The reason not to use array sections with
MPI_SEND is that the compiler has to create a temporary copy with some MPI implementations. This is due to the fact that Fortran can only properly pass array sections to subroutines with explicit interfaces and has to generate temporary "flattened" copies in all other cases, usually on the stack of the calling subroutine. Unfortunately in Fortran before the TR 29113 extension to F2008 there is no way to declare subroutines that take variable type arguments and MPI implementations usually resort to language hacks, e.g.
MPI_Send is entirely implemented in C and relies on Fortran always passing the data as a pointer.
Some MPI libraries work around this issue by generating huge number of overloads for
- one that takes a single
- one that takes an 1-d array of
- one that takes an 2-d array of
- and so on
The same is then repeated for
DOUBLE PRECISION, etc. This is still a hack as it does not cover cases where one passes user-defined type. Further it greatly complicates the C implementation as it now has to understand the Fortran array descriptors, which are very compiler-specific.
Fortunately times are changing. The TR 29113 extension to Fortran 2008 includes two new features:
- assumed-type arguments:
- assumed-dimension arguments:
The combination of both, i.e.
TYPE(*), DIMENSION(..), INTENT(IN) :: buf, describes an argument that can both be of varying type and have any dimension. This is already being taken advantage of in the new
mpi_f08 interface in MPI-3.
Non-blocking calls present bigger problems in Fortran that go beyond what Alexander Vogt has described. The reason is that Fortran does not have the concept of suppressing compiler optimisations (i.e. there is no
volatile keyword in Fortran). The following code might not run as expected:
INTEGER :: data
data = 10
CALL MPI_IRECV(data, 1, MPI_INTEGER, 0, 0, MPI_COMM_WORLD, req, ierr)
! data is not used here
CALL MPI_WAIT(req, MPI_STATUS_IGNORE, ierr)
! data is used here
One might expect that after the call to
data would contain the value received from rank 0, but this might very well not be the case. The reason is that the compiler cannot know that
data might change asynchronously after
MPI_IRECV returns and therefore keep its value in a register instead. That's why non-blocking MPI calls are generally considered as dangerous in Fortran.
TR 29113 has solution for that second problem too with the
ASYNCHRONOUS attribute. If you take a look at the
mpi_f08 definition of
buf argument is declared as:
TYPE(*), DIMENSION(..), INTENT(OUT), ASYNCHRONOUS :: buf
buf is a scalar argument, i.e. no temporary copy is created, a TR 29113 compliant compiler would not resort to register optimisations for the buffer argument.