I have a question.
uint64_t var = 1; // this is 000000...00001 right?
And in my code this works:
var ^ (1 << 43)
But how does it know 1 should be in 64 bits? Shouldn’t I write this instead?
var ^ ( (uint64_t) 1 << 43 )
As you supposed, 1 is a plain signed
int (which probably on your platform is 32 bit wide in 2's complement arithmetic), and so is 43, so by any chance
1<<43 results in an overflow: in facts, if both arguments are of type
int operator rules dictate that the result will be an
int as well.
Still, in C signed integer overflow is undefined behavior, so in line of principle anything could happen. In your case, probably the compiler emitted code to perform that shift in a 64 bit register, so by luck it appears to work; to get a guaranteed-correct result you should use the second form you wrote, or, in alternative, specify
1 as an
unsigned long long literal using the
ull suffix (
unsigned long long is guaranteed to be at least 64 bit).
var ^ ( 1ULL << 43 )
I recommend OP's approach, cast the constant
( (uint64_t) 1 << 43 )
For OP's small example, the 2 below will likely perform the same.
uint64_t var = 1; // OP solution) var ^ ( (uint64_t) 1 << 43 ) // Others suggested answer var ^ ( 1ULL << 43 )
The above results have the same value, but different types. The potential difference lies in how 2 types exist in C:
unsigned long long and what may follow.
uint64_thas an exact range 0 to 264-1.
unsigned long longhas a range 0 to at least 264-1.
unsigned long long will always be 64-bits, as it seems to be on many a machine there days, there is no issue, but let's look to the future and say this code was run on a machine where
unsigned long long was 16 bytes (0 to at least 2128-1).
A contrived example below: The first result of the
^ is a
uint64_t, when multiplied by 3, the product will still be
uint64_t, performing a modulo 264, should overflow occur, then the result is assigned to
d1. In the next case, the result of
^ is an
unsigned long long and when multiplied by 3, the product may be bigger than 264 which is then assigned to
d2 have a different answer.
double d1, d2; d1 = 3*(var ^ ( (uint64_t) 1 << 43 )); d2 = 3*(var ^ ( 1ULL << 43 ));
If one wants to work with
unit64_t, be consistent. Do not assume
unsigned long long are the same. If it is OK for your answer to be a
unsigned long long, fine. But in my experience, if one starts using fixed sized types like
uint64_t, one does not want variant size types messing up the computations.
A portable way to have a
unit64_t constant is to use
UINT64_C macro (from
UINT64_C(1) << 43
UINT64_C(c) is defined to something like
c ## ULL.
From the C standard:
_C(value)shall expand to an integer constant expression corresponding to the type
_t. The macro
(value)shall expand to an integer constant expression corresponding to the type
_t. For example, if
uint_least64_tis a name for the type
unsigned long long int, then
UINT64_C(0x123)might expand to the integer constant
Your compiler doesn't know that the shift should be done in 64 bits. However, with this particular version of the compiler in this particular configuration for this particular code, two wrongs happen to make a right. Don't count on it.
int is a 32-bit type on your platform (which is very likely), the two wrongs in
1 << 43 are:
xis of type
unsigned int, then
x << 43has undefined behavior, as does
x << 32or any other
x << nwhere n ≥ 32. For example
1u << 43would have undefined behavior too.
0x12345 << 16has undefined behavior, because the type of the left operand is the signed type
intbut the result value doesn't fit in
int. On the other hand,
0x12345u << 16is well-defined and has the value
“Undefined behavior” means that the compiler is free to generate code that crashes or returns a wrong result. It so happens that you got the desired result in this case — this is not forbidden, however Murphy's law dictates that one day the generated code won't do what you want.
To guarantee that the operation takes place on a 64-bit type, you need to ensure that the left operand is a 64-bit type — the type of the variable that you're assigning the result to doesn't matter. It's the same issue as
float x = 1 / 2 resulting in
x containing 0 and not 0.5: only the types of the operands matter to determine the behavior of the arithmetic operator. Any of
(uint64)1 << 43 or
(long long)1 << 43 or
(unsigned long long)1 << 43 or
1ll << 43 or
1ull << 43 will do. If you use a signed type, then the behavior is only defined if there is no overflow, so if you're expecting truncation on overflow, be sure to use an unsigned type. An unsigned type is generally recommended even if overflow isn't supposed to happen because the behavior is reproducible — if you use a signed type, then the mere act of printing out values for debugging purposes could change the behavior (because compilers like to take advantage of undefined behavior to generate whatever code is most efficient on a micro level, which can be very sensitive to things like pressure on register allocation).
Since you intend the result to be of type
uint64_t, it is clearer to perform all computations with that type. Thus:
uint64_t var = 1; … var ^ ((uint64_t)1 << 43) …