use of com.simiacryptus.mindseye.eval.SampledTrainable in project MindsEye by SimiaCryptus.
the class ImageDecompositionLab method train.
/**
* Train.
*
* @param log the log
* @param monitor the monitor
* @param network the network
* @param data the data
* @param timeoutMinutes the timeout minutes
* @param mask the mask
*/
protected void train(@Nonnull final NotebookOutput log, final TrainingMonitor monitor, final Layer network, @Nonnull final Tensor[][] data, final int timeoutMinutes, final boolean... mask) {
log.out("Training for %s minutes, mask=%s", timeoutMinutes, Arrays.toString(mask));
log.code(() -> {
@Nonnull SampledTrainable trainingSubject = new SampledArrayTrainable(data, network, data.length);
trainingSubject = (SampledTrainable) ((TrainableDataMask) trainingSubject).setMask(mask);
@Nonnull final ValidatingTrainer validatingTrainer = new ValidatingTrainer(trainingSubject, new ArrayTrainable(data, network)).setMaxTrainingSize(data.length).setMinTrainingSize(5).setMonitor(monitor).setTimeout(timeoutMinutes, TimeUnit.MINUTES).setMaxIterations(1000);
validatingTrainer.getRegimen().get(0).setOrientation(new GradientDescent()).setLineSearchFactory(name -> name.equals(QQN.CURSOR_NAME) ? new QuadraticSearch().setCurrentRate(1.0) : new QuadraticSearch().setCurrentRate(1.0));
validatingTrainer.run();
});
}
use of com.simiacryptus.mindseye.eval.SampledTrainable in project MindsEye by SimiaCryptus.
the class EncodingProblem method run.
@Nonnull
@Override
public EncodingProblem run(@Nonnull final NotebookOutput log) {
@Nonnull final TrainingMonitor monitor = TestUtil.getMonitor(history);
Tensor[][] trainingData;
try {
trainingData = data.trainingData().map(labeledObject -> {
return new Tensor[] { new Tensor(features).set(this::random), labeledObject.data };
}).toArray(i -> new Tensor[i][]);
} catch (@Nonnull final IOException e) {
throw new RuntimeException(e);
}
@Nonnull final DAGNetwork imageNetwork = revFactory.vectorToImage(log, features);
log.h3("Network Diagram");
log.code(() -> {
return Graphviz.fromGraph(TestUtil.toGraph(imageNetwork)).height(400).width(600).render(Format.PNG).toImage();
});
@Nonnull final PipelineNetwork trainingNetwork = new PipelineNetwork(2);
@Nullable final DAGNode image = trainingNetwork.add(imageNetwork, trainingNetwork.getInput(0));
@Nullable final DAGNode softmax = trainingNetwork.add(new SoftmaxActivationLayer(), trainingNetwork.getInput(0));
trainingNetwork.add(new SumInputsLayer(), trainingNetwork.add(new EntropyLossLayer(), softmax, softmax), trainingNetwork.add(new NthPowerActivationLayer().setPower(1.0 / 2.0), trainingNetwork.add(new MeanSqLossLayer(), image, trainingNetwork.getInput(1))));
log.h3("Training");
log.p("We start by training apply a very small population to improve initial convergence performance:");
TestUtil.instrumentPerformance(trainingNetwork);
@Nonnull final Tensor[][] primingData = Arrays.copyOfRange(trainingData, 0, 1000);
@Nonnull final ValidatingTrainer preTrainer = optimizer.train(log, (SampledTrainable) new SampledArrayTrainable(primingData, trainingNetwork, trainingSize, batchSize).setMinSamples(trainingSize).setMask(true, false), new ArrayTrainable(primingData, trainingNetwork, batchSize), monitor);
log.code(() -> {
preTrainer.setTimeout(timeoutMinutes / 2, TimeUnit.MINUTES).setMaxIterations(batchSize).run();
});
TestUtil.extractPerformance(log, trainingNetwork);
log.p("Then our main training phase:");
TestUtil.instrumentPerformance(trainingNetwork);
@Nonnull final ValidatingTrainer mainTrainer = optimizer.train(log, (SampledTrainable) new SampledArrayTrainable(trainingData, trainingNetwork, trainingSize, batchSize).setMinSamples(trainingSize).setMask(true, false), new ArrayTrainable(trainingData, trainingNetwork, batchSize), monitor);
log.code(() -> {
mainTrainer.setTimeout(timeoutMinutes, TimeUnit.MINUTES).setMaxIterations(batchSize).run();
});
TestUtil.extractPerformance(log, trainingNetwork);
if (!history.isEmpty()) {
log.code(() -> {
return TestUtil.plot(history);
});
log.code(() -> {
return TestUtil.plotTime(history);
});
}
try {
@Nonnull String filename = log.getName().toString() + EncodingProblem.modelNo++ + "_plot.png";
ImageIO.write(Util.toImage(TestUtil.plot(history)), "png", log.file(filename));
log.appendFrontMatterProperty("result_plot", filename, ";");
} catch (IOException e) {
throw new RuntimeException(e);
}
// log.file()
@Nonnull final String modelName = "encoding_model_" + EncodingProblem.modelNo++ + ".json";
log.appendFrontMatterProperty("result_model", modelName, ";");
log.p("Saved model as " + log.file(trainingNetwork.getJson().toString(), modelName, modelName));
log.h3("Results");
@Nonnull final PipelineNetwork testNetwork = new PipelineNetwork(2);
testNetwork.add(imageNetwork, testNetwork.getInput(0));
log.code(() -> {
@Nonnull final TableOutput table = new TableOutput();
Arrays.stream(trainingData).map(tensorArray -> {
@Nullable final Tensor predictionSignal = testNetwork.eval(tensorArray).getData().get(0);
@Nonnull final LinkedHashMap<CharSequence, Object> row = new LinkedHashMap<>();
row.put("Source", log.image(tensorArray[1].toImage(), ""));
row.put("Echo", log.image(predictionSignal.toImage(), ""));
return row;
}).filter(x -> null != x).limit(10).forEach(table::putRow);
return table;
});
log.p("Learned Model Statistics:");
log.code(() -> {
@Nonnull final ScalarStatistics scalarStatistics = new ScalarStatistics();
trainingNetwork.state().stream().flatMapToDouble(x -> Arrays.stream(x)).forEach(v -> scalarStatistics.add(v));
return scalarStatistics.getMetrics();
});
log.p("Learned Representation Statistics:");
log.code(() -> {
@Nonnull final ScalarStatistics scalarStatistics = new ScalarStatistics();
Arrays.stream(trainingData).flatMapToDouble(row -> Arrays.stream(row[0].getData())).forEach(v -> scalarStatistics.add(v));
return scalarStatistics.getMetrics();
});
log.p("Some rendered unit vectors:");
for (int featureNumber = 0; featureNumber < features; featureNumber++) {
@Nonnull final Tensor input = new Tensor(features).set(featureNumber, 1);
@Nullable final Tensor tensor = imageNetwork.eval(input).getData().get(0);
TestUtil.renderToImages(tensor, true).forEach(img -> {
log.out(log.image(img, ""));
});
}
return this;
}
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