I observed a surprising behavior when testing simple arithmetic operations at limit cases, on an x86 architecture:

```
const double max = 9.9e307; // Near std::numeric_limits<double>::max()
const double init[] = { max, max, max };
const valarray<double> myvalarray(init, 3);
const double mysum = myvalarray.sum();
cout << "Sum is " << mysum << endl; // Sum is 1.#INF
const double myavg1 = mysum/myvalarray.size();
cout << "Average (1) is " << myavg1 << endl; // Average (1) is 1.#INF
const double myavg2 = myvalarray.sum()/myvalarray.size();
cout << "Average (2) is " << myavg2 << endl; // Average (2) is 9.9e+307
```

(Tested with MSVC in *release* mode, as well as gcc through Codepad.org. MSVC's debug mode sets average (2) to `#INF`

.)

I expected average (2) to be equal to average (1), but it seems to me the C++ built-in division operator got optimized by the compiler and somehow prevented the accumulation to reach `#INF`

.

In short: The average of big numbers doesn't yields `#INF`

.

I observed the same behavior with an std algorithm on MSVC:

```
const double mysum = accumulate(init, init+3, 0.);
cout << "Sum is " << mysum << endl; // Sum is 1.#INF
const double myavg1 = mysum/static_cast<size_t>(3);
cout << "Average (1) is " << myavg1 << endl; // Average (1) is 1.#INF
const double myavg2 = accumulate(init, init+3, 0.)/static_cast<size_t>(3);
cout << "Average (2) is " << myavg2 << endl; // Average (2) is 9.9e+307
```

(This time however, gcc set average (2) to `#INF`

: http://codepad.org/C5CTEYHj.)

- Would someone care to explain how this "effect" was achieved?
- Is that a "feature"? Or can I consider this an "unexpected behavior" instead of simply "surprising"?

Thanks

`init`

array?`{9.9e+307,9.9e+307,9.9e+307}`

? – kennytm Apr 19 '11 at 13:06