I have some undefined behaviour in a seemingly innocuous function which is parsing a double
value from a buffer. I read the double
in two halves, because I am reasonably certain the language standard says that shifting char
values is only valid in a 32-bit context.
inline double ReadLittleEndianDouble( const unsigned char *buf )
{
uint64_t lo = (buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0];
uint64_t hi = (buf[7] << 24) | (buf[6] << 16) | (buf[5] << 8) | buf[4];
uint64_t val = (hi << 32) | lo;
return *(double*)&val;
}
Since I am storing 32-bit values into 64-bit variables lo
and hi
, I reasonably expect that the high-order 32-bits of these variables will always be 0x00000000
. But sometimes they contain 0xffffffff
or other non-zero rubbish.
The fix is to mask it like this:
uint64_t val = ((hi & 0xffffffffULL) << 32) | (lo & 0xffffffffULL);
Alternatively, it seems to work if I mask during the assignment instead:
uint64_t lo = ((buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0]) & 0xffffffff;
uint64_t hi = ((buf[7] << 24) | (buf[6] << 16) | (buf[5] << 8) | buf[4]) & 0xffffffff;
I would like to know why this is necessary. All I can think of to explain this is that my compiler is doing all the shifting and combining for lo
and hi
directly on 64-bit registers, and I might expect undefined behaviour in the high-order 32-bits if this is the case.
Can someone please confirm my suspicions or otherwise explain what is happening here, and comment on which (if any) of my two solutions is preferable?
<<
operator is not applied to achar
operand. The integer promotions are applied to the operands, sochar
is promoted toint
(or conceivably tounsigned int
on a really bizarre implementation). The right operand (at most 24) is not "greater or equal to the number of bits in the promoted left operand"; the problem is thatfoo << 24
can overflow. Casting tounsigned
should suffice ifint
andunsigned int
are at least 32 bits wide. Casting touint64_t
is probably cleaner.bswap
and others might not. I couldn't speculate on what the compiler emits though.uint64_t
could come out undefined. On my system,int
is 32-bits wide, so I don't have overflow (but I will make it explicit).(buf[7] << 24)
may produce a negative number ifbuf[7] > CHAR_MAX
(technically undefined behaviour but a common implementation is to produce a negativeint
), so when you assign it to auint64_t
it is made positive module 2^64, resulting in FFFF.... on the left. Your "Alternatively" solution still has the undefined behaviour