Tommy -- chux and eigenchris, along with the others have provided excellent answers, but if I am looking at your comments correctly, you still seem to be struggling with the nuts-and-bolts of "how would I take this info and then use this in creating a custom float representation where the user specifies the amount of bits for the exponent?" Don't feel bad, it is a clear as mud the first dozen times you go through it. I think I can take a stab at clearing it up.

You are familiar with the IEEE754-Single-Precision-Floating-Point representation of:

```
IEEE-754 Single Precision Floating Point Representation of (13.25)
0 1 0 0 0 0 0 1 0 1 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
|- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -|
|s| exp | mantissa |
```

That the `1-bit sign-bit`

, `8-bit biased exponent`

(in 8-bit excess-127 notation), and the remaining `23-bit mantissa`

.

When you allow the user to choose the number of bits in the exponent, you are going to have to **rework** the exponent notation to work with the new user-chosen limit.

**What will that change?**

So the only thing you need to focus on is `exponent handling`

.

How would you approach this? Recall, the current 8-bit exponent is in what is called **excess-127 notation** (where 127 represents the largest value for `7`

bits allowing any bias to be contained and expressed within the current `8-bit`

limit. If your user chooses 6 bits as the exponent size, then what? You will have to provide a similar method to insure you have a fixed number to represent your new **excess-##** notation that will work within the user limit.

Take a `6-bit`

user limit, then a choice for the unbiased exponent value could be tried as `31`

(the largest values that can be represented in `5-bits`

). To that you could apply the same logic (taking the 13.25 example above). Your binary representation for the number is `1101.01`

to which you move the decimal `3 positions to the left`

to get `1.10101`

which gives you an exponent bias of `3`

.

In your `6-bit exponent`

case you would add `3 + 31`

to obtain your `excess-31 notation`

for the exponent: `100010`

, then put the mantissa in "hidden bit" format (i.e. drop the leading `1`

from `1.10101`

resulting in your new custom Tommy Precision Representation:

```
IEEE-754 Tommy Precision Floating Point Representation of (13.25)
0 1 0 0 0 1 0 1 0 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
|- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -|
|s| exp | mantissa |
```

With `1-bit sign-bit`

, `6-bit biased exponent`

(in 6-bit excess-31 notation), and the remaining `25-bit mantissa`

.

The same rules would apply to reversing the process to get your floating point number back from the above notation. (just using `31`

instead of `127`

to back the bias out of the exponent)

Hopefully this helps in some way. I don't see much else you can do if you are truly going to allow for a user-selected exponent size. Remember, the IEEE-754 standard wasn't something that was guessed at and a lot of good reasoning and trade-offs went into arriving at the 1-8-23 sign-exponent-mantissa layout. However, I think your exercise does a great job at requiring you to firmly understand the standard.

Now totally lost and **not addressed** in this discussion is what effects this would have on the range of numbers that could be represented in this `Custom Precision Floating Point Representation`

. I haven't looked at it, but the primary limitation would seem to be a reduction in the `MAX/MIN`

that could be represented.

`00001100`

. That needs to be shifted over to be`11000000 x 2^-4`

, and then we forget about the leftmost bit (since it's "always" 1) and just say this is`[1]1000000 x 2^-4`

.