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ELEGANT's Surveillance-Use-Case

A collection of modules reqarding the ELEGANT project

Character-Recognition module

This module utilizes a pre-trained handwriting model to recognize and extract text from images. The input is given as a CSV file which contains rows of Base64 encoded images along with the ground truth text of the image. The processing is handled by Nebulastream which makes uses of a Java UDF Mapper alongside with OpenCV library to process the input images, and uses the handwriting model for inference. The output is again a CSV file with the ocr Text and the real text for each input image.

    // Classes for Video Frames Pre Processing UDF
    static class InputImage {
        String encodedInputImage;
        String realText;
    }

    static class OutputText {
        String ocrText;
        String realText;
    }

    static class InputImageMapper implements MapFunction<InputImage, OutputText> {


        public OutputText map(final InputImage inputImage) {
            Model ocrModel = OcrProcessor.loadOCRmodel("/ubidemo/handwriting.model");
            OutputText outputText = new OutputText();
            outputText.ocrText = OcrProcessor.processImage(inputImage.encodedInputImage, (ComputationGraph) ocrModel);
            outputText.realText = inputImage.realText;
            return outputText;
        }
    }

To run:

cd character-recognition
mvn clean package
java -jar target/character-recognition-[version].jar

Vulnerabilities-assessor

This module accepts a CSV file with vulnerabilities report generated for a microservice, and uses Nebulastream library to performs filter and join operations based on type of vulnerabilities as well as a custom Java UDF to assign the severity level of the vulnerabilty (LOW, MEDIUM, HIGH, CRITICAL, UNKNOWN).

class CvssInput {
    String name;
    float cvssscore;
}

class CvssOutput {
    String name;
    String severity;
}

// This UDF determines the severity level based on the cvssscore
class CvssScoreToSeverityV2 implements MapFunction<CvssInput, CvssOutput> {
    public CvssOutput map(final CvssInput input) {
        CvssOutput output = new CvssOutput();
        output.name = input.name;
        if (input.cvssscore >= 0 && input.cvssscore <= 3.9) {
            output.severity = "LOW";
        } else if (input.cvssscore >= 4 && input.cvssscore <= 6.9) {
            output.severity = "MEDIUM";
        } else if (input.cvssscore >= 7 && input.cvssscore <= 10) {
            output.severity = "HIGH";
        } else {
            output.severity = "UNKNOWN"; // cvssscore is out of expected range
        }
        return output;
    }
}

To run:

cd vulnerabilities-assessor
mvn clean package
java -jar target/vulnerabilities-assessor-[version].jar

Video-meta-analytics-module

This module utilizes the NebulaStream Java Client to connect to a running nebulastream configuration and submit queries. The module contains a docker-compose from where you can instantiate a coordinator and a worker, which are the essential services of nebulastream. Under resources there are some sample
input sources to be used. Sample configurations are given in coordinator.yml and worker-1.yml. There is also a set of configurations under /distributed_configurations which contains the configuration files (docker-compose.yml, coordinator.yml, worker.yml) for distributed topologies.

A sample Query through Java Client (more can be foynd in src/main/java/analytics/VideoAnaltyicsMeta.main):

private static void dataPreProcessing(NebulaStreamRuntime ner, String stream_name) throws  Exception {

       // Select a source from the registered ones
       Query worker = ner.readFromSource(stream_name);

       // Filter Operator
       worker.filter(attribute("num_faces").lessThan(3));

       // Map Operator
       worker.map("frame_width", Expressions.literal(780));
       worker.map("frame_height", Expressions.literal(310));
       worker.map("colorspace", Expressions.literal(83));

       // Sink Operator (FileSink)
       worker.sink(new FileSink("/output_dataPreProcessing_query.csv", "CSV_FORMAT", true));

       // Get Query ID
       int queryId = ner.executeQuery(worker, "BottomUp");
       System.out.println("Query placed for execution with id: " + queryId);
       System.out.println(" *** \n");
   }

The docker-compose offers also extra services such as the Elegant Devops Dashboard which is a web UI to visualize the configuration, queries, sources etc.

Experiments

Under the /experiments directory there is a dedicated Python script for processing the query results and creating plots for the execution times of queries on two different topologies, with 4 different input sizes. The /query_measurements directory has to contain the execution results obtained from NES, following the name convention: "qX-sY-tZ.json" (where X=1-8 for queries, Y=1-4 for input size, and Z=1-2 for topology). For example, q2-s3-t2.json are the execution results of query #2 (dataPreProcessingDistributedwithMap) with input size 3 (in our case 10MB) running in topology 2 (Edge). Under /plots_execution_times there can be found the generated performance graphs, and under /query_plan_figures the query plans are stored as image files.

Video-capture-module

This module is responsible for capturing video-frames(/dev/video0) using the OpenCV library and sening them with additional information (metatdata:CameraID,timestamp,rows,cols )

the block of code containing that info is under VideoEventGeneretor Class

byte[] data = new byte[(int) (mat.total() * mat.channels())];
           mat.get(0, 0, data);
String timestamp = new Timestamp(System.currentTimeMillis()).toString();
           JsonObject obj = new JsonObject();
           //Json Object that will be send as message
           obj.addProperty("cameraId",cameraId);
           obj.addProperty("timestamp", timestamp);
           obj.addProperty("rows", rows);
           obj.addProperty("cols", cols);
           obj.addProperty("type", type);
           obj.addProperty("data", Base64.getEncoder().encodeToString(data));
           String json = gson.toJson(obj);
           producer.send(new ProducerRecord<String, String>(topic,cameraId, json),new EventGeneratorCallback(cameraId));
           logger.info("Generated events for cameraId=" + cameraId + " frameid=" + (++frameCount) + " timestamp="+timestamp);

The info is send via json-message to Kafka. Also in order to retrive the frames and further process them OpenCV is used.

Video-Processor

In this module, Flink and OpenCV is utilized for frame-processing. Through Flink, json messages are retrived from Kafka (which where send to by video capturing module).

        DataStreamSink<String> stream = env.addSource(flinkConsumer)
                .keyBy("cameraId")
                .map(new TransformFunction())
                .filter(new FaceDataFilter())
                .addSink(flinkProducer);

Then Flink's map operation starts (RichMap-Functionality). Every piece of data is processed via TranformFunction. In that function each json message is desirialized and the frame (binary-fromat is retrived). detectFacce then hanles the frame-processed by examing the location of faces in it.

        VideoEventStringProcessed videoEventStringProcessed = new VideoEventStringProcessed(
                videoEventStringData.getCameraId(),
                videoEventStringData.getTimestamp(),
                videoEventStringData.getRows(),
                videoEventStringData.getCols(),
                videoEventStringData.getType(),
                videoEventStringData.getData(),
                lista
        );

        return videoEventStringProcessed;
    }

The function will return original data with an additional list. That list contains info of the points(bottom-left,top-right) that are needed to represent a facial-area. . The return of map is a string containing the jsonized class mentioned above.Then the filter operation will eliminate the data(frames) that does not contain face by checking the list property. Data are sinked for further processing.

Video-Stream-Similarity

This module is responsible for exposing the similarity of faces in frames.

        DataStreamSink<String> stream = env.addSource(flinkConsumer)
                .map(new SimilarityProcess())
                .addSink(flinkProducer);

The SimilarityProcess is the following:

public class SimilarityProcess extends RichMapFunction<VideoEventStringProcessed, String> {
    @Override
    public String map(VideoEventStringProcessed videoEventStringProcessed) throws Exception {
        faceSimilarity.loadModel();
        List<Mat> corpFaces = FaceProcessor.corpFaces(videoEventStringProcessed);
        for (int i =0 ; i < corpFaces.size();i++){
            //Get Simialarity
            SimilarityProcessor.saveImage(corpFaces.get(i),videoEventStringProcessed,"/tmp/similarity/");
            faceSimilarity.whoIs(corpFaces.get(i));
        }
        //TODO:return something decent
        return "i did the similarity";
    }

By using OpenCV firstly we corp the frames, amd tjem feed them to the ML model. The whoIs function will output the similarity measurment between the input image/face and pre-detrmined ones.

#Video-Stream-Transcoding/Preprocessing The flow of this module using Flink and OpenCV is the following:

        DataStreamSink<String> stream = env.addSource(flinkConsumer)
                .keyBy("cameraId")
                .map(new TranscodeFunction(colorspace,frameWidth,frameHeight,processedImageDir))
                .addSink(flinkProducer);

Inside map function each frame will go under changes:

  @Override
public String map(VideoEventStringData videoEventStringData) throws Exception {
        //Get frame from image
        Mat data = getMat(videoEventStringData);
        Mat dataProcessed = changeFrameResolution(data,frameWidth,frameHeight);
        dataProcessed = changeFrameColorSpace(dataProcessed,colorspace);
        byte[] encodedImage = encodeData(dataProcessed);
        saveImage(dataProcessed,videoEventStringData,outputDir);

        Gson gson = new Gson();
        JsonObject obj = new JsonObject();
        //Json Object that will be send as message
        obj.addProperty("cameraId",videoEventStringData.getCameraId());
        obj.addProperty("timestamp", videoEventStringData.getTimestamp());
        obj.addProperty("rows", videoEventStringData.getRows());
        obj.addProperty("cols", videoEventStringData.getCols());
        obj.addProperty("type", videoEventStringData.getType());
        obj.addProperty("data", Base64.getEncoder().encodeToString(encodedImage));

        String json = gson.toJson(obj);


        return json;

Frameheight,Framewidth and colorspace will be changed. The result will be a json string tha will be sunk to a Kafka Producer through flink's Map-Operator.

Instructions to run Capture, Processor, Similarity modules

In order to run the code-base OpenCV needs to be installed thats why, thats why install.sh has been provided under the video-stream -processor module. Then :

  1. Run start.sh. This script creates directories and copies files needed for the modules to run sucessfully. Also run a Kafka-docker image
  2. cd into the video-stream-processor module and run
mvn clean package
java -jar target/video-stream-processor*

This will start the processor module. 3. cd to the video-processor module and follow the same flow to start capturing frames

mvn clean package
java -jar target/video-stream-capture*
  1. Same goes for video-stream similarity

Instructions to run Dockerized

  1. cd into video-processor docker run --network=host --env-file src/main/resources/processor.env processor
  2. cd into video-similarity docker run --network=host --env-file src/main/resources/similarity.env -it similarity-image
  3. cd into video-capture docker run --network=host --env-file=src/main/resources/capture.env --device=/dev/video0:/dev/video0 capture:latest

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