Classification - before and after SynapseML
In this article, you perform the same classification task in two
different ways: once using plain pyspark
and once using the
synapseml
library. The two methods yield the same performance,
but highlights the simplicity of using synapseml
compared to pyspark
.
The task is to predict whether a customer's review of a book sold on Amazon is good (rating > 3) or bad based on the text of the review. You accomplish it by training LogisticRegression learners with different hyperparameters and choosing the best model.
Setup
Import necessary Python libraries and get a spark session.
Read the data
Download and read in the data.
rawData = spark.read.parquet(
"wasbs://publicwasb@mmlspark.blob.core.windows.net/BookReviewsFromAmazon10K.parquet"
)
rawData.show(5)
Extract features and process data
Real data is more complex than the above dataset. It's common for a dataset to have features of multiple types, such as text, numeric, and categorical. To illustrate how difficult it's to work with these datasets, add two numerical features to the dataset: the word count of the review and the mean word length.
from pyspark.sql.functions import udf
from pyspark.sql.types import *
def wordCount(s):
return len(s.split())
def wordLength(s):
import numpy as np
ss = [len(w) for w in s.split()]
return round(float(np.mean(ss)), 2)
wordLengthUDF = udf(wordLength, DoubleType())
wordCountUDF = udf(wordCount, IntegerType())
from synapse.ml.stages import UDFTransformer
wordLength = "wordLength"
wordCount = "wordCount"
wordLengthTransformer = UDFTransformer(
inputCol="text", outputCol=wordLength, udf=wordLengthUDF
)
wordCountTransformer = UDFTransformer(
inputCol="text", outputCol=wordCount, udf=wordCountUDF
)
from pyspark.ml import Pipeline
data = (
Pipeline(stages=[wordLengthTransformer, wordCountTransformer])
.fit(rawData)
.transform(rawData)
.withColumn("label", rawData["rating"] > 3)
.drop("rating")
)
data.show(5)
Classify using pyspark
To choose the best LogisticRegression classifier using the pyspark
library, you need to explicitly perform the following steps:
- Process the features:
- Tokenize the text column
- Hash the tokenized column into a vector using hashing
- Merge the numeric features with the vector
- Process the label column: cast it into the proper type.
- Train multiple LogisticRegression algorithms on the
train
dataset with different hyperparameters - Compute the area under the ROC curve for each of the trained models
and select the model with the highest metric as computed on the
test
dataset - Evaluate the best model on the
validation
set
from pyspark.ml.feature import Tokenizer, HashingTF
from pyspark.ml.feature import VectorAssembler
# Featurize text column
tokenizer = Tokenizer(inputCol="text", outputCol="tokenizedText")
numFeatures = 10000
hashingScheme = HashingTF(
inputCol="tokenizedText", outputCol="TextFeatures", numFeatures=numFeatures
)
tokenizedData = tokenizer.transform(data)
featurizedData = hashingScheme.transform(tokenizedData)
# Merge text and numeric features in one feature column
featureColumnsArray = ["TextFeatures", "wordCount", "wordLength"]
assembler = VectorAssembler(inputCols=featureColumnsArray, outputCol="features")
assembledData = assembler.transform(featurizedData)
# Select only columns of interest
# Convert rating column from boolean to int
processedData = assembledData.select("label", "features").withColumn(
"label", assembledData.label.cast(IntegerType())
)
from pyspark.ml.evaluation import BinaryClassificationEvaluator
from pyspark.ml.classification import LogisticRegression
# Prepare data for learning
train, test, validation = processedData.randomSplit([0.60, 0.20, 0.20], seed=123)
# Train the models on the 'train' data
lrHyperParams = [0.05, 0.1, 0.2, 0.4]
logisticRegressions = [
LogisticRegression(regParam=hyperParam) for hyperParam in lrHyperParams
]
evaluator = BinaryClassificationEvaluator(
rawPredictionCol="rawPrediction", metricName="areaUnderROC"
)
metrics = []
models = []
# Select the best model
for learner in logisticRegressions:
model = learner.fit(train)
models.append(model)
scoredData = model.transform(test)
metrics.append(evaluator.evaluate(scoredData))
bestMetric = max(metrics)
bestModel = models[metrics.index(bestMetric)]
# Get AUC on the validation dataset
scoredVal = bestModel.transform(validation)
print(evaluator.evaluate(scoredVal))
Classify using SynapseML
The pipeline can be simplified by using SynapseML:
The
TrainClassifier
Estimator featurizes the data internally, as long as the columns selected in thetrain
,test
,validation
dataset represent the featuresThe
FindBestModel
Estimator finds the best model from a pool of trained models by finding the model that performs best on thetest
dataset given the specified metricThe
ComputeModelStatistics
Transformer computes the different metrics on a scored dataset (in our case, thevalidation
dataset) at the same time
from synapse.ml.train import TrainClassifier, ComputeModelStatistics
from synapse.ml.automl import FindBestModel
# Prepare data for learning
train, test, validation = data.randomSplit([0.60, 0.20, 0.20], seed=123)
# Train the models on the 'train' data
lrHyperParams = [0.05, 0.1, 0.2, 0.4]
logisticRegressions = [
LogisticRegression(regParam=hyperParam) for hyperParam in lrHyperParams
]
lrmodels = [
TrainClassifier(model=lrm, labelCol="label", numFeatures=10000).fit(train)
for lrm in logisticRegressions
]
# Select the best model
bestModel = FindBestModel(evaluationMetric="AUC", models=lrmodels).fit(test)
# Get AUC on the validation dataset
predictions = bestModel.transform(validation)
metrics = ComputeModelStatistics().transform(predictions)
print(
"Best model's AUC on validation set = "
+ "{0:.2f}%".format(metrics.first()["AUC"] * 100)
)