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OpenOCR / tools /utils /e2e_metric /Deteval.py
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 import json
import numpy as np
import scipy.io as io
from tools.utils.utility import check_install
from tools.utils.e2e_metric.polygon_fast import iod, area_of_intersection, area
def get_socre_A(gt_dir, pred_dict):
allInputs = 1
def input_reading_mod(pred_dict):
"""This helper reads input from txt files"""
det = []
n = len(pred_dict)
for i in range(n):
points = pred_dict[i]["points"]
text = pred_dict[i]["texts"]
point = ",".join(map(
str,
points.reshape(-1, ), ))
det.append([point, text])
return det
def gt_reading_mod(gt_dict):
"""This helper reads groundtruths from mat files"""
gt = []
n = len(gt_dict)
for i in range(n):
points = gt_dict[i]["points"].tolist()
h = len(points)
text = gt_dict[i]["text"]
xx = [
np.array(
["x:"], dtype="<U2"),
0,
np.array(
["y:"], dtype="<U2"),
0,
np.array(
["#"], dtype="<U1"),
np.array(
["#"], dtype="<U1"),
]
t_x, t_y = [], []
for j in range(h):
t_x.append(points[j][0])
t_y.append(points[j][1])
xx[1] = np.array([t_x], dtype="int16")
xx[3] = np.array([t_y], dtype="int16")
if text != "":
xx[4] = np.array([text], dtype="U{}".format(len(text)))
xx[5] = np.array(["c"], dtype="<U1")
gt.append(xx)
return gt
def detection_filtering(detections, groundtruths, threshold=0.5):
for gt_id, gt in enumerate(groundtruths):
if (gt[5] == "#") and (gt[1].shape[1] > 1):
gt_x = list(map(int, np.squeeze(gt[1])))
gt_y = list(map(int, np.squeeze(gt[3])))
for det_id, detection in enumerate(detections):
detection_orig = detection
detection = [float(x) for x in detection[0].split(",")]
detection = list(map(int, detection))
det_x = detection[0::2]
det_y = detection[1::2]
det_gt_iou = iod(det_x, det_y, gt_x, gt_y)
if det_gt_iou > threshold:
detections[det_id] = []
detections[:] = [item for item in detections if item != []]
return detections
def sigma_calculation(det_x, det_y, gt_x, gt_y):
"""
sigma = inter_area / gt_area
"""
return np.round(
(area_of_intersection(det_x, det_y, gt_x, gt_y) / area(gt_x, gt_y)),
2)
def tau_calculation(det_x, det_y, gt_x, gt_y):
if area(det_x, det_y) == 0.0:
return 0
return np.round((area_of_intersection(det_x, det_y, gt_x, gt_y) /
area(det_x, det_y)), 2)
##############################Initialization###################################
# global_sigma = []
# global_tau = []
# global_pred_str = []
# global_gt_str = []
###############################################################################
for input_id in range(allInputs):
if ((input_id != ".DS_Store") and (input_id != "Pascal_result.txt") and
(input_id != "Pascal_result_curved.txt") and
(input_id != "Pascal_result_non_curved.txt") and
(input_id != "Deteval_result.txt") and
(input_id != "Deteval_result_curved.txt") and
(input_id != "Deteval_result_non_curved.txt")):
detections = input_reading_mod(pred_dict)
groundtruths = gt_reading_mod(gt_dir)
detections = detection_filtering(
detections,
groundtruths) # filters detections overlapping with DC area
dc_id = []
for i in range(len(groundtruths)):
if groundtruths[i][5] == "#":
dc_id.append(i)
cnt = 0
for a in dc_id:
num = a - cnt
del groundtruths[num]
cnt += 1
local_sigma_table = np.zeros((len(groundtruths), len(detections)))
local_tau_table = np.zeros((len(groundtruths), len(detections)))
local_pred_str = {}
local_gt_str = {}
for gt_id, gt in enumerate(groundtruths):
if len(detections) > 0:
for det_id, detection in enumerate(detections):
detection_orig = detection
detection = [float(x) for x in detection[0].split(",")]
detection = list(map(int, detection))
pred_seq_str = detection_orig[1].strip()
det_x = detection[0::2]
det_y = detection[1::2]
gt_x = list(map(int, np.squeeze(gt[1])))
gt_y = list(map(int, np.squeeze(gt[3])))
gt_seq_str = str(gt[4].tolist()[0])
local_sigma_table[gt_id, det_id] = sigma_calculation(
det_x, det_y, gt_x, gt_y)
local_tau_table[gt_id, det_id] = tau_calculation(
det_x, det_y, gt_x, gt_y)
local_pred_str[det_id] = pred_seq_str
local_gt_str[gt_id] = gt_seq_str
global_sigma = local_sigma_table
global_tau = local_tau_table
global_pred_str = local_pred_str
global_gt_str = local_gt_str
single_data = {}
single_data["sigma"] = global_sigma
single_data["global_tau"] = global_tau
single_data["global_pred_str"] = global_pred_str
single_data["global_gt_str"] = global_gt_str
return single_data
def get_socre_B(gt_dir, img_id, pred_dict):
allInputs = 1
def input_reading_mod(pred_dict):
"""This helper reads input from txt files"""
det = []
n = len(pred_dict)
for i in range(n):
points = pred_dict[i]["points"]
text = pred_dict[i]["texts"]
point = ",".join(map(
str,
points.reshape(-1, ), ))
det.append([point, text])
return det
def gt_reading_mod(gt_dir, gt_id):
gt = io.loadmat("%s/poly_gt_img%s.mat" % (gt_dir, gt_id))
gt = gt["polygt"]
return gt
def detection_filtering(detections, groundtruths, threshold=0.5):
for gt_id, gt in enumerate(groundtruths):
if (gt[5] == "#") and (gt[1].shape[1] > 1):
gt_x = list(map(int, np.squeeze(gt[1])))
gt_y = list(map(int, np.squeeze(gt[3])))
for det_id, detection in enumerate(detections):
detection_orig = detection
detection = [float(x) for x in detection[0].split(",")]
detection = list(map(int, detection))
det_x = detection[0::2]
det_y = detection[1::2]
det_gt_iou = iod(det_x, det_y, gt_x, gt_y)
if det_gt_iou > threshold:
detections[det_id] = []
detections[:] = [item for item in detections if item != []]
return detections
def sigma_calculation(det_x, det_y, gt_x, gt_y):
"""
sigma = inter_area / gt_area
"""
return np.round(
(area_of_intersection(det_x, det_y, gt_x, gt_y) / area(gt_x, gt_y)),
2)
def tau_calculation(det_x, det_y, gt_x, gt_y):
if area(det_x, det_y) == 0.0:
return 0
return np.round((area_of_intersection(det_x, det_y, gt_x, gt_y) /
area(det_x, det_y)), 2)
##############################Initialization###################################
# global_sigma = []
# global_tau = []
# global_pred_str = []
# global_gt_str = []
###############################################################################
for input_id in range(allInputs):
if ((input_id != ".DS_Store") and (input_id != "Pascal_result.txt") and
(input_id != "Pascal_result_curved.txt") and
(input_id != "Pascal_result_non_curved.txt") and
(input_id != "Deteval_result.txt") and
(input_id != "Deteval_result_curved.txt") and
(input_id != "Deteval_result_non_curved.txt")):
detections = input_reading_mod(pred_dict)
groundtruths = gt_reading_mod(gt_dir, img_id).tolist()
detections = detection_filtering(
detections,
groundtruths) # filters detections overlapping with DC area
dc_id = []
for i in range(len(groundtruths)):
if groundtruths[i][5] == "#":
dc_id.append(i)
cnt = 0
for a in dc_id:
num = a - cnt
del groundtruths[num]
cnt += 1
local_sigma_table = np.zeros((len(groundtruths), len(detections)))
local_tau_table = np.zeros((len(groundtruths), len(detections)))
local_pred_str = {}
local_gt_str = {}
for gt_id, gt in enumerate(groundtruths):
if len(detections) > 0:
for det_id, detection in enumerate(detections):
detection_orig = detection
detection = [float(x) for x in detection[0].split(",")]
detection = list(map(int, detection))
pred_seq_str = detection_orig[1].strip()
det_x = detection[0::2]
det_y = detection[1::2]
gt_x = list(map(int, np.squeeze(gt[1])))
gt_y = list(map(int, np.squeeze(gt[3])))
gt_seq_str = str(gt[4].tolist()[0])
local_sigma_table[gt_id, det_id] = sigma_calculation(
det_x, det_y, gt_x, gt_y)
local_tau_table[gt_id, det_id] = tau_calculation(
det_x, det_y, gt_x, gt_y)
local_pred_str[det_id] = pred_seq_str
local_gt_str[gt_id] = gt_seq_str
global_sigma = local_sigma_table
global_tau = local_tau_table
global_pred_str = local_pred_str
global_gt_str = local_gt_str
single_data = {}
single_data["sigma"] = global_sigma
single_data["global_tau"] = global_tau
single_data["global_pred_str"] = global_pred_str
single_data["global_gt_str"] = global_gt_str
return single_data
def get_score_C(gt_label, text, pred_bboxes):
"""
get score for CentripetalText (CT) prediction.
"""
check_install("Polygon", "Polygon3")
import Polygon as plg
def gt_reading_mod(gt_label, text):
"""This helper reads groundtruths from mat files"""
groundtruths = []
nbox = len(gt_label)
for i in range(nbox):
label = {"transcription": text[i][0], "points": gt_label[i].numpy()}
groundtruths.append(label)
return groundtruths
def get_union(pD, pG):
areaA = pD.area()
areaB = pG.area()
return areaA + areaB - get_intersection(pD, pG)
def get_intersection(pD, pG):
pInt = pD & pG
if len(pInt) == 0:
return 0
return pInt.area()
def detection_filtering(detections, groundtruths, threshold=0.5):
for gt in groundtruths:
point_num = gt["points"].shape[1] // 2
if gt["transcription"] == "###" and (point_num > 1):
gt_p = np.array(gt["points"]).reshape(point_num,
2).astype("int32")
gt_p = plg.Polygon(gt_p)
for det_id, detection in enumerate(detections):
det_y = detection[0::2]
det_x = detection[1::2]
det_p = np.concatenate((np.array(det_x), np.array(det_y)))
det_p = det_p.reshape(2, -1).transpose()
det_p = plg.Polygon(det_p)
try:
det_gt_iou = get_intersection(det_p,
gt_p) / det_p.area()
except:
print(det_x, det_y, gt_p)
if det_gt_iou > threshold:
detections[det_id] = []
detections[:] = [item for item in detections if item != []]
return detections
def sigma_calculation(det_p, gt_p):
"""
sigma = inter_area / gt_area
"""
if gt_p.area() == 0.0:
return 0
return get_intersection(det_p, gt_p) / gt_p.area()
def tau_calculation(det_p, gt_p):
"""
tau = inter_area / det_area
"""
if det_p.area() == 0.0:
return 0
return get_intersection(det_p, gt_p) / det_p.area()
detections = []
for item in pred_bboxes:
detections.append(item[:, ::-1].reshape(-1))
groundtruths = gt_reading_mod(gt_label, text)
detections = detection_filtering(
detections, groundtruths) # filters detections overlapping with DC area
for idx in range(len(groundtruths) - 1, -1, -1):
# NOTE: source code use 'orin' to indicate '#', here we use 'anno',
# which may cause slight drop in fscore, about 0.12
if groundtruths[idx]["transcription"] == "###":
groundtruths.pop(idx)
local_sigma_table = np.zeros((len(groundtruths), len(detections)))
local_tau_table = np.zeros((len(groundtruths), len(detections)))
for gt_id, gt in enumerate(groundtruths):
if len(detections) > 0:
for det_id, detection in enumerate(detections):
point_num = gt["points"].shape[1] // 2
gt_p = np.array(gt["points"]).reshape(point_num,
2).astype("int32")
gt_p = plg.Polygon(gt_p)
det_y = detection[0::2]
det_x = detection[1::2]
det_p = np.concatenate((np.array(det_x), np.array(det_y)))
det_p = det_p.reshape(2, -1).transpose()
det_p = plg.Polygon(det_p)
local_sigma_table[gt_id, det_id] = sigma_calculation(det_p,
gt_p)
local_tau_table[gt_id, det_id] = tau_calculation(det_p, gt_p)
data = {}
data["sigma"] = local_sigma_table
data["global_tau"] = local_tau_table
data["global_pred_str"] = ""
data["global_gt_str"] = ""
return data
def combine_results(all_data, rec_flag=True):
tr = 0.7
tp = 0.6
fsc_k = 0.8
k = 2
global_sigma = []
global_tau = []
global_pred_str = []
global_gt_str = []
for data in all_data:
global_sigma.append(data["sigma"])
global_tau.append(data["global_tau"])
global_pred_str.append(data["global_pred_str"])
global_gt_str.append(data["global_gt_str"])
global_accumulative_recall = 0
global_accumulative_precision = 0
total_num_gt = 0
total_num_det = 0
hit_str_count = 0
hit_count = 0
def one_to_one(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idy,
rec_flag, ):
hit_str_num = 0
for gt_id in range(num_gt):
gt_matching_qualified_sigma_candidates = np.where(
local_sigma_table[gt_id, :] > tr)
gt_matching_num_qualified_sigma_candidates = (
gt_matching_qualified_sigma_candidates[0].shape[0])
gt_matching_qualified_tau_candidates = np.where(
local_tau_table[gt_id, :] > tp)
gt_matching_num_qualified_tau_candidates = (
gt_matching_qualified_tau_candidates[0].shape[0])
det_matching_qualified_sigma_candidates = np.where(
local_sigma_table[:, gt_matching_qualified_sigma_candidates[0]]
> tr)
det_matching_num_qualified_sigma_candidates = (
det_matching_qualified_sigma_candidates[0].shape[0])
det_matching_qualified_tau_candidates = np.where(
local_tau_table[:, gt_matching_qualified_tau_candidates[0]] >
tp)
det_matching_num_qualified_tau_candidates = (
det_matching_qualified_tau_candidates[0].shape[0])
if ((gt_matching_num_qualified_sigma_candidates == 1) and
(gt_matching_num_qualified_tau_candidates == 1) and
(det_matching_num_qualified_sigma_candidates == 1) and
(det_matching_num_qualified_tau_candidates == 1)):
global_accumulative_recall = global_accumulative_recall + 1.0
global_accumulative_precision = global_accumulative_precision + 1.0
local_accumulative_recall = local_accumulative_recall + 1.0
local_accumulative_precision = local_accumulative_precision + 1.0
gt_flag[0, gt_id] = 1
matched_det_id = np.where(local_sigma_table[gt_id, :] > tr)
# recg start
if rec_flag:
gt_str_cur = global_gt_str[idy][gt_id]
pred_str_cur = global_pred_str[idy][matched_det_id[0]
.tolist()[0]]
if pred_str_cur == gt_str_cur:
hit_str_num += 1
else:
if pred_str_cur.lower() == gt_str_cur.lower():
hit_str_num += 1
# recg end
det_flag[0, matched_det_id] = 1
return (
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, )
def one_to_many(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idy,
rec_flag, ):
hit_str_num = 0
for gt_id in range(num_gt):
# skip the following if the groundtruth was matched
if gt_flag[0, gt_id] > 0:
continue
non_zero_in_sigma = np.where(local_sigma_table[gt_id, :] > 0)
num_non_zero_in_sigma = non_zero_in_sigma[0].shape[0]
if num_non_zero_in_sigma >= k:
####search for all detections that overlaps with this groundtruth
qualified_tau_candidates = np.where((local_tau_table[
gt_id, :] >= tp) & (det_flag[0, :] == 0))
num_qualified_tau_candidates = qualified_tau_candidates[
0].shape[0]
if num_qualified_tau_candidates == 1:
if (local_tau_table[gt_id, qualified_tau_candidates] >= tp
) and (
local_sigma_table[gt_id, qualified_tau_candidates]
>= tr):
# became an one-to-one case
global_accumulative_recall = global_accumulative_recall + 1.0
global_accumulative_precision = (
global_accumulative_precision + 1.0)
local_accumulative_recall = local_accumulative_recall + 1.0
local_accumulative_precision = (
local_accumulative_precision + 1.0)
gt_flag[0, gt_id] = 1
det_flag[0, qualified_tau_candidates] = 1
# recg start
if rec_flag:
gt_str_cur = global_gt_str[idy][gt_id]
pred_str_cur = global_pred_str[idy][
qualified_tau_candidates[0].tolist()[0]]
if pred_str_cur == gt_str_cur:
hit_str_num += 1
else:
if pred_str_cur.lower() == gt_str_cur.lower():
hit_str_num += 1
# recg end
elif np.sum(local_sigma_table[gt_id,
qualified_tau_candidates]) >= tr:
gt_flag[0, gt_id] = 1
det_flag[0, qualified_tau_candidates] = 1
# recg start
if rec_flag:
gt_str_cur = global_gt_str[idy][gt_id]
pred_str_cur = global_pred_str[idy][
qualified_tau_candidates[0].tolist()[0]]
if pred_str_cur == gt_str_cur:
hit_str_num += 1
else:
if pred_str_cur.lower() == gt_str_cur.lower():
hit_str_num += 1
# recg end
global_accumulative_recall = global_accumulative_recall + fsc_k
global_accumulative_precision = (
global_accumulative_precision +
num_qualified_tau_candidates * fsc_k)
local_accumulative_recall = local_accumulative_recall + fsc_k
local_accumulative_precision = (
local_accumulative_precision +
num_qualified_tau_candidates * fsc_k)
return (
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, )
def many_to_one(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idy,
rec_flag, ):
hit_str_num = 0
for det_id in range(num_det):
# skip the following if the detection was matched
if det_flag[0, det_id] > 0:
continue
non_zero_in_tau = np.where(local_tau_table[:, det_id] > 0)
num_non_zero_in_tau = non_zero_in_tau[0].shape[0]
if num_non_zero_in_tau >= k:
####search for all detections that overlaps with this groundtruth
qualified_sigma_candidates = np.where((
local_sigma_table[:, det_id] >= tp) & (gt_flag[0, :] == 0))
num_qualified_sigma_candidates = qualified_sigma_candidates[
0].shape[0]
if num_qualified_sigma_candidates == 1:
if (
local_tau_table[qualified_sigma_candidates, det_id]
>= tp
) and (local_sigma_table[qualified_sigma_candidates, det_id]
>= tr):
# became an one-to-one case
global_accumulative_recall = global_accumulative_recall + 1.0
global_accumulative_precision = (
global_accumulative_precision + 1.0)
local_accumulative_recall = local_accumulative_recall + 1.0
local_accumulative_precision = (
local_accumulative_precision + 1.0)
gt_flag[0, qualified_sigma_candidates] = 1
det_flag[0, det_id] = 1
# recg start
if rec_flag:
pred_str_cur = global_pred_str[idy][det_id]
gt_len = len(qualified_sigma_candidates[0])
for idx in range(gt_len):
ele_gt_id = qualified_sigma_candidates[
0].tolist()[idx]
if ele_gt_id not in global_gt_str[idy]:
continue
gt_str_cur = global_gt_str[idy][ele_gt_id]
if pred_str_cur == gt_str_cur:
hit_str_num += 1
break
else:
if pred_str_cur.lower() == gt_str_cur.lower(
):
hit_str_num += 1
break
# recg end
elif np.sum(local_tau_table[qualified_sigma_candidates,
det_id]) >= tp:
det_flag[0, det_id] = 1
gt_flag[0, qualified_sigma_candidates] = 1
# recg start
if rec_flag:
pred_str_cur = global_pred_str[idy][det_id]
gt_len = len(qualified_sigma_candidates[0])
for idx in range(gt_len):
ele_gt_id = qualified_sigma_candidates[0].tolist()[
idx]
if ele_gt_id not in global_gt_str[idy]:
continue
gt_str_cur = global_gt_str[idy][ele_gt_id]
if pred_str_cur == gt_str_cur:
hit_str_num += 1
break
else:
if pred_str_cur.lower() == gt_str_cur.lower():
hit_str_num += 1
break
# recg end
global_accumulative_recall = (
global_accumulative_recall +
num_qualified_sigma_candidates * fsc_k)
global_accumulative_precision = (
global_accumulative_precision + fsc_k)
local_accumulative_recall = (
local_accumulative_recall +
num_qualified_sigma_candidates * fsc_k)
local_accumulative_precision = local_accumulative_precision + fsc_k
return (
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, )
for idx in range(len(global_sigma)):
local_sigma_table = np.array(global_sigma[idx])
local_tau_table = global_tau[idx]
num_gt = local_sigma_table.shape[0]
num_det = local_sigma_table.shape[1]
total_num_gt = total_num_gt + num_gt
total_num_det = total_num_det + num_det
local_accumulative_recall = 0
local_accumulative_precision = 0
gt_flag = np.zeros((1, num_gt))
det_flag = np.zeros((1, num_det))
#######first check for one-to-one case##########
(
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, ) = one_to_one(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idx,
rec_flag, )
hit_str_count += hit_str_num
#######then check for one-to-many case##########
(
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, ) = one_to_many(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idx,
rec_flag, )
hit_str_count += hit_str_num
#######then check for many-to-one case##########
(
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
hit_str_num, ) = many_to_one(
local_sigma_table,
local_tau_table,
local_accumulative_recall,
local_accumulative_precision,
global_accumulative_recall,
global_accumulative_precision,
gt_flag,
det_flag,
idx,
rec_flag, )
hit_str_count += hit_str_num
try:
recall = global_accumulative_recall / total_num_gt
except ZeroDivisionError:
recall = 0
try:
precision = global_accumulative_precision / total_num_det
except ZeroDivisionError:
precision = 0
try:
f_score = 2 * precision * recall / (precision + recall)
except ZeroDivisionError:
f_score = 0
try:
seqerr = 1 - float(hit_str_count) / global_accumulative_recall
except ZeroDivisionError:
seqerr = 1
try:
recall_e2e = float(hit_str_count) / total_num_gt
except ZeroDivisionError:
recall_e2e = 0
try:
precision_e2e = float(hit_str_count) / total_num_det
except ZeroDivisionError:
precision_e2e = 0
try:
f_score_e2e = 2 * precision_e2e * recall_e2e / (
precision_e2e + recall_e2e)
except ZeroDivisionError:
f_score_e2e = 0
final = {
"total_num_gt": total_num_gt,
"total_num_det": total_num_det,
"global_accumulative_recall": global_accumulative_recall,
"hit_str_count": hit_str_count,
"recall": recall,
"precision": precision,
"f_score": f_score,
"seqerr": seqerr,
"recall_e2e": recall_e2e,
"precision_e2e": precision_e2e,
"f_score_e2e": f_score_e2e,
}
return final