As @Angew pointed out, the `!=`

operator needs the same type on both sides.
`(float)i != i`

results in promotion of the RHS to float as well, so we have `(float)i != (float)i`

.

g++ also generates an infinite loop, but it doesn't optimize away the work from inside it. You can see it converts int->float with `cvtsi2ss`

and does `ucomiss xmm0,xmm0`

to compare `(float)i`

with itself. (That was your first clue that your C++ source doesn't mean what you thought it did like @Angew's answer explains.)

`x != x`

is only true when it's "unordered" because `x`

was NaN. (`INFINITY`

compares equal to itself in IEEE math, but NaN doesn't. `NAN == NAN`

is false, `NAN != NAN`

is true).

gcc7.4 and older correctly optimizes your code to `jnp`

as the loop branch (https://godbolt.org/z/fyOhW1) : keep looping as long as the operands to `x != x`

weren't NaN. (gcc8 and later also checks `je`

to a break out of the loop, failing to optimize based on the fact that it will always be true for any non-NaN input). x86 FP compares set PF on unordered.

And BTW, that means **clang's optimization is also safe**: it just has to CSE `(float)i != (implicit conversion to float)i`

as being the same, and prove that `i -> float`

is never NaN for the possible range of `int`

.

(Although given that this loop will hit signed-overflow UB, it's allowed to emit literally any asm it wants, including a `ud2`

illegal instruction, or an empty infinite loop regardless of what the loop body actually was.) But ignoring the signed-overflow UB, this optimization is still 100% legal.

GCC fails to optimize away the loop body **even with **`-fwrapv`

to make signed-integer overflow well-defined (as 2's complement wraparound). https://godbolt.org/z/t9A8t_

Even enabling `-fno-trapping-math`

doesn't help. (GCC's default is unfortunately to enable

`-ftrapping-math`

even though GCC's implementation of it is broken/buggy.) int->float conversion can cause an FP inexact exception (for numbers too large to be represented exactly), so with exceptions possibly unmasked it's reasonable not to optimize away the loop body. (Because converting `16777217`

to float could have an observable side-effect if the inexact exception is unmasked.)

But with `-O3 -fwrapv -fno-trapping-math`

, it's 100% missed optimization not to compile this to an empty infinite loop. Without `#pragma STDC FENV_ACCESS ON`

, the state of the sticky flags that record masked FP exceptions is not an observable side-effect of the code. No `int`

->`float`

conversion can result in NaN, so `x != x`

can't be true.

These compilers are all optimizing for C++ implementations that use IEEE 754 single-precision (binary32) `float`

and 32-bit `int`

.

The **bugfixed **`(int)(float)i != i`

loop would have UB on C++ implementations with narrow 16-bit `int`

and/or wider `float`

, because you'd hit signed-integer overflow UB before reaching the first integer that wasn't exactly representable as a `float`

.

But UB under a different set of implementation-defined choices doesn't have any negative consequences when compiling for an implementation like gcc or clang with the x86-64 System V ABI.

BTW, you could statically calculate the result of this loop from `FLT_RADIX`

and `FLT_MANT_DIG`

, defined in `<climits>`

. Or at least you can in theory, if `float`

actually fits the model of an IEEE float rather than some other kind of real-number representation like a Posit / unum.

I'm not sure how much the ISO C++ standard nails down about `float`

behaviour and whether a format that wasn't based on fixed-width exponent and significand fields would be standards compliant.

In comments:

@geza I would be interested to hear the resulting number!

@nada: it's 16777216

Are you claiming you got this loop to print / return `16777216`

?

Update: since that comment has been deleted, I think not. Probably the OP is just quoting the `float`

before the first integer that can't be exactly represented as a 32-bit `float`

. https://en.wikipedia.org/wiki/Single-precision_floating-point_format#Precision_limits_on_integer_values i.e. what they were hoping to verify with this buggy code.

The bugfixed version would of course print `16777217`

, the first integer that's *not* exactly representable, rather than the value before that.

(All the higher float values are exact integers, but they're multiples of 2, then 4, then 8, etc. for exponent values higher than the significand width. Many higher integer values can be represented, but 1 unit in the last place (of the significand) is greater than 1 so they're not contiguous integers. The largest finite `float`

is just below 2^128, which is too large for even `int64_t`

.)

If any compiler did exit the original loop and print that, it would be a compiler bug.

`gcc`

does the same infinite loops optimization if you compile with`-Ofast`

instead, so it's an optimization`gcc`

deems unsafe, but it can do it.`ucomiss xmm0,xmm0`

to compare`(float)i`

with itself. That was your first clue that your C++ source doesn't mean what you thought it did. Are you claiming you got this loop to print / return`16777216`

? What compiler/version/options was that with? Because that would be a compiler bug. gcc correctly optimizes your code to`jnp`

as the loop branch (godbolt.org/z/XJYWeu) : keep looping as long as the operands to`!=`

weren't NaN.`-ffast-math`

option that is implicitly enabled by`-Ofast`

that allows GCC to apply unsafe floating-point optimizations and thus generate the same code as Clang. MSVC behaves exactly the same way: without`/fp:fast`

, it generates a bunch of code that results in an infinite loop; with`/fp:fast`

, it emits a single`jmp`

instruction. I'm assuming that without explicitly turning on unsafe FP optimizations, these compilers get hung up on the IEEE 754 requirements regarding NaN values. Rather interesting that Clang doesn't, actually. Its static analyzer is better. @12345ieee`(float) i`

differed from the mathematical value of`i`

, then the result (the value returned in the`return`

statement) would be 16,777,217, not 16,777,216.3more comments