Given a normalized floating point number f what is the next **normalized** floating point number after/before f.

With bit twiddling, extracting mantissa and exponent I have:

```
next_normalized(double&){
if mantissa is not all ones
maximally denormalize while maintaining equality
add 1 to mantissa
normalize
else
check overflow
set mantissa to 1
add (mantissa size in bits) to exponent.
endif
}
```

But rather than do that can it be done with floating point operations?

As

```
std::numeric_limits<double>::epsilon()
```

is only an error difference in a "neighborhood" of 1. - e.g.:

```
normalized(d+=std::numeric_limits<double>::epsilon()) = d for d large
```

it seems more an error ratio than an error difference, thus my naive intuition is

```
(1.+std::numeric_limits<double>::epsilon())*f //should be the next.
```

And

```
(1.-std::numeric_limits<double>::epsilon())*f //should be the previous.
```

In particular I have 3 questions has anyone done any of the following (for IEEE754):

1)done the error analysis on this issue?

2)proved (or can prove) that for any **normalized** double d

```
(1.+std::numeric_limits<double>::epsilon())*d != d ?
```

3)proved that for any **normalized** double number d no double f exists such that

```
d < f < (1.+std::numeric_limits<double>::epsilon())*d ?
```