There are several ways of representing signed numbers in binary. You are thinking of sign-and-magnitude, which is what IEEE floating point format uses. The most significant bit of a single precision `float`

or double precision `double`

is used to represent the sign, as you described. Integer values in modern computers are represented in two's complement. The range of values representable in two's complement depends on how many bits are used. The number of bits used depends on your compiler, the target you are compiling for and the variable type you choose. An 8-bit two's complement number can represent numbers in the range -128 to +127. In `C`

you would typically use the `char`

type for a signed 8-bit value and `int`

for a signed 32-bit value, all processors I'm aware of today would represent these in two's complement. To find out how many bytes of storage your system uses to store an `int`

you can use the `sizeof`

operator in `C`

, in most systems an `int`

is 4 bytes, or 32-bits. In an N-bit two's complement number the most significant bit (bit N-1) can, in fact, be used to determine the sign of the number, but the remaining bits are not to be interpreted as the magnitude.

See Wikipedia's article on two's complement.

One interesting fact of two's complement is that the most negative number representable in N bits has no representable positive counterpart in N bits. In other words, you cannot represent the absolute value of the most negative value. The most negative value in two's complement representable in N bits has the most significant bit (bit N-1) set, and the remaining bits 0, its value is -pow(2,N-1). For N=8 the most negative value is 0x80 and the value is -pow(2,8-1) which is -pow(2,7) or -128. The largest positive number representable in two's complement in 8 bits is 0x7F, a '0' in the most significant bit and '1' in the remaining bits, or pow(2,7)-1 or +127.