Could someone help explain what this C one liner does?

I can usually figure out most C code but this one is over my head.

``````#define kroundup32(x) (--(x), (x)|=(x)>>1, (x)|=(x)>>2, (x)|=(x)>>4, (x)|=(x)>>8, (x)|=(x)>>16, ++(x))
``````

an example usage would be something like:

``````int x = 57;
kroundup32(x);
//x is now 64
``````

A few other examples are:

1 to 1
2 to 2
7 to 8
31 to 32
60 to 64
3000 to 4096

I know it's rounding an integer to it's nearest power of 2, but that's about as far as my knowledge goes.

Any explanations would be greatly appreciated.

Thanks

-

``````(--(x), (x)|=(x)>>1, (x)|=(x)>>2, (x)|=(x)>>4, (x)|=(x)>>8, (x)|=(x)>>16, ++(x))
``````
1. Decrease x by 1
2. OR x with (x / 2).
3. OR x with (x / 4).
4. OR x with (x / 16).
5. OR x with (x / 256).
6. OR x with (x / 65536).
7. Increase x by 1.

For a 32-bit unsigned integer, this should move a value up to the closest power of 2 that is equal or greater. The OR sections set all the lower bits below the highest bit, so it ends up as a power of 2 minus one, then you add one back to it. It looks like it's somewhat optimized and therefore not very readable; doing it by bitwise operations and bit shifting alone, and as a macro (so no function call overhead).

-
Great, I understand what it's doing now. Thank you! – GWW Aug 2 '10 at 3:50
+1 for one who encoded(optimized) it & +1 for @thomasrutter for decoding it :) – Kedar Aug 2 '10 at 6:07
Um, wouldn't this actually only work for 16 bits? – Nathan Ernst Aug 2 '10 at 7:50
No, it shifts the highest bit by 1 + 2 + 4 + 8 + 16 = 31 bits. – starblue Aug 2 '10 at 11:08
Here's an alternative explanation: It works by copying the highest set bit to all of the lower bits, and then adding one, which results in carries that set all of the lower bits to 0 and one bit beyond the highest set bit to 1. If the original number was a power of 2, then the decrement will reduce it to one less, so that we round up to the same original value. Source – mre Jan 30 '13 at 16:53

The bitwise or and shift operations essentially set every bit between the highest set bit and bit zero. This will produce a number of the form `2^n - 1`. The final increment adds one to get a number of the form `2^n`. The initial decrement ensures that you don't round numbers which are already powers of two up to the next power, so that e.g. 2048 doesn't become 4096.

-

At my machine `kroundup32` gives 6.000m rounds/sec
And next function gives 7.693m rounds/sec

``````inline int scan_msb(int x)
{
#if defined(__i386__) || defined(__x86_64__)
int y;
__asm__("bsr %1, %0"
: "=r" (y)
: "r" (x)
: "flags"); /* ZF */
return y;
#else
#error "Implement me for your platform"
#endif
}

inline int roundup32(int x)
{
if (x == 0) return x;
else {
const int bit = scan_msb(x);
const int mask = ~((~0) << bit);
if (x & mask) return (1 << (bit+1));
else return (1 << bit);
}
}
``````

So @thomasrutter I woudn't say that it is "highly optimized".

And appropriate (only meaningful part) assembly (for GCC 4.4.4):

``````kroundup32:
subl    \$1, %edi
movl    %edi, %eax
sarl    %eax
orl %edi, %eax
movl    %eax, %edx
sarl    \$2, %edx
orl %eax, %edx
movl    %edx, %eax
sarl    \$4, %eax
orl %edx, %eax
movl    %eax, %edx
sarl    \$8, %edx
orl %eax, %edx
movl    %edx, %eax
sarl    \$16, %eax
orl %edx, %eax
ret

roundup32:
testl   %edi, %edi
movl    %edi, %eax
je  .L6
movl    \$-1, %edx
bsr %edi, %ecx
sall    %cl, %edx
notl    %edx
testl   %edi, %edx
jne .L10
movl    \$1, %eax
sall    %cl, %eax
.L6:
rep
ret
.L10:
By some reason I haven't found appropriate implementation of `scan_msb` (like `#define scan_msb(x) if (__builtin_constant_p (x)) ...`) within standart headers of GCC (only `__TBB_machine_lg`/`__TBB_Log2`).