Short answer: encapsulation.
static describes both lifetime and visibility of a variable, and its meaning changes depending on the context. My opinion is that it is one of the more useful and important language features for encapsulation in c. Ignoring the complex relationship to
extern, here's a simplified description:
static variables defined at the file level have program lifetime and compilation unit visibility. This means all functions in a .c file can access/modify the variable, but other .c files won't know about the variable. This is super useful for making sure variables used across functions with a compilation unit don't accidentally link with variables in other compilation units. Personally, I highly recommend all file variables to be static by default. Only remove the
static specifier if you really want another compilation unit to have access to it (although a getter function may be safer)
static within a block scope (most importantly function scope) have program lifetime, and scope visibility. That means it functions as if you declared the variable globally in the file, but only code within that block scope can see it. It also means from one call to the next, the variable does not get destroyed and state can be transferred from call to call.
One really important difference with static variables is that they are default-initialized to zero. This differs from all other variables in c, and is the reason your program prints the value 0. Often times with trivial programs we don't notice the difference because the stack hasn't been polluted with variables yet, but it becomes critical for any program of size.
The most common use for this that I have seen is to enable one-time initialization within a scope. They are also extremely useful for synchronization primitives like
pthread_mutex_t. One time I even implemented a state-machine with function-scope static variable.
int started;//oops, anybody in the entire program can change this value, especially with such a common name!
static int lastCall;
// This is default-initialized to 0
static int functionStaticVariable;
//Increment each time I'm called
//tell the outside world that I'm the one who was called last
lastCall = 1;
//return (a copy of) my internal state.
char *getSharedMemory(unsigned int bytes)
// Here I cannot see functionStaticVariable, but I can see globalVariable
//functionStaticVariable++; // this would cause a compilation failure
// static pointer is default-initialized to zero (i.e. NULL)
static char *sharedMemory;
if(sharedMemory == 0)
// This block only executes once, the first time the function is called.
// Actually this is a nice side-effect because it means if the function is never called we don't clutter the stack with unused memory
// Although we will probably never free this memory
sharedMemory = (char *)malloc(bytes);
// tell the outside world that this function has been called
lastCall = 2;//valid
//Woah, this is such a bad idea, but actually does _not_ return memory that gets invalidated
Hopefully you can see with this pattern you could protect a variable by placing it inside a function and doing optional things like acquiring a mutex-lock in order to allocate the memory. You could even implement the double-lock pattern this way.
I secretly wish that all C++ programmers learned good c encapsulation, because actually the language really encourages it. You can do an incredible amount by placing only functions that need to communicate with each other together in a compilation unit. In a non-OOP language, this can be very powerful.
Full details of static and extern are described by https://en.cppreference.com/w/c/language/storage_duration.