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Show Source |    | About   «  4.2. Sorting Terminology and Notation   ::   Contents   ::   4.4. Bubble Sort  »

4.3. Insertion Sort

4.3.1. Insertion Sort

What would you do if you have a stack of phone bills from the past two years and you want to order by date? A fairly natural way to handle this is to look at the first two bills and put them in order. Then take the third bill and put it into the right position with respect to the first two, and so on. As you take each bill, you would add it to the sorted pile that you have already made. This simple approach is the inspiration for our first sorting algorithm, called Insertion Sort.

Insertion Sort iterates through a list of records. For each iteration, the current record is inserted in turn at the correct position within a sorted list composed of those records already processed. Here is an implementation. The input is an array named A that stores \(n\) records.

static void inssort(int[] A) {
  for (int i=1; i<A.length; i++) // Insert i'th record
    for (int j=i; (j>0) && (A[j] < A[j-1]); j--)
      swap(A, j, j-1);
}
static <T extends Comparable<T>> void inssort(T[] A) {
  for (int i=1; i<A.length; i++) // Insert i'th record
    for (int j=i; (j>0) && (A[j].compareTo(A[j-1]) < 0); j--)
      swap(A, j, j-1);
}

(Note that to make the explanation for these sorting algorithms as simple as possible, our visualizations will show the array as though it stored simple integers rather than more complex records. But you should realize that in practice, there is rarely any point to sorting an array of simple integers. Nearly always we want to sort more complex records that each have a key value. In such cases we must have a way to associate a key value with a record. The Java version of the code snippet above uses an int array, while the Java (Generic) version shows a version using an Object that supports the Comparable interface.)

Here we see the first few iterations of Insertion Sort.

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This continues on with each record in turn. Call the current record \(x\). Insertion Sort will move it to the left so long as its value is less than that of the record immediately preceding it. As soon as a key value less than or equal to \(x\) is encountered, inssort is done with that record because all records to its left in the array must have smaller keys.

4.3.2. Insertion Sort Analysis

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While the best case is significantly faster than the average and worst cases, the average and worst cases are usually more reliable indicators of the “typical” running time. However, there are situations where we can expect the input to be in sorted or nearly sorted order. One example is when an already sorted list is slightly disordered by a small number of additions to the list; restoring sorted order using Insertion Sort might be a good idea if we know that the disordering is slight. And even when the input is not perfectly sorted, Insertion Sort’s cost goes up in proportion to the number of inversions. So a “nearly sorted” list will always be cheap to sort with Insertion Sort. Examples of algorithms that take advantage of Insertion Sort’s near-best-case running time are Shellsort and Quicksort.

Counting comparisons or swaps yields similar results. Each time through the inner for loop yields both a comparison and a swap, except the last (i.e., the comparison that fails the inner for loop’s test), which has no swap. Thus, the number of swaps for the entire sort operation is \(n-1\) less than the number of comparisons. This is 0 in the best case, and \(\Theta(n^2)\) in the average and worst cases.

Later we will see algorithms whose growth rate is much better than \(\Theta(n^2)\). Thus for larger arrays, Insertion Sort will not be so good a performer as other algorithms. So Insertion Sort is not the best sorting algorithm to use in most situations. But there are special situations where it is ideal. We already know that Insertion Sort works great when the input is sorted or nearly so. Another good time to use Insertion Sort is when the array is very small, since Insertion Sort is so simple. The algorithms that have better asymptotic growth rates tend to be more complicated, which leads to larger constant factors in their running time. That means they typically need fewer comparisons for larger arrays, but they cost more per comparison. This observation might not seem that helpful, since even an algorithm with high cost per comparison will be fast on small input sizes. But there are times when we might need to do many, many sorts on very small arrays. You should spend some time right now trying to think of a situation where you will need to sort many small arrays. Actually, it happens a lot.

See Computational Fairy Tales: Why Tailors Use Insertion Sort for a discussion on how the relative costs of search and insert can affect what is the best sort algorithm to use.

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