In theory yes, but only really plausible for a global pinned to that register permanently.
(Assuming an ISA with memory-mapped CPU registers in the first place1, of course; typically only microcontroller ISAs are like this; it makes a high-performance implementation much harder.)
Pointers have to stay valid (keep pointing to the same object) when you pass them to functions like qsort
or printf
, or your own functions. But complicated functions will often save some registers to memory (typically the stack) to be restored at the end of the function, and inside that function will put their own values in those registers.
So that pointer to a CPU register will be pointing to something else, potentially one of the function's local variables, when that function dereferences a pointer you passed it, if you just pick a normal call-preserved register.
The only way I see around this problem would be to reserve a register for a specific C++ object program-wide. Like something similar to GNU C/C++ register char foo asm("r16");
at global scope, but with a hypothetical compiler where that doesn't prevent you from taking its address. Such a hypothetical compiler would have to be stricter than GCC about making sure the value of the global was always in that register for every memory access through a pointer, unlike what GCC documents for register-asm globals. You'd have to recompile libraries to not use that register for anything (like gcc -ffixed-r16
or let them see the definition.)
Or of course a C++ implementation is allowed to decide to do all that on its own for some C++ object (likely a global), including generating all library code to respect that whole-program register allocation.
If we're only talking about doing this over a limited scope (not for calls into unknown functions), sure it would be safe to compile int *p = &x;
to take the address of the CPU register x
was currently in, if escape analysis proved that all uses of p
were limited. I was going to say this would be useless because any such proof would give you enough info to just optimize away the indirection and compile *p
to access as a register instead of memory, but there is a use-case:
If you have two or more variables and do if (condition) p = &y;
before dereferencing p
, the compiler might know that x
would definitely still be in the same register when *p
is evaluated, but not know whether p
is pointing to x
or y
. So it would be potentially useful to keep x
or y
in registers, especially if they're also being read/written directly by other code mixed with derefs of p
.
Of course I've been assuming a "normal" ISA and a "normal" calling convention. It's possible to imagine weird and wonderful machines, and/or C++ implementations on them or normal machines, that might work very significantly differently.
What ISO C++ has to say about this: not much
The ISO C++ abstract machine only has memory, and every object has an address. (Subject to the as-if rule if the address is never used.) Loading data into registers is an implementation detail.
So yes, in a machine like AVR (8-bit RISC microcontroller) or 8051 where some CPU registers are memory-mapped, a C++ pointer could point at them1. Having memory-mapped CPU registers is a thing on some microcontrollers like AVR2. (e.g. What is the benefit of having the registers as a part of memory in AVR microcontrollers? has a diagram. (And asks the odd question of why we have registers at all, instead of just using memory addresses, if they're going to be memory mapped.)
This AVR Godbolt link doesn't really show much, mostly just playing around with a GNU C register-asm global.
Footnote 1: In normal C++ implementations for normal ISAs, a C++ pointer maps pretty directly to a machine address that can be dereferenced somehow from asm. (Perhaps very inconveniently on machines like 6502, but still).
In a machine without virtual memory, such a pointer is normally a physical address. (Assuming a normal flat memory model, not segmented.) I'm not aware of any ISAs with virtual memory and memory-mapped CPU registers, but there are lots of obscure ISAs I don't know about. If one exists, it might make sense for the register mapping to be into a fixed part of virtual address space so the address could be checked for register access in parallel with TLB lookup. Either way it would make a pipelined implementation of the ISA a huge pain because detecting hazards like RAW hazards that require bypass forwarding (or stalling) now involves checking memory accesses. Normal ISAs only need to match register numbers against each other while decoding a machine instruction. With memory allowing indirect addressing via registers, memory disambiguation / store forwarding would need to interact with detecting when an instruction reads the result of the previous register write, because that read or write could be via memory.
There are old non-pipelined CPUs with virtual memory, but pipelining is one major reason you'd never want memory-map the registers on a modern ISA with any ambitions of being used as the main CPU for a desktop / laptop / mobile device where performance is relevant. These days, it would make little sense to include the complexity of virtual memory but not pipeline the design. There are some pipelined microcontrollers / low-end CPUs without virtual memory.
Footnote 2: Memory-mapped CPU registers are basically non-existent on modern mainstream 32 and 64-bit ISAs. Do general purpose registers are generally memory mapped?
Microcontrollers with memory-mapped CPU registers often implement the register file as part of internal SRAM that they have anyway to act as regular memory.
In ARM, x86-64, MIPS, and RISC-V, and all similar ISAs, the only way to address registers is by encoding the register number into the machine code of an instruction. Register indirection would only be possible with self-modifying code, which C++ does not otherwise require and which normal implementations don't use. And besides, register numbers are a separate address-space from memory. e.g. ARM has 16 basic integer regs, so an instruction like add r0, r1, r2
will have three 4-bit fields in the encoding of that machine instruction, one for each operand. (In ARM mode, not Thumb.) Those register numbers have nothing to do with memory address 0
, 1
, or 2
.
Note that memory-mapped I/O registers are common on all modern ISAs, normally sharing physical address space with RAM. The I/O addresses are normally called registers, but the register is in the peripheral, like a network card, not in the CPU. Reading or writing it will have some side-effect, so in C++ you'd normally use a volatile int *constexpr ioport = 0x1234;
or something for MMIO. MMIO registers are definitely not one of the general-purpose integer registers you can use in an instruction like AArch64 add w0, w1, w2
.