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I am new to Linux. I came across this piece of code to print environmental variables. It is kind of confusing me. How can this code print the environmental variables?

#include <stdio.h>

extern char **environ;
int main()
    char **var;
    for(var=environ; *var!=NULL;++var)

    return 0;

what is extern here?

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up vote 1 down vote accepted

If you don't know what extern means, please find a book to learn C from. It simply means 'defined somewhere else, but used here'.

The environ global variable is declared in <unistd.h> these days (though for a long time there was no header that declared it). It is like the argv array to the program, an array of character pointers each of which points at an environment variable in the name=value format. The list is terminated by a null pointer, like argv is. There is no count for the environment, though.

for (var = environ; *var != NULL; ++var)
    printf("%s\n", *var);

So, on the first iteration, var points at the first environment variable; then it is incremented to the next, until the value *var (a char *) is NULL, indicating the end of the list.

That loop could also be written as:

char **var = environ;
while (*var != 0)
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Why have we used ++var? cant we use ++var – user1263375 Mar 12 '12 at 6:29
In the for loop code, ++var and var++ are essentially the same. In the while loop code, using *++var would skip the first entry. There's a related program that I call al (for argument list) that is like echo but prints its arguments one per line: #include <stdio.h> int main(int argc, char **argv) { while (*++argv) puts(*argv); return 0; } which uses *++argv instead of the similar *var++ because it deliberately skips the program name. – Jonathan Leffler Mar 12 '12 at 9:06

From wikipedia http://en.wikipedia.org/wiki/External_variable:

Definition, declaration and the extern keyword

To understand how external variables relate to the extern keyword, it is necessary to know the difference between defining and declaring a variable. When a variable is defined, the compiler allocates memory for that variable and possibly also initializes its contents to some value. When a variable is declared, the compiler requires that the variable be defined elsewhere. The declaration informs the compiler that a variable by that name and type exists, but the compiler need not allocate memory for it since it is allocated elsewhere.

The extern keyword means "declare without defining". In other words, it is a way to explicitly declare a variable, or to force a declaration without a definition. It is also possible to explicitly define a variable, i.e. to force a definition. It is done by assigning an initialization value to a variable. If neither the extern keyword nor an initialization value are present, the statement can be either a declaration or a definition. It is up to the compiler to analyse the modules of the program and decide.

A variable must be defined once in one of the modules of the program. If there is no definition or more than one, an error is produced, possibly in the linking stage. A variable may be declared many times, as long as the declarations are consistent with each other and with the definition (something which header files facilitate greatly). It may be declared in many modules, including the module where it was defined, and even many times in the same module. But it is usually pointless to declare it more than once in a module.

An external variable may also be declared inside a function. In this case the extern keyword must be used, otherwise the compiler will consider it a definition of a local variable, which has a different scope, lifetime and initial value. This declaration will only be visible inside the function instead of throughout the function's module.

The extern keyword applied to a function prototype does absolutely nothing (the extern keyword applied to a function definition is, of course, non-sensical). A function prototype is always a declaration and never a definition. Also, in ANSI C, a function is always external, but some compiler extensions and newer C standards allow a function to be defined inside a function.

An external variable must be defined, exactly once, outside of any function; this sets aside storage for it. The variable must also be declared in each function that wants to access it; this states the type of the variable. The declaration may be an explicit extern statement or may be implicit from context. ... You should note that we are using the words definition and declaration carefully when we refer to external variables in this section. Definition refers to the place where the variable is created or assigned storage; declaration refers to places where the nature of the variable is stated but no storage is allocated.

—The C Programming Language

Scope, lifetime and the static keyword

An external variable can be accessed by all the functions in all the modules of a program. It is a global variable. For a function to be able to use the variable, a declaration or the definition of the external variable must lie before the function definition in the source code. Or there must be a declaration of the variable, with the keyword extern, inside the function.

The static keyword (static and extern are mutually exclusive), applied to the definition of an external variable, changes this a bit: the variable can only be accessed by the functions in the same module where it was defined. But it is possible for a function in the same module to pass a reference (pointer) of the variable to another function in another module. In this case, even though the function is in another module, it can read and modify the contents of the variable—it just cannot refer to it by name.

It is also possible to use the static keyword on the definition of a local variable. Without the static keyword, the variable is automatically allocated when the function is called and released when the function exits (thus the name "automatic variable"). Its value is not retained between function calls. With the static keyword, the variable is allocated when the program starts and released when the program ends. Its value is not lost between function calls. The variable is still local, since it can only be accessed by name inside the function that defined it. But a reference (pointer) to it can be passed to another function, allowing it to read and modify the contents of the variable (again without referring to it by name).

External variables are allocated and initialized when the program starts, and the memory is only released when the program ends. Their lifetime is the same as the program's.

If the initialization is not done explicitly, external (static or not) and local static variables are initialized to zero. Local automatic variables are uninitialized, i.e. contain "trash" values.

The static keyword applied to a function definition prevents the function from being called by name from outside its module (it remains possible to pass a function pointer out of the module and use that to invoke the function).

Example (C programming language)

File 1:

  int GlobalVariable;         // implicit definition
  void SomeFunction();        // function prototype (declaration)

  int main() {
    GlobalVariable = 1;
    return 0;

File 2:

  extern int GlobalVariable;  // explicit declaration

  void SomeFunction() {       // function header (definition)

In this example, the variable GlobalVariable is defined in File 1. In order to utilize the same variable in File 2, it must be declared. Regardless of the number of files, a global variable is only defined once, however, it must be declared in any file outside of the one containing the definition.

If the program is in several source files, and a variable is defined in file1 and used in file2 and file3, then extern declarations are needed in file2 and file3 to connect the occurrences of the variable. The usual practice is to collect extern declarations of variables and functions in a separate file, historically called a header, that is included by #include at the front of each source file. The suffix .h is conventional for header names.

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Extern defines a variable or a function that can be used from other files... I highly advise reading some of the many articles available on the Internet on C programming: https://www.google.ca/search?client=opera&rls=en&q=learn+c&sourceid=opera&ie=utf-8&oe=utf-8&channel=suggest

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extern char **environ;

the variable environ comes from your library which you will link.

That variable saved the system environment variables of your current

linux system. That's why you can do so.

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