Right, hey guys, i could really do with some help on my genetic algorithm here.It's driving me insane. Right, the problem i have is as follows

The genetic algorithm is not complete yet, i've just implemented the roulette wheel selection method. I know the fitness function is off too. The Roulette wheel selection works. But if two children have the same parent, then when it comes to outputting the data, it doesn't seem to work.

I'm not sure if the problem is the way i am assigning the variables to the children structs, or if it's the way i'm displaying the data. If someone could point me in the right direction. I'm not the strongest of programmers as you can see. Thanks.

```
#include <cstdlib>
#include <iostream.h>
#include <string.h>
#include <math.h>
#define Binscale 5 //Length of the Binary strings for each numbers, should be 10
#define ParentNumberInit 6 // should be 100
using namespace std;
//defining the functions
void conversion1(char binary_code[Binscale], int Value, int Fitness);
int fitnessfunction(int Value);
struct Parent
{
int Value;
char binary_code[Binscale];
int Fitness;
};
int main()
{
Parent parent[ParentNumberInit]; // initialises the array of which the parents are stored
int Value; // value is 1 to start the loop
int option; // option is the menu choice
int MutationRate = 9;
int CrossOver = 3;
srand((unsigned)time(0));
//menu
cout<<" Welcome to the numbers interface select an Option"<<endl;
cout<<" 1. Create a Parent Population "<<endl;
cout<<" 2. Test Fitness number "<<endl;
cout<<" 3. Return to menu "<<endl;
cout<<" 0. Quit! "<<endl;
cout<<endl;
cin>>option;
//Initiate Children
Parent child[ParentNumberInit];
//initalizes all elements in the array, and sets their value to 0.
for (int ParentNumber = 0; ParentNumber < ParentNumberInit; ParentNumber++)
{
parent[ParentNumber].Value = 0;
parent[ParentNumber].Fitness = 0;
child[ParentNumber].Value=0;
child[ParentNumber].Fitness=0;
for (int BitLengthTemp = 0; BitLengthTemp <= Binscale; BitLengthTemp++)
{
parent[ParentNumber].binary_code[Binscale] = 0;
}
for (int BitLengthTemp = 0; BitLengthTemp <= Binscale; BitLengthTemp++)
{
child[ParentNumber].binary_code[Binscale] = 0;
}
}
while(option != 0) // continuous while loop to keep the program going
{
if(option == 1) // number being input.
{
// Random Number Generator
//loops through to create all of the parents
for (int ParentNumber = 0; ParentNumber < ParentNumberInit; ParentNumber++)
{
//stops the numbers being created, being to large for the system to handle.
int Binarymax = (pow(2,Binscale)) - 1;
int randomnumber = rand() %(Binarymax);
parent[ParentNumber].Value = randomnumber;
//uses the fitness function to define the fitness of the solution
parent[ParentNumber].Fitness = fitnessfunction(parent[ParentNumber].Value);
//runs the binary conversion function. The main bulk of the work
conversion1( parent[ParentNumber].binary_code,
parent[ParentNumber].Value,
parent[ParentNumber].Fitness);
} // end of the loop, so that anohter parent can be created.
cout<<endl<<"Generation 1 :"<<endl<<endl<<endl;
//loop through all of the parents to display their information
for (int z = 0; z < ParentNumberInit; z++)
{
cout<<"Parent "<<(z+1)<<" Value = "<<parent[z].Value<<endl;
cout<<"Binary Conversion: ";
//Uses for loop to output the binary conversions.
for (int a = 0; a < Binscale; a ++)
{
cout<<parent[z].binary_code[a];
}
//Outputs the Fitness of each parent
cout<<endl<<"Fitness "<<parent[z].Fitness<<endl<<endl;
}
long int RouletteMax = 0;
int RandomNumber = 0;
int RunningTotal= 0;
/* Definitions
------------------
RouletteMax
The roulette max, is the sum of the populations fitness.
RandomNumber
When the Random Number is created it mimics the roulette wheel ball. The random
number being the number that the ball rests on. The Random number is calculated
between 0 and the RouletteMax.
Running Total
The running total is calculated, so that the roulette wheel can work. When a random
number is created, it is matched against the running total. If the random number is
is smaller than the running total, a parent has been found and is therefore selected
*/
//calculating the RouletteMax
for (int ParentNumber = 0; ParentNumber < ParentNumberInit; ParentNumber++)
{
RouletteMax = RouletteMax + parent[ParentNumber].Fitness;
}
cout<<"Roulette Max is "<<RouletteMax;
// loop through to create the exact amount of children as there are parents
for (int Child = 0; Child < ParentNumberInit; Child++ )
{
//Creating the variable RandNumber. note that it can be 0 also
RandomNumber = rand()% RouletteMax;
//The for loop that mimics the roulette wheel. Will match the parent with
//the child.
for (int ChildNumber = 0; ChildNumber < ParentNumberInit; ChildNumber++)
{
//Sets the first value for the running total, and subsequent values if the
//following parameter is not met
RunningTotal = parent[ChildNumber].Fitness + RunningTotal;
//If the RandomNumber is less than total, Parent has been found. Therefore
//The child will replicate the chromosome from the Parent.
if (RandomNumber < RunningTotal)
{
cout<<endl<<endl<<"Child: "<<(Child+1)<<endl;
cout<<endl<<endl<<"Random Number Generated is "<<RandomNumber<<endl<<endl;
cout<<"Parent "<<(ChildNumber+1)<<" has been chosen"<<endl;
//Copy the Parents variables to the child. Cannot do this for the binary array
child[ChildNumber].Value = parent[ChildNumber].Value;
child[ChildNumber].Fitness = parent[ChildNumber].Fitness;
cout<<"Child Value = "<<child[ChildNumber].Value<<endl;
cout<<"Child Fitness = "<<child[ChildNumber].Fitness<<endl;
//Ends the loop as the for loop condition is met once childnumber becomes ParentNumberInit
ChildNumber = ParentNumberInit;
//Once the Parent has been found, the running total needs to be reset, so future loops do not
//already have a large running total number
RunningTotal = 0;
}
} // end childnumber loop
} // end child loop
for (int Number = 0; Number < ParentNumberInit; Number++ )
{
conversion1(child[Number].binary_code,child[Number].Value,child[Number].Fitness);
}
//Will display the information of the new generation, the children.
cout<<endl<<"Generation 2 :"<<endl<<endl<<endl;
//loop through all of the parents to display their information
for (int z = 0; z < ParentNumberInit; z++)
{
cout<<"Child "<<(z+1)<<" Value = "<<child[z].Value<<endl;
cout<<"Binary Conversion: ";
//Uses for loop to output the binary conversions.
for (int a = 0; a < Binscale; a ++)
{
cout<<child[z].binary_code[a];
}
//Outputs the Fitness of each parent
cout<<endl<<"Fitness "<<child[z].Fitness<<endl<<endl;
}
//ending statement.
cout<<endl<<" Enter 5 to return to menu "<<endl;
cin>>option;
} // end of option 1
if(option == 2 ) //Simple test fitness setup
{
int number;
cout<<"give us an integer butt "<<endl;
cin>>number;
number = fitnessfunction(number);
cout<<"Fitness of Value is "<<number<<endl;
cin>>option;
}
//shows the menu through the use of a loop
if(option == 3 ) //menu
{
cout<<" Welcome to the numbers interface select an Option"<<endl;
cout<<" 1. Start Genetic Algorithm "<<endl;
cout<<" 2. Test Fitness number "<<endl;
cout<<" 3. Return to menu "<<endl;
cout<<" 0. Quit! "<<endl;
cout<<endl;
cin>>option;
}
if(option>3) // Error Checking, number entered cannot be greater than 5, as there are no options above 5
{
option = 5;
}
}
//signals completion of the program
return 0;
} // end of while loops
/////////////////////////////////////////////////////////////////////////////////////////////////
/*
* Freshly completed, Conversion 1 is the first step in creating a genetic algorithm
* it creates a single parent that can be used throughout the main program
* this parent is defined within a struct and contains the Value,
* the binary conversion and the fitness of the function.
*
*/
void conversion1(char binary_code[Binscale], int Value, int Fitness)
{
int binary_num = 1;
int outcome;
int i;
binary_num = 1;
for(i = 0; i < Binscale; i++)
{
if(i != 0)
binary_num *= 2; //HOWEVER LONG b.l (EG 10 = 512)
}
for (i = 0; i < Binscale; i ++)
{
outcome = Value - binary_num; //WHATEVER NUMBER IN, TAKES AWAY BINAY_NUM AWAY
if(outcome >= 0) //IF GREATER THAN 0 THE NUMBER IS 1
{
binary_code[i] = '1';
Value = Value - binary_num; //TAKES AWAY BINARY NUM FROM THE INPUT
}
else //OTHERWISE ONE
{
binary_code[i] = '0';
}
binary_num = binary_num/2;
}
// end of for loop
}
int fitnessfunction(int Value)
{
Value = (Value*Value)+1;
Value = (10000/Value);
return Value;
}
```