On Sunday, 30 May 2021 at 17:31:37 UTC, Dukc wrote:
> On Sunday, 30 May 2021 at 14:28:25 UTC, Dylan Graham wrote:
> Hi, all!
This is LWDR (Light Weight D Runtime) It is a ground-up implementation of a D runtime targeting the ARM Cortex-M microcontrollers and other microcontroller platforms with RTOSes (Real Time Operating Systems).
Sounds very useful! However, first thing first: What's the license? DUB package says it's FOSS. Great, but what kind of FOSS? It makes a big difference whether it's GNU or BSD, for instance.
I haven't put any thought into the license. Since LWDR is derived from DRuntime, I assume I'll have to use its license. If not, I'd like to go with something permissive like MIT.
> > It doesn't, and possibly may not, support all D features in order to make it viable for the constrained environments. For example, all memory allocation is manually done via new
and delete
- no GC.
Regarding new
- is there a good way to iterate though chunks allocated with new
? One could call an unmodified piece of D code that normally uses the GC, and then manually free all it's allocations.
Bingo. I was thinking of thread-local tracking of allocations. Something like follows:
Impl:
size_t numAllocations = 0;
List!(void*) allocations;
void* allocateMemoryForNew(int size)
{
numAllocations++;
auto ptr = rtosbackend_heapalloc(size);
allocations.add(ptr);
return allocations;
}
void deallocateMemory(void* ptr)
{
allocations.removeLastOccurenceOf(ptr);
numAllocations--;
rtosbackend_heapfreealloc(ptr);
}
struct MemAlloc
{
size_t allocs;
void free() {
// allocs should be less than numAllocations,
// so delete the last n items of allocations
auto difference = numAllocations - allocs;
foreach(i; 0 .. difference) {
auto ptr = allocations[allocations.length - i]; // get ith to last
deallocateMemory(ptr);
}
}
}
MemAlloc enterTrackedMemory()
{
return MemAlloc(.numAllocations);
}
Usage:
auto mem0 = enterTrackedMemory(); // mem0 says that there should be 0 allocations
A a = new A(); // 1 allocation
{
auto mem1 = enterTrackedMemory(); // mem1 says that there should be 1 allocations total
auto b = new A(); // 1 allocation, so total is now 2
mem1.free; // we need to get back to 1 allocation, so delete b (most recent allocation)
}
mem0.free; // delete everything
This works with scope(...)
.
There's some caveats with this - if a phobos function calls a user function, anything that user function allocates will be wiped, too (may or may not be desirable behaviour), unless some protocol for opting out of tracking is implemented.
> > It works by providing a series of barebones API hooks (alloc, dealloc, assert, etc) (defined in rtoslink.d
), which you must implement and/or point to your RTOS implementation.
Quickly looking, the implementation looks very portable, save for exceptions. with rtoslink.d
, this will probably enable a lot of stuff on any platform without DRuntime. Not just microcontrollers. If I'm right, you just did a BIG service for D on bare-metal.
Exceptions are a nightmare. It works for GDC with GCC code. My codebase uses GCC for its C (ST toolchain), so I need to write some code that can take LDC's exception handling and make it compatible with how GCC operates. So, it looks like there will be multiple exception handling implementations (LDC with GCC backend, LDC with clang backend, GDC with GCC backend). I wish D had something like Zig's error handling.
Otherwise, thank you! It was designed to be agnostic as much as possible. I didn't know it'd help out for more than just microcontrollers :)