| |
| |
| import math |
| from collections import namedtuple |
| import numpy as np |
| from shapely.geometry import Polygon |
|
|
|
|
| class DetectionICDAR2013Evaluator(object): |
| def __init__( |
| self, |
| area_recall_constraint=0.8, area_precision_constraint=0.4, |
| ev_param_ind_center_diff_thr=1, |
| mtype_oo_o=1.0, mtype_om_o=0.8, mtype_om_m=1.0 |
| ): |
|
|
|
|
| self.area_recall_constraint = area_recall_constraint |
| self.area_precision_constraint = area_precision_constraint |
| self.ev_param_ind_center_diff_thr = ev_param_ind_center_diff_thr |
| self.mtype_oo_o = mtype_oo_o |
| self.mtype_om_o = mtype_om_o |
| self.mtype_om_m = mtype_om_m |
|
|
| def evaluate_image(self, gt, pred): |
|
|
| def get_union(pD,pG): |
| return Polygon(pD).union(Polygon(pG)).area |
|
|
| def get_intersection_over_union(pD,pG): |
| return get_intersection(pD, pG) / get_union(pD, pG) |
|
|
| def get_intersection(pD,pG): |
| return Polygon(pD).intersection(Polygon(pG)).area |
|
|
| def one_to_one_match(row, col): |
| cont = 0 |
| for j in range(len(recallMat[0])): |
| if recallMat[row,j] >= self.area_recall_constraint and precisionMat[row,j] >= self.area_precision_constraint: |
| cont = cont +1 |
| if (cont != 1): |
| return False |
| cont = 0 |
| for i in range(len(recallMat)): |
| if recallMat[i,col] >= self.area_recall_constraint and precisionMat[i,col] >= self.area_precision_constraint: |
| cont = cont +1 |
| if (cont != 1): |
| return False |
| |
| if recallMat[row,col] >= self.area_recall_constraint and precisionMat[row,col] >= self.area_precision_constraint: |
| return True |
| return False |
| |
| def one_to_many_match(gtNum): |
| many_sum = 0 |
| detRects = [] |
| for detNum in range(len(recallMat[0])): |
| if gtRectMat[gtNum] == 0 and detRectMat[detNum] == 0 and detNum not in detDontCareRectsNum: |
| if precisionMat[gtNum,detNum] >= self.area_precision_constraint: |
| many_sum += recallMat[gtNum,detNum] |
| detRects.append(detNum) |
| if round(many_sum,4) >= self.area_recall_constraint: |
| return True,detRects |
| else: |
| return False,[] |
| |
| def many_to_one_match(detNum): |
| many_sum = 0 |
| gtRects = [] |
| for gtNum in range(len(recallMat)): |
| if gtRectMat[gtNum] == 0 and detRectMat[detNum] == 0 and gtNum not in gtDontCareRectsNum: |
| if recallMat[gtNum,detNum] >= self.area_recall_constraint: |
| many_sum += precisionMat[gtNum,detNum] |
| gtRects.append(gtNum) |
| if round(many_sum,4) >= self.area_precision_constraint: |
| return True,gtRects |
| else: |
| return False,[] |
| |
| def center_distance(r1, r2): |
| return ((np.mean(r1, axis=0) - np.mean(r2, axis=0)) ** 2).sum() ** 0.5 |
| |
| def diag(r): |
| r = np.array(r) |
| return ((r[:, 0].max() - r[:, 0].min()) ** 2 + (r[:, 1].max() - r[:, 1].min()) ** 2) ** 0.5 |
| |
| perSampleMetrics = {} |
| |
| recall = 0 |
| precision = 0 |
| hmean = 0 |
| recallAccum = 0. |
| precisionAccum = 0. |
| gtRects = [] |
| detRects = [] |
| gtPolPoints = [] |
| detPolPoints = [] |
| gtDontCareRectsNum = [] |
| detDontCareRectsNum = [] |
| pairs = [] |
| evaluationLog = "" |
| |
| recallMat = np.empty([1,1]) |
| precisionMat = np.empty([1,1]) |
| |
| for n in range(len(gt)): |
| points = gt[n]['points'] |
| |
| dontCare = gt[n]['ignore'] |
|
|
| if not Polygon(points).is_valid or not Polygon(points).is_simple: |
| continue |
|
|
| gtRects.append(points) |
| gtPolPoints.append(points) |
| if dontCare: |
| gtDontCareRectsNum.append( len(gtRects)-1 ) |
| |
| evaluationLog += "GT rectangles: " + str(len(gtRects)) + (" (" + str(len(gtDontCareRectsNum)) + " don't care)\n" if len(gtDontCareRectsNum)>0 else "\n") |
| |
| for n in range(len(pred)): |
| points = pred[n]['points'] |
|
|
| if not Polygon(points).is_valid or not Polygon(points).is_simple: |
| continue |
|
|
| detRect = points |
| detRects.append(detRect) |
| detPolPoints.append(points) |
| if len(gtDontCareRectsNum)>0 : |
| for dontCareRectNum in gtDontCareRectsNum: |
| dontCareRect = gtRects[dontCareRectNum] |
| intersected_area = get_intersection(dontCareRect,detRect) |
| rdDimensions = Polygon(detRect).area |
| if (rdDimensions==0) : |
| precision = 0 |
| else: |
| precision= intersected_area / rdDimensions |
| if (precision > self.area_precision_constraint): |
| detDontCareRectsNum.append( len(detRects)-1 ) |
| break |
|
|
| evaluationLog += "DET rectangles: " + str(len(detRects)) + (" (" + str(len(detDontCareRectsNum)) + " don't care)\n" if len(detDontCareRectsNum)>0 else "\n") |
|
|
| if len(gtRects)==0: |
| recall = 1 |
| precision = 0 if len(detRects)>0 else 1 |
|
|
| if len(detRects)>0: |
| |
| outputShape=[len(gtRects),len(detRects)] |
| recallMat = np.empty(outputShape) |
| precisionMat = np.empty(outputShape) |
| gtRectMat = np.zeros(len(gtRects),np.int8) |
| detRectMat = np.zeros(len(detRects),np.int8) |
| for gtNum in range(len(gtRects)): |
| for detNum in range(len(detRects)): |
| rG = gtRects[gtNum] |
| rD = detRects[detNum] |
| intersected_area = get_intersection(rG,rD) |
| rgDimensions = Polygon(rG).area |
| rdDimensions = Polygon(rD).area |
| recallMat[gtNum,detNum] = 0 if rgDimensions==0 else intersected_area / rgDimensions |
| precisionMat[gtNum,detNum] = 0 if rdDimensions==0 else intersected_area / rdDimensions |
|
|
| |
| evaluationLog += "Find one-to-one matches\n" |
| for gtNum in range(len(gtRects)): |
| for detNum in range(len(detRects)): |
| if gtRectMat[gtNum] == 0 and detRectMat[detNum] == 0 and gtNum not in gtDontCareRectsNum and detNum not in detDontCareRectsNum : |
| match = one_to_one_match(gtNum, detNum) |
| if match is True : |
| |
| rG = gtRects[gtNum] |
| rD = detRects[detNum] |
| normDist = center_distance(rG, rD); |
| normDist /= diag(rG) + diag(rD); |
| normDist *= 2.0; |
| if normDist < self.ev_param_ind_center_diff_thr: |
| gtRectMat[gtNum] = 1 |
| detRectMat[detNum] = 1 |
| recallAccum += self.mtype_oo_o |
| precisionAccum += self.mtype_oo_o |
| pairs.append({'gt':gtNum,'det':detNum,'type':'OO'}) |
| evaluationLog += "Match GT #" + str(gtNum) + " with Det #" + str(detNum) + "\n" |
| else: |
| evaluationLog += "Match Discarded GT #" + str(gtNum) + " with Det #" + str(detNum) + " normDist: " + str(normDist) + " \n" |
| |
| evaluationLog += "Find one-to-many matches\n" |
| for gtNum in range(len(gtRects)): |
| if gtNum not in gtDontCareRectsNum: |
| match,matchesDet = one_to_many_match(gtNum) |
| if match is True : |
| evaluationLog += "num_overlaps_gt=" + str(num_overlaps_gt(gtNum)) |
| gtRectMat[gtNum] = 1 |
| recallAccum += (self.mtype_oo_o if len(matchesDet)==1 else self.mtype_om_o) |
| precisionAccum += (self.mtype_oo_o if len(matchesDet)==1 else self.mtype_om_o*len(matchesDet)) |
| pairs.append({'gt':gtNum,'det':matchesDet,'type': 'OO' if len(matchesDet)==1 else 'OM'}) |
| for detNum in matchesDet : |
| detRectMat[detNum] = 1 |
| evaluationLog += "Match GT #" + str(gtNum) + " with Det #" + str(matchesDet) + "\n" |
|
|
| |
| evaluationLog += "Find many-to-one matches\n" |
| for detNum in range(len(detRects)): |
| if detNum not in detDontCareRectsNum: |
| match,matchesGt = many_to_one_match(detNum) |
| if match is True : |
| detRectMat[detNum] = 1 |
| recallAccum += (self.mtype_oo_o if len(matchesGt)==1 else self.mtype_om_m*len(matchesGt)) |
| precisionAccum += (self.mtype_oo_o if len(matchesGt)==1 else self.mtype_om_m) |
| pairs.append({'gt':matchesGt,'det':detNum,'type': 'OO' if len(matchesGt)==1 else 'MO'}) |
| for gtNum in matchesGt : |
| gtRectMat[gtNum] = 1 |
| evaluationLog += "Match GT #" + str(matchesGt) + " with Det #" + str(detNum) + "\n" |
|
|
| numGtCare = (len(gtRects) - len(gtDontCareRectsNum)) |
| if numGtCare == 0: |
| recall = float(1) |
| precision = float(0) if len(detRects)>0 else float(1) |
| else: |
| recall = float(recallAccum) / numGtCare |
| precision = float(0) if (len(detRects) - len(detDontCareRectsNum))==0 else float(precisionAccum) / (len(detRects) - len(detDontCareRectsNum)) |
| hmean = 0 if (precision + recall)==0 else 2.0 * precision * recall / (precision + recall) |
|
|
| numGtCare = len(gtRects) - len(gtDontCareRectsNum) |
| numDetCare = len(detRects) - len(detDontCareRectsNum) |
|
|
| perSampleMetrics = { |
| 'precision':precision, |
| 'recall':recall, |
| 'hmean':hmean, |
| 'pairs':pairs, |
| 'recallMat':[] if len(detRects)>100 else recallMat.tolist(), |
| 'precisionMat':[] if len(detRects)>100 else precisionMat.tolist(), |
| 'gtPolPoints':gtPolPoints, |
| 'detPolPoints':detPolPoints, |
| 'gtCare': numGtCare, |
| 'detCare': numDetCare, |
| 'gtDontCare':gtDontCareRectsNum, |
| 'detDontCare':detDontCareRectsNum, |
| 'recallAccum':recallAccum, |
| 'precisionAccum':precisionAccum, |
| 'evaluationLog': evaluationLog |
| } |
|
|
| return perSampleMetrics |
|
|
| def combine_results(self, results): |
| numGt = 0 |
| numDet = 0 |
| methodRecallSum = 0 |
| methodPrecisionSum = 0 |
|
|
| for result in results: |
| numGt += result['gtCare'] |
| numDet += result['detCare'] |
| methodRecallSum += result['recallAccum'] |
| methodPrecisionSum += result['precisionAccum'] |
|
|
| methodRecall = 0 if numGt==0 else methodRecallSum/numGt |
| methodPrecision = 0 if numDet==0 else methodPrecisionSum/numDet |
| methodHmean = 0 if methodRecall + methodPrecision==0 else 2* methodRecall * methodPrecision / (methodRecall + methodPrecision) |
| |
| methodMetrics = {'precision':methodPrecision, 'recall':methodRecall,'hmean': methodHmean } |
|
|
| return methodMetrics |
|
|
|
|
| if __name__=='__main__': |
| evaluator = DetectionICDAR2013Evaluator() |
| gts = [[{ |
| 'points': [(0, 0), (1, 0), (1, 1), (0, 1)], |
| 'text': 1234, |
| 'ignore': False, |
| }, { |
| 'points': [(2, 2), (3, 2), (3, 3), (2, 3)], |
| 'text': 5678, |
| 'ignore': True, |
| }]] |
| preds = [[{ |
| 'points': [(0.1, 0.1), (1, 0), (1, 1), (0, 1)], |
| 'text': 123, |
| 'ignore': False, |
| }]] |
| results = [] |
| for gt, pred in zip(gts, preds): |
| results.append(evaluator.evaluate_image(gt, pred)) |
| metrics = evaluator.combine_results(results) |
| print(metrics) |
|
|
