tflite_flutter_helper 0.1.0

Easy, fast processing and manipulation input and output of TensorFlow Lite Models.

TensorFlow Lite Flutter Helper Library

Makes use of TensorFlow Lite Interpreter on Flutter easier by providing simple architecture for processing and manipulating input and output of TFLite Models.

API design and documentation is identical to the TensorFlow Lite Android Support Library.

Getting Started

Setup TFLite Flutter Plugin

Include tflite_flutter: ^<latest_version> in your pubspec.yaml. Follow the initial setup instructions given here

Image Processing

TFLite Helper depends on flutter image package internally for Image Processing.

Basic image manipulation and conversion

The TensorFlow Lite Support Library has a suite of basic image manipulation methods such as crop and resize. To use it, create an ImageProcessor and add the required operations. To convert the image into the tensor format required by the TensorFlow Lite interpreter, create a TensorImage to be used as input:

// Initialization code
// Create an ImageProcessor with all ops required. For more ops, please
// refer to the ImageProcessor Ops section in this README.
ImageProcessor imageProcessor = ImageProcessorBuilder()
  .add(ResizeOp(224, 224, ResizeMethod.NEAREST_NEIGHBOUR))
  .build();

// Create a TensorImage object from a File
TensorImage tensorImage = TensorImage.fromFile(imageFile);

// Preprocess the image.
// The image for imageFile will be resized to (224, 224)
tensorImage = imageProcessor.process(tensorImage);

Create output objects and run the model

// Create a container for the result and specify that this is a quantized model.
// Hence, the 'DataType' is defined as UINT8 (8-bit unsigned integer)
TensorBuffer probabilityBuffer =
    TensorBuffer.createFixedSize(<int>[1, 1001], TfLiteType.uint8);

Loading the model and running inference:

import 'package:tflite_flutter/tflite_flutter.dart';

try {
    // Create interpreter from asset.
    Interpreter interpreter =
        await Interpreter.fromAsset("mobilenet_v1_1.0_224_quant.tflite");
    interpreter.run(tensorImage.buffer, probabilityBuffer.buffer);
} catch (e) {
    print('Error loading model: ' + e.toString());
}

Accessing the result

Developers can access the output directly through probabilityBuffer.getDoubleList(). If the model produces a quantized output, remember to convert the result. For the MobileNet quantized model, the developer needs to divide each output value by 255 to obtain the probability ranging from 0 (least likely) to 1 (most likely) for each category.

Optional: Mapping results to labels

Developers can also optionally map the results to labels. First, copy the text file containing labels into the module’s assets directory. Next, load the label file using the following code:

List<String> labels = await FileUtil.loadLabels("assets/labels.txt");

The following snippet demonstrates how to associate the probabilities with category labels:

TensorLabel tensorLabel = TensorLabel.fromList(
      labels, probabilityProcessor.process(probabilityBuffer));

Map<String, double> doubleMap = tensorLabel.getMapWithFloatValue();

ImageProcessor Architecture

The design of the ImageProcessor allowed the image manipulation operations to be defined up front and optimised during the build process. The ImageProcessor currently supports three basic preprocessing operations:

int cropSize = min(_inputImage.height, _inputImage.width);

ImageProcessor imageProcessor = ImageProcessorBuilder()
    // Center crop the image to the largest square possible
    .add(ResizeWithCropOrPadOp(cropSize, cropSize))
    // Resize using Bilinear or Nearest neighbour
    .add(ResizeOp(224, 224, ResizeMethod.NEAREST_NEIGHBOUR))
    // Rotation clockwise in 90 degree increments
    .add(Rot90Op(rotationDegrees ~/ 90))
    .add(NormalizeOp(127.5, 127.5))
    .add(QuantizeOp(128.0, 1 / 128.0))
    .build();

See more details here about normalization and quantization.

Quantization

The TensorProcessor can be used to quantize input tensors or dequantize output tensors. For example, when processing a quantized output TensorBuffer, the developer can use DequantizeOp to dequantize the result to a floating point probability between 0 and 1:

// Post-processor which dequantize the result
TensorProcessor probabilityProcessor =
    TensorProcessorBuilder().add(DequantizeOp(0, 1 / 255.0)).build();
TensorBuffer dequantizedBuffer =
    probabilityProcessor.process(probabilityBuffer);

Reading Qunatization Params

// Quantization Params of input tensor at index 0
QuantizationParams inputParams = interpreter.getInputTensor(0).params;

// Quantization Params of output tensor at index 0
QuantizationParams outputParams = interpreter.getOutputTensor(0).params;

Coming Soon

• More image operations
• Support for text-related applications.
• Support for audio-related applications.