I've seen this pattern used a lot in C & C++.
unsigned int flags = -1; // all bits are true
Is this a good portable way to accomplish this? Or is using 0xffffffff
or ~0
better?
I recommend you to do it exactly as you have shown, since it is the most straight forward one. Initialize to -1
which will work always, independent of the actual sign representation, while ~
will sometimes have surprising behavior because you will have to have the right operand type. Only then you will get the most high value of an unsigned
type.
For an example of a possible surprise, consider this one:
unsigned long a = ~0u;
It won't necessarily store a pattern with all bits 1 into a
. But it will first create a pattern with all bits 1 in an unsigned int
, and then assign it to a
. What happens when unsigned long
has more bits is that not all of those are 1.
And consider this one, which will fail on a non-two's complement representation:
unsigned int a = ~0; // Should have done ~0u !
The reason for that is that ~0
has to invert all bits. Inverting that will yield -1
on a two's complement machine (which is the value we need!), but will not yield -1
on another representation. On a one's complement machine, it yields zero. Thus, on a one's complement machine, the above will initialize a
to zero.
The thing you should understand is that it's all about values - not bits. The variable is initialized with a value. If in the initializer you modify the bits of the variable used for initialization, the value will be generated according to those bits. The value you need, to initialize a
to the highest possible value, is -1
or UINT_MAX
. The second will depend on the type of a
- you will need to use ULONG_MAX
for an unsigned long
. However, the first will not depend on its type, and it's a nice way of getting the highest value.
We are not talking about whether -1
has all bits one (it doesn't always have). And we're not talking about whether ~0
has all bits one (it has, of course).
But what we are talking about is what the result of the initialized flags
variable is. And for it, only -1
will work with every type and machine.
-1
is represented by, nor does it ask what bits ~0
has. We may not care about values, but the compiler does. We can't ignore the fact that operations work with and by values. The value of ~0
may not be -1
, but this is the value you need. See my answer and @Dingo's summary.
Aug 2, 2010 at 4:20
unsigned int a = -1;
the value of a
is equal to "-1 modulo UINT_MAX+1" (positive remainder), which is here (UINT_MAX + 1) - 1
i.e. UINT_MAX
, whose bit representation is all 1s (even on one's complement machines).
unsigned int flags = -1;
is portable.unsigned int flags = ~0;
isn't portable because it
relies on a two's-complement representation.unsigned int flags = 0xffffffff;
isn't portable because
it assumes 32-bit ints.If you want to set all bits in a way guaranteed by the C standard, use the first one.
~0
yields an int
value with all bits set, of course. But assigning an int
to an unsigned int
does not necessarily result in the unsigned int having the same bit pattern as the signed bit pattern. Only with a 2's complement representation is this always the case. On a 1s' complement or sign-magnitude representation, assigning a negative int
value to an unsigned int
results in a different bit pattern. This is because the C++ standard defines signed -> unsigned conversion to be the modulo-equal value, not the value with the same bits.
Aug 6, 2010 at 0:46
Frankly I think all fff's is more readable. As to the comment that its an antipattern, if you really care that all the bits are set/cleared, I would argue that you are probably in a situation where you care about the size of the variable anyway, which would call for something like boost::uint16_t, etc.
A way which avoids the problems mentioned is to simply do:
unsigned int flags = 0;
flags = ~flags;
Portable and to the point.
unsigned int const flags = ~0u;
~0
is an integer that has all bits set to 1, but when you then assign that int
to the unsigned
variable flags
, you perform a value conversion from -2**31
(assuming a 32-bit int
) to (-2**31 % 2**32) == 2**31
, which is an integer with all bits but the first set to 1.
Dec 12, 2012 at 1:53
u
suffix in your answer. That would of course work, but still has the problem of specifying the data type you use (unsigned
and no larger) twice, which could lead to errors. The error is most likely to show up if the assignment and initial variable declaration are farther apart, though.
Dec 13, 2012 at 1:26
unsigned int flags = -1; // all bits are true
"Is this a good[,] portable way to accomplish this?"
Portable? Yes.
Good? Debatable, as evidenced by all the confusion shown on this thread. Being clear enough that your fellow programmers can understand the code without confusion should be one of the dimensions we measure for good code.
Also, this method is prone to compiler warnings. To elide the warning without crippling your compiler, you'd need an explicit cast. For example,
unsigned int flags = static_cast<unsigned int>(-1);
The explicit cast requires that you pay attention to the target type. If you're paying attention to the target type, then you'll naturally avoid the pitfalls of the other approaches.
My advice would be to pay attention to the target type and make sure there are no implicit conversions. For example:
unsigned int flags1 = UINT_MAX;
unsigned int flags2 = ~static_cast<unsigned int>(0);
unsigned long flags3 = ULONG_MAX;
unsigned long flags4 = ~static_cast<unsigned long>(0);
All of which are correct and more obvious to your fellow programmers.
And with C++11: We can use auto
to make any of these even simpler:
auto flags1 = UINT_MAX;
auto flags2 = ~static_cast<unsigned int>(0);
auto flags3 = ULONG_MAX;
auto flags4 = ~static_cast<unsigned long>(0);
I consider correct and obvious better than simply correct.
I am not sure using an unsigned int for flags is a good idea in the first place in C++. What about bitset and the like?
std::numeric_limit<unsigned int>::max()
is better because 0xffffffff
assumes that unsigned int is a 32-bit integer.
auto
. auto const flags = std::numeric_limit<unsigned>::max()
.
Dec 12, 2012 at 1:55
Converting -1 into any unsigned type is guaranteed by the standard to result in all-ones. Use of ~0U
is generally bad since 0
has type unsigned int
and will not fill all the bits of a larger unsigned type, unless you explicitly write something like ~0ULL
. On sane systems, ~0
should be identical to -1
, but since the standard allows ones-complement and sign/magnitude representations, strictly speaking it's not portable.
Of course it's always okay to write out 0xffffffff
if you know you need exactly 32 bits, but -1 has the advantage that it will work in any context even when you do not know the size of the type, such as macros that work on multiple types, or if the size of the type varies by implementation. If you do know the type, another safe way to get all-ones is the limit macros UINT_MAX
, ULONG_MAX
, ULLONG_MAX
, etc.
Personally I always use -1. It always works and you don't have to think about it.
~(type)0
(well, fill in the right type
of course). Casting zero still results in a zero, so that's clear, and negating all the bits in the target type is pretty clearly defined. It's not that often that I actually want that operation though; YMMV.
Aug 1, 2010 at 21:12
neg
instruction. Machines which have bogus signed arithmetic behavior have separate signed/unsigned arithmetic opcodes. Of course a really good compiler would just always ignore the signed opcodes even for signed values and thereby get twos-complement for free.
Aug 5, 2010 at 4:41
var = ~(0*var)
case will fail for var
being an unsigned type narrower than int
. Perhaps var = ~(0U*var)
? (personally I still prefer -1
, though).
As long as you have #include <limits.h>
as one of your includes, you should just use
unsigned int flags = UINT_MAX;
If you want a long's worth of bits, you could use
unsigned long flags = ULONG_MAX;
These values are guaranteed to have all the value bits of the result set to 1, regardless of how signed integers are implemented.
Yes. As mentioned in other answers, -1
is the most portable; however, it is not very semantic and triggers compiler warnings.
To solve these issues, try this simple helper:
static const struct All1s
{
template<typename UnsignedType>
inline operator UnsignedType(void) const
{
static_assert(std::is_unsigned<UnsignedType>::value, "This is designed only for unsigned types");
return static_cast<UnsignedType>(-1);
}
} ALL_BITS_TRUE;
Usage:
unsigned a = ALL_BITS_TRUE;
uint8_t b = ALL_BITS_TRUE;
uint16_t c = ALL_BITS_TRUE;
uint32_t d = ALL_BITS_TRUE;
uint64_t e = ALL_BITS_TRUE;
ALL_BITS_TRUE ^ a
where a
is a signed integer? The type stays signed integer and the bit-pattern (object representation) depends on the target being 2's complement or not.
Jul 23, 2019 at 21:59
ALL_BITS_TRUE ^ a
gives a compile error because ALL_BITS_TRUE
is ambiguous. It could be used like uint32_t(ALL_BITS_TRUE) ^ a
, however. You can try it yourself on cpp.sh :) Nowadays I'd add a static_assert(std::is_unsigned<UnsignedType>::value, "This is designed only for unsigned types");
in the operator
to be sure users don't try to use int(ALL_BITS_TRUE)
. I'll update the answer.
Jul 25, 2019 at 2:17
See litb's answer for a very clear explanation of the issues.
My disagreement is that, very strictly speaking, there are no guarantees for either case. I don't know of any architecture that does not represent an unsigned value of 'one less than two to the power of the number of bits' as all bits set, but here is what the Standard actually says (3.9.1/7 plus note 44):
The representations of integral types shall define values by use of a pure binary numeration system. [Note 44:]A positional representation for integers that uses the binary digits 0 and 1, in which the values represented by successive bits are additive, begin with 1, and are multiplied by successive integral power of 2, except perhaps for the bit with the highest position.
That leaves the possibility for one of the bits to be anything at all.
On Intel's IA-32 processors it is OK to write 0xFFFFFFFF to a 64-bit register and get the expected results. This is because IA32e (the 64-bit extension to IA32) only supports 32-bit immediates. In 64-bit instructions 32-bit immediates are sign-extended to 64-bits.
The following is illegal:
mov rax, 0ffffffffffffffffh
The following puts 64 1s in RAX:
mov rax, 0ffffffffh
Just for completeness, the following puts 32 1s in the lower part of RAX (aka EAX):
mov eax, 0ffffffffh
And in fact I've had programs fail when I wanted to write 0xffffffff to a 64-bit variable and I got a 0xffffffffffffffff instead. In C this would be:
uint64_t x;
x = UINT64_C(0xffffffff)
printf("x is %"PRIx64"\n", x);
the result is:
x is 0xffffffffffffffff
I thought to post this as a comment to all the answers that said that 0xFFFFFFFF assumes 32 bits, but so many people answered it I figured I'd add it as a separate answer.
UINT64_C(0xffffffff)
expands to something like 0xffffffffuLL
, it is definitely a compiler bug. The C standard largely discusses values, the value represented by 0xffffffff
is 4294967295 (not 36893488147419103231), and there aren't any conversions to signed integer types in sight.
I would not do the -1 thing. It's rather non-intuitive (to me at least). Assigning signed data to an unsigned variable just seems to be a violation of the natural order of things.
In your situation, I always use 0xFFFF
. (Use the right number of Fs for the variable size of course.)
[BTW, I very rarely see the -1 trick done in real-world code.]
Additionally, if you really care about the individual bits in a vairable, it would be good idea to start using the fixed-width uint8_t
, uint16_t
, uint32_t
types.
Although the 0xFFFF
(or 0xFFFFFFFF
, etc.) may be easier to read, it can break portability in code which would otherwise be portable. Consider, for example, a library routine to count how many items in a data structure have certain bits set (the exact bits being specified by the caller). The routine may be totally agnostic as to what the bits represent, but still need to have an "all bits set" constant. In such a case, -1 will be vastly better than a hex constant since it will work with any bit size.
The other possibility, if a typedef
value is used for the bitmask, would be to use ~(bitMaskType)0; if bitmask happens to only be a 16-bit type, that expression will only have 16 bits set (even if 'int' would otherwise be 32 bits) but since 16 bits will be all that are required, things should be fine provided that one actually uses the appropriate type in the typecast.
Incidentally, expressions of the form longvar &= ~[hex_constant]
have a nasty gotcha if the hex constant is too large to fit in an int
, but will fit in an unsigned int
. If an int
is 16 bits, then longvar &= ~0x4000;
or longvar &= ~0x10000
; will clear one bit of longvar
, but longvar &= ~0x8000;
will clear out bit 15 and all bits above that. Values which fit in int
will have the complement operator applied to a type int
, but the result will be sign extended to long
, setting the upper bits. Values which are too big for unsigned int
will have the complement operator applied to type long
. Values which are between those sizes, however, will apply the complement operator to type unsigned int
, which will then be converted to type long
without sign extension.
As others have mentioned, -1 is the correct way to create an integer that will convert to an unsigned type with all bits set to 1. However, the most important thing in C++ is using correct types. Therefore, the correct answer to your problem (which includes the answer to the question you asked) is this:
std::bitset<32> const flags(-1);
This will always contain the exact amount of bits you need. It constructs a std::bitset
with all bits set to 1 for the same reasons mentioned in other answers.
It is certainly safe, as -1 will always have all available bits set, but I like ~0 better. -1 just doesn't make much sense for an unsigned int
. 0xFF
... is not good because it depends on the width of the type.
Practically: Yes
Theoretically: No.
-1 = 0xFFFFFFFF (or whatever size an int is on your platform) is only true with two's complement arithmetic. In practice, it will work, but there are legacy machines out there (IBM mainframes, etc.) where you've got an actual sign bit rather than a two's complement representation. Your proposed ~0 solution should work everywhere.
Leveraging on the fact that assigning all bits to one for an unsigned type is equivalent to taking the maximum possible value for the given type,
and extending the scope of the question to all unsigned integer types:
Assigning -1 works for any unsigned integer type (unsigned int, uint8_t, uint16_t, etc.) for both C and C++.
As an alternative, for C++, you can either:
<limits>
and use std::numeric_limits< your_type >::max()
The purpose could be add more clarity, as assigning -1
would always need some explanatory comment.
A way to make the meaning bit more obvious and yet to avoid repeating the type:
const auto flags = static_cast<unsigned int>(-1);
An additional effort to emphasize, why Adrian McCarthy's approach here might be the best solution at latest since C++11 in terms of a compromise between standard conformity, type safety/explicit clearness and reduction of possible ambiguities:
unsigned int flagsPreCpp11 = ~static_cast<unsigned int>(0);
auto flags = ~static_cast<unsigned int>(0); // C++11 initialization
predeclaredflags = ~static_cast<decltype(predeclaredflags)>(0); // C++11 assignment to already declared variable
I'm going to explain my preference in detail below. As Johannes mentioned totally correctly, the fundamental origin of irritations here is the question about value vs. according bit representation semantics and about what types we're talking about exactly (the assigned value type vs. the possible compile time integral constant's type). Since there's no standard built-in mechanism to explicitly ensure the set of all bits to 1 for the concrete use case of the OP about unsigned integer values, it's obvious, that it's impossible to be fully independent of value semantics here (std::bitset is a common pure bit-layer refering container but the question was about unsigned integers in general). But we might be able to reduce ambiguity here.
Comparison of the 'better' standard compliant approaches:
The OP's way:
unsigned int flags = -1;
PROs:
CONs:
Refering to maximum values via defines:
unsigned int flags = UINT_MAX;
This circumvents the signed unsigned transition issue of the -1 approach but introduces several new problems: In doubt, one has to look twice here again, at the latest if you want to change the target type to unsigned long for instance. And here, one has to be sure about the fact, that the maximum value leads to all bits set to 1 by the standard (and padding bit concerns again). Bit semantics are also not obvious here directly from the code solely again.
Refering to maximum values more explicitly:
auto flags = std::numeric_limits<unsigned int>::max();
On my opinion, that's the better maximum value approach since it's macro/define free and one is explicit about the involved type. But all other concerns about the approach type itself remain.
Adrian's approach (and why I think, it's the preferred one before C++11 and since):
unsigned int flagsPreCpp11 = ~static_cast<unsigned int>(0);
auto flagsCpp11 = ~static_cast<unsigned int>(0);
PROs:
CONs:
If assigned to a member for instance, there's a small chance that you mismatch types with pre C++11:
Declaration in class:
unsigned long m_flags;
Initialization in constructor:
m_flags(~static_cast<unsigned int>(0))
But since C++11, the usage of decltype + auto is powerful to prevent most of these possible issues. And some of these type mismatch scenarios (on interface boundaries for instance) are also possible for the -1 approach.
Robust final C++11 approach for pre-declared variables:
m_flags(~static_cast<decltype(m_flags)>(0)) // member initialization case
So with a full view on the weighting of the PROs and CONs of all approaches here, I recommend this one as the preferred approach, at latest since C++11.
Update: Thanks to a hint by Andrew Henle, I removed the statement about its readability since that might be a too subjective statement. But I still think, its readability is at least not that worse than most of the maximum value approaches or the ones with explicit maximum value provision via compile time integrals/literals since static_cast-usage is "established" too and built-in in contrast to defines/macros and even the std-lib.
I say:
int x;
memset(&x, 0xFF, sizeof(int));
This will always give you the desired result.
yes the representation shown is very much correct as if we do it the other way round u will require an operator to reverse all the bits but in this case the logic is quite straightforward if we consider the size of the integers in the machine
for instance in most machines an integer is 2 bytes = 16 bits maximum value it can hold is 2^16-1=65535 2^16=65536
0%65536=0 -1%65536=65535 which corressponds to 1111.............1 and all the bits are set to 1 (if we consider residue classes mod 65536) hence it is much straight forward.
I guess
no if u consider this notion it is perfectly dine for unsigned ints and it actually works out
just check the following program fragment
int main() {
unsigned int a=2;
cout<<(unsigned int)pow(double(a),double(sizeof(a)*8));
unsigned int b=-1;
cout<<"\n"<<b;
getchar();
return 0;
}
answer for b = 4294967295 whcih is -1%2^32 on 4 byte integers
hence it is perfectly valid for unsigned integers
in case of any discrepancies plzz report
-1
will always work, the fact that a comment is needed after it shows that it's not clear code. If the variable is meant to be a collection of flags, why assign it an integer? Its type may be an integer, but its certainly not semantically an integer. You're never going to increment it or multiply it. So I would use0xffffffff
not for portability or correctness, but for clarity.-1
remains a portable and backward compatible solution for both languages, but it could affect some of the reasoning in other answers.