Difference between revisions of "CSC111 Lab 13"

From dftwiki3
Jump to: navigation, search
(Factorial)
(Factorial)
Line 53: Line 53:
  
 
;Question 1
 
;Question 1
 +
:
 
:*Add print statements to your fact function so that it will print exactly what it does.  For example, before it tests to see if ''n'' is less than equal to 1, you could print:
 
:*Add print statements to your fact function so that it will print exactly what it does.  For example, before it tests to see if ''n'' is less than equal to 1, you could print:
  

Revision as of 10:38, 28 April 2010

--D. Thiebaut 15:09, 28 April 2010 (UTC)


This lab deals with recursive functions.

Factorial

Create a copy of this simple example:

# factorial.py
# Demonstrates a recursive factorial function

def fact( n ):
    if n<=1: 
        return 1
    y = fact( n-1 )
    result = n * y
    return result


def main():
    n = input( "Enter a positive number: " )
    x = fact( n )
    print "the factorial of %d is %d." % ( n , x )

main()


Run your program and verify that it computes the correct result. Below are some factorials numbers to compare your output to.

  1! =                    1
  2! =                    2
  3! =                    6
  4! =                   24
  5! =                  120
  6! =                  720
  7! =                 5040
  8! =                40320
  9! =               362880
 10! =              3628800
 11! =             39916800
 12! =            479001600
 13! =           6227020800
 14! =          87178291200
Question 1
  • Add print statements to your fact function so that it will print exactly what it does. For example, before it tests to see if n is less than equal to 1, you could print:
    print "fact function started.  Receives n =", n
    print "testing if n is >= 1"
  • Add print statements that will show the values of y and result.
  • Run your program and observe the print statements. Can you see better how fact recursively calls itself?
Question 2
  • Create the more sophisticated program shown below. Observe it well and try to figure out what the indent variable does.


# factorialPrint.py
# Demonstrates a recursive factorial function
 
def fact( n, indent ):
    print indent, "fact(%d) started" % n
    print indent, "comparing %d to 1" % n
    if n<=1: 
        print indent, "%d is <= 1.  Returning 1" % 1
        return 1

    print indent, "%d is not <= 1.  Calling fact(%d) and storing it in y" % (n, n-1)
    y = fact( n-1, indent + "    "  )
    print indent, "just received %d from fact( %d )." % ( y, n-1 )
    result = n * y
    print indent, "multiplied %d by %d.  It's %d.  Returning %d to caller" % ( n, y, result, result )
    return result
 
 
def main():
    # print first 15 factorials 
    n = input( "Enter a positive integer: " )
    print "Main calls fact( %d )" % n 
    y = fact( n, "   " )
    print "Main receives result = ", y
 
main()
  • Run the program
  • Explain the pattern made by the printed lines. Why this shape?
  • Where does the stopping condition appear in the printed lines?

Binary Search

Create a copy of the binary search program we saw recently in class. Observe the main function. Make sure you figure out how large the array is.

Run the program and verify that the search function does a good job locating or not the numbers.

First problem

Modify the program so that it counts the number of comparisons that it performs. A good way to do this is to create a global variable, count that is declared at the beginning of your program, and which you increment by one, every time the binsearch function compares two quantities. These comparisons are a good indicator of the amount of "work" done by the function, since it is obvious just looking at the program to figure out how much time the function will call itself. The correct way to use count as a global variables is illustrated below. You initialize the variable at the beginning of the program, and in the functions that need to use it, you define count as global so that python will know that count is not just a local variable used inside the function, but refers to something defined outside the function.

  1. program header

count = 0

def binsearch( ... ):

   global count
   ...
   count += 1


def main():

   global count
   
   ...
   count = 0
   binsearch( ... )
   ...

Make the main program print the number of comparisons performed after the function returns to main.

Make sure you reset the counter to 0 for every new search!