In masked form for any platform (32bit, 64bit... future as long as PHP_INT_MAX
is defined) which would perhaps offer a performance benefit (no branching):
function uintRShift($uint,$shift)
{
//if ($shift===0) return $uint;
//PHP_INT_MAX on 32 =7FFFFFFF, or zero & 32 ones
$mask=PHP_INT_MAX>>($shift-1);
return $uint>>$shift&$mask;
}
The mask setup puts all zeros for the left-most $shift
bits of $uint
. Note: Uncomment the first line if you want to be able to/tolerant of zero shifting a negative/large number (since the mask will modify a negative/large number even with $shift=0
).
The unit testing code to show it's working in 32 bit:
class UintRShiftTest extends PHPUnit_Framework_TestCase {
public function provide_shifts() {
return array(
/* start shift end*/
array(0, 4, 0)
,array(0xf, 4, 0)
,array(0xff, 4, 0xf)
,array(0xfffffff, 4, 0xffffff)
,array(0xffffffff, 4, 0xfffffff)
,array(-1, 4, 0xfffffff)//Same as above
,array(0, 1, 0)
,array(0xf, 1, 0x7)
,array(-1, 1, 0x7fffffff)
);
}
/**
* @dataProvider provide_shifts
*/
function test_uintRShift($start,$shift,$end) {
$this->assertEquals($end,uintRShift($start,$shift));
}
}
For what it's worth the above mentioned function:
function uintRShift_branch($uint,$shift)
{
if ($uint<0) {
return ($uint>>$shift)+(2<<~$shift);
} else {
return $uint>>$shift;
}
}
Fails automated test:
#4 Reports -1
. This can perhaps be justified by PHP reporting 0xffffffff
as a large positive number (documentation suggests large integers are automagically switched to floats, although the bit shift seems to treat it as a regular integer still)
#8 Results in -2147483649
which is actually correct (same as 0x7fffffff
) but below the minimum int value for PHP:-2147483648