I have an unsigned int that actually stores a signed int, and the signed int ranges from -128 to 127.

I would like to store this value back in the unsigned int so that I can simply apply a mask 0xFF and get the signed char.

How do I do the conversion ?


unsigned int foo = -100;
foo = (char)foo;
char bar = foo & 0xFF;
assert(bar == -100);
  • 1
    I cannot understand your question. – Iharob Al Asimi Jan 6 '16 at 20:26
  • 2
    Does this give you the result you expect or an unexpected one? – GWW Jan 6 '16 at 20:27
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    Please notice: 'char', 'signed char' and 'unsigned char' are three distinct types, where 'char' is signed or not, but distinct (use signed char and avoid bit operations) – user2249683 Jan 6 '16 at 20:34
  • Implicit conversion like signed char bar = foo; will yield the same result. – Oleg Andriyanov Jan 6 '16 at 20:38
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    "I have an unsigned int that actually stores a signed int" -- Why? Why not just store it in a signed int in the first place? – Keith Thompson Jan 6 '16 at 20:47

The & 0xFF operation will produce a value in the range 0 to 255. It's not possible to get a negative number this way. So, even if you use & 0xFF somewhere, you will still need to apply a conversion later to get to the range -128 to 127.

In your code:

char bar = foo & 0xFF;

there is an implicit conversion to char. This relies on implementation-defined behaviour but this will work on all but the most esoteric of systems. The most common implementation definition is the inverse of the conversion that applies when converting unsigned char to char.

(Your previous line foo = (char)foo; should be removed).


char bar = foo;

would produce exactly the same effect (again, except for on those esoteric systems).


Since the unsigned int foo value does not reach the boundaries of -128 or 127 the implicit conversion will work for this case. But if unsigned int foo had a bigger value you will be losing bytes at the moment when storing it in a char variable and will get unexpected results on your program.

  • C does not guarantee that this will be the case. I'm not sure about C++, but if your answer is specific to C++ then you should say so. – John Bollinger Jan 6 '16 at 21:35
  • To my best knowledge, there is no difference between C and C++ in this respect. – 5gon12eder Jan 6 '16 at 22:12

Answering for C,

If you have an unsigned int whose value was set by assignment of a value of type char (where char happens to be a signed type) or of type signed char, where the assigned value was negative, then the stored value is the arithmetic sum of the assigned negative value and one more than UINT_MAX. This will be far beyond the range of values representable by (signed) char on any C system I have ever encountered. If you convert that value back to (signed) char, whether implicitly or via a cast, "either the result is implementation-defined, or an implementation-defined signal is raised" (C2011,

Converting back to the original char value in a way that avoids implementation-defined behavior is a bit tricky (but relying on implementation-defined behavior may afford much easier approaches). Certainly, masking off all but the 8 lowest-order value bits does not do the trick, as it always gives you a positive value. Also, it assumes that char is 8 bits wide, which, in principle, is not guaranteed. It does not necessarily even give you the correct bit pattern, as C permits negative integers to be represented in any of three different ways.

Here's an approach that will work on any conforming C system:

unsigned int foo = SOME_SIGNED_CHAR_VALUE;
signed char bar;

/* ... */

if (foo <= SCHAR_MAX) {
    /* foo's value is representable as a signed char */
    bar = foo;
} else {
    /* mask off the highest-order value bits to yield a value that fits in an int */
    int foo2 = foo & INT_MAX;

    /* reverse the conversion to unsigned int, as if unsigned int had the same
       number of value bits as int; the other bits are already accounted for */
    bar = (foo2 - INT_MAX) - 1;

That relies only on characteristics of integer representation and conversion that C itself defines.


Don't do it.

Casting to a smaller size may truncate the value. Casting from signed to unsigned or opposite may results wrong value (e.g. 255 -> -1).

If you have to make calculations with different data types, pick one common type, prefereably signed and long int (32-bit), and check boundaries before casting down (to smaller size).

Signed helps you detect underflows (e.g. when result gets less than 0), long int (or just simply: int, which means natural word length) suits for machines (32-bit or 64-bit), and it's big enough for most purposes.

Also try to avoid mixed types in formulas, especially when they contain division (/).

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