Let's start with floor( ) and ceiling( ) (which I'm going to call "ceil" from here on). These are basic mathematical functions which map real numbers to integers. Formally, they are defined as follows:

```
floor(x) = max { n in Z | n <= x }
ceil(x) = min { n in Z | n >= x }
```

More plainly, the floor of `x`

is the largest integer that is no bigger than `x`

, and the ceil is the smallest integer that is no smaller than `x`

. Some examples:

`floor(1.5)`

is `1`

.
`ceil(2)`

is `2`

.
`floor(-3.14159)`

is `-4`

.

Consult wikipedia for more details.

Ok, now lets move on to rounding. Every real number x either *is* an integer (in which case `floor(x) == x == ceil(x)`

), or lies between two integers `floor(x) < x < ceil(x)`

. Mathematically, a "rounding rule" is a function `f`

that maps real numbers to integers with the following property: for every real number `x`

, `f(x) = floor(x)`

or `f(x) = ceil(x)`

. This leaves lots of flexibility about which possible result is chosen in any situation, so there are lots of different rounding rules. Here are some examples (these certainly aren't exhaustive):

each of `floor( )`

and `ceil( )`

is a rounding rule.

"round toward zero": simply throw away the fractional part of the input. This is also called *truncation*, and is often written as a mathematical function called `trunc( )`

. It can be defined as `trunc(x) = ceil(x)`

if `x < 0`

, and `trunc(x) = floor(x)`

otherwise*. For example, `trunc(1.5)`

is `1`

and `trunc(-2.7)`

is `-2`

.

"round away from zero" or "round towards infinity": This is the "opposite" of truncation; if `x < 0`

the result is `floor(x)`

, and the result is `ceil(x)`

otherwise. There isn't a common mathematical name for this rule, so I'll just call it `round-away( )`

. Examples: `round-away(1.001)`

is `2`

, and `round-away(-0.7071067812)`

is `-1`

.

"round to odd": If the input `x`

is an integer, return `x`

. Otherwise, look at `floor(x)`

and `ceil(x)`

. Because they are consecutive integers, one of them will be even and the other will be odd. Return the one that is odd. Some examples: `round-to-odd(1.001)`

is `1`

, `round-to-odd(-2.001)`

is `-3`

, and `round-to-odd(4.0)`

is `4.0`

.

"round to nearest, ties to even": This is the default rounding mode of IEEE-754. I would call it `round( )`

, but that name is (rather perversely) used for a different rounding rule in the C library, and I don't want to confuse everyone, so I'll call it `rne( )`

instead here. Here the idea is as follows: if there is a unique integer closest to `x`

, return that integer. Otherwise, `x`

lies exactly halfway between two integers; one of them is even and the other is odd. Return the even one.

This last rule can be written as "RU with fix-up", though that is a somewhat odd way to think of it, mathematically. More commonly, it's formally defined more or less as follows:

```
rne(x) = floor(x) if x - floor(x) < 0.5
floor(x) if x - floor(x) = 0.5 and floor(x) is even.
ceil(x) if x - floor(x) = 0.5 and floor(x) is odd.
ceil(x) if x - floor(x) > 0.5
```

Some examples of this `rne( )`

rule in action: `rne(0.5)`

is `0`

. `rne(-1.5)`

is `-2`

. `rne(1.3)`

is `1`

. `rne(1.8)`

is `2`

.

Ok, so this is all talking about *rounding to integral values*. What does that have to do with rounding to the nearest floating-point number as in IEEE-754? A rounding rule may be used not only to round to integer, but to round to any fixed number of digits as well, by simply scaling it by a factor of `b**n`

, where `b`

is the base of the representation and `n`

is chosen so that the desired rounding point of the number ends up in the units position (the LSB). Of course, we don't actually need to scale the number and un-scale the result; instead we simply replace `ceil(x)`

and `floor(x)`

in the rounding rule with the values of `x`

rounded down and up to the desired number of digits.

[*] I'm defining *mathematical* functions on real numbers here, not giving IEEE-754 implementations. Thus, there's no need to deal with edge cases like `-0`

, `inf`

, or `nan`

.

Handbook of Floating-point Arithmeticby Muller et al. – Eric Postpischil Nov 14 '13 at 14:47