My company does not want to migrate from FORTRAN 77. Senior guys are not interested in newer versions.
The use of allocate and deallocate are forbidden, since they are worried about memory leaks.
The program allocates a large chunk of memory (lets call it mem_pool), which is used everywhere instead of dynamic memory allocation.
The current implementation follows something like this:
subroutine my_func(args, mem_pool, size_pool) double precision mem_pool integer size_pool integer free_index, p_a, p_b, size_a, size_b, ... ! Declare args ... free_index = 1 size_a = 10 ! I somehow determined I want *20* integers (size of 10 doubles) size_b = 14 ! I somehow determined I want 14 doubles p_a = free_index free_index = free_index + size_a p_b = free_index free_index = free_index + size_b if (free_index .gt. size_pool) then ! error endif ! make second element in array "a" equal to 3 call assign_int_array_element( mem_pool(p_a), 2, 3) ! make third element in array "b" equal to 3.14159 call assign_dbl_array_element( mem_pool(p_b), 3, 3.14159) size_remaining = size_pool - free_index + 1 call some_func( mem_pool(p_a), mem_pool(free_index), size_remaining) call other_func(mem_pool(p_b), mem_pool(free_index), size_remaining) return end
where mem_pool is some large chunk of double precision memory of size size_pool. mem_pool is an argument in some_func and other_func in case you want to use some memory in those subroutines. size_remaining will become size_pool in those routines.
I feel like there are several undesirable consequences to this. You must have the discipline to check that free_index is greater than size_pool. If the data p_a points to is of integer type, the values of size_a should take into account conversions of double precision data size to integer data size. You can't do operations like:
mem_pool(p_a + 2) = 3
because the current subroutine will assume the data is double precision type rather than integer type (hence the need for assign_int_array_element and assign_dbl_array_element). You have to carry around the memory pool and its maximum available size in every subroutine. Different programmers change variable names, use alternatives such as free_index = 0 and p_a = free_index + 1, etc, etc.
I'm envisioning something like looks like C/C++ alloca, but uses a heap memory pool. It should simply take the type of data you want, the size, and the allocated arrays should "go out of scope" (the changes to free_index are forgotten) at the end of the subroutine. It should automatically check the memory pool size is respected and let me work directly with the arrays without calling new subroutines.
I want to be able to write something like (this code is not correct, just an example of how I want it to work):
subroutine my_func(args) integer a(*) double precision b(*) ... ! Declare args ... call alloca_fortran(a, 20, TYPE_INT) ! Allocate 20 integers for a call alloca_fortran(b, 14, TYPE_DBL) ! Allocate 14 doubles for b a(2) = 3 b(3) = 3.14159 call some_func(a) call other_func(b) return end
where the internals of alloca_fortran do all the memory pool management and checking. I guess my real question is - Is there any way I can improve our approach such that it is more convenient to modify and removes the need for programmers to act like operating systems when it comes to our memory management? I want to ask for memory, and then be able to use it without screwing around with the internals, and manipulate arrays directly in that routine.
Not having pointers in FORTRAN 77 makes me feel like this is impossible. Is there any way the subroutines can look like FORTRAN 77, but the internals of alloca_fortran use a newer version to get a and b to point to the correct memory in the memory pool?
I realize this question is pretty vague, and I realize I may just have to carry around mem_pool, free_index, and size_pool. I also realize that I may be asking for something that is impossible to do. I just wanted to know if anyone has any idea how to make this as clean as it can be.