Nothing
R/multi-split.hierarchical.R
In hdi: High-Dimensional Inference
Defines functions
createtree.from.hclust
mssplit.hierarch.testing
update.extinct
getmultadj.fortree
find.onesidedparents
signif.partialFtest
get.signif.clusters
## [Currently unused completely]
get.signif.clusters <- function(tree,
c.test,
extinct)
{
## This is not required anymore
## if(length(extinct)>0)## check if the excting numbers are truly the leafs of extinct branches
## stopifnot(all(unlist(lapply(tree[extinct],function(node) is.na(node$child1) && is.na(node$child2)))))
signif.clusters <- extinct
for(i in c.test) ## TODO w/o for()
{
signif.clusters <- c(signif.clusters,tree[[i]]$parent)
}
## return
unique(signif.clusters)
}
##' Only called from mssplit.hierarch.testing() :
signif.partialFtest <- function(tree,
c,## current cluster to test
x,
y,
split.out,
family)
{
stopifnot((ns <- length(split.out)) >= 1)
pvalue <- numeric(ns)
for(i in 1:ns) {
sel.model <- which(split.out[[i]]$sel.models)
intersection <- intersect(tree[[c]]$vars, sel.model)
if((hasI <- length(intersection) > 0)) {
yt <- y[-split.out[[i]]$split ]
xt <- x[-split.out[[i]]$split,]
}
pvalue[i] <-
## MM speed FIXME: use lm.fit() and pf() {for p-val of F test}
if(!hasI) {
1
} else if(length(intersection)==length(sel.model)) {
## the intersection equals the screened set
anova(lm(yt~1),
lm(yt~xt[,sel.model,drop=FALSE]),## RIGHT? we should only look at what
test="F")$P[2]
} else {
Shat.withoutc <- setdiff(sel.model, tree[[c]]$vars)
anova(lm(yt~xt[, Shat.withoutc, drop=FALSE]),
lm(yt~xt[, sel.model, drop=FALSE]),## RIGHT? we should only look at what
test="F")$P[2]
}
}
## return
pvalue
}
find.onesidedparents <- function(c,
tree,
extinct,
inheritance.enable=TRUE) {
onesidedparents <- c()
if(inheritance.enable && length(extinct)>=1) {
## we assume that all nodes that are part of an extinct branch are in the vector extinct
currentnode <- c
while(TRUE) {
oldnode <- currentnode
currentnode <- tree[[currentnode]]$parent
if(is.na(currentnode)) {
## we reached the top
## no more one sided parents to be found
break
}
if((tree[[currentnode]]$child1 == oldnode || tree[[currentnode]]$child1 %in% extinct) &&
(tree[[currentnode]]$child2 == oldnode || tree[[currentnode]]$child2 %in% extinct)) {
## the current node is a one-sided parent!
onesidedparents <- c(onesidedparents,currentnode)
}
}
}
return(onesidedparents)
}
getmultadj.fortree <- function(tree,
c,
split.out,
extinct,
c.test)
{## we assume here that the c has a parent that is significant
## this should be implicity true in the way we loop over the nodes in the R code
## This approach is not necessarily efficient
one.sided.parents <- find.onesidedparents(c=c,
tree=tree,
extinct=extinct)## find the ancestor nodes where the other branch side is extinct
mC <- numeric(length(split.out))
for(i in 1:length(split.out)) {
sel.model <- which(split.out[[i]]$sel.models)
if(any(tree[[c]]$vars %in% sel.model)) {
mC[i] <- length(sel.model)/length(intersect(tree[[c]]$vars,sel.model))
## Inheritance procedure
for(p in one.sided.parents) {
notextinct.child <- setdiff(c(tree[[p]]$child1,
tree[[p]]$child2),
extinct)
mC[i] <- mC[i] * length(intersect(tree[[notextinct.child]]$vars,sel.model))/
length(intersect(tree[[p]]$vars,sel.model))
}
## Shaeffer improvement
if(!is.na(tree[[c]]$parent)) {
sibling <- setdiff(c(tree[[tree[[c]]$parent]]$child1,
tree[[tree[[c]]$parent]]$child2),
c)
if(sibling %in% c.test) {
## the sibling is a leaf and is not rejected yet
mC[i] <- mC[i] * length(intersect(tree[[c]]$vars,sel.model))/
length(intersect(tree[[tree[[c]]$parent]]$vars,sel.model))
}
}
}else{
mC[i] <- 1
}
}
mC
}
update.extinct <- function(nowextinct,
tree,
c.test,
oldextinct)
{
## with the new extinct cluster, update all parts of the tree that are now extinct
newextinct <- c(nowextinct,oldextinct)
current.node <- nowextinct
while(TRUE) {
## go up in the tree till you find a node with a second child that is not extinct yet
current.node <- tree[[current.node]]$parent
found.notextinct <- (!tree[[current.node]]$child1 %in% newextinct ||
!tree[[current.node]]$child2 %in% newextinct)
if(found.notextinct)
break## stop, this node is not extinct and therefore we are done
## else
## print("We found extra extincts!")
newextinct <- c(newextinct,current.node)
}
if(any(duplicated(newextinct)))
message("we have some duplicates in newextinct")
## return
unique(newextinct)
}
mssplit.hierarch.testing <- function(tree,
hh,
x,
y,
gamma,
split.out,
alpha = 0.05,
family,
verbose=FALSE)
{
## signif.cluster## this is implicitly known since we only go through the cluster points
## of which the parents were possible to reject
## But what to do with the branches that were extinct? need to save them too someway
extinct <- c()
## the current clusters we are about to test
c.test <- 1## the root node
tree.pvals <- matrix(NA,
length(tree),## number of cluster nodes
length(split.out))## number of splits
clusters.tested <- c(1)
pvals.tested <- c(-1)
while(TRUE)
{
found.signif <- FALSE
## loop through the c.test depth first
c.test.new <- c.test## we aren't supposed to change the set we are looping over
for(c in c.test)
{
if(is.na(tree.pvals[c,1]))
{## haven't calculated the p-values yet for this node
pvalues <- signif.partialFtest(tree=tree,
c=c,
y=y,
x=x,
split.out=split.out,
family=family)
tree.pvals[c,] <- pvalues## save them for later, if we get back to the same nodes
}else{
pvalues <- tree.pvals[c,]
}
## Now determine the weights to use to determine significance
## 4.2 INFERENCE OF HIERARCHICALLY ORDERED CLUSTERS OF VARIABLES
mult.adj <- getmultadj.fortree(tree=tree,
c=c,
split.out=split.out,
extinct=extinct,
c.test=c.test.new)
pvalues.adj <- pvalues*mult.adj
## Then do the aggregation as for multisplit
##(Based on multi-split.R code)
##(should extract this as a separate function)
quant.gamma <- quantile(pvalues.adj, gamma) / gamma
if(length(gamma) > 1)
penalty <- (1 - log(min(gamma)))
else
penalty <- 1
pvals.pre <- min(quant.gamma) * penalty
agg.pvalue <- pmin(pvals.pre, 1)
## track the pval
pvals.tested[match(c,clusters.tested)] <- agg.pvalue
if(agg.pvalue <= alpha)## add the children
{## depth first search
if(is.na(tree[[c]]$child1))
{
stopifnot(is.na(tree[[c]]$child2))## the second child should be NA too
## OLD## extinct <- c(extinct,c)
## TODO add all parents of an extinct branch that are extinct too
extinct <- update.extinct(nowextinct=c,
tree=tree,
c.test=c.test.new,
oldextinct=extinct)
}else{
clusters.tested <- c(clusters.tested,
tree[[c]]$child1,
tree[[c]]$child2)
c.test.new <- c(tree[[c]]$child1,
tree[[c]]$child2,
c.test.new)
}
c.test.new <- setdiff(c.test.new,c)## remove the current tested cluster that was found significant from the to test
found.signif <- TRUE
## Note: can optimize the c.test further with the
}
}
## never remove clusters you did not found significant from c.test,
## we will revisit it later potentially
## stop looping through the c.test if we have looped once through c.test and nothing was found significant
c.test <- c.test.new
if(verbose) {
cat("length of c.test:", length(c.test), "\n")
cat("c.test itself:", c.test, "\n")
}
if(!found.signif)
break
}
message("doing final post processing")
## will still have to transform the output to be able to match the one from lowerbound etc.
## out <- list()
## out$c.test <- c.test
## out$extinct <- extinct
## out$tree <- tree
## TODO convert to the lowerbound output thingie and you are done!
## ---- check out the tree plot and verify correctness
## out <- list()
## signif.clusters <- get.signif.clusters(tree=tree,
## c.test=c.test,
## extinct=extinct)
## can we also only return the significant clusters?
clusters <- list()
pval <- list()
leftChild <- list()
rightChild <- list()
k <- 0
## we somehow need to all clusters we have tested
## OLDOLDOLD
## for(i in 1:length(signif.clusters))
## {
## ct <- signif.clusters[i]
## OLDOLDOLD
for(i in 1:length(clusters.tested))
{
ct <- clusters.tested[i]
k <- k+1
clusters[[k]] <- tree[[ct]]$vars
pval[[k]] <- pvals.tested[i]##
## if(ct %in% signif.clusters)
## pval[[k]] <- 0
## else
## pval[[k]] <- 1
leftChild[[k]] <- match(tree[[ct]]$child1,clusters.tested)
rightChild[[k]] <- match(tree[[ct]]$child2,clusters.tested)
## lc <- leftChild[[k]]
## rc <- rightChild[[k]]
## if(!is.na(lc)) {
## k <- k+1
## clusters[[k]] <- tree[[lc]]$vars
## pval[[k]] <- 1## not significant
## leftChild[[k]] <- tree[[lc]]$child1
## rightChild[[k]] <- tree[[lc]]$child2
## }
## if(!is.na(rc)) {
## k <- k+1
## clusters[[k]] <- tree[[rc]]$vars
## pval[[k]] <- 1## not significant
## leftChild[[k]] <- tree[[rc]]$child1
## rightChild[[k]] <- tree[[rc]]$child2
## }
}
lCh <- unlist( leftChild); lCh[is.na(lCh)] <- -1
rCh <- unlist(rightChild); rCh[is.na(rCh)] <- -1
## return
list(
clusters = clusters,
pval = unlist(pval),
leftChild = lCh,
rightChild = rCh,
alpha = alpha,
hh = hh)
## TODO next steps are doing 4.2.1 inheritance procedure
## TODO afterwards try 4.1 exploiting logical relationships Shaffer improvements
}
createtree.from.hclust <- function(hh,
verbose=TRUE)
{## Note: an object oriented approach probably has better performance
p <- length(hh$order)
## the root node
tree <- list()## the implicit numbering is the node number
tree[[1]] <- list(child1=NA,
child2=NA,
parent=NA,
vars=which(cutree(hh,1)==1))## this is equivalent to 1:p but conserves variable names
parent <- rep(1,p)
if(verbose)
cat("Converting the hclust output to a tree data structure\n",
paste0("building the tree is ",0,"% done.\n"))
nn <- 2 ## this is the running node number to add to the tree
for(i in 2:nrow(hh$merge)) {
if(verbose && (i %% round(nrow(hh$merge)/4)==0))
cat("building the tree is ", round(i/round(nrow(hh$merge))*100),"% done.\n")
old.cut <- cutree(hh,i-1)
new.cut <- cutree(hh,i)
tparent <- NA
## find out what cluster has been split up FAST WAY
tparent <- parent[min(which(old.cut!=new.cut))]
c <- (parent==tparent)
## ## Identification approach, clusters themselves
## old.clusters <- split(1:p,old.cut)
## new.clusters <- split(1:p,new.cut)
## ## I actually only have to do this for the clusters of cluster size that is
## ## not in the new clusters :)
## old.table <- table(old.cut)## table(parent)
## new.table <- table(new.cut)
## ## alternative OLD
## old.disappeared <- as.numeric(names(old.table)[old.table==setdiff(old.table,intersect(old.table,new.table))])
## if(length(old.disappeared)==0)
## {## there are duplicate cluster sizes
## ## just check out the duplicate ones
## duplicate.c.sizes <- as.numeric(names(table(old.table))[table(old.table)>1])
## old.disappeared <- NA
## for(d in duplicate.c.sizes)
## {
## if(sum(old.table==d)>sum(new.table==d))
## {
## old.disappeared <- which(old.table==d)
## break
## }
## }
## }
##
## if(length(old.disappeared)==1)
## {
## c <- old.clusters[[old.disappeared]]
## tparent <- unique(parent[c])
## }else{
## for(c in old.clusters[old.disappeared])
## {
## if(any(sapply(sapply(new.clusters,identical,c),isTRUE)))
## {## there is a new cluster identical to the c
## ##==> the cluster c was not split up
## }
## else{
## tparent <- unique(parent[c])
## stopifnot(length(tparent)==1)
## break
## }
## }
## }
browser(expr=is.na(tparent))
browser(expr=(length(tparent)>1))
stopifnot(!is.na(tparent))
## update the parent
stopifnot(is.na(tree[[tparent]]$child1) && is.na(tree[[tparent]]$child2))
tree[[tparent]]$child1 <- nn
tree[[tparent]]$child2 <- nn+1
## create child 1
child1.c <- which(new.cut == unique(new.cut[c])[1])
tree[[nn]] <- list(child1=NA,
child2=NA,
parent=tparent,
vars=child1.c)
parent[child1.c] <- nn
nn <- nn+1
## create child 2
child2.c <- which(new.cut == unique(new.cut[c])[2])
tree[[nn]] <- list(child1=NA,
child2=NA,
parent=tparent,
vars=child2.c)
parent[child2.c] <- nn
nn <- nn+1
}
if(verbose)
cat("building the tree is ",100,"% done.\n", sep="")
tree
} ## {createtree.from.hclust}
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Defines functions createtree.from.hclust mssplit.hierarch.testing update.extinct getmultadj.fortree find.onesidedparents signif.partialFtest get.signif.clusters
## [Currently unused completely]
get.signif.clusters <- function(tree,
c.test,
extinct)
{
## This is not required anymore
## if(length(extinct)>0)## check if the excting numbers are truly the leafs of extinct branches
## stopifnot(all(unlist(lapply(tree[extinct],function(node) is.na(node$child1) && is.na(node$child2)))))
signif.clusters <- extinct
for(i in c.test) ## TODO w/o for()
{
signif.clusters <- c(signif.clusters,tree[[i]]$parent)
}
## return
unique(signif.clusters)
}
##' Only called from mssplit.hierarch.testing() :
signif.partialFtest <- function(tree,
c,## current cluster to test
x,
y,
split.out,
family)
{
stopifnot((ns <- length(split.out)) >= 1)
pvalue <- numeric(ns)
for(i in 1:ns) {
sel.model <- which(split.out[[i]]$sel.models)
intersection <- intersect(tree[[c]]$vars, sel.model)
if((hasI <- length(intersection) > 0)) {
yt <- y[-split.out[[i]]$split ]
xt <- x[-split.out[[i]]$split,]
}
pvalue[i] <-
## MM speed FIXME: use lm.fit() and pf() {for p-val of F test}
if(!hasI) {
1
} else if(length(intersection)==length(sel.model)) {
## the intersection equals the screened set
anova(lm(yt~1),
lm(yt~xt[,sel.model,drop=FALSE]),## RIGHT? we should only look at what
test="F")$P[2]
} else {
Shat.withoutc <- setdiff(sel.model, tree[[c]]$vars)
anova(lm(yt~xt[, Shat.withoutc, drop=FALSE]),
lm(yt~xt[, sel.model, drop=FALSE]),## RIGHT? we should only look at what
test="F")$P[2]
}
}
## return
pvalue
}
find.onesidedparents <- function(c,
tree,
extinct,
inheritance.enable=TRUE) {
onesidedparents <- c()
if(inheritance.enable && length(extinct)>=1) {
## we assume that all nodes that are part of an extinct branch are in the vector extinct
currentnode <- c
while(TRUE) {
oldnode <- currentnode
currentnode <- tree[[currentnode]]$parent
if(is.na(currentnode)) {
## we reached the top
## no more one sided parents to be found
break
}
if((tree[[currentnode]]$child1 == oldnode || tree[[currentnode]]$child1 %in% extinct) &&
(tree[[currentnode]]$child2 == oldnode || tree[[currentnode]]$child2 %in% extinct)) {
## the current node is a one-sided parent!
onesidedparents <- c(onesidedparents,currentnode)
}
}
}
return(onesidedparents)
}
getmultadj.fortree <- function(tree,
c,
split.out,
extinct,
c.test)
{## we assume here that the c has a parent that is significant
## this should be implicity true in the way we loop over the nodes in the R code
## This approach is not necessarily efficient
one.sided.parents <- find.onesidedparents(c=c,
tree=tree,
extinct=extinct)## find the ancestor nodes where the other branch side is extinct
mC <- numeric(length(split.out))
for(i in 1:length(split.out)) {
sel.model <- which(split.out[[i]]$sel.models)
if(any(tree[[c]]$vars %in% sel.model)) {
mC[i] <- length(sel.model)/length(intersect(tree[[c]]$vars,sel.model))
## Inheritance procedure
for(p in one.sided.parents) {
notextinct.child <- setdiff(c(tree[[p]]$child1,
tree[[p]]$child2),
extinct)
mC[i] <- mC[i] * length(intersect(tree[[notextinct.child]]$vars,sel.model))/
length(intersect(tree[[p]]$vars,sel.model))
}
## Shaeffer improvement
if(!is.na(tree[[c]]$parent)) {
sibling <- setdiff(c(tree[[tree[[c]]$parent]]$child1,
tree[[tree[[c]]$parent]]$child2),
c)
if(sibling %in% c.test) {
## the sibling is a leaf and is not rejected yet
mC[i] <- mC[i] * length(intersect(tree[[c]]$vars,sel.model))/
length(intersect(tree[[tree[[c]]$parent]]$vars,sel.model))
}
}
}else{
mC[i] <- 1
}
}
mC
}
update.extinct <- function(nowextinct,
tree,
c.test,
oldextinct)
{
## with the new extinct cluster, update all parts of the tree that are now extinct
newextinct <- c(nowextinct,oldextinct)
current.node <- nowextinct
while(TRUE) {
## go up in the tree till you find a node with a second child that is not extinct yet
current.node <- tree[[current.node]]$parent
found.notextinct <- (!tree[[current.node]]$child1 %in% newextinct ||
!tree[[current.node]]$child2 %in% newextinct)
if(found.notextinct)
break## stop, this node is not extinct and therefore we are done
## else
## print("We found extra extincts!")
newextinct <- c(newextinct,current.node)
}
if(any(duplicated(newextinct)))
message("we have some duplicates in newextinct")
## return
unique(newextinct)
}
mssplit.hierarch.testing <- function(tree,
hh,
x,
y,
gamma,
split.out,
alpha = 0.05,
family,
verbose=FALSE)
{
## signif.cluster## this is implicitly known since we only go through the cluster points
## of which the parents were possible to reject
## But what to do with the branches that were extinct? need to save them too someway
extinct <- c()
## the current clusters we are about to test
c.test <- 1## the root node
tree.pvals <- matrix(NA,
length(tree),## number of cluster nodes
length(split.out))## number of splits
clusters.tested <- c(1)
pvals.tested <- c(-1)
while(TRUE)
{
found.signif <- FALSE
## loop through the c.test depth first
c.test.new <- c.test## we aren't supposed to change the set we are looping over
for(c in c.test)
{
if(is.na(tree.pvals[c,1]))
{## haven't calculated the p-values yet for this node
pvalues <- signif.partialFtest(tree=tree,
c=c,
y=y,
x=x,
split.out=split.out,
family=family)
tree.pvals[c,] <- pvalues## save them for later, if we get back to the same nodes
}else{
pvalues <- tree.pvals[c,]
}
## Now determine the weights to use to determine significance
## 4.2 INFERENCE OF HIERARCHICALLY ORDERED CLUSTERS OF VARIABLES
mult.adj <- getmultadj.fortree(tree=tree,
c=c,
split.out=split.out,
extinct=extinct,
c.test=c.test.new)
pvalues.adj <- pvalues*mult.adj
## Then do the aggregation as for multisplit
##(Based on multi-split.R code)
##(should extract this as a separate function)
quant.gamma <- quantile(pvalues.adj, gamma) / gamma
if(length(gamma) > 1)
penalty <- (1 - log(min(gamma)))
else
penalty <- 1
pvals.pre <- min(quant.gamma) * penalty
agg.pvalue <- pmin(pvals.pre, 1)
## track the pval
pvals.tested[match(c,clusters.tested)] <- agg.pvalue
if(agg.pvalue <= alpha)## add the children
{## depth first search
if(is.na(tree[[c]]$child1))
{
stopifnot(is.na(tree[[c]]$child2))## the second child should be NA too
## OLD## extinct <- c(extinct,c)
## TODO add all parents of an extinct branch that are extinct too
extinct <- update.extinct(nowextinct=c,
tree=tree,
c.test=c.test.new,
oldextinct=extinct)
}else{
clusters.tested <- c(clusters.tested,
tree[[c]]$child1,
tree[[c]]$child2)
c.test.new <- c(tree[[c]]$child1,
tree[[c]]$child2,
c.test.new)
}
c.test.new <- setdiff(c.test.new,c)## remove the current tested cluster that was found significant from the to test
found.signif <- TRUE
## Note: can optimize the c.test further with the
}
}
## never remove clusters you did not found significant from c.test,
## we will revisit it later potentially
## stop looping through the c.test if we have looped once through c.test and nothing was found significant
c.test <- c.test.new
if(verbose) {
cat("length of c.test:", length(c.test), "\n")
cat("c.test itself:", c.test, "\n")
}
if(!found.signif)
break
}
message("doing final post processing")
## will still have to transform the output to be able to match the one from lowerbound etc.
## out <- list()
## out$c.test <- c.test
## out$extinct <- extinct
## out$tree <- tree
## TODO convert to the lowerbound output thingie and you are done!
## ---- check out the tree plot and verify correctness
## out <- list()
## signif.clusters <- get.signif.clusters(tree=tree,
## c.test=c.test,
## extinct=extinct)
## can we also only return the significant clusters?
clusters <- list()
pval <- list()
leftChild <- list()
rightChild <- list()
k <- 0
## we somehow need to all clusters we have tested
## OLDOLDOLD
## for(i in 1:length(signif.clusters))
## {
## ct <- signif.clusters[i]
## OLDOLDOLD
for(i in 1:length(clusters.tested))
{
ct <- clusters.tested[i]
k <- k+1
clusters[[k]] <- tree[[ct]]$vars
pval[[k]] <- pvals.tested[i]##
## if(ct %in% signif.clusters)
## pval[[k]] <- 0
## else
## pval[[k]] <- 1
leftChild[[k]] <- match(tree[[ct]]$child1,clusters.tested)
rightChild[[k]] <- match(tree[[ct]]$child2,clusters.tested)
## lc <- leftChild[[k]]
## rc <- rightChild[[k]]
## if(!is.na(lc)) {
## k <- k+1
## clusters[[k]] <- tree[[lc]]$vars
## pval[[k]] <- 1## not significant
## leftChild[[k]] <- tree[[lc]]$child1
## rightChild[[k]] <- tree[[lc]]$child2
## }
## if(!is.na(rc)) {
## k <- k+1
## clusters[[k]] <- tree[[rc]]$vars
## pval[[k]] <- 1## not significant
## leftChild[[k]] <- tree[[rc]]$child1
## rightChild[[k]] <- tree[[rc]]$child2
## }
}
lCh <- unlist( leftChild); lCh[is.na(lCh)] <- -1
rCh <- unlist(rightChild); rCh[is.na(rCh)] <- -1
## return
list(
clusters = clusters,
pval = unlist(pval),
leftChild = lCh,
rightChild = rCh,
alpha = alpha,
hh = hh)
## TODO next steps are doing 4.2.1 inheritance procedure
## TODO afterwards try 4.1 exploiting logical relationships Shaffer improvements
}
createtree.from.hclust <- function(hh,
verbose=TRUE)
{## Note: an object oriented approach probably has better performance
p <- length(hh$order)
## the root node
tree <- list()## the implicit numbering is the node number
tree[[1]] <- list(child1=NA,
child2=NA,
parent=NA,
vars=which(cutree(hh,1)==1))## this is equivalent to 1:p but conserves variable names
parent <- rep(1,p)
if(verbose)
cat("Converting the hclust output to a tree data structure\n",
paste0("building the tree is ",0,"% done.\n"))
nn <- 2 ## this is the running node number to add to the tree
for(i in 2:nrow(hh$merge)) {
if(verbose && (i %% round(nrow(hh$merge)/4)==0))
cat("building the tree is ", round(i/round(nrow(hh$merge))*100),"% done.\n")
old.cut <- cutree(hh,i-1)
new.cut <- cutree(hh,i)
tparent <- NA
## find out what cluster has been split up FAST WAY
tparent <- parent[min(which(old.cut!=new.cut))]
c <- (parent==tparent)
## ## Identification approach, clusters themselves
## old.clusters <- split(1:p,old.cut)
## new.clusters <- split(1:p,new.cut)
## ## I actually only have to do this for the clusters of cluster size that is
## ## not in the new clusters :)
## old.table <- table(old.cut)## table(parent)
## new.table <- table(new.cut)
## ## alternative OLD
## old.disappeared <- as.numeric(names(old.table)[old.table==setdiff(old.table,intersect(old.table,new.table))])
## if(length(old.disappeared)==0)
## {## there are duplicate cluster sizes
## ## just check out the duplicate ones
## duplicate.c.sizes <- as.numeric(names(table(old.table))[table(old.table)>1])
## old.disappeared <- NA
## for(d in duplicate.c.sizes)
## {
## if(sum(old.table==d)>sum(new.table==d))
## {
## old.disappeared <- which(old.table==d)
## break
## }
## }
## }
##
## if(length(old.disappeared)==1)
## {
## c <- old.clusters[[old.disappeared]]
## tparent <- unique(parent[c])
## }else{
## for(c in old.clusters[old.disappeared])
## {
## if(any(sapply(sapply(new.clusters,identical,c),isTRUE)))
## {## there is a new cluster identical to the c
## ##==> the cluster c was not split up
## }
## else{
## tparent <- unique(parent[c])
## stopifnot(length(tparent)==1)
## break
## }
## }
## }
browser(expr=is.na(tparent))
browser(expr=(length(tparent)>1))
stopifnot(!is.na(tparent))
## update the parent
stopifnot(is.na(tree[[tparent]]$child1) && is.na(tree[[tparent]]$child2))
tree[[tparent]]$child1 <- nn
tree[[tparent]]$child2 <- nn+1
## create child 1
child1.c <- which(new.cut == unique(new.cut[c])[1])
tree[[nn]] <- list(child1=NA,
child2=NA,
parent=tparent,
vars=child1.c)
parent[child1.c] <- nn
nn <- nn+1
## create child 2
child2.c <- which(new.cut == unique(new.cut[c])[2])
tree[[nn]] <- list(child1=NA,
child2=NA,
parent=tparent,
vars=child2.c)
parent[child2.c] <- nn
nn <- nn+1
}
if(verbose)
cat("building the tree is ",100,"% done.\n", sep="")
tree
} ## {createtree.from.hclust}
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