import * as tf from '@tensorflow/tfjs/dist/tf.es2017.js'; import { BoundingBox } from '../classes/BoundingBox'; import { Dimensions } from '../classes/Dimensions'; import { ObjectDetection } from '../classes/ObjectDetection'; import { convLayer } from '../common'; import { ConvParams, SeparableConvParams } from '../common/types'; import { toNetInput } from '../dom'; import { NetInput } from '../dom/NetInput'; import { TNetInput } from '../dom/types'; import { NeuralNetwork } from '../NeuralNetwork'; import { sigmoid } from '../ops'; import { nonMaxSuppression } from '../ops/nonMaxSuppression'; import { normalize } from '../ops/normalize'; import { TinyYolov2Config, validateConfig } from './config'; import { convWithBatchNorm } from './convWithBatchNorm'; import { depthwiseSeparableConv } from './depthwiseSeparableConv'; import { extractParams } from './extractParams'; import { extractParamsFromWeigthMap } from './extractParamsFromWeigthMap'; import { leaky } from './leaky'; import { ITinyYolov2Options, TinyYolov2Options } from './TinyYolov2Options'; import { DefaultTinyYolov2NetParams, MobilenetParams, TinyYolov2NetParams } from './types'; export class TinyYolov2Base extends NeuralNetwork { public static DEFAULT_FILTER_SIZES = [ 3, 16, 32, 64, 128, 256, 512, 1024, 1024 ] private _config: TinyYolov2Config constructor(config: TinyYolov2Config) { super('TinyYolov2') validateConfig(config) this._config = config } public get config(): TinyYolov2Config { return this._config } public get withClassScores(): boolean { return this.config.withClassScores || this.config.classes.length > 1 } public get boxEncodingSize(): number { return 5 + (this.withClassScores ? this.config.classes.length : 0) } public runTinyYolov2(x: tf.Tensor4D, params: DefaultTinyYolov2NetParams): tf.Tensor4D { let out = convWithBatchNorm(x, params.conv0) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = convWithBatchNorm(out, params.conv1) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = convWithBatchNorm(out, params.conv2) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = convWithBatchNorm(out, params.conv3) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = convWithBatchNorm(out, params.conv4) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = convWithBatchNorm(out, params.conv5) out = tf.maxPool(out, [2, 2], [1, 1], 'same') out = convWithBatchNorm(out, params.conv6) out = convWithBatchNorm(out, params.conv7) return convLayer(out, params.conv8, 'valid', false) } public runMobilenet(x: tf.Tensor4D, params: MobilenetParams): tf.Tensor4D { let out = this.config.isFirstLayerConv2d ? leaky(convLayer(x, params.conv0 as ConvParams, 'valid', false)) : depthwiseSeparableConv(x, params.conv0 as SeparableConvParams) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = depthwiseSeparableConv(out, params.conv1) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = depthwiseSeparableConv(out, params.conv2) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = depthwiseSeparableConv(out, params.conv3) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = depthwiseSeparableConv(out, params.conv4) out = tf.maxPool(out, [2, 2], [2, 2], 'same') out = depthwiseSeparableConv(out, params.conv5) out = tf.maxPool(out, [2, 2], [1, 1], 'same') out = params.conv6 ? depthwiseSeparableConv(out, params.conv6) : out out = params.conv7 ? depthwiseSeparableConv(out, params.conv7) : out return convLayer(out, params.conv8, 'valid', false) } public forwardInput(input: NetInput, inputSize: number): tf.Tensor4D { const { params } = this if (!params) { throw new Error('TinyYolov2 - load model before inference') } return tf.tidy(() => { // let batchTensor = input.toBatchTensor(inputSize, false).toFloat() let batchTensor = tf.cast(input.toBatchTensor(inputSize, false), 'float32'); batchTensor = this.config.meanRgb ? normalize(batchTensor, this.config.meanRgb) : batchTensor batchTensor = batchTensor.div(tf.scalar(256)) as tf.Tensor4D return this.config.withSeparableConvs ? this.runMobilenet(batchTensor, params as MobilenetParams) : this.runTinyYolov2(batchTensor, params as DefaultTinyYolov2NetParams) }) } public async forward(input: TNetInput, inputSize: number): Promise { return await this.forwardInput(await toNetInput(input), inputSize) } public async detect(input: TNetInput, forwardParams: ITinyYolov2Options = {}): Promise { const { inputSize, scoreThreshold } = new TinyYolov2Options(forwardParams) const netInput = await toNetInput(input) const out = await this.forwardInput(netInput, inputSize) const out0 = tf.tidy(() => tf.unstack(out)[0].expandDims()) as tf.Tensor4D const inputDimensions = { width: netInput.getInputWidth(0), height: netInput.getInputHeight(0) } const results = await this.extractBoxes(out0, netInput.getReshapedInputDimensions(0), scoreThreshold) out.dispose() out0.dispose() const boxes = results.map(res => res.box) const scores = results.map(res => res.score) const classScores = results.map(res => res.classScore) const classNames = results.map(res => this.config.classes[res.label]) const indices = nonMaxSuppression( boxes.map(box => box.rescale(inputSize)), scores, this.config.iouThreshold, true ) const detections = indices.map(idx => new ObjectDetection( scores[idx], classScores[idx], classNames[idx], boxes[idx], inputDimensions ) ) return detections } protected getDefaultModelName(): string { return '' } protected extractParamsFromWeigthMap(weightMap: tf.NamedTensorMap) { return extractParamsFromWeigthMap(weightMap, this.config) } protected extractParams(weights: Float32Array) { const filterSizes = this.config.filterSizes || TinyYolov2Base.DEFAULT_FILTER_SIZES const numFilters = filterSizes ? filterSizes.length : undefined if (numFilters !== 7 && numFilters !== 8 && numFilters !== 9) { throw new Error(`TinyYolov2 - expected 7 | 8 | 9 convolutional filters, but found ${numFilters} filterSizes in config`) } return extractParams(weights, this.config, this.boxEncodingSize, filterSizes) } protected async extractBoxes( outputTensor: tf.Tensor4D, inputBlobDimensions: Dimensions, scoreThreshold?: number ) { const { width, height } = inputBlobDimensions const inputSize = Math.max(width, height) const correctionFactorX = inputSize / width const correctionFactorY = inputSize / height const numCells = outputTensor.shape[1] const numBoxes = this.config.anchors.length const [boxesTensor, scoresTensor, classScoresTensor] = tf.tidy(() => { const reshaped = outputTensor.reshape([numCells, numCells, numBoxes, this.boxEncodingSize]) const boxes = reshaped.slice([0, 0, 0, 0], [numCells, numCells, numBoxes, 4]) const scores = reshaped.slice([0, 0, 0, 4], [numCells, numCells, numBoxes, 1]) const classScores = this.withClassScores ? tf.softmax(reshaped.slice([0, 0, 0, 5], [numCells, numCells, numBoxes, this.config.classes.length]), 3) : tf.scalar(0) return [boxes, scores, classScores] }) const results = [] as any; const scoresData = await scoresTensor.array() const boxesData = await boxesTensor.array() for (let row = 0; row < numCells; row ++) { for (let col = 0; col < numCells; col ++) { for (let anchor = 0; anchor < numBoxes; anchor ++) { const score = sigmoid(scoresData[row][col][anchor][0]); if (!scoreThreshold || score > scoreThreshold) { const ctX = ((col + sigmoid(boxesData[row][col][anchor][0])) / numCells) * correctionFactorX const ctY = ((row + sigmoid(boxesData[row][col][anchor][1])) / numCells) * correctionFactorY const width = ((Math.exp(boxesData[row][col][anchor][2]) * this.config.anchors[anchor].x) / numCells) * correctionFactorX const height = ((Math.exp(boxesData[row][col][anchor][3]) * this.config.anchors[anchor].y) / numCells) * correctionFactorY const x = (ctX - (width / 2)) const y = (ctY - (height / 2)) const pos = { row, col, anchor } const { classScore, label } = this.withClassScores ? await this.extractPredictedClass(classScoresTensor as tf.Tensor4D, pos) : { classScore: 1, label: 0 } results.push({ box: new BoundingBox(x, y, x + width, y + height), score: score, classScore: score * classScore, label, ...pos }) } } } } boxesTensor.dispose() scoresTensor.dispose() classScoresTensor.dispose() return results } private async extractPredictedClass(classesTensor: tf.Tensor4D, pos: { row: number, col: number, anchor: number },) { const { row, col, anchor } = pos const classesData = await classesTensor.array() return Array(this.config.classes.length).fill(0) .map((_, i) => classesData[row][col][anchor][i]) .map((classScore, label) => ({ classScore, label })) .reduce((max, curr) => max.classScore > curr.classScore ? max : curr) } }