MPI provides various means to build libraries that use it "behind the scenes". For starters, you can initialise MPI on demand. MPI-2 modified the requirements for calling
MPI_Init so every compliant implementation should be able to correctly initialise with
NULL arguments to
MPI_Init (because the actual program arguments might not be available to the library). Since MPI should only be initialised once, the library must check if it was already initialised by calling
MPI_Initialized. The code basically looks like this:
The initialisation code also registers an exit handler by calling
atexit() from the C standard library. Within this exit handler it finalises the MPI library if it not already finalised. Failure to do so might result in
mpiexec terminating the whole MPI job with a message that at least one process has exited without finalising MPI:
This arrangement allows you to write your
integral_count_MPI function simply like:
... MPI computations ...
integral_count_MPI will demand-initialise the MPI library on the first call. Later calls will not result in reinitialisation because of the way
library_init is written. Also no explicit finalisation is necessary - the exit handler will take care.
Note that you will still need to launch the code via the MPI process launcher (
mpiexec, etc.) and will have to be careful with doing I/O, since the serial part of the code would execute in each instance. Many MPI-enabled libraries provide their own I/O routines for that purpose that filter on the process rank and allow only rank 0 to perform the actual I/O. You can also use the dynamic process management facilities of MPI to spawn additional processes on demand, but that would require that you abstract a huge portion of the process management into the library that performs the integration, which would make it quite complex (and the code of your main program would look awkward).