# bitwise not (~) operator, clarification needed

Suppose you have the following C code

`````` unsigned char a = 1;

printf("%d\n", ~a); // prints -2
printf("%d\n", a); // prints 1
``````

I am surprised to see -2 printed as a result of ~1 conversion:

Opposite of 0000 0001

is 1111 1110 --> anything but -2

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Write the value of 0 and -1 in binary. –  Hans Passant Sep 12 '10 at 18:19
"1111 1110 --> anything but -2" Where are you getting this? That's exactly -2 in two's complement. –  recursive Sep 12 '10 at 18:19
try `print("%x")` –  pmg Sep 12 '10 at 18:22
`~` is a bitwise operator, meaning it operates on the individual bits of a number; a binary operator is an operator that takes two operands. –  James McNellis Sep 12 '10 at 18:24
Use `%u` for unsigned decimal conversion. –  John Bode Sep 12 '10 at 21:13

It is two's complement.

In two's complement representation, if a number x's most significant bit is 1, then the actual value would be −(~x + 1).

For instance,

``````0b11110000 = -(~0b1111 + 1) = -(15 + 1) = -16.
``````

This is a natural representation of negative numbers, because

``````0000001 =  1
0000000 =  0
1111111 = -1  (wrap around)
1111110 = -2
1111101 = -3 etc.
``````

See http://en.wikipedia.org/wiki/Two%27s_complement for detail.

BTW, to print an unsigned value, use the `%hhu` or `%hhx` format. See http://www.ideone.com/YafE3.

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%d stands for signed decimal number, not unsigned. So your bit pattern, even though it is stored in an unsigned variable, is interpreted as a signed number.

See this Wikipedia entry on signed number representations for an understanding of the bit values. In particular see Two's complement.

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But in a call to a varargs function an `unsigned char` is more usually promoted to an `int` than an `unsigned int` so `%d` is likely to be the correct format specification in this case. –  Charles Bailey Sep 12 '10 at 18:40
But `unsigned char` is promoted to `int` before the bitwise negation takes place. You'd have to cast back to `unsigned char` afterwards for it to work as desired. –  R.. Sep 12 '10 at 18:47

One (mildly humorous) way to think of signed maths is to recognize that the most significant bit really represents an infinite number of bits above it. So in a 16-bit signed number, the most significant bit is 32768+65536+131072+262144+...etc. which is 32768*(1+2+4+8+...) Using the standard formula for a power series, (1+ X + X^2 + X^3 +...) = 1/(1-X), one discovers that (1+2+4+8+...) is -1, so the sum of all those bits is -32768.

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