There are (at least) two basic approaches. One would be to create a struct with some bitfields:
struct bits {
unsigned a : 1;
unsigned b : 7;
unsigned c : 4;
unsigned d : 3;
unsigned e : 1;
};
bits b;
b.a = val1;
b.b = val2;
b.c = val3;
b.d = val4;
b.e = val5;
To get the 16-bit value, you could (for one example) create a union of that struct with a uint16_t
. Just one minor problem: the standard doesn't guarantee what order the bit fields will end up in when you look at the 16-bit value. Just for example, you might need to reverse the order I've given above to get the order from most to least significant bits that you really want (but changing compilers might muck things up again).
The other obvious possibility would be to use shifting and masking to put the pieces together into a number:
int16_t result = val1 | (val2 << 1) | (val3 << 8) | (val4 << 12) | (val5 << 15);
For the moment, I've assumed each of the inputs starts out in the correct range (i.e., has a value that can be represented in the chosen number of bits). If there's a possibility that could be wrong, you'd want to mask it to the correct number of bits first. The usual way to do that is something like:
uint16_t result = input & ((1 << num_bits) - 1);
In case you're curious about the math there, it works like this. Lets's assume we want to ensure an input fits in 4 bits. Shifting 1
left 4 bits produces 00010000
(in binary). Subtracting one from that then clears the one bit that's set, and sets all the less significant bits than that, giving 00001111
for our example. That gives us the first least significant bits set. When we do a bit-wise AND
between that and the input, any higher bits that were set in the input are cleared in the result.