I read this line in a book:

It is provably impossible to build a compiler that can actually determine whether or not a C++ function will change the value of a particular variable.

The paragraph was talking about why the compiler is conservative when checking for const-ness.

Why is it impossible to build such a compiler?

The compiler can always check if a variable is reassigned, a non-const function is being invoked on it, or if it is being passed in as a non-const parameter...

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    First thing that comes to my mind is dynamic link libraries. If I compile code on my machine, and you compile code on your machine, and we link them at run time, how could your compiler know if I modified variables or not? – Mooing Duck Jul 1 '13 at 17:20
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    @MooingDuck Exactly this. More broadly, the compiler does not compile the function individually, but compiles it as part of a broader picture which may not all be within the compiler's scope. – called2voyage Jul 1 '13 at 17:24
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    "impossible" may be an overstatement - "computationally infeasible" (as in NP-hard) may be a better characterization, but is a little harder for the student to grasp. Imagine a linked list or other abstract data structure. If I call a function that changes one node in that list/tree/whatever, how could a compiler ever hope to prove exactly which node got modified (and maybe more importantly, which ones didn't) without basically fully simulating the program with the expected input, all while not taking 3 days to compile one source file... – twalberg Jul 1 '13 at 17:36
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    @twalberg Impossible is not an overstatement, the Halting problem applies here as several answers explain. It is simply not possible to algorithmically fully analyze a general program. – Fiktik Jul 1 '13 at 18:42
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    @twalberg Compilers that only compile a subset of valid programs aren't very useful. – Caleb Jul 1 '13 at 19:03

13 Answers 13


Why is it impossible to build such a compiler?

For the same reason that you can't write a program that will determine whether any given program will terminate. This is known as the halting problem, and it's one of those things that's not computable.

To be clear, you can write a compiler that can determine that a function does change the variable in some cases, but you can't write one that reliably tells you that the function will or won't change the variable (or halt) for every possible function.

Here's an easy example:

void foo() {
    if (bar() == 0) this->a = 1;

How can a compiler determine, just from looking at that code, whether foo will ever change a? Whether it does or doesn't depends on conditions external to the function, namely the implementation of bar. There's more than that to the proof that the halting problem isn't computable, but it's already nicely explained at the linked Wikipedia article (and in every computation theory textbook), so I'll not attempt to explain it correctly here.

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    @mrsoltys, quantum computers are "only" exponentially faster for some problems, they can not solve undecidable problems. – zch Jul 1 '13 at 18:52
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    @mrsoltys Those exponentially complicated algorithms (like factoring) is perfect for quantum computers, but halting problem is a logical dilemma, it's not computable no matter what kind of "computer" you have. – user1032613 Jul 1 '13 at 18:56
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    @mrsoltys, just to be a smartass, yes, it would change. Unfortunately, it would mean the algorithm is both terminated and still running, unfortunately, you can't tell which without directly observing, by which you affect the actual state. – Nathan Ernst Jul 1 '13 at 19:11
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    @ThorbjørnRavnAndersen: O.K., so, suppose I'm executing a program. How exactly do I determine whether it will terminate? – ruakh Jul 1 '13 at 21:09
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    @ThorbjørnRavnAndersen But if you actually execute the program, and it doesn't terminate (e.g. an infinite loop), you will never find out that it doesn't terminate... you just keep on executing one more step, because it could be the last one... – MaxAxeHax Jul 1 '13 at 21:33

Imagine such compiler exists. Let's also assume that for convenience it provides a library function that returns 1 if the passed function modifies a given variable and 0 when the function doesn't. Then what should this program print?

int variable = 0;

void f() {
    if (modifies_variable(f, variable)) {
        /* do nothing */
    } else {
        /* modify variable */
        variable = 1;

int main(int argc, char **argv) {
    if (modifies_variable(f, variable)) {
        printf("Modifies variable\n");
    } else {
        printf("Does not modify variable\n");

    return 0;
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    Nice! The I am a liar paradox as written by a programmer. – Krumelur Jul 1 '13 at 20:07
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    It's actually just a nice adaption of the famous proof for undecidability of the halting problem. – Konstantin Weitz Jul 1 '13 at 21:04
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    In this concrete case "modifies_variable" should return true: There's at least one execution path in which the variable is indeed modified. And that execution path is reached after a call to an external, non-deterministic function - so whole function is non-deterministic. For these 2 reasons, the compiler should take the pesimistic view and decide it does modify the variable. If the path to modifying the variable is reached after a deterministic comparison (verifiable by the compiler) yields false (i.e. "1==1") then compiler could safely say such function never modifies variable – Joe Pineda Jul 1 '13 at 23:10
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    @JoePineda: The question is whether f modifies the variable — not whether it could modify the variable. This answer is correct. – Neil G Jul 2 '13 at 5:27
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    @JoePineda: nothing prevents me from copy/pasting the code of modifies_variable from the compiler source, totally nullifying your argument. (assuming open-source, but the point should be clear) – orlp Jul 4 '13 at 0:32

Don't confuse "will or will not modify a variable given these inputs" for "has an execution path which modifies a variable."

The former is called opaque predicate determination, and is trivially impossible to decide - aside from reduction from the halting problem, you could just point out the inputs might come from an unknown source (eg. the user). This is true of all languages, not just C++.

The latter statement, however, can be determined by looking at the parse tree, which is something that all optimizing compilers do. The reason they do is that pure functions (and referentially transparent functions, for some definition of referentially transparent) have all sorts of nice optimizations that can be applied, like being easily inlinable or having their values determined at compile-time; but to know if a function is pure, we need to know if it can ever modify a variable.

So, what appears to be a surprising statement about C++ is actually a trivial statement about all languages.

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    This is the best answer imho, it's important to make that distinction. – UncleZeiv Jul 2 '13 at 9:45
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    +1, good answer. – LarsH Jul 2 '13 at 11:10
  • "trivially impossible" ? – Kip Jul 5 '13 at 15:26
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    @Kip "trivially impossible to decide" probably means "impossible to decide, and the proof is trivial". – fredoverflow Mar 26 '14 at 21:54

I think the key word in "whether or not a C++ function will change the value of a particular variable" is "will". It is certainly possible to build a compiler that checks whether or not a C++ function is allowed to change the value of a particular variable, you cannot say with certainty that the change is going to happen:

void maybe(int& val) {
    cout << "Should I change value? [Y/N] >";
    string reply;
    cin >> reply;
    if (reply == "Y") {
        val = 42;
  • "It is certainly possible to build a compiler that checks whether or not a C++ function can change the value of a particular variable" No, it is not. See Caleb's answer. For a compiler to know if foo() can change a, it would have to know if it is possible for bar() to return 0. And there is no computable function that can tell all possible return values of any computable function. So there exist code paths such that the compiler won't be able to tell if they will ever be reached. If a variable is changed only in a code path that can't be reached it won't change, but a compiler won't detect it – Martin Epsz Jul 1 '13 at 18:30
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    @MartinEpsz By "can" I mean "is allowed to change", not "can possibly change". I believer that this is what OP had in mind when talking about const-ness checks. – dasblinkenlight Jul 1 '13 at 18:33
  • @dasblinkenlight I would have to agree that I believe the OP may have meant the first one, "is allowed o change", or "may or may not change" vs. "will definitely not change". Of course I can't think of a scenario where this would be an issue. You could even modify the compiler to simply answer "may change" on any function containing either the identifier or a call to a function which has a "may change" answer attribute. That said, C and C++ are horrible languages to try this with, since they have such a loose definition of things. I think this is why const-ness would be an issue in C++ at all. – DDS Jul 2 '13 at 21:35
  • @MartinEpsz: "And there is no computable function that can tell all possible return values of any computable function". I think that checking "all possible return values" is an incorrect approach. There are mathematical systems (maxima, mathlab) that can solve equations, which means it would make sense to apply similar approach to functions. I.e. treat it as an equation with several unknowns. The problems are flow control + side effects => unsolvable situations. IMO, without those (functional language, no assignment/side effects), it would've possible to predict which path program will take – SigTerm Jul 2 '13 at 23:36
  • Should read if (reply == "Y") { instead of if (reply == Y) {... – Pierre Arnaud Jul 3 '13 at 7:13

I don't think it's necessary to invoke the halting problem to explain that you can't algorithmically know at compile time whether a given function will modify a certain variable or not.

Instead, it's sufficient to point out that a function's behavior often depends on run-time conditions, which the compiler can't know about in advance. E.g.

int y;

int main(int argc, char *argv[]) {
   if (argc > 2) y++;

How could the compiler predict with certainty whether y will be modified?


It can be done and compilers are doing it all the time for some functions, this is for instance a trivial optimisation for simple inline accessors or many pure functions.

What is impossible is to know it in the general case.

Whenever there is a system call or a function call coming from another module, or a call to a potentially overriden method, anything could happen, included hostile takeover from some hacker's use of a stack overflow to change an unrelated variable.

However you should use const, avoid globals, prefer references to pointers, avoid reusing variables for unrelated tasks, etc. that will makes the compiler's life easier when performing aggressive optimisations.

  • Finally and yes. – SChepurin Jul 2 '13 at 13:04
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    If I recall it correctly, that's the whole point of functional programming, right? By using only purely deterministic, no side-effects functions, compilers are free to do aggressive optimizations, pre-execution, post-execution, memoization and even execution at compile time. The point that I think a lot of the answerers are ignoring (or confused about) is that it is indeed possible for a well-behaved subset of all programs. And no, this subset isn't trivial or uninteresting, actually it's very useful. But it's indeed impossible for the absolute general case. – Joe Pineda Jul 3 '13 at 23:19
  • Overloading is a compile-time concept. You probably meant "overridden method". – fredoverflow Mar 26 '14 at 22:04
  • @FredOverflow: yes, I mean overriden. Overloading is indeed a compile time concept. Thanks for spotting it (of course if the implementation comes from another compilation unit, the compiler can still have troubles analysing it, but that was not what I meant). I will fix the answer. – kriss Mar 27 '14 at 0:14

There are multiple avenues to explaining this, one of which is the Halting Problem:

In computability theory, the halting problem can be stated as follows: "Given a description of an arbitrary computer program, decide whether the program finishes running or continues to run forever". This is equivalent to the problem of deciding, given a program and an input, whether the program will eventually halt when run with that input, or will run forever.

Alan Turing proved in 1936 that a general algorithm to solve the halting problem for all possible program-input pairs cannot exist.

If I write a program that looks like this:

do tons of complex stuff
if (condition on result of complex stuff)
    change value of x
    do not change value of x

Does the value of x change? To determine this, you would first have to determine whether the do tons of complex stuff part causes the condition to fire - or even more basic, whether it halts. That's something the compiler can't do.


Really surprised that there isn't an answer that using the halting problem directly! There's a very straightforward reduction from this problem to the halting problem.

Imagine that the compiler could tell whether or not a function changed the value of a variable. Then it would certainly be able to tell whether the following function changes the value of y or not, assuming that the value of x can be tracked in all the calls throughout the rest of the program:

foo(int x){

Now, for any program we like, let's rewrite it as:

int y;
    int x;
    run the program normally

Notice that, if, and only if, our program changes the value of y, does it then terminate - foo() is the last thing it does before exiting. This means we've solved the halting problem!

What the above reduction shows us is that the problem of determining whether a variable's value changes is at least as hard as the halting problem. The halting problem is known to be incomputable, so this one must be also.

  • I'm not sure I follow your reasoning, about why our program terminates iff it changes the value of y. Looks to me like foo() returns quickly, and then main() exits. (Also, you're calling foo() without an argument... that's part of my confusion.) – LarsH Jul 2 '13 at 1:16
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    @LarsH: Iff the modified program terminates, the last function it called was f. If y was modified, f was called (the other statements can't change y, since it was only introduced by the modification). Hence, if y was modified, the program terminates. – MSalters Jul 2 '13 at 11:00

As soon as a function calls another function that the compiler doesn't "see" the source of, it either has to assume that the variable is changed, or things may well go wrong further below. For example, say we have this in "foo.cpp":

 void foo(int& x)
    ifstream f("f.dat", ifstream::binary);
    f.read((char *)&x, sizeof(x));

and we have this in "bar.cpp":

void bar(int& x)

How can the compiler "know" that x is not changing (or IS changing, more appropriately) in bar?

I'm sure we can come up with something more complex, if this isn't complex enough.

  • The compiler can know that x is not changing in bar if bar x is passed as pass-by-reference-to-const, right? – Cricketer Jul 1 '13 at 17:30
  • Yes, but if I add a const_cast in foo, it would still make x change - I'd be in breach of the contract that says that you are not to change const variables, but since you can convert anything to "more const", and const_cast exists, the designers of the language surely had the idea in mind that sometimes there are good reasons to believe that const values may need changing. – Mats Petersson Jul 1 '13 at 17:34
  • @MatsPetersson: I believe that if you const_cast you get to keep all the pieces that break because the compiler may, but does not have to compensate for that. – Zan Lynx Jul 1 '13 at 17:45
  • @ZanLynx: Yes, I'm sure that's correct. But at the same time, the cast does exist, which means that someone who designed the language did have some sort of idea that "we may need this at some point" - which means it's not meant to not do anything useful at all. – Mats Petersson Jul 1 '13 at 17:47

It is impossible in general to for the compiler to determine if the variable will be changed, as have been pointed out.

When checking const-ness, the question of interest seems to be if the variable can be changed by a function. Even this is hard in languages that support pointers. You can't control what other code does with a pointer, it could even be read from an external source (though unlikely). In languages that restrict access to memory, these types of guarantees can be possible and allows for more aggressive optimization than C++ does.

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    One thing I wish was supported in languages would be a distinction between ephemeral, returnable, and persistable references (or pointers). Ephemeral references may only be copied to other ephemeral references, returnable ones may be copied to ephemeral or returnable ones, and persistable ones can be copied any which way. The return value of a function will be constrained by the most restrictive of the arguments that are passed as "returnable" parameters. I consider it unfortunate that in many languages, when one passes a reference there's nothing to indicate how long it may be used. – supercat Jul 1 '13 at 17:41
  • That would certainly be useful. There are of course patterns for this, but in C++ (and many other languages) it is always possible to "cheat". – Krumelur Jul 1 '13 at 17:45
  • A major way in which .NET is superior to Java is that it has a concept of an ephemeral reference, but unfortunately there is no way for objects to expose properties as ephemeral references (what I'd really like to see would be a means by which code using a property would pass an ephemeral reference to a code (along with temporary variables) that should be used to manipulate the object. – supercat Jul 1 '13 at 17:57

To make the question more specific I suggest the following set of constraints may have been what the author of the book may have had in mind:

  1. Assume the compiler is examining the behavior of a specific function with respect to const-ness of a variable. For correctness a compiler would have to assume (because of aliasing as explained below) if the function called another function the variable is changed, so assumption #1 only applies to code fragments that don't make function calls.
  2. Assume the variable isn't modified by an asynchronous or concurrent activity.
  3. Assume the compiler is only determining if the variable can be modified, not whether it will be modified. In other words the compiler is only performing static analysis.
  4. Assume the compiler is only considering correctly functioning code (not considering array overruns/underruns, bad pointers, etc.)

In the context of compiler design, I think assumptions 1,3,4 make perfect sense in the view of a compiler writer in the context of code gen correctness and/or code optimization. Assumption 2 makes sense in the absence of the volatile keyword. And these assumptions also focus the question enough to make judging a proposed answer much more definitive :-)

Given those assumptions, a key reason why const-ness can't be assumed is due to variable aliasing. The compiler can't know whether another variable points to the const variable. Aliasing could be due to another function in the same compilation unit, in which case the compiler could look across functions and use a call tree to statically determine that aliasing could occur. But if the aliasing is due to a library or other foreign code, then the compiler has no way to know upon function entry whether variables are aliased.

You could argue that if a variable/argument is marked const then it shouldn't be subject to change via aliasing, but for a compiler writer that's pretty risky. It can even be risky for a human programmer to declare a variable const as part of, say a large project where he doesn't know the behavior of the whole system, or the OS, or a library, to really know a variable won't change.


Even if a variable is declared const, doesn't mean some badly written code can overwrite it.

//   g++ -o foo foo.cc

#include <iostream>
void const_func(const int&a, int* b)
   b[0] = 2;
   b[1] = 2;

int main() {
   int a = 1;
   int b = 3;

   std::cout << a << std::endl;
   std::cout << a << std::endl;


  • This happens because a and b are stack variables, and b[1] just happens to be the same memory location as a. – Mark Lakata Jul 1 '13 at 23:59
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    -1. Undefined Behavior removes all restrictions on the compiler's behavior. – MSalters Jul 2 '13 at 11:03
  • Unsure about the down vote. This is just an example that goes to the OP's original question about why can't a compiler figure out if something is truly const if everything is labelled const. It is because undefined behavior is a part of C/C++. I was trying to find a different way to answer his question rather than mention the halting problem or external human input. – Mark Lakata Jul 2 '13 at 18:44

To expand on my comments, that book's text is unclear which obfuscates the issue.

As I commented, that book is trying to say, "let's get an infinite number of monkeys to write every conceivable C++ function which could ever be written. There will be cases where if we pick a variable that (some particular function the monkeys wrote) uses, we can't work out whether the function will change that variable."

Of course for some (even many) functions in any given application, this can be determined by the compiler, and very easily. But not for all (or necessarily most).

This function can be easily so analysed:

static int global;

void foo()

"foo" clearly does not modify "global". It doesn't modify anything at all, and a compiler can work this out very easily.

This function cannot be so analysed:

static int global;

int foo()
    if ((rand() % 100) > 50)
        global = 1;
    return 1;

Since "foo"'s actions depends on a value which can change at runtime, it patently cannot be determined at compile time whether it will modify "global".

This whole concept is far simpler to understand than computer scientists make it out to be. If the function can do something different based on things can change at runtime, then you can't work out what it'll do until it runs, and each time it runs it may do something different. Whether it's provably impossible or not, it's obviously impossible.

  • what you say is true, but even for very simple programs for wich everything is known at compile time you won't be able to proove anything, not even that the program will stop. This is the halting problem. For instance you could write a program based on Hailstone Sequences en.wikipedia.org/wiki/Collatz_conjecture and make it return true if it converge to one. Compilers won't be able to do it (as it would overflow in many cases) and even mathematicians don't know if it's true or not. – kriss Jul 13 '13 at 22:04
  • If you mean "there are some very simple looking programs for which you cannot prove anything" I entirely agree. But Turing's classic Halting Problem proof relies essentially on a program itself being able to tell whether it halts in order to set up a contradiction. As this is mathematics not implementation. There are certainly programs it is entirely possible to statically determine at compile time whether a particular variable will be modified, and whether the program will halt. It may not be mathematically provable, but it's practically achievable in certain cases. – El Zorko Jul 14 '13 at 11:37

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