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preprocessing.py
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preprocessing.py
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import os
import cv2
import copy
import numpy as np
import imgaug as ia
from imgaug import augmenters as iaa
from keras.utils import Sequence
import xml.etree.ElementTree as ET
from utils import BoundBox, normalize, bbox_iou
def parse_annotation(ann_dir, img_dir, labels=[], ext='', prefix=""):
all_imgs = []
seen_labels = {}
for ann in sorted(os.listdir(ann_dir)):
img = {'object':[]}
tree = ET.parse(ann_dir + ann)
for elem in tree.iter():
if 'filename' in elem.tag:
img['filename'] = img_dir + prefix+ elem.text + ext
#print("########### image --- {}".format(img['filename']))
if 'width' in elem.tag:
img['width'] = int(elem.text)
if 'height' in elem.tag:
img['height'] = int(elem.text)
if 'object' in elem.tag or 'part' in elem.tag:
obj = {}
for attr in list(elem):
if 'name' in attr.tag:
obj['name'] = attr.text
if obj['name'] in seen_labels:
seen_labels[obj['name']] += 1
else:
seen_labels[obj['name']] = 1
if len(labels) > 0 and obj['name'] not in labels:
break
else:
img['object'] += [obj]
if 'bndbox' in attr.tag:
for dim in list(attr):
if 'xmin' in dim.tag:
obj['xmin'] = int(round(float(dim.text)))
if 'ymin' in dim.tag:
obj['ymin'] = int(round(float(dim.text)))
if 'xmax' in dim.tag:
obj['xmax'] = int(round(float(dim.text)))
if 'ymax' in dim.tag:
obj['ymax'] = int(round(float(dim.text)))
if len(img['object']) > 0:
all_imgs += [img]
return all_imgs, seen_labels
class BatchGenerator(Sequence):
def __init__(self, images,
config,
shuffle=True,
jitter=True,
norm=None):
self.generator = None
self.images = images
self.config = config
self.shuffle = shuffle
self.jitter = jitter
self.norm = norm
self.counter = 0
self.anchors = [BoundBox(0, 0, config['ANCHORS'][2*i], config['ANCHORS'][2*i+1]) \
for i in range(len(config['ANCHORS'])//2)]
### augmentors by https://github.com/aleju/imgaug
sometimes = lambda aug: iaa.Sometimes(0.5, aug)
# Define our sequence of augmentation steps that will be applied to every image
# All augmenters with per_channel=0.5 will sample one value _per image_
# in 50% of all cases. In all other cases they will sample new values
# _per channel_.
self.aug_pipe = iaa.Sequential(
[
# apply the following augmenters to most images
#iaa.Fliplr(0.5), # horizontally flip 50% of all images
#iaa.Flipud(0.2), # vertically flip 20% of all images
#sometimes(iaa.Crop(percent=(0, 0.1))), # crop images by 0-10% of their height/width
sometimes(iaa.Affine(
#scale={"x": (0.8, 1.2), "y": (0.8, 1.2)}, # scale images to 80-120% of their size, individually per axis
#translate_percent={"x": (-0.2, 0.2), "y": (-0.2, 0.2)}, # translate by -20 to +20 percent (per axis)
#rotate=(-5, 5), # rotate by -45 to +45 degrees
#shear=(-5, 5), # shear by -16 to +16 degrees
#order=[0, 1], # use nearest neighbour or bilinear interpolation (fast)
#cval=(0, 255), # if mode is constant, use a cval between 0 and 255
#mode=ia.ALL # use any of scikit-image's warping modes (see 2nd image from the top for examples)
)),
# execute 0 to 5 of the following (less important) augmenters per image
# don't execute all of them, as that would often be way too strong
iaa.SomeOf((0, 5),
[
#sometimes(iaa.Superpixels(p_replace=(0, 1.0), n_segments=(20, 200))),
# convert images into their superpixel representation
iaa.OneOf([
iaa.GaussianBlur((0, 3.0)), # blur images with a sigma between 0 and 3.0
iaa.AverageBlur(k=(2, 7)), # blur image using local means with kernel sizes between 2 and 7
iaa.MedianBlur(k=(3, 11)), # blur image using local medians with kernel sizes between 2 and 7
]),
iaa.Sharpen(alpha=(0, 1.0), lightness=(0.75, 1.5)), # sharpen images
#iaa.Emboss(alpha=(0, 1.0), strength=(0, 2.0)), # emboss images
# search either for all edges or for directed edges
#sometimes(iaa.OneOf([
# iaa.EdgeDetect(alpha=(0, 0.7)),
# iaa.DirectedEdgeDetect(alpha=(0, 0.7), direction=(0.0, 1.0)),
#])),
iaa.AdditiveGaussianNoise(loc=0, scale=(0.0, 0.05*255), per_channel=0.5), # add gaussian noise to images
iaa.OneOf([
iaa.Dropout((0.01, 0.1), per_channel=0.5), # randomly remove up to 10% of the pixels
#iaa.CoarseDropout((0.03, 0.15), size_percent=(0.02, 0.05), per_channel=0.2),
]),
#iaa.Invert(0.05, per_channel=True), # invert color channels
iaa.Add((-10, 10), per_channel=0.5), # change brightness of images (by -10 to 10 of original value)
iaa.Multiply((0.5, 1.5), per_channel=0.5), # change brightness of images (50-150% of original value)
iaa.ContrastNormalization((0.5, 2.0), per_channel=0.5), # improve or worsen the contrast
#iaa.Grayscale(alpha=(0.0, 1.0)),
#sometimes(iaa.ElasticTransformation(alpha=(0.5, 3.5), sigma=0.25)), # move pixels locally around (with random strengths)
#sometimes(iaa.PiecewiseAffine(scale=(0.01, 0.05))) # sometimes move parts of the image around
],
random_order=True
)
],
random_order=True
)
if shuffle: np.random.shuffle(self.images)
def __len__(self):
return int(np.ceil(float(len(self.images))/self.config['BATCH_SIZE']))
def __getitem__(self, idx):
l_bound = idx*self.config['BATCH_SIZE']
r_bound = (idx+1)*self.config['BATCH_SIZE']
if r_bound > len(self.images):
r_bound = len(self.images)
l_bound = r_bound - self.config['BATCH_SIZE']
instance_count = 0
x_batch = np.zeros((r_bound - l_bound, self.config['IMAGE_H'], self.config['IMAGE_W'], 3)) # input images
b_batch = np.zeros((r_bound - l_bound, 1 , 1 , 1 , self.config['TRUE_BOX_BUFFER'], 4)) # list of self.config['TRUE_self.config['BOX']_BUFFER'] GT boxes
y_batch = np.zeros((r_bound - l_bound, self.config['GRID_H'], self.config['GRID_W'], self.config['BOX'], 4+1+1)) # desired network output
for train_instance in self.images[l_bound:r_bound]:
# augment input image and fix object's position and size
img, all_objs = self.aug_image(train_instance, jitter=self.jitter)
# construct output from object's x, y, w, h
true_box_index = 0
for obj in all_objs:
if obj['xmax'] > obj['xmin'] and obj['ymax'] > obj['ymin'] and obj['name'] in self.config['LABELS']:
center_x = .5*(obj['xmin'] + obj['xmax'])
center_x = center_x / (float(self.config['IMAGE_W']) / self.config['GRID_W'])
center_y = .5*(obj['ymin'] + obj['ymax'])
center_y = center_y / (float(self.config['IMAGE_H']) / self.config['GRID_H'])
grid_x = int(np.floor(center_x))
grid_y = int(np.floor(center_y))
if grid_x < self.config['GRID_W'] and grid_y < self.config['GRID_H']:
obj_indx = self.config['LABELS'].index(obj['name'])
center_w = (obj['xmax'] - obj['xmin']) / (float(self.config['IMAGE_W']) / self.config['GRID_W']) # unit: grid cell
center_h = (obj['ymax'] - obj['ymin']) / (float(self.config['IMAGE_H']) / self.config['GRID_H']) # unit: grid cell
box = [center_x, center_y, center_w, center_h]
# find the anchor that best predicts this box
best_anchor = -1
max_iou = -1
shifted_box = BoundBox(0,
0,
center_w,
center_h)
for i in range(len(self.anchors)):
anchor = self.anchors[i]
iou = bbox_iou(shifted_box, anchor)
if max_iou < iou:
best_anchor = i
max_iou = iou
# assign ground truth x, y, w, h, confidence and class probs to y_batch
y_batch[instance_count, grid_y, grid_x, best_anchor, 0:4] = box
y_batch[instance_count, grid_y, grid_x, best_anchor, 4 ] = 1.
y_batch[instance_count, grid_y, grid_x, best_anchor, 5 ] = obj_indx
# assign the true box to b_batch
b_batch[instance_count, 0, 0, 0, true_box_index] = box
true_box_index += 1
true_box_index = true_box_index % self.config['TRUE_BOX_BUFFER']
# assign input image to x_batch
if self.norm != None:
x_batch[instance_count] = self.norm(img)
else:
# plot image and bounding boxes for sanity check
for obj in all_objs:
if obj['xmax'] > obj['xmin'] and obj['ymax'] > obj['ymin']:
cv2.rectangle(img[:,:,::-1], (obj['xmin'],obj['ymin']), (obj['xmax'],obj['ymax']), (255,0,0), 3)
cv2.putText(img[:,:,::-1], obj['name'],
(obj['xmin']+2, obj['ymin']+12),
0, 1.2e-3 * img.shape[0],
(0,255,0), 2)
x_batch[instance_count] = img
# increase instance counter in current batch
instance_count += 1
self.counter += 1 #delete by xinxiao li -- to increase it in get_generator
#print ' new batch created', self.counter
return [x_batch, b_batch], y_batch
def on_epoch_end(self):
if self.shuffle: np.random.shuffle(self.images)
self.counter = 0
"""
def get_generator(self):
self.counter = 0 #reset the counter
return self
def get_dateset_size(self):
return self.__len__()
def next(self):
if self.counter >= self.__len__() :
self.counter = 1 # next one
return self.__getitem__(0)
else:
self.counter += 1
return self.__getitem__(self.counter-1)
"""
def aug_image(self, train_instance, jitter):
#from IPython.core.debugger import Pdb; Pdb().set_trace()
image_name = train_instance['filename']
#print("----------------- image:------ {}--".format(image_name))
image = cv2.imread(image_name)
h, w, c = image.shape
all_objs = copy.deepcopy(train_instance['object'])
if jitter:
### scale the image
scale = np.random.uniform() / 10. + 1.
image = cv2.resize(image, (0,0), fx = scale, fy = scale)
### translate the image
max_offx = (scale-1.) * w
max_offy = (scale-1.) * h
offx = int(np.random.uniform() * max_offx)
offy = int(np.random.uniform() * max_offy)
image = image[offy : (offy + h), offx : (offx + w)]
### flip the image
flip = np.random.binomial(1, .5)
if flip > 0.5: image = cv2.flip(image, 1)
image = self.aug_pipe.augment_image(image)
# resize the image to standard size
image = cv2.resize(image, (self.config['IMAGE_H'], self.config['IMAGE_W']))
image = image[:,:,::-1]
# fix object's position and size
for obj in all_objs:
for attr in ['xmin', 'xmax']:
if jitter: obj[attr] = int(obj[attr] * scale - offx)
obj[attr] = int(obj[attr] * float(self.config['IMAGE_W']) / w)
obj[attr] = max(min(obj[attr], self.config['IMAGE_W']), 0)
for attr in ['ymin', 'ymax']:
if jitter: obj[attr] = int(obj[attr] * scale - offy)
obj[attr] = int(obj[attr] * float(self.config['IMAGE_H']) / h)
obj[attr] = max(min(obj[attr], self.config['IMAGE_H']), 0)
if jitter and flip > 0.5:
xmin = obj['xmin']
obj['xmin'] = self.config['IMAGE_W'] - obj['xmax']
obj['xmax'] = self.config['IMAGE_W'] - xmin
return image, all_objs