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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.

Thanks for all your help !

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1  
Which particular aspects of bitwise operations are you having trouble with? –  Oli 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));
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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';
}
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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))
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1  
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.

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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

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;

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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

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