To make the program do what you wan you could take a look at this code, It may be get you started.
I found it very useful, and tested it against mathematica solution, and it is ok.
for more information go here

```
/*
A simple code for option valuation using the explicit forward Euler method
for the class Derivative Securities, fall 2010
http://www.math.nyu.edu/faculty/goodman/teaching/DerivSec10/index.html
Written for this purpose by Jonathan Goodman, instructor.
Assignment 8
*/
#include <iostream>
#include <fstream>
#include <math.h>
#define NSPOTS 100 /* The number of spot prices computed */
/* A program to compute a simple binomial tree price for a European style put option */
using namespace std;
// The pricer, main is at the bottom of the file
void FE( // Solve a pricing PDE using the forward Euler method
double T, double sigma, double r, double K, // The standard option parameters
double Smin, double Smax, // The min and max prices to return
int nPrices, // The number of prices to compute between Smin and Smax,
// Determines the accuracy and the cost of the computation
double prices[], // An array of option prices to be returned.
double intrinsic[], // The intrinsic value at the same prices
double spots[], // The corresponding spot prices, computed here for convenience.
// Both arrays must be allocated in the calling procedure
double *SEarly ) { // The early exercise boundary
// Setup for the computation, compute computational parameters and allocate the memory
double xMin = log(Smin); // Work in the log variable
double xMax = log(Smax);
double dx = ( xMax - xMin )/ ( (double( nPrices - 1 ) ) ); // The number of gaps is one less than the number of prices
double CFL = .8; // The time step ratio
double dt = CFL*dx*dx/sigma; // The forward Euler time step size, to be adjusted slightly
int nTimeSteps = (int) (T/dt); // The number of time steps, rounded down to the nearest integer
nTimeSteps++; // Now rounded up
dt = T / ( (double) nTimeSteps ); // Adjust the time step to land precisely at T in n steps.
int nx = nPrices + 2*nTimeSteps; // The number of prices at the final time, growing by 2 ...
// ... each time step
xMin = xMin - nTimeSteps*dx; // The x values now start here
double *fOld; // The values of the pricing function at the old time
fOld = new double [nx]; // Allocated using old style C++ for simplicity
double *fNew; // The values of the pricing function at the new time
fNew = new double [nx];
double *V; // The intrinsic value = the final condition
V = new double [nx];
// Get the final conditions and the early exercise values
double x; // The log variable
double S; // A stock price = exp(x)
int j;
for ( j = 0; j < nx; j++ ) {
x = xMin + j*dx;
S = exp(x);
if ( S < K ) V[j] = K-S; // A put struck at K
else V[j] = 0;
fOld[j] = V[j]; // The final condition is the intrinsic value
}
// The time stepping loop
double alpha, beta, gamma; // The coefficients in the finite difference formula
alpha = beta = gamma = .333333333333; // XXXXXXXXXXXXXXXXXXXXXXXXXXX
int jMin = 1; // The smallest and largest j ...
int jMax = nx - 1; // ... for which f is updated. Skip 1 on each end the first time.
int jEarly ; // The last index of early exercise
for ( int k = nTimeSteps; k > 0; k-- ) { // This is, after all, a backward equation
jEarly = 0; // re-initialize the early exercise pointer
for ( j = jMin; j < jMax; j++ ) { // Compute the new values
x = xMin + j*dx; // In case the coefficients depend on S
S = exp(x);
fNew[j] = alpha*fOld[j-1] + beta*fOld[j] + gamma*fOld[j+1]; // Compute the continuation value
if ( fNew[j] < V[j] ) {
fNew[j] = V[j]; // Take the max with the intrinsic value
jEarly = j; // and record the largest early exercise index
}
}
for ( j = jMin; j < jMax; j++ ) // Copy the new values back into the old array
fOld[j] = fNew[j];
jMin++; // Move the boundaries in by one
jMax--;
}
// Copy the computed solution into the desired place
jMin--; // The last decrement and increment were mistakes
jMax++;
int i = 0; // The index into the output array
for ( j = jMin; j < jMax; j++ ) { // Now the range of j should match the output array
x = xMin + j*dx;
S = exp(x);
prices[i] = fOld[j];
intrinsic[i] = V[j];
spots[i++] = S; // Increment i after all copy operations
}
double xEarly = xMin + jEarly*dx;
*SEarly = exp(xEarly); // Pass back the computed early exercise boundary
delete fNew; // Be a good citizen and free the memory when you're done.
delete fOld;
delete V;
return;
}
int main() {
cout << "Hello " << endl;
ofstream csvFile; // The file for output, will be csv format for Excel.
csvFile.open ("PutPrice.csv");
double sigma = .3;
double r = .003;
double T = .5;
double K = 100;
double Smin = 60;
double Smax = 180;
double prices[NSPOTS];
double intrinsic[NSPOTS];
double spots[ NSPOTS];
double SEarly;
FE( T, sigma, r, K, Smin, Smax, NSPOTS, prices, intrinsic, spots, &SEarly );
for ( int j = 0; j < NSPOTS; j++ ) { // Write out the spot prices for plotting
csvFile << spots[j];
if ( j < (NSPOTS - 1) ) csvFile << ", "; // Don't put a comma after the last value
}
csvFile << endl;
for ( int j = 0; j < NSPOTS; j++ ) { // Write out the intrinsic prices for plotting
csvFile << intrinsic[j];
if ( j < (NSPOTS - 1) ) csvFile << ", "; // Don't put a comma after the last value
}
csvFile << endl;
for ( int j = 0; j < NSPOTS; j++ ) { // Write out the computed option prices
csvFile << prices[j];
if ( j < (NSPOTS - 1) ) csvFile << ", ";
}
csvFile << endl;
csvFile << "Critical price," << SEarly << endl;
csvFile << "T ," << T << endl;
csvFile << "r ," << r << endl;
csvFile << "sigma ," << sigma << endl;
csvFile << "strike ," << K << endl;
return 0 ;
}
```