It depends on bit width of unsigned/int
.
The below 2 are not the same (when unsigned <= 32
bits). u32_x + u32_y
becomes 0.
u64_a = 0; u32_x = 1; u32_y = 0xFFFFFFFF;
uint64_t u64_z = u32_x + u64_a + u32_y;
uint64_t u64_z = u32_x + u32_y + u64_a; // u32_x + u32_y carry does not add to sum.
They are the same (when unsigned >= 34
bits). Integer promotions caused u32_x + u32_y
addition to occur at 64-bit math. Order is irrelevant.
It is UB (when unsigned == 33
bits). Integer promotions caused addition to occur at signed 33-bit math and signed overflow is UB.
Are compilers allowed to do such a reordering ...?
(32 bit math): Re-order yes, but same results must occur, so not that re-ordering OP proposes. Below are the same
// Same
u32_x + u64_a + u32_y;
u64_a + u32_x + u32_y;
u32_x + (uint64_t) u32_y + u64_a;
...
// Same as each other below, but not the same as the 3 above.
uint64_t u64_z = u32_x + u32_y + u64_a;
uint64_t u64_z = u64_a + (u32_x + u32_y);
... can we trust them to notice the result inconsistency and keep the expression order as is?
Trust yes, but OP's coding goal is not crystal clear. Should u32_x + u32_y
carry contribute? If OP wants that contribution, code should be
uint64_t u64_z = u64_a + u32_x + u32_y;
uint64_t u64_z = u32_x + u64_a + u32_y;
uint64_t u64_z = u32_x + (u32_y + u64_a);
But not
uint64_t u64_z = u32_x + u32_y + u64_a;
uint32_t
values - which don't overflow, they wrap. These are not different behaviours.((uint32_t)-1 + (uint32_t)1) + (uint64_t)0
results in0
, whereas(uint32_t)-1 + ((uint32_t)1 + (uint64_t)0)
results in0x100000000
, and these two values are not equal. So it's significant whether or not the compiler can apply that transformation. But yeah, the standard only uses the word "overflow" for signed integers, not unsigned.