mirror of
https://github.com/blakeblackshear/frigate.git
synced 2024-11-30 19:09:13 +01:00
231 lines
8.8 KiB
Python
231 lines
8.8 KiB
Python
import logging
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import os
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import numpy as np
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import openvino as ov
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from pydantic import Field
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from typing_extensions import Literal
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from frigate.detectors.detection_api import DetectionApi
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from frigate.detectors.detector_config import BaseDetectorConfig, ModelTypeEnum
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logger = logging.getLogger(__name__)
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DETECTOR_KEY = "openvino"
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class OvDetectorConfig(BaseDetectorConfig):
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type: Literal[DETECTOR_KEY]
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device: str = Field(default=None, title="Device Type")
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class OvDetector(DetectionApi):
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type_key = DETECTOR_KEY
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supported_models = [ModelTypeEnum.ssd, ModelTypeEnum.yolonas, ModelTypeEnum.yolox]
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def __init__(self, detector_config: OvDetectorConfig):
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self.ov_core = ov.Core()
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self.ov_model_type = detector_config.model.model_type
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self.h = detector_config.model.height
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self.w = detector_config.model.width
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if detector_config.device == "AUTO":
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logger.warning(
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"OpenVINO AUTO device type is not currently supported. Attempting to use GPU instead."
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)
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detector_config.device = "GPU"
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if not os.path.isfile(detector_config.model.path):
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logger.error(f"OpenVino model file {detector_config.model.path} not found.")
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raise FileNotFoundError
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self.interpreter = self.ov_core.compile_model(
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model=detector_config.model.path, device_name=detector_config.device
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)
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self.model_invalid = False
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if self.ov_model_type not in self.supported_models:
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logger.error(
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f"OpenVino detector does not support {self.ov_model_type} models."
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)
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self.model_invalid = True
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# Ensure the SSD model has the right input and output shapes
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if self.ov_model_type == ModelTypeEnum.ssd:
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model_inputs = self.interpreter.inputs
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model_outputs = self.interpreter.outputs
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if len(model_inputs) != 1:
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logger.error(
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f"SSD models must only have 1 input. Found {len(model_inputs)}."
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)
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self.model_invalid = True
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if len(model_outputs) != 1:
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logger.error(
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f"SSD models must only have 1 output. Found {len(model_outputs)}."
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)
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self.model_invalid = True
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if model_inputs[0].get_shape() != ov.Shape([1, self.w, self.h, 3]):
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logger.error(
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f"SSD model input doesn't match. Found {model_inputs[0].get_shape()}."
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)
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self.model_invalid = True
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output_shape = model_outputs[0].get_shape()
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if output_shape[0] != 1 or output_shape[1] != 1 or output_shape[3] != 7:
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logger.error(f"SSD model output doesn't match. Found {output_shape}.")
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self.model_invalid = True
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if self.ov_model_type == ModelTypeEnum.yolonas:
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model_inputs = self.interpreter.inputs
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model_outputs = self.interpreter.outputs
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if len(model_inputs) != 1:
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logger.error(
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f"YoloNAS models must only have 1 input. Found {len(model_inputs)}."
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)
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self.model_invalid = True
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if len(model_outputs) != 1:
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logger.error(
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f"YoloNAS models must be exported in flat format and only have 1 output. Found {len(model_outputs)}."
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)
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self.model_invalid = True
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if model_inputs[0].get_shape() != ov.Shape([1, 3, self.w, self.h]):
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logger.error(
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f"YoloNAS model input doesn't match. Found {model_inputs[0].get_shape()}, but expected {[1, 3, self.w, self.h]}."
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)
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self.model_invalid = True
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output_shape = model_outputs[0].partial_shape
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if output_shape[-1] != 7:
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logger.error(
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f"YoloNAS models must be exported in flat format. Model output doesn't match. Found {output_shape}."
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)
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self.model_invalid = True
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if self.ov_model_type == ModelTypeEnum.yolox:
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self.output_indexes = 0
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while True:
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try:
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tensor_shape = self.interpreter.output(self.output_indexes).shape
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logger.info(
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f"Model Output-{self.output_indexes} Shape: {tensor_shape}"
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)
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self.output_indexes += 1
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except Exception:
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logger.info(f"Model has {self.output_indexes} Output Tensors")
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break
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self.num_classes = tensor_shape[2] - 5
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logger.info(f"YOLOX model has {self.num_classes} classes")
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self.set_strides_grids()
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def set_strides_grids(self):
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grids = []
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expanded_strides = []
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strides = [8, 16, 32]
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hsize_list = [self.h // stride for stride in strides]
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wsize_list = [self.w // stride for stride in strides]
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for hsize, wsize, stride in zip(hsize_list, wsize_list, strides):
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xv, yv = np.meshgrid(np.arange(wsize), np.arange(hsize))
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grid = np.stack((xv, yv), 2).reshape(1, -1, 2)
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grids.append(grid)
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shape = grid.shape[:2]
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expanded_strides.append(np.full((*shape, 1), stride))
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self.grids = np.concatenate(grids, 1)
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self.expanded_strides = np.concatenate(expanded_strides, 1)
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## Takes in class ID, confidence score, and array of [x, y, w, h] that describes detection position,
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## returns an array that's easily passable back to Frigate.
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def process_yolo(self, class_id, conf, pos):
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return [
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class_id, # class ID
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conf, # confidence score
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(pos[1] - (pos[3] / 2)) / self.h, # y_min
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(pos[0] - (pos[2] / 2)) / self.w, # x_min
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(pos[1] + (pos[3] / 2)) / self.h, # y_max
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(pos[0] + (pos[2] / 2)) / self.w, # x_max
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]
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def detect_raw(self, tensor_input):
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infer_request = self.interpreter.create_infer_request()
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# TODO: see if we can use shared_memory=True
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input_tensor = ov.Tensor(array=tensor_input)
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infer_request.infer(input_tensor)
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detections = np.zeros((20, 6), np.float32)
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if self.model_invalid:
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return detections
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if self.ov_model_type == ModelTypeEnum.ssd:
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results = infer_request.get_output_tensor(0).data[0][0]
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for i, (_, class_id, score, xmin, ymin, xmax, ymax) in enumerate(results):
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if i == 20:
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break
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detections[i] = [
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class_id,
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float(score),
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ymin,
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xmin,
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ymax,
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xmax,
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]
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return detections
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if self.ov_model_type == ModelTypeEnum.yolonas:
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predictions = infer_request.get_output_tensor(0).data
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for i, prediction in enumerate(predictions):
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if i == 20:
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break
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(_, x_min, y_min, x_max, y_max, confidence, class_id) = prediction
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# when running in GPU mode, empty predictions in the output have class_id of -1
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if class_id < 0:
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break
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detections[i] = [
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class_id,
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confidence,
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y_min / self.h,
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x_min / self.w,
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y_max / self.h,
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x_max / self.w,
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]
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return detections
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if self.ov_model_type == ModelTypeEnum.yolox:
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out_tensor = infer_request.get_output_tensor()
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# [x, y, h, w, box_score, class_no_1, ..., class_no_80],
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results = out_tensor.data
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results[..., :2] = (results[..., :2] + self.grids) * self.expanded_strides
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results[..., 2:4] = np.exp(results[..., 2:4]) * self.expanded_strides
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image_pred = results[0, ...]
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class_conf = np.max(
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image_pred[:, 5 : 5 + self.num_classes], axis=1, keepdims=True
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)
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class_pred = np.argmax(image_pred[:, 5 : 5 + self.num_classes], axis=1)
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class_pred = np.expand_dims(class_pred, axis=1)
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conf_mask = (image_pred[:, 4] * class_conf.squeeze() >= 0.3).squeeze()
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# Detections ordered as (x1, y1, x2, y2, obj_conf, class_conf, class_pred)
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detections = np.concatenate(
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(image_pred[:, :5], class_conf, class_pred), axis=1
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)
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detections = detections[conf_mask]
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ordered = detections[detections[:, 5].argsort()[::-1]][:20]
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for i, object_detected in enumerate(ordered):
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detections[i] = self.process_yolo(
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object_detected[6], object_detected[5], object_detected[:4]
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)
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return detections
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