# how to parallalize a backpropagation algorithm [closed]

I have problems parallelizing this code, can you help me please parallelizing it?

Backpropagation is a method for computing how to adjust the values of the weight matrices so that output values are closer to desired target values. A standard procedure is to a set of pattern-target vector pairs as a training set to adjust the weights and another set of pattern-target vector pairs to test or validate the trained network.

A pattern-target pair is a pattern vector with Ninput elements and a target vector with Nouput elements. The pattern is presented to the neural network as input and the output is computed as above. The output vector is compared with the associated target vector to compute weight corrections which will reduce a measure of error called sum of squares of error or sse. This term is defined below.

#include <iostream>
#include <fstream>
#include <cstdlib>
#include <cmath>

using namespace std;
int N_PT_pair, Ninput, Nhidden, Noutput;
double** W1,**W2,**pattern,**target;

int save_weights(char* filename);
double** allocate_matrix(int rows,int cols);
int deallocate_matrix(double**a,int rows);
double bptrain(int MaxEpoch, double lrate);
double f(double x){return 1.0/(1.0+exp(-x));}

int main(int argc, char *argv[])
{
int MaxEpoch;
double lrate;
char * weight_filename, *PTpair_filename;
if(argc<3){
cout<<"This program takes at least two arguments\n";
cout<<"The file name for weights and the training set\n"<<endl;
return -1;
}
weight_filename = argv[1];
PTpair_filename = argv[2];
if(argc>3)
MaxEpoch = atoi(argv[3]);
else
MaxEpoch = 1000;
if(argc>4)
lrate = atof(argv[4]);
else
lrate = 0.05;

{

}
bptrain(MaxEpoch,lrate);
save_weights(weight_filename);

{

deallocate_matrix(pattern,N_PT_pair);

deallocate_matrix(target,N_PT_pair);

deallocate_matrix(W1,Nhidden+1);

deallocate_matrix(W2,Noutput+1);
}

return 0;
}
double bptrain(int MaxEpoch, double lrate)
{
int epoch, pt, i, j, k;
double sse, sum, **dW1, **dW2, \
*input,*hidden_out,*output,*delta1,*delta2;

{

dW1=allocate_matrix(Nhidden+1,Ninput+1);

dW2=allocate_matrix(Noutput+1,Nhidden+1);

}

hidden_out = new double[Nhidden+1];
output = new double[Noutput+1];
delta1 = new double[Nhidden+1];
delta2 = new double[Noutput+1];
if (hidden_out==NULL||output==NULL||delta1==NULL||delta2==NULL)
{ cout<<"error allocating array"<<endl; exit(-1);}

for(epoch=0; epoch<MaxEpoch; epoch++)
{

{

for(j=0; j<=Nhidden; j++)

for(i=0; i<=Ninput; i++)
dW1[j][i]=0.0;

for(k=0;k<=Noutput;k++)

for(j=0; j<=Nhidden; j++)
dW2[k][j]=0.0;
}
sse = 0; // Sum of square of errors

After all pattern-target pairs are presented, the weight corrections are added applied to the W1 and W2 arrays using the selected learning rule. This procedure called an epoch is repeated as often as needed to reduce errors to a desired level. The pseudo code below expresses this procedure more clearly. and this is the main loop to parallelize.

for( pt=0; pt<N_PT_pair; pt++)
{
input = pattern[pt];
input[0] = 1;

// Compute hidden outputs
hidden_out[ 0 ] = 1;

for (j=1; j<=Nhidden; j++)
{
sum = 0.0;

for (i=0; i<=Ninput; i++)
sum += W1[j][i]*input[i];
hidden_out[j] = f(sum);
}
// Compute outputs

for (k=1; k<=Noutput; k++)
{
sum = 0.0;

for (j=0; j<=Nhidden; j++)
sum += W2[k][j]*hidden_out[j];
output[ k ] = f(sum);
}
//Compute delta2[ ] and contribution to dW2[ ][ ]

for( k=1; k<=Noutput; k++)
{
delta2[k] = output[k]*(1-output[k])*(target[pt][k] - output[k]);
for( j=0; j<=Nhidden; j++)
dW2[k][j] += delta2[k]*hidden_out[j];
}
//compute delta1[ ] and contribution to dW1[ ][ ]
for(j=1; j<=Nhidden; j++)
{
sum = 0.0;

for(k=1; k<=Noutput; k++)
sum+= delta2[k]*W2[k][j];

delta1[j] = hidden_out[j]*(1-hidden_out[j])*sum;

for( i=0; i<=Ninput; i++)
dW1[j][i] += delta1[j]*input[i];
}

for(k=1; k<=Noutput; k++)
sse+=pow((target[pt][k]-output[k]),2);
} // end of pt loop
if(epoch%(MaxEpoch/100)==0)
cout << "mean square error = " << sse/N_PT_pair<<endl;

//update weights

{

for(j=0; j<=Nhidden; j++)

for(i=0; i<=Ninput; i++)
W1[j][i]+=lrate*dW1[j][i];

for(k=0; k<=Noutput; k++)

for(j=0; j<=Nhidden; j++)
W2[k][j]+=lrate*dW2[k][j];
}
} // end of epoch loop
delete [ ] hidden_out;
delete [ ] output;
delete [ ] delta1;
delete [ ] delta2;

{

deallocate_matrix(dW1,Nhidden+1);

deallocate_matrix(dW2,Noutput+1);

}

return 0;
}
{
ifstream infile;
int i, j, k;
infile.open(filename);
if(infile.fail())
{cout<<"weight file open failed"<<endl;exit(-1);}
infile >> Ninput >> Nhidden >> Noutput;

{

W1=allocate_matrix(Nhidden+1,Ninput+1);

W2=allocate_matrix(Noutput+1,Nhidden+1);
}

{

for(j=1; j<=Nhidden; j++)
for( i=0;i<=Ninput;i++)

infile >> W1[j][i];

for(k=1; k<=Noutput; k++)
for(j=0;j<=Nhidden;j++)

infile >> W2[k][j];
}

infile.close();
return 0;

}
int save_weights(char* filename)
{
ofstream outfile;
int i, j, k;
outfile.open(filename);
if(outfile.fail())
{cout<<"weight file open failed"<<endl;exit(-1);}
outfile << Ninput <<" "<< Nhidden <<" "<< Noutput<<endl;
for(j=1;j<=Nhidden;j++)
{
for( i=0; i<=Ninput; i++)
outfile << W1[j][i]<<" ";
outfile<<endl;
}
outfile<<endl;
for(k=1; k<=Noutput; k++)
{
for(j=0; j<=Nhidden; j++)
outfile << W2[k][j]<<" ";
outfile<<endl;
}
outfile.close();
return 0;
}
{
ifstream infile;
int pt, i, k, Ntemp;
infile.open(filename);
if(infile.fail())
{cout<<"PTpair file open failed"<<endl; exit(-1);}
infile >> Ntemp;
if (Ntemp!=Ninput)
{   cout<<"PTpair input size does not fit net\n"<<endl; exit(-1);
}
infile >> Ntemp;
if (Ntemp!=Noutput)
{   cout<<"PTpair output size does not fit net\n"<<endl; exit(-1);
}
infile >>N_PT_pair;

{

pattern=allocate_matrix(N_PT_pair,Ninput+1);

target=allocate_matrix(N_PT_pair,Noutput+1);

}

for(pt=0; pt<N_PT_pair; pt++)
{
pattern[pt][0] = 1;

{

{
for(i=1; i<=Ninput; i++)

infile >> pattern[pt][i];
}

{
for(k=1; k<=Noutput; k++)

infile >> target[pt][k];
}
}
}

infile.close();
return 0;
}
double** allocate_matrix(int rows,int cols)
{
double **a;
a = new double*[rows];
if(a==NULL){cout<<"matrix allocation failed"<<endl;exit(-1);}

for (int j=0;j<rows;j++){
a[j] =  new double[cols];
if(a[j]==NULL) {cout<<"matrix allocation failed"<<endl;exit(-1);}
}
return a;
}
int deallocate_matrix(double**a,int rows)
{
// #pragma omp parallel for shared(a,rows)
for(int i=0;i<rows;i++)
delete [] a[i];
delete [ ] a;
return 0;
}
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Welcome to Stack Overflow! What have you tried? –  Oli Charlesworth May 30 '12 at 7:51
This question is a duplicate of your previous one! You should edit and extend it instead. –  Hristo Iliev May 30 '12 at 8:26
In Backpropagation (for multilayer perceptrons) we have at least one matrix-vector multiplication and there exist numerous libraries that parallelize this, e. g. CUBLAS or MKL. This would be the easiest way. –  alfa May 30 '12 at 8:56