CSCI 3500: Studio 3

Pointers


One tricky part of writing good C code is using pointers correctly. Understanding how pointers work, how to use them to index arrays, how they relate to strings, and how to reference and dereference data correctly is vital.

In this studio, you will:

  1. Learn about pointers and strings in C
  2. Use pointers to index into an array
  3. Write some basic string manipulation functions

Please complete the required exercises below, as well as any optional enrichment exercises that you wish to complete.

As you work through these exercises, please record your answers in a text file. When finished, submit your work via the git repository.

Make sure that the name of each person who worked on these exercises is listed in the first answer, and make sure you number each of your responses so it is easy to match your responses with each exercise.


Required Exercises

  1. As the answer to the first exercise, list the names of the people who worked together on this studio.

  2. Let's start by building a minimal program. Look at the programs from the previous studios, and write out a main function. Inside your function you should only have the statement "return 0;" This is a valid C program, though it doesn't do much. When it runs it will immediately quit and return zero to the terminal.

    (You don't see the zero, but any command you run through the terminal returns some value and you can get that value if you want. By convention in Linux/Unix a return value of zero indicates that the program ran successfully, while any non-zero value indicates an error. These return values are especially useful for scripting a set of commands in sequence, as they tell you whether or not each step was successful and allow you to react appropriately. Typing the command "echo $?" will show the return value of the last command executed. You can try this now if you want- remember the program "cat" prints a file to the terminal, so if you use cat with a real file that exists you should get a return value of zero, while if you use the command "cat FileDoesNotExist" you should get some non-zero return value. You can also try returning different values from your program as well. But I digress- this is not the purpose of this studio, but still good for any Linux programmer to know.)

    Make sure your code compiles successfully. Remember we use the GCC compiler to build C programs. If you have named your program pointers.c then you can use a command such as gcc -Wall pointers.c -o pointers to build your code. You can leave this answer blank.

  3. Now back to pointers. Pointers are an essential part of programming in C, and one of the biggest things we use them for is accessing arrays. We can have arrays of any data type: chars, ints, floats, doubles, and so on. Copy the following line into your main() function.

    char *messagePtr = "HELLOWORLD!"

    Let's break down this statement. There are several important pieces.

    1. messagePtr - This is the name of a variable we have just defined.

    2. The asterisk - Declares that messagePtr is a pointer.

    3. char - This declares that messagePtr is a pointer to a char. Remember that a char is a one-byte data type.

    4. "HELLOWORLD!" - This is the string that the variable messagePtr points to, called a string literal.

    Next, let's print this string just to make sure everything is working correctly. Observe that the %s format specifier tells printf() to print a string.

    printf("%s\n", messagePtr);

    You will also need to include stdio.h at the top of your file.

    You can leave the answer to this question blank.

  4. We can access the elements of a string by dereferencing the string pointer. A pointer points to data in memory, and dereferencing that pointer gives us the value of the data. The simplest way to dereference is through the use of the square bracket index notation. The code messagePtr[0] gives you the first character "H", the code messagePtr[1] gives you the second character "E", etc.

    Print out each character of the string using a for-loop with index notation. You can print a character as such: "printf("%c\n", char_to_print). Your output should look like:

    H
    E
    L
    L
    O
    W
    O
    R
    L
    D
    !
    

    As the answer to this question, copy-paste your for-loop.

  5. The dereference operator in C is the asterisk (*) and is also important when using pointers. Just like indexing a pointer, the dereference operator obtains the value of the data that is pointed to.

    If the pointer messagePtr is a pointer to a character, what character does it point to? In other words, what do you think is the value of the dereference operation *messagePtr?

  6. Check your answer to the last exercise by dereferencing messagePtr and printing it out. The dereference operator is the asterisk when placed to the left of a pointer. You can print out a single character like so:

    printf("%c\n", *pointer_to_string);

    What was printed?

  7. Another way to use pointers is with pointer arithmetic. Suppose we have a regular string pointer called ptr, as seen above this points to the first character of the string. To access the next character we could add to this pointer as such:

    ptr + 1 //same as saying ptr[1]

    or we could access the fourth element of the string by adding:

    ptr + 3 //accesses fourth element, same as ptr[3]

    The index notation you just used is essentially pointer arithmetic (in fact the C standard defines index notation in terms of pointer arithmetic).

    Try printing the value of the next few bytes of the string using pointer arithmetic. To do so, add one, two, or three to the pointer before dereferencing. For example: *(messagePtr + 1).

  8. Write a second for-loop to print the entire contents of the string using pointer arithmetic, one character at a time. As the answer to this question, copy and paste your new for-loop.

  9. It's easy to use pointers with strings when we know exactly what the string is. It's harder when we don't. For example, how did you figure out how many iterations of the for-loop you needed for the previous exercises? If you're like most of us, you just counted out the eleven characters in "HELLOWORLD!". So, how do we handle arbitrary strings?

    Recall that in a properly formatted C-style string the string pointer indicates the first character of the string and always ends with a null-terminator (ends with the character '\0'). See the diagram below.

    A diagram of the string in memory. There are
	  twelve consecutive bytes, starting with H, E, L, L, O and
	  continuing. The eleventh byte is the exclamation point, and the
	  twelfth byte is the NULL terminator.

    We can always use the null-terminator to know when a string ends. For this exercise I want you to print the string using a while loop instead of a for-loop. Use the fact that the string ends with a null value as your loop condition. You can use the keyword NULL or the null character '\0' to compare against. As the answer to this question copy-paste your while loop.

  10. It's also important to understand how pointers are treated when calling functions. Recall that the two basic ways to pass arguments to functions are pass-by-value and pass-by-reference. The C language does not support pass-by-reference, and everything is passed by value. So for example, you can't pass a string to a function.

    Suppose we want to write a function that uses strings- what can we do instead? The answer is to pass a pointer to the function- we can pass a pointer by value, and that pointer can point to a string. Copy the following function definition above your main() function:

    void printReverse( char* string ){
    
    }
    

    Starting with your code from the previous exercise, write a function that prints a string in reverse order. For example, printing the string pointed to by messagePtr should produce the output:

    !
    D
    L
    R
    O
    W
    O
    L
    L
    E
    H
    

    You should not make any assumptions about the string passed to the function. Use the fact that strings are always null-terminated to figure out how long the string is. (Do not use the C-standard library function strlen()- get the value yourself.) Your code should work equally well with messagePtr or with another string such as:

    char *secondString = "Another string!";

    As the answer to this exercise, copy-paste your function.

  11. For our last exercise today, we will write a second function that creates a reversed copy of an input string. Feel free to borrow code from any of the other exercises you've done today. Start with the following outline. This code should also go above your main() function.

    #include <stdlib.h>
    
    char* reverseString( char* input ){
    
    //1. First count how many characters are in the input string
    
    //This creates enough space to store the reversed string, plus one more byte
    //for the null terminator
    char* output = (char*)malloc( number_of_chars_in_input+1 );
    
    //2. Copy the input string to the output string in reverse order. There are
    //multiple ways to do this- consider using a counter, or consider using two
    //pointers. 
    
    //REMEMBER THAT YOUR OUTPUT STRING MUST END WITH A NULL TERMINATOR. This is not
    //provided for you automatically- you must put it there!
    
    	return output; 
    }
    

    The above code bears some explanation. Look up the function malloc() in the manual pages. This function takes a number and returns a pointer to a region of memory with that many bytes. For example, malloc(10) returns a pointer to a region of memory with 10 bytes that you can modify however you'd like. This is necessary because we need someplace to put our reversed string. Then, the last line returns that pointer so it can be used.

    Verify your function works with the following code in your main function:

    char* reversedMessage = reverseString( messagePtr );
    printf("Reversed string: %s\n", reversedMessage);
    

    As the answer to this exercise, copy-paste your last function.

Optional Enrichment Exercises

  1. None.