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Diffstat (limited to 'examples')
-rw-r--r-- | examples/src/main/scala/org/apache/spark/examples/mllib/LDAExample.scala | 283 |
1 files changed, 283 insertions, 0 deletions
diff --git a/examples/src/main/scala/org/apache/spark/examples/mllib/LDAExample.scala b/examples/src/main/scala/org/apache/spark/examples/mllib/LDAExample.scala new file mode 100644 index 0000000000..f4c545ad70 --- /dev/null +++ b/examples/src/main/scala/org/apache/spark/examples/mllib/LDAExample.scala @@ -0,0 +1,283 @@ +/* + * Licensed to the Apache Software Foundation (ASF) under one or more + * contributor license agreements. See the NOTICE file distributed with + * this work for additional information regarding copyright ownership. + * The ASF licenses this file to You under the Apache License, Version 2.0 + * (the "License"); you may not use this file except in compliance with + * the License. You may obtain a copy of the License at + * + * http://www.apache.org/licenses/LICENSE-2.0 + * + * Unless required by applicable law or agreed to in writing, software + * distributed under the License is distributed on an "AS IS" BASIS, + * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. + * See the License for the specific language governing permissions and + * limitations under the License. + */ + +package org.apache.spark.examples.mllib + +import java.text.BreakIterator + +import scala.collection.mutable + +import scopt.OptionParser + +import org.apache.log4j.{Level, Logger} + +import org.apache.spark.{SparkContext, SparkConf} +import org.apache.spark.mllib.clustering.LDA +import org.apache.spark.mllib.linalg.{Vector, Vectors} +import org.apache.spark.rdd.RDD + + +/** + * An example Latent Dirichlet Allocation (LDA) app. Run with + * {{{ + * ./bin/run-example mllib.LDAExample [options] <input> + * }}} + * If you use it as a template to create your own app, please use `spark-submit` to submit your app. + */ +object LDAExample { + + private case class Params( + input: Seq[String] = Seq.empty, + k: Int = 20, + maxIterations: Int = 10, + docConcentration: Double = -1, + topicConcentration: Double = -1, + vocabSize: Int = 10000, + stopwordFile: String = "", + checkpointDir: Option[String] = None, + checkpointInterval: Int = 10) extends AbstractParams[Params] + + def main(args: Array[String]) { + val defaultParams = Params() + + val parser = new OptionParser[Params]("LDAExample") { + head("LDAExample: an example LDA app for plain text data.") + opt[Int]("k") + .text(s"number of topics. default: ${defaultParams.k}") + .action((x, c) => c.copy(k = x)) + opt[Int]("maxIterations") + .text(s"number of iterations of learning. default: ${defaultParams.maxIterations}") + .action((x, c) => c.copy(maxIterations = x)) + opt[Double]("docConcentration") + .text(s"amount of topic smoothing to use (> 1.0) (-1=auto)." + + s" default: ${defaultParams.docConcentration}") + .action((x, c) => c.copy(docConcentration = x)) + opt[Double]("topicConcentration") + .text(s"amount of term (word) smoothing to use (> 1.0) (-1=auto)." + + s" default: ${defaultParams.topicConcentration}") + .action((x, c) => c.copy(topicConcentration = x)) + opt[Int]("vocabSize") + .text(s"number of distinct word types to use, chosen by frequency. (-1=all)" + + s" default: ${defaultParams.vocabSize}") + .action((x, c) => c.copy(vocabSize = x)) + opt[String]("stopwordFile") + .text(s"filepath for a list of stopwords. Note: This must fit on a single machine." + + s" default: ${defaultParams.stopwordFile}") + .action((x, c) => c.copy(stopwordFile = x)) + opt[String]("checkpointDir") + .text(s"Directory for checkpointing intermediate results." + + s" Checkpointing helps with recovery and eliminates temporary shuffle files on disk." + + s" default: ${defaultParams.checkpointDir}") + .action((x, c) => c.copy(checkpointDir = Some(x))) + opt[Int]("checkpointInterval") + .text(s"Iterations between each checkpoint. Only used if checkpointDir is set." + + s" default: ${defaultParams.checkpointInterval}") + .action((x, c) => c.copy(checkpointInterval = x)) + arg[String]("<input>...") + .text("input paths (directories) to plain text corpora." + + " Each text file line should hold 1 document.") + .unbounded() + .required() + .action((x, c) => c.copy(input = c.input :+ x)) + } + + parser.parse(args, defaultParams).map { params => + run(params) + }.getOrElse { + parser.showUsageAsError + sys.exit(1) + } + } + + private def run(params: Params) { + val conf = new SparkConf().setAppName(s"LDAExample with $params") + val sc = new SparkContext(conf) + + Logger.getRootLogger.setLevel(Level.WARN) + + // Load documents, and prepare them for LDA. + val preprocessStart = System.nanoTime() + val (corpus, vocabArray, actualNumTokens) = + preprocess(sc, params.input, params.vocabSize, params.stopwordFile) + corpus.cache() + val actualCorpusSize = corpus.count() + val actualVocabSize = vocabArray.size + val preprocessElapsed = (System.nanoTime() - preprocessStart) / 1e9 + + println() + println(s"Corpus summary:") + println(s"\t Training set size: $actualCorpusSize documents") + println(s"\t Vocabulary size: $actualVocabSize terms") + println(s"\t Training set size: $actualNumTokens tokens") + println(s"\t Preprocessing time: $preprocessElapsed sec") + println() + + // Run LDA. + val lda = new LDA() + lda.setK(params.k) + .setMaxIterations(params.maxIterations) + .setDocConcentration(params.docConcentration) + .setTopicConcentration(params.topicConcentration) + .setCheckpointInterval(params.checkpointInterval) + if (params.checkpointDir.nonEmpty) { + lda.setCheckpointDir(params.checkpointDir.get) + } + val startTime = System.nanoTime() + val ldaModel = lda.run(corpus) + val elapsed = (System.nanoTime() - startTime) / 1e9 + + println(s"Finished training LDA model. Summary:") + println(s"\t Training time: $elapsed sec") + val avgLogLikelihood = ldaModel.logLikelihood / actualCorpusSize.toDouble + println(s"\t Training data average log likelihood: $avgLogLikelihood") + println() + + // Print the topics, showing the top-weighted terms for each topic. + val topicIndices = ldaModel.describeTopics(maxTermsPerTopic = 10) + val topics = topicIndices.map { case (terms, termWeights) => + terms.zip(termWeights).map { case (term, weight) => (vocabArray(term.toInt), weight) } + } + println(s"${params.k} topics:") + topics.zipWithIndex.foreach { case (topic, i) => + println(s"TOPIC $i") + topic.foreach { case (term, weight) => + println(s"$term\t$weight") + } + println() + } + + } + + /** + * Load documents, tokenize them, create vocabulary, and prepare documents as term count vectors. + * @return (corpus, vocabulary as array, total token count in corpus) + */ + private def preprocess( + sc: SparkContext, + paths: Seq[String], + vocabSize: Int, + stopwordFile: String): (RDD[(Long, Vector)], Array[String], Long) = { + + // Get dataset of document texts + // One document per line in each text file. + val textRDD: RDD[String] = sc.textFile(paths.mkString(",")) + + // Split text into words + val tokenizer = new SimpleTokenizer(sc, stopwordFile) + val tokenized: RDD[(Long, IndexedSeq[String])] = textRDD.zipWithIndex().map { case (text, id) => + id -> tokenizer.getWords(text) + } + tokenized.cache() + + // Counts words: RDD[(word, wordCount)] + val wordCounts: RDD[(String, Long)] = tokenized + .flatMap { case (_, tokens) => tokens.map(_ -> 1L) } + .reduceByKey(_ + _) + wordCounts.cache() + val fullVocabSize = wordCounts.count() + // Select vocab + // (vocab: Map[word -> id], total tokens after selecting vocab) + val (vocab: Map[String, Int], selectedTokenCount: Long) = { + val tmpSortedWC: Array[(String, Long)] = if (vocabSize == -1 || fullVocabSize <= vocabSize) { + // Use all terms + wordCounts.collect().sortBy(-_._2) + } else { + // Sort terms to select vocab + wordCounts.sortBy(_._2, ascending = false).take(vocabSize) + } + (tmpSortedWC.map(_._1).zipWithIndex.toMap, tmpSortedWC.map(_._2).sum) + } + + val documents = tokenized.map { case (id, tokens) => + // Filter tokens by vocabulary, and create word count vector representation of document. + val wc = new mutable.HashMap[Int, Int]() + tokens.foreach { term => + if (vocab.contains(term)) { + val termIndex = vocab(term) + wc(termIndex) = wc.getOrElse(termIndex, 0) + 1 + } + } + val indices = wc.keys.toArray.sorted + val values = indices.map(i => wc(i).toDouble) + + val sb = Vectors.sparse(vocab.size, indices, values) + (id, sb) + } + + val vocabArray = new Array[String](vocab.size) + vocab.foreach { case (term, i) => vocabArray(i) = term } + + (documents, vocabArray, selectedTokenCount) + } +} + +/** + * Simple Tokenizer. + * + * TODO: Formalize the interface, and make this a public class in mllib.feature + */ +private class SimpleTokenizer(sc: SparkContext, stopwordFile: String) extends Serializable { + + private val stopwords: Set[String] = if (stopwordFile.isEmpty) { + Set.empty[String] + } else { + val stopwordText = sc.textFile(stopwordFile).collect() + stopwordText.flatMap(_.stripMargin.split("\\s+")).toSet + } + + // Matches sequences of Unicode letters + private val allWordRegex = "^(\\p{L}*)$".r + + // Ignore words shorter than this length. + private val minWordLength = 3 + + def getWords(text: String): IndexedSeq[String] = { + + val words = new mutable.ArrayBuffer[String]() + + // Use Java BreakIterator to tokenize text into words. + val wb = BreakIterator.getWordInstance + wb.setText(text) + + // current,end index start,end of each word + var current = wb.first() + var end = wb.next() + while (end != BreakIterator.DONE) { + // Convert to lowercase + val word: String = text.substring(current, end).toLowerCase + // Remove short words and strings that aren't only letters + word match { + case allWordRegex(w) if w.length >= minWordLength && !stopwords.contains(w) => + words += w + case _ => + } + + current = end + try { + end = wb.next() + } catch { + case e: Exception => + // Ignore remaining text in line. + // This is a known bug in BreakIterator (for some Java versions), + // which fails when it sees certain characters. + end = BreakIterator.DONE + } + } + words + } + +} |