I'm learning about binary representation of integers and tried to write a function that returns an int multiplied by 2 using saturation. The thought process is if the value overflows positively the function returns INT_MAX, and conversely if it overflows negatively it returns INT_MIN. In all other cases the binary value is left shifted by 1.

What I'm wondering is why I have to cast the value 0xC0000000 as an int in order to get my function to work correctly when I pass the argument x = 1.

Here is my function:

int timestwo (int x){
    if(x >= 0x40000000) // INT_MAX/2 + 1
        return 0x7fffffff; // INT_MAX
    else if(x < (int) 0xC0000000) // INT_MIN/2
        return 0x80000000; // INT_MIN
        return x << 1;
    return 0;
  • 1
    Assuming twos-complement 32-bit int, return x << 1; results in undefined behavior if x <= ( int ) 0x80000000 and x >= ( int ) 0xC0000000. Feb 12 '20 at 10:58
  • So, why do you assume you know the actual values for INT_MAX and INT_MIN? And worse, if you know there are such constants, why don't you use them? The constants are there to avoid architecture dependencies, that are commonly solved by comparing values of the same type. Feb 13 '20 at 6:42
  • @LuisColorado As said in the post, it is a learning exercise. I determined INT_MAX and INT_MIN for a specific architecture relevant to the exercise to better learn about bit-wise representation. I would have gained nothing by just plopping in the constants.
    – qq4
    Feb 14 '20 at 13:54
  • @qq4, you don't say in the exercise (and neither you do in your comment above) the reasons to use the values, instead of the constants. How have you determined that the constants will don't work and your values do? I'm afraid you are not telling something essential. Feb 14 '20 at 18:36

Hexadecimal (and octal) literals in C are typed using the smallest promoted (=int or a higher ranking type) type, signed or unsigned, that can accommodate the value. This differs from decimal literals, which stay within signed types if they don't have the u/U suffix, or within unsigned types otherwise (

integer-literal types

This makes 0xC0000000 on a system with 32-bit integers unsigned and comparing (or otherwise pairing by means of an operator) an unsigned with a signed of the same rank forces the signed to become unsigned (, so without the (int) cast you get an implicit (unsigned int)x < (unsigned int) 0xC0000000.


The value specified by the constant 0xC0000000 will not fit in an int (assuming 32 bit), but it does fit in an unsigned int, so the type of this constant is unsigned int. This unsigned value is larger than 1 so the comparison evaluates to false.

The result of the cast to int is actually implementation defined, although on a two's complement system this will typically result in what you would expect.

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