371 lines
17 KiB
R
371 lines
17 KiB
R
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# Internal function to calculate how many CPU cores are available.
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getCores <- function(){
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cores <- NA
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if (requireNamespace("parallel", quietly = TRUE)){
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cores <- parallel::detectCores()
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}
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if (is.na(cores)){
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message("Unable to detect how many cores are available; defaulting to only using one. Feel free to override this by pre-specifying the cores argument.")
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cores <- 1
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}
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return(cores)
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}
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train.internal <- function(dataset, splitFinder,
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nodeResponseCombiner, forestResponseCombiner, ntree,
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numberOfSplits, mtry, nodeSize, maxNodeDepth,
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splitPureNodes, savePath, savePath.overwrite,
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cores, randomSeed, displayProgress){
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# Some quick checks on parameters
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ntree <- as.integer(ntree)
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numberOfSplits <- as.integer(numberOfSplits)
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mtry <- as.integer(mtry)
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nodeSize <- as.integer(nodeSize)
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maxNodeDepth <- as.integer(maxNodeDepth)
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cores <- as.integer(cores)
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if (ntree <= 0){
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stop("ntree must be strictly positive.")
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}
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if (numberOfSplits < 0){
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stop("numberOfSplits cannot be negative.")
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}
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if (mtry <= 0){
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stop("mtry must be strictly positive. If you want to try all covariates, you can set it to be very large.")
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}
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if (nodeSize <= 0){
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stop("nodeSize must be strictly positive.")
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}
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if (maxNodeDepth <= 0){
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stop("maxNodeDepth must be strictly positive")
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}
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if (cores <= 0){
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stop("cores must be strictly positive")
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}
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if(is.null(savePath.overwrite) | length(savePath.overwrite)==0 | !(savePath.overwrite[1] %in% c("warn", "delete", "merge"))){
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stop("savePath.overwrite must be one of c(\"warn\", \"delete\", \"merge\")")
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}
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if(is.null(splitFinder)){
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splitFinder <- splitFinderDefault(dataset$responses)
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}
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if(is.null(nodeResponseCombiner)){
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nodeResponseCombiner <- nodeResponseCombinerDefault(dataset$responses)
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}
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if(is.null(forestResponseCombiner)){
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forestResponseCombiner <- forestResponseCombinerDefault(dataset$responses)
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}
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if(class(nodeResponseCombiner) != "ResponseCombiner"){
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stop("nodeResponseCombiner must be a ResponseCombiner")
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}
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if(class(splitFinder) != "SplitFinder"){
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stop("splitFinder must be a SplitFinder")
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}
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if(class(forestResponseCombiner) != "ResponseCombiner"){
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stop("forestResponseCombiner must be a ResponseCombiner")
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}
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treeTrainer <- createTreeTrainer(responseCombiner=nodeResponseCombiner,
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splitFinder=splitFinder,
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covariateList=dataset$covariateList,
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numberOfSplits=numberOfSplits,
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nodeSize=nodeSize,
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maxNodeDepth=maxNodeDepth,
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mtry=mtry,
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splitPureNodes=splitPureNodes)
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forestTrainer <- createForestTrainer(treeTrainer=treeTrainer,
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covariateList=dataset$covariateList,
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treeResponseCombiner=forestResponseCombiner,
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dataset=dataset$dataset,
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ntree=ntree,
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randomSeed=randomSeed,
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saveTreeLocation=savePath,
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displayProgress=displayProgress)
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params <- list(
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splitFinder=splitFinder,
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nodeResponseCombiner=nodeResponseCombiner,
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forestResponseCombiner=forestResponseCombiner,
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ntree=ntree,
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numberOfSplits=numberOfSplits,
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mtry=mtry,
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nodeSize=nodeSize,
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splitPureNodes=splitPureNodes,
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maxNodeDepth = maxNodeDepth,
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randomSeed=randomSeed
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)
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# We'll be saving an offline version of the forest
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if(!is.null(savePath)){
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if(file.exists(savePath)){ # we might have to remove the folder or display an error
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if(savePath.overwrite[1] == "warn"){
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stop(paste(savePath, "already exists; will not modify it. Please remove/rename it or set the savePath.overwrite to either 'delete' or 'merge'"))
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} else if(savePath.overwrite[1] == "delete"){
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unlink(savePath)
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}
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}
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if(savePath.overwrite[1] != "merge"){
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dir.create(savePath)
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}
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# First save forest components (so that if the training crashes mid-way through it can theoretically be recovered by the user)
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saveForestComponents(savePath,
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covariateList=dataset$covariateList,
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params=params,
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forestCall=match.call())
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if(cores > 1){
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.jcall(forestTrainer, "V", "trainParallelOnDisk", .object_Optional(), as.integer(cores))
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} else {
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.jcall(forestTrainer, "V", "trainSerialOnDisk", .object_Optional())
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}
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# Need to now load forest trees back into memory
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forest.java <- .jcall(.class_DataUtils, makeResponse(.class_Forest), "loadForest", savePath, forestResponseCombiner$javaObject)
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}
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else{ # save directly into memory
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if(cores > 1){
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forest.java <- .jcall(forestTrainer, makeResponse(.class_Forest), "trainParallelInMemory", .object_Optional(), as.integer(cores))
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} else {
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forest.java <- .jcall(forestTrainer, makeResponse(.class_Forest), "trainSerialInMemory", .object_Optional())
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}
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}
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forestObject <- list(params=params, javaObject=forest.java,
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covariateList=dataset$covariateList, dataset=dataset$dataset)
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class(forestObject) <- "JRandomForest"
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return(forestObject)
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}
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#' Train Random Forests
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#'
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#' Trains the random forest. The type of response the random forest can be
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#' trained on varies depending on the \code{splitFinder},
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#' \code{nodeResponseCombiner}, and the \code{forestResponseCombiner}
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#' parameters. Make sure these are compatible with each other, and with the
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#' response you plug in. \code{splitFinder} should work on the responses you are
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#' providing; \code{nodeResponseCombiner} should combine these responses into
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#' some intermediate product, and \code{forestResponseCombiner} combines these
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#' intermediate products into the final output product. Note that
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#' \code{nodeResponseCombiner} and \code{forestResponseCombiner} can be inferred
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#' from the data (so feel free to not specify them), and \code{splitFinder} can
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#' be inferred but you might want to change its default.
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#'
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#' @param formula You may specify the response and covariates as a formula
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#' instead; make sure the response in the formula is still properly
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#' constructed.
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#' @param data A data.frame containing the columns of the predictors and
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#' responses.
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#' @param splitFinder A split finder that's used to score splits in the random
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#' forest training algorithm. See \code{\link{CompetingRiskSplitFinders}}
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#' or \code{\link{WeightedVarianceSplitFinder}}. If you don't specify one,
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#' this function tries to pick one based on the response. For
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#' \code{\link{CR_Response}} without censor times, it will pick a
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#' \code{\link{LogRankSplitFinder}}; while if censor times were provided it
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#' will pick \code{\link{GrayLogRankSplitFinder}}; for integer or numeric
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#' responses it picks a \code{\link{WeightedVarianceSplitFinder}}.
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#' @param nodeResponseCombiner A response combiner that's used to combine
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#' responses for each terminal node in a tree (regression example; average the
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#' observations in each tree into a single number). See
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#' \code{\link{CR_ResponseCombiner}} or
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#' \code{\link{MeanResponseCombiner}}. If you don't specify one, this function
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#' tries to pick one based on the response. For \code{\link{CR_Response}} it
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#' picks a \code{\link{CR_ResponseCombiner}}; for integer or numeric
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#' responses it picks a \code{\link{MeanResponseCombiner}}.
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#' @param forestResponseCombiner A response combiner that's used to combine
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#' predictions across trees into one final result (regression example; average
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#' the prediction of each tree into a single number). See
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#' \code{\link{CR_FunctionCombiner}} or
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#' \code{\link{MeanResponseCombiner}}. If you don't specify one, this function
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#' tries to pick one based on the response. For \code{\link{CR_Response}} it
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#' picks a \code{\link{CR_FunctionCombiner}}; for integer or numeric
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#' responses it picks a \code{\link{MeanResponseCombiner}}.
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#' @param ntree An integer that specifies how many trees should be trained.
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#' @param numberOfSplits A tuning parameter specifying how many random splits
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#' should be tried for a covariate; a value of 0 means all splits will be
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#' tried (with an exception for factors, who might have too many splits to
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#' feasibly compute).
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#' @param mtry A tuning parameter specifying how many covariates will be
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#' randomly chosen to be tried in the splitting process. This value must be at
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#' least 1.
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#' @param nodeSize The algorithm will not attempt to split a node that has
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#' observations less than 2*\code{nodeSize}; this guarantees that any two
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#' sibling terminal nodes together have an average size of at least
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#' \code{nodeSize}; note that it doesn't guarantee that every node is at least
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#' as large as \code{nodeSize}.
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#' @param maxNodeDepth This parameter is analogous to \code{nodeSize} in that it
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#' controls tree length; by default \code{maxNodeDepth} is an extremely high
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#' number and tree depth is controlled by \code{nodeSize}.
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#' @param splitPureNodes This parameter determines whether the algorithm will
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#' split a pure node. If set to FALSE, then before every split it will check
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#' that every response is the same, and if so, not split. If set to TRUE it
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#' forgoes that check and splits it. Prediction accuracy won't change under
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#' any sensible \code{nodeResponseCombiner}; as all terminal nodes from a
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#' split pure node should give the same prediction, so this parameter only
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#' affects performance. If your response is continuous you'll likely
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#' experience faster train times by setting it to TRUE. Default value is TRUE.
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#' @param savePath If set, this parameter will save each tree of the random
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#' forest in this directory as the forest is trained. Use this parameter if
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#' you need to save memory while training. See also \code{\link{loadForest}}
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#' @param savePath.overwrite This parameter controls the behaviour for what
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#' happens if \code{savePath} is pointing to an existing directory. If set to
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#' \code{warn} (default) then \code{train} refuses to proceed. If set to
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#' \code{delete} then all the contents in that folder are deleted for the new
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#' forest to be trained. Note that all contents are deleted, even those files
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#' not related to \code{largeRCRF}. Use only if you're sure it's safe. If set
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#' to \code{merge}, then the files describing the forest (such as its
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#' parameters) are overwritten but the saved trees are not. The algorithm
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#' assumes (without checking) that the existing trees are from a previous run
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#' and starts from where it left off. This option is useful if recovering from
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#' a crash.
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#' @param cores This parameter specifies how many trees will be simultaneously
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#' trained. By default the package attempts to detect how many cores you have
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#' by using the \code{parallel} package and using all of them. You may specify
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#' a lower number if you wish. It is not recommended to specify a number
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#' greater than the number of available cores as this will hurt performance
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#' with no available benefit.
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#' @param randomSeed This parameter specifies a random seed if reproducible,
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#' deterministic forests are desired.
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#' @param displayProgress A logical indicating whether the progress should be
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#' displayed to console; default is \code{TRUE}. Useful to set to FALSE in
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#' some automated situations.
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#' @export
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#' @return A \code{JRandomForest} object. You may call \code{predict} or
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#' \code{print} on it.
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#' @seealso \code{\link{predict.JRandomForest}}
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#' @note If saving memory is a concern, you can replace \code{covariateData} or
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#' \code{data} with an environment containing one element called \code{data}
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#' as the actual dataset. After the data has been imported into Java, but
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#' before the forest training begins, the dataset in the environment is
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#' deleted, freeing up memory in R.
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#' @examples
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#' # Regression Example
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#' x1 <- rnorm(1000)
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#' x2 <- rnorm(1000)
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#' y <- 1 + x1 + x2 + rnorm(1000)
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#'
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#' data <- data.frame(x1, x2, y)
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#' forest <- train(y ~ x1 + x2, data, WeightedVarianceSplitFinder(),
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#' MeanResponseCombiner(), MeanResponseCombiner(), ntree=100,
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#' numberOfSplits = 5, mtry = 1, nodeSize = 5)
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#'
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#' # Fix x2 to be 0
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#' newData <- data.frame(x1 = seq(from=-2, to=2, by=0.5), x2 = 0)
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#' ypred <- predict(forest, newData)
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#'
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#' plot(ypred ~ newData$x1, type="l")
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#'
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#' # Competing Risk Example
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#' x1 <- abs(rnorm(1000))
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#' x2 <- abs(rnorm(1000))
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#'
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#' T1 <- rexp(1000, rate=x1)
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#' T2 <- rweibull(1000, shape=x1, scale=x2)
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#' C <- rexp(1000)
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#' u <- pmin(T1, T2, C)
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#' delta <- ifelse(u==T1, 1, ifelse(u==T2, 2, 0))
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#'
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#' data <- data.frame(x1, x2)
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#'
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#' forest <- train(CR_Response(delta, u) ~ x1 + x2, data,
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#' LogRankSplitFinder(1:2), CR_ResponseCombiner(1:2),
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#' CR_FunctionCombiner(1:2), ntree=100, numberOfSplits=5,
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#' mtry=1, nodeSize=10)
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#' newData <- data.frame(x1 = c(-1, 0, 1), x2 = 0)
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#' ypred <- predict(forest, newData)
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train <- function(formula, data, splitFinder = NULL, nodeResponseCombiner = NULL,
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forestResponseCombiner = NULL, ntree, numberOfSplits, mtry,
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nodeSize, maxNodeDepth = 100000, splitPureNodes=TRUE, savePath=NULL,
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savePath.overwrite=c("warn", "delete", "merge"), cores = getCores(),
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randomSeed = NULL, displayProgress = TRUE){
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dataset <- processFormula(formula, data)
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forest <- train.internal(dataset, splitFinder = splitFinder,
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nodeResponseCombiner = nodeResponseCombiner,
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forestResponseCombiner = forestResponseCombiner,
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ntree = ntree, numberOfSplits = numberOfSplits,
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mtry = mtry, nodeSize = nodeSize, maxNodeDepth = maxNodeDepth,
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splitPureNodes = splitPureNodes, savePath = savePath,
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savePath.overwrite = savePath.overwrite, cores = cores,
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randomSeed = randomSeed, displayProgress = displayProgress)
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forest$call <- match.call()
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forest$formula <- formula
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return(forest)
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}
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createForestTrainer <- function(treeTrainer,
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covariateList,
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treeResponseCombiner,
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dataset,
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ntree,
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randomSeed,
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saveTreeLocation,
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displayProgress){
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builderClassReturned <- makeResponse(.class_ForestTrainer_Builder)
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builder <- .jcall(.class_ForestTrainer, builderClassReturned, "builder")
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builder <- .jcall(builder, builderClassReturned, "treeTrainer", treeTrainer)
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builder <- .jcall(builder, builderClassReturned, "covariates", covariateList)
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builder <- .jcall(builder, builderClassReturned, "treeResponseCombiner", treeResponseCombiner$javaObject)
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builder <- .jcall(builder, builderClassReturned, "data", dataset)
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builder <- .jcall(builder, builderClassReturned, "ntree", as.integer(ntree))
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builder <- .jcall(builder, builderClassReturned, "displayProgress", displayProgress)
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if(!is.null(randomSeed)){
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builder <- .jcall(builder, builderClassReturned, "randomSeed", .jlong(randomSeed))
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}
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else{
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builder <- .jcall(builder, builderClassReturned, "randomSeed", .jlong(as.integer(Sys.time())))
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}
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if(!is.null(saveTreeLocation)){
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builder <- .jcall(builder, builderClassReturned, "saveTreeLocation", saveTreeLocation)
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}
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forestTrainer <- .jcall(builder, makeResponse(.class_ForestTrainer), "build")
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return(forestTrainer)
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}
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createTreeTrainer <- function(responseCombiner, splitFinder, covariateList, numberOfSplits, nodeSize, maxNodeDepth, mtry, splitPureNodes){
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builderClassReturned <- makeResponse(.class_TreeTrainer_Builder)
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builder <- .jcall(.class_TreeTrainer, builderClassReturned, "builder")
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builder <- .jcall(builder, builderClassReturned, "responseCombiner", responseCombiner$javaObject)
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builder <- .jcall(builder, builderClassReturned, "splitFinder", splitFinder$javaObject)
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builder <- .jcall(builder, builderClassReturned, "covariates", covariateList)
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builder <- .jcall(builder, builderClassReturned, "numberOfSplits", as.integer(numberOfSplits))
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builder <- .jcall(builder, builderClassReturned, "nodeSize", as.integer(nodeSize))
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builder <- .jcall(builder, builderClassReturned, "maxNodeDepth", as.integer(maxNodeDepth))
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builder <- .jcall(builder, builderClassReturned, "mtry", as.integer(mtry))
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builder <- .jcall(builder, builderClassReturned, "checkNodePurity", !splitPureNodes)
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treeTrainer <- .jcall(builder, makeResponse(.class_TreeTrainer), "build")
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return(treeTrainer)
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}
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