# What is the internal representation of inf and NaN?

A friend & I were debating how Inf's and NaN's are stored during lunch today.

Take Fortran 90 for example. 4-byte reals can obtain the value of Inf or NaN. How is this stored internally? Presumably, a 4-byte real is a number represented internally by a 32 digit binary number. Are Inf's and NaN's stored as 33 bit binary numbers?

The IEEE single precision floating point standard representation requires a 32 bit word, which may be represented as numbered from 0 to 31, left to right. The first bit is the sign bit, `S`, the next eight bits are the exponent bits, '`E`', and the final 23 bits are the fraction '`F`':

```S EEEEEEEE FFFFFFFFFFFFFFFFFFFFFFF
0 1      8 9                    31
```

The value `V` represented by the word may be determined as follows:

• If `E=255` and `F` is nonzero, then `V=NaN` ("Not a number")
• If `E=255` and `F` is zero and `S` is `1`, then `V=-Infinity`
• If `E=255` and `F` is zero and `S` is `0`, then `V=Infinity`
• If `0<E<255` then `V=(-1)**S * 2 ** (E-127) * (1.F)` where "`1.F`" is intended to represent the binary number created by prefixing F with an implicit leading 1 and a binary point.
• If `E=0` and `F` is nonzero, then `V=(-1)**S * 2 ** (-126) * (0.F)` These are "unnormalized" values.
• If `E=0` and `F` is zero and `S` is `1`, then `V=-0`
• If `E=0` and `F` is zero and `S` is `0`, then `V=0`

Most floating point representations are based upon the IEEE standard, which has set patterns defined for Inf and NaN.