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Let me exemplify this,

int a = 100;
int b = a;

int main(int argc, char **argv, char ** env)
  printf("The value of b=%d\r\n",b);

  return 0;

Now, I get the compilation error as expected.

[joshis1@localhost global_var]$ gcc global_var.c -o global_var.out
global_var.c:4:1: error: initializer element is not constant
 int b = a;

What I want to learn here is why do I get the error? why compiler restricts this operation. I understand that initialized global variables are stored in Data segments. The compiler could have first resolved the value of a,and then could have assigned the same value to b. Why it lacks this feature? Is it complex for compiler to do? Is there any rationale behind this functionality or just a pitfall of C?

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marked as duplicate by alk, Jens, H2CO3, Cristian Ciupitu, sandrstar Oct 3 '13 at 3:55

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

Error message is your answer. –  Grijesh Chauhan Oct 2 '13 at 5:11
Well, how the compiler is supposed to run executable code (evaluate an expression) outside a function? C++ compilers can do this, but that usually works by creating some helper functions that run before main(), and that is ugly, hackish, implicit and hidden, so your program doesn't really do what you think it does, and C programers don't like that. (C++ programmers do.) –  user529758 Oct 2 '13 at 5:11
The compiler is a compiler not an interpreter –  Jim Rhodes Oct 2 '13 at 5:11
@GrijeshChauhan Does not apply. OP knows why he gets the error, he's looking for the design decision behind it. –  user529758 Oct 2 '13 at 5:12
@H2CO3 evaluate initialiser as it's value known, and store it in data as b's initialiser - i believe that's what Joshi wanted. But something prevents this (and i rejoice that it is). Runtime evaluation is out-of-question. I'm done with these annoying and loudly misunderstandings. –  keltar Oct 2 '13 at 5:45

4 Answers 4

up vote 8 down vote accepted

The official documentation, taken from line 1644, 6.7.8 Initialization, says:

All the expressions in an initializer for an object that has static storage duration shall be constant expressions or string literals.

Why the rule exists is a more difficult question - perhaps as you suggest it is difficult for the compiler to do. In C++ such an expression is valid, but global initialiser may invoke constructors, etc, whereas for C, to keep things compact, globals are evaluated at the compile phase. int b = a; is evaluable at compile time, but what about int b = a + c;? int b = pow(a, 2);? Where would you stop? C decides that not allowing you to start is the best solution.

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It is more than just "hard" for a compiler to do. It touches upon the halting problem. If static initializes were not constants, then to evaluate them at compile time would require interpreting the parsed code, which might not terminate. On the other hand, if static initializes were not constants, but they were determined at run time, then you would need a very complicated mechanism to detect and order all the static initialization. C++ approaches that, but it is far from straightforward. Basically order between initialization blocks isn't guaranteed. –  Edwin Buck Oct 2 '13 at 6:02
@EdwinBuck: Of course that's an imaginary problem that keeps getting repeated like if it was a law of Nature. Nobody expects a compiler to terminate given bad code. That's never a problem. Try giving a C++ compiler some useful metaprograms and see what happens. On the other hand, if it could interpret imperative C++ instead of interpreting a hard-to-use functional metalanguage, it would be done in a millisecond, having used negligible amount of heap. Sometimes being practical completely and utterly trumps some theoretical purity. –  Kuba Ober Oct 2 '13 at 13:11
@KubaOber The halting problem is far from imaginary. Compilers are expected to terminate, but one could easily fail it with: #define a b+1, #define b a+1, if true interpretation was desired. The only part that requires one's imagination is in imagining how to abuse it in interesting ways. –  Edwin Buck Oct 2 '13 at 20:07

From your comment:

...how can I force compiler to make this work?

Well you can't make the compiler accept what you have but you can accomplish your goal by defining the value you want to assign to both variables.



Now if you need to change the initial value, you only need to change it in one place;

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Sorry, this is what I am not looking for. –  dexterous_stranger Oct 2 '13 at 5:55
@SHREYASJOSHI if you are not satisfied with "you cannot; the language forbids this" then you are using the wrong language. Think about which part of the equation is under your control. –  tripleee Oct 2 '13 at 6:26

C is portable to very simple, small machines. Evaluating expressions that aren't constant requires runtime code, in a function. In embedded programming you might not want any functions (or code) that you did not explicitly program.

Your compiler probably will evaluate the initializer as a language extension, if configured with different options. If that fails, you could try C++ (even just the C-like subset) or another language that does more things you like :v) .

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Others have stated why initializers in general can't be allowed to be arbitrary expressions.

The way to "force the compiler to accept the code" is to change the code. The canonical way to perform arbitrary initialization of file scope, external linkage (vulgo: "global") variables is to call an initialization function at the start of main() that does all the initialization in the sequence you need:

#include <stdio.h>
int a;
int b;

void init(void)
     a = 100;
     b = a;

int main(int argc, char **argv)
     printf("The value of b=%d\n", b);

     return 0;
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