# Mathematic calculations in programming

I'm trying to work on a demonstration about multithreading. I need an example of a computationally-intensive function/method. But at the same time, the code that does the computing should be simple.

For example, I'm looking for a function that maybe does something like calculate the nth digit of pi or e:

``````function calculatePiToNthDecimalDigit(digits) {
var pi = "3.";

for (var i = 1; i < digits; i++) {
pi += digitOfPiAtDecimalPlace(i);
}

return pi;
}

function digitOfPiAtDecimalPlace(decimalPlace) {
...
}
``````

Can anyone give me an example of a function that is relatively simple but can be used in succession (e.g. tight loop) to generate a very hard-to-compute (takes a long time) value?

-

The simplest I can think of is summing a huge list of numbers. Addition is obviously easy, but if the list is huge, that will make it computationally-intensive, and the problem lends itself well to multi-threading.

-

Real tests come from real problems. How about the numerical integration of a function using a simple formula such as the trapezoidal rule:

Lets try to prove that using C#

``````void Main(string[] args)
{
int N = 2097153;
double two = Integral(0, Math.PI, N);
double err = (2.0 - two) / 2.0;
Console.WriteLine("N={0} err={1}", N, err);
}
double f(double x) { return Math.Sin(x); }
double Integral(double a, double b, int N)
{
double h = (b - a) / N;
double res = (f(a) + f(b)) / 2;
for (int j = 1; j < N; j++)
{
double x = a + j*h;
res += f(x);
}
return h * res;
}
``````

at which point I get `N=2097153` and `err=2.1183055309848E-13` after several milliseconds. If you go much higher in accuracy then the error starts to up as round-off errors start to creep in. I think something similar might happen with a calculation for `Pi` whereas you will reach you machine accuracy within a few milliseconds and beyond that you are really calculating garbage. You could just repeat the integral several times for a longer overall effect.

So you might be ok to show a drop in time from lets say 140 ms down to 90 ms and count it as a victory.

-
As an addition to this: I was able to get a `+195%` speedup using 3 threads compared to a sequential calculation using a quad core machine. I used the `ThreadPool.QueueUserWorkItem()` method. – ja72 Aug 21 '11 at 11:31

The multiplication of two NxN matrices has complexity proportional to N^3, so it is relatively easy to create a "computationally intensive" task, just by squaring a sufficiently large matrix. For example, as size goes from N=10 to N=100 to N=1000, the number of (scalar) multiplications required by the classic algorithm for matrix multiplication goes from one thousand to one million to one billion.

Also such a task has plenty of opportunities for parallel processing, if your multi-threading demonstration is meant to take advantage of such opportunities. E.g. the same row can be multiplied by more than one column in parallel.

-