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How the conversion works ? For example: Scope of char[-128, 127], scope of unsigned char[0, 255]

char x = -128;
unsigned char y = static_cast<unsigned char>(x);
cout<<y; //128

Why not 0 ?

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Why do you expect it to be 0? – Adam Rosenfield Jul 10 '12 at 18:06
    
@AdamRosenfield probably because the OP thinks that the cast is doing something bitshift-like. – Matt Ball Jul 10 '12 at 18:08
3  
For an 8-bit value, the cast doesn't change the bits: it simply changes the meaning of the bits. In this case the binary value is always "0x80" (only one bit - the high bit - set). For "signed", this equals -128. For "unsigned", it equals "128". Under no circumstances does it equal "zero" (i.e. "all bits cleared"). – paulsm4 Jul 10 '12 at 18:10
    
@paulsm4: This conversion is not bit-preserving in general. (It is for two's-complement representation, which is very common) – Ben Voigt Jul 10 '12 at 18:16
    
And in a sign-magnitude representation, the byte with only the top bit set represents negative 0, which might be a trap representation or might behave more or less like 0 does in integer arithmetic. Implementer's choice. – Steve Jessop Jul 10 '12 at 18:33

Unsigned arithmetic, including conversion from signed types, is modular, with the modulus being 2n (where n is the number of bits).

Assuming that char has 8 bits, then -128 is congruent to 128, modulo 256; so that is the result of the conversion.

UPDATE: as noted in the comments, this assumes that -128 is a valid value for type char, which is not necessarily the case. char has a range of at least [0..127], and signed char at least [-127..127].

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1  
There was some talk on a since-deleted post about non-2's complement implementations. This answer assumes 2's complement, although not for the reason you were accused of there. The thing that would go wrong here on a non-two's complement implementation is that the expression -128 used to initialize x is outside the range of char on a non-two's complement implementation where char is signed and CHAR_BIT is 8. Then the value stored to x is implementation-defined, but it cannot possibly be equal to 128 modulo 256, so y will end up with some other value. – Steve Jessop Jul 10 '12 at 18:19
    
@Steve: For one's complement, or sign-magnitude, you'd be right. But there do exist (theoretically at least) representations with a [-128,127] range other than two's complement. – Ben Voigt Jul 10 '12 at 18:20
    
@Ben: yeah, OK. They'd be disallowed in C, but C++ is either less strict or less explicit what signed integer formats are permitted. I've never entirely understood the definition of a "pure binary representation". So we can say that with 2's complement the result is 128. With 1s' complement and sign-magnitude it's implementation-defined but definitely not 128 when CHAR_BIT is 8 and char is signed. If CHAR_BIT is greater than 8 or char is unsigned then it's 128 regardless of representation. Any other exotic architectures to consider and then ignore? :-) – Steve Jessop Jul 10 '12 at 18:21
    
So, wait...how does the modular arithmetic thing not effectively mandate two's complement? (If i read from a void* i've casted to a signed or unsigned char*, C++ doesn't know whether that byte i wrote earlier is signed or unsigned. In order for this modular arithmetic thing to apply (and assuming 8-bit chars for simplicity's sake), -128 and 128 would have to have the same 8 bits.) – cHao Jul 10 '12 at 18:24
    
@cHao: what do you mean, "C++ doesn't know that char is signed or unsigned"? C++ permits char to be either a signed type or an unsigned type, but it's implementation-defined. Once the implementation has made its choice, it has to stick to it, so the compiler always knows whether char is signed or unsigned even though the C++ standard doesn't mind which. On a 1s' complement system with a signed char type and some pointer char *p pointing to a negative value, (unsigned char)*p != *(unsigned char*)p. Casting a pointer side-steps the integer conversion. – Steve Jessop Jul 10 '12 at 18:25

Unsigned arithmetic, and conversion to unsigned, takes place modulo 2N. You have an 8-bit character, so N is 8, and 2N is 256.

-128 and 128 are congruent modulo 256.

Here is the actual rule found in section 4.7 ([conv.integral]):

  • If the destination type is unsigned, the resulting value is the least unsigned integer congruent to the source integer (modulo 2n where n is the number of bits used to represent the unsigned type). [ Note: In a two’s complement representation, this conversion is conceptual and there is no change in the bit pattern (if there is no truncation). — end note ]
  • If the destination type is signed, the value is unchanged if it can be represented in the destination type (and bit-field width); otherwise, the value is implementation-defined.
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The conversion works by reinterpreting the same bit pattern in a different way, not by adding +128 to bias the scope. Read up on two's complement to learn more.

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This isn't required by the Standard. – Ben Voigt Jul 10 '12 at 18:14
    
Perhaps not mandated by standard, but that is how it is done. – Dženan Feb 4 '13 at 17:36

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