# Represent 10000 booleans using only 10000 bits

I want to represent 10000 bits of information.(Each can be either one or zero). Is there any way I can do this?

Wikipedia explains a bit hack to achieve this. But then it asks me to have a number that's as large as 2^10000 for storing 10000 bits.

Is there some way that's tractable even for storing large number of bits?

• You can't ask for implementation details and specify "language-agnostic".. Commented Mar 18, 2013 at 18:58
• An integer on a 32-bit machine, used as a bit-field, can hold 32 bits. So an array of 32 integers can hold 1024 bits... Commented Mar 18, 2013 at 18:59
• @harold I am basically asking for an algorithm. And that algorithm should not use any language specific constructs. Commented Mar 18, 2013 at 19:00
• @antlersoft an array of 32 integers itself uses 32*4*8 bits. Commented Mar 18, 2013 at 19:02
• This isn't really a language-agnostic question. In some languages, you can simply declare a packed array of Booleans. In others, you have to do your own bit-twiddling. As for not using any "language specific constructs", that's not really possible; bitwise operations on integers are the only sensible approach in some languages, but they're language-specific in that not all languages provide them. Commented Mar 18, 2013 at 19:11

As wikipedia explains, a bit field is an appropriate choice here. a bit field that can hold 10,000 bits has 2^10000 states.

A good choice for doing this (given that integers are 32/64 bits) is a bit vector, which is asked about and explained in excruciating detail here:

bit vector implementation of set in Programming Pearls, 2nd Edition

The general idea is that you use an array of integers which are used as bit fields.

• Precisely. A common choice is to use a character array as a bit field, but this depends on your programming environment. Commented Mar 18, 2013 at 19:07

You can make bool take 1 bit for example if you have a bunch of them eg. in a struct, like this:

struct A { bool a:1, b:1, c:1, d:1, e:1; };

Above method won't be useful if the number of variables are large. So instead create an array of integers of size 10000/4*8. It will create exactly 10000 bits. Now you can access each bit by using offset and << or >>(like for accessing 55th bit, use floor(55/4*8) and >>55%32. you can reach that bit).

• Yes, but then indexing is difficult. Commented Mar 18, 2013 at 19:10
• You're assuming that an "integer" is exactly 32 bits. That's not even true for all implementations of C. Commented Mar 18, 2013 at 19:13
• @Keith or you can use 'char' for simpler implementation Commented Mar 18, 2013 at 19:17
• Ok, how many bits in a `char`? And is `char` signed or unsigned? Both answers vary even across conforming C implementations. Trying to make it "language agnostic" is even more difficult. Commented Mar 18, 2013 at 19:22
• doesn't matter when you are using bit wise. Char always uses 8 bit. Commented Mar 18, 2013 at 19:25

In C++ you can do this very simply, using one of two standard library containers:

## `std::vector<bool>`

This specialization of a standard vector acts (almost) like any other vector, but compresses its contents to one bit per element. Aside from enjoying that fact, you can just treat it like a vector:

``````// Create a vector of 10000 booleans
std::vector<bool> lots_of_bits(10000);
// Set all the odd ones to true
for (int i = 1; i < lots_of_bits.size(); i += 2) {
lots_of_bits[i] = true;
}
// Add another 100 trues at the end
for (int j = 0; j < 100; ++j) {
lots_of_bits.push_back(true);
}
// etc.
``````

## `std::bitset<N>`

The "new, improved" bit vector which does not pretend to be a standard container. In particular, it's of fixed size and you need to know the size at compile time. That can be a bit restrictive, but it's otherwise a pretty useful class. Like `std::vector<bool>`, it implements the `[]` operator for getting and setting individual bits. It also supports the bitwise logical operators `&`, `|`, '^' and `~` (and, or, xor and not), as well as left and right bitshifts, and some other utilities.

Is your concern that accessing bit number `n` requires shifting `n` times? If so, you can make the problem tractable by dividing your 10,000 bits into 10,000 / 8 buckets using an array of characters (assuming C or C++ here). Now you can access bit number `n` by figuring out what bucket that bit is in (`n / 8`) and then what position within the bucket (`n % 8`). Then you just do the masking. No extra storage required (except the padding at the end, so a few extra bits if you don't have a perfect multiple of 32 bits).

• Use `CHAR_BIT` rather than `8` if you want complete portability -- and use `unsigned char` rather than plain `char`, which may be either signed or unsigned. Commented Mar 18, 2013 at 19:40