# Vastly different output C++ monte carlo approximation

doing a C++ approximation of Pi using a random number generator, output works exactly as expected on my AMD 64 machine running Ubuntu, however on my school machine the second algorithm I've implemented is broken, and would love some insight as to why. Code is as follows:

``````#ifndef RANDOMNUMBER_H_
#define RANDOMNUMBER_H_

class RandomNumber {
public:
RandomNumber() {
x = time(NULL);
m = pow(2, 19); //some constant value
M = 65915 * 7915; //multiply of some simple numbers p and q
method = 1;
}
RandomNumber(int seed) {
x = ((seed > 0) ? seed : time(NULL));
m = pow(2, 19); //some constant value
method = 1; //method number
M = 6543 * 7915; //multiply of some simple numbers p and q
}
void setSeed(long int seed) {
x = seed; //set start value
}

void chooseMethod(int method) {
this->method = ((method > 0 && method <= 2) ? method : 1); //choose one of     two method
}

long int linearCongruential() { //first generator, that uses linear congruential method
long int c = 0; // some constant
long int a = 69069; //some constant
x = (a * x + c) % m; //solution next value
return x;
}

long int BBS() { //algorithm Blum - Blum - Shub
x = (long int) (pow(x, 2)) % M;
return x;
}
double nextPoint() { //return random number in range (-1;1)
double point;
if (method == 1) //use first method
point = linearCongruential() / double(m);
else
point = BBS() / double(M);
return point;
}
private:
long int x; //current value
long int m; // some range for first method
long int M; //some range for second method
int method; //method number
};

#endif /* RANDOMNUMBER_H_ */
``````

and test class:

``````#include <iostream>
#include <stdlib.h>
#include <math.h>
#include <iomanip>
#include "RandomNumber.h"
using namespace std;

int main(int argc, char* argv[]) {
cout.setf(ios::fixed);
cout.precision(6);
RandomNumber random;
random.setSeed(argc);
srand((unsigned) time(NULL));
cout << "---------------------------------" << endl;
cout << "   Monte Carlo Pi Approximation" << endl;
cout << "---------------------------------" << endl;
cout << " Enter number of points: ";
long int k1;
cin >> k1;
cout << "Select generator number: ";
int method;
cin >> method;
random.chooseMethod(method);
cout << "---------------------------------" << endl;
long int k2 = 0;
double sumX = 0;
double sumY = 0;
for (long int i = 0; i < k1; i++) {
double x = pow(-1, int(random.nextPoint() * 10) % 2)
* random.nextPoint();
double y = pow(-1, int(random.nextPoint() * 10) % 2)
* random.nextPoint();
sumX += x;
sumY += y;
if ((pow(x, 2) + pow(y, 2)) <= 1)
k2++;

}
double pi = 4 * (double(k2) / k1);
cout << "M(X)  = " << setw(10) << sumX / k1 << endl; //mathematical expectation of x
cout << "M(Y)  = " << setw(10) << sumY / k1 << endl; //mathematical expectation of y
cout << endl << "Pi = " << pi << endl << endl; //approximate Pi

return 0;
}
``````

The second method returns 4.000 consistently on my lab machine, yet returns a rather close approximation on my personal machine.

-
Sounds like a difference in integer length or some such. Or perhaps you've wandered into "undefined" territory with integer overflow, etc. –  Hot Licks Nov 27 '12 at 20:33
what compilers are you using? –  piokuc Nov 27 '12 at 20:33
What OS and compiler is your lab machine? –  Olaf Dietsche Nov 27 '12 at 20:34
So, what's different between the two machines in terms of OS (64/32bit), hardware and the compiler? –  NPE Nov 27 '12 at 20:34
Also, are you 100% positive you're running exactly the same code, having done a complete clean rebuild in both cases? –  NPE Nov 27 '12 at 20:35
show 1 more comment

For one thing, the BBS generator as you're using it will always return `1`.

Since your program takes no arguments, presumably its `argc` will be `1`. You pass `argc` as the seed (why?), so the initial value of `x` is `1`.

`BBS()` has the following logic:

``````x = (long int) (pow(x, 2)) % M;
``````

Clearly, `1` squared modulo `M` gives `1`, so `x` never changes.

When you run the simulation with such a generator, your program will always output `4`.

P.S. Wikipedia has the following to say about the initial value `x0` for Blum Blum Shub:

The seed `x0` should be an integer that's co-prime to `M` (i.e. `p` and `q` are not factors of `x0`) and not `1` or `0`.

-
Perhaps they're running it with arguments? I'd bet that they meant to pass in `atoi(argv[1])`. –  Xymostech Nov 27 '12 at 20:47
@Xymostech: That's what I thought (on both points). –  NPE Nov 27 '12 at 20:47
What I was meaning to do is if arguments are passed, then call the setSeed function, otherwise use system time. Working on that but thank you for the help. –  js7354 Nov 28 '12 at 6:27