train_frcnn.py

from __future__ import division
import random
import pprint
import sys
import time
import numpy as np
from optparse import OptionParser
import pickle

from keras import backend as K
from keras.optimizers import Adam, SGD, RMSprop
from keras.layers import Input
from keras.models import Model
from faster_rcnn import config, data_generators
from faster_rcnn import losses as losses
from faster_rcnn import resnet as nn
from faster_rcnn.parser import get_data
import faster_rcnn.roi_helpers as roi_helpers
from keras.utils import generic_utils

sys.setrecursionlimit(40000)

parser = OptionParser()
parser.add_option("-p", "--path", dest="train_path", help="Path to training data.")
parser.add_option("--hf", dest="horizontal_flips", help="Augment with horizontal flips in training. (Default=false).", action="store_true", default=False)
parser.add_option("--vf", dest="vertical_flips", help="Augment with vertical flips in training. (Default=false).", action="store_true", default=False)
parser.add_option("--rot", "--rot_90", dest="rot_90", help="Augment with 90 degree rotations in training. (Default=false).",
                  action="store_true", default=False)
(options, args) = parser.parse_args()

if not options.train_path:   # if filename is not given
    parser.error('Error: path to training data must be specified. Pass --path to command line')

# pass the settings from the command line, and persist them in the config object
C = config.Config()
C.use_horizontal_flips = bool(options.horizontal_flips)
C.use_vertical_flips = bool(options.vertical_flips)
C.rot_90 = bool(options.rot_90)

all_imgs, classes_count, class_mapping = get_data(options.train_path)
C.class_mapping = class_mapping

with open(C.config_filename, 'wb') as config_f:
    pickle.dump(C,config_f)
    print('Config has been written to {}, and can be loaded when testing to ensure correct results'.format(C.config_filename))

train_imgs = [s for s in all_imgs if s['imageset'] == 'trainval']
val_imgs = [s for s in all_imgs if s['imageset'] == 'test']

print('Train samples {}, Val samples {}'.format(len(train_imgs), len(val_imgs)))

data_gen_train = data_generators.get_anchor_gt(train_imgs, classes_count, C, K.image_dim_ordering(), mode='train')
data_gen_val = data_generators.get_anchor_gt(val_imgs, classes_count, C, K.image_dim_ordering(), mode='val')

img_input = Input(shape=(None, None, 3))
roi_input = Input(shape=(C.num_rois, 4))

# define the base network (resnet here)
shared_layers = nn.nn_base(img_input, trainable=True)

# define the RPN, built on the base layers
num_anchors = len(C.anchor_box_scales) * len(C.anchor_box_ratios)
rpn = nn.rpn(shared_layers, num_anchors)

# define the classifer, built on the base layers
classifier = nn.classifier(shared_layers, roi_input, C.num_rois, nb_classes=len(classes_count), trainable=True)

# defining the models and a model that holds both the RPN and the classifier
model_rpn = Model(img_input, rpn[:2])
model_classifier = Model([img_input, roi_input], classifier)
model_all = Model([img_input, roi_input], rpn[:2] + classifier)

model_rpn.compile(optimizer=Adam(lr=1e-4), loss=[losses.rpn_loss_cls(num_anchors), losses.rpn_loss_regr(num_anchors)])
model_classifier.compile(optimizer=Adam(lr=1e-4), loss=[losses.class_loss_cls, losses.class_loss_regr(len(classes_count)-1)], metrics={'dense_class_{}'.format(len(classes_count)): 'accuracy'})
model_all.compile(optimizer='sgd', loss='mae')

epoch_length = 1000
num_epochs = 2000
iter_num = 0

losses = np.zeros((epoch_length, 5))
rpn_accuracy_rpn_monitor, rpn_accuracy_for_epoch = [], []
t0 = start_time = time.time()

best_loss = np.Inf
with open('out.csv', 'w') as f:
    f.write('Accuracy,RPN classifier,RPN regression,Detector classifier,Detector regression,Total')
    f.write('\t')

try:
    for epoch_num in range(num_epochs):
        progbar = generic_utils.Progbar(epoch_length)
        print('Epoch {}/{}'.format(epoch_num + 1, num_epochs))
        while True:
            try:
                if len(rpn_accuracy_rpn_monitor) == epoch_length and C.verbose:
                    mean_overlapping_bboxes = float(sum(rpn_accuracy_rpn_monitor))/len(rpn_accuracy_rpn_monitor)
                    rpn_accuracy_rpn_monitor = []
                    print('Average number of overlapping bounding boxes from RPN = {} for {} previous iterations'.format(mean_overlapping_bboxes, epoch_length))
                    if mean_overlapping_bboxes == 0:
                        print('RPN is not producing bounding boxes that overlap the ground truth boxes. Check RPN settings or keep training.')

                X, Y, img_data = next(data_gen_train)
                loss_rpn = model_rpn.train_on_batch(X, Y)
                P_rpn = model_rpn.predict_on_batch(X)
                R = roi_helpers.rpn_to_roi(P_rpn[0], P_rpn[1], C, K.image_dim_ordering(), use_regr=True, overlap_thresh=0.7, max_boxes=300)

                # note: calc_iou converts from (x1,y1,x2,y2) to (x,y,w,h) format
                X2, Y1, Y2 = roi_helpers.calc_iou(R, img_data, C, class_mapping)

                neg_samples = np.where(Y1[0, :, -1] == 1)
                pos_samples = np.where(Y1[0, :, -1] == 0)

                if len(neg_samples) > 0:
                    neg_samples = neg_samples[0]
                else:
                    neg_samples = []

                if len(pos_samples) > 0:
                    pos_samples = pos_samples[0]
                else:
                    pos_samples = []

                rpn_accuracy_rpn_monitor.append(len(pos_samples))
                rpn_accuracy_for_epoch.append((len(pos_samples)))

                if len(pos_samples) < C.num_rois//2:
                    selected_pos_samples = pos_samples.tolist()
                else:
                    selected_pos_samples = np.random.choice(pos_samples, C.num_rois//2, replace=False).tolist()
                try:
                    selected_neg_samples = np.random.choice(neg_samples, C.num_rois - len(selected_pos_samples), replace=False).tolist()
                except:
                    selected_neg_samples = np.random.choice(neg_samples, C.num_rois - len(selected_pos_samples), replace=True).tolist()

                sel_samples = selected_pos_samples + selected_neg_samples

                loss_class = model_classifier.train_on_batch([X, X2[:, sel_samples, :]], [Y1[:, sel_samples, :], Y2[:, sel_samples, :]])

                losses[iter_num, 0] = loss_rpn[1]
                losses[iter_num, 1] = loss_rpn[2]

                losses[iter_num, 2] = loss_class[1]
                losses[iter_num, 3] = loss_class[2]
                losses[iter_num, 4] = loss_class[3]

                iter_num += 1

                progbar.update(iter_num, [('rpn_cls', np.mean(losses[:iter_num, 0])), ('rpn_regr', np.mean(losses[:iter_num, 1])),
                                          ('detector_cls', np.mean(losses[:iter_num, 2])), ('detector_regr', np.mean(losses[:iter_num, 3]))])

                if iter_num == epoch_length:
                    loss_rpn_cls = np.mean(losses[:, 0])
                    loss_rpn_regr = np.mean(losses[:, 1])
                    loss_class_cls = np.mean(losses[:, 2])
                    loss_class_regr = np.mean(losses[:, 3])
                    class_acc = np.mean(losses[:, 4])

                    mean_overlapping_bboxes = float(sum(rpn_accuracy_for_epoch)) / len(rpn_accuracy_for_epoch)
                    rpn_accuracy_for_epoch = []

                    if C.verbose:
                        print('Mean number of bounding boxes from RPN overlapping ground truth boxes: {}'.format(mean_overlapping_bboxes))
                        print('Classifier accuracy for bounding boxes from RPN: {}'.format(class_acc))
                        print('Loss RPN classifier: {}'.format(loss_rpn_cls))
                        print('Loss RPN regression: {}'.format(loss_rpn_regr))
                        print('Loss Detector classifier: {}'.format(loss_class_cls))
                        print('Loss Detector regression: {}'.format(loss_class_regr))
                        print('Elapsed time: {}'.format(time.time() - start_time))

                    target_text_file = open('out.csv', 'a')
                    target_text_file.write('{},{},{},{},{},{}'.format(class_acc, loss_rpn_cls, 
                                            loss_rpn_regr, loss_class_cls, loss_class_regr, 
                                            loss_rpn_cls + loss_rpn_regr + loss_class_cls + loss_class_regr))
                    target_text_file.write('\t')

                    curr_loss = loss_rpn_cls + loss_rpn_regr + loss_class_cls + loss_class_regr
                    iter_num = 0
                    start_time = time.time()

                    if curr_loss < best_loss:
                        if C.verbose:
                            print('Total loss decreased from {} to {}, saving weights'.format(best_loss,curr_loss))
                        best_loss = curr_loss
                        model_all.save_weights(C.model_path)

                    break

            except Exception as e:
                print('Exception: {}'.format(e))
                continue
except KeyboardInterrupt:
    t1 = time.time()
    print('\nIt took {:.2f}s'.format(t1-t0))
    sys.exit('Keyboard Interrupt')