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cherrydata / ssd-pytorch-master /utils /utils_map.py
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import glob
import json
import math
import operator
import os
import shutil
import sys
try:
 from pycocotools.coco import COCO
 from pycocotools.cocoeval import COCOeval
except:
 pass
import cv2
import matplotlib
matplotlib.use('Agg')
from matplotlib import pyplot as plt
import numpy as np
'''
 0,0 ------> x (width)
 |
 | (Left,Top)
 | *_________
 | | |
 | |
 y |_________|
 (height) *
 (Right,Bottom)
'''
def log_average_miss_rate(precision, fp_cumsum, num_images):
 """
 log-average miss rate:
 Calculated by averaging miss rates at 9 evenly spaced FPPI points
 between 10e-2 and 10e0, in log-space.
 output:
 lamr | log-average miss rate
 mr | miss rate
 fppi | false positives per image
 references:
 [1] Dollar, Piotr, et al. "Pedestrian Detection: An Evaluation of the
 State of the Art." Pattern Analysis and Machine Intelligence, IEEE
 Transactions on 34.4 (2012): 743 - 761.
 """
if precision.size == 0:
 lamr = 0
 mr = 1
 fppi = 0
 return lamr, mr, fppi
fppi = fp_cumsum / float(num_images)
 mr = (1 - precision)
fppi_tmp = np.insert(fppi, 0, -1.0)
 mr_tmp = np.insert(mr, 0, 1.0)
ref = np.logspace(-2.0, 0.0, num = 9)
 for i, ref_i in enumerate(ref):
 j = np.where(fppi_tmp <= ref_i)[-1][-1]
 ref[i] = mr_tmp[j]
lamr = math.exp(np.mean(np.log(np.maximum(1e-10, ref))))
return lamr, mr, fppi
"""
 throw error and exit
"""
def error(msg):
 print(msg)
 sys.exit(0)
"""
 check if the number is a float between 0.0 and 1.0
"""
def is_float_between_0_and_1(value):
 try:
 val = float(value)
 if val > 0.0 and val < 1.0:
 return True
 else:
 return False
 except ValueError:
 return False
"""
 Calculate the AP given the recall and precision array
 1st) We compute a version of the measured precision/recall curve with
 precision monotonically decreasing
 2nd) We compute the AP as the area under this curve by numerical integration.
"""
def voc_ap(rec, prec):
 """
 --- Official matlab code VOC2012---
 mrec=[0 ; rec ; 1];
 mpre=[0 ; prec ; 0];
 for i=numel(mpre)-1:-1:1
 mpre(i)=max(mpre(i),mpre(i+1));
 end
 i=find(mrec(2:end)~=mrec(1:end-1))+1;
 ap=sum((mrec(i)-mrec(i-1)).*mpre(i));
 """
 rec.insert(0, 0.0) # insert 0.0 at begining of list
 rec.append(1.0) # insert 1.0 at end of list
 mrec = rec[:]
 prec.insert(0, 0.0) # insert 0.0 at begining of list
 prec.append(0.0) # insert 0.0 at end of list
 mpre = prec[:]
 """
 This part makes the precision monotonically decreasing
 (goes from the end to the beginning)
 matlab: for i=numel(mpre)-1:-1:1
 mpre(i)=max(mpre(i),mpre(i+1));
 """
 for i in range(len(mpre)-2, -1, -1):
 mpre[i] = max(mpre[i], mpre[i+1])
 """
 This part creates a list of indexes where the recall changes
 matlab: i=find(mrec(2:end)~=mrec(1:end-1))+1;
 """
 i_list = []
 for i in range(1, len(mrec)):
 if mrec[i] != mrec[i-1]:
 i_list.append(i) # if it was matlab would be i + 1
 """
 The Average Precision (AP) is the area under the curve
 (numerical integration)
 matlab: ap=sum((mrec(i)-mrec(i-1)).*mpre(i));
 """
 ap = 0.0
 for i in i_list:
 ap += ((mrec[i]-mrec[i-1])*mpre[i])
 return ap, mrec, mpre
"""
 Convert the lines of a file to a list
"""
def file_lines_to_list(path):
 # open txt file lines to a list
 with open(path) as f:
 content = f.readlines()
 # remove whitespace characters like `\n` at the end of each line
 content = [x.strip() for x in content]
 return content
"""
 Draws text in image
"""
def draw_text_in_image(img, text, pos, color, line_width):
 font = cv2.FONT_HERSHEY_PLAIN
 fontScale = 1
 lineType = 1
 bottomLeftCornerOfText = pos
 cv2.putText(img, text,
 bottomLeftCornerOfText,
 font,
 fontScale,
 color,
 lineType)
 text_width, _ = cv2.getTextSize(text, font, fontScale, lineType)[0]
 return img, (line_width + text_width)
"""
 Plot - adjust axes
"""
def adjust_axes(r, t, fig, axes):
 # get text width for re-scaling
 bb = t.get_window_extent(renderer=r)
 text_width_inches = bb.width / fig.dpi
 # get axis width in inches
 current_fig_width = fig.get_figwidth()
 new_fig_width = current_fig_width + text_width_inches
 propotion = new_fig_width / current_fig_width
 # get axis limit
 x_lim = axes.get_xlim()
 axes.set_xlim([x_lim[0], x_lim[1]*propotion])
"""
 Draw plot using Matplotlib
"""
def draw_plot_func(dictionary, n_classes, window_title, plot_title, x_label, output_path, to_show, plot_color, true_p_bar):
 # sort the dictionary by decreasing value, into a list of tuples
 sorted_dic_by_value = sorted(dictionary.items(), key=operator.itemgetter(1))
 # unpacking the list of tuples into two lists
 sorted_keys, sorted_values = zip(*sorted_dic_by_value)
 #
if true_p_bar != "":
 """
 Special case to draw in:
 - green -> TP: True Positives (object detected and matches ground-truth)
 - red -> FP: False Positives (object detected but does not match ground-truth)
 - orange -> FN: False Negatives (object not detected but present in the ground-truth)
 """
 fp_sorted = []
 tp_sorted = []
 for key in sorted_keys:
 fp_sorted.append(dictionary[key] - true_p_bar[key])
 tp_sorted.append(true_p_bar[key])
 plt.barh(range(n_classes), fp_sorted, align='center', color='crimson', label='False Positive')
 plt.barh(range(n_classes), tp_sorted, align='center', color='forestgreen', label='True Positive', left=fp_sorted)
 # add legend
 plt.legend(loc='lower right')
 """
 Write number on side of bar
 """
 fig = plt.gcf() # gcf - get current figure
 axes = plt.gca()
 r = fig.canvas.get_renderer()
 for i, val in enumerate(sorted_values):
 fp_val = fp_sorted[i]
 tp_val = tp_sorted[i]
 fp_str_val = " " + str(fp_val)
 tp_str_val = fp_str_val + " " + str(tp_val)
 # trick to paint multicolor with offset:
 # first paint everything and then repaint the first number
 t = plt.text(val, i, tp_str_val, color='forestgreen', va='center', fontweight='bold')
 plt.text(val, i, fp_str_val, color='crimson', va='center', fontweight='bold')
 if i == (len(sorted_values)-1): # largest bar
 adjust_axes(r, t, fig, axes)
 else:
 plt.barh(range(n_classes), sorted_values, color=plot_color)
 """
 Write number on side of bar
 """
 fig = plt.gcf() # gcf - get current figure
 axes = plt.gca()
 r = fig.canvas.get_renderer()
 for i, val in enumerate(sorted_values):
 str_val = " " + str(val) # add a space before
 if val < 1.0:
 str_val = " {0:.2f}".format(val)
 t = plt.text(val, i, str_val, color=plot_color, va='center', fontweight='bold')
 # re-set axes to show number inside the figure
 if i == (len(sorted_values)-1): # largest bar
 adjust_axes(r, t, fig, axes)
 # set window title
 fig.canvas.set_window_title(window_title)
 # write classes in y axis
 tick_font_size = 12
 plt.yticks(range(n_classes), sorted_keys, fontsize=tick_font_size)
 """
 Re-scale height accordingly
 """
 init_height = fig.get_figheight()
 # comput the matrix height in points and inches
 dpi = fig.dpi
 height_pt = n_classes * (tick_font_size * 1.4) # 1.4 (some spacing)
 height_in = height_pt / dpi
 # compute the required figure height
top_margin = 0.15 # in percentage of the figure height
 bottom_margin = 0.05 # in percentage of the figure height
 figure_height = height_in / (1 - top_margin - bottom_margin)
 # set new height
 if figure_height > init_height:
 fig.set_figheight(figure_height)
# set plot title
 plt.title(plot_title, fontsize=14)
 # set axis titles
 # plt.xlabel('classes')
 plt.xlabel(x_label, fontsize='large')
 # adjust size of window
 fig.tight_layout()
 # save the plot
 fig.savefig(output_path)
 # show image
 if to_show:
 plt.show()
 # close the plot
 plt.close()
def get_map(MINOVERLAP, draw_plot, score_threhold=0.5, path = './map_out'):
 GT_PATH = os.path.join(path, 'ground-truth')
 DR_PATH = os.path.join(path, 'detection-results')
 IMG_PATH = os.path.join(path, 'images-optional')
 TEMP_FILES_PATH = os.path.join(path, '.temp_files')
 RESULTS_FILES_PATH = os.path.join(path, 'results')
show_animation = True
 if os.path.exists(IMG_PATH):
for dirpath, dirnames, files in os.walk(IMG_PATH):
 if not files:
 show_animation = False
 else:
 show_animation = False
if not os.path.exists(TEMP_FILES_PATH):
 os.makedirs(TEMP_FILES_PATH)
if os.path.exists(RESULTS_FILES_PATH):
 shutil.rmtree(RESULTS_FILES_PATH)
 else:
 os.makedirs(RESULTS_FILES_PATH)
 if draw_plot:
 try:
 matplotlib.use('TkAgg')
 except:
 pass
 os.makedirs(os.path.join(RESULTS_FILES_PATH, "AP"))
 os.makedirs(os.path.join(RESULTS_FILES_PATH, "F1"))
 os.makedirs(os.path.join(RESULTS_FILES_PATH, "Recall"))
 os.makedirs(os.path.join(RESULTS_FILES_PATH, "Precision"))
 if show_animation:
 os.makedirs(os.path.join(RESULTS_FILES_PATH, "images", "detections_one_by_one"))
ground_truth_files_list = glob.glob(GT_PATH + '/*.txt')
 if len(ground_truth_files_list) == 0:
 error("Error: No ground-truth files found!")
 ground_truth_files_list.sort()
 gt_counter_per_class = {}
 counter_images_per_class = {}
for txt_file in ground_truth_files_list:
 file_id = txt_file.split(".txt", 1)[0]
 file_id = os.path.basename(os.path.normpath(file_id))
 temp_path = os.path.join(DR_PATH, (file_id + ".txt"))
 if not os.path.exists(temp_path):
 error_msg = "Error. File not found: {}\n".format(temp_path)
 error(error_msg)
 lines_list = file_lines_to_list(txt_file)
 bounding_boxes = []
 is_difficult = False
 already_seen_classes = []
 for line in lines_list:
 try:
 if "difficult" in line:
 class_name, left, top, right, bottom, _difficult = line.split()
 is_difficult = True
 else:
 class_name, left, top, right, bottom = line.split()
 except:
 if "difficult" in line:
 line_split = line.split()
 _difficult = line_split[-1]
 bottom = line_split[-2]
 right = line_split[-3]
 top = line_split[-4]
 left = line_split[-5]
 class_name = ""
 for name in line_split[:-5]:
 class_name += name + " "
 class_name = class_name[:-1]
 is_difficult = True
 else:
 line_split = line.split()
 bottom = line_split[-1]
 right = line_split[-2]
 top = line_split[-3]
 left = line_split[-4]
 class_name = ""
 for name in line_split[:-4]:
 class_name += name + " "
 class_name = class_name[:-1]
bbox = left + " " + top + " " + right + " " + bottom
 if is_difficult:
 bounding_boxes.append({"class_name":class_name, "bbox":bbox, "used":False, "difficult":True})
 is_difficult = False
 else:
 bounding_boxes.append({"class_name":class_name, "bbox":bbox, "used":False})
 if class_name in gt_counter_per_class:
 gt_counter_per_class[class_name] += 1
 else:
 gt_counter_per_class[class_name] = 1
if class_name not in already_seen_classes:
 if class_name in counter_images_per_class:
 counter_images_per_class[class_name] += 1
 else:
 counter_images_per_class[class_name] = 1
 already_seen_classes.append(class_name)
with open(TEMP_FILES_PATH + "/" + file_id + "_ground_truth.json", 'w') as outfile:
 json.dump(bounding_boxes, outfile)
gt_classes = list(gt_counter_per_class.keys())
 gt_classes = sorted(gt_classes)
 n_classes = len(gt_classes)
dr_files_list = glob.glob(DR_PATH + '/*.txt')
 dr_files_list.sort()
 for class_index, class_name in enumerate(gt_classes):
 bounding_boxes = []
 for txt_file in dr_files_list:
 file_id = txt_file.split(".txt",1)[0]
 file_id = os.path.basename(os.path.normpath(file_id))
 temp_path = os.path.join(GT_PATH, (file_id + ".txt"))
 if class_index == 0:
 if not os.path.exists(temp_path):
 error_msg = "Error. File not found: {}\n".format(temp_path)
 error(error_msg)
 lines = file_lines_to_list(txt_file)
 for line in lines:
 try:
 tmp_class_name, confidence, left, top, right, bottom = line.split()
 except:
 line_split = line.split()
 bottom = line_split[-1]
 right = line_split[-2]
 top = line_split[-3]
 left = line_split[-4]
 confidence = line_split[-5]
 tmp_class_name = ""
 for name in line_split[:-5]:
 tmp_class_name += name + " "
 tmp_class_name = tmp_class_name[:-1]
if tmp_class_name == class_name:
 bbox = left + " " + top + " " + right + " " +bottom
 bounding_boxes.append({"confidence":confidence, "file_id":file_id, "bbox":bbox})
bounding_boxes.sort(key=lambda x:float(x['confidence']), reverse=True)
 with open(TEMP_FILES_PATH + "/" + class_name + "_dr.json", 'w') as outfile:
 json.dump(bounding_boxes, outfile)
sum_AP = 0.0
 ap_dictionary = {}
 lamr_dictionary = {}
 with open(RESULTS_FILES_PATH + "/results.txt", 'w') as results_file:
 results_file.write("# AP and precision/recall per class\n")
 count_true_positives = {}
for class_index, class_name in enumerate(gt_classes):
 count_true_positives[class_name] = 0
 dr_file = TEMP_FILES_PATH + "/" + class_name + "_dr.json"
 dr_data = json.load(open(dr_file))
nd = len(dr_data)
 tp = [0] * nd
 fp = [0] * nd
 score = [0] * nd
 score_threhold_idx = 0
 for idx, detection in enumerate(dr_data):
 file_id = detection["file_id"]
 score[idx] = float(detection["confidence"])
 if score[idx] >= score_threhold:
 score_threhold_idx = idx
if show_animation:
 ground_truth_img = glob.glob1(IMG_PATH, file_id + ".*")
 if len(ground_truth_img) == 0:
 error("Error. Image not found with id: " + file_id)
 elif len(ground_truth_img) > 1:
 error("Error. Multiple image with id: " + file_id)
 else:
 img = cv2.imread(IMG_PATH + "/" + ground_truth_img[0])
 img_cumulative_path = RESULTS_FILES_PATH + "/images/" + ground_truth_img[0]
 if os.path.isfile(img_cumulative_path):
 img_cumulative = cv2.imread(img_cumulative_path)
 else:
 img_cumulative = img.copy()
 bottom_border = 60
 BLACK = [0, 0, 0]
 img = cv2.copyMakeBorder(img, 0, bottom_border, 0, 0, cv2.BORDER_CONSTANT, value=BLACK)
gt_file = TEMP_FILES_PATH + "/" + file_id + "_ground_truth.json"
 ground_truth_data = json.load(open(gt_file))
 ovmax = -1
 gt_match = -1
 bb = [float(x) for x in detection["bbox"].split()]
 for obj in ground_truth_data:
 if obj["class_name"] == class_name:
 bbgt = [ float(x) for x in obj["bbox"].split() ]
 bi = [max(bb[0],bbgt[0]), max(bb[1],bbgt[1]), min(bb[2],bbgt[2]), min(bb[3],bbgt[3])]
 iw = bi[2] - bi[0] + 1
 ih = bi[3] - bi[1] + 1
 if iw > 0 and ih > 0:
 ua = (bb[2] - bb[0] + 1) * (bb[3] - bb[1] + 1) + (bbgt[2] - bbgt[0]
 + 1) * (bbgt[3] - bbgt[1] + 1) - iw * ih
 ov = iw * ih / ua
 if ov > ovmax:
 ovmax = ov
 gt_match = obj
if show_animation:
 status = "NO MATCH FOUND!"
min_overlap = MINOVERLAP
 if ovmax >= min_overlap:
 if "difficult" not in gt_match:
 if not bool(gt_match["used"]):
 tp[idx] = 1
 gt_match["used"] = True
 count_true_positives[class_name] += 1
 with open(gt_file, 'w') as f:
 f.write(json.dumps(ground_truth_data))
 if show_animation:
 status = "MATCH!"
 else:
 fp[idx] = 1
 if show_animation:
 status = "REPEATED MATCH!"
 else:
 fp[idx] = 1
 if ovmax > 0:
 status = "INSUFFICIENT OVERLAP"
"""
 Draw image to show animation
 """
 if show_animation:
 height, widht = img.shape[:2]
 white = (255,255,255)
 light_blue = (255,200,100)
 green = (0,255,0)
 light_red = (30,30,255)
 margin = 10
 # 1nd line
 v_pos = int(height - margin - (bottom_border / 2.0))
 text = "Image: " + ground_truth_img[0] + " "
 img, line_width = draw_text_in_image(img, text, (margin, v_pos), white, 0)
 text = "Class [" + str(class_index) + "/" + str(n_classes) + "]: " + class_name + " "
 img, line_width = draw_text_in_image(img, text, (margin + line_width, v_pos), light_blue, line_width)
 if ovmax != -1:
 color = light_red
 if status == "INSUFFICIENT OVERLAP":
 text = "IoU: {0:.2f}% ".format(ovmax*100) + "< {0:.2f}% ".format(min_overlap*100)
 else:
 text = "IoU: {0:.2f}% ".format(ovmax*100) + ">= {0:.2f}% ".format(min_overlap*100)
 color = green
 img, _ = draw_text_in_image(img, text, (margin + line_width, v_pos), color, line_width)
 # 2nd line
 v_pos += int(bottom_border / 2.0)
 rank_pos = str(idx+1)
 text = "Detection #rank: " + rank_pos + " confidence: {0:.2f}% ".format(float(detection["confidence"])*100)
 img, line_width = draw_text_in_image(img, text, (margin, v_pos), white, 0)
 color = light_red
 if status == "MATCH!":
 color = green
 text = "Result: " + status + " "
 img, line_width = draw_text_in_image(img, text, (margin + line_width, v_pos), color, line_width)
font = cv2.FONT_HERSHEY_SIMPLEX
 if ovmax > 0:
bbgt = [ int(round(float(x))) for x in gt_match["bbox"].split() ]
 cv2.rectangle(img,(bbgt[0],bbgt[1]),(bbgt[2],bbgt[3]),light_blue,2)
 cv2.rectangle(img_cumulative,(bbgt[0],bbgt[1]),(bbgt[2],bbgt[3]),light_blue,2)
 cv2.putText(img_cumulative, class_name, (bbgt[0],bbgt[1] - 5), font, 0.6, light_blue, 1, cv2.LINE_AA)
 bb = [int(i) for i in bb]
 cv2.rectangle(img,(bb[0],bb[1]),(bb[2],bb[3]),color,2)
 cv2.rectangle(img_cumulative,(bb[0],bb[1]),(bb[2],bb[3]),color,2)
 cv2.putText(img_cumulative, class_name, (bb[0],bb[1] - 5), font, 0.6, color, 1, cv2.LINE_AA)
cv2.imshow("Animation", img)
 cv2.waitKey(20)
output_img_path = RESULTS_FILES_PATH + "/images/detections_one_by_one/" + class_name + "_detection" + str(idx) + ".jpg"
 cv2.imwrite(output_img_path, img)
 cv2.imwrite(img_cumulative_path, img_cumulative)
cumsum = 0
 for idx, val in enumerate(fp):
 fp[idx] += cumsum
 cumsum += val
cumsum = 0
 for idx, val in enumerate(tp):
 tp[idx] += cumsum
 cumsum += val
rec = tp[:]
 for idx, val in enumerate(tp):
 rec[idx] = float(tp[idx]) / np.maximum(gt_counter_per_class[class_name], 1)
prec = tp[:]
 for idx, val in enumerate(tp):
 prec[idx] = float(tp[idx]) / np.maximum((fp[idx] + tp[idx]), 1)
ap, mrec, mprec = voc_ap(rec[:], prec[:])
 F1 = np.array(rec)*np.array(prec)*2 / np.where((np.array(prec)+np.array(rec))==0, 1, (np.array(prec)+np.array(rec)))
sum_AP += ap
 text = "{0:.2f}%".format(ap*100) + " = " + class_name + " AP " #class_name + " AP = {0:.2f}%".format(ap*100)
if len(prec)>0:
 F1_text = "{0:.2f}".format(F1[score_threhold_idx]) + " = " + class_name + " F1 "
 Recall_text = "{0:.2f}%".format(rec[score_threhold_idx]*100) + " = " + class_name + " Recall "
 Precision_text = "{0:.2f}%".format(prec[score_threhold_idx]*100) + " = " + class_name + " Precision "
 else:
 F1_text = "0.00" + " = " + class_name + " F1 "
Recall_text = "0.00%" + " = " + class_name + " Recall "
Precision_text = "0.00%" + " = " + class_name + " Precision "
rounded_prec = [ '%.2f' % elem for elem in prec ]
 rounded_rec = [ '%.2f' % elem for elem in rec ]
 results_file.write(text + "\n Precision: " + str(rounded_prec) + "\n Recall :" + str(rounded_rec) + "\n\n")
if len(prec)>0:
 print(text + "\t||\tscore_threhold=" + str(score_threhold) + " : " + "F1=" + "{0:.2f}".format(F1[score_threhold_idx])\
 + " ; Recall=" + "{0:.2f}%".format(rec[score_threhold_idx]*100) + " ; Precision=" + "{0:.2f}%".format(prec[score_threhold_idx]*100))
 else:
 print(text + "\t||\tscore_threhold=" + str(score_threhold) + " : " + "F1=0.00% ; Recall=0.00% ; Precision=0.00%")
 ap_dictionary[class_name] = ap
n_images = counter_images_per_class[class_name]
 lamr, mr, fppi = log_average_miss_rate(np.array(rec), np.array(fp), n_images)
 lamr_dictionary[class_name] = lamr
if draw_plot:
 plt.plot(rec, prec, '-o')
 area_under_curve_x = mrec[:-1] + [mrec[-2]] + [mrec[-1]]
 area_under_curve_y = mprec[:-1] + [0.0] + [mprec[-1]]
 plt.fill_between(area_under_curve_x, 0, area_under_curve_y, alpha=0.2, edgecolor='r')
fig = plt.gcf()
 fig.canvas.set_window_title('AP ' + class_name)
plt.title('class: ' + text)
 plt.xlabel('Recall')
 plt.ylabel('Precision')
 axes = plt.gca()
 axes.set_xlim([0.0,1.0])
 axes.set_ylim([0.0,1.05])
fig.savefig(RESULTS_FILES_PATH + "/AP/" + class_name + ".png")
 plt.cla()
plt.plot(score, F1, "-", color='orangered')
 plt.title('class: ' + F1_text + "\nscore_threhold=" + str(score_threhold))
 plt.xlabel('Score_Threhold')
 plt.ylabel('F1')
 axes = plt.gca()
 axes.set_xlim([0.0,1.0])
 axes.set_ylim([0.0,1.05])
 fig.savefig(RESULTS_FILES_PATH + "/F1/" + class_name + ".png")
 plt.cla()
plt.plot(score, rec, "-H", color='gold')
 plt.title('class: ' + Recall_text + "\nscore_threhold=" + str(score_threhold))
 plt.xlabel('Score_Threhold')
 plt.ylabel('Recall')
 axes = plt.gca()
 axes.set_xlim([0.0,1.0])
 axes.set_ylim([0.0,1.05])
 fig.savefig(RESULTS_FILES_PATH + "/Recall/" + class_name + ".png")
 plt.cla()
plt.plot(score, prec, "-s", color='palevioletred')
 plt.title('class: ' + Precision_text + "\nscore_threhold=" + str(score_threhold))
 plt.xlabel('Score_Threhold')
 plt.ylabel('Precision')
 axes = plt.gca()
 axes.set_xlim([0.0,1.0])
 axes.set_ylim([0.0,1.05])
 fig.savefig(RESULTS_FILES_PATH + "/Precision/" + class_name + ".png")
 plt.cla()
if show_animation:
 cv2.destroyAllWindows()
 if n_classes == 0:
 print("未检测到任何种类,请检查标签信息与get_map.py中的classes_path是否修改。")
 return 0
 results_file.write("\n# mAP of all classes\n")
 mAP = sum_AP / n_classes
 text = "mAP = {0:.2f}%".format(mAP*100)
 results_file.write(text + "\n")
 print(text)
shutil.rmtree(TEMP_FILES_PATH)
"""
 Count total of detection-results
 """
 det_counter_per_class = {}
 for txt_file in dr_files_list:
 lines_list = file_lines_to_list(txt_file)
 for line in lines_list:
 class_name = line.split()[0]
 if class_name in det_counter_per_class:
 det_counter_per_class[class_name] += 1
 else:
 det_counter_per_class[class_name] = 1
 dr_classes = list(det_counter_per_class.keys())
"""
 Write number of ground-truth objects per class to results.txt
 """
 with open(RESULTS_FILES_PATH + "/results.txt", 'a') as results_file:
 results_file.write("\n# Number of ground-truth objects per class\n")
 for class_name in sorted(gt_counter_per_class):
 results_file.write(class_name + ": " + str(gt_counter_per_class[class_name]) + "\n")
"""
 Finish counting true positives
 """
 for class_name in dr_classes:
 if class_name not in gt_classes:
 count_true_positives[class_name] = 0
"""
 Write number of detected objects per class to results.txt
 """
 with open(RESULTS_FILES_PATH + "/results.txt", 'a') as results_file:
 results_file.write("\n# Number of detected objects per class\n")
 for class_name in sorted(dr_classes):
 n_det = det_counter_per_class[class_name]
 text = class_name + ": " + str(n_det)
 text += " (tp:" + str(count_true_positives[class_name]) + ""
 text += ", fp:" + str(n_det - count_true_positives[class_name]) + ")\n"
 results_file.write(text)
"""
 Plot the total number of occurences of each class in the ground-truth
 """
 if draw_plot:
 window_title = "ground-truth-info"
 plot_title = "ground-truth\n"
 plot_title += "(" + str(len(ground_truth_files_list)) + " files and " + str(n_classes) + " classes)"
 x_label = "Number of objects per class"
 output_path = RESULTS_FILES_PATH + "/ground-truth-info.png"
 to_show = False
 plot_color = 'forestgreen'
 draw_plot_func(
 gt_counter_per_class,
 n_classes,
 window_title,
 plot_title,
 x_label,
 output_path,
 to_show,
 plot_color,
 '',
 )
# """
 # Plot the total number of occurences of each class in the "detection-results" folder
 # """
 # if draw_plot:
 # window_title = "detection-results-info"
 # # Plot title
 # plot_title = "detection-results\n"
 # plot_title += "(" + str(len(dr_files_list)) + " files and "
 # count_non_zero_values_in_dictionary = sum(int(x) > 0 for x in list(det_counter_per_class.values()))
 # plot_title += str(count_non_zero_values_in_dictionary) + " detected classes)"
 # # end Plot title
 # x_label = "Number of objects per class"
 # output_path = RESULTS_FILES_PATH + "/detection-results-info.png"
 # to_show = False
 # plot_color = 'forestgreen'
 # true_p_bar = count_true_positives
 # draw_plot_func(
 # det_counter_per_class,
 # len(det_counter_per_class),
 # window_title,
 # plot_title,
 # x_label,
 # output_path,
 # to_show,
 # plot_color,
 # true_p_bar
 # )
"""
 Draw log-average miss rate plot (Show lamr of all classes in decreasing order)
 """
 if draw_plot:
 window_title = "lamr"
 plot_title = "log-average miss rate"
 x_label = "log-average miss rate"
 output_path = RESULTS_FILES_PATH + "/lamr.png"
 to_show = False
 plot_color = 'royalblue'
 draw_plot_func(
 lamr_dictionary,
 n_classes,
 window_title,
 plot_title,
 x_label,
 output_path,
 to_show,
 plot_color,
 ""
 )
"""
 Draw mAP plot (Show AP's of all classes in decreasing order)
 """
 if draw_plot:
 window_title = "mAP"
 plot_title = "mAP = {0:.2f}%".format(mAP*100)
 x_label = "Average Precision"
 output_path = RESULTS_FILES_PATH + "/mAP.png"
 to_show = True
 plot_color = 'royalblue'
 draw_plot_func(
 ap_dictionary,
 n_classes,
 window_title,
 plot_title,
 x_label,
 output_path,
 to_show,
 plot_color,
 ""
 )
 return mAP
def preprocess_gt(gt_path, class_names):
 image_ids = os.listdir(gt_path)
 results = {}
images = []
 bboxes = []
 for i, image_id in enumerate(image_ids):
 lines_list = file_lines_to_list(os.path.join(gt_path, image_id))
 boxes_per_image = []
 image = {}
 image_id = os.path.splitext(image_id)[0]
 image['file_name'] = image_id + '.jpg'
 image['width'] = 1
 image['height'] = 1
 #-----------------------------------------------------------------#
 # 感谢 多学学英语吧 的提醒
 # 解决了'Results do not correspond to current coco set'问题
 #-----------------------------------------------------------------#
 image['id'] = str(image_id)
for line in lines_list:
 difficult = 0
if "difficult" in line:
 line_split = line.split()
 left, top, right, bottom, _difficult = line_split[-5:]
 class_name = ""
 for name in line_split[:-5]:
 class_name += name + " "
 class_name = class_name[:-1]
 difficult = 1
 else:
 line_split = line.split()
 left, top, right, bottom = line_split[-4:]
 class_name = ""
 for name in line_split[:-4]:
 class_name += name + " "
 class_name = class_name[:-1]
left, top, right, bottom = float(left), float(top), float(right), float(bottom)
 if class_name not in class_names:
 continue
 cls_id = class_names.index(class_name) + 1
 bbox = [left, top, right - left, bottom - top, difficult, str(image_id), cls_id, (right - left) * (bottom - top) - 10.0]
 boxes_per_image.append(bbox)
 images.append(image)
 bboxes.extend(boxes_per_image)
 results['images'] = images
categories = []
 for i, cls in enumerate(class_names):
 category = {}
 category['supercategory'] = cls
 category['name'] = cls
 category['id'] = i + 1
 categories.append(category)
 results['categories'] = categories
annotations = []
 for i, box in enumerate(bboxes):
 annotation = {}
 annotation['area'] = box[-1]
 annotation['category_id'] = box[-2]
 annotation['image_id'] = box[-3]
 annotation['iscrowd'] = box[-4]
 annotation['bbox'] = box[:4]
 annotation['id'] = i
 annotations.append(annotation)
 results['annotations'] = annotations
 return results
def preprocess_dr(dr_path, class_names):
 image_ids = os.listdir(dr_path)
 results = []
 for image_id in image_ids:
 lines_list = file_lines_to_list(os.path.join(dr_path, image_id))
 image_id = os.path.splitext(image_id)[0]
 for line in lines_list:
 line_split = line.split()
 confidence, left, top, right, bottom = line_split[-5:]
 class_name = ""
 for name in line_split[:-5]:
 class_name += name + " "
 class_name = class_name[:-1]
 left, top, right, bottom = float(left), float(top), float(right), float(bottom)
 result = {}
 result["image_id"] = str(image_id)
 if class_name not in class_names:
 continue
 result["category_id"] = class_names.index(class_name) + 1
 result["bbox"] = [left, top, right - left, bottom - top]
 result["score"] = float(confidence)
 results.append(result)
 return results
def get_coco_map(class_names, path):
 GT_PATH = os.path.join(path, 'ground-truth')
 DR_PATH = os.path.join(path, 'detection-results')
 COCO_PATH = os.path.join(path, 'coco_eval')
if not os.path.exists(COCO_PATH):
 os.makedirs(COCO_PATH)
GT_JSON_PATH = os.path.join(COCO_PATH, 'instances_gt.json')
 DR_JSON_PATH = os.path.join(COCO_PATH, 'instances_dr.json')
with open(GT_JSON_PATH, "w") as f:
 results_gt = preprocess_gt(GT_PATH, class_names)
 json.dump(results_gt, f, indent=4)
with open(DR_JSON_PATH, "w") as f:
 results_dr = preprocess_dr(DR_PATH, class_names)
 json.dump(results_dr, f, indent=4)
 if len(results_dr) == 0:
 print("未检测到任何目标。")
 return [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]
cocoGt = COCO(GT_JSON_PATH)
 cocoDt = cocoGt.loadRes(DR_JSON_PATH)
 cocoEval = COCOeval(cocoGt, cocoDt, 'bbox')
cocoEval.evaluate()
 cocoEval.accumulate()
 cocoEval.summarize()
return cocoEval.stats