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find_prius_lenovo.py
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find_prius_lenovo.py
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import numpy as np
import time
from datetime import timedelta
import multiprocessing
from multiprocessing import Pool
import cv2
import os
import copy
import argparse
ap = argparse.ArgumentParser()
ap.add_argument("-p", "--path", required=False,
help="path to input image")
ap.add_argument("-y", "--yolo", default='yolo-coco',
help="base path to YOLO directory")
ap.add_argument("-c", "--confidence", type=float, default=0.5,
help="minimum probability to filter weak detections")
ap.add_argument("-t", "--threshold", type=float, default=0.3,
help="threshold when applying non-maxima suppression")
args = vars(ap.parse_args())
def image_has_shade(boundaries, image):
for (lower, upper) in boundaries:
lower = np.array(lower, dtype = "uint8")
upper = np.array(upper, dtype = "uint8")
mask = cv2.inRange(image, lower, upper)
output = cv2.bitwise_and(image, image, mask = mask)
return output.any() > 0
def has_required_shades(image):
shadeList = []
for shade in requiredShades:
shadeList.append(image_has_shade(shade, image))
return all(shadeList)
confidenceVal = 0.4
thresholdVal = 0.3
dullBlueGrey = [
#8db1b7 <-> 50757f
([127,117,80], [183,177,141])]
darkBlueShades = [
#56a3be <-> 84bac8
([190,163,86], [200,186,133])]
lightBlueShades = [
#d3e8eb <-> 84bac8
([200,186,133], [235,232,222])]
requiredShades = []
requiredShades.append(dullBlueGrey)
requiredShades.append(darkBlueShades)
requiredShades.append(lightBlueShades)# construct the argument parse and parse the arguments
labelsPath = os.path.sep.join(["./yolo-coco", "coco.names"])
LABELS = open(labelsPath).read().strip().split("\n")# initialize a list of colors to represent each possible class label
np.random.seed(42)
COLORS = np.random.randint(0, 255, size=(len(LABELS), 3),
dtype="uint8")# derive the paths to the YOLO weights and model configuration
weightsPath = os.path.sep.join(["./yolo-coco", "yolov3.weights"])
configPath = os.path.sep.join(["./yolo-coco", "yolov3.cfg"])# load our YOLO object detector trained on COCO dataset (80 classes)
print("[INFO] loading YOLO from disk..." + weightsPath)
def predictImage(image,file,net):
# load our input image and grab its spatial dimensions
(H, W) = image.shape[:2] # determine only the *output* layer names that we need from YOLO
layer_names = net.getLayerNames()
output_layers = [layer_names[i[0] - 1] for i in net.getUnconnectedOutLayers()] # construct a blob from the input image and then perform a forward
# pass of the YOLO object detector, giving us our bounding boxes and
# associated probabilities
blob = cv2.dnn.blobFromImage(image, 1 / 255.0, (416, 416),
swapRB=True, crop=False)
net.setInput(blob)
start = time.time()
outputs = net.forward(output_layers)
end = time.time() # show timing information on YOLO
#print("[INFO] YOLO took {:.6f} seconds".format(end - start)) # initialize our lists of detected bounding boxes, confidences, and
# class IDs, respectively
boxes = []
confidences = []
classIDs = [] # loop over each of the layer outputs
hasShades = False
for output in outputs:
# loop over each of the detections
for detection in output:
# extract the class ID and confidence (i.e., probability) of
# the current object detection
scores = detection[5:]
classID = np.argmax(scores)
confidence = scores[classID] # filter out weak predictions by ensuring the detected
# probability is greater than the minimum probability
if confidence > confidenceVal:
# scale the bounding box coordinates back relative to the
# size of the image, keeping in mind that YOLO actually
# returns the center (x, y)-coordinates of the bounding
# box followed by the boxes' width and height
box = detection[0:4] * np.array([W, H, W, H])
(centerX, centerY, width, height) = box.astype("int")
# use the center (x, y)-coordinates to derive the top and
# and left corner of the bounding box
x = int(centerX - (width / 2))
y = int(centerY - (height / 2))
# update our list of bounding box coordinates, confidences,
# and class IDs
boxes.append([x, y, int(width), int(height)])
confidences.append(float(confidence))
classIDs.append(classID)
# apply non-maxima suppression to suppress weak, overlapping bounding
# boxes
idxs = cv2.dnn.NMSBoxes(boxes, confidences, confidenceVal,thresholdVal)
# ensure at least one detection exists
if len(idxs) > 0:
hasShades = False
# loop over the indexes we are keeping
for i in idxs.flatten():
# extract the bounding box coordinates
(x, y) = (boxes[i][0], boxes[i][1])
(w, h) = (boxes[i][2], boxes[i][3])
# draw a bounding box rectangle and label on the image
color = [int(c) for c in COLORS[classIDs[i]]]
if classIDs[i] == 2:
text = ""
if has_required_shades(image[max(y,0):y + h, max(x,0):x + w]):
#text = "{}: {:.4f}".format(result[0]['make'], float(result[0]['prob']))
text = "{}".format('Match')
cv2.putText(image, text, (x + 2, (y - h - 20)), cv2.FONT_HERSHEY_SIMPLEX,0.5, color, 2)
cv2.rectangle(image, (x, y), (x + w, y + h), (0,0,255), 2)
hasShades = True
if hasShades is True:
print("Interesting Image: " + file)
cv2.imwrite("out_" + file, image)
def predict(file):
try:
image = cv2.imread(args["path"] +file)
if has_required_shades(image) is True:
net = cv2.dnn.readNetFromDarknet(configPath, weightsPath)
predictImage(image, file, net)
except Exception as e:
print(e)
print("Removing File: " + file)
if os.path.exists(args["path"] + file):
os.remove(args["path"] + file)
def start_predicting():
print("Processor Count: " + str(multiprocessing.cpu_count()))
print("Populating images")
arr = os.listdir(args["path"])
count = 0
for file in arr:
if file.endswith("jpg"):
images.append(file)
count = count + 1
if count > 1000:
break
print("Images populated. Images: " + str(len(images)))
def start_pool():
print("Starting Pool")
p = Pool(2)
p.map(predict, images)
images = []
procs = 4
if __name__ == '__main__':
start_predicting()
start_pool()