After coming across something similar in a co-worker's code, I'm having trouble understanding why/how this code executes without compiler warnings or errors.

#include <iostream>

int main (void)
    unsigned int u = 42;

    const int& s = u;

    std::cout << "u=" << u << " s=" << s << "\n";

    u = 6 * 9;

    std::cout << "u=" << u << " s=" << s << "\n";


u=42 s=42
u=54 s=42

First, I expect the compiler to issue some kind of diagnostic when I mix signed/unsigned integers like this. Certainly it does if I attempt to compare with <. That's one thing that confuses me.

Second, I'm not sure how the second line of output is generated. I expected the value of s to be 54. How does this work? Is the compiler creating an anonymous, automatic signed integer variable, assigning the value of u, and pointing the reference s at that value? Or is it doing something else, like changing s from a reference to a plain integer variable?

  • 1
    const int& s = u; first creates a new temporary int which is then assigned to the const int&. That's why it won't work with a non-const reference Jan 14 at 15:22
  • 8
    This is an interesting C++ gotcha that I've never seen before. Jan 14 at 15:24
  • 2
    It may help understand the behavior to realize that in C++ a const reference can, in some cases, extend the lifetime of a temporary that is assigned to it. Basically, if the temporary was created during the initialization of the reference, in most cases it will extend the lifetime of the temporary to that of the reference. A function local variable is one of those cases. Jan 14 at 15:26
  • 2
    See here for more about the lifetime extension. "The lifetime of a temporary object may be extended by binding to a const lvalue reference [or to an rvalue reference (since C++11)], see reference initialization for details." Jan 14 at 15:27
  • 1
    @Eljay: this special case is not UB: eel.is/c++draft/basic.lval#11.2
    – geza

References can't bind to objects with different type directly. Given const int& s = u;, u is implicitly converted to int firstly, which is a temporary and then s binds to the temporary int. (Lvalue-references to const (and rvalue-references) could bind to temporaries.) The lifetime of the temporary is prolonged to the lifetime of s, i.e. it'll be destroyed when get out of main.

  • 1
    Thanks for the explanation. This is completely counterintuitive to me. No wonder why people dread C++!
    – russoue
    Jan 18 at 17:55

For the first part about mixing signed/unsigned integers:
Both int and unsigned int are stored in the memory as 4 bytes with total of 32-bits (May vary according to the used compiler) to represent their values in binary form of base-2.
The main difference between them is that the regular int reserves the most significant bit (The 32nd bit) for the sign magnitude where:
0 means positive integer and 1 mean negative integer.
and therefore int can carry values up to 2^31 of positive and negative integers.
while the unsigned int uses the whole 32-bits allowing the variable to carry 2^32
Which is the double of what a normal int can hold. So exchanging values between int and unsigned int is fine as long as the value is positive and less than or equal to 2^31 assigning larger or negative values is possible but it will cause overflow and assign values that are different from the expected ones.

  • 1
    The question isn't about exchanging values between signed and unsigned variables. It's about reference binding. Read the accepted answer, it clarifies everything.
    – bolov
    Jan 19 at 22:33
  • I was answering the first part about mixing signed / unsigned integers Jan 20 at 2:45

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