# pixel distance on trees

Here is my tree. The first column is an identifier for the branch, where `0` is the trunk, `L` is the first branch on the left and `R` is the first branch on the right. `LL` is the branch on the extreme left after the second bifurcation, etc.. the variable `length` contains the length of each branch.

``````> tree
branch length
1      0     20
2      L     12
3     LL     19
4      R     19
5     RL     12
6    RLL     10
7    RLR     12
8     RR     17
``````

and here is a drawing of this tree Here are two positions on this tree

``````pos1 = tree[3,]; pos1\$length = 12
pos2 = tree[6,]; pos2\$length = 3
``````

I built this algorithm to calculate the shortest distance along the branches between any two points on the tree.

``````distance = function(tree, pos1, pos2){
if (identical(pos1\$branch, pos2\$branch)){Dist=pos1\$length-pos2\$length;return(Dist)}
pos1path = strsplit(pos1\$branch, "")[]
if (pos1path!="0") {pos1path = c("0", pos1path)}
pos2path = strsplit(pos2\$branch, "")[]
if (pos2path!="0") {pos2path = c("0", pos1path)}
CommonTrace="included"; for (i in 1:min(length(pos1path), length(pos2path))) {if (pos1path[i] != pos2path[i]) {CommonTrace = i-1; break}}

if(CommonTrace=="included"){
CommonTrace = min(length(pos1path), length(pos2path))
if (length(pos1path) > length(pos2path)) {longerpos = pos1; shorterpos = pos2; longerpospath = pos1path} else {longerpos = pos2; shorterpos = pos1; longerpospath = pos2path}
distToNode = 0
if ((CommonTrace+1) != length(longerpospath)){
for (i in (CommonTrace+1):(length(longerpospath)-1)){ distToNode = distToNode + tree\$length[tree\$branch == paste(longerpospath[2:i], collapse='')]}
}
Dist = distToNode + longerpos\$length + (tree[tree\$branch == shorterpos\$branch,]\$length-shorterpos\$length)
if (identical(shorterpos, pos1)){Dist=-Dist}
return(Dist)
} else { # if they are sisterbranch
Dist=0
if((CommonTrace+1) != length(pos1path)){
for (i in (CommonTrace+1):(length(pos1path)-1)){ Dist = Dist + tree\$length[tree\$branch == paste(pos1path[2:i], collapse='')]}
}
if((CommonTrace+1) != length(pos2path)){
for (i in (CommonTrace+1):(length(pos2path)-1)){ Dist = Dist + tree\$length[tree\$branch == paste(pos2path[2:i], collapse='')]}
}
Dist = Dist + pos1\$length + pos2\$length # signdistance does not apply!
return(Dist)
}
}
``````

I think the algorithm works fine. I then just loop through all positions of interest.

``````for (i in allpositions){
for (j in allpositions){
mat[i,j] = distance(tree, i, j)
}
}
``````

The issue is that I have very big trees with about 50000 positions and I would like to calculate the distance between any two positions, that is I have several times 50000^2 distances to compute. It takes forever! Can you help me to improve my code?

• Can you show what you have done so far? – Dominic Comtois Mar 27 '15 at 7:08
• Thank you. See edit. – Remi.b Mar 27 '15 at 15:09
• You probably did, but I need to ask... Are you sure you explored all possibilities in terms of packages that could be helpful to do that? I'm thinking maybe igraph or something similar? – Dominic Comtois Mar 27 '15 at 15:47

This is a provisional answer intended to help the OP identify the problem in his algorithm.

I've added `cats` after each loop; Run the code and look at the newly created `tree_cat.txt` file, it will give you hints on where the problems might be. Individual cells in the m matrix (`m[1, 1]` for instance) are written and written over many times. So something is to be checked with the indices.

The good news is that there are 121*121 = 14641 operations of writing in matrix cells. So the problem is really about the indexing used when assigning new matrix values.

``````tree <- read.table(text="branch length
1      0     20
2      L     12
3     LL     19
4      R     19
5     RL     12
6    RLL     10
7    RLR     12

m = matrix(0, ncol=sum(tree\$length), nrow=sum(tree\$length))
catn <- function(...) cat(..., "\n")
capture.output(
for (originbranch in 1:nrow(tree)) {
catn("originbranch = ", originbranch)
for (originpatch in 1:tree\$length[originbranch]) {
catn("  originpatch = ", originpatch)
for (destinationbranch in 1:nrow(tree)) {
catn("    destinationbranch = ", destinationbranch)
for (destinationpatch in 1:tree\$length[destinationbranch]){
catn("      destinationpatch = ", destinationpatch)
split_dest = unlist(strsplit(tree\$branch[destinationbranch], ""))
split_orig =  unlist(strsplit(tree\$branch[originbranch], ""))
depth = 0
for (i in 1:min(c(length(split_orig), length(split_dest)))) {
catn("        i = ", i)
if (split_dest[i] == split_orig[i]){
depth = depth + 1
} else {
break
}
}
distdest = 0
distorig = 0
for (upperbranch in depth:length(split_orig)){
catn("        upperbranch_orig = ", upperbranch)
distorig = distorig + tree\$length[tree\$branch == paste(split_orig[1:upperbranch], collapse="")]
}
for (upperbranch in depth:length(split_dest)){
catn("        upperbranch_dest = ", upperbranch)
distdest = distdest + tree\$length[tree\$branch == paste(split_dest[1:upperbranch], collapse="")]
}
distorig = distorig + destinationpatch - tree\$length[originbranch]
distdest = distdest + destinationpatch - tree\$length[destinationbranch]
dist = distorig + distdest
m[originpatch, destinationpatch] = dist ## PROBLEMATIC INDEXING!!
catn(sprintf("        ----->   Matrix element written: m[%d, %d] = %d", originpatch, destinationpatch, dist))
}
}
}
}, file = "tree_cat.txt")
``````

I'm not entirely clear on your concept of pixel distance, but based on my understanding, the code below provides a function pixel_dist which calculates the pixel distance between two pixel points specified along tree branches.

I've used igraph to map your tree to a graph where the branches are graph edges and graph vertices are branch intersections and use the graph functions to do the basic vertex distance calculations.

``````library(igraph)
#  Assign vertex name to tree branch intersections
temp <- gsub("R","1", gsub("L","0",tree\$branch))
temp <- strsplit(temp,split=character(0))
tree\$upper_vert <- sapply(temp, function(x) {n <- length(x);  2^n + 2^((n-1):0)%*%as.numeric(x) }  )
tree\$lower_vert <- as.integer(tree\$upper_vert/2)
tree\$branch[tree\$branch=="0"] <- "trunk"
tree[tree\$branch=="trunk",c("lower_vert","upper_vert")] <- c(0,1)

#  Create graph of tree
tree_graph <- graph.data.frame(tree[,c("lower_vert","upper_vert")], directed=TRUE)    # CORRECTED
E(tree_graph)\$label <- paste(tree\$branch, tree\$length,sep="-")
E(tree_graph)\$branch <- tree\$branch
E(tree_graph)\$length <- tree\$length
E(tree_graph)\$weight <- tree\$length
#
#  assign x & y positions for plotting
#
V(tree_graph)\$y <- as.integer(as.numeric(V(tree_graph)\$name)^.5) + 1
V(tree_graph)["0"]\$y <- 0
V(tree_graph)["1"]\$y <- 1
V(tree_graph)\$x <- as.numeric(V(tree_graph)\$name) - 3*(2^(V(tree_graph)\$y-2)) + .5
V(tree_graph)["0"]\$x <- 0
V(tree_graph)["1"]\$x <- 0
plot(tree_graph)
#
#  calculate distances between vertices
#
vert_dist <- shortest.paths(tree_graph, weights=V(tree_graph)\$length, mode="all")  # distances between vertices
vert_dist_dir <- shortest.paths(tree_graph, weights=V(tree_graph)\$length, mode="in")  # distances between vertices along directed edges ADDED
#
# Calculate distances from end vertex of each edge (branch)
#
edge_node <- get.edges(tree_graph, E(tree_graph))    #  list of vertices for each edge
brnch_dist <- sapply(edge_node[,2], function(x) vert_dist[x, edge_node[,2]])  # distance between end vertex of each edge
colnames(brnch_dist) <- E(tree_graph)\$branch
rownames(brnch_dist) <- E(tree_graph)\$branch

brnch_dist_dir <- sapply(edge_node[,2], function(x) vert_dist_dir[x, edge_node[,2]])  # directed distance between end vertex of each edge - ADDED
colnames(brnch_dist_dir) <- E(tree_graph)\$branch
rownames(brnch_dist_dir) <- E(tree_graph)\$branch
#
# calcuates total pixel distance given branches and pixel distances along branch  # CORRECTED
#
pixel_dist <- function(b1, pix1, b2, pix2, brnch_dist, brnch_dist_dir) {
if(!is.infinite(brnch_dist_dir[b1,b2]) )     #  directed edges same from b1 to b2
pixel_dist <- brnch_dist[b1,b2] - E(tree_graph)[branch== b2]\$length + E(tree_graph)[branch== b1]\$length + pix2 - pix1
else {
if(!is.infinite(brnch_dist_dir[b2,b1]) )   # directed edges same from b2 to b1
pixel_dist <- brnch_dist[b1,b2] + E(tree_graph)[branch== b2]\$length - E(tree_graph)[branch== b1]\$length + pix2 - pix1
else                                         # opposing directed edges
pixel_dist <- brnch_dist[b1,b2] - E(tree_graph)[branch== b2]\$length - E(tree_graph)[branch== b1]\$length + pix2 + pix1
}
return(pixel_dist)
}

pixel_dist(b1="L",pix1=3, b2="R", pix2=5, brnch_dist=brnch_dist, brnch_dist_dir=brnch_dist_dir)
``````

A plot of the tree graph with branch names, lengths, and directions I wasn't clear on how you intended to place pixel distances in a matrix but you could use the pixel_dist function or something like it with the prior code to calculate the matrix values.

# EDIT

The code above has been modified to properly account for edge direction in calculating pixel distance.

• I am sorry if my question is unclear. I'll try to edit it to improve it. I haven't looked at the code yet but I would expect from the command `pixel_dist(b1="L",pix1=3, b2="R", pix2=5, brnch_dist=brnch_dist)` to return `8` and not `22`. It should return 8 because, there is a distance of 5, from pixel2 to the bifurcation and a distance of 3 from the pixel1 to the bifurcation. Thank you – Remi.b Mar 28 '15 at 0:00
• Your comment and example helped to clarify my understanding of pixel distance. I've tried to correct the code to properly account for edge direction and checked a number of cases including your example. It seems to work for cases in which the tree branches are traversed in up only, down only, and up and down directions. – WaltS Mar 28 '15 at 14:28