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# Ultralytics YOLO 🚀, AGPL-3.0 license
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import argparse
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import cv2
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import numpy as np
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from tflite_runtime import interpreter as tflite
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from ultralytics.utils import ASSETS, yaml_load
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from ultralytics.utils.checks import check_yaml
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# Declare as global variables, can be updated based trained model image size
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img_width = 640
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img_height = 640
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class LetterBox:
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def __init__(
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self, new_shape=(img_width, img_height), auto=False, scaleFill=False, scaleup=True, center=True, stride=32
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):
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"""Initializes LetterBox with parameters for reshaping and transforming image while maintaining aspect ratio."""
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self.new_shape = new_shape
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self.auto = auto
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self.scaleFill = scaleFill
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self.scaleup = scaleup
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self.stride = stride
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self.center = center # Put the image in the middle or top-left
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def __call__(self, labels=None, image=None):
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"""Return updated labels and image with added border."""
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if labels is None:
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labels = {}
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img = labels.get("img") if image is None else image
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shape = img.shape[:2] # current shape [height, width]
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new_shape = labels.pop("rect_shape", self.new_shape)
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if isinstance(new_shape, int):
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new_shape = (new_shape, new_shape)
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# Scale ratio (new / old)
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r = min(new_shape[0] / shape[0], new_shape[1] / shape[1])
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if not self.scaleup: # only scale down, do not scale up (for better val mAP)
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r = min(r, 1.0)
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# Compute padding
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ratio = r, r # width, height ratios
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new_unpad = int(round(shape[1] * r)), int(round(shape[0] * r))
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dw, dh = new_shape[1] - new_unpad[0], new_shape[0] - new_unpad[1] # wh padding
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if self.auto: # minimum rectangle
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dw, dh = np.mod(dw, self.stride), np.mod(dh, self.stride) # wh padding
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elif self.scaleFill: # stretch
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dw, dh = 0.0, 0.0
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new_unpad = (new_shape[1], new_shape[0])
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ratio = new_shape[1] / shape[1], new_shape[0] / shape[0] # width, height ratios
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if self.center:
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dw /= 2 # divide padding into 2 sides
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dh /= 2
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if shape[::-1] != new_unpad: # resize
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img = cv2.resize(img, new_unpad, interpolation=cv2.INTER_LINEAR)
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top, bottom = int(round(dh - 0.1)) if self.center else 0, int(round(dh + 0.1))
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left, right = int(round(dw - 0.1)) if self.center else 0, int(round(dw + 0.1))
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img = cv2.copyMakeBorder(
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img, top, bottom, left, right, cv2.BORDER_CONSTANT, value=(114, 114, 114)
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) # add border
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if labels.get("ratio_pad"):
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labels["ratio_pad"] = (labels["ratio_pad"], (left, top)) # for evaluation
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if len(labels):
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labels = self._update_labels(labels, ratio, dw, dh)
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labels["img"] = img
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labels["resized_shape"] = new_shape
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return labels
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else:
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return img
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def _update_labels(self, labels, ratio, padw, padh):
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"""Update labels."""
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labels["instances"].convert_bbox(format="xyxy")
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labels["instances"].denormalize(*labels["img"].shape[:2][::-1])
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labels["instances"].scale(*ratio)
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labels["instances"].add_padding(padw, padh)
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return labels
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class Yolov8TFLite:
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def __init__(self, tflite_model, input_image, confidence_thres, iou_thres):
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"""
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Initializes an instance of the Yolov8TFLite class.
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Args:
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tflite_model: Path to the TFLite model.
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input_image: Path to the input image.
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confidence_thres: Confidence threshold for filtering detections.
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iou_thres: IoU (Intersection over Union) threshold for non-maximum suppression.
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"""
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self.tflite_model = tflite_model
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self.input_image = input_image
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self.confidence_thres = confidence_thres
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self.iou_thres = iou_thres
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# Load the class names from the COCO dataset
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self.classes = yaml_load(check_yaml("coco8.yaml"))["names"]
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# Generate a color palette for the classes
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self.color_palette = np.random.uniform(0, 255, size=(len(self.classes), 3))
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def draw_detections(self, img, box, score, class_id):
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"""
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Draws bounding boxes and labels on the input image based on the detected objects.
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Args:
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img: The input image to draw detections on.
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box: Detected bounding box.
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score: Corresponding detection score.
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class_id: Class ID for the detected object.
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Returns:
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None
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"""
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# Extract the coordinates of the bounding box
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x1, y1, w, h = box
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# Retrieve the color for the class ID
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color = self.color_palette[class_id]
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# Draw the bounding box on the image
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cv2.rectangle(img, (int(x1), int(y1)), (int(x1 + w), int(y1 + h)), color, 2)
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# Create the label text with class name and score
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label = f"{self.classes[class_id]}: {score:.2f}"
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# Calculate the dimensions of the label text
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(label_width, label_height), _ = cv2.getTextSize(label, cv2.FONT_HERSHEY_SIMPLEX, 0.5, 1)
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# Calculate the position of the label text
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label_x = x1
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label_y = y1 - 10 if y1 - 10 > label_height else y1 + 10
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# Draw a filled rectangle as the background for the label text
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cv2.rectangle(
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img,
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(int(label_x), int(label_y - label_height)),
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(int(label_x + label_width), int(label_y + label_height)),
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color,
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cv2.FILLED,
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)
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# Draw the label text on the image
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cv2.putText(img, label, (int(label_x), int(label_y)), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 0), 1, cv2.LINE_AA)
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def preprocess(self):
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"""
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Preprocesses the input image before performing inference.
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Returns:
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image_data: Preprocessed image data ready for inference.
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"""
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# Read the input image using OpenCV
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self.img = cv2.imread(self.input_image)
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print("image before", self.img)
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# Get the height and width of the input image
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self.img_height, self.img_width = self.img.shape[:2]
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letterbox = LetterBox(new_shape=[img_width, img_height], auto=False, stride=32)
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image = letterbox(image=self.img)
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image = [image]
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image = np.stack(image)
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image = image[..., ::-1].transpose((0, 3, 1, 2))
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img = np.ascontiguousarray(image)
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# n, h, w, c
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image = img.astype(np.float32)
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return image / 255
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def postprocess(self, input_image, output):
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"""
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Performs post-processing on the model's output to extract bounding boxes, scores, and class IDs.
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Args:
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input_image (numpy.ndarray): The input image.
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output (numpy.ndarray): The output of the model.
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Returns:
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numpy.ndarray: The input image with detections drawn on it.
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"""
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boxes = []
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scores = []
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class_ids = []
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for pred in output:
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pred = np.transpose(pred)
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for box in pred:
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x, y, w, h = box[:4]
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x1 = x - w / 2
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y1 = y - h / 2
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boxes.append([x1, y1, w, h])
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idx = np.argmax(box[4:])
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scores.append(box[idx + 4])
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class_ids.append(idx)
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indices = cv2.dnn.NMSBoxes(boxes, scores, self.confidence_thres, self.iou_thres)
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for i in indices:
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# Get the box, score, and class ID corresponding to the index
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box = boxes[i]
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gain = min(img_width / self.img_width, img_height / self.img_height)
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pad = (
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round((img_width - self.img_width * gain) / 2 - 0.1),
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round((img_height - self.img_height * gain) / 2 - 0.1),
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)
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box[0] = (box[0] - pad[0]) / gain
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box[1] = (box[1] - pad[1]) / gain
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box[2] = box[2] / gain
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box[3] = box[3] / gain
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score = scores[i]
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class_id = class_ids[i]
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if score > 0.25:
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print(box, score, class_id)
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# Draw the detection on the input image
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self.draw_detections(input_image, box, score, class_id)
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return input_image
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def main(self):
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"""
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Performs inference using a TFLite model and returns the output image with drawn detections.
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Returns:
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output_img: The output image with drawn detections.
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"""
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# Create an interpreter for the TFLite model
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interpreter = tflite.Interpreter(model_path=self.tflite_model)
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self.model = interpreter
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interpreter.allocate_tensors()
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# Get the model inputs
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input_details = interpreter.get_input_details()
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output_details = interpreter.get_output_details()
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# Store the shape of the input for later use
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input_shape = input_details[0]["shape"]
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self.input_width = input_shape[1]
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self.input_height = input_shape[2]
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# Preprocess the image data
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img_data = self.preprocess()
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img_data = img_data
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# img_data = img_data.cpu().numpy()
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# Set the input tensor to the interpreter
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print(input_details[0]["index"])
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print(img_data.shape)
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img_data = img_data.transpose((0, 2, 3, 1))
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scale, zero_point = input_details[0]["quantization"]
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img_data_int8 = (img_data / scale + zero_point).astype(np.int8)
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interpreter.set_tensor(input_details[0]["index"], img_data_int8)
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# Run inference
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interpreter.invoke()
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# Get the output tensor from the interpreter
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output = interpreter.get_tensor(output_details[0]["index"])
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scale, zero_point = output_details[0]["quantization"]
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output = (output.astype(np.float32) - zero_point) * scale
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output[:, [0, 2]] *= img_width
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output[:, [1, 3]] *= img_height
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print(output)
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# Perform post-processing on the outputs to obtain output image.
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return self.postprocess(self.img, output)
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if __name__ == "__main__":
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# Create an argument parser to handle command-line arguments
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parser = argparse.ArgumentParser()
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parser.add_argument(
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"--model", type=str, default="yolov8n_full_integer_quant.tflite", help="Input your TFLite model."
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)
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parser.add_argument("--img", type=str, default=str(ASSETS / "bus.jpg"), help="Path to input image.")
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parser.add_argument("--conf-thres", type=float, default=0.5, help="Confidence threshold")
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parser.add_argument("--iou-thres", type=float, default=0.5, help="NMS IoU threshold")
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args = parser.parse_args()
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# Create an instance of the Yolov8TFLite class with the specified arguments
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detection = Yolov8TFLite(args.model, args.img, args.conf_thres, args.iou_thres)
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# Perform object detection and obtain the output image
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output_image = detection.main()
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# Display the output image in a window
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cv2.imshow("Output", output_image)
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# Wait for a key press to exit
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cv2.waitKey(0)
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