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Sunday, 16 December 2012

ARRAYS


Arrays in Java
We looked at the basics of Java's built-in arrays, starting from creating an array to iterating over the elements of an array, as well as at a few typical array manipulations in class today. See the link to a complete implementation for you to play with at the end of this document.

Topics, in no particular order:

1. Creating an array
2. Iterating over the elements of an array
3. Copying an array
4. Resizing an array
5. Reversing an array
6. Shifing an array left
7. Shifing an array right
8. Inserting an element into an array
9. Removing an element from an array
10. Rotating an array left
11. Rotating an array right

Creating an array
In Java, you create a new array in the following:

Foo[] x = new Foo[100];

Now x refers to an array of 100 Foo references. Note that the array doesn't actually contain the instances of Foo (the objects that is), but rather hold the references to the objects. We can assign other references to this array:

Foo[] y = x;

Now y is just another reference to the same array, and any change made through y will change the array referred to by x.

A Java array has a single attribute called length that gives you the capacity of the array; x.length for example would produce the value 100 in this case. The capacity of an array is fixed, and once created, cannot be changed. We "resize" and array by creating a new one with higher capacity, and copying the elements to the new one. See resizing an array for details.

Iterating over the elements of an array
Iterating over the elements of an array is the same as the following: for each element v in the array x, do something with v. There are two traditional patterns for iterating over the elements of an array: using a while or a for loop. Let's print the elements of the array x using a while loop (here the doing something is printing the element):

int i = 0;
while (i < x.length) {
      System.out.println(x[i]);
      i++;
}

And then using for loop:

for (int i = 0; i < x.length; i++)
    System.out.println(x[i]);

Java has another form of the for loop to implement this "foreach" pattern:

for (Foo v : x)
    System.out.println(v);

This version of the for has one advantage: it does exactly what it says - for each element v in the array x, it prints the element v! No indexing needed at all. It also has a disadvantage: there is no way to iterate over a part of the array, which is important when the size is not equal to the capacity of the array.

Copying an array
Copying the elements of a source array to destination array is simply a matter of copying  the array element by element using an iterator.

public static Object[] copyArray(Object[] source) {
    Object[] copy = new Object[source.length];
    for (int i = 0; i < source.length; i++)
        copy[i] = source[i];
    return copy;
}

For you information, the java.util.Arrays class provides a set of methods to do just this for you in a very efficient way. Here's how:

public static Object[] copyArray(Object[] source) {
    Object[] copy = java.util.Arrays.copyOf(source, source.length);
    return copy;
}

Resizing an array
There is the classic problem of arrays - once created, it cannot change its capacity! The only way to "resize" an array is to first create a new and larger array, and copy the existing elements to the new array. The following static method resizes oldArray to have a capacity of newCapacity, and returns a reference to the resized array.

static Object[] resize(Object[] oldArray, int newCapacity) {
    Object[] newArray = new Object[newCapacity];
    for (int i = 0; i < oldArray.length; i++)
        newArray[i] = oldArray[i];
    return newArray;
}

We can use this method in the following way:

Object[] data = new Object[10];
for (int i = 0; i < 10; i++)
     data[i] = new String(String.valueOf(i));

// The array "data" is now full, so need to resize before we can
// add more elements to it.
data = resize(data, 20);
for (int i = 10; i < 20; i++)
    data[i] = new String(String.valueOf(i));

Reversing an array
The simplest way of reversing an array is to first copy the elements to another array in the reverse order, and then copy the elements back to the original array. This out-of-place method is rather inefficient, but it's simple and it works.

public static void reverse(Object[] array) {
    Object[] tmpArray = new Object[array.length];
    int i = 0;                         // index into array
    int j = tmpArray.length - 1;        // index into the reverse copy
    while (i < array.length) {
        tmpArray[j] = array[i];
        i++;
        j--;
   }
   // Now copy the elements in tmpArray back into the original array.
   for (int i = 0; i < array.length; i++)
       array[i] = tmpArray[i];

  // NOTE: the following DOES NOT work! Why?
  // array = tmparray;
}

Fortunately, there is an in-place method that is far more efficient!

public static void reverse(Object[] array) {
    int i = 0;                          // forward index into left half
    int j = array.length - 1;           // backward index into right half
    while (i < j) {
        // Exchange array[i] with array[j]
        Object tmp = array[i];
        array[i] = array[j];
        array[j] = tmp;
                   
        i++;
        j--;
    }
}

Shifing an array left
Shifting an entire array left moves each element one (or more, depending how the shift amount) position to the left. Obviously, the first element in the array will fall off the beginning and be lost forever. The last slot of the array before the shift (ie., the slot where where the last element was until the shift) is now unused (we can put a null there to signify that). The size of the array remains the same however, because the assumption is that you would something in the now-unused slot. For example, shifing the array [5, 3, 9, 13, 2] left by one position will result in the array [3, 9, 13, 2, -]. Note how the array[0] element with value of 5 is now lost, and there is an empty slot at the end (shown as - above).

public static void shiftLeft(Object array[]) {
    for (int i = 1; i < array.length; i++)
        array[i - 1] = array[i];
    array[a.length - 1] = null;        // Now empty
}

What would happen if this were a circular or cyclic array? See show to rotate an array left.

Shifing an array right
Shifting an entire array right moves each element one (or more, depending how the shift amount) position to the right. Obviously, the last element in the array will fall off the end and be lost forever. The first slot of the array before the shift (ie., the slot where where the 1st element was until the shift) is now unused (we can put a null there to signify that). The size of the array remains the same however, because the assumption is that you would something in the now-unused slot. For example, shifing the array [5, 3, 9, 13, 2] right by one position will result in the array [-, 5, 3, 9, 13]. Note how the array[4] element with value of 2 is now lost, and there is an empty slot in the beginning (shown as - above).

public static void shiftRight(Object array[]) {
    for (int i = array.length - 1; i > 0; i--)
        array[i] = array[i - 1];
    array[0] = null;                    // Now empty.
}

What would happen if this were a circular or cyclic array? See show to rotate an array right.

Inserting an element into an array
Inserting an element into any slot in an array requires that we first make room for it by shifting some of the elements to the right, and then insert the new element in the newly formed gap. The only time we don't have to shift is when we insert in the next available empty slot in the array (the one after the last element). The insertion also assumes that there is at least one empty slot in the array, or else it must be resized as we had done earlier (or, if it's non-resizable by policy, then we can throw an exception). For example, inserting the value 7 in the slot with index 2 in the array [3, 9, 12, 5] produces the array [3, 9, 7, 12, 5].

// Insert the given element at the given index in the non-resizable array
// with size elements.
public static void insert(Object[] array, int size, Object elem, int index) {
    if (size == array.length)
        throw new RuntimeException("no space left");
    else {
        // make a hole by shifting elements to the right.
        for (int i = index; i < size; i++)
            array[i + 1] = array[i];

        // now fill the hole/gap with the new element.
        array[index] = elem;
   }
}

Removing an element from an array
After removing the element at a given index, we need to plug the hole by shifting all the elements to its right one position to the left.

// Removes the element at the given index from the array with size elements.
public static void remove(Object[] array, int size, int index) {
    // Shift all elements [index+1 ... size-1] one position to the
    // left.
    for (int i = index + 1; i < size; i++)
        array[i - 1] = array[i];

    // Now nullify the unused slot at the end.
    array[size - 1] = null;
}

Rotating an array left
Rotating an array left is equivalent to shifting a circular or cyclic array left — the 1st element will not be lost, but rather move to the last slot. Rotating the array [5, 3, 9, 13, 2] left by one position will result in the array [3, 9, 13, 2, 5].

public static void rotateLeft(Object array[]) {
    Object firstElement = array[0];
    for (int i = 1; i < array.length; i++)
        array[i - 1] = array[i];
    array[a.length - 1] = firstElement;
}

There is a much more elegant solution that we'll see when we discuss circular or cyclic arrays (wait till we study the Queue ADT).

Rotating an array right
Rotating an array right is equivalent to shifting a circular or cyclic array right — the last element will not be lost, but rather move to the 1st slot. Rotating the array [5, 3, 9, 13, 2] right by one position will result in the array [2, 5, 3, 9, 13].

public static void rotateRight(Object array[]) {
    Object lastElement = array[array.length - 1];
    for (int i = array.length - 1; i > 0; i--)
        array[i] = array[i - 1];
    array[0] = lastElement;
}

There is a much more elegant solution that we'll see when we discuss circular or cyclic arrays (wait till we study the Queue ADT).

You can look at the example ArrayExamples.java class to see how these can be implemented. Run the ArrayExamples.main() to see the output.

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