How can 1111 1111 be the two-s complement representation of -1?

My book says that to get the two's-complement representation, to just flip the bits and add 1. Correct me if I am wrong but the binary representation of -1 would be:

``````1000 0001
``````

The MSB 1 denotes the sign (1 being negative number) and the 1 at the very end is where the 1 comes from.

So when I flip the bits:

``````0111 1110
``````

So why does my book say that the two's complement representation of -1 is 1111 1111? I assume I am messing up somewhere.

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read your book carefully –  Walter Tross Feb 3 '14 at 16:14

The book has right. 1111 1111 is the representation of -1 in two's complement.

Try add one to 1111 1111. The result is:

``````  1111 1111 +
0000 0001
---------
1 0000 0000
``````

The "one" at the beginning of the result is the "carry bit". The result is your answer: 0. At first glance you would say that overflow has occurred, but not at this time, because the result (the zero) can be represented on 8 bits.

One more example:

If you add -1 to -1 then you should get -2:

``````  1111 1111 +
1111 1111
---------
1 1111 1110
``````

And so on...

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So why does my book say that the two's complement representation of -1 is 1111 1111?

It's because the MSB is negative and the rest is positive:

``````1111 1111 = -128 + 64 + 32 + 16 + 8 + 4 + 2 + 1 => -1
``````
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