There are many ways to do this in R. Specifically, `by`

, `aggregate`

, `split`

, and `plyr`

, `cast`

, `tapply`

, `data.table`

, and so forth.

Broadly speaking, these problems are of the form split-apply-combine. Hadley Wickham has written a beautiful article that will give you deeper insight into the whole category of problems, and it is well worth reading. His `plyr`

package implements the strategy, and allows for solving problems of the same form but of even greater complexity than this one. It is well worth learning as a general tool for solving data manipulation problems.

Performance is an issue on very large datasets, and for that it is hard to beat solutions based on `data.table`

. If you only deal with medium-sized datasets or smaller, however, taking the time to learn `data.table`

is likely not worth the effort.

Many of the other solutions below do not require any additional packages. Some of them are even fairly fast on medium-large datasets. Their primary disadvantage is either one of metaphor or of flexibility. By metaphor I mean that it is a tool designed for something else being coerced to solve this particular type of problem in a 'clever' way. By flexibility I mean they lack the ability to solve as wide a range of similar problems or to easily produce tidy output.

**Examples**

With **by**:

By is in base R. In its most user-friendly form, it takes in vectors and applies a function to them. However, its output is not in a very manipulable form.

```
res.by <- by( df$speed, df$dive, mean)
> res.by
df$dive: dive1
[1] 0.5790946
--------------------------------------------------------------------------------------------------------
df$dive: dive2
[1] 0.4864489
```

To get around this, for simple uses of `by`

the `as.data.frame`

method in the `taRifx`

library works:

```
library(taRifx)
> as.data.frame(res.by)
IDX1 value
1 dive1 0.6736807
2 dive2 0.4051447
```

Or **aggregate**:

`aggregate`

is in base R. It takes in data.frames, outputs data.frames, and uses a formula interface.

```
> aggregate( speed ~ dive, df, mean )
dive speed
1 dive1 0.5790946
2 dive2 0.4864489
```

Or **split**:

`split`

is also in base R. As the name suggests, it performs only the "split" part of the split-apply-combine strategy. To make the rest work, I'll write a small function that uses `sapply`

for apply-combine. `sapply`

automatically simplifies the result as much as possible. In our case, that means a vector rather than a data.frame, since we've got only 1 dimension of results.

```
splitmean <- function(df) {
s <- split( df, df$dive)
sapply( s, function(x) mean(x$speed) )
}
> splitmean(df)
dive1 dive2
0.5790946 0.4864489
```

Or **plyr**:

Here's what the official page has to say about `plyr`

:

It’s already possible to do this with base R functions (like split and
the apply family of functions), but plyr makes it all a bit easier
with:

- totally consistent names, arguments and outputs
- convenient parallelisation through the foreach package
- input from and output to data.frames, matrices and lists
- progress bars to keep track of long running operations
- built-in error recovery, and informative error messages
- labels that are maintained across all transformations

In other words, if you learn one tool for split-apply-combine manipulation it should be `plyr`

.

```
library(plyr)
res.plyr <- ddply( df, .(dive), function(x) mean(x$speed) )
> res.plyr
dive V1
1 dive1 0.5790946
2 dive2 0.4864489
```

Or **reshape2**:

The `reshape2`

library is not designed with split-apply-combine as its primary focus. Instead, it uses a two-part melt/cast strategy to perform a wide variety of data reshaping tasks. However, since it allows an aggregation function it can be used for this problem. It would not be my first choice for split-apply-combine operations, but its reshaping capabilities are powerful and thus you should learn this package as well.

```
library(reshape2)
> dcast( melt(df), variable ~ dive, mean)
Using dive as id variables
variable dive1 dive2
1 speed 0.5790946 0.4864489
```

Or **data.table**:

```
library(data.table)
dt <- data.table(df)
setkey(dt,dive)
> dt[,mean(speed),by=dive]
dive V1
[1,] dive1 0.5790946
[2,] dive2 0.4864489
```

**Benchmarks**

```
library(microbenchmark)
m <- microbenchmark(
by( df$speed, df$dive, mean),
aggregate( speed ~ dive, df, mean ),
splitmean(df),
ddply( df, .(dive), function(x) mean(x$speed) ),
dcast( melt(df), variable ~ dive, mean),
dt[,mean(speed),by=dive]
)
> m
Unit: microseconds
expr min lq median uq max
1 aggregate(speed ~ dive, df, mean) 1605.643 1684.8465 1737.637 1775.9915 11789.40
2 by(df$speed, df$dive, mean) 541.197 574.7545 585.738 600.6465 11285.62
3 dcast(melt(df), variable ~ dive, mean) 8530.402 8813.4140 8891.369 9052.4820 19821.68
4 ddply(df, .(dive), function(x) mean(x$speed)) 2397.988 2488.1875 2526.845 2561.5525 2709.40
5 dt[, mean(speed), by = dive] 1958.580 2120.1100 2200.713 2228.7730 12237.70
6 splitmean(df) 406.410 428.5130 434.851 441.0425 10385.83
```

As usual, `data.table`

has a little more overhead so comes in about average for small datasets. These are microseconds, though, so the differences are trivial. Any of the approaches works fine here, and you should choose based on:

- What you're already familiar with or want to be familiar with (
`plyr`

is always worth learning for its flexibility; `data.table`

is worth learning if you plan to analyze huge datasets; `by`

and `aggregate`

and `split`

are all base R functions and thus universally available)
- What output it returns (numeric, data.frame, or data.table -- the latter of which inherits from data.frame)

But what if we have a big dataset? Let's try 10^7 rows split over ten groups.

```
df <- data.frame(dive=factor(sample(letters[1:10],10^7,replace=TRUE)),speed=runif(10^7))
dt <- data.table(df)
setkey(dt,dive)
m <- microbenchmark(
by( df$speed, df$dive, mean),
aggregate( speed ~ dive, df, mean ),
splitmean(df),
ddply( df, .(dive), function(x) mean(x$speed) ),
dcast( melt(df), variable ~ dive, mean),
dt[,mean(speed),by=dive],
times=2
)
> m
Unit: milliseconds
expr min lq median uq max
1 aggregate(speed ~ dive, df, mean) 13659.9110 13659.9110 14297.3680 14934.8249 14934.8249
2 by(df$speed, df$dive, mean) 4360.3613 4360.3613 4430.0481 4499.7349 4499.7349
3 dcast(melt(df), variable ~ dive, mean) 35475.4970 35475.4970 37486.6646 39497.8322 39497.8322
4 ddply(df, .(dive), function(x) mean(x$speed)) 2677.5361 2677.5361 2970.7232 3263.9104 3263.9104
5 dt[, mean(speed), by = dive] 130.9694 130.9694 135.4456 139.9218 139.9218
6 splitmean(df) 1199.3081 1199.3081 1214.6454 1229.9826 1229.9826
```

autoplot(m)

Then `data.table`

is clearly the way to go.

If you have more groups, the difference becomes more pronounced. With **1,000 groups** and the same 10^7 rows:

```
df <- data.frame(dive=factor(sample(seq(1000),10^7,replace=TRUE)),speed=runif(10^7))
dt <- data.table(df)
setkey(dt,dive)
# then run the same microbenchmark as above
Unit: milliseconds
expr min lq median uq max
1 aggregate(speed ~ dive, df, mean) 17029.8938 17029.8938 17137.8127 17245.7315 17245.7315
2 by(df$speed, df$dive, mean) 4934.1082 4934.1082 4935.0431 4935.9780 4935.9780
3 dcast(melt(df), variable ~ dive, mean) 35298.9326 35298.9326 36683.8644 38068.7962 38068.7962
4 ddply(df, .(dive), function(x) mean(x$speed)) 17369.4667 17369.4667 18043.4250 18717.3833 18717.3833
5 dt[, mean(speed), by = dive] 155.9649 155.9649 158.7881 161.6113 161.6113
6 splitmean(df) 16857.3220 16857.3220 17113.7004 17370.0789 17370.0789
autoplot(m)
```

So `data.table`

continues scaling well. The `split`

/`sapply`

strategy seems to scale poorly in the number of groups (meaning the `split()`

is likely slow and the `sapply`

is fast). `by`

continues to be relatively efficient--at 5 seconds, it's definitely noticeable to the user but for a dataset this large still not unreasonable. Still, if you're routinely working with datasets of this size, `data.table`

is clearly the way to go.