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darknet.py
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darknet.py
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#!/usr/bin/env python3
"""
Python 3 wrapper for identifying objects in images
Running the script requires opencv-python to be installed (`pip install opencv-python`)
Directly viewing or returning bounding-boxed images requires scikit-image to be installed (`pip install scikit-image`)
Use pip3 instead of pip on some systems to be sure to install modules for python3
"""
from ctypes import *
import math
import random
import os
class BOX(Structure):
_fields_ = [("x", c_float),
("y", c_float),
("w", c_float),
("h", c_float)]
class DETECTION(Structure):
_fields_ = [("bbox", BOX),
("classes", c_int),
("best_class_idx", c_int),
("prob", POINTER(c_float)),
("mask", POINTER(c_float)),
("objectness", c_float),
("sort_class", c_int),
("uc", POINTER(c_float)),
("points", c_int),
("embeddings", POINTER(c_float)),
("embedding_size", c_int),
("sim", c_float),
("track_id", c_int)]
class DETNUMPAIR(Structure):
_fields_ = [("num", c_int),
("dets", POINTER(DETECTION))]
class IMAGE(Structure):
_fields_ = [("w", c_int),
("h", c_int),
("c", c_int),
("data", POINTER(c_float))]
class METADATA(Structure):
_fields_ = [("classes", c_int),
("names", POINTER(c_char_p))]
def network_width(net):
return lib.network_width(net)
def network_height(net):
return lib.network_height(net)
def bbox2points(bbox):
"""
From bounding box yolo format
to corner points cv2 rectangle
"""
x, y, w, h = bbox
xmin = int(round(x - (w / 2)))
xmax = int(round(x + (w / 2)))
ymin = int(round(y - (h / 2)))
ymax = int(round(y + (h / 2)))
return xmin, ymin, xmax, ymax
def class_colors(names):
"""
Create a dict with one random BGR color for each
class name
"""
return {name: (
random.randint(0, 255),
random.randint(0, 255),
random.randint(0, 255)) for name in names}
def load_network(config_file, data_file, weights, batch_size=1):
"""
load model description and weights from config files
args:
config_file (str): path to .cfg model file
data_file (str): path to .data model file
weights (str): path to weights
returns:
network: trained model
class_names
class_colors
"""
network = load_net_custom(
config_file.encode("ascii"),
weights.encode("ascii"), 0, batch_size)
metadata = load_meta(data_file.encode("ascii"))
class_names = [metadata.names[i].decode("ascii") for i in range(metadata.classes)]
colors = class_colors(class_names)
return network, class_names, colors
def print_detections(detections, coordinates=False):
print("\nObjects:")
for label, confidence, bbox in detections:
x, y, w, h = bbox
if coordinates:
print("{}: {}% (left_x: {:.0f} top_y: {:.0f} width: {:.0f} height: {:.0f})".format(label, confidence, x, y, w, h))
else:
print("{}: {}%".format(label, confidence))
def draw_boxes(detections, image, colors):
import cv2
for label, confidence, bbox in detections:
left, top, right, bottom = bbox2points(bbox)
cv2.rectangle(image, (left, top), (right, bottom), colors[label], 1)
cv2.putText(image, "{} [{:.2f}]".format(label, float(confidence)),
(left, top - 5), cv2.FONT_HERSHEY_SIMPLEX, 0.5,
colors[label], 2)
return image
def decode_detection(detections):
decoded = []
for label, confidence, bbox in detections:
confidence = str(round(confidence * 100, 2))
decoded.append((str(label), confidence, bbox))
return decoded
# https://www.pyimagesearch.com/2015/02/16/faster-non-maximum-suppression-python/
# Malisiewicz et al.
def non_max_suppression_fast(detections, overlap_thresh):
boxes = []
for detection in detections:
_, _, _, (x, y, w, h) = detection
x1 = x - w / 2
y1 = y - h / 2
x2 = x + w / 2
y2 = y + h / 2
boxes.append(np.array([x1, y1, x2, y2]))
boxes_array = np.array(boxes)
# initialize the list of picked indexes
pick = []
# grab the coordinates of the bounding boxes
x1 = boxes_array[:, 0]
y1 = boxes_array[:, 1]
x2 = boxes_array[:, 2]
y2 = boxes_array[:, 3]
# compute the area of the bounding boxes and sort the bounding
# boxes by the bottom-right y-coordinate of the bounding box
area = (x2 - x1 + 1) * (y2 - y1 + 1)
idxs = np.argsort(y2)
# keep looping while some indexes still remain in the indexes
# list
while len(idxs) > 0:
# grab the last index in the indexes list and add the
# index value to the list of picked indexes
last = len(idxs) - 1
i = idxs[last]
pick.append(i)
# find the largest (x, y) coordinates for the start of
# the bounding box and the smallest (x, y) coordinates
# for the end of the bounding box
xx1 = np.maximum(x1[i], x1[idxs[:last]])
yy1 = np.maximum(y1[i], y1[idxs[:last]])
xx2 = np.minimum(x2[i], x2[idxs[:last]])
yy2 = np.minimum(y2[i], y2[idxs[:last]])
# compute the width and height of the bounding box
w = np.maximum(0, xx2 - xx1 + 1)
h = np.maximum(0, yy2 - yy1 + 1)
# compute the ratio of overlap
overlap = (w * h) / area[idxs[:last]]
# delete all indexes from the index list that have
idxs = np.delete(idxs, np.concatenate(([last],
np.where(overlap > overlap_thresh)[0])))
# return only the bounding boxes that were picked using the
# integer data type
return [detections[i] for i in pick]
def remove_negatives(detections, class_names, num):
"""
Remove all classes with 0% confidence within the detection
"""
predictions = []
for j in range(num):
for idx, name in enumerate(class_names):
if detections[j].prob[idx] > 0:
bbox = detections[j].bbox
bbox = (bbox.x, bbox.y, bbox.w, bbox.h)
predictions.append((name, detections[j].prob[idx], (bbox)))
return predictions
def remove_negatives_faster(detections, class_names, num):
"""
Faster version of remove_negatives (very useful when using yolo9000)
"""
predictions = []
for j in range(num):
if detections[j].best_class_idx == -1:
continue
name = class_names[detections[j].best_class_idx]
bbox = detections[j].bbox
bbox = (bbox.x, bbox.y, bbox.w, bbox.h)
predictions.append((name, detections[j].prob[detections[j].best_class_idx], bbox))
return predictions
def detect_image(network, class_names, image, thresh=.5, hier_thresh=.5, nms=.45):
"""
Returns a list with highest confidence class and their bbox
"""
pnum = pointer(c_int(0))
predict_image(network, image)
detections = get_network_boxes(network, image.w, image.h,
thresh, hier_thresh, None, 0, pnum, 0)
num = pnum[0]
if nms:
do_nms_sort(detections, num, len(class_names), nms)
predictions = remove_negatives(detections, class_names, num)
predictions = decode_detection(predictions)
free_detections(detections, num)
return sorted(predictions, key=lambda x: x[1])
if os.name == "posix":
cwd = os.path.dirname(__file__)
lib = CDLL(cwd + "/libdarknet.so", RTLD_GLOBAL)
elif os.name == "nt":
cwd = os.path.dirname(__file__)
os.environ['PATH'] = cwd + ';' + os.environ['PATH']
lib = CDLL("darknet.dll", RTLD_GLOBAL)
else:
print("Unsupported OS")
exit
lib.network_width.argtypes = [c_void_p]
lib.network_width.restype = c_int
lib.network_height.argtypes = [c_void_p]
lib.network_height.restype = c_int
copy_image_from_bytes = lib.copy_image_from_bytes
copy_image_from_bytes.argtypes = [IMAGE,c_char_p]
predict = lib.network_predict_ptr
predict.argtypes = [c_void_p, POINTER(c_float)]
predict.restype = POINTER(c_float)
set_gpu = lib.cuda_set_device
init_cpu = lib.init_cpu
make_image = lib.make_image
make_image.argtypes = [c_int, c_int, c_int]
make_image.restype = IMAGE
get_network_boxes = lib.get_network_boxes
get_network_boxes.argtypes = [c_void_p, c_int, c_int, c_float, c_float, POINTER(c_int), c_int, POINTER(c_int), c_int]
get_network_boxes.restype = POINTER(DETECTION)
make_network_boxes = lib.make_network_boxes
make_network_boxes.argtypes = [c_void_p]
make_network_boxes.restype = POINTER(DETECTION)
free_detections = lib.free_detections
free_detections.argtypes = [POINTER(DETECTION), c_int]
free_batch_detections = lib.free_batch_detections
free_batch_detections.argtypes = [POINTER(DETNUMPAIR), c_int]
free_ptrs = lib.free_ptrs
free_ptrs.argtypes = [POINTER(c_void_p), c_int]
network_predict = lib.network_predict_ptr
network_predict.argtypes = [c_void_p, POINTER(c_float)]
reset_rnn = lib.reset_rnn
reset_rnn.argtypes = [c_void_p]
load_net = lib.load_network
load_net.argtypes = [c_char_p, c_char_p, c_int]
load_net.restype = c_void_p
load_net_custom = lib.load_network_custom
load_net_custom.argtypes = [c_char_p, c_char_p, c_int, c_int]
load_net_custom.restype = c_void_p
free_network_ptr = lib.free_network_ptr
free_network_ptr.argtypes = [c_void_p]
free_network_ptr.restype = c_void_p
do_nms_obj = lib.do_nms_obj
do_nms_obj.argtypes = [POINTER(DETECTION), c_int, c_int, c_float]
do_nms_sort = lib.do_nms_sort
do_nms_sort.argtypes = [POINTER(DETECTION), c_int, c_int, c_float]
free_image = lib.free_image
free_image.argtypes = [IMAGE]
letterbox_image = lib.letterbox_image
letterbox_image.argtypes = [IMAGE, c_int, c_int]
letterbox_image.restype = IMAGE
load_meta = lib.get_metadata
lib.get_metadata.argtypes = [c_char_p]
lib.get_metadata.restype = METADATA
load_image = lib.load_image_color
load_image.argtypes = [c_char_p, c_int, c_int]
load_image.restype = IMAGE
rgbgr_image = lib.rgbgr_image
rgbgr_image.argtypes = [IMAGE]
predict_image = lib.network_predict_image
predict_image.argtypes = [c_void_p, IMAGE]
predict_image.restype = POINTER(c_float)
predict_image_letterbox = lib.network_predict_image_letterbox
predict_image_letterbox.argtypes = [c_void_p, IMAGE]
predict_image_letterbox.restype = POINTER(c_float)
network_predict_batch = lib.network_predict_batch
network_predict_batch.argtypes = [c_void_p, IMAGE, c_int, c_int, c_int,
c_float, c_float, POINTER(c_int), c_int, c_int]
network_predict_batch.restype = POINTER(DETNUMPAIR)