Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm not used to binary files, and I'm trying to get the hang of it. I managed to store some integers and unsigned char, and read them without too much pain. Now, when I'm trying to save some booleans, I see that each of my bool takes exactly 1 octet in my file, which seems logical since a lone bool is stored in a char-sized data (correct me if I'm wrong!).

But since I'm going to have 3 or 4 bools to serialize, I figure it is a waste to store them like this : 00000001 00000001 00000000, for instance, when I could have 00000110. I guess to obtain this I should use bitwise operation, but I'm not very good with them... so could somebody tell me:

  1. How to store up to 8 bools in a single octet using bitwise manipulations?
  2. How to give proper values to (up to 8 bools) from a single octet using bitwise manipulation?
  3. (And, bonus question, does anybody can recommend a simple, non-mathematical-oriented-mind like mine, bit manipulation tutorial if this exists? Everything I found I understood but could not put into practice...)

I'm using C++ but I guess most C-syntaxic languages will use the same kind of operation.

share|improve this question
Which particular aspects of bitwise operations are you having trouble with? –  Oliver Charlesworth Feb 1 '11 at 8:42

6 Answers 6

up vote 2 down vote accepted

To store bools in a byte:

bool flag; // value to store
unsigned char b = 0; // all false
int position; // ranges from 0..7
b = b | (flag << position);

To read it back:

flag = (b & (1 << position));
share|improve this answer
This shows how to do it, but maybe some explanation would also be helpful as the OP seemed unsure of the logic behind it. –  KyleWpppd Feb 1 '11 at 8:46
It works, thank you very much ! –  Raveline Feb 1 '11 at 8:58

The easy way is to use std::bitset which allows you to use indexing to access individual bits (bools), then get the resulting value as an integer. It also allows the reverse.

int main() {
  std::bitset<8> s;
  s[1] = s[2] = true;  // 0b_0000_0110
  cout << s.to_ulong() << '\n';
share|improve this answer
I didn't known about std::bitset, thank you very much for making me discover it. However, I need an unsigned char and even thought I could convert to an int, then to the uchar, I'm going for the no-casting operations. –  Raveline Feb 1 '11 at 9:01
@Raveline: The cast from ulong to unsigned char is not a problem here. –  Fred Nurk Feb 1 '11 at 9:22

Without wrapping in fancy template/pre-processor machinery:

  • Set bit 3 in var:
    var |= (1 << 3)
  • Set bit n in var:
    var |= (1 << n)
  • Clear bit n in var:
    var &= ~(1 << n)
  • Test bit n in var: (the !! ensures the result is 0 or 1)
    !!(var & (1 << n))
share|improve this answer
You should count from 0 not from 1. –  Luka Rahne Feb 1 '11 at 8:50
@ralu: Eh? I think you'll find I do. "bit 3" above refers to the fourth bit, yes? –  bobbogo Feb 7 '11 at 11:57

Try reading this in order.

  1. http://www.cprogramming.com/tutorial/bitwise_operators.html

  2. http://www-graphics.stanford.edu/~seander/bithacks.html#ConditionalSetOrClearBitsWithoutBranching

Some people willthink that 2nd link is way too hardcore, but once you will master simple manipulation, it will come handy.

share|improve this answer
This looks great, I'll read it asap. Thank you for the link. –  Raveline Feb 1 '11 at 9:00
Great link to Bit Twiddling Hacks. TVM –  bobbogo Feb 1 '11 at 9:01
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. –  dg99 May 1 at 0:11

Basic stuff first:

  • The only combination of bits that means false is 00000000 all the others mean true i.e: 00001000,01010101
  • 00000000 = 0(decimal), 00000001 = 2^0, 00000010 = 2^1, 00000100 = 2^2, …. ,10000000 = 2^7
  • There is a big difference between the operands (&&, ||) and (&,|) the first ones give the result of the logic operation between the two numbers, for example:

    00000000 && 00000000 = false,

    01010101 && 10101010 = true

    00001100 || 00000000 = true,

    00000000 || 00000000 = false

    The second pair makes a bitwise operation (the logic operation between each bit of the numbers):

    00000000 & 00000000 = 00000000 = false

    00001111 & 11110000 = 00000000 = false

    01010101 & 10101001 = 00000001 = true

    00001111 | 11110000 = 11111111 = true

    00001100 | 00000011 = 00001111 = true

To work with this and play with the bits, you only need to know some basic tricks:

  • To set a bit to 1 you make the operation | with an octet that has a 1 in that position and ceros in the rest.

For example: we want the first bit of the octet A to be 1 we make: A|00000001

  • To set a bit to 0 you make the operation & with an octet that has a 0 in that position and ones in the rest.

For example: we want the last bit of the octet A to be 0 we make: A&01111111

  • To get the Boolean value that holds a bit you make the operation & with an octet that has a 1 in that position and ceros in the rest.

For example: we want to see the value of the third bit of the octet A, we make: A&00000100, if A was XXXXX1XX we get 00000100 = true and if A was XXXXX0XX we get 00000000 = false;

share|improve this answer

You can always serialize bitfields. Something like:

struct bools 
    bool a:1;
    bool b:1;
    bool c:1;
    bool d:1;

has a sizeof 1

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.