examined because their definition is missing. That's an open world scenario. In a closed world scenario, all possible (i.e. called/referenced) functions are defined and available to the analysis. –  Jens Dec 31 '13 at 21:39
Oh I didn't mean to imply any missing definitions. From a C++ point of view the keyword extern is technically redundant in the above code. You can just remove it if it seems to indicate "missing". ;-) –  Cheers and hth. - Alf Dec 31 '13 at 21:47

It's almost certainly equivalent, modulo the fact that C is not a turing-equivalent language (a given C implementation is a gigantic finite state machine rather than a turing machine, due to the Representation of Types). Pointers need not be kept in their original representations in objects whose effective type is pointer type; you can examine the representation and perform arbitrary operations on it, for example, encrypting pointers and decrypting them later. Determining whether an arbitrary computation is reversible, or whether two computations are inverses of one another, is (offhand) probably equivalent to determining halting.

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re " C is not a turing-equivalent language", if you mean "turing complete" then that's wrong. the core language does not define any i/o facilities or means to interface with hardware or anything, so as a statement about the core language it's literally true, but totally irrelevant. once you add i/o, however, you get infinite memory. and that observation was made long before Turing's time, even by George Boole. –  Cheers and hth. - Alf Dec 30 '13 at 23:06
C does not define IO facilities that allow addressing unlimited storage; they may exist as an implementation extension, but not something usable by a strictly conforming program. –  R.. Dec 30 '13 at 23:17
POSIX claims not to conflict with ISO C, and requires fseek to fail with EOVERFLOW if the resulting offset is not representable in type long. Assuming this behavior conforms with ISO C (you may dispute that), that destroys one of your best chances of achieving unlimited storage, though perhaps you could argue that it's recoverable by using rewind and repeated getc to position yourself. However even then, the number of times you call getc is limited by the largest number you can otherwise represent; you could apply the principle of using files to store "unlimited size" data... –  R.. Dec 31 '13 at 0:04
@Cheersandhth.-Alf: They are not infinite streams. They're arbitrary stdio FILE streams that, depending on the implementation, may be attached to the same sort of seekable files you obtain with fopen, interactive devices, or something else. In the cases where they're associated with a terminal or pipe, they are entirely one-way and provide no storage at all since the program can never read back what it wrote. –  R.. Dec 31 '13 at 1:46
@Cheersandhth.-Alf Infinite streams stdin and stdout make a terrible offhand example of an infinite ribbon, since a Turing Machine infinite ribbon is something that one can write to and read back the same thing from. One can, however, interface a C program with an infinite ribbon. Such a composite C program + ribbon would be an appropriate Turing Machine. This is not a very insightful statement to make, however, as a finite automaton interfaced with an infinite ribbon is a Turing Machine too. This does not tell us that a C program is more than a finite automaton. –  Pascal Cuoq Dec 31 '13 at 2:53

If I understood you correctly: yes, checking whether a C or C++ program accesses an invalid pointer is equivalent to the halting problem (of a C or C++ program, in any case).

Suppose you had a tool that told you whether a program accessed an invalid pointer, and a program you wanted to check for halting. By adding extra information to each pointer you can make it checkable (at runtime) whether the pointer is valid or not; add such checks, with an infinite loop on failure. You now have a program with no invalid pointer accesses. By replacing all places the program can terminate with an invalid pointer access you get a program which has an invalid pointer access if and only if the original program terminates.

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I don't want to check if a program accesses an invalid pointer, I want to track the flow of a pointer value. It seems to me that tracking that flow from where a pointer value is created to all of its possible uses is equivalent to the Halting Problem because I can not track values statically through memory. –  Jens Jan 1 '14 at 19:40
@Jens: Would this include finding all values? If so, then a similar argument works: assuming you can find all uses of each pointer in your program, add a new pointer, and make it used at every exit. If your detector finds the pointer has been used, your program terminates, otherwise it doesn't. –  Anton Golov Jan 1 '14 at 22:14
Not all values, just select ones. But for those select ones I would want to find all uses. And that is hard considering that the value-flow of values in C/C++ is statically not completely trackable; I can only ever approximate. –  Jens Jan 3 '14 at 2:03
Okay, well, the algorithm I described above would work for checking for halting, so yes, your problem is equivalent to the halting problem. –  Anton Golov Jan 3 '14 at 2:06

Static analysis is almost always an approximation, often provable by reduction to the halting problem with programs like the one in Alf's answer. However, the approximation can err on the side of either false positives or false negatives.

  • A "conservative" static check will only have false negatives. It will never accept a "bad" program, but it will inevitably reject some "sufficiently complicated" good programs.
  • A "liberal" static check will have false positives. Sometimes it accepts a bad program by mistake but (generally) it will also accept all good programs.

Some examples:

  • Java's type system is conservative: a variable with a type T will always contain an instance of type T (or a subtype of T or null) at runtime no matter what.
  • GCC's option to warn about uninitialized variables is liberal: it doesn't find all potential uses of an uninitialized variable. Here's an example of a false positive program.
  • In contrast, Java does a conservative uninitialized variable check for local variables. It refuses to compile the program if it sees any potential execution path using a potentially uninitialized variable.

Liberal checks are often used by compilers to emit warnings and by external static analysis tools. Things like type systems and compiler optimizations tend to rely on conservative checks to be correct.

Many tasks have several reasonable conservative and liberal algorithms of varying accuracy. Alias analysis is certainly one of these.

For more information, see any good compiler textbook, such as the dragon book.

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