D is not designed to operate at platforms where the native integer/pointer size is under 32 bits. Nonetheless, I've lately been learning AVR programming with D, and thought I'd share my experiences.
I'm not the first one to do this. Ernesto Castellotti, Adam Ruppe and others have experimented before me, but this still seems a fringe area for D.
Overall D works passably. There are shortcomings, but since you do everything yourself anyway on platforms like this, and the alternative would be C, D so far seems a viable option. I think that with relatively little modification, AVR and similar platforms could be made a first-class citizen for D (albeit without a full standard library support since they're still bare-metal platforms - LWDR on the other hand could probably work).
size_t
is defined as uint
, which is maybe technically wrong, but in practice makes dealing with array lengths much easier than it'd be otherwise. The problem is that LDC doesn't currently fully work with this scheme. As a result, array indexing does not work unless you disable bounds checking. My current solution is to define a custom indexing function instead:
pragma(inline, true)
@trusted pure ref ix(El, Idx)(El[] arr, Idx idx)
{ // I haven't yet hooked the D assert failure handler so
// using a custom replacement instead.
// Casting to ushort necessary to work around the mentioned issue.
if(idx >= cast(ushort) arr.length) assert0();
return arr.ptr[idx];
}
Another big limitation on AVR isn't due to the bit width, but it's Harvard architechture. LLVM considers pointers to program memory a different type from data pointers, but LDC declares function pointers as data pointers, resulting in LLVM type error trying to compile their usage code. One would have to define some sort of custom function pointer type, implementing it's invocation in assembly or LLVM IR.
The good news for D?
First off, when something doesn't work, you can usually hack together something custom, and put it behind a reasonably usable API. Even portable D code offers a far better arsenal of tricks than most languages, as that custom indexing function shows (returns by ref, works with any type, gets inlined, can be done in the first place despite requiring potentially type system breaking system code). When that isn't enough, LLVM intrinsics, inline IR and assembly let one to implement almost anything. For example, need a special target-specific return statement for an interrupt handler?
// Timer/Counter1 compare match A interrupt
extern(C) @trusted void __vector_11()
{ /* ...
Normal D code here - no need to implement
the whole handler in assembly!
...
*/
// Return while enabling interrupts
__asm("reti", "");
// Prevent emitting a reduntant regular return instruction.
// (Yes this works! I checked the object assembly!)
// OTOH risking UB to save one word of program memory isn't a good tradeoff
// even on atmega328p so in my own code I'm using assert0() instead.
assume0();
}
// I'm not going to use the definition in ldc.llvmasm
// because it's defined as @trusted, which doesn't fit at all.
pragma(LDC_inline_ir) R llvmIR(string s, R, P...)(P) pure nothrow @nogc;
// Calling this function is always undefined behaviour.
alias assume0 = llvmIR!("unreachable", noreturn);
I could improve this even further by hiding reti
inside an inlined noreturn
D function, or failing that, a mixin.
Second, even on a bare-metal microcontroller with no preimplemented memory allocator, all business logic can be @safe pure
. As with application code, only low-level type manipulation, I/O and memory / global variable management need to be impure and/or @system
/@trusted
. Since there's no garbage collector, some algorithms need to be written differently. A simple approach is to give the needed working memory to a function as an array argument. Otherwise, it's not that different from your regular desktop application.
Third, you have the tools to make the object code as compact as you want. For some reason, the linker doesn't recognise unused functions by default, even with -L--gc-sections
and --fvisibility=hidden
. I spent a long time fighting the linker, once finally finding out that --function-sections
flag for the compiler is needed. From there, it was smooth sailing. My build (and disassembly) script:
ldc2 -betterC -O1 --function-sections -mtriple=avr -mcpu=atmega328p --gcc=avr-gcc --Xcc=-mmcu=atmega328p -L--gc-sections delay.d
avr-objdump -x -D delay >delay.s
avr-objcopy -O ihex delay delay.hex
Note that I don't use -Oz
. For some reason that tries to link to GCC-defined function that isn't in my GCC library (maybe I have a GCC version mismatch). But I find -O1 emits almost as compact code anyway, while being clearer to read in disassembly. -Os
actually emits a bigger binary than O1
. With this one can define all sorts of inlined or CTFE functions for convenience, with no effect on the final binary size.
Just thought to share my experiences, in case someone is interested in D on 8-bit. Note that I've been using LDC all along. I'm pretty sure GDC can also be used for AVR, but I don't know how the experience would compare. For LDC, I think the experience is better than expected considering it's an environment D isn't designed for. Solving a few worst codegen bugs might make it about as good there as on any bare-metal platform. As always though, LDC is a volunteer project so I'm not saying that anyone should tackle them.
Maybe I'll publish my avr code at some point, but not promising.