# Grab triangles within a lower triangle

I have the need to grab all the thee element triangles that make up the lower triangle of a symmetric matrix. I can not think of how to grab all these pieces in the order of far left column working down and then next column to the right and so on. I know that the numbe rof mini triangles inside of the lower triangle is:

n = x(x - 1)/2
where: x = nrow(mats[[i]])


Here I've created three matrices with letters (it's easier for me to conceptualize this way) and the elements in the order I'm looking for:

FUN <- function(n) {
matrix(LETTERS[1:(n*n)], n)
}

mats <- lapply(3:5, FUN)


So this is the output I'd like to get (I put it in code rather than output format) for each of the matrices created above:

list(c("B", "C", "F"))

list(c("B", "C", "G"), c("C", "D", "H"), c("G", "H", "L"))

list(c("B", "C", "H"), c("C", "D", "I"), c("D", "E", "J"),
c("H", "I", "N"), c("I", "J", "O"), c("N", "O", "T"))


How can I do this task in the fastest manner possible while staying in base R?

Not sure if this visual of what I'm after is helpful but it may be:

-
Is a 5x5 matrix the largest that you would expect to have to test? –  Brandon Bertelsen Dec 7 '12 at 5:48
No it could be larger (though I highly doubt it would ever be much larger). –  Tyler Rinker Dec 7 '12 at 5:56
@TylerRinker - I just had to force close my R session while attempting some benchmarking on a 10K * 10K matrix. 1K*1K was a matter of a couple of seconds. I wonder if people out there might have more efficient implementations. –  thelatemail Dec 7 '12 at 6:08

Nice problem! Here is how you can solve it using a bit of recursion (followed by a MUCH simpler version)

triangle <- function(base.idx, mat) {
upper.idx <- base.idx - 1L
right.idx <- base.idx + nrow(mat)
paste(mat[c(upper.idx, base.idx, right.idx)], collapse = " ")
}

get.triangles <- function(mat) {
N <- nrow(mat)
if (N == 3L) {
return(triangle(3L, mat))
} else {
left.idx  <- 3:N
right.mat <- mat[2:N, 2:N]
left.triangles  <- sapply(left.idx, triangle, mat)
right.triangles <- Recall(right.mat)
return(c(left.triangles, right.triangles))
}
}

x <- lapply(mats, get.triangles)

# [[1]]
# [1] "B C F"
#
# [[2]]
# [1] "B C G" "C D H" "G H L"
#
# [[3]]
# [1] "B C H" "C D I" "D E J" "H I N" "I J O" "N O T"


I'll just comment on the output not being exactly as you asked. It is because creating recursive functions that return a flat list are always difficult to work with: somehow you always end up with nested lists...

So the last step should be:

lapply(x, strsplit, split = " ")


and it will be in the same format you asked for.

And here is an even simpler version (forget about recursion!)

get.triangles <- function(mat) {
base.idx  <- seq_along(mat)[row(mat) > col(mat) + 1]
upper.idx <- base.idx - 1L
right.idx <- base.idx + nrow(mat)

lapply(mapply(c, upper.idx, base.idx, right.idx, SIMPLIFY = FALSE),
function(i)mat[i])
}

-
thank you that works very nicely. I will utilize the method without recursion as there's no need to use strsplit (and if it's a numeric matrix no need to use as.numeric). +1 –  Tyler Rinker Dec 7 '12 at 5:10

Edited to add a SIMPLIFY=FALSE which now gives exactly what you want:

Basically, this method gets the indexes of all the top left corners of the triangles that you want and then grabs the [cell below] + [cell below + to the right]. Thrill. One added benefit of this method is that it works for matrix and data.frame objects.

bot.tris <- function(data) {
idx1 <- unlist(sapply((nrow(data)-2):1,function(x) tail(2:(nrow(data)-1),x)))
idx2 <- rep(1:(nrow(data)-2),(nrow(data)-2):1)
mapply(function(x,y) {c(data[x,y],data[x+1,y],data[x+1,y+1])},idx1,idx2,SIMPLIFY=FALSE)
}


And the result:

> result <- lapply(mats,bot.tris)
> str(result)
List of 3
$:List of 1 ..$ : chr [1:3] "B" "C" "F"
$:List of 3 ..$ : chr [1:3] "B" "C" "G"
..$: chr [1:3] "C" "D" "H" ..$ : chr [1:3] "G" "H" "L"
$:List of 6 ..$ : chr [1:3] "B" "C" "H"
..$: chr [1:3] "C" "D" "I" ..$ : chr [1:3] "D" "E" "J"
..$: chr [1:3] "H" "I" "N" ..$ : chr [1:3] "I" "J" "O"
..\$ : chr [1:3] "N" "O" "T"

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This approach is definitely less coding and very easy to understand. I benchmarked both responses and flodel's is faster. Both functions here are faster than what I had (nothing). Thank you for much for tackling the problem. +1 –  Tyler Rinker Dec 7 '12 at 5:20
"Both functions here are faster than what I had (nothing)" - I like that :-) –  thelatemail Dec 7 '12 at 5:22