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deteval.py
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deteval.py
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import math
from collections import namedtuple
from copy import deepcopy
import numpy as np
def default_evaluation_params():
"""
default_evaluation_params: Default parameters to use for the validation and evaluation.
"""
return {
'AREA_RECALL_CONSTRAINT' : 0.8,
'AREA_PRECISION_CONSTRAINT' : 0.4,
'EV_PARAM_IND_CENTER_DIFF_THR': 1,
'MTYPE_OO_O':1.,
'MTYPE_OM_O':0.8,
'MTYPE_OM_M':1.,
'GT_SAMPLE_NAME_2_ID':'gt_img_([0-9]+).txt',
'DET_SAMPLE_NAME_2_ID':'res_img_([0-9]+).txt',
'CRLF':False # Lines are delimited by Windows CRLF format
}
def calc_deteval_metrics(pred_bboxes_dict, gt_bboxes_dict, transcriptions_dict=None,
eval_hparams=None, bbox_format='rect', verbose=False):
"""
현재는 rect(xmin, ymin, xmax, ymax) 형식의 bounding box만 지원함. 다른 형식(quadrilateral,
poligon, etc.)의 데이터가 들어오면 외접하는 rect로 변환해서 이용하고 있음.
"""
def one_to_one_match(row, col):
cont = 0
for j in range(len(recallMat[0])):
if recallMat[row,j] >= eval_hparams['AREA_RECALL_CONSTRAINT'] and precisionMat[row,j] >= eval_hparams['AREA_PRECISION_CONSTRAINT'] :
cont = cont +1
if (cont != 1):
return False
cont = 0
for i in range(len(recallMat)):
if recallMat[i,col] >= eval_hparams['AREA_RECALL_CONSTRAINT'] and precisionMat[i,col] >= eval_hparams['AREA_PRECISION_CONSTRAINT'] :
cont = cont +1
if (cont != 1):
return False
if recallMat[row,col] >= eval_hparams['AREA_RECALL_CONSTRAINT'] and precisionMat[row,col] >= eval_hparams['AREA_PRECISION_CONSTRAINT'] :
return True
return False
def num_overlaps_gt(gtNum):
cont = 0
for detNum in range(len(detRects)):
if detNum not in detDontCareRectsNum:
if recallMat[gtNum,detNum] > 0 :
cont = cont +1
return cont
def num_overlaps_det(detNum):
cont = 0
for gtNum in range(len(recallMat)):
if gtNum not in gtDontCareRectsNum:
if recallMat[gtNum,detNum] > 0 :
cont = cont +1
return cont
def is_single_overlap(row, col):
if num_overlaps_gt(row)==1 and num_overlaps_det(col)==1:
return True
else:
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] >= eval_hparams['AREA_PRECISION_CONSTRAINT'] :
many_sum += recallMat[gtNum,detNum]
detRects.append(detNum)
if round(many_sum,4) >=eval_hparams['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] >= eval_hparams['AREA_RECALL_CONSTRAINT'] :
many_sum += precisionMat[gtNum,detNum]
gtRects.append(gtNum)
if round(many_sum,4) >=eval_hparams['AREA_PRECISION_CONSTRAINT'] :
return True,gtRects
else:
return False,[]
def area(a, b):
dx = min(a.xmax, b.xmax) - max(a.xmin, b.xmin) + 1
dy = min(a.ymax, b.ymax) - max(a.ymin, b.ymin) + 1
if (dx>=0) and (dy>=0):
return dx*dy
else:
return 0.
def center(r):
x = float(r.xmin) + float(r.xmax - r.xmin + 1) / 2.
y = float(r.ymin) + float(r.ymax - r.ymin + 1) / 2.
return Point(x,y)
def point_distance(r1, r2):
distx = math.fabs(r1.x - r2.x)
disty = math.fabs(r1.y - r2.y)
return math.sqrt(distx * distx + disty * disty )
def center_distance(r1, r2):
return point_distance(center(r1), center(r2))
def diag(r):
w = (r.xmax - r.xmin + 1)
h = (r.ymax - r.ymin + 1)
return math.sqrt(h * h + w * w)
if eval_hparams is None:
eval_hparams = default_evaluation_params()
if bbox_format != 'rect':
raise NotImplementedError
# bbox들이 rect 이외의 형식으로 되어있는 경우 rect 형식으로 변환
_pred_bboxes_dict, _gt_bboxes_dict= deepcopy(pred_bboxes_dict), deepcopy(gt_bboxes_dict)
pred_bboxes_dict, gt_bboxes_dict = dict(), dict()
for sample_name, bboxes in _pred_bboxes_dict.items():
# 원래 rect 형식이었으면 변환 없이 그대로 이용
if len(bboxes) > 0 and np.array(bboxes[0]).ndim == 1 and len(bboxes[0]) == 4:
pred_bboxes_dict = _pred_bboxes_dict
break
pred_bboxes_dict[sample_name] = []
for bbox in map(np.array, bboxes):
rect = [bbox[:, 0].min(), bbox[:, 1].min(), bbox[:, 0].max(), bbox[:, 1].max()]
pred_bboxes_dict[sample_name].append(rect)
for sample_name, bboxes in _gt_bboxes_dict.items():
# 원래 rect 형식이었으면 변환 없이 그대로 이용
if len(bboxes) > 0 and np.array(bboxes[0]).ndim == 1 and len(bboxes[0]) == 4:
gt_bboxes_dict = _gt_bboxes_dict
break
gt_bboxes_dict[sample_name] = []
for bbox in map(np.array, bboxes):
rect = [bbox[:, 0].min(), bbox[:, 1].min(), bbox[:, 0].max(), bbox[:, 1].max()]
gt_bboxes_dict[sample_name].append(rect)
perSampleMetrics = {}
methodRecallSum = 0
methodPrecisionSum = 0
Rectangle = namedtuple('Rectangle', 'xmin ymin xmax ymax')
Point = namedtuple('Point', 'x y')
numGt = 0
numDet = 0
for sample_name in gt_bboxes_dict:
recall = 0
precision = 0
hmean = 0
recallAccum = 0.
precisionAccum = 0.
gtRects = []
detRects = []
gtPolPoints = []
detPolPoints = []
gtDontCareRectsNum = [] # Array of Ground Truth Rectangles' keys marked as don't Care
detDontCareRectsNum = [] # Array of Detected Rectangles' matched with a don't Care GT
pairs = []
evaluationLog = ""
recallMat = np.empty([1, 1])
precisionMat = np.empty([1, 1])
pointsList = gt_bboxes_dict[sample_name]
if transcriptions_dict is None:
transcriptionsList = None
else:
transcriptionsList = transcriptions_dict[sample_name]
for n in range(len(pointsList)):
points = pointsList[n]
transcription = transcriptionsList[n]
dontCare = transcription == "###"
gtRect = Rectangle(*points)
gtRects.append(gtRect)
gtPolPoints.append(np.array(points).tolist())
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")
if sample_name in pred_bboxes_dict:
pointsList = pred_bboxes_dict[sample_name]
for n in range(len(pointsList)):
points = pointsList[n]
detRect = Rectangle(*points)
detRects.append(detRect)
detPolPoints.append(np.array(points).tolist())
if len(gtDontCareRectsNum)>0 :
for dontCareRectNum in gtDontCareRectsNum:
dontCareRect = gtRects[dontCareRectNum]
intersected_area = area(dontCareRect,detRect)
rdDimensions = ( (detRect.xmax - detRect.xmin+1) * (detRect.ymax - detRect.ymin+1))
if (rdDimensions==0) :
precision = 0
else:
precision= intersected_area / rdDimensions
if (precision > eval_hparams['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:
#Calculate recall and precision matrixs
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 = area(rG,rD)
rgDimensions = ( (rG.xmax - rG.xmin+1) * (rG.ymax - rG.ymin+1) )
rdDimensions = ( (rD.xmax - rD.xmin+1) * (rD.ymax - rD.ymin+1))
recallMat[gtNum,detNum] = 0 if rgDimensions==0 else intersected_area / rgDimensions
precisionMat[gtNum,detNum] = 0 if rdDimensions==0 else intersected_area / rdDimensions
# Find one-to-one matches
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 :
#in deteval we have to make other validation before mark as one-to-one
if is_single_overlap(gtNum, detNum) is True :
rG = gtRects[gtNum]
rD = detRects[detNum]
normDist = center_distance(rG, rD)
normDist /= diag(rG) + diag(rD)
normDist *= 2.0
if normDist < eval_hparams['EV_PARAM_IND_CENTER_DIFF_THR'] :
gtRectMat[gtNum] = 1
detRectMat[detNum] = 1
recallAccum += eval_hparams['MTYPE_OO_O']
precisionAccum += eval_hparams['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"
else:
evaluationLog += "Match Discarded GT #" + str(gtNum) + " with Det #" + str(detNum) + " not single overlap\n"
# Find one-to-many matches
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))
#in deteval we have to make other validation before mark as one-to-one
if num_overlaps_gt(gtNum)>=2 :
gtRectMat[gtNum] = 1
recallAccum += (eval_hparams['MTYPE_OO_O'] if len(matchesDet)==1 else eval_hparams['MTYPE_OM_O'])
precisionAccum += (eval_hparams['MTYPE_OO_O'] if len(matchesDet)==1 else eval_hparams['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"
else:
evaluationLog += "Match Discarded GT #" + str(gtNum) + " with Det #" + str(matchesDet) + " not single overlap\n"
# Find many-to-one matches
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 :
#in deteval we have to make other validation before mark as one-to-one
if num_overlaps_det(detNum)>=2 :
detRectMat[detNum] = 1
recallAccum += (eval_hparams['MTYPE_OO_O'] if len(matchesGt)==1 else eval_hparams['MTYPE_OM_M']*len(matchesGt))
precisionAccum += (eval_hparams['MTYPE_OO_O'] if len(matchesGt)==1 else eval_hparams['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"
else:
evaluationLog += "Match Discarded GT #" + str(matchesGt) + " with Det #" + str(detNum) + " not single overlap\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)
methodRecallSum += recallAccum
methodPrecisionSum += precisionAccum
numGt += len(gtRects) - len(gtDontCareRectsNum)
numDet += len(detRects) - len(detDontCareRectsNum)
perSampleMetrics[sample_name] = {
'precision': precision,
'recall': recall,
'hmean': hmean,
'pairs': pairs,
'recall_matrix': [] if len(detRects)>100 else recallMat.tolist(),
'precision_matrix': [] if len(detRects)>100 else precisionMat.tolist(),
'gt_bboxes': gtPolPoints,
'det_bboxes': detPolPoints,
'gt_dont_care': gtDontCareRectsNum,
'det_dont_care': detDontCareRectsNum,
}
if verbose:
perSampleMetrics[sample_name].update(evaluation_log=evaluationLog)
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}
resDict = {'calculated': True, 'Message': '', 'total': methodMetrics,
'per_sample': perSampleMetrics, 'eval_hparams': eval_hparams}
return resDict