Mercurial Hosting > traffic-intelligence
view scripts/dltrack.py @ 1239:31173c4699d2
minor comment
author | Nicolas Saunier <nicolas.saunier@polymtl.ca> |
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date | Fri, 06 Oct 2023 17:02:32 -0400 |
parents | b684135d817f |
children | bb14f919d1cb |
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#! /usr/bin/env python3 # from https://docs.ultralytics.com/modes/track/ import sys, argparse from copy import copy from collections import Counter import numpy as np from scipy.optimize import linear_sum_assignment from ultralytics import YOLO from torch import cat from torchvision.ops import box_iou import cv2 from trafficintelligence import cvutils, moving, storage, utils parser = argparse.ArgumentParser(description='The program tracks objects using the ultralytics models and trakcers.')#, epilog = 'Either the configuration filename or the other parameters (at least video and database filenames) need to be provided.') parser.add_argument('-i', dest = 'videoFilename', help = 'name of the video file', required = True) parser.add_argument('-d', dest = 'databaseFilename', help = 'name of the Sqlite database file', required = True) parser.add_argument('-m', dest = 'detectorFilename', help = 'name of the detection model file', required = True) parser.add_argument('-t', dest = 'trackerFilename', help = 'name of the tracker file', required = True) parser.add_argument('-o', dest = 'homographyFilename', help = 'filename of the homography matrix', default = 'homography.txt') parser.add_argument('-k', dest = 'maskFilename', help = 'name of the mask file') parser.add_argument('--undistort', dest = 'undistort', help = 'undistort the video', action = 'store_true') parser.add_argument('--intrinsic', dest = 'intrinsicCameraMatrixFilename', help = 'name of the intrinsic camera file') parser.add_argument('--distortion-coefficients', dest = 'distortionCoefficients', help = 'distortion coefficients', nargs = '*', type = float) parser.add_argument('--display', dest = 'display', help = 'show the raw detection and tracking results', action = 'store_true') parser.add_argument('-f', dest = 'firstFrameNum', help = 'number of first frame number to process', type = int, default = 0) parser.add_argument('-l', dest = 'lastFrameNum', help = 'number of last frame number to process', type = int, default = float('Inf')) parser.add_argument('--bike-prop', dest = 'bikeProportion', help = 'minimum proportion of time a person classified as bike or motorbike to be classified as cyclist', type = float, default = 0.2) parser.add_argument('--cyclist-iou', dest = 'cyclistIou', help = 'IoU threshold to associate a bike and ped bounding box', type = float, default = 0.15) parser.add_argument('--cyclist-match-prop', dest = 'cyclistMatchingProportion', help = 'minimum proportion of time a bike exists and is associated with a pedestrian to be merged as cyclist', type = float, default = 0.3) parser.add_argument('--max-temp-overal', dest = 'maxTemporalOverlap', help = 'maximum proportion of time to merge 2 bikes associated with same pedestrian', type = float, default = 0.05) args = parser.parse_args() # TODO add option to refine position with mask for vehicles # use 2 x bytetrack track buffer to remove objects from existing ones # Load a model model = YOLO(args.detectorFilename) # seg yolov8x-seg.pt # seg could be used on cropped image... if can be loaded and kept in memory # model = YOLO('/home/nicolas/Research/Data/classification-models/yolo_nas_l.pt ') # AttributeError: 'YoloNAS_L' object has no attribute 'get' # Track with the model if args.display: windowName = 'frame' cv2.namedWindow(windowName, cv2.WINDOW_NORMAL) capture = cv2.VideoCapture(args.videoFilename) objects = {} featureNum = 1 frameNum = args.firstFrameNum capture.set(cv2.CAP_PROP_POS_FRAMES, frameNum) lastFrameNum = args.lastFrameNum success, frame = capture.read() results = model.track(frame, tracker=args.trackerFilename, classes=list(moving.cocoTypeNames.keys()), persist=True, verbose=False) # create object with user type and list of 3 features (bottom ones and middle) + projection while capture.isOpened() and success and frameNum <= lastFrameNum: #for frameNum, result in enumerate(results): result = results[0] if frameNum %10 == 0: print(frameNum, len(result.boxes), 'objects') for box in result.boxes: #print(box.cls, box.id, box.xyxy) if box.id is not None: # None are objects with low confidence num = int(box.id.item()) #xyxy = box.xyxy[0].tolist() if num in objects: objects[num].timeInterval.last = frameNum objects[num].features[0].timeInterval.last = frameNum objects[num].features[1].timeInterval.last = frameNum objects[num].bboxes[frameNum] = copy(box.xyxy) objects[num].userTypes.append(moving.coco2Types[int(box.cls.item())]) objects[num].features[0].tmpPositions[frameNum] = moving.Point(box.xyxy[0,0].item(), box.xyxy[0,1].item()) objects[num].features[1].tmpPositions[frameNum] = moving.Point(box.xyxy[0,2].item(), box.xyxy[0,3].item()) else: inter = moving.TimeInterval(frameNum, frameNum) objects[num] = moving.MovingObject(num, inter) objects[num].bboxes = {frameNum: copy(box.xyxy)} objects[num].userTypes = [moving.coco2Types[int(box.cls.item())]] objects[num].features = [moving.MovingObject(featureNum, copy(inter)), moving.MovingObject(featureNum+1, copy(inter))] objects[num].featureNumbers = [featureNum, featureNum+1] objects[num].features[0].tmpPositions = {frameNum: moving.Point(box.xyxy[0,0].item(), box.xyxy[0,1].item())} objects[num].features[1].tmpPositions = {frameNum: moving.Point(box.xyxy[0,2].item(), box.xyxy[0,3].item())} featureNum += 2 if args.display: cvutils.cvImshow(windowName, result.plot()) # original image in orig_img key = cv2.waitKey() if cvutils.quitKey(key): break frameNum += 1 success, frame = capture.read() results = model.track(frame, persist=True) # classification for num, obj in objects.items(): obj.setUserType(utils.mostCommon(obj.userTypes)) # improve? mix with speed? # add quality control: avoid U-turns # merge bikes and people twowheels = [num for num, obj in objects.items() if obj.getUserType() in (3,4)] pedestrians = [num for num, obj in objects.items() if obj.getUserType() == 2] def mergeObjects(obj1, obj2): obj1.features = obj1.features+obj2.features obj1.featureNumbers = obj1.featureNumbers+obj2.featureNumbers obj1.timeInterval = moving.TimeInterval(min(obj1.getFirstInstant(), obj2.getFirstInstant()), max(obj1.getLastInstant(), obj2.getLastInstant())) costs = [] for twInd in twowheels: tw = objects[twInd] tw.nBBoxes = len(tw.bboxes) twCost = [] for pedInd in pedestrians: ped = objects[pedInd] nmatches = 0 for t in tw.bboxes: if t in ped.bboxes: #print(tw.num, ped.num, t, box_iou(tw.bboxes[t], ped.bboxes[t])) if not tw.commonTimeInterval(ped).empty() and box_iou(tw.bboxes[t], ped.bboxes[t]).item() > args.cyclistIou: nmatches += 1 twCost.append(nmatches/tw.nBBoxes) costs.append(twCost) costs = -np.array(costs) # before matching, scan for pedestrians with good non-overlapping temporal match with different bikes for pedInd in range(costs.shape[1]): nMatchedBikes = (costs[:,pedInd] < -args.cyclistMatchingProportion).sum() if nMatchedBikes == 0: # peds that have no bike matching: see if they have been classified as bikes sometimes userTypeStats = Counter(obj.userTypes) if (4 in userTypeStats or (3 in userTypeStats and 4 in userTypeStats and userTypeStats[3]<=userTypeStats[4])) and userTypeStats[3]+userTypeStats[4] > args.bikeProportion*userTypeStats.total(): # 3 is motorcycle and 4 is cyclist (verif if not turning all motorbike into cyclists) obj.setUserType(4) elif nMatchedBikes > 1: # try to merge bikes first twIndices = np.nonzero(costs[:,pedInd] < -args.cyclistMatchingProportion)[0] # we have to compute temporal overlaps of all 2 wheels among themselves, then remove the ones with the most overlap (sum over column) one by one until there is little left nTwoWheels = len(twIndices) twTemporalOverlaps = np.zeros((nTwoWheels,nTwoWheels)) for i in range(nTwoWheels): for j in range(i): twi = objects[twowheels[twIndices[i]]] twj = objects[twowheels[twIndices[j]]] twTemporalOverlaps[i,j] = len(set(twi.bboxes).intersection(set(twj.bboxes)))/max(len(twi.bboxes), len(twj.bboxes)) #twTemporalOverlaps[j,i] = twTemporalOverlaps[i,j] tw2merge = list(range(nTwoWheels)) while len(tw2merge)>0 and (twTemporalOverlaps[np.ix_(tw2merge, tw2merge)] > args.maxTemporalOverlap).sum(0).max() >= 2: i = (twTemporalOverlaps[np.ix_(tw2merge, tw2merge)] > args.maxTemporalOverlap).sum(0).argmax() del tw2merge[i] twIndices = [twIndices[i] for i in tw2merge] tw1 = objects[twowheels[twIndices[0]]] twCost = costs[twIndices[0],:]*tw1.nBBoxes nBBoxes = tw1.nBBoxes for twInd in twIndices[1:]: mergeObjects(tw1, objects[twowheels[twInd]]) twCost = twCost + costs[twInd,:]*objects[twowheels[twInd]].nBBoxes nBBoxes += objects[twowheels[twInd]].nBBoxes twIndicesToKeep = list(range(costs.shape[0])) for twInd in twIndices[1:]: twIndicesToKeep.remove(twInd) del objects[twowheels[twInd]] twowheels = [twowheels[i] for i in twIndicesToKeep] costs = costs[twIndicesToKeep,:] twIndices, matchingPedIndices = linear_sum_assignment(costs) for twInd, pedInd in zip(twIndices, matchingPedIndices): # caution indices in the cost matrix if -costs[twInd, pedInd] >= args.cyclistMatchingProportion: tw = objects[twowheels[twInd]] ped = objects[pedestrians[pedInd]] mergeObjects(tw, ped) del objects[pedestrians[pedInd]] #TODO Verif overlap piéton vélo : si long hors overlap, changement mode (trouver exemples) # interpolate and generate velocity (?) for the features (bboxes) before saving for num, obj in objects.items(): #obj.features[1].timeInterval = copy(obj.getTimeInterval()) for f in obj.getFeatures(): if f.length() != len(f.tmpPositions): # interpolate f.positions = moving.Trajectory.fromPointDict(f.tmpPositions) #obj.features[1].positions = moving.Trajectory.fromPointDict(obj.features[1].tmpPositions) else: f.positions = moving.Trajectory.fromPointList(list(f.tmpPositions.values())) #obj.features[1].positions = moving.Trajectory.fromPointList(list(obj.features[1].tmpPositions.values())) storage.saveTrajectoriesToSqlite(args.databaseFilename, list(objects.values()), 'object') # todo save bbox and mask to study localization / representation # apply quality checks deviation and acceleration bounds? # def mergeBBoxes(tw, ped): # 'merges ped into tw (2nd obj into first obj)' # timeInstants = set(tw.bboxes).union(set(ped.bboxes)) # for t in timeInstants: # if t in tw.bboxes and t in ped.bboxes: # tw.features[0].tmpPositions[t] = moving.Point(min(tw.features[0].tmpPositions[t].x, ped.features[0].tmpPositions[t].x), # min(tw.features[0].tmpPositions[t].y, ped.features[0].tmpPositions[t].y)) # tw.features[1].tmpPositions[t] = moving.Point(max(tw.features[1].tmpPositions[t].x, ped.features[1].tmpPositions[t].x), # max(tw.features[1].tmpPositions[t].y, ped.features[1].tmpPositions[t].y)) # elif t in ped.bboxes: # tw.features[0].tmpPositions[t] = ped.features[0].tmpPositions[t] # tw.features[1].tmpPositions[t] = ped.features[1].tmpPositions[t] # tw.timeInterval = moving.TimeInterval(min(tw.getFirstInstant(), ped.getFirstInstant()), max(tw.getLastInstant(), ped.getLastInstant()))