In C programming language we are not allowed to use address-of operator(&) with variables which are declared with register storage class specifier.

It gives error: address of register variable ‘var_name’ requested

But if we make a c++ program and perform the same task (i.e use the & with register storage variable) it doesn't gives us any error.


#include <iostream>
using namespace std;
int main()
    register int a;
    int * ptr;
    a = 5;
    ptr = &a;
    cout << ptr << endl;
    return 0;

Output :-


Well this must be an extra feature of C++, but the question is on the difference between register class storage in C and C++.

  • 5
    register is a hint in C++, so compiler is authorized to ignore it. If you take its address then compiler ignore it. Commented Dec 6, 2015 at 14:42
  • 3
    @Jean-BaptisteYunès It's a hint in C too. Commented Dec 6, 2015 at 14:44
  • 2
    probably no modern compiler support register keyword anyway
    – David Haim
    Commented Dec 6, 2015 at 14:46
  • You are not making a reference to a register variable; you are making a pointer to a register variable. On many platforms, registers do not belong to the addressing space and thus don't have addresses, in other words, you can't point to a register. When making a pointer to a register variable, compilers may put the variable onto the stack or assign the variable to a temporary memory location, so that a pointer can be created. Commented Dec 6, 2015 at 20:08

3 Answers 3


The restriction on taking the address was deliberately removed in C++ - there was no benefit to it, and it made the language more complicated. (E.g. what would happen if you bound a reference to a register variable?)

The register keyword hasn't been much use for many years - compilers are very good at figuring out what to put in registers by themselves. Indeed in C++ the keyword is currently deprecated and will eventually be removed.

  • 1
    It's not just deprecated, it has no effect. Commented Dec 6, 2015 at 15:21
  • 1
    @sqykly But you can take the address of an inline function in C++. All it means is that there must be at least one out of line definition, even if all call sites are inlined. Similarly taking the address of a register variable doesn't necessarily prevent the compiler putting it in register, as long as the required semantics are preserved. Commented Dec 6, 2015 at 15:39
  • 3
    @alanstokes registers do not have addresses. In order to get an address, the compiler needs to put it in memory somewhere. In order to make that mean anything, it also has to update that value in memory at any point the receiver of said address can access it and read it back afterwards. This sounds a lot like just ignoring the hint, no?
    – sqykly
    Commented Dec 6, 2015 at 15:46
  • 3
    I shall play devil's advocate: some implementations - embedded ones, mostly- have register as an actual command, not just a hint. This is because you often need to have control over registers; programmers know what they're doing. I asked a question whether that was allowed and I'll shamelessly give a link to it.
    – edmz
    Commented Dec 6, 2015 at 19:15
  • 2
    The register keyword in C states that you can't take the address of the variable, which in turn implies that the variable will not be aliased by any pointer. This may allow the compiler to perform optimizations that it would not otherwise be able to do, even if it doesn't put the variable in a register. (Yes, modern compilers are very smart, but providing them with more information allows them to be even smarter. The programmer does have information they lack.) Of course, if C++ does allow you to take the address of the variable, then register is less useful in that language.
    – Ray
    Commented Dec 7, 2015 at 0:53

The register storage class originally hinted to the compiler that the variable so qualified was to be used so frequently that keeping its value in memory would be a performance drawback. The vast majority of CPU architectures (maybe not SPARC? Not even certain there's a counterexample) cannot perform any operation between two variables without first loading one or both from memory into its registers. Loading variables from memory into registers and writing them back to memory once operated upon takes many times more CPU cycles than the operations themselves. Thus, if a variable is used frequently, one can achieve a performance gain by setting aside a register for it and not bothering with memory at all.

Doing so, however, has a variety of requirements. Many are different for every CPU architecture:

  • All processors have a fixed number of registers, but each processor model has a different number. In the 80s you might have had 4 that could reasonably be used for a register variable.
  • Most processors do not support the use of every register for every instruction. In the 80s it was not uncommon to have only one register that you could use for addition and subtraction, and you probably couldn't use that same register as a pointer.
  • Calling conventions dictated differing sets of registers that could be expected to be overwritten by subroutines i.e. function calls.
  • The size of a register differs between processors, so there are cases where a register variable will not fit in a register.

Because C is intended to be independent of platform, these restrictions could not be enforced by the standard. In other words, while it may be impossible to compile a procedure with 20 register variables for a system that only had 4 machine registers, the C program itself should not be "wrong", as there is no logical reason a machine cannot have 20 registers. Thus, the register storage class was always just a hint that the compiler could ignore if the specific target platform would not support it.

The inability to reference a register is different. A register is specifically not kept updated in memory and not kept current if changes are made to memory; that's the whole point of the storage class. Since they are not intended to have a guaranteed representation in memory, they cannot logically have an address in memory that will be meaningful to external code that may obtain the pointer. Registers have no address to their own CPU, and they almost never have an address accessible to any coprocessor. Therefore, any attempt to obtain a reference to a register is always a mistake. The C standard could comfortably enforce this rule.

As computing evolved, however, some trends developed that weakened the purpose of the register storage class itself:

  • Processors came with greater numbers of registers. Today you probably have at least 16, and they can probably all be used interchangeably for most purposes.
  • Multi-core processors and distributed code execution has become very common; only one core has access to any one register and they never share without involving memory anyway.
  • Algorithms for allocating registers to variables became very effective.

Indeed, compilers are now so good at allocating variables to registers that they will usually do a better job at optimization than any human. They certainly know which ones you are using most frequently without you telling them. It would be more complicated for the compiler (i.e. not for the standard or for the programmer) to produce these optimizations if they were required to honor your manual register hints. It became increasingly common for compilers to categorically ignore them. By the time C++ existed, it was obsolete. It is included in the standard for backward compatibility, to keep C++ as close as possible to a proper superset of C. The requirements of a compiler to honor the hint and thus the requirements to enforce the conditions under which the hint could be honored were weakened accordingly. Today, the storage class itself is deprecated.

Therefore, even though it is still the case today (and will be until computers don't even have registers) that you cannot logically have a reference to a CPU register, the expectation that the register storage class will be honored is so long gone that it is unreasonable for the standard to require compilers to require you to be logical in your use of it.

  • 5
    Nit: I think you mean C++ is a superset of C (which technically it isn't, although a lot of work has gone into minimising incompatibilities) Commented Dec 6, 2015 at 19:10
  • 1
    x86 processors can do string operations on two memory operands: see CMPS and MOVS instructions (opcodes 0xA4 through 0xA7).
    – Ruslan
    Commented Dec 6, 2015 at 19:44
  • @ruslan movs and cmps are rarely used by compilers now, but they do involve multiple registers: ds, es, ecx/rcx, esi/rsi, and edi/rdi. cmps involves eflags as well. Typically *cx, *di and *si are going to need to be loaded from memory before and sometimes after use. I guess the immediate-to-memory address mode is actually a good counterexample, though. Will fix. 65x has block move instructions like movs too, memory to memory with 3 implicit registers.
    – sqykly
    Commented Dec 6, 2015 at 23:48
  • @ruslan scratch imm to mem; that's not an operation between two variables as stated.
    – sqykly
    Commented Dec 6, 2015 at 23:58
  • @sqykly I wouldn't say it's rarely used. When you do a memcpy(), gcc uses movsd on my 32-bit system, and it's not a call to libc, it's inlined.
    – Ruslan
    Commented Dec 7, 2015 at 6:07

A referenced register would be the register itself. If the calling function passed ESI as a referenced parameter, then the called function would use ESI as the parameter. As pointed out by Alan Stokes, the issue is if another function also calls the same function, but this time with EDI as the same referenced parameter.

In order for this to work, two overloaded like instances of the called function would need to be created, one taking ESI as a parameter, one taking EDI as a parameter. I don't know if any actual C++ compiler actually implements such an optimization in general, but that is how this could be done.

One example of register by reference is the way std::swap() gets optimized (both parameters are references), which often ends up as inlined code. Sometimes no swap takes place: for example, std::swap(a, b), no swap takes place, instead the sense of a and b is swapped in the code that follows (references to what was a become references to b and vice versa).

Otherwise, a reference parameter will force the variable to be located in memory instead of a register.

  • How would that work if a different calling function was using EDI? Or are you thinking of inlined calls? Commented Dec 6, 2015 at 19:12

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