# How do you perform floating point arithmetic on two floating point numbers?

Suppose I wanted to add, subtract, and/or multiply the following two floating point numbers that follow the format:

1 bit sign

3 bit exponent (bias 3)

6 bit mantissa

Can someone briefly explain how I would do that? I've tried searching online for helpful resources, but I haven't been able to find anything too intuitive. However, I know the procedure is generally supposed to be very simple. As an example, here are two numbers that I'd like to perform the three operations on:

0 110 010001

1 010 010000

-
What sources did you find, what did you find hard to understand? –  Joni Feb 19 '13 at 7:27
You are mistaken when you say that "the procedure is generally supposed to be very simple". It's not rocket science, but it's not tic-tac-toe either. More complicated than implementing a balanced binary B-tree, for instance. –  TonyK Oct 22 '13 at 19:17

To start, take the significand encoding and prefix it with a “1.”, and write the result with the sign determined by the sign bit. So, for your example numbers, we have:

``````+1.010001
-1.010000
``````

However, these have different scales, because they have different exponents. The exponent of the second one is four less than the first one (0102 compared to 1102). So shift it right by four bits:

``````+1.010001
- .0001010000
``````

Now both significands have the same scale (exponent 1102), so we can perform normal arithmetic, in binary:

``````+1.010001
- .0001010000
_____________
+1.0011000000
``````

Next, round the significand to the available bits (seven). In this case, the trailing bits are zero, so the rounding does not change anything:

``````+1.001100
``````

At this point, we could have a significand that needed more shifting, if it were greater than 2 (102) or less than 1. However, this significand is just where we want it, between 1 and 2. So we can keep the exponent as is (1102).

Convert the sign back to a bit, take the leading “1.” off the significand, and put the bits together:

``````0 110 001100
``````

Exceptions would arise if the number overflowed or underflowed the normal exponent range, but those did not happen here.

-