I doubt you can achieve what you want nicely in C (unless you want to change the compiler).
You say you want an OpenMP style of programming. That is tantamount to a single top level thread, that can fork children to operate on shared space provided by the parent. Fancy OpenMP does this recursively.
To do this nicely, you system/tools/compiler need to be able to identify
* threads of computations
* what variables are declared by each thread
* what variables (or parts thereof) are offered by a thread to its thread children
If you can do these things (and it is easier with explicit language support, OpenMP enabled compilers are aided in this process by the OpenMP pragmas), then you can partition a thread's data into 3 parts:
1. storage accessed only by the thread, and not by its children
2. storage declared by the thread, but accessed only by individual children (e.g., slices of arrays)
3. storage read and written by the parent thread and its children
At this point, you can consider layout out "local variables" for a thread, and thus to stack space.
Thread-local storage is allocated only to the parent thread's stack space. Parent-declared but child-processed storage becomes space allocated to the child's local space/stacks. Storage read and written by all, can be placed anywhere it can be accessed (in the parent thread's local space, in his stack, in heap store) and will need access protection to prevent data races. [You can't coerce traditional C compilers to do this for you.]
This partitioning of the data to different thread local/stack spaces makes your apparent scheme of using C and setting "all threads stacks" to one place in shared memory difficult to harness. If all threads have the same stack area, which storage is local to a thread? In particular, if two threads each want to write to their own local variable I, and I is in the shared space, then it isn't really local. If you partition the shared space into disjoint thread stacks, then you don't really have sharing of storage, at least not by name; at best you can share using pointers into other threads stacks. All this will be difficult to program, therefore error prone and I wouldn't want to have to debug programs written for such a system. It also places additional demand on your precious shared space; you have thread-local variables eating it up, but not needing sharing.
If you have a static number of threads, and continue to insist on using some available C compiler, you might be better off to hand-allocate the shared data (either dynamically at runtime, or at coding/compile-time by partitioning the shared memory). But your threads can now run with their "standard" stack in their local memories and no stack switching is needed.
[EDIT: After my comment on cactus stacks, OP wanted to know more. I' m including
the comment here, and some pointers to details about them]
A stack can be shared by multiple threads. The notion of a cactus stack is one in which a parent thread, having an existing (cactus) stack, shares that with all of its parallel children, who each get stack space of their own but can see/share the parent's stack.
Our PARLANSE parallel programming language implements this concept directly, and we use it in application programs that are some 2-4 million lines of code. Each function call heap-allocates
its activation records (using a thread local allocator for speed), and has access to all parent stack segments by lexical-level up addressing, implemented as a box of pointers passed by a parent to its child on a function call. The Intel blog below describes exactly the reasons we did this.