If the distribution of bits among those numbers is known beforehand, it's simple: Just put the bits of each element in the array to the proper position in the resulting int, like this (e.g. in C++ code):
unsigned int encoded = (val) | (val << 5) | (val << 10) |
(val << 16) | (val << 23);
val is an array of int, and that it contains numbers which are 5, 5, 6, 7 and 9 bits long. Decoding is equally simple:
decoded = encoded & 0x1F;
decoded = (encoded >> 5) & 0x1F;
decoded = (encoded >> 10) & 0x3F;
decoded = (encoded >> 16) & 0x7F;
decoded = (encoded >> 23);
If the bit lengths aren't known beforehand, and the only known fact is, that their bit size combined is 32, then, for the general case, it's impossible to encode them into a maximum of 32 bits; because you already need this amount of bits to store the actual numbers; but you would also have to know the bit lengths of the encoded numbers; for this you would need additional storage. This all is valid provided that these numbers aren't somehow redundant and could be compressed.
There are of course ways to make it shorter than 4 bytes per integer; depending on the exact properties of the numbers to work on, one or the other algorithm might be better suited; here is a short list of a few possible algorithms:
- If you know that the integers can be a maximum of 9 bits long, you could use the simple method shown above, but with offsets of 9 to store the numbers; you would get down to 45 bits for 5 values with this method.
- Having a length indicator before each element is another possibility (as suggested by Robert Rouhani)
- Another is e.g. proposed in this question (using Dlugosz' Variable-Length-Integer)
- You could also use Variable-length quantity.
The first two methods have the disadvantage that they only can represent a fixed maximum number of bits. This kind of processing falls into the domain of compression, for a more theoretical analysis make sure to read up on some literature on that topic; of special interest here are Universal Codes, as pointed out in Kaganar's comment; the last two algorithms in the list above are such universal codes. They should get you down to 48 bits for your example input of 5 values with 5,5,6,7 and 9 bits (4 times 8 bits for the 4 values having less than 8 bits, and 1 time 16 bits for the 9 bits number). The advantage of these two methods to the other methods on the list is that they are suited for arbitrarily large numbers; there might be other Universl Codes better suited to your purpose, make sure to check out the others as well.