It seems uninitialized global variable is treated as weak symbol in Gcc. What is the reason behind this?
gcc, in C mode:
Uninitialised globals which are not declared
Common symbols are merged at link time so that they all refer to the same storage; if more than one object attempts to initialise such a symbol, you will get a link-time error. (If they aren't explicitly initialised anywhere, they will be placed in the BSS, i.e. initialised to 0.)
gcc, in C++ mode:
Not the same - it doesn't do the common symbols thing. "Uninitialised" globals which are not declared
In either case, a weak symbol allows an initialised symbol to be overridden by a non-weak initialised symbol of the same name at link time.
To illustrate (concentrating on the C case here), I'll use 4 variants of a main program, which are all the same except for the way that
and also, another file which initialises the same global,
(Note that this case fails instead if you're using C++.)
If we try with both
It works fine once the initialisation from
But pulling in the other definition from
The question is based on an incorrect premise. Uninitialized global variables are not weak symbols.
Apparently the question is referring to the ability to define the same uninitialized object with external linkage in multiple translation units. Formally, it is not allowed - it is an error in both C and C++. However, at least in C is recognized by C99 standard as "common extension" of the language, implemented in many real-life compilers
Note, that contrary to the popular belief, C language explicitly prohibits introducing multiple definitions of entities with external linkage in the program, just like C++ does.
However, the extension allowing this has been pretty popular with many C compilers, of which GCC just happens to be one.
Is this what you meant?
$ gcc weak.c $ ./a.out weak value is 0. $ gcc weak.c strong.c $ ./a.out weak value is 42.
Any multiple definition of a global symbol is undefined behavior, so gcc (or rather the GNU binutils linker) is free to do whatever it wants. In practice, it follows the traditional behavior to avoid breaking code that relies on this behavior.