```
float** matrix::mult(float** matrix1){
float** result=new float *[n];
int i,j,k;
for(i=0;i<n;i++){
result[i]=new float [n];
}
vect v1;
vect v2;
vect v3;
vect total;
clock_t start, end;
start = clock();
float result_ij=0;
for(i=0;i<n;i++){
for(j=0;j<n;j++){
result_ij=0;
total.v=_mm_set1_ps(0);
for(k=0;k<n;k=k+4){
v1.v=_mm_set_ps(user_matrix[k][j],user_matrix[k+1][j],user_matrix[k+2][j],user_matrix[k+3][j]);
v2.v=_mm_set_ps(matrix1[i][k],matrix1[i][k+1],matrix1[i][k+2],matrix1[i][k+3]);
v3.v=_mm_mul_ps(v1.v,v2.v);
total.v=_mm_add_ps(total.v,v3.v);
}
result[i][j]=total.a[1]+total.a[0]+total.a[2]+total.a[3];
}
}
end = clock();
cout<<(double)(end-start)/CLOCKS_PER_SEC<<endl;
return result;
}
```

This code is about exactly the same speed as the scalar code. I can't see why this would be so slow, it was compiled with g++ and the vect type is a union.

```
union vect {
__m128 v;
float a[4];
} ;
```

For the matrix as a multidimensional array, what is the fastest way to load that into the SSE register?