It is not that easy to do it automatically. The
DO CONCURRENT construct has a forall-header which means that it could accept multiple loops, index variables definition and a mask. Basically, you need to replace:
DO CONCURRENT([<type-spec> :: ]<forall-triplet-spec 1>, <forall-triplet-spec 2>, ...[, <scalar-mask-expression>])
<type-spec> :: <indexes>]
!$omp parallel do
DO <forall-triplet-spec 1>
DO <forall-triplet-spec 2>
[IF (<scalar-mask-expression>) THEN]
!$omp end parallel do
(things in square brackets are optional, based on the presence of the corresponding parts in the forall-header)
Note that this would not be as effective as parallelising one big loop with
<iters 1>*<iters 2>*... independent iterations which is what
DO CONCURRENT is expected to do. Note also that forall-header permits a type-spec that allows one to define loop indexes inside the header and you will need to surround the whole thing in
BLOCK ... END BLOCK construct to preserve the semantics. You would also need to check if scalar-mask-expr exists at the end of the forall-header and if it does you should also put that
IF ... END IF inside the innermost loop.
If you only have array assignments inside the body of the
DO CONCURRENT you would could also transform it into
FORALL and use the
workshare OpenMP directive. It would be much easier than the above.
DO CONCURRENT <forall-header>
!$omp parallel workshare
!$omp end parallel workshare
Given all the above, the only systematic way that I can think about is to systematically go through your source code, searching for
DO CONCURRENT and systematically replacing it with one of the above transformed constructs based on the content of the forall-header and the loop body.
Edit: Usage of OpenMP
workshare directive is currently discouraged. It turns out that at least Intel Fortran Compiler and GCC serialise
FORALL statements and constructs inside OpenMP
workshare directives by surrounding them with OpenMP
single directive during compilation which brings no speedup whatsoever. Other compilers might implement it differently but it's better to avoid its usage if portable performance is to be achieved.