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evalInstanceLevelSemanticLabeling.py
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evalInstanceLevelSemanticLabeling.py
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#!/usr/bin/python
#
# The evaluation script for instance-level semantic labeling.
# We use this script to evaluate your approach on the test set.
# You can use the script to evaluate on the validation set.
#
# Please check the description of the "getPrediction" method below
# and set the required environment variables as needed, such that
# this script can locate your results.
# If the default implementation of the method works, then it's most likely
# that our evaluation server will be able to process your results as well.
#
# To run this script, make sure that your results contain text files
# (one for each test set image) with the content:
# relPathPrediction1 labelIDPrediction1 confidencePrediction1
# relPathPrediction2 labelIDPrediction2 confidencePrediction2
# relPathPrediction3 labelIDPrediction3 confidencePrediction3
# ...
#
# - The given paths "relPathPrediction" point to images that contain
# binary masks for the described predictions, where any non-zero is
# part of the predicted instance. The paths must not contain spaces,
# must be relative to the root directory and must point to locations
# within the root directory.
# - The label IDs "labelIDPrediction" specify the class of that mask,
# encoded as defined in labels.py. Note that the regular ID is used,
# not the train ID.
# - The field "confidencePrediction" is a float value that assigns a
# confidence score to the mask.
#
# Note that this tool creates a file named "gtInstances.json" during its
# first run. This file helps to speed up computation and should be deleted
# whenever anything changes in the ground truth annotations or anything
# goes wrong.
# python imports
from __future__ import print_function, absolute_import, division
import os, sys
import fnmatch
from copy import deepcopy
# Cityscapes imports
from cityscapesscripts.helpers.csHelpers import *
from cityscapesscripts.evaluation.instances2dict import instances2dict
###################################
# PLEASE READ THESE INSTRUCTIONS!!!
###################################
# Provide the prediction file for the given ground truth file.
# Please read the instructions above for a description of
# the result file.
#
# The current implementation expects the results to be in a certain root folder.
# This folder is one of the following with decreasing priority:
# - environment variable CITYSCAPES_RESULTS
# - environment variable CITYSCAPES_DATASET/results
# - ../../results/"
# (Remember to set the variables using "export CITYSCAPES_<VARIABLE>=<path>".)
#
# Within the root folder, a matching prediction file is recursively searched.
# A file matches, if the filename follows the pattern
# <city>_123456_123456*.txt
# for a ground truth filename
# <city>_123456_123456_gtFine_instanceIds.png
def getPrediction( groundTruthFile , args ):
# determine the prediction path, if the method is first called
if not args.predictionPath:
rootPath = None
if 'CITYSCAPES_RESULTS' in os.environ:
rootPath = os.environ['CITYSCAPES_RESULTS']
elif 'CITYSCAPES_DATASET' in os.environ:
rootPath = os.path.join( os.environ['CITYSCAPES_DATASET'] , "results" )
else:
rootPath = os.path.join(os.path.dirname(os.path.realpath(__file__)),'..','..','results')
if not os.path.isdir(rootPath):
printError("Could not find a result root folder. Please read the instructions of this method.")
args.predictionPath = os.path.abspath(rootPath)
# walk the prediction path, if not happened yet
if not args.predictionWalk:
walk = []
for root, dirnames, filenames in os.walk(args.predictionPath):
walk.append( (root,filenames) )
args.predictionWalk = walk
csFile = getCsFileInfo(groundTruthFile)
filePattern = "{}_{}_{}*.txt".format( csFile.city , csFile.sequenceNb , csFile.frameNb )
predictionFile = None
for root, filenames in args.predictionWalk:
for filename in fnmatch.filter(filenames, filePattern):
if not predictionFile:
predictionFile = os.path.join(root, filename)
else:
printError("Found multiple predictions for ground truth {}".format(groundTruthFile))
if not predictionFile:
printError("Found no prediction for ground truth {}".format(groundTruthFile))
return predictionFile
######################
# Parameters
######################
# A dummy class to collect all bunch of data
class CArgs(object):
pass
# And a global object of that class
args = CArgs()
# Where to look for Cityscapes
if 'CITYSCAPES_DATASET' in os.environ:
args.cityscapesPath = os.environ['CITYSCAPES_DATASET']
else:
args.cityscapesPath = os.path.join(os.path.dirname(os.path.realpath(__file__)),'..','..')
# Parameters that should be modified by user
args.exportFile = os.path.join( args.cityscapesPath , "evaluationResults" , "resultInstanceLevelSemanticLabeling.json" )
args.groundTruthSearch = os.path.join( args.cityscapesPath , "gtFine" , "val" , "*", "*_gtFine_instanceIds.png" )
# overlaps for evaluation
args.overlaps = np.arange(0.5,1.,0.05)
# minimum region size for evaluation [pixels]
args.minRegionSizes = np.array( [ 100 , 1000 , 1000 ] )
# distance thresholds [m]
args.distanceThs = np.array( [ float('inf') , 100 , 50 ] )
# distance confidences
args.distanceConfs = np.array( [ -float('inf') , 0.5 , 0.5 ] )
args.gtInstancesFile = os.path.join(os.path.dirname(os.path.realpath(__file__)),'gtInstances.json')
args.distanceAvailable = False
args.JSONOutput = True
args.quiet = False
args.csv = False
args.colorized = True
args.instLabels = []
# store some parameters for finding predictions in the args variable
# the values are filled when the method getPrediction is first called
args.predictionPath = None
args.predictionWalk = None
# Determine the labels that have instances
def setInstanceLabels(args):
args.instLabels = []
for label in labels:
if label.hasInstances and not label.ignoreInEval:
args.instLabels.append(label.name)
# Read prediction info
# imgFile, predId, confidence
def readPredInfo(predInfoFileName,args):
predInfo = {}
if (not os.path.isfile(predInfoFileName)):
printError("Infofile '{}' for the predictions not found.".format(predInfoFileName))
with open(predInfoFileName, 'r') as f:
for line in f:
splittedLine = line.split(" ")
if len(splittedLine) != 3:
printError( "Invalid prediction file. Expected content: relPathPrediction1 labelIDPrediction1 confidencePrediction1" )
if os.path.isabs(splittedLine[0]):
printError( "Invalid prediction file. First entry in each line must be a relative path." )
filename = os.path.join( os.path.dirname(predInfoFileName),splittedLine[0] )
filename = os.path.abspath( filename )
# check if that file is actually somewhere within the prediction root
if os.path.commonprefix( [filename,args.predictionPath] ) != args.predictionPath:
printError( "Predicted mask {} in prediction text file {} points outside of prediction path.".format(filename,predInfoFileName) )
imageInfo = {}
imageInfo["labelID"] = int(float(splittedLine[1]))
imageInfo["conf"] = float(splittedLine[2])
predInfo[filename] = imageInfo
return predInfo
# Routine to read ground truth image
def readGTImage(gtImageFileName,args):
return Image.open(gtImageFileName)
# either read or compute a dictionary of all ground truth instances
def getGtInstances(groundTruthList,args):
gtInstances = {}
# if there is a global statistics json, then load it
if (os.path.isfile(args.gtInstancesFile)):
if not args.quiet:
print("Loading ground truth instances from JSON.")
with open(args.gtInstancesFile) as json_file:
gtInstances = json.load(json_file)
# otherwise create it
else:
if (not args.quiet):
print("Creating ground truth instances from png files.")
gtInstances = instances2dict(groundTruthList,not args.quiet)
writeDict2JSON(gtInstances, args.gtInstancesFile)
return gtInstances
# Filter instances, ignore labels without instances
def filterGtInstances(singleImageInstances,args):
instanceDict = {}
for labelName in singleImageInstances:
if not labelName in args.instLabels:
continue
instanceDict[labelName] = singleImageInstances[labelName]
return instanceDict
# match ground truth instances with predicted instances
def matchGtWithPreds(predictionList,groundTruthList,gtInstances,args):
matches = {}
if not args.quiet:
print("Matching {} pairs of images...".format(len(predictionList)))
count = 0
for (pred,gt) in zip(predictionList,groundTruthList):
# key for dicts
dictKey = os.path.abspath(gt)
# Read input files
gtImage = readGTImage(gt,args)
predInfo = readPredInfo(pred,args)
# Get and filter ground truth instances
unfilteredInstances = gtInstances[ dictKey ]
curGtInstancesOrig = filterGtInstances(unfilteredInstances,args)
# Try to assign all predictions
(curGtInstances,curPredInstances) = assignGt2Preds(curGtInstancesOrig, gtImage, predInfo, args)
# append to global dict
matches[ dictKey ] = {}
matches[ dictKey ]["groundTruth"] = curGtInstances
matches[ dictKey ]["prediction"] = curPredInstances
count += 1
if not args.quiet:
print("\rImages Processed: {}".format(count), end=' ')
sys.stdout.flush()
if not args.quiet:
print("")
return matches
# For a given frame, assign all predicted instances to ground truth instances
def assignGt2Preds(gtInstancesOrig, gtImage, predInfo, args):
# In this method, we create two lists
# - predInstances: contains all predictions and their associated gt
# - gtInstances: contains all gt instances and their associated predictions
predInstances = {}
predInstCount = 0
# Create a prediction array for each class
for label in args.instLabels:
predInstances[label] = []
# We already know about the gt instances
# Add the matching information array
gtInstances = deepcopy(gtInstancesOrig)
for label in gtInstances:
for gt in gtInstances[label]:
gt["matchedPred"] = []
# Make the gt a numpy array
gtNp = np.array(gtImage)
# Get a mask of void labels in the groundtruth
voidLabelIDList = []
for label in labels:
if label.ignoreInEval:
voidLabelIDList.append(label.id)
boolVoid = np.in1d(gtNp, voidLabelIDList).reshape(gtNp.shape)
# Loop through all prediction masks
for predImageFile in predInfo:
# Additional prediction info
labelID = predInfo[predImageFile]["labelID"]
predConf = predInfo[predImageFile]["conf"]
# label name
labelName = id2label[int(labelID)].name
# maybe we are not interested in that label
if not labelName in args.instLabels:
continue
# Read the mask
predImage = Image.open(predImageFile)
predImage = predImage.convert("L")
predNp = np.array(predImage)
# make the image really binary, i.e. everything non-zero is part of the prediction
boolPredInst = predNp != 0
predPixelCount = np.count_nonzero( boolPredInst )
# skip if actually empty
if not predPixelCount:
continue
# The information we want to collect for this instance
predInstance = {}
predInstance["imgName"] = predImageFile
predInstance["predID"] = predInstCount
predInstance["labelID"] = int(labelID)
predInstance["pixelCount"] = predPixelCount
predInstance["confidence"] = predConf
# Determine the number of pixels overlapping void
predInstance["voidIntersection"] = np.count_nonzero( np.logical_and(boolVoid, boolPredInst) )
# A list of all overlapping ground truth instances
matchedGt = []
# Loop through all ground truth instances with matching label
# This list contains all ground truth instances that distinguish groups
# We do not know, if a certain instance is actually a single object or a group
# e.g. car or cargroup
# However, for now we treat both the same and do the rest later
for (gtNum,gtInstance) in enumerate(gtInstancesOrig[labelName]):
intersection = np.count_nonzero( np.logical_and( gtNp == gtInstance["instID"] , boolPredInst) )
# If they intersect add them as matches to both dicts
if (intersection > 0):
gtCopy = gtInstance.copy()
predCopy = predInstance.copy()
# let the two know their intersection
gtCopy["intersection"] = intersection
predCopy["intersection"] = intersection
# append ground truth to matches
matchedGt.append(gtCopy)
# append prediction to ground truth instance
gtInstances[labelName][gtNum]["matchedPred"].append(predCopy)
predInstance["matchedGt"] = matchedGt
predInstCount += 1
predInstances[labelName].append(predInstance)
return (gtInstances,predInstances)
def evaluateMatches(matches, args):
# In the end, we need two vectors for each class and for each overlap
# The first vector (y_true) is binary and is 1, where the ground truth says true,
# and is 0 otherwise.
# The second vector (y_score) is float [0...1] and represents the confidence of
# the prediction.
#
# We represent the following cases as:
# | y_true | y_score
# gt instance with matched prediction | 1 | confidence
# gt instance w/o matched prediction | 1 | 0.0
# false positive prediction | 0 | confidence
#
# The current implementation makes only sense for an overlap threshold >= 0.5,
# since only then, a single prediction can either be ignored or matched, but
# never both. Further, it can never match to two gt instances.
# For matching, we vary the overlap and do the following steps:
# 1.) remove all predictions that satisfy the overlap criterion with an ignore region (either void or *group)
# 2.) remove matches that do not satisfy the overlap
# 3.) mark non-matched predictions as false positive
# AP
overlaps = args.overlaps
# region size
minRegionSizes = args.minRegionSizes
# distance thresholds
distThs = args.distanceThs
# distance confidences
distConfs = args.distanceConfs
# only keep the first, if distances are not available
if not args.distanceAvailable:
minRegionSizes = [ minRegionSizes[0] ]
distThs = [ distThs [0] ]
distConfs = [ distConfs [0] ]
# last three must be of same size
if len(distThs) != len(minRegionSizes):
printError("Number of distance thresholds and region sizes different")
if len(distThs) != len(distConfs):
printError("Number of distance thresholds and confidences different")
# Here we hold the results
# First dimension is class, second overlap
ap = np.zeros( (len(distThs) , len(args.instLabels) , len(overlaps)) , np.float )
for dI,(minRegionSize,distanceTh,distanceConf) in enumerate(zip(minRegionSizes,distThs,distConfs)):
for (oI,overlapTh) in enumerate(overlaps):
for (lI,labelName) in enumerate(args.instLabels):
y_true = np.empty( 0 )
y_score = np.empty( 0 )
# count hard false negatives
hardFns = 0
# found at least one gt and predicted instance?
haveGt = False
havePred = False
for img in matches:
predInstances = matches[img]["prediction" ][labelName]
gtInstances = matches[img]["groundTruth"][labelName]
# filter groups in ground truth
gtInstances = [ gt for gt in gtInstances if gt["instID"]>=1000 and gt["pixelCount"]>=minRegionSize and gt["medDist"]<=distanceTh and gt["distConf"]>=distanceConf ]
if gtInstances:
haveGt = True
if predInstances:
havePred = True
curTrue = np.ones ( len(gtInstances) )
curScore = np.ones ( len(gtInstances) ) * (-float("inf"))
curMatch = np.zeros( len(gtInstances) , dtype=np.bool )
# collect matches
for (gtI,gt) in enumerate(gtInstances):
foundMatch = False
for pred in gt["matchedPred"]:
overlap = float(pred["intersection"]) / (gt["pixelCount"]+pred["pixelCount"]-pred["intersection"])
if overlap > overlapTh:
# the score
confidence = pred["confidence"]
# if we already hat a prediction for this groundtruth
# the prediction with the lower score is automatically a false positive
if curMatch[gtI]:
maxScore = max( curScore[gtI] , confidence )
minScore = min( curScore[gtI] , confidence )
curScore[gtI] = maxScore
# append false positive
curTrue = np.append(curTrue,0)
curScore = np.append(curScore,minScore)
curMatch = np.append(curMatch,True)
# otherwise set score
else:
foundMatch = True
curMatch[gtI] = True
curScore[gtI] = confidence
if not foundMatch:
hardFns += 1
# remove non-matched ground truth instances
curTrue = curTrue [ curMatch==True ]
curScore = curScore[ curMatch==True ]
# collect non-matched predictions as false positive
for pred in predInstances:
foundGt = False
for gt in pred["matchedGt"]:
overlap = float(gt["intersection"]) / (gt["pixelCount"]+pred["pixelCount"]-gt["intersection"])
if overlap > overlapTh:
foundGt = True
break
if not foundGt:
# collect number of void and *group pixels
nbIgnorePixels = pred["voidIntersection"]
for gt in pred["matchedGt"]:
# group?
if gt["instID"] < 1000:
nbIgnorePixels += gt["intersection"]
# small ground truth instances
if gt["pixelCount"] < minRegionSize or gt["medDist"]>distanceTh or gt["distConf"]<distanceConf:
nbIgnorePixels += gt["intersection"]
proportionIgnore = float(nbIgnorePixels)/pred["pixelCount"]
# if not ignored
# append false positive
if proportionIgnore <= overlapTh:
curTrue = np.append(curTrue,0)
confidence = pred["confidence"]
curScore = np.append(curScore,confidence)
# append to overall results
y_true = np.append(y_true,curTrue)
y_score = np.append(y_score,curScore)
# compute the average precision
if haveGt and havePred:
# compute precision recall curve first
# sorting and cumsum
scoreArgSort = np.argsort(y_score)
yScoreSorted = y_score[scoreArgSort]
yTrueSorted = y_true[scoreArgSort]
yTrueSortedCumsum = np.cumsum(yTrueSorted)
# unique thresholds
(thresholds,uniqueIndices) = np.unique( yScoreSorted , return_index=True )
# since we need to add an artificial point to the precision-recall curve
# increase its length by 1
nbPrecRecall = len(uniqueIndices) + 1
# prepare precision recall
nbExamples = len(yScoreSorted)
nbTrueExamples = yTrueSortedCumsum[-1]
precision = np.zeros(nbPrecRecall)
recall = np.zeros(nbPrecRecall)
# deal with the first point
# only thing we need to do, is to append a zero to the cumsum at the end.
# an index of -1 uses that zero then
yTrueSortedCumsum = np.append( yTrueSortedCumsum , 0 )
# deal with remaining
for idxRes,idxScores in enumerate(uniqueIndices):
cumSum = yTrueSortedCumsum[idxScores-1]
tp = nbTrueExamples - cumSum
fp = nbExamples - idxScores - tp
fn = cumSum + hardFns
p = float(tp)/(tp+fp)
r = float(tp)/(tp+fn)
precision[idxRes] = p
recall [idxRes] = r
# first point in curve is artificial
precision[-1] = 1.
recall [-1] = 0.
# compute average of precision-recall curve
# integration is performed via zero order, or equivalently step-wise integration
# first compute the widths of each step:
# use a convolution with appropriate kernel, manually deal with the boundaries first
recallForConv = np.copy(recall)
recallForConv = np.append( recallForConv[0] , recallForConv )
recallForConv = np.append( recallForConv , 0. )
stepWidths = np.convolve(recallForConv,[-0.5,0,0.5],'valid')
# integrate is now simply a dot product
apCurrent = np.dot( precision , stepWidths )
elif haveGt:
apCurrent = 0.0
else:
apCurrent = float('nan')
ap[dI,lI,oI] = apCurrent
return ap
def computeAverages(aps,args):
# max distance index
dInf = np.argmax( args.distanceThs )
d50m = np.where( np.isclose( args.distanceThs , 50. ) )
d100m = np.where( np.isclose( args.distanceThs , 100. ) )
o50 = np.where(np.isclose(args.overlaps,0.5 ))
avgDict = {}
avgDict["allAp"] = np.nanmean(aps[ dInf,:,: ])
avgDict["allAp50%"] = np.nanmean(aps[ dInf,:,o50])
if args.distanceAvailable:
avgDict["allAp50m"] = np.nanmean(aps[ d50m,:, :])
avgDict["allAp100m"] = np.nanmean(aps[d100m,:, :])
avgDict["allAp50%50m"] = np.nanmean(aps[ d50m,:,o50])
avgDict["classes"] = {}
for (lI,labelName) in enumerate(args.instLabels):
avgDict["classes"][labelName] = {}
avgDict["classes"][labelName]["ap"] = np.average(aps[ dInf,lI, :])
avgDict["classes"][labelName]["ap50%"] = np.average(aps[ dInf,lI,o50])
if args.distanceAvailable:
avgDict["classes"][labelName]["ap50m"] = np.average(aps[ d50m,lI, :])
avgDict["classes"][labelName]["ap100m"] = np.average(aps[d100m,lI, :])
avgDict["classes"][labelName]["ap50%50m"] = np.average(aps[ d50m,lI,o50])
return avgDict
def printResults(avgDict, args):
sep = ("," if args.csv else "")
col1 = (":" if not args.csv else "")
noCol = (colors.ENDC if args.colorized else "")
bold = (colors.BOLD if args.colorized else "")
lineLen = 50
if args.distanceAvailable:
lineLen += 40
print("")
if not args.csv:
print("#"*lineLen)
line = bold
line += "{:<15}".format("what" ) + sep + col1
line += "{:>15}".format("AP" ) + sep
line += "{:>15}".format("AP_50%" ) + sep
if args.distanceAvailable:
line += "{:>15}".format("AP_50m" ) + sep
line += "{:>15}".format("AP_100m" ) + sep
line += "{:>15}".format("AP_50%50m" ) + sep
line += noCol
print(line)
if not args.csv:
print("#"*lineLen)
for (lI,labelName) in enumerate(args.instLabels):
apAvg = avgDict["classes"][labelName]["ap"]
ap50o = avgDict["classes"][labelName]["ap50%"]
if args.distanceAvailable:
ap50m = avgDict["classes"][labelName]["ap50m"]
ap100m = avgDict["classes"][labelName]["ap100m"]
ap5050 = avgDict["classes"][labelName]["ap50%50m"]
line = "{:<15}".format(labelName) + sep + col1
line += getColorEntry(apAvg , args) + sep + "{:>15.3f}".format(apAvg ) + sep
line += getColorEntry(ap50o , args) + sep + "{:>15.3f}".format(ap50o ) + sep
if args.distanceAvailable:
line += getColorEntry(ap50m , args) + sep + "{:>15.3f}".format(ap50m ) + sep
line += getColorEntry(ap100m, args) + sep + "{:>15.3f}".format(ap100m) + sep
line += getColorEntry(ap5050, args) + sep + "{:>15.3f}".format(ap5050) + sep
line += noCol
print(line)
allApAvg = avgDict["allAp"]
allAp50o = avgDict["allAp50%"]
if args.distanceAvailable:
allAp50m = avgDict["allAp50m"]
allAp100m = avgDict["allAp100m"]
allAp5050 = avgDict["allAp50%50m"]
if not args.csv:
print("-"*lineLen)
line = "{:<15}".format("average") + sep + col1
line += getColorEntry(allApAvg , args) + sep + "{:>15.3f}".format(allApAvg) + sep
line += getColorEntry(allAp50o , args) + sep + "{:>15.3f}".format(allAp50o) + sep
if args.distanceAvailable:
line += getColorEntry(allAp50m , args) + sep + "{:>15.3f}".format(allAp50m) + sep
line += getColorEntry(allAp100m, args) + sep + "{:>15.3f}".format(allAp100m) + sep
line += getColorEntry(allAp5050, args) + sep + "{:>15.3f}".format(allAp5050) + sep
line += noCol
print(line)
print("")
def prepareJSONDataForResults(avgDict, aps, args):
JSONData = {}
JSONData["averages"] = avgDict
JSONData["overlaps"] = args.overlaps.tolist()
JSONData["minRegionSizes"] = args.minRegionSizes.tolist()
JSONData["distanceThresholds"] = args.distanceThs.tolist()
JSONData["minStereoDensities"] = args.distanceConfs.tolist()
JSONData["instLabels"] = args.instLabels
JSONData["resultApMatrix"] = aps.tolist()
return JSONData
# Work through image list
def evaluateImgLists(predictionList, groundTruthList, args):
# determine labels of interest
setInstanceLabels(args)
# get dictionary of all ground truth instances
gtInstances = getGtInstances(groundTruthList,args)
# match predictions and ground truth
matches = matchGtWithPreds(predictionList,groundTruthList,gtInstances,args)
writeDict2JSON(matches,"matches.json")
# evaluate matches
apScores = evaluateMatches(matches, args)
# averages
avgDict = computeAverages(apScores,args)
# result dict
resDict = prepareJSONDataForResults(avgDict, apScores, args)
if args.JSONOutput:
# create output folder if necessary
path = os.path.dirname(args.exportFile)
ensurePath(path)
# Write APs to JSON
writeDict2JSON(resDict, args.exportFile)
if not args.quiet:
# Print results
printResults(avgDict, args)
return resDict
# The main method
def main():
global args
argv = sys.argv[1:]
predictionImgList = []
groundTruthImgList = []
# the image lists can either be provided as arguments
if (len(argv) > 3):
for arg in argv:
if ("gt" in arg or "groundtruth" in arg):
groundTruthImgList.append(arg)
elif ("pred" in arg):
predictionImgList.append(arg)
# however the no-argument way is prefered
elif len(argv) == 0:
# use the ground truth search string specified above
groundTruthImgList = glob.glob(args.groundTruthSearch)
if not groundTruthImgList:
printError("Cannot find any ground truth images to use for evaluation. Searched for: {}".format(args.groundTruthSearch))
# get the corresponding prediction for each ground truth imag
for gt in groundTruthImgList:
predictionImgList.append( getPrediction(gt,args) )
# print some info for user
print("Note that this tool uses the file '{}' to cache the ground truth instances.".format(args.gtInstancesFile))
print("If anything goes wrong, or if you change the ground truth, please delete the file.")
# evaluate
evaluateImgLists(predictionImgList, groundTruthImgList, args)
return
# call the main method
if __name__ == "__main__":
main()