Static variables have a property of preserving their value even after they are out of their scope! Hence, static variables preserve their previous value in their previous scope and are not initialized again in the new scope.
In the Java programming language, the keyword static means that the particular member belongs to a type itself, rather than to an instance of that type. This means we'll create only one instance of that static member that is shared across all instances of the class.
In the static memory allocation, variables get allocated permanently, till the program executes or function call finishes. In the Dynamic memory allocation, variables get allocated only if your program unit gets active.
A global variable can be accessed from anywhere inside the program while a static variable only has a block scope. So, the benefit of using a static variable as a global variable is that it can be accessed from anywhere inside the program since it is declared globally.
(1) is the more foreign topic if you're a newbie, so here's an example:
#include <stdio.h>
void foo()
{
int a = 10;
static int sa = 10;
a += 5;
sa += 5;
printf("a = %d, sa = %d\n", a, sa);
}
int main()
{
int i;
for (i = 0; i < 10; ++i)
foo();
}
This prints:
a = 15, sa = 15
a = 15, sa = 20
a = 15, sa = 25
a = 15, sa = 30
a = 15, sa = 35
a = 15, sa = 40
a = 15, sa = 45
a = 15, sa = 50
a = 15, sa = 55
a = 15, sa = 60
This is useful for cases where a function needs to keep some state between invocations, and you don't want to use global variables. Beware, however, this feature should be used very sparingly - it makes your code not thread-safe and harder to understand.
(2) Is used widely as an "access control" feature. If you have a .c file implementing some functionality, it usually exposes only a few "public" functions to users. The rest of its functions should be made static
, so that the user won't be able to access them. This is encapsulation, a good practice.
Quoting Wikipedia:
In the C programming language, static is used with global variables and functions to set their scope to the containing file. In local variables, static is used to store the variable in the statically allocated memory instead of the automatically allocated memory. While the language does not dictate the implementation of either type of memory, statically allocated memory is typically reserved in data segment of the program at compile time, while the automatically allocated memory is normally implemented as a transient call stack.
And to answer your second question, it's not like in C#.
In C++, however, static
is also used to define class attributes (shared between all objects of the same class) and methods. In C there are no classes, so this feature is irrelevant.
There is one more use not covered here, and that is as part of an array type declaration as an argument to a function:
int someFunction(char arg[static 10])
{
...
}
In this context, this specifies that arguments passed to this function must be an array of type char
with at least 10 elements in it. For more info see my question here.
Short answer ... it depends.
Static defined local variables do not lose their value between function calls. In other words they are global variables, but scoped to the local function they are defined in.
Static global variables are not visible outside of the C file they are defined in.
Static functions are not visible outside of the C file they are defined in.
Multi-file variable scope example
Here I illustrate how static affects the scope of function definitions across multiple files.
a.c
#include <stdio.h>
/*
Undefined behavior: already defined in main.
Binutils 2.24 gives an error and refuses to link.
https://stackoverflow.com/questions/27667277/why-does-borland-compile-with-multiple-definitions-of-same-object-in-different-c
*/
/*int i = 0;*/
/* Works in GCC as an extension: https://stackoverflow.com/a/3692486/895245 */
/*int i;*/
/* OK: extern. Will use the one in main. */
extern int i;
/* OK: only visible to this file. */
static int si = 0;
void a() {
i++;
si++;
puts("a()");
printf("i = %d\n", i);
printf("si = %d\n", si);
puts("");
}
main.c
#include <stdio.h>
int i = 0;
static int si = 0;
void a();
void m() {
i++;
si++;
puts("m()");
printf("i = %d\n", i);
printf("si = %d\n", si);
puts("");
}
int main() {
m();
m();
a();
a();
return 0;
}
GitHub upstream.
Compile and run:
gcc -c a.c -o a.o
gcc -c main.c -o main.o
gcc -o main main.o a.o
Output:
m()
i = 1
si = 1
m()
i = 2
si = 2
a()
i = 3
si = 1
a()
i = 4
si = 2
Interpretation
si
, one for each filei
As usual, the smaller the scope, the better, so always declare variables static
if you can.
In C programming, files are often used to represent "classes", and static
variables represent private static members of the class.
What standards say about it
C99 N1256 draft 6.7.1 "Storage-class specifiers" says that static
is a "storage-class specifier".
6.2.2/3 "Linkages of identifiers" says static
implies internal linkage
:
If the declaration of a file scope identifier for an object or a function contains the storage-class specifier static, the identifier has internal linkage.
and 6.2.2/2 says that internal linkage
behaves like in our example:
In the set of translation units and libraries that constitutes an entire program, each declaration of a particular identifier with external linkage denotes the same object or function. Within one translation unit, each declaration of an identifier with internal linkage denotes the same object or function.
where "translation unit is a source file after preprocessing.
How GCC implements it for ELF (Linux)?
With the STB_LOCAL
binding.
If we compile:
int i = 0;
static int si = 0;
and disassemble the symbol table with:
readelf -s main.o
the output contains:
Num: Value Size Type Bind Vis Ndx Name
5: 0000000000000004 4 OBJECT LOCAL DEFAULT 4 si
10: 0000000000000000 4 OBJECT GLOBAL DEFAULT 4 i
so the binding is the only significant difference between them. Value
is just their offset into the .bss
section, so we expect it to differ.
STB_LOCAL
is documented on the ELF spec at http://www.sco.com/developers/gabi/2003-12-17/ch4.symtab.html:
STB_LOCAL Local symbols are not visible outside the object file containing their definition. Local symbols of the same name may exist in multiple files without interfering with each other
which makes it a perfect choice to represent static
.
Variables without static are STB_GLOBAL
, and the spec says:
When the link editor combines several relocatable object files, it does not allow multiple definitions of STB_GLOBAL symbols with the same name.
which is coherent with the link errors on multiple non static definitions.
If we crank up the optimization with -O3
, the si
symbol is removed entirely from the symbol table: it cannot be used from outside anyways. TODO why keep static variables on the symbol table at all when there is no optimization? Can they be used for anything? Maybe for debugging.
See also
static
functions: https://stackoverflow.com/a/30319812/895245
static
with extern
, which does "the opposite": How do I use extern to share variables between source files?
C++ anonymous namespaces
In C++, you might want to use anonymous namespaces instead of static, which achieves a similar effect, but further hides type definitions: Unnamed/anonymous namespaces vs. static functions
It depends:
int foo()
{
static int x;
return ++x;
}
The function would return 1, 2, 3, etc. --- the variable is not on the stack.
static int foo()
{
}
It means that this function has scope only in this file. So a.c and b.c can have different foo()
s, and foo is not exposed to shared objects. So if you defined foo in a.c you couldn't access it from b.c
or from any other places.
In most C libraries all "private" functions are static and most "public" are not.
People keep saying that 'static' in C has two meanings. I offer an alternate way of viewing it that gives it a single meaning:
The reason it seems to have two meanings is that, in C, every item to which 'static' may be applied already has one of these two properties, so it seems as if that particular usage only involves the other.
For example, consider variables. Variables declared outside of functions already have persistence (in the data segment), so applying 'static' can only make them not visible outside the current scope (compilation unit). Contrariwise, variables declared inside of functions already have non-visibility outside the current scope (function), so applying 'static' can only make them persistent.
Applying 'static' to functions is just like applying it to global variables - code is necessarily persistent (at least within the language), so only visibility can be altered.
NOTE: These comments only apply to C. In C++, applying 'static' to class methods is truly giving the keyword a different meaning. Similarly for the C99 array-argument extension.
From Wikipedia:
In the C programming language, static is used with global variables and functions to set their scope to the containing file. In local variables, static is used to store the variable in the statically allocated memory instead of the automatically allocated memory. While the language does not dictate the implementation of either type of memory, statically allocated memory is typically reserved in data segment of the program at compile time, while the automatically allocated memory is normally implemented as a transient call stack.
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