18

If there is for example a class that requires a pointer and a bool. For simplicity an int pointer will be used in examples, but the pointer type is irrelevant as long as it points to something whose size() is more than 1 .

Defining the class with { bool , int *} data members will result in the class having a size that is double the size of the pointer and a lot of wasted space

If the pointer does not point to a char (or other data of size(1)), then presumably the low bit will always be zero. The class could defined with {int *} or for convenience: union { int *, uintptr_t }

The bool is implemented by setting/clearing the low bit of the pointer as per the logical bool value and clearing the bit when you need to use the pointer.

The defined way:

struct myData
{
 int * ptr;
 bool flag;
};
myData x;

// initialize
x.ptr = new int;
x.flag = false;

// set flag true
x.flag = true;

// set flag false
x.flag = false;

// use ptr
*(x.ptr)=7;

// change ptr
x = y;                // y is another int *

And the proposed way:

union tiny
{
 int * ptr;
 uintptr_t flag;
};
tiny x;

// initialize
x.ptr = new int;

// set flag true
x.flag |= 1;

// set flag false
x.flag &= ~1;

// use ptr
tiny clean=x;      // note that clean will likely be optimized out
clean.flag &= ~1;  // back to original value as assigned to ptr
*(clean.ptr)=7;

// change ptr
bool flag=x.flag;
x.ptr = y;             // y is another int *
x.flag |= flag;

This seems to be undefined behavior, but how portable is this?

  • 1
    The slow down would from changing the bit back and forth is probably more trouble than its worth, have you checked to make sure it actually runs faster – aaronman Nov 15 '13 at 0:54
  • 1
    @aaronman - it is significantly faster, hence the question – Glenn Teitelbaum Nov 15 '13 at 0:57
  • what's your mean of Defining the class as a bool? – DarkHorse Nov 15 '13 at 0:58
  • @DarkHorse it read as a bool and a pointer - clarifications in last edit should help – Glenn Teitelbaum Nov 15 '13 at 1:05
11

As long as you restore the pointer's low-order bit before trying to use it as a pointer, it's likely to be "reasonably" portable, as long as your system, your C++ implementation, and your code meet certain assumptions.

I can't necessarily give you a complete list of assumptions, but off the top of my head:

  • It assumes you're not pointing to anything whose size is 1 byte. This excludes char, unsigned char, signed char, int8_t, and uint8_t. (And that assumes CHAR_BIT == 8; on exotic systems with, say, 16-bit or 32-bit bytes, other types might be excluded.)
  • It assumes objects whose size is at least 2 bytes are always aligned at an even address. Note that x86 doesn't require this; you can access a 4-byte int at an odd address, but it will be slightly slower. But compilers typically arrange for objects to be stored at even addresses. Other architectures may have different requirements.
  • It assumes a pointer to an even address has its low-order bit set to 0.

For that last assumption, I actually have a concrete counterexample. On Cray vector systems (J90, T90, and SV1 are the ones I've used myself) a machine address points to a 64-bit word, but the C compiler under Unicos sets CHAR_BIT == 8. Byte pointers are implemented in software, with the 3-bit byte offset within a word stored in the otherwise unused high-order 3 bits of the 64-bit pointer. So a pointer to an 8-byte aligned object could have easily its low-order bit set to 1.

There have been Lisp implementations (example) that use the low-order 2 bits of pointers to store a type tag. I vaguely recall this causing serious problems during porting.

Bottom line: You can probably get away with it for most systems. Future architectures are largely unpredictable, and I can easily imagine your scheme breaking on the next Big New Thing.

Some things to consider:

Can you store the boolean values in a bit vector outside your class? (Maintaining the association between your pointer and the corresponding bit in the bit vector is left as an exercise).

Consider adding code to all pointer operations that fails with an error message if it ever sees a pointer with its low-order bit set to 1. Use #ifdef to remove the checking code in your production version. If you start running into problems on some platform, build a version of your code with the checks enabled and see what happens.

I suspect that, as your application grows (they seldom shrink), you'll want to store more than just a bool along with your pointer. If that happens, the space issue goes away, because you're already using that extra space anyway.

  • If the structure or union contains any type requiring an alignment more stringent than byte alignment, then the structure as a whole will be aligned on a suitable address. You could only run into problems if every member of the structure is a char type of some sort; such a structure does not need to be aligned specially. – Jonathan Leffler Nov 15 '13 at 2:21
  • 1
    @JonathanLeffler: Yes if there are any such types. There very probably are, but it's entirely possible for a 2-byte or 4-byte type to require only 1-byte alignment. Not common these days, but permitted by the language. – Keith Thompson Nov 15 '13 at 2:22
  • If you're going to downvote, it would be nice to explain what you think is wrong with the answer. – Keith Thompson Nov 15 '13 at 21:38
  • That Lisp example was useful; I was thinking of using the LSB of a pointer to store if a cons cell was allocated from a memory pool for a Lisp implementation. Might not be as portable as I first thought. Should not work on Cray (as you said) nor on AVR/Arduino systems. – paulotorrens Jun 20 '15 at 20:28
4

In "theory": it's undefined behavior as far as I know.

In "reality": it'll work on everyday x86/x64 machines, and probably ARM too?
I can't really make a statement beyond that.

  • bit operations that change the pointer value and then restore them seem to be standard. Whether non narrow character types have an align > 1 seems to be where it gets into implementation specific – Glenn Teitelbaum Nov 15 '13 at 1:31
  • @GlennTeitelbaum Yep, alignment is implementation specific, that's the "theory" part of the answer. Practically though, most compilers align pointers for performance reasons. Even if a CPU architecture doesn't allow for unaligned accesses, there's nothing stopping the compiler from generating/using pointer values that are unaligned. eg. See gcc's --munaligned-access. – Austin Phillips Nov 15 '13 at 1:40
  • @GlennTeitelbaum: The trouble isn't just the alignment, it's the fact that the language doesn't allow you to treat pointers as integers. So if you do that, it's technically undefined behavior as far as "standard C++" is concerned --- so unless your compiler makes extra guarantees (which it might), the code isn't standard C++ and therefore isn't guaranteed to behave correctly. – user541686 Nov 15 '13 at 2:22
  • In theory, you have to go through some fairly convoluted set of casts (uintptr_t is one of them) to convert the pointer to a manipulable integer, and then do the bit flipping or testing, and the conversions back again. I'm surprised it is quicker than doing the job the regular way, though not completely since half as much data means you get better cache locality. – Jonathan Leffler Nov 15 '13 at 2:25
  • @Mehrdad - it seems that as long as you take a pointer - convert it tto an integral type of at least the size of the pointer - do something - undo it - and then convert it back to pointer - its okay: the result of an additive or **bitwise** operation, one of whose operands is an integer representation of a safely-derived pointer value P, if that result converted by reinterpret_cast<void*> would compare equal to a safely-derived pointer computable from reinterpret_cast<void*>(P). – Glenn Teitelbaum Nov 15 '13 at 2:25
2

It's very portable, and furthermore, you can assert when you accept the raw pointer to make sure it meets the alignment requirement. This will insure against the unfathomable future compiler that somehow messes you up.

Only reasons not to do it are the readability cost and general maintenance associated with "hacky" stuff like that. I'd shy away from it unless there's a clear gain to be made. But it is sometimes totally worth it.

0

Conform to those rules and it should be very portable.

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