# If I copy a float to another variable, will they be equal?

I know that using `==` to check equality of floating-point variables is not a good way. But I just want to know that with the following statements:

``````float x = ...

float y = x;

assert(y == x)
``````

Since `y` is copied from `x`, will the assertion be true?

• Let me provide a bounty of 50 to someone who actually proves inequality by a demonstration with real code. I want to see the 80 vs 64 bit thing in action. Plus another 50 for an explanation of the generated assembler code that shows one variable being in a register and the other not (or whatever the reason for the inequality might be, I'd like it explained on a low level). Commented Jan 13, 2020 at 12:58
• @ThomasWeller the GCC bug about this: gcc.gnu.org/bugzilla/show_bug.cgi?id=323 ; however, I've just tried to repro it on an x86-64 system and it doesn't, even with -ffast-math. I suspect you need an old GCC on a 32-bit system. Commented Jan 13, 2020 at 15:49
• @pjc50: Actually you need an 80-bit system to reproduce bug 323; it's the 80x87 FPU which caused the problem. x86-64 uses the SSE FPU. The extra bits cause the problem, because they're rounded when spilling a value to a 32 bits float. Commented Jan 13, 2020 at 16:20
• If MSalters's theory is correct (and I suspect it is), then you can repro either by compiling for 32-bit (`-m32`), or by instructing GCC to use the x87 FPU (`-mfpmath=387`). Commented Jan 13, 2020 at 18:52
• Change "48 bit" to "80 bit", and then you can remove the "mythical" adjective there, @Hot. That's precisely what was being discussed immediately before your comment. The x87 (FPU for x86 architecture) uses 80-bit registers, an "extended-precision" format. Commented Jan 14, 2020 at 0:04

Besides the `assert(NaN==NaN);` case pointed out by kmdreko, you can have situations with x87-math, when 80bit floats are temporarily stored to memory and later compared to values which are still stored inside a register.

Possible minimal example, which fails with gcc9.2 when compiled with `-O2 -m32`:

``````#include <cassert>

int main(int argc, char**){
float x = 1.f/(argc+2);
volatile float y = x;
assert(x==y);
}
``````

Godbolt Demo: https://godbolt.org/z/X-Xt4R

The `volatile` can probably be omitted, if you manage to create sufficient register-pressure to have `y` stored and reloaded from memory (but confuse the compiler enough, not to omit the comparison all-together).

See GCC FAQ reference:

• It seems strange that the extra bits would be considered in comparing a `float` with standard precision to extra precision.
– Nat
Commented Jan 14, 2020 at 13:59
• @Nat It is strange; this is a bug. Commented Jan 14, 2020 at 14:00
• @ThomasWeller No, that's a reasonable award. Though I would like the answer to point out that this is non-compliant behaviour Commented Jan 14, 2020 at 14:01
• I can extend this answer, pointing out what exactly happens in the assembly code, and that this actually violates the standard -- though I wouldn't call myself a language-lawyer, so I can't guarantee that there isn't an obscure clause which explicitly allows that behavior. I assume the OP was more interested in practical complications on actual compilers, not on completely bug-free, fully compliant compilers (which de-facto don't exist, I guess).
– chtz
Commented Jan 14, 2020 at 14:19
• Worth mentioning that `-ffloat-store` appears to be the way to prevent this. Commented Jan 14, 2020 at 14:22

It won't be true if `x` is `NaN`, since comparisons on `NaN` are always false (yes, even `NaN == NaN`). For all other cases (normal values, subnormal values, infinities, zeros) this assertion will be true.

The advice for avoiding `==` for floats applies to calculations due to floating point numbers being unable to express many results exactly when used in arithmetic expressions. Assignment is not a calculation and there's no reason that assignment would yield a different value than the original.

Extended-precision evaluation should be a non-issue if the standard is followed. From `<cfloat>` inherited from C [5.2.4.2.2.8] (emphasis mine):

Except for assignment and cast (which remove all extra range and precision), the values of operations with floating operands and values subject to the usual arithmetic conversions and of floating constants are evaluated to a format whose range and precision may be greater than required by the type.

However, as the comments have pointed out, some cases with certain compilers, build-options, and targets could make this paradoxically false.

• What if `x` is computed in a register in the first line, keeping more precision than the minimum for a `float`. The `y = x` may be in memory, keeping only `float` precision. Then the test for equality would be done with the memory against the register, with different precisions, and thus no guarantee. Commented Jan 13, 2020 at 5:43
• `x+pow(b,2)==x+pow(a,3)` could differ from `auto one=x+pow(b,2); auto two=y+pow(a,3); one==two` because one might compare using more precision than the other (if one/two are 64 bit values in ram, while intermediste values are 80ish bits on fpu). So assignment can do something, sometimes. Commented Jan 13, 2020 at 5:43
• @evg Sure! My answer simply follows the standard. All bets are off if you tell your compiler to be non-confoming, especially when enabling fast-math. Commented Jan 13, 2020 at 8:59
• @Voo See the quote in my answer. The value of the RHS is assigned to the variable on the LHS. There is no legal justification for the resulting value of the LHS to differ from the value of the RHS. I appreciate that several compilers have bugs in this regard. But whether something's stored in a register is supposed to have nothing to do with it. Commented Jan 13, 2020 at 13:44
• @Voo: In ISO C++, rounding to type width is supposed to happen on any assignment. In most compilers that target x87, it really only happens when the compiler decides to spill / reload. You can force it with `gcc -ffloat-store` for strict compliance. But this question is about `x=y; x==y;` without doing anything to either var in between. If `y` is already rounded to fit in a float, converting to double or long double and back won't change the value. ... Commented Jan 13, 2020 at 20:22

Yes, `y` will assuredly take on the value of `x`:

`[expr.ass]/2`: In simple assignment (=), the object referred to by the left operand is modified ([defns.access]) by replacing its value with the result of the right operand.

There is no leeway for other values to be assigned.

(Others have already pointed out that an equivalence comparison `==` will nonetheless evaluate to `false` for NaN values.)

The usual issue with floating-point `==` is that it's easy to not have quite the value you think you do. Here, we know that the two values, whatever they are, are the same.

• @ThomasWeller That's a known bug in a consequently non-compliant implementation. Good to mention it though! Commented Jan 14, 2020 at 14:00
• At first, I thought that language lawyering the distinction between "value" and "result" would be perverse, but this distinction is not required to be without difference by the language of C2.2, 7.1.6; C3.3, 7.1.6; C4.2, 7.1.6, or C5.3, 7.1.6 of the draft Standard you cite. Commented Jan 14, 2020 at 22:12
• @EricTowers Sorry can you clarify those references? I'm not finding what you're pointing to Commented Jan 15, 2020 at 11:09
• @LightnessRacesBY-SA3.0 : C. C2.2, C3.3, C4.2, and C5.3. Commented Jan 15, 2020 at 15:06
• @EricTowers Yeah, still not following you. Your first link goes to the Appendix C index (doesn't tell me anything). Your next four links all go to `[expr]`. If I'm to ignore the links and focus on the citations, I'm left with the confusion that e.g. C.5.3 doesn't seem to address the use of the term "value" or the term "result" (though it does use "result" once in its normal English context). Perhaps you could more clearly describe where you think the standard makes a distinction, and provide a single clear citation to this happening. Thanks! Commented Jan 15, 2020 at 15:26

Yes, in all cases (disregarding NaNs and x87 issues), this will be true.

If you do a `memcmp` on them you will be able test for equality while being able to compare NaNs and sNaNs. This will also require the compiler to take the address of the variable which will coerce the value into a 32-bit `float` instead of an 80-bit one. This will eliminate the x87 issues. The second assertion here is intended to fail to show that `==` will not compare NaNs as true:

``````#include <cmath>
#include <cassert>
#include <cstring>

int main(void)
{
float x = std::nan("");
float y = x;
assert(!std::memcmp(&y, &x, sizeof(float)));
assert(y == x);
return 0;
}
``````

Note that if the NaNs have a different internal representation (i.e. differing mantissa), the `memcmp` will not compare true.

In usual cases, it would evaluate to true. (or the assert statement won't do anything)

Edit:

By 'usual cases' I mean am excluding the aforementioned scenarios (such as NaN values and 80x87 floating point units) as pointed by other users.

Given the obsolesence of 8087 chips in today's context, the issue is rather isolated and for the question to be applicable in current state of floating-point architecture used, its true for all cases except for NaNs.

• I thought it was entirely possible for `x` to be in a floating point register while `y` is loaded from memory. Memory might have less precision than a register, causing the comparison to fail. Commented Jan 13, 2020 at 5:41
• The edit makes this answer incorrect. The C++ standard requires that assignment convert the value to the destination type—excess precision may be used in expression evaluations but may not be retained through assignment. It is immaterial whether the value is held in a register or memory; the C++ standard requires it be, as the code is written, a `float` value without extra precision. Commented Jan 13, 2020 at 12:33
• @AProgrammer Given that a(n extremely) buggy compiler could theoretically cause `int a=1; int b=a; assert( a==b );` to throw an assertion, I think it only makes sense to answer this question in relation to a correctly-functioning compiler (while possibly noting that some versions of some compilers do / have-been-known-to get this wrong). In practical terms, if for some reason a compiler doesn't remove the extra precision from the result of a register-stored assignment, it should do so before it uses that value. Commented Jan 13, 2020 at 14:29