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How can we manipulate the 32 bits high order and 32 bits low order of u64 type in Linux kernel. I tried this one, but the compiler reported a lot of warnings.

#define HI_BYTES(_a) (_a & 0xffffffff00000000)
#define LO_BYTES(_a) (_a & 0x00000000ffffffff)
/* _v is 32 bit value */
#define HI_BYTES_SET(_a, _v) do {_a = (_a & 0x00000000ffffffff) | (_v << 32)} while (0)
#define LO_BYTES_SET(_a, _v) do {_a = (_a & 0xffffffff00000000) | (_v)} while (0)

Any suggestions are appreciated. Thank a lot!

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What do the warnings say? –  Robin Green Apr 19 '11 at 8:31
u64? Perhaps you mean uint64_t? And do you really need to mess with macros instead of sticking in a small inline function and letting the compiler do its job? –  Nicholas Knight Apr 19 '11 at 8:33
it complained about the shift amount and the constant value 0xffffffff00000000 is too big. Thank everyone for taking time to answer –  dien Apr 19 '11 at 14:52

2 Answers 2

up vote 5 down vote accepted

I suspect, for a start, that you're going to need qualifiers on those big honkin' hex numbers, something along the lines of:


Unadorned integer constants are of the int type and that's probably not enough to hold the given values.

Other than that, you should post the warnings you're getting so we don't have to play the Psychic Debugging game :-)

And one other thing that may be problematic is v << 32 for a 32-bit v. I'd probably opt for something like:

#define HI_BYTES(_a) (_a & 0xffffffff00000000ULL)
#define LO_BYTES(_a) (_a & 0x00000000ffffffffULL)
#define HI_BYTES_SET(_a, _v)\
    do {\
        u64 _xyzzy = _v;\
        _a = (_xyzzy << 32) | LO_BYTES(_a)\
    } while (0)
#define LO_BYTES_SET(_a, _v)\
    do {\
        u64 _xyzzy = _v;\
        _a = HI_BYTES(_a) | (_xyzzy)\
    } while (0)

This would make sure that everything is of the correct type before doing any bit shifting. Keep in mind that's untested, you'll have to confirm the correct behaviour.

But, of course, I missed the most obvious solution as put forward by Nicholas Knight in a comment. Get rid of the macros altogether. This is something far better handled by functions (marked inline if you wish but I rarely find this necessary since gcc optimises things insanely well anyway).

This way, the compiler can coerce data types and you don't run into the problems you invariably do with macros like #define SQR(x) ((x)*(x)) and i = SQR(j++).

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As already said by others, the correct typedef is uint64_t. Constants of that type can be obtained by the predefined macro UINT64_C, e.g UINT64_C(1) will probably result in 1ULL. But actually I don't think you need these.

If you really have a variable of that type (i.e with fixed width 64 and unsigned) shifting twice with 32 bit should always give the correct result. To only have the high order bits

((a >> 32) << 32)

The compiler will optimize this to the perfect assembler for your platform. (For gcc, compile with -march=native and check the assembler with -S.)

To be sure that this is really an uint64_t best is really as others said to have a function. This then converts to the right type(s), and you don't have to worry.

Such a small function definition belongs in a header file, so you must either declare it inline (or static if you must), otherwise you will encounter "multiply defined symbol" errors at link time.

To also have a symbol declared of your function somewhere, you'd have to put an extern inline declaration (not definition) in exactly one compilation unit.

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Thank Jens Gustedt a lot :D –  dien Apr 19 '11 at 14:51
u64 is actually a valid type for the Linux kernel - not all compilers may provide a uint64_t type. –  paxdiablo Apr 20 '11 at 3:19

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