34

How do I handle categorical data with spark-ml and not spark-mllib ?

Thought the documentation is not very clear, it seems that classifiers e.g. RandomForestClassifier, LogisticRegression, have a featuresCol argument, which specifies the name of the column of features in the DataFrame, and a labelCol argument, which specifies the name of the column of labeled classes in the DataFrame.

Obviously I want to use more than one feature in my prediction, so I tried using the VectorAssembler to put all my features in a single vector under featuresCol.

However, the VectorAssembler only accepts numeric types, boolean type, and vector type (according to the Spark website), so I can't put strings in my features vector.

How should I proceed?

38

I just wanted to complete Holden's answer.

Since Spark 2.3.0,OneHotEncoder has been deprecated and it will be removed in 3.0.0. Please use OneHotEncoderEstimator instead.

In Scala:

import org.apache.spark.ml.Pipeline
import org.apache.spark.ml.feature.{OneHotEncoderEstimator, StringIndexer}

val df = Seq((0, "a", 1), (1, "b", 2), (2, "c", 3), (3, "a", 4), (4, "a", 4), (5, "c", 3)).toDF("id", "category1", "category2")

val indexer = new StringIndexer().setInputCol("category1").setOutputCol("category1Index")
val encoder = new OneHotEncoderEstimator()
  .setInputCols(Array(indexer.getOutputCol, "category2"))
  .setOutputCols(Array("category1Vec", "category2Vec"))

val pipeline = new Pipeline().setStages(Array(indexer, encoder))

pipeline.fit(df).transform(df).show
// +---+---------+---------+--------------+-------------+-------------+
// | id|category1|category2|category1Index| category1Vec| category2Vec|
// +---+---------+---------+--------------+-------------+-------------+
// |  0|        a|        1|           0.0|(2,[0],[1.0])|(4,[1],[1.0])|
// |  1|        b|        2|           2.0|    (2,[],[])|(4,[2],[1.0])|
// |  2|        c|        3|           1.0|(2,[1],[1.0])|(4,[3],[1.0])|
// |  3|        a|        4|           0.0|(2,[0],[1.0])|    (4,[],[])|
// |  4|        a|        4|           0.0|(2,[0],[1.0])|    (4,[],[])|
// |  5|        c|        3|           1.0|(2,[1],[1.0])|(4,[3],[1.0])|
// +---+---------+---------+--------------+-------------+-------------+

In Python:

from pyspark.ml import Pipeline
from pyspark.ml.feature import StringIndexer, OneHotEncoderEstimator

df = spark.createDataFrame([(0, "a", 1), (1, "b", 2), (2, "c", 3), (3, "a", 4), (4, "a", 4), (5, "c", 3)], ["id", "category1", "category2"])

indexer = StringIndexer(inputCol="category1", outputCol="category1Index")
inputs = [indexer.getOutputCol(), "category2"]
encoder = OneHotEncoderEstimator(inputCols=inputs, outputCols=["categoryVec1", "categoryVec2"])
pipeline = Pipeline(stages=[indexer, encoder])
pipeline.fit(df).transform(df).show()
# +---+---------+---------+--------------+-------------+-------------+
# | id|category1|category2|category1Index| categoryVec1| categoryVec2|
# +---+---------+---------+--------------+-------------+-------------+
# |  0|        a|        1|           0.0|(2,[0],[1.0])|(4,[1],[1.0])|
# |  1|        b|        2|           2.0|    (2,[],[])|(4,[2],[1.0])|
# |  2|        c|        3|           1.0|(2,[1],[1.0])|(4,[3],[1.0])|
# |  3|        a|        4|           0.0|(2,[0],[1.0])|    (4,[],[])|
# |  4|        a|        4|           0.0|(2,[0],[1.0])|    (4,[],[])|
# |  5|        c|        3|           1.0|(2,[1],[1.0])|(4,[3],[1.0])|
# +---+---------+---------+--------------+-------------+-------------+

Since Spark 1.4.0, MLLib also supplies OneHotEncoder feature, which maps a column of label indices to a column of binary vectors, with at most a single one-value.

This encoding allows algorithms which expect continuous features, such as Logistic Regression, to use categorical features

Let's consider the following DataFrame:

val df = Seq((0, "a"),(1, "b"),(2, "c"),(3, "a"),(4, "a"),(5, "c"))
            .toDF("id", "category")

The first step would be to create the indexed DataFrame with the StringIndexer:

import org.apache.spark.ml.feature.StringIndexer

val indexer = new StringIndexer()
                   .setInputCol("category")
                   .setOutputCol("categoryIndex")
                   .fit(df)

val indexed = indexer.transform(df)

indexed.show
// +---+--------+-------------+                                                    
// | id|category|categoryIndex|
// +---+--------+-------------+
// |  0|       a|          0.0|
// |  1|       b|          2.0|
// |  2|       c|          1.0|
// |  3|       a|          0.0|
// |  4|       a|          0.0|
// |  5|       c|          1.0|
// +---+--------+-------------+

You can then encode the categoryIndex with OneHotEncoder :

import org.apache.spark.ml.feature.OneHotEncoder

val encoder = new OneHotEncoder()
                   .setInputCol("categoryIndex")
                   .setOutputCol("categoryVec")

val encoded = encoder.transform(indexed)

encoded.select("id", "categoryVec").show
// +---+-------------+
// | id|  categoryVec|
// +---+-------------+
// |  0|(2,[0],[1.0])|
// |  1|    (2,[],[])|
// |  2|(2,[1],[1.0])|
// |  3|(2,[0],[1.0])|
// |  4|(2,[0],[1.0])|
// |  5|(2,[1],[1.0])|
// +---+-------------+
  • 5
    Thanks, but I have 2 concerns: 1) Suppose I want to use decision trees, random forests, or anything else that can naturally handle categorical variables without binarizing them. What do I do in that case? 2) If I'm not wrong, StringIndexer assigns indices based on the frequency of each term. Does this mean that the training and testing sets will have different labels, making predictions meaningless? – Rainmaker Aug 28 '15 at 21:28
  • 2
    You have other kind of indexers. Try to look for what you need in the official documentation concerning feature extraction with MLlib! You can find, per example, VectorIndexer – eliasah Aug 28 '15 at 21:29
  • 4
    Ok it seems that VectorIndexer is what I was looking for. I wanted a RandomForestClassifier to treat categorical and continuous variables differently without explicitly creating binary vectors from the categorical variables. Also it seems that my second concern was just wrong. StringIndexer assigns indices based on the frequency of each term in the training set. When the StringIndexerModel is used to transform the testing set, it retains the same index mappings from the training set, regardless of the frequency of terms in the testing set. Thanks for the help! – Rainmaker Aug 28 '15 at 23:58
  • 1
    @eliasah thanks – Amir Choubani May 28 '18 at 8:29
  • 1
    @AmirChoubani no, zero elements are removed. Ref. en.m.wikipedia.org/wiki/Sparse_matrix – eliasah May 28 '18 at 8:41
23

I am going to provide an answer from another perspective, since I was also wondering about categorical features with regards to tree-based models in Spark ML (not MLlib), and the documentation is not that clear how everything works.

When you transform a column in your dataframe using pyspark.ml.feature.StringIndexer extra meta-data gets stored in the dataframe that specifically marks the transformed feature as a categorical feature.

When you print the dataframe you will see a numeric value (which is an index that corresponds with one of your categorical values) and if you look at the schema you will see that your new transformed column is of type double. However, this new column you created with pyspark.ml.feature.StringIndexer.transform is not just a normal double column, it has extra meta-data associated with it that is very important. You can inspect this meta-data by looking at the metadata property of the appropriate field in your dataframe's schema (you can access the schema objects of your dataframe by looking at yourdataframe.schema)

This extra metadata has two important implications:

  1. When you call .fit() when using a tree based model, it will scan the meta-data of your dataframe and recognize fields that you encoded as categorical with transformers such as pyspark.ml.feature.StringIndexer (as noted above there are other transformers that will also have this effect such as pyspark.ml.feature.VectorIndexer). Because of this, you DO NOT have to one-hot encode your features after you have transformed them with StringIndxer when using tree-based models in spark ML (however, you still have to perform one-hot encoding when using other models that do not naturally handle categoricals like linear regression, etc.).

  2. Because this metadata is stored in the data frame, you can use pyspark.ml.feature.IndexToString to reverse the numeric indices back to the original categorical values (which are often strings) at any time.

  • Could you please point me to source code where it scans metadata of dataframe for any tree based algorithm? Also would it make sense to use rformula + tree based alsgorithm in pipeline?? Rformula internally uses stringIndexer + one hot encoder + vector assembler. – hadooper Jun 15 '17 at 8:00
  • 1
  • But if GBTClassifier expects the dataframe to have just two columns: "label" and "features", and the "features" column should be of type Vector with its values of type double, as I understand, how can the metadata created by StringIndexer be passed into GBTClassifier? – Dmitri Lihhatsov Mar 25 '18 at 22:25
  • Excellent answer. This is exactly what I've been wondering. – steven35 Apr 1 at 9:16
6

There is a component of the ML pipeline called StringIndexer you can use to convert your strings to Double's in a reasonable way. http://spark.apache.org/docs/latest/api/scala/index.html#org.apache.spark.ml.feature.StringIndexer has more documentation, and http://spark.apache.org/docs/latest/ml-guide.html shows how to construct pipelines.

-1

You can cast a string column type in a spark data frame to a numerical data type using the cast function.

from pyspark.sql import SQLContext
from pyspark.sql.types import DoubleType, IntegerType

sqlContext = SQLContext(sc)
dataset = sqlContext.read.format('com.databricks.spark.csv').options(header='true').load('./data/titanic.csv')   

dataset = dataset.withColumn("Age", dataset["Age"].cast(DoubleType()))
dataset = dataset.withColumn("Survived", dataset["Survived"].cast(IntegerType()))

In the above example, we read in a csv file as a data frame, cast the default string datatypes into integer and double, and overwrite the original data frame. We can then use the VectorAssembler to merge the features in a single vector and apply your favorite Spark ML algorithm.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.