Due: Monday, Jan 30th in class Late assignments will be penalized 20% per day.

Book Questions from Introduction to Algorithms - 3rd ed.

1.2-2, 1.2-3

2.2-3, 2-2

Insertion sort implementation.

Hints:

1.2-2 & 1.2-3 Remember that n must be an integer.

2.2-3 Be sure to give a mathematically rigorous justification for your answer and not simply an intuitive explanation. Consider what the probability is for the ith element being the desired one and how many elements were searched to find it.

2-2 (a) - Consider what two criteria are necessary for a sorting algorithm to be correct (the obvious one is that the elements end up in non-decreasing order, what is the other?)

(b) - What must be true both before and after the inner loop executes (consider what the inner loop does)? Remember you must show it holds for initialization, maintenance, and termination conditions.

(c) - What must be true both before and after the outer loop executes (consider what the outer loop does)? Remember you must show it holds for initialization, maintenance, and termination conditions.

(d) - Note this version of bubble-sort uses fixed iteration loops, i.e. no while statements.

Implementation

A skeleton project is provided in CS360_Sorter_Insert.zip. The zip file contains both a Visual Studio project and a Linux/OSX makefile to compile the code. Sorter.cpp contains both utility functions as well as empty sort function stubs - you should not need to modify main() or any of the utility functions.

Your Task

Implement the sort algorithm as given in the pseudocode below for insertion sort. Insert counter increment statements (note: a count global variable is provided), into each sorting function for each executable line of pseudocode (e.g. count all three lines required to implement a swap as a single operation). Use this counter to empirically measure the runtime of each sort. Only increment the counter for statements within the sorting functions, i.e. do not include any initialization overhead incurred in main() or the utility functions. Note that count is reset prior to each sort call but the results are stored in a 2D array counter which is used to display a table of all results once all the sorts and runs have completed.

Generate runs for 13 input sizes by changing the #define MAX_RUNS symbolic constant. This will generate data for increasing powers of 2 from 24 = 16 to 216 = 65536.

The #define NUM_AVG sets the number of data sets of each size to generate in order to compute an average runtime for each size. This value should be set to a reasonable number, e.g. 10, to give a good approximation of the average runtime of each sort. Note that the larger the value that is chosen, the longer the program will take to run.

You should generate tables for two different input ranges

Once the data for all input sizes and element ranges have been generated, make a meaningful plot (e.g. using Excel) of the data showing important characteristics. In particular:

Hint: To plot cn2, consider making another column in the spreadsheet that computes the values for each empirical input size n and then plot that data as connected points without showing the individual data points.

Insertion Sort

INSERTION-SORT(A)
1  for j = 2 to A.length
2     key = A[j]
3     // Insert A[j] into the sorted sequence A[1..j-1]
4     i = j - 1
5     while i > 0 and A[i] > key
6        A[i+1] = A[i]
7        i = i - 1
8     A[i+1] = key

HINTS:

Function call statements DO NOT increment the counter since their runtime is evaluated by the execution of the function.

Return statement DO NOT increment the counter.

Loop statements, i.e. for and while, will execute one more time than the statements in the loop body. Hence a counter can be added to a loop as follows

for (...) {
   count++;
   // Body of loop
}
count++;

while (...) {
   count++;
   // Body of loop
}
count++;

For simple logic constructs, e.g. if, if/else, a count update can be added after the structure since only one branch will execute depending on the result of the condition

if (...) {
   // Body of if
}
count++;

if (...) {
   // Body of if branch
} else {
   // Body of else branch
}
count++;

For chained logical structures, i.e. if/else if/ else, there will need to be counters in each branch for the total number of conditions evaluated since they execute sequentially

if (...) {
   count++;
   // Body of first if branch
} else if (...) {
   count += 2;
   // Body of second if branch
} else if (...) {
   count += 3;
   // Body of third if branch
} else {
   count += however many if conditions there are
   // Body of else branch
}