IEEE 754 floating point numbers can represent positive or negative
infinity, and *NaN* (not a number). These three values arise from
calculations whose result is undefined or cannot be represented
accurately. You can also deliberately set a floating-point variable to
any of them, which is sometimes useful. Some examples of calculations
that produce infinity or NaN:

1/0 = ∞log (0) = -∞sqrt (-1) = NaN

When a calculation produces any of these values, an exception also occurs; see FP Exceptions.

The basic operations and math functions all accept infinity and NaN and
produce sensible output. Infinities propagate through calculations as
one would expect: for example, *2 + ∞ = ∞*,
*4/∞ = 0*, atan *(∞) = π/2*. NaN, on
the other hand, infects any calculation that involves it. Unless the
calculation would produce the same result no matter what real value
replaced NaN, the result is NaN.

In comparison operations, positive infinity is larger than all values
except itself and NaN, and negative infinity is smaller than all values
except itself and NaN. NaN is *unordered*: it is not equal to,
greater than, or less than anything, *including itself*. ```
x ==
x
```

is false if the value of `x`

is NaN. You can use this to test
whether a value is NaN or not, but the recommended way to test for NaN
is with the `isnan`

function (see Floating-Point Number Classification Functions). In
addition, `<`

, `>`

, `<=`

, and `>=`

will raise an
exception when applied to NaNs.

`math.h` defines macros that allow you to explicitly set a variable
to infinity or NaN.

- Macro:
`float`

**INFINITY**¶ -
An expression representing positive infinity. It is equal to the value produced by mathematical operations like

`1.0 / 0.0`

.`-INFINITY`

represents negative infinity.You can test whether a floating-point value is infinite by comparing it to this macro. However, this is not recommended; you should use the

`isfinite`

macro instead. See Floating-Point Number Classification Functions.This macro was introduced in the ISO C99 standard.

- Macro:
`float`

**NAN**¶ -
An expression representing a value which is “not a number”. This macro is a GNU extension, available only on machines that support the “not a number” value—that is to say, on all machines that support IEEE floating point.

You can use ‘

`#ifdef NAN`’ to test whether the machine supports NaN. (Of course, you must arrange for GNU extensions to be visible, such as by defining`_GNU_SOURCE`

, and then you must include`math.h`.)

- Macro:
`float`

**SNANF**¶ - Macro:
`double`

**SNAN**¶ - Macro:
`long double`

**SNANL**¶ - Macro:
`_FloatN`

**SNANFN**¶ - Macro:
`_FloatNx`

**SNANFNx**¶ -
These macros, defined by TS 18661-1:2014 and TS 18661-3:2015, are constant expressions for signaling NaNs.

- Macro:
`int`

**FE_SNANS_ALWAYS_SIGNAL**¶ -
This macro, defined by TS 18661-1:2014, is defined to

`1`

in`fenv.h`to indicate that functions and operations with signaling NaN inputs and floating-point results always raise the invalid exception and return a quiet NaN, even in cases (such as`fmax`

,`hypot`

and`pow`

) where a quiet NaN input can produce a non-NaN result. Because some compiler optimizations may not handle signaling NaNs correctly, this macro is only defined if compiler support for signaling NaNs is enabled. That support can be enabled with the GCC option`-fsignaling-nans`.

IEEE 754 also allows for another unusual value: negative zero. This value is produced when you divide a positive number by negative infinity, or when a negative result is smaller than the limits of representation.