# Numerical solution to differential equations in C++, path to take?

Edit

I am now using odeint. It is fairly simple to use and less memory hungry than my brute force algorithm implementation.

Check my questions here-->http://stackoverflow.com/questions/12060111/using-odeint-function-definition

and here-->http://stackoverflow.com/questions/12150160/odeint-streaming-observer-and-related-questions

I am trying to implement a numerical method (Explicit Euler) to solve a set of three coupled differential equations. I have worked with C before, but that was a very long time ago (effectively forgotten everything). I have a pretty good idea on what I want my program to do and also have a rough algorithm.

I am interested in using C++ for this task (picked up Stroustroup's Programming: Principles and Practice using C++). My question is, should I go with arrays or vectors? Vectors seem easier to handle, but I was unable to find how you can make a function return a vector? Is it possible for a function to return more than one vector? At this point, I am familiarizing myself with the C++ syntax.

I basically need my function to return many arrays. I realize that it is not possible in C++, so I can also work with some nested structure such as {{arr1},{arr2},{arr3}..}. Please bear with me as I am a noob and come from programming in Mathematica.

Thanks!

-
Please please don't use explicit euler. Don't use RK4 either. Use a method which has error control, like Dormand Prince or Burlisch Stoer. There are plenty of libraries for doing that: boost::numeric::odeint is one of them, GSL has other stuff. This is a difficult enough topic to not want to write code yourself. – Alexandre C. Dec 11 '11 at 15:15
For sure, I agree, but I was asked to do this by my teacher to verify my answer with his. Then we move on to something more accurate.Thank you for the tip on not using RK4! – Antillar Maximus Dec 11 '11 at 15:20

If you want to use C++ for integrating ordinary differential equations and you don't want to reinvent the wheel use odeint. This lib is on its way of becoming the de facto standard for solving ODEs in C++. The code is very flexible and highly optimized and can compete with any handcrafted C-code (and Fortran anyway).

Commenting on you question on returning vectors or arrays: Functions can return vectors and arrays if the are wrapped in a class (like std::array). But this is not recommended, since you make many unnecessary copies (incl. calling the constructors and destructors every time). I assume you want to put your function equation into a c++ function and let it return the resulting vector. For this task it's much better if you pass a reference to a vector to the function and let the function fill this vector. This is also the way how odeint has implemented this.

-
All compilers worth their salt implement copy elision. Optimize for readability first. – Thomas Dec 11 '11 at 15:19
Thank you Andre! I will look into the standard library you have linked me to. I use VC++ 2010, will the library you linked to cause problems with the compiler? I am not an experienced programmer, so I don't know. Also, just out of curiosity can you please give me a simple example of how this is done (sample code)? I can do some more studying based on your example. The reason I am doing this using an inaccurate technique is because my mentor wants me to match my numbers with his before we go to the next level and make it more accurate. – Antillar Maximus Dec 11 '11 at 15:25
As far as I know the lib has been tested with MSVC 2010 as well and is running without problems. To get an idea of how the lib you can find an example right on the main site of odeint. It is quite easy and straight forward. There's is a good documentation as well, which is written currently. – André Bergner Dec 11 '11 at 18:21
I also wanted to note somthing to the comments of your orignal question (I cant comment there?). The correct choice of the integration method you use depends on several details of your problem. For instance, if you have a stiff system you need another solver as you would need for a hamiltonian system. If you have a simple standard system (e.g. Lotka-Volterra) RK4 is just fine. Euler is also important if you're dealing with stochastic differential equations. And at last it depends on what you want to do with the data (level of accuracy, equidistant sampling or not,...). – André Bergner Dec 11 '11 at 18:33

http://www.codeproject.com/KB/recipes/odeint.aspx

-

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 ;

}
``````
-
Thank you sir! I will study this. It looks very complicated, but I can spend some time on it and ask here for hep. – Antillar Maximus Dec 11 '11 at 15:26