int pcount_r (unsigned x) {
if(x==0)
return 0;
else
return ((x & 1) + pcount_r(x >> 1));
}
just wondering why the input argument is unsigned.
best regards!
It is implementation-defined what E1 >> E2
produces when E1 has a signed type and negative value (C99 6.5.7:5). On the other-hand, E1 >> E2
is unambiguously defined by the standard. Accepting and operating on an unsigned integer is a way to make the function most portable.
Incidentally, it is usual to use unsigned types for bit-twiddling.
int >> shift == crap
but unsigned >> shift == rulez
Oct 26, 2012 at 0:25
If the number is signed, then right-shifting will copy the sign-bit (the last bit), effectively giving negative numbers an infinite number of bits.
int pcount_r(int x) {
if (x == 0)
return 0;
else if (x < 0)
return sizeof(int)*8 - pcount_r(~x);
else
return (x & 1) + pcount_r(x >> 1);
}
~
("bitwise not") inverts all the bits of the number, including the sign-bit.
Oct 25, 2012 at 20:11
The problem is that C (unlike Java) does not support signed (arithmetic) shifts. CPUs have two different types of shift operators, signed and unsigned. For example, on an x86, the SAR instruction does an arithmetic shift right, and SHR does an unsigned shift right. Since, C only has one shift right operator (>>), it cannot support both of them. If the compiler implements the code above using an unsigned shift (SHR) and you supply a negative number to that procedure you will get a wrong answer.
shr
it would always be correct. The problem arises when sar
is used and the input has the signbit set, the algorithm would never terminate.
>>
into SAR or SHR is made by the compiler by applying exactly the same rules that allow it to determine whether integer or floating-point computations are intended. C99 6.3.1.8: “Many operators that expect operands of arithmetic type cause conversions and yield result types in a similar way. The purpose is to determine a common real type…”
Oct 25, 2012 at 19:51
sar
). As for the signbit adding one, well, it is on, so you have to count it, right?