# Alternative to loops in R [duplicate]

Possible Duplicate:
Speed up the loop operation in R

I have a few questions regarding loops. I know that R works faster with vectorized calculations, and I would like to change the below code to take advantage of this. Looking into some other answers on the forum the sapply function seems to be able to replace the inside for loop, but I am generating a vector of zeros so there is an error. Tao remains 1000, and I think this is creating the problem.

My primary concern is speed, as I need to create a loop around the entire algorithm and plot in different V and n sizes for some further analysis.

Alternative loop

``````tao = 1000
L = (tao - 1)
n = 10
V = 5
I = 10000
V_s = matrix(rnorm(I), I, 1)
V_b = matrix(rnorm(I), I, 1)

signal <- matrix(0, L, 1)

for( j in (n:L)){

sapply(((j-n+1):j),function (tao) signal[j] = signal[j] + abs(V_s[tao] - V_b[tao]))

signal[j] = (signal[j] / (n * V) )

}
``````

Original loop

``````tao = 1000
L = (tao - 1)
n = 10
V = 5
I = 10000
V_s = matrix(rnorm(I), I, 1)
V_b = matrix(rnorm(I), I, 1)

signal <- matrix(0, L, 1)

for( j in (n:L)){

for( tao in ((j-n+1):j))    {

signal[j] = (signal[j] + abs(V_s[tao] - V_b[tao]))

}
signal[j] = (signal[j] / (n * V) )

}
``````
• Is there a reason you use matrices instead of vectors, whereas V_s, V_b and signal seems to have only one column ? – juba Jan 25 '13 at 10:29
• If you put `browser()` inside the for(tao) loop, you'll be able to inspect the inner workings of the function and see what's going on. – Roman Luštrik Jan 25 '13 at 10:37
• @juba , I used the matrix formatting in a later approach, but essentially yes, it is a vector. – Morten Jan 25 '13 at 10:47
• General advice on speeding up R code: stackoverflow.com/a/8474941/636656 – Ari B. Friedman Jan 25 '13 at 10:58

Using filters, you can do your computation even without any loop (and `sapply` is nothing more than a hidden loop).

``````absdif <- abs(V_s - V_b)
signal <- filter(absdif[1:L], rep(1/(n*V), n), sides=1)
signal[is.na(signal)] <- 0
``````

Understanding what is happening in the second line is not trivial when your not used to filters, though. Let's have a closer look:

First we compute the absolute differences of `V_s` and `V_b`, which you loop uses frequently. Then comes the filter. Your computation is nothing more than summing up the the `n` past values at each time value `j`. Thus, we have something like

``````signal[j] <- sum(absdif[j-n+1:j])
``````

That is exactly what convolution filters do - summing up some values - in the general form by multiplication with some weight. As weight we choose `1/(n*V)`, for all values, which corresponds to the normalization you do in your outer loop. The last argument, `sides=1` simply tells the filter to take values only from the past (`sides=2` would mean `sum(absdif[(j-n/2):(j+n/2)])`).

The last line just fills up the `NA` values at the beginning (where the filter does not have enough data to compute the sum - this equals to skipping the first `n` values).

Finally, some timing:

``````   User      System       total
0.037       0.000       0.037
``````

The solution of juba:

``````   User      System       total
0.007       0.000       0.008
``````

The solution using filters:

``````   User      System       total
0.000       0.000       0.001
``````

Note that the concept of filters is really well researched and can be done incredibly fast.

Edit: As noted in `?filter`, R does not use Fast fourier transform with the standard `filter` command. Usually, FFT is the most efficient way to implement convolutions. However, even this can be done by replacing the filter command with

``````signal <- convolve(absdif[1:L], rep(1/(n*V), n), type='filter')
``````

Note that now the first `n` entries are stripped of instead of set to `NA`. The result is the same, however. Timing this time is of no use - the total time is below the three digit output of `system.time`... However, note the following remark in the R help of `filter`:

convolve(, type="filter") uses the FFT for computations and so may be faster for long filters on univariate series, but it does not return a time series (and so the time alignment is unclear), nor does it handle missing values. filter is faster for a filter of length 100 on a series of length 1000, for example

• Nice solution, didn't know about this use of `filter()`. – juba Jan 25 '13 at 11:13
• +1, although filter is also probably a loop in disguise... – Paul Hiemstra Jan 25 '13 at 11:16
• @PaulHiemstra Maybe, but a very efficient one it seems :) – juba Jan 25 '13 at 11:24
• @Paul Well, vectorization always is just a hidden loop, but with different steps of optimization in between. And filters should be on the same level of optimization than, say, the `abs` operator is. However, while thinking about it, we can still do better. See my edit in a second. – Thilo Jan 25 '13 at 11:27
• Thanks for the answer, I ran your suggestions and received a different output than I was expecting. I should substitute your solution with both my for loops? – Morten Jan 25 '13 at 11:59

Vectorizing calculations doesn't always mean using an *apply function.

For example, you can simplify and speed up things by replacing your second for loop with vector indexing :

``````for(j in (n:L)){
sel <- (j-n+1):j
signal[j] <- sum(abs(V_s[sel] - V_b[sel])) / (n*V)
}
``````

For this solution, the execution time on my system is :

``````utilisateur     système      écoulé
0.008       0.004       0.009
``````

Whereas for your `for` loops it is :

``````utilisateur     système      écoulé
0.06        0.00        0.06
``````

By the way, you should't use the `tao` name for two different things.

• Exactly. Vectorization almost always results in speed improvements. `*apply` functions rarely do. – Ari B. Friedman Jan 25 '13 at 10:57
• This has shortened the processing time significantly, thanks for your help and input. – Morten Jan 25 '13 at 12:26

Assuming your explicit loop is a correct calc, try this:

`````` signal[j]<- signal[j] +
sapply((j-n+1):j,
FUN = function(iter){
abs(V_s[iter] - V_b[iter])
}, V_s = V_s, V_b = V_b)
``````

Note that sapply is returning the iter-th index absolute difference between V_s and V_b. This is then added to signal[j]