Just want to summarise the different methods for this.

First, @VincentZoonekynd's solution.
This is very general -- it allows me to apply *any* function to my matrix.
However it is a little slow because I am applying these to matrices of order ~5000x1000x3 and want back out a (5000/kernelSize) x (1000/kernelSize) x 3 image.

First, generate a matrix to test on (I made it smaller so as not to kill my computer whilst testing various methods):

```
sz <- c(1000,300,3)
img <- array(runif(prod(sz)),dim=sz)
kernelSize <- 3
outSz <- c(ceiling(sz[1:2]/kernelSize),3)
FUN <- mean
```

## Method 0: loop

```
############
# METHOD 0 #
############
# Loopy. base standard.
t0 <- system.time({
out0 <- array(NA,dim=outSz)
for ( i in seq(1,sz[1],by=kernelSize) ) {
for ( j in seq(1,sz[2],by=kernelSize) ) {
for ( c in 1:sz[3] ) {
# work out mean in 3x3 window, fancy footwork
# with pmin just to make sure we don't go out of bounds
out0[ ceiling(i/kernelSize), ceiling(j/kernelSize),c ] <-
FUN(img[ pmin(i-1 + 1:kernelSize,sz[1]),
pmin(j-1 + 1:kernelSize,sz[2]),
c])
}
}
}})
```

## Method 1: tapply

```
############
# METHOD 1 #
############
# @Vincent Zoonekynd.
# I can apply *any* function I want. how awesome!
# NOTE: I just realised that there is a slice.index(img,i)
# is the same as his a(img,i) function.
t1 <- system.time({
out1 <- tapply(
img,
list( floor((slice.index(img,1)-1)/kernelSize),
floor((slice.index(img,2)-1)/kernelSize),
slice.index(img,3) ),
FUN )
})
cat('METHOD 0:',t0['elapsed'],'\n')
cat('METHOD 1:',t1['elapsed'],'\n')
cat(all(out0==out1),'\n')
```

This gives:

```
METHOD 0: 13.549
METHOD 1: 19.415
TRUE
```

Which are a bit slow, given that I would like to apply this to bigger `img`

matrices.

What surprised me (at first) was that METHOD 0 (loops) was *faster* than METHOD 1 (`tapply`

).

However, then I remembered that `tapply`

has a reputation for being not much faster than an explicit loop (why is that? I remember reading it somewhere...the function code looks like it might do the for loop anyway, as opposed to calling external code).

I also have this general feeling that `vapply`

and `sapply`

are the fast versions of `apply`

(again, not sure if this is definitively true but I've certainly found so).

## Method 2: vapply

So, I tried to rewrite my loopy version using `vapply`

.
(There's probably a better way to do handle the 3rd dimension, but oh well...).
This basically generates a big list of coordinates into `img`

. The coordinates give the `(i,j)`

of the corner of each `kernelSize*kernelSize`

square.

Then `vapply`

loops through them all and calculates the mean.

```
##########
# METHOD 2
##########
# use 'vapply'
t2 <- system.time({
is <- seq(1,sz[1],by=kernelSize)
js <- seq(1,sz[2],by=kernelSize)
# generate a (nrow*nsize) x 2 array with
# all (i,j) combinations for corners of
# kernelSize*kernelSize squares.
# Do it column-major so we can reshape after.
coords <- cbind( rep.int(is,length(js)), rep(js,each=length(is)) )
out2 <- array(NA,dim=outSz)
for ( c in 1:sz[3] ) {
out2[,,c] <- array(
vapply( 1:nrow(coords), function(i) {
FUN(img[coords[i,1]:pmin(sz[1],coords[i,1]+kernelSize-1),
coords[i,2]:pmin(sz[2],coords[i,2]+kernelSize-1),
c])
}, 0 ),
dim=outSz[1:2] )
}})
cat('METHOD 2:',t2['elapsed'],'\n')
cat(all(out0==out2),'\n')
```

This gives:

```
METHOD 2: 12.627
TRUE
```

So, it is a bit faster than a loop to use `vapply`

(I do feel like I'm not getting as much out of `vapply`

as I could be though...like I'm not using it in the right way).

## Method 3: filter

This still isn't quite fast enough, so I then incorporated the information that I **only want a mean** in each window, and this is basically a convolution of `[ 1/3 1/3 1/3 ]`

with the matrix in each dimension.

This loses the general applicability of applying an arbitrary `FUN`

but gets big speedups in return.

Basically, I make a kernel `[1/3, 1/3, 1/3]`

and convolve it with `img`

twice, once in the x direction and once in the y. Then I only extract every 3rd value (since I wanted non-overlapping windows).

This seems a bit wasteful to me in that I calculate the mean for *every* 3x3 window in my original matrix, instead of just *non-overlapping* windows, but I don't know how to tell R not to calculate those values that I'm going to throw away anyway.

However you have to take a bit of care at the borders -- say there's only a 2x2 patch left over, then the mean is over 4 instead of 9 values.
My current code **doesn't** handle this, but I don't mind if it's just the border that's out, because I'm only doing the downsampling for display purposes.

(It would be nice to fix this one last thing though...)

```
##########
# METHOD 3
##########
# Convolve using `filter`,
# since the mean in a window is just a
# convolution.
t3 <- system.time({
is <- pmin(seq(1,sz[1],by=kernelSize) + floor(kernelSize/2),sz[1]-1)
js <- pmin(seq(1,sz[2],by=kernelSize) + floor(kernelSize/2),sz[2]-1)
out3 <- array(NA,dim=outSz)
for ( c in 1:3 ) {
out3[,,c] <- (t(filter(
t(filter(img[,,c],rep(1,kernelSize))),
rep(1,kernelSize))))[is,js]
}
out3 <- out3/(kernelSize*kernelSize)
})
cat('METHOD 3:',t3['elapsed'],'\n')
cat(sum(out0!=out3),'\n')
```

This returns:

```
METHOD 3: 1.593
300
```

So this method is *by far* the quickest, and the error just along the last column of `out3`

(once per channel), since (I guess) there are border conditions.

`mean`

this is just a convolution (I do have trouble with speed as my arrays are usually ~5000x1000x3 and I want to end up with a 5000/windowSize x 1000/windowSize x 3 image). Just a todo note to myself. – mathematical.coffee Feb 7 '12 at 12:23