I have a short program that performs a numerical computation, and obtains an incorrect NaN result when some specific conditions hold. I cannot see how this NaN result can arise. Note that I am not using compiler options that allow the reordering of arithmetic operations, such as `-ffath-math`

.

**Question:** I am looking for an explanation of how the NaN result arises. Mathematically, there is nothing in the computation that leads to division by zero or similar. Am I missing something obvious?

Note that I am not asking how to fix the problem—that is easy. I am simply looking for an understanding of how the NaN appears.

### Minimal example

Note that this example is very fragile and even minor modifications, such as adding `printf()`

calls in the loop to observe values, will change the behaviour. This is why I was unable to minimize it further.

```
// prog.c
#include <stdio.h>
#include <math.h>
typedef long long myint;
void fun(const myint n, double *result) {
double z = -1.0;
double phi = 0.0;
for (myint i = 0; i < n; i++) {
double r = sqrt(1 - z*z);
/* avoids division by zero when r == 0 */
if (i != 0 && i != n-1) {
phi += 1.0 / r;
}
double x = r*cos(phi);
double y = r*sin(phi);
result[i + n*0] = x;
result[i + n*1] = y;
result[i + n*2] = z;
z += 2.0 / (n - 1);
}
}
#define N 11
int main(void) {
// perform computation
double res[3*N];
fun(N, res);
// output result
for (int i=0; i < N; i++) {
printf("%g %g %g\n", res[i+N*0], res[i+N*1], res[i+N*2]);
}
return 0;
}
```

Compile with:

```
gcc -O3 -mfpmath=387 prog.c -o prog -lm
```

The last line of the output is:

```
nan nan 1
```

Instead of NaN, I expect a number close to zero.

#### Critical features of the example

The following must all hold for the NaN output to appear:

Compile with GCC on an x86 platform. I was able to reproduce with this GCC 12.2.0 (from MacPorts) on macOS 10.14.6, as well as with GCC versions 9.3.0, 8.3.0 and 7.5.0 on Linux (openSUSE Leap 15.3).

I

*cannot*reproduce it with GCC 10.2.0 or later on Linux, or GCC 11.3.0 on macOS.Choose to use x87 instructions with

`-mfpmath=387`

, and an optimization level of`-O2`

or`-O3`

.`myint`

must be a*signed*64-bit type.Thinking of

`result`

as an n-by-3 matrix, it must be stored in column-major order.No

`printf()`

calls in the main loop of`fun()`

.

Without these features, I do get the expected output, i.e. something like `1.77993e-08 -1.12816e-08 1`

or `0 0 1`

as the last line.

#### Explanation of the program

Even though it doesn't really matter to the question, I give a short explanation of what the program does, to make it easier to follow. It computes `x`

, `y`

, `z`

three-dimensional coordinates of `n`

points on the surface of a sphere in a specific arrangement. `z`

values go from -1 to 1 in equal increments, however, the last value won't be precisely 1 due to numerical round-off errors. The coordinates are written into an `n`

-by-3 matrix, `result`

, stored in column-major order. `r`

and `phi`

are polar coordinates in the (x, y) plane.

Note that when `z`

is `-1`

or `1`

then `r`

becomes 0. This happens in the first and last iteration steps. This would lead to division by 0 in the `1.0 / r`

expression. However, `1.0 / r`

is excluded from the first and last iteration of the loop.

`printf`

s to try to observe variable values makes the problem go away. I spent quite a lot of time trying to figure this out with no success, and also a lot of time obtaining this minimal example from something more complicated that depended on libraries. The example is extremely fragile, very minor modifications change the behaviour`z`

produced a value "a little" greater than 1 and thereby causing`sqrt(1 - z*z);`

producing a NaN. But again... this is just an idea - I'm not sure at all`z * z > 1.0`

use`isnan(r)`

and it triggers. The problematic result of`1 - z*z`

is`-1.11022e-16`

godbolt.org/z/M349szcj8 . Fascinating.10more comments