With constant time code, typically code that may branch (and incur run-time time differences), like
return !r; is avoided.
Note that a well optimized compiler may emit the exact same code for
return 1 & ((r - 1) >> 8); as
return !r;. This exercise is therefore, at best, code to coax the compiler input emitting constant time code.
What about uncommon platforms?
return 1 & ((r - 1) >> 8); is well explained by @Some programmer dude good answer when
int is 8-bit 2's complement - something that is very common.
unsigned char, and
r > 0,
r-1 is non-negative and
1 & ((r - 1) >> 8) returns 0 even if
int is 2's complement, 1's complement or sign-magnitude, 16-bit, 32-bit etc.
r == 0,
r-1 is -1. It is implementation define behavior what
1 & ((r - 1) >> 8) returns. It returns 1 with
int as 2's complement or 1's complement, but 0 with sign-magnitude.
// fails with sign-magnitude (rare)
// fails when byte width > 8 (uncommon)
return 1 & ((r - 1) >> 8);
Small changes can fix to work as desired in more cases1. Also see @Eric Postpischil
r - 1 is done using
int encoding is irrelevant.
// v--- add u v--- shift by byte width
return 1 & ((r - 1u) >> CHAR_BIT);
1 Somewhat rare: When
unsigned char size is the same as
unsigned, OP's code and this fix fail. If wider math integer was available, code could use that: e.g.:
return 1 & ((r - 1LLU) >> CHAR_BIT);