I have started a migration of a high energy physics algorithm written in FORTRAN to an object oriented approach in C++. The FORTRAN code uses a lot of global variables all across a lot of functions.
I have simplified the global variables into a set of input variables, and a set of invariants (variables calculated once at the beginning of the algorithm and then used by all the functions).
Also, I have divided the full algorithm into three logical steps, represented by three different classes. So, in a very simple way, I have something like this:
double calculateFactor(double x, double y, double z)
{
InvariantsTypeA invA();
InvariantsTypeB invB();
// they need x, y and z
invA.CalculateValues();
invB.CalculateValues();
Step1 s1();
Step2 s2();
Step3 s3();
// they need x, y, z, invA and invB
return s1.Eval() + s2.Eval() + s3.Eval();
}
My problem is:
- for doing the calculations all the
InvariantsTypeX
andStepX
objects need the input parameters (and these are not just three). - the three objects
s1
,s2
ands3
need the data of theinvA
andinvB
objects. - all the classes use several other classes through composition to do their job, and all those classes also need the input and the invariants (by example,
s1
has a member objecttheta
of classThetaMatrix
that needsx
,z
andinvB
to get constructed). - I cannot rewrite the algorithm to reduce the global values, because it follows several high energy physics formulas, and those formulas are just like that.
Is there a good pattern to share the input parameters and the invariants to all the objects used to calculate the result?
Should I use singletons? (but the calculateFactor
function is evaluated around a million of times)
Or should I pass all the required data as arguments to the objects when they are created?(but if I do that then the data will be passed everywhere in every member object of every class, creating a mess)
Thanks.