Spark MLlib - Decision Tree源码分析

时间:2023-03-09 23:17:24
Spark MLlib - Decision Tree源码分析

http://spark.apache.org/docs/latest/mllib-decision-tree.html

以决策树作为开始,因为简单,而且也比较容易用到,当前的boosting或random forest也是常以其为基础的

决策树算法本身参考之前的blog,其实就是贪婪算法,每次切分使得数据变得最为有序

 

那么如何来定义有序或无序?

无序node impurity
Spark MLlib - Decision Tree源码分析

对于分类问题,我们可以用熵entropy或Gini来表示信息的无序程度
对于回归问题,我们用方差Variance来表示无序程度,方差越大,说明数据间差异越大

information gain

用于表示,由父节点划分后得到子节点,所带来的impurity的下降,即有序性的增益

Spark MLlib - Decision Tree源码分析

 

MLib决策树的例子

下面直接看个regression的例子,分类的case,差不多,

import org.apache.spark.mllib.tree.DecisionTree
import org.apache.spark.mllib.util.MLUtils // Load and parse the data file.
// Cache the data since we will use it again to compute training error.
val data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt").cache() // Train a DecisionTree model.
// Empty categoricalFeaturesInfo indicates all features are continuous.
val categoricalFeaturesInfo = Map[Int, Int]()
val impurity = "variance"
val maxDepth = 5
val maxBins = 100 val model = DecisionTree.trainRegressor(data, categoricalFeaturesInfo, impurity,
maxDepth, maxBins) // Evaluate model on training instances and compute training error
val labelsAndPredictions = data.map { point =>
val prediction = model.predict(point.features)
(point.label, prediction)
}
val trainMSE = labelsAndPredictions.map{ case(v, p) => math.pow((v - p), 2)}.mean()
println("Training Mean Squared Error = " + trainMSE)
println("Learned regression tree model:\n" + model)

还是比较简单的,

由于是回归,所以impurity的定义为variance

maxDepth,最大树深,设为5

maxBins,最大的划分数

先理解什么是bin,决策树的算法就是对feature的取值不断的进行划分

对于离散的feature,比较简单,如果有m个值,最多Spark MLlib - Decision Tree源码分析 个划分,如果值是有序的,那么就最多m-1个划分

比如年龄feature,有老,中,少3个值,如果无序有Spark MLlib - Decision Tree源码分析个,即3种划分,老|中,少;老,中|少;老,少|中

但如果是有序的,即按老,中,少的序,那么只有m-1个,即2种划分,老|中,少;老,中|少

对于连续的feature,其实就是进行范围划分,而划分的点就是split,划分出的区间就是bin

对于连续feature,理论上划分点是无数的,但是出于效率我们总要选取合适的划分点

有个比较常用的方法是取出训练集中该feature出现过的值作为划分点,

但对于分布式数据,取出所有的值进行排序也比较费资源,所以可以采取sample的方式

 

源码分析

首先调用,DecisionTree.trainRegressor,类似调用静态函数(object DecisionTree)

org.apache.spark.mllib.tree.DecisionTree.scala

/**
* Method to train a decision tree model for regression.
*
* @param input Training dataset: RDD of [[org.apache.spark.mllib.regression.LabeledPoint]].
* Labels are real numbers.
* @param categoricalFeaturesInfo Map storing arity of categorical features.
* E.g., an entry (n -> k) indicates that feature n is categorical
* with k categories indexed from 0: {0, 1, ..., k-1}.
* @param impurity Criterion used for information gain calculation.
* Supported values: "variance".
* @param maxDepth Maximum depth of the tree.
* E.g., depth 0 means 1 leaf node; depth 1 means 1 internal node + 2 leaf nodes.
* (suggested value: 5)
* @param maxBins maximum number of bins used for splitting features
* (suggested value: 32)
* @return DecisionTreeModel that can be used for prediction
*/
def trainRegressor(
input: RDD[LabeledPoint],
categoricalFeaturesInfo: Map[Int, Int],
impurity: String,
maxDepth: Int,
maxBins: Int): DecisionTreeModel = {
val impurityType = Impurities.fromString(impurity)
train(input, Regression, impurityType, maxDepth, 0, maxBins, Sort, categoricalFeaturesInfo)
}

调用静态函数train

  def train(
input: RDD[LabeledPoint],
algo: Algo,
impurity: Impurity,
maxDepth: Int,
numClassesForClassification: Int,
maxBins: Int,
quantileCalculationStrategy: QuantileStrategy,
categoricalFeaturesInfo: Map[Int,Int]): DecisionTreeModel = {
val strategy = new Strategy(algo, impurity, maxDepth, numClassesForClassification, maxBins,
quantileCalculationStrategy, categoricalFeaturesInfo)
new DecisionTree(strategy).train(input)
}

可以看到将所有参数封装到Strategy类,然后初始化DecisionTree类对象,继续调用成员函数train

/**
* :: Experimental ::
* A class which implements a decision tree learning algorithm for classification and regression.
* It supports both continuous and categorical features.
* @param strategy The configuration parameters for the tree algorithm which specify the type
* of algorithm (classification, regression, etc.), feature type (continuous,
* categorical), depth of the tree, quantile calculation strategy, etc.
*/
@Experimental
class DecisionTree (private val strategy: Strategy) extends Serializable with Logging { strategy.assertValid() /**
* Method to train a decision tree model over an RDD
* @param input Training data: RDD of [[org.apache.spark.mllib.regression.LabeledPoint]]
* @return DecisionTreeModel that can be used for prediction
*/
def train(input: RDD[LabeledPoint]): DecisionTreeModel = {
// Note: random seed will not be used since numTrees = 1.
val rf = new RandomForest(strategy, numTrees = 1, featureSubsetStrategy = "all", seed = 0)
val rfModel = rf.train(input)
rfModel.trees(0)
} }

可以看到,这里DecisionTree的设计是基于RandomForest的特例,即单颗树的RandomForest

所以调用RandomForest.train(),最终因为只有一棵树,所以取trees(0)

 

org.apache.spark.mllib.tree.RandomForest.scala

重点看下,RandomForest里面的train做了什么?

/**
* Method to train a decision tree model over an RDD
* @param input Training data: RDD of [[org.apache.spark.mllib.regression.LabeledPoint]]
* @return RandomForestModel that can be used for prediction
*/
def train(input: RDD[LabeledPoint]): RandomForestModel = {
//1. metadata
val retaggedInput = input.retag(classOf[LabeledPoint])
val metadata =
DecisionTreeMetadata.buildMetadata(retaggedInput, strategy, numTrees, featureSubsetStrategy) // 2. Find the splits and the corresponding bins (interval between the splits) using a sample
// of the input data.
val (splits, bins) = DecisionTree.findSplitsBins(retaggedInput, metadata) // 3. Bin feature values (TreePoint representation).
// Cache input RDD for speedup during multiple passes.
val treeInput = TreePoint.convertToTreeRDD(retaggedInput, bins, metadata)
val baggedInput = if (numTrees > 1) {
BaggedPoint.convertToBaggedRDD(treeInput, numTrees, seed)
} else {
BaggedPoint.convertToBaggedRDDWithoutSampling(treeInput)
}.persist(StorageLevel.MEMORY_AND_DISK) // set maxDepth and compute memory usage
// depth of the decision tree
// Max memory usage for aggregates
// TODO: Calculate memory usage more precisely.
//........ /*
* The main idea here is to perform group-wise training of the decision tree nodes thus
* reducing the passes over the data from (# nodes) to (# nodes / maxNumberOfNodesPerGroup).
* Each data sample is handled by a particular node (or it reaches a leaf and is not used
* in lower levels).
*/ // FIFO queue of nodes to train: (treeIndex, node)
val nodeQueue = new mutable.Queue[(Int, Node)]()
val rng = new scala.util.Random()
rng.setSeed(seed) // Allocate and queue root nodes.
val topNodes: Array[Node] = Array.fill[Node](numTrees)(Node.emptyNode(nodeIndex = 1))
Range(0, numTrees).foreach(treeIndex => nodeQueue.enqueue((treeIndex, topNodes(treeIndex)))) while (nodeQueue.nonEmpty) {
// Collect some nodes to split, and choose features for each node (if subsampling).
// Each group of nodes may come from one or multiple trees, and at multiple levels.
val (nodesForGroup, treeToNodeToIndexInfo) =
RandomForest.selectNodesToSplit(nodeQueue, maxMemoryUsage, metadata, rng) // 对decision tree没有意义,nodeQueue只有一个node,不需要选 // 4. Choose node splits, and enqueue new nodes as needed.
DecisionTree.findBestSplits(baggedInput, metadata, topNodes, nodesForGroup,
treeToNodeToIndexInfo, splits, bins, nodeQueue, timer)
}
val trees = topNodes.map(topNode => new DecisionTreeModel(topNode, strategy.algo))
RandomForestModel.build(trees)
}

1. DecisionTreeMetadata.buildMetadata

org.apache.spark.mllib.tree.impl.DecisionTreeMetadata.scala

这里生成一些后面需要用到的metadata

最关键的是计算每个feature的bins和splits的数目,

计算bins的数目

    //bins数目最大不能超过训练集中样本的size
val maxPossibleBins = math.min(strategy.maxBins, numExamples).toInt
//设置默认值
val numBins = Array.fill[Int](numFeatures)(maxPossibleBins)
if (numClasses > 2) {
// Multiclass classification
val maxCategoriesForUnorderedFeature =
((math.log(maxPossibleBins / 2 + 1) / math.log(2.0)) + 1).floor.toInt
strategy.categoricalFeaturesInfo.foreach { case (featureIndex, numCategories) =>
// Decide if some categorical features should be treated as unordered features,
// which require 2 * ((1 << numCategories - 1) - 1) bins.
// We do this check with log values to prevent overflows in case numCategories is large.
// The next check is equivalent to: 2 * ((1 << numCategories - 1) - 1) <= maxBins
if (numCategories <= maxCategoriesForUnorderedFeature) {
unorderedFeatures.add(featureIndex)
numBins(featureIndex) = numUnorderedBins(numCategories)
} else {
numBins(featureIndex) = numCategories
}
}
} else {
// Binary classification or regression
strategy.categoricalFeaturesInfo.foreach { case (featureIndex, numCategories) =>
numBins(featureIndex) = numCategories
}
}

其他case,bins数目等于feature的numCategories

对于unordered情况,比较特殊,

/**
* Given the arity of a categorical feature (arity = number of categories),
* return the number of bins for the feature if it is to be treated as an unordered feature.
* There is 1 split for every partitioning of categories into 2 disjoint, non-empty sets;
* there are math.pow(2, arity - 1) - 1 such splits.
* Each split has 2 corresponding bins.
*/
def numUnorderedBins(arity: Int): Int = 2 * ((1 << arity - 1) - 1)

根据bins数目,计算splits

/**
* Number of splits for the given feature.
* For unordered features, there are 2 bins per split.
* For ordered features, there is 1 more bin than split.
*/
def numSplits(featureIndex: Int): Int = if (isUnordered(featureIndex)) {
numBins(featureIndex) >> 1
} else {
numBins(featureIndex) - 1
}

 

2. DecisionTree.findSplitsBins

首先找出每个feature上可能出现的splits和相应的bins,这是后续算法的基础

这里的注释解释了上面如何计算splits和bins数目的算法

a,对于连续数据,对于一个feature,splits = numBins - 1;上面也说了对于连续值,其实splits可以无限的,如何找到numBins - 1个splits,很简单,这里用sample

b,对于离散数据,两个case

    b.1, 无序的feature,用于low-arity(参数较少)的multiclass分类,这种case下划分的可能性比较多,Spark MLlib - Decision Tree源码分析,所以用subsets of categories来作为划分

    b.2, 有序的feature,用于regression,二元分类,或high-arity的多元分类,这种case下划分的可能比较少,m-1,所以用每个category作为划分

/**
* Returns splits and bins for decision tree calculation.
* Continuous and categorical features are handled differently.
*
* Continuous features:
* For each feature, there are numBins - 1 possible splits representing the possible binary
* decisions at each node in the tree.
* This finds locations (feature values) for splits using a subsample of the data.
*
* Categorical features:
* For each feature, there is 1 bin per split.
* Splits and bins are handled in 2 ways:
* (a) "unordered features"
* For multiclass classification with a low-arity feature
* (i.e., if isMulticlass && isSpaceSufficientForAllCategoricalSplits),
* the feature is split based on subsets of categories.
* (b) "ordered features"
* For regression and binary classification,
* and for multiclass classification with a high-arity feature,
* there is one bin per category.
*
* @param input Training data: RDD of [[org.apache.spark.mllib.regression.LabeledPoint]]
* @param metadata Learning and dataset metadata
* @return A tuple of (splits, bins).
* Splits is an Array of [[org.apache.spark.mllib.tree.model.Split]]
* of size (numFeatures, numSplits).
* Bins is an Array of [[org.apache.spark.mllib.tree.model.Bin]]
* of size (numFeatures, numBins).
*/
protected[tree] def findSplitsBins(
input: RDD[LabeledPoint],
metadata: DecisionTreeMetadata): (Array[Array[Split]], Array[Array[Bin]]) = {
val numFeatures = metadata.numFeatures // Sample the input only if there are continuous features.
val hasContinuousFeatures = Range(0, numFeatures).exists(metadata.isContinuous)
val sampledInput = if (hasContinuousFeatures) { // 对于连续特征,取值会比较多,需要做抽样
// Calculate the number of samples for approximate quantile calculation.
val requiredSamples = math.max(metadata.maxBins * metadata.maxBins, 10000) // 抽样数要远大于桶数
val fraction = if (requiredSamples < metadata.numExamples) { // 设置抽样比例
requiredSamples.toDouble / metadata.numExamples
} else {
1.0
}
input.sample(withReplacement = false, fraction, new XORShiftRandom().nextInt()).collect()
} else {
new Array[LabeledPoint](0)
} metadata.quantileStrategy match {
case Sort =>
val splits = new Array[Array[Split]](numFeatures) // 初始化splits和bins
val bins = new Array[Array[Bin]](numFeatures) // Find all splits.
// Iterate over all features.
var featureIndex = 0
while (featureIndex < numFeatures) { // 遍历所有的feature
val numSplits = metadata.numSplits(featureIndex) // 取出前面算出的splits和bins的数目
val numBins = metadata.numBins(featureIndex)
if (metadata.isContinuous(featureIndex)) { // 对于连续的feature
val numSamples = sampledInput.length
splits(featureIndex) = new Array[Split](numSplits)
bins(featureIndex) = new Array[Bin](numBins)
val featureSamples = sampledInput.map(lp => lp.features(featureIndex)).sorted // 从sampledInput里面取出该feature的所有取值,排序
val stride: Double = numSamples.toDouble / metadata.numBins(featureIndex) // 取样数/桶数,决定split(划分)的步长
logDebug("stride = " + stride)
for (splitIndex <- 0 until numSplits) { // 开始划分
val sampleIndex = splitIndex * stride.toInt // 划分数×步长,得到划分所用的sample的index
// Set threshold halfway in between 2 samples.
val threshold = (featureSamples(sampleIndex) + featureSamples(sampleIndex + 1)) / 2.0 // 划分点选取在前后两个sample的均值
splits(featureIndex)(splitIndex) =
new Split(featureIndex, threshold, Continuous, List()) // 创建Split对象
}
bins(featureIndex)(0) = new Bin(new DummyLowSplit(featureIndex, Continuous), // 初始化第一个split,DummyLowSplit,取值是Double.MinValue
splits(featureIndex)(0), Continuous, Double.MinValue)
for (splitIndex <- 1 until numSplits) { // 创建所有的bins
bins(featureIndex)(splitIndex) =
new Bin(splits(featureIndex)(splitIndex - 1), splits(featureIndex)(splitIndex),
Continuous, Double.MinValue)
}
bins(featureIndex)(numSplits) = new Bin(splits(featureIndex)(numSplits - 1), // 初始化最后一个split,DummyHighSplit,取值是Double.MaxValue
new DummyHighSplit(featureIndex, Continuous), Continuous, Double.MinValue)
} else { // 对于分类的feature
// Categorical feature
val featureArity = metadata.featureArity(featureIndex) // 离散特征中的取值个数
if (metadata.isUnordered(featureIndex)) { // 无序的离散特征
// TODO: The second half of the bins are unused. Actually, we could just use
// splits and not build bins for unordered features. That should be part of
// a later PR since it will require changing other code (using splits instead
// of bins in a few places).
// Unordered features
// 2^(maxFeatureValue - 1) - 1 combinations
splits(featureIndex) = new Array[Split](numSplits)
bins(featureIndex) = new Array[Bin](numBins)
var splitIndex = 0
while (splitIndex < numSplits) {
val categories: List[Double] =
extractMultiClassCategories(splitIndex + 1, featureArity)
splits(featureIndex)(splitIndex) =
new Split(featureIndex, Double.MinValue, Categorical, categories)
bins(featureIndex)(splitIndex) = {
if (splitIndex == 0) {
new Bin(
new DummyCategoricalSplit(featureIndex, Categorical),
splits(featureIndex)(0),
Categorical,
Double.MinValue)
} else {
new Bin(
splits(featureIndex)(splitIndex - 1),
splits(featureIndex)(splitIndex),
Categorical,
Double.MinValue)
}
}
splitIndex += 1
}
} else { // 有序的离散特征,不需要事先算,因为splits就等于featureArity
// Ordered features
// Bins correspond to feature values, so we do not need to compute splits or bins
// beforehand. Splits are constructed as needed during training.
splits(featureIndex) = new Array[Split](0)
bins(featureIndex) = new Array[Bin](0)
}
}
featureIndex += 1
}
(splits, bins)
case MinMax =>
throw new UnsupportedOperationException("minmax not supported yet.")
case ApproxHist =>
throw new UnsupportedOperationException("approximate histogram not supported yet.")
}
}

 

3. TreePoint和BaggedPoint

TreePoint是LabeledPoint的内部数据结构,这里需要做转换,

private def labeledPointToTreePoint(
labeledPoint: LabeledPoint,
bins: Array[Array[Bin]],
featureArity: Array[Int],
isUnordered: Array[Boolean]): TreePoint = {
val numFeatures = labeledPoint.features.size
val arr = new Array[Int](numFeatures)
var featureIndex = 0
while (featureIndex < numFeatures) {
arr(featureIndex) = findBin(featureIndex, labeledPoint, featureArity(featureIndex),
isUnordered(featureIndex), bins)
featureIndex += 1
}
new TreePoint(labeledPoint.label, arr) //只是将labeledPoint中的value替换成arr
}

arr是findBin的结果,

这里主要是针对连续特征做处理,将连续的值通过二分查找转换为相应bin的index

对于离散数据,bin等同于featureValue.toInt

BaggedPoint,由于random forest是比较典型的bagging算法,所以需要对训练集做bootstrap sample

而对于decision tree是特殊的单根random forest,所以不需要做抽样

BaggedPoint.convertToBaggedRDDWithoutSampling(treeInput)

其实只是做简单的封装

 

4. DecisionTree.findBestSplits

这段代码写的有点复杂,尤其和randomForest混杂一起

总之,关键在

// find best split for each node
val (split: Split, stats: InformationGainStats, predict: Predict) =
binsToBestSplit(aggStats, splits, featuresForNode, nodes(nodeIndex))
(nodeIndex, (split, stats, predict))
}.collectAsMap()

看看binsToBestSplit的实现,为了清晰一点,我们只看continuous feature

四个参数,

binAggregates: DTStatsAggregator, 就是ImpurityAggregator,给出如果算出impurity的逻辑

splits: Array[Array[Split]], feature对应的splits

featuresForNode: Option[Array[Int]], tree node对应的feature 
node: Node, 哪个tree node

返回值,

(Split, InformationGainStats, Predict),

Split,最优的split对象(包含featureindex和splitindex)

InformationGainStats,该split产生的Gain对象,表明产生多少增益,多大程度降低impurity

Predict,该节点的预测值,对于连续feature就是平均值,看后面的分析

private def binsToBestSplit(
binAggregates: DTStatsAggregator,
splits: Array[Array[Split]],
featuresForNode: Option[Array[Int]],
node: Node): (Split, InformationGainStats, Predict) = {
// For each (feature, split), calculate the gain, and select the best (feature, split).
val (bestSplit, bestSplitStats) =
Range(0, binAggregates.metadata.numFeaturesPerNode).map { featureIndexIdx => //遍历每个feature
//......取出feature对应的splits
// Find best split.
val (bestFeatureSplitIndex, bestFeatureGainStats) =
Range(0, numSplits).map { case splitIdx => //遍历每个splits
val leftChildStats = binAggregates.getImpurityCalculator(nodeFeatureOffset, splitIdx)
val rightChildStats = binAggregates.getImpurityCalculator(nodeFeatureOffset, numSplits)
rightChildStats.subtract(leftChildStats)
predictWithImpurity = Some(predictWithImpurity.getOrElse(
calculatePredictImpurity(leftChildStats, rightChildStats)))
val gainStats = calculateGainForSplit(leftChildStats, //算出gain,InformationGainStats对象
rightChildStats, binAggregates.metadata, predictWithImpurity.get._2)
(splitIdx, gainStats)
}.maxBy(_._2.gain) //找到gain最大的split的index
(splits(featureIndex)(bestFeatureSplitIndex), bestFeatureGainStats)
}
//......省略离散特征的case
}.maxBy(_._2.gain) //找到gain最大的feature的split (bestSplit, bestSplitStats, predictWithImpurity.get._1)
}

 

Predict,这个需要分析一下

predictWithImpurity.get._1,predictWithImpurity元组的第一个元素

calculatePredictImpurity的返回值中的predict

private def calculatePredictImpurity(
leftImpurityCalculator: ImpurityCalculator,
rightImpurityCalculator: ImpurityCalculator): (Predict, Double) = {
val parentNodeAgg = leftImpurityCalculator.copy
parentNodeAgg.add(rightImpurityCalculator)
val predict = calculatePredict(parentNodeAgg)
val impurity = parentNodeAgg.calculate() (predict, impurity)
}
private def calculatePredict(impurityCalculator: ImpurityCalculator): Predict = {
val predict = impurityCalculator.predict
val prob = impurityCalculator.prob(predict)
new Predict(predict, prob)
}

这里predict和impurity有什么不同,可以看出

impurity = ImpurityCalculator.calculate()

predict = ImpurityCalculator.predict

对于连续feature,我们就看Variance的实现,

/**
* Calculate the impurity from the stored sufficient statistics.
*/
def calculate(): Double = Variance.calculate(stats(0), stats(1), stats(2))
@DeveloperApi
override def calculate(count: Double, sum: Double, sumSquares: Double): Double = {
if (count == 0) {
return 0
}
val squaredLoss = sumSquares - (sum * sum) / count
squaredLoss / count
}

从calculate的实现可以看到,impurity求的就是方差, 不是标准差(均方差)

/**
* Prediction which should be made based on the sufficient statistics.
*/
def predict: Double = if (count == 0) {
0
} else {
stats(1) / count
}

predict求的就是平均值