Difference between revisions of "Kernal Blas"

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(Calculation of Pi)
(Calculation of Pi)
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When we run the program we see:
 
When we run the program we see:
====== 1st Run ======
+
 
 +
'''1st Run  
 
  1000            3.152 - took - 0 millisecs
 
  1000            3.152 - took - 0 millisecs
 
  10000          3.1328 - took - 0 millisecs
 
  10000          3.1328 - took - 0 millisecs
Line 36: Line 37:
 
  10000000        3.1417368 - took - 998 millisecs
 
  10000000        3.1417368 - took - 998 millisecs
 
  100000000      3.1419176 - took - 10035 millisecs
 
  100000000      3.1419176 - took - 10035 millisecs
 
+
 
  ''The first column represents the "stride" or the number of digits of pi we are calculating to.
 
  ''The first column represents the "stride" or the number of digits of pi we are calculating to.
  
 
With this method, we can see that the accuracy of the calculation is slightly off. This is due to the randomization of points within the circle. Running the program again will give us slightly different results.
 
With this method, we can see that the accuracy of the calculation is slightly off. This is due to the randomization of points within the circle. Running the program again will give us slightly different results.
  
====== 2nd Run ======
+
''' 2nd Run
 
  1000            3.12 - took - 0 millisecs
 
  1000            3.12 - took - 0 millisecs
 
  10000          3.1428 - took - 0 millisecs
 
  10000          3.1428 - took - 0 millisecs

Revision as of 14:36, 21 February 2018


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Kernal Blas

Team Members

  1. Shan Ariel Sioson
  2. Joseph Pham

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Progress

Assignment 1

Calculation of Pi

For this assessment, I used code found at helloacm.com

In this version, the value of PI is calculated using the Monte Carlo method. This method states:

  1. A circle with radius r in a squre with side length 2r
  2. The area of the circle is Πr2 and the area of the square is 4r2
  3. The ratio of the area of the circle to the area of the square is: Πr2 / 4r2 = Π / 4
  4. If you randomly generate N points inside the square, approximately N * Π / 4 of those points (M) should fall inside the circle.
  5. Π is then approximated as:
  • N * Π / 4 = M
  • Π / 4 = M / N
  • Π = 4 * M / N

For simplicity the radius of the circle is 1. With this, we randomly generate points within the area and count the number of times each point falls within the circle, between 0 and 1. We then calculate the ratio and multiply by 4 which will give us the approximation of Π.


When we run the program we see:

1st Run

1000            3.152 - took - 0 millisecs
10000           3.1328 - took - 0 millisecs
100000          3.14744 - took - 9 millisecs
1000000         3.141028 - took - 96 millisecs
10000000        3.1417368 - took - 998 millisecs
100000000       3.1419176 - took - 10035 millisecs

The first column represents the "stride" or the number of digits of pi we are calculating to.

With this method, we can see that the accuracy of the calculation is slightly off. This is due to the randomization of points within the circle. Running the program again will give us slightly different results.

2nd Run

1000            3.12 - took - 0 millisecs
10000           3.1428 - took - 0 millisecs
100000          3.13528 - took - 9 millisecs
1000000         3.143348 - took - 106 millisecs
10000000        3.1414228 - took - 1061 millisecs
100000000       3.14140056 - took - 8281 millisecs

The hotspot within the code lies in the loops. There iteration for the loops is O(n2)


Potential Speedup:

Using Gustafson's Law:

P = 50% of the code
P = 0.50
n = ?

S(n)= n - ( 1 - P ) ∙ ( n - 1 )
Sn = n - ( 1 - .5 ) ∙ ( n - 1 )
Sn =

Assignment 2

Assignment 3