You have a problem with obtuse triangles, `x*x + y*y - z*z`

would mathematically give a negative result, that is then reduced modulo `2^WIDTH`

(where `WIDTH`

is the number of value bits in `unsigned long long`

, at least 64 and probably exactly that) yielding a - probably large - positive value (or in rare cases 0). Then the computed result of `t = (x*x + y*y - z*z)/(2*x*y)`

can be larger than 1, and `acos(t)`

would return a NaN.

The correct way to find out whether the triangle is obtuse/acute/right-angled with the given argument type is to check whether `x*x + y*y < /* > / == */ z*z`

- if you can be sure the mathematical results don't exceed the `unsigned long long`

range.

If you can't be sure of that, you can either convert the variables to `double`

before the computation,

```
double xd = x, yd = y, zd = z;
double t = (xd*xd + yd*yd - zd*zd)/(2*xd*yd);
```

with possible loss of precision and incorrect results for nearly right-angled triangles (e.g. for the slightly obtuse triangle `x = 2^29, y = 2^56-1, z = 2^56+2`

, both `y`

and `z`

would be converted to 2^56 with standard 64-bit `double`

s, `xd*xd + yd*yd = 2^58 + 2^112`

would be evaluated to `2^112`

, subtracting `zd*zd`

then results in 0).

Or you can compare `x*x + y*y`

to `z*z`

- or `x*x`

to `z*z - y*y`

- using only integer arithmetic. If `x*x`

is representable as an `unsigned long long`

(I assume that `0 < x <= y <= z`

), it's relatively easy, first check whether `(z - y)*(z + y)`

would exceed `ULLONG_MAX`

, if yes, the triangle is obtuse, otherwise calculate and compare. If `x*x`

is not representable, it becomes complicated, I think the easiest way (except for using a big integer library, of course) would be to compute the high and if necessary low 64 (or whatever width `unsigned long long`

has) bits separately by splitting the numbers at half the width and compare those.

Further note: Your value for π, `3.14159265`

is too inaccurate, right-angled triangles will be reported as obtuse.

`unsigned long long`

and not`double`

? – Troubadour Oct 10 '12 at 22:20