signed int x= 5;
unsigned int y=x;
what is the value of y? and how?
It depends on the maximum value of the
Thus y = x + ((2^{32} − 1) + 1) = 2^{32} − 5 = 4294967291. In a 2's complement platform, which most implementations are nowadays, 5 = ~5 + 1 = 0xFFFFFFFA + 1 = 0xFFFFFFFB = 4294967291. 


From the C99 standard:
So you'll be looking at, effectively, This just happens to mean that the twoscomplement representation is used unchanged as an unsigned integer, which makes this very fast on most modern computers, as they use twoscomplement for signed integers. 


The value of When you convert signed integer value to unsigned type, the value is reduced modulo 2^N, where N is the number of valueforming bits in the unsigned type. This applies to both negative and positive signed values. If you are converting from signed type to unsigned type of the same size, the above means that positive signed values remain unchanged ( 


Signed values are typically stored as something called two's complement:
This means that the actual representation of the numbers 5 and 4294967291 in memory (for a 32 bit word) are identical, e.g:
The contents of x is copied verbatim, i.e. bitwise to
the value of It's important to note what happens when casting to a larger type. A signed value that is cast to a larger signed value will be signextended. This will not happen if the source value is unsigned, e.g.:
or analogically if you don't want the sign extension to occur:



y=0xfffffffb it's the binary representation of 5 (two's complement) 


UINT_MAX
is implementation defined. – kennytm Sep 8 '10 at 14:37