# ctree() - How to get the list of splitting conditions for each terminal node?

I have an output from `ctree()` (`party` package) that looks like the following. How do I get the list of splitting conditions for each terminal node, like like `sns <= 0, dta <= 1; sns <= 0, dta > 1` and so on?

``````1) sns <= 0; criterion = 1, statistic = 14655.021
2) dta <= 1; criterion = 1, statistic = 3286.389
3)*  weights = 153682
2) dta > 1
4)*  weights = 289415
1) sns > 0
5) dta <= 2; criterion = 1, statistic = 1882.439
6)*  weights = 245457
5) dta > 2
7) dta <= 6; criterion = 1, statistic = 1170.813
8)*  weights = 328582
7) dta > 6
``````

Thanks

This function should do the job

`````` CtreePathFunc <- function (ct, data) {

ResulTable <- data.frame(Node = character(), Path = character())

for(Node in unique(where(ct))){
# Taking all possible non-Terminal nodes that are smaller than the selected terminal node
NonTerminalNodes <- setdiff(1:(Node - 1), unique(where(ct))[unique(where(ct)) < Node])

# Getting the weigths for that node
NodeWeights <- nodes(ct, Node)[[1]]\$weights

# Finding the path
Path <- NULL
for (i in NonTerminalNodes){
if(any(NodeWeights & nodes(ct, i)[[1]][2][[1]] == 1)) Path <- append(Path, i)
}

# Finding the splitting creteria for that path
Path2 <- SB <- NULL

for(i in 1:length(Path)){
if(i == length(Path)) {
n <- nodes(ct, Node)[[1]]
} else {n <- nodes(ct, Path[i + 1])[[1]]}

if(all(data[which(as.logical(n\$weights)), as.character(unlist(nodes(ct,Path[i])[[1]][[5]])[length(unlist(nodes(ct,Path[i])[[1]][[5]]))])] <= as.numeric(unlist(nodes(ct,Path[i])[[1]][[5]])[3]))){
SB <- "<="
} else {SB <- ">"}
Path2 <- paste(c(Path2, paste(as.character(unlist(nodes(ct,Path[i])[[1]][[5]])[length(unlist(nodes(ct,Path[i])[[1]][[5]]))]),
SB,
as.character(unlist(nodes(ct,Path[i])[[1]][[5]])[3]))),
collapse = ", ")
}

# Output
ResulTable <- rbind(ResulTable, cbind(Node = Node, Path = Path2))
}
return(ResulTable)
}
``````

Testing

``````library(party)
airq <- subset(airquality, !is.na(Ozone))
ct <- ctree(Ozone ~ ., data = airq,  controls = ctree_control(maxsurrogate = 3))
Result <- CtreePathFunc(ct, airq)
Result

##   Node                               Path
## 1    5 Temp <= 82, Wind > 6.9, Temp <= 77
## 2    3            Temp <= 82, Wind <= 6.9
## 3    6  Temp <= 82, Wind > 6.9, Temp > 77
## 4    9             Temp > 82, Wind > 10.3
## 5    8            Temp > 82, Wind <= 10.3
``````
• +1 for "NonTerminalNodes" get method – Galled Apr 24 '14 at 17:26
• Takes long time, but gives a very good response. And you forgot to put the "airq" matrix as variable. – Galled Jun 3 '14 at 2:18
• Thanks, @Galled. Edited. I also forgot to `library(party)`. It was one of my first answers in SO, so was a bit noob there – David Arenburg Jun 3 '14 at 5:43
• Is there any updated version of this function that also deals with categorical explanatory variables? @DavidArenburg – João Daniel Aug 9 '14 at 21:05
• @JoãoDaniel, I didn't write one. Maybe post a new question and see if someone can elaborate, as I'm not sure I'll have time to write one in the new future – David Arenburg Aug 10 '14 at 7:09

If you use the new recommended `partykit` implementation of `ctree()` rather than the old `party` package, then you can use the function `.list.rules.party()`. This is not yet officially exported, yet, but can be leveraged to extract the desired information.

``````library("partykit")
airq <- subset(airquality, !is.na(Ozone))
ct <- ctree(Ozone ~ ., data = airq)
partykit:::.list.rules.party(ct)
##                                      3                                      5
##             "Temp <= 82 & Wind <= 6.9" "Temp <= 82 & Wind > 6.9 & Temp <= 77"
##                                      6                                      8
##  "Temp <= 82 & Wind > 6.9 & Temp > 77"             "Temp > 82 & Wind <= 10.3"
##                                      9
##              "Temp > 82 & Wind > 10.3"
``````

Due I needed this function but for categorical data, I make, more or less answering the question @JoãoDaniel (I've only tested with categorical predictor variables), the next functions:

``````# returns string w/o leading or trailing whitespace
trim <- function (x) gsub("^\\s+|\\s+\$", "", x)
getVariable <- function (x) sub("(.*?)[[:space:]].*", "\\1", x)
getSimbolo <- function (x) sub("(.*?)[[:space:]](.*?)[[:space:]].*", "\\2", x)

getReglaFinal = function(elemento) {
x = as.data.frame(strsplit(as.character(elemento),";"))
Regla = apply(x,1, trim)
Regla = data.frame(Regla)
indice = as.numeric(rownames(Regla))
variable = apply(Regla,1, getVariable)
simbolo = apply(Regla,1, getSimbolo)

ReglaRaw = data.frame(Regla,indice,variable,simbolo)
cols <- c( 'variable' , 'simbolo' )
ReglaRaw\$tipo_corte <- apply(  ReglaRaw[ , cols ] ,1 , paste , collapse = "" )
#print(ReglaRaw)
cortes = unique(ReglaRaw\$tipo_corte)
#print(cortes)
ReglaFinal = ""
for(i in 1:length(cortes)){
#print("------------------------------------")
#print(cortes[i])
#print(ReglaRaw\$indice[ReglaRaw\$tipo_corte==cortes[i]])
maximo = max(ReglaRaw\$indice[ReglaRaw\$tipo_corte==cortes[i]])
#print(maximo)
tmp = as.character(ReglaRaw\$Regla[ReglaRaw\$indice==maximo])
if(ReglaFinal==""){
ReglaFinal = tmp
}else{
ReglaFinal = paste(ReglaFinal,tmp,sep="; ",collapse="; ")
}
}
return(ReglaFinal)
}#getReglaFinal

CtreePathFuncAllCat <- function (ct) {

ResulTable <- data.frame(Node = character(), Path = character())

for(Node in unique(where(ct))){

# Taking all possible non-Terminal nodes that are smaller than the selected terminal node
NonTerminalNodes <- setdiff(1:(Node - 1), unique(where(ct))[unique(where(ct)) < Node])

# Getting the weigths for that node
NodeWeights <- nodes(ct, Node)[[1]]\$weights

# Finding the path
Path <- NULL
for (i in NonTerminalNodes){
if(any(NodeWeights & nodes(ct, i)[[1]][2][[1]] == 1)) Path <- append(Path, i)
}

# Finding the splitting creteria for that path
Path2 <- SB <- NULL

variablesNombres <- array()
variablesPuntos <- list()

for(i in 1:length(Path)){
n <- nodes(ct, Path[i])[[1]]

if(i == length(Path)) {
nextNodeID = Node
} else {
nextNodeID = Path[i+1]
}

vec_puntos  = as.vector(n[[5]]\$splitpoint)
vec_nombre  = n[[5]]\$variableName
vec_niveles = attr(n[[5]]\$splitpoint,"levels")

index = 0

if((length(vec_puntos)!=length(vec_niveles)) && (length(vec_niveles)!=0) ){
index = vec_puntos
vec_puntos = vector(length=length(vec_niveles))
vec_puntos[index] = TRUE
}

if(length(vec_niveles)==0){
index = vec_puntos
vec_puntos = n[[5]]\$splitpoint
}

if(index==0){
if(nextNodeID==n\$right\$nodeID){
vec_puntos = !vec_puntos
}else{
vec_puntos = !!vec_puntos
}
if(i != 1) {
for(j in 1:(length(Path)-1)){
if(length(variablesNombres)>=j){
if( variablesNombres[j]==vec_nombre){
vec_puntos = vec_puntos*variablesPuntos[[j]]
}
}
}
vec_puntos = vec_puntos==1
}
SB = "="
}else{
if(nextNodeID==n\$right\$nodeID){
SB = ">"
}else{
SB = "<="
}

}

variablesPuntos[[i]] = vec_puntos
variablesNombres[i] = vec_nombre

if(length(vec_niveles)==0){
descripcion = vec_puntos
}else{
descripcion = paste(vec_niveles[vec_puntos],collapse=", ")
}
Path2 <- paste(c(Path2, paste(c(variablesNombres[i],SB,"{",descripcion, "}"),collapse=" ")
),
collapse = "; ")
}

# Output
ResulTable <- rbind(ResulTable, cbind(Node = Node, Path = Path2))
}

we = weights(ct)
c0 = as.matrix(where(ct))
c3 = sapply(we, function(w) sum(w))
c3 = as.matrix(unique(cbind(c0,c3)))
Counts = as.matrix(c3[,2])
c2 = drop(Predict(ct))
Means = as.matrix(unique(c2))

ResulTable = data.frame(ResulTable,Means,Counts)
ResulTable  = ResulTable[ order(ResulTable\$Means) ,]

ResulTable\$TruePath =  apply(as.data.frame(ResulTable\$Path),1, getReglaFinal)

ResulTable2 = ResulTable

ResulTable2\$SQL <- paste("WHEN ",gsub("\\'([-+]?([0-9]*\\.[0-9]+|[0-9]+))\\'", "\\1",gsub("\\, ", "','", gsub(" \\}", "')", gsub("\\{ ", "('", gsub("\\;", " AND ", ResulTable2\$TruePath)))))," THEN ")

cols <- c( 'SQL' , 'Node' )
ResulTable2\$SQL <- apply(  ResulTable2[ , cols ] ,1 , paste , collapse = "'Nodo " )

ResulTable2\$SQL <- gsub("THEN'", "THEN '", gsub(" '", "'",  paste(ResulTable2\$SQL,"'")))

ResultadoFinal\$SQL = paste(" CASE ",paste(ResulTable2\$SQL,sep="",collapse=" ")," END ",collapse="")

}#CtreePathFuncAllCat
``````

Here is a test:

``````library(party)
#With ordered factors
TreeModel1 = ctree(PB~ME+SYMPT+HIST+BSE+DECT, data = mammoexp)
Result2 <- CtreePathFuncAllCat(TreeModel1)
Result2
##\$PreTable
##  Node                                                Path    Means Counts
##3    7    DECT > { Somewhat likely }; SYMPT > { Disagree } 6.526316    114
##2    6   DECT > { Somewhat likely }; SYMPT <= { Disagree } 7.640000    175
##1    4  DECT <= { Somewhat likely }; DECT > { Not likely } 8.161905    105
##4    3 DECT <= { Somewhat likely }; DECT <= { Not likely } 9.833333     18
##                                          TruePath
##3   DECT > { Somewhat likely }; SYMPT > { Disagree }
##2  DECT > { Somewhat likely }; SYMPT <= { Disagree }
##1 DECT <= { Somewhat likely }; DECT > { Not likely }
##4                             DECT <= { Not likely }
##
##\$Table
##  Node                                               Path    Means Counts
##3    7   DECT > { Somewhat likely }; SYMPT > { Disagree } 6.526316    114
##2    6  DECT > { Somewhat likely }; SYMPT <= { Disagree } 7.640000    175
##1    4 DECT <= { Somewhat likely }; DECT > { Not likely } 8.161905    105
##4    3                             DECT <= { Not likely } 9.833333     18
##
##\$SQL
##[1] " CASE  WHEN  DECT > ('Somewhat likely') AND  SYMPT > ('Disagree')  THEN 'Nodo 7' WHEN  DECT > ('Somewhat likely') AND  SYMPT <= ('Disagree')  THEN 'Nodo 6' WHEN  DECT <= ('Somewhat likely') AND  DECT > ('Not likely')  THEN 'Nodo 4' WHEN  DECT <= ('Not likely')  THEN 'Nodo 3'  END "

#With unordered factors
TreeModel2 = ctree(count~spray, data = InsectSprays)
plot(TreeModel2, type="simple")
Result2 <- CtreePathFuncAllCat(TreeModel2)
Result2
##\$PreTable
##Node                                  Path     Means Counts            TruePath
##2    5 spray = { C, D, E }; spray = { C, E }  2.791667     24    spray = { C, E }
##3    4    spray = { C, D, E }; spray = { D }  4.916667     12       spray = { D }
##1    2                   spray = { A, B, F } 15.500000     36 spray = { A, B, F }
##
##\$Table
##Node                Path     Means Counts
##2    5    spray = { C, E }  2.791667     24
##3    4       spray = { D }  4.916667     12
##1    2 spray = { A, B, F } 15.500000     36
##
##\$SQL
##[1] " CASE  WHEN  spray = ('C','E')  THEN 'Nodo 5' WHEN  spray = ('D')  THEN 'Nodo 4' WHEN  spray = ('A','B','F')  THEN 'Nodo 2'  END "

#With continuous variables
airq <- subset(airquality, !is.na(Ozone))
TreeModel3 <- ctree(Ozone ~ ., data = airq,  controls = ctree_control(maxsurrogate = 3))
Result2 <- CtreePathFuncAllCat(TreeModel3)
Result2
##\$PreTable
##  Node                                           Path    Means Counts
##1    5 Temp <= { 82 }; Wind > { 6.9 }; Temp <= { 77 } 18.47917     48
##3    6  Temp <= { 82 }; Wind > { 6.9 }; Temp > { 77 } 31.14286     21
##4    9                 Temp > { 82 }; Wind > { 10.3 } 48.71429      7
##2    3                Temp <= { 82 }; Wind <= { 6.9 } 55.60000     10
##5    8                Temp > { 82 }; Wind <= { 10.3 } 81.63333     30
##                                     TruePath
##1                Temp <= { 77 }; Wind > { 6.9 }
##3 Temp <= { 82 }; Wind > { 6.9 }; Temp > { 77 }
##4                Temp > { 82 }; Wind > { 10.3 }
##2               Temp <= { 82 }; Wind <= { 6.9 }
##5               Temp > { 82 }; Wind <= { 10.3 }
##
##\$Table
##  Node                                          Path    Means Counts
##1    5                Temp <= { 77 }; Wind > { 6.9 } 18.47917     48
##3    6 Temp <= { 82 }; Wind > { 6.9 }; Temp > { 77 } 31.14286     21
##4    9                Temp > { 82 }; Wind > { 10.3 } 48.71429      7
##2    3               Temp <= { 82 }; Wind <= { 6.9 } 55.60000     10
##5    8               Temp > { 82 }; Wind <= { 10.3 } 81.63333     30
##
##\$SQL
##[1] " CASE  WHEN  Temp <= (77) AND  Wind > (6.9)  THEN 'Nodo 5' WHEN  Temp <= (82) AND  Wind > (6.9) AND  Temp > (77)  THEN 'Nodo 6' WHEN  Temp > (82) AND  Wind > (10.3)  THEN 'Nodo 9' WHEN  Temp <= (82) AND  Wind <= (6.9)  THEN 'Nodo 3' WHEN  Temp > (82) AND  Wind <= (10.3)  THEN 'Nodo 8'  END "
``````

Update! Now the function supports mix of categorical and numerical variables!

• Good work with this, however, it only appears to work for categorical variables: When I tried this on the results of the airct tree CtreePathFuncAllCat(ct), it returns the splitting fields, but not the splitting criteria. Any idea how to get the path for categorical and continuous variables? – Chris L Feb 12 '15 at 21:52
• @clevelandfrowns I update the function, and now works with continous and categorical data. – Galled Feb 18 '15 at 20:54

The `CtreePathFunc` function rewritten in more of a Hadley-verse (and I think more comprehensible) way. Also handling categorical variables.

``````library(magrittr)
splitPoint <- nodeSplit\$splitpoint
if("levels" %>% is_in(splitPoint %>% attributes %>% names)){
splitPoint %>% attr("levels") %>% .[splitPoint]
}else{
splitPoint %>% as.numeric
}
}

hasWeigths <- function(ct, path, terminalNode, pathNumber){
ct %>%
nodes(pathNumber %>% equals(path %>% length) %>% ifelse(terminalNode, path[pathNumber + 1]) ) %>%
.[[1]] %>% use_series("weights") %>% as.logical %>% which
}

dataFilter <- function(ct, dts, path, terminalNode, pathNumber){
whichWeights <- hasWeigths(ct, path, terminalNode, pathNumber)
nodes(ct, path[pathNumber])[[1]][[5]] %>%
buildDataFilter(dts, whichWeights)
}

buildDataFilter <- function(nodeSplit, ...) UseMethod("buildDataFilter")

buildDataFilter.nominalSplit <-
function(nodeSplit, dts, whichWeights){
varName <- nodeSplit\$variableName
includedLevels <- dts[ whichWeights
,varName] %>% unique
paste( varName, "=="
,includedLevels %>% paste(collapse = ", ") %>% paste0("{", ., "}"))
}

buildDataFilter.orderedSplit <-
function(nodeSplit, dts, whichWeights){
varName <- nodeSplit\$variableName

dts[ whichWeights
,varName] %>%
is_weakly_less_than(splitter) %>%
all %>%
ifelse("<=" ,">") %>%
paste(varName, ., splitter)
}

readTerminalNodePaths <- function (ct, dts) {

nodeWeights <- function(Node) nodes(ct, Node)[[1]]\$weights
sgmnts <- ct %>% where %>% unique
nodesFirstTreeWeightIsOne <- function(node) nodes(ct, node)[[1]][2][[1]] == 1

# Take the inner nodes smaller than the selected terminal node
innerNodes <-
function(Node) setdiff( 1:(Node - 1)
,sgmnts[sgmnts < Node])
pathForTerminalNode <- function(terminalNode){
innerNodes(terminalNode) %>%
sapply(function(innerNode){
if(any(nodeWeights(terminalNode) & nodesFirstTreeWeightIsOne(innerNode))) innerNode
}) %>%
unlist
}

# Find the splits criteria
sgmnts %>% sapply(function(terminalNode){ #

path <- terminalNode %>% pathForTerminalNode

path %>% length %>% seq %>%
sapply(function(nodeNumber){
dataFilter(ct, dts, path, terminalNode, nodeNumber)
}, simplify = FALSE) %>%
unlist %>% paste(collapse = " & ") %>%
data.frame(Node = terminalNode, Path = .)

}, simplify = FALSE) %>%
Reduce(f = rbind)
}
``````

Testing

``````shiftFirstPart <- function(vctr, divideBy, proportion = .5){
vctr[vctr %>% length %>% multiply_by(proportion) %>% round %>% seq] %<>% divide_by(divideBy)
vctr
}
set.seed(11)
n <- 13000
gdt <-
data.frame( is_buyer = runif(n) %>% shiftFirstPart(1.5) %>% round %>% factor(labels = c("no", "yes"))
,age = runif(n) %>% shiftFirstPart(1.5) %>%
cut(breaks = c(0, .3, .6, 1), include_lowest = TRUE, ordered_result = TRUE, labels = c("low", "mid", "high"))
,city = runif(n) %>% shiftFirstPart(1.5) %>%
cut(breaks = c(0, .3, .6, 1), include_lowest = TRUE, labels = c("Chigaco", "Boston", "Memphis"))
,point = runif(n) %>% shiftFirstPart(1.2)
)

gct <- ctree( is_buyer ~ ., data = gdt)