# How does the computer converts binary number into its decimal equivalent in 2's complement

(My question is related to 2's complement only)

Suppose I give you this binary number 11111110 which is stored as two's complement on a machine and I want you to find its decimal equivalent. Some may say it is -2 while some may say it is 254 as they don't know whether its signed or unsigned. (I know it is a signed number so I took its complement and added 1 which gave me 2, so answer is -2. But if I didn't knew the sign, I would have said 254).

In short, how does the computer converts such binary representation which is stored in 2's complement into its decimal equivalent without making mistakes?

Does the computer knows about its sign? (if yes then where is this information stored?)

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Technically you can not convert a binary represented number into a decimal, because computers do not have any storage facility to represent decimal numbers.

Practically this might sound absurd, since we are always dealing with numbers in decimal representation. But these decimal representations are never actually stored in decimal. Only thing a computer does is converting a number into decimal representation when displaying it. And this conversion is related to program construction and library design.

I'll give a small example on C language. In C you have signed and unsigned integer variables. When you are writing a program these variables are used to store numbers in memory. Who knows about their signs? The compiler. Assembly languages have signed and unsigned operations. Compiler keeps track of the sign of all variables and generate appropriate code for signed and unsigned case. So your program works with signed or unsigned integers perfectly when it is compiled.

Assume you used a `printf` sentence to print an integer variable and you used `%d` format converter to print the value in decimal representation. This conversion will be handled by `printf` function defined in standart input output library of C. The function reads the variable from memory, converts the binary representation to decimal representation by using a simple base conversion algorithm. But the target of the algorithm is a char sequence, not an integer. So this algorithm does two things, it both converts binary to decimal representation; and it converts bits to char values (or ASCII codes to be more precise). `printf` should know the sign of the number to carry on the conversion successfully and this information is again supplied by the compiler constructs placed at compile time. By using these constructs `printf` could check whether the integer is signed or unsigned and use the appropriate conversion method.

Other programming languages follow similar paths. In essence numbers are always stored in binary. The signed or unsigned representation is known by compiler/interpreter and thus is a common knowledge. The decimal conversion is only carried on for cosmetic reasons and the target of conversion is a char sequence or a string.

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Thank you, this was at high level, but What if I write a basic boot loader that prints a negative number (this number is obviously stored in memory in 2's complement somewhere after 0x7c00), and if I don't tell the CPU about its SIGN then he (the CPU) would definitely print it wrong? I still don't get it :( –  dimSutar Mar 28 '13 at 10:52
@dimSutar When you remove the power of operating system from the picture, a similar logic still holds. CPU has instructions for signed and unsigned numbers, similarly BIOS can put signed or unsigned numbers to screen. So you have to tell CPU and BIOS the correct form used. Somebody (you or anyone else) put that negative number into memory. That guy should also announce the sign convention used when storing the number. Without it you don't have any way to know, and you can only guess. Mostly the convention used is in harmony with common sense. Such as, a video card brand code is never signed. –  utkuerd Mar 28 '13 at 12:29

This is because when you specify that you want to use a signed number the computer will interpret the first bit `[1]1111110` as the sign of the number made from the rest of the bits `1[1111110]`. So 1 means - and 0 means +; a "char" can store numbers from -127 to 127; a "unsigned char" can store numbers from 0 to 255;

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