"C" Programing Functions
In C, a function is equivalent to a subroutine or
function in Fortran, or a procedure or function in Pascal. A function provides
a convenient way to encapsulate some computation, which can then be used
without worrying about its implementation. With properly designed functions, it
is possible to ignore how a job is done; knowing what is done is
sufficient. C makes the sue of functions easy, convinient and efficient; you
will often see a short function defined and called only once, just because it
clarifies some piece of code.
So far we have used only functions like printf, getchar
and putchar that have been provided for us; now it's time to write a few of our
own. Since C has no exponentiation operator like the ** of Fortran, let us
illustrate the mechanics of function definition by writing a function
power(m,n) to raise an integer m to a positive integer power n. That is, the
value of power(2,5) is 32. This function is not a practical exponentiation
routine, since it handles only positive powers of small integers, but it's good
enough for illustration.(The standard library contains a function pow(x,y) that
computes xy.)
Here is the function power and a main program to exercise
it, so you can see the whole structure at once.
#include
int power(int m,
int n);
/* test power
function */
main()
{
int i;
for (i = 0; i < 10; ++i)
printf("%d %d %d\n", i, power(2,i), power(-3,i));
return 0; }
/* power: raise
base to n-th power; n >= 0 */
int power(int base, int n)
{
int i, p;
p = 1;
for (i = 1; i
<= n; ++i)
p = p *
base;
return p;
}
A function definition has this form:
return-type function-name(parameter declarations, if any)
{
declarations
statements
}
The function power is called twice by main, in the line
printf("%d
%d %d\n", i, power(2,i), power(-3,i));
Each call passes two arguments to power, which each time
returns an integer to be formatted and printed. In an expression, power(2,i) is
an integer just as 2 and i are. (Not all functions produce an integer value; we
will take this up in Functions and Program Structure.)
The first line of power itself,
int power(int base, int n)
declares the parameter types and names, and the type of
the result that the function returns. The names used by power for its
parameters are local to power, and are not visible to any other function: other
routines can use the same names without conflict. This is also true of the
variables i and p: the i in power is unrelated to the i in main.
We will generally use parameter for a variable
named in the parenthesized list in a function. The terms formal argument and
actual argument are sometimes used for the same distinction.
The value that power computes is returned to main by the
return: statement. Any expression may follow return:
return expression;
A function need not return a value; a return statement
with no expression causes control, but no useful value, to be returned to the
caller, as does ``falling off the end'' of a function by reaching the
terminating right brace. And the calling function can ignore a value returned
by a function.
You may have noticed that there is a return statement at
the end of main. Since main is a function like any other, it may return a value
to its caller, which is in effect the environment in which the program was
executed. Typically, a return value of zero implies normal termination;
non-zero values signal unusual or erroneous termination conditions. In the
interests of simplicity, we have omitted return statements from our main
functions up to this point, but we will include them hereafter, as a reminder
that programs should return status to their environment.
The declaration
int power(int base, int n);
just before main says that power is a function that
expects two int arguments and returns an int. This declaration, which is called
a function prototype, has to agree with the definition and uses of
power. It is an error if the definition of a function or any uses of it do not
agree with its prototype.
parameter names need not agree. Indeed, parameter names
are optional in a function prototype, so for the prototype we could have
written
int power(int, int);
Well-chosen names are good documentation however, so we
will often use them.
A note of history: the biggest change between ANSI C and
earlier versions is how functions are declared and defined. In the original
definition of C, the power function would have been written like this:
/* power: raise base to n-th power; n >= 0 */
/* (old-style version) */
power(base, n)
int base, n;
{
int i, p;
p = 1;
for (i = 1; i
<= n; ++i)
p = p * base;
return p;
}
The parameters are named between the parentheses, and
their types are declared before opening the left brace; undeclared parameters
are taken as int. (The body of the function is the same as before.)
The declaration of power at the beginning of the program
would have looked like this:
int power();
No parameter list was
permitted, so the compiler could not readily check that power was being called
correctly. Indeed, since by default power would have been assumed to return an
int, the entire declaration might well have been omitted.
The new syntax of function prototypes makes it
much easier for a compiler to detect errors in the number of arguments or their
types. The old style of declaration and definition still works in ANSI C, at
least for a transition period, but we strongly recommend that you use the new
form when you have a compiler that supports it.
Exercise Rewrite the temperature conversion program of Variables and Arithmetic
Expressions to use a function for
conversion.
0 comments:
Post a Comment