a.bit_fld is only 3 bits big, it can't store the value
0x10. Behavior is implementation-defined, but in this case it has probably stored 0.
1 << 2 is binary
100 as you say. Assuming we did store 0 at the first step, the result of
( a.bit_fld | (1<<2)) is an
int with value 4 (binary
In a signed 2's complement 3-bit representation, this bit pattern represents the value -4, so it's not at all surprising if -4 is what you get when you store the value 4 to
a.bit_fld, although again this is implementation-defined.
a.bit_fld is promoted to
int before passing it as a vararg. The 2's complement 32 bit representation of -4 is
0xfffffffc, which is what you see.
It's also undefined behavior to pass an
int instead of an
unsigned int to
printf for the
%x format. It's not surprising that it appears to work, though: for varargs in general there are certain circumstances where it's valid to pass an
int and read it as an
printf isn't one of them, but an implementation isn't going to go out of its way to stop it appearing to work.