# Storing 8 logical true/false values inside 1 byte?

I'm working on a microcontroller with only 2KB of SRAM and desperately need to conserve some memory. Trying to work out how I can put 8 `0`/`1` values into a single byte using a bitfield but can't quite work it out.

``````struct Bits
{
int8_t b0:1, b1:1, b2:1, b3:1, b4:1, b5:1, b6:1, b7:1;
};

int main(){
Bits b;
b.b0 = 0;
b.b1 = 1;

cout << (int)b.b0; // outputs 0, correct
cout << (int)b.b1; // outputs -1, should be outputting 1
}
``````

What gives?

• Have you looked at using a `std::bitset` Commented Apr 24, 2015 at 19:18
• You may use unsigned instead of int
– user2249683
Commented Apr 24, 2015 at 19:20
• Actually, throwing C++ away and sticking to C will cut your memory use down significantly. Absent that, your code is fine. -1 is "true". You can also, as Dieter suggests, make your fields unsigned. Commented Apr 24, 2015 at 19:26
• @LeeDanielCrocker, using `b.b1` by itself will evaluate true, but watch out for `b.b1 == true`. Ask me how I know.... Commented Apr 24, 2015 at 19:30
• the definition of the bit fields should use 'unsigned int8, not int8 otherwise each bit will try to be the sign bit., which results in difficulties. Commented Apr 24, 2015 at 19:53

All of your bitfield members are signed 1-bit integers. On a two's complement system, that means they can represent only either `0` or `-1`. Use `uint8_t` if you want `0` and `1`:

``````struct Bits
{
uint8_t b0:1, b1:1, b2:1, b3:1, b4:1, b5:1, b6:1, b7:1;
};
``````
• NMDV, yet on another 2's complement system, might the values of `int8_t b0:1` be `0` and `1`? I find scant info on signed 1 bit width bit-fields. The only thing I find in the C/C++ specs about `int8_t` with bit-fields is that it is an "implementation-defined" type. Commented Apr 24, 2015 at 20:34
• @chux If the representable values were not 0 and -1 it would not be a 2s-complement representation. (In the hypothetical case of a 1s-complement or sign-magnitude representation, the representable values would be +0 and -0, or possibly 0 and [trap representation]. I'm not aware of any signed integer format in which a 1-bit field would represent the values 0 and 1.)
– zwol
Commented Apr 24, 2015 at 20:55
• @zwol Agreed: C specifies 'the sign bit has the value −(2^M) (two’s complement);" §6.2.6.2 2. So that specifies it must be `0` or `-1`. Commented Apr 24, 2015 at 20:57
• @chux Pedantically, a two's complement system could define `int8_t` to be `char` and then define `char` bitfields to be unsigned, so the program is still implementation-dependent. In fact, the common ABI specifies the latter. The former is up to the library implementation and is fairly arbitrary when `char` is signed. Commented Apr 25, 2015 at 12:42
• Just a caution on use of single bits. If the underlying compiled code uses read-modify-write of the entire byte to set a bit, you may find interrupt handlers that use similar operations on these bits can cause corruption of the data. Commented Apr 29, 2015 at 7:58

As a word of caution - the standard doesn't really enforce an implementation scheme for bitfields. There is no guarantee that `Bits` will be 1 byte, and hypothetically it is entirely possible for it to be larger.

In practice however the actual implementations usually follow the obvious logic and it will "almost always" be 1 byte in size, but again, there is no requirement that it is guaranteed. Just in case you want to be sure, you could do it manually.

BTW `-1` is still `true` but it `-1 != true`

• Can You put a reference? Iirc the size is guaranteed the order isnt Commented Apr 24, 2015 at 22:44
• @Alex - I don't seem to find anything about guaranteeing the size. Commented Apr 24, 2015 at 22:59
• I think the size is safe (but the implementation doesn't have to support anything other than `int` and `unsigned int` I think): "An implementation may allocate any addressable storage unit large enough to hold a bit-field. If enough space remains, a bit-field that immediately follows another bit-field in a structure shall be packed into adjacent bits of the same unit." I think that means if the implementation allows an 8-bit type for bitfields that OP's code is fine. Commented Apr 24, 2015 at 23:15

As noted, these variables consist of only a sign bit, so the only available values are `0` and `-1`.

A more appropriate type for these bitfields would be `bool`. C++14 §9.6/4:

If the value `true` or `false` is stored into a bit-field of type `bool` of any size (including a one bit bit-field), the original `bool` value and the value of the bit-field shall compare equal.

Yes, `std::uint8_t` will do the job, but you might as well use the best fit. You won't need things like the cast for `std::cout << (int)b.b0;`.

• `bool` is not required to be 1 byte, `std::uint8_t` is.
– edmz
Commented Apr 25, 2015 at 12:04
• @black The size of the bitfield type is not necessarily related to the size of the struct. Anyway, on a small microcontroller, `bool` is very likely to be 1 byte. Commented Apr 25, 2015 at 12:28

Signed and unsigned integers are the answer.

Keep in mind that signaling is just an interpretation of bits, -1 or 1 is just the 'print' serializer interpreting the "variable type", as it was "revealed" to cout functions (look operator overloading) by compiler, the bit is the same, its value also (on/off) - since you have only 1 bit.

Don't care about that, but is a good practice to be explicit, so prefer to declare your variable with unsigned, it instructs the compiler to mount a proper code when you set or get the value to a serializer like "print" (cout).

"COUT" OPERATOR OVERLOADING: "cout" works through a series of functions which the parameter overloading instructs the compiler which function to call. So, there are two functions, one receives an unsigned and another signed, thus they can interpret the same data differently, and you can change it, instructing the compiler to call another one using cast. See cout << myclass