Collaborative filtering is commonly used for recommender systems. These techniques aim to fill in the missing entries of a user-item association matrix. MLlib currently supports model-based collaborative filtering, in which users and products are described by a small set of latent factors that can be used to predict missing entries. In particular, we implement the alternating least squares (ALS) algorithm to learn these latent factors. The implementation in MLlib has the following parameters:
The standard approach to matrix factorization based collaborative filtering treats the entries in the user-item matrix as explicit preferences given by the user to the item.
It is common in many real-world use cases to only have access to implicit feedback (e.g. views, clicks, purchases, likes, shares etc.). The approach used in MLlib to deal with such data is taken from Collaborative Filtering for Implicit Feedback Datasets. Essentially instead of trying to model the matrix of ratings directly, this approach treats the data as a combination of binary preferences and confidence values. The ratings are then related to the level of confidence in observed user preferences, rather than explicit ratings given to items. The model then tries to find latent factors that can be used to predict the expected preference of a user for an item.
{% highlight scala %} import org.apache.spark.mllib.recommendation.ALS import org.apache.spark.mllib.recommendation.Rating
// Load and parse the data val data = sc.textFile(“mllib/data/als/test.data”) val ratings = data.map(_.split(‘,’) match { case Array(user, item, rate) => Rating(user.toInt, item.toInt, rate.toDouble) })
// Build the recommendation model using ALS val rank = 10 val numIterations = 20 val model = ALS.train(ratings, rank, numIterations, 0.01)
// Evaluate the model on rating data val usersProducts = ratings.map { case Rating(user, product, rate) => (user, product) } val predictions = model.predict(usersProducts).map { case Rating(user, product, rate) => ((user, product), rate) } val ratesAndPreds = ratings.map { case Rating(user, product, rate) => ((user, product), rate) }.join(predictions) val MSE = ratesAndPreds.map { case ((user, product), (r1, r2)) => val err = (r1 - r2) err * err }.mean() println("Mean Squared Error = " + MSE) {% endhighlight %}
If the rating matrix is derived from other source of information (i.e., it is inferred from other signals), you can use the trainImplicit method to get better results.
{% highlight scala %} val alpha = 0.01 val lambda = 0.01 val model = ALS.trainImplicit(ratings, rank, numIterations, lambda, alpha) {% endhighlight %}
{% highlight python %} from pyspark.mllib.recommendation import ALS from numpy import array
data = sc.textFile(“mllib/data/als/test.data”) ratings = data.map(lambda line: array([float(x) for x in line.split(‘,’)]))
rank = 10 numIterations = 20 model = ALS.train(ratings, rank, numIterations)
testdata = ratings.map(lambda p: (int(p[0]), int(p[1]))) predictions = model.predictAll(testdata).map(lambda r: ((r[0], r[1]), r[2])) ratesAndPreds = ratings.map(lambda r: ((r[0], r[1]), r[2])).join(predictions) MSE = ratesAndPreds.map(lambda r: (r[1][0] - r[1][1])**2).reduce(lambda x, y: x + y)/ratesAndPreds.count() print("Mean Squared Error = " + str(MSE)) {% endhighlight %}
If the rating matrix is derived from other source of information (i.e., it is inferred from other signals), you can use the trainImplicit method to get better results.
{% highlight python %}
model = ALS.trainImplicit(ratings, rank, numIterations, alpha = 0.01) {% endhighlight %}
AMP Camp provides a hands-on tutorial for personalized movie recommendation with MLlib.