# How to convert 2+(2/7) to IEEE 754 floating point

Can someone explain to me the steps to convert a number in decimal format (such as 2+(2/7)) into IEEE 754 Floating Point representation? Thanks!

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Are you asking about an arithmetic expression evaluator in assembly code, or what? –  500 - Internal Server Error Apr 21 '11 at 23:46
arithmetic expression –  Casey Flynn Apr 21 '11 at 23:50
You mean other than just `2.0+(2.0/7.0)`? Do you want the binary representation of those numbers in IEEE754 and a description of how the addition and divide works, or something else? –  Chris Dodd Apr 22 '11 at 16:56

First, `2 + 2/7` isn't in what most people would call "decimal format". "Decimal format" would more commonly be used to indicate a number like:

``````2.285714285714285714285714285714285714285714...
``````

Even the `...` is a little bit fast and loose. More commonly, the number would be truncated or rounded to some number of decimal digits:

``````2.2857142857142857
``````

Of course, at this point, it is no longer exactly equal to `2 + 2/7`, but is "close enough" for most uses.

We do something similar to convert a number to a IEEE-754 format; instead of base 10, we begin by writing the number in base 2:

``````10.010010010010010010010010010010010010010010010010010010010010...
``````

Next we "normalize" the number, by writing it in the form `2^e * 1.xxx...` for some exponent `e` (specifically, the digit position of the leading bit of our number):

``````2^1 * 1.0010010010010010010010010010010010010010010010010010010010010...
``````

At this point, we have to choose a specific IEEE-754 format, because we need to know how many digits to keep around. Let's choose "single-precision", which has a 24-bit significand. We round the repeating binary number to 24 bits:

``````2^1 * 1.00100100100100100100100  10010010010010010010010010010010010010...
24 leading bits          bits to be rounded away
``````

Because the trailing bits to be rounded off are larger than `1000...`, the number rounds up to:

``````2^1 * 1.00100100100100100100101
``````

Now, how does this value actually get encoded in IEEE-754 format? The single-precision format has a leading signbit (zero, because the number is positive), followed by eight bits that contain the value `127 + e` in binary, followed by the fractional part of the significand:

``````0 10000000 00100100100100100100101
s exponent fraction of significand
``````

In hexadecimal, this gives `0x40124925`.

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