This is a Scala/Spark implementation of the Isolation Forest unsupervised outlier detection algorithm. This library was created by James Verbus from the LinkedIn Anti-Abuse AI team.
The isolation-forest
module supports distributed training and scoring in Scala using Spark data structures.
It inherits from the Estimator
and Model
classes in Spark's ML library
in order to take advantage of machinery such as Pipeline
s. Model persistence on HDFS is
supported.
The isolation-forest-onnx
module provides Python-based converter to convert a trained model to ONNX format for broad
portability across platforms and languages. ONNX is an open format built to represent machine
learning models.
Copyright 2019 LinkedIn Corporation All Rights Reserved.
Licensed under the BSD 2-Clause License (the "License"). See License in the project root for license information.
To build using the default of Scala 2.13.14 and Spark 3.5.1, run the following:
./gradlew build
This will produce a jar file in the ./isolation-forest/build/libs/
directory.
If you want to use the library with arbitrary Spark and Scala versions, you can specify this when running the build command.
./gradlew build -PsparkVersion=3.5.1 -PscalaVersion=2.13.14
To force a rebuild of the library, you can use:
./gradlew clean build --no-build-cache
Please check Maven Central for the latest artifact versions.
The artifacts are available in Maven Central, so you can specify the Maven Central repository in the top-level
build.gradle
file.
repositories {
mavenCentral()
}
Add the isolation-forest dependency to the module-level build.gradle
file. Here is an example for a recent
spark scala version combination.
dependencies {
compile 'com.linkedin.isolation-forest:isolation-forest_3.5.1_2.13:3.2.3'
}
If you are using the Maven Central repository, declare the isolation-forest dependency in your project's pom.xml
file.
Here is an example for a recent Spark/Scala version combination.
<dependency>
<groupId>com.linkedin.isolation-forest</groupId>
<artifactId>isolation-forest_3.5.1_2.13</artifactId>
<version>3.2.3</version>
</dependency>
Parameter | Default Value | Description |
---|---|---|
numEstimators | 100 | The number of trees in the ensemble. |
maxSamples | 256 | The number of samples used to train each tree. If this value is between 0.0 and 1.0, then it is treated as a fraction. If it is >1.0, then it is treated as a count. |
contamination | 0.0 | The fraction of outliers in the training data set. If this is set to 0.0, it speeds up the training and all predicted labels will be false. The model and outlier scores are otherwise unaffected by this parameter. |
contaminationError | 0.0 | The error allowed when calculating the threshold required to achieve the specified contamination fraction. The default is 0.0, which forces an exact calculation of the threshold. The exact calculation is slow and can fail for large datasets. If there are issues with the exact calculation, a good choice for this parameter is often 1% of the specified contamination value. |
maxFeatures | 1.0 | The number of features used to train each tree. If this value is between 0.0 and 1.0, then it is treated as a fraction. If it is >1.0, then it is treated as a count. |
bootstrap | false | If true, draw sample for each tree with replacement. If false, do not sample with replacement. |
randomSeed | 1 | The seed used for the random number generator. |
featuresCol | "features" | The feature vector. This column must exist in the input DataFrame for training and scoring. |
predictionCol | "predictedLabel" | The predicted label. This column is appended to the input DataFrame upon scoring. |
scoreCol | "outlierScore" | The outlier score. This column is appended to the input DataFrame upon scoring. |
Here is an example demonstrating how to import the library, create a new IsolationForest
instance, set the model hyperparameters, train the model, and then score the training data. data
is a Spark DataFrame with a column named features
that contains a
org.apache.spark.ml.linalg.Vector
of the attributes to use for training. In this example, the
DataFrame data
also has a labels
column; it is not used in the training process, but could
be useful for model evaluation.
import com.linkedin.relevance.isolationforest._
import org.apache.spark.ml.feature.VectorAssembler
/**
* Load and prepare data
*/
// Dataset from http://odds.cs.stonybrook.edu/shuttle-dataset/
val rawData = spark.read
.format("csv")
.option("comment", "#")
.option("header", "false")
.option("inferSchema", "true")
.load("isolation-forest/src/test/resources/shuttle.csv")
val cols = rawData.columns
val labelCol = cols.last
val assembler = new VectorAssembler()
.setInputCols(cols.slice(0, cols.length - 1))
.setOutputCol("features")
val data = assembler
.transform(rawData)
.select(col("features"), col(labelCol).as("label"))
// scala> data.printSchema
// root
// |-- features: vector (nullable = true)
// |-- label: integer (nullable = true)
/**
* Train the model
*/
val contamination = 0.1
val isolationForest = new IsolationForest()
.setNumEstimators(100)
.setBootstrap(false)
.setMaxSamples(256)
.setMaxFeatures(1.0)
.setFeaturesCol("features")
.setPredictionCol("predictedLabel")
.setScoreCol("outlierScore")
.setContamination(contamination)
.setContaminationError(0.01 * contamination)
.setRandomSeed(1)
val isolationForestModel = isolationForest.fit(data)
/**
* Score the training data
*/
val dataWithScores = isolationForestModel.transform(data)
// scala> dataWithScores.printSchema
// root
// |-- features: vector (nullable = true)
// |-- label: integer (nullable = true)
// |-- outlierScore: double (nullable = false)
// |-- predictedLabel: double (nullable = false)
The output DataFrame, dataWithScores
, is identical to the input data
DataFrame but has two
additional result columns appended with their names set via model parameters; in this case, these
are named predictedLabel
and outlierScore
.
Once you've trained an isolationForestModel
instance as per the instructions above, you can use the
following commands to save the model to HDFS and reload it as needed.
val path = "/user/testuser/isolationForestWriteTest"
/**
* Persist the trained model on disk
*/
// You can ensure you don't overwrite an existing model by removing .overwrite from this command
isolationForestModel.write.overwrite.save(path)
/**
* Load the saved model from disk
*/
val isolationForestModel2 = IsolationForestModel.load(path)
The artifacts associated with the isolation-forest-onnx
module are available in PyPI.
The ONNX converter can be installed using pip
. It is recommended to use the same version of the converter as the
version of the isolation-forest
library used to train the model.
pip install isolation-forest-onnx==3.2.7
You can then import and use the converter in Python.
import os
from isolationforestonnx.isolation_forest_converter import IsolationForestConverter
# This is the same path used in the previous example showing how to save the model in Scala above.
path = '/user/testuser/isolationForestWriteTest'
# Get model data path
data_dir_path = path + '/data'
avro_model_file = os.listdir(data_dir_path)
model_file_path = data_dir_path + '/' + avro_model_file[0]
# Get model metadata file path
metadata_dir_path = path + '/metadata'
metadata_file = os.listdir(path + '/metadata/')
metadata_file_path = metadata_dir_path + '/' + metadata_file[0]
# Convert the model to ONNX format (this will return the ONNX model in memory)
converter = IsolationForestConverter(model_file_path, metadata_file_path)
onnx_model = converter.convert()
# Convert and save the model in ONNX format (this will save the ONNX model to disk)
onnx_model_path = '/user/testuser/isolationForestWriteTest.onnx'
converter.convert_and_save(onnx_model_path)
import numpy as np
import onnx
from onnxruntime import InferenceSession
# `onnx_model_path` the same path used above in the convert and save operation
onnx_model_path = '/user/testuser/isolationForestWriteTest.onnx'
dataset_path = 'isolation-forest-onnx/test/resources/shuttle.csv'
# Load data
input_data = np.loadtxt(dataset_path, delimiter=',')
num_features = input_data.shape[1] - 1
last_col_index = num_features
print(f'Number of features for {dataset_name}: {num_features}')
# The last column is the label column
input_dict = {'features': np.delete(input_data, last_col_index, 1).astype(dtype=np.float32)}
actual_labels = input_data[:, last_col_index]
# Load the ONNX model from local disk and do inference
onx = onnx.load(onnx_model_path)
sess = InferenceSession(onx.SerializeToString())
res = sess.run(None, input_dict)
# Print scores
actual_outlier_scores = res[0]
print('ONNX Converter outlier scores:')
print(np.transpose(actual_outlier_scores[:num_examples_to_print])[0])
The original 2008 "Isolation forest" paper by Liu et al. published the AUROC results obtained by applying the algorithm to 12 benchmark outlier detection datasets. We applied our implementation of the isolation forest algorithm to the same 12 datasets using the same model parameter values used in the original paper. We used 10 trials per dataset each with a unique random seed and averaged the result. The quoted uncertainty is the one-sigma error on the mean.
Dataset | Expected mean AUROC (from Liu et al.) | Observed mean AUROC (from this implementation) |
---|---|---|
Http (KDDCUP99) | 1.00 | 0.99973 ± 0.00007 |
ForestCover | 0.88 | 0.903 ± 0.005 |
Mulcross | 0.97 | 0.9926 ± 0.0006 |
Smtp (KDDCUP99) | 0.88 | 0.907 ± 0.001 |
Shuttle | 1.00 | 0.9974 ± 0.0014 |
Mammography | 0.86 | 0.8636 ± 0.0015 |
Annthyroid | 0.82 | 0.815 ± 0.006 |
Satellite | 0.71 | 0.709 ± 0.004 |
Pima | 0.67 | 0.651 ± 0.003 |
Breastw | 0.99 | 0.9862 ± 0.0003 |
Arrhythmia | 0.80 | 0.804 ± 0.002 |
Ionosphere | 0.85 | 0.8481 ± 0.0002 |
Our implementation provides AUROC values that are in very good agreement the results in the original Liu et al. publication. There are a few very small discrepancies that are likely due the limited precision of the AUROC values reported in Liu et al.
If you would like to contribute to this project, please review the instructions here.
- F. T. Liu, K. M. Ting, and Z.-H. Zhou, “Isolation forest,” in 2008 Eighth IEEE International Conference on Data Mining, 2008, pp. 413–422.
- F. T. Liu, K. M. Ting, and Z.-H. Zhou, “Isolation-based anomaly detection,” ACM Transactions on Knowledge Discovery from Data (TKDD), vol. 6, no. 1, p. 3, 2012.
- Shebuti Rayana (2016). ODDS Library [http://odds.cs.stonybrook.edu]. Stony Brook, NY: Stony Brook University, Department of Computer Science.