We have introduced many applications and techniques that use pointers. We have introduced some advanced pointer issues already. This chapter brings together some topics we have briefly mentioned and others to complete our study C pointers.
In this chapter we will:
We introduced the concept of a pointer to a pointer previously. You can have a pointer to a pointer of any type.
Consider the following:
char ch; /* a character */ char *pch; /* a pointer to a character */ char **ppch; /* a pointer to a pointer to a character */
We can visualise this in Figure 11.1. Here we can see that **ppch refers to memory address of *pch which refers to the memory address of the variable ch. But what does this mean in practice?
Fig. 11.1 Pointers to pointers Recall that char * refers to a (NULL terminated string. So one common and convenient notion is to declare a pointer to a pointer to a string (Figure 11.2)
Fig. 11.2 Pointer to String Taking this one stage further we can have several strings being pointed to by the pointer (Figure 11.3)
Fig. 11.3 Pointer to Several Strings We can refer to individual strings by ppch[0], ppch[1], ..... Thus this is identical to declaring char *ppch[].
One common occurrence of this type is in C command line argument input which we now consider.
C lets read arguments from the command line which can then be used in our
programs.
We can type arguments after the program name when we run the program.
We have seen this with the compiler for example
c89 -o prog prog.c
c89 is the program, -o prog prog.c the arguments.
In order to be able to use such arguments in our code we must define them as
follows:
main(int argc, char **argv)
So our main function now has its own arguments. These are the only
arguments main accepts.
A simple program example:
#include<stdio.h>
main (int argc, char **argv)
{ /* program to print arguments
from command line */
int i;
printf("argc = %d\n\n",argc);
for (i=0;i<argc;++i)
printf("argv[%d]: %s\n",
i, argv[i]);
}
Assume it is compiled to run it as args.
So if we type:
args f1 "f2" f3 4 stop!
The output would be:
argc = 6
argv[0] = args
argv[1] = f1
argv[2] = f2
argv[3] = f3
argv[4] = 4
argv[5] = stop!
NOTE: argv[0] is program name. argc counts program name Embedded " " are ignored. Blank spaces delimit end of arguments. Put blanks in "" if needed.
Pointer to a function are perhaps on of the more confusing uses of pointers in C. Pointers to functions are not as common as other pointer uses. However, one common use is in a passing pointers to a function as a parameter in a function call. (Yes this is getting confusing, hold on to your hats for a moment).
This is especially useful when alternative functions maybe used to perform similar tasks on data. You can pass the data and the function to be used to some control function for instance. As we will see shortly the C standard library provided some basic sorting ( qsort) and searching (bsearch) functions for free. You can easily embed your own functions.
To declare a pointer to a function do:
int (*pf) ();
This simply declares a pointer *pf to function that returns and int. No actual function is pointed to yet.
If we have a function int f() then we may simply (!!) write:
pf = &f;
For compiler prototyping to fully work it is better to have full function prototypes for the function and the pointer to a function:
int f(int); int (*pf) (int) = &f;
Now f() returns an int and takes one int as a parameter.
You can do things like:
ans = f(5); ans = pf(5);
which are equivalent.
The qsort standard library function is very useful function that is designed to sort an array by a key value of any type into ascending order, as long as the elements of the array are of fixed type.
qsort is prototyped in (stdlib.h):
void qsort(void *base, size_t num_elements, size_t element_size, int (*compare)(void const *, void const *));
The argument base points to the array to be sorted, num_elements indicates how long the array is, element_size is the size in bytes of each array element and the final argument compare is a pointer to a function.
qsort calls the compare function which is user defined to compare the data when sorting. Note that qsort maintains it's data type independence by giving the comparison responsibility to the user. The compare function must return certain (integer) values according to the comparison result:
Some quite complicated data structures can be sorted in this manner. For example, to sort the following structure by integer key:
typedef struct { int key; struct other_data; } Record;
We can write a compare function, record_compare:
int record\_compare(void const *a, void const *a) { return ( ((Record *)a)->key - ((Record *)b)->key ); }
Assuming that we have an array of array_length Records suitably filled with date we can call qsort like this:
qsort( array, arraylength, sizeof(Record), record_compare);
Further examples of standard library and system calls that use pointers to functions may be found in Chapters 15.4 and 19.1.
Exercise 12476
Write a program last that prints the last n lines of its text input. By default n should be 5, but your program should allow an optional argument so that
last -n
prints out the last n lines, where n is any integer. Your program should make the best use of available storage. (Input of text could be by reading a file specified from the command or reading a file from standard input)
Exercise 12477
Write a program that sorts a list of integers in ascending order. However if a -r flag is present on the command line your program should sort the list in descending order. (You may use any sorting routine you wish)
Exercise 12478
Write a program that reads the following structure and sorts the data by keyword using qsort
typedef struct { char keyword[10]; int other_data; } Record;
Exercise 12479
An insertion sort is performed by adding values to an array one by one. The first value is simply stored at the beginning of the array. Each subsequent value is added by finding its ordered position in the array, moving data as needed to accommodate the value and inserting the value in this position.
Write a function called insort that performs this task and behaves in the same manner as qsort, i.e it can sort an array by a key value of any type and it has similar prototyping.