# Feature Extraction and Transformation - RDD-based API

## TF-IDF

Note We recommend using the DataFrame-based API, which is detailed in the ML user guide on TF-IDF.

Term frequency-inverse document frequency (TF-IDF) is a feature vectorization method widely used in text mining to reflect the importance of a term to a document in the corpus. Denote a term by $t$, a document by $d$, and the corpus by $D$. Term frequency $TF(t, d)$ is the number of times that term $t$ appears in document $d$, while document frequency $DF(t, D)$ is the number of documents that contains term $t$. If we only use term frequency to measure the importance, it is very easy to over-emphasize terms that appear very often but carry little information about the document, e.g., “a”, “the”, and “of”. If a term appears very often across the corpus, it means it doesn’t carry special information about a particular document. Inverse document frequency is a numerical measure of how much information a term provides: $IDF(t, D) = \log \frac{|D| + 1}{DF(t, D) + 1},$ where $|D|$ is the total number of documents in the corpus. Since logarithm is used, if a term appears in all documents, its IDF value becomes 0. Note that a smoothing term is applied to avoid dividing by zero for terms outside the corpus. The TF-IDF measure is simply the product of TF and IDF: $TFIDF(t, d, D) = TF(t, d) \cdot IDF(t, D).$ There are several variants on the definition of term frequency and document frequency. In spark.mllib, we separate TF and IDF to make them flexible.

Our implementation of term frequency utilizes the hashing trick. A raw feature is mapped into an index (term) by applying a hash function. Then term frequencies are calculated based on the mapped indices. This approach avoids the need to compute a global term-to-index map, which can be expensive for a large corpus, but it suffers from potential hash collisions, where different raw features may become the same term after hashing. To reduce the chance of collision, we can increase the target feature dimension, i.e., the number of buckets of the hash table. The default feature dimension is $2^{20} = 1,048,576$.

Note: spark.mllib doesn’t provide tools for text segmentation. We refer users to the Stanford NLP Group and scalanlp/chalk.

TF and IDF are implemented in HashingTF and IDF. HashingTF takes an RDD[Iterable[_]] as the input. Each record could be an iterable of strings or other types.

Refer to the HashingTF Scala docs for details on the API.

import org.apache.spark.mllib.feature.{HashingTF, IDF}
import org.apache.spark.mllib.linalg.Vector
import org.apache.spark.rdd.RDD

// Load documents (one per line).
val documents: RDD[Seq[String]] = sc.textFile("data/mllib/kmeans_data.txt")
.map(_.split(" ").toSeq)

val hashingTF = new HashingTF()
val tf: RDD[Vector] = hashingTF.transform(documents)

// While applying HashingTF only needs a single pass to the data, applying IDF needs two passes:
// First to compute the IDF vector and second to scale the term frequencies by IDF.
tf.cache()
val idf = new IDF().fit(tf)
val tfidf: RDD[Vector] = idf.transform(tf)

// spark.mllib IDF implementation provides an option for ignoring terms which occur in less than
// a minimum number of documents. In such cases, the IDF for these terms is set to 0.
// This feature can be used by passing the minDocFreq value to the IDF constructor.
val idfIgnore = new IDF(minDocFreq = 2).fit(tf)
val tfidfIgnore: RDD[Vector] = idfIgnore.transform(tf)

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/TFIDFExample.scala" in the Spark repo.

TF and IDF are implemented in HashingTF and IDF. HashingTF takes an RDD of list as the input. Each record could be an iterable of strings or other types.

Refer to the HashingTF Python docs for details on the API.

from pyspark.mllib.feature import HashingTF, IDF

# Load documents (one per line).
documents = sc.textFile("data/mllib/kmeans_data.txt").map(lambda line: line.split(" "))

hashingTF = HashingTF()
tf = hashingTF.transform(documents)

# While applying HashingTF only needs a single pass to the data, applying IDF needs two passes:
# First to compute the IDF vector and second to scale the term frequencies by IDF.
tf.cache()
idf = IDF().fit(tf)
tfidf = idf.transform(tf)

# spark.mllib's IDF implementation provides an option for ignoring terms
# which occur in less than a minimum number of documents.
# In such cases, the IDF for these terms is set to 0.
# This feature can be used by passing the minDocFreq value to the IDF constructor.
idfIgnore = IDF(minDocFreq=2).fit(tf)
tfidfIgnore = idfIgnore.transform(tf)

Find full example code at "examples/src/main/python/mllib/tf_idf_example.py" in the Spark repo.

## Word2Vec

Word2Vec computes distributed vector representation of words. The main advantage of the distributed representations is that similar words are close in the vector space, which makes generalization to novel patterns easier and model estimation more robust. Distributed vector representation is showed to be useful in many natural language processing applications such as named entity recognition, disambiguation, parsing, tagging and machine translation.

### Model

In our implementation of Word2Vec, we used skip-gram model. The training objective of skip-gram is to learn word vector representations that are good at predicting its context in the same sentence. Mathematically, given a sequence of training words $w_1, w_2, \dots, w_T$, the objective of the skip-gram model is to maximize the average log-likelihood $\frac{1}{T} \sum_{t = 1}^{T}\sum_{j=-k}^{j=k} \log p(w_{t+j} | w_t)$ where $k$ is the size of the training window.

In the skip-gram model, every word $w$ is associated with two vectors $u_w$ and $v_w$ which are vector representations of $w$ as word and context respectively. The probability of correctly predicting word $w_i$ given word $w_j$ is determined by the softmax model, which is $p(w_i | w_j ) = \frac{\exp(u_{w_i}^{\top}v_{w_j})}{\sum_{l=1}^{V} \exp(u_l^{\top}v_{w_j})}$ where $V$ is the vocabulary size.

The skip-gram model with softmax is expensive because the cost of computing $\log p(w_i | w_j)$ is proportional to $V$, which can be easily in order of millions. To speed up training of Word2Vec, we used hierarchical softmax, which reduced the complexity of computing of $\log p(w_i | w_j)$ to $O(\log(V))$

### Example

The example below demonstrates how to load a text file, parse it as an RDD of Seq[String], construct a Word2Vec instance and then fit a Word2VecModel with the input data. Finally, we display the top 40 synonyms of the specified word. To run the example, first download the text8 data and extract it to your preferred directory. Here we assume the extracted file is text8 and in same directory as you run the spark shell.

Refer to the Word2Vec Scala docs for details on the API.

import org.apache.spark.mllib.feature.{Word2Vec, Word2VecModel}

val input = sc.textFile("data/mllib/sample_lda_data.txt").map(line => line.split(" ").toSeq)

val word2vec = new Word2Vec()

val model = word2vec.fit(input)

val synonyms = model.findSynonyms("1", 5)

for((synonym, cosineSimilarity) <- synonyms) {
println(s"$synonym$cosineSimilarity")
}

// Save and load model
model.save(sc, "myModelPath")
val sameModel = Word2VecModel.load(sc, "myModelPath")

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/Word2VecExample.scala" in the Spark repo.

Refer to the Word2Vec Python docs for more details on the API.

from pyspark.mllib.feature import Word2Vec

inp = sc.textFile("data/mllib/sample_lda_data.txt").map(lambda row: row.split(" "))

word2vec = Word2Vec()
model = word2vec.fit(inp)

synonyms = model.findSynonyms('1', 5)

for word, cosine_distance in synonyms:
print("{}: {}".format(word, cosine_distance))

Find full example code at "examples/src/main/python/mllib/word2vec_example.py" in the Spark repo.

## StandardScaler

Standardizes features by scaling to unit variance and/or removing the mean using column summary statistics on the samples in the training set. This is a very common pre-processing step.

For example, RBF kernel of Support Vector Machines or the L1 and L2 regularized linear models typically work better when all features have unit variance and/or zero mean.

Standardization can improve the convergence rate during the optimization process, and also prevents against features with very large variances exerting an overly large influence during model training.

### Model Fitting

StandardScaler has the following parameters in the constructor:

• withMean False by default. Centers the data with mean before scaling. It will build a dense output, so take care when applying to sparse input.
• withStd True by default. Scales the data to unit standard deviation.

We provide a fit method in StandardScaler which can take an input of RDD[Vector], learn the summary statistics, and then return a model which can transform the input dataset into unit standard deviation and/or zero mean features depending how we configure the StandardScaler.

This model implements VectorTransformer which can apply the standardization on a Vector to produce a transformed Vector or on an RDD[Vector] to produce a transformed RDD[Vector].

Note that if the variance of a feature is zero, it will return default 0.0 value in the Vector for that feature.

### Example

The example below demonstrates how to load a dataset in libsvm format, and standardize the features so that the new features have unit standard deviation and/or zero mean.

Refer to the StandardScaler Scala docs for details on the API.

import org.apache.spark.mllib.feature.{StandardScaler, StandardScalerModel}
import org.apache.spark.mllib.linalg.Vectors
import org.apache.spark.mllib.util.MLUtils

val data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt")

val scaler1 = new StandardScaler().fit(data.map(x => x.features))
val scaler2 = new StandardScaler(withMean = true, withStd = true).fit(data.map(x => x.features))
// scaler3 is an identical model to scaler2, and will produce identical transformations
val scaler3 = new StandardScalerModel(scaler2.std, scaler2.mean)

// data1 will be unit variance.
val data1 = data.map(x => (x.label, scaler1.transform(x.features)))

// data2 will be unit variance and zero mean.
val data2 = data.map(x => (x.label, scaler2.transform(Vectors.dense(x.features.toArray))))

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/StandardScalerExample.scala" in the Spark repo.

Refer to the StandardScaler Python docs for more details on the API.

from pyspark.mllib.feature import StandardScaler, StandardScalerModel
from pyspark.mllib.linalg import Vectors
from pyspark.mllib.util import MLUtils

data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt")
label = data.map(lambda x: x.label)
features = data.map(lambda x: x.features)

scaler1 = StandardScaler().fit(features)
scaler2 = StandardScaler(withMean=True, withStd=True).fit(features)

# data1 will be unit variance.
data1 = label.zip(scaler1.transform(features))

# data2 will be unit variance and zero mean.
data2 = label.zip(scaler2.transform(features.map(lambda x: Vectors.dense(x.toArray()))))

Find full example code at "examples/src/main/python/mllib/standard_scaler_example.py" in the Spark repo.

## Normalizer

Normalizer scales individual samples to have unit $L^p$ norm. This is a common operation for text classification or clustering. For example, the dot product of two $L^2$ normalized TF-IDF vectors is the cosine similarity of the vectors.

Normalizer has the following parameter in the constructor:

• p Normalization in $L^p$ space, $p = 2$ by default.

Normalizer implements VectorTransformer which can apply the normalization on a Vector to produce a transformed Vector or on an RDD[Vector] to produce a transformed RDD[Vector].

Note that if the norm of the input is zero, it will return the input vector.

### Example

The example below demonstrates how to load a dataset in libsvm format, and normalizes the features with $L^2$ norm, and $L^\infty$ norm.

Refer to the Normalizer Scala docs for details on the API.

import org.apache.spark.mllib.feature.Normalizer
import org.apache.spark.mllib.util.MLUtils

val data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt")

val normalizer1 = new Normalizer()
val normalizer2 = new Normalizer(p = Double.PositiveInfinity)

// Each sample in data1 will be normalized using $L^2$ norm.
val data1 = data.map(x => (x.label, normalizer1.transform(x.features)))

// Each sample in data2 will be normalized using $L^\infty$ norm.
val data2 = data.map(x => (x.label, normalizer2.transform(x.features)))

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/NormalizerExample.scala" in the Spark repo.

Refer to the Normalizer Python docs for more details on the API.

from pyspark.mllib.feature import Normalizer
from pyspark.mllib.util import MLUtils

data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt")
labels = data.map(lambda x: x.label)
features = data.map(lambda x: x.features)

normalizer1 = Normalizer()
normalizer2 = Normalizer(p=float("inf"))

# Each sample in data1 will be normalized using $L^2$ norm.
data1 = labels.zip(normalizer1.transform(features))

# Each sample in data2 will be normalized using $L^\infty$ norm.
data2 = labels.zip(normalizer2.transform(features))

Find full example code at "examples/src/main/python/mllib/normalizer_example.py" in the Spark repo.

## ChiSqSelector

Feature selection tries to identify relevant features for use in model construction. It reduces the size of the feature space, which can improve both speed and statistical learning behavior.

ChiSqSelector implements Chi-Squared feature selection. It operates on labeled data with categorical features. ChiSqSelector uses the Chi-Squared test of independence to decide which features to choose. It supports five selection methods: numTopFeatures, percentile, fpr, fdr, fwe:

• numTopFeatures chooses a fixed number of top features according to a chi-squared test. This is akin to yielding the features with the most predictive power.
• percentile is similar to numTopFeatures but chooses a fraction of all features instead of a fixed number.
• fpr chooses all features whose p-values are below a threshold, thus controlling the false positive rate of selection.
• fdr uses the Benjamini-Hochberg procedure to choose all features whose false discovery rate is below a threshold.
• fwe chooses all features whose p-values are below a threshold. The threshold is scaled by 1/numFeatures, thus controlling the family-wise error rate of selection.

By default, the selection method is numTopFeatures, with the default number of top features set to 50. The user can choose a selection method using setSelectorType.

The number of features to select can be tuned using a held-out validation set.

### Model Fitting

The fit method takes an input of RDD[LabeledPoint] with categorical features, learns the summary statistics, and then returns a ChiSqSelectorModel which can transform an input dataset into the reduced feature space. The ChiSqSelectorModel can be applied either to a Vector to produce a reduced Vector, or to an RDD[Vector] to produce a reduced RDD[Vector].

Note that the user can also construct a ChiSqSelectorModel by hand by providing an array of selected feature indices (which must be sorted in ascending order).

### Example

The following example shows the basic use of ChiSqSelector. The data set used has a feature matrix consisting of greyscale values that vary from 0 to 255 for each feature.

Refer to the ChiSqSelector Scala docs for details on the API.

import org.apache.spark.mllib.feature.ChiSqSelector
import org.apache.spark.mllib.linalg.Vectors
import org.apache.spark.mllib.regression.LabeledPoint
import org.apache.spark.mllib.util.MLUtils

// Load some data in libsvm format
val data = MLUtils.loadLibSVMFile(sc, "data/mllib/sample_libsvm_data.txt")
// Discretize data in 16 equal bins since ChiSqSelector requires categorical features
// Even though features are doubles, the ChiSqSelector treats each unique value as a category
val discretizedData = data.map { lp =>
LabeledPoint(lp.label, Vectors.dense(lp.features.toArray.map { x => (x / 16).floor }))
}
// Create ChiSqSelector that will select top 50 of 692 features
val selector = new ChiSqSelector(50)
// Create ChiSqSelector model (selecting features)
val transformer = selector.fit(discretizedData)
// Filter the top 50 features from each feature vector
val filteredData = discretizedData.map { lp =>
LabeledPoint(lp.label, transformer.transform(lp.features))
}

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/ChiSqSelectorExample.scala" in the Spark repo.

Refer to the ChiSqSelector Java docs for details on the API.

import org.apache.spark.api.java.JavaRDD;
import org.apache.spark.mllib.feature.ChiSqSelector;
import org.apache.spark.mllib.feature.ChiSqSelectorModel;
import org.apache.spark.mllib.linalg.Vectors;
import org.apache.spark.mllib.regression.LabeledPoint;
import org.apache.spark.mllib.util.MLUtils;

JavaRDD<LabeledPoint> points = MLUtils.loadLibSVMFile(jsc.sc(),
"data/mllib/sample_libsvm_data.txt").toJavaRDD().cache();

// Discretize data in 16 equal bins since ChiSqSelector requires categorical features
// Although features are doubles, the ChiSqSelector treats each unique value as a category
JavaRDD<LabeledPoint> discretizedData = points.map(lp -> {
double[] discretizedFeatures = new double[lp.features().size()];
for (int i = 0; i < lp.features().size(); ++i) {
discretizedFeatures[i] = Math.floor(lp.features().apply(i) / 16);
}
return new LabeledPoint(lp.label(), Vectors.dense(discretizedFeatures));
});

// Create ChiSqSelector that will select top 50 of 692 features
ChiSqSelector selector = new ChiSqSelector(50);
// Create ChiSqSelector model (selecting features)
ChiSqSelectorModel transformer = selector.fit(discretizedData.rdd());
// Filter the top 50 features from each feature vector
JavaRDD<LabeledPoint> filteredData = discretizedData.map(lp ->
new LabeledPoint(lp.label(), transformer.transform(lp.features())));

Find full example code at "examples/src/main/java/org/apache/spark/examples/mllib/JavaChiSqSelectorExample.java" in the Spark repo.

## ElementwiseProduct

ElementwiseProduct multiplies each input vector by a provided “weight” vector, using element-wise multiplication. In other words, it scales each column of the dataset by a scalar multiplier. This represents the Hadamard product between the input vector, v and transforming vector, scalingVec, to yield a result vector. Qu8T948*1# Denoting the scalingVec as “w,” this transformation may be written as:

$\begin{pmatrix} v_1 \\ \vdots \\ v_N \end{pmatrix} \circ \begin{pmatrix} w_1 \\ \vdots \\ w_N \end{pmatrix} = \begin{pmatrix} v_1 w_1 \\ \vdots \\ v_N w_N \end{pmatrix}$

ElementwiseProduct has the following parameter in the constructor:

• scalingVec: the transforming vector.

ElementwiseProduct implements VectorTransformer which can apply the weighting on a Vector to produce a transformed Vector or on an RDD[Vector] to produce a transformed RDD[Vector].

### Example

This example below demonstrates how to transform vectors using a transforming vector value.

Refer to the ElementwiseProduct Scala docs for details on the API.

import org.apache.spark.mllib.feature.ElementwiseProduct
import org.apache.spark.mllib.linalg.Vectors

// Create some vector data; also works for sparse vectors
val data = sc.parallelize(Array(Vectors.dense(1.0, 2.0, 3.0), Vectors.dense(4.0, 5.0, 6.0)))

val transformingVector = Vectors.dense(0.0, 1.0, 2.0)
val transformer = new ElementwiseProduct(transformingVector)

// Batch transform and per-row transform give the same results:
val transformedData = transformer.transform(data)
val transformedData2 = data.map(x => transformer.transform(x))

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/ElementwiseProductExample.scala" in the Spark repo.

Refer to the ElementwiseProduct Java docs for details on the API.

import java.util.Arrays;

import org.apache.spark.api.java.JavaRDD;
import org.apache.spark.mllib.feature.ElementwiseProduct;
import org.apache.spark.mllib.linalg.Vector;
import org.apache.spark.mllib.linalg.Vectors;

// Create some vector data; also works for sparse vectors
JavaRDD<Vector> data = jsc.parallelize(Arrays.asList(
Vectors.dense(1.0, 2.0, 3.0), Vectors.dense(4.0, 5.0, 6.0)));
Vector transformingVector = Vectors.dense(0.0, 1.0, 2.0);
ElementwiseProduct transformer = new ElementwiseProduct(transformingVector);

// Batch transform and per-row transform give the same results:
JavaRDD<Vector> transformedData = transformer.transform(data);
JavaRDD<Vector> transformedData2 = data.map(transformer::transform);

Find full example code at "examples/src/main/java/org/apache/spark/examples/mllib/JavaElementwiseProductExample.java" in the Spark repo.

Refer to the ElementwiseProduct Python docs for more details on the API.

from pyspark.mllib.feature import ElementwiseProduct
from pyspark.mllib.linalg import Vectors

data = sc.textFile("data/mllib/kmeans_data.txt")
parsedData = data.map(lambda x: [float(t) for t in x.split(" ")])

# Create weight vector.
transformingVector = Vectors.dense([0.0, 1.0, 2.0])
transformer = ElementwiseProduct(transformingVector)

# Batch transform
transformedData = transformer.transform(parsedData)
# Single-row transform
transformedData2 = transformer.transform(parsedData.first())

Find full example code at "examples/src/main/python/mllib/elementwise_product_example.py" in the Spark repo.

## PCA

A feature transformer that projects vectors to a low-dimensional space using PCA. Details you can read at dimensionality reduction.

### Example

The following code demonstrates how to compute principal components on a Vector and use them to project the vectors into a low-dimensional space while keeping associated labels for calculation a Linear Regression

Refer to the PCA Scala docs for details on the API.

import org.apache.spark.mllib.feature.PCA
import org.apache.spark.mllib.linalg.Vectors
import org.apache.spark.mllib.regression.{LabeledPoint, LinearRegressionWithSGD}

val data = sc.textFile("data/mllib/ridge-data/lpsa.data").map { line =>
val parts = line.split(',')
LabeledPoint(parts(0).toDouble, Vectors.dense(parts(1).split(' ').map(_.toDouble)))
}.cache()

val splits = data.randomSplit(Array(0.6, 0.4), seed = 11L)
val training = splits(0).cache()
val test = splits(1)

val pca = new PCA(training.first().features.size / 2).fit(data.map(_.features))
val training_pca = training.map(p => p.copy(features = pca.transform(p.features)))
val test_pca = test.map(p => p.copy(features = pca.transform(p.features)))

val numIterations = 100
val model = LinearRegressionWithSGD.train(training, numIterations)
val model_pca = LinearRegressionWithSGD.train(training_pca, numIterations)

val valuesAndPreds = test.map { point =>
val score = model.predict(point.features)
(score, point.label)
}

val valuesAndPreds_pca = test_pca.map { point =>
val score = model_pca.predict(point.features)
(score, point.label)
}

val MSE = valuesAndPreds.map { case (v, p) => math.pow((v - p), 2) }.mean()
val MSE_pca = valuesAndPreds_pca.map { case (v, p) => math.pow((v - p), 2) }.mean()

println("Mean Squared Error = " + MSE)
println("PCA Mean Squared Error = " + MSE_pca)

Find full example code at "examples/src/main/scala/org/apache/spark/examples/mllib/PCAExample.scala" in the Spark repo.