コード例 #1
0
def test_faults_in_visual_source():
    # Create the fault client
    fault_client = MockFaultClient()

    # Populate fault client with at least one "old" fault.
    fault_client.trigger_service_fault_async(
        service_fault_pb2.ServiceFault(
            fault_id=service_fault_pb2.ServiceFaultId(fault_name="fault1")))
    init_fault_amount = fault_client.get_total_fault_count()

    visual_src = VisualImageSource(
        "source1", FakeCamera(capture_with_error, decode_with_error))

    # Attempt to get an image with no fault client enabled. Make sure no error is raised, and
    # values are returned as none.
    image, timestamp = visual_src.get_image_and_timestamp()
    assert image is None
    assert timestamp is None

    # attempt to decode an image with no fault client enabled. Make sure no error is raised.
    im_proto = image_pb2.Image(rows=10)
    success = visual_src.image_decode_with_error_checking(
        None, im_proto, None, None)
    assert im_proto.rows == 15
    assert not success

    # Setup faults
    visual_src.initialize_faults(fault_client, "service1")
    assert fault_client.get_total_fault_count() == 0
    assert visual_src.camera_capture_fault is not None
    assert visual_src.camera_capture_fault.fault_id.service_name == "service1"
    assert visual_src.decode_data_fault is not None
    assert visual_src.decode_data_fault.fault_id.service_name == "service1"

    # With fault client setup, check that faults are thrown when the bad functions get called.
    image, timestamp = visual_src.get_image_and_timestamp()
    assert image is None
    assert timestamp is None
    assert fault_client.service_fault_counts[
        visual_src.camera_capture_fault.fault_id.fault_name] == 1
    im_proto = image_pb2.Image(rows=21)
    success = visual_src.image_decode_with_error_checking(
        None, im_proto, None, None)
    assert im_proto.rows == 15
    assert fault_client.service_fault_counts[
        visual_src.decode_data_fault.fault_id.fault_name] == 1
    assert not success
コード例 #2
0
def test_faults_are_cleared_on_success():
    # Check that captures/decodes that fail and then later succeed will cause the faults to get cleared.
    class FailsThenSucceeds(CameraInterface):
        def __init__(self):
            self.capture_count = 0
            self.decode_count = 0

        def blocking_capture(self):
            self.capture_count += 1
            if self.capture_count == 1:
                raise Exception("Fake bad capture.")
            return "image", 1

        def image_decode(self, image_data, image_proto, image_format,
                         quality_percent):
            self.decode_count += 1
            if self.decode_count == 1:
                raise Exception("Fake bad decode.")

    visual_src = VisualImageSource("source1", FailsThenSucceeds())
    fault_client = MockFaultClient()
    visual_src.initialize_faults(fault_client, "service1")
    # The first call to the capture and decode functions cause a fault to be thrown.
    image, timestamp = visual_src.get_image_and_timestamp()
    assert fault_client.service_fault_counts[
        visual_src.camera_capture_fault.fault_id.fault_name] == 1
    success = visual_src.image_decode_with_error_checking(
        None, image_pb2.Image(rows=21), None, None)
    assert fault_client.service_fault_counts[
        visual_src.decode_data_fault.fault_id.fault_name] == 1

    # The second calls will succeed, and now cause the faults to be cleared.
    image, timestamp = visual_src.get_image_and_timestamp()
    assert fault_client.service_fault_counts[
        visual_src.camera_capture_fault.fault_id.fault_name] == 0
    success = visual_src.image_decode_with_error_checking(
        None, image_pb2.Image(rows=21), None, None)
    assert fault_client.service_fault_counts[
        visual_src.decode_data_fault.fault_id.fault_name] == 0
コード例 #3
0
ファイル: identify_object.py プロジェクト: greck2908/spot-sdk
def main(argv):
    """An example using the API to list and get specific objects."""
    parser = argparse.ArgumentParser()
    bosdyn.client.util.add_common_arguments(parser)
    parser.add_argument('-i', '--image-source', help='Image source on the robot to use.')
    parser.add_argument(
        '-q', '--image-source-service', help=
        'Image *service* for the image source to use.  Defaults to the main image service if not provided.',
        default='')
    parser.add_argument('-s', '--service',
                        help='Service name of external machine learning server in the directory.',
                        required=False)
    parser.add_argument('-m', '--model', help='Model file on the server')
    parser.add_argument('-c', '--confidence', help='Minimum confidence to return an object.',
                        default=0.5, type=float)
    parser.add_argument('-j', '--input-image',
                        help='Path to an image to use instead of an image source.')
    parser.add_argument(
        '-l', '--model-list',
        help='List all available network compute servers and their provided models.',
        action='store_true')
    parser.add_argument('-r', '--disable-rotation',
                        help='Disable rotation of images (to align with horizontal)',
                        action='store_true')
    options = parser.parse_args(argv)

    if options.image_source is not None and options.input_image is not None:
        print('Error: cannot provide both an input image and an image source.')
        sys.exit(1)

    if options.model_list and (options.image_source is not None or options.input_image is not None):
        print('Error: cannot list models with input image source or input image.')
        sys.exit(1)

    if options.image_source is None and options.input_image is None and options.model_list == False:
        default_image_source = 'frontleft_fisheye_image'
        print('No image source provided so defaulting to "' + default_image_source + '".')
        options.image_source = default_image_source

    # Create robot object with a world object client
    sdk = bosdyn.client.create_standard_sdk('IdentifyObjectClient')
    robot = sdk.create_robot(options.hostname)
    robot.authenticate(options.username, options.password)

    #Time sync is necessary so that time-based filter requests can be converted
    robot.time_sync.wait_for_sync()

    #Create the network compute client
    network_compute_client = robot.ensure_client(NetworkComputeBridgeClient.default_service_name)

    directory_client = robot.ensure_client(
        bosdyn.client.directory.DirectoryClient.default_service_name)

    robot_state_client = robot.ensure_client(RobotStateClient.default_service_name)
    robot_command_client = robot.ensure_client(RobotCommandClient.default_service_name)
    robot.time_sync.wait_for_sync()

    if options.model_list:
        server_service_names = get_all_network_compute_services(directory_client)

        print('Found ' + str(len(server_service_names)) +
              ' available service(s).  Listing their models:')
        print('------------------------------------')

        for service in server_service_names:
            print('    ' + service)
            server_data = network_compute_bridge_pb2.NetworkComputeServerConfiguration(
                service_name=service)
            list_req = network_compute_bridge_pb2.ListAvailableModelsRequest(
                server_config=server_data)
            response = network_compute_client.list_available_models_command(list_req)

            if response.header.error.message:
                print('        Error message: {}'.format(response.header.error.message))
            else:
                for model in response.available_models:
                    print('        ' + model)
        sys.exit(0)

    # A service name must be provided if not doing a directory list.
    if options.service is None or len(options.service) == 0:
        print('Error: --service must be provided for operations other than --model-list')
        sys.exit(1)

    server_data = network_compute_bridge_pb2.NetworkComputeServerConfiguration(
        service_name=options.service)

    if options.image_source is not None:
        if options.model is None:
            print('Error: you must provide a model.')
            sys.exit(1)

        img_source_and_service = network_compute_bridge_pb2.ImageSourceAndService(
            image_source=options.image_source, image_service=options.image_source_service)

        input_data = network_compute_bridge_pb2.NetworkComputeInputData(
            image_source_and_service=img_source_and_service, model_name=options.model,
            min_confidence=options.confidence)
    else:
        # Read the input image.
        image_in = cv2.imread(options.input_image)
        if image_in is None:
            print('Error: failed to read "' + options.input_image + '".  Does the file exist?')
            sys.exit(1)

        rgb = cv2.cvtColor(image_in, cv2.COLOR_BGR2RGB)

        success, im_buffer = cv2.imencode(".jpg", rgb)

        if not success:
            print('Error: failed to encode input image as a jpg.  Abort.')
            sys.exit(1)

        height = image_in.shape[0]
        width = image_in.shape[1]

        image_proto = image_pb2.Image(format=image_pb2.Image.FORMAT_JPEG, cols=width, rows=height,
                                      data=im_buffer.tobytes(),
                                      pixel_format=image_pb2.Image.PIXEL_FORMAT_RGB_U8)

        input_data = network_compute_bridge_pb2.NetworkComputeInputData(
            image=image_proto, model_name=options.model, min_confidence=options.confidence)

    if options.disable_rotation:
        input_data.rotate_image = network_compute_bridge_pb2.NetworkComputeInputData.ROTATE_IMAGE_NO_ROTATION
    else:
        input_data.rotate_image = network_compute_bridge_pb2.NetworkComputeInputData.ROTATE_IMAGE_ALIGN_HORIZONTAL

    process_img_req = network_compute_bridge_pb2.NetworkComputeRequest(
        input_data=input_data, server_config=server_data)

    response = network_compute_client.network_compute_bridge_command(process_img_req)

    if len(response.object_in_image) <= 0:
        print('No objects found')
    else:
        print('Got ' + str(len(response.object_in_image)) + ' objects.')

    if options.image_source is not None:
        # We asked for an image to be taken, so the return proto should have an image in it.
        dtype = np.uint8
        img = np.frombuffer(response.image_response.shot.image.data, dtype=dtype)
        if response.image_response.shot.image.format == image_pb2.Image.FORMAT_RAW:
            img = img.reshape(response.image_response.shot.image.rows,
                              response.image_response.shot.image.cols)
        else:
            img = cv2.imdecode(img, -1)
    else:
        # To save bandwidth, the network_compute_bridge service won't re-send us back our own
        # image.
        img = image_in

    # The image always comes back in the raw orientation.  Rotate it to horizontal so that we can
    # visualize it the same as it was processed.
    img, rotmat = rotate_image_nocrop(img, response.image_rotation_angle)

    # Convert to color for nicer drawing
    if len(img.shape) < 3:
        img = cv2.cvtColor(img, cv2.COLOR_GRAY2RGB)

    # Draw bounding boxes in the image for all the detections.
    for obj in response.object_in_image:
        print(obj)
        conf_msg = wrappers_pb2.FloatValue()
        obj.additional_properties.Unpack(conf_msg)
        confidence = conf_msg.value

        polygon = []
        min_x = float('inf')
        min_y = float('inf')
        for v in obj.image_properties.coordinates.vertexes:
            # If we are rotating the output image, make sure to rotate the bounding box points
            # as well
            x, y = rotate_point(v.x, v.y, rotmat)
            polygon.append([x, y])
            min_x = min(min_x, x)
            min_y = min(min_y, y)

        polygon = np.array(polygon, np.int32)
        polygon = polygon.reshape((-1, 1, 2))
        cv2.polylines(img, [polygon], True, (0, 255, 0), 2)

        caption = "{} {:.3f}".format(obj.name, confidence)
        cv2.putText(img, caption, (int(min_x), int(min_y)), cv2.FONT_HERSHEY_SIMPLEX, 0.5,
                    (0, 255, 0), 2)

    cv2.imwrite('identify_object_output.jpg', img)
コード例 #4
0
def _send_request(server, image_path, model, confidence, verbose=False):
    start = time.time()

    channel = grpc.insecure_channel(server)
    stub = network_compute_bridge_service_pb2_grpc.NetworkComputeBridgeWorkerStub(channel)
    server_data = network_compute_bridge_pb2.NetworkComputeServerConfiguration(service_name='test')
    # Read the input image.
    image_in = cv2.imread(image_path)
    if image_in is None:
        print('Error: failed to read "' + image_path + '".  Does the file exist?')
        sys.exit(1)

    rgb = cv2.cvtColor(image_in, cv2.COLOR_BGR2RGB)

    success, im_buffer = cv2.imencode(".jpg", rgb)

    if not success:
        print('Error: failed to encode input image as a jpg.  Abort.')
        sys.exit(1)

    height = image_in.shape[0]
    width = image_in.shape[1]

    image_proto = image_pb2.Image(format=image_pb2.Image.FORMAT_JPEG, cols=width, rows=height,
                                  data=im_buffer.tobytes(),
                                  pixel_format=image_pb2.Image.PIXEL_FORMAT_RGB_U8)

    input_data = network_compute_bridge_pb2.NetworkComputeInputData(image=image_proto,
                                                                    model_name=model,
                                                                    min_confidence=confidence)

    process_img_req = network_compute_bridge_pb2.NetworkComputeRequest(
        input_data=input_data, server_config=server_data)

    response = stub.NetworkCompute(process_img_req)
    end = time.time()
    latency = end - start
    print(f'latency: {latency * 1000} ms')

    if verbose:
        if len(response.object_in_image) <= 0:
            print('No objects found')
        else:
            print('Got ' + str(len(response.object_in_image)) + ' objects.')

        # Draw bounding boxes in the image for all the detections.
        for obj in response.object_in_image:
            print(obj)
            conf_msg = wrappers_pb2.FloatValue()
            obj.additional_properties.Unpack(conf_msg)
            confidence = conf_msg.value

            polygon = []
            min_x = float('inf')
            min_y = float('inf')
            for v in obj.image_properties.coordinates.vertexes:
                polygon.append([v.x, v.y])
                min_x = min(min_x, v.x)
                min_y = min(min_y, v.y)

            polygon = np.array(polygon, np.int32)
            polygon = polygon.reshape((-1, 1, 2))
            cv2.polylines(image_in, [polygon], True, (0, 255, 0), 2)

            caption = "{} {:.3f}".format(obj.name, confidence)
            cv2.putText(image_in, caption, (int(min_x), int(min_y)), cv2.FONT_HERSHEY_SIMPLEX, 0.5,
                        (0, 255, 0), 2)

        cv2.imwrite(append_str_to_filename(image_path, 'detections'), image_in)
    return latency