edgetpuvision/detect.py - edgetpuvision-mtk - Git at Google

 # Copyright 2019 Google LLC
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     https://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.

 """A demo which runs object detection on camera frames.

 export TEST_DATA=/usr/lib/python3/dist-packages/edgetpu/test_data

 Run face detection model:
 python3 -m edgetpuvision.detect \
   --model ${TEST_DATA}/mobilenet_ssd_v2_face_quant_postprocess_edgetpu.tflite

 Run coco model:
 python3 -m edgetpuvision.detect \
   --model ${TEST_DATA}/mobilenet_ssd_v2_coco_quant_postprocess_edgetpu.tflite \
   --labels ${TEST_DATA}/coco_labels.txt
 """

 import argparse
 import collections
 import colorsys
 import itertools
 import time

 from edgetpu.detection.engine import DetectionEngine

 from . import svg
 from . import utils
 from .apps import run_app

 CSS_STYLES = str(svg.CssStyle({'.back': svg.Style(fill='black',
                                                   stroke='black',
                                                   stroke_width='0.5em'),
                                '.bbox': svg.Style(fill_opacity=0.0,
                                                   stroke_width='0.1em')}))

 BBox = collections.namedtuple('BBox', ('x', 'y', 'w', 'h'))
 BBox.area = lambda self: self.w * self.h
 BBox.scale = lambda self, sx, sy: BBox(x=self.x * sx, y=self.y * sy,
                                        w=self.w * sx, h=self.h * sy)
 BBox.__str__ = lambda self: 'BBox(x=%.2f y=%.2f w=%.2f h=%.2f)' % self

 Object = collections.namedtuple('Object', ('id', 'label', 'score', 'bbox'))
 Object.__str__ = lambda self: 'Object(id=%d, label=%s, score=%.2f, %s)' % self

 def size_em(length):
     return '%sem' % str(0.6 * (length + 1))

 def color(i, total):
     return tuple(int(255.0 * c) for c in colorsys.hsv_to_rgb(i / total, 1.0, 1.0))

 def make_palette(keys):
     return {key : svg.rgb(color(i, len(keys))) for i, key in enumerate(keys)}

 def make_get_color(color, labels):
     if color:
         return lambda obj_id: color

     if labels:
         palette = make_palette(labels.keys())
         return lambda obj_id: palette[obj_id]

     return lambda obj_id: 'white'

 def overlay(title, objs, get_color, inference_time, inference_rate, layout):
     x0 = 0
     y0 = 0
     width, height = layout.render_size
     font_size = 0.03 * height

     defs = svg.Defs()
     defs += CSS_STYLES

     doc = svg.Svg(width=width, height=height,
                   font_size=font_size, font_family='monospace', font_weight=500)
     doc += defs

     for obj in objs:
         percent = int(100 * obj.score)
         if obj.label:
             caption = '%d%% %s' % (percent, obj.label)
         else:
             caption = '%d%%' % percent

         x, y, w, h = obj.bbox.scale(*layout.render_size)
         color = get_color(obj.id)

         doc += svg.Rect(x=x, y=y, width=w, height=h,
                         style='stroke:%s' % color, _class='bbox')
         doc += svg.Rect(x=x, y=y+h ,
                         width=size_em(len(caption)), height='1.2em', fill=color)
         t = svg.Text(x=x, y=y+h, fill='black')
         t += svg.TSpan(caption, dy='1em')
         doc += t

     ox = x0 + 20
     oy1, oy2 = y0 + 20 + font_size, y0 + height - 20

     # Title
     if title:
         doc += svg.Rect(x=0, y=0, width=size_em(len(title)), height='1em',
                         transform='translate(%s, %s) scale(1,-1)' % (ox, oy1), _class='back')
         doc += svg.Text(title, x=ox, y=oy1, fill='white')

     # Info
     lines = [
         'Objects: %d' % len(objs),
         'Inference time: %.2f ms (%.2f fps)' % (inference_time * 1000, 1.0 / inference_time)
     ]

     for i, line in enumerate(reversed(lines)):
         y = oy2 - i * 1.7 * font_size
         doc += svg.Rect(x=0, y=0, width=size_em(len(line)), height='1em',
                        transform='translate(%s, %s) scale(1,-1)' % (ox, y), _class='back')
         doc += svg.Text(line, x=ox, y=y, fill='white')

     return str(doc)


 def convert(obj, labels):
     x0, y0, x1, y1 = obj.bounding_box.flatten().tolist()
     return Object(id=obj.label_id,
                   label=labels[obj.label_id] if labels else None,
                   score=obj.score,
                   bbox=BBox(x=x0, y=y0, w=x1 - x0, h=y1 - y0))

 def print_results(inference_rate, objs):
     print('\nInference (rate=%.2f fps):' % inference_rate)
     for i, obj in enumerate(objs):
         print('    %d: %s, area=%.2f' % (i, obj, obj.bbox.area()))

 def render_gen(args):
     fps_counter  = utils.avg_fps_counter(30)

     engines, titles = utils.make_engines(args.model, DetectionEngine)
     assert utils.same_input_image_sizes(engines)
     engines = itertools.cycle(engines)
     engine = next(engines)

     labels = utils.load_labels(args.labels) if args.labels else None
     filtered_labels = set(l.strip() for l in args.filter.split(',')) if args.filter else None
     get_color = make_get_color(args.color, labels)

     draw_overlay = True

     yield utils.input_image_size(engine)

     output = None
     while True:
         tensor, layout, command = (yield output)

         inference_rate = next(fps_counter)
         if draw_overlay:
             start = time.monotonic()
             objs = engine .detect_with_input_tensor(tensor, threshold=args.threshold, top_k=args.top_k)
             inference_time = time.monotonic() - start
             objs = [convert(obj, labels) for obj in objs]

             if labels and filtered_labels:
                 objs = [obj for obj in objs if obj.label in filtered_labels]

             objs = [obj for obj in objs if args.min_area <= obj.bbox.area() <= args.max_area]

             if args.print:
                 print_results(inference_rate, objs)

             title = titles[engine]
             output = overlay(title, objs, get_color, inference_time, inference_rate, layout)
         else:
             output = None

         if command == 'o':
             draw_overlay = not draw_overlay
         elif command == 'n':
             engine = next(engines)

 def add_render_gen_args(parser):
     parser.add_argument('--model',
                         help='.tflite model path', required=True)
     parser.add_argument('--labels',
                         help='labels file path')
     parser.add_argument('--top_k', type=int, default=50,
                         help='Max number of objects to detect')
     parser.add_argument('--threshold', type=float, default=0.1,
                         help='Detection threshold')
     parser.add_argument('--min_area', type=float, default=0.0,
                         help='Min bounding box area')
     parser.add_argument('--max_area', type=float, default=1.0,
                         help='Max bounding box area')
     parser.add_argument('--filter', default=None,
                         help='Comma-separated list of allowed labels')
     parser.add_argument('--color', default=None,
                         help='Bounding box display color'),
     parser.add_argument('--print', default=False, action='store_true',
                         help='Print inference results')

 def main():
     run_app(add_render_gen_args, render_gen)

 if __name__ == '__main__':
     main()
	# Copyright 2019 Google LLC
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# https://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	"""A demo which runs object detection on camera frames.

	export TEST_DATA=/usr/lib/python3/dist-packages/edgetpu/test_data

	Run face detection model:
	python3 -m edgetpuvision.detect \
	--model ${TEST_DATA}/mobilenet_ssd_v2_face_quant_postprocess_edgetpu.tflite

	Run coco model:
	python3 -m edgetpuvision.detect \
	--model ${TEST_DATA}/mobilenet_ssd_v2_coco_quant_postprocess_edgetpu.tflite \
	--labels ${TEST_DATA}/coco_labels.txt
	"""

	import argparse
	import collections
	import colorsys
	import itertools
	import time

	from edgetpu.detection.engine import DetectionEngine

	from . import svg
	from . import utils
	from .apps import run_app

	CSS_STYLES = str(svg.CssStyle({'.back': svg.Style(fill='black',
	stroke='black',
	stroke_width='0.5em'),
	'.bbox': svg.Style(fill_opacity=0.0,
	stroke_width='0.1em')}))

	BBox = collections.namedtuple('BBox', ('x', 'y', 'w', 'h'))
	BBox.area = lambda self: self.w * self.h
	BBox.scale = lambda self, sx, sy: BBox(x=self.x * sx, y=self.y * sy,
	w=self.w * sx, h=self.h * sy)
	BBox.__str__ = lambda self: 'BBox(x=%.2f y=%.2f w=%.2f h=%.2f)' % self

	Object = collections.namedtuple('Object', ('id', 'label', 'score', 'bbox'))
	Object.__str__ = lambda self: 'Object(id=%d, label=%s, score=%.2f, %s)' % self

	def size_em(length):
	return '%sem' % str(0.6 * (length + 1))

	def color(i, total):
	return tuple(int(255.0 * c) for c in colorsys.hsv_to_rgb(i / total, 1.0, 1.0))

	def make_palette(keys):
	return {key : svg.rgb(color(i, len(keys))) for i, key in enumerate(keys)}

	def make_get_color(color, labels):
	if color:
	return lambda obj_id: color

	if labels:
	palette = make_palette(labels.keys())
	return lambda obj_id: palette[obj_id]

	return lambda obj_id: 'white'

	def overlay(title, objs, get_color, inference_time, inference_rate, layout):
	x0 = 0
	y0 = 0
	width, height = layout.render_size
	font_size = 0.03 * height

	defs = svg.Defs()
	defs += CSS_STYLES

	doc = svg.Svg(width=width, height=height,
	font_size=font_size, font_family='monospace', font_weight=500)
	doc += defs

	for obj in objs:
	percent = int(100 * obj.score)
	if obj.label:
	caption = '%d%% %s' % (percent, obj.label)
	else:
	caption = '%d%%' % percent

	x, y, w, h = obj.bbox.scale(*layout.render_size)
	color = get_color(obj.id)

	doc += svg.Rect(x=x, y=y, width=w, height=h,
	style='stroke:%s' % color, _class='bbox')
	doc += svg.Rect(x=x, y=y+h ,
	width=size_em(len(caption)), height='1.2em', fill=color)
	t = svg.Text(x=x, y=y+h, fill='black')
	t += svg.TSpan(caption, dy='1em')
	doc += t

	ox = x0 + 20
	oy1, oy2 = y0 + 20 + font_size, y0 + height - 20

	# Title
	if title:
	doc += svg.Rect(x=0, y=0, width=size_em(len(title)), height='1em',
	transform='translate(%s, %s) scale(1,-1)' % (ox, oy1), _class='back')
	doc += svg.Text(title, x=ox, y=oy1, fill='white')

	# Info
	lines = [
	'Objects: %d' % len(objs),
	'Inference time: %.2f ms (%.2f fps)' % (inference_time * 1000, 1.0 / inference_time)
	]

	for i, line in enumerate(reversed(lines)):
	y = oy2 - i * 1.7 * font_size
	doc += svg.Rect(x=0, y=0, width=size_em(len(line)), height='1em',
	transform='translate(%s, %s) scale(1,-1)' % (ox, y), _class='back')
	doc += svg.Text(line, x=ox, y=y, fill='white')

	return str(doc)


	def convert(obj, labels):
	x0, y0, x1, y1 = obj.bounding_box.flatten().tolist()
	return Object(id=obj.label_id,
	label=labels[obj.label_id] if labels else None,
	score=obj.score,
	bbox=BBox(x=x0, y=y0, w=x1 - x0, h=y1 - y0))

	def print_results(inference_rate, objs):
	print('\nInference (rate=%.2f fps):' % inference_rate)
	for i, obj in enumerate(objs):
	print(' %d: %s, area=%.2f' % (i, obj, obj.bbox.area()))

	def render_gen(args):
	fps_counter = utils.avg_fps_counter(30)

	engines, titles = utils.make_engines(args.model, DetectionEngine)
	assert utils.same_input_image_sizes(engines)
	engines = itertools.cycle(engines)
	engine = next(engines)

	labels = utils.load_labels(args.labels) if args.labels else None
	filtered_labels = set(l.strip() for l in args.filter.split(',')) if args.filter else None
	get_color = make_get_color(args.color, labels)

	draw_overlay = True

	yield utils.input_image_size(engine)

	output = None
	while True:
	tensor, layout, command = (yield output)

	inference_rate = next(fps_counter)
	if draw_overlay:
	start = time.monotonic()
	objs = engine .detect_with_input_tensor(tensor, threshold=args.threshold, top_k=args.top_k)
	inference_time = time.monotonic() - start
	objs = [convert(obj, labels) for obj in objs]

	if labels and filtered_labels:
	objs = [obj for obj in objs if obj.label in filtered_labels]

	objs = [obj for obj in objs if args.min_area <= obj.bbox.area() <= args.max_area]

	if args.print:
	print_results(inference_rate, objs)

	title = titles[engine]
	output = overlay(title, objs, get_color, inference_time, inference_rate, layout)
	else:
	output = None

	if command == 'o':
	draw_overlay = not draw_overlay
	elif command == 'n':
	engine = next(engines)

	def add_render_gen_args(parser):
	parser.add_argument('--model',
	help='.tflite model path', required=True)
	parser.add_argument('--labels',
	help='labels file path')
	parser.add_argument('--top_k', type=int, default=50,
	help='Max number of objects to detect')
	parser.add_argument('--threshold', type=float, default=0.1,
	help='Detection threshold')
	parser.add_argument('--min_area', type=float, default=0.0,
	help='Min bounding box area')
	parser.add_argument('--max_area', type=float, default=1.0,
	help='Max bounding box area')
	parser.add_argument('--filter', default=None,
	help='Comma-separated list of allowed labels')
	parser.add_argument('--color', default=None,
	help='Bounding box display color'),
	parser.add_argument('--print', default=False, action='store_true',
	help='Print inference results')

	def main():
	run_app(add_render_gen_args, render_gen)

	if __name__ == '__main__':
	main()