# What do 1.#INF00, -1.#IND00 and -1.#IND mean?

I'm messing around with some C code using floats, and I'm getting 1.#INF00, -1.#IND00 and -1.#IND when I try to print floats in the screen. What does those values mean?

I believe that 1.#INF00 means positive infinity, but what about -1.#IND00 and -1.#IND? I also saw sometimes this value: 1.\$NaN which is Not a Number, but what causes those strange values and how can those help me with debugging?

I'm using MinGW which I believe uses IEEE 754 representation for float point numbers.

Can someone list all those invalid values and what they mean?

• It is the way the Microsoft C runtime library formats Infinity and NaN floating point values. MinGW does not have its own CRT, it uses the OS supplied msvcrt.dll. The exact way it looks depends on the printf() format specifier you used, thus the extra zeros, it can even turn into 1.#J. The C99 standard sets the expected output, adopted in VS2015, so this quirk is going to disappear. Aug 16, 2018 at 7:04

• My program just printed out 1.#IND or 1.#INF (on Windows) or nan or inf (on Linux). What happened?
• How can I tell if a number is really a number and not a NaN or an infinity?
• How can I find out more details at runtime about kinds of NaNs and infinities?
• Do you have any sample code to show how this works?

These questions have to do with floating point exceptions. If you get some strange non-numeric output where you're expecting a number, you've either exceeded the finite limits of floating point arithmetic or you've asked for some result that is undefined. To keep things simple, I'll stick to working with the double floating point type. Similar remarks hold for float types.

Debugging 1.#IND, 1.#INF, nan, and inf

If your operation would generate a larger positive number than could be stored in a double, the operation will return 1.#INF on Windows or inf on Linux. Similarly your code will return -1.#INF or -inf if the result would be a negative number too large to store in a double. Dividing a positive number by zero produces a positive infinity and dividing a negative number by zero produces a negative infinity. Example code at the end of this page will demonstrate some operations that produce infinities.

Some operations don't make mathematical sense, such as taking the square root of a negative number. (Yes, this operation makes sense in the context of complex numbers, but a double represents a real number and so there is no double to represent the result.) The same is true for logarithms of negative numbers. Both sqrt(-1.0) and log(-1.0) would return a NaN, the generic term for a "number" that is "not a number". Windows displays a NaN as -1.#IND ("IND" for "indeterminate") while Linux displays nan. Other operations that would return a NaN include 0/0, 0*∞, and ∞/∞. See the sample code below for examples.

In short, if you get 1.#INF or inf, look for overflow or division by zero. If you get 1.#IND or nan, look for illegal operations. Maybe you simply have a bug. If it's more subtle and you have something that is difficult to compute, see Avoiding Overflow, Underflow, and Loss of Precision. That article gives tricks for computing results that have intermediate steps overflow if computed directly.

• I know the OP didn't really ask for this, but as a handy test, `myfloat == myfloat` will return false if you have one of these magic values. Jan 13, 2012 at 10:24
• @tenpn Actually in C++, +infinity==+infinity. Try checking 1.0 / 0.0: `1.#INF00` == `1.#INF00` returns true, `-1.#INF00` == `-1.#INF00` returns true, but `1.#INF00` == `-1.#INF00` is false. Feb 21, 2012 at 17:15
• Not sure about other configurations, but on Windows 7 / Visual studio 2010. float nan = sqrtf(-1.0f); nan == nan; // evaluates to true... in contrary to what tenpn said.. (Comment By Yevgen V)
– Jeff
Aug 10, 2012 at 0:04
• If you can use C++11 have a look at std::isfinite() and the like. If you can use Boost you're lucky as well Sep 11, 2014 at 14:39
• @Jeff that's likely related to optimization. See the relevant docs page. Aug 16, 2018 at 5:46

For anyone wondering about the difference between `-1.#IND00` and `-1.#IND` (which the question specifically asked, and none of the answers address):

`-1.#IND00`

This specifically means a non-zero number divided by zero, e.g. `3.14 / 0` (source)

`-1.#IND` (a synonym for `NaN`)

This means one of four things (see wiki from source):

1) `sqrt` or `log` of a negative number

2) operations where both variables are 0 or infinity, e.g. `0 / 0`

3) operations where at least one variable is already `NaN`, e.g. `NaN * 5`

4) out of range trig, e.g. `arcsin(2)`

As far as debugging (your second question) though, and in developing libraries where you want to check for special input values, you may find the following functions useful in Windows C++:

_isnan(), _isfinite(), and _fpclass()

On Linux/Unix you should find isnan(), isfinite(), isnormal(), isinf(), fpclassify() useful (and you may need to link with libm by using the compiler flag -lm).

For those of you in a .NET environment the following can be a handy way to filter non-numbers out (this example is in VB.NET, but it's probably similar in C#):

``````If Double.IsNaN(MyVariableName) Then
MyVariableName = 0 ' Or whatever you want to do here to "correct" the situation
End If
``````

If you try to use a variable that has a NaN value you will get the following error:

Value was either too large or too small for a Decimal.

• This doesn't detect `1.#INF`. You also need to use `Double.IsInfinity(MyVariableName)` to check for +/- infinity. Jan 25, 2014 at 2:56